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OpenBLAS/kernel/power/zgemv_t_4.c

zgemv_t_4.c 27 kB
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power8:Added initial zgemv_(t|n) ,i(d|z)amax,i(d|z)amin,dgemv_t(transposed),zrot z13: improved zgemv_(t|n)_4,zscal,zaxpy
7 years ago
Exclude altivec code paths if the compiler does not support them
5 years ago
power8:Added initial zgemv_(t|n) ,i(d|z)amax,i(d|z)amin,dgemv_t(transposed),zrot z13: improved zgemv_(t|n)_4,zscal,zaxpy
7 years ago
Exclude altivec code paths if the compiler does not support them
5 years ago
power8:Added initial zgemv_(t|n) ,i(d|z)amax,i(d|z)amin,dgemv_t(transposed),zrot z13: improved zgemv_(t|n)_4,zscal,zaxpy
7 years ago
sgemv cgemv pairs
6 years ago
power8:Added initial zgemv_(t|n) ,i(d|z)amax,i(d|z)amin,dgemv_t(transposed),zrot z13: improved zgemv_(t|n)_4,zscal,zaxpy
7 years ago
aligned
6 years ago
power8:Added initial zgemv_(t|n) ,i(d|z)amax,i(d|z)amin,dgemv_t(transposed),zrot z13: improved zgemv_(t|n)_4,zscal,zaxpy
7 years ago
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  1. /***************************************************************************

  2. Copyright (c) 2018, 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. #define NBMAX 4096

  31. #if defined(__VEC__) || defined(__ALTIVEC__)

  32. 

  33. #define HAVE_KERNEL_4x4_VEC 1

  34. #define HAVE_KERNEL_4x2_VEC 1

  35. #define HAVE_KERNEL_4x1_VEC 1

  36. 

  37. #endif

  38. #if defined(HAVE_KERNEL_4x4_VEC) || defined(HAVE_KERNEL_4x2_VEC) || defined(HAVE_KERNEL_4x1_VEC)

  39. #include <altivec.h> 

  40. #endif

  41. 

  42. #ifdef HAVE_KERNEL_4x4_VEC_ASM

  43. 

  44. #elif HAVE_KERNEL_4x4_VEC

  45. 

  46. static void zgemv_kernel_4x4(BLASLONG n, BLASLONG lda, FLOAT *ap, FLOAT *x, FLOAT *y, FLOAT alpha_r, FLOAT alpha_i) {

  47.     BLASLONG i;

  48.     FLOAT *a0, *a1, *a2, *a3;

  49.     a0 = ap;

  50.     a1 = ap + lda;

  51.     a2 = a1 + lda;

  52.     a3 = a2 + lda;

  53.     //p for positive(real*real,image*image) r for image (real*image,image*real)

  54.     register __vector double vtemp0_p = {0.0, 0.0};

  55.     register __vector double vtemp0_r = {0.0, 0.0};

  56.     register __vector double vtemp1_p = {0.0, 0.0};

  57.     register __vector double vtemp1_r = {0.0, 0.0};

  58.     register __vector double vtemp2_p = {0.0, 0.0};

  59.     register __vector double vtemp2_r = {0.0, 0.0};

  60.     register __vector double vtemp3_p = {0.0, 0.0};

  61.     register __vector double vtemp3_r = {0.0, 0.0};

  62.     i = 0;

  63.     n = n << 1;

  64.     while (i < n) {

  65. 

  66.         register __vector double vx_0 = *(__vector double*) (&x[i]);

  67.         register __vector double vx_1 = *(__vector double*) (&x[i + 2]);

  68.         register __vector double vx_2 = *(__vector double*) (&x[i + 4]);

  69.         register __vector double vx_3 = *(__vector double*) (&x[i + 6]);

  70. 

  71.         register __vector double va0 = *(__vector double*) (&a0[i]);

  72.         register __vector double va0_1 = *(__vector double*) (&a0[i + 2]);

  73.         register __vector double va0_2 = *(__vector double*) (&a0[i + 4]);

  74.         register __vector double va0_3 = *(__vector double*) (&a0[i + 6]);

  75. 

  76.         register __vector double va1 = *(__vector double*) (&a1[i]);

  77.         register __vector double va1_1 = *(__vector double*) (&a1[i + 2]);

  78.         register __vector double va1_2 = *(__vector double*) (&a1[i + 4]);

  79.         register __vector double va1_3 = *(__vector double*) (&a1[i + 6]);

  80. 

  81.         register __vector double va2 = *(__vector double*) (&a2[i]);

  82.         register __vector double va2_1 = *(__vector double*) (&a2[i + 2]);

  83.         register __vector double va2_2 = *(__vector double*) (&a2[i + 4]);

  84.         register __vector double va2_3 = *(__vector double*) (&a2[i + 6]);

  85. 

  86.         register __vector double va3 = *(__vector double*) (&a3[i]);

  87.         register __vector double va3_1 = *(__vector double*) (&a3[i + 2]);

  88.         register __vector double va3_2 = *(__vector double*) (&a3[i + 4]);

  89.         register __vector double va3_3 = *(__vector double*) (&a3[i + 6]);

  90. 

  91.         register __vector double vxr_0 = vec_xxpermdi(vx_0, vx_0, 2);

  92.         register __vector double vxr_1 = vec_xxpermdi(vx_1, vx_1, 2);

  93. 

  94.         i += 8;

  95. 

  96.         vtemp0_p += vx_0*va0;

  97.         vtemp0_r += vxr_0*va0;

  98. 

  99.         vtemp1_p += vx_0*va1;

  100.         vtemp1_r += vxr_0*va1;

  101. 

  102.         vtemp2_p += vx_0*va2;

  103.         vtemp2_r += vxr_0*va2;

  104. 

  105.         vtemp3_p += vx_0*va3;

  106.         vtemp3_r += vxr_0*va3;

  107. 

  108.         vtemp0_p += vx_1*va0_1;

  109.         vtemp0_r += vxr_1*va0_1;

  110. 

  111.         vtemp1_p += vx_1*va1_1;

  112.         vtemp1_r += vxr_1*va1_1;

  113.         vxr_0 = vec_xxpermdi(vx_2, vx_2, 2);

  114.         vtemp2_p += vx_1*va2_1;

  115.         vtemp2_r += vxr_1*va2_1;

  116. 

  117.         vtemp3_p += vx_1*va3_1;

  118.         vtemp3_r += vxr_1*va3_1;

  119. 

  120.         vtemp0_p += vx_2*va0_2;

  121.         vtemp0_r += vxr_0*va0_2;

  122.         vxr_1 = vec_xxpermdi(vx_3, vx_3, 2);

  123. 

  124.         vtemp1_p += vx_2*va1_2;

  125.         vtemp1_r += vxr_0*va1_2;

  126. 

  127.         vtemp2_p += vx_2*va2_2;

  128.         vtemp2_r += vxr_0*va2_2;

  129. 

  130.         vtemp3_p += vx_2*va3_2;

  131.         vtemp3_r += vxr_0*va3_2;

  132. 

  133.         vtemp0_p += vx_3*va0_3;

  134.         vtemp0_r += vxr_1*va0_3;

  135. 

  136.         vtemp1_p += vx_3*va1_3;

  137.         vtemp1_r += vxr_1*va1_3;

  138. 

  139.         vtemp2_p += vx_3*va2_3;

  140.         vtemp2_r += vxr_1*va2_3;

  141. 

  142.         vtemp3_p += vx_3*va3_3;

  143.         vtemp3_r += vxr_1*va3_3;

  144. 

  145.     }

  146. 

  147. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  148. 

  149.     register FLOAT temp_r0 = vtemp0_p[0] - vtemp0_p[1];

  150.     register FLOAT temp_i0 = vtemp0_r[0] + vtemp0_r[1];

  151. 

  152.     register FLOAT temp_r1 = vtemp1_p[0] - vtemp1_p[1];

  153.     register FLOAT temp_i1 = vtemp1_r[0] + vtemp1_r[1];

  154. 

  155.     register FLOAT temp_r2 = vtemp2_p[0] - vtemp2_p[1];

  156.     register FLOAT temp_i2 = vtemp2_r[0] + vtemp2_r[1];

  157. 

  158.     register FLOAT temp_r3 = vtemp3_p[0] - vtemp3_p[1];

  159.     register FLOAT temp_i3 = vtemp3_r[0] + vtemp3_r[1];

  160. 

  161. #else

  162.     register FLOAT temp_r0 = vtemp0_p[0] + vtemp0_p[1];

  163.     register FLOAT temp_i0 = vtemp0_r[0] - vtemp0_r[1];

  164. 

  165.     register FLOAT temp_r1 = vtemp1_p[0] + vtemp1_p[1];

  166.     register FLOAT temp_i1 = vtemp1_r[0] - vtemp1_r[1];

  167. 

  168.     register FLOAT temp_r2 = vtemp2_p[0] + vtemp2_p[1];

  169.     register FLOAT temp_i2 = vtemp2_r[0] - vtemp2_r[1];

  170. 

  171.     register FLOAT temp_r3 = vtemp3_p[0] + vtemp3_p[1];

  172.     register FLOAT temp_i3 = vtemp3_r[0] - vtemp3_r[1];

  173. 

  174. #endif    

  175. 

  176. #if !defined(XCONJ)

  177. 

  178.     y[0] += alpha_r * temp_r0 - alpha_i * temp_i0;

  179.     y[1] += alpha_r * temp_i0 + alpha_i * temp_r0;

  180.     y[2] += alpha_r * temp_r1 - alpha_i * temp_i1;

  181.     y[3] += alpha_r * temp_i1 + alpha_i * temp_r1;

  182.     y[4] += alpha_r * temp_r2 - alpha_i * temp_i2;

  183.     y[5] += alpha_r * temp_i2 + alpha_i * temp_r2;

  184.     y[6] += alpha_r * temp_r3 - alpha_i * temp_i3;

  185.     y[7] += alpha_r * temp_i3 + alpha_i * temp_r3;

  186. 

  187. #else

  188. 

  189.     y[0] += alpha_r * temp_r0 + alpha_i * temp_i0;

  190.     y[1] -= alpha_r * temp_i0 - alpha_i * temp_r0;

  191.     y[2] += alpha_r * temp_r1 + alpha_i * temp_i1;

  192.     y[3] -= alpha_r * temp_i1 - alpha_i * temp_r1;

  193.     y[4] += alpha_r * temp_r2 + alpha_i * temp_i2;

  194.     y[5] -= alpha_r * temp_i2 - alpha_i * temp_r2;

  195.     y[6] += alpha_r * temp_r3 + alpha_i * temp_i3;

  196.     y[7] -= alpha_r * temp_i3 - alpha_i * temp_r3;

  197. 

  198. #endif

  199. }

  200. 

  201. #else

  202. 

  203. static void zgemv_kernel_4x4(BLASLONG n, BLASLONG lda, FLOAT *ap, FLOAT *x, FLOAT *y, FLOAT alpha_r, FLOAT alpha_i) {

  204.     BLASLONG i;

  205.     FLOAT *a0, *a1, *a2, *a3;

  206.     a0 = ap;

  207.     a1 = ap + lda;

  208.     a2 = a1 + lda;

  209.     a3 = a2 + lda;

  210. 

  211.     FLOAT temp_r0 = 0.0;

  212.     FLOAT temp_r1 = 0.0;

  213.     FLOAT temp_r2 = 0.0;

  214.     FLOAT temp_r3 = 0.0;

  215.     FLOAT temp_i0 = 0.0;

  216.     FLOAT temp_i1 = 0.0;

  217.     FLOAT temp_i2 = 0.0;

  218.     FLOAT temp_i3 = 0.0;

  219. 

  220.     for (i = 0; i < 2 * n; i += 2) {

  221. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  222.         temp_r0 += a0[i] * x[i] - a0[i + 1] * x[i + 1];

  223.         temp_i0 += a0[i] * x[i + 1] + a0[i + 1] * x[i];

  224.         temp_r1 += a1[i] * x[i] - a1[i + 1] * x[i + 1];

  225.         temp_i1 += a1[i] * x[i + 1] + a1[i + 1] * x[i];

  226.         temp_r2 += a2[i] * x[i] - a2[i + 1] * x[i + 1];

  227.         temp_i2 += a2[i] * x[i + 1] + a2[i + 1] * x[i];

  228.         temp_r3 += a3[i] * x[i] - a3[i + 1] * x[i + 1];

  229.         temp_i3 += a3[i] * x[i + 1] + a3[i + 1] * x[i];

  230. #else

  231.         temp_r0 += a0[i] * x[i] + a0[i + 1] * x[i + 1];

  232.         temp_i0 += a0[i] * x[i + 1] - a0[i + 1] * x[i];

  233.         temp_r1 += a1[i] * x[i] + a1[i + 1] * x[i + 1];

  234.         temp_i1 += a1[i] * x[i + 1] - a1[i + 1] * x[i];

  235.         temp_r2 += a2[i] * x[i] + a2[i + 1] * x[i + 1];

  236.         temp_i2 += a2[i] * x[i + 1] - a2[i + 1] * x[i];

  237.         temp_r3 += a3[i] * x[i] + a3[i + 1] * x[i + 1];

  238.         temp_i3 += a3[i] * x[i + 1] - a3[i + 1] * x[i];

  239. #endif

  240.     }

  241. 

  242. #if !defined(XCONJ)

  243. 

  244.     y[0] += alpha_r * temp_r0 - alpha_i * temp_i0;

  245.     y[1] += alpha_r * temp_i0 + alpha_i * temp_r0;

  246.     y[2] += alpha_r * temp_r1 - alpha_i * temp_i1;

  247.     y[3] += alpha_r * temp_i1 + alpha_i * temp_r1;

  248.     y[4] += alpha_r * temp_r2 - alpha_i * temp_i2;

  249.     y[5] += alpha_r * temp_i2 + alpha_i * temp_r2;

  250.     y[6] += alpha_r * temp_r3 - alpha_i * temp_i3;

  251.     y[7] += alpha_r * temp_i3 + alpha_i * temp_r3;

  252. 

  253. #else

  254. 

  255.     y[0] += alpha_r * temp_r0 + alpha_i * temp_i0;

  256.     y[1] -= alpha_r * temp_i0 - alpha_i * temp_r0;

  257.     y[2] += alpha_r * temp_r1 + alpha_i * temp_i1;

  258.     y[3] -= alpha_r * temp_i1 - alpha_i * temp_r1;

  259.     y[4] += alpha_r * temp_r2 + alpha_i * temp_i2;

  260.     y[5] -= alpha_r * temp_i2 - alpha_i * temp_r2;

  261.     y[6] += alpha_r * temp_r3 + alpha_i * temp_i3;

  262.     y[7] -= alpha_r * temp_i3 - alpha_i * temp_r3;

  263. 

  264. #endif

  265. }

  266. 

  267. #endif

  268. 

  269. #ifdef HAVE_KERNEL_4x2_VEC

  270. 

  271. static void zgemv_kernel_4x2(BLASLONG n, BLASLONG lda, FLOAT *ap, FLOAT *x, FLOAT *y, FLOAT alpha_r, FLOAT alpha_i) {

  272.     BLASLONG i;

  273.     FLOAT *a0, *a1;

  274.     a0 = ap;

  275.     a1 = ap + lda; 

  276.     //p for positive(real*real,image*image) r for image (real*image,image*real)

  277.     register __vector double vtemp0_p = {0.0, 0.0};

  278.     register __vector double vtemp0_r = {0.0, 0.0};

  279.     register __vector double vtemp1_p = {0.0, 0.0};

  280.     register __vector double vtemp1_r = {0.0, 0.0}; 

  281.     i = 0;

  282.     n = n << 1;

  283.     while (i < n) {

  284. 

  285.         register __vector double vx_0 = *(__vector double*) (&x[i]);

  286.         register __vector double vx_1 = *(__vector double*) (&x[i + 2]);

  287.         register __vector double vx_2 = *(__vector double*) (&x[i + 4]);

  288.         register __vector double vx_3 = *(__vector double*) (&x[i + 6]);

  289. 

  290.         register __vector double va0 = *(__vector double*) (&a0[i]);

  291.         register __vector double va0_1 = *(__vector double*) (&a0[i + 2]);

  292.         register __vector double va0_2 = *(__vector double*) (&a0[i + 4]);

  293.         register __vector double va0_3 = *(__vector double*) (&a0[i + 6]);

  294. 

  295.         register __vector double va1 = *(__vector double*) (&a1[i]);

  296.         register __vector double va1_1 = *(__vector double*) (&a1[i + 2]);

  297.         register __vector double va1_2 = *(__vector double*) (&a1[i + 4]);

  298.         register __vector double va1_3 = *(__vector double*) (&a1[i + 6]);

  299. 

  300.         register __vector double vxr_0 = vec_xxpermdi(vx_0, vx_0, 2);

  301.         register __vector double vxr_1 = vec_xxpermdi(vx_1, vx_1, 2);

  302. 

  303.         i += 8;

  304. 

  305.         vtemp0_p += vx_0*va0;

  306.         vtemp0_r += vxr_0*va0;

  307. 

  308.         vtemp1_p += vx_0*va1;

  309.         vtemp1_r += vxr_0*va1;

  310. 

  311.         vxr_0 = vec_xxpermdi(vx_2, vx_2, 2);  

  312.         vtemp0_p += vx_1*va0_1;

  313.         vtemp0_r += vxr_1*va0_1;

  314. 

  315.         vtemp1_p += vx_1*va1_1;

  316.         vtemp1_r += vxr_1*va1_1;

  317.         vxr_1 = vec_xxpermdi(vx_3, vx_3, 2);

  318. 

  319.         vtemp0_p += vx_2*va0_2;

  320.         vtemp0_r += vxr_0*va0_2;

  321. 

  322.         vtemp1_p += vx_2*va1_2;

  323.         vtemp1_r += vxr_0*va1_2;

  324. 

  325.         vtemp0_p += vx_3*va0_3;

  326.         vtemp0_r += vxr_1*va0_3;

  327. 

  328.         vtemp1_p += vx_3*va1_3;

  329.         vtemp1_r += vxr_1*va1_3;

  330.  

  331.     }

  332. 

  333. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  334.     register FLOAT temp_r0 = vtemp0_p[0] - vtemp0_p[1];

  335.     register FLOAT temp_i0 = vtemp0_r[0] + vtemp0_r[1];

  336. 

  337.     register FLOAT temp_r1 = vtemp1_p[0] - vtemp1_p[1];

  338.     register FLOAT temp_i1 = vtemp1_r[0] + vtemp1_r[1]; 

  339. 

  340. #else

  341.     register FLOAT temp_r0 = vtemp0_p[0] + vtemp0_p[1];

  342.     register FLOAT temp_i0 = vtemp0_r[0] - vtemp0_r[1];

  343. 

  344.     register FLOAT temp_r1 = vtemp1_p[0] + vtemp1_p[1];

  345.     register FLOAT temp_i1 = vtemp1_r[0] - vtemp1_r[1];

  346. 

  347. #endif    

  348. 

  349. #if !defined(XCONJ)

  350. 

  351.     y[0] += alpha_r * temp_r0 - alpha_i * temp_i0;

  352.     y[1] += alpha_r * temp_i0 + alpha_i * temp_r0;

  353.     y[2] += alpha_r * temp_r1 - alpha_i * temp_i1;

  354.     y[3] += alpha_r * temp_i1 + alpha_i * temp_r1;

  355. 

  356. #else

  357. 

  358.     y[0] += alpha_r * temp_r0 + alpha_i * temp_i0;

  359.     y[1] -= alpha_r * temp_i0 - alpha_i * temp_r0;

  360.     y[2] += alpha_r * temp_r1 + alpha_i * temp_i1;

  361.     y[3] -= alpha_r * temp_i1 - alpha_i * temp_r1;

  362. 

  363. #endif

  364. }

  365. 

  366. #else

  367. 

  368. static void zgemv_kernel_4x2(BLASLONG n, BLASLONG lda, FLOAT *ap, FLOAT *x, FLOAT *y, FLOAT alpha_r, FLOAT alpha_i) {

  369.     BLASLONG i;

  370.     FLOAT *a0, *a1;

  371.     a0 = ap;

  372.     a1 = ap + lda;

  373. 

  374.     FLOAT temp_r0 = 0.0;

  375.     FLOAT temp_r1 = 0.0;

  376.     FLOAT temp_i0 = 0.0;

  377.     FLOAT temp_i1 = 0.0;

  378. 

  379.     for (i = 0; i < 2 * n; i += 2) {

  380. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  381.         temp_r0 += a0[i] * x[i] - a0[i + 1] * x[i + 1];

  382.         temp_i0 += a0[i] * x[i + 1] + a0[i + 1] * x[i];

  383.         temp_r1 += a1[i] * x[i] - a1[i + 1] * x[i + 1];

  384.         temp_i1 += a1[i] * x[i + 1] + a1[i + 1] * x[i];

  385. #else

  386.         temp_r0 += a0[i] * x[i] + a0[i + 1] * x[i + 1];

  387.         temp_i0 += a0[i] * x[i + 1] - a0[i + 1] * x[i];

  388.         temp_r1 += a1[i] * x[i] + a1[i + 1] * x[i + 1];

  389.         temp_i1 += a1[i] * x[i + 1] - a1[i + 1] * x[i];

  390. #endif

  391.     }

  392. 

  393. #if !defined(XCONJ)

  394. 

  395.     y[0] += alpha_r * temp_r0 - alpha_i * temp_i0;

  396.     y[1] += alpha_r * temp_i0 + alpha_i * temp_r0;

  397.     y[2] += alpha_r * temp_r1 - alpha_i * temp_i1;

  398.     y[3] += alpha_r * temp_i1 + alpha_i * temp_r1;

  399. 

  400. #else

  401. 

  402.     y[0] += alpha_r * temp_r0 + alpha_i * temp_i0;

  403.     y[1] -= alpha_r * temp_i0 - alpha_i * temp_r0;

  404.     y[2] += alpha_r * temp_r1 + alpha_i * temp_i1;

  405.     y[3] -= alpha_r * temp_i1 - alpha_i * temp_r1;

  406. 

  407. #endif

  408. }

  409. 

  410. #endif

  411. 

  412. #ifdef HAVE_KERNEL_4x1_VEC

  413. 

  414. static void zgemv_kernel_4x1(BLASLONG n, FLOAT *ap, FLOAT *x, FLOAT *y, FLOAT alpha_r, FLOAT alpha_i) {

  415.     BLASLONG i;

  416.     FLOAT *a0 ;

  417.     a0 = ap;  

  418.     //p for positive(real*real,image*image) r for image (real*image,image*real)

  419.     register __vector double vtemp0_p = {0.0, 0.0};

  420.     register __vector double vtemp0_r = {0.0, 0.0};

  421.     i = 0;

  422.     n = n << 1;

  423.     while (i < n) {

  424. 

  425.         register __vector double vx_0 = *(__vector double*) (&x[i]);

  426.         register __vector double vx_1 = *(__vector double*) (&x[i + 2]);

  427.         register __vector double vx_2 = *(__vector double*) (&x[i + 4]);

  428.         register __vector double vx_3 = *(__vector double*) (&x[i + 6]);

  429. 

  430.         register __vector double va0 = *(__vector double*) (&a0[i]);

  431.         register __vector double va0_1 = *(__vector double*) (&a0[i + 2]);

  432.         register __vector double va0_2 = *(__vector double*) (&a0[i + 4]);

  433.         register __vector double va0_3 = *(__vector double*) (&a0[i + 6]);

  434.        

  435.         register __vector double vxr_0 = vec_xxpermdi(vx_0, vx_0, 2);

  436.         register __vector double vxr_1 = vec_xxpermdi(vx_1, vx_1, 2);

  437. 

  438.         i += 8;

  439. 

  440.         vtemp0_p += vx_0*va0;

  441.         vtemp0_r += vxr_0*va0;

  442.  

  443.         vxr_0 = vec_xxpermdi(vx_2, vx_2, 2);  

  444.         vtemp0_p += vx_1*va0_1;

  445.         vtemp0_r += vxr_1*va0_1;

  446.  

  447.         vxr_1 = vec_xxpermdi(vx_3, vx_3, 2);

  448. 

  449.         vtemp0_p += vx_2*va0_2;

  450.         vtemp0_r += vxr_0*va0_2;

  451.  

  452.         vtemp0_p += vx_3*va0_3;

  453.         vtemp0_r += vxr_1*va0_3;

  454.  

  455.     }

  456. 

  457. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  458.     register FLOAT temp_r0 = vtemp0_p[0] - vtemp0_p[1];

  459.     register FLOAT temp_i0 = vtemp0_r[0] + vtemp0_r[1];

  460. 

  461. #else

  462.     register FLOAT temp_r0 = vtemp0_p[0] + vtemp0_p[1];

  463.     register FLOAT temp_i0 = vtemp0_r[0] - vtemp0_r[1]; 

  464. 

  465. #endif    

  466. 

  467. #if !defined(XCONJ)

  468. 

  469.     y[0] += alpha_r * temp_r0 - alpha_i * temp_i0;

  470.     y[1] += alpha_r * temp_i0 + alpha_i * temp_r0; 

  471. 

  472. #else

  473. 

  474.     y[0] += alpha_r * temp_r0 + alpha_i * temp_i0;

  475.     y[1] -= alpha_r * temp_i0 - alpha_i * temp_r0; 

  476. #endif

  477. 

  478. }

  479. 

  480. #else

  481. 

  482. static void zgemv_kernel_4x1(BLASLONG n, FLOAT *ap, FLOAT *x, FLOAT *y, FLOAT alpha_r, FLOAT alpha_i) {

  483.     BLASLONG i;

  484.     FLOAT *a0;

  485.     a0 = ap;

  486. 

  487.     FLOAT temp_r0 = 0.0;

  488.     FLOAT temp_i0 = 0.0;

  489. 

  490.     for (i = 0; i < 2 * n; i += 2) {

  491. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  492.         temp_r0 += a0[i] * x[i] - a0[i + 1] * x[i + 1];

  493.         temp_i0 += a0[i] * x[i + 1] + a0[i + 1] * x[i];

  494. #else

  495.         temp_r0 += a0[i] * x[i] + a0[i + 1] * x[i + 1];

  496.         temp_i0 += a0[i] * x[i + 1] - a0[i + 1] * x[i];

  497. #endif

  498.     }

  499. 

  500. #if !defined(XCONJ)

  501. 

  502.     y[0] += alpha_r * temp_r0 - alpha_i * temp_i0;

  503.     y[1] += alpha_r * temp_i0 + alpha_i * temp_r0;

  504. 

  505. #else

  506. 

  507.     y[0] += alpha_r * temp_r0 + alpha_i * temp_i0;

  508.     y[1] -= alpha_r * temp_i0 - alpha_i * temp_r0;

  509. 

  510. #endif

  511. 

  512. }

  513. 

  514. #endif

  515. 

  516. static __attribute__((always_inline)) void copy_x(BLASLONG n, FLOAT *src, FLOAT *dest, BLASLONG inc_src) {

  517.     BLASLONG i;

  518.     for (i = 0; i < n; i++) {

  519.         *dest = *src;

  520.         *(dest + 1) = *(src + 1);

  521.         dest += 2;

  522.         src += inc_src;

  523.     }

  524. }

  525. 

  526. int CNAME(BLASLONG m, BLASLONG n, BLASLONG dummy1, FLOAT alpha_r, FLOAT alpha_i, FLOAT *a, BLASLONG lda, FLOAT *x, BLASLONG inc_x, FLOAT *y, BLASLONG inc_y, FLOAT *buffer) {

  527.     BLASLONG i;

  528.     BLASLONG j;

  529.     FLOAT *a_ptr;

  530.     FLOAT *x_ptr;

  531.     FLOAT *y_ptr;

  532. 

  533.     BLASLONG n1;

  534.     BLASLONG m1;

  535.     BLASLONG m2;

  536.     BLASLONG m3;

  537.     BLASLONG n2;

  538.     FLOAT ybuffer[8] __attribute__((aligned(16)));

  539.     FLOAT *xbuffer;

  540. 

  541.     if (m < 1) return (0);

  542.     if (n < 1) return (0);

  543. 

  544.     inc_x <<= 1;

  545.     inc_y <<= 1;

  546.     lda <<= 1;

  547. 

  548.     xbuffer = buffer;

  549. 

  550.     n1 = n >> 2;

  551.     n2 = n & 3;

  552. 

  553.     m3 = m & 3;

  554.     m1 = m - m3;

  555.     m2 = (m & (NBMAX - 1)) - m3;

  556. 

  557.     BLASLONG NB = NBMAX;

  558. 

  559.     while (NB == NBMAX) {

  560. 

  561.         m1 -= NB;

  562.         if (m1 < 0) {

  563.             if (m2 == 0) break;

  564.             NB = m2;

  565.         }

  566. 

  567.         y_ptr = y;

  568.         a_ptr = a;

  569.         x_ptr = x;

  570. 

  571.         if (inc_x != 2)

  572.             copy_x(NB, x_ptr, xbuffer, inc_x);

  573.         else

  574.             xbuffer = x_ptr;

  575. 

  576.         if (inc_y == 2) {

  577. 

  578.             for (i = 0; i < n1; i++) {

  579.                 zgemv_kernel_4x4(NB, lda, a_ptr, xbuffer, y_ptr, alpha_r, alpha_i);

  580.                 a_ptr += lda << 2;

  581.                 y_ptr += 8;

  582. 

  583.             }

  584. 

  585.             if (n2 & 2) {

  586.                 zgemv_kernel_4x2(NB, lda, a_ptr, xbuffer, y_ptr, alpha_r, alpha_i);

  587.                 a_ptr += lda << 1;

  588.                 y_ptr += 4;

  589. 

  590.             }

  591. 

  592.             if (n2 & 1) {

  593.                 zgemv_kernel_4x1(NB, a_ptr, xbuffer, y_ptr, alpha_r, alpha_i);

  594.                 a_ptr += lda;

  595.                 y_ptr += 2;

  596. 

  597.             }

  598. 

  599.         } else {

  600. 

  601.             for (i = 0; i < n1; i++) {

  602.                 memset(ybuffer, 0, sizeof (ybuffer));

  603.                 zgemv_kernel_4x4(NB, lda, a_ptr, xbuffer, ybuffer, alpha_r, alpha_i);

  604. 

  605.                 a_ptr += lda << 2;

  606. 

  607.                 y_ptr[0] += ybuffer[0];

  608.                 y_ptr[1] += ybuffer[1];

  609.                 y_ptr += inc_y;

  610.                 y_ptr[0] += ybuffer[2];

  611.                 y_ptr[1] += ybuffer[3];

  612.                 y_ptr += inc_y;

  613.                 y_ptr[0] += ybuffer[4];

  614.                 y_ptr[1] += ybuffer[5];

  615.                 y_ptr += inc_y;

  616.                 y_ptr[0] += ybuffer[6];

  617.                 y_ptr[1] += ybuffer[7];

  618.                 y_ptr += inc_y;

  619. 

  620.             }

  621. 

  622.             for (i = 0; i < n2; i++) {

  623.                 memset(ybuffer, 0, sizeof (ybuffer));

  624.                 zgemv_kernel_4x1(NB, a_ptr, xbuffer, ybuffer, alpha_r, alpha_i);

  625.                 a_ptr += lda;

  626.                 y_ptr[0] += ybuffer[0];

  627.                 y_ptr[1] += ybuffer[1];

  628.                 y_ptr += inc_y;

  629. 

  630.             }

  631. 

  632.         }

  633.         a += 2 * NB;

  634.         x += NB * inc_x;

  635.     }

  636. 

  637.     if (m3 == 0) return (0);

  638. 

  639.     x_ptr = x;

  640.     j = 0;

  641.     a_ptr = a;

  642.     y_ptr = y;

  643. 

  644.     if (m3 == 3) {

  645. 

  646.         FLOAT temp_r;

  647.         FLOAT temp_i;

  648.         FLOAT x0 = x_ptr[0];

  649.         FLOAT x1 = x_ptr[1];

  650.         x_ptr += inc_x;

  651.         FLOAT x2 = x_ptr[0];

  652.         FLOAT x3 = x_ptr[1];

  653.         x_ptr += inc_x;

  654.         FLOAT x4 = x_ptr[0];

  655.         FLOAT x5 = x_ptr[1];

  656.         while (j < n) {

  657. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  658.             temp_r = a_ptr[0] * x0 - a_ptr[1] * x1;

  659.             temp_i = a_ptr[0] * x1 + a_ptr[1] * x0;

  660.             temp_r += a_ptr[2] * x2 - a_ptr[3] * x3;

  661.             temp_i += a_ptr[2] * x3 + a_ptr[3] * x2;

  662.             temp_r += a_ptr[4] * x4 - a_ptr[5] * x5;

  663.             temp_i += a_ptr[4] * x5 + a_ptr[5] * x4;

  664. #else

  665. 

  666.             temp_r = a_ptr[0] * x0 + a_ptr[1] * x1;

  667.             temp_i = a_ptr[0] * x1 - a_ptr[1] * x0;

  668.             temp_r += a_ptr[2] * x2 + a_ptr[3] * x3;

  669.             temp_i += a_ptr[2] * x3 - a_ptr[3] * x2;

  670.             temp_r += a_ptr[4] * x4 + a_ptr[5] * x5;

  671.             temp_i += a_ptr[4] * x5 - a_ptr[5] * x4;

  672. #endif

  673. 

  674. #if !defined(XCONJ) 

  675.             y_ptr[0] += alpha_r * temp_r - alpha_i * temp_i;

  676.             y_ptr[1] += alpha_r * temp_i + alpha_i * temp_r;

  677. #else

  678.             y_ptr[0] += alpha_r * temp_r + alpha_i * temp_i;

  679.             y_ptr[1] -= alpha_r * temp_i - alpha_i * temp_r;

  680. #endif

  681. 

  682.             a_ptr += lda;

  683.             y_ptr += inc_y;

  684.             j++;

  685.         }

  686.         return (0);

  687.     }

  688. 

  689.     if (m3 == 2) {

  690. 

  691.         FLOAT temp_r;

  692.         FLOAT temp_i;

  693.         FLOAT temp_r1;

  694.         FLOAT temp_i1;

  695.         FLOAT x0 = x_ptr[0];

  696.         FLOAT x1 = x_ptr[1];

  697.         x_ptr += inc_x;

  698.         FLOAT x2 = x_ptr[0];

  699.         FLOAT x3 = x_ptr[1];

  700. 

  701.         while (j < (n & -2)) {

  702. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  703.             temp_r = a_ptr[0] * x0 - a_ptr[1] * x1;

  704.             temp_i = a_ptr[0] * x1 + a_ptr[1] * x0;

  705.             temp_r += a_ptr[2] * x2 - a_ptr[3] * x3;

  706.             temp_i += a_ptr[2] * x3 + a_ptr[3] * x2;

  707.             a_ptr += lda;

  708.             temp_r1 = a_ptr[0] * x0 - a_ptr[1] * x1;

  709.             temp_i1 = a_ptr[0] * x1 + a_ptr[1] * x0;

  710.             temp_r1 += a_ptr[2] * x2 - a_ptr[3] * x3;

  711.             temp_i1 += a_ptr[2] * x3 + a_ptr[3] * x2;

  712. #else

  713. 

  714.             temp_r = a_ptr[0] * x0 + a_ptr[1] * x1;

  715.             temp_i = a_ptr[0] * x1 - a_ptr[1] * x0;

  716.             temp_r += a_ptr[2] * x2 + a_ptr[3] * x3;

  717.             temp_i += a_ptr[2] * x3 - a_ptr[3] * x2;

  718.             a_ptr += lda;

  719.             temp_r1 = a_ptr[0] * x0 + a_ptr[1] * x1;

  720.             temp_i1 = a_ptr[0] * x1 - a_ptr[1] * x0;

  721.             temp_r1 += a_ptr[2] * x2 + a_ptr[3] * x3;

  722.             temp_i1 += a_ptr[2] * x3 - a_ptr[3] * x2;

  723. #endif

  724. 

  725. #if !defined(XCONJ) 

  726.             y_ptr[0] += alpha_r * temp_r - alpha_i * temp_i;

  727.             y_ptr[1] += alpha_r * temp_i + alpha_i * temp_r;

  728.             y_ptr += inc_y;

  729.             y_ptr[0] += alpha_r * temp_r1 - alpha_i * temp_i1;

  730.             y_ptr[1] += alpha_r * temp_i1 + alpha_i * temp_r1;

  731. #else

  732.             y_ptr[0] += alpha_r * temp_r + alpha_i * temp_i;

  733.             y_ptr[1] -= alpha_r * temp_i - alpha_i * temp_r;

  734.             y_ptr += inc_y;

  735.             y_ptr[0] += alpha_r * temp_r1 + alpha_i * temp_i1;

  736.             y_ptr[1] -= alpha_r * temp_i1 - alpha_i * temp_r1;

  737. #endif

  738. 

  739.             a_ptr += lda;

  740.             y_ptr += inc_y;

  741.             j += 2;

  742.         }

  743. 

  744.         while (j < n) {

  745. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  746.             temp_r = a_ptr[0] * x0 - a_ptr[1] * x1;

  747.             temp_i = a_ptr[0] * x1 + a_ptr[1] * x0;

  748.             temp_r += a_ptr[2] * x2 - a_ptr[3] * x3;

  749.             temp_i += a_ptr[2] * x3 + a_ptr[3] * x2;

  750. #else

  751. 

  752.             temp_r = a_ptr[0] * x0 + a_ptr[1] * x1;

  753.             temp_i = a_ptr[0] * x1 - a_ptr[1] * x0;

  754.             temp_r += a_ptr[2] * x2 + a_ptr[3] * x3;

  755.             temp_i += a_ptr[2] * x3 - a_ptr[3] * x2;

  756. #endif

  757. 

  758. #if !defined(XCONJ) 

  759.             y_ptr[0] += alpha_r * temp_r - alpha_i * temp_i;

  760.             y_ptr[1] += alpha_r * temp_i + alpha_i * temp_r;

  761. #else

  762.             y_ptr[0] += alpha_r * temp_r + alpha_i * temp_i;

  763.             y_ptr[1] -= alpha_r * temp_i - alpha_i * temp_r;

  764. #endif

  765. 

  766.             a_ptr += lda;

  767.             y_ptr += inc_y;

  768.             j++;

  769.         }

  770. 

  771.         return (0);

  772.     }

  773. 

  774.     if (m3 == 1) {

  775. 

  776.         FLOAT temp_r;

  777.         FLOAT temp_i;

  778.         FLOAT temp_r1;

  779.         FLOAT temp_i1;

  780.         FLOAT x0 = x_ptr[0];

  781.         FLOAT x1 = x_ptr[1];

  782. 

  783.         while (j < (n & -2)) {

  784. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  785.             temp_r = a_ptr[0] * x0 - a_ptr[1] * x1;

  786.             temp_i = a_ptr[0] * x1 + a_ptr[1] * x0;

  787.             a_ptr += lda;

  788.             temp_r1 = a_ptr[0] * x0 - a_ptr[1] * x1;

  789.             temp_i1 = a_ptr[0] * x1 + a_ptr[1] * x0;

  790. #else

  791. 

  792.             temp_r = a_ptr[0] * x0 + a_ptr[1] * x1;

  793.             temp_i = a_ptr[0] * x1 - a_ptr[1] * x0;

  794.             a_ptr += lda;

  795.             temp_r1 = a_ptr[0] * x0 + a_ptr[1] * x1;

  796.             temp_i1 = a_ptr[0] * x1 - a_ptr[1] * x0;

  797. #endif

  798. 

  799. #if !defined(XCONJ) 

  800.             y_ptr[0] += alpha_r * temp_r - alpha_i * temp_i;

  801.             y_ptr[1] += alpha_r * temp_i + alpha_i * temp_r;

  802.             y_ptr += inc_y;

  803.             y_ptr[0] += alpha_r * temp_r1 - alpha_i * temp_i1;

  804.             y_ptr[1] += alpha_r * temp_i1 + alpha_i * temp_r1;

  805. #else

  806.             y_ptr[0] += alpha_r * temp_r + alpha_i * temp_i;

  807.             y_ptr[1] -= alpha_r * temp_i - alpha_i * temp_r;

  808.             y_ptr += inc_y;

  809.             y_ptr[0] += alpha_r * temp_r1 + alpha_i * temp_i1;

  810.             y_ptr[1] -= alpha_r * temp_i1 - alpha_i * temp_r1;

  811. #endif

  812. 

  813.             a_ptr += lda;

  814.             y_ptr += inc_y;

  815.             j += 2;

  816.         }

  817. 

  818.         while (j < n) {

  819. #if ( !defined(CONJ) && !defined(XCONJ) ) || ( defined(CONJ) && defined(XCONJ) )

  820.             temp_r = a_ptr[0] * x0 - a_ptr[1] * x1;

  821.             temp_i = a_ptr[0] * x1 + a_ptr[1] * x0;

  822. #else

  823. 

  824.             temp_r = a_ptr[0] * x0 + a_ptr[1] * x1;

  825.             temp_i = a_ptr[0] * x1 - a_ptr[1] * x0;

  826. #endif

  827. 

  828. #if !defined(XCONJ) 

  829.             y_ptr[0] += alpha_r * temp_r - alpha_i * temp_i;

  830.             y_ptr[1] += alpha_r * temp_i + alpha_i * temp_r;

  831. #else

  832.             y_ptr[0] += alpha_r * temp_r + alpha_i * temp_i;

  833.             y_ptr[1] -= alpha_r * temp_i - alpha_i * temp_r;

  834. #endif

  835. 

  836.             a_ptr += lda;

  837.             y_ptr += inc_y;

  838.             j++;

  839.         }

  840.         return (0);

  841.     }

  842. 

  843.     return (0);

  844. 

  845. }

  846.

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