ref: 210336f9b78b4089163bc16804a1e76984c6c46d
dir: /src/pitch.c/
/* * (c) Fabien Coelho <fabien@coelho.net> 03/2000 for sox. see sox copyright. * * pitch shifting. * * I found a code on the Computer Music Journal web site * <http://mitpress.mit.edu/e-journals/Computer_Music_Journal/> * for pitch shifting the AD 1848 PC soundcards, with * a lot of (unclear) pointer and integer arithmetics, and * combine effects (feedback, delay, mixing). * * I tried to understand the code, dropped the other effects, * translated the stuff in float so it's easier to understand, * drop one of the lookup tables (I know that sin(pi/2-x) = cos(x)), * and added interpolation and fade options of my own. * cross fading is always symetric. * * Basically, the algorithm performs a resampling at the desire rate * to achieve the shift (interpolation function) on small overlapping windows, * and successive windows are faded in/out one into the other to * rebuild the final signal. * * I'm quite disappointed. At first thought, I looked for an FT-based * algorithm, something like "switch the signal to frequencies, shift * frequencies, and come back to time", but it does not seem to work * that way... at least not so easily. Or maybe my attempt was buggy. * * Here is the result. It can certainly be improved. * The result buzzes some time. * Lot of options available so than one can adjust the result. * * so as to lower the pitch, a larger window sounds better (30ms)? * so as to upper the pitch, a smaller window... (10ms)? * * Some speed-optimization could be added at code size expanse/expense? */ #include "st_i.h" #include <stdlib.h> /* malloc(), free() */ #include <string.h> /* memcpy() */ #include <math.h> /* cos(), pow() */ static st_effect_t st_pitch_effect; /* float type for the computations. should be common to all effects? I use such trick in vol, pan, speed, pitch and stretch... */ #ifndef PITCH_FLOAT #define PITCH_FLOAT double #define PITCH_FLOAT_SCAN "%lf" #endif /* cross fading options for transitions */ #define PITCH_FADE_COS 0 /* cosine */ #define PITCH_FADE_HAM 1 /* Hamming */ #define PITCH_FADE_LIN 2 /* linear */ #define PITCH_FADE_TRA 3 /* trapezoid */ #define PITCH_FADE_DEFAULT PITCH_FADE_COS /* interpolation options */ #define PITCH_INTERPOLE_CUB 0 /* cubic */ #define PITCH_INTERPOLE_LIN 1 /* linear */ #define PITCH_INTERPOLE_DEFAULT PITCH_INTERPOLE_CUB /* default window width */ #define PITCH_DEFAULT_WIDTH ((PITCH_FLOAT)(20.0e0)) /* 20 ms */ /* constants. */ #define OCTAVA ((PITCH_FLOAT)(1200.0e0)) /* in cents */ #define THOUSAND ((PITCH_FLOAT)(1000.0e0)) /* in units */ #define HUNDRED ((PITCH_FLOAT)(100.0e0)) #define FOUR ((PITCH_FLOAT)(4.0e0)) #define TWO ((PITCH_FLOAT)(2.0e0)) #define ONE ((PITCH_FLOAT)(1.0e0)) #define HALF ((PITCH_FLOAT)(0.5e0)) #define QUARTER ((PITCH_FLOAT)(0.25e0)) #define ONESIXTH ((PITCH_FLOAT)(1.0e0/6.0e0)) #define ZERO ((PITCH_FLOAT)(0.0e0)) /* linear factors for the Hamming window 0<=i<=n: HAM_n(i) = HAM0 + HAM1*cos(i*PI/n) */ #define HAM1 ((PITCH_FLOAT)(0.46e0)) #define HAM0 ((PITCH_FLOAT)(0.54e0)) /* state of buffer management... */ typedef enum { pi_input, pi_compute, pi_output } pitch_state_t; /* structure hold by the effect descriptor. */ typedef struct { /* OPTIONS */ PITCH_FLOAT shift; /* shift in cents, >0 to treble, <0 to bass */ PITCH_FLOAT width; /* sweep size in ms */ int interopt; /* interpole option */ int fadeopt; /* fade option */ PITCH_FLOAT coef; /* coefficient used by trapezoid */ /* what about coef1/coef2 for hamming... */ /* COMPUTATION */ PITCH_FLOAT rate; /* sweep rate, around 1.0 */ unsigned int step; /* size of half a sweep, rounded to integer... */ PITCH_FLOAT * fade; /* fading factors table lookup, ~ 1.0 -> ~ 0.0 */ int overlap; /* needed overlap */ PITCH_FLOAT * tmp; /* temporary buffer */ PITCH_FLOAT * acc; /* accumulation buffer */ unsigned int iacc; /* part of acc already output */ st_size_t size; /* size of buffer for processing chunks. */ unsigned int index; /* index of next empty input item. */ st_sample_t *buf; /* bufferize input */ pitch_state_t state; /* buffer management status. */ } * pitch_t; /* // debug functions static char * fadeoptname(int opt) { switch (opt) { case PITCH_FADE_COS: return "cosine"; case PITCH_FADE_HAM: return "hamming"; case PITCH_FADE_LIN: return "linear"; case PITCH_FADE_TRA: return "trapezoid"; default: return "UNEXPECTED"; } } static void debug(pitch_t pitch, char * where) { st_debug("%s: ind=%d sz=%ld step=%d o=%d rate=%f ia=%d st=%d fo=%s", where, pitch->index, pitch->size, pitch->step, pitch->overlap, pitch->rate, pitch->iacc, pitch->state, fadeoptname(pitch->fadeopt)); } */ /* compute f(x) as a linear interpolation... */ static PITCH_FLOAT lin( PITCH_FLOAT f0, /* f(0) */ PITCH_FLOAT f1, /* f(1) */ PITCH_FLOAT x) /* 0.0 <= x < 1.0 */ { return f0 * (ONE - x) + f1 * x; } /* compute f(x) as a cubic function... */ static PITCH_FLOAT cub( PITCH_FLOAT fm1, /* f(-1) */ PITCH_FLOAT f0, /* f(0) */ PITCH_FLOAT f1, /* f(1) */ PITCH_FLOAT f2, /* f(2) */ PITCH_FLOAT x) /* 0.0 <= x < 1.0 */ { /* a x^3 + b x^2 + c x + d */ register PITCH_FLOAT a, b, c, d; d = f0; b = HALF * (f1+fm1) - f0; a = ONESIXTH * (f2-f1+fm1-f0-FOUR*b); c = f1 - a - b - d; return ((a * x + b) * x + c) * x + d; } /* interpolate a quarter (half a window) * * ibuf buffer of ilen length is swept at rate speed. * result put in output buffer obuf of size olen. */ static void interpolation( pitch_t pitch, st_sample_t *ibuf, int ilen, PITCH_FLOAT * out, int olen, PITCH_FLOAT rate) /* signed */ { register int i, size; register PITCH_FLOAT index; size = pitch->step; /* size == olen? */ if (rate>0) /* sweep forwards */ { for (index=ZERO, i=0; i<olen; i++, index+=rate) { register int ifl = (int) index; /* FLOOR */ register PITCH_FLOAT frac = index - ifl; if (pitch->interopt==PITCH_INTERPOLE_LIN) out[i] = lin((PITCH_FLOAT) ibuf[ifl], (PITCH_FLOAT) ibuf[ifl+1], frac); else out[i] = cub((PITCH_FLOAT) ibuf[ifl-1], (PITCH_FLOAT) ibuf[ifl], (PITCH_FLOAT) ibuf[ifl+1], (PITCH_FLOAT) ibuf[ifl+2], frac); } } else /* rate < 0, sweep backwards */ { for (index=ilen-1, i=olen-1; i>=0; i--, index+=rate) { register int ifl = (int) index; /* FLOOR */ register PITCH_FLOAT frac = index - ifl; if (pitch->interopt==PITCH_INTERPOLE_LIN) out[i] = lin((PITCH_FLOAT) ibuf[ifl], (PITCH_FLOAT) ibuf[ifl+1], frac); else out[i] = cub((PITCH_FLOAT) ibuf[ifl-1], (PITCH_FLOAT) ibuf[ifl], (PITCH_FLOAT) ibuf[ifl+1], (PITCH_FLOAT) ibuf[ifl+2], frac); } } } /* from input buffer to acc */ static void process_intput_buffer(pitch_t pitch) { register int i, len = pitch->step; /* forwards sweep */ interpolation(pitch, pitch->buf+pitch->overlap, pitch->step+pitch->overlap, pitch->tmp, pitch->step, pitch->rate); for (i=0; i<len; i++) pitch->acc[i] = pitch->fade[i]*pitch->tmp[i]; /* backwards sweep */ interpolation(pitch, pitch->buf, pitch->step+pitch->overlap, pitch->tmp, pitch->step, -pitch->rate); for (i=0; i<len; i++) pitch->acc[i] += pitch->fade[pitch->step-i-1]*pitch->tmp[i]; } /* * Process options */ int st_pitch_getopts(eff_t effp, int n, char **argv) { pitch_t pitch = (pitch_t) effp->priv; /* get pitch shift */ pitch->shift = ZERO; /* default is no change */ if (n && !sscanf(argv[0], PITCH_FLOAT_SCAN, &pitch->shift)) { st_fail(st_pitch_effect.usage); return ST_EOF; } /* sweep size in ms */ pitch->width = PITCH_DEFAULT_WIDTH; if (n>1 && !sscanf(argv[1], PITCH_FLOAT_SCAN, &pitch->width)) { st_fail(st_pitch_effect.usage); return ST_EOF; } /* interpole option */ pitch->interopt = PITCH_INTERPOLE_DEFAULT; if (n>2) { switch(argv[2][0]) { case 'l': case 'L': pitch->interopt = PITCH_INTERPOLE_LIN; break; case 'c': case 'C': pitch->interopt = PITCH_INTERPOLE_CUB; break; default: st_fail(st_pitch_effect.usage); return ST_EOF; } } /* fade option */ pitch->fadeopt = PITCH_FADE_DEFAULT; /* default */ if (n>3) { switch (argv[3][0]) /* what a parser;-) */ { case 'l': case 'L': pitch->fadeopt = PITCH_FADE_LIN; break; case 't': case 'T': pitch->fadeopt = PITCH_FADE_TRA; break; case 'h': case 'H': pitch->fadeopt = PITCH_FADE_HAM; break; case 'c': case 'C': pitch->fadeopt = PITCH_FADE_COS; break; default: st_fail(st_pitch_effect.usage); return ST_EOF; } } pitch->coef = QUARTER; if (n>4 && (!sscanf(argv[4], PITCH_FLOAT_SCAN, &pitch->coef) || pitch->coef<ZERO || pitch->coef>HALF)) { st_fail(st_pitch_effect.usage); return ST_EOF; } return ST_SUCCESS; } /* * Start processing */ int st_pitch_start(eff_t effp) { pitch_t pitch = (pitch_t) effp->priv; register int sample_rate = effp->outinfo.rate; unsigned int i; /* check constraints. sox does already take care of that I guess? */ if (effp->outinfo.rate != effp->ininfo.rate) { st_fail("PITCH cannot handle different rates (in=%ld, out=%ld)" " use resample or rate", effp->ininfo.rate, effp->outinfo.rate); return ST_EOF; } if (effp->outinfo.channels != effp->ininfo.channels) { st_fail("PITCH cannot handle different channels (in=%ld, out=%ld)" " use avg or pan", effp->ininfo.channels, effp->outinfo.channels); return ST_EOF; } /* computer inner stuff... */ pitch->state = pi_input; /* Should I trust pow? * BTW, the twelve's root of two is 1.0594630943592952645618252, * if we consider an equal temperament. */ pitch->rate = pow(TWO, pitch->shift/OCTAVA); /* size is half of the actual target window size, because of symetry. */ pitch->step = ((pitch->width*(HALF/THOUSAND))*sample_rate); /* make size odd? do we care? */ /* if (!(size & 1)) size++; */ /* security for safe cubic interpolation */ if (pitch->rate > ONE) pitch->overlap = (int) ((pitch->rate-ONE)*pitch->step) + 2; else pitch->overlap = 2; pitch->size = pitch->step + 2*pitch->overlap; pitch->fade = (PITCH_FLOAT *) malloc(pitch->step*sizeof(PITCH_FLOAT)); pitch->tmp = (PITCH_FLOAT *) malloc(pitch->step*sizeof(PITCH_FLOAT)); pitch->acc = (PITCH_FLOAT *) malloc(pitch->step*sizeof(PITCH_FLOAT)); pitch->buf = (st_sample_t *) malloc(pitch->size*sizeof(st_sample_t)); if (!pitch->fade || !pitch->tmp || !pitch->acc || !pitch->buf) { st_fail("malloc failed in st_pitch_start"); return ST_EOF; } pitch->index = pitch->overlap; /* default initial signal */ for (i=0; i<pitch->size; i++) pitch->buf[i] = 0; if (pitch->fadeopt == PITCH_FADE_HAM) { /* does it make sense to have such an option? */ register PITCH_FLOAT pi_step = M_PI / (pitch->step-1); for (i=0; i<pitch->step; i++) pitch->fade[i] = (PITCH_FLOAT) (HAM0 + HAM1*cos(pi_step*i)); } else if (pitch->fadeopt == PITCH_FADE_COS) { register PITCH_FLOAT pi_2_step = M_PI_2 / (pitch->step-1); pitch->fade[0] = ONE; /* cos(0) == 1.0 */ for (i=1; i<pitch->step-1; i++) pitch->fade[i] = (PITCH_FLOAT) cos(pi_2_step*i); pitch->fade[pitch->step-1] = ZERO; /* cos(PI/2) == 0.0 */ } else if (pitch->fadeopt == PITCH_FADE_LIN) { register PITCH_FLOAT stepth = ONE / (pitch->step-1); pitch->fade[0] = ONE; for (i=1; i<pitch->step-1; i++) pitch->fade[i] = (pitch->step-i-1) * stepth; pitch->fade[pitch->step-1] = ZERO; } else if (pitch->fadeopt == PITCH_FADE_TRA) { /* 0 <= coef <= 0.5 */ register unsigned int plat = (int) (pitch->step*pitch->coef); register PITCH_FLOAT slope = ONE / (pitch->step - 2*plat); for (i=0; i<plat; i++) pitch->fade[i] = ONE; for (; i<pitch->step-plat; i++) pitch->fade[i] = slope * (pitch->step-plat-i-1); for (; i<pitch->step; i++) pitch->fade[i] = ZERO; } else { st_fail("unexpected PITCH_FADE parameter %d", pitch->fadeopt); return ST_EOF; } return ST_SUCCESS; } /* Processes input. */ int st_pitch_flow(eff_t effp, st_sample_t *ibuf, st_sample_t *obuf, st_size_t *isamp, st_size_t *osamp) { pitch_t pitch = (pitch_t) effp->priv; int i, size; st_size_t len, iindex, oindex; size = pitch->size; /* size to process */ len = min(*isamp, *osamp); iindex = 0; oindex = 0; /* warning: because of the asynchroneous nature of buffering, the output index can reach the buffer limits before full consumption. I put the input index just in case. If the code is correct, eithier len or iindex is redundant. */ while (len>0 && iindex<*isamp && oindex<*osamp) { if (pitch->state == pi_input) { register int tocopy = min(pitch->size-pitch->index, len); memcpy(pitch->buf+pitch->index, ibuf+iindex, tocopy*sizeof(st_sample_t)); len -= tocopy; pitch->index += tocopy; iindex += tocopy; if (pitch->index==pitch->size) pitch->state = pi_compute; } if (pitch->state == pi_compute) { process_intput_buffer(pitch); pitch->state = pi_output; pitch->iacc = 0; } if (pitch->state == pi_output) { int toout = min(*osamp-oindex, pitch->step-pitch->iacc); for (i=0; i<toout; i++) { float f; f = pitch->acc[pitch->iacc++]; ST_EFF_SAMPLE_CLIP_COUNT(f); obuf[oindex++] = f; } if (pitch->iacc == pitch->step) { pitch->state = pi_input; /* shift input buffer. memmove? */ for (i=0; i<2*pitch->overlap; i++) pitch->buf[i] = pitch->buf[i+pitch->step]; pitch->index = 2*pitch->overlap; } } } /* report consumption. */ *isamp = iindex; *osamp = oindex; return ST_SUCCESS; } /* at the end... */ int st_pitch_drain(eff_t effp, st_sample_t *obuf, st_size_t *osamp) { pitch_t pitch = (pitch_t) effp->priv; st_size_t i; if (pitch->state == pi_input) { /* complete input buffer content with 0. */ for (i=pitch->index; i<pitch->size; i++) pitch->buf[i] = 0; pitch->state = pi_compute; } if (pitch->state == pi_compute) { process_intput_buffer(pitch); pitch->state = pi_output; pitch->iacc = 0; } /* (pitch->state == pi_output) */ for (i=0; i<*osamp && i<pitch->index-pitch->overlap;) { float f; f = pitch->acc[pitch->iacc++]; ST_EFF_SAMPLE_CLIP_COUNT(f); obuf[i++] = f; } /* report... */ *osamp = i; if ((pitch->index - pitch->overlap) == 0) return ST_EOF; else return ST_SUCCESS; } /* * Do anything required when you stop reading samples. * Don't close input file! */ int st_pitch_stop(eff_t effp) { pitch_t pitch = (pitch_t) effp->priv; free(pitch->fade); free(pitch->tmp); free(pitch->acc); free(pitch->buf); return ST_SUCCESS; } static st_effect_t st_pitch_effect = { "pitch", "Usage: pitch shift width interpole fade\n" " (in cents, in ms, cub/lin, cos/ham/lin/trap)" " (defaults: 0 20 c c)", 0, st_pitch_getopts, st_pitch_start, st_pitch_flow, st_pitch_drain, st_pitch_stop }; const st_effect_t *st_pitch_effect_fn(void) { return &st_pitch_effect; }