Files
openairinterface5g/openair1/PHY/NR_TRANSPORT/nr_dlsch_coding.c
2026-07-09 07:57:51 +02:00

279 lines
11 KiB
C

/*
* SPDX-License-Identifier: LicenseRef-CSSL-1.0
*/
/*! \file PHY/NR_TRANSPORT/nr_dlsch_coding_slot.c
* \brief Top-level routines for implementing LDPC-coded (DLSCH) transport channels from 38-212, 15.2
*/
#include "PHY/defs_gNB.h"
#include "PHY/CODING/coding_extern.h"
#include "PHY/CODING/coding_defs.h"
#include "PHY/CODING/nrLDPC_coding/nrLDPC_coding_interface.h"
#include "PHY/CODING/nrLDPC_extern.h"
#include "PHY/NR_TRANSPORT/nr_transport_proto.h"
#include "PHY/NR_TRANSPORT/nr_transport_common_proto.h"
#include "PHY/NR_TRANSPORT/nr_dlsch.h"
#include "SCHED_NR/sched_nr.h"
#include "common/utils/LOG/log.h"
#include "common/utils/nr/nr_common.h"
#include <syscall.h>
#include <openair2/UTIL/OPT/opt.h>
// #define DEBUG_DLSCH_CODING
// #define DEBUG_DLSCH_FREE 1
void free_gNB_dlsch(NR_gNB_DLSCH_t *dlsch, uint16_t N_RB, const NR_DL_FRAME_PARMS *frame_parms)
{
int max_layers = min(frame_parms->nb_antennas_tx, NR_MAX_NB_LAYERS);
uint16_t a_segments = MAX_NUM_NR_DLSCH_SEGMENTS_PER_LAYER * max_layers;
if (N_RB != 273) {
a_segments = a_segments * N_RB;
a_segments = a_segments / 273 + 1;
}
if (dlsch->b) {
free16(dlsch->b, a_segments * 1056);
dlsch->b = NULL;
}
if (dlsch->f) {
free16(dlsch->f, N_RB * frame_parms->symbols_per_slot * NR_NB_SC_PER_RB * 8 * NR_MAX_NB_LAYERS);
dlsch->f = NULL;
}
for (int r = 0; r < a_segments; r++) {
free(dlsch->c[r]);
dlsch->c[r] = NULL;
}
free(dlsch->c);
}
NR_gNB_DLSCH_t new_gNB_dlsch(NR_DL_FRAME_PARMS *frame_parms, uint16_t N_RB)
{
int max_layers = min(frame_parms->nb_antennas_tx, NR_MAX_NB_LAYERS);
uint16_t a_segments = MAX_NUM_NR_DLSCH_SEGMENTS_PER_LAYER * max_layers; // number of segments to be allocated
if (N_RB != 273) {
a_segments = a_segments * N_RB;
a_segments = a_segments / 273 + 1;
}
LOG_D(PHY, "Allocating %d segments (MAX %d, N_PRB %d)\n", a_segments, MAX_NUM_NR_DLSCH_SEGMENTS_PER_LAYER, N_RB);
uint32_t dlsch_bytes = a_segments * 1056; // allocated bytes per segment
NR_gNB_DLSCH_t dlsch = {0};
dlsch.b = malloc16(dlsch_bytes);
AssertFatal(dlsch.b, "cannot allocate memory for dlsch.b\n");
bzero(dlsch.b, dlsch_bytes);
dlsch.c = (uint8_t **)malloc16(a_segments * sizeof(uint8_t *));
for (int r = 0; r < a_segments; r++) {
// account for filler in first segment and CRCs for multiple segment case
// [hna] 8448 is the maximum CB size in NR
// 68*348 = 68*(maximum size of Zc)
// In section 5.3.2 in 38.212, the for loop is up to N + 2*Zc (maximum size of N is 66*Zc, therefore 68*Zc)
dlsch.c[r] = malloc16(8448);
AssertFatal(dlsch.c[r], "cannot allocate dlsch.c[%d]\n", r);
bzero(dlsch.c[r], 8448);
}
dlsch.f = malloc16(N_RB * frame_parms->symbols_per_slot * NR_NB_SC_PER_RB * 8 * NR_MAX_NB_LAYERS);
AssertFatal(dlsch.f, "cannot allocate dlsch->f\n");
bzero(dlsch.f, N_RB * frame_parms->symbols_per_slot * NR_NB_SC_PER_RB * 8 * NR_MAX_NB_LAYERS);
return (dlsch);
}
int nr_dlsch_encoding(PHY_VARS_gNB *gNB,
int n_dlsch,
NR_gNB_DLSCH_t *dlsch_array,
int frame,
uint8_t slot,
unsigned char *output,
time_stats_t *tinput,
time_stats_t *tinput_memcpy,
time_stats_t *tprep,
time_stats_t *tparity,
time_stats_t *toutput,
time_stats_t *tconcat,
time_stats_t *dlsch_rate_matching_stats,
time_stats_t *dlsch_interleaving_stats,
time_stats_t *dlsch_segmentation_stats)
{
nrLDPC_TB_encoding_parameters_t TBs[n_dlsch];
memset(TBs, 0, sizeof(TBs));
int num_segments = 0;
for (int i = 0; i < n_dlsch; i++) {
NR_gNB_DLSCH_t *dlsch = &dlsch_array[i];
unsigned int crc = 1;
const nfapi_nr_dl_tti_pdsch_pdu_rel15_t *rel15 = &dlsch->pdsch_pdu->pdsch_pdu_rel15;
uint32_t A = rel15->TBSize[0] << 3;
unsigned char *a = dlsch->pdu;
if (rel15->rnti != SI_RNTI) {
ws_trace_t tmp = {.nr = true,
.direction = DIRECTION_DOWNLINK,
.type = gNB->frame_parms.frame_type == FDD ? FDD_RADIO : TDD_RADIO,
.pdu_buffer = a,
.pdu_buffer_size = rel15->TBSize[0],
.ueid = 0,
.rntiType = WS_C_RNTI,
.rnti = rel15->rnti,
.sysFrame = frame,
.subframe = slot,
.harq_pid = 0, // difficult to find the harq pid here
.oob_event = 0,
.oob_event_value = 0};
trace_pdu(&tmp);
}
NR_gNB_PHY_STATS_t *phy_stats = NULL;
if (rel15->rnti != 0xFFFF)
phy_stats = get_phy_stats(gNB, rel15->rnti);
if (phy_stats) {
phy_stats->frame = frame;
phy_stats->dlsch_stats.total_bytes_tx += rel15->TBSize[0];
phy_stats->dlsch_stats.current_RI = rel15->nrOfLayers;
phy_stats->dlsch_stats.current_Qm = rel15->qamModOrder[0];
}
int max_bytes = MAX_NUM_NR_DLSCH_SEGMENTS_PER_LAYER * rel15->nrOfLayers * 1056;
int B;
if (A > NR_MAX_PDSCH_TBS) {
// Add 24-bit crc (polynomial A) to payload
crc = crc24a(a, A) >> 8;
a[A >> 3] = ((uint8_t *)&crc)[2];
a[1 + (A >> 3)] = ((uint8_t *)&crc)[1];
a[2 + (A >> 3)] = ((uint8_t *)&crc)[0];
// printf("CRC %x (A %d)\n",crc,A);
// printf("a0 %d a1 %d a2 %d\n", a[A>>3], a[1+(A>>3)], a[2+(A>>3)]);
B = A + 24;
AssertFatal((A / 8) + 4 <= max_bytes, "A %d is too big (A/8+4 = %d > %d)\n", A, (A / 8) + 4, max_bytes);
memcpy(dlsch->b, a, (A / 8) + 4); // why is this +4 if the CRC is only 3 bytes?
} else {
// Add 16-bit crc (polynomial A) to payload
crc = crc16(a, A) >> 16;
a[A >> 3] = ((uint8_t *)&crc)[1];
a[1 + (A >> 3)] = ((uint8_t *)&crc)[0];
// printf("CRC %x (A %d)\n",crc,A);
// printf("a0 %d a1 %d \n", a[A>>3], a[1+(A>>3)]);
B = A + 16;
AssertFatal((A / 8) + 3 <= max_bytes, "A %d is too big (A/8+3 = %d > %d)\n", A, (A / 8) + 3, max_bytes);
memcpy(dlsch->b, a, (A / 8) + 3); // using 3 bytes to mimic the case of 24 bit crc
}
nrLDPC_TB_encoding_parameters_t *TB_parameters = &TBs[i];
// The harq_pid is not unique among the active HARQ processes in the instance so we use i instead
TB_parameters->harq_unique_pid = i;
TB_parameters->BG = rel15->maintenance_parms_v3.ldpcBaseGraph;
TB_parameters->A = A;
start_meas(dlsch_segmentation_stats);
TB_parameters->Kb = nr_segmentation(dlsch->b,
dlsch->c,
B,
&TB_parameters->C,
&TB_parameters->K,
&TB_parameters->Z,
&TB_parameters->F,
TB_parameters->BG);
stop_meas(dlsch_segmentation_stats);
if (TB_parameters->C > MAX_NUM_NR_DLSCH_SEGMENTS_PER_LAYER * rel15->nrOfLayers) {
LOG_E(PHY, "nr_segmentation.c: too many segments %d, B %d\n", TB_parameters->C, B);
return (-1);
}
num_segments += TB_parameters->C;
}
nrLDPC_segment_encoding_parameters_t segments[num_segments];
memset(segments, 0, sizeof(segments));
size_t segments_offset = 0;
size_t dlsch_offset = 0;
for (int i = 0; i < n_dlsch; i++) {
NR_gNB_DLSCH_t *dlsch = &dlsch_array[i];
const nfapi_nr_dl_tti_pdsch_pdu_rel15_t *rel15 = &dlsch->pdsch_pdu->pdsch_pdu_rel15;
nrLDPC_TB_encoding_parameters_t *TB_parameters = &TBs[i];
#ifdef DEBUG_DLSCH_CODING
for (int r = 0; r < TB_parameters->C; r++) {
LOG_D(PHY, "Encoder: B %d F %d \n", dlsch->B, TB_parameters->F);
LOG_D(PHY, "start ldpc encoder segment %d/%d\n", r, TB_parameters->C);
LOG_D(PHY, "input %d %d %d %d %d \n", dlsch->c[r][0], dlsch->c[r][1], dlsch->c[r][2], dlsch->c[r][3], dlsch->c[r][4]);
for (int cnt = 0; cnt < 22 * (TB_parameters->Z) / 8; cnt++) {
LOG_D(PHY, "%d ", dlsch->c[r][cnt]);
}
LOG_D(PHY, "\n");
}
#endif
int rbsize = dlsch->freq_alloc.num_rbs;
TB_parameters->nb_rb = rbsize;
TB_parameters->Qm = rel15->qamModOrder[0];
TB_parameters->mcs = rel15->mcsIndex[0];
TB_parameters->nb_layers = rel15->nrOfLayers;
TB_parameters->rv_index = rel15->rvIndex[0];
int nb_re_dmrs =
(rel15->dmrsConfigType == NFAPI_NR_DMRS_TYPE1) ? (6 * rel15->numDmrsCdmGrpsNoData) : (4 * rel15->numDmrsCdmGrpsNoData);
TB_parameters->G = nr_get_G(rbsize,
rel15->NrOfSymbols,
nb_re_dmrs,
get_num_dmrs(rel15->dlDmrsSymbPos),
dlsch->unav_res,
rel15->qamModOrder[0],
rel15->nrOfLayers);
TB_parameters->tbslbrm = rel15->maintenance_parms_v3.tbSizeLbrmBytes;
TB_parameters->output = &output[dlsch_offset >> 3];
TB_parameters->segments = &segments[segments_offset];
for (int r = 0; r < TB_parameters->C; r++) {
nrLDPC_segment_encoding_parameters_t *segment_parameters = &TB_parameters->segments[r];
int E = nr_get_E(TB_parameters->G, TB_parameters->C, TB_parameters->Qm, rel15->nrOfLayers, r);
if (E < 0)
return -1;
segment_parameters->c = dlsch->c[r];
segment_parameters->E = E;
reset_meas(&segment_parameters->ts_interleave);
reset_meas(&segment_parameters->ts_rate_match);
reset_meas(&segment_parameters->ts_ldpc_encode);
}
segments_offset += TB_parameters->C;
/* output and its parts for each dlsch should be aligned on 64 bytes (or 8 * 64 bits)
* => dlsch_offset should remain a multiple of 8 * 64 with enough offset to fit each dlsch
*/
const size_t dlsch_size = rbsize * gNB->frame_parms.symbols_per_slot * NR_NB_SC_PER_RB * rel15->qamModOrder[0] * rel15->nrOfLayers;
dlsch_offset += ceil_mod(dlsch_size, 8 * 64);
}
nrLDPC_slot_encoding_parameters_t slot_parameters = {.frame = frame,
.slot = slot,
.nb_TBs = n_dlsch,
.threadPool = &gNB->threadPool,
.tinput = tinput,
.tprep = tprep,
.tparity = tparity,
.toutput = toutput,
.TBs = TBs};
gNB->nrLDPC_coding_interface.nrLDPC_coding_encoder(&slot_parameters);
for (int i = 0; i < n_dlsch; i++) {
nrLDPC_TB_encoding_parameters_t *TB_parameters = &TBs[i];
for (int r = 0; r < TB_parameters->C; r++) {
nrLDPC_segment_encoding_parameters_t *segment_parameters = &TB_parameters->segments[r];
merge_meas(dlsch_interleaving_stats, &segment_parameters->ts_interleave);
merge_meas(dlsch_rate_matching_stats, &segment_parameters->ts_rate_match);
// merge_meas(, &segment_parameters->ts_ldpc_encode);
}
}
return 0;
}