jni/libsndfile/tests/dft_cmp.c - jami-client-android - Gitiles

 /*
 ** 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	<stdio.h>
 #include	<stdlib.h>
 #include	<math.h>

 #include	"dft_cmp.h"
 #include	"utils.h"

 #ifndef		M_PI
 #define		M_PI		3.14159265358979323846264338
 #endif

 #define		DFT_SPEC_LENGTH		(DFT_DATA_LENGTH / 2)

 static void	dft_magnitude (const double *data, double *spectrum) ;
 static double calc_max_spectral_difference (const double *spec1, const double *spec2) ;

 /*--------------------------------------------------------------------------------
 **	Public functions.
 */

 double
 dft_cmp_float (int linenum, const float *in_data, const float *test_data, int len, double target_snr, int allow_exit)
 {	static double orig [DFT_DATA_LENGTH] ;
 	static double test [DFT_DATA_LENGTH] ;
 	unsigned	k ;

 	if (len != DFT_DATA_LENGTH)
 	{	printf ("Error (line %d) : dft_cmp_float : Bad input array length.\n", linenum) ;
 		return 1 ;
 		} ;

 	for (k = 0 ; k < ARRAY_LEN (orig) ; k++)
 	{	test [k] = test_data [k] ;
 		orig [k] = in_data [k] ;
 		} ;

 	return dft_cmp_double (linenum, orig, test, len, target_snr, allow_exit) ;
 } /* dft_cmp_float */

 double
 dft_cmp_double (int linenum, const double *orig, const double *test, int len, double target_snr, int allow_exit)
 {	static double orig_spec [DFT_SPEC_LENGTH] ;
 	static double test_spec [DFT_SPEC_LENGTH] ;
 	double		snr ;

 	if (! orig || ! test)
 	{	printf ("Error (line %d) : dft_cmp_double : Bad input arrays.\n", linenum) ;
 		return 1 ;
 		} ;

 	if (len != DFT_DATA_LENGTH)
 	{	printf ("Error (line %d) : dft_cmp_double : Bad input array length.\n", linenum) ;
 		return 1 ;
 		} ;

 	dft_magnitude (orig, orig_spec) ;
 	dft_magnitude (test, test_spec) ;

 	snr = calc_max_spectral_difference (orig_spec, test_spec) ;

 	if (snr > target_snr)
 	{	printf ("\n\nLine %d: Actual SNR (% 4.1f) > target SNR (% 4.1f).\n\n", linenum, snr, target_snr) ;
 		oct_save_double	(orig, test, len) ;
 		if (allow_exit)
 			exit (1) ;
 		} ;

 	if (snr < -500.0)
 		snr = -500.0 ;

 	return snr ;
 } /* dft_cmp_double */

 /*--------------------------------------------------------------------------------
 **	Quick dirty calculation of magnitude spectrum for real valued data using
 **	Discrete Fourier Transform. Since the data is real, the DFT is only
 **	calculated for positive frequencies.
 */

 static void
 dft_magnitude (const double *data, double *spectrum)
 {	static double cos_angle [DFT_DATA_LENGTH] = { 0.0 } ;
 	static double sin_angle [DFT_DATA_LENGTH] ;

 	double	real_part, imag_part ;
 	int		k, n ;

 	/* If sine and cosine tables haven't been initialised, do so. */
 	if (cos_angle [0] == 0.0)
 		for (n = 0 ; n < DFT_DATA_LENGTH ; n++)
 		{	cos_angle [n] = cos (2.0 * M_PI * n / DFT_DATA_LENGTH) ;
 			sin_angle [n] = -1.0 * sin (2.0 * M_PI * n / DFT_DATA_LENGTH) ;
 			} ;

 	/* DFT proper. Since the data is real, only generate a half spectrum. */
 	for (k = 1 ; k < DFT_SPEC_LENGTH ; k++)
 	{	real_part = 0.0 ;
 		imag_part = 0.0 ;

 		for (n = 0 ; n < DFT_DATA_LENGTH ; n++)
 		{	real_part += data [n] * cos_angle [(k * n) % DFT_DATA_LENGTH] ;
 			imag_part += data [n] * sin_angle [(k * n) % DFT_DATA_LENGTH] ;
 			} ;

 		spectrum [k] = sqrt (real_part * real_part + imag_part * imag_part) ;
 		} ;

 	spectrum [k] = 0.0 ;

 	spectrum [0] = spectrum [1] = spectrum [2] = spectrum [3] = spectrum [4] = 0.0 ;

 	return ;
 } /* dft_magnitude */

 static double
 calc_max_spectral_difference (const double *orig, const double *test)
 {	double orig_max = 0.0, max_diff = 0.0 ;
 	int	k ;

 	for (k = 0 ; k < DFT_SPEC_LENGTH ; k++)
 	{	if (orig_max < orig [k])
 			orig_max = orig [k] ;
 		if (max_diff < fabs (orig [k] - test [k]))
 			max_diff = fabs (orig [k] - test [k]) ;
 		} ;

 	if (max_diff < 1e-25)
 		return -500.0 ;

 	return 20.0 * log10 (max_diff / orig_max) ;
 } /* calc_max_spectral_difference */
	/*
	** 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 <stdio.h>
	#include <stdlib.h>
	#include <math.h>

	#include "dft_cmp.h"
	#include "utils.h"

	#ifndef M_PI
	#define M_PI 3.14159265358979323846264338
	#endif

	#define DFT_SPEC_LENGTH (DFT_DATA_LENGTH / 2)

	static void dft_magnitude (const double data, double spectrum) ;
	static double calc_max_spectral_difference (const double spec1, const double spec2) ;

	/*--------------------------------------------------------------------------------
	** Public functions.
	*/

	double
	dft_cmp_float (int linenum, const float in_data, const float test_data, int len, double target_snr, int allow_exit)
	{ static double orig [DFT_DATA_LENGTH] ;
	static double test [DFT_DATA_LENGTH] ;
	unsigned k ;

	if (len != DFT_DATA_LENGTH)
	{ printf ("Error (line %d) : dft_cmp_float : Bad input array length.\n", linenum) ;
	return 1 ;
	} ;

	for (k = 0 ; k < ARRAY_LEN (orig) ; k++)
	{ test [k] = test_data [k] ;
	orig [k] = in_data [k] ;
	} ;

	return dft_cmp_double (linenum, orig, test, len, target_snr, allow_exit) ;
	} /* dft_cmp_float */

	double
	dft_cmp_double (int linenum, const double orig, const double test, int len, double target_snr, int allow_exit)
	{ static double orig_spec [DFT_SPEC_LENGTH] ;
	static double test_spec [DFT_SPEC_LENGTH] ;
	double snr ;

	if (! orig \|\| ! test)
	{ printf ("Error (line %d) : dft_cmp_double : Bad input arrays.\n", linenum) ;
	return 1 ;
	} ;

	if (len != DFT_DATA_LENGTH)
	{ printf ("Error (line %d) : dft_cmp_double : Bad input array length.\n", linenum) ;
	return 1 ;
	} ;

	dft_magnitude (orig, orig_spec) ;
	dft_magnitude (test, test_spec) ;

	snr = calc_max_spectral_difference (orig_spec, test_spec) ;

	if (snr > target_snr)
	{ printf ("\n\nLine %d: Actual SNR (% 4.1f) > target SNR (% 4.1f).\n\n", linenum, snr, target_snr) ;
	oct_save_double (orig, test, len) ;
	if (allow_exit)
	exit (1) ;
	} ;

	if (snr < -500.0)
	snr = -500.0 ;

	return snr ;
	} /* dft_cmp_double */

	/*--------------------------------------------------------------------------------
	** Quick dirty calculation of magnitude spectrum for real valued data using
	** Discrete Fourier Transform. Since the data is real, the DFT is only
	** calculated for positive frequencies.
	*/

	static void
	dft_magnitude (const double data, double spectrum)
	{ static double cos_angle [DFT_DATA_LENGTH] = { 0.0 } ;
	static double sin_angle [DFT_DATA_LENGTH] ;

	double real_part, imag_part ;
	int k, n ;

	/* If sine and cosine tables haven't been initialised, do so. */
	if (cos_angle [0] == 0.0)
	for (n = 0 ; n < DFT_DATA_LENGTH ; n++)
	{ cos_angle [n] = cos (2.0 * M_PI * n / DFT_DATA_LENGTH) ;
	sin_angle [n] = -1.0 * sin (2.0 * M_PI * n / DFT_DATA_LENGTH) ;
	} ;

	/* DFT proper. Since the data is real, only generate a half spectrum. */
	for (k = 1 ; k < DFT_SPEC_LENGTH ; k++)
	{ real_part = 0.0 ;
	imag_part = 0.0 ;

	for (n = 0 ; n < DFT_DATA_LENGTH ; n++)
	{ real_part += data [n] * cos_angle [(k * n) % DFT_DATA_LENGTH] ;
	imag_part += data [n] * sin_angle [(k * n) % DFT_DATA_LENGTH] ;
	} ;

	spectrum [k] = sqrt (real_part * real_part + imag_part * imag_part) ;
	} ;

	spectrum [k] = 0.0 ;

	spectrum [0] = spectrum [1] = spectrum [2] = spectrum [3] = spectrum [4] = 0.0 ;

	return ;
	} /* dft_magnitude */

	static double
	calc_max_spectral_difference (const double orig, const double test)
	{ double orig_max = 0.0, max_diff = 0.0 ;
	int k ;

	for (k = 0 ; k < DFT_SPEC_LENGTH ; k++)
	{ if (orig_max < orig [k])
	orig_max = orig [k] ;
	if (max_diff < fabs (orig [k] - test [k]))
	max_diff = fabs (orig [k] - test [k]) ;
	} ;

	if (max_diff < 1e-25)
	return -500.0 ;

	return 20.0 * log10 (max_diff / orig_max) ;
	} /* calc_max_spectral_difference */