/* This file is part of libmspack. * (C) 2003-2004 Stuart Caie. * * The Quantum method was created by David Stafford, adapted by Microsoft * Corporation. * * This decompressor is based on an implementation by Matthew Russotto, used * with permission. * * libmspack is free software; you can redistribute it and/or modify it under * the terms of the GNU Lesser General Public License (LGPL) version 2.1 * * For further details, see the file COPYING.LIB distributed with libmspack */ /* Quantum decompression implementation */ /* This decompressor was researched and implemented by Matthew Russotto. It * has since been tidied up by Stuart Caie. More information can be found at * http://www.speakeasy.org/~russotto/quantumcomp.html */ #include #include /* import bit-reading macros and code */ #define BITS_TYPE struct qtmd_stream #define BITS_VAR qtm #define BITS_ORDER_MSB #define READ_BYTES do { \ unsigned char b0, b1; \ READ_IF_NEEDED; b0 = *i_ptr++; \ READ_IF_NEEDED; b1 = *i_ptr++; \ INJECT_BITS((b0 << 8) | b1, 16); \ } while (0) #include /* Quantum static data tables: * * Quantum uses 'position slots' to represent match offsets. For every * match, a small 'position slot' number and a small offset from that slot * are encoded instead of one large offset. * * position_base[] is an index to the position slot bases * * extra_bits[] states how many bits of offset-from-base data is needed. * * length_base[] and length_extra[] are equivalent in function, but are * used for encoding selector 6 (variable length match) match lengths, * instead of match offsets. * * They are generated with the following code: * unsigned int i, offset; * for (i = 0, offset = 0; i < 42; i++) { * position_base[i] = offset; * extra_bits[i] = ((i < 2) ? 0 : (i - 2)) >> 1; * offset += 1 << extra_bits[i]; * } * for (i = 0, offset = 0; i < 26; i++) { * length_base[i] = offset; * length_extra[i] = (i < 2 ? 0 : i - 2) >> 2; * offset += 1 << length_extra[i]; * } * length_base[26] = 254; length_extra[26] = 0; */ static const unsigned int position_base[42] = { 0, 1, 2, 3, 4, 6, 8, 12, 16, 24, 32, 48, 64, 96, 128, 192, 256, 384, 512, 768, 1024, 1536, 2048, 3072, 4096, 6144, 8192, 12288, 16384, 24576, 32768, 49152, 65536, 98304, 131072, 196608, 262144, 393216, 524288, 786432, 1048576, 1572864 }; static const unsigned char extra_bits[42] = { 0, 0, 0, 0, 1, 1, 2, 2, 3, 3, 4, 4, 5, 5, 6, 6, 7, 7, 8, 8, 9, 9, 10, 10, 11, 11, 12, 12, 13, 13, 14, 14, 15, 15, 16, 16, 17, 17, 18, 18, 19, 19 }; static const unsigned char length_base[27] = { 0, 1, 2, 3, 4, 5, 6, 8, 10, 12, 14, 18, 22, 26, 30, 38, 46, 54, 62, 78, 94, 110, 126, 158, 190, 222, 254 }; static const unsigned char length_extra[27] = { 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 4, 4, 4, 4, 5, 5, 5, 5, 0 }; /* Arithmetic decoder: * * GET_SYMBOL(model, var) fetches the next symbol from the stated model * and puts it in var. * * If necessary, qtmd_update_model() is called. */ #define GET_SYMBOL(model, var) do { \ range = ((H - L) & 0xFFFF) + 1; \ symf = ((((C - L + 1) * model.syms[0].cumfreq)-1) / range) & 0xFFFF; \ \ for (i = 1; i < model.entries; i++) { \ if (model.syms[i].cumfreq <= symf) break; \ } \ (var) = model.syms[i-1].sym; \ \ range = (H - L) + 1; \ symf = model.syms[0].cumfreq; \ H = L + ((model.syms[i-1].cumfreq * range) / symf) - 1; \ L = L + ((model.syms[i].cumfreq * range) / symf); \ \ do { model.syms[--i].cumfreq += 8; } while (i > 0); \ if (model.syms[0].cumfreq > 3800) qtmd_update_model(&model); \ \ while (1) { \ if ((L & 0x8000) != (H & 0x8000)) { \ if ((L & 0x4000) && !(H & 0x4000)) { \ /* underflow case */ \ C ^= 0x4000; L &= 0x3FFF; H |= 0x4000; \ } \ else break; \ } \ L <<= 1; H = (H << 1) | 1; \ ENSURE_BITS(1); \ C = (C << 1) | PEEK_BITS(1); \ REMOVE_BITS(1); \ } \ } while (0) static void qtmd_update_model(struct qtmd_model *model) { struct qtmd_modelsym tmp; int i, j; if (--model->shiftsleft) { for (i = model->entries - 1; i >= 0; i--) { /* -1, not -2; the 0 entry saves this */ model->syms[i].cumfreq >>= 1; if (model->syms[i].cumfreq <= model->syms[i+1].cumfreq) { model->syms[i].cumfreq = model->syms[i+1].cumfreq + 1; } } } else { model->shiftsleft = 50; for (i = 0; i < model->entries; i++) { /* no -1, want to include the 0 entry */ /* this converts cumfreqs into frequencies, then shifts right */ model->syms[i].cumfreq -= model->syms[i+1].cumfreq; model->syms[i].cumfreq++; /* avoid losing things entirely */ model->syms[i].cumfreq >>= 1; } /* now sort by frequencies, decreasing order -- this must be an * inplace selection sort, or a sort with the same (in)stability * characteristics */ for (i = 0; i < model->entries - 1; i++) { for (j = i + 1; j < model->entries; j++) { if (model->syms[i].cumfreq < model->syms[j].cumfreq) { tmp = model->syms[i]; model->syms[i] = model->syms[j]; model->syms[j] = tmp; } } } /* then convert frequencies back to cumfreq */ for (i = model->entries - 1; i >= 0; i--) { model->syms[i].cumfreq += model->syms[i+1].cumfreq; } } } /* Initialises a model to decode symbols from [start] to [start]+[len]-1 */ static void qtmd_init_model(struct qtmd_model *model, struct qtmd_modelsym *syms, int start, int len) { int i; model->shiftsleft = 4; model->entries = len; model->syms = syms; for (i = 0; i <= len; i++) { syms[i].sym = start + i; /* actual symbol */ syms[i].cumfreq = len - i; /* current frequency of that symbol */ } } /*-------- main Quantum code --------*/ struct qtmd_stream *qtmd_init(struct mspack_system *system, struct mspack_file *input, struct mspack_file *output, int window_bits, int input_buffer_size) { unsigned int window_size = 1 << window_bits; struct qtmd_stream *qtm; int i; if (!system) return NULL; /* Quantum supports window sizes of 2^10 (1Kb) through 2^21 (2Mb) */ if (window_bits < 10 || window_bits > 21) return NULL; /* round up input buffer size to multiple of two */ input_buffer_size = (input_buffer_size + 1) & -2; if (input_buffer_size < 2) return NULL; /* allocate decompression state */ if (!(qtm = (struct qtmd_stream *) system->alloc(system, sizeof(struct qtmd_stream)))) { return NULL; } /* allocate decompression window and input buffer */ qtm->window = (unsigned char *) system->alloc(system, (size_t) window_size); qtm->inbuf = (unsigned char *) system->alloc(system, (size_t) input_buffer_size); if (!qtm->window || !qtm->inbuf) { system->free(qtm->window); system->free(qtm->inbuf); system->free(qtm); return NULL; } /* initialise decompression state */ qtm->sys = system; qtm->input = input; qtm->output = output; qtm->inbuf_size = input_buffer_size; qtm->window_size = window_size; qtm->window_posn = 0; qtm->frame_todo = QTM_FRAME_SIZE; qtm->header_read = 0; qtm->error = MSPACK_ERR_OK; qtm->i_ptr = qtm->i_end = &qtm->inbuf[0]; qtm->o_ptr = qtm->o_end = &qtm->window[0]; qtm->input_end = 0; qtm->bits_left = 0; qtm->bit_buffer = 0; /* initialise arithmetic coding models * - model 4 depends on window size, ranges from 20 to 24 * - model 5 depends on window size, ranges from 20 to 36 * - model 6pos depends on window size, ranges from 20 to 42 */ i = window_bits * 2; qtmd_init_model(&qtm->model0, &qtm->m0sym[0], 0, 64); qtmd_init_model(&qtm->model1, &qtm->m1sym[0], 64, 64); qtmd_init_model(&qtm->model2, &qtm->m2sym[0], 128, 64); qtmd_init_model(&qtm->model3, &qtm->m3sym[0], 192, 64); qtmd_init_model(&qtm->model4, &qtm->m4sym[0], 0, (i > 24) ? 24 : i); qtmd_init_model(&qtm->model5, &qtm->m5sym[0], 0, (i > 36) ? 36 : i); qtmd_init_model(&qtm->model6, &qtm->m6sym[0], 0, i); qtmd_init_model(&qtm->model6len, &qtm->m6lsym[0], 0, 27); qtmd_init_model(&qtm->model7, &qtm->m7sym[0], 0, 7); /* all ok */ return qtm; } int qtmd_decompress(struct qtmd_stream *qtm, off_t out_bytes) { unsigned int frame_todo, frame_end, window_posn, match_offset, range; unsigned char *window, *i_ptr, *i_end, *runsrc, *rundest; int i, j, selector, extra, sym, match_length; unsigned short H, L, C, symf; register unsigned int bit_buffer; register unsigned char bits_left; /* easy answers */ if (!qtm || (out_bytes < 0)) return MSPACK_ERR_ARGS; if (qtm->error) return qtm->error; /* flush out any stored-up bytes before we begin */ i = qtm->o_end - qtm->o_ptr; if ((off_t) i > out_bytes) i = (int) out_bytes; if (i) { if (qtm->sys->write(qtm->output, qtm->o_ptr, i) != i) { return qtm->error = MSPACK_ERR_WRITE; } qtm->o_ptr += i; out_bytes -= i; } if (out_bytes == 0) return MSPACK_ERR_OK; /* restore local state */ RESTORE_BITS; window = qtm->window; window_posn = qtm->window_posn; frame_todo = qtm->frame_todo; H = qtm->H; L = qtm->L; C = qtm->C; /* while we do not have enough decoded bytes in reserve: */ while ((qtm->o_end - qtm->o_ptr) < out_bytes) { /* read header if necessary. Initialises H, L and C */ if (!qtm->header_read) { H = 0xFFFF; L = 0; READ_BITS(C, 16); qtm->header_read = 1; } /* decode more, up to the number of bytes needed, the frame boundary, * or the window boundary, whichever comes first */ frame_end = window_posn + (out_bytes - (qtm->o_end - qtm->o_ptr)); if ((window_posn + frame_todo) < frame_end) { frame_end = window_posn + frame_todo; } if (frame_end > qtm->window_size) { frame_end = qtm->window_size; } while (window_posn < frame_end) { GET_SYMBOL(qtm->model7, selector); if (selector < 4) { /* literal byte */ struct qtmd_model *mdl = (selector == 0) ? &qtm->model0 : ((selector == 1) ? &qtm->model1 : ((selector == 2) ? &qtm->model2 : &qtm->model3)); GET_SYMBOL((*mdl), sym); window[window_posn++] = sym; frame_todo--; } else { /* match repeated string */ switch (selector) { case 4: /* selector 4 = fixed length match (3 bytes) */ GET_SYMBOL(qtm->model4, sym); READ_MANY_BITS(extra, extra_bits[sym]); match_offset = position_base[sym] + extra + 1; match_length = 3; break; case 5: /* selector 5 = fixed length match (4 bytes) */ GET_SYMBOL(qtm->model5, sym); READ_MANY_BITS(extra, extra_bits[sym]); match_offset = position_base[sym] + extra + 1; match_length = 4; break; case 6: /* selector 6 = variable length match */ GET_SYMBOL(qtm->model6len, sym); READ_MANY_BITS(extra, length_extra[sym]); match_length = length_base[sym] + extra + 5; GET_SYMBOL(qtm->model6, sym); READ_MANY_BITS(extra, extra_bits[sym]); match_offset = position_base[sym] + extra + 1; break; default: /* should be impossible, model7 can only return 0-6 */ D(("got %d from selector", selector)) return qtm->error = MSPACK_ERR_DECRUNCH; } rundest = &window[window_posn]; frame_todo -= match_length; /* does match destination wrap the window? This situation is possible * where the window size is less than the 32k frame size, but matches * must not go beyond a frame boundary */ if ((window_posn + match_length) > qtm->window_size) { /* copy first part of match, before window end */ i = qtm->window_size - window_posn; j = window_posn - match_offset; while (i--) *rundest++ = window[j++ & (qtm->window_size - 1)]; /* flush currently stored data */ i = (&window[qtm->window_size] - qtm->o_ptr); /* this should not happen, but if it does then this code * can't handle the situation (can't flush up to the end of * the window, but can't break out either because we haven't * finished writing the match). bail out in this case */ if (i > out_bytes) { D(("during window-wrap match; %d bytes to flush but only need %d", i, (int) out_bytes)) return qtm->error = MSPACK_ERR_DECRUNCH; } if (qtm->sys->write(qtm->output, qtm->o_ptr, i) != i) { return qtm->error = MSPACK_ERR_WRITE; } out_bytes -= i; qtm->o_ptr = &window[0]; qtm->o_end = &window[0]; /* copy second part of match, after window wrap */ rundest = &window[0]; i = match_length - (qtm->window_size - window_posn); while (i--) *rundest++ = window[j++ & (qtm->window_size - 1)]; window_posn = window_posn + match_length - qtm->window_size; break; /* because "window_posn < frame_end" has now failed */ } else { /* normal match - output won't wrap window or frame end */ i = match_length; /* does match _offset_ wrap the window? */ if (match_offset > window_posn) { /* j = length from match offset to end of window */ j = match_offset - window_posn; if (j > (int) qtm->window_size) { D(("match offset beyond window boundaries")) return qtm->error = MSPACK_ERR_DECRUNCH; } runsrc = &window[qtm->window_size - j]; if (j < i) { /* if match goes over the window edge, do two copy runs */ i -= j; while (j-- > 0) *rundest++ = *runsrc++; runsrc = window; } while (i-- > 0) *rundest++ = *runsrc++; } else { runsrc = rundest - match_offset; while (i-- > 0) *rundest++ = *runsrc++; } window_posn += match_length; } } /* if (window_posn+match_length > frame_end) */ } /* while (window_posn < frame_end) */ qtm->o_end = &window[window_posn]; /* if we subtracted too much from frame_todo, it will * wrap around past zero and go above its max value */ if (frame_todo > QTM_FRAME_SIZE) { D(("overshot frame alignment")) return qtm->error = MSPACK_ERR_DECRUNCH; } /* another frame completed? */ if (frame_todo == 0) { /* re-align input */ if (bits_left & 7) REMOVE_BITS(bits_left & 7); /* special Quantum hack -- cabd.c injects a trailer byte to allow the * decompressor to realign itself. CAB Quantum blocks, unlike LZX * blocks, can have anything from 0 to 4 trailing null bytes. */ do { READ_BITS(i, 8); } while (i != 0xFF); qtm->header_read = 0; frame_todo = QTM_FRAME_SIZE; } /* window wrap? */ if (window_posn == qtm->window_size) { /* flush all currently stored data */ i = (qtm->o_end - qtm->o_ptr); /* break out if we have more than enough to finish this request */ if (i >= out_bytes) break; if (qtm->sys->write(qtm->output, qtm->o_ptr, i) != i) { return qtm->error = MSPACK_ERR_WRITE; } out_bytes -= i; qtm->o_ptr = &window[0]; qtm->o_end = &window[0]; window_posn = 0; } } /* while (more bytes needed) */ if (out_bytes) { i = (int) out_bytes; if (qtm->sys->write(qtm->output, qtm->o_ptr, i) != i) { return qtm->error = MSPACK_ERR_WRITE; } qtm->o_ptr += i; } /* store local state */ STORE_BITS; qtm->window_posn = window_posn; qtm->frame_todo = frame_todo; qtm->H = H; qtm->L = L; qtm->C = C; return MSPACK_ERR_OK; } void qtmd_free(struct qtmd_stream *qtm) { struct mspack_system *sys; if (qtm) { sys = qtm->sys; sys->free(qtm->window); sys->free(qtm->inbuf); sys->free(qtm); } }