821 lines
31 KiB
Python
821 lines
31 KiB
Python
import struct
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from typing import Optional, List, Dict, Any
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from typing_extensions import Final
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from bemani.protocol.stream import InputStream, OutputStream
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from bemani.protocol.node import Node
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class BinaryEncodingException(Exception):
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"""
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Generic exception to be thrown when we encounter an issue decoding a binary stream
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"""
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class PackedOrdering:
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"""
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A class that helps us encapsulate Konami's batshit backtracking hole-fill algorithm.
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Everything is aligned on a boundary appropriate for its data size. Strings and arrays are
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forced to be aligned to a 4 byte boundary on account of having an integer length field.
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All of these are padded to 4 bytes in terms of the room they take up in the stream.
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For the things that are 2 byte or 1 byte aligned, we end up sticking them after each other
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in 4 byte increments. That is, to say, if we have a unsigned byte to pack, we reserve 4 bytes
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and stick it in the first byte slot, and if up to three additional bytes come in we will pack
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them after this in sequential order. It would make sense to not pad out strings and arrays and
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store bytes/shorts in these unused locations, but that's not what actually happens. Also note
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that we will never pack bytes after a short or vice versa, even if there is room. This also explains
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the bizarre behavior of not using spare bytes after strings or arrays. I'll emphasize again:
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everything is stored aligned, and in a 4 byte chunk, only similarly-sized objects can be packed. If
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this 4 byte chunk is already partially occupied, we can only add another thing to it if 1) the
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item being added is the same size as the object that exists and 2) the object can be added with
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the correct alignment.
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A simple example:
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[1: byte] [2: byte] [3: integer]
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Packing would look like this (assuming all locations are a byte):
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1 2 0 0 3 3 3 3
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An example:
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[1: byte] [2: string, length 3] [3: short] [4: byte]
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Packing would look like this (assuming all locations are a byte):
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1 4 0 0 2 2 2 2 2 2 2 0 3 3 0 0
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"""
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def __init__(self, size: int, allow_expansion: bool=False) -> None:
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"""
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Initialize with a known size. If this is to be used to create a packing instead of deduce
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a packing, then allow_expansion should be set to true and new holes will be created when
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needed. If this is to be used for decoding a current packing, allow_expansion should be set
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to False to ensure we don't choose locations outside the buffer.
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Parameters:
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size - Number of bytes to work with as an integer
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allow_expansion - Boolean describing whether to add to the end of the order when needed
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"""
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self.order: List[Optional[int]] = []
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self.expand = allow_expansion
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for _ in range(size):
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self.order.append(None)
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self.__orderlen = size
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self.__lastbyte = 0
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self.__lastshort = 0
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self.__lastint = 0
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def __append_empty(self) -> None:
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self.order.append(None)
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self.__orderlen = self.__orderlen + 1
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def mark_used(self, size: int, offset: int, round_to: int=1) -> None:
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"""
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Mark size bytes at offset as being used. If needed, round to the nearest byte/half/integer.
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Parameters:
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size - Number of bytes to mark
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offset - Offset into binary chunk to start marking
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round_to - Optional integer specifying how many bytes to round to. Valid values are 1, 2 and 4
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"""
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# Round to nearest value if needed
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while (size & (round_to - 1)) != 0:
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size = size + 1
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# Expand buffer if needed
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if self.expand:
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while self.__orderlen < (size + offset):
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self.__append_empty()
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# Mark buffer as used
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for i in range(size):
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self.order[i + offset] = size
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def get_next_byte(self) -> Optional[int]:
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"""
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Returns an integer location where the next byte will be found/stored, respecting Konami logic.
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Will return None if its not possible to find this integer a spot and we aren't expanding.
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"""
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# If we expand for additions, make sure we've padded to a 4 byte boundary
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if self.expand:
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while (self.__orderlen & 3) != 0:
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self.__append_empty()
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for i in range(self.__lastbyte, self.__orderlen, 4):
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if self.order[i] is not None:
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# See if this has room for a byte
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for j in range(0, 4):
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if self.order[i + j] == 1:
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# This is okay, we can pack after this
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continue
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elif self.order[i + j] is None:
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# This is open, pack here
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self.__lastbyte = i
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return i + j
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else:
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# This is something else, can't pack here
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break
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else:
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# Couldn't find optimal packing, pack here
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self.__lastbyte = i
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return i
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if self.expand:
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self.__lastbyte = self.__orderlen
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return self.__orderlen
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else:
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return None
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def get_next_short(self) -> Optional[int]:
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"""
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Returns an integer location where the next short will be found/stored, respecting Konami logic.
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Will return None if its not possible to find this integer a spot and we aren't expanding.
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"""
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# If we expand for additions, make sure we've padded to a 4 byte boundary
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if self.expand:
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while (self.__orderlen & 3) != 0:
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self.__append_empty()
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for i in range(self.__lastshort, self.__orderlen, 4):
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if self.order[i] is not None:
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for j in range(0, 4, 2):
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if self.order[i + j] == 2 and self.order[i + j + 1] == 2:
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# This is okay, we can pack after this
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continue
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elif self.order[i + j] is None and self.order[i + j + 1] is None:
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# This is open, pack here
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self.__lastshort = i
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return i + j
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else:
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# This is something else, can't pack here
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break
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else:
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# Couldn't find optimal packing, pack here
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self.__lastshort = i
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return i
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if self.expand:
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self.__lastshort = self.__orderlen
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return self.__orderlen
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else:
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return None
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def get_next_int(self) -> Optional[int]:
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"""
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Returns an integer location where the next integer will be found/stored, respecting Konami logic.
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Will return None if its not possible to find this integer a spot and we aren't expanding.
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"""
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# If we expand for additions, make sure we've padded to a 4 byte boundary
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if self.expand:
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while (self.__orderlen & 3) != 0:
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self.__append_empty()
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for i in range(self.__lastint, self.__orderlen, 4):
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if self.order[i] is not None:
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continue
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if self.order[i + 1] is not None:
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continue
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if self.order[i + 2] is not None:
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continue
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if self.order[i + 3] is not None:
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continue
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self.__lastint = i
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return i
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if self.expand:
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self.__lastint = self.__orderlen
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return self.__orderlen
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else:
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return None
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@staticmethod
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def node_to_body_ordering(node: Node, include_children: bool=True, include_void: bool=False) -> List[Dict[str, Any]]:
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"""
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Walk this node, attributes and children in the correct order to create a node
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ordering for the purpose of mapping Node objects to their actual data
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in a binary packet data chunk. We will use this to unpack data to determine the
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values of nodes, or to create the data that goes with these nodes.
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Paramters:
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include_children - Whether this ordering should include children. Defaults to True.
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include_void - Whether this ordering should include positions for void nodes. Defaults
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to false.
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Returns:
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List of dictionary objects:
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- type - 'attribute' or 'value' to specify that this position in the
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node walk is a string attribute or a node value
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- node - This Node object, for the purpose of assignment
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- name - The name of the attribute if type is 'attribute' or the name
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of the node if type is 'value'
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- alignment - The alignment that this particular data object requiers
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"""
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ordering = []
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# Include the node itself if it has a value or we include voids
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if node.data_length != 0 or include_void:
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alignment = node.data_length
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if alignment is None:
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# Take care of string types
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alignment = 4
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if alignment > 4:
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# Take care of 64 bit integers that are 32 bit aligned
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alignment = 4
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ordering.append({
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'type': 'value',
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'node': node,
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'name': node.name,
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'alignment': alignment,
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})
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order = sorted(node.attributes.keys())
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for attr in order:
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ordering.append({
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'type': 'attribute',
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'node': node,
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'name': attr,
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'alignment': 4,
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})
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if include_children:
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for child in node.children:
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ordering.extend(PackedOrdering.node_to_body_ordering(child))
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return ordering
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class BinaryDecoder:
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"""
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A class capable of taking a binary blob and decoding it to a Node tree.
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"""
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def __init__(self, data: bytes, encoding: str) -> None:
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"""
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Initialize the object.
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Parameters:
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- data - A binary blob of data to be decoded
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- encoding - A string representing the text encoding for string elements. Should be either
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'shift-jis', 'euc-jp' or 'utf-8'
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"""
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self.stream = InputStream(data)
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self.encoding = encoding
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self.executed = False
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def __read_node_name(self) -> str:
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"""
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Given the current position in the stream, read the 6-bit-byte packed string name of the
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node.
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Returns:
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A string representing the name in ascii
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"""
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length = self.stream.read_int()
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if length is None:
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raise BinaryEncodingException("Ran out of data when attempting to read node name length!")
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binary_length = int(((length * 6) + 7) / 8)
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def int_to_bin(integer: int) -> str:
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val = bin(integer)[2:]
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while len(val) < 8:
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val = '0' + val
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return val
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data = ''
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for _ in range(binary_length):
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next_byte = self.stream.read_int()
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if next_byte is None:
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raise BinaryEncodingException("Ran out of data when attempting to read node name!")
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data = data + int_to_bin(next_byte)
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data_str = [data[i:(i + 6)] for i in range(0, len(data), 6)]
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data_int = [int(val, 2) for val in data_str]
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ret = ''.join([Node.NODE_NAME_CHARS[val] for val in data_int])
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ret = ret[:length]
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return ret
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def __read_node(self, node_type: int) -> Node:
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"""
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Given an integer node type, read the node's name, possible attributes
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and children. Will return a Node representing this node. Note
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that calling this on the first node should return a tree of all nodes.
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Returns:
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Node object
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"""
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name = self.__read_node_name()
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node = Node(name=name, type=node_type)
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while True:
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child_type = self.stream.read_int()
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if child_type is None:
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raise BinaryEncodingException("Ran out of data when attempting to read node type!")
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if child_type == Node.END_OF_NODE:
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return node
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elif child_type == Node.ATTR_TYPE:
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key = self.__read_node_name()
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node.set_attribute(key)
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else:
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child = self.__read_node(child_type)
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node.add_child(child)
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def get_tree(self) -> Node:
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"""
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Parse the header and body such that we can return a Node tree
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representing the data passed to us.
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Returns:
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Node object
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"""
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if self.executed:
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raise BinaryEncodingException("Logic error, should only call this once per instance")
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self.executed = True
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# Read the header first
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header_length = self.stream.read_int(4)
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if header_length is None:
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raise BinaryEncodingException("Ran out of data when attempting to read header length!")
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node_type = self.stream.read_int()
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if node_type is None:
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raise BinaryEncodingException("Ran out of data when attempting to read root node type!")
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root = self.__read_node(node_type)
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eod = self.stream.read_int()
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if eod != Node.END_OF_DOCUMENT:
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raise BinaryEncodingException(f'Unknown node type {eod} at end of document')
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# Skip by any padding
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while self.stream.pos < header_length + 4:
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self.stream.read_byte()
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# Read the body next
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body_length = self.stream.read_int(4)
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if body_length is not None and body_length > 0:
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# We have a body
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body = self.stream.read_blob(body_length)
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if body is None:
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raise BinaryEncodingException('Body has insufficient data')
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ordering = PackedOrdering(body_length)
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values = PackedOrdering.node_to_body_ordering(root)
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for value in values:
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node = value['node']
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if value['type'] == 'attribute':
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size = None
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enc = 's'
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dtype = 'str'
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array = False
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composite = False
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else:
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size = node.data_length
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enc = node.data_encoding
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dtype = node.data_type
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array = node.is_array
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composite = node.is_composite
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if composite and array:
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raise Exception('Logic error, no support for composite arrays!')
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if not array:
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# Scalar value
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alignment = value['alignment']
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if alignment == 1:
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loc = ordering.get_next_byte()
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elif alignment == 2:
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loc = ordering.get_next_short()
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elif alignment == 4:
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loc = ordering.get_next_int()
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if loc is None:
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raise BinaryEncodingException("Ran out of data when attempting to read node data location!")
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if size is None:
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# The size should be read from the first 4 bytes
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size = struct.unpack('>I', body[loc:(loc + 4)])[0]
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ordering.mark_used(size + 4, loc, round_to=4)
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loc = loc + 4
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decode_data = body[loc:(loc + size)]
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decode_value = f'>{size}{enc}'
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else:
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# The size is built-in
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ordering.mark_used(size, loc)
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decode_data = body[loc:(loc + size)]
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decode_value = f'>{enc}'
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if composite:
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val_list = list(struct.unpack(decode_value, decode_data))
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if value['type'] == 'attribute':
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raise Exception('Logic error, shouldn\'t have composite attribute type!')
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node.set_value(val_list)
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continue
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val = struct.unpack(decode_value, decode_data)[0]
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if dtype == 'str':
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# Need to convert this from encoding to standard string.
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# Also, need to lob off the trailing null.
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try:
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val = val[:-1].decode(self.encoding)
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except UnicodeDecodeError:
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# Nothing we can do here
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pass
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if value['type'] == 'attribute':
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node.set_attribute(value['name'], val)
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else:
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node.set_value(val)
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else:
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# Array value
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loc = ordering.get_next_int()
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if loc is None:
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raise BinaryEncodingException("Ran out of data when attempting to read array length location!")
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# The raw size in bytes
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length = struct.unpack('>I', body[loc:(loc + 4)])[0]
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elems = int(length / size)
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ordering.mark_used(length + 4, loc, round_to=4)
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loc = loc + 4
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decode_data = body[loc:(loc + length)]
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decode_value = f'>{enc * elems}'
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val = struct.unpack(decode_value, decode_data)
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node.set_value([v for v in val])
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return root
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|
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class BinaryEncoder:
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"""
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A class capable of taking a Node tree and encoding it into a binary format.
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"""
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def __init__(self, tree: Node, encoding: str) -> None:
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"""
|
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Initialize the object.
|
|
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Parameters:
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tree - A binary blob of data to be decoded
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encoding - A string representing the text encoding for string elements. Should be either
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'shift-jis', 'euc-jp' or 'utf-8'
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"""
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self.stream = OutputStream()
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self.encoding = encoding
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self.tree = tree
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self.__body: List[int] = []
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self.__body_len = 0
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self.executed = False
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# Generate the characer LUT
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self.char_lut: Dict[str, int] = {}
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for i in range(len(Node.NODE_NAME_CHARS)):
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self.char_lut[Node.NODE_NAME_CHARS[i]] = i
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def __write_node_name(self, name: str) -> None:
|
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"""
|
|
Given the current position in the stream, write the 6-bit-byte packed string name of the
|
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node.
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|
Parameters:
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name - A string name which should be encoded as a node name
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"""
|
|
def char_to_bin(ch: str) -> str:
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index = self.char_lut[ch]
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val = bin(index)[2:]
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|
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while len(val) < 6:
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val = '0' + val
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return val[-6:]
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|
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# Convert to six bit bytes
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length = len(name)
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data = ''.join([char_to_bin(c) for c in name])
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# Pad out the rest with zeros
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while (len(data) & 0x7) != 0:
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data = data + '0'
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# Convert to 8-bit bytes
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data_chunks = [data[i:(i + 8)] for i in range(0, len(data), 8)]
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data_int = [int(val, 2) for val in data_chunks]
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# Output
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self.stream.write_int(length)
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for val in data_int:
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self.stream.write_int(val)
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|
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def __write_node(self, node: Node) -> None:
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"""
|
|
Given an integer node type, read the node's name, possible attributes
|
|
and children. Will return a Node representing this node. Note
|
|
that calling this on the first node should return a tree of all nodes.
|
|
|
|
Parameters:
|
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node - A Node which should be encoded.
|
|
"""
|
|
to_write = PackedOrdering.node_to_body_ordering(node, include_children=False, include_void=True)
|
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for thing in to_write:
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# First, write the type of this node out
|
|
if thing['type'] == 'value':
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self.stream.write_int(thing['node'].type)
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|
else:
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self.stream.write_int(Node.ATTR_TYPE)
|
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# Now, write the name out
|
|
self.__write_node_name(thing['name'])
|
|
|
|
# Now, write out the children
|
|
for child in node.children:
|
|
self.__write_node(child)
|
|
|
|
# Now, write out the end of node marker
|
|
self.stream.write_int(Node.END_OF_NODE)
|
|
|
|
def __add_data(self, data: bytes, length: int, offset: int) -> None:
|
|
"""
|
|
Given some binary data, a length and an offset, add the data to the offset in the
|
|
output body. This function will ensure that any new bytes that aren't copied are
|
|
zero'd out. This includes bytes before the offset as well as any pad bytes after
|
|
the offset + length in order to pad this body to a 4 byte boundary.
|
|
|
|
Parameters:
|
|
data - A blob of binary data which should be copied into the output
|
|
length - Number of characters of data to copy
|
|
offset - Offset into the body to start copying
|
|
"""
|
|
while self.__body_len < (length + offset):
|
|
self.__body.append(0)
|
|
self.__body_len = self.__body_len + 1
|
|
|
|
# Make sure its padded to 4 bytes
|
|
while (self.__body_len & 0x3) != 0:
|
|
self.__body.append(0)
|
|
self.__body_len = self.__body_len + 1
|
|
|
|
for i in range(length):
|
|
self.__body[offset + i] = data[i]
|
|
|
|
def get_data(self) -> bytes:
|
|
"""
|
|
Encode the header and body into binary formrt.
|
|
|
|
Returns:
|
|
Binary blob of data that can be decoded by a game.
|
|
"""
|
|
if self.executed:
|
|
raise Exception("Logic error, should only call this once per instance")
|
|
self.executed = True
|
|
|
|
# Generate the header first
|
|
self.__write_node(self.tree)
|
|
self.stream.write_int(Node.END_OF_DOCUMENT)
|
|
self.stream.write_pad(4)
|
|
|
|
header_length = len(self.stream.data)
|
|
header = self.stream.data[:]
|
|
|
|
# Generate the body
|
|
values = PackedOrdering.node_to_body_ordering(self.tree)
|
|
if len(values) > 0:
|
|
ordering = PackedOrdering(0, allow_expansion=True)
|
|
|
|
for value in values:
|
|
node = value['node']
|
|
|
|
if value['type'] == 'attribute':
|
|
size = None
|
|
enc = 's'
|
|
dtype = 'str'
|
|
array = False
|
|
composite = False
|
|
val = node.attribute(value['name'])
|
|
else:
|
|
size = node.data_length
|
|
enc = node.data_encoding
|
|
dtype = node.data_type
|
|
array = node.is_array
|
|
composite = node.is_composite
|
|
val = node.value
|
|
|
|
if val is None:
|
|
raise BinaryEncodingException(
|
|
f'Node \'{value["name"]}\' has invalid value None',
|
|
)
|
|
|
|
if not array:
|
|
# Scalar value
|
|
alignment = value['alignment']
|
|
|
|
if alignment == 1:
|
|
loc = ordering.get_next_byte()
|
|
elif alignment == 2:
|
|
loc = ordering.get_next_short()
|
|
elif alignment == 4:
|
|
loc = ordering.get_next_int()
|
|
if loc is None:
|
|
raise BinaryEncodingException("Ran out of data when attempting to allocate node location!")
|
|
|
|
if dtype == 'str':
|
|
# Need to convert this to encoding from standard string.
|
|
# Also, need to lob off the trailing null.
|
|
if not isinstance(val, str):
|
|
raise BinaryEncodingException(
|
|
f'Node \'{value["name"]}\' has non-string value!',
|
|
)
|
|
|
|
try:
|
|
valbytes = val.encode(self.encoding) + b'\0'
|
|
except UnicodeEncodeError:
|
|
raise BinaryEncodingException(
|
|
f'Node \'{value["name"]}\' has un-encodable string value \'{val}\''
|
|
)
|
|
size = len(valbytes)
|
|
self.__add_data(struct.pack('>I', size) + valbytes, size + 4, loc)
|
|
ordering.mark_used(size + 4, loc, round_to=4)
|
|
|
|
# We took care of this one
|
|
continue
|
|
elif dtype == 'bin':
|
|
# Store raw binary
|
|
size = len(val)
|
|
self.__add_data(struct.pack('>I', size) + val, size + 4, loc)
|
|
ordering.mark_used(size + 4, loc, round_to=4)
|
|
|
|
# We took care of this one
|
|
continue
|
|
elif composite:
|
|
# Array, but not, somewhat silly
|
|
if size is None:
|
|
raise Exception("Logic error, node size not set yet this is not an attribute!")
|
|
|
|
encode_value = f'>{enc}'
|
|
self.__add_data(struct.pack(encode_value, *val), size, loc)
|
|
ordering.mark_used(size, loc)
|
|
|
|
# We took care of this one
|
|
continue
|
|
elif dtype == 'bool':
|
|
val = 1 if val else 0
|
|
|
|
# The size is built-in, emit it
|
|
if size is None:
|
|
raise Exception("Logic error, node size not set yet this is not an attribute!")
|
|
|
|
encode_value = f'>{enc}'
|
|
self.__add_data(struct.pack(encode_value, val), size, loc)
|
|
ordering.mark_used(size, loc)
|
|
else:
|
|
# Array value
|
|
loc = ordering.get_next_int()
|
|
if loc is None:
|
|
raise BinaryEncodingException("Ran out of data when attempting allocate array location!")
|
|
if size is None:
|
|
raise Exception("Logic error, node size not set yet this is not an attribute!")
|
|
|
|
# The raw size in bytes
|
|
elems = len(val)
|
|
length = elems * size
|
|
|
|
# Write out the header (number of bytes taken up)
|
|
data = struct.pack('>I', length)
|
|
encode_value = f'>{enc}'
|
|
|
|
# Write out data one element at a time
|
|
for v in val:
|
|
if dtype == 'bool':
|
|
data = data + struct.pack(encode_value, 1 if v else 0)
|
|
else:
|
|
data = data + struct.pack(encode_value, v)
|
|
|
|
self.__add_data(data, length + 4, loc)
|
|
ordering.mark_used(length + 4, loc, round_to=4)
|
|
|
|
return b''.join([
|
|
struct.pack('>I', header_length),
|
|
header,
|
|
struct.pack('>I', self.__body_len),
|
|
bytes(self.__body),
|
|
])
|
|
|
|
|
|
class BinaryEncoding:
|
|
"""
|
|
Wrapper class representing a Binary Encoding.
|
|
"""
|
|
MAGIC: Final[int] = 0xA0
|
|
|
|
COMPRESSED_WITH_DATA: Final[int] = 0x42
|
|
COMPRESSED_WITHOUT_DATA: Final[int] = 0x43
|
|
DECOMPRESSED_WITH_DATA: Final[int] = 0x45
|
|
DECOMPRESSED_WITHOUT_DATA: Final[int] = 0x46
|
|
|
|
# The string values should match the constants in EAmuseProtocol.
|
|
# I have no better way to link these than to write this comment,
|
|
# as otherwise we would have a circular dependency.
|
|
ENCODINGS: Final[Dict[int, str]] = {
|
|
0x00: "ascii",
|
|
0x20: "shift-jis-legacy",
|
|
0x60: "euc-jp",
|
|
0x80: "shift-jis",
|
|
0xA0: "utf-8",
|
|
}
|
|
|
|
def __init__(self) -> None:
|
|
"""
|
|
Initialize the encoding object.
|
|
"""
|
|
self.encoding: Optional[str] = None
|
|
|
|
def __sanitize_encoding(self, enc: str) -> str:
|
|
"""
|
|
Convert an internal encoding value from an externally acceptible value.
|
|
|
|
Parameters:
|
|
enc - The encoding as a string as passed from an outside caller
|
|
|
|
Returns:
|
|
An encoding string suitable for internal use.
|
|
"""
|
|
if enc == "shift-jis-legacy":
|
|
return "shift-jis"
|
|
return enc
|
|
|
|
def decode(self, data: bytes, skip_on_exceptions: bool=False) -> Optional[Node]:
|
|
"""
|
|
Given a data blob, decode the data with the current encoding. Will
|
|
also set the class property value 'encoding' to the encoding used
|
|
on the last decode.
|
|
|
|
Parameters:
|
|
data - Binary blob representing the data to decode
|
|
|
|
Returns:
|
|
Node object representing the root of the decoded tree, or None
|
|
if we couldn't decode the object for some reason.
|
|
"""
|
|
try:
|
|
data_magic, contents, encoding_raw, encoding_swapped = struct.unpack(">BBBB", data[0:4])
|
|
except struct.error:
|
|
# Couldn't even parse magic
|
|
return None
|
|
|
|
if data_magic != BinaryEncoding.MAGIC:
|
|
return None
|
|
if ((~encoding_raw) & 0xFF) != encoding_swapped:
|
|
return None
|
|
if contents not in [BinaryEncoding.COMPRESSED_WITH_DATA, BinaryEncoding.COMPRESSED_WITHOUT_DATA]:
|
|
# We don't support uncompressed data.
|
|
return None
|
|
|
|
encoding = BinaryEncoding.ENCODINGS.get(encoding_raw)
|
|
|
|
if encoding is not None:
|
|
self.encoding = encoding
|
|
try:
|
|
decoder = BinaryDecoder(data[4:], self.__sanitize_encoding(encoding))
|
|
return decoder.get_tree()
|
|
except BinaryEncodingException:
|
|
if skip_on_exceptions:
|
|
return None
|
|
else:
|
|
raise
|
|
else:
|
|
return None
|
|
|
|
def encode(self, tree: Node, encoding: Optional[str]=None) -> bytes:
|
|
"""
|
|
Given a tree of Node objects, encode the data with the current encoding.
|
|
|
|
Parameters:
|
|
tree - Node tree representing the data to encode
|
|
encoding - The text encoding to use. If None, will try to use the encoding from
|
|
the last successful decode
|
|
|
|
Returns:
|
|
Binary blob representing encoded data
|
|
"""
|
|
if encoding is None:
|
|
encoding = self.encoding
|
|
if encoding is None:
|
|
raise BinaryEncodingException('Unknown encoding')
|
|
|
|
encoding_magic = None
|
|
for magic, encstr in BinaryEncoding.ENCODINGS.items():
|
|
if encstr == encoding:
|
|
encoding_magic = magic
|
|
break
|
|
|
|
if encoding_magic is None:
|
|
raise BinaryEncodingException(f"Invalid text encoding {encoding}")
|
|
|
|
encoder = BinaryEncoder(tree, self.__sanitize_encoding(encoding))
|
|
data = encoder.get_data()
|
|
return struct.pack(">BBBB", BinaryEncoding.MAGIC, BinaryEncoding.COMPRESSED_WITH_DATA, encoding_magic, (~encoding_magic & 0xFF)) + data
|