/* 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. * */ // Based on xoreos' BitStream implementation #ifndef COMMON_BITSTREAM_H #define COMMON_BITSTREAM_H #include "common/scummsys.h" #include "common/textconsole.h" #include "common/stream.h" #include "common/types.h" #include "common/util.h" namespace Common { /** * @defgroup common_bitstream Bit stream * @ingroup common * * @brief API for implementing a bit stream. * * @{ */ /** * A template implementing a bit stream for different data memory layouts. * * Such a bit stream reads valueBits-wide values from the data stream and * gives access to their bits, one at a time. * * For example, a bit stream with the layout parameters 32, true, false * for valueBits, isLE and isMSB2LSB, reads 32-bit little-endian values * from the data stream and hands out the bits in the order of LSB to MSB. */ template class BitStreamImpl { private: STREAM *_stream; //!< The input stream. DisposeAfterUse::Flag _disposeAfterUse; //!< Whether to delete the stream on destruction. uint64 _bitContainer; //!< The currently available bits. uint8 _bitsLeft; //!< Number of bits currently left in the bit container. uint32 _size; //!< Total bit stream size (in bits). uint32 _pos; //!< Current bit stream position (in bits). /** Read a data value. */ inline uint32 readData() { if (isLE) { if (valueBits == 8) return _stream->readByte(); if (valueBits == 16) return _stream->readUint16LE(); if (valueBits == 32) return _stream->readUint32LE(); } else { if (valueBits == 8) return _stream->readByte(); if (valueBits == 16) return _stream->readUint16BE(); if (valueBits == 32) return _stream->readUint32BE(); } assert(false); return 0; } /** Fill the container with at least @p min bits. */ inline void fillContainer(size_t min) { while (_bitsLeft < min) { uint64 data; if (_pos + _bitsLeft + valueBits <= _size) { data = readData(); } else { // Peeking data out of bounds is well-defined and returns 0 bits. // This is for convenience when using speed-up techniques reading // more bits than actually available. Call eos() to check if data // was actually read out of bounds. Peeking out of bounds does not // set the eos flag. data = 0; } // Move the data value to the right position in the bit container if (MSB2LSB) _bitContainer |= data << (64 - valueBits - _bitsLeft); else _bitContainer |= data << _bitsLeft; _bitsLeft += valueBits; } } /** Get @p n bits from the bit container. */ inline static uint32 getNBits(uint64 value, size_t n) { if (n == 0) return 0; const size_t toShift = 64 - n; if (MSB2LSB) return value >> toShift; else return (value << toShift) >> toShift; } /** Skip already read bits. */ inline void skipBits(size_t n) { assert(n <= _bitsLeft); // Shift to the next bit if (MSB2LSB) _bitContainer <<= n; else _bitContainer >>= n; _bitsLeft -= n; _pos += n; } public: /** Create a bit stream using this input data stream and optionally delete it on destruction. */ BitStreamImpl(STREAM *stream, DisposeAfterUse::Flag disposeAfterUse = DisposeAfterUse::NO) : _stream(stream), _disposeAfterUse(disposeAfterUse), _bitContainer(0), _bitsLeft(0), _pos(0) { if ((valueBits != 8) && (valueBits != 16) && (valueBits != 32)) error("BitStreamImpl: Invalid memory layout %d, %d, %d", valueBits, int(isLE), int(MSB2LSB)); _size = (_stream->size() & ~((uint32) ((valueBits >> 3) - 1))) * 8; } /** Create a bit stream using this input data stream. */ BitStreamImpl(STREAM &stream) : _stream(&stream), _disposeAfterUse(DisposeAfterUse::NO), _bitContainer(0), _bitsLeft(0), _pos(0) { if ((valueBits != 8) && (valueBits != 16) && (valueBits != 32)) error("BitStreamImpl: Invalid memory layout %d, %d, %d", valueBits, int(isLE), int(MSB2LSB)); _size = (_stream->size() & ~((uint32) ((valueBits >> 3) - 1))) * 8; } ~BitStreamImpl() { if (_disposeAfterUse == DisposeAfterUse::YES) delete _stream; } /** Read a bit from the bit stream, without changing the stream's position. */ uint peekBit() { fillContainer(1); return getNBits(_bitContainer, 1); } /** Read a bit from the bit stream. */ uint getBit() { const uint b = peekBit(); skipBits(1); return b; } /** * Read a multi-bit value from the bit stream, without changing the stream's position. * * The bit order is the same as in @ref getBits(). */ uint32 peekBits(size_t n) { if (n > 32) error("BitStreamImpl::peekBits(): Too many bits requested to be peeked"); fillContainer(n); return getNBits(_bitContainer, n); } /** * Read a multi-bit value from the bit stream. * * The value is read as if just taken as a whole from the bit stream. * * For example: * Reading a 4-bit value from an 8-bit bit stream with the contents 01010011: * If the bit stream is MSB2LSB, the 4-bit value would be 0101. * If the bit stream is LSB2MSB, the 4-bit value would be 0011. */ uint32 getBits(size_t n) { if (n > 32) error("BitStreamImpl::getBits(): Too many bits requested to be read"); const uint32 b = peekBits(n); skipBits(n); return b; } /** * Add a bit to the value x, making it an n+1-bit value. * * The current value is shifted and the bit is added to the * appropriate place, depending on the stream's bit order. * * For example: * A bit y is added to the value 00001100 with size 4. * If the stream's bit order is MSB2LSB, the resulting value is 0001100y. * If the stream's bit order is LSB2MSB, the resulting value is 000y1100. */ void addBit(uint32 &x, uint32 n) { if (n >= 32) error("BitStreamImpl::addBit(): Too many bits requested to be read"); if (MSB2LSB) x = (x << 1) | getBit(); else x = (x & ~(1 << n)) | (getBit() << n); } /** Rewind the bit stream back to the start. */ void rewind() { _stream->seek(0); _bitContainer = 0; _bitsLeft = 0; _pos = 0; } /** Skip the specified number of bits. */ void skip(uint32 n) { while (n > 32) { fillContainer(32); skipBits(32); n -= 32; } fillContainer(n); skipBits(n); } /** Skip the bits to closest data value border. */ void align() { uint32 bitsAfterBoundary = _pos % valueBits; if (bitsAfterBoundary) { skip(valueBits - bitsAfterBoundary); } } /** Return the stream position in bits. */ uint64 pos() const { return _pos; } /** Return the stream size in bits. */ uint64 size() const { return _size; } bool eos() const { return _stream->eos() || (_pos >= _size); } static bool isMSB2LSB() { return MSB2LSB; } }; /** * A cut-down version of MemoryReadStream specifically for use with BitStream. * It removes the virtual call overhead for reading bytes from a memory buffer, * and allows directly inlining this access. * * The code duplication with MemoryReadStream is not ideal. * It might be possible to avoid this by making this a final subclass of * MemoryReadStream, but that is a C++11 feature. */ class BitStreamMemoryStream { private: const byte * const _ptrOrig; const byte *_ptr; const uint32 _size; uint32 _pos; DisposeAfterUse::Flag _disposeMemory; bool _eos; /** @overload */ public: BitStreamMemoryStream(const byte *dataPtr, uint32 dataSize, DisposeAfterUse::Flag disposeMemory = DisposeAfterUse::NO) : _ptrOrig(dataPtr), _ptr(dataPtr), _size(dataSize), _pos(0), _disposeMemory(disposeMemory), _eos(false) {} ~BitStreamMemoryStream() { if (_disposeMemory) free(const_cast(_ptrOrig)); } bool eos() const { return _eos; } bool err() const { return false; } int64 pos() const { return _pos; } int64 size() const { return _size; } bool seek(uint32 offset) { assert(offset <= _size); _eos = false; _pos = offset; _ptr = _ptrOrig + _pos; return true; } byte readByte() { if (_pos >= _size) { _eos = true; return 0; } _pos++; return *_ptr++; } uint16 readUint16LE() { if (_pos + 2 > _size) { _eos = true; if (_pos < _size) { _pos++; return *_ptr++; } else { return 0; } } uint16 val = READ_LE_UINT16(_ptr); _pos += 2; _ptr += 2; return val; } uint16 readUint16BE() { if (_pos + 2 > _size) { _eos = true; if (_pos < _size) { _pos++; return (*_ptr++) << 8; } else { return 0; } } uint16 val = READ_LE_UINT16(_ptr); _pos += 2; _ptr += 2; return val; } uint32 readUint32LE() { if (_pos + 4 > _size) { uint32 val = readByte(); val |= (uint32)readByte() << 8; val |= (uint32)readByte() << 16; val |= (uint32)readByte() << 24; return val; } uint32 val = READ_LE_UINT32(_ptr); _pos += 4; _ptr += 4; return val; } uint32 readUint32BE() { if (_pos + 4 > _size) { uint32 val = (uint32)readByte() << 24; val |= (uint32)readByte() << 16; val |= (uint32)readByte() << 8; val |= (uint32)readByte(); return val; } uint32 val = READ_BE_UINT32(_ptr); _pos += 4; _ptr += 4; return val; } }; /** * @name Typedefs for various memory layouts * @{ */ /** 8-bit data, MSB to LSB. */ typedef BitStreamImpl BitStream8MSB; /** 8-bit data, LSB to MSB. */ typedef BitStreamImpl BitStream8LSB; /** 16-bit little-endian data, MSB to LSB. */ typedef BitStreamImpl BitStream16LEMSB; /** 16-bit little-endian data, LSB to MSB. */ typedef BitStreamImpl BitStream16LELSB; /** 16-bit big-endian data, MSB to LSB. */ typedef BitStreamImpl BitStream16BEMSB; /** 16-bit big-endian data, LSB to MSB. */ typedef BitStreamImpl BitStream16BELSB; /** 32-bit little-endian data, MSB to LSB. */ typedef BitStreamImpl BitStream32LEMSB; /** 32-bit little-endian data, LSB to MSB. */ typedef BitStreamImpl BitStream32LELSB; /** 32-bit big-endian data, MSB to LSB. */ typedef BitStreamImpl BitStream32BEMSB; /** 32-bit big-endian data, LSB to MSB. */ typedef BitStreamImpl BitStream32BELSB; /** 8-bit data, MSB to LSB. */ typedef BitStreamImpl BitStreamMemory8MSB; /** 8-bit data, LSB to MSB. */ typedef BitStreamImpl BitStreamMemory8LSB; /** 16-bit little-endian data, MSB to LSB. */ typedef BitStreamImpl BitStreamMemory16LEMSB; /** 16-bit little-endian data, LSB to MSB. */ typedef BitStreamImpl BitStreamMemory16LELSB; /** 16-bit big-endian data, MSB to LSB. */ typedef BitStreamImpl BitStreamMemory16BEMSB; /** 16-bit big-endian data, LSB to MSB. */ typedef BitStreamImpl BitStreamMemory16BELSB; /** 32-bit little-endian data, MSB to LSB. */ typedef BitStreamImpl BitStreamMemory32LEMSB; /** 32-bit little-endian data, LSB to MSB. */ typedef BitStreamImpl BitStreamMemory32LELSB; /** 32-bit big-endian data, MSB to LSB. */ typedef BitStreamImpl BitStreamMemory32BEMSB; /** 32-bit big-endian data, LSB to MSB. */ typedef BitStreamImpl BitStreamMemory32BELSB; /** @} */ /** @} */ } // End of namespace Common #endif // COMMON_BITSTREAM_H