boo/soxr/lsr-tests/multi_channel_test.c

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/*
** Copyright (C) 2002-2011 Erik de Castro Lopo <erikd@mega-nerd.com>
**
** This program is free software; you can redistribute it and/or modify
** it under the terms of the GNU General Public License as published by
** the Free Software Foundation; either version 2 of the License, or
** (at your option) any later version.
**
** This program 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 General Public License for more details.
**
** You should have received a copy of the GNU General Public License
** along with this program; if not, write to the Free Software
** Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307, USA.
*/
#include "config.h"
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <assert.h>
#include <samplerate.h>
#include "util.h"
#define BUFFER_LEN 50000
#define BLOCK_LEN (12)
#define MAX_CHANNELS 10
static void simple_test (int converter, int channel_count, double target_snr) ;
static void process_test (int converter, int channel_count, double target_snr) ;
static void callback_test (int converter, int channel_count, double target_snr) ;
int
main (void)
{ double target ;
int k ;
puts ("\n Zero Order Hold interpolator :") ;
target = 38.0 ;
for (k = 1 ; k <= 3 ; k++)
{ simple_test (SRC_ZERO_ORDER_HOLD, k, target) ;
process_test (SRC_ZERO_ORDER_HOLD, k, target) ;
callback_test (SRC_ZERO_ORDER_HOLD, k, target) ;
} ;
puts ("\n Linear interpolator :") ;
target = 79.0 ;
for (k = 1 ; k <= 3 ; k++)
{ simple_test (SRC_LINEAR, k, target) ;
process_test (SRC_LINEAR, k, target) ;
callback_test (SRC_LINEAR, k, target) ;
} ;
puts ("\n Sinc interpolator :") ;
target = 100.0 ;
for (k = 1 ; k <= MAX_CHANNELS ; k++)
{ simple_test (SRC_SINC_FASTEST, k, target) ;
process_test (SRC_SINC_FASTEST, k, target) ;
callback_test (SRC_SINC_FASTEST, k, target) ;
} ;
puts ("") ;
return 0 ;
} /* main */
/*==============================================================================
*/
static float input_serial [BUFFER_LEN * MAX_CHANNELS] ;
static float input_interleaved [BUFFER_LEN * MAX_CHANNELS] ;
static float output_interleaved [BUFFER_LEN * MAX_CHANNELS] ;
static float output_serial [BUFFER_LEN * MAX_CHANNELS] ;
static void
simple_test (int converter, int channel_count, double target_snr)
{ SRC_DATA src_data ;
double freq, snr ;
int ch, error, frames ;
printf ("\t%-22s (%2d channel%c) ............ ", "simple_test", channel_count, channel_count > 1 ? 's' : ' ') ;
fflush (stdout) ;
assert (channel_count <= MAX_CHANNELS) ;
memset (input_serial, 0, sizeof (input_serial)) ;
memset (input_interleaved, 0, sizeof (input_interleaved)) ;
memset (output_interleaved, 0, sizeof (output_interleaved)) ;
memset (output_serial, 0, sizeof (output_serial)) ;
frames = BUFFER_LEN ;
/* Calculate channel_count separate windowed sine waves. */
for (ch = 0 ; ch < channel_count ; ch++)
{ freq = (200.0 + 33.333333333 * ch) / 44100.0 ;
gen_windowed_sines (1, &freq, 1.0, input_serial + ch * frames, frames) ;
} ;
/* Interleave the data in preparation for SRC. */
interleave_data (input_serial, input_interleaved, frames, channel_count) ;
/* Choose a converstion ratio <= 1.0. */
src_data.src_ratio = 0.95 ;
src_data.data_in = input_interleaved ;
src_data.input_frames = frames ;
src_data.data_out = output_interleaved ;
src_data.output_frames = frames ;
if ((error = src_simple (&src_data, converter, channel_count)))
{ printf ("\n\nLine %d : %s\n\n", __LINE__, src_strerror (error)) ;
exit (1) ;
} ;
if (fabs (src_data.output_frames_gen - src_data.src_ratio * src_data.input_frames) > 2)
{ printf ("\n\nLine %d : bad output data length %ld should be %d.\n", __LINE__,
src_data.output_frames_gen, (int) floor (src_data.src_ratio * src_data.input_frames)) ;
printf ("\tsrc_ratio : %.4f\n", src_data.src_ratio) ;
printf ("\tinput_len : %ld\n", src_data.input_frames) ;
printf ("\toutput_len : %ld\n\n", src_data.output_frames_gen) ;
exit (1) ;
} ;
/* De-interleave data so SNR can be calculated for each channel. */
deinterleave_data (output_interleaved, output_serial, frames, channel_count) ;
for (ch = 0 ; ch < channel_count ; ch++)
{ snr = calculate_snr (output_serial + ch * frames, frames, 1) ;
if (snr < target_snr)
{ printf ("\n\nLine %d: channel %d snr %f should be %f\n", __LINE__, ch, snr, target_snr) ;
save_oct_float ("output.dat", input_serial, channel_count * frames, output_serial, channel_count * frames) ;
exit (1) ;
} ;
} ;
puts ("ok") ;
return ;
} /* simple_test */
/*==============================================================================
*/
static void
process_test (int converter, int channel_count, double target_snr)
{ SRC_STATE *src_state ;
SRC_DATA src_data ;
double freq, snr ;
int ch, error, frames, current_in, current_out ;
printf ("\t%-22s (%2d channel%c) ............ ", "process_test", channel_count, channel_count > 1 ? 's' : ' ') ;
fflush (stdout) ;
assert (channel_count <= MAX_CHANNELS) ;
memset (input_serial, 0, sizeof (input_serial)) ;
memset (input_interleaved, 0, sizeof (input_interleaved)) ;
memset (output_interleaved, 0, sizeof (output_interleaved)) ;
memset (output_serial, 0, sizeof (output_serial)) ;
frames = BUFFER_LEN ;
/* Calculate channel_count separate windowed sine waves. */
for (ch = 0 ; ch < channel_count ; ch++)
{ freq = (400.0 + 11.333333333 * ch) / 44100.0 ;
gen_windowed_sines (1, &freq, 1.0, input_serial + ch * frames, frames) ;
} ;
/* Interleave the data in preparation for SRC. */
interleave_data (input_serial, input_interleaved, frames, channel_count) ;
/* Perform sample rate conversion. */
if ((src_state = src_new (converter, channel_count, &error)) == NULL)
{ printf ("\n\nLine %d : src_new() failed : %s\n\n", __LINE__, src_strerror (error)) ;
exit (1) ;
} ;
src_data.end_of_input = 0 ; /* Set this later. */
/* Choose a converstion ratio < 1.0. */
src_data.src_ratio = 0.95 ;
src_data.data_in = input_interleaved ;
src_data.data_out = output_interleaved ;
current_in = current_out = 0 ;
while (1)
{ src_data.input_frames = MAX (MIN (BLOCK_LEN, frames - current_in), 0) ;
src_data.output_frames = MAX (MIN (BLOCK_LEN, frames - current_out), 0) ;
if ((error = src_process (src_state, &src_data)))
{ printf ("\n\nLine %d : %s\n\n", __LINE__, src_strerror (error)) ;
exit (1) ;
} ;
if (src_data.end_of_input && src_data.output_frames_gen == 0)
break ;
current_in += src_data.input_frames_used ;
current_out += src_data.output_frames_gen ;
src_data.data_in += src_data.input_frames_used * channel_count ;
src_data.data_out += src_data.output_frames_gen * channel_count ;
src_data.end_of_input = (current_in >= frames) ? 1 : 0 ;
} ;
src_state = src_delete (src_state) ;
if (fabs (current_out - src_data.src_ratio * current_in) > 2)
{ printf ("\n\nLine %d : bad output data length %d should be %d.\n", __LINE__,
current_out, (int) floor (src_data.src_ratio * current_in)) ;
printf ("\tsrc_ratio : %.4f\n", src_data.src_ratio) ;
printf ("\tinput_len : %d\n", frames) ;
printf ("\toutput_len : %d\n\n", current_out) ;
exit (1) ;
} ;
/* De-interleave data so SNR can be calculated for each channel. */
deinterleave_data (output_interleaved, output_serial, frames, channel_count) ;
for (ch = 0 ; ch < channel_count ; ch++)
{ snr = calculate_snr (output_serial + ch * frames, frames, 1) ;
if (snr < target_snr)
{ printf ("\n\nLine %d: channel %d snr %f should be %f\n", __LINE__, ch, snr, target_snr) ;
save_oct_float ("output.dat", input_serial, channel_count * frames, output_serial, channel_count * frames) ;
exit (1) ;
} ;
} ;
puts ("ok") ;
return ;
} /* process_test */
/*==============================================================================
*/
typedef struct
{ int channels ;
long total_frames ;
long current_frame ;
float *data ;
} TEST_CB_DATA ;
static long
test_callback_func (void *cb_data, float **data)
{ TEST_CB_DATA *pcb_data ;
long frames ;
if ((pcb_data = cb_data) == NULL)
return 0 ;
if (data == NULL)
return 0 ;
*data = pcb_data->data + (pcb_data->current_frame * pcb_data->channels) ;
if (pcb_data->total_frames - pcb_data->current_frame < BLOCK_LEN)
frames = pcb_data->total_frames - pcb_data->current_frame ;
else
frames = BLOCK_LEN ;
pcb_data->current_frame += frames ;
return frames ;
} /* test_callback_func */
static void
callback_test (int converter, int channel_count, double target_snr)
{ TEST_CB_DATA test_callback_data ;
SRC_STATE *src_state = NULL ;
double freq, snr, src_ratio ;
int ch, error, frames, read_total, read_count ;
printf ("\t%-22s (%2d channel%c) ............ ", "callback_test", channel_count, channel_count > 1 ? 's' : ' ') ;
fflush (stdout) ;
assert (channel_count <= MAX_CHANNELS) ;
memset (input_serial, 0, sizeof (input_serial)) ;
memset (input_interleaved, 0, sizeof (input_interleaved)) ;
memset (output_interleaved, 0, sizeof (output_interleaved)) ;
memset (output_serial, 0, sizeof (output_serial)) ;
memset (&test_callback_data, 0, sizeof (test_callback_data)) ;
frames = BUFFER_LEN ;
/* Calculate channel_count separate windowed sine waves. */
for (ch = 0 ; ch < channel_count ; ch++)
{ freq = (200.0 + 33.333333333 * ch) / 44100.0 ;
gen_windowed_sines (1, &freq, 1.0, input_serial + ch * frames, frames) ;
} ;
/* Interleave the data in preparation for SRC. */
interleave_data (input_serial, input_interleaved, frames, channel_count) ;
/* Perform sample rate conversion. */
src_ratio = 0.95 ;
test_callback_data.channels = channel_count ;
test_callback_data.total_frames = frames ;
test_callback_data.current_frame = 0 ;
test_callback_data.data = input_interleaved ;
if ((src_state = src_callback_new (test_callback_func, converter, channel_count, &error, &test_callback_data)) == NULL)
{ printf ("\n\nLine %d : %s\n\n", __LINE__, src_strerror (error)) ;
exit (1) ;
} ;
read_total = 0 ;
while (read_total < frames)
{ read_count = src_callback_read (src_state, src_ratio, frames - read_total, output_interleaved + read_total * channel_count) ;
if (read_count <= 0)
break ;
read_total += read_count ;
} ;
if ((error = src_error (src_state)) != 0)
{ printf ("\n\nLine %d : %s\n\n", __LINE__, src_strerror (error)) ;
exit (1) ;
} ;
src_state = src_delete (src_state) ;
if (fabs (read_total - src_ratio * frames) > 2)
{ printf ("\n\nLine %d : bad output data length %d should be %d.\n", __LINE__,
read_total, (int) floor (src_ratio * frames)) ;
printf ("\tsrc_ratio : %.4f\n", src_ratio) ;
printf ("\tinput_len : %d\n", frames) ;
printf ("\toutput_len : %d\n\n", read_total) ;
exit (1) ;
} ;
/* De-interleave data so SNR can be calculated for each channel. */
deinterleave_data (output_interleaved, output_serial, frames, channel_count) ;
for (ch = 0 ; ch < channel_count ; ch++)
{ snr = calculate_snr (output_serial + ch * frames, frames, 1) ;
if (snr < target_snr)
{ printf ("\n\nLine %d: channel %d snr %f should be %f\n", __LINE__, ch, snr, target_snr) ;
save_oct_float ("output.dat", input_serial, channel_count * frames, output_serial, channel_count * frames) ;
exit (1) ;
} ;
} ;
puts ("ok") ;
return ;
} /* callback_test */