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Diffstat (limited to 'libSBRdec/src/env_calc.cpp')
-rw-r--r-- | libSBRdec/src/env_calc.cpp | 3131 |
1 files changed, 1984 insertions, 1147 deletions
diff --git a/libSBRdec/src/env_calc.cpp b/libSBRdec/src/env_calc.cpp index 73bd7ba..d7a8bb5 100644 --- a/libSBRdec/src/env_calc.cpp +++ b/libSBRdec/src/env_calc.cpp @@ -1,74 +1,85 @@ - -/* ----------------------------------------------------------------------------------------------------------- +/* ----------------------------------------------------------------------------- Software License for The Fraunhofer FDK AAC Codec Library for Android -© Copyright 1995 - 2015 Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V. - All rights reserved. +© 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. +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: +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 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 +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. +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. +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." +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. +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. +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. +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 @@ -79,11 +90,19 @@ Am Wolfsmantel 33 www.iis.fraunhofer.de/amm amm-info@iis.fraunhofer.de ------------------------------------------------------------------------------------------------------------ */ +----------------------------------------------------------------------------- */ + +/**************************** SBR decoder library ****************************** + + Author(s): + + Description: + +*******************************************************************************/ /*! \file - \brief Envelope calculation + \brief Envelope calculation The envelope adjustor compares the energies present in the transposed highband to the reference energies conveyed with the bitstream. @@ -111,16 +130,17 @@ amm-info@iis.fraunhofer.de However, in average only the data of 1 frame is being processed as the adjustor is called once per frame. - Depending on the frequency range set in the bitstream, only QMF-subbands between - <em>lowSubband</em> and <em>highSubband</em> are adjusted. + Depending on the frequency range set in the bitstream, only QMF-subbands + between <em>lowSubband</em> and <em>highSubband</em> are adjusted. - Scaling of spectral data to maximize SNR (see #QMF_SCALE_FACTOR) as well as a special Mantissa-Exponent format - ( see calculateSbrEnvelope() ) are being used. The main entry point for this modules is calculateSbrEnvelope(). + Scaling of spectral data to maximize SNR (see #QMF_SCALE_FACTOR) as well as a + special Mantissa-Exponent format ( see calculateSbrEnvelope() ) are being + used. The main entry point for this modules is calculateSbrEnvelope(). - \sa sbr_scale.h, #QMF_SCALE_FACTOR, calculateSbrEnvelope(), \ref documentationOverview + \sa sbr_scale.h, #QMF_SCALE_FACTOR, calculateSbrEnvelope(), \ref + documentationOverview */ - #include "env_calc.h" #include "sbrdec_freq_sca.h" @@ -129,203 +149,260 @@ amm-info@iis.fraunhofer.de #include "sbr_ram.h" #include "sbr_rom.h" -#include "genericStds.h" /* need FDKpow() for debug outputs */ - -#if defined(__arm__) -#include "arm/env_calc_arm.cpp" -#endif - -typedef struct -{ - FIXP_DBL nrgRef[MAX_FREQ_COEFFS]; - FIXP_DBL nrgEst[MAX_FREQ_COEFFS]; - FIXP_DBL nrgGain[MAX_FREQ_COEFFS]; - FIXP_DBL noiseLevel[MAX_FREQ_COEFFS]; - FIXP_DBL nrgSine[MAX_FREQ_COEFFS]; - - SCHAR nrgRef_e[MAX_FREQ_COEFFS]; - SCHAR nrgEst_e[MAX_FREQ_COEFFS]; - SCHAR nrgGain_e[MAX_FREQ_COEFFS]; - SCHAR noiseLevel_e[MAX_FREQ_COEFFS]; - SCHAR nrgSine_e[MAX_FREQ_COEFFS]; -} -ENV_CALC_NRGS; - -static void equalizeFiltBufferExp(FIXP_DBL *filtBuffer, - SCHAR *filtBuffer_e, - FIXP_DBL *NrgGain, - SCHAR *NrgGain_e, - int subbands); - -static void calcNrgPerSubband(FIXP_DBL **analysBufferReal, - FIXP_DBL **analysBufferImag, - int lowSubband, int highSubband, - int start_pos, int next_pos, - SCHAR frameExp, - FIXP_DBL *nrgEst, - SCHAR *nrgEst_e ); - -static void calcNrgPerSfb(FIXP_DBL **analysBufferReal, - FIXP_DBL **analysBufferImag, - int nSfb, - UCHAR *freqBandTable, - int start_pos, int next_pos, - SCHAR input_e, - FIXP_DBL *nrg_est, - SCHAR *nrg_est_e ); - -static void calcSubbandGain(FIXP_DBL nrgRef, SCHAR nrgRef_e, ENV_CALC_NRGS* nrgs, int c, - FIXP_DBL tmpNoise, SCHAR tmpNoise_e, - UCHAR sinePresentFlag, - UCHAR sineMapped, - int noNoiseFlag); - -static void calcAvgGain(ENV_CALC_NRGS* nrgs, - int lowSubband, - int highSubband, - FIXP_DBL *sumRef_m, - SCHAR *sumRef_e, - FIXP_DBL *ptrAvgGain_m, - SCHAR *ptrAvgGain_e); - -static void adjustTimeSlot_EldGrid(FIXP_DBL *ptrReal, - ENV_CALC_NRGS* nrgs, - UCHAR *ptrHarmIndex, - int lowSubbands, - int noSubbands, - int scale_change, - int noNoiseFlag, - int *ptrPhaseIndex, - int scale_diff_low); - -static void adjustTimeSlotLC(FIXP_DBL *ptrReal, - ENV_CALC_NRGS* nrgs, - UCHAR *ptrHarmIndex, - int lowSubbands, - int noSubbands, - int scale_change, - int noNoiseFlag, - int *ptrPhaseIndex); -static void adjustTimeSlotHQ(FIXP_DBL *ptrReal, - FIXP_DBL *ptrImag, - HANDLE_SBR_CALCULATE_ENVELOPE h_sbr_cal_env, - ENV_CALC_NRGS* nrgs, - int lowSubbands, - int noSubbands, - int scale_change, - FIXP_SGL smooth_ratio, - int noNoiseFlag, - int filtBufferNoiseShift); - +#include "genericStds.h" /* need FDKpow() for debug outputs */ + +typedef struct { + FIXP_DBL nrgRef[MAX_FREQ_COEFFS]; + FIXP_DBL nrgEst[MAX_FREQ_COEFFS]; + FIXP_DBL nrgGain[MAX_FREQ_COEFFS]; + FIXP_DBL noiseLevel[MAX_FREQ_COEFFS]; + FIXP_DBL nrgSine[MAX_FREQ_COEFFS]; + + SCHAR nrgRef_e[MAX_FREQ_COEFFS]; + SCHAR nrgEst_e[MAX_FREQ_COEFFS]; + SCHAR nrgGain_e[MAX_FREQ_COEFFS]; + SCHAR noiseLevel_e[MAX_FREQ_COEFFS]; + SCHAR nrgSine_e[MAX_FREQ_COEFFS]; + /* yet another exponent [0]: for ts < no_cols; [1]: for ts >= no_cols */ + SCHAR exponent[2]; +} ENV_CALC_NRGS; + +static void equalizeFiltBufferExp(FIXP_DBL *filtBuffer, SCHAR *filtBuffer_e, + FIXP_DBL *NrgGain, SCHAR *NrgGain_e, + int subbands); + +static void calcNrgPerSubband(FIXP_DBL **analysBufferReal, + FIXP_DBL **analysBufferImag, int lowSubband, + int highSubband, int start_pos, int next_pos, + SCHAR frameExp, FIXP_DBL *nrgEst, + SCHAR *nrgEst_e); + +static void calcNrgPerSfb(FIXP_DBL **analysBufferReal, + FIXP_DBL **analysBufferImag, int nSfb, + UCHAR *freqBandTable, int start_pos, int next_pos, + SCHAR input_e, FIXP_DBL *nrg_est, SCHAR *nrg_est_e); + +static void calcSubbandGain(FIXP_DBL nrgRef, SCHAR nrgRef_e, + ENV_CALC_NRGS *nrgs, int c, FIXP_DBL tmpNoise, + SCHAR tmpNoise_e, UCHAR sinePresentFlag, + UCHAR sineMapped, int noNoiseFlag); + +static void calcAvgGain(ENV_CALC_NRGS *nrgs, int lowSubband, int highSubband, + FIXP_DBL *sumRef_m, SCHAR *sumRef_e, + FIXP_DBL *ptrAvgGain_m, SCHAR *ptrAvgGain_e); + +static void adjustTimeSlot_EldGrid(FIXP_DBL *ptrReal, ENV_CALC_NRGS *nrgs, + UCHAR *ptrHarmIndex, int lowSubbands, + int noSubbands, int scale_change, + int noNoiseFlag, int *ptrPhaseIndex, + int scale_diff_low); + +static void adjustTimeSlotLC(FIXP_DBL *ptrReal, ENV_CALC_NRGS *nrgs, + UCHAR *ptrHarmIndex, int lowSubbands, + int noSubbands, int scale_change, int noNoiseFlag, + int *ptrPhaseIndex); + +/** + * \brief Variant of adjustTimeSlotHQ() which only regards gain and noise but no + * additional harmonics + */ +static void adjustTimeSlotHQ_GainAndNoise( + FIXP_DBL *ptrReal, FIXP_DBL *ptrImag, + HANDLE_SBR_CALCULATE_ENVELOPE h_sbr_cal_env, ENV_CALC_NRGS *nrgs, + int lowSubbands, int noSubbands, int scale_change, FIXP_SGL smooth_ratio, + int noNoiseFlag, int filtBufferNoiseShift); +/** + * \brief Variant of adjustTimeSlotHQ() which only adds the additional harmonics + */ +static void adjustTimeSlotHQ_AddHarmonics( + FIXP_DBL *ptrReal, FIXP_DBL *ptrImag, + HANDLE_SBR_CALCULATE_ENVELOPE h_sbr_cal_env, ENV_CALC_NRGS *nrgs, + int lowSubbands, int noSubbands, int scale_change); + +static void adjustTimeSlotHQ(FIXP_DBL *ptrReal, FIXP_DBL *ptrImag, + HANDLE_SBR_CALCULATE_ENVELOPE h_sbr_cal_env, + ENV_CALC_NRGS *nrgs, int lowSubbands, + int noSubbands, int scale_change, + FIXP_SGL smooth_ratio, int noNoiseFlag, + int filtBufferNoiseShift); /*! \brief Map sine flags from bitstream to QMF bands - The bitstream carries only 1 sine flag per band and frame. - This function maps every sine flag from the bitstream to a specific QMF subband - and to a specific envelope where the sine shall start. - The result is stored in the vector sineMapped which contains one entry per - QMF subband. The value of an entry specifies the envelope where a sine - shall start. A value of #MAX_ENVELOPES indicates that no sine is present - in the subband. - The missing harmonics flags from the previous frame (harmFlagsPrev) determine - if a sine starts at the beginning of the frame or at the transient position. - Additionally, the flags in harmFlagsPrev are being updated by this function - for the next frame. + The bitstream carries only 1 sine flag per band (Sfb) and frame. + This function maps every sine flag from the bitstream to a specific QMF + subband and to a specific envelope where the sine shall start. The result is + stored in the vector sineMapped which contains one entry per QMF subband. The + value of an entry specifies the envelope where a sine shall start. A value of + 32 indicates that no sine is present in the subband. The missing harmonics + flags from the previous frame (harmFlagsPrev) determine if a sine starts at + the beginning of the frame or at the transient position. Additionally, the + flags in harmFlagsPrev are being updated by this function for the next frame. */ -static void mapSineFlags(UCHAR *freqBandTable, /*!< Band borders (there's only 1 flag per band) */ - int nSfb, /*!< Number of bands in the table */ - UCHAR *addHarmonics, /*!< vector with 1 flag per sfb */ - int *harmFlagsPrev, /*!< Packed 'addHarmonics' */ - int tranEnv, /*!< Transient position */ - SCHAR *sineMapped) /*!< Resulting vector of sine start positions for each QMF band */ +static void mapSineFlags( + UCHAR *freqBandTable, /*!< Band borders (there's only 1 flag per band) */ + int nSfb, /*!< Number of bands in the table */ + ULONG *addHarmonics, /*!< Packed addHarmonics of current frame (aligned to + the MSB) */ + ULONG *harmFlagsPrev, /*!< Packed addHarmonics of previous frame (aligned to + the LSB) */ + ULONG *harmFlagsPrevActive, /*!< Packed sineMapped of previous frame + (aligned to the LSB) */ + int tranEnv, /*!< Transient position */ + SCHAR *sineMapped) /*!< Resulting vector of sine start positions for each + QMF band */ { int i; - int lowSubband2 = freqBandTable[0]<<1; - int bitcount = 0; - int oldflags = *harmFlagsPrev; - int newflags = 0; + int bitcount = 31; + ULONG harmFlagsQmfBands[ADD_HARMONICS_FLAGS_SIZE] = {0}; + ULONG *curFlags = addHarmonics; /* - Format of harmFlagsPrev: + Format of addHarmonics (aligned to MSB): - first word = flags for highest 16 sfb bands in use - second word = flags for next lower 16 sfb bands (if present) - third word = flags for lowest 16 sfb bands (if present) + Up to MAX_FREQ_COEFFS sfb bands can be flagged for a sign. + first word = flags for lowest 32 sfb bands in use + second word = flags for higest 32 sfb bands (if present) - Up to MAX_FREQ_COEFFS sfb bands can be flagged for a sign. - The lowest bit of the first word corresponds to the _highest_ sfb band in use. - This is ensures that each flag is mapped to the same QMF band even after a - change of the crossover-frequency. - */ + Format of harmFlagsPrev (aligned to LSB): + Index is absolute (not relative to lsb) so it is correct even if lsb + changes first word = flags for lowest 32 qmf bands (0...31) second word = + flags for next higher 32 qmf bands (32...63) - /* Reset the output vector first */ - FDKmemset(sineMapped, MAX_ENVELOPES,MAX_FREQ_COEFFS); /* MAX_ENVELOPES means 'no sine' */ - - freqBandTable += nSfb; - addHarmonics += nSfb-1; - - for (i=nSfb; i!=0; i--) { - int ui = *freqBandTable--; /* Upper limit of the current scale factor band. */ - int li = *freqBandTable; /* Lower limit of the current scale factor band. */ - - if ( *addHarmonics-- ) { /* There is a sine in this band */ + */ - unsigned int mask = 1 << bitcount; - newflags |= mask; /* Set flag */ + /* Reset the output vector first */ + FDKmemset(sineMapped, 32, + MAX_FREQ_COEFFS * sizeof(SCHAR)); /* 32 means 'no sine' */ + FDKmemclear(harmFlagsPrevActive, ADD_HARMONICS_FLAGS_SIZE * sizeof(ULONG)); + for (i = 0; i < nSfb; i++) { + ULONG maskSfb = + 1 << bitcount; /* mask to extract addHarmonics flag of current Sfb */ + + if (*curFlags & maskSfb) { /* There is a sine in this band */ + const int lsb = freqBandTable[0]; /* start of sbr range */ + /* qmf band to which sine should be added */ + const int qmfBand = (freqBandTable[i] + freqBandTable[i + 1]) >> 1; + const int qmfBandDiv32 = qmfBand >> 5; + const int maskQmfBand = + 1 << (qmfBand & + 31); /* mask to extract harmonic flag from prevFlags */ + + /* mapping of sfb with sine to a certain qmf band -> for harmFlagsPrev */ + harmFlagsQmfBands[qmfBandDiv32] |= maskQmfBand; /* - If there was a sine in the last frame, let it continue from the first envelope on - else start at the transient position. + If there was a sine in the last frame, let it continue from the first + envelope on else start at the transient position. Indexing of sineMapped + starts relative to lsb. */ - sineMapped[(ui+li-lowSubband2) >> 1] = ( oldflags & mask ) ? 0 : tranEnv; + sineMapped[qmfBand - lsb] = + (harmFlagsPrev[qmfBandDiv32] & maskQmfBand) ? 0 : tranEnv; + if (sineMapped[qmfBand - lsb] < PVC_NTIMESLOT) { + harmFlagsPrevActive[qmfBandDiv32] |= maskQmfBand; + } } - if ((++bitcount == 16) || i==1) { - bitcount = 0; - *harmFlagsPrev++ = newflags; - oldflags = *harmFlagsPrev; /* Fetch 16 of the old flags */ - newflags = 0; + if (bitcount-- == 0) { + bitcount = 31; + curFlags++; } } + FDKmemcpy(harmFlagsPrev, harmFlagsQmfBands, + sizeof(ULONG) * ADD_HARMONICS_FLAGS_SIZE); } +/*! + \brief Restore sineMapped of previous frame + + For PVC it might happen that the PVC framing (always 0) is out of sync with + the SBR framing. The adding of additional harmonics is done based on the SBR + framing. If the SBR framing is trailing the PVC framing the sine mapping of + the previous SBR frame needs to be used for the overlapping time slots. +*/ +/*static*/ void mapSineFlagsPvc( + UCHAR *freqBandTable, /*!< Band borders (there's only 1 flag per + band) */ + int nSfb, /*!< Number of bands in the table */ + ULONG *harmFlagsPrev, /*!< Packed addHarmonics of previous frame + (aligned to the MSB) */ + ULONG *harmFlagsPrevActive, /*!< Packed sineMapped of previous + frame (aligned to the LSB) */ + SCHAR *sineMapped, /*!< Resulting vector of sine start positions + for each QMF band */ + int sinusoidalPos, /*!< sinusoidal position */ + SCHAR *sinusoidalPosPrev, /*!< sinusoidal position of previous + frame */ + int trailingSbrFrame) /*!< indication if the SBR framing is + trailing the PVC framing */ +{ + /* Reset the output vector first */ + FDKmemset(sineMapped, 32, MAX_FREQ_COEFFS); /* 32 means 'no sine' */ + + if (trailingSbrFrame) { + /* restore sineMapped[] of previous frame */ + int i; + const int lsb = freqBandTable[0]; + const int usb = freqBandTable[nSfb]; + for (i = lsb; i < usb; i++) { + const int qmfBandDiv32 = i >> 5; + const int maskQmfBand = + 1 << (i & 31); /* mask to extract harmonic flag from prevFlags */ + + /* Two cases need to be distinguished ... */ + if (harmFlagsPrevActive[qmfBandDiv32] & maskQmfBand) { + /* the sine mapping already started last PVC frame -> seamlessly + * continue */ + sineMapped[i - lsb] = 0; + } else if (harmFlagsPrev[qmfBandDiv32] & maskQmfBand) { + /* sinusoidalPos of prev PVC frame was >= PVC_NTIMESLOT -> sine starts + * in this frame */ + sineMapped[i - lsb] = + *sinusoidalPosPrev - PVC_NTIMESLOT; /* we are 16 sbr time slots + ahead of last frame now */ + } + } + } + *sinusoidalPosPrev = sinusoidalPos; +} /*! \brief Reduce gain-adjustment induced aliasing for real valued filterbank. */ -/*static*/ void -aliasingReduction(FIXP_DBL* degreeAlias, /*!< estimated aliasing for each QMF channel */ - ENV_CALC_NRGS* nrgs, - int* useAliasReduction, /*!< synthetic sine engergy for each subband, used as flag */ - int noSubbands) /*!< number of QMF channels to process */ +/*static*/ void aliasingReduction( + FIXP_DBL *degreeAlias, /*!< estimated aliasing for each QMF + channel */ + ENV_CALC_NRGS *nrgs, + UCHAR *useAliasReduction, /*!< synthetic sine energy for each + subband, used as flag */ + int noSubbands) /*!< number of QMF channels to process */ { - FIXP_DBL* nrgGain = nrgs->nrgGain; /*!< subband gains to be modified */ - SCHAR* nrgGain_e = nrgs->nrgGain_e; /*!< subband gains to be modified (exponents) */ - FIXP_DBL* nrgEst = nrgs->nrgEst; /*!< subband energy before amplification */ - SCHAR* nrgEst_e = nrgs->nrgEst_e; /*!< subband energy before amplification (exponents) */ + FIXP_DBL *nrgGain = nrgs->nrgGain; /*!< subband gains to be modified */ + SCHAR *nrgGain_e = + nrgs->nrgGain_e; /*!< subband gains to be modified (exponents) */ + FIXP_DBL *nrgEst = nrgs->nrgEst; /*!< subband energy before amplification */ + SCHAR *nrgEst_e = + nrgs->nrgEst_e; /*!< subband energy before amplification (exponents) */ int grouping = 0, index = 0, noGroups, k; int groupVector[MAX_FREQ_COEFFS]; /* Calculate grouping*/ - for (k = 0; k < noSubbands-1; k++ ){ - if ( (degreeAlias[k + 1] != FL2FXCONST_DBL(0.0f)) && useAliasReduction[k] ) { - if(grouping==0){ + for (k = 0; k < noSubbands - 1; k++) { + if ((degreeAlias[k + 1] != FL2FXCONST_DBL(0.0f)) && useAliasReduction[k]) { + if (grouping == 0) { groupVector[index++] = k; grouping = 1; - } - else{ - if(groupVector[index-1] + 3 == k){ + } else { + if (groupVector[index - 1] + 3 == k) { groupVector[index++] = k + 1; grouping = 0; } } - } - else{ - if(grouping){ - if(useAliasReduction[k]) + } else { + if (grouping) { + if (useAliasReduction[k]) groupVector[index++] = k + 1; else groupVector[index++] = k; @@ -334,90 +411,384 @@ aliasingReduction(FIXP_DBL* degreeAlias, /*!< estimated aliasing for each } } - if(grouping){ + if (grouping) { groupVector[index++] = noSubbands; } noGroups = index >> 1; - /*Calculate new gain*/ - for (int group = 0; group < noGroups; group ++) { - FIXP_DBL nrgOrig = FL2FXCONST_DBL(0.0f); /* Original signal energy in current group of bands */ - SCHAR nrgOrig_e = 0; - FIXP_DBL nrgAmp = FL2FXCONST_DBL(0.0f); /* Amplified signal energy in group (using current gains) */ - SCHAR nrgAmp_e = 0; - FIXP_DBL nrgMod = FL2FXCONST_DBL(0.0f); /* Signal energy in group when applying modified gains */ - SCHAR nrgMod_e = 0; - FIXP_DBL groupGain; /* Total energy gain in group */ - SCHAR groupGain_e; - FIXP_DBL compensation; /* Compensation factor for the energy change when applying modified gains */ - SCHAR compensation_e; - - int startGroup = groupVector[2*group]; - int stopGroup = groupVector[2*group+1]; - - /* Calculate total energy in group before and after amplification with current gains: */ - for(k = startGroup; k < stopGroup; k++){ + for (int group = 0; group < noGroups; group++) { + FIXP_DBL nrgOrig = FL2FXCONST_DBL( + 0.0f); /* Original signal energy in current group of bands */ + SCHAR nrgOrig_e = 0; + FIXP_DBL nrgAmp = FL2FXCONST_DBL( + 0.0f); /* Amplified signal energy in group (using current gains) */ + SCHAR nrgAmp_e = 0; + FIXP_DBL nrgMod = FL2FXCONST_DBL( + 0.0f); /* Signal energy in group when applying modified gains */ + SCHAR nrgMod_e = 0; + FIXP_DBL groupGain; /* Total energy gain in group */ + SCHAR groupGain_e; + FIXP_DBL compensation; /* Compensation factor for the energy change when + applying modified gains */ + SCHAR compensation_e; + + int startGroup = groupVector[2 * group]; + int stopGroup = groupVector[2 * group + 1]; + + /* Calculate total energy in group before and after amplification with + * current gains: */ + for (k = startGroup; k < stopGroup; k++) { /* Get original band energy */ FIXP_DBL tmp = nrgEst[k]; - SCHAR tmp_e = nrgEst_e[k]; + SCHAR tmp_e = nrgEst_e[k]; FDK_add_MantExp(tmp, tmp_e, nrgOrig, nrgOrig_e, &nrgOrig, &nrgOrig_e); /* Multiply band energy with current gain */ - tmp = fMult(tmp,nrgGain[k]); + tmp = fMult(tmp, nrgGain[k]); tmp_e = tmp_e + nrgGain_e[k]; FDK_add_MantExp(tmp, tmp_e, nrgAmp, nrgAmp_e, &nrgAmp, &nrgAmp_e); } /* Calculate total energy gain in group */ - FDK_divide_MantExp(nrgAmp, nrgAmp_e, - nrgOrig, nrgOrig_e, - &groupGain, &groupGain_e); + FDK_divide_MantExp(nrgAmp, nrgAmp_e, nrgOrig, nrgOrig_e, &groupGain, + &groupGain_e); - for(k = startGroup; k < stopGroup; k++){ + for (k = startGroup; k < stopGroup; k++) { FIXP_DBL tmp; - SCHAR tmp_e; + SCHAR tmp_e; FIXP_DBL alpha = degreeAlias[k]; if (k < noSubbands - 1) { - if (degreeAlias[k + 1] > alpha) - alpha = degreeAlias[k + 1]; + if (degreeAlias[k + 1] > alpha) alpha = degreeAlias[k + 1]; } /* Modify gain depending on the degree of aliasing */ - FDK_add_MantExp( fMult(alpha,groupGain), groupGain_e, - fMult(/*FL2FXCONST_DBL(1.0f)*/ (FIXP_DBL)MAXVAL_DBL - alpha,nrgGain[k]), nrgGain_e[k], - &nrgGain[k], &nrgGain_e[k] ); + FDK_add_MantExp( + fMult(alpha, groupGain), groupGain_e, + fMult(/*FL2FXCONST_DBL(1.0f)*/ (FIXP_DBL)MAXVAL_DBL - alpha, + nrgGain[k]), + nrgGain_e[k], &nrgGain[k], &nrgGain_e[k]); /* Apply modified gain to original energy */ - tmp = fMult(nrgGain[k],nrgEst[k]); + tmp = fMult(nrgGain[k], nrgEst[k]); tmp_e = nrgGain_e[k] + nrgEst_e[k]; /* Accumulate energy with modified gains applied */ - FDK_add_MantExp( tmp, tmp_e, - nrgMod, nrgMod_e, - &nrgMod, &nrgMod_e ); + FDK_add_MantExp(tmp, tmp_e, nrgMod, nrgMod_e, &nrgMod, &nrgMod_e); } - /* Calculate compensation factor to retain the energy of the amplified signal */ - FDK_divide_MantExp(nrgAmp, nrgAmp_e, - nrgMod, nrgMod_e, - &compensation, &compensation_e); + /* Calculate compensation factor to retain the energy of the amplified + * signal */ + FDK_divide_MantExp(nrgAmp, nrgAmp_e, nrgMod, nrgMod_e, &compensation, + &compensation_e); /* Apply compensation factor to all gains of the group */ - for(k = startGroup; k < stopGroup; k++){ - nrgGain[k] = fMult(nrgGain[k],compensation); + for (k = startGroup; k < stopGroup; k++) { + nrgGain[k] = fMult(nrgGain[k], compensation); nrgGain_e[k] = nrgGain_e[k] + compensation_e; } } } +#define INTER_TES_SF_CHANGE 3 + +typedef struct { + FIXP_DBL subsample_power_low[(((1024) / (32) * (4) / 2) + (3 * (4)))]; + FIXP_DBL subsample_power_high[(((1024) / (32) * (4) / 2) + (3 * (4)))]; + FIXP_DBL gain[(((1024) / (32) * (4) / 2) + (3 * (4)))]; + SCHAR subsample_power_low_sf[(((1024) / (32) * (4) / 2) + (3 * (4)))]; + SCHAR subsample_power_high_sf[(((1024) / (32) * (4) / 2) + (3 * (4)))]; +} ITES_TEMP; + +static void apply_inter_tes(FIXP_DBL **qmfReal, FIXP_DBL **qmfImag, + const QMF_SCALE_FACTOR *sbrScaleFactor, + const SCHAR exp[2], const int RATE, + const int startPos, const int stopPos, + const int lowSubband, const int nbSubband, + const UCHAR gamma_idx) { + int highSubband = lowSubband + nbSubband; + FIXP_DBL *subsample_power_high, *subsample_power_low; + SCHAR *subsample_power_high_sf, *subsample_power_low_sf; + FIXP_DBL total_power_high = (FIXP_DBL)0; + FIXP_DBL total_power_low = (FIXP_DBL)0; + FIXP_DBL *gain; + int gain_sf[(((1024) / (32) * (4) / 2) + (3 * (4)))]; + + /* gamma[gamma_idx] = {0.0f, 1.0f, 2.0f, 4.0f} */ + int gamma_sf = + (int)gamma_idx - 1; /* perhaps +1 to save one bit? (0.99999f vs 1.f) */ + + int nbSubsample = stopPos - startPos; + int i, j; + + C_ALLOC_SCRATCH_START(pTmp, ITES_TEMP, 1); + subsample_power_high = pTmp->subsample_power_high; + subsample_power_low = pTmp->subsample_power_low; + subsample_power_high_sf = pTmp->subsample_power_high_sf; + subsample_power_low_sf = pTmp->subsample_power_low_sf; + gain = pTmp->gain; + + if (gamma_idx > 0) { + int preShift2 = 32 - fNormz((FIXP_DBL)nbSubsample); + int total_power_low_sf = 1 - DFRACT_BITS; + int total_power_high_sf = 1 - DFRACT_BITS; + + for (i = 0; i < nbSubsample; ++i) { + FIXP_DBL bufferReal[(((1024) / (32) * (4) / 2) + (3 * (4)))]; + FIXP_DBL bufferImag[(((1024) / (32) * (4) / 2) + (3 * (4)))]; + FIXP_DBL maxVal = (FIXP_DBL)0; + + int ts = startPos + i; + + int low_sf = (ts < 3 * RATE) ? sbrScaleFactor->ov_lb_scale + : sbrScaleFactor->lb_scale; + low_sf = 15 - low_sf; + + for (j = 0; j < lowSubband; ++j) { + bufferImag[j] = qmfImag[startPos + i][j]; + maxVal |= (FIXP_DBL)((LONG)(bufferImag[j]) ^ + ((LONG)bufferImag[j] >> (DFRACT_BITS - 1))); + bufferReal[j] = qmfReal[startPos + i][j]; + maxVal |= (FIXP_DBL)((LONG)(bufferReal[j]) ^ + ((LONG)bufferReal[j] >> (DFRACT_BITS - 1))); + } + + subsample_power_low[i] = (FIXP_DBL)0; + subsample_power_low_sf[i] = 0; + + if (maxVal != FL2FXCONST_DBL(0.f)) { + /* multiply first, then shift for safe summation */ + int preShift = 1 - CntLeadingZeros(maxVal); + int postShift = 32 - fNormz((FIXP_DBL)lowSubband); + + /* reduce preShift because otherwise we risk to square -1.f */ + if (preShift != 0) preShift++; + + subsample_power_low_sf[i] += (low_sf + preShift) * 2 + postShift + 1; + + scaleValues(bufferReal, lowSubband, -preShift); + scaleValues(bufferImag, lowSubband, -preShift); + for (j = 0; j < lowSubband; ++j) { + FIXP_DBL addme; + addme = fPow2Div2(bufferReal[j]); + subsample_power_low[i] += addme >> postShift; + addme = fPow2Div2(bufferImag[j]); + subsample_power_low[i] += addme >> postShift; + } + } + + /* now get high */ + + maxVal = (FIXP_DBL)0; + + int high_sf = exp[(ts < 16 * RATE) ? 0 : 1]; + + for (j = lowSubband; j < highSubband; ++j) { + bufferImag[j] = qmfImag[startPos + i][j]; + maxVal |= (FIXP_DBL)((LONG)(bufferImag[j]) ^ + ((LONG)bufferImag[j] >> (DFRACT_BITS - 1))); + bufferReal[j] = qmfReal[startPos + i][j]; + maxVal |= (FIXP_DBL)((LONG)(bufferReal[j]) ^ + ((LONG)bufferReal[j] >> (DFRACT_BITS - 1))); + } + + subsample_power_high[i] = (FIXP_DBL)0; + subsample_power_high_sf[i] = 0; + + if (maxVal != FL2FXCONST_DBL(0.f)) { + int preShift = 1 - CntLeadingZeros(maxVal); + /* reduce preShift because otherwise we risk to square -1.f */ + if (preShift != 0) preShift++; + + int postShift = 32 - fNormz((FIXP_DBL)(highSubband - lowSubband)); + subsample_power_high_sf[i] += (high_sf + preShift) * 2 + postShift + 1; - /* Convert headroom bits to exponent */ -#define SCALE2EXP(s) (15-(s)) -#define EXP2SCALE(e) (15-(e)) + scaleValues(&bufferReal[lowSubband], highSubband - lowSubband, + -preShift); + scaleValues(&bufferImag[lowSubband], highSubband - lowSubband, + -preShift); + for (j = lowSubband; j < highSubband; j++) { + subsample_power_high[i] += fPow2Div2(bufferReal[j]) >> postShift; + subsample_power_high[i] += fPow2Div2(bufferImag[j]) >> postShift; + } + } + + /* sum all together */ + FIXP_DBL new_summand = subsample_power_low[i]; + int new_summand_sf = subsample_power_low_sf[i]; + + /* make sure the current sum, and the new summand have the same SF */ + if (new_summand_sf > total_power_low_sf) { + int diff = fMin(DFRACT_BITS - 1, new_summand_sf - total_power_low_sf); + total_power_low >>= diff; + total_power_low_sf = new_summand_sf; + } else if (new_summand_sf < total_power_low_sf) { + new_summand >>= total_power_low_sf - new_summand_sf; + } + + total_power_low += (new_summand >> preShift2); + + new_summand = subsample_power_high[i]; + new_summand_sf = subsample_power_high_sf[i]; + if (new_summand_sf > total_power_high_sf) { + total_power_high >>= + fMin(DFRACT_BITS - 1, new_summand_sf - total_power_high_sf); + total_power_high_sf = new_summand_sf; + } else if (new_summand_sf < total_power_high_sf) { + new_summand >>= total_power_high_sf - new_summand_sf; + } + + total_power_high += (new_summand >> preShift2); + } + + total_power_low_sf += preShift2; + total_power_high_sf += preShift2; + + /* gain[i] = e_LOW[i] */ + for (i = 0; i < nbSubsample; ++i) { + int sf2; + FIXP_DBL mult = + fMultNorm(subsample_power_low[i], (FIXP_DBL)nbSubsample, &sf2); + int mult_sf = subsample_power_low_sf[i] + DFRACT_BITS - 1 + sf2; + + if (total_power_low != FIXP_DBL(0)) { + gain[i] = fDivNorm(mult, total_power_low, &sf2); + gain_sf[i] = mult_sf - total_power_low_sf + sf2; + gain[i] = sqrtFixp_lookup(gain[i], &gain_sf[i]); + if (gain_sf[i] < 0) { + gain[i] >>= -gain_sf[i]; + gain_sf[i] = 0; + } + } else { + if (mult == FIXP_DBL(0)) { + gain[i] = FIXP_DBL(0); + gain_sf[i] = 0; + } else { + gain[i] = (FIXP_DBL)MAXVAL_DBL; + gain_sf[i] = 0; + } + } + } + + FIXP_DBL total_power_high_after = (FIXP_DBL)0; + int total_power_high_after_sf = 1 - DFRACT_BITS; + + /* gain[i] = g_inter[i] */ + for (i = 0; i < nbSubsample; ++i) { + if (gain_sf[i] < 0) { + gain[i] >>= -gain_sf[i]; + gain_sf[i] = 0; + } + + /* calculate: gain[i] = 1.0f + gamma * (gain[i] - 1.0f); */ + FIXP_DBL one = (FIXP_DBL)MAXVAL_DBL >> + gain_sf[i]; /* to substract this from gain[i] */ + + /* gamma is actually always 1 according to the table, so skip the + * fMultDiv2 */ + FIXP_DBL mult = (gain[i] - one) >> 1; + int mult_sf = gain_sf[i] + gamma_sf; + + one = FL2FXCONST_DBL(0.5f) >> mult_sf; + gain[i] = one + mult; + gain_sf[i] += gamma_sf + 1; /* +1 because of fMultDiv2() */ + + /* set gain to at least 0.2f */ + FIXP_DBL point_two = FL2FXCONST_DBL(0.8f); /* scaled up by 2 */ + int point_two_sf = -2; + + FIXP_DBL tmp = gain[i]; + if (point_two_sf < gain_sf[i]) { + point_two >>= gain_sf[i] - point_two_sf; + } else { + tmp >>= point_two_sf - gain_sf[i]; + } + + /* limit and calculate gain[i]^2 too */ + FIXP_DBL gain_pow2; + int gain_pow2_sf; + if (tmp < point_two) { + gain[i] = FL2FXCONST_DBL(0.8f); + gain_sf[i] = -2; + gain_pow2 = FL2FXCONST_DBL(0.64f); + gain_pow2_sf = -4; + } else { + /* this upscaling seems quite important */ + int r = CountLeadingBits(gain[i]); + gain[i] <<= r; + gain_sf[i] -= r; + + gain_pow2 = fPow2(gain[i]); + gain_pow2_sf = gain_sf[i] << 1; + } + + int room; + subsample_power_high[i] = + fMultNorm(subsample_power_high[i], gain_pow2, &room); + subsample_power_high_sf[i] = + subsample_power_high_sf[i] + gain_pow2_sf + room; + + int new_summand_sf = subsample_power_high_sf[i]; /* + gain_pow2_sf; */ + if (new_summand_sf > total_power_high_after_sf) { + total_power_high_after >>= + fMin(DFRACT_BITS - 1, new_summand_sf - total_power_high_after_sf); + total_power_high_after_sf = new_summand_sf; + } else if (new_summand_sf < total_power_high_after_sf) { + subsample_power_high[i] >>= total_power_high_after_sf - new_summand_sf; + } + total_power_high_after += subsample_power_high[i] >> preShift2; + } + + total_power_high_after_sf += preShift2; + + int sf2 = 0; + FIXP_DBL gain_adj_2 = FL2FX_DBL(0.5f); + int gain_adj_2_sf = 1; + + if ((total_power_high != (FIXP_DBL)0) && + (total_power_high_after != (FIXP_DBL)0)) { + gain_adj_2 = fDivNorm(total_power_high, total_power_high_after, &sf2); + gain_adj_2_sf = total_power_high_sf - total_power_high_after_sf + sf2; + } + + FIXP_DBL gain_adj = sqrtFixp_lookup(gain_adj_2, &gain_adj_2_sf); + int gain_adj_sf = gain_adj_2_sf; + + for (i = 0; i < nbSubsample; ++i) { + gain[i] = fMult(gain[i], gain_adj); + gain_sf[i] += gain_adj_sf; + + /* limit gain */ + if (gain_sf[i] > INTER_TES_SF_CHANGE) { + gain[i] = (FIXP_DBL)MAXVAL_DBL; + gain_sf[i] = INTER_TES_SF_CHANGE; + } + } + + for (i = 0; i < nbSubsample; ++i) { + /* equalize gain[]'s scale factors */ + gain[i] >>= INTER_TES_SF_CHANGE - gain_sf[i]; + + for (j = lowSubband; j < highSubband; j++) { + qmfReal[startPos + i][j] = fMult(qmfReal[startPos + i][j], gain[i]); + qmfImag[startPos + i][j] = fMult(qmfImag[startPos + i][j], gain[i]); + } + } + } else { /* gamma_idx == 0 */ + /* Inter-TES is not active. Still perform the scale change to have a + * consistent scaling for all envelopes of this frame. */ + for (i = 0; i < nbSubsample; ++i) { + for (j = lowSubband; j < highSubband; j++) { + qmfReal[startPos + i][j] >>= INTER_TES_SF_CHANGE; + qmfImag[startPos + i][j] >>= INTER_TES_SF_CHANGE; + } + } + } + C_ALLOC_SCRATCH_END(pTmp, ITES_TEMP, 1); +} /*! \brief Apply spectral envelope to subband samples @@ -430,7 +801,8 @@ aliasingReduction(FIXP_DBL* degreeAlias, /*!< estimated aliasing for each the suffixes <em>_m</em> and <em>_e</em> respectively. The control data in #hFrameData containts envelope data which is represented by this format but stored in single words. (See requantizeEnvelopeData() for details). This data - is unpacked within calculateSbrEnvelope() to follow the described suffix convention. + is unpacked within calculateSbrEnvelope() to follow the described suffix + convention. The actual value (comparable to the corresponding float-variable in the research-implementation) of a mantissa/exponent-pair can be calculated as @@ -438,49 +810,45 @@ aliasingReduction(FIXP_DBL* degreeAlias, /*!< estimated aliasing for each \f$ value = value\_m * 2^{value\_e} \f$ All energies and noise levels decoded from the bitstream suit for an - original signal magnitude of \f$\pm 32768 \f$ rather than \f$ \pm 1\f$. Therefore, - the scale factor <em>hb_scale</em> passed into this function will be converted - to an 'input exponent' (#input_e), which fits the internal representation. + original signal magnitude of \f$\pm 32768 \f$ rather than \f$ \pm 1\f$. + Therefore, the scale factor <em>hb_scale</em> passed into this function will + be converted to an 'input exponent' (#input_e), which fits the internal + representation. Before the actual processing, an exponent #adj_e for resulting adjusted samples is derived from the maximum reference energy. Then, for each envelope, the following steps are performed: - \li Calculate energy in the signal to be adjusted. Depending on the the value of - #interpolFreq (interpolation mode), this is either done seperately - for each QMF-subband or for each SBR-band. - The resulting energies are stored in #nrgEst_m[#MAX_FREQ_COEFFS] (mantissas) - and #nrgEst_e[#MAX_FREQ_COEFFS] (exponents). - \li Calculate gain and noise level for each subband:<br> - \f$ gain = \sqrt{ \frac{nrgRef}{nrgEst} \cdot (1 - noiseRatio) } - \hspace{2cm} - noise = \sqrt{ nrgRef \cdot noiseRatio } - \f$<br> - where <em>noiseRatio</em> and <em>nrgRef</em> are extracted from the - bitstream and <em>nrgEst</em> is the subband energy before adjustment. - The resulting gains are stored in #nrgGain_m[#MAX_FREQ_COEFFS] - (mantissas) and #nrgGain_e[#MAX_FREQ_COEFFS] (exponents), the noise levels - are stored in #noiseLevel_m[#MAX_FREQ_COEFFS] and #noiseLevel_e[#MAX_FREQ_COEFFS] - (exponents). - The sine levels are stored in #nrgSine_m[#MAX_FREQ_COEFFS] - and #nrgSine_e[#MAX_FREQ_COEFFS]. - \li Noise limiting: The gain for each subband is limited both absolutely - and relatively compared to the total gain over all subbands. - \li Boost gain: Calculate and apply boost factor for each limiter band - in order to compensate for the energy loss imposed by the limiting. - \li Apply gains and add noise: The gains and noise levels are applied - to all timeslots of the current envelope. A short FIR-filter (length 4 - QMF-timeslots) can be used to smooth the sudden change at the envelope borders. - Each complex subband sample of the current timeslot is multiplied by the - smoothed gain, then random noise with the calculated level is added. + \li Calculate energy in the signal to be adjusted. Depending on the the value + of #interpolFreq (interpolation mode), this is either done seperately for each + QMF-subband or for each SBR-band. The resulting energies are stored in + #nrgEst_m[#MAX_FREQ_COEFFS] (mantissas) and #nrgEst_e[#MAX_FREQ_COEFFS] + (exponents). \li Calculate gain and noise level for each subband:<br> \f$ gain + = \sqrt{ \frac{nrgRef}{nrgEst} \cdot (1 - noiseRatio) } \hspace{2cm} noise = + \sqrt{ nrgRef \cdot noiseRatio } \f$<br> where <em>noiseRatio</em> and + <em>nrgRef</em> are extracted from the bitstream and <em>nrgEst</em> is the + subband energy before adjustment. The resulting gains are stored in + #nrgGain_m[#MAX_FREQ_COEFFS] (mantissas) and #nrgGain_e[#MAX_FREQ_COEFFS] + (exponents), the noise levels are stored in #noiseLevel_m[#MAX_FREQ_COEFFS] + and #noiseLevel_e[#MAX_FREQ_COEFFS] (exponents). The sine levels are stored in + #nrgSine_m[#MAX_FREQ_COEFFS] and #nrgSine_e[#MAX_FREQ_COEFFS]. \li Noise + limiting: The gain for each subband is limited both absolutely and relatively + compared to the total gain over all subbands. \li Boost gain: Calculate and + apply boost factor for each limiter band in order to compensate for the energy + loss imposed by the limiting. \li Apply gains and add noise: The gains and + noise levels are applied to all timeslots of the current envelope. A short + FIR-filter (length 4 QMF-timeslots) can be used to smooth the sudden change at + the envelope borders. Each complex subband sample of the current timeslot is + multiplied by the smoothed gain, then random noise with the calculated level + is added. \note To reduce the stack size, some of the local arrays could be located within the time output buffer. Of the 512 samples temporarily available there, about half the size is already used by #SBR_FRAME_DATA. A pointer to the - remaining free memory could be supplied by an additional argument to calculateSbrEnvelope() - in sbr_dec: + remaining free memory could be supplied by an additional argument to + calculateSbrEnvelope() in sbr_dec: \par \code @@ -490,12 +858,12 @@ aliasingReduction(FIXP_DBL* degreeAlias, /*!< estimated aliasing for each hFrameData, QmfBufferReal, QmfBufferImag, - timeOutPtr + sizeof(SBR_FRAME_DATA)/sizeof(Float) + 1); - \endcode + timeOutPtr + sizeof(SBR_FRAME_DATA)/sizeof(Float) + + 1); \endcode \par - Within calculateSbrEnvelope(), some pointers could be defined instead of the arrays - #nrgRef_m, #nrgRef_e, #nrgEst_m, #nrgEst_e, #noiseLevel_m: + Within calculateSbrEnvelope(), some pointers could be defined instead of the + arrays #nrgRef_m, #nrgRef_e, #nrgEst_m, #nrgEst_e, #noiseLevel_m: \par \code @@ -508,56 +876,103 @@ aliasingReduction(FIXP_DBL* degreeAlias, /*!< estimated aliasing for each <br> */ -void -calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling factors */ - HANDLE_SBR_CALCULATE_ENVELOPE h_sbr_cal_env, /*!< Handle to struct filled by the create-function */ - HANDLE_SBR_HEADER_DATA hHeaderData, /*!< Static control data */ - HANDLE_SBR_FRAME_DATA hFrameData, /*!< Control data of current frame */ - FIXP_DBL **analysBufferReal, /*!< Real part of subband samples to be processed */ - FIXP_DBL **analysBufferImag, /*!< Imag part of subband samples to be processed */ - const int useLP, - FIXP_DBL *degreeAlias, /*!< Estimated aliasing for each QMF channel */ - const UINT flags, - const int frameErrorFlag - ) -{ - int c, i, j, envNoise = 0; - UCHAR* borders = hFrameData->frameInfo.borders; - - FIXP_SGL *noiseLevels = hFrameData->sbrNoiseFloorLevel; +void calculateSbrEnvelope( + QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling factors */ + HANDLE_SBR_CALCULATE_ENVELOPE + h_sbr_cal_env, /*!< Handle to struct filled by the create-function */ + HANDLE_SBR_HEADER_DATA hHeaderData, /*!< Static control data */ + HANDLE_SBR_FRAME_DATA hFrameData, /*!< Control data of current frame */ + PVC_DYNAMIC_DATA *pPvcDynamicData, + FIXP_DBL * + *analysBufferReal, /*!< Real part of subband samples to be processed */ + FIXP_DBL * + *analysBufferImag, /*!< Imag part of subband samples to be processed */ + const int useLP, + FIXP_DBL *degreeAlias, /*!< Estimated aliasing for each QMF channel */ + const UINT flags, const int frameErrorFlag) { + int c, i, i_stop, j, envNoise = 0; + UCHAR *borders = hFrameData->frameInfo.borders; + UCHAR *bordersPvc = hFrameData->frameInfo.pvcBorders; + int pvc_mode = pPvcDynamicData->pvc_mode; + int first_start = + ((pvc_mode > 0) ? bordersPvc[0] : borders[0]) * hHeaderData->timeStep; + FIXP_SGL *noiseLevels = hFrameData->sbrNoiseFloorLevel; HANDLE_FREQ_BAND_DATA hFreq = &hHeaderData->freqBandData; + UCHAR **pFreqBandTable = hFreq->freqBandTable; + UCHAR *pFreqBandTableNoise = hFreq->freqBandTableNoise; - int lowSubband = hFreq->lowSubband; + int lowSubband = hFreq->lowSubband; int highSubband = hFreq->highSubband; - int noSubbands = highSubband - lowSubband; + int noSubbands = highSubband - lowSubband; + + /* old high subband before headerchange + we asume no headerchange here */ + int ov_highSubband = hFreq->highSubband; + + int noNoiseBands = hFreq->nNfb; + UCHAR *noSubFrameBands = hFreq->nSfb; + int no_cols = hHeaderData->numberTimeSlots * hHeaderData->timeStep; + + SCHAR sineMapped[MAX_FREQ_COEFFS]; + SCHAR ov_adj_e = SCALE2EXP(sbrScaleFactor->ov_hb_scale); + SCHAR adj_e = 0; + SCHAR output_e; + SCHAR final_e = 0; + /* inter-TES is active in one or more envelopes of the current SBR frame */ + const int iTES_enable = hFrameData->iTESactive; + const int iTES_scale_change = (iTES_enable) ? INTER_TES_SF_CHANGE : 0; + SCHAR maxGainLimit_e = (frameErrorFlag) ? MAX_GAIN_CONCEAL_EXP : MAX_GAIN_EXP; - int noNoiseBands = hFreq->nNfb; - int no_cols = hHeaderData->numberTimeSlots * hHeaderData->timeStep; - UCHAR first_start = borders[0] * hHeaderData->timeStep; + UCHAR smooth_length = 0; - SCHAR sineMapped[MAX_FREQ_COEFFS]; - SCHAR ov_adj_e = SCALE2EXP(sbrScaleFactor->ov_hb_scale); - SCHAR adj_e = 0; - SCHAR output_e; - SCHAR final_e = 0; + FIXP_SGL *pIenv = hFrameData->iEnvelope; - SCHAR maxGainLimit_e = (frameErrorFlag) ? MAX_GAIN_CONCEAL_EXP : MAX_GAIN_EXP; + C_ALLOC_SCRATCH_START(useAliasReduction, UCHAR, 64) - int useAliasReduction[64]; - UCHAR smooth_length = 0; + /* if values differ we had a headerchange; if old highband is bigger then new + one we need to patch overlap-highband-scaling for this frame (see use of + ov_highSubband) as overlap contains higher frequency components which would + get lost */ + if (hFreq->highSubband < hFreq->ov_highSubband) { + ov_highSubband = hFreq->ov_highSubband; + } - FIXP_SGL * pIenv = hFrameData->iEnvelope; + if (pvc_mode > 0) { + if (hFrameData->frameInfo.bordersNoise[0] > bordersPvc[0]) { + /* noise envelope of previous frame is trailing into current PVC frame */ + envNoise = -1; + noiseLevels = h_sbr_cal_env->prevSbrNoiseFloorLevel; + noNoiseBands = h_sbr_cal_env->prevNNfb; + noSubFrameBands = h_sbr_cal_env->prevNSfb; + lowSubband = h_sbr_cal_env->prevLoSubband; + highSubband = h_sbr_cal_env->prevHiSubband; + + noSubbands = highSubband - lowSubband; + ov_highSubband = highSubband; + if (highSubband < h_sbr_cal_env->prev_ov_highSubband) { + ov_highSubband = h_sbr_cal_env->prev_ov_highSubband; + } - /* - Extract sine flags for all QMF bands - */ - mapSineFlags(hFreq->freqBandTable[1], - hFreq->nSfb[1], - hFrameData->addHarmonics, - h_sbr_cal_env->harmFlagsPrev, - hFrameData->frameInfo.tranEnv, - sineMapped); + pFreqBandTable[0] = h_sbr_cal_env->prevFreqBandTableLo; + pFreqBandTable[1] = h_sbr_cal_env->prevFreqBandTableHi; + pFreqBandTableNoise = h_sbr_cal_env->prevFreqBandTableNoise; + } + mapSineFlagsPvc(pFreqBandTable[1], noSubFrameBands[1], + h_sbr_cal_env->harmFlagsPrev, + h_sbr_cal_env->harmFlagsPrevActive, sineMapped, + hFrameData->sinusoidal_position, + &h_sbr_cal_env->sinusoidal_positionPrev, + (borders[0] > bordersPvc[0]) ? 1 : 0); + } else { + /* + Extract sine flags for all QMF bands + */ + mapSineFlags(pFreqBandTable[1], noSubFrameBands[1], + hFrameData->addHarmonics, h_sbr_cal_env->harmFlagsPrev, + h_sbr_cal_env->harmFlagsPrevActive, + hFrameData->frameInfo.tranEnv, sineMapped); + } /* Scan for maximum in bufferd noise levels. @@ -567,163 +982,289 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling in reference energies */ if (!useLP) - adj_e = h_sbr_cal_env->filtBufferNoise_e - getScalefactor(h_sbr_cal_env->filtBufferNoise, noSubbands); + adj_e = h_sbr_cal_env->filtBufferNoise_e - + getScalefactor(h_sbr_cal_env->filtBufferNoise, noSubbands); /* Scan for maximum reference energy to be able to select appropriate values for adj_e and final_e. */ - - for (i = 0; i < hFrameData->frameInfo.nEnvelopes; i++) { - INT maxSfbNrg_e = -FRACT_BITS+NRG_EXP_OFFSET; /* start value for maximum search */ - - /* Fetch frequency resolution for current envelope: */ - for (j=hFreq->nSfb[hFrameData->frameInfo.freqRes[i]]; j!=0; j--) { - maxSfbNrg_e = fixMax(maxSfbNrg_e,(INT)((LONG)(*pIenv++) & MASK_E)); - } - maxSfbNrg_e -= NRG_EXP_OFFSET; + if (pvc_mode > 0) { + INT maxSfbNrg_e = pPvcDynamicData->predEsg_expMax; /* Energy -> magnitude (sqrt halfens exponent) */ - maxSfbNrg_e = (maxSfbNrg_e+1) >> 1; /* +1 to go safe (round to next higher int) */ + maxSfbNrg_e = + (maxSfbNrg_e + 1) >> 1; /* +1 to go safe (round to next higher int) */ /* Some safety margin is needed for 2 reasons: - The signal energy is not equally spread over all subband samples in a specific sfb of an envelope (Nrg could be too high by a factor of envWidth * sfbWidth) - - Smoothing can smear high gains of the previous envelope into the current + - Smoothing can smear high gains of the previous envelope into the + current */ maxSfbNrg_e += 6; - if (borders[i] < hHeaderData->numberTimeSlots) - /* This envelope affects timeslots that belong to the output frame */ - adj_e = (maxSfbNrg_e > adj_e) ? maxSfbNrg_e : adj_e; + adj_e = maxSfbNrg_e; + // final_e should not exist for PVC fixfix framing + } else { + for (i = 0; i < hFrameData->frameInfo.nEnvelopes; i++) { + INT maxSfbNrg_e = + -FRACT_BITS + NRG_EXP_OFFSET; /* start value for maximum search */ + + /* Fetch frequency resolution for current envelope: */ + for (j = noSubFrameBands[hFrameData->frameInfo.freqRes[i]]; j != 0; j--) { + maxSfbNrg_e = fixMax(maxSfbNrg_e, (INT)((LONG)(*pIenv++) & MASK_E)); + } + maxSfbNrg_e -= NRG_EXP_OFFSET; + + /* Energy -> magnitude (sqrt halfens exponent) */ + maxSfbNrg_e = + (maxSfbNrg_e + 1) >> 1; /* +1 to go safe (round to next higher int) */ + + /* Some safety margin is needed for 2 reasons: + - The signal energy is not equally spread over all subband samples in + a specific sfb of an envelope (Nrg could be too high by a factor of + envWidth * sfbWidth) + - Smoothing can smear high gains of the previous envelope into the + current + */ + maxSfbNrg_e += 6; - if (borders[i+1] > hHeaderData->numberTimeSlots) - /* This envelope affects timeslots after the output frame */ - final_e = (maxSfbNrg_e > final_e) ? maxSfbNrg_e : final_e; + if (borders[i] < hHeaderData->numberTimeSlots) + /* This envelope affects timeslots that belong to the output frame */ + adj_e = fMax(maxSfbNrg_e, adj_e); + if (borders[i + 1] > hHeaderData->numberTimeSlots) + /* This envelope affects timeslots after the output frame */ + final_e = fMax(maxSfbNrg_e, final_e); + } } - /* Calculate adjustment factors and apply them for every envelope. */ pIenv = hFrameData->iEnvelope; - for (i = 0; i < hFrameData->frameInfo.nEnvelopes; i++) { - + if (pvc_mode > 0) { + /* iterate over SBR time slots starting with bordersPvc[i] */ + i = bordersPvc[0]; /* usually 0; can be >0 if switching from legacy SBR to + PVC */ + i_stop = PVC_NTIMESLOT; + FDK_ASSERT(bordersPvc[hFrameData->frameInfo.nEnvelopes] == PVC_NTIMESLOT); + } else { + /* iterate over SBR envelopes starting with 0 */ + i = 0; + i_stop = hFrameData->frameInfo.nEnvelopes; + } + for (; i < i_stop; i++) { int k, noNoiseFlag; - SCHAR noise_e, input_e = SCALE2EXP(sbrScaleFactor->hb_scale); + SCHAR noise_e, input_e = SCALE2EXP(sbrScaleFactor->hb_scale); C_ALLOC_SCRATCH_START(pNrgs, ENV_CALC_NRGS, 1); /* Helper variables. */ - UCHAR start_pos = hHeaderData->timeStep * borders[i]; /* Start-position in time (subband sample) for current envelope. */ - UCHAR stop_pos = hHeaderData->timeStep * borders[i+1]; /* Stop-position in time (subband sample) for current envelope. */ - UCHAR freq_res = hFrameData->frameInfo.freqRes[i]; /* Frequency resolution for current envelope. */ - + int start_pos, stop_pos, freq_res; + if (pvc_mode > 0) { + start_pos = + hHeaderData->timeStep * + i; /* Start-position in time (subband sample) for current envelope. */ + stop_pos = hHeaderData->timeStep * (i + 1); /* Stop-position in time + (subband sample) for + current envelope. */ + freq_res = + hFrameData->frameInfo + .freqRes[0]; /* Frequency resolution for current envelope. */ + FDK_ASSERT( + freq_res == + hFrameData->frameInfo.freqRes[hFrameData->frameInfo.nEnvelopes - 1]); + } else { + start_pos = hHeaderData->timeStep * + borders[i]; /* Start-position in time (subband sample) for + current envelope. */ + stop_pos = hHeaderData->timeStep * + borders[i + 1]; /* Stop-position in time (subband sample) for + current envelope. */ + freq_res = + hFrameData->frameInfo + .freqRes[i]; /* Frequency resolution for current envelope. */ + } - /* Always do fully initialize the temporary energy table. This prevents negative energies and extreme gain factors in - cases where the number of limiter bands exceeds the number of subbands. The latter can be caused by undetected bit - errors and is tested by some streams from the certification set. */ + /* Always fully initialize the temporary energy table. This prevents + negative energies and extreme gain factors in cases where the number of + limiter bands exceeds the number of subbands. The latter can be caused by + undetected bit errors and is tested by some streams from the + certification set. */ FDKmemclear(pNrgs, sizeof(ENV_CALC_NRGS)); - /* If the start-pos of the current envelope equals the stop pos of the current - noise envelope, increase the pointer (i.e. choose the next noise-floor).*/ - if (borders[i] == hFrameData->frameInfo.bordersNoise[envNoise+1]){ - noiseLevels += noNoiseBands; /* The noise floor data is stored in a row [noiseFloor1 noiseFloor2...].*/ - envNoise++; - } + if (pvc_mode > 0) { + /* get predicted energy values from PVC module */ + expandPredEsg(pPvcDynamicData, i, (int)MAX_FREQ_COEFFS, pNrgs->nrgRef, + pNrgs->nrgRef_e); - if(i==hFrameData->frameInfo.tranEnv || i==h_sbr_cal_env->prevTranEnv) /* attack */ + if (i == borders[0]) { + mapSineFlags(pFreqBandTable[1], noSubFrameBands[1], + hFrameData->addHarmonics, h_sbr_cal_env->harmFlagsPrev, + h_sbr_cal_env->harmFlagsPrevActive, + hFrameData->sinusoidal_position, sineMapped); + } + + if (i >= hFrameData->frameInfo.bordersNoise[envNoise + 1]) { + if (envNoise >= 0) { + noiseLevels += noNoiseBands; /* The noise floor data is stored in a + row [noiseFloor1 noiseFloor2...].*/ + } else { + /* leave trailing noise envelope of past frame */ + noNoiseBands = hFreq->nNfb; + noSubFrameBands = hFreq->nSfb; + noiseLevels = hFrameData->sbrNoiseFloorLevel; + + lowSubband = hFreq->lowSubband; + highSubband = hFreq->highSubband; + + noSubbands = highSubband - lowSubband; + ov_highSubband = highSubband; + if (highSubband < hFreq->ov_highSubband) { + ov_highSubband = hFreq->ov_highSubband; + } + + pFreqBandTable[0] = hFreq->freqBandTableLo; + pFreqBandTable[1] = hFreq->freqBandTableHi; + pFreqBandTableNoise = hFreq->freqBandTableNoise; + } + envNoise++; + } + } else { + /* If the start-pos of the current envelope equals the stop pos of the + current noise envelope, increase the pointer (i.e. choose the next + noise-floor).*/ + if (borders[i] == hFrameData->frameInfo.bordersNoise[envNoise + 1]) { + noiseLevels += noNoiseBands; /* The noise floor data is stored in a row + [noiseFloor1 noiseFloor2...].*/ + envNoise++; + } + } + if (i == hFrameData->frameInfo.tranEnv || + i == h_sbr_cal_env->prevTranEnv) /* attack */ { noNoiseFlag = 1; - if (!useLP) - smooth_length = 0; /* No smoothing on attacks! */ - } - else { + if (!useLP) smooth_length = 0; /* No smoothing on attacks! */ + } else { noNoiseFlag = 0; if (!useLP) - smooth_length = (1 - hHeaderData->bs_data.smoothingLength) << 2; /* can become either 0 or 4 */ + smooth_length = (1 - hHeaderData->bs_data.smoothingLength) + << 2; /* can become either 0 or 4 */ } - /* Energy estimation in transposed highband. */ if (hHeaderData->bs_data.interpolFreq) - calcNrgPerSubband(analysBufferReal, - (useLP) ? NULL : analysBufferImag, - lowSubband, highSubband, - start_pos, stop_pos, - input_e, - pNrgs->nrgEst, - pNrgs->nrgEst_e); + calcNrgPerSubband(analysBufferReal, (useLP) ? NULL : analysBufferImag, + lowSubband, highSubband, start_pos, stop_pos, input_e, + pNrgs->nrgEst, pNrgs->nrgEst_e); else - calcNrgPerSfb(analysBufferReal, - (useLP) ? NULL : analysBufferImag, - hFreq->nSfb[freq_res], - hFreq->freqBandTable[freq_res], - start_pos, stop_pos, - input_e, - pNrgs->nrgEst, + calcNrgPerSfb(analysBufferReal, (useLP) ? NULL : analysBufferImag, + noSubFrameBands[freq_res], pFreqBandTable[freq_res], + start_pos, stop_pos, input_e, pNrgs->nrgEst, pNrgs->nrgEst_e); /* Calculate subband gains */ { - UCHAR * table = hFreq->freqBandTable[freq_res]; - UCHAR * pUiNoise = &hFreq->freqBandTableNoise[1]; /*! Upper limit of the current noise floor band. */ + UCHAR *table = pFreqBandTable[freq_res]; + UCHAR *pUiNoise = + &pFreqBandTableNoise[1]; /*! Upper limit of the current noise floor + band. */ - FIXP_SGL * pNoiseLevels = noiseLevels; + FIXP_SGL *pNoiseLevels = noiseLevels; - FIXP_DBL tmpNoise = FX_SGL2FX_DBL((FIXP_SGL)((LONG)(*pNoiseLevels) & MASK_M)); - SCHAR tmpNoise_e = (UCHAR)((LONG)(*pNoiseLevels++) & MASK_E) - NOISE_EXP_OFFSET; + FIXP_DBL tmpNoise = + FX_SGL2FX_DBL((FIXP_SGL)((LONG)(*pNoiseLevels) & MASK_M)); + SCHAR tmpNoise_e = + (UCHAR)((LONG)(*pNoiseLevels++) & MASK_E) - NOISE_EXP_OFFSET; int cc = 0; c = 0; - for (j = 0; j < hFreq->nSfb[freq_res]; j++) { + if (pvc_mode > 0) { + for (j = 0; j < noSubFrameBands[freq_res]; j++) { + UCHAR sinePresentFlag = 0; + int li = table[j]; + int ui = table[j + 1]; + + for (k = li; k < ui; k++) { + sinePresentFlag |= (i >= sineMapped[cc]); + cc++; + } - FIXP_DBL refNrg = FX_SGL2FX_DBL((FIXP_SGL)((LONG)(*pIenv) & MASK_M)); - SCHAR refNrg_e = (SCHAR)((LONG)(*pIenv) & MASK_E) - NRG_EXP_OFFSET; + for (k = li; k < ui; k++) { + FIXP_DBL refNrg = pNrgs->nrgRef[k - lowSubband]; + SCHAR refNrg_e = pNrgs->nrgRef_e[k - lowSubband]; + + if (k >= *pUiNoise) { + tmpNoise = + FX_SGL2FX_DBL((FIXP_SGL)((LONG)(*pNoiseLevels) & MASK_M)); + tmpNoise_e = + (SCHAR)((LONG)(*pNoiseLevels++) & MASK_E) - NOISE_EXP_OFFSET; + + pUiNoise++; + } - UCHAR sinePresentFlag = 0; - int li = table[j]; - int ui = table[j+1]; + FDK_ASSERT(k >= lowSubband); - for (k=li; k<ui; k++) { - sinePresentFlag |= (i >= sineMapped[cc]); - cc++; + if (useLP) useAliasReduction[k - lowSubband] = !sinePresentFlag; + + pNrgs->nrgSine[c] = FL2FXCONST_DBL(0.0f); + pNrgs->nrgSine_e[c] = 0; + + calcSubbandGain(refNrg, refNrg_e, pNrgs, c, tmpNoise, tmpNoise_e, + sinePresentFlag, i >= sineMapped[c], noNoiseFlag); + + c++; + } } + } else { + for (j = 0; j < noSubFrameBands[freq_res]; j++) { + FIXP_DBL refNrg = FX_SGL2FX_DBL((FIXP_SGL)((LONG)(*pIenv) & MASK_M)); + SCHAR refNrg_e = (SCHAR)((LONG)(*pIenv) & MASK_E) - NRG_EXP_OFFSET; - for (k=li; k<ui; k++) { - if (k >= *pUiNoise) { - tmpNoise = FX_SGL2FX_DBL((FIXP_SGL)((LONG)(*pNoiseLevels) & MASK_M)); - tmpNoise_e = (SCHAR)((LONG)(*pNoiseLevels++) & MASK_E) - NOISE_EXP_OFFSET; + UCHAR sinePresentFlag = 0; + int li = table[j]; + int ui = table[j + 1]; - pUiNoise++; + for (k = li; k < ui; k++) { + sinePresentFlag |= (i >= sineMapped[cc]); + cc++; } - FDK_ASSERT(k >= lowSubband); + for (k = li; k < ui; k++) { + if (k >= *pUiNoise) { + tmpNoise = + FX_SGL2FX_DBL((FIXP_SGL)((LONG)(*pNoiseLevels) & MASK_M)); + tmpNoise_e = + (SCHAR)((LONG)(*pNoiseLevels++) & MASK_E) - NOISE_EXP_OFFSET; + + pUiNoise++; + } + + FDK_ASSERT(k >= lowSubband); - if (useLP) - useAliasReduction[k-lowSubband] = !sinePresentFlag; + if (useLP) useAliasReduction[k - lowSubband] = !sinePresentFlag; - pNrgs->nrgSine[c] = FL2FXCONST_DBL(0.0f); - pNrgs->nrgSine_e[c] = 0; + pNrgs->nrgSine[c] = FL2FXCONST_DBL(0.0f); + pNrgs->nrgSine_e[c] = 0; - calcSubbandGain(refNrg, refNrg_e, pNrgs, c, - tmpNoise, tmpNoise_e, - sinePresentFlag, i >= sineMapped[c], - noNoiseFlag); + calcSubbandGain(refNrg, refNrg_e, pNrgs, c, tmpNoise, tmpNoise_e, + sinePresentFlag, i >= sineMapped[c], noNoiseFlag); - pNrgs->nrgRef[c] = refNrg; - pNrgs->nrgRef_e[c] = refNrg_e; + pNrgs->nrgRef[c] = refNrg; + pNrgs->nrgRef_e[c] = refNrg_e; - c++; + c++; + } + pIenv++; } - pIenv++; } } @@ -732,19 +1273,30 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling */ for (c = 0; c < hFreq->noLimiterBands; c++) { - FIXP_DBL sumRef, boostGain, maxGain; FIXP_DBL accu = FL2FXCONST_DBL(0.0f); - SCHAR sumRef_e, boostGain_e, maxGain_e, accu_e = 0; + SCHAR sumRef_e, boostGain_e, maxGain_e, accu_e = 0; + int maxGainLimGainSum_e = 0; - calcAvgGain(pNrgs, - hFreq->limiterBandTable[c], hFreq->limiterBandTable[c+1], - &sumRef, &sumRef_e, - &maxGain, &maxGain_e); + calcAvgGain(pNrgs, hFreq->limiterBandTable[c], + hFreq->limiterBandTable[c + 1], &sumRef, &sumRef_e, &maxGain, + &maxGain_e); /* Multiply maxGain with limiterGain: */ - maxGain = fMult(maxGain, FDK_sbrDecoder_sbr_limGains_m[hHeaderData->bs_data.limiterGains]); - maxGain_e += FDK_sbrDecoder_sbr_limGains_e[hHeaderData->bs_data.limiterGains]; + maxGain = fMult( + maxGain, + FDK_sbrDecoder_sbr_limGains_m[hHeaderData->bs_data.limiterGains]); + /* maxGain_e += + * FDK_sbrDecoder_sbr_limGains_e[hHeaderData->bs_data.limiterGains]; */ + /* The addition of maxGain_e and FDK_sbrDecoder_sbr_limGains_e[3] might + yield values greater than 127 which doesn't fit into an SCHAR! In these + rare situations limit maxGain_e to 127. + */ + maxGainLimGainSum_e = + maxGain_e + + FDK_sbrDecoder_sbr_limGains_e[hHeaderData->bs_data.limiterGains]; + maxGain_e = + (maxGainLimGainSum_e > 127) ? (SCHAR)127 : (SCHAR)maxGainLimGainSum_e; /* Scale mantissa of MaxGain into range between 0.5 and 1: */ if (maxGain == FL2FXCONST_DBL(0.0f)) @@ -752,7 +1304,7 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling else { SCHAR charTemp = CountLeadingBits(maxGain); maxGain_e -= charTemp; - maxGain <<= (int)charTemp; + maxGain <<= (int)charTemp; } if (maxGain_e >= maxGainLimit_e) { /* upper limit (e.g. 96 dB) */ @@ -760,20 +1312,21 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling maxGain_e = maxGainLimit_e; } - /* Every subband gain is compared to the scaled "average gain" and limited if necessary: */ - for (k = hFreq->limiterBandTable[c]; k < hFreq->limiterBandTable[c+1]; k++) { - if ( (pNrgs->nrgGain_e[k] > maxGain_e) || (pNrgs->nrgGain_e[k] == maxGain_e && pNrgs->nrgGain[k]>maxGain) ) { - + for (k = hFreq->limiterBandTable[c]; k < hFreq->limiterBandTable[c + 1]; + k++) { + if ((pNrgs->nrgGain_e[k] > maxGain_e) || + (pNrgs->nrgGain_e[k] == maxGain_e && pNrgs->nrgGain[k] > maxGain)) { FIXP_DBL noiseAmp; - SCHAR noiseAmp_e; + SCHAR noiseAmp_e; - FDK_divide_MantExp(maxGain, maxGain_e, pNrgs->nrgGain[k], pNrgs->nrgGain_e[k], &noiseAmp, &noiseAmp_e); - pNrgs->noiseLevel[k] = fMult(pNrgs->noiseLevel[k],noiseAmp); + FDK_divide_MantExp(maxGain, maxGain_e, pNrgs->nrgGain[k], + pNrgs->nrgGain_e[k], &noiseAmp, &noiseAmp_e); + pNrgs->noiseLevel[k] = fMult(pNrgs->noiseLevel[k], noiseAmp); pNrgs->noiseLevel_e[k] += noiseAmp_e; - pNrgs->nrgGain[k] = maxGain; - pNrgs->nrgGain_e[k] = maxGain_e; + pNrgs->nrgGain[k] = maxGain; + pNrgs->nrgGain_e[k] = maxGain_e; } } @@ -783,21 +1336,22 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling 2. Calculate boost factor by comparison with reference energy 3. Apply boost factor to compensate for the energy loss due to limiting */ - for (k = hFreq->limiterBandTable[c]; k < hFreq->limiterBandTable[c + 1]; k++) { - + for (k = hFreq->limiterBandTable[c]; k < hFreq->limiterBandTable[c + 1]; + k++) { /* 1.a Add energy of adjusted signal (using preliminary gain) */ - FIXP_DBL tmp = fMult(pNrgs->nrgGain[k],pNrgs->nrgEst[k]); - SCHAR tmp_e = pNrgs->nrgGain_e[k] + pNrgs->nrgEst_e[k]; + FIXP_DBL tmp = fMult(pNrgs->nrgGain[k], pNrgs->nrgEst[k]); + SCHAR tmp_e = pNrgs->nrgGain_e[k] + pNrgs->nrgEst_e[k]; FDK_add_MantExp(tmp, tmp_e, accu, accu_e, &accu, &accu_e); /* 1.b Add sine energy (if present) */ - if(pNrgs->nrgSine[k] != FL2FXCONST_DBL(0.0f)) { - FDK_add_MantExp(pNrgs->nrgSine[k], pNrgs->nrgSine_e[k], accu, accu_e, &accu, &accu_e); - } - else { + if (pNrgs->nrgSine[k] != FL2FXCONST_DBL(0.0f)) { + FDK_add_MantExp(pNrgs->nrgSine[k], pNrgs->nrgSine_e[k], accu, accu_e, + &accu, &accu_e); + } else { /* 1.c Add noise energy (if present) */ - if(noNoiseFlag == 0) { - FDK_add_MantExp(pNrgs->noiseLevel[k], pNrgs->noiseLevel_e[k], accu, accu_e, &accu, &accu_e); + if (noNoiseFlag == 0) { + FDK_add_MantExp(pNrgs->noiseLevel[k], pNrgs->noiseLevel_e[k], accu, + accu_e, &accu, &accu_e); } } } @@ -812,33 +1366,30 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling boostGain_e = sumRef_e - accu_e + div_e; } - /* 2.b Result too high? --> Limit the boost factor to +4 dB */ - if((boostGain_e > 3) || - (boostGain_e == 2 && boostGain > FL2FXCONST_DBL(0.6279716f)) || - (boostGain_e == 3 && boostGain > FL2FXCONST_DBL(0.3139858f)) ) - { + if ((boostGain_e > 3) || + (boostGain_e == 2 && boostGain > FL2FXCONST_DBL(0.6279716f)) || + (boostGain_e == 3 && boostGain > FL2FXCONST_DBL(0.3139858f))) { boostGain = FL2FXCONST_DBL(0.6279716f); boostGain_e = 2; } /* 3. Multiply all signal components with the boost factor */ - for (k = hFreq->limiterBandTable[c]; k < hFreq->limiterBandTable[c + 1]; k++) { - pNrgs->nrgGain[k] = fMultDiv2(pNrgs->nrgGain[k],boostGain); + for (k = hFreq->limiterBandTable[c]; k < hFreq->limiterBandTable[c + 1]; + k++) { + pNrgs->nrgGain[k] = fMultDiv2(pNrgs->nrgGain[k], boostGain); pNrgs->nrgGain_e[k] = pNrgs->nrgGain_e[k] + boostGain_e + 1; - pNrgs->nrgSine[k] = fMultDiv2(pNrgs->nrgSine[k],boostGain); + pNrgs->nrgSine[k] = fMultDiv2(pNrgs->nrgSine[k], boostGain); pNrgs->nrgSine_e[k] = pNrgs->nrgSine_e[k] + boostGain_e + 1; - pNrgs->noiseLevel[k] = fMultDiv2(pNrgs->noiseLevel[k],boostGain); + pNrgs->noiseLevel[k] = fMultDiv2(pNrgs->noiseLevel[k], boostGain); pNrgs->noiseLevel_e[k] = pNrgs->noiseLevel_e[k] + boostGain_e + 1; } } /* End of noise limiting */ if (useLP) - aliasingReduction(degreeAlias+lowSubband, - pNrgs, - useAliasReduction, + aliasingReduction(degreeAlias + lowSubband, pNrgs, useAliasReduction, noSubbands); /* For the timeslots within the range for the output frame, @@ -852,14 +1403,14 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling /* Convert energies to amplitude levels */ - for (k=0; k<noSubbands; k++) { - FDK_sqrt_MantExp(&pNrgs->nrgSine[k], &pNrgs->nrgSine_e[k], &noise_e); - FDK_sqrt_MantExp(&pNrgs->nrgGain[k], &pNrgs->nrgGain_e[k], &pNrgs->nrgGain_e[k]); - FDK_sqrt_MantExp(&pNrgs->noiseLevel[k], &pNrgs->noiseLevel_e[k], &noise_e); + for (k = 0; k < noSubbands; k++) { + FDK_sqrt_MantExp(&pNrgs->nrgSine[k], &pNrgs->nrgSine_e[k], &noise_e); + FDK_sqrt_MantExp(&pNrgs->nrgGain[k], &pNrgs->nrgGain_e[k], + &pNrgs->nrgGain_e[k]); + FDK_sqrt_MantExp(&pNrgs->noiseLevel[k], &pNrgs->noiseLevel_e[k], + &noise_e); } - - /* Apply calculated gains and adaptive noise */ @@ -868,40 +1419,42 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling { int scale_change, sc_change; FIXP_SGL smooth_ratio; - int filtBufferNoiseShift=0; + int filtBufferNoiseShift = 0; /* Initialize smoothing buffers with the first valid values */ - if (h_sbr_cal_env->startUp) - { + if (h_sbr_cal_env->startUp) { if (!useLP) { h_sbr_cal_env->filtBufferNoise_e = noise_e; - FDKmemcpy(h_sbr_cal_env->filtBuffer_e, pNrgs->nrgGain_e, noSubbands*sizeof(SCHAR)); - FDKmemcpy(h_sbr_cal_env->filtBufferNoise, pNrgs->noiseLevel, noSubbands*sizeof(FIXP_DBL)); - FDKmemcpy(h_sbr_cal_env->filtBuffer, pNrgs->nrgGain, noSubbands*sizeof(FIXP_DBL)); - + FDKmemcpy(h_sbr_cal_env->filtBuffer_e, pNrgs->nrgGain_e, + noSubbands * sizeof(SCHAR)); + FDKmemcpy(h_sbr_cal_env->filtBufferNoise, pNrgs->noiseLevel, + noSubbands * sizeof(FIXP_DBL)); + FDKmemcpy(h_sbr_cal_env->filtBuffer, pNrgs->nrgGain, + noSubbands * sizeof(FIXP_DBL)); } h_sbr_cal_env->startUp = 0; } if (!useLP) { - - equalizeFiltBufferExp(h_sbr_cal_env->filtBuffer, /* buffered */ - h_sbr_cal_env->filtBuffer_e, /* buffered */ - pNrgs->nrgGain, /* current */ - pNrgs->nrgGain_e, /* current */ + equalizeFiltBufferExp(h_sbr_cal_env->filtBuffer, /* buffered */ + h_sbr_cal_env->filtBuffer_e, /* buffered */ + pNrgs->nrgGain, /* current */ + pNrgs->nrgGain_e, /* current */ noSubbands); /* Adapt exponent of buffered noise levels to the current exponent so they can easily be smoothed */ - if((h_sbr_cal_env->filtBufferNoise_e - noise_e)>=0) { - int shift = fixMin(DFRACT_BITS-1,(int)(h_sbr_cal_env->filtBufferNoise_e - noise_e)); - for (k=0; k<noSubbands; k++) + if ((h_sbr_cal_env->filtBufferNoise_e - noise_e) >= 0) { + int shift = fixMin(DFRACT_BITS - 1, + (int)(h_sbr_cal_env->filtBufferNoise_e - noise_e)); + for (k = 0; k < noSubbands; k++) h_sbr_cal_env->filtBufferNoise[k] <<= shift; - } - else { - int shift = fixMin(DFRACT_BITS-1,-(int)(h_sbr_cal_env->filtBufferNoise_e - noise_e)); - for (k=0; k<noSubbands; k++) + } else { + int shift = + fixMin(DFRACT_BITS - 1, + -(int)(h_sbr_cal_env->filtBufferNoise_e - noise_e)); + for (k = 0; k < noSubbands; k++) h_sbr_cal_env->filtBufferNoise[k] >>= shift; } @@ -909,60 +1462,61 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling } /* find best scaling! */ - scale_change = -(DFRACT_BITS-1); - for(k=0;k<noSubbands;k++) { - scale_change = fixMax(scale_change,(int)pNrgs->nrgGain_e[k]); + scale_change = -(DFRACT_BITS - 1); + for (k = 0; k < noSubbands; k++) { + scale_change = fixMax(scale_change, (int)pNrgs->nrgGain_e[k]); } - sc_change = (start_pos<no_cols)? adj_e - input_e : final_e - input_e; + sc_change = (start_pos < no_cols) ? adj_e - input_e : final_e - input_e; - if ((scale_change-sc_change+1)<0) - scale_change-=(scale_change-sc_change+1); + if ((scale_change - sc_change + 1) < 0) + scale_change -= (scale_change - sc_change + 1); - scale_change = (scale_change-sc_change)+1; + scale_change = (scale_change - sc_change) + 1; - for(k=0;k<noSubbands;k++) { - int sc = scale_change-pNrgs->nrgGain_e[k] + (sc_change-1); - pNrgs->nrgGain[k] >>= sc; - pNrgs->nrgGain_e[k] += sc; + for (k = 0; k < noSubbands; k++) { + int sc = scale_change - pNrgs->nrgGain_e[k] + (sc_change - 1); + pNrgs->nrgGain[k] >>= sc; + pNrgs->nrgGain_e[k] += sc; } if (!useLP) { - for(k=0;k<noSubbands;k++) { - int sc = scale_change-h_sbr_cal_env->filtBuffer_e[k] + (sc_change-1); + for (k = 0; k < noSubbands; k++) { + int sc = + scale_change - h_sbr_cal_env->filtBuffer_e[k] + (sc_change - 1); h_sbr_cal_env->filtBuffer[k] >>= sc; } } - for (j = start_pos; j < stop_pos; j++) - { - /* This timeslot is located within the first part of the processing buffer - and will be fed into the QMF-synthesis for the current frame. + for (j = start_pos; j < stop_pos; j++) { + /* This timeslot is located within the first part of the processing + buffer and will be fed into the QMF-synthesis for the current frame. adj_e - input_e This timeslot will not yet be fed into the QMF so we do not care about the adj_e. sc_change = final_e - input_e */ - if ( (j==no_cols) && (start_pos<no_cols) ) - { - int shift = (int) (noise_e - final_e); + if ((j == no_cols) && (start_pos < no_cols)) { + int shift = (int)(noise_e - final_e); if (!useLP) - filtBufferNoiseShift = shift; /* shifting of h_sbr_cal_env->filtBufferNoise[k] will be applied in function adjustTimeSlotHQ() */ - if (shift>=0) { - shift = fixMin(DFRACT_BITS-1,shift); - for (k=0; k<noSubbands; k++) { + filtBufferNoiseShift = shift; /* shifting of + h_sbr_cal_env->filtBufferNoise[k] + will be applied in function + adjustTimeSlotHQ() */ + if (shift >= 0) { + shift = fixMin(DFRACT_BITS - 1, shift); + for (k = 0; k < noSubbands; k++) { pNrgs->nrgSine[k] <<= shift; - pNrgs->noiseLevel[k] <<= shift; + pNrgs->noiseLevel[k] <<= shift; /* if (!useLP) h_sbr_cal_env->filtBufferNoise[k] <<= shift; */ } - } - else { - shift = fixMin(DFRACT_BITS-1,-shift); - for (k=0; k<noSubbands; k++) { + } else { + shift = fixMin(DFRACT_BITS - 1, -shift); + for (k = 0; k < noSubbands; k++) { pNrgs->nrgSine[k] >>= shift; - pNrgs->noiseLevel[k] >>= shift; + pNrgs->noiseLevel[k] >>= shift; /* if (!useLP) h_sbr_cal_env->filtBufferNoise[k] >>= shift; @@ -973,182 +1527,248 @@ calculateSbrEnvelope (QMF_SCALE_FACTOR *sbrScaleFactor, /*!< Scaling /* update noise scaling */ noise_e = final_e; if (!useLP) - h_sbr_cal_env->filtBufferNoise_e = noise_e; /* scaling value unused! */ + h_sbr_cal_env->filtBufferNoise_e = + noise_e; /* scaling value unused! */ /* update gain buffer*/ sc_change -= (final_e - input_e); - if (sc_change<0) { - for(k=0;k<noSubbands;k++) { - pNrgs->nrgGain[k] >>= -sc_change; - pNrgs->nrgGain_e[k] += -sc_change; + if (sc_change < 0) { + for (k = 0; k < noSubbands; k++) { + pNrgs->nrgGain[k] >>= -sc_change; + pNrgs->nrgGain_e[k] += -sc_change; } if (!useLP) { - for(k=0;k<noSubbands;k++) { - h_sbr_cal_env->filtBuffer[k] >>= -sc_change; + for (k = 0; k < noSubbands; k++) { + h_sbr_cal_env->filtBuffer[k] >>= -sc_change; } } } else { - scale_change+=sc_change; + scale_change += sc_change; } - } // if + } /* if */ if (!useLP) { - /* Prevent the smoothing filter from running on constant levels */ - if (j-start_pos < smooth_length) - smooth_ratio = FDK_sbrDecoder_sbr_smoothFilter[j-start_pos]; + if (j - start_pos < smooth_length) + smooth_ratio = FDK_sbrDecoder_sbr_smoothFilter[j - start_pos]; else smooth_ratio = FL2FXCONST_SGL(0.0f); - adjustTimeSlotHQ(&analysBufferReal[j][lowSubband], - &analysBufferImag[j][lowSubband], - h_sbr_cal_env, - pNrgs, - lowSubband, - noSubbands, - scale_change, - smooth_ratio, - noNoiseFlag, - filtBufferNoiseShift); - } - else - { + if (iTES_enable) { + /* adjustTimeSlotHQ() without adding of additional harmonics */ + adjustTimeSlotHQ_GainAndNoise( + &analysBufferReal[j][lowSubband], + &analysBufferImag[j][lowSubband], h_sbr_cal_env, pNrgs, + lowSubband, noSubbands, scale_change, smooth_ratio, noNoiseFlag, + filtBufferNoiseShift); + } else { + adjustTimeSlotHQ(&analysBufferReal[j][lowSubband], + &analysBufferImag[j][lowSubband], h_sbr_cal_env, + pNrgs, lowSubband, noSubbands, scale_change, + smooth_ratio, noNoiseFlag, filtBufferNoiseShift); + } + } else { + FDK_ASSERT(!iTES_enable); /* not supported */ if (flags & SBRDEC_ELD_GRID) { - adjustTimeSlot_EldGrid(&analysBufferReal[j][lowSubband], - pNrgs, - &h_sbr_cal_env->harmIndex, - lowSubband, - noSubbands, - scale_change, - noNoiseFlag, - &h_sbr_cal_env->phaseIndex, - EXP2SCALE(adj_e) - sbrScaleFactor->lb_scale); - } else - { - adjustTimeSlotLC(&analysBufferReal[j][lowSubband], - pNrgs, - &h_sbr_cal_env->harmIndex, - lowSubband, - noSubbands, - scale_change, - noNoiseFlag, - &h_sbr_cal_env->phaseIndex); + /* FDKmemset(analysBufferReal[j], 0, 64 * sizeof(FIXP_DBL)); */ + adjustTimeSlot_EldGrid(&analysBufferReal[j][lowSubband], pNrgs, + &h_sbr_cal_env->harmIndex, lowSubband, + noSubbands, scale_change, noNoiseFlag, + &h_sbr_cal_env->phaseIndex, + EXP2SCALE(adj_e) - sbrScaleFactor->lb_scale); + } else { + adjustTimeSlotLC(&analysBufferReal[j][lowSubband], pNrgs, + &h_sbr_cal_env->harmIndex, lowSubband, noSubbands, + scale_change, noNoiseFlag, + &h_sbr_cal_env->phaseIndex); + } + } + /* In case the envelope spans accross the no_cols border both exponents + * are needed. */ + /* nrgGain_e[0...(noSubbands-1)] are equalized by + * equalizeFiltBufferExp() */ + pNrgs->exponent[(j < no_cols) ? 0 : 1] = + (SCHAR)((15 - sbrScaleFactor->hb_scale) + pNrgs->nrgGain_e[0] + 1 - + scale_change); + } /* for */ + + if (iTES_enable) { + apply_inter_tes( + analysBufferReal, /* pABufR, */ + analysBufferImag, /* pABufI, */ + sbrScaleFactor, pNrgs->exponent, hHeaderData->timeStep, start_pos, + stop_pos, lowSubband, noSubbands, + hFrameData + ->interTempShapeMode[i] /* frameData->interTempShapeMode[env] */ + ); + + /* add additional harmonics */ + for (j = start_pos; j < stop_pos; j++) { + /* match exponent of additional harmonics to scale change of QMF data + * caused by apply_inter_tes() */ + scale_change = 0; + + if ((start_pos <= no_cols) && (stop_pos > no_cols)) { + /* Scaling of analysBuffers was potentially changed within this + envelope. The pNrgs->nrgSine_e match the second part of the + envelope. For (j<=no_cols) the exponent of the sine energies has + to be adapted. */ + scale_change = pNrgs->exponent[1] - pNrgs->exponent[0]; } + + adjustTimeSlotHQ_AddHarmonics( + &analysBufferReal[j][lowSubband], + &analysBufferImag[j][lowSubband], h_sbr_cal_env, pNrgs, + lowSubband, noSubbands, + -iTES_scale_change + ((j < no_cols) ? scale_change : 0)); } - } // for + } if (!useLP) { /* Update time-smoothing-buffers for gains and noise levels - The gains and the noise values of the current envelope are copied into the buffer. - This has to be done at the end of each envelope as the values are required for - a smooth transition to the next envelope. */ - FDKmemcpy(h_sbr_cal_env->filtBuffer, pNrgs->nrgGain, noSubbands*sizeof(FIXP_DBL)); - FDKmemcpy(h_sbr_cal_env->filtBuffer_e, pNrgs->nrgGain_e, noSubbands*sizeof(SCHAR)); - FDKmemcpy(h_sbr_cal_env->filtBufferNoise, pNrgs->noiseLevel, noSubbands*sizeof(FIXP_DBL)); + The gains and the noise values of the current envelope are copied + into the buffer. This has to be done at the end of each envelope as + the values are required for a smooth transition to the next envelope. + */ + FDKmemcpy(h_sbr_cal_env->filtBuffer, pNrgs->nrgGain, + noSubbands * sizeof(FIXP_DBL)); + FDKmemcpy(h_sbr_cal_env->filtBuffer_e, pNrgs->nrgGain_e, + noSubbands * sizeof(SCHAR)); + FDKmemcpy(h_sbr_cal_env->filtBufferNoise, pNrgs->noiseLevel, + noSubbands * sizeof(FIXP_DBL)); } - } C_ALLOC_SCRATCH_END(pNrgs, ENV_CALC_NRGS, 1); } + /* adapt adj_e to the scale change caused by apply_inter_tes() */ + adj_e += iTES_scale_change; + /* Rescale output samples */ { FIXP_DBL maxVal; int ov_reserve, reserve; /* Determine headroom in old adjusted samples */ - maxVal = maxSubbandSample( analysBufferReal, - (useLP) ? NULL : analysBufferImag, - lowSubband, - highSubband, - 0, - first_start); + maxVal = + maxSubbandSample(analysBufferReal, (useLP) ? NULL : analysBufferImag, + lowSubband, ov_highSubband, 0, first_start); ov_reserve = fNorm(maxVal); /* Determine headroom in new adjusted samples */ - maxVal = maxSubbandSample( analysBufferReal, - (useLP) ? NULL : analysBufferImag, - lowSubband, - highSubband, - first_start, - no_cols); + maxVal = + maxSubbandSample(analysBufferReal, (useLP) ? NULL : analysBufferImag, + lowSubband, highSubband, first_start, no_cols); reserve = fNorm(maxVal); /* Determine common output exponent */ - if (ov_adj_e - ov_reserve > adj_e - reserve ) /* set output_e to the maximum */ - output_e = ov_adj_e - ov_reserve; - else - output_e = adj_e - reserve; + output_e = fMax(ov_adj_e - ov_reserve, adj_e - reserve); /* Rescale old samples */ - rescaleSubbandSamples( analysBufferReal, - (useLP) ? NULL : analysBufferImag, - lowSubband, highSubband, - 0, first_start, - ov_adj_e - output_e); + rescaleSubbandSamples(analysBufferReal, (useLP) ? NULL : analysBufferImag, + lowSubband, ov_highSubband, 0, first_start, + ov_adj_e - output_e); /* Rescale new samples */ - rescaleSubbandSamples( analysBufferReal, - (useLP) ? NULL : analysBufferImag, - lowSubband, highSubband, - first_start, no_cols, - adj_e - output_e); + rescaleSubbandSamples(analysBufferReal, (useLP) ? NULL : analysBufferImag, + lowSubband, highSubband, first_start, no_cols, + adj_e - output_e); } /* Update hb_scale */ sbrScaleFactor->hb_scale = EXP2SCALE(output_e); /* Save the current final exponent for the next frame: */ - sbrScaleFactor->ov_hb_scale = EXP2SCALE(final_e); + /* adapt final_e to the scale change caused by apply_inter_tes() */ + sbrScaleFactor->ov_hb_scale = EXP2SCALE(final_e + iTES_scale_change); - - /* We need to remeber to the next frame that the transient + /* We need to remember to the next frame that the transient will occur in the first envelope (if tranEnv == nEnvelopes). */ - if(hFrameData->frameInfo.tranEnv == hFrameData->frameInfo.nEnvelopes) + if (hFrameData->frameInfo.tranEnv == hFrameData->frameInfo.nEnvelopes) h_sbr_cal_env->prevTranEnv = 0; else h_sbr_cal_env->prevTranEnv = -1; -} + if (pvc_mode > 0) { + /* Not more than just the last noise envelope reaches into the next PVC + frame! This should be true because bs_noise_position is <= 15 */ + FDK_ASSERT(hFrameData->frameInfo + .bordersNoise[hFrameData->frameInfo.nNoiseEnvelopes - 1] < + PVC_NTIMESLOT); + if (hFrameData->frameInfo + .bordersNoise[hFrameData->frameInfo.nNoiseEnvelopes] > + PVC_NTIMESLOT) { + FDK_ASSERT(noiseLevels == + (hFrameData->sbrNoiseFloorLevel + + (hFrameData->frameInfo.nNoiseEnvelopes - 1) * noNoiseBands)); + h_sbr_cal_env->prevNNfb = noNoiseBands; + + h_sbr_cal_env->prevNSfb[0] = noSubFrameBands[0]; + h_sbr_cal_env->prevNSfb[1] = noSubFrameBands[1]; + + h_sbr_cal_env->prevLoSubband = lowSubband; + h_sbr_cal_env->prevHiSubband = highSubband; + h_sbr_cal_env->prev_ov_highSubband = ov_highSubband; + + FDKmemcpy(h_sbr_cal_env->prevFreqBandTableLo, pFreqBandTable[0], + noSubFrameBands[0] + 1); + FDKmemcpy(h_sbr_cal_env->prevFreqBandTableHi, pFreqBandTable[1], + noSubFrameBands[1] + 1); + FDKmemcpy(h_sbr_cal_env->prevFreqBandTableNoise, + hFreq->freqBandTableNoise, sizeof(hFreq->freqBandTableNoise)); + + FDKmemcpy(h_sbr_cal_env->prevSbrNoiseFloorLevel, noiseLevels, + MAX_NOISE_COEFFS * sizeof(FIXP_SGL)); + } + } + C_ALLOC_SCRATCH_END(useAliasReduction, UCHAR, 64) +} /*! \brief Create envelope instance - Must be called once for each channel before calculateSbrEnvelope() can be used. + Must be called once for each channel before calculateSbrEnvelope() can be + used. \return errorCode, 0 if successful */ SBR_ERROR -createSbrEnvelopeCalc (HANDLE_SBR_CALCULATE_ENVELOPE hs, /*!< pointer to envelope instance */ - HANDLE_SBR_HEADER_DATA hHeaderData, /*!< static SBR control data, initialized with defaults */ - const int chan, /*!< Channel for which to assign buffers */ - const UINT flags) -{ +createSbrEnvelopeCalc( + HANDLE_SBR_CALCULATE_ENVELOPE hs, /*!< pointer to envelope instance */ + HANDLE_SBR_HEADER_DATA + hHeaderData, /*!< static SBR control data, initialized with defaults */ + const int chan, /*!< Channel for which to assign buffers */ + const UINT flags) { SBR_ERROR err = SBRDEC_OK; int i; /* Clear previous missing harmonics flags */ - for (i=0; i<(MAX_FREQ_COEFFS+15)>>4; i++) { + for (i = 0; i < ADD_HARMONICS_FLAGS_SIZE; i++) { hs->harmFlagsPrev[i] = 0; + hs->harmFlagsPrevActive[i] = 0; } hs->harmIndex = 0; + FDKmemclear(hs->prevSbrNoiseFloorLevel, sizeof(hs->prevSbrNoiseFloorLevel)); + hs->prevNNfb = 0; + FDKmemclear(hs->prevFreqBandTableNoise, sizeof(hs->prevFreqBandTableNoise)); + hs->sinusoidal_positionPrev = 0; + /* Setup pointers for time smoothing. The buffer itself will be initialized later triggered by the startUp-flag. */ hs->prevTranEnv = -1; - /* initialization */ resetSbrEnvelopeCalc(hs); - if (chan==0) { /* do this only once */ + if (chan == 0) { /* do this only once */ err = resetFreqBandTables(hHeaderData, flags); } @@ -1158,16 +1778,12 @@ createSbrEnvelopeCalc (HANDLE_SBR_CALCULATE_ENVELOPE hs, /*!< pointer to envel /*! \brief Create envelope instance - Must be called once for each channel before calculateSbrEnvelope() can be used. + Must be called once for each channel before calculateSbrEnvelope() can be + used. \return errorCode, 0 if successful */ -int -deleteSbrEnvelopeCalc (HANDLE_SBR_CALCULATE_ENVELOPE hs) -{ - return 0; -} - +int deleteSbrEnvelopeCalc(HANDLE_SBR_CALCULATE_ENVELOPE hs) { return 0; } /*! \brief Reset envelope instance @@ -1177,18 +1793,18 @@ deleteSbrEnvelopeCalc (HANDLE_SBR_CALCULATE_ENVELOPE hs) \return errorCode, 0 if successful */ -void -resetSbrEnvelopeCalc (HANDLE_SBR_CALCULATE_ENVELOPE hCalEnv) /*!< pointer to envelope instance */ +void resetSbrEnvelopeCalc( + HANDLE_SBR_CALCULATE_ENVELOPE hCalEnv) /*!< pointer to envelope instance */ { hCalEnv->phaseIndex = 0; - /* Noise exponent needs to be reset because the output exponent for the next frame depends on it */ + /* Noise exponent needs to be reset because the output exponent for the next + * frame depends on it */ hCalEnv->filtBufferNoise_e = 0; hCalEnv->startUp = 1; } - /*! \brief Equalize exponents of the buffered gain values and the new ones @@ -1196,40 +1812,41 @@ resetSbrEnvelopeCalc (HANDLE_SBR_CALCULATE_ENVELOPE hCalEnv) /*!< pointer to env can be performed. This function is called once for each envelope before adjusting. */ -static void equalizeFiltBufferExp(FIXP_DBL *filtBuffer, /*!< bufferd gains */ - SCHAR *filtBuffer_e, /*!< exponents of bufferd gains */ - FIXP_DBL *nrgGain, /*!< gains for current envelope */ - SCHAR *nrgGain_e, /*!< exponents of gains for current envelope */ - int subbands) /*!< Number of QMF subbands */ +static void equalizeFiltBufferExp( + FIXP_DBL *filtBuffer, /*!< bufferd gains */ + SCHAR *filtBuffer_e, /*!< exponents of bufferd gains */ + FIXP_DBL *nrgGain, /*!< gains for current envelope */ + SCHAR *nrgGain_e, /*!< exponents of gains for current envelope */ + int subbands) /*!< Number of QMF subbands */ { - int band; - int diff; - - for (band=0; band<subbands; band++){ - diff = (int) (nrgGain_e[band] - filtBuffer_e[band]); - if (diff>0) { - filtBuffer[band] >>= diff; /* Compensate for the scale change by shifting the mantissa. */ - filtBuffer_e[band] += diff; /* New gain is bigger, use its exponent */ - } - else if (diff<0) { + int band; + int diff; + + for (band = 0; band < subbands; band++) { + diff = (int)(nrgGain_e[band] - filtBuffer_e[band]); + if (diff > 0) { + filtBuffer[band] >>= + diff; /* Compensate for the scale change by shifting the mantissa. */ + filtBuffer_e[band] += diff; /* New gain is bigger, use its exponent */ + } else if (diff < 0) { /* The buffered gains seem to be larger, but maybe there are some unused bits left in the mantissa */ - int reserve = CntLeadingZeros(fixp_abs(filtBuffer[band]))-1; + int reserve = CntLeadingZeros(fixp_abs(filtBuffer[band])) - 1; if ((-diff) <= reserve) { /* There is enough space in the buffered mantissa so that we can take the new exponent as common. */ filtBuffer[band] <<= (-diff); - filtBuffer_e[band] += diff; /* becomes equal to *ptrNewExp */ - } - else { - filtBuffer[band] <<= reserve; /* Shift the mantissa as far as possible: */ - filtBuffer_e[band] -= reserve; /* Compensate in the exponent: */ + filtBuffer_e[band] += diff; /* becomes equal to *ptrNewExp */ + } else { + filtBuffer[band] <<= + reserve; /* Shift the mantissa as far as possible: */ + filtBuffer_e[band] -= reserve; /* Compensate in the exponent: */ /* For the remaining difference, change the new gain value */ - diff = fixMin(-(reserve + diff),DFRACT_BITS-1); + diff = fixMin(-(reserve + diff), DFRACT_BITS - 1); nrgGain[band] >>= diff; nrgGain_e[band] += diff; } @@ -1244,31 +1861,41 @@ static void equalizeFiltBufferExp(FIXP_DBL *filtBuffer, /*!< bufferd gains * This function is used to rescale the audio data in the overlap buffer which has already been envelope adjusted with the last frame. */ -void rescaleSubbandSamples(FIXP_DBL ** re, /*!< Real part of input and output subband samples */ - FIXP_DBL ** im, /*!< Imaginary part of input and output subband samples */ - int lowSubband, /*!< Begin of frequency range to process */ - int highSubband, /*!< End of frequency range to process */ - int start_pos, /*!< Begin of time rage (QMF-timeslot) */ - int next_pos, /*!< End of time rage (QMF-timeslot) */ - int shift) /*!< number of bits to shift */ +void rescaleSubbandSamples( + FIXP_DBL **re, /*!< Real part of input and output subband samples */ + FIXP_DBL **im, /*!< Imaginary part of input and output subband samples */ + int lowSubband, /*!< Begin of frequency range to process */ + int highSubband, /*!< End of frequency range to process */ + int start_pos, /*!< Begin of time rage (QMF-timeslot) */ + int next_pos, /*!< End of time rage (QMF-timeslot) */ + int shift) /*!< number of bits to shift */ { - int width = highSubband-lowSubband; + int width = highSubband - lowSubband; - if ( (width > 0) && (shift!=0) ) { - if (im!=NULL) { - for (int l=start_pos; l<next_pos; l++) { - scaleValues(&re[l][lowSubband], width, shift); - scaleValues(&im[l][lowSubband], width, shift); + if ((width > 0) && (shift != 0)) { + if (im != NULL) { + for (int l = start_pos; l < next_pos; l++) { + scaleValues(&re[l][lowSubband], width, shift); + scaleValues(&im[l][lowSubband], width, shift); } - } else - { - for (int l=start_pos; l<next_pos; l++) { - scaleValues(&re[l][lowSubband], width, shift); + } else { + for (int l = start_pos; l < next_pos; l++) { + scaleValues(&re[l][lowSubband], width, shift); } } } } +static inline FIXP_DBL FDK_get_maxval_real(FIXP_DBL maxVal, FIXP_DBL *reTmp, + INT width) { + maxVal = (FIXP_DBL)0; + while (width-- != 0) { + FIXP_DBL tmp = *(reTmp++); + maxVal |= (FIXP_DBL)((LONG)(tmp) ^ ((LONG)tmp >> (DFRACT_BITS - 1))); + } + + return maxVal; +} /*! \brief Determine headroom for shifting @@ -1279,55 +1906,58 @@ void rescaleSubbandSamples(FIXP_DBL ** re, /*!< Real part of input and output \return Number of free bits in the biggest spectral value */ -FIXP_DBL maxSubbandSample( FIXP_DBL ** re, /*!< Real part of input and output subband samples */ - FIXP_DBL ** im, /*!< Real part of input and output subband samples */ - int lowSubband, /*!< Begin of frequency range to process */ - int highSubband, /*!< Number of QMF bands to process */ - int start_pos, /*!< Begin of time rage (QMF-timeslot) */ - int next_pos /*!< End of time rage (QMF-timeslot) */ - ) -{ +FIXP_DBL maxSubbandSample( + FIXP_DBL **re, /*!< Real part of input and output subband samples */ + FIXP_DBL **im, /*!< Real part of input and output subband samples */ + int lowSubband, /*!< Begin of frequency range to process */ + int highSubband, /*!< Number of QMF bands to process */ + int start_pos, /*!< Begin of time rage (QMF-timeslot) */ + int next_pos /*!< End of time rage (QMF-timeslot) */ +) { FIXP_DBL maxVal = FL2FX_DBL(0.0f); unsigned int width = highSubband - lowSubband; FDK_ASSERT(width <= (64)); - if ( width > 0 ) { - if (im!=NULL) - { - for (int l=start_pos; l<next_pos; l++) - { -#ifdef FUNCTION_FDK_get_maxval - maxVal = FDK_get_maxval(maxVal, &re[l][lowSubband], &im[l][lowSubband], width); -#else - int k=width; + if (width > 0) { + if (im != NULL) { + for (int l = start_pos; l < next_pos; l++) { + int k = width; FIXP_DBL *reTmp = &re[l][lowSubband]; FIXP_DBL *imTmp = &im[l][lowSubband]; - do{ + do { FIXP_DBL tmp1 = *(reTmp++); FIXP_DBL tmp2 = *(imTmp++); - maxVal |= (FIXP_DBL)((LONG)(tmp1)^((LONG)tmp1>>(DFRACT_BITS-1))); - maxVal |= (FIXP_DBL)((LONG)(tmp2)^((LONG)tmp2>>(DFRACT_BITS-1))); - } while(--k!=0); -#endif + maxVal |= + (FIXP_DBL)((LONG)(tmp1) ^ ((LONG)tmp1 >> (DFRACT_BITS - 1))); + maxVal |= + (FIXP_DBL)((LONG)(tmp2) ^ ((LONG)tmp2 >> (DFRACT_BITS - 1))); + } while (--k != 0); } - } else - { - for (int l=start_pos; l<next_pos; l++) { - int k=width; - FIXP_DBL *reTmp = &re[l][lowSubband]; - do{ - FIXP_DBL tmp = *(reTmp++); - maxVal |= (FIXP_DBL)((LONG)(tmp)^((LONG)tmp>>(DFRACT_BITS-1))); - }while(--k!=0); + } else { + for (int l = start_pos; l < next_pos; l++) { + maxVal |= FDK_get_maxval_real(maxVal, &re[l][lowSubband], width); } } } - return(maxVal); + if (maxVal > (FIXP_DBL)0) { + /* For negative input values, maxVal is too small by 1. Add 1 only when + * necessary: if maxVal is a power of 2 */ + FIXP_DBL lowerPow2 = + (FIXP_DBL)(1 << (DFRACT_BITS - 1 - CntLeadingZeros(maxVal))); + if (maxVal == lowerPow2) maxVal += (FIXP_DBL)1; + } + + return (maxVal); } -#define SHIFT_BEFORE_SQUARE (3) /* (7/2) */ +/* #define SHIFT_BEFORE_SQUARE (3) */ /* (7/2) */ +/* Avoid assertion failures triggerd by overflows which occured in robustness + tests. Setting the SHIFT_BEFORE_SQUARE to 4 has negligible effect on (USAC) + conformance results. */ +#define SHIFT_BEFORE_SQUARE (4) /* ((8 - 0) / 2) */ + /*!< If the accumulator does not provide enough overflow bits or does not provide a high dynamic range, the below energy calculation @@ -1351,92 +1981,100 @@ FIXP_DBL maxSubbandSample( FIXP_DBL ** re, /*!< Real part of input and output This function is used when interpolFreq is true. */ -static void calcNrgPerSubband(FIXP_DBL **analysBufferReal, /*!< Real part of subband samples */ - FIXP_DBL **analysBufferImag, /*!< Imaginary part of subband samples */ - int lowSubband, /*!< Begin of the SBR frequency range */ - int highSubband, /*!< High end of the SBR frequency range */ - int start_pos, /*!< First QMF-slot of current envelope */ - int next_pos, /*!< Last QMF-slot of current envelope + 1 */ - SCHAR frameExp, /*!< Common exponent for all input samples */ - FIXP_DBL *nrgEst, /*!< resulting Energy (0..1) */ - SCHAR *nrgEst_e ) /*!< Exponent of resulting Energy */ +static void calcNrgPerSubband( + FIXP_DBL **analysBufferReal, /*!< Real part of subband samples */ + FIXP_DBL **analysBufferImag, /*!< Imaginary part of subband samples */ + int lowSubband, /*!< Begin of the SBR frequency range */ + int highSubband, /*!< High end of the SBR frequency range */ + int start_pos, /*!< First QMF-slot of current envelope */ + int next_pos, /*!< Last QMF-slot of current envelope + 1 */ + SCHAR frameExp, /*!< Common exponent for all input samples */ + FIXP_DBL *nrgEst, /*!< resulting Energy (0..1) */ + SCHAR *nrgEst_e) /*!< Exponent of resulting Energy */ { FIXP_SGL invWidth; - SCHAR preShift; - SCHAR shift; + SCHAR preShift; + SCHAR shift; FIXP_DBL sum; - int k,l; + int k; /* Divide by width of envelope later: */ invWidth = FX_DBL2FX_SGL(GetInvInt(next_pos - start_pos)); - /* The common exponent needs to be doubled because all mantissas are squared: */ + /* The common exponent needs to be doubled because all mantissas are squared: + */ frameExp = frameExp << 1; - for (k=lowSubband; k<highSubband; k++) { - FIXP_DBL bufferReal[(((1024)/(32))+(6))]; - FIXP_DBL bufferImag[(((1024)/(32))+(6))]; - FIXP_DBL maxVal = FL2FX_DBL(0.0f); + for (k = lowSubband; k < highSubband; k++) { + FIXP_DBL bufferReal[(((1024) / (32) * (4) / 2) + (3 * (4)))]; + FIXP_DBL bufferImag[(((1024) / (32) * (4) / 2) + (3 * (4)))]; + FIXP_DBL maxVal; - if (analysBufferImag!=NULL) - { - for (l=start_pos;l<next_pos;l++) - { + if (analysBufferImag != NULL) { + int l; + maxVal = FL2FX_DBL(0.0f); + for (l = start_pos; l < next_pos; l++) { bufferImag[l] = analysBufferImag[l][k]; - maxVal |= (FIXP_DBL)((LONG)(bufferImag[l])^((LONG)bufferImag[l]>>(DFRACT_BITS-1))); + maxVal |= (FIXP_DBL)((LONG)(bufferImag[l]) ^ + ((LONG)bufferImag[l] >> (DFRACT_BITS - 1))); bufferReal[l] = analysBufferReal[l][k]; - maxVal |= (FIXP_DBL)((LONG)(bufferReal[l])^((LONG)bufferReal[l]>>(DFRACT_BITS-1))); + maxVal |= (FIXP_DBL)((LONG)(bufferReal[l]) ^ + ((LONG)bufferReal[l] >> (DFRACT_BITS - 1))); } - } - else - { - for (l=start_pos;l<next_pos;l++) - { + } else { + int l; + maxVal = FL2FX_DBL(0.0f); + for (l = start_pos; l < next_pos; l++) { bufferReal[l] = analysBufferReal[l][k]; - maxVal |= (FIXP_DBL)((LONG)(bufferReal[l])^((LONG)bufferReal[l]>>(DFRACT_BITS-1))); + maxVal |= (FIXP_DBL)((LONG)(bufferReal[l]) ^ + ((LONG)bufferReal[l] >> (DFRACT_BITS - 1))); } } - if (maxVal!=FL2FXCONST_DBL(0.f)) { - - + if (maxVal != FL2FXCONST_DBL(0.f)) { /* If the accu does not provide enough overflow bits, we cannot shift the samples up to the limit. Instead, keep up to 3 free bits in each sample, i.e. up to 6 bits after calculation of square. Please note the comment on saturated arithmetic above! */ - FIXP_DBL accu = FL2FXCONST_DBL(0.0f); - preShift = CntLeadingZeros(maxVal)-1; + FIXP_DBL accu; + preShift = CntLeadingZeros(maxVal) - 1; preShift -= SHIFT_BEFORE_SQUARE; - if (preShift>=0) { - if (analysBufferImag!=NULL) { - for (l=start_pos; l<next_pos; l++) { + /* Limit preShift to a maximum value to prevent accumulator overflow in + exceptional situations where the signal in the analysis-buffer is very + small (small maxVal). + */ + preShift = fMin(preShift, (SCHAR)25); + + accu = FL2FXCONST_DBL(0.0f); + if (preShift >= 0) { + int l; + if (analysBufferImag != NULL) { + for (l = start_pos; l < next_pos; l++) { FIXP_DBL temp1 = bufferReal[l] << (int)preShift; FIXP_DBL temp2 = bufferImag[l] << (int)preShift; accu = fPow2AddDiv2(accu, temp1); accu = fPow2AddDiv2(accu, temp2); } - } else - { - for (l=start_pos; l<next_pos; l++) { + } else { + for (l = start_pos; l < next_pos; l++) { FIXP_DBL temp = bufferReal[l] << (int)preShift; accu = fPow2AddDiv2(accu, temp); } } - } - else { /* if negative shift value */ + } else { /* if negative shift value */ + int l; int negpreShift = -preShift; - if (analysBufferImag!=NULL) { - for (l=start_pos; l<next_pos; l++) { + if (analysBufferImag != NULL) { + for (l = start_pos; l < next_pos; l++) { FIXP_DBL temp1 = bufferReal[l] >> (int)negpreShift; FIXP_DBL temp2 = bufferImag[l] >> (int)negpreShift; accu = fPow2AddDiv2(accu, temp1); accu = fPow2AddDiv2(accu, temp2); } - } else - { - for (l=start_pos; l<next_pos; l++) { + } else { + for (l = start_pos; l < next_pos; l++) { FIXP_DBL temp = bufferReal[l] >> (int)negpreShift; accu = fPow2AddDiv2(accu, temp); } @@ -1451,13 +2089,12 @@ static void calcNrgPerSubband(FIXP_DBL **analysBufferReal, /*!< Real part of su /* Divide by width of envelope and apply frame scale: */ *nrgEst++ = fMult(sum, invWidth); shift += 2 * preShift; - if (analysBufferImag!=NULL) + if (analysBufferImag != NULL) *nrgEst_e++ = frameExp - shift; else - *nrgEst_e++ = frameExp - shift + 1; /* +1 due to missing imag. part */ - } /* maxVal!=0 */ + *nrgEst_e++ = frameExp - shift + 1; /* +1 due to missing imag. part */ + } /* maxVal!=0 */ else { - /* Prevent a zero-mantissa-number from being misinterpreted due to its exponent. */ *nrgEst++ = FL2FXCONST_DBL(0.0f); @@ -1472,45 +2109,42 @@ static void calcNrgPerSubband(FIXP_DBL **analysBufferReal, /*!< Real part of su This function is used when interpolFreq is false. */ -static void calcNrgPerSfb(FIXP_DBL **analysBufferReal, /*!< Real part of subband samples */ - FIXP_DBL **analysBufferImag, /*!< Imaginary part of subband samples */ - int nSfb, /*!< Number of scale factor bands */ - UCHAR *freqBandTable, /*!< First Subband for each Sfb */ - int start_pos, /*!< First QMF-slot of current envelope */ - int next_pos, /*!< Last QMF-slot of current envelope + 1 */ - SCHAR input_e, /*!< Common exponent for all input samples */ - FIXP_DBL *nrgEst, /*!< resulting Energy (0..1) */ - SCHAR *nrgEst_e ) /*!< Exponent of resulting Energy */ +static void calcNrgPerSfb( + FIXP_DBL **analysBufferReal, /*!< Real part of subband samples */ + FIXP_DBL **analysBufferImag, /*!< Imaginary part of subband samples */ + int nSfb, /*!< Number of scale factor bands */ + UCHAR *freqBandTable, /*!< First Subband for each Sfb */ + int start_pos, /*!< First QMF-slot of current envelope */ + int next_pos, /*!< Last QMF-slot of current envelope + 1 */ + SCHAR input_e, /*!< Common exponent for all input samples */ + FIXP_DBL *nrgEst, /*!< resulting Energy (0..1) */ + SCHAR *nrgEst_e) /*!< Exponent of resulting Energy */ { - FIXP_SGL invWidth; - FIXP_DBL temp; - SCHAR preShift; - SCHAR shift, sum_e; - FIXP_DBL sum; + FIXP_SGL invWidth; + FIXP_DBL temp; + SCHAR preShift; + SCHAR shift, sum_e; + FIXP_DBL sum; - int j,k,l,li,ui; + int j, k, l, li, ui; FIXP_DBL sumAll, sumLine; /* Single precision would be sufficient, but overflow bits are required for accumulation */ /* Divide by width of envelope later: */ invWidth = FX_DBL2FX_SGL(GetInvInt(next_pos - start_pos)); - /* The common exponent needs to be doubled because all mantissas are squared: */ + /* The common exponent needs to be doubled because all mantissas are squared: + */ input_e = input_e << 1; - for(j=0; j<nSfb; j++) { + for (j = 0; j < nSfb; j++) { li = freqBandTable[j]; - ui = freqBandTable[j+1]; + ui = freqBandTable[j + 1]; - FIXP_DBL maxVal = maxSubbandSample( analysBufferReal, - analysBufferImag, - li, - ui, - start_pos, - next_pos ); + FIXP_DBL maxVal = maxSubbandSample(analysBufferReal, analysBufferImag, li, + ui, start_pos, next_pos); - if (maxVal!=FL2FXCONST_DBL(0.f)) { - - preShift = CntLeadingZeros(maxVal)-1; + if (maxVal != FL2FXCONST_DBL(0.f)) { + preShift = CntLeadingZeros(maxVal) - 1; /* If the accu does not provide enough overflow bits, we cannot shift the samples up to the limit. @@ -1522,38 +2156,34 @@ static void calcNrgPerSfb(FIXP_DBL **analysBufferReal, /*!< Real part of subba sumAll = FL2FXCONST_DBL(0.0f); - - for (k=li; k<ui; k++) { - + for (k = li; k < ui; k++) { sumLine = FL2FXCONST_DBL(0.0f); - if (analysBufferImag!=NULL) { - if (preShift>=0) { - for (l=start_pos; l<next_pos; l++) { - temp = analysBufferReal[l][k] << (int)preShift; + if (analysBufferImag != NULL) { + if (preShift >= 0) { + for (l = start_pos; l < next_pos; l++) { + temp = analysBufferReal[l][k] << (int)preShift; sumLine += fPow2Div2(temp); - temp = analysBufferImag[l][k] << (int)preShift; + temp = analysBufferImag[l][k] << (int)preShift; sumLine += fPow2Div2(temp); - } } else { - for (l=start_pos; l<next_pos; l++) { - temp = analysBufferReal[l][k] >> -(int)preShift; + for (l = start_pos; l < next_pos; l++) { + temp = analysBufferReal[l][k] >> -(int)preShift; sumLine += fPow2Div2(temp); - temp = analysBufferImag[l][k] >> -(int)preShift; + temp = analysBufferImag[l][k] >> -(int)preShift; sumLine += fPow2Div2(temp); } } - } else - { - if (preShift>=0) { - for (l=start_pos; l<next_pos; l++) { - temp = analysBufferReal[l][k] << (int)preShift; + } else { + if (preShift >= 0) { + for (l = start_pos; l < next_pos; l++) { + temp = analysBufferReal[l][k] << (int)preShift; sumLine += fPow2Div2(temp); } } else { - for (l=start_pos; l<next_pos; l++) { - temp = analysBufferReal[l][k] >> -(int)preShift; + for (l = start_pos; l < next_pos; l++) { + temp = analysBufferReal[l][k] >> -(int)preShift; sumLine += fPow2Div2(temp); } } @@ -1561,8 +2191,8 @@ static void calcNrgPerSfb(FIXP_DBL **analysBufferReal, /*!< Real part of subba /* The number of QMF-channels per SBR bands may be up to 15. Shift right to avoid overflows in sum over all channels. */ - sumLine = sumLine >> (4-1); - sumAll += sumLine; + sumLine = sumLine >> (4 - 1); + sumAll += sumLine; } /* Convert double precision to Mantissa/Exponent: */ @@ -1570,62 +2200,66 @@ static void calcNrgPerSfb(FIXP_DBL **analysBufferReal, /*!< Real part of subba sum = sumAll << (int)shift; /* Divide by width of envelope: */ - sum = fMult(sum,invWidth); + sum = fMult(sum, invWidth); /* Divide by width of Sfb: */ - sum = fMult(sum, FX_DBL2FX_SGL(GetInvInt(ui-li))); + sum = fMult(sum, FX_DBL2FX_SGL(GetInvInt(ui - li))); /* Set all Subband energies in the Sfb to the average energy: */ - if (analysBufferImag!=NULL) - sum_e = input_e + 4 - shift; /* -4 to compensate right-shift */ + if (analysBufferImag != NULL) + sum_e = input_e + 4 - shift; /* -4 to compensate right-shift */ else - sum_e = input_e + 4 + 1 - shift; /* -4 to compensate right-shift; +1 due to missing imag. part */ + sum_e = input_e + 4 + 1 - + shift; /* -4 to compensate right-shift; +1 due to missing + imag. part */ sum_e -= 2 * preShift; } /* maxVal!=0 */ else { - /* Prevent a zero-mantissa-number from being misinterpreted due to its exponent. */ sum = FL2FXCONST_DBL(0.0f); sum_e = 0; } - for (k=li; k<ui; k++) - { - *nrgEst++ = sum; + for (k = li; k < ui; k++) { + *nrgEst++ = sum; *nrgEst_e++ = sum_e; } } } - /*! \brief Calculate gain, noise, and additional sine level for one subband. The resulting energy gain is given by mantissa and exponent. */ -static void calcSubbandGain(FIXP_DBL nrgRef, /*!< Reference Energy according to envelope data */ - SCHAR nrgRef_e, /*!< Reference Energy according to envelope data (exponent) */ - ENV_CALC_NRGS* nrgs, - int i, - FIXP_DBL tmpNoise, /*!< Relative noise level */ - SCHAR tmpNoise_e, /*!< Relative noise level (exponent) */ - UCHAR sinePresentFlag, /*!< Indicates if sine is present on band */ - UCHAR sineMapped, /*!< Indicates if sine must be added */ - int noNoiseFlag) /*!< Flag to suppress noise addition */ +static void calcSubbandGain( + FIXP_DBL nrgRef, /*!< Reference Energy according to envelope data */ + SCHAR + nrgRef_e, /*!< Reference Energy according to envelope data (exponent) */ + ENV_CALC_NRGS *nrgs, int i, FIXP_DBL tmpNoise, /*!< Relative noise level */ + SCHAR tmpNoise_e, /*!< Relative noise level (exponent) */ + UCHAR sinePresentFlag, /*!< Indicates if sine is present on band */ + UCHAR sineMapped, /*!< Indicates if sine must be added */ + int noNoiseFlag) /*!< Flag to suppress noise addition */ { - FIXP_DBL nrgEst = nrgs->nrgEst[i]; /*!< Energy in transposed signal */ - SCHAR nrgEst_e = nrgs->nrgEst_e[i]; /*!< Energy in transposed signal (exponent) */ - FIXP_DBL *ptrNrgGain = &nrgs->nrgGain[i]; /*!< Resulting energy gain */ - SCHAR *ptrNrgGain_e = &nrgs->nrgGain_e[i]; /*!< Resulting energy gain (exponent) */ - FIXP_DBL *ptrNoiseLevel = &nrgs->noiseLevel[i]; /*!< Resulting absolute noise energy */ - SCHAR *ptrNoiseLevel_e = &nrgs->noiseLevel_e[i]; /*!< Resulting absolute noise energy (exponent) */ - FIXP_DBL *ptrNrgSine = &nrgs->nrgSine[i]; /*!< Additional sine energy */ - SCHAR *ptrNrgSine_e = &nrgs->nrgSine_e[i]; /*!< Additional sine energy (exponent) */ + FIXP_DBL nrgEst = nrgs->nrgEst[i]; /*!< Energy in transposed signal */ + SCHAR nrgEst_e = + nrgs->nrgEst_e[i]; /*!< Energy in transposed signal (exponent) */ + FIXP_DBL *ptrNrgGain = &nrgs->nrgGain[i]; /*!< Resulting energy gain */ + SCHAR *ptrNrgGain_e = + &nrgs->nrgGain_e[i]; /*!< Resulting energy gain (exponent) */ + FIXP_DBL *ptrNoiseLevel = + &nrgs->noiseLevel[i]; /*!< Resulting absolute noise energy */ + SCHAR *ptrNoiseLevel_e = + &nrgs->noiseLevel_e[i]; /*!< Resulting absolute noise energy (exponent) */ + FIXP_DBL *ptrNrgSine = &nrgs->nrgSine[i]; /*!< Additional sine energy */ + SCHAR *ptrNrgSine_e = + &nrgs->nrgSine_e[i]; /*!< Additional sine energy (exponent) */ FIXP_DBL a, b, c; - SCHAR a_e, b_e, c_e; + SCHAR a_e, b_e, c_e; /* This addition of 1 prevents divisions by zero in the reference code. @@ -1633,74 +2267,64 @@ static void calcSubbandGain(FIXP_DBL nrgRef, /*!< Reference Energy a very high which could cause some trouble due to the smoothing. */ b_e = (int)(nrgEst_e - 1); - if (b_e>=0) { - nrgEst = (FL2FXCONST_DBL(0.5f) >> (INT)fixMin(b_e+1,DFRACT_BITS-1)) + (nrgEst >> 1); - nrgEst_e += 1; /* shift by 1 bit to avoid overflow */ + if (b_e >= 0) { + nrgEst = (FL2FXCONST_DBL(0.5f) >> (INT)fixMin(b_e + 1, DFRACT_BITS - 1)) + + (nrgEst >> 1); + nrgEst_e += 1; /* shift by 1 bit to avoid overflow */ } else { - nrgEst = (nrgEst >> (INT)(fixMin(-b_e+1,DFRACT_BITS-1))) + (FL2FXCONST_DBL(0.5f) >> 1); - nrgEst_e = 2; /* shift by 1 bit to avoid overflow */ + nrgEst = (nrgEst >> (INT)(fixMin(-b_e + 1, DFRACT_BITS - 1))) + + (FL2FXCONST_DBL(0.5f) >> 1); + nrgEst_e = 2; /* shift by 1 bit to avoid overflow */ } /* A = NrgRef * TmpNoise */ - a = fMult(nrgRef,tmpNoise); + a = fMult(nrgRef, tmpNoise); a_e = nrgRef_e + tmpNoise_e; /* B = 1 + TmpNoise */ b_e = (int)(tmpNoise_e - 1); - if (b_e>=0) { - b = (FL2FXCONST_DBL(0.5f) >> (INT)fixMin(b_e+1,DFRACT_BITS-1)) + (tmpNoise >> 1); - b_e = tmpNoise_e + 1; /* shift by 1 bit to avoid overflow */ + if (b_e >= 0) { + b = (FL2FXCONST_DBL(0.5f) >> (INT)fixMin(b_e + 1, DFRACT_BITS - 1)) + + (tmpNoise >> 1); + b_e = tmpNoise_e + 1; /* shift by 1 bit to avoid overflow */ } else { - b = (tmpNoise >> (INT)(fixMin(-b_e+1,DFRACT_BITS-1))) + (FL2FXCONST_DBL(0.5f) >> 1); - b_e = 2; /* shift by 1 bit to avoid overflow */ + b = (tmpNoise >> (INT)(fixMin(-b_e + 1, DFRACT_BITS - 1))) + + (FL2FXCONST_DBL(0.5f) >> 1); + b_e = 2; /* shift by 1 bit to avoid overflow */ } /* noiseLevel = A / B = (NrgRef * TmpNoise) / (1 + TmpNoise) */ - FDK_divide_MantExp( a, a_e, - b, b_e, - ptrNoiseLevel, ptrNoiseLevel_e); + FDK_divide_MantExp(a, a_e, b, b_e, ptrNoiseLevel, ptrNoiseLevel_e); if (sinePresentFlag) { - /* C = (1 + TmpNoise) * NrgEst */ - c = fMult(b,nrgEst); + c = fMult(b, nrgEst); c_e = b_e + nrgEst_e; /* gain = A / C = (NrgRef * TmpNoise) / (1 + TmpNoise) * NrgEst */ - FDK_divide_MantExp( a, a_e, - c, c_e, - ptrNrgGain, ptrNrgGain_e); + FDK_divide_MantExp(a, a_e, c, c_e, ptrNrgGain, ptrNrgGain_e); if (sineMapped) { - /* sineLevel = nrgRef/ (1 + TmpNoise) */ - FDK_divide_MantExp( nrgRef, nrgRef_e, - b, b_e, - ptrNrgSine, ptrNrgSine_e); + FDK_divide_MantExp(nrgRef, nrgRef_e, b, b_e, ptrNrgSine, ptrNrgSine_e); } - } - else { + } else { if (noNoiseFlag) { /* B = NrgEst */ b = nrgEst; b_e = nrgEst_e; - } - else { + } else { /* B = NrgEst * (1 + TmpNoise) */ - b = fMult(b,nrgEst); + b = fMult(b, nrgEst); b_e = b_e + nrgEst_e; } - /* gain = nrgRef / B */ - FDK_divide_MantExp( nrgRef, nrgRef_e, - b, b_e, - ptrNrgGain, ptrNrgGain_e); + FDK_divide_MantExp(nrgRef, nrgRef_e, b, b_e, ptrNrgGain, ptrNrgGain_e); } } - /*! \brief Calculate "average gain" for the specified subband range. @@ -1709,121 +2333,140 @@ static void calcSubbandGain(FIXP_DBL nrgRef, /*!< Reference Energy a The result is used as a relative limit for all gains within the current "limiter band" (a certain frequency range). */ -static void calcAvgGain(ENV_CALC_NRGS* nrgs, - int lowSubband, /*!< Begin of the limiter band */ - int highSubband, /*!< High end of the limiter band */ - FIXP_DBL *ptrSumRef, - SCHAR *ptrSumRef_e, - FIXP_DBL *ptrAvgGain, /*!< Resulting overall gain (mantissa) */ - SCHAR *ptrAvgGain_e) /*!< Resulting overall gain (exponent) */ +static void calcAvgGain( + ENV_CALC_NRGS *nrgs, int lowSubband, /*!< Begin of the limiter band */ + int highSubband, /*!< High end of the limiter band */ + FIXP_DBL *ptrSumRef, SCHAR *ptrSumRef_e, + FIXP_DBL *ptrAvgGain, /*!< Resulting overall gain (mantissa) */ + SCHAR *ptrAvgGain_e) /*!< Resulting overall gain (exponent) */ { - FIXP_DBL *nrgRef = nrgs->nrgRef; /*!< Reference Energy according to envelope data */ - SCHAR *nrgRef_e = nrgs->nrgRef_e; /*!< Reference Energy according to envelope data (exponent) */ - FIXP_DBL *nrgEst = nrgs->nrgEst; /*!< Energy in transposed signal */ - SCHAR *nrgEst_e = nrgs->nrgEst_e; /*!< Energy in transposed signal (exponent) */ + FIXP_DBL *nrgRef = + nrgs->nrgRef; /*!< Reference Energy according to envelope data */ + SCHAR *nrgRef_e = + nrgs->nrgRef_e; /*!< Reference Energy according to envelope data + (exponent) */ + FIXP_DBL *nrgEst = nrgs->nrgEst; /*!< Energy in transposed signal */ + SCHAR *nrgEst_e = + nrgs->nrgEst_e; /*!< Energy in transposed signal (exponent) */ FIXP_DBL sumRef = 1; FIXP_DBL sumEst = 1; - SCHAR sumRef_e = -FRACT_BITS; - SCHAR sumEst_e = -FRACT_BITS; - int k; + SCHAR sumRef_e = -FRACT_BITS; + SCHAR sumEst_e = -FRACT_BITS; + int k; - for (k=lowSubband; k<highSubband; k++){ + for (k = lowSubband; k < highSubband; k++) { /* Add nrgRef[k] to sumRef: */ - FDK_add_MantExp( sumRef, sumRef_e, - nrgRef[k], nrgRef_e[k], - &sumRef, &sumRef_e ); + FDK_add_MantExp(sumRef, sumRef_e, nrgRef[k], nrgRef_e[k], &sumRef, + &sumRef_e); /* Add nrgEst[k] to sumEst: */ - FDK_add_MantExp( sumEst, sumEst_e, - nrgEst[k], nrgEst_e[k], - &sumEst, &sumEst_e ); + FDK_add_MantExp(sumEst, sumEst_e, nrgEst[k], nrgEst_e[k], &sumEst, + &sumEst_e); } - FDK_divide_MantExp(sumRef, sumRef_e, - sumEst, sumEst_e, - ptrAvgGain, ptrAvgGain_e); + FDK_divide_MantExp(sumRef, sumRef_e, sumEst, sumEst_e, ptrAvgGain, + ptrAvgGain_e); *ptrSumRef = sumRef; *ptrSumRef_e = sumRef_e; } static void adjustTimeSlot_EldGrid( - FIXP_DBL *ptrReal, /*!< Subband samples to be adjusted, real part */ - ENV_CALC_NRGS* nrgs, - UCHAR *ptrHarmIndex, /*!< Harmonic index */ - int lowSubband, /*!< Lowest QMF-channel in the currently used SBR range. */ - int noSubbands, /*!< Number of QMF subbands */ - int scale_change, /*!< Number of bits to shift adjusted samples */ - int noNoiseFlag, /*!< Flag to suppress noise addition */ - int *ptrPhaseIndex, /*!< Start index to random number array */ - int scale_diff_low) /*!< */ + FIXP_DBL *RESTRICT + ptrReal, /*!< Subband samples to be adjusted, real part */ + ENV_CALC_NRGS *nrgs, UCHAR *ptrHarmIndex, /*!< Harmonic index */ + int lowSubband, /*!< Lowest QMF-channel in the currently used SBR range. */ + int noSubbands, /*!< Number of QMF subbands */ + int scale_change, /*!< Number of bits to shift adjusted samples */ + int noNoiseFlag, /*!< Flag to suppress noise addition */ + int *ptrPhaseIndex, /*!< Start index to random number array */ + int scale_diff_low) /*!< */ + { int k; - FIXP_DBL signalReal, sbNoise; + FIXP_DBL signalReal, sbNoise; int tone_count = 0; - FIXP_DBL *pGain = nrgs->nrgGain; /*!< Gains of current envelope */ - FIXP_DBL *pNoiseLevel = nrgs->noiseLevel; /*!< Noise levels of current envelope */ - FIXP_DBL *pSineLevel = nrgs->nrgSine; /*!< Sine levels */ - - int phaseIndex = *ptrPhaseIndex; - UCHAR harmIndex = *ptrHarmIndex; - - static const INT harmonicPhase [2][4] = { - { 1, 0, -1, 0}, - { 0, 1, 0, -1} - }; - - static const FIXP_DBL harmonicPhaseX [2][4] = { - { FL2FXCONST_DBL(2.0*1.245183154539139e-001), FL2FXCONST_DBL(2.0*-1.123767859325028e-001), FL2FXCONST_DBL(2.0*-1.245183154539139e-001), FL2FXCONST_DBL(2.0* 1.123767859325028e-001) }, - { FL2FXCONST_DBL(2.0*1.245183154539139e-001), FL2FXCONST_DBL(2.0* 1.123767859325028e-001), FL2FXCONST_DBL(2.0*-1.245183154539139e-001), FL2FXCONST_DBL(2.0*-1.123767859325028e-001) } - }; + FIXP_DBL *pGain = nrgs->nrgGain; /*!< Gains of current envelope */ + FIXP_DBL *RESTRICT pNoiseLevel = + nrgs->noiseLevel; /*!< Noise levels of current envelope */ + FIXP_DBL *RESTRICT pSineLevel = nrgs->nrgSine; /*!< Sine levels */ - for (k=0; k < noSubbands; k++) { + int phaseIndex = *ptrPhaseIndex; + UCHAR harmIndex = *ptrHarmIndex; - phaseIndex = (phaseIndex + 1) & (SBR_NF_NO_RANDOM_VAL - 1); + static const INT harmonicPhase[4][2] = {{1, 0}, {0, 1}, {-1, 0}, {0, -1}}; - if( (pSineLevel[0] != FL2FXCONST_DBL(0.0f)) || (noNoiseFlag == 1) ){ - sbNoise = FL2FXCONST_DBL(0.0f); - } else { - sbNoise = pNoiseLevel[0]; - } + static const FIXP_DBL harmonicPhaseX[4][2] = { + {FL2FXCONST_DBL(2.0 * 1.245183154539139e-001), + FL2FXCONST_DBL(2.0 * 1.245183154539139e-001)}, + {FL2FXCONST_DBL(2.0 * -1.123767859325028e-001), + FL2FXCONST_DBL(2.0 * 1.123767859325028e-001)}, + {FL2FXCONST_DBL(2.0 * -1.245183154539139e-001), + FL2FXCONST_DBL(2.0 * -1.245183154539139e-001)}, + {FL2FXCONST_DBL(2.0 * 1.123767859325028e-001), + FL2FXCONST_DBL(2.0 * -1.123767859325028e-001)}}; - signalReal = fMultDiv2(*ptrReal,*pGain) << ((int)scale_change); + const FIXP_DBL *p_harmonicPhaseX = &harmonicPhaseX[harmIndex][0]; + const INT *p_harmonicPhase = &harmonicPhase[harmIndex][0]; - signalReal += (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[phaseIndex][0], sbNoise)<<4); + *(ptrReal - 1) = fAddSaturate( + *(ptrReal - 1), + SATURATE_SHIFT(fMultDiv2(p_harmonicPhaseX[lowSubband & 1], pSineLevel[0]), + scale_diff_low, DFRACT_BITS)); + FIXP_DBL pSineLevel_prev = (FIXP_DBL)0; - signalReal += pSineLevel[0] * harmonicPhase[0][harmIndex]; + int idx_k = lowSubband & 1; - *ptrReal = signalReal; + for (k = 0; k < noSubbands; k++) { + FIXP_DBL sineLevel_curr = *pSineLevel++; + phaseIndex = (phaseIndex + 1) & (SBR_NF_NO_RANDOM_VAL - 1); - if (k == 0) { - *(ptrReal-1) += scaleValue(fMultDiv2(harmonicPhaseX[lowSubband&1][harmIndex], pSineLevel[0]), -scale_diff_low) ; - if (k < noSubbands - 1) { - *(ptrReal) += fMultDiv2(pSineLevel[1], harmonicPhaseX[(lowSubband+1)&1][harmIndex]); - } + signalReal = fMultDiv2(*ptrReal, *pGain++) << ((int)scale_change); + sbNoise = *pNoiseLevel++; + if (((INT)sineLevel_curr | noNoiseFlag) == 0) { + signalReal += + (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[phaseIndex][0], sbNoise) + << 4); } - if (k > 0 && k < noSubbands - 1 && tone_count < 16) { - *(ptrReal) += fMultDiv2(pSineLevel[- 1], harmonicPhaseX [(lowSubband+k)&1] [harmIndex]); - *(ptrReal) += fMultDiv2(pSineLevel[+ 1], harmonicPhaseX [(lowSubband+k+1)&1][harmIndex]); - } - if (k == noSubbands - 1 && tone_count < 16) { - if (k > 0) { - *(ptrReal) += fMultDiv2(pSineLevel[- 1], harmonicPhaseX [(lowSubband+k)&1][harmIndex]); + signalReal += sineLevel_curr * p_harmonicPhase[0]; + signalReal = + fMultAddDiv2(signalReal, pSineLevel_prev, p_harmonicPhaseX[idx_k]); + pSineLevel_prev = sineLevel_curr; + idx_k = !idx_k; + if (k < noSubbands - 1) { + signalReal = + fMultAddDiv2(signalReal, pSineLevel[0], p_harmonicPhaseX[idx_k]); + } else /* (k == noSubbands - 1) */ + { + if (k + lowSubband + 1 < 63) { + *(ptrReal + 1) += fMultDiv2(pSineLevel_prev, p_harmonicPhaseX[idx_k]); } - if (k + lowSubband + 1< 63) { - *(ptrReal+1) += fMultDiv2(pSineLevel[0], harmonicPhaseX[(lowSubband+k+1)&1][harmIndex]); + } + *ptrReal++ = signalReal; + + if (pSineLevel_prev != FL2FXCONST_DBL(0.0f)) { + if (++tone_count == 16) { + k++; + break; } } + } + /* Run again, if previous loop got breaked with tone_count = 16 */ + for (; k < noSubbands; k++) { + FIXP_DBL sineLevel_curr = *pSineLevel++; + phaseIndex = (phaseIndex + 1) & (SBR_NF_NO_RANDOM_VAL - 1); - if(pSineLevel[0] != FL2FXCONST_DBL(0.0f)){ - tone_count++; + signalReal = fMultDiv2(*ptrReal, *pGain++) << ((int)scale_change); + sbNoise = *pNoiseLevel++; + if (((INT)sineLevel_curr | noNoiseFlag) == 0) { + signalReal += + (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[phaseIndex][0], sbNoise) + << 4); } - ptrReal++; - pNoiseLevel++; - pGain++; - pSineLevel++; + signalReal += sineLevel_curr * p_harmonicPhase[0]; + *ptrReal++ = signalReal; } *ptrHarmIndex = (harmIndex + 1) & 3; @@ -1835,29 +2478,30 @@ static void adjustTimeSlot_EldGrid( and add the noisefloor. */ -static void adjustTimeSlotLC(FIXP_DBL *ptrReal, /*!< Subband samples to be adjusted, real part */ - ENV_CALC_NRGS* nrgs, - UCHAR *ptrHarmIndex, /*!< Harmonic index */ - int lowSubband, /*!< Lowest QMF-channel in the currently used SBR range. */ - int noSubbands, /*!< Number of QMF subbands */ - int scale_change, /*!< Number of bits to shift adjusted samples */ - int noNoiseFlag, /*!< Flag to suppress noise addition */ - int *ptrPhaseIndex) /*!< Start index to random number array */ +static void adjustTimeSlotLC( + FIXP_DBL *ptrReal, /*!< Subband samples to be adjusted, real part */ + ENV_CALC_NRGS *nrgs, UCHAR *ptrHarmIndex, /*!< Harmonic index */ + int lowSubband, /*!< Lowest QMF-channel in the currently used SBR range. */ + int noSubbands, /*!< Number of QMF subbands */ + int scale_change, /*!< Number of bits to shift adjusted samples */ + int noNoiseFlag, /*!< Flag to suppress noise addition */ + int *ptrPhaseIndex) /*!< Start index to random number array */ { - FIXP_DBL *pGain = nrgs->nrgGain; /*!< Gains of current envelope */ - FIXP_DBL *pNoiseLevel = nrgs->noiseLevel; /*!< Noise levels of current envelope */ - FIXP_DBL *pSineLevel = nrgs->nrgSine; /*!< Sine levels */ + FIXP_DBL *pGain = nrgs->nrgGain; /*!< Gains of current envelope */ + FIXP_DBL *pNoiseLevel = + nrgs->noiseLevel; /*!< Noise levels of current envelope */ + FIXP_DBL *pSineLevel = nrgs->nrgSine; /*!< Sine levels */ - int k; - int index = *ptrPhaseIndex; - UCHAR harmIndex = *ptrHarmIndex; - UCHAR freqInvFlag = (lowSubband & 1); - FIXP_DBL signalReal, sineLevel, sineLevelNext, sineLevelPrev; - int tone_count = 0; - int sineSign = 1; + int k; + int index = *ptrPhaseIndex; + UCHAR harmIndex = *ptrHarmIndex; + UCHAR freqInvFlag = (lowSubband & 1); + FIXP_DBL signalReal, sineLevel, sineLevelNext, sineLevelPrev; + int tone_count = 0; + int sineSign = 1; - #define C1 ((FIXP_SGL)FL2FXCONST_SGL(2.f*0.00815f)) - #define C1_CLDFB ((FIXP_SGL)FL2FXCONST_SGL(2.f*0.16773f)) +#define C1 ((FIXP_SGL)FL2FXCONST_SGL(2.f * 0.00815f)) +#define C1_CLDFB ((FIXP_SGL)FL2FXCONST_SGL(2.f * 0.16773f)) /* First pass for k=0 pulled out of the loop: @@ -1870,38 +2514,40 @@ static void adjustTimeSlotLC(FIXP_DBL *ptrReal, /*!< Subband samples to be of the signal and should be carried out with full accuracy (supplying #FRACT_BITS valid bits). */ - signalReal = fMultDiv2(*ptrReal,*pGain++) << ((int)scale_change); - sineLevel = *pSineLevel++; + signalReal = fMultDiv2(*ptrReal, *pGain++) << ((int)scale_change); + sineLevel = *pSineLevel++; sineLevelNext = (noSubbands > 1) ? pSineLevel[0] : FL2FXCONST_DBL(0.0f); - if (sineLevel!=FL2FXCONST_DBL(0.0f)) tone_count++; + if (sineLevel != FL2FXCONST_DBL(0.0f)) + tone_count++; else if (!noNoiseFlag) - /* Add noisefloor to the amplified signal */ - signalReal += (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], pNoiseLevel[0])<<4); + /* Add noisefloor to the amplified signal */ + signalReal += + (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], pNoiseLevel[0]) + << 4); { - if (!(harmIndex&0x1)) { + if (!(harmIndex & 0x1)) { /* harmIndex 0,2 */ - signalReal += (harmIndex&0x2) ? -sineLevel : sineLevel; + signalReal += (harmIndex & 0x2) ? -sineLevel : sineLevel; *ptrReal++ = signalReal; - } - else { + } else { /* harmIndex 1,3 in combination with freqInvFlag */ - int shift = (int) (scale_change+1); - shift = (shift>=0) ? fixMin(DFRACT_BITS-1,shift) : fixMax(-(DFRACT_BITS-1),shift); + int shift = (int)(scale_change + 1); + shift = (shift >= 0) ? fixMin(DFRACT_BITS - 1, shift) + : fixMax(-(DFRACT_BITS - 1), shift); - FIXP_DBL tmp1 = (shift>=0) ? ( fMultDiv2(C1, sineLevel) >> shift ) - : ( fMultDiv2(C1, sineLevel) << (-shift) ); + FIXP_DBL tmp1 = (shift >= 0) ? (fMultDiv2(C1, sineLevel) >> shift) + : (fMultDiv2(C1, sineLevel) << (-shift)); FIXP_DBL tmp2 = fMultDiv2(C1, sineLevelNext); - /* save switch and compare operations and reduce to XOR statement */ - if ( ((harmIndex>>1)&0x1)^freqInvFlag) { - *(ptrReal-1) += tmp1; - signalReal -= tmp2; + if (((harmIndex >> 1) & 0x1) ^ freqInvFlag) { + *(ptrReal - 1) += tmp1; + signalReal -= tmp2; } else { - *(ptrReal-1) -= tmp1; - signalReal += tmp2; + *(ptrReal - 1) -= tmp1; + signalReal += tmp2; } *ptrReal++ = signalReal; freqInvFlag = !freqInvFlag; @@ -1910,45 +2556,51 @@ static void adjustTimeSlotLC(FIXP_DBL *ptrReal, /*!< Subband samples to be pNoiseLevel++; - if ( noSubbands > 2 ) { - if (!(harmIndex&0x1)) { + if (noSubbands > 2) { + if (!(harmIndex & 0x1)) { /* harmIndex 0,2 */ - if(!harmIndex) - { + if (!harmIndex) { sineSign = 0; } - for (k=noSubbands-2; k!=0; k--) { + for (k = noSubbands - 2; k != 0; k--) { FIXP_DBL sinelevel = *pSineLevel++; index++; - if (((signalReal = (sineSign ? -sinelevel : sinelevel)) == FL2FXCONST_DBL(0.0f)) && !noNoiseFlag) - { + if (((signalReal = (sineSign ? -sinelevel : sinelevel)) == + FL2FXCONST_DBL(0.0f)) && + !noNoiseFlag) { /* Add noisefloor to the amplified signal */ index &= (SBR_NF_NO_RANDOM_VAL - 1); - signalReal += (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], pNoiseLevel[0])<<4); + signalReal += (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], + pNoiseLevel[0]) + << 4); } - - /* The next multiplication constitutes the actual envelope adjustment of the signal. */ - signalReal += fMultDiv2(*ptrReal,*pGain++) << ((int)scale_change); + + /* The next multiplication constitutes the actual envelope adjustment of + * the signal. */ + signalReal += fMultDiv2(*ptrReal, *pGain++) << ((int)scale_change); pNoiseLevel++; *ptrReal++ = signalReal; } /* for ... */ - } - else { + } else { /* harmIndex 1,3 in combination with freqInvFlag */ - if (harmIndex==1) freqInvFlag = !freqInvFlag; + if (harmIndex == 1) freqInvFlag = !freqInvFlag; - for (k=noSubbands-2; k!=0; k--) { + for (k = noSubbands - 2; k != 0; k--) { index++; - /* The next multiplication constitutes the actual envelope adjustment of the signal. */ - signalReal = fMultDiv2(*ptrReal,*pGain++) << ((int)scale_change); + /* The next multiplication constitutes the actual envelope adjustment of + * the signal. */ + signalReal = fMultDiv2(*ptrReal, *pGain++) << ((int)scale_change); - if (*pSineLevel++!=FL2FXCONST_DBL(0.0f)) tone_count++; + if (*pSineLevel++ != FL2FXCONST_DBL(0.0f)) + tone_count++; else if (!noNoiseFlag) { /* Add noisefloor to the amplified signal */ index &= (SBR_NF_NO_RANDOM_VAL - 1); - signalReal += (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], pNoiseLevel[0])<<4); + signalReal += (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], + pNoiseLevel[0]) + << 4); } pNoiseLevel++; @@ -1966,76 +2618,247 @@ static void adjustTimeSlotLC(FIXP_DBL *ptrReal, /*!< Subband samples to be if (noSubbands > -1) { index++; - /* The next multiplication constitutes the actual envelope adjustment of the signal. */ - signalReal = fMultDiv2(*ptrReal,*pGain) << ((int)scale_change); - sineLevelPrev = fMultDiv2(pSineLevel[-1],FL2FX_SGL(0.0163f)); - sineLevel = pSineLevel[0]; + /* The next multiplication constitutes the actual envelope adjustment of the + * signal. */ + signalReal = fMultDiv2(*ptrReal, *pGain) << ((int)scale_change); + sineLevelPrev = fMultDiv2(pSineLevel[-1], FL2FX_SGL(0.0163f)); + sineLevel = pSineLevel[0]; - if (pSineLevel[0]!=FL2FXCONST_DBL(0.0f)) tone_count++; + if (pSineLevel[0] != FL2FXCONST_DBL(0.0f)) + tone_count++; else if (!noNoiseFlag) { - /* Add noisefloor to the amplified signal */ - index &= (SBR_NF_NO_RANDOM_VAL - 1); - signalReal = signalReal + (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], pNoiseLevel[0])<<4); + /* Add noisefloor to the amplified signal */ + index &= (SBR_NF_NO_RANDOM_VAL - 1); + signalReal = + signalReal + + (fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], pNoiseLevel[0]) + << 4); } - if (!(harmIndex&0x1)) { + if (!(harmIndex & 0x1)) { /* harmIndex 0,2 */ - *ptrReal = signalReal + ( (sineSign) ? -sineLevel : sineLevel); - } - else { + *ptrReal = signalReal + ((sineSign) ? -sineLevel : sineLevel); + } else { /* harmIndex 1,3 in combination with freqInvFlag */ - if(tone_count <= 16){ + if (tone_count <= 16) { if (freqInvFlag) { - *ptrReal++ = signalReal - sineLevelPrev; + *ptrReal++ = signalReal - sineLevelPrev; if (noSubbands + lowSubband < 63) *ptrReal = *ptrReal + fMultDiv2(C1, sineLevel); - } - else { + } else { *ptrReal++ = signalReal + sineLevelPrev; if (noSubbands + lowSubband < 63) *ptrReal = *ptrReal - fMultDiv2(C1, sineLevel); } - } - else *ptrReal = signalReal; + } else + *ptrReal = signalReal; } } *ptrHarmIndex = (harmIndex + 1) & 3; *ptrPhaseIndex = index & (SBR_NF_NO_RANDOM_VAL - 1); } -static void adjustTimeSlotHQ( - FIXP_DBL *RESTRICT ptrReal, /*!< Subband samples to be adjusted, real part */ - FIXP_DBL *RESTRICT ptrImag, /*!< Subband samples to be adjusted, imag part */ - HANDLE_SBR_CALCULATE_ENVELOPE h_sbr_cal_env, - ENV_CALC_NRGS* nrgs, - int lowSubband, /*!< Lowest QMF-channel in the currently used SBR range. */ - int noSubbands, /*!< Number of QMF subbands */ - int scale_change, /*!< Number of bits to shift adjusted samples */ - FIXP_SGL smooth_ratio, /*!< Impact of last envelope */ - int noNoiseFlag, /*!< Start index to random number array */ - int filtBufferNoiseShift) /*!< Shift factor of filtBufferNoise */ + +static void adjustTimeSlotHQ_GainAndNoise( + FIXP_DBL *RESTRICT + ptrReal, /*!< Subband samples to be adjusted, real part */ + FIXP_DBL *RESTRICT + ptrImag, /*!< Subband samples to be adjusted, imag part */ + HANDLE_SBR_CALCULATE_ENVELOPE h_sbr_cal_env, ENV_CALC_NRGS *nrgs, + int lowSubband, /*!< Lowest QMF-channel in the currently used SBR range. */ + int noSubbands, /*!< Number of QMF subbands */ + int scale_change, /*!< Number of bits to shift adjusted samples */ + FIXP_SGL smooth_ratio, /*!< Impact of last envelope */ + int noNoiseFlag, /*!< Start index to random number array */ + int filtBufferNoiseShift) /*!< Shift factor of filtBufferNoise */ { + FIXP_DBL *RESTRICT gain = nrgs->nrgGain; /*!< Gains of current envelope */ + FIXP_DBL *RESTRICT noiseLevel = + nrgs->noiseLevel; /*!< Noise levels of current envelope */ + FIXP_DBL *RESTRICT pSineLevel = nrgs->nrgSine; /*!< Sine levels */ + + FIXP_DBL *RESTRICT filtBuffer = + h_sbr_cal_env->filtBuffer; /*!< Gains of last envelope */ + FIXP_DBL *RESTRICT filtBufferNoise = + h_sbr_cal_env->filtBufferNoise; /*!< Noise levels of last envelope */ + int *RESTRICT ptrPhaseIndex = + &h_sbr_cal_env->phaseIndex; /*!< Start index to random number array */ + + int k; + FIXP_DBL signalReal, signalImag; + FIXP_DBL noiseReal, noiseImag; + FIXP_DBL smoothedGain, smoothedNoise; + FIXP_SGL direct_ratio = + /*FL2FXCONST_SGL(1.0f) */ (FIXP_SGL)MAXVAL_SGL - smooth_ratio; + int index = *ptrPhaseIndex; + int shift; - FIXP_DBL *RESTRICT gain = nrgs->nrgGain; /*!< Gains of current envelope */ - FIXP_DBL *RESTRICT noiseLevel = nrgs->noiseLevel; /*!< Noise levels of current envelope */ - FIXP_DBL *RESTRICT pSineLevel = nrgs->nrgSine; /*!< Sine levels */ + *ptrPhaseIndex = (index + noSubbands) & (SBR_NF_NO_RANDOM_VAL - 1); - FIXP_DBL *RESTRICT filtBuffer = h_sbr_cal_env->filtBuffer; /*!< Gains of last envelope */ - FIXP_DBL *RESTRICT filtBufferNoise = h_sbr_cal_env->filtBufferNoise; /*!< Noise levels of last envelope */ - UCHAR *RESTRICT ptrHarmIndex =&h_sbr_cal_env->harmIndex; /*!< Harmonic index */ - int *RESTRICT ptrPhaseIndex =&h_sbr_cal_env->phaseIndex; /*!< Start index to random number array */ + filtBufferNoiseShift += + 1; /* due to later use of fMultDiv2 instead of fMult */ + if (filtBufferNoiseShift < 0) { + shift = fixMin(DFRACT_BITS - 1, -filtBufferNoiseShift); + } else { + shift = fixMin(DFRACT_BITS - 1, filtBufferNoiseShift); + } - int k; + if (smooth_ratio > FL2FXCONST_SGL(0.0f)) { + for (k = 0; k < noSubbands; k++) { + /* + Smoothing: The old envelope has been bufferd and a certain ratio + of the old gains and noise levels is used. + */ + smoothedGain = + fMult(smooth_ratio, filtBuffer[k]) + fMult(direct_ratio, gain[k]); + + if (filtBufferNoiseShift < 0) { + smoothedNoise = (fMultDiv2(smooth_ratio, filtBufferNoise[k]) >> shift) + + fMult(direct_ratio, noiseLevel[k]); + } else { + smoothedNoise = (fMultDiv2(smooth_ratio, filtBufferNoise[k]) << shift) + + fMult(direct_ratio, noiseLevel[k]); + } + + /* + The next 2 multiplications constitute the actual envelope adjustment + of the signal and should be carried out with full accuracy + (supplying #DFRACT_BITS valid bits). + */ + signalReal = fMultDiv2(*ptrReal, smoothedGain) << ((int)scale_change); + signalImag = fMultDiv2(*ptrImag, smoothedGain) << ((int)scale_change); + + index++; + + if ((pSineLevel[k] != FL2FXCONST_DBL(0.0f)) || noNoiseFlag) { + /* Just the amplified signal is saved */ + *ptrReal++ = signalReal; + *ptrImag++ = signalImag; + } else { + /* Add noisefloor to the amplified signal */ + index &= (SBR_NF_NO_RANDOM_VAL - 1); + noiseReal = + fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], smoothedNoise) + << 4; + noiseImag = + fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][1], smoothedNoise) + << 4; + *ptrReal++ = (signalReal + noiseReal); + *ptrImag++ = (signalImag + noiseImag); + } + } + } else { + for (k = 0; k < noSubbands; k++) { + smoothedGain = gain[k]; + signalReal = fMultDiv2(*ptrReal, smoothedGain) << scale_change; + signalImag = fMultDiv2(*ptrImag, smoothedGain) << scale_change; + + index++; + + if ((pSineLevel[k] == FL2FXCONST_DBL(0.0f)) && (noNoiseFlag == 0)) { + /* Add noisefloor to the amplified signal */ + smoothedNoise = noiseLevel[k]; + index &= (SBR_NF_NO_RANDOM_VAL - 1); + noiseReal = + fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], smoothedNoise); + noiseImag = + fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][1], smoothedNoise); + + /* FDK_sbrDecoder_sbr_randomPhase is downscaled by 2^3 */ + signalReal += noiseReal << 4; + signalImag += noiseImag << 4; + } + *ptrReal++ = signalReal; + *ptrImag++ = signalImag; + } + } +} + +static void adjustTimeSlotHQ_AddHarmonics( + FIXP_DBL *RESTRICT + ptrReal, /*!< Subband samples to be adjusted, real part */ + FIXP_DBL *RESTRICT + ptrImag, /*!< Subband samples to be adjusted, imag part */ + HANDLE_SBR_CALCULATE_ENVELOPE h_sbr_cal_env, ENV_CALC_NRGS *nrgs, + int lowSubband, /*!< Lowest QMF-channel in the currently used SBR range. */ + int noSubbands, /*!< Number of QMF subbands */ + int scale_change /*!< Scale mismatch between QMF input and sineLevel + exponent. */ +) { + FIXP_DBL *RESTRICT pSineLevel = nrgs->nrgSine; /*!< Sine levels */ + UCHAR *RESTRICT ptrHarmIndex = + &h_sbr_cal_env->harmIndex; /*!< Harmonic index */ + + int k; + FIXP_DBL signalReal, signalImag; + UCHAR harmIndex = *ptrHarmIndex; + int freqInvFlag = (lowSubband & 1); + FIXP_DBL sineLevel; + + *ptrHarmIndex = (harmIndex + 1) & 3; + + for (k = 0; k < noSubbands; k++) { + sineLevel = pSineLevel[k]; + freqInvFlag ^= 1; + if (sineLevel != FL2FXCONST_DBL(0.f)) { + signalReal = ptrReal[k]; + signalImag = ptrImag[k]; + sineLevel = scaleValue(sineLevel, scale_change); + if (harmIndex & 2) { + /* case 2,3 */ + sineLevel = -sineLevel; + } + if (!(harmIndex & 1)) { + /* case 0,2: */ + ptrReal[k] = signalReal + sineLevel; + } else { + /* case 1,3 */ + if (!freqInvFlag) sineLevel = -sineLevel; + ptrImag[k] = signalImag + sineLevel; + } + } + } +} + +static void adjustTimeSlotHQ( + FIXP_DBL *RESTRICT + ptrReal, /*!< Subband samples to be adjusted, real part */ + FIXP_DBL *RESTRICT + ptrImag, /*!< Subband samples to be adjusted, imag part */ + HANDLE_SBR_CALCULATE_ENVELOPE h_sbr_cal_env, ENV_CALC_NRGS *nrgs, + int lowSubband, /*!< Lowest QMF-channel in the currently used SBR range. */ + int noSubbands, /*!< Number of QMF subbands */ + int scale_change, /*!< Number of bits to shift adjusted samples */ + FIXP_SGL smooth_ratio, /*!< Impact of last envelope */ + int noNoiseFlag, /*!< Start index to random number array */ + int filtBufferNoiseShift) /*!< Shift factor of filtBufferNoise */ +{ + FIXP_DBL *RESTRICT gain = nrgs->nrgGain; /*!< Gains of current envelope */ + FIXP_DBL *RESTRICT noiseLevel = + nrgs->noiseLevel; /*!< Noise levels of current envelope */ + FIXP_DBL *RESTRICT pSineLevel = nrgs->nrgSine; /*!< Sine levels */ + + FIXP_DBL *RESTRICT filtBuffer = + h_sbr_cal_env->filtBuffer; /*!< Gains of last envelope */ + FIXP_DBL *RESTRICT filtBufferNoise = + h_sbr_cal_env->filtBufferNoise; /*!< Noise levels of last envelope */ + UCHAR *RESTRICT ptrHarmIndex = + &h_sbr_cal_env->harmIndex; /*!< Harmonic index */ + int *RESTRICT ptrPhaseIndex = + &h_sbr_cal_env->phaseIndex; /*!< Start index to random number array */ + + int k; FIXP_DBL signalReal, signalImag; - FIXP_DBL noiseReal, noiseImag; - FIXP_DBL smoothedGain, smoothedNoise; - FIXP_SGL direct_ratio = /*FL2FXCONST_SGL(1.0f) */ (FIXP_SGL)MAXVAL_SGL - smooth_ratio; - int index = *ptrPhaseIndex; - UCHAR harmIndex = *ptrHarmIndex; + FIXP_DBL noiseReal, noiseImag; + FIXP_DBL smoothedGain, smoothedNoise; + FIXP_SGL direct_ratio = + /*FL2FXCONST_SGL(1.0f) */ (FIXP_SGL)MAXVAL_SGL - smooth_ratio; + int index = *ptrPhaseIndex; + UCHAR harmIndex = *ptrHarmIndex; int freqInvFlag = (lowSubband & 1); FIXP_DBL sineLevel; int shift; - *ptrPhaseIndex = (index+noSubbands) & (SBR_NF_NO_RANDOM_VAL - 1); + *ptrPhaseIndex = (index + noSubbands) & (SBR_NF_NO_RANDOM_VAL - 1); *ptrHarmIndex = (harmIndex + 1) & 3; /* @@ -2047,30 +2870,29 @@ static void adjustTimeSlotHQ( of the whole function decreased by about 20 % */ - filtBufferNoiseShift += 1; /* due to later use of fMultDiv2 instead of fMult */ - if (filtBufferNoiseShift<0) - shift = fixMin(DFRACT_BITS-1,-filtBufferNoiseShift); + filtBufferNoiseShift += + 1; /* due to later use of fMultDiv2 instead of fMult */ + if (filtBufferNoiseShift < 0) + shift = fixMin(DFRACT_BITS - 1, -filtBufferNoiseShift); else - shift = fixMin(DFRACT_BITS-1, filtBufferNoiseShift); + shift = fixMin(DFRACT_BITS - 1, filtBufferNoiseShift); if (smooth_ratio > FL2FXCONST_SGL(0.0f)) { - - for (k=0; k<noSubbands; k++) { + for (k = 0; k < noSubbands; k++) { /* Smoothing: The old envelope has been bufferd and a certain ratio of the old gains and noise levels is used. */ - smoothedGain = fMult(smooth_ratio,filtBuffer[k]) + - fMult(direct_ratio,gain[k]); + smoothedGain = + fMult(smooth_ratio, filtBuffer[k]) + fMult(direct_ratio, gain[k]); - if (filtBufferNoiseShift<0) { - smoothedNoise = (fMultDiv2(smooth_ratio,filtBufferNoise[k])>>shift) + - fMult(direct_ratio,noiseLevel[k]); - } - else { - smoothedNoise = (fMultDiv2(smooth_ratio,filtBufferNoise[k])<<shift) + - fMult(direct_ratio,noiseLevel[k]); + if (filtBufferNoiseShift < 0) { + smoothedNoise = (fMultDiv2(smooth_ratio, filtBufferNoise[k]) >> shift) + + fMult(direct_ratio, noiseLevel[k]); + } else { + smoothedNoise = (fMultDiv2(smooth_ratio, filtBufferNoise[k]) << shift) + + fMult(direct_ratio, noiseLevel[k]); } /* @@ -2078,50 +2900,53 @@ static void adjustTimeSlotHQ( of the signal and should be carried out with full accuracy (supplying #DFRACT_BITS valid bits). */ - signalReal = fMultDiv2(*ptrReal,smoothedGain)<<((int)scale_change); - signalImag = fMultDiv2(*ptrImag,smoothedGain)<<((int)scale_change); + signalReal = fMultDiv2(*ptrReal, smoothedGain) << ((int)scale_change); + signalImag = fMultDiv2(*ptrImag, smoothedGain) << ((int)scale_change); index++; if (pSineLevel[k] != FL2FXCONST_DBL(0.0f)) { sineLevel = pSineLevel[k]; - switch(harmIndex) { - case 0: - *ptrReal++ = (signalReal + sineLevel); - *ptrImag++ = (signalImag); - break; - case 2: - *ptrReal++ = (signalReal - sineLevel); - *ptrImag++ = (signalImag); - break; - case 1: - *ptrReal++ = (signalReal); - if (freqInvFlag) - *ptrImag++ = (signalImag - sineLevel); - else - *ptrImag++ = (signalImag + sineLevel); - break; - case 3: - *ptrReal++ = signalReal; - if (freqInvFlag) - *ptrImag++ = (signalImag + sineLevel); - else - *ptrImag++ = (signalImag - sineLevel); - break; + switch (harmIndex) { + case 0: + *ptrReal++ = (signalReal + sineLevel); + *ptrImag++ = (signalImag); + break; + case 2: + *ptrReal++ = (signalReal - sineLevel); + *ptrImag++ = (signalImag); + break; + case 1: + *ptrReal++ = (signalReal); + if (freqInvFlag) + *ptrImag++ = (signalImag - sineLevel); + else + *ptrImag++ = (signalImag + sineLevel); + break; + case 3: + *ptrReal++ = signalReal; + if (freqInvFlag) + *ptrImag++ = (signalImag + sineLevel); + else + *ptrImag++ = (signalImag - sineLevel); + break; } - } - else { + } else { if (noNoiseFlag) { /* Just the amplified signal is saved */ *ptrReal++ = (signalReal); *ptrImag++ = (signalImag); - } - else { + } else { /* Add noisefloor to the amplified signal */ index &= (SBR_NF_NO_RANDOM_VAL - 1); - noiseReal = fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], smoothedNoise)<<4; - noiseImag = fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][1], smoothedNoise)<<4; + /* FDK_sbrDecoder_sbr_randomPhase is downscaled by 2^3 */ + noiseReal = + fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], smoothedNoise) + << 4; + noiseImag = + fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][1], smoothedNoise) + << 4; *ptrReal++ = (signalReal + noiseReal); *ptrImag++ = (signalImag + noiseImag); } @@ -2129,52 +2954,48 @@ static void adjustTimeSlotHQ( freqInvFlag ^= 1; } - } - else - { - for (k=0; k<noSubbands; k++) - { - smoothedGain = gain[k]; + } else { + for (k = 0; k < noSubbands; k++) { + smoothedGain = gain[k]; signalReal = fMultDiv2(*ptrReal, smoothedGain) << scale_change; signalImag = fMultDiv2(*ptrImag, smoothedGain) << scale_change; index++; - if ((sineLevel = pSineLevel[k]) != FL2FXCONST_DBL(0.0f)) - { - switch (harmIndex) - { - case 0: - signalReal += sineLevel; - break; - case 1: - if (freqInvFlag) - signalImag -= sineLevel; - else - signalImag += sineLevel; - break; - case 2: - signalReal -= sineLevel; - break; - case 3: - if (freqInvFlag) - signalImag += sineLevel; - else - signalImag -= sineLevel; - break; + if ((sineLevel = pSineLevel[k]) != FL2FXCONST_DBL(0.0f)) { + switch (harmIndex) { + case 0: + signalReal += sineLevel; + break; + case 1: + if (freqInvFlag) + signalImag -= sineLevel; + else + signalImag += sineLevel; + break; + case 2: + signalReal -= sineLevel; + break; + case 3: + if (freqInvFlag) + signalImag += sineLevel; + else + signalImag -= sineLevel; + break; } - } - else - { - if (noNoiseFlag == 0) - { + } else { + if (noNoiseFlag == 0) { /* Add noisefloor to the amplified signal */ smoothedNoise = noiseLevel[k]; index &= (SBR_NF_NO_RANDOM_VAL - 1); - noiseReal = fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], smoothedNoise); - noiseImag = fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][1], smoothedNoise); - signalReal += noiseReal<<4; - signalImag += noiseImag<<4; + noiseReal = fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][0], + smoothedNoise); + noiseImag = fMultDiv2(FDK_sbrDecoder_sbr_randomPhase[index][1], + smoothedNoise); + + /* FDK_sbrDecoder_sbr_randomPhase is downscaled by 2^3 */ + signalReal += noiseReal << 4; + signalImag += noiseImag << 4; } } *ptrReal++ = signalReal; @@ -2185,7 +3006,6 @@ static void adjustTimeSlotHQ( } } - /*! \brief Reset limiter bands. @@ -2195,14 +3015,15 @@ static void adjustTimeSlotHQ( \return SBRDEC_OK if ok, SBRDEC_UNSUPPORTED_CONFIG on error */ SBR_ERROR -ResetLimiterBands ( UCHAR *limiterBandTable, /*!< Resulting band borders in QMF channels */ - UCHAR *noLimiterBands, /*!< Resulting number of limiter band */ - UCHAR *freqBandTable, /*!< Table with possible band borders */ - int noFreqBands, /*!< Number of bands in freqBandTable */ - const PATCH_PARAM *patchParam, /*!< Transposer patch parameters */ - int noPatches, /*!< Number of transposer patches */ - int limiterBands) /*!< Selected 'band density' from bitstream */ -{ +ResetLimiterBands( + UCHAR *limiterBandTable, /*!< Resulting band borders in QMF channels */ + UCHAR *noLimiterBands, /*!< Resulting number of limiter band */ + UCHAR *freqBandTable, /*!< Table with possible band borders */ + int noFreqBands, /*!< Number of bands in freqBandTable */ + const PATCH_PARAM *patchParam, /*!< Transposer patch parameters */ + int noPatches, /*!< Number of transposer patches */ + int limiterBands, /*!< Selected 'band density' from bitstream */ + UCHAR sbrPatchingMode, int xOverQmf[MAX_NUM_PATCHES], int b41Sbr) { int i, k, isPatchBorder[2], loLimIndex, hiLimIndex, tempNoLim, nBands; UCHAR workLimiterBandTable[MAX_FREQ_COEFFS / 2 + MAX_NUM_PATCHES + 1]; int patchBorders[MAX_NUM_PATCHES + 1]; @@ -2212,13 +3033,28 @@ ResetLimiterBands ( UCHAR *limiterBandTable, /*!< Resulting band borders in QM int highSubband = freqBandTable[noFreqBands]; /* 1 limiter band. */ - if(limiterBands == 0) { + if (limiterBands == 0) { limiterBandTable[0] = 0; limiterBandTable[1] = highSubband - lowSubband; nBands = 1; } else { - for (i = 0; i < noPatches; i++) { - patchBorders[i] = patchParam[i].guardStartBand - lowSubband; + if (!sbrPatchingMode && xOverQmf != NULL) { + noPatches = 0; + + if (b41Sbr == 1) { + for (i = 1; i < MAX_NUM_PATCHES_HBE; i++) + if (xOverQmf[i] != 0) noPatches++; + } else { + for (i = 1; i < MAX_STRETCH_HBE; i++) + if (xOverQmf[i] != 0) noPatches++; + } + for (i = 0; i < noPatches; i++) { + patchBorders[i] = xOverQmf[i] - lowSubband; + } + } else { + for (i = 0; i < noPatches; i++) { + patchBorders[i] = patchParam[i].guardStartBand - lowSubband; + } } patchBorders[i] = highSubband - lowSubband; @@ -2236,35 +3072,38 @@ ResetLimiterBands ( UCHAR *limiterBandTable, /*!< Resulting band borders in QM loLimIndex = 0; hiLimIndex = 1; - while (hiLimIndex <= tempNoLim) { FIXP_DBL div_m, oct_m, temp; - INT div_e = 0, oct_e = 0, temp_e = 0; + INT div_e = 0, oct_e = 0, temp_e = 0; k2 = workLimiterBandTable[hiLimIndex] + lowSubband; kx = workLimiterBandTable[loLimIndex] + lowSubband; - div_m = fDivNorm(k2, kx, &div_e); + div_m = fDivNorm(k2, kx, &div_e); /* calculate number of octaves */ - oct_m = fLog2(div_m, div_e, &oct_e); + oct_m = fLog2(div_m, div_e, &oct_e); /* multiply with limiterbands per octave */ /* values 1, 1.2, 2, 3 -> scale factor of 2 */ - temp = fMultNorm(oct_m, FDK_sbrDecoder_sbr_limiterBandsPerOctaveDiv4_DBL[limiterBands], &temp_e); + temp = fMultNorm( + oct_m, FDK_sbrDecoder_sbr_limiterBandsPerOctaveDiv4_DBL[limiterBands], + &temp_e); - /* overall scale factor of temp ist addition of scalefactors from log2 calculation, - limiter bands scalefactor (2) and limiter bands multiplication */ + /* overall scale factor of temp ist addition of scalefactors from log2 + calculation, limiter bands scalefactor (2) and limiter bands + multiplication */ temp_e += oct_e + 2; /* div can be a maximum of 64 (k2 = 64 and kx = 1) -> oct can be a maximum of 6 - -> temp can be a maximum of 18 (as limiterBandsPerOctoave is a maximum factor of 3) + -> temp can be a maximum of 18 (as limiterBandsPerOctoave is a maximum + factor of 3) -> we need a scale factor of 5 for comparisson */ - if (temp >> (5 - temp_e) < FL2FXCONST_DBL (0.49f) >> 5) { - - if (workLimiterBandTable[hiLimIndex] == workLimiterBandTable[loLimIndex]) { + if (temp >> (5 - temp_e) < FL2FXCONST_DBL(0.49f) >> 5) { + if (workLimiterBandTable[hiLimIndex] == + workLimiterBandTable[loLimIndex]) { workLimiterBandTable[hiLimIndex] = highSubband; nBands--; hiLimIndex++; @@ -2296,12 +3135,11 @@ ResetLimiterBands ( UCHAR *limiterBandTable, /*!< Resulting band borders in QM } loLimIndex = hiLimIndex; hiLimIndex++; - } shellsort(workLimiterBandTable, tempNoLim + 1); /* Test if algorithm exceeded maximum allowed limiterbands */ - if( nBands > MAX_NUM_LIMITERS || nBands <= 0) { + if (nBands > MAX_NUM_LIMITERS || nBands <= 0) { return SBRDEC_UNSUPPORTED_CONFIG; } @@ -2314,4 +3152,3 @@ ResetLimiterBands ( UCHAR *limiterBandTable, /*!< Resulting band borders in QM return SBRDEC_OK; } - |