/* 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. * */ // Resource library #include "common/dcl.h" #include "common/util.h" #include "common/endian.h" #include "common/stream.h" #include "common/textconsole.h" #include "sci/decompressor.h" #include "sci/sci.h" #include "sci/resource.h" namespace Sci { int Decompressor::unpack(Common::ReadStream *src, byte *dest, uint32 nPacked, uint32 nUnpacked) { uint32 chunk; while (nPacked && !(src->eos() || src->err())) { chunk = MIN(1024, nPacked); src->read(dest, chunk); nPacked -= chunk; dest += chunk; } return (src->eos() || src->err()) ? 1 : 0; } void Decompressor::init(Common::ReadStream *src, byte *dest, uint32 nPacked, uint32 nUnpacked) { _src = src; _dest = dest; _szPacked = nPacked; _szUnpacked = nUnpacked; _nBits = 0; _dwRead = _dwWrote = 0; _dwBits = 0; } void Decompressor::fetchBitsMSB() { while (_nBits <= 24) { _dwBits |= ((uint32)_src->readByte()) << (24 - _nBits); _nBits += 8; _dwRead++; } } uint32 Decompressor::getBitsMSB(int n) { // fetching more data to buffer if needed if (_nBits < n) fetchBitsMSB(); uint32 ret = _dwBits >> (32 - n); _dwBits <<= n; _nBits -= n; return ret; } byte Decompressor::getByteMSB() { return getBitsMSB(8); } void Decompressor::fetchBitsLSB() { while (_nBits <= 24) { _dwBits |= ((uint32)_src->readByte()) << _nBits; _nBits += 8; _dwRead++; } } uint32 Decompressor::getBitsLSB(int n) { // fetching more data to buffer if needed if (_nBits < n) fetchBitsLSB(); uint32 ret = (_dwBits & ~((~0) << n)); _dwBits >>= n; _nBits -= n; return ret; } byte Decompressor::getByteLSB() { return getBitsLSB(8); } void Decompressor::putByte(byte b) { _dest[_dwWrote++] = b; } //------------------------------- // Huffman decompressor //------------------------------- int DecompressorHuffman::unpack(Common::ReadStream *src, byte *dest, uint32 nPacked, uint32 nUnpacked) { init(src, dest, nPacked, nUnpacked); byte numnodes; int16 c; uint16 terminator; numnodes = _src->readByte(); terminator = _src->readByte() | 0x100; _nodes = new byte [numnodes << 1]; _src->read(_nodes, numnodes << 1); while ((c = getc2()) != terminator && (c >= 0) && !isFinished()) putByte(c); delete[] _nodes; return _dwWrote == _szUnpacked ? 0 : 1; } int16 DecompressorHuffman::getc2() { byte *node = _nodes; int16 next; while (node[1]) { if (getBitsMSB(1)) { next = node[1] & 0x0F; // use lower 4 bits if (next == 0) return getByteMSB() | 0x100; } else next = node[1] >> 4; // use higher 4 bits node += next << 1; } return (int16)(*node | (node[1] << 8)); } //------------------------------- // LZW Decompressor for SCI0/01/1 //------------------------------- void DecompressorLZW::init(Common::ReadStream *src, byte *dest, uint32 nPacked, uint32 nUnpacked) { Decompressor::init(src, dest, nPacked, nUnpacked); _numbits = 9; _curtoken = 0x102; _endtoken = 0x1ff; } int DecompressorLZW::unpack(Common::ReadStream *src, byte *dest, uint32 nPacked, uint32 nUnpacked) { byte *buffer = NULL; switch (_compression) { case kCompLZW: // SCI0 LZW compression return unpackLZW(src, dest, nPacked, nUnpacked); break; case kCompLZW1: // SCI01/1 LZW compression return unpackLZW1(src, dest, nPacked, nUnpacked); break; case kCompLZW1View: buffer = new byte[nUnpacked]; unpackLZW1(src, buffer, nPacked, nUnpacked); reorderView(buffer, dest); break; case kCompLZW1Pic: buffer = new byte[nUnpacked]; unpackLZW1(src, buffer, nPacked, nUnpacked); reorderPic(buffer, dest, nUnpacked); break; } delete[] buffer; return 0; } int DecompressorLZW::unpackLZW(Common::ReadStream *src, byte *dest, uint32 nPacked, uint32 nUnpacked) { init(src, dest, nPacked, nUnpacked); uint16 token; // The last received value uint16 tokenlastlength = 0; uint16 *tokenlist = (uint16 *)malloc(4096 * sizeof(uint16)); // pointers to dest[] uint16* tokenlengthlist = (uint16 *)malloc(4096 * sizeof(uint16)); // char length of each token if (!tokenlist || !tokenlengthlist) { free(tokenlist); free(tokenlengthlist); error("[DecompressorLZW::unpackLZW] Cannot allocate token memory buffers"); } while (!isFinished()) { token = getBitsLSB(_numbits); if (token == 0x101) { free(tokenlist); free(tokenlengthlist); return 0; // terminator } if (token == 0x100) { // reset command _numbits = 9; _endtoken = 0x1FF; _curtoken = 0x0102; } else { if (token > 0xff) { if (token >= _curtoken) { warning("unpackLZW: Bad token %x", token); free(tokenlist); free(tokenlengthlist); return SCI_ERROR_DECOMPRESSION_ERROR; } tokenlastlength = tokenlengthlist[token] + 1; if (_dwWrote + tokenlastlength > _szUnpacked) { // For me this seems a normal situation, It's necessary to handle it warning("unpackLZW: Trying to write beyond the end of array(len=%d, destctr=%d, tok_len=%d)", _szUnpacked, _dwWrote, tokenlastlength); for (int i = 0; _dwWrote < _szUnpacked; i++) putByte(dest[tokenlist[token] + i]); } else for (int i = 0; i < tokenlastlength; i++) putByte(dest[tokenlist[token] + i]); } else { tokenlastlength = 1; if (_dwWrote >= _szUnpacked) warning("unpackLZW: Try to write single byte beyond end of array"); else putByte(token); } if (_curtoken > _endtoken && _numbits < 12) { _numbits++; _endtoken = (_endtoken << 1) + 1; } if (_curtoken <= _endtoken) { tokenlist[_curtoken] = _dwWrote - tokenlastlength; tokenlengthlist[_curtoken] = tokenlastlength; _curtoken++; } } } free(tokenlist); free(tokenlengthlist); return _dwWrote == _szUnpacked ? 0 : SCI_ERROR_DECOMPRESSION_ERROR; } int DecompressorLZW::unpackLZW1(Common::ReadStream *src, byte *dest, uint32 nPacked, uint32 nUnpacked) { init(src, dest, nPacked, nUnpacked); byte *stak = (byte *)malloc(0x1014); uint32 tokensSize = 0x1004 * sizeof(Tokenlist); Tokenlist *tokens = (Tokenlist *)malloc(tokensSize); if (!stak || !tokens) { free(stak); free(tokens); error("[DecompressorLZW::unpackLZW1] Cannot allocate decompression buffers"); } memset(tokens, 0, tokensSize); byte lastchar = 0; uint16 stakptr = 0, lastbits = 0; byte decryptstart = 0; uint16 bitstring; uint16 token; bool bExit = false; while (!isFinished() && !bExit) { switch (decryptstart) { case 0: bitstring = getBitsMSB(_numbits); if (bitstring == 0x101) {// found end-of-data signal bExit = true; continue; } putByte(bitstring); lastbits = bitstring; lastchar = (bitstring & 0xff); decryptstart = 1; break; case 1: bitstring = getBitsMSB(_numbits); if (bitstring == 0x101) { // found end-of-data signal bExit = true; continue; } if (bitstring == 0x100) { // start-over signal _numbits = 9; _curtoken = 0x102; _endtoken = 0x1ff; decryptstart = 0; continue; } token = bitstring; if (token >= _curtoken) { // index past current point token = lastbits; stak[stakptr++] = lastchar; } while ((token > 0xff) && (token < 0x1004)) { // follow links back in data stak[stakptr++] = tokens[token].data; token = tokens[token].next; } lastchar = stak[stakptr++] = token & 0xff; // put stack in buffer while (stakptr > 0) { putByte(stak[--stakptr]); if (_dwWrote == _szUnpacked) { bExit = true; continue; } } // put token into record if (_curtoken <= _endtoken) { tokens[_curtoken].data = lastchar; tokens[_curtoken].next = lastbits; _curtoken++; if (_curtoken == _endtoken && _numbits < 12) { _numbits++; _endtoken = (_endtoken << 1) + 1; } } lastbits = bitstring; break; } } free(stak); free(tokens); return _dwWrote == _szUnpacked ? 0 : SCI_ERROR_DECOMPRESSION_ERROR; } #define PAL_SIZE 1284 #define EXTRA_MAGIC_SIZE 15 #define VIEW_HEADER_COLORS_8BIT 0x80 void DecompressorLZW::decodeRLE(byte **rledata, byte **pixeldata, byte *outbuffer, int size) { int pos = 0; byte nextbyte; byte *rd = *rledata; byte *ob = outbuffer; byte *pd = *pixeldata; while (pos < size) { nextbyte = *rd++; *ob++ = nextbyte; pos++; switch (nextbyte & 0xC0) { case 0x40: case 0x00: memcpy(ob, pd, nextbyte); pd += nextbyte; ob += nextbyte; pos += nextbyte; break; case 0xC0: break; case 0x80: nextbyte = *pd++; *ob++ = nextbyte; pos++; break; } } *rledata = rd; *pixeldata = pd; } /** * Does the same this as decodeRLE, only to determine the length of the * compressed source data. */ int DecompressorLZW::getRLEsize(byte *rledata, int dsize) { int pos = 0; byte nextbyte; int size = 0; while (pos < dsize) { nextbyte = *(rledata++); pos++; size++; switch (nextbyte & 0xC0) { case 0x40: case 0x00: pos += nextbyte; break; case 0xC0: break; case 0x80: pos++; break; } } return size; } void DecompressorLZW::reorderPic(byte *src, byte *dest, int dsize) { uint16 view_size, view_start, cdata_size; int i; byte *seeker = src; byte *writer = dest; char viewdata[7]; byte *cdata, *cdata_start; *writer++ = PIC_OP_OPX; *writer++ = PIC_OPX_SET_PALETTE; for (i = 0; i < 256; i++) /* Palette translation map */ *writer++ = i; WRITE_LE_UINT32(writer, 0); /* Palette stamp */ writer += 4; view_size = READ_LE_UINT16(seeker); seeker += 2; view_start = READ_LE_UINT16(seeker); seeker += 2; cdata_size = READ_LE_UINT16(seeker); seeker += 2; memcpy(viewdata, seeker, sizeof(viewdata)); seeker += sizeof(viewdata); memcpy(writer, seeker, 4*256); /* Palette */ seeker += 4*256; writer += 4*256; if (view_start != PAL_SIZE + 2) { /* +2 for the opcode */ memcpy(writer, seeker, view_start-PAL_SIZE-2); seeker += view_start - PAL_SIZE - 2; writer += view_start - PAL_SIZE - 2; } if (dsize != view_start + EXTRA_MAGIC_SIZE + view_size) { memcpy(dest + view_size + view_start + EXTRA_MAGIC_SIZE, seeker, dsize - view_size - view_start - EXTRA_MAGIC_SIZE); seeker += dsize - view_size - view_start - EXTRA_MAGIC_SIZE; } cdata_start = cdata = (byte *)malloc(cdata_size); memcpy(cdata, seeker, cdata_size); seeker += cdata_size; writer = dest + view_start; *writer++ = PIC_OP_OPX; *writer++ = PIC_OPX_EMBEDDED_VIEW; *writer++ = 0; *writer++ = 0; *writer++ = 0; WRITE_LE_UINT16(writer, view_size + 8); writer += 2; memcpy(writer, viewdata, sizeof(viewdata)); writer += sizeof(viewdata); *writer++ = 0; decodeRLE(&seeker, &cdata, writer, view_size); free(cdata_start); } void DecompressorLZW::buildCelHeaders(byte **seeker, byte **writer, int celindex, int *cc_lengths, int max) { for (int c = 0; c < max; c++) { memcpy(*writer, *seeker, 6); *seeker += 6; *writer += 6; int w = *((*seeker)++); WRITE_LE_UINT16(*writer, w); /* Zero extension */ *writer += 2; *writer += cc_lengths[celindex]; celindex++; } } void DecompressorLZW::reorderView(byte *src, byte *dest) { byte *cellengths; int loopheaders; int lh_present; int lh_mask; int pal_offset; int cel_total; int unknown; byte *seeker = src; char celcounts[100]; byte *writer = dest; byte *lh_ptr; byte *rle_ptr, *pix_ptr; int l, lb, c, celindex, lh_last = -1; int chptr; int w; int *cc_lengths; byte **cc_pos; /* Parse the main header */ cellengths = src + READ_LE_UINT16(seeker) + 2; seeker += 2; loopheaders = *seeker++; lh_present = *seeker++; lh_mask = READ_LE_UINT16(seeker); seeker += 2; unknown = READ_LE_UINT16(seeker); seeker += 2; pal_offset = READ_LE_UINT16(seeker); seeker += 2; cel_total = READ_LE_UINT16(seeker); seeker += 2; cc_pos = (byte **) malloc(sizeof(byte *) * cel_total); cc_lengths = (int *) malloc(sizeof(int) * cel_total); for (c = 0; c < cel_total; c++) cc_lengths[c] = READ_LE_UINT16(cellengths + 2 * c); *writer++ = loopheaders; *writer++ = VIEW_HEADER_COLORS_8BIT; WRITE_LE_UINT16(writer, lh_mask); writer += 2; WRITE_LE_UINT16(writer, unknown); writer += 2; WRITE_LE_UINT16(writer, pal_offset); writer += 2; lh_ptr = writer; writer += 2 * loopheaders; /* Make room for the loop offset table */ pix_ptr = writer; memcpy(celcounts, seeker, lh_present); seeker += lh_present; lb = 1; celindex = 0; rle_ptr = pix_ptr = cellengths + (2 * cel_total); w = 0; for (l = 0; l < loopheaders; l++) { if (lh_mask & lb) { /* The loop is _not_ present */ if (lh_last == -1) { warning("Error: While reordering view: Loop not present, but can't re-use last loop"); lh_last = 0; } WRITE_LE_UINT16(lh_ptr, lh_last); lh_ptr += 2; } else { lh_last = writer - dest; WRITE_LE_UINT16(lh_ptr, lh_last); lh_ptr += 2; WRITE_LE_UINT16(writer, celcounts[w]); writer += 2; WRITE_LE_UINT16(writer, 0); writer += 2; /* Now, build the cel offset table */ chptr = (writer - dest) + (2 * celcounts[w]); for (c = 0; c < celcounts[w]; c++) { WRITE_LE_UINT16(writer, chptr); writer += 2; cc_pos[celindex+c] = dest + chptr; chptr += 8 + READ_LE_UINT16(cellengths + 2 * (celindex + c)); } buildCelHeaders(&seeker, &writer, celindex, cc_lengths, celcounts[w]); celindex += celcounts[w]; w++; } lb = lb << 1; } if (celindex < cel_total) { warning("View decompression generated too few (%d / %d) headers", celindex, cel_total); free(cc_pos); free(cc_lengths); return; } /* Figure out where the pixel data begins. */ for (c = 0; c < cel_total; c++) pix_ptr += getRLEsize(pix_ptr, cc_lengths[c]); rle_ptr = cellengths + (2 * cel_total); for (c = 0; c < cel_total; c++) decodeRLE(&rle_ptr, &pix_ptr, cc_pos[c] + 8, cc_lengths[c]); if (pal_offset) { *writer++ = 'P'; *writer++ = 'A'; *writer++ = 'L'; for (c = 0; c < 256; c++) *writer++ = c; seeker -= 4; /* The missing four. Don't ask why. */ memcpy(writer, seeker, 4*256 + 4); } free(cc_pos); free(cc_lengths); } //---------------------------------------------- // DCL decompressor for SCI1.1 //---------------------------------------------- int DecompressorDCL::unpack(Common::ReadStream *src, byte *dest, uint32 nPacked, uint32 nUnpacked) { return Common::decompressDCL(src, dest, nPacked, nUnpacked) ? 0 : SCI_ERROR_DECOMPRESSION_ERROR; } #ifdef ENABLE_SCI32 //---------------------------------------------- // STACpack/LZS decompressor for SCI32 // Based on Andre Beck's code from http://micky.ibh.de/~beck/stuff/lzs4i4l/ //---------------------------------------------- int DecompressorLZS::unpack(Common::ReadStream *src, byte *dest, uint32 nPacked, uint32 nUnpacked) { init(src, dest, nPacked, nUnpacked); return unpackLZS(); } int DecompressorLZS::unpackLZS() { uint16 offs = 0; uint32 clen; while (!isFinished()) { if (getBitsMSB(1)) { // Compressed bytes follow if (getBitsMSB(1)) { // Seven bit offset follows offs = getBitsMSB(7); if (!offs) // This is the end marker - a 7 bit offset of zero break; if (!(clen = getCompLen())) { warning("lzsDecomp: length mismatch"); return SCI_ERROR_DECOMPRESSION_ERROR; } copyComp(offs, clen); } else { // Eleven bit offset follows offs = getBitsMSB(11); if (!(clen = getCompLen())) { warning("lzsDecomp: length mismatch"); return SCI_ERROR_DECOMPRESSION_ERROR; } copyComp(offs, clen); } } else // Literal byte follows putByte(getByteMSB()); } // end of while () return _dwWrote == _szUnpacked ? 0 : SCI_ERROR_DECOMPRESSION_ERROR; } uint32 DecompressorLZS::getCompLen() { uint32 clen; int nibble; // The most probable cases are hardcoded switch (getBitsMSB(2)) { case 0: return 2; case 1: return 3; case 2: return 4; default: switch (getBitsMSB(2)) { case 0: return 5; case 1: return 6; case 2: return 7; default: // Ok, no shortcuts anymore - just get nibbles and add up clen = 8; do { nibble = getBitsMSB(4); clen += nibble; } while (nibble == 0xf); return clen; } } } void DecompressorLZS::copyComp(int offs, uint32 clen) { int hpos = _dwWrote - offs; while (clen--) putByte(_dest[hpos++]); } #endif // #ifdef ENABLE_SCI32 } // End of namespace Sci