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531 lines
13 KiB
C
531 lines
13 KiB
C
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/* Resampling library
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* Copyright (C) <2001> David A. Schleef <ds@schleef.org>
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*
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* This library is free software; you can redistribute it and/or
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* modify it under the terms of the GNU Library General Public
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* License as published by the Free Software Foundation; either
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* version 2 of the License, or any later version.
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*
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* This library is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* Library General Public License for more details.
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*
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* You should have received a copy of the GNU Library General Public
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* License along with this library; if not, write to the
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* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
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* Boston, MA 02111-1307, USA.
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*/
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#include <string.h>
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#include <math.h>
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#include <stdio.h>
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#include <stdlib.h>
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#include <resample.h>
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inline double sinc(double x)
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{
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if(x==0)return 1;
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return sin(x) / x;
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}
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inline double window_func(double x)
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{
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x = 1 - x*x;
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return x*x;
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}
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signed short double_to_s16(double x)
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{
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if(x<-32768){
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printf("clipped\n");
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return -32768;
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}
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if(x>32767){
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printf("clipped\n");
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return -32767;
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}
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return rint(x);
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}
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signed short double_to_s16_ppcasm(double x)
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{
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if(x<-32768){
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return -32768;
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}
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if(x>32767){
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return -32767;
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}
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return rint(x);
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}
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static void resample_sinc_ft(resample_t * r);
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void resample_init(resample_t * r)
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{
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r->i_start = 0;
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if(r->filter_length&1){
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r->o_start = 0;
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}else{
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r->o_start = r->o_inc * 0.5;
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}
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memset(r->acc, 0, sizeof(r->acc));
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resample_reinit(r);
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}
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void resample_reinit(resample_t * r)
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{
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/* i_inc is the number of samples that the output increments for
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* each input sample. o_inc is the opposite. */
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r->i_inc = (double) r->o_rate / r->i_rate;
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r->o_inc = (double) r->i_rate / r->o_rate;
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r->halftaps = (r->filter_length - 1.0) * 0.5;
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switch (r->method) {
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default:
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case RESAMPLE_NEAREST:
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r->scale = resample_nearest;
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break;
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case RESAMPLE_BILINEAR:
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r->scale = resample_bilinear;
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break;
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case RESAMPLE_SINC_SLOW:
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r->scale = resample_sinc;
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break;
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case RESAMPLE_SINC:
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r->scale = resample_sinc_ft;
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break;
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}
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}
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/*
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* Prepare to be confused.
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*
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* We keep a "timebase" that is based on output samples. The zero
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* of the timebase cooresponds to the next output sample that will
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* be written.
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*
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* i_start is the "time" that corresponds to the first input sample
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* in an incoming buffer. Since the output depends on input samples
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* ahead in time, i_start will tend to be around halftaps.
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*
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* i_start_buf is the time of the first sample in the temporary
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* buffer.
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*/
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void resample_scale(resample_t * r, void *i_buf, unsigned int i_size)
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{
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int o_size;
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r->i_buf = i_buf;
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r->i_samples = i_size / 2 / r->channels;
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r->i_start_buf = r->i_start - r->filter_length * r->i_inc;
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/* i_start is the offset (in a given output sample) that is the
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* beginning of the current input buffer */
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r->i_end = r->i_start + r->i_inc * r->i_samples;
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r->o_samples = floor(r->i_end - r->halftaps * r->i_inc);
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o_size = r->o_samples * r->channels * 2;
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r->o_buf = r->get_buffer(r->priv, o_size);
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if(r->verbose){
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printf("resample_scale: i_buf=%p i_size=%d\n",
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i_buf,i_size);
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printf("resample_scale: i_samples=%d o_samples=%d i_inc=%g o_buf=%p\n",
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r->i_samples, r->o_samples, r->i_inc, r->o_buf);
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printf("resample_scale: i_start=%g i_end=%g o_start=%g\n",
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r->i_start, r->i_end, r->o_start);
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}
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if ((r->filter_length + r->i_samples)*2*2 > r->buffer_len) {
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int size = (r->filter_length + r->i_samples) * sizeof(double) * 2;
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if(r->verbose){
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printf("resample temp buffer size=%d\n",size);
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}
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if(r->buffer)free(r->buffer);
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r->buffer_len = size;
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r->buffer = malloc(size);
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memset(r->buffer, 0, size);
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}
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if(r->channels==2){
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conv_double_short(
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r->buffer + r->filter_length * sizeof(double) * 2,
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r->i_buf, r->i_samples * 2);
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}else{
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conv_double_short_dstr(
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r->buffer + r->filter_length * sizeof(double) * 2,
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r->i_buf, r->i_samples, sizeof(double) * 2);
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}
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r->scale(r);
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memcpy(r->buffer,
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r->buffer + r->i_samples * sizeof(double) * 2,
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r->filter_length * sizeof(double) * 2);
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/* updating times */
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r->i_start += r->i_samples * r->i_inc;
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r->o_start += r->o_samples * r->o_inc - r->i_samples;
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/* adjusting timebase zero */
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r->i_start -= r->o_samples;
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}
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void resample_nearest(resample_t * r)
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{
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signed short *i_ptr, *o_ptr;
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int i_count = 0;
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double a;
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int i;
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i_ptr = (signed short *) r->i_buf;
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o_ptr = (signed short *) r->o_buf;
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a = r->o_start;
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i_count = 0;
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#define SCALE_LOOP(COPY,INC) \
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for (i = 0; i < r->o_samples; i++) { \
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COPY; \
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a += r->o_inc; \
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while (a >= 1) { \
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a -= 1; \
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i_ptr+=INC; \
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i_count++; \
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} \
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o_ptr+=INC; \
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}
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switch (r->channels) {
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case 1:
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SCALE_LOOP(o_ptr[0] = i_ptr[0], 1);
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break;
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case 2:
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SCALE_LOOP(o_ptr[0] = i_ptr[0];
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o_ptr[1] = i_ptr[1], 2);
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break;
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default:
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{
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int n, n_chan = r->channels;
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SCALE_LOOP(for (n = 0; n < n_chan; n++) o_ptr[n] =
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i_ptr[n], n_chan);
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}
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}
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if (i_count != r->i_samples) {
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printf("handled %d in samples (expected %d)\n", i_count,
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r->i_samples);
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}
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}
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void resample_bilinear(resample_t * r)
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{
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signed short *i_ptr, *o_ptr;
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int o_count = 0;
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double b;
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int i;
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double acc0, acc1;
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i_ptr = (signed short *) r->i_buf;
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o_ptr = (signed short *) r->o_buf;
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acc0 = r->acc[0];
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acc1 = r->acc[1];
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b = r->i_start;
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for (i = 0; i < r->i_samples; i++) {
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b += r->i_inc;
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//printf("in %d\n",i_ptr[0]);
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if(b>=2){
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printf("not expecting b>=2\n");
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}
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if (b >= 1) {
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acc0 += (1.0 - (b-r->i_inc)) * i_ptr[0];
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acc1 += (1.0 - (b-r->i_inc)) * i_ptr[1];
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o_ptr[0] = rint(acc0);
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//printf("out %d\n",o_ptr[0]);
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o_ptr[1] = rint(acc1);
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o_ptr += 2;
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o_count++;
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b -= 1.0;
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acc0 = b * i_ptr[0];
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acc1 = b * i_ptr[1];
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} else {
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acc0 += i_ptr[0] * r->i_inc;
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acc1 += i_ptr[1] * r->i_inc;
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}
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i_ptr += 2;
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}
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r->acc[0] = acc0;
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r->acc[1] = acc1;
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if (o_count != r->o_samples) {
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printf("handled %d out samples (expected %d)\n", o_count,
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r->o_samples);
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}
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}
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void resample_sinc_slow(resample_t * r)
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{
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signed short *i_ptr, *o_ptr;
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int i, j;
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double c0, c1;
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double a;
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int start;
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double center;
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double weight;
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if (!r->buffer) {
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int size = r->filter_length * 2 * r->channels;
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printf("resample temp buffer\n");
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r->buffer = malloc(size);
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memset(r->buffer, 0, size);
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}
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i_ptr = (signed short *) r->i_buf;
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o_ptr = (signed short *) r->o_buf;
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a = r->i_start;
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#define GETBUF(index,chan) (((index)<0) \
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? ((short *)(r->buffer))[((index)+r->filter_length)*2+(chan)] \
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: i_ptr[(index)*2+(chan)])
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{
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double sinx, cosx, sind, cosd;
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double x, d;
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double t;
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for (i = 0; i < r->o_samples; i++) {
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start = floor(a) - r->filter_length;
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center = a - r->halftaps;
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x = M_PI * (start - center) * r->o_inc;
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sinx = sin(M_PI * (start - center) * r->o_inc);
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cosx = cos(M_PI * (start - center) * r->o_inc);
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d = M_PI * r->o_inc;
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sind = sin(M_PI * r->o_inc);
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cosd = cos(M_PI * r->o_inc);
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c0 = 0;
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c1 = 0;
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for (j = 0; j < r->filter_length; j++) {
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weight = (x==0)?1:(sinx/x);
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//printf("j %d sin %g cos %g\n",j,sinx,cosx);
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//printf("j %d sin %g x %g sinc %g\n",j,sinx,x,weight);
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c0 += weight * GETBUF((start + j), 0);
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c1 += weight * GETBUF((start + j), 1);
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t = cosx * cosd - sinx * sind;
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sinx = cosx * sind + sinx * cosd;
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cosx = t;
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x += d;
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}
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o_ptr[0] = rint(c0);
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o_ptr[1] = rint(c1);
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o_ptr += 2;
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a += r->o_inc;
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}
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}
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memcpy(r->buffer,
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i_ptr + (r->i_samples - r->filter_length) * r->channels,
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r->filter_length * 2 * r->channels);
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}
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void resample_sinc(resample_t * r)
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{
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double *ptr;
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signed short *o_ptr;
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int i, j;
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double c0, c1;
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double a;
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int start;
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double center;
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double weight;
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double x0, x, d;
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double scale;
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ptr = (double *) r->buffer;
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o_ptr = (signed short *) r->o_buf;
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/* scale provides a cutoff frequency for the low
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* pass filter aspects of sinc(). scale=M_PI
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* will cut off at the input frequency, which is
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* good for up-sampling, but will cause aliasing
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* for downsampling. Downsampling needs to be
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* cut off at o_rate, thus scale=M_PI*r->i_inc. */
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/* actually, it needs to be M_PI*r->i_inc*r->i_inc.
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* Need to research why. */
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scale = M_PI*r->i_inc;
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for (i = 0; i < r->o_samples; i++) {
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a = r->o_start + i * r->o_inc;
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start = floor(a - r->halftaps);
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//printf("%d: a=%g start=%d end=%d\n",i,a,start,start+r->filter_length-1);
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center = a;
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//x = M_PI * (start - center) * r->o_inc;
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//d = M_PI * r->o_inc;
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//x = (start - center) * r->o_inc;
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x0 = (start - center) * r->o_inc;
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d = r->o_inc;
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c0 = 0;
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c1 = 0;
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for (j = 0; j < r->filter_length; j++) {
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x = x0 + d * j;
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weight = sinc(x*scale*r->i_inc)*scale/M_PI;
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weight *= window_func(x/r->halftaps*r->i_inc);
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c0 += weight * ptr[(start + j + r->filter_length)*2 + 0];
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c1 += weight * ptr[(start + j + r->filter_length)*2 + 1];
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}
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o_ptr[0] = double_to_s16(c0);
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o_ptr[1] = double_to_s16(c1);
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o_ptr += 2;
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}
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}
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/*
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* Resampling audio is best done using a sinc() filter.
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*
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*
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* out[t] = Sum( in[t'] * sinc((t-t')/delta_t), all t')
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*
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* The immediate problem with this algorithm is that it involves a
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* sum over an infinite number of input samples, both in the past
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* and future. Note that even though sinc(x) is bounded by 1/x,
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* and thus decays to 0 for large x, since sum(x,{x=0,1..,n}) diverges
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* as log(n), we need to be careful about convergence. This is
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* typically done by using a windowing function, which also makes
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* the sum over a finite number of input samples.
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*
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* The next problem is computational: sinc(), and especially
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* sinc() multiplied by a non-trivial windowing function is expensive
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* to calculate, and also difficult to find SIMD optimizations. Since
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||
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* the time increment on input and output is different, it is not
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* possible to use a FIR filter, because the taps would have to be
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* recalculated for every t.
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*
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||
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* To get around the expense of calculating sinc() for every point,
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||
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* we pre-calculate sinc() at a number of points, and then interpolate
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||
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* for the values we want in calculations. The interpolation method
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||
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* chosen is bi-cubic, which requires both the evalated function and
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||
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* its derivative at every pre-sampled point. Also, if the sampled
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* 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));
|
||
|
}
|
||
|
}
|
||
|
|