/github/workspace/src/BasicMathFunctions/mult/kernels/plp_mult_f32p_xpulpv2.c
Functions
Name | |
---|---|
void | plp_mult_f32p_xpulpv2(void * S) Parallel multiplication with interleaved access of 32-bit float vectors kernel for XPULPV2 extension. |
Functions Documentation
function plp_mult_f32p_xpulpv2
void plp_mult_f32p_xpulpv2(
void * S
)
Parallel multiplication with interleaved access of 32-bit float vectors kernel for XPULPV2 extension.
Parameters:
- S points to the instance structure for float parallel multiplication
Return: none
Source code
/* =====================================================================
* Project: PULP DSP Library
* Title: plp_mult_f32p_xpulpv2.c
* Description: 32-bit floating-point multiplication for XPULPV2 with interleaved access
*
* $Date: 10. July 2021
* $Revision: V0
*
* Target Processor: PULP cores
* ===================================================================== */
/*
* Copyright (C) 2021 ETH Zurich and University of Bologna.
*
* Author: Aron Szakacs, ETH Zurich
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* Notice: project inspired by ARM CMSIS DSP and parts of source code
* ported and adopted for RISC-V PULP platform from ARM CMSIS DSP
* released under Copyright (C) 2010-2019 ARM Limited or its affiliates
* with Apache-2.0.
*/
#include "plp_math.h"
void plp_mult_f32p_xpulpv2(void *S) {
float32_t *pSrcA = (float32_t *)(((plp_mult_instance_f32 *)S)->pSrcA) + rt_core_id();
float32_t *pSrcB = (float32_t *)(((plp_mult_instance_f32 *)S)->pSrcB) + rt_core_id();
uint32_t blkSizePE = ((plp_mult_instance_f32 *)S)->blkSizePE;
uint32_t nPE = ((plp_mult_instance_f32 *)S)->nPE;
float32_t *pDst = (float32_t *)(((plp_mult_instance_f32 *)S)->pDst) + rt_core_id();
uint32_t blkCnt, tmpBS; /* Loop counter, temporal BlockSize */
// float32_t sum1 = 0, sum2=0; /* Temporary return variable */
// rt_team_barrier();
/* #if defined(PLP_MATH_LOOPUNROLL) */
/* #undef PLP_MATH_LOOPUNROLL */
/* #endif */
/* #if defined(PLP_MATH_LOOPUNROLL) */
/* tmpBS = (blkSizePE>>1); */
/* uint32_t tmpIdx = 2*nPE; */
/* for (blkCnt=0; blkCnt<tmpBS; blkCnt++){ */
/* //printf("blkCnt %d, tmpIdx*blkCnt %d\n", blkCnt, tmpIdx*blkCnt); */
/* sum1 += pSrcA[tmpIdx*blkCnt] * pSrcB[tmpIdx*blkCnt]; */
/* sum2 += pSrcA[tmpIdx*blkCnt + nPE] * pSrcB[tmpIdx*blkCnt + nPE]; */
/* } */
/* #else // PLP_MATH_LOOPUNROLL */
for (blkCnt = 0; blkCnt < blkSizePE; blkCnt++) {
pDst[nPE * blkCnt] = pSrcA[nPE * blkCnt] * pSrcB[nPE * blkCnt];
}
/* #endif // PLP_MATH_LOOPUNROLL */
//* resBufferPE = sum1 + sum2;
// printf("resBufferPE %d, core id %d\n", *resBufferPE, rt_core_id());
}
/* #define PLP_MATH_LOOPUNROLL */
Updated on 2023-03-01 at 16:16:32 +0000