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Jython is an implementation of the high-level, dynamic, object-oriented
language Python written in 100% Pure Java, and seamlessly integrated with
the Java platform. It thus allows you to run Python on any Java platform.
"""runpy.py - locating and running Python code using the module namespace
Provides support for locating and running Python scripts using the Python
module namespace instead of the native filesystem.
This allows Python code to play nicely with non-filesystem based PEP 302
importers when locating support scripts as well as when importing modules.
"""
# Written by Nick Coghlan
# to implement PEP 338 (Executing Modules as Scripts)
import sys
import imp
from pkgutil import read_code
try:
from imp import get_loader
except ImportError:
from pkgutil import get_loader
__all__ = [
"run_module", "run_path",
]
class _TempModule(object):
"""Temporarily replace a module in sys.modules with an empty namespace"""
def __init__(self, mod_name):
self.mod_name = mod_name
self.module = imp.new_module(mod_name)
self._saved_module = []
def __enter__(self):
mod_name = self.mod_name
try:
self._saved_module.append(sys.modules[mod_name])
except KeyError:
pass
sys.modules[mod_name] = self.module
return self
def __exit__(self, *args):
if self._saved_module:
sys.modules[self.mod_name] = self._saved_module[0]
else:
del sys.modules[self.mod_name]
self._saved_module = []
class _ModifiedArgv0(object):
def __init__(self, value):
self.value = value
self._saved_value = self._sentinel = object()
def __enter__(self):
if self._saved_value is not self._sentinel:
raise RuntimeError("Already preserving saved value")
self._saved_value = sys.argv[0]
sys.argv[0] = self.value
def __exit__(self, *args):
self.value = self._sentinel
sys.argv[0] = self._saved_value
def _run_code(code, run_globals, init_globals=None,
mod_name=None, mod_fname=None,
mod_loader=None, pkg_name=None):
"""Helper to run code in nominated namespace"""
if init_globals is not None:
run_globals.update(init_globals)
run_globals.update(__name__ = mod_name,
__file__ = mod_fname,
__loader__ = mod_loader,
__package__ = pkg_name)
exec code in run_globals
return run_globals
def _run_module_code(code, init_globals=None,
mod_name=None, mod_fname=None,
mod_loader=None, pkg_name=None):
"""Helper to run code in new namespace with sys modified"""
with _TempModule(mod_name) as temp_module, _ModifiedArgv0(mod_fname):
mod_globals = temp_module.module.__dict__
_run_code(code, mod_globals, init_globals,
mod_name, mod_fname, mod_loader, pkg_name)
# Copy the globals of the temporary module, as they
# may be cleared when the temporary module goes away
return mod_globals.copy()
# This helper is needed due to a missing component in the PEP 302
# loader protocol (specifically, "get_filename" is non-standard)
# Since we can't introduce new features in maintenance releases,
# support was added to zipimporter under the name '_get_filename'
def _get_filename(loader, mod_name):
for attr in ("get_filename", "_get_filename"):
meth = getattr(loader, attr, None)
if meth is not None:
return meth(mod_name)
return None
# Helper to get the loader, code and filename for a module
def _get_module_details(mod_name):
loader = get_loader(mod_name)
if loader is None:
raise ImportError("No module named %s" % mod_name)
if loader.is_package(mod_name):
if mod_name == "__main__" or mod_name.endswith(".__main__"):
raise ImportError("Cannot use package as __main__ module")
try:
pkg_main_name = mod_name + ".__main__"
return _get_module_details(pkg_main_name)
except ImportError, e:
raise ImportError(("%s; %r is a package and cannot " +
"be directly executed") %(e, mod_name))
code = loader.get_code(mod_name)
if code is None:
raise ImportError("No code object available for %s" % mod_name)
filename = _get_filename(loader, mod_name)
return mod_name, loader, code, filename
def _get_main_module_details():
# Helper that gives a nicer error message when attempting to
# execute a zipfile or directory by invoking __main__.py
main_name = "__main__"
try:
return _get_module_details(main_name)
except ImportError as exc:
if main_name in str(exc):
raise ImportError("can't find %r module in %r" %
(main_name, sys.path[0]))
raise
# This function is the actual implementation of the -m switch and direct
# execution of zipfiles and directories and is deliberately kept private.
# This avoids a repeat of the situation where run_module() no longer met the
# needs of mainmodule.c, but couldn't be changed because it was public
def _run_module_as_main(mod_name, alter_argv=True):
"""Runs the designated module in the __main__ namespace
Note that the executed module will have full access to the
__main__ namespace. If this is not desirable, the run_module()
function should be used to run the module code in a fresh namespace.
At the very least, these variables in __main__ will be overwritten:
__name__
__file__
__loader__
__package__
"""
try:
if alter_argv or mod_name != "__main__": # i.e. -m switch
mod_name, loader, code, fname = _get_module_details(mod_name)
else: # i.e. directory or zipfile execution
mod_name, loader, code, fname = _get_main_module_details()
except ImportError as exc:
msg = "%s: %s" % (sys.executable, str(exc))
sys.exit(msg)
pkg_name = mod_name.rpartition('.')[0]
main_globals = sys.modules["__main__"].__dict__
if alter_argv:
sys.argv[0] = fname
return _run_code(code, main_globals, None,
"__main__", fname, loader, pkg_name)
def run_module(mod_name, init_globals=None,
run_name=None, alter_sys=False):
"""Execute a module's code without importing it
Returns the resulting top level namespace dictionary
"""
mod_name, loader, code, fname = _get_module_details(mod_name)
if run_name is None:
run_name = mod_name
pkg_name = mod_name.rpartition('.')[0]
if alter_sys:
return _run_module_code(code, init_globals, run_name,
fname, loader, pkg_name)
else:
# Leave the sys module alone
return _run_code(code, {}, init_globals, run_name,
fname, loader, pkg_name)
# XXX (ncoghlan): Perhaps expose the C API function
# as imp.get_importer instead of reimplementing it in Python?
def _get_importer(path_name):
"""Python version of PyImport_GetImporter C API function"""
cache = sys.path_importer_cache
try:
importer = cache[path_name]
except KeyError:
# Not yet cached. Flag as using the
# standard machinery until we finish
# checking the hooks
cache[path_name] = None
for hook in sys.path_hooks:
try:
importer = hook(path_name)
break
except ImportError:
pass
else:
# The following check looks a bit odd. The trick is that
# NullImporter raises ImportError if the supplied path is a
# *valid* directory entry (and hence able to be handled
# by the standard import machinery)
try:
importer = imp.NullImporter(path_name)
except ImportError:
return None
cache[path_name] = importer
return importer
def _get_code_from_file(fname):
# Check for a compiled file first
with open(fname, "rb") as f:
code = read_code(f)
if code is None:
# That didn't work, so try it as normal source code
with open(fname, "rU") as f:
code = compile(f.read(), fname, 'exec')
return code
def run_path(path_name, init_globals=None, run_name=None):
"""Execute code located at the specified filesystem location
Returns the resulting top level namespace dictionary
The file path may refer directly to a Python script (i.e.
one that could be directly executed with execfile) or else
it may refer to a zipfile or directory containing a top
level __main__.py script.
"""
if run_name is None:
run_name = ""
importer = _get_importer(path_name)
if isinstance(importer, imp.NullImporter):
# Not a valid sys.path entry, so run the code directly
# execfile() doesn't help as we want to allow compiled files
code = _get_code_from_file(path_name)
return _run_module_code(code, init_globals, run_name, path_name)
else:
# Importer is defined for path, so add it to
# the start of sys.path
sys.path.insert(0, path_name)
try:
# Here's where things are a little different from the run_module
# case. There, we only had to replace the module in sys while the
# code was running and doing so was somewhat optional. Here, we
# have no choice and we have to remove it even while we read the
# code. If we don't do this, a __loader__ attribute in the
# existing __main__ module may prevent location of the new module.
main_name = "__main__"
saved_main = sys.modules[main_name]
del sys.modules[main_name]
try:
mod_name, loader, code, fname = _get_main_module_details()
finally:
sys.modules[main_name] = saved_main
pkg_name = ""
with _TempModule(run_name) as temp_module, \
_ModifiedArgv0(path_name):
mod_globals = temp_module.module.__dict__
return _run_code(code, mod_globals, init_globals,
run_name, fname, loader, pkg_name).copy()
finally:
try:
sys.path.remove(path_name)
except ValueError:
pass
if __name__ == "__main__":
# Run the module specified as the next command line argument
if len(sys.argv) < 2:
print >> sys.stderr, "No module specified for execution"
else:
del sys.argv[0] # Make the requested module sys.argv[0]
_run_module_as_main(sys.argv[0])