/* ScummVM - Graphic Adventure Engine * * ScummVM is the legal property of its developers, whose names * are too numerous to list here. Please refer to the COPYRIGHT * file distributed with this source distribution. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * $URL$ * $Id$ * */ #include "sound/shorten.h" #ifdef SOUND_SHORTEN_H // Based on etree's Shorten tool, version 3.6.1 // http://etree.org/shnutils/shorten/ // FIXME: This doesn't work yet correctly #include "common/endian.h" #include "common/util.h" #include "common/stream.h" #include "sound/audiostream.h" #include "sound/mixer.h" #include "sound/raw.h" namespace Audio { #define MASKTABSIZE 33 #define MAX_SUPPORTED_VERSION 3 #define DEFAULT_BLOCK_SIZE 256 enum kShortenTypes { kTypeAU1 = 0, // lossless ulaw kTypeS8 = 1, // signed 8 bit kTypeU8 = 2, // unsigned 8 bit kTypeS16HL = 3, // signed 16 bit shorts: high-low kTypeU16HL = 4, // unsigned 16 bit shorts: high-low kTypeS16LH = 5, // signed 16 bit shorts: low-high kTypeU16LH = 6, // unsigned 16 bit shorts: low-high kTypeULaw = 7, // lossy ulaw kTypeAU2 = 8, // new ulaw with zero mapping kTypeAU3 = 9, // lossless alaw kTypeALaw = 10, // lossy alaw kTypeWAV = 11, // WAV kTypeAIFF = 12, // AIFF kTypeEOF = 13, kTypeGenericULaw = 128, kTypeGenericALaw = 129 }; enum kShortenCommands { kCmdDiff0 = 0, kCmdDiff1 = 1, kCmdDiff2 = 2, kCmdDiff3 = 3, kCmdQuit = 4, kCmdBlockSize = 5, kCmdBitShift = 6, kCmdQLPC = 7, kCmdZero = 8, kCmdVerbatim = 9 }; #ifndef M_LN2 #define M_LN2 0.69314718055994530942 #endif // --------------------------------------------------------------------------- class ShortenGolombReader { public: ShortenGolombReader(Common::ReadStream *stream, int version); ~ShortenGolombReader() {} uint32 getUint32(uint32 numBits); // UINT_GET int32 getURice(uint32 numBits); // uvar_get int32 getSRice(uint32 numBits); // var_get private: int _version; uint32 _nbitget; uint32 _buf; uint32 _masktab[MASKTABSIZE]; Common::ReadStream *_stream; }; ShortenGolombReader::ShortenGolombReader(Common::ReadStream *stream, int version) { _stream = stream; _version = version; uint32 val = 0; _masktab[0] = 0; _nbitget = 0; _buf = 0; for (int i = 1; i < MASKTABSIZE; i++) { val <<= 1; val |= 1; _masktab[i] = val; } } int32 ShortenGolombReader::getURice(uint32 numBits) { int32 result = 0; if (!_nbitget) { _buf = _stream->readUint32BE(); _nbitget = 32; } for (result = 0; !(_buf & (1L << --_nbitget)); result++) { if (!_nbitget) { _buf = _stream->readUint32BE(); _nbitget = 32; } } while (numBits != 0) { if (_nbitget >= numBits) { result = (result << numBits) | ((_buf >> (_nbitget - numBits)) & _masktab[numBits]); _nbitget -= numBits; numBits = 0; } else { result = (result << _nbitget) | (_buf & _masktab[_nbitget]); _buf = _stream->readUint32BE(); numBits -= _nbitget; _nbitget = 32; } } return result; } int32 ShortenGolombReader::getSRice(uint32 numBits) { uint32 uvar = (uint32) getURice(numBits + 1); return (uvar & 1) ? (int32) ~(uvar >> 1) : (int32) (uvar >> 1); } uint32 ShortenGolombReader::getUint32(uint32 numBits) { return (_version == 0) ? (uint32)getURice(numBits) : (uint32)getURice(getURice(2)); } // --------------------------------------------------------------------------- byte *loadShortenFromStream(Common::ReadStream &stream, int &size, int &rate, byte &flags) { int32 *buffer[2], *offset[2]; // up to 2 channels byte *unpackedBuffer = 0; byte *pBuf = unpackedBuffer; int prevSize = 0; int32 *lpc = 0; ShortenGolombReader *gReader; uint32 i, j, version, mean, type, channels, blockSize; uint32 maxLPC = 0, lpcqOffset = 0; int32 bitShift = 0, wrap = 0; flags = 0; size = 0; // Read header byte magic[4]; stream.read(magic, 4); if (memcmp(magic, "ajkg", 4) != 0) { warning("loadShortenFromStream: No 'ajkg' header"); return NULL; } version = stream.readByte(); if (version > MAX_SUPPORTED_VERSION) { warning("loadShortenFromStream: Can't decode version %d, maximum supported version is %d", version, MAX_SUPPORTED_VERSION); return NULL; } mean = (version < 2) ? 0 : 4; gReader = new ShortenGolombReader(&stream, version); // Get file type type = gReader->getUint32(4); switch (type) { case kTypeS8: break; case kTypeU8: flags |= Audio::FLAG_UNSIGNED; break; case kTypeS16LH: flags |= Audio::FLAG_LITTLE_ENDIAN; case kTypeS16HL: flags |= Audio::FLAG_16BITS; break; case kTypeU16LH: flags |= Audio::FLAG_LITTLE_ENDIAN; case kTypeU16HL: flags |= Audio::FLAG_16BITS; flags |= Audio::FLAG_UNSIGNED; break; case kTypeWAV: // TODO: Perhaps implement this if we find WAV Shorten encoded files warning("loadShortenFromStream: Type WAV is not supported"); delete gReader; return NULL; case kTypeAIFF: // TODO: Perhaps implement this if we find AIFF Shorten encoded files warning("loadShortenFromStream: Type AIFF is not supported"); delete gReader; return NULL; case kTypeAU1: case kTypeAU2: case kTypeAU3: case kTypeULaw: case kTypeALaw: case kTypeEOF: case kTypeGenericULaw: case kTypeGenericALaw: default: warning("loadShortenFromStream: Type %d is not supported", type); delete gReader; return NULL; } // Get channels channels = gReader->getUint32(0); if (channels != 1 && channels != 2) { warning("loadShortenFromStream: Only 1 or 2 channels are supported, stream contains %d channels", channels); delete gReader; return NULL; } // Get block size if (version > 0) { blockSize = gReader->getUint32((int) (log((double) DEFAULT_BLOCK_SIZE) / M_LN2)); maxLPC = gReader->getUint32(2); mean = gReader->getUint32(0); uint32 skipBytes = gReader->getUint32(1); if (skipBytes > 0) { prevSize = size; size += skipBytes; unpackedBuffer = (byte *) realloc(unpackedBuffer, size); pBuf = unpackedBuffer + prevSize; for (i = 0; i < skipBytes; i++) { *pBuf++ = gReader->getUint32(7) & 0xFF; } } } else { blockSize = DEFAULT_BLOCK_SIZE; } wrap = MAX(3, maxLPC); // Initialize buffers for (i = 0; i < channels; i++) { buffer[i] = (int32 *)malloc((blockSize + wrap) * 4); offset[i] = (int32 *)malloc((MAX(1, mean)) * 4); memset(buffer[i], 0, (blockSize + wrap) * 4); memset(offset[i], 0, (MAX(1, mean)) * 4); } if (maxLPC > 0) lpc = (int32 *) malloc(maxLPC * 4); if (version > 1) lpcqOffset = 1 << 5; // Init offset int32 offsetMean = 0; uint32 blocks = MAX(1, mean); if (type == kTypeU8) offsetMean = 0x80; else if (type == kTypeU16HL || type == kTypeU16LH) offsetMean = 0x8000; for (uint32 channel = 0; channel < channels; channel++) for (uint32 block = 0; block < blocks; block++) offset[channel][block] = offsetMean; uint32 curChannel = 0, cmd = 0; // Parse Shorten commands while (true) { cmd = gReader->getURice(2); if (cmd == kCmdQuit) break; switch (cmd) { case kCmdZero: case kCmdDiff0: case kCmdDiff1: case kCmdDiff2: case kCmdDiff3: case kCmdQLPC: { int32 channelOffset = 0, energy = 0; uint32 lpcNum = 0; if (cmd != kCmdZero) { energy = gReader->getURice(3); // hack for version 0 if (version == 0) energy--; } // Find mean offset (code duplicated below) if (mean == 0) { channelOffset = offset[curChannel][0]; } else { int32 sum = (version < 2) ? 0 : mean / 2; for (i = 0; i < mean; i++) sum += offset[curChannel][i]; channelOffset = sum / mean; if (version >= 2 && bitShift > 0) channelOffset = (channelOffset >> (bitShift - 1)) >> 1; } // FIXME: The original code in this bit tries to modify memory outside of the array (negative indices) // in cases kCmdDiff1, kCmdDiff2 and kCmdDiff3 // I've removed those invalid writes, since they happen all the time (even when curChannel is 0) switch (cmd) { case kCmdZero: for (i = 0; i < blockSize; i++) buffer[curChannel][i] = 0; break; case kCmdDiff0: for (i = 0; i < blockSize; i++) buffer[curChannel][i] = gReader->getSRice(energy) + channelOffset; break; case kCmdDiff1: gReader->getSRice(energy); // i = 0 (to fix invalid table/memory access) for (i = 1; i < blockSize; i++) buffer[curChannel][i] = gReader->getSRice(energy) + buffer[curChannel][i - 1]; break; case kCmdDiff2: gReader->getSRice(energy); // i = 0 (to fix invalid table/memory access) gReader->getSRice(energy); // i = 1 (to fix invalid table/memory access) for (i = 2; i < blockSize; i++) buffer[curChannel][i] = gReader->getSRice(energy) + 2 * buffer[curChannel][i - 1] - buffer[curChannel][i - 2]; break; case kCmdDiff3: gReader->getSRice(energy); // i = 0 (to fix invalid table/memory access) gReader->getSRice(energy); // i = 1 (to fix invalid table/memory access) gReader->getSRice(energy); // i = 2 (to fix invalid table/memory access) for (i = 3; i < blockSize; i++) buffer[curChannel][i] = gReader->getSRice(energy) + 3 * (buffer[curChannel][i - 1] - buffer[curChannel][i - 2]) + buffer[curChannel][i - 3]; break; case kCmdQLPC: lpcNum = gReader->getURice(2); // Safeguard: if maxLPC < lpcNum, realloc the lpc buffer if (maxLPC < lpcNum) { warning("Safeguard: maxLPC < lpcNum (should never happen)"); maxLPC = lpcNum; lpc = (int32 *) realloc(lpc, maxLPC * 4); } for (i = 0; i < lpcNum; i++) lpc[i] = gReader->getSRice(5); for (i = 0; i < lpcNum; i++) buffer[curChannel][i - lpcNum] -= channelOffset; for (i = 0; i < blockSize; i++) { int32 sum = lpcqOffset; for (j = 0; j < lpcNum; j++) { // FIXME: The original code did an invalid memory access here // (if i and j are 0, the array index requested is -1) // I've removed those invalid writes, since they happen all the time (even when curChannel is 0) if (i <= j) // ignore invalid table/memory access continue; sum += lpc[j] * buffer[curChannel][i - j - 1]; } buffer[curChannel][i] = gReader->getSRice(energy) + (sum >> 5); } if (channelOffset > 0) for (i = 0; i < blockSize; i++) buffer[curChannel][i] += channelOffset; break; } // Store mean value, if appropriate (duplicated code from above) if (mean > 0) { int32 sum = (version < 2) ? 0 : blockSize / 2; for (i = 0; i < blockSize; i++) sum += buffer[curChannel][i]; for (i = 1; i < mean; i++) offset[curChannel][i - 1] = offset[curChannel][i]; offset[curChannel][mean - 1] = sum / blockSize; if (version >= 2 && bitShift > 0) offset[curChannel][mean - 1] = offset[curChannel][mean - 1] << bitShift; } // Do the wrap // FIXME: removed for now, as this corrupts the heap, because it // accesses negative array indices //for (int32 k = -wrap; k < 0; k++) // buffer[curChannel][k] = buffer[curChannel][k + blockSize]; // Fix bitshift if (bitShift > 0) { for (i = 0; i < blockSize; i++) buffer[curChannel][i] <<= bitShift; } if (curChannel == channels - 1) { int dataSize = (flags & Audio::FLAG_16BITS) ? 2 : 1; int limit = (flags & Audio::FLAG_16BITS) ? 32767 : 127; limit = (flags & Audio::FLAG_UNSIGNED) ? limit * 2 + 1 : limit; prevSize = size; size += (blockSize * dataSize); unpackedBuffer = (byte *) realloc(unpackedBuffer, size); pBuf = unpackedBuffer + prevSize; if (flags & Audio::FLAG_16BITS) { for (i = 0; i < blockSize; i++) { for (j = 0; j < channels; j++) { int16 val = (int16)(MIN(buffer[j][i], limit) & 0xFFFF); // values are written in LE *pBuf++ = (byte) (val & 0xFF); *pBuf++ = (byte) ((val >> 8) & 0xFF); } } } else { for (i = 0; i < blockSize; i++) for (j = 0; j < channels; j++) *pBuf++ = (byte)(MIN(buffer[j][i], limit) & 0xFF); } } curChannel = (curChannel + 1) % channels; } break; case kCmdBlockSize: blockSize = gReader->getUint32((uint32)log((double) blockSize / M_LN2)); break; case kCmdBitShift: bitShift = gReader->getURice(2); break; case kCmdVerbatim: { uint32 vLen = (uint32)gReader->getURice(5); prevSize = size; size += vLen; unpackedBuffer = (byte *) realloc(unpackedBuffer, size); pBuf = unpackedBuffer + prevSize; while (vLen--) { *pBuf++ = (byte)(gReader->getURice(8) & 0xFF); } } break; default: warning("loadShortenFromStream: Unknown command: %d", cmd); // Cleanup for (i = 0; i < channels; i++) { free(buffer[i]); free(offset[i]); } if (maxLPC > 0) free(lpc); if (size > 0) free(unpackedBuffer); delete gReader; return NULL; break; } } // Rate is always 44100Hz rate = 44100; // Cleanup for (i = 0; i < channels; i++) { free(buffer[i]); free(offset[i]); } if (maxLPC > 0) free(lpc); if (size > 0) free(unpackedBuffer); delete gReader; return unpackedBuffer; } AudioStream *makeShortenStream(Common::SeekableReadStream &stream) { int size, rate; byte *data, flags; data = loadShortenFromStream(stream, size, rate, flags); if (!data) return 0; // Since we allocated our own buffer for the data, we must specify DisposeAfterUse::YES. return makeRawMemoryStream(data, size, DisposeAfterUse::YES, rate, flags); } } // End of namespace Audio #endif // defined(SOUND_SHORTEN_H)