ref: f09c4ff40d21f9447f7c26a7f4b7dbdd6aa696a5
dir: /src/fade.c/
/* This code is based in skel.c * Written by Chris Bagwell (cbagwell@sprynet.com) - March 16, 1999 * Non-skel parts written by * Ari Moisio <armoi@sci.fi> Aug 29 2000. * * Copyright 1999 Chris Bagwell And Sundry Contributors * This source code is freely redistributable and may be used for * any purpose. This copyright notice must be maintained. * Chris Bagwell And Sundry Contributors are not responsible for * the consequences of using this software. */ /* Fade curves */ #define FADE_QUARTER 'q' /* Quarter of sine wave, 0 to pi/2 */ #define FADE_HALF 'h' /* Half of sine wave, pi/2 to 1.5 * pi * scaled so that -1 means no output * and 1 means 0 db attenuation. */ #define FADE_LOG 'l' /* Logarithmic curve. Fades -100 db * in given time. */ #define FADE_TRI 't' /* Linear slope. */ #define FADE_PAR 'p' /* Inverted parabola. */ #include <math.h> #include <string.h> #include "st_i.h" /* Private data for fade file */ typedef struct fadestuff { /* These are measured as samples */ st_size_t in_start, in_stop, out_start, out_stop, samplesdone; char *in_stop_str, *out_start_str, *out_stop_str; char in_fadetype, out_fadetype; int endpadwarned; } *fade_t; #define FADE_USAGE "Usage: fade [ type ] fade-in-length [ stop-time [ fade-out-length ] ]\nTimes in seconds.\nFade type one of q, h, t, l or p.\n" /* prototypes */ static double fade_gain(st_size_t index, st_size_t range, char fadetype); /* * Process options * * Don't do initialization now. * The 'info' fields are not yet filled in. */ int st_fade_getopts(eff_t effp, int n, char **argv) { fade_t fade = (fade_t) effp->priv; char t_char[2]; int t_argno; if (n < 1 || n > 4) { /* Wrong number of arguments. */ st_fail(FADE_USAGE); return(ST_EOF); } /* because sample rate is unavailable at this point we store the * string off for later computations. */ if (sscanf(argv[0], "%1[qhltp]", t_char)) { fade->in_fadetype = *t_char; fade->out_fadetype = *t_char; argv++; n--; } else { /* No type given. */ fade->in_fadetype = 'l'; fade->out_fadetype = 'l'; } fade->in_stop_str = malloc(strlen(argv[0])+1); if (!fade->in_stop_str) { st_fail("Could not allocate memory"); return (ST_EOF); } strcpy(fade->in_stop_str,argv[0]); /* Do a dummy parse to see if it will fail */ if (st_parsesamples(0, fade->in_stop_str, &fade->in_stop, 't') != ST_SUCCESS) { st_fail(FADE_USAGE); return(ST_EOF); } fade->out_start_str = fade->out_stop_str = 0; for (t_argno = 1; t_argno < n && t_argno < 3; t_argno++) { /* See if there is fade-in/fade-out times/curves specified. */ if(t_argno == 1) { fade->out_stop_str = malloc(strlen(argv[t_argno])+1); if (!fade->out_stop_str) { st_fail("Could not allocate memory"); return (ST_EOF); } strcpy(fade->out_stop_str,argv[t_argno]); /* Do a dummy parse to see if it will fail */ if (st_parsesamples(0, fade->out_stop_str, &fade->out_stop, 't') != ST_SUCCESS) { st_fail(FADE_USAGE); return(ST_EOF); } } else { fade->out_start_str = malloc(strlen(argv[t_argno])+1); if (!fade->out_start_str) { st_fail("Could not allocate memory"); return (ST_EOF); } strcpy(fade->out_start_str,argv[t_argno]); /* Do a dummy parse to see if it will fail */ if (st_parsesamples(0, fade->out_start_str, &fade->out_start, 't') != ST_SUCCESS) { st_fail(FADE_USAGE); return(ST_EOF); } } } /* End for(t_argno) */ return(ST_SUCCESS); } /* * Prepare processing. * Do all initializations. */ int st_fade_start(eff_t effp) { fade_t fade = (fade_t) effp->priv; /* converting time values to samples */ fade->in_start = 0; if (st_parsesamples(effp->ininfo.rate, fade->in_stop_str, &fade->in_stop, 't') != ST_SUCCESS) { st_fail(FADE_USAGE); return(ST_EOF); } /* See if user specified a stop time */ if (fade->out_stop_str) { if (st_parsesamples(effp->ininfo.rate, fade->out_stop_str, &fade->out_stop, 't') != ST_SUCCESS) { st_fail(FADE_USAGE); return(ST_EOF); } fade->out_stop += fade->out_start; /* See if user wants to fade out. */ if (fade->out_start_str) { if (st_parsesamples(effp->ininfo.rate, fade->out_start_str, &fade->out_start, 't') != ST_SUCCESS) { st_fail(FADE_USAGE); return(ST_EOF); } /* Fade time is relative to stop time. */ fade->out_start = fade->out_stop - fade->out_start; } else /* If user doesn't want to fade out then set to stop * time. */ fade->out_start = fade->out_stop; } else /* If not specified then user doesn't wants to process all * of file. Use a value of zero to indicate this. */ fade->out_stop = 0; /* Sanity check for fade times vs total time */ if (fade->in_stop > fade->out_start && fade->out_start != 0) { /* Fades too long */ st_fail("Fade: End of fade-in should not happen before beginning of fade-out"); return(ST_EOF); } /* endif fade time sanity */ /* If lead-in is required it is handled as negative sample numbers */ fade->samplesdone = (fade->in_start < 0 ? fade->in_start :0); fade->endpadwarned = 0; return(ST_SUCCESS); } /* * Processed signed long samples from ibuf to obuf. * Return number of samples processed. */ int st_fade_flow(eff_t effp, st_sample_t *ibuf, st_sample_t *obuf, st_size_t *isamp, st_size_t *osamp) { fade_t fade = (fade_t) effp->priv; /* len is total samples, chcnt counts channels */ int len = 0, chcnt = 0, t_output = 0; st_sample_t t_ibuf; len = ((*isamp > *osamp) ? *osamp : *isamp); *osamp = 0; *isamp = 0; for(; len; len--) { t_ibuf = (fade->samplesdone < 0 ? 0 : *ibuf); if ((fade->samplesdone >= fade->in_start) && (fade->out_stop == 0 || fade->samplesdone < fade->out_stop)) { /* something to generate output */ if (fade->samplesdone < fade->in_stop) { /* fade-in phase, increase gain */ *obuf = t_ibuf * fade_gain(fade->samplesdone - fade->in_start, fade->in_stop - fade->in_start, fade->in_fadetype); } /* endif fade-in */ if (fade->samplesdone >= fade->in_stop && (fade->out_start == 0 || fade->samplesdone < fade->out_start)) { /* steady gain phase */ *obuf = t_ibuf; } /* endif steady phase */ if (fade->out_start != 0 && fade->samplesdone >= fade->out_start) { /* fade-out phase, decrease gain */ *obuf = t_ibuf * fade_gain(fade->out_stop - fade->samplesdone, fade->out_stop - fade->out_start, fade->out_fadetype); } /* endif fade-out */ t_output = 1; } else { /* No output generated */ t_output = 0; } /* endif something to output */ if (fade->samplesdone >= 0 ) { /* Something to input */ *isamp += 1; ibuf++; } /* endif something accepted as input */ if (t_output) { /* Output generated, update pointers and counters */ obuf++; *osamp += 1; } /* endif t_output */ /* Process next channel */ chcnt++; if (chcnt >= effp->ininfo.channels) { /* all channels of this sample processed */ chcnt = 0; fade->samplesdone += 1; } /* endif all channels */ } /* endfor */ return(ST_SUCCESS); } /* * Drain out remaining samples if the effect generates any. */ int st_fade_drain(eff_t effp, st_sample_t *obuf, st_size_t *osamp) { fade_t fade = (fade_t) effp->priv; int len, t_chan = 0; len = *osamp; *osamp = 0; if (fade->out_stop != 0 && fade->samplesdone < fade->out_stop && !(fade->endpadwarned)) { /* Warning about padding silence into end of sample */ st_warn("Fade: warning: End time passed end-of-file. Padding with silence"); fade->endpadwarned = 1; } /* endif endpadwarned */ for (;len && (fade->out_stop != 0 && fade->samplesdone < fade->out_stop); len--) { *obuf = 0; obuf++; *osamp += 1; t_chan++; if (t_chan >= effp->ininfo.channels) { fade->samplesdone += 1; t_chan = 0; } /* endif channels */ } /* endfor */ return(ST_SUCCESS); } /* * Do anything required when you stop reading samples. * (free allocated memory, etc.) */ int st_fade_stop(eff_t effp) { fade_t fade = (fade_t) effp->priv; if (fade->in_stop_str) free(fade->in_stop_str); if (fade->out_start_str) free(fade->out_start_str); if (fade->out_stop_str) free(fade->out_stop_str); return (ST_SUCCESS); } /* Function returns gain value 0.0 - 1.0 according index / range ratio * and -1.0 if type is invalid * todo: to optimize performance calculate gain every now and then and interpolate */ static double fade_gain(st_size_t index, st_size_t range, char type) { double retval = 0.0, findex = 0.0; findex = 1.0 * index / range; /* todo: are these really needed */ findex = (findex < 0 ? 0.0 : findex); findex = (findex > 1.0 ? 1.0 : findex); switch (type) { case FADE_TRI : /* triangle */ retval = findex; break; case FADE_QUARTER : /* quarter of sinewave */ retval = sin(findex * M_PI / 2); break; case FADE_HALF : /* half of sinewave... eh cosine wave */ retval = (1 - cos(findex * M_PI )) / 2 ; break; case FADE_LOG : /* logaritmic */ /* 5 means 100 db attenuation. */ /* todo: should this be adopted with bit depth */ retval = pow(0.1, (1 - findex) * 5); break; case FADE_PAR : /* inverted parabola */ retval = (1 - (1 - findex) * (1 - findex)); break; /* todo: more fade curves? */ default : /* Error indicating wrong fade curve */ retval = -1.0; break; } /* endswitch */ return retval; }