/* * FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application * Copyright (C) 2005-2014, Anthony Minessale II * * Version: MPL 1.1 * * The contents of this file are subject to the Mozilla Public License Version * 1.1 (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * http://www.mozilla.org/MPL/ * * Software distributed under the License is distributed on an "AS IS" basis, * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License * for the specific language governing rights and limitations under the * License. * * The Original Code is FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application * * The Initial Developer of the Original Code is * Anthony Minessale II * Portions created by the Initial Developer are Copyright (C) * the Initial Developer. All Rights Reserved. * * Contributor(s): * * Anthony Minessale II * * * switch_resample.c -- Resampler * */ #include #include #ifndef WIN32 #include #endif #include #define NORMFACT (float)0x8000 #define MAXSAMPLE (float)0x7FFF #define MAXSAMPLEC (char)0x7F #define QUALITY 0 #ifndef MIN #define MIN(a,b) ((a) < (b) ? (a) : (b)) #endif #ifndef MAX #define MAX(a,b) ((a) > (b) ? (a) : (b)) #endif #define resample_buffer(a, b, c) a > b ? ((a / 1000) / 2) * c : ((b / 1000) / 2) * c SWITCH_DECLARE(switch_status_t) switch_resample_perform_create(switch_audio_resampler_t **new_resampler, uint32_t from_rate, uint32_t to_rate, uint32_t to_size, int quality, uint32_t channels, const char *file, const char *func, int line) { int err = 0; switch_audio_resampler_t *resampler; double lto_rate, lfrom_rate; switch_zmalloc(resampler, sizeof(*resampler)); if (!channels) channels = 1; resampler->resampler = speex_resampler_init(channels, from_rate, to_rate, quality, &err); if (!resampler->resampler) { free(resampler); return SWITCH_STATUS_GENERR; } *new_resampler = resampler; lto_rate = (double) resampler->to_rate; lfrom_rate = (double) resampler->from_rate; resampler->from_rate = from_rate; resampler->to_rate = to_rate; resampler->factor = (lto_rate / lfrom_rate); resampler->rfactor = (lfrom_rate / lto_rate); resampler->channels = channels; //resampler->to_size = resample_buffer(to_rate, from_rate, (uint32_t) to_size); resampler->to_size = switch_resample_calc_buffer_size(resampler->to_rate, resampler->from_rate, to_size) / 2; resampler->to = malloc(resampler->to_size * sizeof(int16_t) * resampler->channels); switch_assert(resampler->to); return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(uint32_t) switch_resample_process(switch_audio_resampler_t *resampler, int16_t *src, uint32_t srclen) { int to_size = switch_resample_calc_buffer_size(resampler->to_rate, resampler->from_rate, srclen) / 2; if (to_size > resampler->to_size) { resampler->to_size = to_size; resampler->to = realloc(resampler->to, resampler->to_size * sizeof(int16_t) * resampler->channels); switch_assert(resampler->to); } resampler->to_len = resampler->to_size; speex_resampler_process_interleaved_int(resampler->resampler, src, &srclen, resampler->to, &resampler->to_len); return resampler->to_len; } SWITCH_DECLARE(void) switch_resample_destroy(switch_audio_resampler_t **resampler) { if (resampler && *resampler) { if ((*resampler)->resampler) { speex_resampler_destroy((*resampler)->resampler); } free((*resampler)->to); free(*resampler); *resampler = NULL; } } SWITCH_DECLARE(switch_size_t) switch_float_to_short(float *f, short *s, switch_size_t len) { switch_size_t i; float ft; for (i = 0; i < len; i++) { ft = f[i] * NORMFACT; if (ft >= 0) { s[i] = (short) (ft + 0.5); } else { s[i] = (short) (ft - 0.5); } if ((float) s[i] > MAXSAMPLE) s[i] = (short) MAXSAMPLE / 2; if (s[i] < (short) -MAXSAMPLE) s[i] = (short) -MAXSAMPLE / 2; } return len; } SWITCH_DECLARE(int) switch_char_to_float(char *c, float *f, int len) { int i; if (len % 2) { return (-1); } for (i = 1; i < len; i += 2) { f[(int) (i / 2)] = (float) (((c[i]) * 0x100) + c[i - 1]); f[(int) (i / 2)] /= NORMFACT; if (f[(int) (i / 2)] > MAXSAMPLE) f[(int) (i / 2)] = MAXSAMPLE; if (f[(int) (i / 2)] < -MAXSAMPLE) f[(int) (i / 2)] = -MAXSAMPLE; } return len / 2; } SWITCH_DECLARE(int) switch_float_to_char(float *f, char *c, int len) { int i; float ft; long l; for (i = 0; i < len; i++) { ft = f[i] * NORMFACT; if (ft >= 0) { l = (long) (ft + 0.5); } else { l = (long) (ft - 0.5); } c[i * 2] = (unsigned char) ((l) & 0xff); c[i * 2 + 1] = (unsigned char) (((l) >> 8) & 0xff); } return len * 2; } SWITCH_DECLARE(int) switch_short_to_float(short *s, float *f, int len) { int i; for (i = 0; i < len; i++) { f[i] = (float) (s[i]) / NORMFACT; /* f[i] = (float) s[i]; */ } return len; } SWITCH_DECLARE(void) switch_swap_linear(int16_t *buf, int len) { int i; for (i = 0; i < len; i++) { buf[i] = ((buf[i] >> 8) & 0x00ff) | ((buf[i] << 8) & 0xff00); } } SWITCH_DECLARE(void) switch_generate_sln_silence(int16_t *data, uint32_t samples, uint32_t channels, uint32_t divisor) { int16_t s; uint32_t x, i, j; int sum_rnd = 0; int16_t rnd2 = (int16_t) switch_micro_time_now() + (int16_t) (intptr_t) data; if (channels == 0) channels = 1; assert(divisor); if (divisor == (uint32_t)-1) { memset(data, 0, samples * 2); return; } for (i = 0; i < samples; i++, sum_rnd = 0) { for (x = 0; x < 6; x++) { rnd2 = rnd2 * 31821U + 13849U; sum_rnd += rnd2; } s = (int16_t) ((int16_t) sum_rnd / (int) divisor); for (j = 0; j < channels; j++) { *data = s; data++; } } } SWITCH_DECLARE(uint32_t) switch_merge_sln(int16_t *data, uint32_t samples, int16_t *other_data, uint32_t other_samples, int channels) { int i; int32_t x, z; if (channels == 0) channels = 1; if (samples > other_samples) { x = other_samples; } else { x = samples; } for (i = 0; i < x * channels; i++) { z = data[i] + other_data[i]; switch_normalize_to_16bit(z); data[i] = (int16_t) z; } return x; } SWITCH_DECLARE(uint32_t) switch_unmerge_sln(int16_t *data, uint32_t samples, int16_t *other_data, uint32_t other_samples, int channels) { int i; int32_t x; if (channels == 0) channels = 1; if (samples > other_samples) { x = other_samples; } else { x = samples; } for (i = 0; i < x * channels; i++) { data[i] -= other_data[i]; } return x; } SWITCH_DECLARE(void) switch_mux_channels(int16_t *data, switch_size_t samples, uint32_t orig_channels, uint32_t channels) { switch_size_t i = 0; uint32_t j = 0; switch_assert(channels < 11); if (orig_channels > channels) { if (channels == 1) { for (i = 0; i < samples; i++) { int32_t z = 0; for (j = 0; j < orig_channels; j++) { z += (int16_t) data[i * orig_channels + j]; } switch_normalize_to_16bit(z); data[i] = (int16_t) z; } } else if (channels == 2) { int mark_buf = 0; for (i = 0; i < samples; i++) { int32_t z_left = 0, z_right = 0; for (j = 0; j < orig_channels; j++) { if (j % 2) { z_left += (int16_t) data[i * orig_channels + j]; } else { z_right += (int16_t) data[i * orig_channels + j]; } } /* mark_buf will always be smaller than the size of data in bytes because orig_channels > channels */ switch_normalize_to_16bit(z_left); data[mark_buf++] = (int16_t) z_left; switch_normalize_to_16bit(z_right); data[mark_buf++] = (int16_t) z_right; } } } else if (orig_channels < channels) { /* interesting problem... take a give buffer and double up every sample in the buffer without using any other buffer..... This way beats the other i think bacause there is no malloc but I do have to copy the data twice */ #if 1 uint32_t k = 0, len = samples * orig_channels; for (i = 0; i < len; i++) { data[i+len] = data[i]; } for (i = 0; i < samples; i++) { for (j = 0; j < channels; j++) { data[k++] = data[i + samples]; } } #else uint32_t k = 0, len = samples * 2 * orig_channels; int16_t *orig = NULL; switch_zmalloc(orig, len); memcpy(orig, data, len); for (i = 0; i < samples; i++) { for (j = 0; j < channels; j++) { data[k++] = orig[i]; } } free(orig); #endif } } SWITCH_DECLARE(void) switch_change_sln_volume_granular(int16_t *data, uint32_t samples, int32_t vol) { double newrate = 0; // change in dB mapped to ratio for output sample // computed as (powf(10.0f, (float)(change_in_dB) / 20.0f)) static const double pos[SWITCH_GRANULAR_VOLUME_MAX] = { 1.122018, 1.258925, 1.412538, 1.584893, 1.778279, 1.995262, 2.238721, 2.511887, 2.818383, 3.162278, 3.548134, 3.981072, 4.466835, 5.011872, 5.623413, 6.309574, 7.079458, 7.943282, 8.912509, 10.000000, 11.220183, 12.589254, 14.125375, 15.848933, 17.782795, 19.952621, 22.387213, 25.118862, 28.183832, 31.622776, 35.481335, 39.810719, 44.668358, 50.118729, 56.234131, 63.095726, 70.794586, 79.432816, 89.125107, 100.000000, 112.201836, 125.892517, 141.253784, 158.489334, 177.827942, 199.526215, 223.872070, 251.188705, 281.838318, 316.227753 }; static const double neg[SWITCH_GRANULAR_VOLUME_MAX] = { 0.891251, 0.794328, 0.707946, 0.630957, 0.562341, 0.501187, 0.446684, 0.398107, 0.354813, 0.316228, 0.281838, 0.251189, 0.223872, 0.199526, 0.177828, 0.158489, 0.141254, 0.125893, 0.112202, 0.100000, 0.089125, 0.079433, 0.070795, 0.063096, 0.056234, 0.050119, 0.044668, 0.039811, 0.035481, 0.031623, 0.028184, 0.025119, 0.022387, 0.019953, 0.017783, 0.015849, 0.014125, 0.012589, 0.011220, 0.010000, 0.008913, 0.007943, 0.007079, 0.006310, 0.005623, 0.005012, 0.004467, 0.003981, 0.003548, 0.000000 // NOTE mapped -50 dB ratio to total silence instead of 0.003162 }; const double *chart; uint32_t i; if (vol == 0) return; switch_normalize_volume_granular(vol); if (vol > 0) { chart = pos; } else { chart = neg; } i = abs(vol) - 1; switch_assert(i < SWITCH_GRANULAR_VOLUME_MAX); newrate = chart[i]; if (newrate) { int32_t tmp; uint32_t x; int16_t *fp = data; for (x = 0; x < samples; x++) { tmp = (int32_t) (fp[x] * newrate); switch_normalize_to_16bit(tmp); fp[x] = (int16_t) tmp; } } else { memset(data, 0, samples * 2); } } SWITCH_DECLARE(void) switch_change_sln_volume(int16_t *data, uint32_t samples, int32_t vol) { double newrate = 0; double pos[4] = {1.3, 2.3, 3.3, 4.3}; double neg[4] = {.80, .60, .40, .20}; double *chart; uint32_t i; if (vol == 0) return; switch_normalize_volume(vol); if (vol > 0) { chart = pos; } else { chart = neg; } i = abs(vol) - 1; switch_assert(i < 4); newrate = chart[i]; if (newrate) { int32_t tmp; uint32_t x; int16_t *fp = data; for (x = 0; x < samples; x++) { tmp = (int32_t) (fp[x] * newrate); switch_normalize_to_16bit(tmp); fp[x] = (int16_t) tmp; } } } struct switch_agc_s { switch_memory_pool_t *pool; uint32_t energy_avg; uint32_t margin; uint32_t change_factor; char *token; int vol; uint32_t score; uint32_t score_count; uint32_t score_sum; uint32_t score_avg; uint32_t score_over; uint32_t score_under; uint32_t period_len; uint32_t low_energy_point; }; SWITCH_DECLARE(void) switch_agc_set(switch_agc_t *agc, uint32_t energy_avg, uint32_t low_energy_point, uint32_t margin, uint32_t change_factor, uint32_t period_len) { agc->energy_avg = energy_avg; agc->margin = margin; agc->change_factor = change_factor; agc->period_len = period_len; agc->low_energy_point = low_energy_point; agc->score = 0; agc->score_count = 0; agc->score_sum = 0; agc->score_avg = 0; agc->score_over = 0; agc->score_under = 0; } SWITCH_DECLARE(switch_status_t) switch_agc_create(switch_agc_t **agcP, uint32_t energy_avg, uint32_t low_energy_point, uint32_t margin, uint32_t change_factor, uint32_t period_len) { switch_agc_t *agc; switch_memory_pool_t *pool; char id[80] = ""; switch_assert(agcP); switch_core_new_memory_pool(&pool); agc = switch_core_alloc(pool, sizeof(*agc)); agc->pool = pool; switch_agc_set(agc, energy_avg, low_energy_point, margin, change_factor, period_len); switch_snprintf(id, sizeof(id), "%p", (void *)agc); switch_agc_set_token(agc, id); *agcP = agc; return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(void) switch_agc_destroy(switch_agc_t **agcP) { switch_agc_t *agc; switch_assert(agcP); agc = *agcP; *agcP = NULL; if (agc) { switch_memory_pool_t *pool = agc->pool; switch_core_destroy_memory_pool(&pool); } } SWITCH_DECLARE(void) switch_agc_set_energy_avg(switch_agc_t *agc, uint32_t energy_avg) { switch_assert(agc); agc->energy_avg = energy_avg; } SWITCH_DECLARE(void) switch_agc_set_energy_low(switch_agc_t *agc, uint32_t low_energy_point) { switch_assert(agc); agc->low_energy_point = low_energy_point; } SWITCH_DECLARE(void) switch_agc_set_token(switch_agc_t *agc, const char *token) { agc->token = switch_core_strdup(agc->pool, token); } SWITCH_DECLARE(switch_status_t) switch_agc_feed(switch_agc_t *agc, int16_t *data, uint32_t samples, uint32_t channels) { if (!channels) channels = 1; if (agc->vol) { switch_change_sln_volume_granular(data, samples * channels, agc->vol); } if (agc->energy_avg) { uint32_t energy = 0; int i; for (i = 0; i < samples * channels; i++) { energy += abs(data[i]); } if (samples) { agc->score = energy / samples * channels; } agc->score_sum += agc->score; agc->score_count++; if (agc->score_count > agc->period_len) { agc->score_avg = (int)((double)agc->score_sum / agc->score_count); agc->score_count = 0; agc->score_sum = 0; if (agc->score_avg > agc->energy_avg) { if (agc->score_avg - agc->energy_avg > agc->margin) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG1, "[%s] OVER++ SCORE AVG: %d ENERGY AVG: %d MARGIN: %d\n", agc->token, agc->score_avg, agc->energy_avg, agc->margin); agc->score_over++; } else { agc->score_over = 0; } } else { agc->score_over = 0; } if (agc->score_avg < agc->low_energy_point) { agc->score_under = agc->change_factor + 1; switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG1, "[%s] BELOW LOW POINT, SCORE AVG: %d ENERGY AVG: %d MARGIN: %d\n", agc->token, agc->score_avg, agc->energy_avg, agc->margin); } else if (((agc->score_avg < agc->energy_avg) && (agc->energy_avg - agc->score_avg > agc->margin))) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG1, "[%s] UNDER++ SCORE AVG: %d ENERGY AVG: %d MARGIN: %d\n", agc->token, agc->score_avg, agc->energy_avg, agc->margin); agc->score_under++; } else { agc->score_under = 0; } switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG1, "[%s] AVG %d over: %d under: %d\n", agc->token, agc->score_avg, agc->score_over, agc->score_under); if (agc->score_over > agc->change_factor) { agc->vol--; switch_normalize_volume_granular(agc->vol); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG1, "[%s] VOL DOWN %d\n", agc->token, agc->vol); //agc->score_over = 0; } else if (agc->score_under > agc->change_factor) { agc->vol++; switch_normalize_volume_granular(agc->vol); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG1, "[%s] VOL UP %d\n", agc->token, agc->vol); //agc->score_under = 0; } } } return SWITCH_STATUS_SUCCESS; } /* For Emacs: * Local Variables: * mode:c * indent-tabs-mode:t * tab-width:4 * c-basic-offset:4 * End: * For VIM: * vim:set softtabstop=4 shiftwidth=4 tabstop=4 noet: */