libSACdec/src/sac_dec.h - third_party/android/platform/external/aac - Git at Google

 /* -----------------------------------------------------------------------------
 Software License for The Fraunhofer FDK AAC Codec Library for Android

 © Copyright  1995 - 2018 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 surround decoder library *************************

    Author(s):

    Description: SAC Decoder Library structures

 *******************************************************************************/

 #ifndef SAC_DEC_H
 #define SAC_DEC_H

 #include "common_fix.h"

 #include "sac_dec_interface.h" /* library interface in ../include */

 #include "FDK_qmf_domain.h"
 #include "sac_qmf.h"
 #include "FDK_bitstream.h" /* mp4 bitbuffer */
 #include "sac_calcM1andM2.h"
 #include "FDK_hybrid.h"
 #include "FDK_decorrelate.h"
 #include "sac_reshapeBBEnv.h"

 #include "sac_dec_conceal.h"

 #include "sac_tsd.h"

 #ifndef MAX
 #define MAX(a, b) ((a) > (b) ? (a) : (b))
 #endif

 #define ICCdefault 0
 #define IPDdefault 0
 #define arbdmxGainDefault 0
 #define CPCdefault 10
 #define tttCLD1default 15
 #define tttCLD2default 0

 #define IS_HQ_ONLY(aot)                                                      \
   ((aot) == AOT_ER_AAC_LD || (aot) == AOT_ER_AAC_ELD || (aot) == AOT_USAC || \
    (aot) == AOT_RSVD50)

 #define SCONST(x) FL2FXCONST_DBL(x)

 #define PC_NUM_BANDS (8)
 #define PC_NUM_HYB_BANDS (PC_NUM_BANDS - 3 + 10)
 #define ABS_THR (1e-9f * 32768 * 32768)

 #define MAX_HYBRID_BANDS (MAX_NUM_QMF_BANDS - 3 + 10)
 #define HYBRID_FILTER_DELAY (6)

 #define MAX_RESIDUAL_FRAMES (4)
 #define MAX_RESIDUAL_BISTREAM \
   (836) /*  48000 bps * 3 res / (8 * 44100 / 2048 ) */
 #define MAX_MDCT_COEFFS (1024)
 #define SACDEC_RESIDUAL_BS_BUF_SIZE \
   (1024) /* used to setup and check residual bitstream buffer */

 #define MAX_NUM_PARAMS (MAX_NUM_OTT + 4 * MAX_NUM_TTT + MAX_INPUT_CHANNELS)
 #define MAX_NUM_PARAMETERS (MAX(MAX_NUM_PARAMS, MAX_NUM_OTT))

 #define MAX_PARAMETER_SETS (9)

 #define MAX_M2_INPUT (MAX_OUTPUT_CHANNELS) /* 3 direct + 5 diffuse */

 #define MAX_QMF_BANDS_TO_HYBRID \
   (3) /* 3 bands are filtered again in "40 bands" case */
 #define PROTO_LEN (13)
 #define BUFFER_LEN_LF (PROTO_LEN)
 #define BUFFER_LEN_HF ((PROTO_LEN - 1) / 2)

 #define MAX_NO_DECORR_CHANNELS (MAX_OUTPUT_CHANNELS)
 #define HRTF_AZIMUTHS (5)

 #define MAX_NUM_OTT_AT 0

 /* left out */

 typedef enum {
   UPMIXTYPE_BYPASS = -1, /*just bypass the input channels without processing*/
   UPMIXTYPE_NORMAL = 0   /*multichannel loudspeaker upmix with spatial data*/
 } UPMIXTYPE;

 static inline int isTwoChMode(UPMIXTYPE upmixType) {
   int retval = 0;
   return retval;
 }

   /* left out end */

 #define MPEGS_BYPASSMODE (0x00000001)
 #define MPEGS_CONCEAL (0x00000002)

 typedef struct STP_DEC *HANDLE_STP_DEC;

 typedef struct {
   SCHAR bsQuantCoarseXXXprev;
   SCHAR bsQuantCoarseXXXprevParse;
 } LOSSLESSSTATE;

 typedef struct {
   SCHAR bsXXXDataMode[MAX_PARAMETER_SETS];
   SCHAR bsQuantCoarseXXX[MAX_PARAMETER_SETS];
   SCHAR bsFreqResStrideXXX[MAX_PARAMETER_SETS];
   SCHAR nocmpQuantCoarseXXX[MAX_PARAMETER_SETS];
   LOSSLESSSTATE *state; /* Link to persistent state information */
 } LOSSLESSDATA;

 struct SPATIAL_BS_FRAME_struct {
   UCHAR bsIndependencyFlag;
   UCHAR newBsData;
   UCHAR numParameterSets;

   /*
   If bsFramingType == 0, then the paramSlot[ps] for 0 <= ps < numParamSets is
   calculated as follows: paramSlot[ps] = ceil(numSlots*(ps+1)/numParamSets) - 1
   Otherwise, it is
     paramSlot[ps] = bsParamSlot[ps]
   */
   INT paramSlot[MAX_PARAMETER_SETS];

   /* These arrays contain the compact indices, only one value per pbstride, only
    * paramsets actually containing data. */
   /* These values are written from the parser in ecDataDec() and read during
    * decode in mapIndexData() */
   SCHAR cmpOttCLDidx[MAX_NUM_OTT + MAX_NUM_OTT_AT][MAX_PARAMETER_SETS]
                     [MAX_PARAMETER_BANDS];
   SCHAR cmpOttICCidx[MAX_NUM_OTT][MAX_PARAMETER_SETS][MAX_PARAMETER_BANDS];

   /* Smoothing */
   UCHAR bsSmoothMode[MAX_PARAMETER_SETS];
   UCHAR bsSmoothTime[MAX_PARAMETER_SETS];
   UCHAR bsFreqResStrideSmg[MAX_PARAMETER_SETS];
   UCHAR bsSmgData[MAX_PARAMETER_SETS]
                  [MAX_PARAMETER_BANDS]; /* smoothing flags, one if band is
                                            smoothed, otherwise zero */

   /* Arbitrary Downmix */
   SCHAR (*cmpArbdmxGainIdx)[MAX_PARAMETER_SETS][MAX_PARAMETER_BANDS];

   /* Lossless control */
   LOSSLESSDATA *CLDLosslessData;
   LOSSLESSDATA *ICCLosslessData;
   /* LOSSLESSDATA *ADGLosslessData; -> is stored in CLDLosslessData[offset] */

   LOSSLESSDATA *IPDLosslessData;
   SCHAR (*cmpOttIPDidx)[MAX_PARAMETER_SETS][MAX_PARAMETER_BANDS];
   int phaseMode;
   int OpdSmoothingMode;

   UCHAR tempShapeEnableChannelGES[MAX_OUTPUT_CHANNELS]; /*!< GES side info. */
   UCHAR bsEnvShapeData[MAX_OUTPUT_CHANNELS]
                       [MAX_TIME_SLOTS]; /*!< GES side info (quantized). */

   UCHAR tempShapeEnableChannelSTP[MAX_OUTPUT_CHANNELS]; /*!< STP side info. */

   TSD_DATA TsdData[1]; /*!< TSD data structure. */
 };

 typedef struct {
   /* Lossless state */
   LOSSLESSSTATE CLDLosslessState[MAX_NUM_PARAMETERS];
   LOSSLESSSTATE ICCLosslessState[MAX_NUM_PARAMETERS];
   LOSSLESSSTATE IPDLosslessState[MAX_NUM_PARAMETERS];
 } BS_LL_STATE;

 typedef struct {
   int prevParamSlot;
   int prevSmgTime;
   UCHAR prevSmgData[MAX_PARAMETER_BANDS];

   FIXP_DBL opdLeftState__FDK[MAX_PARAMETER_BANDS];
   FIXP_DBL opdRightState__FDK[MAX_PARAMETER_BANDS];

 } SMOOTHING_STATE;

 typedef struct {
   FIXP_DBL alpha__FDK;
   FIXP_DBL beta__FDK;
   FIXP_DBL partNrgPrev__FDK[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS]
                            [BB_ENV_SIZE];
   FIXP_DBL normNrgPrev__FDK[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
   FIXP_DBL frameNrgPrev__FDK[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
   INT partNrgPrevSF[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
   INT partNrgPrev2SF[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
   INT normNrgPrevSF[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
   INT frameNrgPrevSF[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
 } RESHAPE_BBENV_STATE;

 typedef struct {
   int maxNumInputChannels;
   int maxNumOutputChannels;
   int maxNumQmfBands;
   int maxNumHybridBands;
   int maxNumXChannels;
   int maxNumVChannels;
   int maxNumDecorChannels;
   int maxNumCmplxQmfBands;
   int maxNumCmplxHybBands;
   int maxNumResChannels;
   int bProcResidual; /* process residual */
   int maxNumResidualChannels;
   int maxNumOttBoxes;
   int maxNumParams;

 } SACDEC_CREATION_PARAMS;

 struct spatialDec_struct {
   SACDEC_ERROR
   errInt;             /* Field to store internal errors.
                          Will be clear at the very beginning of each process call. */
   int staticDecScale; /* static scale of decoder */

   /* GENERAL */
   int samplingFreq;       /* [Hz] */
   CFG_LEVEL decoderLevel; /* 0..5 */
   CFG_EXTENT decoderMode;
   CFG_BINAURAL binauralMode;

   SACDEC_CREATION_PARAMS createParams;

   int numComplexProcessingBands;

   int treeConfig; /* TREE_5151 = 5151, TREE_5152 = 5152, TREE_525 = 525, defined
                      in sac_bitdec.h */

   int numInputChannels;  /* 1 (M) or 2 (L,R) */
   int numOutputChannels; /* 6 for 3/2.1 (FL,FR,FC,LF,BL,BR) */
   int numOttBoxes;       /* number of ott boxes */
   int numM2rows;

   int numOutputChannelsAT; /* Number of output channels after arbitrary tree
                               processing */

   int quantMode; /* QUANT_FINE, QUANT_EBQ1, QUANT_EBQ2, defined in sac_bitdec.h
                   */
   int arbitraryDownmix; /* (arbitraryDownmix != 0) 1 arbitrary downmix data
                            present, 2 arbitrary downmix residual data present*/
   int residualCoding;   /* (residualCoding != 0) => residual coding data present
                          */
   UCHAR nrResidualFrame;
   UCHAR nrArbDownmixResidualFrame;
   FDK_BITSTREAM **hResidualBitstreams;
   int tempShapeConfig; /* */
   int decorrType;      /* Indicates to use PS or none PS decorrelator. */
   int decorrConfig;    /* chosen decorrelator */
   int envQuantMode;    /* quantization mode of envelope reshaping data */

   FIXP_DBL clipProtectGain__FDK; /* global gain for upmix */
   char clipProtectGainSF__FDK;   /* global gain for upmix */

   /* Currently ignoring center decorr
      numVChannels = numDirektSignals + numDecorSignals */
   int numDirektSignals;  /* needed for W, Number of direkt signals 515 -> 1 525
                             -> 3 */
   int wStartResidualIdx; /* Where to start read residuals for W, = 0 for 515, =
                             1 for 525 since one residual is used in V */
   int numDecorSignals;   /* needed for W, Number of residual and decorrelated
                             signals, = 2, 3 for center deccorelation*/
   int numVChannels;      /* direct signals + decorelator signals */
   int numXChannels;      /* direct input signals + TTT-residuals */

   int timeSlots;    /* length of spatial frame in QMF samples */
   int curTimeSlot;  /* pointer to the current time slot used for hyperframing */
   int prevTimeSlot; /*  */
   int curPs;
   int frameLength; /* number of output waveform samples/channel/frame */
   UPMIXTYPE upmixType;
   int partiallyComplex;
   int useFDreverb;

   int bShareDelayWithSBR;

   int tp_hybBandBorder; /* Hybrid band indicating the HP filter cut-off. */

   /* FREQUENCY MAPPING */
   int qmfBands;
   int hybridBands;
   const SCHAR *kernels; /* Mapping hybrid band to parameter band. */

   int TsdTs; /**< TSD QMF slot counter 0<= ts < numSlots */

   int *param2hyb; /* Mapping parameter bands to hybrid bands */
   int kernels_width[MAX_PARAMETER_BANDS]; /* Mapping parmeter band to hybrid
                                              band offsets. */

   /* Residual coding */
   int residualSamplingFreq;
   UCHAR residualPresent[MAX_NUM_OTT + MAX_NUM_TTT];
   UCHAR residualBands[MAX_NUM_OTT + MAX_NUM_TTT];    /* 0, if no residual data
                                                         present for this box */
   UCHAR residualQMFBands[MAX_NUM_OTT + MAX_NUM_TTT]; /* needed for optimized
                                                         mdct2qmf calculation */
   SPATIAL_SPECIFIC_CONFIG *pConfigCurrent;

   int arbdmxFramesPerSpatialFrame;
   int arbdmxUpdQMF;

   int numParameterBands; /* Number of parameter bands 40, 28, 20, 14, 10, ...
                             .*/
   int bitstreamParameterBands;
   int *numOttBands; /* number of bands for each ott, is != numParameterBands for
                        LFEs */

   /* 1 MAPPING */
   UCHAR extendFrame;
   UCHAR numParameterSetsPrev;

   int *smgTime;
   UCHAR **smgData;

   /* PARAMETER DATA decoded and dequantized */

   /* Last parameters from prev frame required during decode in mapIndexData()
    * and not touched during parse */
   SCHAR **ottCLDidxPrev;
   SCHAR **ottICCidxPrev;
   SCHAR **arbdmxGainIdxPrev;
   SCHAR **ottIPDidxPrev;
   SCHAR ***outIdxData; /* is this really persistent memory ? */

   /* State mem required during parse in SpatialDecParseFrameData() */
   SCHAR **cmpOttCLDidxPrev;
   SCHAR **cmpOttICCidxPrev;
   SCHAR ***ottICCdiffidx;
   SCHAR **cmpOttIPDidxPrev;

   /* State mem required in parseArbitraryDownmixData */
   SCHAR **cmpArbdmxGainIdxPrev;

   SCHAR ***ottCLD__FDK;
   SCHAR ***ottICC__FDK;

   SCHAR ***arbdmxGain__FDK; /* Holds the artistic downmix correction index.*/

   FIXP_DBL *arbdmxAlpha__FDK;
   FIXP_DBL *arbdmxAlphaPrev__FDK;

   UCHAR stereoConfigIndex;
   int highRateMode;

   int phaseCoding;

   SCHAR ***ottIPD__FDK;

   FIXP_DBL PhaseLeft__FDK[MAX_PARAMETER_BANDS];
   FIXP_DBL PhaseRight__FDK[MAX_PARAMETER_BANDS];
   FIXP_DBL PhasePrevLeft__FDK[MAX_PARAMETER_BANDS];
   FIXP_DBL PhasePrevRight__FDK[MAX_PARAMETER_BANDS];
   int numOttBandsIPD;

   /* GAIN MATRICIES FOR CURRENT and PREVIOUS PARMATER SET(s)*/
   FIXP_DBL ***M2Real__FDK;
   FIXP_DBL ***M2Imag__FDK;
   FIXP_DBL ***M2RealPrev__FDK;
   FIXP_DBL ***M2ImagPrev__FDK;

   /* INPUT SIGNALS */
   FIXP_DBL ***qmfInputRealDelayBuffer__FDK;
   FIXP_DBL ***qmfInputImagDelayBuffer__FDK;

   int pc_filterdelay; /* additional delay to align HQ with LP before hybird
                          analysis */
   int qmfInputDelayBufPos;
   FIXP_DBL **qmfInputReal__FDK;
   FIXP_DBL **qmfInputImag__FDK;

   FIXP_DBL **hybInputReal__FDK;
   FIXP_DBL **hybInputImag__FDK;

   FIXP_DBL **binInputReverb;

   FIXP_DBL binGain, reverbGain;
   FIXP_DBL binCenterGain, reverbCenterGain;

   /* RESIDUAL SIGNALS */

   FIXP_DBL ***qmfResidualReal__FDK;
   FIXP_DBL ***qmfResidualImag__FDK;

   FIXP_DBL **hybResidualReal__FDK;
   FIXP_DBL **hybResidualImag__FDK;

   int qmfOutputRealDryDelayBufPos;
   FIXP_DBL ***qmfOutputRealDryDelayBuffer__FDK;
   FIXP_DBL ***qmfOutputImagDryFilterBuffer__FDK;
   FIXP_DBL *qmfOutputImagDryFilterBufferBase__FDK;

   /* TEMPORARY SIGNALS */

   FIXP_DBL **wReal__FDK;
   FIXP_DBL **wImag__FDK;

   /* OUTPUT SIGNALS */
   FIXP_DBL **hybOutputRealDry__FDK;
   FIXP_DBL **hybOutputImagDry__FDK;
   FIXP_DBL **hybOutputRealWet__FDK;
   FIXP_DBL **hybOutputImagWet__FDK;
   PCM_MPS *timeOut__FDK;

   HANDLE_FDK_QMF_DOMAIN pQmfDomain;

   FDK_ANA_HYB_FILTER
   *hybridAnalysis; /*!< pointer Analysis hybrid filterbank array. */
   FDK_SYN_HYB_FILTER
   *hybridSynthesis; /*!< pointer Synthesis hybrid filterbank array. */
   FIXP_DBL **
       pHybridAnaStatesLFdmx; /*!< pointer to analysis hybrid filter states LF */
   FIXP_DBL **
       pHybridAnaStatesHFdmx; /*!< pointer to analysis hybrid filter states HF */
   FIXP_DBL **
       pHybridAnaStatesLFres; /*!< pointer to analysis hybrid filter states LF */
   FIXP_DBL **
       pHybridAnaStatesHFres; /*!< pointer to analysis hybrid filter states HF */

   DECORR_DEC *apDecor; /*!< pointer decorrelator array. */
   FIXP_DBL **pDecorBufferCplx;

   SMOOTHING_STATE *smoothState; /*!< Pointer to smoothing states. */

   RESHAPE_BBENV_STATE *reshapeBBEnvState; /*!< GES handle. */
   SCHAR row2channelDmxGES[MAX_OUTPUT_CHANNELS];

   HANDLE_STP_DEC hStpDec; /*!< STP handle. */

   const UCHAR *pActivM2ParamBands;

   int bOverwriteM1M2prev; /* Overwrite previous M2/M2 params with first set of
                              new frame after SSC change (aka
                              decodeAfterConfigHasChangedFlag). */
   SpatialDecConcealmentInfo concealInfo;
 };

 #define SACDEC_SYNTAX_MPS 1
 #define SACDEC_SYNTAX_USAC 2
 #define SACDEC_SYNTAX_RSVD50 4
 #define SACDEC_SYNTAX_L2 8
 #define SACDEC_SYNTAX_L3 16
 #define SACDEC_SYNTAX_LD 32

 static inline int GetProcBand(spatialDec_struct *self, int qs) {
   return self->kernels[qs];
 }

 #endif /* SAC_DEC_H */
	/* -----------------------------------------------------------------------------
	Software License for The Fraunhofer FDK AAC Codec Library for Android

	© Copyright 1995 - 2018 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 surround decoder library ***********************

	Author(s):

	Description: SAC Decoder Library structures

	*******************************************************************************/

	#ifndef SAC_DEC_H
	#define SAC_DEC_H

	#include "common_fix.h"

	#include "sac_dec_interface.h" /* library interface in ../include */

	#include "FDK_qmf_domain.h"
	#include "sac_qmf.h"
	#include "FDK_bitstream.h" /* mp4 bitbuffer */
	#include "sac_calcM1andM2.h"
	#include "FDK_hybrid.h"
	#include "FDK_decorrelate.h"
	#include "sac_reshapeBBEnv.h"

	#include "sac_dec_conceal.h"

	#include "sac_tsd.h"

	#ifndef MAX
	#define MAX(a, b) ((a) > (b) ? (a) : (b))
	#endif

	#define ICCdefault 0
	#define IPDdefault 0
	#define arbdmxGainDefault 0
	#define CPCdefault 10
	#define tttCLD1default 15
	#define tttCLD2default 0

	#define IS_HQ_ONLY(aot) \
	((aot) == AOT_ER_AAC_LD \|\| (aot) == AOT_ER_AAC_ELD \|\| (aot) == AOT_USAC \|\| \
	(aot) == AOT_RSVD50)

	#define SCONST(x) FL2FXCONST_DBL(x)

	#define PC_NUM_BANDS (8)
	#define PC_NUM_HYB_BANDS (PC_NUM_BANDS - 3 + 10)
	#define ABS_THR (1e-9f * 32768 * 32768)

	#define MAX_HYBRID_BANDS (MAX_NUM_QMF_BANDS - 3 + 10)
	#define HYBRID_FILTER_DELAY (6)

	#define MAX_RESIDUAL_FRAMES (4)
	#define MAX_RESIDUAL_BISTREAM \
	(836) /* 48000 bps * 3 res / (8 * 44100 / 2048 ) */
	#define MAX_MDCT_COEFFS (1024)
	#define SACDEC_RESIDUAL_BS_BUF_SIZE \
	(1024) /* used to setup and check residual bitstream buffer */

	#define MAX_NUM_PARAMS (MAX_NUM_OTT + 4 * MAX_NUM_TTT + MAX_INPUT_CHANNELS)
	#define MAX_NUM_PARAMETERS (MAX(MAX_NUM_PARAMS, MAX_NUM_OTT))

	#define MAX_PARAMETER_SETS (9)

	#define MAX_M2_INPUT (MAX_OUTPUT_CHANNELS) /* 3 direct + 5 diffuse */

	#define MAX_QMF_BANDS_TO_HYBRID \
	(3) /* 3 bands are filtered again in "40 bands" case */
	#define PROTO_LEN (13)
	#define BUFFER_LEN_LF (PROTO_LEN)
	#define BUFFER_LEN_HF ((PROTO_LEN - 1) / 2)

	#define MAX_NO_DECORR_CHANNELS (MAX_OUTPUT_CHANNELS)
	#define HRTF_AZIMUTHS (5)

	#define MAX_NUM_OTT_AT 0

	/* left out */

	typedef enum {
	UPMIXTYPE_BYPASS = -1, /just bypass the input channels without processing/
	UPMIXTYPE_NORMAL = 0 /multichannel loudspeaker upmix with spatial data/
	} UPMIXTYPE;

	static inline int isTwoChMode(UPMIXTYPE upmixType) {
	int retval = 0;
	return retval;
	}

	/* left out end */

	#define MPEGS_BYPASSMODE (0x00000001)
	#define MPEGS_CONCEAL (0x00000002)

	typedef struct STP_DEC *HANDLE_STP_DEC;

	typedef struct {
	SCHAR bsQuantCoarseXXXprev;
	SCHAR bsQuantCoarseXXXprevParse;
	} LOSSLESSSTATE;

	typedef struct {
	SCHAR bsXXXDataMode[MAX_PARAMETER_SETS];
	SCHAR bsQuantCoarseXXX[MAX_PARAMETER_SETS];
	SCHAR bsFreqResStrideXXX[MAX_PARAMETER_SETS];
	SCHAR nocmpQuantCoarseXXX[MAX_PARAMETER_SETS];
	LOSSLESSSTATE state; / Link to persistent state information */
	} LOSSLESSDATA;

	struct SPATIAL_BS_FRAME_struct {
	UCHAR bsIndependencyFlag;
	UCHAR newBsData;
	UCHAR numParameterSets;

	/*
	If bsFramingType == 0, then the paramSlot[ps] for 0 <= ps < numParamSets is
	calculated as follows: paramSlot[ps] = ceil(numSlots*(ps+1)/numParamSets) - 1
	Otherwise, it is
	paramSlot[ps] = bsParamSlot[ps]
	*/
	INT paramSlot[MAX_PARAMETER_SETS];

	/* These arrays contain the compact indices, only one value per pbstride, only
	* paramsets actually containing data. */
	/* These values are written from the parser in ecDataDec() and read during
	* decode in mapIndexData() */
	SCHAR cmpOttCLDidx[MAX_NUM_OTT + MAX_NUM_OTT_AT][MAX_PARAMETER_SETS]
	[MAX_PARAMETER_BANDS];
	SCHAR cmpOttICCidx[MAX_NUM_OTT][MAX_PARAMETER_SETS][MAX_PARAMETER_BANDS];

	/* Smoothing */
	UCHAR bsSmoothMode[MAX_PARAMETER_SETS];
	UCHAR bsSmoothTime[MAX_PARAMETER_SETS];
	UCHAR bsFreqResStrideSmg[MAX_PARAMETER_SETS];
	UCHAR bsSmgData[MAX_PARAMETER_SETS]
	[MAX_PARAMETER_BANDS]; /* smoothing flags, one if band is
	smoothed, otherwise zero */

	/* Arbitrary Downmix */
	SCHAR (*cmpArbdmxGainIdx)[MAX_PARAMETER_SETS][MAX_PARAMETER_BANDS];

	/* Lossless control */
	LOSSLESSDATA *CLDLosslessData;
	LOSSLESSDATA *ICCLosslessData;
	/* LOSSLESSDATA ADGLosslessData; -> is stored in CLDLosslessData[offset] /

	LOSSLESSDATA *IPDLosslessData;
	SCHAR (*cmpOttIPDidx)[MAX_PARAMETER_SETS][MAX_PARAMETER_BANDS];
	int phaseMode;
	int OpdSmoothingMode;

	UCHAR tempShapeEnableChannelGES[MAX_OUTPUT_CHANNELS]; /!< GES side info. /
	UCHAR bsEnvShapeData[MAX_OUTPUT_CHANNELS]
	[MAX_TIME_SLOTS]; /!< GES side info (quantized). /

	UCHAR tempShapeEnableChannelSTP[MAX_OUTPUT_CHANNELS]; /!< STP side info. /

	TSD_DATA TsdData[1]; /!< TSD data structure. /
	};

	typedef struct {
	/* Lossless state */
	LOSSLESSSTATE CLDLosslessState[MAX_NUM_PARAMETERS];
	LOSSLESSSTATE ICCLosslessState[MAX_NUM_PARAMETERS];
	LOSSLESSSTATE IPDLosslessState[MAX_NUM_PARAMETERS];
	} BS_LL_STATE;

	typedef struct {
	int prevParamSlot;
	int prevSmgTime;
	UCHAR prevSmgData[MAX_PARAMETER_BANDS];

	FIXP_DBL opdLeftState__FDK[MAX_PARAMETER_BANDS];
	FIXP_DBL opdRightState__FDK[MAX_PARAMETER_BANDS];

	} SMOOTHING_STATE;

	typedef struct {
	FIXP_DBL alpha__FDK;
	FIXP_DBL beta__FDK;
	FIXP_DBL partNrgPrev__FDK[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS]
	[BB_ENV_SIZE];
	FIXP_DBL normNrgPrev__FDK[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
	FIXP_DBL frameNrgPrev__FDK[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
	INT partNrgPrevSF[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
	INT partNrgPrev2SF[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
	INT normNrgPrevSF[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
	INT frameNrgPrevSF[2 * MAX_OUTPUT_CHANNELS + MAX_INPUT_CHANNELS];
	} RESHAPE_BBENV_STATE;

	typedef struct {
	int maxNumInputChannels;
	int maxNumOutputChannels;
	int maxNumQmfBands;
	int maxNumHybridBands;
	int maxNumXChannels;
	int maxNumVChannels;
	int maxNumDecorChannels;
	int maxNumCmplxQmfBands;
	int maxNumCmplxHybBands;
	int maxNumResChannels;
	int bProcResidual; /* process residual */
	int maxNumResidualChannels;
	int maxNumOttBoxes;
	int maxNumParams;

	} SACDEC_CREATION_PARAMS;

	struct spatialDec_struct {
	SACDEC_ERROR
	errInt; /* Field to store internal errors.
	Will be clear at the very beginning of each process call. */
	int staticDecScale; /* static scale of decoder */

	/* GENERAL */
	int samplingFreq; /* [Hz] */
	CFG_LEVEL decoderLevel; /* 0..5 */
	CFG_EXTENT decoderMode;
	CFG_BINAURAL binauralMode;

	SACDEC_CREATION_PARAMS createParams;

	int numComplexProcessingBands;

	int treeConfig; /* TREE_5151 = 5151, TREE_5152 = 5152, TREE_525 = 525, defined
	in sac_bitdec.h */

	int numInputChannels; /* 1 (M) or 2 (L,R) */
	int numOutputChannels; /* 6 for 3/2.1 (FL,FR,FC,LF,BL,BR) */
	int numOttBoxes; /* number of ott boxes */
	int numM2rows;

	int numOutputChannelsAT; /* Number of output channels after arbitrary tree
	processing */

	int quantMode; /* QUANT_FINE, QUANT_EBQ1, QUANT_EBQ2, defined in sac_bitdec.h
	*/
	int arbitraryDownmix; /* (arbitraryDownmix != 0) 1 arbitrary downmix data
	present, 2 arbitrary downmix residual data present*/
	int residualCoding; /* (residualCoding != 0) => residual coding data present
	*/
	UCHAR nrResidualFrame;
	UCHAR nrArbDownmixResidualFrame;
	FDK_BITSTREAM **hResidualBitstreams;
	int tempShapeConfig; /* */
	int decorrType; /* Indicates to use PS or none PS decorrelator. */
	int decorrConfig; /* chosen decorrelator */
	int envQuantMode; /* quantization mode of envelope reshaping data */

	FIXP_DBL clipProtectGain__FDK; /* global gain for upmix */
	char clipProtectGainSF__FDK; /* global gain for upmix */

	/* Currently ignoring center decorr
	numVChannels = numDirektSignals + numDecorSignals */
	int numDirektSignals; /* needed for W, Number of direkt signals 515 -> 1 525
	-> 3 */
	int wStartResidualIdx; /* Where to start read residuals for W, = 0 for 515, =
	1 for 525 since one residual is used in V */
	int numDecorSignals; /* needed for W, Number of residual and decorrelated
	signals, = 2, 3 for center deccorelation*/
	int numVChannels; /* direct signals + decorelator signals */
	int numXChannels; /* direct input signals + TTT-residuals */

	int timeSlots; /* length of spatial frame in QMF samples */
	int curTimeSlot; /* pointer to the current time slot used for hyperframing */
	int prevTimeSlot; /* */
	int curPs;
	int frameLength; /* number of output waveform samples/channel/frame */
	UPMIXTYPE upmixType;
	int partiallyComplex;
	int useFDreverb;

	int bShareDelayWithSBR;

	int tp_hybBandBorder; /* Hybrid band indicating the HP filter cut-off. */

	/* FREQUENCY MAPPING */
	int qmfBands;
	int hybridBands;
	const SCHAR kernels; / Mapping hybrid band to parameter band. */

	int TsdTs; /*< TSD QMF slot counter 0<= ts < numSlots /

	int param2hyb; / Mapping parameter bands to hybrid bands */
	int kernels_width[MAX_PARAMETER_BANDS]; /* Mapping parmeter band to hybrid
	band offsets. */

	/* Residual coding */
	int residualSamplingFreq;
	UCHAR residualPresent[MAX_NUM_OTT + MAX_NUM_TTT];
	UCHAR residualBands[MAX_NUM_OTT + MAX_NUM_TTT]; /* 0, if no residual data
	present for this box */
	UCHAR residualQMFBands[MAX_NUM_OTT + MAX_NUM_TTT]; /* needed for optimized
	mdct2qmf calculation */
	SPATIAL_SPECIFIC_CONFIG *pConfigCurrent;

	int arbdmxFramesPerSpatialFrame;
	int arbdmxUpdQMF;

	int numParameterBands; /* Number of parameter bands 40, 28, 20, 14, 10, ...
	.*/
	int bitstreamParameterBands;
	int numOttBands; / number of bands for each ott, is != numParameterBands for
	LFEs */

	/* 1 MAPPING */
	UCHAR extendFrame;
	UCHAR numParameterSetsPrev;

	int *smgTime;
	UCHAR **smgData;

	/* PARAMETER DATA decoded and dequantized */

	/* Last parameters from prev frame required during decode in mapIndexData()
	* and not touched during parse */
	SCHAR **ottCLDidxPrev;
	SCHAR **ottICCidxPrev;
	SCHAR **arbdmxGainIdxPrev;
	SCHAR **ottIPDidxPrev;
	SCHAR **outIdxData; / is this really persistent memory ? */

	/* State mem required during parse in SpatialDecParseFrameData() */
	SCHAR **cmpOttCLDidxPrev;
	SCHAR **cmpOttICCidxPrev;
	SCHAR ***ottICCdiffidx;
	SCHAR **cmpOttIPDidxPrev;

	/* State mem required in parseArbitraryDownmixData */
	SCHAR **cmpArbdmxGainIdxPrev;

	SCHAR ***ottCLD__FDK;
	SCHAR ***ottICC__FDK;

	SCHAR **arbdmxGain__FDK; / Holds the artistic downmix correction index.*/

	FIXP_DBL *arbdmxAlpha__FDK;
	FIXP_DBL *arbdmxAlphaPrev__FDK;

	UCHAR stereoConfigIndex;
	int highRateMode;

	int phaseCoding;

	SCHAR ***ottIPD__FDK;

	FIXP_DBL PhaseLeft__FDK[MAX_PARAMETER_BANDS];
	FIXP_DBL PhaseRight__FDK[MAX_PARAMETER_BANDS];
	FIXP_DBL PhasePrevLeft__FDK[MAX_PARAMETER_BANDS];
	FIXP_DBL PhasePrevRight__FDK[MAX_PARAMETER_BANDS];
	int numOttBandsIPD;

	/* GAIN MATRICIES FOR CURRENT and PREVIOUS PARMATER SET(s)*/
	FIXP_DBL ***M2Real__FDK;
	FIXP_DBL ***M2Imag__FDK;
	FIXP_DBL ***M2RealPrev__FDK;
	FIXP_DBL ***M2ImagPrev__FDK;

	/* INPUT SIGNALS */
	FIXP_DBL ***qmfInputRealDelayBuffer__FDK;
	FIXP_DBL ***qmfInputImagDelayBuffer__FDK;

	int pc_filterdelay; /* additional delay to align HQ with LP before hybird
	analysis */
	int qmfInputDelayBufPos;
	FIXP_DBL **qmfInputReal__FDK;
	FIXP_DBL **qmfInputImag__FDK;

	FIXP_DBL **hybInputReal__FDK;
	FIXP_DBL **hybInputImag__FDK;

	FIXP_DBL **binInputReverb;

	FIXP_DBL binGain, reverbGain;
	FIXP_DBL binCenterGain, reverbCenterGain;

	/* RESIDUAL SIGNALS */

	FIXP_DBL ***qmfResidualReal__FDK;
	FIXP_DBL ***qmfResidualImag__FDK;

	FIXP_DBL **hybResidualReal__FDK;
	FIXP_DBL **hybResidualImag__FDK;

	int qmfOutputRealDryDelayBufPos;
	FIXP_DBL ***qmfOutputRealDryDelayBuffer__FDK;
	FIXP_DBL ***qmfOutputImagDryFilterBuffer__FDK;
	FIXP_DBL *qmfOutputImagDryFilterBufferBase__FDK;

	/* TEMPORARY SIGNALS */

	FIXP_DBL **wReal__FDK;
	FIXP_DBL **wImag__FDK;

	/* OUTPUT SIGNALS */
	FIXP_DBL **hybOutputRealDry__FDK;
	FIXP_DBL **hybOutputImagDry__FDK;
	FIXP_DBL **hybOutputRealWet__FDK;
	FIXP_DBL **hybOutputImagWet__FDK;
	PCM_MPS *timeOut__FDK;

	HANDLE_FDK_QMF_DOMAIN pQmfDomain;

	FDK_ANA_HYB_FILTER
	hybridAnalysis; /!< pointer Analysis hybrid filterbank array. */
	FDK_SYN_HYB_FILTER
	hybridSynthesis; /!< pointer Synthesis hybrid filterbank array. */
	FIXP_DBL **
	pHybridAnaStatesLFdmx; /!< pointer to analysis hybrid filter states LF /
	FIXP_DBL **
	pHybridAnaStatesHFdmx; /!< pointer to analysis hybrid filter states HF /
	FIXP_DBL **
	pHybridAnaStatesLFres; /!< pointer to analysis hybrid filter states LF /
	FIXP_DBL **
	pHybridAnaStatesHFres; /!< pointer to analysis hybrid filter states HF /

	DECORR_DEC apDecor; /!< pointer decorrelator array. */
	FIXP_DBL **pDecorBufferCplx;

	SMOOTHING_STATE smoothState; /!< Pointer to smoothing states. */

	RESHAPE_BBENV_STATE reshapeBBEnvState; /!< GES handle. */
	SCHAR row2channelDmxGES[MAX_OUTPUT_CHANNELS];

	HANDLE_STP_DEC hStpDec; /!< STP handle. /

	const UCHAR *pActivM2ParamBands;

	int bOverwriteM1M2prev; /* Overwrite previous M2/M2 params with first set of
	new frame after SSC change (aka
	decodeAfterConfigHasChangedFlag). */
	SpatialDecConcealmentInfo concealInfo;
	};

	#define SACDEC_SYNTAX_MPS 1
	#define SACDEC_SYNTAX_USAC 2
	#define SACDEC_SYNTAX_RSVD50 4
	#define SACDEC_SYNTAX_L2 8
	#define SACDEC_SYNTAX_L3 16
	#define SACDEC_SYNTAX_LD 32

	static inline int GetProcBand(spatialDec_struct *self, int qs) {
	return self->kernels[qs];
	}

	#endif /* SAC_DEC_H */