Commit b2bdf7eb authored by Raymond Knopp's avatar Raymond Knopp

temporary commit

parent adf76a5f
......@@ -185,7 +185,7 @@ set(CMAKE_EXE_LINKER_FLAGS "${CMAKE_EXE_LINKER_FLAGS} -Wl,-rpath -Wl,${CMAKE_CU
# set a flag for changes in the source code
# these changes are related to hardcoded path to include .h files
set(CMAKE_C_FLAGS_DEBUG "${CMAKE_C_FLAGS} -g -DMALLOC_CHECK_=3")
set(CMAKE_C_FLAGS_RELWITHDEBINFO "${CMAKE_C_FLAGS} -g -DMALLOC_CHECK_=3 -O2")
set(CMAKE_C_FLAGS_RELWITHDEBINFO "${CMAKE_C_FLAGS} -g -DMALLOC_CHECK_=3 -O3")
set(GIT_BRANCH "UNKNOWN")
......@@ -1590,6 +1590,7 @@ set(L2_NR_SRC
${NR_RRC_DIR}/L2_nr_interface.c
${NR_RRC_DIR}/nr_rrc_config.c
${NR_RRC_DIR}/rrc_gNB_nsa.c
${NR_RRC_DIR}/rrc_gNB_internode.c
${NR_RRC_DIR}/rrc_gNB_reconfig.c
${NR_RRC_DIR}/rrc_gNB_UE_context.c
)
......
......@@ -886,15 +886,18 @@ void init_gNB(int single_thread_flag,int wait_for_sync) {
PHY_VARS_gNB *gNB;
LOG_I(PHY,"[nr-softmodem.c] gNB (%p) structure about to allocated RC.nb_nr_L1_inst:%d\n",RC.gNB,RC.nb_nr_L1_inst);
if (RC.gNB == NULL) RC.gNB = (PHY_VARS_gNB **) malloc((1+RC.nb_nr_L1_inst)*sizeof(PHY_VARS_gNB *));
if (RC.gNB == NULL) {
RC.gNB = (PHY_VARS_gNB **) malloc((1+RC.nb_nr_L1_inst)*sizeof(PHY_VARS_gNB *));
for (inst=0; inst<RC.nb_nr_L1_inst; inst++) {
RC.gNB[inst] = (PHY_VARS_gNB *) malloc(sizeof(PHY_VARS_gNB));
memset((void*)RC.gNB[inst],0,sizeof(PHY_VARS_gNB));
}
}
LOG_I(PHY,"gNB L1 structure RC.gNB allocated @ %p\n",RC.gNB);
for (inst=0; inst<RC.nb_nr_L1_inst; inst++) {
if (RC.gNB[inst] == NULL) {
RC.gNB[inst] = (PHY_VARS_gNB *) malloc(sizeof(PHY_VARS_gNB));
memset((void*)RC.gNB[inst],0,sizeof(PHY_VARS_gNB));
}
LOG_I(PHY,"[lte-softmodem.c] gNB structure RC.gNB[%d] allocated @ %p\n",inst,RC.gNB[inst]);
gNB = RC.gNB[inst];
gNB->abstraction_flag = 0;
......
......@@ -87,23 +87,29 @@ static inline void nrLDPC_cnProc_BG2(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_pr
// Set of results pointer to correct BN address
p_cnProcBufResBit = p_cnProcBufRes + (j*bitOffsetInGroup);
__m256i *pj0 = &p_cnProcBuf[lut_idxCnProcG3[j][0]];
__m256i *pj1 = &p_cnProcBuf[lut_idxCnProcG3[j][1]];
// Loop over CNs
for (i=0; i<M; i++)
{
// Abs and sign of 32 CNs (first BN)
ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][0] + i];
ymm0 = pj0[i];
sgn = _mm256_sign_epi8(*p_ones, ymm0);
min = _mm256_abs_epi8(ymm0);
// 32 CNs of second BN
ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][1] + i];
// ymm0 = p_cnProcBuf[lut_idxCnProcG3[j][1] + i];
ymm0 = pj1[i];
min = _mm256_min_epu8(min, _mm256_abs_epi8(ymm0));
sgn = _mm256_sign_epi8(sgn, ymm0);
// Store result
min = _mm256_min_epu8(min, *p_maxLLR); // 128 in epi8 is -127
*p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
p_cnProcBufResBit++;
//*p_cnProcBufResBit = _mm256_sign_epi8(min, sgn);
//p_cnProcBufResBit++;
p_cnProcBufResBit[i]=_mm256_sign_epi8(min, sgn);
}
}
}
......
......@@ -39,7 +39,7 @@
#include "nrLDPC_bnProc.h"
#define NR_LDPC_ENABLE_PARITY_CHECK
//#define NR_LDPC_PROFILER_DETAIL
#define NR_LDPC_PROFILER_DETAIL
#ifdef NR_LDPC_DEBUG_MODE
#include "nrLDPC_tools/nrLDPC_debug.h"
......
......@@ -153,17 +153,17 @@ static inline void nrLDPC_cn2bnProcBuf(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_
for (j=0; j<3; j++)
{
p_cnProcBufRes = &cnProcBufRes[lut_startAddrCnGroups[0] + j*bitOffsetInGroup];
for (i=0; i<M; i++)
{
bnProcBuf[p_lut_cn2bn[j*M + i]] = p_cnProcBufRes[i];
}
}
}
// =====================================================================
// CN group with 4 BNs
p_lut_cn2bn += (M*3); // Number of elements of previous group
// p_lut_cn2bn += (M*3); // Number of elements of previous group
M = lut_numCnInCnGroups[1]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG2_R15[1]*NR_LDPC_ZMAX;
......@@ -278,11 +278,10 @@ static inline void nrLDPC_cn2bnProcBuf_BG1(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf
for (j=0; j<3; j++)
{
p_cnProcBufRes = &cnProcBufRes[lut_startAddrCnGroups[0] + j*bitOffsetInGroup];
for (i=0; i<M; i++)
{
bnProcBuf[p_lut_cn2bn[j*M + i]] = p_cnProcBufRes[i];
}
}
}
// =====================================================================
......@@ -422,6 +421,32 @@ static inline void nrLDPC_cn2bnProcBuf_BG1(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf
}
}
static inline uint32_t *bn2cnmap(uint32_t* p_lut_cn2bn,int8_t *p_cnProcBuf,int8_t *bnProcBufRes,int M2) __attribute__((always_inline));
static inline uint32_t *bn2cnmap(uint32_t* p_lut_cn2bn,int8_t *p_cnProcBuf,int8_t *bnProcBufRes,int M2) {
__m128i tmp;
for (int i=0;i<M2;i++) {
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],0);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],1);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],2);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],3);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],4);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],5);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],6);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],7);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],8);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],9);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],10);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],11);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],12);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],13);
tmp=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],14);
((__m128i *)p_cnProcBuf)[i]=_mm_insert_epi8(tmp,bnProcBufRes[*p_lut_cn2bn++],15);
}
return(p_lut_cn2bn);
}
/**
\brief Copies the values in the BN processing results buffer to their corresponding place in the CN processing buffer for BG2.
......@@ -457,7 +482,6 @@ static inline void nrLDPC_bn2cnProcBuf(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_
for (j=0; j<2; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[0] + j*bitOffsetInGroup];
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
......@@ -474,7 +498,6 @@ static inline void nrLDPC_bn2cnProcBuf(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_
for (j=0; j<3; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[1] + j*bitOffsetInGroup];
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
......@@ -491,7 +514,6 @@ static inline void nrLDPC_bn2cnProcBuf(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_
for (j=0; j<4; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[2] + j*bitOffsetInGroup];
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
......@@ -508,7 +530,6 @@ static inline void nrLDPC_bn2cnProcBuf(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_
for (j=0; j<5; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[3] + j*bitOffsetInGroup];
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
......@@ -521,7 +542,6 @@ static inline void nrLDPC_bn2cnProcBuf(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_
p_lut_cn2bn += (M*6); // Number of elements of previous group
M = lut_numCnInCnGroups[4]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG2_R15[4]*NR_LDPC_ZMAX;
for (j=0; j<8; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[4] + j*bitOffsetInGroup];
......@@ -542,7 +562,7 @@ static inline void nrLDPC_bn2cnProcBuf(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_
for (j=0; j<10; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[5] + j*bitOffsetInGroup];
printf("5 BN: cNProcBuf output at %d\n",lut_startAddrCnGroups[5] + j*bitOffsetInGroup);
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
......@@ -551,6 +571,7 @@ static inline void nrLDPC_bn2cnProcBuf(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf* p_
}
/**
\brief Copies the values in the BN processing results buffer to their corresponding place in the CN processing buffer for BG1.
\param p_lut Pointer to decoder LUTs
......@@ -566,7 +587,7 @@ static inline void nrLDPC_bn2cnProcBuf_BG1(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf
int8_t* bnProcBufRes = p_procBuf->bnProcBufRes;
int8_t* p_cnProcBuf;
const uint32_t* p_lut_cn2bn;
uint32_t* p_lut_cn2bn;
uint32_t bitOffsetInGroup;
uint32_t i;
uint32_t j;
......@@ -582,153 +603,343 @@ static inline void nrLDPC_bn2cnProcBuf_BG1(t_nrLDPC_lut* p_lut, t_nrLDPC_procBuf
M = lut_numCnInCnGroups[0]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[0]*NR_LDPC_ZMAX;
for (j=0; j<2; j++)
for (j=0;j<2; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[0] + j*bitOffsetInGroup];
p_lut_cn2bn = bn2cnmap(p_lut_cn2bn,p_cnProcBuf,bnProcBufRes,M>>4);
/*
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
// p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
p_cnProcBuf[i] = bnProcBufRes[*p_lut_cn2bn++];
}
*/
}
// =====================================================================
// CN group with 4 BNs
p_lut_cn2bn += (M*3); // Number of elements of previous group
// p_lut_cn2bn += (M*3); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[1]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[1]*NR_LDPC_ZMAX;
for (j=0; j<3; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[1] + j*bitOffsetInGroup];
p_lut_cn2bn = bn2cnmap(p_lut_cn2bn,p_cnProcBuf,bnProcBufRes,M>>4);
/*
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
}
// p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
p_cnProcBuf[i] = bnProcBufRes[*p_lut_cn2bn++];
}*/
}
// =====================================================================
// CN group with 5 BNs
p_lut_cn2bn += (M*4); // Number of elements of previous group
// p_lut_cn2bn += (M*4); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[2]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[2]*NR_LDPC_ZMAX;
for (j=0; j<4; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[2] + j*bitOffsetInGroup];
p_lut_cn2bn = bn2cnmap(p_lut_cn2bn,p_cnProcBuf,bnProcBufRes,M>>4);
/*
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
}
// p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
p_cnProcBuf[i] = bnProcBufRes[*p_lut_cn2bn++];
}*/
}
// =====================================================================
// CN group with 6 BNs
p_lut_cn2bn += (M*5); // Number of elements of previous group
// p_lut_cn2bn += (M*5); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[3]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[3]*NR_LDPC_ZMAX;
for (j=0; j<5; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[3] + j*bitOffsetInGroup];
p_lut_cn2bn = bn2cnmap(p_lut_cn2bn,p_cnProcBuf,bnProcBufRes,M>>4);
/*
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
}
// p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
p_cnProcBuf[i] = bnProcBufRes[*p_lut_cn2bn++];
}*/
}
// =====================================================================
// CN group with 7 BNs
p_lut_cn2bn += (M*6); // Number of elements of previous group
// p_lut_cn2bn += (M*6); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[4]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[4]*NR_LDPC_ZMAX;
for (j=0; j<6; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[4] + j*bitOffsetInGroup];
p_lut_cn2bn = bn2cnmap(p_lut_cn2bn,p_cnProcBuf,bnProcBufRes,M>>4);
/*
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
}
// p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
p_cnProcBuf[i] = bnProcBufRes[*p_lut_cn2bn++];
}*/
}
// =====================================================================
// CN group with 8 BNs
p_lut_cn2bn += (M*7); // Number of elements of previous group
// p_lut_cn2bn += (M*7); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[5]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[5]*NR_LDPC_ZMAX;
for (j=0; j<7; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[5] + j*bitOffsetInGroup];
p_lut_cn2bn = bn2cnmap(p_lut_cn2bn,p_cnProcBuf,bnProcBufRes,M>>4);
/*
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
}
// p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
p_cnProcBuf[i] = bnProcBufRes[*p_lut_cn2bn++];
}*/
}
// =====================================================================
// CN group with 9 BNs
p_lut_cn2bn += (M*8); // Number of elements of previous group
// p_lut_cn2bn += (M*8); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[6]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[6]*NR_LDPC_ZMAX;
for (j=0; j<8; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[6] + j*bitOffsetInGroup];
p_lut_cn2bn = bn2cnmap(p_lut_cn2bn,p_cnProcBuf,bnProcBufRes,M>>4);
/*
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
}
// p_lut_cn2bn += (M*8); // Number of elements of previous group
p_cnProcBuf[i] = bnProcBufRes[*p_lut_cn2bn++];
}*/
}
// =====================================================================
// CN group with 10 BNs
p_lut_cn2bn += (M*9); // Number of elements of previous group
// p_lut_cn2bn += (M*9); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[7]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[7]*NR_LDPC_ZMAX;
for (j=0; j<9; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[7] + j*bitOffsetInGroup];
p_lut_cn2bn = bn2cnmap(p_lut_cn2bn,p_cnProcBuf,bnProcBufRes,M>>4);
/*
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
}
// p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
p_cnProcBuf[i] = bnProcBufRes[*p_lut_cn2bn++];
}*/
}
// =====================================================================
// CN group with 19 BNs
p_lut_cn2bn += (M*10); // Number of elements of previous group
// p_lut_cn2bn += (M*10); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[8]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[8]*NR_LDPC_ZMAX;
for (j=0; j<19; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[8] + j*bitOffsetInGroup];
p_lut_cn2bn = bn2cnmap(p_lut_cn2bn,p_cnProcBuf,bnProcBufRes,M>>4);
/*
for (i=0; i<M; i++)
{
p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
}
// p_cnProcBuf[i] = bnProcBufRes[p_lut_cn2bn[j*M + i]];
p_cnProcBuf[i] = bnProcBufRes[*p_lut_cn2bn++];
}*/
}
}
static inline void memcpy_printer(uint32_t* p_lut_cn2bn,int dest0,int M) {
int dest=0,src=p_lut_cn2bn[0],len=1;
for (int i=1;i<M;i++) {
if (p_lut_cn2bn[i]!= (1+p_lut_cn2bn[i-1])) {
printf("memcpy(%d,%d,%d)\n",dest0+dest,src,len);
len=1;
dest=i;
src=p_lut_cn2bn[i];
}
else if (i==(M-1)) printf("memcpy(%d,%d,%d)\n",dest0+dest,src,len);
else len++;
// printf("p_lut_cn2bn[%d] : %d\n",i,p_lut_cn2bn[i]);
}
}
static inline void nrLDPC_prep_bn2cnProcBuf_BG1(t_nrLDPC_lut* p_lut, uint16_t Z)
{
const uint32_t* lut_cn2bnProcBuf = p_lut->cn2bnProcBuf;
const uint32_t* lut_cn2bnProcBuf2 = p_lut->cn2bnProcBuf2;
const uint8_t* lut_numCnInCnGroups = p_lut->numCnInCnGroups;
const uint32_t* lut_startAddrCnGroups = p_lut->startAddrCnGroups;
uint32_t* p_lut_cn2bn;
uint32_t bitOffsetInGroup;
uint32_t i;
uint32_t j;
uint32_t M;
// For CN groups 3 to 19 no need to send the last BN back since it's single edge
// and BN processing does not change the value already in the CN proc buf
// =====================================================================
// CN group with 3 BNs
p_lut_cn2bn = &lut_cn2bnProcBuf[0];
M = lut_numCnInCnGroups[0]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[0]*NR_LDPC_ZMAX;
for (j=0;j<2; j++)
{
printf("******3 BN (%d): cNProcBuf output at %d\n",j,lut_startAddrCnGroups[0] + j*bitOffsetInGroup);
memcpy_printer(p_lut_cn2bn,lut_startAddrCnGroups[0] + j*bitOffsetInGroup,M);
}
// =====================================================================
// CN group with 4 BNs
p_lut_cn2bn += (M*3); // Number of elements of previous group
M = lut_numCnInCnGroups[1]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[1]*NR_LDPC_ZMAX;
for (j=0; j<3; j++)
{
printf("******4 BN (%d): cNProcBuf output at %d\n",j,lut_startAddrCnGroups[1] + j*bitOffsetInGroup);
memcpy_printer(p_lut_cn2bn,lut_startAddrCnGroups[0] + j*bitOffsetInGroup,M);
}
// =====================================================================
// CN group with 5 BNs
// p_lut_cn2bn += (M*4); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[2]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[2]*NR_LDPC_ZMAX;
for (j=0; j<4; j++)
{
printf("******5 BN (%d): cNProcBuf output at %d\n",j,lut_startAddrCnGroups[2] + j*bitOffsetInGroup);
memcpy_printer(p_lut_cn2bn,lut_startAddrCnGroups[0] + j*bitOffsetInGroup,M);
}
// =====================================================================
// CN group with 6 BNs
// p_lut_cn2bn += (M*5); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[3]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[3]*NR_LDPC_ZMAX;
for (j=0; j<5; j++)
{
printf("******6 BN (%d): cNProcBuf output at %d\n",j,lut_startAddrCnGroups[3] + j*bitOffsetInGroup);
}
// =====================================================================
// CN group with 7 BNs
// p_lut_cn2bn += (M*6); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[4]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[4]*NR_LDPC_ZMAX;
for (j=0; j<6; j++)
{
printf("******7 BN (%d): cNProcBuf output at %d\n",j,lut_startAddrCnGroups[4] + j*bitOffsetInGroup);
}
// =====================================================================
// CN group with 8 BNs
// p_lut_cn2bn += (M*7); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[5]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[5]*NR_LDPC_ZMAX;
for (j=0; j<7; j++)
{
printf("******8 BN (%d): cNProcBuf output at %d\n",j,lut_startAddrCnGroups[5] + j*bitOffsetInGroup);
}
// =====================================================================
// CN group with 9 BNs
// p_lut_cn2bn += (M*8); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[6]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[6]*NR_LDPC_ZMAX;
for (j=0; j<8; j++)
{
printf("******9 BN (%d): cNProcBuf output at %d\n",j,lut_startAddrCnGroups[6] + j*bitOffsetInGroup);
}
// =====================================================================
// CN group with 10 BNs
// p_lut_cn2bn += (M*9); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[7]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[7]*NR_LDPC_ZMAX;
for (j=0; j<9; j++)
{
p_cnProcBuf = &cnProcBuf[lut_startAddrCnGroups[7] + j*bitOffsetInGroup];
printf("******10 BN (%d): cNProcBuf output at %d\n",j,lut_startAddrCnGroups[7] + j*bitOffsetInGroup);
}
// =====================================================================
// CN group with 19 BNs
// p_lut_cn2bn += (M*10); // Number of elements of previous group
p_lut_cn2bn += M; // Number of elements of previous group
M = lut_numCnInCnGroups[8]*Z;
bitOffsetInGroup = lut_numCnInCnGroups_BG1_R13[8]*NR_LDPC_ZMAX;
for (j=0; j<19; j++)
{
printf("******19 BN (%d): cNProcBuf output at %d\n",j,lut_startAddrCnGroups[8] + j*bitOffsetInGroup);
}
}
/**
\brief Copies the values in the LLR results buffer to their corresponding place in the output LLR vector.
......
......@@ -48,6 +48,7 @@ typedef struct nrLDPC_lut {
const uint32_t* llr2CnProcBuf; /**< LUT for input LLRs to CN processing buffer */
const uint8_t* numEdgesPerBn; /**< LUT with number of edges per BN */
const uint32_t* cn2bnProcBuf; /**< LUT for transferring CN processing results to BN processing buffer */
const uint32_t* cn2bnProcBuf2; /**< LUT for transferring CN processing results to BN processing buffer */
const uint16_t* llr2llrProcBuf; /**< LUT for transferring input LLRs to LLR processing buffer */
} t_nrLDPC_lut;
......
......@@ -377,10 +377,14 @@ typedef struct {
NR_ServingCellConfigCommon_t *servingcellconfigcommon;
NR_RRCReconfiguration_t *reconfig[MAX_NR_RRC_UE_CONTEXTS];
NR_RadioBearerConfig_t *rb_config[MAX_NR_RRC_UE_CONTEXTS];
NR_CellGroupConfig_t *secondaryCellGroup[MAX_NR_RRC_UE_CONTEXTS];
NR_SRB_INFO SI;
NR_SRB_INFO Srb0;
int initial_csi_index[MAX_NR_RRC_UE_CONTEXTS];
int n_physical_antenna_ports;
} rrc_gNB_carrier_data_t;
//---------------------------------------------------
......
......@@ -33,6 +33,11 @@
#include "RRC/NR/nr_rrc_defs.h"
#include "flexran_agent_extern.h"
#include "NR_RRCReconfiguration.h"
#include "NR_UE-NR-Capability.h"
#include "NR_UE-CapabilityRAT-ContainerList.h"
#include "NR_CG-Config.h"
#include "NR_CG-ConfigInfo.h"
int rrc_init_nr_global_param(void);
......@@ -57,10 +62,36 @@ void rrc_gNB_generate_SgNBAdditionRequestAcknowledge(
rrc_gNB_ue_context_t *const ue_context_pP
);
void rrc_parse_ue_capabilities(gNB_RRC_INST *rrc,NR_UE_CapabilityRAT_ContainerList_t *UE_CapabilityRAT_ContainerList);
void rrc_add_nsa_user(gNB_RRC_INST *rrc,struct rrc_gNB_ue_context_s *ue_context_p);
void fill_default_secondaryCellGroup(NR_ServingCellConfigCommon_t *servingcellconfigcommon,
NR_RRCReconfiguration_IEs_t *reconfig,
NR_CellGroupConfig_t *secondaryCellGroup,
int scg_id,
int servCellIndex,
int n_physical_antenna_ports,
int initial_csi_index);
void fill_default_reconfig(NR_ServingCellConfigCommon_t *servingcellconfigcommon,
NR_RRCReconfiguration_IEs_t *reconfig,
NR_CellGroupConfig_t *secondaryCellGroup,
int n_physical_antenna_ports,
int initial_csi_index);
int generate_CG_Config(gNB_RRC_INST *rrc,
NR_CG_Config_t *cg_Config,
NR_RRCReconfiguration_t *reconfig,
NR_RadioBearerConfig_t *rbconfig);
int parse_CG_ConfigInfo(gNB_RRC_INST *rrc, NR_CG_ConfigInfo_t *CG_ConfigInfo);
#if defined(ENABLE_ITTI)
/**\brief RRC eNB task.
\param void *args_p Pointer on arguments to start the task. */
void *rrc_gnb_task(void *args_p);
#endif
\ No newline at end of file
#endif
......@@ -33,11 +33,24 @@
#include "nr_rrc_defs.h"
#include "NR_RRCReconfiguration.h"
#include "NR_UE-NR-Capability.h"
#include "NR_UE-CapabilityRAT-ContainerList.h"
#include "NR_CG-Config.h"
void rrc_parse_ue_capabilities(gNB_RRC_INST *rrc,BIT_STRING_t *ueCapabilityRAT_Container_nr,BIT_STRING_t *ueCapabilityRAT_Container_MRDC) {
void rrc_parse_ue_capabilities(gNB_RRC_INST *rrc,NR_UE_CapabilityRAT_ContainerList_t *UE_CapabilityRAT_ContainerList) {
struct rrc_gNB_ue_context_s *ue_context_p = NULL;
int rnti = taus()&65535;
OCTET_STRING_t *ueCapabilityRAT_Container_nr;
OCTET_STRING_t *ueCapabilityRAT_Container_MRDC;
AssertFatal(UE_CapabilityRAT_ContainerList!=NULL,"UE_CapabilityRAT_ContainerList is null\n");
AssertFatal(UE_CapabilityRAT_ContainerList->list.size != 2, "UE_CapabilityRAT_ContainerList->list.size %d != 2\n",UE_CapabilityRAT_ContainerList->list.size);
if (UE_CapabilityRAT_ContainerList->list.array[0]->rat_Type == NR_RAT_Type_nr) ueCapabilityRAT_Container_nr = &UE_CapabilityRAT_ContainerList->list.array[0]->ue_CapabilityRAT_Container;
else if (UE_CapabilityRAT_ContainerList->list.array[0]->rat_Type == NR_RAT_Type_eutra_nr) ueCapabilityRAT_Container_MRDC = &UE_CapabilityRAT_ContainerList->list.array[0]->ue_CapabilityRAT_Container;
if (UE_CapabilityRAT_ContainerList->list.array[1]->rat_Type == NR_RAT_Type_nr) ueCapabilityRAT_Container_nr = &UE_CapabilityRAT_ContainerList->list.array[1]->ue_CapabilityRAT_Container;
else if (UE_CapabilityRAT_ContainerList->list.array[1]->rat_Type == NR_RAT_Type_eutra_nr) ueCapabilityRAT_Container_MRDC = &UE_CapabilityRAT_ContainerList->list.array[1]->ue_CapabilityRAT_Container;
AssertFatal(ueCapabilityRAT_Container_nr!=NULL,"ueCapabilityRAT_Container_nr is NULL\n");
AssertFatal(ueCapabilityRAT_Container_MRDC!=NULL,"ueCapabilityRAT_Container_MRDC is NULL\n");
......@@ -83,9 +96,10 @@ void rrc_parse_ue_capabilities(gNB_RRC_INST *rrc,BIT_STRING_t *ueCapabilityRAT_C
xer_fprint(stdout, &asn_DEF_NR_UE_MRDC_Capability, ue_context_p->ue_context.UE_Capability_MRDC);
}
rrc_add_nsa_user(rrc,ue_context_p);
}
void rrc_add_nsa_user(gNB_RRC_INST *rrc) {
void rrc_add_nsa_user(gNB_RRC_INST *rrc,struct rrc_gNB_ue_context_s *ue_context_p) {
// generate nr-Config-r15 containers for LTE RRC : inside message for X2 EN-DC (CG-Config Message from 38.331)
......@@ -104,7 +118,17 @@ void rrc_add_nsa_user(gNB_RRC_INST *rrc) {
carrier->reconfig[rrc->Nb_ue]->criticalExtensions.present = NR_RRCReconfiguration__criticalExtensions_PR_rrcReconfiguration;
NR_RRCReconfiguration_IEs_t *reconfig_ies=calloc(1,sizeof(NR_RRCReconfiguration_IEs_t));
carrier->reconfig[rrc->Nb_ue]->criticalExtensions.choice.rrcReconfiguration = reconfig_ies;
fill_default_reconfig(carrier->ServingCellConfigCommon,reconfig_ies);
fill_default_reconfig(carrier->ServingCellConfigCommon,
reconfig_ies,
carrier->secondaryCellGroup[rrc->Nb_ue],
carrier->n_physical_antenna_ports,
carrier->initial_csi_index[rrc->Nb_ue]);
carrier->rb_config[rrc->Nb_ue] = calloc(1,sizeof(NR_RadioBearerConfig_t));
fill_default_rbconfig(rrc,carrier->rb_config[rrc->Nb_ue]);
NR_CG_Config_t *CG_Config = calloc(1,sizeof(*CG_Config));
memset((void*)CG_Config,0,sizeof(*CG_Config));
generate_CG_Config(rrc,CG_Config,carrier->reconfig[rrc->Nb_ue],carrier->rb_config[rrc->Nb_ue]);
// Send to X2 entity to transport to MeNB
rrc->Nb_ue++;
}
......
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