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175 lines
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ReStructuredText
175 lines
7.2 KiB
ReStructuredText
Waf tutorial
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============
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Waf is a piece of software used to help building software projects.
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The goal of this tutorial is to provide a quick overview of how to set up
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the scripts for a project using Waf.
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Waf scripts and commands
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------------------------
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A software typically has *source files* which are kept in a version control system (git, subversion, etc),
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and *build scripts* (Makefiles, ..) which describe what to do with those files. A few *build files* are usually
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obtained after transforming the *source files*, but they are optional. The build scripts in Waf are files named 'wscript'.
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In general, a project will consist of several phases:
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* configure: configure the project, find the location of the prerequisites
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* build: transform the source files into build files
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* install: install the build files
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* uninstall: uninstall the build files
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* dist: create an archive of the source files
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* clean: remove the build files
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Each phase is modelled in the wscript file as a python function which takes as argument an instance of :py:class:`waflib.Context.Context`.
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Let's start with a new wscript file in the directory '/tmp/myproject'::
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def configure(conf):
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print("configure!")
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def build(bld):
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print("build!")
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We will also use a Waf binary file, for example http://waf.googlecode.com/files/waf-1.6.1, which we will copy in the project directory::
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$ cd /tmp/myproject
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$ wget http://waf.googlecode.com/files/waf-1.6.1
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To execute the project, we will simply call the command as an argument to ``waf``::
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$ ./waf-1.6.1 configure build
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configure!
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build!
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Targets
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-------
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An important part of the build system is to declare the creation of targets. Here is a very simple example::
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def build(bld):
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tg = bld(rule='cp ${SRC} ${TGT}', source='wscript', target='foo.txt')
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bld(rule='cp ${SRC} ${TGT}', source='foo.txt', target='bar.txt')
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The call ``bld(..)`` creates an object called *task generator*, which is used to create *tasks* which will actually
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call the command ``cp``. The commands are not executed unless all the scripts have been read, which is important
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for computing the build order.
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The expressions *${SRC}* and *${TGT}* are shortcuts to avoid repeating the file names. More shortcuts can be defined
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by using the *${}* symbol, which reads the values from the attribute bld.env::
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def build(bld):
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bld.env.MESSAGE = 'Hello, world!'
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bld(rule='echo ${MESSAGE}', always=True)
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The bld object is an instance of :py:class:`waflib.Build.BuildContext`, its *env* attribute is an instance :py:class:`waflib.ConfigSet.ConfigSet`.
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The values are set in this object to be shared/stored/loaded easily. Here is how to do the same thing by sharing data between the configuration and build::
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def configure(cnf):
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cnf.env.MESSAGE = 'Hello, world!'
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def build(bld):
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bld(rule='echo ${MESSAGE}', always=True)
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Scripts and Tools
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-----------------
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To let a script use a script from a subdirectory, the method :py:meth:`waflib.Context.Context.recurse` has to be used with
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the relative path to the folder containing the wscript file. For example, to call the function *build* in the script ``src/wscript``,
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one should write::
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def build(bld):
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bld.recurse('src')
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The support for specific languages and compilers is provided through specific modules called *Waf tools*. The tools are
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similar to wscript files and provide functions such as *configure* or *build*. Here is a simple project for the C programming language::
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def options(opt):
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opt.load('compiler_c')
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def configure(cnf):
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cnf.load('compiler_c')
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def build(bld):
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bld(features='c cprogram', source='main.c', target='app')
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The function *options* is another predefined command used for setting command-line options. Its argument is an instance of :py:meth:`waflib.Options.OptionsContext`. The tool *compiler_c* is provided for detecting if a C compiler is present and to set various variables such as ``cnf.env.CFLAGS``.
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The task generator declared in *bld* does not have a *rule* keyword, but a list of *features* which is used to reference methods that will call the appropriate rules. In this case, a rule is called for compiling the file, and another is used for linking the object files into the binary *app*. Other tool-dependent features exist such as *javac*, *cs*, or *tex*.
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A C and C++ project
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-------------------
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Here is a script for a more complicated project::
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def options(opt):
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opt.load('compiler_c compiler_cxx')
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def configure(cnf):
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cnf.load('compiler_c compiler_cxx')
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conf.check(features='cxx cxxprogram', lib=['m'], cflags=['-Wall'], defines=['var=foo'], uselib_store='M')
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def build(bld):
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bld(features='c cshlib', source='b.c', target='mylib')
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bld(features='c cxx cxxprogram', source='a.c main.cpp', target='app', use=['M','mylib'], lib=['dl'])
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The method :py:func:`waflib.Tools.c_config.check` executes a build internally to check if the library ``libm`` is present on the operating system.
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It will then define variables such as:
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* ``conf.env.LIB_M = ['m']``
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* ``conf.env.CFLAGS_M = ['-Wall']``
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* ``conf.env.DEFINES_M = ['var=foo']``
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By stating ``use=['M', 'mylib']``, the program *app* is going to inherit all the *M* variables defined
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during the configuration. The program will also use the library *mylib* and both the build order and the dependencies
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will be modified so that *mylib* is linked before *app*.
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The ``use`` attribute is also working for other languages such as Java (dependencies between jar files) or C# (dependencies between assemblies).
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Project-specific extensions
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---------------------------
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The *feature* keyword is a high-level reference to existing Waf methods.
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For example, the **c** feature will add the method :py:func:`waflib.Tools.ccroot.apply_incpaths` for execution.
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To add a new method that will add the task generator path to the include path for all C targets,
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one may use such a declaration::
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from waflib import Utils
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from waflib.TaskGen import feature, before_method
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@feature('c')
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@before_method('apply_incpaths')
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def add_current_dir_to_includes(self):
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self.includes = Utils.to_list(self.includes)
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self.includes.append(self.path)
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def build(bld):
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tg = bld(features='c', source='main.c', target='app')
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The *feature* methods are bound to the :py:class:`waflib.TaskGen.task_gen` class, which is the class of the
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object *tg* in the example. New features can be declared in the same manner::
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from waflib.TaskGen import feature, after_method
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@feature('debug_tasks')
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@after_method('apply_link')
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def print_debug(self):
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print('tasks created %r' % self.tasks)
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def build(bld):
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tg = bld(features='c cprogram debug_tasks', source='main.c', target='app')
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The declaration can be made more user-friendly by binding new methods to the context classes::
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from waflib.Build import BuildContext
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def enterprise_program(self, *k, **kw):
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kw['features'] = 'c cprogram debug_tasks'
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return self(*k, **kw)
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BuildContext.enterprise_program = enterprise_program
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def build(bld):
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# no feature line
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bld.enterprise_program(source='main.c', target='app')
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The support code may be turned into a Waf tool by moving it to a separate file.
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To ease the deployment, the new Waf tool can even be added to the waf file (see http://code.google.com/p/waf/source/browse/trunk/README).
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Conclusion
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----------
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This concludes the tutorial. For more information consult the apis, the Waf book and the examples.
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