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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/aacenc_tns.cpp
parent2f84a54ec1d10b10293c7b1f4ab9fee31f3c6327 (diff)
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): Alex Groeschel, Tobias Chalupka
+
+ Description: Temporal noise shaping
+
+*******************************************************************************/
+
+#include "aacenc_tns.h"
+#include "psy_const.h"
+#include "psy_configuration.h"
+#include "tns_func.h"
+#include "aacEnc_rom.h"
+#include "aacenc_tns.h"
+#include "FDK_lpc.h"
+
+#define FILTER_DIRECTION 0 /* 0 = up, 1 = down */
+
+static const FIXP_DBL acfWindowLong[12 + 3 + 1] = {
+ 0x7fffffff, 0x7fb80000, 0x7ee00000, 0x7d780000, 0x7b800000, 0x78f80000,
+ 0x75e00000, 0x72380000, 0x6e000000, 0x69380000, 0x63e00000, 0x5df80000,
+ 0x57800000, 0x50780000, 0x48e00000, 0x40b80000};
+
+static const FIXP_DBL acfWindowShort[4 + 3 + 1] = {
+ 0x7fffffff, 0x7e000000, 0x78000000, 0x6e000000,
+ 0x60000000, 0x4e000000, 0x38000000, 0x1e000000};
+
+typedef struct {
+ INT bitRateFrom[2]; /* noneSbr=0, useSbr=1 */
+ INT bitRateTo[2]; /* noneSbr=0, useSbr=1 */
+ TNS_PARAMETER_TABULATED paramTab[2]; /* mono=0, stereo=1 */
+
+} TNS_INFO_TAB;
+
+#define TNS_TIMERES_SCALE (1)
+#define FL2_TIMERES_FIX(a) (FL2FXCONST_DBL(a / (float)(1 << TNS_TIMERES_SCALE)))
+
+static const TNS_INFO_TAB tnsInfoTab[] = {
+ {{16000, 13500},
+ {32000, 28000},
+ {{{1, 1},
+ {1437, 1500},
+ {1400, 600},
+ {12, 12},
+ {FILTER_DIRECTION, FILTER_DIRECTION},
+ {3, 1},
+ {FL2_TIMERES_FIX(0.4f), FL2_TIMERES_FIX(1.2f)},
+ 1},
+ {{1, 1},
+ {1437, 1500},
+ {1400, 600},
+ {12, 12},
+ {FILTER_DIRECTION, FILTER_DIRECTION},
+ {3, 1},
+ {FL2_TIMERES_FIX(0.4f), FL2_TIMERES_FIX(1.2f)},
+ 1}}},
+ {{32001, 28001},
+ {60000, 52000},
+ {{{1, 1},
+ {1437, 1500},
+ {1400, 600},
+ {12, 10},
+ {FILTER_DIRECTION, FILTER_DIRECTION},
+ {3, 1},
+ {FL2_TIMERES_FIX(0.4f), FL2_TIMERES_FIX(1.0f)},
+ 1},
+ {{1, 1},
+ {1437, 1500},
+ {1400, 600},
+ {12, 10},
+ {FILTER_DIRECTION, FILTER_DIRECTION},
+ {3, 1},
+ {FL2_TIMERES_FIX(0.4f), FL2_TIMERES_FIX(1.0f)},
+ 1}}},
+ {{60001, 52001},
+ {384000, 384000},
+ {{{1, 1},
+ {1437, 1500},
+ {1400, 600},
+ {12, 8},
+ {FILTER_DIRECTION, FILTER_DIRECTION},
+ {3, 1},
+ {FL2_TIMERES_FIX(0.4f), FL2_TIMERES_FIX(1.0f)},
+ 1},
+ {{1, 1},
+ {1437, 1500},
+ {1400, 600},
+ {12, 8},
+ {FILTER_DIRECTION, FILTER_DIRECTION},
+ {3, 1},
+ {FL2_TIMERES_FIX(0.4f), FL2_TIMERES_FIX(1.0f)},
+ 1}}}};
+
+typedef struct {
+ INT samplingRate;
+ SCHAR maxBands[2]; /* long=0; short=1 */
+
+} TNS_MAX_TAB_ENTRY;
+
+static const TNS_MAX_TAB_ENTRY tnsMaxBandsTab1024[] = {
+ {96000, {31, 9}}, {88200, {31, 9}}, {64000, {34, 10}}, {48000, {40, 14}},
+ {44100, {42, 14}}, {32000, {51, 14}}, {24000, {46, 14}}, {22050, {46, 14}},
+ {16000, {42, 14}}, {12000, {42, 14}}, {11025, {42, 14}}, {8000, {39, 14}}};
+
+static const TNS_MAX_TAB_ENTRY tnsMaxBandsTab960[] =
+{
+ { 96000, { 31, 9}},
+ { 88200, { 31, 9}},
+ { 64000, { 34, 10}},
+ { 48000, { 49, 14}},
+ { 44100, { 49, 14}},
+ { 32000, { 49, 14}},
+ { 24000, { 46, 15}},
+ { 22050, { 46, 14}},
+ { 16000, { 46, 15}},
+ { 12000, { 42, 15}},
+ { 11025, { 42, 15}},
+ { 8000, { 40, 15}}
+};
+
+static const TNS_MAX_TAB_ENTRY tnsMaxBandsTab120[] = {
+ {48000, {12, -1}}, /* 48000 */
+ {44100, {12, -1}}, /* 44100 */
+ {32000, {15, -1}}, /* 32000 */
+ {24000, {15, -1}}, /* 24000 */
+ {22050, {15, -1}} /* 22050 */
+};
+
+static const TNS_MAX_TAB_ENTRY tnsMaxBandsTab128[] = {
+ {48000, {12, -1}}, /* 48000 */
+ {44100, {12, -1}}, /* 44100 */
+ {32000, {15, -1}}, /* 32000 */
+ {24000, {15, -1}}, /* 24000 */
+ {22050, {15, -1}} /* 22050 */
+};
+
+static const TNS_MAX_TAB_ENTRY tnsMaxBandsTab240[] = {
+ {96000, {22, -1}}, /* 96000 */
+ {48000, {22, -1}}, /* 48000 */
+ {44100, {22, -1}}, /* 44100 */
+ {32000, {21, -1}}, /* 32000 */
+ {24000, {21, -1}}, /* 24000 */
+ {22050, {21, -1}} /* 22050 */
+};
+
+static const TNS_MAX_TAB_ENTRY tnsMaxBandsTab256[] = {
+ {96000, {25, -1}}, /* 96000 */
+ {48000, {25, -1}}, /* 48000 */
+ {44100, {25, -1}}, /* 44100 */
+ {32000, {24, -1}}, /* 32000 */
+ {24000, {24, -1}}, /* 24000 */
+ {22050, {24, -1}} /* 22050 */
+};
+static const TNS_MAX_TAB_ENTRY tnsMaxBandsTab480[] = {{48000, {31, -1}},
+ {44100, {32, -1}},
+ {32000, {37, -1}},
+ {24000, {30, -1}},
+ {22050, {30, -1}}};
+
+static const TNS_MAX_TAB_ENTRY tnsMaxBandsTab512[] = {{48000, {31, -1}},
+ {44100, {32, -1}},
+ {32000, {37, -1}},
+ {24000, {31, -1}},
+ {22050, {31, -1}}};
+
+static void FDKaacEnc_Parcor2Index(const FIXP_LPC *parcor, INT *RESTRICT index,
+ const INT order, const INT bitsPerCoeff);
+
+static void FDKaacEnc_Index2Parcor(const INT *index, FIXP_LPC *RESTRICT parcor,
+ const INT order, const INT bitsPerCoeff);
+
+static void FDKaacEnc_CalcGaussWindow(FIXP_DBL *win, const int winSize,
+ const INT samplingRate,
+ const INT transformResolution,
+ const FIXP_DBL timeResolution,
+ const INT timeResolution_e);
+
+static const TNS_PARAMETER_TABULATED *FDKaacEnc_GetTnsParam(const INT bitRate,
+ const INT channels,
+ const INT sbrLd) {
+ int i;
+ const TNS_PARAMETER_TABULATED *tnsConfigTab = NULL;
+
+ for (i = 0; i < (int)(sizeof(tnsInfoTab) / sizeof(TNS_INFO_TAB)); i++) {
+ if ((bitRate >= tnsInfoTab[i].bitRateFrom[sbrLd ? 1 : 0]) &&
+ bitRate <= tnsInfoTab[i].bitRateTo[sbrLd ? 1 : 0]) {
+ tnsConfigTab = &tnsInfoTab[i].paramTab[(channels == 1) ? 0 : 1];
+ }
+ }
+
+ return tnsConfigTab;
+}
+
+static INT getTnsMaxBands(const INT sampleRate, const INT granuleLength,
+ const INT isShortBlock) {
+ int i;
+ INT numBands = -1;
+ const TNS_MAX_TAB_ENTRY *pMaxBandsTab = NULL;
+ int maxBandsTabSize = 0;
+
+ switch (granuleLength) {
+ case 960:
+ pMaxBandsTab = tnsMaxBandsTab960;
+ maxBandsTabSize = sizeof(tnsMaxBandsTab960) / sizeof(TNS_MAX_TAB_ENTRY);
+ break;
+ case 1024:
+ pMaxBandsTab = tnsMaxBandsTab1024;
+ maxBandsTabSize = sizeof(tnsMaxBandsTab1024) / sizeof(TNS_MAX_TAB_ENTRY);
+ break;
+ case 120:
+ pMaxBandsTab = tnsMaxBandsTab120;
+ maxBandsTabSize = sizeof(tnsMaxBandsTab120) / sizeof(TNS_MAX_TAB_ENTRY);
+ break;
+ case 128:
+ pMaxBandsTab = tnsMaxBandsTab128;
+ maxBandsTabSize = sizeof(tnsMaxBandsTab128) / sizeof(TNS_MAX_TAB_ENTRY);
+ break;
+ case 240:
+ pMaxBandsTab = tnsMaxBandsTab240;
+ maxBandsTabSize = sizeof(tnsMaxBandsTab240) / sizeof(TNS_MAX_TAB_ENTRY);
+ break;
+ case 256:
+ pMaxBandsTab = tnsMaxBandsTab256;
+ maxBandsTabSize = sizeof(tnsMaxBandsTab256) / sizeof(TNS_MAX_TAB_ENTRY);
+ break;
+ case 480:
+ pMaxBandsTab = tnsMaxBandsTab480;
+ maxBandsTabSize = sizeof(tnsMaxBandsTab480) / sizeof(TNS_MAX_TAB_ENTRY);
+ break;
+ case 512:
+ pMaxBandsTab = tnsMaxBandsTab512;
+ maxBandsTabSize = sizeof(tnsMaxBandsTab512) / sizeof(TNS_MAX_TAB_ENTRY);
+ break;
+ default:
+ numBands = -1;
+ }
+
+ if (pMaxBandsTab != NULL) {
+ for (i = 0; i < maxBandsTabSize; i++) {
+ numBands = pMaxBandsTab[i].maxBands[(!isShortBlock) ? 0 : 1];
+ if (sampleRate >= pMaxBandsTab[i].samplingRate) {
+ break;
+ }
+ }
+ }
+
+ return numBands;
+}
+
+/***************************************************************************/
+/*!
+ \brief FDKaacEnc_FreqToBandWidthRounding
+
+ Returns index of nearest band border
+
+ \param frequency
+ \param sampling frequency
+ \param total number of bands
+ \param pointer to table of band borders
+
+ \return band border
+****************************************************************************/
+
+INT FDKaacEnc_FreqToBandWidthRounding(const INT freq, const INT fs,
+ const INT numOfBands,
+ const INT *bandStartOffset) {
+ INT lineNumber, band;
+
+ /* assert(freq >= 0); */
+ lineNumber = (freq * bandStartOffset[numOfBands] * 4 / fs + 1) / 2;
+
+ /* freq > fs/2 */
+ if (lineNumber >= bandStartOffset[numOfBands]) return numOfBands;
+
+ /* find band the line number lies in */
+ for (band = 0; band < numOfBands; band++) {
+ if (bandStartOffset[band + 1] > lineNumber) break;
+ }
+
+ /* round to nearest band border */
+ if (lineNumber - bandStartOffset[band] >
+ bandStartOffset[band + 1] - lineNumber) {
+ band++;
+ }
+
+ return (band);
+}
+
+/*****************************************************************************
+
+ functionname: FDKaacEnc_InitTnsConfiguration
+ description: fill TNS_CONFIG structure with sensible content
+ returns:
+ input: bitrate, samplerate, number of channels,
+ blocktype (long or short),
+ TNS Config struct (modified),
+ psy config struct,
+ tns active flag
+ output:
+
+*****************************************************************************/
+AAC_ENCODER_ERROR FDKaacEnc_InitTnsConfiguration(
+ INT bitRate, INT sampleRate, INT channels, INT blockType, INT granuleLength,
+ INT isLowDelay, INT ldSbrPresent, TNS_CONFIG *tC, PSY_CONFIGURATION *pC,
+ INT active, INT useTnsPeak) {
+ int i;
+ // float acfTimeRes = (blockType == SHORT_WINDOW) ? 0.125f : 0.046875f;
+
+ if (channels <= 0) return (AAC_ENCODER_ERROR)1;
+
+ tC->isLowDelay = isLowDelay;
+
+ /* initialize TNS filter flag, order, and coefficient resolution (in bits per
+ * coeff) */
+ tC->tnsActive = (active) ? TRUE : FALSE;
+ tC->maxOrder = (blockType == SHORT_WINDOW) ? 5 : 12; /* maximum: 7, 20 */
+ if (bitRate < 16000) tC->maxOrder -= 2;
+ tC->coefRes = (blockType == SHORT_WINDOW) ? 3 : 4;
+
+ /* LPC stop line: highest MDCT line to be coded, but do not go beyond
+ * TNS_MAX_BANDS! */
+ tC->lpcStopBand = getTnsMaxBands(sampleRate, granuleLength,
+ (blockType == SHORT_WINDOW) ? 1 : 0);
+
+ if (tC->lpcStopBand < 0) {
+ return (AAC_ENCODER_ERROR)1;
+ }
+
+ tC->lpcStopBand = fMin(tC->lpcStopBand, pC->sfbActive);
+ tC->lpcStopLine = pC->sfbOffset[tC->lpcStopBand];
+
+ switch (granuleLength) {
+ case 960:
+ case 1024:
+ /* TNS start line: skip lower MDCT lines to prevent artifacts due to
+ * filter mismatch */
+ if (blockType == SHORT_WINDOW) {
+ tC->lpcStartBand[LOFILT] = 0;
+ } else {
+ tC->lpcStartBand[LOFILT] =
+ (sampleRate < 9391) ? 2 : ((sampleRate < 18783) ? 4 : 8);
+ }
+ tC->lpcStartLine[LOFILT] = pC->sfbOffset[tC->lpcStartBand[LOFILT]];
+
+ i = tC->lpcStopBand;
+ while (pC->sfbOffset[i] >
+ (tC->lpcStartLine[LOFILT] +
+ (tC->lpcStopLine - tC->lpcStartLine[LOFILT]) / 4))
+ i--;
+ tC->lpcStartBand[HIFILT] = i;
+ tC->lpcStartLine[HIFILT] = pC->sfbOffset[i];
+
+ tC->confTab.threshOn[HIFILT] = 1437;
+ tC->confTab.threshOn[LOFILT] = 1500;
+
+ tC->confTab.tnsLimitOrder[HIFILT] = tC->maxOrder;
+ tC->confTab.tnsLimitOrder[LOFILT] = fMax(0, tC->maxOrder - 7);
+
+ tC->confTab.tnsFilterDirection[HIFILT] = FILTER_DIRECTION;
+ tC->confTab.tnsFilterDirection[LOFILT] = FILTER_DIRECTION;
+
+ tC->confTab.acfSplit[HIFILT] =
+ -1; /* signal Merged4to2QuartersAutoCorrelation in
+ FDKaacEnc_MergedAutoCorrelation*/
+ tC->confTab.acfSplit[LOFILT] =
+ -1; /* signal Merged4to2QuartersAutoCorrelation in
+ FDKaacEnc_MergedAutoCorrelation */
+
+ tC->confTab.filterEnabled[HIFILT] = 1;
+ tC->confTab.filterEnabled[LOFILT] = 1;
+ tC->confTab.seperateFiltersAllowed = 1;
+
+ /* compute autocorrelation window based on maximum filter order for given
+ * block type */
+ /* for (i = 0; i <= tC->maxOrder + 3; i++) {
+ float acfWinTemp = acfTimeRes * i;
+ acfWindow[i] = FL2FXCONST_DBL(1.0f - acfWinTemp * acfWinTemp);
+ }
+ */
+ if (blockType == SHORT_WINDOW) {
+ FDKmemcpy(tC->acfWindow[HIFILT], acfWindowShort,
+ fMin((LONG)sizeof(acfWindowShort),
+ (LONG)sizeof(tC->acfWindow[HIFILT])));
+ FDKmemcpy(tC->acfWindow[LOFILT], acfWindowShort,
+ fMin((LONG)sizeof(acfWindowShort),
+ (LONG)sizeof(tC->acfWindow[HIFILT])));
+ } else {
+ FDKmemcpy(tC->acfWindow[HIFILT], acfWindowLong,
+ fMin((LONG)sizeof(acfWindowLong),
+ (LONG)sizeof(tC->acfWindow[HIFILT])));
+ FDKmemcpy(tC->acfWindow[LOFILT], acfWindowLong,
+ fMin((LONG)sizeof(acfWindowLong),
+ (LONG)sizeof(tC->acfWindow[HIFILT])));
+ }
+ break;
+ case 480:
+ case 512: {
+ const TNS_PARAMETER_TABULATED *pCfg =
+ FDKaacEnc_GetTnsParam(bitRate, channels, ldSbrPresent);
+ if (pCfg != NULL) {
+ FDKmemcpy(&(tC->confTab), pCfg, sizeof(tC->confTab));
+
+ tC->lpcStartBand[HIFILT] = FDKaacEnc_FreqToBandWidthRounding(
+ pCfg->filterStartFreq[HIFILT], sampleRate, pC->sfbCnt,
+ pC->sfbOffset);
+ tC->lpcStartLine[HIFILT] = pC->sfbOffset[tC->lpcStartBand[HIFILT]];
+ tC->lpcStartBand[LOFILT] = FDKaacEnc_FreqToBandWidthRounding(
+ pCfg->filterStartFreq[LOFILT], sampleRate, pC->sfbCnt,
+ pC->sfbOffset);
+ tC->lpcStartLine[LOFILT] = pC->sfbOffset[tC->lpcStartBand[LOFILT]];
+
+ FDKaacEnc_CalcGaussWindow(
+ tC->acfWindow[HIFILT], tC->maxOrder + 1, sampleRate, granuleLength,
+ pCfg->tnsTimeResolution[HIFILT], TNS_TIMERES_SCALE);
+ FDKaacEnc_CalcGaussWindow(
+ tC->acfWindow[LOFILT], tC->maxOrder + 1, sampleRate, granuleLength,
+ pCfg->tnsTimeResolution[LOFILT], TNS_TIMERES_SCALE);
+ } else {
+ tC->tnsActive =
+ FALSE; /* no configuration available, disable tns tool */
+ }
+ } break;
+ default:
+ tC->tnsActive = FALSE; /* no configuration available, disable tns tool */
+ }
+
+ return AAC_ENC_OK;
+}
+
+/***************************************************************************/
+/*!
+ \brief FDKaacEnc_ScaleUpSpectrum
+
+ Scales up spectrum lines in a given frequency section
+
+ \param scaled spectrum
+ \param original spectrum
+ \param frequency line to start scaling
+ \param frequency line to enc scaling
+
+ \return scale factor
+
+****************************************************************************/
+static inline INT FDKaacEnc_ScaleUpSpectrum(FIXP_DBL *dest, const FIXP_DBL *src,
+ const INT startLine,
+ const INT stopLine) {
+ INT i, scale;
+
+ FIXP_DBL maxVal = FL2FXCONST_DBL(0.f);
+
+ /* Get highest value in given spectrum */
+ for (i = startLine; i < stopLine; i++) {
+ maxVal = fixMax(maxVal, fixp_abs(src[i]));
+ }
+ scale = CountLeadingBits(maxVal);
+
+ /* Scale spectrum according to highest value */
+ for (i = startLine; i < stopLine; i++) {
+ dest[i] = src[i] << scale;
+ }
+
+ return scale;
+}
+
+/***************************************************************************/
+/*!
+ \brief FDKaacEnc_CalcAutoCorrValue
+
+ Calculate autocorellation value for one lag
+
+ \param pointer to spectrum
+ \param start line
+ \param stop line
+ \param lag to be calculated
+ \param scaling of the lag
+
+****************************************************************************/
+static inline FIXP_DBL FDKaacEnc_CalcAutoCorrValue(const FIXP_DBL *spectrum,
+ const INT startLine,
+ const INT stopLine,
+ const INT lag,
+ const INT scale) {
+ int i;
+ FIXP_DBL result = FL2FXCONST_DBL(0.f);
+
+ /* This versions allows to save memory accesses, when computing pow2 */
+ /* It is of interest for ARM, XTENSA without parallel memory access */
+ if (lag == 0) {
+ for (i = startLine; i < stopLine; i++) {
+ result += (fPow2(spectrum[i]) >> scale);
+ }
+ } else {
+ for (i = startLine; i < (stopLine - lag); i++) {
+ result += (fMult(spectrum[i], spectrum[i + lag]) >> scale);
+ }
+ }
+
+ return result;
+}
+
+/***************************************************************************/
+/*!
+ \brief FDKaacEnc_AutoCorrNormFac
+
+ Autocorrelation function for 1st and 2nd half of the spectrum
+
+ \param pointer to spectrum
+ \param pointer to autocorrelation window
+ \param filter start line
+
+****************************************************************************/
+static inline FIXP_DBL FDKaacEnc_AutoCorrNormFac(const FIXP_DBL value,
+ const INT scale, INT *sc) {
+#define HLM_MIN_NRG 0.0000000037252902984619140625f /* 2^-28 */
+#define MAX_INV_NRGFAC (1.f / HLM_MIN_NRG)
+
+ FIXP_DBL retValue;
+ FIXP_DBL A, B;
+
+ if (scale >= 0) {
+ A = value;
+ B = FL2FXCONST_DBL(HLM_MIN_NRG) >> fixMin(DFRACT_BITS - 1, scale);
+ } else {
+ A = value >> fixMin(DFRACT_BITS - 1, (-scale));
+ B = FL2FXCONST_DBL(HLM_MIN_NRG);
+ }
+
+ if (A > B) {
+ int shift = 0;
+ FIXP_DBL tmp = invSqrtNorm2(value, &shift);
+
+ retValue = fMult(tmp, tmp);
+ *sc += (2 * shift);
+ } else {
+ /* MAX_INV_NRGFAC*FDKpow(2,-28) = 1/2^-28 * 2^-28 = 1.0 */
+ retValue =
+ /*FL2FXCONST_DBL(MAX_INV_NRGFAC*FDKpow(2,-28))*/ (FIXP_DBL)MAXVAL_DBL;
+ *sc += scale + 28;
+ }
+
+ return retValue;
+}
+
+static void FDKaacEnc_MergedAutoCorrelation(
+ const FIXP_DBL *spectrum, const INT isLowDelay,
+ const FIXP_DBL acfWindow[MAX_NUM_OF_FILTERS][TNS_MAX_ORDER + 3 + 1],
+ const INT lpcStartLine[MAX_NUM_OF_FILTERS], const INT lpcStopLine,
+ const INT maxOrder, const INT acfSplit[MAX_NUM_OF_FILTERS], FIXP_DBL *_rxx1,
+ FIXP_DBL *_rxx2) {
+ int i, idx0, idx1, idx2, idx3, idx4, lag;
+ FIXP_DBL rxx1_0, rxx2_0, rxx3_0, rxx4_0;
+
+ /* buffer for temporal spectrum */
+ C_ALLOC_SCRATCH_START(pSpectrum, FIXP_DBL, (1024))
+
+ /* MDCT line indices separating the 1st, 2nd, 3rd, and 4th analysis quarters
+ */
+ if ((acfSplit[LOFILT] == -1) || (acfSplit[HIFILT] == -1)) {
+ /* autocorrelation function for 1st, 2nd, 3rd, and 4th quarter of the
+ * spectrum */
+ idx0 = lpcStartLine[LOFILT];
+ i = lpcStopLine - lpcStartLine[LOFILT];
+ idx1 = idx0 + i / 4;
+ idx2 = idx0 + i / 2;
+ idx3 = idx0 + i * 3 / 4;
+ idx4 = lpcStopLine;
+ } else {
+ FDK_ASSERT(acfSplit[LOFILT] == 1);
+ FDK_ASSERT(acfSplit[HIFILT] == 3);
+ i = (lpcStopLine - lpcStartLine[HIFILT]) / 3;
+ idx0 = lpcStartLine[LOFILT];
+ idx1 = lpcStartLine[HIFILT];
+ idx2 = idx1 + i;
+ idx3 = idx2 + i;
+ idx4 = lpcStopLine;
+ }
+
+ /* copy spectrum to temporal buffer and scale up as much as possible */
+ INT sc1 = FDKaacEnc_ScaleUpSpectrum(pSpectrum, spectrum, idx0, idx1);
+ INT sc2 = FDKaacEnc_ScaleUpSpectrum(pSpectrum, spectrum, idx1, idx2);
+ INT sc3 = FDKaacEnc_ScaleUpSpectrum(pSpectrum, spectrum, idx2, idx3);
+ INT sc4 = FDKaacEnc_ScaleUpSpectrum(pSpectrum, spectrum, idx3, idx4);
+
+ /* get scaling values for summation */
+ INT nsc1, nsc2, nsc3, nsc4;
+ for (nsc1 = 1; (1 << nsc1) < (idx1 - idx0); nsc1++)
+ ;
+ for (nsc2 = 1; (1 << nsc2) < (idx2 - idx1); nsc2++)
+ ;
+ for (nsc3 = 1; (1 << nsc3) < (idx3 - idx2); nsc3++)
+ ;
+ for (nsc4 = 1; (1 << nsc4) < (idx4 - idx3); nsc4++)
+ ;
+
+ /* compute autocorrelation value at lag zero, i. e. energy, for each quarter
+ */
+ rxx1_0 = FDKaacEnc_CalcAutoCorrValue(pSpectrum, idx0, idx1, 0, nsc1);
+ rxx2_0 = FDKaacEnc_CalcAutoCorrValue(pSpectrum, idx1, idx2, 0, nsc2);
+ rxx3_0 = FDKaacEnc_CalcAutoCorrValue(pSpectrum, idx2, idx3, 0, nsc3);
+ rxx4_0 = FDKaacEnc_CalcAutoCorrValue(pSpectrum, idx3, idx4, 0, nsc4);
+
+ /* compute energy normalization factors, i. e. 1/energy (saves some divisions)
+ */
+ if (rxx1_0 != FL2FXCONST_DBL(0.f)) {
+ INT sc_fac1 = -1;
+ FIXP_DBL fac1 =
+ FDKaacEnc_AutoCorrNormFac(rxx1_0, ((-2 * sc1) + nsc1), &sc_fac1);
+ _rxx1[0] = scaleValue(fMult(rxx1_0, fac1), sc_fac1);
+
+ if (isLowDelay) {
+ for (lag = 1; lag <= maxOrder; lag++) {
+ /* compute energy-normalized and windowed autocorrelation values at this
+ * lag */
+ FIXP_DBL x1 =
+ FDKaacEnc_CalcAutoCorrValue(pSpectrum, idx0, idx1, lag, nsc1);
+ _rxx1[lag] =
+ fMult(scaleValue(fMult(x1, fac1), sc_fac1), acfWindow[LOFILT][lag]);
+ }
+ } else {
+ for (lag = 1; lag <= maxOrder; lag++) {
+ if ((3 * lag) <= maxOrder + 3) {
+ FIXP_DBL x1 =
+ FDKaacEnc_CalcAutoCorrValue(pSpectrum, idx0, idx1, lag, nsc1);
+ _rxx1[lag] = fMult(scaleValue(fMult(x1, fac1), sc_fac1),
+ acfWindow[LOFILT][3 * lag]);
+ }
+ }
+ }
+ }
+
+ /* auto corr over upper 3/4 of spectrum */
+ if (!((rxx2_0 == FL2FXCONST_DBL(0.f)) && (rxx3_0 == FL2FXCONST_DBL(0.f)) &&
+ (rxx4_0 == FL2FXCONST_DBL(0.f)))) {
+ FIXP_DBL fac2, fac3, fac4;
+ fac2 = fac3 = fac4 = FL2FXCONST_DBL(0.f);
+ INT sc_fac2, sc_fac3, sc_fac4;
+ sc_fac2 = sc_fac3 = sc_fac4 = 0;
+
+ if (rxx2_0 != FL2FXCONST_DBL(0.f)) {
+ fac2 = FDKaacEnc_AutoCorrNormFac(rxx2_0, ((-2 * sc2) + nsc2), &sc_fac2);
+ sc_fac2 -= 2;
+ }
+ if (rxx3_0 != FL2FXCONST_DBL(0.f)) {
+ fac3 = FDKaacEnc_AutoCorrNormFac(rxx3_0, ((-2 * sc3) + nsc3), &sc_fac3);
+ sc_fac3 -= 2;
+ }
+ if (rxx4_0 != FL2FXCONST_DBL(0.f)) {
+ fac4 = FDKaacEnc_AutoCorrNormFac(rxx4_0, ((-2 * sc4) + nsc4), &sc_fac4);
+ sc_fac4 -= 2;
+ }
+
+ _rxx2[0] = scaleValue(fMult(rxx2_0, fac2), sc_fac2) +
+ scaleValue(fMult(rxx3_0, fac3), sc_fac3) +
+ scaleValue(fMult(rxx4_0, fac4), sc_fac4);
+
+ for (lag = 1; lag <= maxOrder; lag++) {
+ /* merge quarters 2, 3, 4 into one autocorrelation; quarter 1 stays
+ * separate */
+ FIXP_DBL x2 = scaleValue(fMult(FDKaacEnc_CalcAutoCorrValue(
+ pSpectrum, idx1, idx2, lag, nsc2),
+ fac2),
+ sc_fac2) +
+ scaleValue(fMult(FDKaacEnc_CalcAutoCorrValue(
+ pSpectrum, idx2, idx3, lag, nsc3),
+ fac3),
+ sc_fac3) +
+ scaleValue(fMult(FDKaacEnc_CalcAutoCorrValue(
+ pSpectrum, idx3, idx4, lag, nsc4),
+ fac4),
+ sc_fac4);
+
+ _rxx2[lag] = fMult(x2, acfWindow[HIFILT][lag]);
+ }
+ }
+
+ C_ALLOC_SCRATCH_END(pSpectrum, FIXP_DBL, (1024))
+}
+
+/*****************************************************************************
+ functionname: FDKaacEnc_TnsDetect
+ description: do decision, if TNS shall be used or not
+ returns:
+ input: tns data structure (modified),
+ tns config structure,
+ scalefactor size and table,
+ spectrum,
+ subblock num, blocktype,
+ sfb-wise energy.
+
+*****************************************************************************/
+INT FDKaacEnc_TnsDetect(TNS_DATA *tnsData, const TNS_CONFIG *tC,
+ TNS_INFO *tnsInfo, INT sfbCnt, const FIXP_DBL *spectrum,
+ INT subBlockNumber, INT blockType) {
+ /* autocorrelation function for 1st, 2nd, 3rd, and 4th quarter of the
+ * spectrum. */
+ FIXP_DBL rxx1[TNS_MAX_ORDER + 1]; /* higher part */
+ FIXP_DBL rxx2[TNS_MAX_ORDER + 1]; /* lower part */
+ FIXP_LPC parcor_tmp[TNS_MAX_ORDER];
+
+ int i;
+
+ FDKmemclear(rxx1, sizeof(rxx1));
+ FDKmemclear(rxx2, sizeof(rxx2));
+
+ TNS_SUBBLOCK_INFO *tsbi =
+ (blockType == SHORT_WINDOW)
+ ? &tnsData->dataRaw.Short.subBlockInfo[subBlockNumber]
+ : &tnsData->dataRaw.Long.subBlockInfo;
+
+ tnsData->filtersMerged = FALSE;
+
+ tsbi->tnsActive[HIFILT] = FALSE;
+ tsbi->predictionGain[HIFILT] = 1000;
+ tsbi->tnsActive[LOFILT] = FALSE;
+ tsbi->predictionGain[LOFILT] = 1000;
+
+ tnsInfo->numOfFilters[subBlockNumber] = 0;
+ tnsInfo->coefRes[subBlockNumber] = tC->coefRes;
+ for (i = 0; i < tC->maxOrder; i++) {
+ tnsInfo->coef[subBlockNumber][HIFILT][i] =
+ tnsInfo->coef[subBlockNumber][LOFILT][i] = 0;
+ }
+
+ tnsInfo->length[subBlockNumber][HIFILT] =
+ tnsInfo->length[subBlockNumber][LOFILT] = 0;
+ tnsInfo->order[subBlockNumber][HIFILT] =
+ tnsInfo->order[subBlockNumber][LOFILT] = 0;
+
+ if ((tC->tnsActive) && (tC->maxOrder > 0)) {
+ int sumSqrCoef;
+
+ FDKaacEnc_MergedAutoCorrelation(
+ spectrum, tC->isLowDelay, tC->acfWindow, tC->lpcStartLine,
+ tC->lpcStopLine, tC->maxOrder, tC->confTab.acfSplit, rxx1, rxx2);
+
+ /* compute higher TNS filter coefficients in lattice form (ParCor) with
+ * LeRoux-Gueguen/Schur algorithm */
+ {
+ FIXP_DBL predictionGain_m;
+ INT predictionGain_e;
+
+ CLpc_AutoToParcor(rxx2, 0, parcor_tmp, tC->confTab.tnsLimitOrder[HIFILT],
+ &predictionGain_m, &predictionGain_e);
+ tsbi->predictionGain[HIFILT] =
+ (INT)fMultNorm(predictionGain_m, predictionGain_e, 1000, 31, 31);
+ }
+
+ /* non-linear quantization of TNS lattice coefficients with given resolution
+ */
+ FDKaacEnc_Parcor2Index(parcor_tmp, tnsInfo->coef[subBlockNumber][HIFILT],
+ tC->confTab.tnsLimitOrder[HIFILT], tC->coefRes);
+
+ /* reduce filter order by truncating trailing zeros, compute sum(abs(coefs))
+ */
+ for (i = tC->confTab.tnsLimitOrder[HIFILT] - 1; i >= 0; i--) {
+ if (tnsInfo->coef[subBlockNumber][HIFILT][i] != 0) {
+ break;
+ }
+ }
+
+ tnsInfo->order[subBlockNumber][HIFILT] = i + 1;
+
+ sumSqrCoef = 0;
+ for (; i >= 0; i--) {
+ sumSqrCoef += tnsInfo->coef[subBlockNumber][HIFILT][i] *
+ tnsInfo->coef[subBlockNumber][HIFILT][i];
+ }
+
+ tnsInfo->direction[subBlockNumber][HIFILT] =
+ tC->confTab.tnsFilterDirection[HIFILT];
+ tnsInfo->length[subBlockNumber][HIFILT] = sfbCnt - tC->lpcStartBand[HIFILT];
+
+ /* disable TNS if predictionGain is less than 3dB or sumSqrCoef is too small
+ */
+ if ((tsbi->predictionGain[HIFILT] > tC->confTab.threshOn[HIFILT]) ||
+ (sumSqrCoef > (tC->confTab.tnsLimitOrder[HIFILT] / 2 + 2))) {
+ tsbi->tnsActive[HIFILT] = TRUE;
+ tnsInfo->numOfFilters[subBlockNumber]++;
+
+ /* compute second filter for lower quarter; only allowed for long windows!
+ */
+ if ((blockType != SHORT_WINDOW) && (tC->confTab.filterEnabled[LOFILT]) &&
+ (tC->confTab.seperateFiltersAllowed)) {
+ /* compute second filter for lower frequencies */
+
+ /* compute TNS filter in lattice (ParCor) form with LeRoux-Gueguen
+ * algorithm */
+ INT predGain;
+ {
+ FIXP_DBL predictionGain_m;
+ INT predictionGain_e;
+
+ CLpc_AutoToParcor(rxx1, 0, parcor_tmp,
+ tC->confTab.tnsLimitOrder[LOFILT],
+ &predictionGain_m, &predictionGain_e);
+ predGain =
+ (INT)fMultNorm(predictionGain_m, predictionGain_e, 1000, 31, 31);
+ }
+
+ /* non-linear quantization of TNS lattice coefficients with given
+ * resolution */
+ FDKaacEnc_Parcor2Index(parcor_tmp,
+ tnsInfo->coef[subBlockNumber][LOFILT],
+ tC->confTab.tnsLimitOrder[LOFILT], tC->coefRes);
+
+ /* reduce filter order by truncating trailing zeros, compute
+ * sum(abs(coefs)) */
+ for (i = tC->confTab.tnsLimitOrder[LOFILT] - 1; i >= 0; i--) {
+ if (tnsInfo->coef[subBlockNumber][LOFILT][i] != 0) {
+ break;
+ }
+ }
+ tnsInfo->order[subBlockNumber][LOFILT] = i + 1;
+
+ sumSqrCoef = 0;
+ for (; i >= 0; i--) {
+ sumSqrCoef += tnsInfo->coef[subBlockNumber][LOFILT][i] *
+ tnsInfo->coef[subBlockNumber][LOFILT][i];
+ }
+
+ tnsInfo->direction[subBlockNumber][LOFILT] =
+ tC->confTab.tnsFilterDirection[LOFILT];
+ tnsInfo->length[subBlockNumber][LOFILT] =
+ tC->lpcStartBand[HIFILT] - tC->lpcStartBand[LOFILT];
+
+ /* filter lower quarter if gain is high enough, but not if it's too high
+ */
+ if (((predGain > tC->confTab.threshOn[LOFILT]) &&
+ (predGain < (16000 * tC->confTab.tnsLimitOrder[LOFILT]))) ||
+ ((sumSqrCoef > 9) &&
+ (sumSqrCoef < 22 * tC->confTab.tnsLimitOrder[LOFILT]))) {
+ /* compare lower to upper filter; if they are very similar, merge them
+ */
+ tsbi->tnsActive[LOFILT] = TRUE;
+ sumSqrCoef = 0;
+ for (i = 0; i < tC->confTab.tnsLimitOrder[LOFILT]; i++) {
+ sumSqrCoef += fAbs(tnsInfo->coef[subBlockNumber][HIFILT][i] -
+ tnsInfo->coef[subBlockNumber][LOFILT][i]);
+ }
+ if ((sumSqrCoef < 2) &&
+ (tnsInfo->direction[subBlockNumber][LOFILT] ==
+ tnsInfo->direction[subBlockNumber][HIFILT])) {
+ tnsData->filtersMerged = TRUE;
+ tnsInfo->length[subBlockNumber][HIFILT] =
+ sfbCnt - tC->lpcStartBand[LOFILT];
+ for (; i < tnsInfo->order[subBlockNumber][HIFILT]; i++) {
+ if (fAbs(tnsInfo->coef[subBlockNumber][HIFILT][i]) > 1) {
+ break;
+ }
+ }
+ for (i--; i >= 0; i--) {
+ if (tnsInfo->coef[subBlockNumber][HIFILT][i] != 0) {
+ break;
+ }
+ }
+ if (i < tnsInfo->order[subBlockNumber][HIFILT]) {
+ tnsInfo->order[subBlockNumber][HIFILT] = i + 1;
+ }
+ } else {
+ tnsInfo->numOfFilters[subBlockNumber]++;
+ }
+ } /* filter lower part */
+ tsbi->predictionGain[LOFILT] = predGain;
+
+ } /* second filter allowed */
+ } /* if predictionGain > 1437 ... */
+ } /* maxOrder > 0 && tnsActive */
+
+ return 0;
+}
+
+/***************************************************************************/
+/*!
+ \brief FDKaacLdEnc_TnsSync
+
+ synchronize TNS parameters when TNS gain difference small (relative)
+
+ \param pointer to TNS data structure (destination)
+ \param pointer to TNS data structure (source)
+ \param pointer to TNS config structure
+ \param number of sub-block
+ \param block type
+
+ \return void
+****************************************************************************/
+void FDKaacEnc_TnsSync(TNS_DATA *tnsDataDest, const TNS_DATA *tnsDataSrc,
+ TNS_INFO *tnsInfoDest, TNS_INFO *tnsInfoSrc,
+ const INT blockTypeDest, const INT blockTypeSrc,
+ const TNS_CONFIG *tC) {
+ int i, w, absDiff, nWindows;
+ TNS_SUBBLOCK_INFO *sbInfoDest;
+ const TNS_SUBBLOCK_INFO *sbInfoSrc;
+
+ /* if one channel contains short blocks and the other not, do not synchronize
+ */
+ if ((blockTypeSrc == SHORT_WINDOW && blockTypeDest != SHORT_WINDOW) ||
+ (blockTypeDest == SHORT_WINDOW && blockTypeSrc != SHORT_WINDOW)) {
+ return;
+ }
+
+ if (blockTypeDest != SHORT_WINDOW) {
+ sbInfoDest = &tnsDataDest->dataRaw.Long.subBlockInfo;
+ sbInfoSrc = &tnsDataSrc->dataRaw.Long.subBlockInfo;
+ nWindows = 1;
+ } else {
+ sbInfoDest = &tnsDataDest->dataRaw.Short.subBlockInfo[0];
+ sbInfoSrc = &tnsDataSrc->dataRaw.Short.subBlockInfo[0];
+ nWindows = 8;
+ }
+
+ for (w = 0; w < nWindows; w++) {
+ const TNS_SUBBLOCK_INFO *pSbInfoSrcW = sbInfoSrc + w;
+ TNS_SUBBLOCK_INFO *pSbInfoDestW = sbInfoDest + w;
+ INT doSync = 1, absDiffSum = 0;
+
+ /* if TNS is active in at least one channel, check if ParCor coefficients of
+ * higher filter are similar */
+ if (pSbInfoDestW->tnsActive[HIFILT] || pSbInfoSrcW->tnsActive[HIFILT]) {
+ for (i = 0; i < tC->maxOrder; i++) {
+ absDiff = fAbs(tnsInfoDest->coef[w][HIFILT][i] -
+ tnsInfoSrc->coef[w][HIFILT][i]);
+ absDiffSum += absDiff;
+ /* if coefficients diverge too much between channels, do not synchronize
+ */
+ if ((absDiff > 1) || (absDiffSum > 2)) {
+ doSync = 0;
+ break;
+ }
+ }
+
+ if (doSync) {
+ /* if no significant difference was detected, synchronize coefficient
+ * sets */
+ if (pSbInfoSrcW->tnsActive[HIFILT]) {
+ /* no dest filter, or more dest than source filters: use one dest
+ * filter */
+ if ((!pSbInfoDestW->tnsActive[HIFILT]) ||
+ ((pSbInfoDestW->tnsActive[HIFILT]) &&
+ (tnsInfoDest->numOfFilters[w] > tnsInfoSrc->numOfFilters[w]))) {
+ pSbInfoDestW->tnsActive[HIFILT] = tnsInfoDest->numOfFilters[w] = 1;
+ }
+ tnsDataDest->filtersMerged = tnsDataSrc->filtersMerged;
+ tnsInfoDest->order[w][HIFILT] = tnsInfoSrc->order[w][HIFILT];
+ tnsInfoDest->length[w][HIFILT] = tnsInfoSrc->length[w][HIFILT];
+ tnsInfoDest->direction[w][HIFILT] = tnsInfoSrc->direction[w][HIFILT];
+ tnsInfoDest->coefCompress[w][HIFILT] =
+ tnsInfoSrc->coefCompress[w][HIFILT];
+
+ for (i = 0; i < tC->maxOrder; i++) {
+ tnsInfoDest->coef[w][HIFILT][i] = tnsInfoSrc->coef[w][HIFILT][i];
+ }
+ } else
+ pSbInfoDestW->tnsActive[HIFILT] = tnsInfoDest->numOfFilters[w] = 0;
+ }
+ }
+ }
+}
+
+/***************************************************************************/
+/*!
+ \brief FDKaacEnc_TnsEncode
+
+ perform TNS encoding
+
+ \param pointer to TNS info structure
+ \param pointer to TNS data structure
+ \param number of sfbs
+ \param pointer to TNS config structure
+ \param low-pass line
+ \param pointer to spectrum
+ \param number of sub-block
+ \param block type
+
+ \return ERROR STATUS
+****************************************************************************/
+INT FDKaacEnc_TnsEncode(TNS_INFO *tnsInfo, TNS_DATA *tnsData,
+ const INT numOfSfb, const TNS_CONFIG *tC,
+ const INT lowPassLine, FIXP_DBL *spectrum,
+ const INT subBlockNumber, const INT blockType) {
+ INT i, startLine, stopLine;
+
+ if (((blockType == SHORT_WINDOW) &&
+ (!tnsData->dataRaw.Short.subBlockInfo[subBlockNumber]
+ .tnsActive[HIFILT])) ||
+ ((blockType != SHORT_WINDOW) &&
+ (!tnsData->dataRaw.Long.subBlockInfo.tnsActive[HIFILT]))) {
+ return 1;
+ }
+
+ startLine = (tnsData->filtersMerged) ? tC->lpcStartLine[LOFILT]
+ : tC->lpcStartLine[HIFILT];
+ stopLine = tC->lpcStopLine;
+
+ for (i = 0; i < tnsInfo->numOfFilters[subBlockNumber]; i++) {
+ INT lpcGainFactor;
+ FIXP_LPC LpcCoeff[TNS_MAX_ORDER];
+ FIXP_DBL workBuffer[TNS_MAX_ORDER];
+ FIXP_LPC parcor_tmp[TNS_MAX_ORDER];
+
+ FDKaacEnc_Index2Parcor(tnsInfo->coef[subBlockNumber][i], parcor_tmp,
+ tnsInfo->order[subBlockNumber][i], tC->coefRes);
+
+ lpcGainFactor = CLpc_ParcorToLpc(
+ parcor_tmp, LpcCoeff, tnsInfo->order[subBlockNumber][i], workBuffer);
+
+ FDKmemclear(workBuffer, TNS_MAX_ORDER * sizeof(FIXP_DBL));
+ CLpc_Analysis(&spectrum[startLine], stopLine - startLine, LpcCoeff,
+ lpcGainFactor, tnsInfo->order[subBlockNumber][i], workBuffer,
+ NULL);
+
+ /* update for second filter */
+ startLine = tC->lpcStartLine[LOFILT];
+ stopLine = tC->lpcStartLine[HIFILT];
+ }
+
+ return (0);
+}
+
+static void FDKaacEnc_CalcGaussWindow(FIXP_DBL *win, const int winSize,
+ const INT samplingRate,
+ const INT transformResolution,
+ const FIXP_DBL timeResolution,
+ const INT timeResolution_e) {
+#define PI_E (2)
+#define PI_M FL2FXCONST_DBL(3.1416f / (float)(1 << PI_E))
+
+#define EULER_E (2)
+#define EULER_M FL2FXCONST_DBL(2.7183 / (float)(1 << EULER_E))
+
+#define COEFF_LOOP_SCALE (4)
+
+ INT i, e1, e2, gaussExp_e;
+ FIXP_DBL gaussExp_m;
+
+ /* calc. window exponent from time resolution:
+ *
+ * gaussExp = PI * samplingRate * 0.001f * timeResolution /
+ * transformResolution; gaussExp = -0.5f * gaussExp * gaussExp;
+ */
+ gaussExp_m = fMultNorm(
+ timeResolution,
+ fMult(PI_M,
+ fDivNorm((FIXP_DBL)(samplingRate),
+ (FIXP_DBL)(LONG)(transformResolution * 1000.f), &e1)),
+ &e2);
+ gaussExp_m = -fPow2Div2(gaussExp_m);
+ gaussExp_e = 2 * (e1 + e2 + timeResolution_e + PI_E);
+
+ FDK_ASSERT(winSize < (1 << COEFF_LOOP_SCALE));
+
+ /* calc. window coefficients
+ * win[i] = (float)exp( gaussExp * (i+0.5) * (i+0.5) );
+ */
+ for (i = 0; i < winSize; i++) {
+ win[i] = fPow(
+ EULER_M, EULER_E,
+ fMult(gaussExp_m,
+ fPow2((i * FL2FXCONST_DBL(1.f / (float)(1 << COEFF_LOOP_SCALE)) +
+ FL2FXCONST_DBL(.5f / (float)(1 << COEFF_LOOP_SCALE))))),
+ gaussExp_e + 2 * COEFF_LOOP_SCALE, &e1);
+
+ win[i] = scaleValueSaturate(win[i], e1);
+ }
+}
+
+static INT FDKaacEnc_Search3(FIXP_LPC parcor) {
+ INT i, index = 0;
+
+ for (i = 0; i < 8; i++) {
+ if (parcor > FDKaacEnc_tnsCoeff3Borders[i]) index = i;
+ }
+ return (index - 4);
+}
+
+static INT FDKaacEnc_Search4(FIXP_LPC parcor) {
+ INT i, index = 0;
+
+ for (i = 0; i < 16; i++) {
+ if (parcor > FDKaacEnc_tnsCoeff4Borders[i]) index = i;
+ }
+ return (index - 8);
+}
+
+/*****************************************************************************
+
+ functionname: FDKaacEnc_Parcor2Index
+
+*****************************************************************************/
+static void FDKaacEnc_Parcor2Index(const FIXP_LPC *parcor, INT *RESTRICT index,
+ const INT order, const INT bitsPerCoeff) {
+ INT i;
+ for (i = 0; i < order; i++) {
+ if (bitsPerCoeff == 3)
+ index[i] = FDKaacEnc_Search3(parcor[i]);
+ else
+ index[i] = FDKaacEnc_Search4(parcor[i]);
+ }
+}
+
+/*****************************************************************************
+
+ functionname: FDKaacEnc_Index2Parcor
+ description: inverse quantization for reflection coefficients
+ returns: -
+ input: quantized values, ptr. to reflection coefficients,
+ no. of coefficients, resolution
+ output: reflection coefficients
+
+*****************************************************************************/
+static void FDKaacEnc_Index2Parcor(const INT *index, FIXP_LPC *RESTRICT parcor,
+ const INT order, const INT bitsPerCoeff) {
+ INT i;
+ for (i = 0; i < order; i++)
+ parcor[i] = bitsPerCoeff == 4 ? FDKaacEnc_tnsEncCoeff4[index[i] + 8]
+ : FDKaacEnc_tnsEncCoeff3[index[i] + 4];
+}