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Merge pull request #4996 from iha-taisei/sdgemv_sve_unroll
Loop-unrolled transposed [SD]GEMV kernels for A64FX and Neoverse V1tags/v0.3.29
Martin Kroeker
GitHub
10 months ago
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GPG Key ID: B5690EEEBB952194
4 changed files with 390 additions and 4 deletions
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+2 -2kernel/arm64/KERNEL.A64FX
-
+2 -2kernel/arm64/KERNEL.NEOVERSEV1
-
+152 -0kernel/arm64/gemv_t_sve_v1x3.c
-
+234 -0kernel/arm64/gemv_t_sve_v4x3.c
+ 2
- 2
kernel/arm64/KERNEL.A64FX
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| @@ -2,5 +2,5 @@ include $(KERNELDIR)/KERNEL.ARMV8SVE | |||
| SGEMVNKERNEL = gemv_n_sve.c | |||
| DGEMVNKERNEL = gemv_n_sve.c | |||
| SGEMVTKERNEL = gemv_t_sve.c | |||
| DGEMVTKERNEL = gemv_t_sve.c | |||
| SGEMVTKERNEL = gemv_t_sve_v4x3.c | |||
| DGEMVTKERNEL = gemv_t_sve_v4x3.c | |||
+ 2
- 2
kernel/arm64/KERNEL.NEOVERSEV1
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| @@ -1,4 +1,4 @@ | |||
| include $(KERNELDIR)/KERNEL.ARMV8SVE | |||
| SGEMVTKERNEL = gemv_t_sve.c | |||
| DGEMVTKERNEL = gemv_t_sve.c | |||
| SGEMVTKERNEL = gemv_t_sve_v1x3.c | |||
| DGEMVTKERNEL = gemv_t_sve_v1x3.c | |||
+ 152
- 0
kernel/arm64/gemv_t_sve_v1x3.c
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| @@ -0,0 +1,152 @@ | |||
| /*************************************************************************** | |||
| Copyright (c) 2024, The OpenBLAS Project | |||
| All rights reserved. | |||
| Redistribution and use in source and binary forms, with or without | |||
| modification, are permitted provided that the following conditions are | |||
| met: | |||
| 1. Redistributions of source code must retain the above copyright | |||
| notice, this list of conditions and the following disclaimer. | |||
| 2. Redistributions in binary form must reproduce the above copyright | |||
| notice, this list of conditions and the following disclaimer in | |||
| the documentation and/or other materials provided with the | |||
| distribution. | |||
| 3. Neither the name of the OpenBLAS project nor the names of | |||
| its contributors may be used to endorse or promote products | |||
| derived from this software without specific prior written | |||
| permission. | |||
| THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" | |||
| AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE | |||
| IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE | |||
| ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE | |||
| LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL | |||
| DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR | |||
| SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER | |||
| CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, | |||
| OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE | |||
| USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. | |||
| *****************************************************************************/ | |||
| #include <arm_sve.h> | |||
| #include "common.h" | |||
| #ifdef DOUBLE | |||
| #define SV_COUNT svcntd | |||
| #define SV_TYPE svfloat64_t | |||
| #define SV_TRUE svptrue_b64 | |||
| #define SV_WHILE svwhilelt_b64_s64 | |||
| #define SV_DUP svdup_f64 | |||
| #else | |||
| #define SV_COUNT svcntw | |||
| #define SV_TYPE svfloat32_t | |||
| #define SV_TRUE svptrue_b32 | |||
| #define SV_WHILE svwhilelt_b32_s64 | |||
| #define SV_DUP svdup_f32 | |||
| #endif | |||
| int CNAME(BLASLONG m, BLASLONG n, BLASLONG dummy1, FLOAT alpha, FLOAT *a, | |||
| BLASLONG lda, FLOAT *x, BLASLONG inc_x, FLOAT *y, BLASLONG inc_y, | |||
| FLOAT *buffer) | |||
| { | |||
| BLASLONG i; | |||
| BLASLONG ix,iy; | |||
| BLASLONG j; | |||
| FLOAT *a_ptr; | |||
| FLOAT temp; | |||
| iy = 0; | |||
| if (inc_x == 1) { | |||
| BLASLONG width = (n + 3 - 1) / 3; | |||
| FLOAT *a0_ptr = a + lda * width * 0; | |||
| FLOAT *a1_ptr = a + lda * width * 1; | |||
| FLOAT *a2_ptr = a + lda * width * 2; | |||
| FLOAT *y0_ptr = y + inc_y * width * 0; | |||
| FLOAT *y1_ptr = y + inc_y * width * 1; | |||
| FLOAT *y2_ptr = y + inc_y * width * 2; | |||
| for (j = 0; j < width; j++) { | |||
| svbool_t pg00 = ((j + width * 0) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg01 = ((j + width * 1) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg02 = ((j + width * 2) < n) ? SV_TRUE() : svpfalse(); | |||
| SV_TYPE temp00_vec = SV_DUP(0.0); | |||
| SV_TYPE temp01_vec = SV_DUP(0.0); | |||
| SV_TYPE temp02_vec = SV_DUP(0.0); | |||
| i = 0; | |||
| BLASLONG sve_size = SV_COUNT(); | |||
| while ((i + sve_size * 1 - 1) < m) { | |||
| SV_TYPE x0_vec = svld1_vnum(SV_TRUE(), x + i, 0); | |||
| SV_TYPE a00_vec = svld1_vnum(pg00, a0_ptr + i, 0); | |||
| SV_TYPE a01_vec = svld1_vnum(pg01, a1_ptr + i, 0); | |||
| SV_TYPE a02_vec = svld1_vnum(pg02, a2_ptr + i, 0); | |||
| temp00_vec = svmla_m(pg00, temp00_vec, a00_vec, x0_vec); | |||
| temp01_vec = svmla_m(pg01, temp01_vec, a01_vec, x0_vec); | |||
| temp02_vec = svmla_m(pg02, temp02_vec, a02_vec, x0_vec); | |||
| i += sve_size * 1; | |||
| } | |||
| if (i < m) { | |||
| svbool_t pg0 = SV_WHILE(i + sve_size * 0, m); | |||
| pg00 = svand_z(SV_TRUE(), pg0, pg00); | |||
| pg01 = svand_z(SV_TRUE(), pg0, pg01); | |||
| pg02 = svand_z(SV_TRUE(), pg0, pg02); | |||
| SV_TYPE x0_vec = svld1_vnum(pg0, x + i, 0); | |||
| SV_TYPE a00_vec = svld1_vnum(pg00, a0_ptr + i, 0); | |||
| SV_TYPE a01_vec = svld1_vnum(pg01, a1_ptr + i, 0); | |||
| SV_TYPE a02_vec = svld1_vnum(pg02, a2_ptr + i, 0); | |||
| temp00_vec = svmla_m(pg00, temp00_vec, a00_vec, x0_vec); | |||
| temp01_vec = svmla_m(pg01, temp01_vec, a01_vec, x0_vec); | |||
| temp02_vec = svmla_m(pg02, temp02_vec, a02_vec, x0_vec); | |||
| } | |||
| if ((j + width * 0) < n) { | |||
| temp = svaddv(SV_TRUE(), temp00_vec); | |||
| y0_ptr[iy] += alpha * temp; | |||
| } | |||
| if ((j + width * 1) < n) { | |||
| temp = svaddv(SV_TRUE(), temp01_vec); | |||
| y1_ptr[iy] += alpha * temp; | |||
| } | |||
| if ((j + width * 2) < n) { | |||
| temp = svaddv(SV_TRUE(), temp02_vec); | |||
| y2_ptr[iy] += alpha * temp; | |||
| } | |||
| iy += inc_y; | |||
| a0_ptr += lda; | |||
| a1_ptr += lda; | |||
| a2_ptr += lda; | |||
| } | |||
| return(0); | |||
| } | |||
| a_ptr = a; | |||
| for (j = 0; j < n; j++) { | |||
| temp = 0.0; | |||
| ix = 0; | |||
| for (i = 0; i < m; i++) { | |||
| temp += a_ptr[i] * x[ix]; | |||
| ix += inc_x; | |||
| } | |||
| y[iy] += alpha * temp; | |||
| iy += inc_y; | |||
| a_ptr += lda; | |||
| } | |||
| return(0); | |||
| } | |||
+ 234
- 0
kernel/arm64/gemv_t_sve_v4x3.c
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| @@ -0,0 +1,234 @@ | |||
| /*************************************************************************** | |||
| Copyright (c) 2024, The OpenBLAS Project | |||
| All rights reserved. | |||
| Redistribution and use in source and binary forms, with or without | |||
| modification, are permitted provided that the following conditions are | |||
| met: | |||
| 1. Redistributions of source code must retain the above copyright | |||
| notice, this list of conditions and the following disclaimer. | |||
| 2. Redistributions in binary form must reproduce the above copyright | |||
| notice, this list of conditions and the following disclaimer in | |||
| the documentation and/or other materials provided with the | |||
| distribution. | |||
| 3. Neither the name of the OpenBLAS project nor the names of | |||
| its contributors may be used to endorse or promote products | |||
| derived from this software without specific prior written | |||
| permission. | |||
| THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" | |||
| AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE | |||
| IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE | |||
| ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE | |||
| LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL | |||
| DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR | |||
| SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER | |||
| CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, | |||
| OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE | |||
| USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. | |||
| *****************************************************************************/ | |||
| #include <arm_sve.h> | |||
| #include "common.h" | |||
| #ifdef DOUBLE | |||
| #define SV_COUNT svcntd | |||
| #define SV_TYPE svfloat64_t | |||
| #define SV_TRUE svptrue_b64 | |||
| #define SV_WHILE svwhilelt_b64_s64 | |||
| #define SV_DUP svdup_f64 | |||
| #else | |||
| #define SV_COUNT svcntw | |||
| #define SV_TYPE svfloat32_t | |||
| #define SV_TRUE svptrue_b32 | |||
| #define SV_WHILE svwhilelt_b32_s64 | |||
| #define SV_DUP svdup_f32 | |||
| #endif | |||
| int CNAME(BLASLONG m, BLASLONG n, BLASLONG dummy1, FLOAT alpha, FLOAT *a, | |||
| BLASLONG lda, FLOAT *x, BLASLONG inc_x, FLOAT *y, BLASLONG inc_y, | |||
| FLOAT *buffer) | |||
| { | |||
| BLASLONG i; | |||
| BLASLONG ix,iy; | |||
| BLASLONG j; | |||
| FLOAT *a_ptr; | |||
| FLOAT temp; | |||
| iy = 0; | |||
| if (inc_x == 1) { | |||
| BLASLONG width = (n + 3 - 1) / 3; | |||
| FLOAT *a0_ptr = a + lda * width * 0; | |||
| FLOAT *a1_ptr = a + lda * width * 1; | |||
| FLOAT *a2_ptr = a + lda * width * 2; | |||
| FLOAT *y0_ptr = y + inc_y * width * 0; | |||
| FLOAT *y1_ptr = y + inc_y * width * 1; | |||
| FLOAT *y2_ptr = y + inc_y * width * 2; | |||
| for (j = 0; j < width; j++) { | |||
| svbool_t pg00 = ((j + width * 0) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg10 = ((j + width * 0) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg20 = ((j + width * 0) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg30 = ((j + width * 0) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg01 = ((j + width * 1) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg11 = ((j + width * 1) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg21 = ((j + width * 1) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg31 = ((j + width * 1) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg02 = ((j + width * 2) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg12 = ((j + width * 2) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg22 = ((j + width * 2) < n) ? SV_TRUE() : svpfalse(); | |||
| svbool_t pg32 = ((j + width * 2) < n) ? SV_TRUE() : svpfalse(); | |||
| SV_TYPE temp00_vec = SV_DUP(0.0); | |||
| SV_TYPE temp10_vec = SV_DUP(0.0); | |||
| SV_TYPE temp20_vec = SV_DUP(0.0); | |||
| SV_TYPE temp30_vec = SV_DUP(0.0); | |||
| SV_TYPE temp01_vec = SV_DUP(0.0); | |||
| SV_TYPE temp11_vec = SV_DUP(0.0); | |||
| SV_TYPE temp21_vec = SV_DUP(0.0); | |||
| SV_TYPE temp31_vec = SV_DUP(0.0); | |||
| SV_TYPE temp02_vec = SV_DUP(0.0); | |||
| SV_TYPE temp12_vec = SV_DUP(0.0); | |||
| SV_TYPE temp22_vec = SV_DUP(0.0); | |||
| SV_TYPE temp32_vec = SV_DUP(0.0); | |||
| i = 0; | |||
| BLASLONG sve_size = SV_COUNT(); | |||
| while ((i + sve_size * 4 - 1) < m) { | |||
| SV_TYPE x0_vec = svld1_vnum(SV_TRUE(), x + i, 0); | |||
| SV_TYPE x1_vec = svld1_vnum(SV_TRUE(), x + i, 1); | |||
| SV_TYPE x2_vec = svld1_vnum(SV_TRUE(), x + i, 2); | |||
| SV_TYPE x3_vec = svld1_vnum(SV_TRUE(), x + i, 3); | |||
| SV_TYPE a00_vec = svld1_vnum(pg00, a0_ptr + i, 0); | |||
| SV_TYPE a10_vec = svld1_vnum(pg10, a0_ptr + i, 1); | |||
| SV_TYPE a20_vec = svld1_vnum(pg20, a0_ptr + i, 2); | |||
| SV_TYPE a30_vec = svld1_vnum(pg30, a0_ptr + i, 3); | |||
| SV_TYPE a01_vec = svld1_vnum(pg01, a1_ptr + i, 0); | |||
| SV_TYPE a11_vec = svld1_vnum(pg11, a1_ptr + i, 1); | |||
| SV_TYPE a21_vec = svld1_vnum(pg21, a1_ptr + i, 2); | |||
| SV_TYPE a31_vec = svld1_vnum(pg31, a1_ptr + i, 3); | |||
| SV_TYPE a02_vec = svld1_vnum(pg02, a2_ptr + i, 0); | |||
| SV_TYPE a12_vec = svld1_vnum(pg12, a2_ptr + i, 1); | |||
| SV_TYPE a22_vec = svld1_vnum(pg22, a2_ptr + i, 2); | |||
| SV_TYPE a32_vec = svld1_vnum(pg32, a2_ptr + i, 3); | |||
| temp00_vec = svmla_m(pg00, temp00_vec, a00_vec, x0_vec); | |||
| temp10_vec = svmla_m(pg10, temp10_vec, a10_vec, x1_vec); | |||
| temp20_vec = svmla_m(pg20, temp20_vec, a20_vec, x2_vec); | |||
| temp30_vec = svmla_m(pg30, temp30_vec, a30_vec, x3_vec); | |||
| temp01_vec = svmla_m(pg01, temp01_vec, a01_vec, x0_vec); | |||
| temp11_vec = svmla_m(pg11, temp11_vec, a11_vec, x1_vec); | |||
| temp21_vec = svmla_m(pg21, temp21_vec, a21_vec, x2_vec); | |||
| temp31_vec = svmla_m(pg31, temp31_vec, a31_vec, x3_vec); | |||
| temp02_vec = svmla_m(pg02, temp02_vec, a02_vec, x0_vec); | |||
| temp12_vec = svmla_m(pg12, temp12_vec, a12_vec, x1_vec); | |||
| temp22_vec = svmla_m(pg22, temp22_vec, a22_vec, x2_vec); | |||
| temp32_vec = svmla_m(pg32, temp32_vec, a32_vec, x3_vec); | |||
| i += sve_size * 4; | |||
| } | |||
| if (i < m) { | |||
| svbool_t pg0 = SV_WHILE(i + sve_size * 0, m); | |||
| svbool_t pg1 = SV_WHILE(i + sve_size * 1, m); | |||
| svbool_t pg2 = SV_WHILE(i + sve_size * 2, m); | |||
| svbool_t pg3 = SV_WHILE(i + sve_size * 3, m); | |||
| pg00 = svand_z(SV_TRUE(), pg0, pg00); | |||
| pg10 = svand_z(SV_TRUE(), pg1, pg10); | |||
| pg20 = svand_z(SV_TRUE(), pg2, pg20); | |||
| pg30 = svand_z(SV_TRUE(), pg3, pg30); | |||
| pg01 = svand_z(SV_TRUE(), pg0, pg01); | |||
| pg11 = svand_z(SV_TRUE(), pg1, pg11); | |||
| pg21 = svand_z(SV_TRUE(), pg2, pg21); | |||
| pg31 = svand_z(SV_TRUE(), pg3, pg31); | |||
| pg02 = svand_z(SV_TRUE(), pg0, pg02); | |||
| pg12 = svand_z(SV_TRUE(), pg1, pg12); | |||
| pg22 = svand_z(SV_TRUE(), pg2, pg22); | |||
| pg32 = svand_z(SV_TRUE(), pg3, pg32); | |||
| SV_TYPE x0_vec = svld1_vnum(pg0, x + i, 0); | |||
| SV_TYPE x1_vec = svld1_vnum(pg1, x + i, 1); | |||
| SV_TYPE x2_vec = svld1_vnum(pg2, x + i, 2); | |||
| SV_TYPE x3_vec = svld1_vnum(pg3, x + i, 3); | |||
| SV_TYPE a00_vec = svld1_vnum(pg00, a0_ptr + i, 0); | |||
| SV_TYPE a10_vec = svld1_vnum(pg10, a0_ptr + i, 1); | |||
| SV_TYPE a20_vec = svld1_vnum(pg20, a0_ptr + i, 2); | |||
| SV_TYPE a30_vec = svld1_vnum(pg30, a0_ptr + i, 3); | |||
| SV_TYPE a01_vec = svld1_vnum(pg01, a1_ptr + i, 0); | |||
| SV_TYPE a11_vec = svld1_vnum(pg11, a1_ptr + i, 1); | |||
| SV_TYPE a21_vec = svld1_vnum(pg21, a1_ptr + i, 2); | |||
| SV_TYPE a31_vec = svld1_vnum(pg31, a1_ptr + i, 3); | |||
| SV_TYPE a02_vec = svld1_vnum(pg02, a2_ptr + i, 0); | |||
| SV_TYPE a12_vec = svld1_vnum(pg12, a2_ptr + i, 1); | |||
| SV_TYPE a22_vec = svld1_vnum(pg22, a2_ptr + i, 2); | |||
| SV_TYPE a32_vec = svld1_vnum(pg32, a2_ptr + i, 3); | |||
| temp00_vec = svmla_m(pg00, temp00_vec, a00_vec, x0_vec); | |||
| temp10_vec = svmla_m(pg10, temp10_vec, a10_vec, x1_vec); | |||
| temp20_vec = svmla_m(pg20, temp20_vec, a20_vec, x2_vec); | |||
| temp30_vec = svmla_m(pg30, temp30_vec, a30_vec, x3_vec); | |||
| temp01_vec = svmla_m(pg01, temp01_vec, a01_vec, x0_vec); | |||
| temp11_vec = svmla_m(pg11, temp11_vec, a11_vec, x1_vec); | |||
| temp21_vec = svmla_m(pg21, temp21_vec, a21_vec, x2_vec); | |||
| temp31_vec = svmla_m(pg31, temp31_vec, a31_vec, x3_vec); | |||
| temp02_vec = svmla_m(pg02, temp02_vec, a02_vec, x0_vec); | |||
| temp12_vec = svmla_m(pg12, temp12_vec, a12_vec, x1_vec); | |||
| temp22_vec = svmla_m(pg22, temp22_vec, a22_vec, x2_vec); | |||
| temp32_vec = svmla_m(pg32, temp32_vec, a32_vec, x3_vec); | |||
| } | |||
| temp00_vec = svadd_x(SV_TRUE(), temp00_vec, temp10_vec); | |||
| temp01_vec = svadd_x(SV_TRUE(), temp01_vec, temp11_vec); | |||
| temp02_vec = svadd_x(SV_TRUE(), temp02_vec, temp12_vec); | |||
| temp20_vec = svadd_x(SV_TRUE(), temp20_vec, temp30_vec); | |||
| temp21_vec = svadd_x(SV_TRUE(), temp21_vec, temp31_vec); | |||
| temp22_vec = svadd_x(SV_TRUE(), temp22_vec, temp32_vec); | |||
| temp00_vec = svadd_x(SV_TRUE(), temp00_vec, temp20_vec); | |||
| temp01_vec = svadd_x(SV_TRUE(), temp01_vec, temp21_vec); | |||
| temp02_vec = svadd_x(SV_TRUE(), temp02_vec, temp22_vec); | |||
| if ((j + width * 0) < n) { | |||
| temp = svaddv(SV_TRUE(), temp00_vec); | |||
| y0_ptr[iy] += alpha * temp; | |||
| } | |||
| if ((j + width * 1) < n) { | |||
| temp = svaddv(SV_TRUE(), temp01_vec); | |||
| y1_ptr[iy] += alpha * temp; | |||
| } | |||
| if ((j + width * 2) < n) { | |||
| temp = svaddv(SV_TRUE(), temp02_vec); | |||
| y2_ptr[iy] += alpha * temp; | |||
| } | |||
| iy += inc_y; | |||
| a0_ptr += lda; | |||
| a1_ptr += lda; | |||
| a2_ptr += lda; | |||
| } | |||
| return(0); | |||
| } | |||
| a_ptr = a; | |||
| for (j = 0; j < n; j++) { | |||
| temp = 0.0; | |||
| ix = 0; | |||
| for (i = 0; i < m; i++) { | |||
| temp += a_ptr[i] * x[ix]; | |||
| ix += inc_x; | |||
| } | |||
| y[iy] += alpha * temp; | |||
| iy += inc_y; | |||
| a_ptr += lda; | |||
| } | |||
| return(0); | |||
| } | |||