cpython/Lib/packaging/compiler/ccompiler.py

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"""Abstract base class for compilers.
This modules contains CCompiler, an abstract base class that defines the
interface for the compiler abstraction model used by packaging.
"""
import os
from shutil import move
from packaging import logger
from packaging.util import split_quoted, execute, newer_group, spawn
from packaging.errors import (CompileError, LinkError, UnknownFileError)
from packaging.compiler import gen_preprocess_options
class CCompiler:
"""Abstract base class to define the interface that must be implemented
by real compiler classes. Also has some utility methods used by
several compiler classes.
The basic idea behind a compiler abstraction class is that each
instance can be used for all the compile/link steps in building a
single project. Thus, attributes common to all of those compile and
link steps -- include directories, macros to define, libraries to link
against, etc. -- are attributes of the compiler instance. To allow for
variability in how individual files are treated, most of those
attributes may be varied on a per-compilation or per-link basis.
"""
# 'name' is a class attribute that identifies this class. It
# keeps code that wants to know what kind of compiler it's dealing with
# from having to import all possible compiler classes just to do an
# 'isinstance'.
name = None
description = None
# XXX things not handled by this compiler abstraction model:
# * client can't provide additional options for a compiler,
# e.g. warning, optimization, debugging flags. Perhaps this
# should be the domain of concrete compiler abstraction classes
# (UnixCCompiler, MSVCCompiler, etc.) -- or perhaps the base
# class should have methods for the common ones.
# * can't completely override the include or library searchg
# path, ie. no "cc -I -Idir1 -Idir2" or "cc -L -Ldir1 -Ldir2".
# I'm not sure how widely supported this is even by Unix
# compilers, much less on other platforms. And I'm even less
# sure how useful it is; maybe for cross-compiling, but
# support for that is a ways off. (And anyways, cross
# compilers probably have a dedicated binary with the
# right paths compiled in. I hope.)
# * can't do really freaky things with the library list/library
# dirs, e.g. "-Ldir1 -lfoo -Ldir2 -lfoo" to link against
# different versions of libfoo.a in different locations. I
# think this is useless without the ability to null out the
# library search path anyways.
# Subclasses that rely on the standard filename generation methods
# implemented below should override these; see the comment near
# those methods ('object_filenames()' et. al.) for details:
src_extensions = None # list of strings
obj_extension = None # string
static_lib_extension = None
shared_lib_extension = None # string
static_lib_format = None # format string
shared_lib_format = None # prob. same as static_lib_format
exe_extension = None # string
# Default language settings. language_map is used to detect a source
# file or Extension target language, checking source filenames.
# language_order is used to detect the language precedence, when deciding
# what language to use when mixing source types. For example, if some
# extension has two files with ".c" extension, and one with ".cpp", it
# is still linked as c++.
language_map = {".c": "c",
".cc": "c++",
".cpp": "c++",
".cxx": "c++",
".m": "objc",
}
language_order = ["c++", "objc", "c"]
def __init__(self, verbose=0, dry_run=False, force=False):
self.dry_run = dry_run
self.force = force
self.verbose = verbose
# 'output_dir': a common output directory for object, library,
# shared object, and shared library files
self.output_dir = None
# 'macros': a list of macro definitions (or undefinitions). A
# macro definition is a 2-tuple (name, value), where the value is
# either a string or None (no explicit value). A macro
# undefinition is a 1-tuple (name,).
self.macros = []
# 'include_dirs': a list of directories to search for include files
self.include_dirs = []
# 'libraries': a list of libraries to include in any link
# (library names, not filenames: eg. "foo" not "libfoo.a")
self.libraries = []
# 'library_dirs': a list of directories to search for libraries
self.library_dirs = []
# 'runtime_library_dirs': a list of directories to search for
# shared libraries/objects at runtime
self.runtime_library_dirs = []
# 'objects': a list of object files (or similar, such as explicitly
# named library files) to include on any link
self.objects = []
for key, value in self.executables.items():
self.set_executable(key, value)
def set_executables(self, **args):
"""Define the executables (and options for them) that will be run
to perform the various stages of compilation. The exact set of
executables that may be specified here depends on the compiler
class (via the 'executables' class attribute), but most will have:
compiler the C/C++ compiler
linker_so linker used to create shared objects and libraries
linker_exe linker used to create binary executables
archiver static library creator
On platforms with a command line (Unix, DOS/Windows), each of these
is a string that will be split into executable name and (optional)
list of arguments. (Splitting the string is done similarly to how
Unix shells operate: words are delimited by spaces, but quotes and
backslashes can override this. See
'distutils.util.split_quoted()'.)
"""
# Note that some CCompiler implementation classes will define class
# attributes 'cpp', 'cc', etc. with hard-coded executable names;
# this is appropriate when a compiler class is for exactly one
# compiler/OS combination (eg. MSVCCompiler). Other compiler
# classes (UnixCCompiler, in particular) are driven by information
# discovered at run-time, since there are many different ways to do
# basically the same things with Unix C compilers.
for key, value in args.items():
if key not in self.executables:
raise ValueError("unknown executable '%s' for class %s" % \
(key, self.__class__.__name__))
self.set_executable(key, value)
def set_executable(self, key, value):
if isinstance(value, str):
setattr(self, key, split_quoted(value))
else:
setattr(self, key, value)
def _find_macro(self, name):
i = 0
for defn in self.macros:
if defn[0] == name:
return i
i = i + 1
return None
def _check_macro_definitions(self, definitions):
"""Ensures that every element of 'definitions' is a valid macro
definition, ie. either (name,value) 2-tuple or a (name,) tuple. Do
nothing if all definitions are OK, raise TypeError otherwise.
"""
for defn in definitions:
if not (isinstance(defn, tuple) and
(len(defn) == 1 or
(len(defn) == 2 and
(isinstance(defn[1], str) or defn[1] is None))) and
isinstance(defn[0], str)):
raise TypeError(("invalid macro definition '%s': " % defn) + \
"must be tuple (string,), (string, string), or " + \
"(string, None)")
# -- Bookkeeping methods -------------------------------------------
def define_macro(self, name, value=None):
"""Define a preprocessor macro for all compilations driven by this
compiler object. The optional parameter 'value' should be a
string; if it is not supplied, then the macro will be defined
without an explicit value and the exact outcome depends on the
compiler used (XXX true? does ANSI say anything about this?)
"""
# Delete from the list of macro definitions/undefinitions if
# already there (so that this one will take precedence).
i = self._find_macro(name)
if i is not None:
del self.macros[i]
defn = (name, value)
self.macros.append(defn)
def undefine_macro(self, name):
"""Undefine a preprocessor macro for all compilations driven by
this compiler object. If the same macro is defined by
'define_macro()' and undefined by 'undefine_macro()' the last call
takes precedence (including multiple redefinitions or
undefinitions). If the macro is redefined/undefined on a
per-compilation basis (ie. in the call to 'compile()'), then that
takes precedence.
"""
# Delete from the list of macro definitions/undefinitions if
# already there (so that this one will take precedence).
i = self._find_macro(name)
if i is not None:
del self.macros[i]
undefn = (name,)
self.macros.append(undefn)
def add_include_dir(self, dir):
"""Add 'dir' to the list of directories that will be searched for
header files. The compiler is instructed to search directories in
the order in which they are supplied by successive calls to
'add_include_dir()'.
"""
self.include_dirs.append(dir)
def set_include_dirs(self, dirs):
"""Set the list of directories that will be searched to 'dirs' (a
list of strings). Overrides any preceding calls to
'add_include_dir()'; subsequence calls to 'add_include_dir()' add
to the list passed to 'set_include_dirs()'. This does not affect
any list of standard include directories that the compiler may
search by default.
"""
self.include_dirs = dirs[:]
def add_library(self, libname):
"""Add 'libname' to the list of libraries that will be included in
all links driven by this compiler object. Note that 'libname'
should *not* be the name of a file containing a library, but the
name of the library itself: the actual filename will be inferred by
the linker, the compiler, or the compiler class (depending on the
platform).
The linker will be instructed to link against libraries in the
order they were supplied to 'add_library()' and/or
'set_libraries()'. It is perfectly valid to duplicate library
names; the linker will be instructed to link against libraries as
many times as they are mentioned.
"""
self.libraries.append(libname)
def set_libraries(self, libnames):
"""Set the list of libraries to be included in all links driven by
this compiler object to 'libnames' (a list of strings). This does
not affect any standard system libraries that the linker may
include by default.
"""
self.libraries = libnames[:]
def add_library_dir(self, dir):
"""Add 'dir' to the list of directories that will be searched for
libraries specified to 'add_library()' and 'set_libraries()'. The
linker will be instructed to search for libraries in the order they
are supplied to 'add_library_dir()' and/or 'set_library_dirs()'.
"""
self.library_dirs.append(dir)
def set_library_dirs(self, dirs):
"""Set the list of library search directories to 'dirs' (a list of
strings). This does not affect any standard library search path
that the linker may search by default.
"""
self.library_dirs = dirs[:]
def add_runtime_library_dir(self, dir):
"""Add 'dir' to the list of directories that will be searched for
shared libraries at runtime.
"""
self.runtime_library_dirs.append(dir)
def set_runtime_library_dirs(self, dirs):
"""Set the list of directories to search for shared libraries at
runtime to 'dirs' (a list of strings). This does not affect any
standard search path that the runtime linker may search by
default.
"""
self.runtime_library_dirs = dirs[:]
def add_link_object(self, object):
"""Add 'object' to the list of object files (or analogues, such as
explicitly named library files or the output of "resource
compilers") to be included in every link driven by this compiler
object.
"""
self.objects.append(object)
def set_link_objects(self, objects):
"""Set the list of object files (or analogues) to be included in
every link to 'objects'. This does not affect any standard object
files that the linker may include by default (such as system
libraries).
"""
self.objects = objects[:]
# -- Private utility methods --------------------------------------
# (here for the convenience of subclasses)
# Helper method to prep compiler in subclass compile() methods
def _setup_compile(self, outdir, macros, incdirs, sources, depends,
extra):
"""Process arguments and decide which source files to compile."""
if outdir is None:
outdir = self.output_dir
elif not isinstance(outdir, str):
raise TypeError("'output_dir' must be a string or None")
if macros is None:
macros = self.macros
elif isinstance(macros, list):
macros = macros + (self.macros or [])
else:
raise TypeError("'macros' (if supplied) must be a list of tuples")
if incdirs is None:
incdirs = self.include_dirs
elif isinstance(incdirs, (list, tuple)):
incdirs = list(incdirs) + (self.include_dirs or [])
else:
raise TypeError(
"'include_dirs' (if supplied) must be a list of strings")
if extra is None:
extra = []
# Get the list of expected output (object) files
objects = self.object_filenames(sources,
strip_dir=False,
output_dir=outdir)
assert len(objects) == len(sources)
pp_opts = gen_preprocess_options(macros, incdirs)
build = {}
for i in range(len(sources)):
src = sources[i]
obj = objects[i]
ext = os.path.splitext(src)[1]
self.mkpath(os.path.dirname(obj))
build[obj] = (src, ext)
return macros, objects, extra, pp_opts, build
def _get_cc_args(self, pp_opts, debug, before):
2011-06-01 10:20:44 -03:00
# works for unixccompiler and cygwinccompiler
cc_args = pp_opts + ['-c']
if debug:
cc_args[:0] = ['-g']
if before:
cc_args[:0] = before
return cc_args
def _fix_compile_args(self, output_dir, macros, include_dirs):
"""Typecheck and fix-up some of the arguments to the 'compile()'
method, and return fixed-up values. Specifically: if 'output_dir'
is None, replaces it with 'self.output_dir'; ensures that 'macros'
is a list, and augments it with 'self.macros'; ensures that
'include_dirs' is a list, and augments it with 'self.include_dirs'.
Guarantees that the returned values are of the correct type,
i.e. for 'output_dir' either string or None, and for 'macros' and
'include_dirs' either list or None.
"""
if output_dir is None:
output_dir = self.output_dir
elif not isinstance(output_dir, str):
raise TypeError("'output_dir' must be a string or None")
if macros is None:
macros = self.macros
elif isinstance(macros, list):
macros = macros + (self.macros or [])
else:
raise TypeError("'macros' (if supplied) must be a list of tuples")
if include_dirs is None:
include_dirs = self.include_dirs
elif isinstance(include_dirs, (list, tuple)):
include_dirs = list(include_dirs) + (self.include_dirs or [])
else:
raise TypeError(
"'include_dirs' (if supplied) must be a list of strings")
return output_dir, macros, include_dirs
def _fix_object_args(self, objects, output_dir):
"""Typecheck and fix up some arguments supplied to various methods.
Specifically: ensure that 'objects' is a list; if output_dir is
None, replace with self.output_dir. Return fixed versions of
'objects' and 'output_dir'.
"""
if not isinstance(objects, (list, tuple)):
raise TypeError("'objects' must be a list or tuple of strings")
objects = list(objects)
if output_dir is None:
output_dir = self.output_dir
elif not isinstance(output_dir, str):
raise TypeError("'output_dir' must be a string or None")
return objects, output_dir
def _fix_lib_args(self, libraries, library_dirs, runtime_library_dirs):
"""Typecheck and fix up some of the arguments supplied to the
'link_*' methods. Specifically: ensure that all arguments are
lists, and augment them with their permanent versions
(eg. 'self.libraries' augments 'libraries'). Return a tuple with
fixed versions of all arguments.
"""
if libraries is None:
libraries = self.libraries
elif isinstance(libraries, (list, tuple)):
libraries = list(libraries) + (self.libraries or [])
else:
raise TypeError(
"'libraries' (if supplied) must be a list of strings")
if library_dirs is None:
library_dirs = self.library_dirs
elif isinstance(library_dirs, (list, tuple)):
library_dirs = list(library_dirs) + (self.library_dirs or [])
else:
raise TypeError(
"'library_dirs' (if supplied) must be a list of strings")
if runtime_library_dirs is None:
runtime_library_dirs = self.runtime_library_dirs
elif isinstance(runtime_library_dirs, (list, tuple)):
runtime_library_dirs = (list(runtime_library_dirs) +
(self.runtime_library_dirs or []))
else:
raise TypeError("'runtime_library_dirs' (if supplied) "
"must be a list of strings")
return libraries, library_dirs, runtime_library_dirs
def _need_link(self, objects, output_file):
"""Return true if we need to relink the files listed in 'objects'
to recreate 'output_file'.
"""
if self.force:
return True
else:
if self.dry_run:
newer = newer_group(objects, output_file, missing='newer')
else:
newer = newer_group(objects, output_file)
return newer
def detect_language(self, sources):
"""Detect the language of a given file, or list of files. Uses
language_map, and language_order to do the job.
"""
if not isinstance(sources, list):
sources = [sources]
lang = None
index = len(self.language_order)
for source in sources:
base, ext = os.path.splitext(source)
extlang = self.language_map.get(ext)
try:
extindex = self.language_order.index(extlang)
if extindex < index:
lang = extlang
index = extindex
except ValueError:
pass
return lang
# -- Worker methods ------------------------------------------------
# (must be implemented by subclasses)
def preprocess(self, source, output_file=None, macros=None,
include_dirs=None, extra_preargs=None, extra_postargs=None):
"""Preprocess a single C/C++ source file, named in 'source'.
Output will be written to file named 'output_file', or stdout if
'output_file' not supplied. 'macros' is a list of macro
definitions as for 'compile()', which will augment the macros set
with 'define_macro()' and 'undefine_macro()'. 'include_dirs' is a
list of directory names that will be added to the default list.
Raises PreprocessError on failure.
"""
pass
def compile(self, sources, output_dir=None, macros=None,
include_dirs=None, debug=False, extra_preargs=None,
extra_postargs=None, depends=None):
"""Compile one or more source files.
'sources' must be a list of filenames, most likely C/C++
files, but in reality anything that can be handled by a
particular compiler and compiler class (eg. MSVCCompiler can
handle resource files in 'sources'). Return a list of object
filenames, one per source filename in 'sources'. Depending on
the implementation, not all source files will necessarily be
compiled, but all corresponding object filenames will be
returned.
If 'output_dir' is given, object files will be put under it, while
retaining their original path component. That is, "foo/bar.c"
normally compiles to "foo/bar.o" (for a Unix implementation); if
'output_dir' is "build", then it would compile to
"build/foo/bar.o".
'macros', if given, must be a list of macro definitions. A macro
definition is either a (name, value) 2-tuple or a (name,) 1-tuple.
The former defines a macro; if the value is None, the macro is
defined without an explicit value. The 1-tuple case undefines a
macro. Later definitions/redefinitions/ undefinitions take
precedence.
'include_dirs', if given, must be a list of strings, the
directories to add to the default include file search path for this
compilation only.
'debug' is a boolean; if true, the compiler will be instructed to
output debug symbols in (or alongside) the object file(s).
'extra_preargs' and 'extra_postargs' are implementation- dependent.
On platforms that have the notion of a command line (e.g. Unix,
DOS/Windows), they are most likely lists of strings: extra
command-line arguments to prepand/append to the compiler command
line. On other platforms, consult the implementation class
documentation. In any event, they are intended as an escape hatch
for those occasions when the abstract compiler framework doesn't
cut the mustard.
'depends', if given, is a list of filenames that all targets
depend on. If a source file is older than any file in
depends, then the source file will be recompiled. This
supports dependency tracking, but only at a coarse
granularity.
Raises CompileError on failure.
"""
# A concrete compiler class can either override this method
# entirely or implement _compile().
macros, objects, extra_postargs, pp_opts, build = \
self._setup_compile(output_dir, macros, include_dirs, sources,
depends, extra_postargs)
cc_args = self._get_cc_args(pp_opts, debug, extra_preargs)
for obj in objects:
try:
src, ext = build[obj]
except KeyError:
continue
self._compile(obj, src, ext, cc_args, extra_postargs, pp_opts)
# Return *all* object filenames, not just the ones we just built.
return objects
def _compile(self, obj, src, ext, cc_args, extra_postargs, pp_opts):
"""Compile 'src' to product 'obj'."""
# A concrete compiler class that does not override compile()
# should implement _compile().
pass
def create_static_lib(self, objects, output_libname, output_dir=None,
debug=False, target_lang=None):
"""Link a bunch of stuff together to create a static library file.
The "bunch of stuff" consists of the list of object files supplied
as 'objects', the extra object files supplied to
'add_link_object()' and/or 'set_link_objects()', the libraries
supplied to 'add_library()' and/or 'set_libraries()', and the
libraries supplied as 'libraries' (if any).
'output_libname' should be a library name, not a filename; the
filename will be inferred from the library name. 'output_dir' is
the directory where the library file will be put.
'debug' is a boolean; if true, debugging information will be
included in the library (note that on most platforms, it is the
compile step where this matters: the 'debug' flag is included here
just for consistency).
'target_lang' is the target language for which the given objects
are being compiled. This allows specific linkage time treatment of
certain languages.
Raises LibError on failure.
"""
pass
# values for target_desc parameter in link()
SHARED_OBJECT = "shared_object"
SHARED_LIBRARY = "shared_library"
EXECUTABLE = "executable"
def link(self, target_desc, objects, output_filename, output_dir=None,
libraries=None, library_dirs=None, runtime_library_dirs=None,
export_symbols=None, debug=False, extra_preargs=None,
extra_postargs=None, build_temp=None, target_lang=None):
"""Link a bunch of stuff together to create an executable or
shared library file.
The "bunch of stuff" consists of the list of object files supplied
as 'objects'. 'output_filename' should be a filename. If
'output_dir' is supplied, 'output_filename' is relative to it
(i.e. 'output_filename' can provide directory components if
needed).
'libraries' is a list of libraries to link against. These are
library names, not filenames, since they're translated into
filenames in a platform-specific way (eg. "foo" becomes "libfoo.a"
on Unix and "foo.lib" on DOS/Windows). However, they can include a
directory component, which means the linker will look in that
specific directory rather than searching all the normal locations.
'library_dirs', if supplied, should be a list of directories to
search for libraries that were specified as bare library names
(ie. no directory component). These are on top of the system
default and those supplied to 'add_library_dir()' and/or
'set_library_dirs()'. 'runtime_library_dirs' is a list of
directories that will be embedded into the shared library and used
to search for other shared libraries that *it* depends on at
run-time. (This may only be relevant on Unix.)
'export_symbols' is a list of symbols that the shared library will
export. (This appears to be relevant only on Windows.)
'debug' is as for 'compile()' and 'create_static_lib()', with the
slight distinction that it actually matters on most platforms (as
opposed to 'create_static_lib()', which includes a 'debug' flag
mostly for form's sake).
'extra_preargs' and 'extra_postargs' are as for 'compile()' (except
of course that they supply command-line arguments for the
particular linker being used).
'target_lang' is the target language for which the given objects
are being compiled. This allows specific linkage time treatment of
certain languages.
Raises LinkError on failure.
"""
raise NotImplementedError
# Old 'link_*()' methods, rewritten to use the new 'link()' method.
def link_shared_lib(self, objects, output_libname, output_dir=None,
libraries=None, library_dirs=None,
runtime_library_dirs=None, export_symbols=None,
debug=False, extra_preargs=None, extra_postargs=None,
build_temp=None, target_lang=None):
self.link(CCompiler.SHARED_LIBRARY, objects,
self.library_filename(output_libname, lib_type='shared'),
output_dir,
libraries, library_dirs, runtime_library_dirs,
export_symbols, debug,
extra_preargs, extra_postargs, build_temp, target_lang)
def link_shared_object(self, objects, output_filename, output_dir=None,
libraries=None, library_dirs=None,
runtime_library_dirs=None, export_symbols=None,
debug=False, extra_preargs=None, extra_postargs=None,
build_temp=None, target_lang=None):
self.link(CCompiler.SHARED_OBJECT, objects,
output_filename, output_dir,
libraries, library_dirs, runtime_library_dirs,
export_symbols, debug,
extra_preargs, extra_postargs, build_temp, target_lang)
def link_executable(self, objects, output_progname, output_dir=None,
libraries=None, library_dirs=None,
runtime_library_dirs=None, debug=False,
extra_preargs=None, extra_postargs=None,
target_lang=None):
self.link(CCompiler.EXECUTABLE, objects,
self.executable_filename(output_progname), output_dir,
libraries, library_dirs, runtime_library_dirs, None,
debug, extra_preargs, extra_postargs, None, target_lang)
# -- Miscellaneous methods -----------------------------------------
# These are all used by the 'gen_lib_options() function; there is
# no appropriate default implementation so subclasses should
# implement all of these.
def library_dir_option(self, dir):
"""Return the compiler option to add 'dir' to the list of
directories searched for libraries.
"""
raise NotImplementedError
def runtime_library_dir_option(self, dir):
"""Return the compiler option to add 'dir' to the list of
directories searched for runtime libraries.
"""
raise NotImplementedError
def library_option(self, lib):
"""Return the compiler option to add 'dir' to the list of libraries
linked into the shared library or executable.
"""
raise NotImplementedError
def has_function(self, funcname, includes=None, include_dirs=None,
libraries=None, library_dirs=None):
"""Return a boolean indicating whether funcname is supported on
the current platform. The optional arguments can be used to
augment the compilation environment.
"""
# this can't be included at module scope because it tries to
# import math which might not be available at that point - maybe
# the necessary logic should just be inlined?
import tempfile
if includes is None:
includes = []
if include_dirs is None:
include_dirs = []
if libraries is None:
libraries = []
if library_dirs is None:
library_dirs = []
fd, fname = tempfile.mkstemp(".c", funcname, text=True)
with os.fdopen(fd, "w") as f:
for incl in includes:
f.write("""#include "%s"\n""" % incl)
f.write("""\
main (int argc, char **argv) {
%s();
}
""" % funcname)
try:
objects = self.compile([fname], include_dirs=include_dirs)
except CompileError:
return False
try:
self.link_executable(objects, "a.out",
libraries=libraries,
library_dirs=library_dirs)
except (LinkError, TypeError):
return False
return True
def find_library_file(self, dirs, lib, debug=False):
"""Search the specified list of directories for a static or shared
library file 'lib' and return the full path to that file. If
'debug' is true, look for a debugging version (if that makes sense on
the current platform). Return None if 'lib' wasn't found in any of
the specified directories.
"""
raise NotImplementedError
# -- Filename generation methods -----------------------------------
# The default implementation of the filename generating methods are
# prejudiced towards the Unix/DOS/Windows view of the world:
# * object files are named by replacing the source file extension
# (eg. .c/.cpp -> .o/.obj)
# * library files (shared or static) are named by plugging the
# library name and extension into a format string, eg.
# "lib%s.%s" % (lib_name, ".a") for Unix static libraries
# * executables are named by appending an extension (possibly
# empty) to the program name: eg. progname + ".exe" for
# Windows
#
# To reduce redundant code, these methods expect to find
# several attributes in the current object (presumably defined
# as class attributes):
# * src_extensions -
# list of C/C++ source file extensions, eg. ['.c', '.cpp']
# * obj_extension -
# object file extension, eg. '.o' or '.obj'
# * static_lib_extension -
# extension for static library files, eg. '.a' or '.lib'
# * shared_lib_extension -
# extension for shared library/object files, eg. '.so', '.dll'
# * static_lib_format -
# format string for generating static library filenames,
# eg. 'lib%s.%s' or '%s.%s'
# * shared_lib_format
# format string for generating shared library filenames
# (probably same as static_lib_format, since the extension
# is one of the intended parameters to the format string)
# * exe_extension -
# extension for executable files, eg. '' or '.exe'
def object_filenames(self, source_filenames, strip_dir=False, output_dir=''):
if output_dir is None:
output_dir = ''
obj_names = []
for src_name in source_filenames:
base, ext = os.path.splitext(src_name)
base = os.path.splitdrive(base)[1] # Chop off the drive
base = base[os.path.isabs(base):] # If abs, chop off leading /
if ext not in self.src_extensions:
raise UnknownFileError("unknown file type '%s' (from '%s')" %
(ext, src_name))
if strip_dir:
base = os.path.basename(base)
obj_names.append(os.path.join(output_dir,
base + self.obj_extension))
return obj_names
def shared_object_filename(self, basename, strip_dir=False, output_dir=''):
assert output_dir is not None
if strip_dir:
basename = os.path.basename(basename)
return os.path.join(output_dir, basename + self.shared_lib_extension)
def executable_filename(self, basename, strip_dir=False, output_dir=''):
assert output_dir is not None
if strip_dir:
basename = os.path.basename(basename)
return os.path.join(output_dir, basename + (self.exe_extension or ''))
def library_filename(self, libname, lib_type='static', # or 'shared'
strip_dir=False, output_dir=''):
assert output_dir is not None
if lib_type not in ("static", "shared", "dylib"):
raise ValueError(
"'lib_type' must be 'static', 'shared' or 'dylib'")
fmt = getattr(self, lib_type + "_lib_format")
ext = getattr(self, lib_type + "_lib_extension")
dir, base = os.path.split(libname)
filename = fmt % (base, ext)
if strip_dir:
dir = ''
return os.path.join(output_dir, dir, filename)
# -- Utility methods -----------------------------------------------
def execute(self, func, args, msg=None, level=1):
execute(func, args, msg, self.dry_run)
def spawn(self, cmd):
spawn(cmd, dry_run=self.dry_run)
def move_file(self, src, dst):
logger.info("moving %r to %r", src, dst)
if self.dry_run:
return
return move(src, dst)
def mkpath(self, name, mode=0o777):
name = os.path.normpath(name)
if os.path.isdir(name) or name == '':
return
if self.dry_run:
head = ''
for part in name.split(os.sep):
logger.info("created directory %s%s", head, part)
head += part + os.sep
return
os.makedirs(name, mode)