mirror of
https://github.com/OpenMathLib/OpenBLAS
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147 lines
6.0 KiB
C
147 lines
6.0 KiB
C
/***************************************************************************
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Copyright (c) 2025, The OpenBLAS Project
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All rights reserved.
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Redistribution and use in source and binary forms, with or without
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modification, are permitted provided that the following conditions are
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met:
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1. Redistributions of source code must retain the above copyright
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notice, this list of conditions and the following disclaimer.
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2. Redistributions in binary form must reproduce the above copyright
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notice, this list of conditions and the following disclaimer in
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the documentation and/or other materials provided with the
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distribution.
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3. Neither the name of the OpenBLAS project nor the names of
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its contributors may be used to endorse or promote products
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derived from this software without specific prior written
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permission.
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THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
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AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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ARE DISCLAIMED. IN NO EVENT SHALL THE OPENBLAS PROJECT OR CONTRIBUTORS BE
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LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
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SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
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CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
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OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE
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USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*****************************************************************************/
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#include <arm_sve.h>
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#include "common.h"
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#ifdef DOUBLE
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#define SV_COUNT svcntd
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#define SV_TYPE svfloat64_t
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#define SV_TRUE svptrue_b64
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#define SV_WHILE svwhilelt_b64_s64
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#define SV_DUP svdup_f64
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#else
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#define SV_COUNT svcntw
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#define SV_TYPE svfloat32_t
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#define SV_TRUE svptrue_b32
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#define SV_WHILE svwhilelt_b32_s64
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#define SV_DUP svdup_f32
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#endif
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static FLOAT dot_kernel_sve(BLASLONG n, FLOAT* x, FLOAT* y)
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{
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SV_TYPE temp0_vec = SV_DUP(0.0);
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SV_TYPE temp1_vec = SV_DUP(0.0);
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SV_TYPE temp2_vec = SV_DUP(0.0);
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SV_TYPE temp3_vec = SV_DUP(0.0);
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SV_TYPE temp4_vec = SV_DUP(0.0);
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SV_TYPE temp5_vec = SV_DUP(0.0);
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SV_TYPE temp6_vec = SV_DUP(0.0);
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SV_TYPE temp7_vec = SV_DUP(0.0);
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BLASLONG i = 0;
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BLASLONG sve_size = SV_COUNT();
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while ((i + sve_size * 8 - 1) < n) {
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FLOAT *x0_ptr = x + i;
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SV_TYPE x0_vec = svld1_vnum(SV_TRUE(), x0_ptr, 0);
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SV_TYPE x1_vec = svld1_vnum(SV_TRUE(), x0_ptr, 1);
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SV_TYPE x2_vec = svld1_vnum(SV_TRUE(), x0_ptr, 2);
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SV_TYPE x3_vec = svld1_vnum(SV_TRUE(), x0_ptr, 3);
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SV_TYPE x4_vec = svld1_vnum(SV_TRUE(), x0_ptr, 4);
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SV_TYPE x5_vec = svld1_vnum(SV_TRUE(), x0_ptr, 5);
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SV_TYPE x6_vec = svld1_vnum(SV_TRUE(), x0_ptr, 6);
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SV_TYPE x7_vec = svld1_vnum(SV_TRUE(), x0_ptr, 7);
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FLOAT *y0_ptr = y + i;
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SV_TYPE y0_vec = svld1_vnum(SV_TRUE(), y0_ptr, 0);
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SV_TYPE y1_vec = svld1_vnum(SV_TRUE(), y0_ptr, 1);
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SV_TYPE y2_vec = svld1_vnum(SV_TRUE(), y0_ptr, 2);
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SV_TYPE y3_vec = svld1_vnum(SV_TRUE(), y0_ptr, 3);
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SV_TYPE y4_vec = svld1_vnum(SV_TRUE(), y0_ptr, 4);
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SV_TYPE y5_vec = svld1_vnum(SV_TRUE(), y0_ptr, 5);
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SV_TYPE y6_vec = svld1_vnum(SV_TRUE(), y0_ptr, 6);
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SV_TYPE y7_vec = svld1_vnum(SV_TRUE(), y0_ptr, 7);
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temp0_vec = svmla_x(SV_TRUE(), temp0_vec, x0_vec, y0_vec);
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temp1_vec = svmla_x(SV_TRUE(), temp1_vec, x1_vec, y1_vec);
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temp2_vec = svmla_x(SV_TRUE(), temp2_vec, x2_vec, y2_vec);
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temp3_vec = svmla_x(SV_TRUE(), temp3_vec, x3_vec, y3_vec);
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temp4_vec = svmla_x(SV_TRUE(), temp4_vec, x4_vec, y4_vec);
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temp5_vec = svmla_x(SV_TRUE(), temp5_vec, x5_vec, y5_vec);
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temp6_vec = svmla_x(SV_TRUE(), temp6_vec, x6_vec, y6_vec);
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temp7_vec = svmla_x(SV_TRUE(), temp7_vec, x7_vec, y7_vec);
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i += sve_size * 8;
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}
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if (i < n) {
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svbool_t pg0 = SV_WHILE(i + sve_size * 0, n);
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svbool_t pg1 = SV_WHILE(i + sve_size * 1, n);
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svbool_t pg2 = SV_WHILE(i + sve_size * 2, n);
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svbool_t pg3 = SV_WHILE(i + sve_size * 3, n);
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svbool_t pg4 = SV_WHILE(i + sve_size * 4, n);
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svbool_t pg5 = SV_WHILE(i + sve_size * 5, n);
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svbool_t pg6 = SV_WHILE(i + sve_size * 6, n);
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svbool_t pg7 = SV_WHILE(i + sve_size * 7, n);
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FLOAT *x0_ptr = x + i;
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SV_TYPE x0_vec = svld1_vnum(pg0, x0_ptr, 0);
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SV_TYPE x1_vec = svld1_vnum(pg1, x0_ptr, 1);
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SV_TYPE x2_vec = svld1_vnum(pg2, x0_ptr, 2);
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SV_TYPE x3_vec = svld1_vnum(pg3, x0_ptr, 3);
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SV_TYPE x4_vec = svld1_vnum(pg4, x0_ptr, 4);
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SV_TYPE x5_vec = svld1_vnum(pg5, x0_ptr, 5);
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SV_TYPE x6_vec = svld1_vnum(pg6, x0_ptr, 6);
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SV_TYPE x7_vec = svld1_vnum(pg7, x0_ptr, 7);
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FLOAT *y0_ptr = y + i;
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SV_TYPE y0_vec = svld1_vnum(pg0, y0_ptr, 0);
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SV_TYPE y1_vec = svld1_vnum(pg1, y0_ptr, 1);
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SV_TYPE y2_vec = svld1_vnum(pg2, y0_ptr, 2);
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SV_TYPE y3_vec = svld1_vnum(pg3, y0_ptr, 3);
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SV_TYPE y4_vec = svld1_vnum(pg4, y0_ptr, 4);
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SV_TYPE y5_vec = svld1_vnum(pg5, y0_ptr, 5);
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SV_TYPE y6_vec = svld1_vnum(pg6, y0_ptr, 6);
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SV_TYPE y7_vec = svld1_vnum(pg7, y0_ptr, 7);
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temp0_vec = svmla_m(pg0, temp0_vec, x0_vec, y0_vec);
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temp1_vec = svmla_m(pg1, temp1_vec, x1_vec, y1_vec);
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temp2_vec = svmla_m(pg2, temp2_vec, x2_vec, y2_vec);
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temp3_vec = svmla_m(pg3, temp3_vec, x3_vec, y3_vec);
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temp4_vec = svmla_m(pg4, temp4_vec, x4_vec, y4_vec);
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temp5_vec = svmla_m(pg5, temp5_vec, x5_vec, y5_vec);
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temp6_vec = svmla_m(pg6, temp6_vec, x6_vec, y6_vec);
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temp7_vec = svmla_m(pg7, temp7_vec, x7_vec, y7_vec);
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}
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temp0_vec = svadd_x(SV_TRUE(), temp0_vec, temp1_vec);
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temp2_vec = svadd_x(SV_TRUE(), temp2_vec, temp3_vec);
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temp4_vec = svadd_x(SV_TRUE(), temp4_vec, temp5_vec);
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temp6_vec = svadd_x(SV_TRUE(), temp6_vec, temp7_vec);
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temp0_vec = svadd_x(SV_TRUE(), temp0_vec, temp2_vec);
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temp4_vec = svadd_x(SV_TRUE(), temp4_vec, temp6_vec);
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temp0_vec = svadd_x(SV_TRUE(), temp0_vec, temp4_vec);
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return svaddv(SV_TRUE(), temp0_vec);
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}
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