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OpenBLAS/kernel/arm64/sbgemm_kernel_8x4_neoversen...

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

  2.  * Copyright (c) 2022, The OpenBLAS Project

  3.  * All rights reserved.

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

  5.  * modification, are permitted provided that the following conditions are

  6.  * met:

  7.  * 1. Redistributions of source code must retain the above copyright

  8.  * notice, this list of conditions and the following disclaimer.

  9.  * 2. Redistributions in binary form must reproduce the above copyright

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

  11.  * the documentation and/or other materials provided with the

  12.  * distribution.

  13.  * 3. Neither the name of the OpenBLAS project nor the names of

  14.  * its contributors may be used to endorse or promote products

  15.  * derived from this software without specific prior written permission.

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

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

  18.  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE

  19.  * ARE DISCLAIMED. IN NO EVENT SHALL THE OPENBLAS PROJECT OR CONTRIBUTORS BE

  20.  * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR

  21.  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF

  22.  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS

  23.  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN

  24.  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)

  25.  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE

  26.  * POSSIBILITY OF SUCH DAMAGE.

  27.  * *****************************************************************************/

  28. 

  29. #include <arm_sve.h>

  30. 

  31. #include "common.h"

  32. 

  33. #define INIT_C(M, N) mc##M##N = svdup_f32(0);

  34. 

  35. #define MATMUL(M, N) mc##M##N = svbfmmla(mc##M##N, ma##M, mb##N);

  36. 

  37. #define INIT_C_8x4 \

  38.   do {             \

  39.     INIT_C(0, 0);  \

  40.     INIT_C(0, 1);  \

  41.     INIT_C(1, 0);  \

  42.     INIT_C(1, 1);  \

  43.     INIT_C(2, 0);  \

  44.     INIT_C(2, 1);  \

  45.     INIT_C(3, 0);  \

  46.     INIT_C(3, 1);  \

  47.   } while (0);

  48. 

  49. #ifdef ALPHA_ONE

  50. #define UPDATE_C(PG, PTR, DST, SRC) \

  51.   do {                              \

  52.     DST = svld1_f32((PG), (PTR));   \

  53.     DST = svadd_z((PG), SRC, DST);  \

  54.     svst1_f32((PG), (PTR), DST);    \

  55.   } while (0);

  56. #else

  57. #define UPDATE_C(PG, PTR, DST, SRC)         \

  58.   do {                                      \

  59.     DST = svld1_f32((PG), (PTR));           \

  60.     DST = svmad_z((PG), svalpha, SRC, DST); \

  61.     svst1_f32((PG), (PTR), DST);            \

  62.   } while (0);

  63. #endif

  64. 

  65. #ifdef ALPHA_ONE

  66. int sbgemm_kernel_neoversen2_alpha_one(BLASLONG m, BLASLONG n, BLASLONG k, FLOAT alpha, IFLOAT * A, IFLOAT * B, FLOAT * C, BLASLONG ldc)

  67. #else

  68. int sbgemm_kernel_neoversen2_alpha(BLASLONG m, BLASLONG n, BLASLONG k, FLOAT alpha, IFLOAT * A, IFLOAT * B, FLOAT * C, BLASLONG ldc)

  69. #endif

  70. {

  71.   BLASLONG pad_k = (k + 3) & ~3;

  72. 

  73.   svbfloat16_t ma0, ma1, ma2, ma3, mb0, mb1;

  74.   svfloat32_t mc00, mc01, mc10, mc11, mc20, mc21, mc30, mc31, 

  75.               vc0, vc1, vc2, vc3, vc4, vc5, vc6, vc7, 

  76.               oc0, oc1, oc2, oc3, oc4, oc5, oc6, oc7;

  77.   svfloat32_t svalpha = svdup_f32(alpha);

  78. 

  79.   svbool_t pg16 = svptrue_b16();

  80.   svbool_t pg16_low = svdupq_b16(1, 1, 1, 1, 0, 0, 0, 0);

  81.   svbool_t pg32 = svptrue_b32();

  82.   svbool_t pg32_low = svdupq_b32(1, 1, 0, 0);

  83.   svbool_t pg32_first = svdupq_b32(1, 0, 0, 0);

  84. 

  85.   bfloat16_t *ptr_a = (bfloat16_t *)A;

  86.   bfloat16_t *ptr_b = (bfloat16_t *)B;

  87.   FLOAT *ptr_c = C;

  88. 

  89.   bfloat16_t *ptr_a0, *ptr_a1, *ptr_a2, *ptr_a3;

  90.   bfloat16_t *ptr_b0, *ptr_b1;

  91.   FLOAT *ptr_c0, *ptr_c1, *ptr_c2, *ptr_c3;

  92. 

  93.   for (BLASLONG j = 0; j < n / 4; j++) {

  94.     ptr_c0 = ptr_c;

  95.     ptr_c1 = ptr_c0 + ldc;

  96.     ptr_c2 = ptr_c1 + ldc;

  97.     ptr_c3 = ptr_c2 + ldc;

  98.     ptr_c += 4 * ldc;

  99.     ptr_a = (bfloat16_t *)A;

  100. 

  101.     for (BLASLONG i = 0; i < m / 8; i++) {

  102.       ptr_a0 = ptr_a;

  103.       ptr_a += 8 * pad_k;

  104. 

  105.       ptr_b0 = ptr_b;

  106. 

  107.       INIT_C_8x4;

  108. 

  109.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  110.         ma0 = svld1_bf16(pg16, ptr_a0);

  111.         ma1 = svld1_bf16(pg16, ptr_a0 + 8);

  112.         ma2 = svld1_bf16(pg16, ptr_a0 + 16);

  113.         ma3 = svld1_bf16(pg16, ptr_a0 + 24);

  114. 

  115.         mb0 = svld1_bf16(pg16, ptr_b0);

  116.         mb1 = svld1_bf16(pg16, ptr_b0 + 8);

  117. 

  118.         MATMUL(0, 0); MATMUL(0, 1);

  119.         MATMUL(1, 0); MATMUL(1, 1);

  120.         MATMUL(2, 0); MATMUL(2, 1);

  121.         MATMUL(3, 0); MATMUL(3, 1);

  122. 

  123.         ptr_a0 += 32;

  124.         ptr_b0 += 16;

  125.       }

  126. 

  127.       vc0 = svuzp1(mc00, mc10);

  128.       vc1 = svuzp1(mc20, mc30);

  129.       vc2 = svuzp2(mc00, mc10);

  130.       vc3 = svuzp2(mc20, mc30);

  131.       vc4 = svuzp1(mc01, mc11);

  132.       vc5 = svuzp1(mc21, mc31);

  133.       vc6 = svuzp2(mc01, mc11);

  134.       vc7 = svuzp2(mc21, mc31);

  135. 

  136.       UPDATE_C(pg32, ptr_c0, oc0, vc0);

  137.       UPDATE_C(pg32, ptr_c0+4, oc1, vc1);

  138.       UPDATE_C(pg32, ptr_c1, oc2, vc2);

  139.       UPDATE_C(pg32, ptr_c1+4, oc3, vc3);

  140.       UPDATE_C(pg32, ptr_c2, oc4, vc4)

  141.       UPDATE_C(pg32, ptr_c2+4, oc5, vc5);

  142.       UPDATE_C(pg32, ptr_c3, oc6, vc6)

  143.       UPDATE_C(pg32, ptr_c3+4, oc7, vc7);

  144. 

  145.       ptr_c0 += 8;

  146.       ptr_c1 += 8;

  147.       ptr_c2 += 8;

  148.       ptr_c3 += 8;

  149.     }

  150. 

  151.     if (m & 4) {

  152.       ptr_a0 = ptr_a;

  153.       ptr_a += 4 * pad_k;

  154.       ptr_b0 = ptr_b;

  155. 

  156.       INIT_C(0, 0); INIT_C(0, 1);

  157.       INIT_C(1, 0); INIT_C(1, 1);

  158. 

  159.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  160.         ma0 = svld1_bf16(pg16, ptr_a0);

  161.         ma1 = svld1_bf16(pg16, ptr_a0 + 8);

  162.         mb0 = svld1_bf16(pg16, ptr_b0);

  163.         mb1 = svld1_bf16(pg16, ptr_b0 + 8);

  164. 

  165.         MATMUL(0, 0); MATMUL(0, 1);

  166.         MATMUL(1, 0); MATMUL(1, 1);

  167. 

  168.         ptr_a0 += 16;

  169.         ptr_b0 += 16;

  170.       }

  171. 

  172.       vc0 = svuzp1(mc00, mc10);

  173.       vc1 = svuzp2(mc00, mc10);

  174.       vc2 = svuzp1(mc01, mc11);

  175.       vc3 = svuzp2(mc01, mc11);

  176. 

  177.       UPDATE_C(pg32, ptr_c0, oc0, vc0);

  178.       UPDATE_C(pg32, ptr_c1, oc1, vc1);

  179.       UPDATE_C(pg32, ptr_c2, oc2, vc2);

  180.       UPDATE_C(pg32, ptr_c3, oc3, vc3);

  181. 

  182.       ptr_c0 += 4;

  183.       ptr_c1 += 4;

  184.       ptr_c2 += 4;

  185.       ptr_c3 += 4;

  186.     }

  187. 

  188.     if (m & 2) {

  189.       ptr_a0 = ptr_a;

  190.       ptr_a += 2 * pad_k;

  191.       ptr_b0 = ptr_b;

  192. 

  193.       INIT_C(0, 0); INIT_C(0, 1);

  194.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  195.         ma0 = svld1_bf16(pg16, ptr_a0);

  196.         mb0 = svld1_bf16(pg16, ptr_b0);

  197.         mb1 = svld1_bf16(pg16, ptr_b0 + 8);

  198. 

  199.         MATMUL(0, 0); MATMUL(0, 1);

  200. 

  201.         ptr_a0 += 8;

  202.         ptr_b0 += 16;

  203.       }

  204. 

  205.       vc0 = svuzp1(mc00, mc00);

  206.       vc1 = svuzp2(mc00, mc00);

  207.       vc2 = svuzp1(mc01, mc01);

  208.       vc3 = svuzp2(mc01, mc01);

  209. 

  210.       UPDATE_C(pg32_low, ptr_c0, oc0, vc0);

  211.       UPDATE_C(pg32_low, ptr_c1, oc1, vc1);

  212.       UPDATE_C(pg32_low, ptr_c2, oc2, vc2);

  213.       UPDATE_C(pg32_low, ptr_c3, oc3, vc3);

  214. 

  215.       ptr_c0 += 2;

  216.       ptr_c1 += 2;

  217.       ptr_c2 += 2;

  218.       ptr_c3 += 2;

  219.     }

  220. 

  221.     if (m & 1) {

  222.       ptr_a0 = ptr_a;

  223.       ptr_b0 = ptr_b;

  224. 

  225.       INIT_C(0, 0); INIT_C(0, 1);

  226.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  227.         ma0 = svld1_bf16(pg16_low, ptr_a0);

  228.         mb0 = svld1_bf16(pg16, ptr_b0);

  229.         mb1 = svld1_bf16(pg16, ptr_b0 + 8);

  230. 

  231.         MATMUL(0, 0); MATMUL(0, 1);

  232. 

  233.         ptr_a0 += 4;

  234.         ptr_b0 += 16;

  235.       }

  236. 

  237.       vc1 = svuzp2(mc00, mc00);

  238.       vc3 = svuzp2(mc01, mc01);

  239. 

  240.       UPDATE_C(pg32_first, ptr_c0, oc0, mc00);

  241.       UPDATE_C(pg32_first, ptr_c1, oc1, vc1);

  242.       UPDATE_C(pg32_first, ptr_c2, oc2, mc01);

  243.       UPDATE_C(pg32_first, ptr_c3, oc3, vc3);

  244. 

  245.     }

  246. 

  247.     ptr_b += 4 * pad_k;

  248.   }

  249. 

  250.   if (n & 2) {

  251.     ptr_c0 = ptr_c;

  252.     ptr_c1 = ptr_c0 + ldc;

  253.     ptr_c += 2 * ldc;

  254.     ptr_a = (bfloat16_t *)A;

  255. 

  256.     for (BLASLONG i = 0; i < m / 8; i++) {

  257.       ptr_a0 = ptr_a;

  258.       ptr_a += 8 * pad_k;

  259. 

  260.       ptr_b0 = ptr_b;

  261. 

  262.       INIT_C(0, 0);

  263.       INIT_C(1, 0);

  264.       INIT_C(2, 0);

  265.       INIT_C(3, 0);

  266. 

  267.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  268.         ma0 = svld1_bf16(pg16, ptr_a0);

  269.         ma1 = svld1_bf16(pg16, ptr_a0 + 8);

  270.         ma2 = svld1_bf16(pg16, ptr_a0 + 16);

  271.         ma3 = svld1_bf16(pg16, ptr_a0 + 24);

  272. 

  273.         mb0 = svld1_bf16(pg16, ptr_b0);

  274. 

  275.         MATMUL(0, 0);

  276.         MATMUL(1, 0);

  277.         MATMUL(2, 0);

  278.         MATMUL(3, 0);

  279. 

  280.         ptr_a0 += 32;

  281.         ptr_b0 += 8;

  282.       }

  283. 

  284.       vc0 = svuzp1(mc00, mc10);

  285.       vc1 = svuzp1(mc20, mc30);

  286.       vc2 = svuzp2(mc00, mc10);

  287.       vc3 = svuzp2(mc20, mc30);

  288. 

  289.       UPDATE_C(pg32, ptr_c0, oc0, vc0);

  290.       UPDATE_C(pg32, ptr_c0 + 4, oc1, vc1);

  291.       UPDATE_C(pg32, ptr_c1, oc2, vc2);

  292.       UPDATE_C(pg32, ptr_c1 + 4, oc3, vc3);

  293. 

  294.       ptr_c0 += 8;

  295.       ptr_c1 += 8;

  296.     }

  297. 

  298.     if (m & 4) {

  299.       ptr_a0 = ptr_a;

  300.       ptr_a += 4 * pad_k;

  301.       ptr_b0 = ptr_b;

  302. 

  303.       INIT_C(0, 0);

  304.       INIT_C(1, 0);

  305. 

  306.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  307.         ma0 = svld1_bf16(pg16, ptr_a0);

  308.         ma1 = svld1_bf16(pg16, ptr_a0 + 8);

  309.         mb0 = svld1_bf16(pg16, ptr_b0);

  310.         MATMUL(0, 0);

  311.         MATMUL(1, 0);

  312.         ptr_a0 += 16;

  313.         ptr_b0 += 8;

  314.       }

  315. 

  316.       vc0 = svuzp1(mc00, mc10);

  317.       vc1 = svuzp2(mc00, mc10);

  318. 

  319.       UPDATE_C(pg32, ptr_c0, oc0, vc0);

  320.       UPDATE_C(pg32, ptr_c1, oc1, vc1);

  321. 

  322.       ptr_c0 += 4;

  323.       ptr_c1 += 4;

  324.     }

  325. 

  326.     if (m & 2) {

  327.       ptr_a0 = ptr_a;

  328.       ptr_a += 2 * pad_k;

  329.       ptr_b0 = ptr_b;

  330. 

  331.       INIT_C(0, 0);

  332. 

  333.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  334.         ma0 = svld1_bf16(pg16, ptr_a0);

  335.         mb0 = svld1_bf16(pg16, ptr_b0);

  336. 

  337.         MATMUL(0, 0);

  338. 

  339.         ptr_a0 += 8;

  340.         ptr_b0 += 8;

  341.       }

  342. 

  343.       vc0 = svuzp1(mc00, mc00);

  344.       vc1 = svuzp2(mc00, mc00);

  345.       UPDATE_C(pg32_low, ptr_c0, oc0, vc0);

  346.       UPDATE_C(pg32_low, ptr_c1, oc1, vc1);

  347. 

  348.       ptr_c0 += 2;

  349.       ptr_c1 += 2;

  350. 

  351.     }

  352. 

  353.     if (m & 1) {

  354.       ptr_a0 = ptr_a;

  355.       ptr_b0 = ptr_b;

  356.       INIT_C(0, 0);

  357.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  358.         ma0 = svld1_bf16(pg16_low, ptr_a0);

  359.         mb0 = svld1_bf16(pg16, ptr_b0);

  360.         MATMUL(0, 0);

  361.         ptr_a0 += 4;

  362.         ptr_b0 += 8;

  363.       }

  364.       vc1 = svuzp2(mc00, mc00);

  365. 

  366.       UPDATE_C(pg32_first, ptr_c0, oc0, mc00);

  367.       UPDATE_C(pg32_first, ptr_c1, oc1, vc1);

  368.     }

  369. 

  370.     ptr_b += 2 * pad_k;

  371.   }

  372. 

  373.   if (n & 1) {

  374.     ptr_c0 = ptr_c;

  375.     ptr_a = (bfloat16_t *)A;

  376. 

  377.     for (BLASLONG i = 0; i < m / 8; i++) {

  378.       ptr_a0 = ptr_a;

  379.       ptr_a += 8 * pad_k;

  380. 

  381.       ptr_b0 = ptr_b;

  382. 

  383.       INIT_C(0, 0);

  384.       INIT_C(1, 0);

  385.       INIT_C(2, 0);

  386.       INIT_C(3, 0);

  387. 

  388.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  389.         ma0 = svld1_bf16(pg16, ptr_a0);

  390.         ma1 = svld1_bf16(pg16, ptr_a0 + 8);

  391.         ma2 = svld1_bf16(pg16, ptr_a0 + 16);

  392.         ma3 = svld1_bf16(pg16, ptr_a0 + 24);

  393. 

  394.         mb0 = svld1_bf16(pg16_low, ptr_b0);

  395. 

  396.         MATMUL(0, 0);

  397.         MATMUL(1, 0);

  398.         MATMUL(2, 0);

  399.         MATMUL(3, 0);

  400. 

  401.         ptr_a0 += 32;

  402.         ptr_b0 += 4;

  403.       }

  404. 

  405.       vc0 = svuzp1(mc00, mc10);

  406.       vc1 = svuzp1(mc20, mc30);

  407. 

  408.       UPDATE_C(pg32, ptr_c0, oc0, vc0);

  409.       UPDATE_C(pg32, ptr_c0 + 4, oc1, vc1);

  410. 

  411.       ptr_c0 += 8;

  412.     }

  413. 

  414.     if (m & 4) {

  415.       ptr_a0 = ptr_a;

  416.       ptr_a += 4 * pad_k;

  417.       ptr_b0 = ptr_b;

  418.       INIT_C(0, 0);

  419.       INIT_C(1, 0);

  420.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  421.         ma0 = svld1_bf16(pg16, ptr_a0);

  422.         ma1 = svld1_bf16(pg16, ptr_a0 + 8);

  423.         mb0 = svld1_bf16(pg16_low, ptr_b0);

  424.         MATMUL(0, 0);

  425.         MATMUL(1, 0);

  426.         ptr_a0 += 16;

  427.         ptr_b0 += 4;

  428.       }

  429.       vc0 = svuzp1(mc00, mc10);

  430.       UPDATE_C(pg32, ptr_c0, oc0, vc0);

  431.       ptr_c0 += 4;

  432.     }

  433. 

  434.     if (m & 2) {

  435.       ptr_a0 = ptr_a;

  436.       ptr_a += 2 * pad_k;

  437.       ptr_b0 = ptr_b;

  438. 

  439.       INIT_C(0, 0);

  440. 

  441.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  442.         ma0 = svld1_bf16(pg16, ptr_a0);

  443.         mb0 = svld1_bf16(pg16_low, ptr_b0);

  444. 

  445.         MATMUL(0, 0);

  446. 

  447.         ptr_a0 += 8;

  448.         ptr_b0 += 4;

  449.       }

  450.       vc0 = svuzp1(mc00, mc00);

  451.       UPDATE_C(pg32_low, ptr_c0, oc0, vc0);

  452.       ptr_c0 += 2;

  453.     }

  454. 

  455.     if (m & 1) {

  456.       ptr_a0 = ptr_a;

  457.       ptr_b0 = ptr_b;

  458.       INIT_C(0, 0);

  459.       for (BLASLONG p = 0; p < pad_k; p += 4) {

  460.         ma0 = svld1_bf16(pg16_low, ptr_a0);

  461.         mb0 = svld1_bf16(pg16_low, ptr_b0);

  462.         MATMUL(0, 0);

  463.         ptr_a0 += 4;

  464.         ptr_b0 += 4;

  465.       }

  466.       UPDATE_C(pg32_first, ptr_c0, oc0, mc00);

  467.     }

  468.   }

  469. 

  470.   return 0;

  471. }