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gflags.py
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gflags.py
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#!/usr/bin/env python
#
# Copyright (c) 2002, Google Inc.
# All rights reserved.
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions are
# met:
#
# * Redistributions of source code must retain the above copyright
# notice, this list of conditions and the following disclaimer.
# * Redistributions in binary form must reproduce the above
# copyright notice, this list of conditions and the following disclaimer
# in the documentation and/or other materials provided with the
# distribution.
# * Neither the name of Google Inc. nor the names of its
# contributors may be used to endorse or promote products derived from
# this software without specific prior written permission.
#
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
# LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
# A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
# OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
# SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
# LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
# THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#
# ---
# Author: Chad Lester
# Design and style contributions by:
# Amit Patel, Bogdan Cocosel, Daniel Dulitz, Eric Tiedemann,
# Eric Veach, Laurence Gonsalves, Matthew Springer
# Code reorganized a bit by Craig Silverstein
"""This module is used to define and parse command line flags.
This module defines a *distributed* flag-definition policy: rather than
an application having to define all flags in or near main(), each python
module defines flags that are useful to it. When one python module
imports another, it gains access to the other's flags. (This is
implemented by having all modules share a common, global registry object
containing all the flag information.)
Flags are defined through the use of one of the DEFINE_xxx functions.
The specific function used determines how the flag is parsed, checked,
and optionally type-converted, when it's seen on the command line.
IMPLEMENTATION: DEFINE_* creates a 'Flag' object and registers it with a
'FlagValues' object (typically the global FlagValues FLAGS, defined
here). The 'FlagValues' object can scan the command line arguments and
pass flag arguments to the corresponding 'Flag' objects for
value-checking and type conversion. The converted flag values are
available as attributes of the 'FlagValues' object.
Code can access the flag through a FlagValues object, for instance
gflags.FLAGS.myflag. Typically, the __main__ module passes the command
line arguments to gflags.FLAGS for parsing.
At bottom, this module calls getopt(), so getopt functionality is
supported, including short- and long-style flags, and the use of -- to
terminate flags.
Methods defined by the flag module will throw 'FlagsError' exceptions.
The exception argument will be a human-readable string.
FLAG TYPES: This is a list of the DEFINE_*'s that you can do. All flags
take a name, default value, help-string, and optional 'short' name
(one-letter name). Some flags have other arguments, which are described
with the flag.
DEFINE_string: takes any input, and interprets it as a string.
DEFINE_bool or
DEFINE_boolean: typically does not take an argument: say --myflag to
set FLAGS.myflag to true, or --nomyflag to set
FLAGS.myflag to false. Alternately, you can say
--myflag=true or --myflag=t or --myflag=1 or
--myflag=false or --myflag=f or --myflag=0
DEFINE_float: takes an input and interprets it as a floating point
number. Takes optional args lower_bound and upper_bound;
if the number specified on the command line is out of
range, it will raise a FlagError.
DEFINE_integer: takes an input and interprets it as an integer. Takes
optional args lower_bound and upper_bound as for floats.
DEFINE_enum: takes a list of strings which represents legal values. If
the command-line value is not in this list, raise a flag
error. Otherwise, assign to FLAGS.flag as a string.
DEFINE_list: Takes a comma-separated list of strings on the commandline.
Stores them in a python list object.
DEFINE_spaceseplist: Takes a space-separated list of strings on the
commandline. Stores them in a python list object.
Example: --myspacesepflag "foo bar baz"
DEFINE_multistring: The same as DEFINE_string, except the flag can be
specified more than once on the commandline. The
result is a python list object (list of strings),
even if the flag is only on the command line once.
DEFINE_multi_int: The same as DEFINE_integer, except the flag can be
specified more than once on the commandline. The
result is a python list object (list of ints), even if
the flag is only on the command line once.
SPECIAL FLAGS: There are a few flags that have special meaning:
--help prints a list of all the flags in a human-readable fashion
--helpshort prints a list of all key flags (see below).
--helpxml prints a list of all flags, in XML format. DO NOT parse
the output of --help and --helpshort. Instead, parse
the output of --helpxml. For more info, see
"OUTPUT FOR --helpxml" below.
--flagfile=foo read flags from file foo.
--undefok=f1,f2 ignore unrecognized option errors for f1,f2.
For boolean flags, you should use --undefok=boolflag, and
--boolflag and --noboolflag will be accepted. Do not use
--undefok=noboolflag.
-- as in getopt(), terminates flag-processing
FLAGS VALIDATORS: If your program:
- requires flag X to be specified
- needs flag Y to match a regular expression
- or requires any more general constraint to be satisfied
then validators are for you!
Each validator represents a constraint over one flag, which is enforced
starting from the initial parsing of the flags and until the program
terminates.
Also, lower_bound and upper_bound for numerical flags are enforced using flag
validators.
Howto:
If you want to enforce a constraint over one flag, use
gflags.RegisterValidator(flag_name,
checker,
message='Flag validation failed',
flag_values=FLAGS)
After flag values are initially parsed, and after any change to the specified
flag, method checker(flag_value) will be executed. If constraint is not
satisfied, an IllegalFlagValue exception will be raised. See
RegisterValidator's docstring for a detailed explanation on how to construct
your own checker.
EXAMPLE USAGE:
FLAGS = gflags.FLAGS
gflags.DEFINE_integer('my_version', 0, 'Version number.')
gflags.DEFINE_string('filename', None, 'Input file name', short_name='f')
gflags.RegisterValidator('my_version',
lambda value: value % 2 == 0,
message='--my_version must be divisible by 2')
gflags.MarkFlagAsRequired('filename')
NOTE ON --flagfile:
Flags may be loaded from text files in addition to being specified on
the commandline.
Any flags you don't feel like typing, throw them in a file, one flag per
line, for instance:
--myflag=myvalue
--nomyboolean_flag
You then specify your file with the special flag '--flagfile=somefile'.
You CAN recursively nest flagfile= tokens OR use multiple files on the
command line. Lines beginning with a single hash '#' or a double slash
'//' are comments in your flagfile.
Any flagfile=<file> will be interpreted as having a relative path from
the current working directory rather than from the place the file was
included from:
myPythonScript.py --flagfile=config/somefile.cfg
If somefile.cfg includes further --flagfile= directives, these will be
referenced relative to the original CWD, not from the directory the
including flagfile was found in!
The caveat applies to people who are including a series of nested files
in a different dir than they are executing out of. Relative path names
are always from CWD, not from the directory of the parent include
flagfile. We do now support '~' expanded directory names.
Absolute path names ALWAYS work!
EXAMPLE USAGE:
FLAGS = gflags.FLAGS
# Flag names are globally defined! So in general, we need to be
# careful to pick names that are unlikely to be used by other libraries.
# If there is a conflict, we'll get an error at import time.
gflags.DEFINE_string('name', 'Mr. President', 'your name')
gflags.DEFINE_integer('age', None, 'your age in years', lower_bound=0)
gflags.DEFINE_boolean('debug', False, 'produces debugging output')
gflags.DEFINE_enum('gender', 'male', ['male', 'female'], 'your gender')
def main(argv):
try:
argv = FLAGS(argv) # parse flags
except gflags.FlagsError, e:
print '%s\\nUsage: %s ARGS\\n%s' % (e, sys.argv[0], FLAGS)
sys.exit(1)
if FLAGS.debug: print 'non-flag arguments:', argv
print 'Happy Birthday', FLAGS.name
if FLAGS.age is not None:
print 'You are a %d year old %s' % (FLAGS.age, FLAGS.gender)
if __name__ == '__main__':
main(sys.argv)
KEY FLAGS:
As we already explained, each module gains access to all flags defined
by all the other modules it transitively imports. In the case of
non-trivial scripts, this means a lot of flags ... For documentation
purposes, it is good to identify the flags that are key (i.e., really
important) to a module. Clearly, the concept of "key flag" is a
subjective one. When trying to determine whether a flag is key to a
module or not, assume that you are trying to explain your module to a
potential user: which flags would you really like to mention first?
We'll describe shortly how to declare which flags are key to a module.
For the moment, assume we know the set of key flags for each module.
Then, if you use the app.py module, you can use the --helpshort flag to
print only the help for the flags that are key to the main module, in a
human-readable format.
NOTE: If you need to parse the flag help, do NOT use the output of
--help / --helpshort. That output is meant for human consumption, and
may be changed in the future. Instead, use --helpxml; flags that are
key for the main module are marked there with a <key>yes</key> element.
The set of key flags for a module M is composed of:
1. Flags defined by module M by calling a DEFINE_* function.
2. Flags that module M explictly declares as key by using the function
DECLARE_key_flag(<flag_name>)
3. Key flags of other modules that M specifies by using the function
ADOPT_module_key_flags(<other_module>)
This is a "bulk" declaration of key flags: each flag that is key for
<other_module> becomes key for the current module too.
Notice that if you do not use the functions described at points 2 and 3
above, then --helpshort prints information only about the flags defined
by the main module of our script. In many cases, this behavior is good
enough. But if you move part of the main module code (together with the
related flags) into a different module, then it is nice to use
DECLARE_key_flag / ADOPT_module_key_flags and make sure --helpshort
lists all relevant flags (otherwise, your code refactoring may confuse
your users).
Note: each of DECLARE_key_flag / ADOPT_module_key_flags has its own
pluses and minuses: DECLARE_key_flag is more targeted and may lead a
more focused --helpshort documentation. ADOPT_module_key_flags is good
for cases when an entire module is considered key to the current script.
Also, it does not require updates to client scripts when a new flag is
added to the module.
EXAMPLE USAGE 2 (WITH KEY FLAGS):
Consider an application that contains the following three files (two
auxiliary modules and a main module)
File libfoo.py:
import gflags
gflags.DEFINE_integer('num_replicas', 3, 'Number of replicas to start')
gflags.DEFINE_boolean('rpc2', True, 'Turn on the usage of RPC2.')
... some code ...
File libbar.py:
import gflags
gflags.DEFINE_string('bar_gfs_path', '/gfs/path',
'Path to the GFS files for libbar.')
gflags.DEFINE_string('email_for_bar_errors', '[email protected]',
'Email address for bug reports about module libbar.')
gflags.DEFINE_boolean('bar_risky_hack', False,
'Turn on an experimental and buggy optimization.')
... some code ...
File myscript.py:
import gflags
import libfoo
import libbar
gflags.DEFINE_integer('num_iterations', 0, 'Number of iterations.')
# Declare that all flags that are key for libfoo are
# key for this module too.
gflags.ADOPT_module_key_flags(libfoo)
# Declare that the flag --bar_gfs_path (defined in libbar) is key
# for this module.
gflags.DECLARE_key_flag('bar_gfs_path')
... some code ...
When myscript is invoked with the flag --helpshort, the resulted help
message lists information about all the key flags for myscript:
--num_iterations, --num_replicas, --rpc2, and --bar_gfs_path.
Of course, myscript uses all the flags declared by it (in this case,
just --num_replicas) or by any of the modules it transitively imports
(e.g., the modules libfoo, libbar). E.g., it can access the value of
FLAGS.bar_risky_hack, even if --bar_risky_hack is not declared as a key
flag for myscript.
OUTPUT FOR --helpxml:
The --helpxml flag generates output with the following structure:
<?xml version="1.0"?>
<AllFlags>
<program>PROGRAM_BASENAME</program>
<usage>MAIN_MODULE_DOCSTRING</usage>
(<flag>
[<key>yes</key>]
<file>DECLARING_MODULE</file>
<name>FLAG_NAME</name>
<meaning>FLAG_HELP_MESSAGE</meaning>
<default>DEFAULT_FLAG_VALUE</default>
<current>CURRENT_FLAG_VALUE</current>
<type>FLAG_TYPE</type>
[OPTIONAL_ELEMENTS]
</flag>)*
</AllFlags>
Notes:
1. The output is intentionally similar to the output generated by the
C++ command-line flag library. The few differences are due to the
Python flags that do not have a C++ equivalent (at least not yet),
e.g., DEFINE_list.
2. New XML elements may be added in the future.
3. DEFAULT_FLAG_VALUE is in serialized form, i.e., the string you can
pass for this flag on the command-line. E.g., for a flag defined
using DEFINE_list, this field may be foo,bar, not ['foo', 'bar'].
4. CURRENT_FLAG_VALUE is produced using str(). This means that the
string 'false' will be represented in the same way as the boolean
False. Using repr() would have removed this ambiguity and simplified
parsing, but would have broken the compatibility with the C++
command-line flags.
5. OPTIONAL_ELEMENTS describe elements relevant for certain kinds of
flags: lower_bound, upper_bound (for flags that specify bounds),
enum_value (for enum flags), list_separator (for flags that consist of
a list of values, separated by a special token).
6. We do not provide any example here: please use --helpxml instead.
This module requires at least python 2.2.1 to run.
"""
import cgi
import getopt
import os
import re
import string
import struct
import sys
# pylint: disable-msg=C6204
try:
import fcntl
except ImportError:
fcntl = None
try:
# Importing termios will fail on non-unix platforms.
import termios
except ImportError:
termios = None
import gflags_validators
# pylint: enable-msg=C6204
# Are we running under pychecker?
_RUNNING_PYCHECKER = 'pychecker.python' in sys.modules
def _GetCallingModuleObjectAndName():
"""Returns the module that's calling into this module.
We generally use this function to get the name of the module calling a
DEFINE_foo... function.
"""
# Walk down the stack to find the first globals dict that's not ours.
for depth in range(1, sys.getrecursionlimit()):
if not sys._getframe(depth).f_globals is globals():
globals_for_frame = sys._getframe(depth).f_globals
module, module_name = _GetModuleObjectAndName(globals_for_frame)
if module_name is not None:
return module, module_name
raise AssertionError("No module was found")
def _GetCallingModule():
"""Returns the name of the module that's calling into this module."""
return _GetCallingModuleObjectAndName()[1]
def _GetThisModuleObjectAndName():
"""Returns: (module object, module name) for this module."""
return _GetModuleObjectAndName(globals())
# module exceptions:
class FlagsError(Exception):
"""The base class for all flags errors."""
pass
class DuplicateFlag(FlagsError):
"""Raised if there is a flag naming conflict."""
pass
class CantOpenFlagFileError(FlagsError):
"""Raised if flagfile fails to open: doesn't exist, wrong permissions, etc."""
pass
class DuplicateFlagCannotPropagateNoneToSwig(DuplicateFlag):
"""Special case of DuplicateFlag -- SWIG flag value can't be set to None.
This can be raised when a duplicate flag is created. Even if allow_override is
True, we still abort if the new value is None, because it's currently
impossible to pass None default value back to SWIG. See FlagValues.SetDefault
for details.
"""
pass
class DuplicateFlagError(DuplicateFlag):
"""A DuplicateFlag whose message cites the conflicting definitions.
A DuplicateFlagError conveys more information than a DuplicateFlag,
namely the modules where the conflicting definitions occur. This
class was created to avoid breaking external modules which depend on
the existing DuplicateFlags interface.
"""
def __init__(self, flagname, flag_values, other_flag_values=None):
"""Create a DuplicateFlagError.
Args:
flagname: Name of the flag being redefined.
flag_values: FlagValues object containing the first definition of
flagname.
other_flag_values: If this argument is not None, it should be the
FlagValues object where the second definition of flagname occurs.
If it is None, we assume that we're being called when attempting
to create the flag a second time, and we use the module calling
this one as the source of the second definition.
"""
self.flagname = flagname
first_module = flag_values.FindModuleDefiningFlag(
flagname, default='<unknown>')
if other_flag_values is None:
second_module = _GetCallingModule()
else:
second_module = other_flag_values.FindModuleDefiningFlag(
flagname, default='<unknown>')
msg = "The flag '%s' is defined twice. First from %s, Second from %s" % (
self.flagname, first_module, second_module)
DuplicateFlag.__init__(self, msg)
class IllegalFlagValue(FlagsError):
"""The flag command line argument is illegal."""
pass
class UnrecognizedFlag(FlagsError):
"""Raised if a flag is unrecognized."""
pass
# An UnrecognizedFlagError conveys more information than an UnrecognizedFlag.
# Since there are external modules that create DuplicateFlags, the interface to
# DuplicateFlag shouldn't change. The flagvalue will be assigned the full value
# of the flag and its argument, if any, allowing handling of unrecognized flags
# in an exception handler.
# If flagvalue is the empty string, then this exception is an due to a
# reference to a flag that was not already defined.
class UnrecognizedFlagError(UnrecognizedFlag):
def __init__(self, flagname, flagvalue=''):
self.flagname = flagname
self.flagvalue = flagvalue
UnrecognizedFlag.__init__(
self, "Unknown command line flag '%s'" % flagname)
# Global variable used by expvar
_exported_flags = {}
_help_width = 80 # width of help output
def GetHelpWidth():
"""Returns: an integer, the width of help lines that is used in TextWrap."""
if (not sys.stdout.isatty()) or (termios is None) or (fcntl is None):
return _help_width
try:
data = fcntl.ioctl(sys.stdout, termios.TIOCGWINSZ, '1234')
columns = struct.unpack('hh', data)[1]
# Emacs mode returns 0.
# Here we assume that any value below 40 is unreasonable
if columns >= 40:
return columns
# Returning an int as default is fine, int(int) just return the int.
return int(os.getenv('COLUMNS', _help_width))
except (TypeError, IOError, struct.error):
return _help_width
def CutCommonSpacePrefix(text):
"""Removes a common space prefix from the lines of a multiline text.
If the first line does not start with a space, it is left as it is and
only in the remaining lines a common space prefix is being searched
for. That means the first line will stay untouched. This is especially
useful to turn doc strings into help texts. This is because some
people prefer to have the doc comment start already after the
apostrophe and then align the following lines while others have the
apostrophes on a separate line.
The function also drops trailing empty lines and ignores empty lines
following the initial content line while calculating the initial
common whitespace.
Args:
text: text to work on
Returns:
the resulting text
"""
text_lines = text.splitlines()
# Drop trailing empty lines
while text_lines and not text_lines[-1]:
text_lines = text_lines[:-1]
if text_lines:
# We got some content, is the first line starting with a space?
if text_lines[0] and text_lines[0][0].isspace():
text_first_line = []
else:
text_first_line = [text_lines.pop(0)]
# Calculate length of common leading whitespace (only over content lines)
common_prefix = os.path.commonprefix([line for line in text_lines if line])
space_prefix_len = len(common_prefix) - len(common_prefix.lstrip())
# If we have a common space prefix, drop it from all lines
if space_prefix_len:
for index in xrange(len(text_lines)):
if text_lines[index]:
text_lines[index] = text_lines[index][space_prefix_len:]
return '\n'.join(text_first_line + text_lines)
return ''
def TextWrap(text, length=None, indent='', firstline_indent=None, tabs=' '):
"""Wraps a given text to a maximum line length and returns it.
We turn lines that only contain whitespace into empty lines. We keep
new lines and tabs (e.g., we do not treat tabs as spaces).
Args:
text: text to wrap
length: maximum length of a line, includes indentation
if this is None then use GetHelpWidth()
indent: indent for all but first line
firstline_indent: indent for first line; if None, fall back to indent
tabs: replacement for tabs
Returns:
wrapped text
Raises:
FlagsError: if indent not shorter than length
FlagsError: if firstline_indent not shorter than length
"""
# Get defaults where callee used None
if length is None:
length = GetHelpWidth()
if indent is None:
indent = ''
if len(indent) >= length:
raise FlagsError('Indent must be shorter than length')
# In line we will be holding the current line which is to be started
# with indent (or firstline_indent if available) and then appended
# with words.
if firstline_indent is None:
firstline_indent = ''
line = indent
else:
line = firstline_indent
if len(firstline_indent) >= length:
raise FlagsError('First line indent must be shorter than length')
# If the callee does not care about tabs we simply convert them to
# spaces If callee wanted tabs to be single space then we do that
# already here.
if not tabs or tabs == ' ':
text = text.replace('\t', ' ')
else:
tabs_are_whitespace = not tabs.strip()
line_regex = re.compile('([ ]*)(\t*)([^ \t]+)', re.MULTILINE)
# Split the text into lines and the lines with the regex above. The
# resulting lines are collected in result[]. For each split we get the
# spaces, the tabs and the next non white space (e.g. next word).
result = []
for text_line in text.splitlines():
# Store result length so we can find out whether processing the next
# line gave any new content
old_result_len = len(result)
# Process next line with line_regex. For optimization we do an rstrip().
# - process tabs (changes either line or word, see below)
# - process word (first try to squeeze on line, then wrap or force wrap)
# Spaces found on the line are ignored, they get added while wrapping as
# needed.
for spaces, current_tabs, word in line_regex.findall(text_line.rstrip()):
# If tabs weren't converted to spaces, handle them now
if current_tabs:
# If the last thing we added was a space anyway then drop
# it. But let's not get rid of the indentation.
if (((result and line != indent) or
(not result and line != firstline_indent)) and line[-1] == ' '):
line = line[:-1]
# Add the tabs, if that means adding whitespace, just add it at
# the line, the rstrip() code while shorten the line down if
# necessary
if tabs_are_whitespace:
line += tabs * len(current_tabs)
else:
# if not all tab replacement is whitespace we prepend it to the word
word = tabs * len(current_tabs) + word
# Handle the case where word cannot be squeezed onto current last line
if len(line) + len(word) > length and len(indent) + len(word) <= length:
result.append(line.rstrip())
line = indent + word
word = ''
# No space left on line or can we append a space?
if len(line) + 1 >= length:
result.append(line.rstrip())
line = indent
else:
line += ' '
# Add word and shorten it up to allowed line length. Restart next
# line with indent and repeat, or add a space if we're done (word
# finished) This deals with words that cannot fit on one line
# (e.g. indent + word longer than allowed line length).
while len(line) + len(word) >= length:
line += word
result.append(line[:length])
word = line[length:]
line = indent
# Default case, simply append the word and a space
if word:
line += word + ' '
# End of input line. If we have content we finish the line. If the
# current line is just the indent but we had content in during this
# original line then we need to add an empty line.
if (result and line != indent) or (not result and line != firstline_indent):
result.append(line.rstrip())
elif len(result) == old_result_len:
result.append('')
line = indent
return '\n'.join(result)
def DocToHelp(doc):
"""Takes a __doc__ string and reformats it as help."""
# Get rid of starting and ending white space. Using lstrip() or even
# strip() could drop more than maximum of first line and right space
# of last line.
doc = doc.strip()
# Get rid of all empty lines
whitespace_only_line = re.compile('^[ \t]+$', re.M)
doc = whitespace_only_line.sub('', doc)
# Cut out common space at line beginnings
doc = CutCommonSpacePrefix(doc)
# Just like this module's comment, comments tend to be aligned somehow.
# In other words they all start with the same amount of white space
# 1) keep double new lines
# 2) keep ws after new lines if not empty line
# 3) all other new lines shall be changed to a space
# Solution: Match new lines between non white space and replace with space.
doc = re.sub('(?<=\S)\n(?=\S)', ' ', doc, re.M)
return doc
def _GetModuleObjectAndName(globals_dict):
"""Returns the module that defines a global environment, and its name.
Args:
globals_dict: A dictionary that should correspond to an environment
providing the values of the globals.
Returns:
A pair consisting of (1) module object and (2) module name (a
string). Returns (None, None) if the module could not be
identified.
"""
# The use of .items() (instead of .iteritems()) is NOT a mistake: if
# a parallel thread imports a module while we iterate over
# .iteritems() (not nice, but possible), we get a RuntimeError ...
# Hence, we use the slightly slower but safer .items().
for name, module in sys.modules.items():
if getattr(module, '__dict__', None) is globals_dict:
if name == '__main__':
# Pick a more informative name for the main module.
name = sys.argv[0]
return (module, name)
return (None, None)
def _GetMainModule():
"""Returns: string, name of the module from which execution started."""
# First, try to use the same logic used by _GetCallingModuleObjectAndName(),
# i.e., call _GetModuleObjectAndName(). For that we first need to
# find the dictionary that the main module uses to store the
# globals.
#
# That's (normally) the same dictionary object that the deepest
# (oldest) stack frame is using for globals.
deepest_frame = sys._getframe(0)
while deepest_frame.f_back is not None:
deepest_frame = deepest_frame.f_back
globals_for_main_module = deepest_frame.f_globals
main_module_name = _GetModuleObjectAndName(globals_for_main_module)[1]
# The above strategy fails in some cases (e.g., tools that compute
# code coverage by redefining, among other things, the main module).
# If so, just use sys.argv[0]. We can probably always do this, but
# it's safest to try to use the same logic as _GetCallingModuleObjectAndName()
if main_module_name is None:
main_module_name = sys.argv[0]
return main_module_name
class FlagValues:
"""Registry of 'Flag' objects.
A 'FlagValues' can then scan command line arguments, passing flag
arguments through to the 'Flag' objects that it owns. It also
provides easy access to the flag values. Typically only one
'FlagValues' object is needed by an application: gflags.FLAGS
This class is heavily overloaded:
'Flag' objects are registered via __setitem__:
FLAGS['longname'] = x # register a new flag
The .value attribute of the registered 'Flag' objects can be accessed
as attributes of this 'FlagValues' object, through __getattr__. Both
the long and short name of the original 'Flag' objects can be used to
access its value:
FLAGS.longname # parsed flag value
FLAGS.x # parsed flag value (short name)
Command line arguments are scanned and passed to the registered 'Flag'
objects through the __call__ method. Unparsed arguments, including
argv[0] (e.g. the program name) are returned.
argv = FLAGS(sys.argv) # scan command line arguments
The original registered Flag objects can be retrieved through the use
of the dictionary-like operator, __getitem__:
x = FLAGS['longname'] # access the registered Flag object
The str() operator of a 'FlagValues' object provides help for all of
the registered 'Flag' objects.
"""
def __init__(self):
# Since everything in this class is so heavily overloaded, the only
# way of defining and using fields is to access __dict__ directly.
# Dictionary: flag name (string) -> Flag object.
self.__dict__['__flags'] = {}
# Dictionary: module name (string) -> list of Flag objects that are defined
# by that module.
self.__dict__['__flags_by_module'] = {}
# Dictionary: module id (int) -> list of Flag objects that are defined by
# that module.
self.__dict__['__flags_by_module_id'] = {}
# Dictionary: module name (string) -> list of Flag objects that are
# key for that module.
self.__dict__['__key_flags_by_module'] = {}
# Set if we should use new style gnu_getopt rather than getopt when parsing
# the args. Only possible with Python 2.3+
self.UseGnuGetOpt(False)
def UseGnuGetOpt(self, use_gnu_getopt=True):
"""Use GNU-style scanning. Allows mixing of flag and non-flag arguments.
See http://docs.python.org/library/getopt.html#getopt.gnu_getopt
Args:
use_gnu_getopt: wether or not to use GNU style scanning.
"""
self.__dict__['__use_gnu_getopt'] = use_gnu_getopt
def IsGnuGetOpt(self):
return self.__dict__['__use_gnu_getopt']
def FlagDict(self):
return self.__dict__['__flags']
def FlagsByModuleDict(self):
"""Returns the dictionary of module_name -> list of defined flags.
Returns:
A dictionary. Its keys are module names (strings). Its values
are lists of Flag objects.
"""
return self.__dict__['__flags_by_module']
def FlagsByModuleIdDict(self):
"""Returns the dictionary of module_id -> list of defined flags.
Returns:
A dictionary. Its keys are module IDs (ints). Its values
are lists of Flag objects.
"""
return self.__dict__['__flags_by_module_id']
def KeyFlagsByModuleDict(self):
"""Returns the dictionary of module_name -> list of key flags.
Returns:
A dictionary. Its keys are module names (strings). Its values
are lists of Flag objects.
"""
return self.__dict__['__key_flags_by_module']
def _RegisterFlagByModule(self, module_name, flag):
"""Records the module that defines a specific flag.
We keep track of which flag is defined by which module so that we
can later sort the flags by module.
Args:
module_name: A string, the name of a Python module.
flag: A Flag object, a flag that is key to the module.
"""
flags_by_module = self.FlagsByModuleDict()
flags_by_module.setdefault(module_name, []).append(flag)
def _RegisterFlagByModuleId(self, module_id, flag):
"""Records the module that defines a specific flag.
Args:
module_id: An int, the ID of the Python module.
flag: A Flag object, a flag that is key to the module.
"""
flags_by_module_id = self.FlagsByModuleIdDict()
flags_by_module_id.setdefault(module_id, []).append(flag)
def _RegisterKeyFlagForModule(self, module_name, flag):
"""Specifies that a flag is a key flag for a module.
Args:
module_name: A string, the name of a Python module.
flag: A Flag object, a flag that is key to the module.
"""
key_flags_by_module = self.KeyFlagsByModuleDict()
# The list of key flags for the module named module_name.
key_flags = key_flags_by_module.setdefault(module_name, [])
# Add flag, but avoid duplicates.
if flag not in key_flags:
key_flags.append(flag)
def _GetFlagsDefinedByModule(self, module):
"""Returns the list of flags defined by a module.
Args:
module: A module object or a module name (a string).
Returns:
A new list of Flag objects. Caller may update this list as he
wishes: none of those changes will affect the internals of this
FlagValue object.
"""
if not isinstance(module, str):
module = module.__name__
return list(self.FlagsByModuleDict().get(module, []))
def _GetKeyFlagsForModule(self, module):
"""Returns the list of key flags for a module.
Args:
module: A module object or a module name (a string)
Returns:
A new list of Flag objects. Caller may update this list as he
wishes: none of those changes will affect the internals of this
FlagValue object.
"""
if not isinstance(module, str):
module = module.__name__
# Any flag is a key flag for the module that defined it. NOTE:
# key_flags is a fresh list: we can update it without affecting the
# internals of this FlagValues object.
key_flags = self._GetFlagsDefinedByModule(module)
# Take into account flags explicitly declared as key for a module.
for flag in self.KeyFlagsByModuleDict().get(module, []):
if flag not in key_flags:
key_flags.append(flag)
return key_flags
def FindModuleDefiningFlag(self, flagname, default=None):
"""Return the name of the module defining this flag, or default.
Args:
flagname: Name of the flag to lookup.
default: Value to return if flagname is not defined. Defaults
to None.
Returns:
The name of the module which registered the flag with this name.
If no such module exists (i.e. no flag with this name exists),
we return default.
"""
for module, flags in self.FlagsByModuleDict().iteritems():
for flag in flags:
if flag.name == flagname or flag.short_name == flagname:
return module
return default
def FindModuleIdDefiningFlag(self, flagname, default=None):
"""Return the ID of the module defining this flag, or default.
Args:
flagname: Name of the flag to lookup.
default: Value to return if flagname is not defined. Defaults
to None.
Returns:
The ID of the module which registered the flag with this name.
If no such module exists (i.e. no flag with this name exists),
we return default.
"""
for module_id, flags in self.FlagsByModuleIdDict().iteritems():
for flag in flags:
if flag.name == flagname or flag.short_name == flagname:
return module_id
return default
def AppendFlagValues(self, flag_values):
"""Appends flags registered in another FlagValues instance.
Args:
flag_values: registry to copy from
"""
for flag_name, flag in flag_values.FlagDict().iteritems():
# Each flags with shortname appears here twice (once under its
# normal name, and again with its short name). To prevent