Exemplo n.º 1
0
int main ()
{

    int cores = 2;
    int N     = 10;
    int LDA   = 10;
    int NRHS  = 5;
    int LDB   = 10;
    int info;
    int info_solution;
    int i,j;
    int LDAxN = LDA*N;
    int LDBxNRHS = LDB*NRHS;

    PLASMA_Complex32_t *A1 = (PLASMA_Complex32_t *)malloc(LDA*N*(sizeof*A1));
    PLASMA_Complex32_t *A2 = (PLASMA_Complex32_t *)malloc(LDA*N*(sizeof*A2));
    PLASMA_Complex32_t *B1 = (PLASMA_Complex32_t *)malloc(LDB*NRHS*(sizeof*B1));
    PLASMA_Complex32_t *B2 = (PLASMA_Complex32_t *)malloc(LDB*NRHS*(sizeof*B2));
    PLASMA_Complex32_t *L;
    int *IPIV;

    /* Check if unable to allocate memory */
    if ((!A1)||(!A2)||(!B1)||(!B2)){
        printf("Out of Memory \n ");
        exit(0);
    }

    /*Plasma Initialize*/
    PLASMA_Init(cores);
    printf("-- PLASMA is initialized to run on %d cores. \n",cores);

    /* Initialize A1 and A2 Matrix */
    LAPACKE_clarnv_work(IONE, ISEED, LDAxN, A1);
    for ( i = 0; i < N; i++)
        for (  j = 0; j < N; j++)
            A2[LDA*j+i] = A1[LDA*j+i];

    /* Initialize B1 and B2 */
    LAPACKE_clarnv_work(IONE, ISEED, LDBxNRHS, B1);
    for ( i = 0; i < N; i++)
        for ( j = 0; j < NRHS; j++)
            B2[LDB*j+i] = B1[LDB*j+i];

    /* PLASMA CGESV */
    info = PLASMA_Alloc_Workspace_cgesv_incpiv(N, &L, &IPIV);
    info = PLASMA_cgesv_incpiv(N, NRHS, A2, LDA, L, IPIV, B2, LDB);

    /* Check the factorization and the solution */
    info_solution = check_solution(N, NRHS, A1, LDA, B1, B2, LDB);

    if ((info_solution != 0)|(info != 0))
       printf("-- Error in CGESV example ! \n");
    else
       printf("-- Run of CGESV example successful ! \n");

    free(A1); free(A2); free(B1); free(B2); free(IPIV); free(L);

    PLASMA_Finalize();

    exit(0);
}
Exemplo n.º 2
0
static int
RunTest(int *iparam, double *dparam, real_Double_t *t_) 
{
    plasma_context_t *plasma;
    Quark_Task_Flags task_flags = Quark_Task_Flags_Initializer;
    PLASMA_Complex64_t *A, *A2 = NULL;
    real_Double_t       t;
    int                *ipiv, *ipiv2 = NULL;
    int i;
    int m     = iparam[TIMING_N];
    int n     = iparam[TIMING_NRHS];
    int check = iparam[TIMING_CHECK];
    int lda   = m;
    PLASMA_sequence *sequence = NULL;
    PLASMA_request request = PLASMA_REQUEST_INITIALIZER;

    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );

    PLASMA_Disable(PLASMA_AUTOTUNING);
    PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
    PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );

    /* Allocate Data */
    A  = (PLASMA_Complex64_t *)malloc(lda*n*sizeof(PLASMA_Complex64_t));

    /* Check if unable to allocate memory */
    if ( (! A) ) {
        printf("Out of Memory \n ");
        return -1;
    }

    /* Initialiaze Data */
    LAPACKE_zlarnv_work(1, ISEED, lda*n, A);

    /* Allocate Workspace */
    ipiv  = (int *)malloc( n*sizeof(int) );

    /* Save A in lapack layout for check */
    if ( check ) {
        A2 = (PLASMA_Complex64_t *)malloc(lda*n*sizeof(PLASMA_Complex64_t));
        ipiv2 = (int *)malloc( n*sizeof(int) );
        LAPACKE_zlacpy_work(LAPACK_COL_MAJOR,' ', m, n, A, lda, A2, lda);
    
        LAPACKE_zgetrf_work(LAPACK_COL_MAJOR, m, n, A2, lda, ipiv2 );
    }

    plasma = plasma_context_self();
    PLASMA_Sequence_Create(&sequence);
    QUARK_Task_Flag_Set(&task_flags, TASK_SEQUENCE, (intptr_t)sequence->quark_sequence);
    QUARK_Task_Flag_Set(&task_flags, TASK_THREAD_COUNT, iparam[TIMING_THRDNBR] );

    plasma_dynamic_spawn();
    CORE_zgetrf_reclap_init();

    t = -cWtime();
    QUARK_CORE_zgetrf_reclap(plasma->quark, &task_flags,
                             m, n, n,
                             A, lda, ipiv,
                             sequence, &request,
                             0, 0,
                             iparam[TIMING_THRDNBR]);
    PLASMA_Sequence_Wait(sequence);
    t += cWtime();
    *t_ = t;
    
    PLASMA_Sequence_Destroy(sequence);

    /* Check the solution */
    if ( check )
    {
        double *work = (double *)malloc(max(m,n)*sizeof(double));

        /* Check ipiv */
        for(i=0; i<n; i++)
        {
            if( ipiv[i] != ipiv2[i] ) {
                fprintf(stderr, "\nPLASMA (ipiv[%d] = %d, A[%d] = %e) / LAPACK (ipiv[%d] = %d, A[%d] = [%e])\n",
                        i, ipiv[i],  i, creal(A[  i * lda + i ]), 
                        i, ipiv2[i], i, creal(A2[ i * lda + i ])); 
                break;
            }
        }

        dparam[TIMING_ANORM] = LAPACKE_zlange_work(LAPACK_COL_MAJOR, lapack_const(PlasmaMaxNorm), 
                                                   m, n, A, lda, work);
        dparam[TIMING_XNORM] = LAPACKE_zlange_work(LAPACK_COL_MAJOR, lapack_const(PlasmaMaxNorm), 
                                                   m, n, A2, lda, work);
        dparam[TIMING_BNORM] = 0.0;

        CORE_zaxpy( m, n, -1.0, A, lda, A2, lda);

        dparam[TIMING_RES] = LAPACKE_zlange_work(LAPACK_COL_MAJOR, lapack_const(PlasmaMaxNorm), 
                                                 m, n, A2, lda, work);

        free( A2 );
        free( ipiv2 );
        free( work );
    }
    
    free( A  );
    free( ipiv );
    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 3
0
static int
RunTest(int *iparam, _PREC *dparam, real_Double_t *t_)
{
    PLASMA_Complex32_t *A, *Acpy = NULL;
    real_Double_t       t;
    int n       = iparam[TIMING_N]; 
    int nb      = iparam[TIMING_NB];
    int check   = iparam[TIMING_CHECK];

    n = ((n % nb) == 0) ? (n / nb) * nb : ((n / nb) + 1) * nb ;
    dparam[TIMING_ANORM] = (_PREC)n;
    dparam[TIMING_BNORM] = (_PREC)_FADDS;

    /* Allocate Data */
    A = (PLASMA_Complex32_t *)malloc(n*n*sizeof(PLASMA_Complex32_t));

    /* Check if unable to allocate memory */
    if ( (!A) ) {
        printf("Out of Memory \n ");
        exit(0);
    }
    
    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE, iparam[TIMING_NB] );
    /* } */

     /* Initialiaze Data */
    LAPACKE_clarnv_work(1, ISEED, n*n, A);

    /* Save A and b  */
    if (check) {
        Acpy = (PLASMA_Complex32_t *)malloc(n*n*sizeof(PLASMA_Complex32_t));
        LAPACKE_clacpy_work(LAPACK_COL_MAJOR, lapack_const(PlasmaUpperLower), n, n, A, n, Acpy, n);
    }

    t = -cWtime();
    PLASMA_cgecfi( n, n, A, PlasmaCM, n, 1, PlasmaCCRB, nb, nb);
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if (check)
      {
        dparam[TIMING_RES] = (_PREC)c_check_conversion(n, n, n, 1, nb, nb, Acpy, A, map_CM, map_CCRB);
        free(Acpy);
      }

    free( A );

    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 4
0
int main( int argc, char *argv[] )
{
    int
    i, j,
    size,
    n_threads,
    n_repeats,
    n_trials,
    nb_alg,
    increment,
    begin;

    FLA_Datatype
    datatype = FLA_DOUBLE;

    FLA_Obj
    A;

    double
    b_norm_value = 0.0,
    dtime,
    *dtimes,
    *flops,
    *T;

    char
    output_file_m[100];

    FILE
    *fpp;

    fprintf( stdout, "%c Enter number of repeats: ", '%' );
    scanf( "%d", &n_repeats );
    fprintf( stdout, "%c %d\n", '%', n_repeats );

    fprintf( stdout, "%c Enter blocksize: ", '%' );
    scanf( "%d", &nb_alg );
    fprintf( stdout, "%c %d\n", '%', nb_alg );

    fprintf( stdout, "%c Enter problem size parameters: first, inc, num: ", '%' );
    scanf( "%d%d%d", &begin, &increment, &n_trials );
    fprintf( stdout, "%c %d %d %d\n", '%', begin, increment, n_trials );

    fprintf( stdout, "%c Enter number of threads: ", '%' );
    scanf( "%d", &n_threads );
    fprintf( stdout, "%c %d\n\n", '%', n_threads );

    sprintf( output_file_m, "%s/%s_output.m", OUTPUT_PATH, OUTPUT_FILE );
    fpp = fopen( output_file_m, "a" );

    fprintf( fpp, "%%\n" );
    fprintf( fpp, "%% | Matrix Size |    PLASMA   |\n" );
    fprintf( fpp, "%% |    n x n    |    GFlops   |\n" );
    fprintf( fpp, "%% -----------------------------\n" );

    FLA_Init();
    PLASMA_Init( n_threads );

    PLASMA_Disable( PLASMA_AUTOTUNING );
    PLASMA_Set( PLASMA_TILE_SIZE, nb_alg );
    PLASMA_Set( PLASMA_INNER_BLOCK_SIZE, nb_alg / 4 );

    dtimes = ( double * ) FLA_malloc( n_repeats * sizeof( double ) );
    flops  = ( double * ) FLA_malloc( n_trials  * sizeof( double ) );

    fprintf( fpp, "%s = [\n", OUTPUT_FILE );

    for ( i = 0; i < n_trials; i++ )
    {
        size = begin + i * increment;

        FLA_Obj_create( datatype, size, size, 0, 0, &A );

        for ( j = 0; j < n_repeats; j++ )
        {
            FLA_Random_matrix( A );

            PLASMA_Alloc_Workspace_dgeqrf( size, size, &T );

            dtime = FLA_Clock();

            PLASMA_dgeqrf( size, size, FLA_Obj_buffer_at_view( A ), size, T );

            dtime = FLA_Clock() - dtime;
            dtimes[j] = dtime;

            free( T );
        }

        dtime = dtimes[0];
        for ( j = 1; j < n_repeats; j++ )
            dtime = min( dtime, dtimes[j] );
        flops[i] = 4.0 / 3.0 * size * size * size / dtime / 1e9;

        fprintf( fpp, "   %d   %6.3f\n", size, flops[i] );

        printf( "Time: %e  |  GFlops: %6.3f\n",
                dtime, flops[i] );
        printf( "Matrix size: %d x %d  |  nb_alg: %d\n",
                size, size, nb_alg );
        printf( "Norm of difference: %le\n\n", b_norm_value );

        FLA_Obj_free( &A );
    }

    fprintf( fpp, "];\n" );

    fflush( fpp );
    fclose( fpp );

    FLA_free( dtimes );
    FLA_free( flops );

    PLASMA_Finalize();
    FLA_Finalize();

    return 0;
}
Exemplo n.º 5
0
static int
RunTest(int *iparam, float *dparam, real_Double_t *t_) 
{
    float *A, *Acpy = NULL, *b, *x;
    real_Double_t       t;
    int                *piv;
    int m     = iparam[TIMING_M];
    int n     = iparam[TIMING_N];
    int nrhs  = iparam[TIMING_NRHS];
    int check = iparam[TIMING_CHECK];
    int lda   = m;
    int ldb   = m;

    /* Allocate Data */
    A   = (float *)malloc(lda*n*sizeof(float));
    piv = (int *)malloc( min(m, n) * sizeof(int));
    
    /* Check if unable to allocate memory */
    if ( !A || !piv ){
        printf("Out of Memory \n ");
        return -1;
    }
    
    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );
    
    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
    PLASMA_Disable(PLASMA_AUTOTUNING);
    PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
    PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );
    /* } else { */
    /*     PLASMA_Get(PLASMA_TILE_SIZE,        &iparam[TIMING_NB] ); */
    /*     PLASMA_Get(PLASMA_INNER_BLOCK_SIZE, &iparam[TIMING_IB] ); */
    /* }  */
    
    /* Initialize Data */
    /*LAPACKE_slarnv_work(1, ISEED, n*lda, A);*/
    PLASMA_splrnt(m, n, A, lda, 3456);

    /* Save AT in lapack layout for check */
    if ( check && (m == n) ) {
        Acpy = (float *)malloc(lda*n*sizeof(float));
        LAPACKE_slacpy_work(LAPACK_COL_MAJOR, 'A', m, n, A, lda, Acpy, lda);
    }

    t = -cWtime();
    PLASMA_sgetrf( m, n, A, lda, piv );
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if ( check && (m == n) )
      {
        b  = (float *)malloc(ldb*nrhs *sizeof(float));
        x  = (float *)malloc(ldb*nrhs *sizeof(float));

        LAPACKE_slarnv_work(1, ISEED, ldb*nrhs, x);
        LAPACKE_slacpy_work(LAPACK_COL_MAJOR, 'A', n, nrhs, x, ldb, b, ldb);

        PLASMA_sgetrs( PlasmaNoTrans, n, nrhs, A, lda, piv, x, ldb );

        dparam[TIMING_RES] = s_check_solution(m, n, nrhs, Acpy, lda, b, x, ldb,
                                              &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]), 
                                              &(dparam[TIMING_XNORM]));

        free( Acpy ); free( b ); free( x );
      }

    free( A );
    free( piv );
    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 6
0
static int
RunTest(int *iparam, float *dparam, real_Double_t *t_) 
{
    float *AT, *BT, *CT;
    float *A = NULL, *B = NULL, *C1 = NULL, *C2 = NULL;
    float alpha, beta;
    PLASMA_desc        *descA, *descB, *descC;
    real_Double_t       t;
    int nb, nb2, nt;
    int n       = iparam[TIMING_N];
    int check   = iparam[TIMING_CHECK];
    int lda     = n;
    
    /* Allocate Data */
    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
    /* } */
    /* } else { */
    /*     PLASMA_Get(PLASMA_TILE_SIZE,        &iparam[TIMING_NB] ); */
    /* }  */
    nb  = iparam[TIMING_NB];
    nb2 = nb * nb;
    nt  = n / nb + ((n % nb == 0) ? 0 : 1);

    AT = (float *)malloc(nt*nt*nb2*sizeof(float));
    BT = (float *)malloc(nt*nt*nb2*sizeof(float));
    CT = (float *)malloc(nt*nt*nb2*sizeof(float));

    /* Check if unable to allocate memory */
    if ( (!AT) || (!BT) || (!CT) ) {
        printf("Out of Memory \n ");
        exit(0);
    }
  
#if defined(PLASMA_CUDA)
    cudaHostRegister(AT, nt*nt*nb2*sizeof(float), cudaHostRegisterPortable);
    cudaHostRegister(BT, nt*nt*nb2*sizeof(float), cudaHostRegisterPortable);
    cudaHostRegister(CT, nt*nt*nb2*sizeof(float), cudaHostRegisterPortable);
#endif

     /* Initialiaze Data */
    LAPACKE_slarnv_work(1, ISEED, 1, &alpha);
    LAPACKE_slarnv_work(1, ISEED, 1, &beta);
    LAPACKE_slarnv_work(1, ISEED, nt*nt*nb2, AT);
    LAPACKE_slarnv_work(1, ISEED, nt*nt*nb2, BT);
    LAPACKE_slarnv_work(1, ISEED, nt*nt*nb2, CT);

    /* Initialize AT and bT for Symmetric Positif Matrix */
    PLASMA_Desc_Create(&descA, AT, PlasmaRealFloat, nb, nb, nb*nb, n, n, 0, 0, n, n);
    PLASMA_Desc_Create(&descB, BT, PlasmaRealFloat, nb, nb, nb*nb, n, n, 0, 0, n, n);
    PLASMA_Desc_Create(&descC, CT, PlasmaRealFloat, nb, nb, nb*nb, n, n, 0, 0, n, n);

    if (check)
      {
          C2 = (float *)malloc(n*lda*sizeof(float));
          PLASMA_Tile_to_Lapack(descC, (void*)C2, n);
      }

#if defined(PLASMA_CUDA)
    core_cublas_init();
#endif

    t = -cWtime();
    PLASMA_sgemm_Tile( PlasmaNoTrans, PlasmaNoTrans, alpha, descA, descB, beta, descC );
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if (check)
      {
          A = (float *)malloc(n*lda*sizeof(float));
          PLASMA_Tile_to_Lapack(descA, (void*)A, n);
          free(AT);

          B = (float *)malloc(n*lda*sizeof(float));
          PLASMA_Tile_to_Lapack(descB, (void*)B, n);
          free(BT);

          C1 = (float *)malloc(n*lda*sizeof(float));
          PLASMA_Tile_to_Lapack(descC, (void*)C1, n);
          free(CT);

          dparam[TIMING_RES] = s_check_gemm( PlasmaNoTrans, PlasmaNoTrans, n, n, n, 
                                            alpha, A, lda, B, lda, beta, C1, C2, lda,
                                            &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]), 
                                            &(dparam[TIMING_XNORM]));
          free(C2);
      }
    else {
        free( AT );
        free( BT );
        free( CT );
    }

    PLASMA_Desc_Destroy(&descA);
    PLASMA_Desc_Destroy(&descB);
    PLASMA_Desc_Destroy(&descC);
    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 7
0
static int
RunTest(int *iparam, _PREC *dparam, real_Double_t *t_) 
{
    PLASMA_Complex32_t *A = NULL, *AT;
    PLASMA_desc        *descA;
    real_Double_t       t;
    int n       = iparam[TIMING_N];
    int nb      = iparam[TIMING_NB];
    int check   = iparam[TIMING_CHECK];

    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE, iparam[TIMING_NB] );
    /* } */

    n = ((n % nb) == 0) ? (n / nb) * nb : ((n / nb) + 1) * nb ;
    dparam[TIMING_ANORM] = (_PREC)n;

    /* Allocate Data */
    AT = (PLASMA_Complex32_t *)malloc(n*n*sizeof(PLASMA_Complex32_t));

    /* Check if unable to allocate memory */
    if ( (!AT) ) {
        printf("Out of Memory \n ");
        exit(0);
    }
    
     /* Initialiaze Data */
    PLASMA_Desc_Create(&descA, AT, PlasmaComplexFloat, nb, nb, nb*nb, n, n, 0, 0, n, n);
    LAPACKE_clarnv_work(1, ISEED, n*n, AT);

    /* Save A and b  */
    if (check) {
        A = (PLASMA_Complex32_t *)malloc(n*n*sizeof(PLASMA_Complex32_t));
        LAPACKE_clacpy_work(LAPACK_COL_MAJOR, lapack_const(PlasmaUpperLower), n, n, AT, n, A, n);
    }

    t = -cWtime();
    PLASMA_Lapack_to_Tile( (void *)A, n, descA);
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if (check)
      {
        dparam[TIMING_RES] = (_PREC)c_check_conversion(n, n, n, 1, nb, nb, A, AT, map_CM, map_CCRB);
        free(A);
      }

    PLASMA_Desc_Destroy(&descA);
    free( AT );

    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 8
0
static int
RunTest(int *iparam, float *dparam, real_Double_t *t_) 
{
    float *AT, *Q = NULL;
    float *W;
    PLASMA_desc *descA = NULL;
    PLASMA_desc *descQ = NULL;
    PLASMA_desc *descT = NULL;
    real_Double_t       t;
    int nb, nb2, nt;
    int n     = iparam[TIMING_N];
    int check = iparam[TIMING_CHECK];
    int lda = n;
    int uplo = PlasmaUpper;
    int vec  = PlasmaNoVec;

    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );

    PLASMA_Disable(PLASMA_AUTOTUNING);
    PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
    PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );

    nb  = iparam[TIMING_NB];
    nb2 = nb * nb;
    nt  = n / nb + ((n % nb == 0) ? 0 : 1);
    
    /* Allocate Data */
    AT  = (float *)malloc(lda*n*sizeof(float));
    W   = (float *)malloc(n*sizeof(float));
    if (vec == PlasmaVec){
       Q = (float *)malloc(lda*n*sizeof(float));
       if ( (!Q) ) {
          printf("Out of Memory -Q-\n ");
          return -2;
       }
    }
       
    /* Check if unable to allocate memory */
    if ( (!AT) || (!W) ) {
        printf("Out of Memory -\n ");
        return -2;
    }

    /* Initialize Data */
    PLASMA_Desc_Create(&descA, AT, PlasmaRealFloat, nb, nb, nb*nb, lda, n, 0, 0, n, n);
    PLASMA_splgsy_Tile((float)0.0, descA, 51 );

    if (vec == PlasmaVec)
      PLASMA_Desc_Create(&descQ, Q, PlasmaRealFloat, nb, nb, nb*nb, lda, n, 0, 0, n, n);

    /* Save AT and bT in lapack layout for check */
    if ( check ) {
    }

    /* Allocate Workspace */
    PLASMA_Alloc_Workspace_ssyev(n, n, &descT);

    t = -cWtime();
    PLASMA_ssyev_Tile( vec, uplo, descA, W, descT, descQ );
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if ( check )
      {
      }

    /* DeAllocate Workspace */
    PLASMA_Dealloc_Handle_Tile(&descT);

    PLASMA_Desc_Destroy(&descA);
 
    if (vec == PlasmaVec) {
      PLASMA_Desc_Destroy(&descQ);
      free( Q );
    }
    free( AT );
    free( W );
    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 9
0
int main ()
{

    int cores = 2;
    int N     = 10;
    int LDA   = 10;
    int NRHS  = 5;
    int LDB   = 10;
    int info;
    int info_solution;
    int i,j;
    int LDAxN = LDA*N;
    int LDBxNRHS = LDB*NRHS;

    PLASMA_Complex64_t *A1 = (PLASMA_Complex64_t *)malloc(LDA*N*(sizeof*A1));
    PLASMA_Complex64_t *A2 = (PLASMA_Complex64_t *)malloc(LDA*N*(sizeof*A2));
    PLASMA_Complex64_t *B1 = (PLASMA_Complex64_t *)malloc(LDB*NRHS*(sizeof*B1));
    PLASMA_Complex64_t *B2 = (PLASMA_Complex64_t *)malloc(LDB*NRHS*(sizeof*B2));
    PLASMA_desc *L;
    int *IPIV;

    /* Check if unable to allocate memory */
    if ((!A1)||(!A2)||(!B1)||(!B2)){
        printf("Out of Memory \n ");
        return EXIT_SUCCESS;
    }

    /*Plasma Initialize*/
    PLASMA_Init(cores);
    printf("-- PLASMA is initialized to run on %d cores. \n",cores);

    /* Initialize A1 and A2 Matrix */
    LAPACKE_zlarnv_work(IONE, ISEED, LDAxN, A1);
    for ( i = 0; i < N; i++)
        for (  j = 0; j < N; j++)
            A2[LDA*j+i] = A1[LDA*j+i];

    /* Initialize B1 and B2 */
    LAPACKE_zlarnv_work(IONE, ISEED, LDBxNRHS, B1);
    for ( i = 0; i < N; i++)
        for ( j = 0; j < NRHS; j++)
            B2[LDB*j+i] = B1[LDB*j+i];


    /* Allocate L and IPIV */
    info = PLASMA_Alloc_Workspace_zgetrf_incpiv(N, N, &L, &IPIV);

    /* LU factorization of the matrix A */
    info = PLASMA_zgetrf_incpiv(N, N, A2, LDA, L, IPIV);

    /* Solve the problem */
    info = PLASMA_ztrsmpl(N, NRHS, A2, LDA, L, IPIV, B2, LDB);
    info = PLASMA_ztrsm(PlasmaLeft, PlasmaUpper, PlasmaNoTrans, PlasmaNonUnit, 
                        N, NRHS, (PLASMA_Complex64_t)1.0, A2, LDA, B2, LDB);

    /* Check the solution */
    info_solution = check_solution(N, NRHS, A1, LDA, B1, B2, LDB);

    if ((info_solution != 0)|(info != 0))
       printf("-- Error in ZGETRS example ! \n");
    else
       printf("-- Run of ZGETRS example successful ! \n");

    free(A1); free(A2); free(B1); free(B2); free(IPIV); free(L);

    PLASMA_Finalize();

    return EXIT_SUCCESS;
}
Exemplo n.º 10
0
static int
RunTest(int *iparam, double *dparam, real_Double_t *t_) 
{
    PLASMA_Complex64_t *AT;
    PLASMA_desc        *descA, *descT;
    real_Double_t       t;
    int nb;
    int M     = iparam[TIMING_N];
    int N     = iparam[TIMING_M];
    //int N = M/nrhs; //RUN WITH NRHS = 10 or 20 (ALSO USED IN TIMING.C)
    int lda = M;

    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
        PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );
    /* } else { */
    /*     PLASMA_Get(PLASMA_TILE_SIZE,        &iparam[TIMING_NB] ); */
    /*     PLASMA_Get(PLASMA_INNER_BLOCK_SIZE, &iparam[TIMING_IB] ); */
    /* }  */
    nb  = iparam[TIMING_NB];

    /* Householder mode */
    //PLASMA_Set(PLASMA_HOUSEHOLDER_MODE, PLASMA_FLAT_HOUSEHOLDER);
    PLASMA_Set(PLASMA_HOUSEHOLDER_MODE, PLASMA_TREE_HOUSEHOLDER);
    PLASMA_Set(PLASMA_HOUSEHOLDER_SIZE, 4);
    
    /* Allocate Data */
    AT  = (PLASMA_Complex64_t *)malloc(lda*N*sizeof(PLASMA_Complex64_t));

    /* Check if unable to allocate memory */
    if ( !AT ){
        printf("Out of Memory \n ");
        exit(0);
    }

    /* Initialiaze Data */
    PLASMA_Desc_Create(&descA, AT, PlasmaComplexDouble, nb, nb, nb*nb, M, N, 0, 0, M, N);
    LAPACKE_zlarnv_work(1, ISEED, lda*N, AT);

    /* Allocate Workspace */
    PLASMA_Alloc_Workspace_zgels_Tile(M, N, &descT);

    t = -cWtime();
    PLASMA_zgeqrf_Tile( descA, descT );
    t += cWtime();
    *t_ = t;
    
    /* Allocate Workspace */
    PLASMA_Dealloc_Handle_Tile(&descT);

    PLASMA_Desc_Destroy(&descA);

    free( AT );
    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 11
0
static int
RunTest(int *iparam, float *dparam, real_Double_t *t_) 
{
    PLASMA_Complex32_t *A, *Acpy = NULL, *L, *b, *x;
    real_Double_t       t;
    int                *piv;
    int n     = iparam[TIMING_N];
    int nrhs  = iparam[TIMING_NRHS];
    int check = iparam[TIMING_CHECK];
    int lda      = n;
    int ldb      = n;

    /* Allocate Data */
    A = (PLASMA_Complex32_t *)malloc(lda*n*sizeof(PLASMA_Complex32_t));
    
    /* Check if unable to allocate memory */
    if ( !A ){
        printf("Out of Memory \n ");
        exit(0);
    }
    
    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );
    
    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
    PLASMA_Disable(PLASMA_AUTOTUNING);
    PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
    PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );
    /* } else { */
    /*     PLASMA_Get(PLASMA_TILE_SIZE,        &iparam[TIMING_NB] ); */
    /*     PLASMA_Get(PLASMA_INNER_BLOCK_SIZE, &iparam[TIMING_IB] ); */
    /* }  */
    
    /* Initialiaze Data */
    LAPACKE_clarnv_work(1, ISEED, n*lda, A);

    /* Allocate Workspace */
    PLASMA_Alloc_Workspace_cgesv_incpiv(n, &L, &piv);

    /* Save AT in lapack layout for check */
    if ( check ) {
        Acpy = (PLASMA_Complex32_t *)malloc(lda*n*sizeof(PLASMA_Complex32_t));
        LAPACKE_clacpy_work(LAPACK_COL_MAJOR,' ', n, n, A, lda, Acpy, lda);
    }

    t = -cWtime();
    PLASMA_cgetrf_incpiv( n, n, A, lda, L, piv );
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if ( check )
      {
        b  = (PLASMA_Complex32_t *)malloc(ldb*nrhs *sizeof(PLASMA_Complex32_t));
        x  = (PLASMA_Complex32_t *)malloc(ldb*nrhs *sizeof(PLASMA_Complex32_t));

        LAPACKE_clarnv_work(1, ISEED, ldb*nrhs, x);
        LAPACKE_clacpy_work(LAPACK_COL_MAJOR,' ', n, nrhs, x, ldb, b, ldb);

        PLASMA_cgetrs_incpiv( PlasmaNoTrans, n, nrhs, A, lda, L, piv, x, ldb );

        dparam[TIMING_RES] = c_check_solution(n, n, nrhs, Acpy, lda, b, x, ldb,
                                             &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]), 
                                             &(dparam[TIMING_XNORM]));

        free( Acpy ); free( b ); free( x );
      }

    free( A );
    free( L );
    free( piv );
    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 12
0
static int
RunTest(int *iparam, float *dparam, real_Double_t *t_) 
{
    float *A = NULL, *AT, *b = NULL, *bT, *x;
    real_Double_t       t;
    PLASMA_desc        *descA, *descB;
    int nb, nb2, nt;
    int n     = iparam[TIMING_N];
    int nrhs  = iparam[TIMING_NRHS];
    int check = iparam[TIMING_CHECK];
    int lda = n;
    int ldb = n;

    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
    /* } else { */
    /*     PLASMA_Get(PLASMA_TILE_SIZE,        &iparam[TIMING_NB] ); */
    /* }  */
    nb  = iparam[TIMING_NB];
    nb2 = nb * nb;
    nt  = n / nb + ((n % nb == 0) ? 0 : 1);
    
    /* Allocate Data */
    AT = (float *)malloc(nt*nt*nb2*sizeof(float));

    /* Check if unable to allocate memory */
    if ( !AT ){
        printf("Out of Memory \n ");
        exit(0);
    }

    /* Initialiaze Data */
    PLASMA_Desc_Create(&descA, AT, PlasmaRealFloat, nb, nb, nb*nb, n, n, 0, 0, n, n);
    PLASMA_splgsy_Tile((float)n, descA, 51 );

    /* Save AT in lapack layout for check */
    if ( check ) {
        A = (float *)malloc(lda*n    *sizeof(float));
        PLASMA_Tile_to_Lapack(descA, (void*)A, n);
    }

    /* PLASMA SPOSV */
    t = -cWtime();
    PLASMA_spotrf_Tile(PlasmaUpper, descA);
    t += cWtime();
    *t_ = t;

    /* Check the solution */
    if ( check )
      {
        b  = (float *)malloc(ldb*nrhs *sizeof(float));
        bT = (float *)malloc(nt*nb2   *sizeof(float));
        x  = (float *)malloc(ldb*nrhs *sizeof(float));

        LAPACKE_slarnv_work(1, ISEED, nt*nb2, bT);
        PLASMA_Desc_Create(&descB, bT, PlasmaRealFloat, nb, nb, nb*nb, n, nrhs, 0, 0, n, nrhs);
        PLASMA_Tile_to_Lapack(descB, (void*)b, n);

        PLASMA_spotrs_Tile( PlasmaUpper, descA, descB );

        PLASMA_Tile_to_Lapack(descB, (void*)x, n);

        dparam[TIMING_RES] = s_check_solution(n, n, nrhs, A, lda, b, x, ldb,
                                             &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]), 
                                             &(dparam[TIMING_XNORM]));
        PLASMA_Desc_Destroy(&descB);
        free( A );
        free( b );
        free( bT );
        free( x );
      }

    PLASMA_Desc_Destroy(&descA);

    free(AT);
    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 13
0
int main ()
{

    int cores = 2;
    int N     = 10;
    int LDA   = 10;
    int NRHS  = 5;
    int LDB   = 10;
    int info;
    int info_solution;
    int i,j;
    int NminusOne = N-1;
    int LDBxNRHS = LDB*NRHS;

    float *A1   = (float *)malloc(LDA*N*sizeof(float));
    float *A2   = (float *)malloc(LDA*N*sizeof(float));
    float *B1   = (float *)malloc(LDB*NRHS*sizeof(float));
    float *B2   = (float *)malloc(LDB*NRHS*sizeof(float));
    float *WORK = (float *)malloc(2*LDA*sizeof(float));
    float *D                = (float *)malloc(LDA*sizeof(float));

    /* Check if unable to allocate memory */
    if ((!A1)||(!A2)||(!B1)||(!B2)){
        printf("Out of Memory \n ");
        exit(0);
    }

    /* Plasma Initialize */
    PLASMA_Init(cores);
    printf("-- PLASMA is initialized to run on %d cores. \n",cores);

    /*-------------------------------------------------------------
    *  TESTING SPOSV
    */

    /* Initialize A1 and A2 for Symmetric Positif Matrix */
    LAPACKE_slarnv_work(IONE, ISEED, LDA, D);
    slagsy(&N, &NminusOne, D, A1, &LDA, ISEED, WORK, &info);
    for ( i = 0; i < N; i++)
        for (  j = 0; j < N; j++)
            A2[LDA*j+i] = A1[LDA*j+i];

    for ( i = 0; i < N; i++){
        A1[LDA*i+i] = A1[LDA*i+i] + (float)N ;
        A2[LDA*i+i] = A1[LDA*i+i];
    }

    /* Initialize B1 and B2 */
    LAPACKE_slarnv_work(IONE, ISEED, LDBxNRHS, B1);
    for ( i = 0; i < N; i++)
        for ( j = 0; j < NRHS; j++)
            B2[LDB*j+i] = B1[LDB*j+i];

    /* PLASMA SPOSV */
    info = PLASMA_sposv(PlasmaUpper, N, NRHS, A2, LDA, B2, LDB);

    /* Check the solution */
    info_solution = check_solution(N, NRHS, A1, LDA, B1, B2, LDB);

    if ((info_solution != 0)|(info != 0))
       printf("-- Error in SPOSV example ! \n");
    else
       printf("-- Run of SPOSV example successful ! \n");

    free(A1); free(A2); free(B1); free(B2); free(WORK); free(D);

    PLASMA_Finalize();

    exit(0);
}
Exemplo n.º 14
0
static int
RunTest(int *iparam, double *dparam, real_Double_t *t_) 
{
    PLASMA_Complex64_t *A, *Acpy = NULL, *b = NULL, *x;
    real_Double_t       t;
    int n     = iparam[TIMING_N];
    int nrhs  = iparam[TIMING_NRHS];
    int check = iparam[TIMING_CHECK];
    int lda = n;
    int ldb = n;

    /* Allocate Data */
    A = (PLASMA_Complex64_t *)malloc(lda*n*   sizeof(PLASMA_Complex64_t));
    x = (PLASMA_Complex64_t *)malloc(ldb*nrhs*sizeof(PLASMA_Complex64_t));

    /* Check if unable to allocate memory */
    if ( (!A) || (!x) ) {
        printf("Out of Memory \n ");
        exit(0);
    }
    
    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
    PLASMA_Disable(PLASMA_AUTOTUNING);
    PLASMA_Set(PLASMA_TILE_SIZE, iparam[TIMING_NB] );
    /* } */

     /* Initialiaze Data */
    PLASMA_zplghe((double)n, n, A, lda, 51 );
    LAPACKE_zlarnv_work(1, ISEED, n*nrhs, x);

    /* Save A and b  */
    if (check) {
        Acpy = (PLASMA_Complex64_t *)malloc(lda*n*   sizeof(PLASMA_Complex64_t));
        b    = (PLASMA_Complex64_t *)malloc(ldb*nrhs*sizeof(PLASMA_Complex64_t));
        LAPACKE_zlacpy_work(LAPACK_COL_MAJOR,' ', n, n,    A, lda, Acpy, lda);
        LAPACKE_zlacpy_work(LAPACK_COL_MAJOR,' ', n, nrhs, x, ldb, b,    ldb);
      }

    /* PLASMA ZPOSV */
    t = -cWtime();
    PLASMA_zposv(PlasmaUpper, n, nrhs, A, lda, x, ldb);
    t += cWtime();
    *t_ = t;

    /* Check the solution */
    if (check)
      {
        dparam[TIMING_RES] = z_check_solution(n, n, nrhs, Acpy, lda, b, x, ldb,
                                             &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]), 
                                             &(dparam[TIMING_XNORM]));
        free(Acpy); free(b);
      }

    free(A); free(x); 

    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 15
0
static int
RunTest(int *iparam, double *dparam, real_Double_t *t_) 
{
    double *A, *b, *x;
    double *Acpy = NULL;
    double *bcpy = NULL;
    real_Double_t       t;
    int                *piv;
    int n       = iparam[TIMING_N];
    int nrhs    = iparam[TIMING_NRHS];
    int check   = iparam[TIMING_CHECK];
    int                 lda = n;
    int                 ldb = n;
    int                iter = 0;
    
    /* Allocate Data */
    A = (double *)malloc(lda*n*   sizeof(double));
    b = (double *)malloc(ldb*nrhs*sizeof(double));
    x = (double *)malloc(ldb*nrhs*sizeof(double));
    piv = (int *)malloc( n*sizeof(int));

    /* Check if unable to allocate memory */
    if ( (!A) || (!b) || (!x) || (!piv) ) {
        printf("Out of Memory \n ");
        return -1;
    }
    
    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
        PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );
    /* } */

     /* Initialiaze Data */
    LAPACKE_dlarnv_work(1, ISEED, lda*n,    A);
    LAPACKE_dlarnv_work(1, ISEED, ldb*nrhs, b);

    /* Save A and b  */
    if (check) {
        Acpy = (double *)malloc(lda*n*   sizeof(double));
        bcpy = (double *)malloc(ldb*nrhs*sizeof(double));
        LAPACKE_dlacpy_work(LAPACK_COL_MAJOR,' ', n, n,    A, lda, Acpy, lda);
        LAPACKE_dlacpy_work(LAPACK_COL_MAJOR,' ', n, nrhs, b, ldb, bcpy, ldb);
      }

    t = -cWtime();
    PLASMA_dsgesv( n, nrhs, A, lda, piv, b, ldb, x, ldb, &iter );
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if (check)
      {
        dparam[TIMING_RES] = d_check_solution(n, n, nrhs, Acpy, lda, bcpy, x, ldb,
                                             &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]), 
                                             &(dparam[TIMING_XNORM]));
        free(Acpy); free(bcpy);
      }

    free( piv );
    free( x );
    free( b );
    free( A );

    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 16
0
int main ()
{

    int cores = 2;
    int M     = 10;
    int N     = 15;
    int LDA   = 10;
    int K = min(M, N);
    int info;
    int info_ortho, info_factorization;
    int i,j;
    int LDAxN = LDA*N;

    double *A1 = (double *)malloc(LDA*N*sizeof(double));
    double *A2 = (double *)malloc(LDA*N*sizeof(double));
    double *Q  = (double *)malloc(LDA*N*sizeof(double));
    double *T;

    /* Check if unable to allocate memory */
    if ((!A1)||(!A2)||(!Q)){
        printf("Out of Memory \n ");
        exit(0);
    }

    /* Plasma Initialization */
    PLASMA_Init(cores);
    printf("-- PLASMA is initialized to run on %d cores. \n",cores);

    /* Allocate T */
    PLASMA_Alloc_Workspace_dgelqf(M, N, &T);

    /* Initialize A1 and A2 */
    LAPACKE_dlarnv_work(IONE, ISEED, LDAxN, A1);
    for (i = 0; i < M; i++)
        for (j = 0; j < N; j++)
            A2[LDA*j+i] = A1[LDA*j+i] ;

    /* Factorization QR of the matrix A2 */
    info = PLASMA_dgelqf(M, N, A2, LDA, T);

    /* Building the economy-size Q */
    memset((void*)Q, 0, LDA*N*sizeof(double));
    for (i = 0; i < K; i++)
        Q[LDA*i+i] = 1.0;

    PLASMA_dorglq(M, N, K, A2, LDA, T, Q, LDA);

    /* Check the orthogonality, factorization and the solution */
    info_ortho = check_orthogonality(M, N, LDA, Q);
    info_factorization = check_factorization(M, N, A1, A2, LDA, Q);

    if ((info_ortho != 0)|(info_factorization != 0)|(info != 0))
       printf("-- Error in DGELQF example ! \n");
    else
       printf("-- Run of DGELQF example successful ! \n");

    free(A1); free(A2); free(Q); free(T);

    PLASMA_Finalize();

    exit(0);
}
Exemplo n.º 17
0
int main ()
{

    int cores = 2;
    int M     = 15;
    int N     = 10;
    int LDA   = 15;
    int NRHS  = 5;
    int LDB   = 15;

    int info;
    int info_solution;
    int i,j;
    int LDAxN = LDA*N;
    int LDBxNRHS = LDB*NRHS;

    double *A1 = (double *)malloc(LDA*N*sizeof(double));
    double *A2 = (double *)malloc(LDA*N*sizeof(double));
    double *B1 = (double *)malloc(LDB*NRHS*sizeof(double));
    double *B2 = (double *)malloc(LDB*NRHS*sizeof(double));
    double *T;

    /* Check if unable to allocate memory */
    if ((!A1)||(!A2)||(!B1)||(!B2)){
        printf("Out of Memory \n ");
        exit(0);
    }

    /* Plasma Initialization */
    PLASMA_Init(cores);
    printf("-- PLASMA is initialized to run on %d cores. \n",cores);

    /* Allocate T */
    PLASMA_Alloc_Workspace_dgeqrf(M, N, &T);

    /* Initialize A1 and A2 */
    LAPACKE_dlarnv_work(IONE, ISEED, LDAxN, A1);
    for (i = 0; i < M; i++)
        for (j = 0; j < N; j++)
            A2[LDA*j+i] = A1[LDA*j+i] ;

    /* Initialize B1 and B2 */
    LAPACKE_dlarnv_work(IONE, ISEED, LDBxNRHS, B1);
    for (i = 0; i < M; i++)
        for (j = 0; j < NRHS; j++)
             B2[LDB*j+i] = B1[LDB*j+i] ;

    /* Factorization QR of the matrix A2 */
    info = PLASMA_dgeqrf(M, N, A2, LDA, T);

    /* Solve the problem */
    info = PLASMA_dgeqrs(M, N, NRHS, A2, LDA, T, B2, LDB);

    /* Check the solution */
    info_solution = check_solution(M, N, NRHS, A1, LDA, B1, B2, LDB);

    if ((info_solution != 0)|(info != 0))
       printf("-- Error in DGEQRS example ! \n");
    else
       printf("-- Run of DGEQRS example successful ! \n");

    free(A1); free(A2); free(B1); free(B2); free(T);

    PLASMA_Finalize();

    exit(0);
}
Exemplo n.º 18
0
/*
 * This function returns the solution of Ax=b
 *
 * The function assumes that A is symmetric & positive definite and employs the
 * Cholesky decomposition implemented by PLASMA for homogeneous multicore processors.
 *
 * A is mxm, b is mx1
 *
 * The function returns 0 in case of error, 1 if successfull
 *
 * This function is often called repetitively to solve problems of identical
 * dimensions. To avoid repetitive malloc's and free's, allocated memory is
 * retained between calls and free'd-malloc'ed when not of the appropriate size.
 * A call with NULL as the first argument forces this memory to be released.
 */
int AX_EQ_B_PLASMA_CHOL(LM_REAL *A, LM_REAL *B, LM_REAL *x, int m)
{
__STATIC__ LM_REAL *buf=NULL;
__STATIC__ int buf_sz=0;

LM_REAL *a;
int a_sz, tot_sz;
int info, nrhs=1;

    if(A==NULL){
#ifdef LINSOLVERS_RETAIN_MEMORY
      if(buf) free(buf);
      buf=NULL;
      buf_sz=0;
#endif /* LINSOLVERS_RETAIN_MEMORY */

      PLASMA_Finalize();
      PLASMA_ncores=-PLASMA_ncores;

      return 1;
    }

    /* calculate required memory size */
    a_sz=m*m;
    tot_sz=a_sz;

#ifdef LINSOLVERS_RETAIN_MEMORY
    if(tot_sz>buf_sz){ /* insufficient memory, allocate a "big" memory chunk at once */
      if(buf) free(buf); /* free previously allocated memory */

      buf_sz=tot_sz;
      buf=(LM_REAL *)malloc(buf_sz*sizeof(LM_REAL));
      if(!buf){
        fprintf(stderr, RCAT("memory allocation in ", AX_EQ_B_PLASMA_CHOL) "() failed!\n");
        exit(1);
      }
    }
#else
    buf_sz=tot_sz;
    buf=(LM_REAL *)malloc(buf_sz*sizeof(LM_REAL));
    if(!buf){
      fprintf(stderr, RCAT("memory allocation in ", AX_EQ_B_PLASMA_CHOL) "() failed!\n");
      exit(1);
    }
#endif /* LINSOLVERS_RETAIN_MEMORY */

    a=buf;

    /* store A into a and B into x; A is assumed to be symmetric,
     * hence no transposition is needed
     */
    memcpy(a, A, a_sz*sizeof(LM_REAL));
    memcpy(x, B, m*sizeof(LM_REAL));

  /* initialize PLASMA */
  if(PLASMA_ncores<0){
    PLASMA_ncores=-PLASMA_ncores;
    PLASMA_Init(PLASMA_ncores);
    fprintf(stderr, RCAT("\n", AX_EQ_B_PLASMA_CHOL) "(): PLASMA is running on %d cores.\n\n", PLASMA_ncores);
  }
  
  /* Solve the linear system */
  info=PLASMA_POSV(PlasmaLower, m, 1, a, m, x, m);
  /* error treatment */
  if(info!=0){
    if(info<0){
      fprintf(stderr, RCAT(RCAT("LAPACK error: illegal value for argument %d of ", PLASMA_POSV) " in ",
                      AX_EQ_B_PLASMA_CHOL) "()\n", -info);
      exit(1);
    }
    else{
      fprintf(stderr, RCAT(RCAT("LAPACK error: the leading minor of order %d is not positive definite,\n"
                                "the factorization could not be completed for ", PLASMA_POSV) " in ", AX_EQ_B_CHOL) "()\n", info);
#ifndef LINSOLVERS_RETAIN_MEMORY
      free(buf);
#endif
      return 0;
    }
  }

#ifndef LINSOLVERS_RETAIN_MEMORY
  free(buf);
#endif

	return 1;
}
Exemplo n.º 19
0
int main (int argc, char **argv)
{
    int ncores, sched;
    int info;
    char func[32];

    /* Check for number of arguments*/
    if ( argc < 4) {
        printf(" Proper Usage is : ./stesting ncores sched FUNC ...\n"
               "   - ncores : number of cores \n"
               "   - sched  : 0 for static, 1 for dynamic\n"
               "   - FUNC   : name of function to test\n");
        exit(1);
    }

    sscanf( argv[1], "%d", &ncores );
    sscanf( argv[2], "%d", &sched  );
    sscanf( argv[3], "%s", func   );

    PLASMA_Init(ncores);
    if ( sched == 0 )
        PLASMA_Set( PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );
    else
        PLASMA_Set( PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );

    argc -= 4;
    argv += 4;
    info  = 0;

    /*
     * Norms
     */
    if ( strcmp(func, "LANGE") == 0 ) {
        info = testing_slange( argc, argv );
    /*
     * Blas Level 3
     */
    } else if ( strcmp(func, "GEMM") == 0 ) {
        info = testing_sgemm( argc, argv );
#ifdef COMPLEX
    } else if ( strcmp(func, "HEMM") == 0 ) {
        info = testing_ssymm( argc, argv );
    } else if ( strcmp(func, "HERK") == 0 ) {
        info = testing_ssyrk( argc, argv );
    } else if ( strcmp(func, "HER2K") == 0 ) {
      info = testing_ssyr2k( argc, argv );
#endif
    } else if ( strcmp(func, "SYMM") == 0 ) {
        info = testing_ssymm( argc, argv );
    } else if ( strcmp(func, "SYRK") == 0 ) {
        info = testing_ssyrk( argc, argv );
        } else if ( strcmp(func, "SYR2K") == 0 ) {
                info = testing_ssyr2k( argc, argv );
    } else if ( strcmp(func, "TRMM") == 0 ) {
        info = testing_strmm( argc, argv );
    } else if ( strcmp(func, "TRSM") == 0 ) {
        info = testing_strsm( argc, argv );
    /*
     * Linear system
     */
    } else if ( strcmp(func, "POSV") == 0 ) {
        info = testing_sposv( argc, argv );
    } else if ( strcmp(func, "GELS") == 0 ) {
        info = testing_sgels( argc, argv );
    } else if ( strcmp(func, "GESV") == 0 ) {
        info = testing_sgesv( argc, argv );
    /*
     * Eigenvalue Problems
     */
    } else if ( strcmp(func, "HEEV") == 0 ) {
      info = testing_ssyev( argc, argv );
    } else if ( strcmp(func, "HEGV") == 0 ) {
      info = testing_ssygv( argc, argv );
    } else if ( strcmp(func, "HEGST") == 0 ) {
      info = testing_ssygst( argc, argv );
    /*
     * Singular Value Decomposition
     */
    } else if ( strcmp(func, "GESVD") == 0 ) {
      info = testing_sgesvd( argc, argv );
#ifdef DOUBLE
    /*
     * Mixed precision
     */
    } else if ( strcmp(func, "SPOSV") == 0 ) {
        info = testing_dsposv( argc, argv );
    } else if ( strcmp(func, "SGESV") == 0 ) {
        info = testing_dsgesv( argc, argv );
    } else if ( strcmp(func, "SUNGESV") == 0 ) {
        info = testing_dsungesv( argc, argv );
#endif
    /* Layout Transformation */
    } else if ( strcmp(func, "GECFI") == 0 ) {
        info = testing_sgecfi( argc, argv );
    } else if ( strcmp(func, "GETMI") == 0 ) {
        info = testing_sgetmi( argc, argv );
    } else {
        fprintf(stderr, "Function unknown\n");
    }

    if ( info == -1 ) {
        printf( "TESTING %s FAILED : incorrect number of arguments\n", func);
    } else if ( info == -2 ) {
        printf( "TESTING %s FAILED : not enough memory\n", func);
    }

    PLASMA_Finalize();

    return EXIT_SUCCESS;
}
Exemplo n.º 20
0
static int
RunTest(int *iparam, double *dparam, real_Double_t *t_) 
{
    double *A = NULL, *AT, *b = NULL, *bT, *x;
    PLASMA_desc        *descA, *descB, *descT;
    real_Double_t       t;
    int nb, nb2, nt;
    int n     = iparam[TIMING_N];
    int nrhs  = iparam[TIMING_NRHS];
    int check = iparam[TIMING_CHECK];
    int lda = n;
    int ldb = n;

    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );
  
#if defined(PLASMA_CUDA)
  core_cublas_init();
#endif

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
        PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );
    /* } else { */
    /*     PLASMA_Get(PLASMA_TILE_SIZE,        &iparam[TIMING_NB] ); */
    /*     PLASMA_Get(PLASMA_INNER_BLOCK_SIZE, &iparam[TIMING_IB] ); */
    /* }  */
    nb  = iparam[TIMING_NB];
    nb2 = nb * nb;
    nt  = n / nb + ((n % nb == 0) ? 0 : 1);
    
    /* Allocate Data */
    AT  = (double *)malloc(nt*nt*nb2*sizeof(double));

    /* Check if unable to allocate memory */
    if ( !AT ){
        printf("Out of Memory \n ");
        exit(0);
    }
  
#if defined(PLASMA_CUDA)
    cudaHostRegister((void*)AT, nt*nt*nb2*sizeof(double), cudaHostRegisterPortable);
#endif

    /* Initialiaze Data */
    PLASMA_Desc_Create(&descA, AT, PlasmaRealDouble, nb, nb, nb*nb, n, n, 0, 0, n, n);
    LAPACKE_dlarnv_work(1, ISEED, nt*nt*nb2, AT);

    /* Allocate Workspace */
    PLASMA_Alloc_Workspace_dgels_Tile(n, n, &descT);
  
#if defined(PLASMA_CUDA)
    cudaHostRegister((void*)descT->mat, descT->lm*descT->ln*sizeof(double), cudaHostRegisterPortable);
#endif

    /* Save AT in lapack layout for check */
    if ( check ) {
        A = (double *)malloc(lda*n    *sizeof(double));
        PLASMA_Tile_to_Lapack(descA, (void*)A, n);
    }

    t = -cWtime();
    PLASMA_dgeqrf_Tile( descA, descT );
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if ( check )
      {
        b  = (double *)malloc(ldb*nrhs *sizeof(double));
        bT = (double *)malloc(nt*nb2   *sizeof(double));
        x  = (double *)malloc(ldb*nrhs *sizeof(double));

        LAPACKE_dlarnv_work(1, ISEED, nt*nb2, bT);
        PLASMA_Desc_Create(&descB, bT, PlasmaRealDouble, nb, nb, nb*nb, n, nrhs, 0, 0, n, nrhs);
        PLASMA_Tile_to_Lapack(descB, (void*)b, n);

        PLASMA_dgeqrs_Tile( descA, descT, descB );

        PLASMA_Tile_to_Lapack(descB, (void*)x, n);

        dparam[TIMING_RES] = d_check_solution(n, n, nrhs, A, lda, b, x, ldb,
                                             &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]), 
                                             &(dparam[TIMING_XNORM]));

        PLASMA_Desc_Destroy(&descB);
        free( A ); 
        free( b ); 
        free( bT ); 
        free( x );
      }

    /* Allocate Workspace */
    PLASMA_Dealloc_Handle_Tile(&descT);

    PLASMA_Desc_Destroy(&descA);

    free( AT );
    PLASMA_Finalize();
#if defined(PLASMA_CUDA)
#endif
    return 0;
}
Exemplo n.º 21
0
static int
RunTest(int *iparam, double *dparam, real_Double_t *t_)
{
    PLASMA_Complex64_t *A, *B1, *B2 = NULL;
    PLASMA_Complex64_t alpha;
    real_Double_t       t;
    int n       = iparam[TIMING_N];
    int nrhs    = n;
    int check   = iparam[TIMING_CHECK];
    int lda     = n;

    /* Allocate Data */
    A  = (PLASMA_Complex64_t *)malloc(lda*n   *sizeof(PLASMA_Complex64_t));
    B1 = (PLASMA_Complex64_t *)malloc(lda*nrhs*sizeof(PLASMA_Complex64_t));

    /* Check if unable to allocate memory */
    if ( (!A) || (!B1) ) {
        printf("Out of Memory \n ");
        exit(0);
    }

    /* Initialize Plasma */
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE, iparam[TIMING_NB] );
    /* } */

     /* Initialiaze Data */
    lapack_zlarnv(1, ISEED, n   *lda,  A );
    lapack_zlarnv(1, ISEED, nrhs*lda,  B1);
    lapack_zlarnv(1, ISEED, 1,  &alpha);
    int i;
    for(i=0;i<max(n, nrhs);i++)
      A[lda*i+i] = A[lda*i+i] + 2.0;

    if (check)
    {
        B2 = (PLASMA_Complex64_t *)malloc(lda*nrhs*sizeof(PLASMA_Complex64_t));
        memcpy(B2, B1, lda*nrhs*sizeof(PLASMA_Complex64_t));
    }

    t = -cWtime();
    PLASMA_ztrsm( PlasmaLeft, PlasmaUpper, PlasmaNoTrans, PlasmaUnit,
          n, nrhs, alpha, A, lda, B1, lda );
    t += cWtime();
    *t_ = t;

    /* Check the solution */
    if (check)
      {
    dparam[TIMING_RES] = z_check_trsm( PlasmaLeft, PlasmaUpper, PlasmaNoTrans, PlasmaUnit, n, nrhs,
                      alpha, A, lda, B1, B2, lda,
                      &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]),
                      &(dparam[TIMING_XNORM]));
    free(B2);
      }

    free( A );
    free( B1 );

    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 22
0
static int
RunTest(int *iparam, double *dparam, real_Double_t *t_) 
{
    PLASMA_Complex64_t *A = NULL, *AT, *b, *bT, *x;
    PLASMA_desc        *descA, *descB, *descL;
    real_Double_t       t;
    int                *piv;
    int nb, nb2, nt;
    int n     = iparam[TIMING_N];
    int nrhs  = iparam[TIMING_NRHS];
    int check = iparam[TIMING_CHECK];
    int lda      = n;
    int ldb      = n;

    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
        PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );
    /* } else { */
    /*     PLASMA_Get(PLASMA_TILE_SIZE,        &iparam[TIMING_NB] ); */
    /*     PLASMA_Get(PLASMA_INNER_BLOCK_SIZE, &iparam[TIMING_IB] ); */
    /* }  */
    nb  = iparam[TIMING_NB];
    nb2 = nb * nb;
    nt  = n / nb + ((n % nb == 0) ? 0 : 1);
    
    /* Allocate Data */
    AT  = (PLASMA_Complex64_t *)malloc(nt*nt*nb2*sizeof(PLASMA_Complex64_t));

    /* Check if unable to allocate memory */
    if ( !AT ){
        printf("Out of Memory \n ");
        exit(0);
    }

    /* Initialiaze Data */
    PLASMA_Desc_Create(&descA, AT, PlasmaComplexDouble, nb, nb, nb*nb, n, n, 0, 0, n, n);
    LAPACKE_zlarnv_work(1, ISEED, nt*nt*nb2, AT);

    /* Allocate Workspace */
    PLASMA_Alloc_Workspace_zgesv_incpiv_Tile(n, &descL, &piv);

    /* Save AT in lapack layout for check */
    if ( check ) {
        A = (PLASMA_Complex64_t *)malloc(lda*n    *sizeof(PLASMA_Complex64_t));
        PLASMA_Tile_to_Lapack(descA, (void*)A, n);
    }

    t = -cWtime();
    PLASMA_zgetrf_incpiv_Tile( descA, descL, piv );
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if ( check )
      {
        b  = (PLASMA_Complex64_t *)malloc(ldb*nrhs *sizeof(PLASMA_Complex64_t));
        bT = (PLASMA_Complex64_t *)malloc(nt*nb2   *sizeof(PLASMA_Complex64_t));
        x  = (PLASMA_Complex64_t *)malloc(ldb*nrhs *sizeof(PLASMA_Complex64_t));

        LAPACKE_zlarnv_work(1, ISEED, n*nrhs, b);
        PLASMA_Desc_Create(&descB, bT, PlasmaComplexDouble, nb, nb, nb*nb, n, nrhs, 0, 0, n, nrhs);
        PLASMA_Lapack_to_Tile((void*)b, n, descB);

        PLASMA_zgetrs_incpiv_Tile( descA, descL, piv, descB );

        PLASMA_Tile_to_Lapack(descB, (void*)x, n);

        dparam[TIMING_RES] = z_check_solution(n, n, nrhs, A, lda, b, x, ldb,
                                             &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]), 
                                             &(dparam[TIMING_XNORM]));

        PLASMA_Desc_Destroy(&descB);
        free( A ); free( b ); free( bT ); free( x );
      }

    /* Deallocate Workspace */
    PLASMA_Dealloc_Handle_Tile(&descL);

    PLASMA_Desc_Destroy(&descA);

    free( AT );
    free( piv );
    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 23
0
static int
RunTest(int *iparam, float *dparam, real_Double_t *t_) 
{
    float *AT, *bT, *x;
    float *A = NULL;
    float *b = NULL;
    PLASMA_desc        *descA, *descB;
    real_Double_t       t;
    int                *piv;
    int n     = iparam[TIMING_N];
    int nb    = iparam[TIMING_NB];
    int nrhs  = iparam[TIMING_NRHS];
    int check = iparam[TIMING_CHECK];
    int lda = n;
    int ldb = n;

    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    else
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING );

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
        PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );
    /* } else { */
    /*     PLASMA_Get(PLASMA_TILE_SIZE,        &iparam[TIMING_NB] ); */
    /*     PLASMA_Get(PLASMA_INNER_BLOCK_SIZE, &iparam[TIMING_IB] ); */
    /* }  */
    
    /* Allocate Data */
    AT  = (float *)malloc(lda*n   *sizeof(float));
    bT  = (float *)malloc(ldb*nrhs*sizeof(float));
    piv = (int *)malloc( n*sizeof(int));

    /* Check if unable to allocate memory */
    if ( (!AT) || (!bT) || (!piv) ) {
        printf("Out of Memory \n ");
        return -1;
    }

    /* Initialize AT and bT for Symmetric Positif Matrix */
    PLASMA_Desc_Create(&descA, AT, PlasmaRealFloat, nb, nb, nb*nb, lda, n,    0, 0, n, n);
    PLASMA_Desc_Create(&descB, bT, PlasmaRealFloat, nb, nb, nb*nb, ldb, nrhs, 0, 0, n, nrhs);
    LAPACKE_slarnv_work(1, ISEED, lda*n,    AT);
    LAPACKE_slarnv_work(1, ISEED, ldb*nrhs, bT);

    /* Save AT and bT in lapack layout for check */
    if ( check ) {
        A = (float *)malloc(lda*n   *sizeof(float));
        b = (float *)malloc(ldb*nrhs*sizeof(float));
        PLASMA_sTile_to_Lapack(descA, (void*)A, lda);
        PLASMA_sTile_to_Lapack(descB, (void*)b, ldb);
    }

    t = -cWtime();
    PLASMA_sgesv_Tile( descA, piv, descB );
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if ( check )
      {
        x = (float *)malloc(ldb*nrhs *sizeof(float));
        PLASMA_sTile_to_Lapack(descB, (void*)x, n);

        dparam[TIMING_RES] = s_check_solution(n, n, nrhs, A, lda, b, x, ldb,
                                             &(dparam[TIMING_ANORM]), &(dparam[TIMING_BNORM]), 
                                             &(dparam[TIMING_XNORM]));
        free(A); free(b); free(x);
      }

    PLASMA_Desc_Destroy(&descA);
    PLASMA_Desc_Destroy(&descB);

    free( AT ); free( bT );
    free( piv );
    PLASMA_Finalize();

    return 0;
}
Exemplo n.º 24
0
int main ()
{

    int cores = 2;
    int N     = 10 ;
    int LDA   = 10 ;
    int NRHS  = 5 ;
    int LDB   = 10 ;
    int info;
    int info_solution;
    int i,j;
    int NminusOne = N-1;
    int LDBxNRHS = LDB*NRHS;

    PLASMA_Complex32_t *A1   = (PLASMA_Complex32_t *)malloc(LDA*N*sizeof(PLASMA_Complex32_t));
    PLASMA_Complex32_t *A2   = (PLASMA_Complex32_t *)malloc(LDA*N*sizeof(PLASMA_Complex32_t));
    PLASMA_Complex32_t *B1   = (PLASMA_Complex32_t *)malloc(LDB*NRHS*sizeof(PLASMA_Complex32_t));
    PLASMA_Complex32_t *B2   = (PLASMA_Complex32_t *)malloc(LDB*NRHS*sizeof(PLASMA_Complex32_t));
    PLASMA_Complex32_t *WORK = (PLASMA_Complex32_t *)malloc(2*LDA*sizeof(PLASMA_Complex32_t));
    float *D                = (float *)malloc(LDA*sizeof(float));

    /* Check if unable to allocate memory */
    if ((!A1)||(!A2)||(!B1)||(!B2)) {
        printf("Out of Memory \n ");
        exit(0);
    }

    /* Plasma Initialize */
    PLASMA_Init(cores);
    printf("-- PLASMA is initialized to run on %d cores. \n",cores);

    /* Initialize A1 and A2 for Symmetric Positive Matrix */
    LAPACKE_slarnv_work(IONE, ISEED, LDA, D);
    claghe(&N, &NminusOne, D, A1, &LDA, ISEED, WORK, &info);
    for ( i = 0; i < N; i++)
        for (  j = 0; j < N; j++)
            A2[LDA*j+i] = A1[LDA*j+i];

    for ( i = 0; i < N; i++) {
        A1[LDA*i+i] = A1[LDA*i+i]+ (PLASMA_Complex32_t)N ;
        A2[LDA*i+i] = A1[LDA*i+i];
    }

    /* Initialize B1 and B2 */
    LAPACKE_clarnv_work(IONE, ISEED, LDBxNRHS, B1);
    for ( i = 0; i < N; i++)
        for ( j = 0; j < NRHS; j++)
            B2[LDB*j+i] = B1[LDB*j+i];

    /* PLASMA routines */
    info = PLASMA_cpotrf(PlasmaLower, N, A2, LDA);
    info = PLASMA_ctrsm(PlasmaLeft, PlasmaLower, PlasmaNoTrans, PlasmaNonUnit,
                        N, NRHS, (PLASMA_Complex32_t)1.0, A2, LDA, B2, LDB);
    info = PLASMA_ctrsm(PlasmaLeft, PlasmaLower, PlasmaConjTrans, PlasmaNonUnit,
                        N, NRHS, (PLASMA_Complex32_t)1.0, A2, LDA, B2, LDB);

    /* Check the solution */
    info_solution = check_solution(N, NRHS, A1, LDA, B1, B2, LDB);

    if ((info_solution != 0)|(info != 0))
        printf("-- Error in CTRSM example ! \n");
    else
        printf("-- Run of CTRSM example successful ! \n");

    free(A1);
    free(A2);
    free(B1);
    free(B2);
    free(WORK);
    free(D);

    PLASMA_Finalize();

    exit(0);
}
Exemplo n.º 25
0
static int
RunTest(int *iparam, float *dparam, real_Double_t *t_) 
{
    PLASMA_Complex32_t *AT, *BT, *Q = NULL;
    float *W;
    PLASMA_desc *descA, *descB, *descQ, *descT;
    real_Double_t       t;
    int nb, nb2, nt;
    int n     = iparam[TIMING_N];
    int check = iparam[TIMING_CHECK];
    int lda = n;
    int itype = 1;
    int vec   = PlasmaNoVec;
    int uplo  = PlasmaUpper;

    /* Initialize Plasma */ 
    PLASMA_Init( iparam[TIMING_THRDNBR] );
    //    if ( iparam[TIMING_SCHEDULER] )
        PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_DYNAMIC_SCHEDULING );
    /* else */
    /*     PLASMA_Set(PLASMA_SCHEDULING_MODE, PLASMA_STATIC_SCHEDULING ); */

    /*if ( !iparam[TIMING_AUTOTUNING] ) {*/
        PLASMA_Disable(PLASMA_AUTOTUNING);
        PLASMA_Set(PLASMA_TILE_SIZE,        iparam[TIMING_NB] );
        PLASMA_Set(PLASMA_INNER_BLOCK_SIZE, iparam[TIMING_IB] );
    /* } else { */
    /*     PLASMA_Get(PLASMA_TILE_SIZE,        &iparam[TIMING_NB] ); */
    /*     PLASMA_Get(PLASMA_INNER_BLOCK_SIZE, &iparam[TIMING_IB] ); */
    /* }  */
    nb  = iparam[TIMING_NB];
    nb2 = nb * nb;
    nt  = n / nb + ((n % nb == 0) ? 0 : 1);
    
    /* Allocate Data */
    AT  = (PLASMA_Complex32_t *)malloc(nt*nt*nb2*sizeof(PLASMA_Complex32_t));
    BT  = (PLASMA_Complex32_t *)malloc(nt*nt*nb2*sizeof(PLASMA_Complex32_t));
    W  = (float *)malloc(n*sizeof(float));
    if (vec == PlasmaVec){
       Q = (PLASMA_Complex32_t *)malloc(nt*nt*nb2*sizeof(PLASMA_Complex32_t));
       if ( (!Q) ) {
          printf("Out of Memory -Q-\n ");
          exit(0);
       }
    }
       
    /* Check if unable to allocate memory */
    if ( (!AT) || (!BT) || (!W) ) {
        printf("Out of Memory -\n ");
        exit(0);
    }

    /* Initialiaze Data */
    PLASMA_Desc_Create(&descA, AT, PlasmaComplexFloat, nb, nb, nb*nb, lda, n, 0, 0, n, n);
    PLASMA_cplghe_Tile((float)0.0, descA, 51 );

    PLASMA_Desc_Create(&descB, BT, PlasmaComplexFloat, nb, nb, nb*nb, lda, n, 0, 0, n, n);
    PLASMA_cplghe_Tile((float)n, descB, 51 );

    PLASMA_Desc_Create(&descQ, Q, PlasmaComplexFloat, nb, nb, nb*nb, lda, n, 0, 0, n, n);

    /* Save AT and bT in lapack layout for check */
    if ( check ) {
    }

    /* Allocate Workspace */
    PLASMA_Alloc_Workspace_chegv(n, n, &descT);

    t = -cWtime();
    PLASMA_chegv_Tile( itype, vec, uplo, descA, descB, W, descT, descQ );
    t += cWtime();
    *t_ = t;
    
    /* Check the solution */
    if ( check )
      {
      }

    /* DeAllocate Workspace */
    PLASMA_Dealloc_Handle_Tile(&descT);

    PLASMA_Desc_Destroy(&descA);
    PLASMA_Desc_Destroy(&descB);
    PLASMA_Desc_Destroy(&descQ);

    if (vec == PlasmaVec)
       free( Q );
    free( AT );
    free( W );
    PLASMA_Finalize();

    return 0;
}