/* 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. * * $URL$ * $Id$ * */ /* Reads data from a resource file and stores the result in memory. ** This is for SCI version 0 style compression. */ #include "common/stream.h" #include "common/endian.h" #include "sci/sci_memory.h" #include "sci/include/sciresource.h" namespace Sci { //#define _SCI_DECOMPRESS_DEBUG // 9-12 bit LZW encoding int decrypt1(uint8 *dest, uint8 *src, int length, int complength) { // Doesn't do length checking yet /* Theory: Considering the input as a bit stream, we get a series of ** 9 bit elements in the beginning. Every one of them is a 'token' ** and either represents a literal (if < 0x100), or a link to a previous ** token (tokens start at 0x102, because 0x101 is the end-of-stream ** indicator and 0x100 is used to reset the bit stream decoder). ** If it's a link, the indicated token and the character following it are ** placed into the output stream. Note that the 'indicated token' may ** very well consist of a link-token-plus-literal construct again, so ** it's possible to represent strings longer than 2 recursively. ** If the maximum number of tokens has been reached, the bit length is ** increased by one, up to a maximum of 12 bits. ** This implementation remembers the position each token was print to in ** the output array, and the length of this token. This method should ** be faster than the recursive approach. */ uint16 bitlen = 9; // no. of bits to read (max. 12) uint16 bitmask = 0x01ff; uint16 bitctr = 0; // current bit position uint16 bytectr = 0; // current byte position uint16 token; // The last received value uint16 maxtoken = 0x200; // The biggest token uint16 tokenlist[4096]; // pointers to dest[] uint16 tokenlengthlist[4096]; // char length of each token uint16 tokenctr = 0x102; // no. of registered tokens (starts here) uint16 tokenlastlength = 0; uint16 destctr = 0; while (bytectr < complength) { uint32 tokenmaker = src[bytectr++] >> bitctr; if (bytectr < complength) tokenmaker |= (src[bytectr] << (8 - bitctr)); if (bytectr + 1 < complength) tokenmaker |= (src[bytectr+1] << (16 - bitctr)); token = tokenmaker & bitmask; bitctr += bitlen - 8; while (bitctr >= 8) { bitctr -= 8; bytectr++; } if (token == 0x101) return 0; // terminator if (token == 0x100) { // reset command maxtoken = 0x200; bitlen = 9; bitmask = 0x01ff; tokenctr = 0x0102; } else { { int i; if (token > 0xff) { if (token >= tokenctr) { #ifdef _SCI_DECOMPRESS_DEBUG fprintf(stderr, "decrypt1: Bad token %x!\n", token); #endif // Well this is really bad // May be it should throw something like SCI_ERROR_DECOMPRESSION_INSANE } else { tokenlastlength = tokenlengthlist[token] + 1; if (destctr + tokenlastlength > length) { #ifdef _SCI_DECOMPRESS_DEBUG // For me this seems a normal situation, It's necessary to handle it printf("decrypt1: Trying to write beyond the end of array(len=%d, destctr=%d, tok_len=%d)!\n", length, destctr, tokenlastlength); #endif i = 0; for (; destctr < length; destctr++) { dest[destctr++] = dest [tokenlist[token] + i]; i++; } } else for (i = 0; i < tokenlastlength; i++) { dest[destctr++] = dest[tokenlist[token] + i]; } } } else { tokenlastlength = 1; if (destctr >= length) { #ifdef _SCI_DECOMPRESS_DEBUG printf("decrypt1: Try to write single byte beyond end of array!\n"); #endif } else dest[destctr++] = (byte)token; } } if (tokenctr == maxtoken) { if (bitlen < 12) { bitlen++; bitmask <<= 1; bitmask |= 1; maxtoken <<= 1; } else continue; // no further tokens allowed } tokenlist[tokenctr] = destctr - tokenlastlength; tokenlengthlist[tokenctr++] = tokenlastlength; } } return 0; } // Huffman-style token encoding /***************************************************************************/ /* This code was taken from Carl Muckenhoupt's sde.c, with some minor */ /* modifications. */ /***************************************************************************/ // decrypt2 helper function int16 getc2(uint8 *node, uint8 *src, uint16 *bytectr, uint16 *bitctr, int complength) { uint16 next; while (node[1] != 0) { int16 value = (src[*bytectr] << (*bitctr)); (*bitctr)++; if (*bitctr == 8) { (*bitctr) = 0; (*bytectr)++; } if (value & 0x80) { next = node[1] & 0x0f; // low 4 bits if (next == 0) { uint16 result = (src[*bytectr] << (*bitctr)); if (++(*bytectr) > complength) return -1; else if (*bytectr < complength) result |= src[*bytectr] >> (8 - (*bitctr)); result &= 0x0ff; return (result | 0x100); } } else { next = node[1] >> 4; // high 4 bits } node += next << 1; } return (int16)READ_LE_UINT16(node); } // Huffman token decryptor int decrypt2(uint8* dest, uint8* src, int length, int complength) { // no complength checking atm */ uint8 numnodes, terminator; uint8 *nodes; int16 c; uint16 bitctr = 0, bytectr; numnodes = src[0]; terminator = src[1]; bytectr = 2 + (numnodes << 1); nodes = src + 2; while (((c = getc2(nodes, src, &bytectr, &bitctr, complength)) != (0x0100 | terminator)) && (c >= 0)) { if (length-- == 0) return SCI_ERROR_DECOMPRESSION_OVERFLOW; *dest = (uint8)c; dest++; } return (c == -1) ? SCI_ERROR_DECOMPRESSION_OVERFLOW : 0; } // Carl Muckenhoupt's decompression code ends here int sci0_get_compression_method(Common::ReadStream &stream) { uint16 compressionMethod; stream.readUint16LE(); stream.readUint16LE(); stream.readUint16LE(); compressionMethod = stream.readUint16LE(); if (stream.err()) return SCI_ERROR_IO_ERROR; return compressionMethod; } int decompress0(resource_t *result, Common::ReadStream &stream, int sci_version) { uint16 compressedLength; uint16 compressionMethod; uint8 *buffer; result->id = stream.readUint16LE(); if (stream.err()) return SCI_ERROR_IO_ERROR; result->number = result->id & 0x07ff; result->type = result->id >> 11; if ((result->number > sci_max_resource_nr[sci_version]) || (result->type > sci_invalid_resource)) return SCI_ERROR_DECOMPRESSION_INSANE; compressedLength = stream.readUint16LE(); result->size = stream.readUint16LE(); compressionMethod = stream.readUint16LE(); if (stream.err()) return SCI_ERROR_IO_ERROR; if (result->size > SCI_MAX_RESOURCE_SIZE) return SCI_ERROR_RESOURCE_TOO_BIG; // With SCI0, this simply cannot happen. if (compressedLength > 4) compressedLength -= 4; else { // Object has size zero (e.g. view.000 in sq3) (does this really exist?) result->data = 0; result->status = SCI_STATUS_NOMALLOC; return SCI_ERROR_EMPTY_OBJECT; } buffer = (uint8*)sci_malloc(compressedLength); result->data = (unsigned char *)sci_malloc(result->size); if (stream.read(buffer, compressedLength) != compressedLength) { free(result->data); free(buffer); return SCI_ERROR_IO_ERROR; }; #ifdef _SCI_DECOMPRESS_DEBUG fprintf(stderr, "Resource %s.%03hi encrypted with method %hi at %.2f%%" " ratio\n", sci_resource_types[result->type], result->number, compressionMethod, (result->size == 0) ? -1.0 : (100.0 * compressedLength / result->size)); fprintf(stderr, " compressedLength = 0x%hx, actualLength=0x%hx\n", compressedLength, result->size); #endif switch (compressionMethod) { case 0: // no compression if (result->size != compressedLength) { free(result->data); result->data = NULL; result->status = SCI_STATUS_NOMALLOC; free(buffer); return SCI_ERROR_DECOMPRESSION_OVERFLOW; } memcpy(result->data, buffer, compressedLength); result->status = SCI_STATUS_ALLOCATED; break; case 1: // LZW compression if (decrypt1(result->data, buffer, result->size, compressedLength)) { free(result->data); result->data = 0; // So that we know that it didn't work result->status = SCI_STATUS_NOMALLOC; free(buffer); return SCI_ERROR_DECOMPRESSION_OVERFLOW; } result->status = SCI_STATUS_ALLOCATED; break; case 2: // Some sort of Huffman encoding if (decrypt2(result->data, buffer, result->size, compressedLength)) { free(result->data); result->data = 0; // So that we know that it didn't work result->status = SCI_STATUS_NOMALLOC; free(buffer); return SCI_ERROR_DECOMPRESSION_OVERFLOW; } result->status = SCI_STATUS_ALLOCATED; break; default: fprintf(stderr, "Resource %s.%03hi: Compression method %hi not " "supported!\n", sci_resource_types[result->type], result->number, compressionMethod); free(result->data); result->data = 0; // So that we know that it didn't work result->status = SCI_STATUS_NOMALLOC; free(buffer); return SCI_ERROR_UNKNOWN_COMPRESSION; } free(buffer); return 0; } } // End of namespace Sci