635 lines
21 KiB
Python
635 lines
21 KiB
Python
from .lib.py3compat import int2byte
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from .lib import (BitStreamReader, BitStreamWriter, encode_bin,
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decode_bin)
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from .core import (Struct, MetaField, StaticField, FormatField,
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OnDemand, Pointer, Switch, Value, RepeatUntil, MetaArray, Sequence, Range,
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Select, Pass, SizeofError, Buffered, Restream, Reconfig)
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from .adapters import (BitIntegerAdapter, PaddingAdapter,
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ConstAdapter, CStringAdapter, LengthValueAdapter, IndexingAdapter,
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PaddedStringAdapter, FlagsAdapter, StringAdapter, MappingAdapter)
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#===============================================================================
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# fields
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#===============================================================================
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def Field(name, length):
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"""
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A field consisting of a specified number of bytes.
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:param str name: the name of the field
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:param length: the length of the field. the length can be either an integer
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(StaticField), or a function that takes the context as an argument and
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returns the length (MetaField)
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"""
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if callable(length):
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return MetaField(name, length)
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else:
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return StaticField(name, length)
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def BitField(name, length, swapped = False, signed = False, bytesize = 8):
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"""
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BitFields, as the name suggests, are fields that operate on raw, unaligned
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bits, and therefore must be enclosed in a BitStruct. Using them is very
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similar to all normal fields: they take a name and a length (in bits).
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:param str name: name of the field
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:param int length: number of bits in the field, or a function that takes
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the context as its argument and returns the length
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:param bool swapped: whether the value is byte-swapped
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:param bool signed: whether the value is signed
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:param int bytesize: number of bits per byte, for byte-swapping
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>>> foo = BitStruct("foo",
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... BitField("a", 3),
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... Flag("b"),
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... Padding(3),
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... Nibble("c"),
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... BitField("d", 5),
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... )
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>>> foo.parse("\\xe1\\x1f")
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Container(a = 7, b = False, c = 8, d = 31)
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>>> foo = BitStruct("foo",
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... BitField("a", 3),
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... Flag("b"),
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... Padding(3),
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... Nibble("c"),
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... Struct("bar",
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... Nibble("d"),
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... Bit("e"),
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... )
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... )
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>>> foo.parse("\\xe1\\x1f")
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Container(a = 7, b = False, bar = Container(d = 15, e = 1), c = 8)
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"""
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return BitIntegerAdapter(Field(name, length),
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length,
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swapped=swapped,
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signed=signed,
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bytesize=bytesize
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)
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def Padding(length, pattern = b"\x00", strict = False):
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r"""a padding field (value is discarded)
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* length - the length of the field. the length can be either an integer,
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or a function that takes the context as an argument and returns the
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length
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* pattern - the padding pattern (character/byte) to use. default is b"\x00"
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* strict - whether or not to raise an exception is the actual padding
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pattern mismatches the desired pattern. default is False.
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"""
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return PaddingAdapter(Field(None, length),
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pattern = pattern,
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strict = strict,
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)
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def Flag(name, truth = 1, falsehood = 0, default = False):
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"""
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A flag.
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Flags are usually used to signify a Boolean value, and this construct
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maps values onto the ``bool`` type.
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.. note:: This construct works with both bit and byte contexts.
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.. warning:: Flags default to False, not True. This is different from the
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C and Python way of thinking about truth, and may be subject to change
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in the future.
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:param str name: field name
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:param int truth: value of truth (default 1)
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:param int falsehood: value of falsehood (default 0)
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:param bool default: default value (default False)
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"""
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return SymmetricMapping(Field(name, 1),
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{True : int2byte(truth), False : int2byte(falsehood)},
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default = default,
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)
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#===============================================================================
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# field shortcuts
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#===============================================================================
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def Bit(name):
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"""a 1-bit BitField; must be enclosed in a BitStruct"""
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return BitField(name, 1)
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def Nibble(name):
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"""a 4-bit BitField; must be enclosed in a BitStruct"""
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return BitField(name, 4)
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def Octet(name):
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"""an 8-bit BitField; must be enclosed in a BitStruct"""
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return BitField(name, 8)
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def UBInt8(name):
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"""unsigned, big endian 8-bit integer"""
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return FormatField(name, ">", "B")
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def UBInt16(name):
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"""unsigned, big endian 16-bit integer"""
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return FormatField(name, ">", "H")
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def UBInt32(name):
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"""unsigned, big endian 32-bit integer"""
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return FormatField(name, ">", "L")
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def UBInt64(name):
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"""unsigned, big endian 64-bit integer"""
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return FormatField(name, ">", "Q")
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def SBInt8(name):
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"""signed, big endian 8-bit integer"""
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return FormatField(name, ">", "b")
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def SBInt16(name):
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"""signed, big endian 16-bit integer"""
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return FormatField(name, ">", "h")
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def SBInt32(name):
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"""signed, big endian 32-bit integer"""
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return FormatField(name, ">", "l")
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def SBInt64(name):
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"""signed, big endian 64-bit integer"""
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return FormatField(name, ">", "q")
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def ULInt8(name):
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"""unsigned, little endian 8-bit integer"""
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return FormatField(name, "<", "B")
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def ULInt16(name):
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"""unsigned, little endian 16-bit integer"""
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return FormatField(name, "<", "H")
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def ULInt32(name):
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"""unsigned, little endian 32-bit integer"""
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return FormatField(name, "<", "L")
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def ULInt64(name):
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"""unsigned, little endian 64-bit integer"""
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return FormatField(name, "<", "Q")
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def SLInt8(name):
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"""signed, little endian 8-bit integer"""
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return FormatField(name, "<", "b")
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def SLInt16(name):
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"""signed, little endian 16-bit integer"""
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return FormatField(name, "<", "h")
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def SLInt32(name):
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"""signed, little endian 32-bit integer"""
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return FormatField(name, "<", "l")
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def SLInt64(name):
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"""signed, little endian 64-bit integer"""
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return FormatField(name, "<", "q")
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def UNInt8(name):
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"""unsigned, native endianity 8-bit integer"""
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return FormatField(name, "=", "B")
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def UNInt16(name):
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"""unsigned, native endianity 16-bit integer"""
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return FormatField(name, "=", "H")
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def UNInt32(name):
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"""unsigned, native endianity 32-bit integer"""
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return FormatField(name, "=", "L")
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def UNInt64(name):
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"""unsigned, native endianity 64-bit integer"""
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return FormatField(name, "=", "Q")
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def SNInt8(name):
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"""signed, native endianity 8-bit integer"""
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return FormatField(name, "=", "b")
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def SNInt16(name):
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"""signed, native endianity 16-bit integer"""
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return FormatField(name, "=", "h")
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def SNInt32(name):
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"""signed, native endianity 32-bit integer"""
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return FormatField(name, "=", "l")
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def SNInt64(name):
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"""signed, native endianity 64-bit integer"""
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return FormatField(name, "=", "q")
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def BFloat32(name):
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"""big endian, 32-bit IEEE floating point number"""
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return FormatField(name, ">", "f")
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def LFloat32(name):
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"""little endian, 32-bit IEEE floating point number"""
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return FormatField(name, "<", "f")
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def NFloat32(name):
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"""native endianity, 32-bit IEEE floating point number"""
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return FormatField(name, "=", "f")
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def BFloat64(name):
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"""big endian, 64-bit IEEE floating point number"""
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return FormatField(name, ">", "d")
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def LFloat64(name):
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"""little endian, 64-bit IEEE floating point number"""
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return FormatField(name, "<", "d")
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def NFloat64(name):
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"""native endianity, 64-bit IEEE floating point number"""
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return FormatField(name, "=", "d")
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#===============================================================================
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# arrays
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#===============================================================================
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def Array(count, subcon):
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"""
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Repeats the given unit a fixed number of times.
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:param int count: number of times to repeat
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:param ``Construct`` subcon: construct to repeat
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>>> c = Array(4, UBInt8("foo"))
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>>> c.parse("\\x01\\x02\\x03\\x04")
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[1, 2, 3, 4]
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>>> c.parse("\\x01\\x02\\x03\\x04\\x05\\x06")
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[1, 2, 3, 4]
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>>> c.build([5,6,7,8])
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'\\x05\\x06\\x07\\x08'
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>>> c.build([5,6,7,8,9])
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Traceback (most recent call last):
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...
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construct.core.RangeError: expected 4..4, found 5
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"""
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if callable(count):
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con = MetaArray(count, subcon)
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else:
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con = MetaArray(lambda ctx: count, subcon)
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con._clear_flag(con.FLAG_DYNAMIC)
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return con
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def PrefixedArray(subcon, length_field = UBInt8("length")):
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"""an array prefixed by a length field.
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* subcon - the subcon to be repeated
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* length_field - a construct returning an integer
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"""
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return LengthValueAdapter(
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Sequence(subcon.name,
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length_field,
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Array(lambda ctx: ctx[length_field.name], subcon),
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nested = False
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)
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)
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def OpenRange(mincount, subcon):
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from sys import maxsize
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return Range(mincount, maxsize, subcon)
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def GreedyRange(subcon):
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"""
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Repeats the given unit one or more times.
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:param ``Construct`` subcon: construct to repeat
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>>> from construct import GreedyRange, UBInt8
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>>> c = GreedyRange(UBInt8("foo"))
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>>> c.parse("\\x01")
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[1]
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>>> c.parse("\\x01\\x02\\x03")
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[1, 2, 3]
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>>> c.parse("\\x01\\x02\\x03\\x04\\x05\\x06")
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[1, 2, 3, 4, 5, 6]
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>>> c.parse("")
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Traceback (most recent call last):
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...
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construct.core.RangeError: expected 1..2147483647, found 0
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>>> c.build([1,2])
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'\\x01\\x02'
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>>> c.build([])
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Traceback (most recent call last):
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...
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construct.core.RangeError: expected 1..2147483647, found 0
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"""
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return OpenRange(1, subcon)
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def OptionalGreedyRange(subcon):
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"""
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Repeats the given unit zero or more times. This repeater can't
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fail, as it accepts lists of any length.
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:param ``Construct`` subcon: construct to repeat
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>>> from construct import OptionalGreedyRange, UBInt8
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>>> c = OptionalGreedyRange(UBInt8("foo"))
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>>> c.parse("")
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[]
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>>> c.parse("\\x01\\x02")
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[1, 2]
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>>> c.build([])
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''
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>>> c.build([1,2])
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'\\x01\\x02'
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"""
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return OpenRange(0, subcon)
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#===============================================================================
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# subconstructs
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#===============================================================================
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def Optional(subcon):
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"""an optional construct. if parsing fails, returns None.
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* subcon - the subcon to optionally parse or build
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"""
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return Select(subcon.name, subcon, Pass)
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def Bitwise(subcon):
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"""converts the stream to bits, and passes the bitstream to subcon
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* subcon - a bitwise construct (usually BitField)
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"""
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# subcons larger than MAX_BUFFER will be wrapped by Restream instead
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# of Buffered. implementation details, don't stick your nose in :)
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MAX_BUFFER = 1024 * 8
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def resizer(length):
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if length & 7:
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raise SizeofError("size must be a multiple of 8", length)
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return length >> 3
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if not subcon._is_flag(subcon.FLAG_DYNAMIC) and subcon.sizeof() < MAX_BUFFER:
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con = Buffered(subcon,
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encoder = decode_bin,
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decoder = encode_bin,
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resizer = resizer
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)
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else:
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con = Restream(subcon,
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stream_reader = BitStreamReader,
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stream_writer = BitStreamWriter,
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resizer = resizer)
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return con
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def Aligned(subcon, modulus = 4, pattern = b"\x00"):
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r"""aligns subcon to modulus boundary using padding pattern
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* subcon - the subcon to align
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* modulus - the modulus boundary (default is 4)
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* pattern - the padding pattern (default is \x00)
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"""
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if modulus < 2:
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raise ValueError("modulus must be >= 2", modulus)
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def padlength(ctx):
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return (modulus - (subcon._sizeof(ctx) % modulus)) % modulus
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return SeqOfOne(subcon.name,
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subcon,
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# ??????
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# ??????
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# ??????
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# ??????
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Padding(padlength, pattern = pattern),
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nested = False,
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)
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def SeqOfOne(name, *args, **kw):
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"""a sequence of one element. only the first element is meaningful, the
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rest are discarded
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* name - the name of the sequence
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* args - subconstructs
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* kw - any keyword arguments to Sequence
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"""
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return IndexingAdapter(Sequence(name, *args, **kw), index = 0)
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def Embedded(subcon):
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"""embeds a struct into the enclosing struct.
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* subcon - the struct to embed
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"""
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return Reconfig(subcon.name, subcon, subcon.FLAG_EMBED)
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def Rename(newname, subcon):
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"""renames an existing construct
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* newname - the new name
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* subcon - the subcon to rename
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"""
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return Reconfig(newname, subcon)
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def Alias(newname, oldname):
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"""creates an alias for an existing element in a struct
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* newname - the new name
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* oldname - the name of an existing element
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"""
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return Value(newname, lambda ctx: ctx[oldname])
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#===============================================================================
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# mapping
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#===============================================================================
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def SymmetricMapping(subcon, mapping, default = NotImplemented):
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"""defines a symmetrical mapping: a->b, b->a.
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* subcon - the subcon to map
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* mapping - the encoding mapping (a dict); the decoding mapping is
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achieved by reversing this mapping
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* default - the default value to use when no mapping is found. if no
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default value is given, and exception is raised. setting to Pass would
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return the value "as is" (unmapped)
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"""
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reversed_mapping = dict((v, k) for k, v in mapping.items())
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return MappingAdapter(subcon,
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encoding = mapping,
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decoding = reversed_mapping,
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encdefault = default,
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decdefault = default,
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)
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def Enum(subcon, **kw):
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"""a set of named values mapping.
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* subcon - the subcon to map
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* kw - keyword arguments which serve as the encoding mapping
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* _default_ - an optional, keyword-only argument that specifies the
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default value to use when the mapping is undefined. if not given,
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and exception is raised when the mapping is undefined. use `Pass` to
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pass the unmapped value as-is
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"""
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return SymmetricMapping(subcon, kw, kw.pop("_default_", NotImplemented))
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def FlagsEnum(subcon, **kw):
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"""a set of flag values mapping.
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* subcon - the subcon to map
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* kw - keyword arguments which serve as the encoding mapping
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"""
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return FlagsAdapter(subcon, kw)
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#===============================================================================
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# structs
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#===============================================================================
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def AlignedStruct(name, *subcons, **kw):
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"""a struct of aligned fields
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* name - the name of the struct
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* subcons - the subcons that make up this structure
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* kw - keyword arguments to pass to Aligned: 'modulus' and 'pattern'
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"""
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return Struct(name, *(Aligned(sc, **kw) for sc in subcons))
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def BitStruct(name, *subcons):
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"""a struct of bitwise fields
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* name - the name of the struct
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* subcons - the subcons that make up this structure
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"""
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return Bitwise(Struct(name, *subcons))
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def EmbeddedBitStruct(*subcons):
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"""an embedded BitStruct. no name is necessary.
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* subcons - the subcons that make up this structure
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"""
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return Bitwise(Embedded(Struct(None, *subcons)))
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#===============================================================================
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# strings
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#===============================================================================
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def String(name, length, encoding=None, padchar=None, paddir="right",
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trimdir="right"):
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"""
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A configurable, fixed-length string field.
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The padding character must be specified for padding and trimming to work.
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:param str name: name
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:param int length: length, in bytes
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:param str encoding: encoding (e.g. "utf8") or None for no encoding
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:param str padchar: optional character to pad out strings
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:param str paddir: direction to pad out strings; one of "right", "left",
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or "both"
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:param str trim: direction to trim strings; one of "right", "left"
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>>> from construct import String
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>>> String("foo", 5).parse("hello")
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'hello'
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>>>
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>>> String("foo", 12, encoding = "utf8").parse("hello joh\\xd4\\x83n")
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u'hello joh\\u0503n'
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>>>
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>>> foo = String("foo", 10, padchar = "X", paddir = "right")
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>>> foo.parse("helloXXXXX")
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'hello'
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>>> foo.build("hello")
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'helloXXXXX'
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"""
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con = StringAdapter(Field(name, length), encoding=encoding)
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if padchar is not None:
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con = PaddedStringAdapter(con, padchar=padchar, paddir=paddir,
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trimdir=trimdir)
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return con
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def PascalString(name, length_field=UBInt8("length"), encoding=None):
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"""
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A length-prefixed string.
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``PascalString`` is named after the string types of Pascal, which are
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length-prefixed. Lisp strings also follow this convention.
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The length field will appear in the same ``Container`` as the
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``PascalString``, with the given name.
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:param str name: name
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:param ``Construct`` length_field: a field which will store the length of
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the string
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:param str encoding: encoding (e.g. "utf8") or None for no encoding
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|
|
>>> foo = PascalString("foo")
|
|
>>> foo.parse("\\x05hello")
|
|
'hello'
|
|
>>> foo.build("hello world")
|
|
'\\x0bhello world'
|
|
>>>
|
|
>>> foo = PascalString("foo", length_field = UBInt16("length"))
|
|
>>> foo.parse("\\x00\\x05hello")
|
|
'hello'
|
|
>>> foo.build("hello")
|
|
'\\x00\\x05hello'
|
|
"""
|
|
|
|
return StringAdapter(
|
|
LengthValueAdapter(
|
|
Sequence(name,
|
|
length_field,
|
|
Field("data", lambda ctx: ctx[length_field.name]),
|
|
)
|
|
),
|
|
encoding=encoding,
|
|
)
|
|
|
|
def CString(name, terminators=b"\x00", encoding=None,
|
|
char_field=Field(None, 1)):
|
|
"""
|
|
A string ending in a terminator.
|
|
|
|
``CString`` is similar to the strings of C, C++, and other related
|
|
programming languages.
|
|
|
|
By default, the terminator is the NULL byte (b``0x00``).
|
|
|
|
:param str name: name
|
|
:param iterable terminators: sequence of valid terminators, in order of
|
|
preference
|
|
:param str encoding: encoding (e.g. "utf8") or None for no encoding
|
|
:param ``Construct`` char_field: construct representing a single character
|
|
|
|
>>> foo = CString("foo")
|
|
>>> foo.parse(b"hello\\x00")
|
|
b'hello'
|
|
>>> foo.build(b"hello")
|
|
b'hello\\x00'
|
|
>>> foo = CString("foo", terminators = b"XYZ")
|
|
>>> foo.parse(b"helloX")
|
|
b'hello'
|
|
>>> foo.parse(b"helloY")
|
|
b'hello'
|
|
>>> foo.parse(b"helloZ")
|
|
b'hello'
|
|
>>> foo.build(b"hello")
|
|
b'helloX'
|
|
"""
|
|
|
|
return Rename(name,
|
|
CStringAdapter(
|
|
RepeatUntil(lambda obj, ctx: obj in terminators, char_field),
|
|
terminators=terminators,
|
|
encoding=encoding,
|
|
)
|
|
)
|
|
|
|
|
|
#===============================================================================
|
|
# conditional
|
|
#===============================================================================
|
|
def IfThenElse(name, predicate, then_subcon, else_subcon):
|
|
"""an if-then-else conditional construct: if the predicate indicates True,
|
|
`then_subcon` will be used; otherwise `else_subcon`
|
|
* name - the name of the construct
|
|
* predicate - a function taking the context as an argument and returning
|
|
True or False
|
|
* then_subcon - the subcon that will be used if the predicate returns True
|
|
* else_subcon - the subcon that will be used if the predicate returns False
|
|
"""
|
|
return Switch(name, lambda ctx: bool(predicate(ctx)),
|
|
{
|
|
True : then_subcon,
|
|
False : else_subcon,
|
|
}
|
|
)
|
|
|
|
def If(predicate, subcon, elsevalue = None):
|
|
"""an if-then conditional construct: if the predicate indicates True,
|
|
subcon will be used; otherwise, `elsevalue` will be returned instead.
|
|
* predicate - a function taking the context as an argument and returning
|
|
True or False
|
|
* subcon - the subcon that will be used if the predicate returns True
|
|
* elsevalue - the value that will be used should the predicate return False.
|
|
by default this value is None.
|
|
"""
|
|
return IfThenElse(subcon.name,
|
|
predicate,
|
|
subcon,
|
|
Value("elsevalue", lambda ctx: elsevalue)
|
|
)
|
|
|
|
|
|
#===============================================================================
|
|
# misc
|
|
#===============================================================================
|
|
def OnDemandPointer(offsetfunc, subcon, force_build = True):
|
|
"""an on-demand pointer.
|
|
* offsetfunc - a function taking the context as an argument and returning
|
|
the absolute stream position
|
|
* subcon - the subcon that will be parsed from the `offsetfunc()` stream
|
|
position on demand
|
|
* force_build - see OnDemand. by default True.
|
|
"""
|
|
return OnDemand(Pointer(offsetfunc, subcon),
|
|
advance_stream = False,
|
|
force_build = force_build
|
|
)
|
|
|
|
def Magic(data):
|
|
return ConstAdapter(Field(None, len(data)), data)
|