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diff --git a/libAACenc/src/qc_main.cpp b/libAACenc/src/qc_main.cpp new file mode 100644 index 0000000..749398a --- /dev/null +++ b/libAACenc/src/qc_main.cpp @@ -0,0 +1,1620 @@ + +/* ----------------------------------------------------------------------------------------------------------- +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 author: M. Werner + contents/description: Quantizing & coding + +******************************************************************************/ + +#include "qc_main.h" +#include "quantize.h" +#include "interface.h" +#include "adj_thr.h" +#include "sf_estim.h" +#include "bit_cnt.h" +#include "dyn_bits.h" +#include "channel_map.h" +#include "aacEnc_ram.h" + +#include "genericStds.h" + + +typedef struct { + QCDATA_BR_MODE bitrateMode; + LONG vbrQualFactor; +} TAB_VBR_QUAL_FACTOR; + +static const TAB_VBR_QUAL_FACTOR tableVbrQualFactor[] = { + {QCDATA_BR_MODE_CBR, FL2FXCONST_DBL(0.00f)}, + {QCDATA_BR_MODE_VBR_1, FL2FXCONST_DBL(0.160f)}, /* 32 kbps mono AAC-LC + SBR + PS */ + {QCDATA_BR_MODE_VBR_2, FL2FXCONST_DBL(0.148f)}, /* 64 kbps stereo AAC-LC + SBR */ + {QCDATA_BR_MODE_VBR_3, FL2FXCONST_DBL(0.135f)}, /* 80 - 96 kbps stereo AAC-LC */ + {QCDATA_BR_MODE_VBR_4, FL2FXCONST_DBL(0.111f)}, /* 128 kbps stereo AAC-LC */ + {QCDATA_BR_MODE_VBR_5, FL2FXCONST_DBL(0.070f)}, /* 192 kbps stereo AAC-LC */ + {QCDATA_BR_MODE_SFR, FL2FXCONST_DBL(0.00f)}, + {QCDATA_BR_MODE_FF, FL2FXCONST_DBL(0.00f)} +}; + +static INT isConstantBitrateMode( + const QCDATA_BR_MODE bitrateMode + ) +{ + return ( ((bitrateMode==QCDATA_BR_MODE_CBR) || (bitrateMode==QCDATA_BR_MODE_SFR) || (bitrateMode==QCDATA_BR_MODE_FF)) ? 1 : 0 ); +} + + + +typedef enum{ + FRAME_LEN_BYTES_MODULO = 1, + FRAME_LEN_BYTES_INT = 2 +}FRAME_LEN_RESULT_MODE; + +/* forward declarations */ + +static INT FDKaacEnc_calcMaxValueInSfb(INT sfbCnt, + INT maxSfbPerGroup, + INT sfbPerGroup, + INT *RESTRICT sfbOffset, + SHORT *RESTRICT quantSpectrum, + UINT *RESTRICT maxValue); + +static void FDKaacEnc_crashRecovery(INT nChannels, + PSY_OUT_ELEMENT* psyOutElement, + QC_OUT* qcOut, + QC_OUT_ELEMENT *qcElement, + INT bitsToSave, + AUDIO_OBJECT_TYPE aot, + UINT syntaxFlags, + SCHAR epConfig); + +static +AAC_ENCODER_ERROR FDKaacEnc_reduceBitConsumption(int* iterations, + const int maxIterations, + int gainAdjustment, + int* chConstraintsFulfilled, + int* calculateQuant, + int nChannels, + PSY_OUT_ELEMENT* psyOutElement, + QC_OUT* qcOut, + QC_OUT_ELEMENT* qcOutElement, + ELEMENT_BITS* elBits, + AUDIO_OBJECT_TYPE aot, + UINT syntaxFlags, + SCHAR epConfig); + + +void FDKaacEnc_QCClose (QC_STATE **phQCstate, QC_OUT **phQC); + +/***************************************************************************** + + functionname: FDKaacEnc_calcFrameLen + description: + returns: + input: + output: + +*****************************************************************************/ +static INT FDKaacEnc_calcFrameLen(INT bitRate, + INT sampleRate, + INT granuleLength, + FRAME_LEN_RESULT_MODE mode) +{ + + INT result; + + result = ((granuleLength)>>3)*(bitRate); + + switch(mode) { + case FRAME_LEN_BYTES_MODULO: + result %= sampleRate; + break; + case FRAME_LEN_BYTES_INT: + result /= sampleRate; + break; + } + return(result); +} + +/***************************************************************************** + + functionname:FDKaacEnc_framePadding + description: Calculates if padding is needed for actual frame + returns: + input: + output: + +*****************************************************************************/ +static INT FDKaacEnc_framePadding(INT bitRate, + INT sampleRate, + INT granuleLength, + INT *paddingRest) +{ + INT paddingOn; + INT difference; + + paddingOn = 0; + + difference = FDKaacEnc_calcFrameLen( bitRate, + sampleRate, + granuleLength, + FRAME_LEN_BYTES_MODULO ); + *paddingRest-=difference; + + if (*paddingRest <= 0 ) { + paddingOn = 1; + *paddingRest += sampleRate; + } + + return( paddingOn ); +} + + +/********************************************************************************* + + functionname: FDKaacEnc_QCOutNew + description: + return: + +**********************************************************************************/ +AAC_ENCODER_ERROR FDKaacEnc_QCOutNew(QC_OUT **phQC, + const INT nElements, + const INT nChannels, + const INT nSubFrames + ,UCHAR *dynamic_RAM + ) +{ + AAC_ENCODER_ERROR ErrorStatus; + int n, i; + int elInc = 0, chInc = 0; + + for (n=0; n<nSubFrames; n++) { + phQC[n] = GetRam_aacEnc_QCout(n); + if (phQC[n] == NULL) { + ErrorStatus = AAC_ENC_NO_MEMORY; + goto QCOutNew_bail; + } + + for (i=0; i<nChannels; i++) { + phQC[n]->pQcOutChannels[i] = GetRam_aacEnc_QCchannel(chInc, dynamic_RAM); + if ( phQC[n]->pQcOutChannels[i] == NULL + ) + { + ErrorStatus = AAC_ENC_NO_MEMORY; + goto QCOutNew_bail; + } + chInc++; + } /* nChannels */ + + for (i=0; i<nElements; i++) { + phQC[n]->qcElement[i] = GetRam_aacEnc_QCelement(elInc); + if (phQC[n]->qcElement[i] == NULL) + { + ErrorStatus = AAC_ENC_NO_MEMORY; + goto QCOutNew_bail; + } + elInc++; + } /* nElements */ + + } /* nSubFrames */ + + + return AAC_ENC_OK; + +QCOutNew_bail: + return ErrorStatus; +} + +/********************************************************************************* + + functionname: FDKaacEnc_QCOutInit + description: + return: + +**********************************************************************************/ +AAC_ENCODER_ERROR FDKaacEnc_QCOutInit(QC_OUT *phQC[(1)], + const INT nSubFrames, + const CHANNEL_MAPPING *cm) +{ + INT n,i,ch; + + for (n=0; n<nSubFrames; n++) { + INT chInc = 0; + for (i=0; i<cm->nElements; i++) { + for (ch=0; ch<cm->elInfo[i].nChannelsInEl; ch++) { + phQC[n]->qcElement[i]->qcOutChannel[ch] = phQC[n]->pQcOutChannels[chInc]; + chInc++; + } /* chInEl */ + } /* nElements */ + } /* nSubFrames */ + + return AAC_ENC_OK; +} + +/********************************************************************************* + + functionname: FDKaacEnc_QCNew + description: + return: + +**********************************************************************************/ +AAC_ENCODER_ERROR FDKaacEnc_QCNew(QC_STATE **phQC, + INT nElements + ,UCHAR* dynamic_RAM + ) +{ + AAC_ENCODER_ERROR ErrorStatus; + int i; + + QC_STATE* hQC = GetRam_aacEnc_QCstate(); + *phQC = hQC; + if (hQC == NULL) { + ErrorStatus = AAC_ENC_NO_MEMORY; + goto QCNew_bail; + } + + if (FDKaacEnc_AdjThrNew(&hQC->hAdjThr, nElements)) { + ErrorStatus = AAC_ENC_NO_MEMORY; + goto QCNew_bail; + } + + if (FDKaacEnc_BCNew(&(hQC->hBitCounter), dynamic_RAM)) { + ErrorStatus = AAC_ENC_NO_MEMORY; + goto QCNew_bail; + } + + for (i=0; i<nElements; i++) { + hQC->elementBits[i] = GetRam_aacEnc_ElementBits(i); + if (hQC->elementBits[i] == NULL) { + ErrorStatus = AAC_ENC_NO_MEMORY; + goto QCNew_bail; + } + } + + return AAC_ENC_OK; + +QCNew_bail: + FDKaacEnc_QCClose(phQC, NULL); + return ErrorStatus; +} + +/********************************************************************************* + + functionname: FDKaacEnc_QCInit + description: + return: + +**********************************************************************************/ +AAC_ENCODER_ERROR FDKaacEnc_QCInit(QC_STATE *hQC, + struct QC_INIT *init) +{ + hQC->maxBitsPerFrame = init->maxBits; + hQC->minBitsPerFrame = init->minBits; + hQC->nElements = init->channelMapping->nElements; + hQC->bitResTotMax = init->bitRes; + hQC->bitResTot = init->bitRes; + hQC->maxBitFac = init->maxBitFac; + hQC->bitrateMode = init->bitrateMode; + hQC->invQuant = init->invQuant; + hQC->maxIterations = init->maxIterations; + + if ( isConstantBitrateMode(hQC->bitrateMode) ) { + INT bitresPerChannel = (hQC->bitResTotMax / init->channelMapping->nChannelsEff); + /* 0: full bitreservoir, 1: reduced bitreservoir, 2: disabled bitreservoir */ + hQC->bitDistributenMode = (bitresPerChannel>50) ? 0 : (bitresPerChannel>0) ? 1 : 2; + } + else { + hQC->bitDistributenMode = 0; /* full bitreservoir */ + } + + + hQC->padding.paddingRest = init->padding.paddingRest; + + hQC->globHdrBits = init->staticBits; /* Bit overhead due to transport */ + + FDKaacEnc_InitElementBits(hQC, + init->channelMapping, + init->bitrate, + (init->averageBits/init->nSubFrames) - hQC->globHdrBits, + hQC->maxBitsPerFrame/init->channelMapping->nChannelsEff); + + switch(hQC->bitrateMode){ + case QCDATA_BR_MODE_CBR: + case QCDATA_BR_MODE_VBR_1: + case QCDATA_BR_MODE_VBR_2: + case QCDATA_BR_MODE_VBR_3: + case QCDATA_BR_MODE_VBR_4: + case QCDATA_BR_MODE_VBR_5: + case QCDATA_BR_MODE_SFR: + case QCDATA_BR_MODE_FF: + if((int)hQC->bitrateMode < (int)(sizeof(tableVbrQualFactor)/sizeof(TAB_VBR_QUAL_FACTOR))){ + hQC->vbrQualFactor = (FIXP_DBL)tableVbrQualFactor[hQC->bitrateMode].vbrQualFactor; + } else { + hQC->vbrQualFactor = FL2FXCONST_DBL(0.f); /* default setting */ + } + break; + case QCDATA_BR_MODE_INVALID: + default: + hQC->vbrQualFactor = FL2FXCONST_DBL(0.f); + break; + } + + FDKaacEnc_AdjThrInit(hQC->hAdjThr, + init->meanPe, + hQC->elementBits, /* or channelBitrates, was: channelBitrate */ + init->channelMapping->nElements, + hQC->vbrQualFactor); + + return AAC_ENC_OK; +} + + + +/********************************************************************************* + + functionname: FDKaacEnc_QCMainPrepare + description: + return: + +**********************************************************************************/ +AAC_ENCODER_ERROR FDKaacEnc_QCMainPrepare(ELEMENT_INFO *elInfo, + ATS_ELEMENT* RESTRICT adjThrStateElement, + PSY_OUT_ELEMENT* RESTRICT psyOutElement, + QC_OUT_ELEMENT* RESTRICT qcOutElement, + AUDIO_OBJECT_TYPE aot, + UINT syntaxFlags, + SCHAR epConfig + ) +{ + AAC_ENCODER_ERROR ErrorStatus = AAC_ENC_OK; + INT nChannels = elInfo->nChannelsInEl; + + PSY_OUT_CHANNEL** RESTRICT psyOutChannel = psyOutElement->psyOutChannel; /* may be modified in-place */ + + FDKaacEnc_CalcFormFactor(qcOutElement->qcOutChannel, psyOutChannel, nChannels); + + /* prepare and calculate PE without reduction */ + FDKaacEnc_peCalculation(&qcOutElement->peData, psyOutChannel, qcOutElement->qcOutChannel, &psyOutElement->toolsInfo, adjThrStateElement, nChannels); + + ErrorStatus = FDKaacEnc_ChannelElementWrite( NULL, elInfo, NULL, + psyOutElement, + psyOutElement->psyOutChannel, + syntaxFlags, + aot, + epConfig, + &qcOutElement->staticBitsUsed, + 0 ); + + return ErrorStatus; +} + +/********************************************************************************* + + functionname: FDKaacEnc_AdjustBitrate + description: adjusts framelength via padding on a frame to frame basis, + to achieve a bitrate that demands a non byte aligned + framelength + return: errorcode + +**********************************************************************************/ +AAC_ENCODER_ERROR FDKaacEnc_AdjustBitrate(QC_STATE *RESTRICT hQC, + CHANNEL_MAPPING *RESTRICT cm, + INT *avgTotalBits, + INT bitRate, /* total bitrate */ + INT sampleRate, /* output sampling rate */ + INT granuleLength) /* frame length */ +{ + INT paddingOn; + INT frameLen; + + /* Do we need an extra padding byte? */ + paddingOn = FDKaacEnc_framePadding(bitRate, + sampleRate, + granuleLength, + &hQC->padding.paddingRest); + + frameLen = paddingOn + FDKaacEnc_calcFrameLen(bitRate, + sampleRate, + granuleLength, + FRAME_LEN_BYTES_INT); + + *avgTotalBits = frameLen<<3; + + return AAC_ENC_OK; +} + +static AAC_ENCODER_ERROR FDKaacEnc_distributeElementDynBits(QC_STATE* hQC, + QC_OUT_ELEMENT* qcElement[(6)], + CHANNEL_MAPPING* cm, + INT codeBits) +{ + + INT i, firstEl = cm->nElements-1; + INT totalBits = 0; + + for (i=(cm->nElements-1); i>=0; i--) { + if ((cm->elInfo[i].elType == ID_SCE) || (cm->elInfo[i].elType == ID_CPE) || + (cm->elInfo[i].elType == ID_LFE)) + { + qcElement[i]->grantedDynBits = (INT)fMult(hQC->elementBits[i]->relativeBitsEl, (FIXP_DBL)codeBits); + totalBits += qcElement[i]->grantedDynBits; + firstEl = i; + } + } + qcElement[firstEl]->grantedDynBits += codeBits - totalBits; + + return AAC_ENC_OK; +} + +/** + * \brief Verify whether minBitsPerFrame criterion can be satisfied. + * + * This function evaluates the bit consumption only if minBitsPerFrame parameter is not 0. + * In hyperframing mode the difference between grantedDynBits and usedDynBits of all sub frames + * results the number of fillbits to be written. + * This bits can be distrubitued in superframe to reach minBitsPerFrame bit consumption in single AU's. + * The return value denotes if enough desired fill bits are available to achieve minBitsPerFrame in all frames. + * This check can only be used within superframes. + * + * \param qcOut Pointer to coding data struct. + * \param minBitsPerFrame Minimal number of bits to be consumed in each frame. + * \param nSubFrames Number of frames in superframe + * + * \return + * - 1: all fine + * - 0: criterion not fulfilled + */ +static int checkMinFrameBitsDemand( + QC_OUT** qcOut, + const INT minBitsPerFrame, + const INT nSubFrames + ) +{ + int result = 1; /* all fine*/ + return result; +} + +//////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// + +//////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// +/********************************************************************************* + + functionname: FDKaacEnc_getMinimalStaticBitdemand + description: calculate minmal size of static bits by reduction , + to zero spectrum and deactivating tns and MS + return: number of static bits + +**********************************************************************************/ +static int FDKaacEnc_getMinimalStaticBitdemand(CHANNEL_MAPPING* cm, + PSY_OUT** psyOut) +{ + AUDIO_OBJECT_TYPE aot = AOT_AAC_LC; + UINT syntaxFlags = 0; + SCHAR epConfig = -1; + int i, bitcount = 0; + + for (i=0; i<cm->nElements; i++) { + ELEMENT_INFO elInfo = cm->elInfo[i]; + + if ( (elInfo.elType == ID_SCE) + || (elInfo.elType == ID_CPE) + || (elInfo.elType == ID_LFE) ) + { + INT minElBits = 0; + + FDKaacEnc_ChannelElementWrite( NULL, &elInfo, NULL, + psyOut[0]->psyOutElement[i], + psyOut[0]->psyOutElement[i]->psyOutChannel, + syntaxFlags, + aot, + epConfig, + &minElBits, + 1 ); + bitcount += minElBits; + } + } + + return bitcount; +} + +//////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// + +static AAC_ENCODER_ERROR FDKaacEnc_prepareBitDistribution(QC_STATE* hQC, + PSY_OUT** psyOut, + QC_OUT** qcOut, + CHANNEL_MAPPING* cm, + QC_OUT_ELEMENT* qcElement[(1)][(6)], + INT avgTotalBits, + INT *totalAvailableBits, + INT *avgTotalDynBits) +{ + int i; + /* get maximal allowed dynamic bits */ + qcOut[0]->grantedDynBits = (fixMin(hQC->maxBitsPerFrame, avgTotalBits) - hQC->globHdrBits)&~7; + qcOut[0]->grantedDynBits -= (qcOut[0]->globalExtBits + qcOut[0]->staticBits + qcOut[0]->elementExtBits); + qcOut[0]->maxDynBits = ((hQC->maxBitsPerFrame)&~7) - (qcOut[0]->globalExtBits + qcOut[0]->staticBits + qcOut[0]->elementExtBits); + /* assure that enough bits are available */ + if ((qcOut[0]->grantedDynBits+hQC->bitResTot) < 0) { + /* crash recovery allows to reduce static bits to a minimum */ + if ( (qcOut[0]->grantedDynBits+hQC->bitResTot) < (FDKaacEnc_getMinimalStaticBitdemand(cm, psyOut)-qcOut[0]->staticBits) ) + return AAC_ENC_BITRES_TOO_LOW; + } + + /* distribute dynamic bits to each element */ + FDKaacEnc_distributeElementDynBits(hQC, + qcElement[0], + cm, + qcOut[0]->grantedDynBits); + + *avgTotalDynBits = 0; /*frameDynBits;*/ + + *totalAvailableBits = avgTotalBits; + + /* sum up corrected granted PE */ + qcOut[0]->totalGrantedPeCorr = 0; + + for (i=0; i<cm->nElements; i++) + { + ELEMENT_INFO elInfo = cm->elInfo[i]; + int nChannels = elInfo.nChannelsInEl; + + if ((elInfo.elType == ID_SCE) || (elInfo.elType == ID_CPE) || + (elInfo.elType == ID_LFE)) + { + /* for ( all sub frames ) ... */ + FDKaacEnc_DistributeBits(hQC->hAdjThr, + hQC->hAdjThr->adjThrStateElem[i], + psyOut[0]->psyOutElement[i]->psyOutChannel, + &qcElement[0][i]->peData, + &qcElement[0][i]->grantedPe, + &qcElement[0][i]->grantedPeCorr, + nChannels, + psyOut[0]->psyOutElement[i]->commonWindow, + qcElement[0][i]->grantedDynBits, + hQC->elementBits[i]->bitResLevelEl, + hQC->elementBits[i]->maxBitResBitsEl, + hQC->maxBitFac, + hQC->bitDistributenMode); + + *totalAvailableBits += hQC->elementBits[i]->bitResLevelEl; + /* get total corrected granted PE */ + qcOut[0]->totalGrantedPeCorr += qcElement[0][i]->grantedPeCorr; + } /* -end- if(ID_SCE || ID_CPE || ID_LFE) */ + + } /* -end- element loop */ + + *totalAvailableBits = FDKmin(hQC->maxBitsPerFrame, (*totalAvailableBits)); + + return AAC_ENC_OK; +} + +//////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// +static AAC_ENCODER_ERROR FDKaacEnc_updateUsedDynBits(INT* sumDynBitsConsumed, + QC_OUT_ELEMENT* qcElement[(6)], + CHANNEL_MAPPING* cm) +{ + INT i; + + *sumDynBitsConsumed = 0; + + for (i=0; i<cm->nElements; i++) + { + ELEMENT_INFO elInfo = cm->elInfo[i]; + + if ((elInfo.elType == ID_SCE) || (elInfo.elType == ID_CPE) || + (elInfo.elType == ID_LFE)) + { + /* sum up bits consumed */ + *sumDynBitsConsumed += qcElement[i]->dynBitsUsed; + } /* -end- if(ID_SCE || ID_CPE || ID_LFE) */ + + } /* -end- element loop */ + + return AAC_ENC_OK; +} + + +static INT FDKaacEnc_getTotalConsumedDynBits(QC_OUT** qcOut, + INT nSubFrames) +{ + INT c, totalBits=0; + + /* sum up bit consumption for all sub frames */ + for (c=0; c<nSubFrames; c++) + { + /* bit consumption not valid if dynamic bits + not available in one sub frame */ + if (qcOut[c]->usedDynBits==-1) return -1; + totalBits += qcOut[c]->usedDynBits; + } + + return totalBits; + +} + +static INT FDKaacEnc_getTotalConsumedBits(QC_OUT** qcOut, + QC_OUT_ELEMENT* qcElement[(1)][(6)], + CHANNEL_MAPPING* cm, + INT globHdrBits, + INT nSubFrames) +{ + int c, i; + int totalUsedBits = 0; + + for (c = 0 ; c < nSubFrames ; c++ ) + { + int dataBits = 0; + for (i=0; i<cm->nElements; i++) + { + if ((cm->elInfo[i].elType == ID_SCE) || (cm->elInfo[i].elType == ID_CPE) || + (cm->elInfo[i].elType == ID_LFE)) + { + dataBits += qcElement[c][i]->dynBitsUsed + qcElement[c][i]->staticBitsUsed + qcElement[c][i]->extBitsUsed; + } + } + dataBits += qcOut[c]->globalExtBits; + + totalUsedBits += (8 - (dataBits) % 8) % 8; + totalUsedBits += dataBits + globHdrBits; /* header bits for every frame */ + } + return totalUsedBits; +} + +static AAC_ENCODER_ERROR FDKaacEnc_BitResRedistribution( + QC_STATE *const hQC, + const CHANNEL_MAPPING *const cm, + const INT avgTotalBits + ) +{ + /* check bitreservoir fill level */ + if (hQC->bitResTot < 0) { + return AAC_ENC_BITRES_TOO_LOW; + } + else if (hQC->bitResTot > hQC->bitResTotMax) { + return AAC_ENC_BITRES_TOO_HIGH; + } + else { + INT i, firstEl = cm->nElements-1; + INT totalBits = 0, totalBits_max = 0; + + int totalBitreservoir = FDKmin(hQC->bitResTot, (hQC->maxBitsPerFrame-avgTotalBits)); + int totalBitreservoirMax = FDKmin(hQC->bitResTotMax, (hQC->maxBitsPerFrame-avgTotalBits)); + + int sc_bitResTot = CountLeadingBits(totalBitreservoir); + int sc_bitResTotMax = CountLeadingBits(totalBitreservoirMax); + + for (i=(cm->nElements-1); i>=0; i--) { + if ((cm->elInfo[i].elType == ID_SCE) || (cm->elInfo[i].elType == ID_CPE) || + (cm->elInfo[i].elType == ID_LFE)) + { + hQC->elementBits[i]->bitResLevelEl = (INT)fMult(hQC->elementBits[i]->relativeBitsEl, (FIXP_DBL)(totalBitreservoir<<sc_bitResTot))>>sc_bitResTot; + totalBits += hQC->elementBits[i]->bitResLevelEl; + + hQC->elementBits[i]->maxBitResBitsEl = (INT)fMult(hQC->elementBits[i]->relativeBitsEl, (FIXP_DBL)(totalBitreservoirMax<<sc_bitResTotMax))>>sc_bitResTotMax; + totalBits_max += hQC->elementBits[i]->maxBitResBitsEl; + + firstEl = i; + } + } + hQC->elementBits[firstEl]->bitResLevelEl += totalBitreservoir - totalBits; + hQC->elementBits[firstEl]->maxBitResBitsEl += totalBitreservoirMax - totalBits_max; + } + + return AAC_ENC_OK; +} + + +AAC_ENCODER_ERROR FDKaacEnc_QCMain(QC_STATE* RESTRICT hQC, + PSY_OUT** psyOut, + QC_OUT** qcOut, + INT avgTotalBits, + CHANNEL_MAPPING* cm + ,AUDIO_OBJECT_TYPE aot, + UINT syntaxFlags, + SCHAR epConfig + ) +{ + int i, c; + AAC_ENCODER_ERROR ErrorStatus = AAC_ENC_OK; + INT avgTotalDynBits = 0; /* maximal allowd dynamic bits for all frames */ + INT totalAvailableBits = 0; + INT nSubFrames = 1; + + /*-------------------------------------------- */ + /* redistribute total bitreservoir to elements */ + ErrorStatus = FDKaacEnc_BitResRedistribution(hQC, cm, avgTotalBits); + if (ErrorStatus != AAC_ENC_OK) { + return ErrorStatus; + } + + /*-------------------------------------------- */ + /* fastenc needs one time threshold simulation, + in case of multiple frames, one more guess has to be calculated */ + + /*-------------------------------------------- */ + /* helper pointer */ + QC_OUT_ELEMENT* qcElement[(1)][(6)]; + + /* work on a copy of qcChannel and qcElement */ + for (i=0; i<cm->nElements; i++) + { + ELEMENT_INFO elInfo = cm->elInfo[i]; + + if ((elInfo.elType == ID_SCE) || (elInfo.elType == ID_CPE) || + (elInfo.elType == ID_LFE)) + { + /* for ( all sub frames ) ... */ + for (c = 0 ; c < nSubFrames ; c++ ) + { + { + qcElement[c][i] = qcOut[c]->qcElement[i]; + } + } + } + } + + /*-------------------------------------------- */ + /*-------------------------------------------- */ + if ( isConstantBitrateMode(hQC->bitrateMode) ) + { + /* calc granted dynamic bits for sub frame and + distribute it to each element */ + ErrorStatus = FDKaacEnc_prepareBitDistribution( + hQC, + psyOut, + qcOut, + cm, + qcElement, + avgTotalBits, + &totalAvailableBits, + &avgTotalDynBits); + + if (ErrorStatus != AAC_ENC_OK) { + return ErrorStatus; + } + } + else { + qcOut[0]->grantedDynBits = ((hQC->maxBitsPerFrame - (hQC->globHdrBits))&~7) + - (qcOut[0]->globalExtBits + qcOut[0]->staticBits + qcOut[0]->elementExtBits); + qcOut[0]->maxDynBits = qcOut[0]->grantedDynBits; + + totalAvailableBits = hQC->maxBitsPerFrame; + avgTotalDynBits = 0; + } + +#ifdef PNS_PRECOUNT_ENABLE + /* Calculate estimated pns bits and substract them from grantedDynBits to get a more accurate number of available bits. */ + if (syntaxFlags & (AC_LD|AC_ELD)) + { + int estimatedPnsBits = 0, ch; + + for (ch=0; ch<cm->nChannels; ch++) { + qcOut[0]->pQcOutChannels[ch]->sectionData.noiseNrgBits = noisePreCount(psyOut[0]->pPsyOutChannels[ch]->noiseNrg, psyOut[0]->pPsyOutChannels[ch]->maxSfbPerGroup); + estimatedPnsBits += qcOut[0]->pQcOutChannels[ch]->sectionData.noiseNrgBits; + } + qcOut[0]->grantedDynBits -= estimatedPnsBits; + } +#endif + + /* for ( all sub frames ) ... */ + for (c = 0 ; c < nSubFrames ; c++ ) + { + /* for CBR and VBR mode */ + FDKaacEnc_AdjustThresholds(hQC->hAdjThr->adjThrStateElem, + qcElement[c], + qcOut[c], + psyOut[c]->psyOutElement, + isConstantBitrateMode(hQC->bitrateMode), + cm); + + } /* -end- sub frame counter */ + + /*-------------------------------------------- */ + INT iterations[(1)][(6)]; + INT chConstraintsFulfilled[(1)][(6)][(2)]; + INT calculateQuant[(1)][(6)][(2)]; + INT constraintsFulfilled[(1)][(6)]; + /*-------------------------------------------- */ + + + /* for ( all sub frames ) ... */ + for (c = 0 ; c < nSubFrames ; c++ ) + { + for (i=0; i<cm->nElements; i++) + { + ELEMENT_INFO elInfo = cm->elInfo[i]; + INT ch, nChannels = elInfo.nChannelsInEl; + + if ((elInfo.elType == ID_SCE) || (elInfo.elType == ID_CPE) || + (elInfo.elType == ID_LFE)) + { + /* Turn thresholds into scalefactors, optimize bit consumption and verify conformance */ + FDKaacEnc_EstimateScaleFactors(psyOut[c]->psyOutElement[i]->psyOutChannel, + qcElement[c][i]->qcOutChannel, + hQC->invQuant, + cm->elInfo[i].nChannelsInEl); + + + /*-------------------------------------------- */ + constraintsFulfilled[c][i] = 1; + iterations[c][i] = 0 ; + + for (ch = 0; ch < nChannels; ch++) + { + chConstraintsFulfilled[c][i][ch] = 1; + calculateQuant[c][i][ch] = 1; + } + + /*-------------------------------------------- */ + + } /* -end- if(ID_SCE || ID_CPE || ID_LFE) */ + + } /* -end- element loop */ + + qcOut[c]->usedDynBits = -1; + + } /* -end- sub frame counter */ + + + + INT quantizationDone = 0; + INT sumDynBitsConsumedTotal = 0; + INT decreaseBitConsumption = -1; /* no direction yet! */ + + /*-------------------------------------------- */ + /* -start- Quantization loop ... */ + /*-------------------------------------------- */ + do /* until max allowed bits per frame and maxDynBits!=-1*/ + { + quantizationDone = 0; + + c = 0; /* get frame to process */ + + for (i=0; i<cm->nElements; i++) + { + ELEMENT_INFO elInfo = cm->elInfo[i]; + INT ch, nChannels = elInfo.nChannelsInEl; + + if ((elInfo.elType == ID_SCE) || (elInfo.elType == ID_CPE) || + (elInfo.elType == ID_LFE)) + { + do /* until spectral values < MAX_QUANT */ + { + /*-------------------------------------------- */ + if (!constraintsFulfilled[c][i]) + { + FDKaacEnc_reduceBitConsumption(&iterations[c][i], + hQC->maxIterations, + (decreaseBitConsumption) ? 1 : -1, + chConstraintsFulfilled[c][i], + calculateQuant[c][i], + nChannels, + psyOut[c]->psyOutElement[i], + qcOut[c], + qcElement[c][i], + hQC->elementBits[i], + aot, + syntaxFlags, + epConfig); + } + + /*-------------------------------------------- */ + /*-------------------------------------------- */ + constraintsFulfilled[c][i] = 1 ; + + /*-------------------------------------------- */ + /* quantize spectrum (per each channel) */ + for (ch = 0; ch < nChannels; ch++) + { + /*-------------------------------------------- */ + chConstraintsFulfilled[c][i][ch] = 1; + + /*-------------------------------------------- */ + + if (calculateQuant[c][i][ch]) + { + QC_OUT_CHANNEL* qcOutCh = qcElement[c][i]->qcOutChannel[ch]; + PSY_OUT_CHANNEL* psyOutCh = psyOut[c]->psyOutElement[i]->psyOutChannel[ch]; + + calculateQuant[c][i][ch] = 0; /* calculate quantization only if necessary */ + + /*-------------------------------------------- */ + FDKaacEnc_QuantizeSpectrum(psyOutCh->sfbCnt, + psyOutCh->maxSfbPerGroup, + psyOutCh->sfbPerGroup, + psyOutCh->sfbOffsets, + qcOutCh->mdctSpectrum, + qcOutCh->globalGain, + qcOutCh->scf, + qcOutCh->quantSpec) ; + + /*-------------------------------------------- */ + if (FDKaacEnc_calcMaxValueInSfb(psyOutCh->sfbCnt, + psyOutCh->maxSfbPerGroup, + psyOutCh->sfbPerGroup, + psyOutCh->sfbOffsets, + qcOutCh->quantSpec, + qcOutCh->maxValueInSfb) > MAX_QUANT) + { + chConstraintsFulfilled[c][i][ch] = 0; + constraintsFulfilled[c][i] = 0 ; + /* if quanizted value out of range; increase global gain! */ + decreaseBitConsumption = 1; + } + + /*-------------------------------------------- */ + + } /* if calculateQuant[c][i][ch] */ + + } /* channel loop */ + + /*-------------------------------------------- */ + /* quantize spectrum (per each channel) */ + + /*-------------------------------------------- */ + + } while (!constraintsFulfilled[c][i]) ; /* does not regard bit consumption */ + + + /*-------------------------------------------- */ + /*-------------------------------------------- */ + qcElement[c][i]->dynBitsUsed = 0 ; /* reset dynamic bits */ + + /* quantization valid in current channel! */ + for (ch = 0; ch < nChannels; ch++) + { + QC_OUT_CHANNEL* qcOutCh = qcElement[c][i]->qcOutChannel[ch]; + PSY_OUT_CHANNEL *psyOutCh = psyOut[c]->psyOutElement[i]->psyOutChannel[ch]; + + /* count dynamic bits */ + INT chDynBits = FDKaacEnc_dynBitCount(hQC->hBitCounter, + qcOutCh->quantSpec, + qcOutCh->maxValueInSfb, + qcOutCh->scf, + psyOutCh->lastWindowSequence, + psyOutCh->sfbCnt, + psyOutCh->maxSfbPerGroup, + psyOutCh->sfbPerGroup, + psyOutCh->sfbOffsets, + &qcOutCh->sectionData, + psyOutCh->noiseNrg, + psyOutCh->isBook, + psyOutCh->isScale, + syntaxFlags) ; + + /* sum up dynamic channel bits */ + qcElement[c][i]->dynBitsUsed += chDynBits; + } + + /* save dynBitsUsed for correction of bits2pe relation */ + if(hQC->hAdjThr->adjThrStateElem[i]->dynBitsLast==-1) { + hQC->hAdjThr->adjThrStateElem[i]->dynBitsLast = qcElement[c][i]->dynBitsUsed; + } + } /* -end- if(ID_SCE || ID_CPE || ID_LFE) */ + + } /* -end- element loop */ + + /* update dynBits of current subFrame */ + FDKaacEnc_updateUsedDynBits(&qcOut[c]->usedDynBits, + qcElement[c], + cm); + + /* get total consumed bits, dyn bits in all sub frames have to be valid */ + sumDynBitsConsumedTotal = FDKaacEnc_getTotalConsumedDynBits(qcOut, nSubFrames); + + if (sumDynBitsConsumedTotal==-1) + { + quantizationDone = 0; /* bit consumption not valid in all sub frames */ + } + else + { + int sumBitsConsumedTotal = FDKaacEnc_getTotalConsumedBits(qcOut, qcElement, cm, hQC->globHdrBits, nSubFrames); + + /* in all frames are valid dynamic bits */ + if (sumBitsConsumedTotal < totalAvailableBits && (decreaseBitConsumption==1) && checkMinFrameBitsDemand(qcOut,hQC->minBitsPerFrame,nSubFrames) + /*()*/ ) + { + quantizationDone = 1; /* exit bit adjustment */ + } + if (sumBitsConsumedTotal > totalAvailableBits && (decreaseBitConsumption==0) ) +// /*()*/ ) + { + quantizationDone = 0; /* reset! */ + break; + } + } + + + /*-------------------------------------------- */ + + int emergencyIterations = 1; + int dynBitsOvershoot = 0; + + for (c = 0 ; c < nSubFrames ; c++ ) + { + for (i=0; i<cm->nElements; i++) + { + ELEMENT_INFO elInfo = cm->elInfo[i]; + + if ((elInfo.elType == ID_SCE) || (elInfo.elType == ID_CPE) || + (elInfo.elType == ID_LFE)) + { + /* iteration limitation */ + emergencyIterations &= ((iterations[c][i] < hQC->maxIterations) ? 0 : 1); + } + } + /* detection if used dyn bits exceeds the maximal allowed criterion */ + dynBitsOvershoot |= ((qcOut[c]->usedDynBits > qcOut[c]->maxDynBits) ? 1 : 0); + } + + if (quantizationDone==0 || dynBitsOvershoot) + { + + int sumBitsConsumedTotal = FDKaacEnc_getTotalConsumedBits(qcOut, qcElement, cm, hQC->globHdrBits, nSubFrames); + + if ( (sumDynBitsConsumedTotal >= avgTotalDynBits) || (sumDynBitsConsumedTotal==0) ) { + quantizationDone = 1; + } + if (emergencyIterations && (sumBitsConsumedTotal < totalAvailableBits)) { + quantizationDone = 1; + } + if ((sumBitsConsumedTotal > totalAvailableBits) || !checkMinFrameBitsDemand(qcOut,hQC->minBitsPerFrame,nSubFrames)) { + quantizationDone = 0; + } + if ((sumBitsConsumedTotal < totalAvailableBits) && checkMinFrameBitsDemand(qcOut,hQC->minBitsPerFrame,nSubFrames)) { + decreaseBitConsumption = 0; + } + else { + decreaseBitConsumption = 1; + } + + if (dynBitsOvershoot) { + quantizationDone = 0; + decreaseBitConsumption = 1; + } + + /* reset constraints fullfilled flags */ + FDKmemclear(constraintsFulfilled, sizeof(constraintsFulfilled)); + FDKmemclear(chConstraintsFulfilled, sizeof(chConstraintsFulfilled)); + + + }/* quantizationDone */ + + } while (!quantizationDone) ; + + /*-------------------------------------------- */ + /* ... -end- Quantization loop */ + /*-------------------------------------------- */ + + /*-------------------------------------------- */ + /*-------------------------------------------- */ + + return AAC_ENC_OK; +} + + +static AAC_ENCODER_ERROR FDKaacEnc_reduceBitConsumption(int* iterations, + const int maxIterations, + int gainAdjustment, + int* chConstraintsFulfilled, + int* calculateQuant, + int nChannels, + PSY_OUT_ELEMENT* psyOutElement, + QC_OUT* qcOut, + QC_OUT_ELEMENT* qcOutElement, + ELEMENT_BITS* elBits, + AUDIO_OBJECT_TYPE aot, + UINT syntaxFlags, + SCHAR epConfig) +{ + int ch; + + /** SOLVING PROBLEM **/ + if ((*iterations)++ >= maxIterations) + { + if (qcOutElement->dynBitsUsed==0) { + } + /* crash recovery */ + else { + INT bitsToSave = 0; + if ( (bitsToSave = fixMax((qcOutElement->dynBitsUsed + 8) - (elBits->bitResLevelEl + qcOutElement->grantedDynBits), + (qcOutElement->dynBitsUsed + qcOutElement->staticBitsUsed + 8) - (elBits->maxBitsEl))) > 0 ) + { + FDKaacEnc_crashRecovery(nChannels, + psyOutElement, + qcOut, + qcOutElement, + bitsToSave, + aot, + syntaxFlags, + epConfig) ; + } + else + { + for (ch = 0; ch < nChannels; ch++) + { + qcOutElement->qcOutChannel[ch]->globalGain += 1; + } + } + for (ch = 0; ch < nChannels; ch++) + { + calculateQuant[ch] = 1; + } + } + } + else /* iterations >= maxIterations */ + { + /* increase gain (+ next iteration) */ + for (ch = 0; ch < nChannels; ch++) + { + if(!chConstraintsFulfilled[ch]) + { + qcOutElement->qcOutChannel[ch]->globalGain += gainAdjustment ; + calculateQuant[ch] = 1; /* global gain has changed, recalculate quantization in next iteration! */ + } + } + } + + return AAC_ENC_OK; +} + +AAC_ENCODER_ERROR FDKaacEnc_updateFillBits(CHANNEL_MAPPING* cm, + QC_STATE* qcKernel, + ELEMENT_BITS* RESTRICT elBits[(6)], + QC_OUT** qcOut) +{ + switch (qcKernel->bitrateMode) { + case QCDATA_BR_MODE_SFR: + break; + + case QCDATA_BR_MODE_FF: + break; + + case QCDATA_BR_MODE_VBR_1: + case QCDATA_BR_MODE_VBR_2: + case QCDATA_BR_MODE_VBR_3: + case QCDATA_BR_MODE_VBR_4: + case QCDATA_BR_MODE_VBR_5: + qcOut[0]->totFillBits = (qcOut[0]->grantedDynBits - qcOut[0]->usedDynBits)&7; /* precalculate alignment bits */ + break; + + case QCDATA_BR_MODE_CBR: + case QCDATA_BR_MODE_INVALID: + default: + INT bitResSpace = qcKernel->bitResTotMax - qcKernel->bitResTot ; + /* processing fill-bits */ + INT deltaBitRes = qcOut[0]->grantedDynBits - qcOut[0]->usedDynBits ; + qcOut[0]->totFillBits = fixMax((deltaBitRes&7), (deltaBitRes - (fixMax(0,bitResSpace-7)&~7))); + break; + } /* switch (qcKernel->bitrateMode) */ + + return AAC_ENC_OK; +} + + + + +/********************************************************************************* + + functionname: FDKaacEnc_calcMaxValueInSfb + description: + return: + +**********************************************************************************/ + +static INT FDKaacEnc_calcMaxValueInSfb(INT sfbCnt, + INT maxSfbPerGroup, + INT sfbPerGroup, + INT *RESTRICT sfbOffset, + SHORT *RESTRICT quantSpectrum, + UINT *RESTRICT maxValue) +{ + INT sfbOffs,sfb; + INT maxValueAll = 0; + + for (sfbOffs=0;sfbOffs<sfbCnt;sfbOffs+=sfbPerGroup) + for (sfb = 0; sfb < maxSfbPerGroup; sfb++) + { + INT line; + INT maxThisSfb = 0; + for (line = sfbOffset[sfbOffs+sfb]; line < sfbOffset[sfbOffs+sfb+1]; line++) + { + INT tmp = fixp_abs(quantSpectrum[line]); + maxThisSfb = fixMax(tmp, maxThisSfb); + } + + maxValue[sfbOffs+sfb] = maxThisSfb; + maxValueAll = fixMax(maxThisSfb, maxValueAll); + } + return maxValueAll; +} + + +/********************************************************************************* + + functionname: FDKaacEnc_updateBitres + description: + return: + +**********************************************************************************/ +void FDKaacEnc_updateBitres(CHANNEL_MAPPING *cm, + QC_STATE* qcKernel, + QC_OUT** qcOut) +{ + switch (qcKernel->bitrateMode) { + case QCDATA_BR_MODE_FF: + case QCDATA_BR_MODE_VBR_1: + case QCDATA_BR_MODE_VBR_2: + case QCDATA_BR_MODE_VBR_3: + case QCDATA_BR_MODE_VBR_4: + case QCDATA_BR_MODE_VBR_5: + /* variable bitrate */ + qcKernel->bitResTot = FDKmin(qcKernel->maxBitsPerFrame, qcKernel->bitResTotMax); + break; + + case QCDATA_BR_MODE_CBR: + case QCDATA_BR_MODE_SFR: + case QCDATA_BR_MODE_INVALID: + default: + int c = 0; + /* constant bitrate */ + { + qcKernel->bitResTot += qcOut[c]->grantedDynBits - (qcOut[c]->usedDynBits + qcOut[c]->totFillBits + qcOut[c]->alignBits); + } + break; + } +} + +/********************************************************************************* + + functionname: FDKaacEnc_FinalizeBitConsumption + description: + return: + +**********************************************************************************/ +AAC_ENCODER_ERROR FDKaacEnc_FinalizeBitConsumption(CHANNEL_MAPPING *cm, + QC_STATE *qcKernel, + QC_OUT *qcOut, + QC_OUT_ELEMENT** qcElement, + HANDLE_TRANSPORTENC hTpEnc, + AUDIO_OBJECT_TYPE aot, + UINT syntaxFlags, + SCHAR epConfig) +{ + QC_OUT_EXTENSION fillExtPayload; + INT totFillBits, alignBits; + + { + int exactTpBits; + int max_iter = 3; + + /* Get total consumed bits in AU */ + qcOut->totalBits = qcOut->staticBits + qcOut->usedDynBits + qcOut->totFillBits + + qcOut->elementExtBits + qcOut->globalExtBits; + + /* Now we can get the exact transport bit amount, and hopefully it is equal to the estimated value */ + exactTpBits = transportEnc_GetStaticBits(hTpEnc, qcOut->totalBits); + + if (exactTpBits != qcKernel->globHdrBits) { + INT diffFillBits = 0; + + /* Number of bits which can be moved to bitreservoir. */ + INT bitsToBitres = qcKernel->globHdrBits - exactTpBits; + + if (bitsToBitres>0) { + /* if bitreservoir can not take all bits, move ramaining bits to fillbits */ + diffFillBits = FDKmax(0, bitsToBitres - (qcKernel->bitResTotMax-qcKernel->bitResTot)); + } + else if (bitsToBitres<0) { + /* if bits mus be taken from bitreservoir, reduce fillbits first. */ + diffFillBits = (FDKmax(FDKmax(bitsToBitres, -qcKernel->bitResTot), -qcOut->totFillBits)); + } + + diffFillBits = (diffFillBits+7)&~7; /* assure previous alignment */ + + qcOut->totFillBits += diffFillBits; + qcOut->totalBits += diffFillBits; + qcOut->grantedDynBits += diffFillBits; + + /* new header bits */ + qcKernel->globHdrBits = transportEnc_GetStaticBits(hTpEnc, qcOut->totalBits); + } + } + + /* Save total fill bits and distribut to alignment and fill bits */ + totFillBits = qcOut->totFillBits; + + /* fake a fill extension payload */ + FDKmemclear(&fillExtPayload, sizeof(QC_OUT_EXTENSION)); + + fillExtPayload.type = EXT_FILL_DATA; + fillExtPayload.nPayloadBits = totFillBits; + + /* ask bitstream encoder how many of that bits can be written in a fill extension data entity */ + qcOut->totFillBits = FDKaacEnc_writeExtensionData( NULL, + &fillExtPayload, + 0, 0, + syntaxFlags, + aot, + epConfig ); + + /* now distribute extra fillbits and alignbits */ + alignBits = 7 - (qcOut->staticBits + qcOut->usedDynBits + qcOut->elementExtBits + + qcOut->totFillBits + qcOut->globalExtBits -1)%8; + + /* Maybe we could remove this */ + if( ((alignBits + qcOut->totFillBits - totFillBits)==8) && (qcOut->totFillBits>8) ) + qcOut->totFillBits -= 8; + + qcOut->totalBits = qcOut->staticBits + qcOut->usedDynBits + qcOut->totFillBits + + alignBits + qcOut->elementExtBits + qcOut->globalExtBits; + + if ( (qcOut->totalBits>qcKernel->maxBitsPerFrame) || (qcOut->totalBits<qcKernel->minBitsPerFrame) ) { + return AAC_ENC_QUANT_ERROR; + } + + qcOut->alignBits = alignBits; + + return AAC_ENC_OK; +} + + + +/********************************************************************************* + + functionname: FDKaacEnc_crashRecovery + description: fulfills constraints by means of brute force... + => bits are saved by cancelling out spectral lines!! + (beginning at the highest frequencies) + return: errorcode + +**********************************************************************************/ + +static void FDKaacEnc_crashRecovery(INT nChannels, + PSY_OUT_ELEMENT* psyOutElement, + QC_OUT* qcOut, + QC_OUT_ELEMENT *qcElement, + INT bitsToSave, + AUDIO_OBJECT_TYPE aot, + UINT syntaxFlags, + SCHAR epConfig) +{ + INT ch ; + INT savedBits = 0 ; + INT sfb, sfbGrp ; + INT bitsPerScf[(2)][MAX_GROUPED_SFB] ; + INT sectionToScf[(2)][MAX_GROUPED_SFB] ; + INT *sfbOffset ; + INT sect, statBitsNew ; + QC_OUT_CHANNEL **qcChannel = qcElement->qcOutChannel; + PSY_OUT_CHANNEL **psyChannel = psyOutElement->psyOutChannel; + + /* create a table which converts frq-bins to bit-demand... [bitsPerScf] */ + /* ...and another one which holds the corresponding sections [sectionToScf] */ + for (ch = 0; ch < nChannels; ch++) + { + sfbOffset = psyChannel[ch]->sfbOffsets ; + + for (sect = 0; sect < qcChannel[ch]->sectionData.noOfSections; sect++) + { + INT sfb ; + INT codeBook = qcChannel[ch]->sectionData.huffsection[sect].codeBook ; + + for (sfb = qcChannel[ch]->sectionData.huffsection[sect].sfbStart; + sfb < qcChannel[ch]->sectionData.huffsection[sect].sfbStart + + qcChannel[ch]->sectionData.huffsection[sect].sfbCnt; + sfb++) + { + bitsPerScf[ch][sfb] = 0; + if ( (codeBook != CODE_BOOK_PNS_NO) /*&& + (sfb < (qcChannel[ch]->sectionData.noOfGroups*qcChannel[ch]->sectionData.maxSfbPerGroup))*/ ) + { + INT sfbStartLine = sfbOffset[sfb] ; + INT noOfLines = sfbOffset[sfb+1] - sfbStartLine ; + bitsPerScf[ch][sfb] = FDKaacEnc_countValues(&(qcChannel[ch]->quantSpec[sfbStartLine]), noOfLines, codeBook) ; + } + sectionToScf[ch][sfb] = sect ; + } + + } + } + + /* LOWER [maxSfb] IN BOTH CHANNELS!! */ + /* Attention: in case of stereo: maxSfbL == maxSfbR, GroupingL == GroupingR ; */ + + for (sfb = qcChannel[0]->sectionData.maxSfbPerGroup-1; sfb >= 0; sfb--) + { + for (sfbGrp = 0; sfbGrp < psyChannel[0]->sfbCnt; sfbGrp += psyChannel[0]->sfbPerGroup) + { + for (ch = 0; ch < nChannels; ch++) + { + int sect = sectionToScf[ch][sfbGrp+sfb]; + qcChannel[ch]->sectionData.huffsection[sect].sfbCnt-- ; + savedBits += bitsPerScf[ch][sfbGrp+sfb] ; + + if (qcChannel[ch]->sectionData.huffsection[sect].sfbCnt == 0) { + savedBits += (psyChannel[ch]->lastWindowSequence!=SHORT_WINDOW) ? FDKaacEnc_sideInfoTabLong[0] + : FDKaacEnc_sideInfoTabShort[0]; + } + } + } + + /* ...have enough bits been saved? */ + if (savedBits >= bitsToSave) + break ; + + } /* sfb loop */ + + /* if not enough bits saved, + clean whole spectrum and remove side info overhead */ + if (sfb == -1) { + sfb = 0 ; + } + + for (ch = 0; ch < nChannels; ch++) + { + qcChannel[ch]->sectionData.maxSfbPerGroup = sfb ; + psyChannel[ch]->maxSfbPerGroup = sfb ; + /* when no spectrum is coded save tools info in bitstream */ + if(sfb==0) { + FDKmemclear(&psyChannel[ch]->tnsInfo, sizeof(TNS_INFO)); + FDKmemclear(&psyOutElement->toolsInfo, sizeof(TOOLSINFO)); + } + } + /* dynamic bits will be updated in iteration loop */ + + { /* if stop sfb has changed save bits in side info, e.g. MS or TNS coding */ + ELEMENT_INFO elInfo; + + FDKmemclear(&elInfo, sizeof(ELEMENT_INFO)); + elInfo.nChannelsInEl = nChannels; + elInfo.elType = (nChannels == 2) ? ID_CPE : ID_SCE; + + FDKaacEnc_ChannelElementWrite( NULL, &elInfo, NULL, + psyOutElement, + psyChannel, + syntaxFlags, + aot, + epConfig, + &statBitsNew, + 0 ); + } + + savedBits = qcElement->staticBitsUsed - statBitsNew; + + /* update static and dynamic bits */ + qcElement->staticBitsUsed -= savedBits; + qcElement->grantedDynBits += savedBits; + + qcOut->staticBits -= savedBits; + qcOut->grantedDynBits += savedBits; + qcOut->maxDynBits += savedBits; + + +} + + + +void FDKaacEnc_QCClose (QC_STATE **phQCstate, QC_OUT **phQC) +{ + int n, i; + + if (phQC!=NULL) { + + for (n=0;n<(1);n++) { + if (phQC[n] != NULL) { + QC_OUT *hQC = phQC[n]; + for (i=0; i<(6); i++) { + } + + for (i=0; i<(6); i++) { + if (hQC->qcElement[i]) + FreeRam_aacEnc_QCelement(&hQC->qcElement[i]); + } + + FreeRam_aacEnc_QCout(&phQC[n]); + } + } + } + + if (phQCstate!=NULL) { + if (*phQCstate != NULL) { + QC_STATE *hQCstate = *phQCstate; + + if (hQCstate->hAdjThr != NULL) + FDKaacEnc_AdjThrClose(&hQCstate->hAdjThr); + + if (hQCstate->hBitCounter != NULL) + FDKaacEnc_BCClose(&hQCstate->hBitCounter); + + for (i=0; i<(6); i++) { + if (hQCstate->elementBits[i]!=NULL) { + FreeRam_aacEnc_ElementBits(&hQCstate->elementBits[i]); + } + } + FreeRam_aacEnc_QCstate(phQCstate); + } + } +} + |