def raw_id(self, value): if isinstance(value, int): self.rootTag["id"] = nbt.TAG_Short(value) elif isinstance(value, basestring): self.rootTag["id"] = nbt.TAG_String(value) else: raise TypeError("Invalid type for ItemRef.id: %r", type(value)) self.dirty = True
def TileEntities(self): chestTag = nbt.TAG_Compound() chestTag["id"] = nbt.TAG_String("Chest") chestTag["Items"] = nbt.TAG_List(self.rootTag["Inventory"]) chestTag["x"] = nbt.TAG_Int(0) chestTag["y"] = nbt.TAG_Int(0) chestTag["z"] = nbt.TAG_Int(0) return nbt.TAG_List([chestTag], name="TileEntities")
def testModify(self): level = self.testCreate() # Most of the value types work as expected. Here, we replace the entire tag with a TAG_String level["About"]["Author"] = nbt.TAG_String("YARRR~!") # Because the tag type usually doesn't change, # we can replace the string tag's value instead of replacing the entire tag. level["About"]["Author"].value = "Stew Pickles" # Remove members of a TAG_Compound using del, similar to a python dict. del(level["About"]) # Replace all of the wood blocks with gold using a boolean index array blocks = level["Map"]["Blocks"].value blocks[blocks == 5] = 41 level["Entities"][0] = nbt.TAG_Compound([nbt.TAG_String("Creeper", "id"), nbt.TAG_List([nbt.TAG_Double(d) for d in (1, 1, 1)], "Pos")])
def id(self, value): if "id" not in self.rootTag: # no id tag - freshly minted item tag # get proper tag type from blocktypes if self.blockTypes is None: raise NoParentError( "ItemRef must be parented to a world before assigning id for the first time." ) if self.blockTypes.itemStackVersion == VERSION_1_7: self.rootTag["id"] = nbt.TAG_Short(0) elif self.blockTypes.itemStackVersion == VERSION_1_8: self.rootTag["id"] = nbt.TAG_String("minecraft:air") else: raise AssertionError("Unexpected itemStackVersion: %s", self.blockTypes.itemStackVersion) idTag = self.rootTag["id"] if isinstance(value, ItemType): if idTag.tagID == nbt.ID_STRING: idTag.value = value.internalName else: idTag.value = value.ID if value.meta is not None: self.Damage = value.meta elif isinstance(value, int): if idTag.tagID == nbt.ID_SHORT: self.rootTag["id"].value = value elif idTag.tagID == nbt.ID_STRING: if self.blockTypes is None: raise NoParentError( "ItemRef must be parented to a world before assigning numeric IDs to an 1.8 ItemStack." ) itemType = self.blockTypes.itemTypes[value] self.rootTag["id"].value = itemType.internalName elif isinstance(value, basestring): if idTag.tagID == nbt.ID_STRING: self.rootTag["id"].value = value elif idTag.tagID == nbt.ID_SHORT: if self.blockTypes is None: raise NoParentError( "ItemRef must be parented to a world before assigning textual IDs to an 1.7 ItemStack." ) itemType = self.blockTypes.itemTypes[value] self.rootTag["id"].value = itemType.ID else: raise TypeError("Invalid type for ItemRef.id: %r", type(value)) self.dirty = True
def saveToFile(self, filename): super(ZipSchematic, self).saveChanges() schematicDat = nbt.TAG_Compound() schematicDat.name = "Mega Schematic" schematicDat["Width"] = nbt.TAG_Int(self.size[0]) schematicDat["Height"] = nbt.TAG_Int(self.size[1]) schematicDat["Length"] = nbt.TAG_Int(self.size[2]) schematicDat["Materials"] = nbt.TAG_String(self.blocktypes.name) schematicDat.save(self.worldFolder.getFilePath("schematic.dat")) basedir = self.worldFolder.filename assert os.path.isdir(basedir) with closing(zipfile.ZipFile(filename, "w", zipfile.ZIP_STORED)) as z: for root, dirs, files in os.walk(basedir): # NOTE: ignore empty directories for fn in files: absfn = os.path.join(root, fn) zfn = absfn[len(basedir) + len(os.sep):] # XXX: relative path z.write(absfn, zfn)
def testRevision(history): revA = history.createRevision() log.info("revA") # rev A @1 - touch chunk 1 cx, cz = iter(revA.chunkPositions("")).next() chunk = readChunkTag(revA, cx, cz) old_tag = tag = nbt.load(buf=history.rootFolder.readChunkBytes(cx, cz, "")) assert readChunkTag(history.rootNode, cx, cz) == tag assert chunk == tag chunk["Level"]["test"] = nbt.TAG_String("test string") writeChunkTag(revA, cx, cz, chunk) tag = readChunkTag(revA, cx, cz) assert "test" in tag["Level"] and tag["Level"]["test"].value == "test string" revB = history.createRevision() log.info("revB") # rev B @2 - delete chunk 2 tag = readChunkTag(revB, cx, cz) assert "test" in tag["Level"] and tag["Level"]["test"].value == "test string" revB.deleteChunk(cx+1, cz, "") assert not revB.containsChunk(cx+1, cz, "") revC = history.createRevision() log.info("revC") # rev C @3 - delete file assert not revC.containsChunk(cx+1, cz, "") revC.deleteFile("level.dat") assert not revC.containsFile("level.dat") changes = revC.getChanges() assert changes.chunks[""] == set() assert changes.files == {"level.dat"} tailRev = history.getRevision(0) history.writeAllChanges() # initial folder (rev idx 0) and following nodes replaced by reverse nodes # rev C @3 replaced by initial folder assert revC.invalid revC = history.getHead() assert tailRev is revC changes = revC.getChanges() assert changes.chunks[""] == set() assert changes.files == {"level.dat"} # rev D - create chunk 3 revD = history.createRevision() log.info("revD") assert not revD.containsFile("level.dat") writeChunkTag(revD, 1000, 1000, old_tag) assert not history.rootFolder.containsFile("level.dat") assert not history.rootFolder.containsChunk(cx+1, cz, "") assert "test" in tag["Level"] tag = readChunkTag(history.rootFolder, cx, cz) assert tag != old_tag assert "test" in tag["Level"] # grab rev B revBagain = history.getRevision(2) assert "test" in readChunkTag(revBagain, cx, cz)["Level"] assert not revBagain.containsChunk(cx+1, cz, "") # rev B should be read only with pytest.raises(IOError): writeChunkTag(revBagain, cx, cz, old_tag) # check all changes so far allChanges = history.getRevisionChanges(0, revD) assert allChanges.chunks[""] == {(cx, cz), (cx+1, cz), (1000, 1000)} assert allChanges.files == {"level.dat"} # insert rev E after rev B # world folder is now at the end of an orphan chain at rev @2 # orphaned revisions are read only and still valid, but do not appear in the history revE = history.createRevision(2) assert "test" in readChunkTag(revE, cx, cz)["Level"] assert not revE.containsChunk(cx+1, cz, "") history.close()
def created_nbt(): # The root of an NBT file is always a TAG_Compound. level = nbt.TAG_Compound(name="MinecraftLevel") # Subtags of a TAG_Compound are automatically named when you use the [] operator. level["About"] = nbt.TAG_Compound() level["About"]["Author"] = nbt.TAG_String("codewarrior") level["About"]["CreatedOn"] = nbt.TAG_Long(time.time()) level["Environment"] = nbt.TAG_Compound() level["Environment"]["SkyBrightness"] = nbt.TAG_Byte(16) level["Environment"]["SurroundingWaterHeight"] = nbt.TAG_Short(32) level["Environment"]["FogColor"] = nbt.TAG_Int(0xcccccc) entity = nbt.TAG_Compound() entity["id"] = nbt.TAG_String("Creeper") entity["Pos"] = nbt.TAG_List( [nbt.TAG_Float(d) for d in (32.5, 64.0, 33.3)]) level["Entities"] = nbt.TAG_List([entity]) spawn = nbt.TAG_List( (nbt.TAG_Short(100), nbt.TAG_Short(45), nbt.TAG_Short(55))) mapTag = nbt.TAG_Compound() mapTag["Spawn"] = spawn level["Map"] = mapTag mapTag2 = nbt.TAG_Compound([spawn]) mapTag2.name = "Map" # I think it looks more familiar with [] syntax. l, w, h = 128, 128, 128 mapTag["Height"] = nbt.TAG_Short(h) # y dimension mapTag["Length"] = nbt.TAG_Short(l) # z dimension mapTag["Width"] = nbt.TAG_Short(w) # x dimension # Byte arrays are stored as numpy.uint8 arrays. mapTag["Blocks"] = nbt.TAG_Byte_Array() mapTag["Blocks"].value = numpy.zeros( l * w * h, dtype=numpy.uint8) # create lots of air! # The blocks array is indexed (y,z,x) for indev levels, so reshape the blocks mapTag["Blocks"].value.shape = (h, l, w) # Replace the bottom layer of the indev level with wood mapTag["Blocks"].value[0, :, :] = 5 # This is a great way to learn the power of numpy array slicing and indexing. mapTag["Data"] = nbt.TAG_Byte_Array() mapTag["Data"].value = numpy.zeros(l * w * h, dtype=numpy.uint8) # Save a few more tag types for completeness level["ShortArray"] = nbt.TAG_Short_Array( numpy.zeros((16, 16), dtype='uint16')) level["IntArray"] = nbt.TAG_Int_Array(numpy.zeros((16, 16), dtype='uint32')) level["Float"] = nbt.TAG_Float(0.3) return level
def exportStructure(filename, dim, selection, author=None, excludedBlocks=None): """ Parameters ---------- filename : unicode dim : mceditlib.worldeditor.WorldEditorDimension selection : mceditlib.selection.SelectionBox Returns ------- """ excludedBlocks = set(excludedBlocks or []) rootTag = nbt.TAG_Compound() rootTag['author'] = nbt.TAG_String(author or "Anonymous") rootTag['version'] = nbt.TAG_Int(1) rootTag['size'] = nbt.TAG_List([nbt.TAG_Int(s) for s in selection.size]) entities = rootTag['entities'] = nbt.TAG_List(list_type=nbt.ID_COMPOUND) blocks = rootTag['blocks'] = nbt.TAG_List(list_type=nbt.ID_COMPOUND) palette = rootTag['palette'] = nbt.TAG_List(list_type=nbt.ID_COMPOUND) ox, oy, oz = selection.origin paletteIDs = {} for x, y, z in selection.positions: block = dim.getBlock(x, y, z) if block in excludedBlocks: continue paletteIdx = paletteIDs.get(block.nameAndState, None) if paletteIdx is None: paletteTag = nbt.TAG_Compound() paletteTag['Name'] = nbt.TAG_String(block.internalName) if len(block.stateDict): paletteTag['Properties'] = nbt.TAG_Compound() for k, v in block.stateDict.iteritems(): paletteTag['Properties'][k] = nbt.TAG_String(v) paletteIdx = paletteIDs[block.nameAndState] = len(palette) palette.append(paletteTag) blockTag = nbt.TAG_Compound() blockTag['state'] = nbt.TAG_Int(paletteIdx) blockTag['pos'] = nbt.TAG_List( [nbt.TAG_Int(a) for a in x - ox, y - oy, z - oz]) tileEntity = dim.getTileEntity((x, y, z)) if tileEntity: tileEntity = tileEntity.copyWithOffset(-selection.origin) blockTag['nbt'] = tileEntity.rootTag blocks.append(blockTag) for entity in dim.getEntities(selection): entity = entity.copyWithOffset(-selection.origin) entityTag = nbt.TAG_Compound() entityTag['pos'] = nbt.TAG_List( [nbt.TAG_Double(a) for a in entity.Position]) entityTag['blockPos'] = nbt.TAG_List( [nbt.TAG_Int(int(floor(a))) for a in entity.Position]) entityTag['nbt'] = entity.rootTag entities.append(entityTag) rootTag.save(filename)
def __init__(self, shape=None, filename=None, blocktypes='Alpha', readonly=False, resume=False): """ Creates an object which stores a section of a Minecraft world as an NBT structure. The order of the coordinates for the block arrays in the file is y,z,x. This is the same order used in Minecraft 1.4's chunk sections. :type shape: tuple :param shape: The shape of the schematic as (x, y, z) :type filename: basestring :param filename: Path to a file to load a saved schematic from. :type blocktypes: basestring or BlockTypeSet :param blocktypes: The name of a builtin blocktypes set (one of "Classic", "Alpha", "Pocket") to indicate allowable blocks. The default is Alpha. An instance of BlockTypeSet may be passed instead. :rtype: SchematicFileAdapter """ self.EntityRef = PCEntityRef self.TileEntityRef = PCTileEntityRef if filename is None and shape is None: raise ValueError("shape or filename required to create %s" % self.__class__.__name__) if filename: self.filename = filename if os.path.exists(filename): rootTag = nbt.load(filename) else: rootTag = None else: self.filename = None rootTag = None if blocktypes in blocktypeClassesByName: self.blocktypes = blocktypeClassesByName[blocktypes]() else: assert (isinstance(blocktypes, BlockTypeSet)) self.blocktypes = blocktypes if rootTag: self.rootTag = rootTag if "Materials" in rootTag: self.blocktypes = blocktypeClassesByName[self.Materials]() else: rootTag["Materials"] = nbt.TAG_String(self.blocktypes.name) w = self.rootTag["Width"].value l = self.rootTag["Length"].value h = self.rootTag["Height"].value assert self.rootTag["Blocks"].value.size == w * l * h self._Blocks = self.rootTag["Blocks"].value.astype( 'uint16').reshape(h, l, w) # _Blocks is y, z, x del self.rootTag["Blocks"] if "AddBlocks" in self.rootTag: # Use WorldEdit's "AddBlocks" array to load and store the 4 high bits of a block ID. # Unlike Minecraft's NibbleArrays, this array stores the first block's bits in the # 4 high bits of the first byte. size = (h * l * w) # If odd, add one to the size to make sure the adjacent slices line up. add = numpy.empty(size + (size & 1), 'uint16') # Fill the even bytes with data add[::2] = self.rootTag["AddBlocks"].value # Copy the low 4 bits to the odd bytes add[1::2] = add[::2] & 0xf # Shift the even bytes down add[::2] >>= 4 # Shift every byte up before merging it with Blocks add <<= 8 self._Blocks |= add[:size].reshape(h, l, w) del self.rootTag["AddBlocks"] self.rootTag["Data"].value = self.rootTag["Data"].value.reshape( h, l, w) if "Biomes" in self.rootTag: self.rootTag["Biomes"].value.shape = (l, w) # If BlockIDs is present, it contains an ID->internalName mapping # from the source level's FML tag. if "BlockIDs" in self.rootTag: self.blocktypes.addBlockIDsFromSchematicTag( self.rootTag["BlockIDs"]) # If itemStackVersion is present, it was exported from MCEdit 2.0. # Its value is either 17 or 18, the values of the version constants. # ItemIDs will also be present. # If itemStackVersion is not present, this schematic was exported from # WorldEdit or MCEdit 1.0. The itemStackVersion cannot be determined # without searching the entities for an itemStack and checking # the type of its `id` tag. If no itemStacks are found, the # version defaults to 1.8 which does not need an ItemIDs tag. if "itemStackVersion" in self.rootTag: itemStackVersion = self.rootTag["itemStackVersion"].value if itemStackVersion not in (VERSION_1_7, VERSION_1_8): raise LevelFormatError("Unknown item stack version %d" % itemStackVersion) if itemStackVersion == VERSION_1_7: itemIDs = self.rootTag.get("ItemIDs") if itemIDs is not None: self.blocktypes.addItemIDsFromSchematicTag(itemIDs) self.blocktypes.itemStackVersion = itemStackVersion else: self.blocktypes.itemStackVersion = self.getItemStackVersionFromEntities( ) else: rootTag = nbt.TAG_Compound(name="Schematic") rootTag["Height"] = nbt.TAG_Short(shape[1]) rootTag["Length"] = nbt.TAG_Short(shape[2]) rootTag["Width"] = nbt.TAG_Short(shape[0]) rootTag["Entities"] = nbt.TAG_List() rootTag["TileEntities"] = nbt.TAG_List() rootTag["Materials"] = nbt.TAG_String(self.blocktypes.name) rootTag["itemStackVersion"] = nbt.TAG_Byte( self.blocktypes.itemStackVersion) self._Blocks = zeros((shape[1], shape[2], shape[0]), 'uint16') rootTag["Data"] = nbt.TAG_Byte_Array( zeros((shape[1], shape[2], shape[0]), uint8)) rootTag["Biomes"] = nbt.TAG_Byte_Array( zeros((shape[2], shape[0]), uint8)) self.rootTag = rootTag self.rootTag["BlockIDs"] = blockIDMapping(blocktypes) itemMapping = itemIDMapping(blocktypes) if itemMapping is not None: self.rootTag[ "ItemIDs"] = itemMapping # Only present for Forge 1.7 # Expand blocks and data to chunk edges h16 = (self.Height + 15) & ~0xf l16 = (self.Length + 15) & ~0xf w16 = (self.Width + 15) & ~0xf blocks = self._Blocks self._Blocks = numpy.zeros((h16, l16, w16), blocks.dtype) self._Blocks[:blocks.shape[0], :blocks.shape[1], :blocks. shape[2]] = blocks data = self.rootTag["Data"].value self.rootTag["Data"].value = numpy.zeros((h16, l16, w16), data.dtype) self.rootTag["Data"].value[:data.shape[0], :data.shape[1], :data. shape[2]] = data self.rootTag["Data"].value &= 0xF # discard high bits self.entitiesByChunk = defaultdict(list) for tag in self.rootTag["Entities"]: ref = self.EntityRef(tag) pos = ref.Position cx, cy, cz = pos.chunkPos() self.entitiesByChunk[cx, cz].append(tag) self.tileEntitiesByChunk = defaultdict(list) for tag in self.rootTag["TileEntities"]: ref = self.TileEntityRef(tag) pos = ref.Position cx, cy, cz = pos.chunkPos() self.tileEntitiesByChunk[cx, cz].append(tag)
def itemIDMapping(blocktypes): mapping = nbt.TAG_Compound() for name, ID in blocktypes.itemTypes.IDsByInternalName.iteritems(): mapping[str(ID)] = nbt.TAG_String(name) return mapping
def Materials(self, val): if "Materials" not in self.rootTag: self.rootTag["Materials"] = nbt.TAG_String() self.rootTag["Materials"].value = val
def __init__(self, shape=None, filename=None, blocktypes='Alpha', readonly=False, resume=False): """ Creates an object which stores a section of a Minecraft world as an NBT structure. The order of the coordinates for the block arrays in the file is y,z,x. This is the same order used in Minecraft 1.4's chunk sections. :type shape: tuple :param shape: The shape of the schematic as (x, y, z) :type filename: basestring :param filename: Path to a file to load a saved schematic from. :type blocktypes: basestring or BlockTypeSet :param blocktypes: The name of a builtin blocktypes set (one of "Classic", "Alpha", "Pocket") to indicate allowable blocks. The default is Alpha. An instance of BlockTypeSet may be passed instead. :rtype: SchematicFileAdapter """ if filename is None and shape is None: raise ValueError("shape or filename required to create %s" % self.__class__.__name__) if filename: self.filename = filename if os.path.exists(filename): rootTag = nbt.load(filename) else: rootTag = None else: self.filename = None rootTag = None if blocktypes in blocktypes_named: self.blocktypes = blocktypes_named[blocktypes] else: assert (isinstance(blocktypes, BlockTypeSet)) self.blocktypes = blocktypes if rootTag: self.rootTag = rootTag if "Materials" in rootTag: self.blocktypes = blocktypes_named[self.Materials] else: rootTag["Materials"] = nbt.TAG_String(self.blocktypes.name) w = self.rootTag["Width"].value l = self.rootTag["Length"].value h = self.rootTag["Height"].value assert self.rootTag["Blocks"].value.size == w * l * h self._Blocks = self.rootTag["Blocks"].value.astype( 'uint16').reshape(h, l, w) # _Blocks is y, z, x del self.rootTag["Blocks"] if "AddBlocks" in self.rootTag: # Use WorldEdit's "AddBlocks" array to load and store the 4 high bits of a block ID. # Unlike Minecraft's NibbleArrays, this array stores the first block's bits in the # 4 high bits of the first byte. size = (h * l * w) # If odd, add one to the size to make sure the adjacent slices line up. add = numpy.empty(size + (size & 1), 'uint16') # Fill the even bytes with data add[::2] = self.rootTag["AddBlocks"].value # Copy the low 4 bits to the odd bytes add[1::2] = add[::2] & 0xf # Shift the even bytes down add[::2] >>= 4 # Shift every byte up before merging it with Blocks add <<= 8 self._Blocks |= add[:size].reshape(h, l, w) del self.rootTag["AddBlocks"] self.rootTag["Data"].value = self.rootTag["Data"].value.reshape( h, l, w) if "Biomes" in self.rootTag: self.rootTag["Biomes"].value.shape = (l, w) else: rootTag = nbt.TAG_Compound(name="Schematic") rootTag["Height"] = nbt.TAG_Short(shape[1]) rootTag["Length"] = nbt.TAG_Short(shape[2]) rootTag["Width"] = nbt.TAG_Short(shape[0]) rootTag["Entities"] = nbt.TAG_List() rootTag["TileEntities"] = nbt.TAG_List() rootTag["Materials"] = nbt.TAG_String(self.blocktypes.name) self._Blocks = zeros((shape[1], shape[2], shape[0]), 'uint16') rootTag["Data"] = nbt.TAG_Byte_Array( zeros((shape[1], shape[2], shape[0]), uint8)) rootTag["Biomes"] = nbt.TAG_Byte_Array( zeros((shape[2], shape[0]), uint8)) self.rootTag = rootTag #expand blocks and data to chunk edges h16 = (self.Height + 15) & ~0xf l16 = (self.Length + 15) & ~0xf w16 = (self.Width + 15) & ~0xf blocks = self._Blocks self._Blocks = numpy.zeros((h16, l16, w16), blocks.dtype) self._Blocks[:blocks.shape[0], :blocks.shape[1], :blocks. shape[2]] = blocks data = self.rootTag["Data"].value self.rootTag["Data"].value = numpy.zeros((h16, l16, w16), data.dtype) self.rootTag["Data"].value[:data.shape[0], :data.shape[1], :data. shape[2]] = data self.rootTag["Data"].value &= 0xF # discard high bits self.Entities = [ self.EntityRef(tag) for tag in self.rootTag["Entities"] ] self.TileEntities = [ self.EntityRef(tag) for tag in self.rootTag["TileEntities"] ]