cpython/Lib/importlib/_bootstrap.py

1795 lines
63 KiB
Python

"""Core implementation of import.
This module is NOT meant to be directly imported! It has been designed such
that it can be bootstrapped into Python as the implementation of import. As
such it requires the injection of specific modules and attributes in order to
work. One should use importlib as the public-facing version of this module.
"""
#
# IMPORTANT: Whenever making changes to this module, be sure to run
# a top-level make in order to get the frozen version of the module
# update. Not doing so, will result in the Makefile to fail for
# all others who don't have a ./python around to freeze the module
# in the early stages of compilation.
#
# See importlib._setup() for what is injected into the global namespace.
# When editing this code be aware that code executed at import time CANNOT
# reference any injected objects! This includes not only global code but also
# anything specified at the class level.
# XXX Make sure all public names have no single leading underscore and all
# others do.
# Bootstrap-related code ######################################################
_CASE_INSENSITIVE_PLATFORMS = 'win', 'cygwin', 'darwin'
def _make_relax_case():
if sys.platform.startswith(_CASE_INSENSITIVE_PLATFORMS):
def _relax_case():
"""True if filenames must be checked case-insensitively."""
return b'PYTHONCASEOK' in _os.environ
else:
def _relax_case():
"""True if filenames must be checked case-insensitively."""
return False
return _relax_case
# TODO: Expose from marshal
def _w_long(x):
"""Convert a 32-bit integer to little-endian.
XXX Temporary until marshal's long functions are exposed.
"""
return (int(x) & 0xFFFFFFFF).to_bytes(4, 'little')
# TODO: Expose from marshal
def _r_long(int_bytes):
"""Convert 4 bytes in little-endian to an integer.
XXX Temporary until marshal's long function are exposed.
"""
return int.from_bytes(int_bytes, 'little')
def _path_join(*path_parts):
"""Replacement for os.path.join()."""
return path_sep.join([part.rstrip(path_separators)
for part in path_parts if part])
def _path_split(path):
"""Replacement for os.path.split()."""
if len(path_separators) == 1:
front, _, tail = path.rpartition(path_sep)
return front, tail
for x in reversed(path):
if x in path_separators:
front, tail = path.rsplit(x, maxsplit=1)
return front, tail
return '', path
def _path_is_mode_type(path, mode):
"""Test whether the path is the specified mode type."""
try:
stat_info = _os.stat(path)
except OSError:
return False
return (stat_info.st_mode & 0o170000) == mode
# XXX Could also expose Modules/getpath.c:isfile()
def _path_isfile(path):
"""Replacement for os.path.isfile."""
return _path_is_mode_type(path, 0o100000)
# XXX Could also expose Modules/getpath.c:isdir()
def _path_isdir(path):
"""Replacement for os.path.isdir."""
if not path:
path = _os.getcwd()
return _path_is_mode_type(path, 0o040000)
def _write_atomic(path, data, mode=0o666):
"""Best-effort function to write data to a path atomically.
Be prepared to handle a FileExistsError if concurrent writing of the
temporary file is attempted."""
# id() is used to generate a pseudo-random filename.
path_tmp = '{}.{}'.format(path, id(path))
fd = _os.open(path_tmp,
_os.O_EXCL | _os.O_CREAT | _os.O_WRONLY, mode & 0o666)
try:
# We first write data to a temporary file, and then use os.replace() to
# perform an atomic rename.
with _io.FileIO(fd, 'wb') as file:
file.write(data)
_os.replace(path_tmp, path)
except OSError:
try:
_os.unlink(path_tmp)
except OSError:
pass
raise
def _wrap(new, old):
"""Simple substitute for functools.update_wrapper."""
for replace in ['__module__', '__name__', '__qualname__', '__doc__']:
if hasattr(old, replace):
setattr(new, replace, getattr(old, replace))
new.__dict__.update(old.__dict__)
_code_type = type(_wrap.__code__)
def new_module(name):
"""Create a new module.
The module is not entered into sys.modules.
"""
return type(_io)(name)
# Module-level locking ########################################################
# A dict mapping module names to weakrefs of _ModuleLock instances
_module_locks = {}
# A dict mapping thread ids to _ModuleLock instances
_blocking_on = {}
class _DeadlockError(RuntimeError):
pass
class _ModuleLock:
"""A recursive lock implementation which is able to detect deadlocks
(e.g. thread 1 trying to take locks A then B, and thread 2 trying to
take locks B then A).
"""
def __init__(self, name):
self.lock = _thread.allocate_lock()
self.wakeup = _thread.allocate_lock()
self.name = name
self.owner = None
self.count = 0
self.waiters = 0
def has_deadlock(self):
# Deadlock avoidance for concurrent circular imports.
me = _thread.get_ident()
tid = self.owner
while True:
lock = _blocking_on.get(tid)
if lock is None:
return False
tid = lock.owner
if tid == me:
return True
def acquire(self):
"""
Acquire the module lock. If a potential deadlock is detected,
a _DeadlockError is raised.
Otherwise, the lock is always acquired and True is returned.
"""
tid = _thread.get_ident()
_blocking_on[tid] = self
try:
while True:
with self.lock:
if self.count == 0 or self.owner == tid:
self.owner = tid
self.count += 1
return True
if self.has_deadlock():
raise _DeadlockError("deadlock detected by %r" % self)
if self.wakeup.acquire(False):
self.waiters += 1
# Wait for a release() call
self.wakeup.acquire()
self.wakeup.release()
finally:
del _blocking_on[tid]
def release(self):
tid = _thread.get_ident()
with self.lock:
if self.owner != tid:
raise RuntimeError("cannot release un-acquired lock")
assert self.count > 0
self.count -= 1
if self.count == 0:
self.owner = None
if self.waiters:
self.waiters -= 1
self.wakeup.release()
def __repr__(self):
return "_ModuleLock({!r}) at {}".format(self.name, id(self))
class _DummyModuleLock:
"""A simple _ModuleLock equivalent for Python builds without
multi-threading support."""
def __init__(self, name):
self.name = name
self.count = 0
def acquire(self):
self.count += 1
return True
def release(self):
if self.count == 0:
raise RuntimeError("cannot release un-acquired lock")
self.count -= 1
def __repr__(self):
return "_DummyModuleLock({!r}) at {}".format(self.name, id(self))
# The following two functions are for consumption by Python/import.c.
def _get_module_lock(name):
"""Get or create the module lock for a given module name.
Should only be called with the import lock taken."""
lock = None
try:
lock = _module_locks[name]()
except KeyError:
pass
if lock is None:
if _thread is None:
lock = _DummyModuleLock(name)
else:
lock = _ModuleLock(name)
def cb(_):
del _module_locks[name]
_module_locks[name] = _weakref.ref(lock, cb)
return lock
def _lock_unlock_module(name):
"""Release the global import lock, and acquires then release the
module lock for a given module name.
This is used to ensure a module is completely initialized, in the
event it is being imported by another thread.
Should only be called with the import lock taken."""
lock = _get_module_lock(name)
_imp.release_lock()
try:
lock.acquire()
except _DeadlockError:
# Concurrent circular import, we'll accept a partially initialized
# module object.
pass
else:
lock.release()
# Frame stripping magic ###############################################
def _call_with_frames_removed(f, *args, **kwds):
"""remove_importlib_frames in import.c will always remove sequences
of importlib frames that end with a call to this function
Use it instead of a normal call in places where including the importlib
frames introduces unwanted noise into the traceback (e.g. when executing
module code)
"""
return f(*args, **kwds)
# Finder/loader utility code ###############################################
# Magic word to reject .pyc files generated by other Python versions.
# It should change for each incompatible change to the bytecode.
#
# The value of CR and LF is incorporated so if you ever read or write
# a .pyc file in text mode the magic number will be wrong; also, the
# Apple MPW compiler swaps their values, botching string constants.
#
# The magic numbers must be spaced apart at least 2 values, as the
# -U interpeter flag will cause MAGIC+1 being used. They have been
# odd numbers for some time now.
#
# There were a variety of old schemes for setting the magic number.
# The current working scheme is to increment the previous value by
# 10.
#
# Starting with the adoption of PEP 3147 in Python 3.2, every bump in magic
# number also includes a new "magic tag", i.e. a human readable string used
# to represent the magic number in __pycache__ directories. When you change
# the magic number, you must also set a new unique magic tag. Generally this
# can be named after the Python major version of the magic number bump, but
# it can really be anything, as long as it's different than anything else
# that's come before. The tags are included in the following table, starting
# with Python 3.2a0.
#
# Known values:
# Python 1.5: 20121
# Python 1.5.1: 20121
# Python 1.5.2: 20121
# Python 1.6: 50428
# Python 2.0: 50823
# Python 2.0.1: 50823
# Python 2.1: 60202
# Python 2.1.1: 60202
# Python 2.1.2: 60202
# Python 2.2: 60717
# Python 2.3a0: 62011
# Python 2.3a0: 62021
# Python 2.3a0: 62011 (!)
# Python 2.4a0: 62041
# Python 2.4a3: 62051
# Python 2.4b1: 62061
# Python 2.5a0: 62071
# Python 2.5a0: 62081 (ast-branch)
# Python 2.5a0: 62091 (with)
# Python 2.5a0: 62092 (changed WITH_CLEANUP opcode)
# Python 2.5b3: 62101 (fix wrong code: for x, in ...)
# Python 2.5b3: 62111 (fix wrong code: x += yield)
# Python 2.5c1: 62121 (fix wrong lnotab with for loops and
# storing constants that should have been removed)
# Python 2.5c2: 62131 (fix wrong code: for x, in ... in listcomp/genexp)
# Python 2.6a0: 62151 (peephole optimizations and STORE_MAP opcode)
# Python 2.6a1: 62161 (WITH_CLEANUP optimization)
# Python 2.7a0: 62171 (optimize list comprehensions/change LIST_APPEND)
# Python 2.7a0: 62181 (optimize conditional branches:
# introduce POP_JUMP_IF_FALSE and POP_JUMP_IF_TRUE)
# Python 2.7a0 62191 (introduce SETUP_WITH)
# Python 2.7a0 62201 (introduce BUILD_SET)
# Python 2.7a0 62211 (introduce MAP_ADD and SET_ADD)
# Python 3000: 3000
# 3010 (removed UNARY_CONVERT)
# 3020 (added BUILD_SET)
# 3030 (added keyword-only parameters)
# 3040 (added signature annotations)
# 3050 (print becomes a function)
# 3060 (PEP 3115 metaclass syntax)
# 3061 (string literals become unicode)
# 3071 (PEP 3109 raise changes)
# 3081 (PEP 3137 make __file__ and __name__ unicode)
# 3091 (kill str8 interning)
# 3101 (merge from 2.6a0, see 62151)
# 3103 (__file__ points to source file)
# Python 3.0a4: 3111 (WITH_CLEANUP optimization).
# Python 3.0a5: 3131 (lexical exception stacking, including POP_EXCEPT)
# Python 3.1a0: 3141 (optimize list, set and dict comprehensions:
# change LIST_APPEND and SET_ADD, add MAP_ADD)
# Python 3.1a0: 3151 (optimize conditional branches:
# introduce POP_JUMP_IF_FALSE and POP_JUMP_IF_TRUE)
# Python 3.2a0: 3160 (add SETUP_WITH)
# tag: cpython-32
# Python 3.2a1: 3170 (add DUP_TOP_TWO, remove DUP_TOPX and ROT_FOUR)
# tag: cpython-32
# Python 3.2a2 3180 (add DELETE_DEREF)
# Python 3.3a0 3190 __class__ super closure changed
# Python 3.3a0 3200 (__qualname__ added)
# 3210 (added size modulo 2**32 to the pyc header)
# Python 3.3a1 3220 (changed PEP 380 implementation)
# Python 3.3a4 3230 (revert changes to implicit __class__ closure)
# Python 3.4a1 3250 (evaluate positional default arguments before
# keyword-only defaults)
# Python 3.4a1 3260 (add LOAD_CLASSDEREF; allow locals of class to override
# free vars)
#
# MAGIC must change whenever the bytecode emitted by the compiler may no
# longer be understood by older implementations of the eval loop (usually
# due to the addition of new opcodes).
_MAGIC_BYTES = (3260).to_bytes(2, 'little') + b'\r\n'
_RAW_MAGIC_NUMBER = int.from_bytes(_MAGIC_BYTES, 'little')
_PYCACHE = '__pycache__'
SOURCE_SUFFIXES = ['.py'] # _setup() adds .pyw as needed.
DEBUG_BYTECODE_SUFFIXES = ['.pyc']
OPTIMIZED_BYTECODE_SUFFIXES = ['.pyo']
def cache_from_source(path, debug_override=None):
"""Given the path to a .py file, return the path to its .pyc/.pyo file.
The .py file does not need to exist; this simply returns the path to the
.pyc/.pyo file calculated as if the .py file were imported. The extension
will be .pyc unless sys.flags.optimize is non-zero, then it will be .pyo.
If debug_override is not None, then it must be a boolean and is used in
place of sys.flags.optimize.
If sys.implementation.cache_tag is None then NotImplementedError is raised.
"""
debug = not sys.flags.optimize if debug_override is None else debug_override
if debug:
suffixes = DEBUG_BYTECODE_SUFFIXES
else:
suffixes = OPTIMIZED_BYTECODE_SUFFIXES
head, tail = _path_split(path)
base_filename, sep, _ = tail.partition('.')
tag = sys.implementation.cache_tag
if tag is None:
raise NotImplementedError('sys.implementation.cache_tag is None')
filename = ''.join([base_filename, sep, tag, suffixes[0]])
return _path_join(head, _PYCACHE, filename)
def source_from_cache(path):
"""Given the path to a .pyc./.pyo file, return the path to its .py file.
The .pyc/.pyo file does not need to exist; this simply returns the path to
the .py file calculated to correspond to the .pyc/.pyo file. If path does
not conform to PEP 3147 format, ValueError will be raised. If
sys.implementation.cache_tag is None then NotImplementedError is raised.
"""
if sys.implementation.cache_tag is None:
raise NotImplementedError('sys.implementation.cache_tag is None')
head, pycache_filename = _path_split(path)
head, pycache = _path_split(head)
if pycache != _PYCACHE:
raise ValueError('{} not bottom-level directory in '
'{!r}'.format(_PYCACHE, path))
if pycache_filename.count('.') != 2:
raise ValueError('expected only 2 dots in '
'{!r}'.format(pycache_filename))
base_filename = pycache_filename.partition('.')[0]
return _path_join(head, base_filename + SOURCE_SUFFIXES[0])
def _get_sourcefile(bytecode_path):
"""Convert a bytecode file path to a source path (if possible).
This function exists purely for backwards-compatibility for
PyImport_ExecCodeModuleWithFilenames() in the C API.
"""
if len(bytecode_path) == 0:
return None
rest, _, extension = bytecode_path.rparition('.')
if not rest or extension.lower()[-3:-1] != '.py':
return bytecode_path
try:
source_path = source_from_cache(bytecode_path)
except (NotImplementedError, ValueError):
source_path = bytcode_path[-1:]
return source_path if _path_isfile(source_stats) else bytecode_path
def _calc_mode(path):
"""Calculate the mode permissions for a bytecode file."""
try:
mode = _os.stat(path).st_mode
except OSError:
mode = 0o666
# We always ensure write access so we can update cached files
# later even when the source files are read-only on Windows (#6074)
mode |= 0o200
return mode
def _verbose_message(message, *args, verbosity=1):
"""Print the message to stderr if -v/PYTHONVERBOSE is turned on."""
if sys.flags.verbose >= verbosity:
if not message.startswith(('#', 'import ')):
message = '# ' + message
print(message.format(*args), file=sys.stderr)
def set_package(fxn):
"""Set __package__ on the returned module."""
def set_package_wrapper(*args, **kwargs):
module = fxn(*args, **kwargs)
if getattr(module, '__package__', None) is None:
module.__package__ = module.__name__
if not hasattr(module, '__path__'):
module.__package__ = module.__package__.rpartition('.')[0]
return module
_wrap(set_package_wrapper, fxn)
return set_package_wrapper
def set_loader(fxn):
"""Set __loader__ on the returned module."""
def set_loader_wrapper(self, *args, **kwargs):
module = fxn(self, *args, **kwargs)
if getattr(module, '__loader__', None) is None:
module.__loader__ = self
return module
_wrap(set_loader_wrapper, fxn)
return set_loader_wrapper
def module_for_loader(fxn):
"""Decorator to handle selecting the proper module for loaders.
The decorated function is passed the module to use instead of the module
name. The module passed in to the function is either from sys.modules if
it already exists or is a new module. If the module is new, then __name__
is set the first argument to the method, __loader__ is set to self, and
__package__ is set accordingly (if self.is_package() is defined) will be set
before it is passed to the decorated function (if self.is_package() does
not work for the module it will be set post-load).
If an exception is raised and the decorator created the module it is
subsequently removed from sys.modules.
The decorator assumes that the decorated function takes the module name as
the second argument.
"""
def module_for_loader_wrapper(self, fullname, *args, **kwargs):
module = sys.modules.get(fullname)
is_reload = module is not None
if not is_reload:
# This must be done before open() is called as the 'io' module
# implicitly imports 'locale' and would otherwise trigger an
# infinite loop.
module = new_module(fullname)
# This must be done before putting the module in sys.modules
# (otherwise an optimization shortcut in import.c becomes wrong)
module.__initializing__ = True
sys.modules[fullname] = module
module.__loader__ = self
try:
is_package = self.is_package(fullname)
except (ImportError, AttributeError):
pass
else:
if is_package:
module.__package__ = fullname
else:
module.__package__ = fullname.rpartition('.')[0]
else:
module.__initializing__ = True
try:
# If __package__ was not set above, __import__() will do it later.
return fxn(self, module, *args, **kwargs)
except:
if not is_reload:
del sys.modules[fullname]
raise
finally:
module.__initializing__ = False
_wrap(module_for_loader_wrapper, fxn)
return module_for_loader_wrapper
def _check_name(method):
"""Decorator to verify that the module being requested matches the one the
loader can handle.
The first argument (self) must define _name which the second argument is
compared against. If the comparison fails then ImportError is raised.
"""
def _check_name_wrapper(self, name=None, *args, **kwargs):
if name is None:
name = self.name
elif self.name != name:
raise ImportError("loader cannot handle %s" % name, name=name)
return method(self, name, *args, **kwargs)
_wrap(_check_name_wrapper, method)
return _check_name_wrapper
def _requires_builtin(fxn):
"""Decorator to verify the named module is built-in."""
def _requires_builtin_wrapper(self, fullname):
if fullname not in sys.builtin_module_names:
raise ImportError("{} is not a built-in module".format(fullname),
name=fullname)
return fxn(self, fullname)
_wrap(_requires_builtin_wrapper, fxn)
return _requires_builtin_wrapper
def _requires_frozen(fxn):
"""Decorator to verify the named module is frozen."""
def _requires_frozen_wrapper(self, fullname):
if not _imp.is_frozen(fullname):
raise ImportError("{} is not a frozen module".format(fullname),
name=fullname)
return fxn(self, fullname)
_wrap(_requires_frozen_wrapper, fxn)
return _requires_frozen_wrapper
def _find_module_shim(self, fullname):
"""Try to find a loader for the specified module by delegating to
self.find_loader()."""
# Call find_loader(). If it returns a string (indicating this
# is a namespace package portion), generate a warning and
# return None.
loader, portions = self.find_loader(fullname)
if loader is None and len(portions):
msg = "Not importing directory {}: missing __init__"
_warnings.warn(msg.format(portions[0]), ImportWarning)
return loader
def _validate_bytecode_header(data, source_stats=None, name=None, path=None):
"""Validate the header of the passed-in bytecode against source_stats (if
given) and returning the bytecode that can be compiled by compile().
All other arguments are used to enhance error reporting.
ImportError is raised when the magic number is incorrect or the bytecode is
found to be stale. EOFError is raised when the data is found to be
truncated.
"""
exc_details = {}
if name is not None:
exc_details['name'] = name
else:
# To prevent having to make all messages have a conditional name.
name = '<bytecode>'
if path is not None:
exc_details['path'] = path
magic = data[:4]
raw_timestamp = data[4:8]
raw_size = data[8:12]
if magic != _MAGIC_BYTES:
message = 'bad magic number in {!r}: {!r}'.format(name, magic)
_verbose_message(message)
raise ImportError(message, **exc_details)
elif len(raw_timestamp) != 4:
message = 'incomplete timestamp in {!r}'.format(name)
_verbose_message(message)
raise EOFError(message)
elif len(raw_size) != 4:
message = 'incomplete size in {!r}'.format(name)
_verbose_message(message)
raise EOFError(message)
if source_stats is not None:
try:
source_mtime = int(source_stats['mtime'])
except KeyError:
pass
else:
if _r_long(raw_timestamp) != source_mtime:
message = 'bytecode is stale for {!r}'.format(name)
_verbose_message(message)
raise ImportError(message, **exc_details)
try:
source_size = source_stats['size'] & 0xFFFFFFFF
except KeyError:
pass
else:
if _r_long(raw_size) != source_size:
raise ImportError("bytecode is stale for {!r}".format(name),
**exc_details)
return data[12:]
def _compile_bytecode(data, name=None, bytecode_path=None, source_path=None):
"""Compile bytecode as returned by _validate_bytecode_header()."""
code = marshal.loads(data)
if isinstance(code, _code_type):
_verbose_message('code object from {!r}', bytecode_path)
if source_path is not None:
_imp._fix_co_filename(code, source_path)
return code
else:
raise ImportError("Non-code object in {!r}".format(bytecode_path),
name=name, path=bytecode_path)
def _code_to_bytecode(code, mtime=0, source_size=0):
"""Compile a code object into bytecode for writing out to a byte-compiled
file."""
data = bytearray(_MAGIC_BYTES)
data.extend(_w_long(mtime))
data.extend(_w_long(source_size))
data.extend(marshal.dumps(code))
return data
# Loaders #####################################################################
class BuiltinImporter:
"""Meta path import for built-in modules.
All methods are either class or static methods to avoid the need to
instantiate the class.
"""
@classmethod
def module_repr(cls, module):
return "<module '{}' (built-in)>".format(module.__name__)
@classmethod
def find_module(cls, fullname, path=None):
"""Find the built-in module.
If 'path' is ever specified then the search is considered a failure.
"""
if path is not None:
return None
return cls if _imp.is_builtin(fullname) else None
@classmethod
@set_package
@set_loader
@_requires_builtin
def load_module(cls, fullname):
"""Load a built-in module."""
is_reload = fullname in sys.modules
try:
return _call_with_frames_removed(_imp.init_builtin, fullname)
except:
if not is_reload and fullname in sys.modules:
del sys.modules[fullname]
raise
@classmethod
@_requires_builtin
def get_code(cls, fullname):
"""Return None as built-in modules do not have code objects."""
return None
@classmethod
@_requires_builtin
def get_source(cls, fullname):
"""Return None as built-in modules do not have source code."""
return None
@classmethod
@_requires_builtin
def is_package(cls, fullname):
"""Return False as built-in modules are never packages."""
return False
class FrozenImporter:
"""Meta path import for frozen modules.
All methods are either class or static methods to avoid the need to
instantiate the class.
"""
@classmethod
def module_repr(cls, m):
return "<module '{}' (frozen)>".format(m.__name__)
@classmethod
def find_module(cls, fullname, path=None):
"""Find a frozen module."""
return cls if _imp.is_frozen(fullname) else None
@classmethod
@set_package
@set_loader
@_requires_frozen
def load_module(cls, fullname):
"""Load a frozen module."""
is_reload = fullname in sys.modules
try:
m = _call_with_frames_removed(_imp.init_frozen, fullname)
# Let our own module_repr() method produce a suitable repr.
del m.__file__
return m
except:
if not is_reload and fullname in sys.modules:
del sys.modules[fullname]
raise
@classmethod
@_requires_frozen
def get_code(cls, fullname):
"""Return the code object for the frozen module."""
return _imp.get_frozen_object(fullname)
@classmethod
@_requires_frozen
def get_source(cls, fullname):
"""Return None as frozen modules do not have source code."""
return None
@classmethod
@_requires_frozen
def is_package(cls, fullname):
"""Return True if the frozen module is a package."""
return _imp.is_frozen_package(fullname)
class WindowsRegistryFinder:
"""Meta path finder for modules declared in the Windows registry.
"""
REGISTRY_KEY = (
"Software\\Python\\PythonCore\\{sys_version}"
"\\Modules\\{fullname}")
REGISTRY_KEY_DEBUG = (
"Software\\Python\\PythonCore\\{sys_version}"
"\\Modules\\{fullname}\\Debug")
DEBUG_BUILD = False # Changed in _setup()
@classmethod
def _open_registry(cls, key):
try:
return _winreg.OpenKey(_winreg.HKEY_CURRENT_USER, key)
except OSError:
return _winreg.OpenKey(_winreg.HKEY_LOCAL_MACHINE, key)
@classmethod
def _search_registry(cls, fullname):
if cls.DEBUG_BUILD:
registry_key = cls.REGISTRY_KEY_DEBUG
else:
registry_key = cls.REGISTRY_KEY
key = registry_key.format(fullname=fullname,
sys_version=sys.version[:3])
try:
with cls._open_registry(key) as hkey:
filepath = _winreg.QueryValue(hkey, "")
except OSError:
return None
return filepath
@classmethod
def find_module(cls, fullname, path=None):
"""Find module named in the registry."""
filepath = cls._search_registry(fullname)
if filepath is None:
return None
try:
_os.stat(filepath)
except OSError:
return None
for loader, suffixes, _ in _get_supported_file_loaders():
if filepath.endswith(tuple(suffixes)):
return loader(fullname, filepath)
class _LoaderBasics:
"""Base class of common code needed by both SourceLoader and
SourcelessFileLoader."""
def is_package(self, fullname):
"""Concrete implementation of InspectLoader.is_package by checking if
the path returned by get_filename has a filename of '__init__.py'."""
filename = _path_split(self.get_filename(fullname))[1]
filename_base = filename.rsplit('.', 1)[0]
tail_name = fullname.rpartition('.')[2]
return filename_base == '__init__' and tail_name != '__init__'
@module_for_loader
def _load_module(self, module, *, sourceless=False):
"""Helper for load_module able to handle either source or sourceless
loading."""
name = module.__name__
code_object = self.get_code(name)
module.__file__ = self.get_filename(name)
if not sourceless:
try:
module.__cached__ = cache_from_source(module.__file__)
except NotImplementedError:
module.__cached__ = module.__file__
else:
module.__cached__ = module.__file__
if self.is_package(name):
module.__path__ = [_path_split(module.__file__)[0]]
# __package__ and __loader set by @module_for_loader.
_call_with_frames_removed(exec, code_object, module.__dict__)
return module
class SourceLoader(_LoaderBasics):
def path_mtime(self, path):
"""Optional method that returns the modification time (an int) for the
specified path, where path is a str.
Raises IOError when the path cannot be handled.
"""
raise IOError
def path_stats(self, path):
"""Optional method returning a metadata dict for the specified path
to by the path (str).
Possible keys:
- 'mtime' (mandatory) is the numeric timestamp of last source
code modification;
- 'size' (optional) is the size in bytes of the source code.
Implementing this method allows the loader to read bytecode files.
Raises IOError when the path cannot be handled.
"""
return {'mtime': self.path_mtime(path)}
def _cache_bytecode(self, source_path, cache_path, data):
"""Optional method which writes data (bytes) to a file path (a str).
Implementing this method allows for the writing of bytecode files.
The source path is needed in order to correctly transfer permissions
"""
# For backwards compatibility, we delegate to set_data()
return self.set_data(cache_path, data)
def set_data(self, path, data):
"""Optional method which writes data (bytes) to a file path (a str).
Implementing this method allows for the writing of bytecode files.
"""
def get_source(self, fullname):
"""Concrete implementation of InspectLoader.get_source."""
import tokenize
path = self.get_filename(fullname)
try:
source_bytes = self.get_data(path)
except OSError as exc:
raise ImportError("source not available through get_data()",
name=fullname) from exc
readsource = _io.BytesIO(source_bytes).readline
try:
encoding = tokenize.detect_encoding(readsource)
except SyntaxError as exc:
raise ImportError("Failed to detect encoding",
name=fullname) from exc
newline_decoder = _io.IncrementalNewlineDecoder(None, True)
try:
return newline_decoder.decode(source_bytes.decode(encoding[0]))
except UnicodeDecodeError as exc:
raise ImportError("Failed to decode source file",
name=fullname) from exc
def source_to_code(self, data, path, *, _optimize=-1):
"""Return the code object compiled from source.
The 'data' argument can be any object type that compile() supports.
"""
return _call_with_frames_removed(compile, data, path, 'exec',
dont_inherit=True, optimize=_optimize)
def get_code(self, fullname):
"""Concrete implementation of InspectLoader.get_code.
Reading of bytecode requires path_stats to be implemented. To write
bytecode, set_data must also be implemented.
"""
source_path = self.get_filename(fullname)
source_mtime = None
try:
bytecode_path = cache_from_source(source_path)
except NotImplementedError:
bytecode_path = None
else:
try:
st = self.path_stats(source_path)
except IOError:
pass
else:
source_mtime = int(st['mtime'])
try:
data = self.get_data(bytecode_path)
except OSError:
pass
else:
try:
bytes_data = _validate_bytecode_header(data,
source_stats=st, name=fullname,
path=bytecode_path)
except (ImportError, EOFError):
pass
else:
_verbose_message('{} matches {}', bytecode_path,
source_path)
return _compile_bytecode(bytes_data, name=fullname,
bytecode_path=bytecode_path,
source_path=source_path)
source_bytes = self.get_data(source_path)
code_object = self.source_to_code(source_bytes, source_path)
_verbose_message('code object from {}', source_path)
if (not sys.dont_write_bytecode and bytecode_path is not None and
source_mtime is not None):
data = _code_to_bytecode(code_object, source_mtime,
len(source_bytes))
try:
self._cache_bytecode(source_path, bytecode_path, data)
_verbose_message('wrote {!r}', bytecode_path)
except NotImplementedError:
pass
return code_object
def load_module(self, fullname):
"""Concrete implementation of Loader.load_module.
Requires ExecutionLoader.get_filename and ResourceLoader.get_data to be
implemented to load source code. Use of bytecode is dictated by whether
get_code uses/writes bytecode.
"""
return self._load_module(fullname)
class FileLoader:
"""Base file loader class which implements the loader protocol methods that
require file system usage."""
def __init__(self, fullname, path):
"""Cache the module name and the path to the file found by the
finder."""
self.name = fullname
self.path = path
@_check_name
def load_module(self, fullname):
"""Load a module from a file."""
# Issue #14857: Avoid the zero-argument form so the implementation
# of that form can be updated without breaking the frozen module
return super(FileLoader, self).load_module(fullname)
@_check_name
def get_filename(self, fullname):
"""Return the path to the source file as found by the finder."""
return self.path
def get_data(self, path):
"""Return the data from path as raw bytes."""
with _io.FileIO(path, 'r') as file:
return file.read()
class SourceFileLoader(FileLoader, SourceLoader):
"""Concrete implementation of SourceLoader using the file system."""
def path_stats(self, path):
"""Return the metadata for the path."""
st = _os.stat(path)
return {'mtime': st.st_mtime, 'size': st.st_size}
def _cache_bytecode(self, source_path, bytecode_path, data):
# Adapt between the two APIs
mode = _calc_mode(source_path)
return self.set_data(bytecode_path, data, _mode=mode)
def set_data(self, path, data, *, _mode=0o666):
"""Write bytes data to a file."""
parent, filename = _path_split(path)
path_parts = []
# Figure out what directories are missing.
while parent and not _path_isdir(parent):
parent, part = _path_split(parent)
path_parts.append(part)
# Create needed directories.
for part in reversed(path_parts):
parent = _path_join(parent, part)
try:
_os.mkdir(parent)
except FileExistsError:
# Probably another Python process already created the dir.
continue
except OSError as exc:
# Could be a permission error, read-only filesystem: just forget
# about writing the data.
_verbose_message('could not create {!r}: {!r}', parent, exc)
return
try:
_write_atomic(path, data, _mode)
_verbose_message('created {!r}', path)
except OSError as exc:
# Same as above: just don't write the bytecode.
_verbose_message('could not create {!r}: {!r}', path, exc)
class SourcelessFileLoader(FileLoader, _LoaderBasics):
"""Loader which handles sourceless file imports."""
def load_module(self, fullname):
return self._load_module(fullname, sourceless=True)
def get_code(self, fullname):
path = self.get_filename(fullname)
data = self.get_data(path)
bytes_data = _validate_bytecode_header(data, name=fullname, path=path)
return _compile_bytecode(bytes_data, name=fullname, bytecode_path=path)
def get_source(self, fullname):
"""Return None as there is no source code."""
return None
# Filled in by _setup().
EXTENSION_SUFFIXES = []
class ExtensionFileLoader:
"""Loader for extension modules.
The constructor is designed to work with FileFinder.
"""
def __init__(self, name, path):
self.name = name
self.path = path
@_check_name
@set_package
@set_loader
def load_module(self, fullname):
"""Load an extension module."""
is_reload = fullname in sys.modules
try:
module = _call_with_frames_removed(_imp.load_dynamic,
fullname, self.path)
_verbose_message('extension module loaded from {!r}', self.path)
if self.is_package(fullname) and not hasattr(module, '__path__'):
module.__path__ = [_path_split(self.path)[0]]
return module
except:
if not is_reload and fullname in sys.modules:
del sys.modules[fullname]
raise
def is_package(self, fullname):
"""Return True if the extension module is a package."""
file_name = _path_split(self.path)[1]
return any(file_name == '__init__' + suffix
for suffix in EXTENSION_SUFFIXES)
def get_code(self, fullname):
"""Return None as an extension module cannot create a code object."""
return None
def get_source(self, fullname):
"""Return None as extension modules have no source code."""
return None
class _NamespacePath:
"""Represents a namespace package's path. It uses the module name
to find its parent module, and from there it looks up the parent's
__path__. When this changes, the module's own path is recomputed,
using path_finder. For top-level modules, the parent module's path
is sys.path."""
def __init__(self, name, path, path_finder):
self._name = name
self._path = path
self._last_parent_path = tuple(self._get_parent_path())
self._path_finder = path_finder
def _find_parent_path_names(self):
"""Returns a tuple of (parent-module-name, parent-path-attr-name)"""
parent, dot, me = self._name.rpartition('.')
if dot == '':
# This is a top-level module. sys.path contains the parent path.
return 'sys', 'path'
# Not a top-level module. parent-module.__path__ contains the
# parent path.
return parent, '__path__'
def _get_parent_path(self):
parent_module_name, path_attr_name = self._find_parent_path_names()
return getattr(sys.modules[parent_module_name], path_attr_name)
def _recalculate(self):
# If the parent's path has changed, recalculate _path
parent_path = tuple(self._get_parent_path()) # Make a copy
if parent_path != self._last_parent_path:
loader, new_path = self._path_finder(self._name, parent_path)
# Note that no changes are made if a loader is returned, but we
# do remember the new parent path
if loader is None:
self._path = new_path
self._last_parent_path = parent_path # Save the copy
return self._path
def __iter__(self):
return iter(self._recalculate())
def __len__(self):
return len(self._recalculate())
def __repr__(self):
return "_NamespacePath({!r})".format(self._path)
def __contains__(self, item):
return item in self._recalculate()
def append(self, item):
self._path.append(item)
class NamespaceLoader:
def __init__(self, name, path, path_finder):
self._path = _NamespacePath(name, path, path_finder)
@classmethod
def module_repr(cls, module):
return "<module '{}' (namespace)>".format(module.__name__)
@module_for_loader
def load_module(self, module):
"""Load a namespace module."""
_verbose_message('namespace module loaded with path {!r}', self._path)
module.__path__ = self._path
return module
# Finders #####################################################################
class PathFinder:
"""Meta path finder for sys.path and package __path__ attributes."""
@classmethod
def invalidate_caches(cls):
"""Call the invalidate_caches() method on all path entry finders
stored in sys.path_importer_caches (where implemented)."""
for finder in sys.path_importer_cache.values():
if hasattr(finder, 'invalidate_caches'):
finder.invalidate_caches()
@classmethod
def _path_hooks(cls, path):
"""Search sequence of hooks for a finder for 'path'.
If 'hooks' is false then use sys.path_hooks.
"""
if not sys.path_hooks:
_warnings.warn('sys.path_hooks is empty', ImportWarning)
for hook in sys.path_hooks:
try:
return hook(path)
except ImportError:
continue
else:
return None
@classmethod
def _path_importer_cache(cls, path):
"""Get the finder for the path entry from sys.path_importer_cache.
If the path entry is not in the cache, find the appropriate finder
and cache it. If no finder is available, store None.
"""
if path == '':
path = '.'
try:
finder = sys.path_importer_cache[path]
except KeyError:
finder = cls._path_hooks(path)
sys.path_importer_cache[path] = finder
return finder
@classmethod
def _get_loader(cls, fullname, path):
"""Find the loader or namespace_path for this module/package name."""
# If this ends up being a namespace package, namespace_path is
# the list of paths that will become its __path__
namespace_path = []
for entry in path:
if not isinstance(entry, (str, bytes)):
continue
finder = cls._path_importer_cache(entry)
if finder is not None:
if hasattr(finder, 'find_loader'):
loader, portions = finder.find_loader(fullname)
else:
loader = finder.find_module(fullname)
portions = []
if loader is not None:
# We found a loader: return it immediately.
return loader, namespace_path
# This is possibly part of a namespace package.
# Remember these path entries (if any) for when we
# create a namespace package, and continue iterating
# on path.
namespace_path.extend(portions)
else:
return None, namespace_path
@classmethod
def find_module(cls, fullname, path=None):
"""Find the module on sys.path or 'path' based on sys.path_hooks and
sys.path_importer_cache."""
if path is None:
path = sys.path
loader, namespace_path = cls._get_loader(fullname, path)
if loader is not None:
return loader
else:
if namespace_path:
# We found at least one namespace path. Return a
# loader which can create the namespace package.
return NamespaceLoader(fullname, namespace_path, cls._get_loader)
else:
return None
class FileFinder:
"""File-based finder.
Interactions with the file system are cached for performance, being
refreshed when the directory the finder is handling has been modified.
"""
def __init__(self, path, *details):
"""Initialize with the path to search on and a variable number of
2-tuples containing the loader and the file suffixes the loader
recognizes."""
loaders = []
for loader, suffixes in details:
loaders.extend((suffix, loader) for suffix in suffixes)
self._loaders = loaders
# Base (directory) path
self.path = path or '.'
self._path_mtime = -1
self._path_cache = set()
self._relaxed_path_cache = set()
def invalidate_caches(self):
"""Invalidate the directory mtime."""
self._path_mtime = -1
find_module = _find_module_shim
def find_loader(self, fullname):
"""Try to find a loader for the specified module, or the namespace
package portions. Returns (loader, list-of-portions)."""
is_namespace = False
tail_module = fullname.rpartition('.')[2]
try:
mtime = _os.stat(self.path).st_mtime
except OSError:
mtime = -1
if mtime != self._path_mtime:
self._fill_cache()
self._path_mtime = mtime
# tail_module keeps the original casing, for __file__ and friends
if _relax_case():
cache = self._relaxed_path_cache
cache_module = tail_module.lower()
else:
cache = self._path_cache
cache_module = tail_module
# Check if the module is the name of a directory (and thus a package).
if cache_module in cache:
base_path = _path_join(self.path, tail_module)
if _path_isdir(base_path):
for suffix, loader in self._loaders:
init_filename = '__init__' + suffix
full_path = _path_join(base_path, init_filename)
if _path_isfile(full_path):
return (loader(fullname, full_path), [base_path])
else:
# A namespace package, return the path if we don't also
# find a module in the next section.
is_namespace = True
# Check for a file w/ a proper suffix exists.
for suffix, loader in self._loaders:
full_path = _path_join(self.path, tail_module + suffix)
_verbose_message('trying {}'.format(full_path), verbosity=2)
if cache_module + suffix in cache:
if _path_isfile(full_path):
return (loader(fullname, full_path), [])
if is_namespace:
_verbose_message('possible namespace for {}'.format(base_path))
return (None, [base_path])
return (None, [])
def _fill_cache(self):
"""Fill the cache of potential modules and packages for this directory."""
path = self.path
try:
contents = _os.listdir(path)
except (FileNotFoundError, PermissionError, NotADirectoryError):
# Directory has either been removed, turned into a file, or made
# unreadable.
contents = []
# We store two cached versions, to handle runtime changes of the
# PYTHONCASEOK environment variable.
if not sys.platform.startswith('win'):
self._path_cache = set(contents)
else:
# Windows users can import modules with case-insensitive file
# suffixes (for legacy reasons). Make the suffix lowercase here
# so it's done once instead of for every import. This is safe as
# the specified suffixes to check against are always specified in a
# case-sensitive manner.
lower_suffix_contents = set()
for item in contents:
name, dot, suffix = item.partition('.')
if dot:
new_name = '{}.{}'.format(name, suffix.lower())
else:
new_name = name
lower_suffix_contents.add(new_name)
self._path_cache = lower_suffix_contents
if sys.platform.startswith(_CASE_INSENSITIVE_PLATFORMS):
self._relaxed_path_cache = {fn.lower() for fn in contents}
@classmethod
def path_hook(cls, *loader_details):
"""A class method which returns a closure to use on sys.path_hook
which will return an instance using the specified loaders and the path
called on the closure.
If the path called on the closure is not a directory, ImportError is
raised.
"""
def path_hook_for_FileFinder(path):
"""Path hook for importlib.machinery.FileFinder."""
if not _path_isdir(path):
raise ImportError("only directories are supported", path=path)
return cls(path, *loader_details)
return path_hook_for_FileFinder
def __repr__(self):
return "FileFinder({!r})".format(self.path)
# Import itself ###############################################################
class _ImportLockContext:
"""Context manager for the import lock."""
def __enter__(self):
"""Acquire the import lock."""
_imp.acquire_lock()
def __exit__(self, exc_type, exc_value, exc_traceback):
"""Release the import lock regardless of any raised exceptions."""
_imp.release_lock()
def _resolve_name(name, package, level):
"""Resolve a relative module name to an absolute one."""
bits = package.rsplit('.', level - 1)
if len(bits) < level:
raise ValueError('attempted relative import beyond top-level package')
base = bits[0]
return '{}.{}'.format(base, name) if name else base
def _find_module(name, path):
"""Find a module's loader."""
if not sys.meta_path:
_warnings.warn('sys.meta_path is empty', ImportWarning)
for finder in sys.meta_path:
with _ImportLockContext():
loader = finder.find_module(name, path)
if loader is not None:
# The parent import may have already imported this module.
if name not in sys.modules:
return loader
else:
return sys.modules[name].__loader__
else:
return None
def _sanity_check(name, package, level):
"""Verify arguments are "sane"."""
if not isinstance(name, str):
raise TypeError("module name must be str, not {}".format(type(name)))
if level < 0:
raise ValueError('level must be >= 0')
if package:
if not isinstance(package, str):
raise TypeError("__package__ not set to a string")
elif package not in sys.modules:
msg = ("Parent module {!r} not loaded, cannot perform relative "
"import")
raise SystemError(msg.format(package))
if not name and level == 0:
raise ValueError("Empty module name")
_ERR_MSG = 'No module named {!r}'
def _find_and_load_unlocked(name, import_):
path = None
parent = name.rpartition('.')[0]
if parent:
if parent not in sys.modules:
_call_with_frames_removed(import_, parent)
# Crazy side-effects!
if name in sys.modules:
return sys.modules[name]
# Backwards-compatibility; be nicer to skip the dict lookup.
parent_module = sys.modules[parent]
try:
path = parent_module.__path__
except AttributeError:
msg = (_ERR_MSG + '; {} is not a package').format(name, parent)
raise ImportError(msg, name=name)
loader = _find_module(name, path)
if loader is None:
exc = ImportError(_ERR_MSG.format(name), name=name)
# TODO(brett): switch to a proper ModuleNotFound exception in Python
# 3.4.
exc._not_found = True
raise exc
elif name not in sys.modules:
# The parent import may have already imported this module.
loader.load_module(name)
_verbose_message('import {!r} # {!r}', name, loader)
# Backwards-compatibility; be nicer to skip the dict lookup.
module = sys.modules[name]
if parent:
# Set the module as an attribute on its parent.
parent_module = sys.modules[parent]
setattr(parent_module, name.rpartition('.')[2], module)
# Set __package__ if the loader did not.
if getattr(module, '__package__', None) is None:
try:
module.__package__ = module.__name__
if not hasattr(module, '__path__'):
module.__package__ = module.__package__.rpartition('.')[0]
except AttributeError:
pass
# Set loader if need be.
if getattr(module, '__loader__', None) is None:
try:
module.__loader__ = loader
except AttributeError:
pass
return module
def _find_and_load(name, import_):
"""Find and load the module, and release the import lock."""
try:
lock = _get_module_lock(name)
finally:
_imp.release_lock()
lock.acquire()
try:
return _find_and_load_unlocked(name, import_)
finally:
lock.release()
def _gcd_import(name, package=None, level=0):
"""Import and return the module based on its name, the package the call is
being made from, and the level adjustment.
This function represents the greatest common denominator of functionality
between import_module and __import__. This includes setting __package__ if
the loader did not.
"""
_sanity_check(name, package, level)
if level > 0:
name = _resolve_name(name, package, level)
_imp.acquire_lock()
if name not in sys.modules:
return _find_and_load(name, _gcd_import)
module = sys.modules[name]
if module is None:
_imp.release_lock()
message = ("import of {} halted; "
"None in sys.modules".format(name))
raise ImportError(message, name=name)
_lock_unlock_module(name)
return module
def _handle_fromlist(module, fromlist, import_):
"""Figure out what __import__ should return.
The import_ parameter is a callable which takes the name of module to
import. It is required to decouple the function from assuming importlib's
import implementation is desired.
"""
# The hell that is fromlist ...
# If a package was imported, try to import stuff from fromlist.
if hasattr(module, '__path__'):
if '*' in fromlist:
fromlist = list(fromlist)
fromlist.remove('*')
if hasattr(module, '__all__'):
fromlist.extend(module.__all__)
for x in fromlist:
if not hasattr(module, x):
from_name = '{}.{}'.format(module.__name__, x)
try:
_call_with_frames_removed(import_, from_name)
except ImportError as exc:
# Backwards-compatibility dictates we ignore failed
# imports triggered by fromlist for modules that don't
# exist.
# TODO(brett): In Python 3.4, have import raise
# ModuleNotFound and catch that.
if getattr(exc, '_not_found', False):
if exc.name == from_name:
continue
raise
return module
def _calc___package__(globals):
"""Calculate what __package__ should be.
__package__ is not guaranteed to be defined or could be set to None
to represent that its proper value is unknown.
"""
package = globals.get('__package__')
if package is None:
package = globals['__name__']
if '__path__' not in globals:
package = package.rpartition('.')[0]
return package
def _get_supported_file_loaders():
"""Returns a list of file-based module loaders.
Each item is a tuple (loader, suffixes, allow_packages).
"""
extensions = ExtensionFileLoader, _imp.extension_suffixes()
source = SourceFileLoader, SOURCE_SUFFIXES
bytecode = SourcelessFileLoader, BYTECODE_SUFFIXES
return [extensions, source, bytecode]
def __import__(name, globals=None, locals=None, fromlist=(), level=0):
"""Import a module.
The 'globals' argument is used to infer where the import is occuring from
to handle relative imports. The 'locals' argument is ignored. The
'fromlist' argument specifies what should exist as attributes on the module
being imported (e.g. ``from module import <fromlist>``). The 'level'
argument represents the package location to import from in a relative
import (e.g. ``from ..pkg import mod`` would have a 'level' of 2).
"""
if level == 0:
module = _gcd_import(name)
else:
globals_ = globals if globals is not None else {}
package = _calc___package__(globals_)
module = _gcd_import(name, package, level)
if not fromlist:
# Return up to the first dot in 'name'. This is complicated by the fact
# that 'name' may be relative.
if level == 0:
return _gcd_import(name.partition('.')[0])
elif not name:
return module
else:
# Figure out where to slice the module's name up to the first dot
# in 'name'.
cut_off = len(name) - len(name.partition('.')[0])
# Slice end needs to be positive to alleviate need to special-case
# when ``'.' not in name``.
return sys.modules[module.__name__[:len(module.__name__)-cut_off]]
else:
return _handle_fromlist(module, fromlist, _gcd_import)
def _setup(sys_module, _imp_module):
"""Setup importlib by importing needed built-in modules and injecting them
into the global namespace.
As sys is needed for sys.modules access and _imp is needed to load built-in
modules, those two modules must be explicitly passed in.
"""
global _imp, sys, BYTECODE_SUFFIXES
_imp = _imp_module
sys = sys_module
if sys.flags.optimize:
BYTECODE_SUFFIXES = OPTIMIZED_BYTECODE_SUFFIXES
else:
BYTECODE_SUFFIXES = DEBUG_BYTECODE_SUFFIXES
module_type = type(sys)
for name, module in sys.modules.items():
if isinstance(module, module_type):
if getattr(module, '__loader__', None) is None:
if name in sys.builtin_module_names:
module.__loader__ = BuiltinImporter
elif _imp.is_frozen(name):
module.__loader__ = FrozenImporter
self_module = sys.modules[__name__]
for builtin_name in ('_io', '_warnings', 'builtins', 'marshal'):
if builtin_name not in sys.modules:
builtin_module = BuiltinImporter.load_module(builtin_name)
else:
builtin_module = sys.modules[builtin_name]
setattr(self_module, builtin_name, builtin_module)
os_details = ('posix', ['/']), ('nt', ['\\', '/'])
for builtin_os, path_separators in os_details:
# Assumption made in _path_join()
assert all(len(sep) == 1 for sep in path_separators)
path_sep = path_separators[0]
if builtin_os in sys.modules:
os_module = sys.modules[builtin_os]
break
else:
try:
os_module = BuiltinImporter.load_module(builtin_os)
break
except ImportError:
continue
else:
raise ImportError('importlib requires posix or nt')
try:
thread_module = BuiltinImporter.load_module('_thread')
except ImportError:
# Python was built without threads
thread_module = None
weakref_module = BuiltinImporter.load_module('_weakref')
if builtin_os == 'nt':
winreg_module = BuiltinImporter.load_module('winreg')
setattr(self_module, '_winreg', winreg_module)
setattr(self_module, '_os', os_module)
setattr(self_module, '_thread', thread_module)
setattr(self_module, '_weakref', weakref_module)
setattr(self_module, 'path_sep', path_sep)
setattr(self_module, 'path_separators', ''.join(path_separators))
# Constants
setattr(self_module, '_relax_case', _make_relax_case())
EXTENSION_SUFFIXES.extend(_imp.extension_suffixes())
if builtin_os == 'nt':
SOURCE_SUFFIXES.append('.pyw')
if '_d.pyd' in EXTENSION_SUFFIXES:
WindowsRegistryFinder.DEBUG_BUILD = True
def _install(sys_module, _imp_module):
"""Install importlib as the implementation of import."""
_setup(sys_module, _imp_module)
supported_loaders = _get_supported_file_loaders()
sys.path_hooks.extend([FileFinder.path_hook(*supported_loaders)])
sys.meta_path.append(BuiltinImporter)
sys.meta_path.append(FrozenImporter)
if _os.__name__ == 'nt':
sys.meta_path.append(WindowsRegistryFinder)
sys.meta_path.append(PathFinder)