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C

/**
*
* \section COPYRIGHT
*
* Copyright 2013-2014 The libLTE Developers. See the
* COPYRIGHT file at the top-level directory of this distribution.
*
* \section LICENSE
*
* This file is part of the libLTE library.
*
* libLTE is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as
* published by the Free Software Foundation, either version 3 of
* the License, or (at your option) any later version.
*
* libLTE is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* A copy of the GNU Lesser General Public License can be found in
* the LICENSE file in the top-level directory of this distribution
* and at http://www.gnu.org/licenses/.
*
*/
#include <stdint.h>
#include <stdio.h>
#include <string.h>
#include <strings.h>
#include <stdlib.h>
#include <stdbool.h>
#include <assert.h>
#include <math.h>
#include "prb.h"
#include "liblte/phy/phch/pdsch.h"
#include "liblte/phy/common/base.h"
#include "liblte/phy/utils/bit.h"
#include "liblte/phy/utils/debug.h"
#include "liblte/phy/utils/vector.h"
const enum modem_std modulations[4] =
{ LTE_BPSK, LTE_QPSK, LTE_QAM16, LTE_QAM64 };
#define MAX_PDSCH_RE(cp) (2 * (CP_NSYMB(cp) - 1) * 12 - 6)
#define HAS_REF(l, cp, nof_ports) ((l == 1 && nof_ports == 4) \
|| l == 0 \
|| l == CP_NSYMB(cp) - 3)
int pdsch_cp(pdsch_t *q, cf_t *input, cf_t *output, ra_prb_t *prb_alloc,
int nsubframe, bool put) {
int s, n, l, lp, lstart, lend, nof_refs;
bool is_pbch, is_sss;
cf_t *in_ptr = input, *out_ptr = output;
int offset;
assert(q->cell_id >= 0);
INFO("%s %d RE from %d PRB\n", put ? "Putting" : "Getting",
prb_alloc->re_sf[nsubframe], prb_alloc->slot[0].nof_prb);
if (q->nof_ports == 1) {
nof_refs = 2;
} else {
nof_refs = 4;
}
for (s = 0; s < 2; s++) {
if (s == 0) {
lstart = prb_alloc->lstart;
} else {
lstart = 0;
}
for (l = lstart; l < CP_NSYMB(q->cp); l++) {
for (n = 0; n < prb_alloc->slot[s].nof_prb; n++) {
lend = CP_NSYMB(q->cp);
is_pbch = is_sss = false;
// Skip PSS/SSS signals
if (s == 0 && (nsubframe == 0 || nsubframe == 5)) {
if (prb_alloc->slot[s].prb_idx[n] >= q->nof_prb / 2 - 3
&& prb_alloc->slot[s].prb_idx[n] <= q->nof_prb / 2 + 3) {
lend = CP_NSYMB(q->cp) - 2;
is_sss = true;
}
}
// Skip PBCH
if (s == 1 && nsubframe == 0) {
if (prb_alloc->slot[s].prb_idx[n] >= q->nof_prb / 2 - 3
&& prb_alloc->slot[s].prb_idx[n] <= q->nof_prb / 2 + 3) {
lstart = 4;
is_pbch = true;
}
}
lp = l + s * CP_NSYMB(q->cp);
if (put) {
out_ptr = &output[(lp * q->nof_prb + prb_alloc->slot[s].prb_idx[n])
* RE_X_RB];
} else {
in_ptr = &input[(lp * q->nof_prb + prb_alloc->slot[s].prb_idx[n])
* RE_X_RB];
}
if (is_pbch && (q->nof_prb % 2)
&& (prb_alloc->slot[s].prb_idx[n] == q->nof_prb / 2 - 3
&& prb_alloc->slot[s].prb_idx[n] == q->nof_prb / 2 + 3)) {
if (l < lstart) {
prb_cp_half(&in_ptr, &out_ptr, 1);
}
}
if (l >= lstart && l < lend) {
if (HAS_REF(l, q->cp, q->nof_ports)) {
if (nof_refs == 2 && l != 0) {
offset = q->cell_id % 3 + 3;
} else {
offset = q->cell_id % 3;
}
prb_cp_ref(&in_ptr, &out_ptr, offset, nof_refs, 1, put);
} else {
prb_cp(&in_ptr, &out_ptr, 1);
}
}
if (is_sss && (q->nof_prb % 2)
&& (prb_alloc->slot[s].prb_idx[n] == q->nof_prb / 2 - 3
&& prb_alloc->slot[s].prb_idx[n] == q->nof_prb / 2 + 3)) {
if (l >= lend) {
prb_cp_half(&in_ptr, &out_ptr, 1);
}
}
}
}
}
if (put) {
return (int) (input - in_ptr);
} else {
return (int) (output - out_ptr);
}
}
/**
* Puts PDSCH in slot number 1
*
* Returns the number of symbols written to sf_symbols
*
* 36.211 10.3 section 6.3.5
*/
int pdsch_put(pdsch_t *q, cf_t *pdsch_symbols, cf_t *sf_symbols,
ra_prb_t *prb_alloc, int nsubframe) {
return pdsch_cp(q, pdsch_symbols, sf_symbols, prb_alloc, nsubframe, true);
}
/**
* Extracts PDSCH from slot number 1
*
* Returns the number of symbols written to PDSCH
*
* 36.211 10.3 section 6.3.5
*/
int pdsch_get(pdsch_t *q, cf_t *sf_symbols, cf_t *pdsch_symbols,
ra_prb_t *prb_alloc, int nsubframe) {
return pdsch_cp(q, sf_symbols, pdsch_symbols, prb_alloc, nsubframe, false);
}
/** Initializes the PDCCH transmitter and receiver */
int pdsch_init(pdsch_t *q, unsigned short user_rnti, int nof_prb, int nof_ports,
int cell_id, lte_cp_t cp) {
int ret = -1;
int i;
if (cell_id < 0) {
return -1;
}
if (nof_ports > MAX_PORTS) {
fprintf(stderr, "Invalid number of ports %d\n", nof_ports);
return -1;
}
bzero(q, sizeof(pdsch_t));
q->cell_id = cell_id;
q->cp = cp;
q->nof_ports = nof_ports;
q->nof_prb = nof_prb;
q->rnti = user_rnti;
q->max_symbols = nof_prb * MAX_PDSCH_RE(cp);
INFO("Init PDSCH: %d ports %d PRBs, max_symbols: %d\n", q->nof_ports,
q->nof_prb, q->max_symbols);
for (i = 0; i < 4; i++) {
if (modem_table_std(&q->mod[i], modulations[i], true)) {
goto clean;
}
}
if (crc_init(&q->crc_tb, LTE_CRC24A, 24)) {
goto clean;
}
if (crc_init(&q->crc_cb, LTE_CRC24B, 24)) {
goto clean;
}
demod_soft_init(&q->demod);
demod_soft_alg_set(&q->demod, APPROX);
for (i = 0; i < NSUBFRAMES_X_FRAME; i++) {
if (sequence_pdsch(&q->seq_pdsch[i], q->rnti, 0, 2 * i, q->cell_id,
q->max_symbols * q->mod[3].nbits_x_symbol)) {
goto clean;
}
}
if (tcod_init(&q->encoder, MAX_LONG_CB)) {
goto clean;
}
if (tdec_init(&q->decoder, MAX_LONG_CB)) {
goto clean;
}
if (rm_turbo_init(&q->rm_turbo, 3 * MAX_LONG_CB)) {
goto clean;
}
q->cb_in_b = malloc(sizeof(char) * MAX_LONG_CB);
if (!q->cb_in_b) {
goto clean;
}
q->cb_out_b = malloc(sizeof(char) * (3 * MAX_LONG_CB + 12));
if (!q->cb_out_b) {
goto clean;
}
q->pdsch_rm_f = malloc(sizeof(float) * (3 * MAX_LONG_CB + 12));
if (!q->pdsch_rm_f) {
goto clean;
}
q->pdsch_e_bits = malloc(
sizeof(char) * q->max_symbols * q->mod[3].nbits_x_symbol);
if (!q->pdsch_e_bits) {
goto clean;
}
q->pdsch_llr = malloc(
sizeof(float) * q->max_symbols * q->mod[3].nbits_x_symbol);
if (!q->pdsch_llr) {
goto clean;
}
q->pdsch_d = malloc(sizeof(cf_t) * q->max_symbols);
if (!q->pdsch_d) {
goto clean;
}
for (i = 0; i < nof_ports; i++) {
q->ce[i] = malloc(sizeof(cf_t) * q->max_symbols);
if (!q->ce[i]) {
goto clean;
}
q->pdsch_x[i] = malloc(sizeof(cf_t) * q->max_symbols);
if (!q->pdsch_x[i]) {
goto clean;
}
q->pdsch_symbols[i] = malloc(sizeof(cf_t) * q->max_symbols);
if (!q->pdsch_symbols[i]) {
goto clean;
}
}
ret = 0;
clean: if (ret == -1) {
pdsch_free(q);
}
return ret;
}
void pdsch_free(pdsch_t *q) {
int i;
if (q->cb_in_b) {
free(q->cb_in_b);
}
if (q->cb_out_b) {
free(q->cb_out_b);
}
if (q->pdsch_e_bits) {
free(q->pdsch_e_bits);
}
if (q->pdsch_rm_f) {
free(q->pdsch_rm_f);
}
if (q->pdsch_llr) {
free(q->pdsch_llr);
}
if (q->pdsch_d) {
free(q->pdsch_d);
}
for (i = 0; i < q->nof_ports; i++) {
if (q->ce[i]) {
free(q->ce[i]);
}
if (q->pdsch_x[i]) {
free(q->pdsch_x[i]);
}
if (q->pdsch_symbols[i]) {
free(q->pdsch_symbols[i]);
}
}
for (i = 0; i < NSUBFRAMES_X_FRAME; i++) {
sequence_free(&q->seq_pdsch[i]);
}
for (i = 0; i < 4; i++) {
modem_table_free(&q->mod[i]);
}
tdec_free(&q->decoder);
tcod_free(&q->encoder);
rm_turbo_free(&q->rm_turbo);
}
struct cb_segm {
int F;
int C;
int K1;
int K2;
int C1;
int C2;
};
/* Calculate Codeblock Segmentation as in Section 5.1.2 of 36.212 */
void codeblock_segmentation(struct cb_segm *s, int tbs) {
int Bp, B, idx1;
B = tbs + 24;
/* Calculate CB sizes */
if (B < 6114) {
s->C = 1;
Bp = B;
} else {
s->C = (int) ceilf((float) B / (6114 - 24));
Bp = B + 24 * s->C;
}
idx1 = lte_find_cb_index(Bp / s->C);
s->K1 = lte_cb_size(idx1);
if (s->C == 1) {
s->K2 = 0;
s->C2 = 0;
s->C1 = 1;
} else {
s->K2 = lte_cb_size(idx1 - 1);
s->C2 = (s->C * s->K1 - Bp) / (s->K1 - s->K2);
s->C1 = s->C - s->C2;
}
s->F = s->C1 * s->K1 + s->C2 * s->K2 - Bp;
INFO(
"CB Segmentation: TBS: %d, C=%d, C+=%d K+=%d, C-=%d, K-=%d, F=%d, Bp=%d\n",
tbs, s->C, s->C1, s->K1, s->C2, s->K2, s->F, Bp);
}
/* Decode a transport block according to 36.212 5.3.2
*
*/
int pdsch_decode_tb(pdsch_t *q, char *data, int tbs, int nb_e, int rv_idx) {
char parity[24];
char *p_parity = parity;
unsigned int par_rx, par_tx;
int i;
int cb_len, rp, wp, rlen, F, n_e;
struct cb_segm cbs;
/* Compute CB segmentation for this TBS */
codeblock_segmentation(&cbs, tbs);
rp = 0;
rp = 0;
wp = 0;
for (i = 0; i < cbs.C; i++) {
/* Get read/write lengths */
if (i < cbs.C - cbs.C2) {
cb_len = cbs.K1;
} else {
cb_len = cbs.K2;
}
if (cbs.C == 1) {
rlen = cb_len;
} else {
rlen = cb_len - 24;
}
if (i == 0) {
F = cbs.F;
} else {
F = 0;
}
if (i < cbs.C - 1) {
n_e = nb_e / cbs.C;
} else {
n_e = nb_e - rp;
}
INFO("CB#%d: cb_len: %d, rlen: %d, wp: %d, rp: %d, F: %d, E: %d\n", i,
cb_len, rlen - F, wp, rp, F, n_e);
/* Rate Unmatching */
rm_turbo_rx(&q->rm_turbo, &q->pdsch_llr[rp], n_e, q->pdsch_rm_f,
3 * cb_len + 12, rv_idx);
/* Turbo Decoding */
tdec_run_all(&q->decoder, q->pdsch_rm_f, q->cb_in_b, TDEC_ITERATIONS,
cb_len);
if (cbs.C > 1) {
/* Check Codeblock CRC */
//crc_attach(&q->crc_cb, q->pdsch_b[wp], cb_len);
}
if (VERBOSE_ISDEBUG()) {
DEBUG("CB#%d Len=%d: ", i, cb_len);
vec_fprint_b(stdout, q->cb_in_b, cb_len);
}
/* Copy data to another buffer, removing the Codeblock CRC */
if (i < cbs.C - 1) {
memcpy(&data[wp], &q->cb_in_b[F], (rlen - F) * sizeof(char));
} else {
INFO("Last CB, appending parity: %d to %d from %d and 24 from %d\n",
rlen - F - 24, wp, F, rlen - 24);
/* Append Transport Block parity bits to the last CB */
memcpy(&data[wp], &q->cb_in_b[F], (rlen - F - 24) * sizeof(char));
memcpy(parity, &q->cb_in_b[rlen - 24], 24 * sizeof(char));
}
/* Set read/write pointers */
wp += (rlen - F);
rp += n_e;
}
INFO("END CB#%d: wp: %d, rp: %d\n", i, wp, rp);
// Compute transport block CRC
par_rx = crc_checksum(&q->crc_tb, data, tbs);
// check parity bits
par_tx = bit_unpack(&p_parity, 24);
if (VERBOSE_ISDEBUG()) {
DEBUG("DATA: ", 0);
vec_fprint_b(stdout, data, tbs);
DEBUG("PARITY: ", 0);
vec_fprint_b(stdout, parity, 24);
}
if (!par_rx) {
printf("\n\tCAUTION!! Received all-zero transport block\n\n");
}
return (par_rx != par_tx);
}
/** Decodes the PDSCH from the received symbols
*/
int pdsch_decode(pdsch_t *q, cf_t *sf_symbols, cf_t *ce[MAX_PORTS], char *data,
int nsubframe, ra_mcs_t mcs, ra_prb_t *prb_alloc) {
/* Set pointers for layermapping & precoding */
int i;
cf_t *x[MAX_LAYERS];
int nof_symbols, nof_bits, nof_bits_e;
nof_bits = mcs.tbs;
nof_symbols = prb_alloc->re_sf[nsubframe];
nof_bits_e = nof_symbols * q->mod[mcs.mod - 1].nbits_x_symbol;
if (nof_bits > nof_bits_e) {
fprintf(stderr, "Invalid code rate %.2f\n", (float) nof_bits / nof_bits_e);
return -1;
}
if (nof_symbols > q->max_symbols) {
fprintf(stderr,
"Error too many RE per subframe (%d). PDSCH configured for %d RE (%d PRB)\n",
nof_symbols, q->max_symbols, q->nof_prb);
return -1;
}
INFO(
"Decoding PDSCH SF: %d, Mod %d, NofBits: %d, NofSymbols: %d, NofBitsE: %d\n",
nsubframe, mcs.mod, nof_bits, nof_symbols, nof_bits_e);
if (nsubframe < 0 || nsubframe > NSUBFRAMES_X_FRAME) {
fprintf(stderr, "Invalid subframe %d\n", nsubframe);
return -1;
}
/* number of layers equals number of ports */
for (i = 0; i < q->nof_ports; i++) {
x[i] = q->pdsch_x[i];
}
memset(&x[q->nof_ports], 0, sizeof(cf_t*) * (MAX_LAYERS - q->nof_ports));
/* extract symbols */
pdsch_get(q, sf_symbols, q->pdsch_symbols[0], prb_alloc, nsubframe);
/* extract channel estimates */
for (i = 0; i < q->nof_ports; i++) {
pdsch_get(q, ce[i], q->ce[i], prb_alloc, nsubframe);
}
/* TODO: only diversity is supported */
if (q->nof_ports == 1) {
/* no need for layer demapping */
predecoding_single_zf(q->pdsch_symbols[0], q->ce[0], q->pdsch_d,
nof_symbols);
} else {
predecoding_diversity_zf(q->pdsch_symbols[0], q->ce, x, q->nof_ports,
nof_symbols);
layerdemap_diversity(x, q->pdsch_d, q->nof_ports,
nof_symbols / q->nof_ports);
}
/* demodulate symbols */
demod_soft_sigma_set(&q->demod, 2.0 / q->mod[mcs.mod - 1].nbits_x_symbol);
demod_soft_table_set(&q->demod, &q->mod[mcs.mod - 1]);
demod_soft_demodulate(&q->demod, q->pdsch_d, q->pdsch_llr, nof_symbols);
/* descramble */
scrambling_f_offset(&q->seq_pdsch[nsubframe], q->pdsch_llr, 0, nof_bits_e);
return pdsch_decode_tb(q, data, nof_bits, nof_bits_e, 0);
}
/* Encode a transport block according to 36.212 5.3.2
*
*/
void pdsch_encode_tb(pdsch_t *q, char *data, int tbs, int nb_e, int rv_idx) {
char parity[24];
char *p_parity = parity;
unsigned int par;
int i;
int cb_len, rp, wp, rlen, F, n_e;
struct cb_segm cbs;
/* Compute CB segmentation */
codeblock_segmentation(&cbs, tbs);
/* Compute transport block CRC */
par = crc_checksum(&q->crc_tb, data, tbs);
/* parity bits will be appended later */
bit_pack(par, &p_parity, 24);
if (VERBOSE_ISDEBUG()) {
DEBUG("DATA: ", 0);
vec_fprint_b(stdout, data, tbs);
DEBUG("PARITY: ", 0);
vec_fprint_b(stdout, parity, 24);
}
/* Add filler bits to the new data buffer */
for (i = 0; i < cbs.F; i++) {
q->cb_in_b[i] = LTE_NULL_BIT;
}
wp = 0;
rp = 0;
for (i = 0; i < cbs.C; i++) {
/* Get read lengths */
if (i < cbs.C - cbs.C2) {
cb_len = cbs.K1;
} else {
cb_len = cbs.K2;
}
if (cbs.C > 1) {
rlen = cb_len - 24;
} else {
rlen = cb_len;
}
if (i == 0) {
F = cbs.F;
} else {
F = 0;
}
if (i < cbs.C - 1) {
n_e = nb_e / cbs.C;
} else {
n_e = nb_e - wp;
}
INFO("CB#%d: cb_len: %d, rlen: %d, wp: %d, rp: %d, F: %d, E: %d\n", i,
cb_len, rlen - F, wp, rp, F, n_e);
/* Copy data to another buffer, making space for the Codeblock CRC */
if (i < cbs.C - 1) {
memcpy(&q->cb_in_b[F], &data[rp], (rlen - F) * sizeof(char));
} else {
INFO("Last CB, appending parity: %d from %d and 24 to %d\n",
rlen - F - 24, rp, rlen - 24);
/* Append Transport Block parity bits to the last CB */
memcpy(&q->cb_in_b[F], &data[rp], (rlen - F - 24) * sizeof(char));
memcpy(&q->cb_in_b[rlen - 24], parity, 24 * sizeof(char));
}
if (cbs.C > 1) {
/* Attach Codeblock CRC */
crc_attach(&q->crc_cb, q->cb_in_b, rlen);
}
if (VERBOSE_ISDEBUG()) {
DEBUG("CB#%d Len=%d: ", i, cb_len);
vec_fprint_b(stdout, q->cb_in_b, cb_len);
}
/* Turbo Encoding */
tcod_encode(&q->encoder, q->cb_in_b, q->cb_out_b, cb_len);
/* Rate matching */
rm_turbo_tx(&q->rm_turbo, q->cb_out_b, 3 * cb_len + 12,
&q->pdsch_e_bits[wp], n_e, rv_idx);
/* Set read/write pointers */
rp += (rlen - F);
wp += n_e;
}
INFO("END CB#%d: wp: %d, rp: %d\n", i, wp, rp);
}
/** Converts the PDSCH data bits to symbols mapped to the slot ready for transmission
*/
int pdsch_encode(pdsch_t *q, char *data, cf_t *sf_symbols[MAX_PORTS],
int nsubframe, ra_mcs_t mcs, ra_prb_t *prb_alloc) {
int i;
int nof_symbols, nof_bits, nof_bits_e;
/* Set pointers for layermapping & precoding */
cf_t *x[MAX_LAYERS];
if (nsubframe < 0 || nsubframe > NSUBFRAMES_X_FRAME) {
fprintf(stderr, "Invalid subframe %d\n", nsubframe);
return -1;
}
nof_bits = mcs.tbs;
nof_symbols = prb_alloc->re_sf[nsubframe];
nof_bits_e = nof_symbols * q->mod[mcs.mod - 1].nbits_x_symbol;
if (nof_bits > nof_bits_e) {
fprintf(stderr, "Invalid code rate %.2f\n", (float) nof_bits / nof_bits_e);
return -1;
}
if (nof_symbols > q->max_symbols) {
fprintf(stderr,
"Error too many RE per subframe (%d). PDSCH configured for %d RE (%d PRB)\n",
nof_symbols, q->max_symbols, q->nof_prb);
return -1;
}
INFO(
"Encoding PDSCH SF: %d, Mod %d, NofBits: %d, NofSymbols: %d, NofBitsE: %d\n",
nsubframe, mcs.mod, nof_bits, nof_symbols, nof_bits_e);
/* number of layers equals number of ports */
for (i = 0; i < q->nof_ports; i++) {
x[i] = q->pdsch_x[i];
}
memset(&x[q->nof_ports], 0, sizeof(cf_t*) * (MAX_LAYERS - q->nof_ports));
pdsch_encode_tb(q, data, nof_bits, nof_bits_e, 0);
scrambling_b_offset(&q->seq_pdsch[nsubframe], q->pdsch_e_bits, 0, nof_bits_e);
mod_modulate(&q->mod[mcs.mod - 1], q->pdsch_e_bits, q->pdsch_d, nof_bits_e);
/* TODO: only diversity supported */
if (q->nof_ports > 1) {
layermap_diversity(q->pdsch_d, x, q->nof_ports, nof_symbols);
precoding_diversity(x, q->pdsch_symbols, q->nof_ports,
nof_symbols / q->nof_ports);
} else {
memcpy(q->pdsch_symbols[0], q->pdsch_d, nof_symbols * sizeof(cf_t));
}
/* mapping to resource elements */
for (i = 0; i < q->nof_ports; i++) {
pdsch_put(q, q->pdsch_symbols[i], sf_symbols[i], prb_alloc, nsubframe);
}
return 0;
}