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Commit 0ee70df3 authored by Sy's avatar Sy
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openair1/PHY/CODING/nrLDPC_decoder/nrLDPC_tools/Makefile 0 → 100644
View file @ 0ee70df3
C=gcc
CFLAGS=-W -Wall -mavx2
LDFLAGS=
EXEC=cnProc_gen
SRC= $(wildcard *.c)
OBJ= $(SRC:.c=.o)
all: $(EXEC)
cnProc_gen: $(OBJ)
$(CC) -o $@ $^ $(LDFLAGS)
main.o: cnProc_gen.h
%.o: %.c
$(CC) -o $@ -c $< $(CFLAGS)
.PHONY: clean mrproper
clean:
rm -rf *.o
mrproper: clean
rm -rf $(EXEC)
zip:
tar -zcvf sauvegarde.tar.gz main.c cnProc_gen.c cnProc_geno.h Makefile
openair1/PHY/CODING/nrLDPC_decoder/nrLDPC_tools/cnProc_gen.c 0 → 100644
View file @ 0ee70df3
#include <stdint.h>
#include <immintrin.h>
#include "../nrLDPCdecoder_defs.h"
#include "../nrLDPC_types.h"
#include "../nrLDPC_init.h"
#include "../nrLDPC_mPass.h"
//#include "nrLDPC_cnProc.h"
#include "../nrLDPC_bnProc.h"
#include "cnProc_gen.h"
void nrLDPC_cnProc_BG1(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_procBuf, uint16_t Z)
{
printf("void nrLDPC_cnProc_BG1_Z%d\n",Z);
const uint8_t* lut_numCnInCnGroups = p_lut->numCnInCnGroups;
const uint32_t* lut_startAddrCnGroups = p_lut->startAddrCnGroups;
int8_t* cnProcBuf = p_procBuf->cnProcBuf;
int8_t* cnProcBufRes = p_procBuf->cnProcBufRes;
//__m256i* p_cnProcBuf;
//__m256i* p_cnProcBufRes;
// Number of CNs in Groups
uint32_t M;
uint32_t i;
uint32_t j;
uint32_t k;
// Offset to each bit within a group in terms of 32 Byte
uint32_t bitOffsetInGroup;
//__m256i ymm0, min, sgn;
//__m256i* p_cnProcBufResBit;
// const __m256i* p_ones = (__m256i*) ones256_epi8;
// const __m256i* p_maxLLR = (__m256i*) maxLLR256_epi8;
// LUT with offsets for bits that need to be processed
// 1. bit proc requires LLRs of 2. and 3. bit, 2.bits of 1. and 3. etc.
// Offsets are in units of bitOffsetInGroup (1*384/32)
// const uint8_t lut_idxCnProcG3[3][2] = {{12,24}, {0,24}, {0,12}};
// =====================================================================
// Process group with 3 BNs
// LUT with offsets for bits that need to be processed
// 1. bit proc requires LLRs of 2. and 3. bit, 2.bits of 1. and 3. etc.
// Offsets are in units of bitOffsetInGroup (1*384/32)
const uint8_t lut_idxCnProcG3[3][2] = {{12,24}, {0,24}, {0,12}};
printf(" __m256i ymm0, min, sgn;\n");
printf(" const __m256i* p_ones = (__m256i*) ones256_epi8;\n");
printf(" const __m256i* p_maxLLR = (__m256i*) maxLLR256_epi8;\n");
if (lut_numCnInCnGroups[0] > 0)
{
// Number of groups of 32 CNs for parallel processing
// Ceil for values not divisible by 32
M = (lut_numCnInCnGroups[0]*Z + 31)>>5;
// Set the offset to each bit within a group in terms of 32 Byte
bitOffsetInGroup = (lut_numCnInCnGroups_BG1_R13[0]*NR_LDPC_ZMAX)>>5;
// Set pointers to start of group 3
//p_cnProcBuf = (__m256i*) &cnProcBuf [lut_startAddrCnGroups[0]];
//p_cnProcBufRes = (__m256i*) &cnProcBufRes[lut_startAddrCnGroups[0]];
// Loop over every BN
int iprime=0;
for (j=0; j<3; j++)
{
// Set of results pointer to correct BN address
//p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
// Loop over CNs
for (i=0; i<M; i++,iprime++)
{
// Abs and sign of 32 CNs (first BN)
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[0]+lut_idxCnProcG3[j][0] + i);
// sgn = _mm256_sign_epi8(*p_ones, ymm0);
printf(" sgn = _mm256_sign_epi8(*p_ones, ymm0);\n");
// min = _mm256_abs_epi8(ymm0);
printf(" min = _mm256_abs_epi8(ymm0);\n");
// 32 CNs of second BN
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][1] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[0]+lut_idxCnProcG3[j][1] + i);
// min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
printf(" min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));\n");
// sgn = _mm256_sign_epi8(sgn, ymm0);
printf(" sgn = _mm256_sign_epi8(sgn, ymm0);\n");
// Store result
// min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
printf(" min = _mm256_min_epu8(min, *p_maxLLR);\n");
// *p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
// p_cnProcBufResBit++;
printf(" ((__m256i*)cnProcB ufRestBit)[%d] = _mm256_sign_epi8(min, sgn);\n",lut_numCnInCnGroups[0]+(j*bitOffsetInGroup)+i);
}
}
}
// =====================================================================
// Process group with 4 BNs
// Offset is 5*384/32 = 60
const uint8_t lut_idxCnProcG4[4][3] = {{60,120,180}, {0,120,180}, {0,60,180}, {0,60,120}};
if (lut_numCnInCnGroups[1] > 0)
{
// Number of groups of 32 CNs for parallel processing
// Ceil for values not divisible by 32
M = (lut_numCnInCnGroups[1]*Z + 31)>>5;
// Set the offset to each bit within a group in terms of 32 Byte
bitOffsetInGroup = (lut_numCnInCnGroups_BG1_R13[1]*NR_LDPC_ZMAX)>>5;
// Set pointers to start of group 4
//p_cnProcBuf = (__m256i*) &cnProcBuf [lut_startAddrCnGroups[1]];
//p_cnProcBufRes = (__m256i*) &cnProcBufRes[lut_startAddrCnGroups[1]];
// Loop over every BN
int iprime=0;
for (j=0; j<4; j++)
{
// Set of results pointer to correct BN address
//p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
// Loop over CNs
for (i=0; i<M; i++,iprime++)
{
// Abs and sign of 32 CNs (first BN)
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[1]+lut_idxCnProcG4[j][0] + i);
// sgn = _mm256_sign_epi8(*p_ones, ymm0);
printf(" sgn = _mm256_sign_epi8(*p_ones, ymm0);\n");
// min = _mm256_abs_epi8(ymm0);
printf(" min = _mm256_abs_epi8(ymm0);\n");
// Loop over BNs
for (k=1; k<3; k++)
{
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[1]+lut_idxCnProcG4[j][k] + i);
// min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
printf(" min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));\n");
// sgn = _mm256_sign_epi8(sgn, ymm0);
printf(" sgn = _mm256_sign_epi8(sgn, ymm0);\n");
}
// Store result
// min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
printf(" min = _mm256_min_epu8(min, *p_maxLLR);\n");
// *p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
// p_cnProcBufResBit++;
printf(" ((__m256i*)cnProcBufRestBit)[%d] = _mm256_sign_epi8(min, sgn);\n",lut_numCnInCnGroups[1]+(j*bitOffsetInGroup)+i);
}
}
}
// =====================================================================
// Process group with 5 BNs
// Offset is 18*384/32 = 216
const uint16_t lut_idxCnProcG5[5][4] = {{216,432,648,864}, {0,432,648,864},
{0,216,648,864}, {0,216,432,864}, {0,216,432,648}};
if (lut_numCnInCnGroups[2] > 0)
{
// Number of groups of 32 CNs for parallel processing
// Ceil for values not divisible by 32
M = (lut_numCnInCnGroups[2]*Z + 31)>>5;
// Set the offset to each bit within a group in terms of 32 Byte
bitOffsetInGroup = (lut_numCnInCnGroups_BG1_R13[2]*NR_LDPC_ZMAX)>>5;
// Set pointers to start of group 4
//p_cnProcBuf = (__m256i*) &cnProcBuf [lut_startAddrCnGroups[1]];
//p_cnProcBufRes = (__m256i*) &cnProcBufRes[lut_startAddrCnGroups[1]];
// Loop over every BN
int iprime=0;
for (j=0; j<5; j++)
{
// Set of results pointer to correct BN address
//p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
// Loop over CNs
for (i=0; i<M; i++,iprime++)
{
// Abs and sign of 32 CNs (first BN)
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[2]+lut_idxCnProcG5[j][0] + i);
// sgn = _mm256_sign_epi8(*p_ones, ymm0);
printf(" sgn = _mm256_sign_epi8(*p_ones, ymm0);\n");
// min = _mm256_abs_epi8(ymm0);
printf(" min = _mm256_abs_epi8(ymm0);\n");
// Loop over BNs
for (k=1; k<4; k++)
{
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[2]+lut_idxCnProcG5[j][k] + i);
// min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
printf(" min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));\n");
// sgn = _mm256_sign_epi8(sgn, ymm0);
printf(" sgn = _mm256_sign_epi8(sgn, ymm0);\n");
}
// Store result
// min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
printf(" min = _mm256_min_epu8(min, *p_maxLLR);\n");
// *p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
// p_cnProcBufResBit++;
printf(" ((__m256i*)cnProcBufRestBit)[%d] = _mm256_sign_epi8(min, sgn);\n",lut_numCnInCnGroups[2]+(j*bitOffsetInGroup)+i);
}
}
}
// =====================================================================
// Process group with 6 BNs
// Offset is 8*384/32 = 96
const uint16_t lut_idxCnProcG6[6][5] = {{96,192,288,384,480}, {0,192,288,384,480},
{0,96,288,384,480}, {0,96,192,384,480},
{0,96,192,288,480}, {0,96,192,288,384}};
if (lut_numCnInCnGroups[3] > 0)
{
// Number of groups of 32 CNs for parallel processing
// Ceil for values not divisible by 32
M = (lut_numCnInCnGroups[3]*Z + 31)>>5;
// Set the offset to each bit within a group in terms of 32 Byte
bitOffsetInGroup = (lut_numCnInCnGroups_BG1_R13[3]*NR_LDPC_ZMAX)>>5;
// Set pointers to start of group 4
//p_cnProcBuf = (__m256i*) &cnProcBuf [lut_startAddrCnGroups[1]];
//p_cnProcBufRes = (__m256i*) &cnProcBufRes[lut_startAddrCnGroups[1]];
// Loop over every BN
int iprime=0;
for (j=0; j<6; j++)
{
// Set of results pointer to correct BN address
//p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
// Loop over CNs
for (i=0; i<M; i++,iprime++)
{
// Abs and sign of 32 CNs (first BN)
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[3]+lut_idxCnProcG6[j][0] + i);
// sgn = _mm256_sign_epi8(*p_ones, ymm0);
printf(" sgn = _mm256_sign_epi8(*p_ones, ymm0);\n");
// min = _mm256_abs_epi8(ymm0);
printf(" min = _mm256_abs_epi8(ymm0);\n");
// Loop over BNs
for (k=1; k<5; k++)
{
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[3]+lut_idxCnProcG6[j][k] + i);
// min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
printf(" min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));\n");
// sgn = _mm256_sign_epi8(sgn, ymm0);
printf(" sgn = _mm256_sign_epi8(sgn, ymm0);\n");
}
// Store result
// min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
printf(" min = _mm256_min_epu8(min, *p_maxLLR);\n");
// *p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
// p_cnProcBufResBit++;
printf(" ((__m256i*)cnProcBufRestBit)[%d] = _mm256_sign_epi8(min, sgn);\n",lut_numCnInCnGroups[3]+(j*bitOffsetInGroup)+i);
}
}
}
// =====================================================================
// Process group with 7 BNs
// Offset is 5*384/32 = 60
const uint16_t lut_idxCnProcG7[7][6] = {{60,120,180,240,300,360}, {0,120,180,240,300,360},
{0,60,180,240,300,360}, {0,60,120,240,300,360},
{0,60,120,180,300,360}, {0,60,120,180,240,360},
{0,60,120,180,240,300}};
if (lut_numCnInCnGroups[4] > 0)
{
// Number of groups of 32 CNs for parallel processing
// Ceil for values not divisible by 32
M = (lut_numCnInCnGroups[4]*Z + 31)>>5;
// Set the offset to each bit within a group in terms of 32 Byte
bitOffsetInGroup = (lut_numCnInCnGroups_BG1_R13[4]*NR_LDPC_ZMAX)>>5;
// Set pointers to start of group 4
//p_cnProcBuf = (__m256i*) &cnProcBuf [lut_startAddrCnGroups[1]];
//p_cnProcBufRes = (__m256i*) &cnProcBufRes[lut_startAddrCnGroups[1]];
// Loop over every BN
int iprime=0;
for (j=0; j<7; j++)
{
// Set of results pointer to correct BN address
//p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
// Loop over CNs
for (i=0; i<M; i++,iprime++)
{
// Abs and sign of 32 CNs (first BN)
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[4]+lut_idxCnProcG7[j][0] + i);
// sgn = _mm256_sign_epi8(*p_ones, ymm0);
printf(" sgn = _mm256_sign_epi8(*p_ones, ymm0);\n");
// min = _mm256_abs_epi8(ymm0);
printf(" min = _mm256_abs_epi8(ymm0);\n");
// Loop over BNs
for (k=1; k<6; k++)
{
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[4]+lut_idxCnProcG7[j][k] + i);
// min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
printf(" min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));\n");
// sgn = _mm256_sign_epi8(sgn, ymm0);
printf(" sgn = _mm256_sign_epi8(sgn, ymm0);\n");
}
// Store result
// min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
printf(" min = _mm256_min_epu8(min, *p_maxLLR);\n");
// *p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
// p_cnProcBufResBit++;
printf(" ((__m256i*)cnProcBufRestBit)[%d] = _mm256_sign_epi8(min, sgn);\n",lut_numCnInCnGroups[4]+(j*bitOffsetInGroup)+i);
}
}
}
// =====================================================================
// Process group with 8 BNs
// Offset is 2*384/32 = 24
const uint8_t lut_idxCnProcG8[8][7] = {{24,48,72,96,120,144,168}, {0,48,72,96,120,144,168},
{0,24,72,96,120,144,168}, {0,24,48,96,120,144,168},
{0,24,48,72,120,144,168}, {0,24,48,72,96,144,168},
{0,24,48,72,96,120,168}, {0,24,48,72,96,120,144}};
if (lut_numCnInCnGroups[5] > 0)
{
// Number of groups of 32 CNs for parallel processing
// Ceil for values not divisible by 32
M = (lut_numCnInCnGroups[5]*Z + 31)>>5;
// Set the offset to each bit within a group in terms of 32 Byte
bitOffsetInGroup = (lut_numCnInCnGroups_BG1_R13[5]*NR_LDPC_ZMAX)>>5;
// Set pointers to start of group 4
//p_cnProcBuf = (__m256i*) &cnProcBuf [lut_startAddrCnGroups[1]];
//p_cnProcBufRes = (__m256i*) &cnProcBufRes[lut_startAddrCnGroups[1]];
// Loop over every BN
int iprime=0;
for (j=0; j<8; j++)
{
// Set of results pointer to correct BN address
//p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
// Loop over CNs
for (i=0; i<M; i++,iprime++)
{
// Abs and sign of 32 CNs (first BN)
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[5]+lut_idxCnProcG8[j][0] + i);
// sgn = _mm256_sign_epi8(*p_ones, ymm0);
printf(" sgn = _mm256_sign_epi8(*p_ones, ymm0);\n");
// min = _mm256_abs_epi8(ymm0);
printf(" min = _mm256_abs_epi8(ymm0);\n");
// Loop over BNs
for (k=1; k<7; k++)
{
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[5]+lut_idxCnProcG8[j][k] + i);
// min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
printf(" min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));\n");
// sgn = _mm256_sign_epi8(sgn, ymm0);
printf(" sgn = _mm256_sign_epi8(sgn, ymm0);\n");
}
// Store result
// min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
printf(" min = _mm256_min_epu8(min, *p_maxLLR);\n");
// *p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
// p_cnProcBufResBit++;
printf(" ((__m256i*)cnProcBufRestBit)[%d] = _mm256_sign_epi8(min, sgn);\n",lut_numCnInCnGroups[5]+(j*bitOffsetInGroup)+i);
}
}
}
// =====================================================================
// Process group with 9 BNs
// Offset is 2*384/32 = 24
const uint8_t lut_idxCnProcG9[9][8] = {{24,48,72,96,120,144,168,192}, {0,48,72,96,120,144,168,192},
{0,24,72,96,120,144,168,192}, {0,24,48,96,120,144,168,192},
{0,24,48,72,120,144,168,192}, {0,24,48,72,96,144,168,192},
{0,24,48,72,96,120,168,192}, {0,24,48,72,96,120,144,192},
{0,24,48,72,96,120,144,168}};
if (lut_numCnInCnGroups[6] > 0)
{
// Number of groups of 32 CNs for parallel processing
// Ceil for values not divisible by 32
M = (lut_numCnInCnGroups[6]*Z + 31)>>5;
// Set the offset to each bit within a group in terms of 32 Byte
bitOffsetInGroup = (lut_numCnInCnGroups_BG1_R13[6]*NR_LDPC_ZMAX)>>5;
// Set pointers to start of group 9
//p_cnProcBuf = (__m256i*) &cnProcBuf [lut_startAddrCnGroups[1]];
//p_cnProcBufRes = (__m256i*) &cnProcBufRes[lut_startAddrCnGroups[1]];
// Loop over every BN
int iprime=0;
for (j=0; j<9; j++)
{
// Set of results pointer to correct BN address
//p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
// Loop over CNs
for (i=0; i<M; i++,iprime++)
{
// Abs and sign of 32 CNs (first BN)
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[6]+lut_idxCnProcG9[j][0] + i);
// sgn = _mm256_sign_epi8(*p_ones, ymm0);
printf(" sgn = _mm256_sign_epi8(*p_ones, ymm0);\n");
// min = _mm256_abs_epi8(ymm0);
printf(" min = _mm256_abs_epi8(ymm0);\n");
// Loop over BNs
for (k=1; k<8; k++)
{
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[6]+lut_idxCnProcG9[j][k] + i);
// min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
printf(" min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));\n");
// sgn = _mm256_sign_epi8(sgn, ymm0);
printf(" sgn = _mm256_sign_epi8(sgn, ymm0);\n");
}
// Store result
// min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
printf(" min = _mm256_min_epu8(min, *p_maxLLR);\n");
// *p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
// p_cnProcBufResBit++;
printf(" ((__m256i*)cnProcBufRestBit)[%d] = _mm256_sign_epi8(min, sgn);\n",lut_numCnInCnGroups[6]+(j*bitOffsetInGroup)+i);
}
}
}
// =====================================================================
// Process group with 10 BNs
// Offset is 1*384/32 = 12
const uint8_t lut_idxCnProcG10[10][9] = {{12,24,36,48,60,72,84,96,108}, {0,24,36,48,60,72,84,96,108},
{0,12,36,48,60,72,84,96,108}, {0,12,24,48,60,72,84,96,108},
{0,12,24,36,60,72,84,96,108}, {0,12,24,36,48,72,84,96,108},
{0,12,24,36,48,60,84,96,108}, {0,12,24,36,48,60,72,96,108},
{0,12,24,36,48,60,72,84,108}, {0,12,24,36,48,60,72,84,96}};
if (lut_numCnInCnGroups[7] > 0)
{
// Number of groups of 32 CNs for parallel processing
// Ceil for values not divisible by 32
M = (lut_numCnInCnGroups[7]*Z + 31)>>5;
// Set the offset to each bit within a group in terms of 32 Byte
bitOffsetInGroup = (lut_numCnInCnGroups_BG1_R13[7]*NR_LDPC_ZMAX)>>5;
// Set pointers to start of group 10
//p_cnProcBuf = (__m256i*) &cnProcBuf [lut_startAddrCnGroups[1]];
//p_cnProcBufRes = (__m256i*) &cnProcBufRes[lut_startAddrCnGroups[1]];
// Loop over every BN
int iprime=0;
for (j=0; j<10; j++)
{
// Set of results pointer to correct BN address
//p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
// Loop over CNs
for (i=0; i<M; i++,iprime++)
{
// Abs and sign of 32 CNs (first BN)
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[7]+lut_idxCnProcG10[j][0] + i);
// sgn = _mm256_sign_epi8(*p_ones, ymm0);
printf(" sgn = _mm256_sign_epi8(*p_ones, ymm0);\n");
// min = _mm256_abs_epi8(ymm0);
printf(" min = _mm256_abs_epi8(ymm0);\n");
// Loop over BNs
for (k=1; k<9; k++)
{
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[7]+lut_idxCnProcG10[j][k] + i);
// min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
printf(" min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));\n");
// sgn = _mm256_sign_epi8(sgn, ymm0);
printf(" sgn = _mm256_sign_epi8(sgn, ymm0);\n");
}
// Store result
// min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
printf(" min = _mm256_min_epu8(min, *p_maxLLR);\n");
// *p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
// p_cnProcBufResBit++;
printf(" ((__m256i*)cnProcBufRestBit)[%d] = _mm256_sign_epi8(min, sgn);\n",lut_numCnInCnGroups[7]+(j*bitOffsetInGroup)+i);
}
}
}
// =====================================================================
// Process group with 19 BNs
// Offset is 4*384/32 = 12
const uint16_t lut_idxCnProcG19[19][18] = {{48,96,144,192,240,288,336,384,432,480,528,576,624,672,720,768,816,864}, {0,96,144,192,240,288,336,384,432,480,528,576,624,672,720,768,816,864},
{0,48,144,192,240,288,336,384,432,480,528,576,624,672,720,768,816,864}, {0,48,96,192,240,288,336,384,432,480,528,576,624,672,720,768,816,864},
{0,48,96,144,240,288,336,384,432,480,528,576,624,672,720,768,816,864}, {0,48,96,144,192,288,336,384,432,480,528,576,624,672,720,768,816,864},
{0,48,96,144,192,240,336,384,432,480,528,576,624,672,720,768,816,864}, {0,48,96,144,192,240,288,384,432,480,528,576,624,672,720,768,816,864},
{0,48,96,144,192,240,288,336,432,480,528,576,624,672,720,768,816,864}, {0,48,96,144,192,240,288,336,384,480,528,576,624,672,720,768,816,864},
{0,48,96,144,192,240,288,336,384,432,528,576,624,672,720,768,816,864}, {0,48,96,144,192,240,288,336,384,432,480,576,624,672,720,768,816,864},
{0,48,96,144,192,240,288,336,384,432,480,528,624,672,720,768,816,864}, {0,48,96,144,192,240,288,336,384,432,480,528,576,672,720,768,816,864},
{0,48,96,144,192,240,288,336,384,432,480,528,576,624,720,768,816,864}, {0,48,96,144,192,240,288,336,384,432,480,528,576,624,672,768,816,864},
{0,48,96,144,192,240,288,336,384,432,480,528,576,624,672,720,816,864}, {0,48,96,144,192,240,288,336,384,432,480,528,576,624,672,720,768,864},
{0,48,96,144,192,240,288,336,384,432,480,528,576,624,672,720,768,816}};
if (lut_numCnInCnGroups[8] > 0)
{
// Number of groups of 32 CNs for parallel processing
// Ceil for values not divisible by 32
M = (lut_numCnInCnGroups[8]*Z + 31)>>5;
// Set the offset to each bit within a group in terms of 32 Byte
bitOffsetInGroup = (lut_numCnInCnGroups_BG1_R13[8]*NR_LDPC_ZMAX)>>5;
// Set pointers to start of group 19
//p_cnProcBuf = (__m256i*) &cnProcBuf [lut_startAddrCnGroups[1]];
//p_cnProcBufRes = (__m256i*) &cnProcBufRes[lut_startAddrCnGroups[1]];
// Loop over every BN
int iprime=0;
for (j=0; j<19; j++)
{
// Set of results pointer to correct BN address
//p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
// Loop over CNs
for (i=0; i<M; i++,iprime++)
{
// Abs and sign of 32 CNs (first BN)
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[8]+lut_idxCnProcG19[j][0] + i);
// sgn = _mm256_sign_epi8(*p_ones, ymm0);
printf(" sgn = _mm256_sign_epi8(*p_ones, ymm0);\n");
// min = _mm256_abs_epi8(ymm0);
printf(" min = _mm256_abs_epi8(ymm0);\n");
// Loop over BNs
for (k=1; k<18; k++)
{
printf(" ymm0 = ((__m256i*)&cnProcBuf)[%d];\n",lut_startAddrCnGroups[8]+lut_idxCnProcG19[j][k] + i);
// min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
printf(" min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));\n");
// sgn = _mm256_sign_epi8(sgn, ymm0);
printf(" sgn = _mm256_sign_epi8(sgn, ymm0);\n");
}
// Store result
// min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
printf(" min = _mm256_min_epu8(min, *p_maxLLR);\n");
// *p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
// p_cnProcBufResBit++;
printf(" ((__m256i*)cnProcBufRestBit)[%d] = _mm256_sign_epi8(min, sgn);\n",lut_numCnInCnGroups[8]+(j*bitOffsetInGroup)+i);
}
}
}
}//end of the function nrLDPC_cnProc_BG1
openair1/PHY/CODING/nrLDPC_decoder/nrLDPC_tools/cnProc_gen.h 0 → 100644
View file @ 0ee70df3
#ifndef NRLDPC_CN_GEN
#define NRLDPC_DN_GEN
void nrLDPC_cnProc_BG1(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_procBuf, uint16_t Z);
#endif
openair1/PHY/CODING/nrLDPC_decoder/nrLDPC_tools/main.c 0 → 100644
View file @ 0ee70df3
#include <stdio.h>
#include <immintrin.h>
//#include "../nrLDPCdecoder_defs.h"
#include "../nrLDPC_types.h"
#include "../nrLDPC_init.h"
#include "../nrLDPC_mPass.h"
//#include "../nrLDPC_cnProc.h"
#include "../nrLDPC_bnProc.h"
#include "cnProc_gen.h"
int main(int argc, char *argv[])
{
//short lift_size[51]= {2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,18,20,22,24,26,28,30,32,36,40,44,48,52,56,60,64,72,80,88,96,104,112,120,128,144,160,176,192,208,224,240,256,288,320,352,384};
// unsigned int errors, errors_bit, crc_misses;
// double errors_bit_uncoded;
//short block_length=8448; // decoder supports length: 1201 -> 1280, 2401 -> 2560
// short No_iteration=5;
//int n_segments=1;
//double rate=0.333;
//int nom_rate=1;
//int denom_rate=3;
//double SNR0=-2.0,SNR,SNR_lin;
//unsigned char qbits=8;
// unsigned int decoded_errors[10000]; // initiate the size of matrix equivalent to size of SNR
//int c,i=0, i1 = 0;
// int n_trials = 1;
// double SNR_step = 0.1;
// randominit(0);
//int test_uncoded= 0;
//short BG=1,Zc,Kb;
// cpu_freq_GHz = get_cpu_freq_GHz();
//printf("the decoder supports BG2, Kb=10, Z=128 & 256\n");
//printf(" range of blocklength: 1201 -> 1280, 2401 -> 2560\n");
// printf("block length %d: \n", block_length);
//printf("n_trials %d: \n", n_trials);
// printf("SNR0 %f: \n", SNR0);
//find minimum value in all sets of lifting size
/* Zc=0;
for (i1=0; i1 < 51; i1++)
{
if (lift_size[i1] >= (double) block_length/Kb)
{
Zc = lift_size[i1];
//printf("%d\n",Zc);
break;
}
}*/
// Allocate LDPC decoder buffers
// p_nrLDPC_procBuf = nrLDPC_init_mem();
t_nrLDPC_procBuf cnProcBuf;
t_nrLDPC_procBuf* p_procBuf = &cnProcBuf;
// load_nrLDPClib();
t_nrLDPC_lut lut_numCnInCnGroups;
t_nrLDPC_lut* p_lut = &lut_numCnInCnGroups;
// load_nrLDPClib_ref("_orig", &encoder_orig);
nrLDPC_cnProc_BG1(p_lut,p_procBuf,384);
//nrLDPC_cnProc_BG1(&lut_numCnInCnGroups, &cnProcBuf, 380);
//for (block_length=8;block_length<=MAX_BLOCK_LENGTH;block_length+=8)
//determine number of bits in codeword
/*
char fname[200];
sprintf(fname,"cnProc_BG1_Zc_%d.c",384);
FILE *fd=fopen(fname,"w");
// AssertFatal(fd!=NULL,"cannot open %s\n",fname);
*/
//fclose(fd);
return(0);
}
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