% \iffalse meta-comment % %% File: expl3.dtx % % Copyright (C) 1990-2024 The LaTeX Project % % It may be distributed and/or modified under the conditions of the % LaTeX Project Public License (LPPL), either version 1.3c of this % license or (at your option) any later version. The latest version % of this license is in the file % % https://www.latex-project.org/lppl.txt % % This file is part of the "l3kernel bundle" (The Work in LPPL) % and all files in that bundle must be distributed together. % % ----------------------------------------------------------------------- % % The development version of the bundle can be found at % % https://github.com/latex3/latex3 % % for those people who are interested. % %<*driver|generic|package|2ekernel> % \def\ExplFileDate{2024-12-25}% %<*driver> \documentclass[full]{l3doc} \usepackage{graphicx} \begin{document} \DocInput{\jobname.dtx} \end{document} % % \fi % % \providecommand\acro[1]{\textsc{\MakeLowercase{#1}}} % \newenvironment{arg-description}{% % \begin{itemize}\def\makelabel##1{\hss\llap{\bfseries##1}}}{\end{itemize}} % % \title{^^A % The \pkg{expl3} package and \LaTeX3 programming^^A % } % % \author{^^A % The \LaTeX{} Project\thanks % {^^A % E-mail: % \href{mailto:latex-team@latex-project.org} % {latex-team@latex-project.org}^^A % }^^A % } % % \date{Released 2024-12-25} % % \maketitle % % \begin{documentation} % % \begin{abstract} % % This document gives an introduction to a new set of programming % conventions that have been designed to meet the requirements of % implementing large scale \TeX{} macro programming projects such as % \LaTeX{}. These programming conventions are the base layer of \LaTeX3. % % The main features of the system described are: % \begin{itemize} % \item classification of the macros (or, in \LaTeX{} terminology, % commands) into \LaTeX{} functions and \LaTeX{} parameters, and also % into modules containing related commands; % \item a systematic naming scheme based on these classifications; % \item a simple mechanism for controlling the expansion of a function's % arguments. % \end{itemize} % This system is being used as the basis for \TeX{} programming within % The \LaTeX{} Project. Note that the language is not intended for either % document mark-up or style specification. Instead, it is intended that % such features will be built on top of the conventions described here. % % This document is an introduction to the ideas behind the \pkg{expl3} % programming interface. For the complete documentation of the programming % layer provided by The \LaTeX{} Project, see the accompanying % \texttt{interface3} document. % % \end{abstract} % % \section{Introduction} % % The first step to develop a \LaTeX{} kernel beyond \LaTeXe{} is to % address how the underlying system is programmed. Rather than the % current mix of \LaTeX{} and \TeX{} macros, the \LaTeX3 system provides % its own consistent interface to all of the functions needed to % control \TeX{}. A key part of this work is to ensure that everything % is documented, so that \LaTeX{} programmers and users can work % efficiently without needing to be familiar with the internal nature % of the kernel or with plain \TeX{}. % % The \pkg{expl3} bundle provides this new programming interface for % \LaTeX{}. To make programming systematic, \LaTeX3 uses some very % different conventions to \LaTeXe{} or plain \TeX{}. As a result, % programmers starting with \LaTeX3 need to become familiar with % the syntax of the new language. % % The next section shows where this language fits into a complete % \TeX{}-based document processing system. We then describe the major % features of the syntactic structure of command names, including the % argument specification syntax used in function names. % % The practical ideas behind this argument syntax will be explained, % together with the expansion control mechanism and the interface % used to define variant forms of functions. % % As we shall demonstrate, the use of a structured naming scheme and of % variant forms for functions greatly improves the readability of the % code and hence also its reliability. Moreover, experience has shown % that the longer command names which result from the new syntax do not % make the process of \emph{writing} code significantly harder. % % \section{Languages and interfaces} % % It is possible to identify several distinct languages related to the % various interfaces that are needed in a \TeX{}-based document processing % system. This section looks at those we consider most important for % the \LaTeX3 system. % % \begin{description} % \item[Document mark-up] This comprises those commands (often called % tags) that are to embedded in the document (the |.tex| file). % % It is generally accepted that such mark-up should be essentially % \emph{declarative}. It may be traditional \TeX{}-based mark-up such % as \LaTeXe{}, as described in~\cite{A-W:LLa94} and~\cite{A-W:GMS94}, % or a mark-up language defined via \acro{HTML} or \acro{XML}. % % One problem with more traditional \TeX{} coding conventions (as % described in~\cite{A-W:K-TB}) is that the names and syntax of \TeX{}'s % primitive formatting commands are ingeniously designed to be % \enquote{natural} when used directly by the author as document mark-up % or in macros. Ironically, the ubiquity (and widely recognised % superiority) of logical mark-up has meant that such explicit % formatting commands are almost never needed in documents or in % author-defined macros. Thus they are used almost exclusively by % \TeX{} programmers to define higher-level commands, and their % idiosyncratic syntax is not at all popular with this community. % Moreover, many of them have names that could be very useful as % document mark-up tags were they not pre-empted as primitives % (\emph{e.g.}~\tn{box} or \tn{special}). % % \item[Designer interface] This relates a (human) typographic % designer's specification for a document to a program that % \enquote{formats % the document}. It should ideally use a declarative language that % facilitates expression of the relationship and spacing rules % specified for the layout of the various document elements. % % This language is not embedded in document text and it will be very % different in form to the document mark-up language. For \LaTeX{}, % this level was almost completely missing from \LaTeX{}2.09; \LaTeXe{} % made some improvements in this area but it is still the case that % implementing a design specification in \LaTeX{} requires far more % \enquote{low-level} coding than is acceptable. % % \item[Programmer interface] % This language is the implementation language within which the % basic typesetting functionality is implemented, building upon the % primitives of \TeX{} (or a successor program). It may also be used % to implement the previous two languages \enquote{within} \TeX{}, as in % the % current \LaTeX{} system. % % \end{description} % % The last layer is covered by the conventions described in this % document, which describes a system aimed at providing a suitable % basis for coding \LaTeX3. Its main distinguishing features are % summarised here: % \begin{itemize} % \item A consistent naming scheme for all commands, including \TeX{} % primitives. % \item The classification of commands as \LaTeX{} functions or \LaTeX{} % parameters, and also their division into modules according to their % functionality. % \item A simple mechanism for controlling argument expansion. % \item Provision of a set of core \LaTeX{} functions that is sufficient % for handling programming constructs such as queues, sets, stacks, % property lists. % \item A \TeX{} programming environment in which, for example, all % white space is ignored. % \end{itemize} % % \section{The naming scheme} % % \LaTeX3 does not use |@| as a \enquote{letter} for defining % internal macros. Instead, the symbols |_| and |:| % are used in internal macro names to provide structure. In % contrast to the plain \TeX{} format and the \LaTeXe{} kernel, these % extra letters are used only between parts of a macro name (no % strange vowel replacement). % % While \TeX{} is actually a macro processor, by % convention for the \pkg{expl3} programming language we distinguish between % \emph{functions} and \emph{variables}. Functions can have arguments and they % are either expanded or executed. Variables can be assigned values and they % are used in arguments to functions; they are not used directly but are % manipulated by functions (including getting and setting functions). % Functions and variables with a related functionality (for example accessing % counters, or manipulating token lists, \emph{etc.})\ are collected together % into a % \emph{module}. % % \subsection{Examples} % % Before giving the details of the naming scheme, here are a few typical % examples to indicate the flavour of the scheme; first some variable % names. % \begin{quote} % \cs{l_tmpa_box} is a local variable (hence the~|l_| prefix) % corresponding to a box register.\\ % \cs{g_tmpa_int} is a global variable (hence the~|g_| prefix) % corresponding to an integer register (i.e.~a \TeX{} count % register).\\ % \cs{c_empty_tl} is the constant~(|c_|) token list variable % that is always empty. % \end{quote} % % Now here is an example of a typical function name. % % \cs{seq_push:Nn} is the function which puts the token list specified % by its second argument onto the stack specified by its first argument. % The different natures of the two arguments are indicated by the~|:Nn| % suffix. The first argument must be a single token which \enquote{names} % the stack parameter: such single-token arguments are denoted~|N|. % The second argument is a normal \TeX{} \enquote{undelimited argument}, % which % may either be a single token or a balanced, brace-delimited token % list (which we shall here call a \textit{braced token list}): the~|n| % denotes such a \enquote{normal} argument form. The name of the function % indicates it belongs to the |seq| module. % % \subsection{Formal naming syntax} % % We shall now look in more detail at the syntax of these names. A % function name in \LaTeX3 has a name consisting of three parts: % \begin{quote} % |\|\meta{module}|_|\meta{description}|:|\meta{arg-spec} % \end{quote} % while a variable has (up to) four distinct parts to its name: % \begin{quote} % |\|\meta{scope}|_|\meta{module}|_|\meta{description}|_|\meta{type} % \end{quote} % % The syntax of all names contains % \begin{quote} % \meta{module} and \meta{description} % \end{quote} % these both give information about the command. % % A \emph{module} is a collection of closely related functions and % variables. Typical module names include~|int| for integer parameters % and related functions,~|seq| for sequences and~|box| for boxes. % % Packages providing new programming functionality will add new modules % as needed; the programmer can choose any unused name, consisting % of letters only, for a module. In general, the module name and module % prefix should be related: for example, the kernel module containing % \texttt{box} functions is called \texttt{l3box}. Module names and % programmers' contact details are listed in \pkg{l3prefixes.csv}. % % The \emph{description} gives more detailed information about the % function or parameter, and provides a unique name for it. It should % consist of letters and, possibly,~|_|~characters. In general, the % description should use |_| to divide up \enquote{words} or other easy to % follow parts of the name. For example, the \LaTeX3 kernel provides % \cs{if_cs_exist:N} which, as might be expected, tests if a command % name exists. % % Where functions for variable manipulation can perform assignments % either locally or globally, the latter case is indicated by the inclusion of % a |g| in the second part of the function name. Thus \cs{tl_set:Nn} is a local % function but \cs{tl_gset:Nn} acts globally. Functions of this type are % always documented together, and the scope of action may therefore be % inferred from the presence or absence of a |g|. See the next subsection for % more detail on variable scope. % % \subsubsection{Separating private and public material} % % One of the issues with the \TeX{} language is that it doesn't support % name spaces and encapsulation other than by convention. As a result % nearly every internal command in the \LaTeXe{} kernel has eventually % be used by extension packages as an entry point for modifications or % extensions. The consequences of this is that nowadays it is next to % impossible to change anything in the \LaTeXe{} kernel (even if it is % clearly just an internal command) without breaking something. % % In \pkg{expl3} we hope to improve this situation drastically by % clearly separating public interfaces (that extension packages can use % and rely on) and private functions and variables (that should not % appear outside of their module). There is (nearly) no way to enforce % this without severe computing overhead, so we implement it only % through a naming convention, and some support mechanisms. However, we % think that this naming convention is easy to understand and to follow, % so that we are confident that this will adopted and provides the % desired results. % % Functions created by a module may either be \enquote{public} (documented % with a defined interface) or \enquote{private} (to be used only within % that module, and thus not formally documented). It is important that % only documented interfaces are used; at the same time, it is necessary to % show within the name of a function or variable whether it is public % or private. % % To allow clear separation of these two cases, the following convention % is used. To denote a private function or a private variable (of the module), % two |_| characters are used in front of the module name, e.g. % \begin{verbatim} % \module_foo:nnn % \end{verbatim} % is a public function which should be documented while % \begin{verbatim} % \__module_foo:nnn % \end{verbatim} % is private to the module, and should \emph{not} be used outside of that % module. % % For variables, to avoid three |_| in a row, the separator for the variable % scope and any leading |_| for a private interface in the module part are % combined. Thus % \begin{verbatim} % \l_module_foo_tl % \end{verbatim} % is a public variable and % \begin{verbatim} % \l__module_foo_tl % \end{verbatim} % is private. % % \subsubsection{Using \texttt{@@} and \pkg{DocStrip} to mark private code} % % The formal syntax for internal functions allows clear separation of public % and private code, but includes redundant information (every internal function % or variable includes \texttt{__\meta{module}}). To aid programmers, the % \pkg{DocStrip} program introduces the syntax % \begin{quote} % \ttfamily % |%<@@=|\meta{module}|>| % \end{quote} % which then allows |@@| (and |_@@| in case of variables) to be used as % a place holder for \texttt{__\meta{module}} in code. Thus for example % \begin{verbatim} % %<@@=foo> % % \begin{macrocode} % \cs_new:Npn \@@_function:n #1 % ... % \tl_new:N \l_@@_my_tl % % \end{macrocode} % \end{verbatim} % is converted by \pkg{DocStrip} to % \begin{verbatim} % \cs_new:Npn \__foo_function:n #1 % ... % \tl_new:N \l__foo_my_tl % \end{verbatim} % on extraction. As you can see both |_@@| and |@@| are mapped to % \texttt{__\meta{module}}, because we think that this helps to % distinguish variables from functions in the source when the |@@| % convention is used. % % \subsubsection{Variables: declaration} % % In well-formed \pkg{expl3} code, variables should always be declared before % assignment is attempted. This is true even for variable types where the % underlying \TeX{} implementation will allow direct assignment. This applies % both to setting directly (\cs{tl_set:Nn}, etc.) and to setting equal % (\cs{tl_set_eq:NN}, etc.). % % To help programmers to adhere to this approach, the debugging option % |check-declarations| may be given % \begin{verbatim} % \debug_on:n { check-declarations } % \end{verbatim} % and will issue an error whenever an assignment is made to a non-declared % variable. There is a performance implication, so this option should only % be used for testing. % % \subsubsection{Variables: scope and type} % % The \meta{scope} part of the name describes how the variable can be % accessed. Variables are classified as local, global or constant. % This \emph{scope} type appears as a code at the beginning of the name; % the codes used are: % \begin{arg-description} % \item[c] constants (global variables whose value should not be % changed); % \item[g] variables whose value should only be set globally; % \item[l] variables whose value should only be set locally. % \end{arg-description} % % Separate functions are provided to assign data to local and global % variables; for example, \cs{tl_set:Nn} and \cs{tl_gset:Nn} respectively % set the value of a local or global \enquote{token list} variable. % Note that it is a poor \TeX{} practice to intermix local and global % assignments to a variable; otherwise you risk exhausting the save % stack.\footnote{See \emph{The \TeX{}book}, p.\,301, for further % information.} % % The \meta{type} is in the list of available % \emph{data-types};\footnote{Of course, if a totally new data type is % needed then this will not be the case. However, it is hoped that only % the kernel team will need to create new data types.} these include the % primitive \TeX{} data-types, such as the various registers, but to % these are added data-types built within the \LaTeX{} programming % system. % % The data types in \LaTeX3 are: % \begin{description} % \item[bitset] a string of bits (\texttt{0} and \texttt{1} tokens) that are % accessed by position or by name; % \item[bool] either true or false (the \LaTeX3 implementation does % not use \tn{iftrue} or \tn{iffalse}); % \item[box] box register; % \item[cctab] category code table; % \item[clist] comma separated list; % \item[coffin] a \enquote{box with handles} --- a higher-level data % type for carrying out |box| alignment operations; % \item[dim] \enquote{rigid} lengths; % \item[fp] floating-point values; % \item[fparray] fixed-size vector of floating-point values; % \item[int] integer-valued count register; % \item[intarray] fixed-size vector of integer values; % \item[ior] an input stream (for reading from a file); % \item[iow] an output stream (for writing to a file); % \item[muskip] math mode \enquote{rubber} lengths; % \item[prop] property list; % \item[regex] regular expression; % \item[seq] sequence: a data-type used to implement lists (with % access at both ends) and stacks; % \item[skip] \enquote{rubber} lengths; % \item[str] \TeX{} strings: a special case of |tl| in which all % characters have category \enquote{other} (catcode~$12$), % other than spaces which are category \enquote{space} % (catcode~$10$); % \item[token] equal to a single arbitrary token; % \item[tl] \enquote{token list variables}: placeholders for token lists. % \end{description} % When the \meta{type} and \meta{module} are identical (as often happens in % the more basic modules) the \meta{module} part is often omitted for % aesthetic reasons. % % The name \enquote{token list} may cause confusion, and so some % background is useful. \TeX{} works with tokens and lists of tokens, % rather than characters. It provides two ways to store these token % lists: within macros and as token registers (|toks|). The % implementation in \LaTeX3 means that |toks| are not required, and that % all operations for storing tokens can use the |tl| variable type. % % There are two more special types of constants: % \begin{arg-description} % \item[q] constants of quark type; % \item[s] constants of scan mark type. % \end{arg-description} % The \meta{type} part of quark and scan mark constants is omitted, and % the \meta{module} part of general quarks and scan marks is often % omitted too. % % Experienced \TeX{} programmers will notice that some of the variable % types listed are native \TeX{} registers whilst others are not. In % general, the underlying \TeX{} implementation for a data structure may % vary but the \emph{documented interface} will be stable. For example, % the |prop| data type was originally implemented as a |toks|, but % is currently built on top of the |tl| data structure. % % \subsubsection{Variables: guidance} % % Both comma lists and sequences have similar characteristics. % They both use special delimiters to mark out one entry from the % next, and are both accessible at both ends. In general, it is % easier to create comma lists `by hand' as they can be typed % in directly. User input often takes the form of a comma separated % list and so there are many cases where this is the obvious % data type to use. On the other hand, sequences use special internal % tokens to separate entries. This means that they can be used to % contain material that comma lists cannot (such as items that may % themselves contain commas!). In general, comma lists should be % preferred for creating fixed lists inside programs and for % handling user input where commas will not occur. On the other % hand, sequences should be used to store arbitrary lists of % data. % % \pkg{expl3} implements stacks using the sequence data structure. % Thus creating stacks involves first creating a sequence, and % then using the sequence functions which work in a stack manner % (\cs{seq_push:Nn}, \emph{etc}.). % % Due to the nature of the underlying \TeX{} implementation, it is % possible to assign values to token list variables and comma lists % without first declaring them. However, this is \emph{not supported % behavior}. The \LaTeX3 coding convention is that all variables must % be declared before use. % % The \pkg{expl3} package can be loaded with the \texttt{check-declarations} % option to verify that all variables are declared before use. This has % a performance implication and is therefore intended for testing during % development and not for use in production documents. % % \subsubsection{Functions: argument specifications} % % Function names end with an \meta{arg-spec} after a colon. This % gives an indication of the types of argument that a function takes, % and provides a convenient method of naming similar functions that % differ only in their argument forms (see the next section for % examples). % % The \meta{arg-spec} consists of a (possibly empty) list of letters, % each denoting one argument of the function. The letter, including % its case, conveys information about the type of argument required. % % All functions have a base form with arguments using one of the % following argument specifiers: % \begin{arg-description} % \item[n] Unexpanded token or braced token list.\\ % This is a standard \TeX{} undelimited macro argument. % \item[N] Single token (unlike~|n|, the argument must \emph{not} be % surrounded by braces).\\ % A typical example of a command taking an~|N| % argument is~|\cs_set|, in which the command being defined must be % unbraced. % \item[p] Primitive \TeX{} parameter specification.\\ % This can be something simple like~|#1#2#3|, but may use arbitrary % delimited argument syntax such as: |#1,#2\q_stop#3|. This is used % when defining functions. % \item[T,F] % These are special cases of~|n| arguments, used for the % true and false code in conditional commands. % \end{arg-description} % There are two other specifiers with more general meanings: % \begin{arg-description} % \item[D] Stands for \textbf{Do not use}. This special case is used % for \TeX{} primitives. These functions have no standardized % syntax, they are engine dependent and their name can change % without warning, thus their use is \emph{strongly discouraged} in % package code: programmers should instead use the interfaces % documented in \href{interface3.pdf}{interface3.pdf}%^^A % \footnote{If a primitive offers a functionality not yet in the % kernel, programmers and users are encouraged to write to the % \texttt{LaTeX-L} mailing list % (\url{mailto:LATEX-L@listserv.uni-heidelberg.de}) describing % their use-case and intended behaviour, so that a possible % interface can be discussed. Temporarily, while an interface is % not provided, programmers may use the procedure described in the % \href{l3styleguide.pdf}{l3styleguide.pdf}.}. % \item[w] This means that the argument syntax is \enquote{weird} in that it % does not follow any standard rule. It is used for functions with % arguments that take non standard forms: examples are \TeX{}-level % delimited arguments and the boolean tests needed after certain % primitive |\if|\ldots{} commands. % \end{arg-description} % % In case of |n| arguments that consist of a single token the % surrounding braces can be omitted in nearly all % situations---functions that force the use of braces even for single % token arguments are explicitly mentioned. However, programmers are % encouraged to always use braces around \texttt{n} arguments, as this % makes the relationship between function and argument clearer. % % Further argument specifiers are available as part of the expansion % control system. These are discussed in the next section. % % \section{Expansion control} % % Let's take a look at some typical operations one might want to % perform. Suppose we maintain a stack of open files and we use the % stack |\g_ior_file_name_seq| to keep track of them (\texttt{ior} is % the prefix used for the file reading module). The basic operation here % is to push a name onto this stack which could be done by the operation % \begin{quote} % \cs{seq_gpush:Nn} |\g_ior_file_name_seq {#1}| % \end{quote} % where |#1| is the filename. In other words, this operation would % push the file name as is onto the stack. % % However, we might face a situation where the filename is stored in % a variable of some sort, say |\l_ior_curr_file_tl|. In this case we % want to retrieve the value of the variable. If we simply use % \begin{quote} % \cs{seq_gpush:Nn} |\g_ior_file_name_seq| |\l_ior_curr_file_tl| % \end{quote} % we do not get the value of the variable pushed onto the stack, % only the variable name itself. Instead a suitable number of % \cs{exp_after:wN} would be necessary (together with extra braces) to % change the order of expansion,\footnote{\cs{exp_after:wN} is % the \LaTeX3 name for the \TeX{} \tn{expandafter} primitive.} \emph{i.e.} % \begin{quote} % \cs{exp_after:wN} \\ % | |\cs{seq_gpush:Nn} \\ % \cs{exp_after:wN} \\ % | \g_ior_file_name_seq| \\ % \cs{exp_after:wN} \\ % | { \l_ior_curr_file_tl }| % \end{quote} % % The above example is probably the simplest case but already shows % how the code changes to something difficult to understand. % Furthermore there is an assumption in this: that the storage bin % reveals its contents after exactly one expansion. Relying on this % means that you cannot do proper checking plus you have to know % exactly how a storage bin acts in order to get the correct number % of expansions. Therefore \LaTeX3 provides the programmer with a % general scheme that keeps the code compact and easy to understand. % % To denote that some argument to a function needs special treatment one % just uses different letters in the arg-spec part of the function to % mark the desired behavior. In the above example one would write % \begin{quote} % \cs{seq_gpush:NV} |\g_ior_file_name_seq \l_ior_curr_file_tl| % \end{quote} % to achieve the desired effect. Here the |V| (the second argument) % is for \enquote{retrieve the value of the variable} before passing it to % the base function. % % The following letters can be used to denote special treatment of % arguments before passing it to the base function: % \begin{description} % \item[c] Character string used as a command name.\\ The argument (a % token or braced token list) is \emph{fully expanded}; the result % must be a sequence of characters which is then used to construct a % command name (\emph{via}~\tn{csname} \ldots \tn{endcsname}). This % command name is a single token that is passed to the function as % the argument. Hence % \begin{quote} % \cs{seq_gpush:cV} |{ g_file_name_seq }| \cs{l_tmpa_tl} % \end{quote} % is equivalent to % \begin{quote} % \cs{seq_gpush:NV} |\g_file_name_seq| \cs{l_tmpa_tl}. % \end{quote} % Full expansion means that (a) the entire % argument must be expandable and (b) any variables are % converted to their content. So the preceding examples are also % equivalent to % \begin{quote} % \cs{tl_new:N} |\g_file_seq_name_tl| \\ % \cs{tl_gset:Nn} |\g_file_seq_name_tl { g_file_name_seq }| \\ % \cs{seq_gpush:cV} |{| \cs{tl_use:N} |\g_file_seq_name_tl }| \cs{l_tmpa_tl}. % \end{quote} % (Token list variables are expandable and we could omit the % accessor function \cs{tl_use:N}. Other variable types require the % appropriate \cs{\meta{var}_use:N} functions to be used in this % context.) % \item[V] Value of a variable.\\ % This means that the contents of the register in question is used % as the argument, be it an integer, a length-type register, a token % list variable or similar. The value is passed to the function as a % braced token list. Can be applied to variables which have a % \cs{\meta{var}_use:N} function (other than boxes), % and which therefore deliver a single \enquote{value}. % \item[v] Value of a register, constructed from a character string % used as a command name.\\ % This is a combination of |c| and |V| which first constructs a % control sequence from the argument and then passes the value of % the resulting register to the function. Can be applied to % variables which have a \cs{\meta{var}_use:N} function (other than % boxes), and which therefore deliver a single % \enquote{value}. % \item[e] Fully-expanded token or braced token list.\\ % This means that the argument is expanded as in the replacement % text of a~\tn{message}, and the expansion is passed to the function as % a braced token list. % \item[o] One-level-expanded token or braced token list.\\ % This means that the argument is expanded one level, as by % \tn{expandafter}, and the expansion is passed to the function as a % braced token list. Note that if the original argument is a braced % token list then only the first token in that list is expanded. % In general, using \texttt{V} should be preferred to using % \texttt{o} for simple variable retrieval. % \item[f] Expanding the first token recursively in a braced token % list.\\ Almost the same as the |e| type except here the token list % is expanded fully until the first unexpandable token is found and % the rest is left unchanged. Note that if this function finds a % space at the beginning of the argument it gobbles it and does not % expand the next token. % \item[x] Fully-expanded token or braced token list.\\ % This expansion is very similar to |e|-type but is not nestable, % can only be used to create non-expandable functions, and requires % that |#| tokens are doubled in the argument. In almost all cases, % |e|-type should be preferred: retained largely for historical % reasons, and should where possible be replaced by the |e|-type % equivalent. % \end{description} % % \subsection{Simpler means better} % % Anyone who programs in \TeX{} is frustratingly familiar with the % problem of arranging that arguments to functions are suitably expanded % before the function is called. To illustrate how expansion control % can bring instant relief to this problem we shall consider two % examples copied from \texttt{latex.ltx}. % % \begin{verbatim} % \global\expandafter\let % \csname\cf@encoding \string#1\expandafter\endcsname % \csname ?\string#1\endcsname % \end{verbatim} % This first piece of code is in essence simply a global \tn{let} whose % two arguments firstly have to be constructed before \tn{let} is % executed. The |#1| is a control sequence name such as % |\textcurrency|. The token to be defined is obtained by % concatenating the characters of the current font encoding stored in % |\cf@encoding|, which has to be fully expanded, and the name of the % symbol. The second token is the same except it uses the default % encoding |?|. The result is a mess of interwoven \tn{expandafter} % and \tn{csname} beloved of all \TeX{} programmers, and the code is % essentially unreadable. % % Using the conventions and functionality outlined here, the task would % be achieved with code such as this: % \begin{verbatim} % \cs_gset_eq:cc % { \cf@encoding \token_to_str:N #1 } { ? \token_to_str:N #1 } % \end{verbatim} % The command \cs{cs_gset_eq:cc} is a global~\tn{let} that generates % command names out of both of its arguments before making the % definition. This produces code that is far more readable and more % likely to be correct first time. (\cs{token_to_str:N} is the \LaTeX3 % name for \tn{string}.) % % Here is the second example. % \begin{verbatim} % \expandafter % \in@ % \csname sym#3% % \expandafter % \endcsname % \expandafter % {% % \group@list}% % \end{verbatim} % This piece of code is part of the definition of another function. It % first produces two things: a token list, by expanding |\group@list| once; % and a token whose name comes from~`|sym#3|'. Then the function~\cs{in@} % is called and this tests if its first argument occurs in the token list % of its second argument. % % Again we can improve enormously on the code. First we shall rename % the function~\cs{in@}, which tests if its first argument appears % within its second argument, according to our conventions. Such a % function takes two normal \enquote{\texttt{n}} arguments and operates % on token lists: it might reasonably be named |\tl_test_in:nn|. Thus % the variant function we need would be defined with the appropriate % argument types and its name would be |\tl_test_in:cV|. Now this code % fragment would be simply: % \begin{verbatim} % \tl_test_in:cV { sym #3 } \group@list % \end{verbatim} % This code could be improved further by using a sequence |\l_group_seq| % rather than the bare token list |\group@list|. Note that, in addition % to the lack of \tn{expandafter}, the space after the~|}| is % silently ignored since all white space is ignored in this programming % environment. % % \subsection{New functions from old} % % For many common functions the \LaTeX3 kernel provides variants % with a range of argument forms, and similarly it is expected that % extension packages providing new functions will make them available in % all the commonly needed forms. % % However, there will be occasions where it is necessary to construct a % new such variant form; therefore the expansion module provides a % straightforward mechanism for the creation of functions with any % required argument type, starting from a function that takes \enquote{normal} % \TeX{} undelimited arguments. % % To illustrate this let us suppose you have a \enquote{base function} % |\demo_cmd:Nnn| that takes three normal arguments, and that you need % to construct the variant |\demo_cmd:cne|, for which the first argument % is used to construct the \emph{name} of a command, whilst the third % argument must be fully expanded before being passed to % |\demo_cmd:Nnn|. % To produce the variant form from the base form, simply use this: % \begin{verbatim} % \cs_generate_variant:Nn \demo_cmd:Nnn { cne } % \end{verbatim} % This defines the variant form so that you can then write, for example: % \begin{verbatim} % \demo_cmd:cne { abc } { pq } { \rst \xyz } % \end{verbatim} % rather than \ldots\ well, something like this! % \begin{verbatim} % \def \tempa {{pq}}% % \edef \tempb {\rst \xyz}% % \expandafter % \demo@cmd:nnn % \csname abc% % \expandafter % \expandafter % \expandafter % \endcsname % \expandafter % \tempa % \expandafter % {% % \tempb % }% % \end{verbatim} % % Another example: you may wish to declare a function % |\demo_cmd_b:enene|, a variant of an existing function % |\demo_cmd_b:nnnnn|, that fully % expands arguments 1,~3 and~5, and produces commands to pass as % arguments 2 and~4 using~\tn{csname}. % The definition you need is simply % \begin{verbatim} % \cs_generate_variant:Nn \demo_cmd_b:nnnnn { enene } % \end{verbatim} % % This extension mechanism is written so that if the same new form of % some existing command is implemented by two extension packages then the % two definitions are identical and thus no conflict occurs. % % \section{The distribution} % % The \pkg{expl3} modules are designed to be loaded on top of \LaTeXe{}. % % \begin{bfseries} % The core \pkg{expl3} language is broadly stable, and thus % the syntax conventions and functions provided % are now ready for wider use. There may still be changes to some % functions, but these will be minor when compared to the scope of % \pkg{expl3}. A robust mechanism is in place for such deprecations. % \end{bfseries} % % The distribution of \pkg{expl3} is split up into three packages on % CTAN: \pkg{l3kernel}, \pkg{l3packages} and \pkg{l3experimental}. % The core programming layer provided by \pkg{l3kernel} has been loaded % as part of the \LaTeX{} since 2020-02-02. For historical reasons, in % older kernel releases % \begin{verbatim} % \RequirePackage{expl3} % \end{verbatim} % loads the code distributed as \pkg{l3kernel}. This monolithic % package contains all of the modules regarded by the team as stable, % and any changes in this code are very limited. This material is % therefore suitable for use in third-party packages without concern % about changes in support. All of this code is documented in % \texttt{interface3.pdf}. % % The material in \pkg{l3packages} is also stable; this bundle provides % user-level commands, some of which have been integrated in the % \LaTeX{} kernel. % % Finally, \pkg{l3experimental} contains modules ready for public use % but not yet integrated into \pkg{l3kernel}. These modules have to % be loaded explicitly. The team anticipate that all of these modules % will move to stable status over time, but they may be more flexible % in terms of interface and functionality detail. Feedback on these % modules is extremely valuable. % % \section{Moving from \LaTeXe{} to \pkg{expl3}} % % To help programmers to use \pkg{expl3} code in existing \LaTeXe{} package, % some short notes on making the change are probably desirable. % Suggestions for inclusion here are welcome! Some of the following % is concerned with code, and some with coding style. % % \begin{itemize} % \item \pkg{expl3} is mainly focused on programming. This means that % some areas still require the use of \LaTeXe{} internal macros. % For example, you may well need \tn{IfPackageLoadedTF}, as there % is currently no native \pkg{expl3} package loading module. % \item User level macros should be generated using the mechanism % available in the \pkg{ltcmd} module, which is part of the % the \LaTeX{} kernel since 2020-10-01. % \item At an internal level, most functions should be generated % \tn{long} (using \cs{cs_new:Npn}) rather than \enquote{short} (using % \cs{cs_new_nopar:Npn}). % \item Where possible, declare all variables and functions (using % \cs{cs_new:Npn}, \cs{tl_new:N}, etc.) before use. % \item Prefer \enquote{higher-level} functions over \enquote{lower-level}, % where possible. So for example use \cs{cs_if_exist:NTF} and not % \cs{if_cs_exist:N}. % \item Use space to make code readable. In general, we recommend % a layout such as: % \begin{verbatim} % \cs_new:Npn \foo_bar:Nn #1#2 % { % \cs_if_exist:NTF #1 % { \__foo_bar:n {#2} } % { \__foo_bar:nn {#2} { literal } } % } % \end{verbatim} % where spaces are used around |{| and |}| except for isolated % |#1|, |#2|, \emph{etc.} % \item Put different code items on separate lines: readability is % much more useful than compactness. % \item Use long, descriptive names for functions and variables, % and for auxiliary functions use the parent function name plus % |aux|, |auxi|, |auxii| and so on. % \item If in doubt, ask the team via the LaTeX-L list: someone will % soon get back to you! % \end{itemize} % % \section{Load-time options for \pkg{expl3}} % % To support code authors, the \pkg{expl3} package for \LaTeXe{} includes % a small number of load-time options. These all work in a key--value % sense, recognising the \texttt{true} and \texttt{false} values. Giving % the option name alone is equivalent to using the option with the % \texttt{true} value. % % \DescribeOption{check-declarations} % All variables used in \pkg{expl3} code should be declared. This is enforced % by \TeX{} for variable types based on \TeX{} registers, but not for those % which are constructed using macros as the underlying storage system. The % \texttt{check-declarations} option enables checking for all variable % assignments, issuing an error if any variables are assigned without being % initialised. See also \cs{debug_on:n} \texttt{\{check-declarations\}} % in \pkg{interface3} for finer control. % % \DescribeOption{log-functions} % The \texttt{log-functions} option is used to enable recording of every new % function name in the \texttt{.log} file. This is useful for debugging % purposes, as it means that there is a complete list of all functions % created by each module loaded (with the exceptions of a very small number % required by the bootstrap code). See also \cs{debug_on:n} % \texttt{\{log-functions\}} in \pkg{interface3} for finer control. % % \DescribeOption{backend} % Selects the backend to be used for color, graphics and related operations that % are backend-dependent. Options available are % \begin{itemize}[font = \texttt] % \item[dvips] Use the \texttt{dvips} driver. % \item[dvipdfmx] Use the \texttt{dvipdfmx} driver. % \item[dvisvgm] Use the \texttt{dvisvgm} driver. % \item[luatex] Use the direct PDF output mode of \LuaTeX{} % \item[pdftex] Use the direct PDF output mode of \pdfTeX{} % \item[xetex] Use the \XeTeX{} version of the \texttt{dvipdfmx} driver. % \end{itemize} % For historical reasons, there is also \texttt{pdfmode} as an equivalent of % \texttt{luatex} or \texttt{pdftex}, and \texttt{xdvipdfmx} as % an equivalent to \texttt{xetex}, but these are deprecated % % \DescribeOption{suppress-backend-headers} % The \texttt{suppress-backend-headers} option suppresses loading of % backend-specific header files; currently this only affects \texttt{dvips}. % This option is available to support DVI-based routes that do not % support the |header| line used by \texttt{dvips}. % % The debugging options may also be given using % \verb|\keys_set:nn { sys } { ... }|; the \texttt{backend} option can be % given in this way \emph{only} if a backend has not already been loaded. % This method of setting options is useful where \pkg{expl3} is pre-loaded % by the \LaTeXe{} format. % % \section{Using \pkg{expl3} with formats other than \LaTeXe{}} % % As well as the \LaTeXe{} package \pkg{expl3}, there is also a % \enquote{generic} loader for the code, \texttt{expl3-generic.tex}. % This may be loaded using the plain \TeX{} syntax % \begin{verbatim} % \input expl3-generic % % \end{verbatim} % This enables the programming layer to work with the other formats. % As no options are available loading in this way, the \enquote{native} % drivers are automatically used. If this \enquote{generic} loader is % used with \LaTeXe{} the code automatically switches to the appropriate % package route. % % After loading the programming layer using the generic interface, the % commands \cs{ExplSyntaxOn} and \cs{ExplSyntaxOff} and the code-level % functions and variables detailed in \pkg{interface3} are available. % Note that other \LaTeXe{} packages \emph{using} \pkg{expl3} are not % loadable: package loading is dependent on the \LaTeXe{} package-management % mechanism. % % \section{Getting the version of \pkg{expl3}} % % \begin{function}{\ExplLoaderFileDate} % Once the programming layer is loaded by one of the loaders, you can access % its version in the ISO date format \meta{year}-\meta{month}-\meta{day}, % through \cs{ExplLoaderFileDate}. % % The current version of \pkg{expl3} is \ExplLoaderFileDate. % \end{function} % % \section{Engine/primitive requirements} % % To use \pkg{expl3} and the higher level packages provided by the % team, the minimal set of primitive requirements is currently described % in \href{README.md}{README.md}. % % Practically, these requirements are met by the engines % \begin{itemize} % \item \pdfTeX{} v1.40.20 or later. % \item \XeTeX{} v0.999991 or later. % \item \LuaTeX{} v1.10 or later. % \item e-(u)\pTeX{} v3.8.2 or later. % \item Prote (2021) or later. % \end{itemize} % % Additional modules beyond the core of \pkg{expl3} may require additional % primitives. In particular, third-party authors may significantly % extend the primitive coverage requirements. % % \section{The \LaTeX{} Project} % % Development of \LaTeX3 is carried out by The \LaTeX{} Project: % \url{https://www.latex-project.org/latex3/}. % % \begin{thebibliography}{1} % % \bibitem{A-W:K-TB} % Donald E Knuth % \newblock \emph{The \TeX{}book}. % \newblock Addison-Wesley, Reading, Massachusetts, 1984. % % \bibitem{A-W:GMS94} % Goossens, Mittelbach and Samarin. % \newblock \emph{ The \LaTeX{} Companion}. % \newblock Addison-Wesley, Reading, Massachusetts, 1994. % % \bibitem{A-W:LLa94} % Leslie Lamport. % \newblock \emph{\LaTeX{}: A Document Preparation System}. % \newblock Addison-Wesley, Reading, Massachusetts, second edition, 1994. % % \bibitem{tub:MR97-1} % Frank Mittelbach and Chris Rowley. % \newblock \enquote{The \LaTeX{} Project}. % \newblock \emph{TUGboat}, % Vol.\,18, No.\,3, pp.\,195--198, 1997. % % \end{thebibliography} % % \end{documentation} % % \begin{implementation} % % \section{\pkg{expl3} implementation} % % The implementation here covers several things. There are two % \enquote{loaders} to define: the parts of the code that are specific to % \LaTeXe{} or to non-\LaTeXe{} formats. These have to cover the same % concepts as each other but in rather different ways: as a result, much % of the code is given in separate blocks. There is also a short piece of % code for the start of the \enquote{payload}: this is to ensure that % loading is always done in the right way. % % \subsection{Loader interlock} % % A short piece of set up to check that the loader and \enquote{payload} % versions match. % % \begin{macro}{\ExplLoaderFileDate} % As DocStrip is used to generate \cs{ExplFileDate} % for all files from the same source, it has to match. Thus the loaders % simply save this information with a new name. % \begin{macrocode} %<*loader> \let\ExplLoaderFileDate\ExplFileDate % % \end{macrocode} % \end{macro} % % \begin{macro}{\c__kernel_expl_date_tl} % The \LaTeXe{} loader stores a private copy of \cs{ExplFileDate}, % which is fixed when the format is build and cannot be changed later. % While \cs{ExplFileDate} ensures that the loader (either % \texttt{2ekernel} or \texttt{package}) version matches the version % of \file{expl3-code.tex}, this one ensures that the version of an % eventual |\usepackage{expl3}| matches the version from the format. % It seems to be common to have stray format files in the user tree % which trigger errors due to mismatched versions (\emph{e.g.} % \url{https://github.com/latex3/latex3/issues/781}). % % This block also goes to the generic loader, as \pkg{expl3} isn't % preloaded there, so the kernel date should be equal to the loader % date. % \begin{macrocode} %<*2ekernel|generic> \begingroup \catcode`\_=11 \expandafter \ifx\csname c__kernel_expl_date_tl\endcsname\relax \global\let\c__kernel_expl_date_tl\ExplFileDate \fi \endgroup % % \end{macrocode} % \end{macro} % % The interlock test itself is simple: \cs{ExplLoaderFileDate} must be % defined and identical to \cs{ExplFileDate}. As this has to work for % both \LaTeXe{} and other formats, there is some auto-detection involved. % (Done this way avoids having two very similar blocks for \LaTeXe{} and % other formats.) % \begin{macrocode} %<*!loader> \begingroup \def\next{\endgroup}% \expandafter\ifx\csname PackageError\endcsname\relax \begingroup \def\next{\endgroup\endgroup}% \def\PackageError#1#2#3% {% \endgroup \errhelp{#3}% \errmessage{#1 Error: #2!}% }% \fi \expandafter\ifx\csname ExplLoaderFileDate\endcsname\relax \def\next {% \PackageError{expl3}{No expl3 loader detected} {% You have attempted to use the expl3 code directly rather than using the correct loader. Loading of expl3 will abort. }% \endgroup \endinput } \else \ifx\ExplLoaderFileDate\ExplFileDate \else \def\next {% \PackageError{expl3}{Mismatched expl3 files detected} {% You have attempted to load expl3 with mismatched files: probably you have one or more files 'locally installed' which are in conflict. Loading of expl3 will abort. }% \endgroup \endinput }% \fi \fi \next % % \end{macrocode} % % A reload test for the payload, just in case. % \begin{macrocode} %<*!loader> \begingroup\expandafter\expandafter\expandafter\endgroup \expandafter\ifx\csname ver@expl3-code.tex\endcsname\relax \expandafter\edef\csname ver@expl3-code.tex\endcsname {% \ExplFileDate\space L3 programming layer }% \else \expandafter\endinput \fi % % \end{macrocode} % % All good: log the version of the code used (for log completeness). As this % is more-or-less \cs{ProvidesPackage} without a separate file and as this also % needs to work without \LaTeXe{}, just write the information directly to the % log. % \begin{macrocode} %<*!loader> \immediate\write-1 % {% Package: expl3 \ExplFileDate\space L3 programming layer (code)% }% % % \end{macrocode} % % \subsection{\LaTeXe{} loaders} % % Loading with \LaTeXe{} may be as part of the format (pre-loading) % or as a package. We have to allow for both possible paths, and of % course the package being loaded on to of the pre-load. That means % the code here must be safe against re-loading. % % \begin{macrocode} %<*package&loader|2ekernel> % \end{macrocode} % % Identify the package or add to the format message. % \begin{macrocode} %<*2ekernel> \ifdefined\LaTeXReleaseInfo \LaTeXReleaseInfo\expandafter{\the\LaTeXReleaseInfo \show@release@info{L3 programming layer <\ExplFileDate>}% }% \else \everyjob\expandafter{\the\everyjob \message{L3 programming layer <\ExplFileDate>}% }% \fi % %<*!2ekernel> \ProvidesPackage{expl3} [% \ExplFileDate\space L3 programming layer (loader) ]% % % \end{macrocode} % % \begin{macro}{\ProvidesExplPackage, \ProvidesExplClass, \ProvidesExplFile} % For other packages and classes building on this one it is convenient % not to need \cs{ExplSyntaxOn} each time. All macros use the same % internal one with the proper \LaTeXe{} command. % \begin{macrocode} \protected\def\ProvidesExplPackage {\@expl@provides@file@@Nnnnnn\ProvidesPackage{Package}} \protected\def\ProvidesExplClass {\@expl@provides@file@@Nnnnnn\ProvidesClass{Document Class}} \protected\def\ProvidesExplFile {\@expl@provides@file@@Nnnnnn\ProvidesFile{File}} % \end{macrocode} % \end{macro} % % \begin{macro}{\@expl@provides@file@@Nnnnnn} % \begin{macro}{\@expl@provides@file@@N} % \begin{macro}{\@expl@provides@generic@@wnnw} % We need to check the existence of the % \cs[no-index]{Provides\meta{thing}}, since we need to load this very % early in the \LaTeXe{} kernel. The gymnastics with the version identifier % argument allow for the case where it starts with a \texttt{v} and the one % where it does not: formally the \texttt{v} is not part of the version, % but a lot of people include it. % \begin{macrocode} \protected\long\def\@expl@provides@file@@Nnnnnn#1#2#3#4#5#6% {% \ifnum0% \ifdefined#11\fi \ifx\relax#1\else1\fi =11 \expandafter#1% \else \@expl@provides@generic@@wnnw{#2}% \fi {#3}[{#4 \ifx\relax#5\relax\else\@expl@provides@file@@N#5\space\fi #6}]% \ExplSyntaxOn } \long\def\@expl@provides@file@@N#1{v\if#1v\else#1\fi} \protected\long\def\@expl@provides@generic@@wnnw#1\fi#2[#3]% {% \immediate\write-1{#1: #2 #3}% } % \end{macrocode} % \end{macro} % \end{macro} % \end{macro} % % Load the business end: this leaves \cs{expl3} syntax on. % The test ensures we only load once without needing to know if % there was a preloading step. % \begin{macrocode} \begingroup\expandafter\expandafter\expandafter\endgroup \expandafter\ifx\csname tex\string _let:D\endcsname\relax \expandafter\@firstofone \else \expandafter\@gobble \fi {\input expl3-code.tex }% % \end{macrocode} % % A check that the bootstrap code did not abort loading: if it did, % bail out silently here. % \begin{macrocode} \begingroup\expandafter\expandafter\expandafter\endgroup \expandafter\ifx\csname tex\string _let:D\endcsname\relax \expandafter\endinput \fi % \end{macrocode} % % \begin{macrocode} %<@@=expl> % \end{macrocode} % % At this point, if we have \cs{c__kernel_expl_date_tl} defined, just % call the \cs{__kernel_dependency_version_check:Nn} auxiliary to check % if it matches \cs{ExplLoaderFileDate}. Here the test is performed % only if \cs{c__kernel_expl_date_tl} exists because this file can be % loaded in a \LaTeXe{} format without \pkg{expl3} preloaded, where that % token list doesn't exist. % % This is all done in the \texttt{package} \pkg{docstrip} guard because % it doesn't apply to \pkg{expl3.ltx}. % \begin{macrocode} %<*package> \ifcsname\detokenize{c__kernel_expl_date_tl}\endcsname \expandafter\@firstofone \else % \end{macrocode} % If \cs{c__kernel_expl_date_tl} does \emph{not} exist we may be loading % in a format without \pkg{expl3} preloaded or in the earlier (although % still compatible) version in which the error mentioned above showed % up. If loading as a package, \file{expl3-code.tex} got read and here % the \pkg{expl3} syntax is on. Otherwise it was already loaded in a % slightly older kernel, so we fire the incompatibility error message and % abort loading. % \begin{macrocode} \ifodd\csname\detokenize{l__kernel_expl_bool}\endcsname % \end{macrocode} % In package mode all files are loaded in one go, so versions will % match. We just have to set \cs{c__kernel_expl_date_tl} so that % further dependencies don't break: % \begin{macrocode} \global\expandafter\let\csname\detokenize {c__kernel_expl_date_tl}\endcsname\ExplLoaderFileDate \expandafter\expandafter \expandafter\@gobble \else % \end{macrocode} % And reloading in an incompatible version is an error: % \begin{macrocode} \expandafter\expandafter \expandafter\@firstofone \fi \fi {\csname\detokenize{__kernel_dependency_version_check:Nn}\endcsname \ExplLoaderFileDate{expl3.sty}}% % % \end{macrocode} % % Here we can also detect whether we're reloading. This code goes into % \texttt{expl3.ltx} and \texttt{expl3.sty}, the former loaded into the % \LaTeXe{} format. When this code is loaded for the first time, the % \cs{g_@@_reload_bool} boolean doesn't exist (\cs{else} branch of the % \cs{ifcsname} below), so we create it. If the \cs{ifcsname} is true, % then we do \cs{ExplSyntaxOn} (because when reloading, % \texttt{expl3-code.tex} isn't read again), and set % \cs{g_@@_reload_bool} to true. % \begin{macrocode} \ifcsname\detokenize{g_@@_reload_bool}\endcsname \ExplSyntaxOn \bool_gset_true:N \g_@@_reload_bool \else \bool_new:N \g_@@_reload_bool \fi % \end{macrocode} % % \begin{variable}{\c_@@_def_ext_tl} % Needed by \LaTeXe{}, and avoiding a re-load issue. Variables are % best checked explicitly, rather than with \cs{g_@@_reload_bool} % because some appear only in one of the code files, so % \cs{g_@@_reload_bool} doesn't necessarily mean that the variable % is already declared. % \begin{macrocode} \tl_if_exist:NF \c_@@_def_ext_tl { \tl_const:Nn \c_@@_def_ext_tl { def } } % \end{macrocode} % \end{variable} % % \begin{macro} % {\__kernel_sys_configuration_load:n,\__kernel_sys_configuration_load_std:n} % To load configurations, we have the following cases % \begin{itemize} % \item \pkg{expl3} is pre-loaded: by the time any configuration loads, % we have the full file loading stack, and only need the standard % version of the code here. % \item The package is loaded with pre-loading: we again use the standard % version, but we don't test just yet. % \item The package is used without pre-loaded code: we need to manually % manage \pkg{expl3} syntax. % \end{itemize} % \begin{macrocode} \cs_gset_protected:Npn \__kernel_sys_configuration_load:n #1 %<*!2ekernel> { \ExplSyntaxOff \cs_undefine:c { ver@ #1 .def } \@onefilewithoptions {#1} [ ] [ ] \c_@@_def_ext_tl \ExplSyntaxOn } \cs_gset_protected:Npn \__kernel_sys_configuration_load_std:n #1 % { \cs_undefine:c { ver@ #1 .def } \@onefilewithoptions {#1} [ ] [ ] \c_@@_def_ext_tl } % \end{macrocode} % \end{macro} % % \begin{variable}{\l_@@_options_clist} % \begin{macrocode} %<*!2ekernel> \clist_if_exist:NF \l_@@_options_clist { \clist_new:N \l_@@_options_clist } \DeclareOption* { \clist_put_right:NV \l_@@_options_clist \CurrentOption } \ProcessOptions \relax % % \end{macrocode} % \end{variable} % % Pretty standard setting creation. % \begin{macrocode} \keys_define:nn { sys } { backend .choices:nn = { dvipdfmx , dvips , dvisvgm , luatex , pdftex , pdfmode , xdvipdfmx , xetex } { \sys_load_backend:n {#1} } , check-declarations .choice: , check-declarations / true .code:n = { \debug_on:n { check-declarations } } , check-declarations / false .code:n = { \__kernel_if_debug:TF { \debug_off:n { check-declarations } } { } } , check-declarations .default:n = true , driver .meta:n = { backend = #1 } , enable-debug .code:n = {} , % A stub log-functions .choice: , log-functions / true .code:n = { \debug_on:n { log-functions } } , log-functions / false .code:n = { \__kernel_if_debug:TF { \debug_off:n { log-functions } } { } } , log-functions .default:n = true , suppress-backend-headers .bool_gset_inverse:N = \g__kernel_backend_header_bool , suppress-backend-headers .initial:n = false , undo-recent-deprecations .code:n = {} % A stub } % \end{macrocode} % % \begin{macro}{\@expl@sys@load@backend@@@@} % A backend has to be in place by the start of the document: this has % to be before global options are checked for use. % % The \cs[no-index]{@expl@...@@@@} macros defined in this package are % interfaces for \LaTeXe{}. There are currently (this will change % with the next release of \LaTeXe{}) two possible cases, at this % point of the code: either \cs{@expl@sys@load@backend@@@@} (and the % others) already exist because they were defined in % \texttt{ltexpl.ltx} (in \texttt{2ekernel} mode) or in % \texttt{expl3.ltx} (in \texttt{package} mode). % % In \texttt{2ekernel} mode, if they exist we are using a future % (2020-10-01) release of \LaTeXe{} and we don't need (and can't) % patch \LaTeXe's internals because these commands are already there. % Though if they don't exist in \texttt{2ekernel} mode, we're using % an older version of the kernel, so we \emph{must} patch. % % In \texttt{package} mode, if these commands exist, then we are using % a version of \LaTeXe{} with \pkg{expl3} preloaded (any version) % and in any case patching is already done or the macros are in the % format itself, so nothing to do. % But if in \texttt{package} mode these macros don't exist, we have an % even older version of \LaTeXe{} which doesn't even have % \pkg{expl3} preloaded, so patching is necessary. % % All this means that in both \texttt{2ekernel} and \texttt{package} % mode we have to check whether \cs{@expl@sys@load@backend@@@@} % exists, and patch some \LaTeXe{} internals if it doesn't. % % In newer \LaTeXe{}, these macros have an empty definition in % \texttt{ltexpl.dtx} in case something wrong happens while loading % this file (\texttt{expl3.ltx}), so they can safely be used in the % \LaTeXe{} kernel. % % \cs{@expl@sys@load@backend@@@@} is inserted right at the beginning % of \cs{document}, but after closing the group started by \cs{begin}. % When using \cs{tl_put_left:Nn} to patch the backend loading in % \cs{document}, we need to make sure that it happens at group level % zero, thus the strange |\endgroup...\begingroup| thing. % % This chunk of code should only be executed when loading % \texttt{expl3.sty} in a \LaTeXe{} without \pkg{expl3} preloaded, so % we check if \cs{@expl@sys@load@backend@@@@} exists. % \begin{macrocode} \cs_if_exist:NF \@expl@sys@load@backend@@@@ { \tl_put_left:Nn \document { \endgroup \@expl@sys@load@backend@@@@ \begingroup } } % \end{macrocode} % % Now we define it anyhow. % \begin{macrocode} \cs_gset_protected:Npn \@expl@sys@load@backend@@@@ { \str_if_exist:NF \c_sys_backend_str { \sys_load_backend:n { } } } % \end{macrocode} % \end{macro} % % Process package options. % \begin{macrocode} %<*!2ekernel> \keys_set:nV { sys } \l_@@_options_clist \str_if_exist:NF \c_sys_backend_str { \sys_load_backend:n { } } % % \end{macrocode} % % \begin{macrocode} %<*!2ekernel> \bool_if:NT \g_@@_reload_bool { \cs_gset_eq:NN \__kernel_sys_configuration_load:n \__kernel_sys_configuration_load_std:n \ExplSyntaxOff \file_input_stop: } % % \end{macrocode} % % Load the dynamic part of the code, either now or during the next run. % \begin{macrocode} \cs_if_free:cTF { ver@expl3.sty } { \tex_everyjob:D \exp_after:wN { \tex_the:D \tex_everyjob:D \__kernel_sys_everyjob: } } { \__kernel_sys_everyjob: } % \end{macrocode} % % \begin{variable}{\s_@@_stop} % Internal scan marks. This code has to be reload-safe, so this one % has to be guarded with \cs{if_cs_exist:N} (\cs{cs_if_exist:NF}) wouldn't % do because it returns false for control sequences equal to \cs{scan_stop:}. % \begin{macrocode} \reverse_if:N \if_cs_exist:N \s_@@_stop \scan_new:N \s_@@_stop \fi: % \end{macrocode} % \end{variable} % % \begin{macro}{\@pushfilename, \@popfilename} % \begin{macro}{\@@_status_pop:w} % \begin{macro}{\@expl@push@filename@@@@} % \begin{macro}{\@expl@push@filename@aux@@@@} % \begin{macro}{\@expl@pop@filename@@@@} % The idea here is to use \LaTeXe{}'s \tn{@pushfilename} and % \tn{@popfilename} to track the current syntax status. This can be % achieved by saving the current status flag at each push to a stack, % then recovering it at the pop stage and checking if the code % environment should still be active. % % Here the code follows the same patching logic than above for % \cs{@expl@sys@load@backend@@@@}. % \begin{macrocode} \cs_if_exist:NF \@expl@push@filename@@@@ { \tl_put_left:Nn \@pushfilename { \@expl@push@filename@@@@ } \tl_put_right:Nn \@pushfilename { \@expl@push@filename@aux@@@@ } } \cs_gset_protected:Npn \@expl@push@filename@@@@ { \exp_args:Ne \__kernel_file_input_push:n { \tl_to_str:N \@currname . \tl_to_str:N \@currext } \tl_put_left:Ne \l_@@_status_stack_tl { \bool_if:NTF \l__kernel_expl_bool { 1 } { 0 } } \ExplSyntaxOff } % \end{macrocode} % This bit of trickery is needed to grab the name of the file being loaded % so we can record it. % \begin{macrocode} \cs_gset_protected:Npn \@expl@push@filename@aux@@@@ #1#2#3 { \str_gset:Nn \g_file_curr_name_str {#3} #1 #2 {#3} } % \end{macrocode} % % \begin{macrocode} \cs_if_exist:NF \@expl@pop@filename@@@@ { \tl_put_right:Nn \@popfilename { \@expl@pop@filename@@@@ } } \cs_gset_protected:Npn \@expl@pop@filename@@@@ { \__kernel_file_input_pop: \tl_if_empty:NTF \l_@@_status_stack_tl { \ExplSyntaxOff } { \exp_after:wN \@@_status_pop:w \l_@@_status_stack_tl \s_@@_stop } } % \end{macrocode} % The pop auxiliary function removes the first item from the stack, % saves the rest of the stack and then does the test. The flag here % is not a proper \texttt{bool}, so a low-level test is used. % \begin{macrocode} \cs_gset_protected:Npn \@@_status_pop:w #1#2 \s_@@_stop { \tl_set:Nn \l_@@_status_stack_tl {#2} \int_if_odd:nTF {#1} { \ExplSyntaxOn } { \ExplSyntaxOff } } % \end{macrocode} % \end{macro} % \end{macro} % \end{macro} % \end{macro} % \end{macro} % % \begin{variable}{\l_@@_status_stack_tl} % As \pkg{expl3} itself cannot be loaded with the code environment % already active, at the end of the package \cs{ExplSyntaxOff} can % safely be called. % \begin{macrocode} \tl_if_exist:NF \l_@@_status_stack_tl { \tl_new:N \l_@@_status_stack_tl \tl_set:Nn \l_@@_status_stack_tl { 0 } } % \end{macrocode} % \end{variable} % % Tidy up configuration loading, as promised. % \begin{macrocode} %<*!2ekernel> \cs_gset_eq:NN \__kernel_sys_configuration_load:n \__kernel_sys_configuration_load_std:n % % \end{macrocode} % % For pre-loading, we have to manually disable the syntax. % \begin{macrocode} %<*2ekernel> \ExplSyntaxOff % % \end{macrocode} % % \begin{macrocode} % % \end{macrocode} % % \subsection{Generic loader} % % \begin{macrocode} %<*generic> % \end{macrocode} % % The generic loader starts with a test to ensure that the current format is % not \LaTeXe{}! % \begin{macrocode} \begingroup \def\tempa{LaTeX2e}% \def\next{}% \ifx\fmtname\tempa \def\next {% \PackageInfo{expl3}{Switching from generic to LaTeX2e loader}% % \end{macrocode} % The \cs{relax} stops \cs{RequirePackage} from scanning for a date % argument. Putting \tn{endinput} \emph{after} loading the package is % crucial, as otherwise \tn{endinput} would close the file % \file{expl3.sty} at the end of its first line: indeed, as long as % \file{expl3.sty} is open it is impossible to close the file % \file{expl3-generic.tex}. % \begin{macrocode} \RequirePackage{expl3}\relax \endinput }% \fi \expandafter\endgroup \next % \end{macrocode} % % Reload check and identify the package: % no \LaTeXe{} mechanism so this is all pretty basic. % \begin{macrocode} \begingroup\expandafter\expandafter\expandafter\endgroup \expandafter\ifx\csname ver@expl3-generic.tex\endcsname\relax \else \immediate\write-1 {% Package expl3 Info: The package is already loaded.% }% \expandafter\endinput \fi \immediate\write-1 {% Package: expl3 \ExplFileDate\space L3 programming layer (loader)% }% \expandafter\edef\csname ver@expl3-generic.tex\endcsname {\ExplFileDate\space L3 programming layer}% % \end{macrocode} % % \begin{macrocode} \ifnum\currentgrouplevel=0 % \else \errhelp{expl3 cannot be loaded inside a group: reading the code has been aborted.}% \errmessage{expl3 Error: Loading attempted inside a group!}% \expandafter\endinput \fi % \end{macrocode} % % \begin{variable}[int]{\l@expl@tidy@tl} % Save the category code of |@| and then set it to \enquote{letter}. % \begin{macrocode} \expandafter\edef\csname l@expl@tidy@tl\endcsname {% \catcode64=\the\catcode64\relax \let\expandafter\noexpand\csname l@expl@tidy@tl\endcsname \noexpand\undefined }% \catcode64=11 % % \end{macrocode} % \end{variable} % % \begin{macro}{\AtBeginDocument} % \begin{macro}[int]{\expl@AtBeginDocument} % There are a few uses of \cs{AtBeginDocument} in the package code: the % easiest way around that is to simply do the code \enquote{now}. As % bundles such as \pkg{miniltx} may have defined \cs{AtBeginDocument} % any existing definition is saved for restoration after the payload. % \begin{macrocode} \let\expl@AtBeginDocument\AtBeginDocument \def\AtBeginDocument#1{#1}% \expandafter\def\expandafter\l@expl@tidy@tl\expandafter {% \l@expl@tidy@tl \let\AtBeginDocument\expl@AtBeginDocument \let\expl@AtBeginDocument\undefined }% % \end{macrocode} % \end{macro} % \end{macro} % % Load the business end: this leaves \cs{expl3} syntax on. % \begin{macrocode} \input expl3-code.tex % % \end{macrocode} % % A check that the bootstrap code did not abort loading: if it did, % bail out silently here. % \begin{macrocode} \begingroup\expandafter\expandafter\expandafter\endgroup \expandafter\ifx\csname tex\string _let:D\endcsname\relax \expandafter\endinput \fi % \end{macrocode} % % \begin{macro}{\__kernel_sys_configuration_load:n} % Very basic. % \begin{macrocode} \cs_gset_protected:Npn \__kernel_sys_configuration_load:n #1 { \group_begin: \cs_set_protected:Npn \ProvidesExplFile { \char_set_catcode_space:n { `\ } \ProvidesExplFileAux } \cs_set_protected:Npn \ProvidesExplFileAux ##1##2##3##4 { \group_end: \iow_log:e { File:~##1~##2~v##3~##4 } } \tex_input:D #1 .def \scan_stop: } % \end{macrocode} % \end{macro} % % \begin{macro}{\g__kernel_backend_header_bool} % Load the dynamic code and standard back-end. % \begin{macrocode} \__kernel_sys_everyjob: \bool_new:N \g__kernel_backend_header_bool \bool_gset_true:N \g__kernel_backend_header_bool \sys_load_backend:n { } % \end{macrocode} % \end{macro} % % For the generic loader, a few final steps to take. Turn of \cs{expl3} % syntax and tidy up the small number of temporary changes. % \begin{macrocode} \ExplSyntaxOff \l@expl@tidy@tl % \end{macrocode} % % \begin{macrocode} % % \end{macrocode} % % \end{implementation} % % \PrintIndex