ref: 0519583288057272ec626e6ad391be44a75574d9
dir: /src/polyphas.c/
/* libSoX rate change effect file. * * July 14, 1998 * Copyright 1998 K. Bradley, Carnegie Mellon University * * 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 * * October 29, 1999 * Various changes, bugfixes, speedups, by Stan Brooks. * */ #include "sox_i.h" #include <stdio.h> #include <stdlib.h> #include <string.h> #define Float float/*double*/ #define ISCALE 0x10000 #define MF 30 typedef struct { int up, down; /* up/down conversion factors for this stage */ int filt_len; /* # coefficients in filter_array */ Float *filt_array; /* filter coefficients */ int held; /* # samples held in input but not yet processed */ int hsize; /* # samples of past-history kept in lower window */ int size; /* # samples current data which window can accept */ Float *window; /* this is past_hist[hsize], then input[size] */ } polystage; typedef struct { unsigned lcmrate; /* least common multiple of rates */ unsigned inskip, outskip; /* LCM increments for I & O rates */ double Factor; /* out_rate/in_rate */ unsigned long total; /* number of filter stages */ size_t oskip; /* output samples to skip at start*/ double inpipe; /* output samples 'in the pipe' */ polystage *stage[MF]; /* array of pointers to polystage structs */ int win_type; int win_width; Float cutoff; int m1[MF], m2[MF], b1[MF], b2[MF]; /* arrays used in optimize_factors */ } priv_t; /* * Process options */ static int sox_poly_getopts(sox_effect_t * effp, int n, char **argv) { priv_t * rate = (priv_t *) effp->priv; rate->win_type = 0; /* 0: nuttall, 1: hamming */ rate->win_width = 1024; rate->cutoff = 0.95; while (n >= 2) { /* Window type check */ if(!strcmp(argv[0], "-w")) { if(!strcmp(argv[1], "ham")) rate->win_type = 1; if(!strcmp(argv[1], "nut")) rate->win_type = 0; argv += 2; n -= 2; continue; } /* Window width check */ if(!strcmp(argv[0], "-width")) { rate->win_width = atoi(argv[1]); argv += 2; n -= 2; continue; } /* Cutoff frequency check */ if(!strcmp(argv[0], "-cutoff")) { rate->cutoff = atof(argv[1]); argv += 2; n -= 2; continue; } lsx_fail("Polyphase: unknown argument (%s %s)!", argv[0], argv[1]); return SOX_EOF; } return SOX_SUCCESS; } /* * Prepare processing. */ static const unsigned short primes[] = { 2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97, 101, 103, 107, 109, 113, 127, 131, 137, 139, 149, 151, 157, 163, 167, 173, 179, 181, 191, 193, 197, 199, 211, 223, 227, 229, 233, 239, 241, 251, 257, 263, 269, 271, 277, 281, 283, 293, 307, 311, 313, 317, 331, 337, 347, 349, 353, 359, 367, 373, 379, 383, 389, 397, 401, 409, 419, 421, 431, 433, 439, 443, 449, 457, 461, 463, 467, 479, 487, 491, 499, 503, 509, 521, 523, 541, 547, 557, 563, 569, 571, 577, 587, 593, 599, 601, 607, 613, 617, 619, 631, 641, 643, 647, 653, 659, 661, 673, 677, 683, 691, 701, 709, 719, 727, 733, 739, 743, 751, 757, 761, 769, 773, 787, 797, 809, 811, 821, 823, 827, 829, 839, 853, 857, 859, 863, 877, 881, 883, 887, 907, 911, 919, 929, 937, 941, 947, 953, 967, 971, 977, 983, 991, 997, 0 }; static int prime(unsigned n, int *q0) { const unsigned short *p; int pr, *q; p = primes; q = q0; lsx_debug("factors(%d) =",n); while (n > 1) { while ((pr = *p) && (n % pr)) p++; if (!pr) { lsx_fail("Number %d too large of a prime.",n); pr = n; } *q++ = pr; n /= pr; } *q = 0; for (pr=0; pr<q-q0; pr++) lsx_debug(" %d",q0[pr]); lsx_debug(" "); return (q-q0); } static int permute(int *m, int *l, int ct, int ct1, size_t amalg) { size_t k, n; int *p; int *q; p=l; q=m; while (ct1>ct) { *q++=1; ct++;} while ((*q++=*p++)) ; if (ct<=1) return ct; for (k=ct; k>1; ) { int tmp; unsigned long j; j = (rand()%32768) + ((rand()%32768)<<13); /* reasonably big */ j = j % k; /* non-negative! */ k--; if (j != k) { tmp = m[k]; m[k]=m[j]; m[j]=tmp; } } /* now m is a 'random' permutation of l */ p = q = m; n = *q++; while ((k=*q++)) { if ((n * k <= amalg) && (rand() & 1)) { n *= k; } else { *p++ = n; n = k; } } if (n) *p++=n; *p = 0; /*for (k=0; k<p-m; k++) lsx_debug(" %d",m[k]);*/ /*lsx_debug("");*/ return (p-m); } static int optimize_factors(priv_t * rate, unsigned numer, unsigned denom, int *l1, int *l2) { unsigned f_min; int c_min,u_min,ct1,ct2; size_t amalg; int k; memset(rate->m1,0,sizeof(int)*MF); memset(rate->m2,0,sizeof(int)*MF); memset(rate->b1,0,sizeof(int)*MF); memset(rate->b2,0,sizeof(int)*MF); f_min = numer; if (f_min>denom) f_min = denom; c_min = 1<<30; u_min = 0; /* Find the prime factors of numer and denom */ ct1 = prime(numer,l1); ct2 = prime(denom,l2); for (amalg = max(9,l2[0]); amalg <= (size_t)(9+l2[ct2-1]); amalg++) { for (k = 0; k<100000; k++) { unsigned f; int u,u1,u2,j,cost; cost = 0; f = denom; u = min(ct1,ct2) + 1; /*lsx_debug("pfacts(%d): ", numer);*/ u1 = permute(rate->m1,l1,ct1,u,amalg); /*lsx_debug("pfacts(%d): ", denom);*/ u2 = permute(rate->m2,l2,ct2,u,amalg); u = max(u1,u2); for (j=0; j<u; j++) { if (j>=u1) rate->m1[j]=1; if (j>=u2) rate->m2[j]=1; f = (f * rate->m1[j])/rate->m2[j]; if (f < f_min) goto fail; cost += f + rate->m1[j]*rate->m2[j]; } if (c_min>cost) { c_min = cost; u_min = u; if (sox_globals.verbosity >= 4) { lsx_debug("c_min %d, [%d-%d]:",c_min,numer,denom); for (j=0; j<u; j++) lsx_debug(" (%d,%d)",rate->m1[j],rate->m2[j]); lsx_debug(" "); } memcpy(rate->b1,rate->m1,u*sizeof(int)); memcpy(rate->b2,rate->m2,u*sizeof(int)); } fail: ;; } if (u_min) break; } if (u_min) { memcpy(l1,rate->b1,u_min*sizeof(int)); memcpy(l2,rate->b2,u_min*sizeof(int)); } l1[u_min] = 0; l2[u_min] = 0; return u_min; } /* Calculate a Nuttall window of a given length. Buffer must already be allocated to appropriate size. */ static void nuttall(Float *buffer, int length) { int j; double N; int N1; if(buffer == NULL || length <= 0) lsx_fail("Illegal buffer %p or length %d to nuttall.", (void *)buffer, length); /* Initial variable setups. */ N = length; N1 = length/2; for(j = 0; j < length; j++) { buffer[j] = 0.3635819 + 0.4891775 * cos(2*M_PI*1*(j - N1) / N) + 0.1365995 * cos(2*M_PI*2*(j - N1) / N) + 0.0106411 * cos(2*M_PI*3*(j - N1) / N); } } /* Calculate a Hamming window of given length. Buffer must already be allocated to appropriate size. */ static void hamming(Float *buffer, int length) { int j; int N1; if(buffer == NULL || length <= 0) lsx_fail("Illegal buffer %p or length %d to hamming.",(void *)buffer,length); N1 = length/2; for(j=0;j<length;j++) buffer[j] = 0.5 - 0.46 * cos(M_PI*j/N1); } /* Calculate the sinc function properly */ static Float sinc(double value) { return(fabs(value) < 1E-50 ? 1.0 : sin(value) / value); } /* Design a low-pass FIR filter using window technique. Length of filter is in length, cutoff frequency in cutoff. 0 < cutoff <= 1.0 (normalized frequency) buffer must already be allocated. */ static void fir_design(priv_t * rate, Float *buffer, int length, double cutoff) { int j; double sum; if(buffer == NULL || length < 0 || cutoff < 0 || cutoff > M_PI) lsx_fail("Illegal buffer %p, length %d, or cutoff %f.",(void *)buffer,length,cutoff); /* Use the user-option of window type */ if (rate->win_type == 0) nuttall(buffer, length); /* Design Nuttall window: ** dB cutoff */ else hamming(buffer,length); /* Design Hamming window: 43 dB cutoff */ /* lsx_debug("# fir_design length=%d, cutoff=%8.4f",length,cutoff); */ /* Design filter: windowed sinc function */ sum = 0.0; for(j=0;j<length;j++) { buffer[j] *= sinc(M_PI*cutoff*(j-length/2)); /* center at length/2 */ /* lsx_debug("%.1f %.6f",(float)j,buffer[j]); */ sum += buffer[j]; } sum = (double)1.0/sum; /* Normalize buffer to have gain of 1.0: prevent roundoff error */ for(j=0;j<length;j++) { buffer[j] *= sum; } /* lsx_debug("# end"); */ } #define RIBLEN 2048 static int sox_poly_start(sox_effect_t * effp) { priv_t * rate = (priv_t *) effp->priv; static int l1[MF], l2[MF]; double skip = 0; int total, size, uprate; int k; if (effp->in_signal.rate == effp->out_signal.rate) return SOX_EFF_NULL; effp->out_signal.channels = effp->in_signal.channels; rate->lcmrate = lsx_lcm((unsigned)effp->in_signal.rate, (unsigned)effp->out_signal.rate); /* Cursory check for LCM overflow. * If both rates are below 65k, there should be no problem. * 16 bits x 16 bits = 32 bits, which we can handle. */ rate->inskip = rate->lcmrate / (sox_sample_t)effp->in_signal.rate; rate->outskip = rate->lcmrate / (sox_sample_t)effp->out_signal.rate; rate->Factor = (double)rate->inskip / (double)rate->outskip; rate->inpipe = 0; { int f = RIBLEN/max(rate->inskip,rate->outskip); if (f == 0) f = 1; size = f * rate->outskip; /* reasonable input block size */ } /* Find the prime factors of inskip and outskip */ total = optimize_factors(rate, rate->inskip, rate->outskip, l1, l2); rate->total = total; /* l1 and l2 are now lists of the up/down factors for conversion */ lsx_debug("Poly: input rate %g, output rate %g. %d stages.", effp->in_signal.rate, effp->out_signal.rate,total); lsx_debug("Poly: window: %s size: %d cutoff: %f.", (rate->win_type == 0) ? ("nut") : ("ham"), rate->win_width, rate->cutoff); /* Create an array of filters and past history */ uprate = effp->in_signal.rate; for (k = 0; k < total; k++) { int j, prod, f_cutoff, f_len; polystage *s; rate->stage[k] = s = lsx_malloc(sizeof(polystage)); s->up = l1[k]; s->down = l2[k]; f_cutoff = max(s->up, s->down); f_len = max(20 * f_cutoff, rate->win_width); prod = s->up * s->down; if (prod > 2*f_len) prod = s->up; f_len = ((f_len+prod-1)/prod) * prod; /* reduces rounding-errors in polyphase() */ s->size = size; s->hsize = f_len/s->up; /* this much of window is past-history */ s->held = 0; lsx_debug("Poly: stage %d: Up by %d, down by %d, i_samps %d, hsize %d", k+1,s->up,s->down,size, s->hsize); s->filt_len = f_len; s->filt_array = lsx_malloc(sizeof(Float) * f_len); s->window = lsx_malloc(sizeof(Float) * (s->hsize+size)); /* zero past_history section of window */ for(j = 0; j < s->hsize; j++) s->window[j] = 0.0; uprate *= s->up; lsx_debug("Poly: : filt_len %d, cutoff freq %.1f", f_len, uprate * rate->cutoff / f_cutoff); uprate /= s->down; fir_design(rate, s->filt_array, f_len, rate->cutoff / f_cutoff); skip *= s->up; skip += f_len; skip /= s->down; size = (size * s->up) / s->down; /* this is integer */ } rate->oskip = skip/2; { /* bogus last stage is for output buffering */ polystage *s; rate->stage[k] = s = lsx_malloc(sizeof(polystage)); s->up = s->down = 0; s->size = size; s->hsize = 0; s->held = 0; s->filt_len = 0; s->filt_array = NULL; s->window = lsx_malloc(sizeof(Float) * size); } lsx_debug("Poly: output samples %d, oskip %lu",size, (unsigned long)rate->oskip); return (SOX_SUCCESS); } /* * Processed signed long samples from ibuf to obuf. * Return number of samples processed. */ /* REMARK: putting this in a separate subroutine improves gcc's optimization */ static double sox_prod(const Float *q, int qstep, const Float *p, int n) { double sum = 0; const Float *p0; p0 = p-n; while (p>p0) { sum += *p * *q; q += qstep; p -= 1; } return sum; } static void polyphase(Float *output, polystage *s) { int mm; int up = s->up; int down = s->down; int f_len = s->filt_len; const Float *in; Float *o; /* output pointer */ Float *o_top; in = s->window + s->hsize; /*for (mm=0; mm<s->filt_len; mm++) lsx_debug("cf_%d %f",mm,s->filt_array[mm]);*/ /* assumes s->size divisible by down (now true) */ o_top = output + (s->size * up) / down; /*lsx_debug(" isize %d, osize %d, up %d, down %d, N %d", s->size, o_top-output, up, down, f_len);*/ for (mm=0, o=output; o < o_top; mm+=down, o++) { double sum; const Float *p, *q; q = s->filt_array + (mm%up); /* decimated coef pointer */ p = in + (mm/up); sum = sox_prod(q, up, p, f_len/up); *o = sum * up; } } static void update_hist(Float *hist, int hist_size, int in_size) { Float *p, *p1, *q; p = hist; p1 = hist+hist_size; q = hist+in_size; while (p<p1) *p++ = *q++; } static int sox_poly_flow(sox_effect_t * effp, const sox_sample_t *ibuf, sox_sample_t *obuf, size_t *isamp, size_t *osamp) { priv_t * rate = (priv_t *) effp->priv; polystage *s0,*s1; /* Sanity check: how much can we tolerate? */ /* lsx_debug("*isamp=%d *osamp=%d",*isamp,*osamp); */ s0 = rate->stage[0]; /* the first stage */ s1 = rate->stage[rate->total]; /* the 'last' stage is output buffer */ { size_t in_size, gap, k; in_size = *isamp; gap = s0->size - s0->held; /* space available in this 'input' buffer */ if ((in_size > gap) || (ibuf==NULL)) { *isamp = in_size = gap; } if (in_size > 0) { Float *q; q = s0->window + s0->hsize; if (s0!=s1) q += s0->held; /* the last (output) buffer doesn't shift history */ if (ibuf != NULL) { rate->inpipe += rate->Factor * in_size; for (k=0; k<in_size; k++) *q++ = (Float)ibuf[k] / ISCALE; } else { /* ibuf==NULL is draining */ for(k=0;k<in_size;k++) *q++ = 0.0; } s0->held += in_size; } } if (s0->held == s0->size && s1->held == 0) { size_t k; /* input buffer full, output buffer empty, so do process */ for(k=0; k<rate->total; k++) { polystage *s; Float *out; s = rate->stage[k]; out = rate->stage[k+1]->window + rate->stage[k+1]->hsize; /* lsx_debug("k=%d insize=%d",k,in_size); */ polyphase(out, s); /* copy input history into lower portion of rate->window[k] */ update_hist(s->window, s->hsize, s->size); s->held = 0; } s1->held = s1->size; s1->hsize = 0; } { sox_sample_t *q; size_t out_size; size_t oskip; Float *out_buf; size_t k; oskip = rate->oskip; out_size = s1->held; out_buf = s1->window + s1->hsize; if(ibuf == NULL && out_size > ceil(rate->inpipe)) { out_size = ceil(rate->inpipe); } if (out_size > oskip + *osamp) out_size = oskip + *osamp; for(q=obuf, k=oskip; k < out_size; k++) { float f; f = out_buf[k] * ISCALE; /* should clip-limit */ SOX_SAMPLE_CLIP_COUNT(f, effp->clips); *q++ = f; } *osamp = q-obuf; rate->inpipe -= *osamp; oskip -= out_size - *osamp; rate->oskip = oskip; s1->hsize += out_size; s1->held -= out_size; if (s1->held == 0) { s1->hsize = 0; } } return (SOX_SUCCESS); } /* * Process tail of input samples. */ static int sox_poly_drain(sox_effect_t * effp, sox_sample_t *obuf, size_t *osamp) { size_t in_size; /* Call "flow" with NULL input. */ sox_poly_flow(effp, NULL, obuf, &in_size, osamp); return (SOX_SUCCESS); } /* * Do anything required when you stop reading samples. * Don't close input file! */ static int sox_poly_stop(sox_effect_t * effp) { priv_t * rate = (priv_t *)effp->priv; size_t k; for (k = 0; k <= rate->total; k++) { free(rate->stage[k]->window); free(rate->stage[k]->filt_array); free(rate->stage[k]); } return SOX_SUCCESS; } static sox_effect_handler_t sox_polyphase_effect = { "polyphase", "-w {nut|ham} window type\n" " -width n window width in samples [default 1024]\n" "\n" " -cutoff float frequency cutoff for base bandwidth [default 0.95]", SOX_EFF_RATE | SOX_EFF_DEPRECATED, sox_poly_getopts, sox_poly_start, sox_poly_flow, sox_poly_drain, sox_poly_stop, NULL, sizeof(priv_t) }; const sox_effect_handler_t *sox_polyphase_effect_fn(void) { return &sox_polyphase_effect; }