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# Copyright (c) 2021 The Regents of the University of California.
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"""
Script to run SPEC CPU2017 benchmarks with gem5.
The script expects a benchmark program name and the simulation
size. The system is fixed with 2 CPU cores, MESI Two Level system
cache and 3 GB DDR4 memory. It uses the x86 board.
This script will count the total number of instructions executed
in the ROI. It also tracks how much wallclock and simulated time.
Usage:
------
```
scons build/X86/gem5.opt
./build/X86/gem5.opt \
configs/example/gem5_library/x86-spec-cpu2017-benchmarks.py \
--image <full_path_to_the_spec-2017_disk_image> \
--partition <root_partition_to_mount> \
--benchmark <benchmark_name> \
--size <simulation_size>
```
"""
import argparse
import time
import os
import json
import m5
from m5.objects import Root
from gem5.utils.requires import requires
from gem5.components.boards.x86_board import X86Board
from gem5.components.memory import DualChannelDDR4_2400
from gem5.components.processors.simple_switchable_processor import(
SimpleSwitchableProcessor,
)
from gem5.components.processors.cpu_types import CPUTypes
from gem5.isas import ISA
from gem5.coherence_protocol import CoherenceProtocol
from gem5.resources.resource import Resource, CustomResource
from m5.stats.gem5stats import get_simstat
from m5.util import warn
from m5.util import fatal
# We check for the required gem5 build.
requires(
isa_required=ISA.X86,
coherence_protocol_required=CoherenceProtocol.MESI_TWO_LEVEL,
kvm_required=True,
)
# Following are the list of benchmark programs for SPEC CPU2017.
# More information is available at:
# https://www.gem5.org/documentation/benchmark_status/gem5-20
benchmark_choices =["500.perlbench_r", "502.gcc_r", "503.bwaves_r",
"505.mcf_r", "507.cactusBSSN_r", "508.namd_r",
"510.parest_r", "511.povray_r", "519.lbm_r",
"520.omnetpp_r", "521.wrf_r", "523.xalancbmk_r",
"525.x264_r", "527.cam4_r", "531.deepsjeng_r",
"538.imagick_r", "541.leela_r", "544.nab_r",
"548.exchange2_r", "549.fotonik3d_r", "554.roms_r",
"557.xz_r", "600.perlbench_s", "602.gcc_s",
"603.bwaves_s", "605.mcf_s", "607.cactusBSSN_s",
"608.namd_s", "610.parest_s", "611.povray_s",
"619.lbm_s", "620.omnetpp_s", "621.wrf_s",
"623.xalancbmk_s", "625.x264_s", "627.cam4_s",
"631.deepsjeng_s", "638.imagick_s", "641.leela_s",
"644.nab_s", "648.exchange2_s", "649.fotonik3d_s",
"654.roms_s", "996.specrand_fs", "997.specrand_fr",
"998.specrand_is", "999.specrand_ir"
]
# Following are the input size.
size_choices = ["test", "train", "ref"]
parser = argparse.ArgumentParser(
description="An example configuration script to run the \
SPEC CPU2017 benchmarks."
)
# The arguments accepted are: a. disk-image name, b. benchmark name, c.
# simulation size, and, d. root partition.
# root partition is set to 1 by default.
parser.add_argument(
"--image",
type = str,
required = True,
help = "Input the full path to the built spec-2017 disk-image."
)
parser.add_argument(
"--partition",
type = str,
required = True,
help = "Input the root partition of the SPEC disk-image. If the disk is \
not partitioned, then pass \"\"."
)
parser.add_argument(
"--benchmark",
type = str,
required = True,
help = "Input the benchmark program to execute.",
choices=benchmark_choices,
)
parser.add_argument(
"--size",
type = str,
required = True,
help = "Sumulation size the benchmark program.",
choices = size_choices,
)
args = parser.parse_args()
# We expect the user to input the full path of the disk-image.
if args.image[0] != "/":
# We need to get the absolute path to this file. We assume that the file is
# present on the current working directory.
args.image = os.path.abspath(args.image)
if not os.path.exists(args.image):
warn("Disk image not found!")
print("Instructions on building the disk image can be found at: ")
print(
"https://gem5art.readthedocs.io/en/latest/tutorials/spec-tutorial.html"
)
fatal("The disk-image is not found at {}".format(args.image))
# Setting up all the fixed system parameters here
# Caches: MESI Two Level Cache Hierarchy
from gem5.components.cachehierarchies.ruby.\
mesi_two_level_cache_hierarchy import(
MESITwoLevelCacheHierarchy,
)
cache_hierarchy = MESITwoLevelCacheHierarchy(
l1d_size = "32kB",
l1d_assoc = 8,
l1i_size="32kB",
l1i_assoc=8,
l2_size="256kB",
l2_assoc=16,
num_l2_banks=2,
)
# Memory: Dual Channel DDR4 2400 DRAM device.
# The X86 board only supports 3 GB of main memory.
memory = DualChannelDDR4_2400(size = "3GB")
# Here we setup the processor. This is a special switchable processor in which
# a starting core type and a switch core type must be specified. Once a
# configuration is instantiated a user may call `processor.switch()` to switch
# from the starting core types to the switch core types. In this simulation
# we start with KVM cores to simulate the OS boot, then switch to the Timing
# cores for the command we wish to run after boot.
processor = SimpleSwitchableProcessor(
starting_core_type=CPUTypes.KVM,
switch_core_type=CPUTypes.TIMING,
num_cores=2,
)
# Here we setup the board. The X86Board allows for Full-System X86 simulations
board = X86Board(
clk_freq="3GHz",
processor=processor,
memory=memory,
cache_hierarchy=cache_hierarchy,
)
# SPEC CPU2017 benchmarks output placed in /home/gem5/spec2017/results
# directory on the disk-image. The following folder is created in the
# m5.options.outdir and the output from the disk-image folder is copied to
# this folder.
output_dir = "speclogs_" + ''.join(x.strip() for x in time.asctime().split())
output_dir = output_dir.replace(":","")
# We create this folder if it is absent.
try:
os.makedirs(os.path.join(m5.options.outdir, output_dir))
except FileExistsError:
warn("output directory already exists!")
# Here we set the FS workload, i.e., SPEC CPU2017 benchmark
# After simulation has ended you may inspect
# `m5out/system.pc.com_1.device` to the stdout, if any.
# After the system boots, we execute the benchmark program and wait till the
# `m5_exit instruction encountered` is encountered. We start collecting
# the number of committed instructions till ROI ends (marked by another
# `m5_exit instruction encountered`). We then start copying the output logs,
# present in the /home/gem5/spec2017/results directory to the `output_dir`.
# The runscript.sh file places `m5 exit` before and after the following command
# Therefore, we only pass this command without m5 exit.
command = "{} {} {}".format(args.benchmark, args.size, output_dir)
# For enabling CustomResource, we pass an additional parameter to mount the
# correct partition.
metadata = {
"additional_metadata" : {
"root_partition" : args.partition,
},
}
board.set_kernel_disk_workload(
# The x86 linux kernel will be automatically downloaded to the
# `~/.cache/gem5` directory if not already present.
# SPEC CPU2017 benchamarks were tested with kernel version 4.19.83
kernel=Resource(
"x86-linux-kernel-4.19.83",
),
# The location of the x86 SPEC CPU 2017 image
disk_image=CustomResource(
args.image,
metadata=metadata
),
readfile_contents=command,
)
# We need this for long running processes.
m5.disableAllListeners()
root = Root(full_system = True, system = board)
# sim_quantum must be set when KVM cores are used.
root.sim_quantum = int(1e9)
m5.instantiate()
# We maintain the wall clock time.
globalStart = time.time()
print("Running the simulation")
print("Using KVM cpu")
start_tick = m5.curTick()
end_tick = m5.curTick()
m5.stats.reset()
exit_event = m5.simulate()
if exit_event.getCause() == "m5_exit instruction encountered":
# We have completed booting the OS using KVM cpu
# Reached the start of ROI
print("Done booting Linux")
print("Resetting stats at the start of ROI!")
m5.stats.reset()
start_tick = m5.curTick()
# We switch to timing cpu for detailed simulation.
processor.switch()
else:
print("Unexpected termination of simulation before ROI was reached!")
print(
"Exiting @ tick {} because {}.".format(
m5.curTick(),
exit_event.getCause()
)
)
exit(-1)
# Simulate the ROI
exit_event = m5.simulate()
# Reached the end of ROI
gem5stats = get_simstat(root)
# We get the number of committed instructions from the timing
# cores. We then sum and print them at the end.
roi_insts = float(\
json.loads(gem5stats.dumps())\
["system"]["processor"]["cores2"]["core"]["exec_context.thread_0"]\
["numInsts"]["value"]
) + float(\
json.loads(gem5stats.dumps())\
["system"]["processor"]["cores3"]["core"]["exec_context.thread_0"]\
["numInsts"]["value"]\
)
if exit_event.getCause() == "m5_exit instruction encountered":
print("Dump stats at the end of the ROI!")
m5.stats.dump()
end_tick = m5.curTick()
m5.stats.reset()
else:
print("Unexpected termination of simulation while ROI was being executed!")
print(
"Exiting @ tick {} because {}.".format(
m5.curTick(),
exit_event.getCause()
)
)
exit(-1)
# We need to copy back the contents of the `speclogs' directory to
# m5.options.outdir
exit_event = m5.simulate()
if exit_event.getCause() == "m5_exit instruction encountered":
print("Output logs copied!")
else:
print("Unexpected termination of simulation while copying speclogs!")
print(
"Exiting @ tick {} because {}.".format(
m5.curTick(),
exit_event.getCause()
)
)
exit(-1)
print("Done with the simulation")
print()
print("Performance statistics:")
print("Simulated time in ROI: %.2fs" % ((end_tick-start_tick)/1e12))
print("Instructions executed in ROI: %d" % ((roi_insts)))
print("Ran a total of", m5.curTick()/1e12, "simulated seconds")
print("Total wallclock time: %.2fs, %.2f min" % \
(time.time()-globalStart, (time.time()-globalStart)/60))