dl/test/compare.c - deps/third_party/openmax - Git at Google

 /*
  *  Copyright (c) 2013 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include <stdio.h>
 #include <math.h>
 #include "armSP.h"
 #include "compare.h"

 extern int verbose;

 // Convert to dB
 static double Db(double x) {
     return (x <= 0) ? -1000.0 : 10 * log(x) / log(10);
 }

 static double CalculateSNR(double signal_power, double noise_power) {
     return (noise_power == 0) ? 1000 : Db(signal_power / noise_power);
 }

 /*
  * Compute the SNR of the actual signal, returning the SNR of the real
  * and imaginary parts separately, and also the overall (complex SNR)
  */

 void CompareComplex32(struct SnrResult* snr, OMX_SC32* actual,
                       OMX_SC32* expected, int size) {
   double real_signal_power = 0;
   double imag_signal_power = 0;
   double complex_signal_power = 0;
   double real_noise_power = 0;
   double imag_noise_power = 0;
   double complex_noise_power = 0;
   int k;

   for (k = 0; k < size; ++k) {
     double x2;
     double y2;
     double z2;

     if (verbose > 255) {
       printf("%4d: (%10d, %10d) (%10d, %10d)\n", k,
              actual[k].Re, actual[k].Im,
              expected[k].Re, expected[k].Im);
     }

     x2 = pow((double) expected[k].Re, 2);
     y2 = pow((double) expected[k].Im, 2);
     real_signal_power += x2;
     imag_signal_power += y2;
     complex_signal_power += x2 + y2;

     x2 = pow((double) actual[k].Re - expected[k].Re, 2);
     y2 = pow((double) actual[k].Im - expected[k].Im, 2);

     real_noise_power += x2;
     imag_noise_power += y2;
     complex_noise_power += x2 + y2;
   }

   snr->real_snr_ = CalculateSNR(real_signal_power, real_noise_power);
   snr->imag_snr_ = CalculateSNR(imag_signal_power, imag_noise_power);
   snr->complex_snr_ = CalculateSNR(complex_signal_power, complex_noise_power);
 }

 /*
  * Compute the SNR of the actual real signal, returning the SNR.
  */

 void CompareReal32(struct SnrResult* snr, OMX_S32* actual,
                    OMX_S32* expected, int size) {
   double real_signal_power = 0;
   double real_noise_power = 0;

   int k;
   for (k = 0; k < size; ++k) {
     double x2;

     x2 = pow((double) expected[k], 2);

     real_signal_power += x2;

     x2 = pow((double) actual[k] - expected[k], 2);

     real_noise_power += x2;
   }

   snr->real_snr_ = CalculateSNR(real_signal_power, real_noise_power);
   snr->imag_snr_ = -10000;
   snr->complex_snr_ = -10000;
 }

 void CompareReal16(struct SnrResult* snr, OMX_S16* actual,
                    OMX_S16* expected, int size) {
   double real_signal_power = 0;
   double real_noise_power = 0;

   int k;
   for (k = 0; k < size; ++k) {
     double x2;

     x2 = pow((double) expected[k], 2);

     real_signal_power += x2;

     x2 = pow((double) actual[k] - expected[k], 2);

     real_noise_power += x2;
   }

   snr->real_snr_ = CalculateSNR(real_signal_power, real_noise_power);
   snr->imag_snr_ = -10000;
   snr->complex_snr_ = -10000;
 }

 void CompareComplexFloat(struct SnrResult* snr, OMX_FC32* actual,
                          OMX_FC32* expected, int size) {
   double real_signal_power = 0;
   double imag_signal_power = 0;
   double complex_signal_power = 0;
   double real_noise_power = 0;
   double imag_noise_power = 0;
   double complex_noise_power = 0;
   int k;

   for (k = 0; k < size; ++k) {
     double x2;
     double y2;
     double z2;

     if (verbose > 255) {
       printf("%4d: (%10g, %10g) (%10g, %10g)\n", k,
              actual[k].Re, actual[k].Im,
              expected[k].Re, expected[k].Im);
     }

     x2 = pow((double) expected[k].Re, 2);
     y2 = pow((double) expected[k].Im, 2);
     real_signal_power += x2;
     imag_signal_power += y2;
     complex_signal_power += x2 + y2;

     x2 = pow((double) actual[k].Re - expected[k].Re, 2);
     y2 = pow((double) actual[k].Im - expected[k].Im, 2);

     real_noise_power += x2;
     imag_noise_power += y2;
     complex_noise_power += x2 + y2;
   }

   snr->real_snr_ = CalculateSNR(real_signal_power, real_noise_power);
   snr->imag_snr_ = CalculateSNR(imag_signal_power, imag_noise_power);
   snr->complex_snr_ = CalculateSNR(complex_signal_power, complex_noise_power);
 }

 void CompareFloat(struct SnrResult* snr, OMX_F32* actual,
                   OMX_F32* expected, int size) {
   double signal_power = 0;
   double noise_power = 0;

   int k;
   for (k = 0; k < size; ++k) {
     double x2;

     x2 = pow((double) expected[k], 2);

     signal_power += x2;

     x2 = pow((double) actual[k] - expected[k], 2);

     noise_power += x2;
   }

   snr->real_snr_ = CalculateSNR(signal_power, noise_power);
   snr->imag_snr_ = -10000;
   snr->complex_snr_ = snr->real_snr_;
 }
	/*
	* Copyright (c) 2013 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include <stdio.h>
	#include <math.h>
	#include "armSP.h"
	#include "compare.h"

	extern int verbose;

	// Convert to dB
	static double Db(double x) {
	return (x <= 0) ? -1000.0 : 10 * log(x) / log(10);
	}

	static double CalculateSNR(double signal_power, double noise_power) {
	return (noise_power == 0) ? 1000 : Db(signal_power / noise_power);
	}

	/*
	* Compute the SNR of the actual signal, returning the SNR of the real
	* and imaginary parts separately, and also the overall (complex SNR)
	*/

	void CompareComplex32(struct SnrResult* snr, OMX_SC32* actual,
	OMX_SC32* expected, int size) {
	double real_signal_power = 0;
	double imag_signal_power = 0;
	double complex_signal_power = 0;
	double real_noise_power = 0;
	double imag_noise_power = 0;
	double complex_noise_power = 0;
	int k;

	for (k = 0; k < size; ++k) {
	double x2;
	double y2;
	double z2;

	if (verbose > 255) {
	printf("%4d: (%10d, %10d) (%10d, %10d)\n", k,
	actual[k].Re, actual[k].Im,
	expected[k].Re, expected[k].Im);
	}

	x2 = pow((double) expected[k].Re, 2);
	y2 = pow((double) expected[k].Im, 2);
	real_signal_power += x2;
	imag_signal_power += y2;
	complex_signal_power += x2 + y2;

	x2 = pow((double) actual[k].Re - expected[k].Re, 2);
	y2 = pow((double) actual[k].Im - expected[k].Im, 2);

	real_noise_power += x2;
	imag_noise_power += y2;
	complex_noise_power += x2 + y2;
	}

	snr->real_snr_ = CalculateSNR(real_signal_power, real_noise_power);
	snr->imag_snr_ = CalculateSNR(imag_signal_power, imag_noise_power);
	snr->complex_snr_ = CalculateSNR(complex_signal_power, complex_noise_power);
	}

	/*
	* Compute the SNR of the actual real signal, returning the SNR.
	*/

	void CompareReal32(struct SnrResult* snr, OMX_S32* actual,
	OMX_S32* expected, int size) {
	double real_signal_power = 0;
	double real_noise_power = 0;

	int k;
	for (k = 0; k < size; ++k) {
	double x2;

	x2 = pow((double) expected[k], 2);

	real_signal_power += x2;

	x2 = pow((double) actual[k] - expected[k], 2);

	real_noise_power += x2;
	}

	snr->real_snr_ = CalculateSNR(real_signal_power, real_noise_power);
	snr->imag_snr_ = -10000;
	snr->complex_snr_ = -10000;
	}

	void CompareReal16(struct SnrResult* snr, OMX_S16* actual,
	OMX_S16* expected, int size) {
	double real_signal_power = 0;
	double real_noise_power = 0;

	int k;
	for (k = 0; k < size; ++k) {
	double x2;

	x2 = pow((double) expected[k], 2);

	real_signal_power += x2;

	x2 = pow((double) actual[k] - expected[k], 2);

	real_noise_power += x2;
	}

	snr->real_snr_ = CalculateSNR(real_signal_power, real_noise_power);
	snr->imag_snr_ = -10000;
	snr->complex_snr_ = -10000;
	}

	void CompareComplexFloat(struct SnrResult* snr, OMX_FC32* actual,
	OMX_FC32* expected, int size) {
	double real_signal_power = 0;
	double imag_signal_power = 0;
	double complex_signal_power = 0;
	double real_noise_power = 0;
	double imag_noise_power = 0;
	double complex_noise_power = 0;
	int k;

	for (k = 0; k < size; ++k) {
	double x2;
	double y2;
	double z2;

	if (verbose > 255) {
	printf("%4d: (%10g, %10g) (%10g, %10g)\n", k,
	actual[k].Re, actual[k].Im,
	expected[k].Re, expected[k].Im);
	}

	x2 = pow((double) expected[k].Re, 2);
	y2 = pow((double) expected[k].Im, 2);
	real_signal_power += x2;
	imag_signal_power += y2;
	complex_signal_power += x2 + y2;

	x2 = pow((double) actual[k].Re - expected[k].Re, 2);
	y2 = pow((double) actual[k].Im - expected[k].Im, 2);

	real_noise_power += x2;
	imag_noise_power += y2;
	complex_noise_power += x2 + y2;
	}

	snr->real_snr_ = CalculateSNR(real_signal_power, real_noise_power);
	snr->imag_snr_ = CalculateSNR(imag_signal_power, imag_noise_power);
	snr->complex_snr_ = CalculateSNR(complex_signal_power, complex_noise_power);
	}

	void CompareFloat(struct SnrResult* snr, OMX_F32* actual,
	OMX_F32* expected, int size) {
	double signal_power = 0;
	double noise_power = 0;

	int k;
	for (k = 0; k < size; ++k) {
	double x2;

	x2 = pow((double) expected[k], 2);

	signal_power += x2;

	x2 = pow((double) actual[k] - expected[k], 2);

	noise_power += x2;
	}

	snr->real_snr_ = CalculateSNR(signal_power, noise_power);
	snr->imag_snr_ = -10000;
	snr->complex_snr_ = snr->real_snr_;
	}