/* ***** BEGIN LICENSE BLOCK ***** * Source last modified: $Id: sbrside.c,v 1.1 2005/02/26 01:47:35 jrecker Exp $ * * Portions Copyright (c) 1995-2005 RealNetworks, Inc. All Rights Reserved. * * The contents of this file, and the files included with this file, * are subject to the current version of the RealNetworks Public * Source License (the "RPSL") available at * http://www.helixcommunity.org/content/rpsl unless you have licensed * the file under the current version of the RealNetworks Community * Source License (the "RCSL") available at * http://www.helixcommunity.org/content/rcsl, in which case the RCSL * will apply. You may also obtain the license terms directly from * RealNetworks. You may not use this file except in compliance with * the RPSL or, if you have a valid RCSL with RealNetworks applicable * to this file, the RCSL. Please see the applicable RPSL or RCSL for * the rights, obligations and limitations governing use of the * contents of the file. * * This file is part of the Helix DNA Technology. RealNetworks is the * developer of the Original Code and owns the copyrights in the * portions it created. * * This file, and the files included with this file, is distributed * and made available on an 'AS IS' basis, WITHOUT WARRANTY OF ANY * KIND, EITHER EXPRESS OR IMPLIED, AND REALNETWORKS HEREBY DISCLAIMS * ALL SUCH WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES * OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, QUIET * ENJOYMENT OR NON-INFRINGEMENT. * * Technology Compatibility Kit Test Suite(s) Location: * http://www.helixcommunity.org/content/tck * * Contributor(s): * * ***** END LICENSE BLOCK ***** */ /************************************************************************************** * Fixed-point HE-AAC decoder * Jon Recker (jrecker@real.com) * February 2005 * * sbrside.c - functions for unpacking side info from SBR bitstream **************************************************************************************/ #include "sbr_aac.h" /************************************************************************************** * Function: GetSampRateIdx * * Description: get index of given sample rate * * Inputs: sample rate (in Hz) * * Outputs: none * * Return: index of sample rate (table 1.15 in 14496-3:2001(E)) * -1 if sample rate not found in table **************************************************************************************/ int GetSampRateIdx(int sampRate) { int idx; for (idx = 0; idx < NUM_SAMPLE_RATES; idx++) { if (sampRate == sampRateTab[idx]) return idx; } return -1; } /************************************************************************************** * Function: UnpackSBRHeader * * Description: unpack SBR header (table 4.56) * * Inputs: BitStreamInfo struct pointing to start of SBR header * * Outputs: initialized SBRHeader struct for this SCE/CPE block * * Return: non-zero if frame reset is triggered, zero otherwise **************************************************************************************/ int UnpackSBRHeader(BitStreamInfo *bsi, SBRHeader *sbrHdr) { SBRHeader sbrHdrPrev; /* save previous values so we know whether to reset decoder */ sbrHdrPrev.startFreq = sbrHdr->startFreq; sbrHdrPrev.stopFreq = sbrHdr->stopFreq; sbrHdrPrev.freqScale = sbrHdr->freqScale; sbrHdrPrev.alterScale = sbrHdr->alterScale; sbrHdrPrev.crossOverBand = sbrHdr->crossOverBand; sbrHdrPrev.noiseBands = sbrHdr->noiseBands; sbrHdr->ampRes = GetBits(bsi, 1); sbrHdr->startFreq = GetBits(bsi, 4); sbrHdr->stopFreq = GetBits(bsi, 4); sbrHdr->crossOverBand = GetBits(bsi, 3); sbrHdr->resBitsHdr = GetBits(bsi, 2); sbrHdr->hdrExtra1 = GetBits(bsi, 1); sbrHdr->hdrExtra2 = GetBits(bsi, 1); if (sbrHdr->hdrExtra1) { sbrHdr->freqScale = GetBits(bsi, 2); sbrHdr->alterScale = GetBits(bsi, 1); sbrHdr->noiseBands = GetBits(bsi, 2); } else { /* defaults */ sbrHdr->freqScale = 2; sbrHdr->alterScale = 1; sbrHdr->noiseBands = 2; } if (sbrHdr->hdrExtra2) { sbrHdr->limiterBands = GetBits(bsi, 2); sbrHdr->limiterGains = GetBits(bsi, 2); sbrHdr->interpFreq = GetBits(bsi, 1); sbrHdr->smoothMode = GetBits(bsi, 1); } else { /* defaults */ sbrHdr->limiterBands = 2; sbrHdr->limiterGains = 2; sbrHdr->interpFreq = 1; sbrHdr->smoothMode = 1; } sbrHdr->count++; /* if any of these have changed from previous frame, reset the SBR module */ if (sbrHdr->startFreq != sbrHdrPrev.startFreq || sbrHdr->stopFreq != sbrHdrPrev.stopFreq || sbrHdr->freqScale != sbrHdrPrev.freqScale || sbrHdr->alterScale != sbrHdrPrev.alterScale || sbrHdr->crossOverBand != sbrHdrPrev.crossOverBand || sbrHdr->noiseBands != sbrHdrPrev.noiseBands ) return -1; else return 0; } /* cLog2[i] = ceil(log2(i)) (disregard i == 0) */ static const unsigned char cLog2[9] = {0, 0, 1, 2, 2, 3, 3, 3, 3}; /************************************************************************************** * Function: UnpackSBRGrid * * Description: unpack SBR grid (table 4.62) * * Inputs: BitStreamInfo struct pointing to start of SBR grid * initialized SBRHeader struct for this SCE/CPE block * * Outputs: initialized SBRGrid struct for this channel * * Return: none **************************************************************************************/ static void UnpackSBRGrid(BitStreamInfo *bsi, SBRHeader *sbrHdr, SBRGrid *sbrGrid) { int numEnvRaw, env, rel, pBits, border, middleBorder; unsigned char relBordLead[MAX_NUM_ENV], relBordTrail[MAX_NUM_ENV]; unsigned char relBorder0[3], relBorder1[3], relBorder[3]; unsigned char numRelBorder0, numRelBorder1, numRelBorder, numRelLead, numRelTrail; unsigned char absBordLead, absBordTrail, absBorder; sbrGrid->ampResFrame = sbrHdr->ampRes; sbrGrid->frameClass = GetBits(bsi, 2); switch (sbrGrid->frameClass) { case SBR_GRID_FIXFIX: numEnvRaw = GetBits(bsi, 2); sbrGrid->numEnv = (1 << numEnvRaw); if (sbrGrid->numEnv == 1) sbrGrid->ampResFrame = 0; ASSERT(sbrGrid->numEnv == 1 || sbrGrid->numEnv == 2 || sbrGrid->numEnv == 4); sbrGrid->freqRes[0] = GetBits(bsi, 1); for (env = 1; env < sbrGrid->numEnv; env++) sbrGrid->freqRes[env] = sbrGrid->freqRes[0]; absBordLead = 0; absBordTrail = NUM_TIME_SLOTS; numRelLead = sbrGrid->numEnv - 1; numRelTrail = 0; /* numEnv = 1, 2, or 4 */ if (sbrGrid->numEnv == 1) border = NUM_TIME_SLOTS / 1; else if (sbrGrid->numEnv == 2) border = NUM_TIME_SLOTS / 2; else border = NUM_TIME_SLOTS / 4; for (rel = 0; rel < numRelLead; rel++) relBordLead[rel] = border; middleBorder = (sbrGrid->numEnv >> 1); break; case SBR_GRID_FIXVAR: absBorder = GetBits(bsi, 2) + NUM_TIME_SLOTS; numRelBorder = GetBits(bsi, 2); sbrGrid->numEnv = numRelBorder + 1; for (rel = 0; rel < numRelBorder; rel++) relBorder[rel] = 2*GetBits(bsi, 2) + 2; pBits = cLog2[sbrGrid->numEnv + 1]; sbrGrid->pointer = GetBits(bsi, pBits); for (env = sbrGrid->numEnv - 1; env >= 0; env--) sbrGrid->freqRes[env] = GetBits(bsi, 1); absBordLead = 0; absBordTrail = absBorder; numRelLead = 0; numRelTrail = numRelBorder; for (rel = 0; rel < numRelTrail; rel++) relBordTrail[rel] = relBorder[rel]; if (sbrGrid->pointer > 1) middleBorder = sbrGrid->numEnv + 1 - sbrGrid->pointer; else middleBorder = sbrGrid->numEnv - 1; break; case SBR_GRID_VARFIX: absBorder = GetBits(bsi, 2); numRelBorder = GetBits(bsi, 2); sbrGrid->numEnv = numRelBorder + 1; for (rel = 0; rel < numRelBorder; rel++) relBorder[rel] = 2*GetBits(bsi, 2) + 2; pBits = cLog2[sbrGrid->numEnv + 1]; sbrGrid->pointer = GetBits(bsi, pBits); for (env = 0; env < sbrGrid->numEnv; env++) sbrGrid->freqRes[env] = GetBits(bsi, 1); absBordLead = absBorder; absBordTrail = NUM_TIME_SLOTS; numRelLead = numRelBorder; numRelTrail = 0; for (rel = 0; rel < numRelLead; rel++) relBordLead[rel] = relBorder[rel]; if (sbrGrid->pointer == 0) middleBorder = 1; else if (sbrGrid->pointer == 1) middleBorder = sbrGrid->numEnv - 1; else middleBorder = sbrGrid->pointer - 1; break; case SBR_GRID_VARVAR: absBordLead = GetBits(bsi, 2); /* absBorder0 */ absBordTrail = GetBits(bsi, 2) + NUM_TIME_SLOTS; /* absBorder1 */ numRelBorder0 = GetBits(bsi, 2); numRelBorder1 = GetBits(bsi, 2); sbrGrid->numEnv = numRelBorder0 + numRelBorder1 + 1; ASSERT(sbrGrid->numEnv <= 5); for (rel = 0; rel < numRelBorder0; rel++) relBorder0[rel] = 2*GetBits(bsi, 2) + 2; for (rel = 0; rel < numRelBorder1; rel++) relBorder1[rel] = 2*GetBits(bsi, 2) + 2; pBits = cLog2[numRelBorder0 + numRelBorder1 + 2]; sbrGrid->pointer = GetBits(bsi, pBits); for (env = 0; env < sbrGrid->numEnv; env++) sbrGrid->freqRes[env] = GetBits(bsi, 1); numRelLead = numRelBorder0; numRelTrail = numRelBorder1; for (rel = 0; rel < numRelLead; rel++) relBordLead[rel] = relBorder0[rel]; for (rel = 0; rel < numRelTrail; rel++) relBordTrail[rel] = relBorder1[rel]; if (sbrGrid->pointer > 1) middleBorder = sbrGrid->numEnv + 1 - sbrGrid->pointer; else middleBorder = sbrGrid->numEnv - 1; break; } /* build time border vector */ sbrGrid->envTimeBorder[0] = absBordLead * SAMPLES_PER_SLOT; rel = 0; border = absBordLead; for (env = 1; env <= numRelLead; env++) { border += relBordLead[rel++]; sbrGrid->envTimeBorder[env] = border * SAMPLES_PER_SLOT; } rel = 0; border = absBordTrail; for (env = sbrGrid->numEnv - 1; env > numRelLead; env--) { border -= relBordTrail[rel++]; sbrGrid->envTimeBorder[env] = border * SAMPLES_PER_SLOT; } sbrGrid->envTimeBorder[sbrGrid->numEnv] = absBordTrail * SAMPLES_PER_SLOT; if (sbrGrid->numEnv > 1) { sbrGrid->numNoiseFloors = 2; sbrGrid->noiseTimeBorder[0] = sbrGrid->envTimeBorder[0]; sbrGrid->noiseTimeBorder[1] = sbrGrid->envTimeBorder[middleBorder]; sbrGrid->noiseTimeBorder[2] = sbrGrid->envTimeBorder[sbrGrid->numEnv]; } else { sbrGrid->numNoiseFloors = 1; sbrGrid->noiseTimeBorder[0] = sbrGrid->envTimeBorder[0]; sbrGrid->noiseTimeBorder[1] = sbrGrid->envTimeBorder[1]; } } /************************************************************************************** * Function: UnpackDeltaTimeFreq * * Description: unpack time/freq flags for delta coding of SBR envelopes (table 4.63) * * Inputs: BitStreamInfo struct pointing to start of dt/df flags * number of envelopes * number of noise floors * * Outputs: delta flags for envelope and noise floors * * Return: none **************************************************************************************/ static void UnpackDeltaTimeFreq(BitStreamInfo *bsi, int numEnv, unsigned char *deltaFlagEnv, int numNoiseFloors, unsigned char *deltaFlagNoise) { int env, noiseFloor; for (env = 0; env < numEnv; env++) deltaFlagEnv[env] = GetBits(bsi, 1); for (noiseFloor = 0; noiseFloor < numNoiseFloors; noiseFloor++) deltaFlagNoise[noiseFloor] = GetBits(bsi, 1); } /************************************************************************************** * Function: UnpackInverseFilterMode * * Description: unpack invf flags for chirp factor calculation (table 4.64) * * Inputs: BitStreamInfo struct pointing to start of invf flags * number of noise floor bands * * Outputs: invf flags for noise floor bands * * Return: none **************************************************************************************/ static void UnpackInverseFilterMode(BitStreamInfo *bsi, int numNoiseFloorBands, unsigned char *mode) { int n; for (n = 0; n < numNoiseFloorBands; n++) mode[n] = GetBits(bsi, 2); } /************************************************************************************** * Function: UnpackSinusoids * * Description: unpack sinusoid (harmonic) flags for each SBR subband (table 4.67) * * Inputs: BitStreamInfo struct pointing to start of sinusoid flags * number of high resolution SBR subbands (nHigh) * * Outputs: sinusoid flags for each SBR subband, zero-filled above nHigh * * Return: none **************************************************************************************/ static void UnpackSinusoids(BitStreamInfo *bsi, int nHigh, int addHarmonicFlag, unsigned char *addHarmonic) { int n; n = 0; if (addHarmonicFlag) { for ( ; n < nHigh; n++) addHarmonic[n] = GetBits(bsi, 1); } /* zero out unused bands */ for ( ; n < MAX_QMF_BANDS; n++) addHarmonic[n] = 0; } /************************************************************************************** * Function: CopyCouplingGrid * * Description: copy grid parameters from left to right for channel coupling * * Inputs: initialized SBRGrid struct for left channel * * Outputs: initialized SBRGrid struct for right channel * * Return: none **************************************************************************************/ static void CopyCouplingGrid(SBRGrid *sbrGridLeft, SBRGrid *sbrGridRight) { int env, noiseFloor; sbrGridRight->frameClass = sbrGridLeft->frameClass; sbrGridRight->ampResFrame = sbrGridLeft->ampResFrame; sbrGridRight->pointer = sbrGridLeft->pointer; sbrGridRight->numEnv = sbrGridLeft->numEnv; for (env = 0; env < sbrGridLeft->numEnv; env++) { sbrGridRight->envTimeBorder[env] = sbrGridLeft->envTimeBorder[env]; sbrGridRight->freqRes[env] = sbrGridLeft->freqRes[env]; } sbrGridRight->envTimeBorder[env] = sbrGridLeft->envTimeBorder[env]; /* borders are [0, numEnv] inclusive */ sbrGridRight->numNoiseFloors = sbrGridLeft->numNoiseFloors; for (noiseFloor = 0; noiseFloor <= sbrGridLeft->numNoiseFloors; noiseFloor++) sbrGridRight->noiseTimeBorder[noiseFloor] = sbrGridLeft->noiseTimeBorder[noiseFloor]; /* numEnvPrev, numNoiseFloorsPrev, freqResPrev are updated in DecodeSBREnvelope() and DecodeSBRNoise() */ } /************************************************************************************** * Function: CopyCouplingInverseFilterMode * * Description: copy invf flags from left to right for channel coupling * * Inputs: invf flags for left channel * number of noise floor bands * * Outputs: invf flags for right channel * * Return: none **************************************************************************************/ static void CopyCouplingInverseFilterMode(int numNoiseFloorBands, unsigned char *modeLeft, unsigned char *modeRight) { int band; for (band = 0; band < numNoiseFloorBands; band++) modeRight[band] = modeLeft[band]; } /************************************************************************************** * Function: UnpackSBRSingleChannel * * Description: unpack sideband info (grid, delta flags, invf flags, envelope and * noise floor configuration, sinusoids) for a single channel * * Inputs: BitStreamInfo struct pointing to start of sideband info * initialized PSInfoSBR struct (after parsing SBR header and building * frequency tables) * base output channel (range = [0, nChans-1]) * * Outputs: updated PSInfoSBR struct (SBRGrid and SBRChan) * * Return: none **************************************************************************************/ void UnpackSBRSingleChannel(BitStreamInfo *bsi, PSInfoSBR *psi, int chBase) { int bitsLeft; SBRHeader *sbrHdr = &(psi->sbrHdr[chBase]); SBRGrid *sbrGridL = &(psi->sbrGrid[chBase+0]); SBRFreq *sbrFreq = &(psi->sbrFreq[chBase]); SBRChan *sbrChanL = &(psi->sbrChan[chBase+0]); psi->dataExtra = GetBits(bsi, 1); if (psi->dataExtra) psi->resBitsData = GetBits(bsi, 4); UnpackSBRGrid(bsi, sbrHdr, sbrGridL); UnpackDeltaTimeFreq(bsi, sbrGridL->numEnv, sbrChanL->deltaFlagEnv, sbrGridL->numNoiseFloors, sbrChanL->deltaFlagNoise); UnpackInverseFilterMode(bsi, sbrFreq->numNoiseFloorBands, sbrChanL->invfMode[1]); DecodeSBREnvelope(bsi, psi, sbrGridL, sbrFreq, sbrChanL, 0); DecodeSBRNoise(bsi, psi, sbrGridL, sbrFreq, sbrChanL, 0); sbrChanL->addHarmonicFlag[1] = GetBits(bsi, 1); UnpackSinusoids(bsi, sbrFreq->nHigh, sbrChanL->addHarmonicFlag[1], sbrChanL->addHarmonic[1]); psi->extendedDataPresent = GetBits(bsi, 1); if (psi->extendedDataPresent) { psi->extendedDataSize = GetBits(bsi, 4); if (psi->extendedDataSize == 15) psi->extendedDataSize += GetBits(bsi, 8); bitsLeft = 8 * psi->extendedDataSize; /* get ID, unpack extension info, do whatever is necessary with it... */ while (bitsLeft > 0) { GetBits(bsi, 8); bitsLeft -= 8; } } } /************************************************************************************** * Function: UnpackSBRChannelPair * * Description: unpack sideband info (grid, delta flags, invf flags, envelope and * noise floor configuration, sinusoids) for a channel pair * * Inputs: BitStreamInfo struct pointing to start of sideband info * initialized PSInfoSBR struct (after parsing SBR header and building * frequency tables) * base output channel (range = [0, nChans-1]) * * Outputs: updated PSInfoSBR struct (SBRGrid and SBRChan for both channels) * * Return: none **************************************************************************************/ void UnpackSBRChannelPair(BitStreamInfo *bsi, PSInfoSBR *psi, int chBase) { int bitsLeft; SBRHeader *sbrHdr = &(psi->sbrHdr[chBase]); SBRGrid *sbrGridL = &(psi->sbrGrid[chBase+0]), *sbrGridR = &(psi->sbrGrid[chBase+1]); SBRFreq *sbrFreq = &(psi->sbrFreq[chBase]); SBRChan *sbrChanL = &(psi->sbrChan[chBase+0]), *sbrChanR = &(psi->sbrChan[chBase+1]); psi->dataExtra = GetBits(bsi, 1); if (psi->dataExtra) { psi->resBitsData = GetBits(bsi, 4); psi->resBitsData = GetBits(bsi, 4); } psi->couplingFlag = GetBits(bsi, 1); if (psi->couplingFlag) { UnpackSBRGrid(bsi, sbrHdr, sbrGridL); CopyCouplingGrid(sbrGridL, sbrGridR); UnpackDeltaTimeFreq(bsi, sbrGridL->numEnv, sbrChanL->deltaFlagEnv, sbrGridL->numNoiseFloors, sbrChanL->deltaFlagNoise); UnpackDeltaTimeFreq(bsi, sbrGridR->numEnv, sbrChanR->deltaFlagEnv, sbrGridR->numNoiseFloors, sbrChanR->deltaFlagNoise); UnpackInverseFilterMode(bsi, sbrFreq->numNoiseFloorBands, sbrChanL->invfMode[1]); CopyCouplingInverseFilterMode(sbrFreq->numNoiseFloorBands, sbrChanL->invfMode[1], sbrChanR->invfMode[1]); DecodeSBREnvelope(bsi, psi, sbrGridL, sbrFreq, sbrChanL, 0); DecodeSBRNoise(bsi, psi, sbrGridL, sbrFreq, sbrChanL, 0); DecodeSBREnvelope(bsi, psi, sbrGridR, sbrFreq, sbrChanR, 1); DecodeSBRNoise(bsi, psi, sbrGridR, sbrFreq, sbrChanR, 1); /* pass RIGHT sbrChan struct */ UncoupleSBREnvelope(psi, sbrGridL, sbrFreq, sbrChanR); UncoupleSBRNoise(psi, sbrGridL, sbrFreq, sbrChanR); } else { UnpackSBRGrid(bsi, sbrHdr, sbrGridL); UnpackSBRGrid(bsi, sbrHdr, sbrGridR); UnpackDeltaTimeFreq(bsi, sbrGridL->numEnv, sbrChanL->deltaFlagEnv, sbrGridL->numNoiseFloors, sbrChanL->deltaFlagNoise); UnpackDeltaTimeFreq(bsi, sbrGridR->numEnv, sbrChanR->deltaFlagEnv, sbrGridR->numNoiseFloors, sbrChanR->deltaFlagNoise); UnpackInverseFilterMode(bsi, sbrFreq->numNoiseFloorBands, sbrChanL->invfMode[1]); UnpackInverseFilterMode(bsi, sbrFreq->numNoiseFloorBands, sbrChanR->invfMode[1]); DecodeSBREnvelope(bsi, psi, sbrGridL, sbrFreq, sbrChanL, 0); DecodeSBREnvelope(bsi, psi, sbrGridR, sbrFreq, sbrChanR, 1); DecodeSBRNoise(bsi, psi, sbrGridL, sbrFreq, sbrChanL, 0); DecodeSBRNoise(bsi, psi, sbrGridR, sbrFreq, sbrChanR, 1); } sbrChanL->addHarmonicFlag[1] = GetBits(bsi, 1); UnpackSinusoids(bsi, sbrFreq->nHigh, sbrChanL->addHarmonicFlag[1], sbrChanL->addHarmonic[1]); sbrChanR->addHarmonicFlag[1] = GetBits(bsi, 1); UnpackSinusoids(bsi, sbrFreq->nHigh, sbrChanR->addHarmonicFlag[1], sbrChanR->addHarmonic[1]); psi->extendedDataPresent = GetBits(bsi, 1); if (psi->extendedDataPresent) { psi->extendedDataSize = GetBits(bsi, 4); if (psi->extendedDataSize == 15) psi->extendedDataSize += GetBits(bsi, 8); bitsLeft = 8 * psi->extendedDataSize; /* get ID, unpack extension info, do whatever is necessary with it... */ while (bitsLeft > 0) { GetBits(bsi, 8); bitsLeft -= 8; } } }