From 2228e360595641dd906bf1773307f43d304f5b2e Mon Sep 17 00:00:00 2001 From: The Android Open Source Project Date: Wed, 11 Jul 2012 10:15:24 -0700 Subject: Snapshot 2bda038c163298531d47394bc2c09e1409c5d0db Change-Id: If584e579464f28b97d50e51fc76ba654a5536c54 --- libSBRenc/src/ps_encode.cpp | 1054 +++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1054 insertions(+) create mode 100644 libSBRenc/src/ps_encode.cpp (limited to 'libSBRenc/src/ps_encode.cpp') diff --git a/libSBRenc/src/ps_encode.cpp b/libSBRenc/src/ps_encode.cpp new file mode 100644 index 0000000..e60f83d --- /dev/null +++ b/libSBRenc/src/ps_encode.cpp @@ -0,0 +1,1054 @@ + +/* ----------------------------------------------------------------------------------------------------------- +Software License for The Fraunhofer FDK AAC Codec Library for Android + +© Copyright 1995 - 2012 Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V. + All rights reserved. + + 1. INTRODUCTION +The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software that implements +the MPEG Advanced Audio Coding ("AAC") encoding and decoding scheme for digital audio. +This FDK AAC Codec software is intended to be used on a wide variety of Android devices. + +AAC's HE-AAC and HE-AAC v2 versions are regarded as today's most efficient general perceptual +audio codecs. AAC-ELD is considered the best-performing full-bandwidth communications codec by +independent studies and is widely deployed. AAC has been standardized by ISO and IEC as part +of the MPEG specifications. + +Patent licenses for necessary patent claims for the FDK AAC Codec (including those of Fraunhofer) +may be obtained through Via Licensing (www.vialicensing.com) or through the respective patent owners +individually for the purpose of encoding or decoding bit streams in products that are compliant with +the ISO/IEC MPEG audio standards. Please note that most manufacturers of Android devices already license +these patent claims through Via Licensing or directly from the patent owners, and therefore FDK AAC Codec +software may already be covered under those patent licenses when it is used for those licensed purposes only. + +Commercially-licensed AAC software libraries, including floating-point versions with enhanced sound quality, +are also available from Fraunhofer. Users are encouraged to check the Fraunhofer website for additional +applications information and documentation. + +2. COPYRIGHT LICENSE + +Redistribution and use in source and binary forms, with or without modification, are permitted without +payment of copyright license fees provided that you satisfy the following conditions: + +You must retain the complete text of this software license in redistributions of the FDK AAC Codec or +your modifications thereto in source code form. + +You must retain the complete text of this software license in the documentation and/or other materials +provided with redistributions of the FDK AAC Codec or your modifications thereto in binary form. +You must make available free of charge copies of the complete source code of the FDK AAC Codec and your +modifications thereto to recipients of copies in binary form. + +The name of Fraunhofer may not be used to endorse or promote products derived from this library without +prior written permission. + +You may not charge copyright license fees for anyone to use, copy or distribute the FDK AAC Codec +software or your modifications thereto. + +Your modified versions of the FDK AAC Codec must carry prominent notices stating that you changed the software +and the date of any change. For modified versions of the FDK AAC Codec, the term +"Fraunhofer FDK AAC Codec Library for Android" must be replaced by the term +"Third-Party Modified Version of the Fraunhofer FDK AAC Codec Library for Android." + +3. NO PATENT LICENSE + +NO EXPRESS OR IMPLIED LICENSES TO ANY PATENT CLAIMS, including without limitation the patents of Fraunhofer, +ARE GRANTED BY THIS SOFTWARE LICENSE. Fraunhofer provides no warranty of patent non-infringement with +respect to this software. + +You may use this FDK AAC Codec software or modifications thereto only for purposes that are authorized +by appropriate patent licenses. + +4. DISCLAIMER + +This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors +"AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, including but not limited to the implied warranties +of merchantability and fitness for a particular purpose. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR +CONTRIBUTORS BE LIABLE for any direct, indirect, incidental, special, exemplary, or consequential damages, +including but not limited to procurement of substitute goods or services; loss of use, data, or profits, +or business interruption, however caused and on any theory of liability, whether in contract, strict +liability, or tort (including negligence), arising in any way out of the use of this software, even if +advised of the possibility of such damage. + +5. CONTACT INFORMATION + +Fraunhofer Institute for Integrated Circuits IIS +Attention: Audio and Multimedia Departments - FDK AAC LL +Am Wolfsmantel 33 +91058 Erlangen, Germany + +www.iis.fraunhofer.de/amm +amm-info@iis.fraunhofer.de +----------------------------------------------------------------------------------------------------------- */ + +/***************************** MPEG Audio Encoder *************************** + + Initial Authors: M. Neuendorf, N. Rettelbach, M. Multrus + Contents/Description: PS parameter extraction, encoding + +******************************************************************************/ +/*! + \file + \brief PS parameter extraction, encoding functions +*/ + +#include "ps_main.h" + + +#include "sbr_ram.h" +#include "ps_encode.h" + +#include "qmf.h" + +#include "ps_const.h" +#include "sbr_misc.h" + +#include "genericStds.h" + +inline void FDKsbrEnc_addFIXP_DBL(const FIXP_DBL *X, const FIXP_DBL *Y, FIXP_DBL *Z, INT n) +{ + for (INT i=0; i>1) + (Y[i]>>1); +} + +#define LOG10_2_10 3.01029995664f /* 10.0f*log10(2.f) */ + +static const INT iidGroupBordersLoRes[QMF_GROUPS_LO_RES + SUBQMF_GROUPS_LO_RES + 1] = +{ + 0, 1, 2, 3, 4, 5, /* 6 subqmf subbands - 0th qmf subband */ + 6, 7, /* 2 subqmf subbands - 1st qmf subband */ + 8, 9, /* 2 subqmf subbands - 2nd qmf subband */ + 10, 11, 12, 13, 14, 15, 16, 18, 21, 25, 30, 42, 71 +}; + +static const UCHAR iidGroupWidthLdLoRes[QMF_GROUPS_LO_RES + SUBQMF_GROUPS_LO_RES] = +{ + 0, 0, 0, 0, 0, 0, + 0, 0, + 0, 0, + 0, 0, 0, 0, 0, 0, 1, 2, 2, 3, 4, 5 +}; + + +static const INT subband2parameter20[QMF_GROUPS_LO_RES + SUBQMF_GROUPS_LO_RES] = +{ + 1, 0, 0, 1, 2, 3, /* 6 subqmf subbands - 0th qmf subband */ + 4, 5, /* 2 subqmf subbands - 1st qmf subband */ + 6, 7, /* 2 subqmf subbands - 2nd qmf subband */ + 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19 +}; + + +typedef enum { + MAX_TIME_DIFF_FRAMES = 20, + MAX_PS_NOHEADER_CNT = 10, + MAX_NOENV_CNT = 10, + DO_NOT_USE_THIS_MODE = 0x7FFFFF +} __PS_CONSTANTS; + + + +static const FIXP_DBL iidQuant_fx[15] = { + 0xce000000, 0xdc000000, 0xe4000000, 0xec000000, 0xf2000000, 0xf8000000, 0xfc000000, 0x00000000, + 0x04000000, 0x08000000, 0x0e000000, 0x14000000, 0x1c000000, 0x24000000, 0x32000000 +}; + +static const FIXP_DBL iidQuantFine_fx[31] = { + 0x9c000001, 0xa6000001, 0xb0000001, 0xba000001, 0xc4000000, 0xce000000, 0xd4000000, 0xda000000, + 0xe0000000, 0xe6000000, 0xec000000, 0xf0000000, 0xf4000000, 0xf8000000, 0xfc000000, 0x00000000, + 0x04000000, 0x08000000, 0x0c000000, 0x10000000, 0x14000000, 0x1a000000, 0x20000000, 0x26000000, + 0x2c000000, 0x32000000, 0x3c000000, 0x45ffffff, 0x4fffffff, 0x59ffffff, 0x63ffffff +}; + + + +static const FIXP_DBL iccQuant[8] = { + 0x7fffffff, 0x77ef9d7f, 0x6babc97f, 0x4ceaf27f, 0x2f0ed3c0, 0x00000000, 0xb49ba601, 0x80000000 +}; + +static FDK_PSENC_ERROR InitPSData( + HANDLE_PS_DATA hPsData + ) +{ + FDK_PSENC_ERROR error = PSENC_OK; + + if(hPsData == NULL) { + error = PSENC_INVALID_HANDLE; + } + else { + int i, env; + FDKmemclear(hPsData,sizeof(PS_DATA)); + + for (i=0; iiidIdxLast[i] = 0; + hPsData->iccIdxLast[i] = 0; + } + + hPsData->iidEnable = hPsData->iidEnableLast = 0; + hPsData->iccEnable = hPsData->iccEnableLast = 0; + hPsData->iidQuantMode = hPsData->iidQuantModeLast = PS_IID_RES_COARSE; + hPsData->iccQuantMode = hPsData->iccQuantModeLast = PS_ICC_ROT_A; + + for(env=0; enviccDiffMode[env] = PS_DELTA_FREQ; + hPsData->iccDiffMode[env] = PS_DELTA_FREQ; + + for (i=0; iiidIdx[env][i] = 0; + hPsData->iccIdx[env][i] = 0; + } + } + + hPsData->nEnvelopesLast = 0; + + hPsData->headerCnt = MAX_PS_NOHEADER_CNT; + hPsData->iidTimeCnt = MAX_TIME_DIFF_FRAMES; + hPsData->iccTimeCnt = MAX_TIME_DIFF_FRAMES; + hPsData->noEnvCnt = MAX_NOENV_CNT; + } + + return error; +} + +static FIXP_DBL quantizeCoef( const FIXP_DBL *RESTRICT input, + const INT nBands, + const FIXP_DBL *RESTRICT quantTable, + const INT idxOffset, + const INT nQuantSteps, + INT *RESTRICT quantOut) +{ + INT idx, band; + FIXP_DBL quantErr = FL2FXCONST_DBL(0.f); + + for (band=0; band>1)-(quantTable[idx+1]>>1)) > + fixp_abs((input[band]>>1)-(quantTable[idx]>>1)) ) + { + break; + } + } + quantErr += (fixp_abs(input[band]-quantTable[idx])>>PS_QUANT_SCALE); /* don't scale before subtraction; diff smaller (64-25)/64 */ + quantOut[band] = idx - idxOffset; + } + + return quantErr; +} + +static INT getICCMode(const INT nBands, + const INT rotType) +{ + INT mode = 0; + + switch(nBands) { + case PS_BANDS_COARSE: + mode = PS_RES_COARSE; + break; + case PS_BANDS_MID: + mode = PS_RES_MID; + break; + default: + mode = 0; + } + if(rotType==PS_ICC_ROT_B){ + mode += 3; + } + + return mode; +} + + +static INT getIIDMode(const INT nBands, + const INT iidRes) +{ + INT mode = 0; + + switch(nBands) { + case PS_BANDS_COARSE: + mode = PS_RES_COARSE; + break; + case PS_BANDS_MID: + mode = PS_RES_MID; + break; + default: + mode = 0; + break; + } + + if(iidRes == PS_IID_RES_FINE){ + mode += 3; + } + + return mode; +} + + +static INT envelopeReducible(FIXP_DBL iid[PS_MAX_ENVELOPES][PS_MAX_BANDS], + FIXP_DBL icc[PS_MAX_ENVELOPES][PS_MAX_BANDS], + INT psBands, + INT nEnvelopes) +{ + #define THRESH_SCALE 7 + + INT reducible = 1; /* true */ + INT e = 0, b = 0; + FIXP_DBL dIid = FL2FXCONST_DBL(0.f); + FIXP_DBL dIcc = FL2FXCONST_DBL(0.f); + + FIXP_DBL iidErrThreshold, iccErrThreshold; + FIXP_DBL iidMeanError, iccMeanError; + + /* square values to prevent sqrt, + multiply bands to prevent division; bands shifted DFRACT_BITS instead (DFRACT_BITS-1) because fMultDiv2 used*/ + iidErrThreshold = fMultDiv2 ( FL2FXCONST_DBL(6.5f*6.5f/(IID_SCALE_FT*IID_SCALE_FT)), (FIXP_DBL)(psBands<<((DFRACT_BITS)-THRESH_SCALE)) ); + iccErrThreshold = fMultDiv2 ( FL2FXCONST_DBL(0.75f*0.75f), (FIXP_DBL)(psBands<<((DFRACT_BITS)-THRESH_SCALE)) ); + + if (nEnvelopes <= 1) { + reducible = 0; + } else { + + /* mean error criterion */ + for (e=0; (e < nEnvelopes/2) && (reducible!=0 ) ; e++) { + iidMeanError = iccMeanError = FL2FXCONST_DBL(0.f); + for(b=0; b>1) - (iid[2*e+1][b]>>1); /* scale 1 bit; squared -> 2 bit */ + dIcc = (icc[2*e][b]>>1) - (icc[2*e+1][b]>>1); + iidMeanError += fPow2Div2(dIid)>>(5-1); /* + (bands=20) scale = 5 */ + iccMeanError += fPow2Div2(dIcc)>>(5-1); + } /* --> scaling = 7 bit = THRESH_SCALE !! */ + + /* instead sqrt values are squared! + instead of division, multiply threshold with psBands + scaling necessary!! */ + + /* quit as soon as threshold is reached */ + if ( (iidMeanError > (iidErrThreshold)) || + (iccMeanError > (iccErrThreshold)) ) { + reducible = 0; + } + } + } /* nEnvelopes != 1 */ + + return reducible; +} + + +static void processIidData(PS_DATA *psData, + FIXP_DBL iid[PS_MAX_ENVELOPES][PS_MAX_BANDS], + const INT psBands, + const INT nEnvelopes, + const FIXP_DBL quantErrorThreshold) +{ + INT iidIdxFine [PS_MAX_ENVELOPES][PS_MAX_BANDS]; + INT iidIdxCoarse[PS_MAX_ENVELOPES][PS_MAX_BANDS]; + + FIXP_DBL errIID = FL2FXCONST_DBL(0.f); + FIXP_DBL errIIDFine = FL2FXCONST_DBL(0.f); + INT bitsIidFreq = 0; + INT bitsIidTime = 0; + INT bitsFineTot = 0; + INT bitsCoarseTot = 0; + INT error = 0; + INT env, band; + INT diffMode[PS_MAX_ENVELOPES], diffModeFine[PS_MAX_ENVELOPES]; + INT loudnDiff = 0; + INT iidTransmit = 0; + + bitsIidFreq = bitsIidTime = 0; + + /* Quantize IID coefficients */ + for(env=0;enviidEnable = 0; + for(env=0;env fMultI(FL2FXCONST_DBL(0.7f),iidTransmit)){ /* 0.7f empiric value */ + psData->iidEnable = 1; + } + + /* if iid not active -> RESET data */ + if(psData->iidEnable==0) { + psData->iidTimeCnt = MAX_TIME_DIFF_FRAMES; + for(env=0;enviidDiffMode[env] = PS_DELTA_FREQ; + FDKmemclear(psData->iidIdx[env], sizeof(INT)*psBands); + } + return; + } + + /* count COARSE quantization bits for first envelope*/ + bitsIidFreq = FDKsbrEnc_EncodeIid(NULL, iidIdxCoarse[0], NULL, psBands, PS_IID_RES_COARSE, PS_DELTA_FREQ, &error); + + if( (psData->iidTimeCnt>=MAX_TIME_DIFF_FRAMES) || (psData->iidQuantModeLast==PS_IID_RES_FINE) ) { + bitsIidTime = DO_NOT_USE_THIS_MODE; + } + else { + bitsIidTime = FDKsbrEnc_EncodeIid(NULL, iidIdxCoarse[0], psData->iidIdxLast, psBands, PS_IID_RES_COARSE, PS_DELTA_TIME, &error); + } + + /* decision DELTA_FREQ vs DELTA_TIME */ + if(bitsIidTime>bitsIidFreq) { + diffMode[0] = PS_DELTA_FREQ; + bitsCoarseTot = bitsIidFreq; + } + else { + diffMode[0] = PS_DELTA_TIME; + bitsCoarseTot = bitsIidTime; + } + + /* count COARSE quantization bits for following envelopes*/ + for(env=1;envbitsIidFreq) { + diffMode[env] = PS_DELTA_FREQ; + bitsCoarseTot += bitsIidFreq; + } + else { + diffMode[env] = PS_DELTA_TIME; + bitsCoarseTot += bitsIidTime; + } + } + + + /* count FINE quantization bits for first envelope*/ + bitsIidFreq = FDKsbrEnc_EncodeIid(NULL, iidIdxFine[0], NULL, psBands, PS_IID_RES_FINE, PS_DELTA_FREQ, &error); + + if( (psData->iidTimeCnt>=MAX_TIME_DIFF_FRAMES) || (psData->iidQuantModeLast==PS_IID_RES_COARSE) ) { + bitsIidTime = DO_NOT_USE_THIS_MODE; + } + else { + bitsIidTime = FDKsbrEnc_EncodeIid(NULL, iidIdxFine[0], psData->iidIdxLast, psBands, PS_IID_RES_FINE, PS_DELTA_TIME, &error); + } + + /* decision DELTA_FREQ vs DELTA_TIME */ + if(bitsIidTime>bitsIidFreq) { + diffModeFine[0] = PS_DELTA_FREQ; + bitsFineTot = bitsIidFreq; + } + else { + diffModeFine[0] = PS_DELTA_TIME; + bitsFineTot = bitsIidTime; + } + + /* count FINE quantization bits for following envelopes*/ + for(env=1;envbitsIidFreq) { + diffModeFine[env] = PS_DELTA_FREQ; + bitsFineTot += bitsIidFreq; + } + else { + diffModeFine[env] = PS_DELTA_TIME; + bitsFineTot += bitsIidTime; + } + } + + if(bitsFineTot == bitsCoarseTot){ + /* if same number of bits is needed, use the quantization with lower error */ + if(errIIDFine < errIID){ + bitsCoarseTot = DO_NOT_USE_THIS_MODE; + } else { + bitsFineTot = DO_NOT_USE_THIS_MODE; + } + } else { + /* const FIXP_DBL minThreshold = FL2FXCONST_DBL(0.2f/(IID_SCALE_FT*PS_QUANT_SCALE_FT)*(psBands*nEnvelopes)); */ + const FIXP_DBL minThreshold = (FIXP_DBL)((LONG)0x00019999 * (psBands*nEnvelopes)); + + /* decision RES_FINE vs RES_COARSE */ + /* test if errIIDFine*quantErrorThreshold < errIID */ + /* shiftVal 2 comes from scaling of quantErrorThreshold */ + if(fixMax(((errIIDFine>>1)+(minThreshold>>1))>>1, fMult(quantErrorThreshold,errIIDFine)) < (errIID>>2) ) { + bitsCoarseTot = DO_NOT_USE_THIS_MODE; + } + else if(fixMax(((errIID>>1)+(minThreshold>>1))>>1, fMult(quantErrorThreshold,errIID)) < (errIIDFine>>2) ) { + bitsFineTot = DO_NOT_USE_THIS_MODE; + } + } + + /* decision RES_FINE vs RES_COARSE */ + if(bitsFineTotiidQuantMode = PS_IID_RES_FINE; + for(env=0;enviidDiffMode[env] = diffModeFine[env]; + FDKmemcpy(psData->iidIdx[env], iidIdxFine[env], psBands*sizeof(INT)); + } + } + else { + psData->iidQuantMode = PS_IID_RES_COARSE; + for(env=0;enviidDiffMode[env] = diffMode[env]; + FDKmemcpy(psData->iidIdx[env], iidIdxCoarse[env], psBands*sizeof(INT)); + } + } + + /* Count DELTA_TIME encoding streaks */ + for(env=0;enviidDiffMode[env]==PS_DELTA_TIME) + psData->iidTimeCnt++; + else + psData->iidTimeCnt=0; + } +} + + +static INT similarIid(PS_DATA *psData, + const INT psBands, + const INT nEnvelopes) +{ + const INT diffThr = (psData->iidQuantMode == PS_IID_RES_COARSE) ? 2 : 3; + const INT sumDiffThr = diffThr * psBands/4; + INT similar = 0; + INT diff = 0; + INT sumDiff = 0; + INT env = 0; + INT b = 0; + if ((nEnvelopes == psData->nEnvelopesLast) && (nEnvelopes==1)) { + similar = 1; + for (env=0; enviidIdx[env][b] - psData->iidIdxLast[b]); + sumDiff += diff; + if ( (diff > diffThr) /* more than x quantization steps in any band */ + || (sumDiff > sumDiffThr) ) { /* more than x quantisations steps overall difference */ + similar = 0; + } + b++; + } while ((b0)); + } + } /* nEnvelopes==1 */ + + return similar; +} + + +static INT similarIcc(PS_DATA *psData, + const INT psBands, + const INT nEnvelopes) +{ + const INT diffThr = 2; + const INT sumDiffThr = diffThr * psBands/4; + INT similar = 0; + INT diff = 0; + INT sumDiff = 0; + INT env = 0; + INT b = 0; + if ((nEnvelopes == psData->nEnvelopesLast) && (nEnvelopes==1)) { + similar = 1; + for (env=0; enviccIdx[env][b] - psData->iccIdxLast[b]); + sumDiff += diff; + if ( (diff > diffThr) /* more than x quantisation step in any band */ + || (sumDiff > sumDiffThr) ) { /* more than x quantisations steps overall difference */ + similar = 0; + } + b++; + } while ((b0)); + } + } /* nEnvelopes==1 */ + + return similar; +} + +static void processIccData(PS_DATA *psData, + FIXP_DBL icc[PS_MAX_ENVELOPES][PS_MAX_BANDS], /* const input values: unable to declare as const, since it does not poINT to const memory */ + const INT psBands, + const INT nEnvelopes) +{ + FIXP_DBL errICC = FL2FXCONST_DBL(0.f); + INT env, band; + INT bitsIccFreq, bitsIccTime; + INT error = 0; + INT inCoherence=0, iccTransmit=0; + INT *iccIdxLast; + + iccIdxLast = psData->iccIdxLast; + + /* Quantize ICC coefficients */ + for(env=0;enviccIdx[env]); + } + + /* Check if ICC coefficients should be used */ + psData->iccEnable = 0; + for(env=0;enviccIdx[env][band]; + iccTransmit ++; + } + } + if(inCoherence > fMultI(FL2FXCONST_DBL(0.5f),iccTransmit)){ /* 0.5f empiric value */ + psData->iccEnable = 1; + } + + if(psData->iccEnable==0) { + psData->iccTimeCnt = MAX_TIME_DIFF_FRAMES; + for(env=0;enviccDiffMode[env] = PS_DELTA_FREQ; + FDKmemclear(psData->iccIdx[env], sizeof(INT)*psBands); + } + return; + } + + for(env=0;enviccIdx[env], NULL, psBands, PS_DELTA_FREQ, &error); + + if(psData->iccTimeCnticcIdx[env], iccIdxLast, psBands, PS_DELTA_TIME, &error); + } + else { + bitsIccTime = DO_NOT_USE_THIS_MODE; + } + + if(bitsIccFreq>bitsIccTime) { + psData->iccDiffMode[env] = PS_DELTA_TIME; + psData->iccTimeCnt++; + } + else { + psData->iccDiffMode[env] = PS_DELTA_FREQ; + psData->iccTimeCnt=0; + } + iccIdxLast = psData->iccIdx[env]; + } +} + +static void calculateIID(FIXP_DBL ldPwrL[PS_MAX_ENVELOPES][PS_MAX_BANDS], + FIXP_DBL ldPwrR[PS_MAX_ENVELOPES][PS_MAX_BANDS], + FIXP_DBL iid[PS_MAX_ENVELOPES][PS_MAX_BANDS], + INT nEnvelopes, + INT psBands) +{ + INT i=0; + INT env=0; + for(env=0; env>(LD_DATA_SHIFT+1)) ); + IID = fixMax( IID, (FIXP_DBL)(MINVAL_DBL>>(LD_DATA_SHIFT+1)) ); + iid[env][i] = IID << (LD_DATA_SHIFT+1); + } + } +} + +static void calculateICC(FIXP_DBL ldPwrL[PS_MAX_ENVELOPES][PS_MAX_BANDS], + FIXP_DBL ldPwrR[PS_MAX_ENVELOPES][PS_MAX_BANDS], + FIXP_DBL pwrCr[PS_MAX_ENVELOPES][PS_MAX_BANDS], + FIXP_DBL pwrCi[PS_MAX_ENVELOPES][PS_MAX_BANDS], + FIXP_DBL icc[PS_MAX_ENVELOPES][PS_MAX_BANDS], + INT nEnvelopes, + INT psBands) +{ + INT i = 0; + INT env = 0; + INT border = psBands; + + switch (psBands) { + case PS_BANDS_COARSE: + border = 5; + break; + case PS_BANDS_MID: + border = 11; + break; + default: + break; + } + + for(env=0; env>1) + (ldPwrR[env][i]>>1) + (FIXP_DBL)1) ); + INT scale, invScale = CountLeadingBits(invNrg); + + scale = (DFRACT_BITS-1) - invScale; + ICC = fMult(pwrCr[env][i], invNrg<>1)>>1) - (FIXP_DBL)((sc1-1)<<(DFRACT_BITS-1-LD_DATA_SHIFT)) ); + + FIXP_DBL invNrg = CalcInvLdData ( -((ldPwrL[env][i]>>1) + (ldPwrR[env][i]>>1) + (FIXP_DBL)1) ); + sc1 = CountLeadingBits(invNrg); + invNrg <<= sc1; + + sc2 = CountLeadingBits(ICC); + ICC = fMult(ICC<>= -sc1; + } + else { + if (ICC >= ((FIXP_DBL)MAXVAL_DBL>>sc1) ) + ICC = (FIXP_DBL)MAXVAL_DBL; + else + ICC <<= sc1; + } + + icc[env][i] = ICC; + } + } +} + +void FDKsbrEnc_initPsBandNrgScale(HANDLE_PS_ENCODE hPsEncode) +{ + INT group, bin; + INT nIidGroups = hPsEncode->nQmfIidGroups + hPsEncode->nSubQmfIidGroups; + + FDKmemclear(hPsEncode->psBandNrgScale, PS_MAX_BANDS*sizeof(SCHAR)); + + for (group=0; group < nIidGroups; group++) { + /* Translate group to bin */ + bin = hPsEncode->subband2parameterIndex[group]; + + /* Translate from 20 bins to 10 bins */ + if (hPsEncode->psEncMode == PS_BANDS_COARSE) { + bin = bin>>1; + } + + hPsEncode->psBandNrgScale[bin] = (hPsEncode->psBandNrgScale[bin]==0) + ? (hPsEncode->iidGroupWidthLd[group] + 5) + : (fixMax(hPsEncode->iidGroupWidthLd[group],hPsEncode->psBandNrgScale[bin]) + 1) ; + + } +} + +FDK_PSENC_ERROR FDKsbrEnc_CreatePSEncode( + HANDLE_PS_ENCODE *phPsEncode + ) +{ + FDK_PSENC_ERROR error = PSENC_OK; + + if (phPsEncode==NULL) { + error = PSENC_INVALID_HANDLE; + } + else { + HANDLE_PS_ENCODE hPsEncode = NULL; + if (NULL==(hPsEncode = GetRam_PsEncode())) { + error = PSENC_MEMORY_ERROR; + goto bail; + } + FDKmemclear(hPsEncode,sizeof(PS_ENCODE)); + *phPsEncode = hPsEncode; /* return allocated handle */ + } +bail: + return error; +} + +FDK_PSENC_ERROR FDKsbrEnc_InitPSEncode( + HANDLE_PS_ENCODE hPsEncode, + const PS_BANDS psEncMode, + const FIXP_DBL iidQuantErrorThreshold + ) +{ + FDK_PSENC_ERROR error = PSENC_OK; + + if (NULL==hPsEncode) { + error = PSENC_INVALID_HANDLE; + } + else { + if (PSENC_OK != (InitPSData(&hPsEncode->psData))) { + goto bail; + } + + switch(psEncMode){ + case PS_BANDS_COARSE: + case PS_BANDS_MID: + hPsEncode->nQmfIidGroups = QMF_GROUPS_LO_RES; + hPsEncode->nSubQmfIidGroups = SUBQMF_GROUPS_LO_RES; + FDKmemcpy(hPsEncode->iidGroupBorders, iidGroupBordersLoRes, (hPsEncode->nQmfIidGroups + hPsEncode->nSubQmfIidGroups + 1)*sizeof(INT)); + FDKmemcpy(hPsEncode->subband2parameterIndex, subband2parameter20, (hPsEncode->nQmfIidGroups + hPsEncode->nSubQmfIidGroups) *sizeof(INT)); + FDKmemcpy(hPsEncode->iidGroupWidthLd, iidGroupWidthLdLoRes, (hPsEncode->nQmfIidGroups + hPsEncode->nSubQmfIidGroups) *sizeof(UCHAR)); + break; + default: + error = PSENC_INIT_ERROR; + goto bail; + } + + hPsEncode->psEncMode = psEncMode; + hPsEncode->iidQuantErrorThreshold = iidQuantErrorThreshold; + FDKsbrEnc_initPsBandNrgScale(hPsEncode); + } +bail: + return error; +} + + +FDK_PSENC_ERROR FDKsbrEnc_DestroyPSEncode( + HANDLE_PS_ENCODE *phPsEncode + ) +{ + FDK_PSENC_ERROR error = PSENC_OK; + + if (NULL !=phPsEncode) { + FreeRam_PsEncode(phPsEncode); + } + + return error; +} + +typedef struct { + FIXP_DBL pwrL[PS_MAX_ENVELOPES][PS_MAX_BANDS]; + FIXP_DBL pwrR[PS_MAX_ENVELOPES][PS_MAX_BANDS]; + FIXP_DBL ldPwrL[PS_MAX_ENVELOPES][PS_MAX_BANDS]; + FIXP_DBL ldPwrR[PS_MAX_ENVELOPES][PS_MAX_BANDS]; + FIXP_DBL pwrCr[PS_MAX_ENVELOPES][PS_MAX_BANDS]; + FIXP_DBL pwrCi[PS_MAX_ENVELOPES][PS_MAX_BANDS]; + +} PS_PWR_DATA; + + +FDK_PSENC_ERROR FDKsbrEnc_PSEncode( + HANDLE_PS_ENCODE hPsEncode, + HANDLE_PS_OUT hPsOut, + UCHAR *dynBandScale, + UINT maxEnvelopes, + FIXP_DBL *hybridData[HYBRID_FRAMESIZE][MAX_PS_CHANNELS][2], + const INT frameSize, + const INT sendHeader + ) +{ + FDK_PSENC_ERROR error = PSENC_OK; + + HANDLE_PS_DATA hPsData = &hPsEncode->psData; + FIXP_DBL iid [PS_MAX_ENVELOPES][PS_MAX_BANDS]; + FIXP_DBL icc [PS_MAX_ENVELOPES][PS_MAX_BANDS]; + int envBorder[PS_MAX_ENVELOPES+1]; + + int group, bin, col, subband, band; + int i = 0; + + int env = 0; + int psBands = (int) hPsEncode->psEncMode; + int nIidGroups = hPsEncode->nQmfIidGroups + hPsEncode->nSubQmfIidGroups; + int nEnvelopes = fixMin(maxEnvelopes, (UINT)PS_MAX_ENVELOPES); + + C_ALLOC_SCRATCH_START(pwrData, PS_PWR_DATA, 1); + + for(env=0; envpwrL[env][band] = pwrData->pwrR[env][band] = pwrData->pwrCr[env][band] = pwrData->pwrCi[env][band] = FIXP_DBL(1); + } + + /**** calculate energies and correlation ****/ + + /* start with hybrid data */ + for (group=0; group < nIidGroups; group++) { + /* Translate group to bin */ + bin = hPsEncode->subband2parameterIndex[group]; + + /* Translate from 20 bins to 10 bins */ + if (hPsEncode->psEncMode == PS_BANDS_COARSE) { + bin >>= 1; + } + + /* determine group border */ + int bScale = hPsEncode->psBandNrgScale[bin]; + + FIXP_DBL pwrL_env_bin = pwrData->pwrL[env][bin]; + FIXP_DBL pwrR_env_bin = pwrData->pwrR[env][bin]; + FIXP_DBL pwrCr_env_bin = pwrData->pwrCr[env][bin]; + FIXP_DBL pwrCi_env_bin = pwrData->pwrCi[env][bin]; + + int scale = (int)dynBandScale[bin]; + for (col=envBorder[env]; coliidGroupBorders[group]; subband < hPsEncode->iidGroupBorders[group+1]; subband++) { + FIXP_QMF l_real = (hybridData[col][0][0][subband]) << scale; + FIXP_QMF l_imag = (hybridData[col][0][1][subband]) << scale; + FIXP_QMF r_real = (hybridData[col][1][0][subband]) << scale; + FIXP_QMF r_imag = (hybridData[col][1][1][subband]) << scale; + + pwrL_env_bin += (fPow2Div2(l_real) + fPow2Div2(l_imag)) >> bScale; + pwrR_env_bin += (fPow2Div2(r_real) + fPow2Div2(r_imag)) >> bScale; + pwrCr_env_bin += (fMultDiv2(l_real, r_real) + fMultDiv2(l_imag, r_imag)) >> bScale; + pwrCi_env_bin += (fMultDiv2(r_real, l_imag) - fMultDiv2(l_real, r_imag)) >> bScale; + } + } + /* assure, nrg's of left and right channel are not negative; necessary on 16 bit multiply units */ + pwrData->pwrL[env][bin] = fixMax((FIXP_DBL)0,pwrL_env_bin); + pwrData->pwrR[env][bin] = fixMax((FIXP_DBL)0,pwrR_env_bin); + + pwrData->pwrCr[env][bin] = pwrCr_env_bin; + pwrData->pwrCi[env][bin] = pwrCi_env_bin; + + } /* nIidGroups */ + + /* calc logarithmic energy */ + LdDataVector(pwrData->pwrL[env], pwrData->ldPwrL[env], psBands); + LdDataVector(pwrData->pwrR[env], pwrData->ldPwrR[env], psBands); + + } /* nEnvelopes */ + + /* calculate iid and icc */ + calculateIID(pwrData->ldPwrL, pwrData->ldPwrR, iid, nEnvelopes, psBands); + calculateICC(pwrData->ldPwrL, pwrData->ldPwrR, pwrData->pwrCr, pwrData->pwrCi, icc, nEnvelopes, psBands); + + /*** Envelope Reduction ***/ + while (envelopeReducible(iid,icc,psBands,nEnvelopes)) { + int e=0; + /* sum energies of two neighboring envelopes */ + nEnvelopes >>= 1; + for (e=0; epwrL[2*e], pwrData->pwrL[2*e+1], pwrData->pwrL[e], psBands); + FDKsbrEnc_addFIXP_DBL(pwrData->pwrR[2*e], pwrData->pwrR[2*e+1], pwrData->pwrR[e], psBands); + FDKsbrEnc_addFIXP_DBL(pwrData->pwrCr[2*e],pwrData->pwrCr[2*e+1],pwrData->pwrCr[e],psBands); + FDKsbrEnc_addFIXP_DBL(pwrData->pwrCi[2*e],pwrData->pwrCi[2*e+1],pwrData->pwrCi[e],psBands); + + /* calc logarithmic energy */ + LdDataVector(pwrData->pwrL[e], pwrData->ldPwrL[e], psBands); + LdDataVector(pwrData->pwrR[e], pwrData->ldPwrR[e], psBands); + + /* reduce number of envelopes and adjust borders */ + envBorder[e] = envBorder[2*e]; + } + envBorder[nEnvelopes] = envBorder[2*nEnvelopes]; + + /* re-calculate iid and icc */ + calculateIID(pwrData->ldPwrL, pwrData->ldPwrR, iid, nEnvelopes, psBands); + calculateICC(pwrData->ldPwrL, pwrData->ldPwrR, pwrData->pwrCr, pwrData->pwrCi, icc, nEnvelopes, psBands); + } + + + /* */ + if(sendHeader) { + hPsData->headerCnt = MAX_PS_NOHEADER_CNT; + hPsData->iidTimeCnt = MAX_TIME_DIFF_FRAMES; + hPsData->iccTimeCnt = MAX_TIME_DIFF_FRAMES; + hPsData->noEnvCnt = MAX_NOENV_CNT; + } + + /*** Parameter processing, quantisation etc ***/ + processIidData(hPsData, iid, psBands, nEnvelopes, hPsEncode->iidQuantErrorThreshold); + processIccData(hPsData, icc, psBands, nEnvelopes); + + + /*** Initialize output struct ***/ + + /* PS Header on/off ? */ + if( (hPsData->headerCntiidQuantMode == hPsData->iidQuantModeLast) && (hPsData->iccQuantMode == hPsData->iccQuantModeLast) ) + && ( (hPsData->iidEnable == hPsData->iidEnableLast) && (hPsData->iccEnable == hPsData->iccEnableLast) ) ) { + hPsOut->enablePSHeader = 0; + } + else { + hPsOut->enablePSHeader = 1; + hPsData->headerCnt = 0; + } + + /* nEnvelopes = 0 ? */ + if ( (hPsData->noEnvCnt < MAX_NOENV_CNT) + && (similarIid(hPsData, psBands, nEnvelopes)) + && (similarIcc(hPsData, psBands, nEnvelopes)) ) { + hPsOut->nEnvelopes = nEnvelopes = 0; + hPsData->noEnvCnt++; + } else { + hPsData->noEnvCnt = 0; + } + + + if (nEnvelopes>0) { + + hPsOut->enableIID = hPsData->iidEnable; + hPsOut->iidMode = getIIDMode(psBands, hPsData->iidQuantMode); + + hPsOut->enableICC = hPsData->iccEnable; + hPsOut->iccMode = getICCMode(psBands, hPsData->iccQuantMode); + + hPsOut->enableIpdOpd = 0; + hPsOut->frameClass = 0; + hPsOut->nEnvelopes = nEnvelopes; + + for(env=0; envframeBorder[env] = envBorder[env+1]; + } + + for(env=0; envnEnvelopes; env++) { + hPsOut->deltaIID[env] = (PS_DELTA)hPsData->iidDiffMode[env]; + + for(band=0; bandiid[env][band] = hPsData->iidIdx[env][band]; + } + } + + for(env=0; envnEnvelopes; env++) { + hPsOut->deltaICC[env] = (PS_DELTA)hPsData->iccDiffMode[env]; + for(band=0; bandicc[env][band] = hPsData->iccIdx[env][band]; + } + } + + /* IPD OPD not supported right now */ + FDKmemclear(hPsOut->ipd, PS_MAX_ENVELOPES*PS_MAX_BANDS*sizeof(PS_DELTA)); + for(env=0; envdeltaIPD[env] = PS_DELTA_FREQ; + hPsOut->deltaOPD[env] = PS_DELTA_FREQ; + } + + FDKmemclear(hPsOut->ipdLast, PS_MAX_BANDS*sizeof(INT)); + FDKmemclear(hPsOut->opdLast, PS_MAX_BANDS*sizeof(INT)); + + for(band=0; bandiidLast[band] = hPsData->iidIdxLast[band]; + hPsOut->iccLast[band] = hPsData->iccIdxLast[band]; + } + + /* save iids and iccs for differential time coding in the next frame */ + hPsData->nEnvelopesLast = nEnvelopes; + hPsData->iidEnableLast = hPsData->iidEnable; + hPsData->iccEnableLast = hPsData->iccEnable; + hPsData->iidQuantModeLast = hPsData->iidQuantMode; + hPsData->iccQuantModeLast = hPsData->iccQuantMode; + for (i=0; iiidIdxLast[i] = hPsData->iidIdx[nEnvelopes-1][i]; + hPsData->iccIdxLast[i] = hPsData->iccIdx[nEnvelopes-1][i]; + } + } /* Envelope > 0 */ + + C_ALLOC_SCRATCH_END(pwrData, PS_PWR_DATA, 1) + + return error; +} + -- cgit v1.2.3