configs/splash2/cluster.py - public/gem5 - Git at Google

 # Copyright (c) 2006-2007 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: Ron Dreslinski

 # Simple test script
 #
 # "m5 test.py"

 from __future__ import print_function

 import os
 import optparse
 import sys

 import m5
 from m5.objects import *

 # --------------------
 # Define Command Line Options
 # ====================

 parser = optparse.OptionParser()

 parser.add_option("-d", "--detailed", action="store_true")
 parser.add_option("-t", "--timing", action="store_true")
 parser.add_option("-m", "--maxtick", type="int")
 parser.add_option("-c", "--numclusters",
                   help="Number of clusters", type="int")
 parser.add_option("-n", "--numcpus",
                   help="Number of cpus in total", type="int")
 parser.add_option("-f", "--frequency",
                   default = "1GHz",
                   help="Frequency of each CPU")
 parser.add_option("--l1size",
                   default = "32kB")
 parser.add_option("--l1latency",
                   default = 1)
 parser.add_option("--l2size",
                   default = "256kB")
 parser.add_option("--l2latency",
                   default = 10)
 parser.add_option("--rootdir",
                   help="ROot directory of Splash2",
                   default="/dist/splash2/codes/")
 parser.add_option("-b", "--benchmark",
                   help="Splash 2 benchmark to run")

 (options, args) = parser.parse_args()

 if args:
     print("Error: script doesn't take any positional arguments")
     sys.exit(1)

 # --------------------
 # Define Splash2 Benchmarks
 # ====================
 class Cholesky(Process):
         executable = options.rootdir + '/kernels/cholesky/CHOLESKY'
         cmd = 'CHOLESKY -p' + str(options.numcpus) + ' '\
              + options.rootdir + '/kernels/cholesky/inputs/tk23.O'

 class FFT(Process):
         executable = options.rootdir + 'kernels/fft/FFT'
         cmd = 'FFT -p' + str(options.numcpus) + ' -m18'

 class LU_contig(Process):
         executable = options.rootdir + 'kernels/lu/contiguous_blocks/LU'
         cmd = 'LU -p' + str(options.numcpus)

 class LU_noncontig(Process):
         executable = options.rootdir + 'kernels/lu/non_contiguous_blocks/LU'
         cmd = 'LU -p' + str(options.numcpus)

 class Radix(Process):
         executable = options.rootdir + 'kernels/radix/RADIX'
         cmd = 'RADIX -n524288 -p' + str(options.numcpus)

 class Barnes(Process):
         executable = options.rootdir + 'apps/barnes/BARNES'
         cmd = 'BARNES'
         input = options.rootdir + 'apps/barnes/input.p' + str(options.numcpus)

 class FMM(Process):
         executable = options.rootdir + 'apps/fmm/FMM'
         cmd = 'FMM'
         input = options.rootdir + 'apps/fmm/inputs/input.2048.p' + str(options.numcpus)

 class Ocean_contig(Process):
         executable = options.rootdir + 'apps/ocean/contiguous_partitions/OCEAN'
         cmd = 'OCEAN -p' + str(options.numcpus)

 class Ocean_noncontig(Process):
         executable = options.rootdir + 'apps/ocean/non_contiguous_partitions/OCEAN'
         cmd = 'OCEAN -p' + str(options.numcpus)

 class Raytrace(Process):
         executable = options.rootdir + 'apps/raytrace/RAYTRACE'
         cmd = 'RAYTRACE -p' + str(options.numcpus) + ' ' \
              + options.rootdir + 'apps/raytrace/inputs/teapot.env'

 class Water_nsquared(Process):
         executable = options.rootdir + 'apps/water-nsquared/WATER-NSQUARED'
         cmd = 'WATER-NSQUARED'
         input = options.rootdir + 'apps/water-nsquared/input.p' + str(options.numcpus)

 class Water_spatial(Process):
         executable = options.rootdir + 'apps/water-spatial/WATER-SPATIAL'
         cmd = 'WATER-SPATIAL'
         input = options.rootdir + 'apps/water-spatial/input.p' + str(options.numcpus)


 # --------------------
 # Base L1 Cache Definition
 # ====================

 class L1(Cache):
     latency = options.l1latency
     mshrs = 12
     tgts_per_mshr = 8

 # ----------------------
 # Base L2 Cache Definition
 # ----------------------

 class L2(Cache):
     latency = options.l2latency
     mshrs = 92
     tgts_per_mshr = 16
     write_buffers = 8

 # ----------------------
 # Define the clusters with their cpus
 # ----------------------
 class Cluster:
     pass

 cpusPerCluster = options.numcpus/options.numclusters

 busFrequency = Frequency(options.frequency)
 busFrequency *= cpusPerCluster

 all_cpus = []
 all_l1s = []
 all_l1buses = []
 if options.timing:
     clusters = [ Cluster() for i in xrange(options.numclusters)]
     for j in xrange(options.numclusters):
         clusters[j].id = j
     for cluster in clusters:
         cluster.clusterbus = L2XBar(clock=busFrequency)
         all_l1buses += [cluster.clusterbus]
         cluster.cpus = [TimingSimpleCPU(cpu_id = i + cluster.id,
                                         clock=options.frequency)
                         for i in xrange(cpusPerCluster)]
         all_cpus += cluster.cpus
         cluster.l1 = L1(size=options.l1size, assoc = 4)
         all_l1s += [cluster.l1]
 elif options.detailed:
     clusters = [ Cluster() for i in xrange(options.numclusters)]
     for j in xrange(options.numclusters):
         clusters[j].id = j
     for cluster in clusters:
         cluster.clusterbus = L2XBar(clock=busFrequency)
         all_l1buses += [cluster.clusterbus]
         cluster.cpus = [DerivO3CPU(cpu_id = i + cluster.id,
                                    clock=options.frequency)
                         for i in xrange(cpusPerCluster)]
         all_cpus += cluster.cpus
         cluster.l1 = L1(size=options.l1size, assoc = 4)
         all_l1s += [cluster.l1]
 else:
     clusters = [ Cluster() for i in xrange(options.numclusters)]
     for j in xrange(options.numclusters):
         clusters[j].id = j
     for cluster in clusters:
         cluster.clusterbus = L2XBar(clock=busFrequency)
         all_l1buses += [cluster.clusterbus]
         cluster.cpus = [AtomicSimpleCPU(cpu_id = i + cluster.id,
                                         clock=options.frequency)
                         for i in xrange(cpusPerCluster)]
         all_cpus += cluster.cpus
         cluster.l1 = L1(size=options.l1size, assoc = 4)
         all_l1s += [cluster.l1]

 # ----------------------
 # Create a system, and add system wide objects
 # ----------------------
 system = System(cpu = all_cpus, l1_ = all_l1s, l1bus_ = all_l1buses,
                 physmem = SimpleMemory(),
                 membus = SystemXBar(clock = busFrequency))
 system.clock = '1GHz'

 system.toL2bus = L2XBar(clock = busFrequency)
 system.l2 = L2(size = options.l2size, assoc = 8)

 # ----------------------
 # Connect the L2 cache and memory together
 # ----------------------

 system.physmem.port = system.membus.master
 system.l2.cpu_side = system.toL2bus.slave
 system.l2.mem_side = system.membus.master

 # ----------------------
 # Connect the L2 cache and clusters together
 # ----------------------
 for cluster in clusters:
     cluster.l1.cpu_side = cluster.clusterbus.master
     cluster.l1.mem_side = system.toL2bus.slave
     for cpu in cluster.cpus:
         cpu.icache_port = cluster.clusterbus.slave
         cpu.dcache_port = cluster.clusterbus.slave

 # ----------------------
 # Define the root
 # ----------------------

 root = Root(full_system = False, system = system)

 # --------------------
 # Pick the correct Splash2 Benchmarks
 # ====================
 if options.benchmark == 'Cholesky':
     root.workload = Cholesky()
 elif options.benchmark == 'FFT':
     root.workload = FFT()
 elif options.benchmark == 'LUContig':
     root.workload = LU_contig()
 elif options.benchmark == 'LUNoncontig':
     root.workload = LU_noncontig()
 elif options.benchmark == 'Radix':
     root.workload = Radix()
 elif options.benchmark == 'Barnes':
     root.workload = Barnes()
 elif options.benchmark == 'FMM':
     root.workload = FMM()
 elif options.benchmark == 'OceanContig':
     root.workload = Ocean_contig()
 elif options.benchmark == 'OceanNoncontig':
     root.workload = Ocean_noncontig()
 elif options.benchmark == 'Raytrace':
     root.workload = Raytrace()
 elif options.benchmark == 'WaterNSquared':
     root.workload = Water_nsquared()
 elif options.benchmark == 'WaterSpatial':
     root.workload = Water_spatial()
 else:
     m5.util.panic("""
 The --benchmark environment variable was set to something improper.
 Use Cholesky, FFT, LUContig, LUNoncontig, Radix, Barnes, FMM, OceanContig,
 OceanNoncontig, Raytrace, WaterNSquared, or WaterSpatial
 """)

 # --------------------
 # Assign the workload to the cpus
 # ====================

 for cluster in clusters:
     for cpu in cluster.cpus:
         cpu.workload = root.workload

 # ----------------------
 # Run the simulation
 # ----------------------

 if options.timing or options.detailed:
     root.system.mem_mode = 'timing'

 # instantiate configuration
 m5.instantiate()

 # simulate until program terminates
 if options.maxtick:
     exit_event = m5.simulate(options.maxtick)
 else:
     exit_event = m5.simulate(m5.MaxTick)

 print('Exiting @ tick', m5.curTick(), 'because', exit_event.getCause())
	# Copyright (c) 2006-2007 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: Ron Dreslinski

	# Simple test script
	#
	# "m5 test.py"

	from __future__ import print_function

	import os
	import optparse
	import sys

	import m5
	from m5.objects import *

	# --------------------
	# Define Command Line Options
	# ====================

	parser = optparse.OptionParser()

	parser.add_option("-d", "--detailed", action="store_true")
	parser.add_option("-t", "--timing", action="store_true")
	parser.add_option("-m", "--maxtick", type="int")
	parser.add_option("-c", "--numclusters",
	help="Number of clusters", type="int")
	parser.add_option("-n", "--numcpus",
	help="Number of cpus in total", type="int")
	parser.add_option("-f", "--frequency",
	default = "1GHz",
	help="Frequency of each CPU")
	parser.add_option("--l1size",
	default = "32kB")
	parser.add_option("--l1latency",
	default = 1)
	parser.add_option("--l2size",
	default = "256kB")
	parser.add_option("--l2latency",
	default = 10)
	parser.add_option("--rootdir",
	help="ROot directory of Splash2",
	default="/dist/splash2/codes/")
	parser.add_option("-b", "--benchmark",
	help="Splash 2 benchmark to run")

	(options, args) = parser.parse_args()

	if args:
	print("Error: script doesn't take any positional arguments")
	sys.exit(1)

	# --------------------
	# Define Splash2 Benchmarks
	# ====================
	class Cholesky(Process):
	executable = options.rootdir + '/kernels/cholesky/CHOLESKY'
	cmd = 'CHOLESKY -p' + str(options.numcpus) + ' '\
	+ options.rootdir + '/kernels/cholesky/inputs/tk23.O'

	class FFT(Process):
	executable = options.rootdir + 'kernels/fft/FFT'
	cmd = 'FFT -p' + str(options.numcpus) + ' -m18'

	class LU_contig(Process):
	executable = options.rootdir + 'kernels/lu/contiguous_blocks/LU'
	cmd = 'LU -p' + str(options.numcpus)

	class LU_noncontig(Process):
	executable = options.rootdir + 'kernels/lu/non_contiguous_blocks/LU'
	cmd = 'LU -p' + str(options.numcpus)

	class Radix(Process):
	executable = options.rootdir + 'kernels/radix/RADIX'
	cmd = 'RADIX -n524288 -p' + str(options.numcpus)

	class Barnes(Process):
	executable = options.rootdir + 'apps/barnes/BARNES'
	cmd = 'BARNES'
	input = options.rootdir + 'apps/barnes/input.p' + str(options.numcpus)

	class FMM(Process):
	executable = options.rootdir + 'apps/fmm/FMM'
	cmd = 'FMM'
	input = options.rootdir + 'apps/fmm/inputs/input.2048.p' + str(options.numcpus)

	class Ocean_contig(Process):
	executable = options.rootdir + 'apps/ocean/contiguous_partitions/OCEAN'
	cmd = 'OCEAN -p' + str(options.numcpus)

	class Ocean_noncontig(Process):
	executable = options.rootdir + 'apps/ocean/non_contiguous_partitions/OCEAN'
	cmd = 'OCEAN -p' + str(options.numcpus)

	class Raytrace(Process):
	executable = options.rootdir + 'apps/raytrace/RAYTRACE'
	cmd = 'RAYTRACE -p' + str(options.numcpus) + ' ' \
	+ options.rootdir + 'apps/raytrace/inputs/teapot.env'

	class Water_nsquared(Process):
	executable = options.rootdir + 'apps/water-nsquared/WATER-NSQUARED'
	cmd = 'WATER-NSQUARED'
	input = options.rootdir + 'apps/water-nsquared/input.p' + str(options.numcpus)

	class Water_spatial(Process):
	executable = options.rootdir + 'apps/water-spatial/WATER-SPATIAL'
	cmd = 'WATER-SPATIAL'
	input = options.rootdir + 'apps/water-spatial/input.p' + str(options.numcpus)


	# --------------------
	# Base L1 Cache Definition
	# ====================

	class L1(Cache):
	latency = options.l1latency
	mshrs = 12
	tgts_per_mshr = 8

	# ----------------------
	# Base L2 Cache Definition
	# ----------------------

	class L2(Cache):
	latency = options.l2latency
	mshrs = 92
	tgts_per_mshr = 16
	write_buffers = 8

	# ----------------------
	# Define the clusters with their cpus
	# ----------------------
	class Cluster:
	pass

	cpusPerCluster = options.numcpus/options.numclusters

	busFrequency = Frequency(options.frequency)
	busFrequency *= cpusPerCluster

	all_cpus = []
	all_l1s = []
	all_l1buses = []
	if options.timing:
	clusters = [ Cluster() for i in xrange(options.numclusters)]
	for j in xrange(options.numclusters):
	clusters[j].id = j
	for cluster in clusters:
	cluster.clusterbus = L2XBar(clock=busFrequency)
	all_l1buses += [cluster.clusterbus]
	cluster.cpus = [TimingSimpleCPU(cpu_id = i + cluster.id,
	clock=options.frequency)
	for i in xrange(cpusPerCluster)]
	all_cpus += cluster.cpus
	cluster.l1 = L1(size=options.l1size, assoc = 4)
	all_l1s += [cluster.l1]
	elif options.detailed:
	clusters = [ Cluster() for i in xrange(options.numclusters)]
	for j in xrange(options.numclusters):
	clusters[j].id = j
	for cluster in clusters:
	cluster.clusterbus = L2XBar(clock=busFrequency)
	all_l1buses += [cluster.clusterbus]
	cluster.cpus = [DerivO3CPU(cpu_id = i + cluster.id,
	clock=options.frequency)
	for i in xrange(cpusPerCluster)]
	all_cpus += cluster.cpus
	cluster.l1 = L1(size=options.l1size, assoc = 4)
	all_l1s += [cluster.l1]
	else:
	clusters = [ Cluster() for i in xrange(options.numclusters)]
	for j in xrange(options.numclusters):
	clusters[j].id = j
	for cluster in clusters:
	cluster.clusterbus = L2XBar(clock=busFrequency)
	all_l1buses += [cluster.clusterbus]
	cluster.cpus = [AtomicSimpleCPU(cpu_id = i + cluster.id,
	clock=options.frequency)
	for i in xrange(cpusPerCluster)]
	all_cpus += cluster.cpus
	cluster.l1 = L1(size=options.l1size, assoc = 4)
	all_l1s += [cluster.l1]

	# ----------------------
	# Create a system, and add system wide objects
	# ----------------------
	system = System(cpu = all_cpus, l1_ = all_l1s, l1bus_ = all_l1buses,
	physmem = SimpleMemory(),
	membus = SystemXBar(clock = busFrequency))
	system.clock = '1GHz'

	system.toL2bus = L2XBar(clock = busFrequency)
	system.l2 = L2(size = options.l2size, assoc = 8)

	# ----------------------
	# Connect the L2 cache and memory together
	# ----------------------

	system.physmem.port = system.membus.master
	system.l2.cpu_side = system.toL2bus.slave
	system.l2.mem_side = system.membus.master

	# ----------------------
	# Connect the L2 cache and clusters together
	# ----------------------
	for cluster in clusters:
	cluster.l1.cpu_side = cluster.clusterbus.master
	cluster.l1.mem_side = system.toL2bus.slave
	for cpu in cluster.cpus:
	cpu.icache_port = cluster.clusterbus.slave
	cpu.dcache_port = cluster.clusterbus.slave

	# ----------------------
	# Define the root
	# ----------------------

	root = Root(full_system = False, system = system)

	# --------------------
	# Pick the correct Splash2 Benchmarks
	# ====================
	if options.benchmark == 'Cholesky':
	root.workload = Cholesky()
	elif options.benchmark == 'FFT':
	root.workload = FFT()
	elif options.benchmark == 'LUContig':
	root.workload = LU_contig()
	elif options.benchmark == 'LUNoncontig':
	root.workload = LU_noncontig()
	elif options.benchmark == 'Radix':
	root.workload = Radix()
	elif options.benchmark == 'Barnes':
	root.workload = Barnes()
	elif options.benchmark == 'FMM':
	root.workload = FMM()
	elif options.benchmark == 'OceanContig':
	root.workload = Ocean_contig()
	elif options.benchmark == 'OceanNoncontig':
	root.workload = Ocean_noncontig()
	elif options.benchmark == 'Raytrace':
	root.workload = Raytrace()
	elif options.benchmark == 'WaterNSquared':
	root.workload = Water_nsquared()
	elif options.benchmark == 'WaterSpatial':
	root.workload = Water_spatial()
	else:
	m5.util.panic("""
	The --benchmark environment variable was set to something improper.
	Use Cholesky, FFT, LUContig, LUNoncontig, Radix, Barnes, FMM, OceanContig,
	OceanNoncontig, Raytrace, WaterNSquared, or WaterSpatial
	""")

	# --------------------
	# Assign the workload to the cpus
	# ====================

	for cluster in clusters:
	for cpu in cluster.cpus:
	cpu.workload = root.workload

	# ----------------------
	# Run the simulation
	# ----------------------

	if options.timing or options.detailed:
	root.system.mem_mode = 'timing'

	# instantiate configuration
	m5.instantiate()

	# simulate until program terminates
	if options.maxtick:
	exit_event = m5.simulate(options.maxtick)
	else:
	exit_event = m5.simulate(m5.MaxTick)

	print('Exiting @ tick', m5.curTick(), 'because', exit_event.getCause())