automake

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GNU Automake

This manual is for GNU Automake (version 1.15.1, 17 June 2017), a program that creates GNU standards-compliant Makefiles from template files.

Copyright © 1995-2017 Free Software Foundation, Inc.

Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.3 or any later version published by the Free Software Foundation; with no Invariant Sections, with no Front-Cover texts, and with no Back-Cover Texts. A copy of the license is included in the section entitled “GNU Free Documentation License.”

Table of Contents


1 Introduction

Automake is a tool for automatically generating Makefile.ins from files called Makefile.am. Each Makefile.am is basically a series of make variable definitions1, with rules being thrown in occasionally. The generated Makefile.ins are compliant with the GNU Makefile standards.

The GNU Makefile Standards Document (see Makefile Conventions in The GNU Coding Standards) is long, complicated, and subject to change. The goal of Automake is to remove the burden of Makefile maintenance from the back of the individual GNU maintainer (and put it on the back of the Automake maintainers).

The typical Automake input file is simply a series of variable definitions. Each such file is processed to create a Makefile.in.

Automake does constrain a project in certain ways; for instance, it assumes that the project uses Autoconf (see Introduction in The Autoconf Manual), and enforces certain restrictions on the configure.ac contents.

Automake requires perl in order to generate the Makefile.ins. However, the distributions created by Automake are fully GNU standards-compliant, and do not require perl in order to be built.

For more information on bug reports, See Reporting Bugs.


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2 An Introduction to the Autotools

If you are new to Automake, maybe you know that it is part of a set of tools called The Autotools. Maybe you’ve already delved into a package full of files named configure, configure.ac, Makefile.in, Makefile.am, aclocal.m4, …, some of them claiming to be generated by Autoconf or Automake. But the exact purpose of these files and their relations is probably fuzzy. The goal of this chapter is to introduce you to this machinery, to show you how it works and how powerful it is. If you’ve never installed or seen such a package, do not worry: this chapter will walk you through it.

If you need some teaching material, more illustrations, or a less automake-centered continuation, some slides for this introduction are available in Alexandre Duret-Lutz’s Autotools Tutorial. This chapter is the written version of the first part of his tutorial.


2.1 Introducing the GNU Build System

It is a truth universally acknowledged, that as a developer in possession of a new package, you must be in want of a build system.

In the Unix world, such a build system is traditionally achieved using the command make (see Overview in The GNU Make Manual). You express the recipe to build your package in a Makefile. This file is a set of rules to build the files in the package. For instance the program prog may be built by running the linker on the files main.o, foo.o, and bar.o; the file main.o may be built by running the compiler on main.c; etc. Each time make is run, it reads Makefile, checks the existence and modification time of the files mentioned, decides what files need to be built (or rebuilt), and runs the associated commands.

When a package needs to be built on a different platform than the one it was developed on, its Makefile usually needs to be adjusted. For instance the compiler may have another name or require more options. In 1991, David J. MacKenzie got tired of customizing Makefile for the 20 platforms he had to deal with. Instead, he handcrafted a little shell script called configure to automatically adjust the Makefile (see Genesis in The Autoconf Manual). Compiling his package was now as simple as running ./configure && make.

Today this process has been standardized in the GNU project. The GNU Coding Standards (see The Release Process in The GNU Coding Standards) explains how each package of the GNU project should have a configure script, and the minimal interface it should have. The Makefile too should follow some established conventions. The result? A unified build system that makes all packages almost indistinguishable by the installer. In its simplest scenario, all the installer has to do is to unpack the package, run ./configure && make && make install, and repeat with the next package to install.

We call this build system the GNU Build System, since it was grown out of the GNU project. However it is used by a vast number of other packages: following any existing convention has its advantages.

The Autotools are tools that will create a GNU Build System for your package. Autoconf mostly focuses on configure and Automake on Makefiles. It is entirely possible to create a GNU Build System without the help of these tools. However it is rather burdensome and error-prone. We will discuss this again after some illustration of the GNU Build System in action.


2.2 Use Cases for the GNU Build System

In this section we explore several use cases for the GNU Build System. You can replay all of these examples on the amhello-1.0.tar.gz package distributed with Automake. If Automake is installed on your system, you should find a copy of this file in prefix/share/doc/automake/amhello-1.0.tar.gz, where prefix is the installation prefix specified during configuration (prefix defaults to /usr/local, however if Automake was installed by some GNU/Linux distribution it most likely has been set to /usr). If you do not have a copy of Automake installed, you can find a copy of this file inside the doc/ directory of the Automake package.

Some of the following use cases present features that are in fact extensions to the GNU Build System. Read: they are not specified by the GNU Coding Standards, but they are nonetheless part of the build system created by the Autotools. To keep things simple, we do not point out the difference. Our objective is to show you many of the features that the build system created by the Autotools will offer to you.


2.2.1 Basic Installation

The most common installation procedure looks as follows.

~ % tar zxf amhello-1.0.tar.gz
~ % cd amhello-1.0
~/amhello-1.0 % ./configure
…
config.status: creating Makefile
config.status: creating src/Makefile
…
~/amhello-1.0 % make
…
~/amhello-1.0 % make check
…
~/amhello-1.0 % su
Password:
/home/adl/amhello-1.0 # make install
…
/home/adl/amhello-1.0 # exit
~/amhello-1.0 % make installcheck

The user first unpacks the package. Here, and in the following examples, we will use the non-portable tar zxf command for simplicity. On a system without GNU tar installed, this command should read gunzip -c amhello-1.0.tar.gz | tar xf -.

The user then enters the newly created directory to run the configure script. This script probes the system for various features, and finally creates the Makefiles. In this toy example there are only two Makefiles, but in real-world projects, there may be many more, usually one Makefile per directory.

It is now possible to run make. This will construct all the programs, libraries, and scripts that need to be constructed for the package. In our example, this compiles the hello program. All files are constructed in place, in the source tree; we will see later how this can be changed.

make check causes the package’s tests to be run. This step is not mandatory, but it is often good to make sure the programs that have been built behave as they should, before you decide to install them. Our example does not contain any tests, so running make check is a no-op.

After everything has been built, and maybe tested, it is time to install it on the system. That means copying the programs, libraries, header files, scripts, and other data files from the source directory to their final destination on the system. The command make install will do that. However, by default everything will be installed in subdirectories of /usr/local: binaries will go into /usr/local/bin, libraries will end up in /usr/local/lib, etc. This destination is usually not writable by any user, so we assume that we have to become root before we can run make install. In our example, running make install will copy the program hello into /usr/local/bin and README into /usr/local/share/doc/amhello.

A last and optional step is to run make installcheck. This command may run tests on the installed files. make check tests the files in the source tree, while make installcheck tests their installed copies. The tests run by the latter can be different from those run by the former. For instance, there are tests that cannot be run in the source tree. Conversely, some packages are set up so that make installcheck will run the very same tests as make check, only on different files (non-installed vs. installed). It can make a difference, for instance when the source tree’s layout is different from that of the installation. Furthermore it may help to diagnose an incomplete installation.

Presently most packages do not have any installcheck tests because the existence of installcheck is little known, and its usefulness is neglected. Our little toy package is no better: make installcheck does nothing.


2.2.2 Standard Makefile Targets

So far we have come across four ways to run make in the GNU Build System: make, make check, make install, and make installcheck. The words check, install, and installcheck, passed as arguments to make, are called targets. make is a shorthand for make all, all being the default target in the GNU Build System.

Here is a list of the most useful targets that the GNU Coding Standards specify.

make all

Build programs, libraries, documentation, etc. (same as make).

make install

Install what needs to be installed, copying the files from the package’s tree to system-wide directories.

make install-strip

Same as make install, then strip debugging symbols. Some users like to trade space for useful bug reports...

make uninstall

The opposite of make install: erase the installed files. (This needs to be run from the same build tree that was installed.)

make clean

Erase from the build tree the files built by make all.

make distclean

Additionally erase anything ./configure created.

make check

Run the test suite, if any.

make installcheck

Check the installed programs or libraries, if supported.

make dist

Recreate package-version.tar.gz from all the source files.


2.2.3 Standard Directory Variables

The GNU Coding Standards also specify a hierarchy of variables to denote installation directories. Some of these are:

Directory variableDefault value
prefix/usr/local
  exec_prefix${prefix}
    bindir${exec_prefix}/bin
    libdir${exec_prefix}/lib
    …
  includedir${prefix}/include
  datarootdir${prefix}/share
    datadir${datarootdir}
    mandir${datarootdir}/man
    infodir${datarootdir}/info
    docdir${datarootdir}/doc/${PACKAGE}
  …

Each of these directories has a role which is often obvious from its name. In a package, any installable file will be installed in one of these directories. For instance in amhello-1.0, the program hello is to be installed in bindir, the directory for binaries. The default value for this directory is /usr/local/bin, but the user can supply a different value when calling configure. Also the file README will be installed into docdir, which defaults to /usr/local/share/doc/amhello.

As a user, if you wish to install a package on your own account, you could proceed as follows:

~/amhello-1.0 % ./configure --prefix ~/usr
…
~/amhello-1.0 % make
…
~/amhello-1.0 % make install

This would install ~/usr/bin/hello and ~/usr/share/doc/amhello/README.

The list of all such directory options is shown by ./configure --help.


2.2.4 Standard Configuration Variables

The GNU Coding Standards also define a set of standard configuration variables used during the build. Here are some:

CC

C compiler command

CFLAGS

C compiler flags

CXX

C++ compiler command

CXXFLAGS

C++ compiler flags

LDFLAGS

linker flags

CPPFLAGS

C/C++ preprocessor flags

configure usually does a good job at setting appropriate values for these variables, but there are cases where you may want to override them. For instance you may have several versions of a compiler installed and would like to use another one, you may have header files installed outside the default search path of the compiler, or even libraries out of the way of the linker.

Here is how one would call configure to force it to use gcc-3 as C compiler, use header files from ~/usr/include when compiling, and libraries from ~/usr/lib when linking.

~/amhello-1.0 % ./configure --prefix ~/usr CC=gcc-3 \
CPPFLAGS=-I$HOME/usr/include LDFLAGS=-L$HOME/usr/lib

Again, a full list of these variables appears in the output of ./configure --help.


2.2.5 Overriding Default Configuration Setting with config.site

When installing several packages using the same setup, it can be convenient to create a file to capture common settings. If a file named prefix/share/config.site exists, configure will source it at the beginning of its execution.

Recall the command from the previous section:

~/amhello-1.0 % ./configure --prefix ~/usr CC=gcc-3 \
CPPFLAGS=-I$HOME/usr/include LDFLAGS=-L$HOME/usr/lib

Assuming we are installing many package in ~/usr, and will always want to use these definitions of CC, CPPFLAGS, and LDFLAGS, we can automate this by creating the following ~/usr/share/config.site file:

test -z "$CC" && CC=gcc-3
test -z "$CPPFLAGS" && CPPFLAGS=-I$HOME/usr/include
test -z "$LDFLAGS" && LDFLAGS=-L$HOME/usr/lib

Now, any time a configure script is using the ~/usr prefix, it will execute the above config.site and define these three variables.

~/amhello-1.0 % ./configure --prefix ~/usr
configure: loading site script /home/adl/usr/share/config.site
…

See Setting Site Defaults in The Autoconf Manual, for more information about this feature.


2.2.6 Parallel Build Trees (a.k.a. VPATH Builds)

The GNU Build System distinguishes two trees: the source tree, and the build tree.

The source tree is rooted in the directory containing configure. It contains all the sources files (those that are distributed), and may be arranged using several subdirectories.

The build tree is rooted in the directory in which configure was run, and is populated with all object files, programs, libraries, and other derived files built from the sources (and hence not distributed). The build tree usually has the same subdirectory layout as the source tree; its subdirectories are created automatically by the build system.

If configure is executed in its own directory, the source and build trees are combined: derived files are constructed in the same directories as their sources. This was the case in our first installation example (see Basic Installation).

A common request from users is that they want to confine all derived files to a single directory, to keep their source directories uncluttered. Here is how we could run configure to build everything in a subdirectory called build/.

~ % tar zxf ~/amhello-1.0.tar.gz
~ % cd amhello-1.0
~/amhello-1.0 % mkdir build && cd build
~/amhello-1.0/build % ../configure
…
~/amhello-1.0/build % make

These setups, where source and build trees are different, are often called parallel builds or VPATH builds. The expression parallel build is misleading: the word parallel is a reference to the way the build tree shadows the source tree, it is not about some concurrency in the way build commands are run. For this reason we refer to such setups using the name VPATH builds in the following. VPATH is the name of the make feature used by the Makefiles to allow these builds (see VPATH Search Path for All Prerequisites in The GNU Make Manual).

VPATH builds have other interesting uses. One is to build the same sources with multiple configurations. For instance:

~ % tar zxf ~/amhello-1.0.tar.gz
~ % cd amhello-1.0
~/amhello-1.0 % mkdir debug optim && cd debug
~/amhello-1.0/debug % ../configure CFLAGS='-g -O0'
…
~/amhello-1.0/debug % make
…
~/amhello-1.0/debug % cd ../optim
~/amhello-1.0/optim % ../configure CFLAGS='-O3 -fomit-frame-pointer'
…
~/amhello-1.0/optim % make

With network file systems, a similar approach can be used to build the same sources on different machines. For instance, suppose that the sources are installed on a directory shared by two hosts: HOST1 and HOST2, which may be different platforms.

~ % cd /nfs/src
/nfs/src % tar zxf ~/amhello-1.0.tar.gz

On the first host, you could create a local build directory:

[HOST1] ~ % mkdir /tmp/amh && cd /tmp/amh
[HOST1] /tmp/amh % /nfs/src/amhello-1.0/configure
...
[HOST1] /tmp/amh % make && sudo make install
...

(Here we assume that the installer has configured sudo so it can execute make install with root privileges; it is more convenient than using su like in Basic Installation).

On the second host, you would do exactly the same, possibly at the same time:

[HOST2] ~ % mkdir /tmp/amh && cd /tmp/amh
[HOST2] /tmp/amh % /nfs/src/amhello-1.0/configure
...
[HOST2] /tmp/amh % make && sudo make install
...

In this scenario, nothing forbids the /nfs/src/amhello-1.0 directory from being read-only. In fact VPATH builds are also a means of building packages from a read-only medium such as a CD-ROM. (The FSF used to sell CD-ROM with unpacked source code, before the GNU project grew so big.)


2.2.7 Two-Part Installation

In our last example (see Parallel Build Trees (a.k.a. VPATH Builds)), a source tree was shared by two hosts, but compilation and installation were done separately on each host.

The GNU Build System also supports networked setups where part of the installed files should be shared amongst multiple hosts. It does so by distinguishing architecture-dependent files from architecture-independent files, and providing two Makefile targets to install each of these classes of files.

These targets are install-exec for architecture-dependent files and install-data for architecture-independent files. The command we used up to now, make install, can be thought of as a shorthand for make install-exec install-data.

From the GNU Build System point of view, the distinction between architecture-dependent files and architecture-independent files is based exclusively on the directory variable used to specify their installation destination. In the list of directory variables we provided earlier (see Standard Directory Variables), all the variables based on exec-prefix designate architecture-dependent directories whose files will be installed by make install-exec. The others designate architecture-independent directories and will serve files installed by make install-data. See The Two Parts of Install, for more details.

Here is how we could revisit our two-host installation example, assuming that (1) we want to install the package directly in /usr, and (2) the directory /usr/share is shared by the two hosts.

On the first host we would run

[HOST1] ~ % mkdir /tmp/amh && cd /tmp/amh
[HOST1] /tmp/amh % /nfs/src/amhello-1.0/configure --prefix /usr
...
[HOST1] /tmp/amh % make && sudo make install
...

On the second host, however, we need only install the architecture-specific files.

[HOST2] ~ % mkdir /tmp/amh && cd /tmp/amh
[HOST2] /tmp/amh % /nfs/src/amhello-1.0/configure --prefix /usr
...
[HOST2] /tmp/amh % make && sudo make install-exec
...

In packages that have installation checks, it would make sense to run make installcheck (see Basic Installation) to verify that the package works correctly despite the apparent partial installation.


2.2.8 Cross-Compilation

To cross-compile is to build on one platform a binary that will run on another platform. When speaking of cross-compilation, it is important to distinguish between the build platform on which the compilation is performed, and the host platform on which the resulting executable is expected to run. The following configure options are used to specify each of them:

--build=build

The system on which the package is built.

--host=host

The system where built programs and libraries will run.

When the --host is used, configure will search for the cross-compiling suite for this platform. Cross-compilation tools commonly have their target architecture as prefix of their name. For instance my cross-compiler for MinGW32 has its binaries called i586-mingw32msvc-gcc, i586-mingw32msvc-ld, i586-mingw32msvc-as, etc.

Here is how we could build amhello-1.0 for i586-mingw32msvc on a GNU/Linux PC.

~/amhello-1.0 % ./configure --build i686-pc-linux-gnu --host i586-mingw32msvc
checking for a BSD-compatible install... /usr/bin/install -c
checking whether build environment is sane... yes
checking for gawk... gawk
checking whether make sets $(MAKE)... yes
checking for i586-mingw32msvc-strip... i586-mingw32msvc-strip
checking for i586-mingw32msvc-gcc... i586-mingw32msvc-gcc
checking for C compiler default output file name... a.exe
checking whether the C compiler works... yes
checking whether we are cross compiling... yes
checking for suffix of executables... .exe
checking for suffix of object files... o
checking whether we are using the GNU C compiler... yes
checking whether i586-mingw32msvc-gcc accepts -g... yes
checking for i586-mingw32msvc-gcc option to accept ANSI C...
…
~/amhello-1.0 % make
…
~/amhello-1.0 % cd src; file hello.exe
hello.exe: MS Windows PE 32-bit Intel 80386 console executable not relocatable

The --host and --build options are usually all we need for cross-compiling. The only exception is if the package being built is itself a cross-compiler: we need a third option to specify its target architecture.

--target=target

When building compiler tools: the system for which the tools will create output.

For instance when installing GCC, the GNU Compiler Collection, we can use --target=target to specify that we want to build GCC as a cross-compiler for target. Mixing --build and --target, we can actually cross-compile a cross-compiler; such a three-way cross-compilation is known as a Canadian cross.

See Specifying the System Type in The Autoconf Manual, for more information about these configure options.


2.2.9 Renaming Programs at Install Time

The GNU Build System provides means to automatically rename executables and manpages before they are installed (see Man Pages). This is especially convenient when installing a GNU package on a system that already has a proprietary implementation you do not want to overwrite. For instance, you may want to install GNU tar as gtar so you can distinguish it from your vendor’s tar.

This can be done using one of these three configure options.

--program-prefix=prefix

Prepend prefix to installed program names.

--program-suffix=suffix

Append suffix to installed program names.

--program-transform-name=program

Run sed program on installed program names.

The following commands would install hello as /usr/local/bin/test-hello, for instance.

~/amhello-1.0 % ./configure --program-prefix test-
…
~/amhello-1.0 % make
…
~/amhello-1.0 % sudo make install

2.2.10 Building Binary Packages Using DESTDIR

The GNU Build System’s make install and make uninstall interface does not exactly fit the needs of a system administrator who has to deploy and upgrade packages on lots of hosts. In other words, the GNU Build System does not replace a package manager.

Such package managers usually need to know which files have been installed by a package, so a mere make install is inappropriate.

The DESTDIR variable can be used to perform a staged installation. The package should be configured as if it was going to be installed in its final location (e.g., --prefix /usr), but when running make install, the DESTDIR should be set to the absolute name of a directory into which the installation will be diverted. From this directory it is easy to review which files are being installed where, and finally copy them to their final location by some means.

For instance here is how we could create a binary package containing a snapshot of all the files to be installed.

~/amhello-1.0 % ./configure --prefix /usr
…
~/amhello-1.0 % make
…
~/amhello-1.0 % make DESTDIR=$HOME/inst install
…
~/amhello-1.0 % cd ~/inst
~/inst % find . -type f -print > ../files.lst
~/inst % tar zcvf ~/amhello-1.0-i686.tar.gz `cat ../files.lst`
./usr/bin/hello
./usr/share/doc/amhello/README

After this example, amhello-1.0-i686.tar.gz is ready to be uncompressed in / on many hosts. (Using `cat ../files.lst` instead of ‘.’ as argument for tar avoids entries for each subdirectory in the archive: we would not like tar to restore the modification time of /, /usr/, etc.)

Note that when building packages for several architectures, it might be convenient to use make install-data and make install-exec (see Two-Part Installation) to gather architecture-independent files in a single package.

See What Gets Installed, for more information.


2.2.11 Preparing Distributions

We have already mentioned make dist. This target collects all your source files and the necessary parts of the build system to create a tarball named package-version.tar.gz.

Another, more useful command is make distcheck. The distcheck target constructs package-version.tar.gz just as well as dist, but it additionally ensures most of the use cases presented so far work:

All of these actions are performed in a temporary directory, so that no root privileges are required. Please note that the exact location and the exact structure of such a subdirectory (where the extracted sources are placed, how the temporary build and install directories are named and how deeply they are nested, etc.) is to be considered an implementation detail, which can change at any time; so do not rely on it.

Releasing a package that fails make distcheck means that one of the scenarios we presented will not work and some users will be disappointed. Therefore it is a good practice to release a package only after a successful make distcheck. This of course does not imply that the package will be flawless, but at least it will prevent some of the embarrassing errors you may find in packages released by people who have never heard about distcheck (like DESTDIR not working because of a typo, or a distributed file being erased by make clean, or even VPATH builds not working).

See Creating amhello-1.0.tar.gz, to recreate amhello-1.0.tar.gz using make distcheck. See Checking the Distribution, for more information about distcheck.


2.2.12 Automatic Dependency Tracking

Dependency tracking is performed as a side-effect of compilation. Each time the build system compiles a source file, it computes its list of dependencies (in C these are the header files included by the source being compiled). Later, any time make is run and a dependency appears to have changed, the dependent files will be rebuilt.

Automake generates code for automatic dependency tracking by default, unless the developer chooses to override it; for more information, see Automatic dependency tracking.

When configure is executed, you can see it probing each compiler for the dependency mechanism it supports (several mechanisms can be used):

~/amhello-1.0 % ./configure --prefix /usr
…
checking dependency style of gcc... gcc3
…

Because dependencies are only computed as a side-effect of the compilation, no dependency information exists the first time a package is built. This is OK because all the files need to be built anyway: make does not have to decide which files need to be rebuilt. In fact, dependency tracking is completely useless for one-time builds and there is a configure option to disable this:

--disable-dependency-tracking

Speed up one-time builds.

Some compilers do not offer any practical way to derive the list of dependencies as a side-effect of the compilation, requiring a separate run (maybe of another tool) to compute these dependencies. The performance penalty implied by these methods is important enough to disable them by default. The option --enable-dependency-tracking must be passed to configure to activate them.

--enable-dependency-tracking

Do not reject slow dependency extractors.

See Dependency Tracking Evolution in Brief History of Automake, for some discussion about the different dependency tracking schemes used by Automake over the years.


2.2.13 Nested Packages

Although nesting packages isn’t something we would recommend to someone who is discovering the Autotools, it is a nice feature worthy of mention in this small advertising tour.

Autoconfiscated packages (that means packages whose build system have been created by Autoconf and friends) can be nested to arbitrary depth.

A typical setup is that package A will distribute one of the libraries it needs in a subdirectory. This library B is a complete package with its own GNU Build System. The configure script of A will run the configure script of B as part of its execution, building and installing A will also build and install B. Generating a distribution for A will also include B.

It is possible to gather several packages like this. GCC is a heavy user of this feature. This gives installers a single package to configure, build and install, while it allows developers to work on subpackages independently.

When configuring nested packages, the configure options given to the top-level configure are passed recursively to nested configures. A package that does not understand an option will ignore it, assuming it is meaningful to some other package.

The command configure --help=recursive can be used to display the options supported by all the included packages.

See Nesting Packages, for an example setup.


2.3 How Autotools Help

There are several reasons why you may not want to implement the GNU Build System yourself (read: write a configure script and Makefiles yourself).

  • As we have seen, the GNU Build System has a lot of features (see Use Cases for the GNU Build System). Some users may expect features you have not implemented because you did not need them.
  • Implementing these features portably is difficult and exhausting. Think of writing portable shell scripts, and portable Makefiles, for systems you may not have handy. See Portable Shell Programming in The Autoconf Manual, to convince yourself.
  • You will have to upgrade your setup to follow changes to the GNU Coding Standards.

The GNU Autotools take all this burden off your back and provide:

  • Tools to create a portable, complete, and self-contained GNU Build System, from simple instructions. Self-contained meaning the resulting build system does not require the GNU Autotools.
  • A central place where fixes and improvements are made: a bug-fix for a portability issue will benefit every package.

Yet there also exist reasons why you may want NOT to use the Autotools... For instance you may be already using (or used to) another incompatible build system. Autotools will only be useful if you do accept the concepts of the GNU Build System. People who have their own idea of how a build system should work will feel frustrated by the Autotools.


2.4 A Small Hello World

In this section we recreate the amhello-1.0 package from scratch. The first subsection shows how to call the Autotools to instantiate the GNU Build System, while the second explains the meaning of the configure.ac and Makefile.am files read by the Autotools.


2.4.1 Creating amhello-1.0.tar.gz

Here is how we can recreate amhello-1.0.tar.gz from scratch. The package is simple enough so that we will only need to write 5 files. (You may copy them from the final amhello-1.0.tar.gz that is distributed with Automake if you do not want to write them.)

Create the following files in an empty directory.

  • src/main.c is the source file for the hello program. We store it in the src/ subdirectory, because later, when the package evolves, it will ease the addition of a man/ directory for man pages, a data/ directory for data files, etc.
    ~/amhello % cat src/main.c
    #include <config.h>
    #include <stdio.h>
    
    int
    main (void)
    {
      puts ("Hello World!");
      puts ("This is " PACKAGE_STRING ".");
      return 0;
    }
    
  • README contains some very limited documentation for our little package.
    ~/amhello % cat README
    This is a demonstration package for GNU Automake.
    Type 'info Automake' to read the Automake manual.
    
  • Makefile.am and src/Makefile.am contain Automake instructions for these two directories.
    ~/amhello % cat src/Makefile.am
    bin_PROGRAMS = hello
    hello_SOURCES = main.c
    ~/amhello % cat Makefile.am
    SUBDIRS = src
    dist_doc_DATA = README
    
  • Finally, configure.ac contains Autoconf instructions to create the configure script.
    ~/amhello % cat configure.ac
    AC_INIT([amhello], [1.0], [bug-automake@gnu.org])
    AM_INIT_AUTOMAKE([-Wall -Werror foreign])
    AC_PROG_CC
    AC_CONFIG_HEADERS([config.h])
    AC_CONFIG_FILES([
     Makefile
     src/Makefile
    ])
    AC_OUTPUT
    

Once you have these five files, it is time to run the Autotools to instantiate the build system. Do this using the autoreconf command as follows:

~/amhello % autoreconf --install
configure.ac: installing './install-sh'
configure.ac: installing './missing'
configure.ac: installing './compile'
src/Makefile.am: installing './depcomp'

At this point the build system is complete.

In addition to the three scripts mentioned in its output, you can see that autoreconf created four other files: configure, config.h.in, Makefile.in, and src/Makefile.in. The latter three files are templates that will be adapted to the system by configure under the names config.h, Makefile, and src/Makefile. Let’s do this:

~/amhello % ./configure
checking for a BSD-compatible install... /usr/bin/install -c
checking whether build environment is sane... yes
checking for gawk... no
checking for mawk... mawk
checking whether make sets $(MAKE)... yes
checking for gcc... gcc
checking for C compiler default output file name... a.out
checking whether the C compiler works... yes
checking whether we are cross compiling... no
checking for suffix of executables...
checking for suffix of object files... o
checking whether we are using the GNU C compiler... yes
checking whether gcc accepts -g... yes
checking for gcc option to accept ISO C89... none needed
checking for style of include used by make... GNU
checking dependency style of gcc... gcc3
configure: creating ./config.status
config.status: creating Makefile
config.status: creating src/Makefile
config.status: creating config.h
config.status: executing depfiles commands

You can see Makefile, src/Makefile, and config.h being created at the end after configure has probed the system. It is now possible to run all the targets we wish (see Standard Makefile Targets). For instance:

~/amhello % make
…
~/amhello % src/hello
Hello World!
This is amhello 1.0.
~/amhello % make distcheck
…
=============================================
amhello-1.0 archives ready for distribution:
amhello-1.0.tar.gz
=============================================

Note that running autoreconf is only needed initially when the GNU Build System does not exist. When you later change some instructions in a Makefile.am or configure.ac, the relevant part of the build system will be regenerated automatically when you execute make.

autoreconf is a script that calls autoconf, automake, and a bunch of other commands in the right order. If you are beginning with these tools, it is not important to figure out in which order all of these tools should be invoked and why. However, because Autoconf and Automake have separate manuals, the important point to understand is that autoconf is in charge of creating configure from configure.ac, while automake is in charge of creating Makefile.ins from Makefile.ams and configure.ac. This should at least direct you to the right manual when seeking answers.


2.4.2 amhello’s configure.ac Setup Explained

Let us begin with the contents of configure.ac.

AC_INIT([amhello], [1.0], [bug-automake@gnu.org])
AM_INIT_AUTOMAKE([-Wall -Werror foreign])
AC_PROG_CC
AC_CONFIG_HEADERS([config.h])
AC_CONFIG_FILES([
 Makefile
 src/Makefile
])
AC_OUTPUT

This file is read by both autoconf (to create configure) and automake (to create the various Makefile.ins). It contains a series of M4 macros that will be expanded as shell code to finally form the configure script. We will not elaborate on the syntax of this file, because the Autoconf manual has a whole section about it (see Writing configure.ac in The Autoconf Manual).

The macros prefixed with AC_ are Autoconf macros, documented in the Autoconf manual (see Autoconf Macro Index in The Autoconf Manual). The macros that start with AM_ are Automake macros, documented later in this manual (see Macro Index).

The first two lines of configure.ac initialize Autoconf and Automake. AC_INIT takes in as parameters the name of the package, its version number, and a contact address for bug-reports about the package (this address is output at the end of ./configure --help, for instance). When adapting this setup to your own package, by all means please do not blindly copy Automake’s address: use the mailing list of your package, or your own mail address.

The argument to AM_INIT_AUTOMAKE is a list of options for automake (see Changing Automake’s Behavior). -Wall and -Werror ask automake to turn on all warnings and report them as errors. We are speaking of Automake warnings here, such as dubious instructions in Makefile.am. This has absolutely nothing to do with how the compiler will be called, even though it may support options with similar names. Using -Wall -Werror is a safe setting when starting to work on a package: you do not want to miss any issues. Later you may decide to relax things a bit. The foreign option tells Automake that this package will not follow the GNU Standards. GNU packages should always distribute additional files such as ChangeLog, AUTHORS, etc. We do not want automake to complain about these missing files in our small example.

The AC_PROG_CC line causes the configure script to search for a C compiler and define the variable CC with its name. The src/Makefile.in file generated by Automake uses the variable CC to build hello, so when configure creates src/Makefile from src/Makefile.in, it will define CC with the value it has found. If Automake is asked to create a Makefile.in that uses CC but configure.ac does not define it, it will suggest you add a call to AC_PROG_CC.

The AC_CONFIG_HEADERS([config.h]) invocation causes the configure script to create a config.h file gathering ‘#define’s defined by other macros in configure.ac. In our case, the AC_INIT macro already defined a few of them. Here is an excerpt of config.h after configure has run:

…
/* Define to the address where bug reports for this package should be sent. */
#define PACKAGE_BUGREPORT "bug-automake@gnu.org"

/* Define to the full name and version of this package. */
#define PACKAGE_STRING "amhello 1.0"
…

As you probably noticed, src/main.c includes config.h so it can use PACKAGE_STRING. In a real-world project, config.h can grow really big, with one ‘#define’ per feature probed on the system.

The AC_CONFIG_FILES macro declares the list of files that configure should create from their *.in templates. Automake also scans this list to find the Makefile.am files it must process. (This is important to remember: when adding a new directory to your project, you should add its Makefile to this list, otherwise Automake will never process the new Makefile.am you wrote in that directory.)

Finally, the AC_OUTPUT line is a closing command that actually produces the part of the script in charge of creating the files registered with AC_CONFIG_HEADERS and AC_CONFIG_FILES.

When starting a new project, we suggest you start with such a simple configure.ac, and gradually add the other tests it requires. The command autoscan can also suggest a few of the tests your package may need (see Using autoscan to Create configure.ac in The Autoconf Manual).


2.4.3 amhello’s Makefile.am Setup Explained

We now turn to src/Makefile.am. This file contains Automake instructions to build and install hello.

bin_PROGRAMS = hello
hello_SOURCES = main.c

A Makefile.am has the same syntax as an ordinary Makefile. When automake processes a Makefile.am it copies the entire file into the output Makefile.in (that will be later turned into Makefile by configure) but will react to certain variable definitions by generating some build rules and other variables. Often Makefile.ams contain only a list of variable definitions as above, but they can also contain other variable and rule definitions that automake will pass along without interpretation.

Variables that end with _PROGRAMS are special variables that list programs that the resulting Makefile should build. In Automake speak, this _PROGRAMS suffix is called a primary; Automake recognizes other primaries such as _SCRIPTS, _DATA, _LIBRARIES, etc. corresponding to different types of files.

The ‘bin’ part of the bin_PROGRAMS tells automake that the resulting programs should be installed in bindir. Recall that the GNU Build System uses a set of variables to denote destination directories and allow users to customize these locations (see Standard Directory Variables). Any such directory variable can be put in front of a primary (omitting the dir suffix) to tell automake where to install the listed files.

Programs need to be built from source files, so for each program prog listed in a _PROGRAMS variable, automake will look for another variable named prog_SOURCES listing its source files. There may be more than one source file: they will all be compiled and linked together.

Automake also knows that source files need to be distributed when creating a tarball (unlike built programs). So a side-effect of this hello_SOURCES declaration is that main.c will be part of the tarball created by make dist.

Finally here are some explanations regarding the top-level Makefile.am.

SUBDIRS = src
dist_doc_DATA = README

SUBDIRS is a special variable listing all directories that make should recurse into before processing the current directory. So this line is responsible for make building src/hello even though we run it from the top-level. This line also causes make install to install src/hello before installing README (not that this order matters).

The line dist_doc_DATA = README causes README to be distributed and installed in docdir. Files listed with the _DATA primary are not automatically part of the tarball built with make dist, so we add the dist_ prefix so they get distributed. However, for README it would not have been necessary: automake automatically distributes any README file it encounters (the list of other files automatically distributed is presented by automake --help). The only important effect of this second line is therefore to install README during make install.

One thing not covered in this example is accessing the installation directory values (see Standard Directory Variables) from your program code, that is, converting them into defined macros. For this, see Defining Directories in The Autoconf Manual.


3 General ideas

The following sections cover a few basic ideas that will help you understand how Automake works.


3.1 General Operation

Automake works by reading a Makefile.am and generating a Makefile.in. Certain variables and rules defined in the Makefile.am instruct Automake to generate more specialized code; for instance, a bin_PROGRAMS variable definition will cause rules for compiling and linking programs to be generated.

The variable definitions and rules in the Makefile.am are copied mostly verbatim into the generated file, with all variable definitions preceding all rules. This allows you to add almost arbitrary code into the generated Makefile.in. For instance, the Automake distribution includes a non-standard rule for the git-dist target, which the Automake maintainer uses to make distributions from the source control system.

Note that most GNU make extensions are not recognized by Automake. Using such extensions in a Makefile.am will lead to errors or confusing behavior.

A special exception is that the GNU make append operator, ‘+=’, is supported. This operator appends its right hand argument to the variable specified on the left. Automake will translate the operator into an ordinary ‘=’ operator; ‘+=’ will thus work with any make program.

Automake tries to keep comments grouped with any adjoining rules or variable definitions.

Generally, Automake is not particularly smart in the parsing of unusual Makefile constructs, so you’re advised to avoid fancy constructs or “creative” use of whitespace. For example, TAB characters cannot be used between a target name and the following “:” character, and variable assignments shouldn’t be indented with TAB characters. Also, using more complex macro in target names can cause trouble:

% cat Makefile.am
$(FOO:=x): bar
% automake
Makefile.am:1: bad characters in variable name '$(FOO'
Makefile.am:1: ':='-style assignments are not portable

A rule defined in Makefile.am generally overrides any such rule of a similar name that would be automatically generated by automake. Although this is a supported feature, it is generally best to avoid making use of it, as sometimes the generated rules are very particular.

Similarly, a variable defined in Makefile.am or AC_SUBSTed from configure.ac will override any definition of the variable that automake would ordinarily create. This feature is more often useful than the ability to override a rule. Be warned that many of the variables generated by automake are considered to be for internal use only, and their names might change in future releases.

When examining a variable definition, Automake will recursively examine variables referenced in the definition. For example, if Automake is looking at the content of foo_SOURCES in this snippet

xs = a.c b.c
foo_SOURCES = c.c $(xs)

it would use the files a.c, b.c, and c.c as the contents of foo_SOURCES.

Automake also allows a form of comment that is not copied into the output; all lines beginning with ‘##’ (leading spaces allowed) are completely ignored by Automake.

It is customary to make the first line of Makefile.am read:

## Process this file with automake to produce Makefile.in

3.2 Strictness

While Automake is intended to be used by maintainers of GNU packages, it does make some effort to accommodate those who wish to use it, but do not want to use all the GNU conventions.

To this end, Automake supports three levels of strictness—the strictness indicating how stringently Automake should check standards conformance.

The valid strictness levels are:

foreign

Automake will check for only those things that are absolutely required for proper operations. For instance, whereas GNU standards dictate the existence of a NEWS file, it will not be required in this mode. This strictness will also turn off some warnings by default (among them, portability warnings). The name comes from the fact that Automake is intended to be used for GNU programs; these relaxed rules are not the standard mode of operation.

gnu

Automake will check—as much as possible—for compliance to the GNU standards for packages. This is the default.

gnits

Automake will check for compliance to the as-yet-unwritten Gnits standards. These are based on the GNU standards, but are even more detailed. Unless you are a Gnits standards contributor, it is recommended that you avoid this option until such time as the Gnits standard is actually published (which may never happen).

See The effect of --gnu and --gnits, for more information on the precise implications of the strictness level.


3.3 The Uniform Naming Scheme

Automake variables generally follow a uniform naming scheme that makes it easy to decide how programs (and other derived objects) are built, and how they are installed. This scheme also supports configure time determination of what should be built.

At make time, certain variables are used to determine which objects are to be built. The variable names are made of several pieces that are concatenated together.

The piece that tells automake what is being built is commonly called the primary. For instance, the primary PROGRAMS holds a list of programs that are to be compiled and linked.

A different set of names is used to decide where the built objects should be installed. These names are prefixes to the primary, and they indicate which standard directory should be used as the installation directory. The standard directory names are given in the GNU standards (see Directory Variables in The GNU Coding Standards). Automake extends this list with pkgdatadir, pkgincludedir, pkglibdir, and pkglibexecdir; these are the same as the non-‘pkg’ versions, but with ‘$(PACKAGE)’ appended. For instance, pkglibdir is defined as ‘$(libdir)/$(PACKAGE)’.

For each primary, there is one additional variable named by prepending ‘EXTRA_’ to the primary name. This variable is used to list objects that may or may not be built, depending on what configure decides. This variable is required because Automake must statically know the entire list of objects that may be built in order to generate a Makefile.in that will work in all cases.

For instance, cpio decides at configure time which programs should be built. Some of the programs are installed in bindir, and some are installed in sbindir:

EXTRA_PROGRAMS = mt rmt
bin_PROGRAMS = cpio pax
sbin_PROGRAMS = $(MORE_PROGRAMS)

Defining a primary without a prefix as a variable, e.g., ‘PROGRAMS’, is an error.

Note that the common ‘dir’ suffix is left off when constructing the variable names; thus one writes ‘bin_PROGRAMS’ and not ‘bindir_PROGRAMS’.

Not every sort of object can be installed in every directory. Automake will flag those attempts it finds in error (but see below how to override the check if you really need to). Automake will also diagnose obvious misspellings in directory names.

Sometimes the standard directories—even as augmented by Automake—are not enough. In particular it is sometimes useful, for clarity, to install objects in a subdirectory of some predefined directory. To this end, Automake allows you to extend the list of possible installation directories. A given prefix (e.g., ‘zar’) is valid if a variable of the same name with ‘dir’ appended is defined (e.g., ‘zardir’).

For instance, the following snippet will install file.xml into ‘$(datadir)/xml’.

xmldir = $(datadir)/xml
xml_DATA = file.xml

This feature can also be used to override the sanity checks Automake performs to diagnose suspicious directory/primary couples (in the unlikely case these checks are undesirable, and you really know what you’re doing). For example, Automake would error out on this input:

# Forbidden directory combinations, automake will error out on this.
pkglib_PROGRAMS = foo
doc_LIBRARIES = libquux.a

but it will succeed with this:

# Work around forbidden directory combinations.  Do not use this
# without a very good reason!
my_execbindir = $(pkglibdir)
my_doclibdir = $(docdir)
my_execbin_PROGRAMS = foo
my_doclib_LIBRARIES = libquux.a

The ‘exec’ substring of the ‘my_execbindir’ variable lets the files be installed at the right time (see The Two Parts of Install).

The special prefix ‘noinst_’ indicates that the objects in question should be built but not installed at all. This is usually used for objects required to build the rest of your package, for instance static libraries (see Building a library), or helper scripts.

The special prefix ‘check_’ indicates that the objects in question should not be built until the ‘make check’ command is run. Those objects are not installed either.

The current primary names are ‘PROGRAMS’, ‘LIBRARIES’, ‘LTLIBRARIES’, ‘LISP’, ‘PYTHON’, ‘JAVA’, ‘SCRIPTS’, ‘DATA’, ‘HEADERS’, ‘MANS’, and ‘TEXINFOS’.

Some primaries also allow additional prefixes that control other aspects of automake’s behavior. The currently defined prefixes are ‘dist_’, ‘nodist_’, ‘nobase_’, and ‘notrans_’. These prefixes are explained later (see Program and Library Variables) (see Man Pages).


3.4 Staying below the command line length limit

Traditionally, most unix-like systems have a length limitation for the command line arguments and environment contents when creating new processes (see for example http://www.in-ulm.de/~mascheck/various/argmax/ for an overview on this issue), which of course also applies to commands spawned by make. POSIX requires this limit to be at least 4096 bytes, and most modern systems have quite high limits (or are unlimited).

In order to create portable Makefiles that do not trip over these limits, it is necessary to keep the length of file lists bounded. Unfortunately, it is not possible to do so fully transparently within Automake, so your help may be needed. Typically, you can split long file lists manually and use different installation directory names for each list. For example,

data_DATA = file1 … fileN fileN+1 … file2N

may also be written as

data_DATA = file1 … fileN
data2dir = $(datadir)
data2_DATA = fileN+1 … file2N

and will cause Automake to treat the two lists separately during make install. See The Two Parts of Install for choosing directory names that will keep the ordering of the two parts of installation Note that make dist may still only work on a host with a higher length limit in this example.

Automake itself employs a couple of strategies to avoid long command lines. For example, when ‘${srcdir}/’ is prepended to file names, as can happen with above $(data_DATA) lists, it limits the amount of arguments passed to external commands.

Unfortunately, some system’s make commands may prepend VPATH prefixes like ‘${srcdir}/’ to file names from the source tree automatically (see Automatic Rule Rewriting in The Autoconf Manual). In this case, the user may have to switch to use GNU Make, or refrain from using VPATH builds, in order to stay below the length limit.

For libraries and programs built from many sources, convenience archives may be used as intermediates in order to limit the object list length (see Libtool Convenience Libraries).


3.5 How derived variables are named

Sometimes a Makefile variable name is derived from some text the maintainer supplies. For instance, a program name listed in ‘_PROGRAMS’ is rewritten into the name of a ‘_SOURCES’ variable. In cases like this, Automake canonicalizes the text, so that program names and the like do not have to follow Makefile variable naming rules. All characters in the name except for letters, numbers, the strudel (@), and the underscore are turned into underscores when making variable references.

For example, if your program is named sniff-glue, the derived variable name would be ‘sniff_glue_SOURCES’, not ‘sniff-glue_SOURCES’. Similarly the sources for a library named libmumble++.a should be listed in the ‘libmumble___a_SOURCES’ variable.

The strudel is an addition, to make the use of Autoconf substitutions in variable names less obfuscating.


3.6 Variables reserved for the user

Some Makefile variables are reserved by the GNU Coding Standards for the use of the “user”—the person building the package. For instance, CFLAGS is one such variable.

Sometimes package developers are tempted to set user variables such as CFLAGS because it appears to make their job easier. However, the package itself should never set a user variable, particularly not to include switches that are required for proper compilation of the package. Since these variables are documented as being for the package builder, that person rightfully expects to be able to override any of these variables at build time.

To get around this problem, Automake introduces an automake-specific shadow variable for each user flag variable. (Shadow variables are not introduced for variables like CC, where they would make no sense.) The shadow variable is named by prepending ‘AM_’ to the user variable’s name. For instance, the shadow variable for YFLAGS is AM_YFLAGS. The package maintainer—that is, the author(s) of the Makefile.am and configure.ac files—may adjust these shadow variables however necessary.

See Flag Variables Ordering, for more discussion about these variables and how they interact with per-target variables.


3.7 Programs automake might require

Automake sometimes requires helper programs so that the generated Makefile can do its work properly. There are a fairly large number of them, and we list them here.

Although all of these files are distributed and installed with Automake, a couple of them are maintained separately. The Automake copies are updated before each release, but we mention the original source in case you need more recent versions.

ar-lib

This is a wrapper primarily for the Microsoft lib archiver, to make it more POSIX-like.

compile

This is a wrapper for compilers that do not accept options -c and -o at the same time. It is only used when absolutely required. Such compilers are rare, with the Microsoft C/C++ Compiler as the most notable exception. This wrapper also makes the following common options available for that compiler, while performing file name translation where needed: -I, -L, -l, -Wl, and -Xlinker.

config.guess
config.sub

These two programs compute the canonical triplets for the given build, host, or target architecture. These programs are updated regularly to support new architectures and fix probes broken by changes in new kernel versions. Each new release of Automake comes with up-to-date copies of these programs. If your copy of Automake is getting old, you are encouraged to fetch the latest versions of these files from http://savannah.gnu.org/git/?group=config before making a release.

depcomp

This program understands how to run a compiler so that it will generate not only the desired output but also dependency information that is then used by the automatic dependency tracking feature (see Automatic dependency tracking).

install-sh

This is a replacement for the install program that works on platforms where install is unavailable or unusable.

mdate-sh

This script is used to generate a version.texi file. It examines a file and prints some date information about it.

missing

This wraps a number of programs that are typically only required by maintainers. If the program in question doesn’t exist, or seems to old, missing will print an informative warning before failing out, to provide the user with more context and information.

mkinstalldirs

This script used to be a wrapper around ‘mkdir -p’, which is not portable. Now we prefer to use ‘install-sh -d’ when configure finds that ‘mkdir -p’ does not work, this makes one less script to distribute.

For backward compatibility mkinstalldirs is still used and distributed when automake finds it in a package. But it is no longer installed automatically, and it should be safe to remove it.

py-compile

This is used to byte-compile Python scripts.

test-driver

This implements the default test driver offered by the parallel testsuite harness.

texinfo.tex

Not a program, this file is required for ‘make dvi’, ‘make ps’ and ‘make pdf’ to work when Texinfo sources are in the package. The latest version can be downloaded from http://www.gnu.org/software/texinfo/.

ylwrap

This program wraps lex and yacc to rename their output files. It also ensures that, for instance, multiple yacc instances can be invoked in a single directory in parallel.


4 Some example packages

This section contains two small examples.

The first example (see A simple example, start to finish) assumes you have an existing project already using Autoconf, with handcrafted Makefiles, and that you want to convert it to using Automake. If you are discovering both tools, it is probably better that you look at the Hello World example presented earlier (see A Small Hello World).

The second example (see Building true and false) shows how two programs can be built from the same file, using different compilation parameters. It contains some technical digressions that are probably best skipped on first read.


4.1 A simple example, start to finish

Let’s suppose you just finished writing zardoz, a program to make your head float from vortex to vortex. You’ve been using Autoconf to provide a portability framework, but your Makefile.ins have been ad-hoc. You want to make them bulletproof, so you turn to Automake.

The first step is to update your configure.ac to include the commands that automake needs. The way to do this is to add an AM_INIT_AUTOMAKE call just after AC_INIT:

AC_INIT([zardoz], [1.0])
AM_INIT_AUTOMAKE
…

Since your program doesn’t have any complicating factors (e.g., it doesn’t use gettext, it doesn’t want to build a shared library), you’re done with this part. That was easy!

Now you must regenerate configure. But to do that, you’ll need to tell autoconf how to find the new macro you’ve used. The easiest way to do this is to use the aclocal program to generate your aclocal.m4 for you. But wait… maybe you already have an aclocal.m4, because you had to write some hairy macros for your program. The aclocal program lets you put your own macros into acinclude.m4, so simply rename and then run:

mv aclocal.m4 acinclude.m4
aclocal
autoconf

Now it is time to write your Makefile.am for zardoz. Since zardoz is a user program, you want to install it where the rest of the user programs go: bindir. Additionally, zardoz has some Texinfo documentation. Your configure.ac script uses AC_REPLACE_FUNCS, so you need to link against ‘$(LIBOBJS)’. So here’s what you’d write:

bin_PROGRAMS = zardoz
zardoz_SOURCES = main.c head.c float.c vortex9.c gun.c
zardoz_LDADD = $(LIBOBJS)

info_TEXINFOS = zardoz.texi

Now you can run ‘automake --add-missing’ to generate your Makefile.in and grab any auxiliary files you might need, and you’re done!


4.2 Building true and false

Here is another, trickier example. It shows how to generate two programs (true and false) from the same source file (true.c). The difficult part is that each compilation of true.c requires different cpp flags.

bin_PROGRAMS = true false
false_SOURCES =
false_LDADD = false.o

true.o: true.c
        $(COMPILE) -DEXIT_CODE=0 -c true.c

false.o: true.c
        $(COMPILE) -DEXIT_CODE=1 -o false.o -c true.c

Note that there is no true_SOURCES definition. Automake will implicitly assume that there is a source file named true.c (see Default _SOURCES), and define rules to compile true.o and link true. The ‘true.o: true.c’ rule supplied by the above Makefile.am, will override the Automake generated rule to build true.o.

false_SOURCES is defined to be empty—that way no implicit value is substituted. Because we have not listed the source of false, we have to tell Automake how to link the program. This is the purpose of the false_LDADD line. A false_DEPENDENCIES variable, holding the dependencies of the false target will be automatically generated by Automake from the content of false_LDADD.

The above rules won’t work if your compiler doesn’t accept both -c and -o. The simplest fix for this is to introduce a bogus dependency (to avoid problems with a parallel make):

true.o: true.c false.o
        $(COMPILE) -DEXIT_CODE=0 -c true.c

false.o: true.c
        $(COMPILE) -DEXIT_CODE=1 -c true.c && mv true.o false.o

As it turns out, there is also a much easier way to do this same task. Some of the above technique is useful enough that we’ve kept the example in the manual. However if you were to build true and false in real life, you would probably use per-program compilation flags, like so:

bin_PROGRAMS = false true

false_SOURCES = true.c
false_CPPFLAGS = -DEXIT_CODE=1

true_SOURCES = true.c
true_CPPFLAGS = -DEXIT_CODE=0

In this case Automake will cause true.c to be compiled twice, with different flags. In this instance, the names of the object files would be chosen by automake; they would be false-true.o and true-true.o. (The name of the object files rarely matters.)


5 Creating a Makefile.in

To create all the Makefile.ins for a package, run the automake program in the top level directory, with no arguments. automake will automatically find each appropriate Makefile.am (by scanning configure.ac; see Scanning configure.ac, using aclocal) and generate the corresponding Makefile.in. Note that automake has a rather simplistic view of what constitutes a package; it assumes that a package has only one configure.ac, at the top. If your package has multiple configure.acs, then you must run automake in each directory holding a configure.ac. (Alternatively, you may rely on Autoconf’s autoreconf, which is able to recurse your package tree and run automake where appropriate.)

You can optionally give automake an argument; .am is appended to the argument and the result is used as the name of the input file. This feature is generally only used to automatically rebuild an out-of-date Makefile.in. Note that automake must always be run from the topmost directory of a project, even if being used to regenerate the Makefile.in in some subdirectory. This is necessary because automake must scan configure.ac, and because automake uses the knowledge that a Makefile.in is in a subdirectory to change its behavior in some cases.

Automake will run autoconf to scan configure.ac and its dependencies (i.e., aclocal.m4 and any included file), therefore autoconf must be in your PATH. If there is an AUTOCONF variable in your environment it will be used instead of autoconf, this allows you to select a particular version of Autoconf. By the way, don’t misunderstand this paragraph: automake runs autoconf to scan your configure.ac, this won’t build configure and you still have to run autoconf yourself for this purpose.

automake accepts the following options:

-a
--add-missing

Automake requires certain common files to exist in certain situations; for instance, config.guess is required if configure.ac invokes AC_CANONICAL_HOST. Automake is distributed with several of these files (see Programs automake might require); this option will cause the missing ones to be automatically added to the package, whenever possible. In general if Automake tells you a file is missing, try using this option. By default Automake tries to make a symbolic link pointing to its own copy of the missing file; this can be changed with --copy.

Many of the potentially-missing files are common scripts whose location may be specified via the AC_CONFIG_AUX_DIR macro. Therefore, AC_CONFIG_AUX_DIR’s setting affects whether a file is considered missing, and where the missing file is added (see Other things Automake recognizes).

In some strictness modes, additional files are installed, see The effect of --gnu and --gnits for more information.

--libdir=dir

Look for Automake data files in directory dir instead of in the installation directory. This is typically used for debugging.

--print-libdir

Print the path of the installation directory containing Automake-provided scripts and data files (like e.g., texinfo.texi and install-sh).

-c
--copy

When used with --add-missing, causes installed files to be copied. The default is to make a symbolic link.

-f
--force-missing

When used with --add-missing, causes standard files to be reinstalled even if they already exist in the source tree. This involves removing the file from the source tree before creating the new symlink (or, with --copy, copying the new file).

--foreign

Set the global strictness to foreign. For more information, see Strictness.

--gnits

Set the global strictness to gnits. For more information, see The effect of --gnu and --gnits.

--gnu

Set the global strictness to gnu. For more information, see The effect of --gnu and --gnits. This is the default strictness.

--help

Print a summary of the command line options and exit.

-i
--ignore-deps

This disables the dependency tracking feature in generated Makefiles; see Automatic dependency tracking.

--include-deps

This enables the dependency tracking feature. This feature is enabled by default. This option is provided for historical reasons only and probably should not be used.

--no-force

Ordinarily automake creates all Makefile.ins mentioned in configure.ac. This option causes it to only update those Makefile.ins that are out of date with respect to one of their dependents.

-o dir
--output-dir=dir

Put the generated Makefile.in in the directory dir. Ordinarily each Makefile.in is created in the directory of the corresponding Makefile.am. This option is deprecated and will be removed in a future release.

-v
--verbose

Cause Automake to print information about which files are being read or created.

--version

Print the version number of Automake and exit.

-W CATEGORY
--warnings=category

Output warnings falling in category. category can be one of:

gnu

warnings related to the GNU Coding Standards (see The GNU Coding Standards).

obsolete

obsolete features or constructions

override

user redefinitions of Automake rules or variables

portability

portability issues (e.g., use of make features that are known to be not portable)

extra-portability

extra portability issues related to obscure tools. One example of such a tool is the Microsoft lib archiver.

syntax

weird syntax, unused variables, typos

unsupported

unsupported or incomplete features

all

all the warnings

none

turn off all the warnings

error

treat warnings as errors

A category can be turned off by prefixing its name with ‘no-’. For instance, -Wno-syntax will hide the warnings about unused variables.

The categories output by default are ‘obsolete’, ‘syntax’ and ‘unsupported’. Additionally, ‘gnu’ and ‘portability’ are enabled in --gnu and --gnits strictness.

Turning off ‘portability’ will also turn off ‘extra-portability’, and similarly turning on ‘extra-portability’ will also turn on ‘portability’. However, turning on ‘portability’ or turning off ‘extra-portability’ will not affect the other category.

The environment variable WARNINGS can contain a comma separated list of categories to enable. It will be taken into account before the command-line switches, this way -Wnone will also ignore any warning category enabled by WARNINGS. This variable is also used by other tools like autoconf; unknown categories are ignored for this reason.

If the environment variable AUTOMAKE_JOBS contains a positive number, it is taken as the maximum number of Perl threads to use in automake for generating multiple Makefile.in files concurrently. This is an experimental feature.


6 Scanning configure.ac, using aclocal

Automake scans the package’s configure.ac to determine certain information about the package. Some autoconf macros are required and some variables must be defined in configure.ac. Automake will also use information from configure.ac to further tailor its output.

Automake also supplies some Autoconf macros to make the maintenance easier. These macros can automatically be put into your aclocal.m4 using the aclocal program.


6.1 Configuration requirements

The one real requirement of Automake is that your configure.ac call AM_INIT_AUTOMAKE. This macro does several things that are required for proper Automake operation (see Autoconf macros supplied with Automake).

Here are the other macros that Automake requires but which are not run by AM_INIT_AUTOMAKE:

AC_CONFIG_FILES
AC_OUTPUT

These two macros are usually invoked as follows near the end of configure.ac.

…
AC_CONFIG_FILES([
  Makefile
  doc/Makefile
  src/Makefile
  src/lib/Makefile
  …
])
AC_OUTPUT

Automake uses these to determine which files to create (see Creating Output Files in The Autoconf Manual). A listed file is considered to be an Automake generated Makefile if there exists a file with the same name and the .am extension appended. Typically, ‘AC_CONFIG_FILES([foo/Makefile])’ will cause Automake to generate foo/Makefile.in if foo/Makefile.am exists.

When using AC_CONFIG_FILES with multiple input files, as in

AC_CONFIG_FILES([Makefile:top.in:Makefile.in:bot.in])

automake will generate the first .in input file for which a .am file exists. If no such file exists the output file is not considered to be generated by Automake.

Files created by AC_CONFIG_FILES, be they Automake Makefiles or not, are all removed by ‘make distclean’. Their inputs are automatically distributed, unless they are the output of prior AC_CONFIG_FILES commands. Finally, rebuild rules are generated in the Automake Makefile existing in the subdirectory of the output file, if there is one, or in the top-level Makefile otherwise.

The above machinery (cleaning, distributing, and rebuilding) works fine if the AC_CONFIG_FILES specifications contain only literals. If part of the specification uses shell variables, automake will not be able to fulfill this setup, and you will have to complete the missing bits by hand. For instance, on

file=input
…
AC_CONFIG_FILES([output:$file],, [file=$file])

automake will output rules to clean output, and rebuild it. However the rebuild rule will not depend on input, and this file will not be distributed either. (You must add ‘EXTRA_DIST = input’ to your Makefile.am if input is a source file.)

Similarly

file=output
file2=out:in
…
AC_CONFIG_FILES([$file:input],, [file=$file])
AC_CONFIG_FILES([$file2],, [file2=$file2])

will only cause input to be distributed. No file will be cleaned automatically (add ‘DISTCLEANFILES = output out’ yourself), and no rebuild rule will be output.

Obviously automake cannot guess what value ‘$file’ is going to hold later when configure is run, and it cannot use the shell variable ‘$file’ in a Makefile. However, if you make reference to ‘$file’ as ‘${file}’ (i.e., in a way that is compatible with make’s syntax) and furthermore use AC_SUBST to ensure that ‘${file}’ is meaningful in a Makefile, then automake will be able to use ‘${file}’ to generate all of these rules. For instance, here is how the Automake package itself generates versioned scripts for its test suite:

AC_SUBST([APIVERSION], …)
…
AC_CONFIG_FILES(
  [tests/aclocal-${APIVERSION}:tests/aclocal.in],
  [chmod +x tests/aclocal-${APIVERSION}],
  [APIVERSION=$APIVERSION])
AC_CONFIG_FILES(
  [tests/automake-${APIVERSION}:tests/automake.in],
  [chmod +x tests/automake-${APIVERSION}])

Here cleaning, distributing, and rebuilding are done automatically, because ‘${APIVERSION}’ is known at make-time.

Note that you should not use shell variables to declare Makefile files for which automake must create Makefile.in. Even AC_SUBST does not help here, because automake needs to know the file name when it runs in order to check whether Makefile.am exists. (In the very hairy case that your setup requires such use of variables, you will have to tell Automake which Makefile.ins to generate on the command-line.)

It is possible to let automake emit conditional rules for AC_CONFIG_FILES with the help of AM_COND_IF (see Other things Automake recognizes).

To summarize:

  • Use literals for Makefiles, and for other files whenever possible.
  • Use ‘$file’ (or ‘${file}’ without ‘AC_SUBST([file])’) for files that automake should ignore.
  • Use ‘${file}’ and ‘AC_SUBST([file])’ for files that automake should not ignore.

6.2 Other things Automake recognizes

Every time Automake is run it calls Autoconf to trace configure.ac. This way it can recognize the use of certain macros and tailor the generated Makefile.in appropriately. Currently recognized macros and their effects are:

AC_CANONICAL_BUILD
AC_CANONICAL_HOST
AC_CANONICAL_TARGET

Automake will ensure that config.guess and config.sub exist. Also, the Makefile variables build_triplet, host_triplet and target_triplet are introduced. See Getting the Canonical System Type in The Autoconf Manual.

AC_CONFIG_AUX_DIR

Automake will look for various helper scripts, such as install-sh, in the directory named in this macro invocation. (The full list of scripts is: ar-lib, config.guess, config.sub, depcomp, compile, install-sh, ltmain.sh, mdate-sh, missing, mkinstalldirs, py-compile, test-driver, texinfo.tex, ylwrap.) Not all scripts are always searched for; some scripts will only be sought if the generated Makefile.in requires them.

If AC_CONFIG_AUX_DIR is not given, the scripts are looked for in their standard locations. For mdate-sh, texinfo.tex, and ylwrap, the standard location is the source directory corresponding to the current Makefile.am. For the rest, the standard location is the first one of ., .., or ../.. (relative to the top source directory) that provides any one of the helper scripts. See Finding ‘configure’ Input in The Autoconf Manual.

Required files from AC_CONFIG_AUX_DIR are automatically distributed, even if there is no Makefile.am in this directory.

AC_CONFIG_LIBOBJ_DIR

Automake will require the sources file declared with AC_LIBSOURCE (see below) in the directory specified by this macro.

AC_CONFIG_HEADERS

Automake will generate rules to rebuild these headers from the corresponding templates (usually, the template for a foo.h header being foo.h.in). Older versions of Automake required the use of AM_CONFIG_HEADER; this is no longer the case, and that macro has indeed been removed.

As with AC_CONFIG_FILES (see Configuration requirements), parts of the specification using shell variables will be ignored as far as cleaning, distributing, and rebuilding is concerned.

Automake will generate rules to remove configure generated links on ‘make distclean’ and to distribute named source files as part of ‘make dist’.

As for AC_CONFIG_FILES (see Configuration requirements), parts of the specification using shell variables will be ignored as far as cleaning and distributing is concerned. (There are no rebuild rules for links.)

AC_LIBOBJ
AC_LIBSOURCE
AC_LIBSOURCES

Automake will automatically distribute any file listed in AC_LIBSOURCE or AC_LIBSOURCES.

Note that the AC_LIBOBJ macro calls AC_LIBSOURCE. So if an Autoconf macro is documented to call ‘AC_LIBOBJ([file])’, then file.c will be distributed automatically by Automake. This encompasses many macros like AC_FUNC_ALLOCA, AC_FUNC_MEMCMP, AC_REPLACE_FUNCS, and others.

By the way, direct assignments to LIBOBJS are no longer supported. You should always use AC_LIBOBJ for this purpose. See AC_LIBOBJ vs. LIBOBJS in The Autoconf Manual.

AC_PROG_RANLIB

This is required if any libraries are built in the package. See Particular Program Checks in The Autoconf Manual.

AC_PROG_CXX

This is required if any C++ source is included. See Particular Program Checks in The Autoconf Manual.

AC_PROG_OBJC

This is required if any Objective C source is included. See Particular Program Checks in The Autoconf Manual.

AC_PROG_OBJCXX

This is required if any Objective C++ source is included. See Particular Program Checks in The Autoconf Manual.

AC_PROG_F77

This is required if any Fortran 77 source is included. See Particular Program Checks in The Autoconf Manual.

AC_F77_LIBRARY_LDFLAGS

This is required for programs and shared libraries that are a mixture of languages that include Fortran 77 (see Mixing Fortran 77 With C and C++). See Autoconf macros supplied with Automake.

AC_FC_SRCEXT

Automake will add the flags computed by AC_FC_SRCEXT to compilation of files with the respective source extension (see Fortran Compiler Characteristics in The Autoconf Manual).

AC_PROG_FC

This is required if any Fortran 90/95 source is included. This macro is distributed with Autoconf version 2.58 and later. See Particular Program Checks in The Autoconf Manual.

AC_PROG_LIBTOOL

Automake will turn on processing for libtool (see Introduction in The Libtool Manual).

AC_PROG_YACC

If a Yacc source file is seen, then you must either use this macro or define the variable YACC in configure.ac. The former is preferred (see Particular Program Checks in The Autoconf Manual).

AC_PROG_LEX

If a Lex source file is seen, then this macro must be used. See Particular Program Checks in The Autoconf Manual.

AC_REQUIRE_AUX_FILE

For each AC_REQUIRE_AUX_FILE([file]), automake will ensure that file exists in the aux directory, and will complain otherwise. It will also automatically distribute the file. This macro should be used by third-party Autoconf macros that require some supporting files in the aux directory specified with AC_CONFIG_AUX_DIR above. See Finding configure Input in The Autoconf Manual.

AC_SUBST

The first argument is automatically defined as a variable in each generated Makefile.in, unless AM_SUBST_NOTMAKE is also used for this variable. See Setting Output Variables in The Autoconf Manual.

For every substituted variable var, automake will add a line var = value to each Makefile.in file. Many Autoconf macros invoke AC_SUBST to set output variables this way, e.g., AC_PATH_XTRA defines X_CFLAGS and X_LIBS. Thus, you can access these variables as $(X_CFLAGS) and $(X_LIBS) in any Makefile.am if AC_PATH_XTRA is called.

AM_CONDITIONAL

This introduces an Automake conditional (see Conditionals).

AM_COND_IF

This macro allows automake to detect subsequent access within configure.ac to a conditional previously introduced with AM_CONDITIONAL, thus enabling conditional AC_CONFIG_FILES (see Usage of Conditionals).

AM_GNU_GETTEXT

This macro is required for packages that use GNU gettext (see Gettext). It is distributed with gettext. If Automake sees this macro it ensures that the package meets some of gettext’s requirements.

AM_GNU_GETTEXT_INTL_SUBDIR

This macro specifies that the intl/ subdirectory is to be built, even if the AM_GNU_GETTEXT macro was invoked with a first argument of ‘external’.

AM_MAINTAINER_MODE([default-mode])

This macro adds an --enable-maintainer-mode option to configure. If this is used, automake will cause “maintainer-only” rules to be turned off by default in the generated Makefile.ins, unless default-mode is ‘enable’. This macro defines the MAINTAINER_MODE conditional, which you can use in your own Makefile.am. See missing and AM_MAINTAINER_MODE.

AM_SUBST_NOTMAKE(var)

Prevent Automake from defining a variable var, even if it is substituted by config.status. Normally, Automake defines a make variable for each configure substitution, i.e., for each AC_SUBST([var]). This macro prevents that definition from Automake. If AC_SUBST has not been called for this variable, then AM_SUBST_NOTMAKE has no effects. Preventing variable definitions may be useful for substitution of multi-line values, where var = @value@ might yield unintended results.

m4_include

Files included by configure.ac using this macro will be detected by Automake and automatically distributed. They will also appear as dependencies in Makefile rules.

m4_include is seldom used by configure.ac authors, but can appear in aclocal.m4 when aclocal detects that some required macros come from files local to your package (as opposed to macros installed in a system-wide directory, see Auto-generating aclocal.m4).


6.3 Auto-generating aclocal.m4

Automake includes a number of Autoconf macros that can be used in your package (see Autoconf macros supplied with Automake); some of them are actually required by Automake in certain situations. These macros must be defined in your aclocal.m4; otherwise they will not be seen by autoconf.

The aclocal program will automatically generate aclocal.m4 files based on the contents of configure.ac. This provides a convenient way to get Automake-provided macros, without having to search around. The aclocal mechanism allows other packages to supply their own macros (see Writing your own aclocal macros). You can also use it to maintain your own set of custom macros (see Handling Local Macros).

At startup, aclocal scans all the .m4 files it can find, looking for macro definitions (see Macro Search Path). Then it scans configure.ac. Any mention of one of the macros found in the first step causes that macro, and any macros it in turn requires, to be put into aclocal.m4.

Putting the file that contains the macro definition into aclocal.m4 is usually done by copying the entire text of this file, including unused macro definitions as well as both ‘#’ and ‘dnl’ comments. If you want to make a comment that will be completely ignored by aclocal, use ‘##’ as the comment leader.

When a file selected by aclocal is located in a subdirectory specified as a relative search path with aclocal’s -I argument, aclocal assumes the file belongs to the package and uses m4_include instead of copying it into aclocal.m4. This makes the package smaller, eases dependency tracking, and cause the file to be distributed automatically. (See Handling Local Macros, for an example.) Any macro that is found in a system-wide directory, or via an absolute search path will be copied. So use ‘-I `pwd`/reldir’ instead of ‘-I reldir’ whenever some relative directory should be considered outside the package.

The contents of acinclude.m4, if this file exists, are also automatically included in aclocal.m4. We recommend against using acinclude.m4 in new packages (see Handling Local Macros).

While computing aclocal.m4, aclocal runs autom4te (see Using Autom4te in The Autoconf Manual) in order to trace the macros that are really used, and omit from aclocal.m4 all macros that are mentioned but otherwise unexpanded (this can happen when a macro is called conditionally). autom4te is expected to be in the PATH, just as autoconf. Its location can be overridden using the AUTOM4TE environment variable.


6.3.1 aclocal Options

aclocal accepts the following options:

--automake-acdir=dir

Look for the automake-provided macro files in dir instead of in the installation directory. This is typically used for debugging.

--system-acdir=dir

Look for the system-wide third-party macro files (and the special dirlist file) in dir instead of in the installation directory. This is typically used for debugging.

--diff[=command]

Run command on M4 file that would be installed or overwritten by --install. The default command is ‘diff -u’. This option implies --install and --dry-run.

--dry-run

Do not actually overwrite (or create) aclocal.m4 and M4 files installed by --install.

--help

Print a summary of the command line options and exit.

-I dir

Add the directory dir to the list of directories searched for .m4 files.

--install

Install system-wide third-party macros into the first directory specified with ‘-I dir’ instead of copying them in the output file. Note that this will happen also if dir is an absolute path.

When this option is used, and only when this option is used, aclocal will also honor ‘#serial number’ lines that appear in macros: an M4 file is ignored if there exists another M4 file with the same basename and a greater serial number in the search path (see Serial Numbers).

--force

Always overwrite the output file. The default is to overwrite the output file only when really needed, i.e., when its contents changes or if one of its dependencies is younger.

This option forces the update of aclocal.m4 (or the file specified with --output below) and only this file, it has absolutely no influence on files that may need to be installed by --install.

--output=file

Cause the output to be put into file instead of aclocal.m4.

--print-ac-dir

Prints the name of the directory that aclocal will search to find third-party .m4 files. When this option is given, normal processing is suppressed. This option was used in the past by third-party packages to determine where to install .m4 macro files, but this usage is today discouraged, since it causes ‘$(prefix)’ not to be thoroughly honored (which violates the GNU Coding Standards), and a similar semantics can be better obtained with the ACLOCAL_PATH environment variable; see Writing your own aclocal macros.

--verbose

Print the names of the files it examines.

--version

Print the version number of Automake and exit.

-W CATEGORY
--warnings=category

Output warnings falling in category. category can be one of:

syntax

dubious syntactic constructs, underquoted macros, unused macros, etc.

unsupported

unknown macros

all

all the warnings, this is the default

none

turn off all the warnings

error

treat warnings as errors

All warnings are output by default.

The environment variable WARNINGS is honored in the same way as it is for automake (see Creating a Makefile.in).


6.3.2 Macro Search Path

By default, aclocal searches for .m4 files in the following directories, in this order:

acdir-APIVERSION

This is where the .m4 macros distributed with Automake itself are stored. APIVERSION depends on the Automake release used; for example, for Automake 1.11.x, APIVERSION = 1.11.

acdir

This directory is intended for third party .m4 files, and is configured when automake itself is built. This is @datadir@/aclocal/, which typically expands to ${prefix}/share/aclocal/. To find the compiled-in value of acdir, use the --print-ac-dir option (see aclocal Options).

As an example, suppose that automake-1.11.2 was configured with --prefix=/usr/local. Then, the search path would be:

  1. /usr/local/share/aclocal-1.11.2/
  2. /usr/local/share/aclocal/

The paths for the acdir and acdir-APIVERSION directories can be changed respectively through aclocal options --system-acdir and --automake-acdir (see aclocal Options). Note however that these options are only intended for use by the internal Automake test suite, or for debugging under highly unusual situations; they are not ordinarily needed by end-users.

As explained in (see aclocal Options), there are several options that can be used to change or extend this search path.

Modifying the Macro Search Path: ‘-I dir

Any extra directories specified using -I options (see aclocal Options) are prepended to this search list. Thus, ‘aclocal -I /foo -I /bar’ results in the following search path:

  1. /foo
  2. /bar
  3. acdir-APIVERSION
  4. acdir

Modifying the Macro Search Path: dirlist

There is a third mechanism for customizing the search path. If a dirlist file exists in acdir, then that file is assumed to contain a list of directory patterns, one per line. aclocal expands these patterns to directory names, and adds them to the search list after all other directories. dirlist entries may use shell wildcards such as ‘*’, ‘?’, or [...].

For example, suppose acdir/dirlist contains the following:

/test1
/test2
/test3*

and that aclocal was called with the ‘-I /foo -I /bar’ options. Then, the search path would be

  1. /foo
  2. /bar
  3. acdir-APIVERSION
  4. acdir
  5. /test1
  6. /test2

and all directories with path names starting with /test3.

If the --system-acdir=dir option is used, then aclocal will search for the dirlist file in dir; but remember the warnings above against the use of --system-acdir.

dirlist is useful in the following situation: suppose that automake version 1.11.2 is installed with ‘--prefix=/usr’ by the system vendor. Thus, the default search directories are

  1. /usr/share/aclocal-1.11/
  2. /usr/share/aclocal/

However, suppose further that many packages have been manually installed on the system, with $prefix=/usr/local, as is typical. In that case, many of these “extra” .m4 files are in /usr/local/share/aclocal. The only way to force /usr/bin/aclocal to find these “extra” .m4 files is to always call ‘aclocal -I /usr/local/share/aclocal’. This is inconvenient. With dirlist, one may create a file /usr/share/aclocal/dirlist containing only the single line

/usr/local/share/aclocal

Now, the “default” search path on the affected system is

  1. /usr/share/aclocal-1.11/
  2. /usr/share/aclocal/
  3. /usr/local/share/aclocal/

without the need for -I options; -I options can be reserved for project-specific needs (my-source-dir/m4/), rather than using it to work around local system-dependent tool installation directories.

Similarly, dirlist can be handy if you have installed a local copy of Automake in your account and want aclocal to look for macros installed at other places on the system.

Modifying the Macro Search Path: ACLOCAL_PATH

The fourth and last mechanism to customize the macro search path is also the simplest. Any directory included in the colon-separated environment variable ACLOCAL_PATH is added to the search path and takes precedence over system directories (including those found via dirlist), with the exception of the versioned directory acdir-APIVERSION (see Macro Search Path). However, directories passed via -I will take precedence over directories in ACLOCAL_PATH.

Also note that, if the --install option is used, any .m4 file containing a required macro that is found in a directory listed in ACLOCAL_PATH will be installed locally. In this case, serial numbers in .m4 are honored too, see Serial Numbers.

Conversely to dirlist, ACLOCAL_PATH is useful if you are using a global copy of Automake and want aclocal to look for macros somewhere under your home directory.

Planned future incompatibilities

The order in which the directories in the macro search path are currently looked up is confusing and/or suboptimal in various aspects, and is probably going to be changed in the future Automake release. In particular, directories in ACLOCAL_PATH and acdir might end up taking precedence over acdir-APIVERSION, and directories in acdir/dirlist might end up taking precedence over acdir. This is a possible future incompatibility!


6.3.3 Writing your own aclocal macros

The aclocal program doesn’t have any built-in knowledge of any macros, so it is easy to extend it with your own macros.

This can be used by libraries that want to supply their own Autoconf macros for use by other programs. For instance, the gettext library supplies a macro AM_GNU_GETTEXT that should be used by any package using gettext. When the library is installed, it installs this macro so that aclocal will find it.

A macro file’s name should end in .m4. Such files should be installed in $(datadir)/aclocal. This is as simple as writing:

aclocaldir = $(datadir)/aclocal
aclocal_DATA = mymacro.m4 myothermacro.m4

Please do use $(datadir)/aclocal, and not something based on the result of ‘aclocal --print-ac-dir’ (see Installing to Hard-Coded Locations, for arguments). It might also be helpful to suggest to the user to add the $(datadir)/aclocal directory to his ACLOCAL_PATH variable (see ACLOCAL_PATH) so that aclocal will find the .m4 files installed by your package automatically.

A file of macros should be a series of properly quoted AC_DEFUN’s (see Macro Definitions in The Autoconf Manual). The aclocal programs also understands AC_REQUIRE (see Prerequisite Macros in The Autoconf Manual), so it is safe to put each macro in a separate file. Each file should have no side effects but macro definitions. Especially, any call to AC_PREREQ should be done inside the defined macro, not at the beginning of the file.

Starting with Automake 1.8, aclocal will warn about all underquoted calls to AC_DEFUN. We realize this will annoy a lot of people, because aclocal was not so strict in the past and many third party macros are underquoted; and we have to apologize for this temporary inconvenience. The reason we have to be stricter is that a future implementation of aclocal (see The Future of aclocal) will have to temporarily include all of these third party .m4 files, maybe several times, including even files that are not actually needed. Doing so should alleviate many problems of the current implementation, however it requires a stricter style from the macro authors. Hopefully it is easy to revise the existing macros. For instance,

# bad style
AC_PREREQ(2.68)
AC_DEFUN(AX_FOOBAR,
[AC_REQUIRE([AX_SOMETHING])dnl
AX_FOO
AX_BAR
])

should be rewritten as

AC_DEFUN([AX_FOOBAR],
[AC_PREREQ([2.68])dnl
AC_REQUIRE([AX_SOMETHING])dnl
AX_FOO
AX_BAR
])

Wrapping the AC_PREREQ call inside the macro ensures that Autoconf 2.68 will not be required if AX_FOOBAR is not actually used. Most importantly, quoting the first argument of AC_DEFUN allows the macro to be redefined or included twice (otherwise this first argument would be expanded during the second definition). For consistency we like to quote even arguments such as 2.68 that do not require it.

If you have been directed here by the aclocal diagnostic but are not the maintainer of the implicated macro, you will want to contact the maintainer of that macro. Please make sure you have the latest version of the macro and that the problem hasn’t already been reported before doing so: people tend to work faster when they aren’t flooded by mails.

Another situation where aclocal is commonly used is to manage macros that are used locally by the package, Handling Local Macros.


6.3.4 Handling Local Macros

Feature tests offered by Autoconf do not cover all needs. People often have to supplement existing tests with their own macros, or with third-party macros.

There are two ways to organize custom macros in a package.

The first possibility (the historical practice) is to list all your macros in acinclude.m4. This file will be included in aclocal.m4 when you run aclocal, and its macro(s) will henceforth be visible to autoconf. However if it contains numerous macros, it will rapidly become difficult to maintain, and it will be almost impossible to share macros between packages.

The second possibility, which we do recommend, is to write each macro in its own file and gather all these files in a directory. This directory is usually called m4/. Then it’s enough to update configure.ac by adding a proper call to AC_CONFIG_MACRO_DIRS:

AC_CONFIG_MACRO_DIRS([m4])

aclocal will then take care of automatically adding m4/ to its search path for m4 files.

When ‘aclocal’ is run, it will build an aclocal.m4 that m4_includes any file from m4/ that defines a required macro. Macros not found locally will still be searched in system-wide directories, as explained in Macro Search Path.

Custom macros should be distributed for the same reason that configure.ac is: so that other people have all the sources of your package if they want to work on it. Actually, this distribution happens automatically because all m4_included files are distributed.

However there is no consensus on the distribution of third-party macros that your package may use. Many libraries install their own macro in the system-wide aclocal directory (see Writing your own aclocal macros). For instance, Guile ships with a file called guile.m4 that contains the macro GUILE_FLAGS that can be used to define setup compiler and linker flags appropriate for using Guile. Using GUILE_FLAGS in configure.ac will cause aclocal to copy guile.m4 into aclocal.m4, but as guile.m4 is not part of the project, it will not be distributed. Technically, that means a user who needs to rebuild aclocal.m4 will have to install Guile first. This is probably OK, if Guile already is a requirement to build the package. However, if Guile is only an optional feature, or if your package might run on architectures where Guile cannot be installed, this requirement will hinder development. An easy solution is to copy such third-party macros in your local m4/ directory so they get distributed.

Since Automake 1.10, aclocal offers the option --install to copy these system-wide third-party macros in your local macro directory, helping to solve the above problem.

With this setup, system-wide macros will be copied to m4/ the first time you run aclocal. Then the locally installed macros will have precedence over the system-wide installed macros each time aclocal is run again.

One reason why you should keep --install in the flags even after the first run is that when you later edit configure.ac and depend on a new macro, this macro will be installed in your m4/ automatically. Another one is that serial numbers (see Serial Numbers) can be used to update the macros in your source tree automatically when new system-wide versions are installed. A serial number should be a single line of the form

#serial nnn

where nnn contains only digits and dots. It should appear in the M4 file before any macro definition. It is a good practice to maintain a serial number for each macro you distribute, even if you do not use the --install option of aclocal: this allows other people to use it.


6.3.5 Serial Numbers

Because third-party macros defined in *.m4 files are naturally shared between multiple projects, some people like to version them. This makes it easier to tell which of two M4 files is newer. Since at least 1996, the tradition is to use a ‘#serial’ line for this.

A serial number should be a single line of the form

# serial version

where version is a version number containing only digits and dots. Usually people use a single integer, and they increment it each time they change the macro (hence the name of “serial”). Such a line should appear in the M4 file before any macro definition.

The ‘#’ must be the first character on the line, and it is OK to have extra words after the version, as in

#serial version garbage

Normally these serial numbers are completely ignored by aclocal and autoconf, like any genuine comment. However when using aclocal’s --install feature, these serial numbers will modify the way aclocal selects the macros to install in the package: if two files with the same basename exist in your search path, and if at least one of them uses a ‘#serial’ line, aclocal will ignore the file that has the older ‘#serial’ line (or the file that has none).

Note that a serial number applies to a whole M4 file, not to any macro it contains. A file can contains multiple macros, but only one serial.

Here is a use case that illustrates the use of --install and its interaction with serial numbers. Let’s assume we maintain a package called MyPackage, the configure.ac of which requires a third-party macro AX_THIRD_PARTY defined in /usr/share/aclocal/thirdparty.m4 as follows:

# serial 1
AC_DEFUN([AX_THIRD_PARTY], [...])

MyPackage uses an m4/ directory to store local macros as explained in Handling Local Macros, and has

AC_CONFIG_MACRO_DIRS([m4])

in its configure.ac.

Initially the m4/ directory is empty. The first time we run aclocal --install, it will notice that

  • configure.ac uses AX_THIRD_PARTY
  • No local macros define AX_THIRD_PARTY
  • /usr/share/aclocal/thirdparty.m4 defines AX_THIRD_PARTY with serial 1.

Because /usr/share/aclocal/thirdparty.m4 is a system-wide macro and aclocal was given the --install option, it will copy this file in m4/thirdparty.m4, and output an aclocal.m4 that contains ‘m4_include([m4/thirdparty.m4])’.

The next time ‘aclocal --install’ is run, something different happens. aclocal notices that

  • configure.ac uses AX_THIRD_PARTY
  • m4/thirdparty.m4 defines AX_THIRD_PARTY with serial 1.
  • /usr/share/aclocal/thirdparty.m4 defines AX_THIRD_PARTY with serial 1.

Because both files have the same serial number, aclocal uses the first it found in its search path order (see Macro Search Path). aclocal therefore ignores /usr/share/aclocal/thirdparty.m4 and outputs an aclocal.m4 that contains ‘m4_include([m4/thirdparty.m4])’.

Local directories specified with -I are always searched before system-wide directories, so a local file will always be preferred to the system-wide file in case of equal serial numbers.

Now suppose the system-wide third-party macro is changed. This can happen if the package installing this macro is updated. Let’s suppose the new macro has serial number 2. The next time ‘aclocal --install’ is run the situation is the following:

  • configure.ac uses AX_THIRD_PARTY
  • m4/thirdparty.m4 defines AX_THIRD_PARTY with serial 1.
  • /usr/share/aclocal/thirdparty.m4 defines AX_THIRD_PARTY with serial 2.

When aclocal sees a greater serial number, it immediately forgets anything it knows from files that have the same basename and a smaller serial number. So after it has found /usr/share/aclocal/thirdparty.m4 with serial 2, aclocal will proceed as if it had never seen m4/thirdparty.m4. This brings us back to a situation similar to that at the beginning of our example, where no local file defined the macro. aclocal will install the new version of the macro in m4/thirdparty.m4, in this case overriding the old version. MyPackage just had its macro updated as a side effect of running aclocal.

If you are leery of letting aclocal update your local macro, you can run ‘aclocal --diff’ to review the changes ‘aclocal --install’ would perform on these macros.

Finally, note that the --force option of aclocal has absolutely no effect on the files installed by --install. For instance, if you have modified your local macros, do not expect --install --force to replace the local macros by their system-wide versions. If you want to do so, simply erase the local macros you want to revert, and run ‘aclocal --install’.


6.3.6 The Future of aclocal

aclocal is expected to disappear. This feature really should not be offered by Automake. Automake should focus on generating Makefiles; dealing with M4 macros really is Autoconf’s job. The fact that some people install Automake just to use aclocal, but do not use automake otherwise is an indication of how that feature is misplaced.

The new implementation will probably be done slightly differently. For instance, it could enforce the m4/-style layout discussed in Handling Local Macros.

We have no idea when and how this will happen. This has been discussed several times in the past, but someone still has to commit to that non-trivial task.

From the user point of view, aclocal’s removal might turn out to be painful. There is a simple precaution that you may take to make that switch more seamless: never call aclocal yourself. Keep this guy under the exclusive control of autoreconf and Automake’s rebuild rules. Hopefully you won’t need to worry about things breaking, when aclocal disappears, because everything will have been taken care of. If otherwise you used to call aclocal directly yourself or from some script, you will quickly notice the change.

Many packages come with a script called bootstrap or autogen.sh, that will just call aclocal, libtoolize, gettextize or autopoint, autoconf, autoheader, and automake in the right order. Actually this is precisely what autoreconf can do for you. If your package has such a bootstrap or autogen.sh script, consider using autoreconf. That should simplify its logic a lot (less things to maintain, yum!), it’s even likely you will not need the script anymore, and more to the point you will not call aclocal directly anymore.

For the time being, third-party packages should continue to install public macros into /usr/share/aclocal/. If aclocal is replaced by another tool it might make sense to rename the directory, but supporting /usr/share/aclocal/ for backward compatibility should be really easy provided all macros are properly written (see Writing your own aclocal macros).


6.4 Autoconf macros supplied with Automake

Automake ships with several Autoconf macros that you can use from your configure.ac. When you use one of them it will be included by aclocal in aclocal.m4.


6.4.1 Public Macros

AM_INIT_AUTOMAKE([OPTIONS])

Runs many macros required for proper operation of the generated Makefiles.

Today, AM_INIT_AUTOMAKE is called with a single argument: a space-separated list of Automake options that should be applied to every Makefile.am in the tree. The effect is as if each option were listed in AUTOMAKE_OPTIONS (see Changing Automake’s Behavior).

This macro can also be called in another, deprecated form: AM_INIT_AUTOMAKE(PACKAGE, VERSION, [NO-DEFINE]). In this form, there are two required arguments: the package and the version number. This usage is mostly obsolete because the package and version can be obtained from Autoconf’s AC_INIT macro. However, differently from what happens for AC_INIT invocations, this AM_INIT_AUTOMAKE invocation supports shell variables’ expansions in the PACKAGE and VERSION arguments (which otherwise defaults, respectively, to the PACKAGE_TARNAME and PACKAGE_VERSION defined via the AC_INIT invocation; see The AC_INIT macro in The Autoconf Manual); and this can be still be useful in some selected situations. Our hope is that future Autoconf versions will improve their support for package versions defined dynamically at configure runtime; when (and if) this happens, support for the two-args AM_INIT_AUTOMAKE invocation will likely be removed from Automake.

If your configure.ac has:

AC_INIT([src/foo.c])
AM_INIT_AUTOMAKE([mumble], [1.5])

you should modernize it as follows:

AC_INIT([mumble], [1.5])
AC_CONFIG_SRCDIR([src/foo.c])
AM_INIT_AUTOMAKE

Note that if you’re upgrading your configure.ac from an earlier version of Automake, it is not always correct to simply move the package and version arguments from AM_INIT_AUTOMAKE directly to AC_INIT, as in the example above. The first argument to AC_INIT should be the name of your package (e.g., ‘GNU Automake’), not the tarball name (e.g., ‘automake’) that you used to pass to AM_INIT_AUTOMAKE. Autoconf tries to derive a tarball name from the package name, which should work for most but not all package names. (If it doesn’t work for yours, you can use the four-argument form of AC_INIT to provide the tarball name explicitly).

By default this macro AC_DEFINE’s PACKAGE and VERSION. This can be avoided by passing the no-define option (see List of Automake options):

AM_INIT_AUTOMAKE([no-define ...])
AM_PATH_LISPDIR

Searches for the program emacs, and, if found, sets the output variable lispdir to the full path to Emacs’ site-lisp directory.

Note that this test assumes the emacs found to be a version that supports Emacs Lisp (such as GNU Emacs or XEmacs). Other emacsen can cause this test to hang (some, like old versions of MicroEmacs, start up in interactive mode, requiring C-x C-c to exit, which is hardly obvious for a non-emacs user). In most cases, however, you should be able to use C-c to kill the test. In order to avoid problems, you can set EMACS to “no” in the environment, or use the --with-lispdir option to configure to explicitly set the correct path (if you’re sure you have an emacs that supports Emacs Lisp).

AM_PROG_AR([act-if-fail])

You must use this macro when you use the archiver in your project, if you want support for unusual archivers such as Microsoft lib. The content of the optional argument is executed if the archiver interface is not recognized; the default action is to abort configure with an error message.

AM_PROG_AS

Use this macro when you have assembly code in your project. This will choose the assembler for you (by default the C compiler) and set CCAS, and will also set CCASFLAGS if required.

AM_PROG_CC_C_O

This is an obsolescent macro that checks that the C compiler supports the -c and -o options together. Note that, since Automake 1.14, the AC_PROG_CC is rewritten to implement such checks itself, and thus the explicit use of AM_PROG_CC_C_O should no longer be required.

AM_PROG_LEX

Like AC_PROG_LEX (see Particular Program Checks in The Autoconf Manual), but uses the missing script on systems that do not have lex. HP-UX 10 is one such system.

AM_PROG_GCJ

This macro finds the gcj program or causes an error. It sets GCJ and GCJFLAGS. gcj is the Java front-end to the GNU Compiler Collection.

AM_PROG_UPC([compiler-search-list])

Find a compiler for Unified Parallel C and define the UPC variable. The default compiler-search-list is ‘upcc upc’. This macro will abort configure if no Unified Parallel C compiler is found.

AM_MISSING_PROG(name, program)

Find a maintainer tool program and define the name environment variable with its location. If program is not detected, then name will instead invoke the missing script, in order to give useful advice to the user about the missing maintainer tool. See missing and AM_MAINTAINER_MODE, for more information on when the missing script is appropriate.

AM_SILENT_RULES

Control the machinery for less verbose build output (see How Automake can help in silencing make).

AM_WITH_DMALLOC

Add support for the Dmalloc package. If the user runs configure with --with-dmalloc, then define WITH_DMALLOC and add -ldmalloc to LIBS.


6.4.2 Obsolete Macros

Although using some of the following macros was required in past releases, you should not use any of them in new code. All these macros will be removed in the next major Automake version; if you are still using them, running autoupdate should adjust your configure.ac automatically (see Using autoupdate to Modernize configure.ac in The Autoconf Manual). Do it NOW!

AM_PROG_MKDIR_P

From Automake 1.8 to 1.9.6 this macro used to define the output variable mkdir_p to one of mkdir -p, install-sh -d, or mkinstalldirs.

Nowadays Autoconf provides a similar functionality with AC_PROG_MKDIR_P (see Particular Program Checks in The Autoconf Manual), however this defines the output variable MKDIR_P instead. In case you are still using the AM_PROG_MKDIR_P macro in your configure.ac, or its provided variable $(mkdir_p) in your Makefile.am, you are advised to switch ASAP to the more modern Autoconf-provided interface instead; both the macro and the variable might be removed in a future major Automake release.


6.4.3 Private Macros

The following macros are private macros you should not call directly. They are called by the other public macros when appropriate. Do not rely on them, as they might be changed in a future version. Consider them as implementation details; or better, do not consider them at all: skip this section!

_AM_DEPENDENCIES
AM_SET_DEPDIR
AM_DEP_TRACK
AM_OUTPUT_DEPENDENCY_COMMANDS

These macros are used to implement Automake’s automatic dependency tracking scheme. They are called automatically by Automake when required, and there should be no need to invoke them manually.

AM_MAKE_INCLUDE

This macro is used to discover how the user’s make handles include statements. This macro is automatically invoked when needed; there should be no need to invoke it manually.

AM_PROG_INSTALL_STRIP

This is used to find a version of install that can be used to strip a program at installation time. This macro is automatically included when required.

AM_SANITY_CHECK

This checks to make sure that a file created in the build directory is newer than a file in the source directory. This can fail on systems where the clock is set incorrectly. This macro is automatically run from AM_INIT_AUTOMAKE.


7 Directories

For simple projects that distribute all files in the same directory it is enough to have a single Makefile.am that builds everything in place.

In larger projects, it is common to organize files in different directories, in a tree. For example, there could be a directory for the program’s source, one for the testsuite, and one for the documentation; or, for very large projects, there could be one directory per program, per library or per module.

The traditional approach is to build these subdirectories recursively, employing make recursion: each directory contains its own Makefile, and when make is run from the top-level directory, it enters each subdirectory in turn, and invokes there a new make instance to build the directory’s contents.

Because this approach is very widespread, Automake offers built-in support for it. However, it is worth nothing that the use of make recursion has its own serious issues and drawbacks, and that it’s well possible to have packages with a multi directory layout that make little or no use of such recursion (examples of such packages are GNU Bison and GNU Automake itself); see also the An Alternative Approach to Subdirectories section below.


7.1 Recursing subdirectories

In packages using make recursion, the top level Makefile.am must tell Automake which subdirectories are to be built. This is done via the SUBDIRS variable.

The SUBDIRS variable holds a list of subdirectories in which building of various sorts can occur. The rules for many targets (e.g., all) in the generated Makefile will run commands both locally and in all specified subdirectories. Note that the directories listed in SUBDIRS are not required to contain Makefile.ams; only Makefiles (after configuration). This allows inclusion of libraries from packages that do not use Automake (such as gettext; see also Third-Party Makefiles).

In packages that use subdirectories, the top-level Makefile.am is often very short. For instance, here is the Makefile.am from the GNU Hello distribution:

EXTRA_DIST = BUGS ChangeLog.O README-alpha
SUBDIRS = doc intl po src tests

When Automake invokes make in a subdirectory, it uses the value of the MAKE variable. It passes the value of the variable AM_MAKEFLAGS to the make invocation; this can be set in Makefile.am if there are flags you must always pass to make.

The directories mentioned in SUBDIRS are usually direct children of the current directory, each subdirectory containing its own Makefile.am with a SUBDIRS pointing to deeper subdirectories. Automake can be used to construct packages of arbitrary depth this way.

By default, Automake generates Makefiles that work depth-first in postfix order: the subdirectories are built before the current directory. However, it is possible to change this ordering. You can do this by putting ‘.’ into SUBDIRS. For instance, putting ‘.’ first will cause a prefix ordering of directories.

Using

SUBDIRS = lib src . test

will cause lib/ to be built before src/, then the current directory will be built, finally the test/ directory will be built. It is customary to arrange test directories to be built after everything else since they are meant to test what has been constructed.

In addition to the built-in recursive targets defined by Automake (all, check, etc.), the developer can also define his own recursive targets. That is done by passing the names of such targets as arguments to the m4 macro AM_EXTRA_RECURSIVE_TARGETS in configure.ac. Automake generates rules to handle the recursion for such targets; and the developer can define real actions for them by defining corresponding -local targets.

% cat configure.ac
AC_INIT([pkg-name], [1.0]
AM_INIT_AUTOMAKE
AM_EXTRA_RECURSIVE_TARGETS([foo])
AC_CONFIG_FILES([Makefile sub/Makefile sub/src/Makefile])
AC_OUTPUT
% cat Makefile.am
SUBDIRS = sub
foo-local:
        @echo This will be run by "make foo".
% cat sub/Makefile.am
SUBDIRS = src
% cat sub/src/Makefile.am
foo-local:
        @echo This too will be run by a "make foo" issued either in
        @echo the 'sub/src/' directory, the 'sub/' directory, or the
        @echo top-level directory.

7.2 Conditional Subdirectories

It is possible to define the SUBDIRS variable conditionally if, like in the case of GNU Inetutils, you want to only build a subset of the entire package.

To illustrate how this works, let’s assume we have two directories src/ and opt/. src/ should always be built, but we want to decide in configure whether opt/ will be built or not. (For this example we will assume that opt/ should be built when the variable ‘$want_opt’ was set to ‘yes’.)

Running make should thus recurse into src/ always, and then maybe in opt/.

However ‘make dist’ should always recurse into both src/ and opt/. Because opt/ should be distributed even if it is not needed in the current configuration. This means opt/Makefile should be created unconditionally.

There are two ways to setup a project like this. You can use Automake conditionals (see Conditionals) or use Autoconf AC_SUBST variables (see Setting Output Variables in The Autoconf Manual). Using Automake conditionals is the preferred solution. Before we illustrate these two possibilities, let’s introduce DIST_SUBDIRS.


7.2.1 SUBDIRS vs. DIST_SUBDIRS

Automake considers two sets of directories, defined by the variables SUBDIRS and DIST_SUBDIRS.

SUBDIRS contains the subdirectories of the current directory that must be built (see Recursing subdirectories). It must be defined manually; Automake will never guess a directory is to be built. As we will see in the next two sections, it is possible to define it conditionally so that some directory will be omitted from the build.

DIST_SUBDIRS is used in rules that need to recurse in all directories, even those that have been conditionally left out of the build. Recall our example where we may not want to build subdirectory opt/, but yet we want to distribute it? This is where DIST_SUBDIRS comes into play: ‘opt’ may not appear in SUBDIRS, but it must appear in DIST_SUBDIRS.

Precisely, DIST_SUBDIRS is used by ‘make maintainer-clean’, ‘make distclean’ and ‘make dist’. All other recursive rules use SUBDIRS.

If SUBDIRS is defined conditionally using Automake conditionals, Automake will define DIST_SUBDIRS automatically from the possible values of SUBDIRS in all conditions.

If SUBDIRS contains AC_SUBST variables, DIST_SUBDIRS will not be defined correctly because Automake does not know the possible values of these variables. In this case DIST_SUBDIRS needs to be defined manually.


7.2.2 Subdirectories with AM_CONDITIONAL

configure should output the Makefile for each directory and define a condition into which opt/ should be built.

…
AM_CONDITIONAL([COND_OPT], [test "$want_opt" = yes])
AC_CONFIG_FILES([Makefile src/Makefile opt/Makefile])
…

Then SUBDIRS can be defined in the top-level Makefile.am as follows.

if COND_OPT
  MAYBE_OPT = opt
endif
SUBDIRS = src $(MAYBE_OPT)

As you can see, running make will rightly recurse into src/ and maybe opt/.

As you can’t see, running ‘make dist’ will recurse into both src/ and opt/ directories because ‘make dist’, unlike ‘make all’, doesn’t use the SUBDIRS variable. It uses the DIST_SUBDIRS variable.

In this case Automake will define ‘DIST_SUBDIRS = src opt’ automatically because it knows that MAYBE_OPT can contain ‘opt’ in some condition.


7.2.3 Subdirectories with AC_SUBST

Another possibility is to define MAYBE_OPT from ./configure using AC_SUBST:

…
if test "$want_opt" = yes; then
  MAYBE_OPT=opt
else
  MAYBE_OPT=
fi
AC_SUBST([MAYBE_OPT])
AC_CONFIG_FILES([Makefile src/Makefile opt/Makefile])
…

In this case the top-level Makefile.am should look as follows.

SUBDIRS = src $(MAYBE_OPT)
DIST_SUBDIRS = src opt

The drawback is that since Automake cannot guess what the possible values of MAYBE_OPT are, it is necessary to define DIST_SUBDIRS.


7.2.4 Unconfigured Subdirectories

The semantics of DIST_SUBDIRS are often misunderstood by some users that try to configure and build subdirectories conditionally. Here by configuring we mean creating the Makefile (it might also involve running a nested configure script: this is a costly operation that explains why people want to do it conditionally, but only the Makefile is relevant to the discussion).

The above examples all assume that every Makefile is created, even in directories that are not going to be built. The simple reason is that we want ‘make dist’ to distribute even the directories that are not being built (e.g., platform-dependent code), hence make dist must recurse into the subdirectory, hence this directory must be configured and appear in DIST_SUBDIRS.

Building packages that do not configure every subdirectory is a tricky business, and we do not recommend it to the novice as it is easy to produce an incomplete tarball by mistake. We will not discuss this topic in depth here, yet for the adventurous here are a few rules to remember.

  • SUBDIRS should always be a subset of DIST_SUBDIRS.

    It makes little sense to have a directory in SUBDIRS that is not in DIST_SUBDIRS. Think of the former as a way to tell which directories listed in the latter should be built.

  • Any directory listed in DIST_SUBDIRS and SUBDIRS must be configured.

    I.e., the Makefile must exists or the recursive make rules will not be able to process the directory.

  • Any configured directory must be listed in DIST_SUBDIRS.

    So that the cleaning rules remove the generated Makefiles. It would be correct to see DIST_SUBDIRS as a variable that lists all the directories that have been configured.

In order to prevent recursion in some unconfigured directory you must therefore ensure that this directory does not appear in DIST_SUBDIRS (and SUBDIRS). For instance, if you define SUBDIRS conditionally using AC_SUBST and do not define DIST_SUBDIRS explicitly, it will be default to ‘$(SUBDIRS)’; another possibility is to force DIST_SUBDIRS = $(SUBDIRS).

Of course, directories that are omitted from DIST_SUBDIRS will not be distributed unless you make other arrangements for this to happen (for instance, always running ‘make dist’ in a configuration where all directories are known to appear in DIST_SUBDIRS; or writing a dist-hook target to distribute these directories).

In few packages, unconfigured directories are not even expected to be distributed. Although these packages do not require the aforementioned extra arrangements, there is another pitfall. If the name of a directory appears in SUBDIRS or DIST_SUBDIRS, automake will make sure the directory exists. Consequently automake cannot be run on such a distribution when one directory has been omitted. One way to avoid this check is to use the AC_SUBST method to declare conditional directories; since automake does not know the values of AC_SUBST variables it cannot ensure the corresponding directory exists.


7.3 An Alternative Approach to Subdirectories

If you’ve ever read Peter Miller’s excellent paper, Recursive Make Considered Harmful, the preceding sections on the use of make recursion will probably come as unwelcome advice. For those who haven’t read the paper, Miller’s main thesis is that recursive make invocations are both slow and error-prone.

Automake provides sufficient cross-directory support 2 to enable you to write a single Makefile.am for a complex multi-directory package.

By default an installable file specified in a subdirectory will have its directory name stripped before installation. For instance, in this example, the header file will be installed as $(includedir)/stdio.h:

include_HEADERS = inc/stdio.h

However, the ‘nobase_’ prefix can be used to circumvent this path stripping. In this example, the header file will be installed as $(includedir)/sys/types.h:

nobase_include_HEADERS = sys/types.h

nobase_’ should be specified first when used in conjunction with either ‘dist_’ or ‘nodist_’ (see Fine-grained Distribution Control). For instance:

nobase_dist_pkgdata_DATA = images/vortex.pgm sounds/whirl.ogg

Finally, note that a variable using the ‘nobase_’ prefix can often be replaced by several variables, one for each destination directory (see The Uniform Naming Scheme). For instance, the last example could be rewritten as follows:

imagesdir = $(pkgdatadir)/images
soundsdir = $(pkgdatadir)/sounds
dist_images_DATA = images/vortex.pgm
dist_sounds_DATA = sounds/whirl.ogg

This latter syntax makes it possible to change one destination directory without changing the layout of the source tree.

Currently, ‘nobase_*_LTLIBRARIES’ are the only exception to this rule, in that there is no particular installation order guarantee for an otherwise equivalent set of variables without ‘nobase_’ prefix.


7.4 Nesting Packages

In the GNU Build System, packages can be nested to arbitrary depth. This means that a package can embed other packages with their own configure, Makefiles, etc.

These other packages should just appear as subdirectories of their parent package. They must be listed in SUBDIRS like other ordinary directories. However the subpackage’s Makefiles should be output by its own configure script, not by the parent’s configure. This is achieved using the AC_CONFIG_SUBDIRS Autoconf macro (see Configuring Other Packages in Subdirectories in The Autoconf Manual).

Here is an example package for an arm program that links with a hand library that is a nested package in subdirectory hand/.

arm’s configure.ac:

AC_INIT([arm], [1.0])
AC_CONFIG_AUX_DIR([.])
AM_INIT_AUTOMAKE
AC_PROG_CC
AC_CONFIG_FILES([Makefile])
# Call hand's ./configure script recursively.
AC_CONFIG_SUBDIRS([hand])
AC_OUTPUT

arm’s Makefile.am:

# Build the library in the hand subdirectory first.
SUBDIRS = hand

# Include hand's header when compiling this directory.
AM_CPPFLAGS = -I$(srcdir)/hand

bin_PROGRAMS = arm
arm_SOURCES = arm.c
# link with the hand library.
arm_LDADD = hand/libhand.a

Now here is hand’s hand/configure.ac:

AC_INIT([hand], [1.2])
AC_CONFIG_AUX_DIR([.])
AM_INIT_AUTOMAKE
AC_PROG_CC
AM_PROG_AR
AC_PROG_RANLIB
AC_CONFIG_FILES([Makefile])
AC_OUTPUT

and its hand/Makefile.am:

lib_LIBRARIES = libhand.a
libhand_a_SOURCES = hand.c

When ‘make dist’ is run from the top-level directory it will create an archive arm-1.0.tar.gz that contains the arm code as well as the hand subdirectory. This package can be built and installed like any ordinary package, with the usual ‘./configure && make && make install’ sequence (the hand subpackage will be built and installed by the process).

When ‘make dist’ is run from the hand directory, it will create a self-contained hand-1.2.tar.gz archive. So although it appears to be embedded in another package, it can still be used separately.

The purpose of the ‘AC_CONFIG_AUX_DIR([.])’ instruction is to force Automake and Autoconf to search for auxiliary scripts in the current directory. For instance, this means that there will be two copies of install-sh: one in the top-level of the arm package, and another one in the hand/ subdirectory for the hand package.

The historical default is to search for these auxiliary scripts in the parent directory and the grandparent directory. So if the ‘AC_CONFIG_AUX_DIR([.])’ line was removed from hand/configure.ac, that subpackage would share the auxiliary script of the arm package. This may looks like a gain in size (a few kilobytes), but it is actually a loss of modularity as the hand subpackage is no longer self-contained (‘make dist’ in the subdirectory will not work anymore).

Packages that do not use Automake need more work to be integrated this way. See Third-Party Makefiles.


8 Building Programs and Libraries

A large part of Automake’s functionality is dedicated to making it easy to build programs and libraries.


8.1 Building a program

In order to build a program, you need to tell Automake which sources are part of it, and which libraries it should be linked with.

This section also covers conditional compilation of sources or programs. Most of the comments about these also apply to libraries (see Building a library) and libtool libraries (see Building a Shared Library).


8.1.1 Defining program sources

In a directory containing source that gets built into a program (as opposed to a library or a script), the PROGRAMS primary is used. Programs can be installed in bindir, sbindir, libexecdir, pkglibexecdir, or not at all (noinst_). They can also be built only for ‘make check’, in which case the prefix is ‘check_’.

For instance:

bin_PROGRAMS = hello

In this simple case, the resulting Makefile.in will contain code to generate a program named hello.

Associated with each program are several assisting variables that are named after the program. These variables are all optional, and have reasonable defaults. Each variable, its use, and default is spelled out below; we use the “hello” example throughout.

The variable hello_SOURCES is used to specify which source files get built into an executable:

hello_SOURCES = hello.c version.c getopt.c getopt1.c getopt.h system.h

This causes each mentioned .c file to be compiled into the corresponding .o. Then all are linked to produce hello.

If hello_SOURCES is not specified, then it defaults to the single file hello.c (see Default _SOURCES).

Multiple programs can be built in a single directory. Multiple programs can share a single source file, which must be listed in each _SOURCES definition.

Header files listed in a _SOURCES definition will be included in the distribution but otherwise ignored. In case it isn’t obvious, you should not include the header file generated by configure in a _SOURCES variable; this file should not be distributed. Lex (.l) and Yacc (.y) files can also be listed; see Yacc and Lex support.


8.1.2 Linking the program

If you need to link against libraries that are not found by configure, you can use LDADD to do so. This variable is used to specify additional objects or libraries to link with; it is inappropriate for specifying specific linker flags, you should use AM_LDFLAGS for this purpose.

Sometimes, multiple programs are built in one directory but do not share the same link-time requirements. In this case, you can use the prog_LDADD variable (where prog is the name of the program as it appears in some _PROGRAMS variable, and usually written in lowercase) to override LDADD. If this variable exists for a given program, then that program is not linked using LDADD.

For instance, in GNU cpio, pax, cpio and mt are linked against the library libcpio.a. However, rmt is built in the same directory, and has no such link requirement. Also, mt and rmt are only built on certain architectures. Here is what cpio’s src/Makefile.am looks like (abridged):

bin_PROGRAMS = cpio pax $(MT)
libexec_PROGRAMS = $(RMT)
EXTRA_PROGRAMS = mt rmt

LDADD = ../lib/libcpio.a $(INTLLIBS)
rmt_LDADD =

cpio_SOURCES = …
pax_SOURCES = …
mt_SOURCES = …
rmt_SOURCES = …

prog_LDADD is inappropriate for passing program-specific linker flags (except for -l, -L, -dlopen and -dlpreopen). So, use the prog_LDFLAGS variable for this purpose.

It is also occasionally useful to have a program depend on some other target that is not actually part of that program. This can be done using either the prog_DEPENDENCIES or the EXTRA_prog_DEPENDENCIES variable. Each program depends on the contents both variables, but no further interpretation is done.

Since these dependencies are associated to the link rule used to create the programs they should normally list files used by the link command. That is *.$(OBJEXT), *.a, or *.la files. In rare cases you may need to add other kinds of files such as linker scripts, but listing a source file in _DEPENDENCIES is wrong. If some source file needs to be built before all the components of a program are built, consider using the BUILT_SOURCES variable instead (see Built Sources).

If prog_DEPENDENCIES is not supplied, it is computed by Automake. The automatically-assigned value is the contents of prog_LDADD, with most configure substitutions, -l, -L, -dlopen and -dlpreopen options removed. The configure substitutions that are left in are only ‘$(LIBOBJS)’ and ‘$(ALLOCA)’; these are left because it is known that they will not cause an invalid value for prog_DEPENDENCIES to be generated.

Conditional compilation of sources shows a situation where _DEPENDENCIES may be used.

The EXTRA_prog_DEPENDENCIES may be useful for cases where you merely want to augment the automake-generated prog_DEPENDENCIES rather than replacing it.

We recommend that you avoid using -l options in LDADD or prog_LDADD when referring to libraries built by your package. Instead, write the file name of the library explicitly as in the above cpio example. Use -l only to list third-party libraries. If you follow this rule, the default value of prog_DEPENDENCIES will list all your local libraries and omit the other ones.


8.1.3 Conditional compilation of sources

You can’t put a configure substitution (e.g., ‘@FOO@’ or ‘$(FOO)’ where FOO is defined via AC_SUBST) into a _SOURCES variable. The reason for this is a bit hard to explain, but suffice to say that it simply won’t work. Automake will give an error if you try to do this.

Fortunately there are two other ways to achieve the same result. One is to use configure substitutions in _LDADD variables, the other is to use an Automake conditional.

Conditional Compilation using _LDADD Substitutions

Automake must know all the source files that could possibly go into a program, even if not all the files are built in every circumstance. Any files that are only conditionally built should be listed in the appropriate EXTRA_ variable. For instance, if hello-linux.c or hello-generic.c were conditionally included in hello, the Makefile.am would contain:

bin_PROGRAMS = hello
hello_SOURCES = hello-common.c
EXTRA_hello_SOURCES = hello-linux.c hello-generic.c
hello_LDADD = $(HELLO_SYSTEM)
hello_DEPENDENCIES = $(HELLO_SYSTEM)

You can then setup the ‘$(HELLO_SYSTEM)’ substitution from configure.ac:

…
case $host in
  *linux*) HELLO_SYSTEM='hello-linux.$(OBJEXT)' ;;
  *)       HELLO_SYSTEM='hello-generic.$(OBJEXT)' ;;
esac
AC_SUBST([HELLO_SYSTEM])
…

In this case, the variable HELLO_SYSTEM should be replaced by either hello-linux.o or hello-generic.o, and added to both hello_DEPENDENCIES and hello_LDADD in order to be built and linked in.

Conditional Compilation using Automake Conditionals

An often simpler way to compile source files conditionally is to use Automake conditionals. For instance, you could use this Makefile.am construct to build the same hello example:

bin_PROGRAMS = hello
if LINUX
hello_SOURCES = hello-linux.c hello-common.c
else
hello_SOURCES = hello-generic.c hello-common.c
endif

In this case, configure.ac should setup the LINUX conditional using AM_CONDITIONAL (see Conditionals).

When using conditionals like this you don’t need to use the EXTRA_ variable, because Automake will examine the contents of each variable to construct the complete list of source files.

If your program uses a lot of files, you will probably prefer a conditional ‘+=’.

bin_PROGRAMS = hello
hello_SOURCES = hello-common.c
if LINUX
hello_SOURCES += hello-linux.c
else
hello_SOURCES += hello-generic.c
endif

8.1.4 Conditional compilation of programs

Sometimes it is useful to determine the programs that are to be built at configure time. For instance, GNU cpio only builds mt and rmt under special circumstances. The means to achieve conditional compilation of programs are the same you can use to compile source files conditionally: substitutions or conditionals.

Conditional Programs using configure Substitutions

In this case, you must notify Automake of all the programs that can possibly be built, but at the same time cause the generated Makefile.in to use the programs specified by configure. This is done by having configure substitute values into each _PROGRAMS definition, while listing all optionally built programs in EXTRA_PROGRAMS.

bin_PROGRAMS = cpio pax $(MT)
libexec_PROGRAMS = $(RMT)
EXTRA_PROGRAMS = mt rmt

As explained in Support for executable extensions, Automake will rewrite bin_PROGRAMS, libexec_PROGRAMS, and EXTRA_PROGRAMS, appending ‘$(EXEEXT)’ to each binary. Obviously it cannot rewrite values obtained at run-time through configure substitutions, therefore you should take care of appending ‘$(EXEEXT)’ yourself, as in ‘AC_SUBST([MT], ['mt${EXEEXT}'])’.

Conditional Programs using Automake Conditionals

You can also use Automake conditionals (see Conditionals) to select programs to be built. In this case you don’t have to worry about ‘$(EXEEXT)’ or EXTRA_PROGRAMS.

bin_PROGRAMS = cpio pax
if WANT_MT
  bin_PROGRAMS += mt
endif
if WANT_RMT
  libexec_PROGRAMS = rmt
endif

8.2 Building a library

Building a library is much like building a program. In this case, the name of the primary is LIBRARIES. Libraries can be installed in libdir or pkglibdir.

See Building a Shared Library, for information on how to build shared libraries using libtool and the LTLIBRARIES primary.

Each _LIBRARIES variable is a list of the libraries to be built. For instance, to create a library named libcpio.a, but not install it, you would write:

noinst_LIBRARIES = libcpio.a
libcpio_a_SOURCES = …

The sources that go into a library are determined exactly as they are for programs, via the _SOURCES variables. Note that the library name is canonicalized (see How derived variables are named), so the _SOURCES variable corresponding to libcpio.a is ‘libcpio_a_SOURCES’, not ‘libcpio.a_SOURCES’.

Extra objects can be added to a library using the library_LIBADD variable. This should be used for objects determined by configure. Again from cpio:

libcpio_a_LIBADD = $(LIBOBJS) $(ALLOCA)

In addition, sources for extra objects that will not exist until configure-time must be added to the BUILT_SOURCES variable (see Built Sources).

Building a static library is done by compiling all object files, then by invoking ‘$(AR) $(ARFLAGS)’ followed by the name of the library and the list of objects, and finally by calling ‘$(RANLIB)’ on that library. You should call AC_PROG_RANLIB from your configure.ac to define RANLIB (Automake will complain otherwise). You should also call AM_PROG_AR to define AR, in order to support unusual archivers such as Microsoft lib. ARFLAGS will default to cru; you can override this variable by setting it in your Makefile.am or by AC_SUBSTing it from your configure.ac. You can override the AR variable by defining a per-library maude_AR variable (see Program and Library Variables).

Be careful when selecting library components conditionally. Because building an empty library is not portable, you should ensure that any library always contains at least one object.

To use a static library when building a program, add it to LDADD for this program. In the following example, the program cpio is statically linked with the library libcpio.a.

noinst_LIBRARIES = libcpio.a
libcpio_a_SOURCES = …

bin_PROGRAMS = cpio
cpio_SOURCES = cpio.c …
cpio_LDADD = libcpio.a

8.3 Building a Shared Library

Building shared libraries portably is a relatively complex matter. For this reason, GNU Libtool (see Introduction in The Libtool Manual) was created to help build shared libraries in a platform-independent way.


8.3.1 The Libtool Concept

Libtool abstracts shared and static libraries into a unified concept henceforth called libtool libraries. Libtool libraries are files using the .la suffix, and can designate a static library, a shared library, or maybe both. Their exact nature cannot be determined until ./configure is run: not all platforms support all kinds of libraries, and users can explicitly select which libraries should be built. (However the package’s maintainers can tune the default, see The AC_PROG_LIBTOOL macro in The Libtool Manual.)

Because object files for shared and static libraries must be compiled differently, libtool is also used during compilation. Object files built by libtool are called libtool objects: these are files using the .lo suffix. Libtool libraries are built from these libtool objects.

You should not assume anything about the structure of .la or .lo files and how libtool constructs them: this is libtool’s concern, and the last thing one wants is to learn about libtool’s guts. However the existence of these files matters, because they are used as targets and dependencies in Makefiles rules when building libtool libraries. There are situations where you may have to refer to these, for instance when expressing dependencies for building source files conditionally (see Libtool Libraries with Conditional Sources).

People considering writing a plug-in system, with dynamically loaded modules, should look into libltdl: libtool’s dlopening library (see Using libltdl in The Libtool Manual). This offers a portable dlopening facility to load libtool libraries dynamically, and can also achieve static linking where unavoidable.

Before we discuss how to use libtool with Automake in details, it should be noted that the libtool manual also has a section about how to use Automake with libtool (see Using Automake with Libtool in The Libtool Manual).


8.3.2 Building Libtool Libraries

Automake uses libtool to build libraries declared with the LTLIBRARIES primary. Each _LTLIBRARIES variable is a list of libtool libraries to build. For instance, to create a libtool library named libgettext.la, and install it in libdir, write:

lib_LTLIBRARIES = libgettext.la
libgettext_la_SOURCES = gettext.c gettext.h …

Automake predefines the variable pkglibdir, so you can use pkglib_LTLIBRARIES to install libraries in ‘$(libdir)/@PACKAGE@/’.

If gettext.h is a public header file that needs to be installed in order for people to use the library, it should be declared using a _HEADERS variable, not in libgettext_la_SOURCES. Headers listed in the latter should be internal headers that are not part of the public interface.

lib_LTLIBRARIES = libgettext.la
libgettext_la_SOURCES = gettext.c …
include_HEADERS = gettext.h …

A package can build and install such a library along with other programs that use it. This dependency should be specified using LDADD. The following example builds a program named hello that is linked with libgettext.la.

lib_LTLIBRARIES = libgettext.la
libgettext_la_SOURCES = gettext.c …

bin_PROGRAMS = hello
hello_SOURCES = hello.c …
hello_LDADD = libgettext.la

Whether hello is statically or dynamically linked with libgettext.la is not yet known: this will depend on the configuration of libtool and the capabilities of the host.


8.3.3 Building Libtool Libraries Conditionally

Like conditional programs (see Conditional compilation of programs), there are two main ways to build conditional libraries: using Automake conditionals or using Autoconf AC_SUBSTitutions.

The important implementation detail you have to be aware of is that the place where a library will be installed matters to libtool: it needs to be indicated at link-time using the -rpath option.

For libraries whose destination directory is known when Automake runs, Automake will automatically supply the appropriate -rpath option to libtool. This is the case for libraries listed explicitly in some installable _LTLIBRARIES variables such as lib_LTLIBRARIES.

However, for libraries determined at configure time (and thus mentioned in EXTRA_LTLIBRARIES), Automake does not know the final installation directory. For such libraries you must add the -rpath option to the appropriate _LDFLAGS variable by hand.

The examples below illustrate the differences between these two methods.

Here is an example where WANTEDLIBS is an AC_SUBSTed variable set at ./configure-time to either libfoo.la, libbar.la, both, or none. Although ‘$(WANTEDLIBS)’ appears in the lib_LTLIBRARIES, Automake cannot guess it relates to libfoo.la or libbar.la at the time it creates the link rule for these two libraries. Therefore the -rpath argument must be explicitly supplied.

EXTRA_LTLIBRARIES = libfoo.la libbar.la
lib_LTLIBRARIES = $(WANTEDLIBS)
libfoo_la_SOURCES = foo.c …
libfoo_la_LDFLAGS = -rpath '$(libdir)'
libbar_la_SOURCES = bar.c …
libbar_la_LDFLAGS = -rpath '$(libdir)'

Here is how the same Makefile.am would look using Automake conditionals named WANT_LIBFOO and WANT_LIBBAR. Now Automake is able to compute the -rpath setting itself, because it’s clear that both libraries will end up in ‘$(libdir)’ if they are installed.

lib_LTLIBRARIES =
if WANT_LIBFOO
lib_LTLIBRARIES += libfoo.la
endif
if WANT_LIBBAR
lib_LTLIBRARIES += libbar.la
endif
libfoo_la_SOURCES = foo.c …
libbar_la_SOURCES = bar.c …

8.3.4 Libtool Libraries with Conditional Sources

Conditional compilation of sources in a library can be achieved in the same way as conditional compilation of sources in a program (see Conditional compilation of sources). The only difference is that _LIBADD should be used instead of _LDADD and that it should mention libtool objects (.lo files).

So, to mimic the hello example from Conditional compilation of sources, we could build a libhello.la library using either hello-linux.c or hello-generic.c with the following Makefile.am.

lib_LTLIBRARIES = libhello.la
libhello_la_SOURCES = hello-common.c
EXTRA_libhello_la_SOURCES = hello-linux.c hello-generic.c
libhello_la_LIBADD = $(HELLO_SYSTEM)
libhello_la_DEPENDENCIES = $(HELLO_SYSTEM)

And make sure configure defines HELLO_SYSTEM as either hello-linux.lo or hello-generic.lo.

Or we could simply use an Automake conditional as follows.

lib_LTLIBRARIES = libhello.la
libhello_la_SOURCES = hello-common.c
if LINUX
libhello_la_SOURCES += hello-linux.c
else
libhello_la_SOURCES += hello-generic.c
endif

8.3.5 Libtool Convenience Libraries

Sometimes you want to build libtool libraries that should not be installed. These are called libtool convenience libraries and are typically used to encapsulate many sublibraries, later gathered into one big installed library.

Libtool convenience libraries are declared by directory-less variables such as noinst_LTLIBRARIES, check_LTLIBRARIES, or even EXTRA_LTLIBRARIES. Unlike installed libtool libraries they do not need an -rpath flag at link time (actually this is the only difference).

Convenience libraries listed in noinst_LTLIBRARIES are always built. Those listed in check_LTLIBRARIES are built only upon ‘make check’. Finally, libraries listed in EXTRA_LTLIBRARIES are never built explicitly: Automake outputs rules to build them, but if the library does not appear as a Makefile dependency anywhere it won’t be built (this is why EXTRA_LTLIBRARIES is used for conditional compilation).

Here is a sample setup merging libtool convenience libraries from subdirectories into one main libtop.la library.

# -- Top-level Makefile.am --
SUBDIRS = sub1 sub2 …
lib_LTLIBRARIES = libtop.la
libtop_la_SOURCES =
libtop_la_LIBADD = \
  sub1/libsub1.la \
  sub2/libsub2.la \
  …

# -- sub1/Makefile.am --
noinst_LTLIBRARIES = libsub1.la
libsub1_la_SOURCES = …

# -- sub2/Makefile.am --
# showing nested convenience libraries
SUBDIRS = sub2.1 sub2.2 …
noinst_LTLIBRARIES = libsub2.la
libsub2_la_SOURCES =
libsub2_la_LIBADD = \
  sub21/libsub21.la \
  sub22/libsub22.la \
  …

When using such setup, beware that automake will assume libtop.la is to be linked with the C linker. This is because libtop_la_SOURCES is empty, so automake picks C as default language. If libtop_la_SOURCES was not empty, automake would select the linker as explained in How the Linker is Chosen.

If one of the sublibraries contains non-C source, it is important that the appropriate linker be chosen. One way to achieve this is to pretend that there is such a non-C file among the sources of the library, thus forcing automake to select the appropriate linker. Here is the top-level Makefile of our example updated to force C++ linking.

SUBDIRS = sub1 sub2 …
lib_LTLIBRARIES = libtop.la
libtop_la_SOURCES =
# Dummy C++ source to cause C++ linking.
nodist_EXTRA_libtop_la_SOURCES = dummy.cxx
libtop_la_LIBADD = \
  sub1/libsub1.la \
  sub2/libsub2.la \
  …

EXTRA_*_SOURCES’ variables are used to keep track of source files that might be compiled (this is mostly useful when doing conditional compilation using AC_SUBST, see Libtool Libraries with Conditional Sources), and the nodist_ prefix means the listed sources are not to be distributed (see Program and Library Variables). In effect the file dummy.cxx does not need to exist in the source tree. Of course if you have some real source file to list in libtop_la_SOURCES there is no point in cheating with nodist_EXTRA_libtop_la_SOURCES.


8.3.6 Libtool Modules

These are libtool libraries meant to be dlopened. They are indicated to libtool by passing -module at link-time.

pkglib_LTLIBRARIES = mymodule.la
mymodule_la_SOURCES = doit.c
mymodule_la_LDFLAGS = -module

Ordinarily, Automake requires that a library’s name start with lib. However, when building a dynamically loadable module you might wish to use a "nonstandard" name. Automake will not complain about such nonstandard names if it knows the library being built is a libtool module, i.e., if -module explicitly appears in the library’s _LDFLAGS variable (or in the common AM_LDFLAGS variable when no per-library _LDFLAGS variable is defined).

As always, AC_SUBST variables are black boxes to Automake since their values are not yet known when automake is run. Therefore if -module is set via such a variable, Automake cannot notice it and will proceed as if the library was an ordinary libtool library, with strict naming.

If mymodule_la_SOURCES is not specified, then it defaults to the single file mymodule.c (see Default _SOURCES).


8.3.7 _LIBADD, _LDFLAGS, and _LIBTOOLFLAGS

As shown in previous sections, the ‘library_LIBADD’ variable should be used to list extra libtool objects (.lo files) or libtool libraries (.la) to add to library.

The ‘library_LDFLAGS’ variable is the place to list additional libtool linking flags, such as -version-info, -static, and a lot more. See Link mode in The Libtool Manual.

The libtool command has two kinds of options: mode-specific options and generic options. Mode-specific options such as the aforementioned linking flags should be lumped with the other flags passed to the tool invoked by libtool (hence the use of ‘library_LDFLAGS’ for libtool linking flags). Generic options include --tag=tag and --silent (see Invoking libtool in The Libtool Manual for more options) should appear before the mode selection on the command line; in Makefile.ams they should be listed in the ‘library_LIBTOOLFLAGS’ variable.

If ‘library_LIBTOOLFLAGS’ is not defined, then the variable AM_LIBTOOLFLAGS is used instead.

These flags are passed to libtool after the --tag=tag option computed by Automake (if any), so ‘library_LIBTOOLFLAGS’ (or AM_LIBTOOLFLAGS) is a good place to override or supplement the --tag=tag setting.

The libtool rules also use a LIBTOOLFLAGS variable that should not be set in Makefile.am: this is a user variable (see Flag Variables Ordering. It allows users to run ‘make LIBTOOLFLAGS=--silent’, for instance. Note that the verbosity of libtool can also be influenced by the Automake support for silent rules (see How Automake can help in silencing make).


8.3.8 LTLIBOBJS and LTALLOCA

Where an ordinary library might include ‘$(LIBOBJS)’ or ‘$(ALLOCA)’ (see Special handling for LIBOBJS and ALLOCA), a libtool library must use ‘$(LTLIBOBJS)’ or ‘$(LTALLOCA)’. This is required because the object files that libtool operates on do not necessarily end in .o.

Nowadays, the computation of LTLIBOBJS from LIBOBJS is performed automatically by Autoconf (see AC_LIBOBJ vs. LIBOBJS in The Autoconf Manual).


8.3.9 Common Issues Related to Libtool’s Use


8.3.9.1 Error: ‘required file `./ltmain.sh' not found

Libtool comes with a tool called libtoolize that will install libtool’s supporting files into a package. Running this command will install ltmain.sh. You should execute it before aclocal and automake.

People upgrading old packages to newer autotools are likely to face this issue because older Automake versions used to call libtoolize. Therefore old build scripts do not call libtoolize.

Since Automake 1.6, it has been decided that running libtoolize was none of Automake’s business. Instead, that functionality has been moved into the autoreconf command (see Using autoreconf in The Autoconf Manual). If you do not want to remember what to run and when, just learn the autoreconf command. Hopefully, replacing existing bootstrap or autogen.sh scripts by a call to autoreconf should also free you from any similar incompatible change in the future.


8.3.9.2 Objects ‘created with both libtool and without

Sometimes, the same source file is used both to build a libtool library and to build another non-libtool target (be it a program or another library).

Let’s consider the following Makefile.am.

bin_PROGRAMS = prog
prog_SOURCES = prog.c foo.c …

lib_LTLIBRARIES = libfoo.la
libfoo_la_SOURCES = foo.c …

(In this trivial case the issue could be avoided by linking libfoo.la with prog instead of listing foo.c in prog_SOURCES. But let’s assume we really want to keep prog and libfoo.la separate.)

Technically, it means that we should build foo.$(OBJEXT) for prog, and foo.lo for libfoo.la. The problem is that in the course of creating foo.lo, libtool may erase (or replace) foo.$(OBJEXT), and this cannot be avoided.

Therefore, when Automake detects this situation it will complain with a message such as

object 'foo.$(OBJEXT)' created both with libtool and without

A workaround for this issue is to ensure that these two objects get different basenames. As explained in Why are object files sometimes renamed?, this happens automatically when per-targets flags are used.

bin_PROGRAMS = prog
prog_SOURCES = prog.c foo.c …
prog_CFLAGS = $(AM_CFLAGS)

lib_LTLIBRARIES = libfoo.la
libfoo_la_SOURCES = foo.c …

Adding ‘prog_CFLAGS = $(AM_CFLAGS)’ is almost a no-op, because when the prog_CFLAGS is defined, it is used instead of AM_CFLAGS. However as a side effect it will cause prog.c and foo.c to be compiled as prog-prog.$(OBJEXT) and prog-foo.$(OBJEXT), which solves the issue.


8.4 Program and Library Variables

Associated with each program is a collection of variables that can be used to modify how that program is built. There is a similar list of such variables for each library. The canonical name of the program (or library) is used as a base for naming these variables.

In the list below, we use the name “maude” to refer to the program or library. In your Makefile.am you would replace this with the canonical name of your program. This list also refers to “maude” as a program, but in general the same rules apply for both static and dynamic libraries; the documentation below notes situations where programs and libraries differ.

maude_SOURCES

This variable, if it exists, lists all the source files that are compiled to build the program. These files are added to the distribution by default. When building the program, Automake will cause each source file to be compiled to a single .o file (or .lo when using libtool). Normally these object files are named after the source file, but other factors can change this. If a file in the _SOURCES variable has an unrecognized extension, Automake will do one of two things with it. If a suffix rule exists for turning files with the unrecognized extension into .o files, then automake will treat this file as it will any other source file (see Support for Other Languages). Otherwise, the file will be ignored as though it were a header file.

The prefixes dist_ and nodist_ can be used to control whether files listed in a _SOURCES variable are distributed. dist_ is redundant, as sources are distributed by default, but it can be specified for clarity if desired.

It is possible to have both dist_ and nodist_ variants of a given _SOURCES variable at once; this lets you easily distribute some files and not others, for instance:

nodist_maude_SOURCES = nodist.c
dist_maude_SOURCES = dist-me.c

By default the output file (on Unix systems, the .o file) will be put into the current build directory. However, if the option subdir-objects is in effect in the current directory then the .o file will be put into the subdirectory named after the source file. For instance, with subdir-objects enabled, sub/dir/file.c will be compiled to sub/dir/file.o. Some people prefer this mode of operation. You can specify subdir-objects in AUTOMAKE_OPTIONS (see Changing Automake’s Behavior).

EXTRA_maude_SOURCES

Automake needs to know the list of files you intend to compile statically. For one thing, this is the only way Automake has of knowing what sort of language support a given Makefile.in requires. 3 This means that, for example, you can’t put a configure substitution like ‘@my_sources@’ into a ‘_SOURCES’ variable. If you intend to conditionally compile source files and use configure to substitute the appropriate object names into, e.g., _LDADD (see below), then you should list the corresponding source files in the EXTRA_ variable.

This variable also supports dist_ and nodist_ prefixes. For instance, nodist_EXTRA_maude_SOURCES would list extra sources that may need to be built, but should not be distributed.

maude_AR

A static library is created by default by invoking ‘$(AR) $(ARFLAGS)’ followed by the name of the library and then the objects being put into the library. You can override this by setting the _AR variable. This is usually used with C++; some C++ compilers require a special invocation in order to instantiate all the templates that should go into a library. For instance, the SGI C++ compiler likes this variable set like so:

libmaude_a_AR = $(CXX) -ar -o
maude_LIBADD

Extra objects can be added to a library using the _LIBADD variable. For instance, this should be used for objects determined by configure (see Building a library).

In the case of libtool libraries, maude_LIBADD can also refer to other libtool libraries.

maude_LDADD

Extra objects (*.$(OBJEXT)) and libraries (*.a, *.la) can be added to a program by listing them in the _LDADD variable. For instance, this should be used for objects determined by configure (see Linking the program).

_LDADD and _LIBADD are inappropriate for passing program-specific linker flags (except for -l, -L, -dlopen and -dlpreopen). Use the _LDFLAGS variable for this purpose.

For instance, if your configure.ac uses AC_PATH_XTRA, you could link your program against the X libraries like so:

maude_LDADD = $(X_PRE_LIBS) $(X_LIBS) $(X_EXTRA_LIBS)

We recommend that you use -l and -L only when referring to third-party libraries, and give the explicit file names of any library built by your package. Doing so will ensure that maude_DEPENDENCIES (see below) is correctly defined by default.

maude_LDFLAGS

This variable is used to pass extra flags to the link step of a program or a shared library. It overrides the AM_LDFLAGS variable.

maude_LIBTOOLFLAGS

This variable is used to pass extra options to libtool. It overrides the AM_LIBTOOLFLAGS variable. These options are output before libtool’s --mode=mode option, so they should not be mode-specific options (those belong to the compiler or linker flags). See _LIBADD, _LDFLAGS, and _LIBTOOLFLAGS.

maude_DEPENDENCIES
EXTRA_maude_DEPENDENCIES

It is also occasionally useful to have a target (program or library) depend on some other file that is not actually part of that target. This can be done using the _DEPENDENCIES variable. Each target depends on the contents of such a variable, but no further interpretation is done.

Since these dependencies are associated to the link rule used to create the programs they should normally list files used by the link command. That is *.$(OBJEXT), *.a, or *.la files for programs; *.lo and *.la files for Libtool libraries; and *.$(OBJEXT) files for static libraries. In rare cases you may need to add other kinds of files such as linker scripts, but listing a source file in _DEPENDENCIES is wrong. If some source file needs to be built before all the components of a program are built, consider using the BUILT_SOURCES variable (see Built Sources).

If _DEPENDENCIES is not supplied, it is computed by Automake. The automatically-assigned value is the contents of _LDADD or _LIBADD, with most configure substitutions, -l, -L, -dlopen and -dlpreopen options removed. The configure substitutions that are left in are only ‘$(LIBOBJS)’ and ‘$(ALLOCA)’; these are left because it is known that they will not cause an invalid value for _DEPENDENCIES to be generated.

_DEPENDENCIES is more likely used to perform conditional compilation using an AC_SUBST variable that contains a list of objects. See Conditional compilation of sources, and Libtool Libraries with Conditional Sources.

The EXTRA_*_DEPENDENCIES variable may be useful for cases where you merely want to augment the automake-generated _DEPENDENCIES variable rather than replacing it.

You can override the linker on a per-program basis. By default the linker is chosen according to the languages used by the program. For instance, a program that includes C++ source code would use the C++ compiler to link. The _LINK variable must hold the name of a command that can be passed all the .o file names and libraries to link against as arguments. Note that the name of the underlying program is not passed to _LINK; typically one uses ‘$@’:

maude_LINK = $(CCLD) -magic -o $@

If a _LINK variable is not supplied, it may still be generated and used by Automake due to the use of per-target link flags such as _CFLAGS, _LDFLAGS or _LIBTOOLFLAGS, in cases where they apply.

maude_CCASFLAGS
maude_CFLAGS
maude_CPPFLAGS
maude_CXXFLAGS
maude_FFLAGS
maude_GCJFLAGS
maude_LFLAGS
maude_OBJCFLAGS
maude_OBJCXXFLAGS
maude_RFLAGS
maude_UPCFLAGS
maude_YFLAGS

Automake allows you to set compilation flags on a per-program (or per-library) basis. A single source file can be included in several programs, and it will potentially be compiled with different flags for each program. This works for any language directly supported by Automake. These per-target compilation flags are ‘_CCASFLAGS’, ‘_CFLAGS’, ‘_CPPFLAGS’, ‘_CXXFLAGS’, ‘_FFLAGS’, ‘_GCJFLAGS’, ‘_LFLAGS’, ‘_OBJCFLAGS’, ‘_OBJCXXFLAGS’, ‘_RFLAGS’, ‘_UPCFLAGS’, and ‘_YFLAGS’.

When using a per-target compilation flag, Automake will choose a different name for the intermediate object files. Ordinarily a file like sample.c will be compiled to produce sample.o. However, if the program’s _CFLAGS variable is set, then the object file will be named, for instance, maude-sample.o. (See also Why are object files sometimes renamed?).

In compilations with per-target flags, the ordinary ‘AM_’ form of the flags variable is not automatically included in the compilation (however, the user form of the variable is included). So for instance, if you want the hypothetical maude compilations to also use the value of AM_CFLAGS, you would need to write:

maude_CFLAGS = … your flags … $(AM_CFLAGS)

See Flag Variables Ordering, for more discussion about the interaction between user variables, ‘AM_’ shadow variables, and per-target variables.

maude_SHORTNAME

On some platforms the allowable file names are very short. In order to support these systems and per-target compilation flags at the same time, Automake allows you to set a “short name” that will influence how intermediate object files are named. For instance, in the following example,

bin_PROGRAMS = maude
maude_CPPFLAGS = -DSOMEFLAG
maude_SHORTNAME = m
maude_SOURCES = sample.c …

the object file would be named m-sample.o rather than maude-sample.o.

This facility is rarely needed in practice, and we recommend avoiding it until you find it is required.


8.5 Default _SOURCES

_SOURCES variables are used to specify source files of programs (see Building a program), libraries (see Building a library), and Libtool libraries (see Building a Shared Library).

When no such variable is specified for a target, Automake will define one itself. The default is to compile a single C file whose base name is the name of the target itself, with any extension replaced by AM_DEFAULT_SOURCE_EXT, which defaults to .c.

For example if you have the following somewhere in your Makefile.am with no corresponding libfoo_a_SOURCES:

lib_LIBRARIES = libfoo.a sub/libc++.a

libfoo.a will be built using a default source file named libfoo.c, and sub/libc++.a will be built from sub/libc++.c. (In older versions sub/libc++.a would be built from sub_libc___a.c, i.e., the default source was the canonized name of the target, with .c appended. We believe the new behavior is more sensible, but for backward compatibility automake will use the old name if a file or a rule with that name exists and AM_DEFAULT_SOURCE_EXT is not used.)

Default sources are mainly useful in test suites, when building many test programs each from a single source. For instance, in

check_PROGRAMS = test1 test2 test3
AM_DEFAULT_SOURCE_EXT = .cpp

test1, test2, and test3 will be built from test1.cpp, test2.cpp, and test3.cpp. Without the last line, they will be built from test1.c, test2.c, and test3.c.

Another case where this is convenient is building many Libtool modules (modulen.la), each defined in its own file (modulen.c).

AM_LDFLAGS = -module
lib_LTLIBRARIES = module1.la module2.la module3.la

Finally, there is one situation where this default source computation needs to be avoided: when a target should not be built from sources. We already saw such an example in Building true and false; this happens when all the constituents of a target have already been compiled and just need to be combined using a _LDADD variable. Then it is necessary to define an empty _SOURCES variable, so that automake does not compute a default.

bin_PROGRAMS = target
target_SOURCES =
target_LDADD = libmain.a libmisc.a

8.6 Special handling for LIBOBJS and ALLOCA

The ‘$(LIBOBJS)’ and ‘$(ALLOCA)’ variables list object files that should be compiled into the project to provide an implementation for functions that are missing or broken on the host system. They are substituted by configure.

These variables are defined by Autoconf macros such as AC_LIBOBJ, AC_REPLACE_FUNCS (see Generic Function Checks in The Autoconf Manual), or AC_FUNC_ALLOCA (see Particular Function Checks in The Autoconf Manual). Many other Autoconf macros call AC_LIBOBJ or AC_REPLACE_FUNCS to populate ‘$(LIBOBJS)’.

Using these variables is very similar to doing conditional compilation using AC_SUBST variables, as described in Conditional compilation of sources. That is, when building a program, ‘$(LIBOBJS)’ and ‘$(ALLOCA)’ should be added to the associated ‘*_LDADD’ variable, or to the ‘*_LIBADD’ variable when building a library. However there is no need to list the corresponding sources in ‘EXTRA_*_SOURCES’ nor to define ‘*_DEPENDENCIES’. Automake automatically adds ‘$(LIBOBJS)’ and ‘$(ALLOCA)’ to the dependencies, and it will discover the list of corresponding source files automatically (by tracing the invocations of the AC_LIBSOURCE Autoconf macros). If you have already defined ‘*_DEPENDENCIES’ explicitly for an unrelated reason, then you either need to add these variables manually, or use ‘EXTRA_*_DEPENDENCIES’ instead of ‘*_DEPENDENCIES’.

These variables are usually used to build a portability library that is linked with all the programs of the project. We now review a sample setup. First, configure.ac contains some checks that affect either LIBOBJS or ALLOCA.

# configure.ac
…
AC_CONFIG_LIBOBJ_DIR([lib])
…
AC_FUNC_MALLOC             dnl May add malloc.$(OBJEXT) to LIBOBJS
AC_FUNC_MEMCMP             dnl May add memcmp.$(OBJEXT) to LIBOBJS
AC_REPLACE_FUNCS([strdup]) dnl May add strdup.$(OBJEXT) to LIBOBJS
AC_FUNC_ALLOCA             dnl May add alloca.$(OBJEXT) to ALLOCA
…
AC_CONFIG_FILES([
  lib/Makefile
  src/Makefile
])
AC_OUTPUT

The AC_CONFIG_LIBOBJ_DIR tells Autoconf that the source files of these object files are to be found in the lib/ directory. Automake can also use this information, otherwise it expects the source files are to be in the directory where the ‘$(LIBOBJS)’ and ‘$(ALLOCA)’ variables are used.

The lib/ directory should therefore contain malloc.c, memcmp.c, strdup.c, alloca.c. Here is its Makefile.am:

# lib/Makefile.am

noinst_LIBRARIES = libcompat.a
libcompat_a_SOURCES =
libcompat_a_LIBADD = $(LIBOBJS) $(ALLOCA)

The library can have any name, of course, and anyway it is not going to be installed: it just holds the replacement versions of the missing or broken functions so we can later link them in. Many projects also include extra functions, specific to the project, in that library: they are simply added on the _SOURCES line.

There is a small trap here, though: ‘$(LIBOBJS)’ and ‘$(ALLOCA)’ might be empty, and building an empty library is not portable. You should ensure that there is always something to put in libcompat.a. Most projects will also add some utility functions in that directory, and list them in libcompat_a_SOURCES, so in practice libcompat.a cannot be empty.

Finally here is how this library could be used from the src/ directory.

# src/Makefile.am

# Link all programs in this directory with libcompat.a
LDADD = ../lib/libcompat.a

bin_PROGRAMS = tool1 tool2 …
tool1_SOURCES = …
tool2_SOURCES = …

When option subdir-objects is not used, as in the above example, the variables ‘$(LIBOBJS)’ or ‘$(ALLOCA)’ can only be used in the directory where their sources lie. E.g., here it would be wrong to use ‘$(LIBOBJS)’ or ‘$(ALLOCA)’ in src/Makefile.am. However if both subdir-objects and AC_CONFIG_LIBOBJ_DIR are used, it is OK to use these variables in other directories. For instance src/Makefile.am could be changed as follows.

# src/Makefile.am

AUTOMAKE_OPTIONS = subdir-objects
LDADD = $(LIBOBJS) $(ALLOCA)

bin_PROGRAMS = tool1 tool2 …
tool1_SOURCES = …
tool2_SOURCES = …

Because ‘$(LIBOBJS)’ and ‘$(ALLOCA)’ contain object file names that end with ‘.$(OBJEXT)’, they are not suitable for Libtool libraries (where the expected object extension is .lo): LTLIBOBJS and LTALLOCA should be used instead.

LTLIBOBJS is defined automatically by Autoconf and should not be defined by hand (as in the past), however at the time of writing LTALLOCA still needs to be defined from ALLOCA manually. See AC_LIBOBJ vs. LIBOBJS in The Autoconf Manual.


8.7 Variables used when building a program

Occasionally it is useful to know which Makefile variables Automake uses for compilations, and in which order (see Flag Variables Ordering); for instance, you might need to do your own compilation in some special cases.

Some variables are inherited from Autoconf; these are CC, CFLAGS, CPPFLAGS, DEFS, LDFLAGS, and LIBS.

There are some additional variables that Automake defines on its own:

AM_CPPFLAGS

The contents of this variable are passed to every compilation that invokes the C preprocessor; it is a list of arguments to the preprocessor. For instance, -I and -D options should be listed here.

Automake already provides some -I options automatically, in a separate variable that is also passed to every compilation that invokes the C preprocessor. In particular it generates ‘-I.’, ‘-I$(srcdir)’, and a -I pointing to the directory holding config.h (if you’ve used AC_CONFIG_HEADERS). You can disable the default -I options using the nostdinc option.

When a file to be included is generated during the build and not part of a distribution tarball, its location is under $(builddir), not under $(srcdir). This matters especially for packages that use header files placed in sub-directories and want to allow builds outside the source tree (see Parallel Build Trees (a.k.a. VPATH Builds)). In that case we recommend to use a pair of -I options, such as, e.g., ‘-Isome/subdir -I$(srcdir)/some/subdir’ or ‘-I$(top_builddir)/some/subdir -I$(top_srcdir)/some/subdir’. Note that the reference to the build tree should come before the reference to the source tree, so that accidentally leftover generated files in the source directory are ignored.

AM_CPPFLAGS is ignored in preference to a per-executable (or per-library) _CPPFLAGS variable if it is defined.

INCLUDES

This does the same job as AM_CPPFLAGS (or any per-target _CPPFLAGS variable if it is used). It is an older name for the same functionality. This variable is deprecated; we suggest using AM_CPPFLAGS and per-target _CPPFLAGS instead.

AM_CFLAGS

This is the variable the Makefile.am author can use to pass in additional C compiler flags. In some situations, this is not used, in preference to the per-executable (or per-library) _CFLAGS.

COMPILE

This is the command used to actually compile a C source file. The file name is appended to form the complete command line.

AM_LDFLAGS

This is the variable the Makefile.am author can use to pass in additional linker flags. In some situations, this is not used, in preference to the per-executable (or per-library) _LDFLAGS.

This is the command used to actually link a C program. It already includes ‘-o $@’ and the usual variable references (for instance, CFLAGS); it takes as “arguments” the names of the object files and libraries to link in. This variable is not used when the linker is overridden with a per-target _LINK variable or per-target flags cause Automake to define such a _LINK variable.


8.8 Yacc and Lex support

Automake has somewhat idiosyncratic support for Yacc and Lex.

Automake assumes that the .c file generated by yacc (or lex) should be named using the basename of the input file. That is, for a yacc source file foo.y, Automake will cause the intermediate file to be named foo.c (as opposed to y.tab.c, which is more traditional).

The extension of a yacc source file is used to determine the extension of the resulting C or C++ source and header files. Note that header files are generated only when the -d Yacc option is used; see below for more information about this flag, and how to specify it. Files with the extension .y will thus be turned into .c sources and .h headers; likewise, .yy will become .cc and .hh, .y++ will become c++ and h++, .yxx will become .cxx and .hxx, and .ypp will become .cpp and .hpp.

Similarly, lex source files can be used to generate C or C++; the extensions .l, .ll, .l++, .lxx, and .lpp are recognized.

You should never explicitly mention the intermediate (C or C++) file in any SOURCES variable; only list the source file.

The intermediate files generated by yacc (or lex) will be included in any distribution that is made. That way the user doesn’t need to have yacc or lex.

If a yacc source file is seen, then your configure.ac must define the variable YACC. This is most easily done by invoking the macro AC_PROG_YACC (see Particular Program Checks in The Autoconf Manual).

When yacc is invoked, it is passed AM_YFLAGS and YFLAGS. The latter is a user variable and the former is intended for the Makefile.am author.

AM_YFLAGS is usually used to pass the -d option to yacc. Automake knows what this means and will automatically adjust its rules to update and distribute the header file built by ‘yacc -d4. What Automake cannot guess, though, is where this header will be used: it is up to you to ensure the header gets built before it is first used. Typically this is necessary in order for dependency tracking to work when the header is included by another file. The common solution is listing the header file in BUILT_SOURCES (see Built Sources) as follows.

BUILT_SOURCES = parser.h
AM_YFLAGS = -d
bin_PROGRAMS = foo
foo_SOURCES = … parser.y …

If a lex source file is seen, then your configure.ac must define the variable LEX. You can use AC_PROG_LEX to do this (see Particular Program Checks in The Autoconf Manual), but using AM_PROG_LEX macro (see Autoconf macros supplied with Automake) is recommended.

When lex is invoked, it is passed AM_LFLAGS and LFLAGS. The latter is a user variable and the former is intended for the Makefile.am author.

When AM_MAINTAINER_MODE (see missing and AM_MAINTAINER_MODE) is used, the rebuild rule for distributed Yacc and Lex sources are only used when maintainer-mode is enabled, or when the files have been erased.

When lex or yacc sources are used, automake -a automatically installs an auxiliary program called ylwrap in your package (see Programs automake might require). This program is used by the build rules to rename the output of these tools, and makes it possible to include multiple yacc (or lex) source files in a single directory. (This is necessary because yacc’s output file name is fixed, and a parallel make could conceivably invoke more than one instance of yacc simultaneously.)

For yacc, simply managing locking is insufficient. The output of yacc always uses the same symbol names internally, so it isn’t possible to link two yacc parsers into the same executable.

We recommend using the following renaming hack used in gdb:

#define yymaxdepth c_maxdepth
#define yyparse c_parse
#define yylex   c_lex
#define yyerror c_error
#define yylval  c_lval
#define yychar  c_char
#define yydebug c_debug
#define yypact  c_pact
#define yyr1    c_r1
#define yyr2    c_r2
#define yydef   c_def
#define yychk   c_chk
#define yypgo   c_pgo
#define yyact   c_act
#define yyexca  c_exca
#define yyerrflag c_errflag
#define yynerrs c_nerrs
#define yyps    c_ps
#define yypv    c_pv
#define yys     c_s
#define yy_yys  c_yys
#define yystate c_state
#define yytmp   c_tmp
#define yyv     c_v
#define yy_yyv  c_yyv
#define yyval   c_val
#define yylloc  c_lloc
#define yyreds  c_reds
#define yytoks  c_toks
#define yylhs   c_yylhs
#define yylen   c_yylen
#define yydefred c_yydefred
#define yydgoto  c_yydgoto
#define yysindex c_yysindex
#define yyrindex c_yyrindex
#define yygindex c_yygindex
#define yytable  c_yytable
#define yycheck  c_yycheck
#define yyname   c_yyname
#define yyrule   c_yyrule

For each define, replace the ‘c_’ prefix with whatever you like. These defines work for bison, byacc, and traditional yaccs. If you find a parser generator that uses a symbol not covered here, please report the new name so it can be added to the list.


8.9 C++ Support

Automake includes full support for C++.

Any package including C++ code must define the output variable CXX in configure.ac; the simplest way to do this is to use the AC_PROG_CXX macro (see Particular Program Checks in The Autoconf Manual).

A few additional variables are defined when a C++ source file is seen:

CXX

The name of the C++ compiler.

CXXFLAGS

Any flags to pass to the C++ compiler.

AM_CXXFLAGS

The maintainer’s variant of CXXFLAGS.

CXXCOMPILE

The command used to actually compile a C++ source file. The file name is appended to form the complete command line.

The command used to actually link a C++ program.


8.10 Objective C Support

Automake includes some support for Objective C.

Any package including Objective C code must define the output variable OBJC in configure.ac; the simplest way to do this is to use the AC_PROG_OBJC macro (see Particular Program Checks in The Autoconf Manual).

A few additional variables are defined when an Objective C source file is seen:

OBJC

The name of the Objective C compiler.

OBJCFLAGS

Any flags to pass to the Objective C compiler.

AM_OBJCFLAGS

The maintainer’s variant of OBJCFLAGS.

OBJCCOMPILE

The command used to actually compile an Objective C source file. The file name is appended to form the complete command line.

The command used to actually link an Objective C program.


8.11 Objective C++ Support

Automake includes some support for Objective C++.

Any package including Objective C++ code must define the output variable OBJCXX in configure.ac; the simplest way to do this is to use the AC_PROG_OBJCXX macro (see Particular Program Checks in The Autoconf Manual).

A few additional variables are defined when an Objective C++ source file is seen:

OBJCXX

The name of the Objective C++ compiler.

OBJCXXFLAGS

Any flags to pass to the Objective C++ compiler.

AM_OBJCXXFLAGS

The maintainer’s variant of OBJCXXFLAGS.

OBJCXXCOMPILE

The command used to actually compile an Objective C++ source file. The file name is appended to form the complete command line.

The command used to actually link an Objective C++ program.


8.12 Unified Parallel C Support

Automake includes some support for Unified Parallel C.

Any package including Unified Parallel C code must define the output variable UPC in configure.ac; the simplest way to do this is to use the AM_PROG_UPC macro (see Public Macros).

A few additional variables are defined when a Unified Parallel C source file is seen:

UPC

The name of the Unified Parallel C compiler.

UPCFLAGS

Any flags to pass to the Unified Parallel C compiler.

AM_UPCFLAGS

The maintainer’s variant of UPCFLAGS.

UPCCOMPILE

The command used to actually compile a Unified Parallel C source file. The file name is appended to form the complete command line.

The command used to actually link a Unified Parallel C program.


8.13 Assembly Support

Automake includes some support for assembly code. There are two forms of assembler files: normal (*.s) and preprocessed by CPP (*.S or *.sx).

The variable CCAS holds the name of the compiler used to build assembly code. This compiler must work a bit like a C compiler; in particular it must accept -c and -o. The values of CCASFLAGS and AM_CCASFLAGS (or its per-target definition) is passed to the compilation. For preprocessed files, DEFS, DEFAULT_INCLUDES, INCLUDES, CPPFLAGS and AM_CPPFLAGS are also used.

The autoconf macro AM_PROG_AS will define CCAS and CCASFLAGS for you (unless they are already set, it simply sets CCAS to the C compiler and CCASFLAGS to the C compiler flags), but you are free to define these variables by other means.

Only the suffixes .s, .S, and .sx are recognized by automake as being files containing assembly code.


8.14 Fortran 77 Support

Automake includes full support for Fortran 77.

Any package including Fortran 77 code must define the output variable F77 in configure.ac; the simplest way to do this is to use the AC_PROG_F77 macro (see Particular Program Checks in The Autoconf Manual).

A few additional variables are defined when a Fortran 77 source file is seen:

F77

The name of the Fortran 77 compiler.

FFLAGS

Any flags to pass to the Fortran 77 compiler.

AM_FFLAGS

The maintainer’s variant of FFLAGS.

RFLAGS

Any flags to pass to the Ratfor compiler.

AM_RFLAGS

The maintainer’s variant of RFLAGS.

F77COMPILE

The command used to actually compile a Fortran 77 source file. The file name is appended to form the complete command line.

The command used to actually link a pure Fortran 77 program or shared library.

Automake can handle preprocessing Fortran 77 and Ratfor source files in addition to compiling them5. Automake also contains some support for creating programs and shared libraries that are a mixture of Fortran 77 and other languages (see Mixing Fortran 77 With C and C++).

These issues are covered in the following sections.


8.14.1 Preprocessing Fortran 77

N.f is made automatically from N.F or N.r. This rule runs just the preprocessor to convert a preprocessable Fortran 77 or Ratfor source file into a strict Fortran 77 source file. The precise command used is as follows:

.F

$(F77) -F $(DEFS) $(INCLUDES) $(AM_CPPFLAGS) $(CPPFLAGS)
$(AM_FFLAGS) $(FFLAGS)

.r

$(F77) -F $(AM_FFLAGS) $(FFLAGS) $(AM_RFLAGS) $(RFLAGS)


8.14.2 Compiling Fortran 77 Files

N.o is made automatically from N.f, N.F or N.r by running the Fortran 77 compiler. The precise command used is as follows:

.f

$(F77) -c $(AM_FFLAGS) $(FFLAGS)

.F

$(F77) -c $(DEFS) $(INCLUDES) $(AM_CPPFLAGS) $(CPPFLAGS)
$(AM_FFLAGS) $(FFLAGS)

.r

$(F77) -c $(AM_FFLAGS) $(FFLAGS) $(AM_RFLAGS) $(RFLAGS)


8.14.3 Mixing Fortran 77 With C and C++

Automake currently provides limited support for creating programs and shared libraries that are a mixture of Fortran 77 and C and/or C++. However, there are many other issues related to mixing Fortran 77 with other languages that are not (currently) handled by Automake, but that are handled by other packages6.

Automake can help in two ways:

  1. Automatic selection of the linker depending on which combinations of source code.
  2. Automatic selection of the appropriate linker flags (e.g., -L and -l) to pass to the automatically selected linker in order to link in the appropriate Fortran 77 intrinsic and run-time libraries.

    These extra Fortran 77 linker flags are supplied in the output variable FLIBS by the AC_F77_LIBRARY_LDFLAGS Autoconf macro. See Fortran Compiler Characteristics in The Autoconf Manual.

If Automake detects that a program or shared library (as mentioned in some _PROGRAMS or _LTLIBRARIES primary) contains source code that is a mixture of Fortran 77 and C and/or C++, then it requires that the macro AC_F77_LIBRARY_LDFLAGS be called in configure.ac, and that either $(FLIBS) appear in the appropriate _LDADD (for programs) or _LIBADD (for shared libraries) variables. It is the responsibility of the person writing the Makefile.am to make sure that ‘$(FLIBS)’ appears in the appropriate _LDADD or _LIBADD variable.

For example, consider the following Makefile.am:

bin_PROGRAMS = foo
foo_SOURCES  = main.cc foo.f
foo_LDADD    = libfoo.la $(FLIBS)

pkglib_LTLIBRARIES = libfoo.la
libfoo_la_SOURCES  = bar.f baz.c zardoz.cc
libfoo_la_LIBADD   = $(FLIBS)

In this case, Automake will insist that AC_F77_LIBRARY_LDFLAGS is mentioned in configure.ac. Also, if ‘$(FLIBS)’ hadn’t been mentioned in foo_LDADD and libfoo_la_LIBADD, then Automake would have issued a warning.


8.14.3.1 How the Linker is Chosen

When a program or library mixes several languages, Automake choose the linker according to the following priorities. (The names in parentheses are the variables containing the link command.)

  1. Native Java (GCJLINK)
  2. Objective C++ (OBJCXXLINK)
  3. C++ (CXXLINK)
  4. Fortran 77 (F77LINK)
  5. Fortran (FCLINK)
  6. Objective C (OBJCLINK)
  7. Unified Parallel C (UPCLINK)
  8. C (LINK)

For example, if Fortran 77, C and C++ source code is compiled into a program, then the C++ linker will be used. In this case, if the C or Fortran 77 linkers required any special libraries that weren’t included by the C++ linker, then they must be manually added to an _LDADD or _LIBADD variable by the user writing the Makefile.am.

Automake only looks at the file names listed in _SOURCES variables to choose the linker, and defaults to the C linker. Sometimes this is inconvenient because you are linking against a library written in another language and would like to set the linker more appropriately. See Libtool Convenience Libraries, for a trick with nodist_EXTRA_…_SOURCES.

A per-target _LINK variable will override the above selection. Per-target link flags will cause Automake to write a per-target _LINK variable according to the language chosen as above.


8.15 Fortran 9x Support

Automake includes support for Fortran 9x.

Any package including Fortran 9x code must define the output variable FC in configure.ac; the simplest way to do this is to use the AC_PROG_FC macro (see Particular Program Checks in The Autoconf Manual).

A few additional variables are defined when a Fortran 9x source file is seen:

FC

The name of the Fortran 9x compiler.

FCFLAGS

Any flags to pass to the Fortran 9x compiler.

AM_FCFLAGS

The maintainer’s variant of FCFLAGS.

FCCOMPILE

The command used to actually compile a Fortran 9x source file. The file name is appended to form the complete command line.

The command used to actually link a pure Fortran 9x program or shared library.


8.15.1 Compiling Fortran 9x Files

file.o is made automatically from file.f90, file.f95, file.f03, or file.f08 by running the Fortran 9x compiler. The precise command used is as follows:

.f90

$(FC) $(AM_FCFLAGS) $(FCFLAGS) -c $(FCFLAGS_f90) $<

.f95

$(FC) $(AM_FCFLAGS) $(FCFLAGS) -c $(FCFLAGS_f95) $<

.f03

$(FC) $(AM_FCFLAGS) $(FCFLAGS) -c $(FCFLAGS_f03) $<

.f08

$(FC) $(AM_FCFLAGS) $(FCFLAGS) -c $(FCFLAGS_f08) $<


8.16 Compiling Java sources using gcj

Automake includes support for natively compiled Java, using gcj, the Java front end to the GNU Compiler Collection (rudimentary support for compiling Java to bytecode using the javac compiler is also present, albeit deprecated; see Java bytecode compilation (deprecated)).

Any package including Java code to be compiled must define the output variable GCJ in configure.ac; the variable GCJFLAGS must also be defined somehow (either in configure.ac or Makefile.am). The simplest way to do this is to use the AM_PROG_GCJ macro.

By default, programs including Java source files are linked with gcj.

As always, the contents of AM_GCJFLAGS are passed to every compilation invoking gcj (in its role as an ahead-of-time compiler, when invoking it to create .class files, AM_JAVACFLAGS is used instead). If it is necessary to pass options to gcj from Makefile.am, this variable, and not the user variable GCJFLAGS, should be used.

gcj can be used to compile .java, .class, .zip, or .jar files.

When linking, gcj requires that the main class be specified using the --main= option. The easiest way to do this is to use the _LDFLAGS variable for the program.


8.17 Vala Support

Automake provides initial support for Vala (http://www.vala-project.org/). This requires valac version 0.7.0 or later, and currently requires the user to use GNU make.

foo_SOURCES = foo.vala bar.vala zardoc.c

Any .vala file listed in a _SOURCES variable will be compiled into C code by the Vala compiler. The generated .c files are distributed. The end user does not need to have a Vala compiler installed.

Automake ships with an Autoconf macro called AM_PROG_VALAC that will locate the Vala compiler and optionally check its version number.

Macro: AM_PROG_VALAC ([minimum-version], [action-if-found],

[action-if-not-found]) Search for a Vala compiler in PATH. If it is found, the variable VALAC is set to point to it (see below for more details). This macro takes three optional arguments. The first argument, if present, is the minimum version of the Vala compiler required to compile this package. If a compiler is found and satisfies minimum-version, then action-if-found is run (this defaults to do nothing). Otherwise, action-if-not-found is run. If action-if-not-found is not specified, the default value is to print a warning in case no compiler is found, or if a too-old version of the compiler is found.

There are a few variables that are used when compiling Vala sources:

VALAC

Absolute path to the Vala compiler, or simply ‘valac’ if no suitable compiler Vala could be found at configure runtime.

VALAFLAGS

Additional arguments for the Vala compiler.

AM_VALAFLAGS

The maintainer’s variant of VALAFLAGS.

lib_LTLIBRARIES = libfoo.la
libfoo_la_SOURCES = foo.vala

Note that currently, you cannot use per-target *_VALAFLAGS (see Why are object files sometimes renamed?) to produce different C files from one Vala source file.


8.18 Support for Other Languages

Automake currently only includes full support for C, C++ (see C++ Support), Objective C (see Objective C Support), Objective C++ (see Objective C++ Support), Fortran 77 (see Fortran 77 Support), Fortran 9x (see Fortran 9x Support), and Java (see Compiling Java sources using gcj). There is only rudimentary support for other languages, support for which will be improved based on user demand.

Some limited support for adding your own languages is available via the suffix rule handling (see Handling new file extensions).


8.19 Automatic dependency tracking

As a developer it is often painful to continually update the Makefile.am whenever the include-file dependencies change in a project. Automake supplies a way to automatically track dependency changes (see Automatic Dependency Tracking).

Automake always uses complete dependencies for a compilation, including system headers. Automake’s model is that dependency computation should be a side effect of the build. To this end, dependencies are computed by running all compilations through a special wrapper program called depcomp. depcomp understands how to coax many different C and C++ compilers into generating dependency information in the format it requires. ‘automake -a’ will install depcomp into your source tree for you. If depcomp can’t figure out how to properly invoke your compiler, dependency tracking will simply be disabled for your build.

Experience with earlier versions of Automake (see Dependency Tracking Evolution in Brief History of Automake) taught us that it is not reliable to generate dependencies only on the maintainer’s system, as configurations vary too much. So instead Automake implements dependency tracking at build time.

Automatic dependency tracking can be suppressed by putting no-dependencies in the variable AUTOMAKE_OPTIONS, or passing no-dependencies as an argument to AM_INIT_AUTOMAKE (this should be the preferred way). Or, you can invoke automake with the -i option. Dependency tracking is enabled by default.

The person building your package also can choose to disable dependency tracking by configuring with --disable-dependency-tracking.


8.20 Support for executable extensions

On some platforms, such as Windows, executables are expected to have an extension such as .exe. On these platforms, some compilers (GCC among them) will automatically generate foo.exe when asked to generate foo.

Automake provides mostly-transparent support for this. Unfortunately mostly doesn’t yet mean fully. Until the English dictionary is revised, you will have to assist Automake if your package must support those platforms.

One thing you must be aware of is that, internally, Automake rewrites something like this:

bin_PROGRAMS = liver

to this:

bin_PROGRAMS = liver$(EXEEXT)

The targets Automake generates are likewise given the ‘$(EXEEXT)’ extension.

The variables TESTS and XFAIL_TESTS (see Simple Tests) are also rewritten if they contain filenames that have been declared as programs in the same Makefile. (This is mostly useful when some programs from check_PROGRAMS are listed in TESTS.)

However, Automake cannot apply this rewriting to configure substitutions. This means that if you are conditionally building a program using such a substitution, then your configure.ac must take care to add ‘$(EXEEXT)’ when constructing the output variable.

Sometimes maintainers like to write an explicit link rule for their program. Without executable extension support, this is easy—you simply write a rule whose target is the name of the program. However, when executable extension support is enabled, you must instead add the ‘$(EXEEXT)’ suffix.

This might be a nuisance for maintainers who know their package will never run on a platform that has executable extensions. For those maintainers, the no-exeext option (see Changing Automake’s Behavior) will disable this feature. This works in a fairly ugly way; if no-exeext is seen, then the presence of a rule for a target named foo in Makefile.am will override an automake-generated rule for ‘foo$(EXEEXT)’. Without the no-exeext option, this use will give a diagnostic.


9 Other Derived Objects

Automake can handle derived objects that are not C programs. Sometimes the support for actually building such objects must be explicitly supplied, but Automake will still automatically handle installation and distribution.


9.1 Executable Scripts

It is possible to define and install programs that are scripts. Such programs are listed using the SCRIPTS primary name. When the script is distributed in its final, installable form, the Makefile usually looks as follows:

# Install my_script in $(bindir) and distribute it.
dist_bin_SCRIPTS = my_script

Scripts are not distributed by default; as we have just seen, those that should be distributed can be specified using a dist_ prefix as with other primaries.

Scripts can be installed in bindir, sbindir, libexecdir, pkglibexecdir, or pkgdatadir.

Scripts that need not be installed can be listed in noinst_SCRIPTS, and among them, those which are needed only by ‘make check’ should go in check_SCRIPTS.

When a script needs to be built, the Makefile.am should include the appropriate rules. For instance the automake program itself is a Perl script that is generated from automake.in. Here is how this is handled:

bin_SCRIPTS = automake
CLEANFILES = $(bin_SCRIPTS)
EXTRA_DIST = automake.in

do_subst = sed -e 's,[@]datadir[@],$(datadir),g' \
            -e 's,[@]PERL[@],$(PERL),g' \
            -e 's,[@]PACKAGE[@],$(PACKAGE),g' \
            -e 's,[@]VERSION[@],$(VERSION),g' \
            …

automake: automake.in Makefile
        $(do_subst) < $(srcdir)/automake.in > automake
        chmod +x automake

Such scripts for which a build rule has been supplied need to be deleted explicitly using CLEANFILES (see What Gets Cleaned), and their sources have to be distributed, usually with EXTRA_DIST (see Basics of Distribution).

Another common way to build scripts is to process them from configure with AC_CONFIG_FILES. In this situation Automake knows which files should be cleaned and distributed, and what the rebuild rules should look like.

For instance if configure.ac contains

AC_CONFIG_FILES([src/my_script], [chmod +x src/my_script])

to build src/my_script from src/my_script.in, then a src/Makefile.am to install this script in $(bindir) can be as simple as

bin_SCRIPTS = my_script
CLEANFILES = $(bin_SCRIPTS)

There is no need for EXTRA_DIST or any build rule: Automake infers them from AC_CONFIG_FILES (see Configuration requirements). CLEANFILES is still useful, because by default Automake will clean targets of AC_CONFIG_FILES in distclean, not clean.

Although this looks simpler, building scripts this way has one drawback: directory variables such as $(datadir) are not fully expanded and may refer to other directory variables.


9.2 Header files

Header files that must be installed are specified by the HEADERS family of variables. Headers can be installed in includedir, oldincludedir, pkgincludedir or any other directory you may have defined (see The Uniform Naming Scheme). For instance,

include_HEADERS = foo.h bar/bar.h

will install the two files as $(includedir)/foo.h and $(includedir)/bar.h.

The nobase_ prefix is also supported,

nobase_include_HEADERS = foo.h bar/bar.h

will install the two files as $(includedir)/foo.h and $(includedir)/bar/bar.h (see An Alternative Approach to Subdirectories).

Usually, only header files that accompany installed libraries need to be installed. Headers used by programs or convenience libraries are not installed. The noinst_HEADERS variable can be used for such headers. However when the header actually belongs to a single convenience library or program, we recommend listing it in the program’s or library’s _SOURCES variable (see Defining program sources) instead of in noinst_HEADERS. This is clearer for the Makefile.am reader. noinst_HEADERS would be the right variable to use in a directory containing only headers and no associated library or program.

All header files must be listed somewhere; in a _SOURCES variable or in a _HEADERS variable. Missing ones will not appear in the distribution.

For header files that are built and must not be distributed, use the nodist_ prefix as in nodist_include_HEADERS or nodist_prog_SOURCES. If these generated headers are needed during the build, you must also ensure they exist before they are used (see Built Sources).


9.3 Architecture-independent data files

Automake supports the installation of miscellaneous data files using the DATA family of variables.

Such data can be installed in the directories datadir, sysconfdir, sharedstatedir, localstatedir, or pkgdatadir.

By default, data files are not included in a distribution. Of course, you can use the dist_ prefix to change this on a per-variable basis.

Here is how Automake declares its auxiliary data files:

dist_pkgdata_DATA = clean-kr.am clean.am …

9.4 Built Sources

Because Automake’s automatic dependency tracking works as a side-effect of compilation (see Automatic dependency tracking) there is a bootstrap issue: a target should not be compiled before its dependencies are made, but these dependencies are unknown until the target is first compiled.

Ordinarily this is not a problem, because dependencies are distributed sources: they preexist and do not need to be built. Suppose that foo.c includes foo.h. When it first compiles foo.o, make only knows that foo.o depends on foo.c. As a side-effect of this compilation depcomp records the foo.h dependency so that following invocations of make will honor it. In these conditions, it’s clear there is no problem: either foo.o doesn’t exist and has to be built (regardless of the dependencies), or accurate dependencies exist and they can be used to decide whether foo.o should be rebuilt.

It’s a different story if foo.h doesn’t exist by the first make run. For instance, there might be a rule to build foo.h. This time file.o’s build will fail because the compiler can’t find foo.h. make failed to trigger the rule to build foo.h first by lack of dependency information.

The BUILT_SOURCES variable is a workaround for this problem. A source file listed in BUILT_SOURCES is made on ‘make all’ or ‘make check’ (or even ‘make install’) before other targets are processed. However, such a source file is not compiled unless explicitly requested by mentioning it in some other _SOURCES variable.

So, to conclude our introductory example, we could use ‘BUILT_SOURCES = foo.h’ to ensure foo.h gets built before any other target (including foo.o) during ‘make all’ or ‘make check’.

BUILT_SOURCES is actually a bit of a misnomer, as any file which must be created early in the build process can be listed in this variable. Moreover, all built sources do not necessarily have to be listed in BUILT_SOURCES. For instance, a generated .c file doesn’t need to appear in BUILT_SOURCES (unless it is included by another source), because it’s a known dependency of the associated object.

It might be important to emphasize that BUILT_SOURCES is honored only by ‘make all’, ‘make check’ and ‘make install’. This means you cannot build a specific target (e.g., ‘make foo’) in a clean tree if it depends on a built source. However it will succeed if you have run ‘make all’ earlier, because accurate dependencies are already available.

The next section illustrates and discusses the handling of built sources on a toy example.


9.4.1 Built Sources Example

Suppose that foo.c includes bindir.h, which is installation-dependent and not distributed: it needs to be built. Here bindir.h defines the preprocessor macro bindir to the value of the make variable bindir (inherited from configure).

We suggest several implementations below. It’s not meant to be an exhaustive listing of all ways to handle built sources, but it will give you a few ideas if you encounter this issue.

First Try

This first implementation will illustrate the bootstrap issue mentioned in the previous section (see Built Sources).

Here is a tentative Makefile.am.

# This won't work.
bin_PROGRAMS = foo
foo_SOURCES = foo.c
nodist_foo_SOURCES = bindir.h
CLEANFILES = bindir.h
bindir.h: Makefile
        echo '#define bindir "$(bindir)"' >$@

This setup doesn’t work, because Automake doesn’t know that foo.c includes bindir.h. Remember, automatic dependency tracking works as a side-effect of compilation, so the dependencies of foo.o will be known only after foo.o has been compiled (see Automatic dependency tracking). The symptom is as follows.

% make
source='foo.c' object='foo.o' libtool=no \
depfile='.deps/foo.Po' tmpdepfile='.deps/foo.TPo' \
depmode=gcc /bin/sh ./depcomp \
gcc -I. -I. -g -O2 -c `test -f 'foo.c' || echo './'`foo.c
foo.c:2: bindir.h: No such file or directory
make: *** [foo.o] Error 1

In this example bindir.h is not distributed nor installed, and it is not even being built on-time. One may wonder if the ‘nodist_foo_SOURCES = bindir.h’ line has any use at all. This line simply states that bindir.h is a source of foo, so for instance, it should be inspected while generating tags (see Interfacing to etags). In other words, it does not help our present problem, and the build would fail identically without it.

Using BUILT_SOURCES

A solution is to require bindir.h to be built before anything else. This is what BUILT_SOURCES is meant for (see Built Sources).

bin_PROGRAMS = foo
foo_SOURCES = foo.c
nodist_foo_SOURCES = bindir.h
BUILT_SOURCES = bindir.h
CLEANFILES = bindir.h
bindir.h: Makefile
        echo '#define bindir "$(bindir)"' >$@

See how bindir.h gets built first:

% make
echo '#define bindir "/usr/local/bin"' >bindir.h
make  all-am
make[1]: Entering directory `/home/adl/tmp'
source='foo.c' object='foo.o' libtool=no \
depfile='.deps/foo.Po' tmpdepfile='.deps/foo.TPo' \
depmode=gcc /bin/sh ./depcomp \
gcc -I. -I. -g -O2 -c `test -f 'foo.c' || echo './'`foo.c
gcc  -g -O2   -o foo  foo.o
make[1]: Leaving directory `/home/adl/tmp'

However, as said earlier, BUILT_SOURCES applies only to the all, check, and install targets. It still fails if you try to run ‘make foo’ explicitly:

% make clean
test -z "bindir.h" || rm -f bindir.h
test -z "foo" || rm -f foo
rm -f *.o
% : > .deps/foo.Po # Suppress previously recorded dependencies
% make foo
source='foo.c' object='foo.o' libtool=no \
depfile='.deps/foo.Po' tmpdepfile='.deps/foo.TPo' \
depmode=gcc /bin/sh ./depcomp \
gcc -I. -I. -g -O2 -c `test -f 'foo.c' || echo './'`foo.c
foo.c:2: bindir.h: No such file or directory
make: *** [foo.o] Error 1

Recording Dependencies manually

Usually people are happy enough with BUILT_SOURCES because they never build targets such as ‘make foo’ before ‘make all’, as in the previous example. However if this matters to you, you can avoid BUILT_SOURCES and record such dependencies explicitly in the Makefile.am.

bin_PROGRAMS = foo
foo_SOURCES = foo.c
nodist_foo_SOURCES = bindir.h
foo.$(OBJEXT): bindir.h
CLEANFILES = bindir.h
bindir.h: Makefile
        echo '#define bindir "$(bindir)"' >$@

You don’t have to list all the dependencies of foo.o explicitly, only those that might need to be built. If a dependency already exists, it will not hinder the first compilation and will be recorded by the normal dependency tracking code. (Note that after this first compilation the dependency tracking code will also have recorded the dependency between foo.o and bindir.h; so our explicit dependency is really useful to the first build only.)

Adding explicit dependencies like this can be a bit dangerous if you are not careful enough. This is due to the way Automake tries not to overwrite your rules (it assumes you know better than it). ‘foo.$(OBJEXT): bindir.h’ supersedes any rule Automake may want to output to build ‘foo.$(OBJEXT)’. It happens to work in this case because Automake doesn’t have to output any ‘foo.$(OBJEXT):’ target: it relies on a suffix rule instead (i.e., ‘.c.$(OBJEXT):’). Always check the generated Makefile.in if you do this.

Build bindir.h from configure

It’s possible to define this preprocessor macro from configure, either in config.h (see Defining Directories in The Autoconf Manual), or by processing a bindir.h.in file using AC_CONFIG_FILES (see Configuration Actions in The Autoconf Manual).

At this point it should be clear that building bindir.h from configure works well for this example. bindir.h will exist before you build any target, hence will not cause any dependency issue.

The Makefile can be shrunk as follows. We do not even have to mention bindir.h.

bin_PROGRAMS = foo
foo_SOURCES = foo.c

However, it’s not always possible to build sources from configure, especially when these sources are generated by a tool that needs to be built first.

Build bindir.c, not bindir.h.

Another attractive idea is to define bindir as a variable or function exported from bindir.o, and build bindir.c instead of bindir.h.

noinst_PROGRAMS = foo
foo_SOURCES = foo.c bindir.h
nodist_foo_SOURCES = bindir.c
CLEANFILES = bindir.c
bindir.c: Makefile
        echo 'const char bindir[] = "$(bindir)";' >$@

bindir.h contains just the variable’s declaration and doesn’t need to be built, so it won’t cause any trouble. bindir.o is always dependent on bindir.c, so bindir.c will get built first.

Which is best?

There is no panacea, of course. Each solution has its merits and drawbacks.

You cannot use BUILT_SOURCES if the ability to run ‘make foo’ on a clean tree is important to you.

You won’t add explicit dependencies if you are leery of overriding an Automake rule by mistake.

Building files from ./configure is not always possible, neither is converting .h files into .c files.


10 Other GNU Tools

Since Automake is primarily intended to generate Makefile.ins for use in GNU programs, it tries hard to interoperate with other GNU tools.


10.1 Emacs Lisp

Automake provides some support for Emacs Lisp. The LISP primary is used to hold a list of .el files. Possible prefixes for this primary are lisp_ and noinst_. Note that if lisp_LISP is defined, then configure.ac must run AM_PATH_LISPDIR (see Autoconf macros supplied with Automake).

Lisp sources are not distributed by default. You can prefix the LISP primary with dist_, as in dist_lisp_LISP or dist_noinst_LISP, to indicate that these files should be distributed.

Automake will byte-compile all Emacs Lisp source files using the Emacs found by AM_PATH_LISPDIR, if any was found. When performing such byte-compilation, the flags specified in the (developer-reserved) AM_ELCFLAGS and (user-reserved) ELCFLAGS make variables will be passed to the Emacs invocation.

Byte-compiled Emacs Lisp files are not portable among all versions of Emacs, so it makes sense to turn this off if you expect sites to have more than one version of Emacs installed. Furthermore, many packages don’t actually benefit from byte-compilation. Still, we recommend that you byte-compile your Emacs Lisp sources. It is probably better for sites with strange setups to cope for themselves than to make the installation less nice for everybody else.

There are two ways to avoid byte-compiling. Historically, we have recommended the following construct.

lisp_LISP = file1.el file2.el
ELCFILES =

ELCFILES is an internal Automake variable that normally lists all .elc files that must be byte-compiled. Automake defines ELCFILES automatically from lisp_LISP. Emptying this variable explicitly prevents byte-compilation.

Since Automake 1.8, we now recommend using lisp_DATA instead:

lisp_DATA = file1.el file2.el

Note that these two constructs are not equivalent. _LISP will not install a file if Emacs is not installed, while _DATA will always install its files.


Next: , Previous: , Up: Other GNU Tools   [Contents][Index]

10.2 Gettext

If AM_GNU_GETTEXT is seen in configure.ac, then Automake turns on support for GNU gettext, a message catalog system for internationalization (see Introduction in GNU gettext utilities).

The gettext support in Automake requires the addition of one or two subdirectories to the package: po and possibly also intl. The latter is needed if AM_GNU_GETTEXT is not invoked with the ‘external’ argument, or if AM_GNU_GETTEXT_INTL_SUBDIR is used. Automake ensures that these directories exist and are mentioned in SUBDIRS.


10.3 Libtool

Automake provides support for GNU Libtool (see Introduction in The Libtool Manual) with the LTLIBRARIES primary. See Building a Shared Library.


Next: , Previous: , Up: Other GNU Tools   [Contents][Index]

10.4 Java bytecode compilation (deprecated)

Automake provides some minimal support for Java bytecode compilation with the JAVA primary (in addition to the support for compiling Java to native machine code; see Compiling Java sources using gcj). Note however that the interface and most features described here are deprecated. Future Automake releases will strive to provide a better and cleaner interface, which however won’t be backward-compatible; the present interface will probably be removed altogether some time after the introduction of the new interface (if that ever materializes). In any case, the current JAVA primary features are frozen and will no longer be developed, not even to take bug fixes.

Any .java files listed in a _JAVA variable will be compiled with JAVAC at build time. By default, .java files are not included in the distribution, you should use the dist_ prefix to distribute them.

Here is a typical setup for distributing .java files and installing the .class files resulting from their compilation.

javadir = $(datadir)/java
dist_java_JAVA = a.java b.java …

Currently Automake enforces the restriction that only one _JAVA primary can be used in a given Makefile.am. The reason for this restriction is that, in general, it isn’t possible to know which .class files were generated from which .java files, so it would be impossible to know which files to install where. For instance, a .java file can define multiple classes; the resulting .class file names cannot be predicted without parsing the .java file.

There are a few variables that are used when compiling Java sources:

JAVAC

The name of the Java compiler. This defaults to ‘javac’.

JAVACFLAGS

The flags to pass to the compiler. This is considered to be a user variable (see Variables reserved for the user).

AM_JAVACFLAGS

More flags to pass to the Java compiler. This, and not JAVACFLAGS, should be used when it is necessary to put Java compiler flags into Makefile.am.

JAVAROOT

The value of this variable is passed to the -d option to javac. It defaults to ‘$(top_builddir)’.

CLASSPATH_ENV

This variable is a shell expression that is used to set the CLASSPATH environment variable on the javac command line. (In the future we will probably handle class path setting differently.)


10.5 Python

Automake provides support for Python compilation with the PYTHON primary. A typical setup is to call AM_PATH_PYTHON in configure.ac and use a line like the following in Makefile.am:

python_PYTHON = tree.py leave.py

Any files listed in a _PYTHON variable will be byte-compiled with py-compile at install time. py-compile actually creates both standard (.pyc) and optimized (.pyo) byte-compiled versions of the source files. Note that because byte-compilation occurs at install time, any files listed in noinst_PYTHON will not be compiled. Python source files are included in the distribution by default, prepend nodist_ (as in nodist_python_PYTHON) to omit them.

Automake ships with an Autoconf macro called AM_PATH_PYTHON that will determine some Python-related directory variables (see below). If you have called AM_PATH_PYTHON from configure.ac, then you may use the variables python_PYTHON or pkgpython_PYTHON to list Python source files in your Makefile.am, depending on where you want your files installed (see the definitions of pythondir and pkgpythondir below).

Macro: AM_PATH_PYTHON ([version], [action-if-found],

[action-if-not-found])

Search for a Python interpreter on the system. This macro takes three optional arguments. The first argument, if present, is the minimum version of Python required for this package: AM_PATH_PYTHON will skip any Python interpreter that is older than version. If an interpreter is found and satisfies version, then action-if-found is run. Otherwise, action-if-not-found is run.

If action-if-not-found is not specified, as in the following example, the default is to abort configure.

AM_PATH_PYTHON([2.2])

This is fine when Python is an absolute requirement for the package. If Python >= 2.5 was only optional to the package, AM_PATH_PYTHON could be called as follows.

AM_PATH_PYTHON([2.5],, [:])

If the PYTHON variable is set when AM_PATH_PYTHON is called, then that will be the only Python interpreter that is tried.

AM_PATH_PYTHON creates the following output variables based on the Python installation found during configuration.

PYTHON

The name of the Python executable, or ‘:’ if no suitable interpreter could be found.

Assuming action-if-not-found is used (otherwise ./configure will abort if Python is absent), the value of PYTHON can be used to setup a conditional in order to disable the relevant part of a build as follows.

AM_PATH_PYTHON(,, [:])
AM_CONDITIONAL([HAVE_PYTHON], [test "$PYTHON" != :])
PYTHON_VERSION

The Python version number, in the form major.minor (e.g., ‘2.5’). This is currently the value of ‘sys.version[:3]’.

PYTHON_PREFIX

The string ‘${prefix}’. This term may be used in future work that needs the contents of Python’s ‘sys.prefix’, but general consensus is to always use the value from configure.

PYTHON_EXEC_PREFIX

The string ‘${exec_prefix}’. This term may be used in future work that needs the contents of Python’s ‘sys.exec_prefix’, but general consensus is to always use the value from configure.

PYTHON_PLATFORM

The canonical name used by Python to describe the operating system, as given by ‘sys.platform’. This value is sometimes needed when building Python extensions.

pythondir

The directory name for the site-packages subdirectory of the standard Python install tree.

pkgpythondir

This is the directory under pythondir that is named after the package. That is, it is ‘$(pythondir)/$(PACKAGE)’. It is provided as a convenience.

pyexecdir

This is the directory where Python extension modules (shared libraries) should be installed. An extension module written in C could be declared as follows to Automake:

pyexec_LTLIBRARIES = quaternion.la
quaternion_la_SOURCES = quaternion.c support.c support.h
quaternion_la_LDFLAGS = -avoid-version -module
pkgpyexecdir

This is a convenience variable that is defined as ‘$(pyexecdir)/$(PACKAGE)’.

All of these directory variables have values that start with either ‘${prefix}’ or ‘${exec_prefix}’ unexpanded. This works fine in Makefiles, but it makes these variables hard to use in configure. This is mandated by the GNU coding standards, so that the user can run ‘make prefix=/foo install’. The Autoconf manual has a section with more details on this topic (see Installation Directory Variables in The Autoconf Manual). See also Installing to Hard-Coded Locations.


11 Building documentation

Currently Automake provides support for Texinfo and man pages.


11.1 Texinfo

If the current directory contains Texinfo source, you must declare it with the TEXINFOS primary. Generally Texinfo files are converted into info, and thus the info_TEXINFOS variable is most commonly used here. Any Texinfo source file should have the .texi extension. Automake also accepts .txi or .texinfo extensions, but their use is discouraged now, and will elicit runtime warnings.

Automake generates rules to build .info, .dvi, .ps, .pdf and .html files from your Texinfo sources. Following the GNU Coding Standards, only the .info files are built by ‘make all’ and installed by ‘make install’ (unless you use no-installinfo, see below). Furthermore, .info files are automatically distributed so that Texinfo is not a prerequisite for installing your package.

It is worth noting that, contrary to what happens with the other formats, the generated .info files are by default placed in srcdir rather than in the builddir. This can be changed with the info-in-builddir option.

Other documentation formats can be built on request by ‘make dvi’, ‘make ps’, ‘make pdf’ and ‘make html’, and they can be installed with ‘make install-dvi’, ‘make install-ps’, ‘make install-pdf’ and ‘make install-html’ explicitly. ‘make uninstall’ will remove everything: the Texinfo documentation installed by default as well as all the above optional formats.

All of these targets can be extended using ‘-local’ rules (see Extending Automake Rules).

If the .texi file @includes version.texi, then that file will be automatically generated. The file version.texi defines four Texinfo flags you can reference using @value{EDITION}, @value{VERSION}, @value{UPDATED}, and @value{UPDATED-MONTH}.

EDITION
VERSION

Both of these flags hold the version number of your program. They are kept separate for clarity.

UPDATED

This holds the date the primary .texi file was last modified.

UPDATED-MONTH

This holds the name of the month in which the primary .texi file was last modified.

The version.texi support requires the mdate-sh script; this script is supplied with Automake and automatically included when automake is invoked with the --add-missing option.

If you have multiple Texinfo files, and you want to use the version.texi feature, then you have to have a separate version file for each Texinfo file. Automake will treat any include in a Texinfo file that matches vers*.texi just as an automatically generated version file.

Sometimes an info file actually depends on more than one .texi file. For instance, in GNU Hello, hello.texi includes the file fdl.texi. You can tell Automake about these dependencies using the texi_TEXINFOS variable. Here is how GNU Hello does it:

info_TEXINFOS = hello.texi
hello_TEXINFOS = fdl.texi

By default, Automake requires the file texinfo.tex to appear in the same directory as the Makefile.am file that lists the .texi files. If you used AC_CONFIG_AUX_DIR in configure.ac (see Finding ‘configure’ Input in The Autoconf Manual), then texinfo.tex is looked for there. In both cases, automake then supplies texinfo.tex if --add-missing is given, and takes care of its distribution. However, if you set the TEXINFO_TEX variable (see below), it overrides the location of the file and turns off its installation into the source as well as its distribution.

The option no-texinfo.tex can be used to eliminate the requirement for the file texinfo.tex. Use of the variable TEXINFO_TEX is preferable, however, because that allows the dvi, ps, and pdf targets to still work.

Automake generates an install-info rule; some people apparently use this. By default, info pages are installed by ‘make install’, so running make install-info is pointless. This can be prevented via the no-installinfo option. In this case, .info files are not installed by default, and user must request this explicitly using ‘make install-info’.

By default, make install-info and make uninstall-info will try to run the install-info program (if available) to update (or create/remove) the ${infodir}/dir index. If this is undesired, it can be prevented by exporting the AM_UPDATE_INFO_DIR variable to "no".

The following variables are used by the Texinfo build rules.

MAKEINFO

The name of the program invoked to build .info files. This variable is defined by Automake. If the makeinfo program is found on the system then it will be used by default; otherwise missing will be used instead.

MAKEINFOHTML

The command invoked to build .html files. Automake defines this to ‘$(MAKEINFO) --html’.

MAKEINFOFLAGS

User flags passed to each invocation of ‘$(MAKEINFO)’ and ‘$(MAKEINFOHTML)’. This user variable (see Variables reserved for the user) is not expected to be defined in any Makefile; it can be used by users to pass extra flags to suit their needs.

AM_MAKEINFOFLAGS
AM_MAKEINFOHTMLFLAGS

Maintainer flags passed to each makeinfo invocation. Unlike MAKEINFOFLAGS, these variables are meant to be defined by maintainers in Makefile.am. ‘$(AM_MAKEINFOFLAGS)’ is passed to makeinfo when building .info files; and ‘$(AM_MAKEINFOHTMLFLAGS)’ is used when building .html files.

For instance, the following setting can be used to obtain one single .html file per manual, without node separators.

AM_MAKEINFOHTMLFLAGS = --no-headers --no-split

AM_MAKEINFOHTMLFLAGS defaults to ‘$(AM_MAKEINFOFLAGS)’. This means that defining AM_MAKEINFOFLAGS without defining AM_MAKEINFOHTMLFLAGS will impact builds of both .info and .html files.

TEXI2DVI

The name of the command that converts a .texi file into a .dvi file. This defaults to ‘texi2dvi’, a script that ships with the Texinfo package.

TEXI2PDF

The name of the command that translates a .texi file into a .pdf file. This defaults to ‘$(TEXI2DVI) --pdf --batch’.

DVIPS

The name of the command that builds a .ps file out of a .dvi file. This defaults to ‘dvips’.

TEXINFO_TEX

If your package has Texinfo files in many directories, you can use the variable TEXINFO_TEX to tell Automake where to find the canonical texinfo.tex for your package. The value of this variable should be the relative path from the current Makefile.am to texinfo.tex:

TEXINFO_TEX = ../doc/texinfo.tex

11.2 Man Pages

A package can also include man pages (but see the GNU standards on this matter, Man Pages in The GNU Coding Standards.) Man pages are declared using the MANS primary. Generally the man_MANS variable is used. Man pages are automatically installed in the correct subdirectory of mandir, based on the file extension.

File extensions such as .1c are handled by looking for the valid part of the extension and using that to determine the correct subdirectory of mandir. Valid section names are the digits ‘0’ through ‘9’, and the letters ‘l’ and ‘n’.

Sometimes developers prefer to name a man page something like foo.man in the source, and then rename it to have the correct suffix, for example foo.1, when installing the file. Automake also supports this mode. For a valid section named section, there is a corresponding directory named ‘mansectiondir’, and a corresponding _MANS variable. Files listed in such a variable are installed in the indicated section. If the file already has a valid suffix, then it is installed as-is; otherwise the file suffix is changed to match the section.

For instance, consider this example:

man1_MANS = rename.man thesame.1 alsothesame.1c

In this case, rename.man will be renamed to rename.1 when installed, but the other files will keep their names.

By default, man pages are installed by ‘make install’. However, since the GNU project does not require man pages, many maintainers do not expend effort to keep the man pages up to date. In these cases, the no-installman option will prevent the man pages from being installed by default. The user can still explicitly install them via ‘make install-man’.

For fast installation, with many files it is preferable to use ‘mansection_MANS’ over ‘man_MANS’ as well as files that do not need to be renamed.

Man pages are not currently considered to be source, because it is not uncommon for man pages to be automatically generated. Therefore they are not automatically included in the distribution. However, this can be changed by use of the dist_ prefix. For instance here is how to distribute and install the two man pages of GNU cpio (which includes both Texinfo documentation and man pages):

dist_man_MANS = cpio.1 mt.1

The nobase_ prefix is meaningless for man pages and is disallowed.

Executables and manpages may be renamed upon installation (see Renaming Programs at Install Time). For manpages this can be avoided by use of the notrans_ prefix. For instance, suppose an executable ‘foo’ allowing to access a library function ‘foo’ from the command line. The way to avoid renaming of the foo.3 manpage is:

man_MANS = foo.1
notrans_man_MANS = foo.3

notrans_’ must be specified first when used in conjunction with either ‘dist_’ or ‘nodist_’ (see Fine-grained Distribution Control). For instance:

notrans_dist_man3_MANS = bar.3

12 What Gets Installed

Naturally, Automake handles the details of actually installing your program once it has been built. All files named by the various primaries are automatically installed in the appropriate places when the user runs ‘make install’.


12.1 Basics of Installation

A file named in a primary is installed by copying the built file into the appropriate directory. The base name of the file is used when installing.

bin_PROGRAMS = hello subdir/goodbye

In this example, both ‘hello’ and ‘goodbye’ will be installed in ‘$(bindir)’.

Sometimes it is useful to avoid the basename step at install time. For instance, you might have a number of header files in subdirectories of the source tree that are laid out precisely how you want to install them. In this situation you can use the nobase_ prefix to suppress the base name step. For example:

nobase_include_HEADERS = stdio.h sys/types.h

will install stdio.h in ‘$(includedir)’ and types.h in ‘$(includedir)/sys’.

For most file types, Automake will install multiple files at once, while avoiding command line length issues (see Staying below the command line length limit). Since some install programs will not install the same file twice in one invocation, you may need to ensure that file lists are unique within one variable such as ‘nobase_include_HEADERS’ above.

You should not rely on the order in which files listed in one variable are installed. Likewise, to cater for parallel make, you should not rely on any particular file installation order even among different file types (library dependencies are an exception here).


12.2 The Two Parts of Install

Automake generates separate install-data and install-exec rules, in case the installer is installing on multiple machines that share directory structure—these targets allow the machine-independent parts to be installed only once. install-exec installs platform-dependent files, and install-data installs platform-independent files. The install target depends on both of these targets. While Automake tries to automatically segregate objects into the correct category, the Makefile.am author is, in the end, responsible for making sure this is done correctly.

Variables using the standard directory prefixes ‘data’, ‘info’, ‘man’, ‘include’, ‘oldinclude’, ‘pkgdata’, or ‘pkginclude’ are installed by install-data.

Variables using the standard directory prefixes ‘bin’, ‘sbin’, ‘libexec’, ‘sysconf’, ‘localstate’, ‘lib’, or ‘pkglib’ are installed by install-exec.

For instance, data_DATA files are installed by install-data, while bin_PROGRAMS files are installed by install-exec.

Any variable using a user-defined directory prefix with ‘exec’ in the name (e.g., myexecbin_PROGRAMS) is installed by install-exec. All other user-defined prefixes are installed by install-data.


12.3 Extending Installation

It is possible to extend this mechanism by defining an install-exec-local or install-data-local rule. If these rules exist, they will be run at ‘make install’ time. These rules can do almost anything; care is required.

Automake also supports two install hooks, install-exec-hook and install-data-hook. These hooks are run after all other install rules of the appropriate type, exec or data, have completed. So, for instance, it is possible to perform post-installation modifications using an install hook. See Extending Automake Rules, for some examples.


12.4 Staged Installs

Automake generates support for the DESTDIR variable in all install rules. DESTDIR is used during the ‘make install’ step to relocate install objects into a staging area. Each object and path is prefixed with the value of DESTDIR before being copied into the install area. Here is an example of typical DESTDIR usage:

mkdir /tmp/staging &&
make DESTDIR=/tmp/staging install

The mkdir command avoids a security problem if the attacker creates a symbolic link from /tmp/staging to a victim area; then make places install objects in a directory tree built under /tmp/staging. If /gnu/bin/foo and /gnu/share/aclocal/foo.m4 are to be installed, the above command would install /tmp/staging/gnu/bin/foo and /tmp/staging/gnu/share/aclocal/foo.m4.

This feature is commonly used to build install images and packages (see Building Binary Packages Using DESTDIR).

Support for DESTDIR is implemented by coding it directly into the install rules. If your Makefile.am uses a local install rule (e.g., install-exec-local) or an install hook, then you must write that code to respect DESTDIR.

See Makefile Conventions in The GNU Coding Standards, for another usage example.


12.5 Install Rules for the User

Automake also generates rules for targets uninstall, installdirs, and install-strip.

Automake supports uninstall-local and uninstall-hook. There is no notion of separate uninstalls for “exec” and “data”, as these features would not provide additional functionality.

Note that uninstall is not meant as a replacement for a real packaging tool.


13 What Gets Cleaned

The GNU Makefile Standards specify a number of different clean rules. See Standard Targets for Users in The GNU Coding Standards.

Generally the files that can be cleaned are determined automatically by Automake. Of course, Automake also recognizes some variables that can be defined to specify additional files to clean. These variables are MOSTLYCLEANFILES, CLEANFILES, DISTCLEANFILES, and MAINTAINERCLEANFILES.

When cleaning involves more than deleting some hard-coded list of files, it is also possible to supplement the cleaning rules with your own commands. Simply define a rule for any of the mostlyclean-local, clean-local, distclean-local, or maintainer-clean-local targets (see Extending Automake Rules). A common case is deleting a directory, for instance, a directory created by the test suite:

clean-local:
        -rm -rf testSubDir

Since make allows only one set of rules for a given target, a more extensible way of writing this is to use a separate target listed as a dependency:

clean-local: clean-local-check
.PHONY: clean-local-check
clean-local-check:
        -rm -rf testSubDir

As the GNU Standards aren’t always explicit as to which files should be removed by which rule, we’ve adopted a heuristic that we believe was first formulated by François Pinard:

We recommend that you follow this same set of heuristics in your Makefile.am.


14 What Goes in a Distribution


14.1 Basics of Distribution

The dist rule in the generated Makefile.in can be used to generate a gzipped tar file and other flavors of archive for distribution. The file is named based on the PACKAGE and VERSION variables automatically defined by either the AC_INIT invocation or by a deprecated two-arguments invocation of the AM_INIT_AUTOMAKE macro (see Public Macros for how these variables get their values, from either defaults or explicit values – it’s slightly trickier than one would expect). More precisely the gzipped tar file is named ‘${PACKAGE}-${VERSION}.tar.gz’. You can use the make variable GZIP_ENV to control how gzip is run. The default setting is --best.

For the most part, the files to distribute are automatically found by Automake: all source files are automatically included in a distribution, as are all Makefile.am and Makefile.in files. Automake also has a built-in list of commonly used files that are automatically included if they are found in the current directory (either physically, or as the target of a Makefile.am rule); this list is printed by ‘automake --help’. Note that some files in this list are actually distributed only if other certain conditions hold (for example, the config.h.top and config.h.bot files are automatically distributed only if, e.g., ‘AC_CONFIG_HEADERS([config.h])’ is used in configure.ac). Also, files that are read by configure (i.e. the source files corresponding to the files specified in various Autoconf macros such as AC_CONFIG_FILES and siblings) are automatically distributed. Files included in a Makefile.am (using include) or in configure.ac (using m4_include), and helper scripts installed with ‘automake --add-missing’ are also distributed.

Still, sometimes there are files that must be distributed, but which are not covered in the automatic rules. These files should be listed in the EXTRA_DIST variable. You can mention files from subdirectories in EXTRA_DIST.

You can also mention a directory in EXTRA_DIST; in this case the entire directory will be recursively copied into the distribution. Please note that this will also copy everything in the directory, including, e.g., Subversion’s .svn private directories or CVS/RCS version control files; thus we recommend against using this feature as-is. However, you can use the dist-hook feature to ameliorate the problem; see The dist Hook.

If you define SUBDIRS, Automake will recursively include the subdirectories in the distribution. If SUBDIRS is defined conditionally (see Conditionals), Automake will normally include all directories that could possibly appear in SUBDIRS in the distribution. If you need to specify the set of directories conditionally, you can set the variable DIST_SUBDIRS to the exact list of subdirectories to include in the distribution (see Conditional Subdirectories).


14.2 Fine-grained Distribution Control

Sometimes you need tighter control over what does not go into the distribution; for instance, you might have source files that are generated and that you do not want to distribute. In this case Automake gives fine-grained control using the dist and nodist prefixes. Any primary or _SOURCES variable can be prefixed with dist_ to add the listed files to the distribution. Similarly, nodist_ can be used to omit the files from the distribution.

As an example, here is how you would cause some data to be distributed while leaving some source code out of the distribution:

dist_data_DATA = distribute-this
bin_PROGRAMS = foo
nodist_foo_SOURCES = do-not-distribute.c

14.3 The dist Hook

Occasionally it is useful to be able to change the distribution before it is packaged up. If the dist-hook rule exists, it is run after the distribution directory is filled, but before the actual distribution archives are created. One way to use this is for removing unnecessary files that get recursively included by specifying a directory in EXTRA_DIST:

EXTRA_DIST = doc
dist-hook:
        rm -rf `find $(distdir)/doc -type d -name .svn`

Note that the dist-hook recipe shouldn’t assume that the regular files in the distribution directory are writable; this might not be the case if one is packaging from a read-only source tree, or when a make distcheck is being done. For similar reasons, the recipe shouldn’t assume that the subdirectories put into the distribution directory as effect of having them listed in EXTRA_DIST are writable. So, if the dist-hook recipe wants to modify the content of an existing file (or EXTRA_DIST subdirectory) in the distribution directory, it should explicitly to make it writable first:

EXTRA_DIST = README doc
dist-hook:
        chmod u+w $(distdir)/README $(distdir)/doc
        echo "Distribution date: `date`" >> README
        rm -f $(distdir)/doc/HACKING

Two variables that come handy when writing dist-hook rules are ‘$(distdir)’ and ‘$(top_distdir)’.

$(distdir)’ points to the directory where the dist rule will copy files from the current directory before creating the tarball. If you are at the top-level directory, then ‘distdir = $(PACKAGE)-$(VERSION)’. When used from subdirectory named foo/, then ‘distdir = ../$(PACKAGE)-$(VERSION)/foo’. ‘$(distdir)’ can be a relative or absolute path, do not assume any form.

$(top_distdir)’ always points to the root directory of the distributed tree. At the top-level it’s equal to ‘$(distdir)’. In the foo/ subdirectory ‘top_distdir = ../$(PACKAGE)-$(VERSION)’. ‘$(top_distdir)’ too can be a relative or absolute path.

Note that when packages are nested using AC_CONFIG_SUBDIRS (see Nesting Packages), then ‘$(distdir)’ and ‘$(top_distdir)’ are relative to the package where ‘make dist’ was run, not to any sub-packages involved.


14.4 Checking the Distribution

Automake also generates a distcheck rule that can be of help to ensure that a given distribution will actually work. Simplifying a bit, we can say this rule first makes a distribution, and then, operating from it, takes the following steps:

  • tries to do a VPATH build (see Parallel Build Trees (a.k.a. VPATH Builds)), with the srcdir and all its content made read-only;
  • runs the test suite (with make check) on this fresh build;
  • installs the package in a temporary directory (with make install), and tries runs the test suite on the resulting installation (with make installcheck);
  • checks that the package can be correctly uninstalled (by make uninstall) and cleaned (by make distclean);
  • finally, makes another tarball to ensure the distribution is self-contained.

All of these actions are performed in a temporary directory. Please note that the exact location and the exact structure of such a directory (where the read-only sources are placed, how the temporary build and install directories are named and how deeply they are nested, etc.) is to be considered an implementation detail, which can change at any time; so do not reply on it.

DISTCHECK_CONFIGURE_FLAGS

Building the package involves running ‘./configure’. If you need to supply additional flags to configure, define them in the AM_DISTCHECK_CONFIGURE_FLAGS variable in your top-level Makefile.am. The user can still extend or override the flags provided there by defining the DISTCHECK_CONFIGURE_FLAGS variable, on the command line when invoking make. It’s worth nothing that make distcheck needs complete control over the configure options --srcdir and --prefix, so those options cannot be overridden by AM_DISTCHECK_CONFIGURE_FLAGS nor by DISTCHECK_CONFIGURE_FLAGS.

Also note that developers are encouraged to strive to make their code buildable without requiring any special configure option; thus, in general, you shouldn’t define AM_DISTCHECK_CONFIGURE_FLAGS. However, there might be few scenarios in which the use of this variable is justified. GNU m4 offers an example. GNU m4 configures by default with its experimental and seldom used "changeword" feature disabled; so in its case it is useful to have make distcheck run configure with the --with-changeword option, to ensure that the code for changeword support still compiles correctly. GNU m4 also employs the AM_DISTCHECK_CONFIGURE_FLAGS variable to stress-test the use of --program-prefix=g, since at one point the m4 build system had a bug where make installcheck was wrongly assuming it could blindly test "m4", rather than the just-installed "gm4".

distcheck-hook

If the distcheck-hook rule is defined in your top-level Makefile.am, then it will be invoked by distcheck after the new distribution has been unpacked, but before the unpacked copy is configured and built. Your distcheck-hook can do almost anything, though as always caution is advised. Generally this hook is used to check for potential distribution errors not caught by the standard mechanism. Note that distcheck-hook as well as AM_DISTCHECK_CONFIGURE_FLAGS and DISTCHECK_CONFIGURE_FLAGS are not honored in a subpackage Makefile.am, but the flags from AM_DISTCHECK_CONFIGURE_FLAGS and DISTCHECK_CONFIGURE_FLAGS are passed down to the configure script of the subpackage.

distcleancheck

Speaking of potential distribution errors, distcheck also ensures that the distclean rule actually removes all built files. This is done by running ‘make distcleancheck’ at the end of the VPATH build. By default, distcleancheck will run distclean and then make sure the build tree has been emptied by running ‘$(distcleancheck_listfiles)’. Usually this check will find generated files that you forgot to add to the DISTCLEANFILES variable (see What Gets Cleaned).

The distcleancheck behavior should be OK for most packages, otherwise you have the possibility to override the definition of either the distcleancheck rule, or the ‘$(distcleancheck_listfiles)’ variable. For instance, to disable distcleancheck completely, add the following rule to your top-level Makefile.am:

distcleancheck:
        @:

If you want distcleancheck to ignore built files that have not been cleaned because they are also part of the distribution, add the following definition instead:

distcleancheck_listfiles = \
  find . -type f -exec sh -c 'test -f $(srcdir)/$$1 || echo $$1' \
       sh '{}' ';'

The above definition is not the default because it’s usually an error if your Makefiles cause some distributed files to be rebuilt when the user build the package. (Think about the user missing the tool required to build the file; or if the required tool is built by your package, consider the cross-compilation case where it can’t be run.) There is an entry in the FAQ about this (see Errors with distclean), make sure you read it before playing with distcleancheck_listfiles.

distuninstallcheck

distcheck also checks that the uninstall rule works properly, both for ordinary and DESTDIR builds. It does this by invoking ‘make uninstall’, and then it checks the install tree to see if any files are left over. This check will make sure that you correctly coded your uninstall-related rules.

By default, the checking is done by the distuninstallcheck rule, and the list of files in the install tree is generated by ‘$(distuninstallcheck_listfiles)’ (this is a variable whose value is a shell command to run that prints the list of files to stdout).

Either of these can be overridden to modify the behavior of distcheck. For instance, to disable this check completely, you would write:

distuninstallcheck:
        @:

14.5 The Types of Distributions

Automake generates rules to provide archives of the project for distributions in various formats. Their targets are:

dist-gzip

Generate a ‘gzip’ tar archive of the distribution. This is the only format enabled by default.

dist-bzip2

Generate a ‘bzip2’ tar archive of the distribution. bzip2 archives are frequently smaller than gzipped archives. By default, this rule makes ‘bzip2’ use a compression option of -9. To make it use a different one, set the BZIP2 environment variable. For example, ‘make dist-bzip2 BZIP2=-7’.

dist-lzip

Generate an ‘lzip’ tar archive of the distribution. lzip archives are frequently smaller than bzip2-compressed archives.

dist-xz

Generate an ‘xz’ tar archive of the distribution. xz archives are frequently smaller than bzip2-compressed archives. By default, this rule makes ‘xz’ use a compression option of -e. To make it use a different one, set the XZ_OPT environment variable. For example, run this command to use the default compression ratio, but with a progress indicator: ‘make dist-xz XZ_OPT=-ve’.

dist-zip

Generate a ‘zip’ archive of the distribution.

dist-tarZ

Generate a tar archive of the distribution, compressed with the historical (and obsolescent) program compress. This option is deprecated, and it and the corresponding functionality will be removed altogether in Automake 2.0.

dist-shar

Generate a ‘shar’ archive of the distribution. This format archive is obsolescent, and use of this option is deprecated. It and the corresponding functionality will be removed altogether in Automake 2.0.

The rule dist (and its historical synonym dist-all) will create archives in all the enabled formats (see List of Automake options for how to change this list). By default, only the dist-gzip target is hooked to dist.


15 Support for test suites

Automake can generate code to handle two kinds of test suites. One is based on integration with the dejagnu framework. The other (and most used) form is based on the use of generic test scripts, and its activation is triggered by the definition of the special TESTS variable. This second form allows for various degrees of sophistication and customization; in particular, it allows for concurrent execution of test scripts, use of established test protocols such as TAP, and definition of custom test drivers and test runners.

In either case, the testsuite is invoked via ‘make check’.


15.1 Generalities about Testing

The purpose of testing is to determine whether a program or system behaves as expected (e.g., known inputs produce the expected outputs, error conditions are correctly handled or reported, and older bugs do not resurface).

The minimal unit of testing is usually called test case, or simply test. How a test case is defined or delimited, and even what exactly constitutes a test case, depends heavily on the testing paradigm and/or framework in use, so we won’t attempt any more precise definition. The set of the test cases for a given program or system constitutes its testsuite.

A test harness (also testsuite harness) is a program or software component that executes all (or part of) the defined test cases, analyzes their outcomes, and report or register these outcomes appropriately. Again, the details of how this is accomplished (and how the developer and user can influence it or interface with it) varies wildly, and we’ll attempt no precise definition.

A test is said to pass when it can determine that the condition or behaviour it means to verify holds, and is said to fail when it can determine that such condition of behaviour does not hold.

Sometimes, tests can rely on non-portable tools or prerequisites, or simply make no sense on a given system (for example, a test checking a Windows-specific feature makes no sense on a GNU/Linux system). In this case, accordingly to the definition above, the tests can neither be considered passed nor failed; instead, they are skipped – i.e., they are not run, or their result is anyway ignored for what concerns the count of failures an successes. Skips are usually explicitly reported though, so that the user will be aware that not all of the testsuite has really run.

It’s not uncommon, especially during early development stages, that some tests fail for known reasons, and that the developer doesn’t want to tackle these failures immediately (this is especially true when the failing tests deal with corner cases). In this situation, the better policy is to declare that each of those failures is an expected failure (or xfail). In case a test that is expected to fail ends up passing instead, many testing environments will flag the result as a special kind of failure called unexpected pass (or xpass).

Many testing environments and frameworks distinguish between test failures and hard errors. As we’ve seen, a test failure happens when some invariant or expected behaviour of the software under test is not met. An hard error happens when e.g., the set-up of a test case scenario fails, or when some other unexpected or highly undesirable condition is encountered (for example, the program under test experiences a segmentation fault).


15.2 Simple Tests


15.2.1 Scripts-based Testsuites

If the special variable TESTS is defined, its value is taken to be a list of programs or scripts to run in order to do the testing. Under the appropriate circumstances, it’s possible for TESTS to list also data files to be passed to one or more test scripts defined by different means (the so-called “log compilers”, see Parallel Test Harness).

Test scripts can be executed serially or concurrently. Automake supports both these kinds of test execution, with the parallel test harness being the default. The concurrent test harness relies on the concurrence capabilities (if any) offered by the underlying make implementation, and can thus only be as good as those are.

By default, only the exit statuses of the test scripts are considered when determining the testsuite outcome. But Automake allows also the use of more complex test protocols, either standard (see Using the TAP test protocol) or custom (see Custom Test Drivers). Note that you can’t enable such protocols when the serial harness is used, though. In the rest of this section we are going to concentrate mostly on protocol-less tests, since we cover test protocols in a later section (again, see Custom Test Drivers).

When no test protocol is in use, an exit status of 0 from a test script will denote a success, an exit status of 77 a skipped test, an exit status of 99 an hard error, and any other exit status will denote a failure.

You may define the variable XFAIL_TESTS to a list of tests (usually a subset of TESTS) that are expected to fail; this will effectively reverse the result of those tests (with the provision that skips and hard errors remain untouched). You may also instruct the testsuite harness to treat hard errors like simple failures, by defining the DISABLE_HARD_ERRORS make variable to a nonempty value.

Note however that, for tests based on more complex test protocols, the exact effects of XFAIL_TESTS and DISABLE_HARD_ERRORS might change, or they might even have no effect at all (for example, in tests using TAP, there is not way to disable hard errors, and the DISABLE_HARD_ERRORS variable has no effect on them).

The result of each test case run by the scripts in TESTS will be printed on standard output, along with the test name. For test protocols that allow more test cases per test script (such as TAP), a number, identifier and/or brief description specific for the single test case is expected to be printed in addition to the name of the test script. The possible results (whose meanings should be clear from the previous Generalities about Testing) are PASS, FAIL, SKIP, XFAIL, XPASS and ERROR. Here is an example of output from an hypothetical testsuite that uses both plain and TAP tests:

PASS: foo.sh
PASS: zardoz.tap 1 - Daemon started
PASS: zardoz.tap 2 - Daemon responding
SKIP: zardoz.tap 3 - Daemon uses /proc # SKIP /proc is not mounted
PASS: zardoz.tap 4 - Daemon stopped
SKIP: bar.sh
PASS: mu.tap 1
XFAIL: mu.tap 2 # TODO frobnication not yet implemented

A testsuite summary (expected to report at least the number of run, skipped and failed tests) will be printed at the end of the testsuite run.

If the standard output is connected to a capable terminal, then the test results and the summary are colored appropriately. The developer and the user can disable colored output by setting the make variable ‘AM_COLOR_TESTS=no’; the user can in addition force colored output even without a connecting terminal with ‘AM_COLOR_TESTS=always’. It’s also worth noting that some make implementations, when used in parallel mode, have slightly different semantics (see Parallel make in The Autoconf Manual), which can break the automatic detection of a connection to a capable terminal. If this is the case, the user will have to resort to the use of ‘AM_COLOR_TESTS=always’ in order to have the testsuite output colorized.

Test programs that need data files should look for them in srcdir (which is both a make variable and an environment variable made available to the tests), so that they work when building in a separate directory (see Build Directories in The Autoconf Manual), and in particular for the distcheck rule (see Checking the Distribution).

The AM_TESTS_ENVIRONMENT and TESTS_ENVIRONMENT variables can be used to run initialization code and set environment variables for the test scripts. The former variable is developer-reserved, and can be defined in the Makefile.am, while the latter is reserved for the user, which can employ it to extend or override the settings in the former; for this to work portably, however, the contents of a non-empty AM_TESTS_ENVIRONMENT must be terminated by a semicolon.

The AM_TESTS_FD_REDIRECT variable can be used to define file descriptor redirections for the test scripts. One might think that AM_TESTS_ENVIRONMENT could be used for this purpose, but experience has shown that doing so portably is practically impossible. The main hurdle is constituted by Korn shells, which usually set the close-on-exec flag on file descriptors opened with the exec builtin, thus rendering an idiom like AM_TESTS_ENVIRONMENT = exec 9>&2; ineffectual. This issue also affects some Bourne shells, such as the HP-UX’s /bin/sh,

AM_TESTS_ENVIRONMENT = \
## Some environment initializations are kept in a separate shell
## file 'tests-env.sh', which can make it easier to also run tests
## from the command line.
  . $(srcdir)/tests-env.sh; \
## On Solaris, prefer more POSIX-compliant versions of the standard
## tools by default.
  if test -d /usr/xpg4/bin; then \
    PATH=/usr/xpg4/bin:$$PATH; export PATH; \
  fi;
## With this, the test scripts will be able to print diagnostic
## messages to the original standard error stream, even if the test
## driver redirects the stderr of the test scripts to a log file
## before executing them.
AM_TESTS_FD_REDIRECT = 9>&2

Note however that AM_TESTS_ENVIRONMENT is, for historical and implementation reasons, not supported by the serial harness (see Older (and discouraged) serial test harness).

Automake ensures that each file listed in TESTS is built before it is run; you can list both source and derived programs (or scripts) in TESTS; the generated rule will look both in srcdir and .. For instance, you might want to run a C program as a test. To do this you would list its name in TESTS and also in check_PROGRAMS, and then specify it as you would any other program.

Programs listed in check_PROGRAMS (and check_LIBRARIES, check_LTLIBRARIES...) are only built during make check, not during make all. You should list there any program needed by your tests that does not need to be built by make all. Note that check_PROGRAMS are not automatically added to TESTS because check_PROGRAMS usually lists programs used by the tests, not the tests themselves. Of course you can set TESTS = $(check_PROGRAMS) if all your programs are test cases.


15.2.2 Older (and discouraged) serial test harness

First, note that today the use of this harness is strongly discouraged in favour of the parallel test harness (see Parallel Test Harness). Still, there are few situations when the advantages offered by the parallel harness are irrelevant, and when test concurrency can even cause tricky problems. In those cases, it might make sense to still use the serial harness, for simplicity and reliability (we still suggest trying to give the parallel harness a shot though).

The serial test harness is enabled by the Automake option serial-tests. It operates by simply running the tests serially, one at the time, without any I/O redirection. It’s up to the user to implement logging of tests’ output, if that’s required or desired.

For historical and implementation reasons, the AM_TESTS_ENVIRONMENT variable is not supported by this harness (it will be silently ignored if defined); only TESTS_ENVIRONMENT is, and it is to be considered a developer-reserved variable. This is done so that, when using the serial harness, TESTS_ENVIRONMENT can be defined to an invocation of an interpreter through which the tests are to be run. For instance, the following setup may be used to run tests with Perl:

TESTS_ENVIRONMENT = $(PERL) -Mstrict -w
TESTS = foo.pl bar.pl baz.pl

It’s important to note that the use of TESTS_ENVIRONMENT endorsed here would be invalid with the parallel harness. That harness provides a more elegant way to achieve the same effect, with the further benefit of freeing the TESTS_ENVIRONMENT variable for the user (see Parallel Test Harness).

Another, less serious limit of the serial harness is that it doesn’t really distinguish between simple failures and hard errors; this is due to historical reasons only, and might be fixed in future Automake versions.


15.2.3 Parallel Test Harness

By default, Automake generated a parallel (concurrent) test harness. It features automatic collection of the test scripts output in .log files, concurrent execution of tests with make -j, specification of inter-test dependencies, lazy reruns of tests that have not completed in a prior run, and hard errors for exceptional failures.

The parallel test harness operates by defining a set of make rules that run the test scripts listed in TESTS, and, for each such script, save its output in a corresponding .log file and its results (and other “metadata”, see API for Custom Test Drivers) in a corresponding .trs (as in Test ReSults) file. The .log file will contain all the output emitted by the test on its standard output and its standard error. The .trs file will contain, among the other things, the results of the test cases run by the script.

The parallel test harness will also create a summary log file, TEST_SUITE_LOG, which defaults to test-suite.log and requires a .log suffix. This file depends upon all the .log and .trs files created for the test scripts listed in TESTS.

As with the serial harness above, by default one status line is printed per completed test, and a short summary after the suite has completed. However, standard output and standard error of the test are redirected to a per-test log file, so that parallel execution does not produce intermingled output. The output from failed tests is collected in the test-suite.log file. If the variable ‘VERBOSE’ is set, this file is output after the summary.

Each couple of .log and .trs files is created when the corresponding test has completed. The set of log files is listed in the read-only variable TEST_LOGS, and defaults to TESTS, with the executable extension if any (see Support for executable extensions), as well as any suffix listed in TEST_EXTENSIONS removed, and .log appended. Results are undefined if a test file name ends in several concatenated suffixes. TEST_EXTENSIONS defaults to .test; it can be overridden by the user, in which case any extension listed in it must be constituted by a dot, followed by a non-digit alphabetic character, followed by any number of alphabetic characters. For example, ‘.sh’, ‘.T’ and ‘.t1’ are valid extensions, while ‘.x-y’, ‘.6c’ and ‘.t.1’ are not.

It is important to note that, due to current limitations (unlikely to be lifted), configure substitutions in the definition of TESTS can only work if they will expand to a list of tests that have a suffix listed in TEST_EXTENSIONS.

For tests that match an extension .ext listed in TEST_EXTENSIONS, you can provide a custom “test runner” using the variable ext_LOG_COMPILER (note the upper-case extension) and pass options in AM_ext_LOG_FLAGS and allow the user to pass options in ext_LOG_FLAGS. It will cause all tests with this extension to be called with this runner. For all tests without a registered extension, the variables LOG_COMPILER, AM_LOG_FLAGS, and LOG_FLAGS may be used. For example,

TESTS = foo.pl bar.py baz
TEST_EXTENSIONS = .pl .py
PL_LOG_COMPILER = $(PERL)
AM_PL_LOG_FLAGS = -w
PY_LOG_COMPILER = $(PYTHON)
AM_PY_LOG_FLAGS = -v
LOG_COMPILER = ./wrapper-script
AM_LOG_FLAGS = -d

will invoke ‘$(PERL) -w foo.pl’, ‘$(PYTHON) -v bar.py’, and ‘./wrapper-script -d baz’ to produce foo.log, bar.log, and baz.log, respectively. The foo.trs, bar.trs and baz.trs files will be automatically produced as a side-effect.

It’s important to note that, differently from what we’ve seen for the serial test harness (see Older (and discouraged) serial test harness), the AM_TESTS_ENVIRONMENT and TESTS_ENVIRONMENT variables cannot be use to define a custom test runner; the LOG_COMPILER and LOG_FLAGS (or their extension-specific counterparts) should be used instead:

## This is WRONG!
AM_TESTS_ENVIRONMENT = PERL5LIB='$(srcdir)/lib' $(PERL) -Mstrict -w
## Do this instead.
AM_TESTS_ENVIRONMENT = PERL5LIB='$(srcdir)/lib'; export PERL5LIB;
LOG_COMPILER = $(PERL)
AM_LOG_FLAGS = -Mstrict -w

By default, the test suite harness will run all tests, but there are several ways to limit the set of tests that are run:

  • You can set the TESTS variable. For example, you can use a command like this to run only a subset of the tests:
    env TESTS="foo.test bar.test" make -e check
    

    Note however that the command above will unconditionally overwrite the test-suite.log file, thus clobbering the recorded results of any previous testsuite run. This might be undesirable for packages whose testsuite takes long time to execute. Luckily, this problem can easily be avoided by overriding also TEST_SUITE_LOG at runtime; for example,

    env TEST_SUITE_LOG=partial.log TESTS="..." make -e check
    

    will write the result of the partial testsuite runs to the partial.log, without touching test-suite.log.

  • You can set the TEST_LOGS variable. By default, this variable is computed at make run time from the value of TESTS as described above. For example, you can use the following:
    set x subset*.log; shift
    env TEST_LOGS="foo.log $*" make -e check
    

    The comments made above about TEST_SUITE_LOG overriding applies here too.

  • By default, the test harness removes all old per-test .log and .trs files before it starts running tests to regenerate them. The variable RECHECK_LOGS contains the set of .log (and, by implication, .trs) files which are removed. RECHECK_LOGS defaults to TEST_LOGS, which means all tests need to be rechecked. By overriding this variable, you can choose which tests need to be reconsidered. For example, you can lazily rerun only those tests which are outdated, i.e., older than their prerequisite test files, by setting this variable to the empty value:
    env RECHECK_LOGS= make -e check
    
  • You can ensure that all tests are rerun which have failed or passed unexpectedly, by running make recheck in the test directory. This convenience target will set RECHECK_LOGS appropriately before invoking the main test harness.

In order to guarantee an ordering between tests even with make -jN, dependencies between the corresponding .log files may be specified through usual make dependencies. For example, the following snippet lets the test named foo-execute.test depend upon completion of the test foo-compile.test:

TESTS = foo-compile.test foo-execute.test
foo-execute.log: foo-compile.log

Please note that this ordering ignores the results of required tests, thus the test foo-execute.test is run even if the test foo-compile.test failed or was skipped beforehand. Further, please note that specifying such dependencies currently works only for tests that end in one of the suffixes listed in TEST_EXTENSIONS.

Tests without such specified dependencies may be run concurrently with parallel make -jN, so be sure they are prepared for concurrent execution.

The combination of lazy test execution and correct dependencies between tests and their sources may be exploited for efficient unit testing during development. To further speed up the edit-compile-test cycle, it may even be useful to specify compiled programs in EXTRA_PROGRAMS instead of with check_PROGRAMS, as the former allows intertwined compilation and test execution (but note that EXTRA_PROGRAMS are not cleaned automatically, see The Uniform Naming Scheme).

The variables TESTS and XFAIL_TESTS may contain conditional parts as well as configure substitutions. In the latter case, however, certain restrictions apply: substituted test names must end with a nonempty test suffix like .test, so that one of the inference rules generated by automake can apply. For literal test names, automake can generate per-target rules to avoid this limitation.

Please note that it is currently not possible to use $(srcdir)/ or $(top_srcdir)/ in the TESTS variable. This technical limitation is necessary to avoid generating test logs in the source tree and has the unfortunate consequence that it is not possible to specify distributed tests that are themselves generated by means of explicit rules, in a way that is portable to all make implementations (see Make Target Lookup in The Autoconf Manual, the semantics of FreeBSD and OpenBSD make conflict with this). In case of doubt you may want to require to use GNU make, or work around the issue with inference rules to generate the tests.


15.3 Custom Test Drivers


15.3.1 Overview of Custom Test Drivers Support

Starting from Automake version 1.12, the parallel test harness allows the package authors to use third-party custom test drivers, in case the default ones are inadequate for their purposes, or do not support their testing protocol of choice.

A custom test driver is expected to properly run the test programs passed to it (including the command-line arguments passed to those programs, if any), to analyze their execution and outcome, to create the .log and .trs files associated to these test runs, and to display the test results on the console. It is responsibility of the author of the test driver to ensure that it implements all the above steps meaningfully and correctly; Automake isn’t and can’t be of any help here. On the other hand, the Automake-provided code for testsuite summary generation offers support for test drivers allowing several test results per test script, if they take care to register such results properly (see Log files generation and test results recording).

The exact details of how test scripts’ results are to be determined and analyzed is left to the individual drivers. Some drivers might only consider the test script exit status (this is done for example by the default test driver used by the parallel test harness, described in the previous section). Other drivers might implement more complex and advanced test protocols, which might require them to parse and interpreter the output emitted by the test script they’re running (examples of such protocols are TAP and SubUnit).

It’s very important to note that, even when using custom test drivers, most of the infrastructure described in the previous section about the parallel harness remains in place; this includes:

  • list of test scripts defined in TESTS, and overridable at runtime through the redefinition of TESTS or TEST_LOGS;
  • concurrency through the use of make’s option -j;
  • per-test .log and .trs files, and generation of a summary .log file from them;
  • recheck target, RECHECK_LOGS variable, and lazy reruns of tests;
  • inter-test dependencies;
  • support for check_* variables (check_PROGRAMS, check_LIBRARIES, ...);
  • use of VERBOSE environment variable to get verbose output on testsuite failures;
  • definition and honoring of TESTS_ENVIRONMENT, AM_TESTS_ENVIRONMENT and AM_TESTS_FD_REDIRECT variables;
  • definition of generic and extension-specific LOG_COMPILER and LOG_FLAGS variables.

On the other hand, the exact semantics of how (and if) testsuite output colorization, XFAIL_TESTS, and hard errors are supported and handled is left to the individual test drivers.


15.3.2 Declaring Custom Test Drivers

Custom testsuite drivers are declared by defining the make variables LOG_DRIVER or ext_LOG_DRIVER (where ext must be declared in TEST_EXTENSIONS). They must be defined to programs or scripts that will be used to drive the execution, logging, and outcome report of the tests with corresponding extensions (or of those with no registered extension in the case of LOG_DRIVER). Clearly, multiple distinct test drivers can be declared in the same Makefile.am. Note moreover that the LOG_DRIVER variables are not a substitute for the LOG_COMPILER variables: the two sets of variables can, and often do, usefully and legitimately coexist.

The developer-reserved variable AM_LOG_DRIVER_FLAGS and the user-reserved variable LOG_DRIVER_FLAGS can be used to define flags that will be passed to each invocation of LOG_DRIVER, with the user-defined flags obviously taking precedence over the developer-reserved ones. Similarly, for each extension ext declared in TEST_EXTENSIONS, flags listed in AM_ext_LOG_DRIVER_FLAGS and ext_LOG_DRIVER_FLAGS will be passed to invocations of ext_LOG_DRIVER.


15.3.3 API for Custom Test Drivers

Note that the APIs described here are still highly experimental, and will very likely undergo tightenings and likely also extensive changes in the future, to accommodate for new features or to satisfy additional portability requirements.

The main characteristic of these APIs is that they are designed to share as much infrastructure, semantics, and implementation details as possible with the parallel test harness and its default driver.


15.3.3.1 Command-line arguments for test drivers

A custom driver can rely on various command-line options and arguments being passed to it automatically by the Automake-generated test harness. It is mandatory that it understands all of them (even if the exact interpretation of the associated semantics can legitimately change between a test driver and another, and even be a no-op in some drivers).

Here is the list of options:

--test-name=NAME

The name of the test, with VPATH prefix (if any) removed. This can have a suffix and a directory component (as in e.g., sub/foo.test), and is mostly meant to be used in console reports about testsuite advancements and results (see Testsuite progress output).

--log-file=PATH.log

The .log file the test driver must create (see Basics of test metadata). If it has a directory component (as in e.g., sub/foo.log), the test harness will ensure that such directory exists before the test driver is called.

--trs-file=PATH.trs

The .trs file the test driver must create (see Basics of test metadata). If it has a directory component (as in e.g., sub/foo.trs), the test harness will ensure that such directory exists before the test driver is called.

--color-tests={yes|no}

Whether the console output should be colorized or not (see Simple tests and color-tests, to learn when this option gets activated and when it doesn’t).

--expect-failure={yes|no}

Whether the tested program is expected to fail.

--enable-hard-errors={yes|no}

Whether “hard errors” in the tested program should be treated differently from normal failures or not (the default should be yes). The exact meaning of “hard error” is highly dependent from the test protocols or conventions in use.

--

Explicitly terminate the list of options.

The first non-option argument passed to the test driver is the program to be run, and all the following ones are command-line options and arguments for this program.

Note that the exact semantics attached to the --color-tests, --expect-failure and --enable-hard-errors options are left up to the individual test drivers. Still, having a behaviour compatible or at least similar to that provided by the default driver is advised, as that would offer a better consistency and a more pleasant user experience.


15.3.3.2 Log files generation and test results recording

The test driver must correctly generate the files specified by the --log-file and --trs-file option (even when the tested program fails or crashes).

The .log file should ideally contain all the output produced by the tested program, plus optionally other information that might facilitate debugging or analysis of bug reports. Apart from that, its format is basically free.

The .trs file is used to register some metadata through the use of custom reStructuredText fields. This metadata is expected to be employed in various ways by the parallel test harness; for example, to count the test results when printing the testsuite summary, or to decide which tests to re-run upon make recheck. Unrecognized metadata in a .trs file is currently ignored by the harness, but this might change in the future. The list of currently recognized metadata follows.

:test-result:

The test driver must use this field to register the results of each test case run by a test script file. Several :test-result: fields can be present in the same .trs file; this is done in order to support test protocols that allow a single test script to run more test cases.

The only recognized test results are currently PASS, XFAIL, SKIP, FAIL, XPASS and ERROR. These results, when declared with :test-result:, can be optionally followed by text holding the name and/or a brief description of the corresponding test; the harness will ignore such extra text when generating test-suite.log and preparing the testsuite summary.

:recheck:

If this field is present and defined to no, then the corresponding test script will not be run upon a make recheck. What happens when two or more :recheck: fields are present in the same .trs file is undefined behaviour.

:copy-in-global-log:

If this field is present and defined to no, then the content of the .log file will not be copied into the global test-suite.log. We allow to forsake such copying because, while it can be useful in debugging and analysis of bug report, it can also be just a waste of space in normal situations, e.g., when a test script is successful. What happens when two or more :copy-in-global-log: fields are present in the same .trs file is undefined behaviour.

:test-global-result:

This is used to declare the "global result" of the script. Currently, the value of this field is needed only to be reported (more or less verbatim) in the generated global log file $(TEST_SUITE_LOG), so it’s quite free-form. For example, a test script which run 10 test cases, 6 of which pass and 4 of which are skipped, could reasonably have a PASS/SKIP value for this field, while a test script which run 19 successful tests and one failed test could have an ALMOST PASSED value. What happens when two or more :test-global-result: fields are present in the same .trs file is undefined behaviour.

Let’s see a small example. Assume a .trs file contains the following lines:

:test-result: PASS server starts
:global-log-copy: no
:test-result: PASS HTTP/1.1 request
:test-result: FAIL HTTP/1.0 request
:recheck: yes
:test-result: SKIP HTTPS request (TLS library wasn't available)
:test-result: PASS server stops

Then the corresponding test script will be re-run by make check, will contribute with five test results to the testsuite summary (three of these tests being successful, one failed, and one skipped), and the content of the corresponding .log file will not be copied in the global log file test-suite.log.


15.3.3.3 Testsuite progress output

A custom test driver also has the task of displaying, on the standard output, the test results as soon as they become available. Depending on the protocol in use, it can also display the reasons for failures and skips, and, more generally, any useful diagnostic output (but remember that each line on the screen is precious, so that cluttering the screen with overly verbose information is bad idea). The exact format of this progress output is left up to the test driver; in fact, a custom test driver might theoretically even decide not to do any such report, leaving it all to the testsuite summary (that would be a very lousy idea, of course, and serves only to illustrate the flexibility that is granted here).

Remember that consistency is good; so, if possible, try to be consistent with the output of the built-in Automake test drivers, providing a similar “look & feel”. In particular, the testsuite progress output should be colorized when the --color-tests is passed to the driver. On the other end, if you are using a known and widespread test protocol with well-established implementations, being consistent with those implementations’ output might be a good idea too.


15.4 Using the TAP test protocol


15.4.1 Introduction to TAP

TAP, the Test Anything Protocol, is a simple text-based interface between testing modules or programs and a test harness. The tests (also called “TAP producers” in this context) write test results in a simple format on standard output; a test harness (also called “TAP consumer”) will parse and interpret these results, and properly present them to the user, and/or register them for later analysis. The exact details of how this is accomplished can vary among different test harnesses. The Automake harness will present the results on the console in the usual fashion (see Testsuite progress on console), and will use the .trs files (see Basics of test metadata) to store the test results and related metadata. Apart from that, it will try to remain as much compatible as possible with pre-existing and widespread utilities, such as the prove utility, at least for the simpler usages.

TAP started its life as part of the test harness for Perl, but today it has been (mostly) standardized, and has various independent implementations in different languages; among them, C, C++, Perl, Python, PHP, and Java. For a semi-official specification of the TAP protocol, please refer to the documentation of Test::Harness::TAP.

The most relevant real-world usages of TAP are obviously in the testsuites of perl and of many perl modules. Still, also other important third-party packages, such as git, use TAP in their testsuite.


15.4.2 Use TAP with the Automake test harness

Currently, the TAP driver that comes with Automake requires some by-hand steps on the developer’s part (this situation should hopefully be improved in future Automake versions). You’ll have to grab the tap-driver.sh script from the Automake distribution by hand, copy it in your source tree, and use the Automake support for third-party test drivers to instruct the harness to use the tap-driver.sh script and the awk program found by AM_INIT_AUTOMAKE to run your TAP-producing tests. See the example below for clarification.

Apart from the options common to all the Automake test drivers (see Command-line arguments for test drivers), the tap-driver.sh supports the following options, whose names are chosen for enhanced compatibility with the prove utility.

--ignore-exit

Causes the test driver to ignore the exit status of the test scripts; by default, the driver will report an error if the script exits with a non-zero status. This option has effect also on non-zero exit statuses due to termination by a signal.

--comments

Instruct the test driver to display TAP diagnostic (i.e., lines beginning with the ‘#’ character) in the testsuite progress output too; by default, TAP diagnostic is only copied to the .log file.

--no-comments

Revert the effects of --comments.

--merge

Instruct the test driver to merge the test scripts’ standard error into their standard output. This is necessary if you want to ensure that diagnostics from the test scripts are displayed in the correct order relative to test results; this can be of great help in debugging (especially if your test scripts are shell scripts run with shell tracing active). As a downside, this option might cause the test harness to get confused if anything that appears on standard error looks like a test result.

--no-merge

Revert the effects of --merge.

--diagnostic-string=STRING

Change the string that introduces TAP diagnostic from the default value of “#” to STRING. This can be useful if your TAP-based test scripts produce verbose output on which they have limited control (because, say, the output comes from other tools invoked in the scripts), and it might contain text that gets spuriously interpreted as TAP diagnostic: such an issue can be solved by redefining the string that activates TAP diagnostic to a value you know won’t appear by chance in the tests’ output. Note however that this feature is non-standard, as the “official” TAP protocol does not allow for such a customization; so don’t use it if you can avoid it.

Here is an example of how the TAP driver can be set up and used.

% cat configure.ac
AC_INIT([GNU Try Tap], [1.0], [bug-automake@gnu.org])
AC_CONFIG_AUX_DIR([build-aux])
AM_INIT_AUTOMAKE([foreign -Wall -Werror])
AC_CONFIG_FILES([Makefile])
AC_REQUIRE_AUX_FILE([tap-driver.sh])
AC_OUTPUT

% cat Makefile.am
TEST_LOG_DRIVER = env AM_TAP_AWK='$(AWK)' $(SHELL) \
                  $(top_srcdir)/build-aux/tap-driver.sh
TESTS = foo.test bar.test baz.test
EXTRA_DIST = $(TESTS)

% cat foo.test
#!/bin/sh
echo 1..4 # Number of tests to be executed.
echo 'ok 1 - Swallows fly'
echo 'not ok 2 - Caterpillars fly # TODO metamorphosis in progress'
echo 'ok 3 - Pigs fly # SKIP not enough acid'
echo '# I just love word plays ...'
echo 'ok 4 - Flies fly too :-)'

% cat bar.test
#!/bin/sh
echo 1..3
echo 'not ok 1 - Bummer, this test has failed.'
echo 'ok 2 - This passed though.'
echo 'Bail out! Ennui kicking in, sorry...'
echo 'ok 3 - This will not be seen.'

% cat baz.test
#!/bin/sh
echo 1..1
echo ok 1
# Exit with error, even if all the tests have been successful.
exit 7

% cp PREFIX/share/automake-APIVERSION/tap-driver.sh .
% autoreconf -vi && ./configure && make check
...
PASS: foo.test 1 - Swallows fly
XFAIL: foo.test 2 - Caterpillars fly # TODO metamorphosis in progress
SKIP: foo.test 3 - Pigs fly # SKIP not enough acid
PASS: foo.test 4 - Flies fly too :-)
FAIL: bar.test 1 - Bummer, this test has failed.
PASS: bar.test 2 - This passed though.
ERROR: bar.test - Bail out! Ennui kicking in, sorry...
PASS: baz.test 1
ERROR: baz.test - exited with status 7
...
Please report to bug-automake@gnu.org
...
% echo exit status: $?
exit status: 1

% env TEST_LOG_DRIVER_FLAGS='--comments --ignore-exit' \
      TESTS='foo.test baz.test' make -e check
...
PASS: foo.test 1 - Swallows fly
XFAIL: foo.test 2 - Caterpillars fly # TODO metamorphosis in progress
SKIP: foo.test 3 - Pigs fly # SKIP not enough acid
# foo.test: I just love word plays...
PASS: foo.test 4 - Flies fly too :-)
PASS: baz.test 1
...
% echo exit status: $?
exit status: 0

15.4.3 Incompatibilities with other TAP parsers and drivers

For implementation or historical reasons, the TAP driver and harness as implemented by Automake have some minors incompatibilities with the mainstream versions, which you should be aware of.

  • A Bail out! directive doesn’t stop the whole testsuite, but only the test script it occurs in. This doesn’t follow TAP specifications, but on the other hand it maximizes compatibility (and code sharing) with the “hard error” concept of the default testsuite driver.
  • The version and pragma directives are not supported.
  • The --diagnostic-string option of our driver allows to modify the string that introduces TAP diagnostic from the default value of “#”. The standard TAP protocol has currently no way to allow this, so if you use it your diagnostic will be lost to more compliant tools like prove and Test::Harness
  • And there are probably some other small and yet undiscovered incompatibilities, especially in corner cases or with rare usages.

15.5 DejaGnu Tests

If dejagnu appears in AUTOMAKE_OPTIONS, then a dejagnu-based test suite is assumed. The variable DEJATOOL is a list of names that are passed, one at a time, as the --tool argument to runtest invocations; it defaults to the name of the package.

The variable RUNTESTDEFAULTFLAGS holds the --tool and --srcdir flags that are passed to dejagnu by default; this can be overridden if necessary.

The variables EXPECT and RUNTEST can also be overridden to provide project-specific values. For instance, you will need to do this if you are testing a compiler toolchain, because the default values do not take into account host and target names.

The contents of the variable RUNTESTFLAGS are passed to the runtest invocation. This is considered a “user variable” (see Variables reserved for the user). If you need to set runtest flags in Makefile.am, you can use AM_RUNTESTFLAGS instead.

Automake will generate rules to create a local site.exp file, defining various variables detected by configure. This file is automatically read by DejaGnu. It is OK for the user of a package to edit this file in order to tune the test suite. However this is not the place where the test suite author should define new variables: this should be done elsewhere in the real test suite code. Especially, site.exp should not be distributed.

Still, if the package author has legitimate reasons to extend site.exp at make time, he can do so by defining the variable EXTRA_DEJAGNU_SITE_CONFIG; the files listed there will be considered site.exp prerequisites, and their content will be appended to it (in the same order in which they appear in EXTRA_DEJAGNU_SITE_CONFIG). Note that files are not distributed by default.

For more information regarding DejaGnu test suites, see The DejaGnu Manual.


15.6 Install Tests

The installcheck target is available to the user as a way to run any tests after the package has been installed. You can add tests to this by writing an installcheck-local rule.


16 Rebuilding Makefiles

Automake generates rules to automatically rebuild Makefiles, configure, and other derived files like Makefile.in.

If you are using AM_MAINTAINER_MODE in configure.ac, then these automatic rebuilding rules are only enabled in maintainer mode.

Sometimes it is convenient to supplement the rebuild rules for configure or config.status with additional dependencies. The variables CONFIGURE_DEPENDENCIES and CONFIG_STATUS_DEPENDENCIES can be used to list these extra dependencies. These variables should be defined in all Makefiles of the tree (because these two rebuild rules are output in all them), so it is safer and easier to AC_SUBST them from configure.ac. For instance, the following statement will cause configure to be rerun each time version.sh is changed.

AC_SUBST([CONFIG_STATUS_DEPENDENCIES], ['$(top_srcdir)/version.sh'])

Note the ‘$(top_srcdir)/’ in the file name. Since this variable is to be used in all Makefiles, its value must be sensible at any level in the build hierarchy.

Beware not to mistake CONFIGURE_DEPENDENCIES for CONFIG_STATUS_DEPENDENCIES.

CONFIGURE_DEPENDENCIES adds dependencies to the configure rule, whose effect is to run autoconf. This variable should be seldom used, because automake already tracks m4_included files. However it can be useful when playing tricky games with m4_esyscmd or similar non-recommendable macros with side effects. Be also aware that interactions of this variable with the autom4te cache in The Autoconf Manual are quite problematic and can cause subtle breakage, so you might want to disable the cache if you want to use CONFIGURE_DEPENDENCIES.

CONFIG_STATUS_DEPENDENCIES adds dependencies to the config.status rule, whose effect is to run configure. This variable should therefore carry any non-standard source that may be read as a side effect of running configure, like version.sh in the example above.

Speaking of version.sh scripts, we recommend against them today. They are mainly used when the version of a package is updated automatically by a script (e.g., in daily builds). Here is what some old-style configure.acs may look like:

AC_INIT
. $srcdir/version.sh
AM_INIT_AUTOMAKE([name], $VERSION_NUMBER)
…

Here, version.sh is a shell fragment that sets VERSION_NUMBER. The problem with this example is that automake cannot track dependencies (listing version.sh in CONFIG_STATUS_DEPENDENCIES, and distributing this file is up to the user), and that it uses the obsolete form of AC_INIT and AM_INIT_AUTOMAKE. Upgrading to the new syntax is not straightforward, because shell variables are not allowed in AC_INIT’s arguments. We recommend that version.sh be replaced by an M4 file that is included by configure.ac:

m4_include([version.m4])
AC_INIT([name], VERSION_NUMBER)
AM_INIT_AUTOMAKE
…

Here version.m4 could contain something like ‘m4_define([VERSION_NUMBER], [1.2])’. The advantage of this second form is that automake will take care of the dependencies when defining the rebuild rule, and will also distribute the file automatically. An inconvenience is that autoconf will now be rerun each time the version number is bumped, when only configure had to be rerun in the previous setup.


17 Changing Automake’s Behavior


17.1 Options generalities

Various features of Automake can be controlled by options. Except where noted otherwise, options can be specified in one of several ways. Most options can be applied on a per-Makefile basis when listed in a special Makefile variable named AUTOMAKE_OPTIONS. Some of these options only make sense when specified in the toplevel Makefile.am file. Options are applied globally to all processed Makefile files when listed in the first argument of AM_INIT_AUTOMAKE in configure.ac, and some options which require changes to the configure script can only be specified there. These are annotated below.

As a general rule, options specified in AUTOMAKE_OPTIONS take precedence over those specified in AM_INIT_AUTOMAKE, which in turn take precedence over those specified on the command line.

Also, some care must be taken about the interactions among strictness level and warning categories. As a general rule, strictness-implied warnings are overridden by those specified by explicit options. For example, even if ‘portability’ warnings are disabled by default in foreign strictness, an usage like this will end up enabling them:

AUTOMAKE_OPTIONS = -Wportability foreign

However, a strictness level specified in a higher-priority context will override all the explicit warnings specified in a lower-priority context. For example, if configure.ac contains:

AM_INIT_AUTOMAKE([-Wportability])

and Makefile.am contains:

AUTOMAKE_OPTIONS = foreign

then ‘portability’ warnings will be disabled in Makefile.am.


17.2 List of Automake options

gnits
gnu
foreign

Set the strictness as appropriate. The gnits option also implies options readme-alpha and check-news.

check-news

Cause ‘make dist’ to fail unless the current version number appears in the first few lines of the NEWS file.

dejagnu

Cause dejagnu-specific rules to be generated. See DejaGnu Tests.

dist-bzip2

Hook dist-bzip2 to dist.

dist-lzip

Hook dist-lzip to dist.

dist-xz

Hook dist-xz to dist.

dist-zip

Hook dist-zip to dist.

dist-shar

Hook dist-shar to dist. Use of this option is deprecated, as the ‘shar’ format is obsolescent and problematic. Support for it will be removed altogether in Automake 2.0.

dist-tarZ

Hook dist-tarZ to dist. Use of this option is deprecated, as the ‘compress’ program is obsolete. Support for it will be removed altogether in Automake 2.0.

filename-length-max=99

Abort if file names longer than 99 characters are found during ‘make dist’. Such long file names are generally considered not to be portable in tarballs. See the tar-v7 and tar-ustar options below. This option should be used in the top-level Makefile.am or as an argument of AM_INIT_AUTOMAKE in configure.ac, it will be ignored otherwise. It will also be ignored in sub-packages of nested packages (see Nesting Packages).

info-in-builddir

Instruct Automake to place the generated .info files in the builddir rather than in the srcdir. Note that this might make VPATH builds with some non-GNU make implementations more brittle.

no-define

This option is meaningful only when passed as an argument to AM_INIT_AUTOMAKE. It will prevent the PACKAGE and VERSION variables from being AC_DEFINEd. But notice that they will remain defined as shell variables in the generated configure, and as make variables in the generated Makefile; this is deliberate, and required for backward compatibility.

no-dependencies

This is similar to using --ignore-deps on the command line, but is useful for those situations where you don’t have the necessary bits to make automatic dependency tracking work (see Automatic dependency tracking). In this case the effect is to effectively disable automatic dependency tracking.

no-dist

Don’t emit any code related to dist target. This is useful when a package has its own method for making distributions.

no-dist-gzip

Do not hook dist-gzip to dist.

no-exeext

If your Makefile.am defines a rule for target foo, it will override a rule for a target named ‘foo$(EXEEXT)’. This is necessary when EXEEXT is found to be empty. However, by default automake will generate an error for this use. The no-exeext option will disable this error. This is intended for use only where it is known in advance that the package will not be ported to Windows, or any other operating system using extensions on executables.

no-installinfo

The generated Makefile.in will not cause info pages to be built or installed by default. However, info and install-info targets will still be available. This option is disallowed at gnu strictness and above.

no-installman

The generated Makefile.in will not cause man pages to be installed by default. However, an install-man target will still be available for optional installation. This option is disallowed at gnu strictness and above.

nostdinc

This option can be used to disable the standard -I options that are ordinarily automatically provided by Automake.

no-texinfo.tex

Don’t require texinfo.tex, even if there are texinfo files in this directory.

serial-tests

Enable the older serial test suite harness for TESTS (see Older (and discouraged) serial test harness, for more information).

parallel-tests

Enable test suite harness for TESTS that can run tests in parallel (see Parallel Test Harness, for more information). This option is only kept for backward-compatibility, since the parallel test harness is the default now.

readme-alpha

If this release is an alpha release, and the file README-alpha exists, then it will be added to the distribution. If this option is given, version numbers are expected to follow one of two forms. The first form is ‘major.minor.alpha’, where each element is a number; the final period and number should be left off for non-alpha releases. The second form is ‘major.minoralpha’, where alpha is a letter; it should be omitted for non-alpha releases.

std-options

Make the installcheck rule check that installed scripts and programs support the --help and --version options. This also provides a basic check that the program’s run-time dependencies are satisfied after installation.

In a few situations, programs (or scripts) have to be exempted from this test. For instance, false (from GNU coreutils) is never successful, even for --help or --version. You can list such programs in the variable AM_INSTALLCHECK_STD_OPTIONS_EXEMPT. Programs (not scripts) listed in this variable should be suffixed by ‘$(EXEEXT)’ for the sake of Windows or OS/2. For instance, suppose we build false as a program but true.sh as a script, and that neither of them support --help or --version:

AUTOMAKE_OPTIONS = std-options
bin_PROGRAMS = false ...
bin_SCRIPTS = true.sh ...
AM_INSTALLCHECK_STD_OPTIONS_EXEMPT = false$(EXEEXT) true.sh
subdir-objects

If this option is specified, then objects are placed into the subdirectory of the build directory corresponding to the subdirectory of the source file. For instance, if the source file is subdir/file.cxx, then the output file would be subdir/file.o.

tar-v7
tar-ustar
tar-pax

These three mutually exclusive options select the tar format to use when generating tarballs with ‘make dist’. (The tar file created is then compressed according to the set of no-dist-gzip, dist-bzip2, dist-lzip, dist-xz and dist-tarZ options in use.)

These options must be passed as arguments to AM_INIT_AUTOMAKE (see Autoconf macros supplied with Automake) because they can require additional configure checks. Automake will complain if it sees such options in an AUTOMAKE_OPTIONS variable.

tar-v7 selects the old V7 tar format. This is the historical default. This antiquated format is understood by all tar implementations and supports file names with up to 99 characters. When given longer file names some tar implementations will diagnose the problem while other will generate broken tarballs or use non-portable extensions. Furthermore, the V7 format cannot store empty directories. When using this format, consider using the filename-length-max=99 option to catch file names too long.

tar-ustar selects the ustar format defined by POSIX 1003.1-1988. This format is believed to be old enough to be portable. It fully supports empty directories. It can store file names with up to 256 characters, provided that the file name can be split at directory separator in two parts, first of them being at most 155 bytes long. So, in most cases the maximum file name length will be shorter than 256 characters. However you may run against broken tar implementations that incorrectly handle file names longer than 99 characters (please report them to bug-automake@gnu.org so we can document this accurately).

tar-pax selects the new pax interchange format defined by POSIX 1003.1-2001. It does not limit the length of file names. However, this format is very young and should probably be restricted to packages that target only very modern platforms. There are moves to change the pax format in an upward-compatible way, so this option may refer to a more recent version in the future.

See Controlling the Archive Format in GNU Tar, for further discussion about tar formats.

configure knows several ways to construct these formats. It will not abort if it cannot find a tool up to the task (so that the package can still be built), but ‘make dist’ will fail.

version

A version number (e.g., ‘0.30’) can be specified. If Automake is not newer than the version specified, creation of the Makefile.in will be suppressed.

-Wcategory or --warnings=category

These options behave exactly like their command-line counterpart (see Creating a Makefile.in). This allows you to enable or disable some warning categories on a per-file basis. You can also setup some warnings for your entire project; for instance, try ‘AM_INIT_AUTOMAKE([-Wall])’ in your configure.ac.

Unrecognized options are diagnosed by automake.

If you want an option to apply to all the files in the tree, you can use the AM_INIT_AUTOMAKE macro in configure.ac. See Autoconf macros supplied with Automake.


18 Miscellaneous Rules

There are a few rules and variables that didn’t fit anywhere else.


18.1 Interfacing to etags

Automake will generate rules to generate TAGS files for use with GNU Emacs under some circumstances.

If any C, C++ or Fortran 77 source code or headers are present, then tags and TAGS rules will be generated for the directory. All files listed using the _SOURCES, _HEADERS, and _LISP primaries will be used to generate tags. Note that generated source files that are not distributed must be declared in variables like nodist_noinst_HEADERS or nodist_prog_SOURCES or they will be ignored.

A tags rule will be output at the topmost directory of a multi-directory package. When run from this topmost directory, ‘make tags’ will generate a TAGS file that includes by reference all TAGS files from subdirectories.

The tags rule will also be generated if the variable ETAGS_ARGS is defined. This variable is intended for use in directories that contain taggable source that etags does not understand. The user can use the ETAGSFLAGS to pass additional flags to etags; AM_ETAGSFLAGS is also available for use in Makefile.am.

Here is how Automake generates tags for its source, and for nodes in its Texinfo file:

ETAGS_ARGS = automake.in --lang=none \
 --regex='/^@node[ \t]+\([^,]+\)/\1/' automake.texi

If you add file names to ETAGS_ARGS, you will probably also want to define TAGS_DEPENDENCIES. The contents of this variable are added directly to the dependencies for the tags rule.

Automake also generates a ctags rule that can be used to build vi-style tags files. The variable CTAGS is the name of the program to invoke (by default ctags); CTAGSFLAGS can be used by the user to pass additional flags, and AM_CTAGSFLAGS can be used by the Makefile.am.

Automake will also generate an ID rule that will run mkid on the source. This is only supported on a directory-by-directory basis.

Similarly, the cscope rule will create a list of all the source files in the tree and run cscope to build an inverted index database. The variable CSCOPE is the name of the program to invoke (by default cscope); CSCOPEFLAGS and CSCOPE_ARGS can be used by the user to pass additional flags and file names respectively, while AM_CSCOPEFLAGS can be used by the Makefile.am. Note that, currently, the Automake-provided cscope support, when used in a VPATH build, might not work well with non-GNU make implementations (especially with make implementations performing VPATH rewrites in The Autoconf Manual).

Finally, Automake also emits rules to support the GNU Global Tags program. The GTAGS rule runs Global Tags and puts the result in the top build directory. The variable GTAGS_ARGS holds arguments that are passed to gtags.


18.2 Handling new file extensions

It is sometimes useful to introduce a new implicit rule to handle a file type that Automake does not know about.

For instance, suppose you had a compiler that could compile .foo files to .o files. You would simply define a suffix rule for your language:

.foo.o:
        foocc -c -o $@ $<

Then you could directly use a .foo file in a _SOURCES variable and expect the correct results:

bin_PROGRAMS = doit
doit_SOURCES = doit.foo

This was the simpler and more common case. In other cases, you will have to help Automake to figure out which extensions you are defining your suffix rule for. This usually happens when your extension does not start with a dot. Then, all you have to do is to put a list of new suffixes in the SUFFIXES variable before you define your implicit rule.

For instance, the following definition prevents Automake from misinterpreting the ‘.idlC.cpp:’ rule as an attempt to transform .idlC files into .cpp files.

SUFFIXES = .idl C.cpp
.idlC.cpp:
        # whatever

As you may have noted, the SUFFIXES variable behaves like the .SUFFIXES special target of make. You should not touch .SUFFIXES yourself, but use SUFFIXES instead and let Automake generate the suffix list for .SUFFIXES. Any given SUFFIXES go at the start of the generated suffixes list, followed by Automake generated suffixes not already in the list.


19 Include

Automake supports an include directive that can be used to include other Makefile fragments when automake is run. Note that these fragments are read and interpreted by automake, not by make. As with conditionals, make has no idea that include is in use.

There are two forms of include:

include $(srcdir)/file

Include a fragment that is found relative to the current source directory.

include $(top_srcdir)/file

Include a fragment that is found relative to the top source directory.

Note that if a fragment is included inside a conditional, then the condition applies to the entire contents of that fragment.

Makefile fragments included this way are always distributed because they are needed to rebuild Makefile.in.

Inside a fragment, the construct %reldir% is replaced with the directory of the fragment relative to the base Makefile.am. Similarly, %canon_reldir% is replaced with the canonicalized (see How derived variables are named) form of %reldir%. As a convenience, %D% is a synonym for %reldir%, and %C% is a synonym for %canon_reldir%.

A special feature is that if the fragment is in the same directory as the base Makefile.am (i.e., %reldir% is .), then %reldir% and %canon_reldir% will expand to the empty string as well as eat, if present, a following slash or underscore respectively.

Thus, a makefile fragment might look like this:

bin_PROGRAMS += %reldir%/mumble
%canon_reldir%_mumble_SOURCES = %reldir%/one.c

Next: , Previous: , Up: GNU Automake   [Contents][Index]

20 Conditionals

Automake supports a simple type of conditionals.

These conditionals are not the same as conditionals in GNU Make. Automake conditionals are checked at configure time by the configure script, and affect the translation from Makefile.in to Makefile. They are based on options passed to configure and on results that configure has discovered about the host system. GNU Make conditionals are checked at make time, and are based on variables passed to the make program or defined in the Makefile.

Automake conditionals will work with any make program.


20.1 Usage of Conditionals

Before using a conditional, you must define it by using AM_CONDITIONAL in the configure.ac file (see Autoconf macros supplied with Automake).

Macro: AM_CONDITIONAL (conditional, condition)

The conditional name, conditional, should be a simple string starting with a letter and containing only letters, digits, and underscores. It must be different from ‘TRUE’ and ‘FALSE’ that are reserved by Automake.

The shell condition (suitable for use in a shell if statement) is evaluated when configure is run. Note that you must arrange for every AM_CONDITIONAL to be invoked every time configure is run. If AM_CONDITIONAL is run conditionally (e.g., in a shell if statement), then the result will confuse automake.

Conditionals typically depend upon options that the user provides to the configure script. Here is an example of how to write a conditional that is true if the user uses the --enable-debug option.

AC_ARG_ENABLE([debug],
[  --enable-debug    Turn on debugging],
[case "${enableval}" in
  yes) debug=true ;;
  no)  debug=false ;;
  *) AC_MSG_ERROR([bad value ${enableval} for --enable-debug]) ;;
esac],[debug=false])
AM_CONDITIONAL([DEBUG], [test x$debug = xtrue])

Here is an example of how to use that conditional in Makefile.am:

if DEBUG
DBG = debug
else
DBG =
endif
noinst_PROGRAMS = $(DBG)

This trivial example could also be handled using EXTRA_PROGRAMS (see Conditional compilation of programs).

You may only test a single variable in an if statement, possibly negated using ‘!’. The else statement may be omitted. Conditionals may be nested to any depth. You may specify an argument to else in which case it must be the negation of the condition used for the current if. Similarly you may specify the condition that is closed on the endif line:

if DEBUG
DBG = debug
else !DEBUG
DBG =
endif !DEBUG

Unbalanced conditions are errors. The if, else, and endif statements should not be indented, i.e., start on column one.

The else branch of the above two examples could be omitted, since assigning the empty string to an otherwise undefined variable makes no difference.

In order to allow access to the condition registered by AM_CONDITIONAL inside configure.ac, and to allow conditional AC_CONFIG_FILES, AM_COND_IF may be used:

Macro: AM_COND_IF (conditional, [if-true], [if-false])

If conditional is fulfilled, execute if-true, otherwise execute if-false. If either branch contains AC_CONFIG_FILES, it will cause automake to output the rules for the respective files only for the given condition.

AM_COND_IF macros may be nested when m4 quotation is used properly (see M4 Quotation in The Autoconf Manual).

Here is an example of how to define a conditional config file:

AM_CONDITIONAL([SHELL_WRAPPER], [test "x$with_wrapper" = xtrue])
AM_COND_IF([SHELL_WRAPPER],
           [AC_CONFIG_FILES([wrapper:wrapper.in])])

20.2 Limits of Conditionals

Conditionals should enclose complete statements like variables or rules definitions. Automake cannot deal with conditionals used inside a variable definition, for instance, and is not even able to diagnose this situation. The following example would not work:

# This syntax is not understood by Automake
AM_CPPFLAGS = \
  -DFEATURE_A \
if WANT_DEBUG
  -DDEBUG \
endif
  -DFEATURE_B

However the intended definition of AM_CPPFLAGS can be achieved with

if WANT_DEBUG
  DEBUGFLAGS = -DDEBUG
endif
AM_CPPFLAGS = -DFEATURE_A $(DEBUGFLAGS) -DFEATURE_B

or

AM_CPPFLAGS = -DFEATURE_A
if WANT_DEBUG
AM_CPPFLAGS += -DDEBUG
endif
AM_CPPFLAGS += -DFEATURE_B

More details and examples of conditionals are described alongside various Automake features in this manual (see Conditional Subdirectories, see Conditional compilation of sources, see Conditional compilation of programs, see Building Libtool Libraries Conditionally, see Libtool Libraries with Conditional Sources).


21 Silencing make


21.1 Make is verbose by default

Normally, when executing the set of rules associated with a target, make prints each rule before it is executed. This behaviour, while having been in place for a long time, and being even mandated by the POSIX standard, starkly violates the “silence is golden” UNIX principle7:

When a program has nothing interesting or surprising to say, it should say nothing. Well-behaved Unix programs do their jobs unobtrusively, with a minimum of fuss and bother. Silence is golden.

In fact, while such verbosity of make can theoretically be useful to track bugs and understand reasons of failures right away, it can also hide warning and error messages from make-invoked tools, drowning them in a flood of uninteresting and seldom useful messages, and thus allowing them to go easily undetected.

This problem can be very annoying, especially for developers, who usually know quite well what’s going on behind the scenes, and for whom the verbose output from make ends up being mostly noise that hampers the easy detection of potentially important warning messages.


21.2 Standard and generic ways to silence make

Here we describe some common idioms/tricks to obtain a quieter make output, with their relative advantages and drawbacks. In the next section (How Automake can help in silencing make) we’ll see how Automake can help in this respect, providing more elaborate and flexible idioms.

  • make -s

    This simply causes make not to print any rule before executing it.

    The -s flag is mandated by POSIX, universally supported, and its purpose and function are easy to understand.

    But it also has its serious limitations too. First of all, it embodies an “all or nothing” strategy, i.e., either everything is silenced, or nothing is; this lack of granularity can sometimes be a fatal flaw. Moreover, when the -s flag is used, the make output might turn out to be too much terse; in case of errors, the user won’t be able to easily see what rule or command have caused them, or even, in case of tools with poor error reporting, what the errors were!

  • make >/dev/null || make

    Apparently, this perfectly obeys the “silence is golden” rule: warnings from stderr are passed through, output reporting is done only in case of error, and in that case it should provide a verbose-enough report to allow an easy determination of the error location and causes.

    However, calling make two times in a row might hide errors (especially intermittent ones), or subtly change the expected semantic of the make calls — things these which can clearly make debugging and error assessment very difficult.

  • make --no-print-directory

    This is GNU make specific. When called with the --no-print-directory option, GNU make will disable printing of the working directory by invoked sub-makes (the well-known “Entering/Leaving directory ...” messages). This helps to decrease the verbosity of the output, but experience has shown that it can also often render debugging considerably harder in projects using deeply-nested make recursion.

    As an aside, notice that the --no-print-directory option is automatically activated if the -s flag is used.


21.3 How Automake can help in silencing make

The tricks and idioms for silencing make described in the previous section can be useful from time to time, but we’ve seen that they all have their serious drawbacks and limitations. That’s why automake provides support for a more advanced and flexible way of obtaining quieter output from make (for most rules at least).

To give the gist of what Automake can do in this respect, here is a simple comparison between a typical make output (where silent rules are disabled) and one with silent rules enabled:

% cat Makefile.am
bin_PROGRAMS = foo
foo_SOURCES = main.c func.c
% cat main.c
int main (void) { return func (); }  /* func used undeclared */
% cat func.c
int func (void) { int i; return i; } /* i used uninitialized */

The make output is by default very verbose.  This causes warnings
from the compiler to be somewhat hidden, and not immediate to spot.
% make CFLAGS=-Wall
gcc -DPACKAGE_NAME=\"foo\" -DPACKAGE_TARNAME=\"foo\" ...
-DPACKAGE_STRING=\"foo\ 1.0\" -DPACKAGE_BUGREPORT=\"\" ...
-DPACKAGE=\"foo\" -DVERSION=\"1.0\" -I. -Wall -MT main.o
-MD -MP -MF .deps/main.Tpo -c -o main.o main.c
main.c: In function ‘main’:
main.c:3:3: warning: implicit declaration of function ‘func’
mv -f .deps/main.Tpo .deps/main.Po
gcc -DPACKAGE_NAME=\"foo\" -DPACKAGE_TARNAME=\"foo\" ...
-DPACKAGE_STRING=\"foo\ 1.0\" -DPACKAGE_BUGREPORT=\"\" ...
-DPACKAGE=\"foo\" -DVERSION=\"1.0\" -I. -Wall -MT func.o
-MD -MP -MF .deps/func.Tpo -c -o func.o func.c
func.c: In function ‘func’:
func.c:4:3: warning: ‘i’ used uninitialized in this function
mv -f .deps/func.Tpo .deps/func.Po
gcc -Wall -o foo main.o func.o

Clean up, so that we we can rebuild everything from scratch.
% make clean
test -z "foo" || rm -f foo
rm -f *.o

Silent rules enabled: the output is minimal but informative.  In
particular, the warnings from the compiler stick out very clearly.
% make V=0 CFLAGS=-Wall
  CC     main.o
main.c: In function ‘main’:
main.c:3:3: warning: implicit declaration of function ‘func’
  CC     func.o
func.c: In function ‘func’:
func.c:4:3: warning: ‘i’ used uninitialized in this function
  CCLD   foo

Also, in projects using libtool, the use of silent rules can automatically enable the libtool’s --silent option:

% cat Makefile.am
lib_LTLIBRARIES = libx.la

% make # Both make and libtool are verbose by default.
...
libtool: compile: gcc -DPACKAGE_NAME=\"foo\" ... -DLT_OBJDIR=\".libs/\"
  -I. -g -O2 -MT libx.lo -MD -MP -MF .deps/libx.Tpo -c libx.c -fPIC
  -DPIC -o .libs/libx.o
mv -f .deps/libx.Tpo .deps/libx.Plo
/bin/sh ./libtool --tag=CC --mode=link gcc -g -O2 -o libx.la -rpath
  /usr/local/lib libx.lo
libtool: link: gcc -shared .libs/libx.o -Wl,-soname -Wl,libx.so.0
  -o .libs/libx.so.0.0.0
libtool: link: cd .libs && rm -f libx.so && ln -s libx.so.0.0.0 libx.so
...

% make V=0
  CC     libx.lo
  CCLD   libx.la

For Automake-generated Makefiles, the user may influence the verbosity at configure run time as well as at make run time:

  • Passing --enable-silent-rules to configure will cause build rules to be less verbose; the option --disable-silent-rules will cause normal verbose output.
  • At make run time, the default chosen at configure time may be overridden: make V=1 will produce verbose output, make V=0 less verbose output.

Note that silent rules are disabled by default; the user must enable them explicitly at either configure run time or at make run time. We think that this is a good policy, since it provides the casual user with enough information to prepare a good bug report in case anything breaks.

Still, notwithstanding the rationales above, a developer who really wants to make silent rules enabled by default in his own package can do so by calling AM_SILENT_RULES([yes]) in configure.ac.

Users who prefer to have silent rules enabled by default can edit their config.site file to make the variable enable_silent_rules default to ‘yes’. This should still allow disabling silent rules at configure time and at make time.

For portability to different make implementations, package authors are advised to not set the variable V inside the Makefile.am file, to allow the user to override the value for subdirectories as well.

To work at its best, the current implementation of this feature normally uses nested variable expansion ‘$(var1$(V))’, a Makefile feature that is not required by POSIX 2008 but is widely supported in practice. On the rare make implementations that do not support nested variable expansion, whether rules are silent is always determined at configure time, and cannot be overridden at make time. Future versions of POSIX are likely to require nested variable expansion, so this minor limitation should go away with time.

To extend the silent mode to your own rules, you have few choices:

  • You can use the predefined variable AM_V_GEN as a prefix to commands that should output a status line in silent mode, and AM_V_at as a prefix to commands that should not output anything in silent mode. When output is to be verbose, both of these variables will expand to the empty string.
  • You can silence a recipe unconditionally with @, and then use the predefined variable AM_V_P to know whether make is being run in silent or verbose mode, adjust the verbose information your recipe displays accordingly:
    generate-headers:
                    ... [commands defining a shell variable '$headers'] ...; \
            if $(AM_V_P); then set -x; else echo " GEN   [headers]"; fi; \
            rm -f $$headers && generate-header --flags $$headers
    
  • You can add your own variables, so strings of your own choice are shown. The following snippet shows how you would define your own equivalent of AM_V_GEN:
    pkg_verbose = $(pkg_verbose_@AM_V@)
    pkg_verbose_ = $(pkg_verbose_@AM_DEFAULT_V@)
    pkg_verbose_0 = @echo PKG-GEN $@;
    
    foo: foo.in
            $(pkg_verbose)cp $(srcdir)/foo.in $@
    

As a final note, observe that, even when silent rules are enabled, the --no-print-directory option is still required with GNU make if the “Entering/Leaving directory ...” messages are to be disabled.


22 The effect of --gnu and --gnits

The --gnu option (or gnu in the AUTOMAKE_OPTIONS variable) causes automake to check the following:

Note that this option will be extended in the future to do even more checking; it is advisable to be familiar with the precise requirements of the GNU standards. Also, --gnu can require certain non-standard GNU programs to exist for use by various maintainer-only rules; for instance, in the future pathchk might be required for ‘make dist’.

The --gnits option does everything that --gnu does, and checks the following as well:


23 When Automake Isn’t Enough

In some situations, where Automake is not up to one task, one has to resort to handwritten rules or even handwritten Makefiles.


23.1 Extending Automake Rules

With some minor exceptions (for example _PROGRAMS variables, TESTS, or XFAIL_TESTS) being rewritten to append ‘$(EXEEXT)’), the contents of a Makefile.am is copied to Makefile.in verbatim.

These copying semantics mean that many problems can be worked around by simply adding some make variables and rules to Makefile.am. Automake will ignore these additions.

Since a Makefile.in is built from data gathered from three different places (Makefile.am, configure.ac, and automake itself), it is possible to have conflicting definitions of rules or variables. When building Makefile.in the following priorities are respected by automake to ensure the user always has the last word:

  • User defined variables in Makefile.am have priority over variables AC_SUBSTed from configure.ac, and AC_SUBSTed variables have priority over automake-defined variables.
  • As far as rules are concerned, a user-defined rule overrides any automake-defined rule for the same target.

These overriding semantics make it possible to fine tune some default settings of Automake, or replace some of its rules. Overriding Automake rules is often inadvisable, particularly in the topmost directory of a package with subdirectories. The -Woverride option (see Creating a Makefile.in) comes in handy to catch overridden definitions.

Note that Automake does not make any distinction between rules with commands and rules that only specify dependencies. So it is not possible to append new dependencies to an automake-defined target without redefining the entire rule.

However, various useful targets have a ‘-local’ version you can specify in your Makefile.am. Automake will supplement the standard target with these user-supplied targets.

The targets that support a local version are all, info, dvi, ps, pdf, html, check, install-data, install-dvi, install-exec, install-html, install-info, install-pdf, install-ps, uninstall, installdirs, installcheck and the various clean targets (mostlyclean, clean, distclean, and maintainer-clean).

Note that there are no uninstall-exec-local or uninstall-data-local targets; just use uninstall-local. It doesn’t make sense to uninstall just data or just executables.

For instance, here is one way to erase a subdirectory during ‘make clean’ (see What Gets Cleaned).

clean-local:
        -rm -rf testSubDir

You may be tempted to use install-data-local to install a file to some hard-coded location, but you should avoid this (see Installing to Hard-Coded Locations).

With the -local targets, there is no particular guarantee of execution order; typically, they are run early, but with parallel make, there is no way to be sure of that.

In contrast, some rules also have a way to run another rule, called a hook; hooks are always executed after the main rule’s work is done. The hook is named after the principal target, with ‘-hook’ appended. The targets allowing hooks are install-data, install-exec, uninstall, dist, and distcheck.

For instance, here is how to create a hard link to an installed program:

install-exec-hook:
        ln $(DESTDIR)$(bindir)/program$(EXEEXT) \
           $(DESTDIR)$(bindir)/proglink$(EXEEXT)

Although cheaper and more portable than symbolic links, hard links will not work everywhere (for instance, OS/2 does not have ln). Ideally you should fall back to ‘cp -p’ when ln does not work. An easy way, if symbolic links are acceptable to you, is to add AC_PROG_LN_S to configure.ac (see Particular Program Checks in The Autoconf Manual) and use ‘$(LN_S)’ in Makefile.am.

For instance, here is how you could install a versioned copy of a program using ‘$(LN_S)’:

install-exec-hook:
        cd $(DESTDIR)$(bindir) && \
          mv -f prog$(EXEEXT) prog-$(VERSION)$(EXEEXT) && \
          $(LN_S) prog-$(VERSION)$(EXEEXT) prog$(EXEEXT)

Note that we rename the program so that a new version will erase the symbolic link, not the real binary. Also we cd into the destination directory in order to create relative links.

When writing install-exec-hook or install-data-hook, please bear in mind that the exec/data distinction is based on the installation directory, not on the primary used (see The Two Parts of Install). So a foo_SCRIPTS will be installed by install-data, and a barexec_SCRIPTS will be installed by install-exec. You should define your hooks consequently.


23.2 Third-Party Makefiles

In most projects all Makefiles are generated by Automake. In some cases, however, projects need to embed subdirectories with handwritten Makefiles. For instance, one subdirectory could be a third-party project with its own build system, not using Automake.

It is possible to list arbitrary directories in SUBDIRS or DIST_SUBDIRS provided each of these directories has a Makefile that recognizes all the following recursive targets.

When a user runs one of these targets, that target is run recursively in all subdirectories. This is why it is important that even third-party Makefiles support them.

all

Compile the entire package. This is the default target in Automake-generated Makefiles, but it does not need to be the default in third-party Makefiles.

distdir

Copy files to distribute into ‘$(distdir)’, before a tarball is constructed. Of course this target is not required if the no-dist option (see Changing Automake’s Behavior) is used.

The variables ‘$(top_distdir)’ and ‘$(distdir)’ (see The dist Hook) will be passed from the outer package to the subpackage when the distdir target is invoked. These two variables have been adjusted for the directory that is being recursed into, so they are ready to use.

install
install-data
install-exec
uninstall

Install or uninstall files (see What Gets Installed).

install-dvi
install-html
install-info
install-ps
install-pdf

Install only some specific documentation format (see Texinfo).

installdirs

Create install directories, but do not install any files.

check
installcheck

Check the package (see Support for test suites).

mostlyclean
clean
distclean
maintainer-clean

Cleaning rules (see What Gets Cleaned).

dvi
pdf
ps
info
html

Build the documentation in various formats (see Texinfo).

tags
ctags

Build TAGS and CTAGS (see Interfacing to etags).

If you have ever used Gettext in a project, this is a good example of how third-party Makefiles can be used with Automake. The Makefiles gettextize puts in the po/ and intl/ directories are handwritten Makefiles that implement all of these targets. That way they can be added to SUBDIRS in Automake packages.

Directories that are only listed in DIST_SUBDIRS but not in SUBDIRS need only the distclean, maintainer-clean, and distdir rules (see Conditional Subdirectories).

Usually, many of these rules are irrelevant to the third-party subproject, but they are required for the whole package to work. It’s OK to have a rule that does nothing, so if you are integrating a third-party project with no documentation or tag support, you could simply augment its Makefile as follows:

EMPTY_AUTOMAKE_TARGETS = dvi pdf ps info html tags ctags
.PHONY: $(EMPTY_AUTOMAKE_TARGETS)
$(EMPTY_AUTOMAKE_TARGETS):

Another aspect of integrating third-party build systems is whether they support VPATH builds (see Parallel Build Trees (a.k.a. VPATH Builds)). Obviously if the subpackage does not support VPATH builds the whole package will not support VPATH builds. This in turns means that ‘make distcheck’ will not work, because it relies on VPATH builds. Some people can live without this (actually, many Automake users have never heard of ‘make distcheck’). Other people may prefer to revamp the existing Makefiles to support VPATH. Doing so does not necessarily require Automake, only Autoconf is needed (see Build Directories in The Autoconf Manual). The necessary substitutions: ‘@srcdir@’, ‘@top_srcdir@’, and ‘@top_builddir@’ are defined by configure when it processes a Makefile (see Preset Output Variables in The Autoconf Manual), they are not computed by the Makefile like the aforementioned ‘$(distdir)’ and ‘$(top_distdir)’ variables.

It is sometimes inconvenient to modify a third-party Makefile to introduce the above required targets. For instance, one may want to keep the third-party sources untouched to ease upgrades to new versions.

Here are two other ideas. If GNU make is assumed, one possibility is to add to that subdirectory a GNUmakefile that defines the required targets and includes the third-party Makefile. For this to work in VPATH builds, GNUmakefile must lie in the build directory; the easiest way to do this is to write a GNUmakefile.in instead, and have it processed with AC_CONFIG_FILES from the outer package. For example if we assume Makefile defines all targets except the documentation targets, and that the check target is actually called test, we could write GNUmakefile (or GNUmakefile.in) like this:

# First, include the real Makefile
include Makefile
# Then, define the other targets needed by Automake Makefiles.
.PHONY: dvi pdf ps info html check
dvi pdf ps info html:
check: test

A similar idea that does not use include is to write a proxy Makefile that dispatches rules to the real Makefile, either with ‘$(MAKE) -f Makefile.real $(AM_MAKEFLAGS) target’ (if it’s OK to rename the original Makefile) or with ‘cd subdir && $(MAKE) $(AM_MAKEFLAGS) target’ (if it’s OK to store the subdirectory project one directory deeper). The good news is that this proxy Makefile can be generated with Automake. All we need are -local targets (see Extending Automake Rules) that perform the dispatch. Of course the other Automake features are available, so you could decide to let Automake perform distribution or installation. Here is a possible Makefile.am:

all-local:
        cd subdir && $(MAKE) $(AM_MAKEFLAGS) all
check-local:
        cd subdir && $(MAKE) $(AM_MAKEFLAGS) test
clean-local:
        cd subdir && $(MAKE) $(AM_MAKEFLAGS) clean

# Assuming the package knows how to install itself
install-data-local:
        cd subdir && $(MAKE) $(AM_MAKEFLAGS) install-data
install-exec-local:
        cd subdir && $(MAKE) $(AM_MAKEFLAGS) install-exec
uninstall-local:
        cd subdir && $(MAKE) $(AM_MAKEFLAGS) uninstall

# Distribute files from here.
EXTRA_DIST = subdir/Makefile subdir/program.c ...

Pushing this idea to the extreme, it is also possible to ignore the subproject build system and build everything from this proxy Makefile.am. This might sound very sensible if you need VPATH builds but the subproject does not support them.


24 Distributing Makefile.ins

Automake places no restrictions on the distribution of the resulting Makefile.ins. We still encourage software authors to distribute their work under terms like those of the GPL, but doing so is not required to use Automake.

Some of the files that can be automatically installed via the --add-missing switch do fall under the GPL. However, these also have a special exception allowing you to distribute them with your package, regardless of the licensing you choose.


25 Automake API Versioning

New Automake releases usually include bug fixes and new features. Unfortunately they may also introduce new bugs and incompatibilities. This makes four reasons why a package may require a particular Automake version.

Things get worse when maintaining a large tree of packages, each one requiring a different version of Automake. In the past, this meant that any developer (and sometimes users) had to install several versions of Automake in different places, and switch ‘$PATH’ appropriately for each package.

Starting with version 1.6, Automake installs versioned binaries. This means you can install several versions of Automake in the same ‘$prefix’, and can select an arbitrary Automake version by running automake-1.6 or automake-1.7 without juggling with ‘$PATH’. Furthermore, Makefile’s generated by Automake 1.6 will use automake-1.6 explicitly in their rebuild rules.

The number ‘1.6’ in automake-1.6 is Automake’s API version, not Automake’s version. If a bug fix release is made, for instance Automake 1.6.1, the API version will remain 1.6. This means that a package that works with Automake 1.6 should also work with 1.6.1; after all, this is what people expect from bug fix releases.

If your package relies on a feature or a bug fix introduced in a release, you can pass this version as an option to Automake to ensure older releases will not be used. For instance, use this in your configure.ac:

  AM_INIT_AUTOMAKE([1.6.1])    dnl Require Automake 1.6.1 or better.

or, in a particular Makefile.am:

  AUTOMAKE_OPTIONS = 1.6.1   # Require Automake 1.6.1 or better.

Automake will print an error message if its version is older than the requested version.

What is in the API

Automake’s programming interface is not easy to define. Basically it should include at least all documented variables and targets that a Makefile.am author can use, any behavior associated with them (e.g., the places where ‘-hook’’s are run), the command line interface of automake and aclocal, …

What is not in the API

Every undocumented variable, target, or command line option, is not part of the API. You should avoid using them, as they could change from one version to the other (even in bug fix releases, if this helps to fix a bug).

If it turns out you need to use such an undocumented feature, contact automake@gnu.org and try to get it documented and exercised by the test-suite.


26 Upgrading a Package to a Newer Automake Version

Automake maintains three kind of files in a package.

aclocal.m4 is generated by aclocal and contains some Automake-supplied M4 macros. Auxiliary tools are installed by ‘automake --add-missing’ when needed. Makefile.ins are built from Makefile.am by automake, and rely on the definitions of the M4 macros put in aclocal.m4 as well as the behavior of the auxiliary tools installed.

Because all of these files are closely related, it is important to regenerate all of them when upgrading to a newer Automake release. The usual way to do that is

aclocal # with any option needed (such a -I m4)
autoconf
automake --add-missing --force-missing

or more conveniently:

autoreconf -vfi

The use of --force-missing ensures that auxiliary tools will be overridden by new versions (see Creating a Makefile.in).

It is important to regenerate all of these files each time Automake is upgraded, even between bug fixes releases. For instance, it is not unusual for a bug fix to involve changes to both the rules generated in Makefile.in and the supporting M4 macros copied to aclocal.m4.

Presently automake is able to diagnose situations where aclocal.m4 has been generated with another version of aclocal. However it never checks whether auxiliary scripts are up-to-date. In other words, automake will tell you when aclocal needs to be rerun, but it will never diagnose a missing --force-missing.

Before upgrading to a new major release, it is a good idea to read the file NEWS. This file lists all changes between releases: new features, obsolete constructs, known incompatibilities, and workarounds.


27 Frequently Asked Questions about Automake

This chapter covers some questions that often come up on the mailing lists.


27.1 CVS and generated files

Background: distributed generated Files

Packages made with Autoconf and Automake ship with some generated files like configure or Makefile.in. These files were generated on the developer’s machine and are distributed so that end-users do not have to install the maintainer tools required to rebuild them. Other generated files like Lex scanners, Yacc parsers, or Info documentation, are usually distributed on similar grounds.

Automake output rules in Makefiles to rebuild these files. For instance, make will run autoconf to rebuild configure whenever configure.ac is changed. This makes development safer by ensuring a configure is never out-of-date with respect to configure.ac.

As generated files shipped in packages are up-to-date, and because tar preserves times-tamps, these rebuild rules are not triggered when a user unpacks and builds a package.

Background: CVS and Timestamps

Unless you use CVS keywords (in which case files must be updated at commit time), CVS preserves timestamp during ‘cvs commit’ and ‘cvs import -d’ operations.

When you check out a file using ‘cvs checkout’ its timestamp is set to that of the revision that is being checked out.

However, during cvs update, files will have the date of the update, not the original timestamp of this revision. This is meant to make sure that make notices sources files have been updated.

This timestamp shift is troublesome when both sources and generated files are kept under CVS. Because CVS processes files in lexical order, configure.ac will appear newer than configure after a cvs update that updates both files, even if configure was newer than configure.ac when it was checked in. Calling make will then trigger a spurious rebuild of configure.

Living with CVS in Autoconfiscated Projects

There are basically two clans amongst maintainers: those who keep all distributed files under CVS, including generated files, and those who keep generated files out of CVS.

All Files in CVS

  • The CVS repository contains all distributed files so you know exactly what is distributed, and you can checkout any prior version entirely.
  • Maintainers can see how generated files evolve (for instance, you can see what happens to your Makefile.ins when you upgrade Automake and make sure they look OK).
  • Users do not need the autotools to build a checkout of the project, it works just like a released tarball.
  • If users use cvs update to update their copy, instead of cvs checkout to fetch a fresh one, timestamps will be inaccurate. Some rebuild rules will be triggered and attempt to run developer tools such as autoconf or automake.

    Calls to such tools are all wrapped into a call to the missing script discussed later (see missing and AM_MAINTAINER_MODE), so that the user will see more descriptive warnings about missing or out-of-date tools, and possible suggestions about how to obtain them, rather than just some “command not found” error, or (worse) some obscure message from some older version of the required tool they happen to have installed.

    Maintainers interested in keeping their package buildable from a CVS checkout even for those users that lack maintainer-specific tools might want to provide an helper script (or to enhance their existing bootstrap script) to fix the timestamps after a cvs update or a git checkout, to prevent spurious rebuilds. In case of a project committing the Autotools-generated files, as well as the generated .info files, such script might look something like this:

    #!/bin/sh
    # fix-timestamp.sh: prevents useless rebuilds after "cvs update"
    sleep 1
    # aclocal-generated aclocal.m4 depends on locally-installed
    # '.m4' macro files, as well as on 'configure.ac'
    touch aclocal.m4
    sleep 1
    # autoconf-generated configure depends on aclocal.m4 and on
    # configure.ac
    touch configure
    # so does autoheader-generated config.h.in
    touch config.h.in
    # and all the automake-generated Makefile.in files
    touch `find . -name Makefile.in -print`
    # finally, the makeinfo-generated '.info' files depend on the
    # corresponding '.texi' files
    touch doc/*.info
    
  • In distributed development, developers are likely to have different version of the maintainer tools installed. In this case rebuilds triggered by timestamp lossage will lead to spurious changes to generated files. There are several solutions to this:
    • All developers should use the same versions, so that the rebuilt files are identical to files in CVS. (This starts to be difficult when each project you work on uses different versions.)
    • Or people use a script to fix the timestamp after a checkout (the GCC folks have such a script).
    • Or configure.ac uses AM_MAINTAINER_MODE, which will disable all of these rebuild rules by default. This is further discussed in missing and AM_MAINTAINER_MODE.
  • Although we focused on spurious rebuilds, the converse can also happen. CVS’s timestamp handling can also let you think an out-of-date file is up-to-date.

    For instance, suppose a developer has modified Makefile.am and has rebuilt Makefile.in, and then decides to do a last-minute change to Makefile.am right before checking in both files (without rebuilding Makefile.in to account for the change).

    This last change to Makefile.am makes the copy of Makefile.in out-of-date. Since CVS processes files alphabetically, when another developer ‘cvs update’s his or her tree, Makefile.in will happen to be newer than Makefile.am. This other developer will not see that Makefile.in is out-of-date.

Generated Files out of CVS

One way to get CVS and make working peacefully is to never store generated files in CVS, i.e., do not CVS-control files that are Makefile targets (also called derived files).

This way developers are not annoyed by changes to generated files. It does not matter if they all have different versions (assuming they are compatible, of course). And finally, timestamps are not lost, changes to sources files can’t be missed as in the Makefile.am/Makefile.in example discussed earlier.

The drawback is that the CVS repository is not an exact copy of what is distributed and that users now need to install various development tools (maybe even specific versions) before they can build a checkout. But, after all, CVS’s job is versioning, not distribution.

Allowing developers to use different versions of their tools can also hide bugs during distributed development. Indeed, developers will be using (hence testing) their own generated files, instead of the generated files that will be released actually. The developer who prepares the tarball might be using a version of the tool that produces bogus output (for instance a non-portable C file), something other developers could have noticed if they weren’t using their own versions of this tool.

Third-party Files

Another class of files not discussed here (because they do not cause timestamp issues) are files that are shipped with a package, but maintained elsewhere. For instance, tools like gettextize and autopoint (from Gettext) or libtoolize (from Libtool), will install or update files in your package.

These files, whether they are kept under CVS or not, raise similar concerns about version mismatch between developers’ tools. The Gettext manual has a section about this, see Integrating with CVS in GNU gettext tools.


27.2 missing and AM_MAINTAINER_MODE

missing

The missing script is a wrapper around several maintainer tools, designed to warn users if a maintainer tool is required but missing. Typical maintainer tools are autoconf, automake, bison, etc. Because file generated by these tools are shipped with the other sources of a package, these tools shouldn’t be required during a user build and they are not checked for in configure.

However, if for some reason a rebuild rule is triggered and involves a missing tool, missing will notice it and warn the user, even suggesting how to obtain such a tool (at least in case it is a well-known one, like makeinfo or bison). This is more helpful and user-friendly than just having the rebuild rules spewing out a terse error message like ‘sh: tool: command not found’. Similarly, missing will warn the user if it detects that a maintainer tool it attempted to use seems too old (be warned that diagnosing this correctly is typically more difficult that detecting missing tools, and requires cooperation from the tool itself, so it won’t always work).

If the required tool is installed, missing will run it and won’t attempt to continue after failures. This is correct during development: developers love fixing failures. However, users with missing or too old maintainer tools may get an error when the rebuild rule is spuriously triggered, halting the build. This failure to let the build continue is one of the arguments of the AM_MAINTAINER_MODE advocates.

AM_MAINTAINER_MODE

AM_MAINTAINER_MODE allows you to choose whether the so called "rebuild rules" should be enabled or disabled. With AM_MAINTAINER_MODE([enable]), they are enabled by default, otherwise they are disabled by default. In the latter case, if you have AM_MAINTAINER_MODE in configure.ac, and run ‘./configure && make’, then make will *never* attempt to rebuild configure, Makefile.ins, Lex or Yacc outputs, etc. I.e., this disables build rules for files that are usually distributed and that users should normally not have to update.

The user can override the default setting by passing either ‘--enable-maintainer-mode’ or ‘--disable-maintainer-mode’ to configure.

People use AM_MAINTAINER_MODE either because they do not want their users (or themselves) annoyed by timestamps lossage (see CVS and generated files), or because they simply can’t stand the rebuild rules and prefer running maintainer tools explicitly.

AM_MAINTAINER_MODE also allows you to disable some custom build rules conditionally. Some developers use this feature to disable rules that need exotic tools that users may not have available.

Several years ago François Pinard pointed out several arguments against this AM_MAINTAINER_MODE macro. Most of them relate to insecurity. By removing dependencies you get non-dependable builds: changes to sources files can have no effect on generated files and this can be very confusing when unnoticed. He adds that security shouldn’t be reserved to maintainers (what --enable-maintainer-mode suggests), on the contrary. If one user has to modify a Makefile.am, then either Makefile.in should be updated or a warning should be output (this is what Automake uses missing for) but the last thing you want is that nothing happens and the user doesn’t notice it (this is what happens when rebuild rules are disabled by AM_MAINTAINER_MODE).

Jim Meyering, the inventor of the AM_MAINTAINER_MODE macro was swayed by François’s arguments, and got rid of AM_MAINTAINER_MODE in all of his packages.

Still many people continue to use AM_MAINTAINER_MODE, because it helps them working on projects where all files are kept under version control, and because missing isn’t enough if you have the wrong version of the tools.


27.3 Why doesn’t Automake support wildcards?

Developers are lazy. They would often like to use wildcards in Makefile.ams, so that they would not need to remember to update Makefile.ams every time they add, delete, or rename a file.

There are several objections to this:

  • When using CVS (or similar) developers need to remember they have to run ‘cvs add’ or ‘cvs rm’ anyway. Updating Makefile.am accordingly quickly becomes a reflex.

    Conversely, if your application doesn’t compile because you forgot to add a file in Makefile.am, it will help you remember to ‘cvs add’ it.

  • Using wildcards makes it easy to distribute files by mistake. For instance, some code a developer is experimenting with (a test case, say) that should not be part of the distribution.
  • Using wildcards it’s easy to omit some files by mistake. For instance, one developer creates a new file, uses it in many places, but forgets to commit it. Another developer then checks out the incomplete project and is able to run ‘make dist’ successfully, even though a file is missing. By listing files, ‘make distwill complain.
  • Wildcards are not portable to some non-GNU make implementations, e.g., NetBSD make will not expand globs such as ‘*’ in prerequisites of a target.
  • Finally, it’s really hard to forget to add a file to Makefile.am: files that are not listed in Makefile.am are not compiled or installed, so you can’t even test them.

Still, these are philosophical objections, and as such you may disagree, or find enough value in wildcards to dismiss all of them. Before you start writing a patch against Automake to teach it about wildcards, let’s see the main technical issue: portability.

Although ‘$(wildcard ...)’ works with GNU make, it is not portable to other make implementations.

The only way Automake could support $(wildcard ...) is by expanding $(wildcard ...) when automake is run. The resulting Makefile.ins would be portable since they would list all files and not use ‘$(wildcard ...)’. However that means developers would need to remember to run automake each time they add, delete, or rename files.

Compared to editing Makefile.am, this is a very small gain. Sure, it’s easier and faster to type ‘automake; make’ than to type ‘emacs Makefile.am; make’. But nobody bothered enough to write a patch to add support for this syntax. Some people use scripts to generate file lists in Makefile.am or in separate Makefile fragments.

Even if you don’t care about portability, and are tempted to use ‘$(wildcard ...)’ anyway because you target only GNU Make, you should know there are many places where Automake needs to know exactly which files should be processed. As Automake doesn’t know how to expand ‘$(wildcard ...)’, you cannot use it in these places. ‘$(wildcard ...)’ is a black box comparable to AC_SUBSTed variables as far Automake is concerned.

You can get warnings about ‘$(wildcard ...’) constructs using the -Wportability flag.


27.4 Limitations on File Names

Automake attempts to support all kinds of file names, even those that contain unusual characters or are unusually long. However, some limitations are imposed by the underlying operating system and tools.

Most operating systems prohibit the use of the null byte in file names, and reserve ‘/’ as a directory separator. Also, they require that file names are properly encoded for the user’s locale. Automake is subject to these limits.

Portable packages should limit themselves to POSIX file names. These can contain ASCII letters and digits, ‘_’, ‘.’, and ‘-’. File names consist of components separated by ‘/’. File name components cannot begin with ‘-’.

Portable POSIX file names cannot contain components that exceed a 14-byte limit, but nowadays it’s normally safe to assume the more-generous XOPEN limit of 255 bytes. POSIX limits file names to 255 bytes (XOPEN allows 1023 bytes), but you may want to limit a source tarball to file names of 99 bytes to avoid interoperability problems with old versions of tar.

If you depart from these rules (e.g., by using non-ASCII characters in file names, or by using lengthy file names), your installers may have problems for reasons unrelated to Automake. However, if this does not concern you, you should know about the limitations imposed by Automake itself. These limitations are undesirable, but some of them seem to be inherent to underlying tools like Autoconf, Make, M4, and the shell. They fall into three categories: install directories, build directories, and file names.

The following characters:

newline " # $ ' `

should not appear in the names of install directories. For example, the operand of configure’s --prefix option should not contain these characters.

Build directories suffer the same limitations as install directories, and in addition should not contain the following characters:

& @ \

For example, the full name of the directory containing the source files should not contain these characters.

Source and installation file names like main.c are limited even further: they should conform to the POSIX/XOPEN rules described above. In addition, if you plan to port to non-POSIX environments, you should avoid file names that differ only in case (e.g., makefile and Makefile). Nowadays it is no longer worth worrying about the 8.3 limits of DOS file systems.


27.5 Errors with distclean

This is a diagnostic you might encounter while running ‘make distcheck’.

As explained in Checking the Distribution, ‘make distcheck’ attempts to build and check your package for errors like this one.

make distcheck’ will perform a VPATH build of your package (see Parallel Build Trees (a.k.a. VPATH Builds)), and then call ‘make distclean’. Files left in the build directory after ‘make distclean’ has run are listed after this error.

This diagnostic really covers two kinds of errors:

  • files that are forgotten by distclean;
  • distributed files that are erroneously rebuilt.

The former left-over files are not distributed, so the fix is to mark them for cleaning (see What Gets Cleaned), this is obvious and doesn’t deserve more explanations.

The latter bug is not always easy to understand and fix, so let’s proceed with an example. Suppose our package contains a program for which we want to build a man page using help2man. GNU help2man produces simple manual pages from the --help and --version output of other commands (see Overview in The Help2man Manual). Because we don’t want to force our users to install help2man, we decide to distribute the generated man page using the following setup.

# This Makefile.am is bogus.
bin_PROGRAMS = foo
foo_SOURCES = foo.c
dist_man_MANS = foo.1

foo.1: foo$(EXEEXT)
        help2man --output=foo.1 ./foo$(EXEEXT)

This will effectively distribute the man page. However, ‘make distcheck’ will fail with:

ERROR: files left in build directory after distclean:
./foo.1

Why was foo.1 rebuilt? Because although distributed, foo.1 depends on a non-distributed built file: foo$(EXEEXT). foo$(EXEEXT) is built by the user, so it will always appear to be newer than the distributed foo.1.

make distcheck’ caught an inconsistency in our package. Our intent was to distribute foo.1 so users do not need to install help2man, however since this rule causes this file to be always rebuilt, users do need help2man. Either we should ensure that foo.1 is not rebuilt by users, or there is no point in distributing foo.1.

More generally, the rule is that distributed files should never depend on non-distributed built files. If you distribute something generated, distribute its sources.

One way to fix the above example, while still distributing foo.1 is to not depend on foo$(EXEEXT). For instance, assuming foo --version and foo --help do not change unless foo.c or configure.ac change, we could write the following Makefile.am:

bin_PROGRAMS = foo
foo_SOURCES = foo.c
dist_man_MANS = foo.1

foo.1: foo.c $(top_srcdir)/configure.ac
        $(MAKE) $(AM_MAKEFLAGS) foo$(EXEEXT)
        help2man --output=foo.1 ./foo$(EXEEXT)

This way, foo.1 will not get rebuilt every time foo$(EXEEXT) changes. The make call makes sure foo$(EXEEXT) is up-to-date before help2man. Another way to ensure this would be to use separate directories for binaries and man pages, and set SUBDIRS so that binaries are built before man pages.

We could also decide not to distribute foo.1. In this case it’s fine to have foo.1 dependent upon foo$(EXEEXT), since both will have to be rebuilt. However it would be impossible to build the package in a cross-compilation, because building foo.1 involves an execution of foo$(EXEEXT).

Another context where such errors are common is when distributed files are built by tools that are built by the package. The pattern is similar:

distributed-file: built-tools distributed-sources
        build-command

should be changed to

distributed-file: distributed-sources
        $(MAKE) $(AM_MAKEFLAGS) built-tools
        build-command

or you could choose not to distribute distributed-file, if cross-compilation does not matter.

The points made through these examples are worth a summary:

  • Distributed files should never depend upon non-distributed built files.
  • Distributed files should be distributed with all their dependencies.
  • If a file is intended to be rebuilt by users, then there is no point in distributing it.

For desperate cases, it’s always possible to disable this check by setting distcleancheck_listfiles as documented in Checking the Distribution. Make sure you do understand the reason why ‘make distcheck’ complains before you do this. distcleancheck_listfiles is a way to hide errors, not to fix them. You can always do better.


27.6 Flag Variables Ordering

What is the difference between AM_CFLAGS, CFLAGS, and
mumble_CFLAGS?
Why does automake output CPPFLAGS after
AM_CPPFLAGS on compile lines?  Shouldn’t it be the converse?
My configure adds some warning flags into CXXFLAGS.  In
one Makefile.am I would like to append a new flag, however if I
put the flag into AM_CXXFLAGS it is prepended to the other
flags, not appended.

Compile Flag Variables

This section attempts to answer all the above questions. We will mostly discuss CPPFLAGS in our examples, but actually the answer holds for all the compile flags used in Automake: CCASFLAGS, CFLAGS, CPPFLAGS, CXXFLAGS, FCFLAGS, FFLAGS, GCJFLAGS, LDFLAGS, LFLAGS, LIBTOOLFLAGS, OBJCFLAGS, OBJCXXFLAGS, RFLAGS, UPCFLAGS, and YFLAGS.

CPPFLAGS, AM_CPPFLAGS, and mumble_CPPFLAGS are three variables that can be used to pass flags to the C preprocessor (actually these variables are also used for other languages like C++ or preprocessed Fortran). CPPFLAGS is the user variable (see Variables reserved for the user), AM_CPPFLAGS is the Automake variable, and mumble_CPPFLAGS is the variable specific to the mumble target (we call this a per-target variable, see Program and Library Variables).

Automake always uses two of these variables when compiling C sources files. When compiling an object file for the mumble target, the first variable will be mumble_CPPFLAGS if it is defined, or AM_CPPFLAGS otherwise. The second variable is always CPPFLAGS.

In the following example,

bin_PROGRAMS = foo bar
foo_SOURCES = xyz.c
bar_SOURCES = main.c
foo_CPPFLAGS = -DFOO
AM_CPPFLAGS = -DBAZ

xyz.o will be compiled with ‘$(foo_CPPFLAGS) $(CPPFLAGS)’, (because xyz.o is part of the foo target), while main.o will be compiled with ‘$(AM_CPPFLAGS) $(CPPFLAGS)’ (because there is no per-target variable for target bar).

The difference between mumble_CPPFLAGS and AM_CPPFLAGS being clear enough, let’s focus on CPPFLAGS. CPPFLAGS is a user variable, i.e., a variable that users are entitled to modify in order to compile the package. This variable, like many others, is documented at the end of the output of ‘configure --help’.

For instance, someone who needs to add /home/my/usr/include to the C compiler’s search path would configure a package with

./configure CPPFLAGS='-I /home/my/usr/include'

and this flag would be propagated to the compile rules of all Makefiles.

It is also not uncommon to override a user variable at make-time. Many installers do this with prefix, but this can be useful with compiler flags too. For instance, if, while debugging a C++ project, you need to disable optimization in one specific object file, you can run something like

rm file.o
make CXXFLAGS=-O0 file.o
make

The reason ‘$(CPPFLAGS)’ appears after ‘$(AM_CPPFLAGS)’ or ‘$(mumble_CPPFLAGS)’ in the compile command is that users should always have the last say. It probably makes more sense if you think about it while looking at the ‘CXXFLAGS=-O0’ above, which should supersede any other switch from AM_CXXFLAGS or mumble_CXXFLAGS (and this of course replaces the previous value of CXXFLAGS).

You should never redefine a user variable such as CPPFLAGS in Makefile.am. Use ‘automake -Woverride’ to diagnose such mistakes. Even something like

CPPFLAGS = -DDATADIR=\"$(datadir)\" @CPPFLAGS@

is erroneous. Although this preserves configure’s value of CPPFLAGS, the definition of DATADIR will disappear if a user attempts to override CPPFLAGS from the make command line.

AM_CPPFLAGS = -DDATADIR=\"$(datadir)\"

is all that is needed here if no per-target flags are used.

You should not add options to these user variables within configure either, for the same reason. Occasionally you need to modify these variables to perform a test, but you should reset their values afterwards. In contrast, it is OK to modify the ‘AM_’ variables within configure if you AC_SUBST them, but it is rather rare that you need to do this, unless you really want to change the default definitions of the ‘AM_’ variables in all Makefiles.

What we recommend is that you define extra flags in separate variables. For instance, you may write an Autoconf macro that computes a set of warning options for the C compiler, and AC_SUBST them in WARNINGCFLAGS; you may also have an Autoconf macro that determines which compiler and which linker flags should be used to link with library libfoo, and AC_SUBST these in LIBFOOCFLAGS and LIBFOOLDFLAGS. Then, a Makefile.am could use these variables as follows:

AM_CFLAGS = $(WARNINGCFLAGS)
bin_PROGRAMS = prog1 prog2
prog1_SOURCES = …
prog2_SOURCES = …
prog2_CFLAGS = $(LIBFOOCFLAGS) $(AM_CFLAGS)
prog2_LDFLAGS = $(LIBFOOLDFLAGS)

In this example both programs will be compiled with the flags substituted into ‘$(WARNINGCFLAGS)’, and prog2 will additionally be compiled with the flags required to link with libfoo.

Note that listing AM_CFLAGS in a per-target CFLAGS variable is a common idiom to ensure that AM_CFLAGS applies to every target in a Makefile.in.

Using variables like this gives you full control over the ordering of the flags. For instance, if there is a flag in $(WARNINGCFLAGS) that you want to negate for a particular target, you can use something like ‘prog1_CFLAGS = $(AM_CFLAGS) -no-flag’. If all of these flags had been forcefully appended to CFLAGS, there would be no way to disable one flag. Yet another reason to leave user variables to users.

Finally, we have avoided naming the variable of the example LIBFOO_LDFLAGS (with an underscore) because that would cause Automake to think that this is actually a per-target variable (like mumble_LDFLAGS) for some non-declared LIBFOO target.

Other Variables

There are other variables in Automake that follow similar principles to allow user options. For instance, Texinfo rules (see Texinfo) use MAKEINFOFLAGS and AM_MAKEINFOFLAGS. Similarly, DejaGnu tests (see DejaGnu Tests) use RUNTESTDEFAULTFLAGS and AM_RUNTESTDEFAULTFLAGS. The tags and ctags rules (see Interfacing to etags) use ETAGSFLAGS, AM_ETAGSFLAGS, CTAGSFLAGS, and AM_CTAGSFLAGS. Java rules (see Java bytecode compilation (deprecated)) use JAVACFLAGS and AM_JAVACFLAGS. None of these rules support per-target flags (yet).

To some extent, even AM_MAKEFLAGS (see Recursing subdirectories) obeys this naming scheme. The slight difference is that MAKEFLAGS is passed to sub-makes implicitly by make itself.

ARFLAGS (see Building a library) is usually defined by Automake and has neither AM_ nor per-target cousin.

Finally you should not think that the existence of a per-target variable implies the existence of an AM_ variable or of a user variable. For instance, the mumble_LDADD per-target variable overrides the makefile-wide LDADD variable (which is not a user variable), and mumble_LIBADD exists only as a per-target variable. See Program and Library Variables.


27.7 Why are object files sometimes renamed?

This happens when per-target compilation flags are used. Object files need to be renamed just in case they would clash with object files compiled from the same sources, but with different flags. Consider the following example.

bin_PROGRAMS = true false
true_SOURCES = generic.c
true_CPPFLAGS = -DEXIT_CODE=0
false_SOURCES = generic.c
false_CPPFLAGS = -DEXIT_CODE=1

Obviously the two programs are built from the same source, but it would be bad if they shared the same object, because generic.o cannot be built with both ‘-DEXIT_CODE=0and-DEXIT_CODE=1’. Therefore automake outputs rules to build two different objects: true-generic.o and false-generic.o.

automake doesn’t actually look whether source files are shared to decide if it must rename objects. It will just rename all objects of a target as soon as it sees per-target compilation flags used.

It’s OK to share object files when per-target compilation flags are not used. For instance, true and false will both use version.o in the following example.

AM_CPPFLAGS = -DVERSION=1.0
bin_PROGRAMS = true false
true_SOURCES = true.c version.c
false_SOURCES = false.c version.c

Note that the renaming of objects is also affected by the _SHORTNAME variable (see Program and Library Variables).


27.8 Per-Object Flags Emulation

One of my source files needs to be compiled with different flags.  How
do I do?

Automake supports per-program and per-library compilation flags (see Program and Library Variables and Flag Variables Ordering). With this you can define compilation flags that apply to all files compiled for a target. For instance, in

bin_PROGRAMS = foo
foo_SOURCES = foo.c foo.h bar.c bar.h main.c
foo_CFLAGS = -some -flags

foo-foo.o, foo-bar.o, and foo-main.o will all be compiled with ‘-some -flags’. (If you wonder about the names of these object files, see Why are object files sometimes renamed?.) Note that foo_CFLAGS gives the flags to use when compiling all the C sources of the program foo, it has nothing to do with foo.c or foo-foo.o specifically.

What if foo.c needs to be compiled into foo.o using some specific flags, that none of the other files requires? Obviously per-program flags are not directly applicable here. Something like per-object flags are expected, i.e., flags that would be used only when creating foo-foo.o. Automake does not support that, however this is easy to simulate using a library that contains only that object, and compiling this library with per-library flags.

bin_PROGRAMS = foo
foo_SOURCES = bar.c bar.h main.c
foo_CFLAGS = -some -flags
foo_LDADD = libfoo.a
noinst_LIBRARIES = libfoo.a
libfoo_a_SOURCES = foo.c foo.h
libfoo_a_CFLAGS = -some -other -flags

Here foo-bar.o and foo-main.o will all be compiled with ‘-some -flags’, while libfoo_a-foo.o will be compiled using ‘-some -other -flags’. Eventually, all three objects will be linked to form foo.

This trick can also be achieved using Libtool convenience libraries, for instance ‘noinst_LTLIBRARIES = libfoo.la’ (see Libtool Convenience Libraries).

Another tempting idea to implement per-object flags is to override the compile rules automake would output for these files. Automake will not define a rule for a target you have defined, so you could think about defining the ‘foo-foo.o: foo.c’ rule yourself. We recommend against this, because this is error prone. For instance, if you add such a rule to the first example, it will break the day you decide to remove foo_CFLAGS (because foo.c will then be compiled as foo.o instead of foo-foo.o, see Why are object files sometimes renamed?). Also in order to support dependency tracking, the two .o/.obj extensions, and all the other flags variables involved in a compilation, you will end up modifying a copy of the rule previously output by automake for this file. If a new release of Automake generates a different rule, your copy will need to be updated by hand.


27.9 Handling Tools that Produce Many Outputs

This section describes a make idiom that can be used when a tool produces multiple output files. It is not specific to Automake and can be used in ordinary Makefiles.

Suppose we have a program called foo that will read one file called data.foo and produce two files named data.c and data.h. We want to write a Makefile rule that captures this one-to-two dependency.

The naive rule is incorrect:

# This is incorrect.
data.c data.h: data.foo
        foo data.foo

What the above rule really says is that data.c and data.h each depend on data.foo, and can each be built by running ‘foo data.foo’. In other words it is equivalent to:

# We do not want this.
data.c: data.foo
        foo data.foo
data.h: data.foo
        foo data.foo

which means that foo can be run twice. Usually it will not be run twice, because make implementations are smart enough to check for the existence of the second file after the first one has been built; they will therefore detect that it already exists. However there are a few situations where it can run twice anyway:

  • The most worrying case is when running a parallel make. If data.c and data.h are built in parallel, two ‘foo data.foo’ commands will run concurrently. This is harmful.
  • Another case is when the dependency (here data.foo) is (or depends upon) a phony target.

A solution that works with parallel make but not with phony dependencies is the following:

data.c data.h: data.foo
        foo data.foo
data.h: data.c

The above rules are equivalent to

data.c: data.foo
        foo data.foo
data.h: data.foo data.c
        foo data.foo

therefore a parallel make will have to serialize the builds of data.c and data.h, and will detect that the second is no longer needed once the first is over.

Using this pattern is probably enough for most cases. However it does not scale easily to more output files (in this scheme all output files must be totally ordered by the dependency relation), so we will explore a more complicated solution.

Another idea is to write the following:

# There is still a problem with this one.
data.c: data.foo
        foo data.foo
data.h: data.c

The idea is that ‘foo data.foo’ is run only when data.c needs to be updated, but we further state that data.h depends upon data.c. That way, if data.h is required and data.foo is out of date, the dependency on data.c will trigger the build.

This is almost perfect, but suppose we have built data.h and data.c, and then we erase data.h. Then, running ‘make data.h’ will not rebuild data.h. The above rules just state that data.c must be up-to-date with respect to data.foo, and this is already the case.

What we need is a rule that forces a rebuild when data.h is missing. Here it is:

data.c: data.foo
        foo data.foo
data.h: data.c
## Recover from the removal of $@
        @if test -f $@; then :; else \
          rm -f data.c; \
          $(MAKE) $(AM_MAKEFLAGS) data.c; \
        fi

The above scheme can be extended to handle more outputs and more inputs. One of the outputs is selected to serve as a witness to the successful completion of the command, it depends upon all inputs, and all other outputs depend upon it. For instance, if foo should additionally read data.bar and also produce data.w and data.x, we would write:

data.c: data.foo data.bar
        foo data.foo data.bar
data.h data.w data.x: data.c
## Recover from the removal of $@
        @if test -f $@; then :; else \
          rm -f data.c; \
          $(MAKE) $(AM_MAKEFLAGS) data.c; \
        fi

However there are now three minor problems in this setup. One is related to the timestamp ordering of data.h, data.w, data.x, and data.c. Another one is a race condition if a parallel make attempts to run multiple instances of the recover block at once. Finally, the recursive rule breaks ‘make -n’ when run with GNU make (as well as some other make implementations), as it may remove data.h even when it should not (see How the MAKE Variable Works in The GNU Make Manual).

Let us deal with the first problem. foo outputs four files, but we do not know in which order these files are created. Suppose that data.h is created before data.c. Then we have a weird situation. The next time make is run, data.h will appear older than data.c, the second rule will be triggered, a shell will be started to execute the ‘if…fi’ command, but actually it will just execute the then branch, that is: nothing. In other words, because the witness we selected is not the first file created by foo, make will start a shell to do nothing each time it is run.

A simple riposte is to fix the timestamps when this happens.

data.c: data.foo data.bar
        foo data.foo data.bar
data.h data.w data.x: data.c
        @if test -f $@; then \
          touch $@; \
        else \
## Recover from the removal of $@
          rm -f data.c; \
          $(MAKE) $(AM_MAKEFLAGS) data.c; \
        fi

Another solution is to use a different and dedicated file as witness, rather than using any of foo’s outputs.

data.stamp: data.foo data.bar
        @rm -f data.tmp
        @touch data.tmp
        foo data.foo data.bar
        @mv -f data.tmp $@
data.c data.h data.w data.x: data.stamp
## Recover from the removal of $@
        @if test -f $@; then :; else \
          rm -f data.stamp; \
          $(MAKE) $(AM_MAKEFLAGS) data.stamp; \
        fi

data.tmp is created before foo is run, so it has a timestamp older than output files output by foo. It is then renamed to data.stamp after foo has run, because we do not want to update data.stamp if foo fails.

This solution still suffers from the second problem: the race condition in the recover rule. If, after a successful build, a user erases data.c and data.h, and runs ‘make -j’, then make may start both recover rules in parallel. If the two instances of the rule execute ‘$(MAKE) $(AM_MAKEFLAGS) data.stamp’ concurrently the build is likely to fail (for instance, the two rules will create data.tmp, but only one can rename it).

Admittedly, such a weird situation does not arise during ordinary builds. It occurs only when the build tree is mutilated. Here data.c and data.h have been explicitly removed without also removing data.stamp and the other output files. make clean; make will always recover from these situations even with parallel makes, so you may decide that the recover rule is solely to help non-parallel make users and leave things as-is. Fixing this requires some locking mechanism to ensure only one instance of the recover rule rebuilds data.stamp. One could imagine something along the following lines.

data.c data.h data.w data.x: data.stamp
## Recover from the removal of $@
        @if test -f $@; then :; else \
          trap 'rm -rf data.lock data.stamp' 1 2 13 15; \
## mkdir is a portable test-and-set
          if mkdir data.lock 2>/dev/null; then \
## This code is being executed by the first process.
            rm -f data.stamp; \
            $(MAKE) $(AM_MAKEFLAGS) data.stamp; \
            result=$$?; rm -rf data.lock; exit $$result; \
          else \
## This code is being executed by the follower processes.
## Wait until the first process is done.
            while test -d data.lock; do sleep 1; done; \
## Succeed if and only if the first process succeeded.
            test -f data.stamp; \
          fi; \
        fi

Using a dedicated witness, like data.stamp, is very handy when the list of output files is not known beforehand. As an illustration, consider the following rules to compile many *.el files into *.elc files in a single command. It does not matter how ELFILES is defined (as long as it is not empty: empty targets are not accepted by POSIX).

ELFILES = one.el two.el three.el …
ELCFILES = $(ELFILES:=c)

elc-stamp: $(ELFILES)
        @rm -f elc-temp
        @touch elc-temp
        $(elisp_comp) $(ELFILES)
        @mv -f elc-temp $@

$(ELCFILES): elc-stamp
        @if test -f $@; then :; else \
## Recover from the removal of $@
          trap 'rm -rf elc-lock elc-stamp' 1 2 13 15; \
          if mkdir elc-lock 2>/dev/null; then \
## This code is being executed by the first process.
            rm -f elc-stamp; \
            $(MAKE) $(AM_MAKEFLAGS) elc-stamp; \
            rmdir elc-lock; \
          else \
## This code is being executed by the follower processes.
## Wait until the first process is done.
            while test -d elc-lock; do sleep 1; done; \
## Succeed if and only if the first process succeeded.
            test -f elc-stamp; exit $$?; \
          fi; \
        fi

These solutions all still suffer from the third problem, namely that they break the promise that ‘make -n’ should not cause any actual changes to the tree. For those solutions that do not create lock files, it is possible to split the recover rules into two separate recipe commands, one of which does all work but the recursion, and the other invokes the recursive ‘$(MAKE)’. The solutions involving locking could act upon the contents of the ‘MAKEFLAGS’ variable, but parsing that portably is not easy (see The Make Macro MAKEFLAGS in The Autoconf Manual). Here is an example:

ELFILES = one.el two.el three.el …
ELCFILES = $(ELFILES:=c)

elc-stamp: $(ELFILES)
        @rm -f elc-temp
        @touch elc-temp
        $(elisp_comp) $(ELFILES)
        @mv -f elc-temp $@

$(ELCFILES): elc-stamp
## Recover from the removal of $@
        @dry=; for f in x $$MAKEFLAGS; do \
          case $$f in \
            *=*|--*);; \
            *n*) dry=:;; \
          esac; \
        done; \
        if test -f $@; then :; else \
          $$dry trap 'rm -rf elc-lock elc-stamp' 1 2 13 15; \
          if $$dry mkdir elc-lock 2>/dev/null; then \
## This code is being executed by the first process.
            $$dry rm -f elc-stamp; \
            $(MAKE) $(AM_MAKEFLAGS) elc-stamp; \
            $$dry rmdir elc-lock; \
          else \
## This code is being executed by the follower processes.
## Wait until the first process is done.
            while test -d elc-lock && test -z "$$dry"; do \
              sleep 1; \
            done; \
## Succeed if and only if the first process succeeded.
            $$dry test -f elc-stamp; exit $$?; \
          fi; \
        fi

For completeness it should be noted that GNU make is able to express rules with multiple output files using pattern rules (see Pattern Rule Examples in The GNU Make Manual). We do not discuss pattern rules here because they are not portable, but they can be convenient in packages that assume GNU make.


27.10 Installing to Hard-Coded Locations

My package needs to install some configuration file.  I tried to use
the following rule, but ‘make distcheck’ fails.  Why?

# Do not do this.
install-data-local:
        $(INSTALL_DATA) $(srcdir)/afile $(DESTDIR)/etc/afile
My package needs to populate the installation directory of another
package at install-time.  I can easily compute that installation
directory in configure, but if I install files therein,
‘make distcheck’ fails.  How else should I do?

These two setups share their symptoms: ‘make distcheck’ fails because they are installing files to hard-coded paths. In the later case the path is not really hard-coded in the package, but we can consider it to be hard-coded in the system (or in whichever tool that supplies the path). As long as the path does not use any of the standard directory variables (‘$(prefix)’, ‘$(bindir)’, ‘$(datadir)’, etc.), the effect will be the same: user-installations are impossible.

As a (non-root) user who wants to install a package, you usually have no right to install anything in /usr or /usr/local. So you do something like ‘./configure --prefix ~/usr’ to install a package in your own ~/usr tree.

If a package attempts to install something to some hard-coded path (e.g., /etc/afile), regardless of this --prefix setting, then the installation will fail. ‘make distcheck’ performs such a --prefix installation, hence it will fail too.

Now, there are some easy solutions.

The above install-data-local example for installing /etc/afile would be better replaced by

sysconf_DATA = afile

by default sysconfdir will be ‘$(prefix)/etc’, because this is what the GNU Standards require. When such a package is installed on an FHS compliant system, the installer will have to set ‘--sysconfdir=/etc’. As the maintainer of the package you should not be concerned by such site policies: use the appropriate standard directory variable to install your files so that the installer can easily redefine these variables to match their site conventions.

Installing files that should be used by another package is slightly more involved. Let’s take an example and assume you want to install a shared library that is a Python extension module. If you ask Python where to install the library, it will answer something like this:

% python -c 'from distutils import sysconfig;
             print sysconfig.get_python_lib(1,0)'
/usr/lib/python2.5/site-packages

If you indeed use this absolute path to install your shared library, non-root users will not be able to install the package, hence distcheck fails.

Let’s do better. The ‘sysconfig.get_python_lib()’ function actually accepts a third argument that will replace Python’s installation prefix.

% python -c 'from distutils import sysconfig;
             print sysconfig.get_python_lib(1,0,"${exec_prefix}")'
${exec_prefix}/lib/python2.5/site-packages

You can also use this new path. If you do

  • root users can install your package with the same --prefix as Python (you get the behavior of the previous attempt)
  • non-root users can install your package too, they will have the extension module in a place that is not searched by Python but they can work around this using environment variables (and if you installed scripts that use this shared library, it’s easy to tell Python were to look in the beginning of your script, so the script works in both cases).

The AM_PATH_PYTHON macro uses similar commands to define ‘$(pythondir)’ and ‘$(pyexecdir)’ (see Python).

Of course not all tools are as advanced as Python regarding that substitution of prefix. So another strategy is to figure the part of the installation directory that must be preserved. For instance, here is how AM_PATH_LISPDIR (see Emacs Lisp) computes ‘$(lispdir)’:

$EMACS -batch -Q -eval '(while load-path
  (princ (concat (car load-path) "\n"))
  (setq load-path (cdr load-path)))' >conftest.out
lispdir=`sed -n
  -e 's,/$,,'
  -e '/.*\/lib\/x*emacs\/site-lisp$/{
        s,.*/lib/\(x*emacs/site-lisp\)$,${libdir}/\1,;p;q;
      }'
  -e '/.*\/share\/x*emacs\/site-lisp$/{
        s,.*/share/\(x*emacs/site-lisp\),${datarootdir}/\1,;p;q;
      }'
  conftest.out`

I.e., it just picks the first directory that looks like */lib/*emacs/site-lisp or */share/*emacs/site-lisp in the search path of emacs, and then substitutes ‘${libdir}’ or ‘${datadir}’ appropriately.

The emacs case looks complicated because it processes a list and expects two possible layouts, otherwise it’s easy, and the benefits for non-root users are really worth the extra sed invocation.


27.11 Debugging Make Rules

The rules and dependency trees generated by automake can get rather complex, and leave the developer head-scratching when things don’t work as expected. Besides the debug options provided by the make command (see Options Summary in The GNU Make Manual), here’s a couple of further hints for debugging makefiles generated by automake effectively:

  • If less verbose output has been enabled in the package with the use of silent rules (see How Automake can help in silencing make), you can use make V=1 to see the commands being executed.
  • make -n can help show what would be done without actually doing it. Note however, that this will still execute commands prefixed with ‘+’, and, when using GNU make, commands that contain the strings ‘$(MAKE)’ or ‘${MAKE}’ (see Instead of Execution in The GNU Make Manual). Typically, this is helpful to show what recursive rules would do, but it means that, in your own rules, you should not mix such recursion with actions that change any files.8 Furthermore, note that GNU make will update prerequisites for the Makefile file itself even with -n (see Remaking Makefiles in The GNU Make Manual).
  • make SHELL="/bin/bash -vx" can help debug complex rules. See The Make Macro SHELL in The Autoconf Manual, for some portability quirks associated with this construct.
  • echo 'print: ; @echo "$(VAR)"' | make -f Makefile -f - print can be handy to examine the expanded value of variables. You may need to use a target other than ‘print’ if that is already used or a file with that name exists.
  • http://bashdb.sourceforge.net/remake/ provides a modified GNU make command called remake that copes with complex GNU make-specific Makefiles and allows to trace execution, examine variables, and call rules interactively, much like a debugger.

27.12 Reporting Bugs

Most nontrivial software has bugs. Automake is no exception. Although we cannot promise we can or will fix a bug, and we might not even agree that it is a bug, we want to hear about problems you encounter. Often we agree they are bugs and want to fix them.

To make it possible for us to fix a bug, please report it. In order to do so effectively, it helps to know when and how to do it.

Before reporting a bug, it is a good idea to see if it is already known. You can look at the GNU Bug Tracker and the bug-automake mailing list archives for previous bug reports. We previously used a Gnats database for bug tracking, so some bugs might have been reported there already. Please do not use it for new bug reports, however.

If the bug is not already known, it should be reported. It is very important to report bugs in a way that is useful and efficient. For this, please familiarize yourself with How to Report Bugs Effectively and How to Ask Questions the Smart Way. This helps you and developers to save time which can then be spent on fixing more bugs and implementing more features.

For a bug report, a feature request or other suggestions, please send email to bug-automake@gnu.org. This will then open a new bug in the bug tracker. Be sure to include the versions of Autoconf and Automake that you use. Ideally, post a minimal Makefile.am and configure.ac that reproduces the problem you encounter. If you have encountered test suite failures, please attach the test-suite.log file.


Appendix A Copying This Manual


A.1 GNU Free Documentation License

Version 1.3, 3 November 2008
Copyright © 2000-2017 Free Software Foundation, Inc.
http://fsf.org/

Everyone is permitted to copy and distribute verbatim copies
of this license document, but changing it is not allowed.
  1. PREAMBLE

    The purpose of this License is to make a manual, textbook, or other functional and useful document free in the sense of freedom: to assure everyone the effective freedom to copy and redistribute it, with or without modifying it, either commercially or noncommercially. Secondarily, this License preserves for the author and publisher a way to get credit for their work, while not being considered responsible for modifications made by others.

    This License is a kind of “copyleft”, which means that derivative works of the document must themselves be free in the same sense. It complements the GNU General Public License, which is a copyleft license designed for free software.

    We have designed this License in order to use it for manuals for free software, because free software needs free documentation: a free program should come with manuals providing the same freedoms that the software does. But this License is not limited to software manuals; it can be used for any textual work, regardless of subject matter or whether it is published as a printed book. We recommend this License principally for works whose purpose is instruction or reference.

  2. APPLICABILITY AND DEFINITIONS

    This License applies to any manual or other work, in any medium, that contains a notice placed by the copyright holder saying it can be distributed under the terms of this License. Such a notice grants a world-wide, royalty-free license, unlimited in duration, to use that work under the conditions stated herein. The “Document”, below, refers to any such manual or work. Any member of the public is a licensee, and is addressed as “you”. You accept the license if you copy, modify or distribute the work in a way requiring permission under copyright law.

    A “Modified Version” of the Document means any work containing the Document or a portion of it, either copied verbatim, or with modifications and/or translated into another language.

    A “Secondary Section” is a named appendix or a front-matter section of the Document that deals exclusively with the relationship of the publishers or authors of the Document to the Document’s overall subject (or to related matters) and contains nothing that could fall directly within that overall subject. (Thus, if the Document is in part a textbook of mathematics, a Secondary Section may not explain any mathematics.) The relationship could be a matter of historical connection with the subject or with related matters, or of legal, commercial, philosophical, ethical or political position regarding them.

    The “Invariant Sections” are certain Secondary Sections whose titles are designated, as being those of Invariant Sections, in the notice that says that the Document is released under this License. If a section does not fit the above definition of Secondary then it is not allowed to be designated as Invariant. The Document may contain zero Invariant Sections. If the Document does not identify any Invariant Sections then there are none.

    The “Cover Texts” are certain short passages of text that are listed, as Front-Cover Texts or Back-Cover Texts, in the notice that says that the Document is released under this License. A Front-Cover Text may be at most 5 words, and a Back-Cover Text may be at most 25 words.

    A “Transparent” copy of the Document means a machine-readable copy, represented in a format whose specification is available to the general public, that is suitable for revising the document straightforwardly with generic text editors or (for images composed of pixels) generic paint programs or (for drawings) some widely available drawing editor, and that is suitable for input to text formatters or for automatic translation to a variety of formats suitable for input to text formatters. A copy made in an otherwise Transparent file format whose markup, or absence of markup, has been arranged to thwart or discourage subsequent modification by readers is not Transparent. An image format is not Transparent if used for any substantial amount of text. A copy that is not “Transparent” is called “Opaque”.

    Examples of suitable formats for Transparent copies include plain ASCII without markup, Texinfo input format, LaTeX input format, SGML or XML using a publicly available DTD, and standard-conforming simple HTML, PostScript or PDF designed for human modification. Examples of transparent image formats include PNG, XCF and JPG. Opaque formats include proprietary formats that can be read and edited only by proprietary word processors, SGML or XML for which the DTD and/or processing tools are not generally available, and the machine-generated HTML, PostScript or PDF produced by some word processors for output purposes only.

    The “Title Page” means, for a printed book, the title page itself, plus such following pages as are needed to hold, legibly, the material this License requires to appear in the title page. For works in formats which do not have any title page as such, “Title Page” means the text near the most prominent appearance of the work’s title, preceding the beginning of the body of the text.

    The “publisher” means any person or entity that distributes copies of the Document to the public.

    A section “Entitled XYZ” means a named subunit of the Document whose title either is precisely XYZ or contains XYZ in parentheses following text that translates XYZ in another language. (Here XYZ stands for a specific section name mentioned below, such as “Acknowledgements”, “Dedications”, “Endorsements”, or “History”.) To “Preserve the Title” of such a section when you modify the Document means that it remains a section “Entitled XYZ” according to this definition.

    The Document may include Warranty Disclaimers next to the notice which states that this License applies to the Document. These Warranty Disclaimers are considered to be included by reference in this License, but only as regards disclaiming warranties: any other implication that these Warranty Disclaimers may have is void and has no effect on the meaning of this License.

  3. VERBATIM COPYING

    You may copy and distribute the Document in any medium, either commercially or noncommercially, provided that this License, the copyright notices, and the license notice saying this License applies to the Document are reproduced in all copies, and that you add no other conditions whatsoever to those of this License. You may not use technical measures to obstruct or control the reading or further copying of the copies you make or distribute. However, you may accept compensation in exchange for copies. If you distribute a large enough number of copies you must also follow the conditions in section 3.

    You may also lend copies, under the same conditions stated above, and you may publicly display copies.

  4. COPYING IN QUANTITY

    If you publish printed copies (or copies in media that commonly have printed covers) of the Document, numbering more than 100, and the Document’s license notice requires Cover Texts, you must enclose the copies in covers that carry, clearly and legibly, all of these Cover Texts: Front-Cover Texts on the front cover, and Back-Cover Texts on the back cover. Both covers must also clearly and legibly identify you as the publisher of these copies. The front cover must present the full title with all words of the title equally prominent and visible. You may add other material on the covers in addition. Copying with changes limited to the covers, as long as they preserve the title of the Document and satisfy these conditions, can be treated as verbatim copying in other respects.

    If the required texts for either cover are too voluminous to fit legibly, you should put the first ones listed (as many as fit reasonably) on the actual cover, and continue the rest onto adjacent pages.

    If you publish or distribute Opaque copies of the Document numbering more than 100, you must either include a machine-readable Transparent copy along with each Opaque copy, or state in or with each Opaque copy a computer-network location from which the general network-using public has access to download using public-standard network protocols a complete Transparent copy of the Document, free of added material. If you use the latter option, you must take reasonably prudent steps, when you begin distribution of Opaque copies in quantity, to ensure that this Transparent copy will remain thus accessible at the stated location until at least one year after the last time you distribute an Opaque copy (directly or through your agents or retailers) of that edition to the public.

    It is requested, but not required, that you contact the authors of the Document well before redistributing any large number of copies, to give them a chance to provide you with an updated version of the Document.

  5. MODIFICATIONS

    You may copy and distribute a Modified Version of the Document under the conditions of sections 2 and 3 above, provided that you release the Modified Version under precisely this License, with the Modified Version filling the role of the Document, thus licensing distribution and modification of the Modified Version to whoever possesses a copy of it. In addition, you must do these things in the Modified Version:

    1. Use in the Title Page (and on the covers, if any) a title distinct from that of the Document, and from those of previous versions (which should, if there were any, be listed in the History section of the Document). You may use the same title as a previous version if the original publisher of that version gives permission.
    2. List on the Title Page, as authors, one or more persons or entities responsible for authorship of the modifications in the Modified Version, together with at least five of the principal authors of the Document (all of its principal authors, if it has fewer than five), unless they release you from this requirement.
    3. State on the Title page the name of the publisher of the Modified Version, as the publisher.
    4. Preserve all the copyright notices of the Document.
    5. Add an appropriate copyright notice for your modifications adjacent to the other copyright notices.
    6. Include, immediately after the copyright notices, a license notice giving the public permission to use the Modified Version under the terms of this License, in the form shown in the Addendum below.
    7. Preserve in that license notice the full lists of Invariant Sections and required Cover Texts given in the Document’s license notice.
    8. Include an unaltered copy of this License.
    9. Preserve the section Entitled “History”, Preserve its Title, and add to it an item stating at least the title, year, new authors, and publisher of the Modified Version as given on the Title Page. If there is no section Entitled “History” in the Document, create one stating the title, year, authors, and publisher of the Document as given on its Title Page, then add an item describing the Modified Version as stated in the previous sentence.
    10. Preserve the network location, if any, given in the Document for public access to a Transparent copy of the Document, and likewise the network locations given in the Document for previous versions it was based on. These may be placed in the “History” section. You may omit a network location for a work that was published at least four years before the Document itself, or if the original publisher of the version it refers to gives permission.
    11. For any section Entitled “Acknowledgements” or “Dedications”, Preserve the Title of the section, and preserve in the section all the substance and tone of each of the contributor acknowledgements and/or dedications given therein.
    12. Preserve all the Invariant Sections of the Document, unaltered in their text and in their titles. Section numbers or the equivalent are not considered part of the section titles.
    13. Delete any section Entitled “Endorsements”. Such a section may not be included in the Modified Version.
    14. Do not retitle any existing section to be Entitled “Endorsements” or to conflict in title with any Invariant Section.
    15. Preserve any Warranty Disclaimers.

    If the Modified Version includes new front-matter sections or appendices that qualify as Secondary Sections and contain no material copied from the Document, you may at your option designate some or all of these sections as invariant. To do this, add their titles to the list of Invariant Sections in the Modified Version’s license notice. These titles must be distinct from any other section titles.

    You may add a section Entitled “Endorsements”, provided it contains nothing but endorsements of your Modified Version by various parties—for example, statements of peer review or that the text has been approved by an organization as the authoritative definition of a standard.

    You may add a passage of up to five words as a Front-Cover Text, and a passage of up to 25 words as a Back-Cover Text, to the end of the list of Cover Texts in the Modified Version. Only one passage of Front-Cover Text and one of Back-Cover Text may be added by (or through arrangements made by) any one entity. If the Document already includes a cover text for the same cover, previously added by you or by arrangement made by the same entity you are acting on behalf of, you may not add another; but you may replace the old one, on explicit permission from the previous publisher that added the old one.

    The author(s) and publisher(s) of the Document do not by this License give permission to use their names for publicity for or to assert or imply endorsement of any Modified Version.

  6. COMBINING DOCUMENTS

    You may combine the Document with other documents released under this License, under the terms defined in section 4 above for modified versions, provided that you include in the combination all of the Invariant Sections of all of the original documents, unmodified, and list them all as Invariant Sections of your combined work in its license notice, and that you preserve all their Warranty Disclaimers.

    The combined work need only contain one copy of this License, and multiple identical Invariant Sections may be replaced with a single copy. If there are multiple Invariant Sections with the same name but different contents, make the title of each such section unique by adding at the end of it, in parentheses, the name of the original author or publisher of that section if known, or else a unique number. Make the same adjustment to the section titles in the list of Invariant Sections in the license notice of the combined work.

    In the combination, you must combine any sections Entitled “History” in the various original documents, forming one section Entitled “History”; likewise combine any sections Entitled “Acknowledgements”, and any sections Entitled “Dedications”. You must delete all sections Entitled “Endorsements.”

  7. COLLECTIONS OF DOCUMENTS

    You may make a collection consisting of the Document and other documents released under this License, and replace the individual copies of this License in the various documents with a single copy that is included in the collection, provided that you follow the rules of this License for verbatim copying of each of the documents in all other respects.

    You may extract a single document from such a collection, and distribute it individually under this License, provided you insert a copy of this License into the extracted document, and follow this License in all other respects regarding verbatim copying of that document.

  8. AGGREGATION WITH INDEPENDENT WORKS

    A compilation of the Document or its derivatives with other separate and independent documents or works, in or on a volume of a storage or distribution medium, is called an “aggregate” if the copyright resulting from the compilation is not used to limit the legal rights of the compilation’s users beyond what the individual works permit. When the Document is included in an aggregate, this License does not apply to the other works in the aggregate which are not themselves derivative works of the Document.

    If the Cover Text requirement of section 3 is applicable to these copies of the Document, then if the Document is less than one half of the entire aggregate, the Document’s Cover Texts may be placed on covers that bracket the Document within the aggregate, or the electronic equivalent of covers if the Document is in electronic form. Otherwise they must appear on printed covers that bracket the whole aggregate.

  9. TRANSLATION

    Translation is considered a kind of modification, so you may distribute translations of the Document under the terms of section 4. Replacing Invariant Sections with translations requires special permission from their copyright holders, but you may include translations of some or all Invariant Sections in addition to the original versions of these Invariant Sections. You may include a translation of this License, and all the license notices in the Document, and any Warranty Disclaimers, provided that you also include the original English version of this License and the original versions of those notices and disclaimers. In case of a disagreement between the translation and the original version of this License or a notice or disclaimer, the original version will prevail.

    If a section in the Document is Entitled “Acknowledgements”, “Dedications”, or “History”, the requirement (section 4) to Preserve its Title (section 1) will typically require changing the actual title.

  10. TERMINATION

    You may not copy, modify, sublicense, or distribute the Document except as expressly provided under this License. Any attempt otherwise to copy, modify, sublicense, or distribute it is void, and will automatically terminate your rights under this License.

    However, if you cease all violation of this License, then your license from a particular copyright holder is reinstated (a) provisionally, unless and until the copyright holder explicitly and finally terminates your license, and (b) permanently, if the copyright holder fails to notify you of the violation by some reasonable means prior to 60 days after the cessation.

    Moreover, your license from a particular copyright holder is reinstated permanently if the copyright holder notifies you of the violation by some reasonable means, this is the first time you have received notice of violation of this License (for any work) from that copyright holder, and you cure the violation prior to 30 days after your receipt of the notice.

    Termination of your rights under this section does not terminate the licenses of parties who have received copies or rights from you under this License. If your rights have been terminated and not permanently reinstated, receipt of a copy of some or all of the same material does not give you any rights to use it.

  11. FUTURE REVISIONS OF THIS LICENSE

    The Free Software Foundation may publish new, revised versions of the GNU Free Documentation License from time to time. Such new versions will be similar in spirit to the present version, but may differ in detail to address new problems or concerns. See http://www.gnu.org/copyleft/.

    Each version of the License is given a distinguishing version number. If the Document specifies that a particular numbered version of this License “or any later version” applies to it, you have the option of following the terms and conditions either of that specified version or of any later version that has been published (not as a draft) by the Free Software Foundation. If the Document does not specify a version number of this License, you may choose any version ever published (not as a draft) by the Free Software Foundation. If the Document specifies that a proxy can decide which future versions of this License can be used, that proxy’s public statement of acceptance of a version permanently authorizes you to choose that version for the Document.

  12. RELICENSING

    “Massive Multiauthor Collaboration Site” (or “MMC Site”) means any World Wide Web server that publishes copyrightable works and also provides prominent facilities for anybody to edit those works. A public wiki that anybody can edit is an example of such a server. A “Massive Multiauthor Collaboration” (or “MMC”) contained in the site means any set of copyrightable works thus published on the MMC site.

    “CC-BY-SA” means the Creative Commons Attribution-Share Alike 3.0 license published by Creative Commons Corporation, a not-for-profit corporation with a principal place of business in San Francisco, California, as well as future copyleft versions of that license published by that same organization.

    “Incorporate” means to publish or republish a Document, in whole or in part, as part of another Document.

    An MMC is “eligible for relicensing” if it is licensed under this License, and if all works that were first published under this License somewhere other than this MMC, and subsequently incorporated in whole or in part into the MMC, (1) had no cover texts or invariant sections, and (2) were thus incorporated prior to November 1, 2008.

    The operator of an MMC Site may republish an MMC contained in the site under CC-BY-SA on the same site at any time before August 1, 2009, provided the MMC is eligible for relicensing.

ADDENDUM: How to use this License for your documents

To use this License in a document you have written, include a copy of the License in the document and put the following copyright and license notices just after the title page:

  Copyright (C)  year  your name.
  Permission is granted to copy, distribute and/or modify this document
  under the terms of the GNU Free Documentation License, Version 1.3
  or any later version published by the Free Software Foundation;
  with no Invariant Sections, no Front-Cover Texts, and no Back-Cover
  Texts.  A copy of the license is included in the section entitled ``GNU
  Free Documentation License''.

If you have Invariant Sections, Front-Cover Texts and Back-Cover Texts, replace the “with…Texts.” line with this:

    with the Invariant Sections being list their titles, with
    the Front-Cover Texts being list, and with the Back-Cover Texts
    being list.

If you have Invariant Sections without Cover Texts, or some other combination of the three, merge those two alternatives to suit the situation.

If your document contains nontrivial examples of program code, we recommend releasing these examples in parallel under your choice of free software license, such as the GNU General Public License, to permit their use in free software.


Appendix B Indices


B.1 Macro Index

Jump to:   _  
A   M  
Index Entry  Section

_
_AM_DEPENDENCIES: Private Macros

A
AC_CANONICAL_BUILD: Optional
AC_CANONICAL_HOST: Optional
AC_CANONICAL_TARGET: Optional
AC_CONFIG_AUX_DIR: Optional
AC_CONFIG_AUX_DIR: Subpackages
AC_CONFIG_FILES: Requirements
AC_CONFIG_HEADERS: Optional
AC_CONFIG_LIBOBJ_DIR: Optional
AC_CONFIG_LIBOBJ_DIR: LIBOBJS
AC_CONFIG_LINKS: Optional
AC_CONFIG_SUBDIRS: Subpackages
AC_DEFUN: Extending aclocal
AC_F77_LIBRARY_LDFLAGS: Optional
AC_FC_SRCEXT: Optional
AC_INIT: Public Macros
AC_LIBOBJ: Optional
AC_LIBOBJ: LTLIBOBJS
AC_LIBOBJ: LIBOBJS
AC_LIBSOURCE: Optional
AC_LIBSOURCE: LIBOBJS
AC_LIBSOURCES: Optional
AC_OUTPUT: Requirements
AC_PREREQ: Extending aclocal
AC_PROG_CXX: Optional
AC_PROG_F77: Optional
AC_PROG_FC: Optional
AC_PROG_LEX: Public Macros
AC_PROG_LEX: Optional
AC_PROG_LIBTOOL: Optional
AC_PROG_OBJC: Optional
AC_PROG_OBJCXX: Optional
AC_PROG_RANLIB: Optional
AC_PROG_YACC: Optional
AC_REQUIRE_AUX_FILE: Optional
AC_SUBST: Optional
AM_CONDITIONAL: Optional
AM_CONDITIONAL: Usage of Conditionals
AM_CONDITIONAL: Usage of Conditionals
AM_COND_IF: Optional
AM_COND_IF: Usage of Conditionals
AM_COND_IF: Usage of Conditionals
AM_DEP_TRACK: Private Macros
AM_GNU_GETTEXT: Optional
AM_GNU_GETTEXT_INTL_SUBDIR: Optional
AM_INIT_AUTOMAKE: Requirements
AM_INIT_AUTOMAKE: Public Macros
AM_MAINTAINER_MODE: Rebuilding
AM_MAINTAINER_MODE: maintainer-mode
AM_MAINTAINER_MODE([default-mode]): Optional
AM_MAKE_INCLUDE: Private Macros
AM_MISSING_PROG: Public Macros
AM_OUTPUT_DEPENDENCY_COMMANDS: Private Macros
AM_PATH_LISPDIR: Public Macros
AM_PATH_PYTHON: Python
AM_PROG_AR: Public Macros
AM_PROG_AS: Public Macros
AM_PROG_CC_C_O: Public Macros
AM_PROG_GCJ: Public Macros
AM_PROG_INSTALL_STRIP: Private Macros
AM_PROG_LEX: Public Macros
AM_PROG_MKDIR_P: Obsolete Macros
AM_PROG_UPC: Public Macros
AM_PROG_VALAC: Vala Support
AM_SANITY_CHECK: Private Macros
AM_SET_DEPDIR: Private Macros
AM_SILENT_RULES: Public Macros
AM_SUBST_NOTMAKE(var): Optional
AM_WITH_DMALLOC: Public Macros

M
m4_include: Basics of Distribution
m4_include: Optional

Jump to:   _  
A   M  

Next: , Previous: , Up: Indices   [Contents][Index]

B.2 Variable Index

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A   B   C   D   E   F   G   H   I   J   L   M   N   O   P   R   S   T   U   V   W   X   Y  
Index Entry  Section

_
_DATA: Data
_HEADERS: Headers
_LIBRARIES: A Library
_LISP: Emacs Lisp
_LOG_COMPILE: Parallel Test Harness
_LOG_COMPILER: Parallel Test Harness
_LOG_DRIVER: Declaring Custom Test Drivers
_LOG_DRIVER_FLAGS: Declaring Custom Test Drivers
_LOG_FLAGS: Parallel Test Harness
_LTLIBRARIES: Libtool Libraries
_MANS: Man Pages
_PROGRAMS: Uniform
_PROGRAMS: Program Sources
_PYTHON: Python
_SCRIPTS: Scripts
_SOURCES: Program Sources
_SOURCES: Program Sources
_SOURCES: Default _SOURCES
_TEXINFOS: Texinfo
_TEXINFOS: Texinfo

A
ALLOCA: LTLIBOBJS
ALLOCA: LIBOBJS
AM_CCASFLAGS: Assembly Support
AM_CFLAGS: Program Variables
AM_COLOR_TESTS: Scripts-based Testsuites
AM_CPPFLAGS: Program Variables
AM_CPPFLAGS: Assembly Support
AM_CXXFLAGS: C++ Support
AM_DEFAULT_SOURCE_EXT: Default _SOURCES
AM_DEFAULT_V: Automake Silent Rules
AM_DEFAULT_VERBOSITY: Automake Silent Rules
AM_DISTCHECK_CONFIGURE_FLAGS: Checking the Distribution
AM_ETAGSFLAGS: Tags
AM_ext_LOG_DRIVER_FLAGS: Declaring Custom Test Drivers
AM_ext_LOG_FLAGS: Parallel Test Harness
AM_FCFLAGS: Fortran 9x Support
AM_FFLAGS: Fortran 77 Support
AM_GCJFLAGS: Java Support with gcj
AM_INSTALLCHECK_STD_OPTIONS_EXEMPT: List of Automake options
AM_JAVACFLAGS: Java
AM_LDFLAGS: Linking
AM_LDFLAGS: Program Variables
AM_LFLAGS: Yacc and Lex
AM_LIBTOOLFLAGS: Libtool Flags
AM_LOG_DRIVER_FLAGS: Declaring Custom Test Drivers
AM_LOG_FLAGS: Parallel Test Harness
AM_MAKEFLAGS: Subdirectories
AM_MAKEINFOFLAGS: Texinfo
AM_MAKEINFOHTMLFLAGS: Texinfo
AM_OBJCFLAGS: Objective C Support
AM_OBJCXXFLAGS: Objective C++ Support
AM_RFLAGS: Fortran 77 Support
AM_RUNTESTFLAGS: DejaGnu Tests
AM_TESTS_ENVIRONMENT: Scripts-based Testsuites
AM_TESTS_FD_REDIRECT: Scripts-based Testsuites
AM_UPCFLAGS: Unified Parallel C Support
AM_UPDATE_INFO_DIR: Texinfo
AM_V: Automake Silent Rules
AM_VALAFLAGS: Vala Support
AM_V_at: Automake Silent Rules
AM_V_GEN: Automake Silent Rules
AM_YFLAGS: Yacc and Lex
AR: Public Macros
AUTOCONF: automake Invocation
AUTOM4TE: aclocal Invocation
AUTOMAKE_JOBS: automake Invocation
AUTOMAKE_OPTIONS: Public Macros
AUTOMAKE_OPTIONS: Dependencies
AUTOMAKE_OPTIONS: List of Automake options

B
bin_PROGRAMS: Program Sources
bin_SCRIPTS: Scripts
build_triplet: Optional
BUILT_SOURCES: Sources
BZIP2: The Types of Distributions

C
CC: Program Variables
CCAS: Public Macros
CCAS: Assembly Support
CCASFLAGS: Public Macros
CCASFLAGS: Assembly Support
CFLAGS: Program Variables
check_: Uniform
check_LTLIBRARIES: Libtool Convenience Libraries
check_PROGRAMS: Program Sources
check_PROGRAMS: Default _SOURCES
check_SCRIPTS: Scripts
CLASSPATH_ENV: Java
CLEANFILES: Clean
COMPILE: Program Variables
CONFIGURE_DEPENDENCIES: Rebuilding
CONFIG_STATUS_DEPENDENCIES: Rebuilding
CPPFLAGS: Program Variables
CPPFLAGS: Assembly Support
CXX: C++ Support
CXXCOMPILE: C++ Support
CXXFLAGS: C++ Support
CXXLINK: C++ Support
CXXLINK: How the Linker is Chosen

D
DATA: Uniform
DATA: Data
data_DATA: Data
DEFS: Program Variables
DEJATOOL: DejaGnu Tests
DESTDIR: DESTDIR
DESTDIR: Staged Installs
DISABLE_HARD_ERRORS: Scripts-based Testsuites
DISTCHECK_CONFIGURE_FLAGS: Checking the Distribution
distcleancheck_listfiles: Checking the Distribution
distcleancheck_listfiles: Errors with distclean
DISTCLEANFILES: Clean
DISTCLEANFILES: Checking the Distribution
distdir: The dist Hook
distdir: Third-Party Makefiles
distuninstallcheck_listfiles: Checking the Distribution
dist_: Alternative
dist_: Fine-grained Distribution Control
dist_lisp_LISP: Emacs Lisp
dist_noinst_LISP: Emacs Lisp
DIST_SUBDIRS: Subdirectories with AM_CONDITIONAL
DIST_SUBDIRS: Basics of Distribution
DVIPS: Texinfo

E
EMACS: Public Macros
ETAGSFLAGS: Tags
ETAGS_ARGS: Tags
EXPECT: DejaGnu Tests
EXTRA_DIST: Basics of Distribution
EXTRA_maude_DEPENDENCIES: Linking
EXTRA_maude_DEPENDENCIES: Program and Library Variables
EXTRA_maude_SOURCES: Program and Library Variables
EXTRA_PROGRAMS: Conditional Programs
ext_LOG_COMPILE: Parallel Test Harness
ext_LOG_COMPILER: Parallel Test Harness
ext_LOG_DRIVER: Declaring Custom Test Drivers
ext_LOG_DRIVER_FLAGS: Declaring Custom Test Drivers
ext_LOG_FLAGS: Parallel Test Harness

F
F77: Fortran 77 Support
F77COMPILE: Fortran 77 Support
F77LINK: How the Linker is Chosen
FC: Fortran 9x Support
FCCOMPILE: Fortran 9x Support
FCFLAGS: Fortran 9x Support
FCLINK: How the Linker is Chosen
FCLINK: Fortran 9x Support
FFLAGS: Fortran 77 Support
FLIBS: Mixing Fortran 77 With C and C++
FLINK: Fortran 77 Support

G
GCJ: Public Macros
GCJFLAGS: Public Macros
GCJFLAGS: Java Support with gcj
GCJLINK: How the Linker is Chosen
GTAGS_ARGS: Tags
GZIP_ENV: Basics of Distribution

H
HEADERS: Uniform
host_triplet: Optional

I
INCLUDES: Program Variables
include_HEADERS: Headers
info_TEXINFOS: Texinfo

J
JAVA: Uniform
JAVAC: Java
JAVACFLAGS: Java
JAVAROOT: Java

L
LDADD: Linking
LDFLAGS: Program Variables
LFLAGS: Yacc and Lex
libexec_PROGRAMS: Program Sources
libexec_SCRIPTS: Scripts
LIBOBJS: Optional
LIBOBJS: LTLIBOBJS
LIBOBJS: LIBOBJS
LIBRARIES: Uniform
LIBS: Program Variables
LIBTOOLFLAGS: Libtool Flags
lib_LIBRARIES: A Library
lib_LTLIBRARIES: Libtool Libraries
LINK: Program Variables
LINK: How the Linker is Chosen
LISP: Uniform
lispdir: Public Macros
lisp_LISP: Emacs Lisp
localstate_DATA: Data
LOG_COMPILE: Parallel Test Harness
LOG_COMPILER: Parallel Test Harness
LOG_DRIVER: Declaring Custom Test Drivers
LOG_DRIVER_FLAGS: Declaring Custom Test Drivers
LOG_FLAGS: Parallel Test Harness
LTALLOCA: LTLIBOBJS
LTALLOCA: LIBOBJS
LTLIBOBJS: LTLIBOBJS
LTLIBOBJS: LIBOBJS
LTLIBRARIES: Uniform

M
MAINTAINERCLEANFILES: Clean
MAKE: Subdirectories
MAKEINFO: Texinfo
MAKEINFOFLAGS: Texinfo
MAKEINFOHTML: Texinfo
MANS: Uniform
man_MANS: Man Pages
maude_AR: Program and Library Variables
maude_CCASFLAGS: Program and Library Variables
maude_CFLAGS: Program and Library Variables
maude_CPPFLAGS: Program and Library Variables
maude_CXXFLAGS: Program and Library Variables
maude_DEPENDENCIES: Linking
maude_DEPENDENCIES: Program and Library Variables
maude_FFLAGS: Program and Library Variables
maude_GCJFLAGS: Program and Library Variables
maude_LDADD: Linking
maude_LDADD: Program and Library Variables
maude_LDFLAGS: Linking
maude_LDFLAGS: Program and Library Variables
maude_LFLAGS: Program and Library Variables
maude_LIBADD: A Library
maude_LIBADD: Program and Library Variables
maude_LIBTOOLFLAGS: Libtool Flags
maude_LIBTOOLFLAGS: Program and Library Variables
maude_LINK: Program and Library Variables
maude_OBJCFLAGS: Program and Library Variables
maude_OBJCXXFLAGS: Program and Library Variables
maude_RFLAGS: Program and Library Variables
maude_SHORTNAME: Program and Library Variables
maude_SOURCES: Program and Library Variables
maude_UPCFLAGS: Program and Library Variables
maude_YFLAGS: Program and Library Variables
MISSING: Public Macros
MKDIR_P: Obsolete Macros
mkdir_p: Obsolete Macros
MOSTLYCLEANFILES: Clean

N
nobase_: Alternative
nodist_: Alternative
nodist_: Fine-grained Distribution Control
noinst_: Uniform
noinst_HEADERS: Headers
noinst_HEADERS: Headers
noinst_LIBRARIES: A Library
noinst_LISP: Emacs Lisp
noinst_LTLIBRARIES: Libtool Convenience Libraries
noinst_PROGRAMS: Program Sources
noinst_SCRIPTS: Scripts
notrans_: Man Pages

O
OBJC: Objective C Support
OBJCCOMPILE: Objective C Support
OBJCFLAGS: Objective C Support
OBJCLINK: Objective C Support
OBJCLINK: How the Linker is Chosen
OBJCXX: Objective C++ Support
OBJCXXCOMPILE: Objective C++ Support
OBJCXXFLAGS: Objective C++ Support
OBJCXXLINK: Objective C++ Support
OBJCXXLINK: How the Linker is Chosen
oldinclude_HEADERS: Headers

P
PACKAGE: Basics of Distribution
pkgdatadir: Uniform
pkgdata_DATA: Data
pkgdata_SCRIPTS: Scripts
pkgincludedir: Uniform
pkginclude_HEADERS: Headers
pkglibdir: Uniform
pkglibexecdir: Uniform
pkglibexec_PROGRAMS: Program Sources
pkglibexec_SCRIPTS: Scripts
pkglib_LIBRARIES: A Library
pkglib_LTLIBRARIES: Libtool Libraries
pkgpyexecdir: Python
pkgpythondir: Python
PROGRAMS: Uniform
PROGRAMS: Uniform
pyexecdir: Python
PYTHON: Uniform
PYTHON: Python
pythondir: Python
PYTHON_EXEC_PREFIX: Python
PYTHON_PLATFORM: Python
PYTHON_PREFIX: Python
PYTHON_VERSION: Python

R
RECHECK_LOGS: Parallel Test Harness
RFLAGS: Fortran 77 Support
RUNTEST: DejaGnu Tests
RUNTESTDEFAULTFLAGS: DejaGnu Tests
RUNTESTFLAGS: DejaGnu Tests

S
sbin_PROGRAMS: Program Sources
sbin_SCRIPTS: Scripts
SCRIPTS: Uniform
SCRIPTS: Scripts
sharedstate_DATA: Data
SOURCES: Program Sources
SOURCES: Default _SOURCES
SUBDIRS: Subdirectories
SUBDIRS: Basics of Distribution
SUFFIXES: Suffixes
sysconf_DATA: Data

T
TAGS_DEPENDENCIES: Tags
target_triplet: Optional
TESTS: Scripts-based Testsuites
TESTS: Parallel Test Harness
TESTS_ENVIRONMENT: Scripts-based Testsuites
TEST_EXTENSIONS: Parallel Test Harness
TEST_LOGS: Parallel Test Harness
TEST_SUITE_LOG: Parallel Test Harness
TEXI2DVI: Texinfo
TEXI2PDF: Texinfo
TEXINFOS: Uniform
TEXINFOS: Texinfo
TEXINFO_TEX: Texinfo
top_distdir: The dist Hook
top_distdir: Third-Party Makefiles

U
UPC: Public Macros
UPC: Unified Parallel C Support
UPCCOMPILE: Unified Parallel C Support
UPCFLAGS: Unified Parallel C Support
UPCLINK: Unified Parallel C Support
UPCLINK: How the Linker is Chosen

V
V: Automake Silent Rules
VALAC: Vala Support
VALAFLAGS: Vala Support
VERBOSE: Parallel Test Harness
VERSION: Basics of Distribution

W
WARNINGS: automake Invocation
WARNINGS: aclocal Options
WITH_DMALLOC: Public Macros

X
XFAIL_TESTS: Scripts-based Testsuites
XZ_OPT: The Types of Distributions

Y
YACC: Optional
YFLAGS: Yacc and Lex

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Previous: , Up: Indices   [Contents][Index]

B.3 General Index

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A   B   C   D   E   F   G   H   I   J   L   M   N   O   P   R   S   T   U   V   W   X   Y   Z  
Index Entry  Section

#
## (special Automake comment): General Operation
#serial syntax: Serials

$
$(LIBOBJS)’ and empty libraries: LIBOBJS

+
+=: General Operation

-
--add-missing: automake Invocation
--automake-acdir: aclocal Options
--build=build: Cross-Compilation
--copy: automake Invocation
--diff: aclocal Options
--disable-dependency-tracking: Dependency Tracking
--disable-maintainer-mode: Optional
--disable-silent-rules: Automake Silent Rules
--dry-run: aclocal Options
--enable-debug, example: Usage of Conditionals
--enable-dependency-tracking: Dependency Tracking
--enable-maintainer-mode: Optional
--enable-silent-rules: Automake Silent Rules
--force: aclocal Options
--force-missing: automake Invocation
--foreign: automake Invocation
--gnits: automake Invocation
--gnits, complete description: Gnits
--gnu: automake Invocation
--gnu, complete description: Gnits
--gnu, required files: Gnits
--help: automake Invocation
--help: aclocal Options
--help check: List of Automake options
--help=recursive: Nested Packages
--host=host: Cross-Compilation
--include-deps: automake Invocation
--install: aclocal Options
--libdir: automake Invocation
--no-force: automake Invocation
--output: aclocal Options
--output-dir: automake Invocation
--prefix: Standard Directory Variables
--print-ac-dir: aclocal Options
--print-libdir: automake Invocation
--program-prefix=prefix: Renaming
--program-suffix=suffix: Renaming
--program-transform-name=program: Renaming
--system-acdir: aclocal Options
--target=target: Cross-Compilation
--verbose: automake Invocation
--verbose: aclocal Options
--version: automake Invocation
--version: aclocal Options
--version check: List of Automake options
--warnings: automake Invocation
--warnings: aclocal Options
--with-dmalloc: Public Macros
-a: automake Invocation
-c: automake Invocation
-f: automake Invocation
-hook targets: Extending
-i: automake Invocation
-I: aclocal Options
-l and LDADD: Linking
-local targets: Extending
-module, libtool: Libtool Modules
-o: automake Invocation
-v: automake Invocation
-W: automake Invocation
-W: aclocal Options
-Wall: amhello's configure.ac Setup Explained
-Werror: amhello's configure.ac Setup Explained

.
.la suffix, defined: Libtool Concept
.log files: Parallel Test Harness
.trs files: Parallel Test Harness

:
:copy-in-global-log:: Log files generation and test results recording
:recheck:: Log files generation and test results recording
:test-global-result:: Log files generation and test results recording
:test-result:: Log files generation and test results recording

_
_DATA primary, defined: Data
_DEPENDENCIES, defined: Linking
_HEADERS primary, defined: Headers
_JAVA primary, defined: Java
_LDFLAGS, defined: Linking
_LDFLAGS, libtool: Libtool Flags
_LIBADD, libtool: Libtool Flags
_LIBRARIES primary, defined: A Library
_LIBTOOLFLAGS, libtool: Libtool Flags
_LISP primary, defined: Emacs Lisp
_LTLIBRARIES primary, defined: Libtool Libraries
_MANS primary, defined: Man Pages
_PROGRAMS primary variable: Uniform
_PYTHON primary, defined: Python
_SCRIPTS primary, defined: Scripts
_SOURCES and header files: Program Sources
_SOURCES primary, defined: Program Sources
_SOURCES, default: Default _SOURCES
_SOURCES, empty: Default _SOURCES
_TEXINFOS primary, defined: Texinfo

A
acinclude.m4, defined: Complete
aclocal and serial numbers: Serials
aclocal program, introduction: Complete
aclocal search path: Macro Search Path
aclocal’s scheduled death: Future of aclocal
aclocal, extending: Extending aclocal
aclocal, Invocation: aclocal Invocation
aclocal, Invoking: aclocal Invocation
aclocal, Options: aclocal Options
aclocal, using: configure
aclocal.m4, preexisting: Complete
ACLOCAL_PATH: Macro Search Path
AC_CONFIG_FILES, conditional: Usage of Conditionals
AC_SUBST and SUBDIRS: Subdirectories with AC_SUBST
Adding new SUFFIXES: Suffixes
all: Standard Targets
all: Extending
all-local: Extending
ALLOCA, and Libtool: LTLIBOBJS
ALLOCA, example: LIBOBJS
ALLOCA, special handling: LIBOBJS
amhello-1.0.tar.gz, creation: Hello World
amhello-1.0.tar.gz, location: Use Cases
amhello-1.0.tar.gz, use cases: Use Cases
AM_CCASFLAGS and CCASFLAGS: Flag Variables Ordering
AM_CFLAGS and CFLAGS: Flag Variables Ordering
AM_CONDITIONAL and SUBDIRS: Subdirectories with AM_CONDITIONAL
AM_CPPFLAGS and CPPFLAGS: Flag Variables Ordering
AM_CXXFLAGS and CXXFLAGS: Flag Variables Ordering
AM_FCFLAGS and FCFLAGS: Flag Variables Ordering
AM_FFLAGS and FFLAGS: Flag Variables Ordering
AM_GCJFLAGS and GCJFLAGS: Flag Variables Ordering
AM_INIT_AUTOMAKE, example use: Complete
AM_LDFLAGS and LDFLAGS: Flag Variables Ordering
AM_LFLAGS and LFLAGS: Flag Variables Ordering
AM_LIBTOOLFLAGS and LIBTOOLFLAGS: Flag Variables Ordering
AM_MAINTAINER_MODE, purpose: maintainer-mode
AM_OBJCFLAGS and OBJCFLAGS: Flag Variables Ordering
AM_OBJCXXFLAGS and OBJXXCFLAGS: Flag Variables Ordering
AM_RFLAGS and RFLAGS: Flag Variables Ordering
AM_UPCFLAGS and UPCFLAGS: Flag Variables Ordering
AM_YFLAGS and YFLAGS: Flag Variables Ordering
Append operator: General Operation
ARG_MAX: Length Limitations
autogen.sh and autoreconf: Error required file ltmain.sh not found
autom4te: aclocal Invocation
Automake constraints: Introduction
automake options: automake Invocation
Automake parser, limitations of: General Operation
Automake requirements: Introduction
Automake requirements: Requirements
automake, invocation: automake Invocation
automake, invoking: automake Invocation
Automake, recursive operation: General Operation
Automatic dependency tracking: Dependencies
Automatic linker selection: How the Linker is Chosen
autoreconf and libtoolize: Error required file ltmain.sh not found
autoreconf, example: Creating amhello
autoscan: amhello's configure.ac Setup Explained
Autotools, introduction: GNU Build System
Autotools, purpose: Why Autotools
autoupdate: Obsolete Macros
Auxiliary programs: Auxiliary Programs
Avoiding man page renaming: Man Pages
Avoiding path stripping: Alternative

B
Binary package: DESTDIR
bootstrap and autoreconf: Error required file ltmain.sh not found
Bugs, reporting: Introduction
build tree and source tree: VPATH Builds
BUILT_SOURCES, defined: Sources

C
C++ support: C++ Support
canonicalizing Automake variables: Canonicalization
CCASFLAGS and AM_CCASFLAGS: Flag Variables Ordering
CFLAGS and AM_CFLAGS: Flag Variables Ordering
cfortran: Mixing Fortran 77 With C and C++
check: Standard Targets
check: Tests
check: Extending
check-local: Extending
check-news: List of Automake options
check_’ primary prefix, definition: Uniform
check_PROGRAMS example: Default _SOURCES
clean: Standard Targets
clean: Extending
clean-local: Clean
clean-local: Extending
Colorized testsuite output: Scripts-based Testsuites
command line length limit: Length Limitations
Comment, special to Automake: General Operation
Compilation of Java to bytecode: Java
Compilation of Java to native code: Java Support with gcj
Compile Flag Variables: Flag Variables Ordering
Complete example: Complete
Conditional example, --enable-debug: Usage of Conditionals
conditional libtool libraries: Conditional Libtool Libraries
Conditional programs: Conditional Programs
Conditional subdirectories: Conditional Subdirectories
Conditional SUBDIRS: Conditional Subdirectories
Conditionals: Conditionals
config.guess: automake Invocation
config.site example: config.site
configuration variables, overriding: Standard Configuration Variables
Configuration, basics: Basic Installation
Configure substitutions in TESTS: Parallel Test Harness
configure.ac, Hello World: amhello's configure.ac Setup Explained
configure.ac, scanning: configure
conflicting definitions: Extending
Constraints of Automake: Introduction
convenience libraries, libtool: Libtool Convenience Libraries
copying semantics: Extending
cpio example: Uniform
CPPFLAGS and AM_CPPFLAGS: Flag Variables Ordering
cross-compilation: Cross-Compilation
cross-compilation example: Cross-Compilation
CVS and generated files: CVS
CVS and third-party files: CVS
CVS and timestamps: CVS
CXXFLAGS and AM_CXXFLAGS: Flag Variables Ordering

D
DATA primary, defined: Data
debug build, example: VPATH Builds
debugging rules: Debugging Make Rules
default source, Libtool modules example: Default _SOURCES
default verbosity for silent rules: Automake Silent Rules
default _SOURCES: Default _SOURCES
definitions, conflicts: Extending
dejagnu: DejaGnu Tests
dejagnu: List of Automake options
depcomp: Dependencies
dependencies and distributed files: Errors with distclean
Dependency tracking: Dependency Tracking
Dependency tracking: Dependencies
Dependency tracking, disabling: Dependencies
directory variables: Standard Directory Variables
dirlist: Macro Search Path
Disabling dependency tracking: Dependencies
Disabling hard errors: Scripts-based Testsuites
dist: Standard Targets
dist: Basics of Distribution
dist-bzip2: The Types of Distributions
dist-bzip2: List of Automake options
dist-bzip2: List of Automake options
dist-gzip: The Types of Distributions
dist-hook: The dist Hook
dist-hook: Extending
dist-lzip: The Types of Distributions
dist-lzip: List of Automake options
dist-lzip: List of Automake options
dist-shar: The Types of Distributions
dist-shar: List of Automake options
dist-shar: List of Automake options
dist-tarZ: The Types of Distributions
dist-tarZ: List of Automake options
dist-tarZ: List of Automake options
dist-xz: The Types of Distributions
dist-xz: List of Automake options
dist-xz: List of Automake options
dist-zip: The Types of Distributions
dist-zip: List of Automake options
dist-zip: List of Automake options
distcheck: Creating amhello
distcheck: Checking the Distribution
distcheck better than dist: Preparing Distributions
distcheck example: Creating amhello
distcheck-hook: Checking the Distribution
distclean: Standard Targets
distclean: Extending
distclean: Errors with distclean
distclean, diagnostic: Errors with distclean
distclean-local: Clean
distclean-local: Extending
distcleancheck: Checking the Distribution
distdir: Third-Party Makefiles
Distinction between errors and failures in testsuites: Generalities about Testing
Distributions, preparation: Preparing Distributions
distuninstallcheck: Checking the Distribution
dist_ and nobase_: Alternative
dist_ and notrans_: Man Pages
DIST_SUBDIRS, explained: SUBDIRS vs DIST_SUBDIRS
dmalloc, support for: Public Macros
dvi: Texinfo
dvi: Extending
DVI output using Texinfo: Texinfo
dvi-local: Extending

E
E-mail, bug reports: Introduction
EDITION Texinfo flag: Texinfo
else: Usage of Conditionals
Empty libraries: A Library
Empty libraries and ‘$(LIBOBJS): LIBOBJS
empty _SOURCES: Default _SOURCES
endif: Usage of Conditionals
Example conditional --enable-debug: Usage of Conditionals
Example conditional AC_CONFIG_FILES: Usage of Conditionals
Example Hello World: Hello World
Example of recursive operation: General Operation
Example of shared libraries: Libtool Libraries
Example, EXTRA_PROGRAMS: Uniform
Example, false and true: true
Example, mixed language: Mixing Fortran 77 With C and C++
Executable extension: EXEEXT
Exit status 77, special interpretation: Scripts-based Testsuites
Exit status 99, special interpretation: Scripts-based Testsuites
expected failure: Generalities about Testing
expected test failure: Generalities about Testing
Expected test failure: Scripts-based Testsuites
Extending aclocal: Extending aclocal
Extending list of installation directories: Uniform
Extension, executable: EXEEXT
Extra files distributed with Automake: automake Invocation
EXTRA_, prepending: Uniform
EXTRA_PROGRAMS, defined: Uniform
EXTRA_PROGRAMS, defined: Conditional Programs
EXTRA_prog_SOURCES, defined: Conditional Sources

F
false Example: true
FCFLAGS and AM_FCFLAGS: Flag Variables Ordering
Features of the GNU Build System: Use Cases
FFLAGS and AM_FFLAGS: Flag Variables Ordering
file names, limitations on: Limitations on File Names
filename-length-max=99: List of Automake options
Files distributed with Automake: automake Invocation
First line of Makefile.am: General Operation
Flag variables, ordering: Flag Variables Ordering
Flag Variables, Ordering: Flag Variables Ordering
FLIBS, defined: Mixing Fortran 77 With C and C++
foreign: amhello's configure.ac Setup Explained
foreign: List of Automake options
foreign strictness: Strictness
Fortran 77 support: Fortran 77 Support
Fortran 77, mixing with C and C++: Mixing Fortran 77 With C and C++
Fortran 77, Preprocessing: Preprocessing Fortran 77
Fortran 9x support: Fortran 9x Support

G
GCJFLAGS and AM_GCJFLAGS: Flag Variables Ordering
generated files and CVS: CVS
generated files, distributed: CVS
Gettext support: gettext
git-dist: General Operation
git-dist, non-standard example: General Operation
gnits: List of Automake options
gnits strictness: Strictness
gnu: List of Automake options
GNU Build System, basics: Basic Installation
GNU Build System, features: Use Cases
GNU Build System, introduction: GNU Build System
GNU Build System, use cases: Use Cases
GNU Coding Standards: GNU Build System
GNU Gettext support: gettext
GNU make extensions: General Operation
GNU Makefile standards: Introduction
gnu strictness: Strictness
GNUmakefile including Makefile: Third-Party Makefiles

H
hard error: Generalities about Testing
Header files in _SOURCES: Program Sources
HEADERS primary, defined: Headers
HEADERS, installation directories: Headers
Hello World example: Hello World
hook targets: Extending
HP-UX 10, lex problems: Public Macros
html: Texinfo
html: Extending
HTML output using Texinfo: Texinfo
html-local: Extending

I
id: Tags
if: Usage of Conditionals
include: Basics of Distribution
include: Include
include, distribution: Basics of Distribution
Including Makefile fragment: Include
indentation in Makefile.am: General Operation
info: List of Automake options
info: Extending
info-in-builddir: List of Automake options
info-local: Extending
install: Standard Targets
install: The Two Parts of Install
install: Extending
Install hook: Extending Installation
Install, two parts of: The Two Parts of Install
install-data: Two-Part Install
install-data: The Two Parts of Install
install-data: Extending
install-data-hook: Extending
install-data-local: Extending Installation
install-data-local: Extending
install-dvi: Texinfo
install-dvi: Extending
install-dvi-local: Extending
install-exec: Two-Part Install
install-exec: The Two Parts of Install
install-exec: Extending
install-exec-hook: Extending
install-exec-local: Extending Installation
install-exec-local: Extending
install-html: Texinfo
install-html: Extending
install-html-local: Extending
install-info: Texinfo
install-info: List of Automake options
install-info: Extending
install-info target: Texinfo
install-info-local: Extending
install-man: Man Pages
install-man: List of Automake options
install-man target: Man Pages
install-pdf: Texinfo
install-pdf: Extending
install-pdf-local: Extending
install-ps: Texinfo
install-ps: Extending
install-ps-local: Extending
install-strip: Standard Targets
install-strip: Install Rules for the User
Installation directories, extending list: Uniform
Installation support: Install
Installation, basics: Basic Installation
installcheck: Standard Targets
installcheck: Extending
installcheck-local: Extending
installdirs: Install Rules for the User
installdirs: Extending
installdirs-local: Extending
Installing headers: Headers
Installing scripts: Scripts
installing versioned binaries: Extending
Interfacing with third-party packages: Third-Party Makefiles
Invocation of aclocal: aclocal Invocation
Invocation of automake: automake Invocation
Invoking aclocal: aclocal Invocation
Invoking automake: automake Invocation

J
JAVA primary, defined: Java
JAVA restrictions: Java
Java support with gcj: Java Support with gcj
Java to bytecode, compilation: Java
Java to native code, compilation: Java Support with gcj

L
lazy test execution: Parallel Test Harness
LDADD and -l: Linking
LDFLAGS and AM_LDFLAGS: Flag Variables Ordering
lex problems with HP-UX 10: Public Macros
lex, multiple lexers: Yacc and Lex
LFLAGS and AM_LFLAGS: Flag Variables Ordering
libltdl, introduction: Libtool Concept
LIBOBJS, and Libtool: LTLIBOBJS
LIBOBJS, example: LIBOBJS
LIBOBJS, special handling: LIBOBJS
LIBRARIES primary, defined: A Library
libtool convenience libraries: Libtool Convenience Libraries
libtool libraries, conditional: Conditional Libtool Libraries
libtool library, definition: Libtool Concept
libtool modules: Libtool Modules
Libtool modules, default source example: Default _SOURCES
libtool, introduction: Libtool Concept
LIBTOOLFLAGS and AM_LIBTOOLFLAGS: Flag Variables Ordering
libtoolize and autoreconf: Error required file ltmain.sh not found
libtoolize, no longer run by automake: Error required file ltmain.sh not found
Limitations of automake parser: General Operation
Linking Fortran 77 with C and C++: Mixing Fortran 77 With C and C++
LISP primary, defined: Emacs Lisp
LN_S example: Extending
local targets: Extending
LTALLOCA, special handling: LTLIBOBJS
LTLIBOBJS, special handling: LTLIBOBJS
LTLIBRARIES primary, defined: Libtool Libraries
ltmain.sh not found: Error required file ltmain.sh not found

M
m4_include, distribution: Basics of Distribution
Macro search path: Macro Search Path
macro serial numbers: Serials
Macros Automake recognizes: Optional
maintainer-clean-local: Clean
make check: Tests
make clean’ support: Clean
make dist: Basics of Distribution
make distcheck: Checking the Distribution
make distclean’, diagnostic: Errors with distclean
make distcleancheck: Checking the Distribution
make distuninstallcheck: Checking the Distribution
make install’ support: Install
make installcheck’, testing --help and --version: List of Automake options
Make rules, overriding: General Operation
Make targets, overriding: General Operation
Makefile fragment, including: Include
Makefile.am, first line: General Operation
Makefile.am, Hello World: amhello's Makefile.am Setup Explained
Man page renaming, avoiding: Man Pages
MANS primary, defined: Man Pages
many outputs, rules with: Multiple Outputs
mdate-sh: Texinfo
MinGW cross-compilation example: Cross-Compilation
missing, purpose: maintainer-mode
Mixed language example: Mixing Fortran 77 With C and C++
Mixing Fortran 77 with C and C++: Mixing Fortran 77 With C and C++
Mixing Fortran 77 with C and/or C++: Mixing Fortran 77 With C and C++
mkdir -p, macro check: Obsolete Macros
modules, libtool: Libtool Modules
mostlyclean: Extending
mostlyclean-local: Clean
mostlyclean-local: Extending
multiple configurations, example: VPATH Builds
Multiple configure.ac files: automake Invocation
Multiple lex lexers: Yacc and Lex
multiple outputs, rules with: Multiple Outputs
Multiple yacc parsers: Yacc and Lex

N
Nested packages: Nested Packages
Nesting packages: Subpackages
no-define: Public Macros
no-define: List of Automake options
no-dependencies: Dependencies
no-dependencies: List of Automake options
no-dist: List of Automake options
no-dist-gzip: List of Automake options
no-dist-gzip: List of Automake options
no-exeext: List of Automake options
no-installinfo: Texinfo
no-installinfo: List of Automake options
no-installinfo option: Texinfo
no-installman: Man Pages
no-installman: List of Automake options
no-installman option: Man Pages
no-texinfo.tex: List of Automake options
nobase_ and dist_ or nodist_: Alternative
nobase_ prefix: Alternative
nodist_ and nobase_: Alternative
nodist_ and notrans_: Man Pages
noinst_’ primary prefix, definition: Uniform
Non-GNU packages: Strictness
Non-standard targets: General Operation
nostdinc: List of Automake options
notrans_ and dist_ or nodist_: Man Pages
notrans_ prefix: Man Pages

O
OBJCFLAGS and AM_OBJCFLAGS: Flag Variables Ordering
OBJCXXFLAGS and AM_OBJCXXFLAGS: Flag Variables Ordering
Objective C support: Objective C Support
Objective C++ support: Objective C++ Support
Objects in subdirectory: Program and Library Variables
obsolete macros: Obsolete Macros
optimized build, example: VPATH Builds
Option, --warnings=category: List of Automake options
Option, -Wcategory: List of Automake options
Option, check-news: List of Automake options
Option, dejagnu: List of Automake options
Option, dist-bzip2: List of Automake options
Option, dist-lzip: List of Automake options
Option, dist-shar: List of Automake options
Option, dist-tarZ: List of Automake options
Option, dist-xz: List of Automake options
Option, dist-zip: List of Automake options
Option, filename-length-max=99: List of Automake options
Option, foreign: List of Automake options
Option, gnits: List of Automake options
Option, gnu: List of Automake options
Option, info-in-builddir: List of Automake options
Option, no-define: List of Automake options
Option, no-dependencies: List of Automake options
Option, no-dist: List of Automake options
Option, no-dist-gzip: List of Automake options
Option, no-exeext: List of Automake options
Option, no-installinfo: Texinfo
Option, no-installinfo: List of Automake options
Option, no-installman: Man Pages
Option, no-installman: List of Automake options
Option, no-texinfo.tex: List of Automake options
Option, nostdinc: List of Automake options
Option, parallel-tests: List of Automake options
Option, readme-alpha: List of Automake options
Option, serial-tests: List of Automake options
Option, tar-pax: List of Automake options
Option, tar-ustar: List of Automake options
Option, tar-v7: List of Automake options
Option, version: List of Automake options
Option, warnings: List of Automake options
Options, aclocal: aclocal Options
Options, automake: automake Invocation
Options, std-options: List of Automake options
Options, subdir-objects: List of Automake options
Ordering flag variables: Flag Variables Ordering
Overriding make rules: General Operation
Overriding make targets: General Operation
Overriding make variables: General Operation
overriding rules: Extending
overriding semantics: Extending

P
PACKAGE, directory: Uniform
PACKAGE, prevent definition: Public Macros
Packages, nested: Nested Packages
Packages, preparation: Preparing Distributions
Parallel build trees: VPATH Builds
parallel-tests: List of Automake options
Path stripping, avoiding: Alternative
pax format: List of Automake options
pdf: Texinfo
pdf: Extending
PDF output using Texinfo: Texinfo
pdf-local: Extending
Per-object flags, emulated: Per-Object Flags
per-target compilation flags, defined: Program and Library Variables
pkgdatadir, defined: Uniform
pkgincludedir, defined: Uniform
pkglibdir, defined: Uniform
pkglibexecdir, defined: Uniform
Preparing distributions: Preparing Distributions
Preprocessing Fortran 77: Preprocessing Fortran 77
Primary variable, DATA: Data
Primary variable, defined: Uniform
Primary variable, HEADERS: Headers
Primary variable, JAVA: Java
Primary variable, LIBRARIES: A Library
Primary variable, LISP: Emacs Lisp
Primary variable, LTLIBRARIES: Libtool Libraries
Primary variable, MANS: Man Pages
Primary variable, PROGRAMS: Uniform
Primary variable, PYTHON: Python
Primary variable, SCRIPTS: Scripts
Primary variable, SOURCES: Program Sources
Primary variable, TEXINFOS: Texinfo
PROGRAMS primary variable: Uniform
Programs, auxiliary: Auxiliary Programs
PROGRAMS, bindir: Program Sources
Programs, conditional: Conditional Programs
Programs, renaming during installation: Renaming
prog_LDADD, defined: Linking
Proxy Makefile for third-party packages: Third-Party Makefiles
ps: Texinfo
ps: Extending
PS output using Texinfo: Texinfo
ps-local: Extending
PYTHON primary, defined: Python

R
Ratfor programs: Preprocessing Fortran 77
read-only source tree: VPATH Builds
readme-alpha: List of Automake options
README-alpha: Gnits
rebuild rules: Rebuilding
rebuild rules: CVS
recheck: Parallel Test Harness
Recognized macros by Automake: Optional
Recursive operation of Automake: General Operation
recursive targets and third-party Makefiles: Third-Party Makefiles
Register test case result: Log files generation and test results recording
Register test result: Log files generation and test results recording
Renaming programs: Renaming
Reporting bugs: Introduction
Requirements of Automake: Requirements
Requirements, Automake: Introduction
Restrictions for JAVA: Java
reStructuredText field, :copy-in-global-log:: Log files generation and test results recording
reStructuredText field, :recheck:: Log files generation and test results recording
reStructuredText field, :test-global-result:: Log files generation and test results recording
reStructuredText field, :test-result:: Log files generation and test results recording
RFLAGS and AM_RFLAGS: Flag Variables Ordering
rules with multiple outputs: Multiple Outputs
rules, conflicting: Extending
rules, debugging: Debugging Make Rules
rules, overriding: Extending

S
Scanning configure.ac: configure
SCRIPTS primary, defined: Scripts
SCRIPTS, installation directories: Scripts
Selecting the linker automatically: How the Linker is Chosen
serial number and --install: aclocal Options
serial numbers in macros: Serials
serial-tests: List of Automake options
serial-tests, Using: Serial Test Harness
Shared libraries, support for: A Shared Library
Silencing make: Silencing Make
Silent make: Silencing Make
Silent make rules: Silencing Make
Silent rules: Silencing Make
silent rules and libtool: Automake Silent Rules
site.exp: DejaGnu Tests
source tree and build tree: VPATH Builds
source tree, read-only: VPATH Builds
SOURCES primary, defined: Program Sources
Special Automake comment: General Operation
Staged installation: DESTDIR
std-options: List of Automake options
Strictness, command line: automake Invocation
Strictness, defined: Strictness
Strictness, foreign: Strictness
Strictness, gnits: Strictness
Strictness, gnu: Strictness
su, before make install: Basic Installation
subdir-objects: List of Automake options
Subdirectories, building conditionally: Conditional Subdirectories
Subdirectories, configured conditionally: Unconfigured Subdirectories
Subdirectories, not distributed: Unconfigured Subdirectories
Subdirectory, objects in: Program and Library Variables
SUBDIRS and AC_SUBST: Subdirectories with AC_SUBST
SUBDIRS and AM_CONDITIONAL: Subdirectories with AM_CONDITIONAL
SUBDIRS, conditional: Conditional Subdirectories
SUBDIRS, explained: Subdirectories
Subpackages: Nested Packages
Subpackages: Subpackages
suffix .la, defined: Libtool Concept
suffix .lo, defined: Libtool Concept
SUFFIXES, adding: Suffixes
Support for C++: C++ Support
Support for Fortran 77: Fortran 77 Support
Support for Fortran 9x: Fortran 9x Support
Support for GNU Gettext: gettext
Support for Java with gcj: Java Support with gcj
Support for Objective C: Objective C Support
Support for Objective C++: Objective C++ Support
Support for Unified Parallel C: Unified Parallel C Support
Support for Vala: Vala Support

T
tags: Tags
TAGS support: Tags
tar formats: List of Automake options
tar-pax: List of Automake options
tar-ustar: List of Automake options
tar-v7: List of Automake options
Target, install-info: Texinfo
Target, install-man: Man Pages
test case: Generalities about Testing
Test case result, registering: Log files generation and test results recording
test failure: Generalities about Testing
test harness: Generalities about Testing
test metadata: Parallel Test Harness
test pass: Generalities about Testing
Test result, registering: Log files generation and test results recording
test skip: Generalities about Testing
Test suites: Tests
Tests, expected failure: Scripts-based Testsuites
testsuite harness: Generalities about Testing
Testsuite progress on console: Scripts-based Testsuites
Texinfo flag, EDITION: Texinfo
Texinfo flag, UPDATED: Texinfo
Texinfo flag, UPDATED-MONTH: Texinfo
Texinfo flag, VERSION: Texinfo
texinfo.tex: Texinfo
TEXINFOS primary, defined: Texinfo
third-party files and CVS: CVS
Third-party packages, interfacing with: Third-Party Makefiles
timestamps and CVS: CVS
Transforming program names: Renaming
trees, source vs. build: VPATH Builds
true Example: true

U
underquoted AC_DEFUN: Extending aclocal
unexpected pass: Generalities about Testing
unexpected test pass: Generalities about Testing
Unified Parallel C support: Unified Parallel C Support
Uniform naming scheme: Uniform
uninstall: Standard Targets
uninstall: Install Rules for the User
uninstall: Extending
uninstall-hook: Extending
uninstall-local: Extending
Unit tests: Parallel Test Harness
Unpacking: Basic Installation
UPCFLAGS and AM_UPCFLAGS: Flag Variables Ordering
UPDATED Texinfo flag: Texinfo
UPDATED-MONTH Texinfo flag: Texinfo
Use Cases for the GNU Build System: Use Cases
user variables: User Variables
Using aclocal: configure
ustar format: List of Automake options

V
v7 tar format: List of Automake options
Vala Support: Vala Support
variables, conflicting: Extending
Variables, overriding: General Operation
variables, reserved for the user: User Variables
VERSION Texinfo flag: Texinfo
VERSION, prevent definition: Public Macros
version.m4, example: Rebuilding
version.sh, example: Rebuilding
versioned binaries, installing: Extending
VPATH builds: VPATH Builds

W
wildcards: Wildcards
Windows: EXEEXT

X
xfail: Generalities about Testing
xpass: Generalities about Testing

Y
yacc, multiple parsers: Yacc and Lex
YFLAGS and AM_YFLAGS: Flag Variables Ordering
ylwrap: Yacc and Lex

Z
zardoz example: Complete

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Footnotes

(1)

These variables are also called make macros in Make terminology, however in this manual we reserve the term macro for Autoconf’s macros.

(2)

We believe. This work is new and there are probably warts. See Introduction, for information on reporting bugs.

(3)

There are other, more obscure reasons for this limitation as well.

(4)

Please note that automake recognizes -d in AM_YFLAGS only if it is not clustered with other options; for example, it won’t be recognized if AM_YFLAGS is -dt, but it will be if AM_YFLAGS is -d -t or -t -d.

(5)

Much, if not most, of the information in the following sections pertaining to preprocessing Fortran 77 programs was taken almost verbatim from Catalogue of Rules in The GNU Make Manual.

(6)

For example, the cfortran package addresses all of these inter-language issues, and runs under nearly all Fortran 77, C and C++ compilers on nearly all platforms. However, cfortran is not yet Free Software, but it will be in the next major release.

(7)

See also http://catb.org/~esr/writings/taoup/html/ch11s09.html.

(8)

Automake’s ‘dist’ and ‘distcheck’ rules had a bug in this regard in that they created directories even with -n, but this has been fixed in Automake 1.11.