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"""SCons.Action
This encapsulates information about executing any sort of action that
can build one or more target Nodes (typically files) from one or more
source Nodes (also typically files) given a specific Environment.
The base class here is ActionBase. The base class supplies just a few
OO utility methods and some generic methods for displaying information
about an Action in response to the various commands that control printing.
A second-level base class is _ActionAction. This extends ActionBase
by providing the methods that can be used to show and perform an
action. True Action objects will subclass _ActionAction; Action
factory class objects will subclass ActionBase.
The heavy lifting is handled by subclasses for the different types of
actions we might execute:
CommandAction
CommandGeneratorAction
FunctionAction
ListAction
The subclasses supply the following public interface methods used by
other modules:
__call__()
THE public interface, "calling" an Action object executes the
command or Python function. This also takes care of printing
a pre-substitution command for debugging purposes.
get_contents()
Fetches the "contents" of an Action for signature calculation
plus the varlist. This is what gets MD5 checksummed to decide
if a target needs to be rebuilt because its action changed.
genstring()
Returns a string representation of the Action *without*
command substitution, but allows a CommandGeneratorAction to
generate the right action based on the specified target,
source and env. This is used by the Signature subsystem
(through the Executor) to obtain an (imprecise) representation
of the Action operation for informative purposes.
Subclasses also supply the following methods for internal use within
this module:
__str__()
Returns a string approximation of the Action; no variable
substitution is performed.
execute()
The internal method that really, truly, actually handles the
execution of a command or Python function. This is used so
that the __call__() methods can take care of displaying any
pre-substitution representations, and *then* execute an action
without worrying about the specific Actions involved.
get_presig()
Fetches the "contents" of a subclass for signature calculation.
The varlist is added to this to produce the Action's contents.
strfunction()
Returns a substituted string representation of the Action.
This is used by the _ActionAction.show() command to display the
command/function that will be executed to generate the target(s).
There is a related independent ActionCaller class that looks like a
regular Action, and which serves as a wrapper for arbitrary functions
that we want to let the user specify the arguments to now, but actually
execute later (when an out-of-date check determines that it's needed to
be executed, for example). Objects of this class are returned by an
ActionFactory class that provides a __call__() method as a convenient
way for wrapping up the functions.
"""
# Copyright (c) 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008 The SCons Foundation
#
# Permission is hereby granted, free of charge, to any person obtaining
# a copy of this software and associated documentation files (the
# "Software"), to deal in the Software without restriction, including
# without limitation the rights to use, copy, modify, merge, publish,
# distribute, sublicense, and/or sell copies of the Software, and to
# permit persons to whom the Software is furnished to do so, subject to
# the following conditions:
#
# The above copyright notice and this permission notice shall be included
# in all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY
# KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE
# WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
# NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
# LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
# OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
# WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
__revision__ = "src/engine/SCons/Action.py 3842 2008/12/20 22:59:52 scons"
import cPickle
import dis
import os
import string
import sys
import subprocess
from SCons.Debug import logInstanceCreation
import SCons.Errors
import SCons.Executor
import SCons.Util
import SCons.Subst
# we use these a lot, so try to optimize them
is_String = SCons.Util.is_String
is_List = SCons.Util.is_List
class _null:
pass
print_actions = 1
execute_actions = 1
print_actions_presub = 0
def rfile(n):
try:
return n.rfile()
except AttributeError:
return n
def default_exitstatfunc(s):
return s
try:
SET_LINENO = dis.SET_LINENO
HAVE_ARGUMENT = dis.HAVE_ARGUMENT
except AttributeError:
remove_set_lineno_codes = lambda x: x
else:
def remove_set_lineno_codes(code):
result = []
n = len(code)
i = 0
while i < n:
c = code[i]
op = ord(c)
if op >= HAVE_ARGUMENT:
if op != SET_LINENO:
result.append(code[i:i+3])
i = i+3
else:
result.append(c)
i = i+1
return string.join(result, '')
def _callable_contents(obj):
"""Return the signature contents of a callable Python object.
"""
try:
# Test if obj is a method.
return _function_contents(obj.im_func)
except AttributeError:
try:
# Test if obj is a callable object.
return _function_contents(obj.__call__.im_func)
except AttributeError:
try:
# Test if obj is a code object.
return _code_contents(obj)
except AttributeError:
# Test if obj is a function object.
return _function_contents(obj)
def _object_contents(obj):
"""Return the signature contents of any Python object.
We have to handle the case where object contains a code object
since it can be pickled directly.
"""
try:
# Test if obj is a method.
return _function_contents(obj.im_func)
except AttributeError:
try:
# Test if obj is a callable object.
return _function_contents(obj.__call__.im_func)
except AttributeError:
try:
# Test if obj is a code object.
return _code_contents(obj)
except AttributeError:
try:
# Test if obj is a function object.
return _function_contents(obj)
except AttributeError:
# Should be a pickable Python object.
try:
return cPickle.dumps(obj)
except (cPickle.PicklingError, TypeError):
# This is weird, but it seems that nested classes
# are unpickable. The Python docs say it should
# always be a PicklingError, but some Python
# versions seem to return TypeError. Just do
# the best we can.
return str(obj)
def _code_contents(code):
"""Return the signature contents of a code object.
By providing direct access to the code object of the
function, Python makes this extremely easy. Hooray!
Unfortunately, older versions of Python include line
number indications in the compiled byte code. Boo!
So we remove the line number byte codes to prevent
recompilations from moving a Python function.
"""
contents = []
# The code contents depends on the number of local variables
# but not their actual names.
contents.append("%s,%s" % (code.co_argcount, len(code.co_varnames)))
try:
contents.append(",%s,%s" % (len(code.co_cellvars), len(code.co_freevars)))
except AttributeError:
# Older versions of Python do not support closures.
contents.append(",0,0")
# The code contents depends on any constants accessed by the
# function. Note that we have to call _object_contents on each
# constants because the code object of nested functions can
# show-up among the constants.
#
# Note that we also always ignore the first entry of co_consts
# which contains the function doc string. We assume that the
# function does not access its doc string.
contents.append(',(' + string.join(map(_object_contents,code.co_consts[1:]),',') + ')')
# The code contents depends on the variable names used to
# accessed global variable, as changing the variable name changes
# the variable actually accessed and therefore changes the
# function result.
contents.append(',(' + string.join(map(_object_contents,code.co_names),',') + ')')
# The code contents depends on its actual code!!!
contents.append(',(' + str(remove_set_lineno_codes(code.co_code)) + ')')
return string.join(contents, '')
def _function_contents(func):
"""Return the signature contents of a function."""
contents = [_code_contents(func.func_code)]
# The function contents depends on the value of defaults arguments
if func.func_defaults:
contents.append(',(' + string.join(map(_object_contents,func.func_defaults),',') + ')')
else:
contents.append(',()')
# The function contents depends on the closure captured cell values.
try:
closure = func.func_closure or []
except AttributeError:
# Older versions of Python do not support closures.
closure = []
#xxx = [_object_contents(x.cell_contents) for x in closure]
try:
xxx = map(lambda x: _object_contents(x.cell_contents), closure)
except AttributeError:
xxx = []
contents.append(',(' + string.join(xxx, ',') + ')')
return string.join(contents, '')
def _actionAppend(act1, act2):
# This function knows how to slap two actions together.
# Mainly, it handles ListActions by concatenating into
# a single ListAction.
a1 = Action(act1)
a2 = Action(act2)
if a1 is None or a2 is None:
raise TypeError, "Cannot append %s to %s" % (type(act1), type(act2))
if isinstance(a1, ListAction):
if isinstance(a2, ListAction):
return ListAction(a1.list + a2.list)
else:
return ListAction(a1.list + [ a2 ])
else:
if isinstance(a2, ListAction):
return ListAction([ a1 ] + a2.list)
else:
return ListAction([ a1, a2 ])
def _do_create_keywords(args, kw):
"""This converts any arguments after the action argument into
their equivalent keywords and adds them to the kw argument.
"""
v = kw.get('varlist', ())
# prevent varlist="FOO" from being interpreted as ['F', 'O', 'O']
if is_String(v): v = (v,)
kw['varlist'] = tuple(v)
if args:
# turn positional args into equivalent keywords
cmdstrfunc = args[0]
if cmdstrfunc is None or is_String(cmdstrfunc):
kw['cmdstr'] = cmdstrfunc
elif callable(cmdstrfunc):
kw['strfunction'] = cmdstrfunc
else:
raise SCons.Errors.UserError(
'Invalid command display variable type. '
'You must either pass a string or a callback which '
'accepts (target, source, env) as parameters.')
if len(args) > 1:
kw['varlist'] = args[1:] + kw['varlist']
if kw.get('strfunction', _null) is not _null \
and kw.get('cmdstr', _null) is not _null:
raise SCons.Errors.UserError(
'Cannot have both strfunction and cmdstr args to Action()')
def _do_create_action(act, kw):
"""This is the actual "implementation" for the
Action factory method, below. This handles the
fact that passing lists to Action() itself has
different semantics than passing lists as elements
of lists.
The former will create a ListAction, the latter
will create a CommandAction by converting the inner
list elements to strings."""
if isinstance(act, ActionBase):
return act
if is_List(act):
#TODO(1.5) return CommandAction(act, **kw)
return apply(CommandAction, (act,), kw)
if callable(act):
try:
gen = kw['generator']
del kw['generator']
except KeyError:
gen = 0
if gen:
action_type = CommandGeneratorAction
else:
action_type = FunctionAction
return action_type(act, kw)
if is_String(act):
var=SCons.Util.get_environment_var(act)
if var:
# This looks like a string that is purely an Environment
# variable reference, like "$FOO" or "${FOO}". We do
# something special here...we lazily evaluate the contents
# of that Environment variable, so a user could put something
# like a function or a CommandGenerator in that variable
# instead of a string.
return LazyAction(var, kw)
commands = string.split(str(act), '\n')
if len(commands) == 1:
#TODO(1.5) return CommandAction(commands[0], **kw)
return apply(CommandAction, (commands[0],), kw)
# The list of string commands may include a LazyAction, so we
# reprocess them via _do_create_list_action.
return _do_create_list_action(commands, kw)
return None
def _do_create_list_action(act, kw):
"""A factory for list actions. Convert the input list into Actions
and then wrap them in a ListAction."""
acts = []
for a in act:
aa = _do_create_action(a, kw)
if aa is not None: acts.append(aa)
if not acts:
return None
elif len(acts) == 1:
return acts[0]
else:
return ListAction(acts)
def Action(act, *args, **kw):
"""A factory for action objects."""
# Really simple: the _do_create_* routines do the heavy lifting.
_do_create_keywords(args, kw)
if is_List(act):
return _do_create_list_action(act, kw)
return _do_create_action(act, kw)
class ActionBase:
"""Base class for all types of action objects that can be held by
other objects (Builders, Executors, etc.) This provides the
common methods for manipulating and combining those actions."""
def __cmp__(self, other):
return cmp(self.__dict__, other)
def genstring(self, target, source, env):
return str(self)
def get_contents(self, target, source, env):
result = [ self.get_presig(target, source, env) ]
# This should never happen, as the Action() factory should wrap
# the varlist, but just in case an action is created directly,
# we duplicate this check here.
vl = self.varlist
if is_String(vl): vl = (vl,)
for v in vl:
result.append(env.subst('${'+v+'}'))
return string.join(result, '')
def __add__(self, other):
return _actionAppend(self, other)
def __radd__(self, other):
return _actionAppend(other, self)
def presub_lines(self, env):
# CommandGeneratorAction needs a real environment
# in order to return the proper string here, since
# it may call LazyAction, which looks up a key
# in that env. So we temporarily remember the env here,
# and CommandGeneratorAction will use this env
# when it calls its _generate method.
self.presub_env = env
lines = string.split(str(self), '\n')
self.presub_env = None # don't need this any more
return lines
def get_executor(self, env, overrides, tlist, slist, executor_kw):
"""Return the Executor for this Action."""
return SCons.Executor.Executor(self, env, overrides,
tlist, slist, executor_kw)
class _ActionAction(ActionBase):
"""Base class for actions that create output objects."""
def __init__(self, cmdstr=_null, strfunction=_null, varlist=(),
presub=_null, chdir=None, exitstatfunc=None,
**kw):
self.cmdstr = cmdstr
if strfunction is not _null:
if strfunction is None:
self.cmdstr = None
else:
self.strfunction = strfunction
self.varlist = varlist
self.presub = presub
self.chdir = chdir
if not exitstatfunc:
exitstatfunc = default_exitstatfunc
self.exitstatfunc = exitstatfunc
def print_cmd_line(self, s, target, source, env):
sys.stdout.write(s + "\n")
def __call__(self, target, source, env,
exitstatfunc=_null,
presub=_null,
show=_null,
execute=_null,
chdir=_null):
if not is_List(target):
target = [target]
if not is_List(source):
source = [source]
if presub is _null:
presub = self.presub
if presub is _null:
presub = print_actions_presub
if exitstatfunc is _null: exitstatfunc = self.exitstatfunc
if show is _null: show = print_actions
if execute is _null: execute = execute_actions
if chdir is _null: chdir = self.chdir
save_cwd = None
if chdir:
save_cwd = os.getcwd()
try:
chdir = str(chdir.abspath)
except AttributeError:
if not is_String(chdir):
chdir = str(target[0].dir)
if presub:
t = string.join(map(str, target), ' and ')
l = string.join(self.presub_lines(env), '\n ')
out = "Building %s with action:\n %s\n" % (t, l)
sys.stdout.write(out)
cmd = None
if show and self.strfunction:
cmd = self.strfunction(target, source, env)
if cmd:
if chdir:
cmd = ('os.chdir(%s)\n' % repr(chdir)) + cmd
try:
get = env.get
except AttributeError:
print_func = self.print_cmd_line
else:
print_func = get('PRINT_CMD_LINE_FUNC')
if not print_func:
print_func = self.print_cmd_line
print_func(cmd, target, source, env)
stat = 0
if execute:
if chdir:
os.chdir(chdir)
try:
stat = self.execute(target, source, env)
if isinstance(stat, SCons.Errors.BuildError):
s = exitstatfunc(stat.status)
if s:
stat.status = s
else:
stat = s
else:
stat = exitstatfunc(stat)
finally:
if save_cwd:
os.chdir(save_cwd)
if cmd and save_cwd:
print_func('os.chdir(%s)' % repr(save_cwd), target, source, env)
return stat
def _string_from_cmd_list(cmd_list):
"""Takes a list of command line arguments and returns a pretty
representation for printing."""
cl = []
for arg in map(str, cmd_list):
if ' ' in arg or '\t' in arg:
arg = '"' + arg + '"'
cl.append(arg)
return string.join(cl)
# A fiddlin' little function that has an 'import SCons.Environment' which
# can't be moved to the top level without creating an import loop. Since
# this import creates a local variable named 'SCons', it blocks access to
# the global variable, so we move it here to prevent complaints about local
# variables being used uninitialized.
default_ENV = None
def get_default_ENV(env):
global default_ENV
try:
return env['ENV']
except KeyError:
if not default_ENV:
import SCons.Environment
# This is a hideously expensive way to get a default shell
# environment. What it really should do is run the platform
# setup to get the default ENV. Fortunately, it's incredibly
# rare for an Environment not to have a shell environment, so
# we're not going to worry about it overmuch.
default_ENV = SCons.Environment.Environment()['ENV']
return default_ENV
# This function is still in draft mode. We're going to need something like
# it in the long run as more and more places use subprocess, but I'm sure
# it'll have to be tweaked to get the full desired functionality.
# one special arg (so far?), 'error', to tell what to do with exceptions.
def _subproc(env, cmd, error = 'ignore', **kw):
"""Do common setup for a subprocess.Popen() call"""
# allow std{in,out,err} to be "'devnull'"
io = kw.get('stdin')
if is_String(io) and io == 'devnull':
kw['stdin'] = open(os.devnull)
io = kw.get('stdout')
if is_String(io) and io == 'devnull':
kw['stdout'] = open(os.devnull, 'w')
io = kw.get('stderr')
if is_String(io) and io == 'devnull':
kw['stderr'] = open(os.devnull, 'w')
# Figure out what shell environment to use
ENV = kw.get('env', None)
if ENV is None: ENV = get_default_ENV(env)
# Ensure that the ENV values are all strings:
new_env = {}
for key, value in ENV.items():
if is_List(value):
# If the value is a list, then we assume it is a path list,
# because that's a pretty common list-like value to stick
# in an environment variable:
value = SCons.Util.flatten_sequence(value)
new_env[key] = string.join(map(str, value), os.pathsep)
else:
# It's either a string or something else. If it's a string,
# we still want to call str() because it might be a *Unicode*
# string, which makes subprocess.Popen() gag. If it isn't a
# string or a list, then we just coerce it to a string, which
# is the proper way to handle Dir and File instances and will
# produce something reasonable for just about everything else:
new_env[key] = str(value)
kw['env'] = new_env
try:
#FUTURE return subprocess.Popen(cmd, **kw)
return apply(subprocess.Popen, (cmd,), kw)
except EnvironmentError, e:
if error == 'raise': raise
# return a dummy Popen instance that only returns error
class dummyPopen:
def __init__(self, e): self.exception = e
def communicate(self): return ('','')
def wait(self): return -self.exception.errno
stdin = None
class f:
def read(self): return ''
def readline(self): return ''
stdout = stderr = f()
return dummyPopen(e)
class CommandAction(_ActionAction):
"""Class for command-execution actions."""
def __init__(self, cmd, **kw):
# Cmd can actually be a list or a single item; if it's a
# single item it should be the command string to execute; if a
# list then it should be the words of the command string to
# execute. Only a single command should be executed by this
# object; lists of commands should be handled by embedding
# these objects in a ListAction object (which the Action()
# factory above does). cmd will be passed to
# Environment.subst_list() for substituting environment
# variables.
if __debug__: logInstanceCreation(self, 'Action.CommandAction')
#TODO(1.5) _ActionAction.__init__(self, **kw)
apply(_ActionAction.__init__, (self,), kw)
if is_List(cmd):
if filter(is_List, cmd):
raise TypeError, "CommandAction should be given only " \
"a single command"
self.cmd_list = cmd
def __str__(self):
if is_List(self.cmd_list):
return string.join(map(str, self.cmd_list), ' ')
return str(self.cmd_list)
def process(self, target, source, env):
result = env.subst_list(self.cmd_list, 0, target, source)
silent = None
ignore = None
while 1:
try: c = result[0][0][0]
except IndexError: c = None
if c == '@': silent = 1
elif c == '-': ignore = 1
else: break
result[0][0] = result[0][0][1:]
try:
if not result[0][0]:
result[0] = result[0][1:]
except IndexError:
pass
return result, ignore, silent
def strfunction(self, target, source, env):
if self.cmdstr is None:
return None
if self.cmdstr is not _null:
from SCons.Subst import SUBST_RAW
c = env.subst(self.cmdstr, SUBST_RAW, target, source)
if c:
return c
cmd_list, ignore, silent = self.process(target, source, env)
if silent:
return ''
return _string_from_cmd_list(cmd_list[0])
def execute(self, target, source, env):
"""Execute a command action.
This will handle lists of commands as well as individual commands,
because construction variable substitution may turn a single
"command" into a list. This means that this class can actually
handle lists of commands, even though that's not how we use it
externally.
"""
escape_list = SCons.Subst.escape_list
flatten_sequence = SCons.Util.flatten_sequence
try:
shell = env['SHELL']
except KeyError:
raise SCons.Errors.UserError('Missing SHELL construction variable.')
try:
spawn = env['SPAWN']
except KeyError:
raise SCons.Errors.UserError('Missing SPAWN construction variable.')
else:
if is_String(spawn):
spawn = env.subst(spawn, raw=1, conv=lambda x: x)
escape = env.get('ESCAPE', lambda x: x)
ENV = get_default_ENV(env)
# Ensure that the ENV values are all strings:
for key, value in ENV.items():
if not is_String(value):
if is_List(value):
# If the value is a list, then we assume it is a
# path list, because that's a pretty common list-like
# value to stick in an environment variable:
value = flatten_sequence(value)
ENV[key] = string.join(map(str, value), os.pathsep)
else:
# If it isn't a string or a list, then we just coerce
# it to a string, which is the proper way to handle
# Dir and File instances and will produce something
# reasonable for just about everything else:
ENV[key] = str(value)
cmd_list, ignore, silent = self.process(target, map(rfile, source), env)
# Use len() to filter out any "command" that's zero-length.
for cmd_line in filter(len, cmd_list):
# Escape the command line for the interpreter we are using.
cmd_line = escape_list(cmd_line, escape)
result = spawn(shell, escape, cmd_line[0], cmd_line, ENV)
if not ignore and result:
msg = "Error %s" % result
return SCons.Errors.BuildError(errstr=msg,
status=result,
action=self,
command=cmd_line)
return 0
def get_presig(self, target, source, env):
"""Return the signature contents of this action's command line.
This strips $(-$) and everything in between the string,
since those parts don't affect signatures.
"""
from SCons.Subst import SUBST_SIG
cmd = self.cmd_list
if is_List(cmd):
cmd = string.join(map(str, cmd))
else:
cmd = str(cmd)
return env.subst_target_source(cmd, SUBST_SIG, target, source)
def get_implicit_deps(self, target, source, env):
icd = env.get('IMPLICIT_COMMAND_DEPENDENCIES', True)
if is_String(icd) and icd[:1] == '$':
icd = env.subst(icd)
if not icd or icd in ('0', 'None'):
return []
from SCons.Subst import SUBST_SIG
cmd_list = env.subst_list(self.cmd_list, SUBST_SIG, target, source)
res = []
for cmd_line in cmd_list:
if cmd_line:
d = env.WhereIs(str(cmd_line[0]))
if d:
res.append(env.fs.File(d))
return res
class CommandGeneratorAction(ActionBase):
"""Class for command-generator actions."""
def __init__(self, generator, kw):
if __debug__: logInstanceCreation(self, 'Action.CommandGeneratorAction')
self.generator = generator
self.gen_kw = kw
self.varlist = kw.get('varlist', ())
def _generate(self, target, source, env, for_signature):
# ensure that target is a list, to make it easier to write
# generator functions:
if not is_List(target):
target = [target]
ret = self.generator(target=target, source=source, env=env, for_signature=for_signature)
#TODO(1.5) gen_cmd = Action(ret, **self.gen_kw)
gen_cmd = apply(Action, (ret,), self.gen_kw)
if not gen_cmd:
raise SCons.Errors.UserError("Object returned from command generator: %s cannot be used to create an Action." % repr(ret))
return gen_cmd
def __str__(self):
try:
env = self.presub_env
except AttributeError:
env = None
if env is None:
env = SCons.Defaults.DefaultEnvironment()
act = self._generate([], [], env, 1)
return str(act)
def genstring(self, target, source, env):
return self._generate(target, source, env, 1).genstring(target, source, env)
def __call__(self, target, source, env, exitstatfunc=_null, presub=_null,
show=_null, execute=_null, chdir=_null):
act = self._generate(target, source, env, 0)
return act(target, source, env, exitstatfunc, presub,
show, execute, chdir)
def get_presig(self, target, source, env):
"""Return the signature contents of this action's command line.
This strips $(-$) and everything in between the string,
since those parts don't affect signatures.
"""
return self._generate(target, source, env, 1).get_presig(target, source, env)
def get_implicit_deps(self, target, source, env):
return self._generate(target, source, env, 1).get_implicit_deps(target, source, env)
# A LazyAction is a kind of hybrid generator and command action for
# strings of the form "$VAR". These strings normally expand to other
# strings (think "$CCCOM" to "$CC -c -o $TARGET $SOURCE"), but we also
# want to be able to replace them with functions in the construction
# environment. Consequently, we want lazy evaluation and creation of
# an Action in the case of the function, but that's overkill in the more
# normal case of expansion to other strings.
#
# So we do this with a subclass that's both a generator *and*
# a command action. The overridden methods all do a quick check
# of the construction variable, and if it's a string we just call
# the corresponding CommandAction method to do the heavy lifting.
# If not, then we call the same-named CommandGeneratorAction method.
# The CommandGeneratorAction methods work by using the overridden
# _generate() method, that is, our own way of handling "generation" of
# an action based on what's in the construction variable.
class LazyAction(CommandGeneratorAction, CommandAction):
def __init__(self, var, kw):
if __debug__: logInstanceCreation(self, 'Action.LazyAction')
#FUTURE CommandAction.__init__(self, '${'+var+'}', **kw)
apply(CommandAction.__init__, (self, '${'+var+'}'), kw)
self.var = SCons.Util.to_String(var)
self.gen_kw = kw
def get_parent_class(self, env):
c = env.get(self.var)
if is_String(c) and not '\n' in c:
return CommandAction
return CommandGeneratorAction
def _generate_cache(self, env):
c = env.get(self.var, '')
#TODO(1.5) gen_cmd = Action(c, **self.gen_kw)
gen_cmd = apply(Action, (c,), self.gen_kw)
if not gen_cmd:
raise SCons.Errors.UserError("$%s value %s cannot be used to create an Action." % (self.var, repr(c)))
return gen_cmd
def _generate(self, target, source, env, for_signature):
return self._generate_cache(env)
def __call__(self, target, source, env, *args, **kw):
args = (self, target, source, env) + args
c = self.get_parent_class(env)
#TODO(1.5) return c.__call__(*args, **kw)
return apply(c.__call__, args, kw)
def get_presig(self, target, source, env):
c = self.get_parent_class(env)
return c.get_presig(self, target, source, env)
class FunctionAction(_ActionAction):
"""Class for Python function actions."""
def __init__(self, execfunction, kw):
if __debug__: logInstanceCreation(self, 'Action.FunctionAction')
self.execfunction = execfunction
try:
self.funccontents = _callable_contents(execfunction)
except AttributeError:
try:
# See if execfunction will do the heavy lifting for us.
self.gc = execfunction.get_contents
except AttributeError:
# This is weird, just do the best we can.
self.funccontents = _object_contents(execfunction)
#TODO(1.5) _ActionAction.__init__(self, **kw)
apply(_ActionAction.__init__, (self,), kw)
def function_name(self):
try:
return self.execfunction.__name__
except AttributeError:
try:
return self.execfunction.__class__.__name__
except AttributeError:
return "unknown_python_function"
def strfunction(self, target, source, env):
if self.cmdstr is None:
return None
if self.cmdstr is not _null:
from SCons.Subst import SUBST_RAW
c = env.subst(self.cmdstr, SUBST_RAW, target, source)
if c:
return c
def array(a):
def quote(s):
try:
str_for_display = s.str_for_display
except AttributeError:
s = repr(s)
else:
s = str_for_display()
return s
return '[' + string.join(map(quote, a), ", ") + ']'
try:
strfunc = self.execfunction.strfunction
except AttributeError:
pass
else:
if strfunc is None:
return None
if callable(strfunc):
return strfunc(target, source, env)
name = self.function_name()
tstr = array(target)
sstr = array(source)
return "%s(%s, %s)" % (name, tstr, sstr)
def __str__(self):
name = self.function_name()
if name == 'ActionCaller':
return str(self.execfunction)
return "%s(target, source, env)" % name
def execute(self, target, source, env):
exc_info = (None,None,None)
try:
rsources = map(rfile, source)
try:
result = self.execfunction(target=target, source=rsources, env=env)
except KeyboardInterrupt, e:
raise
except SystemExit, e:
raise
except Exception, e:
result = e
exc_info = sys.exc_info()
if result:
result = SCons.Errors.convert_to_BuildError(result, exc_info)
result.node=target
result.action=self
result.command=self.strfunction(target, source, env)
# FIXME: This maintains backward compatibility with respect to
# which type of exceptions were returned by raising an
# exception and which ones were returned by value. It would
# probably be best to always return them by value here, but
# some codes do not check the return value of Actions and I do
# not have the time to modify them at this point.
if (exc_info[1] and
not isinstance(exc_info[1],EnvironmentError)):
raise result
return result
finally:
# Break the cycle between the traceback object and this
# function stack frame. See the sys.exc_info() doc info for
# more information about this issue.
del exc_info
def get_presig(self, target, source, env):
"""Return the signature contents of this callable action."""
try:
return self.gc(target, source, env)
except AttributeError:
return self.funccontents
def get_implicit_deps(self, target, source, env):
return []
class ListAction(ActionBase):
"""Class for lists of other actions."""
def __init__(self, list):
if __debug__: logInstanceCreation(self, 'Action.ListAction')
def list_of_actions(x):
if isinstance(x, ActionBase):
return x
return Action(x)
self.list = map(list_of_actions, list)
# our children will have had any varlist
# applied; we don't need to do it again
self.varlist = ()
def genstring(self, target, source, env):
return string.join(map(lambda a, t=target, s=source, e=env:
a.genstring(t, s, e),
self.list),
'\n')
def __str__(self):
return string.join(map(str, self.list), '\n')
def presub_lines(self, env):
return SCons.Util.flatten_sequence(
map(lambda a, env=env: a.presub_lines(env), self.list))
def get_presig(self, target, source, env):
"""Return the signature contents of this action list.
Simple concatenation of the signatures of the elements.
"""
return string.join(map(lambda x, t=target, s=source, e=env:
x.get_contents(t, s, e),
self.list),
"")
def __call__(self, target, source, env, exitstatfunc=_null, presub=_null,
show=_null, execute=_null, chdir=_null):
for act in self.list:
stat = act(target, source, env, exitstatfunc, presub,
show, execute, chdir)
if stat:
return stat
return 0
def get_implicit_deps(self, target, source, env):
result = []
for act in self.list:
result.extend(act.get_implicit_deps(target, source, env))
return result
class ActionCaller:
"""A class for delaying calling an Action function with specific
(positional and keyword) arguments until the Action is actually
executed.
This class looks to the rest of the world like a normal Action object,
but what it's really doing is hanging on to the arguments until we
have a target, source and env to use for the expansion.
"""
def __init__(self, parent, args, kw):
self.parent = parent
self.args = args
self.kw = kw
def get_contents(self, target, source, env):
actfunc = self.parent.actfunc
try:
# "self.actfunc" is a function.
contents = str(actfunc.func_code.co_code)
except AttributeError:
# "self.actfunc" is a callable object.
try:
contents = str(actfunc.__call__.im_func.func_code.co_code)
except AttributeError:
# No __call__() method, so it might be a builtin
# or something like that. Do the best we can.
contents = str(actfunc)
contents = remove_set_lineno_codes(contents)
return contents
def subst(self, s, target, source, env):
# If s is a list, recursively apply subst()
# to every element in the list
if is_List(s):
result = []
for elem in s:
result.append(self.subst(elem, target, source, env))
return self.parent.convert(result)
# Special-case hack: Let a custom function wrapped in an
# ActionCaller get at the environment through which the action
# was called by using this hard-coded value as a special return.
if s == '$__env__':
return env
elif is_String(s):
return env.subst(s, 1, target, source)
return self.parent.convert(s)
def subst_args(self, target, source, env):
return map(lambda x, self=self, t=target, s=source, e=env:
self.subst(x, t, s, e),
self.args)
def subst_kw(self, target, source, env):
kw = {}
for key in self.kw.keys():
kw[key] = self.subst(self.kw[key], target, source, env)
return kw
def __call__(self, target, source, env):
args = self.subst_args(target, source, env)
kw = self.subst_kw(target, source, env)
#TODO(1.5) return self.parent.actfunc(*args, **kw)
return apply(self.parent.actfunc, args, kw)
def strfunction(self, target, source, env):
args = self.subst_args(target, source, env)
kw = self.subst_kw(target, source, env)
#TODO(1.5) return self.parent.strfunc(*args, **kw)
return apply(self.parent.strfunc, args, kw)
def __str__(self):
#TODO(1.5) return self.parent.strfunc(*self.args, **self.kw)
return apply(self.parent.strfunc, self.args, self.kw)
class ActionFactory:
"""A factory class that will wrap up an arbitrary function
as an SCons-executable Action object.
The real heavy lifting here is done by the ActionCaller class.
We just collect the (positional and keyword) arguments that we're
called with and give them to the ActionCaller object we create,
so it can hang onto them until it needs them.
"""
def __init__(self, actfunc, strfunc, convert=lambda x: x):
self.actfunc = actfunc
self.strfunc = strfunc
self.convert = convert
def __call__(self, *args, **kw):
ac = ActionCaller(self, args, kw)
action = Action(ac, strfunction=ac.strfunction)
return action