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OpenBLAS/interface/gemm_batch.c

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  1. /*****************************************************************************

  2. Copyright (c) 2020, The OpenBLAS Project

  3. All rights reserved.

  4. 

  5. Redistribution and use in source and binary forms, with or without

  6. modification, are permitted provided that the following conditions are

  7. met:

  8. 

  9.    1. Redistributions of source code must retain the above copyright

  10.       notice, this list of conditions and the following disclaimer.

  11. 

  12.    2. Redistributions in binary form must reproduce the above copyright

  13.       notice, this list of conditions and the following disclaimer in

  14.       the documentation and/or other materials provided with the

  15.       distribution.

  16.    3. Neither the name of the OpenBLAS project nor the names of 

  17.       its contributors may be used to endorse or promote products 

  18.       derived from this software without specific prior written 

  19.       permission.

  20. 

  21. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"

  22. AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE

  23. IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE

  24. ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE

  25. LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL

  26. DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR

  27. SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER

  28. CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,

  29. OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE

  30. USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

  31. 

  32. **********************************************************************************/

  33. 

  34. #include <stdio.h>

  35. #include <stdlib.h>

  36. #include "common.h"

  37. 

  38. void openblas_warning(int verbose, const char * msg);

  39. 

  40. #ifndef COMPLEX

  41. #ifdef XDOUBLE

  42. #define ERROR_NAME "QGEMM_BATCH "

  43. #elif defined(DOUBLE)

  44. #define ERROR_NAME "DGEMM_BATCH "

  45. #define GEMM_BATCH_THREAD dgemm_batch_thread

  46. #else

  47. #define ERROR_NAME "SGEMM_BATCH "

  48. #define GEMM_BATCH_THREAD sgemm_batch_thread

  49. #endif

  50. #else

  51. #ifdef XDOUBLE

  52. #define ERROR_NAME "XGEMM_BATCH "

  53. #elif defined(DOUBLE)

  54. #define ERROR_NAME "ZGEMM_BATCH "

  55. #define GEMM_BATCH_THREAD zgemm_batch_thread

  56. #else

  57. #define ERROR_NAME "CGEMM_BATCH "

  58. #define GEMM_BATCH_THREAD cgemm_batch_thread

  59. #endif

  60. #endif

  61. static int (*gemm[])(blas_arg_t *, BLASLONG *, BLASLONG *, IFLOAT *, IFLOAT *, BLASLONG) = {

  62.   GEMM_NN, GEMM_TN, GEMM_RN, GEMM_CN,

  63.   GEMM_NT, GEMM_TT, GEMM_RT, GEMM_CT,

  64.   GEMM_NR, GEMM_TR, GEMM_RR, GEMM_CR,

  65.   GEMM_NC, GEMM_TC, GEMM_RC, GEMM_CC,

  66. };

  67. 

  68. #if defined(SMALL_MATRIX_OPT) && !defined(GEMM3M) && !defined(XDOUBLE)

  69. #define USE_SMALL_MATRIX_OPT 1

  70. #else

  71. #define USE_SMALL_MATRIX_OPT 0

  72. #endif

  73. 

  74. #if USE_SMALL_MATRIX_OPT

  75. #ifndef DYNAMIC_ARCH

  76. #define SMALL_KERNEL_ADDR(table, idx) ((void *)(table[idx]))

  77. #else

  78. #define SMALL_KERNEL_ADDR(table, idx) ((void *)(*(uintptr_t *)((char *)gotoblas + (size_t)(table[idx]))))

  79. #endif

  80. 

  81. 

  82. #ifndef COMPLEX

  83. static size_t gemm_small_kernel[] = {

  84. 	GEMM_SMALL_KERNEL_NN, GEMM_SMALL_KERNEL_TN, 0, 0,

  85. 	GEMM_SMALL_KERNEL_NT, GEMM_SMALL_KERNEL_TT, 0, 0,

  86. };

  87. 

  88. 

  89. static size_t gemm_small_kernel_b0[] = {

  90. 	GEMM_SMALL_KERNEL_B0_NN, GEMM_SMALL_KERNEL_B0_TN, 0, 0,

  91. 	GEMM_SMALL_KERNEL_B0_NT, GEMM_SMALL_KERNEL_B0_TT, 0, 0,

  92. };

  93. 

  94. #define GEMM_SMALL_KERNEL_B0(idx) (int (*)(BLASLONG, BLASLONG, BLASLONG, IFLOAT *, BLASLONG, FLOAT, IFLOAT *, BLASLONG, FLOAT *, BLASLONG)) SMALL_KERNEL_ADDR(gemm_small_kernel_b0, (idx))

  95. #define GEMM_SMALL_KERNEL(idx) (int (*)(BLASLONG, BLASLONG, BLASLONG, IFLOAT *, BLASLONG, FLOAT, IFLOAT *, BLASLONG, FLOAT, FLOAT *, BLASLONG)) SMALL_KERNEL_ADDR(gemm_small_kernel, (idx))

  96. #else

  97. 

  98. static size_t zgemm_small_kernel[] = {

  99. 	GEMM_SMALL_KERNEL_NN, GEMM_SMALL_KERNEL_TN, GEMM_SMALL_KERNEL_RN, GEMM_SMALL_KERNEL_CN,

  100. 	GEMM_SMALL_KERNEL_NT, GEMM_SMALL_KERNEL_TT, GEMM_SMALL_KERNEL_RT, GEMM_SMALL_KERNEL_CT,

  101. 	GEMM_SMALL_KERNEL_NR, GEMM_SMALL_KERNEL_TR, GEMM_SMALL_KERNEL_RR, GEMM_SMALL_KERNEL_CR,

  102. 	GEMM_SMALL_KERNEL_NC, GEMM_SMALL_KERNEL_TC, GEMM_SMALL_KERNEL_RC, GEMM_SMALL_KERNEL_CC,

  103. };

  104. 

  105. static size_t zgemm_small_kernel_b0[] = {

  106. 	GEMM_SMALL_KERNEL_B0_NN, GEMM_SMALL_KERNEL_B0_TN, GEMM_SMALL_KERNEL_B0_RN, GEMM_SMALL_KERNEL_B0_CN,

  107. 	GEMM_SMALL_KERNEL_B0_NT, GEMM_SMALL_KERNEL_B0_TT, GEMM_SMALL_KERNEL_B0_RT, GEMM_SMALL_KERNEL_B0_CT,

  108. 	GEMM_SMALL_KERNEL_B0_NR, GEMM_SMALL_KERNEL_B0_TR, GEMM_SMALL_KERNEL_B0_RR, GEMM_SMALL_KERNEL_B0_CR,

  109. 	GEMM_SMALL_KERNEL_B0_NC, GEMM_SMALL_KERNEL_B0_TC, GEMM_SMALL_KERNEL_B0_RC, GEMM_SMALL_KERNEL_B0_CC,

  110. };

  111. 

  112. #define ZGEMM_SMALL_KERNEL(idx) (int (*)(BLASLONG, BLASLONG, BLASLONG, FLOAT *, BLASLONG, FLOAT , FLOAT, FLOAT *, BLASLONG, FLOAT , FLOAT, FLOAT *, BLASLONG)) SMALL_KERNEL_ADDR(zgemm_small_kernel, (idx))

  113. #define ZGEMM_SMALL_KERNEL_B0(idx) (int (*)(BLASLONG, BLASLONG, BLASLONG, FLOAT *, BLASLONG, FLOAT , FLOAT, FLOAT *, BLASLONG, FLOAT *, BLASLONG)) SMALL_KERNEL_ADDR(zgemm_small_kernel_b0, (idx))

  114. #endif

  115. #endif

  116. 

  117. void CNAME(enum CBLAS_ORDER order, enum CBLAS_TRANSPOSE *  transa_array, enum CBLAS_TRANSPOSE * transb_array,

  118. 	   blasint * m_array, blasint * n_array, blasint * k_array,

  119. #ifndef COMPLEX

  120. 	   FLOAT * alpha_array,

  121. 	   IFLOAT ** a_array, blasint * lda_array,

  122. 	   IFLOAT ** b_array, blasint * ldb_array,

  123. 	   FLOAT * beta_array,

  124. 	   FLOAT ** c_array, blasint * ldc_array, blasint group_count, blasint * group_size) {

  125. #else

  126. 	   void * valpha_array,

  127. 	   void ** va_array, blasint * lda_array,

  128. 	   void ** vb_array, blasint * ldb_array,

  129. 	   void * vbeta_array,

  130. 	   void ** vc_array, blasint * ldc_array, blasint group_count, blasint * group_size) {

  131. 

  132.   FLOAT * alpha_array=(FLOAT *)valpha_array;

  133.   FLOAT * beta_array=(FLOAT *)vbeta_array;

  134.   FLOAT ** a_array=(FLOAT**)va_array;

  135.   FLOAT ** b_array=(FLOAT**)vb_array;

  136.   FLOAT ** c_array=(FLOAT**)vc_array;

  137.     

  138. #endif

  139.   blas_arg_t * args_array=NULL;

  140. 

  141.   int mode=0, group_mode=0;

  142.   blasint total_num=0;

  143. 

  144.   blasint i=0, j=0, matrix_idx=0, count=0;

  145. 

  146.   int group_transa, group_transb;

  147.   BLASLONG group_nrowa, group_nrowb;

  148.   blasint info;

  149. 

  150.   void * group_alpha, * group_beta;

  151.   BLASLONG group_m, group_n, group_k;

  152.   BLASLONG group_lda, group_ldb, group_ldc;

  153.   void * group_routine=NULL;

  154. #ifdef SMALL_MATRIX_OPT

  155.   void * group_small_matrix_opt_routine=NULL;

  156. #endif

  157.   

  158. #if defined (SMP) || defined(SMALL_MATRIX_OPT)

  159.   double MNK;

  160. #endif

  161. 

  162.   PRINT_DEBUG_CNAME;

  163.     

  164.   for(i=0; i<group_count; i++){

  165.     total_num+=group_size[i];

  166.   }

  167. 

  168.   args_array=(blas_arg_t *)malloc(total_num * sizeof(blas_arg_t));

  169.   

  170.   if(args_array == NULL){

  171.     openblas_warning(0, "memory alloc failed!\n");

  172.     return;

  173.   }

  174. 

  175. #ifdef SMP

  176. #ifndef COMPLEX

  177. #ifdef XDOUBLE

  178.   mode  =  BLAS_XDOUBLE | BLAS_REAL;

  179. #elif defined(DOUBLE)

  180.   mode  =  BLAS_DOUBLE  | BLAS_REAL;

  181. #else

  182.   mode  =  BLAS_SINGLE  | BLAS_REAL;

  183. #endif

  184. #else

  185. #ifdef XDOUBLE

  186.   mode  =  BLAS_XDOUBLE | BLAS_COMPLEX;

  187. #elif defined(DOUBLE)

  188.   mode  =  BLAS_DOUBLE  | BLAS_COMPLEX;

  189. #else

  190.   mode  =  BLAS_SINGLE  | BLAS_COMPLEX;

  191. #endif

  192. #endif

  193. #endif

  194.   

  195.   for(i=0; i<group_count; matrix_idx+=group_size[i], i++){

  196.     group_alpha = (void *)&alpha_array[i * COMPSIZE];

  197.     group_beta = (void *)&beta_array[i * COMPSIZE];

  198. 

  199.     group_m = group_n = group_k = 0;

  200.     group_lda = group_ldb = group_ldc = 0;

  201.     group_transa = -1;

  202.     group_transb = -1;

  203.     info   = 0;

  204.     

  205.     if (order == CblasColMajor) {

  206.       group_m = m_array[i];

  207.       group_n = n_array[i];

  208.       group_k = k_array[i];

  209. 

  210.       group_lda = lda_array[i];

  211.       group_ldb = ldb_array[i];

  212.       group_ldc = ldc_array[i];

  213.       

  214.       if (transa_array[i] == CblasNoTrans)     group_transa = 0;

  215.       if (transa_array[i] == CblasTrans)       group_transa = 1;

  216. #ifndef COMPLEX

  217.       if (transa_array[i] == CblasConjNoTrans) group_transa = 0;

  218.       if (transa_array[i] == CblasConjTrans)   group_transa = 1;

  219. #else

  220.       if (transa_array[i] == CblasConjNoTrans) group_transa = 2;

  221.       if (transa_array[i] == CblasConjTrans)   group_transa = 3;

  222. #endif

  223.       if (transb_array[i] == CblasNoTrans)     group_transb = 0;

  224.       if (transb_array[i] == CblasTrans)       group_transb = 1;

  225. #ifndef COMPLEX

  226.       if (transb_array[i] == CblasConjNoTrans) group_transb = 0;

  227.       if (transb_array[i] == CblasConjTrans)   group_transb = 1;

  228. #else

  229.       if (transb_array[i] == CblasConjNoTrans) group_transb = 2;

  230.       if (transb_array[i] == CblasConjTrans)   group_transb = 3;

  231. #endif

  232.       group_nrowa = group_m;

  233.       if (group_transa & 1) group_nrowa = group_k;

  234.       group_nrowb = group_k;

  235.       if (group_transb & 1) group_nrowb = group_n;

  236. 

  237.       info=-1;

  238. 	

  239.       if (group_ldc < group_m) info = 13;

  240.       if (group_ldb < group_nrowb)  info = 10;

  241.       if (group_lda < group_nrowa)  info =  8;

  242.       if (group_k < 0)        info =  5;

  243.       if (group_n < 0)        info =  4;

  244.       if (group_m < 0)        info =  3;

  245.       if (group_transb < 0)        info =  2;

  246.       if (group_transa < 0)        info =  1;

  247. 

  248.     }else if (order == CblasRowMajor) {

  249.       

  250.       group_m = n_array[i];

  251.       group_n = m_array[i];

  252.       group_k = k_array[i];

  253. 

  254.       group_lda = ldb_array[i];

  255.       group_ldb = lda_array[i];

  256.       group_ldc = ldc_array[i];

  257.       

  258.       if (transb_array[i] == CblasNoTrans)     group_transa = 0;

  259.       if (transb_array[i] == CblasTrans)       group_transa = 1;

  260. #ifndef COMPLEX

  261.       if (transb_array[i] == CblasConjNoTrans) group_transa = 0;

  262.       if (transb_array[i] == CblasConjTrans)   group_transa = 1;

  263. #else

  264.       if (transb_array[i] == CblasConjNoTrans) group_transa = 2;

  265.       if (transb_array[i] == CblasConjTrans)   group_transa = 3;

  266. #endif

  267.       if (transa_array[i] == CblasNoTrans)     group_transb = 0;

  268.       if (transa_array[i] == CblasTrans)       group_transb = 1;

  269. #ifndef COMPLEX

  270.       if (transa_array[i] == CblasConjNoTrans) group_transb = 0;

  271.       if (transa_array[i] == CblasConjTrans)   group_transb = 1;

  272. #else

  273.       if (transa_array[i] == CblasConjNoTrans) group_transb = 2;

  274.       if (transa_array[i] == CblasConjTrans)   group_transb = 3;

  275. #endif

  276.       group_nrowa = group_m;

  277.       if (group_transa & 1) group_nrowa = group_k;

  278.       group_nrowb = group_k;

  279.       if (group_transb & 1) group_nrowb = group_n;

  280. 

  281.       info=-1;

  282. 	

  283.       if (group_ldc < group_m) info = 13;

  284.       if (group_ldb < group_nrowb)  info = 10;

  285.       if (group_lda < group_nrowa)  info =  8;

  286.       if (group_k < 0)        info =  5;

  287.       if (group_n < 0)        info =  4;

  288.       if (group_m < 0)        info =  3;

  289.       if (group_transb < 0)        info =  2;

  290.       if (group_transa < 0)        info =  1;      

  291.     }

  292. 

  293.     if (info >= 0) {

  294.       BLASFUNC(xerbla)(ERROR_NAME, &info, sizeof(ERROR_NAME));

  295.       free(args_array);

  296.       return;

  297.     }

  298. 

  299.     if (group_m == 0 || group_n == 0) continue;

  300. 

  301.     group_mode=mode;

  302. 

  303. #if defined(SMP) || defined(SMALL_MATRIX_OPT)

  304.     MNK = (double) group_m * (double) group_n * (double) group_k;

  305. #endif

  306. 

  307. #ifdef SMALL_MATRIX_OPT

  308.     if (MNK <= 100.0*100.0*100.0){

  309.       group_routine=NULL;

  310. #if !defined(COMPLEX)

  311.       if(*(FLOAT *)(group_beta) == 0.0){

  312. 	group_mode=mode | BLAS_SMALL_B0_OPT;

  313. 	group_small_matrix_opt_routine=(void *)(gemm_small_kernel_b0[(group_transb<<2)|group_transa]);

  314.       }else{

  315. 	group_mode=mode | BLAS_SMALL_OPT;

  316. 	group_small_matrix_opt_routine=(void *)(gemm_small_kernel[(group_transb<<2)|group_transa]);

  317.       }

  318. #else

  319.       if(((FLOAT *)(group_beta))[0] == 0.0 && ((FLOAT *)(group_beta))[1] == 0.0){

  320. 	group_mode=mode | BLAS_SMALL_B0_OPT;

  321. 	group_small_matrix_opt_routine=(void *)(zgemm_small_kernel_b0[(group_transb<<2)|group_transa]);

  322.       }else{

  323. 	group_mode=mode | BLAS_SMALL_OPT;

  324. 	group_small_matrix_opt_routine=(void *)(zgemm_small_kernel[(group_transb<<2)|group_transa]);

  325.       }

  326. 

  327. #endif

  328.       

  329.     }else{

  330. #endif

  331.       group_routine=(void*)(gemm[(group_transb<<2)|group_transa]);

  332. #ifdef SMALL_MATRIX_OPT

  333.     }

  334. #endif    

  335. 

  336.     

  337.     for(j=0; j<group_size[i]; j++){

  338.       args_array[count].m=group_m;

  339.       args_array[count].n=group_n;

  340.       args_array[count].k=group_k;

  341.       args_array[count].lda=group_lda;

  342.       args_array[count].ldb=group_ldb;

  343.       args_array[count].ldc=group_ldc;

  344.       args_array[count].alpha=group_alpha;

  345.       args_array[count].beta=group_beta;

  346. 

  347.       if (order == CblasColMajor) {      

  348. 	args_array[count].a=(a_array[matrix_idx+j]);

  349. 	args_array[count].b=(b_array[matrix_idx+j]);

  350.       }else if(order == CblasRowMajor){

  351. 	args_array[count].a=(b_array[matrix_idx+j]);

  352. 	args_array[count].b=(a_array[matrix_idx+j]);

  353.       }

  354.       

  355.       args_array[count].c=(c_array[matrix_idx+j]);

  356.       

  357.       args_array[count].routine_mode=group_mode;

  358.       args_array[count].routine=group_routine;

  359. #ifdef SMALL_MATRIX_OPT

  360.       if (!group_routine)

  361.         args_array[count].routine=group_small_matrix_opt_routine;

  362. #endif      

  363.       count++;

  364.     }

  365.   }

  366. 

  367.   if(count>0){

  368.     GEMM_BATCH_THREAD(args_array,count);

  369.   }

  370. 

  371.   free(args_array);

  372. }