Mercurial > hg > audiostuff
view spandsp-0.0.6pre17/src/time_scale.c @ 4:26cd8f1ef0b1
import spandsp-0.0.6pre17
| author | Peter Meerwald <pmeerw@cosy.sbg.ac.at> |
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| date | Fri, 25 Jun 2010 15:50:58 +0200 |
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/* * SpanDSP - a series of DSP components for telephony * * time_scale.c - Time scaling for linear speech data * * 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 Lesser General Public License version 2.1, * 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 Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. * * $Id: time_scale.c,v 1.30 2009/02/10 13:06:47 steveu Exp $ */ /*! \file */ #if defined(HAVE_CONFIG_H) #include "config.h" #endif #include <stdlib.h> #include <stdio.h> #include <inttypes.h> #include <string.h> #include <fcntl.h> #include <time.h> #include <limits.h> #if defined(HAVE_TGMATH_H) #include <tgmath.h> #endif #if defined(HAVE_MATH_H) #include <math.h> #endif #include "floating_fudge.h" #include "spandsp/telephony.h" #include "spandsp/fast_convert.h" #include "spandsp/time_scale.h" #include "spandsp/saturated.h" #include "spandsp/private/time_scale.h" /* Time scaling for speech, based on the Pointer Interval Controlled OverLap and Add (PICOLA) method, developed by Morita Naotaka. */ static __inline__ int amdf_pitch(int min_pitch, int max_pitch, int16_t amp[], int len) { int i; int j; int acc; int min_acc; int pitch; pitch = min_pitch; min_acc = INT_MAX; for (i = max_pitch; i <= min_pitch; i++) { acc = 0; for (j = 0; j < len; j++) acc += abs(amp[i + j] - amp[j]); if (acc < min_acc) { min_acc = acc; pitch = i; } } return pitch; } /*- End of function --------------------------------------------------------*/ static __inline__ void overlap_add(int16_t amp1[], int16_t amp2[], int len) { int i; float weight; float step; step = 1.0f/len; weight = 0.0f; for (i = 0; i < len; i++) { /* TODO: saturate */ amp2[i] = (int16_t) ((float) amp1[i]*(1.0f - weight) + (float) amp2[i]*weight); weight += step; } } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(int) time_scale_rate(time_scale_state_t *s, float playout_rate) { if (playout_rate <= 0.0f) return -1; /*endif*/ if (playout_rate >= 0.99f && playout_rate <= 1.01f) { /* Treat rate close to normal speed as exactly normal speed, and avoid divide by zero, and other numerical problems. */ playout_rate = 1.0f; } else if (playout_rate < 1.0f) { s->rcomp = playout_rate/(1.0f - playout_rate); } else { s->rcomp = 1.0f/(playout_rate - 1.0f); } /*endif*/ s->playout_rate = playout_rate; return 0; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(time_scale_state_t *) time_scale_init(time_scale_state_t *s, int sample_rate, float playout_rate) { int alloced; if (sample_rate > TIME_SCALE_MAX_SAMPLE_RATE) return NULL; alloced = FALSE; if (s == NULL) { if ((s = (time_scale_state_t *) malloc(sizeof (*s))) == NULL) return NULL; /*endif*/ alloced = TRUE; } /*endif*/ s->sample_rate = sample_rate; s->min_pitch = sample_rate/TIME_SCALE_MIN_PITCH; s->max_pitch = sample_rate/TIME_SCALE_MAX_PITCH; s->buf_len = 2*sample_rate/TIME_SCALE_MIN_PITCH; if (time_scale_rate(s, playout_rate)) { if (alloced) free(s); return NULL; } /*endif*/ s->rate_nudge = 0.0f; s->fill = 0; s->lcp = 0; return s; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(int) time_scale_release(time_scale_state_t *s) { return 0; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(int) time_scale_free(time_scale_state_t *s) { free(s); return 0; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(int) time_scale(time_scale_state_t *s, int16_t out[], int16_t in[], int len) { double lcpf; int pitch; int out_len; int in_len; int k; out_len = 0; in_len = 0; /* Top up the buffer */ if (s->fill + len < s->buf_len) { /* Cannot continue without more samples */ memcpy(s->buf + s->fill, in, sizeof(int16_t)*len); s->fill += len; return out_len; } k = s->buf_len - s->fill; memcpy(s->buf + s->fill, in, sizeof(int16_t)*k); in_len += k; s->fill = s->buf_len; while (s->fill == s->buf_len) { while (s->lcp >= s->buf_len) { memcpy(out + out_len, s->buf, sizeof(int16_t)*s->buf_len); out_len += s->buf_len; if (len - in_len < s->buf_len) { /* Cannot continue without more samples */ memcpy(s->buf, in + in_len, sizeof(int16_t)*(len - in_len)); s->fill = len - in_len; s->lcp -= s->buf_len; return out_len; } memcpy(s->buf, in + in_len, sizeof(int16_t)*s->buf_len); in_len += s->buf_len; s->lcp -= s->buf_len; } if (s->lcp > 0) { memcpy(out + out_len, s->buf, sizeof(int16_t)*s->lcp); out_len += s->lcp; memcpy(s->buf, s->buf + s->lcp, sizeof(int16_t)*(s->buf_len - s->lcp)); if (len - in_len < s->lcp) { /* Cannot continue without more samples */ memcpy(s->buf + (s->buf_len - s->lcp), in + in_len, sizeof(int16_t)*(len - in_len)); s->fill = s->buf_len - s->lcp + len - in_len; s->lcp = 0; return out_len; } memcpy(s->buf + (s->buf_len - s->lcp), in + in_len, sizeof(int16_t)*s->lcp); in_len += s->lcp; s->lcp = 0; } if (s->playout_rate == 1.0f) { s->lcp = 0x7FFFFFFF; } else { pitch = amdf_pitch(s->min_pitch, s->max_pitch, s->buf, s->min_pitch); lcpf = (double) pitch*s->rcomp; /* Nudge around to compensate for fractional samples */ s->lcp = (int) lcpf; /* Note that s->lcp and lcpf are not the same, as lcpf has a fractional part, and s->lcp doesn't */ s->rate_nudge += s->lcp - lcpf; if (s->rate_nudge >= 0.5f) { s->lcp--; s->rate_nudge -= 1.0f; } else if (s->rate_nudge <= -0.5f) { s->lcp++; s->rate_nudge += 1.0f; } if (s->playout_rate < 1.0f) { /* Speed up - drop a chunk of data */ overlap_add(s->buf, s->buf + pitch, pitch); memcpy(&s->buf[pitch], &s->buf[2*pitch], sizeof(int16_t)*(s->buf_len - 2*pitch)); if (len - in_len < pitch) { /* Cannot continue without more samples */ memcpy(s->buf + s->buf_len - pitch, in + in_len, sizeof(int16_t)*(len - in_len)); s->fill += (len - in_len - pitch); return out_len; } memcpy(s->buf + s->buf_len - pitch, in + in_len, sizeof(int16_t)*pitch); in_len += pitch; } else { /* Slow down - insert a chunk of data */ memcpy(out + out_len, s->buf, sizeof(int16_t)*pitch); out_len += pitch; overlap_add(s->buf + pitch, s->buf, pitch); } } } return out_len; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(int) time_scale_max_output_len(time_scale_state_t *s, int input_len) { return (int) (input_len*s->playout_rate + s->min_pitch + 1); } /*- End of function --------------------------------------------------------*/ /*- End of file ------------------------------------------------------------*/