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# Copyright (c) 2015-2016 ARM Limited
# All rights reserved.
#
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# to a hardware implementation of the functionality of the software
# licensed hereunder. You may use the software subject to the license
# terms below provided that you ensure that this notice is replicated
# unmodified and in its entirety in all distributions of the software,
# modified or unmodified, in source code or in binary form.
#
# Copyright (c) 2006-2007 The Regents of The University of Michigan
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# modification, are permitted provided that the following conditions are
# met: redistributions of source code must retain the above copyright
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# neither the name of the copyright holders nor the names of its
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# this software without specific prior written permission.
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# LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#
# Authors: Ron Dreslinski
# Andreas Hansson
from __future__ import print_function
import optparse
import random
import sys
import m5
from m5.objects import *
parser = optparse.OptionParser()
parser.add_option("-a", "--atomic", action="store_true",
help="Use atomic (non-timing) mode")
parser.add_option("-b", "--blocking", action="store_true",
help="Use blocking caches")
parser.add_option("-m", "--maxtick", type="int", default=m5.MaxTick,
metavar="T",
help="Stop after T ticks")
parser.add_option("-p", "--prefetchers", action="store_true",
help="Use prefetchers")
parser.add_option("-s", "--stridepref", action="store_true",
help="Use strided prefetchers")
# This example script has a lot in common with the memtest.py in that
# it is designed to stress tests the memory system. However, this
# script uses oblivious traffic generators to create the stimuli, and
# couples them with memcheckers to verify that the data read matches
# the allowed outcomes. Just like memtest.py, the traffic generators
# and checkers are placed in a tree topology. At the bottom of the
# tree is a shared memory, and then at each level a number of
# generators and checkers are attached, along with a number of caches
# that them selves fan out to subtrees of generators and caches. Thus,
# it is possible to create a system with arbitrarily deep cache
# hierarchies, sharing or no sharing of caches, and generators not
# only at the L1s, but also at the L2s, L3s etc.
#
# The tree specification consists of two colon-separated lists of one
# or more integers, one for the caches, and one for the
# testers/generators. The first integer is the number of
# caches/testers closest to main memory. Each cache then fans out to a
# subtree. The last integer in the list is the number of
# caches/testers associated with the uppermost level of memory. The
# other integers (if any) specify the number of caches/testers
# connected at each level of the crossbar hierarchy. The tester string
# should have one element more than the cache string as there should
# always be testers attached to the uppermost caches.
#
# Since this script tests actual sharing, there is also a possibility
# to stress prefetching and the interaction between prefetchers and
# caches. The traffic generators switch between random address streams
# and linear address streams to ensure that the prefetchers will
# trigger. By default prefetchers are off.
parser.add_option("-c", "--caches", type="string", default="3:2",
help="Colon-separated cache hierarchy specification, "
"see script comments for details "
"[default: %default]")
parser.add_option("-t", "--testers", type="string", default="1:0:2",
help="Colon-separated tester hierarchy specification, "
"see script comments for details "
"[default: %default]")
parser.add_option("-r", "--random", action="store_true",
help="Generate a random tree topology")
parser.add_option("--sys-clock", action="store", type="string",
default='1GHz',
help = """Top-level clock for blocks running at system
speed""")
(options, args) = parser.parse_args()
if args:
print("Error: script doesn't take any positional arguments")
sys.exit(1)
# Start by parsing the command line options and do some basic sanity
# checking
if options.random:
# Generate a tree with a valid number of testers
tree_depth = random.randint(1, 4)
cachespec = [random.randint(1, 3) for i in range(tree_depth)]
testerspec = [random.randint(1, 3) for i in range(tree_depth + 1)]
print("Generated random tree -c", ':'.join(map(str, cachespec)),
"-t", ':'.join(map(str, testerspec)))
else:
try:
cachespec = [int(x) for x in options.caches.split(':')]
testerspec = [int(x) for x in options.testers.split(':')]
except:
print("Error: Unable to parse caches or testers option")
sys.exit(1)
if len(cachespec) < 1:
print("Error: Must have at least one level of caches")
sys.exit(1)
if len(cachespec) != len(testerspec) - 1:
print("Error: Testers must have one element more than caches")
sys.exit(1)
if testerspec[-1] == 0:
print("Error: Must have testers at the uppermost level")
sys.exit(1)
for t in testerspec:
if t < 0:
print("Error: Cannot have a negative number of testers")
sys.exit(1)
for c in cachespec:
if c < 1:
print("Error: Must have 1 or more caches at each level")
sys.exit(1)
# Determine the tester multiplier for each level as the string
# elements are per subsystem and it fans out
multiplier = [1]
for c in cachespec:
if c < 1:
print("Error: Must have at least one cache per level")
multiplier.append(multiplier[-1] * c)
numtesters = 0
for t, m in zip(testerspec, multiplier):
numtesters += t * m
# Define a prototype L1 cache that we scale for all successive levels
proto_l1 = Cache(size = '32kB', assoc = 4,
tag_latency = 1, data_latency = 1, response_latency = 1,
tgts_per_mshr = 8)
if options.blocking:
proto_l1.mshrs = 1
else:
proto_l1.mshrs = 4
if options.prefetchers:
proto_l1.prefetcher = TaggedPrefetcher()
elif options.stridepref:
proto_l1.prefetcher = StridePrefetcher()
cache_proto = [proto_l1]
# Now add additional cache levels (if any) by scaling L1 params, the
# first element is Ln, and the last element L1
for scale in cachespec[:-1]:
# Clone previous level and update params
prev = cache_proto[0]
next = prev()
next.size = prev.size * scale
next.tag_latency = prev.tag_latency * 10
next.data_latency = prev.data_latency * 10
next.response_latency = prev.response_latency * 10
next.assoc = prev.assoc * scale
next.mshrs = prev.mshrs * scale
cache_proto.insert(0, next)
# Create a config to be used by all the traffic generators
cfg_file_name = "configs/example/memcheck.cfg"
cfg_file = open(cfg_file_name, 'w')
# Three states, with random, linear and idle behaviours. The random
# and linear states access memory in the range [0 : 16 Mbyte] with 8
# byte and 64 byte accesses respectively.
cfg_file.write("STATE 0 10000000 RANDOM 65 0 16777216 8 50000 150000 0\n")
cfg_file.write("STATE 1 10000000 LINEAR 65 0 16777216 64 50000 150000 0\n")
cfg_file.write("STATE 2 10000000 IDLE\n")
cfg_file.write("INIT 0\n")
cfg_file.write("TRANSITION 0 1 0.5\n")
cfg_file.write("TRANSITION 0 2 0.5\n")
cfg_file.write("TRANSITION 1 0 0.5\n")
cfg_file.write("TRANSITION 1 2 0.5\n")
cfg_file.write("TRANSITION 2 0 0.5\n")
cfg_file.write("TRANSITION 2 1 0.5\n")
cfg_file.close()
# Make a prototype for the tester to be used throughout
proto_tester = TrafficGen(config_file = cfg_file_name)
# Set up the system along with a DRAM controller
system = System(physmem = DDR3_1600_8x8())
system.voltage_domain = VoltageDomain(voltage = '1V')
system.clk_domain = SrcClockDomain(clock = options.sys_clock,
voltage_domain = system.voltage_domain)
system.memchecker = MemChecker()
# For each level, track the next subsys index to use
next_subsys_index = [0] * (len(cachespec) + 1)
# Recursive function to create a sub-tree of the cache and tester
# hierarchy
def make_cache_level(ncaches, prototypes, level, next_cache):
global next_subsys_index, proto_l1, testerspec, proto_tester
index = next_subsys_index[level]
next_subsys_index[level] += 1
# Create a subsystem to contain the crossbar and caches, and
# any testers
subsys = SubSystem()
setattr(system, 'l%dsubsys%d' % (level, index), subsys)
# The levels are indexing backwards through the list
ntesters = testerspec[len(cachespec) - level]
testers = [proto_tester() for i in xrange(ntesters)]
checkers = [MemCheckerMonitor(memchecker = system.memchecker) \
for i in xrange(ntesters)]
if ntesters:
subsys.tester = testers
subsys.checkers = checkers
if level != 0:
# Create a crossbar and add it to the subsystem, note that
# we do this even with a single element on this level
xbar = L2XBar(width = 32)
subsys.xbar = xbar
if next_cache:
xbar.master = next_cache.cpu_side
# Create and connect the caches, both the ones fanning out
# to create the tree, and the ones used to connect testers
# on this level
tree_caches = [prototypes[0]() for i in xrange(ncaches[0])]
tester_caches = [proto_l1() for i in xrange(ntesters)]
subsys.cache = tester_caches + tree_caches
for cache in tree_caches:
cache.mem_side = xbar.slave
make_cache_level(ncaches[1:], prototypes[1:], level - 1, cache)
for tester, checker, cache in zip(testers, checkers, tester_caches):
tester.port = checker.slave
checker.master = cache.cpu_side
cache.mem_side = xbar.slave
else:
if not next_cache:
print("Error: No next-level cache at top level")
sys.exit(1)
if ntesters > 1:
# Create a crossbar and add it to the subsystem
xbar = L2XBar(width = 32)
subsys.xbar = xbar
xbar.master = next_cache.cpu_side
for tester, checker in zip(testers, checkers):
tester.port = checker.slave
checker.master = xbar.slave
else:
# Single tester
testers[0].port = checkers[0].slave
checkers[0].master = next_cache.cpu_side
# Top level call to create the cache hierarchy, bottom up
make_cache_level(cachespec, cache_proto, len(cachespec), None)
# Connect the lowest level crossbar to the memory
last_subsys = getattr(system, 'l%dsubsys0' % len(cachespec))
last_subsys.xbar.master = system.physmem.port
last_subsys.xbar.point_of_coherency = True
root = Root(full_system = False, system = system)
if options.atomic:
root.system.mem_mode = 'atomic'
else:
root.system.mem_mode = 'timing'
# The system port is never used in the tester so merely connect it
# to avoid problems
root.system.system_port = last_subsys.xbar.slave
# Instantiate configuration
m5.instantiate()
# Simulate until program terminates
exit_event = m5.simulate(options.maxtick)
print('Exiting @ tick', m5.curTick(), 'because', exit_event.getCause())