int main(int argc, char **argv) {
int frame_cnt;
float *llr;
uint16_t *llr_s;
uint8_t *llr_c;
uint8_t *data_tx, *data_rx, *data_rx2, *symbols;
int i, j;
float var[SNR_POINTS], varunc[SNR_POINTS];
int snr_points;
uint32_t errors;
#ifdef TEST_SSE
uint32_t errors2;
srslte_viterbi_t dec_sse;
#endif
srslte_viterbi_t dec;
srslte_convcoder_t cod;
int coded_length;
parse_args(argc, argv);
if (!seed) {
seed = time(NULL);
}
srand(seed);
cod.poly[0] = 0x6D;
cod.poly[1] = 0x4F;
cod.poly[2] = 0x57;
cod.K = 7;
cod.tail_biting = tail_biting;
cod.R = 3;
coded_length = cod.R * (frame_length + ((cod.tail_biting) ? 0 : cod.K - 1));
srslte_viterbi_init(&dec, SRSLTE_VITERBI_37, cod.poly, frame_length, cod.tail_biting);
printf("Convolutional Code 1/3 K=%d Tail bitting: %s\n", cod.K, cod.tail_biting ? "yes" : "no");
#ifdef TEST_SSE
srslte_viterbi_init_sse(&dec_sse, SRSLTE_VITERBI_37, cod.poly, frame_length, cod.tail_biting);
#endif
printf(" Frame length: %d\n", frame_length);
if (ebno_db < 100.0) {
printf(" EbNo: %.2f\n", ebno_db);
}
data_tx = malloc(frame_length * sizeof(uint8_t));
if (!data_tx) {
perror("malloc");
exit(-1);
}
data_rx = malloc(frame_length * sizeof(uint8_t));
if (!data_rx) {
perror("malloc");
exit(-1);
}
data_rx2 = malloc(frame_length * sizeof(uint8_t));
if (!data_rx2) {
perror("malloc");
exit(-1);
}
symbols = malloc(coded_length * sizeof(uint8_t));
if (!symbols) {
perror("malloc");
exit(-1);
}
llr = malloc(coded_length * sizeof(float));
if (!llr) {
perror("malloc");
exit(-1);
}
llr_s = malloc(2 * coded_length * sizeof(uint16_t));
if (!llr_s) {
perror("malloc");
exit(-1);
}
llr_c = malloc(2 * coded_length * sizeof(uint8_t));
if (!llr_c) {
perror("malloc");
exit(-1);
}
float ebno_inc, esno_db;
ebno_inc = (SNR_MAX - SNR_MIN) / SNR_POINTS;
if (ebno_db == 100.0) {
snr_points = SNR_POINTS;
for (i = 0; i < snr_points; i++) {
ebno_db = SNR_MIN + i * ebno_inc;
esno_db = ebno_db + 10 * log10((double) 1 / 3);
var[i] = sqrt(1 / (pow(10, esno_db / 10)));
varunc[i] = sqrt(1 / (pow(10, ebno_db / 10)));
}
} else {
esno_db = ebno_db + 10 * log10((double) 1 / 3);
var[0] = sqrt(1 / (pow(10, esno_db / 10)));
varunc[0] = sqrt(1 / (pow(10, ebno_db / 10)));
snr_points = 1;
}
for (i = 0; i < snr_points; i++) {
frame_cnt = 0;
errors = 0;
#ifdef TEST_SSE
errors2 = 0;
#endif
while (frame_cnt < nof_frames) {
/* generate data_tx */
for (j = 0; j < frame_length; j++) {
data_tx[j] = rand() % 2;
}
/* uncoded BER */
for (j = 0; j < frame_length; j++) {
llr[j] = data_tx[j] ? sqrt(2) : -sqrt(2);
}
srslte_ch_awgn_f(llr, llr, varunc[i], frame_length);
/* coded BER */
srslte_convcoder_encode(&cod, data_tx, symbols, frame_length);
for (j = 0; j < coded_length; j++) {
llr[j] = symbols[j] ? sqrt(2) : -sqrt(2);
}
srslte_ch_awgn_f(llr, llr, var[i], coded_length);
//srslte_vec_fprint_f(stdout, llr, 100);
srslte_vec_quant_fuc(llr, llr_c, 32, 127.5, 255, coded_length);
srslte_vec_quant_fus(llr, llr_s, 8192, 32767.5, 65535, coded_length);
struct timeval t[3];
gettimeofday(&t[1], NULL);
int M = 1;
for (int i=0;i<M;i++) {
#ifdef VITERBI_16
srslte_viterbi_decode_us(&dec, llr_s, data_rx, frame_length);
#else
srslte_viterbi_decode_uc(&dec, llr_c, data_rx, frame_length);
#endif
}
#ifdef TEST_SSE
gettimeofday(&t[2], NULL);
get_time_interval(t);
//printf("Execution time:\t\t%.1f us\n", (float) t[0].tv_usec/M);
gettimeofday(&t[1], NULL);
for (int i=0;i<M;i++) {
srslte_viterbi_decode_uc(&dec_sse, llr_c, data_rx2, frame_length);
}
gettimeofday(&t[2], NULL);
get_time_interval(t);
//printf("Execution time SIMD:\t%.1f us\n", (float) t[0].tv_usec/M);
#endif
/* check errors */
errors += srslte_bit_diff(data_tx, data_rx, frame_length);
#ifdef TEST_SSE
errors2 += srslte_bit_diff(data_tx, data_rx2, frame_length);
#endif
frame_cnt++;
printf("Eb/No: %3.2f %10d/%d ", SNR_MIN + i * ebno_inc,frame_cnt,nof_frames);
printf("BER: %.2e ", (float) errors / (frame_cnt * frame_length));
#ifdef TEST_SSE
printf("BER2: %.2e ", (float) errors2 / (frame_cnt * frame_length));
#endif
printf("\r");
}
printf("\n");
if (snr_points == 1) {
printf("BER : %g\t%u errors\n", (float) errors / (frame_cnt * frame_length), errors);
#ifdef TEST_SSE
printf("BER SSE: %g\t%u errors\n", (float) errors2 / (frame_cnt * frame_length), errors2);
#endif
}
}
srslte_viterbi_free(&dec);
#ifdef TEST_SSE
srslte_viterbi_free(&dec_sse);
#endif
free(data_tx);
free(symbols);
free(llr);
free(llr_c);
free(llr_s);
free(data_rx);
free(data_rx2);
if (snr_points == 1) {
int expected_errors = get_expected_errors(nof_frames, seed, frame_length, tail_biting, ebno_db);
if (expected_errors == -1) {
fprintf(stderr, "Test parameters not defined in test_results.h\n");
exit(-1);
} else {
printf("errors =%d, expected =%d\n", errors, expected_errors);
exit(errors > expected_errors);
}
} else {
printf("\n");
printf("Done\n");
exit(0);
}
}
int main(int argc, char **argv) {
int frame_cnt;
float *llr;
uint8_t *llr_c;
uint8_t *data_tx, *data_rx[NTYPES], *symbols;
int i, j;
float var[SNR_POINTS], varunc[SNR_POINTS];
int snr_points;
float ber[NTYPES][SNR_POINTS];
uint32_t errors[NTYPES];
srslte_viterbi_type_t srslte_viterbi_type[NCODS];
srslte_viterbi_t dec[NCODS];
srslte_convcoder_t cod[NCODS];
int coded_length[NCODS];
int n, ncods, max_coded_length;
parse_args(argc, argv);
if (!seed) {
seed = time(NULL);
}
srand(seed);
switch (K) {
case 9:
cod[0].poly[0] = 0x1ed;
cod[0].poly[1] = 0x19b;
cod[0].poly[2] = 0x127;
cod[0].tail_biting = false;
cod[0].K = 9;
srslte_viterbi_type[0] = SRSLTE_VITERBI_39;
ncods=1;
break;
case 7:
cod[0].poly[0] = 0x6D;
cod[0].poly[1] = 0x4F;
cod[0].poly[2] = 0x57;
cod[0].K = 7;
cod[0].tail_biting = tail_biting;
srslte_viterbi_type[0] = SRSLTE_VITERBI_37;
ncods=1;
break;
default:
cod[0].poly[0] = 0x1ed;
cod[0].poly[1] = 0x19b;
cod[0].poly[2] = 0x127;
cod[0].tail_biting = false;
cod[0].K = 9;
srslte_viterbi_type[0] = SRSLTE_VITERBI_39;
cod[1].poly[0] = 0x6D;
cod[1].poly[1] = 0x4F;
cod[1].poly[2] = 0x57;
cod[1].tail_biting = false;
cod[1].K = 7;
srslte_viterbi_type[1] = SRSLTE_VITERBI_37;
cod[2].poly[0] = 0x6D;
cod[2].poly[1] = 0x4F;
cod[2].poly[2] = 0x57;
cod[2].tail_biting = true;
cod[2].K = 7;
srslte_viterbi_type[2] = SRSLTE_VITERBI_37;
ncods=3;
}
max_coded_length = 0;
for (i=0; i<ncods; i++) {
cod[i].R = 3;
coded_length[i] = cod[i].R * (frame_length + ((cod[i].tail_biting) ? 0 : cod[i].K - 1));
if (coded_length[i] > max_coded_length) {
max_coded_length = coded_length[i];
}
srslte_viterbi_init(&dec[i], srslte_viterbi_type[i], cod[i].poly, frame_length, cod[i].tail_biting);
printf("Convolutional Code 1/3 K=%d Tail bitting: %s\n", cod[i].K, cod[i].tail_biting ? "yes" : "no");
}
printf(" Frame length: %d\n", frame_length);
if (ebno_db < 100.0) {
printf(" EbNo: %.2f\n", ebno_db);
}
data_tx = malloc(frame_length * sizeof(uint8_t));
if (!data_tx) {
perror("malloc");
exit(-1);
}
for (i = 0; i < NTYPES; i++) {
data_rx[i] = malloc(frame_length * sizeof(uint8_t));
if (!data_rx[i]) {
perror("malloc");
exit(-1);
}
}
symbols = malloc(max_coded_length * sizeof(uint8_t));
if (!symbols) {
perror("malloc");
exit(-1);
}
llr = malloc(max_coded_length * sizeof(float));
if (!llr) {
perror("malloc");
exit(-1);
}
llr_c = malloc(2 * max_coded_length * sizeof(uint8_t));
if (!llr_c) {
perror("malloc");
exit(-1);
}
float ebno_inc, esno_db;
ebno_inc = (SNR_MAX - SNR_MIN) / SNR_POINTS;
if (ebno_db == 100.0) {
snr_points = SNR_POINTS;
for (i = 0; i < snr_points; i++) {
ebno_db = SNR_MIN + i * ebno_inc;
esno_db = ebno_db + 10 * log10((double) 1 / 3);
var[i] = sqrt(1 / (pow(10, esno_db / 10)));
varunc[i] = sqrt(1 / (pow(10, ebno_db / 10)));
}
} else {
esno_db = ebno_db + 10 * log10((double) 1 / 3);
var[0] = sqrt(1 / (pow(10, esno_db / 10)));
varunc[0] = sqrt(1 / (pow(10, ebno_db / 10)));
snr_points = 1;
}
float Gain = 32;
for (i = 0; i < snr_points; i++) {
frame_cnt = 0;
for (j = 0; j < NTYPES; j++) {
errors[j] = 0;
}
while (frame_cnt < nof_frames) {
/* generate data_tx */
for (j = 0; j < frame_length; j++) {
data_tx[j] = rand() % 2;
}
/* uncoded BER */
for (j = 0; j < frame_length; j++) {
llr[j] = data_tx[j] ? sqrt(2) : -sqrt(2);
}
srslte_ch_awgn_f(llr, llr, varunc[i], frame_length);
for (j = 0; j < frame_length; j++) {
data_rx[0][j] = llr[j] > 0 ? 1 : 0;
}
/* coded BER */
for (n=0; n<ncods; n++) {
srslte_convcoder_encode(&cod[n], data_tx, symbols, frame_length);
for (j = 0; j < coded_length[n]; j++) {
llr[j] = symbols[j] ? sqrt(2) : -sqrt(2);
}
srslte_ch_awgn_f(llr, llr, var[i], coded_length[n]);
srslte_vec_quant_fuc(llr, llr_c, Gain, 127.5, 255, coded_length[n]);
/* decoder 1 */
srslte_viterbi_decode_uc(&dec[n], llr_c, data_rx[1+n], frame_length);
}
/* check errors */
for (j = 0; j < 1+ncods; j++) {
errors[j] += srslte_bit_diff(data_tx, data_rx[j], frame_length);
}
frame_cnt++;
printf("Eb/No: %3.2f %10d/%d ",
SNR_MIN + i * ebno_inc,frame_cnt,nof_frames);
for (n=0; n<1+ncods; n++) {
printf("BER: %.2e ",(float) errors[n] / (frame_cnt * frame_length));
}
printf("\r");
}
printf("\n");
for (j = 0; j < 1+ncods; j++) {
ber[j][i] = (float) errors[j] / (frame_cnt * frame_length);
}
if (snr_points == 1) {
printf("BER uncoded: %g\t%u errors\n",
(float) errors[0] / (frame_cnt * frame_length), errors[0]);
for (n=0; n<ncods; n++) {
printf("BER K=%d: %g\t%u errors\n",cod[n].K,
(float) errors[1+n] / (frame_cnt * frame_length), errors[1+n]);
}
}
}
for (n=0; n<ncods; n++) {
srslte_viterbi_free(&dec[n]);
}
free(data_tx);
free(symbols);
free(llr);
free(llr_c);
for (i = 0; i < NTYPES; i++) {
free(data_rx[i]);
}
if (snr_points == 1) {
int expected_errors = get_expected_errors(nof_frames,
seed, frame_length, K, tail_biting, ebno_db);
if (expected_errors == -1) {
fprintf(stderr, "Test parameters not defined in test_results.h\n");
exit(-1);
} else {
printf("errors =%d, expected =%d\n", errors[1], expected_errors);
exit(errors[1] > expected_errors);
}
} else {
printf("\n");
output_matlab(ber, snr_points, cod, ncods);
printf("Done\n");
exit(0);
}
}
