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view spandsp-0.0.3/spandsp-0.0.3/src/bert.c @ 5:f762bf195c4b
import spandsp-0.0.3
| author | Peter Meerwald <pmeerw@cosy.sbg.ac.at> |
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| date | Fri, 25 Jun 2010 16:00:21 +0200 |
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/* * SpanDSP - a series of DSP components for telephony * * bert.c - Bit error rate tests. * * Written by Steve Underwood <steveu@coppice.org> * * Copyright (C) 2004 Steve Underwood * * All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2, as * published by the Free Software Foundation. * * This program 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. * * $Id: bert.c,v 1.21 2006/11/19 14:07:24 steveu Exp $ */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include <inttypes.h> #include <stdlib.h> #include <stdio.h> #include <string.h> #include <assert.h> #include <time.h> #include "spandsp/telephony.h" #include "spandsp/logging.h" #include "spandsp/async.h" #include "spandsp/bert.h" static const char *qbf = "VoyeZ Le BricK GeanT QuE J'ExaminE PreS Du WharF 123 456 7890 + - * : = $ % ( )" "ThE QuicK BrowN FoX JumpS OveR ThE LazY DoG 123 456 7890 + - * : = $ % ( )"; int bert_get_bit(bert_state_t *s) { int bit; if (s->limit && s->tx_bits >= s->limit) return PUTBIT_END_OF_DATA; bit = 0; switch (s->pattern_class) { case 0: bit = s->tx_reg & 1; s->tx_reg = (s->tx_reg >> 1) | ((s->tx_reg & 1) << s->shift2); break; case 1: bit = s->tx_reg & 1; s->tx_reg = (s->tx_reg >> 1) | (((s->tx_reg ^ (s->tx_reg >> s->shift)) & 1) << s->shift2); if (s->max_zeros) { /* This generator suppresses runs >s->max_zeros */ if (bit) { if (++s->tx_zeros > s->max_zeros) { s->tx_zeros = 0; bit ^= 1; } } else { s->tx_zeros = 0; } } bit ^= s->invert; break; case 2: if (s->tx_step_bit == 0) { s->tx_step_bit = 7; s->tx_reg = qbf[s->tx_step++]; if (s->tx_reg == 0) { s->tx_reg = 'V'; s->tx_step = 1; } } bit = s->tx_reg & 1; s->tx_reg >>= 1; s->tx_step_bit--; break; } s->tx_bits++; return bit; } /*- End of function --------------------------------------------------------*/ void bert_put_bit(bert_state_t *s, int bit) { int i; int j; int sum; int test; if (bit < 0) { /* Special conditions */ switch (bit) { case PUTBIT_TRAINING_FAILED: span_log(&s->logging, SPAN_LOG_FLOW, "Training failed\n"); break; case PUTBIT_TRAINING_SUCCEEDED: span_log(&s->logging, SPAN_LOG_FLOW, "Training succeeded\n"); break; case PUTBIT_CARRIER_UP: span_log(&s->logging, SPAN_LOG_FLOW, "Carrier up\n"); break; case PUTBIT_CARRIER_DOWN: span_log(&s->logging, SPAN_LOG_FLOW, "Carrier down\n"); break; default: span_log(&s->logging, SPAN_LOG_FLOW, "Eh!\n"); break; } return; } bit = (bit & 1) ^ s->invert; s->rx_bits++; switch (s->pattern_class) { case 0: if (s->resync) { s->rx_reg = (s->rx_reg >> 1) | (bit << s->shift2); s->ref_reg = (s->ref_reg >> 1) | ((s->ref_reg & 1) << s->shift2); if (s->rx_reg == s->ref_reg) { if (++s->resync > s->resync_time) { s->resync = 0; if (s->reporter) s->reporter(s->user_data, BERT_REPORT_SYNCED, &s->results); } } else { s->resync = 2; s->ref_reg = s->master_reg; } } else { s->results.total_bits++; if ((bit ^ s->ref_reg) & 1) s->results.bad_bits++; s->ref_reg = (s->ref_reg >> 1) | ((s->ref_reg & 1) << s->shift2); } break; case 1: if (s->resync) { /* If we get a reasonable period for which we correctly predict the next bit, we must be in sync. */ /* Don't worry about max. zeros tests when resyncing. It might just extend the resync time a little. Trying to include the test might affect robustness. */ if (bit == (int) ((s->rx_reg >> s->shift) & 1)) { if (++s->resync > s->resync_time) { s->resync = 0; if (s->reporter) s->reporter(s->user_data, BERT_REPORT_SYNCED, &s->results); } } else { s->resync = 2; s->rx_reg ^= s->mask; } } else { if (s->max_zeros) { if ((s->rx_reg & s->mask)) { if (++s->rx_zeros > s->max_zeros) { s->rx_zeros = 0; bit ^= 1; } } else { s->rx_zeros = 0; } } s->results.total_bits++; if (bit != (int) ((s->rx_reg >> s->shift) & 1)) { s->results.bad_bits++; s->resync_bad_bits++; s->decade_bad[2][s->decade_ptr[2]]++; } if (--s->step <= 0) { s->step = 100; test = TRUE; for (i = 2; i <= 7; i++) { if (++s->decade_ptr[i] < 10) break; s->decade_ptr[i] = 0; for (sum = 0, j = 0; j < 10; j++) sum += s->decade_bad[i][j]; if (test && sum > 10) { test = FALSE; if (s->error_rate != i && s->reporter) s->reporter(s->user_data, BERT_REPORT_GT_10_2 + i - 2, &s->results); s->error_rate = i; } s->decade_bad[i][0] = 0; if (i < 7) s->decade_bad[i + 1][s->decade_ptr[i + 1]] = sum; } if (i > 7) { if (s->decade_ptr[i] >= 10) s->decade_ptr[i] = 0; if (test) { if (s->error_rate != i && s->reporter) s->reporter(s->user_data, BERT_REPORT_GT_10_2 + i - 2, &s->results); s->error_rate = i; } } else { s->decade_bad[i][s->decade_ptr[i]] = 0; } } if (--s->resync_cnt <= 0) { /* Check if there were enough bad bits during this period to justify a resync. */ if (s->resync_bad_bits >= (s->resync_len*s->resync_percent)/100) { s->resync = 1; s->results.resyncs++; if (s->reporter) s->reporter(s->user_data, BERT_REPORT_UNSYNCED, &s->results); } s->resync_cnt = s->resync_len; s->resync_bad_bits = 0; } } s->rx_reg = (s->rx_reg >> 1) | (((s->rx_reg ^ (s->rx_reg >> s->shift)) & 1) << s->shift2); break; case 2: s->rx_reg = (s->rx_reg >> 1) | (bit << 6); /* TODO: There is no mechanism for synching yet. This only works if things start in sync. */ if (++s->rx_step_bit == 7) { s->rx_step_bit = 0; if ((int) s->rx_reg != qbf[s->rx_step]) { /* We need to work out the number of actual bad bits here. We need to look at the error rate, and see it a resync is needed. etc. */ s->results.bad_bits++; } if (qbf[++s->rx_step] == '\0') s->rx_step = 0; } s->results.total_bits++; break; } if (s->report_frequency > 0) { if (--s->report_countdown <= 0) { if (s->reporter) s->reporter(s->user_data, BERT_REPORT_REGULAR, &s->results); s->report_countdown = s->report_frequency; } } } /*- End of function --------------------------------------------------------*/ int bert_result(bert_state_t *s, bert_results_t *results) { results->total_bits = s->results.total_bits; results->bad_bits = s->results.bad_bits; results->resyncs = s->results.resyncs; return sizeof(*results); } /*- End of function --------------------------------------------------------*/ void bert_set_report(bert_state_t *s, int freq, bert_report_func_t reporter, void *user_data) { s->report_frequency = freq; s->reporter = reporter; s->user_data = user_data; s->report_countdown = s->report_frequency; } /*- End of function --------------------------------------------------------*/ bert_state_t *bert_init(bert_state_t *s, int limit, int pattern, int resync_len, int resync_percent) { int i; int j; memset(s, 0, sizeof(*s)); s->pattern = pattern; s->limit = limit; s->reporter = NULL; s->user_data = NULL; s->report_frequency = 0; s->resync_time = 72; s->invert = 0; switch (s->pattern) { case BERT_PATTERN_ZEROS: s->tx_reg = 0; s->shift2 = 31; s->pattern_class = 0; break; case BERT_PATTERN_ONES: s->tx_reg = ~((uint32_t) 0); s->shift2 = 31; s->pattern_class = 0; break; case BERT_PATTERN_7_TO_1: s->tx_reg = 0xFEFEFEFE; s->shift2 = 31; s->pattern_class = 0; break; case BERT_PATTERN_3_TO_1: s->tx_reg = 0xEEEEEEEE; s->shift2 = 31; s->pattern_class = 0; break; case BERT_PATTERN_1_TO_1: s->tx_reg = 0xAAAAAAAA; s->shift2 = 31; s->pattern_class = 0; break; case BERT_PATTERN_1_TO_3: s->tx_reg = 0x11111111; s->shift2 = 31; s->pattern_class = 0; break; case BERT_PATTERN_1_TO_7: s->tx_reg = 0x01010101; s->shift2 = 31; s->pattern_class = 0; break; case BERT_PATTERN_QBF: s->tx_reg = 0; s->pattern_class = 2; break; case BERT_PATTERN_ITU_O151_23: s->pattern_class = 1; s->tx_reg = 0x7FFFFF; s->mask = 0x20; s->shift = 5; s->shift2 = 22; s->invert = 1; s->resync_time = 56; s->max_zeros = 0; break; case BERT_PATTERN_ITU_O151_20: s->pattern_class = 1; s->tx_reg = 0xFFFFF; s->mask = 0x8; s->shift = 3; s->shift2 = 19; s->invert = 1; s->resync_time = 50; s->max_zeros = 14; break; case BERT_PATTERN_ITU_O151_15: s->pattern_class = 1; s->tx_reg = 0x7FFF; s->mask = 0x2; s->shift = 1; s->shift2 = 14; s->invert = 1; s->resync_time = 40; s->max_zeros = 0; break; case BERT_PATTERN_ITU_O152_11: s->pattern_class = 1; s->tx_reg = 0x7FF; s->mask = 0x4; s->shift = 2; s->shift2 = 10; s->invert = 0; s->resync_time = 32; s->max_zeros = 0; break; case BERT_PATTERN_ITU_O153_9: s->pattern_class = 1; s->tx_reg = 0x1FF; s->mask = 0x10; s->shift = 4; s->shift2 = 8; s->invert = 0; s->resync_time = 28; s->max_zeros = 0; break; } s->tx_bits = 0; s->tx_step = 0; s->tx_step_bit = 0; s->tx_zeros = 0; s->rx_reg = s->tx_reg; s->ref_reg = s->rx_reg; s->master_reg = s->ref_reg; s->rx_bits = 0; s->rx_step = 0; s->rx_step_bit = 0; s->resync = 1; s->resync_cnt = resync_len; s->resync_bad_bits = 0; s->resync_len = resync_len; s->resync_percent = resync_percent; s->results.total_bits = 0; s->results.bad_bits = 0; s->results.resyncs = 0; s->report_countdown = 0; for (i = 0; i < 8; i++) { for (j = 0; j < 10; j++) s->decade_bad[i][j] = 0; s->decade_ptr[i] = 0; } s->error_rate = 8; s->step = 100; span_log_init(&s->logging, SPAN_LOG_NONE, NULL); span_log_set_protocol(&s->logging, "BERT"); return s; } /*- End of function --------------------------------------------------------*/ /*- End of file ------------------------------------------------------------*/