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# -*- coding: utf-8 -*-
# Copyright (c) 2015 Jason Power
# All rights reserved.
#
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# 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
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# documentation and/or other materials provided with the distribution;
# 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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# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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""" This file creates a single CPU and a two-level cache system.
This script takes a single parameter which specifies a binary to execute.
If none is provided it executes 'hello' by default (mostly used for testing)
See Part 1, Chapter 3: Adding cache to the configuration script in the
learning_gem5 book for more information about this script.
This file exports options for the L1 I/D and L2 cache sizes.
IMPORTANT: If you modify this file, it's likely that the Learning gem5 book
also needs to be updated. For now, email Jason <power.jg@gmail.com>
"""
from __future__ import print_function
from __future__ import absolute_import
# import the m5 (gem5) library created when gem5 is built
import m5
# import all of the SimObjects
from m5.objects import *
# Add the common scripts to our path
m5.util.addToPath('../../')
# import the caches which we made
from caches import *
# import the SimpleOpts module
from common import SimpleOpts
# Set the usage message to display
SimpleOpts.set_usage("usage: %prog [options] <binary to execute>")
# Finalize the arguments and grab the opts so we can pass it on to our objects
(opts, args) = SimpleOpts.parse_args()
# get ISA for the default binary to run. This is mostly for simple testing
isa = str(m5.defines.buildEnv['TARGET_ISA']).lower()
# Default to running 'hello', use the compiled ISA to find the binary
# grab the specific path to the binary
thispath = os.path.dirname(os.path.realpath(__file__))
binary = os.path.join(thispath, '../../../',
'tests/test-progs/hello/bin/', isa, 'linux/hello')
# Check if there was a binary passed in via the command line and error if
# there are too many arguments
if len(args) == 1:
binary = args[0]
elif len(args) > 1:
SimpleOpts.print_help()
m5.fatal("Expected a binary to execute as positional argument")
# create the system we are going to simulate
system = System()
# Set the clock fequency of the system (and all of its children)
system.clk_domain = SrcClockDomain()
system.clk_domain.clock = '1GHz'
system.clk_domain.voltage_domain = VoltageDomain()
# Set up the system
system.mem_mode = 'timing' # Use timing accesses
system.mem_ranges = [AddrRange('512MB')] # Create an address range
# Create a simple CPU
system.cpu = TimingSimpleCPU()
# Create an L1 instruction and data cache
system.cpu.icache = L1ICache(opts)
system.cpu.dcache = L1DCache(opts)
# Connect the instruction and data caches to the CPU
system.cpu.icache.connectCPU(system.cpu)
system.cpu.dcache.connectCPU(system.cpu)
# Create a memory bus, a coherent crossbar, in this case
system.l2bus = L2XBar()
# Hook the CPU ports up to the l2bus
system.cpu.icache.connectBus(system.l2bus)
system.cpu.dcache.connectBus(system.l2bus)
# Create an L2 cache and connect it to the l2bus
system.l2cache = L2Cache(opts)
system.l2cache.connectCPUSideBus(system.l2bus)
# Create a memory bus
system.membus = SystemXBar()
# Connect the L2 cache to the membus
system.l2cache.connectMemSideBus(system.membus)
# create the interrupt controller for the CPU
system.cpu.createInterruptController()
# For x86 only, make sure the interrupts are connected to the memory
# Note: these are directly connected to the memory bus and are not cached
if m5.defines.buildEnv['TARGET_ISA'] == "x86":
system.cpu.interrupts[0].pio = system.membus.master
system.cpu.interrupts[0].int_master = system.membus.slave
system.cpu.interrupts[0].int_slave = system.membus.master
# Connect the system up to the membus
system.system_port = system.membus.slave
# Create a DDR3 memory controller
system.mem_ctrl = MemCtrl()
system.mem_ctrl.dram = DDR3_1600_8x8()
system.mem_ctrl.dram.range = system.mem_ranges[0]
system.mem_ctrl.port = system.membus.master
# Create a process for a simple "Hello World" application
process = Process()
# Set the command
# cmd is a list which begins with the executable (like argv)
process.cmd = [binary]
# Set the cpu to use the process as its workload and create thread contexts
system.cpu.workload = process
system.cpu.createThreads()
# set up the root SimObject and start the simulation
root = Root(full_system = False, system = system)
# instantiate all of the objects we've created above
m5.instantiate()
print("Beginning simulation!")
exit_event = m5.simulate()
print('Exiting @ tick %i because %s' % (m5.curTick(), exit_event.getCause()))