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# Copyright (c) 2006-2008 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: Lisa Hsu
from os import getcwd
from os.path import join as joinpath
import m5
from m5.defines import buildEnv
from m5.objects import *
from m5.util import *
addToPath('../common')
def setCPUClass(options):
atomic = False
if options.timing:
class TmpClass(TimingSimpleCPU): pass
elif options.detailed:
if not options.caches:
print "O3 CPU must be used with caches"
sys.exit(1)
class TmpClass(DerivO3CPU): pass
elif options.inorder:
if not options.caches:
print "InOrder CPU must be used with caches"
sys.exit(1)
class TmpClass(InOrderCPU): pass
else:
class TmpClass(AtomicSimpleCPU): pass
atomic = True
CPUClass = None
test_mem_mode = 'atomic'
if not atomic:
if options.checkpoint_restore != None or options.fast_forward:
CPUClass = TmpClass
class TmpClass(AtomicSimpleCPU): pass
else:
test_mem_mode = 'timing'
return (TmpClass, test_mem_mode, CPUClass)
def run(options, root, testsys, cpu_class):
if options.maxtick:
maxtick = options.maxtick
elif options.maxtime:
simtime = m5.ticks.seconds(simtime)
print "simulating for: ", simtime
maxtick = simtime
else:
maxtick = m5.MaxTick
if options.checkpoint_dir:
cptdir = options.checkpoint_dir
elif m5.options.outdir:
cptdir = m5.options.outdir
else:
cptdir = getcwd()
if options.fast_forward and options.checkpoint_restore != None:
fatal("Can't specify both --fast-forward and --checkpoint-restore")
if options.standard_switch and not options.caches:
fatal("Must specify --caches when using --standard-switch")
np = options.num_cpus
max_checkpoints = options.max_checkpoints
switch_cpus = None
if options.prog_intvl:
for i in xrange(np):
testsys.cpu[i].progress_interval = options.prog_intvl
if options.maxinsts:
for i in xrange(np):
testsys.cpu[i].max_insts_any_thread = options.maxinsts
if cpu_class:
switch_cpus = [cpu_class(defer_registration=True, cpu_id=(np+i))
for i in xrange(np)]
for i in xrange(np):
if options.fast_forward:
testsys.cpu[i].max_insts_any_thread = int(options.fast_forward)
switch_cpus[i].system = testsys
if not buildEnv['FULL_SYSTEM']:
switch_cpus[i].workload = testsys.cpu[i].workload
switch_cpus[i].clock = testsys.cpu[0].clock
# simulation period
if options.max_inst:
switch_cpus[i].max_insts_any_thread = options.max_inst
testsys.switch_cpus = switch_cpus
switch_cpu_list = [(testsys.cpu[i], switch_cpus[i]) for i in xrange(np)]
if options.standard_switch:
switch_cpus = [TimingSimpleCPU(defer_registration=True, cpu_id=(np+i))
for i in xrange(np)]
switch_cpus_1 = [DerivO3CPU(defer_registration=True, cpu_id=(2*np+i))
for i in xrange(np)]
for i in xrange(np):
switch_cpus[i].system = testsys
switch_cpus_1[i].system = testsys
if not buildEnv['FULL_SYSTEM']:
switch_cpus[i].workload = testsys.cpu[i].workload
switch_cpus_1[i].workload = testsys.cpu[i].workload
switch_cpus[i].clock = testsys.cpu[0].clock
switch_cpus_1[i].clock = testsys.cpu[0].clock
# if restoring, make atomic cpu simulate only a few instructions
if options.checkpoint_restore != None:
testsys.cpu[i].max_insts_any_thread = 1
# Fast forward to specified location if we are not restoring
elif options.fast_forward:
testsys.cpu[i].max_insts_any_thread = int(options.fast_forward)
# Fast forward to a simpoint (warning: time consuming)
elif options.simpoint:
if testsys.cpu[i].workload[0].simpoint == 0:
fatal('simpoint not found')
testsys.cpu[i].max_insts_any_thread = \
testsys.cpu[i].workload[0].simpoint
# No distance specified, just switch
else:
testsys.cpu[i].max_insts_any_thread = 1
# warmup period
if options.warmup_insts:
switch_cpus[i].max_insts_any_thread = options.warmup_insts
# simulation period
if options.max_inst:
switch_cpus_1[i].max_insts_any_thread = options.max_inst
if not options.caches:
# O3 CPU must have a cache to work.
print "O3 CPU must be used with caches"
sys.exit(1)
testsys.switch_cpus = switch_cpus
testsys.switch_cpus_1 = switch_cpus_1
switch_cpu_list = [(testsys.cpu[i], switch_cpus[i]) for i in xrange(np)]
switch_cpu_list1 = [(switch_cpus[i], switch_cpus_1[i]) for i in xrange(np)]
# set the checkpoint in the cpu before m5.instantiate is called
if options.take_checkpoints != None and \
(options.simpoint or options.at_instruction):
offset = int(options.take_checkpoints)
# Set an instruction break point
if options.simpoint:
for i in xrange(np):
if testsys.cpu[i].workload[0].simpoint == 0:
fatal('no simpoint for testsys.cpu[%d].workload[0]', i)
checkpoint_inst = int(testsys.cpu[i].workload[0].simpoint) + offset
testsys.cpu[i].max_insts_any_thread = checkpoint_inst
# used for output below
options.take_checkpoints = checkpoint_inst
else:
options.take_checkpoints = offset
# Set all test cpus with the right number of instructions
# for the upcoming simulation
for i in xrange(np):
testsys.cpu[i].max_insts_any_thread = offset
m5.instantiate()
if options.checkpoint_restore != None:
from os.path import isdir, exists
from os import listdir
import re
if not isdir(cptdir):
fatal("checkpoint dir %s does not exist!", cptdir)
if options.at_instruction:
checkpoint_dir = joinpath(cptdir, "cpt.%s.%s" % \
(options.bench, options.checkpoint_restore))
if not exists(checkpoint_dir):
fatal("Unable to find checkpoint directory %s", checkpoint_dir)
print "Restoring checkpoint ..."
m5.restoreCheckpoint(checkpoint_dir)
print "Done."
elif options.simpoint:
# assume workload 0 has the simpoint
if testsys.cpu[0].workload[0].simpoint == 0:
fatal('Unable to find simpoint')
options.checkpoint_restore += \
int(testsys.cpu[0].workload[0].simpoint)
checkpoint_dir = joinpath(cptdir, "cpt.%s.%d" % \
(options.bench, options.checkpoint_restore))
if not exists(checkpoint_dir):
fatal("Unable to find checkpoint directory %s.%s",
options.bench, options.checkpoint_restore)
print "Restoring checkpoint ..."
m5.restoreCheckpoint(checkpoint_dir)
print "Done."
else:
dirs = listdir(cptdir)
expr = re.compile('cpt\.([0-9]*)')
cpts = []
for dir in dirs:
match = expr.match(dir)
if match:
cpts.append(match.group(1))
cpts.sort(lambda a,b: cmp(long(a), long(b)))
cpt_num = options.checkpoint_restore
if cpt_num > len(cpts):
fatal('Checkpoint %d not found', cpt_num)
## Adjust max tick based on our starting tick
maxtick = maxtick - int(cpts[cpt_num - 1])
## Restore the checkpoint
m5.restoreCheckpoint(joinpath(cptdir,
"cpt.%s" % cpts[cpt_num - 1]))
if options.standard_switch or cpu_class:
if options.standard_switch:
print "Switch at instruction count:%s" % \
str(testsys.cpu[0].max_insts_any_thread)
exit_event = m5.simulate()
elif cpu_class and options.fast_forward:
print "Switch at instruction count:%s" % \
str(testsys.cpu[0].max_insts_any_thread)
exit_event = m5.simulate()
else:
print "Switch at curTick count:%s" % str(10000)
exit_event = m5.simulate(10000)
print "Switched CPUS @ cycle = %s" % (m5.curTick())
# when you change to Timing (or Atomic), you halt the system
# given as argument. When you are finished with the system
# changes (including switchCpus), you must resume the system
# manually. You DON'T need to resume after just switching
# CPUs if you haven't changed anything on the system level.
m5.changeToTiming(testsys)
m5.switchCpus(switch_cpu_list)
m5.resume(testsys)
if options.standard_switch:
print "Switch at instruction count:%d" % \
(testsys.switch_cpus[0].max_insts_any_thread)
#warmup instruction count may have already been set
if options.warmup_insts:
exit_event = m5.simulate()
else:
exit_event = m5.simulate(options.warmup)
print "Switching CPUS @ cycle = %s" % (m5.curTick())
print "Simulation ends instruction count:%d" % \
(testsys.switch_cpus_1[0].max_insts_any_thread)
m5.drain(testsys)
m5.switchCpus(switch_cpu_list1)
m5.resume(testsys)
num_checkpoints = 0
exit_cause = ''
# If we're taking and restoring checkpoints, use checkpoint_dir
# option only for finding the checkpoints to restore from. This
# lets us test checkpointing by restoring from one set of
# checkpoints, generating a second set, and then comparing them.
if options.take_checkpoints and options.checkpoint_restore:
if m5.options.outdir:
cptdir = m5.options.outdir
else:
cptdir = getcwd()
# Checkpoints being taken via the command line at <when> and at
# subsequent periods of <period>. Checkpoint instructions
# received from the benchmark running are ignored and skipped in
# favor of command line checkpoint instructions.
if options.take_checkpoints != None :
if options.at_instruction or options.simpoint:
checkpoint_inst = int(options.take_checkpoints)
# maintain correct offset if we restored from some instruction
if options.checkpoint_restore != None:
checkpoint_inst += options.checkpoint_restore
print "Creating checkpoint at inst:%d" % (checkpoint_inst)
exit_event = m5.simulate()
print "exit cause = %s" % (exit_event.getCause())
# skip checkpoint instructions should they exist
while exit_event.getCause() == "checkpoint":
exit_event = m5.simulate()
if exit_event.getCause() == \
"a thread reached the max instruction count":
m5.checkpoint(joinpath(cptdir, "cpt.%s.%d" % \
(options.bench, checkpoint_inst)))
print "Checkpoint written."
num_checkpoints += 1
if exit_event.getCause() == "user interrupt received":
exit_cause = exit_event.getCause();
else:
when, period = options.take_checkpoints.split(",", 1)
when = int(when)
period = int(period)
exit_event = m5.simulate(when)
while exit_event.getCause() == "checkpoint":
exit_event = m5.simulate(when - m5.curTick())
if exit_event.getCause() == "simulate() limit reached":
m5.checkpoint(joinpath(cptdir, "cpt.%d"))
num_checkpoints += 1
sim_ticks = when
exit_cause = "maximum %d checkpoints dropped" % max_checkpoints
while num_checkpoints < max_checkpoints and \
exit_event.getCause() == "simulate() limit reached":
if (sim_ticks + period) > maxtick:
exit_event = m5.simulate(maxtick - sim_ticks)
exit_cause = exit_event.getCause()
break
else:
exit_event = m5.simulate(period)
sim_ticks += period
while exit_event.getCause() == "checkpoint":
exit_event = m5.simulate(sim_ticks - m5.curTick())
if exit_event.getCause() == "simulate() limit reached":
m5.checkpoint(joinpath(cptdir, "cpt.%d"))
num_checkpoints += 1
if exit_event.getCause() != "simulate() limit reached":
exit_cause = exit_event.getCause();
else: # no checkpoints being taken via this script
if options.fast_forward:
m5.stats.reset()
print "**** REAL SIMULATION ****"
exit_event = m5.simulate(maxtick)
while exit_event.getCause() == "checkpoint":
m5.checkpoint(joinpath(cptdir, "cpt.%d"))
num_checkpoints += 1
if num_checkpoints == max_checkpoints:
exit_cause = "maximum %d checkpoints dropped" % max_checkpoints
break
exit_event = m5.simulate(maxtick - m5.curTick())
exit_cause = exit_event.getCause()
if exit_cause == '':
exit_cause = exit_event.getCause()
print 'Exiting @ cycle %i because %s' % (m5.curTick(), exit_cause)
if options.checkpoint_at_end:
m5.checkpoint(joinpath(cptdir, "cpt.%d"))
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