benchmarks/streams/SSEVersion.c

b8a1809bSJed Brownstatic const char help[] = "STREAM benchmark specialized for SSE2\n\\n";
b8a1809bSJed Brown
b8a1809bSJed Brown/* Note: this file has been modified significantly from its original version */
b8a1809bSJed Brown#include <emmintrin.h>
b8a1809bSJed Brown#include <petsctime.h>
b8a1809bSJed Brown#include <petscsys.h>
fa8572e2SBarry Smith#if defined(HAVE_NUMA)
b8a1809bSJed Brown#include <numa.h>
fa8572e2SBarry Smith#endif
b8a1809bSJed Brown#include <limits.h>
b8a1809bSJed Brown#include <float.h>
b8a1809bSJed Brown
519f805aSKarl Rupp#if !defined(SSE2)
b8a1809bSJed Brown#  define SSE2 1
b8a1809bSJed Brown#endif
519f805aSKarl Rupp#if !defined(__SSE2__)
b8a1809bSJed Brown#  error SSE2 instruction set is not enabled, try adding -march=native to CFLAGS or disable by adding -DSSE2=0
b8a1809bSJed Brown#endif
519f805aSKarl Rupp#if !defined(PREFETCH_NTA) /* Use software prefetch and set non-temporal policy so that lines evicted from L1D will not subsequently reside in L2 or L3. */
b8a1809bSJed Brown#  define PREFETCH_NTA 1
b8a1809bSJed Brown#endif
519f805aSKarl Rupp#if !defined(STATIC_ALLOC) /* Statically allocate the vectors. Most platforms do not find physical pages when memory is allocated, therefore the faulting strategy still affects performance. */
b8a1809bSJed Brown#  define STATIC_ALLOC 0
b8a1809bSJed Brown#endif
519f805aSKarl Rupp#if !defined(FAULT_TOGETHER) /* Faults all three vectors together which usually interleaves DRAM pages in physical memory. */
b8a1809bSJed Brown#  define FAULT_TOGETHER 0
b8a1809bSJed Brown#endif
519f805aSKarl Rupp#if !defined(USE_MEMCPY) /* Literally call memcpy(3) for the COPY benchmark. Some compilers detect the unoptimized loop as memcpy and call this anyway. */
b8a1809bSJed Brown#  define USE_MEMCPY 0
b8a1809bSJed Brown#endif
b8a1809bSJed Brown
b8a1809bSJed Brown/*
b8a1809bSJed Brown * Program: Stream
b8a1809bSJed Brown * Programmer: Joe R. Zagar
b8a1809bSJed Brown * Revision: 4.0-BETA, October 24, 1995
b8a1809bSJed Brown * Original code developed by John D. McCalpin
b8a1809bSJed Brown *
b8a1809bSJed Brown * This program measures memory transfer rates in MB/s for simple
b8a1809bSJed Brown * computational kernels coded in C.  These numbers reveal the quality
b8a1809bSJed Brown * of code generation for simple uncacheable kernels as well as showing
b8a1809bSJed Brown * the cost of floating-point operations relative to memory accesses.
b8a1809bSJed Brown *
b8a1809bSJed Brown * INSTRUCTIONS:
b8a1809bSJed Brown *
b8a1809bSJed Brown *       1) Stream requires a good bit of memory to run.  Adjust the
b8a1809bSJed Brown *          value of 'N' (below) to give a 'timing calibration' of
b8a1809bSJed Brown *          at least 20 clock-ticks.  This will provide rate estimates
b8a1809bSJed Brown *          that should be good to about 5% precision.
b8a1809bSJed Brown */
b8a1809bSJed Brown
b8a1809bSJed Brown# define N      4000000
b8a1809bSJed Brown# define NTIMES     100
b8a1809bSJed Brown# define OFFSET       0
b8a1809bSJed Brown
b8a1809bSJed Brown# define HLINE "-------------------------------------------------------------\n"
b8a1809bSJed Brown
519f805aSKarl Rupp# if !defined(MIN)
b8a1809bSJed Brown# define MIN(x,y) ((x)<(y) ? (x) : (y))
b8a1809bSJed Brown# endif
519f805aSKarl Rupp# if !defined(MAX)
b8a1809bSJed Brown# define MAX(x,y) ((x)>(y) ? (x) : (y))
b8a1809bSJed Brown# endif
b8a1809bSJed Brown
b8a1809bSJed Brown#if STATIC_ALLOC
b8a1809bSJed Browndouble a[N+OFFSET],b[N+OFFSET],c[N+OFFSET];
b8a1809bSJed Brown#endif
b8a1809bSJed Brown
b8a1809bSJed Brownstatic int checktick(void);
b8a1809bSJed Brownstatic double Second(void);
b8a1809bSJed Brown
b8a1809bSJed Brownint main(int argc,char *argv[])
b8a1809bSJed Brown{
b8a1809bSJed Brown  const char   *label[4] = {"Copy", "Scale","Add", "Triad"};
b8a1809bSJed Brown  const double bytes[4]  = {2 * sizeof(double) * N,
b8a1809bSJed Brown                            2 * sizeof(double) * N,
b8a1809bSJed Brown                            3 * sizeof(double) * N,
b8a1809bSJed Brown                            3 * sizeof(double) * N};
b8a1809bSJed Brown  double       rmstime[4] = {0},maxtime[4] = {0},mintime[4] = {FLT_MAX,FLT_MAX,FLT_MAX,FLT_MAX};
b8a1809bSJed Brown  int          quantum;
b8a1809bSJed Brown  int          BytesPerWord,j,k,size;
b8a1809bSJed Brown  PetscInt     node = -1;
b8a1809bSJed Brown  double       scalar, t, times[4][NTIMES];
b8a1809bSJed Brown#if !STATIC_ALLOC
b8a1809bSJed Brown  double       *PETSC_RESTRICT a,*PETSC_RESTRICT b,*PETSC_RESTRICT c;
b8a1809bSJed Brown#endif
b8a1809bSJed Brown
b8a1809bSJed Brown  PetscInitialize(&argc,&argv,0,help);
b8a1809bSJed Brown  MPI_Comm_size(PETSC_COMM_WORLD,&size);
b8a1809bSJed Brown  PetscOptionsGetInt(PETSC_NULL,"-node",&node,PETSC_NULL);
b8a1809bSJed Brown  /* --- SETUP --- determine precision and check timing --- */
b8a1809bSJed Brown
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,HLINE);
b8a1809bSJed Brown  BytesPerWord = sizeof(double);
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"This system uses %d bytes per DOUBLE PRECISION word.\n",
b8a1809bSJed Brown              BytesPerWord);
b8a1809bSJed Brown
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,HLINE);
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"Array size = %d, Offset = %d\n", N, OFFSET);
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"Total memory required = %.1f MB per process.\n",
b8a1809bSJed Brown              (3 * N * BytesPerWord) / 1048576.0);
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"Each test is run %d times, but only\n", NTIMES);
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"the *best* time for each is used.\n");
b8a1809bSJed Brown
b8a1809bSJed Brown  /* Get initial value for system clock. */
b8a1809bSJed Brown
b8a1809bSJed Brown#if !STATIC_ALLOC
b8a1809bSJed Brown  if (node == -1) {
b8a1809bSJed Brown    posix_memalign((void**)&a,64,N*sizeof(double));
b8a1809bSJed Brown    posix_memalign((void**)&b,64,N*sizeof(double));
b8a1809bSJed Brown    posix_memalign((void**)&c,64,N*sizeof(double));
b8a1809bSJed Brown  } else if (node == -2) {
b8a1809bSJed Brown    a = malloc(N*sizeof(double));
b8a1809bSJed Brown    b = malloc(N*sizeof(double));
b8a1809bSJed Brown    c = malloc(N*sizeof(double));
fa8572e2SBarry Smith#if defined(HAVE_NUMA)
b8a1809bSJed Brown  } else {
b8a1809bSJed Brown    a = numa_alloc_onnode(N*sizeof(double),node);
b8a1809bSJed Brown    b = numa_alloc_onnode(N*sizeof(double),node);
b8a1809bSJed Brown    c = numa_alloc_onnode(N*sizeof(double),node);
fa8572e2SBarry Smith#endif
b8a1809bSJed Brown  }
b8a1809bSJed Brown#endif
b8a1809bSJed Brown#if FAULT_TOGETHER
b8a1809bSJed Brown  for (j=0; j<N; j++) {
b8a1809bSJed Brown    a[j] = 1.0;
b8a1809bSJed Brown    b[j] = 2.0;
b8a1809bSJed Brown    c[j] = 0.0;
b8a1809bSJed Brown  }
b8a1809bSJed Brown#else
b8a1809bSJed Brown  for (j=0; j<N; j++) a[j] = 1.0;
b8a1809bSJed Brown  for (j=0; j<N; j++) b[j] = 2.0;
b8a1809bSJed Brown  for (j=0; j<N; j++) c[j] = 0.0;
b8a1809bSJed Brown#endif
b8a1809bSJed Brown
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,HLINE);
b8a1809bSJed Brown
*6f2b61bcSKarl Rupp  if  ((quantum = checktick()) >= 1)
b8a1809bSJed Brown    PetscPrintf(PETSC_COMM_WORLD,"Your clock granularity/precision appears to be "
b8a1809bSJed Brown                "%d microseconds.\n", quantum);
*6f2b61bcSKarl Rupp  else
b8a1809bSJed Brown    PetscPrintf(PETSC_COMM_WORLD,"Your clock granularity appears to be "
b8a1809bSJed Brown                "less than one microsecond.\n");
b8a1809bSJed Brown
b8a1809bSJed Brown  t = Second();
*6f2b61bcSKarl Rupp  for (j = 0; j < N; j++) a[j] = 2.0E0 * a[j];
b8a1809bSJed Brown  t = 1.0E6 * (Second() - t);
b8a1809bSJed Brown
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"Each test below will take on the order"
b8a1809bSJed Brown              " of %d microseconds.\n", (int) t);
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"   (= %d clock ticks)\n", (int) (t/quantum));
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"Increase the size of the arrays if this shows that\n");
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"you are not getting at least 20 clock ticks per test.\n");
b8a1809bSJed Brown
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,HLINE);
b8a1809bSJed Brown
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"WARNING -- The above is only a rough guideline.\n");
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"For best results, please be sure you know the\n");
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"precision of your system timer.\n");
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,HLINE);
b8a1809bSJed Brown
b8a1809bSJed Brown  /* --- MAIN LOOP --- repeat test cases NTIMES times --- */
b8a1809bSJed Brown
b8a1809bSJed Brown  scalar = 3.0;
b8a1809bSJed Brown  for (k=0; k<NTIMES; k++) {
106b1c52SJed Brown    MPI_Barrier(PETSC_COMM_WORLD);
b8a1809bSJed Brown    /* ### COPY: c <- a ### */
b8a1809bSJed Brown    times[0][k] = Second();
106b1c52SJed Brown    MPI_Barrier(PETSC_COMM_WORLD);
b8a1809bSJed Brown#if USE_MEMCPY
b8a1809bSJed Brown    memcpy(c,a,N*sizeof(double));
b8a1809bSJed Brown#elif SSE2
b8a1809bSJed Brown    for (j=0; j<N; j+=8) {
b8a1809bSJed Brown      _mm_stream_pd(c+j+0,_mm_load_pd(a+j+0));
b8a1809bSJed Brown      _mm_stream_pd(c+j+2,_mm_load_pd(a+j+2));
b8a1809bSJed Brown      _mm_stream_pd(c+j+4,_mm_load_pd(a+j+4));
b8a1809bSJed Brown      _mm_stream_pd(c+j+6,_mm_load_pd(a+j+6));
b8a1809bSJed Brown#  if PREFETCH_NTA
b8a1809bSJed Brown      _mm_prefetch(a+j+64,_MM_HINT_NTA);
b8a1809bSJed Brown#  endif
b8a1809bSJed Brown    }
b8a1809bSJed Brown#else
b8a1809bSJed Brown    for (j=0; j<N; j++) c[j] = a[j];
b8a1809bSJed Brown#endif
106b1c52SJed Brown    MPI_Barrier(PETSC_COMM_WORLD);
b8a1809bSJed Brown    times[0][k] = Second() - times[0][k];
b8a1809bSJed Brown
b8a1809bSJed Brown    /* ### SCALE: b <- scalar * c ### */
b8a1809bSJed Brown    times[1][k] = Second();
106b1c52SJed Brown    MPI_Barrier(PETSC_COMM_WORLD);
b8a1809bSJed Brown#if SSE2
b8a1809bSJed Brown    {
b8a1809bSJed Brown      __m128d scalar2 = _mm_set1_pd(scalar);
b8a1809bSJed Brown      for (j=0; j<N; j+=8) {
b8a1809bSJed Brown        _mm_stream_pd(b+j+0,_mm_mul_pd(scalar2,_mm_load_pd(c+j+0)));
b8a1809bSJed Brown        _mm_stream_pd(b+j+2,_mm_mul_pd(scalar2,_mm_load_pd(c+j+2)));
b8a1809bSJed Brown        _mm_stream_pd(b+j+4,_mm_mul_pd(scalar2,_mm_load_pd(c+j+4)));
b8a1809bSJed Brown        _mm_stream_pd(b+j+6,_mm_mul_pd(scalar2,_mm_load_pd(c+j+6)));
b8a1809bSJed Brown#  if PREFETCH_NTA
b8a1809bSJed Brown        _mm_prefetch(c+j+64,_MM_HINT_NTA);
b8a1809bSJed Brown#  endif
b8a1809bSJed Brown      }
b8a1809bSJed Brown    }
b8a1809bSJed Brown#else
b8a1809bSJed Brown    for (j=0; j<N; j++) b[j] = scalar*c[j];
b8a1809bSJed Brown#endif
106b1c52SJed Brown    MPI_Barrier(PETSC_COMM_WORLD);
b8a1809bSJed Brown    times[1][k] = Second() - times[1][k];
b8a1809bSJed Brown
b8a1809bSJed Brown    /* ### ADD: c <- a + b ### */
b8a1809bSJed Brown    times[2][k] = Second();
106b1c52SJed Brown    MPI_Barrier(PETSC_COMM_WORLD);
b8a1809bSJed Brown#if SSE2
b8a1809bSJed Brown    {
b8a1809bSJed Brown      for (j=0; j<N; j+=8) {
b8a1809bSJed Brown        _mm_stream_pd(c+j+0,_mm_add_pd(_mm_load_pd(a+j+0),_mm_load_pd(b+j+0)));
b8a1809bSJed Brown        _mm_stream_pd(c+j+2,_mm_add_pd(_mm_load_pd(a+j+2),_mm_load_pd(b+j+2)));
b8a1809bSJed Brown        _mm_stream_pd(c+j+4,_mm_add_pd(_mm_load_pd(a+j+4),_mm_load_pd(b+j+4)));
b8a1809bSJed Brown        _mm_stream_pd(c+j+6,_mm_add_pd(_mm_load_pd(a+j+6),_mm_load_pd(b+j+6)));
b8a1809bSJed Brown#  if PREFETCH_NTA
b8a1809bSJed Brown        _mm_prefetch(a+j+64,_MM_HINT_NTA);
b8a1809bSJed Brown        _mm_prefetch(b+j+64,_MM_HINT_NTA);
b8a1809bSJed Brown#  endif
b8a1809bSJed Brown      }
b8a1809bSJed Brown    }
b8a1809bSJed Brown#else
b8a1809bSJed Brown    for (j=0; j<N; j++) c[j] = a[j]+b[j];
b8a1809bSJed Brown#endif
106b1c52SJed Brown    MPI_Barrier(PETSC_COMM_WORLD);
b8a1809bSJed Brown    times[2][k] = Second() - times[2][k];
b8a1809bSJed Brown
b8a1809bSJed Brown    /* ### TRIAD: a <- b + scalar * c ### */
b8a1809bSJed Brown    times[3][k] = Second();
106b1c52SJed Brown    MPI_Barrier(PETSC_COMM_WORLD);
b8a1809bSJed Brown#if SSE2
b8a1809bSJed Brown    {
b8a1809bSJed Brown      __m128d scalar2 = _mm_set1_pd(scalar);
b8a1809bSJed Brown      for (j=0; j<N; j+=8) {
b8a1809bSJed Brown        _mm_stream_pd(a+j+0,_mm_add_pd(_mm_load_pd(b+j+0),_mm_mul_pd(scalar2,_mm_load_pd(c+j+0))));
b8a1809bSJed Brown        _mm_stream_pd(a+j+2,_mm_add_pd(_mm_load_pd(b+j+2),_mm_mul_pd(scalar2,_mm_load_pd(c+j+2))));
b8a1809bSJed Brown        _mm_stream_pd(a+j+4,_mm_add_pd(_mm_load_pd(b+j+4),_mm_mul_pd(scalar2,_mm_load_pd(c+j+4))));
b8a1809bSJed Brown        _mm_stream_pd(a+j+6,_mm_add_pd(_mm_load_pd(b+j+6),_mm_mul_pd(scalar2,_mm_load_pd(c+j+6))));
b8a1809bSJed Brown#  if PREFETCH_NTA
b8a1809bSJed Brown        _mm_prefetch(b+j+64,_MM_HINT_NTA);
b8a1809bSJed Brown        _mm_prefetch(c+j+64,_MM_HINT_NTA);
b8a1809bSJed Brown#  endif
b8a1809bSJed Brown      }
b8a1809bSJed Brown    }
b8a1809bSJed Brown#else
b8a1809bSJed Brown    for (j=0; j<N; j++) a[j] = b[j]+scalar*c[j];
b8a1809bSJed Brown#endif
106b1c52SJed Brown    MPI_Barrier(PETSC_COMM_WORLD);
b8a1809bSJed Brown    times[3][k] = Second() - times[3][k];
b8a1809bSJed Brown  }
b8a1809bSJed Brown
b8a1809bSJed Brown  /* --- SUMMARY --- */
b8a1809bSJed Brown
*6f2b61bcSKarl Rupp  for (k=0; k<NTIMES; k++)
b8a1809bSJed Brown    for (j=0; j<4; j++) {
b8a1809bSJed Brown      rmstime[j] = rmstime[j] + (times[j][k] * times[j][k]);
b8a1809bSJed Brown      mintime[j] = MIN(mintime[j], times[j][k]);
b8a1809bSJed Brown      maxtime[j] = MAX(maxtime[j], times[j][k]);
b8a1809bSJed Brown    }
b8a1809bSJed Brown
b8a1809bSJed Brown
b8a1809bSJed Brown  PetscPrintf(PETSC_COMM_WORLD,"%8s:  %11s  %11s  %11s  %11s  %11s\n","Function","Rate (MB/s)","Total (MB/s)","RMS time","Min time","Max time");
b8a1809bSJed Brown  for (j=0; j<4; j++) {
b8a1809bSJed Brown    rmstime[j] = sqrt(rmstime[j]/(double)NTIMES);
b8a1809bSJed Brown    PetscPrintf(PETSC_COMM_WORLD,"%8s: %11.4f  %11.4f  %11.4f  %11.4f  %11.4f\n", label[j], 1.0e-06*bytes[j]/mintime[j], size*1.0e-06*bytes[j]/mintime[j], rmstime[j], mintime[j], maxtime[j]);
b8a1809bSJed Brown  }
b8a1809bSJed Brown  PetscFinalize();
b8a1809bSJed Brown  return 0;
b8a1809bSJed Brown}
b8a1809bSJed Brown
a6dfd86eSKarl Ruppstatic double Second()
a6dfd86eSKarl Rupp{
b8a1809bSJed Brown  double t;
b8a1809bSJed Brown  PetscTime(t);
b8a1809bSJed Brown  return t;
b8a1809bSJed Brown}
b8a1809bSJed Brown
b8a1809bSJed Brown#define M 20
b8a1809bSJed Brownstatic int checktick()
b8a1809bSJed Brown{
b8a1809bSJed Brown  int    i, minDelta, Delta;
b8a1809bSJed Brown  double t1, t2, timesfound[M];
b8a1809bSJed Brown
b8a1809bSJed Brown  /*  Collect a sequence of M unique time values from the system. */
b8a1809bSJed Brown
b8a1809bSJed Brown  for (i = 0; i < M; i++) {
b8a1809bSJed Brown    t1 = Second();
*6f2b61bcSKarl Rupp    while ((t2 = Second()) - t1 < 1.0E-6) {
*6f2b61bcSKarl Rupp    }
b8a1809bSJed Brown    timesfound[i] = t1 = t2;
b8a1809bSJed Brown  }
b8a1809bSJed Brown
b8a1809bSJed Brown  /*
b8a1809bSJed Brown   * Determine the minimum difference between these M values.
b8a1809bSJed Brown   * This result will be our estimate (in microseconds) for the
b8a1809bSJed Brown   * clock granularity.
b8a1809bSJed Brown   */
b8a1809bSJed Brown
b8a1809bSJed Brown  minDelta = 1000000;
b8a1809bSJed Brown  for (i = 1; i < M; i++) {
b8a1809bSJed Brown    Delta    = (int)(1.0E6 * (timesfound[i]-timesfound[i-1]));
b8a1809bSJed Brown    minDelta = MIN(minDelta, MAX(Delta,0));
b8a1809bSJed Brown  }
b8a1809bSJed Brown
b8a1809bSJed Brown  return(minDelta);
b8a1809bSJed Brown}