""" olefile (formerly OleFileIO_PL) Module to read/write Microsoft OLE2 files (also called Structured Storage or Microsoft Compound Document File Format), such as Microsoft Office 97-2003 documents, Image Composer and FlashPix files, Outlook messages, ... This version is compatible with Python 2.7 and 3.4+ Project website: https://www.decalage.info/olefile olefile is copyright (c) 2005-2018 Philippe Lagadec (https://www.decalage.info) olefile is based on the OleFileIO module from the PIL library v1.1.7 See: http://www.pythonware.com/products/pil/index.htm and http://svn.effbot.org/public/tags/pil-1.1.7/PIL/OleFileIO.py The Python Imaging Library (PIL) is Copyright (c) 1997-2009 by Secret Labs AB Copyright (c) 1995-2009 by Fredrik Lundh See source code and LICENSE.txt for information on usage and redistribution. """ # Since OleFileIO_PL v0.45, only Python 2.7 and 3.4+ are supported # This import enables print() as a function rather than a keyword # (main requirement to be compatible with Python 3.x) # The comment on the line below should be printed on Python 2.5 or older: from __future__ import print_function # This version of olefile requires Python 2.7 or 3.4+. #--- LICENSE ------------------------------------------------------------------ # olefile (formerly OleFileIO_PL) is copyright (c) 2005-2018 Philippe Lagadec # (https://www.decalage.info) # # All rights reserved. # # Redistribution and use in source and binary forms, with or without modification, # are permitted provided that the following conditions are met: # # * Redistributions of source code must retain the above copyright notice, this # list of conditions and the following disclaimer. # * Redistributions in binary form must reproduce the above copyright notice, # this list of conditions and the following disclaimer in the documentation # and/or other materials provided with the distribution. # # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND # ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED # WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE # DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE # FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL # DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR # SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER # CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, # OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. # ---------- # PIL License: # # olefile is based on source code from the OleFileIO module of the Python # Imaging Library (PIL) published by Fredrik Lundh under the following license: # The Python Imaging Library (PIL) is # Copyright (c) 1997-2009 by Secret Labs AB # Copyright (c) 1995-2009 by Fredrik Lundh # # By obtaining, using, and/or copying this software and/or its associated # documentation, you agree that you have read, understood, and will comply with # the following terms and conditions: # # Permission to use, copy, modify, and distribute this software and its # associated documentation for any purpose and without fee is hereby granted, # provided that the above copyright notice appears in all copies, and that both # that copyright notice and this permission notice appear in supporting # documentation, and that the name of Secret Labs AB or the author(s) not be used # in advertising or publicity pertaining to distribution of the software # without specific, written prior permission. # # SECRET LABS AB AND THE AUTHORS DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS # SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. # IN NO EVENT SHALL SECRET LABS AB OR THE AUTHORS BE LIABLE FOR ANY SPECIAL, # INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM # LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR # OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR # PERFORMANCE OF THIS SOFTWARE. __date__ = "2018-09-09" __version__ = '0.46' __author__ = "Philippe Lagadec" __all__ = ['isOleFile', 'OleFileIO', 'OleMetadata', 'enable_logging', 'MAGIC', 'STGTY_EMPTY', 'KEEP_UNICODE_NAMES', 'STGTY_STREAM', 'STGTY_STORAGE', 'STGTY_ROOT', 'STGTY_PROPERTY', 'STGTY_LOCKBYTES', 'MINIMAL_OLEFILE_SIZE', 'DEFECT_UNSURE', 'DEFECT_POTENTIAL', 'DEFECT_INCORRECT', 'DEFECT_FATAL', 'DEFAULT_PATH_ENCODING', 'MAXREGSECT', 'DIFSECT', 'FATSECT', 'ENDOFCHAIN', 'FREESECT', 'MAXREGSID', 'NOSTREAM', 'UNKNOWN_SIZE', 'WORD_CLSID' ] import io import sys import struct, array, os.path, datetime, logging #=== COMPATIBILITY WORKAROUNDS ================================================ # For Python 3.x, need to redefine long as int: if str is not bytes: long = int # Need to make sure we use xrange both on Python 2 and 3.x: try: # on Python 2 we need xrange: iterrange = xrange except: # no xrange, for Python 3 it was renamed as range: iterrange = range #[PL] workaround to fix an issue with array item size on 64 bits systems: if array.array('L').itemsize == 4: # on 32 bits platforms, long integers in an array are 32 bits: UINT32 = 'L' elif array.array('I').itemsize == 4: # on 64 bits platforms, integers in an array are 32 bits: UINT32 = 'I' elif array.array('i').itemsize == 4: # On 64 bit Jython, signed integers ('i') are the only way to store our 32 # bit values in an array in a *somewhat* reasonable way, as the otherwise # perfectly suited 'H' (unsigned int, 32 bits) results in a completely # unusable behaviour. This is most likely caused by the fact that Java # doesn't have unsigned values, and thus Jython's "array" implementation, # which is based on "jarray", doesn't have them either. # NOTE: to trick Jython into converting the values it would normally # interpret as "signed" into "unsigned", a binary-and operation with # 0xFFFFFFFF can be used. This way it is possible to use the same comparing # operations on all platforms / implementations. The corresponding code # lines are flagged with a 'JYTHON-WORKAROUND' tag below. UINT32 = 'i' else: raise ValueError('Need to fix a bug with 32 bit arrays, please contact author...') #[PL] These workarounds were inspired from the Path module # (see http://www.jorendorff.com/articles/python/path/) try: basestring except NameError: basestring = str #[PL] Experimental setting: if True, OLE filenames will be kept in Unicode # if False (default PIL behaviour), all filenames are converted to Latin-1. KEEP_UNICODE_NAMES = True if sys.version_info[0] < 3: # On Python 2.x, the default encoding for path names is UTF-8: DEFAULT_PATH_ENCODING = 'utf-8' else: # On Python 3.x, the default encoding for path names is Unicode (None): DEFAULT_PATH_ENCODING = None # === LOGGING ================================================================= def get_logger(name, level=logging.CRITICAL+1): """ Create a suitable logger object for this module. The goal is not to change settings of the root logger, to avoid getting other modules' logs on the screen. If a logger exists with same name, reuse it. (Else it would have duplicate handlers and messages would be doubled.) The level is set to CRITICAL+1 by default, to avoid any logging. """ # First, test if there is already a logger with the same name, else it # will generate duplicate messages (due to duplicate handlers): if name in logging.Logger.manager.loggerDict: #NOTE: another less intrusive but more "hackish" solution would be to # use getLogger then test if its effective level is not default. logger = logging.getLogger(name) # make sure level is OK: logger.setLevel(level) return logger # get a new logger: logger = logging.getLogger(name) # only add a NullHandler for this logger, it is up to the application # to configure its own logging: logger.addHandler(logging.NullHandler()) logger.setLevel(level) return logger # a global logger object used for debugging: log = get_logger('olefile') def enable_logging(): """ Enable logging for this module (disabled by default). This will set the module-specific logger level to NOTSET, which means the main application controls the actual logging level. """ log.setLevel(logging.NOTSET) #=== CONSTANTS =============================================================== #: magic bytes that should be at the beginning of every OLE file: MAGIC = b'\xD0\xCF\x11\xE0\xA1\xB1\x1A\xE1' #[PL]: added constants for Sector IDs (from AAF specifications) MAXREGSECT = 0xFFFFFFFA #: (-6) maximum SECT DIFSECT = 0xFFFFFFFC #: (-4) denotes a DIFAT sector in a FAT FATSECT = 0xFFFFFFFD #: (-3) denotes a FAT sector in a FAT ENDOFCHAIN = 0xFFFFFFFE #: (-2) end of a virtual stream chain FREESECT = 0xFFFFFFFF #: (-1) unallocated sector #[PL]: added constants for Directory Entry IDs (from AAF specifications) MAXREGSID = 0xFFFFFFFA #: (-6) maximum directory entry ID NOSTREAM = 0xFFFFFFFF #: (-1) unallocated directory entry #[PL] object types in storage (from AAF specifications) STGTY_EMPTY = 0 #: empty directory entry STGTY_STORAGE = 1 #: element is a storage object STGTY_STREAM = 2 #: element is a stream object STGTY_LOCKBYTES = 3 #: element is an ILockBytes object STGTY_PROPERTY = 4 #: element is an IPropertyStorage object STGTY_ROOT = 5 #: element is a root storage # Unknown size for a stream (used by OleStream): UNKNOWN_SIZE = 0x7FFFFFFF # # -------------------------------------------------------------------- # property types VT_EMPTY=0; VT_NULL=1; VT_I2=2; VT_I4=3; VT_R4=4; VT_R8=5; VT_CY=6; VT_DATE=7; VT_BSTR=8; VT_DISPATCH=9; VT_ERROR=10; VT_BOOL=11; VT_VARIANT=12; VT_UNKNOWN=13; VT_DECIMAL=14; VT_I1=16; VT_UI1=17; VT_UI2=18; VT_UI4=19; VT_I8=20; VT_UI8=21; VT_INT=22; VT_UINT=23; VT_VOID=24; VT_HRESULT=25; VT_PTR=26; VT_SAFEARRAY=27; VT_CARRAY=28; VT_USERDEFINED=29; VT_LPSTR=30; VT_LPWSTR=31; VT_FILETIME=64; VT_BLOB=65; VT_STREAM=66; VT_STORAGE=67; VT_STREAMED_OBJECT=68; VT_STORED_OBJECT=69; VT_BLOB_OBJECT=70; VT_CF=71; VT_CLSID=72; VT_VECTOR=0x1000; # map property id to name (for debugging purposes) # VT = {} # for keyword, var in list(vars().items()): # if keyword[:3] == "VT_": # VT[var] = keyword # # -------------------------------------------------------------------- # Some common document types (root.clsid fields) WORD_CLSID = "00020900-0000-0000-C000-000000000046" #TODO: check Excel, PPT, ... #[PL]: Defect levels to classify parsing errors - see OleFileIO._raise_defect() DEFECT_UNSURE = 10 # a case which looks weird, but not sure it's a defect DEFECT_POTENTIAL = 20 # a potential defect DEFECT_INCORRECT = 30 # an error according to specifications, but parsing # can go on DEFECT_FATAL = 40 # an error which cannot be ignored, parsing is # impossible # Minimal size of an empty OLE file, with 512-bytes sectors = 1536 bytes # (this is used in isOleFile and OleFile.open) MINIMAL_OLEFILE_SIZE = 1536 #=== FUNCTIONS =============================================================== def isOleFile (filename): """ Test if a file is an OLE container (according to the magic bytes in its header). .. note:: This function only checks the first 8 bytes of the file, not the rest of the OLE structure. .. versionadded:: 0.16 :param filename: filename, contents or file-like object of the OLE file (string-like or file-like object) - if filename is a string smaller than 1536 bytes, it is the path of the file to open. (bytes or unicode string) - if filename is a string longer than 1535 bytes, it is parsed as the content of an OLE file in memory. (bytes type only) - if filename is a file-like object (with read and seek methods), it is parsed as-is. :type filename: bytes or str or unicode or file :returns: True if OLE, False otherwise. :rtype: bool """ # check if filename is a string-like or file-like object: if hasattr(filename, 'read'): # file-like object: use it directly header = filename.read(len(MAGIC)) # just in case, seek back to start of file: filename.seek(0) elif isinstance(filename, bytes) and len(filename) >= MINIMAL_OLEFILE_SIZE: # filename is a bytes string containing the OLE file to be parsed: header = filename[:len(MAGIC)] else: # string-like object: filename of file on disk with open(filename, 'rb') as fp: header = fp.read(len(MAGIC)) if header == MAGIC: return True else: return False if bytes is str: # version for Python 2.x def i8(c): return ord(c) else: # version for Python 3.x def i8(c): return c if c.__class__ is int else c[0] def i16(c, o = 0): """ Converts a 2-bytes (16 bits) string to an integer. :param c: string containing bytes to convert :param o: offset of bytes to convert in string """ return struct.unpack(" len(fat): self.ole._raise_defect(DEFECT_INCORRECT, 'malformed OLE document, stream too large') # optimization(?): data is first a list of strings, and join() is called # at the end to concatenate all in one string. # (this may not be really useful with recent Python versions) data = [] # if size is zero, then first sector index should be ENDOFCHAIN: if size == 0 and sect != ENDOFCHAIN: log.debug('size == 0 and sect != ENDOFCHAIN:') self.ole._raise_defect(DEFECT_INCORRECT, 'incorrect OLE sector index for empty stream') #[PL] A fixed-length for loop is used instead of an undefined while # loop to avoid DoS attacks: for i in range(nb_sectors): log.debug('Reading stream sector[%d] = %Xh' % (i, sect)) # Sector index may be ENDOFCHAIN, but only if size was unknown if sect == ENDOFCHAIN: if unknown_size: log.debug('Reached ENDOFCHAIN sector for stream with unknown size') break else: # else this means that the stream is smaller than declared: log.debug('sect=ENDOFCHAIN before expected size') self.ole._raise_defect(DEFECT_INCORRECT, 'incomplete OLE stream') # sector index should be within FAT: if sect<0 or sect>=len(fat): log.debug('sect=%d (%X) / len(fat)=%d' % (sect, sect, len(fat))) log.debug('i=%d / nb_sectors=%d' %(i, nb_sectors)) ## tmp_data = b"".join(data) ## f = open('test_debug.bin', 'wb') ## f.write(tmp_data) ## f.close() ## log.debug('data read so far: %d bytes' % len(tmp_data)) self.ole._raise_defect(DEFECT_INCORRECT, 'incorrect OLE FAT, sector index out of range') # stop reading here if the exception is ignored: break #TODO: merge this code with OleFileIO.getsect() ? #TODO: check if this works with 4K sectors: try: fp.seek(offset + sectorsize * sect) except: log.debug('sect=%d, seek=%d, filesize=%d' % (sect, offset+sectorsize*sect, filesize)) self.ole._raise_defect(DEFECT_INCORRECT, 'OLE sector index out of range') # stop reading here if the exception is ignored: break sector_data = fp.read(sectorsize) # [PL] check if there was enough data: # Note: if sector is the last of the file, sometimes it is not a # complete sector (of 512 or 4K), so we may read less than # sectorsize. if len(sector_data)!=sectorsize and sect!=(len(fat)-1): log.debug('sect=%d / len(fat)=%d, seek=%d / filesize=%d, len read=%d' % (sect, len(fat), offset+sectorsize*sect, filesize, len(sector_data))) log.debug('seek+len(read)=%d' % (offset+sectorsize*sect+len(sector_data))) self.ole._raise_defect(DEFECT_INCORRECT, 'incomplete OLE sector') data.append(sector_data) # jump to next sector in the FAT: try: sect = fat[sect] & 0xFFFFFFFF # JYTHON-WORKAROUND except IndexError: # [PL] if pointer is out of the FAT an exception is raised self.ole._raise_defect(DEFECT_INCORRECT, 'incorrect OLE FAT, sector index out of range') # stop reading here if the exception is ignored: break #[PL] Last sector should be a "end of chain" marker: # if sect != ENDOFCHAIN: # raise IOError('incorrect last sector index in OLE stream') data = b"".join(data) # Data is truncated to the actual stream size: if len(data) >= size: log.debug('Read data of length %d, truncated to stream size %d' % (len(data), size)) data = data[:size] # actual stream size is stored for future use: self.size = size elif unknown_size: # actual stream size was not known, now we know the size of read # data: log.debug('Read data of length %d, the stream size was unknown' % len(data)) self.size = len(data) else: # read data is less than expected: log.debug('Read data of length %d, less than expected stream size %d' % (len(data), size)) # TODO: provide details in exception message self.size = len(data) self.ole._raise_defect(DEFECT_INCORRECT, 'OLE stream size is less than declared') # when all data is read in memory, BytesIO constructor is called io.BytesIO.__init__(self, data) # Then the OleStream object can be used as a read-only file object. #--- OleDirectoryEntry ------------------------------------------------------- class OleDirectoryEntry: """ OLE2 Directory Entry """ #[PL] parsing code moved from OleFileIO.loaddirectory # struct to parse directory entries: # <: little-endian byte order, standard sizes # (note: this should guarantee that Q returns a 64 bits int) # 64s: string containing entry name in unicode UTF-16 (max 31 chars) + null char = 64 bytes # H: uint16, number of bytes used in name buffer, including null = (len+1)*2 # B: uint8, dir entry type (between 0 and 5) # B: uint8, color: 0=black, 1=red # I: uint32, index of left child node in the red-black tree, NOSTREAM if none # I: uint32, index of right child node in the red-black tree, NOSTREAM if none # I: uint32, index of child root node if it is a storage, else NOSTREAM # 16s: CLSID, unique identifier (only used if it is a storage) # I: uint32, user flags # Q (was 8s): uint64, creation timestamp or zero # Q (was 8s): uint64, modification timestamp or zero # I: uint32, SID of first sector if stream or ministream, SID of 1st sector # of stream containing ministreams if root entry, 0 otherwise # I: uint32, total stream size in bytes if stream (low 32 bits), 0 otherwise # I: uint32, total stream size in bytes if stream (high 32 bits), 0 otherwise STRUCT_DIRENTRY = '<64sHBBIII16sIQQIII' # size of a directory entry: 128 bytes DIRENTRY_SIZE = 128 assert struct.calcsize(STRUCT_DIRENTRY) == DIRENTRY_SIZE def __init__(self, entry, sid, olefile): """ Constructor for an OleDirectoryEntry object. Parses a 128-bytes entry from the OLE Directory stream. :param entry : string (must be 128 bytes long) :param sid : index of this directory entry in the OLE file directory :param olefile: OleFileIO containing this directory entry """ self.sid = sid # ref to olefile is stored for future use self.olefile = olefile # kids is a list of children entries, if this entry is a storage: # (list of OleDirectoryEntry objects) self.kids = [] # kids_dict is a dictionary of children entries, indexed by their # name in lowercase: used to quickly find an entry, and to detect # duplicates self.kids_dict = {} # flag used to detect if the entry is referenced more than once in # directory: self.used = False # decode DirEntry ( self.name_raw, # 64s: string containing entry name in unicode UTF-16 (max 31 chars) + null char = 64 bytes self.namelength, # H: uint16, number of bytes used in name buffer, including null = (len+1)*2 self.entry_type, self.color, self.sid_left, self.sid_right, self.sid_child, clsid, self.dwUserFlags, self.createTime, self.modifyTime, self.isectStart, self.sizeLow, self.sizeHigh ) = struct.unpack(OleDirectoryEntry.STRUCT_DIRENTRY, entry) if self.entry_type not in [STGTY_ROOT, STGTY_STORAGE, STGTY_STREAM, STGTY_EMPTY]: olefile._raise_defect(DEFECT_INCORRECT, 'unhandled OLE storage type') # only first directory entry can (and should) be root: if self.entry_type == STGTY_ROOT and sid != 0: olefile._raise_defect(DEFECT_INCORRECT, 'duplicate OLE root entry') if sid == 0 and self.entry_type != STGTY_ROOT: olefile._raise_defect(DEFECT_INCORRECT, 'incorrect OLE root entry') #log.debug(struct.unpack(fmt_entry, entry[:len_entry])) # name should be at most 31 unicode characters + null character, # so 64 bytes in total (31*2 + 2): if self.namelength>64: olefile._raise_defect(DEFECT_INCORRECT, 'incorrect DirEntry name length >64 bytes') # if exception not raised, namelength is set to the maximum value: self.namelength = 64 # only characters without ending null char are kept: self.name_utf16 = self.name_raw[:(self.namelength-2)] #TODO: check if the name is actually followed by a null unicode character ([MS-CFB] 2.6.1) #TODO: check if the name does not contain forbidden characters: # [MS-CFB] 2.6.1: "The following characters are illegal and MUST NOT be part of the name: '/', '\', ':', '!'." # name is converted from UTF-16LE to the path encoding specified in the OleFileIO: self.name = olefile._decode_utf16_str(self.name_utf16) log.debug('DirEntry SID=%d: %s' % (self.sid, repr(self.name))) log.debug(' - type: %d' % self.entry_type) log.debug(' - sect: %Xh' % self.isectStart) log.debug(' - SID left: %d, right: %d, child: %d' % (self.sid_left, self.sid_right, self.sid_child)) # sizeHigh is only used for 4K sectors, it should be zero for 512 bytes # sectors, BUT apparently some implementations set it as 0xFFFFFFFF, 1 # or some other value so it cannot be raised as a defect in general: if olefile.sectorsize == 512: if self.sizeHigh != 0 and self.sizeHigh != 0xFFFFFFFF: log.debug('sectorsize=%d, sizeLow=%d, sizeHigh=%d (%X)' % (olefile.sectorsize, self.sizeLow, self.sizeHigh, self.sizeHigh)) olefile._raise_defect(DEFECT_UNSURE, 'incorrect OLE stream size') self.size = self.sizeLow else: self.size = self.sizeLow + (long(self.sizeHigh)<<32) log.debug(' - size: %d (sizeLow=%d, sizeHigh=%d)' % (self.size, self.sizeLow, self.sizeHigh)) self.clsid = _clsid(clsid) # a storage should have a null size, BUT some implementations such as # Word 8 for Mac seem to allow non-null values => Potential defect: if self.entry_type == STGTY_STORAGE and self.size != 0: olefile._raise_defect(DEFECT_POTENTIAL, 'OLE storage with size>0') # check if stream is not already referenced elsewhere: self.is_minifat = False if self.entry_type in (STGTY_ROOT, STGTY_STREAM) and self.size>0: if self.size < olefile.minisectorcutoff \ and self.entry_type==STGTY_STREAM: # only streams can be in MiniFAT # ministream object self.is_minifat = True else: self.is_minifat = False olefile._check_duplicate_stream(self.isectStart, self.is_minifat) self.sect_chain = None def build_sect_chain(self, olefile): if self.sect_chain: return if self.entry_type not in (STGTY_ROOT, STGTY_STREAM) or self.size == 0: return self.sect_chain = list() if self.is_minifat and not olefile.minifat: olefile.loadminifat() next_sect = self.isectStart while next_sect != ENDOFCHAIN: self.sect_chain.append(next_sect) if self.is_minifat: next_sect = olefile.minifat[next_sect] else: next_sect = olefile.fat[next_sect] def build_storage_tree(self): """ Read and build the red-black tree attached to this OleDirectoryEntry object, if it is a storage. Note that this method builds a tree of all subentries, so it should only be called for the root object once. """ log.debug('build_storage_tree: SID=%d - %s - sid_child=%d' % (self.sid, repr(self.name), self.sid_child)) if self.sid_child != NOSTREAM: # if child SID is not NOSTREAM, then this entry is a storage. # Let's walk through the tree of children to fill the kids list: self.append_kids(self.sid_child) # Note from OpenOffice documentation: the safest way is to # recreate the tree because some implementations may store broken # red-black trees... # in the OLE file, entries are sorted on (length, name). # for convenience, we sort them on name instead: # (see rich comparison methods in this class) self.kids.sort() def append_kids(self, child_sid): """ Walk through red-black tree of children of this directory entry to add all of them to the kids list. (recursive method) :param child_sid: index of child directory entry to use, or None when called first time for the root. (only used during recursion) """ log.debug('append_kids: child_sid=%d' % child_sid) #[PL] this method was added to use simple recursion instead of a complex # algorithm. # if this is not a storage or a leaf of the tree, nothing to do: if child_sid == NOSTREAM: return # check if child SID is in the proper range: if child_sid<0 or child_sid>=len(self.olefile.direntries): self.olefile._raise_defect(DEFECT_INCORRECT, 'OLE DirEntry index out of range') else: # get child direntry: child = self.olefile._load_direntry(child_sid) #direntries[child_sid] log.debug('append_kids: child_sid=%d - %s - sid_left=%d, sid_right=%d, sid_child=%d' % (child.sid, repr(child.name), child.sid_left, child.sid_right, child.sid_child)) # Check if kid was not already referenced in a storage: if child.used: self.olefile._raise_defect(DEFECT_INCORRECT, 'OLE Entry referenced more than once') return child.used = True # the directory entries are organized as a red-black tree. # (cf. Wikipedia for details) # First walk through left side of the tree: self.append_kids(child.sid_left) # Check if its name is not already used (case-insensitive): name_lower = child.name.lower() if name_lower in self.kids_dict: self.olefile._raise_defect(DEFECT_INCORRECT, "Duplicate filename in OLE storage") # Then the child_sid OleDirectoryEntry object is appended to the # kids list and dictionary: self.kids.append(child) self.kids_dict[name_lower] = child # Finally walk through right side of the tree: self.append_kids(child.sid_right) # Afterwards build kid's own tree if it's also a storage: child.build_storage_tree() def __eq__(self, other): "Compare entries by name" return self.name == other.name def __lt__(self, other): "Compare entries by name" return self.name < other.name def __ne__(self, other): return not self.__eq__(other) def __le__(self, other): return self.__eq__(other) or self.__lt__(other) # Reflected __lt__() and __le__() will be used for __gt__() and __ge__() #TODO: replace by the same function as MS implementation ? # (order by name length first, then case-insensitive order) def dump(self, tab = 0): "Dump this entry, and all its subentries (for debug purposes only)" TYPES = ["(invalid)", "(storage)", "(stream)", "(lockbytes)", "(property)", "(root)"] try: type_name = TYPES[self.entry_type] except IndexError: type_name = '(UNKNOWN)' print(" "*tab + repr(self.name), type_name, end=' ') if self.entry_type in (STGTY_STREAM, STGTY_ROOT): print(self.size, "bytes", end=' ') print() if self.entry_type in (STGTY_STORAGE, STGTY_ROOT) and self.clsid: print(" "*tab + "{%s}" % self.clsid) for kid in self.kids: kid.dump(tab + 2) def getmtime(self): """ Return modification time of a directory entry. :returns: None if modification time is null, a python datetime object otherwise (UTC timezone) new in version 0.26 """ if self.modifyTime == 0: return None return filetime2datetime(self.modifyTime) def getctime(self): """ Return creation time of a directory entry. :returns: None if modification time is null, a python datetime object otherwise (UTC timezone) new in version 0.26 """ if self.createTime == 0: return None return filetime2datetime(self.createTime) #--- OleFileIO ---------------------------------------------------------------- class OleFileIO: """ OLE container object This class encapsulates the interface to an OLE 2 structured storage file. Use the listdir and openstream methods to access the contents of this file. Object names are given as a list of strings, one for each subentry level. The root entry should be omitted. For example, the following code extracts all image streams from a Microsoft Image Composer file:: ole = OleFileIO("fan.mic") for entry in ole.listdir(): if entry[1:2] == "Image": fin = ole.openstream(entry) fout = open(entry[0:1], "wb") while True: s = fin.read(8192) if not s: break fout.write(s) You can use the viewer application provided with the Python Imaging Library to view the resulting files (which happens to be standard TIFF files). """ def __init__(self, filename=None, raise_defects=DEFECT_FATAL, write_mode=False, debug=False, path_encoding=DEFAULT_PATH_ENCODING): """ Constructor for the OleFileIO class. :param filename: file to open. - if filename is a string smaller than 1536 bytes, it is the path of the file to open. (bytes or unicode string) - if filename is a string longer than 1535 bytes, it is parsed as the content of an OLE file in memory. (bytes type only) - if filename is a file-like object (with read, seek and tell methods), it is parsed as-is. :param raise_defects: minimal level for defects to be raised as exceptions. (use DEFECT_FATAL for a typical application, DEFECT_INCORRECT for a security-oriented application, see source code for details) :param write_mode: bool, if True the file is opened in read/write mode instead of read-only by default. :param debug: bool, set debug mode (deprecated, not used anymore) :param path_encoding: None or str, name of the codec to use for path names (streams and storages), or None for Unicode. Unicode by default on Python 3+, UTF-8 on Python 2.x. (new in olefile 0.42, was hardcoded to Latin-1 until olefile v0.41) """ # minimal level for defects to be raised as exceptions: self._raise_defects_level = raise_defects #: list of defects/issues not raised as exceptions: #: tuples of (exception type, message) self.parsing_issues = [] self.write_mode = write_mode self.path_encoding = path_encoding # initialize all attributes to default values: self._filesize = None self.ministream = None self._used_streams_fat = [] self._used_streams_minifat = [] self.byte_order = None self.directory_fp = None self.direntries = None self.dll_version = None self.fat = None self.first_difat_sector = None self.first_dir_sector = None self.first_mini_fat_sector = None self.fp = None self.header_clsid = None self.header_signature = None self.metadata = None self.mini_sector_shift = None self.mini_sector_size = None self.mini_stream_cutoff_size = None self.minifat = None self.minifatsect = None # TODO: duplicates? self.minisectorcutoff = None self.minisectorsize = None self.ministream = None self.minor_version = None self.nb_sect = None self.num_difat_sectors = None self.num_dir_sectors = None self.num_fat_sectors = None self.num_mini_fat_sectors = None self.reserved1 = None self.reserved2 = None self.root = None self.sector_shift = None self.sector_size = None self.transaction_signature_number = None if filename: self.open(filename, write_mode=write_mode) def __enter__(self): return self def __exit__(self, *args): self.close() def _raise_defect(self, defect_level, message, exception_type=IOError): """ This method should be called for any defect found during file parsing. It may raise an IOError exception according to the minimal level chosen for the OleFileIO object. :param defect_level: defect level, possible values are: - DEFECT_UNSURE : a case which looks weird, but not sure it's a defect - DEFECT_POTENTIAL : a potential defect - DEFECT_INCORRECT : an error according to specifications, but parsing can go on - DEFECT_FATAL : an error which cannot be ignored, parsing is impossible :param message: string describing the defect, used with raised exception. :param exception_type: exception class to be raised, IOError by default """ # added by [PL] if defect_level >= self._raise_defects_level: log.error(message) raise exception_type(message) else: # just record the issue, no exception raised: self.parsing_issues.append((exception_type, message)) log.warning(message) def _decode_utf16_str(self, utf16_str, errors='replace'): """ Decode a string encoded in UTF-16 LE format, as found in the OLE directory or in property streams. Return a string encoded according to the path_encoding specified for the OleFileIO object. :param utf16_str: bytes string encoded in UTF-16 LE format :param errors: str, see python documentation for str.decode() :return: str, encoded according to path_encoding """ unicode_str = utf16_str.decode('UTF-16LE', errors) if self.path_encoding: # an encoding has been specified for path names: return unicode_str.encode(self.path_encoding, errors) else: # path_encoding=None, return the Unicode string as-is: return unicode_str def open(self, filename, write_mode=False): """ Open an OLE2 file in read-only or read/write mode. Read and parse the header, FAT and directory. :param filename: string-like or file-like object, OLE file to parse - if filename is a string smaller than 1536 bytes, it is the path of the file to open. (bytes or unicode string) - if filename is a string longer than 1535 bytes, it is parsed as the content of an OLE file in memory. (bytes type only) - if filename is a file-like object (with read, seek and tell methods), it is parsed as-is. :param write_mode: bool, if True the file is opened in read/write mode instead of read-only by default. (ignored if filename is not a path) """ self.write_mode = write_mode #[PL] check if filename is a string-like or file-like object: # (it is better to check for a read() method) if hasattr(filename, 'read'): #TODO: also check seek and tell methods? # file-like object: use it directly self.fp = filename elif isinstance(filename, bytes) and len(filename) >= MINIMAL_OLEFILE_SIZE: # filename is a bytes string containing the OLE file to be parsed: # convert it to BytesIO self.fp = io.BytesIO(filename) else: # string-like object: filename of file on disk if self.write_mode: # open file in mode 'read with update, binary' # According to https://docs.python.org/2/library/functions.html#open # 'w' would truncate the file, 'a' may only append on some Unixes mode = 'r+b' else: # read-only mode by default mode = 'rb' self.fp = open(filename, mode) # obtain the filesize by using seek and tell, which should work on most # file-like objects: #TODO: do it above, using getsize with filename when possible? #TODO: fix code to fail with clear exception when filesize cannot be obtained filesize=0 self.fp.seek(0, os.SEEK_END) try: filesize = self.fp.tell() finally: self.fp.seek(0) self._filesize = filesize log.debug('File size: %d bytes (%Xh)' % (self._filesize, self._filesize)) # lists of streams in FAT and MiniFAT, to detect duplicate references # (list of indexes of first sectors of each stream) self._used_streams_fat = [] self._used_streams_minifat = [] header = self.fp.read(512) if len(header) != 512 or header[:8] != MAGIC: log.debug('Magic = %r instead of %r' % (header[:8], MAGIC)) self._raise_defect(DEFECT_FATAL, "not an OLE2 structured storage file") # [PL] header structure according to AAF specifications: ##Header ##struct StructuredStorageHeader { // [offset from start (bytes), length (bytes)] ##BYTE _abSig[8]; // [00H,08] {0xd0, 0xcf, 0x11, 0xe0, 0xa1, 0xb1, ## // 0x1a, 0xe1} for current version ##CLSID _clsid; // [08H,16] reserved must be zero (WriteClassStg/ ## // GetClassFile uses root directory class id) ##USHORT _uMinorVersion; // [18H,02] minor version of the format: 33 is ## // written by reference implementation ##USHORT _uDllVersion; // [1AH,02] major version of the dll/format: 3 for ## // 512-byte sectors, 4 for 4 KB sectors ##USHORT _uByteOrder; // [1CH,02] 0xFFFE: indicates Intel byte-ordering ##USHORT _uSectorShift; // [1EH,02] size of sectors in power-of-two; ## // typically 9 indicating 512-byte sectors ##USHORT _uMiniSectorShift; // [20H,02] size of mini-sectors in power-of-two; ## // typically 6 indicating 64-byte mini-sectors ##USHORT _usReserved; // [22H,02] reserved, must be zero ##ULONG _ulReserved1; // [24H,04] reserved, must be zero ##FSINDEX _csectDir; // [28H,04] must be zero for 512-byte sectors, ## // number of SECTs in directory chain for 4 KB ## // sectors ##FSINDEX _csectFat; // [2CH,04] number of SECTs in the FAT chain ##SECT _sectDirStart; // [30H,04] first SECT in the directory chain ##DFSIGNATURE _signature; // [34H,04] signature used for transactions; must ## // be zero. The reference implementation ## // does not support transactions ##ULONG _ulMiniSectorCutoff; // [38H,04] maximum size for a mini stream; ## // typically 4096 bytes ##SECT _sectMiniFatStart; // [3CH,04] first SECT in the MiniFAT chain ##FSINDEX _csectMiniFat; // [40H,04] number of SECTs in the MiniFAT chain ##SECT _sectDifStart; // [44H,04] first SECT in the DIFAT chain ##FSINDEX _csectDif; // [48H,04] number of SECTs in the DIFAT chain ##SECT _sectFat[109]; // [4CH,436] the SECTs of first 109 FAT sectors ##}; # [PL] header decoding: # '<' indicates little-endian byte ordering for Intel (cf. struct module help) fmt_header = '<8s16sHHHHHHLLLLLLLLLL' header_size = struct.calcsize(fmt_header) log.debug( "fmt_header size = %d, +FAT = %d" % (header_size, header_size + 109*4) ) header1 = header[:header_size] ( self.header_signature, self.header_clsid, self.minor_version, self.dll_version, self.byte_order, self.sector_shift, self.mini_sector_shift, self.reserved1, self.reserved2, self.num_dir_sectors, self.num_fat_sectors, self.first_dir_sector, self.transaction_signature_number, self.mini_stream_cutoff_size, self.first_mini_fat_sector, self.num_mini_fat_sectors, self.first_difat_sector, self.num_difat_sectors ) = struct.unpack(fmt_header, header1) log.debug( struct.unpack(fmt_header, header1)) if self.header_signature != MAGIC: # OLE signature should always be present self._raise_defect(DEFECT_FATAL, "incorrect OLE signature") if self.header_clsid != bytearray(16): # according to AAF specs, CLSID should always be zero self._raise_defect(DEFECT_INCORRECT, "incorrect CLSID in OLE header") log.debug( "Minor Version = %d" % self.minor_version ) # TODO: according to MS-CFB, minor version should be 0x003E log.debug( "DLL Version = %d (expected: 3 or 4)" % self.dll_version ) if self.dll_version not in [3, 4]: # version 3: usual format, 512 bytes per sector # version 4: large format, 4K per sector self._raise_defect(DEFECT_INCORRECT, "incorrect DllVersion in OLE header") log.debug( "Byte Order = %X (expected: FFFE)" % self.byte_order ) if self.byte_order != 0xFFFE: # For now only common little-endian documents are handled correctly self._raise_defect(DEFECT_INCORRECT, "incorrect ByteOrder in OLE header") # TODO: add big-endian support for documents created on Mac ? # But according to [MS-CFB] ? v20140502, ByteOrder MUST be 0xFFFE. self.sector_size = 2**self.sector_shift log.debug( "Sector Size = %d bytes (expected: 512 or 4096)" % self.sector_size ) if self.sector_size not in [512, 4096]: self._raise_defect(DEFECT_INCORRECT, "incorrect sector_size in OLE header") if (self.dll_version==3 and self.sector_size!=512) \ or (self.dll_version==4 and self.sector_size!=4096): self._raise_defect(DEFECT_INCORRECT, "sector_size does not match DllVersion in OLE header") self.mini_sector_size = 2**self.mini_sector_shift log.debug( "MiniFAT Sector Size = %d bytes (expected: 64)" % self.mini_sector_size ) if self.mini_sector_size not in [64]: self._raise_defect(DEFECT_INCORRECT, "incorrect mini_sector_size in OLE header") if self.reserved1 != 0 or self.reserved2 != 0: self._raise_defect(DEFECT_INCORRECT, "incorrect OLE header (non-null reserved bytes)") log.debug( "Number of Directory sectors = %d" % self.num_dir_sectors ) # Number of directory sectors (only allowed if DllVersion != 3) if self.sector_size==512 and self.num_dir_sectors!=0: self._raise_defect(DEFECT_INCORRECT, "incorrect number of directory sectors in OLE header") log.debug( "Number of FAT sectors = %d" % self.num_fat_sectors ) # num_fat_sectors = number of FAT sectors in the file log.debug( "First Directory sector = %Xh" % self.first_dir_sector ) # first_dir_sector = 1st sector containing the directory log.debug( "Transaction Signature Number = %d" % self.transaction_signature_number ) # Signature should be zero, BUT some implementations do not follow this # rule => only a potential defect: # (according to MS-CFB, may be != 0 for applications supporting file # transactions) if self.transaction_signature_number != 0: self._raise_defect(DEFECT_POTENTIAL, "incorrect OLE header (transaction_signature_number>0)") log.debug( "Mini Stream cutoff size = %Xh (expected: 1000h)" % self.mini_stream_cutoff_size ) # MS-CFB: This integer field MUST be set to 0x00001000. This field # specifies the maximum size of a user-defined data stream allocated # from the mini FAT and mini stream, and that cutoff is 4096 bytes. # Any user-defined data stream larger than or equal to this cutoff size # must be allocated as normal sectors from the FAT. if self.mini_stream_cutoff_size != 0x1000: self._raise_defect(DEFECT_INCORRECT, "incorrect mini_stream_cutoff_size in OLE header") # if no exception is raised, the cutoff size is fixed to 0x1000 log.warning('Fixing the mini_stream_cutoff_size to 4096 (mandatory value) instead of %d' % self.mini_stream_cutoff_size) self.mini_stream_cutoff_size = 0x1000 # TODO: check if these values are OK log.debug( "First MiniFAT sector = %Xh" % self.first_mini_fat_sector ) log.debug( "Number of MiniFAT sectors = %d" % self.num_mini_fat_sectors ) log.debug( "First DIFAT sector = %Xh" % self.first_difat_sector ) log.debug( "Number of DIFAT sectors = %d" % self.num_difat_sectors ) # calculate the number of sectors in the file # (-1 because header doesn't count) self.nb_sect = ( (filesize + self.sector_size-1) // self.sector_size) - 1 log.debug( "Maximum number of sectors in the file: %d (%Xh)" % (self.nb_sect, self.nb_sect)) #TODO: change this test, because an OLE file MAY contain other data # after the last sector. # file clsid self.header_clsid = _clsid(header[8:24]) #TODO: remove redundant attributes, and fix the code which uses them? self.sectorsize = self.sector_size #1 << i16(header, 30) self.minisectorsize = self.mini_sector_size #1 << i16(header, 32) self.minisectorcutoff = self.mini_stream_cutoff_size # i32(header, 56) # check known streams for duplicate references (these are always in FAT, # never in MiniFAT): self._check_duplicate_stream(self.first_dir_sector) # check MiniFAT only if it is not empty: if self.num_mini_fat_sectors: self._check_duplicate_stream(self.first_mini_fat_sector) # check DIFAT only if it is not empty: if self.num_difat_sectors: self._check_duplicate_stream(self.first_difat_sector) # Load file allocation tables self.loadfat(header) # Load directory. This sets both the direntries list (ordered by sid) # and the root (ordered by hierarchy) members. self.loaddirectory(self.first_dir_sector) self.minifatsect = self.first_mini_fat_sector def close(self): """ close the OLE file, to release the file object """ self.fp.close() def _check_duplicate_stream(self, first_sect, minifat=False): """ Checks if a stream has not been already referenced elsewhere. This method should only be called once for each known stream, and only if stream size is not null. :param first_sect: int, index of first sector of the stream in FAT :param minifat: bool, if True, stream is located in the MiniFAT, else in the FAT """ if minifat: log.debug('_check_duplicate_stream: sect=%Xh in MiniFAT' % first_sect) used_streams = self._used_streams_minifat else: log.debug('_check_duplicate_stream: sect=%Xh in FAT' % first_sect) # some values can be safely ignored (not a real stream): if first_sect in (DIFSECT,FATSECT,ENDOFCHAIN,FREESECT): return used_streams = self._used_streams_fat #TODO: would it be more efficient using a dict or hash values, instead # of a list of long ? if first_sect in used_streams: self._raise_defect(DEFECT_INCORRECT, 'Stream referenced twice') else: used_streams.append(first_sect) def dumpfat(self, fat, firstindex=0): """ Display a part of FAT in human-readable form for debugging purposes """ # dictionary to convert special FAT values in human-readable strings VPL = 8 # values per line (8+1 * 8+1 = 81) fatnames = { FREESECT: "..free..", ENDOFCHAIN: "[ END. ]", FATSECT: "FATSECT ", DIFSECT: "DIFSECT " } nbsect = len(fat) nlines = (nbsect+VPL-1)//VPL print("index", end=" ") for i in range(VPL): print("%8X" % i, end=" ") print() for l in range(nlines): index = l*VPL print("%6X:" % (firstindex+index), end=" ") for i in range(index, index+VPL): if i>=nbsect: break sect = fat[i] aux = sect & 0xFFFFFFFF # JYTHON-WORKAROUND if aux in fatnames: name = fatnames[aux] else: if sect == i+1: name = " --->" else: name = "%8X" % sect print(name, end=" ") print() def dumpsect(self, sector, firstindex=0): """ Display a sector in a human-readable form, for debugging purposes """ VPL=8 # number of values per line (8+1 * 8+1 = 81) tab = array.array(UINT32, sector) if sys.byteorder == 'big': tab.byteswap() nbsect = len(tab) nlines = (nbsect+VPL-1)//VPL print("index", end=" ") for i in range(VPL): print("%8X" % i, end=" ") print() for l in range(nlines): index = l*VPL print("%6X:" % (firstindex+index), end=" ") for i in range(index, index+VPL): if i>=nbsect: break sect = tab[i] name = "%8X" % sect print(name, end=" ") print() def sect2array(self, sect): """ convert a sector to an array of 32 bits unsigned integers, swapping bytes on big endian CPUs such as PowerPC (old Macs) """ a = array.array(UINT32, sect) # if CPU is big endian, swap bytes: if sys.byteorder == 'big': a.byteswap() return a def loadfat_sect(self, sect): """ Adds the indexes of the given sector to the FAT :param sect: string containing the first FAT sector, or array of long integers :returns: index of last FAT sector. """ # a FAT sector is an array of ulong integers. if isinstance(sect, array.array): # if sect is already an array it is directly used fat1 = sect else: # if it's a raw sector, it is parsed in an array fat1 = self.sect2array(sect) # Display the sector contents only if the logging level is debug: if log.isEnabledFor(logging.DEBUG): self.dumpsect(sect) # The FAT is a sector chain starting at the first index of itself. # initialize isect, just in case: isect = None for isect in fat1: isect = isect & 0xFFFFFFFF # JYTHON-WORKAROUND log.debug("isect = %X" % isect) if isect == ENDOFCHAIN or isect == FREESECT: # the end of the sector chain has been reached log.debug("found end of sector chain") break # read the FAT sector s = self.getsect(isect) # parse it as an array of 32 bits integers, and add it to the # global FAT array nextfat = self.sect2array(s) self.fat = self.fat + nextfat return isect def loadfat(self, header): """ Load the FAT table. """ # The 1st sector of the file contains sector numbers for the first 109 # FAT sectors, right after the header which is 76 bytes long. # (always 109, whatever the sector size: 512 bytes = 76+4*109) # Additional sectors are described by DIF blocks log.debug('Loading the FAT table, starting with the 1st sector after the header') sect = header[76:512] log.debug( "len(sect)=%d, so %d integers" % (len(sect), len(sect)//4) ) #fat = [] # [PL] FAT is an array of 32 bits unsigned ints, it's more effective # to use an array than a list in Python. # It's initialized as empty first: self.fat = array.array(UINT32) self.loadfat_sect(sect) #self.dumpfat(self.fat) ## for i in range(0, len(sect), 4): ## ix = i32(sect, i) ## #[PL] if ix == -2 or ix == -1: # ix == 0xFFFFFFFE or ix == 0xFFFFFFFF: ## if ix == 0xFFFFFFFE or ix == 0xFFFFFFFF: ## break ## s = self.getsect(ix) ## #fat = fat + [i32(s, i) for i in range(0, len(s), 4)] ## fat = fat + array.array(UINT32, s) if self.num_difat_sectors != 0: log.debug('DIFAT is used, because file size > 6.8MB.') # [PL] There's a DIFAT because file is larger than 6.8MB # some checks just in case: if self.num_fat_sectors <= 109: # there must be at least 109 blocks in header and the rest in # DIFAT, so number of sectors must be >109. self._raise_defect(DEFECT_INCORRECT, 'incorrect DIFAT, not enough sectors') if self.first_difat_sector >= self.nb_sect: # initial DIFAT block index must be valid self._raise_defect(DEFECT_FATAL, 'incorrect DIFAT, first index out of range') log.debug( "DIFAT analysis..." ) # We compute the necessary number of DIFAT sectors : # Number of pointers per DIFAT sector = (sectorsize/4)-1 # (-1 because the last pointer is the next DIFAT sector number) nb_difat_sectors = (self.sectorsize//4)-1 # (if 512 bytes: each DIFAT sector = 127 pointers + 1 towards next DIFAT sector) nb_difat = (self.num_fat_sectors-109 + nb_difat_sectors-1)//nb_difat_sectors log.debug( "nb_difat = %d" % nb_difat ) if self.num_difat_sectors != nb_difat: raise IOError('incorrect DIFAT') isect_difat = self.first_difat_sector for i in iterrange(nb_difat): log.debug( "DIFAT block %d, sector %X" % (i, isect_difat) ) #TODO: check if corresponding FAT SID = DIFSECT sector_difat = self.getsect(isect_difat) difat = self.sect2array(sector_difat) # Display the sector contents only if the logging level is debug: if log.isEnabledFor(logging.DEBUG): self.dumpsect(sector_difat) self.loadfat_sect(difat[:nb_difat_sectors]) # last DIFAT pointer is next DIFAT sector: isect_difat = difat[nb_difat_sectors] log.debug( "next DIFAT sector: %X" % isect_difat ) # checks: if isect_difat not in [ENDOFCHAIN, FREESECT]: # last DIFAT pointer value must be ENDOFCHAIN or FREESECT raise IOError('incorrect end of DIFAT') ## if len(self.fat) != self.num_fat_sectors: ## # FAT should contain num_fat_sectors blocks ## print("FAT length: %d instead of %d" % (len(self.fat), self.num_fat_sectors)) ## raise IOError('incorrect DIFAT') else: log.debug('No DIFAT, because file size < 6.8MB.') # since FAT is read from fixed-size sectors, it may contain more values # than the actual number of sectors in the file. # Keep only the relevant sector indexes: if len(self.fat) > self.nb_sect: log.debug('len(fat)=%d, shrunk to nb_sect=%d' % (len(self.fat), self.nb_sect)) self.fat = self.fat[:self.nb_sect] log.debug('FAT references %d sectors / Maximum %d sectors in file' % (len(self.fat), self.nb_sect)) # Display the FAT contents only if the logging level is debug: if log.isEnabledFor(logging.DEBUG): log.debug('\nFAT:') self.dumpfat(self.fat) def loadminifat(self): """ Load the MiniFAT table. """ # MiniFAT is stored in a standard sub-stream, pointed to by a header # field. # NOTE: there are two sizes to take into account for this stream: # 1) Stream size is calculated according to the number of sectors # declared in the OLE header. This allocated stream may be more than # needed to store the actual sector indexes. # (self.num_mini_fat_sectors is the number of sectors of size self.sector_size) stream_size = self.num_mini_fat_sectors * self.sector_size # 2) Actually used size is calculated by dividing the MiniStream size # (given by root entry size) by the size of mini sectors, *4 for # 32 bits indexes: nb_minisectors = (self.root.size + self.mini_sector_size-1) // self.mini_sector_size used_size = nb_minisectors * 4 log.debug('loadminifat(): minifatsect=%d, nb FAT sectors=%d, used_size=%d, stream_size=%d, nb MiniSectors=%d' % (self.minifatsect, self.num_mini_fat_sectors, used_size, stream_size, nb_minisectors)) if used_size > stream_size: # This is not really a problem, but may indicate a wrong implementation: self._raise_defect(DEFECT_INCORRECT, 'OLE MiniStream is larger than MiniFAT') # In any case, first read stream_size: s = self._open(self.minifatsect, stream_size, force_FAT=True).read() #[PL] Old code replaced by an array: #self.minifat = [i32(s, i) for i in range(0, len(s), 4)] self.minifat = self.sect2array(s) # Then shrink the array to used size, to avoid indexes out of MiniStream: log.debug('MiniFAT shrunk from %d to %d sectors' % (len(self.minifat), nb_minisectors)) self.minifat = self.minifat[:nb_minisectors] log.debug('loadminifat(): len=%d' % len(self.minifat)) # Display the FAT contents only if the logging level is debug: if log.isEnabledFor(logging.DEBUG): log.debug('\nMiniFAT:') self.dumpfat(self.minifat) def getsect(self, sect): """ Read given sector from file on disk. :param sect: int, sector index :returns: a string containing the sector data. """ # From [MS-CFB]: A sector number can be converted into a byte offset # into the file by using the following formula: # (sector number + 1) x Sector Size. # This implies that sector #0 of the file begins at byte offset Sector # Size, not at 0. # [PL] the original code in PIL was wrong when sectors are 4KB instead of # 512 bytes: #self.fp.seek(512 + self.sectorsize * sect) #[PL]: added safety checks: #print("getsect(%X)" % sect) try: self.fp.seek(self.sectorsize * (sect+1)) except: log.debug('getsect(): sect=%X, seek=%d, filesize=%d' % (sect, self.sectorsize*(sect+1), self._filesize)) self._raise_defect(DEFECT_FATAL, 'OLE sector index out of range') sector = self.fp.read(self.sectorsize) if len(sector) != self.sectorsize: log.debug('getsect(): sect=%X, read=%d, sectorsize=%d' % (sect, len(sector), self.sectorsize)) self._raise_defect(DEFECT_FATAL, 'incomplete OLE sector') return sector def write_sect(self, sect, data, padding=b'\x00'): """ Write given sector to file on disk. :param sect: int, sector index :param data: bytes, sector data :param padding: single byte, padding character if data < sector size """ if not isinstance(data, bytes): raise TypeError("write_sect: data must be a bytes string") if not isinstance(padding, bytes) or len(padding)!=1: raise TypeError("write_sect: padding must be a bytes string of 1 char") #TODO: we could allow padding=None for no padding at all try: self.fp.seek(self.sectorsize * (sect+1)) except: log.debug('write_sect(): sect=%X, seek=%d, filesize=%d' % (sect, self.sectorsize*(sect+1), self._filesize)) self._raise_defect(DEFECT_FATAL, 'OLE sector index out of range') if len(data) < self.sectorsize: # add padding data += padding * (self.sectorsize - len(data)) elif len(data) < self.sectorsize: raise ValueError("Data is larger than sector size") self.fp.write(data) def _write_mini_sect(self, fp_pos, data, padding = b'\x00'): """ Write given sector to file on disk. :param fp_pos: int, file position :param data: bytes, sector data :param padding: single byte, padding character if data < sector size """ if not isinstance(data, bytes): raise TypeError("write_mini_sect: data must be a bytes string") if not isinstance(padding, bytes) or len(padding) != 1: raise TypeError("write_mini_sect: padding must be a bytes string of 1 char") try: self.fp.seek(fp_pos) except: log.debug('write_mini_sect(): fp_pos=%d, filesize=%d' % (fp_pos, self._filesize)) self._raise_defect(DEFECT_FATAL, 'OLE sector index out of range') len_data = len(data) if len_data < self.mini_sector_size: data += padding * (self.mini_sector_size - len_data) if self.mini_sector_size < len_data: raise ValueError("Data is larger than sector size") self.fp.write(data) def loaddirectory(self, sect): """ Load the directory. :param sect: sector index of directory stream. """ log.debug('Loading the Directory:') # The directory is stored in a standard # substream, independent of its size. # open directory stream as a read-only file: # (stream size is not known in advance) self.directory_fp = self._open(sect, force_FAT=True) #[PL] to detect malformed documents and avoid DoS attacks, the maximum # number of directory entries can be calculated: max_entries = self.directory_fp.size // 128 log.debug('loaddirectory: size=%d, max_entries=%d' % (self.directory_fp.size, max_entries)) # Create list of directory entries #self.direntries = [] # We start with a list of "None" object self.direntries = [None] * max_entries ## for sid in iterrange(max_entries): ## entry = fp.read(128) ## if not entry: ## break ## self.direntries.append(OleDirectoryEntry(entry, sid, self)) # load root entry: root_entry = self._load_direntry(0) # Root entry is the first entry: self.root = self.direntries[0] # TODO: read ALL directory entries (ignore bad entries?) # TODO: adapt build_storage_tree to avoid duplicate reads # for i in range(1, max_entries): # self._load_direntry(i) # read and build all storage trees, starting from the root: self.root.build_storage_tree() def _load_direntry (self, sid): """ Load a directory entry from the directory. This method should only be called once for each storage/stream when loading the directory. :param sid: index of storage/stream in the directory. :returns: a OleDirectoryEntry object :exception IOError: if the entry has always been referenced. """ # check if SID is OK: if sid<0 or sid>=len(self.direntries): self._raise_defect(DEFECT_FATAL, "OLE directory index out of range") # check if entry was already referenced: if self.direntries[sid] is not None: self._raise_defect(DEFECT_INCORRECT, "double reference for OLE stream/storage") # if exception not raised, return the object return self.direntries[sid] self.directory_fp.seek(sid * 128) entry = self.directory_fp.read(128) self.direntries[sid] = OleDirectoryEntry(entry, sid, self) return self.direntries[sid] def dumpdirectory(self): """ Dump directory (for debugging only) """ self.root.dump() def _open(self, start, size = UNKNOWN_SIZE, force_FAT=False): """ Open a stream, either in FAT or MiniFAT according to its size. (openstream helper) :param start: index of first sector :param size: size of stream (or nothing if size is unknown) :param force_FAT: if False (default), stream will be opened in FAT or MiniFAT according to size. If True, it will always be opened in FAT. """ log.debug('OleFileIO.open(): sect=%Xh, size=%d, force_FAT=%s' % (start, size, str(force_FAT))) # stream size is compared to the mini_stream_cutoff_size threshold: if size < self.minisectorcutoff and not force_FAT: # ministream object if not self.ministream: # load MiniFAT if it wasn't already done: self.loadminifat() # The first sector index of the miniFAT stream is stored in the # root directory entry: size_ministream = self.root.size log.debug('Opening MiniStream: sect=%Xh, size=%d' % (self.root.isectStart, size_ministream)) self.ministream = self._open(self.root.isectStart, size_ministream, force_FAT=True) return OleStream(fp=self.ministream, sect=start, size=size, offset=0, sectorsize=self.minisectorsize, fat=self.minifat, filesize=self.ministream.size, olefileio=self) else: # standard stream return OleStream(fp=self.fp, sect=start, size=size, offset=self.sectorsize, sectorsize=self.sectorsize, fat=self.fat, filesize=self._filesize, olefileio=self) def _list(self, files, prefix, node, streams=True, storages=False): """ listdir helper :param files: list of files to fill in :param prefix: current location in storage tree (list of names) :param node: current node (OleDirectoryEntry object) :param streams: bool, include streams if True (True by default) - new in v0.26 :param storages: bool, include storages if True (False by default) - new in v0.26 (note: the root storage is never included) """ prefix = prefix + [node.name] for entry in node.kids: if entry.entry_type == STGTY_STORAGE: # this is a storage if storages: # add it to the list files.append(prefix[1:] + [entry.name]) # check its kids self._list(files, prefix, entry, streams, storages) elif entry.entry_type == STGTY_STREAM: # this is a stream if streams: # add it to the list files.append(prefix[1:] + [entry.name]) else: self._raise_defect(DEFECT_INCORRECT, 'The directory tree contains an entry which is not a stream nor a storage.') def listdir(self, streams=True, storages=False): """ Return a list of streams and/or storages stored in this file :param streams: bool, include streams if True (True by default) - new in v0.26 :param storages: bool, include storages if True (False by default) - new in v0.26 (note: the root storage is never included) :returns: list of stream and/or storage paths """ files = [] self._list(files, [], self.root, streams, storages) return files def _find(self, filename): """ Returns directory entry of given filename. (openstream helper) Note: this method is case-insensitive. :param filename: path of stream in storage tree (except root entry), either: - a string using Unix path syntax, for example: 'storage_1/storage_1.2/stream' - or a list of storage filenames, path to the desired stream/storage. Example: ['storage_1', 'storage_1.2', 'stream'] :returns: sid of requested filename :exception IOError: if file not found """ # if filename is a string instead of a list, split it on slashes to # convert to a list: if isinstance(filename, basestring): filename = filename.split('/') # walk across storage tree, following given path: node = self.root for name in filename: for kid in node.kids: if kid.name.lower() == name.lower(): break else: raise IOError("file not found") node = kid return node.sid def openstream(self, filename): """ Open a stream as a read-only file object (BytesIO). Note: filename is case-insensitive. :param filename: path of stream in storage tree (except root entry), either: - a string using Unix path syntax, for example: 'storage_1/storage_1.2/stream' - or a list of storage filenames, path to the desired stream/storage. Example: ['storage_1', 'storage_1.2', 'stream'] :returns: file object (read-only) :exception IOError: if filename not found, or if this is not a stream. """ sid = self._find(filename) entry = self.direntries[sid] if entry.entry_type != STGTY_STREAM: raise IOError("this file is not a stream") return self._open(entry.isectStart, entry.size) def _write_mini_stream(self, entry, data_to_write): if not entry.sect_chain: entry.build_sect_chain(self) nb_sectors = len(entry.sect_chain) if not self.root.sect_chain: self.root.build_sect_chain(self) block_size = self.sector_size // self.mini_sector_size for idx, sect in enumerate(entry.sect_chain): sect_base = sect // block_size sect_offset = sect % block_size fp_pos = (self.root.sect_chain[sect_base] + 1)*self.sector_size + sect_offset*self.mini_sector_size if idx < (nb_sectors - 1): data_per_sector = data_to_write[idx * self.mini_sector_size: (idx + 1) * self.mini_sector_size] else: data_per_sector = data_to_write[idx * self.mini_sector_size:] self._write_mini_sect(fp_pos, data_per_sector) def write_stream(self, stream_name, data): """ Write a stream to disk. For now, it is only possible to replace an existing stream by data of the same size. :param stream_name: path of stream in storage tree (except root entry), either: - a string using Unix path syntax, for example: 'storage_1/storage_1.2/stream' - or a list of storage filenames, path to the desired stream/storage. Example: ['storage_1', 'storage_1.2', 'stream'] :param data: bytes, data to be written, must be the same size as the original stream. """ if not isinstance(data, bytes): raise TypeError("write_stream: data must be a bytes string") sid = self._find(stream_name) entry = self.direntries[sid] if entry.entry_type != STGTY_STREAM: raise IOError("this is not a stream") size = entry.size if size != len(data): raise ValueError("write_stream: data must be the same size as the existing stream") if size < self.minisectorcutoff and entry.entry_type != STGTY_ROOT: return self._write_mini_stream(entry = entry, data_to_write = data) sect = entry.isectStart # number of sectors to write nb_sectors = (size + (self.sectorsize-1)) // self.sectorsize log.debug('nb_sectors = %d' % nb_sectors) for i in range(nb_sectors): ## try: ## self.fp.seek(offset + self.sectorsize * sect) ## except: ## log.debug('sect=%d, seek=%d' % ## (sect, offset+self.sectorsize*sect)) ## raise IOError('OLE sector index out of range') # extract one sector from data, the last one being smaller: if i<(nb_sectors-1): data_sector = data [i*self.sectorsize : (i+1)*self.sectorsize] #TODO: comment this if it works assert(len(data_sector)==self.sectorsize) else: data_sector = data [i*self.sectorsize:] #TODO: comment this if it works log.debug('write_stream: size=%d sectorsize=%d data_sector=%Xh size%%sectorsize=%d' % (size, self.sectorsize, len(data_sector), size % self.sectorsize)) assert(len(data_sector) % self.sectorsize==size % self.sectorsize) self.write_sect(sect, data_sector) ## self.fp.write(data_sector) # jump to next sector in the FAT: try: sect = self.fat[sect] except IndexError: # [PL] if pointer is out of the FAT an exception is raised raise IOError('incorrect OLE FAT, sector index out of range') #[PL] Last sector should be a "end of chain" marker: if sect != ENDOFCHAIN: raise IOError('incorrect last sector index in OLE stream') def get_type(self, filename): """ Test if given filename exists as a stream or a storage in the OLE container, and return its type. :param filename: path of stream in storage tree. (see openstream for syntax) :returns: False if object does not exist, its entry type (>0) otherwise: - STGTY_STREAM: a stream - STGTY_STORAGE: a storage - STGTY_ROOT: the root entry """ try: sid = self._find(filename) entry = self.direntries[sid] return entry.entry_type except: return False def getclsid(self, filename): """ Return clsid of a stream/storage. :param filename: path of stream/storage in storage tree. (see openstream for syntax) :returns: Empty string if clsid is null, a printable representation of the clsid otherwise new in version 0.44 """ sid = self._find(filename) entry = self.direntries[sid] return entry.clsid def getmtime(self, filename): """ Return modification time of a stream/storage. :param filename: path of stream/storage in storage tree. (see openstream for syntax) :returns: None if modification time is null, a python datetime object otherwise (UTC timezone) new in version 0.26 """ sid = self._find(filename) entry = self.direntries[sid] return entry.getmtime() def getctime(self, filename): """ Return creation time of a stream/storage. :param filename: path of stream/storage in storage tree. (see openstream for syntax) :returns: None if creation time is null, a python datetime object otherwise (UTC timezone) new in version 0.26 """ sid = self._find(filename) entry = self.direntries[sid] return entry.getctime() def exists(self, filename): """ Test if given filename exists as a stream or a storage in the OLE container. Note: filename is case-insensitive. :param filename: path of stream in storage tree. (see openstream for syntax) :returns: True if object exist, else False. """ try: sid = self._find(filename) return True except: return False def get_size(self, filename): """ Return size of a stream in the OLE container, in bytes. :param filename: path of stream in storage tree (see openstream for syntax) :returns: size in bytes (long integer) :exception IOError: if file not found :exception TypeError: if this is not a stream. """ sid = self._find(filename) entry = self.direntries[sid] if entry.entry_type != STGTY_STREAM: #TODO: Should it return zero instead of raising an exception ? raise TypeError('object is not an OLE stream') return entry.size def get_rootentry_name(self): """ Return root entry name. Should usually be 'Root Entry' or 'R' in most implementations. """ return self.root.name def getproperties(self, filename, convert_time=False, no_conversion=None): """ Return properties described in substream. :param filename: path of stream in storage tree (see openstream for syntax) :param convert_time: bool, if True timestamps will be converted to Python datetime :param no_conversion: None or list of int, timestamps not to be converted (for example total editing time is not a real timestamp) :returns: a dictionary of values indexed by id (integer) """ #REFERENCE: [MS-OLEPS] https://msdn.microsoft.com/en-us/library/dd942421.aspx # make sure no_conversion is a list, just to simplify code below: if no_conversion == None: no_conversion = [] # stream path as a string to report exceptions: streampath = filename if not isinstance(streampath, str): streampath = '/'.join(streampath) fp = self.openstream(filename) data = {} try: # header s = fp.read(28) clsid = _clsid(s[8:24]) # format id s = fp.read(20) fmtid = _clsid(s[:16]) fp.seek(i32(s, 16)) # get section s = b"****" + fp.read(i32(fp.read(4))-4) # number of properties: num_props = i32(s, 4) except BaseException as exc: # catch exception while parsing property header, and only raise # a DEFECT_INCORRECT then return an empty dict, because this is not # a fatal error when parsing the whole file msg = 'Error while parsing properties header in stream %s: %s' % ( repr(streampath), exc) self._raise_defect(DEFECT_INCORRECT, msg, type(exc)) return data # clamp num_props based on the data length num_props = min(num_props, int(len(s) / 8)) for i in iterrange(num_props): property_id = 0 # just in case of an exception try: property_id = i32(s, 8+i*8) offset = i32(s, 12+i*8) property_type = i32(s, offset) log.debug('property id=%d: type=%d offset=%X' % (property_id, property_type, offset)) # test for common types first (should perhaps use # a dictionary instead?) if property_type == VT_I2: # 16-bit signed integer value = i16(s, offset+4) if value >= 32768: value = value - 65536 elif property_type == VT_UI2: # 2-byte unsigned integer value = i16(s, offset+4) elif property_type in (VT_I4, VT_INT, VT_ERROR): # VT_I4: 32-bit signed integer # VT_ERROR: HRESULT, similar to 32-bit signed integer, # see https://msdn.microsoft.com/en-us/library/cc230330.aspx value = i32(s, offset+4) elif property_type in (VT_UI4, VT_UINT): # 4-byte unsigned integer value = i32(s, offset+4) # FIXME elif property_type in (VT_BSTR, VT_LPSTR): # CodePageString, see https://msdn.microsoft.com/en-us/library/dd942354.aspx # size is a 32 bits integer, including the null terminator, and # possibly trailing or embedded null chars #TODO: if codepage is unicode, the string should be converted as such count = i32(s, offset+4) value = s[offset+8:offset+8+count-1] # remove all null chars: value = value.replace(b'\x00', b'') elif property_type == VT_BLOB: # binary large object (BLOB) # see https://msdn.microsoft.com/en-us/library/dd942282.aspx count = i32(s, offset+4) value = s[offset+8:offset+8+count] elif property_type == VT_LPWSTR: # UnicodeString # see https://msdn.microsoft.com/en-us/library/dd942313.aspx # "the string should NOT contain embedded or additional trailing # null characters." count = i32(s, offset+4) value = self._decode_utf16_str(s[offset+8:offset+8+count*2]) elif property_type == VT_FILETIME: value = long(i32(s, offset+4)) + (long(i32(s, offset+8))<<32) # FILETIME is a 64-bit int: "number of 100ns periods # since Jan 1,1601". if convert_time and property_id not in no_conversion: log.debug('Converting property #%d to python datetime, value=%d=%fs' %(property_id, value, float(value)/10000000)) # convert FILETIME to Python datetime.datetime # inspired from https://code.activestate.com/recipes/511425-filetime-to-datetime/ _FILETIME_null_date = datetime.datetime(1601, 1, 1, 0, 0, 0) log.debug('timedelta days=%d' % (value//(10*1000000*3600*24))) value = _FILETIME_null_date + datetime.timedelta(microseconds=value//10) else: # legacy code kept for backward compatibility: returns a # number of seconds since Jan 1,1601 value = value // 10000000 # seconds elif property_type == VT_UI1: # 1-byte unsigned integer value = i8(s[offset+4]) elif property_type == VT_CLSID: value = _clsid(s[offset+4:offset+20]) elif property_type == VT_CF: # PropertyIdentifier or ClipboardData?? # see https://msdn.microsoft.com/en-us/library/dd941945.aspx count = i32(s, offset+4) value = s[offset+8:offset+8+count] elif property_type == VT_BOOL: # VARIANT_BOOL, 16 bits bool, 0x0000=Fals, 0xFFFF=True # see https://msdn.microsoft.com/en-us/library/cc237864.aspx value = bool(i16(s, offset+4)) else: value = None # everything else yields "None" log.debug('property id=%d: type=%d not implemented in parser yet' % (property_id, property_type)) # missing: VT_EMPTY, VT_NULL, VT_R4, VT_R8, VT_CY, VT_DATE, # VT_DECIMAL, VT_I1, VT_I8, VT_UI8, # see https://msdn.microsoft.com/en-us/library/dd942033.aspx # FIXME: add support for VT_VECTOR # VT_VECTOR is a 32 uint giving the number of items, followed by # the items in sequence. The VT_VECTOR value is combined with the # type of items, e.g. VT_VECTOR|VT_BSTR # see https://msdn.microsoft.com/en-us/library/dd942011.aspx #print("%08x" % property_id, repr(value), end=" ") #print("(%s)" % VT[i32(s, offset) & 0xFFF]) data[property_id] = value except BaseException as exc: # catch exception while parsing each property, and only raise # a DEFECT_INCORRECT, because parsing can go on msg = 'Error while parsing property id %d in stream %s: %s' % ( property_id, repr(streampath), exc) self._raise_defect(DEFECT_INCORRECT, msg, type(exc)) return data def get_metadata(self): """ Parse standard properties streams, return an OleMetadata object containing all the available metadata. (also stored in the metadata attribute of the OleFileIO object) new in version 0.25 """ self.metadata = OleMetadata() self.metadata.parse_properties(self) return self.metadata # # -------------------------------------------------------------------- # This script can be used to dump the directory of any OLE2 structured # storage file. def main(): """ Main function when olefile is runs as a script from the command line. This will open an OLE2 file and display its structure and properties :return: nothing """ import sys, optparse DEFAULT_LOG_LEVEL = "warning" # Default log level LOG_LEVELS = { 'debug': logging.DEBUG, 'info': logging.INFO, 'warning': logging.WARNING, 'error': logging.ERROR, 'critical': logging.CRITICAL } usage = 'usage: %prog [options] [filename2 ...]' parser = optparse.OptionParser(usage=usage) parser.add_option("-c", action="store_true", dest="check_streams", help='check all streams (for debugging purposes)') parser.add_option("-d", action="store_true", dest="debug_mode", help='debug mode, shortcut for -l debug (displays a lot of debug information, for developers only)') parser.add_option('-l', '--loglevel', dest="loglevel", action="store", default=DEFAULT_LOG_LEVEL, help="logging level debug/info/warning/error/critical (default=%default)") (options, args) = parser.parse_args() print('olefile version %s %s - https://www.decalage.info/en/olefile\n' % (__version__, __date__)) # Print help if no arguments are passed if len(args) == 0: print(__doc__) parser.print_help() sys.exit() if options.debug_mode: options.loglevel = 'debug' # setup logging to the console logging.basicConfig(level=LOG_LEVELS[options.loglevel], format='%(levelname)-8s %(message)s') # also enable the module's logger: enable_logging() for filename in args: try: ole = OleFileIO(filename)#, raise_defects=DEFECT_INCORRECT) print("-" * 68) print(filename) print("-" * 68) ole.dumpdirectory() for streamname in ole.listdir(): if streamname[-1][0] == "\005": print("%r: properties" % streamname) try: props = ole.getproperties(streamname, convert_time=True) props = sorted(props.items()) for k, v in props: #[PL]: avoid to display too large or binary values: if isinstance(v, (basestring, bytes)): if len(v) > 50: v = v[:50] if isinstance(v, bytes): # quick and dirty binary check: for c in (1,2,3,4,5,6,7,11,12,14,15,16,17,18,19,20, 21,22,23,24,25,26,27,28,29,30,31): if c in bytearray(v): v = '(binary data)' break print(" ", k, v) except: log.exception('Error while parsing property stream %r' % streamname) if options.check_streams: # Read all streams to check if there are errors: print('\nChecking streams...') for streamname in ole.listdir(): # print name using repr() to convert binary chars to \xNN: print('-', repr('/'.join(streamname)),'-', end=' ') st_type = ole.get_type(streamname) if st_type == STGTY_STREAM: print('size %d' % ole.get_size(streamname)) # just try to read stream in memory: ole.openstream(streamname) else: print('NOT a stream : type=%d' % st_type) print() ## for streamname in ole.listdir(): ## # print name using repr() to convert binary chars to \xNN: ## print('-', repr('/'.join(streamname)),'-', end=' ') ## print(ole.getmtime(streamname)) ## print() print('Modification/Creation times of all directory entries:') for entry in ole.direntries: if entry is not None: print('- %s: mtime=%s ctime=%s' % (entry.name, entry.getmtime(), entry.getctime())) print() # parse and display metadata: try: meta = ole.get_metadata() meta.dump() except: log.exception('Error while parsing metadata') print() #[PL] Test a few new methods: root = ole.get_rootentry_name() print('Root entry name: "%s"' % root) if ole.exists('worddocument'): print("This is a Word document.") print("type of stream 'WordDocument':", ole.get_type('worddocument')) print("size :", ole.get_size('worddocument')) if ole.exists('macros/vba'): print("This document may contain VBA macros.") # print parsing issues: print('\nNon-fatal issues raised during parsing:') if ole.parsing_issues: for exctype, msg in ole.parsing_issues: print('- %s: %s' % (exctype.__name__, msg)) else: print('None') except: log.exception('Error while parsing file %r' % filename) if __name__ == "__main__": main() # this code was developed while listening to The Wedding Present "Sea Monsters"