Although &SCons; provides many useful methods
for building common software products:
programs, libraries, documents.
you frequently want to be
able to build some other type of file
not supported directly by &SCons;.
Fortunately, &SCons; makes it very easy
to define your own &Builder; objects
for any custom file types you want to build.
(In fact, the &SCons; interfaces for creating
&Builder; objects are flexible enough and easy enough to use
that all of the the &SCons; built-in &Builder; objects
are created the mechanisms described in this section.)
Writing Builders That Execute External Commands
The simplest &Builder; to create is
one that executes an external command.
For example, if we want to build
an output file by running the contents
of the input file through a command named
foobuild,
creating that &Builder; might look like:
bld = Builder(action = 'foobuild < $SOURCE > $TARGET')
All the above line does is create a free-standing
&Builder; object.
The next section will show us how to actually use it.
Attaching a Builder to a &ConsEnv;
A &Builder; object isn't useful
until it's attached to a &consenv;
so that we can call it to arrange
for files to be built.
This is done through the &cv-link-BUILDERS;
&consvar; in an environment.
The &cv-BUILDERS; variable is a Python dictionary
that maps the names by which you want to call
various &Builder; objects to the objects themselves.
For example, if we want to call the
&Builder; we just defined by the name
Foo,
our &SConstruct; file might look like:
bld = Builder(action = 'foobuild < $SOURCE > $TARGET')
env = Environment(BUILDERS = {'Foo' : bld})
With the &Builder; attached to our &consenv;
with the name Foo,
we can now actually call it like so:
env.Foo('file.foo', 'file.input')
Then when we run &SCons; it looks like:
% scons -Q
foobuild < file.input > file.foo
Note, however, that the default &cv-BUILDERS;
variable in a &consenv;
comes with a default set of &Builder; objects
already defined:
&b-link-Program;, &b-link-Library;, etc.
And when we explicitly set the &cv-BUILDERS; variable
when we create the &consenv;,
the default &Builder;s are no longer part of
the environment:
bld = Builder(action = 'foobuild < $SOURCE > $TARGET')
env = Environment(BUILDERS = {'Foo' : bld})
env.Foo('file.foo', 'file.input')
env.Program('hello.c')
% scons -Q
AttributeError: SConsEnvironment instance has no attribute 'Program':
File "/home/my/project/SConstruct", line 4:
env.Program('hello.c')
To be able to use both our own defined &Builder; objects
and the default &Builder; objects in the same &consenv;,
you can either add to the &cv-BUILDERS; variable
using the &Append; function:
env = Environment()
bld = Builder(action = 'foobuild < $SOURCE > $TARGET')
env.Append(BUILDERS = {'Foo' : bld})
env.Foo('file.foo', 'file.input')
env.Program('hello.c')
Or you can explicitly set the appropriately-named
key in the &cv-BUILDERS; dictionary:
env = Environment()
bld = Builder(action = 'foobuild < $SOURCE > $TARGET')
env['BUILDERS']['Foo'] = bld
env.Foo('file.foo', 'file.input')
env.Program('hello.c')
Either way, the same &consenv;
can then use both the newly-defined
Foo &Builder;
and the default &b-link-Program; &Builder;:
% scons -Q
foobuild < file.input > file.foo
cc -o hello.o -c hello.c
cc -o hello hello.o
Letting &SCons; Handle The File Suffixes
By supplying additional information
when you create a &Builder;,
you can let &SCons; add appropriate file
suffixes to the target and/or the source file.
For example, rather than having to specify
explicitly that you want the Foo
&Builder; to build the file.foo
target file from the file.input source file,
you can give the .foo
and .input suffixes to the &Builder;,
making for more compact and readable calls to
the Foo &Builder;:
bld = Builder(action = 'foobuild < $SOURCE > $TARGET',
suffix = '.foo',
src_suffix = '.input')
env = Environment(BUILDERS = {'Foo' : bld})
env.Foo('file1')
env.Foo('file2')
% scons -Q
foobuild < file1.input > file1.foo
foobuild < file2.input > file2.foo
You can also supply a prefix keyword argument
if it's appropriate to have &SCons; append a prefix
to the beginning of target file names.
Builders That Execute Python Functions
In &SCons;, you don't have to call an external command
to build a file.
You can, instead, define a Python function
that a &Builder; object can invoke
to build your target file (or files).
Such a &buildfunc; definition looks like:
def build_function(target, source, env):
# Code to build "target" from "source"
return None
The arguments of a &buildfunc; are:
target
A list of Node objects representing
the target or targets to be
built by this builder function.
The file names of these target(s)
may be extracted using the Python &str; function.
source
A list of Node objects representing
the sources to be
used by this builder function to build the targets.
The file names of these source(s)
may be extracted using the Python &str; function.
env
The &consenv; used for building the target(s).
The builder function may use any of the
environment's construction variables
in any way to affect how it builds the targets.
The builder function must
return a 0 or None value
if the target(s) are built successfully.
The builder function
may raise an exception
or return any non-zero value
to indicate that the build is unsuccessful,
Once you've defined the Python function
that will build your target file,
defining a &Builder; object for it is as
simple as specifying the name of the function,
instead of an external command,
as the &Builder;'s
action
argument:
def build_function(target, source, env):
# Code to build "target" from "source"
return None
bld = Builder(action = build_function,
suffix = '.foo',
src_suffix = '.input')
env = Environment(BUILDERS = {'Foo' : bld})
env.Foo('file')
And notice that the output changes slightly,
reflecting the fact that a Python function,
not an external command,
is now called to build the target file:
% scons -Q
build_function(["file.foo"], ["file.input"])
Builders That Create Actions Using a &Generator;
&SCons; Builder objects can create an action "on the fly"
by using a function called a &generator;.
This provides a great deal of flexibility to
construct just the right list of commands
to build your target.
A &generator; looks like:
def generate_actions(source, target, env, for_signature):
return 'foobuild < %s > %s' % (target[0], source[0])
The arguments of a &generator; are:
source
A list of Node objects representing
the sources to be built
by the command or other action
generated by this function.
The file names of these source(s)
may be extracted using the Python &str; function.
target
A list of Node objects representing
the target or targets to be built
by the command or other action
generated by this function.
The file names of these target(s)
may be extracted using the Python &str; function.
env
The &consenv; used for building the target(s).
The generator may use any of the
environment's construction variables
in any way to determine what command
or other action to return.
for_signature
A flag that specifies whether the
generator is being called to contribute to a build signature,
as opposed to actually executing the command.
The &generator; must return a
command string or other action that will be used to
build the specified target(s) from the specified source(s).
Once you've defined a &generator;,
you create a &Builder; to use it
by specifying the generator keyword argument
instead of action.
def generate_actions(source, target, env, for_signature):
return 'foobuild < %s > %s' % (source[0], target[0])
bld = Builder(generator = generate_actions,
suffix = '.foo',
src_suffix = '.input')
env = Environment(BUILDERS = {'Foo' : bld})
env.Foo('file')
% scons -Q
foobuild < file.input > file.foo
Note that it's illegal to specify both an
action
and a
generator
for a &Builder;.
Builders That Modify the Target or Source Lists Using an &Emitter;
&SCons; supports the ability for a Builder to modify the
lists of target(s) from the specified source(s).
You do this by defining an &emitter; function
that takes as its arguments
the list of the targets passed to the builder,
the list of the sources passed to the builder,
and the construction environment.
The emitter function should return the modified
lists of targets that should be built
and sources from which the targets will be built.
For example, suppose you want to define a Builder
that always calls a foobuild program,
and you want to automatically add
a new target file named
new_target
and a new source file named
new_source
whenever it's called.
The &SConstruct; file might look like this:
def modify_targets(target, source, env):
target.append('new_target')
source.append('new_source')
return target, source
bld = Builder(action = 'foobuild $TARGETS - $SOURCES',
suffix = '.foo',
src_suffix = '.input',
emitter = modify_targets)
env = Environment(BUILDERS = {'Foo' : bld})
env.Foo('file')
And would yield the following output:
% scons -Q
foobuild file.foo new_target - file.input new_source
One very flexible thing that you can do is
use a construction variable to specify
different emitter functions for different
construction variable.
To do this, specify a string
containing a construction variable
expansion as the emitter when you call
the &Builder; function,
and set that construction variable to
the desired emitter function
in different construction environments:
bld = Builder(action = 'my_command $SOURCES > $TARGET',
suffix = '.foo',
src_suffix = '.input',
emitter = '$MY_EMITTER')
def modify1(target, source, env):
return target, source + ['modify1.in']
def modify2(target, source, env):
return target, source + ['modify2.in']
env1 = Environment(BUILDERS = {'Foo' : bld},
MY_EMITTER = modify1)
env2 = Environment(BUILDERS = {'Foo' : bld},
MY_EMITTER = modify2)
env1.Foo('file1')
env2.Foo('file2')
import os
env1['ENV']['PATH'] = env2['ENV']['PATH'] + os.pathsep + os.getcwd()
env2['ENV']['PATH'] = env2['ENV']['PATH'] + os.pathsep + os.getcwd()
bld = Builder(action = 'my_command $SOURCES > $TARGET',
suffix = '.foo',
src_suffix = '.input',
emitter = '$MY_EMITTER')
def modify1(target, source, env):
return target, source + ['modify1.in']
def modify2(target, source, env):
return target, source + ['modify2.in']
env1 = Environment(BUILDERS = {'Foo' : bld},
MY_EMITTER = modify1)
env2 = Environment(BUILDERS = {'Foo' : bld},
MY_EMITTER = modify2)
env1.Foo('file1')
env2.Foo('file2')
In this example, the modify1.in
and modify2.in files
get added to the source lists
of the different commands:
% scons -Q
my_command file1.input modify1.in > file1.foo
my_command file2.input modify2.in > file2.foo
Where To Put Your Custom Builders and Tools
The site_scons directory gives you a place to
put Python modules you can import into your &SConscript; files
(site_scons),
add-on tools that can integrate into &SCons;
(site_scons/site_tools),
and a site_scons/site_init.py file that
gets read before any &SConstruct; or &SConscript; file,
allowing you to change &SCons;'s default behavior.
If you get a tool from somewhere (the &SCons; wiki or a third party,
for instance) and you'd like to use it in your project, the
site_scons dir is the simplest place to put it.
Tools come in two flavors; either a Python function that operates on
an &Environment; or a Python file containing two functions,
exists() and generate().
A single-function Tool can just be included in your
site_scons/site_init.py file where it will be
parsed and made available for use. For instance, you could have a
site_scons/site_init.py file like this:
def TOOL_ADD_HEADER(env):
"""A Tool to add a header from $HEADER to the source file"""
add_header = Builder(action=['echo "$HEADER" > $TARGET',
'cat $SOURCE >> $TARGET'])
env.Append(BUILDERS = {'AddHeader' : add_header})
env['HEADER'] = '' # set default value
and a &SConstruct; like this:
# Use TOOL_ADD_HEADER from site_scons/site_init.py
env=Environment(tools=['default', TOOL_ADD_HEADER], HEADER="=====")
env.AddHeader('tgt', 'src')
The TOOL_ADD_HEADER tool method will be
called to add the AddHeader tool to the
environment.
Similarly, a more full-fledged tool with
exists() and generate()
methods can be installed in
site_scons/site_tools/toolname.py. Since
site_scons/site_tools is automatically added
to the head of the tool search path, any tool found there will be
available to all environments. Furthermore, a tool found there
will override a built-in tool of the same name, so if you need to
change the behavior of a built-in tool, site_scons gives you the
hook you need.
Many people have a library of utility Python functions they'd like
to include in &SConscript;s; just put that module in
site_scons/my_utils.py or any valid Python module name of your
choice. For instance you can do something like this in
site_scons/my_utils.py to add
build_id and MakeWorkDir
functions:
from SCons.Script import * # for Execute and Mkdir
def build_id():
"""Return a build ID (stub version)"""
return "100"
def MakeWorkDir(workdir):
"""Create the specified dir immediately"""
Execute(Mkdir(workdir))
And then in your &SConscript; or any sub-&SConscript; anywhere in
your build, you can import my_utils and use it:
import my_utils
print "build_id=" + my_utils.build_id()
my_utils.MakeWorkDir('/tmp/work')
Note that although you can put this library in
site_scons/site_init.py,
it is no better there than site_scons/my_utils.py
since you still have to import that module into your &SConscript;.
Also note that in order to refer to objects in the SCons namespace
such as &Environment; or &Mkdir; or &Execute; in any file other
than a &SConstruct; or &SConscript; you always need to do
from SCons.Script import *
This is true in modules in site_scons such as
site_scons/site_init.py as well.
If you have a machine-wide site dir you'd like to use instead of
./site_scons, use the
--site-dir option to point to your dir.
site_init.py and
site_tools will be located under that dir.
To avoid using a site_scons dir at all, even
if it exists, use the --no-site-dir option.