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OpenBLAS/kernel/arm64/sgemm_small_kernel_tt_sve.c

sgemm_small_kernel_tt_sve.c 26 kB
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Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Better header guard around bridge
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Unroll TT further
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
small gemm kernel packing modifications
8 months ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Unroll TT further
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Unroll TT further
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Unroll TT further
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Unroll TT further
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Unroll TT further
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Unroll TT further
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Unroll TT further
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Unroll TT further
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Unroll TT further
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Unroll TT further
1 year ago
Clean up k2 removal more and unroll SGEMM more
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Unroll TT further
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
Small GEMM for AArch64 This is a fairly conservative addition of small matrix kernels using SVE.
1 year ago
Further tweak small GEMM for AArch64
1 year ago
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  1. /***************************************************************************

  2. Copyright (c) 2024, 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 SUBSTITUTE

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

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

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

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

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

  27. 

  28. #include "common.h"

  29. 

  30. #include <arm_neon.h>

  31. #include <arm_sve.h>

  32. #if defined(__ARM_NEON_SVE_BRIDGE) && defined(__has_include) &&                \

  33.   __has_include(<arm_neon_sve_bridge.h>)

  34. #include <arm_neon_sve_bridge.h>

  35. #else

  36. #define svdup_neonq_f32(fixed_reg)                                             \

  37.   ({                                                                           \

  38.     svfloat32_t scalable_reg;                                                  \

  39.     asm("mov %0.q, %q1" : "=w"(scalable_reg) : "w"(fixed_reg) :);              \

  40.     scalable_reg;                                                              \

  41.   })

  42. #define svdup_neonq_f64(fixed_reg)                                             \

  43.   ({                                                                           \

  44.     svfloat64_t scalable_reg;                                                  \

  45.     asm("mov %0.q, %q1" : "=w"(scalable_reg) : "w"(fixed_reg) :);              \

  46.     scalable_reg;                                                              \

  47.   })

  48. #endif

  49. 

  50. #define RESET_A_POINTER() a_offset = A;

  51. 

  52. #define CREATE_A_POINTER(m, scale) FLOAT* a_offset##m = a_offset + scale * lda;

  53. #define UPDATE_A_POINTER(scale) a_offset = a_offset + scale * lda;

  54. #define A_ELEMENT_K(m, offset_k) *(a_offset##m + (k + offset_k))

  55. #define A_ELEMENT(m) A_ELEMENT_K(m, 0)

  56. 

  57. #define RESET_B_POINTER() b_offset = B;

  58. 

  59. #define CREATE_B_POINTER(n, scale) FLOAT* b_offset##n = b_offset + scale;

  60. #define UPDATE_B_POINTER(scale) b_offset = b_offset + scale;

  61. #define B_ELEMENT_K(n, offset_k) *(b_offset##n + (k + offset_k) * ldb)

  62. #define B_ELEMENT(n) B_ELEMENT_K(n, 0)

  63. 

  64. #define CREATE_C_POINTER(m, scale) FLOAT* c_offset##m = c_offset + scale;

  65. #define INCR_C_POINTER(m, incr) // c_offset ## m += incr * ldc;

  66. #define UPDATE_C_POINTER(scale) c_offset += scale;

  67. #define C_ELEMENT(m, n)                                                        \

  68.   *(c_offset##m + ((j + n) * ldc)) // C[(i+(m))+(j+(n))*ldc]

  69. 

  70. // #undef C_ELEMENT

  71. // #define C_ELEMENT(m, n)             C[(i+(m))+(j+(n))*ldc]

  72. 

  73. #define PACK_ELEMENT_K(m, offset_k) packed_a[(k + offset_k) * v_size2 + m]

  74. #define PACK_ELEMENT(m) PACK_ELEMENT_K(m, 0)

  75. 

  76. // ASIMD

  77. #define DECLARE_RESULT_VECTOR4(m, n)                                           \

  78.   float32x4_t result##m##n = vdupq_n_f32(0.0);

  79. #define DECLARE_RESULT(m, n) float32_t result##m##n = 0.0;

  80. #define BROADCAST_LOAD_A4(m, offset_k)                                         \

  81.   float32x4_t a##m##_k##offset_k = vld1q_dup_f32(&A_ELEMENT_K(m, offset_k));

  82. #define LOAD_A1(m, offset_k)                                                   \

  83.   float32_t a##m##_k##offset_k = A_ELEMENT_K(m, offset_k);

  84. #define VECTOR_LOAD_B4(n, offset_k)                                            \

  85.   float32x4_t b##n##_k##offset_k = vld1q_f32(&B_ELEMENT_K(n, offset_k));

  86. #define GATHER_LOAD_B4(n, offset_k)                                            \

  87.   float32x4_t b##n##_k##offset_k = vdupq_n_f32(B_ELEMENT_K(n, offset_k));      \

  88.   b##n##_k##offset_k =                                                         \

  89.     vsetq_lane_f32(B_ELEMENT_K(n + 1, offset_k), b##n##_k##offset_k, 1);       \

  90.   b##n##_k##offset_k =                                                         \

  91.     vsetq_lane_f32(B_ELEMENT_K(n + 2, offset_k), b##n##_k##offset_k, 2);       \

  92.   b##n##_k##offset_k =                                                         \

  93.     vsetq_lane_f32(B_ELEMENT_K(n + 3, offset_k), b##n##_k##offset_k, 3);

  94. #define VECTOR_UNPACK_B4(n, offset_k)                                          \

  95.   float32x4_t b##n##_k##offset_k = vld1q_f32(&PACK_ELEMENT_K(n, offset_k));

  96. #define VECTOR_PACK_B4(n, offset_k)                                            \

  97.   vst1q_f32(&PACK_ELEMENT_K(n, offset_k), b##n##_k##offset_k);

  98. #define PACK_B0(n, offset_k)                                                   \

  99.   PACK_ELEMENT_K(n, offset_k) = vget_lane_f32(b##n##_k##offset_k, 0);

  100. #define UPDATE_RESULT_VECTOR4(m, n, offset_k)                                  \

  101.   result##m##n =                                                               \

  102.     vfmaq_f32(result##m##n, a##m##_k##offset_k, b##n##_k##offset_k);

  103. #define UPDATE_RESULT(m, n, offset_k)                                          \

  104.   result##m##n = result##m##n + a##m##_k##offset_k * b##n##_k##offset_k;

  105. #ifdef B0

  106. #define VECTOR_STORE4(m, n)                                                    \

  107.   vst1q_f32(&C_ELEMENT(m, n), vmulq_f32(result##m##n, vdupq_n_f32(alpha)));

  108. #define STORE(m, n) C_ELEMENT(m, n) = alpha * result##m##n;

  109. #else

  110. #define VECTOR_STORE4(m, n)                                                    \

  111.   result##m##n = vmulq_f32(result##m##n, vdupq_n_f32(alpha));                  \

  112.   result##m##n =                                                               \

  113.     vfmaq_f32(result##m##n, vld1q_f32(&C_ELEMENT(m, n)), vdupq_n_f32(beta));   \

  114.   vst1q_f32(&C_ELEMENT(m, n), result##m##n);

  115. #define STORE(m, n)                                                            \

  116.   C_ELEMENT(m, n) = C_ELEMENT(m, n) * beta + alpha * result##m##n;

  117. #endif

  118. 

  119. // SVE

  120. #define DECLARE_RESULT_VECTOR(m, n) svfloat32_t result##m##n = svdup_f32(0.0);

  121. #define BROADCAST_LOAD_A(m, offset_k)                                          \

  122.   svfloat32_t a##s##m##_k##offset_k = svdup_f32(A_ELEMENT_K(m, offset_k));

  123. #define BROADCAST_LOAD_B(n, offset_k)                                          \

  124.   svfloat32_t b##s##n##_k##offset_k = svdup_f32(B_ELEMENT_K(n, offset_k));

  125. #define VECTOR_LOAD_A(pg, m, offset_k)                                         \

  126.   svfloat32_t a##s##m##_k##offset_k = svld1(pg, &A_ELEMENT_K(m, offset_k));

  127. #define QUADWORD_LOAD_B(n, offset_k)                                           \

  128.   svfloat32_t b##s##n##_k##offset_k =                                          \

  129.     svld1rq(pg_true, &B_ELEMENT_K(n, offset_k));

  130. #define GATHER_LOAD_A(pg, m, offset_k)                                         \

  131.   svfloat32_t a##s##m##_k##offset_k =                                          \

  132.     svld1_gather_index(pg, &A_ELEMENT_K(m, offset_k), lda_vec);

  133. #define PACK_A(m, offset_k)                                                    \

  134.   svst1(pg_first, &PACK_ELEMENT_K(m, offset_k), a##s##m##_k##offset_k);

  135. #define VECTOR_PACK_A(m, offset_k)                                             \

  136.   svst1(pg_true, &PACK_ELEMENT_K(m* v_size, offset_k), a##s##m##_k##offset_k);

  137. #define QUADWORD_PACK_A(m, offset_k)                                           \

  138.   svst1(pg_quad, &PACK_ELEMENT_K(m, offset_k), a##s##m##_k##offset_k);

  139. #define UNPACK_VECTOR_A(m, offset_k)                                           \

  140.   svfloat32_t a##s##m##_k##offset_k =                                          \

  141.     svld1(pg_true, &PACK_ELEMENT_K(m * v_size, offset_k));

  142. #define UNPACK_BROADCAST_A(m, offset_k)                                        \

  143.   svfloat32_t a##s##m##_k##offset_k = svdup_f32(PACK_ELEMENT_K(m, offset_k));

  144. #define UNPACK_QUADWORD_A(m, offset_k)                                         \

  145.   svfloat32_t a##s##m##_k##offset_k =                                          \

  146.     svld1rq(pg_true, &PACK_ELEMENT_K(m, offset_k));

  147. #define UPDATE_RESULT_VECTOR(pg, m, n, offset_k)                               \

  148.   result##m##n =                                                               \

  149.     svmla_m(pg, result##m##n, a##s##m##_k##offset_k, b##s##n##_k##offset_k);

  150. #define UPDATE_RESULT_VECTOR_QUADWORD(m, n, outer, lane, offset_k)             \

  151.   result##m##n = svmla_lane(                                                   \

  152.     result##m##n, a##s##m##_k##offset_k, b##s##outer##_k##offset_k, lane);

  153. #ifdef B0

  154. #define VECTOR_STORE(pg, m, n)                                                 \

  155.   result##m##n = svmul_m(pg, result##m##n, alpha_vec);                         \

  156.   svst1(pg, &C_ELEMENT(m, n), result##m##n);

  157. #define SCATTER_STORE(pg, m, n)                                                \

  158.   result##m##n = svmul_m(pg, result##m##n, alpha_vec);                         \

  159.   svst1_scatter_index(pg, &C_ELEMENT(m, n), ldc_vec, result##m##n);

  160. #else

  161. #define VECTOR_STORE(pg, m, n)                                                 \

  162.   result##m##n = svmul_m(pg, result##m##n, alpha_vec);                         \

  163.   result##m##n =                                                               \

  164.     svmla_m(pg, result##m##n, svld1(pg, &C_ELEMENT(m, n)), beta_vec);          \

  165.   svst1(pg, &C_ELEMENT(m, n), result##m##n);

  166. #define SCATTER_STORE(pg, m, n)                                                \

  167.   result##m##n = svmul_m(pg, result##m##n, alpha_vec);                         \

  168.   result##m##n = svmla_m(pg,                                                   \

  169.                          result##m##n,                                         \

  170.                          svld1_gather_index(pg, &C_ELEMENT(m, n), ldc_vec),    \

  171.                          beta_vec);                                            \

  172.   svst1_scatter_index(pg, &C_ELEMENT(m, n), ldc_vec, result##m##n);

  173. #endif

  174. 

  175. #ifndef LIKELY

  176. #ifdef __GNUC__

  177. #define LIKELY(x) __builtin_expect(!!(x), 1)

  178. #else

  179. #define LIKELY(x) (x)

  180. #endif

  181. #endif

  182. 

  183. #ifdef B0

  184. int

  185. CNAME(BLASLONG M,

  186.       BLASLONG N,

  187.       BLASLONG K,

  188.       IFLOAT* A,

  189.       BLASLONG lda,

  190.       FLOAT alpha,

  191.       IFLOAT* B,

  192.       BLASLONG ldb,

  193.       FLOAT* C,

  194.       BLASLONG ldc)

  195. #else

  196. int

  197. CNAME(BLASLONG M,

  198.       BLASLONG N,

  199.       BLASLONG K,

  200.       IFLOAT* A,

  201.       BLASLONG lda,

  202.       FLOAT alpha,

  203.       IFLOAT* B,

  204.       BLASLONG ldb,

  205.       FLOAT beta,

  206.       FLOAT* C,

  207.       BLASLONG ldc)

  208. #endif

  209. {

  210.   const uint64_t v_size = svcntw();

  211.   const uint64_t v_size2 = v_size * 2;

  212.   const svbool_t pg_true = svptrue_b32();

  213.   const svbool_t pg_quad = svwhilelt_b32(0, 4);

  214.   const svbool_t pg_first = svwhilelt_b32(0, 1);

  215.   const svfloat32_t alpha_vec = svdup_f32(alpha);

  216. #ifndef B0

  217.   const svfloat32_t beta_vec = svdup_f32(beta);

  218. #endif

  219.   const svuint32_t lda_vec = svindex_u32(0LL, lda);

  220. 

  221.   const BLASLONG v_m2 = M & -v_size2;

  222.   const BLASLONG v_m1 = M & -v_size;

  223.   const BLASLONG n8 = N & -8;

  224.   const BLASLONG n4 = N & -4;

  225. 

  226.   const int pack_a = M >= v_size2 && N >= 8 ? 1 : 0;

  227.   FLOAT* packed_a =

  228.     (pack_a) ? packed_a = (FLOAT*)malloc(K * v_size2 * sizeof(FLOAT)) : NULL;

  229. 

  230.   FLOAT* a_offset = A;

  231.   FLOAT* b_offset = B;

  232.   FLOAT* c_offset = C;

  233. 

  234.   BLASLONG i = 0;

  235.   for (; i < v_m2; i += v_size2) {

  236. 

  237.     CREATE_C_POINTER(0, 0);

  238.     CREATE_C_POINTER(1, v_size);

  239.     CREATE_A_POINTER(0, 0);

  240.     CREATE_A_POINTER(1, v_size);

  241. 

  242.     BLASLONG j = 0;

  243.     for (; j < n8; j += 8) {

  244. 

  245.       CREATE_B_POINTER(0, 0);

  246.       CREATE_B_POINTER(1, 1);

  247.       CREATE_B_POINTER(2, 2);

  248.       CREATE_B_POINTER(3, 3);

  249.       CREATE_B_POINTER(4, 4);

  250.       CREATE_B_POINTER(5, 5);

  251.       CREATE_B_POINTER(6, 6);

  252.       CREATE_B_POINTER(7, 7);

  253.       UPDATE_B_POINTER(8);

  254. 

  255.       BLASLONG k = 0;

  256.       DECLARE_RESULT_VECTOR(0, 0);

  257.       DECLARE_RESULT_VECTOR(0, 1);

  258.       DECLARE_RESULT_VECTOR(0, 2);

  259.       DECLARE_RESULT_VECTOR(0, 3);

  260.       DECLARE_RESULT_VECTOR(0, 4);

  261.       DECLARE_RESULT_VECTOR(0, 5);

  262.       DECLARE_RESULT_VECTOR(0, 6);

  263.       DECLARE_RESULT_VECTOR(0, 7);

  264.       DECLARE_RESULT_VECTOR(1, 0);

  265.       DECLARE_RESULT_VECTOR(1, 1);

  266.       DECLARE_RESULT_VECTOR(1, 2);

  267.       DECLARE_RESULT_VECTOR(1, 3);

  268.       DECLARE_RESULT_VECTOR(1, 4);

  269.       DECLARE_RESULT_VECTOR(1, 5);

  270.       DECLARE_RESULT_VECTOR(1, 6);

  271.       DECLARE_RESULT_VECTOR(1, 7);

  272. 

  273.       if (LIKELY(packed_a != NULL)) {

  274.         if (j == 0) {

  275.           for (; k < K; k++) {

  276. 

  277.             QUADWORD_LOAD_B(0, 0);

  278.             GATHER_LOAD_A(pg_true, 0, 0);

  279.             VECTOR_PACK_A(0, 0);

  280.             UPDATE_RESULT_VECTOR_QUADWORD(0, 0, 0, 0, 0);

  281.             UPDATE_RESULT_VECTOR_QUADWORD(0, 1, 0, 1, 0);

  282.             UPDATE_RESULT_VECTOR_QUADWORD(0, 2, 0, 2, 0);

  283.             UPDATE_RESULT_VECTOR_QUADWORD(0, 3, 0, 3, 0);

  284.             QUADWORD_LOAD_B(4, 0);

  285.             UPDATE_RESULT_VECTOR_QUADWORD(0, 4, 4, 0, 0);

  286.             UPDATE_RESULT_VECTOR_QUADWORD(0, 5, 4, 1, 0);

  287.             UPDATE_RESULT_VECTOR_QUADWORD(0, 6, 4, 2, 0);

  288.             UPDATE_RESULT_VECTOR_QUADWORD(0, 7, 4, 3, 0);

  289.             GATHER_LOAD_A(pg_true, 1, 0);

  290.             VECTOR_PACK_A(1, 0);

  291.             UPDATE_RESULT_VECTOR_QUADWORD(1, 0, 0, 0, 0);

  292.             UPDATE_RESULT_VECTOR_QUADWORD(1, 1, 0, 1, 0);

  293.             UPDATE_RESULT_VECTOR_QUADWORD(1, 2, 0, 2, 0);

  294.             UPDATE_RESULT_VECTOR_QUADWORD(1, 3, 0, 3, 0);

  295.             UPDATE_RESULT_VECTOR_QUADWORD(1, 4, 4, 0, 0);

  296.             UPDATE_RESULT_VECTOR_QUADWORD(1, 5, 4, 1, 0);

  297.             UPDATE_RESULT_VECTOR_QUADWORD(1, 6, 4, 2, 0);

  298.             UPDATE_RESULT_VECTOR_QUADWORD(1, 7, 4, 3, 0);

  299.           }

  300.         } else {

  301.           for (; k < K; k++) {

  302. 

  303.             QUADWORD_LOAD_B(0, 0);

  304.             UNPACK_VECTOR_A(0, 0);

  305.             UPDATE_RESULT_VECTOR_QUADWORD(0, 0, 0, 0, 0);

  306.             UPDATE_RESULT_VECTOR_QUADWORD(0, 1, 0, 1, 0);

  307.             UPDATE_RESULT_VECTOR_QUADWORD(0, 2, 0, 2, 0);

  308.             UPDATE_RESULT_VECTOR_QUADWORD(0, 3, 0, 3, 0);

  309.             QUADWORD_LOAD_B(4, 0);

  310.             UPDATE_RESULT_VECTOR_QUADWORD(0, 4, 4, 0, 0);

  311.             UPDATE_RESULT_VECTOR_QUADWORD(0, 5, 4, 1, 0);

  312.             UPDATE_RESULT_VECTOR_QUADWORD(0, 6, 4, 2, 0);

  313.             UPDATE_RESULT_VECTOR_QUADWORD(0, 7, 4, 3, 0);

  314.             UNPACK_VECTOR_A(1, 0);

  315.             UPDATE_RESULT_VECTOR_QUADWORD(1, 0, 0, 0, 0);

  316.             UPDATE_RESULT_VECTOR_QUADWORD(1, 1, 0, 1, 0);

  317.             UPDATE_RESULT_VECTOR_QUADWORD(1, 2, 0, 2, 0);

  318.             UPDATE_RESULT_VECTOR_QUADWORD(1, 3, 0, 3, 0);

  319.             UPDATE_RESULT_VECTOR_QUADWORD(1, 4, 4, 0, 0);

  320.             UPDATE_RESULT_VECTOR_QUADWORD(1, 5, 4, 1, 0);

  321.             UPDATE_RESULT_VECTOR_QUADWORD(1, 6, 4, 2, 0);

  322.             UPDATE_RESULT_VECTOR_QUADWORD(1, 7, 4, 3, 0);

  323.           }

  324.         }

  325.       } else {

  326.         for (; k < K; k++) {

  327. 

  328.           QUADWORD_LOAD_B(0, 0);

  329.           GATHER_LOAD_A(pg_true, 0, 0);

  330.           UPDATE_RESULT_VECTOR_QUADWORD(0, 0, 0, 0, 0);

  331.           UPDATE_RESULT_VECTOR_QUADWORD(0, 1, 0, 1, 0);

  332.           UPDATE_RESULT_VECTOR_QUADWORD(0, 2, 0, 2, 0);

  333.           UPDATE_RESULT_VECTOR_QUADWORD(0, 3, 0, 3, 0);

  334.           QUADWORD_LOAD_B(4, 0);

  335.           UPDATE_RESULT_VECTOR_QUADWORD(0, 4, 4, 0, 0);

  336.           UPDATE_RESULT_VECTOR_QUADWORD(0, 5, 4, 1, 0);

  337.           UPDATE_RESULT_VECTOR_QUADWORD(0, 6, 4, 2, 0);

  338.           UPDATE_RESULT_VECTOR_QUADWORD(0, 7, 4, 3, 0);

  339.           GATHER_LOAD_A(pg_true, 1, 0);

  340.           UPDATE_RESULT_VECTOR_QUADWORD(1, 0, 0, 0, 0);

  341.           UPDATE_RESULT_VECTOR_QUADWORD(1, 1, 0, 1, 0);

  342.           UPDATE_RESULT_VECTOR_QUADWORD(1, 2, 0, 2, 0);

  343.           UPDATE_RESULT_VECTOR_QUADWORD(1, 3, 0, 3, 0);

  344.           UPDATE_RESULT_VECTOR_QUADWORD(1, 4, 4, 0, 0);

  345.           UPDATE_RESULT_VECTOR_QUADWORD(1, 5, 4, 1, 0);

  346.           UPDATE_RESULT_VECTOR_QUADWORD(1, 6, 4, 2, 0);

  347.           UPDATE_RESULT_VECTOR_QUADWORD(1, 7, 4, 3, 0);

  348.         }

  349.       }

  350.       VECTOR_STORE(pg_true, 0, 0);

  351.       VECTOR_STORE(pg_true, 0, 1);

  352.       VECTOR_STORE(pg_true, 0, 2);

  353.       VECTOR_STORE(pg_true, 0, 3);

  354.       VECTOR_STORE(pg_true, 0, 4);

  355.       VECTOR_STORE(pg_true, 0, 5);

  356.       VECTOR_STORE(pg_true, 0, 6);

  357.       VECTOR_STORE(pg_true, 0, 7);

  358.       VECTOR_STORE(pg_true, 1, 0);

  359.       VECTOR_STORE(pg_true, 1, 1);

  360.       VECTOR_STORE(pg_true, 1, 2);

  361.       VECTOR_STORE(pg_true, 1, 3);

  362.       VECTOR_STORE(pg_true, 1, 4);

  363.       VECTOR_STORE(pg_true, 1, 5);

  364.       VECTOR_STORE(pg_true, 1, 6);

  365.       VECTOR_STORE(pg_true, 1, 7);

  366.       INCR_C_POINTER(0, 8);

  367.       INCR_C_POINTER(1, 8);

  368.     }

  369.     for (; j < n4; j += 4) {

  370. 

  371.       CREATE_B_POINTER(0, 0);

  372.       CREATE_B_POINTER(1, 1);

  373.       CREATE_B_POINTER(2, 2);

  374.       CREATE_B_POINTER(3, 3);

  375.       UPDATE_B_POINTER(4);

  376. 

  377.       BLASLONG k = 0;

  378.       DECLARE_RESULT_VECTOR(0, 0);

  379.       DECLARE_RESULT_VECTOR(0, 1);

  380.       DECLARE_RESULT_VECTOR(0, 2);

  381.       DECLARE_RESULT_VECTOR(0, 3);

  382.       DECLARE_RESULT_VECTOR(1, 0);

  383.       DECLARE_RESULT_VECTOR(1, 1);

  384.       DECLARE_RESULT_VECTOR(1, 2);

  385.       DECLARE_RESULT_VECTOR(1, 3);

  386. 

  387.       if (LIKELY(packed_a != NULL)) {

  388.         for (; k < K; k++) {

  389. 

  390.           QUADWORD_LOAD_B(0, 0);

  391.           UNPACK_VECTOR_A(0, 0);

  392.           UPDATE_RESULT_VECTOR_QUADWORD(0, 0, 0, 0, 0);

  393.           UPDATE_RESULT_VECTOR_QUADWORD(0, 1, 0, 1, 0);

  394.           UPDATE_RESULT_VECTOR_QUADWORD(0, 2, 0, 2, 0);

  395.           UPDATE_RESULT_VECTOR_QUADWORD(0, 3, 0, 3, 0);

  396.           UNPACK_VECTOR_A(1, 0);

  397.           UPDATE_RESULT_VECTOR_QUADWORD(1, 0, 0, 0, 0);

  398.           UPDATE_RESULT_VECTOR_QUADWORD(1, 1, 0, 1, 0);

  399.           UPDATE_RESULT_VECTOR_QUADWORD(1, 2, 0, 2, 0);

  400.           UPDATE_RESULT_VECTOR_QUADWORD(1, 3, 0, 3, 0);

  401.         }

  402.       } else {

  403.         for (; k < K; k++) {

  404. 

  405.           QUADWORD_LOAD_B(0, 0);

  406.           GATHER_LOAD_A(pg_true, 0, 0);

  407.           UPDATE_RESULT_VECTOR_QUADWORD(0, 0, 0, 0, 0);

  408.           UPDATE_RESULT_VECTOR_QUADWORD(0, 1, 0, 1, 0);

  409.           UPDATE_RESULT_VECTOR_QUADWORD(0, 2, 0, 2, 0);

  410.           UPDATE_RESULT_VECTOR_QUADWORD(0, 3, 0, 3, 0);

  411.           GATHER_LOAD_A(pg_true, 1, 0);

  412.           UPDATE_RESULT_VECTOR_QUADWORD(1, 0, 0, 0, 0);

  413.           UPDATE_RESULT_VECTOR_QUADWORD(1, 1, 0, 1, 0);

  414.           UPDATE_RESULT_VECTOR_QUADWORD(1, 2, 0, 2, 0);

  415.           UPDATE_RESULT_VECTOR_QUADWORD(1, 3, 0, 3, 0);

  416.         }

  417.       }

  418.       VECTOR_STORE(pg_true, 0, 0);

  419.       VECTOR_STORE(pg_true, 0, 1);

  420.       VECTOR_STORE(pg_true, 0, 2);

  421.       VECTOR_STORE(pg_true, 0, 3);

  422.       VECTOR_STORE(pg_true, 1, 0);

  423.       VECTOR_STORE(pg_true, 1, 1);

  424.       VECTOR_STORE(pg_true, 1, 2);

  425.       VECTOR_STORE(pg_true, 1, 3);

  426.       INCR_C_POINTER(0, 4);

  427.       INCR_C_POINTER(1, 4);

  428.     }

  429.     for (; j < N; j++) {

  430. 

  431.       CREATE_B_POINTER(0, 0);

  432.       UPDATE_B_POINTER(1);

  433. 

  434.       BLASLONG k = 0;

  435.       DECLARE_RESULT_VECTOR(0, 0);

  436.       DECLARE_RESULT_VECTOR(1, 0);

  437. 

  438.       if (LIKELY(packed_a != NULL)) {

  439.         for (; k < K; k++) {

  440. 

  441.           BROADCAST_LOAD_B(0, 0);

  442.           UNPACK_VECTOR_A(0, 0);

  443.           UPDATE_RESULT_VECTOR(pg_true, 0, 0, 0);

  444.           UNPACK_VECTOR_A(1, 0);

  445.           UPDATE_RESULT_VECTOR(pg_true, 1, 0, 0);

  446.         }

  447.       } else {

  448.         for (; k < K; k++) {

  449. 

  450.           BROADCAST_LOAD_B(0, 0);

  451.           GATHER_LOAD_A(pg_true, 0, 0);

  452.           UPDATE_RESULT_VECTOR(pg_true, 0, 0, 0);

  453.           GATHER_LOAD_A(pg_true, 1, 0);

  454.           UPDATE_RESULT_VECTOR(pg_true, 1, 0, 0);

  455.         }

  456.       }

  457.       VECTOR_STORE(pg_true, 0, 0);

  458.       VECTOR_STORE(pg_true, 1, 0);

  459.       INCR_C_POINTER(0, 1);

  460.       INCR_C_POINTER(1, 1);

  461.     }

  462. 

  463.     UPDATE_A_POINTER(v_size2);

  464.     RESET_B_POINTER();

  465.     UPDATE_C_POINTER(v_size2);

  466.   }

  467.   for (; i < v_m1; i += v_size) {

  468. 

  469.     CREATE_C_POINTER(0, 0);

  470.     CREATE_A_POINTER(0, 0);

  471. 

  472.     BLASLONG j = 0;

  473.     for (; j < n8; j += 8) {

  474. 

  475.       CREATE_B_POINTER(0, 0);

  476.       CREATE_B_POINTER(1, 1);

  477.       CREATE_B_POINTER(2, 2);

  478.       CREATE_B_POINTER(3, 3);

  479.       CREATE_B_POINTER(4, 4);

  480.       CREATE_B_POINTER(5, 5);

  481.       CREATE_B_POINTER(6, 6);

  482.       CREATE_B_POINTER(7, 7);

  483.       UPDATE_B_POINTER(8);

  484. 

  485.       BLASLONG k = 0;

  486.       DECLARE_RESULT_VECTOR(0, 0);

  487.       DECLARE_RESULT_VECTOR(0, 1);

  488.       DECLARE_RESULT_VECTOR(0, 2);

  489.       DECLARE_RESULT_VECTOR(0, 3);

  490.       DECLARE_RESULT_VECTOR(0, 4);

  491.       DECLARE_RESULT_VECTOR(0, 5);

  492.       DECLARE_RESULT_VECTOR(0, 6);

  493.       DECLARE_RESULT_VECTOR(0, 7);

  494. 

  495.       for (; k < K; k++) {

  496. 

  497.         QUADWORD_LOAD_B(0, 0);

  498.         GATHER_LOAD_A(pg_true, 0, 0);

  499.         UPDATE_RESULT_VECTOR_QUADWORD(0, 0, 0, 0, 0);

  500.         UPDATE_RESULT_VECTOR_QUADWORD(0, 1, 0, 1, 0);

  501.         UPDATE_RESULT_VECTOR_QUADWORD(0, 2, 0, 2, 0);

  502.         UPDATE_RESULT_VECTOR_QUADWORD(0, 3, 0, 3, 0);

  503.         QUADWORD_LOAD_B(4, 0);

  504.         UPDATE_RESULT_VECTOR_QUADWORD(0, 4, 4, 0, 0);

  505.         UPDATE_RESULT_VECTOR_QUADWORD(0, 5, 4, 1, 0);

  506.         UPDATE_RESULT_VECTOR_QUADWORD(0, 6, 4, 2, 0);

  507.         UPDATE_RESULT_VECTOR_QUADWORD(0, 7, 4, 3, 0);

  508.       }

  509.       VECTOR_STORE(pg_true, 0, 0);

  510.       VECTOR_STORE(pg_true, 0, 1);

  511.       VECTOR_STORE(pg_true, 0, 2);

  512.       VECTOR_STORE(pg_true, 0, 3);

  513.       VECTOR_STORE(pg_true, 0, 4);

  514.       VECTOR_STORE(pg_true, 0, 5);

  515.       VECTOR_STORE(pg_true, 0, 6);

  516.       VECTOR_STORE(pg_true, 0, 7);

  517.       INCR_C_POINTER(0, 8);

  518.     }

  519.     for (; j < n4; j += 4) {

  520. 

  521.       CREATE_B_POINTER(0, 0);

  522.       CREATE_B_POINTER(1, 1);

  523.       CREATE_B_POINTER(2, 2);

  524.       CREATE_B_POINTER(3, 3);

  525.       UPDATE_B_POINTER(4);

  526. 

  527.       BLASLONG k = 0;

  528.       DECLARE_RESULT_VECTOR(0, 0);

  529.       DECLARE_RESULT_VECTOR(0, 1);

  530.       DECLARE_RESULT_VECTOR(0, 2);

  531.       DECLARE_RESULT_VECTOR(0, 3);

  532. 

  533.       for (; k < K; k++) {

  534. 

  535.         QUADWORD_LOAD_B(0, 0);

  536.         GATHER_LOAD_A(pg_true, 0, 0);

  537.         UPDATE_RESULT_VECTOR_QUADWORD(0, 0, 0, 0, 0);

  538.         UPDATE_RESULT_VECTOR_QUADWORD(0, 1, 0, 1, 0);

  539.         UPDATE_RESULT_VECTOR_QUADWORD(0, 2, 0, 2, 0);

  540.         UPDATE_RESULT_VECTOR_QUADWORD(0, 3, 0, 3, 0);

  541.       }

  542.       VECTOR_STORE(pg_true, 0, 0);

  543.       VECTOR_STORE(pg_true, 0, 1);

  544.       VECTOR_STORE(pg_true, 0, 2);

  545.       VECTOR_STORE(pg_true, 0, 3);

  546.       INCR_C_POINTER(0, 4);

  547.     }

  548.     for (; j < N; j++) {

  549. 

  550.       CREATE_B_POINTER(0, 0);

  551.       UPDATE_B_POINTER(1);

  552. 

  553.       BLASLONG k = 0;

  554.       DECLARE_RESULT_VECTOR(0, 0);

  555. 

  556.       for (; k < K; k++) {

  557. 

  558.         BROADCAST_LOAD_B(0, 0);

  559.         GATHER_LOAD_A(pg_true, 0, 0);

  560.         UPDATE_RESULT_VECTOR(pg_true, 0, 0, 0);

  561.       }

  562.       VECTOR_STORE(pg_true, 0, 0);

  563.       INCR_C_POINTER(0, 1);

  564.     }

  565. 

  566.     UPDATE_A_POINTER(v_size);

  567.     RESET_B_POINTER();

  568.     UPDATE_C_POINTER(v_size);

  569.   }

  570.   for (; i < M; i += v_size) {

  571.     const svbool_t pg_tail = svwhilelt_b32((uint32_t)i, (uint32_t)(M));

  572.     CREATE_C_POINTER(0, 0);

  573.     CREATE_A_POINTER(0, 0);

  574. 

  575.     BLASLONG j = 0;

  576.     for (; j < n8; j += 8) {

  577. 

  578.       CREATE_B_POINTER(0, 0);

  579.       CREATE_B_POINTER(1, 1);

  580.       CREATE_B_POINTER(2, 2);

  581.       CREATE_B_POINTER(3, 3);

  582.       CREATE_B_POINTER(4, 4);

  583.       CREATE_B_POINTER(5, 5);

  584.       CREATE_B_POINTER(6, 6);

  585.       CREATE_B_POINTER(7, 7);

  586.       UPDATE_B_POINTER(8);

  587. 

  588.       BLASLONG k = 0;

  589.       DECLARE_RESULT_VECTOR(0, 0);

  590.       DECLARE_RESULT_VECTOR(0, 1);

  591.       DECLARE_RESULT_VECTOR(0, 2);

  592.       DECLARE_RESULT_VECTOR(0, 3);

  593.       DECLARE_RESULT_VECTOR(0, 4);

  594.       DECLARE_RESULT_VECTOR(0, 5);

  595.       DECLARE_RESULT_VECTOR(0, 6);

  596.       DECLARE_RESULT_VECTOR(0, 7);

  597. 

  598.       for (; k < K; k++) {

  599. 

  600.         QUADWORD_LOAD_B(0, 0);

  601.         GATHER_LOAD_A(pg_tail, 0, 0);

  602.         UPDATE_RESULT_VECTOR_QUADWORD(0, 0, 0, 0, 0);

  603.         UPDATE_RESULT_VECTOR_QUADWORD(0, 1, 0, 1, 0);

  604.         UPDATE_RESULT_VECTOR_QUADWORD(0, 2, 0, 2, 0);

  605.         UPDATE_RESULT_VECTOR_QUADWORD(0, 3, 0, 3, 0);

  606.         QUADWORD_LOAD_B(4, 0);

  607.         UPDATE_RESULT_VECTOR_QUADWORD(0, 4, 4, 0, 0);

  608.         UPDATE_RESULT_VECTOR_QUADWORD(0, 5, 4, 1, 0);

  609.         UPDATE_RESULT_VECTOR_QUADWORD(0, 6, 4, 2, 0);

  610.         UPDATE_RESULT_VECTOR_QUADWORD(0, 7, 4, 3, 0);

  611.       }

  612.       VECTOR_STORE(pg_tail, 0, 0);

  613.       VECTOR_STORE(pg_tail, 0, 1);

  614.       VECTOR_STORE(pg_tail, 0, 2);

  615.       VECTOR_STORE(pg_tail, 0, 3);

  616.       VECTOR_STORE(pg_tail, 0, 4);

  617.       VECTOR_STORE(pg_tail, 0, 5);

  618.       VECTOR_STORE(pg_tail, 0, 6);

  619.       VECTOR_STORE(pg_tail, 0, 7);

  620.       INCR_C_POINTER(0, 8);

  621.     }

  622.     for (; j < n4; j += 4) {

  623. 

  624.       CREATE_B_POINTER(0, 0);

  625.       CREATE_B_POINTER(1, 1);

  626.       CREATE_B_POINTER(2, 2);

  627.       CREATE_B_POINTER(3, 3);

  628.       UPDATE_B_POINTER(4);

  629. 

  630.       BLASLONG k = 0;

  631.       DECLARE_RESULT_VECTOR(0, 0);

  632.       DECLARE_RESULT_VECTOR(0, 1);

  633.       DECLARE_RESULT_VECTOR(0, 2);

  634.       DECLARE_RESULT_VECTOR(0, 3);

  635. 

  636.       for (; k < K; k++) {

  637. 

  638.         QUADWORD_LOAD_B(0, 0);

  639.         GATHER_LOAD_A(pg_tail, 0, 0);

  640.         UPDATE_RESULT_VECTOR_QUADWORD(0, 0, 0, 0, 0);

  641.         UPDATE_RESULT_VECTOR_QUADWORD(0, 1, 0, 1, 0);

  642.         UPDATE_RESULT_VECTOR_QUADWORD(0, 2, 0, 2, 0);

  643.         UPDATE_RESULT_VECTOR_QUADWORD(0, 3, 0, 3, 0);

  644.       }

  645.       VECTOR_STORE(pg_tail, 0, 0);

  646.       VECTOR_STORE(pg_tail, 0, 1);

  647.       VECTOR_STORE(pg_tail, 0, 2);

  648.       VECTOR_STORE(pg_tail, 0, 3);

  649.       INCR_C_POINTER(0, 4);

  650.     }

  651.     for (; j < N; j++) {

  652. 

  653.       CREATE_B_POINTER(0, 0);

  654.       UPDATE_B_POINTER(1);

  655. 

  656.       BLASLONG k = 0;

  657.       DECLARE_RESULT_VECTOR(0, 0);

  658. 

  659.       for (; k < K; k++) {

  660. 

  661.         BROADCAST_LOAD_B(0, 0);

  662.         GATHER_LOAD_A(pg_tail, 0, 0);

  663.         UPDATE_RESULT_VECTOR(pg_tail, 0, 0, 0);

  664.       }

  665.       VECTOR_STORE(pg_tail, 0, 0);

  666.       INCR_C_POINTER(0, 1);

  667.     }

  668. 

  669.     UPDATE_A_POINTER(0);

  670.     RESET_B_POINTER();

  671.     UPDATE_C_POINTER(0);

  672.   }

  673. 

  674.   if (pack_a)

  675.     free(packed_a);

  676. 

  677.   return 0;

  678. }

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