version 2.4.0
Copyright © 2004 - 2015 The SCons Foundation
2004 - 2015
The scons utility builds software (or other files) by determining which component pieces must be rebuilt and executing the necessary commands to rebuild them.
By default,
scons
searches for a file named
SConstruct,
Sconstruct,
or
sconstruct
(in that order) in the current directory and reads its
configuration from the first file found.
An alternate file name may be
specified via the
-f
option.
The SConstruct file can specify subsidiary configuration files using the SConscript() function. By convention, these subsidiary files are named SConscript, although any name may be used. (Because of this naming convention, the term "SConscript files" is sometimes used to refer generically to all scons configuration files, regardless of actual file name.)
The configuration files specify the target files to be built, and (optionally) the rules to build those targets. Reasonable default rules exist for building common software components (executable programs, object files, libraries), so that for most software projects, only the target and input files need be specified.
Before reading the
SConstruct
file,
scons
looks for a directory named
site_scons
in various system directories (see below) and the directory containing the
SConstruct
file; for each of those dirs which exists,
site_scons
is prepended to sys.path,
the file
site_scons/site_init.py,
is evaluated if it exists,
and the directory
site_scons/site_tools
is prepended to the default toolpath if it exists.
See the
--no-site-dir
and
--site-dir
options for more details.
scons reads and executes the SConscript files as Python scripts, so you may use normal Python scripting capabilities (such as flow control, data manipulation, and imported Python libraries) to handle complicated build situations. scons, however, reads and executes all of the SConscript files before it begins building any targets. To make this obvious, scons prints the following messages about what it is doing:
$ scons foo.out scons: Reading SConscript files ... scons: done reading SConscript files. scons: Building targets ... cp foo.in foo.out scons: done building targets. $
The status messages
(everything except the line that reads "cp foo.in foo.out")
may be suppressed using the
-Q
option.
scons does not automatically propagate the external environment used to execute scons to the commands used to build target files. This is so that builds will be guaranteed repeatable regardless of the environment variables set at the time scons is invoked. This also means that if the compiler or other commands that you want to use to build your target files are not in standard system locations, scons will not find them unless you explicitly set the PATH to include those locations. Whenever you create an scons construction environment, you can propagate the value of PATH from your external environment as follows:
import os env = Environment(ENV = {'PATH' : os.environ['PATH']})
Similarly, if the commands use external environment variables like $PATH, $HOME, $JAVA_HOME, $LANG, $SHELL, $TERM, etc., these variables can also be explicitly propagated:
import os env = Environment(ENV = {'PATH' : os.environ['PATH'], 'HOME' : os.environ['HOME']})
Or you may explicitly propagate the invoking user's complete external environment:
import os env = Environment(ENV = os.environ)
This comes at the expense of making your build dependent on the user's environment being set correctly, but it may be more convenient for many configurations.
scons can scan known input files automatically for dependency information (for example, #include statements in C or C++ files) and will rebuild dependent files appropriately whenever any "included" input file changes. scons supports the ability to define new scanners for unknown input file types.
scons knows how to fetch files automatically from SCCS or RCS subdirectories using SCCS, RCS or BitKeeper.
scons is normally executed in a top-level directory containing a SConstruct file, optionally specifying as command-line arguments the target file or files to be built.
By default, the command
scons
will build all target files in or below the current directory. Explicit default targets (to be built when no targets are specified on the command line) may be defined the SConscript file(s) using the Default() function, described below.
Even when Default() targets are specified in the SConscript file(s), all target files in or below the current directory may be built by explicitly specifying the current directory (.) as a command-line target:
scons .
Building all target files, including any files outside of the current directory, may be specified by supplying a command-line target of the root directory (on POSIX systems):
scons /
or the path name(s) of the volume(s) in which all the targets should be built (on Windows systems):
scons C:\ D:\
To build only specific targets, supply them as command-line arguments:
scons foo bar
in which case only the specified targets will be built (along with any derived files on which they depend).
Specifying "cleanup" targets in SConscript files is not usually necessary.
The
-c
flag removes all files
necessary to build the specified target:
scons -c .
to remove all target files, or:
scons -c build export
to remove target files under build and export.
Additional files or directories to remove can be specified using the
Clean()
function.
Conversely, targets that would normally be removed by the
-c
invocation
can be prevented from being removed by using the
NoClean()
function.
A subset of a hierarchical tree may be built by remaining at the top-level directory (where the SConstruct file lives) and specifying the subdirectory as the target to be built:
scons src/subdir
or by changing directory and invoking scons with the
-u
option, which traverses up the directory
hierarchy until it finds the
SConstruct
file, and then builds
targets relatively to the current subdirectory:
cd src/subdir scons -u .
scons
supports building multiple targets in parallel via a
-j
option that takes, as its argument, the number
of simultaneous tasks that may be spawned:
scons -j 4
builds four targets in parallel, for example.
scons
can maintain a cache of target (derived) files that can
be shared between multiple builds. When caching is enabled in a
SConscript file, any target files built by
scons
will be copied
to the cache. If an up-to-date target file is found in the cache, it
will be retrieved from the cache instead of being rebuilt locally.
Caching behavior may be disabled and controlled in other ways by the
--cache-force
,
--cache-disable
,
--cache-readonly
,
and
--cache-show
command-line options. The
--random
option is useful to prevent multiple builds
from trying to update the cache simultaneously.
Values of variables to be passed to the SConscript file(s) may be specified on the command line:
scons debug=1 .
These variables are available in SConscript files through the ARGUMENTS dictionary, and can be used in the SConscript file(s) to modify the build in any way:
if ARGUMENTS.get('debug', 0): env = Environment(CCFLAGS = '-g') else: env = Environment()
The command-line variable arguments are also available in the ARGLIST list, indexed by their order on the command line. This allows you to process them in order rather than by name, if necessary. ARGLIST[0] returns a tuple containing (argname, argvalue). A Python exception is thrown if you try to access a list member that does not exist.
scons requires Python version 2.7 or later. There should be no other dependencies or requirements to run scons.
By default, scons knows how to search for available programming tools on various systems. On Windows systems, scons searches in order for the Microsoft Visual C++ tools, the MinGW tool chain, the Intel compiler tools, and the PharLap ETS compiler. On OS/2 systems, scons searches in order for the OS/2 compiler, the GCC tool chain, and the Microsoft Visual C++ tools, On SGI IRIX, IBM AIX, Hewlett Packard HP-UX, and Sun Solaris systems, scons searches for the native compiler tools (MIPSpro, Visual Age, aCC, and Forte tools respectively) and the GCC tool chain. On all other platforms, including POSIX (Linux and UNIX) platforms, scons searches in order for the GCC tool chain, the Microsoft Visual C++ tools, and the Intel compiler tools. You may, of course, override these default values by appropriate configuration of Environment construction variables.
In general, scons supports the same command-line options as GNU make, and many of those supported by cons.
Ignored for compatibility with non-GNU versions of make.
Clean up by removing all target files for which a construction command is specified. Also remove any files or directories associated to the construction command using the Clean() function. Will not remove any targets specified by the NoClean() function.
Print debug information about the CacheDir() derived-file caching to the specified file. If file is - (a hyphen), the debug information are printed to the standard output. The printed messages describe what signature file names are being looked for in, retrieved from, or written to the CacheDir() directory tree.
Disable the derived-file caching specified by CacheDir(). scons will neither retrieve files from the cache nor copy files to the cache.
When using
CacheDir(),
populate a cache by copying any already-existing, up-to-date
derived files to the cache,
in addition to files built by this invocation.
This is useful to populate a new cache with
all the current derived files,
or to add to the cache any derived files
recently built with caching disabled via the
--cache-disable
option.
Use the cache (if enabled) for reading, but do not not update the cache with changed files.
When using CacheDir() and retrieving a derived file from the cache, show the command that would have been executed to build the file, instead of the usual report, "Retrieved `file' from cache." This will produce consistent output for build logs, regardless of whether a target file was rebuilt or retrieved from the cache.
This specifies how the Configure call should use or generate the results of configuration tests. The option should be specified from among the following choices:
scons will use its normal dependency mechanisms to decide if a test must be rebuilt or not. This saves time by not running the same configuration tests every time you invoke scons, but will overlook changes in system header files or external commands (such as compilers) if you don't specify those dependecies explicitly. This is the default behavior.
If this option is specified, all configuration tests will be re-run regardless of whether the cached results are out of date. This can be used to explicitly force the configuration tests to be updated in response to an otherwise unconfigured change in a system header file or compiler.
If this option is specified, no configuration tests will be rerun and all results will be taken from cache. Note that scons will still consider it an error if --config=cache is specified and a necessary test does not yet have any results in the cache.
Change to the specified
directory
before searching for the
SConstruct,
Sconstruct,
or
sconstruct
file, or doing anything
else. Multiple
-C
options are interpreted
relative to the previous one, and the right-most
-C
option wins. (This option is nearly
equivalent to
-f directory/SConstruct
,
except that it will search for
SConstruct,
Sconstruct,
or
sconstruct
in the specified directory.)
Works exactly the same way as the
-u
option except for the way default targets are handled.
When this option is used and no targets are specified on the command line,
all default targets are built, whether or not they are below the current
directory.
Debug the build process. type[,type...] specifies what type of debugging. Multiple types may be specified, separated by commas. The following types are valid:
Print how many objects are created
of the various classes used internally by SCons
before and after reading the SConscript files
and before and after building targets.
This is not supported when SCons is executed with the Python
-O
(optimized) option
or when the SCons modules
have been compiled with optimization
(that is, when executing from
*.pyo
files).
Print a line for each unlink/relink (or copy) of a variant file from its source file. Includes debugging info for unlinking stale variant files, as well as unlinking old targets before building them.
A synonym for the newer
--tree=derived
option.
This will be deprecated in some future release
and ultimately removed.
Print an explanation of precisely why scons is deciding to (re-)build any targets. (Note: this does not print anything for targets that are not rebuilt.)
Instruct the scanner that searches for libraries to print a message about each potential library name it is searching for, and about the actual libraries it finds.
Print the include tree after each top-level target is built. This is generally used to find out what files are included by the sources of a given derived file:
$ scons --debug=includes foo.o
Prints a summary of hits and misses using the Memoizer, an internal subsystem that counts how often SCons uses cached values in memory instead of recomputing them each time they're needed.
Prints how much memory SCons uses before and after reading the SConscript files and before and after building targets.
A deprecated option preserved for backwards compatibility.
Prints a list of the various objects of the various classes used internally by SCons.
Re-run SCons under the control of the pdb Python debugger.
Print a line each time any target (internal or external) is prepared for building. scons prints this for each target it considers, even if that target is up to date (see also --debug=explain). This can help debug problems with targets that aren't being built; it shows whether scons is at least considering them or not.
Print the raw command line used to build each target before the construction environment variables are substituted. Also shows which targets are being built by this command. Output looks something like this:
$ scons --debug=presub Building myprog.o with action(s): $SHCC $SHCFLAGS $SHCCFLAGS $CPPFLAGS $_CPPINCFLAGS -c -o $TARGET $SOURCES ...
Prints an internal Python stack trace when encountering an otherwise unexplained error.
A synonym for the newer
--tree=all,status
option.
This will be deprecated in some future release
and ultimately removed.
Prints various time profiling information:
the time spent executing each individual build command;
the total build time (time SCons ran from beginning to end);
the total time spent reading and executing SConscript files;
the total time spent SCons itself spend running
(that is, not counting reading and executing SConscript files);
and both the total time spent executing all build commands
and the elapsed wall-clock time spent executing those build commands.
(When
scons
is executed without the
-j
option,
the elapsed wall-clock time will typically
be slightly longer than the total time spent
executing all the build commands,
due to the SCons processing that takes place
in between executing each command.
When
scons
is executed
with
the
-j
option,
and your build configuration allows good parallelization,
the elapsed wall-clock time should
be significantly smaller than the
total time spent executing all the build commands,
since multiple build commands and
intervening SCons processing
should take place in parallel.)
A synonym for the newer
--tree=all
option.
This will be deprecated in some future release
and ultimately removed.
Enable specific checks for
whether or not there is a file on disk
where the SCons configuration expects a directory
(or vice versa),
and whether or not RCS or SCCS sources exist
when searching for source and include files.
The
types
argument can be set to:
all,
to enable all checks explicitly
(the default behavior);
none,
to disable all such checks;
match,
to check that files and directories on disk
match SCons' expected configuration;
rcs,
to check for the existence of an RCS source
for any missing source or include files;
sccs,
to check for the existence of an SCCS source
for any missing source or include files.
Multiple checks can be specified separated by commas;
for example,
--diskcheck=sccs,rcs
would still check for SCCS and RCS sources,
but disable the check for on-disk matches of files and directories.
Disabling some or all of these checks
can provide a performance boost for large configurations,
or when the configuration will check for files and/or directories
across networked or shared file systems,
at the slight increased risk of an incorrect build
or of not handling errors gracefully
(if include files really should be
found in SCCS or RCS, for example,
or if a file really does exist
where the SCons configuration expects a directory).
There are three ways to duplicate files in a build tree: hard links, soft (symbolic) links and copies. The default behaviour of SCons is to prefer hard links to soft links to copies. You can specify different behaviours with this option. ORDER must be one of hard-soft-copy (the default), soft-hard-copy, hard-copy, soft-copy or copy. SCons will attempt to duplicate files using the mechanisms in the specified order.
Use
file
as the initial SConscript file.
Multiple
-f
options may be specified,
in which case
scons
will read all of the specified files.
Print a local help message for this build, if one is defined in
the SConscript file(s), plus a line that describes the
-H
option for command-line option help. If no local help message
is defined, prints the standard help message about command-line
options. Exits after displaying the appropriate message.
Print the standard help message about command-line options and exit.
Ignore all errors from commands executed to rebuild files.
Specifies a
directory
to search for
imported Python modules. If several
-I
options
are used, the directories are searched in the order specified.
Cache implicit dependencies. This causes scons to use the implicit (scanned) dependencies from the last time it was run instead of scanning the files for implicit dependencies. This can significantly speed up SCons, but with the following limitations:
scons will not detect changes to implicit dependency search paths (e.g. CPPPATH, LIBPATH) that would ordinarily cause different versions of same-named files to be used.
scons will miss changes in the implicit dependencies in cases where a new implicit dependency is added earlier in the implicit dependency search path (e.g. CPPPATH, LIBPATH) than a current implicit dependency with the same name.
Forces SCons to ignore the cached implicit dependencies. This causes the
implicit dependencies to be rescanned and recached. This implies
--implicit-cache
.
Force SCons to ignore changes in the implicit dependencies.
This causes cached implicit dependencies to always be used.
This implies
--implicit-cache
.
Starts SCons in interactive mode. The SConscript files are read once and a scons>>> prompt is printed. Targets may now be rebuilt by typing commands at interactive prompt without having to re-read the SConscript files and re-initialize the dependency graph from scratch.
SCons interactive mode supports the following commands:
- build[OPTIONS] [TARGETS] ...
Builds the specified TARGETS (and their dependencies) with the specified SCons command-line OPTIONS. b and scons are synonyms.
The following SCons command-line options affect the build command:
--cache-debug=FILE --cache-disable, --no-cache --cache-force, --cache-populate --cache-readonly --cache-show --debug=TYPE -i, --ignore-errors -j N, --jobs=N -k, --keep-going -n, --no-exec, --just-print, --dry-run, --recon -Q -s, --silent, --quiet --taskmastertrace=FILE --tree=OPTIONSAny other SCons command-line options that are specified do not cause errors but have no effect on the build command (mainly because they affect how the SConscript files are read, which only happens once at the beginning of interactive mode).
- clean[OPTIONS] [TARGETS] ...
Cleans the specified TARGETS (and their dependencies) with the specified options. c is a synonym. This command is itself a synonym for
build --clean
- exit
Exits SCons interactive mode. You can also exit by terminating input (CTRL+D on UNIX or Linux systems, CTRL+Z on Windows systems).
- help[COMMAND]
Provides a help message about the commands available in SCons interactive mode. If COMMAND is specified, h and ? are synonyms.
- shell[COMMANDLINE]
Executes the specified COMMANDLINE in a subshell. If no COMMANDLINE is specified, executes the interactive command interpreter specified in the
SHELL
environment variable (on UNIX and Linux systems) or the COMSPEC environment variable (on Windows systems). sh and ! are synonyms.- version
Prints SCons version information.
An empty line repeats the last typed command. Command-line editing can be used if the readline module is available.
$ scons --interactive scons: Reading SConscript files ... scons: done reading SConscript files. scons>>> build -n prog scons>>> exit
Specifies the number of jobs (commands) to run simultaneously.
If there is more than one
-j
option, the last one is effective.
Continue as much as possible after an error. The target that failed and those that depend on it will not be remade, but other targets specified on the command line will still be processed.
Ignored for compatibility with non-GNU versions of make.
Set the maximum expected drift in the modification time of files to SECONDS. This value determines how long a file must be unmodified before its cached content signature will be used instead of calculating a new content signature (MD5 checksum) of the file's contents. The default value is 2 days, which means a file must have a modification time of at least two days ago in order to have its cached content signature used. A negative value means to never cache the content signature and to ignore the cached value if there already is one. A value of 0 means to always use the cached signature, no matter how old the file is.
Set the block size used to compute MD5 signatures to KILOBYTES. This value determines the size of the chunks which are read in at once when computing MD5 signatures. Files below that size are fully stored in memory before performing the signature computation while bigger files are read in block-by-block. A huge block-size leads to high memory consumption while a very small block-size slows down the build considerably.
The default value is to use a chunk size of 64 kilobytes, which should be appropriate for most uses.
No execute. Print the commands that would be executed to build any out-of-date target files, but do not execute the commands.
Prevents the automatic addition of the standard site_scons dirs to sys.path. Also prevents loading the site_scons/site_init.py modules if they exist, and prevents adding their site_scons/site_tools dirs to the toolpath.
Run SCons under the Python profiler and save the results in the specified file. The results may be analyzed using the Python pstats module.
Do not run any commands, or print anything. Just return an exit status that is zero if the specified targets are already up to date, non-zero otherwise.
Quiets SCons status messages about reading SConscript files, building targets and entering directories. Commands that are executed to rebuild target files are still printed.
Build dependencies in a random order. This is useful when building multiple trees simultaneously with caching enabled, to prevent multiple builds from simultaneously trying to build or retrieve the same target files.
Silent. Do not print commands that are executed to rebuild target files. Also suppresses SCons status messages.
Ignored for compatibility with GNU make.
Uses the named dir as the site dir rather than the default site_scons dirs. This dir will get prepended to sys.path, the module dir/site_init.py will get loaded if it exists, and dir/site_tools will get added to the default toolpath.
The default set of
site_scons
dirs used when
--site-dir
is not specified depends on the system platform, as follows. Note
that the directories are examined in the order given, from most
generic to most specific, so the last-executed site_init.py file is
the most specific one (which gives it the chance to override
everything else), and the dirs are prepended to the paths, again so
the last dir examined comes first in the resulting path.
%ALLUSERSPROFILE/Application Data/scons/site_scons %USERPROFILE%/Local Settings/Application Data/scons/site_scons %APPDATA%/scons/site_scons %HOME%/.scons/site_scons ./site_scons
/Library/Application Support/SCons/site_scons /opt/local/share/scons/site_scons (for MacPorts) /sw/share/scons/site_scons (for Fink) $HOME/Library/Application Support/SCons/site_scons $HOME/.scons/site_scons ./site_scons
/opt/sfw/scons/site_scons /usr/share/scons/site_scons $HOME/.scons/site_scons ./site_scons
/usr/share/scons/site_scons $HOME/.scons/site_scons ./site_scons
Set the size stack used to run threads to KILOBYTES. This value determines the stack size of the threads used to run jobs. These are the threads that execute the actions of the builders for the nodes that are out-of-date. Note that this option has no effect unless the num_jobs option, which corresponds to -j and --jobs, is larger than one. Using a stack size that is too small may cause stack overflow errors. This usually shows up as segmentation faults that cause scons to abort before building anything. Using a stack size that is too large will cause scons to use more memory than required and may slow down the entire build process.
The default value is to use a stack size of 256 kilobytes, which should be appropriate for most uses. You should not need to increase this value unless you encounter stack overflow errors.
Ignored for compatibility with GNU make. (Touching a file to make it appear up-to-date is unnecessary when using scons.)
Prints trace information to the specified file about how the internal Taskmaster object evaluates and controls the order in which Nodes are built. A file name of - may be used to specify the standard output.
Prints a tree of the dependencies after each top-level target is built. This prints out some or all of the tree, in various formats, depending on the options specified:
Print the entire dependency tree after each top-level target is built. This prints out the complete dependency tree, including implicit dependencies and ignored dependencies.
Restricts the tree output to only derived (target) files, not source files.
Prints status information for each displayed node.
Prunes the tree to avoid repeating dependency information for nodes that have already been displayed. Any node that has already been displayed will have its name printed in [square brackets], as an indication that the dependencies for that node can be found by searching for the relevant output higher up in the tree.
Multiple options may be specified, separated by commas:
# Prints only derived files, with status information: scons --tree=derived,status # Prints all dependencies of target, with status information # and pruning dependencies of already-visited Nodes: scons --tree=all,prune,status target
Walks up the directory structure until an SConstruct , Sconstruct or sconstruct file is found, and uses that as the top of the directory tree. If no targets are specified on the command line, only targets at or below the current directory will be built.
Works exactly the same way as the
-u
option except for the way default targets are handled.
When this option is used and no targets are specified on the command line,
all default targets that are defined in the SConscript(s) in the current
directory are built, regardless of what directory the resultant targets end
up in.
Print the scons version, copyright information, list of authors, and any other relevant information. Then exit.
Print a message containing the working directory before and after other processing.
Turn off -w, even if it was turned on implicitly.
Enable or disable warnings. type specifies the type of warnings to be enabled or disabled:
Enables or disables all warnings.
Enables or disables warnings about errors trying to write a copy of a built file to a specified CacheDir(). These warnings are disabled by default.
Enables or disables warnings about unfamiliar signature data in .sconsign files. These warnings are enabled by default.
Enables or disables warnings about dependencies. These warnings are disabled by default.
Enables or disables all warnings about use of
currently deprecated features.
These warnings are enabled by default.
Note that the
--warn=no-deprecated
option does not disable warnings about absolutely all deprecated features.
Warnings for some deprecated features that have already been through
several releases with deprecation warnings
may be mandatory for a release or two
before they are officially no longer supported by SCons.
Warnings for some specific deprecated features
may be enabled or disabled individually;
see below.
- --warn=deprecated-copy, --warn=no-deprecated-copy
Enables or disables warnings about use of the deprecated env.Copy() method.
- --warn=deprecated-source-signatures, --warn=no-deprecated-source-signatures
Enables or disables warnings about use of the deprecated SourceSignatures() function or env.SourceSignatures() method.
- --warn=deprecated-target-signatures, --warn=no-deprecated-target-signatures
Enables or disables warnings about use of the deprecated TargetSignatures() function or env.TargetSignatures() method.
Enables or disables warnings about attempts to specify a build of a target with two different construction environments that use the same action. These warnings are enabled by default.
Enables or disables the specific warning about linking Fortran and C++ object files in a single executable, which can yield unpredictable behavior with some compilers.
Enables or disables warnings about features that will be deprecated in the future. These warnings are disabled by default. Enabling this warning is especially recommended for projects that redistribute SCons configurations for other users to build, so that the project can be warned as soon as possible about to-be-deprecated features that may require changes to the configuration.
Enables or disables warnings about link steps.
Enables or disables warnings about use of the misspelled keywords targets and sources when calling Builders. (Note the last s characters, the correct spellings are target and source.) These warnings are enabled by default.
Enables or disables warnings about missing SConscript files. These warnings are enabled by default.
Enables or disables warnings about the version of Python not having an MD5 checksum module available. These warnings are enabled by default.
Enables or disables warnings about the version of Python
not supporting metaclasses when the
--debug=memoizer
option is used.
These warnings are enabled by default.
Enables or disables warnings about the
--debug=object
feature not working when
scons
is run with the python
-O
option or from optimized Python (.pyo) modules.
Enables or disables warnings about the version of Python
not being able to support parallel builds when the
-j
option is used.
These warnings are enabled by default.
Enables or disables the warning about running SCons with a deprecated version of Python. These warnings are enabled by default.
Enables or disables warnings about attempts to set the reserved construction variable names CHANGED_SOURCES, CHANGED_TARGETS, TARGET, TARGETS, SOURCE, SOURCES, UNCHANGED_SOURCES or UNCHANGED_TARGETS. These warnings are disabled by default.
Enables or disables warnings about requests to set the stack size that could not be honored. These warnings are enabled by default.
Enables or disables warnings about a build rule not building the expected targets. These warnings are not currently enabled by default.
Search the specified repository for any input and target
files not found in the local directory hierarchy. Multiple
-Y
options may be specified, in which case the
repositories are searched in the order specified.
A construction environment is the basic means by which the SConscript files communicate build information to scons. A new construction environment is created using the Environment function:
env = Environment()
Variables, called construction variables, may be set in a construction environment either by specifying them as keywords when the object is created or by assigning them a value after the object is created:
env = Environment(FOO = 'foo') env['BAR'] = 'bar'
As a convenience, construction variables may also be set or modified by the parse_flags keyword argument, which applies the ParseFlags method (described below) to the argument value after all other processing is completed. This is useful either if the exact content of the flags is unknown (for example, read from a control file) or if the flags are distributed to a number of construction variables.
env = Environment(parse_flags = '-Iinclude -DEBUG -lm')
This example adds 'include' to CPPPATH, 'EBUG' to CPPDEFINES, and 'm' to LIBS.
By default, a new construction environment is initialized with a set of builder methods and construction variables that are appropriate for the current platform. An optional platform keyword argument may be used to specify that an environment should be initialized for a different platform:
env = Environment(platform = 'cygwin') env = Environment(platform = 'os2') env = Environment(platform = 'posix') env = Environment(platform = 'win32')
Specifying a platform initializes the appropriate construction variables in the environment to use and generate file names with prefixes and suffixes appropriate for the platform.
Note that the win32 platform adds the SystemDrive and SystemRoot variables from the user's external environment to the construction environment's ENV dictionary. This is so that any executed commands that use sockets to connect with other systems (such as fetching source files from external CVS repository specifications like :pserver:anonymous@cvs.sourceforge.net:/cvsroot/scons) will work on Windows systems.
The platform argument may be function or callable object, in which case the Environment() method will call the specified argument to update the new construction environment:
def my_platform(env): env['VAR'] = 'xyzzy' env = Environment(platform = my_platform)
Additionally, a specific set of tools with which to initialize the environment may be specified as an optional keyword argument:
env = Environment(tools = ['msvc', 'lex'])
Non-built-in tools may be specified using the toolpath argument:
env = Environment(tools = ['default', 'foo'], toolpath = ['tools'])
This looks for a tool specification in tools/foo.py (as well as
using the ordinary default tools for the platform). foo.py should
have two functions: generate(env, **kw) and exists(env).
The
generate()
function
modifies the passed-in environment
to set up variables so that the tool
can be executed;
it may use any keyword arguments
that the user supplies (see below)
to vary its initialization.
The
exists()
function should return a true
value if the tool is available.
Tools in the toolpath are used before
any of the built-in ones. For example, adding gcc.py to the toolpath
would override the built-in gcc tool.
Also note that the toolpath is
stored in the environment for use
by later calls to
Clone()
and
Tool()
methods:
base = Environment(toolpath=['custom_path']) derived = base.Clone(tools=['custom_tool']) derived.CustomBuilder()
The elements of the tools list may also be functions or callable objects, in which case the Environment() method will call the specified elements to update the new construction environment:
def my_tool(env): env['XYZZY'] = 'xyzzy' env = Environment(tools = [my_tool])
The individual elements of the tools list may also themselves be two-element lists of the form (toolname, kw_dict). SCons searches for the toolname specification file as described above, and passes kw_dict, which must be a dictionary, as keyword arguments to the tool's generate function. The generate function can use the arguments to modify the tool's behavior by setting up the environment in different ways or otherwise changing its initialization.
# in tools/my_tool.py: def generate(env, **kw): # Sets MY_TOOL to the value of keyword argument 'arg1' or 1. env['MY_TOOL'] = kw.get('arg1', '1') def exists(env): return 1 # in SConstruct: env = Environment(tools = ['default', ('my_tool', {'arg1': 'abc'})], toolpath=['tools'])
The tool definition (i.e. my_tool()) can use the PLATFORM variable from the environment it receives to customize the tool for different platforms.
If no tool list is specified, then SCons will auto-detect the installed tools using the PATH variable in the ENV construction variable and the platform name when the Environment is constructed. Changing the PATH variable after the Environment is constructed will not cause the tools to be redetected.
SCons supports the following tool specifications out of the box:
Sets construction variables for the 386ASM assembler for the Phar Lap ETS embedded operating system.
Sets: $AS
, $ASCOM
, $ASFLAGS
, $ASPPCOM
, $ASPPFLAGS
.
Uses: $CC
, $CPPFLAGS
, $_CPPDEFFLAGS
, $_CPPINCFLAGS
.
Sets construction variables for the IMB xlc / Visual Age C++ compiler.
Sets: $CXX
, $CXXVERSION
, $SHCXX
, $SHOBJSUFFIX
.
Sets construction variables for the IBM xlc / Visual Age C compiler.
Sets: $CC
, $CCVERSION
, $SHCC
.
Sets construction variables for the IBM Visual Age f77 Fortran compiler.
Sets construction variables for the IBM Visual Age linker.
Sets: $LINKFLAGS
, $SHLIBSUFFIX
, $SHLINKFLAGS
.
Sets construction variables for the Apple linker (similar to the GNU linker).
Sets: $FRAMEWORKPATHPREFIX
, $LDMODULECOM
, $LDMODULEFLAGS
, $LDMODULEPREFIX
, $LDMODULESUFFIX
, $LINKCOM
, $SHLINKCOM
, $SHLINKFLAGS
, $_FRAMEWORKPATH
, $_FRAMEWORKS
.
Uses: $FRAMEWORKSFLAGS
.
Sets construction variables for the ar library archiver.
Sets: $AR
, $ARCOM
, $ARFLAGS
, $LIBPREFIX
, $LIBSUFFIX
, $RANLIB
, $RANLIBCOM
, $RANLIBFLAGS
.
Sets construction variables for the as assembler.
Sets: $AS
, $ASCOM
, $ASFLAGS
, $ASPPCOM
, $ASPPFLAGS
.
Uses: $CC
, $CPPFLAGS
, $_CPPDEFFLAGS
, $_CPPINCFLAGS
.
Sets construction variables for the bcc32 compiler.
Sets: $CC
, $CCCOM
, $CCFLAGS
, $CFILESUFFIX
, $CFLAGS
, $CPPDEFPREFIX
, $CPPDEFSUFFIX
, $INCPREFIX
, $INCSUFFIX
, $SHCC
, $SHCCCOM
, $SHCCFLAGS
, $SHCFLAGS
, $SHOBJSUFFIX
.
Uses: $_CPPDEFFLAGS
, $_CPPINCFLAGS
.
Sets construction variables for the BitKeeper source code control system.
Sets: $BITKEEPER
, $BITKEEPERCOM
, $BITKEEPERGET
, $BITKEEPERGETFLAGS
.
Uses: $BITKEEPERCOMSTR
.
Sets construction variables for generic POSIX C copmilers.
Sets: $CC
, $CCCOM
, $CCFLAGS
, $CFILESUFFIX
, $CFLAGS
, $CPPDEFPREFIX
, $CPPDEFSUFFIX
, $FRAMEWORKPATH
, $FRAMEWORKS
, $INCPREFIX
, $INCSUFFIX
, $SHCC
, $SHCCCOM
, $SHCCFLAGS
, $SHCFLAGS
, $SHOBJSUFFIX
.
Uses: $PLATFORM
.
Sets construction variables for the Compaq Visual Fortran compiler.
Sets: $FORTRAN
, $FORTRANCOM
, $FORTRANMODDIR
, $FORTRANMODDIRPREFIX
, $FORTRANMODDIRSUFFIX
, $FORTRANPPCOM
, $OBJSUFFIX
, $SHFORTRANCOM
, $SHFORTRANPPCOM
.
Uses: $CPPFLAGS
, $FORTRANFLAGS
, $SHFORTRANFLAGS
, $_CPPDEFFLAGS
, $_FORTRANINCFLAGS
, $_FORTRANMODFLAG
.
Sets construction variables for the CVS source code management system.
Sets: $CVS
, $CVSCOFLAGS
, $CVSCOM
, $CVSFLAGS
.
Uses: $CVSCOMSTR
.
Sets construction variables for generic POSIX C++ compilers.
Sets: $CPPDEFPREFIX
, $CPPDEFSUFFIX
, $CXX
, $CXXCOM
, $CXXFILESUFFIX
, $CXXFLAGS
, $INCPREFIX
, $INCSUFFIX
, $OBJSUFFIX
, $SHCXX
, $SHCXXCOM
, $SHCXXFLAGS
, $SHOBJSUFFIX
.
Uses: $CXXCOMSTR
.
Sets variables by calling a default list of Tool modules for the platform on which SCons is running.
Sets construction variables for D language compiler DMD.
Sets: $DC
, $DCOM
, $DDEBUG
, $DDEBUGPREFIX
, $DDEBUGSUFFIX
, $DFILESUFFIX
, $DFLAGPREFIX
, $DFLAGS
, $DFLAGSUFFIX
, $DINCPREFIX
, $DINCSUFFIX
, $DLIB
, $DLIBCOM
, $DLIBDIRPREFIX
, $DLIBDIRSUFFIX
, $DLIBFLAGPREFIX
, $DLIBFLAGSUFFIX
, $DLIBLINKPREFIX
, $DLIBLINKSUFFIX
, $DLINK
, $DLINKCOM
, $DLINKFLAGS
, $DPATH
, $DVERPREFIX
, $DVERSIONS
, $DVERSUFFIX
, $RPATHPREFIX
, $RPATHSUFFIX
, $SHDC
, $SHDCOM
, $SHDLINK
, $SHDLINKCOM
, $SHDLINKFLAGS
, $_DDEBUGFLAGS
, $_DFLAGS
, $_DINCFLAGS
, $_DLIBDIRFLAGS
, $_DLIBFLAGS
, $_DLIBFLAGS
, $_DVERFLAGS
, $_RPATH
.
This tool tries to make working with Docbook in SCons a little easier. It provides several toolchains for creating different output formats, like HTML or PDF. Contained in the package is a distribution of the Docbook XSL stylesheets as of version 1.76.1. As long as you don't specify your own stylesheets for customization, these official versions are picked as default...which should reduce the inevitable setup hassles for you.
Implicit dependencies to images and XIncludes are detected automatically
if you meet the HTML requirements. The additional
stylesheet utils/xmldepend.xsl
by Paul DuBois is used for this purpose.
Note, that there is no support for XML catalog resolving offered! This tool calls the XSLT processors and PDF renderers with the stylesheets you specified, that's it. The rest lies in your hands and you still have to know what you're doing when resolving names via a catalog.
For activating the tool "docbook", you have to add its name to the Environment constructor, like this
env = Environment(tools=['docbook'])
On its startup, the Docbook tool tries to find a required xsltproc
processor, and
a PDF renderer, e.g. fop
. So make sure that these are added to your system's environment
PATH
and can be called directly, without specifying their full path.
For the most basic processing of Docbook to HTML, you need to have installed
the Python lxml
binding to libxml2
, or
the direct Python bindings for libxml2/libxslt
, or
a standalone XSLT processor, currently detected are xsltproc
, saxon
, saxon-xslt
and xalan
.
Rendering to PDF requires you to have one of the applications
fop
or xep
installed.
Creating a HTML or PDF document is very simple and straightforward. Say
env = Environment(tools=['docbook']) env.DocbookHtml('manual.html', 'manual.xml') env.DocbookPdf('manual.pdf', 'manual.xml')
to get both outputs from your XML source manual.xml
. As a shortcut, you can
give the stem of the filenames alone, like this:
env = Environment(tools=['docbook']) env.DocbookHtml('manual') env.DocbookPdf('manual')
and get the same result. Target and source lists are also supported:
env = Environment(tools=['docbook']) env.DocbookHtml(['manual.html','reference.html'], ['manual.xml','reference.xml'])
or even
env = Environment(tools=['docbook']) env.DocbookHtml(['manual','reference'])
Whenever you leave out the list of sources, you may not specify a file extension! The Tool uses the given names as file stems, and adds the suffixes for target and source files accordingly.
The rules given above are valid for the Builders DocbookHtml
,
DocbookPdf
, DocbookEpub
, DocbookSlidesPdf
and DocbookXInclude
. For the
DocbookMan
transformation you
can specify a target name, but the actual output names are automatically
set from the refname
entries in your XML source.
The Builders DocbookHtmlChunked
, DocbookHtmlhelp
and
DocbookSlidesHtml
are special, in that:
they create a large set of files, where the exact names and their number depend on the content of the source file, and
the main target is always named index.html
, i.e. the output name for the
XSL transformation is not picked up by the stylesheets.
As a result, there is simply no use in specifying a target HTML name. So the basic syntax for these builders is always:
env = Environment(tools=['docbook']) env.DocbookHtmlhelp('manual')
If you want to use a specific XSL file, you can set the
additional xsl
parameter to your
Builder call as follows:
env.DocbookHtml('other.html', 'manual.xml', xsl='html.xsl')
Since this may get tedious if you always use the same local naming for your customized XSL files,
e.g. html.xsl
for HTML and pdf.xsl
for PDF output, a set of
variables for setting the default XSL name is provided. These are:
DOCBOOK_DEFAULT_XSL_HTML DOCBOOK_DEFAULT_XSL_HTMLCHUNKED DOCBOOK_DEFAULT_XSL_HTMLHELP DOCBOOK_DEFAULT_XSL_PDF DOCBOOK_DEFAULT_XSL_EPUB DOCBOOK_DEFAULT_XSL_MAN DOCBOOK_DEFAULT_XSL_SLIDESPDF DOCBOOK_DEFAULT_XSL_SLIDESHTML
and you can set them when constructing your environment:
env = Environment(tools=['docbook'], DOCBOOK_DEFAULT_XSL_HTML='html.xsl', DOCBOOK_DEFAULT_XSL_PDF='pdf.xsl') env.DocbookHtml('manual') # now uses html.xsl
Sets: $DOCBOOK_DEFAULT_XSL_EPUB
, $DOCBOOK_DEFAULT_XSL_HTML
, $DOCBOOK_DEFAULT_XSL_HTMLCHUNKED
, $DOCBOOK_DEFAULT_XSL_HTMLHELP
, $DOCBOOK_DEFAULT_XSL_MAN
, $DOCBOOK_DEFAULT_XSL_PDF
, $DOCBOOK_DEFAULT_XSL_SLIDESHTML
, $DOCBOOK_DEFAULT_XSL_SLIDESPDF
, $DOCBOOK_FOP
, $DOCBOOK_FOPCOM
, $DOCBOOK_FOPFLAGS
, $DOCBOOK_XMLLINT
, $DOCBOOK_XMLLINTCOM
, $DOCBOOK_XMLLINTFLAGS
, $DOCBOOK_XSLTPROC
, $DOCBOOK_XSLTPROCCOM
, $DOCBOOK_XSLTPROCFLAGS
, $DOCBOOK_XSLTPROCPARAMS
.
Uses: $DOCBOOK_FOPCOMSTR
, $DOCBOOK_XMLLINTCOMSTR
, $DOCBOOK_XSLTPROCCOMSTR
.
Attaches the DVI
builder to the
construction environment.
Sets construction variables for the dvipdf utility.
Sets: $DVIPDF
, $DVIPDFCOM
, $DVIPDFFLAGS
.
Uses: $DVIPDFCOMSTR
.
Sets construction variables for the dvips utility.
Sets: $DVIPS
, $DVIPSFLAGS
, $PSCOM
, $PSPREFIX
, $PSSUFFIX
.
Uses: $PSCOMSTR
.
Set construction variables for generic POSIX Fortran 03 compilers.
Sets: $F03
, $F03COM
, $F03FLAGS
, $F03PPCOM
, $SHF03
, $SHF03COM
, $SHF03FLAGS
, $SHF03PPCOM
, $_F03INCFLAGS
.
Uses: $F03COMSTR
, $F03PPCOMSTR
, $SHF03COMSTR
, $SHF03PPCOMSTR
.
Set construction variables for generic POSIX Fortran 08 compilers.
Sets: $F08
, $F08COM
, $F08FLAGS
, $F08PPCOM
, $SHF08
, $SHF08COM
, $SHF08FLAGS
, $SHF08PPCOM
, $_F08INCFLAGS
.
Uses: $F08COMSTR
, $F08PPCOMSTR
, $SHF08COMSTR
, $SHF08PPCOMSTR
.
Set construction variables for generic POSIX Fortran 77 compilers.
Sets: $F77
, $F77COM
, $F77FILESUFFIXES
, $F77FLAGS
, $F77PPCOM
, $F77PPFILESUFFIXES
, $FORTRAN
, $FORTRANCOM
, $FORTRANFLAGS
, $SHF77
, $SHF77COM
, $SHF77FLAGS
, $SHF77PPCOM
, $SHFORTRAN
, $SHFORTRANCOM
, $SHFORTRANFLAGS
, $SHFORTRANPPCOM
, $_F77INCFLAGS
.
Uses: $F77COMSTR
, $F77PPCOMSTR
, $FORTRANCOMSTR
, $FORTRANPPCOMSTR
, $SHF77COMSTR
, $SHF77PPCOMSTR
, $SHFORTRANCOMSTR
, $SHFORTRANPPCOMSTR
.
Set construction variables for generic POSIX Fortran 90 compilers.
Sets: $F90
, $F90COM
, $F90FLAGS
, $F90PPCOM
, $SHF90
, $SHF90COM
, $SHF90FLAGS
, $SHF90PPCOM
, $_F90INCFLAGS
.
Uses: $F90COMSTR
, $F90PPCOMSTR
, $SHF90COMSTR
, $SHF90PPCOMSTR
.
Set construction variables for generic POSIX Fortran 95 compilers.
Sets: $F95
, $F95COM
, $F95FLAGS
, $F95PPCOM
, $SHF95
, $SHF95COM
, $SHF95FLAGS
, $SHF95PPCOM
, $_F95INCFLAGS
.
Uses: $F95COMSTR
, $F95PPCOMSTR
, $SHF95COMSTR
, $SHF95PPCOMSTR
.
Set construction variables for generic POSIX Fortran compilers.
Sets: $FORTRAN
, $FORTRANCOM
, $FORTRANFLAGS
, $SHFORTRAN
, $SHFORTRANCOM
, $SHFORTRANFLAGS
, $SHFORTRANPPCOM
.
Uses: $FORTRANCOMSTR
, $FORTRANPPCOMSTR
, $SHFORTRANCOMSTR
, $SHFORTRANPPCOMSTR
.
Set construction variables for the gXX C++ compiler.
Sets: $CXX
, $CXXVERSION
, $SHCXXFLAGS
, $SHOBJSUFFIX
.
Set construction variables for the g77 Fortran compiler.
Calls the f77
Tool module
to set variables.
Sets construction variables for the gas assembler.
Calls the as
module.
Sets: $AS
.
Set construction variables for the gcc C compiler.
Sets: $CC
, $CCVERSION
, $SHCCFLAGS
.
Sets construction variables for the D language compiler GDC.
Sets: $DC
, $DCOM
, $DDEBUG
, $DDEBUGPREFIX
, $DDEBUGSUFFIX
, $DFILESUFFIX
, $DFLAGPREFIX
, $DFLAGS
, $DFLAGSUFFIX
, $DINCPREFIX
, $DINCSUFFIX
, $DLIB
, $DLIBCOM
, $DLIBFLAGPREFIX
, $DLIBFLAGSUFFIX
, $DLINK
, $DLINKCOM
, $DLINKFLAGPREFIX
, $DLINKFLAGS
, $DLINKFLAGSUFFIX
, $DPATH
, $DVERPREFIX
, $DVERSIONS
, $DVERSUFFIX
, $RPATHPREFIX
, $RPATHSUFFIX
, $SHDC
, $SHDCOM
, $SHDLINK
, $SHDLINKCOM
, $SHDLINKFLAGS
, $_DDEBUGFLAGS
, $_DFLAGS
, $_DINCFLAGS
, $_DLIBFLAGS
, $_DVERFLAGS
, $_RPATH
.
This is actually a toolset, which supports internationalization and localization of sofware being constructed with SCons. The toolset loads following tools:
When you enable gettext
, it internally loads all abovementioned tools,
so you're encouraged to see their individual documentation.
Each of the above tools provides its own builder(s) which may be used to
perform particular activities related to software internationalization. You
may be however interested in top-level builder
Translate
described few paragraphs later.
To use gettext
tools add 'gettext'
tool to your
environment:
env = Environment( tools = ['default', 'gettext'] )
Sets construction variables for the GNU F95/F2003 GNU compiler.
Sets: $F77
, $F90
, $F95
, $FORTRAN
, $SHF77
, $SHF77FLAGS
, $SHF90
, $SHF90FLAGS
, $SHF95
, $SHF95FLAGS
, $SHFORTRAN
, $SHFORTRANFLAGS
.
Set construction variables for GNU linker/loader.
Sets: $RPATHPREFIX
, $RPATHSUFFIX
, $SHLINKFLAGS
.
This Tool sets the required construction variables for working with
the Ghostscript command. It also registers an appropriate Action
with the PDF Builder (PDF
), such that the conversion from
PS/EPS to PDF happens automatically for the TeX/LaTeX toolchain.
Finally, it adds an explicit Ghostscript Builder (Gs
) to the
environment.
Uses: $GSCOMSTR
.
Set construction variables for the compilers aCC on HP/UX systems.
Set construction variables for the
aCC on HP/UX systems.
Calls the cXX
tool for additional variables.
Sets: $CXX
, $CXXVERSION
, $SHCXXFLAGS
.
Sets construction variables for the linker on HP/UX systems.
Sets: $LINKFLAGS
, $SHLIBSUFFIX
, $SHLINKFLAGS
.
Sets construction variables for the icc compiler on OS/2 systems.
Sets: $CC
, $CCCOM
, $CFILESUFFIX
, $CPPDEFPREFIX
, $CPPDEFSUFFIX
, $CXXCOM
, $CXXFILESUFFIX
, $INCPREFIX
, $INCSUFFIX
.
Uses: $CCFLAGS
, $CFLAGS
, $CPPFLAGS
, $_CPPDEFFLAGS
, $_CPPINCFLAGS
.
Sets construction variables for the Intel C/C++ compiler.
Calls the intelc
Tool module to set its variables.
Sets construction variables for the Intel Fortran compiler.
Sets: $FORTRAN
, $FORTRANCOM
, $FORTRANPPCOM
, $SHFORTRANCOM
, $SHFORTRANPPCOM
.
Uses: $CPPFLAGS
, $FORTRANFLAGS
, $_CPPDEFFLAGS
, $_FORTRANINCFLAGS
.
Sets construction variables for newer versions of the Intel Fortran compiler for Linux.
Sets: $F77
, $F90
, $F95
, $FORTRAN
, $SHF77
, $SHF77FLAGS
, $SHF90
, $SHF90FLAGS
, $SHF95
, $SHF95FLAGS
, $SHFORTRAN
, $SHFORTRANFLAGS
.
Sets construction variables for the ilink linker on OS/2 systems.
Sets: $LIBDIRPREFIX
, $LIBDIRSUFFIX
, $LIBLINKPREFIX
, $LIBLINKSUFFIX
, $LINK
, $LINKCOM
, $LINKFLAGS
.
Sets construction variables for the Borland ilink32 linker.
Sets: $LIBDIRPREFIX
, $LIBDIRSUFFIX
, $LIBLINKPREFIX
, $LIBLINKSUFFIX
, $LINK
, $LINKCOM
, $LINKFLAGS
.
Sets construction variables for file and directory installation.
Sets: $INSTALL
, $INSTALLSTR
.
Sets construction variables for the Intel C/C++ compiler
(Linux and Windows, version 7 and later).
Calls the gcc
or msvc
(on Linux and Windows, respectively)
to set underlying variables.
Sets: $AR
, $CC
, $CXX
, $INTEL_C_COMPILER_VERSION
, $LINK
.
Sets construction variables for the jar utility.
Sets: $JAR
, $JARCOM
, $JARFLAGS
, $JARSUFFIX
.
Uses: $JARCOMSTR
.
Sets construction variables for the javac compiler.
Sets: $JAVABOOTCLASSPATH
, $JAVAC
, $JAVACCOM
, $JAVACFLAGS
, $JAVACLASSPATH
, $JAVACLASSSUFFIX
, $JAVASOURCEPATH
, $JAVASUFFIX
.
Uses: $JAVACCOMSTR
.
Sets construction variables for the javah tool.
Sets: $JAVACLASSSUFFIX
, $JAVAH
, $JAVAHCOM
, $JAVAHFLAGS
.
Uses: $JAVACLASSPATH
, $JAVAHCOMSTR
.
Sets construction variables for the latex utility.
Sets: $LATEX
, $LATEXCOM
, $LATEXFLAGS
.
Uses: $LATEXCOMSTR
.
Sets construction variables for the D language compiler LDC2.
Sets: $DC
, $DCOM
, $DDEBUG
, $DDEBUGPREFIX
, $DDEBUGSUFFIX
, $DFILESUFFIX
, $DFLAGPREFIX
, $DFLAGS
, $DFLAGSUFFIX
, $DINCPREFIX
, $DINCSUFFIX
, $DLIB
, $DLIBCOM
, $DLIBDIRPREFIX
, $DLIBDIRSUFFIX
, $DLIBFLAGPREFIX
, $DLIBFLAGSUFFIX
, $DLIBLINKPREFIX
, $DLIBLINKSUFFIX
, $DLINK
, $DLINKCOM
, $DLINKFLAGPREFIX
, $DLINKFLAGS
, $DLINKFLAGSUFFIX
, $DPATH
, $DVERPREFIX
, $DVERSIONS
, $DVERSUFFIX
, $RPATHPREFIX
, $RPATHSUFFIX
, $SHDC
, $SHDCOM
, $SHDLINK
, $SHDLINKCOM
, $SHDLINKFLAGS
, $_DDEBUGFLAGS
, $_DFLAGS
, $_DINCFLAGS
, $_DLIBDIRFLAGS
, $_DLIBFLAGS
, $_DLIBFLAGS
, $_DVERFLAGS
, $_RPATH
.
Sets construction variables for the lex lexical analyser.
Sets: $LEX
, $LEXCOM
, $LEXFLAGS
.
Uses: $LEXCOMSTR
.
Sets construction variables for generic POSIX linkers.
Sets: $LDMODULE
, $LDMODULECOM
, $LDMODULEFLAGS
, $LDMODULEPREFIX
, $LDMODULESUFFIX
, $LIBDIRPREFIX
, $LIBDIRSUFFIX
, $LIBLINKPREFIX
, $LIBLINKSUFFIX
, $LINK
, $LINKCOM
, $LINKFLAGS
, $SHLIBSUFFIX
, $SHLINK
, $SHLINKCOM
, $SHLINKFLAGS
.
Uses: $LDMODULECOMSTR
, $LINKCOMSTR
, $SHLINKCOMSTR
.
Sets construction variables for the LinkLoc linker for the Phar Lap ETS embedded operating system.
Sets: $LIBDIRPREFIX
, $LIBDIRSUFFIX
, $LIBLINKPREFIX
, $LIBLINKSUFFIX
, $LINK
, $LINKCOM
, $LINKFLAGS
, $SHLINK
, $SHLINKCOM
, $SHLINKFLAGS
.
Uses: $LINKCOMSTR
, $SHLINKCOMSTR
.
Sets construction variables for the m4 macro processor.
Uses: $M4COMSTR
.
Sets construction variables for the Microsoft assembler.
Sets: $AS
, $ASCOM
, $ASFLAGS
, $ASPPCOM
, $ASPPFLAGS
.
Uses: $ASCOMSTR
, $ASPPCOMSTR
, $CPPFLAGS
, $_CPPDEFFLAGS
, $_CPPINCFLAGS
.
Sets construction variables for the Microsoft IDL compiler.
Sets: $MIDL
, $MIDLCOM
, $MIDLFLAGS
.
Uses: $MIDLCOMSTR
.
Sets construction variables for MinGW (Minimal Gnu on Windows).
Sets: $AS
, $CC
, $CXX
, $LDMODULECOM
, $LIBPREFIX
, $LIBSUFFIX
, $OBJSUFFIX
, $RC
, $RCCOM
, $RCFLAGS
, $RCINCFLAGS
, $RCINCPREFIX
, $RCINCSUFFIX
, $SHCCFLAGS
, $SHCXXFLAGS
, $SHLINKCOM
, $SHLINKFLAGS
, $SHOBJSUFFIX
, $WINDOWSDEFPREFIX
, $WINDOWSDEFSUFFIX
.
Uses: $RCCOMSTR
, $SHLINKCOMSTR
.
This scons tool is a part of scons gettext
toolset. It provides scons
interface to msgfmt(1) command, which generates binary
message catalog (MO
) from a textual translation description
(PO
).
Sets: $MOSUFFIX
, $MSGFMT
, $MSGFMTCOM
, $MSGFMTCOMSTR
, $MSGFMTFLAGS
, $POSUFFIX
.
Uses: $LINGUAS_FILE
.
This scons tool is a part of scons gettext
toolset. It provides
scons interface to msginit(1) program, which creates new
PO
file, initializing the meta information with values from
user's environment (or options).
Sets: $MSGINIT
, $MSGINITCOM
, $MSGINITCOMSTR
, $MSGINITFLAGS
, $POAUTOINIT
, $POCREATE_ALIAS
, $POSUFFIX
, $POTSUFFIX
, $_MSGINITLOCALE
.
Uses: $LINGUAS_FILE
, $POAUTOINIT
, $POTDOMAIN
.
This scons tool is a part of scons gettext
toolset. It provides
scons interface to msgmerge(1) command, which merges two
Uniform style .po
files together.
Sets: $MSGMERGE
, $MSGMERGECOM
, $MSGMERGECOMSTR
, $MSGMERGEFLAGS
, $POSUFFIX
, $POTSUFFIX
, $POUPDATE_ALIAS
.
Uses: $LINGUAS_FILE
, $POAUTOINIT
, $POTDOMAIN
.
Sets construction variables for the Microsoft mslib library archiver.
Sets: $AR
, $ARCOM
, $ARFLAGS
, $LIBPREFIX
, $LIBSUFFIX
.
Uses: $ARCOMSTR
.
Sets construction variables for the Microsoft linker.
Sets: $LDMODULE
, $LDMODULECOM
, $LDMODULEFLAGS
, $LDMODULEPREFIX
, $LDMODULESUFFIX
, $LIBDIRPREFIX
, $LIBDIRSUFFIX
, $LIBLINKPREFIX
, $LIBLINKSUFFIX
, $LINK
, $LINKCOM
, $LINKFLAGS
, $REGSVR
, $REGSVRCOM
, $REGSVRFLAGS
, $SHLINK
, $SHLINKCOM
, $SHLINKFLAGS
, $WIN32DEFPREFIX
, $WIN32DEFSUFFIX
, $WIN32EXPPREFIX
, $WIN32EXPSUFFIX
, $WINDOWSDEFPREFIX
, $WINDOWSDEFSUFFIX
, $WINDOWSEXPPREFIX
, $WINDOWSEXPSUFFIX
, $WINDOWSPROGMANIFESTPREFIX
, $WINDOWSPROGMANIFESTSUFFIX
, $WINDOWSSHLIBMANIFESTPREFIX
, $WINDOWSSHLIBMANIFESTSUFFIX
, $WINDOWS_INSERT_DEF
.
Uses: $LDMODULECOMSTR
, $LINKCOMSTR
, $REGSVRCOMSTR
, $SHLINKCOMSTR
.
Sets variables for Microsoft Platform SDK and/or Windows SDK.
Note that unlike most other Tool modules,
mssdk does not set construction variables,
but sets the environment variables
in the environment SCons uses to execute
the Microsoft toolchain:
%INCLUDE%
,
%LIB%
,
%LIBPATH%
and
%PATH%
.
Uses: $MSSDK_DIR
, $MSSDK_VERSION
, $MSVS_VERSION
.
Sets construction variables for the Microsoft Visual C/C++ compiler.
Sets: $BUILDERS
, $CC
, $CCCOM
, $CCFLAGS
, $CCPCHFLAGS
, $CCPDBFLAGS
, $CFILESUFFIX
, $CFLAGS
, $CPPDEFPREFIX
, $CPPDEFSUFFIX
, $CXX
, $CXXCOM
, $CXXFILESUFFIX
, $CXXFLAGS
, $INCPREFIX
, $INCSUFFIX
, $OBJPREFIX
, $OBJSUFFIX
, $PCHCOM
, $PCHPDBFLAGS
, $RC
, $RCCOM
, $RCFLAGS
, $SHCC
, $SHCCCOM
, $SHCCFLAGS
, $SHCFLAGS
, $SHCXX
, $SHCXXCOM
, $SHCXXFLAGS
, $SHOBJPREFIX
, $SHOBJSUFFIX
.
Uses: $CCCOMSTR
, $CXXCOMSTR
, $PCH
, $PCHSTOP
, $PDB
, $SHCCCOMSTR
, $SHCXXCOMSTR
.
Sets construction variables for Microsoft Visual Studio.
Sets: $MSVSBUILDCOM
, $MSVSCLEANCOM
, $MSVSENCODING
, $MSVSPROJECTCOM
, $MSVSREBUILDCOM
, $MSVSSCONS
, $MSVSSCONSCOM
, $MSVSSCONSCRIPT
, $MSVSSCONSFLAGS
, $MSVSSOLUTIONCOM
.
Sets construction variables for the Metrowerks CodeWarrior compiler.
Sets: $CC
, $CCCOM
, $CFILESUFFIX
, $CPPDEFPREFIX
, $CPPDEFSUFFIX
, $CXX
, $CXXCOM
, $CXXFILESUFFIX
, $INCPREFIX
, $INCSUFFIX
, $MWCW_VERSION
, $MWCW_VERSIONS
, $SHCC
, $SHCCCOM
, $SHCCFLAGS
, $SHCFLAGS
, $SHCXX
, $SHCXXCOM
, $SHCXXFLAGS
.
Uses: $CCCOMSTR
, $CXXCOMSTR
, $SHCCCOMSTR
, $SHCXXCOMSTR
.
Sets construction variables for the Metrowerks CodeWarrior linker.
Sets: $AR
, $ARCOM
, $LIBDIRPREFIX
, $LIBDIRSUFFIX
, $LIBLINKPREFIX
, $LIBLINKSUFFIX
, $LINK
, $LINKCOM
, $SHLINK
, $SHLINKCOM
, $SHLINKFLAGS
.
Sets construction variables for the nasm Netwide Assembler.
Sets: $AS
, $ASCOM
, $ASFLAGS
, $ASPPCOM
, $ASPPFLAGS
.
Uses: $ASCOMSTR
, $ASPPCOMSTR
.
A framework for building binary and source packages.
Sets construction variables for the Package
Builder.
Sets construction variables for the Portable Document Format builder.
Sets: $PDFPREFIX
, $PDFSUFFIX
.
Sets construction variables for the pdflatex utility.
Sets: $LATEXRETRIES
, $PDFLATEX
, $PDFLATEXCOM
, $PDFLATEXFLAGS
.
Uses: $PDFLATEXCOMSTR
.
Sets construction variables for the pdftex utility.
Sets: $LATEXRETRIES
, $PDFLATEX
, $PDFLATEXCOM
, $PDFLATEXFLAGS
, $PDFTEX
, $PDFTEXCOM
, $PDFTEXFLAGS
.
Uses: $PDFLATEXCOMSTR
, $PDFTEXCOMSTR
.
Sets construction variables for interacting with the Perforce source code management system.
Uses: $P4COMSTR
.
Sets construction variables for building Qt applications.
Sets: $QTDIR
, $QT_AUTOSCAN
, $QT_BINPATH
, $QT_CPPPATH
, $QT_LIB
, $QT_LIBPATH
, $QT_MOC
, $QT_MOCCXXPREFIX
, $QT_MOCCXXSUFFIX
, $QT_MOCFROMCXXCOM
, $QT_MOCFROMCXXFLAGS
, $QT_MOCFROMHCOM
, $QT_MOCFROMHFLAGS
, $QT_MOCHPREFIX
, $QT_MOCHSUFFIX
, $QT_UIC
, $QT_UICCOM
, $QT_UICDECLFLAGS
, $QT_UICDECLPREFIX
, $QT_UICDECLSUFFIX
, $QT_UICIMPLFLAGS
, $QT_UICIMPLPREFIX
, $QT_UICIMPLSUFFIX
, $QT_UISUFFIX
.
Sets construction variables for the interaction with the Revision Control System.
Sets: $RCS
, $RCS_CO
, $RCS_COCOM
, $RCS_COFLAGS
.
Uses: $RCS_COCOMSTR
.
Sets construction variables for the rmic utility.
Sets: $JAVACLASSSUFFIX
, $RMIC
, $RMICCOM
, $RMICFLAGS
.
Uses: $RMICCOMSTR
.
Sets construction variables for building with RPCGEN.
Sets: $RPCGEN
, $RPCGENCLIENTFLAGS
, $RPCGENFLAGS
, $RPCGENHEADERFLAGS
, $RPCGENSERVICEFLAGS
, $RPCGENXDRFLAGS
.
Sets construction variables for interacting with the Source Code Control System.
Sets: $SCCS
, $SCCSCOM
, $SCCSFLAGS
, $SCCSGETFLAGS
.
Uses: $SCCSCOMSTR
.
Sets construction variables for the SGI library archiver.
Sets: $AR
, $ARCOMSTR
, $ARFLAGS
, $LIBPREFIX
, $LIBSUFFIX
, $SHLINK
, $SHLINKFLAGS
.
Uses: $ARCOMSTR
, $SHLINKCOMSTR
.
Sets construction variables for the SGI C++ compiler.
Sets: $CXX
, $CXXFLAGS
, $SHCXX
, $SHOBJSUFFIX
.
Sets construction variables for the SGI C compiler.
Sets: $CXX
, $SHOBJSUFFIX
.
Sets construction variables for the SGI linker.
Sets: $LINK
, $RPATHPREFIX
, $RPATHSUFFIX
, $SHLINKFLAGS
.
Sets construction variables for the Sun library archiver.
Sets: $AR
, $ARCOM
, $ARFLAGS
, $LIBPREFIX
, $LIBSUFFIX
, $SHLINK
, $SHLINKCOM
, $SHLINKFLAGS
.
Uses: $ARCOMSTR
, $SHLINKCOMSTR
.
Sets construction variables for the Sun C++ compiler.
Sets: $CXX
, $CXXVERSION
, $SHCXX
, $SHCXXFLAGS
, $SHOBJPREFIX
, $SHOBJSUFFIX
.
Sets construction variables for the Sun C compiler.
Sets: $CXX
, $SHCCFLAGS
, $SHOBJPREFIX
, $SHOBJSUFFIX
.
Set construction variables for the Sun f77 Fortran compiler.
Sets: $F77
, $FORTRAN
, $SHF77
, $SHF77FLAGS
, $SHFORTRAN
, $SHFORTRANFLAGS
.
Set construction variables for the Sun f90 Fortran compiler.
Sets: $F90
, $FORTRAN
, $SHF90
, $SHF90FLAGS
, $SHFORTRAN
, $SHFORTRANFLAGS
.
Set construction variables for the Sun f95 Fortran compiler.
Sets: $F95
, $FORTRAN
, $SHF95
, $SHF95FLAGS
, $SHFORTRAN
, $SHFORTRANFLAGS
.
Sets construction variables for the Sun linker.
Sets: $RPATHPREFIX
, $RPATHSUFFIX
, $SHLINKFLAGS
.
Sets construction variables for the SWIG interface generator.
Sets: $SWIG
, $SWIGCFILESUFFIX
, $SWIGCOM
, $SWIGCXXFILESUFFIX
, $SWIGDIRECTORSUFFIX
, $SWIGFLAGS
, $SWIGINCPREFIX
, $SWIGINCSUFFIX
, $SWIGPATH
, $SWIGVERSION
, $_SWIGINCFLAGS
.
Uses: $SWIGCOMSTR
.
Sets construction variables for the tar archiver.
Sets: $TAR
, $TARCOM
, $TARFLAGS
, $TARSUFFIX
.
Uses: $TARCOMSTR
.
Sets construction variables for the TeX formatter and typesetter.
Sets: $BIBTEX
, $BIBTEXCOM
, $BIBTEXFLAGS
, $LATEX
, $LATEXCOM
, $LATEXFLAGS
, $MAKEINDEX
, $MAKEINDEXCOM
, $MAKEINDEXFLAGS
, $TEX
, $TEXCOM
, $TEXFLAGS
.
Uses: $BIBTEXCOMSTR
, $LATEXCOMSTR
, $MAKEINDEXCOMSTR
, $TEXCOMSTR
.
Set construction variables for the Textfile
and Substfile
builders.
Sets: $LINESEPARATOR
, $SUBSTFILEPREFIX
, $SUBSTFILESUFFIX
, $TEXTFILEPREFIX
, $TEXTFILESUFFIX
.
Uses: $SUBST_DICT
.
Sets construction variables for the Borlan tib library archiver.
Sets: $AR
, $ARCOM
, $ARFLAGS
, $LIBPREFIX
, $LIBSUFFIX
.
Uses: $ARCOMSTR
.
This scons tool is a part of scons gettext
toolset. It provides
scons interface to xgettext(1)
program, which extracts internationalized messages from source code. The tool
provides POTUpdate
builder to make PO
Template files.
Sets: $POTSUFFIX
, $POTUPDATE_ALIAS
, $XGETTEXTCOM
, $XGETTEXTCOMSTR
, $XGETTEXTFLAGS
, $XGETTEXTFROM
, $XGETTEXTFROMPREFIX
, $XGETTEXTFROMSUFFIX
, $XGETTEXTPATH
, $XGETTEXTPATHPREFIX
, $XGETTEXTPATHSUFFIX
, $_XGETTEXTDOMAIN
, $_XGETTEXTFROMFLAGS
, $_XGETTEXTPATHFLAGS
.
Uses: $POTDOMAIN
.
Sets construction variables for the yacc parse generator.
Sets: $YACC
, $YACCCOM
, $YACCFLAGS
, $YACCHFILESUFFIX
, $YACCHXXFILESUFFIX
, $YACCVCGFILESUFFIX
.
Uses: $YACCCOMSTR
.
Sets construction variables for the zip archiver.
Sets: $ZIP
, $ZIPCOM
, $ZIPCOMPRESSION
, $ZIPFLAGS
, $ZIPSUFFIX
.
Uses: $ZIPCOMSTR
.
Additionally, there is a "tool" named default which configures the environment with a default set of tools for the current platform.
On posix and cygwin platforms the GNU tools (e.g. gcc) are preferred by SCons, on Windows the Microsoft tools (e.g. msvc) followed by MinGW are preferred by SCons, and in OS/2 the IBM tools (e.g. icc) are preferred by SCons.
Build rules are specified by calling a construction environment's builder methods. The arguments to the builder methods are target (a list of targets to be built, usually file names) and source (a list of sources to be built, usually file names).
Because long lists of file names can lead to a lot of quoting, scons supplies a Split() global function and a same-named environment method that split a single string into a list, separated on strings of white-space characters. (These are similar to the split() member function of Python strings but work even if the input isn't a string.)
Like all Python arguments, the target and source arguments to a builder method can be specified either with or without the "target" and "source" keywords. When the keywords are omitted, the target is first, followed by the source. The following are equivalent examples of calling the Program builder method:
env.Program('bar', ['bar.c', 'foo.c']) env.Program('bar', Split('bar.c foo.c')) env.Program('bar', env.Split('bar.c foo.c')) env.Program(source = ['bar.c', 'foo.c'], target = 'bar') env.Program(target = 'bar', Split('bar.c foo.c')) env.Program(target = 'bar', env.Split('bar.c foo.c')) env.Program('bar', source = 'bar.c foo.c'.split())
Target and source file names that are not absolute path names (that is, do not begin with / on POSIX systems or \fR on Windows systems, with or without an optional drive letter) are interpreted relative to the directory containing the SConscript file being read. An initial # (hash mark) on a path name means that the rest of the file name is interpreted relative to the directory containing the top-level SConstruct file, even if the # is followed by a directory separator character (slash or backslash).
Examples:
# The comments describing the targets that will be built # assume these calls are in a SConscript file in the # a subdirectory named "subdir". # Builds the program "subdir/foo" from "subdir/foo.c": env.Program('foo', 'foo.c') # Builds the program "/tmp/bar" from "subdir/bar.c": env.Program('/tmp/bar', 'bar.c') # An initial '#' or '#/' are equivalent; the following # calls build the programs "foo" and "bar" (in the # top-level SConstruct directory) from "subdir/foo.c" and # "subdir/bar.c", respectively: env.Program('#foo', 'foo.c') env.Program('#/bar', 'bar.c') # Builds the program "other/foo" (relative to the top-level # SConstruct directory) from "subdir/foo.c": env.Program('#other/foo', 'foo.c')
When the target shares the same base name as the source and only the suffix varies, and if the builder method has a suffix defined for the target file type, then the target argument may be omitted completely, and scons will deduce the target file name from the source file name. The following examples all build the executable program bar (on POSIX systems) or bar.exe (on Windows systems) from the bar.c source file:
env.Program(target = 'bar', source = 'bar.c') env.Program('bar', source = 'bar.c') env.Program(source = 'bar.c') env.Program('bar.c')
As a convenience, a srcdir keyword argument may be specified when calling a Builder. When specified, all source file strings that are not absolute paths will be interpreted relative to the specified srcdir. The following example will build the build/prog (or build/prog.exe on Windows) program from the files src/f1.c and src/f2.c:
env.Program('build/prog', ['f1.c', 'f2.c'], srcdir='src')
It is possible to override or add construction variables when calling a builder method by passing additional keyword arguments. These overridden or added variables will only be in effect when building the target, so they will not affect other parts of the build. For example, if you want to add additional libraries for just one program:
env.Program('hello', 'hello.c', LIBS=['gl', 'glut'])
or generate a shared library with a non-standard suffix:
env.SharedLibrary('word', 'word.cpp', SHLIBSUFFIX='.ocx', LIBSUFFIXES=['.ocx'])
(Note that both the $SHLIBSUFFIX and $LIBSUFFIXES variables must be set if you want SCons to search automatically for dependencies on the non-standard library names; see the descriptions of these variables, below, for more information.)
It is also possible to use the parse_flags keyword argument in an override:
env = Program('hello', 'hello.c', parse_flags = '-Iinclude -DEBUG -lm')
This example adds 'include' to CPPPATH, 'EBUG' to CPPDEFINES, and 'm' to LIBS.
Although the builder methods defined by scons are, in fact, methods of a construction environment object, they may also be called without an explicit environment:
Program('hello', 'hello.c') SharedLibrary('word', 'word.cpp')
In this case, the methods are called internally using a default construction environment that consists of the tools and values that scons has determined are appropriate for the local system.
Builder methods that can be called without an explicit environment may be called from custom Python modules that you import into an SConscript file by adding the following to the Python module:
from SCons.Script import *
All builder methods return a list-like object containing Nodes that represent the target or targets that will be built. A Node is an internal SCons object which represents build targets or sources.
The returned Node-list object
can be passed to other builder methods as source(s)
or passed to any SCons function or method
where a filename would normally be accepted.
For example, if it were necessary
to add a specific
-D
flag when compiling one specific object file:
bar_obj_list = env.StaticObject('bar.c', CPPDEFINES='-DBAR') env.Program(source = ['foo.c', bar_obj_list, 'main.c'])
Using a Node in this way makes for a more portable build by avoiding having to specify a platform-specific object suffix when calling the Program() builder method.
Note that Builder calls will automatically "flatten" the source and target file lists, so it's all right to have the bar_obj list return by the StaticObject() call in the middle of the source file list. If you need to manipulate a list of lists returned by Builders directly using Python, you can either build the list by hand:
foo = Object('foo.c') bar = Object('bar.c') objects = ['begin.o'] + foo + ['middle.o'] + bar + ['end.o'] for object in objects: print str(object)
Or you can use the Flatten() function supplied by scons to create a list containing just the Nodes, which may be more convenient:
foo = Object('foo.c') bar = Object('bar.c') objects = Flatten(['begin.o', foo, 'middle.o', bar, 'end.o']) for object in objects: print str(object)
Note also that because Builder calls return a list-like object, not an actual Python list, you should not use the Python += operator to append Builder results to a Python list. Because the list and the object are different types, Python will not update the original list in place, but will instead create a new Node-list object containing the concatenation of the list elements and the Builder results. This will cause problems for any other Python variables in your SCons configuration that still hold on to a reference to the original list. Instead, use the Python .extend() method to make sure the list is updated in-place. Example:
object_files = [] # Do NOT use += as follows: # # object_files += Object('bar.c') # # It will not update the object_files list in place. # # Instead, use the .extend() method: object_files.extend(Object('bar.c'))
The path name for a Node's file may be used
by passing the Node to the Python-builtin
str()
function:
bar_obj_list = env.StaticObject('bar.c', CPPDEFINES='-DBAR') print "The path to bar_obj is:", str(bar_obj_list[0])
Note again that because the Builder call returns a list, we have to access the first element in the list (bar_obj_list[0]) to get at the Node that actually represents the object file.
Builder calls support a chdir keyword argument that specifies that the Builder's action(s) should be executed after changing directory. If the chdir argument is a string or a directory Node, scons will change to the specified directory. If the chdir is not a string or Node and is non-zero, then scons will change to the target file's directory.
# scons will change to the "sub" subdirectory # before executing the "cp" command. env.Command('sub/dir/foo.out', 'sub/dir/foo.in', "cp dir/foo.in dir/foo.out", chdir='sub') # Because chdir is not a string, scons will change to the # target's directory ("sub/dir") before executing the # "cp" command. env.Command('sub/dir/foo.out', 'sub/dir/foo.in', "cp foo.in foo.out", chdir=1)
Note that scons will not automatically modify its expansion of construction variables like $TARGET and $SOURCE when using the chdir keyword argument--that is, the expanded file names will still be relative to the top-level SConstruct directory, and consequently incorrect relative to the chdir directory. If you use the chdir keyword argument, you will typically need to supply a different command line using expansions like ${TARGET.file} and ${SOURCE.file} to use just the filename portion of the targets and source.
scons provides the following builder methods:
CFile()
,
env.CFile()
Builds a C source file given a lex (.l
)
or yacc (.y
) input file.
The suffix specified by the $CFILESUFFIX
construction variable
(.c
by default)
is automatically added to the target
if it is not already present.
Example:
# builds foo.c env.CFile(target = 'foo.c', source = 'foo.l') # builds bar.c env.CFile(target = 'bar', source = 'bar.y')
Command()
,
env.Command()
The Command
"Builder" is actually implemented
as a function that looks like a Builder,
but actually takes an additional argument of the action
from which the Builder should be made.
See the Command
function description
for the calling syntax and details.
CXXFile()
,
env.CXXFile()
Builds a C++ source file given a lex (.ll
)
or yacc (.yy
)
input file.
The suffix specified by the $CXXFILESUFFIX
construction variable
(.cc
by default)
is automatically added to the target
if it is not already present.
Example:
# builds foo.cc env.CXXFile(target = 'foo.cc', source = 'foo.ll') # builds bar.cc env.CXXFile(target = 'bar', source = 'bar.yy')
DocbookEpub()
,
env.DocbookEpub()
A pseudo-Builder, providing a Docbook toolchain for EPUB output.
env = Environment(tools=['docbook']) env.DocbookEpub('manual.epub', 'manual.xml')
or simply
env = Environment(tools=['docbook']) env.DocbookEpub('manual')
DocbookHtml()
,
env.DocbookHtml()
A pseudo-Builder, providing a Docbook toolchain for HTML output.
env = Environment(tools=['docbook']) env.DocbookHtml('manual.html', 'manual.xml')
or simply
env = Environment(tools=['docbook']) env.DocbookHtml('manual')
DocbookHtmlChunked()
,
env.DocbookHtmlChunked()
A pseudo-Builder, providing a Docbook toolchain for chunked HTML output.
It supports the base.dir
parameter. The
chunkfast.xsl
file (requires "EXSLT") is used as the
default stylesheet. Basic syntax:
env = Environment(tools=['docbook']) env.DocbookHtmlChunked('manual')
where manual.xml
is the input file.
If you use the root.filename
parameter in your own stylesheets you have to specify the new target name.
This ensures that the dependencies get correct, especially for the cleanup via “scons -c
”:
env = Environment(tools=['docbook']) env.DocbookHtmlChunked('mymanual.html', 'manual', xsl='htmlchunk.xsl')
Some basic support for the base.dir
is provided. You
can add the base_dir
keyword to your Builder
call, and the given prefix gets prepended to all the created filenames:
env = Environment(tools=['docbook']) env.DocbookHtmlChunked('manual', xsl='htmlchunk.xsl', base_dir='output/')
Make sure that you don't forget the trailing slash for the base folder, else your files get renamed only!
DocbookHtmlhelp()
,
env.DocbookHtmlhelp()
A pseudo-Builder, providing a Docbook toolchain for HTMLHELP output. Its basic syntax is:
env = Environment(tools=['docbook']) env.DocbookHtmlhelp('manual')
where manual.xml
is the input file.
If you use the root.filename
parameter in your own stylesheets you have to specify the new target name.
This ensures that the dependencies get correct, especially for the cleanup via “scons -c
”:
env = Environment(tools=['docbook']) env.DocbookHtmlhelp('mymanual.html', 'manual', xsl='htmlhelp.xsl')
Some basic support for the base.dir
parameter
is provided. You can add the base_dir
keyword to
your Builder call, and the given prefix gets prepended to all the
created filenames:
env = Environment(tools=['docbook']) env.DocbookHtmlhelp('manual', xsl='htmlhelp.xsl', base_dir='output/')
Make sure that you don't forget the trailing slash for the base folder, else your files get renamed only!
DocbookMan()
,
env.DocbookMan()
A pseudo-Builder, providing a Docbook toolchain for Man page output. Its basic syntax is:
env = Environment(tools=['docbook']) env.DocbookMan('manual')
where manual.xml
is the input file. Note, that
you can specify a target name, but the actual output names are automatically
set from the refname
entries in your XML source.
DocbookPdf()
,
env.DocbookPdf()
A pseudo-Builder, providing a Docbook toolchain for PDF output.
env = Environment(tools=['docbook']) env.DocbookPdf('manual.pdf', 'manual.xml')
or simply
env = Environment(tools=['docbook']) env.DocbookPdf('manual')
DocbookSlidesHtml()
,
env.DocbookSlidesHtml()
A pseudo-Builder, providing a Docbook toolchain for HTML slides output.
env = Environment(tools=['docbook']) env.DocbookSlidesHtml('manual')
If you use the titlefoil.html
parameter in
your own stylesheets you have to give the new target name. This ensures
that the dependencies get correct, especially for the cleanup via
“scons -c
”:
env = Environment(tools=['docbook']) env.DocbookSlidesHtml('mymanual.html','manual', xsl='slideshtml.xsl')
Some basic support for the base.dir
parameter
is provided. You
can add the base_dir
keyword to your Builder
call, and the given prefix gets prepended to all the created filenames:
env = Environment(tools=['docbook']) env.DocbookSlidesHtml('manual', xsl='slideshtml.xsl', base_dir='output/')
Make sure that you don't forget the trailing slash for the base folder, else your files get renamed only!
DocbookSlidesPdf()
,
env.DocbookSlidesPdf()
A pseudo-Builder, providing a Docbook toolchain for PDF slides output.
env = Environment(tools=['docbook']) env.DocbookSlidesPdf('manual.pdf', 'manual.xml')
or simply
env = Environment(tools=['docbook']) env.DocbookSlidesPdf('manual')
DocbookXInclude()
,
env.DocbookXInclude()
A pseudo-Builder, for resolving XIncludes in a separate processing step.
env = Environment(tools=['docbook']) env.DocbookXInclude('manual_xincluded.xml', 'manual.xml')
DocbookXslt()
,
env.DocbookXslt()
A pseudo-Builder, applying a given XSL transformation to the input file.
env = Environment(tools=['docbook']) env.DocbookXslt('manual_transformed.xml', 'manual.xml', xsl='transform.xslt')
Note, that this builder requires the xsl
parameter
to be set.
DVI()
,
env.DVI()
Builds a .dvi
file
from a .tex
,
.ltx
or .latex
input file.
If the source file suffix is .tex
,
scons
will examine the contents of the file;
if the string
\documentclass
or
\documentstyle
is found, the file is assumed to be a LaTeX file and
the target is built by invoking the $LATEXCOM
command line;
otherwise, the $TEXCOM
command line is used.
If the file is a LaTeX file,
the
DVI
builder method will also examine the contents
of the
.aux
file and invoke the $BIBTEX
command line
if the string
bibdata
is found,
start $MAKEINDEX
to generate an index if a
.ind
file is found
and will examine the contents
.log
file and re-run the $LATEXCOM
command
if the log file says it is necessary.
The suffix .dvi
(hard-coded within TeX itself)
is automatically added to the target
if it is not already present.
Examples:
# builds from aaa.tex env.DVI(target = 'aaa.dvi', source = 'aaa.tex') # builds bbb.dvi env.DVI(target = 'bbb', source = 'bbb.ltx') # builds from ccc.latex env.DVI(target = 'ccc.dvi', source = 'ccc.latex')
Gs()
,
env.Gs()
A Builder for explicitly calling the gs
executable.
Depending on the underlying OS, the different names gs
,
gsos2
and gswin32c
are tried.
env = Environment(tools=['gs']) env.Gs('cover.jpg','scons-scons.pdf', GSFLAGS='-dNOPAUSE -dBATCH -sDEVICE=jpeg -dFirstPage=1 -dLastPage=1 -q') )
Install()
,
env.Install()
Installs one or more source files or directories in the specified target, which must be a directory. The names of the specified source files or directories remain the same within the destination directory. The sources may be given as a string or as a node returned by a builder.
env.Install('/usr/local/bin', source = ['foo', 'bar'])
InstallAs()
,
env.InstallAs()
Installs one or more source files or directories to specific names, allowing changing a file or directory name as part of the installation. It is an error if the target and source arguments list different numbers of files or directories.
env.InstallAs(target = '/usr/local/bin/foo', source = 'foo_debug') env.InstallAs(target = ['../lib/libfoo.a', '../lib/libbar.a'], source = ['libFOO.a', 'libBAR.a'])
InstallVersionedLib()
,
env.InstallVersionedLib()
Installs a versioned shared library. The $SHLIBVERSION
construction variable should be defined in the environment
to confirm the version number in the library name.
If $SHLIBVERSION
is not defined a warning will be issued
and the name of the library will be parsed to derive the version.
The symlinks appropriate to the architecture will be generated.
env.InstallVersionedLib(target = '/usr/local/bin/foo', source = 'libxyz.1.5.2.so') env.InstallVersionedLib(target = '/usr/local/bin/foo', source = 'libxyz.1.5.2.so', SHLIBVERSION='1.5.2')
Jar()
,
env.Jar()
Builds a Java archive (.jar
) file
from the specified list of sources.
Any directories in the source list
will be searched for .class
files).
Any .java
files in the source list
will be compiled to .class
files
by calling the Java
Builder.
If the $JARCHDIR
value is set, the
jar
command will change to the specified directory using the
-C
option.
If $JARCHDIR
is not set explicitly,
SCons will use the top of any subdirectory tree
in which Java .class
were built by the Java
Builder.
If the contents any of the source files begin with the string
Manifest-Version
,
the file is assumed to be a manifest
and is passed to the
jar
command with the
m
option set.
env.Jar(target = 'foo.jar', source = 'classes') env.Jar(target = 'bar.jar', source = ['bar1.java', 'bar2.java'])
Java()
,
env.Java()
Builds one or more Java class files.
The sources may be any combination of explicit
.java
files,
or directory trees which will be scanned
for .java
files.
SCons will parse each source .java
file
to find the classes
(including inner classes)
defined within that file,
and from that figure out the
target .class
files that will be created.
The class files will be placed underneath
the specified target directory.
SCons will also search each Java file
for the Java package name,
which it assumes can be found on a line
beginning with the string
package
in the first column;
the resulting .class
files
will be placed in a directory reflecting
the specified package name.
For example,
the file
Foo.java
defining a single public
Foo
class and
containing a package name of
sub.dir
will generate a corresponding
sub/dir/Foo.class
class file.
Examples:
env.Java(target = 'classes', source = 'src') env.Java(target = 'classes', source = ['src1', 'src2']) env.Java(target = 'classes', source = ['File1.java', 'File2.java'])
Java source files can use the native encoding for the underlying OS.
Since SCons compiles in simple ASCII mode by default,
the compiler will generate warnings about unmappable characters,
which may lead to errors as the file is processed further.
In this case, the user must specify the LANG
environment variable to tell the compiler what encoding is used.
For portibility, it's best if the encoding is hard-coded
so that the compile will work if it is done on a system
with a different encoding.
env = Environment() env['ENV']['LANG'] = 'en_GB.UTF-8'
JavaH()
,
env.JavaH()
Builds C header and source files for
implementing Java native methods.
The target can be either a directory
in which the header files will be written,
or a header file name which
will contain all of the definitions.
The source can be the names of .class
files,
the names of .java
files
to be compiled into .class
files
by calling the Java
builder method,
or the objects returned from the
Java
builder method.
If the construction variable
$JAVACLASSDIR
is set, either in the environment
or in the call to the
JavaH
builder method itself,
then the value of the variable
will be stripped from the
beginning of any .class
file names.
Examples:
# builds java_native.h classes = env.Java(target = 'classdir', source = 'src') env.JavaH(target = 'java_native.h', source = classes) # builds include/package_foo.h and include/package_bar.h env.JavaH(target = 'include', source = ['package/foo.class', 'package/bar.class']) # builds export/foo.h and export/bar.h env.JavaH(target = 'export', source = ['classes/foo.class', 'classes/bar.class'], JAVACLASSDIR = 'classes')
Library()
,
env.Library()
A synonym for the
StaticLibrary
builder method.
LoadableModule()
,
env.LoadableModule()
On most systems,
this is the same as
SharedLibrary
.
On Mac OS X (Darwin) platforms,
this creates a loadable module bundle.
M4()
,
env.M4()
Builds an output file from an M4 input file.
This uses a default $M4FLAGS
value of
-E
,
which considers all warnings to be fatal
and stops on the first warning
when using the GNU version of m4.
Example:
env.M4(target = 'foo.c', source = 'foo.c.m4')
Moc()
,
env.Moc()
Builds an output file from a moc input file. Moc input files are either
header files or cxx files. This builder is only available after using the
tool 'qt'. See the $QTDIR
variable for more information.
Example:
env.Moc('foo.h') # generates moc_foo.cc env.Moc('foo.cpp') # generates foo.moc
MOFiles()
,
env.MOFiles()
This builder belongs to msgfmt
tool. The builder compiles
PO
files to MO
files.
Example 1.
Create pl.mo
and en.mo
by compiling
pl.po
and en.po
:
# ... env.MOFiles(['pl', 'en'])
Example 2.
Compile files for languages defined in LINGUAS
file:
# ... env.MOFiles(LINGUAS_FILE = 1)
Example 3.
Create pl.mo
and en.mo
by compiling
pl.po
and en.po
plus files for
languages defined in LINGUAS
file:
# ... env.MOFiles(['pl', 'en'], LINGUAS_FILE = 1)
Example 4.
Compile files for languages defined in LINGUAS
file
(another version):
# ... env['LINGUAS_FILE'] = 1 env.MOFiles()
MSVSProject()
,
env.MSVSProject()
Builds a Microsoft Visual Studio project file, and by default builds a solution file as well.
This
builds a Visual Studio project file, based on the version of Visual Studio
that is configured (either the latest installed version, or the version
specified by $MSVS_VERSION
in the Environment constructor). For
Visual Studio 6, it will generate a .dsp
file. For Visual
Studio 7 (.NET) and later versions, it will generate a
.vcproj
file.
By default, this also
generates a solution file for the specified project, a
.dsw
file for Visual Studio 6 or a
.sln
file for Visual Studio 7 (.NET). This behavior may
be disabled by specifying auto_build_solution=0
when you
call MSVSProject
, in which case you presumably want to build the solution
file(s) by calling the MSVSSolution
Builder (see below).
The MSVSProject
builder takes several lists of filenames to be placed into
the project file. These are currently limited to srcs
,
incs
, localincs
,
resources
, and misc
. These are pretty
self-explanatory, but it should be noted that these lists are added to the
$SOURCES
construction variable as strings, NOT as SCons File Nodes.
This is because they represent file names to be added to the project file, not
the source files used to build the project file.
The above filename lists are all optional, although at least one must be specified for the resulting project file to be non-empty.
In addition to the above lists of values, the following values may be specified:
The name of the target .dsp
or
.vcproj
file. The correct suffix for the version
of Visual Studio must be used, but the $MSVSPROJECTSUFFIX
construction variable will be defined to the correct value (see
example below).
The name of this particular variant. For Visual Studio 7
projects, this can also be a list of variant names. These are
typically things like "Debug" or "Release", but really can be anything
you want. For Visual Studio 7 projects, they may also specify a target
platform separated from the variant name by a |
(vertical pipe) character: Debug|Xbox
. The default
target platform is Win32. Multiple calls to MSVSProject
with
different variants are allowed; all variants will be added to the
project file with their appropriate build targets and
sources.
Additional command line arguments for the different
variants. The number of cmdargs
entries must match
the number of variant
entries, or be empty (not
specified). If you give only one, it will automatically be propagated
to all variants.
An optional string, node, or list of strings or nodes (one
per build variant), to tell the Visual Studio debugger what output
target to use in what build variant. The number of
buildtarget
entries must match the number of
variant
entries.
The name of the file that Visual Studio 7 and later will
run and debug. This appears as the value of the
Output
field in the resulting Visual Studio project
file. If this is not specified, the default is the same as the
specified buildtarget
value.
Note that because SCons always executes its build
commands from the directory in which the SConstruct
file is located, if you
generate a project file in a different directory than the SConstruct
directory, users will not be able to double-click on the file name in
compilation error messages displayed in the Visual Studio console output
window. This can be remedied by adding the Visual C/C++ /FC
compiler option to the $CCFLAGS
variable so that the compiler will
print the full path name of any files that cause compilation errors.
Example usage:
barsrcs = ['bar.cpp'], barincs = ['bar.h'], barlocalincs = ['StdAfx.h'] barresources = ['bar.rc','resource.h'] barmisc = ['bar_readme.txt'] dll = env.SharedLibrary(target = 'bar.dll', source = barsrcs) env.MSVSProject(target = 'Bar' + env['MSVSPROJECTSUFFIX'], srcs = barsrcs, incs = barincs, localincs = barlocalincs, resources = barresources, misc = barmisc, buildtarget = dll, variant = 'Release')
Starting with version 2.4 of
SCons it's also possible to specify the optional argument
DebugSettings
, which creates files for debugging under
Visual Studio:
A dictionary of debug settings that get written to the
.vcproj.user
or the
.vcxproj.user
file, depending on the version
installed. As it is done for cmdargs (see above), you can specify a
DebugSettings
dictionary per variant. If you
give only one, it will be propagated to all variants.
Currently, only Visual Studio v9.0 and Visual Studio
version v11 are implemented, for other versions no file is generated. To
generate the user file, you just need to add a
DebugSettings
dictionary to the environment with the
right parameters for your MSVS version. If the dictionary is empty, or does
not contain any good value, no file will be generated.
Following is a more contrived example, involving the setup of a project for variants and DebugSettings:
# Assuming you store your defaults in a file vars = Variables('variables.py') msvcver = vars.args.get('vc', '9') # Check command args to force one Microsoft Visual Studio version if msvcver == '9' or msvcver == '11': env = Environment(MSVC_VERSION=msvcver+'.0', MSVC_BATCH=False) else: env = Environment() AddOption('--userfile', action='store_true', dest='userfile', default=False, help="Create Visual Studio Project user file") # # 1. Configure your Debug Setting dictionary with options you want in the list # of allowed options, for instance if you want to create a user file to launch # a specific application for testing your dll with Microsoft Visual Studio 2008 (v9): # V9DebugSettings = { 'Command':'c:\\myapp\\using\\thisdll.exe', 'WorkingDirectory': 'c:\\myapp\\using\\', 'CommandArguments': '-p password', # 'Attach':'false', # 'DebuggerType':'3', # 'Remote':'1', # 'RemoteMachine': None, # 'RemoteCommand': None, # 'HttpUrl': None, # 'PDBPath': None, # 'SQLDebugging': None, # 'Environment': '', # 'EnvironmentMerge':'true', # 'DebuggerFlavor': None, # 'MPIRunCommand': None, # 'MPIRunArguments': None, # 'MPIRunWorkingDirectory': None, # 'ApplicationCommand': None, # 'ApplicationArguments': None, # 'ShimCommand': None, # 'MPIAcceptMode': None, # 'MPIAcceptFilter': None, } # # 2. Because there are a lot of different options depending on the Microsoft # Visual Studio version, if you use more than one version you have to # define a dictionary per version, for instance if you want to create a user # file to launch a specific application for testing your dll with Microsoft # Visual Studio 2012 (v11): # V10DebugSettings = { 'LocalDebuggerCommand': 'c:\\myapp\\using\\thisdll.exe', 'LocalDebuggerWorkingDirectory': 'c:\\myapp\\using\\', 'LocalDebuggerCommandArguments': '-p password', # 'LocalDebuggerEnvironment': None, # 'DebuggerFlavor': 'WindowsLocalDebugger', # 'LocalDebuggerAttach': None, # 'LocalDebuggerDebuggerType': None, # 'LocalDebuggerMergeEnvironment': None, # 'LocalDebuggerSQLDebugging': None, # 'RemoteDebuggerCommand': None, # 'RemoteDebuggerCommandArguments': None, # 'RemoteDebuggerWorkingDirectory': None, # 'RemoteDebuggerServerName': None, # 'RemoteDebuggerConnection': None, # 'RemoteDebuggerDebuggerType': None, # 'RemoteDebuggerAttach': None, # 'RemoteDebuggerSQLDebugging': None, # 'DeploymentDirectory': None, # 'AdditionalFiles': None, # 'RemoteDebuggerDeployDebugCppRuntime': None, # 'WebBrowserDebuggerHttpUrl': None, # 'WebBrowserDebuggerDebuggerType': None, # 'WebServiceDebuggerHttpUrl': None, # 'WebServiceDebuggerDebuggerType': None, # 'WebServiceDebuggerSQLDebugging': None, } # # 3. Select the dictionary you want depending on the version of visual Studio # Files you want to generate. # if not env.GetOption('userfile'): dbgSettings = None elif env.get('MSVC_VERSION', None) == '9.0': dbgSettings = V9DebugSettings elif env.get('MSVC_VERSION', None) == '11.0': dbgSettings = V10DebugSettings else: dbgSettings = None # # 4. Add the dictionary to the DebugSettings keyword. # barsrcs = ['bar.cpp', 'dllmain.cpp', 'stdafx.cpp'] barincs = ['targetver.h'] barlocalincs = ['StdAfx.h'] barresources = ['bar.rc','resource.h'] barmisc = ['ReadMe.txt'] dll = env.SharedLibrary(target = 'bar.dll', source = barsrcs) env.MSVSProject(target = 'Bar' + env['MSVSPROJECTSUFFIX'], srcs = barsrcs, incs = barincs, localincs = barlocalincs, resources = barresources, misc = barmisc, buildtarget = [dll[0]] * 2, variant = ('Debug|Win32', 'Release|Win32'), cmdargs = 'vc=%s' % msvcver, DebugSettings = (dbgSettings, {}))
MSVSSolution()
,
env.MSVSSolution()
Builds a Microsoft Visual Studio solution file.
This builds a Visual Studio solution file, based on the
version of Visual Studio that is configured (either the latest installed
version, or the version specified by $MSVS_VERSION
in the
construction environment). For Visual Studio 6, it will generate a
.dsw
file. For Visual Studio 7 (.NET), it will generate a
.sln
file.
The following values must be specified:
The name of the target .dsw or .sln file. The correct
suffix for the version of Visual Studio must be used, but the value
$MSVSSOLUTIONSUFFIX
will be defined to the correct value (see
example below).
The name of this particular variant, or a list of variant names (the latter is only supported for MSVS 7 solutions). These are typically things like "Debug" or "Release", but really can be anything you want. For MSVS 7 they may also specify target platform, like this "Debug|Xbox". Default platform is Win32.
A list of project file names, or Project nodes returned by
calls to the MSVSProject
Builder, to be placed into the solution
file. It should be noted that these file names are NOT added to the
$SOURCES environment variable in form of files, but rather as strings.
This is because they represent file names to be added to the solution
file, not the source files used to build the solution
file.
Example Usage:
env.MSVSSolution(target = 'Bar' + env['MSVSSOLUTIONSUFFIX'], projects = ['bar' + env['MSVSPROJECTSUFFIX']], variant = 'Release')
Object()
,
env.Object()
A synonym for the
StaticObject
builder method.
Package()
,
env.Package()
Builds a Binary Package of the given source files.
env.Package(source = FindInstalledFiles())
Builds software distribution packages.
Packages consist of files to install and packaging information.
The former may be specified with the source
parameter and may be left out,
in which case the FindInstalledFiles
function will collect
all files that have an Install
or InstallAs
Builder attached.
If the target
is not specified
it will be deduced from additional information given to this Builder.
The packaging information is specified
with the help of construction variables documented below.
This information is called a tag to stress that
some of them can also be attached to files with the Tag
function.
The mandatory ones will complain if they were not specified.
They vary depending on chosen target packager.
The target packager may be selected with the "PACKAGETYPE" command line
option or with the $PACKAGETYPE
construction variable. Currently
the following packagers available:
* msi - Microsoft Installer * rpm - Redhat Package Manger * ipkg - Itsy Package Management System * tarbz2 - compressed tar * targz - compressed tar * zip - zip file * src_tarbz2 - compressed tar source * src_targz - compressed tar source * src_zip - zip file source
An updated list is always available under the "package_type" option when running "scons --help" on a project that has packaging activated.
env = Environment(tools=['default', 'packaging']) env.Install('/bin/', 'my_program') env.Package( NAME = 'foo', VERSION = '1.2.3', PACKAGEVERSION = 0, PACKAGETYPE = 'rpm', LICENSE = 'gpl', SUMMARY = 'balalalalal', DESCRIPTION = 'this should be really really long', X_RPM_GROUP = 'Application/fu', SOURCE_URL = 'http://foo.org/foo-1.2.3.tar.gz' )
PCH()
,
env.PCH()
Builds a Microsoft Visual C++ precompiled header. Calling this builder method returns a list of two targets: the PCH as the first element, and the object file as the second element. Normally the object file is ignored. This builder method is only provided when Microsoft Visual C++ is being used as the compiler. The PCH builder method is generally used in conjuction with the PCH construction variable to force object files to use the precompiled header:
env['PCH'] = env.PCH('StdAfx.cpp')[0]
PDF()
,
env.PDF()
Builds a .pdf
file
from a .dvi
input file
(or, by extension, a .tex
,
.ltx
,
or
.latex
input file).
The suffix specified by the $PDFSUFFIX
construction variable
(.pdf
by default)
is added automatically to the target
if it is not already present. Example:
# builds from aaa.tex env.PDF(target = 'aaa.pdf', source = 'aaa.tex') # builds bbb.pdf from bbb.dvi env.PDF(target = 'bbb', source = 'bbb.dvi')
POInit()
,
env.POInit()
This builder belongs to msginit
tool. The builder initializes missing
PO
file(s) if $POAUTOINIT
is set. If
$POAUTOINIT
is not set (default), POInit
prints instruction for
user (that is supposed to be a translator), telling how the
PO
file should be initialized. In normal projects
you should not use POInit
and use POUpdate
instead. POUpdate
chooses intelligently between
msgmerge(1) and msginit(1). POInit
always uses msginit(1) and should be regarded as builder for
special purposes or for temporary use (e.g. for quick, one time initialization
of a bunch of PO
files) or for tests.
Target nodes defined through POInit
are not built by default (they're
Ignore
d from '.'
node) but are added to
special Alias
('po-create'
by default).
The alias name may be changed through the $POCREATE_ALIAS
construction variable. All PO
files defined through
POInit
may be easily initialized by scons po-create.
Example 1.
Initialize en.po
and pl.po
from
messages.pot
:
# ... env.POInit(['en', 'pl']) # messages.pot --> [en.po, pl.po]
Example 2.
Initialize en.po
and pl.po
from
foo.pot
:
# ... env.POInit(['en', 'pl'], ['foo']) # foo.pot --> [en.po, pl.po]
Example 3.
Initialize en.po
and pl.po
from
foo.pot
but using $POTDOMAIN
construction
variable:
# ... env.POInit(['en', 'pl'], POTDOMAIN='foo') # foo.pot --> [en.po, pl.po]
Example 4.
Initialize PO
files for languages defined in
LINGUAS
file. The files will be initialized from template
messages.pot
:
# ... env.POInit(LINGUAS_FILE = 1) # needs 'LINGUAS' file
Example 5.
Initialize en.po
and pl.pl
PO
files plus files for languages defined in
LINGUAS
file. The files will be initialized from template
messages.pot
:
# ... env.POInit(['en', 'pl'], LINGUAS_FILE = 1)
Example 6.
You may preconfigure your environment first, and then initialize
PO
files:
# ... env['POAUTOINIT'] = 1 env['LINGUAS_FILE'] = 1 env['POTDOMAIN'] = 'foo' env.POInit()
which has same efect as:
# ... env.POInit(POAUTOINIT = 1, LINGUAS_FILE = 1, POTDOMAIN = 'foo')
PostScript()
,
env.PostScript()
Builds a .ps
file
from a .dvi
input file
(or, by extension, a .tex
,
.ltx
,
or
.latex
input file).
The suffix specified by the $PSSUFFIX
construction variable
(.ps
by default)
is added automatically to the target
if it is not already present. Example:
# builds from aaa.tex env.PostScript(target = 'aaa.ps', source = 'aaa.tex') # builds bbb.ps from bbb.dvi env.PostScript(target = 'bbb', source = 'bbb.dvi')
POTUpdate()
,
env.POTUpdate()
The builder belongs to xgettext
tool. The builder updates target
POT
file if exists or creates one if it doesn't. The node is
not built by default (i.e. it is Ignore
d from
'.'
), but only on demand (i.e. when given
POT
file is required or when special alias is invoked). This
builder adds its targe node (messages.pot
, say) to a
special alias (pot-update
by default, see
$POTUPDATE_ALIAS
) so you can update/create them easily with
scons pot-update. The file is not written until there is no
real change in internationalized messages (or in comments that enter
POT
file).
You may see xgettext(1) being invoked by the
xgettext
tool even if there is no real change in internationalized
messages (so the POT
file is not being updated). This
happens every time a source file has changed. In such case we invoke
xgettext(1) and compare its output with the content of
POT
file to decide whether the file should be updated or
not.
Example 1.
Let's create po/
directory and place following
SConstruct
script there:
# SConstruct in 'po/' subdir env = Environment( tools = ['default', 'xgettext'] ) env.POTUpdate(['foo'], ['../a.cpp', '../b.cpp']) env.POTUpdate(['bar'], ['../c.cpp', '../d.cpp'])
Then invoke scons few times:
user@host:$ scons # Does not create foo.pot nor bar.pot user@host:$ scons foo.pot # Updates or creates foo.pot user@host:$ scons pot-update # Updates or creates foo.pot and bar.pot user@host:$ scons -c # Does not clean foo.pot nor bar.pot.
the results shall be as the comments above say.
Example 2.
The POTUpdate
builder may be used with no target specified, in which
case default target messages.pot
will be used. The
default target may also be overriden by setting $POTDOMAIN
construction
variable or providing it as an override to POTUpdate
builder:
# SConstruct script env = Environment( tools = ['default', 'xgettext'] ) env['POTDOMAIN'] = "foo" env.POTUpdate(source = ["a.cpp", "b.cpp"]) # Creates foo.pot ... env.POTUpdate(POTDOMAIN = "bar", source = ["c.cpp", "d.cpp"]) # and bar.pot
Example 3.
The sources may be specified within separate file, for example
POTFILES.in
:
# POTFILES.in in 'po/' subdirectory ../a.cpp ../b.cpp # end of file
The name of the file (POTFILES.in
) containing the list of
sources is provided via $XGETTEXTFROM
:
# SConstruct file in 'po/' subdirectory env = Environment( tools = ['default', 'xgettext'] ) env.POTUpdate(XGETTEXTFROM = 'POTFILES.in')
Example 4.
You may use $XGETTEXTPATH
to define source search path. Assume, for
example, that you have files a.cpp
,
b.cpp
, po/SConstruct
,
po/POTFILES.in
. Then your POT
-related
files could look as below:
# POTFILES.in in 'po/' subdirectory a.cpp b.cpp # end of file
# SConstruct file in 'po/' subdirectory env = Environment( tools = ['default', 'xgettext'] ) env.POTUpdate(XGETTEXTFROM = 'POTFILES.in', XGETTEXTPATH='../')
Example 5.
Multiple search directories may be defined within a list, i.e.
XGETTEXTPATH = ['dir1', 'dir2', ...]
. The order in the list
determines the search order of source files. The path to the first file found
is used.
Let's create 0/1/po/SConstruct
script:
# SConstruct file in '0/1/po/' subdirectory env = Environment( tools = ['default', 'xgettext'] ) env.POTUpdate(XGETTEXTFROM = 'POTFILES.in', XGETTEXTPATH=['../', '../../'])
and 0/1/po/POTFILES.in
:
# POTFILES.in in '0/1/po/' subdirectory a.cpp # end of file
Write two *.cpp
files, the first one is
0/a.cpp
:
/* 0/a.cpp */ gettext("Hello from ../../a.cpp")
and the second is 0/1/a.cpp
:
/* 0/1/a.cpp */ gettext("Hello from ../a.cpp")
then run scons. You'll obtain 0/1/po/messages.pot
with the
message "Hello from ../a.cpp"
. When you reverse order in
$XGETTEXTFOM
, i.e. when you write SConscript as
# SConstruct file in '0/1/po/' subdirectory env = Environment( tools = ['default', 'xgettext'] ) env.POTUpdate(XGETTEXTFROM = 'POTFILES.in', XGETTEXTPATH=['../../', '../'])
then the messages.pot
will contain
msgid "Hello from ../../a.cpp"
line and not
msgid "Hello from ../a.cpp"
.
POUpdate()
,
env.POUpdate()
The builder belongs to msgmerge
tool. The builder updates
PO
files with msgmerge(1), or initializes
missing PO
files as described in documentation of
msginit
tool and POInit
builder (see also
$POAUTOINIT
). Note, that POUpdate
does not add its
targets to po-create
alias as POInit
does.
Target nodes defined through POUpdate
are not built by default
(they're Ignore
d from '.'
node). Instead,
they are added automatically to special Alias
('po-update'
by default). The alias name may be changed
through the $POUPDATE_ALIAS
construction variable. You can easilly
update PO
files in your project by scons
po-update.
Example 1.
Update en.po
and pl.po
from
messages.pot
template (see also $POTDOMAIN
),
assuming that the later one exists or there is rule to build it (see
POTUpdate
):
# ... env.POUpdate(['en','pl']) # messages.pot --> [en.po, pl.po]
Example 2.
Update en.po
and pl.po
from
foo.pot
template:
# ... env.POUpdate(['en', 'pl'], ['foo']) # foo.pot --> [en.po, pl.pl]
Example 3.
Update en.po
and pl.po
from
foo.pot
(another version):
# ... env.POUpdate(['en', 'pl'], POTDOMAIN='foo') # foo.pot -- > [en.po, pl.pl]
Example 4.
Update files for languages defined in LINGUAS
file. The
files are updated from messages.pot
template:
# ... env.POUpdate(LINGUAS_FILE = 1) # needs 'LINGUAS' file
Example 5.
Same as above, but update from foo.pot
template:
# ... env.POUpdate(LINGUAS_FILE = 1, source = ['foo'])
Example 6.
Update en.po
and pl.po
plus files for
languages defined in LINGUAS
file. The files are updated
from messages.pot
template:
# produce 'en.po', 'pl.po' + files defined in 'LINGUAS': env.POUpdate(['en', 'pl' ], LINGUAS_FILE = 1)
Example 7.
Use $POAUTOINIT
to automatically initialize PO
file
if it doesn't exist:
# ... env.POUpdate(LINGUAS_FILE = 1, POAUTOINIT = 1)
Example 8.
Update PO
files for languages defined in
LINGUAS
file. The files are updated from
foo.pot
template. All necessary settings are
pre-configured via environment.
# ... env['POAUTOINIT'] = 1 env['LINGUAS_FILE'] = 1 env['POTDOMAIN'] = 'foo' env.POUpdate()
Program()
,
env.Program()
Builds an executable given one or more object files
or C, C++, D, or Fortran source files.
If any C, C++, D or Fortran source files are specified,
then they will be automatically
compiled to object files using the
Object
builder method;
see that builder method's description for
a list of legal source file suffixes
and how they are interpreted.
The target executable file prefix
(specified by the $PROGPREFIX
construction variable; nothing by default)
and suffix
(specified by the $PROGSUFFIX
construction variable;
by default, .exe
on Windows systems,
nothing on POSIX systems)
are automatically added to the target if not already present.
Example:
env.Program(target = 'foo', source = ['foo.o', 'bar.c', 'baz.f'])
RES()
,
env.RES()
Builds a Microsoft Visual C++ resource file.
This builder method is only provided
when Microsoft Visual C++ or MinGW is being used as the compiler. The
.res
(or
.o
for MinGW) suffix is added to the target name if no other suffix is given.
The source
file is scanned for implicit dependencies as though it were a C file.
Example:
env.RES('resource.rc')
RMIC()
,
env.RMIC()
Builds stub and skeleton class files
for remote objects
from Java .class
files.
The target is a directory
relative to which the stub
and skeleton class files will be written.
The source can be the names of .class
files,
or the objects return from the
Java
builder method.
If the construction variable
$JAVACLASSDIR
is set, either in the environment
or in the call to the
RMIC
builder method itself,
then the value of the variable
will be stripped from the
beginning of any .class
file names.
classes = env.Java(target = 'classdir', source = 'src') env.RMIC(target = 'outdir1', source = classes) env.RMIC(target = 'outdir2', source = ['package/foo.class', 'package/bar.class']) env.RMIC(target = 'outdir3', source = ['classes/foo.class', 'classes/bar.class'], JAVACLASSDIR = 'classes')
RPCGenClient()
,
env.RPCGenClient()
Generates an RPC client stub (_clnt.c
) file
from a specified RPC (.x
) source file.
Because rpcgen only builds output files
in the local directory,
the command will be executed
in the source file's directory by default.
# Builds src/rpcif_clnt.c env.RPCGenClient('src/rpcif.x')
RPCGenHeader()
,
env.RPCGenHeader()
Generates an RPC header (.h
) file
from a specified RPC (.x
) source file.
Because rpcgen only builds output files
in the local directory,
the command will be executed
in the source file's directory by default.
# Builds src/rpcif.h env.RPCGenHeader('src/rpcif.x')
RPCGenService()
,
env.RPCGenService()
Generates an RPC server-skeleton (_svc.c
) file
from a specified RPC (.x
) source file.
Because rpcgen only builds output files
in the local directory,
the command will be executed
in the source file's directory by default.
# Builds src/rpcif_svc.c env.RPCGenClient('src/rpcif.x')
RPCGenXDR()
,
env.RPCGenXDR()
Generates an RPC XDR routine (_xdr.c
) file
from a specified RPC (.x
) source file.
Because rpcgen only builds output files
in the local directory,
the command will be executed
in the source file's directory by default.
# Builds src/rpcif_xdr.c env.RPCGenClient('src/rpcif.x')
SharedLibrary()
,
env.SharedLibrary()
Builds a shared library
(.so
on a POSIX system,
.dll
on Windows)
given one or more object files
or C, C++, D or Fortran source files.
If any source files are given,
then they will be automatically
compiled to object files.
The static library prefix and suffix (if any)
are automatically added to the target.
The target library file prefix
(specified by the $SHLIBPREFIX
construction variable;
by default, lib
on POSIX systems,
nothing on Windows systems)
and suffix
(specified by the $SHLIBSUFFIX
construction variable;
by default, .dll
on Windows systems,
.so
on POSIX systems)
are automatically added to the target if not already present.
Example:
env.SharedLibrary(target = 'bar', source = ['bar.c', 'foo.o'])
On Windows systems, the
SharedLibrary
builder method will always build an import
(.lib
) library
in addition to the shared (.dll
) library,
adding a .lib
library with the same basename
if there is not already a .lib
file explicitly
listed in the targets.
On Cygwin systems, the
SharedLibrary
builder method will always build an import
(.dll.a
) library
in addition to the shared (.dll
) library,
adding a .dll.a
library with the same basename
if there is not already a .dll.a
file explicitly
listed in the targets.
Any object files listed in the
source
must have been built for a shared library
(that is, using the
SharedObject
builder method).
scons
will raise an error if there is any mismatch.
On some platforms, there is a distinction between a shared library
(loaded automatically by the system to resolve external references)
and a loadable module (explicitly loaded by user action).
For maximum portability, use the LoadableModule
builder for the latter.
When the $SHLIBVERSION
construction variable is defined a versioned
shared library is created. This modifies the $SHLINKFLAGS
as required,
adds the version number to the library name, and creates the symlinks that
are needed. $SHLIBVERSION
needs to be of the form X.Y.Z, where X
and Y are numbers, and Z is a number but can also contain letters to designate
alpha, beta, or release candidate patch levels.
env.SharedLibrary(target = 'bar', source = ['bar.c', 'foo.o'], SHLIBVERSION='1.5.2')
This builder may create multiple links to the library. On a POSIX system, for the shared library libbar.so.2.3.1, the links created would be libbar.so and libbar.so.2; on a Darwin (OSX) system the library would be libbar.2.3.1.dylib and the link would be libbar.dylib.
On Windows systems, specifying
register=1
will cause the .dll
to be
registered after it is built using REGSVR32.
The command that is run
("regsvr32" by default) is determined by $REGSVR
construction
variable, and the flags passed are determined by $REGSVRFLAGS
. By
default, $REGSVRFLAGS
includes the /s
option,
to prevent dialogs from popping
up and requiring user attention when it is run. If you change
$REGSVRFLAGS
, be sure to include the /s
option.
For example,
env.SharedLibrary(target = 'bar', source = ['bar.cxx', 'foo.obj'], register=1)
will register bar.dll
as a COM object
when it is done linking it.
SharedObject()
,
env.SharedObject()
Builds an object file for
inclusion in a shared library.
Source files must have one of the same set of extensions
specified above for the
StaticObject
builder method.
On some platforms building a shared object requires additional
compiler option
(e.g. -fPIC
for gcc)
in addition to those needed to build a
normal (static) object, but on some platforms there is no difference between a
shared object and a normal (static) one. When there is a difference, SCons
will only allow shared objects to be linked into a shared library, and will
use a different suffix for shared objects. On platforms where there is no
difference, SCons will allow both normal (static)
and shared objects to be linked into a
shared library, and will use the same suffix for shared and normal
(static) objects.
The target object file prefix
(specified by the $SHOBJPREFIX
construction variable;
by default, the same as $OBJPREFIX
)
and suffix
(specified by the $SHOBJSUFFIX
construction variable)
are automatically added to the target if not already present.
Examples:
env.SharedObject(target = 'ddd', source = 'ddd.c') env.SharedObject(target = 'eee.o', source = 'eee.cpp') env.SharedObject(target = 'fff.obj', source = 'fff.for')
Note that the source files will be scanned
according to the suffix mappings in the
SourceFileScanner
object.
See the section "Scanner Objects,"
below, for more information.
StaticLibrary()
,
env.StaticLibrary()
Builds a static library given one or more object files
or C, C++, D or Fortran source files.
If any source files are given,
then they will be automatically
compiled to object files.
The static library prefix and suffix (if any)
are automatically added to the target.
The target library file prefix
(specified by the $LIBPREFIX
construction variable;
by default, lib
on POSIX systems,
nothing on Windows systems)
and suffix
(specified by the $LIBSUFFIX
construction variable;
by default, .lib
on Windows systems,
.a
on POSIX systems)
are automatically added to the target if not already present.
Example:
env.StaticLibrary(target = 'bar', source = ['bar.c', 'foo.o'])
Any object files listed in the
source
must have been built for a static library
(that is, using the
StaticObject
builder method).
scons
will raise an error if there is any mismatch.
StaticObject()
,
env.StaticObject()
Builds a static object file from one or more C, C++, D, or Fortran source files. Source files must have one of the following extensions:
.asm assembly language file .ASM assembly language file .c C file .C Windows: C file POSIX: C++ file .cc C++ file .cpp C++ file .cxx C++ file .cxx C++ file .c++ C++ file .C++ C++ file .d D file .f Fortran file .F Windows: Fortran file POSIX: Fortran file + C pre-processor .for Fortran file .FOR Fortran file .fpp Fortran file + C pre-processor .FPP Fortran file + C pre-processor .m Object C file .mm Object C++ file .s assembly language file .S Windows: assembly language file ARM: CodeSourcery Sourcery Lite .sx assembly language file + C pre-processor POSIX: assembly language file + C pre-processor .spp assembly language file + C pre-processor .SPP assembly language file + C pre-processor
The target object file prefix
(specified by the $OBJPREFIX
construction variable; nothing by default)
and suffix
(specified by the $OBJSUFFIX
construction variable;
.obj
on Windows systems,
.o
on POSIX systems)
are automatically added to the target if not already present.
Examples:
env.StaticObject(target = 'aaa', source = 'aaa.c') env.StaticObject(target = 'bbb.o', source = 'bbb.c++') env.StaticObject(target = 'ccc.obj', source = 'ccc.f')
Note that the source files will be scanned
according to the suffix mappings in
SourceFileScanner
object.
See the section "Scanner Objects,"
below, for more information.
Substfile()
,
env.Substfile()
The Substfile
builder creates a single text file from another file or set of
files by concatenating them with $LINESEPARATOR
and replacing text
using the $SUBST_DICT
construction variable. Nested lists of source files
are flattened. See also Textfile
.
If a single source file is present with an .in
suffix,
the suffix is stripped and the remainder is used as the default target name.
The prefix and suffix specified by the $SUBSTFILEPREFIX
and $SUBSTFILESUFFIX
construction variables
(the null string by default in both cases)
are automatically added to the target if they are not already present.
If a construction variable named $SUBST_DICT
is present,
it may be either a Python dictionary or a sequence of (key,value) tuples.
If it is a dictionary it is converted into a list of tuples in an arbitrary order,
so if one key is a prefix of another key
or if one substitution could be further expanded by another subsitition,
it is unpredictable whether the expansion will occur.
Any occurrences of a key in the source are replaced by the corresponding value, which may be a Python callable function or a string. If the value is a callable, it is called with no arguments to get a string. Strings are subst-expanded and the result replaces the key.
env = Environment(tools = ['default', 'textfile']) env['prefix'] = '/usr/bin' script_dict = {'@prefix@': '/bin', @exec_prefix@: '$prefix'} env.Substfile('script.in', SUBST_DICT = script_dict) conf_dict = {'%VERSION%': '1.2.3', '%BASE%': 'MyProg'} env.Substfile('config.h.in', conf_dict, SUBST_DICT = conf_dict) # UNPREDICTABLE - one key is a prefix of another bad_foo = {'$foo': '$foo', '$foobar': '$foobar'} env.Substfile('foo.in', SUBST_DICT = bad_foo) # PREDICTABLE - keys are applied longest first good_foo = [('$foobar', '$foobar'), ('$foo', '$foo')] env.Substfile('foo.in', SUBST_DICT = good_foo) # UNPREDICTABLE - one substitution could be futher expanded bad_bar = {'@bar@': '@soap@', '@soap@': 'lye'} env.Substfile('bar.in', SUBST_DICT = bad_bar) # PREDICTABLE - substitutions are expanded in order good_bar = (('@bar@', '@soap@'), ('@soap@', 'lye')) env.Substfile('bar.in', SUBST_DICT = good_bar) # the SUBST_DICT may be in common (and not an override) substutions = {} subst = Environment(tools = ['textfile'], SUBST_DICT = substitutions) substitutions['@foo@'] = 'foo' subst['SUBST_DICT']['@bar@'] = 'bar' subst.Substfile('pgm1.c', [Value('#include "@foo@.h"'), Value('#include "@bar@.h"'), "common.in", "pgm1.in" ]) subst.Substfile('pgm2.c', [Value('#include "@foo@.h"'), Value('#include "@bar@.h"'), "common.in", "pgm2.in" ])
Tar()
,
env.Tar()
Builds a tar archive of the specified files
and/or directories.
Unlike most builder methods,
the
Tar
builder method may be called multiple times
for a given target;
each additional call
adds to the list of entries
that will be built into the archive.
Any source directories will
be scanned for changes to
any on-disk files,
regardless of whether or not
scons
knows about them from other Builder or function calls.
env.Tar('src.tar', 'src') # Create the stuff.tar file. env.Tar('stuff', ['subdir1', 'subdir2']) # Also add "another" to the stuff.tar file. env.Tar('stuff', 'another') # Set TARFLAGS to create a gzip-filtered archive. env = Environment(TARFLAGS = '-c -z') env.Tar('foo.tar.gz', 'foo') # Also set the suffix to .tgz. env = Environment(TARFLAGS = '-c -z', TARSUFFIX = '.tgz') env.Tar('foo')
Textfile()
,
env.Textfile()
The Textfile
builder generates a single text file.
The source strings constitute the lines;
nested lists of sources are flattened.
$LINESEPARATOR
is used to separate the strings.
If present, the $SUBST_DICT
construction variable
is used to modify the strings before they are written;
see the Substfile
description for details.
The prefix and suffix specified by the $TEXTFILEPREFIX
and $TEXTFILESUFFIX
construction variables
(the null string and .txt
by default, respectively)
are automatically added to the target if they are not already present.
Examples:
# builds/writes foo.txt env.Textfile(target = 'foo.txt', source = ['Goethe', 42, 'Schiller']) # builds/writes bar.txt env.Textfile(target = 'bar', source = ['lalala', 'tanteratei'], LINESEPARATOR='|*') # nested lists are flattened automatically env.Textfile(target = 'blob', source = ['lalala', ['Goethe', 42 'Schiller'], 'tanteratei']) # files may be used as input by wraping them in File() env.Textfile(target = 'concat', # concatenate files with a marker between source = [File('concat1'), File('concat2')], LINESEPARATOR = '====================\n') Results are: foo.txt ....8<---- Goethe 42 Schiller ....8<---- (no linefeed at the end) bar.txt: ....8<---- lalala|*tanteratei ....8<---- (no linefeed at the end) blob.txt ....8<---- lalala Goethe 42 Schiller tanteratei ....8<---- (no linefeed at the end)
Translate()
,
env.Translate()
This pseudo-builder belongs to gettext
toolset. The builder extracts
internationalized messages from source files, updates POT
template (if necessary) and then updates PO
translations (if
necessary). If $POAUTOINIT
is set, missing PO
files
will be automatically created (i.e. without translator person intervention).
The variables $LINGUAS_FILE
and $POTDOMAIN
are taken into
acount too. All other construction variables used by POTUpdate
, and
POUpdate
work here too.
Example 1.
The simplest way is to specify input files and output languages inline in
a SCons script when invoking Translate
# SConscript in 'po/' directory env = Environment( tools = ["default", "gettext"] ) env['POAUTOINIT'] = 1 env.Translate(['en','pl'], ['../a.cpp','../b.cpp'])
Example 2.
If you wish, you may also stick to conventional style known from
autotools, i.e. using
POTFILES.in
and LINGUAS
files
# LINGUAS en pl #end
# POTFILES.in a.cpp b.cpp # end
# SConscript env = Environment( tools = ["default", "gettext"] ) env['POAUTOINIT'] = 1 env['XGETTEXTPATH'] = ['../'] env.Translate(LINGUAS_FILE = 1, XGETTEXTFROM = 'POTFILES.in')
The last approach is perhaps the recommended one. It allows easily split
internationalization/localization onto separate SCons scripts, where a script
in source tree is responsible for translations (from sources to
PO
files) and script(s) under variant directories are
responsible for compilation of PO
to MO
files to and for installation of MO
files. The "gluing
factor" synchronizing these two scripts is then the content of
LINGUAS
file. Note, that the updated
POT
and PO
files are usually going to be
committed back to the repository, so they must be updated within the source
directory (and not in variant directories). Additionaly, the file listing of
po/
directory contains LINGUAS
file,
so the source tree looks familiar to translators, and they may work with the
project in their usual way.
Example 3. Let's prepare a development tree as below
project/ + SConstruct + build/ + src/ + po/ + SConscript + SConscript.i18n + POTFILES.in + LINGUAS
with build
being variant directory. Write the top-level
SConstruct
script as follows
# SConstruct env = Environment( tools = ["default", "gettext"] ) VariantDir('build', 'src', duplicate = 0) env['POAUTOINIT'] = 1 SConscript('src/po/SConscript.i18n', exports = 'env') SConscript('build/po/SConscript', exports = 'env')
the src/po/SConscript.i18n
as
# src/po/SConscript.i18n Import('env') env.Translate(LINGUAS_FILE=1, XGETTEXTFROM='POTFILES.in', XGETTEXTPATH=['../'])
and the src/po/SConscript
# src/po/SConscript Import('env') env.MOFiles(LINGUAS_FILE = 1)
Such setup produces POT
and PO
files
under source tree in src/po/
and binary
MO
files under variant tree in
build/po/
. This way the POT
and
PO
files are separated from other output files, which must
not be committed back to source repositories (e.g. MO
files).
In above example, the PO
files are not updated,
nor created automatically when you issue scons '.' command.
The files must be updated (created) by hand via scons
po-update and then MO
files can be compiled by
running scons '.'.
TypeLibrary()
,
env.TypeLibrary()
Builds a Windows type library (.tlb
)
file from an input IDL file (.idl
).
In addition, it will build the associated inteface stub and
proxy source files,
naming them according to the base name of the .idl
file.
For example,
env.TypeLibrary(source="foo.idl")
Will create foo.tlb
,
foo.h
,
foo_i.c
,
foo_p.c
and
foo_data.c
files.
Uic()
,
env.Uic()
Builds a header file, an implementation file and a moc file from an ui file.
and returns the corresponding nodes in the above order.
This builder is only available after using the tool 'qt'. Note: you can
specify .ui
files directly as source
files to the Program
,
Library
and SharedLibrary
builders
without using this builder. Using this builder lets you override the standard
naming conventions (be careful: prefixes are always prepended to names of
built files; if you don't want prefixes, you may set them to ``).
See the $QTDIR
variable for more information.
Example:
env.Uic('foo.ui') # -> ['foo.h', 'uic_foo.cc', 'moc_foo.cc'] env.Uic(target = Split('include/foo.h gen/uicfoo.cc gen/mocfoo.cc'), source = 'foo.ui') # -> ['include/foo.h', 'gen/uicfoo.cc', 'gen/mocfoo.cc']
Zip()
,
env.Zip()
Builds a zip archive of the specified files
and/or directories.
Unlike most builder methods,
the
Zip
builder method may be called multiple times
for a given target;
each additional call
adds to the list of entries
that will be built into the archive.
Any source directories will
be scanned for changes to
any on-disk files,
regardless of whether or not
scons
knows about them from other Builder or function calls.
env.Zip('src.zip', 'src') # Create the stuff.zip file. env.Zip('stuff', ['subdir1', 'subdir2']) # Also add "another" to the stuff.tar file. env.Zip('stuff', 'another')
All targets of builder methods automatically depend on their sources. An explicit dependency can be specified using the Depends method of a construction environment (see below).
In addition, scons automatically scans source files for various programming languages, so the dependencies do not need to be specified explicitly. By default, SCons can C source files, C++ source files, Fortran source files with .F (POSIX systems only), .fpp, or .FPP file extensions, and assembly language files with .S (POSIX systems only), .spp, or .SPP files extensions for C preprocessor dependencies. SCons also has default support for scanning D source files, You can also write your own Scanners to add support for additional source file types. These can be added to the default Scanner object used by the Object(), StaticObject(), and SharedObject() Builders by adding them to the SourceFileScanner object. See the section "Scanner Objects" below, for more information about defining your own Scanner objects and using the SourceFileScanner object.
In addition to Builder methods, scons provides a number of other construction environment methods and global functions to manipulate the build configuration.
Usually, a construction environment method and global function with the same name both exist so that you don't have to remember whether to a specific bit of functionality must be called with or without a construction environment. In the following list, if you call something as a global function it looks like:
Function(arguments)
and if you call something through a construction environment it looks like:
env.Function(arguments)
If you can call the functionality in both ways, then both forms are listed.
Global functions may be called from custom Python modules that you import into an SConscript file by adding the following to the Python module:
from SCons.Script import *
Except where otherwise noted, the same-named construction environment method and global function provide the exact same functionality. The only difference is that, where appropriate, calling the functionality through a construction environment will substitute construction variables into any supplied strings. For example:
env = Environment(FOO = 'foo') Default('$FOO') env.Default('$FOO')
In the above example, the first call to the global Default() function will actually add a target named $FOO to the list of default targets, while the second call to the env.Default() construction environment method will expand the value and add a target named foo to the list of default targets. For more on construction variable expansion, see the next section on construction variables.
Construction environment methods and global functions supported by scons include:
Action(action, [cmd/str/fun, [var, ...]] [option=value, ...])
,
env.Action(action, [cmd/str/fun, [var, ...]] [option=value, ...])
Creates an Action object for
the specified
action
.
See the section "Action Objects,"
below, for a complete explanation of the arguments and behavior.
Note that the
env.Action
()
form of the invocation will expand
construction variables in any argument strings,
including the
action
argument, at the time it is called
using the construction variables in the
env
construction environment through which
env.Action
()
was called.
The
Action
()
form delays all variable expansion
until the Action object is actually used.
AddMethod(object, function, [name])
,
env.AddMethod(function, [name])
When called with the
AddMethod
()
form,
adds the specified
function
to the specified
object
as the specified method
name
.
When called with the
env.AddMethod
()
form,
adds the specified
function
to the construction environment
env
as the specified method
name
.
In both cases, if
name
is omitted or
None
,
the name of the
specified
function
itself is used for the method name.
Examples:
# Note that the first argument to the function to # be attached as a method must be the object through # which the method will be called; the Python # convention is to call it 'self'. def my_method(self, arg): print "my_method() got", arg # Use the global AddMethod() function to add a method # to the Environment class. This AddMethod(Environment, my_method) env = Environment() env.my_method('arg') # Add the function as a method, using the function # name for the method call. env = Environment() env.AddMethod(my_method, 'other_method_name') env.other_method_name('another arg')
AddOption(arguments)
This function adds a new command-line option to be recognized.
The specified
arguments
are the same as supported by the standard Python
optparse.add_option
()
method (with a few additional capabilities noted below);
see the documentation for
optparse
for a thorough discussion of its option-processing capabities.
In addition to the arguments and values supported by the
optparse.add_option
()
method,
the SCons
AddOption
function allows you to set the
nargs
keyword value to
'?'
(a string with just the question mark)
to indicate that the specified long option(s) take(s) an
optional
argument.
When
nargs = '?'
is passed to the
AddOption
function, the
const
keyword argument
may be used to supply the "default"
value that should be used when the
option is specified on the command line
without an explicit argument.
If no
default=
keyword argument is supplied when calling
AddOption
,
the option will have a default value of
None
.
Once a new command-line option has been added with
AddOption
,
the option value may be accessed using
GetOption
or
env.GetOption
().
The value may also be set, using
SetOption
or
env.SetOption
(),
if conditions in a
SConscript
require overriding any default value.
Note, however, that a
value specified on the command line will
always
override a value set by any SConscript file.
Any specified
help=
strings for the new option(s)
will be displayed by the
-H
or
-h
options
(the latter only if no other help text is
specified in the SConscript files).
The help text for the local options specified by
AddOption
will appear below the SCons options themselves,
under a separate
Local Options
heading.
The options will appear in the help text
in the order in which the
AddOption
calls occur.
Example:
AddOption('--prefix', dest='prefix', nargs=1, type='string', action='store', metavar='DIR', help='installation prefix') env = Environment(PREFIX = GetOption('prefix'))
AddPostAction(target, action)
,
env.AddPostAction(target, action)
Arranges for the specified
action
to be performed
after the specified
target
has been built.
The specified action(s) may be
an Action object, or anything that
can be converted into an Action object
(see below).
When multiple targets are supplied, the action may be called multiple times, once after each action that generates one or more targets in the list.
AddPreAction(target, action)
,
env.AddPreAction(target, action)
Arranges for the specified
action
to be performed
before the specified
target
is built.
The specified action(s) may be
an Action object, or anything that
can be converted into an Action object
(see below).
When multiple targets are specified, the action(s) may be called multiple times, once before each action that generates one or more targets in the list.
Note that if any of the targets are built in multiple steps,
the action will be invoked just
before the "final" action that specifically
generates the specified target(s).
For example, when building an executable program
from a specified source
.c
file via an intermediate object file:
foo = Program('foo.c') AddPreAction(foo, 'pre_action')
The specified
pre_action
would be executed before
scons
calls the link command that actually
generates the executable program binary
foo
,
not before compiling the
foo.c
file into an object file.
Alias(alias, [targets, [action]])
,
env.Alias(alias, [targets, [action]])
Creates one or more phony targets that
expand to one or more other targets.
An optional
action
(command)
or list of actions
can be specified that will be executed
whenever the any of the alias targets are out-of-date.
Returns the Node object representing the alias,
which exists outside of any file system.
This Node object, or the alias name,
may be used as a dependency of any other target,
including another alias.
Alias
can be called multiple times for the same
alias to add additional targets to the alias,
or additional actions to the list for this alias.
Examples:
Alias('install') Alias('install', '/usr/bin') Alias(['install', 'install-lib'], '/usr/local/lib') env.Alias('install', ['/usr/local/bin', '/usr/local/lib']) env.Alias('install', ['/usr/local/man']) env.Alias('update', ['file1', 'file2'], "update_database $SOURCES")
AllowSubstExceptions([exception, ...])
Specifies the exceptions that will be allowed
when expanding construction variables.
By default,
any construction variable expansions that generate a
NameError
or
IndexError
exception will expand to a
''
(a null string) and not cause scons to fail.
All exceptions not in the specified list
will generate an error message
and terminate processing.
If
AllowSubstExceptions
is called multiple times,
each call completely overwrites the previous list
of allowed exceptions.
Example:
# Requires that all construction variable names exist. # (You may wish to do this if you want to enforce strictly # that all construction variables must be defined before use.) AllowSubstExceptions() # Also allow a string containing a zero-division expansion # like '${1 / 0}' to evalute to ''. AllowSubstExceptions(IndexError, NameError, ZeroDivisionError)
AlwaysBuild(target, ...)
,
env.AlwaysBuild(target, ...)
Marks each given
target
so that it is always assumed to be out of date,
and will always be rebuilt if needed.
Note, however, that
AlwaysBuild
does not add its target(s) to the default target list,
so the targets will only be built
if they are specified on the command line,
or are a dependent of a target specified on the command line--but
they will
always
be built if so specified.
Multiple targets can be passed in to a single call to
AlwaysBuild
.
env.Append(key=val, [...])
Appends the specified keyword arguments to the end of construction variables in the environment. If the Environment does not have the specified construction variable, it is simply added to the environment. If the values of the construction variable and the keyword argument are the same type, then the two values will be simply added together. Otherwise, the construction variable and the value of the keyword argument are both coerced to lists, and the lists are added together. (See also the Prepend method, below.)
Example:
env.Append(CCFLAGS = ' -g', FOO = ['foo.yyy'])
env.AppendENVPath(name, newpath, [envname, sep, delete_existing])
This appends new path elements to the given path in the
specified external environment
(ENV
by default).
This will only add
any particular path once (leaving the last one it encounters and
ignoring the rest, to preserve path order),
and to help assure this,
will normalize all paths (using
os.path.normpath
and
os.path.normcase
).
This can also handle the
case where the given old path variable is a list instead of a
string, in which case a list will be returned instead of a string.
If
delete_existing
is 0, then adding a path that already exists
will not move it to the end; it will stay where it is in the list.
Example:
print 'before:',env['ENV']['INCLUDE'] include_path = '/foo/bar:/foo' env.AppendENVPath('INCLUDE', include_path) print 'after:',env['ENV']['INCLUDE'] yields: before: /foo:/biz after: /biz:/foo/bar:/foo
env.AppendUnique(key=val, [...], delete_existing=0)
Appends the specified keyword arguments to the end of construction variables in the environment. If the Environment does not have the specified construction variable, it is simply added to the environment. If the construction variable being appended to is a list, then any value(s) that already exist in the construction variable will not be added again to the list. However, if delete_existing is 1, existing matching values are removed first, so existing values in the arg list move to the end of the list.
Example:
env.AppendUnique(CCFLAGS = '-g', FOO = ['foo.yyy'])
env.BitKeeper()
A factory function that
returns a Builder object
to be used to fetch source files
using BitKeeper.
The returned Builder
is intended to be passed to the
SourceCode
function.
This function is deprecated. For details, see the entry for the
SourceCode
function.
Example:
env.SourceCode('.', env.BitKeeper())
BuildDir(build_dir, src_dir, [duplicate])
,
env.BuildDir(build_dir, src_dir, [duplicate])
Deprecated synonyms for
VariantDir
and
env.VariantDir
().
The
build_dir
argument becomes the
variant_dir
argument of
VariantDir
or
env.VariantDir
().
Builder(action, [arguments])
,
env.Builder(action, [arguments])
Creates a Builder object for
the specified
action
.
See the section "Builder Objects,"
below, for a complete explanation of the arguments and behavior.
Note that the
env.Builder
()
form of the invocation will expand
construction variables in any arguments strings,
including the
action
argument,
at the time it is called
using the construction variables in the
env
construction environment through which
env.Builder
()
was called.
The
Builder
form delays all variable expansion
until after the Builder object is actually called.
CacheDir(cache_dir)
,
env.CacheDir(cache_dir)
Specifies that
scons
will maintain a cache of derived files in
cache_dir
.
The derived files in the cache will be shared
among all the builds using the same
CacheDir
call.
Specifying a
cache_dir
of
None
disables derived file caching.
Calling
env.CacheDir
()
will only affect targets built
through the specified construction environment.
Calling
CacheDir
sets a global default
that will be used by all targets built
through construction environments
that do
not
have an
env.CacheDir
()
specified.
When a
CacheDir
()
is being used and
scons
finds a derived file that needs to be rebuilt,
it will first look in the cache to see if a
derived file has already been built
from identical input files and an identical build action
(as incorporated into the MD5 build signature).
If so,
scons
will retrieve the file from the cache.
If the derived file is not present in the cache,
scons
will rebuild it and
then place a copy of the built file in the cache
(identified by its MD5 build signature),
so that it may be retrieved by other
builds that need to build the same derived file
from identical inputs.
Use of a specified
CacheDir
may be disabled for any invocation
by using the
--cache-disable
option.
If the
--cache-force
option is used,
scons
will place a copy of
all
derived files in the cache,
even if they already existed
and were not built by this invocation.
This is useful to populate a cache
the first time
CacheDir
is added to a build,
or after using the
--cache-disable
option.
When using
CacheDir
,
scons
will report,
"Retrieved `file' from cache,"
unless the
--cache-show
option is being used.
When the
--cache-show
option is used,
scons
will print the action that
would
have been used to build the file,
without any indication that
the file was actually retrieved from the cache.
This is useful to generate build logs
that are equivalent regardless of whether
a given derived file has been built in-place
or retrieved from the cache.
The
NoCache
method can be used to disable caching of specific files. This can be
useful if inputs and/or outputs of some tool are impossible to
predict or prohibitively large.
Clean(targets, files_or_dirs)
,
env.Clean(targets, files_or_dirs)
This specifies a list of files or directories which should be removed
whenever the targets are specified with the
-c
command line option.
The specified targets may be a list
or an individual target.
Multiple calls to
Clean
are legal,
and create new targets or add files and directories to the
clean list for the specified targets.
Multiple files or directories should be specified
either as separate arguments to the
Clean
method, or as a list.
Clean
will also accept the return value of any of the construction environment
Builder methods.
Examples:
The related
NoClean
function overrides calling
Clean
for the same target,
and any targets passed to both functions will
not
be removed by the
-c
option.
Examples:
Clean('foo', ['bar', 'baz']) Clean('dist', env.Program('hello', 'hello.c')) Clean(['foo', 'bar'], 'something_else_to_clean')
In this example, installing the project creates a subdirectory for the documentation. This statement causes the subdirectory to be removed if the project is deinstalled.
Clean(docdir, os.path.join(docdir, projectname))
env.Clone([key=val, ...])
Returns a separate copy of a construction environment. If there are any keyword arguments specified, they are added to the returned copy, overwriting any existing values for the keywords.
Example:
env2 = env.Clone() env3 = env.Clone(CCFLAGS = '-g')
Additionally, a list of tools and a toolpath may be specified, as in the Environment constructor:
def MyTool(env): env['FOO'] = 'bar' env4 = env.Clone(tools = ['msvc', MyTool])
The
parse_flags
keyword argument is also recognized:
# create an environment for compiling programs that use wxWidgets wx_env = env.Clone(parse_flags = '!wx-config --cflags --cxxflags')
Command(target, source, action, [key=val, ...])
,
env.Command(target, source, action, [key=val, ...])
Executes a specific action (or list of actions) to build a target file or files. This is more convenient than defining a separate Builder object for a single special-case build.
As a special case, the
source_scanner
keyword argument can
be used to specify
a Scanner object
that will be used to scan the sources.
(The global
DirScanner
object can be used
if any of the sources will be directories
that must be scanned on-disk for
changes to files that aren't
already specified in other Builder of function calls.)
Any other keyword arguments specified override any same-named existing construction variables.
An action can be an external command,
specified as a string,
or a callable Python object;
see "Action Objects," below,
for more complete information.
Also note that a string specifying an external command
may be preceded by an
@
(at-sign)
to suppress printing the command in question,
or by a
-
(hyphen)
to ignore the exit status of the external command.
Examples:
env.Command('foo.out', 'foo.in', "$FOO_BUILD < $SOURCES > $TARGET") env.Command('bar.out', 'bar.in', ["rm -f $TARGET", "$BAR_BUILD < $SOURCES > $TARGET"], ENV = {'PATH' : '/usr/local/bin/'}) def rename(env, target, source): import os os.rename('.tmp', str(target[0])) env.Command('baz.out', 'baz.in', ["$BAZ_BUILD < $SOURCES > .tmp", rename ])
Note that the
Command
function will usually assume, by default,
that the specified targets and/or sources are Files,
if no other part of the configuration
identifies what type of entry it is.
If necessary, you can explicitly specify
that targets or source nodes should
be treated as directoriese
by using the
Dir
or
env.Dir
()
functions.
Examples:
env.Command('ddd.list', Dir('ddd'), 'ls -l $SOURCE > $TARGET') env['DISTDIR'] = 'destination/directory' env.Command(env.Dir('$DISTDIR')), None, make_distdir)
(Also note that SCons will usually automatically create any directory necessary to hold a target file, so you normally don't need to create directories by hand.)
Configure(env, [custom_tests, conf_dir, log_file, config_h])
,
env.Configure([custom_tests, conf_dir, log_file, config_h])
Creates a Configure object for integrated functionality similar to GNU autoconf. See the section "Configure Contexts," below, for a complete explanation of the arguments and behavior.
env.Copy([key=val, ...])
A now-deprecated synonym for
env.Clone
().
env.CVS(repository, module)
A factory function that
returns a Builder object
to be used to fetch source files
from the specified
CVS
repository
.
The returned Builder
is intended to be passed to the
SourceCode
function.
This function is deprecated. For details, see the entry for the
SourceCode
function.
The optional specified
module
will be added to the beginning
of all repository path names;
this can be used, in essence,
to strip initial directory names
from the repository path names,
so that you only have to
replicate part of the repository
directory hierarchy in your
local build directory.
Examples:
# Will fetch foo/bar/src.c # from /usr/local/CVSROOT/foo/bar/src.c. env.SourceCode('.', env.CVS('/usr/local/CVSROOT')) # Will fetch bar/src.c # from /usr/local/CVSROOT/foo/bar/src.c. env.SourceCode('.', env.CVS('/usr/local/CVSROOT', 'foo')) # Will fetch src.c # from /usr/local/CVSROOT/foo/bar/src.c. env.SourceCode('.', env.CVS('/usr/local/CVSROOT', 'foo/bar'))
Decider(function)
,
env.Decider(function)
Specifies that all up-to-date decisions for
targets built through this construction environment
will be handled by the specified
function
.
The
function
can be one of the following strings
that specify the type of decision function
to be performed:
timestamp-newer
Specifies that a target shall be considered out of date and rebuilt
if the dependency's timestamp is newer than the target file's timestamp.
This is the behavior of the classic Make utility,
and
make
can be used a synonym for
timestamp-newer
.
timestamp-match
Specifies that a target shall be considered out of date and rebuilt if the dependency's timestamp is different than the timestamp recorded the last time the target was built. This provides behavior very similar to the classic Make utility (in particular, files are not opened up so that their contents can be checksummed) except that the target will also be rebuilt if a dependency file has been restored to a version with an earlier timestamp, such as can happen when restoring files from backup archives.
MD5
Specifies that a target shall be considered out of date and rebuilt
if the dependency's content has changed sine the last time
the target was built,
as determined be performing an MD5 checksum
on the dependency's contents
and comparing it to the checksum recorded the
last time the target was built.
content
can be used as a synonym for
MD5
.
MD5-timestamp
Specifies that a target shall be considered out of date and rebuilt
if the dependency's content has changed sine the last time
the target was built,
except that dependencies with a timestamp that matches
the last time the target was rebuilt will be
assumed to be up-to-date and
not
rebuilt.
This provides behavior very similar
to the
MD5
behavior of always checksumming file contents,
with an optimization of not checking
the contents of files whose timestamps haven't changed.
The drawback is that SCons will
not
detect if a file's content has changed
but its timestamp is the same,
as might happen in an automated script
that runs a build,
updates a file,
and runs the build again,
all within a single second.
Examples:
# Use exact timestamp matches by default. Decider('timestamp-match') # Use MD5 content signatures for any targets built # with the attached construction environment. env.Decider('content')
In addition to the above already-available functions,
the
function
argument may be an actual Python function
that takes the following three arguments:
dependency
The Node (file) which
should cause the
target
to be rebuilt
if it has "changed" since the last tme
target
was built.
target
The Node (file) being built.
In the normal case,
this is what should get rebuilt
if the
dependency
has "changed."
prev_ni
Stored information about the state of the
dependency
the last time the
target
was built.
This can be consulted to match various
file characteristics
such as the timestamp,
size, or content signature.
The
function
should return a
True
(non-zero)
value if the
dependency
has "changed" since the last time
the
target
was built
(indicating that the target
should
be rebuilt),
and
False
(zero)
otherwise
(indicating that the target should
not
be rebuilt).
Note that the decision can be made
using whatever criteria are appopriate.
Ignoring some or all of the function arguments
is perfectly normal.
Example:
def my_decider(dependency, target, prev_ni): return not os.path.exists(str(target)) env.Decider(my_decider)
Default(targets)
,
env.Default(targets)
This specifies a list of default targets,
which will be built by
scons
if no explicit targets are given on the command line.
Multiple calls to
Default
are legal,
and add to the list of default targets.
Multiple targets should be specified as
separate arguments to the
Default
method, or as a list.
Default
will also accept the Node returned by any
of a construction environment's
builder methods.
Examples:
Default('foo', 'bar', 'baz') env.Default(['a', 'b', 'c']) hello = env.Program('hello', 'hello.c') env.Default(hello)
An argument to
Default
of
None
will clear all default targets.
Later calls to
Default
will add to the (now empty) default-target list
like normal.
The current list of targets added using the
Default
function or method is available in the
DEFAULT_TARGETS
list;
see below.
DefaultEnvironment([args])
Creates and returns a default construction environment object. This construction environment is used internally by SCons in order to execute many of the global functions in this list, and to fetch source files transparently from source code management systems.
Depends(target, dependency)
,
env.Depends(target, dependency)
Specifies an explicit dependency;
the
target
will be rebuilt
whenever the
dependency
has changed.
Both the specified
target
and
dependency
can be a string
(usually the path name of a file or directory)
or Node objects,
or a list of strings or Node objects
(such as returned by a Builder call).
This should only be necessary
for cases where the dependency
is not caught by a Scanner
for the file.
Example:
env.Depends('foo', 'other-input-file-for-foo') mylib = env.Library('mylib.c') installed_lib = env.Install('lib', mylib) bar = env.Program('bar.c') # Arrange for the library to be copied into the installation # directory before trying to build the "bar" program. # (Note that this is for example only. A "real" library # dependency would normally be configured through the $LIBS # and $LIBPATH variables, not using an env.Depends() call.) env.Depends(bar, installed_lib)
env.Dictionary([vars])
Returns a dictionary object containing copies of all of the construction variables in the environment. If there are any variable names specified, only the specified construction variables are returned in the dictionary.
Example:
dict = env.Dictionary() cc_dict = env.Dictionary('CC', 'CCFLAGS', 'CCCOM')
Dir(name, [directory])
,
env.Dir(name, [directory])
This returns a Directory Node,
an object that represents the specified directory
name
.
name
can be a relative or absolute path.
directory
is an optional directory that will be used as the parent directory.
If no
directory
is specified, the current script's directory is used as the parent.
If
name
is a list, SCons returns a list of Dir nodes.
Construction variables are expanded in
name
.
Directory Nodes can be used anywhere you would supply a string as a directory name to a Builder method or function. Directory Nodes have attributes and methods that are useful in many situations; see "File and Directory Nodes," below.
env.Dump([key])
Returns a pretty printable representation of the environment.
key
,
if not
None
,
should be a string containing the name of the variable of interest.
This SConstruct:
env=Environment() print env.Dump('CCCOM')
will print:
'$CC -c -o $TARGET $CCFLAGS $CPPFLAGS $_CPPDEFFLAGS $_CPPINCFLAGS $SOURCES'
While this SConstruct:
env=Environment() print env.Dump()
will print:
{ 'AR': 'ar', 'ARCOM': '$AR $ARFLAGS $TARGET $SOURCES\n$RANLIB $RANLIBFLAGS $TARGET', 'ARFLAGS': ['r'], 'AS': 'as', 'ASCOM': '$AS $ASFLAGS -o $TARGET $SOURCES', 'ASFLAGS': [], ...
EnsurePythonVersion(major, minor)
,
env.EnsurePythonVersion(major, minor)
Ensure that the Python version is at least
major
.minor
.
This function will
print out an error message and exit SCons with a non-zero exit code if the
actual Python version is not late enough.
Example:
EnsurePythonVersion(2,2)
EnsureSConsVersion(major, minor, [revision])
,
env.EnsureSConsVersion(major, minor, [revision])
Ensure that the SCons version is at least
major.minor
,
or
major.minor.revision
.
if
revision
is specified.
This function will
print out an error message and exit SCons with a non-zero exit code if the
actual SCons version is not late enough.
Examples:
EnsureSConsVersion(0,14) EnsureSConsVersion(0,96,90)
Environment([key=value, ...])
,
env.Environment([key=value, ...])
Return a new construction environment
initialized with the specified
key
=
value
pairs.
Execute(action, [strfunction, varlist])
,
env.Execute(action, [strfunction, varlist])
Executes an Action object.
The specified
action
may be an Action object
(see the section "Action Objects,"
below, for a complete explanation of the arguments and behavior),
or it may be a command-line string,
list of commands,
or executable Python function,
each of which will be converted
into an Action object
and then executed.
The exit value of the command
or return value of the Python function
will be returned.
Note that
scons
will print an error message if the executed
action
fails--that is,
exits with or returns a non-zero value.
scons
will
not,
however,
automatically terminate the build
if the specified
action
fails.
If you want the build to stop in response to a failed
Execute
call,
you must explicitly check for a non-zero return value:
Execute(Copy('file.out', 'file.in')) if Execute("mkdir sub/dir/ectory"): # The mkdir failed, don't try to build. Exit(1)
Exit([value])
,
env.Exit([value])
This tells
scons
to exit immediately
with the specified
value
.
A default exit value of
0
(zero)
is used if no value is specified.
Export(vars)
,
env.Export(vars)
This tells
scons
to export a list of variables from the current
SConscript file to all other SConscript files.
The exported variables are kept in a global collection,
so subsequent calls to
Export
will over-write previous exports that have the same name.
Multiple variable names can be passed to
Export
as separate arguments or as a list.
Keyword arguments can be used to provide names and their values.
A dictionary can be used to map variables to a different name when exported.
Both local variables and global variables can be exported.
Examples:
env = Environment() # Make env available for all SConscript files to Import(). Export("env") package = 'my_name' # Make env and package available for all SConscript files:. Export("env", "package") # Make env and package available for all SConscript files: Export(["env", "package"]) # Make env available using the name debug: Export(debug = env) # Make env available using the name debug: Export({"debug":env})
Note that the
SConscript
function supports an
exports
argument that makes it easier to to export a variable or
set of variables to a single SConscript file.
See the description of the
SConscript
function, below.
File(name, [directory])
,
env.File(name, [directory])
This returns a
File Node,
an object that represents the specified file
name
.
name
can be a relative or absolute path.
directory
is an optional directory that will be used as the parent directory.
If
name
is a list, SCons returns a list of File nodes.
Construction variables are expanded in
name
.
File Nodes can be used anywhere you would supply a string as a file name to a Builder method or function. File Nodes have attributes and methods that are useful in many situations; see "File and Directory Nodes," below.
FindFile(file, dirs)
,
env.FindFile(file, dirs)
Search for
file
in the path specified by
dirs
.
dirs
may be a list of directory names or a single directory name.
In addition to searching for files that exist in the filesystem,
this function also searches for derived files
that have not yet been built.
Example:
foo = env.FindFile('foo', ['dir1', 'dir2'])
FindInstalledFiles()
,
env.FindInstalledFiles()
Returns the list of targets set up by the
Install
or
InstallAs
builders.
This function serves as a convenient method to select the contents of a binary package.
Example:
Install( '/bin', [ 'executable_a', 'executable_b' ] ) # will return the file node list # [ '/bin/executable_a', '/bin/executable_b' ] FindInstalledFiles() Install( '/lib', [ 'some_library' ] ) # will return the file node list # [ '/bin/executable_a', '/bin/executable_b', '/lib/some_library' ] FindInstalledFiles()
FindPathDirs(variable)
Returns a function
(actually a callable Python object)
intended to be used as the
path_function
of a Scanner object.
The returned object will look up the specified
variable
in a construction environment
and treat the construction variable's value as a list of
directory paths that should be searched
(like
$CPPPATH
,
$LIBPATH
,
etc.).
Note that use of
FindPathDirs
is generally preferable to
writing your own
path_function
for the following reasons:
1) The returned list will contain all appropriate directories
found in source trees
(when
VariantDir
is used)
or in code repositories
(when
Repository
or the
-Y
option are used).
2) scons will identify expansions of
variable
that evaluate to the same list of directories as,
in fact, the same list,
and avoid re-scanning the directories for files,
when possible.
Example:
def my_scan(node, env, path, arg): # Code to scan file contents goes here... return include_files scanner = Scanner(name = 'myscanner', function = my_scan, path_function = FindPathDirs('MYPATH'))
FindSourceFiles(node='"."')
,
env.FindSourceFiles(node='"."')
Returns the list of nodes which serve as the source of the built files.
It does so by inspecting the dependency tree starting at the optional
argument
node
which defaults to the '"."'-node. It will then return all leaves of
node
.
These are all children which have no further children.
This function is a convenient method to select the contents of a Source Package.
Example:
Program( 'src/main_a.c' ) Program( 'src/main_b.c' ) Program( 'main_c.c' ) # returns ['main_c.c', 'src/main_a.c', 'SConstruct', 'src/main_b.c'] FindSourceFiles() # returns ['src/main_b.c', 'src/main_a.c' ] FindSourceFiles( 'src' )
As you can see build support files (SConstruct in the above example) will also be returned by this function.
Flatten(sequence)
,
env.Flatten(sequence)
Takes a sequence (that is, a Python list or tuple) that may contain nested sequences and returns a flattened list containing all of the individual elements in any sequence. This can be helpful for collecting the lists returned by calls to Builders; other Builders will automatically flatten lists specified as input, but direct Python manipulation of these lists does not.
Examples:
foo = Object('foo.c') bar = Object('bar.c') # Because `foo' and `bar' are lists returned by the Object() Builder, # `objects' will be a list containing nested lists: objects = ['f1.o', foo, 'f2.o', bar, 'f3.o'] # Passing such a list to another Builder is all right because # the Builder will flatten the list automatically: Program(source = objects) # If you need to manipulate the list directly using Python, you need to # call Flatten() yourself, or otherwise handle nested lists: for object in Flatten(objects): print str(object)
GetBuildFailures()
Returns a list of exceptions for the
actions that failed while
attempting to build targets.
Each element in the returned list is a
BuildError
object
with the following attributes
that record various aspects
of the build failure:
.node
The node that was being built
when the build failure occurred.
.status
The numeric exit status
returned by the command or Python function
that failed when trying to build the
specified Node.
.errstr
The SCons error string
describing the build failure.
(This is often a generic
message like "Error 2"
to indicate that an executed
command exited with a status of 2.)
.filename
The name of the file or
directory that actually caused the failure.
This may be different from the
.node
attribute.
For example,
if an attempt to build a target named
sub/dir/target
fails because the
sub/dir
directory could not be created,
then the
.node
attribute will be
sub/dir/target
but the
.filename
attribute will be
sub/dir
.
.executor
The SCons Executor object
for the target Node
being built.
This can be used to retrieve
the construction environment used
for the failed action.
.action
The actual SCons Action object that failed.
This will be one specific action
out of the possible list of
actions that would have been
executed to build the target.
.command
The actual expanded command that was executed and failed,
after expansion of
$TARGET
,
$SOURCE
,
and other construction variables.
Note that the
GetBuildFailures
function
will always return an empty list
until any build failure has occurred,
which means that
GetBuildFailures
will always return an empty list
while the
SConscript
files are being read.
Its primary intended use is
for functions that will be
executed before SCons exits
by passing them to the
standard Python
atexit.register
()
function.
Example:
import atexit def print_build_failures(): from SCons.Script import GetBuildFailures for bf in GetBuildFailures(): print "%s failed: %s" % (bf.node, bf.errstr) atexit.register(print_build_failures)
GetBuildPath(file, [...])
,
env.GetBuildPath(file, [...])
Returns the
scons
path name (or names) for the specified
file
(or files).
The specified
file
or files
may be
scons
Nodes or strings representing path names.
GetLaunchDir()
,
env.GetLaunchDir()
Returns the absolute path name of the directory from which
scons
was initially invoked.
This can be useful when using the
-u
,
-U
or
-D
options, which internally
change to the directory in which the
SConstruct
file is found.
GetOption(name)
,
env.GetOption(name)
This function provides a way to query the value of
SCons options set on scons command line
(or set using the
SetOption
function).
The options supported are:
cache_debug
which corresponds to --cache-debug;
cache_disable
which corresponds to --cache-disable;
cache_force
which corresponds to --cache-force;
cache_show
which corresponds to --cache-show;
clean
which corresponds to -c, --clean and --remove;
config
which corresponds to --config;
directory
which corresponds to -C and --directory;
diskcheck
which corresponds to --diskcheck
duplicate
which corresponds to --duplicate;
file
which corresponds to -f, --file, --makefile and --sconstruct;
help
which corresponds to -h and --help;
ignore_errors
which corresponds to --ignore-errors;
implicit_cache
which corresponds to --implicit-cache;
implicit_deps_changed
which corresponds to --implicit-deps-changed;
implicit_deps_unchanged
which corresponds to --implicit-deps-unchanged;
interactive
which corresponds to --interact and --interactive;
keep_going
which corresponds to -k and --keep-going;
max_drift
which corresponds to --max-drift;
no_exec
which corresponds to -n, --no-exec, --just-print, --dry-run and --recon;
no_site_dir
which corresponds to --no-site-dir;
num_jobs
which corresponds to -j and --jobs;
profile_file
which corresponds to --profile;
question
which corresponds to -q and --question;
random
which corresponds to --random;
repository
which corresponds to -Y, --repository and --srcdir;
silent
which corresponds to -s, --silent and --quiet;
site_dir
which corresponds to --site-dir;
stack_size
which corresponds to --stack-size;
taskmastertrace_file
which corresponds to --taskmastertrace; and
warn
which corresponds to --warn and --warning.
See the documentation for the corresponding command line object for information about each specific option.
Glob(pattern, [ondisk, source, strings, exclude])
,
env.Glob(pattern, [ondisk, source, strings, exclude])
Returns Nodes (or strings) that match the specified
pattern
,
relative to the directory of the current
SConscript
file.
The
env.Glob
()
form performs string substition on
pattern
and returns whatever matches
the resulting expanded pattern.
The specified
pattern
uses Unix shell style metacharacters for matching:
* matches everything ? matches any single character [seq] matches any character in seq [!seq] matches any char not in seq
If the first character of a filename is a dot, it must be matched explicitly. Character matches do not span directory separators.
The
Glob
knows about
repositories
(see the
Repository
function)
and source directories
(see the
VariantDir
function)
and
returns a Node (or string, if so configured)
in the local (SConscript) directory
if matching Node is found
anywhere in a corresponding
repository or source directory.
The
ondisk
argument may be set to
False
(or any other non-true value)
to disable the search for matches on disk,
thereby only returning matches among
already-configured File or Dir Nodes.
The default behavior is to
return corresponding Nodes
for any on-disk matches found.
The
source
argument may be set to
True
(or any equivalent value)
to specify that,
when the local directory is a
VariantDir
,
the returned Nodes should be from the
corresponding source directory,
not the local directory.
The
strings
argument may be set to
True
(or any equivalent value)
to have the
Glob
function return strings, not Nodes,
that represent the matched files or directories.
The returned strings will be relative to
the local (SConscript) directory.
(Note that This may make it easier to perform
arbitrary manipulation of file names,
but if the returned strings are
passed to a different
SConscript
file,
any Node translation will be relative
to the other
SConscript
directory,
not the original
SConscript
directory.)
The
exclude
argument may be set to a pattern or a list of patterns
(following the same Unix shell semantics)
which must be filtered out of returned elements.
Elements matching a least one pattern of
this list will be excluded.
Examples:
Program('foo', Glob('*.c')) Zip('/tmp/everything', Glob('.??*') + Glob('*')) sources = Glob('*.cpp', exclude=['os_*_specific_*.cpp']) + Glob('os_%s_specific_*.cpp'%currentOS)
Help(text)
,
env.Help(text)
This specifies help text to be printed if the
-h
argument is given to
scons
.
If
Help
is called multiple times, the text is appended together in the order
that
Help
is called.
Ignore(target, dependency)
,
env.Ignore(target, dependency)
The specified dependency file(s) will be ignored when deciding if the target file(s) need to be rebuilt.
You can also use
Ignore
to remove a target from the default build.
In order to do this you must specify the directory the target will
be built in as the target, and the file you want to skip building
as the dependency.
Note that this will only remove the dependencies listed from the files built by default. It will still be built if that dependency is needed by another object being built. See the third and forth examples below.
Examples:
env.Ignore('foo', 'foo.c') env.Ignore('bar', ['bar1.h', 'bar2.h']) env.Ignore('.','foobar.obj') env.Ignore('bar','bar/foobar.obj')
Import(vars)
,
env.Import(vars)
This tells
scons
to import a list of variables into the current SConscript file. This
will import variables that were exported with
Export
or in the
exports
argument to
SConscript
.
Variables exported by
SConscript
have precedence.
Multiple variable names can be passed to
Import
as separate arguments or as a list. The variable "*" can be used
to import all variables.
Examples:
Import("env") Import("env", "variable") Import(["env", "variable"]) Import("*")
Literal(string)
,
env.Literal(string)
The specified
string
will be preserved as-is
and not have construction variables expanded.
Local(targets)
,
env.Local(targets)
The specified
targets
will have copies made in the local tree,
even if an already up-to-date copy
exists in a repository.
Returns a list of the target Node or Nodes.
env.MergeFlags(arg, [unique])
Merges the specified
arg
values to the construction environment's construction variables.
If the
arg
argument is not a dictionary,
it is converted to one by calling
env.ParseFlags
on the argument
before the values are merged.
Note that
arg
must be a single value,
so multiple strings must
be passed in as a list,
not as separate arguments to
env.MergeFlags
.
By default,
duplicate values are eliminated;
you can, however, specify
unique=0
to allow duplicate
values to be added.
When eliminating duplicate values,
any construction variables that end with
the string
PATH
keep the left-most unique value.
All other construction variables keep
the right-most unique value.
Examples:
# Add an optimization flag to $CCFLAGS. env.MergeFlags('-O3') # Combine the flags returned from running pkg-config with an optimization # flag and merge the result into the construction variables. env.MergeFlags(['!pkg-config gtk+-2.0 --cflags', '-O3']) # Combine an optimization flag with the flags returned from running pkg-config # twice and merge the result into the construction variables. env.MergeFlags(['-O3', '!pkg-config gtk+-2.0 --cflags --libs', '!pkg-config libpng12 --cflags --libs'])
NoCache(target, ...)
,
env.NoCache(target, ...)
Specifies a list of files which should
not
be cached whenever the
CacheDir
method has been activated.
The specified targets may be a list
or an individual target.
Multiple files should be specified
either as separate arguments to the
NoCache
method, or as a list.
NoCache
will also accept the return value of any of the construction environment
Builder methods.
Calling
NoCache
on directories and other non-File Node types has no effect because
only File Nodes are cached.
Examples:
NoCache('foo.elf') NoCache(env.Program('hello', 'hello.c'))
NoClean(target, ...)
,
env.NoClean(target, ...)
Specifies a list of files or directories which should
not
be removed whenever the targets (or their dependencies)
are specified with the
-c
command line option.
The specified targets may be a list
or an individual target.
Multiple calls to
NoClean
are legal,
and prevent each specified target
from being removed by calls to the
-c
option.
Multiple files or directories should be specified
either as separate arguments to the
NoClean
method, or as a list.
NoClean
will also accept the return value of any of the construction environment
Builder methods.
Calling
NoClean
for a target overrides calling
Clean
for the same target,
and any targets passed to both functions will
not
be removed by the
-c
option.
Examples:
NoClean('foo.elf') NoClean(env.Program('hello', 'hello.c'))
env.ParseConfig(command, [function, unique])
Calls the specified
function
to modify the environment as specified by the output of
command
.
The default
function
is
env.MergeFlags
,
which expects the output of a typical
*-config
command
(for example,
gtk-config)
and adds the options
to the appropriate construction variables.
By default,
duplicate values are not
added to any construction variables;
you can specify
unique=0
to allow duplicate
values to be added.
Interpreted options
and the construction variables they affect
are as specified for the
env.ParseFlags
method (which this method calls).
See that method's description, below,
for a table of options and construction variables.
ParseDepends(filename, [must_exist, only_one])
,
env.ParseDepends(filename, [must_exist, only_one])
Parses the contents of the specified
filename
as a list of dependencies in the style of
Make
or
mkdep,
and explicitly establishes all of the listed dependencies.
By default,
it is not an error
if the specified
filename
does not exist.
The optional
must_exist
argument may be set to a non-zero
value to have
scons
throw an exception and
generate an error if the file does not exist,
or is otherwise inaccessible.
The optional
only_one
argument may be set to a non-zero
value to have
scons
thrown an exception and
generate an error
if the file contains dependency
information for more than one target.
This can provide a small sanity check
for files intended to be generated
by, for example, the
gcc -M
flag,
which should typically only
write dependency information for
one output file into a corresponding
.d
file.
The
filename
and all of the files listed therein
will be interpreted relative to
the directory of the
SConscript
file which calls the
ParseDepends
function.
env.ParseFlags(flags, ...)
Parses one or more strings containing
typical command-line flags for GCC tool chains
and returns a dictionary with the flag values
separated into the appropriate SCons construction variables.
This is intended as a companion to the
env.MergeFlags
method, but allows for the values in the returned dictionary
to be modified, if necessary,
before merging them into the construction environment.
(Note that
env.MergeFlags
will call this method if its argument is not a dictionary,
so it is usually not necessary to call
env.ParseFlags
directly unless you want to manipulate the values.)
If the first character in any string is an exclamation mark (!), the rest of the string is executed as a command, and the output from the command is parsed as GCC tool chain command-line flags and added to the resulting dictionary.
Flag values are translated accordig to the prefix found, and added to the following construction variables:
-arch CCFLAGS, LINKFLAGS -D CPPDEFINES -framework FRAMEWORKS -frameworkdir= FRAMEWORKPATH -include CCFLAGS -isysroot CCFLAGS, LINKFLAGS -I CPPPATH -l LIBS -L LIBPATH -mno-cygwin CCFLAGS, LINKFLAGS -mwindows LINKFLAGS -pthread CCFLAGS, LINKFLAGS -std= CFLAGS -Wa, ASFLAGS, CCFLAGS -Wl,-rpath= RPATH -Wl,-R, RPATH -Wl,-R RPATH -Wl, LINKFLAGS -Wp, CPPFLAGS - CCFLAGS + CCFLAGS, LINKFLAGS
Any other strings not associated with options
are assumed to be the names of libraries
and added to the
$LIBS
construction variable.
Examples (all of which produce the same result):
dict = env.ParseFlags('-O2 -Dfoo -Dbar=1') dict = env.ParseFlags('-O2', '-Dfoo', '-Dbar=1') dict = env.ParseFlags(['-O2', '-Dfoo -Dbar=1']) dict = env.ParseFlags('-O2', '!echo -Dfoo -Dbar=1')
env.Perforce()
A factory function that
returns a Builder object
to be used to fetch source files
from the Perforce source code management system.
The returned Builder
is intended to be passed to the
SourceCode
function.
This function is deprecated. For details, see the entry for the
SourceCode
function.
Example:
env.SourceCode('.', env.Perforce())
Perforce uses a number of external environment variables for its operation. Consequently, this function adds the following variables from the user's external environment to the construction environment's ENV dictionary: P4CHARSET, P4CLIENT, P4LANGUAGE, P4PASSWD, P4PORT, P4USER, SystemRoot, USER, and USERNAME.
Platform(string)
The
Platform
form returns a callable object
that can be used to initialize
a construction environment using the
platform keyword of the
Environment
function.
Example:
env = Environment(platform = Platform('win32'))
The
env.Platform
form applies the callable object for the specified platform
string
to the environment through which the method was called.
env.Platform('posix')
Note that the
win32
platform adds the
SystemDrive
and
SystemRoot
variables from the user's external environment
to the construction environment's
$ENV
dictionary.
This is so that any executed commands
that use sockets to connect with other systems
(such as fetching source files from
external CVS repository specifications like
:pserver:anonymous@cvs.sourceforge.net:/cvsroot/scons
)
will work on Windows systems.
Precious(target, ...)
,
env.Precious(target, ...)
Marks each given
target
as precious so it is not deleted before it is rebuilt. Normally
scons
deletes a target before building it.
Multiple targets can be passed in to a single call to
Precious
.
env.Prepend(key=val, [...])
Appends the specified keyword arguments to the beginning of construction variables in the environment. If the Environment does not have the specified construction variable, it is simply added to the environment. If the values of the construction variable and the keyword argument are the same type, then the two values will be simply added together. Otherwise, the construction variable and the value of the keyword argument are both coerced to lists, and the lists are added together. (See also the Append method, above.)
Example:
env.Prepend(CCFLAGS = '-g ', FOO = ['foo.yyy'])
env.PrependENVPath(name, newpath, [envname, sep, delete_existing])
This appends new path elements to the given path in the
specified external environment
($ENV
by default).
This will only add
any particular path once (leaving the first one it encounters and
ignoring the rest, to preserve path order),
and to help assure this,
will normalize all paths (using
os.path.normpath
and
os.path.normcase
).
This can also handle the
case where the given old path variable is a list instead of a
string, in which case a list will be returned instead of a string.
If
delete_existing
is 0, then adding a path that already exists
will not move it to the beginning;
it will stay where it is in the list.
Example:
print 'before:',env['ENV']['INCLUDE'] include_path = '/foo/bar:/foo' env.PrependENVPath('INCLUDE', include_path) print 'after:',env['ENV']['INCLUDE']
The above example will print:
before: /biz:/foo after: /foo/bar:/foo:/biz
env.PrependUnique(key=val, delete_existing=0, [...])
Appends the specified keyword arguments to the beginning of construction variables in the environment. If the Environment does not have the specified construction variable, it is simply added to the environment. If the construction variable being appended to is a list, then any value(s) that already exist in the construction variable will not be added again to the list. However, if delete_existing is 1, existing matching values are removed first, so existing values in the arg list move to the front of the list.
Example:
env.PrependUnique(CCFLAGS = '-g', FOO = ['foo.yyy'])
Progress(callable, [interval])
,
Progress(string, [interval, file, overwrite])
,
Progress(list_of_strings, [interval, file, overwrite])
Allows SCons to show progress made during the build by displaying a string or calling a function while evaluating Nodes (e.g. files).
If the first specified argument is a Python callable
(a function or an object that has a
__call__
()
method),
the function will be called
once every
interval
times a Node is evaluated.
The callable will be passed the evaluated Node
as its only argument.
(For future compatibility,
it's a good idea to also add
*args
and
**kw
as arguments to your function or method.
This will prevent the code from breaking
if SCons ever changes the interface
to call the function with additional arguments in the future.)
An example of a simple custom progress function that prints a string containing the Node name every 10 Nodes:
def my_progress_function(node, *args, **kw): print 'Evaluating node %s!' % node Progress(my_progress_function, interval=10)
A more complicated example of a custom progress display object
that prints a string containing a count
every 100 evaluated Nodes.
Note the use of
\r
(a carriage return)
at the end so that the string
will overwrite itself on a display:
import sys class ProgressCounter(object): count = 0 def __call__(self, node, *args, **kw): self.count += 100 sys.stderr.write('Evaluated %s nodes\r' % self.count) Progress(ProgressCounter(), interval=100)
If the first argument
Progress
is a string,
the string will be displayed
every
interval
evaluated Nodes.
The default is to print the string on standard output;
an alternate output stream
may be specified with the
file=
argument.
The following will print a series of dots
on the error output,
one dot for every 100 evaluated Nodes:
import sys Progress('.', interval=100, file=sys.stderr)
If the string contains the verbatim substring
$TARGET
,
it will be replaced with the Node.
Note that, for performance reasons, this is
not
a regular SCons variable substition,
so you can not use other variables
or use curly braces.
The following example will print the name of
every evaluated Node,
using a
\r
(carriage return) to cause each line to overwritten by the next line,
and the
overwrite=
keyword argument to make sure the previously-printed
file name is overwritten with blank spaces:
import sys Progress('$TARGET\r', overwrite=True)
If the first argument to
Progress
is a list of strings,
then each string in the list will be displayed
in rotating fashion every
interval
evaluated Nodes.
This can be used to implement a "spinner"
on the user's screen as follows:
Progress(['-\r', '\\\r', '|\r', '/\r'], interval=5)
Pseudo(target, ...)
,
env.Pseudo(target, ...)
This indicates that each given
target
should not be created by the build rule, and if the target is created,
an error will be generated. This is similar to the gnu make .PHONY
target. However, in the vast majority of cases, an
Alias
is more appropriate.
Multiple targets can be passed in to a single call to
Pseudo
.
env.RCS()
A factory function that
returns a Builder object
to be used to fetch source files
from RCS.
The returned Builder
is intended to be passed to the
SourceCode
function:
This function is deprecated. For details, see the entry for the
SourceCode
function.
Examples:
env.SourceCode('.', env.RCS())
Note that
scons
will fetch source files
from RCS subdirectories automatically,
so configuring RCS
as demonstrated in the above example
should only be necessary if
you are fetching from
RCS,v
files in the same
directory as the source files,
or if you need to explicitly specify RCS
for a specific subdirectory.
env.Replace(key=val, [...])
Replaces construction variables in the Environment with the specified keyword arguments.
Example:
env.Replace(CCFLAGS = '-g', FOO = 'foo.xxx')
Repository(directory)
,
env.Repository(directory)
Specifies that
directory
is a repository to be searched for files.
Multiple calls to
Repository
are legal,
and each one adds to the list of
repositories that will be searched.
To
scons
,
a repository is a copy of the source tree,
from the top-level directory on down,
which may contain
both source files and derived files
that can be used to build targets in
the local source tree.
The canonical example would be an
official source tree maintained by an integrator.
If the repository contains derived files,
then the derived files should have been built using
scons
,
so that the repository contains the necessary
signature information to allow
scons
to figure out when it is appropriate to
use the repository copy of a derived file,
instead of building one locally.
Note that if an up-to-date derived file
already exists in a repository,
scons
will
not
make a copy in the local directory tree.
In order to guarantee that a local copy
will be made,
use the
Local
method.
Requires(target, prerequisite)
,
env.Requires(target, prerequisite)
Specifies an order-only relationship between the specified target file(s) and the specified prerequisite file(s). The prerequisite file(s) will be (re)built, if necessary, before the target file(s), but the target file(s) do not actually depend on the prerequisites and will not be rebuilt simply because the prerequisite file(s) change.
Example:
env.Requires('foo', 'file-that-must-be-built-before-foo')
Return([vars..., stop=])
By default,
this stops processing the current SConscript
file and returns to the calling SConscript file
the values of the variables named in the
vars
string arguments.
Multiple strings contaning variable names may be passed to
Return
.
Any strings that contain white space
The optional
stop=
keyword argument may be set to a false value
to continue processing the rest of the SConscript
file after the
Return
call.
This was the default behavior prior to SCons 0.98.
However, the values returned
are still the values of the variables in the named
vars
at the point
Return
is called.
Examples:
# Returns without returning a value. Return() # Returns the value of the 'foo' Python variable. Return("foo") # Returns the values of the Python variables 'foo' and 'bar'. Return("foo", "bar") # Returns the values of Python variables 'val1' and 'val2'. Return('val1 val2')
Scanner(function, [argument, keys, path_function, node_class, node_factory, scan_check, recursive])
,
env.Scanner(function, [argument, keys, path_function, node_class, node_factory, scan_check, recursive])
Creates a Scanner object for
the specified
function
.
See the section "Scanner Objects,"
below, for a complete explanation of the arguments and behavior.
env.SCCS()
A factory function that
returns a Builder object
to be used to fetch source files
from SCCS.
The returned Builder
is intended to be passed to the
SourceCode
function.
Example:
env.SourceCode('.', env.SCCS())
Note that
scons
will fetch source files
from SCCS subdirectories automatically,
so configuring SCCS
as demonstrated in the above example
should only be necessary if
you are fetching from
s.SCCS
files in the same
directory as the source files,
or if you need to explicitly specify SCCS
for a specific subdirectory.
SConscript(scripts, [exports, variant_dir, duplicate])
,
env.SConscript(scripts, [exports, variant_dir, duplicate])
,
SConscript(dirs=subdirs, [name=script, exports, variant_dir, duplicate])
,
env.SConscript(dirs=subdirs, [name=script, exports, variant_dir, duplicate])
This tells
scons
to execute
one or more subsidiary SConscript (configuration) files.
Any variables returned by a called script using
Return
will be returned by the call to
SConscript
.
There are two ways to call the
SConscript
function.
The first way you can call
SConscript
is to explicitly specify one or more
scripts
as the first argument.
A single script may be specified as a string;
multiple scripts must be specified as a list
(either explicitly or as created by
a function like
Split
).
Examples:
SConscript('SConscript') # run SConscript in the current directory SConscript('src/SConscript') # run SConscript in the src directory SConscript(['src/SConscript', 'doc/SConscript']) config = SConscript('MyConfig.py')
The second way you can call
SConscript
is to specify a list of (sub)directory names
as a
dirs=
subdirs
keyword argument.
In this case,
scons
will, by default,
execute a subsidiary configuration file named
SConscript
in each of the specified directories.
You may specify a name other than
SConscript
by supplying an optional
name=
script
keyword argument.
The first three examples below have the same effect
as the first three examples above:
SConscript(dirs='.') # run SConscript in the current directory SConscript(dirs='src') # run SConscript in the src directory SConscript(dirs=['src', 'doc']) SConscript(dirs=['sub1', 'sub2'], name='MySConscript')
The optional
exports
argument provides a list of variable names or a dictionary of
named values to export to the
script(s)
.
These variables are locally exported only to the specified
script(s)
,
and do not affect the global pool of variables used by the
Export
function.
The subsidiary
script(s)
must use the
Import
function to import the variables.
Examples:
foo = SConscript('sub/SConscript', exports='env') SConscript('dir/SConscript', exports=['env', 'variable']) SConscript(dirs='subdir', exports='env variable') SConscript(dirs=['one', 'two', 'three'], exports='shared_info')
If the optional
variant_dir
argument is present, it causes an effect equivalent to the
VariantDir
method described below.
(If
variant_dir
is not present, the
duplicate
argument is ignored.)
The
variant_dir
argument is interpreted relative to the directory of the calling
SConscript
file.
See the description of the
VariantDir
function below for additional details and restrictions.
If
variant_dir
is present,
the source directory is the directory in which the
SConscript
file resides and the
SConscript
file is evaluated as if it were in the
variant_dir
directory:
SConscript('src/SConscript', variant_dir = 'build')
is equivalent to
VariantDir('build', 'src') SConscript('build/SConscript')
This later paradigm is often used when the sources are
in the same directory as the
SConstruct
:
SConscript('SConscript', variant_dir = 'build')
is equivalent to
VariantDir('build', '.') SConscript('build/SConscript')
Here are some composite examples:
# collect the configuration information and use it to build src and doc shared_info = SConscript('MyConfig.py') SConscript('src/SConscript', exports='shared_info') SConscript('doc/SConscript', exports='shared_info')
# build debugging and production versions. SConscript # can use Dir('.').path to determine variant. SConscript('SConscript', variant_dir='debug', duplicate=0) SConscript('SConscript', variant_dir='prod', duplicate=0)
# build debugging and production versions. SConscript # is passed flags to use. opts = { 'CPPDEFINES' : ['DEBUG'], 'CCFLAGS' : '-pgdb' } SConscript('SConscript', variant_dir='debug', duplicate=0, exports=opts) opts = { 'CPPDEFINES' : ['NODEBUG'], 'CCFLAGS' : '-O' } SConscript('SConscript', variant_dir='prod', duplicate=0, exports=opts)
# build common documentation and compile for different architectures SConscript('doc/SConscript', variant_dir='build/doc', duplicate=0) SConscript('src/SConscript', variant_dir='build/x86', duplicate=0) SConscript('src/SConscript', variant_dir='build/ppc', duplicate=0)
SConscriptChdir(value)
,
env.SConscriptChdir(value)
By default,
scons
changes its working directory
to the directory in which each
subsidiary SConscript file lives.
This behavior may be disabled
by specifying either:
SConscriptChdir(0) env.SConscriptChdir(0)
in which case
scons
will stay in the top-level directory
while reading all SConscript files.
(This may be necessary when building from repositories,
when all the directories in which SConscript files may be found
don't necessarily exist locally.)
You may enable and disable
this ability by calling
SConscriptChdir()
multiple times.
Example:
env = Environment() SConscriptChdir(0) SConscript('foo/SConscript') # will not chdir to foo env.SConscriptChdir(1) SConscript('bar/SConscript') # will chdir to bar
SConsignFile([file, dbm_module])
,
env.SConsignFile([file, dbm_module])
This tells
scons
to store all file signatures
in the specified database
file
.
If the
file
name is omitted,
.sconsign
is used by default.
(The actual file name(s) stored on disk
may have an appropriated suffix appended
by the
dbm_module
.)
If
file
is not an absolute path name,
the file is placed in the same directory as the top-level
SConstruct
file.
If
file
is
None
,
then
scons
will store file signatures
in a separate
.sconsign
file in each directory,
not in one global database file.
(This was the default behavior
prior to SCons 0.96.91 and 0.97.)
The optional
dbm_module
argument can be used to specify
which Python database module
The default is to use a custom
SCons.dblite
module that uses pickled
Python data structures,
and which works on all Python versions.
Examples:
# Explicitly stores signatures in ".sconsign.dblite" # in the top-level SConstruct directory (the # default behavior). SConsignFile() # Stores signatures in the file "etc/scons-signatures" # relative to the top-level SConstruct directory. SConsignFile("etc/scons-signatures") # Stores signatures in the specified absolute file name. SConsignFile("/home/me/SCons/signatures") # Stores signatures in a separate .sconsign file # in each directory. SConsignFile(None)
env.SetDefault(key=val, [...])
Sets construction variables to default values specified with the keyword arguments if (and only if) the variables are not already set. The following statements are equivalent:
env.SetDefault(FOO = 'foo') if 'FOO' not in env: env['FOO'] = 'foo'
SetOption(name, value)
,
env.SetOption(name, value)
This function provides a way to set a select subset of the scons command line options from a SConscript file. The options supported are:
clean
which corresponds to -c, --clean and --remove;
duplicate
which corresponds to --duplicate;
help
which corresponds to -h and --help;
implicit_cache
which corresponds to --implicit-cache;
max_drift
which corresponds to --max-drift;
no_exec
which corresponds to -n, --no-exec, --just-print, --dry-run and --recon;
num_jobs
which corresponds to -j and --jobs;
random
which corresponds to --random; and
stack_size
which corresponds to --stack-size.
See the documentation for the corresponding command line object for information about each specific option.
Example:
SetOption('max_drift', 1)
SideEffect(side_effect, target)
,
env.SideEffect(side_effect, target)
Declares
side_effect
as a side effect of building
target
.
Both
side_effect
and
target
can be a list, a file name, or a node.
A side effect is a target file that is created or updated
as a side effect of building other targets.
For example, a Windows PDB
file is created as a side effect of building the .obj
files for a static library,
and various log files are created updated
as side effects of various TeX commands.
If a target is a side effect of multiple build commands,
scons
will ensure that only one set of commands
is executed at a time.
Consequently, you only need to use this method
for side-effect targets that are built as a result of
multiple build commands.
Because multiple build commands may update
the same side effect file,
by default the
side_effect
target is
not
automatically removed
when the
target
is removed by the
-c
option.
(Note, however, that the
side_effect
might be removed as part of
cleaning the directory in which it lives.)
If you want to make sure the
side_effect
is cleaned whenever a specific
target
is cleaned,
you must specify this explicitly
with the
Clean
or
env.Clean
function.
SourceCode(entries, builder)
,
env.SourceCode(entries, builder)
This function and its associate factory functions are deprecated. There is no replacement. The intended use was to keep a local tree in sync with an archive, but in actuality the function only causes the archive to be fetched on the first run. Synchronizing with the archive is best done external to SCons.
Arrange for non-existent source files to
be fetched from a source code management system
using the specified
builder
.
The specified
entries
may be a Node, string or list of both,
and may represent either individual
source files or directories in which
source files can be found.
For any non-existent source files,
scons
will search up the directory tree
and use the first
SourceCode
builder it finds.
The specified
builder
may be
None
,
in which case
scons
will not use a builder to fetch
source files for the specified
entries
,
even if a
SourceCode
builder has been specified
for a directory higher up the tree.
scons
will, by default,
fetch files from SCCS or RCS subdirectories
without explicit configuration.
This takes some extra processing time
to search for the necessary
source code management files on disk.
You can avoid these extra searches
and speed up your build a little
by disabling these searches as follows:
env.SourceCode('.', None)
Note that if the specified
builder
is one you create by hand,
it must have an associated
construction environment to use
when fetching a source file.
scons
provides a set of canned factory
functions that return appropriate
Builders for various popular
source code management systems.
Canonical examples of invocation include:
env.SourceCode('.', env.BitKeeper('/usr/local/BKsources')) env.SourceCode('src', env.CVS('/usr/local/CVSROOT')) env.SourceCode('/', env.RCS()) env.SourceCode(['f1.c', 'f2.c'], env.SCCS()) env.SourceCode('no_source.c', None)
SourceSignatures(type)
,
env.SourceSignatures(type)
Note: Although it is not yet officially deprecated,
use of this function is discouraged.
See the
Decider
function for a more flexible and straightforward way
to configure SCons' decision-making.
The
SourceSignatures
function tells
scons
how to decide if a source file
(a file that is not built from any other files)
has changed since the last time it
was used to build a particular target file.
Legal values are
MD5
or
timestamp
.
If the environment method is used, the specified type of source signature is only used when deciding whether targets built with that environment are up-to-date or must be rebuilt. If the global function is used, the specified type of source signature becomes the default used for all decisions about whether targets are up-to-date.
MD5
means
scons
decides that a source file has changed
if the MD5 checksum of its contents has changed since
the last time it was used to rebuild a particular target file.
timestamp
means
scons
decides that a source file has changed
if its timestamp (modification time) has changed since
the last time it was used to rebuild a particular target file.
(Note that although this is similar to the behavior of Make,
by default it will also rebuild if the dependency is
older
than the last time it was used to rebuild the target file.)
There is no different between the two behaviors
for Python
Value
node objects.
MD5
signatures take longer to compute,
but are more accurate than
timestamp
signatures.
The default value is
MD5
.
Note that the default
TargetSignatures
setting (see below)
is to use this
SourceSignatures
setting for any target files that are used
to build other target files.
Consequently, changing the value of
SourceSignatures
will, by default,
affect the up-to-date decision for all files in the build
(or all files built with a specific construction environment
when
env.SourceSignatures
is used).
Split(arg)
,
env.Split(arg)
Returns a list of file names or other objects. If arg is a string, it will be split on strings of white-space characters within the string, making it easier to write long lists of file names. If arg is already a list, the list will be returned untouched. If arg is any other type of object, it will be returned as a list containing just the object.
Example:
files = Split("f1.c f2.c f3.c") files = env.Split("f4.c f5.c f6.c") files = Split(""" f7.c f8.c f9.c """)
env.subst(input, [raw, target, source, conv])
Performs construction variable interpolation
on the specified string or sequence argument
input
.
By default,
leading or trailing white space will
be removed from the result.
and all sequences of white space
will be compressed to a single space character.
Additionally, any
$(
and
$)
character sequences will be stripped from the returned string,
The optional
raw
argument may be set to
1
if you want to preserve white space and
$(
-$)
sequences.
The
raw
argument may be set to
2
if you want to strip
all characters between
any
$(
and
$)
pairs
(as is done for signature calculation).
If the input is a sequence (list or tuple), the individual elements of the sequence will be expanded, and the results will be returned as a list.
The optional
target
and
source
keyword arguments
must be set to lists of
target and source nodes, respectively,
if you want the
$TARGET
,
$TARGETS
,
$SOURCE
and
$SOURCES
to be available for expansion.
This is usually necessary if you are
calling
env.subst
from within a Python function used
as an SCons action.
Returned string values or sequence elements
are converted to their string representation by default.
The optional
conv
argument
may specify a conversion function
that will be used in place of
the default.
For example, if you want Python objects
(including SCons Nodes)
to be returned as Python objects,
you can use the Python
Λ
idiom to pass in an unnamed function
that simply returns its unconverted argument.
Example:
print env.subst("The C compiler is: $CC") def compile(target, source, env): sourceDir = env.subst("${SOURCE.srcdir}", target=target, source=source) source_nodes = env.subst('$EXPAND_TO_NODELIST', conv=lambda x: x)
Tag(node, tags)
Annotates file or directory Nodes with
information about how the
Package
Builder should package those files or directories.
All tags are optional.
Examples:
# makes sure the built library will be installed with 0644 file # access mode Tag( Library( 'lib.c' ), UNIX_ATTR="0644" ) # marks file2.txt to be a documentation file Tag( 'file2.txt', DOC )
TargetSignatures(type)
,
env.TargetSignatures(type)
Note: Although it is not yet officially deprecated,
use of this function is discouraged.
See the
Decider
function for a more flexible and straightforward way
to configure SCons' decision-making.
The
TargetSignatures
function tells
scons
how to decide if a target file
(a file that
is
built from any other files)
has changed since the last time it
was used to build some other target file.
Legal values are
"build"
;
"content"
(or its synonym
"MD5"
);
"timestamp"
;
or
"source"
.
If the environment method is used, the specified type of target signature is only used for targets built with that environment. If the global function is used, the specified type of signature becomes the default used for all target files that don't have an explicit target signature type specified for their environments.
"content"
(or its synonym
"MD5"
)
means
scons
decides that a target file has changed
if the MD5 checksum of its contents has changed since
the last time it was used to rebuild some other target file.
This means
scons
will open up
MD5 sum the contents
of target files after they're built,
and may decide that it does not need to rebuild
"downstream" target files if a file was
rebuilt with exactly the same contents as the last time.
"timestamp"
means
scons
decides that a target file has changed
if its timestamp (modification time) has changed since
the last time it was used to rebuild some other target file.
(Note that although this is similar to the behavior of Make,
by default it will also rebuild if the dependency is
older
than the last time it was used to rebuild the target file.)
"source"
means
scons
decides that a target file has changed
as specified by the corresponding
SourceSignatures
setting
("MD5"
or
"timestamp"
).
This means that
scons
will treat all input files to a target the same way,
regardless of whether they are source files
or have been built from other files.
"build"
means
scons
decides that a target file has changed
if it has been rebuilt in this invocation
or if its content or timestamp have changed
as specified by the corresponding
SourceSignatures
setting.
This "propagates" the status of a rebuilt file
so that other "downstream" target files
will always be rebuilt,
even if the contents or the timestamp
have not changed.
"build"
signatures are fastest because
"content"
(or
"MD5"
)
signatures take longer to compute,
but are more accurate than
"timestamp"
signatures,
and can prevent unnecessary "downstream" rebuilds
when a target file is rebuilt to the exact same contents
as the previous build.
The
"source"
setting provides the most consistent behavior
when other target files may be rebuilt from
both source and target input files.
The default value is
"source"
.
Because the default setting is
"source"
,
using
SourceSignatures
is generally preferable to
TargetSignatures
,
so that the up-to-date decision
will be consistent for all files
(or all files built with a specific construction environment).
Use of
TargetSignatures
provides specific control for how built target files
affect their "downstream" dependencies.
Tool(string, [toolpath, **kw])
,
env.Tool(string, [toolpath, **kw])
The
Tool
form of the function
returns a callable object
that can be used to initialize
a construction environment using the
tools keyword of the Environment() method.
The object may be called with a construction
environment as an argument,
in which case the object will
add the necessary variables
to the construction environment
and the name of the tool will be added to the
$TOOLS
construction variable.
Additional keyword arguments are passed to the tool's
generate
()
method.
Examples:
env = Environment(tools = [ Tool('msvc') ]) env = Environment() t = Tool('msvc') t(env) # adds 'msvc' to the TOOLS variable u = Tool('opengl', toolpath = ['tools']) u(env) # adds 'opengl' to the TOOLS variable
The
env.Tool
form of the function
applies the callable object for the specified tool
string
to the environment through which the method was called.
Additional keyword arguments are passed to the tool's
generate
()
method.
env.Tool('gcc') env.Tool('opengl', toolpath = ['build/tools'])
Value(value, [built_value])
,
env.Value(value, [built_value])
Returns a Node object representing the specified Python value. Value
Nodes can be used as dependencies of targets. If the result of
calling
str
(value
)
changes between SCons runs, any targets depending on
Value
(value
)
will be rebuilt.
(This is true even when using timestamps to decide if
files are up-to-date.)
When using timestamp source signatures, Value Nodes'
timestamps are equal to the system time when the Node is created.
The returned Value Node object has a
write
()
method that can be used to "build" a Value Node
by setting a new value.
The optional
built_value
argument can be specified
when the Value Node is created
to indicate the Node should already be considered
"built."
There is a corresponding
read
()
method that will return the built value of the Node.
Examples:
env = Environment() def create(target, source, env): # A function that will write a 'prefix=$SOURCE' # string into the file name specified as the # $TARGET. f = open(str(target[0]), 'wb') f.write('prefix=' + source[0].get_contents()) # Fetch the prefix= argument, if any, from the command # line, and use /usr/local as the default. prefix = ARGUMENTS.get('prefix', '/usr/local') # Attach a .Config() builder for the above function action # to the construction environment. env['BUILDERS']['Config'] = Builder(action = create) env.Config(target = 'package-config', source = Value(prefix)) def build_value(target, source, env): # A function that "builds" a Python Value by updating # the the Python value with the contents of the file # specified as the source of the Builder call ($SOURCE). target[0].write(source[0].get_contents()) output = env.Value('before') input = env.Value('after') # Attach a .UpdateValue() builder for the above function # action to the construction environment. env['BUILDERS']['UpdateValue'] = Builder(action = build_value) env.UpdateValue(target = Value(output), source = Value(input))
VariantDir(variant_dir, src_dir, [duplicate])
,
env.VariantDir(variant_dir, src_dir, [duplicate])
Use the
VariantDir
function to create a copy of your sources in another location:
if a name under
variant_dir
is not found but exists under
src_dir
,
the file or directory is copied to
variant_dir
.
Target files can be built in a different directory
than the original sources by simply refering to the sources (and targets)
within the variant tree.
VariantDir
can be called multiple times with the same
src_dir
to set up multiple builds with different options
(variants
).
The
src_dir
location must be in or underneath the SConstruct file's directory, and
variant_dir
may not be underneath
src_dir
.
The default behavior is for
scons
to physically duplicate the source files in the variant tree.
Thus, a build performed in the variant tree is guaranteed to be identical
to a build performed in the source tree even if
intermediate source files are generated during the build,
or preprocessors or other scanners search for included files
relative to the source file,
or individual compilers or other invoked tools are hard-coded
to put derived files in the same directory as source files.
If possible on the platform,
the duplication is performed by linking rather than copying;
see also the
--duplicate
command-line option.
Moreover, only the files needed for the build are duplicated;
files and directories that are not used are not present in
variant_dir
.
Duplicating the source tree may be disabled by setting the
duplicate
argument to
0
(zero).
This will cause
scons
to invoke Builders using the path names of source files in
src_dir
and the path names of derived files within
variant_dir
.
This is always more efficient than
duplicate=1
,
and is usually safe for most builds
(but see above for cases that may cause problems).
Note that
VariantDir
works most naturally with a subsidiary SConscript file.
However, you would then call the subsidiary SConscript file
not in the source directory, but in the
variant_dir
,
regardless of the value of
duplicate
.
This is how you tell
scons
which variant of a source tree to build:
# run src/SConscript in two variant directories VariantDir('build/variant1', 'src') SConscript('build/variant1/SConscript') VariantDir('build/variant2', 'src') SConscript('build/variant2/SConscript')
See also the
SConscript
function, described above,
for another way to specify a variant directory
in conjunction with calling a subsidiary SConscript file.
Examples:
# use names in the build directory, not the source directory VariantDir('build', 'src', duplicate=0) Program('build/prog', 'build/source.c')
# this builds both the source and docs in a separate subtree VariantDir('build', '.', duplicate=0) SConscript(dirs=['build/src','build/doc'])
# same as previous example, but only uses SConscript SConscript(dirs='src', variant_dir='build/src', duplicate=0) SConscript(dirs='doc', variant_dir='build/doc', duplicate=0)
WhereIs(program, [path, pathext, reject])
,
env.WhereIs(program, [path, pathext, reject])
Searches for the specified executable
program
,
returning the full path name to the program
if it is found,
and returning None if not.
Searches the specified
path
,
the value of the calling environment's PATH
(env['ENV']['PATH']
),
or the user's current external PATH
(os.environ['PATH']
)
by default.
On Windows systems, searches for executable
programs with any of the file extensions
listed in the specified
pathext
,
the calling environment's PATHEXT
(env['ENV']['PATHEXT']
)
or the user's current PATHEXT
(os.environ['PATHEXT']
)
by default.
Will not select any
path name or names
in the specified
reject
list, if any.
In addition to the global functions and methods, scons supports a number of Python variables that can be used in SConscript files to affect how you want the build to be performed. These variables may be accessed from custom Python modules that you import into an SConscript file by adding the following to the Python module:
from SCons.Script import *
A list keyword=value arguments specified on the command line. Each element in the list is a tuple containing the (keyword,value) of the argument. The separate keyword and value elements of the tuple can be accessed by subscripting for element [0] and [1] of the tuple, respectively.
Example:
print "first keyword, value =", ARGLIST[0][0], ARGLIST[0][1] print "second keyword, value =", ARGLIST[1][0], ARGLIST[1][1] third_tuple = ARGLIST[2] print "third keyword, value =", third_tuple[0], third_tuple[1] for key, value in ARGLIST: # process key and value
A dictionary of all the keyword=value arguments specified on the command line. The dictionary is not in order, and if a given keyword has more than one value assigned to it on the command line, the last (right-most) value is the one in the ARGUMENTS dictionary.
Example:
if ARGUMENTS.get('debug', 0): env = Environment(CCFLAGS = '-g') else: env = Environment()
A list of the targets which scons will actually try to build, regardless of whether they were specified on the command line or via the Default() function or method. The elements of this list may be strings or nodes, so you should run the list through the Python str function to make sure any Node path names are converted to strings.
Because this list may be taken from the list of targets specified using the Default() function or method, the contents of the list may change on each successive call to Default(). See the DEFAULT_TARGETS list, below, for additional information.
Example:
if 'foo' in BUILD_TARGETS: print "Don't forget to test the `foo' program!" if 'special/program' in BUILD_TARGETS: SConscript('special')
Note that the BUILD_TARGETS list only contains targets expected listed on the command line or via calls to the Default() function or method. It does not contain all dependent targets that will be built as a result of making the sure the explicitly-specified targets are up to date.
A list of the targets explicitly specified on the command line. If there are no targets specified on the command line, the list is empty. This can be used, for example, to take specific actions only when a certain target or targets is explicitly being built.
Example:
if 'foo' in COMMAND_LINE_TARGETS: print "Don't forget to test the `foo' program!" if 'special/program' in COMMAND_LINE_TARGETS: SConscript('special')
A list of the target nodes that have been specified using the Default() function or method. The elements of the list are nodes, so you need to run them through the Python str function to get at the path name for each Node.
Example:
print str(DEFAULT_TARGETS[0]) if 'foo' in map(str, DEFAULT_TARGETS): print "Don't forget to test the `foo' program!"
The contents of the DEFAULT_TARGETS list change on on each successive call to the Default() function:
print map(str, DEFAULT_TARGETS) # originally [] Default('foo') print map(str, DEFAULT_TARGETS) # now a node ['foo'] Default('bar') print map(str, DEFAULT_TARGETS) # now a node ['foo', 'bar'] Default(None) print map(str, DEFAULT_TARGETS) # back to []
Consequently, be sure to use DEFAULT_TARGETS only after you've made all of your Default() calls, or else simply be careful of the order of these statements in your SConscript files so that you don't look for a specific default target before it's actually been added to the list.
A construction environment has an associated dictionary of construction variables that are used by built-in or user-supplied build rules. Construction variables must follow the same rules for Python identifiers: the initial character must be an underscore or letter, followed by any number of underscores, letters, or digits.
A number of useful construction variables are automatically defined by scons for each supported platform, and additional construction variables can be defined by the user. The following is a list of the automatically defined construction variables:
The static library archiver.
Specifies the system architecture for which
the package is being built.
The default is the system architecture
of the machine on which SCons is running.
This is used to fill in the
Architecture:
field in an Ipkg
control
file,
and as part of the name of a generated RPM file.
The command line used to generate a static library from object files.
The string displayed when an object file
is generated from an assembly-language source file.
If this is not set, then $ARCOM
(the command line) is displayed.
env = Environment(ARCOMSTR = "Archiving $TARGET")
General options passed to the static library archiver.
The assembler.
The command line used to generate an object file from an assembly-language source file.
The string displayed when an object file
is generated from an assembly-language source file.
If this is not set, then $ASCOM
(the command line) is displayed.
env = Environment(ASCOMSTR = "Assembling $TARGET")
General options passed to the assembler.
The command line used to assemble an assembly-language
source file into an object file
after first running the file through the C preprocessor.
Any options specified
in the $ASFLAGS
and $CPPFLAGS
construction variables
are included on this command line.
The string displayed when an object file
is generated from an assembly-language source file
after first running the file through the C preprocessor.
If this is not set, then $ASPPCOM
(the command line) is displayed.
env = Environment(ASPPCOMSTR = "Assembling $TARGET")
General options when an assembling an assembly-language
source file into an object file
after first running the file through the C preprocessor.
The default is to use the value of $ASFLAGS
.
The bibliography generator for the TeX formatter and typesetter and the LaTeX structured formatter and typesetter.
The command line used to call the bibliography generator for the TeX formatter and typesetter and the LaTeX structured formatter and typesetter.
The string displayed when generating a bibliography
for TeX or LaTeX.
If this is not set, then $BIBTEXCOM
(the command line) is displayed.
env = Environment(BIBTEXCOMSTR = "Generating bibliography $TARGET")
General options passed to the bibliography generator for the TeX formatter and typesetter and the LaTeX structured formatter and typesetter.
The BitKeeper executable.
The command line for fetching source files using BitKeeper.
The string displayed when fetching
a source file using BitKeeper.
If this is not set, then $BITKEEPERCOM
(the command line) is displayed.
The command ($BITKEEPER
) and subcommand
for fetching source files using BitKeeper.
Options that are passed to the BitKeeper get subcommand.
A dictionary mapping the names of the builders available through this environment to underlying Builder objects. Builders named Alias, CFile, CXXFile, DVI, Library, Object, PDF, PostScript, and Program are available by default. If you initialize this variable when an Environment is created:
env = Environment(BUILDERS = {'NewBuilder' : foo})
the default Builders will no longer be available. To use a new Builder object in addition to the default Builders, add your new Builder object like this:
env = Environment() env.Append(BUILDERS = {'NewBuilder' : foo})
or this:
env = Environment() env['BUILDERS]['NewBuilder'] = foo
The C compiler.
The command line used to compile a C source file to a (static) object
file. Any options specified in the $CFLAGS
, $CCFLAGS
and
$CPPFLAGS
construction variables are included on this command
line.
The string displayed when a C source file
is compiled to a (static) object file.
If this is not set, then $CCCOM
(the command line) is displayed.
env = Environment(CCCOMSTR = "Compiling static object $TARGET")
General options that are passed to the C and C++ compilers.
Options added to the compiler command line
to support building with precompiled headers.
The default value expands expands to the appropriate
Microsoft Visual C++ command-line options
when the $PCH
construction variable is set.
Options added to the compiler command line
to support storing debugging information in a
Microsoft Visual C++ PDB file.
The default value expands expands to appropriate
Microsoft Visual C++ command-line options
when the $PDB
construction variable is set.
The Visual C++ compiler option that SCons uses by default
to generate PDB information is /Z7
.
This works correctly with parallel (-j
) builds
because it embeds the debug information in the intermediate object files,
as opposed to sharing a single PDB file between multiple object files.
This is also the only way to get debug information
embedded into a static library.
Using the /Zi
instead may yield improved
link-time performance,
although parallel builds will no longer work.
You can generate PDB files with the /Zi
switch by overriding the default $CCPDBFLAGS
variable as follows:
env['CCPDBFLAGS'] = ['${(PDB and "/Zi /Fd%s" % File(PDB)) or ""}']
An alternative would be to use the /Zi
to put the debugging information in a separate .pdb
file for each object file by overriding
the $CCPDBFLAGS
variable as follows:
env['CCPDBFLAGS'] = '/Zi /Fd${TARGET}.pdb'
The version number of the C compiler. This may or may not be set, depending on the specific C compiler being used.
The suffix for C source files.
This is used by the internal CFile builder
when generating C files from Lex (.l) or YACC (.y) input files.
The default suffix, of course, is
.c
(lower case).
On case-insensitive systems (like Windows),
SCons also treats
.C
(upper case) files
as C files.
General options that are passed to the C compiler (C only; not C++).
A hook for modifying the file that controls the packaging build
(the .spec
for RPM,
the control
for Ipkg,
the .wxs
for MSI).
If set, the function will be called
after the SCons template for the file has been written.
XXX
A reserved variable name that may not be set or used in a construction environment. (See "Variable Substitution," below.)
A reserved variable name that may not be set or used in a construction environment. (See "Variable Substitution," below.)
The name of a file containing the change log text
to be included in the package.
This is included as the
%changelog
section of the RPM
.spec
file.
A function used to produce variables like $_CPPINCFLAGS
. It takes
four or five
arguments: a prefix to concatenate onto each element, a list of
elements, a suffix to concatenate onto each element, an environment
for variable interpolation, and an optional function that will be
called to transform the list before concatenation.
env['_CPPINCFLAGS'] = '$( ${_concat(INCPREFIX, CPPPATH, INCSUFFIX, __env__, RDirs)} $)',
The name of the directory in which
Configure context test files are written.
The default is
.sconf_temp
in the top-level directory
containing the
SConstruct
file.
The name of the Configure context log file.
The default is
config.log
in the top-level directory
containing the
SConstruct
file.
An automatically-generated construction variable
containing the C preprocessor command-line options
to define values.
The value of $_CPPDEFFLAGS
is created
by appending $CPPDEFPREFIX
and $CPPDEFSUFFIX
to the beginning and end
of each definition in $CPPDEFINES
.
A platform independent specification of C preprocessor definitions.
The definitions will be added to command lines
through the automatically-generated
$_CPPDEFFLAGS
construction variable (see above),
which is constructed according to
the type of value of $CPPDEFINES
:
If $CPPDEFINES
is a string,
the values of the
$CPPDEFPREFIX
and $CPPDEFSUFFIX
construction variables
will be added to the beginning and end.
# Will add -Dxyz to POSIX compiler command lines, # and /Dxyz to Microsoft Visual C++ command lines. env = Environment(CPPDEFINES='xyz')
If $CPPDEFINES
is a list,
the values of the
$CPPDEFPREFIX
and $CPPDEFSUFFIX
construction variables
will be appended to the beginning and end
of each element in the list.
If any element is a list or tuple,
then the first item is the name being
defined and the second item is its value:
# Will add -DB=2 -DA to POSIX compiler command lines, # and /DB=2 /DA to Microsoft Visual C++ command lines. env = Environment(CPPDEFINES=[('B', 2), 'A'])
If $CPPDEFINES
is a dictionary,
the values of the
$CPPDEFPREFIX
and $CPPDEFSUFFIX
construction variables
will be appended to the beginning and end
of each item from the dictionary.
The key of each dictionary item
is a name being defined
to the dictionary item's corresponding value;
if the value is
None
,
then the name is defined without an explicit value.
Note that the resulting flags are sorted by keyword
to ensure that the order of the options on the
command line is consistent each time
scons
is run.
# Will add -DA -DB=2 to POSIX compiler command lines, # and /DA /DB=2 to Microsoft Visual C++ command lines. env = Environment(CPPDEFINES={'B':2, 'A':None})
The prefix used to specify preprocessor definitions
on the C compiler command line.
This will be appended to the beginning of each definition
in the $CPPDEFINES
construction variable
when the $_CPPDEFFLAGS
variable is automatically generated.
The suffix used to specify preprocessor definitions
on the C compiler command line.
This will be appended to the end of each definition
in the $CPPDEFINES
construction variable
when the $_CPPDEFFLAGS
variable is automatically generated.
User-specified C preprocessor options.
These will be included in any command that uses the C preprocessor,
including not just compilation of C and C++ source files
via the $CCCOM
,
$SHCCCOM
,
$CXXCOM
and
$SHCXXCOM
command lines,
but also the $FORTRANPPCOM
,
$SHFORTRANPPCOM
,
$F77PPCOM
and
$SHF77PPCOM
command lines
used to compile a Fortran source file,
and the $ASPPCOM
command line
used to assemble an assembly language source file,
after first running each file through the C preprocessor.
Note that this variable does
not
contain
-I
(or similar) include search path options
that scons generates automatically from $CPPPATH
.
See $_CPPINCFLAGS
, below,
for the variable that expands to those options.
An automatically-generated construction variable
containing the C preprocessor command-line options
for specifying directories to be searched for include files.
The value of $_CPPINCFLAGS
is created
by appending $INCPREFIX
and $INCSUFFIX
to the beginning and end
of each directory in $CPPPATH
.
The list of directories that the C preprocessor will search for include
directories. The C/C++ implicit dependency scanner will search these
directories for include files. Don't explicitly put include directory
arguments in CCFLAGS or CXXFLAGS because the result will be non-portable
and the directories will not be searched by the dependency scanner. Note:
directory names in CPPPATH will be looked-up relative to the SConscript
directory when they are used in a command. To force
scons
to look-up a directory relative to the root of the source tree use #:
env = Environment(CPPPATH='#/include')
The directory look-up can also be forced using the
Dir
()
function:
include = Dir('include') env = Environment(CPPPATH=include)
The directory list will be added to command lines
through the automatically-generated
$_CPPINCFLAGS
construction variable,
which is constructed by
appending the values of the
$INCPREFIX
and $INCSUFFIX
construction variables
to the beginning and end
of each directory in $CPPPATH
.
Any command lines you define that need
the CPPPATH directory list should
include $_CPPINCFLAGS
:
env = Environment(CCCOM="my_compiler $_CPPINCFLAGS -c -o $TARGET $SOURCE")
The list of suffixes of files that will be scanned for C preprocessor implicit dependencies (#include lines). The default list is:
[".c", ".C", ".cxx", ".cpp", ".c++", ".cc", ".h", ".H", ".hxx", ".hpp", ".hh", ".F", ".fpp", ".FPP", ".m", ".mm", ".S", ".spp", ".SPP"]
The CVS executable.
Options that are passed to the CVS checkout subcommand.
The command line used to fetch source files from a CVS repository.
The string displayed when fetching
a source file from a CVS repository.
If this is not set, then $CVSCOM
(the command line) is displayed.
General options that are passed to CVS.
By default, this is set to
-d $CVSREPOSITORY
to specify from where the files must be fetched.
The path to the CVS repository.
This is referenced in the default
$CVSFLAGS
value.
The C++ compiler.
The command line used to compile a C++ source file to an object file.
Any options specified in the $CXXFLAGS
and
$CPPFLAGS
construction variables
are included on this command line.
The string displayed when a C++ source file
is compiled to a (static) object file.
If this is not set, then $CXXCOM
(the command line) is displayed.
env = Environment(CXXCOMSTR = "Compiling static object $TARGET")
The suffix for C++ source files.
This is used by the internal CXXFile builder
when generating C++ files from Lex (.ll) or YACC (.yy) input files.
The default suffix is
.cc
.
SCons also treats files with the suffixes
.cpp
,
.cxx
,
.c++
,
and
.C++
as C++ files,
and files with
.mm
suffixes as Objective C++ files.
On case-sensitive systems (Linux, UNIX, and other POSIX-alikes),
SCons also treats
.C
(upper case) files
as C++ files.
General options that are passed to the C++ compiler.
By default, this includes the value of $CCFLAGS
,
so that setting $CCFLAGS
affects both C and C++ compilation.
If you want to add C++-specific flags,
you must set or override the value of $CXXFLAGS
.
The version number of the C++ compiler. This may or may not be set, depending on the specific C++ compiler being used.
DC.
DCOM.
DDEBUG.
_DDEBUGFLAGS.
DDEBUGPREFIX.
DDEBUGSUFFIX.
A long description of the project being packaged. This is included in the relevant section of the file that controls the packaging build.
A language-specific long description for
the specified lang
.
This is used to populate a
%description -l
section of an RPM
.spec
file.
DFILESUFFIX.
DFLAGPREFIX.
_DFLAGS.
DFLAGS.
DFLAGSUFFIX.
_DINCFLAGS.
DINCPREFIX.
DINCSUFFIX.
A function that converts a string into a Dir instance relative to the target being built.
A function that converts a string into a Dir instance relative to the target being built.
A function that converts a list of strings into a list of Dir instances relative to the target being built.
DLIB.
DLIBCOM.
_DLIBDIRFLAGS.
DLIBDIRPREFIX.
DLIBDIRSUFFIX.
DLIBFLAGPREFIX.
_DLIBFLAGS.
DLIBFLAGSUFFIX.
DLIBLINKPREFIX.
DLIBLINKSUFFIX.
DLINK.
DLINKCOM.
DLINKFLAGPREFIX.
DLINKFLAGS.
DLINKFLAGSUFFIX.
The default XSLT file for the DocbookEpub
builder within the
current environment, if no other XSLT gets specified via keyword.
The default XSLT file for the DocbookHtml
builder within the
current environment, if no other XSLT gets specified via keyword.
The default XSLT file for the DocbookHtmlChunked
builder within the
current environment, if no other XSLT gets specified via keyword.
The default XSLT file for the DocbookHtmlhelp
builder within the
current environment, if no other XSLT gets specified via keyword.
The default XSLT file for the DocbookMan
builder within the
current environment, if no other XSLT gets specified via keyword.
The default XSLT file for the DocbookPdf
builder within the
current environment, if no other XSLT gets specified via keyword.
The default XSLT file for the DocbookSlidesHtml
builder within the
current environment, if no other XSLT gets specified via keyword.
The default XSLT file for the DocbookSlidesPdf
builder within the
current environment, if no other XSLT gets specified via keyword.
The path to the PDF renderer fop
or xep
,
if one of them is installed (fop
gets checked first).
The full command-line for the
PDF renderer fop
or xep
.
The string displayed when a renderer like fop
or
xep
is used to create PDF output from an XML file.
Additonal command-line flags for the
PDF renderer fop
or xep
.
The path to the external executable xmllint
, if it's installed.
Note, that this is only used as last fallback for resolving
XIncludes, if no libxml2 or lxml Python binding can be imported
in the current system.
The full command-line for the external executable
xmllint
.
The string displayed when xmllint
is used to resolve
XIncludes for a given XML file.
Additonal command-line flags for the external executable
xmllint
.
The path to the external executable xsltproc
(or saxon
, xalan
), if one of them
is installed.
Note, that this is only used as last fallback for XSL transformations, if
no libxml2 or lxml Python binding can be imported in the current system.
The full command-line for the external executable
xsltproc
(or saxon
,
xalan
).
The string displayed when xsltproc
is used to transform
an XML file via a given XSLT stylesheet.
Additonal command-line flags for the external executable
xsltproc
(or saxon
,
xalan
).
Additonal parameters that are not intended for the XSLT processor executable, but
the XSL processing itself. By default, they get appended at the end of the command line
for saxon
and saxon-xslt
, respectively.
DPATH.
The list of suffixes of files that will be scanned for imported D package files. The default list is:
['.d']
_DVERFLAGS.
DVERPREFIX.
DVERSIONS.
DVERSUFFIX.
The TeX DVI file to PDF file converter.
The command line used to convert TeX DVI files into a PDF file.
The string displayed when a TeX DVI file
is converted into a PDF file.
If this is not set, then $DVIPDFCOM
(the command line) is displayed.
General options passed to the TeX DVI file to PDF file converter.
The TeX DVI file to PostScript converter.
General options passed to the TeX DVI file to PostScript converter.
A dictionary of environment variables
to use when invoking commands. When
$ENV
is used in a command all list
values will be joined using the path separator and any other non-string
values will simply be coerced to a string.
Note that, by default,
scons
does
not
propagate the environment in force when you
execute
scons
to the commands used to build target files.
This is so that builds will be guaranteed
repeatable regardless of the environment
variables set at the time
scons
is invoked.
If you want to propagate your environment variables to the commands executed to build target files, you must do so explicitly:
import os env = Environment(ENV = os.environ)
Note that you can choose only to propagate
certain environment variables.
A common example is
the system
PATH
environment variable,
so that
scons
uses the same utilities
as the invoking shell (or other process):
import os env = Environment(ENV = {'PATH' : os.environ['PATH']})
A function that will be called to escape shell special characters in command lines. The function should take one argument: the command line string to escape; and should return the escaped command line.
The Fortran 03 compiler.
You should normally set the $FORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $F03
if you need to use a specific compiler
or compiler version for Fortran 03 files.
The command line used to compile a Fortran 03 source file to an object file.
You only need to set $F03COM
if you need to use a specific
command line for Fortran 03 files.
You should normally set the $FORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 03 source file
is compiled to an object file.
If this is not set, then $F03COM
or $FORTRANCOM
(the command line) is displayed.
The list of file extensions for which the F03 dialect will be used. By default, this is ['.f03']
General user-specified options that are passed to the Fortran 03 compiler.
Note that this variable does
not
contain
-I
(or similar) include search path options
that scons generates automatically from $F03PATH
.
See
$_F03INCFLAGS
below,
for the variable that expands to those options.
You only need to set $F03FLAGS
if you need to define specific
user options for Fortran 03 files.
You should normally set the $FORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
An automatically-generated construction variable
containing the Fortran 03 compiler command-line options
for specifying directories to be searched for include files.
The value of $_F03INCFLAGS
is created
by appending $INCPREFIX
and $INCSUFFIX
to the beginning and end
of each directory in $F03PATH
.
The list of directories that the Fortran 03 compiler will search for include
directories. The implicit dependency scanner will search these
directories for include files. Don't explicitly put include directory
arguments in $F03FLAGS
because the result will be non-portable
and the directories will not be searched by the dependency scanner. Note:
directory names in $F03PATH
will be looked-up relative to the SConscript
directory when they are used in a command. To force
scons
to look-up a directory relative to the root of the source tree use #:
You only need to set $F03PATH
if you need to define a specific
include path for Fortran 03 files.
You should normally set the $FORTRANPATH
variable,
which specifies the include path
for the default Fortran compiler
for all Fortran versions.
env = Environment(F03PATH='#/include')
The directory look-up can also be forced using the
Dir
()
function:
include = Dir('include') env = Environment(F03PATH=include)
The directory list will be added to command lines
through the automatically-generated
$_F03INCFLAGS
construction variable,
which is constructed by
appending the values of the
$INCPREFIX
and $INCSUFFIX
construction variables
to the beginning and end
of each directory in $F03PATH
.
Any command lines you define that need
the F03PATH directory list should
include $_F03INCFLAGS
:
env = Environment(F03COM="my_compiler $_F03INCFLAGS -c -o $TARGET $SOURCE")
The command line used to compile a Fortran 03 source file to an object file
after first running the file through the C preprocessor.
Any options specified in the $F03FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $F03PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 03 files.
You should normally set the $FORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 03 source file
is compiled to an object file
after first running the file through the C preprocessor.
If this is not set, then $F03PPCOM
or $FORTRANPPCOM
(the command line) is displayed.
The list of file extensions for which the compilation + preprocessor pass for F03 dialect will be used. By default, this is empty
The Fortran 08 compiler.
You should normally set the $FORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $F08
if you need to use a specific compiler
or compiler version for Fortran 08 files.
The command line used to compile a Fortran 08 source file to an object file.
You only need to set $F08COM
if you need to use a specific
command line for Fortran 08 files.
You should normally set the $FORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 08 source file
is compiled to an object file.
If this is not set, then $F08COM
or $FORTRANCOM
(the command line) is displayed.
The list of file extensions for which the F08 dialect will be used. By default, this is ['.f08']
General user-specified options that are passed to the Fortran 08 compiler.
Note that this variable does
not
contain
-I
(or similar) include search path options
that scons generates automatically from $F08PATH
.
See
$_F08INCFLAGS
below,
for the variable that expands to those options.
You only need to set $F08FLAGS
if you need to define specific
user options for Fortran 08 files.
You should normally set the $FORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
An automatically-generated construction variable
containing the Fortran 08 compiler command-line options
for specifying directories to be searched for include files.
The value of $_F08INCFLAGS
is created
by appending $INCPREFIX
and $INCSUFFIX
to the beginning and end
of each directory in $F08PATH
.
The list of directories that the Fortran 08 compiler will search for include
directories. The implicit dependency scanner will search these
directories for include files. Don't explicitly put include directory
arguments in $F08FLAGS
because the result will be non-portable
and the directories will not be searched by the dependency scanner. Note:
directory names in $F08PATH
will be looked-up relative to the SConscript
directory when they are used in a command. To force
scons
to look-up a directory relative to the root of the source tree use #:
You only need to set $F08PATH
if you need to define a specific
include path for Fortran 08 files.
You should normally set the $FORTRANPATH
variable,
which specifies the include path
for the default Fortran compiler
for all Fortran versions.
env = Environment(F08PATH='#/include')
The directory look-up can also be forced using the
Dir
()
function:
include = Dir('include') env = Environment(F08PATH=include)
The directory list will be added to command lines
through the automatically-generated
$_F08INCFLAGS
construction variable,
which is constructed by
appending the values of the
$INCPREFIX
and $INCSUFFIX
construction variables
to the beginning and end
of each directory in $F08PATH
.
Any command lines you define that need
the F08PATH directory list should
include $_F08INCFLAGS
:
env = Environment(F08COM="my_compiler $_F08INCFLAGS -c -o $TARGET $SOURCE")
The command line used to compile a Fortran 08 source file to an object file
after first running the file through the C preprocessor.
Any options specified in the $F08FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $F08PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 08 files.
You should normally set the $FORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 08 source file
is compiled to an object file
after first running the file through the C preprocessor.
If this is not set, then $F08PPCOM
or $FORTRANPPCOM
(the command line) is displayed.
The list of file extensions for which the compilation + preprocessor pass for F08 dialect will be used. By default, this is empty
The Fortran 77 compiler.
You should normally set the $FORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $F77
if you need to use a specific compiler
or compiler version for Fortran 77 files.
The command line used to compile a Fortran 77 source file to an object file.
You only need to set $F77COM
if you need to use a specific
command line for Fortran 77 files.
You should normally set the $FORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 77 source file
is compiled to an object file.
If this is not set, then $F77COM
or $FORTRANCOM
(the command line) is displayed.
The list of file extensions for which the F77 dialect will be used. By default, this is ['.f77']
General user-specified options that are passed to the Fortran 77 compiler.
Note that this variable does
not
contain
-I
(or similar) include search path options
that scons generates automatically from $F77PATH
.
See
$_F77INCFLAGS
below,
for the variable that expands to those options.
You only need to set $F77FLAGS
if you need to define specific
user options for Fortran 77 files.
You should normally set the $FORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
An automatically-generated construction variable
containing the Fortran 77 compiler command-line options
for specifying directories to be searched for include files.
The value of $_F77INCFLAGS
is created
by appending $INCPREFIX
and $INCSUFFIX
to the beginning and end
of each directory in $F77PATH
.
The list of directories that the Fortran 77 compiler will search for include
directories. The implicit dependency scanner will search these
directories for include files. Don't explicitly put include directory
arguments in $F77FLAGS
because the result will be non-portable
and the directories will not be searched by the dependency scanner. Note:
directory names in $F77PATH
will be looked-up relative to the SConscript
directory when they are used in a command. To force
scons
to look-up a directory relative to the root of the source tree use #:
You only need to set $F77PATH
if you need to define a specific
include path for Fortran 77 files.
You should normally set the $FORTRANPATH
variable,
which specifies the include path
for the default Fortran compiler
for all Fortran versions.
env = Environment(F77PATH='#/include')
The directory look-up can also be forced using the
Dir
()
function:
include = Dir('include') env = Environment(F77PATH=include)
The directory list will be added to command lines
through the automatically-generated
$_F77INCFLAGS
construction variable,
which is constructed by
appending the values of the
$INCPREFIX
and $INCSUFFIX
construction variables
to the beginning and end
of each directory in $F77PATH
.
Any command lines you define that need
the F77PATH directory list should
include $_F77INCFLAGS
:
env = Environment(F77COM="my_compiler $_F77INCFLAGS -c -o $TARGET $SOURCE")
The command line used to compile a Fortran 77 source file to an object file
after first running the file through the C preprocessor.
Any options specified in the $F77FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $F77PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 77 files.
You should normally set the $FORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 77 source file
is compiled to an object file
after first running the file through the C preprocessor.
If this is not set, then $F77PPCOM
or $FORTRANPPCOM
(the command line) is displayed.
The list of file extensions for which the compilation + preprocessor pass for F77 dialect will be used. By default, this is empty
The Fortran 90 compiler.
You should normally set the $FORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $F90
if you need to use a specific compiler
or compiler version for Fortran 90 files.
The command line used to compile a Fortran 90 source file to an object file.
You only need to set $F90COM
if you need to use a specific
command line for Fortran 90 files.
You should normally set the $FORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 90 source file
is compiled to an object file.
If this is not set, then $F90COM
or $FORTRANCOM
(the command line) is displayed.
The list of file extensions for which the F90 dialect will be used. By default, this is ['.f90']
General user-specified options that are passed to the Fortran 90 compiler.
Note that this variable does
not
contain
-I
(or similar) include search path options
that scons generates automatically from $F90PATH
.
See
$_F90INCFLAGS
below,
for the variable that expands to those options.
You only need to set $F90FLAGS
if you need to define specific
user options for Fortran 90 files.
You should normally set the $FORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
An automatically-generated construction variable
containing the Fortran 90 compiler command-line options
for specifying directories to be searched for include files.
The value of $_F90INCFLAGS
is created
by appending $INCPREFIX
and $INCSUFFIX
to the beginning and end
of each directory in $F90PATH
.
The list of directories that the Fortran 90 compiler will search for include
directories. The implicit dependency scanner will search these
directories for include files. Don't explicitly put include directory
arguments in $F90FLAGS
because the result will be non-portable
and the directories will not be searched by the dependency scanner. Note:
directory names in $F90PATH
will be looked-up relative to the SConscript
directory when they are used in a command. To force
scons
to look-up a directory relative to the root of the source tree use #:
You only need to set $F90PATH
if you need to define a specific
include path for Fortran 90 files.
You should normally set the $FORTRANPATH
variable,
which specifies the include path
for the default Fortran compiler
for all Fortran versions.
env = Environment(F90PATH='#/include')
The directory look-up can also be forced using the
Dir
()
function:
include = Dir('include') env = Environment(F90PATH=include)
The directory list will be added to command lines
through the automatically-generated
$_F90INCFLAGS
construction variable,
which is constructed by
appending the values of the
$INCPREFIX
and $INCSUFFIX
construction variables
to the beginning and end
of each directory in $F90PATH
.
Any command lines you define that need
the F90PATH directory list should
include $_F90INCFLAGS
:
env = Environment(F90COM="my_compiler $_F90INCFLAGS -c -o $TARGET $SOURCE")
The command line used to compile a Fortran 90 source file to an object file
after first running the file through the C preprocessor.
Any options specified in the $F90FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $F90PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 90 files.
You should normally set the $FORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 90 source file
is compiled after first running the file through the C preprocessor.
If this is not set, then $F90PPCOM
or $FORTRANPPCOM
(the command line) is displayed.
The list of file extensions for which the compilation + preprocessor pass for F90 dialect will be used. By default, this is empty
The Fortran 95 compiler.
You should normally set the $FORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $F95
if you need to use a specific compiler
or compiler version for Fortran 95 files.
The command line used to compile a Fortran 95 source file to an object file.
You only need to set $F95COM
if you need to use a specific
command line for Fortran 95 files.
You should normally set the $FORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 95 source file
is compiled to an object file.
If this is not set, then $F95COM
or $FORTRANCOM
(the command line) is displayed.
The list of file extensions for which the F95 dialect will be used. By default, this is ['.f95']
General user-specified options that are passed to the Fortran 95 compiler.
Note that this variable does
not
contain
-I
(or similar) include search path options
that scons generates automatically from $F95PATH
.
See
$_F95INCFLAGS
below,
for the variable that expands to those options.
You only need to set $F95FLAGS
if you need to define specific
user options for Fortran 95 files.
You should normally set the $FORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
An automatically-generated construction variable
containing the Fortran 95 compiler command-line options
for specifying directories to be searched for include files.
The value of $_F95INCFLAGS
is created
by appending $INCPREFIX
and $INCSUFFIX
to the beginning and end
of each directory in $F95PATH
.
The list of directories that the Fortran 95 compiler will search for include
directories. The implicit dependency scanner will search these
directories for include files. Don't explicitly put include directory
arguments in $F95FLAGS
because the result will be non-portable
and the directories will not be searched by the dependency scanner. Note:
directory names in $F95PATH
will be looked-up relative to the SConscript
directory when they are used in a command. To force
scons
to look-up a directory relative to the root of the source tree use #:
You only need to set $F95PATH
if you need to define a specific
include path for Fortran 95 files.
You should normally set the $FORTRANPATH
variable,
which specifies the include path
for the default Fortran compiler
for all Fortran versions.
env = Environment(F95PATH='#/include')
The directory look-up can also be forced using the
Dir
()
function:
include = Dir('include') env = Environment(F95PATH=include)
The directory list will be added to command lines
through the automatically-generated
$_F95INCFLAGS
construction variable,
which is constructed by
appending the values of the
$INCPREFIX
and $INCSUFFIX
construction variables
to the beginning and end
of each directory in $F95PATH
.
Any command lines you define that need
the F95PATH directory list should
include $_F95INCFLAGS
:
env = Environment(F95COM="my_compiler $_F95INCFLAGS -c -o $TARGET $SOURCE")
The command line used to compile a Fortran 95 source file to an object file
after first running the file through the C preprocessor.
Any options specified in the $F95FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $F95PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 95 files.
You should normally set the $FORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 95 source file
is compiled to an object file
after first running the file through the C preprocessor.
If this is not set, then $F95PPCOM
or $FORTRANPPCOM
(the command line) is displayed.
The list of file extensions for which the compilation + preprocessor pass for F95 dialect will be used. By default, this is empty
A function that converts a string into a File instance relative to the target being built.
A function that converts a string into a File instance relative to the target being built.
The default Fortran compiler for all versions of Fortran.
The command line used to compile a Fortran source file to an object file.
By default, any options specified
in the $FORTRANFLAGS
,
$CPPFLAGS
,
$_CPPDEFFLAGS
,
$_FORTRANMODFLAG
, and
$_FORTRANINCFLAGS
construction variables
are included on this command line.
The string displayed when a Fortran source file
is compiled to an object file.
If this is not set, then $FORTRANCOM
(the command line) is displayed.
The list of file extensions for which the FORTRAN dialect will be used. By default, this is ['.f', '.for', '.ftn']
General user-specified options that are passed to the Fortran compiler.
Note that this variable does
not
contain
-I
(or similar) include or module search path options
that scons generates automatically from $FORTRANPATH
.
See
$_FORTRANINCFLAGS
and $_FORTRANMODFLAG
,
below,
for the variables that expand those options.
An automatically-generated construction variable
containing the Fortran compiler command-line options
for specifying directories to be searched for include
files and module files.
The value of $_FORTRANINCFLAGS
is created
by prepending/appending $INCPREFIX
and $INCSUFFIX
to the beginning and end
of each directory in $FORTRANPATH
.
Directory location where the Fortran compiler should place any module files it generates. This variable is empty, by default. Some Fortran compilers will internally append this directory in the search path for module files, as well.
The prefix used to specify a module directory on the Fortran compiler command
line.
This will be appended to the beginning of the directory
in the $FORTRANMODDIR
construction variables
when the $_FORTRANMODFLAG
variables is automatically generated.
The suffix used to specify a module directory on the Fortran compiler command
line.
This will be appended to the beginning of the directory
in the $FORTRANMODDIR
construction variables
when the $_FORTRANMODFLAG
variables is automatically generated.
An automatically-generated construction variable
containing the Fortran compiler command-line option
for specifying the directory location where the Fortran
compiler should place any module files that happen to get
generated during compilation.
The value of $_FORTRANMODFLAG
is created
by prepending/appending $FORTRANMODDIRPREFIX
and
$FORTRANMODDIRSUFFIX
to the beginning and end of the directory in $FORTRANMODDIR
.
The module file prefix used by the Fortran compiler. SCons assumes that
the Fortran compiler follows the quasi-standard naming convention for
module files of
module_name.mod
.
As a result, this variable is left empty, by default. For situations in
which the compiler does not necessarily follow the normal convention,
the user may use this variable. Its value will be appended to every
module file name as scons attempts to resolve dependencies.
The module file suffix used by the Fortran compiler. SCons assumes that
the Fortran compiler follows the quasi-standard naming convention for
module files of
module_name.mod
.
As a result, this variable is set to ".mod", by default. For situations
in which the compiler does not necessarily follow the normal convention,
the user may use this variable. Its value will be appended to every
module file name as scons attempts to resolve dependencies.
The list of directories that the Fortran compiler will search for
include files and (for some compilers) module files. The Fortran implicit
dependency scanner will search these directories for include files (but
not module files since they are autogenerated and, as such, may not
actually exist at the time the scan takes place). Don't explicitly put
include directory arguments in FORTRANFLAGS because the result will be
non-portable and the directories will not be searched by the dependency
scanner. Note: directory names in FORTRANPATH will be looked-up relative
to the SConscript directory when they are used in a command. To force
scons
to look-up a directory relative to the root of the source tree use #:
env = Environment(FORTRANPATH='#/include')
The directory look-up can also be forced using the
Dir
()
function:
include = Dir('include') env = Environment(FORTRANPATH=include)
The directory list will be added to command lines
through the automatically-generated
$_FORTRANINCFLAGS
construction variable,
which is constructed by
appending the values of the
$INCPREFIX
and $INCSUFFIX
construction variables
to the beginning and end
of each directory in $FORTRANPATH
.
Any command lines you define that need
the FORTRANPATH directory list should
include $_FORTRANINCFLAGS
:
env = Environment(FORTRANCOM="my_compiler $_FORTRANINCFLAGS -c -o $TARGET $SOURCE")
The command line used to compile a Fortran source file to an object file
after first running the file through the C preprocessor.
By default, any options specified in the $FORTRANFLAGS
,
$CPPFLAGS
,
$_CPPDEFFLAGS
,
$_FORTRANMODFLAG
, and
$_FORTRANINCFLAGS
construction variables are included on this command line.
The string displayed when a Fortran source file
is compiled to an object file
after first running the file through the C preprocessor.
If this is not set, then $FORTRANPPCOM
(the command line) is displayed.
The list of file extensions for which the compilation + preprocessor pass for FORTRAN dialect will be used. By default, this is ['.fpp', '.FPP']
The list of suffixes of files that will be scanned for Fortran implicit dependencies (INCLUDE lines and USE statements). The default list is:
[".f", ".F", ".for", ".FOR", ".ftn", ".FTN", ".fpp", ".FPP", ".f77", ".F77", ".f90", ".F90", ".f95", ".F95"]
On Mac OS X with gcc,
a list containing the paths to search for frameworks.
Used by the compiler to find framework-style includes like
#include <Fmwk/Header.h>.
Used by the linker to find user-specified frameworks when linking (see
$FRAMEWORKS
).
For example:
env.AppendUnique(FRAMEWORKPATH='#myframeworkdir')
will add
... -Fmyframeworkdir
to the compiler and linker command lines.
On Mac OS X with gcc, an automatically-generated construction variable
containing the linker command-line options corresponding to
$FRAMEWORKPATH
.
On Mac OS X with gcc, the prefix to be used for the FRAMEWORKPATH entries.
(see $FRAMEWORKPATH
).
The default value is
-F
.
On Mac OS X with gcc,
the prefix to be used for linking in frameworks
(see $FRAMEWORKS
).
The default value is
-framework
.
On Mac OS X with gcc, an automatically-generated construction variable containing the linker command-line options for linking with FRAMEWORKS.
On Mac OS X with gcc, a list of the framework names to be linked into a program or shared library or bundle. The default value is the empty list. For example:
env.AppendUnique(FRAMEWORKS=Split('System Cocoa SystemConfiguration'))
On Mac OS X with gcc,
general user-supplied frameworks options to be added at
the end of a command
line building a loadable module.
(This has been largely superseded by
the $FRAMEWORKPATH
, $FRAMEWORKPATHPREFIX
,
$FRAMEWORKPREFIX
and $FRAMEWORKS
variables
described above.)
The Ghostscript program used, e.g. to convert PostScript to PDF files.
The full Ghostscript command line used for the conversion process. Its default
value is “$GS $GSFLAGS -sOutputFile=$TARGET $SOURCES
”.
The string displayed when
Ghostscript is called for the conversion process.
If this is not set (the default), then $GSCOM
(the command line) is displayed.
General options passed to the Ghostscript program,
when converting PostScript to PDF files for example. Its default value
is “-dNOPAUSE -dBATCH -sDEVICE=pdfwrite
”
The name of the host hardware architecture used to create the Environment. If a platform is specified when creating the Environment, then that Platform's logic will handle setting this value. This value is immutable, and should not be changed by the user after the Environment is initialized. Currently only set for Win32.
Sets the host architecture for Visual Studio compiler. If not set, default to the detected host architecture: note that this may depend on the python you are using. This variable must be passed as an argument to the Environment() constructor; setting it later has no effect.
Valid values are the same as for $TARGET_ARCH
.
This is currently only used on Windows, but in the future it will be used on other OSes as well.
The name of the host operating system used to create the Environment. If a platform is specified when creating the Environment, then that Platform's logic will handle setting this value. This value is immutable, and should not be changed by the user after the Environment is initialized. Currently only set for Win32.
The list of suffixes of files that will be scanned for IDL implicit dependencies (#include or import lines). The default list is:
[".idl", ".IDL"]
Controls whether or not SCons will add implicit dependencies for the commands executed to build targets.
By default, SCons will add
to each target
an implicit dependency on the command
represented by the first argument on any
command line it executes.
The specific file for the dependency is
found by searching the
PATH
variable in the
ENV
environment used to execute the command.
If the construction variable
$IMPLICIT_COMMAND_DEPENDENCIES
is set to a false value
(None
,
False
,
0
,
etc.),
then the implicit dependency will
not be added to the targets
built with that construction environment.
env = Environment(IMPLICIT_COMMAND_DEPENDENCIES = 0)
The prefix used to specify an include directory on the C compiler command
line.
This will be appended to the beginning of each directory
in the $CPPPATH
and $FORTRANPATH
construction variables
when the $_CPPINCFLAGS
and $_FORTRANINCFLAGS
variables are automatically generated.
The suffix used to specify an include directory on the C compiler command
line.
This will be appended to the end of each directory
in the $CPPPATH
and $FORTRANPATH
construction variables
when the $_CPPINCFLAGS
and $_FORTRANINCFLAGS
variables are automatically generated.
A function to be called to install a file into a destination file name. The default function copies the file into the destination (and sets the destination file's mode and permission bits to match the source file's). The function takes the following arguments:
def install(dest, source, env):
dest
is the path name of the destination file.
source
is the path name of the source file.
env
is the construction environment
(a dictionary of construction values)
in force for this file installation.
The string displayed when a file is installed into a destination file name. The default is:
Install file: "$SOURCE" as "$TARGET"
Set by the "intelc" Tool to the major version number of the Intel C compiler selected for use.
The Java archive tool.
The Java archive tool.
The directory to which the Java archive tool should change
(using the
-C
option).
The directory to which the Java archive tool should change
(using the
-C
option).
The command line used to call the Java archive tool.
The command line used to call the Java archive tool.
The string displayed when the Java archive tool
is called
If this is not set, then $JARCOM
(the command line) is displayed.
env = Environment(JARCOMSTR = "JARchiving $SOURCES into $TARGET")
The string displayed when the Java archive tool
is called
If this is not set, then $JARCOM
(the command line) is displayed.
env = Environment(JARCOMSTR = "JARchiving $SOURCES into $TARGET")
General options passed to the Java archive tool.
By default this is set to
cf
to create the necessary
jar
file.
General options passed to the Java archive tool.
By default this is set to
cf
to create the necessary
jar
file.
The suffix for Java archives:
.jar
by default.
The suffix for Java archives:
.jar
by default.
Specifies the list of directories that
will be added to the
javac command line
via the -bootclasspath
option.
The individual directory names will be
separated by the operating system's path separate character
(:
on UNIX/Linux/POSIX,
;
on Windows).
The Java compiler.
The command line used to compile a directory tree containing
Java source files to
corresponding Java class files.
Any options specified in the $JAVACFLAGS
construction variable
are included on this command line.
The string displayed when compiling
a directory tree of Java source files to
corresponding Java class files.
If this is not set, then $JAVACCOM
(the command line) is displayed.
env = Environment(JAVACCOMSTR = "Compiling class files $TARGETS from $SOURCES")
General options that are passed to the Java compiler.
The directory in which Java class files may be found.
This is stripped from the beginning of any Java .class
file names supplied to the
JavaH
builder.
Specifies the list of directories that
will be searched for Java
.class
file.
The directories in this list will be added to the
javac and javah command lines
via the -classpath
option.
The individual directory names will be
separated by the operating system's path separate character
(:
on UNIX/Linux/POSIX,
;
on Windows).
Note that this currently just adds the specified
directory via the -classpath
option.
SCons does not currently search the
$JAVACLASSPATH
directories for dependency
.class
files.
The suffix for Java class files;
.class
by default.
The Java generator for C header and stub files.
The command line used to generate C header and stub files
from Java classes.
Any options specified in the $JAVAHFLAGS
construction variable
are included on this command line.
The string displayed when C header and stub files
are generated from Java classes.
If this is not set, then $JAVAHCOM
(the command line) is displayed.
env = Environment(JAVAHCOMSTR = "Generating header/stub file(s) $TARGETS from $SOURCES")
General options passed to the C header and stub file generator for Java classes.
Specifies the list of directories that
will be searched for input
.java
file.
The directories in this list will be added to the
javac command line
via the -sourcepath
option.
The individual directory names will be
separated by the operating system's path separate character
(:
on UNIX/Linux/POSIX,
;
on Windows).
Note that this currently just adds the specified
directory via the -sourcepath
option.
SCons does not currently search the
$JAVASOURCEPATH
directories for dependency
.java
files.
The suffix for Java files;
.java
by default.
Specifies the Java version being used by the Java
builder.
This is not currently used to select one
version of the Java compiler vs. another.
Instead, you should set this to specify the version of Java
supported by your javac compiler.
The default is 1.4
.
This is sometimes necessary because
Java 1.5 changed the file names that are created
for nested anonymous inner classes,
which can cause a mismatch with the files
that SCons expects will be generated by the javac compiler.
Setting $JAVAVERSION
to 1.5
(or 1.6
, as appropriate)
can make SCons realize that a Java 1.5 or 1.6
build is actually up to date.
The LaTeX structured formatter and typesetter.
The command line used to call the LaTeX structured formatter and typesetter.
The string displayed when calling
the LaTeX structured formatter and typesetter.
If this is not set, then $LATEXCOM
(the command line) is displayed.
env = Environment(LATEXCOMSTR = "Building $TARGET from LaTeX input $SOURCES")
General options passed to the LaTeX structured formatter and typesetter.
The maximum number of times that LaTeX
will be re-run if the
.log
generated by the $LATEXCOM
command
indicates that there are undefined references.
The default is to try to resolve undefined references
by re-running LaTeX up to three times.
The list of suffixes of files that will be scanned
for LaTeX implicit dependencies
(\include
or \import
files).
The default list is:
[".tex", ".ltx", ".latex"]
The linker for building loadable modules.
By default, this is the same as $SHLINK
.
The command line for building loadable modules.
On Mac OS X, this uses the $LDMODULE
,
$LDMODULEFLAGS
and
$FRAMEWORKSFLAGS
variables.
On other systems, this is the same as $SHLINK
.
The string displayed when building loadable modules.
If this is not set, then $LDMODULECOM
(the command line) is displayed.
General user options passed to the linker for building loadable modules.
The prefix used for loadable module file names.
On Mac OS X, this is null;
on other systems, this is
the same as $SHLIBPREFIX
.
The suffix used for loadable module file names. On Mac OS X, this is null; on other systems, this is the same as $SHLIBSUFFIX.
The lexical analyzer generator.
The command line used to call the lexical analyzer generator to generate a source file.
The string displayed when generating a source file
using the lexical analyzer generator.
If this is not set, then $LEXCOM
(the command line) is displayed.
env = Environment(LEXCOMSTR = "Lex'ing $TARGET from $SOURCES")
General options passed to the lexical analyzer generator.
An automatically-generated construction variable
containing the linker command-line options
for specifying directories to be searched for library.
The value of $_LIBDIRFLAGS
is created
by appending $LIBDIRPREFIX
and $LIBDIRSUFFIX
to the beginning and end
of each directory in $LIBPATH
.
The prefix used to specify a library directory on the linker command line.
This will be appended to the beginning of each directory
in the $LIBPATH
construction variable
when the $_LIBDIRFLAGS
variable is automatically generated.
The suffix used to specify a library directory on the linker command line.
This will be appended to the end of each directory
in the $LIBPATH
construction variable
when the $_LIBDIRFLAGS
variable is automatically generated.
TODO
An automatically-generated construction variable
containing the linker command-line options
for specifying libraries to be linked with the resulting target.
The value of $_LIBFLAGS
is created
by appending $LIBLINKPREFIX
and $LIBLINKSUFFIX
to the beginning and end
of each filename in $LIBS
.
The prefix used to specify a library to link on the linker command line.
This will be appended to the beginning of each library
in the $LIBS
construction variable
when the $_LIBFLAGS
variable is automatically generated.
The suffix used to specify a library to link on the linker command line.
This will be appended to the end of each library
in the $LIBS
construction variable
when the $_LIBFLAGS
variable is automatically generated.
The list of directories that will be searched for libraries.
The implicit dependency scanner will search these
directories for include files. Don't explicitly put include directory
arguments in $LINKFLAGS
or $SHLINKFLAGS
because the result will be non-portable
and the directories will not be searched by the dependency scanner. Note:
directory names in LIBPATH will be looked-up relative to the SConscript
directory when they are used in a command. To force
scons
to look-up a directory relative to the root of the source tree use #:
env = Environment(LIBPATH='#/libs')
The directory look-up can also be forced using the
Dir
()
function:
libs = Dir('libs') env = Environment(LIBPATH=libs)
The directory list will be added to command lines
through the automatically-generated
$_LIBDIRFLAGS
construction variable,
which is constructed by
appending the values of the
$LIBDIRPREFIX
and $LIBDIRSUFFIX
construction variables
to the beginning and end
of each directory in $LIBPATH
.
Any command lines you define that need
the LIBPATH directory list should
include $_LIBDIRFLAGS
:
env = Environment(LINKCOM="my_linker $_LIBDIRFLAGS $_LIBFLAGS -o $TARGET $SOURCE")
The prefix used for (static) library file names. A default value is set for each platform (posix, win32, os2, etc.), but the value is overridden by individual tools (ar, mslib, sgiar, sunar, tlib, etc.) to reflect the names of the libraries they create.
A list of all legal prefixes for library file names.
When searching for library dependencies,
SCons will look for files with these prefixes,
the base library name,
and suffixes in the $LIBSUFFIXES
list.
A list of one or more libraries that will be linked with any executable programs created by this environment.
The library list will be added to command lines
through the automatically-generated
$_LIBFLAGS
construction variable,
which is constructed by
appending the values of the
$LIBLINKPREFIX
and $LIBLINKSUFFIX
construction variables
to the beginning and end
of each filename in $LIBS
.
Any command lines you define that need
the LIBS library list should
include $_LIBFLAGS
:
env = Environment(LINKCOM="my_linker $_LIBDIRFLAGS $_LIBFLAGS -o $TARGET $SOURCE")
If you add a
File
object to the
$LIBS
list, the name of that file will be added to
$_LIBFLAGS
,
and thus the link line, as is, without
$LIBLINKPREFIX
or
$LIBLINKSUFFIX
.
For example:
env.Append(LIBS=File('/tmp/mylib.so'))
In all cases, scons will add dependencies from the executable program to all the libraries in this list.
The suffix used for (static) library file names. A default value is set for each platform (posix, win32, os2, etc.), but the value is overridden by individual tools (ar, mslib, sgiar, sunar, tlib, etc.) to reflect the names of the libraries they create.
A list of all legal suffixes for library file names.
When searching for library dependencies,
SCons will look for files with prefixes, in the $LIBPREFIXES
list,
the base library name,
and these suffixes.
The abbreviated name of the license under which this project is released (gpl, lpgl, bsd etc.). See http://www.opensource.org/licenses/alphabetical for a list of license names.
The separator used by the Substfile
and Textfile
builders.
This value is used between sources when constructing the target.
It defaults to the current system line separator.
The $LINGUAS_FILE
defines file(s) containing list of additional linguas
to be processed by POInit
, POUpdate
or MOFiles
builders. It also affects Translate
builder. If the variable contains
a string, it defines name of the list file. The $LINGUAS_FILE
may be a
list of file names as well. If $LINGUAS_FILE
is set to
True
(or non-zero numeric value), the list will be read from
default file named
LINGUAS
.
The linker.
The command line used to link object files into an executable.
The string displayed when object files
are linked into an executable.
If this is not set, then $LINKCOM
(the command line) is displayed.
env = Environment(LINKCOMSTR = "Linking $TARGET")
General user options passed to the linker.
Note that this variable should
not
contain
-l
(or similar) options for linking with the libraries listed in $LIBS
,
nor
-L
(or similar) library search path options
that scons generates automatically from $LIBPATH
.
See
$_LIBFLAGS
above,
for the variable that expands to library-link options,
and
$_LIBDIRFLAGS
above,
for the variable that expands to library search path options.
The M4 macro preprocessor.
The command line used to pass files through the M4 macro preprocessor.
The string displayed when
a file is passed through the M4 macro preprocessor.
If this is not set, then $M4COM
(the command line) is displayed.
General options passed to the M4 macro preprocessor.
The makeindex generator for the TeX formatter and typesetter and the LaTeX structured formatter and typesetter.
The command line used to call the makeindex generator for the TeX formatter and typesetter and the LaTeX structured formatter and typesetter.
The string displayed when calling the makeindex generator for the
TeX formatter and typesetter
and the LaTeX structured formatter and typesetter.
If this is not set, then $MAKEINDEXCOM
(the command line) is displayed.
General options passed to the makeindex generator for the TeX formatter and typesetter and the LaTeX structured formatter and typesetter.
The maximum number of characters allowed on an external command line. On Win32 systems, link lines longer than this many characters are linked via a temporary file name.
The Microsoft IDL compiler.
The command line used to pass files to the Microsoft IDL compiler.
The string displayed when
the Microsoft IDL copmiler is called.
If this is not set, then $MIDLCOM
(the command line) is displayed.
General options passed to the Microsoft IDL compiler.
Suffix used for MO
files (default: '.mo'
).
See msgfmt
tool and MOFiles
builder.
Absolute path to msgfmt(1) binary, found by
Detect()
.
See msgfmt
tool and MOFiles
builder.
Complete command line to run msgfmt(1) program.
See msgfmt
tool and MOFiles
builder.
String to display when msgfmt(1) is invoked
(default: ''
, which means ``print $MSGFMTCOM
'').
See msgfmt
tool and MOFiles
builder.
Additional flags to msgfmt(1).
See msgfmt
tool and MOFiles
builder.
Path to msginit(1) program (found via
Detect()
).
See msginit
tool and POInit
builder.
Complete command line to run msginit(1) program.
See msginit
tool and POInit
builder.
String to display when msginit(1) is invoked
(default: ''
, which means ``print $MSGINITCOM
'').
See msginit
tool and POInit
builder.
List of additional flags to msginit(1) (default:
[]
).
See msginit
tool and POInit
builder.
Internal ``macro''. Computes locale (language) name based on target filename
(default: '${TARGET.filebase}'
).
Absolute path to msgmerge(1) binary as found by
Detect()
.
See msgmerge
tool and POUpdate
builder.
Complete command line to run msgmerge(1) command.
See msgmerge
tool and POUpdate
builder.
String to be displayed when msgmerge(1) is invoked
(default: ''
, which means ``print $MSGMERGECOM
'').
See msgmerge
tool and POUpdate
builder.
Additional flags to msgmerge(1) command.
See msgmerge
tool and POUpdate
builder.
The directory containing the Microsoft SDK (either Platform SDK or Windows SDK) to be used for compilation.
The version string of the Microsoft SDK
(either Platform SDK or Windows SDK)
to be used for compilation.
Supported versions include
6.1
,
6.0A
,
6.0
,
2003R2
and
2003R1
.
When set to any true value,
specifies that SCons should batch
compilation of object files
when calling the Microsoft Visual C/C++ compiler.
All compilations of source files from the same source directory
that generate target files in a same output directory
and were configured in SCons using the same construction environment
will be built in a single call to the compiler.
Only source files that have changed since their
object files were built will be passed to each compiler invocation
(via the $CHANGED_SOURCES
construction variable).
Any compilations where the object (target) file base name
(minus the .obj
)
does not match the source file base name
will be compiled separately.
Use a batch script to set up Microsoft Visual Studio compiler
$MSVC_USE_SCRIPT
overrides $MSVC_VERSION
and $TARGET_ARCH
.
If set to the name of a Visual Studio .bat file (e.g. vcvars.bat),
SCons will run that bat file and extract the relevant variables from
the result (typically %INCLUDE%, %LIB%, and %PATH%). Setting
MSVC_USE_SCRIPT to None bypasses the Visual Studio autodetection
entirely; use this if you are running SCons in a Visual Studio cmd
window and importing the shell's environment variables.
Sets the preferred version of Microsoft Visual C/C++ to use.
If $MSVC_VERSION
is not set, SCons will (by default) select the
latest version of Visual C/C++ installed on your system. If the
specified version isn't installed, tool initialization will fail.
This variable must be passed as an argument to the Environment()
constructor; setting it later has no effect.
Valid values for Windows are
12.0
,
12.0Exp
,
11.0
,
11.0Exp
,
10.0
,
10.0Exp
,
9.0
,
9.0Exp
,
8.0
,
8.0Exp
,
7.1
,
7.0
,
and 6.0
.
Versions ending in Exp
refer to "Express" or
"Express for Desktop" editions.
When the Microsoft Visual Studio tools are initialized, they set up this dictionary with the following keys:
the version of MSVS being used (can be set via
$MSVS_VERSION
)
the available versions of MSVS installed
installed directory of Visual C++
installed directory of Visual Studio
installed directory of the .NET framework
list of installed versions of the .NET framework, sorted latest to oldest.
latest installed version of the .NET framework
installed location of the .NET SDK.
installed location of the Platform SDK.
dictionary of installed Platform SDK modules, where the dictionary keys are keywords for the various modules, and the values are 2-tuples where the first is the release date, and the second is the version number.
If a value isn't set, it wasn't available in the registry.
Sets the architecture for which the generated project(s) should build.
The default value is x86
. amd64
is
also supported by SCons for some Visual Studio versions. Trying to set
$MSVS_ARCH
to an architecture that's not supported for a given Visual
Studio version will generate an error.
The string placed in a generated
Microsoft Visual Studio project file as the value of the
ProjectGUID
attribute. There is no default value. If not
defined, a new GUID is generated.
The path name placed in a generated
Microsoft Visual Studio project file as the value of the
SccAuxPath
attribute if the
MSVS_SCC_PROVIDER
construction variable is also set. There is
no default value.
The root path of projects in
your SCC workspace, i.e the path under which all project and solution files
will be generated. It is used as a reference path from which the relative
paths of the generated Microsoft Visual Studio project and solution files are
computed. The relative project file path is placed as the value of the
SccLocalPath
attribute of the project file and as the
values of the
SccProjectFilePathRelativizedFromConnection[i]
(where [i]
ranges from 0 to the number of projects in the solution) attributes of the
GlobalSection(SourceCodeControl)
section of the Microsoft
Visual Studio solution file. Similarly the relative solution file path is
placed as the values of the SccLocalPath[i]
(where [i]
ranges from 0 to the number of projects in the solution) attributes of the
GlobalSection(SourceCodeControl)
section of the Microsoft
Visual Studio solution file. This is used only if the
MSVS_SCC_PROVIDER
construction variable is also set. The
default value is the current working directory.
The project name placed in
a generated Microsoft Visual Studio project file as the value of the
SccProjectName
attribute if the
MSVS_SCC_PROVIDER
construction variable is also set. In this
case the string is also placed in the SccProjectName0
attribute of the GlobalSection(SourceCodeControl)
section
of the Microsoft Visual Studio solution file. There is no default value.
The
string placed in a generated Microsoft Visual Studio project file as the value
of the SccProvider
attribute. The string is also placed in
the SccProvider0
attribute of the
GlobalSection(SourceCodeControl)
section of the Microsoft
Visual Studio solution file. There is no default value.
Sets the preferred version of Microsoft Visual Studio to use.
If $MSVS_VERSION
is not
set, SCons will (by default) select the latest version of Visual Studio
installed on your system. So, if you have version 6 and version 7 (MSVS .NET)
installed, it will prefer version 7. You can override this by specifying the
MSVS_VERSION
variable in the Environment initialization,
setting it to the appropriate version ('6.0' or '7.0', for example). If the
specified version isn't installed, tool initialization will fail.
This is obsolete: use $MSVC_VERSION
instead. If $MSVS_VERSION
is
set and $MSVC_VERSION
is not, $MSVC_VERSION
will be set automatically
to $MSVS_VERSION
. If both are set to different values, scons will raise an
error.
The build command line placed in a generated Microsoft Visual Studio project file. The default is to have Visual Studio invoke SCons with any specified build targets.
The clean command line placed in a generated Microsoft Visual Studio project file. The default is to have Visual Studio invoke SCons with the -c option to remove any specified targets.
The encoding string placed in a
generated Microsoft Visual Studio project file. The default is encoding
Windows-1252
.
The action used to generate Microsoft Visual Studio project files.
The suffix used for Microsoft Visual
Studio project (DSP) files. The default value is .vcproj
when using Visual Studio version 7.x (.NET) or later version, and
.dsp
when using earlier versions of Visual Studio.
The rebuild command line placed in a generated Microsoft Visual Studio project file. The default is to have Visual Studio invoke SCons with any specified rebuild targets.
The SCons used in generated Microsoft Visual Studio project files. The default is the version of SCons being used to generate the project file.
The default SCons command used in generated Microsoft Visual Studio project files.
The sconscript
file (that is, SConstruct
or SConscript
file) that will be invoked by
Visual Studio project files (through the $MSVSSCONSCOM
variable). The
default is the same sconscript file that contains the call to MSVSProject
to build the project file.
The SCons flags used in generated Microsoft Visual Studio project files.
The action used to generate Microsoft Visual Studio solution files.
The suffix used for Microsoft
Visual Studio solution (DSW) files. The default value is
.sln
when using Visual Studio version 7.x (.NET), and
.dsw
when using earlier versions of Visual Studio.
The program used on Windows systems to embed manifests into DLLs and EXEs.
See also $WINDOWS_EMBED_MANIFEST
.
The Windows command line used to embed manifests into executables.
See also $MTSHLIBCOM
.
Flags passed to the $MT
manifest embedding program (Windows only).
The Windows command line used to embed manifests into shared libraries (DLLs).
See also $MTEXECOM
.
The version number of the MetroWerks CodeWarrior C compiler to be used.
A list of installed versions of the MetroWerks CodeWarrior C compiler on this system.
Specfies the name of the project to package.
When set to non-zero,
suppresses creation of a corresponding Windows static import lib by the
SharedLibrary
builder when used with
MinGW, Microsoft Visual Studio or Metrowerks.
This also suppresses creation
of an export (.exp) file
when using Microsoft Visual Studio.
The prefix used for (static) object file names.
The suffix used for (static) object file names.
The Perforce executable.
The command line used to fetch source files from Perforce.
The string displayed when
fetching a source file from Perforce.
If this is not set, then $P4COM
(the command line) is displayed.
General options that are passed to Perforce.
Specifies the directory where all files in resulting archive will be placed if applicable. The default value is "$NAME-$VERSION".
Selects the package type to build. Currently these are available:
* msi - Microsoft Installer * rpm - Redhat Package Manger * ipkg - Itsy Package Management System * tarbz2 - compressed tar * targz - compressed tar * zip - zip file * src_tarbz2 - compressed tar source * src_targz - compressed tar source * src_zip - zip file source
This may be overridden with the "package_type" command line option.
The version of the package (not the underlying project). This is currently only used by the rpm packager and should reflect changes in the packaging, not the underlying project code itself.
The Microsoft Visual C++ precompiled header that will be used when compiling object files. This variable is ignored by tools other than Microsoft Visual C++. When this variable is defined SCons will add options to the compiler command line to cause it to use the precompiled header, and will also set up the dependencies for the PCH file. Example:
env['PCH'] = 'StdAfx.pch'
The command line used by the
PCH
builder to generated a precompiled header.
The string displayed when generating a precompiled header.
If this is not set, then $PCHCOM
(the command line) is displayed.
A construction variable that, when expanded,
adds the /yD
flag to the command line
only if the $PDB
construction variable is set.
This variable specifies how much of a source file is precompiled. This variable is ignored by tools other than Microsoft Visual C++, or when the PCH variable is not being used. When this variable is define it must be a string that is the name of the header that is included at the end of the precompiled portion of the source files, or the empty string if the "#pragma hrdstop" construct is being used:
env['PCHSTOP'] = 'StdAfx.h'
The Microsoft Visual C++ PDB file that will store debugging information for object files, shared libraries, and programs. This variable is ignored by tools other than Microsoft Visual C++. When this variable is defined SCons will add options to the compiler and linker command line to cause them to generate external debugging information, and will also set up the dependencies for the PDB file. Example:
env['PDB'] = 'hello.pdb'
The Visual C++ compiler switch that SCons uses by default
to generate PDB information is /Z7
.
This works correctly with parallel (-j
) builds
because it embeds the debug information in the intermediate object files,
as opposed to sharing a single PDB file between multiple object files.
This is also the only way to get debug information
embedded into a static library.
Using the /Zi
instead may yield improved
link-time performance,
although parallel builds will no longer work.
You can generate PDB files with the /Zi
switch by overriding the default $CCPDBFLAGS
variable;
see the entry for that variable for specific examples.
A deprecated synonym for $DVIPDFCOM
.
The pdflatex utility.
The command line used to call the pdflatex utility.
The string displayed when calling the pdflatex utility.
If this is not set, then $PDFLATEXCOM
(the command line) is displayed.
env = Environment(PDFLATEX;COMSTR = "Building $TARGET from LaTeX input $SOURCES")
General options passed to the pdflatex utility.
The prefix used for PDF file names.
The suffix used for PDF file names.
The pdftex utility.
The command line used to call the pdftex utility.
The string displayed when calling the pdftex utility.
If this is not set, then $PDFTEXCOM
(the command line) is displayed.
env = Environment(PDFTEXCOMSTR = "Building $TARGET from TeX input $SOURCES")
General options passed to the pdftex utility.
On Solaris systems,
the package-checking program that will
be used (along with $PKGINFO
)
to look for installed versions of
the Sun PRO C++ compiler.
The default is
/usr/sbin/pgkchk
.
On Solaris systems,
the package information program that will
be used (along with $PKGCHK
)
to look for installed versions of
the Sun PRO C++ compiler.
The default is
pkginfo
.
The name of the platform used to create the Environment. If no platform is
specified when the Environment is created,
scons
autodetects the platform.
env = Environment(tools = []) if env['PLATFORM'] == 'cygwin': Tool('mingw')(env) else: Tool('msvc')(env)
The $POAUTOINIT
variable, if set to True
(on non-zero
numeric value), let the msginit
tool to automatically initialize
missing PO
files with
msginit(1). This applies to both,
POInit
and POUpdate
builders (and others that use any of
them).
Common alias for all PO
files created with POInit
builder (default: 'po-create'
).
See msginit
tool and POInit
builder.
Suffix used for PO
files (default: '.po'
)
See msginit
tool and POInit
builder.
The $POTDOMAIN
defines default domain, used to generate
POT
filename as
when
no $POTDOMAIN
.potPOT
file name is provided by the user. This applies to
POTUpdate
, POInit
and POUpdate
builders (and
builders, that use them, e.g. Translate
). Normally (if $POTDOMAIN
is
not defined), the builders use messages.pot
as default
POT
file name.
Suffix used for PO Template files (default: '.pot'
).
See xgettext
tool and POTUpdate
builder.
Name of the common phony target for all PO Templates created with
POUpdate
(default: 'pot-update'
).
See xgettext
tool and POTUpdate
builder.
Common alias for all PO
files being defined with
POUpdate
builder (default: 'po-update'
).
See msgmerge
tool and POUpdate
builder.
A Python function used to print the command lines as they are executed
(assuming command printing is not disabled by the
-q
or
-s
options or their equivalents).
The function should take four arguments:
s
,
the command being executed (a string),
target
,
the target being built (file node, list, or string name(s)),
source
,
the source(s) used (file node, list, or string name(s)), and
env
,
the environment being used.
The function must do the printing itself. The default implementation, used if this variable is not set or is None, is:
def print_cmd_line(s, target, source, env): sys.stdout.write(s + "\n")
Here's an example of a more interesting function:
def print_cmd_line(s, target, source, env): sys.stdout.write("Building %s -> %s...\n" % (' and '.join([str(x) for x in source]), ' and '.join([str(x) for x in target]))) env=Environment(PRINT_CMD_LINE_FUNC=print_cmd_line) env.Program('foo', 'foo.c')
This just prints "Building targetname
from sourcename
..." instead
of the actual commands.
Such a function could also log the actual commands to a log file,
for example.
TODO
The prefix used for executable file names.
The suffix used for executable file names.
The command line used to convert TeX DVI files into a PostScript file.
The string displayed when a TeX DVI file
is converted into a PostScript file.
If this is not set, then $PSCOM
(the command line) is displayed.
The prefix used for PostScript file names.
The prefix used for PostScript file names.
Turn off scanning for mocable files. Use the Moc Builder to explicitly specify files to run moc on.
The path where the qt binaries are installed.
The default value is '$QTDIR
/bin'.
The path where the qt header files are installed.
The default value is '$QTDIR
/include'.
Note: If you set this variable to None,
the tool won't change the $CPPPATH
construction variable.
Prints lots of debugging information while scanning for moc files.
Default value is 'qt'. You may want to set this to 'qt-mt'. Note: If you set
this variable to None, the tool won't change the $LIBS
variable.
The path where the qt libraries are installed.
The default value is '$QTDIR
/lib'.
Note: If you set this variable to None,
the tool won't change the $LIBPATH
construction variable.
Default value is '$QT_BINPATH
/moc'.
Default value is ''. Prefix for moc output files, when source is a cxx file.
Default value is '.moc'. Suffix for moc output files, when source is a cxx file.
Command to generate a moc file from a cpp file.
The string displayed when generating a moc file from a cpp file.
If this is not set, then $QT_MOCFROMCXXCOM
(the command line) is displayed.
Default value is '-i'. These flags are passed to moc, when moccing a C++ file.
Command to generate a moc file from a header.
The string displayed when generating a moc file from a cpp file.
If this is not set, then $QT_MOCFROMHCOM
(the command line) is displayed.
Default value is ''. These flags are passed to moc, when moccing a header file.
Default value is 'moc_'. Prefix for moc output files, when source is a header.
Default value is '$CXXFILESUFFIX
'. Suffix for moc output files, when source is
a header.
Default value is '$QT_BINPATH
/uic'.
Command to generate header files from .ui files.
The string displayed when generating header files from .ui files.
If this is not set, then $QT_UICCOM
(the command line) is displayed.
Default value is ''. These flags are passed to uic, when creating a a h file from a .ui file.
Default value is ''. Prefix for uic generated header files.
Default value is '.h'. Suffix for uic generated header files.
Default value is ''. These flags are passed to uic, when creating a cxx file from a .ui file.
Default value is 'uic_'. Prefix for uic generated implementation files.
Default value is '$CXXFILESUFFIX
'. Suffix for uic generated implementation
files.
Default value is '.ui'. Suffix of designer input files.
The qt tool tries to take this from os.environ.
It also initializes all QT_*
construction variables listed below.
(Note that all paths are constructed
with python's os.path.join() method,
but are listed here with the '/' separator
for easier reading.)
In addition, the construction environment
variables $CPPPATH
,
$LIBPATH
and
$LIBS
may be modified
and the variables
$PROGEMITTER
, $SHLIBEMITTER
and $LIBEMITTER
are modified. Because the build-performance is affected when using this tool,
you have to explicitly specify it at Environment creation:
Environment(tools=['default','qt'])
The qt tool supports the following operations:
Automatic moc file generation from header files.
You do not have to specify moc files explicitly, the tool does it for you.
However, there are a few preconditions to do so: Your header file must have
the same filebase as your implementation file and must stay in the same
directory. It must have one of the suffixes .h, .hpp, .H, .hxx, .hh. You
can turn off automatic moc file generation by setting QT_AUTOSCAN to 0.
See also the corresponding
Moc
()
builder method.
Automatic moc file generation from cxx files.
As stated in the qt documentation, include the moc file at the end of
the cxx file. Note that you have to include the file, which is generated
by the transformation ${QT_MOCCXXPREFIX}<basename>${QT_MOCCXXSUFFIX}, by default
<basename>.moc. A warning is generated after building the moc file, if you
do not include the correct file. If you are using VariantDir, you may
need to specify duplicate=1. You can turn off automatic moc file generation
by setting QT_AUTOSCAN to 0. See also the corresponding
Moc
builder method.
Automatic handling of .ui files.
The implementation files generated from .ui files are handled much the same
as yacc or lex files. Each .ui file given as a source of Program, Library or
SharedLibrary will generate three files, the declaration file, the
implementation file and a moc file. Because there are also generated headers,
you may need to specify duplicate=1 in calls to VariantDir.
See also the corresponding
Uic
builder method.
The archive indexer.
The command line used to index a static library archive.
The string displayed when a static library archive is indexed.
If this is not set, then $RANLIBCOM
(the command line) is displayed.
env = Environment(RANLIBCOMSTR = "Indexing $TARGET")
General options passed to the archive indexer.
The resource compiler used to build a Microsoft Visual C++ resource file.
The command line used to build a Microsoft Visual C++ resource file.
The string displayed when invoking the resource compiler
to build a Microsoft Visual C++ resource file.
If this is not set, then $RCCOM
(the command line) is displayed.
The flags passed to the resource compiler by the RES builder.
An automatically-generated construction variable
containing the command-line options
for specifying directories to be searched
by the resource compiler.
The value of $RCINCFLAGS
is created
by appending $RCINCPREFIX
and $RCINCSUFFIX
to the beginning and end
of each directory in $CPPPATH
.
The prefix (flag) used to specify an include directory
on the resource compiler command line.
This will be appended to the beginning of each directory
in the $CPPPATH
construction variable
when the $RCINCFLAGS
variable is expanded.
The suffix used to specify an include directory
on the resource compiler command line.
This will be appended to the end of each directory
in the $CPPPATH
construction variable
when the $RCINCFLAGS
variable is expanded.
The RCS executable.
Note that this variable is not actually used
for the command to fetch source files from RCS;
see the
$RCS_CO
construction variable, below.
The RCS "checkout" executable, used to fetch source files from RCS.
The command line used to fetch (checkout) source files from RCS.
The string displayed when fetching
a source file from RCS.
If this is not set, then $RCS_COCOM
(the command line) is displayed.
Options that are passed to the $RCS_CO
command.
A function that converts a string into a list of Dir instances by searching the repositories.
The program used on Windows systems
to register a newly-built DLL library
whenever the SharedLibrary
builder
is passed a keyword argument of register=1
.
The command line used on Windows systems
to register a newly-built DLL library
whenever the SharedLibrary
builder
is passed a keyword argument of register=1
.
The string displayed when registering a newly-built DLL file.
If this is not set, then $REGSVRCOM
(the command line) is displayed.
Flags passed to the DLL registration program
on Windows systems when a newly-built DLL library is registered.
By default,
this includes the /s
that prevents dialog boxes from popping up
and requiring user attention.
The Java RMI stub compiler.
The command line used to compile stub
and skeleton class files
from Java classes that contain RMI implementations.
Any options specified in the $RMICFLAGS
construction variable
are included on this command line.
The string displayed when compiling
stub and skeleton class files
from Java classes that contain RMI implementations.
If this is not set, then $RMICCOM
(the command line) is displayed.
env = Environment(RMICCOMSTR = "Generating stub/skeleton class files $TARGETS from $SOURCES")
General options passed to the Java RMI stub compiler.
An automatically-generated construction variable
containing the rpath flags to be used when linking
a program with shared libraries.
The value of $_RPATH
is created
by appending $RPATHPREFIX
and $RPATHSUFFIX
to the beginning and end
of each directory in $RPATH
.
A list of paths to search for shared libraries when running programs.
Currently only used in the GNU (gnulink),
IRIX (sgilink) and Sun (sunlink) linkers.
Ignored on platforms and toolchains that don't support it.
Note that the paths added to RPATH
are not transformed by
scons
in any way: if you want an absolute
path, you must make it absolute yourself.
The prefix used to specify a directory to be searched for
shared libraries when running programs.
This will be appended to the beginning of each directory
in the $RPATH
construction variable
when the $_RPATH
variable is automatically generated.
The suffix used to specify a directory to be searched for
shared libraries when running programs.
This will be appended to the end of each directory
in the $RPATH
construction variable
when the $_RPATH
variable is automatically generated.
The RPC protocol compiler.
Options passed to the RPC protocol compiler
when generating client side stubs.
These are in addition to any flags specified in the
$RPCGENFLAGS
construction variable.
General options passed to the RPC protocol compiler.
Options passed to the RPC protocol compiler
when generating a header file.
These are in addition to any flags specified in the
$RPCGENFLAGS
construction variable.
Options passed to the RPC protocol compiler
when generating server side stubs.
These are in addition to any flags specified in the
$RPCGENFLAGS
construction variable.
Options passed to the RPC protocol compiler
when generating XDR routines.
These are in addition to any flags specified in the
$RPCGENFLAGS
construction variable.
A list of the available implicit dependency scanners. New file scanners may be added by appending to this list, although the more flexible approach is to associate scanners with a specific Builder. See the sections "Builder Objects" and "Scanner Objects," below, for more information.
The SCCS executable.
The command line used to fetch source files from SCCS.
The string displayed when fetching
a source file from a CVS repository.
If this is not set, then $SCCSCOM
(the command line) is displayed.
General options that are passed to SCCS.
Options that are passed specifically to the SCCS "get" subcommand.
This can be set, for example, to
-e
to check out editable files from SCCS.
The
(optional) path to the SCons library directory, initialized from the external
environment. If set, this is used to construct a shorter and more efficient
search path in the $MSVSSCONS
command line executed from Microsoft
Visual Studio project files.
The C compiler used for generating shared-library objects.
The command line used to compile a C source file
to a shared-library object file.
Any options specified in the $SHCFLAGS
,
$SHCCFLAGS
and
$CPPFLAGS
construction variables
are included on this command line.
The string displayed when a C source file
is compiled to a shared object file.
If this is not set, then $SHCCCOM
(the command line) is displayed.
env = Environment(SHCCCOMSTR = "Compiling shared object $TARGET")
Options that are passed to the C and C++ compilers to generate shared-library objects.
Options that are passed to the C compiler (only; not C++) to generate shared-library objects.
The C++ compiler used for generating shared-library objects.
The command line used to compile a C++ source file
to a shared-library object file.
Any options specified in the $SHCXXFLAGS
and
$CPPFLAGS
construction variables
are included on this command line.
The string displayed when a C++ source file
is compiled to a shared object file.
If this is not set, then $SHCXXCOM
(the command line) is displayed.
env = Environment(SHCXXCOMSTR = "Compiling shared object $TARGET")
Options that are passed to the C++ compiler to generate shared-library objects.
SHDC.
SHDCOM.
SHDLINK.
SHDLINKCOM.
SHDLINKFLAGS.
A string naming the shell program that will be passed to the
$SPAWN
function.
See the
$SPAWN
construction variable for more information.
The Fortran 03 compiler used for generating shared-library objects.
You should normally set the $SHFORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $SHF03
if you need to use a specific compiler
or compiler version for Fortran 03 files.
The command line used to compile a Fortran 03 source file
to a shared-library object file.
You only need to set $SHF03COM
if you need to use a specific
command line for Fortran 03 files.
You should normally set the $SHFORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 03 source file
is compiled to a shared-library object file.
If this is not set, then $SHF03COM
or $SHFORTRANCOM
(the command line) is displayed.
Options that are passed to the Fortran 03 compiler
to generated shared-library objects.
You only need to set $SHF03FLAGS
if you need to define specific
user options for Fortran 03 files.
You should normally set the $SHFORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
The command line used to compile a Fortran 03 source file to a
shared-library object file
after first running the file through the C preprocessor.
Any options specified in the $SHF03FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $SHF03PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 03 files.
You should normally set the $SHFORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 03 source file
is compiled to a shared-library object file
after first running the file through the C preprocessor.
If this is not set, then $SHF03PPCOM
or $SHFORTRANPPCOM
(the command line) is displayed.
The Fortran 08 compiler used for generating shared-library objects.
You should normally set the $SHFORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $SHF08
if you need to use a specific compiler
or compiler version for Fortran 08 files.
The command line used to compile a Fortran 08 source file
to a shared-library object file.
You only need to set $SHF08COM
if you need to use a specific
command line for Fortran 08 files.
You should normally set the $SHFORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 08 source file
is compiled to a shared-library object file.
If this is not set, then $SHF08COM
or $SHFORTRANCOM
(the command line) is displayed.
Options that are passed to the Fortran 08 compiler
to generated shared-library objects.
You only need to set $SHF08FLAGS
if you need to define specific
user options for Fortran 08 files.
You should normally set the $SHFORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
The command line used to compile a Fortran 08 source file to a
shared-library object file
after first running the file through the C preprocessor.
Any options specified in the $SHF08FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $SHF08PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 08 files.
You should normally set the $SHFORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 08 source file
is compiled to a shared-library object file
after first running the file through the C preprocessor.
If this is not set, then $SHF08PPCOM
or $SHFORTRANPPCOM
(the command line) is displayed.
The Fortran 77 compiler used for generating shared-library objects.
You should normally set the $SHFORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $SHF77
if you need to use a specific compiler
or compiler version for Fortran 77 files.
The command line used to compile a Fortran 77 source file
to a shared-library object file.
You only need to set $SHF77COM
if you need to use a specific
command line for Fortran 77 files.
You should normally set the $SHFORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 77 source file
is compiled to a shared-library object file.
If this is not set, then $SHF77COM
or $SHFORTRANCOM
(the command line) is displayed.
Options that are passed to the Fortran 77 compiler
to generated shared-library objects.
You only need to set $SHF77FLAGS
if you need to define specific
user options for Fortran 77 files.
You should normally set the $SHFORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
The command line used to compile a Fortran 77 source file to a
shared-library object file
after first running the file through the C preprocessor.
Any options specified in the $SHF77FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $SHF77PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 77 files.
You should normally set the $SHFORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 77 source file
is compiled to a shared-library object file
after first running the file through the C preprocessor.
If this is not set, then $SHF77PPCOM
or $SHFORTRANPPCOM
(the command line) is displayed.
The Fortran 90 compiler used for generating shared-library objects.
You should normally set the $SHFORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $SHF90
if you need to use a specific compiler
or compiler version for Fortran 90 files.
The command line used to compile a Fortran 90 source file
to a shared-library object file.
You only need to set $SHF90COM
if you need to use a specific
command line for Fortran 90 files.
You should normally set the $SHFORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 90 source file
is compiled to a shared-library object file.
If this is not set, then $SHF90COM
or $SHFORTRANCOM
(the command line) is displayed.
Options that are passed to the Fortran 90 compiler
to generated shared-library objects.
You only need to set $SHF90FLAGS
if you need to define specific
user options for Fortran 90 files.
You should normally set the $SHFORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
The command line used to compile a Fortran 90 source file to a
shared-library object file
after first running the file through the C preprocessor.
Any options specified in the $SHF90FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $SHF90PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 90 files.
You should normally set the $SHFORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 90 source file
is compiled to a shared-library object file
after first running the file through the C preprocessor.
If this is not set, then $SHF90PPCOM
or $SHFORTRANPPCOM
(the command line) is displayed.
The Fortran 95 compiler used for generating shared-library objects.
You should normally set the $SHFORTRAN
variable,
which specifies the default Fortran compiler
for all Fortran versions.
You only need to set $SHF95
if you need to use a specific compiler
or compiler version for Fortran 95 files.
The command line used to compile a Fortran 95 source file
to a shared-library object file.
You only need to set $SHF95COM
if you need to use a specific
command line for Fortran 95 files.
You should normally set the $SHFORTRANCOM
variable,
which specifies the default command line
for all Fortran versions.
The string displayed when a Fortran 95 source file
is compiled to a shared-library object file.
If this is not set, then $SHF95COM
or $SHFORTRANCOM
(the command line) is displayed.
Options that are passed to the Fortran 95 compiler
to generated shared-library objects.
You only need to set $SHF95FLAGS
if you need to define specific
user options for Fortran 95 files.
You should normally set the $SHFORTRANFLAGS
variable,
which specifies the user-specified options
passed to the default Fortran compiler
for all Fortran versions.
The command line used to compile a Fortran 95 source file to a
shared-library object file
after first running the file through the C preprocessor.
Any options specified in the $SHF95FLAGS
and $CPPFLAGS
construction variables
are included on this command line.
You only need to set $SHF95PPCOM
if you need to use a specific
C-preprocessor command line for Fortran 95 files.
You should normally set the $SHFORTRANPPCOM
variable,
which specifies the default C-preprocessor command line
for all Fortran versions.
The string displayed when a Fortran 95 source file
is compiled to a shared-library object file
after first running the file through the C preprocessor.
If this is not set, then $SHF95PPCOM
or $SHFORTRANPPCOM
(the command line) is displayed.
The default Fortran compiler used for generating shared-library objects.
The command line used to compile a Fortran source file to a shared-library object file.
The string displayed when a Fortran source file
is compiled to a shared-library object file.
If this is not set, then $SHFORTRANCOM
(the command line) is displayed.
Options that are passed to the Fortran compiler to generate shared-library objects.
The command line used to compile a Fortran source file to a
shared-library object file
after first running the file through the C preprocessor.
Any options specified
in the $SHFORTRANFLAGS
and
$CPPFLAGS
construction variables
are included on this command line.
The string displayed when a Fortran source file
is compiled to a shared-library object file
after first running the file through the C preprocessor.
If this is not set, then $SHFORTRANPPCOM
(the command line) is displayed.
TODO
The prefix used for shared library file names.
The suffix used for shared library file names.
When this construction variable is defined, a versioned shared library
is created. This modifies the $SHLINKFLAGS
as required, adds
the version number to the library name, and creates the symlinks that
are needed. $SHLIBVERSION
needs to be of the form X.Y.Z,
where X and Y are numbers, and Z is a number but can also contain
letters to designate alpha, beta, or release candidate patch levels.
The linker for programs that use shared libraries.
The command line used to link programs using shared libraries.
The string displayed when programs using shared libraries are linked.
If this is not set, then $SHLINKCOM
(the command line) is displayed.
env = Environment(SHLINKCOMSTR = "Linking shared $TARGET")
General user options passed to the linker for programs using shared libraries.
Note that this variable should
not
contain
-l
(or similar) options for linking with the libraries listed in $LIBS
,
nor
-L
(or similar) include search path options
that scons generates automatically from $LIBPATH
.
See
$_LIBFLAGS
above,
for the variable that expands to library-link options,
and
$_LIBDIRFLAGS
above,
for the variable that expands to library search path options.
The prefix used for shared object file names.
The suffix used for shared object file names.
A reserved variable name that may not be set or used in a construction environment. (See "Variable Substitution," below.)
The URL
(web address)
of the location from which the project was retrieved.
This is used to fill in the
Source:
field in the controlling information for Ipkg and RPM packages.
A reserved variable name that may not be set or used in a construction environment. (See "Variable Substitution," below.)
A command interpreter function that will be called to execute command line strings. The function must expect the following arguments:
def spawn(shell, escape, cmd, args, env):
sh
is a string naming the shell program to use.
escape
is a function that can be called to escape shell special characters in
the command line.
cmd
is the path to the command to be executed.
args
is the arguments to the command.
env
is a dictionary of the environment variables
in which the command should be executed.
When this variable is true, static objects and shared objects are assumed to be the same; that is, SCons does not check for linking static objects into a shared library.
The dictionary used by the Substfile
or Textfile
builders
for substitution values.
It can be anything acceptable to the dict() constructor,
so in addition to a dictionary,
lists of tuples are also acceptable.
The prefix used for Substfile
file names,
the null string by default.
The suffix used for Substfile
file names,
the null string by default.
A short summary of what the project is about.
This is used to fill in the
Summary:
field in the controlling information for Ipkg and RPM packages,
and as the
Description:
field in MSI packages.
The scripting language wrapper and interface generator.
The suffix that will be used for intermediate C
source files generated by
the scripting language wrapper and interface generator.
The default value is
_wrap
$CFILESUFFIX
.
By default, this value is used whenever the
-c++
option is
not
specified as part of the
$SWIGFLAGS
construction variable.
The command line used to call the scripting language wrapper and interface generator.
The string displayed when calling
the scripting language wrapper and interface generator.
If this is not set, then $SWIGCOM
(the command line) is displayed.
The suffix that will be used for intermediate C++
source files generated by
the scripting language wrapper and interface generator.
The default value is
_wrap
$CFILESUFFIX
.
By default, this value is used whenever the
-c++
option is specified as part of the
$SWIGFLAGS
construction variable.
The suffix that will be used for intermediate C++ header
files generated by the scripting language wrapper and interface generator.
These are only generated for C++ code when the SWIG 'directors' feature is
turned on.
The default value is
_wrap.h
.
General options passed to
the scripting language wrapper and interface generator.
This is where you should set
-python
,
-perl5
,
-tcl
,
or whatever other options you want to specify to SWIG.
If you set the
-c++
option in this variable,
scons
will, by default,
generate a C++ intermediate source file
with the extension that is specified as the
$CXXFILESUFFIX
variable.
An automatically-generated construction variable
containing the SWIG command-line options
for specifying directories to be searched for included files.
The value of $_SWIGINCFLAGS
is created
by appending $SWIGINCPREFIX
and $SWIGINCSUFFIX
to the beginning and end
of each directory in $SWIGPATH
.
The prefix used to specify an include directory on the SWIG command line.
This will be appended to the beginning of each directory
in the $SWIGPATH
construction variable
when the $_SWIGINCFLAGS
variable is automatically generated.
The suffix used to specify an include directory on the SWIG command line.
This will be appended to the end of each directory
in the $SWIGPATH
construction variable
when the $_SWIGINCFLAGS
variable is automatically generated.
Specifies the output directory in which
the scripting language wrapper and interface generator
should place generated language-specific files.
This will be used by SCons to identify
the files that will be generated by the swig call,
and translated into the
swig -outdir
option on the command line.
The list of directories that the scripting language wrapper and interface generate will search for included files. The SWIG implicit dependency scanner will search these directories for include files. The default value is an empty list.
Don't explicitly put include directory
arguments in SWIGFLAGS;
the result will be non-portable
and the directories will not be searched by the dependency scanner.
Note: directory names in SWIGPATH will be looked-up relative to the SConscript
directory when they are used in a command.
To force
scons
to look-up a directory relative to the root of the source tree use #:
env = Environment(SWIGPATH='#/include')
The directory look-up can also be forced using the
Dir
()
function:
include = Dir('include') env = Environment(SWIGPATH=include)
The directory list will be added to command lines
through the automatically-generated
$_SWIGINCFLAGS
construction variable,
which is constructed by
appending the values of the
$SWIGINCPREFIX
and $SWIGINCSUFFIX
construction variables
to the beginning and end
of each directory in $SWIGPATH
.
Any command lines you define that need
the SWIGPATH directory list should
include $_SWIGINCFLAGS
:
env = Environment(SWIGCOM="my_swig -o $TARGET $_SWIGINCFLAGS $SOURCES")
The version number of the SWIG tool.
The tar archiver.
The command line used to call the tar archiver.
The string displayed when archiving files
using the tar archiver.
If this is not set, then $TARCOM
(the command line) is displayed.
env = Environment(TARCOMSTR = "Archiving $TARGET")
General options passed to the tar archiver.
A reserved variable name that may not be set or used in a construction environment. (See "Variable Substitution," below.)
The name of the target hardware architecture for the compiled objects created by this Environment. This defaults to the value of HOST_ARCH, and the user can override it. Currently only set for Win32.
Sets the target architecture for Visual Studio compiler (i.e. the arch
of the binaries generated by the compiler). If not set, default to
$HOST_ARCH
, or, if that is unset, to the architecture of the
running machine's OS (note that the python build or architecture has no
effect).
This variable must be passed as an argument to the Environment()
constructor; setting it later has no effect.
This is currently only used on Windows, but in the future it will be
used on other OSes as well.
Valid values for Windows are
x86
,
i386
(for 32 bits);
amd64
,
emt64
,
x86_64
(for 64 bits);
and ia64
(Itanium).
For example, if you want to compile 64-bit binaries, you would set
TARGET_ARCH='x86_64'
in your SCons environment.
The name of the target operating system for the compiled objects created by this Environment. This defaults to the value of HOST_OS, and the user can override it. Currently only set for Win32.
A reserved variable name that may not be set or used in a construction environment. (See "Variable Substitution," below.)
The suffix used for tar file names.
The prefix for a temporary file used to execute lines longer than $MAXLINELENGTH. The default is '@'. This may be set for toolchains that use other values, such as '-@' for the diab compiler or '-via' for ARM toolchain.
The TeX formatter and typesetter.
The command line used to call the TeX formatter and typesetter.
The string displayed when calling
the TeX formatter and typesetter.
If this is not set, then $TEXCOM
(the command line) is displayed.
env = Environment(TEXCOMSTR = "Building $TARGET from TeX input $SOURCES")
General options passed to the TeX formatter and typesetter.
List of directories that the LaTeX program will search for include directories. The LaTeX implicit dependency scanner will search these directories for \include and \import files.
The prefix used for Textfile
file names,
the null string by default.
The suffix used for Textfile
file names;
.txt
by default.
A list of the names of the Tool specifications that are part of this construction environment.
A reserved variable name that may not be set or used in a construction environment. (See "Variable Substitution," below.)
A reserved variable name that may not be set or used in a construction environment. (See "Variable Substitution," below.)
The person or organization who supply the packaged software.
This is used to fill in the
Vendor:
field in the controlling information for RPM packages,
and the
Manufacturer:
field in the controlling information for MSI packages.
The version of the project, specified as a string.
A deprecated synonym for $WINDOWS_INSERT_DEF
.
A deprecated synonym for $WINDOWSDEFPREFIX
.
A deprecated synonym for $WINDOWSDEFSUFFIX
.
A deprecated synonym for $WINDOWSEXPSUFFIX
.
A deprecated synonym for $WINDOWSEXPSUFFIX
.
Set this variable to True or 1 to embed the compiler-generated manifest
(normally ${TARGET}.manifest
)
into all Windows exes and DLLs built with this environment,
as a resource during their link step.
This is done using $MT
and $MTEXECOM
and $MTSHLIBCOM
.
When this is set to true,
a library build of a Windows shared library
(.dll
file)
will also build a corresponding .def
file
at the same time,
if a .def
file
is not already listed as a build target.
The default is 0 (do not build a .def
file).
When this is set to true,
scons
will be aware of the
.manifest
files generated by Microsoft Visua C/C++ 8.
The prefix used for Windows .def
file names.
The suffix used for Windows .def
file names.
The prefix used for Windows .exp
file names.
The suffix used for Windows .exp
file names.
The prefix used for executable program .manifest
files
generated by Microsoft Visual C/C++.
The suffix used for executable program .manifest
files
generated by Microsoft Visual C/C++.
The prefix used for shared library .manifest
files
generated by Microsoft Visual C/C++.
The suffix used for shared library .manifest
files
generated by Microsoft Visual C/C++.
This is used to fill in the
Depends:
field in the controlling information for Ipkg packages.
This is used to fill in the
Description:
field in the controlling information for Ipkg packages.
The default value is
$SUMMARY\n$DESCRIPTION
This is used to fill in the
Maintainer:
field in the controlling information for Ipkg packages.
This is used to fill in the
Priority:
field in the controlling information for Ipkg packages.
This is used to fill in the
Section:
field in the controlling information for Ipkg packages.
This is used to fill in the
Language:
attribute in the controlling information for MSI packages.
The text of the software license in RTF format. Carriage return characters will be replaced with the RTF equivalent \\par.
TODO
This is used to fill in the
AutoReqProv:
field in the RPM
.spec
file.
internal, but overridable
This is used to fill in the
BuildRequires:
field in the RPM
.spec
file.
internal, but overridable
internal, but overridable
This is used to fill in the
Conflicts:
field in the RPM
.spec
file.
This value is used as the default attributes
for the files in the RPM package.
The default value is
(-,root,root)
.
This is used to fill in the
Distribution:
field in the RPM
.spec
file.
This is used to fill in the
Epoch:
field in the controlling information for RPM packages.
This is used to fill in the
ExcludeArch:
field in the RPM
.spec
file.
This is used to fill in the
ExclusiveArch:
field in the RPM
.spec
file.
This is used to fill in the
Group:
field in the RPM
.spec
file.
This is used to fill in the
Group(lang):
field in the RPM
.spec
file.
Note that
lang
is not literal
and should be replaced by
the appropriate language code.
This is used to fill in the
Icon:
field in the RPM
.spec
file.
internal, but overridable
This is used to fill in the
Packager:
field in the RPM
.spec
file.
This is used to fill in the
%post:
section in the RPM
.spec
file.
This is used to fill in the
%postun:
section in the RPM
.spec
file.
This is used to fill in the
Prefix:
field in the RPM
.spec
file.
This is used to fill in the
%pre:
section in the RPM
.spec
file.
internal, but overridable
This is used to fill in the
%preun:
section in the RPM
.spec
file.
This is used to fill in the
Provides:
field in the RPM
.spec
file.
This is used to fill in the
Requires:
field in the RPM
.spec
file.
This is used to fill in the
Serial:
field in the RPM
.spec
file.
This is used to fill in the
Url:
field in the RPM
.spec
file.
Path to xgettext(1) program (found via
Detect()
).
See xgettext
tool and POTUpdate
builder.
Complete xgettext command line.
See xgettext
tool and POTUpdate
builder.
A string that is shown when xgettext(1) command is invoked
(default: ''
, which means "print $XGETTEXTCOM
").
See xgettext
tool and POTUpdate
builder.
Internal "macro". Generates xgettext domain name
form source and target (default: '${TARGET.filebase}'
).
Additional flags to xgettext(1).
See xgettext
tool and POTUpdate
builder.
Name of file containing list of xgettext(1)'s source
files. Autotools' users know this as POTFILES.in
so they
will in most cases set XGETTEXTFROM="POTFILES.in"
here.
The $XGETTEXTFROM
files have same syntax and semantics as the well known
GNU POTFILES.in
.
See xgettext
tool and POTUpdate
builder.
Internal "macro". Genrates list of -D<dir>
flags
from the $XGETTEXTPATH
list.
This flag is used to add single $XGETTEXTFROM
file to
xgettext(1)'s commandline (default:
'-f'
).
(default: ''
)
List of directories, there xgettext(1) will look for
source files (default: []
).
This variable works only together with $XGETTEXTFROM
Internal "macro". Generates list of -f<file>
flags
from $XGETTEXTFROM
.
This flag is used to add single search path to
xgettext(1)'s commandline (default:
'-D'
).
(default: ''
)
The parser generator.
The command line used to call the parser generator to generate a source file.
The string displayed when generating a source file
using the parser generator.
If this is not set, then $YACCCOM
(the command line) is displayed.
env = Environment(YACCCOMSTR = "Yacc'ing $TARGET from $SOURCES")
General options passed to the parser generator.
If $YACCFLAGS
contains a -d
option,
SCons assumes that the call will also create a .h file
(if the yacc source file ends in a .y suffix)
or a .hpp file
(if the yacc source file ends in a .yy suffix)
The suffix of the C
header file generated by the parser generator
when the
-d
option is used.
Note that setting this variable does not cause
the parser generator to generate a header
file with the specified suffix,
it exists to allow you to specify
what suffix the parser generator will use of its own accord.
The default value is
.h
.
The suffix of the C++
header file generated by the parser generator
when the
-d
option is used.
Note that setting this variable does not cause
the parser generator to generate a header
file with the specified suffix,
it exists to allow you to specify
what suffix the parser generator will use of its own accord.
The default value is
.hpp
,
except on Mac OS X,
where the default is
${TARGET.suffix}.h
.
because the default bison parser generator just
appends .h
to the name of the generated C++ file.
The suffix of the file
containing the VCG grammar automaton definition
when the
--graph=
option is used.
Note that setting this variable does not cause
the parser generator to generate a VCG
file with the specified suffix,
it exists to allow you to specify
what suffix the parser generator will use of its own accord.
The default value is
.vcg
.
The zip compression and file packaging utility.
The command line used to call the zip utility, or the internal Python function used to create a zip archive.
The
compression
flag
from the Python
zipfile
module used by the internal Python function
to control whether the zip archive
is compressed or not.
The default value is
zipfile.ZIP_DEFLATED
,
which creates a compressed zip archive.
This value has no effect if the
zipfile
module is unavailable.
The string displayed when archiving files
using the zip utility.
If this is not set, then $ZIPCOM
(the command line or internal Python function) is displayed.
env = Environment(ZIPCOMSTR = "Zipping $TARGET")
General options passed to the zip utility.
An optional zip root directory (default empty). The filenames stored in the zip file will be relative to this directory, if given. Otherwise the filenames are relative to the current directory of the command. For instance:
env = Environment() env.Zip('foo.zip', 'subdir1/subdir2/file1', ZIPROOT='subdir1')
will produce a zip file foo.zip
containing a file with the name
subdir2/file1
rather than
subdir1/subdir2/file1
.
The suffix used for zip file names.
Construction variables can be retrieved and set using the Dictionary method of the construction environment:
dict = env.Dictionary() dict["CC"] = "cc"
or using the [] operator:
env["CC"] = "cc"
Construction variables can also be passed to the construction environment constructor:
env = Environment(CC="cc")
or when copying a construction environment using the Clone method:
env2 = env.Clone(CC="cl.exe")
scons
supports
configure contexts,
an integrated mechanism similar to the
various AC_CHECK macros in GNU autoconf
for testing for the existence of C header
files, libraries, etc.
In contrast to autoconf,
scons
does not maintain an explicit cache of the tested values,
but uses its normal dependency tracking to keep the checked values
up to date. However, users may override this behaviour with the
--config
command line option.
The following methods can be used to perform checks:
This creates a configure context, which can be used to perform checks. env specifies the environment for building the tests. This environment may be modified when performing checks. custom_tests is a dictionary containing custom tests. See also the section about custom tests below. By default, no custom tests are added to the configure context. conf_dir specifies a directory where the test cases are built. Note that this directory is not used for building normal targets. The default value is the directory #/.sconf_temp. log_file specifies a file which collects the output from commands that are executed to check for the existence of header files, libraries, etc. The default is the file #/config.log. If you are using the VariantDir() method, you may want to specify a subdirectory under your variant directory. config_h specifies a C header file where the results of tests will be written, e.g. #define HAVE_STDIO_H, #define HAVE_LIBM, etc. The default is to not write a config.h file. You can specify the same config.h file in multiple calls to Configure, in which case scons will concatenate all results in the specified file. Note that SCons uses its normal dependency checking to decide if it's necessary to rebuild the specified config_h file. This means that the file is not necessarily re-built each time scons is run, but is only rebuilt if its contents will have changed and some target that depends on the config_h file is being built.
The optional
clean
and
help
arguments can be used to suppress execution of the configuration
tests when the
-c/--clean
or
-H/-h/--help
options are used, respectively.
The default behavior is always to execute
configure context tests,
since the results of the tests may
affect the list of targets to be cleaned
or the help text.
If the configure tests do not affect these,
then you may add the
clean=False
or
help=False
arguments
(or both)
to avoid unnecessary test execution.
A created Configure instance has the following associated methods:
This method should be called after configuration is done. It returns the environment as modified by the configuration checks performed. After this method is called, no further checks can be performed with this configuration context. However, you can create a new Configure context to perform additional checks. Only one context should be active at a time.
The following Checks are predefined. (This list will likely grow larger as time goes by and developers contribute new useful tests.)
Checks if header is usable in the specified language. header may be a list, in which case the last item in the list is the header file to be checked, and the previous list items are header files whose #include lines should precede the header line being checked for. The optional argument include_quotes must be a two character string, where the first character denotes the opening quote and the second character denotes the closing quote. By default, both characters are " (double quote). The optional argument language should be either C or C++ and selects the compiler to be used for the check. Returns 1 on success and 0 on failure.
This is a wrapper around SConf.CheckHeader which checks if header is usable in the C language. header may be a list, in which case the last item in the list is the header file to be checked, and the previous list items are header files whose #include lines should precede the header line being checked for. The optional argument include_quotes must be a two character string, where the first character denotes the opening quote and the second character denotes the closing quote (both default to \N'34'). Returns 1 on success and 0 on failure.
This is a wrapper around SConf.CheckHeader which checks if header is usable in the C++ language. header may be a list, in which case the last item in the list is the header file to be checked, and the previous list items are header files whose #include lines should precede the header line being checked for. The optional argument include_quotes must be a two character string, where the first character denotes the opening quote and the second character denotes the closing quote (both default to \N'34'). Returns 1 on success and 0 on failure.
Checks if the specified C or C++ function is available. function_name is the name of the function to check for. The optional header argument is a string that will be placed at the top of the test file that will be compiled to check if the function exists; the default is:
#ifdef __cplusplus extern "C" #endif char function_name();
The optional language argument should be C or C++ and selects the compiler to be used for the check; the default is "C".
Checks if library provides symbol. If the value of autoadd is 1 and the library provides the specified symbol, appends the library to the LIBS construction environment variable. library may also be None (the default), in which case symbol is checked with the current LIBS variable, or a list of library names, in which case each library in the list will be checked for symbol. If symbol is not set or is None, then SConf.CheckLib() just checks if you can link against the specified library. The optional language argument should be C or C++ and selects the compiler to be used for the check; the default is "C". The default value for autoadd is 1. This method returns 1 on success and 0 on error.
In contrast to the SConf.CheckLib call, this call provides a more sophisticated way to check against libraries. Again, library specifies the library or a list of libraries to check. header specifies a header to check for. header may be a list, in which case the last item in the list is the header file to be checked, and the previous list items are header files whose #include lines should precede the header line being checked for. language may be one of 'C','c','CXX','cxx','C++' and 'c++'. call can be any valid expression (with a trailing ';'). If call is not set, the default simply checks that you can link against the specified library. autoadd specifies whether to add the library to the environment (only if the check succeeds). This method returns 1 on success and 0 on error.
Checks for the existence of a type defined by typedef. type_name specifies the typedef name to check for. includes is a string containing one or more #include lines that will be inserted into the program that will be run to test for the existence of the type. The optional language argument should be C or C++ and selects the compiler to be used for the check; the default is "C". Example:
sconf.CheckType('foo_type', '#include "my_types.h"', 'C++')
Checks whether the C compiler (as defined by the CC construction variable) works by trying to compile a small source file.
By default, SCons only detects if there is a program with the correct name, not if it is a functioning compiler.
This uses the exact same command than the one used by the object builder for C source file, so it can be used to detect if a particular compiler flag works or not.
Checks whether the C++ compiler (as defined by the CXX construction variable) works by trying to compile a small source file. By default, SCons only detects if there is a program with the correct name, not if it is a functioning compiler.
This uses the exact same command than the one used by the object builder for CXX source files, so it can be used to detect if a particular compiler flag works or not.
Checks whether the C compiler (as defined by the SHCC construction variable) works by trying to compile a small source file. By default, SCons only detects if there is a program with the correct name, not if it is a functioning compiler.
This uses the exact same command than the one used by the object builder for C source file, so it can be used to detect if a particular compiler flag works or not. This does not check whether the object code can be used to build a shared library, only that the compilation (not link) succeeds.
Checks whether the C++ compiler (as defined by the SHCXX construction variable) works by trying to compile a small source file. By default, SCons only detects if there is a program with the correct name, not if it is a functioning compiler.
This uses the exact same command than the one used by the object builder for CXX source files, so it can be used to detect if a particular compiler flag works or not. This does not check whether the object code can be used to build a shared library, only that the compilation (not link) succeeds.
Example of a typical Configure usage:
env = Environment() conf = Configure( env ) if not conf.CheckCHeader( 'math.h' ): print 'We really need math.h!' Exit(1) if conf.CheckLibWithHeader( 'qt', 'qapp.h', 'c++', 'QApplication qapp(0,0);' ): # do stuff for qt - usage, e.g. conf.env.Append( CPPFLAGS = '-DWITH_QT' ) env = conf.Finish()
Checks for the size of a type defined by typedef. type_name specifies the typedef name to check for. The optional header argument is a string that will be placed at the top of the test file that will be compiled to check if the function exists; the default is empty. The optional language argument should be C or C++ and selects the compiler to be used for the check; the default is "C". The optional expect argument should be an integer. If this argument is used, the function will only check whether the type given in type_name has the expected size (in bytes). For example, CheckTypeSize('short', expect = 2) will return success only if short is two bytes.
Checks if the specified symbol is declared. includes is a string containing one or more #include lines that will be inserted into the program that will be run to test for the existence of the type. The optional language argument should be C or C++ and selects the compiler to be used for the check; the default is "C".
This function does not check for anything, but defines a preprocessor symbol that will be added to the configuration header file. It is the equivalent of AC_DEFINE, and defines the symbol name with the optional value and the optional comment comment.
Examples:
env = Environment() conf = Configure( env ) # Puts the following line in the config header file: # #define A_SYMBOL conf.Define('A_SYMBOL') # Puts the following line in the config header file: # #define A_SYMBOL 1 conf.Define('A_SYMBOL', 1)
Be careful about quoting string values, though:
env = Environment() conf = Configure( env ) # Puts the following line in the config header file: # #define A_SYMBOL YA conf.Define('A_SYMBOL', "YA") # Puts the following line in the config header file: # #define A_SYMBOL "YA" conf.Define('A_SYMBOL', '"YA"')
For comment:
env = Environment() conf = Configure( env ) # Puts the following lines in the config header file: # /* Set to 1 if you have a symbol */ # #define A_SYMBOL 1 conf.Define('A_SYMBOL', 1, 'Set to 1 if you have a symbol')
You can define your own custom checks. in addition to the predefined checks. These are passed in a dictionary to the Configure function. This dictionary maps the names of the checks to user defined Python callables (either Python functions or class instances implementing the __call__ method). The first argument of the call is always a CheckContext instance followed by the arguments, which must be supplied by the user of the check. These CheckContext instances define the following methods:
Usually called before the check is started. text will be displayed to the user, e.g. 'Checking for library X...'
Usually called after the check is done. res can be either an integer or a string. In the former case, 'yes' (res != 0) or 'no' (res == 0) is displayed to the user, in the latter case the given string is displayed.
Checks if a file with the specified extension (e.g. '.c') containing text can be compiled using the environment's Object builder. Returns 1 on success and 0 on failure.
Checks, if a file with the specified extension (e.g. '.c') containing text can be compiled using the environment's Program builder. Returns 1 on success and 0 on failure.
Checks, if a file with the specified extension (e.g. '.c') containing text can be compiled using the environment's Program builder. On success, the program is run. If the program executes successfully (that is, its return status is 0), a tuple (1, outputStr) is returned, where outputStr is the standard output of the program. If the program fails execution (its return status is non-zero), then (0, '') is returned.
Checks if the specified action with an optional source file (contents text , extension extension = '' ) can be executed. action may be anything which can be converted to a scons Action. On success, (1, outputStr) is returned, where outputStr is the content of the target file. On failure (0, '') is returned.
Low level implementation for testing specific builds; the methods above are based on this method. Given the Builder instance builder and the optional text of a source file with optional extension, this method returns 1 on success and 0 on failure. In addition, self.lastTarget is set to the build target node, if the build was successful.
Example for implementing and using custom tests:
def CheckQt(context, qtdir): context.Message( 'Checking for qt ...' ) lastLIBS = context.env['LIBS'] lastLIBPATH = context.env['LIBPATH'] lastCPPPATH= context.env['CPPPATH'] context.env.Append(LIBS = 'qt', LIBPATH = qtdir + '/lib', CPPPATH = qtdir + '/include' ) ret = context.TryLink(""" #include <qapp.h> int main(int argc, char **argv) { QApplication qapp(argc, argv); return 0; } """) if not ret: context.env.Replace(LIBS = lastLIBS, LIBPATH=lastLIBPATH, CPPPATH=lastCPPPATH) context.Result( ret ) return ret env = Environment() conf = Configure( env, custom_tests = { 'CheckQt' : CheckQt } ) if not conf.CheckQt('/usr/lib/qt'): print 'We really need qt!' Exit(1) env = conf.Finish()
Often when building software, some variables must be specified at build time. For example, libraries needed for the build may be in non-standard locations, or site-specific compiler options may need to be passed to the compiler. scons provides a Variables object to support overriding construction variables on the command line:
$ scons VARIABLE=foo
The variable values can also be specified in a text-based SConscript file. To create a Variables object, call the Variables() function:
This creates a Variables object that will read construction variables from the file or list of filenames specified in files. If no files are specified, or the files argument is None, then no files will be read. The optional argument args is a dictionary of values that will override anything read from the specified files; it is primarily intended to be passed the ARGUMENTS dictionary that holds variables specified on the command line. Example:
vars = Variables('custom.py') vars = Variables('overrides.py', ARGUMENTS) vars = Variables(None, {FOO:'expansion', BAR:7})
Variables objects have the following methods:
This adds a customizable construction variable to the Variables object. key is the name of the variable. help is the help text for the variable. default is the default value of the variable; if the default value is None and there is no explicit value specified, the construction variable will not be added to the construction environment. validator is called to validate the value of the variable, and should take three arguments: key, value, and environment. The recommended way to handle an invalid value is to raise an exception (see example below). converter is called to convert the value before putting it in the environment, and should take either a value, or the value and environment, as parameters. The converter must return a value, which will be converted into a string before being validated by the validator (if any) and then added to the environment.
Examples:
vars.Add('CC', 'The C compiler') def validate_color(key, val, env): if not val in ['red', 'blue', 'yellow']: raise Exception("Invalid color value '%s'" % val) vars.Add('COLOR', validator=valid_color)
A wrapper script that adds multiple customizable construction variables to a Variables object. list is a list of tuple or list objects that contain the arguments for an individual call to the Add method.
opt.AddVariables( ('debug', '', 0), ('CC', 'The C compiler'), ('VALIDATE', 'An option for testing validation', 'notset', validator, None), )
This updates a construction environment env with the customized construction variables. Any specified variables that are not configured for the Variables object will be saved and may be retrieved with the UnknownVariables() method, below.
Normally this method is not called directly, but is called indirectly by passing the Variables object to the Environment() function:
env = Environment(variables=vars)
The text file(s) that were specified when the Variables object was created are executed as Python scripts, and the values of (global) Python variables set in the file are added to the construction environment.
Example:
CC = 'my_cc'
Returns a dictionary containing any variables that were specified either in the files or the dictionary with which the Variables object was initialized, but for which the Variables object was not configured.
env = Environment(variables=vars) for key, value in vars.UnknownVariables(): print "unknown variable: %s=%s" % (key, value)
This saves the currently set variables into a script file named filename that can be used on the next invocation to automatically load the current settings. This method combined with the Variables method can be used to support caching of variables between runs.
env = Environment() vars = Variables(['variables.cache', 'custom.py']) vars.Add(...) vars.Update(env) vars.Save('variables.cache', env)
This generates help text documenting the customizable construction variables suitable to passing in to the Help() function. env is the construction environment that will be used to get the actual values of customizable variables. Calling with an optional sort function will cause the output to be sorted by the specified argument. The specific sort function should take two arguments and return -1, 0 or 1 (like the standard Python cmp function).
Help(vars.GenerateHelpText(env)) Help(vars.GenerateHelpText(env, sort=cmp))
This method returns a formatted string containing the printable help text for one option. It is normally not called directly, but is called by the GenerateHelpText() method to create the returned help text. It may be overridden with your own function that takes the arguments specified above and returns a string of help text formatted to your liking. Note that the GenerateHelpText() will not put any blank lines or extra characters in between the entries, so you must add those characters to the returned string if you want the entries separated.
def my_format(env, opt, help, default, actual): fmt = "\n%s: default=%s actual=%s (%s)\n" return fmt % (opt, default. actual, help) vars.FormatVariableHelpText = my_format
To make it more convenient to work with customizable Variables, scons provides a number of functions that make it easy to set up various types of Variables:
Return a tuple of arguments
to set up a Boolean option.
The option will use
the specified name
key,
have a default value of
default,
and display the specified
help
text.
The option will interpret the values
y,
yes,
t,
true,
1
,
on
and
all
as true,
and the values
n,
no,
f,
false,
0
,
off
and
none
as false.
Return a tuple of arguments
to set up an option
whose value may be one
of a specified list of legal enumerated values.
The option will use
the specified name
key,
have a default value of
default,
and display the specified
help
text.
The option will only support those
values in the
allowed_values
list.
The optional
map
argument is a dictionary
that can be used to convert
input values into specific legal values
in the
allowed_values
list.
If the value of
ignore_case
is
0
(the default),
then the values are case-sensitive.
If the value of
ignore_case
is
1
,
then values will be matched
case-insensitive.
If the value of
ignore_case
is
2
,
then values will be matched
case-insensitive,
and all input values will be
converted to lower case.
Return a tuple of arguments to set up an option whose value may be one or more of a specified list of legal enumerated values. The option will use the specified name key, have a default value of default, and display the specified help text. The option will only support the values all, none, or the values in the names list. More than one value may be specified, with all values separated by commas. The default may be a string of comma-separated default values, or a list of the default values. The optional map argument is a dictionary that can be used to convert input values into specific legal values in the names list.
Return a tuple of arguments to set up an option whose value is a path name of a package that may be enabled, disabled or given an explicit path name. The option will use the specified name key, have a default value of default, and display the specified help text. The option will support the values yes, true, on, enable or search, in which case the specified default will be used, or the option may be set to an arbitrary string (typically the path name to a package that is being enabled). The option will also support the values no, false, off or disable to disable use of the specified option.
Return a tuple of arguments to set up an option whose value is expected to be a path name. The option will use the specified name key, have a default value of default, and display the specified help text. An additional validator may be specified that will be called to verify that the specified path is acceptable. SCons supplies the following ready-made validators: PathVariable.PathExists (the default), which verifies that the specified path exists; PathVariable.PathIsFile, which verifies that the specified path is an existing file; PathVariable.PathIsDir, which verifies that the specified path is an existing directory; PathVariable.PathIsDirCreate, which verifies that the specified path is a directory and will create the specified directory if the path does not exist; and PathVariable.PathAccept, which simply accepts the specific path name argument without validation, and which is suitable if you want your users to be able to specify a directory path that will be created as part of the build process, for example. You may supply your own validator function, which must take three arguments (key, the name of the variable to be set; val, the specified value being checked; and env, the construction environment) and should raise an exception if the specified value is not acceptable.
These functions make it convenient to create a number of variables with consistent behavior in a single call to the AddVariables method:
vars.AddVariables( BoolVariable('warnings', 'compilation with -Wall and similiar', 1), EnumVariable('debug', 'debug output and symbols', 'no' allowed_values=('yes', 'no', 'full'), map={}, ignorecase=0), # case sensitive ListVariable('shared', 'libraries to build as shared libraries', 'all', names = list_of_libs), PackageVariable('x11', 'use X11 installed here (yes = search some places)', 'yes'), PathVariable('qtdir', 'where the root of Qt is installed', qtdir), PathVariable('foopath', 'where the foo library is installed', foopath, PathVariable.PathIsDir), )
The File() and Dir() functions return File and Dir Nodes, respectively. python objects, respectively. Those objects have several user-visible attributes and methods that are often useful:
The build path of the given file or directory. This path is relative to the top-level directory (where the SConstruct file is found). The build path is the same as the source path if variant_dir is not being used.
The absolute build path of the given file or directory.
The srcnode() method returns another File or Dir object representing the source path of the given File or Dir. The
# Get the current build dir's path, relative to top. Dir('.').path # Current dir's absolute path Dir('.').abspath # Next line is always '.', because it is the top dir's path relative to itself. Dir('#.').path File('foo.c').srcnode().path # source path of the given source file. # Builders also return File objects: foo = env.Program('foo.c') print "foo will be built in %s"%foo.path
A Dir Node or File Node can also be used to create file and subdirectory Nodes relative to the generating Node. A Dir Node will place the new Nodes within the directory it represents. A File node will place the new Nodes within its parent directory (that is, "beside" the file in question). If d is a Dir (directory) Node and f is a File (file) Node, then these methods are available:
Returns a directory Node for a subdirectory of d named name.
Returns a file Node for a file within d named name.
Returns an unresolved Node within d named name.
Returns a directory named name within the parent directory of f.
Returns a file named name within the parent directory of f.
Returns an unresolved Node named name within the parent directory of f.
For example:
# Get a Node for a file within a directory incl = Dir('include') f = incl.File('header.h') # Get a Node for a subdirectory within a directory dist = Dir('project-3.2.1) src = dist.Dir('src') # Get a Node for a file in the same directory cfile = File('sample.c') hfile = cfile.File('sample.h') # Combined example docs = Dir('docs') html = docs.Dir('html') index = html.File('index.html') css = index.File('app.css')
scons can be extended to build different types of targets by adding new Builder objects to a construction environment. In general, you should only need to add a new Builder object when you want to build a new type of file or other external target. If you just want to invoke a different compiler or other tool to build a Program, Object, Library, or any other type of output file for which scons already has an existing Builder, it is generally much easier to use those existing Builders in a construction environment that sets the appropriate construction variables (CC, LINK, etc.).
Builder objects are created using the Builder function. The Builder function accepts the following arguments:
The command line string used to build the target from the source. action can also be: a list of strings representing the command to be executed and its arguments (suitable for enclosing white space in an argument), a dictionary mapping source file name suffixes to any combination of command line strings (if the builder should accept multiple source file extensions), a Python function; an Action object (see the next section); or a list of any of the above.
An action function takes three arguments: source - a list of source nodes, target - a list of target nodes, env - the construction environment.
The prefix that will be prepended to the target file name. This may be specified as a:
* string,
* callable object - a function or other callable that takes two arguments (a construction environment and a list of sources) and returns a prefix,
* dictionary - specifies a mapping from a specific source suffix (of the first source specified) to a corresponding target prefix. Both the source suffix and target prefix specifications may use environment variable substitution, and the target prefix (the 'value' entries in the dictionary) may also be a callable object. The default target prefix may be indicated by a dictionary entry with a key value of None.
b = Builder("build_it < $SOURCE > $TARGET", prefix = "file-") def gen_prefix(env, sources): return "file-" + env['PLATFORM'] + '-' b = Builder("build_it < $SOURCE > $TARGET", prefix = gen_prefix) b = Builder("build_it < $SOURCE > $TARGET", suffix = { None: "file-", "$SRC_SFX_A": gen_prefix })
The suffix that will be appended to the target file name. This may be specified in the same manner as the prefix above. If the suffix is a string, then scons will append a '.' to the beginning of the suffix if it's not already there. The string returned by callable object (or obtained from the dictionary) is untouched and must append its own '.' to the beginning if one is desired.
b = Builder("build_it < $SOURCE > $TARGET" suffix = "-file") def gen_suffix(env, sources): return "." + env['PLATFORM'] + "-file" b = Builder("build_it < $SOURCE > $TARGET", suffix = gen_suffix) b = Builder("build_it < $SOURCE > $TARGET", suffix = { None: ".sfx1", "$SRC_SFX_A": gen_suffix })
When set to any true value, causes scons to add the target suffix specified by the suffix keyword to any target strings that have a different suffix. (The default behavior is to leave untouched any target file name that looks like it already has any suffix.)
b1 = Builder("build_it < $SOURCE > $TARGET" suffix = ".out") b2 = Builder("build_it < $SOURCE > $TARGET" suffix = ".out", ensure_suffix) env = Environment() env['BUILDERS']['B1'] = b1 env['BUILDERS']['B2'] = b2 # Builds "foo.txt" because ensure_suffix is not set. env.B1('foo.txt', 'foo.in') # Builds "bar.txt.out" because ensure_suffix is set. env.B2('bar.txt', 'bar.in')
The expected source file name suffix. This may be a string or a list of strings.
A Scanner object that will be invoked to find implicit dependencies for this target file. This keyword argument should be used for Scanner objects that find implicit dependencies based only on the target file and the construction environment, not for implicit dependencies based on source files. (See the section "Scanner Objects" below, for information about creating Scanner objects.)
A Scanner object that will be invoked to find implicit dependencies in any source files used to build this target file. This is where you would specify a scanner to find things like #include lines in source files. The pre-built DirScanner Scanner object may be used to indicate that this Builder should scan directory trees for on-disk changes to files that scons does not know about from other Builder or function calls. (See the section "Scanner Objects" below, for information about creating your own Scanner objects.)
A factory function that the Builder will use to turn any targets specified as strings into SCons Nodes. By default, SCons assumes that all targets are files. Other useful target_factory values include Dir, for when a Builder creates a directory target, and Entry, for when a Builder can create either a file or directory target.
Example:
MakeDirectoryBuilder = Builder(action=my_mkdir, target_factory=Dir) env = Environment() env.Append(BUILDERS = {'MakeDirectory':MakeDirectoryBuilder}) env.MakeDirectory('new_directory', [])
Note that the call to the MakeDirectory Builder needs to specify an empty source list to make the string represent the builder's target; without that, it would assume the argument is the source, and would try to deduce the target name from it, which in the absence of an automatically-added prefix or suffix would lead to a matching target and source name and a circular dependency.
A factory function that the Builder will use to turn any sources specified as strings into SCons Nodes. By default, SCons assumes that all source are files. Other useful source_factory values include Dir, for when a Builder uses a directory as a source, and Entry, for when a Builder can use files or directories (or both) as sources.
Example:
CollectBuilder = Builder(action=my_mkdir, source_factory=Entry) env = Environment() env.Append(BUILDERS = {'Collect':CollectBuilder}) env.Collect('archive', ['directory_name', 'file_name'])
A function or list of functions to manipulate the target and source lists before dependencies are established and the target(s) are actually built. emitter can also be a string containing a construction variable to expand to an emitter function or list of functions, or a dictionary mapping source file suffixes to emitter functions. (Only the suffix of the first source file is used to select the actual emitter function from an emitter dictionary.)
An emitter function takes three arguments: source - a list of source nodes, target - a list of target nodes, env - the construction environment. An emitter must return a tuple containing two lists, the list of targets to be built by this builder, and the list of sources for this builder.
Example:
def e(target, source, env): return (target + ['foo.foo'], source + ['foo.src']) # Simple association of an emitter function with a Builder. b = Builder("my_build < $TARGET > $SOURCE", emitter = e) def e2(target, source, env): return (target + ['bar.foo'], source + ['bar.src']) # Simple association of a list of emitter functions with a Builder. b = Builder("my_build < $TARGET > $SOURCE", emitter = [e, e2]) # Calling an emitter function through a construction variable. env = Environment(MY_EMITTER = e) b = Builder("my_build < $TARGET > $SOURCE", emitter = '$MY_EMITTER') # Calling a list of emitter functions through a construction variable. env = Environment(EMITTER_LIST = [e, e2]) b = Builder("my_build < $TARGET > $SOURCE", emitter = '$EMITTER_LIST') # Associating multiple emitters with different file # suffixes using a dictionary. def e_suf1(target, source, env): return (target + ['another_target_file'], source) def e_suf2(target, source, env): return (target, source + ['another_source_file']) b = Builder("my_build < $TARGET > $SOURCE", emitter = {'.suf1' : e_suf1, '.suf2' : e_suf2})
Specifies whether this builder is allowed to be called multiple times for the same target file(s). The default is 0, which means the builder can not be called multiple times for the same target file(s). Calling a builder multiple times for the same target simply adds additional source files to the target; it is not allowed to change the environment associated with the target, specify addition environment overrides, or associate a different builder with the target.
A construction environment that can be used to fetch source code using this Builder. (Note that this environment is not used for normal builds of normal target files, which use the environment that was used to call the Builder for the target file.)
A function that returns a list of actions that will be executed to build the target(s) from the source(s). The returned action(s) may be an Action object, or anything that can be converted into an Action object (see the next section).
The generator function takes four arguments: source - a list of source nodes, target - a list of target nodes, env - the construction environment, for_signature - a Boolean value that specifies whether the generator is being called for generating a build signature (as opposed to actually executing the command). Example:
def g(source, target, env, for_signature): return [["gcc", "-c", "-o"] + target + source] b = Builder(generator=g)
The generator and action arguments must not both be used for the same Builder.
Specifies a builder to use when a source file name suffix does not match any of the suffixes of the builder. Using this argument produces a multi-stage builder.
Specifies that this builder expects exactly one source file per call. Giving more than one source file without target files results in implicitly calling the builder multiple times (once for each source given). Giving multiple source files together with target files results in a UserError exception.
The generator and action arguments must not both be used for the same Builder.
When the specified action argument is a dictionary, the default behavior when a builder is passed multiple source files is to make sure that the extensions of all the source files match. If it is legal for this builder to be called with a list of source files with different extensions, this check can be suppressed by setting source_ext_match to None or some other non-true value. When source_ext_match is disable, scons will use the suffix of the first specified source file to select the appropriate action from the action dictionary.
In the following example, the setting of source_ext_match prevents scons from exiting with an error due to the mismatched suffixes of foo.in and foo.extra.
b = Builder(action={'.in' : 'build $SOURCES > $TARGET'}, source_ext_match = None) env = Environment(BUILDERS = {'MyBuild':b}) env.MyBuild('foo.out', ['foo.in', 'foo.extra'])
A construction environment that can be used to fetch source code using this Builder. (Note that this environment is not used for normal builds of normal target files, which use the environment that was used to call the Builder for the target file.)
b = Builder(action="build < $SOURCE > $TARGET") env = Environment(BUILDERS = {'MyBuild' : b}) env.MyBuild('foo.out', 'foo.in', my_arg = 'xyzzy')
A directory from which scons will execute the action(s) specified for this Builder. If the chdir argument is a string or a directory Node, scons will change to the specified directory. If the chdir is not a string or Node and is non-zero, then scons will change to the target file's directory.
Note that scons will not automatically modify its expansion of construction variables like $TARGET and $SOURCE when using the chdir keyword argument--that is, the expanded file names will still be relative to the top-level SConstruct directory, and consequently incorrect relative to the chdir directory. Builders created using chdir keyword argument, will need to use construction variable expansions like ${TARGET.file} and ${SOURCE.file} to use just the filename portion of the targets and source.
b = Builder(action="build < ${SOURCE.file} > ${TARGET.file}", chdir=1) env = Environment(BUILDERS = {'MyBuild' : b}) env.MyBuild('sub/dir/foo.out', 'sub/dir/foo.in')
WARNING:
Python only keeps one current directory
location for all of the threads.
This means that use of the
chdir
argument
will
not
work with the SCons
-j
option,
because individual worker threads spawned
by SCons interfere with each other
when they start changing directory.
Any additional keyword arguments supplied when a Builder object is created (that is, when the Builder() function is called) will be set in the executing construction environment when the Builder object is called. The canonical example here would be to set a construction variable to the repository of a source code system.
Any additional keyword arguments supplied when a Builder object is called will only be associated with the target created by that particular Builder call (and any other files built as a result of the call).
These extra keyword arguments are passed to the following functions: command generator functions, function Actions, and emitter functions.
The Builder() function will turn its action keyword argument into an appropriate internal Action object. You can also explicitly create Action objects using the Action() global function, which can then be passed to the Builder() function. This can be used to configure an Action object more flexibly, or it may simply be more efficient than letting each separate Builder object create a separate Action when multiple Builder objects need to do the same thing.
The Action() global function returns an appropriate object for the action represented by the type of the first argument:
If the first argument is already an Action object, the object is simply returned.
If the first argument is a string, a command-line Action is returned. Note that the command-line string may be preceded by an @ (at-sign) to suppress printing of the specified command line, or by a - (hyphen) to ignore the exit status from the specified command:
Action('$CC -c -o $TARGET $SOURCES') # Doesn't print the line being executed. Action('@build $TARGET $SOURCES') # Ignores return value Action('-build $TARGET $SOURCES')
If the first argument is a list, then a list of Action objects is returned. An Action object is created as necessary for each element in the list. If an element within the list is itself a list, the internal list is the command and arguments to be executed via the command line. This allows white space to be enclosed in an argument by defining a command in a list within a list:
Action([['cc', '-c', '-DWHITE SPACE', '-o', '$TARGET', '$SOURCES']])
If the first argument is a Python function, a function Action is returned. The Python function must take three keyword arguments, target (a Node object representing the target file), source (a Node object representing the source file) and env (the construction environment used for building the target file). The target and source arguments may be lists of Node objects if there is more than one target file or source file. The actual target and source file name(s) may be retrieved from their Node objects via the built-in Python str() function:
target_file_name = str(target) source_file_names = map(lambda x: str(x), source)
The function should return
0
or
None
to indicate a successful build of the target file(s).
The function may raise an exception
or return a non-zero exit status
to indicate an unsuccessful build.
def build_it(target = None, source = None, env = None): # build the target from the source return 0 a = Action(build_it)
If the action argument is not one of the above, None is returned.
The second argument is optional and is used to define the output which is printed when the Action is actually performed. In the absence of this parameter, or if it's an empty string, a default output depending on the type of the action is used. For example, a command-line action will print the executed command. The argument must be either a Python function or a string.
In the first case, it's a function that returns a string to be printed to describe the action being executed. The function may also be specified by the strfunction= keyword argument. Like a function to build a file, this function must take three keyword arguments: target (a Node object representing the target file), source (a Node object representing the source file) and env (a construction environment). The target and source arguments may be lists of Node objects if there is more than one target file or source file.
In the second case, you provide the string itself. The string may also be specified by the cmdstr= keyword argument. The string typically contains variables, notably $TARGET(S) and $SOURCE(S), or consists of just a single variable, which is optionally defined somewhere else. SCons itself heavily uses the latter variant.
Examples:
def build_it(target, source, env): # build the target from the source return 0 def string_it(target, source, env): return "building '%s' from '%s'" % (target[0], source[0]) # Use a positional argument. f = Action(build_it, string_it) s = Action(build_it, "building '$TARGET' from '$SOURCE'") # Alternatively, use a keyword argument. f = Action(build_it, strfunction=string_it) s = Action(build_it, cmdstr="building '$TARGET' from '$SOURCE'") # You can provide a configurable variable. l = Action(build_it, '$STRINGIT')
The third and succeeding arguments, if present, may either be a construction variable or a list of construction variables whose values will be included in the signature of the Action when deciding whether a target should be rebuilt because the action changed. The variables may also be specified by a varlist= keyword parameter; if both are present, they are combined. This is necessary whenever you want a target to be rebuilt when a specific construction variable changes. This is not often needed for a string action, as the expanded variables will normally be part of the command line, but may be needed if a Python function action uses the value of a construction variable when generating the command line.
def build_it(target, source, env): # build the target from the 'XXX' construction variable open(target[0], 'w').write(env['XXX']) return 0 # Use positional arguments. a = Action(build_it, '$STRINGIT', ['XXX']) # Alternatively, use a keyword argument. a = Action(build_it, varlist=['XXX'])
The Action() global function can be passed the following optional keyword arguments to modify the Action object's behavior:
chdir The chdir keyword argument specifies that scons will execute the action after changing to the specified directory. If the chdir argument is a string or a directory Node, scons will change to the specified directory. If the chdir argument is not a string or Node and is non-zero, then scons will change to the target file's directory.
Note that scons will not automatically modify its expansion of construction variables like $TARGET and $SOURCE when using the chdir keyword argument--that is, the expanded file names will still be relative to the top-level SConstruct directory, and consequently incorrect relative to the chdir directory. Builders created using chdir keyword argument, will need to use construction variable expansions like ${TARGET.file} and ${SOURCE.file} to use just the filename portion of the targets and source.
a = Action("build < ${SOURCE.file} > ${TARGET.file}", chdir=1)
exitstatfunc The Action() global function also takes an exitstatfunc keyword argument which specifies a function that is passed the exit status (or return value) from the specified action and can return an arbitrary or modified value. This can be used, for example, to specify that an Action object's return value should be ignored under special conditions and SCons should, therefore, consider that the action always suceeds:
def always_succeed(s): # Always return 0, which indicates success. return 0 a = Action("build < ${SOURCE.file} > ${TARGET.file}", exitstatfunc=always_succeed)
batch_key The batch_key keyword argument can be used to specify that the Action can create multiple target files by processing multiple independent source files simultaneously. (The canonical example is "batch compilation" of multiple object files by passing multiple source files to a single invocation of a compiler such as Microsoft's Visual C / C++ compiler.) If the batch_key argument is any non-False, non-callable Python value, the configured Action object will cause scons to collect all targets built with the Action object and configured with the same construction environment into single invocations of the Action object's command line or function. Command lines will typically want to use the CHANGED_SOURCES construction variable (and possibly CHANGED_TARGETS as well) to only pass to the command line those sources that have actually changed since their targets were built.
Example:
a = Action('build $CHANGED_SOURCES', batch_key=True)
The batch_key argument may also be a callable function that returns a key that will be used to identify different "batches" of target files to be collected for batch building. A batch_key function must take the following arguments:
The action object.
The construction environment configured for the target.
The list of targets for a particular configured action.
The list of source for a particular configured action.
The returned key should typically be a tuple of values derived from the arguments, using any appropriate logic to decide how multiple invocations should be batched. For example, a batch_key function may decide to return the value of a specific construction variable from the env argument which will cause scons to batch-build targets with matching values of that variable, or perhaps return the id() of the entire construction environment, in which case scons will batch-build all targets configured with the same construction environment. Returning None indicates that the particular target should not be part of any batched build, but instead will be built by a separate invocation of action's command or function. Example:
def batch_key(action, env, target, source): tdir = target[0].dir if tdir.name == 'special': # Don't batch-build any target # in the special/ subdirectory. return None return (id(action), id(env), tdir) a = Action('build $CHANGED_SOURCES', batch_key=batch_key)
scons supplies a number of functions that arrange for various common file and directory manipulations to be performed. These are similar in concept to "tasks" in the Ant build tool, although the implementation is slightly different. These functions do not actually perform the specified action at the time the function is called, but instead return an Action object that can be executed at the appropriate time. (In Object-Oriented terminology, these are actually Action Factory functions that return Action objects.)
In practice, there are two natural ways that these Action Functions are intended to be used.
First, if you need to perform the action at the time the SConscript file is being read, you can use the Execute global function to do so:
Execute(Touch('file'))
Second, you can use these functions to supply Actions in a list for use by the Command method. This can allow you to perform more complicated sequences of file manipulation without relying on platform-specific external commands: that
env = Environment(TMPBUILD = '/tmp/builddir') env.Command('foo.out', 'foo.in', [Mkdir('$TMPBUILD'), Copy('$TMPBUILD', '${SOURCE.dir}'), "cd $TMPBUILD && make", Delete('$TMPBUILD')])
Returns an Action object that changes the permissions on the specified dest file or directory to the specified mode. Examples:
Execute(Chmod('file', 0755)) env.Command('foo.out', 'foo.in', [Copy('$TARGET', '$SOURCE'), Chmod('$TARGET', 0755)])
Returns an Action object that will copy the src source file or directory to the dest destination file or directory. Examples:
Execute(Copy('foo.output', 'foo.input')) env.Command('bar.out', 'bar.in', Copy('$TARGET', '$SOURCE'))
Returns an Action that deletes the specified entry, which may be a file or a directory tree. If a directory is specified, the entire directory tree will be removed. If the must_exist flag is set, then a Python error will be thrown if the specified entry does not exist; the default is must_exist=0, that is, the Action will silently do nothing if the entry does not exist. Examples:
Execute(Delete('/tmp/buildroot')) env.Command('foo.out', 'foo.in', [Delete('${TARGET.dir}'), MyBuildAction]) Execute(Delete('file_that_must_exist', must_exist=1))
Returns an Action that creates the specified directory dir . Examples:
Execute(Mkdir('/tmp/outputdir')) env.Command('foo.out', 'foo.in', [Mkdir('/tmp/builddir'), Copy('/tmp/builddir/foo.in', '$SOURCE'), "cd /tmp/builddir && make", Copy('$TARGET', '/tmp/builddir/foo.out')])
Returns an Action that moves the specified src file or directory to the specified dest file or directory. Examples:
Execute(Move('file.destination', 'file.source')) env.Command('output_file', 'input_file', [MyBuildAction, Move('$TARGET', 'file_created_by_MyBuildAction')])
Returns an Action that updates the modification time on the specified file. Examples:
Execute(Touch('file_to_be_touched')) env.Command('marker', 'input_file', [MyBuildAction, Touch('$TARGET')])
Before executing a command, scons performs construction variable interpolation on the strings that make up the command line of builders. Variables are introduced by a $ prefix. Besides construction variables, scons provides the following variables for each command execution:
The file names of all sources of the build command that have changed since the target was last built.
The file names of all targets that would be built from sources that have changed since the target was last built.
The file name of the source of the build command, or the file name of the first source if multiple sources are being built.
The file names of the sources of the build command.
The file name of the target being built, or the file name of the first target if multiple targets are being built.
The file names of all targets being built.
The file names of all sources of the build command that have not changed since the target was last built.
The file names of all targets that would be built from sources that have not changed since the target was last built.
(Note that the above variables are reserved and may not be set in a construction environment.)
For example, given the construction variable CC='cc', targets=['foo'], and sources=['foo.c', 'bar.c']:
action='$CC -c -o $TARGET $SOURCES'
would produce the command line:
cc -c -o foo foo.c bar.c
Variable names may be surrounded by curly braces ({}) to separate the name from the trailing characters. Within the curly braces, a variable name may have a Python slice subscript appended to select one or more items from a list. In the previous example, the string:
${SOURCES[1]}
would produce:
bar.c
Additionally, a variable name may have the following special modifiers appended within the enclosing curly braces to modify the interpolated string:
The base path of the file name, including the directory path but excluding any suffix.
The name of the directory in which the file exists.
The file name, minus any directory portion.
Just the basename of the file, minus any suffix and minus the directory.
Just the file suffix.
The absolute path name of the file.
The POSIX form of the path, with directories separated by / (forward slashes) not backslashes. This is sometimes necessary on Windows systems when a path references a file on other (POSIX) systems.
The directory and file name to the source file linked to this file through VariantDir(). If this file isn't linked, it just returns the directory and filename unchanged.
The directory containing the source file linked to this file through VariantDir(). If this file isn't linked, it just returns the directory part of the filename.
The directory and file name to the source file linked to this file through VariantDir(). If the file does not exist locally but exists in a Repository, the path in the Repository is returned. If this file isn't linked, it just returns the directory and filename unchanged.
The Repository directory containing the source file linked to this file through VariantDir(). If this file isn't linked, it just returns the directory part of the filename.
For example, the specified target will expand as follows for the corresponding modifiers:
$TARGET => sub/dir/file.x ${TARGET.base} => sub/dir/file ${TARGET.dir} => sub/dir ${TARGET.file} => file.x ${TARGET.filebase} => file ${TARGET.suffix} => .x ${TARGET.abspath} => /top/dir/sub/dir/file.x SConscript('src/SConscript', variant_dir='sub/dir') $SOURCE => sub/dir/file.x ${SOURCE.srcpath} => src/file.x ${SOURCE.srcdir} => src Repository('/usr/repository') $SOURCE => sub/dir/file.x ${SOURCE.rsrcpath} => /usr/repository/src/file.x ${SOURCE.rsrcdir} => /usr/repository/src
Note that curly braces braces may also be used to enclose arbitrary Python code to be evaluated. (In fact, this is how the above modifiers are substituted, they are simply attributes of the Python objects that represent TARGET, SOURCES, etc.) See the section "Python Code Substitution" below, for more thorough examples of how this can be used.
Lastly, a variable name may be a callable Python function associated with a construction variable in the environment. The function should take four arguments: target - a list of target nodes, source - a list of source nodes, env - the construction environment, for_signature - a Boolean value that specifies whether the function is being called for generating a build signature. SCons will insert whatever the called function returns into the expanded string:
def foo(target, source, env, for_signature): return "bar" # Will expand $BAR to "bar baz" env=Environment(FOO=foo, BAR="$FOO baz")
You can use this feature to pass arguments to a
Python function by creating a callable class
that stores one or more arguments in an object,
and then uses them when the
__call__()
method is called.
Note that in this case,
the entire variable expansion must
be enclosed by curly braces
so that the arguments will
be associated with the
instantiation of the class:
class foo(object): def __init__(self, arg): self.arg = arg def __call__(self, target, source, env, for_signature): return self.arg + " bar" # Will expand $BAR to "my argument bar baz" env=Environment(FOO=foo, BAR="${FOO('my argument')} baz")
The special pseudo-variables $( and $) may be used to surround parts of a command line that may change without causing a rebuild--that is, which are not included in the signature of target files built with this command. All text between $( and $) will be removed from the command line before it is added to file signatures, and the $( and $) will be removed before the command is executed. For example, the command line:
echo Last build occurred $( $TODAY $). > $TARGET
would execute the command:
echo Last build occurred $TODAY. > $TARGET
but the command signature added to any target files would be:
echo Last build occurred . > $TARGET
Any python code within ${-} pairs gets evaluated by python 'eval', with the python globals set to the current environment's set of construction variables. So in the following case:
env['COND'] = 0 env.Command('foo.out', 'foo.in', '''echo ${COND==1 and 'FOO' or 'BAR'} > $TARGET''')
the command executed will be either
echo FOO > foo.out
or
echo BAR > foo.out
according to the current value of env['COND'] when the command is executed. The evaluation occurs when the target is being built, not when the SConscript is being read. So if env['COND'] is changed later in the SConscript, the final value will be used.
Here's a more interesting example. Note that all of COND, FOO, and BAR are environment variables, and their values are substituted into the final command. FOO is a list, so its elements are interpolated separated by spaces.
env=Environment() env['COND'] = 0 env['FOO'] = ['foo1', 'foo2'] env['BAR'] = 'barbar' env.Command('foo.out', 'foo.in', 'echo ${COND==1 and FOO or BAR} > $TARGET') # Will execute this: # echo foo1 foo2 > foo.out
SCons uses the following rules when converting construction variables into command lines:
When the value is a string it is interpreted as a space delimited list of command line arguments.
When the value is a list it is interpreted as a list of command line arguments. Each element of the list is converted to a string.
Anything that is not a list or string is converted to a string and interpreted as a single command line argument.
Newline characters (\n) delimit lines. The newline parsing is done after all other parsing, so it is not possible for arguments (e.g. file names) to contain embedded newline characters. This limitation will likely go away in a future version of SCons.
You can use the Scanner function to define objects to scan new file types for implicit dependencies. The Scanner function accepts the following arguments:
This can be either: 1) a Python function that will process the Node (file) and return a list of File Nodes representing the implicit dependencies (file names) found in the contents; or: 2) a dictionary that maps keys (typically the file suffix, but see below for more discussion) to other Scanners that should be called.
If the argument is actually a Python function, the function must take three or four arguments:
def scanner_function(node, env, path):
def scanner_function(node, env, path, arg=None):
The node argument is the internal SCons node representing the file. Use str(node) to fetch the name of the file, and node.get_contents() to fetch contents of the file. Note that the file is not guaranteed to exist before the scanner is called, so the scanner function should check that if there's any chance that the scanned file might not exist (for example, if it's built from other files).
The env argument is the construction environment for the scan. Fetch values from it using the env.Dictionary() method.
The path argument is a tuple (or list) of directories that can be searched for files. This will usually be the tuple returned by the path_function argument (see below).
The arg argument is the argument supplied when the scanner was created, if any.
The name of the Scanner. This is mainly used to identify the Scanner internally.
An optional argument that, if specified, will be passed to the scanner function (described above) and the path function (specified below).
An optional list that can be used to determine which scanner should be used for a given Node. In the usual case of scanning for file names, this argument will be a list of suffixes for the different file types that this Scanner knows how to scan. If the argument is a string, then it will be expanded into a list by the current environment.
A Python function that takes four or five arguments: a construction environment, a Node for the directory containing the SConscript file in which the first target was defined, a list of target nodes, a list of source nodes, and an optional argument supplied when the scanner was created. The path_function returns a tuple of directories that can be searched for files to be returned by this Scanner object. (Note that the FindPathDirs() function can be used to return a ready-made path_function for a given construction variable name, instead of having to write your own function from scratch.)
The class of Node that should be returned by this Scanner object. Any strings or other objects returned by the scanner function that are not of this class will be run through the node_factory function.
A Python function that will take a string or other object and turn it into the appropriate class of Node to be returned by this Scanner object.
An optional Python function that takes two arguments, a Node (file) and a construction environment, and returns whether the Node should, in fact, be scanned for dependencies. This check can be used to eliminate unnecessary calls to the scanner function when, for example, the underlying file represented by a Node does not yet exist.
An optional flag that specifies whether this scanner should be re-invoked on the dependency files returned by the scanner. When this flag is not set, the Node subsystem will only invoke the scanner on the file being scanned, and not (for example) also on the files specified by the #include lines in the file being scanned. recursive may be a callable function, in which case it will be called with a list of Nodes found and should return a list of Nodes that should be scanned recursively; this can be used to select a specific subset of Nodes for additional scanning.
Note that scons has a global SourceFileScanner object that is used by the Object(), SharedObject(), and StaticObject() builders to decide which scanner should be used for different file extensions. You can using the SourceFileScanner.add_scanner() method to add your own Scanner object to the scons infrastructure that builds target programs or libraries from a list of source files of different types:
def xyz_scan(node, env, path): contents = node.get_text_contents() # Scan the contents and return the included files. XYZScanner = Scanner(xyz_scan) SourceFileScanner.add_scanner('.xyz', XYZScanner) env.Program('my_prog', ['file1.c', 'file2.f', 'file3.xyz'])
SCons and its configuration files are very portable, due largely to its implementation in Python. There are, however, a few portability issues waiting to trap the unwary.
SCons handles the upper-case .C file suffix differently, depending on the capabilities of the underlying system. On a case-sensitive system such as Linux or UNIX, SCons treats a file with a .C suffix as a C++ source file. On a case-insensitive system such as Windows, SCons treats a file with a .C suffix as a C source file.
SCons handles the upper-case .F file suffix differently, depending on the capabilities of the underlying system. On a case-sensitive system such as Linux or UNIX, SCons treats a file with a .F suffix as a Fortran source file that is to be first run through the standard C preprocessor. On a case-insensitive system such as Windows, SCons treats a file with a .F suffix as a Fortran source file that should not be run through the C preprocessor.
Cygwin supplies a set of tools and utilities that let users work on a Windows system using a more POSIX-like environment. The Cygwin tools, including Cygwin Python, do this, in part, by sharing an ability to interpret UNIX-like path names. For example, the Cygwin tools will internally translate a Cygwin path name like /cygdrive/c/mydir to an equivalent Windows pathname of C:/mydir (equivalent to C:\mydir).
Versions of Python that are built for native Windows execution, such as the python.org and ActiveState versions, do not have the Cygwin path name semantics. This means that using a native Windows version of Python to build compiled programs using Cygwin tools (such as gcc, bison, and flex) may yield unpredictable results. "Mixing and matching" in this way can be made to work, but it requires careful attention to the use of path names in your SConscript files.
In practice, users can sidestep the issue by adopting the following rules: When using gcc, use the Cygwin-supplied Python interpreter to run SCons; when using Microsoft Visual C/C++ (or some other Windows compiler) use the python.org or ActiveState version of Python to run SCons.
On Windows systems, SCons is executed via a wrapper scons.bat file. This has (at least) two ramifications:
First, Windows command-line users that want to use variable assignment on the command line may have to put double quotes around the assignments:
scons "FOO=BAR" "BAZ=BLEH"
Second, the Cygwin shell does not recognize this file as being the same as an scons command issued at the command-line prompt. You can work around this either by executing scons.bat from the Cygwin command line, or by creating a wrapper shell script named scons .
The MinGW bin directory must be in your PATH environment variable or the PATH variable under the ENV construction variable for SCons to detect and use the MinGW tools. When running under the native Windows Python interpreter, SCons will prefer the MinGW tools over the Cygwin tools, if they are both installed, regardless of the order of the bin directories in the PATH variable. If you have both MSVC and MinGW installed and you want to use MinGW instead of MSVC, then you must explicitly tell SCons to use MinGW by passing
tools=['mingw']
to the Environment() function, because SCons will prefer the MSVC tools over the MinGW tools.
To help you get started using SCons, this section contains a brief overview of some common tasks.
env = Environment() env.Program(target = 'foo', source = 'foo.c')
Note: Build the file by specifying the target as an argument ("scons foo" or "scons foo.exe"). or by specifying a dot ("scons .").
env = Environment() env.Program(target = 'foo', source = Split('f1.c f2.c f3.c'))
env = Environment(CCFLAGS = '-g') env.Program(target = 'foo', source = 'foo.c')
Note: You do not need to set CCFLAGS to specify -I options by hand. SCons will construct the right -I options from CPPPATH.
env = Environment(CPPPATH = ['.']) env.Program(target = 'foo', source = 'foo.c')
env = Environment(CPPPATH = ['include1', 'include2']) env.Program(target = 'foo', source = 'foo.c')
env = Environment() env.StaticLibrary(target = 'foo', source = Split('l1.c l2.c')) env.StaticLibrary(target = 'bar', source = ['l3.c', 'l4.c'])
env = Environment() env.SharedLibrary(target = 'foo', source = ['l5.c', 'l6.c']) env.SharedLibrary(target = 'bar', source = Split('l7.c l8.c'))
env = Environment(LIBS = 'mylib', LIBPATH = ['.']) env.Library(target = 'mylib', source = Split('l1.c l2.c')) env.Program(target = 'prog', source = ['p1.c', 'p2.c'])
Notice that when you invoke the Builder, you can leave off the target file suffix, and SCons will add it automatically.
bld = Builder(action = 'pdftex < $SOURCES > $TARGET' suffix = '.pdf', src_suffix = '.tex') env = Environment(BUILDERS = {'PDFBuilder' : bld}) env.PDFBuilder(target = 'foo.pdf', source = 'foo.tex') # The following creates "bar.pdf" from "bar.tex" env.PDFBuilder(target = 'bar', source = 'bar')
Note also that the above initialization overwrites the default Builder objects, so the Environment created above can not be used call Builders like env.Program(), env.Object(), env.StaticLibrary(), etc.
bld = Builder(action = 'pdftex < $SOURCES > $TARGET' suffix = '.pdf', src_suffix = '.tex') env = Environment() env.Append(BUILDERS = {'PDFBuilder' : bld}) env.PDFBuilder(target = 'foo.pdf', source = 'foo.tex') env.Program(target = 'bar', source = 'bar.c')
You also can use other Pythonic techniques to add to the BUILDERS construction variable, such as:
env = Environment() env['BUILDERS]['PDFBuilder'] = bld
The following example shows an extremely simple scanner (the kfile_scan() function) that doesn't use a search path at all and simply returns the file names present on any include lines in the scanned file. This would implicitly assume that all included files live in the top-level directory:
import re include_re = re.compile(r'^include\s+(\S+)$', re.M) def kfile_scan(node, env, path, arg): contents = node.get_text_contents() includes = include_re.findall(contents) return env.File(includes) kscan = Scanner(name = 'kfile', function = kfile_scan, argument = None, skeys = ['.k']) scanners = Environment().Dictionary('SCANNERS') env = Environment(SCANNERS = scanners + [kscan]) env.Command('foo', 'foo.k', 'kprocess < $SOURCES > $TARGET') bar_in = File('bar.in') env.Command('bar', bar_in, 'kprocess $SOURCES > $TARGET') bar_in.target_scanner = kscan
It is important to note that you have to return a list of File nodes from the scan function, simple strings for the file names won't do. As in the examples we are showing here, you can use the File() function of your current Environment in order to create nodes on the fly from a sequence of file names with relative paths.
Here is a similar but more complete example that searches a path of directories (specified as the MYPATH construction variable) for files that actually exist:
import re import os include_re = re.compile(r'^include\s+(\S+)$', re.M) def my_scan(node, env, path, arg): contents = node.get_text_contents() includes = include_re.findall(contents) if includes == []: return [] results = [] for inc in includes: for dir in path: file = str(dir) + os.sep + inc if os.path.exists(file): results.append(file) break return env.File(results) scanner = Scanner(name = 'myscanner', function = my_scan, argument = None, skeys = ['.x'], path_function = FindPathDirs('MYPATH') ) scanners = Environment().Dictionary('SCANNERS') env = Environment(SCANNERS = scanners + [scanner], MYPATH = ['incs']) env.Command('foo', 'foo.x', 'xprocess < $SOURCES > $TARGET')
The FindPathDirs() function used in the previous example returns a function (actually a callable Python object) that will return a list of directories specified in the $MYPATH construction variable. It lets SCons detect the file incs/foo.inc , even if foo.x contains the line include foo.inc only. If you need to customize how the search path is derived, you would provide your own path_function argument when creating the Scanner object, as follows:
# MYPATH is a list of directories to search for files in def pf(env, dir, target, source, arg): top_dir = Dir('#').abspath results = [] if 'MYPATH' in env: for p in env['MYPATH']: results.append(top_dir + os.sep + p) return results scanner = Scanner(name = 'myscanner', function = my_scan, argument = None, skeys = ['.x'], path_function = pf )
Notice that the file names specified in a subdirectory's SConscript file are relative to that subdirectory.
SConstruct: env = Environment() env.Program(target = 'foo', source = 'foo.c') SConscript('sub/SConscript') sub/SConscript: env = Environment() # Builds sub/foo from sub/foo.c env.Program(target = 'foo', source = 'foo.c') SConscript('dir/SConscript') sub/dir/SConscript: env = Environment() # Builds sub/dir/foo from sub/dir/foo.c env.Program(target = 'foo', source = 'foo.c')
You must explicitly Export() and Import() variables that you want to share between SConscript files.
SConstruct: env = Environment() env.Program(target = 'foo', source = 'foo.c') Export("env") SConscript('subdirectory/SConscript') subdirectory/SConscript: Import("env") env.Program(target = 'foo', source = 'foo.c')
Use the variant_dir keyword argument to the SConscript function to establish one or more separate variant build directory trees for a given source directory:
SConstruct: cppdefines = ['FOO'] Export("cppdefines") SConscript('src/SConscript', variant_dir='foo') cppdefines = ['BAR'] Export("cppdefines") SConscript('src/SConscript', variant_dir='bar') src/SConscript: Import("cppdefines") env = Environment(CPPDEFINES = cppdefines) env.Program(target = 'src', source = 'src.c')
Note the use of the Export() method to set the "cppdefines" variable to a different value each time we call the SConscript function.
SConstruct: env = Environment(LIBPATH = ['#libA', '#libB']) Export('env') SConscript('libA/SConscript') SConscript('libB/SConscript') SConscript('Main/SConscript') libA/SConscript: Import('env') env.Library('a', Split('a1.c a2.c a3.c')) libB/SConscript: Import('env') env.Library('b', Split('b1.c b2.c b3.c')) Main/SConscript: Import('env') e = env.Copy(LIBS = ['a', 'b']) e.Program('foo', Split('m1.c m2.c m3.c'))
The '#' in the LIBPATH directories specify that they're relative to the top-level directory, so they don't turn into "Main/libA" when they're used in Main/SConscript.
Specifying only 'a' and 'b' for the library names allows SCons to append the appropriate library prefix and suffix for the current platform (for example, 'liba.a' on POSIX systems, 'a.lib' on Windows).
The following would allow the C compiler to be specified on the command line or in the file custom.py.
vars = Variables('custom.py') vars.Add('CC', 'The C compiler.') env = Environment(variables=vars) Help(vars.GenerateHelpText(env))
The user could specify the C compiler on the command line:
scons "CC=my_cc"
or in the custom.py file:
CC = 'my_cc'
or get documentation on the options:
$ scons -h CC: The C compiler. default: None actual: cc
Since windows.h includes everything and the kitchen sink, it can take quite some time to compile it over and over again for a bunch of object files, so Microsoft provides a mechanism to compile a set of headers once and then include the previously compiled headers in any object file. This technology is called precompiled headers. The general recipe is to create a file named "StdAfx.cpp" that includes a single header named "StdAfx.h", and then include every header you want to precompile in "StdAfx.h", and finally include "StdAfx.h" as the first header in all the source files you are compiling to object files. For example:
StdAfx.h:
#include <windows.h> #include <my_big_header.h>
StdAfx.cpp:
#include <StdAfx.h>
Foo.cpp:
#include <StdAfx.h> /* do some stuff */
Bar.cpp:
#include <StdAfx.h> /* do some other stuff */
SConstruct:
env=Environment() env['PCHSTOP'] = 'StdAfx.h' env['PCH'] = env.PCH('StdAfx.cpp')[0] env.Program('MyApp', ['Foo.cpp', 'Bar.cpp'])
For more information see the document for the PCH builder, and the PCH and PCHSTOP construction variables. To learn about the details of precompiled headers consult the MSDN documention for /Yc, /Yu, and /Yp.
Since including debugging information in programs and shared libraries can cause their size to increase significantly, Microsoft provides a mechanism for including the debugging information in an external file called a PDB file. SCons supports PDB files through the PDB construction variable.
SConstruct:
env=Environment() env['PDB'] = 'MyApp.pdb' env.Program('MyApp', ['Foo.cpp', 'Bar.cpp'])
For more information see the document for the PDB construction variable.