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author | Thomas Vander Stichele <thomas@apestaart.org> | 2001-12-23 10:44:28 +0000 |
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committer | Thomas Vander Stichele <thomas@apestaart.org> | 2001-12-23 10:44:28 +0000 |
commit | 0d4f573fc103544c7972485b010072eda52a0e4b (patch) | |
tree | e8345784eb15612c6557e656fca8a108959d0545 | |
parent | 9161ba1c22b8ac35faf76f34d84f34e16c51ef84 (diff) | |
download | gst-plugins-bad-0d4f573fc103544c7972485b010072eda52a0e4b.tar.gz gst-plugins-bad-0d4f573fc103544c7972485b010072eda52a0e4b.tar.bz2 gst-plugins-bad-0d4f573fc103544c7972485b010072eda52a0e4b.zip |
adding resample lib
Original commit message from CVS:
adding resample lib
-rw-r--r-- | gst-libs/gst/resample/Makefile.am | 26 | ||||
-rw-r--r-- | gst-libs/gst/resample/README | 62 | ||||
-rw-r--r-- | gst-libs/gst/resample/dtos.c | 201 | ||||
-rw-r--r-- | gst-libs/gst/resample/functable.c | 311 | ||||
-rw-r--r-- | gst-libs/gst/resample/resample.c | 530 | ||||
-rw-r--r-- | gst-libs/gst/resample/resample.h | 159 | ||||
-rw-r--r-- | gst-libs/gst/resample/test.c | 352 |
7 files changed, 1641 insertions, 0 deletions
diff --git a/gst-libs/gst/resample/Makefile.am b/gst-libs/gst/resample/Makefile.am new file mode 100644 index 00000000..4fe42224 --- /dev/null +++ b/gst-libs/gst/resample/Makefile.am @@ -0,0 +1,26 @@ +libdir = $(libdir)/gst + +lib_LTLIBRARIES = libresample.la + +if HAVE_CPU_I386 +ARCHCFLAGS = -march=i486 +else +if HAVE_CPU_PPC +ARCHCFLAGS = -Wa,-m7400 +else +ARCHCFLAGS = +endif +endif + +libresample_la_SOURCES = dtos.c functable.c resample.c resample.h +libresample_la_LIBADD = $(GST_LIBS) +libresample_la_CFLAGS = $(GST_CFLAGS) -ffast-math $(ARCHCFLAGS) + +noinst_HEADERS = resample.h + +#check_PROGRAMS = test +#test_SOURCES = test.c +#test_LDADD = libresample.la + + + diff --git a/gst-libs/gst/resample/README b/gst-libs/gst/resample/README new file mode 100644 index 00000000..f7db1105 --- /dev/null +++ b/gst-libs/gst/resample/README @@ -0,0 +1,62 @@ + +This is a snapshot of my current work developing an audio +resampling library. While working on this library, I started +writing lots of general purpose functions that should really +be part of a larger library. Rather than have a constantly +changing library, and since the current code is capable, I +decided to freeze this codebase for use with gstreamer, and +move active development of the code elsewhere. + +The algorithm used is based on Shannon's theorem, which says +that you can recreate an input signal from equidistant samples +using a sin(x)/x filter; thus, you can create new samples from +the regenerated input signal. Since sin(x)/x is expensive to +evaluate, an interpolated lookup table is used. Also, a +windowing function (1-x^2)^2 is used, which aids the convergence +of sin(x)/x for lower frequencies at the expense of higher. + +There is one tunable parameter, which is the filter length. +Longer filter lengths are obviously slower, but more accurate. +There's not much reason to use a filter length longer than 64, +since other approximations start to dominate. Filter lengths +as short as 8 are audially acceptable, but should not be +considered for serious work. + +Performance: A PowerPC G4 at 400 Mhz can resample 2 audio +channels at almost 10x speed with a filter length of 64, without +using Altivec extensions. (My goal was 10x speed, which I almost +reached. Maybe later.) + +Limitations: Currently only supports streams in the form of +interleaved signed 16-bit samples. + +The test.c program is a simple regression test. It creates a +test input pattern (1 sec at 48 khz) that is a frequency ramp +from 0 to 24000 hz, and then converts it to 44100 hz using a +filter length of 64. It then compares the result to the same +pattern generated at 44100 hz, and outputs the result to the +file "out". + +A graph of the correct output should have field 2 and field 4 +almost equal (plus/minus 1) up to about sample 40000 (which +corresponds to 20 khz), and then field 2 should be close to 0 +above that. Running the test program will print to stdout +something like the following: + + time 0.112526 + average error 10k=0.4105 22k=639.34 + +The average error is RMS error over the range [0-10khz] and +[0-22khz], and is expressed in sample values, for an input +amplitude of 16000. Note that RMS errors below 1.0 can't +really be compared, but basically this shows that below +10 khz, the resampler is nearly perfect. Most of the error +is concentrated above 20 khz. + +If the average error is significantly larger after modifying +the code, it's probably not good. + + + +dave... + diff --git a/gst-libs/gst/resample/dtos.c b/gst-libs/gst/resample/dtos.c new file mode 100644 index 00000000..7762595f --- /dev/null +++ b/gst-libs/gst/resample/dtos.c @@ -0,0 +1,201 @@ +/* Resampling library + * Copyright (C) <2001> David A. Schleef <ds@schleef.org> + * + * This library is free software; you can redistribute it and/or + * modify it under the terms of the GNU Library General Public + * License as published by the Free Software Foundation; either + * version 2 of the License, or 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 + * Library General Public License for more details. + * + * You should have received a copy of the GNU Library General Public + * License along with this library; if not, write to the + * Free Software Foundation, Inc., 59 Temple Place - Suite 330, + * Boston, MA 02111-1307, USA. + */ + + +#include <string.h> +#include <math.h> +#include <stdio.h> +#include <stdlib.h> + +//#include <ml.h> +#include <resample.h> + + + +#define short_to_double_table +//#define short_to_double_altivec +#define short_to_double_unroll + +#ifdef short_to_double_table +static float ints_high[256]; +static float ints_low[256]; + +void conv_double_short_table(double *dest, short *src, int n) +{ + static int init = 0; + int i; + unsigned int idx; + if(!init){ + for(i=0;i<256;i++){ + ints_high[i]=256.0*((i<128)?i:i-256); + ints_low[i]=i; + } + init = 1; + } + + if(n&1){ + idx = (unsigned short)*src++; + *dest++ = ints_high[(idx>>8)] + ints_low[(idx&0xff)]; + n-=1; + } + for(i=0;i<n;i+=2){ + idx = (unsigned short)*src++; + *dest++ = ints_high[(idx>>8)] + ints_low[(idx&0xff)]; + idx = (unsigned short)*src++; + *dest++ = ints_high[(idx>>8)] + ints_low[(idx&0xff)]; + } +} + +#endif + +#ifdef short_to_double_unroll +void conv_double_short_unroll(double *dest, short *src, int n) +{ + if(n&1){ + *dest++ = *src++; + n--; + } + if(n&2){ + *dest++ = *src++; + *dest++ = *src++; + n-=2; + } + while(n>0){ + *dest++ = *src++; + *dest++ = *src++; + *dest++ = *src++; + *dest++ = *src++; + n-=4; + } +} +#endif + +void conv_double_short_ref(double *dest, short *src, int n) +{ + int i; + for(i=0;i<n;i++){ + dest[i]=src[i]; + } +} + +#ifdef HAVE_CPU_PPC +#if 0 +static union { int i[4]; float f[4]; } av_tmp __attribute__ ((__aligned__ (16))); + +void conv_double_short_altivec(double *dest, short *src, int n) +{ + int i; + + for(i=0;i<n;i+=4){ + av_tmp.i[0] = src[0]; + av_tmp.i[1] = src[1]; + av_tmp.i[2] = src[2]; + av_tmp.i[3] = src[3]; + + asm( + " lvx 0,0,%0\n" + " vcfsx 1,0,0\n" + " stvx 1,0,%0\n" + : : "r" (&av_tmp) + ); + + dest[0]=av_tmp.f[0]; + dest[1]=av_tmp.f[1]; + dest[2]=av_tmp.f[2]; + dest[3]=av_tmp.f[3]; + src += 4; + dest += 4; + } +} +#endif +#endif + + + +/* double to short */ + +void conv_short_double_ref(short *dest, double *src, int n) +{ + int i; + double x; + + for(i=0;i<n;i++){ + x = *src++; + if(x<-32768.0)x=-32768.0; + if(x>32767.0)x=32767.0; + *dest++ = rint(x); + } +} + +#ifdef HAVE_CPU_PPC +void conv_short_double_ppcasm(short *dest, double *src, int n) +{ + int tmp[2]; + double min = -32768.0; + double max = 32767.0; + double ftmp0, ftmp1; + + asm __volatile__( + "\taddic. %3,%3,-8\n" + "\taddic. %6,%6,-2\n" + "loop:\n" + "\tlfdu %0,8(%3)\n" + "\tfsub %1,%0,%4\n" + "\tfsel %0,%1,%0,%4\n" + "\tfsub %1,%0,%5\n" + "\tfsel %0,%1,%5,%0\n" + "\tfctiw %1,%0\n" + "\taddic. 5,5,-1\n" + "\tstfd %1,0(%2)\n" + "\tlhz 9,6(%2)\n" + "\tsthu 9,2(%6)\n" + "\tbne loop\n" + : "=&f" (ftmp0), "=&f" (ftmp1) + : "b" (tmp), "r" (src), "f" (min), "f" (max), "r" (dest) + : "r9", "r5" ); + +} +#endif + + +void conv_double_short_dstr(double *dest, short *src, int n, int dstr) +{ + int i; + void *d = dest; + for(i=0;i<n;i++){ + (*(double *)d)=*src++; + d += dstr; + } +} + +void conv_short_double_sstr(short *dest, double *src, int n, int sstr) +{ + int i; + double x; + void *s = src; + + for(i=0;i<n;i++){ + x = *(double *)s; + if(x<-32768.0)x=-32768.0; + if(x>32767.0)x=32767.0; + *dest++ = rint(x); + s += sstr; + } +} + diff --git a/gst-libs/gst/resample/functable.c b/gst-libs/gst/resample/functable.c new file mode 100644 index 00000000..d61efca4 --- /dev/null +++ b/gst-libs/gst/resample/functable.c @@ -0,0 +1,311 @@ +/* Resampling library + * Copyright (C) <2001> David A. Schleef <ds@schleef.org> + * + * This library is free software; you can redistribute it and/or + * modify it under the terms of the GNU Library General Public + * License as published by the Free Software Foundation; either + * version 2 of the License, or 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 + * Library General Public License for more details. + * + * You should have received a copy of the GNU Library General Public + * License along with this library; if not, write to the + * Free Software Foundation, Inc., 59 Temple Place - Suite 330, + * Boston, MA 02111-1307, USA. + */ + + +#include <string.h> +#include <math.h> +#include <stdio.h> +#include <stdlib.h> + +#include <resample.h> + + + +double functable_sinc(void *p,double x) +{ + if(x==0)return 1; + return sin(x)/x; +} + +double functable_dsinc(void *p,double x) +{ + if(x==0)return 0; + return cos(x)/x - sin(x)/(x*x); +} + +double functable_window_boxcar(void *p,double x) +{ + if(x<-1 || x>1)return 0; + return 1; +} + +double functable_window_dboxcar(void *p,double x) +{ + return 0; +} + +double functable_window_std(void *p,double x) +{ + if(x<-1 || x>1)return 0; + return (1-x*x)*(1-x*x); +} + +double functable_window_dstd(void *p,double x) +{ + if(x<-1 || x>1)return 0; + return -4*x*(1-x*x); +} + + + +void functable_init(functable_t *t) +{ + int i; + double x; + + t->fx = malloc(sizeof(double)*(t->len+1)); + t->fdx = malloc(sizeof(double)*(t->len+1)); + + t->invoffset = 1.0 / t->offset; + + for(i=0;i<t->len+1;i++){ + x = t->start + t->offset * i; + x *= t->scale; + + t->fx[i] = t->func_x(t->priv,x); + t->fdx[i] = t->scale * t->func_dx(t->priv,x); + } + if(t->func2_x){ + double f1x,f1dx; + double f2x,f2dx; + + for(i=0;i<t->len+1;i++){ + x = t->start + t->offset * i; + x *= t->scale2; + + f2x = t->func2_x(t->priv,x); + f2dx = t->scale2 * t->func2_dx(t->priv,x); + + f1x = t->fx[i]; + f1dx = t->fdx[i]; + + t->fx[i] = f1x * f2x; + t->fdx[i] = f1x * f2dx + f1dx * f2x; + } + } +} + +double functable_eval(functable_t *t,double x) +{ + int i; + double f0, f1, w0, w1; + double x2, x3; + double w; + + if(x<t->start || x>(t->start+(t->len+1)*t->offset)){ + printf("x out of range %g\n",x); + } + x -= t->start; + x /= t->offset; + i = floor(x); + x -= i; + + x2 = x * x; + x3 = x2 * x; + + f1 = 3 * x2 - 2 * x3; + f0 = 1 - f1; + w0 = (x - 2 * x2 + x3) * t->offset; + w1 = (-x2 + x3) * t->offset; + + //printf("i=%d x=%g f0=%g f1=%g w0=%g w1=%g\n",i,x,f0,f1,w0,w1); + + w = t->fx[i] * f0 + t->fx[i + 1] * f1 + + t->fdx[i] * w0 + t->fdx[i + 1] * w1; + + //w = t->fx[i] * (1-x) + t->fx[i+1] * x; + + return w; +} + + +double functable_fir(functable_t *t, double x, int n, double *data, int len) +{ + int i,j; + double f0, f1, w0, w1; + double x2, x3; + double w; + double sum; + + x -= t->start; + x /= t->offset; + i = floor(x); + x -= i; + + x2 = x * x; + x3 = x2 * x; + + f1 = 3 * x2 - 2 * x3; + f0 = 1 - f1; + w0 = (x - 2 * x2 + x3) * t->offset; + w1 = (-x2 + x3) * t->offset; + + sum = 0; + for(j=0;j<len;j++){ + w = t->fx[i] * f0 + t->fx[i + 1] * f1 + + t->fdx[i] * w0 + t->fdx[i + 1] * w1; + sum += data[j*2] * w; + i += n; + } + + return sum; +} + +void functable_fir2(functable_t *t, double *r0, double *r1, double x, + int n, double *data, int len) +{ + int i,j; + double f0, f1, w0, w1; + double x2, x3; + double w; + double sum0, sum1; + double floor_x; + + x -= t->start; + x *= t->invoffset; + floor_x = floor(x); + i = floor_x; + x -= floor_x; + + x2 = x * x; + x3 = x2 * x; + + f1 = 3 * x2 - 2 * x3; + f0 = 1 - f1; + w0 = (x - 2 * x2 + x3) * t->offset; + w1 = (-x2 + x3) * t->offset; + + sum0 = 0; + sum1 = 0; + for(j=0;j<len;j++){ + w = t->fx[i] * f0 + t->fx[i + 1] * f1 + + t->fdx[i] * w0 + t->fdx[i + 1] * w1; + sum0 += data[j*2] * w; + sum1 += data[j*2+1] * w; + i += n; + +#define unroll2 +#define unroll3 +#define unroll4 +#ifdef unroll2 + j++; + + w = t->fx[i] * f0 + t->fx[i + 1] * f1 + + t->fdx[i] * w0 + t->fdx[i + 1] * w1; + sum0 += data[j*2] * w; + sum1 += data[j*2+1] * w; + i += n; +#endif +#ifdef unroll3 + j++; + + w = t->fx[i] * f0 + t->fx[i + 1] * f1 + + t->fdx[i] * w0 + t->fdx[i + 1] * w1; + sum0 += data[j*2] * w; + sum1 += data[j*2+1] * w; + i += n; +#endif +#ifdef unroll4 + j++; + + w = t->fx[i] * f0 + t->fx[i + 1] * f1 + + t->fdx[i] * w0 + t->fdx[i + 1] * w1; + sum0 += data[j*2] * w; + sum1 += data[j*2+1] * w; + i += n; +#endif + } + + *r0 = sum0; + *r1 = sum1; +} + + + +#ifdef unused +void functable_fir2_altivec(functable_t *t, float *r0, float *r1, + double x, int n, float *data, int len) +{ + int i,j; + double f0, f1, w0, w1; + double x2, x3; + double w; + double sum0, sum1; + double floor_x; + + x -= t->start; + x *= t->invoffset; + floor_x = floor(x); + i = floor_x; + x -= floor_x; + + x2 = x * x; + x3 = x2 * x; + + f1 = 3 * x2 - 2 * x3; + f0 = 1 - f1; + w0 = (x - 2 * x2 + x3) * t->offset; + w1 = (-x2 + x3) * t->offset; + + sum0 = 0; + sum1 = 0; + for(j=0;j<len;j++){ + // t->fx, t->fdx needs to be multiplexed by n + // we need 5 consecutive floats, which fit into 2 vecs + // load v0, t->fx[i] + // load v1, t->fx[i+n] + // v2 = v0 (not correct) + // v3 = (v0>>32) || (v1<<3*32) (not correct) + // + // load v4, t->dfx[i] + // load v5, t->dfx[i+n] + // v6 = v4 (not correct) + // v7 = (v4>>32) || (v5<<3*32) (not correct) + // + // v8 = splat(f0) + // v9 = splat(f1) + // v10 = splat(w0) + // v11 = splat(w1) + // + // v12 = v2 * v8 + // v12 += v3 * v9 + // v12 += v6 * v10 + // v12 += v7 * v11 + + w = t->fx[i] * f0 + t->fx[i + 1] * f1 + + t->fdx[i] * w0 + t->fdx[i + 1] * w1; + + // v13 = data[j*2] + // v14 = data[j*2+4] + // v15 = deinterlace_high(v13,v14) + // v16 = deinterlace_low(v13,v14) + // (sum0) v17 += multsum(v13,v15) + // (sum1) v18 += multsum(v14,v16) + + sum0 += data[j*2] * w; + sum1 += data[j*2+1] * w; + i += n; + + } + + *r0 = sum0; + *r1 = sum1; +} +#endif + diff --git a/gst-libs/gst/resample/resample.c b/gst-libs/gst/resample/resample.c new file mode 100644 index 00000000..cedb874e --- /dev/null +++ b/gst-libs/gst/resample/resample.c @@ -0,0 +1,530 @@ +/* Resampling library + * Copyright (C) <2001> David A. Schleef <ds@schleef.org> + * + * This library is free software; you can redistribute it and/or + * modify it under the terms of the GNU Library General Public + * License as published by the Free Software Foundation; either + * version 2 of the License, or 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 + * Library General Public License for more details. + * + * You should have received a copy of the GNU Library General Public + * License along with this library; if not, write to the + * Free Software Foundation, Inc., 59 Temple Place - Suite 330, + * Boston, MA 02111-1307, USA. + */ + + +#include <string.h> +#include <math.h> +#include <stdio.h> +#include <stdlib.h> + +#include <resample.h> + +inline double sinc(double x) +{ + if(x==0)return 1; + return sin(x) / x; +} + +inline double window_func(double x) +{ + x = 1 - x*x; + return x*x; +} + +signed short double_to_s16(double x) +{ + if(x<-32768){ + printf("clipped\n"); + return -32768; + } + if(x>32767){ + printf("clipped\n"); + return -32767; + } + return rint(x); +} + +signed short double_to_s16_ppcasm(double x) +{ + if(x<-32768){ + return -32768; + } + if(x>32767){ + return -32767; + } + return rint(x); +} + +static void resample_sinc_ft(resample_t * r); + +void resample_init(resample_t * r) +{ + r->i_start = 0; + if(r->filter_length&1){ + r->o_start = 0; + }else{ + r->o_start = r->o_inc * 0.5; + } + + memset(r->acc, 0, sizeof(r->acc)); + + resample_reinit(r); +} + +void resample_reinit(resample_t * r) +{ + /* i_inc is the number of samples that the output increments for + * each input sample. o_inc is the opposite. */ + r->i_inc = (double) r->o_rate / r->i_rate; + r->o_inc = (double) r->i_rate / r->o_rate; + + r->halftaps = (r->filter_length - 1.0) * 0.5; + + switch (r->method) { + default: + case RESAMPLE_NEAREST: + r->scale = resample_nearest; + break; + case RESAMPLE_BILINEAR: + r->scale = resample_bilinear; + break; + case RESAMPLE_SINC_SLOW: + r->scale = resample_sinc; + break; + case RESAMPLE_SINC: + r->scale = resample_sinc_ft; + break; + } +} + +/* + * Prepare to be confused. + * + * We keep a "timebase" that is based on output samples. The zero + * of the timebase cooresponds to the next output sample that will + * be written. + * + * i_start is the "time" that corresponds to the first input sample + * in an incoming buffer. Since the output depends on input samples + * ahead in time, i_start will tend to be around halftaps. + * + * i_start_buf is the time of the first sample in the temporary + * buffer. + */ +void resample_scale(resample_t * r, void *i_buf, unsigned int i_size) +{ + int o_size; + + r->i_buf = i_buf; + + r->i_samples = i_size / 2 / r->channels; + + r->i_start_buf = r->i_start - r->filter_length * r->i_inc; + + /* i_start is the offset (in a given output sample) that is the + * beginning of the current input buffer */ + r->i_end = r->i_start + r->i_inc * r->i_samples; + + r->o_samples = floor(r->i_end - r->halftaps * r->i_inc); + + o_size = r->o_samples * r->channels * 2; + r->o_buf = r->get_buffer(r->priv, o_size); + + if(r->verbose){ + printf("resample_scale: i_buf=%p i_size=%d\n", + i_buf,i_size); + printf("resample_scale: i_samples=%d o_samples=%d i_inc=%g o_buf=%p\n", + r->i_samples, r->o_samples, r->i_inc, r->o_buf); + printf("resample_scale: i_start=%g i_end=%g o_start=%g\n", + r->i_start, r->i_end, r->o_start); + } + + if ((r->filter_length + r->i_samples)*2*2 > r->buffer_len) { + int size = (r->filter_length + r->i_samples) * sizeof(double) * 2; + + if(r->verbose){ + printf("resample temp buffer size=%d\n",size); + } + if(r->buffer)free(r->buffer); + r->buffer_len = size; + r->buffer = malloc(size); + memset(r->buffer, 0, size); + } + + if(r->channels==2){ + conv_double_short( + r->buffer + r->filter_length * sizeof(double) * 2, + r->i_buf, r->i_samples * 2); + }else{ + conv_double_short_dstr( + r->buffer + r->filter_length * sizeof(double) * 2, + r->i_buf, r->i_samples, sizeof(double) * 2); + } + + r->scale(r); + + memcpy(r->buffer, + r->buffer + r->i_samples * sizeof(double) * 2, + r->filter_length * sizeof(double) * 2); + + /* updating times */ + r->i_start += r->i_samples * r->i_inc; + r->o_start += r->o_samples * r->o_inc - r->i_samples; + + /* adjusting timebase zero */ + r->i_start -= r->o_samples; +} + +void resample_nearest(resample_t * r) +{ + signed short *i_ptr, *o_ptr; + int i_count = 0; + double a; + int i; + + i_ptr = (signed short *) r->i_buf; + o_ptr = (signed short *) r->o_buf; + + a = r->o_start; + i_count = 0; +#define SCALE_LOOP(COPY,INC) \ + for (i = 0; i < r->o_samples; i++) { \ + COPY; \ + a += r->o_inc; \ + while (a >= 1) { \ + a -= 1; \ + i_ptr+=INC; \ + i_count++; \ + } \ + o_ptr+=INC; \ + } + + switch (r->channels) { + case 1: + SCALE_LOOP(o_ptr[0] = i_ptr[0], 1); + break; + case 2: + SCALE_LOOP(o_ptr[0] = i_ptr[0]; + o_ptr[1] = i_ptr[1], 2); + break; + default: + { + int n, n_chan = r->channels; + + SCALE_LOOP(for (n = 0; n < n_chan; n++) o_ptr[n] = + i_ptr[n], n_chan); + } + } + if (i_count != r->i_samples) { + printf("handled %d in samples (expected %d)\n", i_count, + r->i_samples); + } +} + +void resample_bilinear(resample_t * r) +{ + signed short *i_ptr, *o_ptr; + int o_count = 0; + double b; + int i; + double acc0, acc1; + + i_ptr = (signed short *) r->i_buf; + o_ptr = (signed short *) r->o_buf; + + acc0 = r->acc[0]; + acc1 = r->acc[1]; + b = r->i_start; + for (i = 0; i < r->i_samples; i++) { + b += r->i_inc; + //printf("in %d\n",i_ptr[0]); + if(b>=2){ + printf("not expecting b>=2\n"); + } + if (b >= 1) { + acc0 += (1.0 - (b-r->i_inc)) * i_ptr[0]; + acc1 += (1.0 - (b-r->i_inc)) * i_ptr[1]; + + o_ptr[0] = rint(acc0); + //printf("out %d\n",o_ptr[0]); + o_ptr[1] = rint(acc1); + o_ptr += 2; + o_count++; + + b -= 1.0; + + acc0 = b * i_ptr[0]; + acc1 = b * i_ptr[1]; + } else { + acc0 += i_ptr[0] * r->i_inc; + acc1 += i_ptr[1] * r->i_inc; + } + i_ptr += 2; + } + r->acc[0] = acc0; + r->acc[1] = acc1; + + if (o_count != r->o_samples) { + printf("handled %d out samples (expected %d)\n", o_count, + r->o_samples); + } +} + +void resample_sinc_slow(resample_t * r) +{ + signed short *i_ptr, *o_ptr; + int i, j; + double c0, c1; + double a; + int start; + double center; + double weight; + + if (!r->buffer) { + int size = r->filter_length * 2 * r->channels; + + printf("resample temp buffer\n"); + r->buffer = malloc(size); + memset(r->buffer, 0, size); + } + + i_ptr = (signed short *) r->i_buf; + o_ptr = (signed short *) r->o_buf; + + a = r->i_start; +#define GETBUF(index,chan) (((index)<0) \ + ? ((short *)(r->buffer))[((index)+r->filter_length)*2+(chan)] \ + : i_ptr[(index)*2+(chan)]) + { + double sinx, cosx, sind, cosd; + double x, d; + double t; + + for (i = 0; i < r->o_samples; i++) { + start = floor(a) - r->filter_length; + center = a - r->halftaps; + x = M_PI * (start - center) * r->o_inc; + sinx = sin(M_PI * (start - center) * r->o_inc); + cosx = cos(M_PI * (start - center) * r->o_inc); + d = M_PI * r->o_inc; + sind = sin(M_PI * r->o_inc); + cosd = cos(M_PI * r->o_inc); + c0 = 0; + c1 = 0; + for (j = 0; j < r->filter_length; j++) { + weight = (x==0)?1:(sinx/x); +//printf("j %d sin %g cos %g\n",j,sinx,cosx); +//printf("j %d sin %g x %g sinc %g\n",j,sinx,x,weight); + c0 += weight * GETBUF((start + j), 0); + c1 += weight * GETBUF((start + j), 1); + t = cosx * cosd - sinx * sind; + sinx = cosx * sind + sinx * cosd; + cosx = t; + x += d; + } + o_ptr[0] = rint(c0); + o_ptr[1] = rint(c1); + o_ptr += 2; + a += r->o_inc; + } + } + + memcpy(r->buffer, + i_ptr + (r->i_samples - r->filter_length) * r->channels, + r->filter_length * 2 * r->channels); +} + +void resample_sinc(resample_t * r) +{ + double *ptr; + signed short *o_ptr; + int i, j; + double c0, c1; + double a; + int start; + double center; + double weight; + double x0, x, d; + double scale; + + ptr = (double *) r->buffer; + o_ptr = (signed short *) r->o_buf; + + /* scale provides a cutoff frequency for the low + * pass filter aspects of sinc(). scale=M_PI + * will cut off at the input frequency, which is + * good for up-sampling, but will cause aliasing + * for downsampling. Downsampling needs to be + * cut off at o_rate, thus scale=M_PI*r->i_inc. */ + /* actually, it needs to be M_PI*r->i_inc*r->i_inc. + * Need to research why. */ + scale = M_PI*r->i_inc; + for (i = 0; i < r->o_samples; i++) { + a = r->o_start + i * r->o_inc; + start = floor(a - r->halftaps); +//printf("%d: a=%g start=%d end=%d\n",i,a,start,start+r->filter_length-1); + center = a; + //x = M_PI * (start - center) * r->o_inc; + //d = M_PI * r->o_inc; + //x = (start - center) * r->o_inc; + x0 = (start - center) * r->o_inc; + d = r->o_inc; + c0 = 0; + c1 = 0; + for (j = 0; j < r->filter_length; j++) { + x = x0 + d * j; + weight = sinc(x*scale*r->i_inc)*scale/M_PI; + weight *= window_func(x/r->halftaps*r->i_inc); + c0 += weight * ptr[(start + j + r->filter_length)*2 + 0]; + c1 += weight * ptr[(start + j + r->filter_length)*2 + 1]; + } + o_ptr[0] = double_to_s16(c0); + o_ptr[1] = double_to_s16(c1); + o_ptr += 2; + } +} + + + + +/* + * Resampling audio is best done using a sinc() filter. + * + * + * out[t] = Sum( in[t'] * sinc((t-t')/delta_t), all t') + * + * The immediate problem with this algorithm is that it involves a + * sum over an infinite number of input samples, both in the past + * and future. Note that even though sinc(x) is bounded by 1/x, + * and thus decays to 0 for large x, since sum(x,{x=0,1..,n}) diverges + * as log(n), we need to be careful about convergence. This is + * typically done by using a windowing function, which also makes + * the sum over a finite number of input samples. + * + * The next problem is computational: sinc(), and especially + * sinc() multiplied by a non-trivial windowing function is expensive + * to calculate, and also difficult to find SIMD optimizations. Since + * the time increment on input and output is different, it is not + * possible to use a FIR filter, because the taps would have to be + * recalculated for every t. + * + * To get around the expense of calculating sinc() for every point, + * we pre-calculate sinc() at a number of points, and then interpolate + * for the values we want in calculations. The interpolation method + * chosen is bi-cubic, which requires both the evalated function and + * its derivative at every pre-sampled point. Also, if the sampled + * points are spaced commensurate with the input delta_t, we notice + * that the interpolating weights are the same for every input point. + * This decreases the number of operations to 4 multiplies and 4 adds + * for each tap, regardless of the complexity of the filtering function. + * + * At this point, it is possible to rearrange the problem as the sum + * of 4 properly weghted FIR filters. Typical SIMD computation units + * are highly optimized for FIR filters, making long filter lengths + * reasonable. + */ + +static functable_t *ft; + +double out_tmp[10000]; + +static void resample_sinc_ft(resample_t * r) +{ + double *ptr; + signed short *o_ptr; + int i; + //int j; + double c0, c1; + //double a; + double start_f, start_x; + int start; + double center; + //double weight; + double x, d; + double scale; + int n = 4; + + scale = r->i_inc; // cutoff at 22050 + //scale = 1.0; // cutoff at 24000 + //scale = r->i_inc * 0.5; // cutoff at 11025 + + if(!ft){ + ft = malloc(sizeof(*ft)); + memset(ft,0,sizeof(*ft)); + + ft->len = (r->filter_length + 2) * n; + ft->offset = 1.0 / n; + ft->start = - ft->len * 0.5 * ft->offset; + + ft->func_x = functable_sinc; + ft->func_dx = functable_dsinc; + ft->scale = M_PI * scale; + + ft->func2_x = functable_window_std; + ft->func2_dx = functable_window_dstd; + ft->scale2 = 1.0 / r->halftaps; + + functable_init(ft); + + //printf("len=%d offset=%g start=%g\n",ft->len,ft->offset,ft->start); + } + + ptr = r->buffer; + o_ptr = (signed short *) r->o_buf; + + center = r->o_start; + start_x = center - r->halftaps; + start_f = floor(start_x); + start_x -= start_f; + start = start_f; + for (i = 0; i < r->o_samples; i++) { + //start_f = floor(center - r->halftaps); +//printf("%d: a=%g start=%d end=%d\n",i,a,start,start+r->filter_length-1); + x = start_f - center; + d = 1; + c0 = 0; + c1 = 0; +//#define slow +#ifdef slow + for (j = 0; j < r->filter_length; j++) { + weight = functable_eval(ft,x)*scale; + //weight = sinc(M_PI * scale * x)*scale*r->i_inc; + //weight *= window_func(x / r->halftaps); + c0 += weight * ptr[(start + j + r->filter_length)*2 + 0]; + c1 += weight * ptr[(start + j + r->filter_length)*2 + 1]; + x += d; + } +#else + functable_fir2(ft, + &c0,&c1, + x, n, + ptr+(start + r->filter_length)*2, + r->filter_length); + c0 *= scale; + c1 *= scale; +#endif + + out_tmp[2 * i + 0] = c0; + out_tmp[2 * i + 1] = c1; + center += r->o_inc; + start_x += r->o_inc; + while(start_x>=1.0){ + start_f++; + start_x -= 1.0; + start++; + } + } + + if(r->channels==2){ + conv_short_double(r->o_buf,out_tmp,2 * r->o_samples); + }else{ + conv_short_double_sstr(r->o_buf,out_tmp,r->o_samples,2 * sizeof(double)); + } +} + diff --git a/gst-libs/gst/resample/resample.h b/gst-libs/gst/resample/resample.h new file mode 100644 index 00000000..1cc36edd --- /dev/null +++ b/gst-libs/gst/resample/resample.h @@ -0,0 +1,159 @@ +/* Resampling library + * Copyright (C) <2001> David Schleef <ds@schleef.org> + * + * This library is free software; you can redistribute it and/or + * modify it under the terms of the GNU Library General Public + * License as published by the Free Software Foundation; either + * version 2 of the License, or 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 + * Library General Public License for more details. + * + * You should have received a copy of the GNU Library General Public + * License along with this library; if not, write to the + * Free Software Foundation, Inc., 59 Temple Place - Suite 330, + * Boston, MA 02111-1307, USA. + */ + + +#ifndef __RESAMPLE_H__ +#define __RESAMPLE_H__ + +#include <config.h> + +typedef struct resample_s resample_t; + +struct resample_s { + /* parameters */ + + int method; + int channels; + int verbose; + + int filter_length; + + double i_rate; + double o_rate; + + void *priv; + + void *(*get_buffer)(void *priv, unsigned int size); + + /* internal parameters */ + + double halftaps; + + /* filter state */ + + void *buffer; + int buffer_len; + + double i_start; + double o_start; + + double i_start_buf; + double i_end_buf; + + double i_inc; + double o_inc; + + double i_end; + double o_end; + + int i_samples; + int o_samples; + + void *i_buf, *o_buf; + + double acc[10]; + + /* methods */ + void (*scale)(resample_t *r); + + double ack; +}; + +enum{ + RESAMPLE_NEAREST = 0, + RESAMPLE_BILINEAR, + RESAMPLE_SINC_SLOW, + RESAMPLE_SINC, +}; + +void resample_init(resample_t *r); +void resample_reinit(resample_t *r); + +void resample_scale(resample_t *r, void *i_buf, unsigned int size); + +void resample_nearest(resample_t *r); +void resample_bilinear(resample_t *r); +void resample_sinc(resample_t *r); +void resample_sinc_slow(resample_t *r); + + +typedef struct functable_s functable_t; +struct functable_s { + double start; + double offset; + int len; + + double invoffset; + + double scale; + double scale2; + + double (*func_x)(void *,double x); + double (*func_dx)(void *,double x); + + double (*func2_x)(void *,double x); + double (*func2_dx)(void *,double x); + + double *fx; + double *fdx; + + void *priv; +}; + +void functable_init(functable_t *t); +double functable_eval(functable_t *t,double x); + +double functable_fir(functable_t *t,double x0,int n,double *data,int len); +void functable_fir2(functable_t *t,double *r0, double *r1, double x0, + int n,double *data,int len); + +double functable_sinc(void *p, double x); +double functable_dsinc(void *p, double x); +double functable_window_std(void *p, double x); +double functable_window_dstd(void *p, double x); +double functable_window_boxcar(void *p, double x); +double functable_window_dboxcar(void *p, double x); + +/* math lib stuff */ + +void conv_double_short_table(double *dest, short *src, int n); +void conv_double_short_unroll(double *dest, short *src, int n); +void conv_double_short_ref(double *dest, short *src, int n); +#ifdef HAVE_CPU_PPC +void conv_double_short_altivec(double *dest, short *src, int n); +#endif + +void conv_short_double_ref(short *dest, double *src, int n); +#ifdef HAVE_CPU_PPC +void conv_short_double_ppcasm(short *dest, double *src, int n); +#endif + +#ifdef HAVE_CPU_PPC +#define conv_double_short conv_double_short_table +#define conv_short_double conv_short_double_ppcasm +#else +#define conv_double_short conv_double_short_ref +#define conv_short_double conv_short_double_ref +#endif + +void conv_double_short_dstr(double *dest, short *src, int n, int dstr); +void conv_short_double_sstr(short *dest, double *src, int n, int dstr); + +#endif /* __RESAMPLE_H__ */ + diff --git a/gst-libs/gst/resample/test.c b/gst-libs/gst/resample/test.c new file mode 100644 index 00000000..44d19a65 --- /dev/null +++ b/gst-libs/gst/resample/test.c @@ -0,0 +1,352 @@ + +#include <stdio.h> +#include <stdlib.h> +#include <math.h> +#include <sys/time.h> + +#include <resample.h> + +#define AMP 16000 +#define I_RATE 48000 +#define O_RATE 44100 +//#define O_RATE 24000 + +//#define test_func(x) 1 +//#define test_func(x) sin(2*M_PI*(x)*10) +//#define test_func(x) sin(2*M_PI*(x)*(x)*1000) +#define test_func(x) sin(2*M_PI*(x)*(x)*12000) + +short i_buf[I_RATE*2*2]; +short o_buf[O_RATE*2*2]; + +static int i_offset; +static int o_offset; + +FILE *out; + +void test_res1(void); +void test_res2(void); +void test_res3(void); +void test_res4(void); +void test_res5(void); +void test_res6(void); +void test_res7(void); + +int main(int argc,char *argv[]) +{ + out = fopen("out","w"); + + test_res7(); + + return 0; +} + +void *get_buffer(void *priv, unsigned int size) +{ + void *ret; + ret = ((void *)o_buf) + o_offset; + o_offset += size; + return ret; +} + +struct timeval start_time; +void start_timer(void) +{ + gettimeofday(&start_time,NULL); + //printf("start %ld.%06ld\n",start_time.tv_sec,start_time.tv_usec); +} + +void end_timer(void) +{ + struct timeval end_time; + double diff; + + gettimeofday(&end_time,NULL); + //printf("end %ld.%06ld\n",end_time.tv_sec,end_time.tv_usec); + diff = (end_time.tv_sec - start_time.tv_sec) + + 1e-6*(end_time.tv_usec - start_time.tv_usec); + + printf("time %g\n",diff); + +} + +void test_res1(void) +{ + resample_t *r; + int i; + double sum10k,sum22k; + double f; + int n10k,n22k; + double x; + + for(i=0;i<I_RATE;i++){ + i_buf[i*2+0] = rint(AMP * test_func((double)i/I_RATE)); + //i_buf[i*2+1] = rint(AMP * test_func((double)i/I_RATE)); + i_buf[i*2+1] = (i<1000)?AMP:0; + } + + r = malloc(sizeof(resample_t)); + memset(r,0,sizeof(resample_t)); + + r->i_rate = I_RATE; + r->o_rate = O_RATE; + //r->method = RESAMPLE_SINC_SLOW; + r->method = RESAMPLE_SINC; + r->channels = 2; + //r->verbose = 1; + r->filter_length = 64; + r->get_buffer = get_buffer; + + resample_init(r); + + start_timer(); +#define blocked +#ifdef blocked + for(i=0;i+256<I_RATE;i+=256){ + resample_scale(r,i_buf+i*2,256*2*2); + } + if(I_RATE-i){ + resample_scale(r,i_buf+i*2,(I_RATE-i)*2*2); + } +#else + resample_scale(r,i_buf,I_RATE*2*2); +#endif + end_timer(); + + for(i=0;i<O_RATE;i++){ + f = AMP*test_func((double)i/O_RATE); + //f = rint(AMP*test_func((double)i/O_RATE)); + fprintf(out,"%d %d %d %g %g\n",i, + o_buf[2*i+0],o_buf[2*i+1], + f,o_buf[2*i+0]-f); + } + + sum10k=0; + sum22k=0; + n10k=0; + n22k=0; + for(i=0;i<O_RATE;i++){ + f = AMP*test_func((double)i/O_RATE); + //f = rint(AMP*test_func((double)i/O_RATE)); + x = o_buf[2*i+0]-f; + if(((0.5*i)/O_RATE*I_RATE)<10000){ + sum10k += x*x; + n10k++; + } + if(((0.5*i)/O_RATE*I_RATE)<22050){ + sum22k += x*x; + n22k++; + } + } + printf("average error 10k=%g 22k=%g\n", + sqrt(sum10k/n10k), + sqrt(sum22k/n22k)); +} + + +void test_res2(void) +{ + functable_t *t; + int i; + double x; + double f1,f2; + + t = malloc(sizeof(*t)); + memset(t,0,sizeof(*t)); + + t->start = -50.0; + t->offset = 1; + t->len = 100; + + t->func_x = functable_sinc; + t->func_dx = functable_dsinc; + + functable_init(t); + + for(i=0;i<1000;i++){ + x = -50.0 + 0.1 * i; + f1 = functable_sinc(NULL,x); + f2 = functable_eval(t,x); + fprintf(out,"%d %g %g %g\n",i,f1,f2,f1-f2); + } +} + +void test_res3(void) +{ + functable_t *t; + int i; + double x; + double f1,f2; + int n = 1; + + t = malloc(sizeof(*t)); + memset(t,0,sizeof(*t)); + + t->start = -50.0; + t->offset = 1.0 / n; + t->len = 100 * n; + + t->func_x = functable_sinc; + t->func_dx = functable_dsinc; + + t->func2_x = functable_window_std; + t->func2_dx = functable_window_dstd; + + t->scale = 1.0; + t->scale2 = 1.0 / (M_PI * 16); + + functable_init(t); + + for(i=0;i<1000 * n;i++){ + x = -50.0 + 0.1/n * i; + f1 = functable_sinc(NULL,t->scale * x) * + functable_window_std(NULL,t->scale2 * x); + f2 = functable_eval(t,x); + fprintf(out,"%d %g %g %g\n",i,f1,f2,f2-f1); + } +} + +double sinc_poly(double x) +{ +#define INV3FAC 1.66666666666666666e-1 +#define INV5FAC 8.33333333333333333e-3 +#define INV7FAC 1.984126984e-4 +#define INV9FAC 2.755731922e-6 +#define INV11FAC 2.505210839e-8 + double x2 = x * x; + + return 1 + - x2 * INV3FAC + + x2 * x2 * INV5FAC + - x2 * x2 * x2 * INV7FAC; + //+ x2 * x2 * x2 * x2 * INV9FAC + //- x2 * x2 * x2 * x2 * x2 * INV11FAC; +} + +void test_res4(void) +{ + int i; + double x,f1,f2; + + for(i=1;i<100;i++){ + x = 0.01 * i; + f1 = 1 - sin(x)/x; + f2 = 1 - sinc_poly(x); + + fprintf(out,"%g %.20g %.20g %.20g\n",x,f1,f2,f2-f1); + } +} + + +void test_res5(void) +{ + int i; + double sum; + + start_timer(); + sum = 0; + for(i=0;i<I_RATE;i++){ + sum += i_buf[i*2]; + } + end_timer(); + i_buf[0] = sum; +} + + +void short_to_double(double *d,short *x) { *d = *x; } +void short_to_float(float *f,short *x) { *f = *x; } +void float_to_double(double *f,float *x) { *f = *x; } +void double_to_short(short *f,double *x) { *f = *x; } + +double res6_tmp[1000]; + +void test_res6(void) +{ + int i; + + for(i=0;i<I_RATE;i++){ + i_buf[i] = rint(AMP * test_func((double)i/I_RATE)); + } + + conv_double_short_ref(res6_tmp,i_buf,1000); + for(i=0;i<1000;i++){ + res6_tmp[i] *= 3.0; + } + conv_short_double_ppcasm(o_buf,res6_tmp,1000); + + for(i=0;i<1000;i++){ + fprintf(out,"%d %d %g %d\n",i,i_buf[i],res6_tmp[i],o_buf[i]); + } +} + +void test_res7(void) +{ + resample_t *r; + int i; + double sum10k,sum22k; + double f; + int n10k,n22k; + double x; + + for(i=0;i<I_RATE;i++){ + i_buf[i] = rint(AMP * test_func((double)i/I_RATE)); + } + + r = malloc(sizeof(resample_t)); + memset(r,0,sizeof(resample_t)); + + r->i_rate = I_RATE; + r->o_rate = O_RATE; + //r->method = RESAMPLE_SINC_SLOW; + r->method = RESAMPLE_SINC; + r->channels = 1; + //r->verbose = 1; + r->filter_length = 64; + r->get_buffer = get_buffer; + + resample_init(r); + + start_timer(); +#define blocked +#ifdef blocked + for(i=0;i+256<I_RATE;i+=256){ + resample_scale(r,i_buf+i,256*2); + } + if(I_RATE-i){ + resample_scale(r,i_buf+i,(I_RATE-i)*2); + } +#else + resample_scale(r,i_buf,I_RATE*2); +#endif + end_timer(); + + for(i=0;i<O_RATE;i++){ + f = AMP*test_func((double)i/O_RATE); + //f = rint(AMP*test_func((double)i/O_RATE)); + fprintf(out,"%d %d %d %g %g\n",i, + o_buf[i],0, + f,o_buf[i]-f); + } + + sum10k=0; + sum22k=0; + n10k=0; + n22k=0; + for(i=0;i<O_RATE;i++){ + f = AMP*test_func((double)i/O_RATE); + //f = rint(AMP*test_func((double)i/O_RATE)); + x = o_buf[i]-f; + if(((0.5*i)/O_RATE*I_RATE)<10000){ + sum10k += x*x; + n10k++; + } + if(((0.5*i)/O_RATE*I_RATE)<22050){ + sum22k += x*x; + n22k++; + } + } + printf("average error 10k=%g 22k=%g\n", + sqrt(sum10k/n10k), + sqrt(sum22k/n22k)); +} + |