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authorMatthias P. Braendli <matthias.braendli@mpb.li>2020-03-31 10:03:58 +0200
committerMatthias P. Braendli <matthias.braendli@mpb.li>2020-03-31 10:03:58 +0200
commita1eb6cf861d3c1cbd4e6c016be3cbd2a1e3d797d (patch)
tree2b4790eec8f47fb086e645717f07c53b30ace919 /fdk-aac/libAACenc/src/psy_main.cpp
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parentc6a73c219dbfdfe639372d9922f4eb512f06fa2f (diff)
downloadODR-AudioEnc-a1eb6cf861d3c1cbd4e6c016be3cbd2a1e3d797d.tar.gz
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+/* -----------------------------------------------------------------------------
+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
+----------------------------------------------------------------------------- */
+
+/**************************** AAC encoder library ******************************
+
+ Author(s): M.Werner
+
+ Description: Psychoaccoustic major function block
+
+*******************************************************************************/
+
+#include "psy_const.h"
+
+#include "block_switch.h"
+#include "transform.h"
+#include "spreading.h"
+#include "pre_echo_control.h"
+#include "band_nrg.h"
+#include "psy_configuration.h"
+#include "psy_data.h"
+#include "ms_stereo.h"
+#include "interface.h"
+#include "psy_main.h"
+#include "grp_data.h"
+#include "tns_func.h"
+#include "pns_func.h"
+#include "tonality.h"
+#include "aacEnc_ram.h"
+#include "intensity.h"
+
+/* blending to reduce gibbs artifacts */
+#define FADE_OUT_LEN 6
+static const FIXP_DBL fadeOutFactor[FADE_OUT_LEN] = {
+ 1840644096, 1533870080, 1227096064, 920322048, 613548032, 306774016};
+
+/* forward definitions */
+
+/*****************************************************************************
+
+ functionname: FDKaacEnc_PsyNew
+ description: allocates memory for psychoacoustic
+ returns: an error code
+ input: pointer to a psych handle
+
+*****************************************************************************/
+AAC_ENCODER_ERROR FDKaacEnc_PsyNew(PSY_INTERNAL **phpsy, const INT nElements,
+ const INT nChannels, UCHAR *dynamic_RAM) {
+ AAC_ENCODER_ERROR ErrorStatus;
+ PSY_INTERNAL *hPsy;
+ INT i;
+
+ hPsy = GetRam_aacEnc_PsyInternal();
+ *phpsy = hPsy;
+ if (hPsy == NULL) {
+ ErrorStatus = AAC_ENC_NO_MEMORY;
+ goto bail;
+ }
+
+ for (i = 0; i < nElements; i++) {
+ /* PSY_ELEMENT */
+ hPsy->psyElement[i] = GetRam_aacEnc_PsyElement(i);
+ if (hPsy->psyElement[i] == NULL) {
+ ErrorStatus = AAC_ENC_NO_MEMORY;
+ goto bail;
+ }
+ }
+
+ for (i = 0; i < nChannels; i++) {
+ /* PSY_STATIC */
+ hPsy->pStaticChannels[i] = GetRam_aacEnc_PsyStatic(i);
+ if (hPsy->pStaticChannels[i] == NULL) {
+ ErrorStatus = AAC_ENC_NO_MEMORY;
+ goto bail;
+ }
+ /* AUDIO INPUT BUFFER */
+ hPsy->pStaticChannels[i]->psyInputBuffer = GetRam_aacEnc_PsyInputBuffer(i);
+ if (hPsy->pStaticChannels[i]->psyInputBuffer == NULL) {
+ ErrorStatus = AAC_ENC_NO_MEMORY;
+ goto bail;
+ }
+ }
+
+ /* reusable psych memory */
+ hPsy->psyDynamic = GetRam_aacEnc_PsyDynamic(0, dynamic_RAM);
+
+ return AAC_ENC_OK;
+
+bail:
+ FDKaacEnc_PsyClose(phpsy, NULL);
+
+ return ErrorStatus;
+}
+
+/*****************************************************************************
+
+ functionname: FDKaacEnc_PsyOutNew
+ description: allocates memory for psyOut struc
+ returns: an error code
+ input: pointer to a psych handle
+
+*****************************************************************************/
+AAC_ENCODER_ERROR FDKaacEnc_PsyOutNew(PSY_OUT **phpsyOut, 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++) {
+ phpsyOut[n] = GetRam_aacEnc_PsyOut(n);
+
+ if (phpsyOut[n] == NULL) {
+ ErrorStatus = AAC_ENC_NO_MEMORY;
+ goto bail;
+ }
+
+ for (i = 0; i < nChannels; i++) {
+ phpsyOut[n]->pPsyOutChannels[i] = GetRam_aacEnc_PsyOutChannel(chInc++);
+ if (NULL == phpsyOut[n]->pPsyOutChannels[i]) {
+ ErrorStatus = AAC_ENC_NO_MEMORY;
+ goto bail;
+ }
+ }
+
+ for (i = 0; i < nElements; i++) {
+ phpsyOut[n]->psyOutElement[i] = GetRam_aacEnc_PsyOutElements(elInc++);
+ if (phpsyOut[n]->psyOutElement[i] == NULL) {
+ ErrorStatus = AAC_ENC_NO_MEMORY;
+ goto bail;
+ }
+ }
+ } /* nSubFrames */
+
+ return AAC_ENC_OK;
+
+bail:
+ FDKaacEnc_PsyClose(NULL, phpsyOut);
+ return ErrorStatus;
+}
+
+AAC_ENCODER_ERROR FDKaacEnc_psyInitStates(PSY_INTERNAL *hPsy,
+ PSY_STATIC *psyStatic,
+ AUDIO_OBJECT_TYPE audioObjectType) {
+ /* init input buffer */
+ FDKmemclear(psyStatic->psyInputBuffer,
+ MAX_INPUT_BUFFER_SIZE * sizeof(INT_PCM));
+
+ FDKaacEnc_InitBlockSwitching(&psyStatic->blockSwitchingControl,
+ isLowDelay(audioObjectType));
+
+ return AAC_ENC_OK;
+}
+
+AAC_ENCODER_ERROR FDKaacEnc_psyInit(PSY_INTERNAL *hPsy, PSY_OUT **phpsyOut,
+ const INT nSubFrames,
+ const INT nMaxChannels,
+ const AUDIO_OBJECT_TYPE audioObjectType,
+ CHANNEL_MAPPING *cm) {
+ AAC_ENCODER_ERROR ErrorStatus = AAC_ENC_OK;
+ int i, ch, n, chInc = 0, resetChannels = 3;
+
+ if ((nMaxChannels > 2) && (cm->nChannels == 2)) {
+ chInc = 1;
+ FDKaacEnc_psyInitStates(hPsy, hPsy->pStaticChannels[0], audioObjectType);
+ }
+
+ if ((nMaxChannels == 2)) {
+ resetChannels = 0;
+ }
+
+ for (i = 0; i < cm->nElements; i++) {
+ for (ch = 0; ch < cm->elInfo[i].nChannelsInEl; ch++) {
+ hPsy->psyElement[i]->psyStatic[ch] = hPsy->pStaticChannels[chInc];
+ if (cm->elInfo[i].elType != ID_LFE) {
+ if (chInc >= resetChannels) {
+ FDKaacEnc_psyInitStates(hPsy, hPsy->psyElement[i]->psyStatic[ch],
+ audioObjectType);
+ }
+ mdct_init(&(hPsy->psyElement[i]->psyStatic[ch]->mdctPers), NULL, 0);
+ hPsy->psyElement[i]->psyStatic[ch]->isLFE = 0;
+ } else {
+ hPsy->psyElement[i]->psyStatic[ch]->isLFE = 1;
+ }
+ chInc++;
+ }
+ }
+
+ for (n = 0; n < nSubFrames; n++) {
+ chInc = 0;
+ for (i = 0; i < cm->nElements; i++) {
+ for (ch = 0; ch < cm->elInfo[i].nChannelsInEl; ch++) {
+ phpsyOut[n]->psyOutElement[i]->psyOutChannel[ch] =
+ phpsyOut[n]->pPsyOutChannels[chInc++];
+ }
+ }
+ }
+
+ return ErrorStatus;
+}
+
+/*****************************************************************************
+
+ functionname: FDKaacEnc_psyMainInit
+ description: initializes psychoacoustic
+ returns: an error code
+
+*****************************************************************************/
+
+AAC_ENCODER_ERROR FDKaacEnc_psyMainInit(
+ PSY_INTERNAL *hPsy, AUDIO_OBJECT_TYPE audioObjectType, CHANNEL_MAPPING *cm,
+ INT sampleRate, INT granuleLength, INT bitRate, INT tnsMask, INT bandwidth,
+ INT usePns, INT useIS, INT useMS, UINT syntaxFlags, ULONG initFlags) {
+ AAC_ENCODER_ERROR ErrorStatus;
+ int i, ch;
+ int channelsEff = cm->nChannelsEff;
+ int tnsChannels = 0;
+ FB_TYPE filterBank;
+
+ switch (FDKaacEnc_GetMonoStereoMode(cm->encMode)) {
+ /* ... and map to tnsChannels */
+ case EL_MODE_MONO:
+ tnsChannels = 1;
+ break;
+ case EL_MODE_STEREO:
+ tnsChannels = 2;
+ break;
+ default:
+ tnsChannels = 0;
+ }
+
+ switch (audioObjectType) {
+ default:
+ filterBank = FB_LC;
+ break;
+ case AOT_ER_AAC_LD:
+ filterBank = FB_LD;
+ break;
+ case AOT_ER_AAC_ELD:
+ filterBank = FB_ELD;
+ break;
+ }
+
+ hPsy->granuleLength = granuleLength;
+
+ ErrorStatus = FDKaacEnc_InitPsyConfiguration(
+ bitRate / channelsEff, sampleRate, bandwidth, LONG_WINDOW,
+ hPsy->granuleLength, useIS, useMS, &(hPsy->psyConf[0]), filterBank);
+ if (ErrorStatus != AAC_ENC_OK) return ErrorStatus;
+
+ ErrorStatus = FDKaacEnc_InitTnsConfiguration(
+ (bitRate * tnsChannels) / channelsEff, sampleRate, tnsChannels,
+ LONG_WINDOW, hPsy->granuleLength, isLowDelay(audioObjectType),
+ (syntaxFlags & AC_SBR_PRESENT) ? 1 : 0, &(hPsy->psyConf[0].tnsConf),
+ &hPsy->psyConf[0], (INT)(tnsMask & 2), (INT)(tnsMask & 8));
+
+ if (ErrorStatus != AAC_ENC_OK) return ErrorStatus;
+
+ if (granuleLength > 512) {
+ ErrorStatus = FDKaacEnc_InitPsyConfiguration(
+ bitRate / channelsEff, sampleRate, bandwidth, SHORT_WINDOW,
+ hPsy->granuleLength, useIS, useMS, &hPsy->psyConf[1], filterBank);
+
+ if (ErrorStatus != AAC_ENC_OK) return ErrorStatus;
+
+ ErrorStatus = FDKaacEnc_InitTnsConfiguration(
+ (bitRate * tnsChannels) / channelsEff, sampleRate, tnsChannels,
+ SHORT_WINDOW, hPsy->granuleLength, isLowDelay(audioObjectType),
+ (syntaxFlags & AC_SBR_PRESENT) ? 1 : 0, &hPsy->psyConf[1].tnsConf,
+ &hPsy->psyConf[1], (INT)(tnsMask & 1), (INT)(tnsMask & 4));
+
+ if (ErrorStatus != AAC_ENC_OK) return ErrorStatus;
+ }
+
+ for (i = 0; i < cm->nElements; i++) {
+ for (ch = 0; ch < cm->elInfo[i].nChannelsInEl; ch++) {
+ if (initFlags) {
+ /* reset states */
+ FDKaacEnc_psyInitStates(hPsy, hPsy->psyElement[i]->psyStatic[ch],
+ audioObjectType);
+ }
+
+ FDKaacEnc_InitPreEchoControl(
+ hPsy->psyElement[i]->psyStatic[ch]->sfbThresholdnm1,
+ &hPsy->psyElement[i]->psyStatic[ch]->calcPreEcho,
+ hPsy->psyConf[0].sfbCnt, hPsy->psyConf[0].sfbPcmQuantThreshold,
+ &hPsy->psyElement[i]->psyStatic[ch]->mdctScalenm1);
+ }
+ }
+
+ ErrorStatus = FDKaacEnc_InitPnsConfiguration(
+ &hPsy->psyConf[0].pnsConf, bitRate / channelsEff, sampleRate, usePns,
+ hPsy->psyConf[0].sfbCnt, hPsy->psyConf[0].sfbOffset,
+ cm->elInfo[0].nChannelsInEl, (hPsy->psyConf[0].filterbank == FB_LC));
+ if (ErrorStatus != AAC_ENC_OK) return ErrorStatus;
+
+ if (granuleLength > 512) {
+ ErrorStatus = FDKaacEnc_InitPnsConfiguration(
+ &hPsy->psyConf[1].pnsConf, bitRate / channelsEff, sampleRate, usePns,
+ hPsy->psyConf[1].sfbCnt, hPsy->psyConf[1].sfbOffset,
+ cm->elInfo[1].nChannelsInEl, (hPsy->psyConf[1].filterbank == FB_LC));
+ if (ErrorStatus != AAC_ENC_OK) return ErrorStatus;
+ }
+
+ return ErrorStatus;
+}
+
+/*****************************************************************************
+
+ functionname: FDKaacEnc_psyMain
+ description: psychoacoustic
+ returns: an error code
+
+ This function assumes that enough input data is in the modulo buffer.
+
+*****************************************************************************/
+AAC_ENCODER_ERROR FDKaacEnc_psyMain(INT channels, PSY_ELEMENT *psyElement,
+ PSY_DYNAMIC *psyDynamic,
+ PSY_CONFIGURATION *psyConf,
+ PSY_OUT_ELEMENT *RESTRICT psyOutElement,
+ INT_PCM *pInput, const UINT inputBufSize,
+ INT *chIdx, INT totalChannels) {
+ const INT commonWindow = 1;
+ INT maxSfbPerGroup[(2)];
+ INT mdctSpectrum_e;
+ INT ch; /* counts through channels */
+ INT w; /* counts through windows */
+ INT sfb; /* counts through scalefactor bands */
+ INT line; /* counts through lines */
+
+ PSY_CONFIGURATION *RESTRICT hPsyConfLong = &psyConf[0];
+ PSY_CONFIGURATION *RESTRICT hPsyConfShort = &psyConf[1];
+ PSY_OUT_CHANNEL **RESTRICT psyOutChannel = psyOutElement->psyOutChannel;
+ FIXP_SGL sfbTonality[(2)][MAX_SFB_LONG];
+
+ PSY_STATIC **RESTRICT psyStatic = psyElement->psyStatic;
+
+ PSY_DATA *RESTRICT psyData[(2)];
+ TNS_DATA *RESTRICT tnsData[(2)];
+ PNS_DATA *RESTRICT pnsData[(2)];
+
+ INT zeroSpec = TRUE; /* means all spectral lines are zero */
+
+ INT blockSwitchingOffset;
+
+ PSY_CONFIGURATION *RESTRICT hThisPsyConf[(2)];
+ INT windowLength[(2)];
+ INT nWindows[(2)];
+ INT wOffset;
+
+ INT maxSfb[(2)];
+ INT *pSfbMaxScaleSpec[(2)];
+ FIXP_DBL *pSfbEnergy[(2)];
+ FIXP_DBL *pSfbSpreadEnergy[(2)];
+ FIXP_DBL *pSfbEnergyLdData[(2)];
+ FIXP_DBL *pSfbEnergyMS[(2)];
+ FIXP_DBL *pSfbThreshold[(2)];
+
+ INT isShortWindow[(2)];
+
+ /* number of incoming time samples to be processed */
+ const INT nTimeSamples = psyConf->granuleLength;
+
+ switch (hPsyConfLong->filterbank) {
+ case FB_LC:
+ blockSwitchingOffset =
+ nTimeSamples + (9 * nTimeSamples / (2 * TRANS_FAC));
+ break;
+ case FB_LD:
+ case FB_ELD:
+ blockSwitchingOffset = nTimeSamples;
+ break;
+ default:
+ return AAC_ENC_UNSUPPORTED_FILTERBANK;
+ }
+
+ for (ch = 0; ch < channels; ch++) {
+ psyData[ch] = &psyDynamic->psyData[ch];
+ tnsData[ch] = &psyDynamic->tnsData[ch];
+ pnsData[ch] = &psyDynamic->pnsData[ch];
+
+ psyData[ch]->mdctSpectrum = psyOutChannel[ch]->mdctSpectrum;
+ }
+
+ /* block switching */
+ if (hPsyConfLong->filterbank != FB_ELD) {
+ int err;
+
+ for (ch = 0; ch < channels; ch++) {
+ C_ALLOC_SCRATCH_START(pTimeSignal, INT_PCM, (1024))
+
+ /* copy input data and use for block switching */
+ FDKmemcpy(pTimeSignal, pInput + chIdx[ch] * inputBufSize,
+ nTimeSamples * sizeof(INT_PCM));
+
+ FDKaacEnc_BlockSwitching(&psyStatic[ch]->blockSwitchingControl,
+ nTimeSamples, psyStatic[ch]->isLFE, pTimeSignal);
+
+ /* fill up internal input buffer, to 2xframelength samples */
+ FDKmemcpy(psyStatic[ch]->psyInputBuffer + blockSwitchingOffset,
+ pTimeSignal,
+ (2 * nTimeSamples - blockSwitchingOffset) * sizeof(INT_PCM));
+
+ C_ALLOC_SCRATCH_END(pTimeSignal, INT_PCM, (1024))
+ }
+
+ /* synch left and right block type */
+ err = FDKaacEnc_SyncBlockSwitching(
+ &psyStatic[0]->blockSwitchingControl,
+ (channels > 1) ? &psyStatic[1]->blockSwitchingControl : NULL, channels,
+ commonWindow);
+
+ if (err) {
+ return AAC_ENC_UNSUPPORTED_AOT; /* mixed up LC and LD */
+ }
+
+ } else {
+ for (ch = 0; ch < channels; ch++) {
+ /* copy input data and use for block switching */
+ FDKmemcpy(psyStatic[ch]->psyInputBuffer + blockSwitchingOffset,
+ pInput + chIdx[ch] * inputBufSize,
+ nTimeSamples * sizeof(INT_PCM));
+ }
+ }
+
+ for (ch = 0; ch < channels; ch++)
+ isShortWindow[ch] =
+ (psyStatic[ch]->blockSwitchingControl.lastWindowSequence ==
+ SHORT_WINDOW);
+
+ /* set parameters according to window length */
+ for (ch = 0; ch < channels; ch++) {
+ if (isShortWindow[ch]) {
+ hThisPsyConf[ch] = hPsyConfShort;
+ windowLength[ch] = psyConf->granuleLength / TRANS_FAC;
+ nWindows[ch] = TRANS_FAC;
+ maxSfb[ch] = MAX_SFB_SHORT;
+
+ pSfbMaxScaleSpec[ch] = psyData[ch]->sfbMaxScaleSpec.Short[0];
+ pSfbEnergy[ch] = psyData[ch]->sfbEnergy.Short[0];
+ pSfbSpreadEnergy[ch] = psyData[ch]->sfbSpreadEnergy.Short[0];
+ pSfbEnergyLdData[ch] = psyData[ch]->sfbEnergyLdData.Short[0];
+ pSfbEnergyMS[ch] = psyData[ch]->sfbEnergyMS.Short[0];
+ pSfbThreshold[ch] = psyData[ch]->sfbThreshold.Short[0];
+
+ } else {
+ hThisPsyConf[ch] = hPsyConfLong;
+ windowLength[ch] = psyConf->granuleLength;
+ nWindows[ch] = 1;
+ maxSfb[ch] = MAX_GROUPED_SFB;
+
+ pSfbMaxScaleSpec[ch] = psyData[ch]->sfbMaxScaleSpec.Long;
+ pSfbEnergy[ch] = psyData[ch]->sfbEnergy.Long;
+ pSfbSpreadEnergy[ch] = psyData[ch]->sfbSpreadEnergy.Long;
+ pSfbEnergyLdData[ch] = psyData[ch]->sfbEnergyLdData.Long;
+ pSfbEnergyMS[ch] = psyData[ch]->sfbEnergyMS.Long;
+ pSfbThreshold[ch] = psyData[ch]->sfbThreshold.Long;
+ }
+ }
+
+ /* Transform and get mdctScaling for all channels and windows. */
+ for (ch = 0; ch < channels; ch++) {
+ /* update number of active bands */
+ if (psyStatic[ch]->isLFE) {
+ psyData[ch]->sfbActive = hThisPsyConf[ch]->sfbActiveLFE;
+ psyData[ch]->lowpassLine = hThisPsyConf[ch]->lowpassLineLFE;
+ } else {
+ psyData[ch]->sfbActive = hThisPsyConf[ch]->sfbActive;
+ psyData[ch]->lowpassLine = hThisPsyConf[ch]->lowpassLine;
+ }
+
+ if (hThisPsyConf[ch]->filterbank == FB_ELD) {
+ if (FDKaacEnc_Transform_Real_Eld(
+ psyStatic[ch]->psyInputBuffer, psyData[ch]->mdctSpectrum,
+ psyStatic[ch]->blockSwitchingControl.lastWindowSequence,
+ psyStatic[ch]->blockSwitchingControl.windowShape,
+ &psyStatic[ch]->blockSwitchingControl.lastWindowShape,
+ nTimeSamples, &mdctSpectrum_e, hThisPsyConf[ch]->filterbank,
+ psyStatic[ch]->overlapAddBuffer) != 0) {
+ return AAC_ENC_UNSUPPORTED_FILTERBANK;
+ }
+ } else {
+ if (FDKaacEnc_Transform_Real(
+ psyStatic[ch]->psyInputBuffer, psyData[ch]->mdctSpectrum,
+ psyStatic[ch]->blockSwitchingControl.lastWindowSequence,
+ psyStatic[ch]->blockSwitchingControl.windowShape,
+ &psyStatic[ch]->blockSwitchingControl.lastWindowShape,
+ &psyStatic[ch]->mdctPers, nTimeSamples, &mdctSpectrum_e,
+ hThisPsyConf[ch]->filterbank) != 0) {
+ return AAC_ENC_UNSUPPORTED_FILTERBANK;
+ }
+ }
+
+ for (w = 0; w < nWindows[ch]; w++) {
+ wOffset = w * windowLength[ch];
+
+ /* Low pass / highest sfb */
+ FDKmemclear(
+ &psyData[ch]->mdctSpectrum[psyData[ch]->lowpassLine + wOffset],
+ (windowLength[ch] - psyData[ch]->lowpassLine) * sizeof(FIXP_DBL));
+
+ if ((hPsyConfLong->filterbank != FB_LC) &&
+ (psyData[ch]->lowpassLine >= FADE_OUT_LEN)) {
+ /* Do blending to reduce gibbs artifacts */
+ for (int i = 0; i < FADE_OUT_LEN; i++) {
+ psyData[ch]->mdctSpectrum[psyData[ch]->lowpassLine + wOffset -
+ FADE_OUT_LEN + i] =
+ fMult(psyData[ch]->mdctSpectrum[psyData[ch]->lowpassLine +
+ wOffset - FADE_OUT_LEN + i],
+ fadeOutFactor[i]);
+ }
+ }
+
+ /* Check for zero spectrum. These loops will usually terminate very, very
+ * early. */
+ for (line = 0; (line < psyData[ch]->lowpassLine) && (zeroSpec == TRUE);
+ line++) {
+ if (psyData[ch]->mdctSpectrum[line + wOffset] != (FIXP_DBL)0) {
+ zeroSpec = FALSE;
+ break;
+ }
+ }
+
+ } /* w loop */
+
+ psyData[ch]->mdctScale = mdctSpectrum_e;
+
+ /* rotate internal time samples */
+ FDKmemmove(psyStatic[ch]->psyInputBuffer,
+ psyStatic[ch]->psyInputBuffer + nTimeSamples,
+ nTimeSamples * sizeof(INT_PCM));
+
+ /* ... and get remaining samples from input buffer */
+ FDKmemcpy(psyStatic[ch]->psyInputBuffer + nTimeSamples,
+ pInput + (2 * nTimeSamples - blockSwitchingOffset) +
+ chIdx[ch] * inputBufSize,
+ (blockSwitchingOffset - nTimeSamples) * sizeof(INT_PCM));
+
+ } /* ch */
+
+ /* Do some rescaling to get maximum possible accuracy for energies */
+ if (zeroSpec == FALSE) {
+ /* Calc possible spectrum leftshift for each sfb (1 means: 1 bit left shift
+ * is possible without overflow) */
+ INT minSpecShift = MAX_SHIFT_DBL;
+ INT nrgShift = MAX_SHIFT_DBL;
+ INT finalShift = MAX_SHIFT_DBL;
+ FIXP_DBL currNrg = 0;
+ FIXP_DBL maxNrg = 0;
+
+ for (ch = 0; ch < channels; ch++) {
+ for (w = 0; w < nWindows[ch]; w++) {
+ wOffset = w * windowLength[ch];
+ FDKaacEnc_CalcSfbMaxScaleSpec(
+ psyData[ch]->mdctSpectrum + wOffset, hThisPsyConf[ch]->sfbOffset,
+ pSfbMaxScaleSpec[ch] + w * maxSfb[ch], psyData[ch]->sfbActive);
+
+ for (sfb = 0; sfb < psyData[ch]->sfbActive; sfb++)
+ minSpecShift = fixMin(minSpecShift,
+ (pSfbMaxScaleSpec[ch] + w * maxSfb[ch])[sfb]);
+ }
+ }
+
+ /* Calc possible energy leftshift for each sfb (1 means: 1 bit left shift is
+ * possible without overflow) */
+ for (ch = 0; ch < channels; ch++) {
+ for (w = 0; w < nWindows[ch]; w++) {
+ wOffset = w * windowLength[ch];
+ currNrg = FDKaacEnc_CheckBandEnergyOptim(
+ psyData[ch]->mdctSpectrum + wOffset,
+ pSfbMaxScaleSpec[ch] + w * maxSfb[ch], hThisPsyConf[ch]->sfbOffset,
+ psyData[ch]->sfbActive, pSfbEnergy[ch] + w * maxSfb[ch],
+ pSfbEnergyLdData[ch] + w * maxSfb[ch], minSpecShift - 4);
+
+ maxNrg = fixMax(maxNrg, currNrg);
+ }
+ }
+
+ if (maxNrg != (FIXP_DBL)0) {
+ nrgShift = (CountLeadingBits(maxNrg) >> 1) + (minSpecShift - 4);
+ }
+
+ /* 2check: Hasn't this decision to be made for both channels? */
+ /* For short windows 1 additional bit headroom is necessary to prevent
+ * overflows when summing up energies in FDKaacEnc_groupShortData() */
+ if (isShortWindow[0]) nrgShift--;
+
+ /* both spectrum and energies mustn't overflow */
+ finalShift = fixMin(minSpecShift, nrgShift);
+
+ /* do not shift more than 3 bits more to the left than signal without
+ * blockfloating point would be to avoid overflow of scaled PCM quantization
+ * thresholds */
+ if (finalShift > psyData[0]->mdctScale + 3)
+ finalShift = psyData[0]->mdctScale + 3;
+
+ FDK_ASSERT(finalShift >= 0); /* right shift is not allowed */
+
+ /* correct sfbEnergy and sfbEnergyLdData with new finalShift */
+ FIXP_DBL ldShift = finalShift * FL2FXCONST_DBL(2.0 / 64);
+ for (ch = 0; ch < channels; ch++) {
+ INT maxSfb_ch = maxSfb[ch];
+ INT w_maxSfb_ch = 0;
+ for (w = 0; w < nWindows[ch]; w++) {
+ for (sfb = 0; sfb < psyData[ch]->sfbActive; sfb++) {
+ INT scale = fixMax(0, (pSfbMaxScaleSpec[ch] + w_maxSfb_ch)[sfb] - 4);
+ scale = fixMin((scale - finalShift) << 1, DFRACT_BITS - 1);
+ if (scale >= 0)
+ (pSfbEnergy[ch] + w_maxSfb_ch)[sfb] >>= (scale);
+ else
+ (pSfbEnergy[ch] + w_maxSfb_ch)[sfb] <<= (-scale);
+ (pSfbThreshold[ch] + w_maxSfb_ch)[sfb] =
+ fMult((pSfbEnergy[ch] + w_maxSfb_ch)[sfb], C_RATIO);
+ (pSfbEnergyLdData[ch] + w_maxSfb_ch)[sfb] += ldShift;
+ }
+ w_maxSfb_ch += maxSfb_ch;
+ }
+ }
+
+ if (finalShift != 0) {
+ for (ch = 0; ch < channels; ch++) {
+ INT wLen = windowLength[ch];
+ INT lowpassLine = psyData[ch]->lowpassLine;
+ wOffset = 0;
+ FIXP_DBL *mdctSpectrum = &psyData[ch]->mdctSpectrum[0];
+ for (w = 0; w < nWindows[ch]; w++) {
+ FIXP_DBL *spectrum = &mdctSpectrum[wOffset];
+ for (line = 0; line < lowpassLine; line++) {
+ spectrum[line] <<= finalShift;
+ }
+ wOffset += wLen;
+
+ /* update sfbMaxScaleSpec */
+ for (sfb = 0; sfb < psyData[ch]->sfbActive; sfb++)
+ (pSfbMaxScaleSpec[ch] + w * maxSfb[ch])[sfb] -= finalShift;
+ }
+ /* update mdctScale */
+ psyData[ch]->mdctScale -= finalShift;
+ }
+ }
+
+ } else {
+ /* all spectral lines are zero */
+ for (ch = 0; ch < channels; ch++) {
+ psyData[ch]->mdctScale =
+ 0; /* otherwise mdctScale would be for example 7 and PCM quantization
+ * thresholds would be shifted 14 bits to the right causing some of
+ * them to become 0 (which causes problems later) */
+ /* clear sfbMaxScaleSpec */
+ for (w = 0; w < nWindows[ch]; w++) {
+ for (sfb = 0; sfb < psyData[ch]->sfbActive; sfb++) {
+ (pSfbMaxScaleSpec[ch] + w * maxSfb[ch])[sfb] = 0;
+ (pSfbEnergy[ch] + w * maxSfb[ch])[sfb] = (FIXP_DBL)0;
+ (pSfbEnergyLdData[ch] + w * maxSfb[ch])[sfb] = FL2FXCONST_DBL(-1.0f);
+ (pSfbThreshold[ch] + w * maxSfb[ch])[sfb] = (FIXP_DBL)0;
+ }
+ }
+ }
+ }
+
+ /* Advance psychoacoustics: Tonality and TNS */
+ if ((channels >= 1) && (psyStatic[0]->isLFE)) {
+ tnsData[0]->dataRaw.Long.subBlockInfo.tnsActive[HIFILT] = 0;
+ tnsData[0]->dataRaw.Long.subBlockInfo.tnsActive[LOFILT] = 0;
+ } else {
+ for (ch = 0; ch < channels; ch++) {
+ if (!isShortWindow[ch]) {
+ /* tonality */
+ FDKaacEnc_CalculateFullTonality(
+ psyData[ch]->mdctSpectrum, pSfbMaxScaleSpec[ch],
+ pSfbEnergyLdData[ch], sfbTonality[ch], psyData[ch]->sfbActive,
+ hThisPsyConf[ch]->sfbOffset, hThisPsyConf[ch]->pnsConf.usePns);
+ }
+ } /* ch */
+
+ if (hPsyConfLong->tnsConf.tnsActive || hPsyConfShort->tnsConf.tnsActive) {
+ INT tnsActive[TRANS_FAC] = {0};
+ INT nrgScaling[2] = {0, 0};
+ INT tnsSpecShift = 0;
+
+ for (ch = 0; ch < channels; ch++) {
+ for (w = 0; w < nWindows[ch]; w++) {
+ wOffset = w * windowLength[ch];
+ /* TNS */
+ FDKaacEnc_TnsDetect(
+ tnsData[ch], &hThisPsyConf[ch]->tnsConf,
+ &psyOutChannel[ch]->tnsInfo, hThisPsyConf[ch]->sfbCnt,
+ psyData[ch]->mdctSpectrum + wOffset, w,
+ psyStatic[ch]->blockSwitchingControl.lastWindowSequence);
+ }
+ }
+
+ if (channels == 2) {
+ FDKaacEnc_TnsSync(
+ tnsData[1], tnsData[0], &psyOutChannel[1]->tnsInfo,
+ &psyOutChannel[0]->tnsInfo,
+
+ psyStatic[1]->blockSwitchingControl.lastWindowSequence,
+ psyStatic[0]->blockSwitchingControl.lastWindowSequence,
+ &hThisPsyConf[1]->tnsConf);
+ }
+
+ if (channels >= 1) {
+ FDK_ASSERT(1 == commonWindow); /* all checks for TNS do only work for
+ common windows (which is always set)*/
+ for (w = 0; w < nWindows[0]; w++) {
+ if (isShortWindow[0])
+ tnsActive[w] =
+ tnsData[0]->dataRaw.Short.subBlockInfo[w].tnsActive[HIFILT] ||
+ tnsData[0]->dataRaw.Short.subBlockInfo[w].tnsActive[LOFILT] ||
+ tnsData[channels - 1]
+ ->dataRaw.Short.subBlockInfo[w]
+ .tnsActive[HIFILT] ||
+ tnsData[channels - 1]
+ ->dataRaw.Short.subBlockInfo[w]
+ .tnsActive[LOFILT];
+ else
+ tnsActive[w] =
+ tnsData[0]->dataRaw.Long.subBlockInfo.tnsActive[HIFILT] ||
+ tnsData[0]->dataRaw.Long.subBlockInfo.tnsActive[LOFILT] ||
+ tnsData[channels - 1]
+ ->dataRaw.Long.subBlockInfo.tnsActive[HIFILT] ||
+ tnsData[channels - 1]
+ ->dataRaw.Long.subBlockInfo.tnsActive[LOFILT];
+ }
+ }
+
+ for (ch = 0; ch < channels; ch++) {
+ if (tnsActive[0] && !isShortWindow[ch]) {
+ /* Scale down spectrum if tns is active in one of the two channels
+ * with same lastWindowSequence */
+ /* first part of threshold calculation; it's not necessary to update
+ * sfbMaxScaleSpec */
+ INT shift = 1;
+ for (sfb = 0; sfb < hThisPsyConf[ch]->lowpassLine; sfb++) {
+ psyData[ch]->mdctSpectrum[sfb] =
+ psyData[ch]->mdctSpectrum[sfb] >> shift;
+ }
+
+ /* update thresholds */
+ for (sfb = 0; sfb < psyData[ch]->sfbActive; sfb++) {
+ pSfbThreshold[ch][sfb] >>= (2 * shift);
+ }
+
+ psyData[ch]->mdctScale += shift; /* update mdctScale */
+
+ /* calc sfbEnergies after tnsEncode again ! */
+ }
+ }
+
+ for (ch = 0; ch < channels; ch++) {
+ for (w = 0; w < nWindows[ch]; w++) {
+ wOffset = w * windowLength[ch];
+ FDKaacEnc_TnsEncode(
+ &psyOutChannel[ch]->tnsInfo, tnsData[ch],
+ hThisPsyConf[ch]->sfbCnt, &hThisPsyConf[ch]->tnsConf,
+ hThisPsyConf[ch]->sfbOffset[psyData[ch]->sfbActive],
+ /*hThisPsyConf[ch]->lowpassLine*/ /* filter stops
+ before that
+ line ! */
+ psyData[ch]->mdctSpectrum +
+ wOffset,
+ w, psyStatic[ch]->blockSwitchingControl.lastWindowSequence);
+
+ if (tnsActive[w]) {
+ /* Calc sfb-bandwise mdct-energies for left and right channel again,
+ */
+ /* if tns active in current channel or in one channel with same
+ * lastWindowSequence left and right */
+ FDKaacEnc_CalcSfbMaxScaleSpec(psyData[ch]->mdctSpectrum + wOffset,
+ hThisPsyConf[ch]->sfbOffset,
+ pSfbMaxScaleSpec[ch] + w * maxSfb[ch],
+ psyData[ch]->sfbActive);
+ }
+ }
+ }
+
+ for (ch = 0; ch < channels; ch++) {
+ for (w = 0; w < nWindows[ch]; w++) {
+ if (tnsActive[w]) {
+ if (isShortWindow[ch]) {
+ FDKaacEnc_CalcBandEnergyOptimShort(
+ psyData[ch]->mdctSpectrum + w * windowLength[ch],
+ pSfbMaxScaleSpec[ch] + w * maxSfb[ch],
+ hThisPsyConf[ch]->sfbOffset, psyData[ch]->sfbActive,
+ pSfbEnergy[ch] + w * maxSfb[ch]);
+ } else {
+ nrgScaling[ch] = /* with tns, energy calculation can overflow; ->
+ scaling */
+ FDKaacEnc_CalcBandEnergyOptimLong(
+ psyData[ch]->mdctSpectrum, pSfbMaxScaleSpec[ch],
+ hThisPsyConf[ch]->sfbOffset, psyData[ch]->sfbActive,
+ pSfbEnergy[ch], pSfbEnergyLdData[ch]);
+ tnsSpecShift =
+ fixMax(tnsSpecShift, nrgScaling[ch]); /* nrgScaling is set
+ only if nrg would
+ have an overflow */
+ }
+ } /* if tnsActive */
+ }
+ } /* end channel loop */
+
+ /* adapt scaling to prevent nrg overflow, only for long blocks */
+ for (ch = 0; ch < channels; ch++) {
+ if ((tnsSpecShift != 0) && !isShortWindow[ch]) {
+ /* scale down spectrum, nrg's and thresholds, if there was an overflow
+ * in sfbNrg calculation after tns */
+ for (line = 0; line < hThisPsyConf[ch]->lowpassLine; line++) {
+ psyData[ch]->mdctSpectrum[line] >>= tnsSpecShift;
+ }
+ INT scale = (tnsSpecShift - nrgScaling[ch]) << 1;
+ for (sfb = 0; sfb < psyData[ch]->sfbActive; sfb++) {
+ pSfbEnergyLdData[ch][sfb] -=
+ scale * FL2FXCONST_DBL(1.0 / LD_DATA_SCALING);
+ pSfbEnergy[ch][sfb] >>= scale;
+ pSfbThreshold[ch][sfb] >>= (tnsSpecShift << 1);
+ }
+ psyData[ch]->mdctScale += tnsSpecShift; /* update mdctScale; not
+ necessary to update
+ sfbMaxScaleSpec */
+ }
+ } /* end channel loop */
+
+ } /* TNS active */
+ else {
+ /* In case of disable TNS, reset its dynamic data. Some of its elements is
+ * required in PNS detection below. */
+ FDKmemclear(psyDynamic->tnsData, sizeof(psyDynamic->tnsData));
+ }
+ } /* !isLFE */
+
+ /* Advance thresholds */
+ for (ch = 0; ch < channels; ch++) {
+ INT headroom;
+
+ FIXP_DBL clipEnergy;
+ INT energyShift = psyData[ch]->mdctScale * 2;
+ INT clipNrgShift = energyShift - THR_SHIFTBITS;
+ if (isShortWindow[ch])
+ headroom = 6;
+ else
+ headroom = 0;
+
+ if (clipNrgShift >= 0)
+ clipEnergy = hThisPsyConf[ch]->clipEnergy >> clipNrgShift;
+ else if (clipNrgShift >= -headroom)
+ clipEnergy = hThisPsyConf[ch]->clipEnergy << -clipNrgShift;
+ else
+ clipEnergy = (FIXP_DBL)MAXVAL_DBL;
+
+ for (w = 0; w < nWindows[ch]; w++) {
+ INT i;
+ /* limit threshold to avoid clipping */
+ for (i = 0; i < psyData[ch]->sfbActive; i++) {
+ *(pSfbThreshold[ch] + w * maxSfb[ch] + i) =
+ fixMin(*(pSfbThreshold[ch] + w * maxSfb[ch] + i), clipEnergy);
+ }
+
+ /* spreading */
+ FDKaacEnc_SpreadingMax(psyData[ch]->sfbActive,
+ hThisPsyConf[ch]->sfbMaskLowFactor,
+ hThisPsyConf[ch]->sfbMaskHighFactor,
+ pSfbThreshold[ch] + w * maxSfb[ch]);
+
+ /* PCM quantization threshold */
+ energyShift += PCM_QUANT_THR_SCALE;
+ if (energyShift >= 0) {
+ energyShift = fixMin(DFRACT_BITS - 1, energyShift);
+ for (i = 0; i < psyData[ch]->sfbActive; i++) {
+ *(pSfbThreshold[ch] + w * maxSfb[ch] + i) = fixMax(
+ *(pSfbThreshold[ch] + w * maxSfb[ch] + i) >> THR_SHIFTBITS,
+ (hThisPsyConf[ch]->sfbPcmQuantThreshold[i] >> energyShift));
+ }
+ } else {
+ energyShift = fixMin(DFRACT_BITS - 1, -energyShift);
+ for (i = 0; i < psyData[ch]->sfbActive; i++) {
+ *(pSfbThreshold[ch] + w * maxSfb[ch] + i) = fixMax(
+ *(pSfbThreshold[ch] + w * maxSfb[ch] + i) >> THR_SHIFTBITS,
+ (hThisPsyConf[ch]->sfbPcmQuantThreshold[i] << energyShift));
+ }
+ }
+
+ if (!psyStatic[ch]->isLFE) {
+ /* preecho control */
+ if (psyStatic[ch]->blockSwitchingControl.lastWindowSequence ==
+ STOP_WINDOW) {
+ /* prevent FDKaacEnc_PreEchoControl from comparing stop
+ thresholds with short thresholds */
+ for (i = 0; i < psyData[ch]->sfbActive; i++) {
+ psyStatic[ch]->sfbThresholdnm1[i] = (FIXP_DBL)MAXVAL_DBL;
+ }
+
+ psyStatic[ch]->mdctScalenm1 = 0;
+ psyStatic[ch]->calcPreEcho = 0;
+ }
+
+ FDKaacEnc_PreEchoControl(
+ psyStatic[ch]->sfbThresholdnm1, psyStatic[ch]->calcPreEcho,
+ psyData[ch]->sfbActive, hThisPsyConf[ch]->maxAllowedIncreaseFactor,
+ hThisPsyConf[ch]->minRemainingThresholdFactor,
+ pSfbThreshold[ch] + w * maxSfb[ch], psyData[ch]->mdctScale,
+ &psyStatic[ch]->mdctScalenm1);
+
+ psyStatic[ch]->calcPreEcho = 1;
+
+ if (psyStatic[ch]->blockSwitchingControl.lastWindowSequence ==
+ START_WINDOW) {
+ /* prevent FDKaacEnc_PreEchoControl in next frame to compare start
+ thresholds with short thresholds */
+ for (i = 0; i < psyData[ch]->sfbActive; i++) {
+ psyStatic[ch]->sfbThresholdnm1[i] = (FIXP_DBL)MAXVAL_DBL;
+ }
+
+ psyStatic[ch]->mdctScalenm1 = 0;
+ psyStatic[ch]->calcPreEcho = 0;
+ }
+ }
+
+ /* spread energy to avoid hole detection */
+ FDKmemcpy(pSfbSpreadEnergy[ch] + w * maxSfb[ch],
+ pSfbEnergy[ch] + w * maxSfb[ch],
+ psyData[ch]->sfbActive * sizeof(FIXP_DBL));
+
+ FDKaacEnc_SpreadingMax(psyData[ch]->sfbActive,
+ hThisPsyConf[ch]->sfbMaskLowFactorSprEn,
+ hThisPsyConf[ch]->sfbMaskHighFactorSprEn,
+ pSfbSpreadEnergy[ch] + w * maxSfb[ch]);
+ }
+ }
+
+ /* Calc bandwise energies for mid and side channel. Do it only if 2 channels
+ * exist */
+ if (channels == 2) {
+ for (w = 0; w < nWindows[1]; w++) {
+ wOffset = w * windowLength[1];
+ FDKaacEnc_CalcBandNrgMSOpt(
+ psyData[0]->mdctSpectrum + wOffset,
+ psyData[1]->mdctSpectrum + wOffset,
+ pSfbMaxScaleSpec[0] + w * maxSfb[0],
+ pSfbMaxScaleSpec[1] + w * maxSfb[1], hThisPsyConf[1]->sfbOffset,
+ psyData[0]->sfbActive, pSfbEnergyMS[0] + w * maxSfb[0],
+ pSfbEnergyMS[1] + w * maxSfb[1],
+ (psyStatic[1]->blockSwitchingControl.lastWindowSequence !=
+ SHORT_WINDOW),
+ psyData[0]->sfbEnergyMSLdData, psyData[1]->sfbEnergyMSLdData);
+ }
+ }
+
+ /* group short data (maxSfb[ch] for short blocks is determined here) */
+ for (ch = 0; ch < channels; ch++) {
+ if (isShortWindow[ch]) {
+ int sfbGrp;
+ int noSfb = psyStatic[ch]->blockSwitchingControl.noOfGroups *
+ hPsyConfShort->sfbCnt;
+ /* At this point, energies and thresholds are copied/regrouped from the
+ * ".Short" to the ".Long" arrays */
+ FDKaacEnc_groupShortData(
+ psyData[ch]->mdctSpectrum, &psyData[ch]->sfbThreshold,
+ &psyData[ch]->sfbEnergy, &psyData[ch]->sfbEnergyMS,
+ &psyData[ch]->sfbSpreadEnergy, hPsyConfShort->sfbCnt,
+ psyData[ch]->sfbActive, hPsyConfShort->sfbOffset,
+ hPsyConfShort->sfbMinSnrLdData, psyData[ch]->groupedSfbOffset,
+ &maxSfbPerGroup[ch], psyOutChannel[ch]->sfbMinSnrLdData,
+ psyStatic[ch]->blockSwitchingControl.noOfGroups,
+ psyStatic[ch]->blockSwitchingControl.groupLen,
+ psyConf[1].granuleLength);
+
+ /* calculate ldData arrays (short values are in .Long-arrays after
+ * FDKaacEnc_groupShortData) */
+ for (sfbGrp = 0; sfbGrp < noSfb; sfbGrp += hPsyConfShort->sfbCnt) {
+ LdDataVector(&psyData[ch]->sfbEnergy.Long[sfbGrp],
+ &psyOutChannel[ch]->sfbEnergyLdData[sfbGrp],
+ psyData[ch]->sfbActive);
+ }
+
+ /* calc sfbThrld and set Values smaller 2^-31 to 2^-33*/
+ for (sfbGrp = 0; sfbGrp < noSfb; sfbGrp += hPsyConfShort->sfbCnt) {
+ LdDataVector(&psyData[ch]->sfbThreshold.Long[sfbGrp],
+ &psyOutChannel[ch]->sfbThresholdLdData[sfbGrp],
+ psyData[ch]->sfbActive);
+ for (sfb = 0; sfb < psyData[ch]->sfbActive; sfb++) {
+ psyOutChannel[ch]->sfbThresholdLdData[sfbGrp + sfb] =
+ fixMax(psyOutChannel[ch]->sfbThresholdLdData[sfbGrp + sfb],
+ FL2FXCONST_DBL(-0.515625f));
+ }
+ }
+
+ if (channels == 2) {
+ for (sfbGrp = 0; sfbGrp < noSfb; sfbGrp += hPsyConfShort->sfbCnt) {
+ LdDataVector(&psyData[ch]->sfbEnergyMS.Long[sfbGrp],
+ &psyData[ch]->sfbEnergyMSLdData[sfbGrp],
+ psyData[ch]->sfbActive);
+ }
+ }
+
+ FDKmemcpy(psyOutChannel[ch]->sfbOffsets, psyData[ch]->groupedSfbOffset,
+ (MAX_GROUPED_SFB + 1) * sizeof(INT));
+
+ } else {
+ int i;
+ /* maxSfb[ch] for long blocks */
+ for (sfb = psyData[ch]->sfbActive - 1; sfb >= 0; sfb--) {
+ for (line = hPsyConfLong->sfbOffset[sfb + 1] - 1;
+ line >= hPsyConfLong->sfbOffset[sfb]; line--) {
+ if (psyData[ch]->mdctSpectrum[line] != FL2FXCONST_SGL(0.0f)) break;
+ }
+ if (line > hPsyConfLong->sfbOffset[sfb]) break;
+ }
+ maxSfbPerGroup[ch] = sfb + 1;
+ maxSfbPerGroup[ch] =
+ fixMax(fixMin(5, psyData[ch]->sfbActive), maxSfbPerGroup[ch]);
+
+ /* sfbNrgLdData is calculated in FDKaacEnc_advancePsychLong, copy in
+ * psyOut structure */
+ FDKmemcpy(psyOutChannel[ch]->sfbEnergyLdData,
+ psyData[ch]->sfbEnergyLdData.Long,
+ psyData[ch]->sfbActive * sizeof(FIXP_DBL));
+
+ FDKmemcpy(psyOutChannel[ch]->sfbOffsets, hPsyConfLong->sfbOffset,
+ (MAX_GROUPED_SFB + 1) * sizeof(INT));
+
+ /* sfbMinSnrLdData modified in adjust threshold, copy necessary */
+ FDKmemcpy(psyOutChannel[ch]->sfbMinSnrLdData,
+ hPsyConfLong->sfbMinSnrLdData,
+ psyData[ch]->sfbActive * sizeof(FIXP_DBL));
+
+ /* sfbEnergyMSLdData ist already calculated in FDKaacEnc_CalcBandNrgMSOpt;
+ * only in long case */
+
+ /* calc sfbThrld and set Values smaller 2^-31 to 2^-33*/
+ LdDataVector(psyData[ch]->sfbThreshold.Long,
+ psyOutChannel[ch]->sfbThresholdLdData,
+ psyData[ch]->sfbActive);
+ for (i = 0; i < psyData[ch]->sfbActive; i++) {
+ psyOutChannel[ch]->sfbThresholdLdData[i] =
+ fixMax(psyOutChannel[ch]->sfbThresholdLdData[i],
+ FL2FXCONST_DBL(-0.515625f));
+ }
+ }
+ }
+
+ /*
+ Intensity parameter intialization.
+ */
+ for (ch = 0; ch < channels; ch++) {
+ FDKmemclear(psyOutChannel[ch]->isBook, MAX_GROUPED_SFB * sizeof(INT));
+ FDKmemclear(psyOutChannel[ch]->isScale, MAX_GROUPED_SFB * sizeof(INT));
+ }
+
+ for (ch = 0; ch < channels; ch++) {
+ INT win = (isShortWindow[ch] ? 1 : 0);
+ if (!psyStatic[ch]->isLFE) {
+ /* PNS Decision */
+ FDKaacEnc_PnsDetect(
+ &(psyConf[0].pnsConf), pnsData[ch],
+ psyStatic[ch]->blockSwitchingControl.lastWindowSequence,
+ psyData[ch]->sfbActive,
+ maxSfbPerGroup[ch], /* count of Sfb which are not zero. */
+ psyOutChannel[ch]->sfbThresholdLdData, psyConf[win].sfbOffset,
+ psyData[ch]->mdctSpectrum, psyData[ch]->sfbMaxScaleSpec.Long,
+ sfbTonality[ch], psyOutChannel[ch]->tnsInfo.order[0][0],
+ tnsData[ch]->dataRaw.Long.subBlockInfo.predictionGain[HIFILT],
+ tnsData[ch]->dataRaw.Long.subBlockInfo.tnsActive[HIFILT],
+ psyOutChannel[ch]->sfbEnergyLdData, psyOutChannel[ch]->noiseNrg);
+ } /* !isLFE */
+ } /* ch */
+
+ /*
+ stereo Processing
+ */
+ if (channels == 2) {
+ psyOutElement->toolsInfo.msDigest = MS_NONE;
+ psyOutElement->commonWindow = commonWindow;
+ if (psyOutElement->commonWindow)
+ maxSfbPerGroup[0] = maxSfbPerGroup[1] =
+ fixMax(maxSfbPerGroup[0], maxSfbPerGroup[1]);
+ if (psyStatic[0]->blockSwitchingControl.lastWindowSequence !=
+ SHORT_WINDOW) {
+ /* PNS preprocessing depending on ms processing: PNS not in Short Window!
+ */
+ FDKaacEnc_PreProcessPnsChannelPair(
+ psyData[0]->sfbActive, (&psyData[0]->sfbEnergy)->Long,
+ (&psyData[1]->sfbEnergy)->Long, psyOutChannel[0]->sfbEnergyLdData,
+ psyOutChannel[1]->sfbEnergyLdData, psyData[0]->sfbEnergyMS.Long,
+ &(psyConf[0].pnsConf), pnsData[0], pnsData[1]);
+
+ FDKaacEnc_IntensityStereoProcessing(
+ psyData[0]->sfbEnergy.Long, psyData[1]->sfbEnergy.Long,
+ psyData[0]->mdctSpectrum, psyData[1]->mdctSpectrum,
+ psyData[0]->sfbThreshold.Long, psyData[1]->sfbThreshold.Long,
+ psyOutChannel[1]->sfbThresholdLdData,
+ psyData[0]->sfbSpreadEnergy.Long, psyData[1]->sfbSpreadEnergy.Long,
+ psyOutChannel[0]->sfbEnergyLdData, psyOutChannel[1]->sfbEnergyLdData,
+ &psyOutElement->toolsInfo.msDigest, psyOutElement->toolsInfo.msMask,
+ psyConf[0].sfbCnt, psyConf[0].sfbCnt, maxSfbPerGroup[0],
+ psyConf[0].sfbOffset,
+ psyConf[0].allowIS && psyOutElement->commonWindow,
+ psyOutChannel[1]->isBook, psyOutChannel[1]->isScale, pnsData);
+
+ FDKaacEnc_MsStereoProcessing(
+ psyData, psyOutChannel, psyOutChannel[1]->isBook,
+ &psyOutElement->toolsInfo.msDigest, psyOutElement->toolsInfo.msMask,
+ psyConf[0].allowMS, psyData[0]->sfbActive, psyData[0]->sfbActive,
+ maxSfbPerGroup[0], psyOutChannel[0]->sfbOffsets);
+
+ /* PNS postprocessing */
+ FDKaacEnc_PostProcessPnsChannelPair(
+ psyData[0]->sfbActive, &(psyConf[0].pnsConf), pnsData[0], pnsData[1],
+ psyOutElement->toolsInfo.msMask, &psyOutElement->toolsInfo.msDigest);
+
+ } else {
+ FDKaacEnc_IntensityStereoProcessing(
+ psyData[0]->sfbEnergy.Long, psyData[1]->sfbEnergy.Long,
+ psyData[0]->mdctSpectrum, psyData[1]->mdctSpectrum,
+ psyData[0]->sfbThreshold.Long, psyData[1]->sfbThreshold.Long,
+ psyOutChannel[1]->sfbThresholdLdData,
+ psyData[0]->sfbSpreadEnergy.Long, psyData[1]->sfbSpreadEnergy.Long,
+ psyOutChannel[0]->sfbEnergyLdData, psyOutChannel[1]->sfbEnergyLdData,
+ &psyOutElement->toolsInfo.msDigest, psyOutElement->toolsInfo.msMask,
+ psyStatic[0]->blockSwitchingControl.noOfGroups *
+ hPsyConfShort->sfbCnt,
+ psyConf[1].sfbCnt, maxSfbPerGroup[0], psyData[0]->groupedSfbOffset,
+ psyConf[0].allowIS && psyOutElement->commonWindow,
+ psyOutChannel[1]->isBook, psyOutChannel[1]->isScale, pnsData);
+
+ /* it's OK to pass the ".Long" arrays here. They contain grouped short
+ * data since FDKaacEnc_groupShortData() */
+ FDKaacEnc_MsStereoProcessing(
+ psyData, psyOutChannel, psyOutChannel[1]->isBook,
+ &psyOutElement->toolsInfo.msDigest, psyOutElement->toolsInfo.msMask,
+ psyConf[1].allowMS,
+ psyStatic[0]->blockSwitchingControl.noOfGroups *
+ hPsyConfShort->sfbCnt,
+ hPsyConfShort->sfbCnt, maxSfbPerGroup[0],
+ psyOutChannel[0]->sfbOffsets);
+ }
+ } /* (channels == 2) */
+
+ /*
+ PNS Coding
+ */
+ for (ch = 0; ch < channels; ch++) {
+ if (psyStatic[ch]->isLFE) {
+ /* no PNS coding */
+ for (sfb = 0; sfb < psyData[ch]->sfbActive; sfb++) {
+ psyOutChannel[ch]->noiseNrg[sfb] = NO_NOISE_PNS;
+ }
+ } else {
+ FDKaacEnc_CodePnsChannel(
+ psyData[ch]->sfbActive, &(hThisPsyConf[ch]->pnsConf),
+ pnsData[ch]->pnsFlag, psyData[ch]->sfbEnergyLdData.Long,
+ psyOutChannel[ch]->noiseNrg, /* this is the energy that will be
+ written to the bitstream */
+ psyOutChannel[ch]->sfbThresholdLdData);
+ }
+ }
+
+ /*
+ build output
+ */
+ for (ch = 0; ch < channels; ch++) {
+ INT mask;
+ int grp;
+ psyOutChannel[ch]->maxSfbPerGroup = maxSfbPerGroup[ch];
+ psyOutChannel[ch]->mdctScale = psyData[ch]->mdctScale;
+ if (isShortWindow[ch] == 0) {
+ psyOutChannel[ch]->sfbCnt = hPsyConfLong->sfbActive;
+ psyOutChannel[ch]->sfbPerGroup = hPsyConfLong->sfbActive;
+ psyOutChannel[ch]->lastWindowSequence =
+ psyStatic[ch]->blockSwitchingControl.lastWindowSequence;
+ psyOutChannel[ch]->windowShape =
+ psyStatic[ch]->blockSwitchingControl.windowShape;
+ } else {
+ INT sfbCnt = psyStatic[ch]->blockSwitchingControl.noOfGroups *
+ hPsyConfShort->sfbCnt;
+
+ psyOutChannel[ch]->sfbCnt = sfbCnt;
+ psyOutChannel[ch]->sfbPerGroup = hPsyConfShort->sfbCnt;
+ psyOutChannel[ch]->lastWindowSequence = SHORT_WINDOW;
+ psyOutChannel[ch]->windowShape = SINE_WINDOW;
+ }
+ /* generate grouping mask */
+ mask = 0;
+ for (grp = 0; grp < psyStatic[ch]->blockSwitchingControl.noOfGroups;
+ grp++) {
+ int j;
+ mask <<= 1;
+ for (j = 1; j < psyStatic[ch]->blockSwitchingControl.groupLen[grp]; j++) {
+ mask = (mask << 1) | 1;
+ }
+ }
+ psyOutChannel[ch]->groupingMask = mask;
+
+ /* build interface */
+ FDKmemcpy(psyOutChannel[ch]->groupLen,
+ psyStatic[ch]->blockSwitchingControl.groupLen,
+ MAX_NO_OF_GROUPS * sizeof(INT));
+ FDKmemcpy(psyOutChannel[ch]->sfbEnergy, (&psyData[ch]->sfbEnergy)->Long,
+ MAX_GROUPED_SFB * sizeof(FIXP_DBL));
+ FDKmemcpy(psyOutChannel[ch]->sfbSpreadEnergy,
+ (&psyData[ch]->sfbSpreadEnergy)->Long,
+ MAX_GROUPED_SFB * sizeof(FIXP_DBL));
+ // FDKmemcpy(psyOutChannel[ch]->mdctSpectrum,
+ // psyData[ch]->mdctSpectrum, (1024)*sizeof(FIXP_DBL));
+ }
+
+ return AAC_ENC_OK;
+}
+
+void FDKaacEnc_PsyClose(PSY_INTERNAL **phPsyInternal, PSY_OUT **phPsyOut) {
+ int n, i;
+
+ if (phPsyInternal != NULL) {
+ PSY_INTERNAL *hPsyInternal = *phPsyInternal;
+
+ if (hPsyInternal) {
+ for (i = 0; i < (8); i++) {
+ if (hPsyInternal->pStaticChannels[i]) {
+ if (hPsyInternal->pStaticChannels[i]->psyInputBuffer)
+ FreeRam_aacEnc_PsyInputBuffer(
+ &hPsyInternal->pStaticChannels[i]
+ ->psyInputBuffer); /* AUDIO INPUT BUFFER */
+
+ FreeRam_aacEnc_PsyStatic(
+ &hPsyInternal->pStaticChannels[i]); /* PSY_STATIC */
+ }
+ }
+
+ for (i = 0; i < ((8)); i++) {
+ if (hPsyInternal->psyElement[i])
+ FreeRam_aacEnc_PsyElement(
+ &hPsyInternal->psyElement[i]); /* PSY_ELEMENT */
+ }
+
+ FreeRam_aacEnc_PsyInternal(phPsyInternal);
+ }
+ }
+
+ if (phPsyOut != NULL) {
+ for (n = 0; n < (1); n++) {
+ if (phPsyOut[n]) {
+ for (i = 0; i < (8); i++) {
+ if (phPsyOut[n]->pPsyOutChannels[i])
+ FreeRam_aacEnc_PsyOutChannel(
+ &phPsyOut[n]->pPsyOutChannels[i]); /* PSY_OUT_CHANNEL */
+ }
+
+ for (i = 0; i < ((8)); i++) {
+ if (phPsyOut[n]->psyOutElement[i])
+ FreeRam_aacEnc_PsyOutElements(
+ &phPsyOut[n]->psyOutElement[i]); /* PSY_OUT_ELEMENTS */
+ }
+
+ FreeRam_aacEnc_PsyOut(&phPsyOut[n]);
+ }
+ }
+ }
+}