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OpenBLAS/driver/level3/gemm3m_level3.c

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

  2. /* Copyright 2009, 2010 The University of Texas at Austin.           */

  3. /* All rights reserved.                                              */

  4. /*                                                                   */

  5. /* Redistribution and use in source and binary forms, with or        */

  6. /* without modification, are permitted provided that the following   */

  7. /* conditions are met:                                               */

  8. /*                                                                   */

  9. /*   1. Redistributions of source code must retain the above         */

  10. /*      copyright notice, this list of conditions and the following  */

  11. /*      disclaimer.                                                  */

  12. /*                                                                   */

  13. /*   2. Redistributions in binary form must reproduce the above      */

  14. /*      copyright notice, this list of conditions and the following  */

  15. /*      disclaimer in the documentation and/or other materials       */

  16. /*      provided with the distribution.                              */

  17. /*                                                                   */

  18. /*    THIS  SOFTWARE IS PROVIDED  BY THE  UNIVERSITY OF  TEXAS AT    */

  19. /*    AUSTIN  ``AS IS''  AND ANY  EXPRESS OR  IMPLIED WARRANTIES,    */

  20. /*    INCLUDING, BUT  NOT LIMITED  TO, THE IMPLIED  WARRANTIES OF    */

  21. /*    MERCHANTABILITY  AND FITNESS FOR  A PARTICULAR  PURPOSE ARE    */

  22. /*    DISCLAIMED.  IN  NO EVENT SHALL THE UNIVERSITY  OF TEXAS AT    */

  23. /*    AUSTIN OR CONTRIBUTORS BE  LIABLE FOR ANY DIRECT, INDIRECT,    */

  24. /*    INCIDENTAL,  SPECIAL, EXEMPLARY,  OR  CONSEQUENTIAL DAMAGES    */

  25. /*    (INCLUDING, BUT  NOT LIMITED TO,  PROCUREMENT OF SUBSTITUTE    */

  26. /*    GOODS  OR  SERVICES; LOSS  OF  USE,  DATA,  OR PROFITS;  OR    */

  27. /*    BUSINESS INTERRUPTION) HOWEVER CAUSED  AND ON ANY THEORY OF    */

  28. /*    LIABILITY, WHETHER  IN CONTRACT, STRICT  LIABILITY, OR TORT    */

  29. /*    (INCLUDING NEGLIGENCE OR OTHERWISE)  ARISING IN ANY WAY OUT    */

  30. /*    OF  THE  USE OF  THIS  SOFTWARE,  EVEN  IF ADVISED  OF  THE    */

  31. /*    POSSIBILITY OF SUCH DAMAGE.                                    */

  32. /*                                                                   */

  33. /* The views and conclusions contained in the software and           */

  34. /* documentation are those of the authors and should not be          */

  35. /* interpreted as representing official policies, either expressed   */

  36. /* or implied, of The University of Texas at Austin.                 */

  37. /*********************************************************************/

  38. 

  39. #include <stdio.h>

  40. #include "common.h"

  41. 

  42. #ifndef BETA_OPERATION

  43. #define BETA_OPERATION(M_FROM, M_TO, N_FROM, N_TO, BETA, C, LDC) \

  44. 	GEMM_BETA((M_TO) - (M_FROM), (N_TO - N_FROM), 0, \

  45. 		  BETA[0], BETA[1], NULL, 0, NULL, 0, \

  46. 		  (FLOAT *)(C) + (M_FROM) + (N_FROM) * (LDC) * COMPSIZE, LDC)

  47. #endif

  48. 

  49. #ifndef ICOPYB_OPERATION

  50. #if defined(NN) || defined(NT) || defined(NC) || defined(NR) || \

  51.     defined(RN) || defined(RT) || defined(RC) || defined(RR)

  52. #define ICOPYB_OPERATION(M, N, A, LDA, X, Y, BUFFER) \

  53. 	GEMM3M_ITCOPYB(M, N, (FLOAT *)(A) + ((Y) + (X) * (LDA)) * COMPSIZE, LDA, BUFFER)

  54. #else

  55. #define ICOPYB_OPERATION(M, N, A, LDA, X, Y, BUFFER) \

  56. 	GEMM3M_INCOPYB(M, N, (FLOAT *)(A) + ((X) + (Y) * (LDA)) * COMPSIZE, LDA, BUFFER)

  57. #endif

  58. #endif

  59. 

  60. #ifndef ICOPYR_OPERATION

  61. #if defined(NN) || defined(NT) || defined(NC) || defined(NR) || \

  62.     defined(RN) || defined(RT) || defined(RC) || defined(RR)

  63. #define ICOPYR_OPERATION(M, N, A, LDA, X, Y, BUFFER) \

  64. 	GEMM3M_ITCOPYR(M, N, (FLOAT *)(A) + ((Y) + (X) * (LDA)) * COMPSIZE, LDA, BUFFER)

  65. #else

  66. #define ICOPYR_OPERATION(M, N, A, LDA, X, Y, BUFFER) \

  67. 	GEMM3M_INCOPYR(M, N, (FLOAT *)(A) + ((X) + (Y) * (LDA)) * COMPSIZE, LDA, BUFFER)

  68. #endif

  69. #endif

  70. 

  71. #ifndef ICOPYI_OPERATION

  72. #if defined(NN) || defined(NT) || defined(NC) || defined(NR) || \

  73.     defined(RN) || defined(RT) || defined(RC) || defined(RR)

  74. #define ICOPYI_OPERATION(M, N, A, LDA, X, Y, BUFFER) \

  75. 	GEMM3M_ITCOPYI(M, N, (FLOAT *)(A) + ((Y) + (X) * (LDA)) * COMPSIZE, LDA, BUFFER)

  76. #else

  77. #define ICOPYI_OPERATION(M, N, A, LDA, X, Y, BUFFER) \

  78. 	GEMM3M_INCOPYI(M, N, (FLOAT *)(A) + ((X) + (Y) * (LDA)) * COMPSIZE, LDA, BUFFER)

  79. #endif

  80. #endif

  81. 

  82. 

  83. #ifndef OCOPYB_OPERATION

  84. #if defined(NN) || defined(TN) || defined(CN) || defined(RN) || \

  85.     defined(NR) || defined(TR) || defined(CR) || defined(RR)

  86. #define OCOPYB_OPERATION(M, N, A, LDA, ALPHA_R, ALPHA_I, X, Y, BUFFER) \

  87. 	GEMM3M_ONCOPYB(M, N, (FLOAT *)(A) + ((X) + (Y) * (LDA)) * COMPSIZE, LDA, ALPHA_R, ALPHA_I, BUFFER)

  88. #else

  89. #define OCOPYB_OPERATION(M, N, A, LDA, ALPHA_R, ALPHA_I, X, Y, BUFFER) \

  90. 	GEMM3M_OTCOPYB(M, N, (FLOAT *)(A) + ((Y) + (X) * (LDA)) * COMPSIZE, LDA, ALPHA_R, ALPHA_I, BUFFER)

  91. #endif

  92. #endif

  93. 

  94. #ifndef OCOPYR_OPERATION

  95. #if defined(NN) || defined(TN) || defined(CN) || defined(RN) || \

  96.     defined(NR) || defined(TR) || defined(CR) || defined(RR)

  97. #define OCOPYR_OPERATION(M, N, A, LDA, ALPHA_R, ALPHA_I, X, Y, BUFFER) \

  98. 	GEMM3M_ONCOPYR(M, N, (FLOAT *)(A) + ((X) + (Y) * (LDA)) * COMPSIZE, LDA, ALPHA_R, ALPHA_I, BUFFER)

  99. #else

  100. #define OCOPYR_OPERATION(M, N, A, LDA, ALPHA_R, ALPHA_I, X, Y, BUFFER) \

  101. 	GEMM3M_OTCOPYR(M, N, (FLOAT *)(A) + ((Y) + (X) * (LDA)) * COMPSIZE, LDA, ALPHA_R, ALPHA_I, BUFFER)

  102. #endif

  103. #endif

  104. 

  105. 

  106. #ifndef OCOPYI_OPERATION

  107. #if defined(NN) || defined(TN) || defined(CN) || defined(RN) || \

  108.     defined(NR) || defined(TR) || defined(CR) || defined(RR)

  109. #define OCOPYI_OPERATION(M, N, A, LDA, ALPHA_R, ALPHA_I, X, Y, BUFFER) \

  110. 	GEMM3M_ONCOPYI(M, N, (FLOAT *)(A) + ((X) + (Y) * (LDA)) * COMPSIZE, LDA, ALPHA_R, ALPHA_I, BUFFER)

  111. #else

  112. #define OCOPYI_OPERATION(M, N, A, LDA, ALPHA_R, ALPHA_I, X, Y, BUFFER) \

  113. 	GEMM3M_OTCOPYI(M, N, (FLOAT *)(A) + ((Y) + (X) * (LDA)) * COMPSIZE, LDA, ALPHA_R, ALPHA_I, BUFFER)

  114. #endif

  115. #endif

  116. 

  117. #ifndef KERNEL_FUNC

  118. #define KERNEL_FUNC	GEMM3M_KERNEL

  119. #endif

  120. 

  121. #ifndef KERNEL_OPERATION

  122. #define KERNEL_OPERATION(M, N, K, ALPHA_R, ALPHA_I, SA, SB, C, LDC, X, Y) \

  123. 	KERNEL_FUNC(M, N, K, ALPHA_R, ALPHA_I, SA, SB, (FLOAT *)(C) + ((X) + (Y) * LDC) * COMPSIZE, LDC)

  124. #endif

  125. 

  126. #ifndef A

  127. #define A	args -> a

  128. #endif

  129. #ifndef LDA

  130. #define LDA	args -> lda

  131. #endif

  132. #ifndef B

  133. #define B	args -> b

  134. #endif

  135. #ifndef LDB

  136. #define LDB	args -> ldb

  137. #endif

  138. #ifndef C

  139. #define C	args -> c

  140. #endif

  141. #ifndef LDC

  142. #define LDC	args -> ldc

  143. #endif

  144. #ifndef M

  145. #define M	args -> m

  146. #endif

  147. #ifndef N

  148. #define N	args -> n

  149. #endif

  150. #ifndef K

  151. #define K	args -> k

  152. #endif

  153. 

  154. #if defined(NN) || defined(NT) || defined(TN) || defined(TT)

  155. #define ALPHA1	ONE

  156. #define ALPHA2	ONE

  157. #define ALPHA5	ZERO

  158. #define ALPHA6	ONE

  159. 

  160. #define ALPHA7	ONE

  161. #define ALPHA8	ZERO

  162. #define ALPHA11	ONE

  163. #define ALPHA12	-ONE

  164. 

  165. #define ALPHA13	ZERO

  166. #define ALPHA14	ONE

  167. #define ALPHA17	-ONE

  168. #define ALPHA18	-ONE

  169. #endif

  170. 

  171. #if defined(NR) || defined(NC) || defined(TR) || defined(TC)

  172. #define ALPHA1	ONE

  173. #define ALPHA2	ONE

  174. #define ALPHA5	ONE

  175. #define ALPHA6	ZERO

  176. 

  177. #define ALPHA7	ZERO

  178. #define ALPHA8	ONE

  179. #define ALPHA11	-ONE

  180. #define ALPHA12	-ONE

  181. 

  182. #define ALPHA13	ONE

  183. #define ALPHA14	ZERO

  184. #define ALPHA17	-ONE

  185. #define ALPHA18	ONE

  186. #endif

  187. 

  188. #if defined(RN) || defined(RT) || defined(CN) || defined(CT)

  189. #define ALPHA1	ONE

  190. #define ALPHA2	ONE

  191. #define ALPHA5	ONE

  192. #define ALPHA6	ZERO

  193. 

  194. #define ALPHA7	ZERO

  195. #define ALPHA8	ONE

  196. #define ALPHA11	-ONE

  197. #define ALPHA12	ONE

  198. 

  199. #define ALPHA13	ONE

  200. #define ALPHA14	ZERO

  201. #define ALPHA17	-ONE

  202. #define ALPHA18	-ONE

  203. #endif

  204. 

  205. #if defined(RR) || defined(RC) || defined(CR) || defined(CC)

  206. #define ALPHA1	ONE

  207. #define ALPHA2	ONE

  208. #define ALPHA5	ZERO

  209. #define ALPHA6	-ONE

  210. 

  211. #define ALPHA7	ONE

  212. #define ALPHA8	ZERO

  213. #define ALPHA11	ONE

  214. #define ALPHA12	ONE

  215. 

  216. #define ALPHA13	ZERO

  217. #define ALPHA14	ONE

  218. #define ALPHA17	-ONE

  219. #define ALPHA18	ONE

  220. #endif

  221. 

  222. #ifdef TIMING

  223. #define START_RPCC()		rpcc_counter = rpcc()

  224. #define STOP_RPCC(COUNTER)	COUNTER  += rpcc() - rpcc_counter

  225. #else

  226. #define START_RPCC()

  227. #define STOP_RPCC(COUNTER)

  228. #endif

  229. 

  230. int CNAME(blas_arg_t *args, BLASLONG *range_m, BLASLONG *range_n,

  231. 		  FLOAT *sa, FLOAT *sb, BLASLONG dummy){

  232.   BLASLONG k, lda, ldb, ldc;

  233.   FLOAT *alpha, *beta;

  234.   FLOAT *a, *b, *c;

  235.   BLASLONG m_from, m_to, n_from, n_to;

  236. 

  237.   BLASLONG ls, is, js, jjs;

  238.   BLASLONG min_l, min_i, min_j, min_jj;

  239. 

  240. #ifdef TIMING

  241.   BLASULONG rpcc_counter;

  242.   BLASULONG BLASLONG innercost  = 0;

  243.   BLASULONG BLASLONG outercost  = 0;

  244.   BLASULONG BLASLONG kernelcost = 0;

  245.   double total;

  246. #endif

  247. 

  248.   k = K;

  249. 

  250.   a = (FLOAT *)A;

  251.   b = (FLOAT *)B;

  252.   c = (FLOAT *)C;

  253. 

  254.   lda = LDA;

  255.   ldb = LDB;

  256.   ldc = LDC;

  257. 

  258.   alpha = (FLOAT *)args -> alpha;

  259.   beta  = (FLOAT *)args -> beta;

  260. 

  261.   m_from = 0;

  262.   m_to   = M;

  263. 

  264.   if (range_m) {

  265.     m_from = *(((BLASLONG *)range_m) + 0);

  266.     m_to   = *(((BLASLONG *)range_m) + 1);

  267.   }

  268. 

  269.   n_from = 0;

  270.   n_to   = N;

  271. 

  272.   if (range_n) {

  273.     n_from = *(((BLASLONG *)range_n) + 0);

  274.     n_to   = *(((BLASLONG *)range_n) + 1);

  275.   }

  276. 

  277.   if (beta) {

  278. #ifndef COMPLEX

  279.     if (beta[0] != ONE)

  280. #else

  281.     if ((beta[0] != ONE) || (beta[1] != ZERO))

  282. #endif

  283.       BETA_OPERATION(m_from, m_to, n_from, n_to, beta, c, ldc);

  284.   }

  285. 

  286.   if ((k == 0) || (alpha == NULL)) return 0;

  287. 

  288.   if ((alpha[0] == ZERO)

  289. #ifdef COMPLEX

  290.       && (alpha[1] == ZERO)

  291. #endif

  292.       ) return 0;

  293. 

  294. #if 0

  295.   printf("GEMM: M_from : %ld  M_to : %ld  N_from : %ld  N_to : %ld  k : %ld\n", m_from, m_to, n_from, n_to, k);

  296.   printf("GEMM: P = %4ld  Q = %4ld  R = %4ld\n", (BLASLONG)GEMM3M_P, (BLASLONG)GEMM3M_Q, (BLASLONG)GEMM3M_R);

  297.   printf("GEMM: SA .. %p  SB .. %p\n", sa, sb);

  298. #endif

  299. 

  300. #ifdef TIMING

  301.   innercost = 0;

  302.   outercost = 0;

  303.   kernelcost = 0;

  304. #endif

  305. 

  306.   for(js = n_from; js < n_to; js += GEMM3M_R){

  307.     min_j = n_to - js;

  308.     if (min_j > GEMM3M_R) min_j = GEMM3M_R;

  309. 

  310.     for(ls = 0; ls < k; ls += min_l){

  311.       min_l = k - ls;

  312. 

  313.       if (min_l >= GEMM3M_Q * 2) {

  314. 	min_l = GEMM3M_Q;

  315.       } else {

  316. 	if (min_l > GEMM3M_Q) {

  317. 	  min_l = (min_l + 1) / 2;

  318. #ifdef UNROLL_X

  319. 	  min_l = ((min_l + UNROLL_X - 1)/UNROLL_X) * UNROLL_X;

  320. #endif

  321. 	}

  322.       }

  323. 

  324.       min_i = m_to - m_from;

  325.       if (min_i >= GEMM3M_P * 2) {

  326. 	min_i = GEMM3M_P;

  327.       } else {

  328. 	if (min_i > GEMM3M_P) {

  329. 	  min_i = ((min_i / 2 + GEMM3M_UNROLL_M - 1)/GEMM3M_UNROLL_M) * GEMM3M_UNROLL_M;

  330. 	}

  331.       }

  332. 

  333.       START_RPCC();

  334. 

  335.       ICOPYB_OPERATION(min_l, min_i, a, lda, ls, m_from, sa);

  336. 

  337.       STOP_RPCC(innercost);

  338. 

  339.       for(jjs = js; jjs < js + min_j; jjs += min_jj){

  340. 	min_jj = min_j + js - jjs;

  341. 	if (min_jj > GEMM3M_UNROLL_N*3) min_jj = GEMM3M_UNROLL_N*3;

  342. 

  343. 	START_RPCC();

  344. 

  345. #if defined(NN) || defined(NT) || defined(TN) || defined(TT) || defined(RN) || defined(RT) || defined(CN) || defined(CT)

  346. 	OCOPYB_OPERATION(min_l, min_jj, b, ldb, alpha[0],  alpha[1], ls, jjs, sb + min_l * (jjs - js));

  347. #else

  348. 	OCOPYB_OPERATION(min_l, min_jj, b, ldb, alpha[0], -alpha[1], ls, jjs, sb + min_l * (jjs - js));

  349. #endif

  350. 

  351. 	STOP_RPCC(outercost);

  352. 

  353. 	START_RPCC();

  354. 

  355. 	KERNEL_OPERATION(min_i, min_jj, min_l, ALPHA5, ALPHA6,

  356. 			 sa, sb + min_l * (jjs - js), c, ldc, m_from, jjs);

  357. 

  358. 	STOP_RPCC(kernelcost);

  359. 

  360.       }

  361. 

  362.       for(is = m_from + min_i; is < m_to; is += min_i){

  363. 	min_i = m_to - is;

  364. 	if (min_i >= GEMM3M_P * 2) {

  365. 	  min_i = GEMM3M_P;

  366. 	} else

  367. 	  if (min_i > GEMM3M_P) {

  368. 	    min_i = ((min_i / 2 + GEMM3M_UNROLL_M - 1)/GEMM3M_UNROLL_M) * GEMM3M_UNROLL_M;

  369. 	  }

  370. 

  371. 	START_RPCC();

  372. 

  373. 	ICOPYB_OPERATION(min_l, min_i, a, lda, ls, is, sa);

  374. 

  375. 	STOP_RPCC(innercost);

  376. 

  377. 	START_RPCC();

  378. 

  379. 	KERNEL_OPERATION(min_i, min_j, min_l, ALPHA5, ALPHA6, sa, sb, c, ldc, is, js);

  380. 

  381. 	STOP_RPCC(kernelcost);

  382.       }

  383. 

  384.       min_i = m_to - m_from;

  385.       if (min_i >= GEMM3M_P * 2) {

  386. 	min_i = GEMM3M_P;

  387.       } else {

  388. 	if (min_i > GEMM3M_P) {

  389. 	  min_i = ((min_i / 2 + GEMM3M_UNROLL_M - 1)/GEMM3M_UNROLL_M) * GEMM3M_UNROLL_M;

  390. 	}

  391.       }

  392. 

  393.       START_RPCC();

  394. 

  395.       ICOPYR_OPERATION(min_l, min_i, a, lda, ls, m_from, sa);

  396. 

  397.       STOP_RPCC(innercost);

  398. 

  399.       for(jjs = js; jjs < js + min_j; jjs += min_jj){

  400. 	min_jj = min_j + js - jjs;

  401. 	if (min_jj > GEMM3M_UNROLL_N*3) min_jj = GEMM3M_UNROLL_N*3;

  402. 

  403. 	START_RPCC();

  404. 

  405. #if   defined(NN) || defined(NT) || defined(TN) || defined(TT)

  406. 	OCOPYR_OPERATION(min_l, min_jj, b, ldb, alpha[0],  alpha[1], ls, jjs, sb + min_l * (jjs - js));

  407. #elif defined(RR) || defined(RC) || defined(CR) || defined(CC)

  408. 	OCOPYR_OPERATION(min_l, min_jj, b, ldb, alpha[0], -alpha[1], ls, jjs, sb + min_l * (jjs - js));

  409. #elif defined(RN) || defined(RT) || defined(CN) || defined(CT)

  410. 	OCOPYI_OPERATION(min_l, min_jj, b, ldb, alpha[0],  alpha[1], ls, jjs, sb + min_l * (jjs - js));

  411. #else

  412. 	OCOPYI_OPERATION(min_l, min_jj, b, ldb, alpha[0], -alpha[1], ls, jjs, sb + min_l * (jjs - js));

  413. #endif

  414. 

  415. 	STOP_RPCC(outercost);

  416. 

  417. 	START_RPCC();

  418. 

  419. 	KERNEL_OPERATION(min_i, min_jj, min_l, ALPHA11, ALPHA12,

  420. 			 sa, sb + min_l * (jjs - js), c, ldc, m_from, jjs);

  421. 

  422. 	STOP_RPCC(kernelcost);

  423. 

  424.       }

  425. 

  426.       for(is = m_from + min_i; is < m_to; is += min_i){

  427. 	min_i = m_to - is;

  428. 	if (min_i >= GEMM3M_P * 2) {

  429. 	  min_i = GEMM3M_P;

  430. 	} else

  431. 	  if (min_i > GEMM3M_P) {

  432. 	    min_i = ((min_i / 2 + GEMM3M_UNROLL_M - 1)/GEMM3M_UNROLL_M) * GEMM3M_UNROLL_M;

  433. 	  }

  434. 

  435. 	START_RPCC();

  436. 

  437. 	ICOPYR_OPERATION(min_l, min_i, a, lda, ls, is, sa);

  438. 

  439. 	STOP_RPCC(innercost);

  440. 

  441. 	START_RPCC();

  442. 

  443. 	KERNEL_OPERATION(min_i, min_j, min_l, ALPHA11, ALPHA12, sa, sb, c, ldc, is, js);

  444. 

  445. 	STOP_RPCC(kernelcost);

  446. 

  447.       }

  448. 

  449.       min_i = m_to - m_from;

  450.       if (min_i >= GEMM3M_P * 2) {

  451. 	min_i = GEMM3M_P;

  452.       } else {

  453. 	if (min_i > GEMM3M_P) {

  454. 	  min_i = ((min_i / 2 + GEMM3M_UNROLL_M - 1)/GEMM3M_UNROLL_M) * GEMM3M_UNROLL_M;

  455. 	}

  456.       }

  457. 

  458.       START_RPCC();

  459. 

  460.       ICOPYI_OPERATION(min_l, min_i, a, lda, ls, m_from, sa);

  461. 

  462.       STOP_RPCC(innercost);

  463. 

  464.       for(jjs = js; jjs < js + min_j; jjs += min_jj){

  465. 	min_jj = min_j + js - jjs;

  466. 	if (min_jj > GEMM3M_UNROLL_N*3) min_jj = GEMM3M_UNROLL_N*3;

  467. 

  468. 	START_RPCC();

  469. 

  470. #if   defined(NN) || defined(NT) || defined(TN) || defined(TT)

  471. 	OCOPYI_OPERATION(min_l, min_jj, b, ldb, alpha[0],  alpha[1], ls, jjs, sb + min_l * (jjs - js));

  472. #elif defined(RR) || defined(RC) || defined(CR) || defined(CC)

  473. 	OCOPYI_OPERATION(min_l, min_jj, b, ldb, alpha[0], -alpha[1], ls, jjs, sb + min_l * (jjs - js));

  474. #elif defined(RN) || defined(RT) || defined(CN) || defined(CT)

  475. 	OCOPYR_OPERATION(min_l, min_jj, b, ldb, alpha[0],  alpha[1], ls, jjs, sb + min_l * (jjs - js));

  476. #else

  477. 	OCOPYR_OPERATION(min_l, min_jj, b, ldb, alpha[0], -alpha[1], ls, jjs, sb + min_l * (jjs - js));

  478. #endif

  479. 

  480. 	STOP_RPCC(outercost);

  481. 

  482. 	START_RPCC();

  483. 

  484. 	KERNEL_OPERATION(min_i, min_jj, min_l, ALPHA17, ALPHA18,

  485. 			 sa, sb + min_l * (jjs - js), c, ldc, m_from, jjs);

  486. 

  487. 	STOP_RPCC(kernelcost);

  488. 

  489.       }

  490. 

  491.       for(is = m_from + min_i; is < m_to; is += min_i){

  492. 	min_i = m_to - is;

  493. 	if (min_i >= GEMM3M_P * 2) {

  494. 	  min_i = GEMM3M_P;

  495. 	} else

  496. 	  if (min_i > GEMM3M_P) {

  497. 	    min_i = ((min_i / 2 + GEMM3M_UNROLL_M - 1)/GEMM3M_UNROLL_M) * GEMM3M_UNROLL_M;

  498. 	  }

  499. 

  500. 	START_RPCC();

  501. 

  502. 	ICOPYI_OPERATION(min_l, min_i, a, lda, ls, is, sa);

  503. 

  504. 	STOP_RPCC(innercost);

  505. 

  506. 	START_RPCC();

  507. 

  508. 	KERNEL_OPERATION(min_i, min_j, min_l, ALPHA17, ALPHA18, sa, sb, c, ldc, is, js);

  509. 

  510. 	STOP_RPCC(kernelcost);

  511. 

  512.       }

  513. 

  514.     } /* end of js */

  515.   } /* end of ls */

  516. 

  517. 

  518. #ifdef TIMING

  519.   total = (double)outercost + (double)innercost + (double)kernelcost;

  520. 

  521.   printf( "Copy A : %5.2f Copy  B: %5.2f  Kernel : %5.2f\n",

  522. 	   innercost / total * 100., outercost / total * 100.,

  523. 	  kernelcost / total * 100.);

  524. 

  525.   printf( " Total %10.3f%%  %10.3f MFlops\n",

  526. 	  ((double)(m_to - m_from) * (double)(n_to - n_from) * (double)k) / (double)kernelcost / 2 * 100,

  527. 	  2400. * (2. * (double)(m_to - m_from) * (double)(n_to - n_from) * (double)k) / (double)kernelcost);

  528. #endif

  529. 

  530.   return 0;

  531. }