cpython/Lib/distutils/core.py

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"""distutils.core
The only module that needs to be imported to use the Distutils; provides
the 'setup' function (which must be called); the 'Distribution' class
(which may be subclassed if additional functionality is desired), and
the 'Command' class (which is used both internally by Distutils, and
may be subclassed by clients for still more flexibility)."""
# created 1999/03/01, Greg Ward
__rcsid__ = "$Id$"
import sys, os
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import string, re
from distutils.errors import *
from distutils.fancy_getopt import fancy_getopt
from distutils import util
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# This is not *quite* the same as a Python NAME; I don't allow leading
# underscores. The fact that they're very similar is no coincidence...
command_re = re.compile (r'^[a-zA-Z]([a-zA-Z0-9_]*)$')
# Defining this as a global is probably inadequate -- what about
# listing the available options (or even commands, which can vary
# quite late as well)
usage = '%s [global_opts] cmd1 [cmd1_opts] [cmd2 [cmd2_opts] ...]' % sys.argv[0]
def setup (**attrs):
"""The gateway to the Distutils: do everything your setup script
needs to do, in a highly flexible and user-driven way. Briefly:
create a Distribution instance; parse the command-line, creating
and customizing instances of the command class for each command
found on the command-line; run each of those commands.
The Distribution instance might be an instance of a class
supplied via the 'distclass' keyword argument to 'setup'; if no
such class is supplied, then the 'Distribution' class (also in
this module) is instantiated. All other arguments to 'setup'
(except for 'cmdclass') are used to set attributes of the
Distribution instance.
The 'cmdclass' argument, if supplied, is a dictionary mapping
command names to command classes. Each command encountered on the
command line will be turned into a command class, which is in turn
instantiated; any class found in 'cmdclass' is used in place of the
default, which is (for command 'foo_bar') class 'FooBar' in module
'distutils.command.foo_bar'. The command object must provide an
'options' attribute which is a list of option specifiers for
'distutils.fancy_getopt'. Any command-line options between the
current and the next command are used to set attributes in the
current command object.
When the entire command-line has been successfully parsed, calls the
'run' method on each command object in turn. This method will be
driven entirely by the Distribution object (which each command
object has a reference to, thanks to its constructor), and the
command-specific options that became attributes of each command
object."""
# Determine the distribution class -- either caller-supplied or
# our Distribution (see below).
klass = attrs.get ('distclass')
if klass:
del attrs['distclass']
else:
klass = Distribution
# Create the Distribution instance, using the remaining arguments
# (ie. everything except distclass) to initialize it
dist = klass (attrs)
# Get it to parse the command line; any command-line errors are
# the end-users fault, so turn them into SystemExit to suppress
# tracebacks.
try:
dist.parse_command_line (sys.argv[1:])
except DistutilsArgError, msg:
raise SystemExit, msg
# And finally, run all the commands found on the command line.
dist.run_commands ()
# setup ()
class Distribution:
"""The core of the Distutils. Most of the work hiding behind
'setup' is really done within a Distribution instance, which
farms the work out to the Distutils commands specified on the
command line.
Clients will almost never instantiate Distribution directly,
unless the 'setup' function is totally inadequate to their needs.
However, it is conceivable that a client might wish to subclass
Distribution for some specialized purpose, and then pass the
subclass to 'setup' as the 'distclass' keyword argument. If so,
it is necessary to respect the expectations that 'setup' has of
Distribution: it must have a constructor and methods
'parse_command_line()' and 'run_commands()' with signatures like
those described below."""
# 'global_options' describes the command-line options that may
# be supplied to the client (setup.py) prior to any actual
# commands. Eg. "./setup.py -nv" or "./setup.py --verbose"
# both take advantage of these global options.
global_options = [('verbose', 'v', "run verbosely"),
('dry-run', 'n', "don't actually do anything"),
]
# -- Creation/initialization methods -------------------------------
def __init__ (self, attrs=None):
"""Construct a new Distribution instance: initialize all the
attributes of a Distribution, and then uses 'attrs' (a
dictionary mapping attribute names to values) to assign
some of those attributes their "real" values. (Any attributes
not mentioned in 'attrs' will be assigned to some null
value: 0, None, an empty list or dictionary, etc.) Most
importantly, initialize the 'command_obj' attribute
to the empty dictionary; this will be filled in with real
command objects by 'parse_command_line()'."""
# Default values for our command-line options
self.verbose = 0
self.dry_run = 0
# And for all other attributes (stuff that might be passed in
# from setup.py, rather than from the end-user)
self.name = None
self.version = None
self.author = None
self.licence = None
self.description = None
# 'cmdclass' maps command names to class objects, so we
# can 1) quickly figure out which class to instantiate when
# we need to create a new command object, and 2) have a way
# for the client to override command classes
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self.cmdclass = {}
# The rest of these are really the business of various commands,
# rather than of the Distribution itself. However, they have
# to be here as a conduit to the relevant command class.
self.py_modules = None
self.ext_modules = None
self.package = None
# Now we'll use the attrs dictionary to possibly override
# any or all of these distribution options
if attrs:
for k in attrs.keys():
setattr (self, k, attrs[k])
# And now initialize bookkeeping stuff that can't be supplied by
# the caller at all. 'command_obj' maps command names to
# Command instances -- that's how we enforce that every command
# class is a singleton.
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self.command_obj = {}
# 'have_run' maps command names to boolean values; it keeps track
# of whether we have actually run a particular command, to make it
# cheap to "run" a command whenever we think we might need to -- if
# it's already been done, no need for expensive filesystem
# operations, we just check the 'have_run' dictionary and carry on.
# It's only safe to query 'have_run' for a command class
# that has been instantiated -- a false value will be put inserted
# when the command object is created, and replaced with a true
# value when the command is succesfully run. Thus it's
# probably best to use '.get()' rather than a straight lookup.
self.have_run = {}
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# __init__ ()
def parse_command_line (self, args):
"""Parse the client's command line: set any Distribution
attributes tied to command-line options, create all command
objects, and set their options from the command-line. 'args'
must be a list of command-line arguments, most likely
'sys.argv[1:]' (see the 'setup()' function). This list is
first processed for "global options" -- options that set
attributes of the Distribution instance. Then, it is
alternately scanned for Distutils command and options for
that command. Each new command terminates the options for
the previous command. The allowed options for a command are
determined by the 'options' attribute of the command object
-- thus, we instantiate (and cache) every command object
here, in order to access its 'options' attribute. Any error
in that 'options' attribute raises DistutilsGetoptError; any
error on the command-line raises DistutilsArgError. If no
Distutils commands were found on the command line, raises
DistutilsArgError."""
# We have to parse the command line a bit at a time -- global
# options, then the first command, then its options, and so on --
# because each command will be handled by a different class, and
# the options that are valid for a particular class aren't
# known until we instantiate the command class, which doesn't
# happen until we know what the command is.
self.commands = []
args = fancy_getopt (self.global_options, self, sys.argv[1:])
while args:
# Pull the current command from the head of the command line
command = args[0]
if not command_re.match (command):
raise SystemExit, "invalid command name '%s'" % command
self.commands.append (command)
# Have to instantiate the command class now, so we have a
# way to get its valid options and somewhere to put the
# results of parsing its share of the command-line
cmd_obj = self.create_command_obj (command)
# Require that the command class be derived from Command --
# that way, we can be sure that we at least have the 'run'
# and 'get_option' methods.
if not isinstance (cmd_obj, Command):
raise DistutilsClassError, \
"command class %s must subclass Command" % \
cmd_obj.__class__
# XXX this assumes that cmd_obj provides an 'options'
# attribute, but we're not enforcing that anywhere!
args = fancy_getopt (cmd_obj.options, cmd_obj, args[1:])
self.command_obj[command] = cmd_obj
self.have_run[command] = 0
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# while args
# Oops, no commands found -- an end-user error
if not self.commands:
sys.stderr.write (usage + "\n")
raise DistutilsArgError, "no commands supplied"
# parse_command_line()
# -- Command class/object methods ----------------------------------
# This is a method just so it can be overridden if desired; it doesn't
# actually use or change any attributes of the Distribution instance.
def find_command_class (self, command):
"""Given a command, derives the names of the module and class
expected to implement the command: eg. 'foo_bar' becomes
'distutils.command.foo_bar' (the module) and 'FooBar' (the
class within that module). Loads the module, extracts the
class from it, and returns the class object.
Raises DistutilsModuleError with a semi-user-targeted error
message if the expected module could not be loaded, or the
expected class was not found in it."""
module_name = 'distutils.command.' + command
klass_name = string.join \
(map (string.capitalize, string.split (command, '_')), '')
try:
__import__ (module_name)
module = sys.modules[module_name]
except ImportError:
raise DistutilsModuleError, \
"invalid command '%s' (no module named %s)" % \
(command, module_name)
try:
klass = vars(module)[klass_name]
except KeyError:
raise DistutilsModuleError, \
"invalid command '%s' (no class '%s' in module '%s')" \
% (command, klass_name, module_name)
return klass
# find_command_class ()
def create_command_obj (self, command):
"""Figure out the class that should implement a command,
instantiate it, cache and return the new "command object".
The "command class" is determined either by looking it up in
the 'cmdclass' attribute (this is the mechanism whereby
clients may override default Distutils commands or add their
own), or by calling the 'find_command_class()' method (if the
command name is not in 'cmdclass'."""
# Determine the command class -- either it's in the command_class
# dictionary, or we have to divine the module and class name
klass = self.cmdclass.get(command)
if not klass:
klass = self.find_command_class (command)
self.cmdclass[command] = klass
# Found the class OK -- instantiate it
cmd_obj = klass (self)
return cmd_obj
def find_command_obj (self, command, create=1):
"""Look up and return a command object in the cache maintained by
'create_command_obj()'. If none found, the action taken
depends on 'create': if true (the default), create a new
command object by calling 'create_command_obj()' and return
it; otherwise, return None."""
cmd_obj = self.command_obj.get (command)
if not cmd_obj and create:
cmd_obj = self.create_command_obj (command)
self.command_obj[command] = cmd_obj
return cmd_obj
# -- Methods that operate on the Distribution ----------------------
def announce (self, msg, level=1):
"""Print 'msg' if 'level' is greater than or equal to the verbosity
level recorded in the 'verbose' attribute (which, currently,
can be only 0 or 1)."""
if self.verbose >= level:
print msg
def run_commands (self):
"""Run each command that was seen on the client command line.
Uses the list of commands found and cache of command objects
created by 'create_command_obj()'."""
for cmd in self.commands:
self.run_command (cmd)
def get_option (self, option):
"""Return the value of a distribution option. Raise
DistutilsOptionError if 'option' is not known."""
try:
return getattr (self, opt)
except AttributeError:
raise DistutilsOptionError, \
"unknown distribution option %s" % option
def get_options (self, *options):
"""Return (as a tuple) the values of several distribution
options. Raise DistutilsOptionError if any element of
'options' is not known."""
values = []
try:
for opt in options:
values.append (getattr (self, opt))
except AttributeError, name:
raise DistutilsOptionError, \
"unknown distribution option %s" % name
return tuple (values)
# -- Methods that operate on its Commands --------------------------
def run_command (self, command):
"""Do whatever it takes to run a command (including nothing at all,
if the command has already been run). Specifically: if we have
already created and run the command named by 'command', return
silently without doing anything. If the command named by
'command' doesn't even have a command object yet, create one.
Then invoke 'run()' on that command object (or an existing
one)."""
# Already been here, done that? then return silently.
if self.have_run.get (command):
return
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self.announce ("running " + command)
cmd_obj = self.find_command_obj (command)
cmd_obj.run ()
self.have_run[command] = 1
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def get_command_option (self, command, option):
"""Create a command object for 'command' if necessary, finalize
its option values by invoking its 'set_final_options()'
method, and return the value of its 'option' option. Raise
DistutilsOptionError if 'option' is not known for
that 'command'."""
cmd_obj = self.find_command_obj (command)
cmd_obj.set_final_options ()
return cmd_obj.get_option (option)
try:
return getattr (cmd_obj, option)
except AttributeError:
raise DistutilsOptionError, \
"command %s: no such option %s" % (command, option)
def get_command_options (self, command, *options):
"""Create a command object for 'command' if necessary, finalize
its option values by invoking its 'set_final_options()'
method, and return the values of all the options listed in
'options' for that command. Raise DistutilsOptionError if
'option' is not known for that 'command'."""
cmd_obj = self.find_command_obj (command)
cmd_obj.set_final_options ()
values = []
try:
for opt in options:
values.append (getattr (cmd_obj, option))
except AttributeError, name:
raise DistutilsOptionError, \
"command %s: no such option %s" % (command, name)
return tuple (values)
# end class Distribution
class Command:
"""Abstract base class for defining command classes, the "worker bees"
of the Distutils. A useful analogy for command classes is to
think of them as subroutines with local variables called
"options". The options are "declared" in 'set_initial_options()'
and "initialized" (given their real values) in
'set_final_options()', both of which must be defined by every
command class. The distinction between the two is necessary
because option values might come from the outside world (command
line, option file, ...), and any options dependent on other
options must be computed *after* these outside influences have
been processed -- hence 'set_final_values()'. The "body" of the
subroutine, where it does all its work based on the values of its
options, is the 'run()' method, which must also be implemented by
every command class."""
# -- Creation/initialization methods -------------------------------
def __init__ (self, dist):
"""Create and initialize a new Command object. Most importantly,
invokes the 'set_default_options()' method, which is the
real initializer and depends on the actual command being
instantiated."""
if not isinstance (dist, Distribution):
raise TypeError, "dist must be a Distribution instance"
if self.__class__ is Command:
raise RuntimeError, "Command is an abstract class"
self.distribution = dist
self.set_default_options ()
# end __init__ ()
# Subclasses must define:
# set_default_options()
# provide default values for all options; may be overridden
# by Distutils client, by command-line options, or by options
# from option file
# set_final_options()
# decide on the final values for all options; this is called
# after all possible intervention from the outside world
# (command-line, option file, etc.) has been processed
# run()
# run the command: do whatever it is we're here to do,
# controlled by the command's various option values
def set_default_options (self):
"""Set default values for all the options that this command
supports. Note that these defaults may be overridden
by the command-line supplied by the user; thus, this is
not the place to code dependencies between options; generally,
'set_default_options()' implementations are just a bunch
of "self.foo = None" assignments.
This method must be implemented by all command classes."""
raise RuntimeError, \
"abstract method -- subclass %s must override" % self.__class__
def set_final_options (self):
"""Set final values for all the options that this command
supports. This is always called as late as possible, ie.
after any option assignments from the command-line or from
other commands have been done. Thus, this is the place to to
code option dependencies: if 'foo' depends on 'bar', then it
is safe to set 'foo' from 'bar' as long as 'foo' still has
the same value it was assigned in 'set_default_options()'.
This method must be implemented by all command classes."""
raise RuntimeError, \
"abstract method -- subclass %s must override" % self.__class__
def run (self):
"""A command's raison d'etre: carry out the action it exists
to perform, controlled by the options initialized in
'set_initial_options()', customized by the user and other
commands, and finalized in 'set_final_options()'. All
terminal output and filesystem interaction should be done by
'run()'.
This method must be implemented by all command classes."""
raise RuntimeError, \
"abstract method -- subclass %s must override" % self.__class__
def announce (self, msg, level=1):
"""If the Distribution instance to which this command belongs
has a verbosity level of greater than or equal to 'level'
print 'msg' to stdout."""
if self.distribution.verbose >= level:
print msg
# -- Option query/set methods --------------------------------------
def get_option (self, option):
"""Return the value of a single option for this command. Raise
DistutilsOptionError if 'option' is not known."""
try:
return getattr (self, option)
except AttributeError:
raise DistutilsOptionError, \
"command %s: no such option %s" % \
(self.command_name(), option)
def get_options (self, *options):
"""Return (as a tuple) the values of several options for this
command. Raise DistutilsOptionError if any of the options in
'options' are not known."""
values = []
try:
for opt in options:
values.append (getattr (self, opt))
except AttributeError, name:
raise DistutilsOptionError, \
"command %s: no such option %s" % \
(self.command_name(), name)
return tuple (values)
def set_option (self, option, value):
"""Set the value of a single option for this command. Raise
DistutilsOptionError if 'option' is not known."""
if not hasattr (self, option):
raise DistutilsOptionError, \
"command %s: no such option %s" % \
(self.command_name(), option)
if value is not None:
setattr (self, option, value)
def set_options (self, **optval):
"""Set the values of several options for this command. Raise
DistutilsOptionError if any of the options specified as
keyword arguments are not known."""
for k in optval.keys():
if optval[k] is not None:
self.set_option (k, optval[k])
# -- Convenience methods for commands ------------------------------
def set_undefined_options (self, src_cmd, *option_pairs):
"""Set the values of any "undefined" options from corresponding
option values in some other command object. "Undefined" here
means "is None", which is the convention used to indicate
that an option has not been changed between
'set_initial_values()' and 'set_final_values()'. Usually
called from 'set_final_values()' for options that depend on
some other command rather than another option of the same
command. 'src_cmd' is the other command from which option
values will be taken (a command object will be created for it
if necessary); the remaining arguments are
'(src_option,dst_option)' tuples which mean "take the value
of 'src_option' in the 'src_cmd' command object, and copy it
to 'dst_option' in the current command object"."""
# Option_pairs: list of (src_option, dst_option) tuples
src_cmd_obj = self.distribution.find_command_obj (src_cmd)
src_cmd_obj.set_final_options ()
try:
for (src_option, dst_option) in option_pairs:
if getattr (self, dst_option) is None:
self.set_option (dst_option,
src_cmd_obj.get_option (src_option))
except AttributeError, name:
# duh, which command?
raise DistutilsOptionError, "unknown option %s" % name
def set_peer_option (self, command, option, value):
"""Attempt to simulate a command-line override of some option
value in another command. Creates a command object for
'command' if necessary, sets 'option' to 'value', and invokes
'set_final_options()' on that command object. This will only
have the desired effect if the command object for 'command'
has not previously been created. Generally this is used to
ensure that the options in 'command' dependent on 'option'
are computed, hopefully (but not necessarily) deriving from
'value'. It might be more accurate to call this method
'influence_dependent_peer_options()'."""
cmd_obj = self.distribution.find_command_obj (command)
cmd_obj.set_option (option, value)
cmd_obj.set_final_options ()
def run_peer (self, command):
"""Run some other command: uses the 'run_command()' method of
Distribution, which creates the command object if necessary
and then invokes its 'run()' method."""
self.distribution.run_command (command)
# -- External world manipulation -----------------------------------
def execute (self, func, args, msg=None, level=1):
"""Perform some action that affects the outside world (eg.
by writing to the filesystem). Such actions are special because
they should be disabled by the "dry run" flag (carried around by
the Command's Distribution), and should announce themselves if
the current verbosity level is high enough. This method takes
care of all that bureaucracy for you; all you have to do is
supply the funtion to call and an argument tuple for it (to
embody the "external action" being performed), a message to
print if the verbosity level is high enough, and an optional
verbosity threshold."""
# Generate a message if we weren't passed one
if msg is None:
msg = "%s %s" % (func.__name__, `args`)
if msg[-2:] == ',)': # correct for singleton tuple
msg = msg[0:-2] + ')'
# Print it if verbosity level is high enough
self.announce (msg, level)
# And do it, as long as we're not in dry-run mode
if not self.distribution.dry_run:
apply (func, args)
# execute()
def mkpath (self, name, mode=0777):
util.mkpath (name, mode,
self.distribution.verbose, self.distribution.dry_run)
def copy_file (self, infile, outfile,
preserve_mode=1, preserve_times=1, update=1, level=1):
"""Copy a file respecting verbose and dry-run flags."""
return util.copy_file (infile, outfile,
preserve_mode, preserve_times,
update, self.distribution.verbose >= level,
self.distribution.dry_run)
def copy_tree (self, infile, outfile,
preserve_mode=1, preserve_times=1, preserve_symlinks=0,
update=1, level=1):
"""Copy an entire directory tree respecting verbose and dry-run
flags."""
return util.copy_tree (infile, outfile,
preserve_mode,preserve_times,preserve_symlinks,
update, self.distribution.verbose >= level,
self.distribution.dry_run)
def make_file (self, infiles, outfile, func, args,
exec_msg=None, skip_msg=None, level=1):
"""Special case of 'execute()' for operations that process one or
more input files and generate one output file. Works just like
'execute()', except the operation is skipped and a different
message printed if 'outfile' already exists and is newer than
all files listed in 'infiles'."""
if exec_msg is None:
exec_msg = "generating %s from %s" % \
(outfile, string.join (infiles, ', '))
if skip_msg is None:
skip_msg = "skipping %s (inputs unchanged)" % outfile
# Allow 'infiles' to be a single string
if type (infiles) is StringType:
infiles = (infiles,)
elif type (infiles) not in (ListType, TupleType):
raise TypeError, \
"'infiles' must be a string, or a list or tuple of strings"
# XXX this stuff should probably be moved off to a function
# in 'distutils.util'
from stat import *
if os.path.exists (outfile):
out_mtime = os.stat (outfile)[ST_MTIME]
# Loop over all infiles. If any infile is newer than outfile,
# then we'll have to regenerate outfile
for f in infiles:
in_mtime = os.stat (f)[ST_MTIME]
if in_mtime > out_mtime:
runit = 1
break
else:
runit = 0
else:
runit = 1
# If we determined that 'outfile' must be regenerated, then
# perform the action that presumably regenerates it
if runit:
self.execute (func, args, exec_msg, level)
# Otherwise, print the "skip" message
else:
self.announce (skip_msg, level)
# make_file ()
# def make_files (self, infiles, outfiles, func, args,
# exec_msg=None, skip_msg=None, level=1):
# """Special case of 'execute()' for operations that process one or
# more input files and generate one or more output files. Works
# just like 'execute()', except the operation is skipped and a
# different message printed if all files listed in 'outfiles'
# already exist and are newer than all files listed in
# 'infiles'."""
# pass
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# end class Command