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OpenBLAS/kernel/riscv64/trsm_kernel_LN_rvv_v1.c

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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 CONSEQUENTIAL

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

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

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

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

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

  26. *****************************************************************************/

  27. 

  28. #include "common.h"

  29. 

  30. #if !defined(DOUBLE)

  31. #define VSETVL(n)               __riscv_vsetvl_e32m2(n)

  32. #define VSETVL_MAX              __riscv_vsetvlmax_e32m2()

  33. #define FLOAT_V_T               vfloat32m2_t

  34. #define FLOAT_VX2_T             vfloat32m2x2_t

  35. #define VGET_VX2                __riscv_vget_v_f32m2x2_f32m2

  36. #define VSET_VX2                __riscv_vset_v_f32m2_f32m2x2

  37. #define VLSEV_FLOAT             __riscv_vlse32_v_f32m2

  38. #define VSSEV_FLOAT             __riscv_vsse32_v_f32m2

  39. #define VSEV_FLOAT              __riscv_vse32_v_f32m2

  40. #define VSSEG2_FLOAT            __riscv_vsseg2e32_v_f32m2x2

  41. #define VLSSEG2_FLOAT           __riscv_vlsseg2e32_v_f32m2x2

  42. #define VSSSEG2_FLOAT           __riscv_vssseg2e32_v_f32m2x2

  43. #define VFMACCVF_FLOAT          __riscv_vfmacc_vf_f32m2

  44. #define VFNMSACVF_FLOAT         __riscv_vfnmsac_vf_f32m2

  45. #define VFMULVF_FLOAT           __riscv_vfmul_vf_f32m2

  46. #else

  47. #define VSETVL(n)               __riscv_vsetvl_e64m2(n)

  48. #define VSETVL_MAX              __riscv_vsetvlmax_e64m2()

  49. #define FLOAT_V_T               vfloat64m2_t

  50. #define FLOAT_VX2_T             vfloat64m2x2_t

  51. #define VGET_VX2                __riscv_vget_v_f64m2x2_f64m2

  52. #define VSET_VX2                __riscv_vset_v_f64m2_f64m2x2

  53. #define VLSEV_FLOAT             __riscv_vlse64_v_f64m2

  54. #define VSSEV_FLOAT             __riscv_vsse64_v_f64m2

  55. #define VSEV_FLOAT              __riscv_vse64_v_f64m2

  56. #define VSSEG2_FLOAT            __riscv_vsseg2e64_v_f64m2x2

  57. #define VLSSEG2_FLOAT           __riscv_vlsseg2e64_v_f64m2x2

  58. #define VSSSEG2_FLOAT           __riscv_vssseg2e64_v_f64m2x2

  59. #define VFMVVF_FLOAT            __riscv_vfmv_v_f_f64m2

  60. #define VFMACCVF_FLOAT          __riscv_vfmacc_vf_f64m2

  61. #define VFNMSACVF_FLOAT         __riscv_vfnmsac_vf_f64m2

  62. #define VFMULVF_FLOAT           __riscv_vfmul_vf_f64m2

  63. #endif

  64. 

  65. 

  66. static FLOAT dm1 = -1.;

  67. 

  68. #ifdef CONJ

  69. #define GEMM_KERNEL   GEMM_KERNEL_L

  70. #else

  71. #define GEMM_KERNEL   GEMM_KERNEL_N

  72. #endif

  73. 

  74. #if GEMM_DEFAULT_UNROLL_N == 1

  75. #define GEMM_UNROLL_N_SHIFT 0

  76. #endif

  77. 

  78. #if GEMM_DEFAULT_UNROLL_N == 2

  79. #define GEMM_UNROLL_N_SHIFT 1

  80. #endif

  81. 

  82. #if GEMM_DEFAULT_UNROLL_N == 4

  83. #define GEMM_UNROLL_N_SHIFT 2

  84. #endif

  85. 

  86. #if GEMM_DEFAULT_UNROLL_N == 8

  87. #define GEMM_UNROLL_N_SHIFT 3

  88. #endif

  89. 

  90. #if GEMM_DEFAULT_UNROLL_N == 16

  91. #define GEMM_UNROLL_N_SHIFT 4

  92. #endif

  93. 

  94. // Optimizes the implementation in ../arm64/trsm_kernel_LN_sve.c

  95. 

  96. #ifndef COMPLEX

  97. 

  98. static inline void solve(BLASLONG m, BLASLONG n, FLOAT *a, FLOAT *b, FLOAT *c, BLASLONG ldc) {

  99.     FLOAT aa;

  100.     FLOAT* pc;

  101. 

  102.     int i, j, k;

  103. 

  104.     BLASLONG stride_ldc = sizeof(FLOAT) * ldc;

  105. 

  106.     FLOAT_V_T vb, vc;

  107. 

  108.     size_t vl;

  109. 

  110.     a += (m - 1) * m;

  111.     b += (m - 1) * n;

  112. 

  113.     for (i = m - 1; i >= 0; i--) {

  114. 

  115.         aa = *(a + i);

  116.         pc  = c;

  117.         for (j = n; j > 0; j -= vl) {

  118.             vl = VSETVL(j);

  119.             vb = VLSEV_FLOAT(pc + i, stride_ldc, vl);

  120.             vb = VFMULVF_FLOAT(vb, aa, vl);

  121.             VSEV_FLOAT(b, vb, vl);

  122.             VSSEV_FLOAT(pc + i, stride_ldc, vb, vl);

  123.             b   += vl;

  124. 

  125.             for (k = 0; k < i; k ++) {

  126.                 vc = VLSEV_FLOAT(pc + k, stride_ldc, vl);

  127.                 vc = VFNMSACVF_FLOAT(vc, *(a + k), vb, vl);

  128.                 VSSEV_FLOAT(pc + k, stride_ldc, vc, vl);

  129.             }

  130.             pc  += vl * ldc;

  131.         }

  132.         a -= m;

  133.         b -= 2 * n;

  134.     }

  135. 

  136. }

  137. #else

  138. 

  139. static inline void solve(BLASLONG m, BLASLONG n, FLOAT *a, FLOAT *b, FLOAT *c, BLASLONG ldc) {

  140. 

  141.     FLOAT aa1, aa2;

  142.     FLOAT *pc;

  143.     int i, j, k;

  144. 

  145.     BLASLONG stride_ldc = sizeof(FLOAT) * ldc * 2;

  146. 

  147.     FLOAT_VX2_T vbx2, vsx2, vcx2;

  148.     FLOAT_V_T vb1, vb2, vc1, vc2, vs1, vs2;

  149.     size_t vl;

  150.     a += (m - 1) * m * 2;

  151.     b += (m - 1) * n * 2;

  152. 

  153.     for (i = m - 1; i >= 0; i--) {

  154. 

  155.         aa1 = *(a + i * 2 + 0);

  156.         aa2 = *(a + i * 2 + 1);

  157.         pc  = c;

  158. 

  159.         for (j = n; j > 0; j -= vl) {

  160.             vl = VSETVL(j);

  161.             vbx2 = VLSSEG2_FLOAT(pc + i * 2, stride_ldc, vl);

  162.             vb1 = VGET_VX2(vbx2, 0);

  163.             vb2 = VGET_VX2(vbx2, 1);

  164. #ifndef CONJ

  165.             vs1 =   VFMULVF_FLOAT(vb1, aa1, vl);

  166.             vs1 = VFNMSACVF_FLOAT(vs1, aa2, vb2, vl);

  167.             vs2 =   VFMULVF_FLOAT(vb2, aa1, vl);

  168.             vs2 =  VFMACCVF_FLOAT(vs2, aa2, vb1, vl);

  169. #else

  170.             vs1 =   VFMULVF_FLOAT(vb1, aa1, vl);

  171.             vs1 =  VFMACCVF_FLOAT(vs1, aa2, vb2, vl);

  172.             vs2 =   VFMULVF_FLOAT(vb2, aa1, vl);

  173.             vs2 = VFNMSACVF_FLOAT(vs2, aa2, vb1, vl);

  174. #endif

  175.             vsx2 = VSET_VX2(vsx2, 0, vs1);

  176.             vsx2 = VSET_VX2(vsx2, 1, vs2);

  177.             VSSEG2_FLOAT(b, vsx2, vl);

  178.             VSSSEG2_FLOAT(pc + i * 2, stride_ldc, vsx2, vl);

  179.             b   += vl * 2;

  180. 

  181.             for (k = 0; k < i; k ++) {

  182.                 vcx2 = VLSSEG2_FLOAT(pc + k * 2, stride_ldc, vl);

  183.                 vc1 = VGET_VX2(vcx2, 0);

  184.                 vc2 = VGET_VX2(vcx2, 1);

  185. #ifndef CONJ

  186.                 vc1 =  VFMACCVF_FLOAT(vc1, *(a + k * 2 + 1), vs2, vl);

  187.                 vc1 = VFNMSACVF_FLOAT(vc1, *(a + k * 2 + 0), vs1, vl);

  188.                 vc2 = VFNMSACVF_FLOAT(vc2, *(a + k * 2 + 1), vs1, vl);

  189.                 vc2 = VFNMSACVF_FLOAT(vc2, *(a + k * 2 + 0), vs2, vl);

  190. #else                                                        

  191.                 vc1 = VFNMSACVF_FLOAT(vc1, *(a + k * 2 + 1), vs2, vl);

  192.                 vc1 = VFNMSACVF_FLOAT(vc1, *(a + k * 2 + 0), vs1, vl);

  193.                 vc2 =  VFMACCVF_FLOAT(vc2, *(a + k * 2 + 1), vs1, vl);

  194.                 vc2 = VFNMSACVF_FLOAT(vc2, *(a + k * 2 + 0), vs2, vl);

  195. #endif

  196.                 vcx2 = VSET_VX2(vcx2, 0, vc1);

  197.                 vcx2 = VSET_VX2(vcx2, 1, vc2);

  198.                 VSSSEG2_FLOAT(pc + k * 2, stride_ldc, vcx2, vl);

  199.             }

  200.             pc  += vl * ldc * 2;

  201.         }

  202.         a -= m * 2;

  203.         b -= 4 * n;

  204.     }

  205. }

  206. 

  207. 

  208. #endif

  209. 

  210. 

  211. int CNAME(BLASLONG m, BLASLONG n, BLASLONG k,  FLOAT dummy1,

  212. #ifdef COMPLEX

  213.     FLOAT dummy2,

  214. #endif

  215.     FLOAT *a, FLOAT *b, FLOAT *c, BLASLONG ldc, BLASLONG offset){

  216. 

  217.   BLASLONG i, j;

  218.   FLOAT *aa, *cc;

  219.   BLASLONG  kk;

  220.   

  221.   size_t vl = VSETVL_MAX;

  222. 

  223.     //fprintf(stderr, "%s , %s, m = %4ld  n = %4ld  k = %4ld offset = %4ld\n", __FILE__, __FUNCTION__, m, n, k, offset); // Debug

  224. 

  225.   j = (n >> GEMM_UNROLL_N_SHIFT);

  226. 

  227.   while (j > 0) {

  228. 

  229.     kk = m + offset;

  230. 

  231.     i = m % vl;

  232.     if (i) {

  233.       aa = a + (m - i) * k * COMPSIZE;

  234.       cc = c + (m - i)     * COMPSIZE;

  235. 

  236.       if (k - kk > 0) {

  237.         GEMM_KERNEL(i, GEMM_UNROLL_N, k - kk, dm1,

  238. #ifdef COMPLEX

  239.             ZERO,

  240. #endif

  241.             aa + i             * kk * COMPSIZE,

  242.             b  + GEMM_UNROLL_N * kk * COMPSIZE,

  243.             cc,

  244.             ldc);

  245.       }

  246. 

  247.       solve(i, GEMM_UNROLL_N,

  248.           aa + (kk - i) * i             * COMPSIZE,

  249.           b  + (kk - i) * GEMM_UNROLL_N * COMPSIZE,

  250.           cc, ldc);

  251. 

  252.       kk -= i;

  253. 

  254.     }

  255. 

  256.     int mod = i;

  257.     i = vl;

  258.     if (i <= m) {

  259.       aa = a + (m - mod - vl) * k * COMPSIZE;

  260.       cc = c + (m - mod - vl)     * COMPSIZE;

  261. 

  262.       do {

  263.         if (k - kk > 0) {

  264.           GEMM_KERNEL(vl, GEMM_UNROLL_N, k - kk, dm1,

  265. #ifdef COMPLEX

  266.               ZERO,

  267. #endif

  268.               aa + vl * kk * COMPSIZE,

  269.               b +  GEMM_UNROLL_N * kk * COMPSIZE,

  270.               cc,

  271.               ldc);

  272.         }

  273. 

  274.         solve(vl, GEMM_UNROLL_N,

  275.             aa + (kk - vl) * vl * COMPSIZE,

  276.             b  + (kk - vl) * GEMM_UNROLL_N * COMPSIZE,

  277.             cc, ldc);

  278. 

  279.         aa -= vl * k * COMPSIZE;

  280.         cc -= vl     * COMPSIZE;

  281.         kk -= vl;

  282. 

  283.         i += vl;

  284.       } while (i <= m);

  285.     }

  286. 

  287. 

  288.     b += GEMM_UNROLL_N * k * COMPSIZE;

  289.     c += GEMM_UNROLL_N * ldc * COMPSIZE;

  290.     j --;

  291.   }

  292. 

  293.   if (n & (GEMM_UNROLL_N - 1)) {

  294. 

  295.     j = (GEMM_UNROLL_N >> 1);

  296.     while (j > 0) {

  297.       if (n & j) {

  298. 

  299.         kk = m + offset;

  300. 

  301.         i = m % vl;

  302.         if (i) {

  303.           aa = a + (m - i) * k * COMPSIZE;

  304.           cc = c + (m - i)     * COMPSIZE;

  305. 

  306.           if (k - kk > 0) {

  307.             GEMM_KERNEL(i, j, k - kk, dm1,

  308. #ifdef COMPLEX

  309.                 ZERO,

  310. #endif

  311.                 aa + i * kk * COMPSIZE,

  312.                 b  + j * kk * COMPSIZE,

  313.                 cc, ldc);

  314.           }

  315. 

  316.           solve(i, j,

  317.               aa + (kk - i) * i * COMPSIZE,

  318.               b  + (kk - i) * j * COMPSIZE,

  319.               cc, ldc);

  320. 

  321.           kk -= i;

  322. 

  323.         }

  324. 

  325.         int mod = i;

  326.         i = vl;

  327.         if (i <= m) {

  328.           aa = a + (m - mod - vl) * k * COMPSIZE;

  329.           cc = c + (m - mod - vl)     * COMPSIZE;

  330. 

  331.           do {

  332.             if (k - kk > 0) {

  333.               GEMM_KERNEL(vl, j, k - kk, dm1,

  334. #ifdef COMPLEX

  335.                   ZERO,

  336. #endif

  337.                   aa + vl * kk * COMPSIZE,

  338.                   b +  j             * kk * COMPSIZE,

  339.                   cc,

  340.                   ldc);

  341.             }

  342. 

  343.             solve(vl, j,

  344.                 aa + (kk - vl) * vl * COMPSIZE,

  345.                 b  + (kk - vl) * j             * COMPSIZE,

  346.                 cc, ldc);

  347. 

  348.             aa -= vl * k * COMPSIZE;

  349.             cc -= vl     * COMPSIZE;

  350.             kk -= vl;

  351. 

  352.             i += vl;

  353.           } while (i <= m);

  354.         }

  355. 

  356.         b += j * k   * COMPSIZE;

  357.         c += j * ldc * COMPSIZE;

  358.       }

  359.       j >>= 1;

  360.     }

  361.   }

  362. 

  363.   return 0;

  364. }