src/sigana_ldac.c - platform/external/libldac - Git at Google

 /*
  * Copyright (C) 2003 - 2016 Sony Corporation
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "ldac.h"


 #define LDAC_TH_LOWENERGY_L _scalar(225.47)
 #define LDAC_TH_LOWENERGY_M _scalar(897.61)
 #define LDAC_TH_LOWENERGY_H _scalar(3573.44)

 #define LDAC_TH_CENTROID    _scalar(45.0)
 #define LDAC_TH_ZERODIV     _scalar(1.0e-6)

 /***************************************************************************************************
     Calculate Pseudo Spectrum and Low Band Energy
 ***************************************************************************************************/
 static SCALAR calc_mdct_pseudo_spectrum_ldac(
 SCALAR *p_spec,
 SCALAR *p_psd,
 int n)
 {
     int isp;
     SCALAR low_energy, tmp;
     SCALAR y0, y1, y2;

     {
         y1 = p_spec[0];
         y2 = p_spec[1];
         tmp = y1 * y1 + y2 * y2;
         low_energy = tmp;
         p_psd[0] = sqrt(tmp);
     }

     for (isp = 1; isp < LDAC_NSP_LOWENERGY; isp++) {
         y0 = y1;
         y1 = y2;
         y2 = p_spec[isp+1];
         tmp = y1 * y1 + (y0-y2) * (y0-y2);
         low_energy += tmp;
         p_psd[isp] = sqrt(tmp);
     }

     for (isp = LDAC_NSP_LOWENERGY; isp < n-1; isp++) {
         y0 = y1;
         y1 = y2;
         y2 = p_spec[isp+1];
         tmp = y1 * y1 + (y0-y2) * (y0-y2);
         p_psd[isp] = sqrt(tmp);
     }

     {
         tmp = y1 * y1 + y2 * y2;
         p_psd[n-1] = sqrt(tmp);
     }

     return low_energy;
 }

 /***************************************************************************************************
     Calculate Pseudo Spectrum Centroid
 ***************************************************************************************************/
 static SCALAR calc_spectral_centroid_ldac(
 SCALAR *p_spec,
 int nsp)
 {
     int isp;
     SCALAR centroid;
     SCALAR s1, s2;

     s1 = s2 = _scalar(0.0);
     for (isp = 0; isp < nsp; isp++) {
         s1 += (SCALAR)isp * *p_spec;
         s2 += *p_spec++;
     }

     if (s2 < LDAC_TH_ZERODIV) {
         centroid = _scalar(0.0);
     }
     else {
         centroid = s1 / s2;
     }

     return centroid;
 }

 /***************************************************************************************************
     Calculate Number of Zero Cross
 ***************************************************************************************************/
 static int calc_zero_cross_number_ldac(
 SCALAR *p_time,
 int n)
 {
     int i;
     int zero_cross = 0;
     SCALAR prev;

     prev = _scalar(0.0);
     for (i = 0; i < n; i++) {
         if (prev * *p_time < _scalar(0.0)) {
             zero_cross++;
         }
         prev = *p_time++;
     }

     return zero_cross;
 }

 /***************************************************************************************************
     Analyze Frame Status
 ***************************************************************************************************/
 DECLSPEC int ana_frame_status_ldac(
 SFINFO *p_sfinfo,
 int nlnn)
 {
     AC *p_ac;
     int ich;
     int nchs = p_sfinfo->cfg.ch;
     int nsmpl = npow2_ldac(nlnn+1);
     int cnt, zero_cross;
     int a_status[LDAC_PRCNCH];
     SCALAR low_energy, centroid;
     SCALAR a_psd_spec[LDAC_NSP_PSEUDOANA];

     for (ich = 0; ich < nchs; ich++) {
         p_ac = p_sfinfo->ap_ac[ich];

         low_energy = calc_mdct_pseudo_spectrum_ldac(p_ac->p_acsub->a_spec, a_psd_spec, LDAC_NSP_PSEUDOANA);

         centroid = calc_spectral_centroid_ldac(a_psd_spec, LDAC_NSP_PSEUDOANA);

         zero_cross = calc_zero_cross_number_ldac(p_ac->p_acsub->a_time, nsmpl);

         a_status[ich] = LDAC_FRMSTAT_LEV_0;
         if (low_energy < LDAC_TH_LOWENERGY_L) {
             a_status[ich] = LDAC_FRMSTAT_LEV_3;
         }
         else {
             if (low_energy < LDAC_TH_LOWENERGY_M) {
                 a_status[ich] = LDAC_FRMSTAT_LEV_2;
             }
             else if (low_energy < LDAC_TH_LOWENERGY_H) {
                 a_status[ich] = LDAC_FRMSTAT_LEV_1;
             }

             cnt = p_ac->frmana_cnt;
             if ((centroid > LDAC_TH_CENTROID) && (zero_cross >= LDAC_TH_ZCROSNUM)) {
                 cnt++;

                 if (cnt >= LDAC_MAXCNT_FRMANA) {
                     cnt = LDAC_MAXCNT_FRMANA;
                     a_status[ich] = LDAC_FRMSTAT_LEV_2;
                 }
                 else if (a_status[ich] <= LDAC_FRMSTAT_LEV_1) {
                     a_status[ich]++;
                 }
             }
             else {
                 cnt = 0;
             }
             p_ac->frmana_cnt = cnt;
         }
     }

     if (nchs == LDAC_CHANNEL_1CH) {
         return a_status[0];
     }
     else {
         return min_ldac(a_status[0], a_status[1]);
     }
 }
	/*
	* Copyright (C) 2003 - 2016 Sony Corporation
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "ldac.h"


	#define LDAC_TH_LOWENERGY_L _scalar(225.47)
	#define LDAC_TH_LOWENERGY_M _scalar(897.61)
	#define LDAC_TH_LOWENERGY_H _scalar(3573.44)

	#define LDAC_TH_CENTROID _scalar(45.0)
	#define LDAC_TH_ZERODIV _scalar(1.0e-6)

	/***************************************************************************************************
	Calculate Pseudo Spectrum and Low Band Energy
	***************************************************************************************************/
	static SCALAR calc_mdct_pseudo_spectrum_ldac(
	SCALAR *p_spec,
	SCALAR *p_psd,
	int n)
	{
	int isp;
	SCALAR low_energy, tmp;
	SCALAR y0, y1, y2;

	{
	y1 = p_spec[0];
	y2 = p_spec[1];
	tmp = y1 * y1 + y2 * y2;
	low_energy = tmp;
	p_psd[0] = sqrt(tmp);
	}

	for (isp = 1; isp < LDAC_NSP_LOWENERGY; isp++) {
	y0 = y1;
	y1 = y2;
	y2 = p_spec[isp+1];
	tmp = y1 * y1 + (y0-y2) * (y0-y2);
	low_energy += tmp;
	p_psd[isp] = sqrt(tmp);
	}

	for (isp = LDAC_NSP_LOWENERGY; isp < n-1; isp++) {
	y0 = y1;
	y1 = y2;
	y2 = p_spec[isp+1];
	tmp = y1 * y1 + (y0-y2) * (y0-y2);
	p_psd[isp] = sqrt(tmp);
	}

	{
	tmp = y1 * y1 + y2 * y2;
	p_psd[n-1] = sqrt(tmp);
	}

	return low_energy;
	}

	/***************************************************************************************************
	Calculate Pseudo Spectrum Centroid
	***************************************************************************************************/
	static SCALAR calc_spectral_centroid_ldac(
	SCALAR *p_spec,
	int nsp)
	{
	int isp;
	SCALAR centroid;
	SCALAR s1, s2;

	s1 = s2 = _scalar(0.0);
	for (isp = 0; isp < nsp; isp++) {
	s1 += (SCALAR)isp * *p_spec;
	s2 += *p_spec++;
	}

	if (s2 < LDAC_TH_ZERODIV) {
	centroid = _scalar(0.0);
	}
	else {
	centroid = s1 / s2;
	}

	return centroid;
	}

	/***************************************************************************************************
	Calculate Number of Zero Cross
	***************************************************************************************************/
	static int calc_zero_cross_number_ldac(
	SCALAR *p_time,
	int n)
	{
	int i;
	int zero_cross = 0;
	SCALAR prev;

	prev = _scalar(0.0);
	for (i = 0; i < n; i++) {
	if (prev * *p_time < _scalar(0.0)) {
	zero_cross++;
	}
	prev = *p_time++;
	}

	return zero_cross;
	}

	/***************************************************************************************************
	Analyze Frame Status
	***************************************************************************************************/
	DECLSPEC int ana_frame_status_ldac(
	SFINFO *p_sfinfo,
	int nlnn)
	{
	AC *p_ac;
	int ich;
	int nchs = p_sfinfo->cfg.ch;
	int nsmpl = npow2_ldac(nlnn+1);
	int cnt, zero_cross;
	int a_status[LDAC_PRCNCH];
	SCALAR low_energy, centroid;
	SCALAR a_psd_spec[LDAC_NSP_PSEUDOANA];

	for (ich = 0; ich < nchs; ich++) {
	p_ac = p_sfinfo->ap_ac[ich];

	low_energy = calc_mdct_pseudo_spectrum_ldac(p_ac->p_acsub->a_spec, a_psd_spec, LDAC_NSP_PSEUDOANA);

	centroid = calc_spectral_centroid_ldac(a_psd_spec, LDAC_NSP_PSEUDOANA);

	zero_cross = calc_zero_cross_number_ldac(p_ac->p_acsub->a_time, nsmpl);

	a_status[ich] = LDAC_FRMSTAT_LEV_0;
	if (low_energy < LDAC_TH_LOWENERGY_L) {
	a_status[ich] = LDAC_FRMSTAT_LEV_3;
	}
	else {
	if (low_energy < LDAC_TH_LOWENERGY_M) {
	a_status[ich] = LDAC_FRMSTAT_LEV_2;
	}
	else if (low_energy < LDAC_TH_LOWENERGY_H) {
	a_status[ich] = LDAC_FRMSTAT_LEV_1;
	}

	cnt = p_ac->frmana_cnt;
	if ((centroid > LDAC_TH_CENTROID) && (zero_cross >= LDAC_TH_ZCROSNUM)) {
	cnt++;

	if (cnt >= LDAC_MAXCNT_FRMANA) {
	cnt = LDAC_MAXCNT_FRMANA;
	a_status[ich] = LDAC_FRMSTAT_LEV_2;
	}
	else if (a_status[ich] <= LDAC_FRMSTAT_LEV_1) {
	a_status[ich]++;
	}
	}
	else {
	cnt = 0;
	}
	p_ac->frmana_cnt = cnt;
	}
	}

	if (nchs == LDAC_CHANNEL_1CH) {
	return a_status[0];
	}
	else {
	return min_ldac(a_status[0], a_status[1]);
	}
	}