Vehicle-Anti-Theft-Face-Rec.../venv/Lib/site-packages/numpy/distutils/command/config.py

510 lines
20 KiB
Python

# Added Fortran compiler support to config. Currently useful only for
# try_compile call. try_run works but is untested for most of Fortran
# compilers (they must define linker_exe first).
# Pearu Peterson
import os
import signal
import subprocess
import sys
import textwrap
import warnings
from distutils.command.config import config as old_config
from distutils.command.config import LANG_EXT
from distutils import log
from distutils.file_util import copy_file
from distutils.ccompiler import CompileError, LinkError
import distutils
from numpy.distutils.exec_command import filepath_from_subprocess_output
from numpy.distutils.mingw32ccompiler import generate_manifest
from numpy.distutils.command.autodist import (check_gcc_function_attribute,
check_gcc_function_attribute_with_intrinsics,
check_gcc_variable_attribute,
check_inline,
check_restrict,
check_compiler_gcc4)
LANG_EXT['f77'] = '.f'
LANG_EXT['f90'] = '.f90'
class config(old_config):
old_config.user_options += [
('fcompiler=', None, "specify the Fortran compiler type"),
]
def initialize_options(self):
self.fcompiler = None
old_config.initialize_options(self)
def _check_compiler (self):
old_config._check_compiler(self)
from numpy.distutils.fcompiler import FCompiler, new_fcompiler
if sys.platform == 'win32' and (self.compiler.compiler_type in
('msvc', 'intelw', 'intelemw')):
# XXX: hack to circumvent a python 2.6 bug with msvc9compiler:
# initialize call query_vcvarsall, which throws an IOError, and
# causes an error along the way without much information. We try to
# catch it here, hoping it is early enough, and print an helpful
# message instead of Error: None.
if not self.compiler.initialized:
try:
self.compiler.initialize()
except IOError as e:
msg = textwrap.dedent("""\
Could not initialize compiler instance: do you have Visual Studio
installed? If you are trying to build with MinGW, please use "python setup.py
build -c mingw32" instead. If you have Visual Studio installed, check it is
correctly installed, and the right version (VS 2008 for python 2.6, 2.7 and 3.2,
VS 2010 for >= 3.3).
Original exception was: %s, and the Compiler class was %s
============================================================================""") \
% (e, self.compiler.__class__.__name__)
print(textwrap.dedent("""\
============================================================================"""))
raise distutils.errors.DistutilsPlatformError(msg)
# After MSVC is initialized, add an explicit /MANIFEST to linker
# flags. See issues gh-4245 and gh-4101 for details. Also
# relevant are issues 4431 and 16296 on the Python bug tracker.
from distutils import msvc9compiler
if msvc9compiler.get_build_version() >= 10:
for ldflags in [self.compiler.ldflags_shared,
self.compiler.ldflags_shared_debug]:
if '/MANIFEST' not in ldflags:
ldflags.append('/MANIFEST')
if not isinstance(self.fcompiler, FCompiler):
self.fcompiler = new_fcompiler(compiler=self.fcompiler,
dry_run=self.dry_run, force=1,
c_compiler=self.compiler)
if self.fcompiler is not None:
self.fcompiler.customize(self.distribution)
if self.fcompiler.get_version():
self.fcompiler.customize_cmd(self)
self.fcompiler.show_customization()
def _wrap_method(self, mth, lang, args):
from distutils.ccompiler import CompileError
from distutils.errors import DistutilsExecError
save_compiler = self.compiler
if lang in ['f77', 'f90']:
self.compiler = self.fcompiler
try:
ret = mth(*((self,)+args))
except (DistutilsExecError, CompileError) as e:
str(e)
self.compiler = save_compiler
raise CompileError
self.compiler = save_compiler
return ret
def _compile (self, body, headers, include_dirs, lang):
src, obj = self._wrap_method(old_config._compile, lang,
(body, headers, include_dirs, lang))
# _compile in unixcompiler.py sometimes creates .d dependency files.
# Clean them up.
self.temp_files.append(obj + '.d')
return src, obj
def _link (self, body,
headers, include_dirs,
libraries, library_dirs, lang):
if self.compiler.compiler_type=='msvc':
libraries = (libraries or [])[:]
library_dirs = (library_dirs or [])[:]
if lang in ['f77', 'f90']:
lang = 'c' # always use system linker when using MSVC compiler
if self.fcompiler:
for d in self.fcompiler.library_dirs or []:
# correct path when compiling in Cygwin but with
# normal Win Python
if d.startswith('/usr/lib'):
try:
d = subprocess.check_output(['cygpath',
'-w', d])
except (OSError, subprocess.CalledProcessError):
pass
else:
d = filepath_from_subprocess_output(d)
library_dirs.append(d)
for libname in self.fcompiler.libraries or []:
if libname not in libraries:
libraries.append(libname)
for libname in libraries:
if libname.startswith('msvc'): continue
fileexists = False
for libdir in library_dirs or []:
libfile = os.path.join(libdir, '%s.lib' % (libname))
if os.path.isfile(libfile):
fileexists = True
break
if fileexists: continue
# make g77-compiled static libs available to MSVC
fileexists = False
for libdir in library_dirs:
libfile = os.path.join(libdir, 'lib%s.a' % (libname))
if os.path.isfile(libfile):
# copy libname.a file to name.lib so that MSVC linker
# can find it
libfile2 = os.path.join(libdir, '%s.lib' % (libname))
copy_file(libfile, libfile2)
self.temp_files.append(libfile2)
fileexists = True
break
if fileexists: continue
log.warn('could not find library %r in directories %s' \
% (libname, library_dirs))
elif self.compiler.compiler_type == 'mingw32':
generate_manifest(self)
return self._wrap_method(old_config._link, lang,
(body, headers, include_dirs,
libraries, library_dirs, lang))
def check_header(self, header, include_dirs=None, library_dirs=None, lang='c'):
self._check_compiler()
return self.try_compile(
"/* we need a dummy line to make distutils happy */",
[header], include_dirs)
def check_decl(self, symbol,
headers=None, include_dirs=None):
self._check_compiler()
body = textwrap.dedent("""
int main(void)
{
#ifndef %s
(void) %s;
#endif
;
return 0;
}""") % (symbol, symbol)
return self.try_compile(body, headers, include_dirs)
def check_macro_true(self, symbol,
headers=None, include_dirs=None):
self._check_compiler()
body = textwrap.dedent("""
int main(void)
{
#if %s
#else
#error false or undefined macro
#endif
;
return 0;
}""") % (symbol,)
return self.try_compile(body, headers, include_dirs)
def check_type(self, type_name, headers=None, include_dirs=None,
library_dirs=None):
"""Check type availability. Return True if the type can be compiled,
False otherwise"""
self._check_compiler()
# First check the type can be compiled
body = textwrap.dedent(r"""
int main(void) {
if ((%(name)s *) 0)
return 0;
if (sizeof (%(name)s))
return 0;
}
""") % {'name': type_name}
st = False
try:
try:
self._compile(body % {'type': type_name},
headers, include_dirs, 'c')
st = True
except distutils.errors.CompileError:
st = False
finally:
self._clean()
return st
def check_type_size(self, type_name, headers=None, include_dirs=None, library_dirs=None, expected=None):
"""Check size of a given type."""
self._check_compiler()
# First check the type can be compiled
body = textwrap.dedent(r"""
typedef %(type)s npy_check_sizeof_type;
int main (void)
{
static int test_array [1 - 2 * !(((long) (sizeof (npy_check_sizeof_type))) >= 0)];
test_array [0] = 0
;
return 0;
}
""")
self._compile(body % {'type': type_name},
headers, include_dirs, 'c')
self._clean()
if expected:
body = textwrap.dedent(r"""
typedef %(type)s npy_check_sizeof_type;
int main (void)
{
static int test_array [1 - 2 * !(((long) (sizeof (npy_check_sizeof_type))) == %(size)s)];
test_array [0] = 0
;
return 0;
}
""")
for size in expected:
try:
self._compile(body % {'type': type_name, 'size': size},
headers, include_dirs, 'c')
self._clean()
return size
except CompileError:
pass
# this fails to *compile* if size > sizeof(type)
body = textwrap.dedent(r"""
typedef %(type)s npy_check_sizeof_type;
int main (void)
{
static int test_array [1 - 2 * !(((long) (sizeof (npy_check_sizeof_type))) <= %(size)s)];
test_array [0] = 0
;
return 0;
}
""")
# The principle is simple: we first find low and high bounds of size
# for the type, where low/high are looked up on a log scale. Then, we
# do a binary search to find the exact size between low and high
low = 0
mid = 0
while True:
try:
self._compile(body % {'type': type_name, 'size': mid},
headers, include_dirs, 'c')
self._clean()
break
except CompileError:
#log.info("failure to test for bound %d" % mid)
low = mid + 1
mid = 2 * mid + 1
high = mid
# Binary search:
while low != high:
mid = (high - low) // 2 + low
try:
self._compile(body % {'type': type_name, 'size': mid},
headers, include_dirs, 'c')
self._clean()
high = mid
except CompileError:
low = mid + 1
return low
def check_func(self, func,
headers=None, include_dirs=None,
libraries=None, library_dirs=None,
decl=False, call=False, call_args=None):
# clean up distutils's config a bit: add void to main(), and
# return a value.
self._check_compiler()
body = []
if decl:
if type(decl) == str:
body.append(decl)
else:
body.append("int %s (void);" % func)
# Handle MSVC intrinsics: force MS compiler to make a function call.
# Useful to test for some functions when built with optimization on, to
# avoid build error because the intrinsic and our 'fake' test
# declaration do not match.
body.append("#ifdef _MSC_VER")
body.append("#pragma function(%s)" % func)
body.append("#endif")
body.append("int main (void) {")
if call:
if call_args is None:
call_args = ''
body.append(" %s(%s);" % (func, call_args))
else:
body.append(" %s;" % func)
body.append(" return 0;")
body.append("}")
body = '\n'.join(body) + "\n"
return self.try_link(body, headers, include_dirs,
libraries, library_dirs)
def check_funcs_once(self, funcs,
headers=None, include_dirs=None,
libraries=None, library_dirs=None,
decl=False, call=False, call_args=None):
"""Check a list of functions at once.
This is useful to speed up things, since all the functions in the funcs
list will be put in one compilation unit.
Arguments
---------
funcs : seq
list of functions to test
include_dirs : seq
list of header paths
libraries : seq
list of libraries to link the code snippet to
library_dirs : seq
list of library paths
decl : dict
for every (key, value), the declaration in the value will be
used for function in key. If a function is not in the
dictionary, no declaration will be used.
call : dict
for every item (f, value), if the value is True, a call will be
done to the function f.
"""
self._check_compiler()
body = []
if decl:
for f, v in decl.items():
if v:
body.append("int %s (void);" % f)
# Handle MS intrinsics. See check_func for more info.
body.append("#ifdef _MSC_VER")
for func in funcs:
body.append("#pragma function(%s)" % func)
body.append("#endif")
body.append("int main (void) {")
if call:
for f in funcs:
if f in call and call[f]:
if not (call_args and f in call_args and call_args[f]):
args = ''
else:
args = call_args[f]
body.append(" %s(%s);" % (f, args))
else:
body.append(" %s;" % f)
else:
for f in funcs:
body.append(" %s;" % f)
body.append(" return 0;")
body.append("}")
body = '\n'.join(body) + "\n"
return self.try_link(body, headers, include_dirs,
libraries, library_dirs)
def check_inline(self):
"""Return the inline keyword recognized by the compiler, empty string
otherwise."""
return check_inline(self)
def check_restrict(self):
"""Return the restrict keyword recognized by the compiler, empty string
otherwise."""
return check_restrict(self)
def check_compiler_gcc4(self):
"""Return True if the C compiler is gcc >= 4."""
return check_compiler_gcc4(self)
def check_gcc_function_attribute(self, attribute, name):
return check_gcc_function_attribute(self, attribute, name)
def check_gcc_function_attribute_with_intrinsics(self, attribute, name,
code, include):
return check_gcc_function_attribute_with_intrinsics(self, attribute,
name, code, include)
def check_gcc_variable_attribute(self, attribute):
return check_gcc_variable_attribute(self, attribute)
def get_output(self, body, headers=None, include_dirs=None,
libraries=None, library_dirs=None,
lang="c", use_tee=None):
"""Try to compile, link to an executable, and run a program
built from 'body' and 'headers'. Returns the exit status code
of the program and its output.
"""
# 2008-11-16, RemoveMe
warnings.warn("\n+++++++++++++++++++++++++++++++++++++++++++++++++\n"
"Usage of get_output is deprecated: please do not \n"
"use it anymore, and avoid configuration checks \n"
"involving running executable on the target machine.\n"
"+++++++++++++++++++++++++++++++++++++++++++++++++\n",
DeprecationWarning, stacklevel=2)
self._check_compiler()
exitcode, output = 255, ''
try:
grabber = GrabStdout()
try:
src, obj, exe = self._link(body, headers, include_dirs,
libraries, library_dirs, lang)
grabber.restore()
except Exception:
output = grabber.data
grabber.restore()
raise
exe = os.path.join('.', exe)
try:
# specify cwd arg for consistency with
# historic usage pattern of exec_command()
# also, note that exe appears to be a string,
# which exec_command() handled, but we now
# use a list for check_output() -- this assumes
# that exe is always a single command
output = subprocess.check_output([exe], cwd='.')
except subprocess.CalledProcessError as exc:
exitstatus = exc.returncode
output = ''
except OSError:
# preserve the EnvironmentError exit status
# used historically in exec_command()
exitstatus = 127
output = ''
else:
output = filepath_from_subprocess_output(output)
if hasattr(os, 'WEXITSTATUS'):
exitcode = os.WEXITSTATUS(exitstatus)
if os.WIFSIGNALED(exitstatus):
sig = os.WTERMSIG(exitstatus)
log.error('subprocess exited with signal %d' % (sig,))
if sig == signal.SIGINT:
# control-C
raise KeyboardInterrupt
else:
exitcode = exitstatus
log.info("success!")
except (CompileError, LinkError):
log.info("failure.")
self._clean()
return exitcode, output
class GrabStdout:
def __init__(self):
self.sys_stdout = sys.stdout
self.data = ''
sys.stdout = self
def write (self, data):
self.sys_stdout.write(data)
self.data += data
def flush (self):
self.sys_stdout.flush()
def restore(self):
sys.stdout = self.sys_stdout