Edit
kc3-lang/automake/automake.texi
Tom Tromey
- automake.texi
-
\input texinfo @c -*-texinfo-*- @c %**start of header @setfilename automake.info @settitle automake @setchapternewpage off @c %**end of header @include version.texi @ifinfo This file documents GNU automake @value{VERSION} Copyright (C) 1995 Free Software Foundation, Inc. Permission is granted to make and distribute verbatim copies of this manual provided the copyright notice and this permission notice are preserved on all copies. @ignore Permission is granted to process this file through TeX and print the results, provided the printed document carries copying permission notice identical to this one except for the removal of this paragraph @end ignore Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions, except that this permission notice may be stated in a translation approved by the Foundation. @end ifinfo @titlepage @title GNU AutoMake @subtitle For version @value{VERSION}, @value{UPDATED} @c copyright page @page @vskip 0pt plus 1filll Copyright @copyright{} 1995 Free Software Foundation, Inc. @sp 2 This is the first edition of the GNU AutoMake documentation,@* and is consistent with GNU AutoMake @value{VERSION}.@* @sp 2 Published by the Free Software Foundation @* 675 Massachusetts Avenue, @* Cambridge, MA 02139 USA @* Permission is granted to make and distribute verbatim copies of this manual provided the copyright notice and this permission notice are preserved on all copies. Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions, except that this permission notice may be stated in a translation approved by the Free Software Foundation. @end titlepage @ifinfo @node Top, Introduction, (dir), (dir) @comment node-name, next, previous, up @top This file documents the GNU AutoMake package for creating GNU Standards-compliant Makefiles from template files. This edition documents version @value{VERSION}. @menu * Introduction:: AutoMake's purpose * Details:: Creating an AutoMake template file * Invoking automake:: Creating a Makefile.in * Future:: Some ideas for the future. * Some index:: Index of variables @end menu @end ifinfo @node Introduction @chapter Introduction The GNU Makefile Standards Document (@pxref{Makefile Conventions, , Makefile Conventions, standards.info, The GNU Coding Standards}) is long, complicated, and subject to change. The goal of AutoMake is to remove the burden of Makefile maintenance from back the individual GNU maintainer (and put it on the back of the AutoMake maintainer) Typical AutoMake input files are simply a series of macro definitions. AutoMake processes these files to produce @file{Makefile.in}s which are distribution-ready. AutoMake does force some structure on the package maintainer. However, it is felt that this (minor) inconvenience is more than offset by AutoMake's convenience. @node Details @chapter Making @code{automake} templates @menu * configure:: AutoMake and configure * Depth:: Types of package hierarchy * Programs:: What gets built * Source:: Specifying source files * Scripts:: Building scripts * Libraries:: Building libraries * Libstuff:: Programs that aren't user-visible * Data:: Data files. * Docs:: Specifying documentation files * ANSI:: Automatic de-ANSI-fication * Install:: What gets installed * Distribution:: What gets distributed * Tags:: TAGS files * Dependencies:: Automatic dependency tracking * Extending:: If the defaults aren't enough @end menu @node configure @section How @code{automake} and @code{configure} interact AutoMake enforces a certain amount of structure on the package maintainer. One such item is its requirement that the @file{configure.in} for the package define the variables @samp{PACKAGE} and @samp{VERSION}. @var{PACKAGE} should be the name of the package as it appears when bundled for distribution. For instance, AutoMake defines @samp{PACKAGE} to be @samp{am}. @var{VERSION} should be the version number of the release being worked on. We recommend that you make @file{configure.in} the only place you define the version number for your package; this makes releases simpler. Here is an example of what to put in @file{configure.in}: @example PACKAGE=cpio VERSION=2.3.911 AC_DEFINE_UNQUOTED(PACKAGE, "$PACKAGE") AC_DEFINE_UNQUOTED(VERSION, "$VERSION") AC_SUBST(PACKAGE) AC_SUBST(VERSION) @end example If your @file{configure.in} uses @samp{AC_CONFIG_HEADER}, then in each directory you should define the @samp{CONFIG_HEADER} variable to hold the name of the header. For instance, in cpio's @file{src/Makefile.am}, we see: @example CONFIG_HEADER = ../config.h @end example @code{automake} also assumes that your @file{configure} script will define the variable @samp{INSTALL_SCRIPT}. Until this is incorporated in @code{autoconf}'s @samp{AC_PROG_INSTALL} macro, you can use this replacement instead: @example ## --------------------------------------------------------- ## ## Use AC_PROG_INSTALL, supplementing it with INSTALL_SCRIPT ## ## substitution. ## ## --------------------------------------------------------- ## AC_DEFUN(fp_PROG_INSTALL, [AC_PROG_INSTALL test -z "$INSTALL_SCRIPT" && INSTALL_SCRIPT='$@{INSTALL@} -m 755' AC_SUBST(INSTALL_SCRIPT)dnl ]) @end example @code{automake} also assumes your @file{configure.in} calls @samp{AC_ARG_PROGRAM}. @node Depth @section Types of directory hierarchy @code{automake} supports three kinds of directory hierarcy: ``flat'', ``shallow'', and ``deep''. A flat package is one in which all the files are in a single directory. The @file{Makefile.am} for such a package by definition lacks a @samp{SUBDIRS} macro. (There are not any @code{automake}-using packages which are flat) A deep package is one in which all the source lies in subdirectories; the top level directory contains only configuration information. GNU cpio is a good example of such a package (as is GNU tar, although it does not presently use @code{automake}). The top level @file{Makefile.am} for a deep package will contain a @samp{SUBDIRS} macro, but no other macros to define objects which are built (eg @samp{PROGRAMS}). A shallow package is one in which the primary source resides in the top-level directory, while various parts (typically libraries) reside in subdirectories. @code{automake} is one such package (as is GNU make, which does not currently use @code{automake}). The @samp{SUBDIRS} macro holds a list of subdirectories in which building of various sorts can occur. Many targets (eg @samp{all}) in the generated @file{Makefile} will run both locally and in all specified subdirectories. Note that the directories listed in @samp{SUBDIRS} are not expected to contain @file{Makefile.am}s; only @file{Makefile}s (after configuration). This allows inclusion of libraries from packages which do not use @code{automake} (such as gettext). FIXME supply complete list of recursive targets? @node Programs @section Which Programs Are Built In a directory containing source that gets built into a program (as opposed to a library), the @samp{PROGRAMS} variable is used: @example PROGRAMS = hello @end example In this simple case, the resulting @file{Makefile.in} will contain code to generate a program named @code{hello}. The variable @samp{@var{prog}_SOURCE} is used to specify which source files get built into an executable: @example hello_SOURCE = hello.c @end example This causes @file{hello.o} to be built from @code{hello.c} at compile time, and then linked into @file{hello}. Multiple programs can be built in a single directory -- simply list them all in the @samp{PROGRAMS} definition. Multiple programs can share a single source file. The source file must be listed in each ``_SOURCE'' definition. Sometimes it is useful to determine the programs that are to be built at configure time. For instance, GNU cpio only builts @code{mt} and @code{rmt} under special circumstances. In this case, you must notify AutoMake of all the programs that can possibly be built, but at the same time cause the generated @file{Makefile.in} to use the programs specified by @code{configure}. You can do this using the @code{AM_PROGRAMS} variable. Here is the relevant code from cpio: @example PROGRAMS = @@PROGS@@ AM_PROGRAMS = cpio pax mt rmt @end example If you need to link against libraries that are not found by @code{configure}, you can use @samp{LDADD} to do so. This variable actually can be used to add any options to the linker command line. Sometimes, multiple programs are built in one directory but do not share the same link-time requirements. In this case, you can use the @samp{@var{prog}_LDADD} variable to override the global @samp{LDADD}. (If this variable exists for a given program, then that program is not linked using @samp{LDADD}). For instance, in GNU cpio, @code{pax}, @code{cpio}, and @code{mt} are linked against the library @file{libcpio.a}. However, @code{rmt} is built in the same directory, and has no such link requirement. Thus: @example LDADD = ../lib/libcpio.a @@INTLLIBS@@ rmt_LDADD = @end example @node Source @section Specifying Source Code Any header files in your distribution must be listed in the @samp{HEADERS} variable. This is used both for making distributions, and for automatic de-ANSI-fication. @example HEADERS = hello.h getopt.h rx.h @end example @samp{HEADERS} should also be used to list any sources files which are conditionally built. FIXME probably should use @samp{SOURCES} for this; that support might even work. @node Scripts @section Programs Which are Scripts It is possible to define and install programs which are scripts. Such programs should be listed in the @samp{SCRIPTS} variable. @code{automake} doesn't define any dependencies for scripts; if a script is not to be installed as-is, the @file{Makefile.am} should include the appropriate rules. @code{automake} itself is a script that is generated at configure time from @file{automake.in}. Here is how this is handled: @example SCRIPTS = automake automake: automake.in CONFIG_FILES=$@@ CONFIG_HEADERS= ./config.status @end example @node Libraries @section Building Libraries The @samp{LIBRARIES} variable holds the names of libraries to be built in the current directory. If the libraries to be built vary at configure time, you may define @samp{AM_LIBRARIES} to supply @code{automake} with the full static list of possible libraries. For a given library @samp{zot}, the sources are taken to be in @samp{@var{zot}_SOURCES}, just as for programs. Note that libraries and programs share one namespace in @code{automake}: one directory cannot contain both a library (``liblob.a'') and a program (``lob'') with the same name. Here is how the @file{libcpio.a} library is built in the GNU cpio distribution's @file{lib} subdirectory: @example LIBRARIES = cpio cpio_SOURCES = dirname.c dstring.c error.c filemode.c \ getopt.c getopt1.c idcache.c makepath.c octal.c \ stpcpy.c stripslash.c userspec.c xmalloc.c xstrdup.c @end example @node Libstuff @section Programs which are not User-Visible @code{automake} allows for the automatic building and installation of programs which are not actually used by the user, but are instead used by other user-visible programs. Such programs are installed in a separate directory from user-visible programs. For programs of this sort which are build from C source, define the names in @samp{LIBPROGRAMS}. For scripts, use @samp{LIBSCRIPTS}. In other respects, these variables are similar to @samp{PROGRAMS} and @samp{SCRIPTS}. Both of these variables have ``AM_'' override forms. Here is how to generate a program named @code{goodbye}, a helper for @code{hello}: @example LIBPROGRAMS = goodbye goodbye_SOURCES = goodbye.c @end example @node Data @section Architecture-independent data files @code{automake} supports two different ways to install architecture-independent data files. The first variable that can be used is @samp{DATA}. This is intended to be used for only a small number of data files. The files are installed in @samp{$@{datadir@}}. The second variable that can be used is @samp{PACKAGEDATA}. This is intended for a larger number of data files. The files are installed in @samp{$@{datadir@}/$@{PACKAGE@}}. This variable is what @code{automake} itself uses: @example PACKAGEDATA = clean-kr.am clean.am compile-kr.am compile-vars.am \ compile.am data.am depend.am dist-subd-top.am dist-subd-vars.am \ dist-subd.am dist-vars.am dist.am footer.am header-vars.am header.am \ libscripts.am libprograms.am libraries-vars.am libraries.am library.am \ mans-vars.am mans.am packagedata.am program.am programs.am remake-hdr.am \ remake-subd.am remake.am scripts.am subdirs.am tags.am tags-subd.am \ texinfos-vars.am texinfos.am hack-make.sed nl-remove.sed @end example All @samp{DATA} and @samp{PACKAGEDATA} files are included in a distribution. @node Docs @section Texinfo and Man Pages @subsection Texinfo If the current directory contains Texinfo source, you must declare it with the @samp{TEXINFOS} macro. Note that any Texinfo source file must end in the @file{.texi} extension (@file{.texinfo} won't work). If the @file{.texi} file ``@@include''s @file{version.texi}, then that file will be automatically generated. @file{version.texi} defines three Texinfo macros you can reference: @samp{EDITION}, @samp{VERSION}, and @samp{UPDATED}. The first two hold the version number of your package (but are kept separate for clarity); the last is the date the primary file was last modified. The @file{version.texi} support requires a version of @code{date} that accepts the @samp{-r} (read time from a file) option. Sometimes an info file actually depends on more than one @file{.texi} file. For instance, in the @samp{xdvik} distribution, @file{kpathsea.texi} includes the files @file{install.texi}, @file{copying.texi}, and @file{freedom.texi}. You can tell @code{automake} about these dependencies using the @samp{texi_TEXINFOS} variable. Here is how @samp{xdvik} could do it: @example TEXINFOS = kpathsea.texi kpathsea_TEXINFOS = install.texi copying.texi freedom.texi @end example @code{automake} might be modified to detect these dependencies automatically. Currently @code{automake} can only handle one primary @file{.texi} file. This restriction will be lifted if it proves too onerous. @code{automake} will warn if a directory containing Texinfo source does not also contain the file @file{texinfo.tex}. (I'm not sure if this is a good rule or not. Comments?) @subsection Man pages A package can also include man pages. (Though see the GNU standards on this matter. FIXME xref). Man pages are declared using the @samp{MANS} macro. Here is how the documentation is handled in GNU cpio (which includes both Texinfo documentation and man pages): @example TEXINFOS = cpio.texi MANS = cpio.1 mt.1 @end example Texinfo source, info pages and man pages are all considered to be ``source'' for the purposes of making a distribution. @node ANSI @section Automatic de-ANSI-fication of Source If @file{Makefile.am} includes the text @samp{@@kr@@}, then code to handle automatic de-ANSI-fication is included in the generated @file{Makefile.in}. This means that each C source file will be treated as ANSI C. If no ANSI C compiler is available on the build system, then the code will be turned into K&R C before compilation. Each directory that uses automatic de-ANSI-fication must include the source files @file{ansi2knr.c} and @file{ansi2knr.1}. Also, your @file{configure} script must define the variables @samp{U} and @samp{ANSI2KNR}. Here is a snippet you can add to @file{aclocal.m4} to achieve this: @example ## ------------------------------- ## ## Check for function prototypes. ## ## ------------------------------- ## AC_DEFUN(fp_C_PROTOTYPES, [AC_REQUIRE([fp_PROG_CC_STDC]) AC_MSG_CHECKING([for function prototypes]) if test "$ac_cv_prog_cc_stdc" != no; then AC_MSG_RESULT(yes) AC_DEFINE(PROTOTYPES) U= ANSI2KNR= else AC_MSG_RESULT(no) U=_ ANSI2KNR=./ansi2knr fi AC_SUBST(U)dnl AC_SUBST(ANSI2KNR)dnl ]) ## ----------------------------------------- ## ## ANSIfy the C compiler whenever possible. ## ## ----------------------------------------- ## # @@defmac AC_PROG_CC_STDC # @@maindex PROG_CC_STDC # @@ovindex CC # If the C compiler in not in ANSI C mode by default, try to add an option # to output variable @@code@{CC@} to make it so. This macro tries various # options that select ANSI C on some system or another. It considers the # compiler to be in ANSI C mode if it defines @@code@{__STDC__@} to 1 and # handles function prototypes correctly. # # If you use this macro, you should check after calling it whether the C # compiler has been set to accept ANSI C; if not, the shell variable # @@code@{ac_cv_prog_cc_stdc@} is set to @@samp@{no@}. If you wrote your source # code in ANSI C, you can make an un-ANSIfied copy of it by using the # program @@code@{ansi2knr@}, which comes with Ghostscript. # @@end defmac AC_DEFUN(fp_PROG_CC_STDC, [AC_MSG_CHECKING(for $@{CC-cc@} option to accept ANSI C) AC_CACHE_VAL(ac_cv_prog_cc_stdc, [ac_cv_prog_cc_stdc=no ac_save_CFLAGS="$CFLAGS" # Don't try gcc -ansi; that turns off useful extensions and # breaks some systems' header files. # AIX -qlanglvl=ansi # Ultrix and OSF/1 -std1 # HP-UX -Aa -D_HPUX_SOURCE # SVR4 -Xc for ac_arg in "" -qlanglvl=ansi -std1 "-Aa -D_HPUX_SOURCE" -Xc do CFLAGS="$ac_save_CFLAGS $ac_arg" AC_TRY_COMPILE( [#if !defined(__STDC__) || __STDC__ != 1 choke me #endif ], [int test (int i, double x); struct s1 @{int (*f) (int a);@}; struct s2 @{int (*f) (double a);@};], [ac_cv_prog_cc_stdc="$ac_arg"; break]) done CFLAGS="$ac_save_CFLAGS" ]) AC_MSG_RESULT($ac_cv_prog_cc_stdc) case "x$ac_cv_prog_cc_stdc" in x|xno) ;; *) CC="$CC $ac_cv_prog_cc_stdc" ;; esac ]) @end example @node Install @section What Gets Installed Naturally, @code{automake} handles the details of actually installing your program once it has been built. Any objects specified in @samp{PROGRAMS}, @samp{LIBPROGRAMS}, @samp{SCRIPTS}, @samp{LIBSCRIPTS}, @samp{DATA}, and @samp{PACKAGEDATA} are automatically installed in the appropriate place. @code{automake} also handles installing any specified info and man pages. FIXME xref to Extending node here; sometimes you need to install more. @code{automake} generates separate @samp{install-data} and @samp{install-exec} targets, in case the installer is installing on multiple machines which share directory structure -- these targets allow the machine-independent parts to be installed only once. @code{automake} also generates an @samp{uninstall} target. In the future @code{automake} will be extended to generate an @samp{installdirs} target. @node Distribution @section Building a Release The @samp{dist} target in the generated @file{Makefile.in} can be used to generate a gzip'd tar file for distribution. The tar file is named based on the @var{PACKAGE} and @var{VERSION} variables. For the most part, the files to distribute are automatically found by @code{automake}: all source files are automatically included in a distribution, as are all @file{Makefile.am}s and @file{Makefile.in}s. @code{automake} also has a built-in list of commonly used files which, if present in the current directory, are automatically included. This list is printed by @code{automake --help}. Still, sometimes there are files which must be distributed, but which are not covered in the automatic rules. These files should be listed in the @samp{DIST_OTHER} variable. For instance, in the @code{automake} distribution, @file{automake.in} (the source to @code{automake}) is not found automatically. So in the @file{Makefile.am}, we have: @example DIST_OTHER = automake.in @end example FIXME mention files that are found automatically but not printed by --help. FIXME: describe DIST_SUBDIRS or not? It is a hack which might go away. @node Tags @section Interfacing to @code{etags} @code{automake} will generate rules to generate @file{TAGS} files for use with GNU Emacs under some circumstances. If any C source code or headers are present, then a @file{TAGS} file will be generated for the directory. At the topmost directory of a multi-directory package, a @file{TAGS} file will be generated that will include by reference all @file{TAGS} files from subdirectories. Also, if the variable @samp{ETAGS_ARGS} is defined, a @file{TAGS} file will be generated. This variable is intended for use in directories which contain taggable source that @code{etags} does not understand. (For instance, it could be set to a regexp to recognize node names in Texinfo documentation) @node Dependencies @section Automatic dependency tracking As a developer it is often painful to continually update the @file{Makefile.in} whenever the include-file dependencies change in a project. @code{automake} supplies a way to automatically track dependency changes, and distribute the dependencies in the generated @file{Makefile.in}. Currently this support requires the use of @code{GNU make} and @code{gcc}. It might become possible in the future to supply a different dependency generating program, if there is enough demand. This mode is enabled by default if any C program or library is defined in the current directory. When you decide to make a distribution, the @samp{dist} target will re-run @code{automake} with the @samp{--include-deps} option. This causes the previously generated dependencies to be inserted into the generated @file{Makefile.in}, and thus into the distribution. @samp{--include-deps} also turns off inclusion of the dependency generation code. There should probably be a way to suppress this mode. @node Extending @section When AutoMake Isn't Enough Sometimes @code{automake} isn't enough. Then you just lose. Actually, @code{automake}s implicit copying semantics means that many problems can be worked around by simply adding some @code{make} targets and rules to @file{Makefile.in}. @code{automake} will ignore these additions. There are some caveats to doing this. You can't overload a target already used by @code{automake}. However, various useful targets have a ``-local'' version you can specify in your @file{Makefile.in}. The targets that support a local version are @samp{all}, @samp{info}, @samp{dvi}, @samp{check}, @samp{install-data}, @samp{install-exec}, and @samp{uninstall}. (Currently @samp{install} is also supported, but this might go away) For instance, here is how to install a file in @file{/etc}: @example install-data-local: $(INSTALL_DATA) $(srcdir)/afile /etc/afile @end example @node Invoking automake @chapter Using @code{automake} to Create @file{Makefile.in} There are basically two modes in which @code{automake} can be run. In the first, most common, mode, @code{automake} is simply run without any arguments. It will determine which @file{Makefile.am}s exist by looking in the current directory and immediate subdirectories, and will automatically build @file{Makefile.in}s in these directories. In the second mode, @code{automake} is run with the name of one or more @file{Makefile}s as arguments. It then rebuilds the corresponding @file{Makefile.in}s from the (also) corresponding @file{Makefile.am}s. This second mode is most often used by @code{make} itself, when it notices that a @code{Makefile.in} is out of date. @node Future @chapter Some ideas for the future Here are some things that might happen in the future: @itemize @bullet @item Better error checking would be good. @end itemize @node Some index @chapter Nothing yet @bye NOTES: * Need section on operation of automake: it reads Makefile.am and COPIES the contents...