Difference between revisions of "SPEC CPU2006 benchmarks"
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433.milc floating point C su3imp.in 38027871822 18402.06 output is a little different with the reference | 433.milc floating point C su3imp.in 38027871822 18402.06 output is a little different with the reference | ||
434.zeusmp floating point Fortran zmp_inp 62107158516 27746.77 output is a little different with the reference | 434.zeusmp floating point Fortran zmp_inp 62107158516 27746.77 output is a little different with the reference |
Revision as of 13:32, 29 September 2008
This is a work in-progress. Everyone should feel free to extend this page with their experiences to help new users get started.
Contents
Input sets and Binaries
We can't provide the binaries or input files because of licensing restrictions, but It's not hard to build the binaries by yourself. In this short article, we will share our experiences about what we have done so far.
Build the cross-compiler for alpha machine
Download the crosstool-0.43.tar.gz from http://kegel.com/crosstool and modify these three lines in the demo-alpha.sh :
RESULT_TOP=where_you_want_to_put_the_compiler GCC_LANGUAGES="c,c++,fortran" eval `cat alpha.dat gcc-4.1.0-glibc-2.3.6.dat` sh all.sh --notest
Then follow the steps in the crosstool-howto page to build the cross compiler.
Build the SPEC2006 alpha binaries
Install the SPEC2006 from DVD and modify the CC, CXX, and FC in config/alpha.cfg.
For example: CC = /home/mjwu/crosstool/gcc-4.1.0-glibc-2.3.6/alpha/bin/alpha-gcc CXX = /home/mjwu/crosstool/gcc-4.1.0-glibc-2.3.6/alpha/bin/alpha-g++ FC = /home/mjwu/crosstool/gcc-4.1.0-glibc-2.3.6/alpha/bin/alpha-gfortran
Then follow the instructions in the ./Docs/install-guide-unix.html to build the binaries
For example: runspec --config=alpha.cfg --action=buld --tune=base bzip2
Expand M5 system call functions
Four extra system call functions are needed by SPEC2006. The functions can be modified in:
In m5-stable-mt/src/arch/alpha/linux/process.cc: /* 130 */ SyscallDesc("ftruncate", ftruncateFunc), /* 144 */ SyscallDesc("getrlimit", ignoreFunc), /* 341 */ SyscallDesc("mremap", mremapFunc<AlphaLinux>), /* 367 */ SyscallDesc("getcwd", getcwdFunc),
In m5-stable-mt/src/sim/syscall_emul.hh : ///Target getcwd() handler. SyscallReturn getcwdFunc(SyscallDesc *desc, int num, LiveProcess *p, ThreadContext *tc); //A simple implementation template <class OS> SyscallReturn mremapFunc(SyscallDesc *desc, int num, LiveProcess *p, ThreadContext *tc) { Addr start = tc->getSyscallArg(0); uint64_t length_old = tc->getSyscallArg(1); uint64_t length_new = tc->getSyscallArg(2); if ((start % TheISA::VMPageSize) != 0 || (length_new % TheISA::VMPageSize) != 0) { warn("mremap failing: arguments not page-aligned: " "start 0x%x length 0x%x", start, length_new); return -EINVAL; } if (start != 0) { warn("mremap: ignoring suggested map address 0x%x, using 0x%x", start, p->mmap_end); } // pick next address from our "mmap region" if(length_old < length_new){ warn("mremap size 0x%x %d -> %d",start,length_old,length_new); start = p->mmap_end; p->pTable->allocate(start, length_new-length_old); p->mmap_end += (length_new-length_old); start = tc->getSyscallArg(0); }else{ warn("mremap size 0x%x %d -> %d",start,length_old,length_new); } return start; }
In m5-stable-mt/src/sim/syscall_emul.cc: SyscallReturn getcwdFunc(SyscallDesc *desc, int num, LiveProcess *p, ThreadContext *tc) { char pathname[256]; int path_len = tc->getSyscallArg(1); getcwd(pathname,path_len); BufferArg path(tc->getSyscallArg(0), path_len); strncpy((char *)path.bufferPtr(), pathname, path_len); path.copyOut(tc->getMemPort()); return 0; }
Create the SPEC2006 processes for M5 SE mode
A good reference for the correct command line options can be found here: SPEC_CPU2006_Commands.
For your convenience, here is our benchmark python file for the M5 SE mode.
#Mybench.py #400.perlbench perlbench = LiveProcess() perlbench.executable = binary_dir+'400.perlbench_base.alpha-gcc' perlbench.cmd = [perlbench.executable] + ['-I./lib', 'attrs.pl'] perlbench.output = 'attrs.out' #401.bzip2 bzip2 = LiveProcess() bzip2.executable = binary_dir+'401.bzip2_base.alpha-gcc' data=data_dir+'401.bzip2/data/all/input/input.program' bzip2.cmd = [bzip2.executable] + [data, '1'] bzip2.output = 'input.program.out' #403.gcc gcc = LiveProcess() gcc.executable = binary_dir+'403.gcc_base.alpha-gcc' data=data_dir+'403.gcc/data/test/input/cccp.i' output='/import/home1/mjwu/work_spec2006/403.gcc/m5/cccp.s' gcc.cmd = [gcc.executable] + [data]+['-o',output] gcc.output = 'ccc.out' #410.bwaves bwaves = LiveProcess() bwaves.executable = binary_dir+'410.bwaves_base.alpha-gcc' bwaves.cmd = [bwaves.executable] #416.gamess gamess=LiveProcess() gamess.executable = binary_dir+'416.gamess_base.alpha-gcc' gamess.cmd = [gamess.executable] gamess.input='exam29.config' gamess.output='exam29.output' #429.mcf mcf = LiveProcess() mcf.executable = binary_dir+'429.mcf_base.alpha-gcc' data=data_dir+'429.mcf/data/test/input/inp.in' mcf.cmd = [mcf.executable] + [data] mcf.output = 'inp.out' #433.milc milc=LiveProcess() milc.executable = binary_dir+'433.milc_base.alpha-gcc' stdin=data_dir+'433.milc/data/test/input/su3imp.in' milc.cmd = [milc.executable] milc.input=stdin milc.output='su3imp.out' #434.zeusmp zeusmp=LiveProcess() zeusmp.executable = binary_dir+'434.zeusmp_base.alpha-gcc' zeusmp.cmd = [zeusmp.executable] zeusmp.output = 'zeusmp.stdout' #435.gromacs gromacs = LiveProcess() gromacs.executable = binary_dir+'435.gromacs_base.alpha-gcc' data=data_dir+'435.gromacs/data/test/input/gromacs.tpr' gromacs.cmd = [gromacs.executable] + ['-silent','-deffnm',data,'-nice','0'] #436.cactusADM cactusADM = LiveProcess() cactusADM.executable = binary_dir+'436.cactusADM_base.alpha-gcc' data=data_dir+'436.cactusADM/data/test/input/benchADM.par' cactusADM.cmd = [cactusADM.executable] + [data] cactusADM.cmd = 'benchADM.out' #437.leslie3d leslie3d=LiveProcess() leslie3d.executable = binary_dir+'437.leslie3d_base.alpha-gcc' stdin=data_dir+'437.leslie3d/data/test/input/leslie3d.in' leslie3d.cmd = [leslie3d.executable] leslie3d.input=stdin leslie3d.output='leslie3d.stdout' #444.namd namd = LiveProcess() namd.executable = binary_dir+'444.namd_base.alpha-gcc' input=data_dir+'444.namd/data/all/input/namd.input' namd.cmd = [namd.executable] + ['--input',input,'--iterations','1','--output','namd.out'] namd.output='namd.stdout' #445.gobmk gobmk=LiveProcess() gobmk.executable = binary_dir+'445.gobmk_base.alpha-gcc' stdin=data_dir+'445.gobmk/data/test/input/capture.tst' gobmk.cmd = [gobmk.executable]+['--quiet','--mode','gtp'] gobmk.input=stdin gobmk.output='capture.out' #447.dealII dealII=LiveProcess() dealII.executable = binary_dir+'447.dealII_base.alpha-gcc' dealII.cmd = [gobmk.executable]+['8'] dealII.output='log' #450.soplex soplex=LiveProcess() soplex.executable = binary_dir+'450.soplex_base.alpha-gcc' data=data_dir+'450.soplex/data/test/input/test.mps' soplex.cmd = [soplex.executable]+['-m10000',data] soplex.output = 'test.out' #453.povray povray=LiveProcess() povray.executable = binary_dir+'453.povray_base.alpha-gcc' data=data_dir+'453.povray/data/test/input/SPEC-benchmark-test.ini' #povray.cmd = [povray.executable]+['SPEC-benchmark-test.ini'] povray.cmd = [povray.executable]+[data] povray.output = 'SPEC-benchmark-test.stdout' #454.calculix calculix=LiveProcess() calculix.executable = binary_dir+'454.calculix_base.alpha-gcc' data='/import/RaidHome/mjwu/work_spec2006/454.calculix/m5/beampic' calculix.cmd = [calculix.executable]+['-i',data] calculix.output = 'beampic.log' #456.hmmer hmmer=LiveProcess() hmmer.executable = binary_dir+'456.hmmer_base.alpha-gcc' data=data_dir+'456.hmmer/data/test/input/bombesin.hmm' #data='/import/RaidHome/mjwu/work_spec2006/456.hmmer/m5/bombesin.hmm' hmmer.cmd = [hmmer.executable]+['--fixed', '0', '--mean', '325', '--num', '5000', '--sd', '200', '--seed', '0', data] hmmer.output = 'bombesin.out' #458.sjeng sjeng=LiveProcess() sjeng.executable = binary_dir+'458.sjeng_base.alpha-gcc' data=data_dir+'458.sjeng/data/test/input/test.txt' sjeng.cmd = [sjeng.executable]+[data] sjeng.output = 'test.out' #459.GemsFDTD GemsFDTD=LiveProcess() GemsFDTD.executable = binary_dir+'459.GemsFDTD_base.alpha-gcc' GemsFDTD.cmd = [GemsFDTD.executable] GemsFDTD.output = 'test.log' #462.libquantum libquantum=LiveProcess() libquantum.executable = binary_dir+'462.libquantum_base.alpha-gcc' libquantum.cmd = [libquantum.executable],'33','5' libquantum.output = 'test.out' #464.h264ref h264ref=LiveProcess() h264ref.executable = binary_dir+'464.h264ref_base.alpha-gcc' data=data_dir+'464.h264ref/data/test/input/foreman_test_encoder_baseline.cfg' h264ref.cmd = [h264ref.executable]+['-d',data] h264ref.output = 'foreman_test_encoder_baseline.out' #470.lbm lbm=LiveProcess() lbm.executable = binary_dir+'470.lbm_base.alpha-gcc' data=data_dir+'470.lbm/data/test/input/100_100_130_cf_a.of' lbm.cmd = [lbm.executable]+['20', 'reference.dat', '0', '1' ,data] lbm.output = 'lbm.out' #471.omnetpp omnetpp=LiveProcess() omnetpp.executable = binary_dir+'471.omnetpp_base.alpha-gcc' data=data_dir+'471.omnetpp/data/test/input/omnetpp.ini' omnetpp.cmd = [omnetpp.executable]+[data] omnetpp.output = 'omnetpp.log' #473.astar astar=LiveProcess() astar.executable = binary_dir+'473.astar_base.alpha-gcc' astar.cmd = [astar.executable]+['lake.cfg'] astar.output = 'lake.out' #481.wrf wrf=LiveProcess() wrf.executable = binary_dir+'481.wrf_base.alpha-gcc' wrf.cmd = [wrf.executable]+['namelist.input'] wrf.output = 'rsl.out.0000' #482.sphinx sphinx3=LiveProcess() sphinx3.executable = binary_dir+'482.sphinx_livepretend_base.alpha-gcc' sphinx3.cmd = [sphinx3.executable]+['ctlfile', '.', 'args.an4'] sphinx3.output = 'an4.out' #483.xalancbmk xalancbmk=LiveProcess() xalancbmk.executable = binary_dir+'483.Xalan_base.alpha-gcc' xalancbmk.cmd = [xalancbmk.executable]+['-v','test.xml','xalanc.xsl'] xalancbmk.output = 'test.out' #998.specrand specrand_i=LiveProcess() specrand_i.executable = binary_dir+'998.specrand_base.alpha-gcc' specrand_i.cmd = [specrand_i.executable] + ['324342','24239'] specrand_i.output = 'rand.24239.out' #999.specrand specrand_f=LiveProcess() specrand_f.executable = binary_dir+'999.specrand_base.alpha-gcc' specrand_f.cmd = [specrand_i.executable] + ['324342','24239'] specrand_f.output = 'rand.24239.out'
M5 python configure file
Here is our system configuration python file for the M5 SE mode.
#cmp.py # Simple configuration script import m5 from m5.objects import * import os, optparse, sys m5.AddToPath('./configs') import Simulation from Caches import * import Mybench # Get paths we might need. It's expected this file is in m5/configs/example. config_path = os.path.dirname(os.path.abspath(__file__)) print config_path config_root = os.path.dirname(config_path)+"/configs" print config_root m5_root = os.path.dirname(config_root) print m5_root parser = optparse.OptionParser() # Benchmark options parser.add_option("-b", "--benchmark", default="", help="The benchmark to be loaded.") parser.add_option("-c", "--chkpt", default="", help="The checkpoint to load.") execfile(os.path.join(config_root, "configs", "Options.py")) (options, args) = parser.parse_args() if args: print "Error: script doesn't take any positional arguments" sys.exit(1) if options.benchmark == 'perlbench': process = Mybench.perlbench elif options.benchmark == 'bzip2': process = Mybench.bzip2 elif options.benchmark == 'gcc': process = Mybench.gcc elif options.benchmark == 'bwaves': process = Mybench.bwaves elif options.benchmark == 'gamess': process = Mybench.gamess elif options.benchmark == 'mcf': process = Mybench.mcf elif options.benchmark == 'milc': process = Mybench.milc elif options.benchmark == 'zeusmp': process = Mybench.zeusmp elif options.benchmark == 'gromacs': process = Mybench.gromacs elif options.benchmark == 'cactusADM': process = Mybench.cactusADM elif options.benchmark == 'leslie3d': process = Mybench.leslie3d elif options.benchmark == 'namd': process = Mybench.namd elif options.benchmark == 'gobmk': process = Mybench.gobmk; elif options.benchmark == 'dealII': process = Mybench.dealII elif options.benchmark == 'soplex': process = Mybench.soplex elif options.benchmark == 'povray': process = Mybench.povray elif options.benchmark == 'calculix': process = Mybench.calculix elif options.benchmark == 'hmmer': process = Mybench.hmmer elif options.benchmark == 'sjeng': process = Mybench.sjeng elif options.benchmark == 'GemsFDTD': process = Mybench.GemsFDTD elif options.benchmark == 'libquantum': process = Mybench.libquantum elif options.benchmark == 'h264ref': process = Mybench.h264ref elif options.benchmark == 'tonto': process = Mybench.tonto elif options.benchmark == 'lbm': process = Mybench.lbm elif options.benchmark == 'omnetpp': process = Mybench.omnetpp elif options.benchmark == 'astar': process = Mybench.astar elif options.benchmark == 'wrf': process = Mybench.wrf elif options.benchmark == 'sphinx3': process = Mybench.sphinx3 elif options.benchmark == 'xalancbmk': process = Mybench.xalancbmk elif options.benchmark == 'specrand_i': process = Mybench.specrand_i elif options.benchmark == 'specrand_f': process = Mybench.specrand_f if options.chkpt != "": process.chkpt = options.chkpt (CPUClass, test_mem_mode, FutureClass) = Simulation.setCPUClass(options) CPUClass.clock = '1.0GHz' #np = options.num_cpus np = 1 system = System(cpu = [CPUClass(cpu_id=i) for i in xrange(np)], physmem = PhysicalMemory(range=AddrRange("4096MB")), membus = Bus(), mem_mode = 'timing') system.physmem.port = system.membus.port for i in xrange(np): if options.caches: system.cpu[i].addPrivateSplitL1Caches(L1Cache(size = '64kB'), L1Cache(size = '64kB')) if options.l2cache: system.l2 = L2Cache(size='2MB') system.tol2bus = Bus() system.l2.cpu_side = system.tol2bus.port system.l2.mem_side = system.membus.port system.cpu[i].connectMemPorts(system.tol2bus) else: system.cpu[i].connectMemPorts(system.membus) system.cpu[i].workload = process[i] root = Root(system = system) Simulation.run(options, root, system, FutureClass)
The SPEC2006 testing dataset results
We use the quard-core Xeon 2.5GHz with 16G memory machine. The operation system is 64bits CentOS 5.2.
benchmark | datatype | programming language | input data | number of instructions | host seconds | comment |
400.perlbench | integer | C | attrs.out | - | - | fatal: fault (unalign) detected @ PC 0x12009cedc |
401.bzip2 | integer | C | input.program | 3171671617 | 1353.56 | o.k. |
403.gcc | integer | C | cccp.i | - | - | never end, but o.k. for smaller input |
410.bwaves | floating | Fortran | test | 119365801487 | 51703.94 | o.k. |
416.gamess | floating | Fortran | exam29 | - | - | abormal exit |
429.mcf | integer | C | inp.in | 5112705810 | 3386.09 | o.k. |
benchmark datatype programming language input number of instructions host seconds 433.milc floating point C su3imp.in 38027871822 18402.06 output is a little different with the reference 434.zeusmp floating point Fortran zmp_inp 62107158516 27746.77 output is a little different with the reference 435.gromacs floating point C/Fortran gromacs.tpr 10861507208 4457.33 output error, maybe caused by mremap 436.cactusADM floating point C/Fortran benchADM.par fatal: fault (unalign) detected @ PC 0x120026614 437.leslie3d floating point Fortran leslie3d.in 87402135744 41635.96 o.k. 444.namd floating point C++ namd.input 64449976020 26798.88 o.k. 445.gobmk integer C capture.tst 494502991 260.29 o.k. 447.dealII floating point C++ 8 wrong output 450.soplex floating point C++ test.mps 72422927 31.95 o.k. 453.povray floating point C++ test.ini 3597778011 1737.24 o.k. 454.calculix floating point C beampic.inp 251699786 101.04 o.k. 456.hmmer integer C bombesin.hmm 2386768547 997.97 o.k. 458.sjeng integer C test.txt 21682684235 9406.80 o.k. 459.GemsFDTD floating point Fortran test.in 11046857318 5289.88 o.k. 462.libquantum integer C 33 5 292639209 111.64 o.k. 464.h264ref integer C foreman_test_encoder_baseline.cfg 154340641371 67426.00 o.k. 465.tonto floating point Fortran compile error 470.lbm floating point C 100_100_130_cf_a.of 7058506019 4599.69 o.k. 471.omnetpp integer C++ omnetpp.ini 2450821721 1153.36 o.k. 473.astar integer C++ lake.cfg 35796103621 16433.83 output is a little different with the reference 481.wrf floating point C/Fortran STOP wrf_abort. Need library 482.sphinx3 floating point C args.an4 9352006427 4011.67 o.k. 483.xalancbmk integer C++ test.xml 501493417 276.77 o.k. 998.specrand integer C 324342 24239 71348559 32.93 o.k. 999.specrand floating point C 324342 24239 71348559 32.31.58 o.k.