Back to Multiple platform build/check report for BioC 3.6 |
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This page was generated on 2018-04-12 13:12:26 -0400 (Thu, 12 Apr 2018).
Package 971/1472 | Hostname | OS / Arch | INSTALL | BUILD | CHECK | BUILD BIN | ||||||
OncoSimulR 2.8.0 Ramon Diaz-Uriarte
| malbec1 | Linux (Ubuntu 16.04.1 LTS) / x86_64 | NotNeeded | OK | [ OK ] | |||||||
tokay1 | Windows Server 2012 R2 Standard / x64 | NotNeeded | OK | WARNINGS | OK | |||||||
veracruz1 | OS X 10.11.6 El Capitan / x86_64 | NotNeeded | OK | OK | OK |
Package: OncoSimulR |
Version: 2.8.0 |
Command: /home/biocbuild/bbs-3.6-bioc/R/bin/R CMD check --no-vignettes --timings OncoSimulR_2.8.0.tar.gz |
StartedAt: 2018-04-12 01:34:09 -0400 (Thu, 12 Apr 2018) |
EndedAt: 2018-04-12 01:41:15 -0400 (Thu, 12 Apr 2018) |
EllapsedTime: 425.9 seconds |
RetCode: 0 |
Status: OK |
CheckDir: OncoSimulR.Rcheck |
Warnings: 0 |
############################################################################## ############################################################################## ### ### Running command: ### ### /home/biocbuild/bbs-3.6-bioc/R/bin/R CMD check --no-vignettes --timings OncoSimulR_2.8.0.tar.gz ### ############################################################################## ############################################################################## * using log directory ‘/home/biocbuild/bbs-3.6-bioc/meat/OncoSimulR.Rcheck’ * using R version 3.4.4 (2018-03-15) * using platform: x86_64-pc-linux-gnu (64-bit) * using session charset: UTF-8 * using option ‘--no-vignettes’ * checking for file ‘OncoSimulR/DESCRIPTION’ ... OK * checking extension type ... Package * this is package ‘OncoSimulR’ version ‘2.8.0’ * checking package namespace information ... OK * checking package dependencies ... OK * checking if this is a source package ... OK * checking if there is a namespace ... OK * checking for hidden files and directories ... OK * checking for portable file names ... OK * checking for sufficient/correct file permissions ... OK * checking whether package ‘OncoSimulR’ can be installed ... OK * checking installed package size ... NOTE installed size is 11.2Mb sub-directories of 1Mb or more: doc 5.3Mb libs 5.3Mb * checking package directory ... OK * checking ‘build’ directory ... OK * checking DESCRIPTION meta-information ... OK * checking top-level files ... OK * checking for left-over files ... OK * checking index information ... OK * checking package subdirectories ... OK * checking R files for non-ASCII characters ... OK * checking R files for syntax errors ... OK * checking whether the package can be loaded ... OK * checking whether the package can be loaded with stated dependencies ... OK * checking whether the package can be unloaded cleanly ... OK * checking whether the namespace can be loaded with stated dependencies ... OK * checking whether the namespace can be unloaded cleanly ... OK * checking loading without being on the library search path ... OK * checking dependencies in R code ... OK * checking S3 generic/method consistency ... OK * checking replacement functions ... OK * checking foreign function calls ... OK * checking R code for possible problems ... OK * checking Rd files ... OK * checking Rd metadata ... OK * checking Rd cross-references ... OK * checking for missing documentation entries ... OK * checking for code/documentation mismatches ... OK * checking Rd \usage sections ... OK * checking Rd contents ... OK * checking for unstated dependencies in examples ... OK * checking contents of ‘data’ directory ... OK * checking data for non-ASCII characters ... OK * checking data for ASCII and uncompressed saves ... OK * checking line endings in C/C++/Fortran sources/headers ... OK * checking line endings in Makefiles ... OK * checking compilation flags in Makevars ... OK * checking for GNU extensions in Makefiles ... OK * checking for portable use of $(BLAS_LIBS) and $(LAPACK_LIBS) ... OK * checking compiled code ... OK * checking installed files from ‘inst/doc’ ... OK * checking files in ‘vignettes’ ... OK * checking examples ... OK Examples with CPU or elapsed time > 5s user system elapsed oncoSimulIndiv 6.996 0.58 5.686 * checking for unstated dependencies in ‘tests’ ... OK * checking tests ... Running ‘testthat.R’ OK * checking for unstated dependencies in vignettes ... OK * checking package vignettes in ‘inst/doc’ ... OK * checking running R code from vignettes ... SKIPPED * checking re-building of vignette outputs ... SKIPPED * checking PDF version of manual ... OK * DONE Status: 1 NOTE See ‘/home/biocbuild/bbs-3.6-bioc/meat/OncoSimulR.Rcheck/00check.log’ for details.
OncoSimulR.Rcheck/00install.out
* installing *source* package ‘OncoSimulR’ ... ** libs g++ -std=gnu++11 -I/home/biocbuild/bbs-3.6-bioc/R/include -DNDEBUG -I"/home/biocbuild/bbs-3.6-bioc/R/library/Rcpp/include" -I/usr/local/include -fpic -g -O2 -c BNB_nr.cpp -o BNB_nr.o g++ -std=gnu++11 -I/home/biocbuild/bbs-3.6-bioc/R/include -DNDEBUG -I"/home/biocbuild/bbs-3.6-bioc/R/library/Rcpp/include" -I/usr/local/include -fpic -g -O2 -c BNB_v1.cpp -o BNB_v1.o gcc -I/home/biocbuild/bbs-3.6-bioc/R/include -DNDEBUG -I"/home/biocbuild/bbs-3.6-bioc/R/library/Rcpp/include" -I/usr/local/include -fpic -g -O2 -Wall -c OncoSimulR_init.c -o OncoSimulR_init.o g++ -std=gnu++11 -I/home/biocbuild/bbs-3.6-bioc/R/include -DNDEBUG -I"/home/biocbuild/bbs-3.6-bioc/R/library/Rcpp/include" -I/usr/local/include -fpic -g -O2 -c RcppExports.cpp -o RcppExports.o g++ -std=gnu++11 -I/home/biocbuild/bbs-3.6-bioc/R/include -DNDEBUG -I"/home/biocbuild/bbs-3.6-bioc/R/library/Rcpp/include" -I/usr/local/include -fpic -g -O2 -c accessible_genotypes.cpp -o accessible_genotypes.o g++ -std=gnu++11 -I/home/biocbuild/bbs-3.6-bioc/R/include -DNDEBUG -I"/home/biocbuild/bbs-3.6-bioc/R/library/Rcpp/include" -I/usr/local/include -fpic -g -O2 -c bnb_common.cpp -o bnb_common.o g++ -std=gnu++11 -I/home/biocbuild/bbs-3.6-bioc/R/include -DNDEBUG -I"/home/biocbuild/bbs-3.6-bioc/R/library/Rcpp/include" -I/usr/local/include -fpic -g -O2 -c new_restrict.cpp -o new_restrict.o g++ -std=gnu++11 -I/home/biocbuild/bbs-3.6-bioc/R/include -DNDEBUG -I"/home/biocbuild/bbs-3.6-bioc/R/library/Rcpp/include" -I/usr/local/include -fpic -g -O2 -c new_restrict_former_print_utils.cpp -o new_restrict_former_print_utils.o g++ -std=gnu++11 -shared -L/home/biocbuild/bbs-3.6-bioc/R/lib -L/usr/local/lib -o OncoSimulR.so BNB_nr.o BNB_v1.o OncoSimulR_init.o RcppExports.o accessible_genotypes.o bnb_common.o new_restrict.o new_restrict_former_print_utils.o -L/home/biocbuild/bbs-3.6-bioc/R/lib -lR installing to /home/biocbuild/bbs-3.6-bioc/meat/OncoSimulR.Rcheck/OncoSimulR/libs ** R ** data ** inst ** preparing package for lazy loading ** help *** installing help indices ** building package indices ** installing vignettes ** testing if installed package can be loaded * DONE (OncoSimulR)
OncoSimulR.Rcheck/tests/testthat.Rout
R version 3.4.4 (2018-03-15) -- "Someone to Lean On" Copyright (C) 2018 The R Foundation for Statistical Computing Platform: x86_64-pc-linux-gnu (64-bit) R is free software and comes with ABSOLUTELY NO WARRANTY. You are welcome to redistribute it under certain conditions. Type 'license()' or 'licence()' for distribution details. R is a collaborative project with many contributors. Type 'contributors()' for more information and 'citation()' on how to cite R or R packages in publications. Type 'demo()' for some demos, 'help()' for on-line help, or 'help.start()' for an HTML browser interface to help. Type 'q()' to quit R. > library(testthat) > # library(OncoSimulR) > > test_check("OncoSimulR") Loading required package: OncoSimulR Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. ... output from mue11 Individual OncoSimul trajectory with call: oncoSimulIndiv(fp = fe31, model = "McFL", mu = 1e-06, detectionSize = 5e+06, initSize = 1e+05, finalTime = 5, onlyCancer = FALSE) NumClones TotalPopSize LargestClone MaxNumDrivers MaxDriversLast 1 7 99552 99538 1 0 NumDriversLargestPop TotalPresentDrivers FinalTime NumIter HittedWallTime 1 0 1 5 206 FALSE HittedMaxTries errorMF minDMratio minBMratio OccurringDrivers 1 FALSE 0.001230723 99677.1 1e+05 g2 Final population composition: Genotype N 1 99538 2 g2 0 3 g3 5 4 g6 0 5 g8 1 6 g9 0 7 g10 8 Hitted wall time. Exiting. Hitting wall time is regarded as an error. Using 17400 as seed for C++ generator *** Looping through 5.2. Iter = 1 iteration 1; minNextMutationTime = 11; timeNextPopSample = 1; popParams.size() = 1 We are SAMPLING at time 1 *** Looping through 5.2. Iter = 2 iteration 2; minNextMutationTime = 12; timeNextPopSample = 2; popParams.size() = 1 We are SAMPLING at time 2 *** Looping through 5.2. Iter = 3 iteration 3; minNextMutationTime = 13; timeNextPopSample = 3; popParams.size() = 1 We are SAMPLING at time 3 *** Looping through 5.2. Iter = 4 iteration 4; minNextMutationTime = 14; timeNextPopSample = 4; popParams.size() = 1 We are SAMPLING at time 4 *** Looping through 5.2. Iter = 5 iteration 5; minNextMutationTime = 15; timeNextPopSample = 5; popParams.size() = 1 We are SAMPLING at time 5 *** Looping through 5.2. Iter = 6 iteration 6; minNextMutationTime = 16; timeNextPopSample = 6; popParams.size() = 1 We are SAMPLING at time 6 *** Looping through 5.2. Iter = 7 iteration 7; minNextMutationTime = 17; timeNextPopSample = 7; popParams.size() = 1 We are SAMPLING at time 7 *** Looping through 5.2. Iter = 8 iteration 8; minNextMutationTime = 18; timeNextPopSample = 8; popParams.size() = 1 We are SAMPLING at time 8 *** Looping through 5.2. Iter = 9 iteration 9; minNextMutationTime = 19; timeNextPopSample = 9; popParams.size() = 1 We are SAMPLING at time 9 *** Looping through 5.2. Iter = 10 iteration 10; minNextMutationTime = 20; timeNextPopSample = 10; popParams.size() = 1 We are SAMPLING at time 10 *** Looping through 5.2. Iter = 11 iteration 11; minNextMutationTime = 21; timeNextPopSample = 11; popParams.size() = 1 We are SAMPLING at time 11 *** Looping through 5.2. Iter = 12 iteration 12; minNextMutationTime = 22; timeNextPopSample = 12; popParams.size() = 1 We are SAMPLING at time 12 *** Looping through 5.2. Iter = 13 iteration 13; minNextMutationTime = 23; timeNextPopSample = 13; popParams.size() = 1 We are SAMPLING at time 13 *** Looping through 5.2. Iter = 14 iteration 14; minNextMutationTime = 24; timeNextPopSample = 14; popParams.size() = 1 We are SAMPLING at time 14 *** Looping through 5.2. Iter = 15 iteration 15; minNextMutationTime = 25; timeNextPopSample = 15; popParams.size() = 1 We are SAMPLING at time 15 *** Looping through 5.2. Iter = 16 iteration 16; minNextMutationTime = 26; timeNextPopSample = 16; popParams.size() = 1 We are SAMPLING at time 16 *** Looping through 5.2. Iter = 17 iteration 17; minNextMutationTime = 27; timeNextPopSample = 17; popParams.size() = 1 We are SAMPLING at time 17 *** Looping through 5.2. Iter = 18 iteration 18; minNextMutationTime = 28; timeNextPopSample = 18; popParams.size() = 1 We are SAMPLING at time 18 *** Looping through 5.2. Iter = 19 iteration 19; minNextMutationTime = 29; timeNextPopSample = 19; popParams.size() = 1 We are SAMPLING at time 19 *** Looping through 5.2. Iter = 20 iteration 20; minNextMutationTime = 30; timeNextPopSample = 20; popParams.size() = 1 We are SAMPLING at time 20 *** Looping through 5.2. Iter = 21 iteration 21; minNextMutationTime = 31; timeNextPopSample = 21; popParams.size() = 1 We are SAMPLING at time 21 *** Looping through 5.2. Iter = 22 iteration 22; minNextMutationTime = 32; timeNextPopSample = 22; popParams.size() = 1 We are SAMPLING at time 22 *** Looping through 5.2. Iter = 23 iteration 23; minNextMutationTime = 33; timeNextPopSample = 23; popParams.size() = 1 We are SAMPLING at time 23 *** Looping through 5.2. Iter = 24 iteration 24; minNextMutationTime = 34; timeNextPopSample = 24; popParams.size() = 1 We are SAMPLING at time 24 *** Looping through 5.2. Iter = 25 iteration 25; minNextMutationTime = 35; timeNextPopSample = 25; popParams.size() = 1 We are SAMPLING at time 25 *** Looping through 5.2. Iter = 26 iteration 26; minNextMutationTime = 36; timeNextPopSample = 26; popParams.size() = 1 We are SAMPLING at time 26 *** Looping through 5.2. Iter = 27 iteration 27; minNextMutationTime = 37; timeNextPopSample = 27; popParams.size() = 1 We are SAMPLING at time 27 *** Looping through 5.2. Iter = 28 iteration 28; minNextMutationTime = 27.4816; timeNextPopSample = 28; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 29 iteration 29; minNextMutationTime = 38; timeNextPopSample = 28; popParams.size() = 2 We are SAMPLING at time 28 *** Looping through 5.2. Iter = 30 iteration 30; minNextMutationTime = 39; timeNextPopSample = 29; popParams.size() = 2 We are SAMPLING at time 29 *** Looping through 5.2. Iter = 31 iteration 31; minNextMutationTime = 40; timeNextPopSample = 30; popParams.size() = 1 We are SAMPLING at time 30 *** Looping through 5.2. Iter = 32 iteration 32; minNextMutationTime = 30.8538; timeNextPopSample = 31; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 33 iteration 33; minNextMutationTime = 41; timeNextPopSample = 31; popParams.size() = 2 We are SAMPLING at time 31 *** Looping through 5.2. Iter = 34 iteration 34; minNextMutationTime = 42; timeNextPopSample = 32; popParams.size() = 2 We are SAMPLING at time 32 *** Looping through 5.2. Iter = 35 iteration 35; minNextMutationTime = 43; timeNextPopSample = 33; popParams.size() = 1 We are SAMPLING at time 33 *** Looping through 5.2. Iter = 36 iteration 36; minNextMutationTime = 44; timeNextPopSample = 34; popParams.size() = 1 We are SAMPLING at time 34 *** Looping through 5.2. Iter = 37 iteration 37; minNextMutationTime = 45; timeNextPopSample = 35; popParams.size() = 1 We are SAMPLING at time 35 *** Looping through 5.2. Iter = 38 iteration 38; minNextMutationTime = 46; timeNextPopSample = 36; popParams.size() = 1 We are SAMPLING at time 36 *** Looping through 5.2. Iter = 39 iteration 39; minNextMutationTime = 47; timeNextPopSample = 37; popParams.size() = 1 We are SAMPLING at time 37 *** Looping through 5.2. Iter = 40 iteration 40; minNextMutationTime = 37.6018; timeNextPopSample = 38; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 41 iteration 41; minNextMutationTime = 48; timeNextPopSample = 38; popParams.size() = 2 We are SAMPLING at time 38 *** Looping through 5.2. Iter = 42 iteration 42; minNextMutationTime = 49; timeNextPopSample = 39; popParams.size() = 2 We are SAMPLING at time 39 *** Looping through 5.2. Iter = 43 iteration 43; minNextMutationTime = 50; timeNextPopSample = 40; popParams.size() = 2 We are SAMPLING at time 40 *** Looping through 5.2. Iter = 44 iteration 44; minNextMutationTime = 51; timeNextPopSample = 41; popParams.size() = 2 We are SAMPLING at time 41 *** Looping through 5.2. Iter = 45 iteration 45; minNextMutationTime = 52; timeNextPopSample = 42; popParams.size() = 1 We are SAMPLING at time 42 *** Looping through 5.2. Iter = 46 iteration 46; minNextMutationTime = 53; timeNextPopSample = 43; popParams.size() = 1 We are SAMPLING at time 43 *** Looping through 5.2. Iter = 47 iteration 47; minNextMutationTime = 43.5756; timeNextPopSample = 44; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 48 iteration 48; minNextMutationTime = 54; timeNextPopSample = 44; popParams.size() = 2 We are SAMPLING at time 44 *** Looping through 5.2. Iter = 49 iteration 49; minNextMutationTime = 55; timeNextPopSample = 45; popParams.size() = 2 We are SAMPLING at time 45 *** Looping through 5.2. Iter = 50 iteration 50; minNextMutationTime = 56; timeNextPopSample = 46; popParams.size() = 1 We are SAMPLING at time 46 *** Looping through 5.2. Iter = 51 iteration 51; minNextMutationTime = 46.7129; timeNextPopSample = 47; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 52 iteration 52; minNextMutationTime = 57; timeNextPopSample = 47; popParams.size() = 2 We are SAMPLING at time 47 *** Looping through 5.2. Iter = 53 iteration 53; minNextMutationTime = 58; timeNextPopSample = 48; popParams.size() = 1 We are SAMPLING at time 48 *** Looping through 5.2. Iter = 54 iteration 54; minNextMutationTime = 59; timeNextPopSample = 49; popParams.size() = 1 We are SAMPLING at time 49 *** Looping through 5.2. Iter = 55 iteration 55; minNextMutationTime = 60; timeNextPopSample = 50; popParams.size() = 1 We are SAMPLING at time 50 *** Looping through 5.2. Iter = 56 iteration 56; minNextMutationTime = 61; timeNextPopSample = 51; popParams.size() = 1 We are SAMPLING at time 51 *** Looping through 5.2. Iter = 57 iteration 57; minNextMutationTime = 62; timeNextPopSample = 52; popParams.size() = 1 We are SAMPLING at time 52 *** Looping through 5.2. Iter = 58 iteration 58; minNextMutationTime = 63; timeNextPopSample = 53; popParams.size() = 1 We are SAMPLING at time 53 *** Looping through 5.2. Iter = 59 iteration 59; minNextMutationTime = 64; timeNextPopSample = 54; popParams.size() = 1 We are SAMPLING at time 54 *** Looping through 5.2. Iter = 60 iteration 60; minNextMutationTime = 65; timeNextPopSample = 55; popParams.size() = 1 We are SAMPLING at time 55 *** Looping through 5.2. Iter = 61 iteration 61; minNextMutationTime = 66; timeNextPopSample = 56; popParams.size() = 1 We are SAMPLING at time 56 *** Looping through 5.2. Iter = 62 iteration 62; minNextMutationTime = 67; timeNextPopSample = 57; popParams.size() = 1 We are SAMPLING at time 57 *** Looping through 5.2. Iter = 63 iteration 63; minNextMutationTime = 68; timeNextPopSample = 58; popParams.size() = 1 We are SAMPLING at time 58 *** Looping through 5.2. Iter = 64 iteration 64; minNextMutationTime = 69; timeNextPopSample = 59; popParams.size() = 1 We are SAMPLING at time 59 *** Looping through 5.2. Iter = 65 iteration 65; minNextMutationTime = 70; timeNextPopSample = 60; popParams.size() = 1 We are SAMPLING at time 60 *** Looping through 5.2. Iter = 66 iteration 66; minNextMutationTime = 60.5645; timeNextPopSample = 61; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 67 iteration 67; minNextMutationTime = 71; timeNextPopSample = 61; popParams.size() = 2 We are SAMPLING at time 61 *** Looping through 5.2. Iter = 68 iteration 68; minNextMutationTime = 72; timeNextPopSample = 62; popParams.size() = 2 We are SAMPLING at time 62 *** Looping through 5.2. Iter = 69 iteration 69; minNextMutationTime = 73; timeNextPopSample = 63; popParams.size() = 2 We are SAMPLING at time 63 *** Looping through 5.2. Iter = 70 iteration 70; minNextMutationTime = 74; timeNextPopSample = 64; popParams.size() = 2 We are SAMPLING at time 64 *** Looping through 5.2. Iter = 71 iteration 71; minNextMutationTime = 75; timeNextPopSample = 65; popParams.size() = 2 We are SAMPLING at time 65 *** Looping through 5.2. Iter = 72 iteration 72; minNextMutationTime = 76; timeNextPopSample = 66; popParams.size() = 1 We are SAMPLING at time 66 *** Looping through 5.2. Iter = 73 iteration 73; minNextMutationTime = 77; timeNextPopSample = 67; popParams.size() = 1 We are SAMPLING at time 67 *** Looping through 5.2. Iter = 74 iteration 74; minNextMutationTime = 78; timeNextPopSample = 68; popParams.size() = 1 We are SAMPLING at time 68 *** Looping through 5.2. Iter = 75 iteration 75; minNextMutationTime = 79; timeNextPopSample = 69; popParams.size() = 1 We are SAMPLING at time 69 *** Looping through 5.2. Iter = 76 iteration 76; minNextMutationTime = 80; timeNextPopSample = 70; popParams.size() = 1 We are SAMPLING at time 70 *** Looping through 5.2. Iter = 77 iteration 77; minNextMutationTime = 81; timeNextPopSample = 71; popParams.size() = 1 We are SAMPLING at time 71 *** Looping through 5.2. Iter = 78 iteration 78; minNextMutationTime = 82; timeNextPopSample = 72; popParams.size() = 1 We are SAMPLING at time 72 *** Looping through 5.2. Iter = 79 iteration 79; minNextMutationTime = 83; timeNextPopSample = 73; popParams.size() = 1 We are SAMPLING at time 73 *** Looping through 5.2. Iter = 80 iteration 80; minNextMutationTime = 84; timeNextPopSample = 74; popParams.size() = 1 We are SAMPLING at time 74 *** Looping through 5.2. Iter = 81 iteration 81; minNextMutationTime = 85; timeNextPopSample = 75; popParams.size() = 1 We are SAMPLING at time 75 *** Looping through 5.2. Iter = 82 iteration 82; minNextMutationTime = 86; timeNextPopSample = 76; popParams.size() = 1 We are SAMPLING at time 76 *** Looping through 5.2. Iter = 83 iteration 83; minNextMutationTime = 87; timeNextPopSample = 77; popParams.size() = 1 We are SAMPLING at time 77 *** Looping through 5.2. Iter = 84 iteration 84; minNextMutationTime = 88; timeNextPopSample = 78; popParams.size() = 1 We are SAMPLING at time 78 *** Looping through 5.2. Iter = 85 iteration 85; minNextMutationTime = 89; timeNextPopSample = 79; popParams.size() = 1 We are SAMPLING at time 79 *** Looping through 5.2. Iter = 86 iteration 86; minNextMutationTime = 90; timeNextPopSample = 80; popParams.size() = 1 We are SAMPLING at time 80 *** Looping through 5.2. Iter = 87 iteration 87; minNextMutationTime = 91; timeNextPopSample = 81; popParams.size() = 1 We are SAMPLING at time 81 *** Looping through 5.2. Iter = 88 iteration 88; minNextMutationTime = 92; timeNextPopSample = 82; popParams.size() = 1 We are SAMPLING at time 82 *** Looping through 5.2. Iter = 89 iteration 89; minNextMutationTime = 93; timeNextPopSample = 83; popParams.size() = 1 We are SAMPLING at time 83 *** Looping through 5.2. Iter = 90 iteration 90; minNextMutationTime = 94; timeNextPopSample = 84; popParams.size() = 1 We are SAMPLING at time 84 *** Looping through 5.2. Iter = 91 iteration 91; minNextMutationTime = 95; timeNextPopSample = 85; popParams.size() = 1 We are SAMPLING at time 85 *** Looping through 5.2. Iter = 92 iteration 92; minNextMutationTime = 96; timeNextPopSample = 86; popParams.size() = 1 We are SAMPLING at time 86 *** Looping through 5.2. Iter = 93 iteration 93; minNextMutationTime = 86.7149; timeNextPopSample = 87; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 94 iteration 94; minNextMutationTime = 97; timeNextPopSample = 87; popParams.size() = 2 We are SAMPLING at time 87 *** Looping through 5.2. Iter = 95 iteration 95; minNextMutationTime = 98; timeNextPopSample = 88; popParams.size() = 2 We are SAMPLING at time 88 *** Looping through 5.2. Iter = 96 iteration 96; minNextMutationTime = 99; timeNextPopSample = 89; popParams.size() = 1 We are SAMPLING at time 89 *** Looping through 5.2. Iter = 97 iteration 97; minNextMutationTime = 89.7251; timeNextPopSample = 90; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 98 iteration 98; minNextMutationTime = 100; timeNextPopSample = 90; popParams.size() = 2 We are SAMPLING at time 90 *** Looping through 5.2. Iter = 99 iteration 99; minNextMutationTime = 90.3587; timeNextPopSample = 91; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 100 iteration 100; minNextMutationTime = 101; timeNextPopSample = 91; popParams.size() = 3 We are SAMPLING at time 91 *** Looping through 5.2. Iter = 101 iteration 101; minNextMutationTime = 102; timeNextPopSample = 92; popParams.size() = 2 We are SAMPLING at time 92 *** Looping through 5.2. Iter = 102 iteration 102; minNextMutationTime = 103; timeNextPopSample = 93; popParams.size() = 2 We are SAMPLING at time 93 *** Looping through 5.2. Iter = 103 iteration 103; minNextMutationTime = 104; timeNextPopSample = 94; popParams.size() = 2 We are SAMPLING at time 94 *** Looping through 5.2. Iter = 104 iteration 104; minNextMutationTime = 105; timeNextPopSample = 95; popParams.size() = 2 We are SAMPLING at time 95 *** Looping through 5.2. Iter = 105 iteration 105; minNextMutationTime = 106; timeNextPopSample = 96; popParams.size() = 1 We are SAMPLING at time 96 *** Looping through 5.2. Iter = 106 iteration 106; minNextMutationTime = 107; timeNextPopSample = 97; popParams.size() = 1 We are SAMPLING at time 97 *** Looping through 5.2. Iter = 107 iteration 107; minNextMutationTime = 108; timeNextPopSample = 98; popParams.size() = 1 We are SAMPLING at time 98 *** Looping through 5.2. Iter = 108 iteration 108; minNextMutationTime = 109; timeNextPopSample = 99; popParams.size() = 1 We are SAMPLING at time 99 *** Looping through 5.2. Iter = 109 iteration 109; minNextMutationTime = 110; timeNextPopSample = 100; popParams.size() = 1 We are SAMPLING at time 100 *** Looping through 5.2. Iter = 110 iteration 110; minNextMutationTime = 111; timeNextPopSample = 101; popParams.size() = 1 We are SAMPLING at time 101 *** Looping through 5.2. Iter = 111 iteration 111; minNextMutationTime = 112; timeNextPopSample = 102; popParams.size() = 1 We are SAMPLING at time 102 *** Looping through 5.2. Iter = 112 iteration 112; minNextMutationTime = 113; timeNextPopSample = 103; popParams.size() = 1 We are SAMPLING at time 103 *** Looping through 5.2. Iter = 113 iteration 113; minNextMutationTime = 114; timeNextPopSample = 104; popParams.size() = 1 We are SAMPLING at time 104 *** Looping through 5.2. Iter = 114 iteration 114; minNextMutationTime = 115; timeNextPopSample = 105; popParams.size() = 1 We are SAMPLING at time 105 *** Looping through 5.2. Iter = 115 iteration 115; minNextMutationTime = 116; timeNextPopSample = 106; popParams.size() = 1 We are SAMPLING at time 106 *** Looping through 5.2. Iter = 116 iteration 116; minNextMutationTime = 117; timeNextPopSample = 107; popParams.size() = 1 We are SAMPLING at time 107 *** Looping through 5.2. Iter = 117 iteration 117; minNextMutationTime = 118; timeNextPopSample = 108; popParams.size() = 1 We are SAMPLING at time 108 *** Looping through 5.2. Iter = 118 iteration 118; minNextMutationTime = 119; timeNextPopSample = 109; popParams.size() = 1 We are SAMPLING at time 109 *** Looping through 5.2. Iter = 119 iteration 119; minNextMutationTime = 120; timeNextPopSample = 110; popParams.size() = 1 We are SAMPLING at time 110 *** Looping through 5.2. Iter = 120 iteration 120; minNextMutationTime = 121; timeNextPopSample = 111; popParams.size() = 1 We are SAMPLING at time 111 *** Looping through 5.2. Iter = 121 iteration 121; minNextMutationTime = 111.921; timeNextPopSample = 112; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 122 iteration 122; minNextMutationTime = 122; timeNextPopSample = 112; popParams.size() = 2 We are SAMPLING at time 112 *** Looping through 5.2. Iter = 123 iteration 123; minNextMutationTime = 123; timeNextPopSample = 113; popParams.size() = 2 We are SAMPLING at time 113 *** Looping through 5.2. Iter = 124 iteration 124; minNextMutationTime = 124; timeNextPopSample = 114; popParams.size() = 1 We are SAMPLING at time 114 *** Looping through 5.2. Iter = 125 iteration 125; minNextMutationTime = 125; timeNextPopSample = 115; popParams.size() = 1 We are SAMPLING at time 115 *** Looping through 5.2. Iter = 126 iteration 126; minNextMutationTime = 126; timeNextPopSample = 116; popParams.size() = 1 We are SAMPLING at time 116 *** Looping through 5.2. Iter = 127 iteration 127; minNextMutationTime = 116.291; timeNextPopSample = 117; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 128 iteration 128; minNextMutationTime = 127; timeNextPopSample = 117; popParams.size() = 2 We are SAMPLING at time 117 *** Looping through 5.2. Iter = 129 iteration 129; minNextMutationTime = 128; timeNextPopSample = 118; popParams.size() = 2 We are SAMPLING at time 118 *** Looping through 5.2. Iter = 130 iteration 130; minNextMutationTime = 129; timeNextPopSample = 119; popParams.size() = 1 We are SAMPLING at time 119 *** Looping through 5.2. Iter = 131 iteration 131; minNextMutationTime = 119.614; timeNextPopSample = 120; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 132 iteration 132; minNextMutationTime = 130; timeNextPopSample = 120; popParams.size() = 2 We are SAMPLING at time 120 *** Looping through 5.2. Iter = 133 iteration 133; minNextMutationTime = 131; timeNextPopSample = 121; popParams.size() = 2 We are SAMPLING at time 121 *** Looping through 5.2. Iter = 134 iteration 134; minNextMutationTime = 121.049; timeNextPopSample = 122; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 135 iteration 135; minNextMutationTime = 132; timeNextPopSample = 122; popParams.size() = 2 We are SAMPLING at time 122 *** Looping through 5.2. Iter = 136 iteration 136; minNextMutationTime = 133; timeNextPopSample = 123; popParams.size() = 1 We are SAMPLING at time 123 *** Looping through 5.2. Iter = 137 iteration 137; minNextMutationTime = 134; timeNextPopSample = 124; popParams.size() = 1 We are SAMPLING at time 124 *** Looping through 5.2. Iter = 138 iteration 138; minNextMutationTime = 135; timeNextPopSample = 125; popParams.size() = 1 We are SAMPLING at time 125 *** Looping through 5.2. Iter = 139 iteration 139; minNextMutationTime = 136; timeNextPopSample = 126; popParams.size() = 1 We are SAMPLING at time 126 *** Looping through 5.2. Iter = 140 iteration 140; minNextMutationTime = 137; timeNextPopSample = 127; popParams.size() = 1 We are SAMPLING at time 127 *** Looping through 5.2. Iter = 141 iteration 141; minNextMutationTime = 138; timeNextPopSample = 128; popParams.size() = 1 We are SAMPLING at time 128 *** Looping through 5.2. Iter = 142 iteration 142; minNextMutationTime = 139; timeNextPopSample = 129; popParams.size() = 1 We are SAMPLING at time 129 *** Looping through 5.2. Iter = 143 iteration 143; minNextMutationTime = 140; timeNextPopSample = 130; popParams.size() = 1 We are SAMPLING at time 130 *** Looping through 5.2. Iter = 144 iteration 144; minNextMutationTime = 141; timeNextPopSample = 131; popParams.size() = 1 We are SAMPLING at time 131 *** Looping through 5.2. Iter = 145 iteration 145; minNextMutationTime = 142; timeNextPopSample = 132; popParams.size() = 1 We are SAMPLING at time 132 *** Looping through 5.2. Iter = 146 iteration 146; minNextMutationTime = 143; timeNextPopSample = 133; popParams.size() = 1 We are SAMPLING at time 133 *** Looping through 5.2. Iter = 147 iteration 147; minNextMutationTime = 133.209; timeNextPopSample = 134; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 148 iteration 148; minNextMutationTime = 144; timeNextPopSample = 134; popParams.size() = 2 We are SAMPLING at time 134 *** Looping through 5.2. Iter = 149 iteration 149; minNextMutationTime = 145; timeNextPopSample = 135; popParams.size() = 2 We are SAMPLING at time 135 *** Looping through 5.2. Iter = 150 iteration 150; minNextMutationTime = 146; timeNextPopSample = 136; popParams.size() = 1 We are SAMPLING at time 136 *** Looping through 5.2. Iter = 151 iteration 151; minNextMutationTime = 147; timeNextPopSample = 137; popParams.size() = 1 We are SAMPLING at time 137 *** Looping through 5.2. Iter = 152 iteration 152; minNextMutationTime = 148; timeNextPopSample = 138; popParams.size() = 1 We are SAMPLING at time 138 *** Looping through 5.2. Iter = 153 iteration 153; minNextMutationTime = 149; timeNextPopSample = 139; popParams.size() = 1 We are SAMPLING at time 139 *** Looping through 5.2. Iter = 154 iteration 154; minNextMutationTime = 150; timeNextPopSample = 140; popParams.size() = 1 We are SAMPLING at time 140 *** Looping through 5.2. Iter = 155 iteration 155; minNextMutationTime = 151; timeNextPopSample = 141; popParams.size() = 1 We are SAMPLING at time 141 *** Looping through 5.2. Iter = 156 iteration 156; minNextMutationTime = 141.895; timeNextPopSample = 142; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 157 iteration 157; minNextMutationTime = 152; timeNextPopSample = 142; popParams.size() = 2 We are SAMPLING at time 142 *** Looping through 5.2. Iter = 158 iteration 158; minNextMutationTime = 153; timeNextPopSample = 143; popParams.size() = 2 We are SAMPLING at time 143 *** Looping through 5.2. Iter = 159 iteration 159; minNextMutationTime = 154; timeNextPopSample = 144; popParams.size() = 2 We are SAMPLING at time 144 *** Looping through 5.2. Iter = 160 iteration 160; minNextMutationTime = 155; timeNextPopSample = 145; popParams.size() = 2 We are SAMPLING at time 145 *** Looping through 5.2. Iter = 161 iteration 161; minNextMutationTime = 156; timeNextPopSample = 146; popParams.size() = 2 We are SAMPLING at time 146 *** Looping through 5.2. Iter = 162 iteration 162; minNextMutationTime = 157; timeNextPopSample = 147; popParams.size() = 2 We are SAMPLING at time 147 *** Looping through 5.2. Iter = 163 iteration 163; minNextMutationTime = 158; timeNextPopSample = 148; popParams.size() = 2 We are SAMPLING at time 148 *** Looping through 5.2. Iter = 164 iteration 164; minNextMutationTime = 148.65; timeNextPopSample = 149; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 165 iteration 165; minNextMutationTime = 159; timeNextPopSample = 149; popParams.size() = 3 We are SAMPLING at time 149 *** Looping through 5.2. Iter = 166 iteration 166; minNextMutationTime = 160; timeNextPopSample = 150; popParams.size() = 3 We are SAMPLING at time 150 *** Looping through 5.2. Iter = 167 iteration 167; minNextMutationTime = 161; timeNextPopSample = 151; popParams.size() = 3 We are SAMPLING at time 151 *** Looping through 5.2. Iter = 168 iteration 168; minNextMutationTime = 162; timeNextPopSample = 152; popParams.size() = 2 We are SAMPLING at time 152 *** Looping through 5.2. Iter = 169 iteration 169; minNextMutationTime = 163; timeNextPopSample = 153; popParams.size() = 2 We are SAMPLING at time 153 *** Looping through 5.2. Iter = 170 iteration 170; minNextMutationTime = 164; timeNextPopSample = 154; popParams.size() = 1 We are SAMPLING at time 154 *** Looping through 5.2. Iter = 171 iteration 171; minNextMutationTime = 165; timeNextPopSample = 155; popParams.size() = 1 We are SAMPLING at time 155 *** Looping through 5.2. Iter = 172 iteration 172; minNextMutationTime = 166; timeNextPopSample = 156; popParams.size() = 1 We are SAMPLING at time 156 *** Looping through 5.2. Iter = 173 iteration 173; minNextMutationTime = 167; timeNextPopSample = 157; popParams.size() = 1 We are SAMPLING at time 157 *** Looping through 5.2. Iter = 174 iteration 174; minNextMutationTime = 157.14; timeNextPopSample = 158; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 175 iteration 175; minNextMutationTime = 157.689; timeNextPopSample = 158; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 176 iteration 176; minNextMutationTime = 157.878; timeNextPopSample = 158; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 177 iteration 177; minNextMutationTime = 168; timeNextPopSample = 158; popParams.size() = 4 We are SAMPLING at time 158 *** Looping through 5.2. Iter = 178 iteration 178; minNextMutationTime = 169; timeNextPopSample = 159; popParams.size() = 4 We are SAMPLING at time 159 *** Looping through 5.2. Iter = 179 iteration 179; minNextMutationTime = 159.023; timeNextPopSample = 160; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 180 iteration 180; minNextMutationTime = 170; timeNextPopSample = 160; popParams.size() = 3 We are SAMPLING at time 160 *** Looping through 5.2. Iter = 181 iteration 181; minNextMutationTime = 160.19; timeNextPopSample = 161; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 182 iteration 182; minNextMutationTime = 171; timeNextPopSample = 161; popParams.size() = 2 We are SAMPLING at time 161 *** Looping through 5.2. Iter = 183 iteration 183; minNextMutationTime = 172; timeNextPopSample = 162; popParams.size() = 2 We are SAMPLING at time 162 *** Looping through 5.2. Iter = 184 iteration 184; minNextMutationTime = 173; timeNextPopSample = 163; popParams.size() = 2 We are SAMPLING at time 163 *** Looping through 5.2. Iter = 185 iteration 185; minNextMutationTime = 174; timeNextPopSample = 164; popParams.size() = 2 We are SAMPLING at time 164 *** Looping through 5.2. Iter = 186 iteration 186; minNextMutationTime = 175; timeNextPopSample = 165; popParams.size() = 2 We are SAMPLING at time 165 *** Looping through 5.2. Iter = 187 iteration 187; minNextMutationTime = 176; timeNextPopSample = 166; popParams.size() = 2 We are SAMPLING at time 166 *** Looping through 5.2. Iter = 188 iteration 188; minNextMutationTime = 177; timeNextPopSample = 167; popParams.size() = 2 We are SAMPLING at time 167 *** Looping through 5.2. Iter = 189 iteration 189; minNextMutationTime = 178; timeNextPopSample = 168; popParams.size() = 2 We are SAMPLING at time 168 *** Looping through 5.2. Iter = 190 iteration 190; minNextMutationTime = 179; timeNextPopSample = 169; popParams.size() = 2 We are SAMPLING at time 169 *** Looping through 5.2. Iter = 191 iteration 191; minNextMutationTime = 180; timeNextPopSample = 170; popParams.size() = 2 We are SAMPLING at time 170 *** Looping through 5.2. Iter = 192 iteration 192; minNextMutationTime = 181; timeNextPopSample = 171; popParams.size() = 2 We are SAMPLING at time 171 *** Looping through 5.2. Iter = 193 iteration 193; minNextMutationTime = 182; timeNextPopSample = 172; popParams.size() = 2 We are SAMPLING at time 172 *** Looping through 5.2. Iter = 194 iteration 194; minNextMutationTime = 183; timeNextPopSample = 173; popParams.size() = 2 We are SAMPLING at time 173 *** Looping through 5.2. Iter = 195 iteration 195; minNextMutationTime = 184; timeNextPopSample = 174; popParams.size() = 2 We are SAMPLING at time 174 *** Looping through 5.2. Iter = 196 iteration 196; minNextMutationTime = 185; timeNextPopSample = 175; popParams.size() = 2 We are SAMPLING at time 175 *** Looping through 5.2. Iter = 197 iteration 197; minNextMutationTime = 186; timeNextPopSample = 176; popParams.size() = 2 We are SAMPLING at time 176 *** Looping through 5.2. Iter = 198 iteration 198; minNextMutationTime = 187; timeNextPopSample = 177; popParams.size() = 2 We are SAMPLING at time 177 *** Looping through 5.2. Iter = 199 iteration 199; minNextMutationTime = 188; timeNextPopSample = 178; popParams.size() = 2 We are SAMPLING at time 178 *** Looping through 5.2. Iter = 200 iteration 200; minNextMutationTime = 189; timeNextPopSample = 179; popParams.size() = 2 We are SAMPLING at time 179 *** Looping through 5.2. Iter = 201 iteration 201; minNextMutationTime = 190; timeNextPopSample = 180; popParams.size() = 2 We are SAMPLING at time 180 *** Looping through 5.2. Iter = 202 iteration 202; minNextMutationTime = 191; timeNextPopSample = 181; popParams.size() = 2 We are SAMPLING at time 181 *** Looping through 5.2. Iter = 203 iteration 203; minNextMutationTime = 192; timeNextPopSample = 182; popParams.size() = 2 We are SAMPLING at time 182 *** Looping through 5.2. Iter = 204 iteration 204; minNextMutationTime = 193; timeNextPopSample = 183; popParams.size() = 2 We are SAMPLING at time 183 *** Looping through 5.2. Iter = 205 iteration 205; minNextMutationTime = 183.736; timeNextPopSample = 184; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 206 iteration 206; minNextMutationTime = 194; timeNextPopSample = 184; popParams.size() = 3 We are SAMPLING at time 184 *** Looping through 5.2. Iter = 207 iteration 207; minNextMutationTime = 184.219; timeNextPopSample = 185; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 208 iteration 208; minNextMutationTime = 195; timeNextPopSample = 185; popParams.size() = 4 We are SAMPLING at time 185 *** Looping through 5.2. Iter = 209 iteration 209; minNextMutationTime = 196; timeNextPopSample = 186; popParams.size() = 3 We are SAMPLING at time 186 *** Looping through 5.2. Iter = 210 iteration 210; minNextMutationTime = 197; timeNextPopSample = 187; popParams.size() = 3 We are SAMPLING at time 187 *** Looping through 5.2. Iter = 211 iteration 211; minNextMutationTime = 198; timeNextPopSample = 188; popParams.size() = 2 We are SAMPLING at time 188 *** Looping through 5.2. Iter = 212 iteration 212; minNextMutationTime = 199; timeNextPopSample = 189; popParams.size() = 2 We are SAMPLING at time 189 *** Looping through 5.2. Iter = 213 iteration 213; minNextMutationTime = 200; timeNextPopSample = 190; popParams.size() = 2 We are SAMPLING at time 190 *** Looping through 5.2. Iter = 214 iteration 214; minNextMutationTime = 201; timeNextPopSample = 191; popParams.size() = 2 We are SAMPLING at time 191 *** Looping through 5.2. Iter = 215 iteration 215; minNextMutationTime = 202; timeNextPopSample = 192; popParams.size() = 2 We are SAMPLING at time 192 *** Looping through 5.2. Iter = 216 iteration 216; minNextMutationTime = 203; timeNextPopSample = 193; popParams.size() = 2 We are SAMPLING at time 193 *** Looping through 5.2. Iter = 217 iteration 217; minNextMutationTime = 204; timeNextPopSample = 194; popParams.size() = 2 We are SAMPLING at time 194 *** Looping through 5.2. Iter = 218 iteration 218; minNextMutationTime = 205; timeNextPopSample = 195; popParams.size() = 2 We are SAMPLING at time 195 *** Looping through 5.2. Iter = 219 iteration 219; minNextMutationTime = 206; timeNextPopSample = 196; popParams.size() = 2 We are SAMPLING at time 196 *** Looping through 5.2. Iter = 220 iteration 220; minNextMutationTime = 207; timeNextPopSample = 197; popParams.size() = 1 We are SAMPLING at time 197 *** Looping through 5.2. Iter = 221 iteration 221; minNextMutationTime = 208; timeNextPopSample = 198; popParams.size() = 1 We are SAMPLING at time 198 *** Looping through 5.2. Iter = 222 iteration 222; minNextMutationTime = 209; timeNextPopSample = 199; popParams.size() = 1 We are SAMPLING at time 199 *** Looping through 5.2. Iter = 223 iteration 223; minNextMutationTime = 210; timeNextPopSample = 200; popParams.size() = 1 We are SAMPLING at time 200 *** Looping through 5.2. Iter = 224 iteration 224; minNextMutationTime = 211; timeNextPopSample = 201; popParams.size() = 1 We are SAMPLING at time 201 *** Looping through 5.2. Iter = 225 iteration 225; minNextMutationTime = 212; timeNextPopSample = 202; popParams.size() = 1 We are SAMPLING at time 202 *** Looping through 5.2. Iter = 226 iteration 226; minNextMutationTime = 213; timeNextPopSample = 203; popParams.size() = 1 We are SAMPLING at time 203 *** Looping through 5.2. Iter = 227 iteration 227; minNextMutationTime = 214; timeNextPopSample = 204; popParams.size() = 1 We are SAMPLING at time 204 *** Looping through 5.2. Iter = 228 iteration 228; minNextMutationTime = 204.52; timeNextPopSample = 205; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 229 iteration 229; minNextMutationTime = 215; timeNextPopSample = 205; popParams.size() = 2 We are SAMPLING at time 205 *** Looping through 5.2. Iter = 230 iteration 230; minNextMutationTime = 216; timeNextPopSample = 206; popParams.size() = 2 We are SAMPLING at time 206 *** Looping through 5.2. Iter = 231 iteration 231; minNextMutationTime = 217; timeNextPopSample = 207; popParams.size() = 2 We are SAMPLING at time 207 *** Looping through 5.2. Iter = 232 iteration 232; minNextMutationTime = 218; timeNextPopSample = 208; popParams.size() = 1 We are SAMPLING at time 208 *** Looping through 5.2. Iter = 233 iteration 233; minNextMutationTime = 219; timeNextPopSample = 209; popParams.size() = 1 We are SAMPLING at time 209 *** Looping through 5.2. Iter = 234 iteration 234; minNextMutationTime = 220; timeNextPopSample = 210; popParams.size() = 1 We are SAMPLING at time 210 *** Looping through 5.2. Iter = 235 iteration 235; minNextMutationTime = 221; timeNextPopSample = 211; popParams.size() = 1 We are SAMPLING at time 211 *** Looping through 5.2. Iter = 236 iteration 236; minNextMutationTime = 222; timeNextPopSample = 212; popParams.size() = 1 We are SAMPLING at time 212 *** Looping through 5.2. Iter = 237 iteration 237; minNextMutationTime = 223; timeNextPopSample = 213; popParams.size() = 1 We are SAMPLING at time 213 *** Looping through 5.2. Iter = 238 iteration 238; minNextMutationTime = 224; timeNextPopSample = 214; popParams.size() = 1 We are SAMPLING at time 214 *** Looping through 5.2. Iter = 239 iteration 239; minNextMutationTime = 214.117; timeNextPopSample = 215; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 240 iteration 240; minNextMutationTime = 225; timeNextPopSample = 215; popParams.size() = 2 We are SAMPLING at time 215 *** Looping through 5.2. Iter = 241 iteration 241; minNextMutationTime = 226; timeNextPopSample = 216; popParams.size() = 2 We are SAMPLING at time 216 *** Looping through 5.2. Iter = 242 iteration 242; minNextMutationTime = 227; timeNextPopSample = 217; popParams.size() = 2 We are SAMPLING at time 217 *** Looping through 5.2. Iter = 243 iteration 243; minNextMutationTime = 228; timeNextPopSample = 218; popParams.size() = 2 We are SAMPLING at time 218 *** Looping through 5.2. Iter = 244 iteration 244; minNextMutationTime = 229; timeNextPopSample = 219; popParams.size() = 2 We are SAMPLING at time 219 *** Looping through 5.2. Iter = 245 iteration 245; minNextMutationTime = 230; timeNextPopSample = 220; popParams.size() = 2 We are SAMPLING at time 220 *** Looping through 5.2. Iter = 246 iteration 246; minNextMutationTime = 231; timeNextPopSample = 221; popParams.size() = 2 We are SAMPLING at time 221 *** Looping through 5.2. Iter = 247 iteration 247; minNextMutationTime = 232; timeNextPopSample = 222; popParams.size() = 2 We are SAMPLING at time 222 *** Looping through 5.2. Iter = 248 iteration 248; minNextMutationTime = 233; timeNextPopSample = 223; popParams.size() = 2 We are SAMPLING at time 223 *** Looping through 5.2. Iter = 249 iteration 249; minNextMutationTime = 234; timeNextPopSample = 224; popParams.size() = 2 We are SAMPLING at time 224 *** Looping through 5.2. Iter = 250 iteration 250; minNextMutationTime = 235; timeNextPopSample = 225; popParams.size() = 1 We are SAMPLING at time 225 *** Looping through 5.2. Iter = 251 iteration 251; minNextMutationTime = 236; timeNextPopSample = 226; popParams.size() = 1 We are SAMPLING at time 226 *** Looping through 5.2. Iter = 252 iteration 252; minNextMutationTime = 237; timeNextPopSample = 227; popParams.size() = 1 We are SAMPLING at time 227 *** Looping through 5.2. Iter = 253 iteration 253; minNextMutationTime = 238; timeNextPopSample = 228; popParams.size() = 1 We are SAMPLING at time 228 *** Looping through 5.2. Iter = 254 iteration 254; minNextMutationTime = 239; timeNextPopSample = 229; popParams.size() = 1 We are SAMPLING at time 229 *** Looping through 5.2. Iter = 255 iteration 255; minNextMutationTime = 229.597; timeNextPopSample = 230; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 256 iteration 256; minNextMutationTime = 240; timeNextPopSample = 230; popParams.size() = 2 We are SAMPLING at time 230 *** Looping through 5.2. Iter = 257 iteration 257; minNextMutationTime = 241; timeNextPopSample = 231; popParams.size() = 2 We are SAMPLING at time 231 *** Looping through 5.2. Iter = 258 iteration 258; minNextMutationTime = 242; timeNextPopSample = 232; popParams.size() = 1 We are SAMPLING at time 232 *** Looping through 5.2. Iter = 259 iteration 259; minNextMutationTime = 243; timeNextPopSample = 233; popParams.size() = 1 We are SAMPLING at time 233 *** Looping through 5.2. Iter = 260 iteration 260; minNextMutationTime = 244; timeNextPopSample = 234; popParams.size() = 1 We are SAMPLING at time 234 *** Looping through 5.2. Iter = 261 iteration 261; minNextMutationTime = 245; timeNextPopSample = 235; popParams.size() = 1 We are SAMPLING at time 235 *** Looping through 5.2. Iter = 262 iteration 262; minNextMutationTime = 246; timeNextPopSample = 236; popParams.size() = 1 We are SAMPLING at time 236 *** Looping through 5.2. Iter = 263 iteration 263; minNextMutationTime = 247; timeNextPopSample = 237; popParams.size() = 1 We are SAMPLING at time 237 *** Looping through 5.2. Iter = 264 iteration 264; minNextMutationTime = 248; timeNextPopSample = 238; popParams.size() = 1 We are SAMPLING at time 238 *** Looping through 5.2. Iter = 265 iteration 265; minNextMutationTime = 249; timeNextPopSample = 239; popParams.size() = 1 We are SAMPLING at time 239 *** Looping through 5.2. Iter = 266 iteration 266; minNextMutationTime = 250; timeNextPopSample = 240; popParams.size() = 1 We are SAMPLING at time 240 *** Looping through 5.2. Iter = 267 iteration 267; minNextMutationTime = 251; timeNextPopSample = 241; popParams.size() = 1 We are SAMPLING at time 241 *** Looping through 5.2. Iter = 268 iteration 268; minNextMutationTime = 252; timeNextPopSample = 242; popParams.size() = 1 We are SAMPLING at time 242 *** Looping through 5.2. Iter = 269 iteration 269; minNextMutationTime = 253; timeNextPopSample = 243; popParams.size() = 1 We are SAMPLING at time 243 *** Looping through 5.2. Iter = 270 iteration 270; minNextMutationTime = 254; timeNextPopSample = 244; popParams.size() = 1 We are SAMPLING at time 244 *** Looping through 5.2. Iter = 271 iteration 271; minNextMutationTime = 255; timeNextPopSample = 245; popParams.size() = 1 We are SAMPLING at time 245 *** Looping through 5.2. Iter = 272 iteration 272; minNextMutationTime = 256; timeNextPopSample = 246; popParams.size() = 1 We are SAMPLING at time 246 *** Looping through 5.2. Iter = 273 iteration 273; minNextMutationTime = 246.805; timeNextPopSample = 247; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 274 iteration 274; minNextMutationTime = 257; timeNextPopSample = 247; popParams.size() = 2 We are SAMPLING at time 247 *** Looping through 5.2. Iter = 275 iteration 275; minNextMutationTime = 258; timeNextPopSample = 248; popParams.size() = 1 We are SAMPLING at time 248 *** Looping through 5.2. Iter = 276 iteration 276; minNextMutationTime = 259; timeNextPopSample = 249; popParams.size() = 1 We are SAMPLING at time 249 *** Looping through 5.2. Iter = 277 iteration 277; minNextMutationTime = 260; timeNextPopSample = 250; popParams.size() = 1 We are SAMPLING at time 250 *** Looping through 5.2. Iter = 278 iteration 278; minNextMutationTime = 261; timeNextPopSample = 251; popParams.size() = 1 We are SAMPLING at time 251 *** Looping through 5.2. Iter = 279 iteration 279; minNextMutationTime = 262; timeNextPopSample = 252; popParams.size() = 1 We are SAMPLING at time 252 *** Looping through 5.2. Iter = 280 iteration 280; minNextMutationTime = 263; timeNextPopSample = 253; popParams.size() = 1 We are SAMPLING at time 253 *** Looping through 5.2. Iter = 281 iteration 281; minNextMutationTime = 253.651; timeNextPopSample = 254; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 282 iteration 282; minNextMutationTime = 264; timeNextPopSample = 254; popParams.size() = 2 We are SAMPLING at time 254 *** Looping through 5.2. Iter = 283 iteration 283; minNextMutationTime = 265; timeNextPopSample = 255; popParams.size() = 1 We are SAMPLING at time 255 *** Looping through 5.2. Iter = 284 iteration 284; minNextMutationTime = 266; timeNextPopSample = 256; popParams.size() = 1 We are SAMPLING at time 256 *** Looping through 5.2. Iter = 285 iteration 285; minNextMutationTime = 267; timeNextPopSample = 257; popParams.size() = 1 We are SAMPLING at time 257 *** Looping through 5.2. Iter = 286 iteration 286; minNextMutationTime = 257.043; timeNextPopSample = 258; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 287 iteration 287; minNextMutationTime = 268; timeNextPopSample = 258; popParams.size() = 2 We are SAMPLING at time 258 *** Looping through 5.2. Iter = 288 iteration 288; minNextMutationTime = 269; timeNextPopSample = 259; popParams.size() = 2 We are SAMPLING at time 259 *** Looping through 5.2. Iter = 289 iteration 289; minNextMutationTime = 270; timeNextPopSample = 260; popParams.size() = 2 We are SAMPLING at time 260 *** Looping through 5.2. Iter = 290 iteration 290; minNextMutationTime = 271; timeNextPopSample = 261; popParams.size() = 2 We are SAMPLING at time 261 *** Looping through 5.2. Iter = 291 iteration 291; minNextMutationTime = 272; timeNextPopSample = 262; popParams.size() = 2 We are SAMPLING at time 262 *** Looping through 5.2. Iter = 292 iteration 292; minNextMutationTime = 273; timeNextPopSample = 263; popParams.size() = 2 We are SAMPLING at time 263 *** Looping through 5.2. Iter = 293 iteration 293; minNextMutationTime = 274; timeNextPopSample = 264; popParams.size() = 2 We are SAMPLING at time 264 *** Looping through 5.2. Iter = 294 iteration 294; minNextMutationTime = 264.958; timeNextPopSample = 265; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 295 iteration 295; minNextMutationTime = 275; timeNextPopSample = 265; popParams.size() = 3 We are SAMPLING at time 265 *** Looping through 5.2. Iter = 296 iteration 296; minNextMutationTime = 276; timeNextPopSample = 266; popParams.size() = 3 We are SAMPLING at time 266 *** Looping through 5.2. Iter = 297 iteration 297; minNextMutationTime = 277; timeNextPopSample = 267; popParams.size() = 2 We are SAMPLING at time 267 *** Looping through 5.2. Iter = 298 iteration 298; minNextMutationTime = 278; timeNextPopSample = 268; popParams.size() = 2 We are SAMPLING at time 268 *** Looping through 5.2. Iter = 299 iteration 299; minNextMutationTime = 279; timeNextPopSample = 269; popParams.size() = 2 We are SAMPLING at time 269 *** Looping through 5.2. Iter = 300 iteration 300; minNextMutationTime = 280; timeNextPopSample = 270; popParams.size() = 2 We are SAMPLING at time 270 *** Looping through 5.2. Iter = 301 iteration 301; minNextMutationTime = 281; timeNextPopSample = 271; popParams.size() = 2 We are SAMPLING at time 271 *** Looping through 5.2. Iter = 302 iteration 302; minNextMutationTime = 282; timeNextPopSample = 272; popParams.size() = 2 We are SAMPLING at time 272 *** Looping through 5.2. Iter = 303 iteration 303; minNextMutationTime = 283; timeNextPopSample = 273; popParams.size() = 2 We are SAMPLING at time 273 *** Looping through 5.2. Iter = 304 iteration 304; minNextMutationTime = 284; timeNextPopSample = 274; popParams.size() = 2 We are SAMPLING at time 274 *** Looping through 5.2. Iter = 305 iteration 305; minNextMutationTime = 285; timeNextPopSample = 275; popParams.size() = 2 We are SAMPLING at time 275 *** Looping through 5.2. Iter = 306 iteration 306; minNextMutationTime = 286; timeNextPopSample = 276; popParams.size() = 2 We are SAMPLING at time 276 *** Looping through 5.2. Iter = 307 iteration 307; minNextMutationTime = 287; timeNextPopSample = 277; popParams.size() = 2 We are SAMPLING at time 277 *** Looping through 5.2. Iter = 308 iteration 308; minNextMutationTime = 288; timeNextPopSample = 278; popParams.size() = 2 We are SAMPLING at time 278 *** Looping through 5.2. Iter = 309 iteration 309; minNextMutationTime = 289; timeNextPopSample = 279; popParams.size() = 2 We are SAMPLING at time 279 *** Looping through 5.2. Iter = 310 iteration 310; minNextMutationTime = 290; timeNextPopSample = 280; popParams.size() = 2 We are SAMPLING at time 280 *** Looping through 5.2. Iter = 311 iteration 311; minNextMutationTime = 291; timeNextPopSample = 281; popParams.size() = 2 We are SAMPLING at time 281 *** Looping through 5.2. Iter = 312 iteration 312; minNextMutationTime = 292; timeNextPopSample = 282; popParams.size() = 2 We are SAMPLING at time 282 *** Looping through 5.2. Iter = 313 iteration 313; minNextMutationTime = 293; timeNextPopSample = 283; popParams.size() = 2 We are SAMPLING at time 283 *** Looping through 5.2. Iter = 314 iteration 314; minNextMutationTime = 294; timeNextPopSample = 284; popParams.size() = 2 We are SAMPLING at time 284 *** Looping through 5.2. Iter = 315 iteration 315; minNextMutationTime = 295; timeNextPopSample = 285; popParams.size() = 2 We are SAMPLING at time 285 *** Looping through 5.2. Iter = 316 iteration 316; minNextMutationTime = 296; timeNextPopSample = 286; popParams.size() = 2 We are SAMPLING at time 286 *** Looping through 5.2. Iter = 317 iteration 317; minNextMutationTime = 297; timeNextPopSample = 287; popParams.size() = 1 We are SAMPLING at time 287 *** Looping through 5.2. Iter = 318 iteration 318; minNextMutationTime = 298; timeNextPopSample = 288; popParams.size() = 1 We are SAMPLING at time 288 *** Looping through 5.2. Iter = 319 iteration 319; minNextMutationTime = 299; timeNextPopSample = 289; popParams.size() = 1 We are SAMPLING at time 289 *** Looping through 5.2. Iter = 320 iteration 320; minNextMutationTime = 289.691; timeNextPopSample = 290; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 321 iteration 321; minNextMutationTime = 300; timeNextPopSample = 290; popParams.size() = 2 We are SAMPLING at time 290 *** Looping through 5.2. Iter = 322 iteration 322; minNextMutationTime = 290.2; timeNextPopSample = 291; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 323 iteration 323; minNextMutationTime = 301; timeNextPopSample = 291; popParams.size() = 3 We are SAMPLING at time 291 *** Looping through 5.2. Iter = 324 iteration 324; minNextMutationTime = 302; timeNextPopSample = 292; popParams.size() = 2 We are SAMPLING at time 292 *** Looping through 5.2. Iter = 325 iteration 325; minNextMutationTime = 303; timeNextPopSample = 293; popParams.size() = 1 We are SAMPLING at time 293 *** Looping through 5.2. Iter = 326 iteration 326; minNextMutationTime = 304; timeNextPopSample = 294; popParams.size() = 1 We are SAMPLING at time 294 *** Looping through 5.2. Iter = 327 iteration 327; minNextMutationTime = 305; timeNextPopSample = 295; popParams.size() = 1 We are SAMPLING at time 295 *** Looping through 5.2. Iter = 328 iteration 328; minNextMutationTime = 306; timeNextPopSample = 296; popParams.size() = 1 We are SAMPLING at time 296 *** Looping through 5.2. Iter = 329 iteration 329; minNextMutationTime = 307; timeNextPopSample = 297; popParams.size() = 1 We are SAMPLING at time 297 *** Looping through 5.2. Iter = 330 iteration 330; minNextMutationTime = 308; timeNextPopSample = 298; popParams.size() = 1 We are SAMPLING at time 298 *** Looping through 5.2. Iter = 331 iteration 331; minNextMutationTime = 298.63; timeNextPopSample = 299; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 332 iteration 332; minNextMutationTime = 309; timeNextPopSample = 299; popParams.size() = 2 We are SAMPLING at time 299 *** Looping through 5.2. Iter = 333 iteration 333; minNextMutationTime = 310; timeNextPopSample = 300; popParams.size() = 2 We are SAMPLING at time 300 *** Looping through 5.2. Iter = 334 iteration 334; minNextMutationTime = 311; timeNextPopSample = 301; popParams.size() = 2 We are SAMPLING at time 301 *** Looping through 5.2. Iter = 335 iteration 335; minNextMutationTime = 312; timeNextPopSample = 302; popParams.size() = 2 We are SAMPLING at time 302 *** Looping through 5.2. Iter = 336 iteration 336; minNextMutationTime = 313; timeNextPopSample = 303; popParams.size() = 1 We are SAMPLING at time 303 *** Looping through 5.2. Iter = 337 iteration 337; minNextMutationTime = 314; timeNextPopSample = 304; popParams.size() = 1 We are SAMPLING at time 304 *** Looping through 5.2. Iter = 338 iteration 338; minNextMutationTime = 304.339; timeNextPopSample = 305; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 339 iteration 339; minNextMutationTime = 315; timeNextPopSample = 305; popParams.size() = 2 We are SAMPLING at time 305 *** Looping through 5.2. Iter = 340 iteration 340; minNextMutationTime = 305.871; timeNextPopSample = 306; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 341 iteration 341; minNextMutationTime = 316; timeNextPopSample = 306; popParams.size() = 2 We are SAMPLING at time 306 *** Looping through 5.2. Iter = 342 iteration 342; minNextMutationTime = 306.671; timeNextPopSample = 307; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 343 iteration 343; minNextMutationTime = 317; timeNextPopSample = 307; popParams.size() = 3 We are SAMPLING at time 307 *** Looping through 5.2. Iter = 344 iteration 344; minNextMutationTime = 307.134; timeNextPopSample = 308; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 345 iteration 345; minNextMutationTime = 307.761; timeNextPopSample = 308; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 346 iteration 346; minNextMutationTime = 318; timeNextPopSample = 308; popParams.size() = 4 We are SAMPLING at time 308 *** Looping through 5.2. Iter = 347 iteration 347; minNextMutationTime = 319; timeNextPopSample = 309; popParams.size() = 3 We are SAMPLING at time 309 *** Looping through 5.2. Iter = 348 iteration 348; minNextMutationTime = 320; timeNextPopSample = 310; popParams.size() = 3 We are SAMPLING at time 310 *** Looping through 5.2. Iter = 349 iteration 349; minNextMutationTime = 321; timeNextPopSample = 311; popParams.size() = 2 We are SAMPLING at time 311 *** Looping through 5.2. Iter = 350 iteration 350; minNextMutationTime = 322; timeNextPopSample = 312; popParams.size() = 2 We are SAMPLING at time 312 *** Looping through 5.2. Iter = 351 iteration 351; minNextMutationTime = 323; timeNextPopSample = 313; popParams.size() = 2 We are SAMPLING at time 313 *** Looping through 5.2. Iter = 352 iteration 352; minNextMutationTime = 324; timeNextPopSample = 314; popParams.size() = 1 We are SAMPLING at time 314 *** Looping through 5.2. Iter = 353 iteration 353; minNextMutationTime = 314.403; timeNextPopSample = 315; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 354 iteration 354; minNextMutationTime = 325; timeNextPopSample = 315; popParams.size() = 2 We are SAMPLING at time 315 *** Looping through 5.2. Iter = 355 iteration 355; minNextMutationTime = 326; timeNextPopSample = 316; popParams.size() = 2 We are SAMPLING at time 316 *** Looping through 5.2. Iter = 356 iteration 356; minNextMutationTime = 327; timeNextPopSample = 317; popParams.size() = 2 We are SAMPLING at time 317 *** Looping through 5.2. Iter = 357 iteration 357; minNextMutationTime = 328; timeNextPopSample = 318; popParams.size() = 1 We are SAMPLING at time 318 *** Looping through 5.2. Iter = 358 iteration 358; minNextMutationTime = 329; timeNextPopSample = 319; popParams.size() = 1 We are SAMPLING at time 319 *** Looping through 5.2. Iter = 359 iteration 359; minNextMutationTime = 319.208; timeNextPopSample = 320; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 360 iteration 360; minNextMutationTime = 330; timeNextPopSample = 320; popParams.size() = 2 We are SAMPLING at time 320 *** Looping through 5.2. Iter = 361 iteration 361; minNextMutationTime = 331; timeNextPopSample = 321; popParams.size() = 2 We are SAMPLING at time 321 *** Looping through 5.2. Iter = 362 iteration 362; minNextMutationTime = 332; timeNextPopSample = 322; popParams.size() = 2 We are SAMPLING at time 322 *** Looping through 5.2. Iter = 363 iteration 363; minNextMutationTime = 333; timeNextPopSample = 323; popParams.size() = 2 We are SAMPLING at time 323 *** Looping through 5.2. Iter = 364 iteration 364; minNextMutationTime = 334; timeNextPopSample = 324; popParams.size() = 2 We are SAMPLING at time 324 *** Looping through 5.2. Iter = 365 iteration 365; minNextMutationTime = 335; timeNextPopSample = 325; popParams.size() = 2 We are SAMPLING at time 325 *** Looping through 5.2. Iter = 366 iteration 366; minNextMutationTime = 336; timeNextPopSample = 326; popParams.size() = 2 We are SAMPLING at time 326 *** Looping through 5.2. Iter = 367 iteration 367; minNextMutationTime = 337; timeNextPopSample = 327; popParams.size() = 2 We are SAMPLING at time 327 *** Looping through 5.2. Iter = 368 iteration 368; minNextMutationTime = 338; timeNextPopSample = 328; popParams.size() = 2 We are SAMPLING at time 328 *** Looping through 5.2. Iter = 369 iteration 369; minNextMutationTime = 339; timeNextPopSample = 329; popParams.size() = 2 We are SAMPLING at time 329 *** Looping through 5.2. Iter = 370 iteration 370; minNextMutationTime = 340; timeNextPopSample = 330; popParams.size() = 2 We are SAMPLING at time 330 *** Looping through 5.2. Iter = 371 iteration 371; minNextMutationTime = 341; timeNextPopSample = 331; popParams.size() = 1 We are SAMPLING at time 331 *** Looping through 5.2. Iter = 372 iteration 372; minNextMutationTime = 342; timeNextPopSample = 332; popParams.size() = 1 We are SAMPLING at time 332 *** Looping through 5.2. Iter = 373 iteration 373; minNextMutationTime = 343; timeNextPopSample = 333; popParams.size() = 1 We are SAMPLING at time 333 *** Looping through 5.2. Iter = 374 iteration 374; minNextMutationTime = 344; timeNextPopSample = 334; popParams.size() = 1 We are SAMPLING at time 334 *** Looping through 5.2. Iter = 375 iteration 375; minNextMutationTime = 345; timeNextPopSample = 335; popParams.size() = 1 We are SAMPLING at time 335 *** Looping through 5.2. Iter = 376 iteration 376; minNextMutationTime = 335.414; timeNextPopSample = 336; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 377 iteration 377; minNextMutationTime = 346; timeNextPopSample = 336; popParams.size() = 2 We are SAMPLING at time 336 *** Looping through 5.2. Iter = 378 iteration 378; minNextMutationTime = 347; timeNextPopSample = 337; popParams.size() = 1 We are SAMPLING at time 337 *** Looping through 5.2. Iter = 379 iteration 379; minNextMutationTime = 348; timeNextPopSample = 338; popParams.size() = 1 We are SAMPLING at time 338 *** Looping through 5.2. Iter = 380 iteration 380; minNextMutationTime = 349; timeNextPopSample = 339; popParams.size() = 1 We are SAMPLING at time 339 *** Looping through 5.2. Iter = 381 iteration 381; minNextMutationTime = 350; timeNextPopSample = 340; popParams.size() = 1 We are SAMPLING at time 340 *** Looping through 5.2. Iter = 382 iteration 382; minNextMutationTime = 351; timeNextPopSample = 341; popParams.size() = 1 We are SAMPLING at time 341 *** Looping through 5.2. Iter = 383 iteration 383; minNextMutationTime = 352; timeNextPopSample = 342; popParams.size() = 1 We are SAMPLING at time 342 *** Looping through 5.2. Iter = 384 iteration 384; minNextMutationTime = 353; timeNextPopSample = 343; popParams.size() = 1 We are SAMPLING at time 343 *** Looping through 5.2. Iter = 385 iteration 385; minNextMutationTime = 354; timeNextPopSample = 344; popParams.size() = 1 We are SAMPLING at time 344 *** Looping through 5.2. Iter = 386 iteration 386; minNextMutationTime = 355; timeNextPopSample = 345; popParams.size() = 1 We are SAMPLING at time 345 *** Looping through 5.2. Iter = 387 iteration 387; minNextMutationTime = 356; timeNextPopSample = 346; popParams.size() = 1 We are SAMPLING at time 346 *** Looping through 5.2. Iter = 388 iteration 388; minNextMutationTime = 357; timeNextPopSample = 347; popParams.size() = 1 We are SAMPLING at time 347 *** Looping through 5.2. Iter = 389 iteration 389; minNextMutationTime = 358; timeNextPopSample = 348; popParams.size() = 1 We are SAMPLING at time 348 *** Looping through 5.2. Iter = 390 iteration 390; minNextMutationTime = 359; timeNextPopSample = 349; popParams.size() = 1 We are SAMPLING at time 349 *** Looping through 5.2. Iter = 391 iteration 391; minNextMutationTime = 360; timeNextPopSample = 350; popParams.size() = 1 We are SAMPLING at time 350 *** Looping through 5.2. Iter = 392 iteration 392; minNextMutationTime = 361; timeNextPopSample = 351; popParams.size() = 1 We are SAMPLING at time 351 *** Looping through 5.2. Iter = 393 iteration 393; minNextMutationTime = 362; timeNextPopSample = 352; popParams.size() = 1 We are SAMPLING at time 352 *** Looping through 5.2. Iter = 394 iteration 394; minNextMutationTime = 363; timeNextPopSample = 353; popParams.size() = 1 We are SAMPLING at time 353 *** Looping through 5.2. Iter = 395 iteration 395; minNextMutationTime = 364; timeNextPopSample = 354; popParams.size() = 1 We are SAMPLING at time 354 *** Looping through 5.2. Iter = 396 iteration 396; minNextMutationTime = 365; timeNextPopSample = 355; popParams.size() = 1 We are SAMPLING at time 355 *** Looping through 5.2. Iter = 397 iteration 397; minNextMutationTime = 366; timeNextPopSample = 356; popParams.size() = 1 We are SAMPLING at time 356 *** Looping through 5.2. Iter = 398 iteration 398; minNextMutationTime = 367; timeNextPopSample = 357; popParams.size() = 1 We are SAMPLING at time 357 *** Looping through 5.2. Iter = 399 iteration 399; minNextMutationTime = 368; timeNextPopSample = 358; popParams.size() = 1 We are SAMPLING at time 358 *** Looping through 5.2. Iter = 400 iteration 400; minNextMutationTime = 369; timeNextPopSample = 359; popParams.size() = 1 We are SAMPLING at time 359 *** Looping through 5.2. Iter = 401 iteration 401; minNextMutationTime = 370; timeNextPopSample = 360; popParams.size() = 1 We are SAMPLING at time 360 *** Looping through 5.2. Iter = 402 iteration 402; minNextMutationTime = 371; timeNextPopSample = 361; popParams.size() = 1 We are SAMPLING at time 361 *** Looping through 5.2. Iter = 403 iteration 403; minNextMutationTime = 372; timeNextPopSample = 362; popParams.size() = 1 We are SAMPLING at time 362 *** Looping through 5.2. Iter = 404 iteration 404; minNextMutationTime = 373; timeNextPopSample = 363; popParams.size() = 1 We are SAMPLING at time 363 *** Looping through 5.2. Iter = 405 iteration 405; minNextMutationTime = 374; timeNextPopSample = 364; popParams.size() = 1 We are SAMPLING at time 364 *** Looping through 5.2. Iter = 406 iteration 406; minNextMutationTime = 364.118; timeNextPopSample = 365; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 407 iteration 407; minNextMutationTime = 375; timeNextPopSample = 365; popParams.size() = 2 We are SAMPLING at time 365 *** Looping through 5.2. Iter = 408 iteration 408; minNextMutationTime = 376; timeNextPopSample = 366; popParams.size() = 2 We are SAMPLING at time 366 *** Looping through 5.2. Iter = 409 iteration 409; minNextMutationTime = 377; timeNextPopSample = 367; popParams.size() = 1 We are SAMPLING at time 367 *** Looping through 5.2. Iter = 410 iteration 410; minNextMutationTime = 378; timeNextPopSample = 368; popParams.size() = 1 We are SAMPLING at time 368 *** Looping through 5.2. Iter = 411 iteration 411; minNextMutationTime = 379; timeNextPopSample = 369; popParams.size() = 1 We are SAMPLING at time 369 *** Looping through 5.2. Iter = 412 iteration 412; minNextMutationTime = 380; timeNextPopSample = 370; popParams.size() = 1 We are SAMPLING at time 370 *** Looping through 5.2. Iter = 413 iteration 413; minNextMutationTime = 381; timeNextPopSample = 371; popParams.size() = 1 We are SAMPLING at time 371 *** Looping through 5.2. Iter = 414 iteration 414; minNextMutationTime = 382; timeNextPopSample = 372; popParams.size() = 1 We are SAMPLING at time 372 *** Looping through 5.2. Iter = 415 iteration 415; minNextMutationTime = 383; timeNextPopSample = 373; popParams.size() = 1 We are SAMPLING at time 373 *** Looping through 5.2. Iter = 416 iteration 416; minNextMutationTime = 384; timeNextPopSample = 374; popParams.size() = 1 We are SAMPLING at time 374 *** Looping through 5.2. Iter = 417 iteration 417; minNextMutationTime = 385; timeNextPopSample = 375; popParams.size() = 1 We are SAMPLING at time 375 *** Looping through 5.2. Iter = 418 iteration 418; minNextMutationTime = 375.289; timeNextPopSample = 376; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 419 iteration 419; minNextMutationTime = 386; timeNextPopSample = 376; popParams.size() = 2 We are SAMPLING at time 376 *** Looping through 5.2. Iter = 420 iteration 420; minNextMutationTime = 387; timeNextPopSample = 377; popParams.size() = 2 We are SAMPLING at time 377 *** Looping through 5.2. Iter = 421 iteration 421; minNextMutationTime = 388; timeNextPopSample = 378; popParams.size() = 2 We are SAMPLING at time 378 *** Looping through 5.2. Iter = 422 iteration 422; minNextMutationTime = 389; timeNextPopSample = 379; popParams.size() = 1 We are SAMPLING at time 379 *** Looping through 5.2. Iter = 423 iteration 423; minNextMutationTime = 390; timeNextPopSample = 380; popParams.size() = 1 We are SAMPLING at time 380 *** Looping through 5.2. Iter = 424 iteration 424; minNextMutationTime = 391; timeNextPopSample = 381; popParams.size() = 1 We are SAMPLING at time 381 *** Looping through 5.2. Iter = 425 iteration 425; minNextMutationTime = 392; timeNextPopSample = 382; popParams.size() = 1 We are SAMPLING at time 382 *** Looping through 5.2. Iter = 426 iteration 426; minNextMutationTime = 393; timeNextPopSample = 383; popParams.size() = 1 We are SAMPLING at time 383 *** Looping through 5.2. Iter = 427 iteration 427; minNextMutationTime = 394; timeNextPopSample = 384; popParams.size() = 1 We are SAMPLING at time 384 *** Looping through 5.2. Iter = 428 iteration 428; minNextMutationTime = 395; timeNextPopSample = 385; popParams.size() = 1 We are SAMPLING at time 385 *** Looping through 5.2. Iter = 429 iteration 429; minNextMutationTime = 396; timeNextPopSample = 386; popParams.size() = 1 We are SAMPLING at time 386 *** Looping through 5.2. Iter = 430 iteration 430; minNextMutationTime = 397; timeNextPopSample = 387; popParams.size() = 1 We are SAMPLING at time 387 *** Looping through 5.2. Iter = 431 iteration 431; minNextMutationTime = 398; timeNextPopSample = 388; popParams.size() = 1 We are SAMPLING at time 388 *** Looping through 5.2. Iter = 432 iteration 432; minNextMutationTime = 399; timeNextPopSample = 389; popParams.size() = 1 We are SAMPLING at time 389 *** Looping through 5.2. Iter = 433 iteration 433; minNextMutationTime = 389.199; timeNextPopSample = 390; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 434 iteration 434; minNextMutationTime = 400; timeNextPopSample = 390; popParams.size() = 2 We are SAMPLING at time 390 *** Looping through 5.2. Iter = 435 iteration 435; minNextMutationTime = 401; timeNextPopSample = 391; popParams.size() = 2 We are SAMPLING at time 391 *** Looping through 5.2. Iter = 436 iteration 436; minNextMutationTime = 402; timeNextPopSample = 392; popParams.size() = 1 We are SAMPLING at time 392 *** Looping through 5.2. Iter = 437 iteration 437; minNextMutationTime = 403; timeNextPopSample = 393; popParams.size() = 1 We are SAMPLING at time 393 *** Looping through 5.2. Iter = 438 iteration 438; minNextMutationTime = 404; timeNextPopSample = 394; popParams.size() = 1 We are SAMPLING at time 394 *** Looping through 5.2. Iter = 439 iteration 439; minNextMutationTime = 405; timeNextPopSample = 395; popParams.size() = 1 We are SAMPLING at time 395 *** Looping through 5.2. Iter = 440 iteration 440; minNextMutationTime = 406; timeNextPopSample = 396; popParams.size() = 1 We are SAMPLING at time 396 *** Looping through 5.2. Iter = 441 iteration 441; minNextMutationTime = 407; timeNextPopSample = 397; popParams.size() = 1 We are SAMPLING at time 397 *** Looping through 5.2. Iter = 442 iteration 442; minNextMutationTime = 397.439; timeNextPopSample = 398; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 443 iteration 443; minNextMutationTime = 408; timeNextPopSample = 398; popParams.size() = 2 We are SAMPLING at time 398 *** Looping through 5.2. Iter = 444 iteration 444; minNextMutationTime = 409; timeNextPopSample = 399; popParams.size() = 1 We are SAMPLING at time 399 *** Looping through 5.2. Iter = 445 iteration 445; minNextMutationTime = 410; timeNextPopSample = 400; popParams.size() = 1 We are SAMPLING at time 400 *** Looping through 5.2. Iter = 446 iteration 446; minNextMutationTime = 411; timeNextPopSample = 401; popParams.size() = 1 We are SAMPLING at time 401 *** Looping through 5.2. Iter = 447 iteration 447; minNextMutationTime = 412; timeNextPopSample = 402; popParams.size() = 1 We are SAMPLING at time 402 *** Looping through 5.2. Iter = 448 iteration 448; minNextMutationTime = 413; timeNextPopSample = 403; popParams.size() = 1 We are SAMPLING at time 403 *** Looping through 5.2. Iter = 449 iteration 449; minNextMutationTime = 414; timeNextPopSample = 404; popParams.size() = 1 We are SAMPLING at time 404 *** Looping through 5.2. Iter = 450 iteration 450; minNextMutationTime = 415; timeNextPopSample = 405; popParams.size() = 1 We are SAMPLING at time 405 *** Looping through 5.2. Iter = 451 iteration 451; minNextMutationTime = 416; timeNextPopSample = 406; popParams.size() = 1 We are SAMPLING at time 406 *** Looping through 5.2. Iter = 452 iteration 452; minNextMutationTime = 417; timeNextPopSample = 407; popParams.size() = 1 We are SAMPLING at time 407 *** Looping through 5.2. Iter = 453 iteration 453; minNextMutationTime = 418; timeNextPopSample = 408; popParams.size() = 1 We are SAMPLING at time 408 *** Looping through 5.2. Iter = 454 iteration 454; minNextMutationTime = 419; timeNextPopSample = 409; popParams.size() = 1 We are SAMPLING at time 409 *** Looping through 5.2. Iter = 455 iteration 455; minNextMutationTime = 420; timeNextPopSample = 410; popParams.size() = 1 We are SAMPLING at time 410 *** Looping through 5.2. Iter = 456 iteration 456; minNextMutationTime = 421; timeNextPopSample = 411; popParams.size() = 1 We are SAMPLING at time 411 *** Looping through 5.2. Iter = 457 iteration 457; minNextMutationTime = 422; timeNextPopSample = 412; popParams.size() = 1 We are SAMPLING at time 412 *** Looping through 5.2. Iter = 458 iteration 458; minNextMutationTime = 423; timeNextPopSample = 413; popParams.size() = 1 We are SAMPLING at time 413 *** Looping through 5.2. Iter = 459 iteration 459; minNextMutationTime = 424; timeNextPopSample = 414; popParams.size() = 1 We are SAMPLING at time 414 *** Looping through 5.2. Iter = 460 iteration 460; minNextMutationTime = 414.539; timeNextPopSample = 415; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 461 iteration 461; minNextMutationTime = 425; timeNextPopSample = 415; popParams.size() = 2 We are SAMPLING at time 415 *** Looping through 5.2. Iter = 462 iteration 462; minNextMutationTime = 426; timeNextPopSample = 416; popParams.size() = 2 We are SAMPLING at time 416 *** Looping through 5.2. Iter = 463 iteration 463; minNextMutationTime = 427; timeNextPopSample = 417; popParams.size() = 1 We are SAMPLING at time 417 *** Looping through 5.2. Iter = 464 iteration 464; minNextMutationTime = 428; timeNextPopSample = 418; popParams.size() = 1 We are SAMPLING at time 418 *** Looping through 5.2. Iter = 465 iteration 465; minNextMutationTime = 429; timeNextPopSample = 419; popParams.size() = 1 We are SAMPLING at time 419 *** Looping through 5.2. Iter = 466 iteration 466; minNextMutationTime = 430; timeNextPopSample = 420; popParams.size() = 1 We are SAMPLING at time 420 *** Looping through 5.2. Iter = 467 iteration 467; minNextMutationTime = 431; timeNextPopSample = 421; popParams.size() = 1 We are SAMPLING at time 421 *** Looping through 5.2. Iter = 468 iteration 468; minNextMutationTime = 432; timeNextPopSample = 422; popParams.size() = 1 We are SAMPLING at time 422 *** Looping through 5.2. Iter = 469 iteration 469; minNextMutationTime = 433; timeNextPopSample = 423; popParams.size() = 1 We are SAMPLING at time 423 *** Looping through 5.2. Iter = 470 iteration 470; minNextMutationTime = 434; timeNextPopSample = 424; popParams.size() = 1 We are SAMPLING at time 424 *** Looping through 5.2. Iter = 471 iteration 471; minNextMutationTime = 435; timeNextPopSample = 425; popParams.size() = 1 We are SAMPLING at time 425 *** Looping through 5.2. Iter = 472 iteration 472; minNextMutationTime = 436; timeNextPopSample = 426; popParams.size() = 1 We are SAMPLING at time 426 *** Looping through 5.2. Iter = 473 iteration 473; minNextMutationTime = 437; timeNextPopSample = 427; popParams.size() = 1 We are SAMPLING at time 427 *** Looping through 5.2. Iter = 474 iteration 474; minNextMutationTime = 438; timeNextPopSample = 428; popParams.size() = 1 We are SAMPLING at time 428 *** Looping through 5.2. Iter = 475 iteration 475; minNextMutationTime = 439; timeNextPopSample = 429; popParams.size() = 1 We are SAMPLING at time 429 *** Looping through 5.2. Iter = 476 iteration 476; minNextMutationTime = 440; timeNextPopSample = 430; popParams.size() = 1 We are SAMPLING at time 430 *** Looping through 5.2. Iter = 477 iteration 477; minNextMutationTime = 441; timeNextPopSample = 431; popParams.size() = 1 We are SAMPLING at time 431 *** Looping through 5.2. Iter = 478 iteration 478; minNextMutationTime = 442; timeNextPopSample = 432; popParams.size() = 1 We are SAMPLING at time 432 *** Looping through 5.2. Iter = 479 iteration 479; minNextMutationTime = 443; timeNextPopSample = 433; popParams.size() = 1 We are SAMPLING at time 433 *** Looping through 5.2. Iter = 480 iteration 480; minNextMutationTime = 444; timeNextPopSample = 434; popParams.size() = 1 We are SAMPLING at time 434 *** Looping through 5.2. Iter = 481 iteration 481; minNextMutationTime = 445; timeNextPopSample = 435; popParams.size() = 1 We are SAMPLING at time 435 *** Looping through 5.2. Iter = 482 iteration 482; minNextMutationTime = 446; timeNextPopSample = 436; popParams.size() = 1 We are SAMPLING at time 436 *** Looping through 5.2. Iter = 483 iteration 483; minNextMutationTime = 447; timeNextPopSample = 437; popParams.size() = 1 We are SAMPLING at time 437 *** Looping through 5.2. Iter = 484 iteration 484; minNextMutationTime = 448; timeNextPopSample = 438; popParams.size() = 1 We are SAMPLING at time 438 *** Looping through 5.2. Iter = 485 iteration 485; minNextMutationTime = 449; timeNextPopSample = 439; popParams.size() = 1 We are SAMPLING at time 439 *** Looping through 5.2. Iter = 486 iteration 486; minNextMutationTime = 450; timeNextPopSample = 440; popParams.size() = 1 We are SAMPLING at time 440 *** Looping through 5.2. Iter = 487 iteration 487; minNextMutationTime = 451; timeNextPopSample = 441; popParams.size() = 1 We are SAMPLING at time 441 *** Looping through 5.2. Iter = 488 iteration 488; minNextMutationTime = 452; timeNextPopSample = 442; popParams.size() = 1 We are SAMPLING at time 442 *** Looping through 5.2. Iter = 489 iteration 489; minNextMutationTime = 453; timeNextPopSample = 443; popParams.size() = 1 We are SAMPLING at time 443 *** Looping through 5.2. Iter = 490 iteration 490; minNextMutationTime = 454; timeNextPopSample = 444; popParams.size() = 1 We are SAMPLING at time 444 *** Looping through 5.2. Iter = 491 iteration 491; minNextMutationTime = 455; timeNextPopSample = 445; popParams.size() = 1 We are SAMPLING at time 445 *** Looping through 5.2. Iter = 492 iteration 492; minNextMutationTime = 456; timeNextPopSample = 446; popParams.size() = 1 We are SAMPLING at time 446 *** Looping through 5.2. Iter = 493 iteration 493; minNextMutationTime = 457; timeNextPopSample = 447; popParams.size() = 1 We are SAMPLING at time 447 *** Looping through 5.2. Iter = 494 iteration 494; minNextMutationTime = 458; timeNextPopSample = 448; popParams.size() = 1 We are SAMPLING at time 448 *** Looping through 5.2. Iter = 495 iteration 495; minNextMutationTime = 459; timeNextPopSample = 449; popParams.size() = 1 We are SAMPLING at time 449 *** Looping through 5.2. Iter = 496 iteration 496; minNextMutationTime = 460; timeNextPopSample = 450; popParams.size() = 1 We are SAMPLING at time 450 *** Looping through 5.2. Iter = 497 iteration 497; minNextMutationTime = 461; timeNextPopSample = 451; popParams.size() = 1 We are SAMPLING at time 451 *** Looping through 5.2. Iter = 498 iteration 498; minNextMutationTime = 462; timeNextPopSample = 452; popParams.size() = 1 We are SAMPLING at time 452 *** Looping through 5.2. Iter = 499 iteration 499; minNextMutationTime = 463; timeNextPopSample = 453; popParams.size() = 1 We are SAMPLING at time 453 *** Looping through 5.2. Iter = 500 iteration 500; minNextMutationTime = 464; timeNextPopSample = 454; popParams.size() = 1 We are SAMPLING at time 454 *** Looping through 5.2. Iter = 501 iteration 501; minNextMutationTime = 465; timeNextPopSample = 455; popParams.size() = 1 We are SAMPLING at time 455 *** Looping through 5.2. Iter = 502 iteration 502; minNextMutationTime = 466; timeNextPopSample = 456; popParams.size() = 1 We are SAMPLING at time 456 *** Looping through 5.2. Iter = 503 iteration 503; minNextMutationTime = 467; timeNextPopSample = 457; popParams.size() = 1 We are SAMPLING at time 457 *** Looping through 5.2. Iter = 504 iteration 504; minNextMutationTime = 468; timeNextPopSample = 458; popParams.size() = 1 We are SAMPLING at time 458 *** Looping through 5.2. Iter = 505 iteration 505; minNextMutationTime = 469; timeNextPopSample = 459; popParams.size() = 1 We are SAMPLING at time 459 *** Looping through 5.2. Iter = 506 iteration 506; minNextMutationTime = 470; timeNextPopSample = 460; popParams.size() = 1 We are SAMPLING at time 460 *** Looping through 5.2. Iter = 507 iteration 507; minNextMutationTime = 471; timeNextPopSample = 461; popParams.size() = 1 We are SAMPLING at time 461 *** Looping through 5.2. Iter = 508 iteration 508; minNextMutationTime = 472; timeNextPopSample = 462; popParams.size() = 1 We are SAMPLING at time 462 *** Looping through 5.2. Iter = 509 iteration 509; minNextMutationTime = 473; timeNextPopSample = 463; popParams.size() = 1 We are SAMPLING at time 463 *** Looping through 5.2. Iter = 510 iteration 510; minNextMutationTime = 474; timeNextPopSample = 464; popParams.size() = 1 We are SAMPLING at time 464 *** Looping through 5.2. Iter = 511 iteration 511; minNextMutationTime = 475; timeNextPopSample = 465; popParams.size() = 1 We are SAMPLING at time 465 *** Looping through 5.2. Iter = 512 iteration 512; minNextMutationTime = 476; timeNextPopSample = 466; popParams.size() = 1 We are SAMPLING at time 466 *** Looping through 5.2. Iter = 513 iteration 513; minNextMutationTime = 477; timeNextPopSample = 467; popParams.size() = 1 We are SAMPLING at time 467 *** Looping through 5.2. Iter = 514 iteration 514; minNextMutationTime = 478; timeNextPopSample = 468; popParams.size() = 1 We are SAMPLING at time 468 *** Looping through 5.2. Iter = 515 iteration 515; minNextMutationTime = 479; timeNextPopSample = 469; popParams.size() = 1 We are SAMPLING at time 469 *** Looping through 5.2. Iter = 516 iteration 516; minNextMutationTime = 480; timeNextPopSample = 470; popParams.size() = 1 We are SAMPLING at time 470 *** Looping through 5.2. Iter = 517 iteration 517; minNextMutationTime = 481; timeNextPopSample = 471; popParams.size() = 1 We are SAMPLING at time 471 *** Looping through 5.2. Iter = 518 iteration 518; minNextMutationTime = 482; timeNextPopSample = 472; popParams.size() = 1 We are SAMPLING at time 472 *** Looping through 5.2. Iter = 519 iteration 519; minNextMutationTime = 483; timeNextPopSample = 473; popParams.size() = 1 We are SAMPLING at time 473 *** Looping through 5.2. Iter = 520 iteration 520; minNextMutationTime = 484; timeNextPopSample = 474; popParams.size() = 1 We are SAMPLING at time 474 *** Looping through 5.2. Iter = 521 iteration 521; minNextMutationTime = 474.208; timeNextPopSample = 475; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 522 iteration 522; minNextMutationTime = 485; timeNextPopSample = 475; popParams.size() = 2 We are SAMPLING at time 475 *** Looping through 5.2. Iter = 523 iteration 523; minNextMutationTime = 486; timeNextPopSample = 476; popParams.size() = 1 We are SAMPLING at time 476 *** Looping through 5.2. Iter = 524 iteration 524; minNextMutationTime = 487; timeNextPopSample = 477; popParams.size() = 1 We are SAMPLING at time 477 *** Looping through 5.2. Iter = 525 iteration 525; minNextMutationTime = 488; timeNextPopSample = 478; popParams.size() = 1 We are SAMPLING at time 478 *** Looping through 5.2. Iter = 526 iteration 526; minNextMutationTime = 489; timeNextPopSample = 479; popParams.size() = 1 We are SAMPLING at time 479 *** Looping through 5.2. Iter = 527 iteration 527; minNextMutationTime = 490; timeNextPopSample = 480; popParams.size() = 1 We are SAMPLING at time 480 *** Looping through 5.2. Iter = 528 iteration 528; minNextMutationTime = 491; timeNextPopSample = 481; popParams.size() = 1 We are SAMPLING at time 481 *** Looping through 5.2. Iter = 529 iteration 529; minNextMutationTime = 492; timeNextPopSample = 482; popParams.size() = 1 We are SAMPLING at time 482 *** Looping through 5.2. Iter = 530 iteration 530; minNextMutationTime = 493; timeNextPopSample = 483; popParams.size() = 1 We are SAMPLING at time 483 *** Looping through 5.2. Iter = 531 iteration 531; minNextMutationTime = 494; timeNextPopSample = 484; popParams.size() = 1 We are SAMPLING at time 484 *** Looping through 5.2. Iter = 532 iteration 532; minNextMutationTime = 495; timeNextPopSample = 485; popParams.size() = 1 We are SAMPLING at time 485 *** Looping through 5.2. Iter = 533 iteration 533; minNextMutationTime = 496; timeNextPopSample = 486; popParams.size() = 1 We are SAMPLING at time 486 *** Looping through 5.2. Iter = 534 iteration 534; minNextMutationTime = 497; timeNextPopSample = 487; popParams.size() = 1 We are SAMPLING at time 487 *** Looping through 5.2. Iter = 535 iteration 535; minNextMutationTime = 498; timeNextPopSample = 488; popParams.size() = 1 We are SAMPLING at time 488 *** Looping through 5.2. Iter = 536 iteration 536; minNextMutationTime = 499; timeNextPopSample = 489; popParams.size() = 1 We are SAMPLING at time 489 *** Looping through 5.2. Iter = 537 iteration 537; minNextMutationTime = 500; timeNextPopSample = 490; popParams.size() = 1 We are SAMPLING at time 490 *** Looping through 5.2. Iter = 538 iteration 538; minNextMutationTime = 501; timeNextPopSample = 491; popParams.size() = 1 We are SAMPLING at time 491 *** Looping through 5.2. Iter = 539 iteration 539; minNextMutationTime = 502; timeNextPopSample = 492; popParams.size() = 1 We are SAMPLING at time 492 *** Looping through 5.2. Iter = 540 iteration 540; minNextMutationTime = 503; timeNextPopSample = 493; popParams.size() = 1 We are SAMPLING at time 493 *** Looping through 5.2. Iter = 541 iteration 541; minNextMutationTime = 504; timeNextPopSample = 494; popParams.size() = 1 We are SAMPLING at time 494 *** Looping through 5.2. Iter = 542 iteration 542; minNextMutationTime = 505; timeNextPopSample = 495; popParams.size() = 1 We are SAMPLING at time 495 *** Looping through 5.2. Iter = 543 iteration 543; minNextMutationTime = 506; timeNextPopSample = 496; popParams.size() = 1 We are SAMPLING at time 496 *** Looping through 5.2. Iter = 544 iteration 544; minNextMutationTime = 507; timeNextPopSample = 497; popParams.size() = 1 We are SAMPLING at time 497 *** Looping through 5.2. Iter = 545 iteration 545; minNextMutationTime = 508; timeNextPopSample = 498; popParams.size() = 1 We are SAMPLING at time 498 *** Looping through 5.2. Iter = 546 iteration 546; minNextMutationTime = 509; timeNextPopSample = 499; popParams.size() = 1 We are SAMPLING at time 499 *** Looping through 5.2. Iter = 547 iteration 547; minNextMutationTime = 510; timeNextPopSample = 500; popParams.size() = 1 We are SAMPLING at time 500 *** Looping through 5.2. Iter = 548 iteration 548; minNextMutationTime = 511; timeNextPopSample = 501; popParams.size() = 1 We are SAMPLING at time 501 *** Looping through 5.2. Iter = 549 iteration 549; minNextMutationTime = 512; timeNextPopSample = 502; popParams.size() = 1 We are SAMPLING at time 502 *** Looping through 5.2. Iter = 550 iteration 550; minNextMutationTime = 513; timeNextPopSample = 503; popParams.size() = 1 We are SAMPLING at time 503 *** Looping through 5.2. Iter = 551 iteration 551; minNextMutationTime = 514; timeNextPopSample = 504; popParams.size() = 1 We are SAMPLING at time 504 *** Looping through 5.2. Iter = 552 iteration 552; minNextMutationTime = 515; timeNextPopSample = 505; popParams.size() = 1 We are SAMPLING at time 505 *** Looping through 5.2. Iter = 553 iteration 553; minNextMutationTime = 516; timeNextPopSample = 506; popParams.size() = 1 We are SAMPLING at time 506 *** Looping through 5.2. Iter = 554 iteration 554; minNextMutationTime = 517; timeNextPopSample = 507; popParams.size() = 1 We are SAMPLING at time 507 *** Looping through 5.2. Iter = 555 iteration 555; minNextMutationTime = 518; timeNextPopSample = 508; popParams.size() = 1 We are SAMPLING at time 508 *** Looping through 5.2. Iter = 556 iteration 556; minNextMutationTime = 519; timeNextPopSample = 509; popParams.size() = 1 We are SAMPLING at time 509 *** Looping through 5.2. Iter = 557 iteration 557; minNextMutationTime = 509.923; timeNextPopSample = 510; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 558 iteration 558; minNextMutationTime = 520; timeNextPopSample = 510; popParams.size() = 2 We are SAMPLING at time 510 *** Looping through 5.2. Iter = 559 iteration 559; minNextMutationTime = 521; timeNextPopSample = 511; popParams.size() = 2 We are SAMPLING at time 511 *** Looping through 5.2. Iter = 560 iteration 560; minNextMutationTime = 522; timeNextPopSample = 512; popParams.size() = 2 We are SAMPLING at time 512 *** Looping through 5.2. Iter = 561 iteration 561; minNextMutationTime = 523; timeNextPopSample = 513; popParams.size() = 2 We are SAMPLING at time 513 *** Looping through 5.2. Iter = 562 iteration 562; minNextMutationTime = 524; timeNextPopSample = 514; popParams.size() = 2 We are SAMPLING at time 514 *** Looping through 5.2. Iter = 563 iteration 563; minNextMutationTime = 525; timeNextPopSample = 515; popParams.size() = 2 We are SAMPLING at time 515 *** Looping through 5.2. Iter = 564 iteration 564; minNextMutationTime = 526; timeNextPopSample = 516; popParams.size() = 2 We are SAMPLING at time 516 *** Looping through 5.2. Iter = 565 iteration 565; minNextMutationTime = 527; timeNextPopSample = 517; popParams.size() = 2 We are SAMPLING at time 517 *** Looping through 5.2. Iter = 566 iteration 566; minNextMutationTime = 528; timeNextPopSample = 518; popParams.size() = 2 We are SAMPLING at time 518 *** Looping through 5.2. Iter = 567 iteration 567; minNextMutationTime = 529; timeNextPopSample = 519; popParams.size() = 2 We are SAMPLING at time 519 *** Looping through 5.2. Iter = 568 iteration 568; minNextMutationTime = 530; timeNextPopSample = 520; popParams.size() = 2 We are SAMPLING at time 520 *** Looping through 5.2. Iter = 569 iteration 569; minNextMutationTime = 531; timeNextPopSample = 521; popParams.size() = 2 We are SAMPLING at time 521 *** Looping through 5.2. Iter = 570 iteration 570; minNextMutationTime = 532; timeNextPopSample = 522; popParams.size() = 2 We are SAMPLING at time 522 *** Looping through 5.2. Iter = 571 iteration 571; minNextMutationTime = 533; timeNextPopSample = 523; popParams.size() = 2 We are SAMPLING at time 523 *** Looping through 5.2. Iter = 572 iteration 572; minNextMutationTime = 534; timeNextPopSample = 524; popParams.size() = 2 We are SAMPLING at time 524 *** Looping through 5.2. Iter = 573 iteration 573; minNextMutationTime = 535; timeNextPopSample = 525; popParams.size() = 2 We are SAMPLING at time 525 *** Looping through 5.2. Iter = 574 iteration 574; minNextMutationTime = 536; timeNextPopSample = 526; popParams.size() = 2 We are SAMPLING at time 526 *** Looping through 5.2. Iter = 575 iteration 575; minNextMutationTime = 537; timeNextPopSample = 527; popParams.size() = 2 We are SAMPLING at time 527 *** Looping through 5.2. Iter = 576 iteration 576; minNextMutationTime = 538; timeNextPopSample = 528; popParams.size() = 2 We are SAMPLING at time 528 *** Looping through 5.2. Iter = 577 iteration 577; minNextMutationTime = 539; timeNextPopSample = 529; popParams.size() = 2 We are SAMPLING at time 529 *** Looping through 5.2. Iter = 578 iteration 578; minNextMutationTime = 540; timeNextPopSample = 530; popParams.size() = 2 We are SAMPLING at time 530 *** Looping through 5.2. Iter = 579 iteration 579; minNextMutationTime = 541; timeNextPopSample = 531; popParams.size() = 2 We are SAMPLING at time 531 *** Looping through 5.2. Iter = 580 iteration 580; minNextMutationTime = 531.183; timeNextPopSample = 532; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 581 iteration 581; minNextMutationTime = 542; timeNextPopSample = 532; popParams.size() = 3 We are SAMPLING at time 532 *** Looping through 5.2. Iter = 582 iteration 582; minNextMutationTime = 543; timeNextPopSample = 533; popParams.size() = 2 We are SAMPLING at time 533 *** Looping through 5.2. Iter = 583 iteration 583; minNextMutationTime = 544; timeNextPopSample = 534; popParams.size() = 2 We are SAMPLING at time 534 *** Looping through 5.2. Iter = 584 iteration 584; minNextMutationTime = 545; timeNextPopSample = 535; popParams.size() = 2 We are SAMPLING at time 535 *** Looping through 5.2. Iter = 585 iteration 585; minNextMutationTime = 546; timeNextPopSample = 536; popParams.size() = 2 We are SAMPLING at time 536 *** Looping through 5.2. Iter = 586 iteration 586; minNextMutationTime = 547; timeNextPopSample = 537; popParams.size() = 2 We are SAMPLING at time 537 *** Looping through 5.2. Iter = 587 iteration 587; minNextMutationTime = 548; timeNextPopSample = 538; popParams.size() = 2 We are SAMPLING at time 538 *** Looping through 5.2. Iter = 588 iteration 588; minNextMutationTime = 549; timeNextPopSample = 539; popParams.size() = 2 We are SAMPLING at time 539 *** Looping through 5.2. Iter = 589 iteration 589; minNextMutationTime = 550; timeNextPopSample = 540; popParams.size() = 2 We are SAMPLING at time 540 *** Looping through 5.2. Iter = 590 iteration 590; minNextMutationTime = 551; timeNextPopSample = 541; popParams.size() = 2 We are SAMPLING at time 541 *** Looping through 5.2. Iter = 591 iteration 591; minNextMutationTime = 541.778; timeNextPopSample = 542; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 592 iteration 592; minNextMutationTime = 541.818; timeNextPopSample = 542; popParams.size() = 3 Mutated to existing species 2 (Genotype = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 1) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 1) New popSize = 2 *** Looping through 5.2. Iter = 593 iteration 593; minNextMutationTime = 552; timeNextPopSample = 542; popParams.size() = 3 We are SAMPLING at time 542 *** Looping through 5.2. Iter = 594 iteration 594; minNextMutationTime = 553; timeNextPopSample = 543; popParams.size() = 3 We are SAMPLING at time 543 *** Looping through 5.2. Iter = 595 iteration 595; minNextMutationTime = 554; timeNextPopSample = 544; popParams.size() = 3 We are SAMPLING at time 544 *** Looping through 5.2. Iter = 596 iteration 596; minNextMutationTime = 555; timeNextPopSample = 545; popParams.size() = 3 We are SAMPLING at time 545 *** Looping through 5.2. Iter = 597 iteration 597; minNextMutationTime = 545.268; timeNextPopSample = 546; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 598 iteration 598; minNextMutationTime = 556; timeNextPopSample = 546; popParams.size() = 3 We are SAMPLING at time 546 *** Looping through 5.2. Iter = 599 iteration 599; minNextMutationTime = 546.63; timeNextPopSample = 547; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 600 iteration 600; minNextMutationTime = 546.811; timeNextPopSample = 547; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 601 iteration 601; minNextMutationTime = 557; timeNextPopSample = 547; popParams.size() = 4 We are SAMPLING at time 547 *** Looping through 5.2. Iter = 602 iteration 602; minNextMutationTime = 558; timeNextPopSample = 548; popParams.size() = 3 We are SAMPLING at time 548 *** Looping through 5.2. Iter = 603 iteration 603; minNextMutationTime = 559; timeNextPopSample = 549; popParams.size() = 3 We are SAMPLING at time 549 *** Looping through 5.2. Iter = 604 iteration 604; minNextMutationTime = 560; timeNextPopSample = 550; popParams.size() = 2 We are SAMPLING at time 550 *** Looping through 5.2. Iter = 605 iteration 605; minNextMutationTime = 561; timeNextPopSample = 551; popParams.size() = 2 We are SAMPLING at time 551 *** Looping through 5.2. Iter = 606 iteration 606; minNextMutationTime = 551.65; timeNextPopSample = 552; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 607 iteration 607; minNextMutationTime = 562; timeNextPopSample = 552; popParams.size() = 3 We are SAMPLING at time 552 *** Looping through 5.2. Iter = 608 iteration 608; minNextMutationTime = 563; timeNextPopSample = 553; popParams.size() = 3 We are SAMPLING at time 553 *** Looping through 5.2. Iter = 609 iteration 609; minNextMutationTime = 564; timeNextPopSample = 554; popParams.size() = 3 We are SAMPLING at time 554 *** Looping through 5.2. Iter = 610 iteration 610; minNextMutationTime = 565; timeNextPopSample = 555; popParams.size() = 3 We are SAMPLING at time 555 *** Looping through 5.2. Iter = 611 iteration 611; minNextMutationTime = 555.315; timeNextPopSample = 556; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 612 iteration 612; minNextMutationTime = 566; timeNextPopSample = 556; popParams.size() = 4 We are SAMPLING at time 556 *** Looping through 5.2. Iter = 613 iteration 613; minNextMutationTime = 567; timeNextPopSample = 557; popParams.size() = 2 We are SAMPLING at time 557 *** Looping through 5.2. Iter = 614 iteration 614; minNextMutationTime = 568; timeNextPopSample = 558; popParams.size() = 2 We are SAMPLING at time 558 *** Looping through 5.2. Iter = 615 iteration 615; minNextMutationTime = 558.352; timeNextPopSample = 559; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 616 iteration 616; minNextMutationTime = 569; timeNextPopSample = 559; popParams.size() = 3 We are SAMPLING at time 559 *** Looping through 5.2. Iter = 617 iteration 617; minNextMutationTime = 570; timeNextPopSample = 560; popParams.size() = 3 We are SAMPLING at time 560 *** Looping through 5.2. Iter = 618 iteration 618; minNextMutationTime = 571; timeNextPopSample = 561; popParams.size() = 2 We are SAMPLING at time 561 *** Looping through 5.2. Iter = 619 iteration 619; minNextMutationTime = 572; timeNextPopSample = 562; popParams.size() = 2 We are SAMPLING at time 562 *** Looping through 5.2. Iter = 620 iteration 620; minNextMutationTime = 573; timeNextPopSample = 563; popParams.size() = 2 We are SAMPLING at time 563 *** Looping through 5.2. Iter = 621 iteration 621; minNextMutationTime = 574; timeNextPopSample = 564; popParams.size() = 2 We are SAMPLING at time 564 *** Looping through 5.2. Iter = 622 iteration 622; minNextMutationTime = 575; timeNextPopSample = 565; popParams.size() = 2 We are SAMPLING at time 565 *** Looping through 5.2. Iter = 623 iteration 623; minNextMutationTime = 576; timeNextPopSample = 566; popParams.size() = 2 We are SAMPLING at time 566 *** Looping through 5.2. Iter = 624 iteration 624; minNextMutationTime = 577; timeNextPopSample = 567; popParams.size() = 2 We are SAMPLING at time 567 *** Looping through 5.2. Iter = 625 iteration 625; minNextMutationTime = 578; timeNextPopSample = 568; popParams.size() = 2 We are SAMPLING at time 568 *** Looping through 5.2. Iter = 626 iteration 626; minNextMutationTime = 579; timeNextPopSample = 569; popParams.size() = 2 We are SAMPLING at time 569 *** Looping through 5.2. Iter = 627 iteration 627; minNextMutationTime = 580; timeNextPopSample = 570; popParams.size() = 2 We are SAMPLING at time 570 *** Looping through 5.2. Iter = 628 iteration 628; minNextMutationTime = 581; timeNextPopSample = 571; popParams.size() = 2 We are SAMPLING at time 571 *** Looping through 5.2. Iter = 629 iteration 629; minNextMutationTime = 582; timeNextPopSample = 572; popParams.size() = 2 We are SAMPLING at time 572 *** Looping through 5.2. Iter = 630 iteration 630; minNextMutationTime = 583; timeNextPopSample = 573; popParams.size() = 2 We are SAMPLING at time 573 *** Looping through 5.2. Iter = 631 iteration 631; minNextMutationTime = 584; timeNextPopSample = 574; popParams.size() = 2 We are SAMPLING at time 574 *** Looping through 5.2. Iter = 632 iteration 632; minNextMutationTime = 574.936; timeNextPopSample = 575; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 633 iteration 633; minNextMutationTime = 585; timeNextPopSample = 575; popParams.size() = 3 We are SAMPLING at time 575 *** Looping through 5.2. Iter = 634 iteration 634; minNextMutationTime = 586; timeNextPopSample = 576; popParams.size() = 3 We are SAMPLING at time 576 *** Looping through 5.2. Iter = 635 iteration 635; minNextMutationTime = 587; timeNextPopSample = 577; popParams.size() = 3 We are SAMPLING at time 577 *** Looping through 5.2. Iter = 636 iteration 636; minNextMutationTime = 588; timeNextPopSample = 578; popParams.size() = 3 We are SAMPLING at time 578 *** Looping through 5.2. Iter = 637 iteration 637; minNextMutationTime = 589; timeNextPopSample = 579; popParams.size() = 3 We are SAMPLING at time 579 *** Looping through 5.2. Iter = 638 iteration 638; minNextMutationTime = 590; timeNextPopSample = 580; popParams.size() = 3 We are SAMPLING at time 580 *** Looping through 5.2. Iter = 639 iteration 639; minNextMutationTime = 580.273; timeNextPopSample = 581; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 640 iteration 640; minNextMutationTime = 591; timeNextPopSample = 581; popParams.size() = 4 We are SAMPLING at time 581 *** Looping through 5.2. Iter = 641 iteration 641; minNextMutationTime = 592; timeNextPopSample = 582; popParams.size() = 4 We are SAMPLING at time 582 *** Looping through 5.2. Iter = 642 iteration 642; minNextMutationTime = 593; timeNextPopSample = 583; popParams.size() = 4 We are SAMPLING at time 583 *** Looping through 5.2. Iter = 643 iteration 643; minNextMutationTime = 583.62; timeNextPopSample = 584; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 644 iteration 644; minNextMutationTime = 594; timeNextPopSample = 584; popParams.size() = 4 We are SAMPLING at time 584 *** Looping through 5.2. Iter = 645 iteration 645; minNextMutationTime = 595; timeNextPopSample = 585; popParams.size() = 4 We are SAMPLING at time 585 *** Looping through 5.2. Iter = 646 iteration 646; minNextMutationTime = 596; timeNextPopSample = 586; popParams.size() = 3 We are SAMPLING at time 586 *** Looping through 5.2. Iter = 647 iteration 647; minNextMutationTime = 597; timeNextPopSample = 587; popParams.size() = 2 We are SAMPLING at time 587 *** Looping through 5.2. Iter = 648 iteration 648; minNextMutationTime = 598; timeNextPopSample = 588; popParams.size() = 2 We are SAMPLING at time 588 *** Looping through 5.2. Iter = 649 iteration 649; minNextMutationTime = 599; timeNextPopSample = 589; popParams.size() = 2 We are SAMPLING at time 589 *** Looping through 5.2. Iter = 650 iteration 650; minNextMutationTime = 589.353; timeNextPopSample = 590; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 651 iteration 651; minNextMutationTime = 600; timeNextPopSample = 590; popParams.size() = 3 We are SAMPLING at time 590 *** Looping through 5.2. Iter = 652 iteration 652; minNextMutationTime = 601; timeNextPopSample = 591; popParams.size() = 3 We are SAMPLING at time 591 *** Looping through 5.2. Iter = 653 iteration 653; minNextMutationTime = 602; timeNextPopSample = 592; popParams.size() = 3 We are SAMPLING at time 592 *** Looping through 5.2. Iter = 654 iteration 654; minNextMutationTime = 603; timeNextPopSample = 593; popParams.size() = 3 We are SAMPLING at time 593 *** Looping through 5.2. Iter = 655 iteration 655; minNextMutationTime = 604; timeNextPopSample = 594; popParams.size() = 3 We are SAMPLING at time 594 *** Looping through 5.2. Iter = 656 iteration 656; minNextMutationTime = 605; timeNextPopSample = 595; popParams.size() = 3 We are SAMPLING at time 595 *** Looping through 5.2. Iter = 657 iteration 657; minNextMutationTime = 606; timeNextPopSample = 596; popParams.size() = 3 We are SAMPLING at time 596 *** Looping through 5.2. Iter = 658 iteration 658; minNextMutationTime = 607; timeNextPopSample = 597; popParams.size() = 3 We are SAMPLING at time 597 *** Looping through 5.2. Iter = 659 iteration 659; minNextMutationTime = 608; timeNextPopSample = 598; popParams.size() = 3 We are SAMPLING at time 598 *** Looping through 5.2. Iter = 660 iteration 660; minNextMutationTime = 609; timeNextPopSample = 599; popParams.size() = 3 We are SAMPLING at time 599 *** Looping through 5.2. Iter = 661 iteration 661; minNextMutationTime = 610; timeNextPopSample = 600; popParams.size() = 3 We are SAMPLING at time 600 *** Looping through 5.2. Iter = 662 iteration 662; minNextMutationTime = 611; timeNextPopSample = 601; popParams.size() = 3 We are SAMPLING at time 601 *** Looping through 5.2. Iter = 663 iteration 663; minNextMutationTime = 612; timeNextPopSample = 602; popParams.size() = 3 We are SAMPLING at time 602 *** Looping through 5.2. Iter = 664 iteration 664; minNextMutationTime = 613; timeNextPopSample = 603; popParams.size() = 3 We are SAMPLING at time 603 *** Looping through 5.2. Iter = 665 iteration 665; minNextMutationTime = 614; timeNextPopSample = 604; popParams.size() = 3 We are SAMPLING at time 604 *** Looping through 5.2. Iter = 666 iteration 666; minNextMutationTime = 604.893; timeNextPopSample = 605; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 667 iteration 667; minNextMutationTime = 615; timeNextPopSample = 605; popParams.size() = 4 We are SAMPLING at time 605 *** Looping through 5.2. Iter = 668 iteration 668; minNextMutationTime = 616; timeNextPopSample = 606; popParams.size() = 4 We are SAMPLING at time 606 *** Looping through 5.2. Iter = 669 iteration 669; minNextMutationTime = 617; timeNextPopSample = 607; popParams.size() = 4 We are SAMPLING at time 607 *** Looping through 5.2. Iter = 670 iteration 670; minNextMutationTime = 618; timeNextPopSample = 608; popParams.size() = 3 We are SAMPLING at time 608 *** Looping through 5.2. Iter = 671 iteration 671; minNextMutationTime = 619; timeNextPopSample = 609; popParams.size() = 3 We are SAMPLING at time 609 *** Looping through 5.2. Iter = 672 iteration 672; minNextMutationTime = 620; timeNextPopSample = 610; popParams.size() = 3 We are SAMPLING at time 610 *** Looping through 5.2. Iter = 673 iteration 673; minNextMutationTime = 621; timeNextPopSample = 611; popParams.size() = 2 We are SAMPLING at time 611 *** Looping through 5.2. Iter = 674 iteration 674; minNextMutationTime = 622; timeNextPopSample = 612; popParams.size() = 2 We are SAMPLING at time 612 *** Looping through 5.2. Iter = 675 iteration 675; minNextMutationTime = 623; timeNextPopSample = 613; popParams.size() = 2 We are SAMPLING at time 613 *** Looping through 5.2. Iter = 676 iteration 676; minNextMutationTime = 613.156; timeNextPopSample = 614; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 677 iteration 677; minNextMutationTime = 624; timeNextPopSample = 614; popParams.size() = 3 We are SAMPLING at time 614 *** Looping through 5.2. Iter = 678 iteration 678; minNextMutationTime = 625; timeNextPopSample = 615; popParams.size() = 2 We are SAMPLING at time 615 *** Looping through 5.2. Iter = 679 iteration 679; minNextMutationTime = 626; timeNextPopSample = 616; popParams.size() = 2 We are SAMPLING at time 616 *** Looping through 5.2. Iter = 680 iteration 680; minNextMutationTime = 627; timeNextPopSample = 617; popParams.size() = 2 We are SAMPLING at time 617 *** Looping through 5.2. Iter = 681 iteration 681; minNextMutationTime = 628; timeNextPopSample = 618; popParams.size() = 2 We are SAMPLING at time 618 *** Looping through 5.2. Iter = 682 iteration 682; minNextMutationTime = 629; timeNextPopSample = 619; popParams.size() = 2 We are SAMPLING at time 619 *** Looping through 5.2. Iter = 683 iteration 683; minNextMutationTime = 630; timeNextPopSample = 620; popParams.size() = 2 We are SAMPLING at time 620 *** Looping through 5.2. Iter = 684 iteration 684; minNextMutationTime = 631; timeNextPopSample = 621; popParams.size() = 2 We are SAMPLING at time 621 *** Looping through 5.2. Iter = 685 iteration 685; minNextMutationTime = 621.118; timeNextPopSample = 622; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 686 iteration 686; minNextMutationTime = 632; timeNextPopSample = 622; popParams.size() = 3 We are SAMPLING at time 622 *** Looping through 5.2. Iter = 687 iteration 687; minNextMutationTime = 633; timeNextPopSample = 623; popParams.size() = 2 We are SAMPLING at time 623 *** Looping through 5.2. Iter = 688 iteration 688; minNextMutationTime = 634; timeNextPopSample = 624; popParams.size() = 2 We are SAMPLING at time 624 *** Looping through 5.2. Iter = 689 iteration 689; minNextMutationTime = 635; timeNextPopSample = 625; popParams.size() = 2 We are SAMPLING at time 625 *** Looping through 5.2. Iter = 690 iteration 690; minNextMutationTime = 636; timeNextPopSample = 626; popParams.size() = 2 We are SAMPLING at time 626 *** Looping through 5.2. Iter = 691 iteration 691; minNextMutationTime = 637; timeNextPopSample = 627; popParams.size() = 2 We are SAMPLING at time 627 *** Looping through 5.2. Iter = 692 iteration 692; minNextMutationTime = 638; timeNextPopSample = 628; popParams.size() = 2 We are SAMPLING at time 628 *** Looping through 5.2. Iter = 693 iteration 693; minNextMutationTime = 639; timeNextPopSample = 629; popParams.size() = 2 We are SAMPLING at time 629 *** Looping through 5.2. Iter = 694 iteration 694; minNextMutationTime = 640; timeNextPopSample = 630; popParams.size() = 2 We are SAMPLING at time 630 *** Looping through 5.2. Iter = 695 iteration 695; minNextMutationTime = 641; timeNextPopSample = 631; popParams.size() = 2 We are SAMPLING at time 631 *** Looping through 5.2. Iter = 696 iteration 696; minNextMutationTime = 642; timeNextPopSample = 632; popParams.size() = 2 We are SAMPLING at time 632 *** Looping through 5.2. Iter = 697 iteration 697; minNextMutationTime = 632.578; timeNextPopSample = 633; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 698 iteration 698; minNextMutationTime = 643; timeNextPopSample = 633; popParams.size() = 3 We are SAMPLING at time 633 *** Looping through 5.2. Iter = 699 iteration 699; minNextMutationTime = 644; timeNextPopSample = 634; popParams.size() = 3 We are SAMPLING at time 634 *** Looping through 5.2. Iter = 700 iteration 700; minNextMutationTime = 645; timeNextPopSample = 635; popParams.size() = 3 We are SAMPLING at time 635 *** Looping through 5.2. Iter = 701 iteration 701; minNextMutationTime = 646; timeNextPopSample = 636; popParams.size() = 3 We are SAMPLING at time 636 *** Looping through 5.2. Iter = 702 iteration 702; minNextMutationTime = 647; timeNextPopSample = 637; popParams.size() = 3 We are SAMPLING at time 637 *** Looping through 5.2. Iter = 703 iteration 703; minNextMutationTime = 648; timeNextPopSample = 638; popParams.size() = 3 We are SAMPLING at time 638 *** Looping through 5.2. Iter = 704 iteration 704; minNextMutationTime = 649; timeNextPopSample = 639; popParams.size() = 3 We are SAMPLING at time 639 *** Looping through 5.2. Iter = 705 iteration 705; minNextMutationTime = 650; timeNextPopSample = 640; popParams.size() = 2 We are SAMPLING at time 640 *** Looping through 5.2. Iter = 706 iteration 706; minNextMutationTime = 651; timeNextPopSample = 641; popParams.size() = 2 We are SAMPLING at time 641 *** Looping through 5.2. Iter = 707 iteration 707; minNextMutationTime = 652; timeNextPopSample = 642; popParams.size() = 2 We are SAMPLING at time 642 *** Looping through 5.2. Iter = 708 iteration 708; minNextMutationTime = 653; timeNextPopSample = 643; popParams.size() = 2 We are SAMPLING at time 643 *** Looping through 5.2. Iter = 709 iteration 709; minNextMutationTime = 654; timeNextPopSample = 644; popParams.size() = 2 We are SAMPLING at time 644 *** Looping through 5.2. Iter = 710 iteration 710; minNextMutationTime = 655; timeNextPopSample = 645; popParams.size() = 2 We are SAMPLING at time 645 *** Looping through 5.2. Iter = 711 iteration 711; minNextMutationTime = 656; timeNextPopSample = 646; popParams.size() = 2 We are SAMPLING at time 646 *** Looping through 5.2. Iter = 712 iteration 712; minNextMutationTime = 657; timeNextPopSample = 647; popParams.size() = 2 We are SAMPLING at time 647 *** Looping through 5.2. Iter = 713 iteration 713; minNextMutationTime = 658; timeNextPopSample = 648; popParams.size() = 2 We are SAMPLING at time 648 *** Looping through 5.2. Iter = 714 iteration 714; minNextMutationTime = 659; timeNextPopSample = 649; popParams.size() = 2 We are SAMPLING at time 649 *** Looping through 5.2. Iter = 715 iteration 715; minNextMutationTime = 660; timeNextPopSample = 650; popParams.size() = 2 We are SAMPLING at time 650 *** Looping through 5.2. Iter = 716 iteration 716; minNextMutationTime = 661; timeNextPopSample = 651; popParams.size() = 2 We are SAMPLING at time 651 *** Looping through 5.2. Iter = 717 iteration 717; minNextMutationTime = 662; timeNextPopSample = 652; popParams.size() = 2 We are SAMPLING at time 652 *** Looping through 5.2. Iter = 718 iteration 718; minNextMutationTime = 663; timeNextPopSample = 653; popParams.size() = 2 We are SAMPLING at time 653 *** Looping through 5.2. Iter = 719 iteration 719; minNextMutationTime = 664; timeNextPopSample = 654; popParams.size() = 2 We are SAMPLING at time 654 *** Looping through 5.2. Iter = 720 iteration 720; minNextMutationTime = 665; timeNextPopSample = 655; popParams.size() = 2 We are SAMPLING at time 655 *** Looping through 5.2. Iter = 721 iteration 721; minNextMutationTime = 666; timeNextPopSample = 656; popParams.size() = 2 We are SAMPLING at time 656 *** Looping through 5.2. Iter = 722 iteration 722; minNextMutationTime = 667; timeNextPopSample = 657; popParams.size() = 2 We are SAMPLING at time 657 *** Looping through 5.2. Iter = 723 iteration 723; minNextMutationTime = 668; timeNextPopSample = 658; popParams.size() = 2 We are SAMPLING at time 658 *** Looping through 5.2. Iter = 724 iteration 724; minNextMutationTime = 669; timeNextPopSample = 659; popParams.size() = 2 We are SAMPLING at time 659 *** Looping through 5.2. Iter = 725 iteration 725; minNextMutationTime = 670; timeNextPopSample = 660; popParams.size() = 2 We are SAMPLING at time 660 *** Looping through 5.2. Iter = 726 iteration 726; minNextMutationTime = 671; timeNextPopSample = 661; popParams.size() = 2 We are SAMPLING at time 661 *** Looping through 5.2. Iter = 727 iteration 727; minNextMutationTime = 672; timeNextPopSample = 662; popParams.size() = 2 We are SAMPLING at time 662 *** Looping through 5.2. Iter = 728 iteration 728; minNextMutationTime = 673; timeNextPopSample = 663; popParams.size() = 2 We are SAMPLING at time 663 *** Looping through 5.2. Iter = 729 iteration 729; minNextMutationTime = 674; timeNextPopSample = 664; popParams.size() = 2 We are SAMPLING at time 664 *** Looping through 5.2. Iter = 730 iteration 730; minNextMutationTime = 675; timeNextPopSample = 665; popParams.size() = 2 We are SAMPLING at time 665 *** Looping through 5.2. Iter = 731 iteration 731; minNextMutationTime = 676; timeNextPopSample = 666; popParams.size() = 2 We are SAMPLING at time 666 *** Looping through 5.2. Iter = 732 iteration 732; minNextMutationTime = 677; timeNextPopSample = 667; popParams.size() = 2 We are SAMPLING at time 667 *** Looping through 5.2. Iter = 733 iteration 733; minNextMutationTime = 678; timeNextPopSample = 668; popParams.size() = 2 We are SAMPLING at time 668 *** Looping through 5.2. Iter = 734 iteration 734; minNextMutationTime = 679; timeNextPopSample = 669; popParams.size() = 2 We are SAMPLING at time 669 *** Looping through 5.2. Iter = 735 iteration 735; minNextMutationTime = 680; timeNextPopSample = 670; popParams.size() = 2 We are SAMPLING at time 670 *** Looping through 5.2. Iter = 736 iteration 736; minNextMutationTime = 681; timeNextPopSample = 671; popParams.size() = 2 We are SAMPLING at time 671 *** Looping through 5.2. Iter = 737 iteration 737; minNextMutationTime = 682; timeNextPopSample = 672; popParams.size() = 2 We are SAMPLING at time 672 *** Looping through 5.2. Iter = 738 iteration 738; minNextMutationTime = 683; timeNextPopSample = 673; popParams.size() = 2 We are SAMPLING at time 673 *** Looping through 5.2. Iter = 739 iteration 739; minNextMutationTime = 684; timeNextPopSample = 674; popParams.size() = 2 We are SAMPLING at time 674 *** Looping through 5.2. Iter = 740 iteration 740; minNextMutationTime = 674.179; timeNextPopSample = 675; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 741 iteration 741; minNextMutationTime = 685; timeNextPopSample = 675; popParams.size() = 3 We are SAMPLING at time 675 *** Looping through 5.2. Iter = 742 iteration 742; minNextMutationTime = 686; timeNextPopSample = 676; popParams.size() = 3 We are SAMPLING at time 676 *** Looping through 5.2. Iter = 743 iteration 743; minNextMutationTime = 687; timeNextPopSample = 677; popParams.size() = 3 We are SAMPLING at time 677 *** Looping through 5.2. Iter = 744 iteration 744; minNextMutationTime = 688; timeNextPopSample = 678; popParams.size() = 3 We are SAMPLING at time 678 *** Looping through 5.2. Iter = 745 iteration 745; minNextMutationTime = 689; timeNextPopSample = 679; popParams.size() = 2 We are SAMPLING at time 679 *** Looping through 5.2. Iter = 746 iteration 746; minNextMutationTime = 690; timeNextPopSample = 680; popParams.size() = 2 We are SAMPLING at time 680 *** Looping through 5.2. Iter = 747 iteration 747; minNextMutationTime = 691; timeNextPopSample = 681; popParams.size() = 2 We are SAMPLING at time 681 *** Looping through 5.2. Iter = 748 iteration 748; minNextMutationTime = 692; timeNextPopSample = 682; popParams.size() = 2 We are SAMPLING at time 682 *** Looping through 5.2. Iter = 749 iteration 749; minNextMutationTime = 693; timeNextPopSample = 683; popParams.size() = 2 We are SAMPLING at time 683 *** Looping through 5.2. Iter = 750 iteration 750; minNextMutationTime = 683.963; timeNextPopSample = 684; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 751 iteration 751; minNextMutationTime = 694; timeNextPopSample = 684; popParams.size() = 3 We are SAMPLING at time 684 *** Looping through 5.2. Iter = 752 iteration 752; minNextMutationTime = 695; timeNextPopSample = 685; popParams.size() = 3 We are SAMPLING at time 685 *** Looping through 5.2. Iter = 753 iteration 753; minNextMutationTime = 696; timeNextPopSample = 686; popParams.size() = 2 We are SAMPLING at time 686 *** Looping through 5.2. Iter = 754 iteration 754; minNextMutationTime = 697; timeNextPopSample = 687; popParams.size() = 2 We are SAMPLING at time 687 *** Looping through 5.2. Iter = 755 iteration 755; minNextMutationTime = 698; timeNextPopSample = 688; popParams.size() = 2 We are SAMPLING at time 688 *** Looping through 5.2. Iter = 756 iteration 756; minNextMutationTime = 699; timeNextPopSample = 689; popParams.size() = 2 We are SAMPLING at time 689 *** Looping through 5.2. Iter = 757 iteration 757; minNextMutationTime = 700; timeNextPopSample = 690; popParams.size() = 2 We are SAMPLING at time 690 *** Looping through 5.2. Iter = 758 iteration 758; minNextMutationTime = 701; timeNextPopSample = 691; popParams.size() = 2 We are SAMPLING at time 691 *** Looping through 5.2. Iter = 759 iteration 759; minNextMutationTime = 702; timeNextPopSample = 692; popParams.size() = 2 We are SAMPLING at time 692 *** Looping through 5.2. Iter = 760 iteration 760; minNextMutationTime = 703; timeNextPopSample = 693; popParams.size() = 2 We are SAMPLING at time 693 *** Looping through 5.2. Iter = 761 iteration 761; minNextMutationTime = 704; timeNextPopSample = 694; popParams.size() = 2 We are SAMPLING at time 694 *** Looping through 5.2. Iter = 762 iteration 762; minNextMutationTime = 705; timeNextPopSample = 695; popParams.size() = 2 We are SAMPLING at time 695 *** Looping through 5.2. Iter = 763 iteration 763; minNextMutationTime = 706; timeNextPopSample = 696; popParams.size() = 2 We are SAMPLING at time 696 *** Looping through 5.2. Iter = 764 iteration 764; minNextMutationTime = 707; timeNextPopSample = 697; popParams.size() = 2 We are SAMPLING at time 697 *** Looping through 5.2. Iter = 765 iteration 765; minNextMutationTime = 708; timeNextPopSample = 698; popParams.size() = 2 We are SAMPLING at time 698 *** Looping through 5.2. Iter = 766 iteration 766; minNextMutationTime = 709; timeNextPopSample = 699; popParams.size() = 2 We are SAMPLING at time 699 *** Looping through 5.2. Iter = 767 iteration 767; minNextMutationTime = 710; timeNextPopSample = 700; popParams.size() = 2 We are SAMPLING at time 700 *** Looping through 5.2. Iter = 768 iteration 768; minNextMutationTime = 711; timeNextPopSample = 701; popParams.size() = 2 We are SAMPLING at time 701 *** Looping through 5.2. Iter = 769 iteration 769; minNextMutationTime = 712; timeNextPopSample = 702; popParams.size() = 2 We are SAMPLING at time 702 *** Looping through 5.2. Iter = 770 iteration 770; minNextMutationTime = 713; timeNextPopSample = 703; popParams.size() = 2 We are SAMPLING at time 703 *** Looping through 5.2. Iter = 771 iteration 771; minNextMutationTime = 714; timeNextPopSample = 704; popParams.size() = 2 We are SAMPLING at time 704 *** Looping through 5.2. Iter = 772 iteration 772; minNextMutationTime = 715; timeNextPopSample = 705; popParams.size() = 2 We are SAMPLING at time 705 *** Looping through 5.2. Iter = 773 iteration 773; minNextMutationTime = 716; timeNextPopSample = 706; popParams.size() = 2 We are SAMPLING at time 706 *** Looping through 5.2. Iter = 774 iteration 774; minNextMutationTime = 717; timeNextPopSample = 707; popParams.size() = 2 We are SAMPLING at time 707 *** Looping through 5.2. Iter = 775 iteration 775; minNextMutationTime = 718; timeNextPopSample = 708; popParams.size() = 2 We are SAMPLING at time 708 *** Looping through 5.2. Iter = 776 iteration 776; minNextMutationTime = 719; timeNextPopSample = 709; popParams.size() = 2 We are SAMPLING at time 709 *** Looping through 5.2. Iter = 777 iteration 777; minNextMutationTime = 720; timeNextPopSample = 710; popParams.size() = 2 We are SAMPLING at time 710 *** Looping through 5.2. Iter = 778 iteration 778; minNextMutationTime = 721; timeNextPopSample = 711; popParams.size() = 2 We are SAMPLING at time 711 *** Looping through 5.2. Iter = 779 iteration 779; minNextMutationTime = 722; timeNextPopSample = 712; popParams.size() = 2 We are SAMPLING at time 712 *** Looping through 5.2. Iter = 780 iteration 780; minNextMutationTime = 723; timeNextPopSample = 713; popParams.size() = 2 We are SAMPLING at time 713 *** Looping through 5.2. Iter = 781 iteration 781; minNextMutationTime = 724; timeNextPopSample = 714; popParams.size() = 2 We are SAMPLING at time 714 *** Looping through 5.2. Iter = 782 iteration 782; minNextMutationTime = 725; timeNextPopSample = 715; popParams.size() = 2 We are SAMPLING at time 715 *** Looping through 5.2. Iter = 783 iteration 783; minNextMutationTime = 726; timeNextPopSample = 716; popParams.size() = 2 We are SAMPLING at time 716 *** Looping through 5.2. Iter = 784 iteration 784; minNextMutationTime = 727; timeNextPopSample = 717; popParams.size() = 2 We are SAMPLING at time 717 *** Looping through 5.2. Iter = 785 iteration 785; minNextMutationTime = 717.879; timeNextPopSample = 718; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 786 iteration 786; minNextMutationTime = 728; timeNextPopSample = 718; popParams.size() = 3 We are SAMPLING at time 718 *** Looping through 5.2. Iter = 787 iteration 787; minNextMutationTime = 729; timeNextPopSample = 719; popParams.size() = 3 We are SAMPLING at time 719 *** Looping through 5.2. Iter = 788 iteration 788; minNextMutationTime = 730; timeNextPopSample = 720; popParams.size() = 3 We are SAMPLING at time 720 *** Looping through 5.2. Iter = 789 iteration 789; minNextMutationTime = 731; timeNextPopSample = 721; popParams.size() = 2 We are SAMPLING at time 721 *** Looping through 5.2. Iter = 790 iteration 790; minNextMutationTime = 732; timeNextPopSample = 722; popParams.size() = 2 We are SAMPLING at time 722 *** Looping through 5.2. Iter = 791 iteration 791; minNextMutationTime = 733; timeNextPopSample = 723; popParams.size() = 2 We are SAMPLING at time 723 *** Looping through 5.2. Iter = 792 iteration 792; minNextMutationTime = 734; timeNextPopSample = 724; popParams.size() = 2 We are SAMPLING at time 724 *** Looping through 5.2. Iter = 793 iteration 793; minNextMutationTime = 735; timeNextPopSample = 725; popParams.size() = 2 We are SAMPLING at time 725 *** Looping through 5.2. Iter = 794 iteration 794; minNextMutationTime = 736; timeNextPopSample = 726; popParams.size() = 2 We are SAMPLING at time 726 *** Looping through 5.2. Iter = 795 iteration 795; minNextMutationTime = 737; timeNextPopSample = 727; popParams.size() = 2 We are SAMPLING at time 727 *** Looping through 5.2. Iter = 796 iteration 796; minNextMutationTime = 727.114; timeNextPopSample = 728; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000100000; sp_id = 32) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 32) New popSize = 151 *** Looping through 5.2. Iter = 797 iteration 797; minNextMutationTime = 738; timeNextPopSample = 728; popParams.size() = 2 We are SAMPLING at time 728 *** Looping through 5.2. Iter = 798 iteration 798; minNextMutationTime = 739; timeNextPopSample = 729; popParams.size() = 2 We are SAMPLING at time 729 *** Looping through 5.2. Iter = 799 iteration 799; minNextMutationTime = 740; timeNextPopSample = 730; popParams.size() = 2 We are SAMPLING at time 730 *** Looping through 5.2. Iter = 800 iteration 800; minNextMutationTime = 741; timeNextPopSample = 731; popParams.size() = 2 We are SAMPLING at time 731 *** Looping through 5.2. Iter = 801 iteration 801; minNextMutationTime = 742; timeNextPopSample = 732; popParams.size() = 2 We are SAMPLING at time 732 *** Looping through 5.2. Iter = 802 iteration 802; minNextMutationTime = 743; timeNextPopSample = 733; popParams.size() = 2 We are SAMPLING at time 733 *** Looping through 5.2. Iter = 803 iteration 803; minNextMutationTime = 744; timeNextPopSample = 734; popParams.size() = 2 We are SAMPLING at time 734 *** Looping through 5.2. Iter = 804 iteration 804; minNextMutationTime = 745; timeNextPopSample = 735; popParams.size() = 2 We are SAMPLING at time 735 *** Looping through 5.2. Iter = 805 iteration 805; minNextMutationTime = 746; timeNextPopSample = 736; popParams.size() = 2 We are SAMPLING at time 736 *** Looping through 5.2. Iter = 806 iteration 806; minNextMutationTime = 747; timeNextPopSample = 737; popParams.size() = 2 We are SAMPLING at time 737 *** Looping through 5.2. Iter = 807 iteration 807; minNextMutationTime = 748; timeNextPopSample = 738; popParams.size() = 2 We are SAMPLING at time 738 *** Looping through 5.2. Iter = 808 iteration 808; minNextMutationTime = 749; timeNextPopSample = 739; popParams.size() = 2 We are SAMPLING at time 739 *** Looping through 5.2. Iter = 809 iteration 809; minNextMutationTime = 750; timeNextPopSample = 740; popParams.size() = 2 We are SAMPLING at time 740 *** Looping through 5.2. Iter = 810 iteration 810; minNextMutationTime = 751; timeNextPopSample = 741; popParams.size() = 2 We are SAMPLING at time 741 *** Looping through 5.2. Iter = 811 iteration 811; minNextMutationTime = 752; timeNextPopSample = 742; popParams.size() = 2 We are SAMPLING at time 742 *** Looping through 5.2. Iter = 812 iteration 812; minNextMutationTime = 753; timeNextPopSample = 743; popParams.size() = 2 We are SAMPLING at time 743 *** Looping through 5.2. Iter = 813 iteration 813; minNextMutationTime = 754; timeNextPopSample = 744; popParams.size() = 2 We are SAMPLING at time 744 *** Looping through 5.2. Iter = 814 iteration 814; minNextMutationTime = 755; timeNextPopSample = 745; popParams.size() = 2 We are SAMPLING at time 745 *** Looping through 5.2. Iter = 815 iteration 815; minNextMutationTime = 756; timeNextPopSample = 746; popParams.size() = 2 We are SAMPLING at time 746 *** Looping through 5.2. Iter = 816 iteration 816; minNextMutationTime = 757; timeNextPopSample = 747; popParams.size() = 2 We are SAMPLING at time 747 *** Looping through 5.2. Iter = 817 iteration 817; minNextMutationTime = 758; timeNextPopSample = 748; popParams.size() = 2 We are SAMPLING at time 748 *** Looping through 5.2. Iter = 818 iteration 818; minNextMutationTime = 759; timeNextPopSample = 749; popParams.size() = 2 We are SAMPLING at time 749 *** Looping through 5.2. Iter = 819 iteration 819; minNextMutationTime = 760; timeNextPopSample = 750; popParams.size() = 2 We are SAMPLING at time 750 *** Looping through 5.2. Iter = 820 iteration 820; minNextMutationTime = 761; timeNextPopSample = 751; popParams.size() = 2 We are SAMPLING at time 751 *** Looping through 5.2. Iter = 821 iteration 821; minNextMutationTime = 762; timeNextPopSample = 752; popParams.size() = 2 We are SAMPLING at time 752 *** Looping through 5.2. Iter = 822 iteration 822; minNextMutationTime = 763; timeNextPopSample = 753; popParams.size() = 2 We are SAMPLING at time 753 *** Looping through 5.2. Iter = 823 iteration 823; minNextMutationTime = 764; timeNextPopSample = 754; popParams.size() = 2 We are SAMPLING at time 754 *** Looping through 5.2. Iter = 824 iteration 824; minNextMutationTime = 765; timeNextPopSample = 755; popParams.size() = 2 We are SAMPLING at time 755 *** Looping through 5.2. Iter = 825 iteration 825; minNextMutationTime = 766; timeNextPopSample = 756; popParams.size() = 2 We are SAMPLING at time 756 *** Looping through 5.2. Iter = 826 iteration 826; minNextMutationTime = 756.947; timeNextPopSample = 757; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000100000; sp_id = 32) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 32) New popSize = 78 *** Looping through 5.2. Iter = 827 iteration 827; minNextMutationTime = 767; timeNextPopSample = 757; popParams.size() = 2 We are SAMPLING at time 757 *** Looping through 5.2. Iter = 828 iteration 828; minNextMutationTime = 768; timeNextPopSample = 758; popParams.size() = 2 We are SAMPLING at time 758 *** Looping through 5.2. Iter = 829 iteration 829; minNextMutationTime = 769; timeNextPopSample = 759; popParams.size() = 2 We are SAMPLING at time 759 *** Looping through 5.2. Iter = 830 iteration 830; minNextMutationTime = 770; timeNextPopSample = 760; popParams.size() = 2 We are SAMPLING at time 760 *** Looping through 5.2. Iter = 831 iteration 831; minNextMutationTime = 771; timeNextPopSample = 761; popParams.size() = 2 We are SAMPLING at time 761 *** Looping through 5.2. Iter = 832 iteration 832; minNextMutationTime = 772; timeNextPopSample = 762; popParams.size() = 2 We are SAMPLING at time 762 *** Looping through 5.2. Iter = 833 iteration 833; minNextMutationTime = 773; timeNextPopSample = 763; popParams.size() = 2 We are SAMPLING at time 763 *** Looping through 5.2. Iter = 834 iteration 834; minNextMutationTime = 774; timeNextPopSample = 764; popParams.size() = 2 We are SAMPLING at time 764 *** Looping through 5.2. Iter = 835 iteration 835; minNextMutationTime = 764.994; timeNextPopSample = 765; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000100000; sp_id = 32) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 32) New popSize = 28 *** Looping through 5.2. Iter = 836 iteration 836; minNextMutationTime = 775; timeNextPopSample = 765; popParams.size() = 2 We are SAMPLING at time 765 *** Looping through 5.2. Iter = 837 iteration 837; minNextMutationTime = 776; timeNextPopSample = 766; popParams.size() = 2 We are SAMPLING at time 766 *** Looping through 5.2. Iter = 838 iteration 838; minNextMutationTime = 777; timeNextPopSample = 767; popParams.size() = 2 We are SAMPLING at time 767 *** Looping through 5.2. Iter = 839 iteration 839; minNextMutationTime = 778; timeNextPopSample = 768; popParams.size() = 2 We are SAMPLING at time 768 *** Looping through 5.2. Iter = 840 iteration 840; minNextMutationTime = 779; timeNextPopSample = 769; popParams.size() = 2 We are SAMPLING at time 769 *** Looping through 5.2. Iter = 841 iteration 841; minNextMutationTime = 780; timeNextPopSample = 770; popParams.size() = 2 We are SAMPLING at time 770 *** Looping through 5.2. Iter = 842 iteration 842; minNextMutationTime = 781; timeNextPopSample = 771; popParams.size() = 2 We are SAMPLING at time 771 *** Looping through 5.2. Iter = 843 iteration 843; minNextMutationTime = 782; timeNextPopSample = 772; popParams.size() = 2 We are SAMPLING at time 772 *** Looping through 5.2. Iter = 844 iteration 844; minNextMutationTime = 783; timeNextPopSample = 773; popParams.size() = 2 We are SAMPLING at time 773 *** Looping through 5.2. Iter = 845 iteration 845; minNextMutationTime = 784; timeNextPopSample = 774; popParams.size() = 2 We are SAMPLING at time 774 *** Looping through 5.2. Iter = 846 iteration 846; minNextMutationTime = 785; timeNextPopSample = 775; popParams.size() = 2 We are SAMPLING at time 775 *** Looping through 5.2. Iter = 847 iteration 847; minNextMutationTime = 786; timeNextPopSample = 776; popParams.size() = 2 We are SAMPLING at time 776 *** Looping through 5.2. Iter = 848 iteration 848; minNextMutationTime = 787; timeNextPopSample = 777; popParams.size() = 2 We are SAMPLING at time 777 *** Looping through 5.2. Iter = 849 iteration 849; minNextMutationTime = 788; timeNextPopSample = 778; popParams.size() = 2 We are SAMPLING at time 778 *** Looping through 5.2. Iter = 850 iteration 850; minNextMutationTime = 789; timeNextPopSample = 779; popParams.size() = 2 We are SAMPLING at time 779 *** Looping through 5.2. Iter = 851 iteration 851; minNextMutationTime = 779.742; timeNextPopSample = 780; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 852 iteration 852; minNextMutationTime = 790; timeNextPopSample = 780; popParams.size() = 3 We are SAMPLING at time 780 *** Looping through 5.2. Iter = 853 iteration 853; minNextMutationTime = 791; timeNextPopSample = 781; popParams.size() = 3 We are SAMPLING at time 781 *** Looping through 5.2. Iter = 854 iteration 854; minNextMutationTime = 792; timeNextPopSample = 782; popParams.size() = 2 We are SAMPLING at time 782 *** Looping through 5.2. Iter = 855 iteration 855; minNextMutationTime = 793; timeNextPopSample = 783; popParams.size() = 2 We are SAMPLING at time 783 *** Looping through 5.2. Iter = 856 iteration 856; minNextMutationTime = 794; timeNextPopSample = 784; popParams.size() = 2 We are SAMPLING at time 784 *** Looping through 5.2. Iter = 857 iteration 857; minNextMutationTime = 795; timeNextPopSample = 785; popParams.size() = 2 We are SAMPLING at time 785 *** Looping through 5.2. Iter = 858 iteration 858; minNextMutationTime = 796; timeNextPopSample = 786; popParams.size() = 2 We are SAMPLING at time 786 *** Looping through 5.2. Iter = 859 iteration 859; minNextMutationTime = 797; timeNextPopSample = 787; popParams.size() = 2 We are SAMPLING at time 787 *** Looping through 5.2. Iter = 860 iteration 860; minNextMutationTime = 787.86; timeNextPopSample = 788; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 861 iteration 861; minNextMutationTime = 798; timeNextPopSample = 788; popParams.size() = 3 We are SAMPLING at time 788 *** Looping through 5.2. Iter = 862 iteration 862; minNextMutationTime = 799; timeNextPopSample = 789; popParams.size() = 3 We are SAMPLING at time 789 *** Looping through 5.2. Iter = 863 iteration 863; minNextMutationTime = 800; timeNextPopSample = 790; popParams.size() = 3 We are SAMPLING at time 790 *** Looping through 5.2. Iter = 864 iteration 864; minNextMutationTime = 801; timeNextPopSample = 791; popParams.size() = 3 We are SAMPLING at time 791 *** Looping through 5.2. Iter = 865 iteration 865; minNextMutationTime = 802; timeNextPopSample = 792; popParams.size() = 3 We are SAMPLING at time 792 *** Looping through 5.2. Iter = 866 iteration 866; minNextMutationTime = 803; timeNextPopSample = 793; popParams.size() = 3 We are SAMPLING at time 793 *** Looping through 5.2. Iter = 867 iteration 867; minNextMutationTime = 804; timeNextPopSample = 794; popParams.size() = 3 We are SAMPLING at time 794 *** Looping through 5.2. Iter = 868 iteration 868; minNextMutationTime = 805; timeNextPopSample = 795; popParams.size() = 3 We are SAMPLING at time 795 *** Looping through 5.2. Iter = 869 iteration 869; minNextMutationTime = 806; timeNextPopSample = 796; popParams.size() = 3 We are SAMPLING at time 796 *** Looping through 5.2. Iter = 870 iteration 870; minNextMutationTime = 807; timeNextPopSample = 797; popParams.size() = 3 We are SAMPLING at time 797 *** Looping through 5.2. Iter = 871 iteration 871; minNextMutationTime = 808; timeNextPopSample = 798; popParams.size() = 2 We are SAMPLING at time 798 *** Looping through 5.2. Iter = 872 iteration 872; minNextMutationTime = 809; timeNextPopSample = 799; popParams.size() = 2 We are SAMPLING at time 799 *** Looping through 5.2. Iter = 873 iteration 873; minNextMutationTime = 810; timeNextPopSample = 800; popParams.size() = 1 We are SAMPLING at time 800 *** Looping through 5.2. Iter = 874 iteration 874; minNextMutationTime = 811; timeNextPopSample = 801; popParams.size() = 1 We are SAMPLING at time 801 *** Looping through 5.2. Iter = 875 iteration 875; minNextMutationTime = 801.033; timeNextPopSample = 802; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 876 iteration 876; minNextMutationTime = 812; timeNextPopSample = 802; popParams.size() = 2 We are SAMPLING at time 802 *** Looping through 5.2. Iter = 877 iteration 877; minNextMutationTime = 813; timeNextPopSample = 803; popParams.size() = 2 We are SAMPLING at time 803 *** Looping through 5.2. Iter = 878 iteration 878; minNextMutationTime = 814; timeNextPopSample = 804; popParams.size() = 2 We are SAMPLING at time 804 *** Looping through 5.2. Iter = 879 iteration 879; minNextMutationTime = 815; timeNextPopSample = 805; popParams.size() = 1 We are SAMPLING at time 805 *** Looping through 5.2. Iter = 880 iteration 880; minNextMutationTime = 816; timeNextPopSample = 806; popParams.size() = 1 We are SAMPLING at time 806 *** Looping through 5.2. Iter = 881 iteration 881; minNextMutationTime = 817; timeNextPopSample = 807; popParams.size() = 1 We are SAMPLING at time 807 *** Looping through 5.2. Iter = 882 iteration 882; minNextMutationTime = 818; timeNextPopSample = 808; popParams.size() = 1 We are SAMPLING at time 808 *** Looping through 5.2. Iter = 883 iteration 883; minNextMutationTime = 819; timeNextPopSample = 809; popParams.size() = 1 We are SAMPLING at time 809 *** Looping through 5.2. Iter = 884 iteration 884; minNextMutationTime = 820; timeNextPopSample = 810; popParams.size() = 1 We are SAMPLING at time 810 *** Looping through 5.2. Iter = 885 iteration 885; minNextMutationTime = 821; timeNextPopSample = 811; popParams.size() = 1 We are SAMPLING at time 811 *** Looping through 5.2. Iter = 886 iteration 886; minNextMutationTime = 822; timeNextPopSample = 812; popParams.size() = 1 We are SAMPLING at time 812 *** Looping through 5.2. Iter = 887 iteration 887; minNextMutationTime = 823; timeNextPopSample = 813; popParams.size() = 1 We are SAMPLING at time 813 *** Looping through 5.2. Iter = 888 iteration 888; minNextMutationTime = 813.758; timeNextPopSample = 814; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 889 iteration 889; minNextMutationTime = 824; timeNextPopSample = 814; popParams.size() = 2 We are SAMPLING at time 814 *** Looping through 5.2. Iter = 890 iteration 890; minNextMutationTime = 825; timeNextPopSample = 815; popParams.size() = 2 We are SAMPLING at time 815 *** Looping through 5.2. Iter = 891 iteration 891; minNextMutationTime = 826; timeNextPopSample = 816; popParams.size() = 2 We are SAMPLING at time 816 *** Looping through 5.2. Iter = 892 iteration 892; minNextMutationTime = 827; timeNextPopSample = 817; popParams.size() = 1 We are SAMPLING at time 817 *** Looping through 5.2. Iter = 893 iteration 893; minNextMutationTime = 828; timeNextPopSample = 818; popParams.size() = 1 We are SAMPLING at time 818 *** Looping through 5.2. Iter = 894 iteration 894; minNextMutationTime = 829; timeNextPopSample = 819; popParams.size() = 1 We are SAMPLING at time 819 *** Looping through 5.2. Iter = 895 iteration 895; minNextMutationTime = 830; timeNextPopSample = 820; popParams.size() = 1 We are SAMPLING at time 820 *** Looping through 5.2. Iter = 896 iteration 896; minNextMutationTime = 831; timeNextPopSample = 821; popParams.size() = 1 We are SAMPLING at time 821 *** Looping through 5.2. Iter = 897 iteration 897; minNextMutationTime = 832; timeNextPopSample = 822; popParams.size() = 1 We are SAMPLING at time 822 *** Looping through 5.2. Iter = 898 iteration 898; minNextMutationTime = 822.31; timeNextPopSample = 823; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 899 iteration 899; minNextMutationTime = 833; timeNextPopSample = 823; popParams.size() = 2 We are SAMPLING at time 823 *** Looping through 5.2. Iter = 900 iteration 900; minNextMutationTime = 834; timeNextPopSample = 824; popParams.size() = 2 We are SAMPLING at time 824 *** Looping through 5.2. Iter = 901 iteration 901; minNextMutationTime = 835; timeNextPopSample = 825; popParams.size() = 1 We are SAMPLING at time 825 *** Looping through 5.2. Iter = 902 iteration 902; minNextMutationTime = 836; timeNextPopSample = 826; popParams.size() = 1 We are SAMPLING at time 826 *** Looping through 5.2. Iter = 903 iteration 903; minNextMutationTime = 837; timeNextPopSample = 827; popParams.size() = 1 We are SAMPLING at time 827 *** Looping through 5.2. Iter = 904 iteration 904; minNextMutationTime = 838; timeNextPopSample = 828; popParams.size() = 1 We are SAMPLING at time 828 *** Looping through 5.2. Iter = 905 iteration 905; minNextMutationTime = 839; timeNextPopSample = 829; popParams.size() = 1 We are SAMPLING at time 829 *** Looping through 5.2. Iter = 906 iteration 906; minNextMutationTime = 840; timeNextPopSample = 830; popParams.size() = 1 We are SAMPLING at time 830 *** Looping through 5.2. Iter = 907 iteration 907; minNextMutationTime = 841; timeNextPopSample = 831; popParams.size() = 1 We are SAMPLING at time 831 *** Looping through 5.2. Iter = 908 iteration 908; minNextMutationTime = 842; timeNextPopSample = 832; popParams.size() = 1 We are SAMPLING at time 832 *** Looping through 5.2. Iter = 909 iteration 909; minNextMutationTime = 843; timeNextPopSample = 833; popParams.size() = 1 We are SAMPLING at time 833 *** Looping through 5.2. Iter = 910 iteration 910; minNextMutationTime = 844; timeNextPopSample = 834; popParams.size() = 1 We are SAMPLING at time 834 *** Looping through 5.2. Iter = 911 iteration 911; minNextMutationTime = 834.396; timeNextPopSample = 835; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 912 iteration 912; minNextMutationTime = 845; timeNextPopSample = 835; popParams.size() = 2 We are SAMPLING at time 835 *** Looping through 5.2. Iter = 913 iteration 913; minNextMutationTime = 846; timeNextPopSample = 836; popParams.size() = 2 We are SAMPLING at time 836 *** Looping through 5.2. Iter = 914 iteration 914; minNextMutationTime = 847; timeNextPopSample = 837; popParams.size() = 1 We are SAMPLING at time 837 *** Looping through 5.2. Iter = 915 iteration 915; minNextMutationTime = 848; timeNextPopSample = 838; popParams.size() = 1 We are SAMPLING at time 838 *** Looping through 5.2. Iter = 916 iteration 916; minNextMutationTime = 849; timeNextPopSample = 839; popParams.size() = 1 We are SAMPLING at time 839 *** Looping through 5.2. Iter = 917 iteration 917; minNextMutationTime = 850; timeNextPopSample = 840; popParams.size() = 1 We are SAMPLING at time 840 *** Looping through 5.2. Iter = 918 iteration 918; minNextMutationTime = 851; timeNextPopSample = 841; popParams.size() = 1 We are SAMPLING at time 841 *** Looping through 5.2. Iter = 919 iteration 919; minNextMutationTime = 852; timeNextPopSample = 842; popParams.size() = 1 We are SAMPLING at time 842 *** Looping through 5.2. Iter = 920 iteration 920; minNextMutationTime = 853; timeNextPopSample = 843; popParams.size() = 1 We are SAMPLING at time 843 *** Looping through 5.2. Iter = 921 iteration 921; minNextMutationTime = 854; timeNextPopSample = 844; popParams.size() = 1 We are SAMPLING at time 844 *** Looping through 5.2. Iter = 922 iteration 922; minNextMutationTime = 855; timeNextPopSample = 845; popParams.size() = 1 We are SAMPLING at time 845 *** Looping through 5.2. Iter = 923 iteration 923; minNextMutationTime = 856; timeNextPopSample = 846; popParams.size() = 1 We are SAMPLING at time 846 *** Looping through 5.2. Iter = 924 iteration 924; minNextMutationTime = 857; timeNextPopSample = 847; popParams.size() = 1 We are SAMPLING at time 847 *** Looping through 5.2. Iter = 925 iteration 925; minNextMutationTime = 858; timeNextPopSample = 848; popParams.size() = 1 We are SAMPLING at time 848 *** Looping through 5.2. Iter = 926 iteration 926; minNextMutationTime = 859; timeNextPopSample = 849; popParams.size() = 1 We are SAMPLING at time 849 *** Looping through 5.2. Iter = 927 iteration 927; minNextMutationTime = 860; timeNextPopSample = 850; popParams.size() = 1 We are SAMPLING at time 850 *** Looping through 5.2. Iter = 928 iteration 928; minNextMutationTime = 861; timeNextPopSample = 851; popParams.size() = 1 We are SAMPLING at time 851 *** Looping through 5.2. Iter = 929 iteration 929; minNextMutationTime = 862; timeNextPopSample = 852; popParams.size() = 1 We are SAMPLING at time 852 *** Looping through 5.2. Iter = 930 iteration 930; minNextMutationTime = 863; timeNextPopSample = 853; popParams.size() = 1 We are SAMPLING at time 853 *** Looping through 5.2. Iter = 931 iteration 931; minNextMutationTime = 864; timeNextPopSample = 854; popParams.size() = 1 We are SAMPLING at time 854 *** Looping through 5.2. Iter = 932 iteration 932; minNextMutationTime = 865; timeNextPopSample = 855; popParams.size() = 1 We are SAMPLING at time 855 *** Looping through 5.2. Iter = 933 iteration 933; minNextMutationTime = 866; timeNextPopSample = 856; popParams.size() = 1 We are SAMPLING at time 856 *** Looping through 5.2. Iter = 934 iteration 934; minNextMutationTime = 867; timeNextPopSample = 857; popParams.size() = 1 We are SAMPLING at time 857 *** Looping through 5.2. Iter = 935 iteration 935; minNextMutationTime = 868; timeNextPopSample = 858; popParams.size() = 1 We are SAMPLING at time 858 *** Looping through 5.2. Iter = 936 iteration 936; minNextMutationTime = 869; timeNextPopSample = 859; popParams.size() = 1 We are SAMPLING at time 859 *** Looping through 5.2. Iter = 937 iteration 937; minNextMutationTime = 870; timeNextPopSample = 860; popParams.size() = 1 We are SAMPLING at time 860 *** Looping through 5.2. Iter = 938 iteration 938; minNextMutationTime = 871; timeNextPopSample = 861; popParams.size() = 1 We are SAMPLING at time 861 *** Looping through 5.2. Iter = 939 iteration 939; minNextMutationTime = 861.086; timeNextPopSample = 862; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 940 iteration 940; minNextMutationTime = 872; timeNextPopSample = 862; popParams.size() = 2 We are SAMPLING at time 862 *** Looping through 5.2. Iter = 941 iteration 941; minNextMutationTime = 873; timeNextPopSample = 863; popParams.size() = 2 We are SAMPLING at time 863 *** Looping through 5.2. Iter = 942 iteration 942; minNextMutationTime = 874; timeNextPopSample = 864; popParams.size() = 1 We are SAMPLING at time 864 *** Looping through 5.2. Iter = 943 iteration 943; minNextMutationTime = 875; timeNextPopSample = 865; popParams.size() = 1 We are SAMPLING at time 865 *** Looping through 5.2. Iter = 944 iteration 944; minNextMutationTime = 876; timeNextPopSample = 866; popParams.size() = 1 We are SAMPLING at time 866 *** Looping through 5.2. Iter = 945 iteration 945; minNextMutationTime = 877; timeNextPopSample = 867; popParams.size() = 1 We are SAMPLING at time 867 *** Looping through 5.2. Iter = 946 iteration 946; minNextMutationTime = 867.905; timeNextPopSample = 868; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 947 iteration 947; minNextMutationTime = 878; timeNextPopSample = 868; popParams.size() = 2 We are SAMPLING at time 868 *** Looping through 5.2. Iter = 948 iteration 948; minNextMutationTime = 879; timeNextPopSample = 869; popParams.size() = 2 We are SAMPLING at time 869 *** Looping through 5.2. Iter = 949 iteration 949; minNextMutationTime = 869.039; timeNextPopSample = 870; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 950 iteration 950; minNextMutationTime = 869.861; timeNextPopSample = 870; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 951 iteration 951; minNextMutationTime = 880; timeNextPopSample = 870; popParams.size() = 3 We are SAMPLING at time 870 *** Looping through 5.2. Iter = 952 iteration 952; minNextMutationTime = 881; timeNextPopSample = 871; popParams.size() = 3 We are SAMPLING at time 871 *** Looping through 5.2. Iter = 953 iteration 953; minNextMutationTime = 882; timeNextPopSample = 872; popParams.size() = 3 We are SAMPLING at time 872 *** Looping through 5.2. Iter = 954 iteration 954; minNextMutationTime = 883; timeNextPopSample = 873; popParams.size() = 3 We are SAMPLING at time 873 *** Looping through 5.2. Iter = 955 iteration 955; minNextMutationTime = 873.131; timeNextPopSample = 874; popParams.size() = 3 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000000010; sp_id = 2) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 2) New popSize = 10 *** Looping through 5.2. Iter = 956 iteration 956; minNextMutationTime = 884; timeNextPopSample = 874; popParams.size() = 3 We are SAMPLING at time 874 *** Looping through 5.2. Iter = 957 iteration 957; minNextMutationTime = 885; timeNextPopSample = 875; popParams.size() = 3 We are SAMPLING at time 875 *** Looping through 5.2. Iter = 958 iteration 958; minNextMutationTime = 886; timeNextPopSample = 876; popParams.size() = 3 We are SAMPLING at time 876 *** Looping through 5.2. Iter = 959 iteration 959; minNextMutationTime = 887; timeNextPopSample = 877; popParams.size() = 2 We are SAMPLING at time 877 *** Looping through 5.2. Iter = 960 iteration 960; minNextMutationTime = 888; timeNextPopSample = 878; popParams.size() = 2 We are SAMPLING at time 878 *** Looping through 5.2. Iter = 961 iteration 961; minNextMutationTime = 889; timeNextPopSample = 879; popParams.size() = 2 We are SAMPLING at time 879 *** Looping through 5.2. Iter = 962 iteration 962; minNextMutationTime = 890; timeNextPopSample = 880; popParams.size() = 2 We are SAMPLING at time 880 *** Looping through 5.2. Iter = 963 iteration 963; minNextMutationTime = 891; timeNextPopSample = 881; popParams.size() = 2 We are SAMPLING at time 881 *** Looping through 5.2. Iter = 964 iteration 964; minNextMutationTime = 892; timeNextPopSample = 882; popParams.size() = 2 We are SAMPLING at time 882 *** Looping through 5.2. Iter = 965 iteration 965; minNextMutationTime = 893; timeNextPopSample = 883; popParams.size() = 2 We are SAMPLING at time 883 *** Looping through 5.2. Iter = 966 iteration 966; minNextMutationTime = 894; timeNextPopSample = 884; popParams.size() = 2 We are SAMPLING at time 884 *** Looping through 5.2. Iter = 967 iteration 967; minNextMutationTime = 895; timeNextPopSample = 885; popParams.size() = 1 We are SAMPLING at time 885 *** Looping through 5.2. Iter = 968 iteration 968; minNextMutationTime = 896; timeNextPopSample = 886; popParams.size() = 1 We are SAMPLING at time 886 *** Looping through 5.2. Iter = 969 iteration 969; minNextMutationTime = 886.704; timeNextPopSample = 887; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 970 iteration 970; minNextMutationTime = 897; timeNextPopSample = 887; popParams.size() = 2 We are SAMPLING at time 887 *** Looping through 5.2. Iter = 971 iteration 971; minNextMutationTime = 898; timeNextPopSample = 888; popParams.size() = 2 We are SAMPLING at time 888 *** Looping through 5.2. Iter = 972 iteration 972; minNextMutationTime = 899; timeNextPopSample = 889; popParams.size() = 2 We are SAMPLING at time 889 *** Looping through 5.2. Iter = 973 iteration 973; minNextMutationTime = 900; timeNextPopSample = 890; popParams.size() = 2 We are SAMPLING at time 890 *** Looping through 5.2. Iter = 974 iteration 974; minNextMutationTime = 901; timeNextPopSample = 891; popParams.size() = 2 We are SAMPLING at time 891 *** Looping through 5.2. Iter = 975 iteration 975; minNextMutationTime = 902; timeNextPopSample = 892; popParams.size() = 1 We are SAMPLING at time 892 *** Looping through 5.2. Iter = 976 iteration 976; minNextMutationTime = 903; timeNextPopSample = 893; popParams.size() = 1 We are SAMPLING at time 893 *** Looping through 5.2. Iter = 977 iteration 977; minNextMutationTime = 893.289; timeNextPopSample = 894; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 978 iteration 978; minNextMutationTime = 904; timeNextPopSample = 894; popParams.size() = 2 We are SAMPLING at time 894 *** Looping through 5.2. Iter = 979 iteration 979; minNextMutationTime = 905; timeNextPopSample = 895; popParams.size() = 2 We are SAMPLING at time 895 *** Looping through 5.2. Iter = 980 iteration 980; minNextMutationTime = 906; timeNextPopSample = 896; popParams.size() = 1 We are SAMPLING at time 896 *** Looping through 5.2. Iter = 981 iteration 981; minNextMutationTime = 907; timeNextPopSample = 897; popParams.size() = 1 We are SAMPLING at time 897 *** Looping through 5.2. Iter = 982 iteration 982; minNextMutationTime = 908; timeNextPopSample = 898; popParams.size() = 1 We are SAMPLING at time 898 *** Looping through 5.2. Iter = 983 iteration 983; minNextMutationTime = 909; timeNextPopSample = 899; popParams.size() = 1 We are SAMPLING at time 899 *** Looping through 5.2. Iter = 984 iteration 984; minNextMutationTime = 899.022; timeNextPopSample = 900; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 985 iteration 985; minNextMutationTime = 910; timeNextPopSample = 900; popParams.size() = 2 We are SAMPLING at time 900 *** Looping through 5.2. Iter = 986 iteration 986; minNextMutationTime = 911; timeNextPopSample = 901; popParams.size() = 2 We are SAMPLING at time 901 *** Looping through 5.2. Iter = 987 iteration 987; minNextMutationTime = 912; timeNextPopSample = 902; popParams.size() = 2 We are SAMPLING at time 902 *** Looping through 5.2. Iter = 988 iteration 988; minNextMutationTime = 913; timeNextPopSample = 903; popParams.size() = 2 We are SAMPLING at time 903 *** Looping through 5.2. Iter = 989 iteration 989; minNextMutationTime = 914; timeNextPopSample = 904; popParams.size() = 2 We are SAMPLING at time 904 *** Looping through 5.2. Iter = 990 iteration 990; minNextMutationTime = 904.131; timeNextPopSample = 905; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 991 iteration 991; minNextMutationTime = 915; timeNextPopSample = 905; popParams.size() = 3 We are SAMPLING at time 905 *** Looping through 5.2. Iter = 992 iteration 992; minNextMutationTime = 905.884; timeNextPopSample = 906; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 993 iteration 993; minNextMutationTime = 916; timeNextPopSample = 906; popParams.size() = 3 We are SAMPLING at time 906 *** Looping through 5.2. Iter = 994 iteration 994; minNextMutationTime = 906.893; timeNextPopSample = 907; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 995 iteration 995; minNextMutationTime = 917; timeNextPopSample = 907; popParams.size() = 4 We are SAMPLING at time 907 *** Looping through 5.2. Iter = 996 iteration 996; minNextMutationTime = 918; timeNextPopSample = 908; popParams.size() = 3 We are SAMPLING at time 908 *** Looping through 5.2. Iter = 997 iteration 997; minNextMutationTime = 919; timeNextPopSample = 909; popParams.size() = 2 We are SAMPLING at time 909 *** Looping through 5.2. Iter = 998 iteration 998; minNextMutationTime = 920; timeNextPopSample = 910; popParams.size() = 2 We are SAMPLING at time 910 *** Looping through 5.2. Iter = 999 iteration 999; minNextMutationTime = 921; timeNextPopSample = 911; popParams.size() = 2 We are SAMPLING at time 911 ... iteration 1000 ... currentTime 911 *** Looping through 5.2. Iter = 1000 iteration 1000; minNextMutationTime = 911.969; timeNextPopSample = 912; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1001 iteration 1001; minNextMutationTime = 922; timeNextPopSample = 912; popParams.size() = 3 We are SAMPLING at time 912 *** Looping through 5.2. Iter = 1002 iteration 1002; minNextMutationTime = 923; timeNextPopSample = 913; popParams.size() = 3 We are SAMPLING at time 913 *** Looping through 5.2. Iter = 1003 iteration 1003; minNextMutationTime = 924; timeNextPopSample = 914; popParams.size() = 2 We are SAMPLING at time 914 *** Looping through 5.2. Iter = 1004 iteration 1004; minNextMutationTime = 925; timeNextPopSample = 915; popParams.size() = 2 We are SAMPLING at time 915 *** Looping through 5.2. Iter = 1005 iteration 1005; minNextMutationTime = 926; timeNextPopSample = 916; popParams.size() = 2 We are SAMPLING at time 916 *** Looping through 5.2. Iter = 1006 iteration 1006; minNextMutationTime = 927; timeNextPopSample = 917; popParams.size() = 2 We are SAMPLING at time 917 *** Looping through 5.2. Iter = 1007 iteration 1007; minNextMutationTime = 928; timeNextPopSample = 918; popParams.size() = 2 We are SAMPLING at time 918 *** Looping through 5.2. Iter = 1008 iteration 1008; minNextMutationTime = 929; timeNextPopSample = 919; popParams.size() = 2 We are SAMPLING at time 919 *** Looping through 5.2. Iter = 1009 iteration 1009; minNextMutationTime = 930; timeNextPopSample = 920; popParams.size() = 2 We are SAMPLING at time 920 *** Looping through 5.2. Iter = 1010 iteration 1010; minNextMutationTime = 931; timeNextPopSample = 921; popParams.size() = 2 We are SAMPLING at time 921 *** Looping through 5.2. Iter = 1011 iteration 1011; minNextMutationTime = 921.067; timeNextPopSample = 922; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1012 iteration 1012; minNextMutationTime = 932; timeNextPopSample = 922; popParams.size() = 3 We are SAMPLING at time 922 *** Looping through 5.2. Iter = 1013 iteration 1013; minNextMutationTime = 933; timeNextPopSample = 923; popParams.size() = 3 We are SAMPLING at time 923 *** Looping through 5.2. Iter = 1014 iteration 1014; minNextMutationTime = 934; timeNextPopSample = 924; popParams.size() = 3 We are SAMPLING at time 924 *** Looping through 5.2. Iter = 1015 iteration 1015; minNextMutationTime = 935; timeNextPopSample = 925; popParams.size() = 2 We are SAMPLING at time 925 *** Looping through 5.2. Iter = 1016 iteration 1016; minNextMutationTime = 925.089; timeNextPopSample = 926; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000001000; sp_id = 8) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 8) New popSize = 21 *** Looping through 5.2. Iter = 1017 iteration 1017; minNextMutationTime = 936; timeNextPopSample = 926; popParams.size() = 2 We are SAMPLING at time 926 *** Looping through 5.2. Iter = 1018 iteration 1018; minNextMutationTime = 937; timeNextPopSample = 927; popParams.size() = 2 We are SAMPLING at time 927 *** Looping through 5.2. Iter = 1019 iteration 1019; minNextMutationTime = 938; timeNextPopSample = 928; popParams.size() = 2 We are SAMPLING at time 928 *** Looping through 5.2. Iter = 1020 iteration 1020; minNextMutationTime = 939; timeNextPopSample = 929; popParams.size() = 2 We are SAMPLING at time 929 *** Looping through 5.2. Iter = 1021 iteration 1021; minNextMutationTime = 940; timeNextPopSample = 930; popParams.size() = 2 We are SAMPLING at time 930 *** Looping through 5.2. Iter = 1022 iteration 1022; minNextMutationTime = 941; timeNextPopSample = 931; popParams.size() = 2 We are SAMPLING at time 931 *** Looping through 5.2. Iter = 1023 iteration 1023; minNextMutationTime = 942; timeNextPopSample = 932; popParams.size() = 2 We are SAMPLING at time 932 *** Looping through 5.2. Iter = 1024 iteration 1024; minNextMutationTime = 943; timeNextPopSample = 933; popParams.size() = 2 We are SAMPLING at time 933 *** Looping through 5.2. Iter = 1025 iteration 1025; minNextMutationTime = 933.896; timeNextPopSample = 934; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000001000; sp_id = 8) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 8) New popSize = 80 *** Looping through 5.2. Iter = 1026 iteration 1026; minNextMutationTime = 944; timeNextPopSample = 934; popParams.size() = 2 We are SAMPLING at time 934 *** Looping through 5.2. Iter = 1027 iteration 1027; minNextMutationTime = 945; timeNextPopSample = 935; popParams.size() = 2 We are SAMPLING at time 935 *** Looping through 5.2. Iter = 1028 iteration 1028; minNextMutationTime = 946; timeNextPopSample = 936; popParams.size() = 2 We are SAMPLING at time 936 *** Looping through 5.2. Iter = 1029 iteration 1029; minNextMutationTime = 947; timeNextPopSample = 937; popParams.size() = 2 We are SAMPLING at time 937 *** Looping through 5.2. Iter = 1030 iteration 1030; minNextMutationTime = 948; timeNextPopSample = 938; popParams.size() = 2 We are SAMPLING at time 938 *** Looping through 5.2. Iter = 1031 iteration 1031; minNextMutationTime = 949; timeNextPopSample = 939; popParams.size() = 2 We are SAMPLING at time 939 *** Looping through 5.2. Iter = 1032 iteration 1032; minNextMutationTime = 950; timeNextPopSample = 940; popParams.size() = 2 We are SAMPLING at time 940 *** Looping through 5.2. Iter = 1033 iteration 1033; minNextMutationTime = 951; timeNextPopSample = 941; popParams.size() = 2 We are SAMPLING at time 941 *** Looping through 5.2. Iter = 1034 iteration 1034; minNextMutationTime = 952; timeNextPopSample = 942; popParams.size() = 2 We are SAMPLING at time 942 *** Looping through 5.2. Iter = 1035 iteration 1035; minNextMutationTime = 953; timeNextPopSample = 943; popParams.size() = 2 We are SAMPLING at time 943 *** Looping through 5.2. Iter = 1036 iteration 1036; minNextMutationTime = 954; timeNextPopSample = 944; popParams.size() = 2 We are SAMPLING at time 944 *** Looping through 5.2. Iter = 1037 iteration 1037; minNextMutationTime = 955; timeNextPopSample = 945; popParams.size() = 2 We are SAMPLING at time 945 *** Looping through 5.2. Iter = 1038 iteration 1038; minNextMutationTime = 956; timeNextPopSample = 946; popParams.size() = 2 We are SAMPLING at time 946 *** Looping through 5.2. Iter = 1039 iteration 1039; minNextMutationTime = 957; timeNextPopSample = 947; popParams.size() = 2 We are SAMPLING at time 947 *** Looping through 5.2. Iter = 1040 iteration 1040; minNextMutationTime = 958; timeNextPopSample = 948; popParams.size() = 2 We are SAMPLING at time 948 *** Looping through 5.2. Iter = 1041 iteration 1041; minNextMutationTime = 959; timeNextPopSample = 949; popParams.size() = 2 We are SAMPLING at time 949 *** Looping through 5.2. Iter = 1042 iteration 1042; minNextMutationTime = 960; timeNextPopSample = 950; popParams.size() = 2 We are SAMPLING at time 950 *** Looping through 5.2. Iter = 1043 iteration 1043; minNextMutationTime = 961; timeNextPopSample = 951; popParams.size() = 2 We are SAMPLING at time 951 *** Looping through 5.2. Iter = 1044 iteration 1044; minNextMutationTime = 962; timeNextPopSample = 952; popParams.size() = 2 We are SAMPLING at time 952 *** Looping through 5.2. Iter = 1045 iteration 1045; minNextMutationTime = 952.302; timeNextPopSample = 953; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1046 iteration 1046; minNextMutationTime = 963; timeNextPopSample = 953; popParams.size() = 3 We are SAMPLING at time 953 *** Looping through 5.2. Iter = 1047 iteration 1047; minNextMutationTime = 964; timeNextPopSample = 954; popParams.size() = 3 We are SAMPLING at time 954 *** Looping through 5.2. Iter = 1048 iteration 1048; minNextMutationTime = 965; timeNextPopSample = 955; popParams.size() = 3 We are SAMPLING at time 955 *** Looping through 5.2. Iter = 1049 iteration 1049; minNextMutationTime = 966; timeNextPopSample = 956; popParams.size() = 3 We are SAMPLING at time 956 *** Looping through 5.2. Iter = 1050 iteration 1050; minNextMutationTime = 967; timeNextPopSample = 957; popParams.size() = 3 We are SAMPLING at time 957 *** Looping through 5.2. Iter = 1051 iteration 1051; minNextMutationTime = 968; timeNextPopSample = 958; popParams.size() = 2 We are SAMPLING at time 958 *** Looping through 5.2. Iter = 1052 iteration 1052; minNextMutationTime = 969; timeNextPopSample = 959; popParams.size() = 2 We are SAMPLING at time 959 *** Looping through 5.2. Iter = 1053 iteration 1053; minNextMutationTime = 970; timeNextPopSample = 960; popParams.size() = 2 We are SAMPLING at time 960 *** Looping through 5.2. Iter = 1054 iteration 1054; minNextMutationTime = 971; timeNextPopSample = 961; popParams.size() = 2 We are SAMPLING at time 961 *** Looping through 5.2. Iter = 1055 iteration 1055; minNextMutationTime = 972; timeNextPopSample = 962; popParams.size() = 2 We are SAMPLING at time 962 *** Looping through 5.2. Iter = 1056 iteration 1056; minNextMutationTime = 973; timeNextPopSample = 963; popParams.size() = 2 We are SAMPLING at time 963 *** Looping through 5.2. Iter = 1057 iteration 1057; minNextMutationTime = 974; timeNextPopSample = 964; popParams.size() = 2 We are SAMPLING at time 964 *** Looping through 5.2. Iter = 1058 iteration 1058; minNextMutationTime = 975; timeNextPopSample = 965; popParams.size() = 2 We are SAMPLING at time 965 *** Looping through 5.2. Iter = 1059 iteration 1059; minNextMutationTime = 976; timeNextPopSample = 966; popParams.size() = 2 We are SAMPLING at time 966 *** Looping through 5.2. Iter = 1060 iteration 1060; minNextMutationTime = 977; timeNextPopSample = 967; popParams.size() = 2 We are SAMPLING at time 967 *** Looping through 5.2. Iter = 1061 iteration 1061; minNextMutationTime = 978; timeNextPopSample = 968; popParams.size() = 2 We are SAMPLING at time 968 *** Looping through 5.2. Iter = 1062 iteration 1062; minNextMutationTime = 979; timeNextPopSample = 969; popParams.size() = 2 We are SAMPLING at time 969 *** Looping through 5.2. Iter = 1063 iteration 1063; minNextMutationTime = 980; timeNextPopSample = 970; popParams.size() = 2 We are SAMPLING at time 970 *** Looping through 5.2. Iter = 1064 iteration 1064; minNextMutationTime = 981; timeNextPopSample = 971; popParams.size() = 2 We are SAMPLING at time 971 *** Looping through 5.2. Iter = 1065 iteration 1065; minNextMutationTime = 982; timeNextPopSample = 972; popParams.size() = 2 We are SAMPLING at time 972 *** Looping through 5.2. Iter = 1066 iteration 1066; minNextMutationTime = 983; timeNextPopSample = 973; popParams.size() = 2 We are SAMPLING at time 973 *** Looping through 5.2. Iter = 1067 iteration 1067; minNextMutationTime = 984; timeNextPopSample = 974; popParams.size() = 2 We are SAMPLING at time 974 *** Looping through 5.2. Iter = 1068 iteration 1068; minNextMutationTime = 985; timeNextPopSample = 975; popParams.size() = 2 We are SAMPLING at time 975 *** Looping through 5.2. Iter = 1069 iteration 1069; minNextMutationTime = 975.024; timeNextPopSample = 976; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1070 iteration 1070; minNextMutationTime = 986; timeNextPopSample = 976; popParams.size() = 3 We are SAMPLING at time 976 *** Looping through 5.2. Iter = 1071 iteration 1071; minNextMutationTime = 987; timeNextPopSample = 977; popParams.size() = 2 We are SAMPLING at time 977 *** Looping through 5.2. Iter = 1072 iteration 1072; minNextMutationTime = 988; timeNextPopSample = 978; popParams.size() = 2 We are SAMPLING at time 978 *** Looping through 5.2. Iter = 1073 iteration 1073; minNextMutationTime = 989; timeNextPopSample = 979; popParams.size() = 2 We are SAMPLING at time 979 *** Looping through 5.2. Iter = 1074 iteration 1074; minNextMutationTime = 990; timeNextPopSample = 980; popParams.size() = 2 We are SAMPLING at time 980 *** Looping through 5.2. Iter = 1075 iteration 1075; minNextMutationTime = 991; timeNextPopSample = 981; popParams.size() = 2 We are SAMPLING at time 981 *** Looping through 5.2. Iter = 1076 iteration 1076; minNextMutationTime = 992; timeNextPopSample = 982; popParams.size() = 2 We are SAMPLING at time 982 *** Looping through 5.2. Iter = 1077 iteration 1077; minNextMutationTime = 993; timeNextPopSample = 983; popParams.size() = 2 We are SAMPLING at time 983 *** Looping through 5.2. Iter = 1078 iteration 1078; minNextMutationTime = 994; timeNextPopSample = 984; popParams.size() = 1 We are SAMPLING at time 984 *** Looping through 5.2. Iter = 1079 iteration 1079; minNextMutationTime = 984.996; timeNextPopSample = 985; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1080 iteration 1080; minNextMutationTime = 995; timeNextPopSample = 985; popParams.size() = 2 We are SAMPLING at time 985 *** Looping through 5.2. Iter = 1081 iteration 1081; minNextMutationTime = 996; timeNextPopSample = 986; popParams.size() = 2 We are SAMPLING at time 986 *** Looping through 5.2. Iter = 1082 iteration 1082; minNextMutationTime = 997; timeNextPopSample = 987; popParams.size() = 2 We are SAMPLING at time 987 *** Looping through 5.2. Iter = 1083 iteration 1083; minNextMutationTime = 998; timeNextPopSample = 988; popParams.size() = 2 We are SAMPLING at time 988 *** Looping through 5.2. Iter = 1084 iteration 1084; minNextMutationTime = 999; timeNextPopSample = 989; popParams.size() = 2 We are SAMPLING at time 989 *** Looping through 5.2. Iter = 1085 iteration 1085; minNextMutationTime = 1000; timeNextPopSample = 990; popParams.size() = 1 We are SAMPLING at time 990 *** Looping through 5.2. Iter = 1086 iteration 1086; minNextMutationTime = 1001; timeNextPopSample = 991; popParams.size() = 1 We are SAMPLING at time 991 *** Looping through 5.2. Iter = 1087 iteration 1087; minNextMutationTime = 1002; timeNextPopSample = 992; popParams.size() = 1 We are SAMPLING at time 992 *** Looping through 5.2. Iter = 1088 iteration 1088; minNextMutationTime = 1003; timeNextPopSample = 993; popParams.size() = 1 We are SAMPLING at time 993 *** Looping through 5.2. Iter = 1089 iteration 1089; minNextMutationTime = 1004; timeNextPopSample = 994; popParams.size() = 1 We are SAMPLING at time 994 *** Looping through 5.2. Iter = 1090 iteration 1090; minNextMutationTime = 1005; timeNextPopSample = 995; popParams.size() = 1 We are SAMPLING at time 995 *** Looping through 5.2. Iter = 1091 iteration 1091; minNextMutationTime = 1006; timeNextPopSample = 996; popParams.size() = 1 We are SAMPLING at time 996 *** Looping through 5.2. Iter = 1092 iteration 1092; minNextMutationTime = 1007; timeNextPopSample = 997; popParams.size() = 1 We are SAMPLING at time 997 *** Looping through 5.2. Iter = 1093 iteration 1093; minNextMutationTime = 1008; timeNextPopSample = 998; popParams.size() = 1 We are SAMPLING at time 998 *** Looping through 5.2. Iter = 1094 iteration 1094; minNextMutationTime = 1009; timeNextPopSample = 999; popParams.size() = 1 We are SAMPLING at time 999 *** Looping through 5.2. Iter = 1095 iteration 1095; minNextMutationTime = 1010; timeNextPopSample = 1000; popParams.size() = 1 We are SAMPLING at time 1000 *** Looping through 5.2. Iter = 1096 iteration 1096; minNextMutationTime = 1011; timeNextPopSample = 1001; popParams.size() = 1 We are SAMPLING at time 1001 *** Looping through 5.2. Iter = 1097 iteration 1097; minNextMutationTime = 1012; timeNextPopSample = 1002; popParams.size() = 1 We are SAMPLING at time 1002 *** Looping through 5.2. Iter = 1098 iteration 1098; minNextMutationTime = 1013; timeNextPopSample = 1003; popParams.size() = 1 We are SAMPLING at time 1003 *** Looping through 5.2. Iter = 1099 iteration 1099; minNextMutationTime = 1014; timeNextPopSample = 1004; popParams.size() = 1 We are SAMPLING at time 1004 *** Looping through 5.2. Iter = 1100 iteration 1100; minNextMutationTime = 1015; timeNextPopSample = 1005; popParams.size() = 1 We are SAMPLING at time 1005 *** Looping through 5.2. Iter = 1101 iteration 1101; minNextMutationTime = 1016; timeNextPopSample = 1006; popParams.size() = 1 We are SAMPLING at time 1006 *** Looping through 5.2. Iter = 1102 iteration 1102; minNextMutationTime = 1017; timeNextPopSample = 1007; popParams.size() = 1 We are SAMPLING at time 1007 *** Looping through 5.2. Iter = 1103 iteration 1103; minNextMutationTime = 1018; timeNextPopSample = 1008; popParams.size() = 1 We are SAMPLING at time 1008 *** Looping through 5.2. Iter = 1104 iteration 1104; minNextMutationTime = 1019; timeNextPopSample = 1009; popParams.size() = 1 We are SAMPLING at time 1009 *** Looping through 5.2. Iter = 1105 iteration 1105; minNextMutationTime = 1009.43; timeNextPopSample = 1010; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1106 iteration 1106; minNextMutationTime = 1020; timeNextPopSample = 1010; popParams.size() = 2 We are SAMPLING at time 1010 *** Looping through 5.2. Iter = 1107 iteration 1107; minNextMutationTime = 1021; timeNextPopSample = 1011; popParams.size() = 1 We are SAMPLING at time 1011 *** Looping through 5.2. Iter = 1108 iteration 1108; minNextMutationTime = 1022; timeNextPopSample = 1012; popParams.size() = 1 We are SAMPLING at time 1012 *** Looping through 5.2. Iter = 1109 iteration 1109; minNextMutationTime = 1023; timeNextPopSample = 1013; popParams.size() = 1 We are SAMPLING at time 1013 *** Looping through 5.2. Iter = 1110 iteration 1110; minNextMutationTime = 1024; timeNextPopSample = 1014; popParams.size() = 1 We are SAMPLING at time 1014 *** Looping through 5.2. Iter = 1111 iteration 1111; minNextMutationTime = 1025; timeNextPopSample = 1015; popParams.size() = 1 We are SAMPLING at time 1015 *** Looping through 5.2. Iter = 1112 iteration 1112; minNextMutationTime = 1015.35; timeNextPopSample = 1016; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1113 iteration 1113; minNextMutationTime = 1026; timeNextPopSample = 1016; popParams.size() = 2 We are SAMPLING at time 1016 *** Looping through 5.2. Iter = 1114 iteration 1114; minNextMutationTime = 1027; timeNextPopSample = 1017; popParams.size() = 2 We are SAMPLING at time 1017 *** Looping through 5.2. Iter = 1115 iteration 1115; minNextMutationTime = 1017.79; timeNextPopSample = 1018; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1116 iteration 1116; minNextMutationTime = 1028; timeNextPopSample = 1018; popParams.size() = 3 We are SAMPLING at time 1018 *** Looping through 5.2. Iter = 1117 iteration 1117; minNextMutationTime = 1029; timeNextPopSample = 1019; popParams.size() = 2 We are SAMPLING at time 1019 *** Looping through 5.2. Iter = 1118 iteration 1118; minNextMutationTime = 1030; timeNextPopSample = 1020; popParams.size() = 2 We are SAMPLING at time 1020 *** Looping through 5.2. Iter = 1119 iteration 1119; minNextMutationTime = 1031; timeNextPopSample = 1021; popParams.size() = 2 We are SAMPLING at time 1021 *** Looping through 5.2. Iter = 1120 iteration 1120; minNextMutationTime = 1032; timeNextPopSample = 1022; popParams.size() = 2 We are SAMPLING at time 1022 *** Looping through 5.2. Iter = 1121 iteration 1121; minNextMutationTime = 1033; timeNextPopSample = 1023; popParams.size() = 2 We are SAMPLING at time 1023 *** Looping through 5.2. Iter = 1122 iteration 1122; minNextMutationTime = 1034; timeNextPopSample = 1024; popParams.size() = 2 We are SAMPLING at time 1024 *** Looping through 5.2. Iter = 1123 iteration 1123; minNextMutationTime = 1024.79; timeNextPopSample = 1025; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1124 iteration 1124; minNextMutationTime = 1035; timeNextPopSample = 1025; popParams.size() = 3 We are SAMPLING at time 1025 *** Looping through 5.2. Iter = 1125 iteration 1125; minNextMutationTime = 1036; timeNextPopSample = 1026; popParams.size() = 3 We are SAMPLING at time 1026 *** Looping through 5.2. Iter = 1126 iteration 1126; minNextMutationTime = 1037; timeNextPopSample = 1027; popParams.size() = 3 We are SAMPLING at time 1027 *** Looping through 5.2. Iter = 1127 iteration 1127; minNextMutationTime = 1038; timeNextPopSample = 1028; popParams.size() = 2 We are SAMPLING at time 1028 *** Looping through 5.2. Iter = 1128 iteration 1128; minNextMutationTime = 1039; timeNextPopSample = 1029; popParams.size() = 2 We are SAMPLING at time 1029 *** Looping through 5.2. Iter = 1129 iteration 1129; minNextMutationTime = 1040; timeNextPopSample = 1030; popParams.size() = 2 We are SAMPLING at time 1030 *** Looping through 5.2. Iter = 1130 iteration 1130; minNextMutationTime = 1041; timeNextPopSample = 1031; popParams.size() = 2 We are SAMPLING at time 1031 *** Looping through 5.2. Iter = 1131 iteration 1131; minNextMutationTime = 1042; timeNextPopSample = 1032; popParams.size() = 2 We are SAMPLING at time 1032 *** Looping through 5.2. Iter = 1132 iteration 1132; minNextMutationTime = 1043; timeNextPopSample = 1033; popParams.size() = 2 We are SAMPLING at time 1033 *** Looping through 5.2. Iter = 1133 iteration 1133; minNextMutationTime = 1044; timeNextPopSample = 1034; popParams.size() = 2 We are SAMPLING at time 1034 *** Looping through 5.2. Iter = 1134 iteration 1134; minNextMutationTime = 1045; timeNextPopSample = 1035; popParams.size() = 2 We are SAMPLING at time 1035 *** Looping through 5.2. Iter = 1135 iteration 1135; minNextMutationTime = 1046; timeNextPopSample = 1036; popParams.size() = 2 We are SAMPLING at time 1036 *** Looping through 5.2. Iter = 1136 iteration 1136; minNextMutationTime = 1047; timeNextPopSample = 1037; popParams.size() = 1 We are SAMPLING at time 1037 *** Looping through 5.2. Iter = 1137 iteration 1137; minNextMutationTime = 1048; timeNextPopSample = 1038; popParams.size() = 1 We are SAMPLING at time 1038 *** Looping through 5.2. Iter = 1138 iteration 1138; minNextMutationTime = 1049; timeNextPopSample = 1039; popParams.size() = 1 We are SAMPLING at time 1039 *** Looping through 5.2. Iter = 1139 iteration 1139; minNextMutationTime = 1050; timeNextPopSample = 1040; popParams.size() = 1 We are SAMPLING at time 1040 *** Looping through 5.2. Iter = 1140 iteration 1140; minNextMutationTime = 1051; timeNextPopSample = 1041; popParams.size() = 1 We are SAMPLING at time 1041 *** Looping through 5.2. Iter = 1141 iteration 1141; minNextMutationTime = 1052; timeNextPopSample = 1042; popParams.size() = 1 We are SAMPLING at time 1042 *** Looping through 5.2. Iter = 1142 iteration 1142; minNextMutationTime = 1053; timeNextPopSample = 1043; popParams.size() = 1 We are SAMPLING at time 1043 *** Looping through 5.2. Iter = 1143 iteration 1143; minNextMutationTime = 1054; timeNextPopSample = 1044; popParams.size() = 1 We are SAMPLING at time 1044 *** Looping through 5.2. Iter = 1144 iteration 1144; minNextMutationTime = 1055; timeNextPopSample = 1045; popParams.size() = 1 We are SAMPLING at time 1045 *** Looping through 5.2. Iter = 1145 iteration 1145; minNextMutationTime = 1056; timeNextPopSample = 1046; popParams.size() = 1 We are SAMPLING at time 1046 *** Looping through 5.2. Iter = 1146 iteration 1146; minNextMutationTime = 1057; timeNextPopSample = 1047; popParams.size() = 1 We are SAMPLING at time 1047 *** Looping through 5.2. Iter = 1147 iteration 1147; minNextMutationTime = 1058; timeNextPopSample = 1048; popParams.size() = 1 We are SAMPLING at time 1048 *** Looping through 5.2. Iter = 1148 iteration 1148; minNextMutationTime = 1059; timeNextPopSample = 1049; popParams.size() = 1 We are SAMPLING at time 1049 *** Looping through 5.2. Iter = 1149 iteration 1149; minNextMutationTime = 1060; timeNextPopSample = 1050; popParams.size() = 1 We are SAMPLING at time 1050 *** Looping through 5.2. Iter = 1150 iteration 1150; minNextMutationTime = 1061; timeNextPopSample = 1051; popParams.size() = 1 We are SAMPLING at time 1051 *** Looping through 5.2. Iter = 1151 iteration 1151; minNextMutationTime = 1062; timeNextPopSample = 1052; popParams.size() = 1 We are SAMPLING at time 1052 *** Looping through 5.2. Iter = 1152 iteration 1152; minNextMutationTime = 1063; timeNextPopSample = 1053; popParams.size() = 1 We are SAMPLING at time 1053 *** Looping through 5.2. Iter = 1153 iteration 1153; minNextMutationTime = 1064; timeNextPopSample = 1054; popParams.size() = 1 We are SAMPLING at time 1054 *** Looping through 5.2. Iter = 1154 iteration 1154; minNextMutationTime = 1065; timeNextPopSample = 1055; popParams.size() = 1 We are SAMPLING at time 1055 *** Looping through 5.2. Iter = 1155 iteration 1155; minNextMutationTime = 1066; timeNextPopSample = 1056; popParams.size() = 1 We are SAMPLING at time 1056 *** Looping through 5.2. Iter = 1156 iteration 1156; minNextMutationTime = 1067; timeNextPopSample = 1057; popParams.size() = 1 We are SAMPLING at time 1057 *** Looping through 5.2. Iter = 1157 iteration 1157; minNextMutationTime = 1068; timeNextPopSample = 1058; popParams.size() = 1 We are SAMPLING at time 1058 *** Looping through 5.2. Iter = 1158 iteration 1158; minNextMutationTime = 1069; timeNextPopSample = 1059; popParams.size() = 1 We are SAMPLING at time 1059 *** Looping through 5.2. Iter = 1159 iteration 1159; minNextMutationTime = 1070; timeNextPopSample = 1060; popParams.size() = 1 We are SAMPLING at time 1060 *** Looping through 5.2. Iter = 1160 iteration 1160; minNextMutationTime = 1060.67; timeNextPopSample = 1061; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1161 iteration 1161; minNextMutationTime = 1071; timeNextPopSample = 1061; popParams.size() = 2 We are SAMPLING at time 1061 *** Looping through 5.2. Iter = 1162 iteration 1162; minNextMutationTime = 1072; timeNextPopSample = 1062; popParams.size() = 2 We are SAMPLING at time 1062 *** Looping through 5.2. Iter = 1163 iteration 1163; minNextMutationTime = 1073; timeNextPopSample = 1063; popParams.size() = 2 We are SAMPLING at time 1063 *** Looping through 5.2. Iter = 1164 iteration 1164; minNextMutationTime = 1074; timeNextPopSample = 1064; popParams.size() = 1 We are SAMPLING at time 1064 *** Looping through 5.2. Iter = 1165 iteration 1165; minNextMutationTime = 1075; timeNextPopSample = 1065; popParams.size() = 1 We are SAMPLING at time 1065 *** Looping through 5.2. Iter = 1166 iteration 1166; minNextMutationTime = 1076; timeNextPopSample = 1066; popParams.size() = 1 We are SAMPLING at time 1066 *** Looping through 5.2. Iter = 1167 iteration 1167; minNextMutationTime = 1066.55; timeNextPopSample = 1067; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1168 iteration 1168; minNextMutationTime = 1077; timeNextPopSample = 1067; popParams.size() = 2 We are SAMPLING at time 1067 *** Looping through 5.2. Iter = 1169 iteration 1169; minNextMutationTime = 1078; timeNextPopSample = 1068; popParams.size() = 2 We are SAMPLING at time 1068 *** Looping through 5.2. Iter = 1170 iteration 1170; minNextMutationTime = 1079; timeNextPopSample = 1069; popParams.size() = 1 We are SAMPLING at time 1069 *** Looping through 5.2. Iter = 1171 iteration 1171; minNextMutationTime = 1080; timeNextPopSample = 1070; popParams.size() = 1 We are SAMPLING at time 1070 *** Looping through 5.2. Iter = 1172 iteration 1172; minNextMutationTime = 1081; timeNextPopSample = 1071; popParams.size() = 1 We are SAMPLING at time 1071 *** Looping through 5.2. Iter = 1173 iteration 1173; minNextMutationTime = 1082; timeNextPopSample = 1072; popParams.size() = 1 We are SAMPLING at time 1072 *** Looping through 5.2. Iter = 1174 iteration 1174; minNextMutationTime = 1083; timeNextPopSample = 1073; popParams.size() = 1 We are SAMPLING at time 1073 *** Looping through 5.2. Iter = 1175 iteration 1175; minNextMutationTime = 1084; timeNextPopSample = 1074; popParams.size() = 1 We are SAMPLING at time 1074 *** Looping through 5.2. Iter = 1176 iteration 1176; minNextMutationTime = 1085; timeNextPopSample = 1075; popParams.size() = 1 We are SAMPLING at time 1075 *** Looping through 5.2. Iter = 1177 iteration 1177; minNextMutationTime = 1086; timeNextPopSample = 1076; popParams.size() = 1 We are SAMPLING at time 1076 *** Looping through 5.2. Iter = 1178 iteration 1178; minNextMutationTime = 1087; timeNextPopSample = 1077; popParams.size() = 1 We are SAMPLING at time 1077 *** Looping through 5.2. Iter = 1179 iteration 1179; minNextMutationTime = 1088; timeNextPopSample = 1078; popParams.size() = 1 We are SAMPLING at time 1078 *** Looping through 5.2. Iter = 1180 iteration 1180; minNextMutationTime = 1089; timeNextPopSample = 1079; popParams.size() = 1 We are SAMPLING at time 1079 *** Looping through 5.2. Iter = 1181 iteration 1181; minNextMutationTime = 1090; timeNextPopSample = 1080; popParams.size() = 1 We are SAMPLING at time 1080 *** Looping through 5.2. Iter = 1182 iteration 1182; minNextMutationTime = 1091; timeNextPopSample = 1081; popParams.size() = 1 We are SAMPLING at time 1081 *** Looping through 5.2. Iter = 1183 iteration 1183; minNextMutationTime = 1092; timeNextPopSample = 1082; popParams.size() = 1 We are SAMPLING at time 1082 *** Looping through 5.2. Iter = 1184 iteration 1184; minNextMutationTime = 1093; timeNextPopSample = 1083; popParams.size() = 1 We are SAMPLING at time 1083 *** Looping through 5.2. Iter = 1185 iteration 1185; minNextMutationTime = 1094; timeNextPopSample = 1084; popParams.size() = 1 We are SAMPLING at time 1084 *** Looping through 5.2. Iter = 1186 iteration 1186; minNextMutationTime = 1095; timeNextPopSample = 1085; popParams.size() = 1 We are SAMPLING at time 1085 *** Looping through 5.2. Iter = 1187 iteration 1187; minNextMutationTime = 1096; timeNextPopSample = 1086; popParams.size() = 1 We are SAMPLING at time 1086 *** Looping through 5.2. Iter = 1188 iteration 1188; minNextMutationTime = 1086.48; timeNextPopSample = 1087; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1189 iteration 1189; minNextMutationTime = 1097; timeNextPopSample = 1087; popParams.size() = 2 We are SAMPLING at time 1087 *** Looping through 5.2. Iter = 1190 iteration 1190; minNextMutationTime = 1098; timeNextPopSample = 1088; popParams.size() = 1 We are SAMPLING at time 1088 *** Looping through 5.2. Iter = 1191 iteration 1191; minNextMutationTime = 1099; timeNextPopSample = 1089; popParams.size() = 1 We are SAMPLING at time 1089 *** Looping through 5.2. Iter = 1192 iteration 1192; minNextMutationTime = 1100; timeNextPopSample = 1090; popParams.size() = 1 We are SAMPLING at time 1090 *** Looping through 5.2. Iter = 1193 iteration 1193; minNextMutationTime = 1101; timeNextPopSample = 1091; popParams.size() = 1 We are SAMPLING at time 1091 *** Looping through 5.2. Iter = 1194 iteration 1194; minNextMutationTime = 1102; timeNextPopSample = 1092; popParams.size() = 1 We are SAMPLING at time 1092 *** Looping through 5.2. Iter = 1195 iteration 1195; minNextMutationTime = 1103; timeNextPopSample = 1093; popParams.size() = 1 We are SAMPLING at time 1093 *** Looping through 5.2. Iter = 1196 iteration 1196; minNextMutationTime = 1104; timeNextPopSample = 1094; popParams.size() = 1 We are SAMPLING at time 1094 *** Looping through 5.2. Iter = 1197 iteration 1197; minNextMutationTime = 1105; timeNextPopSample = 1095; popParams.size() = 1 We are SAMPLING at time 1095 *** Looping through 5.2. Iter = 1198 iteration 1198; minNextMutationTime = 1106; timeNextPopSample = 1096; popParams.size() = 1 We are SAMPLING at time 1096 *** Looping through 5.2. Iter = 1199 iteration 1199; minNextMutationTime = 1107; timeNextPopSample = 1097; popParams.size() = 1 We are SAMPLING at time 1097 *** Looping through 5.2. Iter = 1200 iteration 1200; minNextMutationTime = 1108; timeNextPopSample = 1098; popParams.size() = 1 We are SAMPLING at time 1098 *** Looping through 5.2. Iter = 1201 iteration 1201; minNextMutationTime = 1109; timeNextPopSample = 1099; popParams.size() = 1 We are SAMPLING at time 1099 *** Looping through 5.2. Iter = 1202 iteration 1202; minNextMutationTime = 1099.68; timeNextPopSample = 1100; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1203 iteration 1203; minNextMutationTime = 1110; timeNextPopSample = 1100; popParams.size() = 2 We are SAMPLING at time 1100 *** Looping through 5.2. Iter = 1204 iteration 1204; minNextMutationTime = 1111; timeNextPopSample = 1101; popParams.size() = 2 We are SAMPLING at time 1101 *** Looping through 5.2. Iter = 1205 iteration 1205; minNextMutationTime = 1112; timeNextPopSample = 1102; popParams.size() = 2 We are SAMPLING at time 1102 *** Looping through 5.2. Iter = 1206 iteration 1206; minNextMutationTime = 1113; timeNextPopSample = 1103; popParams.size() = 2 We are SAMPLING at time 1103 *** Looping through 5.2. Iter = 1207 iteration 1207; minNextMutationTime = 1114; timeNextPopSample = 1104; popParams.size() = 2 We are SAMPLING at time 1104 *** Looping through 5.2. Iter = 1208 iteration 1208; minNextMutationTime = 1115; timeNextPopSample = 1105; popParams.size() = 2 We are SAMPLING at time 1105 *** Looping through 5.2. Iter = 1209 iteration 1209; minNextMutationTime = 1116; timeNextPopSample = 1106; popParams.size() = 1 We are SAMPLING at time 1106 *** Looping through 5.2. Iter = 1210 iteration 1210; minNextMutationTime = 1117; timeNextPopSample = 1107; popParams.size() = 1 We are SAMPLING at time 1107 *** Looping through 5.2. Iter = 1211 iteration 1211; minNextMutationTime = 1118; timeNextPopSample = 1108; popParams.size() = 1 We are SAMPLING at time 1108 *** Looping through 5.2. Iter = 1212 iteration 1212; minNextMutationTime = 1119; timeNextPopSample = 1109; popParams.size() = 1 We are SAMPLING at time 1109 *** Looping through 5.2. Iter = 1213 iteration 1213; minNextMutationTime = 1120; timeNextPopSample = 1110; popParams.size() = 1 We are SAMPLING at time 1110 *** Looping through 5.2. Iter = 1214 iteration 1214; minNextMutationTime = 1121; timeNextPopSample = 1111; popParams.size() = 1 We are SAMPLING at time 1111 *** Looping through 5.2. Iter = 1215 iteration 1215; minNextMutationTime = 1122; timeNextPopSample = 1112; popParams.size() = 1 We are SAMPLING at time 1112 *** Looping through 5.2. Iter = 1216 iteration 1216; minNextMutationTime = 1123; timeNextPopSample = 1113; popParams.size() = 1 We are SAMPLING at time 1113 *** Looping through 5.2. Iter = 1217 iteration 1217; minNextMutationTime = 1124; timeNextPopSample = 1114; popParams.size() = 1 We are SAMPLING at time 1114 *** Looping through 5.2. Iter = 1218 iteration 1218; minNextMutationTime = 1125; timeNextPopSample = 1115; popParams.size() = 1 We are SAMPLING at time 1115 *** Looping through 5.2. Iter = 1219 iteration 1219; minNextMutationTime = 1126; timeNextPopSample = 1116; popParams.size() = 1 We are SAMPLING at time 1116 *** Looping through 5.2. Iter = 1220 iteration 1220; minNextMutationTime = 1127; timeNextPopSample = 1117; popParams.size() = 1 We are SAMPLING at time 1117 *** Looping through 5.2. Iter = 1221 iteration 1221; minNextMutationTime = 1117.16; timeNextPopSample = 1118; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1222 iteration 1222; minNextMutationTime = 1128; timeNextPopSample = 1118; popParams.size() = 2 We are SAMPLING at time 1118 *** Looping through 5.2. Iter = 1223 iteration 1223; minNextMutationTime = 1129; timeNextPopSample = 1119; popParams.size() = 1 We are SAMPLING at time 1119 *** Looping through 5.2. Iter = 1224 iteration 1224; minNextMutationTime = 1130; timeNextPopSample = 1120; popParams.size() = 1 We are SAMPLING at time 1120 *** Looping through 5.2. Iter = 1225 iteration 1225; minNextMutationTime = 1120.57; timeNextPopSample = 1121; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1226 iteration 1226; minNextMutationTime = 1131; timeNextPopSample = 1121; popParams.size() = 2 We are SAMPLING at time 1121 *** Looping through 5.2. Iter = 1227 iteration 1227; minNextMutationTime = 1132; timeNextPopSample = 1122; popParams.size() = 1 We are SAMPLING at time 1122 *** Looping through 5.2. Iter = 1228 iteration 1228; minNextMutationTime = 1133; timeNextPopSample = 1123; popParams.size() = 1 We are SAMPLING at time 1123 *** Looping through 5.2. Iter = 1229 iteration 1229; minNextMutationTime = 1134; timeNextPopSample = 1124; popParams.size() = 1 We are SAMPLING at time 1124 *** Looping through 5.2. Iter = 1230 iteration 1230; minNextMutationTime = 1135; timeNextPopSample = 1125; popParams.size() = 1 We are SAMPLING at time 1125 *** Looping through 5.2. Iter = 1231 iteration 1231; minNextMutationTime = 1136; timeNextPopSample = 1126; popParams.size() = 1 We are SAMPLING at time 1126 *** Looping through 5.2. Iter = 1232 iteration 1232; minNextMutationTime = 1137; timeNextPopSample = 1127; popParams.size() = 1 We are SAMPLING at time 1127 *** Looping through 5.2. Iter = 1233 iteration 1233; minNextMutationTime = 1138; timeNextPopSample = 1128; popParams.size() = 1 We are SAMPLING at time 1128 *** Looping through 5.2. Iter = 1234 iteration 1234; minNextMutationTime = 1128.24; timeNextPopSample = 1129; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1235 iteration 1235; minNextMutationTime = 1128.5; timeNextPopSample = 1129; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 1) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 1) New popSize = 2 *** Looping through 5.2. Iter = 1236 iteration 1236; minNextMutationTime = 1128.73; timeNextPopSample = 1129; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 1) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 1) New popSize = 3 *** Looping through 5.2. Iter = 1237 iteration 1237; minNextMutationTime = 1139; timeNextPopSample = 1129; popParams.size() = 2 We are SAMPLING at time 1129 *** Looping through 5.2. Iter = 1238 iteration 1238; minNextMutationTime = 1140; timeNextPopSample = 1130; popParams.size() = 1 We are SAMPLING at time 1130 *** Looping through 5.2. Iter = 1239 iteration 1239; minNextMutationTime = 1141; timeNextPopSample = 1131; popParams.size() = 1 We are SAMPLING at time 1131 *** Looping through 5.2. Iter = 1240 iteration 1240; minNextMutationTime = 1142; timeNextPopSample = 1132; popParams.size() = 1 We are SAMPLING at time 1132 *** Looping through 5.2. Iter = 1241 iteration 1241; minNextMutationTime = 1143; timeNextPopSample = 1133; popParams.size() = 1 We are SAMPLING at time 1133 *** Looping through 5.2. Iter = 1242 iteration 1242; minNextMutationTime = 1144; timeNextPopSample = 1134; popParams.size() = 1 We are SAMPLING at time 1134 *** Looping through 5.2. Iter = 1243 iteration 1243; minNextMutationTime = 1145; timeNextPopSample = 1135; popParams.size() = 1 We are SAMPLING at time 1135 *** Looping through 5.2. Iter = 1244 iteration 1244; minNextMutationTime = 1146; timeNextPopSample = 1136; popParams.size() = 1 We are SAMPLING at time 1136 *** Looping through 5.2. Iter = 1245 iteration 1245; minNextMutationTime = 1147; timeNextPopSample = 1137; popParams.size() = 1 We are SAMPLING at time 1137 *** Looping through 5.2. Iter = 1246 iteration 1246; minNextMutationTime = 1148; timeNextPopSample = 1138; popParams.size() = 1 We are SAMPLING at time 1138 *** Looping through 5.2. Iter = 1247 iteration 1247; minNextMutationTime = 1149; timeNextPopSample = 1139; popParams.size() = 1 We are SAMPLING at time 1139 *** Looping through 5.2. Iter = 1248 iteration 1248; minNextMutationTime = 1150; timeNextPopSample = 1140; popParams.size() = 1 We are SAMPLING at time 1140 *** Looping through 5.2. Iter = 1249 iteration 1249; minNextMutationTime = 1151; timeNextPopSample = 1141; popParams.size() = 1 We are SAMPLING at time 1141 *** Looping through 5.2. Iter = 1250 iteration 1250; minNextMutationTime = 1152; timeNextPopSample = 1142; popParams.size() = 1 We are SAMPLING at time 1142 *** Looping through 5.2. Iter = 1251 iteration 1251; minNextMutationTime = 1153; timeNextPopSample = 1143; popParams.size() = 1 We are SAMPLING at time 1143 *** Looping through 5.2. Iter = 1252 iteration 1252; minNextMutationTime = 1154; timeNextPopSample = 1144; popParams.size() = 1 We are SAMPLING at time 1144 *** Looping through 5.2. Iter = 1253 iteration 1253; minNextMutationTime = 1155; timeNextPopSample = 1145; popParams.size() = 1 We are SAMPLING at time 1145 *** Looping through 5.2. Iter = 1254 iteration 1254; minNextMutationTime = 1156; timeNextPopSample = 1146; popParams.size() = 1 We are SAMPLING at time 1146 *** Looping through 5.2. Iter = 1255 iteration 1255; minNextMutationTime = 1157; timeNextPopSample = 1147; popParams.size() = 1 We are SAMPLING at time 1147 *** Looping through 5.2. Iter = 1256 iteration 1256; minNextMutationTime = 1158; timeNextPopSample = 1148; popParams.size() = 1 We are SAMPLING at time 1148 *** Looping through 5.2. Iter = 1257 iteration 1257; minNextMutationTime = 1159; timeNextPopSample = 1149; popParams.size() = 1 We are SAMPLING at time 1149 *** Looping through 5.2. Iter = 1258 iteration 1258; minNextMutationTime = 1160; timeNextPopSample = 1150; popParams.size() = 1 We are SAMPLING at time 1150 *** Looping through 5.2. Iter = 1259 iteration 1259; minNextMutationTime = 1161; timeNextPopSample = 1151; popParams.size() = 1 We are SAMPLING at time 1151 *** Looping through 5.2. Iter = 1260 iteration 1260; minNextMutationTime = 1162; timeNextPopSample = 1152; popParams.size() = 1 We are SAMPLING at time 1152 *** Looping through 5.2. Iter = 1261 iteration 1261; minNextMutationTime = 1152.22; timeNextPopSample = 1153; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1262 iteration 1262; minNextMutationTime = 1163; timeNextPopSample = 1153; popParams.size() = 2 We are SAMPLING at time 1153 *** Looping through 5.2. Iter = 1263 iteration 1263; minNextMutationTime = 1164; timeNextPopSample = 1154; popParams.size() = 2 We are SAMPLING at time 1154 *** Looping through 5.2. Iter = 1264 iteration 1264; minNextMutationTime = 1165; timeNextPopSample = 1155; popParams.size() = 1 We are SAMPLING at time 1155 *** Looping through 5.2. Iter = 1265 iteration 1265; minNextMutationTime = 1166; timeNextPopSample = 1156; popParams.size() = 1 We are SAMPLING at time 1156 *** Looping through 5.2. Iter = 1266 iteration 1266; minNextMutationTime = 1167; timeNextPopSample = 1157; popParams.size() = 1 We are SAMPLING at time 1157 *** Looping through 5.2. Iter = 1267 iteration 1267; minNextMutationTime = 1168; timeNextPopSample = 1158; popParams.size() = 1 We are SAMPLING at time 1158 *** Looping through 5.2. Iter = 1268 iteration 1268; minNextMutationTime = 1169; timeNextPopSample = 1159; popParams.size() = 1 We are SAMPLING at time 1159 *** Looping through 5.2. Iter = 1269 iteration 1269; minNextMutationTime = 1170; timeNextPopSample = 1160; popParams.size() = 1 We are SAMPLING at time 1160 *** Looping through 5.2. Iter = 1270 iteration 1270; minNextMutationTime = 1160.18; timeNextPopSample = 1161; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1271 iteration 1271; minNextMutationTime = 1171; timeNextPopSample = 1161; popParams.size() = 2 We are SAMPLING at time 1161 *** Looping through 5.2. Iter = 1272 iteration 1272; minNextMutationTime = 1172; timeNextPopSample = 1162; popParams.size() = 1 We are SAMPLING at time 1162 *** Looping through 5.2. Iter = 1273 iteration 1273; minNextMutationTime = 1173; timeNextPopSample = 1163; popParams.size() = 1 We are SAMPLING at time 1163 *** Looping through 5.2. Iter = 1274 iteration 1274; minNextMutationTime = 1174; timeNextPopSample = 1164; popParams.size() = 1 We are SAMPLING at time 1164 *** Looping through 5.2. Iter = 1275 iteration 1275; minNextMutationTime = 1175; timeNextPopSample = 1165; popParams.size() = 1 We are SAMPLING at time 1165 *** Looping through 5.2. Iter = 1276 iteration 1276; minNextMutationTime = 1176; timeNextPopSample = 1166; popParams.size() = 1 We are SAMPLING at time 1166 *** Looping through 5.2. Iter = 1277 iteration 1277; minNextMutationTime = 1177; timeNextPopSample = 1167; popParams.size() = 1 We are SAMPLING at time 1167 *** Looping through 5.2. Iter = 1278 iteration 1278; minNextMutationTime = 1178; timeNextPopSample = 1168; popParams.size() = 1 We are SAMPLING at time 1168 *** Looping through 5.2. Iter = 1279 iteration 1279; minNextMutationTime = 1179; timeNextPopSample = 1169; popParams.size() = 1 We are SAMPLING at time 1169 *** Looping through 5.2. Iter = 1280 iteration 1280; minNextMutationTime = 1180; timeNextPopSample = 1170; popParams.size() = 1 We are SAMPLING at time 1170 *** Looping through 5.2. Iter = 1281 iteration 1281; minNextMutationTime = 1181; timeNextPopSample = 1171; popParams.size() = 1 We are SAMPLING at time 1171 *** Looping through 5.2. Iter = 1282 iteration 1282; minNextMutationTime = 1182; timeNextPopSample = 1172; popParams.size() = 1 We are SAMPLING at time 1172 *** Looping through 5.2. Iter = 1283 iteration 1283; minNextMutationTime = 1183; timeNextPopSample = 1173; popParams.size() = 1 We are SAMPLING at time 1173 *** Looping through 5.2. Iter = 1284 iteration 1284; minNextMutationTime = 1184; timeNextPopSample = 1174; popParams.size() = 1 We are SAMPLING at time 1174 *** Looping through 5.2. Iter = 1285 iteration 1285; minNextMutationTime = 1185; timeNextPopSample = 1175; popParams.size() = 1 We are SAMPLING at time 1175 *** Looping through 5.2. Iter = 1286 iteration 1286; minNextMutationTime = 1186; timeNextPopSample = 1176; popParams.size() = 1 We are SAMPLING at time 1176 *** Looping through 5.2. Iter = 1287 iteration 1287; minNextMutationTime = 1187; timeNextPopSample = 1177; popParams.size() = 1 We are SAMPLING at time 1177 *** Looping through 5.2. Iter = 1288 iteration 1288; minNextMutationTime = 1188; timeNextPopSample = 1178; popParams.size() = 1 We are SAMPLING at time 1178 *** Looping through 5.2. Iter = 1289 iteration 1289; minNextMutationTime = 1178.26; timeNextPopSample = 1179; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1290 iteration 1290; minNextMutationTime = 1189; timeNextPopSample = 1179; popParams.size() = 2 We are SAMPLING at time 1179 *** Looping through 5.2. Iter = 1291 iteration 1291; minNextMutationTime = 1190; timeNextPopSample = 1180; popParams.size() = 1 We are SAMPLING at time 1180 *** Looping through 5.2. Iter = 1292 iteration 1292; minNextMutationTime = 1191; timeNextPopSample = 1181; popParams.size() = 1 We are SAMPLING at time 1181 *** Looping through 5.2. Iter = 1293 iteration 1293; minNextMutationTime = 1192; timeNextPopSample = 1182; popParams.size() = 1 We are SAMPLING at time 1182 *** Looping through 5.2. Iter = 1294 iteration 1294; minNextMutationTime = 1193; timeNextPopSample = 1183; popParams.size() = 1 We are SAMPLING at time 1183 *** Looping through 5.2. Iter = 1295 iteration 1295; minNextMutationTime = 1194; timeNextPopSample = 1184; popParams.size() = 1 We are SAMPLING at time 1184 *** Looping through 5.2. Iter = 1296 iteration 1296; minNextMutationTime = 1195; timeNextPopSample = 1185; popParams.size() = 1 We are SAMPLING at time 1185 *** Looping through 5.2. Iter = 1297 iteration 1297; minNextMutationTime = 1196; timeNextPopSample = 1186; popParams.size() = 1 We are SAMPLING at time 1186 *** Looping through 5.2. Iter = 1298 iteration 1298; minNextMutationTime = 1197; timeNextPopSample = 1187; popParams.size() = 1 We are SAMPLING at time 1187 *** Looping through 5.2. Iter = 1299 iteration 1299; minNextMutationTime = 1198; timeNextPopSample = 1188; popParams.size() = 1 We are SAMPLING at time 1188 *** Looping through 5.2. Iter = 1300 iteration 1300; minNextMutationTime = 1199; timeNextPopSample = 1189; popParams.size() = 1 We are SAMPLING at time 1189 *** Looping through 5.2. Iter = 1301 iteration 1301; minNextMutationTime = 1189.53; timeNextPopSample = 1190; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1302 iteration 1302; minNextMutationTime = 1200; timeNextPopSample = 1190; popParams.size() = 2 We are SAMPLING at time 1190 *** Looping through 5.2. Iter = 1303 iteration 1303; minNextMutationTime = 1201; timeNextPopSample = 1191; popParams.size() = 2 We are SAMPLING at time 1191 *** Looping through 5.2. Iter = 1304 iteration 1304; minNextMutationTime = 1202; timeNextPopSample = 1192; popParams.size() = 1 We are SAMPLING at time 1192 *** Looping through 5.2. Iter = 1305 iteration 1305; minNextMutationTime = 1203; timeNextPopSample = 1193; popParams.size() = 1 We are SAMPLING at time 1193 *** Looping through 5.2. Iter = 1306 iteration 1306; minNextMutationTime = 1204; timeNextPopSample = 1194; popParams.size() = 1 We are SAMPLING at time 1194 *** Looping through 5.2. Iter = 1307 iteration 1307; minNextMutationTime = 1205; timeNextPopSample = 1195; popParams.size() = 1 We are SAMPLING at time 1195 *** Looping through 5.2. Iter = 1308 iteration 1308; minNextMutationTime = 1206; timeNextPopSample = 1196; popParams.size() = 1 We are SAMPLING at time 1196 *** Looping through 5.2. Iter = 1309 iteration 1309; minNextMutationTime = 1196.32; timeNextPopSample = 1197; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1310 iteration 1310; minNextMutationTime = 1207; timeNextPopSample = 1197; popParams.size() = 2 We are SAMPLING at time 1197 *** Looping through 5.2. Iter = 1311 iteration 1311; minNextMutationTime = 1197.63; timeNextPopSample = 1198; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1312 iteration 1312; minNextMutationTime = 1208; timeNextPopSample = 1198; popParams.size() = 3 We are SAMPLING at time 1198 *** Looping through 5.2. Iter = 1313 iteration 1313; minNextMutationTime = 1209; timeNextPopSample = 1199; popParams.size() = 2 We are SAMPLING at time 1199 *** Looping through 5.2. Iter = 1314 iteration 1314; minNextMutationTime = 1210; timeNextPopSample = 1200; popParams.size() = 1 We are SAMPLING at time 1200 *** Looping through 5.2. Iter = 1315 iteration 1315; minNextMutationTime = 1211; timeNextPopSample = 1201; popParams.size() = 1 We are SAMPLING at time 1201 *** Looping through 5.2. Iter = 1316 iteration 1316; minNextMutationTime = 1212; timeNextPopSample = 1202; popParams.size() = 1 We are SAMPLING at time 1202 *** Looping through 5.2. Iter = 1317 iteration 1317; minNextMutationTime = 1213; timeNextPopSample = 1203; popParams.size() = 1 We are SAMPLING at time 1203 *** Looping through 5.2. Iter = 1318 iteration 1318; minNextMutationTime = 1214; timeNextPopSample = 1204; popParams.size() = 1 We are SAMPLING at time 1204 *** Looping through 5.2. Iter = 1319 iteration 1319; minNextMutationTime = 1215; timeNextPopSample = 1205; popParams.size() = 1 We are SAMPLING at time 1205 *** Looping through 5.2. Iter = 1320 iteration 1320; minNextMutationTime = 1205.91; timeNextPopSample = 1206; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1321 iteration 1321; minNextMutationTime = 1216; timeNextPopSample = 1206; popParams.size() = 2 We are SAMPLING at time 1206 *** Looping through 5.2. Iter = 1322 iteration 1322; minNextMutationTime = 1217; timeNextPopSample = 1207; popParams.size() = 2 We are SAMPLING at time 1207 *** Looping through 5.2. Iter = 1323 iteration 1323; minNextMutationTime = 1218; timeNextPopSample = 1208; popParams.size() = 1 We are SAMPLING at time 1208 *** Looping through 5.2. Iter = 1324 iteration 1324; minNextMutationTime = 1219; timeNextPopSample = 1209; popParams.size() = 1 We are SAMPLING at time 1209 *** Looping through 5.2. Iter = 1325 iteration 1325; minNextMutationTime = 1220; timeNextPopSample = 1210; popParams.size() = 1 We are SAMPLING at time 1210 *** Looping through 5.2. Iter = 1326 iteration 1326; minNextMutationTime = 1221; timeNextPopSample = 1211; popParams.size() = 1 We are SAMPLING at time 1211 *** Looping through 5.2. Iter = 1327 iteration 1327; minNextMutationTime = 1222; timeNextPopSample = 1212; popParams.size() = 1 We are SAMPLING at time 1212 *** Looping through 5.2. Iter = 1328 iteration 1328; minNextMutationTime = 1223; timeNextPopSample = 1213; popParams.size() = 1 We are SAMPLING at time 1213 *** Looping through 5.2. Iter = 1329 iteration 1329; minNextMutationTime = 1224; timeNextPopSample = 1214; popParams.size() = 1 We are SAMPLING at time 1214 *** Looping through 5.2. Iter = 1330 iteration 1330; minNextMutationTime = 1225; timeNextPopSample = 1215; popParams.size() = 1 We are SAMPLING at time 1215 *** Looping through 5.2. Iter = 1331 iteration 1331; minNextMutationTime = 1226; timeNextPopSample = 1216; popParams.size() = 1 We are SAMPLING at time 1216 *** Looping through 5.2. Iter = 1332 iteration 1332; minNextMutationTime = 1216.8; timeNextPopSample = 1217; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1333 iteration 1333; minNextMutationTime = 1227; timeNextPopSample = 1217; popParams.size() = 2 We are SAMPLING at time 1217 *** Looping through 5.2. Iter = 1334 iteration 1334; minNextMutationTime = 1228; timeNextPopSample = 1218; popParams.size() = 2 We are SAMPLING at time 1218 *** Looping through 5.2. Iter = 1335 iteration 1335; minNextMutationTime = 1229; timeNextPopSample = 1219; popParams.size() = 2 We are SAMPLING at time 1219 *** Looping through 5.2. Iter = 1336 iteration 1336; minNextMutationTime = 1230; timeNextPopSample = 1220; popParams.size() = 2 We are SAMPLING at time 1220 *** Looping through 5.2. Iter = 1337 iteration 1337; minNextMutationTime = 1231; timeNextPopSample = 1221; popParams.size() = 1 We are SAMPLING at time 1221 *** Looping through 5.2. Iter = 1338 iteration 1338; minNextMutationTime = 1232; timeNextPopSample = 1222; popParams.size() = 1 We are SAMPLING at time 1222 *** Looping through 5.2. Iter = 1339 iteration 1339; minNextMutationTime = 1233; timeNextPopSample = 1223; popParams.size() = 1 We are SAMPLING at time 1223 *** Looping through 5.2. Iter = 1340 iteration 1340; minNextMutationTime = 1234; timeNextPopSample = 1224; popParams.size() = 1 We are SAMPLING at time 1224 *** Looping through 5.2. Iter = 1341 iteration 1341; minNextMutationTime = 1235; timeNextPopSample = 1225; popParams.size() = 1 We are SAMPLING at time 1225 *** Looping through 5.2. Iter = 1342 iteration 1342; minNextMutationTime = 1236; timeNextPopSample = 1226; popParams.size() = 1 We are SAMPLING at time 1226 *** Looping through 5.2. Iter = 1343 iteration 1343; minNextMutationTime = 1237; timeNextPopSample = 1227; popParams.size() = 1 We are SAMPLING at time 1227 *** Looping through 5.2. Iter = 1344 iteration 1344; minNextMutationTime = 1238; timeNextPopSample = 1228; popParams.size() = 1 We are SAMPLING at time 1228 *** Looping through 5.2. Iter = 1345 iteration 1345; minNextMutationTime = 1239; timeNextPopSample = 1229; popParams.size() = 1 We are SAMPLING at time 1229 *** Looping through 5.2. Iter = 1346 iteration 1346; minNextMutationTime = 1240; timeNextPopSample = 1230; popParams.size() = 1 We are SAMPLING at time 1230 *** Looping through 5.2. Iter = 1347 iteration 1347; minNextMutationTime = 1241; timeNextPopSample = 1231; popParams.size() = 1 We are SAMPLING at time 1231 *** Looping through 5.2. Iter = 1348 iteration 1348; minNextMutationTime = 1242; timeNextPopSample = 1232; popParams.size() = 1 We are SAMPLING at time 1232 *** Looping through 5.2. Iter = 1349 iteration 1349; minNextMutationTime = 1243; timeNextPopSample = 1233; popParams.size() = 1 We are SAMPLING at time 1233 *** Looping through 5.2. Iter = 1350 iteration 1350; minNextMutationTime = 1244; timeNextPopSample = 1234; popParams.size() = 1 We are SAMPLING at time 1234 *** Looping through 5.2. Iter = 1351 iteration 1351; minNextMutationTime = 1245; timeNextPopSample = 1235; popParams.size() = 1 We are SAMPLING at time 1235 *** Looping through 5.2. Iter = 1352 iteration 1352; minNextMutationTime = 1246; timeNextPopSample = 1236; popParams.size() = 1 We are SAMPLING at time 1236 *** Looping through 5.2. Iter = 1353 iteration 1353; minNextMutationTime = 1236.28; timeNextPopSample = 1237; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1354 iteration 1354; minNextMutationTime = 1247; timeNextPopSample = 1237; popParams.size() = 2 We are SAMPLING at time 1237 *** Looping through 5.2. Iter = 1355 iteration 1355; minNextMutationTime = 1248; timeNextPopSample = 1238; popParams.size() = 2 We are SAMPLING at time 1238 *** Looping through 5.2. Iter = 1356 iteration 1356; minNextMutationTime = 1249; timeNextPopSample = 1239; popParams.size() = 2 We are SAMPLING at time 1239 *** Looping through 5.2. Iter = 1357 iteration 1357; minNextMutationTime = 1250; timeNextPopSample = 1240; popParams.size() = 2 We are SAMPLING at time 1240 *** Looping through 5.2. Iter = 1358 iteration 1358; minNextMutationTime = 1251; timeNextPopSample = 1241; popParams.size() = 2 We are SAMPLING at time 1241 *** Looping through 5.2. Iter = 1359 iteration 1359; minNextMutationTime = 1252; timeNextPopSample = 1242; popParams.size() = 2 We are SAMPLING at time 1242 *** Looping through 5.2. Iter = 1360 iteration 1360; minNextMutationTime = 1253; timeNextPopSample = 1243; popParams.size() = 2 We are SAMPLING at time 1243 *** Looping through 5.2. Iter = 1361 iteration 1361; minNextMutationTime = 1254; timeNextPopSample = 1244; popParams.size() = 1 We are SAMPLING at time 1244 *** Looping through 5.2. Iter = 1362 iteration 1362; minNextMutationTime = 1255; timeNextPopSample = 1245; popParams.size() = 1 We are SAMPLING at time 1245 *** Looping through 5.2. Iter = 1363 iteration 1363; minNextMutationTime = 1245.59; timeNextPopSample = 1246; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1364 iteration 1364; minNextMutationTime = 1256; timeNextPopSample = 1246; popParams.size() = 2 We are SAMPLING at time 1246 *** Looping through 5.2. Iter = 1365 iteration 1365; minNextMutationTime = 1246.64; timeNextPopSample = 1247; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1366 iteration 1366; minNextMutationTime = 1257; timeNextPopSample = 1247; popParams.size() = 3 We are SAMPLING at time 1247 *** Looping through 5.2. Iter = 1367 iteration 1367; minNextMutationTime = 1258; timeNextPopSample = 1248; popParams.size() = 1 We are SAMPLING at time 1248 *** Looping through 5.2. Iter = 1368 iteration 1368; minNextMutationTime = 1248.35; timeNextPopSample = 1249; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1369 iteration 1369; minNextMutationTime = 1259; timeNextPopSample = 1249; popParams.size() = 2 We are SAMPLING at time 1249 *** Looping through 5.2. Iter = 1370 iteration 1370; minNextMutationTime = 1260; timeNextPopSample = 1250; popParams.size() = 1 We are SAMPLING at time 1250 *** Looping through 5.2. Iter = 1371 iteration 1371; minNextMutationTime = 1261; timeNextPopSample = 1251; popParams.size() = 1 We are SAMPLING at time 1251 *** Looping through 5.2. Iter = 1372 iteration 1372; minNextMutationTime = 1262; timeNextPopSample = 1252; popParams.size() = 1 We are SAMPLING at time 1252 *** Looping through 5.2. Iter = 1373 iteration 1373; minNextMutationTime = 1263; timeNextPopSample = 1253; popParams.size() = 1 We are SAMPLING at time 1253 *** Looping through 5.2. Iter = 1374 iteration 1374; minNextMutationTime = 1264; timeNextPopSample = 1254; popParams.size() = 1 We are SAMPLING at time 1254 *** Looping through 5.2. Iter = 1375 iteration 1375; minNextMutationTime = 1265; timeNextPopSample = 1255; popParams.size() = 1 We are SAMPLING at time 1255 *** Looping through 5.2. Iter = 1376 iteration 1376; minNextMutationTime = 1266; timeNextPopSample = 1256; popParams.size() = 1 We are SAMPLING at time 1256 *** Looping through 5.2. Iter = 1377 iteration 1377; minNextMutationTime = 1267; timeNextPopSample = 1257; popParams.size() = 1 We are SAMPLING at time 1257 *** Looping through 5.2. Iter = 1378 iteration 1378; minNextMutationTime = 1268; timeNextPopSample = 1258; popParams.size() = 1 We are SAMPLING at time 1258 *** Looping through 5.2. Iter = 1379 iteration 1379; minNextMutationTime = 1269; timeNextPopSample = 1259; popParams.size() = 1 We are SAMPLING at time 1259 *** Looping through 5.2. Iter = 1380 iteration 1380; minNextMutationTime = 1270; timeNextPopSample = 1260; popParams.size() = 1 We are SAMPLING at time 1260 *** Looping through 5.2. Iter = 1381 iteration 1381; minNextMutationTime = 1271; timeNextPopSample = 1261; popParams.size() = 1 We are SAMPLING at time 1261 *** Looping through 5.2. Iter = 1382 iteration 1382; minNextMutationTime = 1272; timeNextPopSample = 1262; popParams.size() = 1 We are SAMPLING at time 1262 *** Looping through 5.2. Iter = 1383 iteration 1383; minNextMutationTime = 1273; timeNextPopSample = 1263; popParams.size() = 1 We are SAMPLING at time 1263 *** Looping through 5.2. Iter = 1384 iteration 1384; minNextMutationTime = 1274; timeNextPopSample = 1264; popParams.size() = 1 We are SAMPLING at time 1264 *** Looping through 5.2. Iter = 1385 iteration 1385; minNextMutationTime = 1275; timeNextPopSample = 1265; popParams.size() = 1 We are SAMPLING at time 1265 *** Looping through 5.2. Iter = 1386 iteration 1386; minNextMutationTime = 1265.29; timeNextPopSample = 1266; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1387 iteration 1387; minNextMutationTime = 1276; timeNextPopSample = 1266; popParams.size() = 2 We are SAMPLING at time 1266 *** Looping through 5.2. Iter = 1388 iteration 1388; minNextMutationTime = 1277; timeNextPopSample = 1267; popParams.size() = 2 We are SAMPLING at time 1267 *** Looping through 5.2. Iter = 1389 iteration 1389; minNextMutationTime = 1278; timeNextPopSample = 1268; popParams.size() = 2 We are SAMPLING at time 1268 *** Looping through 5.2. Iter = 1390 iteration 1390; minNextMutationTime = 1268.91; timeNextPopSample = 1269; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000100000; sp_id = 32) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 32) New popSize = 2 *** Looping through 5.2. Iter = 1391 iteration 1391; minNextMutationTime = 1279; timeNextPopSample = 1269; popParams.size() = 2 We are SAMPLING at time 1269 *** Looping through 5.2. Iter = 1392 iteration 1392; minNextMutationTime = 1280; timeNextPopSample = 1270; popParams.size() = 2 We are SAMPLING at time 1270 *** Looping through 5.2. Iter = 1393 iteration 1393; minNextMutationTime = 1281; timeNextPopSample = 1271; popParams.size() = 2 We are SAMPLING at time 1271 *** Looping through 5.2. Iter = 1394 iteration 1394; minNextMutationTime = 1271.52; timeNextPopSample = 1272; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1395 iteration 1395; minNextMutationTime = 1282; timeNextPopSample = 1272; popParams.size() = 3 We are SAMPLING at time 1272 *** Looping through 5.2. Iter = 1396 iteration 1396; minNextMutationTime = 1283; timeNextPopSample = 1273; popParams.size() = 3 We are SAMPLING at time 1273 *** Looping through 5.2. Iter = 1397 iteration 1397; minNextMutationTime = 1284; timeNextPopSample = 1274; popParams.size() = 2 We are SAMPLING at time 1274 *** Looping through 5.2. Iter = 1398 iteration 1398; minNextMutationTime = 1274.46; timeNextPopSample = 1275; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1399 iteration 1399; minNextMutationTime = 1285; timeNextPopSample = 1275; popParams.size() = 2 We are SAMPLING at time 1275 *** Looping through 5.2. Iter = 1400 iteration 1400; minNextMutationTime = 1286; timeNextPopSample = 1276; popParams.size() = 2 We are SAMPLING at time 1276 *** Looping through 5.2. Iter = 1401 iteration 1401; minNextMutationTime = 1287; timeNextPopSample = 1277; popParams.size() = 2 We are SAMPLING at time 1277 *** Looping through 5.2. Iter = 1402 iteration 1402; minNextMutationTime = 1288; timeNextPopSample = 1278; popParams.size() = 1 We are SAMPLING at time 1278 *** Looping through 5.2. Iter = 1403 iteration 1403; minNextMutationTime = 1289; timeNextPopSample = 1279; popParams.size() = 1 We are SAMPLING at time 1279 *** Looping through 5.2. Iter = 1404 iteration 1404; minNextMutationTime = 1279.38; timeNextPopSample = 1280; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1405 iteration 1405; minNextMutationTime = 1290; timeNextPopSample = 1280; popParams.size() = 2 We are SAMPLING at time 1280 *** Looping through 5.2. Iter = 1406 iteration 1406; minNextMutationTime = 1291; timeNextPopSample = 1281; popParams.size() = 1 We are SAMPLING at time 1281 *** Looping through 5.2. Iter = 1407 iteration 1407; minNextMutationTime = 1292; timeNextPopSample = 1282; popParams.size() = 1 We are SAMPLING at time 1282 *** Looping through 5.2. Iter = 1408 iteration 1408; minNextMutationTime = 1293; timeNextPopSample = 1283; popParams.size() = 1 We are SAMPLING at time 1283 *** Looping through 5.2. Iter = 1409 iteration 1409; minNextMutationTime = 1294; timeNextPopSample = 1284; popParams.size() = 1 We are SAMPLING at time 1284 *** Looping through 5.2. Iter = 1410 iteration 1410; minNextMutationTime = 1295; timeNextPopSample = 1285; popParams.size() = 1 We are SAMPLING at time 1285 *** Looping through 5.2. Iter = 1411 iteration 1411; minNextMutationTime = 1296; timeNextPopSample = 1286; popParams.size() = 1 We are SAMPLING at time 1286 *** Looping through 5.2. Iter = 1412 iteration 1412; minNextMutationTime = 1286.98; timeNextPopSample = 1287; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1413 iteration 1413; minNextMutationTime = 1297; timeNextPopSample = 1287; popParams.size() = 2 We are SAMPLING at time 1287 *** Looping through 5.2. Iter = 1414 iteration 1414; minNextMutationTime = 1298; timeNextPopSample = 1288; popParams.size() = 2 We are SAMPLING at time 1288 *** Looping through 5.2. Iter = 1415 iteration 1415; minNextMutationTime = 1299; timeNextPopSample = 1289; popParams.size() = 2 We are SAMPLING at time 1289 *** Looping through 5.2. Iter = 1416 iteration 1416; minNextMutationTime = 1289.37; timeNextPopSample = 1290; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1417 iteration 1417; minNextMutationTime = 1300; timeNextPopSample = 1290; popParams.size() = 3 We are SAMPLING at time 1290 *** Looping through 5.2. Iter = 1418 iteration 1418; minNextMutationTime = 1301; timeNextPopSample = 1291; popParams.size() = 2 We are SAMPLING at time 1291 *** Looping through 5.2. Iter = 1419 iteration 1419; minNextMutationTime = 1302; timeNextPopSample = 1292; popParams.size() = 2 We are SAMPLING at time 1292 *** Looping through 5.2. Iter = 1420 iteration 1420; minNextMutationTime = 1303; timeNextPopSample = 1293; popParams.size() = 1 We are SAMPLING at time 1293 *** Looping through 5.2. Iter = 1421 iteration 1421; minNextMutationTime = 1304; timeNextPopSample = 1294; popParams.size() = 1 We are SAMPLING at time 1294 *** Looping through 5.2. Iter = 1422 iteration 1422; minNextMutationTime = 1305; timeNextPopSample = 1295; popParams.size() = 1 We are SAMPLING at time 1295 *** Looping through 5.2. Iter = 1423 iteration 1423; minNextMutationTime = 1306; timeNextPopSample = 1296; popParams.size() = 1 We are SAMPLING at time 1296 *** Looping through 5.2. Iter = 1424 iteration 1424; minNextMutationTime = 1307; timeNextPopSample = 1297; popParams.size() = 1 We are SAMPLING at time 1297 *** Looping through 5.2. Iter = 1425 iteration 1425; minNextMutationTime = 1308; timeNextPopSample = 1298; popParams.size() = 1 We are SAMPLING at time 1298 *** Looping through 5.2. Iter = 1426 iteration 1426; minNextMutationTime = 1309; timeNextPopSample = 1299; popParams.size() = 1 We are SAMPLING at time 1299 *** Looping through 5.2. Iter = 1427 iteration 1427; minNextMutationTime = 1310; timeNextPopSample = 1300; popParams.size() = 1 We are SAMPLING at time 1300 *** Looping through 5.2. Iter = 1428 iteration 1428; minNextMutationTime = 1311; timeNextPopSample = 1301; popParams.size() = 1 We are SAMPLING at time 1301 *** Looping through 5.2. Iter = 1429 iteration 1429; minNextMutationTime = 1312; timeNextPopSample = 1302; popParams.size() = 1 We are SAMPLING at time 1302 *** Looping through 5.2. Iter = 1430 iteration 1430; minNextMutationTime = 1313; timeNextPopSample = 1303; popParams.size() = 1 We are SAMPLING at time 1303 *** Looping through 5.2. Iter = 1431 iteration 1431; minNextMutationTime = 1303.66; timeNextPopSample = 1304; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1432 iteration 1432; minNextMutationTime = 1314; timeNextPopSample = 1304; popParams.size() = 2 We are SAMPLING at time 1304 *** Looping through 5.2. Iter = 1433 iteration 1433; minNextMutationTime = 1315; timeNextPopSample = 1305; popParams.size() = 2 We are SAMPLING at time 1305 *** Looping through 5.2. Iter = 1434 iteration 1434; minNextMutationTime = 1316; timeNextPopSample = 1306; popParams.size() = 1 We are SAMPLING at time 1306 *** Looping through 5.2. Iter = 1435 iteration 1435; minNextMutationTime = 1317; timeNextPopSample = 1307; popParams.size() = 1 We are SAMPLING at time 1307 *** Looping through 5.2. Iter = 1436 iteration 1436; minNextMutationTime = 1318; timeNextPopSample = 1308; popParams.size() = 1 We are SAMPLING at time 1308 *** Looping through 5.2. Iter = 1437 iteration 1437; minNextMutationTime = 1308.94; timeNextPopSample = 1309; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1438 iteration 1438; minNextMutationTime = 1319; timeNextPopSample = 1309; popParams.size() = 2 We are SAMPLING at time 1309 *** Looping through 5.2. Iter = 1439 iteration 1439; minNextMutationTime = 1320; timeNextPopSample = 1310; popParams.size() = 2 We are SAMPLING at time 1310 *** Looping through 5.2. Iter = 1440 iteration 1440; minNextMutationTime = 1321; timeNextPopSample = 1311; popParams.size() = 2 We are SAMPLING at time 1311 *** Looping through 5.2. Iter = 1441 iteration 1441; minNextMutationTime = 1322; timeNextPopSample = 1312; popParams.size() = 1 We are SAMPLING at time 1312 *** Looping through 5.2. Iter = 1442 iteration 1442; minNextMutationTime = 1323; timeNextPopSample = 1313; popParams.size() = 1 We are SAMPLING at time 1313 *** Looping through 5.2. Iter = 1443 iteration 1443; minNextMutationTime = 1324; timeNextPopSample = 1314; popParams.size() = 1 We are SAMPLING at time 1314 *** Looping through 5.2. Iter = 1444 iteration 1444; minNextMutationTime = 1325; timeNextPopSample = 1315; popParams.size() = 1 We are SAMPLING at time 1315 *** Looping through 5.2. Iter = 1445 iteration 1445; minNextMutationTime = 1326; timeNextPopSample = 1316; popParams.size() = 1 We are SAMPLING at time 1316 *** Looping through 5.2. Iter = 1446 iteration 1446; minNextMutationTime = 1316.08; timeNextPopSample = 1317; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1447 iteration 1447; minNextMutationTime = 1327; timeNextPopSample = 1317; popParams.size() = 2 We are SAMPLING at time 1317 *** Looping through 5.2. Iter = 1448 iteration 1448; minNextMutationTime = 1328; timeNextPopSample = 1318; popParams.size() = 1 We are SAMPLING at time 1318 *** Looping through 5.2. Iter = 1449 iteration 1449; minNextMutationTime = 1329; timeNextPopSample = 1319; popParams.size() = 1 We are SAMPLING at time 1319 *** Looping through 5.2. Iter = 1450 iteration 1450; minNextMutationTime = 1330; timeNextPopSample = 1320; popParams.size() = 1 We are SAMPLING at time 1320 *** Looping through 5.2. Iter = 1451 iteration 1451; minNextMutationTime = 1331; timeNextPopSample = 1321; popParams.size() = 1 We are SAMPLING at time 1321 *** Looping through 5.2. Iter = 1452 iteration 1452; minNextMutationTime = 1332; timeNextPopSample = 1322; popParams.size() = 1 We are SAMPLING at time 1322 *** Looping through 5.2. Iter = 1453 iteration 1453; minNextMutationTime = 1333; timeNextPopSample = 1323; popParams.size() = 1 We are SAMPLING at time 1323 *** Looping through 5.2. Iter = 1454 iteration 1454; minNextMutationTime = 1323.97; timeNextPopSample = 1324; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1455 iteration 1455; minNextMutationTime = 1334; timeNextPopSample = 1324; popParams.size() = 2 We are SAMPLING at time 1324 *** Looping through 5.2. Iter = 1456 iteration 1456; minNextMutationTime = 1335; timeNextPopSample = 1325; popParams.size() = 2 We are SAMPLING at time 1325 *** Looping through 5.2. Iter = 1457 iteration 1457; minNextMutationTime = 1336; timeNextPopSample = 1326; popParams.size() = 1 We are SAMPLING at time 1326 *** Looping through 5.2. Iter = 1458 iteration 1458; minNextMutationTime = 1337; timeNextPopSample = 1327; popParams.size() = 1 We are SAMPLING at time 1327 *** Looping through 5.2. Iter = 1459 iteration 1459; minNextMutationTime = 1338; timeNextPopSample = 1328; popParams.size() = 1 We are SAMPLING at time 1328 *** Looping through 5.2. Iter = 1460 iteration 1460; minNextMutationTime = 1339; timeNextPopSample = 1329; popParams.size() = 1 We are SAMPLING at time 1329 *** Looping through 5.2. Iter = 1461 iteration 1461; minNextMutationTime = 1340; timeNextPopSample = 1330; popParams.size() = 1 We are SAMPLING at time 1330 *** Looping through 5.2. Iter = 1462 iteration 1462; minNextMutationTime = 1341; timeNextPopSample = 1331; popParams.size() = 1 We are SAMPLING at time 1331 *** Looping through 5.2. Iter = 1463 iteration 1463; minNextMutationTime = 1342; timeNextPopSample = 1332; popParams.size() = 1 We are SAMPLING at time 1332 *** Looping through 5.2. Iter = 1464 iteration 1464; minNextMutationTime = 1343; timeNextPopSample = 1333; popParams.size() = 1 We are SAMPLING at time 1333 *** Looping through 5.2. Iter = 1465 iteration 1465; minNextMutationTime = 1344; timeNextPopSample = 1334; popParams.size() = 1 We are SAMPLING at time 1334 *** Looping through 5.2. Iter = 1466 iteration 1466; minNextMutationTime = 1345; timeNextPopSample = 1335; popParams.size() = 1 We are SAMPLING at time 1335 *** Looping through 5.2. Iter = 1467 iteration 1467; minNextMutationTime = 1346; timeNextPopSample = 1336; popParams.size() = 1 We are SAMPLING at time 1336 *** Looping through 5.2. Iter = 1468 iteration 1468; minNextMutationTime = 1347; timeNextPopSample = 1337; popParams.size() = 1 We are SAMPLING at time 1337 *** Looping through 5.2. Iter = 1469 iteration 1469; minNextMutationTime = 1348; timeNextPopSample = 1338; popParams.size() = 1 We are SAMPLING at time 1338 *** Looping through 5.2. Iter = 1470 iteration 1470; minNextMutationTime = 1349; timeNextPopSample = 1339; popParams.size() = 1 We are SAMPLING at time 1339 *** Looping through 5.2. Iter = 1471 iteration 1471; minNextMutationTime = 1350; timeNextPopSample = 1340; popParams.size() = 1 We are SAMPLING at time 1340 *** Looping through 5.2. Iter = 1472 iteration 1472; minNextMutationTime = 1351; timeNextPopSample = 1341; popParams.size() = 1 We are SAMPLING at time 1341 *** Looping through 5.2. Iter = 1473 iteration 1473; minNextMutationTime = 1352; timeNextPopSample = 1342; popParams.size() = 1 We are SAMPLING at time 1342 *** Looping through 5.2. Iter = 1474 iteration 1474; minNextMutationTime = 1353; timeNextPopSample = 1343; popParams.size() = 1 We are SAMPLING at time 1343 *** Looping through 5.2. Iter = 1475 iteration 1475; minNextMutationTime = 1354; timeNextPopSample = 1344; popParams.size() = 1 We are SAMPLING at time 1344 *** Looping through 5.2. Iter = 1476 iteration 1476; minNextMutationTime = 1355; timeNextPopSample = 1345; popParams.size() = 1 We are SAMPLING at time 1345 *** Looping through 5.2. Iter = 1477 iteration 1477; minNextMutationTime = 1356; timeNextPopSample = 1346; popParams.size() = 1 We are SAMPLING at time 1346 *** Looping through 5.2. Iter = 1478 iteration 1478; minNextMutationTime = 1357; timeNextPopSample = 1347; popParams.size() = 1 We are SAMPLING at time 1347 *** Looping through 5.2. Iter = 1479 iteration 1479; minNextMutationTime = 1358; timeNextPopSample = 1348; popParams.size() = 1 We are SAMPLING at time 1348 *** Looping through 5.2. Iter = 1480 iteration 1480; minNextMutationTime = 1359; timeNextPopSample = 1349; popParams.size() = 1 We are SAMPLING at time 1349 *** Looping through 5.2. Iter = 1481 iteration 1481; minNextMutationTime = 1360; timeNextPopSample = 1350; popParams.size() = 1 We are SAMPLING at time 1350 *** Looping through 5.2. Iter = 1482 iteration 1482; minNextMutationTime = 1361; timeNextPopSample = 1351; popParams.size() = 1 We are SAMPLING at time 1351 *** Looping through 5.2. Iter = 1483 iteration 1483; minNextMutationTime = 1362; timeNextPopSample = 1352; popParams.size() = 1 We are SAMPLING at time 1352 *** Looping through 5.2. Iter = 1484 iteration 1484; minNextMutationTime = 1363; timeNextPopSample = 1353; popParams.size() = 1 We are SAMPLING at time 1353 *** Looping through 5.2. Iter = 1485 iteration 1485; minNextMutationTime = 1364; timeNextPopSample = 1354; popParams.size() = 1 We are SAMPLING at time 1354 *** Looping through 5.2. Iter = 1486 iteration 1486; minNextMutationTime = 1354.71; timeNextPopSample = 1355; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1487 iteration 1487; minNextMutationTime = 1365; timeNextPopSample = 1355; popParams.size() = 2 We are SAMPLING at time 1355 *** Looping through 5.2. Iter = 1488 iteration 1488; minNextMutationTime = 1366; timeNextPopSample = 1356; popParams.size() = 2 We are SAMPLING at time 1356 *** Looping through 5.2. Iter = 1489 iteration 1489; minNextMutationTime = 1367; timeNextPopSample = 1357; popParams.size() = 1 We are SAMPLING at time 1357 *** Looping through 5.2. Iter = 1490 iteration 1490; minNextMutationTime = 1368; timeNextPopSample = 1358; popParams.size() = 1 We are SAMPLING at time 1358 *** Looping through 5.2. Iter = 1491 iteration 1491; minNextMutationTime = 1369; timeNextPopSample = 1359; popParams.size() = 1 We are SAMPLING at time 1359 *** Looping through 5.2. Iter = 1492 iteration 1492; minNextMutationTime = 1370; timeNextPopSample = 1360; popParams.size() = 1 We are SAMPLING at time 1360 *** Looping through 5.2. Iter = 1493 iteration 1493; minNextMutationTime = 1371; timeNextPopSample = 1361; popParams.size() = 1 We are SAMPLING at time 1361 *** Looping through 5.2. Iter = 1494 iteration 1494; minNextMutationTime = 1372; timeNextPopSample = 1362; popParams.size() = 1 We are SAMPLING at time 1362 *** Looping through 5.2. Iter = 1495 iteration 1495; minNextMutationTime = 1373; timeNextPopSample = 1363; popParams.size() = 1 We are SAMPLING at time 1363 *** Looping through 5.2. Iter = 1496 iteration 1496; minNextMutationTime = 1374; timeNextPopSample = 1364; popParams.size() = 1 We are SAMPLING at time 1364 *** Looping through 5.2. Iter = 1497 iteration 1497; minNextMutationTime = 1375; timeNextPopSample = 1365; popParams.size() = 1 We are SAMPLING at time 1365 *** Looping through 5.2. Iter = 1498 iteration 1498; minNextMutationTime = 1376; timeNextPopSample = 1366; popParams.size() = 1 We are SAMPLING at time 1366 *** Looping through 5.2. Iter = 1499 iteration 1499; minNextMutationTime = 1366.51; timeNextPopSample = 1367; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1500 iteration 1500; minNextMutationTime = 1377; timeNextPopSample = 1367; popParams.size() = 2 We are SAMPLING at time 1367 *** Looping through 5.2. Iter = 1501 iteration 1501; minNextMutationTime = 1378; timeNextPopSample = 1368; popParams.size() = 2 We are SAMPLING at time 1368 *** Looping through 5.2. Iter = 1502 iteration 1502; minNextMutationTime = 1379; timeNextPopSample = 1369; popParams.size() = 2 We are SAMPLING at time 1369 *** Looping through 5.2. Iter = 1503 iteration 1503; minNextMutationTime = 1380; timeNextPopSample = 1370; popParams.size() = 2 We are SAMPLING at time 1370 *** Looping through 5.2. Iter = 1504 iteration 1504; minNextMutationTime = 1381; timeNextPopSample = 1371; popParams.size() = 2 We are SAMPLING at time 1371 *** Looping through 5.2. Iter = 1505 iteration 1505; minNextMutationTime = 1382; timeNextPopSample = 1372; popParams.size() = 2 We are SAMPLING at time 1372 *** Looping through 5.2. Iter = 1506 iteration 1506; minNextMutationTime = 1383; timeNextPopSample = 1373; popParams.size() = 2 We are SAMPLING at time 1373 *** Looping through 5.2. Iter = 1507 iteration 1507; minNextMutationTime = 1384; timeNextPopSample = 1374; popParams.size() = 2 We are SAMPLING at time 1374 *** Looping through 5.2. Iter = 1508 iteration 1508; minNextMutationTime = 1385; timeNextPopSample = 1375; popParams.size() = 2 We are SAMPLING at time 1375 *** Looping through 5.2. Iter = 1509 iteration 1509; minNextMutationTime = 1386; timeNextPopSample = 1376; popParams.size() = 2 We are SAMPLING at time 1376 *** Looping through 5.2. Iter = 1510 iteration 1510; minNextMutationTime = 1376.47; timeNextPopSample = 1377; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1511 iteration 1511; minNextMutationTime = 1387; timeNextPopSample = 1377; popParams.size() = 3 We are SAMPLING at time 1377 *** Looping through 5.2. Iter = 1512 iteration 1512; minNextMutationTime = 1388; timeNextPopSample = 1378; popParams.size() = 3 We are SAMPLING at time 1378 *** Looping through 5.2. Iter = 1513 iteration 1513; minNextMutationTime = 1389; timeNextPopSample = 1379; popParams.size() = 3 We are SAMPLING at time 1379 *** Looping through 5.2. Iter = 1514 iteration 1514; minNextMutationTime = 1390; timeNextPopSample = 1380; popParams.size() = 2 We are SAMPLING at time 1380 *** Looping through 5.2. Iter = 1515 iteration 1515; minNextMutationTime = 1391; timeNextPopSample = 1381; popParams.size() = 2 We are SAMPLING at time 1381 *** Looping through 5.2. Iter = 1516 iteration 1516; minNextMutationTime = 1392; timeNextPopSample = 1382; popParams.size() = 2 We are SAMPLING at time 1382 *** Looping through 5.2. Iter = 1517 iteration 1517; minNextMutationTime = 1393; timeNextPopSample = 1383; popParams.size() = 2 We are SAMPLING at time 1383 *** Looping through 5.2. Iter = 1518 iteration 1518; minNextMutationTime = 1394; timeNextPopSample = 1384; popParams.size() = 2 We are SAMPLING at time 1384 *** Looping through 5.2. Iter = 1519 iteration 1519; minNextMutationTime = 1384.9; timeNextPopSample = 1385; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1520 iteration 1520; minNextMutationTime = 1395; timeNextPopSample = 1385; popParams.size() = 3 We are SAMPLING at time 1385 *** Looping through 5.2. Iter = 1521 iteration 1521; minNextMutationTime = 1396; timeNextPopSample = 1386; popParams.size() = 3 We are SAMPLING at time 1386 *** Looping through 5.2. Iter = 1522 iteration 1522; minNextMutationTime = 1397; timeNextPopSample = 1387; popParams.size() = 2 We are SAMPLING at time 1387 *** Looping through 5.2. Iter = 1523 iteration 1523; minNextMutationTime = 1398; timeNextPopSample = 1388; popParams.size() = 1 We are SAMPLING at time 1388 *** Looping through 5.2. Iter = 1524 iteration 1524; minNextMutationTime = 1399; timeNextPopSample = 1389; popParams.size() = 1 We are SAMPLING at time 1389 *** Looping through 5.2. Iter = 1525 iteration 1525; minNextMutationTime = 1400; timeNextPopSample = 1390; popParams.size() = 1 We are SAMPLING at time 1390 *** Looping through 5.2. Iter = 1526 iteration 1526; minNextMutationTime = 1401; timeNextPopSample = 1391; popParams.size() = 1 We are SAMPLING at time 1391 *** Looping through 5.2. Iter = 1527 iteration 1527; minNextMutationTime = 1402; timeNextPopSample = 1392; popParams.size() = 1 We are SAMPLING at time 1392 *** Looping through 5.2. Iter = 1528 iteration 1528; minNextMutationTime = 1403; timeNextPopSample = 1393; popParams.size() = 1 We are SAMPLING at time 1393 *** Looping through 5.2. Iter = 1529 iteration 1529; minNextMutationTime = 1404; timeNextPopSample = 1394; popParams.size() = 1 We are SAMPLING at time 1394 *** Looping through 5.2. Iter = 1530 iteration 1530; minNextMutationTime = 1405; timeNextPopSample = 1395; popParams.size() = 1 We are SAMPLING at time 1395 *** Looping through 5.2. Iter = 1531 iteration 1531; minNextMutationTime = 1395.37; timeNextPopSample = 1396; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1532 iteration 1532; minNextMutationTime = 1406; timeNextPopSample = 1396; popParams.size() = 2 We are SAMPLING at time 1396 *** Looping through 5.2. Iter = 1533 iteration 1533; minNextMutationTime = 1396.17; timeNextPopSample = 1397; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1534 iteration 1534; minNextMutationTime = 1407; timeNextPopSample = 1397; popParams.size() = 2 We are SAMPLING at time 1397 *** Looping through 5.2. Iter = 1535 iteration 1535; minNextMutationTime = 1408; timeNextPopSample = 1398; popParams.size() = 2 We are SAMPLING at time 1398 *** Looping through 5.2. Iter = 1536 iteration 1536; minNextMutationTime = 1409; timeNextPopSample = 1399; popParams.size() = 1 We are SAMPLING at time 1399 *** Looping through 5.2. Iter = 1537 iteration 1537; minNextMutationTime = 1410; timeNextPopSample = 1400; popParams.size() = 1 We are SAMPLING at time 1400 *** Looping through 5.2. Iter = 1538 iteration 1538; minNextMutationTime = 1411; timeNextPopSample = 1401; popParams.size() = 1 We are SAMPLING at time 1401 *** Looping through 5.2. Iter = 1539 iteration 1539; minNextMutationTime = 1412; timeNextPopSample = 1402; popParams.size() = 1 We are SAMPLING at time 1402 *** Looping through 5.2. Iter = 1540 iteration 1540; minNextMutationTime = 1413; timeNextPopSample = 1403; popParams.size() = 1 We are SAMPLING at time 1403 *** Looping through 5.2. Iter = 1541 iteration 1541; minNextMutationTime = 1414; timeNextPopSample = 1404; popParams.size() = 1 We are SAMPLING at time 1404 *** Looping through 5.2. Iter = 1542 iteration 1542; minNextMutationTime = 1415; timeNextPopSample = 1405; popParams.size() = 1 We are SAMPLING at time 1405 *** Looping through 5.2. Iter = 1543 iteration 1543; minNextMutationTime = 1416; timeNextPopSample = 1406; popParams.size() = 1 We are SAMPLING at time 1406 *** Looping through 5.2. Iter = 1544 iteration 1544; minNextMutationTime = 1417; timeNextPopSample = 1407; popParams.size() = 1 We are SAMPLING at time 1407 *** Looping through 5.2. Iter = 1545 iteration 1545; minNextMutationTime = 1407.73; timeNextPopSample = 1408; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1546 iteration 1546; minNextMutationTime = 1418; timeNextPopSample = 1408; popParams.size() = 2 We are SAMPLING at time 1408 *** Looping through 5.2. Iter = 1547 iteration 1547; minNextMutationTime = 1419; timeNextPopSample = 1409; popParams.size() = 2 We are SAMPLING at time 1409 *** Looping through 5.2. Iter = 1548 iteration 1548; minNextMutationTime = 1420; timeNextPopSample = 1410; popParams.size() = 1 We are SAMPLING at time 1410 *** Looping through 5.2. Iter = 1549 iteration 1549; minNextMutationTime = 1421; timeNextPopSample = 1411; popParams.size() = 1 We are SAMPLING at time 1411 *** Looping through 5.2. Iter = 1550 iteration 1550; minNextMutationTime = 1411.53; timeNextPopSample = 1412; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1551 iteration 1551; minNextMutationTime = 1422; timeNextPopSample = 1412; popParams.size() = 2 We are SAMPLING at time 1412 *** Looping through 5.2. Iter = 1552 iteration 1552; minNextMutationTime = 1423; timeNextPopSample = 1413; popParams.size() = 2 We are SAMPLING at time 1413 *** Looping through 5.2. Iter = 1553 iteration 1553; minNextMutationTime = 1424; timeNextPopSample = 1414; popParams.size() = 1 We are SAMPLING at time 1414 *** Looping through 5.2. Iter = 1554 iteration 1554; minNextMutationTime = 1425; timeNextPopSample = 1415; popParams.size() = 1 We are SAMPLING at time 1415 *** Looping through 5.2. Iter = 1555 iteration 1555; minNextMutationTime = 1426; timeNextPopSample = 1416; popParams.size() = 1 We are SAMPLING at time 1416 *** Looping through 5.2. Iter = 1556 iteration 1556; minNextMutationTime = 1427; timeNextPopSample = 1417; popParams.size() = 1 We are SAMPLING at time 1417 *** Looping through 5.2. Iter = 1557 iteration 1557; minNextMutationTime = 1428; timeNextPopSample = 1418; popParams.size() = 1 We are SAMPLING at time 1418 *** Looping through 5.2. Iter = 1558 iteration 1558; minNextMutationTime = 1429; timeNextPopSample = 1419; popParams.size() = 1 We are SAMPLING at time 1419 *** Looping through 5.2. Iter = 1559 iteration 1559; minNextMutationTime = 1430; timeNextPopSample = 1420; popParams.size() = 1 We are SAMPLING at time 1420 *** Looping through 5.2. Iter = 1560 iteration 1560; minNextMutationTime = 1431; timeNextPopSample = 1421; popParams.size() = 1 We are SAMPLING at time 1421 *** Looping through 5.2. Iter = 1561 iteration 1561; minNextMutationTime = 1432; timeNextPopSample = 1422; popParams.size() = 1 We are SAMPLING at time 1422 *** Looping through 5.2. Iter = 1562 iteration 1562; minNextMutationTime = 1433; timeNextPopSample = 1423; popParams.size() = 1 We are SAMPLING at time 1423 *** Looping through 5.2. Iter = 1563 iteration 1563; minNextMutationTime = 1434; timeNextPopSample = 1424; popParams.size() = 1 We are SAMPLING at time 1424 *** Looping through 5.2. Iter = 1564 iteration 1564; minNextMutationTime = 1435; timeNextPopSample = 1425; popParams.size() = 1 We are SAMPLING at time 1425 *** Looping through 5.2. Iter = 1565 iteration 1565; minNextMutationTime = 1436; timeNextPopSample = 1426; popParams.size() = 1 We are SAMPLING at time 1426 *** Looping through 5.2. Iter = 1566 iteration 1566; minNextMutationTime = 1437; timeNextPopSample = 1427; popParams.size() = 1 We are SAMPLING at time 1427 *** Looping through 5.2. Iter = 1567 iteration 1567; minNextMutationTime = 1438; timeNextPopSample = 1428; popParams.size() = 1 We are SAMPLING at time 1428 *** Looping through 5.2. Iter = 1568 iteration 1568; minNextMutationTime = 1439; timeNextPopSample = 1429; popParams.size() = 1 We are SAMPLING at time 1429 *** Looping through 5.2. Iter = 1569 iteration 1569; minNextMutationTime = 1440; timeNextPopSample = 1430; popParams.size() = 1 We are SAMPLING at time 1430 *** Looping through 5.2. Iter = 1570 iteration 1570; minNextMutationTime = 1430.8; timeNextPopSample = 1431; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1571 iteration 1571; minNextMutationTime = 1441; timeNextPopSample = 1431; popParams.size() = 2 We are SAMPLING at time 1431 *** Looping through 5.2. Iter = 1572 iteration 1572; minNextMutationTime = 1442; timeNextPopSample = 1432; popParams.size() = 2 We are SAMPLING at time 1432 *** Looping through 5.2. Iter = 1573 iteration 1573; minNextMutationTime = 1443; timeNextPopSample = 1433; popParams.size() = 2 We are SAMPLING at time 1433 *** Looping through 5.2. Iter = 1574 iteration 1574; minNextMutationTime = 1444; timeNextPopSample = 1434; popParams.size() = 2 We are SAMPLING at time 1434 *** Looping through 5.2. Iter = 1575 iteration 1575; minNextMutationTime = 1445; timeNextPopSample = 1435; popParams.size() = 2 We are SAMPLING at time 1435 *** Looping through 5.2. Iter = 1576 iteration 1576; minNextMutationTime = 1446; timeNextPopSample = 1436; popParams.size() = 2 We are SAMPLING at time 1436 *** Looping through 5.2. Iter = 1577 iteration 1577; minNextMutationTime = 1436.46; timeNextPopSample = 1437; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1578 iteration 1578; minNextMutationTime = 1447; timeNextPopSample = 1437; popParams.size() = 3 We are SAMPLING at time 1437 *** Looping through 5.2. Iter = 1579 iteration 1579; minNextMutationTime = 1448; timeNextPopSample = 1438; popParams.size() = 3 We are SAMPLING at time 1438 *** Looping through 5.2. Iter = 1580 iteration 1580; minNextMutationTime = 1449; timeNextPopSample = 1439; popParams.size() = 3 We are SAMPLING at time 1439 *** Looping through 5.2. Iter = 1581 iteration 1581; minNextMutationTime = 1450; timeNextPopSample = 1440; popParams.size() = 3 We are SAMPLING at time 1440 *** Looping through 5.2. Iter = 1582 iteration 1582; minNextMutationTime = 1451; timeNextPopSample = 1441; popParams.size() = 3 We are SAMPLING at time 1441 *** Looping through 5.2. Iter = 1583 iteration 1583; minNextMutationTime = 1452; timeNextPopSample = 1442; popParams.size() = 3 We are SAMPLING at time 1442 *** Looping through 5.2. Iter = 1584 iteration 1584; minNextMutationTime = 1453; timeNextPopSample = 1443; popParams.size() = 3 We are SAMPLING at time 1443 *** Looping through 5.2. Iter = 1585 iteration 1585; minNextMutationTime = 1454; timeNextPopSample = 1444; popParams.size() = 2 We are SAMPLING at time 1444 *** Looping through 5.2. Iter = 1586 iteration 1586; minNextMutationTime = 1455; timeNextPopSample = 1445; popParams.size() = 2 We are SAMPLING at time 1445 *** Looping through 5.2. Iter = 1587 iteration 1587; minNextMutationTime = 1456; timeNextPopSample = 1446; popParams.size() = 1 We are SAMPLING at time 1446 *** Looping through 5.2. Iter = 1588 iteration 1588; minNextMutationTime = 1446.57; timeNextPopSample = 1447; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1589 iteration 1589; minNextMutationTime = 1457; timeNextPopSample = 1447; popParams.size() = 2 We are SAMPLING at time 1447 *** Looping through 5.2. Iter = 1590 iteration 1590; minNextMutationTime = 1458; timeNextPopSample = 1448; popParams.size() = 1 We are SAMPLING at time 1448 *** Looping through 5.2. Iter = 1591 iteration 1591; minNextMutationTime = 1459; timeNextPopSample = 1449; popParams.size() = 1 We are SAMPLING at time 1449 *** Looping through 5.2. Iter = 1592 iteration 1592; minNextMutationTime = 1460; timeNextPopSample = 1450; popParams.size() = 1 We are SAMPLING at time 1450 *** Looping through 5.2. Iter = 1593 iteration 1593; minNextMutationTime = 1461; timeNextPopSample = 1451; popParams.size() = 1 We are SAMPLING at time 1451 *** Looping through 5.2. Iter = 1594 iteration 1594; minNextMutationTime = 1462; timeNextPopSample = 1452; popParams.size() = 1 We are SAMPLING at time 1452 *** Looping through 5.2. Iter = 1595 iteration 1595; minNextMutationTime = 1463; timeNextPopSample = 1453; popParams.size() = 1 We are SAMPLING at time 1453 *** Looping through 5.2. Iter = 1596 iteration 1596; minNextMutationTime = 1464; timeNextPopSample = 1454; popParams.size() = 1 We are SAMPLING at time 1454 *** Looping through 5.2. Iter = 1597 iteration 1597; minNextMutationTime = 1465; timeNextPopSample = 1455; popParams.size() = 1 We are SAMPLING at time 1455 *** Looping through 5.2. Iter = 1598 iteration 1598; minNextMutationTime = 1466; timeNextPopSample = 1456; popParams.size() = 1 We are SAMPLING at time 1456 *** Looping through 5.2. Iter = 1599 iteration 1599; minNextMutationTime = 1467; timeNextPopSample = 1457; popParams.size() = 1 We are SAMPLING at time 1457 *** Looping through 5.2. Iter = 1600 iteration 1600; minNextMutationTime = 1468; timeNextPopSample = 1458; popParams.size() = 1 We are SAMPLING at time 1458 *** Looping through 5.2. Iter = 1601 iteration 1601; minNextMutationTime = 1458.83; timeNextPopSample = 1459; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1602 iteration 1602; minNextMutationTime = 1469; timeNextPopSample = 1459; popParams.size() = 2 We are SAMPLING at time 1459 *** Looping through 5.2. Iter = 1603 iteration 1603; minNextMutationTime = 1470; timeNextPopSample = 1460; popParams.size() = 2 We are SAMPLING at time 1460 *** Looping through 5.2. Iter = 1604 iteration 1604; minNextMutationTime = 1471; timeNextPopSample = 1461; popParams.size() = 1 We are SAMPLING at time 1461 *** Looping through 5.2. Iter = 1605 iteration 1605; minNextMutationTime = 1472; timeNextPopSample = 1462; popParams.size() = 1 We are SAMPLING at time 1462 *** Looping through 5.2. Iter = 1606 iteration 1606; minNextMutationTime = 1473; timeNextPopSample = 1463; popParams.size() = 1 We are SAMPLING at time 1463 *** Looping through 5.2. Iter = 1607 iteration 1607; minNextMutationTime = 1474; timeNextPopSample = 1464; popParams.size() = 1 We are SAMPLING at time 1464 *** Looping through 5.2. Iter = 1608 iteration 1608; minNextMutationTime = 1475; timeNextPopSample = 1465; popParams.size() = 1 We are SAMPLING at time 1465 *** Looping through 5.2. Iter = 1609 iteration 1609; minNextMutationTime = 1476; timeNextPopSample = 1466; popParams.size() = 1 We are SAMPLING at time 1466 *** Looping through 5.2. Iter = 1610 iteration 1610; minNextMutationTime = 1466.22; timeNextPopSample = 1467; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1611 iteration 1611; minNextMutationTime = 1477; timeNextPopSample = 1467; popParams.size() = 2 We are SAMPLING at time 1467 *** Looping through 5.2. Iter = 1612 iteration 1612; minNextMutationTime = 1467.56; timeNextPopSample = 1468; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000001000; sp_id = 8) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 8) New popSize = 1 *** Looping through 5.2. Iter = 1613 iteration 1613; minNextMutationTime = 1478; timeNextPopSample = 1468; popParams.size() = 2 We are SAMPLING at time 1468 *** Looping through 5.2. Iter = 1614 iteration 1614; minNextMutationTime = 1479; timeNextPopSample = 1469; popParams.size() = 2 We are SAMPLING at time 1469 *** Looping through 5.2. Iter = 1615 iteration 1615; minNextMutationTime = 1480; timeNextPopSample = 1470; popParams.size() = 2 We are SAMPLING at time 1470 *** Looping through 5.2. Iter = 1616 iteration 1616; minNextMutationTime = 1481; timeNextPopSample = 1471; popParams.size() = 2 We are SAMPLING at time 1471 *** Looping through 5.2. Iter = 1617 iteration 1617; minNextMutationTime = 1482; timeNextPopSample = 1472; popParams.size() = 2 We are SAMPLING at time 1472 *** Looping through 5.2. Iter = 1618 iteration 1618; minNextMutationTime = 1483; timeNextPopSample = 1473; popParams.size() = 2 We are SAMPLING at time 1473 *** Looping through 5.2. Iter = 1619 iteration 1619; minNextMutationTime = 1484; timeNextPopSample = 1474; popParams.size() = 2 We are SAMPLING at time 1474 *** Looping through 5.2. Iter = 1620 iteration 1620; minNextMutationTime = 1485; timeNextPopSample = 1475; popParams.size() = 2 We are SAMPLING at time 1475 *** Looping through 5.2. Iter = 1621 iteration 1621; minNextMutationTime = 1486; timeNextPopSample = 1476; popParams.size() = 2 We are SAMPLING at time 1476 *** Looping through 5.2. Iter = 1622 iteration 1622; minNextMutationTime = 1487; timeNextPopSample = 1477; popParams.size() = 2 We are SAMPLING at time 1477 *** Looping through 5.2. Iter = 1623 iteration 1623; minNextMutationTime = 1488; timeNextPopSample = 1478; popParams.size() = 2 We are SAMPLING at time 1478 *** Looping through 5.2. Iter = 1624 iteration 1624; minNextMutationTime = 1489; timeNextPopSample = 1479; popParams.size() = 2 We are SAMPLING at time 1479 *** Looping through 5.2. Iter = 1625 iteration 1625; minNextMutationTime = 1490; timeNextPopSample = 1480; popParams.size() = 2 We are SAMPLING at time 1480 *** Looping through 5.2. Iter = 1626 iteration 1626; minNextMutationTime = 1491; timeNextPopSample = 1481; popParams.size() = 1 We are SAMPLING at time 1481 *** Looping through 5.2. Iter = 1627 iteration 1627; minNextMutationTime = 1492; timeNextPopSample = 1482; popParams.size() = 1 We are SAMPLING at time 1482 *** Looping through 5.2. Iter = 1628 iteration 1628; minNextMutationTime = 1493; timeNextPopSample = 1483; popParams.size() = 1 We are SAMPLING at time 1483 *** Looping through 5.2. Iter = 1629 iteration 1629; minNextMutationTime = 1494; timeNextPopSample = 1484; popParams.size() = 1 We are SAMPLING at time 1484 *** Looping through 5.2. Iter = 1630 iteration 1630; minNextMutationTime = 1495; timeNextPopSample = 1485; popParams.size() = 1 We are SAMPLING at time 1485 *** Looping through 5.2. Iter = 1631 iteration 1631; minNextMutationTime = 1496; timeNextPopSample = 1486; popParams.size() = 1 We are SAMPLING at time 1486 *** Looping through 5.2. Iter = 1632 iteration 1632; minNextMutationTime = 1497; timeNextPopSample = 1487; popParams.size() = 1 We are SAMPLING at time 1487 *** Looping through 5.2. Iter = 1633 iteration 1633; minNextMutationTime = 1498; timeNextPopSample = 1488; popParams.size() = 1 We are SAMPLING at time 1488 *** Looping through 5.2. Iter = 1634 iteration 1634; minNextMutationTime = 1499; timeNextPopSample = 1489; popParams.size() = 1 We are SAMPLING at time 1489 *** Looping through 5.2. Iter = 1635 iteration 1635; minNextMutationTime = 1500; timeNextPopSample = 1490; popParams.size() = 1 We are SAMPLING at time 1490 *** Looping through 5.2. Iter = 1636 iteration 1636; minNextMutationTime = 1490.15; timeNextPopSample = 1491; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1637 iteration 1637; minNextMutationTime = 1490.23; timeNextPopSample = 1491; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1638 iteration 1638; minNextMutationTime = 1501; timeNextPopSample = 1491; popParams.size() = 3 We are SAMPLING at time 1491 *** Looping through 5.2. Iter = 1639 iteration 1639; minNextMutationTime = 1491.05; timeNextPopSample = 1492; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1640 iteration 1640; minNextMutationTime = 1491.6; timeNextPopSample = 1492; popParams.size() = 3 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000001000000; sp_id = 64) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 64) New popSize = 2 *** Looping through 5.2. Iter = 1641 iteration 1641; minNextMutationTime = 1502; timeNextPopSample = 1492; popParams.size() = 3 We are SAMPLING at time 1492 *** Looping through 5.2. Iter = 1642 iteration 1642; minNextMutationTime = 1503; timeNextPopSample = 1493; popParams.size() = 2 We are SAMPLING at time 1493 *** Looping through 5.2. Iter = 1643 iteration 1643; minNextMutationTime = 1504; timeNextPopSample = 1494; popParams.size() = 1 We are SAMPLING at time 1494 *** Looping through 5.2. Iter = 1644 iteration 1644; minNextMutationTime = 1494.09; timeNextPopSample = 1495; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1645 iteration 1645; minNextMutationTime = 1505; timeNextPopSample = 1495; popParams.size() = 2 We are SAMPLING at time 1495 *** Looping through 5.2. Iter = 1646 iteration 1646; minNextMutationTime = 1506; timeNextPopSample = 1496; popParams.size() = 1 We are SAMPLING at time 1496 *** Looping through 5.2. Iter = 1647 iteration 1647; minNextMutationTime = 1507; timeNextPopSample = 1497; popParams.size() = 1 We are SAMPLING at time 1497 *** Looping through 5.2. Iter = 1648 iteration 1648; minNextMutationTime = 1508; timeNextPopSample = 1498; popParams.size() = 1 We are SAMPLING at time 1498 *** Looping through 5.2. Iter = 1649 iteration 1649; minNextMutationTime = 1509; timeNextPopSample = 1499; popParams.size() = 1 We are SAMPLING at time 1499 *** Looping through 5.2. Iter = 1650 iteration 1650; minNextMutationTime = 1510; timeNextPopSample = 1500; popParams.size() = 1 We are SAMPLING at time 1500 *** Looping through 5.2. Iter = 1651 iteration 1651; minNextMutationTime = 1511; timeNextPopSample = 1501; popParams.size() = 1 We are SAMPLING at time 1501 *** Looping through 5.2. Iter = 1652 iteration 1652; minNextMutationTime = 1512; timeNextPopSample = 1502; popParams.size() = 1 We are SAMPLING at time 1502 *** Looping through 5.2. Iter = 1653 iteration 1653; minNextMutationTime = 1513; timeNextPopSample = 1503; popParams.size() = 1 We are SAMPLING at time 1503 *** Looping through 5.2. Iter = 1654 iteration 1654; minNextMutationTime = 1503.82; timeNextPopSample = 1504; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1655 iteration 1655; minNextMutationTime = 1514; timeNextPopSample = 1504; popParams.size() = 2 We are SAMPLING at time 1504 *** Looping through 5.2. Iter = 1656 iteration 1656; minNextMutationTime = 1515; timeNextPopSample = 1505; popParams.size() = 2 We are SAMPLING at time 1505 *** Looping through 5.2. Iter = 1657 iteration 1657; minNextMutationTime = 1516; timeNextPopSample = 1506; popParams.size() = 1 We are SAMPLING at time 1506 *** Looping through 5.2. Iter = 1658 iteration 1658; minNextMutationTime = 1517; timeNextPopSample = 1507; popParams.size() = 1 We are SAMPLING at time 1507 *** Looping through 5.2. Iter = 1659 iteration 1659; minNextMutationTime = 1518; timeNextPopSample = 1508; popParams.size() = 1 We are SAMPLING at time 1508 *** Looping through 5.2. Iter = 1660 iteration 1660; minNextMutationTime = 1519; timeNextPopSample = 1509; popParams.size() = 1 We are SAMPLING at time 1509 *** Looping through 5.2. Iter = 1661 iteration 1661; minNextMutationTime = 1520; timeNextPopSample = 1510; popParams.size() = 1 We are SAMPLING at time 1510 *** Looping through 5.2. Iter = 1662 iteration 1662; minNextMutationTime = 1521; timeNextPopSample = 1511; popParams.size() = 1 We are SAMPLING at time 1511 *** Looping through 5.2. Iter = 1663 iteration 1663; minNextMutationTime = 1522; timeNextPopSample = 1512; popParams.size() = 1 We are SAMPLING at time 1512 *** Looping through 5.2. Iter = 1664 iteration 1664; minNextMutationTime = 1523; timeNextPopSample = 1513; popParams.size() = 1 We are SAMPLING at time 1513 *** Looping through 5.2. Iter = 1665 iteration 1665; minNextMutationTime = 1524; timeNextPopSample = 1514; popParams.size() = 1 We are SAMPLING at time 1514 *** Looping through 5.2. Iter = 1666 iteration 1666; minNextMutationTime = 1525; timeNextPopSample = 1515; popParams.size() = 1 We are SAMPLING at time 1515 *** Looping through 5.2. Iter = 1667 iteration 1667; minNextMutationTime = 1526; timeNextPopSample = 1516; popParams.size() = 1 We are SAMPLING at time 1516 *** Looping through 5.2. Iter = 1668 iteration 1668; minNextMutationTime = 1516.52; timeNextPopSample = 1517; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1669 iteration 1669; minNextMutationTime = 1527; timeNextPopSample = 1517; popParams.size() = 2 We are SAMPLING at time 1517 *** Looping through 5.2. Iter = 1670 iteration 1670; minNextMutationTime = 1528; timeNextPopSample = 1518; popParams.size() = 2 We are SAMPLING at time 1518 *** Looping through 5.2. Iter = 1671 iteration 1671; minNextMutationTime = 1529; timeNextPopSample = 1519; popParams.size() = 2 We are SAMPLING at time 1519 *** Looping through 5.2. Iter = 1672 iteration 1672; minNextMutationTime = 1530; timeNextPopSample = 1520; popParams.size() = 2 We are SAMPLING at time 1520 *** Looping through 5.2. Iter = 1673 iteration 1673; minNextMutationTime = 1531; timeNextPopSample = 1521; popParams.size() = 2 We are SAMPLING at time 1521 *** Looping through 5.2. Iter = 1674 iteration 1674; minNextMutationTime = 1532; timeNextPopSample = 1522; popParams.size() = 2 We are SAMPLING at time 1522 *** Looping through 5.2. Iter = 1675 iteration 1675; minNextMutationTime = 1533; timeNextPopSample = 1523; popParams.size() = 2 We are SAMPLING at time 1523 *** Looping through 5.2. Iter = 1676 iteration 1676; minNextMutationTime = 1534; timeNextPopSample = 1524; popParams.size() = 2 We are SAMPLING at time 1524 *** Looping through 5.2. Iter = 1677 iteration 1677; minNextMutationTime = 1535; timeNextPopSample = 1525; popParams.size() = 2 We are SAMPLING at time 1525 *** Looping through 5.2. Iter = 1678 iteration 1678; minNextMutationTime = 1536; timeNextPopSample = 1526; popParams.size() = 2 We are SAMPLING at time 1526 *** Looping through 5.2. Iter = 1679 iteration 1679; minNextMutationTime = 1526.12; timeNextPopSample = 1527; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1680 iteration 1680; minNextMutationTime = 1537; timeNextPopSample = 1527; popParams.size() = 3 We are SAMPLING at time 1527 *** Looping through 5.2. Iter = 1681 iteration 1681; minNextMutationTime = 1538; timeNextPopSample = 1528; popParams.size() = 3 We are SAMPLING at time 1528 *** Looping through 5.2. Iter = 1682 iteration 1682; minNextMutationTime = 1539; timeNextPopSample = 1529; popParams.size() = 3 We are SAMPLING at time 1529 *** Looping through 5.2. Iter = 1683 iteration 1683; minNextMutationTime = 1540; timeNextPopSample = 1530; popParams.size() = 3 We are SAMPLING at time 1530 *** Looping through 5.2. Iter = 1684 iteration 1684; minNextMutationTime = 1541; timeNextPopSample = 1531; popParams.size() = 2 We are SAMPLING at time 1531 *** Looping through 5.2. Iter = 1685 iteration 1685; minNextMutationTime = 1542; timeNextPopSample = 1532; popParams.size() = 2 We are SAMPLING at time 1532 *** Looping through 5.2. Iter = 1686 iteration 1686; minNextMutationTime = 1543; timeNextPopSample = 1533; popParams.size() = 2 We are SAMPLING at time 1533 *** Looping through 5.2. Iter = 1687 iteration 1687; minNextMutationTime = 1544; timeNextPopSample = 1534; popParams.size() = 2 We are SAMPLING at time 1534 *** Looping through 5.2. Iter = 1688 iteration 1688; minNextMutationTime = 1545; timeNextPopSample = 1535; popParams.size() = 2 We are SAMPLING at time 1535 *** Looping through 5.2. Iter = 1689 iteration 1689; minNextMutationTime = 1546; timeNextPopSample = 1536; popParams.size() = 2 We are SAMPLING at time 1536 *** Looping through 5.2. Iter = 1690 iteration 1690; minNextMutationTime = 1547; timeNextPopSample = 1537; popParams.size() = 2 We are SAMPLING at time 1537 *** Looping through 5.2. Iter = 1691 iteration 1691; minNextMutationTime = 1548; timeNextPopSample = 1538; popParams.size() = 2 We are SAMPLING at time 1538 *** Looping through 5.2. Iter = 1692 iteration 1692; minNextMutationTime = 1549; timeNextPopSample = 1539; popParams.size() = 2 We are SAMPLING at time 1539 *** Looping through 5.2. Iter = 1693 iteration 1693; minNextMutationTime = 1550; timeNextPopSample = 1540; popParams.size() = 2 We are SAMPLING at time 1540 *** Looping through 5.2. Iter = 1694 iteration 1694; minNextMutationTime = 1551; timeNextPopSample = 1541; popParams.size() = 2 We are SAMPLING at time 1541 *** Looping through 5.2. Iter = 1695 iteration 1695; minNextMutationTime = 1552; timeNextPopSample = 1542; popParams.size() = 2 We are SAMPLING at time 1542 *** Looping through 5.2. Iter = 1696 iteration 1696; minNextMutationTime = 1553; timeNextPopSample = 1543; popParams.size() = 2 We are SAMPLING at time 1543 *** Looping through 5.2. Iter = 1697 iteration 1697; minNextMutationTime = 1543.3; timeNextPopSample = 1544; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000001000000; sp_id = 64) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 64) New popSize = 23 *** Looping through 5.2. Iter = 1698 iteration 1698; minNextMutationTime = 1554; timeNextPopSample = 1544; popParams.size() = 2 We are SAMPLING at time 1544 *** Looping through 5.2. Iter = 1699 iteration 1699; minNextMutationTime = 1555; timeNextPopSample = 1545; popParams.size() = 2 We are SAMPLING at time 1545 *** Looping through 5.2. Iter = 1700 iteration 1700; minNextMutationTime = 1556; timeNextPopSample = 1546; popParams.size() = 2 We are SAMPLING at time 1546 *** Looping through 5.2. Iter = 1701 iteration 1701; minNextMutationTime = 1557; timeNextPopSample = 1547; popParams.size() = 2 We are SAMPLING at time 1547 *** Looping through 5.2. Iter = 1702 iteration 1702; minNextMutationTime = 1558; timeNextPopSample = 1548; popParams.size() = 2 We are SAMPLING at time 1548 *** Looping through 5.2. Iter = 1703 iteration 1703; minNextMutationTime = 1559; timeNextPopSample = 1549; popParams.size() = 2 We are SAMPLING at time 1549 *** Looping through 5.2. Iter = 1704 iteration 1704; minNextMutationTime = 1560; timeNextPopSample = 1550; popParams.size() = 2 We are SAMPLING at time 1550 *** Looping through 5.2. Iter = 1705 iteration 1705; minNextMutationTime = 1561; timeNextPopSample = 1551; popParams.size() = 2 We are SAMPLING at time 1551 *** Looping through 5.2. Iter = 1706 iteration 1706; minNextMutationTime = 1562; timeNextPopSample = 1552; popParams.size() = 2 We are SAMPLING at time 1552 *** Looping through 5.2. Iter = 1707 iteration 1707; minNextMutationTime = 1563; timeNextPopSample = 1553; popParams.size() = 2 We are SAMPLING at time 1553 *** Looping through 5.2. Iter = 1708 iteration 1708; minNextMutationTime = 1564; timeNextPopSample = 1554; popParams.size() = 2 We are SAMPLING at time 1554 *** Looping through 5.2. Iter = 1709 iteration 1709; minNextMutationTime = 1565; timeNextPopSample = 1555; popParams.size() = 2 We are SAMPLING at time 1555 *** Looping through 5.2. Iter = 1710 iteration 1710; minNextMutationTime = 1566; timeNextPopSample = 1556; popParams.size() = 2 We are SAMPLING at time 1556 *** Looping through 5.2. Iter = 1711 iteration 1711; minNextMutationTime = 1556.18; timeNextPopSample = 1557; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1712 iteration 1712; minNextMutationTime = 1567; timeNextPopSample = 1557; popParams.size() = 3 We are SAMPLING at time 1557 *** Looping through 5.2. Iter = 1713 iteration 1713; minNextMutationTime = 1568; timeNextPopSample = 1558; popParams.size() = 2 We are SAMPLING at time 1558 *** Looping through 5.2. Iter = 1714 iteration 1714; minNextMutationTime = 1569; timeNextPopSample = 1559; popParams.size() = 2 We are SAMPLING at time 1559 *** Looping through 5.2. Iter = 1715 iteration 1715; minNextMutationTime = 1570; timeNextPopSample = 1560; popParams.size() = 2 We are SAMPLING at time 1560 *** Looping through 5.2. Iter = 1716 iteration 1716; minNextMutationTime = 1571; timeNextPopSample = 1561; popParams.size() = 1 We are SAMPLING at time 1561 *** Looping through 5.2. Iter = 1717 iteration 1717; minNextMutationTime = 1572; timeNextPopSample = 1562; popParams.size() = 1 We are SAMPLING at time 1562 *** Looping through 5.2. Iter = 1718 iteration 1718; minNextMutationTime = 1573; timeNextPopSample = 1563; popParams.size() = 1 We are SAMPLING at time 1563 *** Looping through 5.2. Iter = 1719 iteration 1719; minNextMutationTime = 1574; timeNextPopSample = 1564; popParams.size() = 1 We are SAMPLING at time 1564 *** Looping through 5.2. Iter = 1720 iteration 1720; minNextMutationTime = 1575; timeNextPopSample = 1565; popParams.size() = 1 We are SAMPLING at time 1565 *** Looping through 5.2. Iter = 1721 iteration 1721; minNextMutationTime = 1576; timeNextPopSample = 1566; popParams.size() = 1 We are SAMPLING at time 1566 *** Looping through 5.2. Iter = 1722 iteration 1722; minNextMutationTime = 1566.34; timeNextPopSample = 1567; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1723 iteration 1723; minNextMutationTime = 1577; timeNextPopSample = 1567; popParams.size() = 2 We are SAMPLING at time 1567 *** Looping through 5.2. Iter = 1724 iteration 1724; minNextMutationTime = 1578; timeNextPopSample = 1568; popParams.size() = 2 We are SAMPLING at time 1568 *** Looping through 5.2. Iter = 1725 iteration 1725; minNextMutationTime = 1579; timeNextPopSample = 1569; popParams.size() = 1 We are SAMPLING at time 1569 *** Looping through 5.2. Iter = 1726 iteration 1726; minNextMutationTime = 1580; timeNextPopSample = 1570; popParams.size() = 1 We are SAMPLING at time 1570 *** Looping through 5.2. Iter = 1727 iteration 1727; minNextMutationTime = 1570.49; timeNextPopSample = 1571; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1728 iteration 1728; minNextMutationTime = 1581; timeNextPopSample = 1571; popParams.size() = 2 We are SAMPLING at time 1571 *** Looping through 5.2. Iter = 1729 iteration 1729; minNextMutationTime = 1582; timeNextPopSample = 1572; popParams.size() = 2 We are SAMPLING at time 1572 *** Looping through 5.2. Iter = 1730 iteration 1730; minNextMutationTime = 1583; timeNextPopSample = 1573; popParams.size() = 2 We are SAMPLING at time 1573 *** Looping through 5.2. Iter = 1731 iteration 1731; minNextMutationTime = 1584; timeNextPopSample = 1574; popParams.size() = 1 We are SAMPLING at time 1574 *** Looping through 5.2. Iter = 1732 iteration 1732; minNextMutationTime = 1585; timeNextPopSample = 1575; popParams.size() = 1 We are SAMPLING at time 1575 *** Looping through 5.2. Iter = 1733 iteration 1733; minNextMutationTime = 1586; timeNextPopSample = 1576; popParams.size() = 1 We are SAMPLING at time 1576 *** Looping through 5.2. Iter = 1734 iteration 1734; minNextMutationTime = 1587; timeNextPopSample = 1577; popParams.size() = 1 We are SAMPLING at time 1577 *** Looping through 5.2. Iter = 1735 iteration 1735; minNextMutationTime = 1588; timeNextPopSample = 1578; popParams.size() = 1 We are SAMPLING at time 1578 *** Looping through 5.2. Iter = 1736 iteration 1736; minNextMutationTime = 1589; timeNextPopSample = 1579; popParams.size() = 1 We are SAMPLING at time 1579 *** Looping through 5.2. Iter = 1737 iteration 1737; minNextMutationTime = 1590; timeNextPopSample = 1580; popParams.size() = 1 We are SAMPLING at time 1580 *** Looping through 5.2. Iter = 1738 iteration 1738; minNextMutationTime = 1591; timeNextPopSample = 1581; popParams.size() = 1 We are SAMPLING at time 1581 *** Looping through 5.2. Iter = 1739 iteration 1739; minNextMutationTime = 1581.91; timeNextPopSample = 1582; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1740 iteration 1740; minNextMutationTime = 1592; timeNextPopSample = 1582; popParams.size() = 2 We are SAMPLING at time 1582 *** Looping through 5.2. Iter = 1741 iteration 1741; minNextMutationTime = 1593; timeNextPopSample = 1583; popParams.size() = 2 We are SAMPLING at time 1583 *** Looping through 5.2. Iter = 1742 iteration 1742; minNextMutationTime = 1594; timeNextPopSample = 1584; popParams.size() = 1 We are SAMPLING at time 1584 *** Looping through 5.2. Iter = 1743 iteration 1743; minNextMutationTime = 1595; timeNextPopSample = 1585; popParams.size() = 1 We are SAMPLING at time 1585 *** Looping through 5.2. Iter = 1744 iteration 1744; minNextMutationTime = 1596; timeNextPopSample = 1586; popParams.size() = 1 We are SAMPLING at time 1586 *** Looping through 5.2. Iter = 1745 iteration 1745; minNextMutationTime = 1597; timeNextPopSample = 1587; popParams.size() = 1 We are SAMPLING at time 1587 *** Looping through 5.2. Iter = 1746 iteration 1746; minNextMutationTime = 1598; timeNextPopSample = 1588; popParams.size() = 1 We are SAMPLING at time 1588 *** Looping through 5.2. Iter = 1747 iteration 1747; minNextMutationTime = 1599; timeNextPopSample = 1589; popParams.size() = 1 We are SAMPLING at time 1589 *** Looping through 5.2. Iter = 1748 iteration 1748; minNextMutationTime = 1600; timeNextPopSample = 1590; popParams.size() = 1 We are SAMPLING at time 1590 *** Looping through 5.2. Iter = 1749 iteration 1749; minNextMutationTime = 1601; timeNextPopSample = 1591; popParams.size() = 1 We are SAMPLING at time 1591 *** Looping through 5.2. Iter = 1750 iteration 1750; minNextMutationTime = 1602; timeNextPopSample = 1592; popParams.size() = 1 We are SAMPLING at time 1592 *** Looping through 5.2. Iter = 1751 iteration 1751; minNextMutationTime = 1603; timeNextPopSample = 1593; popParams.size() = 1 We are SAMPLING at time 1593 *** Looping through 5.2. Iter = 1752 iteration 1752; minNextMutationTime = 1604; timeNextPopSample = 1594; popParams.size() = 1 We are SAMPLING at time 1594 *** Looping through 5.2. Iter = 1753 iteration 1753; minNextMutationTime = 1605; timeNextPopSample = 1595; popParams.size() = 1 We are SAMPLING at time 1595 *** Looping through 5.2. Iter = 1754 iteration 1754; minNextMutationTime = 1595.51; timeNextPopSample = 1596; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1755 iteration 1755; minNextMutationTime = 1606; timeNextPopSample = 1596; popParams.size() = 2 We are SAMPLING at time 1596 *** Looping through 5.2. Iter = 1756 iteration 1756; minNextMutationTime = 1596.14; timeNextPopSample = 1597; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1757 iteration 1757; minNextMutationTime = 1607; timeNextPopSample = 1597; popParams.size() = 3 We are SAMPLING at time 1597 *** Looping through 5.2. Iter = 1758 iteration 1758; minNextMutationTime = 1608; timeNextPopSample = 1598; popParams.size() = 3 We are SAMPLING at time 1598 *** Looping through 5.2. Iter = 1759 iteration 1759; minNextMutationTime = 1609; timeNextPopSample = 1599; popParams.size() = 3 We are SAMPLING at time 1599 *** Looping through 5.2. Iter = 1760 iteration 1760; minNextMutationTime = 1610; timeNextPopSample = 1600; popParams.size() = 3 We are SAMPLING at time 1600 *** Looping through 5.2. Iter = 1761 iteration 1761; minNextMutationTime = 1611; timeNextPopSample = 1601; popParams.size() = 3 We are SAMPLING at time 1601 *** Looping through 5.2. Iter = 1762 iteration 1762; minNextMutationTime = 1612; timeNextPopSample = 1602; popParams.size() = 3 We are SAMPLING at time 1602 *** Looping through 5.2. Iter = 1763 iteration 1763; minNextMutationTime = 1613; timeNextPopSample = 1603; popParams.size() = 3 We are SAMPLING at time 1603 *** Looping through 5.2. Iter = 1764 iteration 1764; minNextMutationTime = 1614; timeNextPopSample = 1604; popParams.size() = 3 We are SAMPLING at time 1604 *** Looping through 5.2. Iter = 1765 iteration 1765; minNextMutationTime = 1615; timeNextPopSample = 1605; popParams.size() = 3 We are SAMPLING at time 1605 *** Looping through 5.2. Iter = 1766 iteration 1766; minNextMutationTime = 1616; timeNextPopSample = 1606; popParams.size() = 3 We are SAMPLING at time 1606 *** Looping through 5.2. Iter = 1767 iteration 1767; minNextMutationTime = 1617; timeNextPopSample = 1607; popParams.size() = 3 We are SAMPLING at time 1607 *** Looping through 5.2. Iter = 1768 iteration 1768; minNextMutationTime = 1618; timeNextPopSample = 1608; popParams.size() = 3 We are SAMPLING at time 1608 *** Looping through 5.2. Iter = 1769 iteration 1769; minNextMutationTime = 1619; timeNextPopSample = 1609; popParams.size() = 3 We are SAMPLING at time 1609 *** Looping through 5.2. Iter = 1770 iteration 1770; minNextMutationTime = 1620; timeNextPopSample = 1610; popParams.size() = 3 We are SAMPLING at time 1610 *** Looping through 5.2. Iter = 1771 iteration 1771; minNextMutationTime = 1621; timeNextPopSample = 1611; popParams.size() = 3 We are SAMPLING at time 1611 *** Looping through 5.2. Iter = 1772 iteration 1772; minNextMutationTime = 1622; timeNextPopSample = 1612; popParams.size() = 3 We are SAMPLING at time 1612 *** Looping through 5.2. Iter = 1773 iteration 1773; minNextMutationTime = 1623; timeNextPopSample = 1613; popParams.size() = 3 We are SAMPLING at time 1613 *** Looping through 5.2. Iter = 1774 iteration 1774; minNextMutationTime = 1624; timeNextPopSample = 1614; popParams.size() = 3 We are SAMPLING at time 1614 *** Looping through 5.2. Iter = 1775 iteration 1775; minNextMutationTime = 1625; timeNextPopSample = 1615; popParams.size() = 3 We are SAMPLING at time 1615 *** Looping through 5.2. Iter = 1776 iteration 1776; minNextMutationTime = 1626; timeNextPopSample = 1616; popParams.size() = 3 We are SAMPLING at time 1616 *** Looping through 5.2. Iter = 1777 iteration 1777; minNextMutationTime = 1627; timeNextPopSample = 1617; popParams.size() = 2 We are SAMPLING at time 1617 *** Looping through 5.2. Iter = 1778 iteration 1778; minNextMutationTime = 1628; timeNextPopSample = 1618; popParams.size() = 2 We are SAMPLING at time 1618 *** Looping through 5.2. Iter = 1779 iteration 1779; minNextMutationTime = 1618.64; timeNextPopSample = 1619; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1780 iteration 1780; minNextMutationTime = 1629; timeNextPopSample = 1619; popParams.size() = 3 We are SAMPLING at time 1619 *** Looping through 5.2. Iter = 1781 iteration 1781; minNextMutationTime = 1630; timeNextPopSample = 1620; popParams.size() = 3 We are SAMPLING at time 1620 *** Looping through 5.2. Iter = 1782 iteration 1782; minNextMutationTime = 1631; timeNextPopSample = 1621; popParams.size() = 2 We are SAMPLING at time 1621 *** Looping through 5.2. Iter = 1783 iteration 1783; minNextMutationTime = 1632; timeNextPopSample = 1622; popParams.size() = 2 We are SAMPLING at time 1622 *** Looping through 5.2. Iter = 1784 iteration 1784; minNextMutationTime = 1633; timeNextPopSample = 1623; popParams.size() = 2 We are SAMPLING at time 1623 *** Looping through 5.2. Iter = 1785 iteration 1785; minNextMutationTime = 1634; timeNextPopSample = 1624; popParams.size() = 2 We are SAMPLING at time 1624 *** Looping through 5.2. Iter = 1786 iteration 1786; minNextMutationTime = 1635; timeNextPopSample = 1625; popParams.size() = 2 We are SAMPLING at time 1625 *** Looping through 5.2. Iter = 1787 iteration 1787; minNextMutationTime = 1636; timeNextPopSample = 1626; popParams.size() = 2 We are SAMPLING at time 1626 *** Looping through 5.2. Iter = 1788 iteration 1788; minNextMutationTime = 1637; timeNextPopSample = 1627; popParams.size() = 2 We are SAMPLING at time 1627 *** Looping through 5.2. Iter = 1789 iteration 1789; minNextMutationTime = 1638; timeNextPopSample = 1628; popParams.size() = 2 We are SAMPLING at time 1628 *** Looping through 5.2. Iter = 1790 iteration 1790; minNextMutationTime = 1639; timeNextPopSample = 1629; popParams.size() = 2 We are SAMPLING at time 1629 *** Looping through 5.2. Iter = 1791 iteration 1791; minNextMutationTime = 1640; timeNextPopSample = 1630; popParams.size() = 2 We are SAMPLING at time 1630 *** Looping through 5.2. Iter = 1792 iteration 1792; minNextMutationTime = 1641; timeNextPopSample = 1631; popParams.size() = 2 We are SAMPLING at time 1631 *** Looping through 5.2. Iter = 1793 iteration 1793; minNextMutationTime = 1642; timeNextPopSample = 1632; popParams.size() = 2 We are SAMPLING at time 1632 *** Looping through 5.2. Iter = 1794 iteration 1794; minNextMutationTime = 1643; timeNextPopSample = 1633; popParams.size() = 2 We are SAMPLING at time 1633 *** Looping through 5.2. Iter = 1795 iteration 1795; minNextMutationTime = 1633.78; timeNextPopSample = 1634; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000000010; sp_id = 2) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 2) New popSize = 7 *** Looping through 5.2. Iter = 1796 iteration 1796; minNextMutationTime = 1644; timeNextPopSample = 1634; popParams.size() = 2 We are SAMPLING at time 1634 *** Looping through 5.2. Iter = 1797 iteration 1797; minNextMutationTime = 1645; timeNextPopSample = 1635; popParams.size() = 2 We are SAMPLING at time 1635 *** Looping through 5.2. Iter = 1798 iteration 1798; minNextMutationTime = 1646; timeNextPopSample = 1636; popParams.size() = 2 We are SAMPLING at time 1636 *** Looping through 5.2. Iter = 1799 iteration 1799; minNextMutationTime = 1647; timeNextPopSample = 1637; popParams.size() = 2 We are SAMPLING at time 1637 *** Looping through 5.2. Iter = 1800 iteration 1800; minNextMutationTime = 1648; timeNextPopSample = 1638; popParams.size() = 2 We are SAMPLING at time 1638 *** Looping through 5.2. Iter = 1801 iteration 1801; minNextMutationTime = 1649; timeNextPopSample = 1639; popParams.size() = 2 We are SAMPLING at time 1639 *** Looping through 5.2. Iter = 1802 iteration 1802; minNextMutationTime = 1639.12; timeNextPopSample = 1640; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1803 iteration 1803; minNextMutationTime = 1650; timeNextPopSample = 1640; popParams.size() = 2 We are SAMPLING at time 1640 *** Looping through 5.2. Iter = 1804 iteration 1804; minNextMutationTime = 1651; timeNextPopSample = 1641; popParams.size() = 1 We are SAMPLING at time 1641 *** Looping through 5.2. Iter = 1805 iteration 1805; minNextMutationTime = 1652; timeNextPopSample = 1642; popParams.size() = 1 We are SAMPLING at time 1642 *** Looping through 5.2. Iter = 1806 iteration 1806; minNextMutationTime = 1653; timeNextPopSample = 1643; popParams.size() = 1 We are SAMPLING at time 1643 *** Looping through 5.2. Iter = 1807 iteration 1807; minNextMutationTime = 1654; timeNextPopSample = 1644; popParams.size() = 1 We are SAMPLING at time 1644 *** Looping through 5.2. Iter = 1808 iteration 1808; minNextMutationTime = 1655; timeNextPopSample = 1645; popParams.size() = 1 We are SAMPLING at time 1645 *** Looping through 5.2. Iter = 1809 iteration 1809; minNextMutationTime = 1656; timeNextPopSample = 1646; popParams.size() = 1 We are SAMPLING at time 1646 *** Looping through 5.2. Iter = 1810 iteration 1810; minNextMutationTime = 1646.25; timeNextPopSample = 1647; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1811 iteration 1811; minNextMutationTime = 1657; timeNextPopSample = 1647; popParams.size() = 2 We are SAMPLING at time 1647 *** Looping through 5.2. Iter = 1812 iteration 1812; minNextMutationTime = 1658; timeNextPopSample = 1648; popParams.size() = 1 We are SAMPLING at time 1648 *** Looping through 5.2. Iter = 1813 iteration 1813; minNextMutationTime = 1659; timeNextPopSample = 1649; popParams.size() = 1 We are SAMPLING at time 1649 *** Looping through 5.2. Iter = 1814 iteration 1814; minNextMutationTime = 1649.62; timeNextPopSample = 1650; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1815 iteration 1815; minNextMutationTime = 1660; timeNextPopSample = 1650; popParams.size() = 2 We are SAMPLING at time 1650 *** Looping through 5.2. Iter = 1816 iteration 1816; minNextMutationTime = 1650.49; timeNextPopSample = 1651; popParams.size() = 2 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000000010; sp_id = 2) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 2) New popSize = 2 *** Looping through 5.2. Iter = 1817 iteration 1817; minNextMutationTime = 1661; timeNextPopSample = 1651; popParams.size() = 2 We are SAMPLING at time 1651 *** Looping through 5.2. Iter = 1818 iteration 1818; minNextMutationTime = 1662; timeNextPopSample = 1652; popParams.size() = 2 We are SAMPLING at time 1652 *** Looping through 5.2. Iter = 1819 iteration 1819; minNextMutationTime = 1663; timeNextPopSample = 1653; popParams.size() = 2 We are SAMPLING at time 1653 *** Looping through 5.2. Iter = 1820 iteration 1820; minNextMutationTime = 1664; timeNextPopSample = 1654; popParams.size() = 2 We are SAMPLING at time 1654 *** Looping through 5.2. Iter = 1821 iteration 1821; minNextMutationTime = 1665; timeNextPopSample = 1655; popParams.size() = 2 We are SAMPLING at time 1655 *** Looping through 5.2. Iter = 1822 iteration 1822; minNextMutationTime = 1666; timeNextPopSample = 1656; popParams.size() = 2 We are SAMPLING at time 1656 *** Looping through 5.2. Iter = 1823 iteration 1823; minNextMutationTime = 1667; timeNextPopSample = 1657; popParams.size() = 2 We are SAMPLING at time 1657 *** Looping through 5.2. Iter = 1824 iteration 1824; minNextMutationTime = 1668; timeNextPopSample = 1658; popParams.size() = 2 We are SAMPLING at time 1658 *** Looping through 5.2. Iter = 1825 iteration 1825; minNextMutationTime = 1658.36; timeNextPopSample = 1659; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1826 iteration 1826; minNextMutationTime = 1669; timeNextPopSample = 1659; popParams.size() = 2 We are SAMPLING at time 1659 *** Looping through 5.2. Iter = 1827 iteration 1827; minNextMutationTime = 1670; timeNextPopSample = 1660; popParams.size() = 1 We are SAMPLING at time 1660 *** Looping through 5.2. Iter = 1828 iteration 1828; minNextMutationTime = 1671; timeNextPopSample = 1661; popParams.size() = 1 We are SAMPLING at time 1661 *** Looping through 5.2. Iter = 1829 iteration 1829; minNextMutationTime = 1672; timeNextPopSample = 1662; popParams.size() = 1 We are SAMPLING at time 1662 *** Looping through 5.2. Iter = 1830 iteration 1830; minNextMutationTime = 1662.41; timeNextPopSample = 1663; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1831 iteration 1831; minNextMutationTime = 1673; timeNextPopSample = 1663; popParams.size() = 2 We are SAMPLING at time 1663 *** Looping through 5.2. Iter = 1832 iteration 1832; minNextMutationTime = 1674; timeNextPopSample = 1664; popParams.size() = 1 We are SAMPLING at time 1664 *** Looping through 5.2. Iter = 1833 iteration 1833; minNextMutationTime = 1675; timeNextPopSample = 1665; popParams.size() = 1 We are SAMPLING at time 1665 *** Looping through 5.2. Iter = 1834 iteration 1834; minNextMutationTime = 1676; timeNextPopSample = 1666; popParams.size() = 1 We are SAMPLING at time 1666 *** Looping through 5.2. Iter = 1835 iteration 1835; minNextMutationTime = 1677; timeNextPopSample = 1667; popParams.size() = 1 We are SAMPLING at time 1667 *** Looping through 5.2. Iter = 1836 iteration 1836; minNextMutationTime = 1678; timeNextPopSample = 1668; popParams.size() = 1 We are SAMPLING at time 1668 *** Looping through 5.2. Iter = 1837 iteration 1837; minNextMutationTime = 1679; timeNextPopSample = 1669; popParams.size() = 1 We are SAMPLING at time 1669 *** Looping through 5.2. Iter = 1838 iteration 1838; minNextMutationTime = 1680; timeNextPopSample = 1670; popParams.size() = 1 We are SAMPLING at time 1670 *** Looping through 5.2. Iter = 1839 iteration 1839; minNextMutationTime = 1681; timeNextPopSample = 1671; popParams.size() = 1 We are SAMPLING at time 1671 *** Looping through 5.2. Iter = 1840 iteration 1840; minNextMutationTime = 1682; timeNextPopSample = 1672; popParams.size() = 1 We are SAMPLING at time 1672 *** Looping through 5.2. Iter = 1841 iteration 1841; minNextMutationTime = 1683; timeNextPopSample = 1673; popParams.size() = 1 We are SAMPLING at time 1673 *** Looping through 5.2. Iter = 1842 iteration 1842; minNextMutationTime = 1684; timeNextPopSample = 1674; popParams.size() = 1 We are SAMPLING at time 1674 *** Looping through 5.2. Iter = 1843 iteration 1843; minNextMutationTime = 1685; timeNextPopSample = 1675; popParams.size() = 1 We are SAMPLING at time 1675 *** Looping through 5.2. Iter = 1844 iteration 1844; minNextMutationTime = 1675.57; timeNextPopSample = 1676; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1845 iteration 1845; minNextMutationTime = 1686; timeNextPopSample = 1676; popParams.size() = 2 We are SAMPLING at time 1676 *** Looping through 5.2. Iter = 1846 iteration 1846; minNextMutationTime = 1687; timeNextPopSample = 1677; popParams.size() = 1 We are SAMPLING at time 1677 *** Looping through 5.2. Iter = 1847 iteration 1847; minNextMutationTime = 1688; timeNextPopSample = 1678; popParams.size() = 1 We are SAMPLING at time 1678 *** Looping through 5.2. Iter = 1848 iteration 1848; minNextMutationTime = 1689; timeNextPopSample = 1679; popParams.size() = 1 We are SAMPLING at time 1679 *** Looping through 5.2. Iter = 1849 iteration 1849; minNextMutationTime = 1679.28; timeNextPopSample = 1680; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1850 iteration 1850; minNextMutationTime = 1690; timeNextPopSample = 1680; popParams.size() = 2 We are SAMPLING at time 1680 *** Looping through 5.2. Iter = 1851 iteration 1851; minNextMutationTime = 1691; timeNextPopSample = 1681; popParams.size() = 1 We are SAMPLING at time 1681 *** Looping through 5.2. Iter = 1852 iteration 1852; minNextMutationTime = 1692; timeNextPopSample = 1682; popParams.size() = 1 We are SAMPLING at time 1682 *** Looping through 5.2. Iter = 1853 iteration 1853; minNextMutationTime = 1693; timeNextPopSample = 1683; popParams.size() = 1 We are SAMPLING at time 1683 *** Looping through 5.2. Iter = 1854 iteration 1854; minNextMutationTime = 1694; timeNextPopSample = 1684; popParams.size() = 1 We are SAMPLING at time 1684 *** Looping through 5.2. Iter = 1855 iteration 1855; minNextMutationTime = 1695; timeNextPopSample = 1685; popParams.size() = 1 We are SAMPLING at time 1685 *** Looping through 5.2. Iter = 1856 iteration 1856; minNextMutationTime = 1696; timeNextPopSample = 1686; popParams.size() = 1 We are SAMPLING at time 1686 *** Looping through 5.2. Iter = 1857 iteration 1857; minNextMutationTime = 1697; timeNextPopSample = 1687; popParams.size() = 1 We are SAMPLING at time 1687 *** Looping through 5.2. Iter = 1858 iteration 1858; minNextMutationTime = 1698; timeNextPopSample = 1688; popParams.size() = 1 We are SAMPLING at time 1688 *** Looping through 5.2. Iter = 1859 iteration 1859; minNextMutationTime = 1699; timeNextPopSample = 1689; popParams.size() = 1 We are SAMPLING at time 1689 *** Looping through 5.2. Iter = 1860 iteration 1860; minNextMutationTime = 1700; timeNextPopSample = 1690; popParams.size() = 1 We are SAMPLING at time 1690 *** Looping through 5.2. Iter = 1861 iteration 1861; minNextMutationTime = 1701; timeNextPopSample = 1691; popParams.size() = 1 We are SAMPLING at time 1691 *** Looping through 5.2. Iter = 1862 iteration 1862; minNextMutationTime = 1702; timeNextPopSample = 1692; popParams.size() = 1 We are SAMPLING at time 1692 *** Looping through 5.2. Iter = 1863 iteration 1863; minNextMutationTime = 1703; timeNextPopSample = 1693; popParams.size() = 1 We are SAMPLING at time 1693 *** Looping through 5.2. Iter = 1864 iteration 1864; minNextMutationTime = 1704; timeNextPopSample = 1694; popParams.size() = 1 We are SAMPLING at time 1694 *** Looping through 5.2. Iter = 1865 iteration 1865; minNextMutationTime = 1705; timeNextPopSample = 1695; popParams.size() = 1 We are SAMPLING at time 1695 *** Looping through 5.2. Iter = 1866 iteration 1866; minNextMutationTime = 1706; timeNextPopSample = 1696; popParams.size() = 1 We are SAMPLING at time 1696 *** Looping through 5.2. Iter = 1867 iteration 1867; minNextMutationTime = 1707; timeNextPopSample = 1697; popParams.size() = 1 We are SAMPLING at time 1697 *** Looping through 5.2. Iter = 1868 iteration 1868; minNextMutationTime = 1708; timeNextPopSample = 1698; popParams.size() = 1 We are SAMPLING at time 1698 *** Looping through 5.2. Iter = 1869 iteration 1869; minNextMutationTime = 1709; timeNextPopSample = 1699; popParams.size() = 1 We are SAMPLING at time 1699 *** Looping through 5.2. Iter = 1870 iteration 1870; minNextMutationTime = 1710; timeNextPopSample = 1700; popParams.size() = 1 We are SAMPLING at time 1700 *** Looping through 5.2. Iter = 1871 iteration 1871; minNextMutationTime = 1711; timeNextPopSample = 1701; popParams.size() = 1 We are SAMPLING at time 1701 *** Looping through 5.2. Iter = 1872 iteration 1872; minNextMutationTime = 1712; timeNextPopSample = 1702; popParams.size() = 1 We are SAMPLING at time 1702 *** Looping through 5.2. Iter = 1873 iteration 1873; minNextMutationTime = 1713; timeNextPopSample = 1703; popParams.size() = 1 We are SAMPLING at time 1703 *** Looping through 5.2. Iter = 1874 iteration 1874; minNextMutationTime = 1714; timeNextPopSample = 1704; popParams.size() = 1 We are SAMPLING at time 1704 *** Looping through 5.2. Iter = 1875 iteration 1875; minNextMutationTime = 1715; timeNextPopSample = 1705; popParams.size() = 1 We are SAMPLING at time 1705 *** Looping through 5.2. Iter = 1876 iteration 1876; minNextMutationTime = 1716; timeNextPopSample = 1706; popParams.size() = 1 We are SAMPLING at time 1706 *** Looping through 5.2. Iter = 1877 iteration 1877; minNextMutationTime = 1717; timeNextPopSample = 1707; popParams.size() = 1 We are SAMPLING at time 1707 *** Looping through 5.2. Iter = 1878 iteration 1878; minNextMutationTime = 1718; timeNextPopSample = 1708; popParams.size() = 1 We are SAMPLING at time 1708 *** Looping through 5.2. Iter = 1879 iteration 1879; minNextMutationTime = 1719; timeNextPopSample = 1709; popParams.size() = 1 We are SAMPLING at time 1709 *** Looping through 5.2. Iter = 1880 iteration 1880; minNextMutationTime = 1720; timeNextPopSample = 1710; popParams.size() = 1 We are SAMPLING at time 1710 *** Looping through 5.2. Iter = 1881 iteration 1881; minNextMutationTime = 1721; timeNextPopSample = 1711; popParams.size() = 1 We are SAMPLING at time 1711 *** Looping through 5.2. Iter = 1882 iteration 1882; minNextMutationTime = 1711.77; timeNextPopSample = 1712; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1883 iteration 1883; minNextMutationTime = 1722; timeNextPopSample = 1712; popParams.size() = 2 We are SAMPLING at time 1712 *** Looping through 5.2. Iter = 1884 iteration 1884; minNextMutationTime = 1723; timeNextPopSample = 1713; popParams.size() = 1 We are SAMPLING at time 1713 *** Looping through 5.2. Iter = 1885 iteration 1885; minNextMutationTime = 1724; timeNextPopSample = 1714; popParams.size() = 1 We are SAMPLING at time 1714 *** Looping through 5.2. Iter = 1886 iteration 1886; minNextMutationTime = 1725; timeNextPopSample = 1715; popParams.size() = 1 We are SAMPLING at time 1715 *** Looping through 5.2. Iter = 1887 iteration 1887; minNextMutationTime = 1726; timeNextPopSample = 1716; popParams.size() = 1 We are SAMPLING at time 1716 *** Looping through 5.2. Iter = 1888 iteration 1888; minNextMutationTime = 1727; timeNextPopSample = 1717; popParams.size() = 1 We are SAMPLING at time 1717 *** Looping through 5.2. Iter = 1889 iteration 1889; minNextMutationTime = 1728; timeNextPopSample = 1718; popParams.size() = 1 We are SAMPLING at time 1718 *** Looping through 5.2. Iter = 1890 iteration 1890; minNextMutationTime = 1729; timeNextPopSample = 1719; popParams.size() = 1 We are SAMPLING at time 1719 *** Looping through 5.2. Iter = 1891 iteration 1891; minNextMutationTime = 1730; timeNextPopSample = 1720; popParams.size() = 1 We are SAMPLING at time 1720 *** Looping through 5.2. Iter = 1892 iteration 1892; minNextMutationTime = 1731; timeNextPopSample = 1721; popParams.size() = 1 We are SAMPLING at time 1721 *** Looping through 5.2. Iter = 1893 iteration 1893; minNextMutationTime = 1732; timeNextPopSample = 1722; popParams.size() = 1 We are SAMPLING at time 1722 *** Looping through 5.2. Iter = 1894 iteration 1894; minNextMutationTime = 1733; timeNextPopSample = 1723; popParams.size() = 1 We are SAMPLING at time 1723 *** Looping through 5.2. Iter = 1895 iteration 1895; minNextMutationTime = 1734; timeNextPopSample = 1724; popParams.size() = 1 We are SAMPLING at time 1724 *** Looping through 5.2. Iter = 1896 iteration 1896; minNextMutationTime = 1735; timeNextPopSample = 1725; popParams.size() = 1 We are SAMPLING at time 1725 *** Looping through 5.2. Iter = 1897 iteration 1897; minNextMutationTime = 1736; timeNextPopSample = 1726; popParams.size() = 1 We are SAMPLING at time 1726 *** Looping through 5.2. Iter = 1898 iteration 1898; minNextMutationTime = 1737; timeNextPopSample = 1727; popParams.size() = 1 We are SAMPLING at time 1727 *** Looping through 5.2. Iter = 1899 iteration 1899; minNextMutationTime = 1738; timeNextPopSample = 1728; popParams.size() = 1 We are SAMPLING at time 1728 *** Looping through 5.2. Iter = 1900 iteration 1900; minNextMutationTime = 1739; timeNextPopSample = 1729; popParams.size() = 1 We are SAMPLING at time 1729 *** Looping through 5.2. Iter = 1901 iteration 1901; minNextMutationTime = 1729.24; timeNextPopSample = 1730; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1902 iteration 1902; minNextMutationTime = 1740; timeNextPopSample = 1730; popParams.size() = 2 We are SAMPLING at time 1730 *** Looping through 5.2. Iter = 1903 iteration 1903; minNextMutationTime = 1741; timeNextPopSample = 1731; popParams.size() = 2 We are SAMPLING at time 1731 *** Looping through 5.2. Iter = 1904 iteration 1904; minNextMutationTime = 1742; timeNextPopSample = 1732; popParams.size() = 1 We are SAMPLING at time 1732 *** Looping through 5.2. Iter = 1905 iteration 1905; minNextMutationTime = 1743; timeNextPopSample = 1733; popParams.size() = 1 We are SAMPLING at time 1733 *** Looping through 5.2. Iter = 1906 iteration 1906; minNextMutationTime = 1733.34; timeNextPopSample = 1734; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1907 iteration 1907; minNextMutationTime = 1744; timeNextPopSample = 1734; popParams.size() = 2 We are SAMPLING at time 1734 *** Looping through 5.2. Iter = 1908 iteration 1908; minNextMutationTime = 1745; timeNextPopSample = 1735; popParams.size() = 2 We are SAMPLING at time 1735 *** Looping through 5.2. Iter = 1909 iteration 1909; minNextMutationTime = 1746; timeNextPopSample = 1736; popParams.size() = 1 We are SAMPLING at time 1736 *** Looping through 5.2. Iter = 1910 iteration 1910; minNextMutationTime = 1747; timeNextPopSample = 1737; popParams.size() = 1 We are SAMPLING at time 1737 *** Looping through 5.2. Iter = 1911 iteration 1911; minNextMutationTime = 1748; timeNextPopSample = 1738; popParams.size() = 1 We are SAMPLING at time 1738 *** Looping through 5.2. Iter = 1912 iteration 1912; minNextMutationTime = 1749; timeNextPopSample = 1739; popParams.size() = 1 We are SAMPLING at time 1739 *** Looping through 5.2. Iter = 1913 iteration 1913; minNextMutationTime = 1750; timeNextPopSample = 1740; popParams.size() = 1 We are SAMPLING at time 1740 *** Looping through 5.2. Iter = 1914 iteration 1914; minNextMutationTime = 1740.19; timeNextPopSample = 1741; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1915 iteration 1915; minNextMutationTime = 1751; timeNextPopSample = 1741; popParams.size() = 2 We are SAMPLING at time 1741 *** Looping through 5.2. Iter = 1916 iteration 1916; minNextMutationTime = 1752; timeNextPopSample = 1742; popParams.size() = 1 We are SAMPLING at time 1742 *** Looping through 5.2. Iter = 1917 iteration 1917; minNextMutationTime = 1753; timeNextPopSample = 1743; popParams.size() = 1 We are SAMPLING at time 1743 *** Looping through 5.2. Iter = 1918 iteration 1918; minNextMutationTime = 1754; timeNextPopSample = 1744; popParams.size() = 1 We are SAMPLING at time 1744 *** Looping through 5.2. Iter = 1919 iteration 1919; minNextMutationTime = 1755; timeNextPopSample = 1745; popParams.size() = 1 We are SAMPLING at time 1745 *** Looping through 5.2. Iter = 1920 iteration 1920; minNextMutationTime = 1756; timeNextPopSample = 1746; popParams.size() = 1 We are SAMPLING at time 1746 *** Looping through 5.2. Iter = 1921 iteration 1921; minNextMutationTime = 1757; timeNextPopSample = 1747; popParams.size() = 1 We are SAMPLING at time 1747 *** Looping through 5.2. Iter = 1922 iteration 1922; minNextMutationTime = 1747.69; timeNextPopSample = 1748; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1923 iteration 1923; minNextMutationTime = 1758; timeNextPopSample = 1748; popParams.size() = 2 We are SAMPLING at time 1748 *** Looping through 5.2. Iter = 1924 iteration 1924; minNextMutationTime = 1759; timeNextPopSample = 1749; popParams.size() = 2 We are SAMPLING at time 1749 *** Looping through 5.2. Iter = 1925 iteration 1925; minNextMutationTime = 1760; timeNextPopSample = 1750; popParams.size() = 2 We are SAMPLING at time 1750 *** Looping through 5.2. Iter = 1926 iteration 1926; minNextMutationTime = 1761; timeNextPopSample = 1751; popParams.size() = 2 We are SAMPLING at time 1751 *** Looping through 5.2. Iter = 1927 iteration 1927; minNextMutationTime = 1762; timeNextPopSample = 1752; popParams.size() = 1 We are SAMPLING at time 1752 *** Looping through 5.2. Iter = 1928 iteration 1928; minNextMutationTime = 1763; timeNextPopSample = 1753; popParams.size() = 1 We are SAMPLING at time 1753 *** Looping through 5.2. Iter = 1929 iteration 1929; minNextMutationTime = 1764; timeNextPopSample = 1754; popParams.size() = 1 We are SAMPLING at time 1754 *** Looping through 5.2. Iter = 1930 iteration 1930; minNextMutationTime = 1765; timeNextPopSample = 1755; popParams.size() = 1 We are SAMPLING at time 1755 *** Looping through 5.2. Iter = 1931 iteration 1931; minNextMutationTime = 1766; timeNextPopSample = 1756; popParams.size() = 1 We are SAMPLING at time 1756 *** Looping through 5.2. Iter = 1932 iteration 1932; minNextMutationTime = 1767; timeNextPopSample = 1757; popParams.size() = 1 We are SAMPLING at time 1757 *** Looping through 5.2. Iter = 1933 iteration 1933; minNextMutationTime = 1768; timeNextPopSample = 1758; popParams.size() = 1 We are SAMPLING at time 1758 *** Looping through 5.2. Iter = 1934 iteration 1934; minNextMutationTime = 1769; timeNextPopSample = 1759; popParams.size() = 1 We are SAMPLING at time 1759 *** Looping through 5.2. Iter = 1935 iteration 1935; minNextMutationTime = 1770; timeNextPopSample = 1760; popParams.size() = 1 We are SAMPLING at time 1760 *** Looping through 5.2. Iter = 1936 iteration 1936; minNextMutationTime = 1771; timeNextPopSample = 1761; popParams.size() = 1 We are SAMPLING at time 1761 *** Looping through 5.2. Iter = 1937 iteration 1937; minNextMutationTime = 1761.31; timeNextPopSample = 1762; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1938 iteration 1938; minNextMutationTime = 1772; timeNextPopSample = 1762; popParams.size() = 2 We are SAMPLING at time 1762 *** Looping through 5.2. Iter = 1939 iteration 1939; minNextMutationTime = 1773; timeNextPopSample = 1763; popParams.size() = 2 We are SAMPLING at time 1763 *** Looping through 5.2. Iter = 1940 iteration 1940; minNextMutationTime = 1774; timeNextPopSample = 1764; popParams.size() = 1 We are SAMPLING at time 1764 *** Looping through 5.2. Iter = 1941 iteration 1941; minNextMutationTime = 1775; timeNextPopSample = 1765; popParams.size() = 1 We are SAMPLING at time 1765 *** Looping through 5.2. Iter = 1942 iteration 1942; minNextMutationTime = 1776; timeNextPopSample = 1766; popParams.size() = 1 We are SAMPLING at time 1766 *** Looping through 5.2. Iter = 1943 iteration 1943; minNextMutationTime = 1777; timeNextPopSample = 1767; popParams.size() = 1 We are SAMPLING at time 1767 *** Looping through 5.2. Iter = 1944 iteration 1944; minNextMutationTime = 1778; timeNextPopSample = 1768; popParams.size() = 1 We are SAMPLING at time 1768 *** Looping through 5.2. Iter = 1945 iteration 1945; minNextMutationTime = 1779; timeNextPopSample = 1769; popParams.size() = 1 We are SAMPLING at time 1769 *** Looping through 5.2. Iter = 1946 iteration 1946; minNextMutationTime = 1780; timeNextPopSample = 1770; popParams.size() = 1 We are SAMPLING at time 1770 *** Looping through 5.2. Iter = 1947 iteration 1947; minNextMutationTime = 1781; timeNextPopSample = 1771; popParams.size() = 1 We are SAMPLING at time 1771 *** Looping through 5.2. Iter = 1948 iteration 1948; minNextMutationTime = 1782; timeNextPopSample = 1772; popParams.size() = 1 We are SAMPLING at time 1772 *** Looping through 5.2. Iter = 1949 iteration 1949; minNextMutationTime = 1783; timeNextPopSample = 1773; popParams.size() = 1 We are SAMPLING at time 1773 *** Looping through 5.2. Iter = 1950 iteration 1950; minNextMutationTime = 1784; timeNextPopSample = 1774; popParams.size() = 1 We are SAMPLING at time 1774 *** Looping through 5.2. Iter = 1951 iteration 1951; minNextMutationTime = 1785; timeNextPopSample = 1775; popParams.size() = 1 We are SAMPLING at time 1775 *** Looping through 5.2. Iter = 1952 iteration 1952; minNextMutationTime = 1786; timeNextPopSample = 1776; popParams.size() = 1 We are SAMPLING at time 1776 *** Looping through 5.2. Iter = 1953 iteration 1953; minNextMutationTime = 1787; timeNextPopSample = 1777; popParams.size() = 1 We are SAMPLING at time 1777 *** Looping through 5.2. Iter = 1954 iteration 1954; minNextMutationTime = 1788; timeNextPopSample = 1778; popParams.size() = 1 We are SAMPLING at time 1778 *** Looping through 5.2. Iter = 1955 iteration 1955; minNextMutationTime = 1778.55; timeNextPopSample = 1779; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1956 iteration 1956; minNextMutationTime = 1789; timeNextPopSample = 1779; popParams.size() = 2 We are SAMPLING at time 1779 *** Looping through 5.2. Iter = 1957 iteration 1957; minNextMutationTime = 1790; timeNextPopSample = 1780; popParams.size() = 2 We are SAMPLING at time 1780 *** Looping through 5.2. Iter = 1958 iteration 1958; minNextMutationTime = 1791; timeNextPopSample = 1781; popParams.size() = 1 We are SAMPLING at time 1781 *** Looping through 5.2. Iter = 1959 iteration 1959; minNextMutationTime = 1792; timeNextPopSample = 1782; popParams.size() = 1 We are SAMPLING at time 1782 *** Looping through 5.2. Iter = 1960 iteration 1960; minNextMutationTime = 1782.76; timeNextPopSample = 1783; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1961 iteration 1961; minNextMutationTime = 1793; timeNextPopSample = 1783; popParams.size() = 2 We are SAMPLING at time 1783 *** Looping through 5.2. Iter = 1962 iteration 1962; minNextMutationTime = 1783.67; timeNextPopSample = 1784; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1963 iteration 1963; minNextMutationTime = 1794; timeNextPopSample = 1784; popParams.size() = 3 We are SAMPLING at time 1784 *** Looping through 5.2. Iter = 1964 iteration 1964; minNextMutationTime = 1795; timeNextPopSample = 1785; popParams.size() = 2 We are SAMPLING at time 1785 *** Looping through 5.2. Iter = 1965 iteration 1965; minNextMutationTime = 1796; timeNextPopSample = 1786; popParams.size() = 2 We are SAMPLING at time 1786 *** Looping through 5.2. Iter = 1966 iteration 1966; minNextMutationTime = 1797; timeNextPopSample = 1787; popParams.size() = 1 We are SAMPLING at time 1787 *** Looping through 5.2. Iter = 1967 iteration 1967; minNextMutationTime = 1798; timeNextPopSample = 1788; popParams.size() = 1 We are SAMPLING at time 1788 *** Looping through 5.2. Iter = 1968 iteration 1968; minNextMutationTime = 1799; timeNextPopSample = 1789; popParams.size() = 1 We are SAMPLING at time 1789 *** Looping through 5.2. Iter = 1969 iteration 1969; minNextMutationTime = 1800; timeNextPopSample = 1790; popParams.size() = 1 We are SAMPLING at time 1790 *** Looping through 5.2. Iter = 1970 iteration 1970; minNextMutationTime = 1790.72; timeNextPopSample = 1791; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1971 iteration 1971; minNextMutationTime = 1801; timeNextPopSample = 1791; popParams.size() = 2 We are SAMPLING at time 1791 *** Looping through 5.2. Iter = 1972 iteration 1972; minNextMutationTime = 1802; timeNextPopSample = 1792; popParams.size() = 2 We are SAMPLING at time 1792 *** Looping through 5.2. Iter = 1973 iteration 1973; minNextMutationTime = 1803; timeNextPopSample = 1793; popParams.size() = 2 We are SAMPLING at time 1793 *** Looping through 5.2. Iter = 1974 iteration 1974; minNextMutationTime = 1804; timeNextPopSample = 1794; popParams.size() = 2 We are SAMPLING at time 1794 *** Looping through 5.2. Iter = 1975 iteration 1975; minNextMutationTime = 1805; timeNextPopSample = 1795; popParams.size() = 2 We are SAMPLING at time 1795 *** Looping through 5.2. Iter = 1976 iteration 1976; minNextMutationTime = 1806; timeNextPopSample = 1796; popParams.size() = 2 We are SAMPLING at time 1796 *** Looping through 5.2. Iter = 1977 iteration 1977; minNextMutationTime = 1807; timeNextPopSample = 1797; popParams.size() = 2 We are SAMPLING at time 1797 *** Looping through 5.2. Iter = 1978 iteration 1978; minNextMutationTime = 1808; timeNextPopSample = 1798; popParams.size() = 2 We are SAMPLING at time 1798 *** Looping through 5.2. Iter = 1979 iteration 1979; minNextMutationTime = 1798.59; timeNextPopSample = 1799; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1980 iteration 1980; minNextMutationTime = 1798.85; timeNextPopSample = 1799; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 1981 iteration 1981; minNextMutationTime = 1809; timeNextPopSample = 1799; popParams.size() = 3 We are SAMPLING at time 1799 *** Looping through 5.2. Iter = 1982 iteration 1982; minNextMutationTime = 1810; timeNextPopSample = 1800; popParams.size() = 2 We are SAMPLING at time 1800 *** Looping through 5.2. Iter = 1983 iteration 1983; minNextMutationTime = 1811; timeNextPopSample = 1801; popParams.size() = 1 We are SAMPLING at time 1801 *** Looping through 5.2. Iter = 1984 iteration 1984; minNextMutationTime = 1812; timeNextPopSample = 1802; popParams.size() = 1 We are SAMPLING at time 1802 *** Looping through 5.2. Iter = 1985 iteration 1985; minNextMutationTime = 1813; timeNextPopSample = 1803; popParams.size() = 1 We are SAMPLING at time 1803 *** Looping through 5.2. Iter = 1986 iteration 1986; minNextMutationTime = 1814; timeNextPopSample = 1804; popParams.size() = 1 We are SAMPLING at time 1804 *** Looping through 5.2. Iter = 1987 iteration 1987; minNextMutationTime = 1815; timeNextPopSample = 1805; popParams.size() = 1 We are SAMPLING at time 1805 *** Looping through 5.2. Iter = 1988 iteration 1988; minNextMutationTime = 1816; timeNextPopSample = 1806; popParams.size() = 1 We are SAMPLING at time 1806 *** Looping through 5.2. Iter = 1989 iteration 1989; minNextMutationTime = 1817; timeNextPopSample = 1807; popParams.size() = 1 We are SAMPLING at time 1807 *** Looping through 5.2. Iter = 1990 iteration 1990; minNextMutationTime = 1818; timeNextPopSample = 1808; popParams.size() = 1 We are SAMPLING at time 1808 *** Looping through 5.2. Iter = 1991 iteration 1991; minNextMutationTime = 1819; timeNextPopSample = 1809; popParams.size() = 1 We are SAMPLING at time 1809 *** Looping through 5.2. Iter = 1992 iteration 1992; minNextMutationTime = 1820; timeNextPopSample = 1810; popParams.size() = 1 We are SAMPLING at time 1810 *** Looping through 5.2. Iter = 1993 iteration 1993; minNextMutationTime = 1810.2; timeNextPopSample = 1811; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 1994 iteration 1994; minNextMutationTime = 1821; timeNextPopSample = 1811; popParams.size() = 2 We are SAMPLING at time 1811 *** Looping through 5.2. Iter = 1995 iteration 1995; minNextMutationTime = 1822; timeNextPopSample = 1812; popParams.size() = 1 We are SAMPLING at time 1812 *** Looping through 5.2. Iter = 1996 iteration 1996; minNextMutationTime = 1823; timeNextPopSample = 1813; popParams.size() = 1 We are SAMPLING at time 1813 *** Looping through 5.2. Iter = 1997 iteration 1997; minNextMutationTime = 1824; timeNextPopSample = 1814; popParams.size() = 1 We are SAMPLING at time 1814 *** Looping through 5.2. Iter = 1998 iteration 1998; minNextMutationTime = 1825; timeNextPopSample = 1815; popParams.size() = 1 We are SAMPLING at time 1815 *** Looping through 5.2. Iter = 1999 iteration 1999; minNextMutationTime = 1826; timeNextPopSample = 1816; popParams.size() = 1 We are SAMPLING at time 1816 ... iteration 2000 ... currentTime 1816 *** Looping through 5.2. Iter = 2000 iteration 2000; minNextMutationTime = 1827; timeNextPopSample = 1817; popParams.size() = 1 We are SAMPLING at time 1817 *** Looping through 5.2. Iter = 2001 iteration 2001; minNextMutationTime = 1828; timeNextPopSample = 1818; popParams.size() = 1 We are SAMPLING at time 1818 *** Looping through 5.2. Iter = 2002 iteration 2002; minNextMutationTime = 1829; timeNextPopSample = 1819; popParams.size() = 1 We are SAMPLING at time 1819 *** Looping through 5.2. Iter = 2003 iteration 2003; minNextMutationTime = 1819.7; timeNextPopSample = 1820; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 2004 iteration 2004; minNextMutationTime = 1830; timeNextPopSample = 1820; popParams.size() = 2 We are SAMPLING at time 1820 *** Looping through 5.2. Iter = 2005 iteration 2005; minNextMutationTime = 1831; timeNextPopSample = 1821; popParams.size() = 2 We are SAMPLING at time 1821 *** Looping through 5.2. Iter = 2006 iteration 2006; minNextMutationTime = 1832; timeNextPopSample = 1822; popParams.size() = 1 We are SAMPLING at time 1822 *** Looping through 5.2. Iter = 2007 iteration 2007; minNextMutationTime = 1833; timeNextPopSample = 1823; popParams.size() = 1 We are SAMPLING at time 1823 *** Looping through 5.2. Iter = 2008 iteration 2008; minNextMutationTime = 1834; timeNextPopSample = 1824; popParams.size() = 1 We are SAMPLING at time 1824 *** Looping through 5.2. Iter = 2009 iteration 2009; minNextMutationTime = 1835; timeNextPopSample = 1825; popParams.size() = 1 We are SAMPLING at time 1825 *** Looping through 5.2. Iter = 2010 iteration 2010; minNextMutationTime = 1836; timeNextPopSample = 1826; popParams.size() = 1 We are SAMPLING at time 1826 *** Looping through 5.2. Iter = 2011 iteration 2011; minNextMutationTime = 1837; timeNextPopSample = 1827; popParams.size() = 1 We are SAMPLING at time 1827 *** Looping through 5.2. Iter = 2012 iteration 2012; minNextMutationTime = 1838; timeNextPopSample = 1828; popParams.size() = 1 We are SAMPLING at time 1828 *** Looping through 5.2. Iter = 2013 iteration 2013; minNextMutationTime = 1839; timeNextPopSample = 1829; popParams.size() = 1 We are SAMPLING at time 1829 *** Looping through 5.2. Iter = 2014 iteration 2014; minNextMutationTime = 1840; timeNextPopSample = 1830; popParams.size() = 1 We are SAMPLING at time 1830 *** Looping through 5.2. Iter = 2015 iteration 2015; minNextMutationTime = 1841; timeNextPopSample = 1831; popParams.size() = 1 We are SAMPLING at time 1831 *** Looping through 5.2. Iter = 2016 iteration 2016; minNextMutationTime = 1842; timeNextPopSample = 1832; popParams.size() = 1 We are SAMPLING at time 1832 *** Looping through 5.2. Iter = 2017 iteration 2017; minNextMutationTime = 1843; timeNextPopSample = 1833; popParams.size() = 1 We are SAMPLING at time 1833 *** Looping through 5.2. Iter = 2018 iteration 2018; minNextMutationTime = 1833.68; timeNextPopSample = 1834; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 2019 iteration 2019; minNextMutationTime = 1844; timeNextPopSample = 1834; popParams.size() = 2 We are SAMPLING at time 1834 *** Looping through 5.2. Iter = 2020 iteration 2020; minNextMutationTime = 1834.32; timeNextPopSample = 1835; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 2021 iteration 2021; minNextMutationTime = 1845; timeNextPopSample = 1835; popParams.size() = 2 We are SAMPLING at time 1835 *** Looping through 5.2. Iter = 2022 iteration 2022; minNextMutationTime = 1846; timeNextPopSample = 1836; popParams.size() = 2 We are SAMPLING at time 1836 *** Looping through 5.2. Iter = 2023 iteration 2023; minNextMutationTime = 1847; timeNextPopSample = 1837; popParams.size() = 2 We are SAMPLING at time 1837 *** Looping through 5.2. Iter = 2024 iteration 2024; minNextMutationTime = 1848; timeNextPopSample = 1838; popParams.size() = 2 We are SAMPLING at time 1838 *** Looping through 5.2. Iter = 2025 iteration 2025; minNextMutationTime = 1849; timeNextPopSample = 1839; popParams.size() = 2 We are SAMPLING at time 1839 *** Looping through 5.2. Iter = 2026 iteration 2026; minNextMutationTime = 1850; timeNextPopSample = 1840; popParams.size() = 2 We are SAMPLING at time 1840 *** Looping through 5.2. Iter = 2027 iteration 2027; minNextMutationTime = 1851; timeNextPopSample = 1841; popParams.size() = 2 We are SAMPLING at time 1841 *** Looping through 5.2. Iter = 2028 iteration 2028; minNextMutationTime = 1852; timeNextPopSample = 1842; popParams.size() = 2 We are SAMPLING at time 1842 *** Looping through 5.2. Iter = 2029 iteration 2029; minNextMutationTime = 1853; timeNextPopSample = 1843; popParams.size() = 2 We are SAMPLING at time 1843 *** Looping through 5.2. Iter = 2030 iteration 2030; minNextMutationTime = 1854; timeNextPopSample = 1844; popParams.size() = 1 We are SAMPLING at time 1844 *** Looping through 5.2. Iter = 2031 iteration 2031; minNextMutationTime = 1855; timeNextPopSample = 1845; popParams.size() = 1 We are SAMPLING at time 1845 *** Looping through 5.2. Iter = 2032 iteration 2032; minNextMutationTime = 1856; timeNextPopSample = 1846; popParams.size() = 1 We are SAMPLING at time 1846 *** Looping through 5.2. Iter = 2033 iteration 2033; minNextMutationTime = 1857; timeNextPopSample = 1847; popParams.size() = 1 We are SAMPLING at time 1847 *** Looping through 5.2. Iter = 2034 iteration 2034; minNextMutationTime = 1858; timeNextPopSample = 1848; popParams.size() = 1 We are SAMPLING at time 1848 *** Looping through 5.2. Iter = 2035 iteration 2035; minNextMutationTime = 1859; timeNextPopSample = 1849; popParams.size() = 1 We are SAMPLING at time 1849 *** Looping through 5.2. Iter = 2036 iteration 2036; minNextMutationTime = 1860; timeNextPopSample = 1850; popParams.size() = 1 We are SAMPLING at time 1850 *** Looping through 5.2. Iter = 2037 iteration 2037; minNextMutationTime = 1861; timeNextPopSample = 1851; popParams.size() = 1 We are SAMPLING at time 1851 *** Looping through 5.2. Iter = 2038 iteration 2038; minNextMutationTime = 1862; timeNextPopSample = 1852; popParams.size() = 1 We are SAMPLING at time 1852 *** Looping through 5.2. Iter = 2039 iteration 2039; minNextMutationTime = 1863; timeNextPopSample = 1853; popParams.size() = 1 We are SAMPLING at time 1853 *** Looping through 5.2. Iter = 2040 iteration 2040; minNextMutationTime = 1864; timeNextPopSample = 1854; popParams.size() = 1 We are SAMPLING at time 1854 *** Looping through 5.2. Iter = 2041 iteration 2041; minNextMutationTime = 1865; timeNextPopSample = 1855; popParams.size() = 1 We are SAMPLING at time 1855 *** Looping through 5.2. Iter = 2042 iteration 2042; minNextMutationTime = 1866; timeNextPopSample = 1856; popParams.size() = 1 We are SAMPLING at time 1856 *** Looping through 5.2. Iter = 2043 iteration 2043; minNextMutationTime = 1867; timeNextPopSample = 1857; popParams.size() = 1 We are SAMPLING at time 1857 *** Looping through 5.2. Iter = 2044 iteration 2044; minNextMutationTime = 1857.21; timeNextPopSample = 1858; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 2045 iteration 2045; minNextMutationTime = 1868; timeNextPopSample = 1858; popParams.size() = 2 We are SAMPLING at time 1858 *** Looping through 5.2. Iter = 2046 iteration 2046; minNextMutationTime = 1869; timeNextPopSample = 1859; popParams.size() = 1 We are SAMPLING at time 1859 *** Looping through 5.2. Iter = 2047 iteration 2047; minNextMutationTime = 1859.74; timeNextPopSample = 1860; popParams.size() = 1 Creating new species 1 from species 0 *** Looping through 5.2. Iter = 2048 iteration 2048; minNextMutationTime = 1870; timeNextPopSample = 1860; popParams.size() = 2 We are SAMPLING at time 1860 *** Looping through 5.2. Iter = 2049 iteration 2049; minNextMutationTime = 1871; timeNextPopSample = 1861; popParams.size() = 2 We are SAMPLING at time 1861 *** Looping through 5.2. Iter = 2050 iteration 2050; minNextMutationTime = 1872; timeNextPopSample = 1862; popParams.size() = 2 We are SAMPLING at time 1862 *** Looping through 5.2. Iter = 2051 iteration 2051; minNextMutationTime = 1873; timeNextPopSample = 1863; popParams.size() = 2 We are SAMPLING at time 1863 *** Looping through 5.2. Iter = 2052 iteration 2052; minNextMutationTime = 1874; timeNextPopSample = 1864; popParams.size() = 2 We are SAMPLING at time 1864 *** Looping through 5.2. Iter = 2053 iteration 2053; minNextMutationTime = 1864.18; timeNextPopSample = 1865; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 2054 iteration 2054; minNextMutationTime = 1875; timeNextPopSample = 1865; popParams.size() = 3 We are SAMPLING at time 1865 *** Looping through 5.2. Iter = 2055 iteration 2055; minNextMutationTime = 1876; timeNextPopSample = 1866; popParams.size() = 3 We are SAMPLING at time 1866 *** Looping through 5.2. Iter = 2056 iteration 2056; minNextMutationTime = 1877; timeNextPopSample = 1867; popParams.size() = 2 We are SAMPLING at time 1867 *** Looping through 5.2. Iter = 2057 iteration 2057; minNextMutationTime = 1878; timeNextPopSample = 1868; popParams.size() = 2 We are SAMPLING at time 1868 *** Looping through 5.2. Iter = 2058 iteration 2058; minNextMutationTime = 1879; timeNextPopSample = 1869; popParams.size() = 2 We are SAMPLING at time 1869 *** Looping through 5.2. Iter = 2059 iteration 2059; minNextMutationTime = 1880; timeNextPopSample = 1870; popParams.size() = 2 We are SAMPLING at time 1870 *** Looping through 5.2. Iter = 2060 iteration 2060; minNextMutationTime = 1881; timeNextPopSample = 1871; popParams.size() = 2 We are SAMPLING at time 1871 *** Looping through 5.2. Iter = 2061 iteration 2061; minNextMutationTime = 1882; timeNextPopSample = 1872; popParams.size() = 2 We are SAMPLING at time 1872 *** Looping through 5.2. Iter = 2062 iteration 2062; minNextMutationTime = 1883; timeNextPopSample = 1873; popParams.size() = 2 We are SAMPLING at time 1873 *** Looping through 5.2. Iter = 2063 iteration 2063; minNextMutationTime = 1884; timeNextPopSample = 1874; popParams.size() = 2 We are SAMPLING at time 1874 *** Looping through 5.2. Iter = 2064 iteration 2064; minNextMutationTime = 1885; timeNextPopSample = 1875; popParams.size() = 2 We are SAMPLING at time 1875 *** Looping through 5.2. Iter = 2065 iteration 2065; minNextMutationTime = 1886; timeNextPopSample = 1876; popParams.size() = 2 We are SAMPLING at time 1876 *** Looping through 5.2. Iter = 2066 iteration 2066; minNextMutationTime = 1876.2; timeNextPopSample = 1877; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 2067 iteration 2067; minNextMutationTime = 1887; timeNextPopSample = 1877; popParams.size() = 3 We are SAMPLING at time 1877 *** Looping through 5.2. Iter = 2068 iteration 2068; minNextMutationTime = 1888; timeNextPopSample = 1878; popParams.size() = 2 We are SAMPLING at time 1878 *** Looping through 5.2. Iter = 2069 iteration 2069; minNextMutationTime = 1889; timeNextPopSample = 1879; popParams.size() = 2 We are SAMPLING at time 1879 *** Looping through 5.2. Iter = 2070 iteration 2070; minNextMutationTime = 1890; timeNextPopSample = 1880; popParams.size() = 2 We are SAMPLING at time 1880 *** Looping through 5.2. Iter = 2071 iteration 2071; minNextMutationTime = 1891; timeNextPopSample = 1881; popParams.size() = 2 We are SAMPLING at time 1881 *** Looping through 5.2. Iter = 2072 iteration 2072; minNextMutationTime = 1892; timeNextPopSample = 1882; popParams.size() = 2 We are SAMPLING at time 1882 *** Looping through 5.2. Iter = 2073 iteration 2073; minNextMutationTime = 1893; timeNextPopSample = 1883; popParams.size() = 2 We are SAMPLING at time 1883 *** Looping through 5.2. Iter = 2074 iteration 2074; minNextMutationTime = 1894; timeNextPopSample = 1884; popParams.size() = 2 We are SAMPLING at time 1884 *** Looping through 5.2. Iter = 2075 iteration 2075; minNextMutationTime = 1895; timeNextPopSample = 1885; popParams.size() = 2 We are SAMPLING at time 1885 *** Looping through 5.2. Iter = 2076 iteration 2076; minNextMutationTime = 1896; timeNextPopSample = 1886; popParams.size() = 2 We are SAMPLING at time 1886 *** Looping through 5.2. Iter = 2077 iteration 2077; minNextMutationTime = 1897; timeNextPopSample = 1887; popParams.size() = 2 We are SAMPLING at time 1887 *** Looping through 5.2. Iter = 2078 iteration 2078; minNextMutationTime = 1898; timeNextPopSample = 1888; popParams.size() = 2 We are SAMPLING at time 1888 *** Looping through 5.2. Iter = 2079 iteration 2079; minNextMutationTime = 1899; timeNextPopSample = 1889; popParams.size() = 2 We are SAMPLING at time 1889 *** Looping through 5.2. Iter = 2080 iteration 2080; minNextMutationTime = 1900; timeNextPopSample = 1890; popParams.size() = 2 We are SAMPLING at time 1890 *** Looping through 5.2. Iter = 2081 iteration 2081; minNextMutationTime = 1901; timeNextPopSample = 1891; popParams.size() = 2 We are SAMPLING at time 1891 *** Looping through 5.2. Iter = 2082 iteration 2082; minNextMutationTime = 1902; timeNextPopSample = 1892; popParams.size() = 2 We are SAMPLING at time 1892 *** Looping through 5.2. Iter = 2083 iteration 2083; minNextMutationTime = 1903; timeNextPopSample = 1893; popParams.size() = 2 We are SAMPLING at time 1893 *** Looping through 5.2. Iter = 2084 iteration 2084; minNextMutationTime = 1904; timeNextPopSample = 1894; popParams.size() = 2 We are SAMPLING at time 1894 *** Looping through 5.2. Iter = 2085 iteration 2085; minNextMutationTime = 1894.47; timeNextPopSample = 1895; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 2086 iteration 2086; minNextMutationTime = 1905; timeNextPopSample = 1895; popParams.size() = 3 We are SAMPLING at time 1895 *** Looping through 5.2. Iter = 2087 iteration 2087; minNextMutationTime = 1906; timeNextPopSample = 1896; popParams.size() = 3 We are SAMPLING at time 1896 *** Looping through 5.2. Iter = 2088 iteration 2088; minNextMutationTime = 1907; timeNextPopSample = 1897; popParams.size() = 2 We are SAMPLING at time 1897 *** Looping through 5.2. Iter = 2089 iteration 2089; minNextMutationTime = 1897.22; timeNextPopSample = 1898; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 2090 iteration 2090; minNextMutationTime = 1897.39; timeNextPopSample = 1898; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 2091 iteration 2091; minNextMutationTime = 1908; timeNextPopSample = 1898; popParams.size() = 4 We are SAMPLING at time 1898 *** Looping through 5.2. Iter = 2092 iteration 2092; minNextMutationTime = 1909; timeNextPopSample = 1899; popParams.size() = 4 We are SAMPLING at time 1899 *** Looping through 5.2. Iter = 2093 iteration 2093; minNextMutationTime = 1910; timeNextPopSample = 1900; popParams.size() = 4 We are SAMPLING at time 1900 *** Looping through 5.2. Iter = 2094 iteration 2094; minNextMutationTime = 1911; timeNextPopSample = 1901; popParams.size() = 3 We are SAMPLING at time 1901 *** Looping through 5.2. Iter = 2095 iteration 2095; minNextMutationTime = 1901.25; timeNextPopSample = 1902; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 2096 iteration 2096; minNextMutationTime = 1912; timeNextPopSample = 1902; popParams.size() = 3 We are SAMPLING at time 1902 *** Looping through 5.2. Iter = 2097 iteration 2097; minNextMutationTime = 1913; timeNextPopSample = 1903; popParams.size() = 3 We are SAMPLING at time 1903 *** Looping through 5.2. Iter = 2098 iteration 2098; minNextMutationTime = 1914; timeNextPopSample = 1904; popParams.size() = 3 We are SAMPLING at time 1904 *** Looping through 5.2. Iter = 2099 iteration 2099; minNextMutationTime = 1915; timeNextPopSample = 1905; popParams.size() = 2 We are SAMPLING at time 1905 *** Looping through 5.2. Iter = 2100 iteration 2100; minNextMutationTime = 1916; timeNextPopSample = 1906; popParams.size() = 2 We are SAMPLING at time 1906 *** Looping through 5.2. Iter = 2101 iteration 2101; minNextMutationTime = 1917; timeNextPopSample = 1907; popParams.size() = 2 We are SAMPLING at time 1907 *** Looping through 5.2. Iter = 2102 iteration 2102; minNextMutationTime = 1918; timeNextPopSample = 1908; popParams.size() = 2 We are SAMPLING at time 1908 *** Looping through 5.2. Iter = 2103 iteration 2103; minNextMutationTime = 1919; timeNextPopSample = 1909; popParams.size() = 2 We are SAMPLING at time 1909 *** Looping through 5.2. Iter = 2104 iteration 2104; minNextMutationTime = 1920; timeNextPopSample = 1910; popParams.size() = 2 We are SAMPLING at time 1910 *** Looping through 5.2. Iter = 2105 iteration 2105; minNextMutationTime = 1921; timeNextPopSample = 1911; popParams.size() = 2 We are SAMPLING at time 1911 *** Looping through 5.2. Iter = 2106 iteration 2106; minNextMutationTime = 1922; timeNextPopSample = 1912; popParams.size() = 2 We are SAMPLING at time 1912 *** Looping through 5.2. Iter = 2107 iteration 2107; minNextMutationTime = 1923; timeNextPopSample = 1913; popParams.size() = 2 We are SAMPLING at time 1913 *** Looping through 5.2. Iter = 2108 iteration 2108; minNextMutationTime = 1913.12; timeNextPopSample = 1914; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 2109 iteration 2109; minNextMutationTime = 1924; timeNextPopSample = 1914; popParams.size() = 3 We are SAMPLING at time 1914 *** Looping through 5.2. Iter = 2110 iteration 2110; minNextMutationTime = 1925; timeNextPopSample = 1915; popParams.size() = 2 We are SAMPLING at time 1915 *** Looping through 5.2. Iter = 2111 iteration 2111; minNextMutationTime = 1926; timeNextPopSample = 1916; popParams.size() = 2 We are SAMPLING at time 1916 *** Looping through 5.2. Iter = 2112 iteration 2112; minNextMutationTime = 1927; timeNextPopSample = 1917; popParams.size() = 2 We are SAMPLING at time 1917 *** Looping through 5.2. Iter = 2113 iteration 2113; minNextMutationTime = 1917.13; timeNextPopSample = 1918; popParams.size() = 2 Creating new species 2 from species 0 *** Looping through 5.2. Iter = 2114 iteration 2114; minNextMutationTime = 1928; timeNextPopSample = 1918; popParams.size() = 3 We are SAMPLING at time 1918 *** Looping through 5.2. Iter = 2115 iteration 2115; minNextMutationTime = 1918.11; timeNextPopSample = 1919; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 2116 iteration 2116; minNextMutationTime = 1929; timeNextPopSample = 1919; popParams.size() = 4 We are SAMPLING at time 1919 *** Looping through 5.2. Iter = 2117 iteration 2117; minNextMutationTime = 1930; timeNextPopSample = 1920; popParams.size() = 4 We are SAMPLING at time 1920 *** Looping through 5.2. Iter = 2118 iteration 2118; minNextMutationTime = 1931; timeNextPopSample = 1921; popParams.size() = 3 We are SAMPLING at time 1921 *** Looping through 5.2. Iter = 2119 iteration 2119; minNextMutationTime = 1921.55; timeNextPopSample = 1922; popParams.size() = 3 Creating new species 3 from species 0 *** Looping through 5.2. Iter = 2120 iteration 2120; minNextMutationTime = 1932; timeNextPopSample = 1922; popParams.size() = 4 We are SAMPLING at time 1922 *** Looping through 5.2. Iter = 2121 iteration 2121; minNextMutationTime = 1933; timeNextPopSample = 1923; popParams.size() = 4 We are SAMPLING at time 1923 *** Looping through 5.2. Iter = 2122 iteration 2122; minNextMutationTime = 1934; timeNextPopSample = 1924; popParams.size() = 4 We are SAMPLING at time 1924 *** Looping through 5.2. Iter = 2123 iteration 2123; minNextMutationTime = 1924.06; timeNextPopSample = 1925; popParams.size() = 4 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 1) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 1) New popSize = 14717 *** Looping through 5.2. Iter = 2124 iteration 2124; minNextMutationTime = 1935; timeNextPopSample = 1925; popParams.size() = 4 We are SAMPLING at time 1925 *** Looping through 5.2. Iter = 2125 iteration 2125; minNextMutationTime = 1936; timeNextPopSample = 1926; popParams.size() = 4 We are SAMPLING at time 1926 *** Looping through 5.2. Iter = 2126 iteration 2126; minNextMutationTime = 1937; timeNextPopSample = 1927; popParams.size() = 4 We are SAMPLING at time 1927 *** Looping through 5.2. Iter = 2127 iteration 2127; minNextMutationTime = 1938; timeNextPopSample = 1928; popParams.size() = 3 We are SAMPLING at time 1928 *** Looping through 5.2. Iter = 2128 iteration 2128; minNextMutationTime = 1928.6; timeNextPopSample = 1929; popParams.size() = 3 Creating new species 3 from species 1 *** Looping through 5.2. Iter = 2129 iteration 2129; minNextMutationTime = 1939; timeNextPopSample = 1929; popParams.size() = 4 We are SAMPLING at time 1929 *** Looping through 5.2. Iter = 2130 iteration 2130; minNextMutationTime = 1940; timeNextPopSample = 1930; popParams.size() = 4 We are SAMPLING at time 1930 *** Looping through 5.2. Iter = 2131 iteration 2131; minNextMutationTime = 1930.06; timeNextPopSample = 1931; popParams.size() = 3 Creating new species 3 from species 1 *** Looping through 5.2. Iter = 2132 iteration 2132; minNextMutationTime = 1941; timeNextPopSample = 1931; popParams.size() = 4 We are SAMPLING at time 1931 *** Looping through 5.2. Iter = 2133 iteration 2133; minNextMutationTime = 1931.24; timeNextPopSample = 1932; popParams.size() = 4 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2 *** Looping through 5.2. Iter = 2134 iteration 2134; minNextMutationTime = 1942; timeNextPopSample = 1932; popParams.size() = 4 We are SAMPLING at time 1932 *** Looping through 5.2. Iter = 2135 iteration 2135; minNextMutationTime = 1943; timeNextPopSample = 1933; popParams.size() = 4 We are SAMPLING at time 1933 *** Looping through 5.2. Iter = 2136 iteration 2136; minNextMutationTime = 1933.75; timeNextPopSample = 1934; popParams.size() = 4 Creating new species 4 from species 1 *** Looping through 5.2. Iter = 2137 iteration 2137; minNextMutationTime = 1944; timeNextPopSample = 1934; popParams.size() = 5 We are SAMPLING at time 1934 *** Looping through 5.2. Iter = 2138 iteration 2138; minNextMutationTime = 1934.56; timeNextPopSample = 1935; popParams.size() = 5 Creating new species 5 from species 0 *** Looping through 5.2. Iter = 2139 iteration 2139; minNextMutationTime = 1945; timeNextPopSample = 1935; popParams.size() = 6 We are SAMPLING at time 1935 *** Looping through 5.2. Iter = 2140 iteration 2140; minNextMutationTime = 1946; timeNextPopSample = 1936; popParams.size() = 5 We are SAMPLING at time 1936 *** Looping through 5.2. Iter = 2141 iteration 2141; minNextMutationTime = 1936.11; timeNextPopSample = 1937; popParams.size() = 4 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 42 *** Looping through 5.2. Iter = 2142 iteration 2142; minNextMutationTime = 1947; timeNextPopSample = 1937; popParams.size() = 4 We are SAMPLING at time 1937 *** Looping through 5.2. Iter = 2143 iteration 2143; minNextMutationTime = 1948; timeNextPopSample = 1938; popParams.size() = 4 We are SAMPLING at time 1938 *** Looping through 5.2. Iter = 2144 iteration 2144; minNextMutationTime = 1949; timeNextPopSample = 1939; popParams.size() = 4 We are SAMPLING at time 1939 *** Looping through 5.2. Iter = 2145 iteration 2145; minNextMutationTime = 1950; timeNextPopSample = 1940; popParams.size() = 4 We are SAMPLING at time 1940 *** Looping through 5.2. Iter = 2146 iteration 2146; minNextMutationTime = 1940.32; timeNextPopSample = 1941; popParams.size() = 4 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 1) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 1) New popSize = 76258 *** Looping through 5.2. Iter = 2147 iteration 2147; minNextMutationTime = 1951; timeNextPopSample = 1941; popParams.size() = 4 We are SAMPLING at time 1941 *** Looping through 5.2. Iter = 2148 iteration 2148; minNextMutationTime = 1952; timeNextPopSample = 1942; popParams.size() = 4 We are SAMPLING at time 1942 *** Looping through 5.2. Iter = 2149 iteration 2149; minNextMutationTime = 1953; timeNextPopSample = 1943; popParams.size() = 4 We are SAMPLING at time 1943 *** Looping through 5.2. Iter = 2150 iteration 2150; minNextMutationTime = 1954; timeNextPopSample = 1944; popParams.size() = 4 We are SAMPLING at time 1944 *** Looping through 5.2. Iter = 2151 iteration 2151; minNextMutationTime = 1955; timeNextPopSample = 1945; popParams.size() = 4 We are SAMPLING at time 1945 *** Looping through 5.2. Iter = 2152 iteration 2152; minNextMutationTime = 1945.21; timeNextPopSample = 1946; popParams.size() = 4 Creating new species 4 from species 1 *** Looping through 5.2. Iter = 2153 iteration 2153; minNextMutationTime = 1945.55; timeNextPopSample = 1946; popParams.size() = 5 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 2 *** Looping through 5.2. Iter = 2154 iteration 2154; minNextMutationTime = 1956; timeNextPopSample = 1946; popParams.size() = 5 We are SAMPLING at time 1946 *** Looping through 5.2. Iter = 2155 iteration 2155; minNextMutationTime = 1957; timeNextPopSample = 1947; popParams.size() = 5 We are SAMPLING at time 1947 *** Looping through 5.2. Iter = 2156 iteration 2156; minNextMutationTime = 1958; timeNextPopSample = 1948; popParams.size() = 5 We are SAMPLING at time 1948 *** Looping through 5.2. Iter = 2157 iteration 2157; minNextMutationTime = 1959; timeNextPopSample = 1949; popParams.size() = 5 We are SAMPLING at time 1949 *** Looping through 5.2. Iter = 2158 iteration 2158; minNextMutationTime = 1949.3; timeNextPopSample = 1950; popParams.size() = 5 Creating new species 5 from species 1 *** Looping through 5.2. Iter = 2159 iteration 2159; minNextMutationTime = 1960; timeNextPopSample = 1950; popParams.size() = 6 We are SAMPLING at time 1950 *** Looping through 5.2. Iter = 2160 iteration 2160; minNextMutationTime = 1950.07; timeNextPopSample = 1951; popParams.size() = 6 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 111 *** Looping through 5.2. Iter = 2161 iteration 2161; minNextMutationTime = 1950.15; timeNextPopSample = 1951; popParams.size() = 6 Creating new species 6 from species 1 *** Looping through 5.2. Iter = 2162 iteration 2162; minNextMutationTime = 1950.55; timeNextPopSample = 1951; popParams.size() = 7 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 126 *** Looping through 5.2. Iter = 2163 iteration 2163; minNextMutationTime = 1950.83; timeNextPopSample = 1951; popParams.size() = 7 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 6 *** Looping through 5.2. Iter = 2164 iteration 2164; minNextMutationTime = 1961; timeNextPopSample = 1951; popParams.size() = 7 We are SAMPLING at time 1951 *** Looping through 5.2. Iter = 2165 iteration 2165; minNextMutationTime = 1951.13; timeNextPopSample = 1952; popParams.size() = 7 Creating new species 7 from species 1 *** Looping through 5.2. Iter = 2166 iteration 2166; minNextMutationTime = 1951.28; timeNextPopSample = 1952; popParams.size() = 8 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 2 *** Looping through 5.2. Iter = 2167 iteration 2167; minNextMutationTime = 1951.95; timeNextPopSample = 1952; popParams.size() = 8 Mutated to existing species 2 (Genotype = 0000000000000000000000000000000000000000000000000000000000001000; sp_id = 8) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 8) New popSize = 66 *** Looping through 5.2. Iter = 2168 iteration 2168; minNextMutationTime = 1962; timeNextPopSample = 1952; popParams.size() = 8 We are SAMPLING at time 1952 *** Looping through 5.2. Iter = 2169 iteration 2169; minNextMutationTime = 1952.62; timeNextPopSample = 1953; popParams.size() = 7 Creating new species 7 from species 1 *** Looping through 5.2. Iter = 2170 iteration 2170; minNextMutationTime = 1952.66; timeNextPopSample = 1953; popParams.size() = 8 Mutated to existing species 1 (Genotype = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 1) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 1) New popSize = 259294 *** Looping through 5.2. Iter = 2171 iteration 2171; minNextMutationTime = 1952.96; timeNextPopSample = 1953; popParams.size() = 8 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 12 *** Looping through 5.2. Iter = 2172 iteration 2172; minNextMutationTime = 1963; timeNextPopSample = 1953; popParams.size() = 8 We are SAMPLING at time 1953 *** Looping through 5.2. Iter = 2173 iteration 2173; minNextMutationTime = 1953.1; timeNextPopSample = 1954; popParams.size() = 8 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 2 *** Looping through 5.2. Iter = 2174 iteration 2174; minNextMutationTime = 1953.35; timeNextPopSample = 1954; popParams.size() = 8 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 2 *** Looping through 5.2. Iter = 2175 iteration 2175; minNextMutationTime = 1953.54; timeNextPopSample = 1954; popParams.size() = 8 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 205 *** Looping through 5.2. Iter = 2176 iteration 2176; minNextMutationTime = 1964; timeNextPopSample = 1954; popParams.size() = 8 We are SAMPLING at time 1954 *** Looping through 5.2. Iter = 2177 iteration 2177; minNextMutationTime = 1954.38; timeNextPopSample = 1955; popParams.size() = 8 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 3 *** Looping through 5.2. Iter = 2178 iteration 2178; minNextMutationTime = 1954.54; timeNextPopSample = 1955; popParams.size() = 8 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 5 *** Looping through 5.2. Iter = 2179 iteration 2179; minNextMutationTime = 1954.55; timeNextPopSample = 1955; popParams.size() = 8 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 13 *** Looping through 5.2. Iter = 2180 iteration 2180; minNextMutationTime = 1954.81; timeNextPopSample = 1955; popParams.size() = 8 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 16 *** Looping through 5.2. Iter = 2181 iteration 2181; minNextMutationTime = 1965; timeNextPopSample = 1955; popParams.size() = 8 We are SAMPLING at time 1955 *** Looping through 5.2. Iter = 2182 iteration 2182; minNextMutationTime = 1966; timeNextPopSample = 1956; popParams.size() = 8 We are SAMPLING at time 1956 *** Looping through 5.2. Iter = 2183 iteration 2183; minNextMutationTime = 1956.56; timeNextPopSample = 1957; popParams.size() = 7 Creating new species 7 from species 1 *** Looping through 5.2. Iter = 2184 iteration 2184; minNextMutationTime = 1967; timeNextPopSample = 1957; popParams.size() = 8 We are SAMPLING at time 1957 *** Looping through 5.2. Iter = 2185 iteration 2185; minNextMutationTime = 1957.12; timeNextPopSample = 1958; popParams.size() = 8 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 15 *** Looping through 5.2. Iter = 2186 iteration 2186; minNextMutationTime = 1968; timeNextPopSample = 1958; popParams.size() = 8 We are SAMPLING at time 1958 *** Looping through 5.2. Iter = 2187 iteration 2187; minNextMutationTime = 1958.47; timeNextPopSample = 1959; popParams.size() = 7 Creating new species 7 from species 1 *** Looping through 5.2. Iter = 2188 iteration 2188; minNextMutationTime = 1969; timeNextPopSample = 1959; popParams.size() = 8 We are SAMPLING at time 1959 *** Looping through 5.2. Iter = 2189 iteration 2189; minNextMutationTime = 1959.47; timeNextPopSample = 1960; popParams.size() = 8 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 28 *** Looping through 5.2. Iter = 2190 iteration 2190; minNextMutationTime = 1959.73; timeNextPopSample = 1960; popParams.size() = 8 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 32 *** Looping through 5.2. Iter = 2191 iteration 2191; minNextMutationTime = 1970; timeNextPopSample = 1960; popParams.size() = 8 We are SAMPLING at time 1960 *** Looping through 5.2. Iter = 2192 iteration 2192; minNextMutationTime = 1960.11; timeNextPopSample = 1961; popParams.size() = 8 Creating new species 8 from species 1 *** Looping through 5.2. Iter = 2193 iteration 2193; minNextMutationTime = 1960.48; timeNextPopSample = 1961; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 1 *** Looping through 5.2. Iter = 2194 iteration 2194; minNextMutationTime = 1960.63; timeNextPopSample = 1961; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 31 *** Looping through 5.2. Iter = 2195 iteration 2195; minNextMutationTime = 1960.74; timeNextPopSample = 1961; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 23 *** Looping through 5.2. Iter = 2196 iteration 2196; minNextMutationTime = 1971; timeNextPopSample = 1961; popParams.size() = 9 We are SAMPLING at time 1961 *** Looping through 5.2. Iter = 2197 iteration 2197; minNextMutationTime = 1961.11; timeNextPopSample = 1962; popParams.size() = 8 Mutated to existing species 2 (Genotype = 0000000000000000000000000000000000000000000000000000000000001000; sp_id = 8) from species 0 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000000; sp_id = 8) New popSize = 82 *** Looping through 5.2. Iter = 2198 iteration 2198; minNextMutationTime = 1961.4; timeNextPopSample = 1962; popParams.size() = 8 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 952 *** Looping through 5.2. Iter = 2199 iteration 2199; minNextMutationTime = 1972; timeNextPopSample = 1962; popParams.size() = 8 We are SAMPLING at time 1962 *** Looping through 5.2. Iter = 2200 iteration 2200; minNextMutationTime = 1962.12; timeNextPopSample = 1963; popParams.size() = 8 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 2 *** Looping through 5.2. Iter = 2201 iteration 2201; minNextMutationTime = 1962.45; timeNextPopSample = 1963; popParams.size() = 8 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 34 *** Looping through 5.2. Iter = 2202 iteration 2202; minNextMutationTime = 1962.53; timeNextPopSample = 1963; popParams.size() = 8 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 48 *** Looping through 5.2. Iter = 2203 iteration 2203; minNextMutationTime = 1962.57; timeNextPopSample = 1963; popParams.size() = 8 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 23 *** Looping through 5.2. Iter = 2204 iteration 2204; minNextMutationTime = 1962.85; timeNextPopSample = 1963; popParams.size() = 8 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 36 *** Looping through 5.2. Iter = 2205 iteration 2205; minNextMutationTime = 1973; timeNextPopSample = 1963; popParams.size() = 8 We are SAMPLING at time 1963 *** Looping through 5.2. Iter = 2206 iteration 2206; minNextMutationTime = 1963.05; timeNextPopSample = 1964; popParams.size() = 8 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 56 *** Looping through 5.2. Iter = 2207 iteration 2207; minNextMutationTime = 1963.06; timeNextPopSample = 1964; popParams.size() = 8 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 55 *** Looping through 5.2. Iter = 2208 iteration 2208; minNextMutationTime = 1963.28; timeNextPopSample = 1964; popParams.size() = 8 Creating new species 8 from species 1 *** Looping through 5.2. Iter = 2209 iteration 2209; minNextMutationTime = 1963.29; timeNextPopSample = 1964; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 47 *** Looping through 5.2. Iter = 2210 iteration 2210; minNextMutationTime = 1963.38; timeNextPopSample = 1964; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 1131 *** Looping through 5.2. Iter = 2211 iteration 2211; minNextMutationTime = 1963.6; timeNextPopSample = 1964; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 1176 *** Looping through 5.2. Iter = 2212 iteration 2212; minNextMutationTime = 1963.6; timeNextPopSample = 1964; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 1179 *** Looping through 5.2. Iter = 2213 iteration 2213; minNextMutationTime = 1963.82; timeNextPopSample = 1964; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 85 *** Looping through 5.2. Iter = 2214 iteration 2214; minNextMutationTime = 1963.84; timeNextPopSample = 1964; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 1 *** Looping through 5.2. Iter = 2215 iteration 2215; minNextMutationTime = 1964; timeNextPopSample = 1964; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 1 *** Looping through 5.2. Iter = 2216 iteration 2216; minNextMutationTime = 1974; timeNextPopSample = 1964; popParams.size() = 9 We are SAMPLING at time 1964 *** Looping through 5.2. Iter = 2217 iteration 2217; minNextMutationTime = 1964.51; timeNextPopSample = 1965; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 1 *** Looping through 5.2. Iter = 2218 iteration 2218; minNextMutationTime = 1964.7; timeNextPopSample = 1965; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 2 *** Looping through 5.2. Iter = 2219 iteration 2219; minNextMutationTime = 1964.78; timeNextPopSample = 1965; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 3 *** Looping through 5.2. Iter = 2220 iteration 2220; minNextMutationTime = 1964.78; timeNextPopSample = 1965; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 53 *** Looping through 5.2. Iter = 2221 iteration 2221; minNextMutationTime = 1964.93; timeNextPopSample = 1965; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 91 *** Looping through 5.2. Iter = 2222 iteration 2222; minNextMutationTime = 1965; timeNextPopSample = 1965; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 1 *** Looping through 5.2. Iter = 2223 iteration 2223; minNextMutationTime = 1975; timeNextPopSample = 1965; popParams.size() = 9 We are SAMPLING at time 1965 *** Looping through 5.2. Iter = 2224 iteration 2224; minNextMutationTime = 1965.13; timeNextPopSample = 1966; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 4 *** Looping through 5.2. Iter = 2225 iteration 2225; minNextMutationTime = 1965.34; timeNextPopSample = 1966; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 2 *** Looping through 5.2. Iter = 2226 iteration 2226; minNextMutationTime = 1965.92; timeNextPopSample = 1966; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 1399 *** Looping through 5.2. Iter = 2227 iteration 2227; minNextMutationTime = 1965.92; timeNextPopSample = 1966; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 3 *** Looping through 5.2. Iter = 2228 iteration 2228; minNextMutationTime = 1976; timeNextPopSample = 1966; popParams.size() = 9 We are SAMPLING at time 1966 *** Looping through 5.2. Iter = 2229 iteration 2229; minNextMutationTime = 1966.14; timeNextPopSample = 1967; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 5 *** Looping through 5.2. Iter = 2230 iteration 2230; minNextMutationTime = 1966.16; timeNextPopSample = 1967; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 3 *** Looping through 5.2. Iter = 2231 iteration 2231; minNextMutationTime = 1966.18; timeNextPopSample = 1967; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 1438 *** Looping through 5.2. Iter = 2232 iteration 2232; minNextMutationTime = 1966.52; timeNextPopSample = 1967; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 1556 *** Looping through 5.2. Iter = 2233 iteration 2233; minNextMutationTime = 1966.73; timeNextPopSample = 1967; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 100 *** Looping through 5.2. Iter = 2234 iteration 2234; minNextMutationTime = 1966.81; timeNextPopSample = 1967; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 3 *** Looping through 5.2. Iter = 2235 iteration 2235; minNextMutationTime = 1966.83; timeNextPopSample = 1967; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 62 *** Looping through 5.2. Iter = 2236 iteration 2236; minNextMutationTime = 1966.86; timeNextPopSample = 1967; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 5 *** Looping through 5.2. Iter = 2237 iteration 2237; minNextMutationTime = 1966.95; timeNextPopSample = 1967; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 100 *** Looping through 5.2. Iter = 2238 iteration 2238; minNextMutationTime = 1977; timeNextPopSample = 1967; popParams.size() = 9 We are SAMPLING at time 1967 *** Looping through 5.2. Iter = 2239 iteration 2239; minNextMutationTime = 1967.13; timeNextPopSample = 1968; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 1563 *** Looping through 5.2. Iter = 2240 iteration 2240; minNextMutationTime = 1967.16; timeNextPopSample = 1968; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 48 *** Looping through 5.2. Iter = 2241 iteration 2241; minNextMutationTime = 1967.33; timeNextPopSample = 1968; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 4 *** Looping through 5.2. Iter = 2242 iteration 2242; minNextMutationTime = 1967.66; timeNextPopSample = 1968; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 53 *** Looping through 5.2. Iter = 2243 iteration 2243; minNextMutationTime = 1967.69; timeNextPopSample = 1968; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 5 *** Looping through 5.2. Iter = 2244 iteration 2244; minNextMutationTime = 1967.8; timeNextPopSample = 1968; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 3 *** Looping through 5.2. Iter = 2245 iteration 2245; minNextMutationTime = 1967.85; timeNextPopSample = 1968; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 65 *** Looping through 5.2. Iter = 2246 iteration 2246; minNextMutationTime = 1978; timeNextPopSample = 1968; popParams.size() = 9 We are SAMPLING at time 1968 *** Looping through 5.2. Iter = 2247 iteration 2247; minNextMutationTime = 1968.04; timeNextPopSample = 1969; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 70 *** Looping through 5.2. Iter = 2248 iteration 2248; minNextMutationTime = 1968.06; timeNextPopSample = 1969; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 59 *** Looping through 5.2. Iter = 2249 iteration 2249; minNextMutationTime = 1968.06; timeNextPopSample = 1969; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 61 *** Looping through 5.2. Iter = 2250 iteration 2250; minNextMutationTime = 1968.21; timeNextPopSample = 1969; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 116 *** Looping through 5.2. Iter = 2251 iteration 2251; minNextMutationTime = 1968.46; timeNextPopSample = 1969; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 70 *** Looping through 5.2. Iter = 2252 iteration 2252; minNextMutationTime = 1968.53; timeNextPopSample = 1969; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 1614 *** Looping through 5.2. Iter = 2253 iteration 2253; minNextMutationTime = 1968.75; timeNextPopSample = 1969; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 3 *** Looping through 5.2. Iter = 2254 iteration 2254; minNextMutationTime = 1968.81; timeNextPopSample = 1969; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 5 *** Looping through 5.2. Iter = 2255 iteration 2255; minNextMutationTime = 1979; timeNextPopSample = 1969; popParams.size() = 9 We are SAMPLING at time 1969 *** Looping through 5.2. Iter = 2256 iteration 2256; minNextMutationTime = 1969.01; timeNextPopSample = 1970; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 70 *** Looping through 5.2. Iter = 2257 iteration 2257; minNextMutationTime = 1969.09; timeNextPopSample = 1970; popParams.size() = 9 Creating new species 9 from species 0 *** Looping through 5.2. Iter = 2258 iteration 2258; minNextMutationTime = 1969.31; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 1939 *** Looping through 5.2. Iter = 2259 iteration 2259; minNextMutationTime = 1969.36; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 3 *** Looping through 5.2. Iter = 2260 iteration 2260; minNextMutationTime = 1969.4; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 4 *** Looping through 5.2. Iter = 2261 iteration 2261; minNextMutationTime = 1969.42; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2016 *** Looping through 5.2. Iter = 2262 iteration 2262; minNextMutationTime = 1969.47; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 76 *** Looping through 5.2. Iter = 2263 iteration 2263; minNextMutationTime = 1969.61; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 93 *** Looping through 5.2. Iter = 2264 iteration 2264; minNextMutationTime = 1969.63; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2113 *** Looping through 5.2. Iter = 2265 iteration 2265; minNextMutationTime = 1969.66; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2137 *** Looping through 5.2. Iter = 2266 iteration 2266; minNextMutationTime = 1969.7; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 97 *** Looping through 5.2. Iter = 2267 iteration 2267; minNextMutationTime = 1969.94; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 11 *** Looping through 5.2. Iter = 2268 iteration 2268; minNextMutationTime = 1969.99; timeNextPopSample = 1970; popParams.size() = 10 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2306 *** Looping through 5.2. Iter = 2269 iteration 2269; minNextMutationTime = 1980; timeNextPopSample = 1970; popParams.size() = 10 We are SAMPLING at time 1970 *** Looping through 5.2. Iter = 2270 iteration 2270; minNextMutationTime = 1970.18; timeNextPopSample = 1971; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 105 *** Looping through 5.2. Iter = 2271 iteration 2271; minNextMutationTime = 1970.25; timeNextPopSample = 1971; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 15 *** Looping through 5.2. Iter = 2272 iteration 2272; minNextMutationTime = 1970.3; timeNextPopSample = 1971; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 16 *** Looping through 5.2. Iter = 2273 iteration 2273; minNextMutationTime = 1970.38; timeNextPopSample = 1971; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2339 *** Looping through 5.2. Iter = 2274 iteration 2274; minNextMutationTime = 1970.4; timeNextPopSample = 1971; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 2 *** Looping through 5.2. Iter = 2275 iteration 2275; minNextMutationTime = 1970.41; timeNextPopSample = 1971; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 17 *** Looping through 5.2. Iter = 2276 iteration 2276; minNextMutationTime = 1970.55; timeNextPopSample = 1971; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 3 *** Looping through 5.2. Iter = 2277 iteration 2277; minNextMutationTime = 1981; timeNextPopSample = 1971; popParams.size() = 9 We are SAMPLING at time 1971 *** Looping through 5.2. Iter = 2278 iteration 2278; minNextMutationTime = 1971; timeNextPopSample = 1972; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 107 *** Looping through 5.2. Iter = 2279 iteration 2279; minNextMutationTime = 1971.04; timeNextPopSample = 1972; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 212 *** Looping through 5.2. Iter = 2280 iteration 2280; minNextMutationTime = 1971.05; timeNextPopSample = 1972; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 5 *** Looping through 5.2. Iter = 2281 iteration 2281; minNextMutationTime = 1971.11; timeNextPopSample = 1972; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 76 *** Looping through 5.2. Iter = 2282 iteration 2282; minNextMutationTime = 1971.22; timeNextPopSample = 1972; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 77 *** Looping through 5.2. Iter = 2283 iteration 2283; minNextMutationTime = 1971.25; timeNextPopSample = 1972; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 18 *** Looping through 5.2. Iter = 2284 iteration 2284; minNextMutationTime = 1971.49; timeNextPopSample = 1972; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 78 *** Looping through 5.2. Iter = 2285 iteration 2285; minNextMutationTime = 1971.72; timeNextPopSample = 1972; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 107 *** Looping through 5.2. Iter = 2286 iteration 2286; minNextMutationTime = 1971.86; timeNextPopSample = 1972; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 233 *** Looping through 5.2. Iter = 2287 iteration 2287; minNextMutationTime = 1982; timeNextPopSample = 1972; popParams.size() = 9 We are SAMPLING at time 1972 *** Looping through 5.2. Iter = 2288 iteration 2288; minNextMutationTime = 1972.02; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2673 *** Looping through 5.2. Iter = 2289 iteration 2289; minNextMutationTime = 1972.11; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 25 *** Looping through 5.2. Iter = 2290 iteration 2290; minNextMutationTime = 1972.12; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 26 *** Looping through 5.2. Iter = 2291 iteration 2291; minNextMutationTime = 1972.17; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 6 *** Looping through 5.2. Iter = 2292 iteration 2292; minNextMutationTime = 1972.2; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 114 *** Looping through 5.2. Iter = 2293 iteration 2293; minNextMutationTime = 1972.25; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 8 *** Looping through 5.2. Iter = 2294 iteration 2294; minNextMutationTime = 1972.42; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 9 *** Looping through 5.2. Iter = 2295 iteration 2295; minNextMutationTime = 1972.58; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 71 *** Looping through 5.2. Iter = 2296 iteration 2296; minNextMutationTime = 1972.66; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 251 *** Looping through 5.2. Iter = 2297 iteration 2297; minNextMutationTime = 1972.7; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 116 *** Looping through 5.2. Iter = 2298 iteration 2298; minNextMutationTime = 1972.73; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 118 *** Looping through 5.2. Iter = 2299 iteration 2299; minNextMutationTime = 1972.77; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 114 *** Looping through 5.2. Iter = 2300 iteration 2300; minNextMutationTime = 1972.83; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 70 *** Looping through 5.2. Iter = 2301 iteration 2301; minNextMutationTime = 1972.92; timeNextPopSample = 1973; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 121 *** Looping through 5.2. Iter = 2302 iteration 2302; minNextMutationTime = 1983; timeNextPopSample = 1973; popParams.size() = 9 We are SAMPLING at time 1973 *** Looping through 5.2. Iter = 2303 iteration 2303; minNextMutationTime = 1973; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2718 *** Looping through 5.2. Iter = 2304 iteration 2304; minNextMutationTime = 1973.12; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 128 *** Looping through 5.2. Iter = 2305 iteration 2305; minNextMutationTime = 1973.15; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 71 *** Looping through 5.2. Iter = 2306 iteration 2306; minNextMutationTime = 1973.18; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 254 *** Looping through 5.2. Iter = 2307 iteration 2307; minNextMutationTime = 1973.3; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 248 *** Looping through 5.2. Iter = 2308 iteration 2308; minNextMutationTime = 1973.43; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2801 *** Looping through 5.2. Iter = 2309 iteration 2309; minNextMutationTime = 1973.47; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 8 *** Looping through 5.2. Iter = 2310 iteration 2310; minNextMutationTime = 1973.6; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 31 *** Looping through 5.2. Iter = 2311 iteration 2311; minNextMutationTime = 1973.67; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2825 *** Looping through 5.2. Iter = 2312 iteration 2312; minNextMutationTime = 1973.8; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 33 *** Looping through 5.2. Iter = 2313 iteration 2313; minNextMutationTime = 1973.86; timeNextPopSample = 1974; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 136 *** Looping through 5.2. Iter = 2314 iteration 2314; minNextMutationTime = 1984; timeNextPopSample = 1974; popParams.size() = 9 We are SAMPLING at time 1974 *** Looping through 5.2. Iter = 2315 iteration 2315; minNextMutationTime = 1974.01; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 11 *** Looping through 5.2. Iter = 2316 iteration 2316; minNextMutationTime = 1974.04; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 141 *** Looping through 5.2. Iter = 2317 iteration 2317; minNextMutationTime = 1974.05; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 12 *** Looping through 5.2. Iter = 2318 iteration 2318; minNextMutationTime = 1974.09; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 75 *** Looping through 5.2. Iter = 2319 iteration 2319; minNextMutationTime = 1974.24; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 35 *** Looping through 5.2. Iter = 2320 iteration 2320; minNextMutationTime = 1974.37; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 47 *** Looping through 5.2. Iter = 2321 iteration 2321; minNextMutationTime = 1974.44; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 260 *** Looping through 5.2. Iter = 2322 iteration 2322; minNextMutationTime = 1974.49; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 2985 *** Looping through 5.2. Iter = 2323 iteration 2323; minNextMutationTime = 1974.66; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 53 *** Looping through 5.2. Iter = 2324 iteration 2324; minNextMutationTime = 1974.69; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 262 *** Looping through 5.2. Iter = 2325 iteration 2325; minNextMutationTime = 1974.7; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 77 *** Looping through 5.2. Iter = 2326 iteration 2326; minNextMutationTime = 1974.72; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 13 *** Looping through 5.2. Iter = 2327 iteration 2327; minNextMutationTime = 1974.79; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 142 *** Looping through 5.2. Iter = 2328 iteration 2328; minNextMutationTime = 1974.87; timeNextPopSample = 1975; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 57 *** Looping through 5.2. Iter = 2329 iteration 2329; minNextMutationTime = 1985; timeNextPopSample = 1975; popParams.size() = 9 We are SAMPLING at time 1975 *** Looping through 5.2. Iter = 2330 iteration 2330; minNextMutationTime = 1975.12; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 142 *** Looping through 5.2. Iter = 2331 iteration 2331; minNextMutationTime = 1975.32; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 51 *** Looping through 5.2. Iter = 2332 iteration 2332; minNextMutationTime = 1975.37; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 15 *** Looping through 5.2. Iter = 2333 iteration 2333; minNextMutationTime = 1975.43; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 17 *** Looping through 5.2. Iter = 2334 iteration 2334; minNextMutationTime = 1975.48; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3109 *** Looping through 5.2. Iter = 2335 iteration 2335; minNextMutationTime = 1975.58; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 288 *** Looping through 5.2. Iter = 2336 iteration 2336; minNextMutationTime = 1975.64; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 84 *** Looping through 5.2. Iter = 2337 iteration 2337; minNextMutationTime = 1975.74; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 151 *** Looping through 5.2. Iter = 2338 iteration 2338; minNextMutationTime = 1975.77; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 148 *** Looping through 5.2. Iter = 2339 iteration 2339; minNextMutationTime = 1975.77; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3108 *** Looping through 5.2. Iter = 2340 iteration 2340; minNextMutationTime = 1975.78; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 290 *** Looping through 5.2. Iter = 2341 iteration 2341; minNextMutationTime = 1975.82; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 149 *** Looping through 5.2. Iter = 2342 iteration 2342; minNextMutationTime = 1975.9; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 153 *** Looping through 5.2. Iter = 2343 iteration 2343; minNextMutationTime = 1975.94; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3124 *** Looping through 5.2. Iter = 2344 iteration 2344; minNextMutationTime = 1975.94; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 18 *** Looping through 5.2. Iter = 2345 iteration 2345; minNextMutationTime = 1975.96; timeNextPopSample = 1976; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 291 *** Looping through 5.2. Iter = 2346 iteration 2346; minNextMutationTime = 1986; timeNextPopSample = 1976; popParams.size() = 9 We are SAMPLING at time 1976 *** Looping through 5.2. Iter = 2347 iteration 2347; minNextMutationTime = 1976.01; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3166 *** Looping through 5.2. Iter = 2348 iteration 2348; minNextMutationTime = 1976.06; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 159 *** Looping through 5.2. Iter = 2349 iteration 2349; minNextMutationTime = 1976.11; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 22 *** Looping through 5.2. Iter = 2350 iteration 2350; minNextMutationTime = 1976.19; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 300 *** Looping through 5.2. Iter = 2351 iteration 2351; minNextMutationTime = 1976.25; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 24 *** Looping through 5.2. Iter = 2352 iteration 2352; minNextMutationTime = 1976.31; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3190 *** Looping through 5.2. Iter = 2353 iteration 2353; minNextMutationTime = 1976.35; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 165 *** Looping through 5.2. Iter = 2354 iteration 2354; minNextMutationTime = 1976.37; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 52 *** Looping through 5.2. Iter = 2355 iteration 2355; minNextMutationTime = 1976.42; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 88 *** Looping through 5.2. Iter = 2356 iteration 2356; minNextMutationTime = 1976.47; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 25 *** Looping through 5.2. Iter = 2357 iteration 2357; minNextMutationTime = 1976.65; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3354 *** Looping through 5.2. Iter = 2358 iteration 2358; minNextMutationTime = 1976.68; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3383 *** Looping through 5.2. Iter = 2359 iteration 2359; minNextMutationTime = 1976.71; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 88 *** Looping through 5.2. Iter = 2360 iteration 2360; minNextMutationTime = 1976.72; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 54 *** Looping through 5.2. Iter = 2361 iteration 2361; minNextMutationTime = 1976.74; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 91 *** Looping through 5.2. Iter = 2362 iteration 2362; minNextMutationTime = 1976.75; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 164 *** Looping through 5.2. Iter = 2363 iteration 2363; minNextMutationTime = 1976.77; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3404 *** Looping through 5.2. Iter = 2364 iteration 2364; minNextMutationTime = 1976.86; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 25 *** Looping through 5.2. Iter = 2365 iteration 2365; minNextMutationTime = 1976.88; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 165 *** Looping through 5.2. Iter = 2366 iteration 2366; minNextMutationTime = 1976.96; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 53 *** Looping through 5.2. Iter = 2367 iteration 2367; minNextMutationTime = 1976.97; timeNextPopSample = 1977; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 95 *** Looping through 5.2. Iter = 2368 iteration 2368; minNextMutationTime = 1987; timeNextPopSample = 1977; popParams.size() = 9 We are SAMPLING at time 1977 *** Looping through 5.2. Iter = 2369 iteration 2369; minNextMutationTime = 1977.04; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 169 *** Looping through 5.2. Iter = 2370 iteration 2370; minNextMutationTime = 1977.05; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 30 *** Looping through 5.2. Iter = 2371 iteration 2371; minNextMutationTime = 1977.15; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 31 *** Looping through 5.2. Iter = 2372 iteration 2372; minNextMutationTime = 1977.26; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 33 *** Looping through 5.2. Iter = 2373 iteration 2373; minNextMutationTime = 1977.27; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 170 *** Looping through 5.2. Iter = 2374 iteration 2374; minNextMutationTime = 1977.29; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3455 *** Looping through 5.2. Iter = 2375 iteration 2375; minNextMutationTime = 1977.39; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3459 *** Looping through 5.2. Iter = 2376 iteration 2376; minNextMutationTime = 1977.51; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 162 *** Looping through 5.2. Iter = 2377 iteration 2377; minNextMutationTime = 1977.52; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3462 *** Looping through 5.2. Iter = 2378 iteration 2378; minNextMutationTime = 1977.52; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 55 *** Looping through 5.2. Iter = 2379 iteration 2379; minNextMutationTime = 1977.54; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 35 *** Looping through 5.2. Iter = 2380 iteration 2380; minNextMutationTime = 1977.55; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 95 *** Looping through 5.2. Iter = 2381 iteration 2381; minNextMutationTime = 1977.57; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 163 *** Looping through 5.2. Iter = 2382 iteration 2382; minNextMutationTime = 1977.61; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 97 *** Looping through 5.2. Iter = 2383 iteration 2383; minNextMutationTime = 1977.66; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 36 *** Looping through 5.2. Iter = 2384 iteration 2384; minNextMutationTime = 1977.73; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 56 *** Looping through 5.2. Iter = 2385 iteration 2385; minNextMutationTime = 1977.74; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 37 *** Looping through 5.2. Iter = 2386 iteration 2386; minNextMutationTime = 1977.74; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 98 *** Looping through 5.2. Iter = 2387 iteration 2387; minNextMutationTime = 1977.83; timeNextPopSample = 1978; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 40 *** Looping through 5.2. Iter = 2388 iteration 2388; minNextMutationTime = 1988; timeNextPopSample = 1978; popParams.size() = 9 We are SAMPLING at time 1978 *** Looping through 5.2. Iter = 2389 iteration 2389; minNextMutationTime = 1978.06; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 296 *** Looping through 5.2. Iter = 2390 iteration 2390; minNextMutationTime = 1978.09; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 301 *** Looping through 5.2. Iter = 2391 iteration 2391; minNextMutationTime = 1978.25; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 322 *** Looping through 5.2. Iter = 2392 iteration 2392; minNextMutationTime = 1978.36; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3583 *** Looping through 5.2. Iter = 2393 iteration 2393; minNextMutationTime = 1978.44; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 179 *** Looping through 5.2. Iter = 2394 iteration 2394; minNextMutationTime = 1978.47; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 105 *** Looping through 5.2. Iter = 2395 iteration 2395; minNextMutationTime = 1978.5; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 180 *** Looping through 5.2. Iter = 2396 iteration 2396; minNextMutationTime = 1978.53; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 185 *** Looping through 5.2. Iter = 2397 iteration 2397; minNextMutationTime = 1978.58; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 110 *** Looping through 5.2. Iter = 2398 iteration 2398; minNextMutationTime = 1978.62; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 109 *** Looping through 5.2. Iter = 2399 iteration 2399; minNextMutationTime = 1978.69; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3600 *** Looping through 5.2. Iter = 2400 iteration 2400; minNextMutationTime = 1978.69; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 319 *** Looping through 5.2. Iter = 2401 iteration 2401; minNextMutationTime = 1978.73; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 57 *** Looping through 5.2. Iter = 2402 iteration 2402; minNextMutationTime = 1978.75; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3605 *** Looping through 5.2. Iter = 2403 iteration 2403; minNextMutationTime = 1978.82; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 110 *** Looping through 5.2. Iter = 2404 iteration 2404; minNextMutationTime = 1978.86; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3638 *** Looping through 5.2. Iter = 2405 iteration 2405; minNextMutationTime = 1978.88; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 60 *** Looping through 5.2. Iter = 2406 iteration 2406; minNextMutationTime = 1978.89; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 62 *** Looping through 5.2. Iter = 2407 iteration 2407; minNextMutationTime = 1978.9; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 320 *** Looping through 5.2. Iter = 2408 iteration 2408; minNextMutationTime = 1978.91; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 111 *** Looping through 5.2. Iter = 2409 iteration 2409; minNextMutationTime = 1978.92; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 61 *** Looping through 5.2. Iter = 2410 iteration 2410; minNextMutationTime = 1978.93; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 188 *** Looping through 5.2. Iter = 2411 iteration 2411; minNextMutationTime = 1978.94; timeNextPopSample = 1979; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 61 *** Looping through 5.2. Iter = 2412 iteration 2412; minNextMutationTime = 1989; timeNextPopSample = 1979; popParams.size() = 9 We are SAMPLING at time 1979 *** Looping through 5.2. Iter = 2413 iteration 2413; minNextMutationTime = 1979.08; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 332 *** Looping through 5.2. Iter = 2414 iteration 2414; minNextMutationTime = 1979.13; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 114 *** Looping through 5.2. Iter = 2415 iteration 2415; minNextMutationTime = 1979.13; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 43 *** Looping through 5.2. Iter = 2416 iteration 2416; minNextMutationTime = 1979.15; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 114 *** Looping through 5.2. Iter = 2417 iteration 2417; minNextMutationTime = 1979.23; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 68 *** Looping through 5.2. Iter = 2418 iteration 2418; minNextMutationTime = 1979.25; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 198 *** Looping through 5.2. Iter = 2419 iteration 2419; minNextMutationTime = 1979.29; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 205 *** Looping through 5.2. Iter = 2420 iteration 2420; minNextMutationTime = 1979.33; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 338 *** Looping through 5.2. Iter = 2421 iteration 2421; minNextMutationTime = 1979.43; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 74 *** Looping through 5.2. Iter = 2422 iteration 2422; minNextMutationTime = 1979.43; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3695 *** Looping through 5.2. Iter = 2423 iteration 2423; minNextMutationTime = 1979.52; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 42 *** Looping through 5.2. Iter = 2424 iteration 2424; minNextMutationTime = 1979.55; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 342 *** Looping through 5.2. Iter = 2425 iteration 2425; minNextMutationTime = 1979.6; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 117 *** Looping through 5.2. Iter = 2426 iteration 2426; minNextMutationTime = 1979.63; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 211 *** Looping through 5.2. Iter = 2427 iteration 2427; minNextMutationTime = 1979.68; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 78 *** Looping through 5.2. Iter = 2428 iteration 2428; minNextMutationTime = 1979.78; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 215 *** Looping through 5.2. Iter = 2429 iteration 2429; minNextMutationTime = 1979.78; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 342 *** Looping through 5.2. Iter = 2430 iteration 2430; minNextMutationTime = 1979.83; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3751 *** Looping through 5.2. Iter = 2431 iteration 2431; minNextMutationTime = 1979.85; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 342 *** Looping through 5.2. Iter = 2432 iteration 2432; minNextMutationTime = 1979.87; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 44 *** Looping through 5.2. Iter = 2433 iteration 2433; minNextMutationTime = 1979.87; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 45 *** Looping through 5.2. Iter = 2434 iteration 2434; minNextMutationTime = 1979.89; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 48 *** Looping through 5.2. Iter = 2435 iteration 2435; minNextMutationTime = 1979.92; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 351 *** Looping through 5.2. Iter = 2436 iteration 2436; minNextMutationTime = 1979.95; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 51 *** Looping through 5.2. Iter = 2437 iteration 2437; minNextMutationTime = 1979.98; timeNextPopSample = 1980; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 353 *** Looping through 5.2. Iter = 2438 iteration 2438; minNextMutationTime = 1990; timeNextPopSample = 1980; popParams.size() = 9 We are SAMPLING at time 1980 *** Looping through 5.2. Iter = 2439 iteration 2439; minNextMutationTime = 1980.01; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3787 *** Looping through 5.2. Iter = 2440 iteration 2440; minNextMutationTime = 1980.04; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 354 *** Looping through 5.2. Iter = 2441 iteration 2441; minNextMutationTime = 1980.11; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 222 *** Looping through 5.2. Iter = 2442 iteration 2442; minNextMutationTime = 1980.17; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3856 *** Looping through 5.2. Iter = 2443 iteration 2443; minNextMutationTime = 1980.19; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 356 *** Looping through 5.2. Iter = 2444 iteration 2444; minNextMutationTime = 1980.27; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3925 *** Looping through 5.2. Iter = 2445 iteration 2445; minNextMutationTime = 1980.29; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 223 *** Looping through 5.2. Iter = 2446 iteration 2446; minNextMutationTime = 1980.34; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 3967 *** Looping through 5.2. Iter = 2447 iteration 2447; minNextMutationTime = 1980.43; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 117 *** Looping through 5.2. Iter = 2448 iteration 2448; minNextMutationTime = 1980.44; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 79 *** Looping through 5.2. Iter = 2449 iteration 2449; minNextMutationTime = 1980.5; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 370 *** Looping through 5.2. Iter = 2450 iteration 2450; minNextMutationTime = 1980.56; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4018 *** Looping through 5.2. Iter = 2451 iteration 2451; minNextMutationTime = 1980.57; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 225 *** Looping through 5.2. Iter = 2452 iteration 2452; minNextMutationTime = 1980.59; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 78 *** Looping through 5.2. Iter = 2453 iteration 2453; minNextMutationTime = 1980.61; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 117 *** Looping through 5.2. Iter = 2454 iteration 2454; minNextMutationTime = 1980.65; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 121 *** Looping through 5.2. Iter = 2455 iteration 2455; minNextMutationTime = 1980.7; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 219 *** Looping through 5.2. Iter = 2456 iteration 2456; minNextMutationTime = 1980.72; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4051 *** Looping through 5.2. Iter = 2457 iteration 2457; minNextMutationTime = 1980.73; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 122 *** Looping through 5.2. Iter = 2458 iteration 2458; minNextMutationTime = 1980.78; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 51 *** Looping through 5.2. Iter = 2459 iteration 2459; minNextMutationTime = 1980.81; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4094 *** Looping through 5.2. Iter = 2460 iteration 2460; minNextMutationTime = 1980.89; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 206 *** Looping through 5.2. Iter = 2461 iteration 2461; minNextMutationTime = 1980.92; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 375 *** Looping through 5.2. Iter = 2462 iteration 2462; minNextMutationTime = 1981; timeNextPopSample = 1981; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 204 *** Looping through 5.2. Iter = 2463 iteration 2463; minNextMutationTime = 1991; timeNextPopSample = 1981; popParams.size() = 9 We are SAMPLING at time 1981 *** Looping through 5.2. Iter = 2464 iteration 2464; minNextMutationTime = 1981.01; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 377 *** Looping through 5.2. Iter = 2465 iteration 2465; minNextMutationTime = 1981.03; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 378 *** Looping through 5.2. Iter = 2466 iteration 2466; minNextMutationTime = 1981.08; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 207 *** Looping through 5.2. Iter = 2467 iteration 2467; minNextMutationTime = 1981.11; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 53 *** Looping through 5.2. Iter = 2468 iteration 2468; minNextMutationTime = 1981.13; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 52 *** Looping through 5.2. Iter = 2469 iteration 2469; minNextMutationTime = 1981.34; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 348 *** Looping through 5.2. Iter = 2470 iteration 2470; minNextMutationTime = 1981.35; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 122 *** Looping through 5.2. Iter = 2471 iteration 2471; minNextMutationTime = 1981.35; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 123 *** Looping through 5.2. Iter = 2472 iteration 2472; minNextMutationTime = 1981.36; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 80 *** Looping through 5.2. Iter = 2473 iteration 2473; minNextMutationTime = 1981.39; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4146 *** Looping through 5.2. Iter = 2474 iteration 2474; minNextMutationTime = 1981.41; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 52 *** Looping through 5.2. Iter = 2475 iteration 2475; minNextMutationTime = 1981.41; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 353 *** Looping through 5.2. Iter = 2476 iteration 2476; minNextMutationTime = 1981.45; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 122 *** Looping through 5.2. Iter = 2477 iteration 2477; minNextMutationTime = 1981.45; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 124 *** Looping through 5.2. Iter = 2478 iteration 2478; minNextMutationTime = 1981.47; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 84 *** Looping through 5.2. Iter = 2479 iteration 2479; minNextMutationTime = 1981.52; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4180 *** Looping through 5.2. Iter = 2480 iteration 2480; minNextMutationTime = 1981.54; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4182 *** Looping through 5.2. Iter = 2481 iteration 2481; minNextMutationTime = 1981.61; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 361 *** Looping through 5.2. Iter = 2482 iteration 2482; minNextMutationTime = 1981.63; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4203 *** Looping through 5.2. Iter = 2483 iteration 2483; minNextMutationTime = 1981.68; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 51 *** Looping through 5.2. Iter = 2484 iteration 2484; minNextMutationTime = 1981.69; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 52 *** Looping through 5.2. Iter = 2485 iteration 2485; minNextMutationTime = 1981.7; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 212 *** Looping through 5.2. Iter = 2486 iteration 2486; minNextMutationTime = 1981.72; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 87 *** Looping through 5.2. Iter = 2487 iteration 2487; minNextMutationTime = 1981.75; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4226 *** Looping through 5.2. Iter = 2488 iteration 2488; minNextMutationTime = 1981.8; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 89 *** Looping through 5.2. Iter = 2489 iteration 2489; minNextMutationTime = 1981.87; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4281 *** Looping through 5.2. Iter = 2490 iteration 2490; minNextMutationTime = 1981.91; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 124 *** Looping through 5.2. Iter = 2491 iteration 2491; minNextMutationTime = 1981.93; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 125 *** Looping through 5.2. Iter = 2492 iteration 2492; minNextMutationTime = 1981.96; timeNextPopSample = 1982; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 219 *** Looping through 5.2. Iter = 2493 iteration 2493; minNextMutationTime = 1992; timeNextPopSample = 1982; popParams.size() = 9 We are SAMPLING at time 1982 *** Looping through 5.2. Iter = 2494 iteration 2494; minNextMutationTime = 1982; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 128 *** Looping through 5.2. Iter = 2495 iteration 2495; minNextMutationTime = 1982.02; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 127 *** Looping through 5.2. Iter = 2496 iteration 2496; minNextMutationTime = 1982.11; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 48 *** Looping through 5.2. Iter = 2497 iteration 2497; minNextMutationTime = 1982.11; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 361 *** Looping through 5.2. Iter = 2498 iteration 2498; minNextMutationTime = 1982.13; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 91 *** Looping through 5.2. Iter = 2499 iteration 2499; minNextMutationTime = 1982.18; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 367 *** Looping through 5.2. Iter = 2500 iteration 2500; minNextMutationTime = 1982.18; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 225 *** Looping through 5.2. Iter = 2501 iteration 2501; minNextMutationTime = 1982.22; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 92 *** Looping through 5.2. Iter = 2502 iteration 2502; minNextMutationTime = 1982.23; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 129 *** Looping through 5.2. Iter = 2503 iteration 2503; minNextMutationTime = 1982.24; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4326 *** Looping through 5.2. Iter = 2504 iteration 2504; minNextMutationTime = 1982.28; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 222 *** Looping through 5.2. Iter = 2505 iteration 2505; minNextMutationTime = 1982.29; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4337 *** Looping through 5.2. Iter = 2506 iteration 2506; minNextMutationTime = 1982.31; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 129 *** Looping through 5.2. Iter = 2507 iteration 2507; minNextMutationTime = 1982.32; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 129 *** Looping through 5.2. Iter = 2508 iteration 2508; minNextMutationTime = 1982.32; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 224 *** Looping through 5.2. Iter = 2509 iteration 2509; minNextMutationTime = 1982.36; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 88 *** Looping through 5.2. Iter = 2510 iteration 2510; minNextMutationTime = 1982.36; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 89 *** Looping through 5.2. Iter = 2511 iteration 2511; minNextMutationTime = 1982.4; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 232 *** Looping through 5.2. Iter = 2512 iteration 2512; minNextMutationTime = 1982.47; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 48 *** Looping through 5.2. Iter = 2513 iteration 2513; minNextMutationTime = 1982.47; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 369 *** Looping through 5.2. Iter = 2514 iteration 2514; minNextMutationTime = 1982.48; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 232 *** Looping through 5.2. Iter = 2515 iteration 2515; minNextMutationTime = 1982.5; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 91 *** Looping through 5.2. Iter = 2516 iteration 2516; minNextMutationTime = 1982.54; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 49 *** Looping through 5.2. Iter = 2517 iteration 2517; minNextMutationTime = 1982.57; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 52 *** Looping through 5.2. Iter = 2518 iteration 2518; minNextMutationTime = 1982.58; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 233 *** Looping through 5.2. Iter = 2519 iteration 2519; minNextMutationTime = 1982.59; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 237 *** Looping through 5.2. Iter = 2520 iteration 2520; minNextMutationTime = 1982.61; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 237 *** Looping through 5.2. Iter = 2521 iteration 2521; minNextMutationTime = 1982.64; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 235 *** Looping through 5.2. Iter = 2522 iteration 2522; minNextMutationTime = 1982.64; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 129 *** Looping through 5.2. Iter = 2523 iteration 2523; minNextMutationTime = 1982.65; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 128 *** Looping through 5.2. Iter = 2524 iteration 2524; minNextMutationTime = 1982.71; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4374 *** Looping through 5.2. Iter = 2525 iteration 2525; minNextMutationTime = 1982.73; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 53 *** Looping through 5.2. Iter = 2526 iteration 2526; minNextMutationTime = 1982.76; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 130 *** Looping through 5.2. Iter = 2527 iteration 2527; minNextMutationTime = 1982.77; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 55 *** Looping through 5.2. Iter = 2528 iteration 2528; minNextMutationTime = 1982.8; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 234 *** Looping through 5.2. Iter = 2529 iteration 2529; minNextMutationTime = 1982.81; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 91 *** Looping through 5.2. Iter = 2530 iteration 2530; minNextMutationTime = 1982.82; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4388 *** Looping through 5.2. Iter = 2531 iteration 2531; minNextMutationTime = 1982.93; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 84 *** Looping through 5.2. Iter = 2532 iteration 2532; minNextMutationTime = 1982.97; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 132 *** Looping through 5.2. Iter = 2533 iteration 2533; minNextMutationTime = 1982.99; timeNextPopSample = 1983; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 83 *** Looping through 5.2. Iter = 2534 iteration 2534; minNextMutationTime = 1993; timeNextPopSample = 1983; popParams.size() = 9 We are SAMPLING at time 1983 *** Looping through 5.2. Iter = 2535 iteration 2535; minNextMutationTime = 1983.04; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 384 *** Looping through 5.2. Iter = 2536 iteration 2536; minNextMutationTime = 1983.08; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 242 *** Looping through 5.2. Iter = 2537 iteration 2537; minNextMutationTime = 1983.14; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4443 *** Looping through 5.2. Iter = 2538 iteration 2538; minNextMutationTime = 1983.17; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 242 *** Looping through 5.2. Iter = 2539 iteration 2539; minNextMutationTime = 1983.17; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4447 *** Looping through 5.2. Iter = 2540 iteration 2540; minNextMutationTime = 1983.29; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 80 *** Looping through 5.2. Iter = 2541 iteration 2541; minNextMutationTime = 1983.33; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 139 *** Looping through 5.2. Iter = 2542 iteration 2542; minNextMutationTime = 1983.39; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4522 *** Looping through 5.2. Iter = 2543 iteration 2543; minNextMutationTime = 1983.4; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4535 *** Looping through 5.2. Iter = 2544 iteration 2544; minNextMutationTime = 1983.43; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 83 *** Looping through 5.2. Iter = 2545 iteration 2545; minNextMutationTime = 1983.44; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 141 *** Looping through 5.2. Iter = 2546 iteration 2546; minNextMutationTime = 1983.5; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 58 *** Looping through 5.2. Iter = 2547 iteration 2547; minNextMutationTime = 1983.52; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4562 *** Looping through 5.2. Iter = 2548 iteration 2548; minNextMutationTime = 1983.53; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4564 *** Looping through 5.2. Iter = 2549 iteration 2549; minNextMutationTime = 1983.57; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 251 *** Looping through 5.2. Iter = 2550 iteration 2550; minNextMutationTime = 1983.73; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 64 *** Looping through 5.2. Iter = 2551 iteration 2551; minNextMutationTime = 1983.73; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 385 *** Looping through 5.2. Iter = 2552 iteration 2552; minNextMutationTime = 1983.78; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 257 *** Looping through 5.2. Iter = 2553 iteration 2553; minNextMutationTime = 1983.86; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4649 *** Looping through 5.2. Iter = 2554 iteration 2554; minNextMutationTime = 1983.88; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 63 *** Looping through 5.2. Iter = 2555 iteration 2555; minNextMutationTime = 1983.89; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 63 *** Looping through 5.2. Iter = 2556 iteration 2556; minNextMutationTime = 1983.91; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 86 *** Looping through 5.2. Iter = 2557 iteration 2557; minNextMutationTime = 1983.91; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 142 *** Looping through 5.2. Iter = 2558 iteration 2558; minNextMutationTime = 1983.92; timeNextPopSample = 1984; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 88 *** Looping through 5.2. Iter = 2559 iteration 2559; minNextMutationTime = 1994; timeNextPopSample = 1984; popParams.size() = 9 We are SAMPLING at time 1984 *** Looping through 5.2. Iter = 2560 iteration 2560; minNextMutationTime = 1984.01; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4782 *** Looping through 5.2. Iter = 2561 iteration 2561; minNextMutationTime = 1984.02; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 266 *** Looping through 5.2. Iter = 2562 iteration 2562; minNextMutationTime = 1984.04; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 399 *** Looping through 5.2. Iter = 2563 iteration 2563; minNextMutationTime = 1984.07; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 94 *** Looping through 5.2. Iter = 2564 iteration 2564; minNextMutationTime = 1984.1; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 271 *** Looping through 5.2. Iter = 2565 iteration 2565; minNextMutationTime = 1984.11; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 267 *** Looping through 5.2. Iter = 2566 iteration 2566; minNextMutationTime = 1984.13; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 265 *** Looping through 5.2. Iter = 2567 iteration 2567; minNextMutationTime = 1984.13; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 65 *** Looping through 5.2. Iter = 2568 iteration 2568; minNextMutationTime = 1984.16; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 97 *** Looping through 5.2. Iter = 2569 iteration 2569; minNextMutationTime = 1984.17; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4772 *** Looping through 5.2. Iter = 2570 iteration 2570; minNextMutationTime = 1984.17; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 98 *** Looping through 5.2. Iter = 2571 iteration 2571; minNextMutationTime = 1984.19; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 65 *** Looping through 5.2. Iter = 2572 iteration 2572; minNextMutationTime = 1984.2; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 145 *** Looping through 5.2. Iter = 2573 iteration 2573; minNextMutationTime = 1984.21; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 401 *** Looping through 5.2. Iter = 2574 iteration 2574; minNextMutationTime = 1984.23; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 98 *** Looping through 5.2. Iter = 2575 iteration 2575; minNextMutationTime = 1984.25; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 144 *** Looping through 5.2. Iter = 2576 iteration 2576; minNextMutationTime = 1984.27; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 67 *** Looping through 5.2. Iter = 2577 iteration 2577; minNextMutationTime = 1984.27; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 68 *** Looping through 5.2. Iter = 2578 iteration 2578; minNextMutationTime = 1984.27; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 145 *** Looping through 5.2. Iter = 2579 iteration 2579; minNextMutationTime = 1984.29; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 100 *** Looping through 5.2. Iter = 2580 iteration 2580; minNextMutationTime = 1984.38; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4825 *** Looping through 5.2. Iter = 2581 iteration 2581; minNextMutationTime = 1984.39; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 146 *** Looping through 5.2. Iter = 2582 iteration 2582; minNextMutationTime = 1984.42; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 146 *** Looping through 5.2. Iter = 2583 iteration 2583; minNextMutationTime = 1984.48; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 406 *** Looping through 5.2. Iter = 2584 iteration 2584; minNextMutationTime = 1984.51; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 404 *** Looping through 5.2. Iter = 2585 iteration 2585; minNextMutationTime = 1984.58; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 102 *** Looping through 5.2. Iter = 2586 iteration 2586; minNextMutationTime = 1984.6; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 68 *** Looping through 5.2. Iter = 2587 iteration 2587; minNextMutationTime = 1984.62; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 68 *** Looping through 5.2. Iter = 2588 iteration 2588; minNextMutationTime = 1984.62; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 266 *** Looping through 5.2. Iter = 2589 iteration 2589; minNextMutationTime = 1984.64; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 69 *** Looping through 5.2. Iter = 2590 iteration 2590; minNextMutationTime = 1984.64; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 70 *** Looping through 5.2. Iter = 2591 iteration 2591; minNextMutationTime = 1984.65; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 103 *** Looping through 5.2. Iter = 2592 iteration 2592; minNextMutationTime = 1984.66; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 73 *** Looping through 5.2. Iter = 2593 iteration 2593; minNextMutationTime = 1984.67; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 75 *** Looping through 5.2. Iter = 2594 iteration 2594; minNextMutationTime = 1984.69; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 74 *** Looping through 5.2. Iter = 2595 iteration 2595; minNextMutationTime = 1984.7; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 397 *** Looping through 5.2. Iter = 2596 iteration 2596; minNextMutationTime = 1984.71; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 268 *** Looping through 5.2. Iter = 2597 iteration 2597; minNextMutationTime = 1984.72; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 103 *** Looping through 5.2. Iter = 2598 iteration 2598; minNextMutationTime = 1984.76; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 72 *** Looping through 5.2. Iter = 2599 iteration 2599; minNextMutationTime = 1984.78; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 106 *** Looping through 5.2. Iter = 2600 iteration 2600; minNextMutationTime = 1984.78; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 397 *** Looping through 5.2. Iter = 2601 iteration 2601; minNextMutationTime = 1984.81; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 397 *** Looping through 5.2. Iter = 2602 iteration 2602; minNextMutationTime = 1984.81; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 108 *** Looping through 5.2. Iter = 2603 iteration 2603; minNextMutationTime = 1984.81; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 146 *** Looping through 5.2. Iter = 2604 iteration 2604; minNextMutationTime = 1984.82; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 72 *** Looping through 5.2. Iter = 2605 iteration 2605; minNextMutationTime = 1984.82; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 74 *** Looping through 5.2. Iter = 2606 iteration 2606; minNextMutationTime = 1984.84; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 268 *** Looping through 5.2. Iter = 2607 iteration 2607; minNextMutationTime = 1984.84; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 109 *** Looping through 5.2. Iter = 2608 iteration 2608; minNextMutationTime = 1984.86; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 114 *** Looping through 5.2. Iter = 2609 iteration 2609; minNextMutationTime = 1984.88; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 401 *** Looping through 5.2. Iter = 2610 iteration 2610; minNextMutationTime = 1984.89; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 75 *** Looping through 5.2. Iter = 2611 iteration 2611; minNextMutationTime = 1984.89; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 402 *** Looping through 5.2. Iter = 2612 iteration 2612; minNextMutationTime = 1984.9; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 115 *** Looping through 5.2. Iter = 2613 iteration 2613; minNextMutationTime = 1984.91; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 118 *** Looping through 5.2. Iter = 2614 iteration 2614; minNextMutationTime = 1984.92; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 269 *** Looping through 5.2. Iter = 2615 iteration 2615; minNextMutationTime = 1984.92; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 148 *** Looping through 5.2. Iter = 2616 iteration 2616; minNextMutationTime = 1984.97; timeNextPopSample = 1985; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4844 *** Looping through 5.2. Iter = 2617 iteration 2617; minNextMutationTime = 1995; timeNextPopSample = 1985; popParams.size() = 9 We are SAMPLING at time 1985 *** Looping through 5.2. Iter = 2618 iteration 2618; minNextMutationTime = 1985; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 144 *** Looping through 5.2. Iter = 2619 iteration 2619; minNextMutationTime = 1985.04; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4882 *** Looping through 5.2. Iter = 2620 iteration 2620; minNextMutationTime = 1985.08; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 152 *** Looping through 5.2. Iter = 2621 iteration 2621; minNextMutationTime = 1985.15; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 282 *** Looping through 5.2. Iter = 2622 iteration 2622; minNextMutationTime = 1985.17; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 115 *** Looping through 5.2. Iter = 2623 iteration 2623; minNextMutationTime = 1985.22; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4967 *** Looping through 5.2. Iter = 2624 iteration 2624; minNextMutationTime = 1985.23; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 78 *** Looping through 5.2. Iter = 2625 iteration 2625; minNextMutationTime = 1985.25; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 81 *** Looping through 5.2. Iter = 2626 iteration 2626; minNextMutationTime = 1985.26; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 284 *** Looping through 5.2. Iter = 2627 iteration 2627; minNextMutationTime = 1985.27; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 285 *** Looping through 5.2. Iter = 2628 iteration 2628; minNextMutationTime = 1985.28; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 157 *** Looping through 5.2. Iter = 2629 iteration 2629; minNextMutationTime = 1985.28; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 82 *** Looping through 5.2. Iter = 2630 iteration 2630; minNextMutationTime = 1985.3; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 156 *** Looping through 5.2. Iter = 2631 iteration 2631; minNextMutationTime = 1985.3; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 83 *** Looping through 5.2. Iter = 2632 iteration 2632; minNextMutationTime = 1985.32; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 114 *** Looping through 5.2. Iter = 2633 iteration 2633; minNextMutationTime = 1985.41; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 290 *** Looping through 5.2. Iter = 2634 iteration 2634; minNextMutationTime = 1985.43; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 116 *** Looping through 5.2. Iter = 2635 iteration 2635; minNextMutationTime = 1985.44; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4968 *** Looping through 5.2. Iter = 2636 iteration 2636; minNextMutationTime = 1985.61; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 77 *** Looping through 5.2. Iter = 2637 iteration 2637; minNextMutationTime = 1985.66; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 294 *** Looping through 5.2. Iter = 2638 iteration 2638; minNextMutationTime = 1985.67; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 297 *** Looping through 5.2. Iter = 2639 iteration 2639; minNextMutationTime = 1985.69; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 116 *** Looping through 5.2. Iter = 2640 iteration 2640; minNextMutationTime = 1985.69; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4970 *** Looping through 5.2. Iter = 2641 iteration 2641; minNextMutationTime = 1985.73; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 412 *** Looping through 5.2. Iter = 2642 iteration 2642; minNextMutationTime = 1985.79; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 293 *** Looping through 5.2. Iter = 2643 iteration 2643; minNextMutationTime = 1985.82; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 293 *** Looping through 5.2. Iter = 2644 iteration 2644; minNextMutationTime = 1985.84; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 121 *** Looping through 5.2. Iter = 2645 iteration 2645; minNextMutationTime = 1985.84; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 413 *** Looping through 5.2. Iter = 2646 iteration 2646; minNextMutationTime = 1985.85; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 156 *** Looping through 5.2. Iter = 2647 iteration 2647; minNextMutationTime = 1985.88; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 118 *** Looping through 5.2. Iter = 2648 iteration 2648; minNextMutationTime = 1985.93; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 4986 *** Looping through 5.2. Iter = 2649 iteration 2649; minNextMutationTime = 1985.96; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 122 *** Looping through 5.2. Iter = 2650 iteration 2650; minNextMutationTime = 1985.98; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 158 *** Looping through 5.2. Iter = 2651 iteration 2651; minNextMutationTime = 1985.99; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 413 *** Looping through 5.2. Iter = 2652 iteration 2652; minNextMutationTime = 1985.99; timeNextPopSample = 1986; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 78 *** Looping through 5.2. Iter = 2653 iteration 2653; minNextMutationTime = 1996; timeNextPopSample = 1986; popParams.size() = 9 We are SAMPLING at time 1986 *** Looping through 5.2. Iter = 2654 iteration 2654; minNextMutationTime = 1986.02; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 418 *** Looping through 5.2. Iter = 2655 iteration 2655; minNextMutationTime = 1986.06; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 121 *** Looping through 5.2. Iter = 2656 iteration 2656; minNextMutationTime = 1986.06; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 296 *** Looping through 5.2. Iter = 2657 iteration 2657; minNextMutationTime = 1986.07; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 80 *** Looping through 5.2. Iter = 2658 iteration 2658; minNextMutationTime = 1986.08; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 80 *** Looping through 5.2. Iter = 2659 iteration 2659; minNextMutationTime = 1986.1; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 85 *** Looping through 5.2. Iter = 2660 iteration 2660; minNextMutationTime = 1986.13; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 123 *** Looping through 5.2. Iter = 2661 iteration 2661; minNextMutationTime = 1986.14; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 297 *** Looping through 5.2. Iter = 2662 iteration 2662; minNextMutationTime = 1986.15; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5014 *** Looping through 5.2. Iter = 2663 iteration 2663; minNextMutationTime = 1986.16; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 125 *** Looping through 5.2. Iter = 2664 iteration 2664; minNextMutationTime = 1986.16; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 86 *** Looping through 5.2. Iter = 2665 iteration 2665; minNextMutationTime = 1986.17; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 298 *** Looping through 5.2. Iter = 2666 iteration 2666; minNextMutationTime = 1986.18; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 421 *** Looping through 5.2. Iter = 2667 iteration 2667; minNextMutationTime = 1986.2; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5043 *** Looping through 5.2. Iter = 2668 iteration 2668; minNextMutationTime = 1986.22; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 157 *** Looping through 5.2. Iter = 2669 iteration 2669; minNextMutationTime = 1986.28; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 84 *** Looping through 5.2. Iter = 2670 iteration 2670; minNextMutationTime = 1986.29; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 418 *** Looping through 5.2. Iter = 2671 iteration 2671; minNextMutationTime = 1986.29; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5044 *** Looping through 5.2. Iter = 2672 iteration 2672; minNextMutationTime = 1986.29; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5047 *** Looping through 5.2. Iter = 2673 iteration 2673; minNextMutationTime = 1986.3; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 420 *** Looping through 5.2. Iter = 2674 iteration 2674; minNextMutationTime = 1986.31; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 159 *** Looping through 5.2. Iter = 2675 iteration 2675; minNextMutationTime = 1986.31; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 85 *** Looping through 5.2. Iter = 2676 iteration 2676; minNextMutationTime = 1986.34; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 87 *** Looping through 5.2. Iter = 2677 iteration 2677; minNextMutationTime = 1986.37; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 91 *** Looping through 5.2. Iter = 2678 iteration 2678; minNextMutationTime = 1986.39; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 96 *** Looping through 5.2. Iter = 2679 iteration 2679; minNextMutationTime = 1986.41; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 127 *** Looping through 5.2. Iter = 2680 iteration 2680; minNextMutationTime = 1986.45; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 127 *** Looping through 5.2. Iter = 2681 iteration 2681; minNextMutationTime = 1986.46; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 160 *** Looping through 5.2. Iter = 2682 iteration 2682; minNextMutationTime = 1986.54; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 160 *** Looping through 5.2. Iter = 2683 iteration 2683; minNextMutationTime = 1986.56; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 98 *** Looping through 5.2. Iter = 2684 iteration 2684; minNextMutationTime = 1986.57; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 159 *** Looping through 5.2. Iter = 2685 iteration 2685; minNextMutationTime = 1986.59; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 128 *** Looping through 5.2. Iter = 2686 iteration 2686; minNextMutationTime = 1986.6; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5061 *** Looping through 5.2. Iter = 2687 iteration 2687; minNextMutationTime = 1986.63; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 98 *** Looping through 5.2. Iter = 2688 iteration 2688; minNextMutationTime = 1986.66; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5113 *** Looping through 5.2. Iter = 2689 iteration 2689; minNextMutationTime = 1986.67; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 430 *** Looping through 5.2. Iter = 2690 iteration 2690; minNextMutationTime = 1986.68; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 435 *** Looping through 5.2. Iter = 2691 iteration 2691; minNextMutationTime = 1986.71; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 434 *** Looping through 5.2. Iter = 2692 iteration 2692; minNextMutationTime = 1986.73; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5116 *** Looping through 5.2. Iter = 2693 iteration 2693; minNextMutationTime = 1986.74; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 437 *** Looping through 5.2. Iter = 2694 iteration 2694; minNextMutationTime = 1986.74; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 297 *** Looping through 5.2. Iter = 2695 iteration 2695; minNextMutationTime = 1986.82; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 458 *** Looping through 5.2. Iter = 2696 iteration 2696; minNextMutationTime = 1986.84; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 96 *** Looping through 5.2. Iter = 2697 iteration 2697; minNextMutationTime = 1986.86; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 131 *** Looping through 5.2. Iter = 2698 iteration 2698; minNextMutationTime = 1986.9; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5195 *** Looping through 5.2. Iter = 2699 iteration 2699; minNextMutationTime = 1986.91; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 299 *** Looping through 5.2. Iter = 2700 iteration 2700; minNextMutationTime = 1986.92; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5190 *** Looping through 5.2. Iter = 2701 iteration 2701; minNextMutationTime = 1986.92; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 301 *** Looping through 5.2. Iter = 2702 iteration 2702; minNextMutationTime = 1986.95; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 132 *** Looping through 5.2. Iter = 2703 iteration 2703; minNextMutationTime = 1986.95; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 133 *** Looping through 5.2. Iter = 2704 iteration 2704; minNextMutationTime = 1986.95; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 302 *** Looping through 5.2. Iter = 2705 iteration 2705; minNextMutationTime = 1986.95; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 459 *** Looping through 5.2. Iter = 2706 iteration 2706; minNextMutationTime = 1986.95; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 460 *** Looping through 5.2. Iter = 2707 iteration 2707; minNextMutationTime = 1986.96; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 135 *** Looping through 5.2. Iter = 2708 iteration 2708; minNextMutationTime = 1986.98; timeNextPopSample = 1987; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 98 *** Looping through 5.2. Iter = 2709 iteration 2709; minNextMutationTime = 1997; timeNextPopSample = 1987; popParams.size() = 9 We are SAMPLING at time 1987 *** Looping through 5.2. Iter = 2710 iteration 2710; minNextMutationTime = 1987; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 309 *** Looping through 5.2. Iter = 2711 iteration 2711; minNextMutationTime = 1987.03; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 102 *** Looping through 5.2. Iter = 2712 iteration 2712; minNextMutationTime = 1987.04; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 309 *** Looping through 5.2. Iter = 2713 iteration 2713; minNextMutationTime = 1987.04; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 134 *** Looping through 5.2. Iter = 2714 iteration 2714; minNextMutationTime = 1987.04; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 135 *** Looping through 5.2. Iter = 2715 iteration 2715; minNextMutationTime = 1987.08; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 160 *** Looping through 5.2. Iter = 2716 iteration 2716; minNextMutationTime = 1987.09; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 468 *** Looping through 5.2. Iter = 2717 iteration 2717; minNextMutationTime = 1987.13; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 101 *** Looping through 5.2. Iter = 2718 iteration 2718; minNextMutationTime = 1987.13; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 310 *** Looping through 5.2. Iter = 2719 iteration 2719; minNextMutationTime = 1987.16; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 167 *** Looping through 5.2. Iter = 2720 iteration 2720; minNextMutationTime = 1987.19; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 466 *** Looping through 5.2. Iter = 2721 iteration 2721; minNextMutationTime = 1987.19; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 310 *** Looping through 5.2. Iter = 2722 iteration 2722; minNextMutationTime = 1987.21; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5293 *** Looping through 5.2. Iter = 2723 iteration 2723; minNextMutationTime = 1987.23; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 139 *** Looping through 5.2. Iter = 2724 iteration 2724; minNextMutationTime = 1987.3; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 172 *** Looping through 5.2. Iter = 2725 iteration 2725; minNextMutationTime = 1987.31; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5317 *** Looping through 5.2. Iter = 2726 iteration 2726; minNextMutationTime = 1987.34; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 145 *** Looping through 5.2. Iter = 2727 iteration 2727; minNextMutationTime = 1987.35; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 312 *** Looping through 5.2. Iter = 2728 iteration 2728; minNextMutationTime = 1987.38; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 466 *** Looping through 5.2. Iter = 2729 iteration 2729; minNextMutationTime = 1987.39; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 145 *** Looping through 5.2. Iter = 2730 iteration 2730; minNextMutationTime = 1987.4; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 104 *** Looping through 5.2. Iter = 2731 iteration 2731; minNextMutationTime = 1987.42; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 317 *** Looping through 5.2. Iter = 2732 iteration 2732; minNextMutationTime = 1987.44; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 172 *** Looping through 5.2. Iter = 2733 iteration 2733; minNextMutationTime = 1987.44; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5322 *** Looping through 5.2. Iter = 2734 iteration 2734; minNextMutationTime = 1987.47; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 171 *** Looping through 5.2. Iter = 2735 iteration 2735; minNextMutationTime = 1987.49; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5360 *** Looping through 5.2. Iter = 2736 iteration 2736; minNextMutationTime = 1987.5; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5373 *** Looping through 5.2. Iter = 2737 iteration 2737; minNextMutationTime = 1987.51; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 105 *** Looping through 5.2. Iter = 2738 iteration 2738; minNextMutationTime = 1987.51; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 318 *** Looping through 5.2. Iter = 2739 iteration 2739; minNextMutationTime = 1987.56; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 147 *** Looping through 5.2. Iter = 2740 iteration 2740; minNextMutationTime = 1987.58; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 104 *** Looping through 5.2. Iter = 2741 iteration 2741; minNextMutationTime = 1987.6; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 465 *** Looping through 5.2. Iter = 2742 iteration 2742; minNextMutationTime = 1987.63; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 110 *** Looping through 5.2. Iter = 2743 iteration 2743; minNextMutationTime = 1987.64; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5393 *** Looping through 5.2. Iter = 2744 iteration 2744; minNextMutationTime = 1987.67; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 146 *** Looping through 5.2. Iter = 2745 iteration 2745; minNextMutationTime = 1987.68; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 470 *** Looping through 5.2. Iter = 2746 iteration 2746; minNextMutationTime = 1987.69; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 470 *** Looping through 5.2. Iter = 2747 iteration 2747; minNextMutationTime = 1987.71; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 467 *** Looping through 5.2. Iter = 2748 iteration 2748; minNextMutationTime = 1987.71; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5394 *** Looping through 5.2. Iter = 2749 iteration 2749; minNextMutationTime = 1987.74; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 459 *** Looping through 5.2. Iter = 2750 iteration 2750; minNextMutationTime = 1987.74; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 147 *** Looping through 5.2. Iter = 2751 iteration 2751; minNextMutationTime = 1987.74; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 111 *** Looping through 5.2. Iter = 2752 iteration 2752; minNextMutationTime = 1987.74; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 460 *** Looping through 5.2. Iter = 2753 iteration 2753; minNextMutationTime = 1987.75; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 149 *** Looping through 5.2. Iter = 2754 iteration 2754; minNextMutationTime = 1987.76; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 464 *** Looping through 5.2. Iter = 2755 iteration 2755; minNextMutationTime = 1987.76; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 112 *** Looping through 5.2. Iter = 2756 iteration 2756; minNextMutationTime = 1987.76; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 150 *** Looping through 5.2. Iter = 2757 iteration 2757; minNextMutationTime = 1987.79; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 173 *** Looping through 5.2. Iter = 2758 iteration 2758; minNextMutationTime = 1987.8; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 152 *** Looping through 5.2. Iter = 2759 iteration 2759; minNextMutationTime = 1987.81; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 467 *** Looping through 5.2. Iter = 2760 iteration 2760; minNextMutationTime = 1987.81; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5393 *** Looping through 5.2. Iter = 2761 iteration 2761; minNextMutationTime = 1987.82; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 317 *** Looping through 5.2. Iter = 2762 iteration 2762; minNextMutationTime = 1987.84; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5415 *** Looping through 5.2. Iter = 2763 iteration 2763; minNextMutationTime = 1987.85; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 113 *** Looping through 5.2. Iter = 2764 iteration 2764; minNextMutationTime = 1987.89; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5445 *** Looping through 5.2. Iter = 2765 iteration 2765; minNextMutationTime = 1987.9; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 149 *** Looping through 5.2. Iter = 2766 iteration 2766; minNextMutationTime = 1987.93; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 175 *** Looping through 5.2. Iter = 2767 iteration 2767; minNextMutationTime = 1987.93; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 114 *** Looping through 5.2. Iter = 2768 iteration 2768; minNextMutationTime = 1987.93; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 176 *** Looping through 5.2. Iter = 2769 iteration 2769; minNextMutationTime = 1987.95; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 148 *** Looping through 5.2. Iter = 2770 iteration 2770; minNextMutationTime = 1987.95; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5446 *** Looping through 5.2. Iter = 2771 iteration 2771; minNextMutationTime = 1987.98; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 115 *** Looping through 5.2. Iter = 2772 iteration 2772; minNextMutationTime = 1987.99; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 470 *** Looping through 5.2. Iter = 2773 iteration 2773; minNextMutationTime = 1988; timeNextPopSample = 1988; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 149 *** Looping through 5.2. Iter = 2774 iteration 2774; minNextMutationTime = 1998; timeNextPopSample = 1988; popParams.size() = 9 We are SAMPLING at time 1988 *** Looping through 5.2. Iter = 2775 iteration 2775; minNextMutationTime = 1988; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 114 *** Looping through 5.2. Iter = 2776 iteration 2776; minNextMutationTime = 1988; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5450 *** Looping through 5.2. Iter = 2777 iteration 2777; minNextMutationTime = 1988.02; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 475 *** Looping through 5.2. Iter = 2778 iteration 2778; minNextMutationTime = 1988.04; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 179 *** Looping through 5.2. Iter = 2779 iteration 2779; minNextMutationTime = 1988.04; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 474 *** Looping through 5.2. Iter = 2780 iteration 2780; minNextMutationTime = 1988.06; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 313 *** Looping through 5.2. Iter = 2781 iteration 2781; minNextMutationTime = 1988.06; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 115 *** Looping through 5.2. Iter = 2782 iteration 2782; minNextMutationTime = 1988.07; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 315 *** Looping through 5.2. Iter = 2783 iteration 2783; minNextMutationTime = 1988.08; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 149 *** Looping through 5.2. Iter = 2784 iteration 2784; minNextMutationTime = 1988.09; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 114 *** Looping through 5.2. Iter = 2785 iteration 2785; minNextMutationTime = 1988.1; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 114 *** Looping through 5.2. Iter = 2786 iteration 2786; minNextMutationTime = 1988.12; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5464 *** Looping through 5.2. Iter = 2787 iteration 2787; minNextMutationTime = 1988.14; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 153 *** Looping through 5.2. Iter = 2788 iteration 2788; minNextMutationTime = 1988.14; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 154 *** Looping through 5.2. Iter = 2789 iteration 2789; minNextMutationTime = 1988.18; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5478 *** Looping through 5.2. Iter = 2790 iteration 2790; minNextMutationTime = 1988.2; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 114 *** Looping through 5.2. Iter = 2791 iteration 2791; minNextMutationTime = 1988.22; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 156 *** Looping through 5.2. Iter = 2792 iteration 2792; minNextMutationTime = 1988.23; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 115 *** Looping through 5.2. Iter = 2793 iteration 2793; minNextMutationTime = 1988.23; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 318 *** Looping through 5.2. Iter = 2794 iteration 2794; minNextMutationTime = 1988.24; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 181 *** Looping through 5.2. Iter = 2795 iteration 2795; minNextMutationTime = 1988.24; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 116 *** Looping through 5.2. Iter = 2796 iteration 2796; minNextMutationTime = 1988.25; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 318 *** Looping through 5.2. Iter = 2797 iteration 2797; minNextMutationTime = 1988.27; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 321 *** Looping through 5.2. Iter = 2798 iteration 2798; minNextMutationTime = 1988.28; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 156 *** Looping through 5.2. Iter = 2799 iteration 2799; minNextMutationTime = 1988.29; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5474 *** Looping through 5.2. Iter = 2800 iteration 2800; minNextMutationTime = 1988.29; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 323 *** Looping through 5.2. Iter = 2801 iteration 2801; minNextMutationTime = 1988.29; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 117 *** Looping through 5.2. Iter = 2802 iteration 2802; minNextMutationTime = 1988.35; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 486 *** Looping through 5.2. Iter = 2803 iteration 2803; minNextMutationTime = 1988.37; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 155 *** Looping through 5.2. Iter = 2804 iteration 2804; minNextMutationTime = 1988.41; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 338 *** Looping through 5.2. Iter = 2805 iteration 2805; minNextMutationTime = 1988.44; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 345 *** Looping through 5.2. Iter = 2806 iteration 2806; minNextMutationTime = 1988.47; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 488 *** Looping through 5.2. Iter = 2807 iteration 2807; minNextMutationTime = 1988.49; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 346 *** Looping through 5.2. Iter = 2808 iteration 2808; minNextMutationTime = 1988.51; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 345 *** Looping through 5.2. Iter = 2809 iteration 2809; minNextMutationTime = 1988.52; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 120 *** Looping through 5.2. Iter = 2810 iteration 2810; minNextMutationTime = 1988.54; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 179 *** Looping through 5.2. Iter = 2811 iteration 2811; minNextMutationTime = 1988.54; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 181 *** Looping through 5.2. Iter = 2812 iteration 2812; minNextMutationTime = 1988.57; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 498 *** Looping through 5.2. Iter = 2813 iteration 2813; minNextMutationTime = 1988.57; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 158 *** Looping through 5.2. Iter = 2814 iteration 2814; minNextMutationTime = 1988.58; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 182 *** Looping through 5.2. Iter = 2815 iteration 2815; minNextMutationTime = 1988.58; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 120 *** Looping through 5.2. Iter = 2816 iteration 2816; minNextMutationTime = 1988.59; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 122 *** Looping through 5.2. Iter = 2817 iteration 2817; minNextMutationTime = 1988.59; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 122 *** Looping through 5.2. Iter = 2818 iteration 2818; minNextMutationTime = 1988.63; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5542 *** Looping through 5.2. Iter = 2819 iteration 2819; minNextMutationTime = 1988.65; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 123 *** Looping through 5.2. Iter = 2820 iteration 2820; minNextMutationTime = 1988.66; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5565 *** Looping through 5.2. Iter = 2821 iteration 2821; minNextMutationTime = 1988.67; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5572 *** Looping through 5.2. Iter = 2822 iteration 2822; minNextMutationTime = 1988.71; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 155 *** Looping through 5.2. Iter = 2823 iteration 2823; minNextMutationTime = 1988.71; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 346 *** Looping through 5.2. Iter = 2824 iteration 2824; minNextMutationTime = 1988.72; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 122 *** Looping through 5.2. Iter = 2825 iteration 2825; minNextMutationTime = 1988.76; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 152 *** Looping through 5.2. Iter = 2826 iteration 2826; minNextMutationTime = 1988.76; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 348 *** Looping through 5.2. Iter = 2827 iteration 2827; minNextMutationTime = 1988.77; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 351 *** Looping through 5.2. Iter = 2828 iteration 2828; minNextMutationTime = 1988.79; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 501 *** Looping through 5.2. Iter = 2829 iteration 2829; minNextMutationTime = 1988.79; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5573 *** Looping through 5.2. Iter = 2830 iteration 2830; minNextMutationTime = 1988.81; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5568 *** Looping through 5.2. Iter = 2831 iteration 2831; minNextMutationTime = 1988.82; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 155 *** Looping through 5.2. Iter = 2832 iteration 2832; minNextMutationTime = 1988.83; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 182 *** Looping through 5.2. Iter = 2833 iteration 2833; minNextMutationTime = 1988.83; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 352 *** Looping through 5.2. Iter = 2834 iteration 2834; minNextMutationTime = 1988.83; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 503 *** Looping through 5.2. Iter = 2835 iteration 2835; minNextMutationTime = 1988.87; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 157 *** Looping through 5.2. Iter = 2836 iteration 2836; minNextMutationTime = 1988.88; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 158 *** Looping through 5.2. Iter = 2837 iteration 2837; minNextMutationTime = 1988.89; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 159 *** Looping through 5.2. Iter = 2838 iteration 2838; minNextMutationTime = 1988.91; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 509 *** Looping through 5.2. Iter = 2839 iteration 2839; minNextMutationTime = 1988.94; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5653 *** Looping through 5.2. Iter = 2840 iteration 2840; minNextMutationTime = 1988.96; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 124 *** Looping through 5.2. Iter = 2841 iteration 2841; minNextMutationTime = 1988.96; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 125 *** Looping through 5.2. Iter = 2842 iteration 2842; minNextMutationTime = 1988.96; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 510 *** Looping through 5.2. Iter = 2843 iteration 2843; minNextMutationTime = 1988.96; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 511 *** Looping through 5.2. Iter = 2844 iteration 2844; minNextMutationTime = 1988.97; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5683 *** Looping through 5.2. Iter = 2845 iteration 2845; minNextMutationTime = 1988.98; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5702 *** Looping through 5.2. Iter = 2846 iteration 2846; minNextMutationTime = 1988.99; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 186 *** Looping through 5.2. Iter = 2847 iteration 2847; minNextMutationTime = 1988.99; timeNextPopSample = 1989; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 514 *** Looping through 5.2. Iter = 2848 iteration 2848; minNextMutationTime = 1999; timeNextPopSample = 1989; popParams.size() = 9 We are SAMPLING at time 1989 *** Looping through 5.2. Iter = 2849 iteration 2849; minNextMutationTime = 1989.01; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5697 *** Looping through 5.2. Iter = 2850 iteration 2850; minNextMutationTime = 1989.03; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 157 *** Looping through 5.2. Iter = 2851 iteration 2851; minNextMutationTime = 1989.03; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 128 *** Looping through 5.2. Iter = 2852 iteration 2852; minNextMutationTime = 1989.03; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 519 *** Looping through 5.2. Iter = 2853 iteration 2853; minNextMutationTime = 1989.04; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 156 *** Looping through 5.2. Iter = 2854 iteration 2854; minNextMutationTime = 1989.04; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 129 *** Looping through 5.2. Iter = 2855 iteration 2855; minNextMutationTime = 1989.06; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5695 *** Looping through 5.2. Iter = 2856 iteration 2856; minNextMutationTime = 1989.07; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 159 *** Looping through 5.2. Iter = 2857 iteration 2857; minNextMutationTime = 1989.09; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 193 *** Looping through 5.2. Iter = 2858 iteration 2858; minNextMutationTime = 1989.11; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 157 *** Looping through 5.2. Iter = 2859 iteration 2859; minNextMutationTime = 1989.11; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5694 *** Looping through 5.2. Iter = 2860 iteration 2860; minNextMutationTime = 1989.14; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 165 *** Looping through 5.2. Iter = 2861 iteration 2861; minNextMutationTime = 1989.15; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 354 *** Looping through 5.2. Iter = 2862 iteration 2862; minNextMutationTime = 1989.16; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 516 *** Looping through 5.2. Iter = 2863 iteration 2863; minNextMutationTime = 1989.17; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 164 *** Looping through 5.2. Iter = 2864 iteration 2864; minNextMutationTime = 1989.17; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 355 *** Looping through 5.2. Iter = 2865 iteration 2865; minNextMutationTime = 1989.18; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 518 *** Looping through 5.2. Iter = 2866 iteration 2866; minNextMutationTime = 1989.18; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 520 *** Looping through 5.2. Iter = 2867 iteration 2867; minNextMutationTime = 1989.19; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 131 *** Looping through 5.2. Iter = 2868 iteration 2868; minNextMutationTime = 1989.19; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 132 *** Looping through 5.2. Iter = 2869 iteration 2869; minNextMutationTime = 1989.21; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 193 *** Looping through 5.2. Iter = 2870 iteration 2870; minNextMutationTime = 1989.23; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 365 *** Looping through 5.2. Iter = 2871 iteration 2871; minNextMutationTime = 1989.25; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 369 *** Looping through 5.2. Iter = 2872 iteration 2872; minNextMutationTime = 1989.25; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 5697 *** Looping through 5.2. Iter = 2873 iteration 2873; minNextMutationTime = 1989.26; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 194 *** Looping through 5.2. Iter = 2874 iteration 2874; minNextMutationTime = 1989.26; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 520 *** Looping through 5.2. Iter = 2875 iteration 2875; minNextMutationTime = 1989.29; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 164 *** Looping through 5.2. Iter = 2876 iteration 2876; minNextMutationTime = 1989.3; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 525 *** Looping through 5.2. Iter = 2877 iteration 2877; minNextMutationTime = 1989.32; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 525 *** Looping through 5.2. Iter = 2878 iteration 2878; minNextMutationTime = 1989.33; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 524 *** Looping through 5.2. Iter = 2879 iteration 2879; minNextMutationTime = 1989.33; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 371 *** Looping through 5.2. Iter = 2880 iteration 2880; minNextMutationTime = 1989.35; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 375 *** Looping through 5.2. Iter = 2881 iteration 2881; minNextMutationTime = 1989.37; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 197 *** Looping through 5.2. Iter = 2882 iteration 2882; minNextMutationTime = 1989.4; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 167 *** Looping through 5.2. Iter = 2883 iteration 2883; minNextMutationTime = 1989.41; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 377 *** Looping through 5.2. Iter = 2884 iteration 2884; minNextMutationTime = 1989.41; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 526 *** Looping through 5.2. Iter = 2885 iteration 2885; minNextMutationTime = 1989.42; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 531 *** Looping through 5.2. Iter = 2886 iteration 2886; minNextMutationTime = 1989.43; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 535 *** Looping through 5.2. Iter = 2887 iteration 2887; minNextMutationTime = 1989.44; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 203 *** Looping through 5.2. Iter = 2888 iteration 2888; minNextMutationTime = 1989.45; timeNextPopSample = 1990; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 205 *** Looping through 5.2. Iter = 2889 iteration 2889; minNextMutationTime = 1989.52; timeNextPopSample = 1990; popParams.size() = 9 Creating new species 9 from species 0 *** Looping through 5.2. Iter = 2890 iteration 2890; minNextMutationTime = 1989.55; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 536 *** Looping through 5.2. Iter = 2891 iteration 2891; minNextMutationTime = 1989.55; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 538 *** Looping through 5.2. Iter = 2892 iteration 2892; minNextMutationTime = 1989.56; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 131 *** Looping through 5.2. Iter = 2893 iteration 2893; minNextMutationTime = 1989.56; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 404 *** Looping through 5.2. Iter = 2894 iteration 2894; minNextMutationTime = 1989.58; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 534 *** Looping through 5.2. Iter = 2895 iteration 2895; minNextMutationTime = 1989.58; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 131 *** Looping through 5.2. Iter = 2896 iteration 2896; minNextMutationTime = 1989.62; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 540 *** Looping through 5.2. Iter = 2897 iteration 2897; minNextMutationTime = 1989.62; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 168 *** Looping through 5.2. Iter = 2898 iteration 2898; minNextMutationTime = 1989.63; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 419 *** Looping through 5.2. Iter = 2899 iteration 2899; minNextMutationTime = 1989.64; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 170 *** Looping through 5.2. Iter = 2900 iteration 2900; minNextMutationTime = 1989.65; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 546 *** Looping through 5.2. Iter = 2901 iteration 2901; minNextMutationTime = 1989.67; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 541 *** Looping through 5.2. Iter = 2902 iteration 2902; minNextMutationTime = 1989.67; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 143 *** Looping through 5.2. Iter = 2903 iteration 2903; minNextMutationTime = 1989.68; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6015 *** Looping through 5.2. Iter = 2904 iteration 2904; minNextMutationTime = 1989.68; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 144 *** Looping through 5.2. Iter = 2905 iteration 2905; minNextMutationTime = 1989.68; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 169 *** Looping through 5.2. Iter = 2906 iteration 2906; minNextMutationTime = 1989.68; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 548 *** Looping through 5.2. Iter = 2907 iteration 2907; minNextMutationTime = 1989.7; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 553 *** Looping through 5.2. Iter = 2908 iteration 2908; minNextMutationTime = 1989.71; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 144 *** Looping through 5.2. Iter = 2909 iteration 2909; minNextMutationTime = 1989.72; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 431 *** Looping through 5.2. Iter = 2910 iteration 2910; minNextMutationTime = 1989.73; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 432 *** Looping through 5.2. Iter = 2911 iteration 2911; minNextMutationTime = 1989.74; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 217 *** Looping through 5.2. Iter = 2912 iteration 2912; minNextMutationTime = 1989.75; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 220 *** Looping through 5.2. Iter = 2913 iteration 2913; minNextMutationTime = 1989.77; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 219 *** Looping through 5.2. Iter = 2914 iteration 2914; minNextMutationTime = 1989.78; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 170 *** Looping through 5.2. Iter = 2915 iteration 2915; minNextMutationTime = 1989.78; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 172 *** Looping through 5.2. Iter = 2916 iteration 2916; minNextMutationTime = 1989.79; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 172 *** Looping through 5.2. Iter = 2917 iteration 2917; minNextMutationTime = 1989.79; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 432 *** Looping through 5.2. Iter = 2918 iteration 2918; minNextMutationTime = 1989.81; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 173 *** Looping through 5.2. Iter = 2919 iteration 2919; minNextMutationTime = 1989.84; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 439 *** Looping through 5.2. Iter = 2920 iteration 2920; minNextMutationTime = 1989.86; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 220 *** Looping through 5.2. Iter = 2921 iteration 2921; minNextMutationTime = 1989.88; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 228 *** Looping through 5.2. Iter = 2922 iteration 2922; minNextMutationTime = 1989.89; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 174 *** Looping through 5.2. Iter = 2923 iteration 2923; minNextMutationTime = 1989.93; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 147 *** Looping through 5.2. Iter = 2924 iteration 2924; minNextMutationTime = 1989.94; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 454 *** Looping through 5.2. Iter = 2925 iteration 2925; minNextMutationTime = 1989.95; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6372 *** Looping through 5.2. Iter = 2926 iteration 2926; minNextMutationTime = 1989.96; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 149 *** Looping through 5.2. Iter = 2927 iteration 2927; minNextMutationTime = 1989.99; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 235 *** Looping through 5.2. Iter = 2928 iteration 2928; minNextMutationTime = 1989.99; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6458 *** Looping through 5.2. Iter = 2929 iteration 2929; minNextMutationTime = 1990; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6463 *** Looping through 5.2. Iter = 2930 iteration 2930; minNextMutationTime = 1990; timeNextPopSample = 1990; popParams.size() = 10 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 188 *** Looping through 5.2. Iter = 2931 iteration 2931; minNextMutationTime = 2000; timeNextPopSample = 1990; popParams.size() = 10 We are SAMPLING at time 1990 *** Looping through 5.2. Iter = 2932 iteration 2932; minNextMutationTime = 1990.01; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 236 *** Looping through 5.2. Iter = 2933 iteration 2933; minNextMutationTime = 1990.01; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 153 *** Looping through 5.2. Iter = 2934 iteration 2934; minNextMutationTime = 1990.01; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 583 *** Looping through 5.2. Iter = 2935 iteration 2935; minNextMutationTime = 1990.02; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 153 *** Looping through 5.2. Iter = 2936 iteration 2936; minNextMutationTime = 1990.03; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6464 *** Looping through 5.2. Iter = 2937 iteration 2937; minNextMutationTime = 1990.04; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6479 *** Looping through 5.2. Iter = 2938 iteration 2938; minNextMutationTime = 1990.04; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 237 *** Looping through 5.2. Iter = 2939 iteration 2939; minNextMutationTime = 1990.07; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 469 *** Looping through 5.2. Iter = 2940 iteration 2940; minNextMutationTime = 1990.07; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 583 *** Looping through 5.2. Iter = 2941 iteration 2941; minNextMutationTime = 1990.08; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 474 *** Looping through 5.2. Iter = 2942 iteration 2942; minNextMutationTime = 1990.09; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 192 *** Looping through 5.2. Iter = 2943 iteration 2943; minNextMutationTime = 1990.1; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 240 *** Looping through 5.2. Iter = 2944 iteration 2944; minNextMutationTime = 1990.14; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 476 *** Looping through 5.2. Iter = 2945 iteration 2945; minNextMutationTime = 1990.23; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 510 *** Looping through 5.2. Iter = 2946 iteration 2946; minNextMutationTime = 1990.24; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 153 *** Looping through 5.2. Iter = 2947 iteration 2947; minNextMutationTime = 1990.24; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 155 *** Looping through 5.2. Iter = 2948 iteration 2948; minNextMutationTime = 1990.26; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 503 *** Looping through 5.2. Iter = 2949 iteration 2949; minNextMutationTime = 1990.27; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 506 *** Looping through 5.2. Iter = 2950 iteration 2950; minNextMutationTime = 1990.28; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 503 *** Looping through 5.2. Iter = 2951 iteration 2951; minNextMutationTime = 1990.29; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 159 *** Looping through 5.2. Iter = 2952 iteration 2952; minNextMutationTime = 1990.32; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 194 *** Looping through 5.2. Iter = 2953 iteration 2953; minNextMutationTime = 1990.34; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6515 *** Looping through 5.2. Iter = 2954 iteration 2954; minNextMutationTime = 1990.36; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 192 *** Looping through 5.2. Iter = 2955 iteration 2955; minNextMutationTime = 1990.38; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 503 *** Looping through 5.2. Iter = 2956 iteration 2956; minNextMutationTime = 1990.38; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6523 *** Looping through 5.2. Iter = 2957 iteration 2957; minNextMutationTime = 1990.39; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 159 *** Looping through 5.2. Iter = 2958 iteration 2958; minNextMutationTime = 1990.39; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 160 *** Looping through 5.2. Iter = 2959 iteration 2959; minNextMutationTime = 1990.45; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 160 *** Looping through 5.2. Iter = 2960 iteration 2960; minNextMutationTime = 1990.47; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 189 *** Looping through 5.2. Iter = 2961 iteration 2961; minNextMutationTime = 1990.48; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 585 *** Looping through 5.2. Iter = 2962 iteration 2962; minNextMutationTime = 1990.48; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 187 *** Looping through 5.2. Iter = 2963 iteration 2963; minNextMutationTime = 1990.5; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 509 *** Looping through 5.2. Iter = 2964 iteration 2964; minNextMutationTime = 1990.53; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 511 *** Looping through 5.2. Iter = 2965 iteration 2965; minNextMutationTime = 1990.53; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 188 *** Looping through 5.2. Iter = 2966 iteration 2966; minNextMutationTime = 1990.56; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 241 *** Looping through 5.2. Iter = 2967 iteration 2967; minNextMutationTime = 1990.56; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 190 *** Looping through 5.2. Iter = 2968 iteration 2968; minNextMutationTime = 1990.56; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 243 *** Looping through 5.2. Iter = 2969 iteration 2969; minNextMutationTime = 1990.64; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 245 *** Looping through 5.2. Iter = 2970 iteration 2970; minNextMutationTime = 1990.65; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 246 *** Looping through 5.2. Iter = 2971 iteration 2971; minNextMutationTime = 1990.68; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 253 *** Looping through 5.2. Iter = 2972 iteration 2972; minNextMutationTime = 1990.68; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 586 *** Looping through 5.2. Iter = 2973 iteration 2973; minNextMutationTime = 1990.69; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 189 *** Looping through 5.2. Iter = 2974 iteration 2974; minNextMutationTime = 1990.69; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6526 *** Looping through 5.2. Iter = 2975 iteration 2975; minNextMutationTime = 1990.7; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 160 *** Looping through 5.2. Iter = 2976 iteration 2976; minNextMutationTime = 1990.7; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 161 *** Looping through 5.2. Iter = 2977 iteration 2977; minNextMutationTime = 1990.72; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 162 *** Looping through 5.2. Iter = 2978 iteration 2978; minNextMutationTime = 1990.82; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 163 *** Looping through 5.2. Iter = 2979 iteration 2979; minNextMutationTime = 1990.82; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 587 *** Looping through 5.2. Iter = 2980 iteration 2980; minNextMutationTime = 1990.83; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6523 *** Looping through 5.2. Iter = 2981 iteration 2981; minNextMutationTime = 1990.86; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 591 *** Looping through 5.2. Iter = 2982 iteration 2982; minNextMutationTime = 1990.86; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 164 *** Looping through 5.2. Iter = 2983 iteration 2983; minNextMutationTime = 1990.87; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 512 *** Looping through 5.2. Iter = 2984 iteration 2984; minNextMutationTime = 1990.87; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 252 *** Looping through 5.2. Iter = 2985 iteration 2985; minNextMutationTime = 1990.88; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 189 *** Looping through 5.2. Iter = 2986 iteration 2986; minNextMutationTime = 1990.89; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 192 *** Looping through 5.2. Iter = 2987 iteration 2987; minNextMutationTime = 1990.92; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 254 *** Looping through 5.2. Iter = 2988 iteration 2988; minNextMutationTime = 1990.93; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 165 *** Looping through 5.2. Iter = 2989 iteration 2989; minNextMutationTime = 1990.93; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 255 *** Looping through 5.2. Iter = 2990 iteration 2990; minNextMutationTime = 1990.98; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 598 *** Looping through 5.2. Iter = 2991 iteration 2991; minNextMutationTime = 1990.99; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 253 *** Looping through 5.2. Iter = 2992 iteration 2992; minNextMutationTime = 1991; timeNextPopSample = 1991; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6525 *** Looping through 5.2. Iter = 2993 iteration 2993; minNextMutationTime = 2001; timeNextPopSample = 1991; popParams.size() = 9 We are SAMPLING at time 1991 *** Looping through 5.2. Iter = 2994 iteration 2994; minNextMutationTime = 1991.02; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 167 *** Looping through 5.2. Iter = 2995 iteration 2995; minNextMutationTime = 1991.04; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 259 *** Looping through 5.2. Iter = 2996 iteration 2996; minNextMutationTime = 1991.05; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 522 *** Looping through 5.2. Iter = 2997 iteration 2997; minNextMutationTime = 1991.06; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 522 *** Looping through 5.2. Iter = 2998 iteration 2998; minNextMutationTime = 1991.1; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 526 *** Looping through 5.2. Iter = 2999 iteration 2999; minNextMutationTime = 1991.13; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 167 ... iteration 3000 ... currentTime 1991.13 *** Looping through 5.2. Iter = 3000 iteration 3000; minNextMutationTime = 1991.14; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 192 *** Looping through 5.2. Iter = 3001 iteration 3001; minNextMutationTime = 1991.14; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 192 *** Looping through 5.2. Iter = 3002 iteration 3002; minNextMutationTime = 1991.15; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 263 *** Looping through 5.2. Iter = 3003 iteration 3003; minNextMutationTime = 1991.15; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 598 *** Looping through 5.2. Iter = 3004 iteration 3004; minNextMutationTime = 1991.16; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 194 *** Looping through 5.2. Iter = 3005 iteration 3005; minNextMutationTime = 1991.16; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 526 *** Looping through 5.2. Iter = 3006 iteration 3006; minNextMutationTime = 1991.17; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 263 *** Looping through 5.2. Iter = 3007 iteration 3007; minNextMutationTime = 1991.17; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 194 *** Looping through 5.2. Iter = 3008 iteration 3008; minNextMutationTime = 1991.18; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 194 *** Looping through 5.2. Iter = 3009 iteration 3009; minNextMutationTime = 1991.19; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 608 *** Looping through 5.2. Iter = 3010 iteration 3010; minNextMutationTime = 1991.19; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 607 *** Looping through 5.2. Iter = 3011 iteration 3011; minNextMutationTime = 1991.2; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 266 *** Looping through 5.2. Iter = 3012 iteration 3012; minNextMutationTime = 1991.2; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 527 *** Looping through 5.2. Iter = 3013 iteration 3013; minNextMutationTime = 1991.21; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 266 *** Looping through 5.2. Iter = 3014 iteration 3014; minNextMutationTime = 1991.23; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 268 *** Looping through 5.2. Iter = 3015 iteration 3015; minNextMutationTime = 1991.23; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 167 *** Looping through 5.2. Iter = 3016 iteration 3016; minNextMutationTime = 1991.24; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 195 *** Looping through 5.2. Iter = 3017 iteration 3017; minNextMutationTime = 1991.26; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6577 *** Looping through 5.2. Iter = 3018 iteration 3018; minNextMutationTime = 1991.27; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 529 *** Looping through 5.2. Iter = 3019 iteration 3019; minNextMutationTime = 1991.28; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 198 *** Looping through 5.2. Iter = 3020 iteration 3020; minNextMutationTime = 1991.29; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 271 *** Looping through 5.2. Iter = 3021 iteration 3021; minNextMutationTime = 1991.3; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 530 *** Looping through 5.2. Iter = 3022 iteration 3022; minNextMutationTime = 1991.32; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 614 *** Looping through 5.2. Iter = 3023 iteration 3023; minNextMutationTime = 1991.32; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 271 *** Looping through 5.2. Iter = 3024 iteration 3024; minNextMutationTime = 1991.35; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 165 *** Looping through 5.2. Iter = 3025 iteration 3025; minNextMutationTime = 1991.35; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 197 *** Looping through 5.2. Iter = 3026 iteration 3026; minNextMutationTime = 1991.36; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 273 *** Looping through 5.2. Iter = 3027 iteration 3027; minNextMutationTime = 1991.38; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 271 *** Looping through 5.2. Iter = 3028 iteration 3028; minNextMutationTime = 1991.38; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 615 *** Looping through 5.2. Iter = 3029 iteration 3029; minNextMutationTime = 1991.41; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 620 *** Looping through 5.2. Iter = 3030 iteration 3030; minNextMutationTime = 1991.42; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 167 *** Looping through 5.2. Iter = 3031 iteration 3031; minNextMutationTime = 1991.42; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 532 *** Looping through 5.2. Iter = 3032 iteration 3032; minNextMutationTime = 1991.45; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 550 *** Looping through 5.2. Iter = 3033 iteration 3033; minNextMutationTime = 1991.46; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 558 *** Looping through 5.2. Iter = 3034 iteration 3034; minNextMutationTime = 1991.46; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 168 *** Looping through 5.2. Iter = 3035 iteration 3035; minNextMutationTime = 1991.47; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 271 *** Looping through 5.2. Iter = 3036 iteration 3036; minNextMutationTime = 1991.48; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 271 *** Looping through 5.2. Iter = 3037 iteration 3037; minNextMutationTime = 1991.53; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6701 *** Looping through 5.2. Iter = 3038 iteration 3038; minNextMutationTime = 1991.57; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 628 *** Looping through 5.2. Iter = 3039 iteration 3039; minNextMutationTime = 1991.57; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6716 *** Looping through 5.2. Iter = 3040 iteration 3040; minNextMutationTime = 1991.59; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6729 *** Looping through 5.2. Iter = 3041 iteration 3041; minNextMutationTime = 1991.59; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 169 *** Looping through 5.2. Iter = 3042 iteration 3042; minNextMutationTime = 1991.6; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 556 *** Looping through 5.2. Iter = 3043 iteration 3043; minNextMutationTime = 1991.61; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6737 *** Looping through 5.2. Iter = 3044 iteration 3044; minNextMutationTime = 1991.62; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 557 *** Looping through 5.2. Iter = 3045 iteration 3045; minNextMutationTime = 1991.62; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 629 *** Looping through 5.2. Iter = 3046 iteration 3046; minNextMutationTime = 1991.63; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 270 *** Looping through 5.2. Iter = 3047 iteration 3047; minNextMutationTime = 1991.64; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 199 *** Looping through 5.2. Iter = 3048 iteration 3048; minNextMutationTime = 1991.66; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 168 *** Looping through 5.2. Iter = 3049 iteration 3049; minNextMutationTime = 1991.67; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 169 *** Looping through 5.2. Iter = 3050 iteration 3050; minNextMutationTime = 1991.67; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6735 *** Looping through 5.2. Iter = 3051 iteration 3051; minNextMutationTime = 1991.67; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 559 *** Looping through 5.2. Iter = 3052 iteration 3052; minNextMutationTime = 1991.68; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 275 *** Looping through 5.2. Iter = 3053 iteration 3053; minNextMutationTime = 1991.69; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6737 *** Looping through 5.2. Iter = 3054 iteration 3054; minNextMutationTime = 1991.69; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 630 *** Looping through 5.2. Iter = 3055 iteration 3055; minNextMutationTime = 1991.7; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 566 *** Looping through 5.2. Iter = 3056 iteration 3056; minNextMutationTime = 1991.7; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 278 *** Looping through 5.2. Iter = 3057 iteration 3057; minNextMutationTime = 1991.71; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 566 *** Looping through 5.2. Iter = 3058 iteration 3058; minNextMutationTime = 1991.72; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 566 *** Looping through 5.2. Iter = 3059 iteration 3059; minNextMutationTime = 1991.73; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 279 *** Looping through 5.2. Iter = 3060 iteration 3060; minNextMutationTime = 1991.73; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6734 *** Looping through 5.2. Iter = 3061 iteration 3061; minNextMutationTime = 1991.74; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 168 *** Looping through 5.2. Iter = 3062 iteration 3062; minNextMutationTime = 1991.75; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 200 *** Looping through 5.2. Iter = 3063 iteration 3063; minNextMutationTime = 1991.75; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 201 *** Looping through 5.2. Iter = 3064 iteration 3064; minNextMutationTime = 1991.77; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 276 *** Looping through 5.2. Iter = 3065 iteration 3065; minNextMutationTime = 1991.77; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 631 *** Looping through 5.2. Iter = 3066 iteration 3066; minNextMutationTime = 1991.8; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 568 *** Looping through 5.2. Iter = 3067 iteration 3067; minNextMutationTime = 1991.82; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 168 *** Looping through 5.2. Iter = 3068 iteration 3068; minNextMutationTime = 1991.84; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 278 *** Looping through 5.2. Iter = 3069 iteration 3069; minNextMutationTime = 1991.84; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 170 *** Looping through 5.2. Iter = 3070 iteration 3070; minNextMutationTime = 1991.87; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 175 *** Looping through 5.2. Iter = 3071 iteration 3071; minNextMutationTime = 1991.88; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 572 *** Looping through 5.2. Iter = 3072 iteration 3072; minNextMutationTime = 1991.89; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6729 *** Looping through 5.2. Iter = 3073 iteration 3073; minNextMutationTime = 1991.9; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 569 *** Looping through 5.2. Iter = 3074 iteration 3074; minNextMutationTime = 1991.91; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 277 *** Looping through 5.2. Iter = 3075 iteration 3075; minNextMutationTime = 1991.91; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 567 *** Looping through 5.2. Iter = 3076 iteration 3076; minNextMutationTime = 1991.91; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 566 *** Looping through 5.2. Iter = 3077 iteration 3077; minNextMutationTime = 1991.93; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 177 *** Looping through 5.2. Iter = 3078 iteration 3078; minNextMutationTime = 1991.94; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 178 *** Looping through 5.2. Iter = 3079 iteration 3079; minNextMutationTime = 1991.95; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6727 *** Looping through 5.2. Iter = 3080 iteration 3080; minNextMutationTime = 1991.95; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 567 *** Looping through 5.2. Iter = 3081 iteration 3081; minNextMutationTime = 1991.97; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 200 *** Looping through 5.2. Iter = 3082 iteration 3082; minNextMutationTime = 1992; timeNextPopSample = 1992; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 582 *** Looping through 5.2. Iter = 3083 iteration 3083; minNextMutationTime = 2002; timeNextPopSample = 1992; popParams.size() = 9 We are SAMPLING at time 1992 *** Looping through 5.2. Iter = 3084 iteration 3084; minNextMutationTime = 1992.03; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 648 *** Looping through 5.2. Iter = 3085 iteration 3085; minNextMutationTime = 1992.04; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6727 *** Looping through 5.2. Iter = 3086 iteration 3086; minNextMutationTime = 1992.04; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6737 *** Looping through 5.2. Iter = 3087 iteration 3087; minNextMutationTime = 1992.06; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6771 *** Looping through 5.2. Iter = 3088 iteration 3088; minNextMutationTime = 1992.08; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 657 *** Looping through 5.2. Iter = 3089 iteration 3089; minNextMutationTime = 1992.09; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6777 *** Looping through 5.2. Iter = 3090 iteration 3090; minNextMutationTime = 1992.1; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 283 *** Looping through 5.2. Iter = 3091 iteration 3091; minNextMutationTime = 1992.12; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 203 *** Looping through 5.2. Iter = 3092 iteration 3092; minNextMutationTime = 1992.12; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 661 *** Looping through 5.2. Iter = 3093 iteration 3093; minNextMutationTime = 1992.12; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 664 *** Looping through 5.2. Iter = 3094 iteration 3094; minNextMutationTime = 1992.14; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6833 *** Looping through 5.2. Iter = 3095 iteration 3095; minNextMutationTime = 1992.14; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 179 *** Looping through 5.2. Iter = 3096 iteration 3096; minNextMutationTime = 1992.17; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 666 *** Looping through 5.2. Iter = 3097 iteration 3097; minNextMutationTime = 1992.17; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 180 *** Looping through 5.2. Iter = 3098 iteration 3098; minNextMutationTime = 1992.2; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 282 *** Looping through 5.2. Iter = 3099 iteration 3099; minNextMutationTime = 1992.2; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 587 *** Looping through 5.2. Iter = 3100 iteration 3100; minNextMutationTime = 1992.2; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 205 *** Looping through 5.2. Iter = 3101 iteration 3101; minNextMutationTime = 1992.21; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 181 *** Looping through 5.2. Iter = 3102 iteration 3102; minNextMutationTime = 1992.23; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 206 *** Looping through 5.2. Iter = 3103 iteration 3103; minNextMutationTime = 1992.25; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 184 *** Looping through 5.2. Iter = 3104 iteration 3104; minNextMutationTime = 1992.25; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 207 *** Looping through 5.2. Iter = 3105 iteration 3105; minNextMutationTime = 1992.25; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 590 *** Looping through 5.2. Iter = 3106 iteration 3106; minNextMutationTime = 1992.29; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 204 *** Looping through 5.2. Iter = 3107 iteration 3107; minNextMutationTime = 1992.29; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 285 *** Looping through 5.2. Iter = 3108 iteration 3108; minNextMutationTime = 1992.32; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 182 *** Looping through 5.2. Iter = 3109 iteration 3109; minNextMutationTime = 1992.35; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6877 *** Looping through 5.2. Iter = 3110 iteration 3110; minNextMutationTime = 1992.35; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6898 *** Looping through 5.2. Iter = 3111 iteration 3111; minNextMutationTime = 1992.36; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6899 *** Looping through 5.2. Iter = 3112 iteration 3112; minNextMutationTime = 1992.38; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 207 *** Looping through 5.2. Iter = 3113 iteration 3113; minNextMutationTime = 1992.38; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 591 *** Looping through 5.2. Iter = 3114 iteration 3114; minNextMutationTime = 1992.39; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 592 *** Looping through 5.2. Iter = 3115 iteration 3115; minNextMutationTime = 1992.41; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 595 *** Looping through 5.2. Iter = 3116 iteration 3116; minNextMutationTime = 1992.42; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 285 *** Looping through 5.2. Iter = 3117 iteration 3117; minNextMutationTime = 1992.43; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6907 *** Looping through 5.2. Iter = 3118 iteration 3118; minNextMutationTime = 1992.44; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 599 *** Looping through 5.2. Iter = 3119 iteration 3119; minNextMutationTime = 1992.46; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 676 *** Looping through 5.2. Iter = 3120 iteration 3120; minNextMutationTime = 1992.46; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6927 *** Looping through 5.2. Iter = 3121 iteration 3121; minNextMutationTime = 1992.46; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 286 *** Looping through 5.2. Iter = 3122 iteration 3122; minNextMutationTime = 1992.48; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 596 *** Looping through 5.2. Iter = 3123 iteration 3123; minNextMutationTime = 1992.48; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 183 *** Looping through 5.2. Iter = 3124 iteration 3124; minNextMutationTime = 1992.48; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 207 *** Looping through 5.2. Iter = 3125 iteration 3125; minNextMutationTime = 1992.48; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 677 *** Looping through 5.2. Iter = 3126 iteration 3126; minNextMutationTime = 1992.49; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 601 *** Looping through 5.2. Iter = 3127 iteration 3127; minNextMutationTime = 1992.5; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 211 *** Looping through 5.2. Iter = 3128 iteration 3128; minNextMutationTime = 1992.52; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 679 *** Looping through 5.2. Iter = 3129 iteration 3129; minNextMutationTime = 1992.53; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 678 *** Looping through 5.2. Iter = 3130 iteration 3130; minNextMutationTime = 1992.53; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 287 *** Looping through 5.2. Iter = 3131 iteration 3131; minNextMutationTime = 1992.54; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 287 *** Looping through 5.2. Iter = 3132 iteration 3132; minNextMutationTime = 1992.54; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 212 *** Looping through 5.2. Iter = 3133 iteration 3133; minNextMutationTime = 1992.54; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 184 *** Looping through 5.2. Iter = 3134 iteration 3134; minNextMutationTime = 1992.55; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 185 *** Looping through 5.2. Iter = 3135 iteration 3135; minNextMutationTime = 1992.55; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 213 *** Looping through 5.2. Iter = 3136 iteration 3136; minNextMutationTime = 1992.56; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 217 *** Looping through 5.2. Iter = 3137 iteration 3137; minNextMutationTime = 1992.56; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 678 *** Looping through 5.2. Iter = 3138 iteration 3138; minNextMutationTime = 1992.56; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 599 *** Looping through 5.2. Iter = 3139 iteration 3139; minNextMutationTime = 1992.58; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 222 *** Looping through 5.2. Iter = 3140 iteration 3140; minNextMutationTime = 1992.6; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 184 *** Looping through 5.2. Iter = 3141 iteration 3141; minNextMutationTime = 1992.61; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 679 *** Looping through 5.2. Iter = 3142 iteration 3142; minNextMutationTime = 1992.62; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6938 *** Looping through 5.2. Iter = 3143 iteration 3143; minNextMutationTime = 1992.62; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 288 *** Looping through 5.2. Iter = 3144 iteration 3144; minNextMutationTime = 1992.64; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 297 *** Looping through 5.2. Iter = 3145 iteration 3145; minNextMutationTime = 1992.65; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 304 *** Looping through 5.2. Iter = 3146 iteration 3146; minNextMutationTime = 1992.66; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 680 *** Looping through 5.2. Iter = 3147 iteration 3147; minNextMutationTime = 1992.68; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 606 *** Looping through 5.2. Iter = 3148 iteration 3148; minNextMutationTime = 1992.69; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 222 *** Looping through 5.2. Iter = 3149 iteration 3149; minNextMutationTime = 1992.69; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 221 *** Looping through 5.2. Iter = 3150 iteration 3150; minNextMutationTime = 1992.7; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 304 *** Looping through 5.2. Iter = 3151 iteration 3151; minNextMutationTime = 1992.7; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 186 *** Looping through 5.2. Iter = 3152 iteration 3152; minNextMutationTime = 1992.74; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 617 *** Looping through 5.2. Iter = 3153 iteration 3153; minNextMutationTime = 1992.75; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 618 *** Looping through 5.2. Iter = 3154 iteration 3154; minNextMutationTime = 1992.75; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 682 *** Looping through 5.2. Iter = 3155 iteration 3155; minNextMutationTime = 1992.75; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 221 *** Looping through 5.2. Iter = 3156 iteration 3156; minNextMutationTime = 1992.76; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 187 *** Looping through 5.2. Iter = 3157 iteration 3157; minNextMutationTime = 1992.77; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 221 *** Looping through 5.2. Iter = 3158 iteration 3158; minNextMutationTime = 1992.78; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6966 *** Looping through 5.2. Iter = 3159 iteration 3159; minNextMutationTime = 1992.8; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 188 *** Looping through 5.2. Iter = 3160 iteration 3160; minNextMutationTime = 1992.8; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 685 *** Looping through 5.2. Iter = 3161 iteration 3161; minNextMutationTime = 1992.82; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 222 *** Looping through 5.2. Iter = 3162 iteration 3162; minNextMutationTime = 1992.82; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 304 *** Looping through 5.2. Iter = 3163 iteration 3163; minNextMutationTime = 1992.84; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 627 *** Looping through 5.2. Iter = 3164 iteration 3164; minNextMutationTime = 1992.84; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6968 *** Looping through 5.2. Iter = 3165 iteration 3165; minNextMutationTime = 1992.84; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 628 *** Looping through 5.2. Iter = 3166 iteration 3166; minNextMutationTime = 1992.84; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 687 *** Looping through 5.2. Iter = 3167 iteration 3167; minNextMutationTime = 1992.86; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 221 *** Looping through 5.2. Iter = 3168 iteration 3168; minNextMutationTime = 1992.87; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6970 *** Looping through 5.2. Iter = 3169 iteration 3169; minNextMutationTime = 1992.9; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 189 *** Looping through 5.2. Iter = 3170 iteration 3170; minNextMutationTime = 1992.91; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 6997 *** Looping through 5.2. Iter = 3171 iteration 3171; minNextMutationTime = 1992.91; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 304 *** Looping through 5.2. Iter = 3172 iteration 3172; minNextMutationTime = 1992.92; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 221 *** Looping through 5.2. Iter = 3173 iteration 3173; minNextMutationTime = 1992.92; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 221 *** Looping through 5.2. Iter = 3174 iteration 3174; minNextMutationTime = 1992.93; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 222 *** Looping through 5.2. Iter = 3175 iteration 3175; minNextMutationTime = 1992.95; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 691 *** Looping through 5.2. Iter = 3176 iteration 3176; minNextMutationTime = 1992.97; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 310 *** Looping through 5.2. Iter = 3177 iteration 3177; minNextMutationTime = 1992.97; timeNextPopSample = 1993; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 223 *** Looping through 5.2. Iter = 3178 iteration 3178; minNextMutationTime = 2003; timeNextPopSample = 1993; popParams.size() = 9 We are SAMPLING at time 1993 *** Looping through 5.2. Iter = 3179 iteration 3179; minNextMutationTime = 1993; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 189 *** Looping through 5.2. Iter = 3180 iteration 3180; minNextMutationTime = 1993.01; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 702 *** Looping through 5.2. Iter = 3181 iteration 3181; minNextMutationTime = 1993.01; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 190 *** Looping through 5.2. Iter = 3182 iteration 3182; minNextMutationTime = 1993.02; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 311 *** Looping through 5.2. Iter = 3183 iteration 3183; minNextMutationTime = 1993.03; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7052 *** Looping through 5.2. Iter = 3184 iteration 3184; minNextMutationTime = 1993.05; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 636 *** Looping through 5.2. Iter = 3185 iteration 3185; minNextMutationTime = 1993.05; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 702 *** Looping through 5.2. Iter = 3186 iteration 3186; minNextMutationTime = 1993.07; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 192 *** Looping through 5.2. Iter = 3187 iteration 3187; minNextMutationTime = 1993.08; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 640 *** Looping through 5.2. Iter = 3188 iteration 3188; minNextMutationTime = 1993.08; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 707 *** Looping through 5.2. Iter = 3189 iteration 3189; minNextMutationTime = 1993.09; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 191 *** Looping through 5.2. Iter = 3190 iteration 3190; minNextMutationTime = 1993.09; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 641 *** Looping through 5.2. Iter = 3191 iteration 3191; minNextMutationTime = 1993.09; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 643 *** Looping through 5.2. Iter = 3192 iteration 3192; minNextMutationTime = 1993.1; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 642 *** Looping through 5.2. Iter = 3193 iteration 3193; minNextMutationTime = 1993.11; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 229 *** Looping through 5.2. Iter = 3194 iteration 3194; minNextMutationTime = 1993.12; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 234 *** Looping through 5.2. Iter = 3195 iteration 3195; minNextMutationTime = 1993.13; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 235 *** Looping through 5.2. Iter = 3196 iteration 3196; minNextMutationTime = 1993.17; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 191 *** Looping through 5.2. Iter = 3197 iteration 3197; minNextMutationTime = 1993.17; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7052 *** Looping through 5.2. Iter = 3198 iteration 3198; minNextMutationTime = 1993.18; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 236 *** Looping through 5.2. Iter = 3199 iteration 3199; minNextMutationTime = 1993.18; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7059 *** Looping through 5.2. Iter = 3200 iteration 3200; minNextMutationTime = 1993.18; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 191 *** Looping through 5.2. Iter = 3201 iteration 3201; minNextMutationTime = 1993.21; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 318 *** Looping through 5.2. Iter = 3202 iteration 3202; minNextMutationTime = 1993.22; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 647 *** Looping through 5.2. Iter = 3203 iteration 3203; minNextMutationTime = 1993.22; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 711 *** Looping through 5.2. Iter = 3204 iteration 3204; minNextMutationTime = 1993.23; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 318 *** Looping through 5.2. Iter = 3205 iteration 3205; minNextMutationTime = 1993.23; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7057 *** Looping through 5.2. Iter = 3206 iteration 3206; minNextMutationTime = 1993.23; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7067 *** Looping through 5.2. Iter = 3207 iteration 3207; minNextMutationTime = 1993.27; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 239 *** Looping through 5.2. Iter = 3208 iteration 3208; minNextMutationTime = 1993.32; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 659 *** Looping through 5.2. Iter = 3209 iteration 3209; minNextMutationTime = 1993.32; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 711 *** Looping through 5.2. Iter = 3210 iteration 3210; minNextMutationTime = 1993.32; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 713 *** Looping through 5.2. Iter = 3211 iteration 3211; minNextMutationTime = 1993.33; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7080 *** Looping through 5.2. Iter = 3212 iteration 3212; minNextMutationTime = 1993.34; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 325 *** Looping through 5.2. Iter = 3213 iteration 3213; minNextMutationTime = 1993.35; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 714 *** Looping through 5.2. Iter = 3214 iteration 3214; minNextMutationTime = 1993.35; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 240 *** Looping through 5.2. Iter = 3215 iteration 3215; minNextMutationTime = 1993.36; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 328 *** Looping through 5.2. Iter = 3216 iteration 3216; minNextMutationTime = 1993.37; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 241 *** Looping through 5.2. Iter = 3217 iteration 3217; minNextMutationTime = 1993.38; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 658 *** Looping through 5.2. Iter = 3218 iteration 3218; minNextMutationTime = 1993.39; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 192 *** Looping through 5.2. Iter = 3219 iteration 3219; minNextMutationTime = 1993.39; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 193 *** Looping through 5.2. Iter = 3220 iteration 3220; minNextMutationTime = 1993.4; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 244 *** Looping through 5.2. Iter = 3221 iteration 3221; minNextMutationTime = 1993.4; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 330 *** Looping through 5.2. Iter = 3222 iteration 3222; minNextMutationTime = 1993.41; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 658 *** Looping through 5.2. Iter = 3223 iteration 3223; minNextMutationTime = 1993.41; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 193 *** Looping through 5.2. Iter = 3224 iteration 3224; minNextMutationTime = 1993.43; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 191 *** Looping through 5.2. Iter = 3225 iteration 3225; minNextMutationTime = 1993.44; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 242 *** Looping through 5.2. Iter = 3226 iteration 3226; minNextMutationTime = 1993.45; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 657 *** Looping through 5.2. Iter = 3227 iteration 3227; minNextMutationTime = 1993.45; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 657 *** Looping through 5.2. Iter = 3228 iteration 3228; minNextMutationTime = 1993.47; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 659 *** Looping through 5.2. Iter = 3229 iteration 3229; minNextMutationTime = 1993.48; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 331 *** Looping through 5.2. Iter = 3230 iteration 3230; minNextMutationTime = 1993.5; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 335 *** Looping through 5.2. Iter = 3231 iteration 3231; minNextMutationTime = 1993.51; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 717 *** Looping through 5.2. Iter = 3232 iteration 3232; minNextMutationTime = 1993.51; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 336 *** Looping through 5.2. Iter = 3233 iteration 3233; minNextMutationTime = 1993.51; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 243 *** Looping through 5.2. Iter = 3234 iteration 3234; minNextMutationTime = 1993.52; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 190 *** Looping through 5.2. Iter = 3235 iteration 3235; minNextMutationTime = 1993.53; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7081 *** Looping through 5.2. Iter = 3236 iteration 3236; minNextMutationTime = 1993.54; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 337 *** Looping through 5.2. Iter = 3237 iteration 3237; minNextMutationTime = 1993.54; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 339 *** Looping through 5.2. Iter = 3238 iteration 3238; minNextMutationTime = 1993.56; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 669 *** Looping through 5.2. Iter = 3239 iteration 3239; minNextMutationTime = 1993.58; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 677 *** Looping through 5.2. Iter = 3240 iteration 3240; minNextMutationTime = 1993.58; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 678 *** Looping through 5.2. Iter = 3241 iteration 3241; minNextMutationTime = 1993.58; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7080 *** Looping through 5.2. Iter = 3242 iteration 3242; minNextMutationTime = 1993.59; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7085 *** Looping through 5.2. Iter = 3243 iteration 3243; minNextMutationTime = 1993.59; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 245 *** Looping through 5.2. Iter = 3244 iteration 3244; minNextMutationTime = 1993.6; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7085 *** Looping through 5.2. Iter = 3245 iteration 3245; minNextMutationTime = 1993.64; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 724 *** Looping through 5.2. Iter = 3246 iteration 3246; minNextMutationTime = 1993.65; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 191 *** Looping through 5.2. Iter = 3247 iteration 3247; minNextMutationTime = 1993.66; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7090 *** Looping through 5.2. Iter = 3248 iteration 3248; minNextMutationTime = 1993.66; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 340 *** Looping through 5.2. Iter = 3249 iteration 3249; minNextMutationTime = 1993.67; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 341 *** Looping through 5.2. Iter = 3250 iteration 3250; minNextMutationTime = 1993.67; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 678 *** Looping through 5.2. Iter = 3251 iteration 3251; minNextMutationTime = 1993.68; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 243 *** Looping through 5.2. Iter = 3252 iteration 3252; minNextMutationTime = 1993.68; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 243 *** Looping through 5.2. Iter = 3253 iteration 3253; minNextMutationTime = 1993.69; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 192 *** Looping through 5.2. Iter = 3254 iteration 3254; minNextMutationTime = 1993.69; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 244 *** Looping through 5.2. Iter = 3255 iteration 3255; minNextMutationTime = 1993.73; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 245 *** Looping through 5.2. Iter = 3256 iteration 3256; minNextMutationTime = 1993.74; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 342 *** Looping through 5.2. Iter = 3257 iteration 3257; minNextMutationTime = 1993.77; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 715 *** Looping through 5.2. Iter = 3258 iteration 3258; minNextMutationTime = 1993.77; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 247 *** Looping through 5.2. Iter = 3259 iteration 3259; minNextMutationTime = 1993.78; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 678 *** Looping through 5.2. Iter = 3260 iteration 3260; minNextMutationTime = 1993.78; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 679 *** Looping through 5.2. Iter = 3261 iteration 3261; minNextMutationTime = 1993.8; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 348 *** Looping through 5.2. Iter = 3262 iteration 3262; minNextMutationTime = 1993.82; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7152 *** Looping through 5.2. Iter = 3263 iteration 3263; minNextMutationTime = 1993.88; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 8 (Genotype = 0000000000000000000000000000000000000000000000000000000000100001; sp_id = 33) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 33) New popSize = 198 *** Looping through 5.2. Iter = 3264 iteration 3264; minNextMutationTime = 1993.89; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 351 *** Looping through 5.2. Iter = 3265 iteration 3265; minNextMutationTime = 1993.9; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7168 *** Looping through 5.2. Iter = 3266 iteration 3266; minNextMutationTime = 1993.9; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 715 *** Looping through 5.2. Iter = 3267 iteration 3267; minNextMutationTime = 1993.91; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 717 *** Looping through 5.2. Iter = 3268 iteration 3268; minNextMutationTime = 1993.92; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 718 *** Looping through 5.2. Iter = 3269 iteration 3269; minNextMutationTime = 1993.93; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 722 *** Looping through 5.2. Iter = 3270 iteration 3270; minNextMutationTime = 1993.94; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 246 *** Looping through 5.2. Iter = 3271 iteration 3271; minNextMutationTime = 1993.96; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 7 (Genotype = 0000000000000000000000000000000000000000000000000000000001000001; sp_id = 65) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 65) New popSize = 251 *** Looping through 5.2. Iter = 3272 iteration 3272; minNextMutationTime = 1993.96; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 682 *** Looping through 5.2. Iter = 3273 iteration 3273; minNextMutationTime = 1993.97; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 4 (Genotype = 0000000000000000000000000000000000000000000000000000000000010001; sp_id = 17) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 17) New popSize = 725 *** Looping through 5.2. Iter = 3274 iteration 3274; minNextMutationTime = 1993.97; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 6 (Genotype = 0000000000000000000000000000000000000000000000000000000000001001; sp_id = 9) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 9) New popSize = 682 *** Looping through 5.2. Iter = 3275 iteration 3275; minNextMutationTime = 1993.97; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 3 (Genotype = 0000000000000000000000000000000000000000000000000000000000000101; sp_id = 5) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 5) New popSize = 7182 *** Looping through 5.2. Iter = 3276 iteration 3276; minNextMutationTime = 1993.98; timeNextPopSample = 1994; popParams.size() = 9 Mutated to existing species 5 (Genotype = 0000000000000000000000000000000000000000000000000000000000000011; sp_id = 3) from species 1 (Genotypes = 0000000000000000000000000000000000000000000000000000000000000001; sp_id = 3) New popSize = 348 *** Looping through 5.2. Iter = 3277 iteration 3277; minNextMutationTime = 2004; timeNextPopSample = 1994; popParams.size() = 9 We are SAMPLING. We reached finalTime 1994 ... finished this run: Total Pop Size = 16051391 Drivers Last = 2 Final Time = 1994 Starting sample-only-last tests Thu Apr 12 01:36:15 2018 Seed = 7394 bozic bozic9 . Poset = p1101 Seed = 7394 Exp Exp9 . Poset = p1101 Seed = 7394 mc mc9 . Poset = p1101 Seed = 3983 bozic bozic9 . Poset = p901 Seed = 3983 Exp Exp9 . Poset = p901 Seed = 3983 mc mc9 . Poset = p901 Seed = 5819 bozic bozic9 . Poset = p701 Seed = 5819 Exp Exp9 . Poset = p701 Seed = 5819 mc mc9 . Poset = p701 Ending sample-only-last tests Thu Apr 12 01:36:36 2018 Starting total-present-drivers tests Thu Apr 12 01:36:36 2018 Ending total-present-drivers tests Thu Apr 12 01:36:37 2018 Starting all fitness at Thu Apr 12 01:36:39 2018Genotype: d1 , d2, f3 Individual s terms are : 0.4 Fitness: 1.4 Genotype: f3 , d1 , d2 Individual s terms are : -0.3 Fitness: 0.7 Genotype: f3 , d1 , d2 Individual s terms are : -0.3 Death rate: 1.3 DEBUG2: Value of rnb = nan DEBUG2: Value of m = 1 DEBUG2: Value of pe = 0 DEBUG2: Value of pm = 1 this is spP popSize = 1 birth = 1 death = 0 W = 1 R = 1 mutation = 1e-06 timeLastUpdate = 77.9747 absfitness = -inf numMutablePos =1 Unrecoverable exception: Algo 2: retval not finite. Aborting. DEBUG2: Value of rnb = nan DEBUG2: Value of m = 1 DEBUG2: Value of pe = 0 DEBUG2: Value of pm = 0.999998 this is spP popSize = 1 birth = 1 death = 0 W = 1 R = 1 mutation = 4e-06 timeLastUpdate = 333.531 absfitness = -inf numMutablePos =4 Unrecoverable exception: Algo 2: retval not finite. Aborting. Ending all-fitness at Thu Apr 12 01:36:44 2018 Starting driverCounts at Thu Apr 12 01:36:44 2018 doing iteration 1 doing iteration 2 doing iteration 3 doing iteration 4 doing iteration 5 doing iteration 6 doing iteration 7 doing iteration 8 doing iteration 9 doing iteration 10 doing iteration 11 doing iteration 12 doing iteration 13 doing iteration 14 doing iteration 15 doing iteration 16 doing iteration 17 doing iteration 18 doing iteration 19 doing iteration 20 doing iteration 21 doing iteration 22 doing iteration 23 doing iteration 24 doing iteration 25 doing iteration 26 doing iteration 27 doing iteration 28 doing iteration 29 doing iteration 30 doing iteration 31 doing iteration 32 doing iteration 33 doing iteration 34 doing iteration 35 doing iteration 36 doing iteration 37 doing iteration 38 doing iteration 39 doing iteration 40 doing iteration 41 doing iteration 42 doing iteration 43 doing iteration 44 doing iteration 45 doing iteration 46 doing iteration 47 doing iteration 48 doing iteration 49 doing iteration 50 doing iteration 51 doing iteration 52 doing iteration 53 doing iteration 54 doing iteration 55 doing iteration 56 doing iteration 57 doing iteration 58 doing iteration 59 doing iteration 60 doing iteration 61 doing iteration 62 doing iteration 63 doing iteration 64 doing iteration 65 doing iteration 66 doing iteration 67 doing iteration 68 doing iteration 69 doing iteration 70 doing iteration 71 doing iteration 72 doing iteration 73 doing iteration 74 doing iteration 75 doing iteration 76 doing iteration 77 doing iteration 78 doing iteration 79 doing iteration 80 doing iteration 81 doing iteration 82 doing iteration 83 doing iteration 84 doing iteration 85 doing iteration 86 doing iteration 87 doing iteration 88 doing iteration 89 doing iteration 90 doing iteration 91 doing iteration 92 doing iteration 93 doing iteration 94 doing iteration 95 doing iteration 96 doing iteration 97 doing iteration 98 doing iteration 99 doing iteration 100 Ending driverCounts at Thu Apr 12 01:36:52 2018 Starting epist-order-modules at Thu Apr 12 01:36:52 2018 Ending epist-order-modules at Thu Apr 12 01:36:52 2018 Starting exercise-plotting-code at Thu Apr 12 01:36:52 2018 Ending exercise-plotting-code at Thu Apr 12 01:37:04 2018 Starting fitness preds at Thu Apr 12 01:37:04 2018 Observed vs expected, case III done tries 1 Ending fitness preds long at Thu Apr 12 01:37:12 2018 Starting fixation at Thu Apr 12 01:37:12 2018 Ending fixation at Thu Apr 12 01:37:35 2018 Starting init-mutant tests Thu Apr 12 01:37:36 2018 done tries 1 done tries 1 done tries 1 Ending init-mutant tests Thu Apr 12 01:37:39 2018 Starting at mutPropGrowth Thu Apr 12 01:37:39 2018 Thu Apr 12 01:37:39 2018 mcf1: a runif is 0.01845909 mcf1a: a runif is 0.632479 mcf1c: a runif is 0.4728942 done tries 1 Thu Apr 12 01:37:40 2018 mcf1_ontime: a runif is 0.4351498 mcf1a: a runif is 0.6159823 mcf1c: a runif is 0.3789529 done tries 1 Thu Apr 12 01:37:41 2018 oss1: a runif is 0.6450749 oss1a: a runif is 0.9851512 oss1c: a runif is 0.9346654 done tries 1 oss1_ontime: a runif is 0.4187848 oss1a: a runif is 0.318398 oss1c: a runif is 0.05379778 done tries 1 ossmcf1: a runif is 0.4986153 ossmcf1a: a runif is 0.4010273 ossmcf1c: a runif is 0.8928362 done tries 1 ossmcf1: a runif is 0.6737999 ossmcf1a: a runif is 0.354306 ossmcf1c: a runif is 0.4856589 done tries 1 DEBUG2: Value of spP.death = 1 DEBUG2: Value of spP.birth = 0 DEBUG2: Value of pM = 1 DEBUG2: Value of spP.W = 1 DEBUG2: Value of spP.mutation = 0 Unrecoverable exception: pE.f: pE not finite. This is expected to happen when mutationPropGrowth = TRUE and you have have an initMutant with death >> birth, as that inevitably leads to net birth rate of 0 and mutation rate of 0. Aborting. Ended test.mutPropGrowth: Thu Apr 12 01:37:49 2018 Starting test.mutator-oncoSimulSample.R test at Thu Apr 12 01:37:50 2018 MCFL: AEu8: a runif is 0.5098031 WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. done tries 1 mcx2bc: a runif is 0.6952078 done tries 1 x2ef: a runif is 0.5895613 done tries 1 x2gh: a runif is 0.8362661 done tries 1 nm2: a runif is 0.4110012 done tries 1 mcz2: a runif is 0.0954404 done tries 1 Finished test.mutator-oncoSimulSample.R test at Thu Apr 12 01:37:57 2018 Starting test.mutator.R test at Thu Apr 12 01:37:57 2018 Individual s terms are : x2gh: a runif is 0.7918236 done tries 1 u6: a runif is 0.03398126 done tries 1 mcfu6: a runif is 0.1207316 done tries 1 nm2: a runif is 0.01585625 done tries 1 nm3: a runif is 0.1495879 done tries 1 mcfl_z2: a runif is 0.2284863 done tries 1 mmdSM1: a runif is 0.1294376 [1] 5.334016e-07 [1] 8.436782e-12 done tries 1 mmpg_mcfl: a runif is 0.4062301 done tries 1 Finished test.mutator.R test at Thu Apr 12 01:38:10 2018 Starting oncoSimulIndiv-miscell tests Thu Apr 12 01:38:10 2018 ...... Done individual 1 . Used 1 attempts. . Running for 0.001688719 secs. ...... Done individual 2 . Used 2 attempts. . Running for 0.003458977 secs. ...... Done individual 1 . Used 1 attempts. . Running for 0.002002716 secs. ...... Done individual 2 . Used 2 attempts. . Running for 0.004139423 secs. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitting max tries is regarded as an error. Ending oncoSimulIndiv-miscell tests Thu Apr 12 01:38:17 2018 Starting oncoSimulSample-failures tests Thu Apr 12 01:38:17 2018 Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted wall time. Exiting. Hitting wall time is regarded as an error. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 0. There can be numerical problems later. Entered Algo2 with mutation rate = 0 Unrecoverable exception: mutation = 0 with numMutable != 0?. Aborting. Ending oncoSimulSample-failures tests Thu Apr 12 01:38:22 2018 Starting oncoSimulSample-limits tests Thu Apr 12 01:38:22 2018 Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Hitted maxtries. Exiting. Hitting max tries is regarded as an error. Ending oncoSimulSample-limits tests Thu Apr 12 01:38:22 2018 Starting per-gene-mutation rates at Thu Apr 12 01:38:22 2018 s01: a runif is 0.4584035 s02: a runif is 0.5597542 s03: a runif is 0.01170086 s04: a runif is 0.7841349 s05: a runif is 0.522031 s06: a runif is 0.6840953 s07: a runif is 0.1050774 s15: a runif is 0.2009383 sz01: a runif is 0.6667587 sz02: a runif is 0.7302239 sz03: a runif is 0.6493194 sz04: a runif is 0.8755105 sz05: a runif is 0.8774868 sz06: a runif is 0.02936305 s3: a runif is 0.1608007 done tries 1 s4: a runif is 0.6559625 done tries 1 s5: a runif is 0.1138907 done tries 1 s6: a runif is 0.1693086 done tries 1 s7: a runif is 0.0967877 done tries 1 s8: a runif is 0.6735857 done tries 1 s9: a runif is 0.151247 done tries 1 s10: a runif is 0.6782784 s12: a runif is 0.8343519 s12b: a runif is 0.5861779 WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. done tries 1 s14: a runif is 0.8728978 WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. s14b: a runif is 0.6265675 WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = WARNING: the smallest mutation rate is 1e-15<= . There can be numerical problems later. 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. done tries 1 s18: a runif is 0.4340974 done tries 1 mcs19: a runif is 0.5616112 WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-11. There can be numerical problems later. done tries 1 s20: a runif is 0.9916827 s20b: a runif is 0.9065737 s20c: a runif is 0.5698162 done tries 1 df1: a runif is 0.134113 df1a: a runif is 0.9882412 df1b: a runif is 0.699106 done tries 1 mcdf2: a runif is 0.1708754 mcdf2a: a runif is 0.9019022 mcdf2b: a runif is 0.6264855 done tries 1 mpgs3: a runif is 0.1109615 mpgs3a: a runif is 0.1628212 mpgs3b: a runif is 0.2539181 done tries 1 mcoss11: a runif is 0.4109857 mcoss1a: a runif is 0.001601573 mcoss1b: a runif is 0.64177 done tries 1 mcoss2: a runif is 0.903511 mcoss2a: a runif is 0.9413505 mcoss2b: a runif is 0.2851401 done tries 1 mpg s14: a runif is 0.5102254 WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. mpg s14b: a runif is 0.5144168 WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= WARNING: the smallest mutation rate is <= 1e-11. That is a really small value1e-11(per-base mutation rate in the human genome is. That is a really small value ˜ 1e-11 to 1e-9). (per-base mutation rate in the human genome isSetting dummyMutationRate to your min/100 = ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= WARNING: the smallest mutation rate is <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is WARNING: the smallest mutation rate is <= <= 1e-111e-11. That is a really small value. That is a really small value(per-base mutation rate in the human genome is(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = Setting dummyMutationRate to your min/100 = 1e-151e-15. There can be numerical problems later. . There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome isWARNING: the smallest mutation rate is ˜ 1e-11 to 1e-9). <= Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. WARNING: the smallest mutation rate is <= 1e-11. That is a really small value(per-base mutation rate in the human genome is ˜ 1e-11 to 1e-9). Setting dummyMutationRate to your min/100 = 1e-15. There can be numerical problems later. done tries 1 mpg mcdf2: a runif is 0.6987842 mpg mcdf2a: a runif is 0.4325937 mpg mcdf2b: a runif is 0.8529822 done tries 1 mcsz033: a runif is 0.6566111 mcsz033a: a runif is 0.2324362 mcsz033b: a runif is 0.363865 [1] 1.494454 [1] 1.805912 [1] 9 [1] 12 T1 is TRUE T2 is TRUE done tries 1 osSFPSMcFL: a runif is 0.4137342 osSFPSMcFLa: a runif is 0.8459487 osSFPSMcFLb: a runif is 0.8635837 done tries 1 Done per-gene-mutation rates at Thu Apr 12 01:39:44 2018 Starting poset-transformations tests Thu Apr 12 01:39:46 2018 Ending poset-transformations tests Thu Apr 12 01:39:50 2018 Starting sample-prob Thu Apr 12 01:39:50 2018 [1] 1.848648e-25 done tries 1 [1] 1.879953e-20 done tries 1 [1] 3.378933e-20 done tries 1 [1] 1.970215e-17 done tries 1 [1] 2.718434e-25 done tries 1 [1] 3.815616e-27 done tries 1 [1] 7.742915e-14 done tries 1 [1] 1.137903e-11 done tries 1 [1] 5.404701e-26 done tries 1 [1] 1.045473e-16 done tries 1 [1] 3.90877e-18 done tries 1 [1] 2.609295e-20 done tries 1 Ending sample-prob tests Thu Apr 12 01:40:33 2018 Starting samplePop tests Thu Apr 12 01:40:33 2018 Ending samplePop tests Thu Apr 12 01:40:53 2018 Starting simuls-runs-examples tests Thu Apr 12 01:40:53 2018 Doing i = 1 name = w Doing i = 2 name = sv Doing i = 3 name = pancr Doing i = 4 name = xor1 Doing i = 5 name = ofe2 Doing i = 1 name = w Doing i = 2 name = sv Doing i = 3 name = pancr Doing i = 4 name = xor1 Doing i = 5 name = ofe2 Doing i = 1 name = w Doing i = 1 name = w Doing i = 2 name = sv Doing i = 2 name = sv Doing i = 3 name = pancr Doing i = 3 name = pancr Doing i = 4 name = xor1 Doing i = 4 name = xor1 Doing i = 5 name = ofe2 Doing i = 5 name = ofe2 Doing i = 1 name = w Doing i = 2 name = sv Doing i = 3 name = pancr Doing i = 4 name = xor1 Doing i = 5 name = ofe2 Ending simuls-runs-examples tests Thu Apr 12 01:41:08 2018 Starting warning-mutPropGrowth tests Thu Apr 12 01:41:08 2018 a runif is 0.7692966 Ending warning-mutPropGrowth tests Thu Apr 12 01:41:09 2018 Starting wide2long tests Thu Apr 12 01:41:09 2018 Ending wide2long tests Thu Apr 12 01:41:10 2018 ══ testthat results ═══════════════════════════════════════════════════════════ OK: 3027 SKIPPED: 10 FAILED: 0 > > proc.time() user system elapsed 413.640 27.004 306.656
OncoSimulR.Rcheck/OncoSimulR-Ex.timings
name | user | system | elapsed | |
OncoSimulWide2Long | 0.812 | 0.008 | 0.818 | |
POM | 1.940 | 0.056 | 2.415 | |
allFitnessEffects | 3.428 | 0.028 | 3.459 | |
benchmarks | 0.012 | 0.000 | 0.009 | |
evalAllGenotypes | 0.192 | 0.004 | 0.198 | |
example-missing-drivers | 0.500 | 0.004 | 0.505 | |
examplePosets | 0.348 | 0.000 | 0.350 | |
examplesFitnessEffects | 0.052 | 0.000 | 0.051 | |
mcfLs | 3.164 | 0.104 | 3.267 | |
oncoSimulIndiv | 6.996 | 0.580 | 5.686 | |
plot.fitnessEffects | 0.800 | 0.008 | 0.809 | |
plot.oncosimul | 3.048 | 0.168 | 2.791 | |
plotClonePhylog | 1.004 | 0.016 | 1.020 | |
plotFitnessLandscape | 1.288 | 0.000 | 1.289 | |
plotPoset | 0.116 | 0.000 | 0.117 | |
poset | 0.148 | 0.000 | 0.149 | |
rfitness | 0.384 | 0.000 | 0.382 | |
samplePop | 0.164 | 0.168 | 0.217 | |
simOGraph | 0.200 | 0.004 | 0.206 | |
to_Magellan | 0.020 | 0.000 | 0.021 | |