/* This file is part of libmspack. * (C) 2003-2011 Stuart Caie. * * 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 */ /* Cabinet (.CAB) files are a form of file archive. Each cabinet contains * "folders", which are compressed spans of data. Each cabinet has * "files", whose metadata is in the cabinet header, but whose actual data * is stored compressed in one of the "folders". Cabinets can span more * than one physical file on disk, in which case they are a "cabinet set", * and usually the last folder of each cabinet extends into the next * cabinet. * * For a complete description of the format, see the MSDN site: * http://msdn.microsoft.com/en-us/library/bb267310.aspx */ /* CAB decompression implementation */ #include #include #include /* Notes on compliance with cabinet specification: * * One of the main changes between cabextract 0.6 and libmspack's cab * decompressor is the move from block-oriented decompression to * stream-oriented decompression. * * cabextract would read one data block from disk, decompress it with the * appropriate method, then write the decompressed data. The CAB * specification is specifically designed to work like this, as it ensures * compression matches do not span the maximum decompressed block size * limit of 32kb. * * However, the compression algorithms used are stream oriented, with * specific hacks added to them to enforce the "individual 32kb blocks" * rule in CABs. In other file formats, they do not have this limitation. * * In order to make more generalised decompressors, libmspack's CAB * decompressor has moved from being block-oriented to more stream * oriented. This also makes decompression slightly faster. * * However, this leads to incompliance with the CAB specification. The * CAB controller can no longer ensure each block of input given to the * decompressors is matched with their output. The "decompressed size" of * each individual block is thrown away. * * Each CAB block is supposed to be seen as individually compressed. This * means each consecutive data block can have completely different * "uncompressed" sizes, ranging from 1 to 32768 bytes. However, in * reality, all data blocks in a folder decompress to exactly 32768 bytes, * excepting the final block. * * Given this situation, the decompression algorithms are designed to * realign their input bitstreams on 32768 output-byte boundaries, and * various other special cases have been made. libmspack will not * correctly decompress LZX or Quantum compressed folders where the blocks * do not follow this "32768 bytes until last block" pattern. It could be * implemented if needed, but hopefully this is not necessary -- it has * not been seen in over 3Gb of CAB archives. */ /* prototypes */ static struct mscabd_cabinet * cabd_open( struct mscab_decompressor *base, const char *filename); static void cabd_close( struct mscab_decompressor *base, struct mscabd_cabinet *origcab); static int cabd_read_headers( struct mspack_system *sys, struct mspack_file *fh, struct mscabd_cabinet_p *cab, off_t offset, int quiet); static char *cabd_read_string( struct mspack_system *sys, struct mspack_file *fh, int *error); static struct mscabd_cabinet *cabd_search( struct mscab_decompressor *base, const char *filename); static int cabd_find( struct mscab_decompressor_p *self, unsigned char *buf, struct mspack_file *fh, const char *filename, off_t flen, off_t *firstlen, struct mscabd_cabinet_p **firstcab); static int cabd_prepend( struct mscab_decompressor *base, struct mscabd_cabinet *cab, struct mscabd_cabinet *prevcab); static int cabd_append( struct mscab_decompressor *base, struct mscabd_cabinet *cab, struct mscabd_cabinet *nextcab); static int cabd_merge( struct mscab_decompressor *base, struct mscabd_cabinet *lcab, struct mscabd_cabinet *rcab); static int cabd_can_merge_folders( struct mspack_system *sys, struct mscabd_folder_p *lfol, struct mscabd_folder_p *rfol); static int cabd_extract( struct mscab_decompressor *base, struct mscabd_file *file, const char *filename); static int cabd_init_decomp( struct mscab_decompressor_p *self, unsigned int ct); static void cabd_free_decomp( struct mscab_decompressor_p *self); static int cabd_sys_read( struct mspack_file *file, void *buffer, int bytes); static int cabd_sys_write( struct mspack_file *file, void *buffer, int bytes); static int cabd_sys_read_block( struct mspack_system *sys, struct mscabd_decompress_state *d, int *out, int ignore_cksum); static unsigned int cabd_checksum( unsigned char *data, unsigned int bytes, unsigned int cksum); static struct noned_state *noned_init( struct mspack_system *sys, struct mspack_file *in, struct mspack_file *out, int bufsize); static int noned_decompress( struct noned_state *s, off_t bytes); static void noned_free( struct noned_state *state); static int cabd_param( struct mscab_decompressor *base, int param, int value); static int cabd_error( struct mscab_decompressor *base); /*************************************** * MSPACK_CREATE_CAB_DECOMPRESSOR *************************************** * constructor */ struct mscab_decompressor * mspack_create_cab_decompressor(struct mspack_system *sys) { struct mscab_decompressor_p *self = NULL; if (!sys) sys = mspack_default_system; if (!mspack_valid_system(sys)) return NULL; if ((self = (struct mscab_decompressor_p *) sys->alloc(sys, sizeof(struct mscab_decompressor_p)))) { self->base.open = &cabd_open; self->base.close = &cabd_close; self->base.search = &cabd_search; self->base.extract = &cabd_extract; self->base.prepend = &cabd_prepend; self->base.append = &cabd_append; self->base.set_param = &cabd_param; self->base.last_error = &cabd_error; self->system = sys; self->d = NULL; self->error = MSPACK_ERR_OK; self->param[MSCABD_PARAM_SEARCHBUF] = 32768; self->param[MSCABD_PARAM_FIXMSZIP] = 0; self->param[MSCABD_PARAM_DECOMPBUF] = 4096; } return (struct mscab_decompressor *) self; } /*************************************** * MSPACK_DESTROY_CAB_DECOMPRESSOR *************************************** * destructor */ void mspack_destroy_cab_decompressor(struct mscab_decompressor *base) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) base; if (self) { struct mspack_system *sys = self->system; if (self->d) { if (self->d->infh) sys->close(self->d->infh); cabd_free_decomp(self); sys->free(self->d); } sys->free(self); } } /*************************************** * CABD_OPEN *************************************** * opens a file and tries to read it as a cabinet file */ static struct mscabd_cabinet *cabd_open(struct mscab_decompressor *base, const char *filename) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) base; struct mscabd_cabinet_p *cab = NULL; struct mspack_system *sys; struct mspack_file *fh; int error; if (!base) return NULL; sys = self->system; if ((fh = sys->open(sys, filename, MSPACK_SYS_OPEN_READ))) { if ((cab = (struct mscabd_cabinet_p *) sys->alloc(sys, sizeof(struct mscabd_cabinet_p)))) { cab->base.filename = filename; error = cabd_read_headers(sys, fh, cab, (off_t) 0, 0); if (error) { cabd_close(base, (struct mscabd_cabinet *) cab); cab = NULL; } self->error = error; } else { self->error = MSPACK_ERR_NOMEMORY; } sys->close(fh); } else { self->error = MSPACK_ERR_OPEN; } return (struct mscabd_cabinet *) cab; } /*************************************** * CABD_CLOSE *************************************** * frees all memory associated with a given mscabd_cabinet. */ static void cabd_close(struct mscab_decompressor *base, struct mscabd_cabinet *origcab) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) base; struct mscabd_folder_data *dat, *ndat; struct mscabd_cabinet *cab, *ncab; struct mscabd_folder *fol, *nfol; struct mscabd_file *fi, *nfi; struct mspack_system *sys; if (!base) return; sys = self->system; self->error = MSPACK_ERR_OK; while (origcab) { /* free files */ for (fi = origcab->files; fi; fi = nfi) { nfi = fi->next; sys->free(fi->filename); sys->free(fi); } /* free folders */ for (fol = origcab->folders; fol; fol = nfol) { nfol = fol->next; /* free folder decompression state if it has been decompressed */ if (self->d && (self->d->folder == (struct mscabd_folder_p *) fol)) { if (self->d->infh) sys->close(self->d->infh); cabd_free_decomp(self); sys->free(self->d); self->d = NULL; } /* free folder data segments */ for (dat = ((struct mscabd_folder_p *)fol)->data.next; dat; dat = ndat) { ndat = dat->next; sys->free(dat); } sys->free(fol); } /* free predecessor cabinets (and the original cabinet's strings) */ for (cab = origcab; cab; cab = ncab) { ncab = cab->prevcab; sys->free(cab->prevname); sys->free(cab->nextname); sys->free(cab->previnfo); sys->free(cab->nextinfo); if (cab != origcab) sys->free(cab); } /* free successor cabinets */ for (cab = origcab->nextcab; cab; cab = ncab) { ncab = cab->nextcab; sys->free(cab->prevname); sys->free(cab->nextname); sys->free(cab->previnfo); sys->free(cab->nextinfo); sys->free(cab); } /* free actual cabinet structure */ cab = origcab->next; sys->free(origcab); /* repeat full procedure again with the cab->next pointer (if set) */ origcab = cab; } } /*************************************** * CABD_READ_HEADERS *************************************** * reads the cabinet file header, folder list and file list. * fills out a pre-existing mscabd_cabinet structure, allocates memory * for folders and files as necessary */ static int cabd_read_headers(struct mspack_system *sys, struct mspack_file *fh, struct mscabd_cabinet_p *cab, off_t offset, int quiet) { int num_folders, num_files, folder_resv, i, x; struct mscabd_folder_p *fol, *linkfol = NULL; struct mscabd_file *file, *linkfile = NULL; unsigned char buf[64]; /* initialise pointers */ cab->base.next = NULL; cab->base.files = NULL; cab->base.folders = NULL; cab->base.prevcab = cab->base.nextcab = NULL; cab->base.prevname = cab->base.nextname = NULL; cab->base.previnfo = cab->base.nextinfo = NULL; cab->base.base_offset = offset; /* seek to CFHEADER */ if (sys->seek(fh, offset, MSPACK_SYS_SEEK_START)) { return MSPACK_ERR_SEEK; } /* read in the CFHEADER */ if (sys->read(fh, &buf[0], cfhead_SIZEOF) != cfhead_SIZEOF) { return MSPACK_ERR_READ; } /* check for "MSCF" signature */ if (EndGetI32(&buf[cfhead_Signature]) != 0x4643534D) { return MSPACK_ERR_SIGNATURE; } /* some basic header fields */ cab->base.length = EndGetI32(&buf[cfhead_CabinetSize]); cab->base.set_id = EndGetI16(&buf[cfhead_SetID]); cab->base.set_index = EndGetI16(&buf[cfhead_CabinetIndex]); /* get the number of folders */ num_folders = EndGetI16(&buf[cfhead_NumFolders]); if (num_folders == 0) { if (!quiet) sys->message(fh, "no folders in cabinet."); return MSPACK_ERR_DATAFORMAT; } /* get the number of files */ num_files = EndGetI16(&buf[cfhead_NumFiles]); if (num_files == 0) { if (!quiet) sys->message(fh, "no files in cabinet."); return MSPACK_ERR_DATAFORMAT; } /* check cabinet version */ if ((buf[cfhead_MajorVersion] != 1) && (buf[cfhead_MinorVersion] != 3)) { if (!quiet) sys->message(fh, "WARNING; cabinet version is not 1.3"); } /* read the reserved-sizes part of header, if present */ cab->base.flags = EndGetI16(&buf[cfhead_Flags]); if (cab->base.flags & cfheadRESERVE_PRESENT) { if (sys->read(fh, &buf[0], cfheadext_SIZEOF) != cfheadext_SIZEOF) { return MSPACK_ERR_READ; } cab->base.header_resv = EndGetI16(&buf[cfheadext_HeaderReserved]); folder_resv = buf[cfheadext_FolderReserved]; cab->block_resv = buf[cfheadext_DataReserved]; if (cab->base.header_resv > 60000) { if (!quiet) sys->message(fh, "WARNING; reserved header > 60000."); } /* skip the reserved header */ if (cab->base.header_resv) { if (sys->seek(fh, (off_t) cab->base.header_resv, MSPACK_SYS_SEEK_CUR)) { return MSPACK_ERR_SEEK; } } } else { cab->base.header_resv = 0; folder_resv = 0; cab->block_resv = 0; } /* read name and info of preceeding cabinet in set, if present */ if (cab->base.flags & cfheadPREV_CABINET) { cab->base.prevname = cabd_read_string(sys, fh, &x); if (x) return x; cab->base.previnfo = cabd_read_string(sys, fh, &x); if (x) return x; } /* read name and info of next cabinet in set, if present */ if (cab->base.flags & cfheadNEXT_CABINET) { cab->base.nextname = cabd_read_string(sys, fh, &x); if (x) return x; cab->base.nextinfo = cabd_read_string(sys, fh, &x); if (x) return x; } /* read folders */ for (i = 0; i < num_folders; i++) { if (sys->read(fh, &buf[0], cffold_SIZEOF) != cffold_SIZEOF) { return MSPACK_ERR_READ; } if (folder_resv) { if (sys->seek(fh, (off_t) folder_resv, MSPACK_SYS_SEEK_CUR)) { return MSPACK_ERR_SEEK; } } if (!(fol = (struct mscabd_folder_p *) sys->alloc(sys, sizeof(struct mscabd_folder_p)))) { return MSPACK_ERR_NOMEMORY; } fol->base.next = NULL; fol->base.comp_type = EndGetI16(&buf[cffold_CompType]); fol->base.num_blocks = EndGetI16(&buf[cffold_NumBlocks]); fol->data.next = NULL; fol->data.cab = (struct mscabd_cabinet_p *) cab; fol->data.offset = offset + (off_t) ( (unsigned int) EndGetI32(&buf[cffold_DataOffset]) ); fol->merge_prev = NULL; fol->merge_next = NULL; /* link folder into list of folders */ if (!linkfol) cab->base.folders = (struct mscabd_folder *) fol; else linkfol->base.next = (struct mscabd_folder *) fol; linkfol = fol; } /* read files */ for (i = 0; i < num_files; i++) { if (sys->read(fh, &buf[0], cffile_SIZEOF) != cffile_SIZEOF) { return MSPACK_ERR_READ; } if (!(file = (struct mscabd_file *) sys->alloc(sys, sizeof(struct mscabd_file)))) { return MSPACK_ERR_NOMEMORY; } file->next = NULL; file->length = EndGetI32(&buf[cffile_UncompressedSize]); file->attribs = EndGetI16(&buf[cffile_Attribs]); file->offset = EndGetI32(&buf[cffile_FolderOffset]); /* set folder pointer */ x = EndGetI16(&buf[cffile_FolderIndex]); if (x < cffileCONTINUED_FROM_PREV) { /* normal folder index; count up to the correct folder. the folder * pointer will be NULL if folder index is invalid */ struct mscabd_folder *ifol = cab->base.folders; while (x--) if (ifol) ifol = ifol->next; file->folder = ifol; if (!ifol) { sys->free(file); D(("invalid folder index")) return MSPACK_ERR_DATAFORMAT; } } else { /* either CONTINUED_TO_NEXT, CONTINUED_FROM_PREV or * CONTINUED_PREV_AND_NEXT */ if ((x == cffileCONTINUED_TO_NEXT) || (x == cffileCONTINUED_PREV_AND_NEXT)) { /* get last folder */ struct mscabd_folder *ifol = cab->base.folders; while (ifol->next) ifol = ifol->next; file->folder = ifol; /* set "merge next" pointer */ fol = (struct mscabd_folder_p *) ifol; if (!fol->merge_next) fol->merge_next = file; } if ((x == cffileCONTINUED_FROM_PREV) || (x == cffileCONTINUED_PREV_AND_NEXT)) { /* get first folder */ file->folder = cab->base.folders; /* set "merge prev" pointer */ fol = (struct mscabd_folder_p *) file->folder; if (!fol->merge_prev) fol->merge_prev = file; } } /* get time */ x = EndGetI16(&buf[cffile_Time]); file->time_h = x >> 11; file->time_m = (x >> 5) & 0x3F; file->time_s = (x << 1) & 0x3E; /* get date */ x = EndGetI16(&buf[cffile_Date]); file->date_d = x & 0x1F; file->date_m = (x >> 5) & 0xF; file->date_y = (x >> 9) + 1980; /* get filename */ file->filename = cabd_read_string(sys, fh, &x); if (x) { sys->free(file); return x; } /* link file entry into file list */ if (!linkfile) cab->base.files = file; else linkfile->next = file; linkfile = file; } return MSPACK_ERR_OK; } static char *cabd_read_string(struct mspack_system *sys, struct mspack_file *fh, int *error) { off_t base = sys->tell(fh); char buf[256], *str; unsigned int len, i, ok; /* read up to 256 bytes */ len = sys->read(fh, &buf[0], 256); /* search for a null terminator in the buffer. reject empty strings */ for (i = 1, ok = 0; i < len; i++) if (!buf[i]) { ok = 1; break; } if (!ok) { *error = MSPACK_ERR_DATAFORMAT; return NULL; } len = i + 1; /* set the data stream to just after the string and return */ if (sys->seek(fh, base + (off_t)len, MSPACK_SYS_SEEK_START)) { *error = MSPACK_ERR_SEEK; return NULL; } if (!(str = (char *) sys->alloc(sys, len))) { *error = MSPACK_ERR_NOMEMORY; return NULL; } sys->copy(&buf[0], str, len); *error = MSPACK_ERR_OK; return str; } /*************************************** * CABD_SEARCH, CABD_FIND *************************************** * cabd_search opens a file, finds its extent, allocates a search buffer, * then reads through the whole file looking for possible cabinet headers. * if it finds any, it tries to read them as real cabinets. returns a linked * list of results * * cabd_find is the inner loop of cabd_search, to make it easier to * break out of the loop and be sure that all resources are freed */ static struct mscabd_cabinet *cabd_search(struct mscab_decompressor *base, const char *filename) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) base; struct mscabd_cabinet_p *cab = NULL; struct mspack_system *sys; unsigned char *search_buf; struct mspack_file *fh; off_t filelen, firstlen = 0; if (!base) return NULL; sys = self->system; /* allocate a search buffer */ search_buf = (unsigned char *) sys->alloc(sys, (size_t) self->param[MSCABD_PARAM_SEARCHBUF]); if (!search_buf) { self->error = MSPACK_ERR_NOMEMORY; return NULL; } /* open file and get its full file length */ if ((fh = sys->open(sys, filename, MSPACK_SYS_OPEN_READ))) { if (!(self->error = mspack_sys_filelen(sys, fh, &filelen))) { self->error = cabd_find(self, search_buf, fh, filename, filelen, &firstlen, &cab); } /* truncated / extraneous data warning: */ if (firstlen && (firstlen != filelen) && (!cab || (cab->base.base_offset == 0))) { if (firstlen < filelen) { sys->message(fh, "WARNING; possible %" LD " extra bytes at end of file.", filelen - firstlen); } else { sys->message(fh, "WARNING; file possibly truncated by %" LD " bytes.", firstlen - filelen); } } sys->close(fh); } else { self->error = MSPACK_ERR_OPEN; } /* free the search buffer */ sys->free(search_buf); return (struct mscabd_cabinet *) cab; } static int cabd_find(struct mscab_decompressor_p *self, unsigned char *buf, struct mspack_file *fh, const char *filename, off_t flen, off_t *firstlen, struct mscabd_cabinet_p **firstcab) { struct mscabd_cabinet_p *cab, *link = NULL; off_t caboff, offset, length; struct mspack_system *sys = self->system; unsigned char *p, *pend, state = 0; unsigned int cablen_u32 = 0, foffset_u32 = 0; int false_cabs = 0; #ifndef LARGEFILE_SUPPORT /* detect 32-bit off_t overflow */ if (flen < 0) { sys->message(fh, largefile_msg); return MSPACK_ERR_OK; } #endif /* search through the full file length */ for (offset = 0; offset < flen; offset += length) { /* search length is either the full length of the search buffer, or the * amount of data remaining to the end of the file, whichever is less. */ length = flen - offset; if (length > self->param[MSCABD_PARAM_SEARCHBUF]) { length = self->param[MSCABD_PARAM_SEARCHBUF]; } /* fill the search buffer with data from disk */ if (sys->read(fh, &buf[0], (int) length) != (int) length) { return MSPACK_ERR_READ; } /* FAQ avoidance strategy */ if ((offset == 0) && (EndGetI32(&buf[0]) == 0x28635349)) { sys->message(fh, "WARNING; found InstallShield header. " "This is probably an InstallShield file. " "Use UNSHIELD from www.synce.org to unpack it."); } /* read through the entire buffer. */ for (p = &buf[0], pend = &buf[length]; p < pend; ) { switch (state) { /* starting state */ case 0: /* we spend most of our time in this while loop, looking for * a leading 'M' of the 'MSCF' signature */ while (p < pend && *p != 0x4D) p++; /* if we found tht 'M', advance state */ if (p++ < pend) state = 1; break; /* verify that the next 3 bytes are 'S', 'C' and 'F' */ case 1: state = (*p++ == 0x53) ? 2 : 0; break; case 2: state = (*p++ == 0x43) ? 3 : 0; break; case 3: state = (*p++ == 0x46) ? 4 : 0; break; /* we don't care about bytes 4-7 (see default: for action) */ /* bytes 8-11 are the overall length of the cabinet */ case 8: cablen_u32 = *p++; state++; break; case 9: cablen_u32 |= *p++ << 8; state++; break; case 10: cablen_u32 |= *p++ << 16; state++; break; case 11: cablen_u32 |= *p++ << 24; state++; break; /* we don't care about bytes 12-15 (see default: for action) */ /* bytes 16-19 are the offset within the cabinet of the filedata */ case 16: foffset_u32 = *p++; state++; break; case 17: foffset_u32 |= *p++ << 8; state++; break; case 18: foffset_u32 |= *p++ << 16; state++; break; case 19: foffset_u32 |= *p++ << 24; /* now we have recieved 20 bytes of potential cab header. work out * the offset in the file of this potential cabinet */ caboff = offset + (p - &buf[0]) - 20; /* should reading cabinet fail, restart search just after 'MSCF' */ offset = caboff + 4; /* capture the "length of cabinet" field if there is a cabinet at * offset 0 in the file, regardless of whether the cabinet can be * read correctly or not */ if (caboff == 0) *firstlen = (off_t) cablen_u32; /* check that the files offset is less than the alleged length of * the cabinet, and that the offset + the alleged length are * 'roughly' within the end of overall file length */ if ((foffset_u32 < cablen_u32) && ((caboff + (off_t) foffset_u32) < (flen + 32)) && ((caboff + (off_t) cablen_u32) < (flen + 32)) ) { /* likely cabinet found -- try reading it */ if (!(cab = (struct mscabd_cabinet_p *) sys->alloc(sys, sizeof(struct mscabd_cabinet_p)))) { return MSPACK_ERR_NOMEMORY; } cab->base.filename = filename; if (cabd_read_headers(sys, fh, cab, caboff, 1)) { /* destroy the failed cabinet */ cabd_close((struct mscab_decompressor *) self, (struct mscabd_cabinet *) cab); false_cabs++; } else { /* cabinet read correctly! */ /* link the cab into the list */ if (!link) *firstcab = cab; else link->base.next = (struct mscabd_cabinet *) cab; link = cab; /* cause the search to restart after this cab's data. */ offset = caboff + (off_t) cablen_u32; #ifndef LARGEFILE_SUPPORT /* detect 32-bit off_t overflow */ if (offset < caboff) { sys->message(fh, largefile_msg); return MSPACK_ERR_OK; } #endif } } /* restart search */ if (offset >= flen) return MSPACK_ERR_OK; if (sys->seek(fh, offset, MSPACK_SYS_SEEK_START)) { return MSPACK_ERR_SEEK; } length = 0; p = pend; state = 0; break; /* for bytes 4-7 and 12-15, just advance state/pointer */ default: p++, state++; } /* switch(state) */ } /* for (... p < pend ...) */ } /* for (... offset < length ...) */ if (false_cabs) { D(("%d false cabinets found", false_cabs)) } return MSPACK_ERR_OK; } /*************************************** * CABD_MERGE, CABD_PREPEND, CABD_APPEND *************************************** * joins cabinets together, also merges split folders between these two * cabinets only. This includes freeing the duplicate folder and file(s) * and allocating a further mscabd_folder_data structure to append to the * merged folder's data parts list. */ static int cabd_prepend(struct mscab_decompressor *base, struct mscabd_cabinet *cab, struct mscabd_cabinet *prevcab) { return cabd_merge(base, prevcab, cab); } static int cabd_append(struct mscab_decompressor *base, struct mscabd_cabinet *cab, struct mscabd_cabinet *nextcab) { return cabd_merge(base, cab, nextcab); } static int cabd_merge(struct mscab_decompressor *base, struct mscabd_cabinet *lcab, struct mscabd_cabinet *rcab) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) base; struct mscabd_folder_data *data, *ndata; struct mscabd_folder_p *lfol, *rfol; struct mscabd_file *fi, *rfi, *lfi; struct mscabd_cabinet *cab; struct mspack_system *sys; if (!self) return MSPACK_ERR_ARGS; sys = self->system; /* basic args check */ if (!lcab || !rcab || (lcab == rcab)) { D(("lcab NULL, rcab NULL or lcab = rcab")) return self->error = MSPACK_ERR_ARGS; } /* check there's not already a cabinet attached */ if (lcab->nextcab || rcab->prevcab) { D(("cabs already joined")) return self->error = MSPACK_ERR_ARGS; } /* do not create circular cabinet chains */ for (cab = lcab->prevcab; cab; cab = cab->prevcab) { if (cab == rcab) {D(("circular!")) return self->error = MSPACK_ERR_ARGS;} } for (cab = rcab->nextcab; cab; cab = cab->nextcab) { if (cab == lcab) {D(("circular!")) return self->error = MSPACK_ERR_ARGS;} } /* warn about odd set IDs or indices */ if (lcab->set_id != rcab->set_id) { sys->message(NULL, "WARNING; merged cabinets with differing Set IDs."); } if (lcab->set_index > rcab->set_index) { sys->message(NULL, "WARNING; merged cabinets with odd order."); } /* merging the last folder in lcab with the first folder in rcab */ lfol = (struct mscabd_folder_p *) lcab->folders; rfol = (struct mscabd_folder_p *) rcab->folders; while (lfol->base.next) lfol = (struct mscabd_folder_p *) lfol->base.next; /* do we need to merge folders? */ if (!lfol->merge_next && !rfol->merge_prev) { /* no, at least one of the folders is not for merging */ /* attach cabs */ lcab->nextcab = rcab; rcab->prevcab = lcab; /* attach folders */ lfol->base.next = (struct mscabd_folder *) rfol; /* attach files */ fi = lcab->files; while (fi->next) fi = fi->next; fi->next = rcab->files; } else { /* folder merge required - do the files match? */ if (! cabd_can_merge_folders(sys, lfol, rfol)) { return self->error = MSPACK_ERR_DATAFORMAT; } /* allocate a new folder data structure */ if (!(data = (struct mscabd_folder_data *) sys->alloc(sys, sizeof(struct mscabd_folder_data)))) { return self->error = MSPACK_ERR_NOMEMORY; } /* attach cabs */ lcab->nextcab = rcab; rcab->prevcab = lcab; /* append rfol's data to lfol */ ndata = &lfol->data; while (ndata->next) ndata = ndata->next; ndata->next = data; *data = rfol->data; rfol->data.next = NULL; /* lfol becomes rfol. * NOTE: special case, don't merge if rfol is merge prev and next, * rfol->merge_next is going to be deleted, so keep lfol's version * instead */ lfol->base.num_blocks += rfol->base.num_blocks - 1; if ((rfol->merge_next == NULL) || (rfol->merge_next->folder != (struct mscabd_folder *) rfol)) { lfol->merge_next = rfol->merge_next; } /* attach the rfol's folder (except the merge folder) */ while (lfol->base.next) lfol = (struct mscabd_folder_p *) lfol->base.next; lfol->base.next = rfol->base.next; /* free disused merge folder */ sys->free(rfol); /* attach rfol's files */ fi = lcab->files; while (fi->next) fi = fi->next; fi->next = rcab->files; /* delete all files from rfol's merge folder */ lfi = NULL; for (fi = lcab->files; fi ; fi = rfi) { rfi = fi->next; /* if file's folder matches the merge folder, unlink and free it */ if (fi->folder == (struct mscabd_folder *) rfol) { if (lfi) lfi->next = rfi; else lcab->files = rfi; sys->free(fi->filename); sys->free(fi); } else lfi = fi; } } /* all done! fix files and folders pointers in all cabs so they all * point to the same list */ for (cab = lcab->prevcab; cab; cab = cab->prevcab) { cab->files = lcab->files; cab->folders = lcab->folders; } for (cab = lcab->nextcab; cab; cab = cab->nextcab) { cab->files = lcab->files; cab->folders = lcab->folders; } return self->error = MSPACK_ERR_OK; } /* decides if two folders are OK to merge */ static int cabd_can_merge_folders(struct mspack_system *sys, struct mscabd_folder_p *lfol, struct mscabd_folder_p *rfol) { struct mscabd_file *lfi, *rfi, *l, *r; int matching = 1; /* check that both folders use the same compression method/settings */ if (lfol->base.comp_type != rfol->base.comp_type) { D(("folder merge: compression type mismatch")) return 0; } /* check there are not too many data blocks after merging */ if ((lfol->base.num_blocks + rfol->base.num_blocks) > CAB_FOLDERMAX) { D(("folder merge: too many data blocks in merged folders")) return 0; } if (!(lfi = lfol->merge_next) || !(rfi = rfol->merge_prev)) { D(("folder merge: one cabinet has no files to merge")) return 0; } /* for all files in lfol (which is the last folder in whichever cab and * only has files to merge), compare them to the files from rfol. They * should be identical in number and order. to verify this, check the * offset and length of each file. */ for (l=lfi, r=rfi; l; l=l->next, r=r->next) { if (!r || (l->offset != r->offset) || (l->length != r->length)) { matching = 0; break; } } if (matching) return 1; /* if rfol does not begin with an identical copy of the files in lfol, make * make a judgement call; if at least ONE file from lfol is in rfol, allow * the merge with a warning about missing files. */ matching = 0; for (l = lfi; l; l = l->next) { for (r = rfi; r; r = r->next) { if (l->offset == r->offset && l->length == r->length) break; } if (r) matching = 1; else sys->message(NULL, "WARNING; merged file %s not listed in both cabinets", l->filename); } return matching; } /*************************************** * CABD_EXTRACT *************************************** * extracts a file from a cabinet */ static int cabd_extract(struct mscab_decompressor *base, struct mscabd_file *file, const char *filename) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) base; struct mscabd_folder_p *fol; struct mspack_system *sys; struct mspack_file *fh; if (!self) return MSPACK_ERR_ARGS; if (!file) return self->error = MSPACK_ERR_ARGS; sys = self->system; fol = (struct mscabd_folder_p *) file->folder; /* validate the file's offset and length */ if ( (file->offset > CAB_LENGTHMAX) || (file->length > CAB_LENGTHMAX) || ((file->offset + file->length) > CAB_LENGTHMAX)) { return self->error = MSPACK_ERR_DATAFORMAT; } /* check if file can be extracted */ if ((!fol) || (fol->merge_prev) || (((file->offset + file->length) / CAB_BLOCKMAX) > fol->base.num_blocks)) { sys->message(NULL, "ERROR; file \"%s\" cannot be extracted, " "cabinet set is incomplete.", file->filename); return self->error = MSPACK_ERR_DATAFORMAT; } /* allocate generic decompression state */ if (!self->d) { self->d = (struct mscabd_decompress_state *) sys->alloc(sys, sizeof(struct mscabd_decompress_state)); if (!self->d) return self->error = MSPACK_ERR_NOMEMORY; self->d->folder = NULL; self->d->data = NULL; self->d->sys = *sys; self->d->sys.read = &cabd_sys_read; self->d->sys.write = &cabd_sys_write; self->d->state = NULL; self->d->infh = NULL; self->d->incab = NULL; } /* do we need to change folder or reset the current folder? */ if ((self->d->folder != fol) || (self->d->offset > file->offset) || !self->d->state) { /* free any existing decompressor */ cabd_free_decomp(self); /* do we need to open a new cab file? */ if (!self->d->infh || (fol->data.cab != self->d->incab)) { /* close previous file handle if from a different cab */ if (self->d->infh) sys->close(self->d->infh); self->d->incab = fol->data.cab; self->d->infh = sys->open(sys, fol->data.cab->base.filename, MSPACK_SYS_OPEN_READ); if (!self->d->infh) return self->error = MSPACK_ERR_OPEN; } /* seek to start of data blocks */ if (sys->seek(self->d->infh, fol->data.offset, MSPACK_SYS_SEEK_START)) { return self->error = MSPACK_ERR_SEEK; } /* set up decompressor */ if (cabd_init_decomp(self, (unsigned int) fol->base.comp_type)) { return self->error; } /* initialise new folder state */ self->d->folder = fol; self->d->data = &fol->data; self->d->offset = 0; self->d->block = 0; self->d->i_ptr = self->d->i_end = &self->d->input[0]; /* read_error lasts for the lifetime of a decompressor */ self->read_error = MSPACK_ERR_OK; } /* open file for output */ if (!(fh = sys->open(sys, filename, MSPACK_SYS_OPEN_WRITE))) { return self->error = MSPACK_ERR_OPEN; } self->error = MSPACK_ERR_OK; /* if file has more than 0 bytes */ if (file->length) { off_t bytes; int error; /* get to correct offset. * - use NULL fh to say 'no writing' to cabd_sys_write() * - if cabd_sys_read() has an error, it will set self->read_error * and pass back MSPACK_ERR_READ */ self->d->outfh = NULL; if ((bytes = file->offset - self->d->offset)) { error = self->d->decompress(self->d->state, bytes); self->error = (error == MSPACK_ERR_READ) ? self->read_error : error; } /* if getting to the correct offset was error free, unpack file */ if (!self->error) { self->d->outfh = fh; error = self->d->decompress(self->d->state, (off_t) file->length); self->error = (error == MSPACK_ERR_READ) ? self->read_error : error; } } /* close output file */ sys->close(fh); self->d->outfh = NULL; return self->error; } /*************************************** * CABD_INIT_DECOMP, CABD_FREE_DECOMP *************************************** * cabd_init_decomp initialises decompression state, according to which * decompression method was used. relies on self->d->folder being the same * as when initialised. * * cabd_free_decomp frees decompression state, according to which method * was used. */ static int cabd_init_decomp(struct mscab_decompressor_p *self, unsigned int ct) { struct mspack_file *fh = (struct mspack_file *) self; assert(self && self->d); self->d->comp_type = ct; switch (ct & cffoldCOMPTYPE_MASK) { case cffoldCOMPTYPE_NONE: self->d->decompress = (int (*)(void *, off_t)) &noned_decompress; self->d->state = noned_init(&self->d->sys, fh, fh, self->param[MSCABD_PARAM_DECOMPBUF]); break; case cffoldCOMPTYPE_MSZIP: self->d->decompress = (int (*)(void *, off_t)) &mszipd_decompress; self->d->state = mszipd_init(&self->d->sys, fh, fh, self->param[MSCABD_PARAM_DECOMPBUF], self->param[MSCABD_PARAM_FIXMSZIP]); break; case cffoldCOMPTYPE_QUANTUM: self->d->decompress = (int (*)(void *, off_t)) &qtmd_decompress; self->d->state = qtmd_init(&self->d->sys, fh, fh, (int) (ct >> 8) & 0x1f, self->param[MSCABD_PARAM_DECOMPBUF]); break; case cffoldCOMPTYPE_LZX: self->d->decompress = (int (*)(void *, off_t)) &lzxd_decompress; self->d->state = lzxd_init(&self->d->sys, fh, fh, (int) (ct >> 8) & 0x1f, 0, self->param[MSCABD_PARAM_DECOMPBUF], (off_t)0,0); break; default: return self->error = MSPACK_ERR_DATAFORMAT; } return self->error = (self->d->state) ? MSPACK_ERR_OK : MSPACK_ERR_NOMEMORY; } static void cabd_free_decomp(struct mscab_decompressor_p *self) { if (!self || !self->d || !self->d->state) return; switch (self->d->comp_type & cffoldCOMPTYPE_MASK) { case cffoldCOMPTYPE_NONE: noned_free((struct noned_state *) self->d->state); break; case cffoldCOMPTYPE_MSZIP: mszipd_free((struct mszipd_stream *) self->d->state); break; case cffoldCOMPTYPE_QUANTUM: qtmd_free((struct qtmd_stream *) self->d->state); break; case cffoldCOMPTYPE_LZX: lzxd_free((struct lzxd_stream *) self->d->state); break; } self->d->decompress = NULL; self->d->state = NULL; } /*************************************** * CABD_SYS_READ, CABD_SYS_WRITE *************************************** * cabd_sys_read is the internal reader function which the decompressors * use. will read data blocks (and merge split blocks) from the cabinet * and serve the read bytes to the decompressors * * cabd_sys_write is the internal writer function which the decompressors * use. it either writes data to disk (self->d->outfh) with the real * sys->write() function, or does nothing with the data when * self->d->outfh == NULL. advances self->d->offset */ static int cabd_sys_read(struct mspack_file *file, void *buffer, int bytes) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) file; unsigned char *buf = (unsigned char *) buffer; struct mspack_system *sys = self->system; int avail, todo, outlen, ignore_cksum; ignore_cksum = self->param[MSCABD_PARAM_FIXMSZIP] && ((self->d->comp_type & cffoldCOMPTYPE_MASK) == cffoldCOMPTYPE_MSZIP); todo = bytes; while (todo > 0) { avail = self->d->i_end - self->d->i_ptr; /* if out of input data, read a new block */ if (avail) { /* copy as many input bytes available as possible */ if (avail > todo) avail = todo; sys->copy(self->d->i_ptr, buf, (size_t) avail); self->d->i_ptr += avail; buf += avail; todo -= avail; } else { /* out of data, read a new block */ /* check if we're out of input blocks, advance block counter */ if (self->d->block++ >= self->d->folder->base.num_blocks) { self->read_error = MSPACK_ERR_DATAFORMAT; break; } /* read a block */ self->read_error = cabd_sys_read_block(sys, self->d, &outlen, ignore_cksum); if (self->read_error) return -1; /* special Quantum hack -- 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. */ if ((self->d->comp_type & cffoldCOMPTYPE_MASK)==cffoldCOMPTYPE_QUANTUM) { *self->d->i_end++ = 0xFF; } /* is this the last block? */ if (self->d->block >= self->d->folder->base.num_blocks) { /* last block */ if ((self->d->comp_type & cffoldCOMPTYPE_MASK) == cffoldCOMPTYPE_LZX) { /* special LZX hack -- on the last block, inform LZX of the * size of the output data stream. */ lzxd_set_output_length((struct lzxd_stream *) self->d->state, (off_t) ((self->d->block-1) * CAB_BLOCKMAX + outlen)); } } else { /* not the last block */ if (outlen != CAB_BLOCKMAX) { self->system->message(self->d->infh, "WARNING; non-maximal data block"); } } } /* if (avail) */ } /* while (todo > 0) */ return bytes - todo; } static int cabd_sys_write(struct mspack_file *file, void *buffer, int bytes) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) file; self->d->offset += bytes; if (self->d->outfh) { return self->system->write(self->d->outfh, buffer, bytes); } return bytes; } /*************************************** * CABD_SYS_READ_BLOCK *************************************** * reads a whole data block from a cab file. the block may span more than * one cab file, if it does then the fragments will be reassembled */ static int cabd_sys_read_block(struct mspack_system *sys, struct mscabd_decompress_state *d, int *out, int ignore_cksum) { unsigned char hdr[cfdata_SIZEOF]; unsigned int cksum; int len; /* reset the input block pointer and end of block pointer */ d->i_ptr = d->i_end = &d->input[0]; do { /* read the block header */ if (sys->read(d->infh, &hdr[0], cfdata_SIZEOF) != cfdata_SIZEOF) { return MSPACK_ERR_READ; } /* skip any reserved block headers */ if (d->data->cab->block_resv && sys->seek(d->infh, (off_t) d->data->cab->block_resv, MSPACK_SYS_SEEK_CUR)) { return MSPACK_ERR_SEEK; } /* blocks must not be over CAB_INPUTMAX in size */ len = EndGetI16(&hdr[cfdata_CompressedSize]); if (((d->i_end - d->i_ptr) + len) > CAB_INPUTMAX) { D(("block size > CAB_INPUTMAX (%ld + %d)", (long)(d->i_end - d->i_ptr), len)) return MSPACK_ERR_DATAFORMAT; } /* blocks must not expand to more than CAB_BLOCKMAX */ if (EndGetI16(&hdr[cfdata_UncompressedSize]) > CAB_BLOCKMAX) { D(("block size > CAB_BLOCKMAX")) return MSPACK_ERR_DATAFORMAT; } /* read the block data */ if (sys->read(d->infh, d->i_end, len) != len) { return MSPACK_ERR_READ; } /* perform checksum test on the block (if one is stored) */ if ((cksum = EndGetI32(&hdr[cfdata_CheckSum]))) { unsigned int sum2 = cabd_checksum(d->i_end, (unsigned int) len, 0); if (cabd_checksum(&hdr[4], 4, sum2) != cksum) { if (!ignore_cksum) return MSPACK_ERR_CHECKSUM; sys->message(d->infh, "WARNING; bad block checksum found"); } } /* advance end of block pointer to include newly read data */ d->i_end += len; /* uncompressed size == 0 means this block was part of a split block * and it continues as the first block of the next cabinet in the set. * otherwise, this is the last part of the block, and no more block * reading needs to be done. */ /* EXIT POINT OF LOOP -- uncompressed size != 0 */ if ((*out = EndGetI16(&hdr[cfdata_UncompressedSize]))) { return MSPACK_ERR_OK; } /* otherwise, advance to next cabinet */ /* close current file handle */ sys->close(d->infh); d->infh = NULL; /* advance to next member in the cabinet set */ if (!(d->data = d->data->next)) { D(("ran out of splits in cabinet set")) return MSPACK_ERR_DATAFORMAT; } /* open next cab file */ d->incab = d->data->cab; if (!(d->infh = sys->open(sys, d->incab->base.filename, MSPACK_SYS_OPEN_READ))) { return MSPACK_ERR_OPEN; } /* seek to start of data blocks */ if (sys->seek(d->infh, d->data->offset, MSPACK_SYS_SEEK_START)) { return MSPACK_ERR_SEEK; } } while (1); /* not reached */ return MSPACK_ERR_OK; } static unsigned int cabd_checksum(unsigned char *data, unsigned int bytes, unsigned int cksum) { unsigned int len, ul = 0; for (len = bytes >> 2; len--; data += 4) { cksum ^= ((data[0]) | (data[1]<<8) | (data[2]<<16) | (data[3]<<24)); } switch (bytes & 3) { case 3: ul |= *data++ << 16; case 2: ul |= *data++ << 8; case 1: ul |= *data; } cksum ^= ul; return cksum; } /*************************************** * NONED_INIT, NONED_DECOMPRESS, NONED_FREE *************************************** * the "not compressed" method decompressor */ struct noned_state { struct mspack_system *sys; struct mspack_file *i; struct mspack_file *o; unsigned char *buf; int bufsize; }; static struct noned_state *noned_init(struct mspack_system *sys, struct mspack_file *in, struct mspack_file *out, int bufsize) { struct noned_state *state = (struct noned_state *) sys->alloc(sys, sizeof(struct noned_state)); unsigned char *buf = (unsigned char *) sys->alloc(sys, (size_t) bufsize); if (state && buf) { state->sys = sys; state->i = in; state->o = out; state->buf = buf; state->bufsize = bufsize; } else { sys->free(buf); sys->free(state); state = NULL; } return state; } static int noned_decompress(struct noned_state *s, off_t bytes) { int run; while (bytes > 0) { run = (bytes > s->bufsize) ? s->bufsize : (int) bytes; if (s->sys->read(s->i, &s->buf[0], run) != run) return MSPACK_ERR_READ; if (s->sys->write(s->o, &s->buf[0], run) != run) return MSPACK_ERR_WRITE; bytes -= run; } return MSPACK_ERR_OK; } static void noned_free(struct noned_state *state) { struct mspack_system *sys; if (state) { sys = state->sys; sys->free(state->buf); sys->free(state); } } /*************************************** * CABD_PARAM *************************************** * allows a parameter to be set */ static int cabd_param(struct mscab_decompressor *base, int param, int value) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) base; if (!self) return MSPACK_ERR_ARGS; switch (param) { case MSCABD_PARAM_SEARCHBUF: if (value < 4) return MSPACK_ERR_ARGS; self->param[MSCABD_PARAM_SEARCHBUF] = value; break; case MSCABD_PARAM_FIXMSZIP: self->param[MSCABD_PARAM_FIXMSZIP] = value; break; case MSCABD_PARAM_DECOMPBUF: if (value < 4) return MSPACK_ERR_ARGS; self->param[MSCABD_PARAM_DECOMPBUF] = value; break; default: return MSPACK_ERR_ARGS; } return MSPACK_ERR_OK; } /*************************************** * CABD_ERROR *************************************** * returns the last error that occurred */ static int cabd_error(struct mscab_decompressor *base) { struct mscab_decompressor_p *self = (struct mscab_decompressor_p *) base; return (self) ? self->error : MSPACK_ERR_ARGS; }