Пример #1
0
for i in range(np):
    if options.smt:
        system.cpu[i].workload = multiprocesses
    elif len(multiprocesses) == 1:
        system.cpu[i].workload = multiprocesses[0]
    else:
        system.cpu[i].workload = multiprocesses[i]

    if options.simpoint_profile:
        system.cpu[i].addSimPointProbe(options.simpoint_interval)

    if options.checker:
        system.cpu[i].addCheckerCpu()

    if options.bp_type:
        bpClass = BPConfig.get(options.bp_type)
        system.cpu[i].branchPred = bpClass()

    system.cpu[i].createThreads()

if options.ruby:
    Ruby.create_system(options, False, system)
    assert (options.num_cpus == len(system.ruby._cpu_ports))

    system.ruby.clk_domain = SrcClockDomain(
        clock=options.ruby_clock, voltage_domain=system.voltage_domain)
    for i in range(np):
        ruby_port = system.ruby._cpu_ports[i]

        # Create the interrupt controller and connect its ports to Ruby
        # Note that the interrupt controller is always present but only
Пример #2
0
def build_test_system(np):
    cmdline = cmd_line_template()
    if buildEnv['TARGET_ISA'] == "alpha":
        test_sys = makeLinuxAlphaSystem(test_mem_mode, bm[0], options.ruby,
                                        cmdline=cmdline)
    elif buildEnv['TARGET_ISA'] == "mips":
        test_sys = makeLinuxMipsSystem(test_mem_mode, bm[0], cmdline=cmdline)
    elif buildEnv['TARGET_ISA'] == "sparc":
        test_sys = makeSparcSystem(test_mem_mode, bm[0], cmdline=cmdline)
    elif buildEnv['TARGET_ISA'] == "x86":
        test_sys = makeLinuxX86System(test_mem_mode, np, bm[0], options.ruby,
                                      cmdline=cmdline)
    elif buildEnv['TARGET_ISA'] == "arm":
        test_sys = makeArmSystem(test_mem_mode, options.machine_type, np,
                                 bm[0], options.dtb_filename,
                                 bare_metal=options.bare_metal,
                                 cmdline=cmdline,
                                 external_memory=
                                   options.external_memory_system,
                                 ruby=options.ruby,
                                 security=options.enable_security_extensions)
        if options.enable_context_switch_stats_dump:
            test_sys.enable_context_switch_stats_dump = True
    else:
        fatal("Incapable of building %s full system!", buildEnv['TARGET_ISA'])

    # Set the cache line size for the entire system
    test_sys.cache_line_size = options.cacheline_size

    # Create a top-level voltage domain
    test_sys.voltage_domain = VoltageDomain(voltage = options.sys_voltage)

    # Create a source clock for the system and set the clock period
    test_sys.clk_domain = SrcClockDomain(clock =  options.sys_clock,
            voltage_domain = test_sys.voltage_domain)

    # Create a CPU voltage domain
    test_sys.cpu_voltage_domain = VoltageDomain()

    # Create a source clock for the CPUs and set the clock period
    test_sys.cpu_clk_domain = SrcClockDomain(clock = options.cpu_clock,
                                             voltage_domain =
                                             test_sys.cpu_voltage_domain)

    if options.kernel is not None:
        test_sys.kernel = binary(options.kernel)
    else:
        print("Error: a kernel must be provided to run in full system mode")
        sys.exit(1)

    if options.script is not None:
        test_sys.readfile = options.script

    if options.lpae:
        test_sys.have_lpae = True

    if options.virtualisation:
        test_sys.have_virtualization = True

    test_sys.init_param = options.init_param

    # For now, assign all the CPUs to the same clock domain
    test_sys.cpu = [TestCPUClass(clk_domain=test_sys.cpu_clk_domain, cpu_id=i)
                    for i in range(np)]

    if CpuConfig.is_kvm_cpu(TestCPUClass) or CpuConfig.is_kvm_cpu(FutureClass):
        test_sys.kvm_vm = KvmVM()

    if options.ruby:
        bootmem = getattr(test_sys, 'bootmem', None)
        Ruby.create_system(options, True, test_sys, test_sys.iobus,
                           test_sys._dma_ports, bootmem)

        # Create a seperate clock domain for Ruby
        test_sys.ruby.clk_domain = SrcClockDomain(clock = options.ruby_clock,
                                        voltage_domain = test_sys.voltage_domain)

        # Connect the ruby io port to the PIO bus,
        # assuming that there is just one such port.
        test_sys.iobus.master = test_sys.ruby._io_port.slave

        for (i, cpu) in enumerate(test_sys.cpu):
            #
            # Tie the cpu ports to the correct ruby system ports
            #
            cpu.clk_domain = test_sys.cpu_clk_domain
            cpu.createThreads()
            cpu.createInterruptController()

            cpu.icache_port = test_sys.ruby._cpu_ports[i].slave
            cpu.dcache_port = test_sys.ruby._cpu_ports[i].slave

            if buildEnv['TARGET_ISA'] in ("x86", "arm"):
                cpu.itb.walker.port = test_sys.ruby._cpu_ports[i].slave
                cpu.dtb.walker.port = test_sys.ruby._cpu_ports[i].slave

            if buildEnv['TARGET_ISA'] in "x86":
                cpu.interrupts[0].pio = test_sys.ruby._cpu_ports[i].master
                cpu.interrupts[0].int_master = test_sys.ruby._cpu_ports[i].slave
                cpu.interrupts[0].int_slave = test_sys.ruby._cpu_ports[i].master

    else:
        if options.caches or options.l2cache:
            # By default the IOCache runs at the system clock
            test_sys.iocache = IOCache(addr_ranges = test_sys.mem_ranges)
            test_sys.iocache.cpu_side = test_sys.iobus.master
            test_sys.iocache.mem_side = test_sys.membus.slave
        elif not options.external_memory_system:
            test_sys.iobridge = Bridge(delay='50ns', ranges = test_sys.mem_ranges)
            test_sys.iobridge.slave = test_sys.iobus.master
            test_sys.iobridge.master = test_sys.membus.slave

        # Sanity check
        if options.simpoint_profile:
            if not CpuConfig.is_noncaching_cpu(TestCPUClass):
                fatal("SimPoint generation should be done with atomic cpu")
            if np > 1:
                fatal("SimPoint generation not supported with more than one CPUs")

        for i in range(np):
            if options.simpoint_profile:
                test_sys.cpu[i].addSimPointProbe(options.simpoint_interval)
            if options.checker:
                test_sys.cpu[i].addCheckerCpu()
            if options.bp_type:
                bpClass = BPConfig.get(options.bp_type)
                test_sys.cpu[i].branchPred = bpClass()
            if options.indirect_bp_type:
                IndirectBPClass = \
                    BPConfig.get_indirect(options.indirect_bp_type)
                test_sys.cpu[i].branchPred.indirectBranchPred = \
                    IndirectBPClass()
            test_sys.cpu[i].createThreads()

        # If elastic tracing is enabled when not restoring from checkpoint and
        # when not fast forwarding using the atomic cpu, then check that the
        # TestCPUClass is DerivO3CPU or inherits from DerivO3CPU. If the check
        # passes then attach the elastic trace probe.
        # If restoring from checkpoint or fast forwarding, the code that does this for
        # FutureCPUClass is in the Simulation module. If the check passes then the
        # elastic trace probe is attached to the switch CPUs.
        if options.elastic_trace_en and options.checkpoint_restore == None and \
            not options.fast_forward:
            CpuConfig.config_etrace(TestCPUClass, test_sys.cpu, options)

        CacheConfig.config_cache(options, test_sys)

        MemConfig.config_mem(options, test_sys)

    return test_sys
Пример #3
0
def build_test_system(np):
    cmdline = cmd_line_template()
    if buildEnv['TARGET_ISA'] == "alpha":
        test_sys = makeLinuxAlphaSystem(test_mem_mode,
                                        bm[0],
                                        options.ruby,
                                        cmdline=cmdline)
    elif buildEnv['TARGET_ISA'] == "mips":
        test_sys = makeLinuxMipsSystem(test_mem_mode, bm[0], cmdline=cmdline)
    elif buildEnv['TARGET_ISA'] == "sparc":
        test_sys = makeSparcSystem(test_mem_mode, bm[0], cmdline=cmdline)
    elif buildEnv['TARGET_ISA'] == "x86":
        test_sys = makeLinuxX86System(test_mem_mode,
                                      options.num_cpus,
                                      bm[0],
                                      options.ruby,
                                      cmdline=cmdline)
    elif buildEnv['TARGET_ISA'] == "arm":
        test_sys = makeArmSystem(
            test_mem_mode,
            options.machine_type,
            options.num_cpus,
            bm[0],
            options.dtb_filename,
            bare_metal=options.bare_metal,
            cmdline=cmdline,
            external_memory=options.external_memory_system,
            ruby=options.ruby,
            security=options.enable_security_extensions)
        if options.enable_context_switch_stats_dump:
            test_sys.enable_context_switch_stats_dump = True
    else:
        fatal("Incapable of building %s full system!", buildEnv['TARGET_ISA'])

    # Set the cache line size for the entire system
    test_sys.cache_line_size = options.cacheline_size

    # Create a top-level voltage domain
    test_sys.voltage_domain = VoltageDomain(voltage=options.sys_voltage)

    # Create a source clock for the system and set the clock period
    test_sys.clk_domain = SrcClockDomain(
        clock=options.sys_clock, voltage_domain=test_sys.voltage_domain)

    # Create a CPU voltage domain
    test_sys.cpu_voltage_domain = VoltageDomain()

    # Create a source clock for the CPUs and set the clock period
    test_sys.cpu_clk_domain = SrcClockDomain(
        clock=options.cpu_clock, voltage_domain=test_sys.cpu_voltage_domain)

    if options.kernel is not None:
        test_sys.kernel = binary(options.kernel)

    if options.script is not None:
        test_sys.readfile = options.script

    if options.lpae:
        test_sys.have_lpae = True

    if options.virtualisation:
        test_sys.have_virtualization = True

    test_sys.init_param = options.init_param

    # For now, assign all the CPUs to the same clock domain
    test_sys.cpu = [
        TestCPUClass(clk_domain=test_sys.cpu_clk_domain, cpu_id=i)
        for i in range(np)
    ]

    if CpuConfig.is_kvm_cpu(TestCPUClass) or CpuConfig.is_kvm_cpu(FutureClass):
        test_sys.kvm_vm = KvmVM()

    if options.ruby:
        bootmem = getattr(test_sys, 'bootmem', None)
        Ruby.create_system(options, True, test_sys, test_sys.iobus,
                           test_sys._dma_ports, bootmem)

        # Create a seperate clock domain for Ruby
        test_sys.ruby.clk_domain = SrcClockDomain(
            clock=options.ruby_clock, voltage_domain=test_sys.voltage_domain)

        # Connect the ruby io port to the PIO bus,
        # assuming that there is just one such port.
        test_sys.iobus.master = test_sys.ruby._io_port.slave

        for (i, cpu) in enumerate(test_sys.cpu):
            #
            # Tie the cpu ports to the correct ruby system ports
            #
            cpu.clk_domain = test_sys.cpu_clk_domain
            cpu.createThreads()
            cpu.createInterruptController()

            cpu.icache_port = test_sys.ruby._cpu_ports[i].slave
            cpu.dcache_port = test_sys.ruby._cpu_ports[i].slave

            if buildEnv['TARGET_ISA'] in ("x86", "arm"):
                cpu.itb.walker.port = test_sys.ruby._cpu_ports[i].slave
                cpu.dtb.walker.port = test_sys.ruby._cpu_ports[i].slave

            if buildEnv['TARGET_ISA'] in "x86":
                cpu.interrupts[0].pio = test_sys.ruby._cpu_ports[i].master
                cpu.interrupts[0].int_master = test_sys.ruby._cpu_ports[
                    i].slave
                cpu.interrupts[0].int_slave = test_sys.ruby._cpu_ports[
                    i].master

    else:
        if options.caches or options.l2cache:
            # By default the IOCache runs at the system clock
            test_sys.iocache = IOCache(addr_ranges=test_sys.mem_ranges)
            test_sys.iocache.cpu_side = test_sys.iobus.master
            test_sys.iocache.mem_side = test_sys.membus.slave
        elif not options.external_memory_system:
            test_sys.iobridge = Bridge(delay='50ns',
                                       ranges=test_sys.mem_ranges)
            test_sys.iobridge.slave = test_sys.iobus.master
            test_sys.iobridge.master = test_sys.membus.slave

        # Sanity check
        if options.simpoint_profile:
            if not CpuConfig.is_noncaching_cpu(TestCPUClass):
                fatal("SimPoint generation should be done with atomic cpu")
            if np > 1:
                fatal(
                    "SimPoint generation not supported with more than one CPUs"
                )

        for i in range(np):
            if options.simpoint_profile:
                test_sys.cpu[i].addSimPointProbe(options.simpoint_interval)
            if options.checker:
                test_sys.cpu[i].addCheckerCpu()
            if options.bp_type:
                bpClass = BPConfig.get(options.bp_type)
                test_sys.cpu[i].branchPred = bpClass()
            test_sys.cpu[i].createThreads()

        # If elastic tracing is enabled when not restoring from checkpoint and
        # when not fast forwarding using the atomic cpu, then check that the
        # TestCPUClass is DerivO3CPU or inherits from DerivO3CPU. If the check
        # passes then attach the elastic trace probe.
        # If restoring from checkpoint or fast forwarding, the code that does this for
        # FutureCPUClass is in the Simulation module. If the check passes then the
        # elastic trace probe is attached to the switch CPUs.
        if options.elastic_trace_en and options.checkpoint_restore == None and \
            not options.fast_forward:
            CpuConfig.config_etrace(TestCPUClass, test_sys.cpu, options)

        CacheConfig.config_cache(options, test_sys)

        MemConfig.config_mem(options, test_sys)

    return test_sys
Пример #4
0
def run(options, root, testsys, cpu_class):
    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")

    if options.standard_switch and options.repeat_switch:
        fatal("Can't specify both --standard-switch and --repeat-switch")

    if options.repeat_switch and options.take_checkpoints:
        fatal("Can't specify both --repeat-switch and --take-checkpoints")

    np = options.num_cpus
    switch_cpus = None

    if options.prog_interval:
        for i in xrange(np):
            testsys.cpu[i].progress_interval = options.prog_interval

    if options.maxinsts:
        for i in xrange(np):
            testsys.cpu[i].max_insts_any_thread = options.maxinsts

    if cpu_class:
        switch_cpus = [cpu_class(switched_out=True, cpu_id=(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
            switch_cpus[i].workload = testsys.cpu[i].workload
            switch_cpus[i].clk_domain = testsys.cpu[i].clk_domain
            switch_cpus[i].progress_interval = \
                testsys.cpu[i].progress_interval
            switch_cpus[i].isa = testsys.cpu[i].isa
            # simulation period
            if options.maxinsts:
                switch_cpus[i].max_insts_any_thread = options.maxinsts
            # Add checker cpu if selected
            if options.checker:
                switch_cpus[i].addCheckerCpu()
            if options.bp_type:
                bpClass = BPConfig.get(options.bp_type)
                switch_cpus[i].branchPred = bpClass()

        # If elastic tracing is enabled attach the elastic trace probe
        # to the switch CPUs
        if options.elastic_trace_en:
            CpuConfig.config_etrace(cpu_class, switch_cpus, options)

        testsys.switch_cpus = switch_cpus
        switch_cpu_list = [(testsys.cpu[i], switch_cpus[i]) for i in xrange(np)]

    if options.repeat_switch:
        switch_class = getCPUClass(options.cpu_type)[0]
        if switch_class.require_caches() and \
                not options.caches:
            print("%s: Must be used with caches" % str(switch_class))
            sys.exit(1)
        if not switch_class.support_take_over():
            print("%s: CPU switching not supported" % str(switch_class))
            sys.exit(1)

        repeat_switch_cpus = [switch_class(switched_out=True, \
                                               cpu_id=(i)) for i in xrange(np)]

        for i in xrange(np):
            repeat_switch_cpus[i].system = testsys
            repeat_switch_cpus[i].workload = testsys.cpu[i].workload
            repeat_switch_cpus[i].clk_domain = testsys.cpu[i].clk_domain
            repeat_switch_cpus[i].isa = testsys.cpu[i].isa

            if options.maxinsts:
                repeat_switch_cpus[i].max_insts_any_thread = options.maxinsts

            if options.checker:
                repeat_switch_cpus[i].addCheckerCpu()

        testsys.repeat_switch_cpus = repeat_switch_cpus

        if cpu_class:
            repeat_switch_cpu_list = [(switch_cpus[i], repeat_switch_cpus[i])
                                      for i in xrange(np)]
        else:
            repeat_switch_cpu_list = [(testsys.cpu[i], repeat_switch_cpus[i])
                                      for i in xrange(np)]

    if options.standard_switch:
        switch_cpus = [TimingSimpleCPU(switched_out=True, cpu_id=(i))
                       for i in xrange(np)]
        switch_cpus_1 = [DerivO3CPU(switched_out=True, cpu_id=(i))
                        for i in xrange(np)]

        for i in xrange(np):
            switch_cpus[i].system =  testsys
            switch_cpus_1[i].system =  testsys
            switch_cpus[i].workload = testsys.cpu[i].workload
            switch_cpus_1[i].workload = testsys.cpu[i].workload
            switch_cpus[i].clk_domain = testsys.cpu[i].clk_domain
            switch_cpus_1[i].clk_domain = testsys.cpu[i].clk_domain
            switch_cpus[i].isa = testsys.cpu[i].isa
            switch_cpus_1[i].isa = testsys.cpu[i].isa

            # 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.maxinsts:
                switch_cpus_1[i].max_insts_any_thread = options.maxinsts

            # attach the checker cpu if selected
            if options.checker:
                switch_cpus[i].addCheckerCpu()
                switch_cpus_1[i].addCheckerCpu()

        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

    if options.take_simpoint_checkpoints != None:
        simpoints, interval_length = parseSimpointAnalysisFile(options, testsys)

    checkpoint_dir = None
    if options.checkpoint_restore:
        cpt_starttick, checkpoint_dir = findCptDir(options, cptdir, testsys)
    root.apply_config(options.param)
    m5.instantiate(checkpoint_dir)

    # Initialization is complete.  If we're not in control of simulation
    # (that is, if we're a slave simulator acting as a component in another
    #  'master' simulator) then we're done here.  The other simulator will
    # call simulate() directly. --initialize-only is used to indicate this.
    if options.initialize_only:
        return

    # Handle the max tick settings now that tick frequency was resolved
    # during system instantiation
    # NOTE: the maxtick variable here is in absolute ticks, so it must
    # include any simulated ticks before a checkpoint
    explicit_maxticks = 0
    maxtick_from_abs = m5.MaxTick
    maxtick_from_rel = m5.MaxTick
    maxtick_from_maxtime = m5.MaxTick
    if options.abs_max_tick:
        maxtick_from_abs = options.abs_max_tick
        explicit_maxticks += 1
    if options.rel_max_tick:
        maxtick_from_rel = options.rel_max_tick
        if options.checkpoint_restore:
            # NOTE: this may need to be updated if checkpoints ever store
            # the ticks per simulated second
            maxtick_from_rel += cpt_starttick
            if options.at_instruction or options.simpoint:
                warn("Relative max tick specified with --at-instruction or" \
                     " --simpoint\n      These options don't specify the " \
                     "checkpoint start tick, so assuming\n      you mean " \
                     "absolute max tick")
        explicit_maxticks += 1
    if options.maxtime:
        maxtick_from_maxtime = m5.ticks.fromSeconds(options.maxtime)
        explicit_maxticks += 1
    if explicit_maxticks > 1:
        warn("Specified multiple of --abs-max-tick, --rel-max-tick, --maxtime."\
             " Using least")
    maxtick = min([maxtick_from_abs, maxtick_from_rel, maxtick_from_maxtime])

    if options.checkpoint_restore != None and maxtick < cpt_starttick:
        fatal("Bad maxtick (%d) specified: " \
              "Checkpoint starts starts from tick: %d", maxtick, cpt_starttick)

    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 @ tick %s" % (m5.curTick()))

        m5.switchCpus(testsys, switch_cpu_list)

        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.standard_switch)
            print("Switching CPUS @ tick %s" % (m5.curTick()))
            print("Simulation ends instruction count:%d" %
                    (testsys.switch_cpus_1[0].max_insts_any_thread))
            m5.switchCpus(testsys, switch_cpu_list1)

    # 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 or options.take_simpoint_checkpoints) \
        and options.checkpoint_restore:

        if m5.options.outdir:
            cptdir = m5.options.outdir
        else:
            cptdir = getcwd()

    if options.take_checkpoints != None :
        # 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.
        exit_event = scriptCheckpoints(options, maxtick, cptdir)

    # Take SimPoint checkpoints
    elif options.take_simpoint_checkpoints != None:
        takeSimpointCheckpoints(simpoints, interval_length, cptdir)

    # Restore from SimPoint checkpoints
    elif options.restore_simpoint_checkpoint != None:
        restoreSimpointCheckpoint()

    else:
        if options.fast_forward:
            m5.stats.reset()
        print("**** REAL SIMULATION ****")

        # If checkpoints are being taken, then the checkpoint instruction
        # will occur in the benchmark code it self.
        if options.repeat_switch and maxtick > options.repeat_switch:
            exit_event = repeatSwitch(testsys, repeat_switch_cpu_list,
                                      maxtick, options.repeat_switch)
        else:
            exit_event = benchCheckpoints(options, maxtick, cptdir)

    print('Exiting @ tick %i because %s' %
          (m5.curTick(), exit_event.getCause()))
    if options.checkpoint_at_end:
        m5.checkpoint(joinpath(cptdir, "cpt.%d"))

    if exit_event.getCode() != 0:
        print("Simulated exit code not 0! Exit code is", exit_event.getCode())
Пример #5
0
for i in range(np):
    if options.smt:
        system.cpu[i].workload = multiprocesses
    elif len(multiprocesses) == 1:
        system.cpu[i].workload = multiprocesses[0]
    else:
        system.cpu[i].workload = multiprocesses[i]

    if options.simpoint_profile:
        system.cpu[i].addSimPointProbe(options.simpoint_interval)

    if options.checker:
        system.cpu[i].addCheckerCpu()

    if options.bp_type:
        bpClass = BPConfig.get(options.bp_type)
        system.cpu[i].branchPred = bpClass()

    if options.indirect_bp_type:
        indirectBPClass = BPConfig.get_indirect(options.indirect_bp_type)
        system.cpu[i].branchPred.indirectBranchPred = indirectBPClass()

    system.cpu[i].createThreads()

system.redirect_paths = redirect_paths(os.path.expanduser(options.chroot))
config_filesystem(options)

if options.ruby:
    Ruby.create_system(options, False, system)
    assert(options.num_cpus == len(system.ruby._cpu_ports))
Пример #6
0
def run(options, root, testsys, cpu_class):
    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")

    if options.standard_switch and options.repeat_switch:
        fatal("Can't specify both --standard-switch and --repeat-switch")

    if options.repeat_switch and options.take_checkpoints:
        fatal("Can't specify both --repeat-switch and --take-checkpoints")

    np = options.num_cpus
    switch_cpus = None

    if options.prog_interval:
        print("enter prog_interval!")  # zyc
        for i in range(np):
            testsys.cpu[i].progress_interval = options.prog_interval

    if options.maxinsts:
        print("enter maxinsts!")  #zyc
        for i in range(np):
            testsys.cpu[i].max_insts_any_thread = options.maxinsts

    if cpu_class:
        print("enter cpu_class")  #zyc
        switch_cpus = [
            cpu_class(switched_out=True, cpu_id=(i)) for i in range(np)
        ]

        for i in range(np):
            if options.fast_forward:
                testsys.cpu[i].max_insts_any_thread = int(options.fast_forward)
            switch_cpus[i].system = testsys
            switch_cpus[i].workload = testsys.cpu[i].workload
            switch_cpus[i].clk_domain = testsys.cpu[i].clk_domain
            switch_cpus[i].progress_interval = \
                testsys.cpu[i].progress_interval
            switch_cpus[i].isa = testsys.cpu[i].isa
            # simulation period
            if options.maxinsts:
                switch_cpus[i].max_insts_any_thread = options.maxinsts
            # Add checker cpu if selected
            if options.checker:
                switch_cpus[i].addCheckerCpu()
            if options.bp_type:
                bpClass = BPConfig.get(options.bp_type)
                switch_cpus[i].branchPred = bpClass()

        # If elastic tracing is enabled attach the elastic trace probe
        # to the switch CPUs
        if options.elastic_trace_en:
            CpuConfig.config_etrace(cpu_class, switch_cpus, options)

        testsys.switch_cpus = switch_cpus
        switch_cpu_list = [(testsys.cpu[i], switch_cpus[i]) for i in range(np)]

    if options.repeat_switch:
        switch_class = getCPUClass(options.cpu_type)[0]
        if switch_class.require_caches() and \
                not options.caches:
            print("%s: Must be used with caches" % str(switch_class))
            sys.exit(1)
        if not switch_class.support_take_over():
            print("%s: CPU switching not supported" % str(switch_class))
            sys.exit(1)

        repeat_switch_cpus = [switch_class(switched_out=True, \
                                               cpu_id=(i)) for i in range(np)]

        for i in range(np):
            repeat_switch_cpus[i].system = testsys
            repeat_switch_cpus[i].workload = testsys.cpu[i].workload
            repeat_switch_cpus[i].clk_domain = testsys.cpu[i].clk_domain
            repeat_switch_cpus[i].isa = testsys.cpu[i].isa

            if options.maxinsts:
                repeat_switch_cpus[i].max_insts_any_thread = options.maxinsts

            if options.checker:
                repeat_switch_cpus[i].addCheckerCpu()

        testsys.repeat_switch_cpus = repeat_switch_cpus

        if cpu_class:
            repeat_switch_cpu_list = [(switch_cpus[i], repeat_switch_cpus[i])
                                      for i in range(np)]
        else:
            repeat_switch_cpu_list = [(testsys.cpu[i], repeat_switch_cpus[i])
                                      for i in range(np)]

    if options.standard_switch:
        switch_cpus = [
            TimingSimpleCPU(switched_out=True, cpu_id=(i)) for i in range(np)
        ]
        switch_cpus_1 = [
            DerivO3CPU(switched_out=True, cpu_id=(i)) for i in range(np)
        ]

        for i in range(np):
            switch_cpus[i].system = testsys
            switch_cpus_1[i].system = testsys
            switch_cpus[i].workload = testsys.cpu[i].workload
            switch_cpus_1[i].workload = testsys.cpu[i].workload
            switch_cpus[i].clk_domain = testsys.cpu[i].clk_domain
            switch_cpus_1[i].clk_domain = testsys.cpu[i].clk_domain
            switch_cpus[i].isa = testsys.cpu[i].isa
            switch_cpus_1[i].isa = testsys.cpu[i].isa

            # 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.maxinsts:
                switch_cpus_1[i].max_insts_any_thread = options.maxinsts

            # attach the checker cpu if selected
            if options.checker:
                switch_cpus[i].addCheckerCpu()
                switch_cpus_1[i].addCheckerCpu()

        testsys.switch_cpus = switch_cpus
        testsys.switch_cpus_1 = switch_cpus_1
        switch_cpu_list = [(testsys.cpu[i], switch_cpus[i]) for i in range(np)]
        switch_cpu_list1 = [(switch_cpus[i], switch_cpus_1[i])
                            for i in range(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 range(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 range(np):
                testsys.cpu[i].max_insts_any_thread = offset

    if options.take_simpoint_checkpoints != None:
        simpoints, interval_length = parseSimpointAnalysisFile(
            options, testsys)

    checkpoint_dir = None
    if options.checkpoint_restore:
        cpt_starttick, checkpoint_dir = findCptDir(options, cptdir, testsys)
    root.apply_config(options.param)
    m5.instantiate(checkpoint_dir)

    # Initialization is complete.  If we're not in control of simulation
    # (that is, if we're a slave simulator acting as a component in another
    #  'master' simulator) then we're done here.  The other simulator will
    # call simulate() directly. --initialize-only is used to indicate this.
    if options.initialize_only:
        return

    # Handle the max tick settings now that tick frequency was resolved
    # during system instantiation
    # NOTE: the maxtick variable here is in absolute ticks, so it must
    # include any simulated ticks before a checkpoint
    explicit_maxticks = 0
    maxtick_from_abs = m5.MaxTick
    maxtick_from_rel = m5.MaxTick
    maxtick_from_maxtime = m5.MaxTick
    if options.abs_max_tick:
        maxtick_from_abs = options.abs_max_tick
        explicit_maxticks += 1
    if options.rel_max_tick:
        maxtick_from_rel = options.rel_max_tick
        if options.checkpoint_restore:
            # NOTE: this may need to be updated if checkpoints ever store
            # the ticks per simulated second
            maxtick_from_rel += cpt_starttick
            if options.at_instruction or options.simpoint:
                warn("Relative max tick specified with --at-instruction or" \
                     " --simpoint\n      These options don't specify the " \
                     "checkpoint start tick, so assuming\n      you mean " \
                     "absolute max tick")
        explicit_maxticks += 1
    if options.maxtime:
        maxtick_from_maxtime = m5.ticks.fromSeconds(options.maxtime)
        explicit_maxticks += 1
    if explicit_maxticks > 1:
        warn("Specified multiple of --abs-max-tick, --rel-max-tick, --maxtime."\
             " Using least")
    maxtick = min([maxtick_from_abs, maxtick_from_rel, maxtick_from_maxtime])

    if options.checkpoint_restore != None and maxtick < cpt_starttick:
        fatal("Bad maxtick (%d) specified: " \
              "Checkpoint starts starts from tick: %d", maxtick, cpt_starttick)

    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 @ tick %s" % (m5.curTick()))

        m5.switchCpus(testsys, switch_cpu_list)

        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.standard_switch)
            print("Switching CPUS @ tick %s" % (m5.curTick()))
            print("Simulation ends instruction count:%d" %
                  (testsys.switch_cpus_1[0].max_insts_any_thread))
            m5.switchCpus(testsys, switch_cpu_list1)

    # 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 or options.take_simpoint_checkpoints) \
        and options.checkpoint_restore:

        if m5.options.outdir:
            cptdir = m5.options.outdir
        else:
            cptdir = getcwd()

    if options.take_checkpoints != None:
        # 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.
        exit_event = scriptCheckpoints(options, maxtick, cptdir)

    # Take SimPoint checkpoints
    elif options.take_simpoint_checkpoints != None:
        takeSimpointCheckpoints(simpoints, interval_length, cptdir)

    # Restore from SimPoint checkpoints
    elif options.restore_simpoint_checkpoint != None:
        restoreSimpointCheckpoint()

    else:
        if options.fast_forward:
            m5.stats.reset()
        print("**** REAL SIMULATION ****")

        # If checkpoints are being taken, then the checkpoint instruction
        # will occur in the benchmark code it self.
        if options.repeat_switch and maxtick > options.repeat_switch:
            exit_event = repeatSwitch(testsys, repeat_switch_cpu_list, maxtick,
                                      options.repeat_switch)
            print("================ enter repeatSwitch ==================="
                  )  # ZYC
        else:
            exit_event = benchCheckpoints(options, maxtick, cptdir)
            print(
                "=================== enter benchCheckpoints ! =================="
            )  #zyc

    print('Exiting @ tick %i because %s' %
          (m5.curTick(), exit_event.getCause()))
    if options.checkpoint_at_end:
        m5.checkpoint(joinpath(cptdir, "cpt.%d"))

    if exit_event.getCode() != 0:
        print("Simulated exit code not 0! Exit code is", exit_event.getCode())