src/python/m5/__init__.py - arm/gem5 - Git at Google

 # Copyright (c) 2005 The Regents of The University of Michigan
 # 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 the copyright holders 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.
 #
 # Authors: Nathan Binkert
 #          Steve Reinhardt

 import atexit, os, sys

 # import the SWIG-wrapped main C++ functions
 import internal
 # import a few SWIG-wrapped items (those that are likely to be used
 # directly by user scripts) completely into this module for
 # convenience
 from internal.main import simulate, SimLoopExitEvent

 # import the m5 compile options
 import defines

 # define a MaxTick parameter
 MaxTick = 2**63 - 1

 # define this here so we can use it right away if necessary
 def panic(string):
     print >>sys.stderr, 'panic:', string
     sys.exit(1)

 # force scalars to one-element lists for uniformity
 def makeList(objOrList):
     if isinstance(objOrList, list):
         return objOrList
     return [objOrList]

 # Prepend given directory to system module search path.  We may not
 # need this anymore if we can structure our config library more like a
 # Python package.
 def AddToPath(path):
     # if it's a relative path and we know what directory the current
     # python script is in, make the path relative to that directory.
     if not os.path.isabs(path) and sys.path[0]:
         path = os.path.join(sys.path[0], path)
     path = os.path.realpath(path)
     # sys.path[0] should always refer to the current script's directory,
     # so place the new dir right after that.
     sys.path.insert(1, path)

 # make a SmartDict out of the build options for our local use
 import smartdict
 build_env = smartdict.SmartDict()
 build_env.update(defines.m5_build_env)

 # make a SmartDict out of the OS environment too
 env = smartdict.SmartDict()
 env.update(os.environ)

 # The final hook to generate .ini files.  Called from the user script
 # once the config is built.
 def instantiate(root):
     params.ticks_per_sec = float(root.clock.frequency)
     root.unproxy_all()
     # ugly temporary hack to get output to config.ini
     sys.stdout = file(os.path.join(options.outdir, 'config.ini'), 'w')
     root.print_ini()
     sys.stdout.close() # close config.ini
     sys.stdout = sys.__stdout__ # restore to original
     internal.main.loadIniFile(resolveSimObject)  # load config.ini into C++
     root.createCCObject()
     root.connectPorts()
     internal.main.finalInit()
     noDot = True # temporary until we fix dot
     if not noDot:
        dot = pydot.Dot()
        instance.outputDot(dot)
        dot.orientation = "portrait"
        dot.size = "8.5,11"
        dot.ranksep="equally"
        dot.rank="samerank"
        dot.write("config.dot")
        dot.write_ps("config.ps")

 # Export curTick to user script.
 def curTick():
     return internal.main.cvar.curTick

 # register our C++ exit callback function with Python
 atexit.register(internal.main.doExitCleanup)

 # This loops until all objects have been fully drained.
 def doDrain(root):
     all_drained = drain(root)
     while (not all_drained):
         all_drained = drain(root)

 # Tries to drain all objects.  Draining might not be completed unless
 # all objects return that they are drained on the first call.  This is
 # because as objects drain they may cause other objects to no longer
 # be drained.
 def drain(root):
     all_drained = False
     drain_event = internal.main.createCountedDrain()
     unready_objects = root.startDrain(drain_event, True)
     # If we've got some objects that can't drain immediately, then simulate
     if unready_objects > 0:
         drain_event.setCount(unready_objects)
         simulate()
     else:
         all_drained = True
     internal.main.cleanupCountedDrain(drain_event)
     return all_drained

 def resume(root):
     root.resume()

 def checkpoint(root, dir):
     if not isinstance(root, objects.Root):
         raise TypeError, "Object is not a root object. Checkpoint must be called on a root object."
     doDrain(root)
     print "Writing checkpoint"
     internal.main.serializeAll(dir)
     resume(root)

 def restoreCheckpoint(root, dir):
     print "Restoring from checkpoint"
     internal.main.unserializeAll(dir)
     resume(root)

 def changeToAtomic(system):
     if not isinstance(system, objects.Root) and not isinstance(system, objects.System):
         raise TypeError, "Object is not a root or system object.  Checkpoint must be "
         "called on a root object."
     doDrain(system)
     print "Changing memory mode to atomic"
     system.changeTiming(internal.main.SimObject.Atomic)

 def changeToTiming(system):
     if not isinstance(system, objects.Root) and not isinstance(system, objects.System):
         raise TypeError, "Object is not a root or system object.  Checkpoint must be "
         "called on a root object."
     doDrain(system)
     print "Changing memory mode to timing"
     system.changeTiming(internal.main.SimObject.Timing)

 def switchCpus(cpuList):
     print "switching cpus"
     if not isinstance(cpuList, list):
         raise RuntimeError, "Must pass a list to this function"
     for i in cpuList:
         if not isinstance(i, tuple):
             raise RuntimeError, "List must have tuples of (oldCPU,newCPU)"

     [old_cpus, new_cpus] = zip(*cpuList)

     for cpu in old_cpus:
         if not isinstance(cpu, objects.BaseCPU):
             raise TypeError, "%s is not of type BaseCPU" % cpu
     for cpu in new_cpus:
         if not isinstance(cpu, objects.BaseCPU):
             raise TypeError, "%s is not of type BaseCPU" % cpu

     # Drain all of the individual CPUs
     drain_event = internal.main.createCountedDrain()
     unready_cpus = 0
     for old_cpu in old_cpus:
         unready_cpus += old_cpu.startDrain(drain_event, False)
     # If we've got some objects that can't drain immediately, then simulate
     if unready_cpus > 0:
         drain_event.setCount(unready_cpus)
         simulate()
     internal.main.cleanupCountedDrain(drain_event)
     # Now all of the CPUs are ready to be switched out
     for old_cpu in old_cpus:
         old_cpu._ccObject.switchOut()
     index = 0
     for new_cpu in new_cpus:
         new_cpu.takeOverFrom(old_cpus[index])
         new_cpu._ccObject.resume()
         index += 1

 # Since we have so many mutual imports in this package, we should:
 # 1. Put all intra-package imports at the *bottom* of the file, unless
 #    they're absolutely needed before that (for top-level statements
 #    or class attributes).  Imports of "trivial" packages that don't
 #    import other packages (e.g., 'smartdict') can be at the top.
 # 2. Never use 'from foo import *' on an intra-package import since
 #    you can get the wrong result if foo is only partially imported
 #    at the point you do that (i.e., because foo is in the middle of
 #    importing *you*).
 from main import options
 import objects
 import params
 from SimObject import resolveSimObject
	# Copyright (c) 2005 The Regents of The University of Michigan
	# 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 the copyright holders 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.
	#
	# Authors: Nathan Binkert
	# Steve Reinhardt

	import atexit, os, sys

	# import the SWIG-wrapped main C++ functions
	import internal
	# import a few SWIG-wrapped items (those that are likely to be used
	# directly by user scripts) completely into this module for
	# convenience
	from internal.main import simulate, SimLoopExitEvent

	# import the m5 compile options
	import defines

	# define a MaxTick parameter
	MaxTick = 2**63 - 1

	# define this here so we can use it right away if necessary
	def panic(string):
	print >>sys.stderr, 'panic:', string
	sys.exit(1)

	# force scalars to one-element lists for uniformity
	def makeList(objOrList):
	if isinstance(objOrList, list):
	return objOrList
	return [objOrList]

	# Prepend given directory to system module search path. We may not
	# need this anymore if we can structure our config library more like a
	# Python package.
	def AddToPath(path):
	# if it's a relative path and we know what directory the current
	# python script is in, make the path relative to that directory.
	if not os.path.isabs(path) and sys.path[0]:
	path = os.path.join(sys.path[0], path)
	path = os.path.realpath(path)
	# sys.path[0] should always refer to the current script's directory,
	# so place the new dir right after that.
	sys.path.insert(1, path)

	# make a SmartDict out of the build options for our local use
	import smartdict
	build_env = smartdict.SmartDict()
	build_env.update(defines.m5_build_env)

	# make a SmartDict out of the OS environment too
	env = smartdict.SmartDict()
	env.update(os.environ)

	# The final hook to generate .ini files. Called from the user script
	# once the config is built.
	def instantiate(root):
	params.ticks_per_sec = float(root.clock.frequency)
	root.unproxy_all()
	# ugly temporary hack to get output to config.ini
	sys.stdout = file(os.path.join(options.outdir, 'config.ini'), 'w')
	root.print_ini()
	sys.stdout.close() # close config.ini
	sys.stdout = sys.__stdout__ # restore to original
	internal.main.loadIniFile(resolveSimObject) # load config.ini into C++
	root.createCCObject()
	root.connectPorts()
	internal.main.finalInit()
	noDot = True # temporary until we fix dot
	if not noDot:
	dot = pydot.Dot()
	instance.outputDot(dot)
	dot.orientation = "portrait"
	dot.size = "8.5,11"
	dot.ranksep="equally"
	dot.rank="samerank"
	dot.write("config.dot")
	dot.write_ps("config.ps")

	# Export curTick to user script.
	def curTick():
	return internal.main.cvar.curTick

	# register our C++ exit callback function with Python
	atexit.register(internal.main.doExitCleanup)

	# This loops until all objects have been fully drained.
	def doDrain(root):
	all_drained = drain(root)
	while (not all_drained):
	all_drained = drain(root)

	# Tries to drain all objects. Draining might not be completed unless
	# all objects return that they are drained on the first call. This is
	# because as objects drain they may cause other objects to no longer
	# be drained.
	def drain(root):
	all_drained = False
	drain_event = internal.main.createCountedDrain()
	unready_objects = root.startDrain(drain_event, True)
	# If we've got some objects that can't drain immediately, then simulate
	if unready_objects > 0:
	drain_event.setCount(unready_objects)
	simulate()
	else:
	all_drained = True
	internal.main.cleanupCountedDrain(drain_event)
	return all_drained

	def resume(root):
	root.resume()

	def checkpoint(root, dir):
	if not isinstance(root, objects.Root):
	raise TypeError, "Object is not a root object. Checkpoint must be called on a root object."
	doDrain(root)
	print "Writing checkpoint"
	internal.main.serializeAll(dir)
	resume(root)

	def restoreCheckpoint(root, dir):
	print "Restoring from checkpoint"
	internal.main.unserializeAll(dir)
	resume(root)

	def changeToAtomic(system):
	if not isinstance(system, objects.Root) and not isinstance(system, objects.System):
	raise TypeError, "Object is not a root or system object. Checkpoint must be "
	"called on a root object."
	doDrain(system)
	print "Changing memory mode to atomic"
	system.changeTiming(internal.main.SimObject.Atomic)

	def changeToTiming(system):
	if not isinstance(system, objects.Root) and not isinstance(system, objects.System):
	raise TypeError, "Object is not a root or system object. Checkpoint must be "
	"called on a root object."
	doDrain(system)
	print "Changing memory mode to timing"
	system.changeTiming(internal.main.SimObject.Timing)

	def switchCpus(cpuList):
	print "switching cpus"
	if not isinstance(cpuList, list):
	raise RuntimeError, "Must pass a list to this function"
	for i in cpuList:
	if not isinstance(i, tuple):
	raise RuntimeError, "List must have tuples of (oldCPU,newCPU)"

	[old_cpus, new_cpus] = zip(*cpuList)

	for cpu in old_cpus:
	if not isinstance(cpu, objects.BaseCPU):
	raise TypeError, "%s is not of type BaseCPU" % cpu
	for cpu in new_cpus:
	if not isinstance(cpu, objects.BaseCPU):
	raise TypeError, "%s is not of type BaseCPU" % cpu

	# Drain all of the individual CPUs
	drain_event = internal.main.createCountedDrain()
	unready_cpus = 0
	for old_cpu in old_cpus:
	unready_cpus += old_cpu.startDrain(drain_event, False)
	# If we've got some objects that can't drain immediately, then simulate
	if unready_cpus > 0:
	drain_event.setCount(unready_cpus)
	simulate()
	internal.main.cleanupCountedDrain(drain_event)
	# Now all of the CPUs are ready to be switched out
	for old_cpu in old_cpus:
	old_cpu._ccObject.switchOut()
	index = 0
	for new_cpu in new_cpus:
	new_cpu.takeOverFrom(old_cpus[index])
	new_cpu._ccObject.resume()
	index += 1

	# Since we have so many mutual imports in this package, we should:
	# 1. Put all intra-package imports at the bottom of the file, unless
	# they're absolutely needed before that (for top-level statements
	# or class attributes). Imports of "trivial" packages that don't
	# import other packages (e.g., 'smartdict') can be at the top.
	# 2. Never use 'from foo import *' on an intra-package import since
	# you can get the wrong result if foo is only partially imported
	# at the point you do that (i.e., because foo is in the middle of
	# importing you).
	from main import options
	import objects
	import params
	from SimObject import resolveSimObject