""" Handle the NBT (Named Binary Tag) data format For more information about the NBT format: https://minecraft.gamepedia.com/NBT_format """ from struct import Struct, error as StructError from gzip import GzipFile try: from collections.abc import MutableMapping, MutableSequence, Sequence except ImportError: # for Python 2.7 from collections import MutableMapping, MutableSequence, Sequence import sys _PY3 = sys.version_info >= (3,) if _PY3: unicode = str basestring = str else: range = xrange TAG_END = 0 TAG_BYTE = 1 TAG_SHORT = 2 TAG_INT = 3 TAG_LONG = 4 TAG_FLOAT = 5 TAG_DOUBLE = 6 TAG_BYTE_ARRAY = 7 TAG_STRING = 8 TAG_LIST = 9 TAG_COMPOUND = 10 TAG_INT_ARRAY = 11 TAG_LONG_ARRAY = 12 class MalformedFileError(Exception): """Exception raised on parse error.""" pass class TAG(object): """TAG, a variable with an intrinsic name.""" id = None def __init__(self, value=None, name=None): self.name = name self.value = value # Parsers and Generators def _parse_buffer(self, buffer): raise NotImplementedError(self.__class__.__name__) def _render_buffer(self, buffer): raise NotImplementedError(self.__class__.__name__) # Printing and Formatting of tree def tag_info(self): """Return Unicode string with class, name and unnested value.""" return self.__class__.__name__ + ( '(%r)' % self.name if self.name else "") + ": " + self.valuestr() def valuestr(self): """Return Unicode string of unnested value. For iterators, this returns a summary.""" return unicode(self.value) def namestr(self): """Return Unicode string of tag name.""" return unicode(self.name) def pretty_tree(self, indent=0): """Return formated Unicode string of self, where iterable items are recursively listed in detail.""" return ("\t" * indent) + self.tag_info() # Python 2 compatibility; Python 3 uses __str__ instead. def __unicode__(self): """Return a unicode string with the result in human readable format. Unlike valuestr(), the result is recursive for iterators till at least one level deep.""" return unicode(self.value) def __str__(self): """Return a string (ascii formated for Python 2, unicode for Python 3) with the result in human readable format. Unlike valuestr(), the result is recursive for iterators till at least one level deep.""" return str(self.value) # Unlike regular iterators, __repr__() is not recursive. # Use pretty_tree for recursive results. # iterators should use __repr__ or tag_info for each item, like # regular iterators def __repr__(self): """Return a string (ascii formated for Python 2, unicode for Python 3) describing the class, name and id for debugging purposes.""" return "<%s(%r) at 0x%x>" % ( self.__class__.__name__, self.name, id(self)) class _TAG_Numeric(TAG): """_TAG_Numeric, comparable to int with an intrinsic name""" def __init__(self, value=None, name=None, buffer=None): super(_TAG_Numeric, self).__init__(value, name) if buffer: self._parse_buffer(buffer) # Parsers and Generators def _parse_buffer(self, buffer): # Note: buffer.read() may raise an IOError, for example if buffer is a # corrupt gzip.GzipFile self.value = self.fmt.unpack(buffer.read(self.fmt.size))[0] def _render_buffer(self, buffer): buffer.write(self.fmt.pack(self.value)) class _TAG_End(TAG): id = TAG_END fmt = Struct(">b") def _parse_buffer(self, buffer): # Note: buffer.read() may raise an IOError, for example if buffer is a # corrupt gzip.GzipFile value = self.fmt.unpack(buffer.read(1))[0] if value != 0: raise ValueError( "A Tag End must be rendered as '0', not as '%d'." % value) def _render_buffer(self, buffer): buffer.write(b'\x00') # == Value Tags ==# class TAG_Byte(_TAG_Numeric): """Represent a single tag storing 1 byte.""" id = TAG_BYTE fmt = Struct(">b") class TAG_Short(_TAG_Numeric): """Represent a single tag storing 1 short.""" id = TAG_SHORT fmt = Struct(">h") class TAG_Int(_TAG_Numeric): """Represent a single tag storing 1 int.""" id = TAG_INT fmt = Struct(">i") """Struct(">i"), 32-bits integer, big-endian""" class TAG_Long(_TAG_Numeric): """Represent a single tag storing 1 long.""" id = TAG_LONG fmt = Struct(">q") class TAG_Float(_TAG_Numeric): """Represent a single tag storing 1 IEEE-754 floating point number.""" id = TAG_FLOAT fmt = Struct(">f") class TAG_Double(_TAG_Numeric): """Represent a single tag storing 1 IEEE-754 double precision floating point number.""" id = TAG_DOUBLE fmt = Struct(">d") class TAG_Byte_Array(TAG, MutableSequence): """ TAG_Byte_Array, comparable to a collections.UserList with an intrinsic name whose values must be bytes """ id = TAG_BYTE_ARRAY def __init__(self, name=None, buffer=None): # TODO: add a value parameter as well super(TAG_Byte_Array, self).__init__(name=name) if buffer: self._parse_buffer(buffer) # Parsers and Generators def _parse_buffer(self, buffer): length = TAG_Int(buffer=buffer) self.value = bytearray(buffer.read(length.value)) def _render_buffer(self, buffer): length = TAG_Int(len(self.value)) length._render_buffer(buffer) buffer.write(bytes(self.value)) # Mixin methods def __len__(self): return len(self.value) def __iter__(self): return iter(self.value) def __contains__(self, item): return item in self.value def __getitem__(self, key): return self.value[key] def __setitem__(self, key, value): # TODO: check type of value self.value[key] = value def __delitem__(self, key): del (self.value[key]) def insert(self, key, value): # TODO: check type of value, or is this done by self.value already? self.value.insert(key, value) # Printing and Formatting of tree def valuestr(self): return "[%i byte(s)]" % len(self.value) def __unicode__(self): return '[' + ",".join([unicode(x) for x in self.value]) + ']' def __str__(self): return '[' + ",".join([str(x) for x in self.value]) + ']' class TAG_Int_Array(TAG, MutableSequence): """ TAG_Int_Array, comparable to a collections.UserList with an intrinsic name whose values must be integers """ id = TAG_INT_ARRAY def __init__(self, name=None, buffer=None): # TODO: add a value parameter as well super(TAG_Int_Array, self).__init__(name=name) if buffer: self._parse_buffer(buffer) def update_fmt(self, length): """ Adjust struct format description to length given """ self.fmt = Struct(">" + str(length) + "i") # Parsers and Generators def _parse_buffer(self, buffer): length = TAG_Int(buffer=buffer).value self.update_fmt(length) self.value = list(self.fmt.unpack(buffer.read(self.fmt.size))) def _render_buffer(self, buffer): length = len(self.value) self.update_fmt(length) TAG_Int(length)._render_buffer(buffer) buffer.write(self.fmt.pack(*self.value)) # Mixin methods def __len__(self): return len(self.value) def __iter__(self): return iter(self.value) def __contains__(self, item): return item in self.value def __getitem__(self, key): return self.value[key] def __setitem__(self, key, value): self.value[key] = value def __delitem__(self, key): del (self.value[key]) def insert(self, key, value): self.value.insert(key, value) # Printing and Formatting of tree def valuestr(self): return "[%i int(s)]" % len(self.value) class TAG_Long_Array(TAG, MutableSequence): """ TAG_Long_Array, comparable to a collections.UserList with an intrinsic name whose values must be integers """ id = TAG_LONG_ARRAY def __init__(self, name=None, buffer=None): super(TAG_Long_Array, self).__init__(name=name) if buffer: self._parse_buffer(buffer) def update_fmt(self, length): """ Adjust struct format description to length given """ self.fmt = Struct(">" + str(length) + "q") # Parsers and Generators def _parse_buffer(self, buffer): length = TAG_Int(buffer=buffer).value self.update_fmt(length) self.value = list(self.fmt.unpack(buffer.read(self.fmt.size))) def _render_buffer(self, buffer): length = len(self.value) self.update_fmt(length) TAG_Int(length)._render_buffer(buffer) buffer.write(self.fmt.pack(*self.value)) # Mixin methods def __len__(self): return len(self.value) def __iter__(self): return iter(self.value) def __contains__(self, item): return item in self.value def __getitem__(self, key): return self.value[key] def __setitem__(self, key, value): self.value[key] = value def __delitem__(self, key): del (self.value[key]) def insert(self, key, value): self.value.insert(key, value) # Printing and Formatting of tree def valuestr(self): return "[%i long(s)]" % len(self.value) class TAG_String(TAG, Sequence): """ TAG_String, comparable to a collections.UserString with an intrinsic name """ id = TAG_STRING def __init__(self, value=None, name=None, buffer=None): super(TAG_String, self).__init__(value, name) if buffer: self._parse_buffer(buffer) # Parsers and Generators def _parse_buffer(self, buffer): length = TAG_Short(buffer=buffer) read = buffer.read(length.value) if len(read) != length.value: raise StructError() self.value = read.decode("utf-8") def _render_buffer(self, buffer): save_val = self.value.encode("utf-8") length = TAG_Short(len(save_val)) length._render_buffer(buffer) buffer.write(save_val) # Mixin methods def __len__(self): return len(self.value) def __iter__(self): return iter(self.value) def __contains__(self, item): return item in self.value def __getitem__(self, key): return self.value[key] # Printing and Formatting of tree def __repr__(self): return self.value # == Collection Tags ==# class TAG_List(TAG, MutableSequence): """ TAG_List, comparable to a collections.UserList with an intrinsic name """ id = TAG_LIST def __init__(self, type=None, value=None, name=None, buffer=None): super(TAG_List, self).__init__(value, name) if type: self.tagID = type.id else: self.tagID = None self.tags = [] if buffer: self._parse_buffer(buffer) # if self.tagID == None: # raise ValueError("No type specified for list: %s" % (name)) # Parsers and Generators def _parse_buffer(self, buffer): self.tagID = TAG_Byte(buffer=buffer).value self.tags = [] length = TAG_Int(buffer=buffer) for x in range(length.value): self.tags.append(TAGLIST[self.tagID](buffer=buffer)) def _render_buffer(self, buffer): TAG_Byte(self.tagID)._render_buffer(buffer) length = TAG_Int(len(self.tags)) length._render_buffer(buffer) for i, tag in enumerate(self.tags): if tag.id != self.tagID: raise ValueError( "List element %d(%s) has type %d != container type %d" % (i, tag, tag.id, self.tagID)) tag._render_buffer(buffer) # Mixin methods def __len__(self): return len(self.tags) def __iter__(self): return iter(self.tags) def __contains__(self, item): return item in self.tags def __getitem__(self, key): return self.tags[key] def __setitem__(self, key, value): self.tags[key] = value def __delitem__(self, key): del (self.tags[key]) def insert(self, key, value): self.tags.insert(key, value) # Printing and Formatting of tree def __repr__(self): return "%i entries of type %s" % ( len(self.tags), TAGLIST[self.tagID].__name__) # Printing and Formatting of tree def valuestr(self): return "[%i %s(s)]" % (len(self.tags), TAGLIST[self.tagID].__name__) def __unicode__(self): return "[" + ", ".join([tag.tag_info() for tag in self.tags]) + "]" def __str__(self): return "[" + ", ".join([tag.tag_info() for tag in self.tags]) + "]" def pretty_tree(self, indent=0): output = [super(TAG_List, self).pretty_tree(indent)] if len(self.tags): output.append(("\t" * indent) + "{") output.extend([tag.pretty_tree(indent + 1) for tag in self.tags]) output.append(("\t" * indent) + "}") return '\n'.join(output) class TAG_Compound(TAG, MutableMapping): """ TAG_Compound, comparable to a collections.OrderedDict with an intrinsic name """ id = TAG_COMPOUND def __init__(self, buffer=None, name=None): # TODO: add a value parameter as well super(TAG_Compound, self).__init__() self.tags = [] if name: self.name = name else: self.name = "" if buffer: self._parse_buffer(buffer) # Parsers and Generators def _parse_buffer(self, buffer): while True: type = TAG_Byte(buffer=buffer) if type.value == TAG_END: # print("found tag_end") break else: name = TAG_String(buffer=buffer).value try: tag = TAGLIST[type.value]() except KeyError: raise ValueError("Unrecognised tag type %d" % type.value) tag.name = name self.tags.append(tag) tag._parse_buffer(buffer) def _render_buffer(self, buffer): for tag in self.tags: TAG_Byte(tag.id)._render_buffer(buffer) TAG_String(tag.name)._render_buffer(buffer) tag._render_buffer(buffer) buffer.write(b'\x00') # write TAG_END # Mixin methods def __len__(self): return len(self.tags) def __iter__(self): for key in self.tags: yield key.name def __contains__(self, key): if isinstance(key, int): return key <= len(self.tags) elif isinstance(key, basestring): for tag in self.tags: if tag.name == key: return True return False elif isinstance(key, TAG): return key in self.tags return False def __getitem__(self, key): if isinstance(key, int): return self.tags[key] elif isinstance(key, basestring): for tag in self.tags: if tag.name == key: return tag else: raise KeyError("Tag %s does not exist" % key) else: raise TypeError( "key needs to be either name of tag, or index of tag, " "not a %s" % type(key).__name__) def __setitem__(self, key, value): assert isinstance(value, TAG), "value must be an nbt.TAG" if isinstance(key, int): # Just try it. The proper error will be raised if it doesn't work. self.tags[key] = value elif isinstance(key, basestring): value.name = key for i, tag in enumerate(self.tags): if tag.name == key: self.tags[i] = value return self.tags.append(value) def __delitem__(self, key): if isinstance(key, int): del (self.tags[key]) elif isinstance(key, basestring): self.tags.remove(self.__getitem__(key)) else: raise ValueError( "key needs to be either name of tag, or index of tag") def keys(self): return [tag.name for tag in self.tags] def iteritems(self): for tag in self.tags: yield (tag.name, tag) # Printing and Formatting of tree def __unicode__(self): return "{" + ", ".join([tag.tag_info() for tag in self.tags]) + "}" def __str__(self): return "{" + ", ".join([tag.tag_info() for tag in self.tags]) + "}" def valuestr(self): return '{%i Entries}' % len(self.tags) def pretty_tree(self, indent=0): output = [super(TAG_Compound, self).pretty_tree(indent)] if len(self.tags): output.append(("\t" * indent) + "{") output.extend([tag.pretty_tree(indent + 1) for tag in self.tags]) output.append(("\t" * indent) + "}") return '\n'.join(output) TAGLIST = {TAG_END: _TAG_End, TAG_BYTE: TAG_Byte, TAG_SHORT: TAG_Short, TAG_INT: TAG_Int, TAG_LONG: TAG_Long, TAG_FLOAT: TAG_Float, TAG_DOUBLE: TAG_Double, TAG_BYTE_ARRAY: TAG_Byte_Array, TAG_STRING: TAG_String, TAG_LIST: TAG_List, TAG_COMPOUND: TAG_Compound, TAG_INT_ARRAY: TAG_Int_Array, TAG_LONG_ARRAY: TAG_Long_Array} class NBTFile(TAG_Compound): """Represent an NBT file object.""" def __init__(self, filename=None, buffer=None, fileobj=None): """ Create a new NBTFile object. Specify either a filename, file object or data buffer. If filename of file object is specified, data should be GZip-compressed. If a data buffer is specified, it is assumed to be uncompressed. If filename is specified, the file is closed after reading and writing. If file object is specified, the caller is responsible for closing the file. """ super(NBTFile, self).__init__() self.filename = filename self.type = TAG_Byte(self.id) closefile = True # make a file object if filename: self.filename = filename self.file = GzipFile(filename, 'rb') elif buffer: if hasattr(buffer, 'name'): self.filename = buffer.name self.file = buffer closefile = False elif fileobj: if hasattr(fileobj, 'name'): self.filename = fileobj.name self.file = GzipFile(fileobj=fileobj) else: self.file = None closefile = False # parse the file given initially if self.file: self.parse_file() if closefile: # Note: GzipFile().close() does NOT close the fileobj, # So we are still responsible for closing that. try: self.file.close() except (AttributeError, IOError): pass self.file = None def parse_file(self, filename=None, buffer=None, fileobj=None): """Completely parse a file, extracting all tags.""" closefile = True if filename: self.file = GzipFile(filename, 'rb') elif buffer: if hasattr(buffer, 'name'): self.filename = buffer.name self.file = buffer closefile = False elif fileobj: if hasattr(fileobj, 'name'): self.filename = fileobj.name self.file = GzipFile(fileobj=fileobj) if self.file: try: type = TAG_Byte(buffer=self.file) if type.value == self.id: name = TAG_String(buffer=self.file).value self._parse_buffer(self.file) self.name = name if closefile: self.file.close() else: raise MalformedFileError( "First record is not a Compound Tag") except StructError as e: raise MalformedFileError( "Partial File Parse: file possibly truncated.") else: raise ValueError( "NBTFile.parse_file(): Need to specify either a " "filename or a file object" ) def write_file(self, filename=None, buffer=None, fileobj=None): """Write this NBT file to a file.""" closefile = True if buffer: self.filename = None self.file = buffer closefile = False elif filename: self.filename = filename self.file = GzipFile(filename, "wb") elif fileobj: self.filename = None self.file = GzipFile(fileobj=fileobj, mode="wb") elif self.filename: self.file = GzipFile(self.filename, "wb") elif not self.file: raise ValueError( "NBTFile.write_file(): Need to specify either a " "filename or a file object" ) # Render tree to file TAG_Byte(self.id)._render_buffer(self.file) TAG_String(self.name)._render_buffer(self.file) self._render_buffer(self.file) # make sure the file is complete try: self.file.flush() except (AttributeError, IOError): pass if closefile: try: self.file.close() except (AttributeError, IOError): pass def __repr__(self): """ Return a string (ascii formated for Python 2, unicode for Python 3) describing the class, name and id for debugging purposes. """ if self.filename: return "<%s(%r) with %s(%r) at 0x%x>" % ( self.__class__.__name__, self.filename, TAG_Compound.__name__, self.name, id(self) ) else: return "<%s with %s(%r) at 0x%x>" % ( self.__class__.__name__, TAG_Compound.__name__, self.name, id(self) )