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gh-81057: Vendor a Subset of distutils for the c-analyzer Tool (gh-102505)

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distutils was removed in November. However, the c-analyzer relies on it. To solve that here, we vendor the parts the tool needs so it can be run against 3.12+. (Also see gh-92584.)

Note that we may end up removing this code later in favor of a solution in common with the peg_generator tool (which also relies on distutils).  At the least, the copy here makes sure the c-analyzer tool works on 3.12+ in the meantime.
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Tools/c-analyzer/distutils/README Normal file
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This is a partial copy of distutils as it was removed in 0faa0ba240e.
It only includes the parts needed by the C parser.

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Tools/c-analyzer/distutils/__init__.py Normal file
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Tools/c-analyzer/distutils/_msvccompiler.py Normal file
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"""distutils._msvccompiler
Contains MSVCCompiler, an implementation of the abstract CCompiler class
for Microsoft Visual Studio 2015.
The module is compatible with VS 2015 and later. You can find legacy support
for older versions in distutils.msvc9compiler and distutils.msvccompiler.
"""
# Written by Perry Stoll
# hacked by Robin Becker and Thomas Heller to do a better job of
# finding DevStudio (through the registry)
# ported to VS 2005 and VS 2008 by Christian Heimes
# ported to VS 2015 by Steve Dower
import os
import subprocess
import winreg
from distutils.errors import DistutilsPlatformError
from distutils.ccompiler import CCompiler
from distutils import log
from itertools import count
def _find_vc2015():
try:
key = winreg.OpenKeyEx(
winreg.HKEY_LOCAL_MACHINE,
r"Software\Microsoft\VisualStudio\SxS\VC7",
access=winreg.KEY_READ | winreg.KEY_WOW64_32KEY
)
except OSError:
log.debug("Visual C++ is not registered")
return None, None
best_version = 0
best_dir = None
with key:
for i in count():
try:
v, vc_dir, vt = winreg.EnumValue(key, i)
except OSError:
break
if v and vt == winreg.REG_SZ and os.path.isdir(vc_dir):
try:
version = int(float(v))
except (ValueError, TypeError):
continue
if version >= 14 and version > best_version:
best_version, best_dir = version, vc_dir
return best_version, best_dir
def _find_vc2017():
"""Returns "15, path" based on the result of invoking vswhere.exe
If no install is found, returns "None, None"
The version is returned to avoid unnecessarily changing the function
result. It may be ignored when the path is not None.
If vswhere.exe is not available, by definition, VS 2017 is not
installed.
"""
root = os.environ.get("ProgramFiles(x86)") or os.environ.get("ProgramFiles")
if not root:
return None, None
try:
path = subprocess.check_output([
os.path.join(root, "Microsoft Visual Studio", "Installer", "vswhere.exe"),
"-latest",
"-prerelease",
"-requires", "Microsoft.VisualStudio.Component.VC.Tools.x86.x64",
"-property", "installationPath",
"-products", "*",
], encoding="mbcs", errors="strict").strip()
except (subprocess.CalledProcessError, OSError, UnicodeDecodeError):
return None, None
path = os.path.join(path, "VC", "Auxiliary", "Build")
if os.path.isdir(path):
return 15, path
return None, None
PLAT_SPEC_TO_RUNTIME = {
'x86' : 'x86',
'x86_amd64' : 'x64',
'x86_arm' : 'arm',
'x86_arm64' : 'arm64'
}
def _find_vcvarsall(plat_spec):
# bpo-38597: Removed vcruntime return value
_, best_dir = _find_vc2017()
if not best_dir:
best_version, best_dir = _find_vc2015()
if not best_dir:
log.debug("No suitable Visual C++ version found")
return None, None
vcvarsall = os.path.join(best_dir, "vcvarsall.bat")
if not os.path.isfile(vcvarsall):
log.debug("%s cannot be found", vcvarsall)
return None, None
return vcvarsall, None
def _get_vc_env(plat_spec):
if os.getenv("DISTUTILS_USE_SDK"):
return {
key.lower(): value
for key, value in os.environ.items()
}
vcvarsall, _ = _find_vcvarsall(plat_spec)
if not vcvarsall:
raise DistutilsPlatformError("Unable to find vcvarsall.bat")
try:
out = subprocess.check_output(
'cmd /u /c "{}" {} && set'.format(vcvarsall, plat_spec),
stderr=subprocess.STDOUT,
).decode('utf-16le', errors='replace')
except subprocess.CalledProcessError as exc:
log.error(exc.output)
raise DistutilsPlatformError("Error executing {}"
.format(exc.cmd))
env = {
key.lower(): value
for key, _, value in
(line.partition('=') for line in out.splitlines())
if key and value
}
return env
def _find_exe(exe, paths=None):
"""Return path to an MSVC executable program.
Tries to find the program in several places: first, one of the
MSVC program search paths from the registry; next, the directories
in the PATH environment variable. If any of those work, return an
absolute path that is known to exist. If none of them work, just
return the original program name, 'exe'.
"""
if not paths:
paths = os.getenv('path').split(os.pathsep)
for p in paths:
fn = os.path.join(os.path.abspath(p), exe)
if os.path.isfile(fn):
return fn
return exe
# A map keyed by get_platform() return values to values accepted by
# 'vcvarsall.bat'. Always cross-compile from x86 to work with the
# lighter-weight MSVC installs that do not include native 64-bit tools.
PLAT_TO_VCVARS = {
'win32' : 'x86',
'win-amd64' : 'x86_amd64',
'win-arm32' : 'x86_arm',
'win-arm64' : 'x86_arm64'
}
class MSVCCompiler(CCompiler) :
"""Concrete class that implements an interface to Microsoft Visual C++,
as defined by the CCompiler abstract class."""
compiler_type = 'msvc'
# Just set this so CCompiler's constructor doesn't barf. We currently
# don't use the 'set_executables()' bureaucracy provided by CCompiler,
# as it really isn't necessary for this sort of single-compiler class.
# Would be nice to have a consistent interface with UnixCCompiler,
# though, so it's worth thinking about.
executables = {}
# Private class data (need to distinguish C from C++ source for compiler)
_c_extensions = ['.c']
_cpp_extensions = ['.cc', '.cpp', '.cxx']
_rc_extensions = ['.rc']
_mc_extensions = ['.mc']
# Needed for the filename generation methods provided by the
# base class, CCompiler.
src_extensions = (_c_extensions + _cpp_extensions +
_rc_extensions + _mc_extensions)
res_extension = '.res'
obj_extension = '.obj'
static_lib_extension = '.lib'
shared_lib_extension = '.dll'
static_lib_format = shared_lib_format = '%s%s'
exe_extension = '.exe'
def __init__(self, verbose=0, dry_run=0, force=0):
CCompiler.__init__ (self, verbose, dry_run, force)
# target platform (.plat_name is consistent with 'bdist')
self.plat_name = None
self.initialized = False

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Tools/c-analyzer/distutils/bcppcompiler.py Normal file
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"""distutils.bcppcompiler
Contains BorlandCCompiler, an implementation of the abstract CCompiler class
for the Borland C++ compiler.
"""
# This implementation by Lyle Johnson, based on the original msvccompiler.py
# module and using the directions originally published by Gordon Williams.
# XXX looks like there's a LOT of overlap between these two classes:
# someone should sit down and factor out the common code as
# WindowsCCompiler! --GPW
import os
from distutils.errors import DistutilsExecError, CompileError
from distutils.ccompiler import \
CCompiler, gen_preprocess_options
from distutils.dep_util import newer
class BCPPCompiler(CCompiler) :
"""Concrete class that implements an interface to the Borland C/C++
compiler, as defined by the CCompiler abstract class.
"""
compiler_type = 'bcpp'
# Just set this so CCompiler's constructor doesn't barf. We currently
# don't use the 'set_executables()' bureaucracy provided by CCompiler,
# as it really isn't necessary for this sort of single-compiler class.
# Would be nice to have a consistent interface with UnixCCompiler,
# though, so it's worth thinking about.
executables = {}
# Private class data (need to distinguish C from C++ source for compiler)
_c_extensions = ['.c']
_cpp_extensions = ['.cc', '.cpp', '.cxx']
# Needed for the filename generation methods provided by the
# base class, CCompiler.
src_extensions = _c_extensions + _cpp_extensions
obj_extension = '.obj'
static_lib_extension = '.lib'
shared_lib_extension = '.dll'
static_lib_format = shared_lib_format = '%s%s'
exe_extension = '.exe'
def __init__ (self,
verbose=0,
dry_run=0,
force=0):
CCompiler.__init__ (self, verbose, dry_run, force)
# These executables are assumed to all be in the path.
# Borland doesn't seem to use any special registry settings to
# indicate their installation locations.
self.cc = "bcc32.exe"
self.linker = "ilink32.exe"
self.lib = "tlib.exe"
self.preprocess_options = None
self.compile_options = ['/tWM', '/O2', '/q', '/g0']
self.compile_options_debug = ['/tWM', '/Od', '/q', '/g0']
self.ldflags_shared = ['/Tpd', '/Gn', '/q', '/x']
self.ldflags_shared_debug = ['/Tpd', '/Gn', '/q', '/x']
self.ldflags_static = []
self.ldflags_exe = ['/Gn', '/q', '/x']
self.ldflags_exe_debug = ['/Gn', '/q', '/x','/r']
# -- Worker methods ------------------------------------------------
def preprocess (self,
source,
output_file=None,
macros=None,
include_dirs=None,
extra_preargs=None,
extra_postargs=None):
(_, macros, include_dirs) = \
self._fix_compile_args(None, macros, include_dirs)
pp_opts = gen_preprocess_options(macros, include_dirs)
pp_args = ['cpp32.exe'] + pp_opts
if output_file is not None:
pp_args.append('-o' + output_file)
if extra_preargs:
pp_args[:0] = extra_preargs
if extra_postargs:
pp_args.extend(extra_postargs)
pp_args.append(source)
# We need to preprocess: either we're being forced to, or the
# source file is newer than the target (or the target doesn't
# exist).
if self.force or output_file is None or newer(source, output_file):
if output_file:
self.mkpath(os.path.dirname(output_file))
try:
self.spawn(pp_args)
except DistutilsExecError as msg:
print(msg)
raise CompileError(msg)
# preprocess()

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"""distutils.ccompiler
Contains CCompiler, an abstract base class that defines the interface
for the Distutils compiler abstraction model."""
import sys, os, re
from distutils.errors import (
DistutilsModuleError, DistutilsPlatformError,
)
from distutils.util import split_quoted
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.
"""
# 'compiler_type' 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'. In concrete CCompiler subclasses, 'compiler_type'
# should really, really be one of the keys of the 'compiler_class'
# dictionary (see below -- used by the 'new_compiler()' factory
# function) -- authors of new compiler interface classes are
# responsible for updating 'compiler_class'!
compiler_type = 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=0, force=0):
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 in self.executables.keys():
self.set_executable(key, self.executables[key])
def set_executables(self, **kwargs):
"""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 in kwargs:
if key not in self.executables:
raise ValueError("unknown executable '%s' for class %s" %
(key, self.__class__.__name__))
self.set_executable(key, kwargs[key])
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 += 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) in (1, 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]
self.macros.append((name, value))
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[:]
# -- Private utility methods --------------------------------------
# (here for the convenience of subclasses)
# Helper method to prep compiler in subclass compile() methods
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
# -- 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
# -- 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 'lib' to the list of libraries
# linked into the shared library or executable.
# """
# raise NotImplementedError
#
# def find_library_file (self, dirs, lib, debug=0):
# """Search the specified list of directories for a static or shared
# library file 'lib' and return the full path to that file. If
# 'debug' 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
# -- Utility methods -----------------------------------------------
def spawn(self, cmd):
raise NotImplementedError
# Map a sys.platform/os.name ('posix', 'nt') to the default compiler
# type for that platform. Keys are interpreted as re match
# patterns. Order is important; platform mappings are preferred over
# OS names.
_default_compilers = (
# Platform string mappings
# on a cygwin built python we can use gcc like an ordinary UNIXish
# compiler
('cygwin.*', 'unix'),
# OS name mappings
('posix', 'unix'),
('nt', 'msvc'),
)
def get_default_compiler(osname=None, platform=None):
"""Determine the default compiler to use for the given platform.
osname should be one of the standard Python OS names (i.e. the
ones returned by os.name) and platform the common value
returned by sys.platform for the platform in question.
The default values are os.name and sys.platform in case the
parameters are not given.
"""
if osname is None:
osname = os.name
if platform is None:
platform = sys.platform
for pattern, compiler in _default_compilers:
if re.match(pattern, platform) is not None or \
re.match(pattern, osname) is not None:
return compiler
# Default to Unix compiler
return 'unix'
# Map compiler types to (module_name, class_name) pairs -- ie. where to
# find the code that implements an interface to this compiler. (The module
# is assumed to be in the 'distutils' package.)
compiler_class = { 'unix': ('unixccompiler', 'UnixCCompiler',
"standard UNIX-style compiler"),
'msvc': ('_msvccompiler', 'MSVCCompiler',
"Microsoft Visual C++"),
'cygwin': ('cygwinccompiler', 'CygwinCCompiler',
"Cygwin port of GNU C Compiler for Win32"),
'mingw32': ('cygwinccompiler', 'Mingw32CCompiler',
"Mingw32 port of GNU C Compiler for Win32"),
'bcpp': ('bcppcompiler', 'BCPPCompiler',
"Borland C++ Compiler"),
}
def new_compiler(plat=None, compiler=None, verbose=0, dry_run=0, force=0):
"""Generate an instance of some CCompiler subclass for the supplied
platform/compiler combination. 'plat' defaults to 'os.name'
(eg. 'posix', 'nt'), and 'compiler' defaults to the default compiler
for that platform. Currently only 'posix' and 'nt' are supported, and
the default compilers are "traditional Unix interface" (UnixCCompiler
class) and Visual C++ (MSVCCompiler class). Note that it's perfectly
possible to ask for a Unix compiler object under Windows, and a
Microsoft compiler object under Unix -- if you supply a value for
'compiler', 'plat' is ignored.
"""
if plat is None:
plat = os.name
try:
if compiler is None:
compiler = get_default_compiler(plat)
(module_name, class_name, long_description) = compiler_class[compiler]
except KeyError:
msg = "don't know how to compile C/C++ code on platform '%s'" % plat
if compiler is not None:
msg = msg + " with '%s' compiler" % compiler
raise DistutilsPlatformError(msg)
try:
module_name = "distutils." + module_name
__import__ (module_name)
module = sys.modules[module_name]
klass = vars(module)[class_name]
except ImportError:
raise
raise DistutilsModuleError(
"can't compile C/C++ code: unable to load module '%s'" % \
module_name)
except KeyError:
raise DistutilsModuleError(
"can't compile C/C++ code: unable to find class '%s' "
"in module '%s'" % (class_name, module_name))
# XXX The None is necessary to preserve backwards compatibility
# with classes that expect verbose to be the first positional
# argument.
return klass(None, dry_run, force)
def gen_preprocess_options(macros, include_dirs):
"""Generate C pre-processor options (-D, -U, -I) as used by at least
two types of compilers: the typical Unix compiler and Visual C++.
'macros' is the usual thing, a list of 1- or 2-tuples, where (name,)
means undefine (-U) macro 'name', and (name,value) means define (-D)
macro 'name' to 'value'. 'include_dirs' is just a list of directory
names to be added to the header file search path (-I). Returns a list
of command-line options suitable for either Unix compilers or Visual
C++.
"""
# XXX it would be nice (mainly aesthetic, and so we don't generate
# stupid-looking command lines) to go over 'macros' and eliminate
# redundant definitions/undefinitions (ie. ensure that only the
# latest mention of a particular macro winds up on the command
# line). I don't think it's essential, though, since most (all?)
# Unix C compilers only pay attention to the latest -D or -U
# mention of a macro on their command line. Similar situation for
# 'include_dirs'. I'm punting on both for now. Anyways, weeding out
# redundancies like this should probably be the province of
# CCompiler, since the data structures used are inherited from it
# and therefore common to all CCompiler classes.
pp_opts = []
for macro in macros:
if not (isinstance(macro, tuple) and 1 <= len(macro) <= 2):
raise TypeError(
"bad macro definition '%s': "
"each element of 'macros' list must be a 1- or 2-tuple"
% macro)
if len(macro) == 1: # undefine this macro
pp_opts.append("-U%s" % macro[0])
elif len(macro) == 2:
if macro[1] is None: # define with no explicit value
pp_opts.append("-D%s" % macro[0])
else:
# XXX *don't* need to be clever about quoting the
# macro value here, because we're going to avoid the
# shell at all costs when we spawn the command!
pp_opts.append("-D%s=%s" % macro)
for dir in include_dirs:
pp_opts.append("-I%s" % dir)
return pp_opts

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"""distutils.cygwinccompiler
Provides the CygwinCCompiler class, a subclass of UnixCCompiler that
handles the Cygwin port of the GNU C compiler to Windows. It also contains
the Mingw32CCompiler class which handles the mingw32 port of GCC (same as
cygwin in no-cygwin mode).
"""
# problems:
#
# * if you use a msvc compiled python version (1.5.2)
# 1. you have to insert a __GNUC__ section in its config.h
# 2. you have to generate an import library for its dll
# - create a def-file for python??.dll
# - create an import library using
# dlltool --dllname python15.dll --def python15.def \
# --output-lib libpython15.a
#
# see also http://starship.python.net/crew/kernr/mingw32/Notes.html
#
# * We put export_symbols in a def-file, and don't use
# --export-all-symbols because it doesn't worked reliable in some
# tested configurations. And because other windows compilers also
# need their symbols specified this no serious problem.
#
# tested configurations:
#
# * cygwin gcc 2.91.57/ld 2.9.4/dllwrap 0.2.4 works
# (after patching python's config.h and for C++ some other include files)
# see also http://starship.python.net/crew/kernr/mingw32/Notes.html
# * mingw32 gcc 2.95.2/ld 2.9.4/dllwrap 0.2.4 works
# (ld doesn't support -shared, so we use dllwrap)
# * cygwin gcc 2.95.2/ld 2.10.90/dllwrap 2.10.90 works now
# - its dllwrap doesn't work, there is a bug in binutils 2.10.90
# see also http://sources.redhat.com/ml/cygwin/2000-06/msg01274.html
# - using gcc -mdll instead dllwrap doesn't work without -static because
# it tries to link against dlls instead their import libraries. (If
# it finds the dll first.)
# By specifying -static we force ld to link against the import libraries,
# this is windows standard and there are normally not the necessary symbols
# in the dlls.
# *** only the version of June 2000 shows these problems
# * cygwin gcc 3.2/ld 2.13.90 works
# (ld supports -shared)
# * mingw gcc 3.2/ld 2.13 works
# (ld supports -shared)
import os
import sys
from subprocess import Popen, PIPE, check_output
import re
from distutils.unixccompiler import UnixCCompiler
from distutils.errors import CCompilerError
from distutils.version import LooseVersion
from distutils.spawn import find_executable
def get_msvcr():
"""Include the appropriate MSVC runtime library if Python was built
with MSVC 7.0 or later.
"""
msc_pos = sys.version.find('MSC v.')
if msc_pos != -1:
msc_ver = sys.version[msc_pos+6:msc_pos+10]
if msc_ver == '1300':
# MSVC 7.0
return ['msvcr70']
elif msc_ver == '1310':
# MSVC 7.1
return ['msvcr71']
elif msc_ver == '1400':
# VS2005 / MSVC 8.0
return ['msvcr80']
elif msc_ver == '1500':
# VS2008 / MSVC 9.0
return ['msvcr90']
elif msc_ver == '1600':
# VS2010 / MSVC 10.0
return ['msvcr100']
else:
raise ValueError("Unknown MS Compiler version %s " % msc_ver)
class CygwinCCompiler(UnixCCompiler):
""" Handles the Cygwin port of the GNU C compiler to Windows.
"""
compiler_type = 'cygwin'
obj_extension = ".o"
static_lib_extension = ".a"
shared_lib_extension = ".dll"
static_lib_format = "lib%s%s"
shared_lib_format = "%s%s"
exe_extension = ".exe"
def __init__(self, verbose=0, dry_run=0, force=0):
UnixCCompiler.__init__(self, verbose, dry_run, force)
status, details = check_config_h()
self.debug_print("Python's GCC status: %s (details: %s)" %
(status, details))
if status is not CONFIG_H_OK:
self.warn(
"Python's pyconfig.h doesn't seem to support your compiler. "
"Reason: %s. "
"Compiling may fail because of undefined preprocessor macros."
% details)
self.gcc_version, self.ld_version, self.dllwrap_version = \
get_versions()
self.debug_print(self.compiler_type + ": gcc %s, ld %s, dllwrap %s\n" %
(self.gcc_version,
self.ld_version,
self.dllwrap_version) )
# ld_version >= "2.10.90" and < "2.13" should also be able to use
# gcc -mdll instead of dllwrap
# Older dllwraps had own version numbers, newer ones use the
# same as the rest of binutils ( also ld )
# dllwrap 2.10.90 is buggy
if self.ld_version >= "2.10.90":
self.linker_dll = "gcc"
else:
self.linker_dll = "dllwrap"
# ld_version >= "2.13" support -shared so use it instead of
# -mdll -static
if self.ld_version >= "2.13":
shared_option = "-shared"
else:
shared_option = "-mdll -static"
# Hard-code GCC because that's what this is all about.
# XXX optimization, warnings etc. should be customizable.
self.set_executables(compiler='gcc -mcygwin -O -Wall',
compiler_so='gcc -mcygwin -mdll -O -Wall',
compiler_cxx='g++ -mcygwin -O -Wall',
linker_exe='gcc -mcygwin',
linker_so=('%s -mcygwin %s' %
(self.linker_dll, shared_option)))
# cygwin and mingw32 need different sets of libraries
if self.gcc_version == "2.91.57":
# cygwin shouldn't need msvcrt, but without the dlls will crash
# (gcc version 2.91.57) -- perhaps something about initialization
self.dll_libraries=["msvcrt"]
self.warn(
"Consider upgrading to a newer version of gcc")
else:
# Include the appropriate MSVC runtime library if Python was built
# with MSVC 7.0 or later.
self.dll_libraries = get_msvcr()
# the same as cygwin plus some additional parameters
class Mingw32CCompiler(CygwinCCompiler):
""" Handles the Mingw32 port of the GNU C compiler to Windows.
"""
compiler_type = 'mingw32'
def __init__(self, verbose=0, dry_run=0, force=0):
CygwinCCompiler.__init__ (self, verbose, dry_run, force)
# ld_version >= "2.13" support -shared so use it instead of
# -mdll -static
if self.ld_version >= "2.13":
shared_option = "-shared"
else:
shared_option = "-mdll -static"
# A real mingw32 doesn't need to specify a different entry point,
# but cygwin 2.91.57 in no-cygwin-mode needs it.
if self.gcc_version <= "2.91.57":
entry_point = '--entry _DllMain@12'
else:
entry_point = ''
if is_cygwingcc():
raise CCompilerError(
'Cygwin gcc cannot be used with --compiler=mingw32')
self.set_executables(compiler='gcc -O -Wall',
compiler_so='gcc -mdll -O -Wall',
compiler_cxx='g++ -O -Wall',
linker_exe='gcc',
linker_so='%s %s %s'
% (self.linker_dll, shared_option,
entry_point))
# Maybe we should also append -mthreads, but then the finished
# dlls need another dll (mingwm10.dll see Mingw32 docs)
# (-mthreads: Support thread-safe exception handling on `Mingw32')
# no additional libraries needed
self.dll_libraries=[]
# Include the appropriate MSVC runtime library if Python was built
# with MSVC 7.0 or later.
self.dll_libraries = get_msvcr()
# Because these compilers aren't configured in Python's pyconfig.h file by
# default, we should at least warn the user if he is using an unmodified
# version.
CONFIG_H_OK = "ok"
CONFIG_H_NOTOK = "not ok"
CONFIG_H_UNCERTAIN = "uncertain"
def check_config_h():
"""Check if the current Python installation appears amenable to building
extensions with GCC.
Returns a tuple (status, details), where 'status' is one of the following
constants:
- CONFIG_H_OK: all is well, go ahead and compile
- CONFIG_H_NOTOK: doesn't look good
- CONFIG_H_UNCERTAIN: not sure -- unable to read pyconfig.h
'details' is a human-readable string explaining the situation.
Note there are two ways to conclude "OK": either 'sys.version' contains
the string "GCC" (implying that this Python was built with GCC), or the
installed "pyconfig.h" contains the string "__GNUC__".
"""
# XXX since this function also checks sys.version, it's not strictly a
# "pyconfig.h" check -- should probably be renamed...
import sysconfig
# if sys.version contains GCC then python was compiled with GCC, and the
# pyconfig.h file should be OK
if "GCC" in sys.version:
return CONFIG_H_OK, "sys.version mentions 'GCC'"
# let's see if __GNUC__ is mentioned in python.h
fn = sysconfig.get_config_h_filename()
try:
config_h = open(fn)
try:
if "__GNUC__" in config_h.read():
return CONFIG_H_OK, "'%s' mentions '__GNUC__'" % fn
else:
return CONFIG_H_NOTOK, "'%s' does not mention '__GNUC__'" % fn
finally:
config_h.close()
except OSError as exc:
return (CONFIG_H_UNCERTAIN,
"couldn't read '%s': %s" % (fn, exc.strerror))
RE_VERSION = re.compile(br'(\d+\.\d+(\.\d+)*)')
def _find_exe_version(cmd):
"""Find the version of an executable by running `cmd` in the shell.
If the command is not found, or the output does not match
`RE_VERSION`, returns None.
"""
executable = cmd.split()[0]
if find_executable(executable) is None:
return None
out = Popen(cmd, shell=True, stdout=PIPE).stdout
try:
out_string = out.read()
finally:
out.close()
result = RE_VERSION.search(out_string)
if result is None:
return None
# LooseVersion works with strings
# so we need to decode our bytes
return LooseVersion(result.group(1).decode())
def get_versions():
""" Try to find out the versions of gcc, ld and dllwrap.
If not possible it returns None for it.
"""
commands = ['gcc -dumpversion', 'ld -v', 'dllwrap --version']
return tuple([_find_exe_version(cmd) for cmd in commands])
def is_cygwingcc():
'''Try to determine if the gcc that would be used is from cygwin.'''
out_string = check_output(['gcc', '-dumpmachine'])
return out_string.strip().endswith(b'cygwin')

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import os
# If DISTUTILS_DEBUG is anything other than the empty string, we run in
# debug mode.
DEBUG = os.environ.get('DISTUTILS_DEBUG')

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"""distutils.dep_util
Utility functions for simple, timestamp-based dependency of files
and groups of files; also, function based entirely on such
timestamp dependency analysis."""
import os
from distutils.errors import DistutilsFileError
def newer (source, target):
"""Return true if 'source' exists and is more recently modified than
'target', or if 'source' exists and 'target' doesn't. Return false if
both exist and 'target' is the same age or younger than 'source'.
Raise DistutilsFileError if 'source' does not exist.
"""
if not os.path.exists(source):
raise DistutilsFileError("file '%s' does not exist" %
os.path.abspath(source))
if not os.path.exists(target):
return 1
from stat import ST_MTIME
mtime1 = os.stat(source)[ST_MTIME]
mtime2 = os.stat(target)[ST_MTIME]
return mtime1 > mtime2
# newer ()

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"""distutils.errors
Provides exceptions used by the Distutils modules. Note that Distutils
modules may raise standard exceptions; in particular, SystemExit is
usually raised for errors that are obviously the end-user's fault
(eg. bad command-line arguments).
This module is safe to use in "from ... import *" mode; it only exports
symbols whose names start with "Distutils" and end with "Error"."""
class DistutilsError (Exception):
"""The root of all Distutils evil."""
pass
class DistutilsModuleError (DistutilsError):
"""Unable to load an expected module, or to find an expected class
within some module (in particular, command modules and classes)."""
pass
class DistutilsFileError (DistutilsError):
"""Any problems in the filesystem: expected file not found, etc.
Typically this is for problems that we detect before OSError
could be raised."""
pass
class DistutilsPlatformError (DistutilsError):
"""We don't know how to do something on the current platform (but
we do know how to do it on some platform) -- eg. trying to compile
C files on a platform not supported by a CCompiler subclass."""
pass
class DistutilsExecError (DistutilsError):
"""Any problems executing an external program (such as the C
compiler, when compiling C files)."""
pass
# Exception classes used by the CCompiler implementation classes
class CCompilerError (Exception):
"""Some compile/link operation failed."""
class PreprocessError (CCompilerError):
"""Failure to preprocess one or more C/C++ files."""
class CompileError (CCompilerError):
"""Failure to compile one or more C/C++ source files."""
class UnknownFileError (CCompilerError):
"""Attempt to process an unknown file type."""

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"""A simple log mechanism styled after PEP 282."""
# The class here is styled after PEP 282 so that it could later be
# replaced with a standard Python logging implementation.
DEBUG = 1
INFO = 2
WARN = 3
ERROR = 4
FATAL = 5
import sys
class Log:
def __init__(self, threshold=WARN):
self.threshold = threshold
def _log(self, level, msg, args):
if level not in (DEBUG, INFO, WARN, ERROR, FATAL):
raise ValueError('%s wrong log level' % str(level))
if level >= self.threshold:
if args:
msg = msg % args
if level in (WARN, ERROR, FATAL):
stream = sys.stderr
else:
stream = sys.stdout
try:
stream.write('%s\n' % msg)
except UnicodeEncodeError:
# emulate backslashreplace error handler
encoding = stream.encoding
msg = msg.encode(encoding, "backslashreplace").decode(encoding)
stream.write('%s\n' % msg)
stream.flush()
def log(self, level, msg, *args):
self._log(level, msg, args)
def debug(self, msg, *args):
self._log(DEBUG, msg, args)
def info(self, msg, *args):
self._log(INFO, msg, args)
def warn(self, msg, *args):
self._log(WARN, msg, args)
def error(self, msg, *args):
self._log(ERROR, msg, args)
def fatal(self, msg, *args):
self._log(FATAL, msg, args)
_global_log = Log()
log = _global_log.log
debug = _global_log.debug
info = _global_log.info
warn = _global_log.warn
error = _global_log.error
fatal = _global_log.fatal

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"""distutils.msvc9compiler
Contains MSVCCompiler, an implementation of the abstract CCompiler class
for the Microsoft Visual Studio 2008.
The module is compatible with VS 2005 and VS 2008. You can find legacy support
for older versions of VS in distutils.msvccompiler.
"""
# Written by Perry Stoll
# hacked by Robin Becker and Thomas Heller to do a better job of
# finding DevStudio (through the registry)
# ported to VS2005 and VS 2008 by Christian Heimes
import os
import subprocess
import sys
import re
from distutils.errors import DistutilsPlatformError
from distutils.ccompiler import CCompiler
from distutils import log
import winreg
RegOpenKeyEx = winreg.OpenKeyEx
RegEnumKey = winreg.EnumKey
RegEnumValue = winreg.EnumValue
RegError = winreg.error
HKEYS = (winreg.HKEY_USERS,
winreg.HKEY_CURRENT_USER,
winreg.HKEY_LOCAL_MACHINE,
winreg.HKEY_CLASSES_ROOT)
NATIVE_WIN64 = (sys.platform == 'win32' and sys.maxsize > 2**32)
if NATIVE_WIN64:
# Visual C++ is a 32-bit application, so we need to look in
# the corresponding registry branch, if we're running a
# 64-bit Python on Win64
VS_BASE = r"Software\Wow6432Node\Microsoft\VisualStudio\%0.1f"
WINSDK_BASE = r"Software\Wow6432Node\Microsoft\Microsoft SDKs\Windows"
NET_BASE = r"Software\Wow6432Node\Microsoft\.NETFramework"
else:
VS_BASE = r"Software\Microsoft\VisualStudio\%0.1f"
WINSDK_BASE = r"Software\Microsoft\Microsoft SDKs\Windows"
NET_BASE = r"Software\Microsoft\.NETFramework"
# A map keyed by get_platform() return values to values accepted by
# 'vcvarsall.bat'. Note a cross-compile may combine these (eg, 'x86_amd64' is
# the param to cross-compile on x86 targeting amd64.)
PLAT_TO_VCVARS = {
'win32' : 'x86',
'win-amd64' : 'amd64',
}
class Reg:
"""Helper class to read values from the registry
"""
def get_value(cls, path, key):
for base in HKEYS:
d = cls.read_values(base, path)
if d and key in d:
return d[key]
raise KeyError(key)
get_value = classmethod(get_value)
def read_keys(cls, base, key):
"""Return list of registry keys."""
try:
handle = RegOpenKeyEx(base, key)
except RegError:
return None
L = []
i = 0
while True:
try:
k = RegEnumKey(handle, i)
except RegError:
break
L.append(k)
i += 1
return L
read_keys = classmethod(read_keys)
def read_values(cls, base, key):
"""Return dict of registry keys and values.
All names are converted to lowercase.
"""
try:
handle = RegOpenKeyEx(base, key)
except RegError:
return None
d = {}
i = 0
while True:
try:
name, value, type = RegEnumValue(handle, i)
except RegError:
break
name = name.lower()
d[cls.convert_mbcs(name)] = cls.convert_mbcs(value)
i += 1
return d
read_values = classmethod(read_values)
def convert_mbcs(s):
dec = getattr(s, "decode", None)
if dec is not None:
try:
s = dec("mbcs")
except UnicodeError:
pass
return s
convert_mbcs = staticmethod(convert_mbcs)
class MacroExpander:
def __init__(self, version):
self.macros = {}
self.vsbase = VS_BASE % version
self.load_macros(version)
def set_macro(self, macro, path, key):
self.macros["$(%s)" % macro] = Reg.get_value(path, key)
def load_macros(self, version):
self.set_macro("VCInstallDir", self.vsbase + r"\Setup\VC", "productdir")
self.set_macro("VSInstallDir", self.vsbase + r"\Setup\VS", "productdir")
self.set_macro("FrameworkDir", NET_BASE, "installroot")
try:
if version >= 8.0:
self.set_macro("FrameworkSDKDir", NET_BASE,
"sdkinstallrootv2.0")
else:
raise KeyError("sdkinstallrootv2.0")
except KeyError:
raise DistutilsPlatformError(
"""Python was built with Visual Studio 2008;
extensions must be built with a compiler than can generate compatible binaries.
Visual Studio 2008 was not found on this system. If you have Cygwin installed,
you can try compiling with MingW32, by passing "-c mingw32" to setup.py.""")
if version >= 9.0:
self.set_macro("FrameworkVersion", self.vsbase, "clr version")
self.set_macro("WindowsSdkDir", WINSDK_BASE, "currentinstallfolder")
else:
p = r"Software\Microsoft\NET Framework Setup\Product"
for base in HKEYS:
try:
h = RegOpenKeyEx(base, p)
except RegError:
continue
key = RegEnumKey(h, 0)
d = Reg.get_value(base, r"%s\%s" % (p, key))
self.macros["$(FrameworkVersion)"] = d["version"]
def sub(self, s):
for k, v in self.macros.items():
s = s.replace(k, v)
return s
def get_build_version():
"""Return the version of MSVC that was used to build Python.
For Python 2.3 and up, the version number is included in
sys.version. For earlier versions, assume the compiler is MSVC 6.
"""
prefix = "MSC v."
i = sys.version.find(prefix)
if i == -1:
return 6
i = i + len(prefix)
s, rest = sys.version[i:].split(" ", 1)
majorVersion = int(s[:-2]) - 6
if majorVersion >= 13:
# v13 was skipped and should be v14
majorVersion += 1
minorVersion = int(s[2:3]) / 10.0
# I don't think paths are affected by minor version in version 6
if majorVersion == 6:
minorVersion = 0
if majorVersion >= 6:
return majorVersion + minorVersion
# else we don't know what version of the compiler this is
return None
def normalize_and_reduce_paths(paths):
"""Return a list of normalized paths with duplicates removed.
The current order of paths is maintained.
"""
# Paths are normalized so things like: /a and /a/ aren't both preserved.
reduced_paths = []
for p in paths:
np = os.path.normpath(p)
# XXX(nnorwitz): O(n**2), if reduced_paths gets long perhaps use a set.
if np not in reduced_paths:
reduced_paths.append(np)
return reduced_paths
def removeDuplicates(variable):
"""Remove duplicate values of an environment variable.
"""
oldList = variable.split(os.pathsep)
newList = []
for i in oldList:
if i not in newList:
newList.append(i)
newVariable = os.pathsep.join(newList)
return newVariable
def find_vcvarsall(version):
"""Find the vcvarsall.bat file
At first it tries to find the productdir of VS 2008 in the registry. If
that fails it falls back to the VS90COMNTOOLS env var.
"""
vsbase = VS_BASE % version
try:
productdir = Reg.get_value(r"%s\Setup\VC" % vsbase,
"productdir")
except KeyError:
log.debug("Unable to find productdir in registry")
productdir = None
if not productdir or not os.path.isdir(productdir):
toolskey = "VS%0.f0COMNTOOLS" % version
toolsdir = os.environ.get(toolskey, None)
if toolsdir and os.path.isdir(toolsdir):
productdir = os.path.join(toolsdir, os.pardir, os.pardir, "VC")
productdir = os.path.abspath(productdir)
if not os.path.isdir(productdir):
log.debug("%s is not a valid directory" % productdir)
return None
else:
log.debug("Env var %s is not set or invalid" % toolskey)
if not productdir:
log.debug("No productdir found")
return None
vcvarsall = os.path.join(productdir, "vcvarsall.bat")
if os.path.isfile(vcvarsall):
return vcvarsall
log.debug("Unable to find vcvarsall.bat")
return None
def query_vcvarsall(version, arch="x86"):
"""Launch vcvarsall.bat and read the settings from its environment
"""
vcvarsall = find_vcvarsall(version)
interesting = {"include", "lib", "libpath", "path"}
result = {}
if vcvarsall is None:
raise DistutilsPlatformError("Unable to find vcvarsall.bat")
log.debug("Calling 'vcvarsall.bat %s' (version=%s)", arch, version)
popen = subprocess.Popen('"%s" %s & set' % (vcvarsall, arch),
stdout=subprocess.PIPE,
stderr=subprocess.PIPE)
try:
stdout, stderr = popen.communicate()
if popen.wait() != 0:
raise DistutilsPlatformError(stderr.decode("mbcs"))
stdout = stdout.decode("mbcs")
for line in stdout.split("\n"):
line = Reg.convert_mbcs(line)
if '=' not in line:
continue
line = line.strip()
key, value = line.split('=', 1)
key = key.lower()
if key in interesting:
if value.endswith(os.pathsep):
value = value[:-1]
result[key] = removeDuplicates(value)
finally:
popen.stdout.close()
popen.stderr.close()
if len(result) != len(interesting):
raise ValueError(str(list(result.keys())))
return result
# More globals
VERSION = get_build_version()
if VERSION < 8.0:
raise DistutilsPlatformError("VC %0.1f is not supported by this module" % VERSION)
# MACROS = MacroExpander(VERSION)
class MSVCCompiler(CCompiler) :
"""Concrete class that implements an interface to Microsoft Visual C++,
as defined by the CCompiler abstract class."""
compiler_type = 'msvc'
# Just set this so CCompiler's constructor doesn't barf. We currently
# don't use the 'set_executables()' bureaucracy provided by CCompiler,
# as it really isn't necessary for this sort of single-compiler class.
# Would be nice to have a consistent interface with UnixCCompiler,
# though, so it's worth thinking about.
executables = {}
# Private class data (need to distinguish C from C++ source for compiler)
_c_extensions = ['.c']
_cpp_extensions = ['.cc', '.cpp', '.cxx']
_rc_extensions = ['.rc']
_mc_extensions = ['.mc']
# Needed for the filename generation methods provided by the
# base class, CCompiler.
src_extensions = (_c_extensions + _cpp_extensions +
_rc_extensions + _mc_extensions)
res_extension = '.res'
obj_extension = '.obj'
static_lib_extension = '.lib'
shared_lib_extension = '.dll'
static_lib_format = shared_lib_format = '%s%s'
exe_extension = '.exe'
def __init__(self, verbose=0, dry_run=0, force=0):
CCompiler.__init__ (self, verbose, dry_run, force)
self.__version = VERSION
self.__root = r"Software\Microsoft\VisualStudio"
# self.__macros = MACROS
self.__paths = []
# target platform (.plat_name is consistent with 'bdist')
self.plat_name = None
self.__arch = None # deprecated name
self.initialized = False
# -- Worker methods ------------------------------------------------
def manifest_setup_ldargs(self, output_filename, build_temp, ld_args):
# If we need a manifest at all, an embedded manifest is recommended.
# See MSDN article titled
# "How to: Embed a Manifest Inside a C/C++ Application"
# (currently at http://msdn2.microsoft.com/en-us/library/ms235591(VS.80).aspx)
# Ask the linker to generate the manifest in the temp dir, so
# we can check it, and possibly embed it, later.
temp_manifest = os.path.join(
build_temp,
os.path.basename(output_filename) + ".manifest")
ld_args.append('/MANIFESTFILE:' + temp_manifest)
def manifest_get_embed_info(self, target_desc, ld_args):
# If a manifest should be embedded, return a tuple of
# (manifest_filename, resource_id). Returns None if no manifest
# should be embedded. See http://bugs.python.org/issue7833 for why
# we want to avoid any manifest for extension modules if we can.
for arg in ld_args:
if arg.startswith("/MANIFESTFILE:"):
temp_manifest = arg.split(":", 1)[1]
break
else:
# no /MANIFESTFILE so nothing to do.
return None
if target_desc == CCompiler.EXECUTABLE:
# by default, executables always get the manifest with the
# CRT referenced.
mfid = 1
else:
# Extension modules try and avoid any manifest if possible.
mfid = 2
temp_manifest = self._remove_visual_c_ref(temp_manifest)
if temp_manifest is None:
return None
return temp_manifest, mfid
def _remove_visual_c_ref(self, manifest_file):
try:
# Remove references to the Visual C runtime, so they will
# fall through to the Visual C dependency of Python.exe.
# This way, when installed for a restricted user (e.g.
# runtimes are not in WinSxS folder, but in Python's own
# folder), the runtimes do not need to be in every folder
# with .pyd's.
# Returns either the filename of the modified manifest or
# None if no manifest should be embedded.
manifest_f = open(manifest_file)
try:
manifest_buf = manifest_f.read()
finally:
manifest_f.close()
pattern = re.compile(
r"""<assemblyIdentity.*?name=("|')Microsoft\."""\
r"""VC\d{2}\.CRT("|').*?(/>|</assemblyIdentity>)""",
re.DOTALL)
manifest_buf = re.sub(pattern, "", manifest_buf)
pattern = r"<dependentAssembly>\s*</dependentAssembly>"
manifest_buf = re.sub(pattern, "", manifest_buf)
# Now see if any other assemblies are referenced - if not, we
# don't want a manifest embedded.
pattern = re.compile(
r"""<assemblyIdentity.*?name=(?:"|')(.+?)(?:"|')"""
r""".*?(?:/>|</assemblyIdentity>)""", re.DOTALL)
if re.search(pattern, manifest_buf) is None:
return None
manifest_f = open(manifest_file, 'w')
try:
manifest_f.write(manifest_buf)
return manifest_file
finally:
manifest_f.close()
except OSError:
pass
# -- Miscellaneous methods -----------------------------------------
# Helper methods for using the MSVC registry settings
def find_exe(self, exe):
"""Return path to an MSVC executable program.
Tries to find the program in several places: first, one of the
MSVC program search paths from the registry; next, the directories
in the PATH environment variable. If any of those work, return an
absolute path that is known to exist. If none of them work, just
return the original program name, 'exe'.
"""
for p in self.__paths:
fn = os.path.join(os.path.abspath(p), exe)
if os.path.isfile(fn):
return fn
# didn't find it; try existing path
for p in os.environ['Path'].split(';'):
fn = os.path.join(os.path.abspath(p),exe)
if os.path.isfile(fn):
return fn
return exe

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"""distutils.msvccompiler
Contains MSVCCompiler, an implementation of the abstract CCompiler class
for the Microsoft Visual Studio.
"""
# Written by Perry Stoll
# hacked by Robin Becker and Thomas Heller to do a better job of
# finding DevStudio (through the registry)
import sys, os
from distutils.errors import DistutilsPlatformError
from distutils.ccompiler import CCompiler
from distutils import log
_can_read_reg = False
try:
import winreg
_can_read_reg = True
hkey_mod = winreg
RegOpenKeyEx = winreg.OpenKeyEx
RegEnumKey = winreg.EnumKey
RegEnumValue = winreg.EnumValue
RegError = winreg.error
except ImportError:
try:
import win32api
import win32con
_can_read_reg = True
hkey_mod = win32con
RegOpenKeyEx = win32api.RegOpenKeyEx
RegEnumKey = win32api.RegEnumKey
RegEnumValue = win32api.RegEnumValue
RegError = win32api.error
except ImportError:
log.info("Warning: Can't read registry to find the "
"necessary compiler setting\n"
"Make sure that Python modules winreg, "
"win32api or win32con are installed.")
if _can_read_reg:
HKEYS = (hkey_mod.HKEY_USERS,
hkey_mod.HKEY_CURRENT_USER,
hkey_mod.HKEY_LOCAL_MACHINE,
hkey_mod.HKEY_CLASSES_ROOT)
def read_keys(base, key):
"""Return list of registry keys."""
try:
handle = RegOpenKeyEx(base, key)
except RegError:
return None
L = []
i = 0
while True:
try:
k = RegEnumKey(handle, i)
except RegError:
break
L.append(k)
i += 1
return L
def read_values(base, key):
"""Return dict of registry keys and values.
All names are converted to lowercase.
"""
try:
handle = RegOpenKeyEx(base, key)
except RegError:
return None
d = {}
i = 0
while True:
try:
name, value, type = RegEnumValue(handle, i)
except RegError:
break
name = name.lower()
d[convert_mbcs(name)] = convert_mbcs(value)
i += 1
return d
def convert_mbcs(s):
dec = getattr(s, "decode", None)
if dec is not None:
try:
s = dec("mbcs")
except UnicodeError:
pass
return s
class MacroExpander:
def __init__(self, version):
self.macros = {}
self.load_macros(version)
def set_macro(self, macro, path, key):
for base in HKEYS:
d = read_values(base, path)
if d:
self.macros["$(%s)" % macro] = d[key]
break
def load_macros(self, version):
vsbase = r"Software\Microsoft\VisualStudio\%0.1f" % version
self.set_macro("VCInstallDir", vsbase + r"\Setup\VC", "productdir")
self.set_macro("VSInstallDir", vsbase + r"\Setup\VS", "productdir")
net = r"Software\Microsoft\.NETFramework"
self.set_macro("FrameworkDir", net, "installroot")
try:
if version > 7.0:
self.set_macro("FrameworkSDKDir", net, "sdkinstallrootv1.1")
else:
self.set_macro("FrameworkSDKDir", net, "sdkinstallroot")
except KeyError as exc: #
raise DistutilsPlatformError(
"""Python was built with Visual Studio 2003;
extensions must be built with a compiler than can generate compatible binaries.
Visual Studio 2003 was not found on this system. If you have Cygwin installed,
you can try compiling with MingW32, by passing "-c mingw32" to setup.py.""")
p = r"Software\Microsoft\NET Framework Setup\Product"
for base in HKEYS:
try:
h = RegOpenKeyEx(base, p)
except RegError:
continue
key = RegEnumKey(h, 0)
d = read_values(base, r"%s\%s" % (p, key))
self.macros["$(FrameworkVersion)"] = d["version"]
def sub(self, s):
for k, v in self.macros.items():
s = s.replace(k, v)
return s
def get_build_version():
"""Return the version of MSVC that was used to build Python.
For Python 2.3 and up, the version number is included in
sys.version. For earlier versions, assume the compiler is MSVC 6.
"""
prefix = "MSC v."
i = sys.version.find(prefix)
if i == -1:
return 6
i = i + len(prefix)
s, rest = sys.version[i:].split(" ", 1)
majorVersion = int(s[:-2]) - 6
if majorVersion >= 13:
# v13 was skipped and should be v14
majorVersion += 1
minorVersion = int(s[2:3]) / 10.0
# I don't think paths are affected by minor version in version 6
if majorVersion == 6:
minorVersion = 0
if majorVersion >= 6:
return majorVersion + minorVersion
# else we don't know what version of the compiler this is
return None
def get_build_architecture():
"""Return the processor architecture.
Possible results are "Intel" or "AMD64".
"""
prefix = " bit ("
i = sys.version.find(prefix)
if i == -1:
return "Intel"
j = sys.version.find(")", i)
return sys.version[i+len(prefix):j]
def normalize_and_reduce_paths(paths):
"""Return a list of normalized paths with duplicates removed.
The current order of paths is maintained.
"""
# Paths are normalized so things like: /a and /a/ aren't both preserved.
reduced_paths = []
for p in paths:
np = os.path.normpath(p)
# XXX(nnorwitz): O(n**2), if reduced_paths gets long perhaps use a set.
if np not in reduced_paths:
reduced_paths.append(np)
return reduced_paths
class MSVCCompiler(CCompiler) :
"""Concrete class that implements an interface to Microsoft Visual C++,
as defined by the CCompiler abstract class."""
compiler_type = 'msvc'
# Just set this so CCompiler's constructor doesn't barf. We currently
# don't use the 'set_executables()' bureaucracy provided by CCompiler,
# as it really isn't necessary for this sort of single-compiler class.
# Would be nice to have a consistent interface with UnixCCompiler,
# though, so it's worth thinking about.
executables = {}
# Private class data (need to distinguish C from C++ source for compiler)
_c_extensions = ['.c']
_cpp_extensions = ['.cc', '.cpp', '.cxx']
_rc_extensions = ['.rc']
_mc_extensions = ['.mc']
# Needed for the filename generation methods provided by the
# base class, CCompiler.
src_extensions = (_c_extensions + _cpp_extensions +
_rc_extensions + _mc_extensions)
res_extension = '.res'
obj_extension = '.obj'
static_lib_extension = '.lib'
shared_lib_extension = '.dll'
static_lib_format = shared_lib_format = '%s%s'
exe_extension = '.exe'
def __init__(self, verbose=0, dry_run=0, force=0):
CCompiler.__init__ (self, verbose, dry_run, force)
self.__version = get_build_version()
self.__arch = get_build_architecture()
if self.__arch == "Intel":
# x86
if self.__version >= 7:
self.__root = r"Software\Microsoft\VisualStudio"
self.__macros = MacroExpander(self.__version)
else:
self.__root = r"Software\Microsoft\Devstudio"
self.__product = "Visual Studio version %s" % self.__version
else:
# Win64. Assume this was built with the platform SDK
self.__product = "Microsoft SDK compiler %s" % (self.__version + 6)
self.initialized = False
# -- Miscellaneous methods -----------------------------------------
# Helper methods for using the MSVC registry settings
def find_exe(self, exe):
"""Return path to an MSVC executable program.
Tries to find the program in several places: first, one of the
MSVC program search paths from the registry; next, the directories
in the PATH environment variable. If any of those work, return an
absolute path that is known to exist. If none of them work, just
return the original program name, 'exe'.
"""
for p in self.__paths:
fn = os.path.join(os.path.abspath(p), exe)
if os.path.isfile(fn):
return fn
# didn't find it; try existing path
for p in os.environ['Path'].split(';'):
fn = os.path.join(os.path.abspath(p),exe)
if os.path.isfile(fn):
return fn
return exe
def get_msvc_paths(self, path, platform='x86'):
"""Get a list of devstudio directories (include, lib or path).
Return a list of strings. The list will be empty if unable to
access the registry or appropriate registry keys not found.
"""
if not _can_read_reg:
return []
path = path + " dirs"
if self.__version >= 7:
key = (r"%s\%0.1f\VC\VC_OBJECTS_PLATFORM_INFO\Win32\Directories"
% (self.__root, self.__version))
else:
key = (r"%s\6.0\Build System\Components\Platforms"
r"\Win32 (%s)\Directories" % (self.__root, platform))
for base in HKEYS:
d = read_values(base, key)
if d:
if self.__version >= 7:
return self.__macros.sub(d[path]).split(";")
else:
return d[path].split(";")
# MSVC 6 seems to create the registry entries we need only when
# the GUI is run.
if self.__version == 6:
for base in HKEYS:
if read_values(base, r"%s\6.0" % self.__root) is not None:
self.warn("It seems you have Visual Studio 6 installed, "
"but the expected registry settings are not present.\n"
"You must at least run the Visual Studio GUI once "
"so that these entries are created.")
break
return []
def set_path_env_var(self, name):
"""Set environment variable 'name' to an MSVC path type value.
This is equivalent to a SET command prior to execution of spawned
commands.
"""
if name == "lib":
p = self.get_msvc_paths("library")
else:
p = self.get_msvc_paths(name)
if p:
os.environ[name] = ';'.join(p)
if get_build_version() >= 8.0:
log.debug("Importing new compiler from distutils.msvc9compiler")
OldMSVCCompiler = MSVCCompiler
from distutils.msvc9compiler import MSVCCompiler
# get_build_architecture not really relevant now we support cross-compile
from distutils.msvc9compiler import MacroExpander

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"""distutils.spawn
Provides the 'spawn()' function, a front-end to various platform-
specific functions for launching another program in a sub-process.
Also provides the 'find_executable()' to search the path for a given
executable name.
"""
import sys
import os
import os.path
def find_executable(executable, path=None):
"""Tries to find 'executable' in the directories listed in 'path'.
A string listing directories separated by 'os.pathsep'; defaults to
os.environ['PATH']. Returns the complete filename or None if not found.
"""
_, ext = os.path.splitext(executable)
if (sys.platform == 'win32') and (ext != '.exe'):
executable = executable + '.exe'
if os.path.isfile(executable):
return executable
if path is None:
path = os.environ.get('PATH', None)
if path is None:
try:
path = os.confstr("CS_PATH")
except (AttributeError, ValueError):
# os.confstr() or CS_PATH is not available
path = os.defpath
# bpo-35755: Don't use os.defpath if the PATH environment variable is
# set to an empty string
# PATH='' doesn't match, whereas PATH=':' looks in the current directory
if not path:
return None
paths = path.split(os.pathsep)
for p in paths:
f = os.path.join(p, executable)
if os.path.isfile(f):
# the file exists, we have a shot at spawn working
return f
return None

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"""distutils.unixccompiler
Contains the UnixCCompiler class, a subclass of CCompiler that handles
the "typical" Unix-style command-line C compiler:
* macros defined with -Dname[=value]
* macros undefined with -Uname
* include search directories specified with -Idir
* libraries specified with -lllib
* library search directories specified with -Ldir
* compile handled by 'cc' (or similar) executable with -c option:
compiles .c to .o
* link static library handled by 'ar' command (possibly with 'ranlib')
* link shared library handled by 'cc -shared'
"""
import os, sys, re
from distutils.dep_util import newer
from distutils.ccompiler import CCompiler, gen_preprocess_options
from distutils.errors import DistutilsExecError, CompileError
# XXX Things not currently handled:
# * optimization/debug/warning flags; we just use whatever's in Python's
# Makefile and live with it. Is this adequate? If not, we might
# have to have a bunch of subclasses GNUCCompiler, SGICCompiler,
# SunCCompiler, and I suspect down that road lies madness.
# * even if we don't know a warning flag from an optimization flag,
# we need some way for outsiders to feed preprocessor/compiler/linker
# flags in to us -- eg. a sysadmin might want to mandate certain flags
# via a site config file, or a user might want to set something for
# compiling this module distribution only via the setup.py command
# line, whatever. As long as these options come from something on the
# current system, they can be as system-dependent as they like, and we
# should just happily stuff them into the preprocessor/compiler/linker
# options and carry on.
class UnixCCompiler(CCompiler):
compiler_type = 'unix'
# These are used by CCompiler in two places: the constructor sets
# instance attributes 'preprocessor', 'compiler', etc. from them, and
# 'set_executable()' allows any of these to be set. The defaults here
# are pretty generic; they will probably have to be set by an outsider
# (eg. using information discovered by the sysconfig about building
# Python extensions).
executables = {'preprocessor' : None,
'compiler' : ["cc"],
'compiler_so' : ["cc"],
'compiler_cxx' : ["cc"],
'linker_so' : ["cc", "-shared"],
'linker_exe' : ["cc"],
'archiver' : ["ar", "-cr"],
'ranlib' : None,
}
if sys.platform[:6] == "darwin":
executables['ranlib'] = ["ranlib"]
# Needed for the filename generation methods provided by the base
# class, CCompiler. NB. whoever instantiates/uses a particular
# UnixCCompiler instance should set 'shared_lib_ext' -- we set a
# reasonable common default here, but it's not necessarily used on all
# Unices!
src_extensions = [".c",".C",".cc",".cxx",".cpp",".m"]
obj_extension = ".o"
static_lib_extension = ".a"
shared_lib_extension = ".so"
dylib_lib_extension = ".dylib"
xcode_stub_lib_extension = ".tbd"
static_lib_format = shared_lib_format = dylib_lib_format = "lib%s%s"
xcode_stub_lib_format = dylib_lib_format
if sys.platform == "cygwin":
exe_extension = ".exe"
def preprocess(self, source, output_file=None, macros=None,
include_dirs=None, extra_preargs=None, extra_postargs=None):
fixed_args = self._fix_compile_args(None, macros, include_dirs)
ignore, macros, include_dirs = fixed_args
pp_opts = gen_preprocess_options(macros, include_dirs)
pp_args = self.preprocessor + pp_opts
if output_file:
pp_args.extend(['-o', output_file])
if extra_preargs:
pp_args[:0] = extra_preargs
if extra_postargs:
pp_args.extend(extra_postargs)
pp_args.append(source)
# We need to preprocess: either we're being forced to, or we're
# generating output to stdout, or there's a target output file and
# the source file is newer than the target (or the target doesn't
# exist).
if self.force or output_file is None or newer(source, output_file):
if output_file:
self.mkpath(os.path.dirname(output_file))
try:
self.spawn(pp_args)
except DistutilsExecError as msg:
raise CompileError(msg)

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"""distutils.util
Miscellaneous utility functions -- anything that doesn't fit into
one of the other *util.py modules.
"""
import os
import re
import string
import sys
from distutils.errors import DistutilsPlatformError
def get_host_platform():
"""Return a string that identifies the current platform. This is used mainly to
distinguish platform-specific build directories and platform-specific built
distributions. Typically includes the OS name and version and the
architecture (as supplied by 'os.uname()'), although the exact information
included depends on the OS; eg. on Linux, the kernel version isn't
particularly important.
Examples of returned values:
linux-i586
linux-alpha (?)
solaris-2.6-sun4u
Windows will return one of:
win-amd64 (64bit Windows on AMD64 (aka x86_64, Intel64, EM64T, etc)
win32 (all others - specifically, sys.platform is returned)
For other non-POSIX platforms, currently just returns 'sys.platform'.
"""
if os.name == 'nt':
if 'amd64' in sys.version.lower():
return 'win-amd64'
if '(arm)' in sys.version.lower():
return 'win-arm32'
if '(arm64)' in sys.version.lower():
return 'win-arm64'
return sys.platform
# Set for cross builds explicitly
if "_PYTHON_HOST_PLATFORM" in os.environ:
return os.environ["_PYTHON_HOST_PLATFORM"]
if os.name != "posix" or not hasattr(os, 'uname'):
# XXX what about the architecture? NT is Intel or Alpha,
# Mac OS is M68k or PPC, etc.
return sys.platform
# Try to distinguish various flavours of Unix
(osname, host, release, version, machine) = os.uname()
# Convert the OS name to lowercase, remove '/' characters, and translate
# spaces (for "Power Macintosh")
osname = osname.lower().replace('/', '')
machine = machine.replace(' ', '_')
machine = machine.replace('/', '-')
if osname[:5] == "linux":
# At least on Linux/Intel, 'machine' is the processor --
# i386, etc.
# XXX what about Alpha, SPARC, etc?
return "%s-%s" % (osname, machine)
elif osname[:5] == "sunos":
if release[0] >= "5": # SunOS 5 == Solaris 2
osname = "solaris"
release = "%d.%s" % (int(release[0]) - 3, release[2:])
# We can't use "platform.architecture()[0]" because a
# bootstrap problem. We use a dict to get an error
# if some suspicious happens.
bitness = {2147483647:"32bit", 9223372036854775807:"64bit"}
machine += ".%s" % bitness[sys.maxsize]
# fall through to standard osname-release-machine representation
elif osname[:3] == "aix":
from _aix_support import aix_platform
return aix_platform()
elif osname[:6] == "cygwin":
osname = "cygwin"
rel_re = re.compile (r'[\d.]+', re.ASCII)
m = rel_re.match(release)
if m:
release = m.group()
elif osname[:6] == "darwin":
import _osx_support, sysconfig
osname, release, machine = _osx_support.get_platform_osx(
sysconfig.get_config_vars(),
osname, release, machine)
return "%s-%s-%s" % (osname, release, machine)
def get_platform():
if os.name == 'nt':
TARGET_TO_PLAT = {
'x86' : 'win32',
'x64' : 'win-amd64',
'arm' : 'win-arm32',
}
return TARGET_TO_PLAT.get(os.environ.get('VSCMD_ARG_TGT_ARCH')) or get_host_platform()
else:
return get_host_platform()
# Needed by 'split_quoted()'
_wordchars_re = _squote_re = _dquote_re = None
def _init_regex():
global _wordchars_re, _squote_re, _dquote_re
_wordchars_re = re.compile(r'[^\\\'\"%s ]*' % string.whitespace)
_squote_re = re.compile(r"'(?:[^'\\]|\\.)*'")
_dquote_re = re.compile(r'"(?:[^"\\]|\\.)*"')
def split_quoted (s):
"""Split a string up according to Unix shell-like rules for quotes and
backslashes. In short: words are delimited by spaces, as long as those
spaces are not escaped by a backslash, or inside a quoted string.
Single and double quotes are equivalent, and the quote characters can
be backslash-escaped. The backslash is stripped from any two-character
escape sequence, leaving only the escaped character. The quote
characters are stripped from any quoted string. Returns a list of
words.
"""
# This is a nice algorithm for splitting up a single string, since it
# doesn't require character-by-character examination. It was a little
# bit of a brain-bender to get it working right, though...
if _wordchars_re is None: _init_regex()
s = s.strip()
words = []
pos = 0
while s:
m = _wordchars_re.match(s, pos)
end = m.end()
if end == len(s):
words.append(s[:end])
break
if s[end] in string.whitespace: # unescaped, unquoted whitespace: now
words.append(s[:end]) # we definitely have a word delimiter
s = s[end:].lstrip()
pos = 0
elif s[end] == '\\': # preserve whatever is being escaped;
# will become part of the current word
s = s[:end] + s[end+1:]
pos = end+1
else:
if s[end] == "'": # slurp singly-quoted string
m = _squote_re.match(s, end)
elif s[end] == '"': # slurp doubly-quoted string
m = _dquote_re.match(s, end)
else:
raise RuntimeError("this can't happen (bad char '%c')" % s[end])
if m is None:
raise ValueError("bad string (mismatched %s quotes?)" % s[end])
(beg, end) = m.span()
s = s[:beg] + s[beg+1:end-1] + s[end:]
pos = m.end() - 2
if pos >= len(s):
words.append(s)
break
return words
# split_quoted ()