ref: b0546451ff5aff0eaa9c5f4fbeb1d6b0541bbdc4
dir: /src/vad.c/
/* libSoX effect: Voice Activity Detector (c) 2009 robs@users.sourceforge.net * * This library 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 2.1 of the License, or (at * your option) any later version. * * This library 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. * * You should have received a copy of the GNU Lesser General Public License * along with this library; if not, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #include "sox_i.h" #include "sgetopt.h" #include <string.h> typedef struct { double * dftBuf, * noiseSpectrum, * spectrum, * measures, meanMeas; } chan_t; typedef struct { /* Configuration parameters: */ double bootTime, noiseTcUp, noiseTcDown, noiseReductionAmount; double measureFreq, measureDuration, measureTc, preTriggerTime; double hpFilterFreq, lpFilterFreq, hpLifterFreq, lpLifterFreq; double triggerTc, triggerLevel, searchTime, gapTime; /* Working variables: */ sox_sample_t * samples; unsigned dftLen_ws, samplesLen_ns, samplesIndex_ns, flushedLen_ns, gapLen; unsigned measurePeriod_ns, measuresLen, measuresIndex; unsigned measureTimer_ns, measureLen_ws, measureLen_ns; unsigned spectrumStart, spectrumEnd, cepstrumStart, cepstrumEnd; /* bins */ int bootCountMax, bootCount; double noiseTcUpMult, noiseTcDownMult; double measureTcMult, triggerMeasTcMult; double * spectrumWindow, * cepstrumWindow; chan_t * channels; } priv_t; #define GETOPT_FREQ(c, name, min) \ case c: p->name = lsx_parse_frequency(lsx_optarg, &parseIndex); \ if (p->name < min || *parseIndex) return lsx_usage(effp); \ break; static int create(sox_effect_t * effp, int argc, char * * argv) { priv_t * p = (priv_t *)effp->priv; #define opt_str "+b:N:n:r:f:m:M:h:l:H:L:T:t:s:g:p:" int c; p->bootTime = .35; p->noiseTcUp = .1; p->noiseTcDown = .01; p->noiseReductionAmount = 1.35; p->measureFreq = 20; p->measureDuration = 2 / p->measureFreq; /* 50% overlap */ p->measureTc = .4; p->hpFilterFreq = 50; p->lpFilterFreq = 6000; p->hpLifterFreq = 150; p->lpLifterFreq = 2000; p->triggerTc = .25; p->triggerLevel = 7; p->searchTime = 1; p->gapTime = .25; while ((c = lsx_getopt(argc, argv, opt_str)) != -1) switch (c) { char * parseIndex; GETOPT_NUMERIC('b', bootTime , .1 , 10) GETOPT_NUMERIC('N', noiseTcUp , .1 , 10) GETOPT_NUMERIC('n', noiseTcDown ,.001 , .1) GETOPT_NUMERIC('r', noiseReductionAmount,0 , 2) GETOPT_NUMERIC('f', measureFreq , 5 , 50) GETOPT_NUMERIC('m', measureDuration, .01 , 1) GETOPT_NUMERIC('M', measureTc , .1 , 1) GETOPT_FREQ( 'h', hpFilterFreq , 10) GETOPT_FREQ( 'l', lpFilterFreq , 1000) GETOPT_FREQ( 'H', hpLifterFreq , 10) GETOPT_FREQ( 'L', lpLifterFreq , 1000) GETOPT_NUMERIC('T', triggerTc , .01 , 1) GETOPT_NUMERIC('t', triggerLevel , 0 , 20) GETOPT_NUMERIC('s', searchTime , .1 , 4) GETOPT_NUMERIC('g', gapTime , .1 , 1) GETOPT_NUMERIC('p', preTriggerTime, 0 , 4) default: lsx_fail("invalid option `-%c'", optopt); return lsx_usage(effp); } return lsx_optind !=argc? lsx_usage(effp) : SOX_SUCCESS; } static int start(sox_effect_t * effp) { priv_t * p = (priv_t *)effp->priv; unsigned i, fixedPreTriggerLen_ns, searchPreTriggerLen_ns; fixedPreTriggerLen_ns = p->preTriggerTime * effp->in_signal.rate + .5; fixedPreTriggerLen_ns *= effp->in_signal.channels; p->measureLen_ws = effp->in_signal.rate * p->measureDuration + .5; p->measureLen_ns = p->measureLen_ws * effp->in_signal.channels; for (p->dftLen_ws = 16; p->dftLen_ws < p->measureLen_ws; p->dftLen_ws <<= 1); lsx_debug("dftLen_ws=%u measureLen_ws=%u", p->dftLen_ws, p->measureLen_ws); p->measurePeriod_ns = effp->in_signal.rate / p->measureFreq + .5; p->measurePeriod_ns *= effp->in_signal.channels; p->measuresLen = ceil(p->searchTime * p->measureFreq); searchPreTriggerLen_ns = p->measuresLen * p->measurePeriod_ns; p->gapLen = p->gapTime * p->measureFreq + .5; p->samplesLen_ns = fixedPreTriggerLen_ns + searchPreTriggerLen_ns + p->measureLen_ns; lsx_Calloc(p->samples, p->samplesLen_ns); lsx_Calloc(p->channels, effp->in_signal.channels); for (i = 0; i < effp->in_signal.channels; ++i) { chan_t * c = &p->channels[i]; lsx_Calloc(c->dftBuf, p->dftLen_ws); lsx_Calloc(c->spectrum, p->dftLen_ws); lsx_Calloc(c->noiseSpectrum, p->dftLen_ws); lsx_Calloc(c->measures, p->measuresLen); } lsx_Calloc(p->spectrumWindow, p->measureLen_ws); for (i = 0; i < p->measureLen_ws; ++i) p->spectrumWindow[i] = -2./ SOX_SAMPLE_MIN / sqrt((double)p->measureLen_ws); lsx_apply_hann(p->spectrumWindow, (int)p->measureLen_ws); p->spectrumStart = p->hpFilterFreq / effp->in_signal.rate * p->dftLen_ws + .5; p->spectrumStart = max(p->spectrumStart, 1); p->spectrumEnd = p->lpFilterFreq / effp->in_signal.rate * p->dftLen_ws + .5; p->spectrumEnd = min(p->spectrumEnd, p->dftLen_ws / 2); lsx_Calloc(p->cepstrumWindow, p->spectrumEnd - p->spectrumStart); for (i = 0; i < p->spectrumEnd - p->spectrumStart; ++i) p->cepstrumWindow[i] = 2 / sqrt((double)p->spectrumEnd - p->spectrumStart); lsx_apply_hann(p->cepstrumWindow,(int)(p->spectrumEnd - p->spectrumStart)); p->cepstrumStart = ceil(effp->in_signal.rate * .5 / p->lpLifterFreq); p->cepstrumEnd = floor(effp->in_signal.rate * .5 / p->hpLifterFreq); p->cepstrumEnd = min(p->cepstrumEnd, p->dftLen_ws / 4); if (p->cepstrumEnd <= p->cepstrumStart) return SOX_EOF; p->noiseTcUpMult = exp(-1 / (p->noiseTcUp * p->measureFreq)); p->noiseTcDownMult = exp(-1 / (p->noiseTcDown * p->measureFreq)); p->measureTcMult = exp(-1 / (p->measureTc * p->measureFreq)); p->triggerMeasTcMult = exp(-1 / (p->triggerTc * p->measureFreq)); p->bootCountMax = p->bootTime * p->measureFreq - .5; p->measureTimer_ns = p->measureLen_ns; p->bootCount = p->measuresIndex = p->flushedLen_ns = p->samplesIndex_ns = 0; return SOX_SUCCESS; } static int flowFlush(sox_effect_t * effp, sox_sample_t const * ibuf, sox_sample_t * obuf, size_t * ilen, size_t * olen) { priv_t * p = (priv_t *)effp->priv; size_t odone = min(p->samplesLen_ns - p->flushedLen_ns, *olen); size_t odone1 = min(odone, p->samplesLen_ns - p->samplesIndex_ns); memcpy(obuf, p->samples + p->samplesIndex_ns, odone1 * sizeof(*obuf)); if ((p->samplesIndex_ns += odone1) == p->samplesLen_ns) { memcpy(obuf + odone1, p->samples, (odone - odone1) * sizeof(*obuf)); p->samplesIndex_ns = odone - odone1; } if ((p->flushedLen_ns += odone) == p->samplesLen_ns) { size_t olen1 = *olen - odone; (effp->handler.flow = lsx_flow_copy)(effp, ibuf, obuf +odone, ilen, &olen1); odone += olen1; } else *ilen = 0; *olen = odone; return SOX_SUCCESS; } static double measure( priv_t * p, chan_t * c, size_t index_ns, unsigned step_ns, int bootCount) { double mult, result = 0; size_t i; for (i = 0; i < p->measureLen_ws; ++i, index_ns = (index_ns + step_ns) % p->samplesLen_ns) c->dftBuf[i] = p->samples[index_ns] * p->spectrumWindow[i]; memset(c->dftBuf + i, 0, (p->dftLen_ws - i) * sizeof(*c->dftBuf)); lsx_safe_rdft((int)p->dftLen_ws, 1, c->dftBuf); memset(c->dftBuf, 0, p->spectrumStart * sizeof(*c->dftBuf)); for (i = p->spectrumStart; i < p->spectrumEnd; ++i) { double d = sqrt(sqr(c->dftBuf[2 * i]) + sqr(c->dftBuf[2 * i + 1])); mult = bootCount >= 0? bootCount / (1. + bootCount) : p->measureTcMult; c->spectrum[i] = c->spectrum[i] * mult + d * (1 - mult); d = sqr(c->spectrum[i]); mult = bootCount >= 0? 0 : d > c->noiseSpectrum[i]? p->noiseTcUpMult : p->noiseTcDownMult; c->noiseSpectrum[i] = c->noiseSpectrum[i] * mult + d * (1 - mult); d = sqrt(max(0, d - p->noiseReductionAmount * c->noiseSpectrum[i])); c->dftBuf[i] = d * p->cepstrumWindow[i - p->spectrumStart]; } memset(c->dftBuf + i, 0, ((p->dftLen_ws >> 1) - i) * sizeof(*c->dftBuf)); lsx_safe_rdft((int)p->dftLen_ws >> 1, 1, c->dftBuf); for (i = p->cepstrumStart; i < p->cepstrumEnd; ++i) result += sqr(c->dftBuf[2 * i]) + sqr(c->dftBuf[2 * i + 1]); result = log(result / (p->cepstrumEnd - p->cepstrumStart)); return max(0, 21 + result); } static int flowTrigger(sox_effect_t * effp, sox_sample_t const * ibuf, sox_sample_t * obuf, size_t * ilen, size_t * olen) { priv_t * p = (priv_t *)effp->priv; sox_bool hasTriggered = sox_false; size_t i, idone = 0, numMeasuresToFlush = 0; while (idone < *ilen && !hasTriggered) { p->measureTimer_ns -= effp->in_signal.channels; for (i = 0; i < effp->in_signal.channels; ++i, ++idone) { chan_t * c = &p->channels[i]; p->samples[p->samplesIndex_ns++] = *ibuf++; if (!p->measureTimer_ns) { size_t x = (p->samplesIndex_ns + p->samplesLen_ns - p->measureLen_ns) % p->samplesLen_ns; double meas = measure(p, c, x, effp->in_signal.channels, p->bootCount); c->measures[p->measuresIndex] = meas; c->meanMeas = c->meanMeas * p->triggerMeasTcMult + meas *(1 - p->triggerMeasTcMult); if (hasTriggered |= c->meanMeas >= p->triggerLevel) { unsigned n = p->measuresLen, k = p->measuresIndex; unsigned j, jTrigger = n, jZero = n; for (j = 0; j < n; ++j, k = (k + n - 1) % n) if (c->measures[k] >= p->triggerLevel && j <= jTrigger + p->gapLen) jZero = jTrigger = j; else if (!c->measures[k] && jTrigger >= jZero) jZero = j; j = min(j, jZero); numMeasuresToFlush = range_limit(j, numMeasuresToFlush, n); } lsx_debug_more("%12g %12g %u", meas, c->meanMeas, (unsigned)numMeasuresToFlush); } } if (p->samplesIndex_ns == p->samplesLen_ns) p->samplesIndex_ns = 0; if (!p->measureTimer_ns) { p->measureTimer_ns = p->measurePeriod_ns; ++p->measuresIndex; p->measuresIndex %= p->measuresLen; if (p->bootCount >= 0) p->bootCount = p->bootCount == p->bootCountMax? -1 : p->bootCount + 1; } } if (hasTriggered) { size_t ilen1 = *ilen - idone; p->flushedLen_ns = (p->measuresLen - numMeasuresToFlush) * p->measurePeriod_ns; p->samplesIndex_ns = (p->samplesIndex_ns + p->flushedLen_ns) % p->samplesLen_ns; (effp->handler.flow = flowFlush)(effp, ibuf, obuf, &ilen1, olen); idone += ilen1; } else *olen = 0; *ilen = idone; return SOX_SUCCESS; } static int drain(sox_effect_t * effp, sox_sample_t * obuf, size_t * olen) { size_t ilen = 0; return effp->handler.flow(effp, NULL, obuf, &ilen, olen); } static int stop(sox_effect_t * effp) { priv_t * p = (priv_t *)effp->priv; unsigned i; for (i = 0; i < effp->in_signal.channels; ++i) { chan_t * c = &p->channels[i]; free(c->measures); free(c->noiseSpectrum); free(c->spectrum); free(c->dftBuf); } free(p->channels); free(p->cepstrumWindow); free(p->spectrumWindow); free(p->samples); return SOX_SUCCESS; } sox_effect_handler_t const * lsx_vad_effect_fn(void) { static sox_effect_handler_t handler = {"vad", NULL, SOX_EFF_MCHAN | SOX_EFF_LENGTH | SOX_EFF_MODIFY, create, start, flowTrigger, drain, stop, NULL, sizeof(priv_t) }; static char const * lines[] = { "[options]", "\t-t trigger-level (7)", "\t-T trigger-time-constant (0.25 s)", "\t-s search-time (1 s)", "\t-g allowed-gap (0.25 s)", "\t-p pre-trigger-time (0 s)", "Advanced options:", "\t-b noise-est-boot-time (0.35 s)", "\t-N noise-est-time-constant-up (0.1 s)", "\t-n noise-est-time-constant-down (0.01 s)", "\t-r noise-reduction-amount (1.35)", "\t-f measurement-frequency (20 Hz)", "\t-m measurement-duration (0.1 s)", "\t-M measurement-time-constant (0.4 s)", "\t-h high-pass-filter (50 Hz)", "\t-l low-pass-filter (6000 Hz)", "\t-H high-pass-lifter (150 Hz)", "\t-L low-pass-lifter (2000 Hz)", }; static char * usage; handler.usage = lsx_usage_lines(&usage, lines, array_length(lines)); return &handler; }