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OpenBLAS/kernel/arm64/gemv_n_sve_v4x3.c

gemv_n_sve_v4x3.c 8.7 kB
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Further performance improvements to [SD]GEMV.
5 months ago
fixed a potential out-of-bounds on gemv.
5 months ago
Further performance improvements to [SD]GEMV.
5 months ago
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  1. /***************************************************************************

  2. Copyright (c) 2025, 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. #include <arm_sve.h>

  34. 

  35. #include "common.h"

  36. 

  37. #ifdef DOUBLE

  38. #define SV_COUNT svcntd

  39. #define SV_TYPE svfloat64_t

  40. #define SV_TRUE svptrue_b64

  41. #define SV_WHILE svwhilelt_b64_s64

  42. #define SV_DUP svdup_f64

  43. #else

  44. #define SV_COUNT svcntw

  45. #define SV_TYPE svfloat32_t

  46. #define SV_TRUE svptrue_b32

  47. #define SV_WHILE svwhilelt_b32_s64

  48. #define SV_DUP svdup_f32

  49. #endif

  50. 

  51. int CNAME(BLASLONG m, BLASLONG n, BLASLONG dummy1, FLOAT alpha, FLOAT *a,

  52.           BLASLONG lda, FLOAT *x, BLASLONG inc_x, FLOAT *y, BLASLONG inc_y,

  53.           FLOAT *buffer)

  54. {

  55.   BLASLONG i;

  56.   BLASLONG ix,iy;

  57.   BLASLONG j;

  58.   FLOAT *a_ptr;

  59.   FLOAT temp;

  60. 

  61.   ix = 0;

  62.   a_ptr = a;

  63. 

  64.   if (inc_y == 1) {

  65.     BLASLONG width = (n + 3 - 1) / 3;

  66. 

  67.     FLOAT *a0_ptr = a_ptr + lda * width * 0;

  68.     FLOAT *a1_ptr = a_ptr + lda * width * 1;

  69.     FLOAT *a2_ptr = a_ptr + lda * width * 2;

  70. 

  71.     FLOAT *x0_ptr = x + inc_x * width * 0;

  72.     FLOAT *x1_ptr = x + inc_x * width * 1;

  73.     FLOAT *x2_ptr = x + inc_x * width * 2;

  74. 

  75.     for (j = 0; j < width; j++) {

  76.       svbool_t pg00 = ((j + width * 0) < n) ? SV_TRUE() : svpfalse();

  77.       svbool_t pg10 = ((j + width * 0) < n) ? SV_TRUE() : svpfalse();

  78.       svbool_t pg20 = ((j + width * 0) < n) ? SV_TRUE() : svpfalse();

  79.       svbool_t pg30 = ((j + width * 0) < n) ? SV_TRUE() : svpfalse();

  80.       svbool_t pg01 = ((j + width * 1) < n) ? SV_TRUE() : svpfalse();

  81.       svbool_t pg11 = ((j + width * 1) < n) ? SV_TRUE() : svpfalse();

  82.       svbool_t pg21 = ((j + width * 1) < n) ? SV_TRUE() : svpfalse();

  83.       svbool_t pg31 = ((j + width * 1) < n) ? SV_TRUE() : svpfalse();

  84.       svbool_t pg02 = ((j + width * 2) < n) ? SV_TRUE() : svpfalse();

  85.       svbool_t pg12 = ((j + width * 2) < n) ? SV_TRUE() : svpfalse();

  86.       svbool_t pg22 = ((j + width * 2) < n) ? SV_TRUE() : svpfalse();

  87.       svbool_t pg32 = ((j + width * 2) < n) ? SV_TRUE() : svpfalse();

  88. 

  89.       SV_TYPE temp0_vec = ((j + width * 0) < n) ? SV_DUP(alpha * x0_ptr[ix]) : SV_DUP(0.0);

  90.       SV_TYPE temp1_vec = ((j + width * 1) < n) ? SV_DUP(alpha * x1_ptr[ix]) : SV_DUP(0.0);

  91.       SV_TYPE temp2_vec = ((j + width * 2) < n) ? SV_DUP(alpha * x2_ptr[ix]) : SV_DUP(0.0);

  92.       i = 0;

  93.       BLASLONG sve_size = SV_COUNT();

  94.       while ((i + sve_size * 4 - 1) < m) {

  95.         SV_TYPE y0_vec = svld1_vnum(SV_TRUE(), y + i, 0);

  96.         SV_TYPE y1_vec = svld1_vnum(SV_TRUE(), y + i, 1);

  97.         SV_TYPE y2_vec = svld1_vnum(SV_TRUE(), y + i, 2);

  98.         SV_TYPE y3_vec = svld1_vnum(SV_TRUE(), y + i, 3);

  99. 

  100.         SV_TYPE a00_vec = svld1_vnum(pg00, a0_ptr + i, 0);

  101.         SV_TYPE a10_vec = svld1_vnum(pg10, a0_ptr + i, 1);

  102.         SV_TYPE a20_vec = svld1_vnum(pg20, a0_ptr + i, 2);

  103.         SV_TYPE a30_vec = svld1_vnum(pg30, a0_ptr + i, 3);

  104.         SV_TYPE a01_vec = svld1_vnum(pg01, a1_ptr + i, 0);

  105.         SV_TYPE a11_vec = svld1_vnum(pg11, a1_ptr + i, 1);

  106.         SV_TYPE a21_vec = svld1_vnum(pg21, a1_ptr + i, 2);

  107.         SV_TYPE a31_vec = svld1_vnum(pg31, a1_ptr + i, 3);

  108.         SV_TYPE a02_vec = svld1_vnum(pg02, a2_ptr + i, 0);

  109.         SV_TYPE a12_vec = svld1_vnum(pg12, a2_ptr + i, 1);

  110.         SV_TYPE a22_vec = svld1_vnum(pg22, a2_ptr + i, 2);

  111.         SV_TYPE a32_vec = svld1_vnum(pg32, a2_ptr + i, 3);

  112. 

  113.         y0_vec = svmla_m(pg00, y0_vec, temp0_vec, a00_vec);

  114.         y1_vec = svmla_m(pg10, y1_vec, temp0_vec, a10_vec);

  115.         y2_vec = svmla_m(pg20, y2_vec, temp0_vec, a20_vec);

  116.         y3_vec = svmla_m(pg30, y3_vec, temp0_vec, a30_vec);

  117.         y0_vec = svmla_m(pg01, y0_vec, temp1_vec, a01_vec);

  118.         y1_vec = svmla_m(pg11, y1_vec, temp1_vec, a11_vec);

  119.         y2_vec = svmla_m(pg21, y2_vec, temp1_vec, a21_vec);

  120.         y3_vec = svmla_m(pg31, y3_vec, temp1_vec, a31_vec);

  121.         y0_vec = svmla_m(pg02, y0_vec, temp2_vec, a02_vec);

  122.         y1_vec = svmla_m(pg12, y1_vec, temp2_vec, a12_vec);

  123.         y2_vec = svmla_m(pg22, y2_vec, temp2_vec, a22_vec);

  124.         y3_vec = svmla_m(pg32, y3_vec, temp2_vec, a32_vec);

  125. 

  126.         svst1_vnum(SV_TRUE(), y + i, 0, y0_vec);

  127.         svst1_vnum(SV_TRUE(), y + i, 1, y1_vec);

  128.         svst1_vnum(SV_TRUE(), y + i, 2, y2_vec);

  129.         svst1_vnum(SV_TRUE(), y + i, 3, y3_vec);

  130.         i += sve_size * 4;

  131.       }

  132. 

  133.       if (i < m) {

  134.         svbool_t pg0 = SV_WHILE(i + sve_size * 0, m);

  135.         svbool_t pg1 = SV_WHILE(i + sve_size * 1, m);

  136.         svbool_t pg2 = SV_WHILE(i + sve_size * 2, m);

  137.         svbool_t pg3 = SV_WHILE(i + sve_size * 3, m);

  138. 

  139.         pg00 = svand_z(SV_TRUE(), pg0, pg00);

  140.         pg10 = svand_z(SV_TRUE(), pg1, pg10);

  141.         pg20 = svand_z(SV_TRUE(), pg2, pg20);

  142.         pg30 = svand_z(SV_TRUE(), pg3, pg30);

  143.         pg01 = svand_z(SV_TRUE(), pg0, pg01);

  144.         pg11 = svand_z(SV_TRUE(), pg1, pg11);

  145.         pg21 = svand_z(SV_TRUE(), pg2, pg21);

  146.         pg31 = svand_z(SV_TRUE(), pg3, pg31);

  147.         pg02 = svand_z(SV_TRUE(), pg0, pg02);

  148.         pg12 = svand_z(SV_TRUE(), pg1, pg12);

  149.         pg22 = svand_z(SV_TRUE(), pg2, pg22);

  150.         pg32 = svand_z(SV_TRUE(), pg3, pg32);

  151. 

  152.         SV_TYPE y0_vec = svld1_vnum(pg0, y + i, 0);

  153.         SV_TYPE y1_vec = svld1_vnum(pg1, y + i, 1);

  154.         SV_TYPE y2_vec = svld1_vnum(pg2, y + i, 2);

  155.         SV_TYPE y3_vec = svld1_vnum(pg3, y + i, 3);

  156. 

  157.         SV_TYPE a00_vec = svld1_vnum(pg00, a0_ptr + i, 0);

  158.         SV_TYPE a10_vec = svld1_vnum(pg10, a0_ptr + i, 1);

  159.         SV_TYPE a20_vec = svld1_vnum(pg20, a0_ptr + i, 2);

  160.         SV_TYPE a30_vec = svld1_vnum(pg30, a0_ptr + i, 3);

  161.         SV_TYPE a01_vec = svld1_vnum(pg01, a1_ptr + i, 0);

  162.         SV_TYPE a11_vec = svld1_vnum(pg11, a1_ptr + i, 1);

  163.         SV_TYPE a21_vec = svld1_vnum(pg21, a1_ptr + i, 2);

  164.         SV_TYPE a31_vec = svld1_vnum(pg31, a1_ptr + i, 3);

  165.         SV_TYPE a02_vec = svld1_vnum(pg02, a2_ptr + i, 0);

  166.         SV_TYPE a12_vec = svld1_vnum(pg12, a2_ptr + i, 1);

  167.         SV_TYPE a22_vec = svld1_vnum(pg22, a2_ptr + i, 2);

  168.         SV_TYPE a32_vec = svld1_vnum(pg32, a2_ptr + i, 3);

  169. 

  170.         y0_vec = svmla_m(pg00, y0_vec, temp0_vec, a00_vec);

  171.         y1_vec = svmla_m(pg10, y1_vec, temp0_vec, a10_vec);

  172.         y2_vec = svmla_m(pg20, y2_vec, temp0_vec, a20_vec);

  173.         y3_vec = svmla_m(pg30, y3_vec, temp0_vec, a30_vec);

  174.         y0_vec = svmla_m(pg01, y0_vec, temp1_vec, a01_vec);

  175.         y1_vec = svmla_m(pg11, y1_vec, temp1_vec, a11_vec);

  176.         y2_vec = svmla_m(pg21, y2_vec, temp1_vec, a21_vec);

  177.         y3_vec = svmla_m(pg31, y3_vec, temp1_vec, a31_vec);

  178.         y0_vec = svmla_m(pg02, y0_vec, temp2_vec, a02_vec);

  179.         y1_vec = svmla_m(pg12, y1_vec, temp2_vec, a12_vec);

  180.         y2_vec = svmla_m(pg22, y2_vec, temp2_vec, a22_vec);

  181.         y3_vec = svmla_m(pg32, y3_vec, temp2_vec, a32_vec);

  182. 

  183.         svst1_vnum(pg0, y + i, 0, y0_vec);

  184.         svst1_vnum(pg1, y + i, 1, y1_vec);

  185.         svst1_vnum(pg2, y + i, 2, y2_vec);

  186.         svst1_vnum(pg3, y + i, 3, y3_vec);

  187.       }

  188.       a0_ptr += lda;

  189.       a1_ptr += lda;

  190.       a2_ptr += lda;

  191.       ix += inc_x;

  192.     }

  193.     return(0);

  194.   }

  195. 

  196.   for (j = 0; j < n; j++) {

  197.     temp = alpha * x[ix];

  198.     iy = 0;

  199.     for (i = 0; i < m; i++) {

  200.       y[iy] += temp * a_ptr[i];

  201.       iy += inc_y;

  202.     }

  203.     a_ptr += lda;

  204.     ix += inc_x;

  205.   }

  206.   return (0);

  207. }

OpenBLAS is an optimized BLAS library based on GotoBLAS2 1.13 BSD version.