/usr/lib/python2.7/dist-packages/pgpdump/packet.py is in python-pgpdump 1.5-1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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import hashlib
from math import ceil, log
import re
from .utils import (PgpdumpException, get_int2, get_int4, get_mpi,
get_key_id, get_hex_data, get_int_bytes, pack_data)
class Packet(object):
'''The base packet object containing various fields pulled from the packet
header as well as a slice of the packet data.'''
def __init__(self, raw, name, new, data):
self.raw = raw
self.name = name
self.new = new
self.length = len(data)
self.data = data
# now let subclasses work their magic
self.parse()
def parse(self):
'''Perform any parsing necessary to populate fields on this packet.
This method is called as the last step in __init__(). The base class
method is a no-op; subclasses should use this as required.'''
return 0
def __repr__(self):
new = "old"
if self.new:
new = "new"
return "<%s: %s (%d), %s, length %d>" % (
self.__class__.__name__, self.name, self.raw, new, self.length)
class AlgoLookup(object):
'''Mixin class containing algorithm lookup methods.'''
pub_algorithms = {
1: "RSA Encrypt or Sign",
2: "RSA Encrypt-Only",
3: "RSA Sign-Only",
16: "ElGamal Encrypt-Only",
17: "DSA Digital Signature Algorithm",
18: "Elliptic Curve",
19: "ECDSA",
20: "Formerly ElGamal Encrypt or Sign",
21: "Diffie-Hellman",
}
@classmethod
def lookup_pub_algorithm(cls, alg):
if 100 <= alg <= 110:
return "Private/Experimental algorithm"
return cls.pub_algorithms.get(alg, "Unknown")
hash_algorithms = {
1: "MD5",
2: "SHA1",
3: "RIPEMD160",
8: "SHA256",
9: "SHA384",
10: "SHA512",
11: "SHA224",
}
@classmethod
def lookup_hash_algorithm(cls, alg):
# reserved values check
if alg in (4, 5, 6, 7):
return "Reserved"
if 100 <= alg <= 110:
return "Private/Experimental algorithm"
return cls.hash_algorithms.get(alg, "Unknown")
sym_algorithms = {
# (Name, IV length)
0: ("Plaintext or unencrypted", 0),
1: ("IDEA", 8),
2: ("Triple-DES", 8),
3: ("CAST5", 8),
4: ("Blowfish", 8),
5: ("Reserved", 8),
6: ("Reserved", 8),
7: ("AES with 128-bit key", 16),
8: ("AES with 192-bit key", 16),
9: ("AES with 256-bit key", 16),
10: ("Twofish with 256-bit key", 16),
11: ("Camellia with 128-bit key", 16),
12: ("Camellia with 192-bit key", 16),
13: ("Camellia with 256-bit key", 16),
}
@classmethod
def _lookup_sym_algorithm(cls, alg):
return cls.sym_algorithms.get(alg, ("Unknown", 0))
@classmethod
def lookup_sym_algorithm(cls, alg):
return cls._lookup_sym_algorithm(alg)[0]
@classmethod
def lookup_sym_algorithm_iv(cls, alg):
return cls._lookup_sym_algorithm(alg)[1]
class SignatureSubpacket(object):
'''A signature subpacket containing a type, type name, some flags, and the
contained data.'''
CRITICAL_BIT = 0x80
CRITICAL_MASK = 0x7f
def __init__(self, raw, hashed, data):
self.raw = raw
self.subtype = raw & self.CRITICAL_MASK
self.hashed = hashed
self.critical = bool(raw & self.CRITICAL_BIT)
self.length = len(data)
self.data = data
subpacket_types = {
2: "Signature Creation Time",
3: "Signature Expiration Time",
4: "Exportable Certification",
5: "Trust Signature",
6: "Regular Expression",
7: "Revocable",
9: "Key Expiration Time",
10: "Placeholder for backward compatibility",
11: "Preferred Symmetric Algorithms",
12: "Revocation Key",
16: "Issuer",
20: "Notation Data",
21: "Preferred Hash Algorithms",
22: "Preferred Compression Algorithms",
23: "Key Server Preferences",
24: "Preferred Key Server",
25: "Primary User ID",
26: "Policy URI",
27: "Key Flags",
28: "Signer's User ID",
29: "Reason for Revocation",
30: "Features",
31: "Signature Target",
32: "Embedded Signature",
}
@property
def name(self):
if self.subtype in (0, 1, 8, 13, 14, 15, 17, 18, 19):
return "Reserved"
return self.subpacket_types.get(self.subtype, "Unknown")
def __repr__(self):
extra = ""
if self.hashed:
extra += "hashed, "
if self.critical:
extra += "critical, "
return "<%s: %s, %slength %d>" % (
self.__class__.__name__, self.name, extra, self.length)
class SignaturePacket(Packet, AlgoLookup):
def __init__(self, *args, **kwargs):
self.sig_version = None
self.raw_sig_type = None
self.raw_pub_algorithm = None
self.raw_hash_algorithm = None
self.raw_creation_time = None
self.creation_time = None
self.raw_expiration_time = None
self.expiration_time = None
self.key_id = None
self.hash2 = None
self.subpackets = []
super(SignaturePacket, self).__init__(*args, **kwargs)
def parse(self):
self.sig_version = self.data[0]
offset = 1
if self.sig_version in (2, 3):
# 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f
# | | [ ctime ] [ key_id ] |
# | |-type pub_algo-|
# |-hash material
# 10 11 12
# | [hash2]
# |-hash_algo
# "hash material" byte must be 0x05
if self.data[offset] != 0x05:
raise PgpdumpException("Invalid v3 signature packet")
offset += 1
self.raw_sig_type = self.data[offset]
offset += 1
self.raw_creation_time = get_int4(self.data, offset)
self.creation_time = datetime.utcfromtimestamp(
self.raw_creation_time)
offset += 4
self.key_id = get_key_id(self.data, offset)
offset += 8
self.raw_pub_algorithm = self.data[offset]
offset += 1
self.raw_hash_algorithm = self.data[offset]
offset += 1
self.hash2 = self.data[offset:offset + 2]
offset += 2
elif self.sig_version == 4:
# 00 01 02 03 ... <hashedsubpackets..> <subpackets..> [hash2]
# | | |-hash_algo
# | |-pub_algo
# |-type
self.raw_sig_type = self.data[offset]
offset += 1
self.raw_pub_algorithm = self.data[offset]
offset += 1
self.raw_hash_algorithm = self.data[offset]
offset += 1
# next is hashed subpackets
length = get_int2(self.data, offset)
offset += 2
self.parse_subpackets(offset, length, True)
offset += length
# followed by subpackets
length = get_int2(self.data, offset)
offset += 2
self.parse_subpackets(offset, length, False)
offset += length
self.hash2 = self.data[offset:offset + 2]
offset += 2
else:
raise PgpdumpException("Unsupported signature packet, version %d" %
self.sig_version)
return offset
def parse_subpackets(self, outer_offset, outer_length, hashed=False):
offset = outer_offset
while offset < outer_offset + outer_length:
# each subpacket is [variable length] [subtype] [data]
sub_offset, sub_len, sub_part = new_tag_length(self.data, offset)
# sub_len includes the subtype single byte, knock that off
sub_len -= 1
# initial length bytes
offset += sub_offset
subtype = self.data[offset]
offset += 1
sub_data = self.data[offset:offset + sub_len]
if len(sub_data) != sub_len:
raise PgpdumpException(
"Unexpected subpackets length: expected %d, got %d" % (
sub_len, len(sub_data)))
subpacket = SignatureSubpacket(subtype, hashed, sub_data)
if subpacket.subtype == 2:
self.raw_creation_time = get_int4(subpacket.data, 0)
self.creation_time = datetime.utcfromtimestamp(
self.raw_creation_time)
elif subpacket.subtype == 3:
self.raw_expiration_time = get_int4(subpacket.data, 0)
elif subpacket.subtype == 16:
self.key_id = get_key_id(subpacket.data, 0)
offset += sub_len
self.subpackets.append(subpacket)
if self.raw_expiration_time:
self.expiration_time = self.creation_time + timedelta(
seconds=self.raw_expiration_time)
sig_types = {
0x00: "Signature of a binary document",
0x01: "Signature of a canonical text document",
0x02: "Standalone signature",
0x10: "Generic certification of a User ID and Public Key packet",
0x11: "Persona certification of a User ID and Public Key packet",
0x12: "Casual certification of a User ID and Public Key packet",
0x13: "Positive certification of a User ID and Public Key packet",
0x18: "Subkey Binding Signature",
0x19: "Primary Key Binding Signature",
0x1f: "Signature directly on a key",
0x20: "Key revocation signature",
0x28: "Subkey revocation signature",
0x30: "Certification revocation signature",
0x40: "Timestamp signature",
0x50: "Third-Party Confirmation signature",
}
@property
def sig_type(self):
return self.sig_types.get(self.raw_sig_type, "Unknown")
@property
def pub_algorithm(self):
return self.lookup_pub_algorithm(self.raw_pub_algorithm)
@property
def hash_algorithm(self):
return self.lookup_hash_algorithm(self.raw_hash_algorithm)
def __repr__(self):
return "<%s: %s, %s, length %d>" % (
self.__class__.__name__, self.pub_algorithm,
self.hash_algorithm, self.length)
class PublicKeyPacket(Packet, AlgoLookup):
def __init__(self, *args, **kwargs):
self.pubkey_version = None
self.fingerprint = None
self.key_id = None
self.raw_creation_time = None
self.creation_time = None
self.raw_days_valid = None
self.expiration_time = None
self.raw_pub_algorithm = None
self.pub_algorithm_type = None
self.modulus = None
self.modulus_bitlen = None
self.exponent = None
self.prime = None
self.group_order = None
self.group_gen = None
self.key_value = None
super(PublicKeyPacket, self).__init__(*args, **kwargs)
def parse(self):
self.pubkey_version = self.data[0]
offset = 1
if self.pubkey_version in (2, 3):
self.raw_creation_time = get_int4(self.data, offset)
self.creation_time = datetime.utcfromtimestamp(
self.raw_creation_time)
offset += 4
self.raw_days_valid = get_int2(self.data, offset)
offset += 2
if self.raw_days_valid > 0:
self.expiration_time = self.creation_time + timedelta(
days=self.raw_days_valid)
self.raw_pub_algorithm = self.data[offset]
offset += 1
offset = self.parse_key_material(offset)
md5 = hashlib.md5()
# Key type must be RSA for v2 and v3 public keys
if self.pub_algorithm_type == "rsa":
key_id = ('%X' % self.modulus)[-8:].zfill(8)
self.key_id = key_id.encode('ascii')
md5.update(get_int_bytes(self.modulus))
md5.update(get_int_bytes(self.exponent))
elif self.pub_algorithm_type == "elg":
# Of course, there are ELG keys in the wild too. This formula
# for calculating key_id and fingerprint is derived from an old
# key and there is a test case based on it.
key_id = ('%X' % self.prime)[-8:].zfill(8)
self.key_id = key_id.encode('ascii')
md5.update(get_int_bytes(self.prime))
md5.update(get_int_bytes(self.group_gen))
else:
raise PgpdumpException("Invalid non-RSA v%d public key" %
self.pubkey_version)
self.fingerprint = md5.hexdigest().upper().encode('ascii')
elif self.pubkey_version == 4:
sha1 = hashlib.sha1()
seed_bytes = (0x99, (self.length >> 8) & 0xff, self.length & 0xff)
sha1.update(pack_data(bytearray(seed_bytes)))
sha1.update(pack_data(self.data))
self.fingerprint = sha1.hexdigest().upper().encode('ascii')
self.key_id = self.fingerprint[24:]
self.raw_creation_time = get_int4(self.data, offset)
self.creation_time = datetime.utcfromtimestamp(
self.raw_creation_time)
offset += 4
self.raw_pub_algorithm = self.data[offset]
offset += 1
offset = self.parse_key_material(offset)
else:
raise PgpdumpException("Unsupported public key packet, version %d" %
self.pubkey_version)
return offset
def parse_key_material(self, offset):
if self.raw_pub_algorithm in (1, 2, 3):
self.pub_algorithm_type = "rsa"
# n, e
self.modulus, offset = get_mpi(self.data, offset)
self.exponent, offset = get_mpi(self.data, offset)
# the length of the modulus in bits
self.modulus_bitlen = int(ceil(log(self.modulus, 2)))
elif self.raw_pub_algorithm == 17:
self.pub_algorithm_type = "dsa"
# p, q, g, y
self.prime, offset = get_mpi(self.data, offset)
self.group_order, offset = get_mpi(self.data, offset)
self.group_gen, offset = get_mpi(self.data, offset)
self.key_value, offset = get_mpi(self.data, offset)
elif self.raw_pub_algorithm in (16, 20):
self.pub_algorithm_type = "elg"
# p, g, y
self.prime, offset = get_mpi(self.data, offset)
self.group_gen, offset = get_mpi(self.data, offset)
self.key_value, offset = get_mpi(self.data, offset)
elif 100 <= self.raw_pub_algorithm <= 110:
# Private/Experimental algorithms, just move on
pass
else:
raise PgpdumpException("Unsupported public key algorithm %d" %
self.raw_pub_algorithm)
return offset
@property
def pub_algorithm(self):
return self.lookup_pub_algorithm(self.raw_pub_algorithm)
def __repr__(self):
return "<%s: 0x%s, %s, length %d>" % (
self.__class__.__name__, self.key_id.decode('ascii'),
self.pub_algorithm, self.length)
class PublicSubkeyPacket(PublicKeyPacket):
'''A Public-Subkey packet (tag 14) has exactly the same format as a
Public-Key packet, but denotes a subkey.'''
pass
class SecretKeyPacket(PublicKeyPacket):
s2k_types = {
# (Name, Length)
0: ("Simple S2K", 2),
1: ("Salted S2K", 10),
2: ("Reserved value", 0),
3: ("Iterated and Salted S2K", 11),
101: ("GnuPG S2K", 6),
}
def __init__(self, *args, **kwargs):
self.s2k_id = None
self.s2k_type = None
self.s2k_cipher = None
self.s2k_hash = None
self.s2k_iv = None
self.checksum = None
self.serial_number = None
# RSA fields
self.exponent_d = None
self.prime_p = None
self.prime_q = None
self.multiplicative_inverse = None
# DSA and Elgamal
self.exponent_x = None
super(SecretKeyPacket, self).__init__(*args, **kwargs)
@classmethod
def lookup_s2k(cls, s2k_type_id):
return cls.s2k_types.get(s2k_type_id, ("Unknown", 0))
def parse(self):
# parse the public part
offset = super(SecretKeyPacket, self).parse()
# parse secret-key packet format from section 5.5.3
self.s2k_id = self.data[offset]
offset += 1
if self.s2k_id == 0:
# plaintext key data
offset = self.parse_private_key_material(offset)
self.checksum = get_int2(self.data, offset)
offset += 2
elif self.s2k_id in (254, 255):
# encrypted key data
cipher_id = self.data[offset]
offset += 1
self.s2k_cipher = self.lookup_sym_algorithm(cipher_id)
# s2k_length is the len of the entire S2K specifier, as per
# section 3.7.1 in RFC 4880
# we parse the info inside the specifier, but verify the # of
# octects we've parsed matches the expected length of the s2k
offset_before_s2k = offset
s2k_type_id = self.data[offset]
offset += 1
name, s2k_length = self.lookup_s2k(s2k_type_id)
self.s2k_type = name
has_iv = True
if s2k_type_id == 0:
# simple string-to-key
hash_id = self.data[offset]
offset += 1
self.s2k_hash = self.lookup_hash_algorithm(hash_id)
elif s2k_type_id == 1:
# salted string-to-key
hash_id = self.data[offset]
offset += 1
self.s2k_hash = self.lookup_hash_algorithm(hash_id)
# ignore 8 bytes
offset += 8
elif s2k_type_id == 2:
# reserved
pass
elif s2k_type_id == 3:
# iterated and salted
hash_id = self.data[offset]
offset += 1
self.s2k_hash = self.lookup_hash_algorithm(hash_id)
# ignore 8 bytes
offset += 8
# ignore count
offset += 1
# TODO: parse and store count ?
elif 100 <= s2k_type_id <= 110:
# GnuPG string-to-key
# According to g10/parse-packet.c near line 1832, the 101 packet
# type is a special GnuPG extension. This S2K extension is
# 6 bytes in total:
#
# Octet 0: 101
# Octet 1: hash algorithm
# Octet 2-4: "GNU"
# Octet 5: mode integer
hash_id = self.data[offset]
offset += 1
self.s2k_hash = self.lookup_hash_algorithm(hash_id)
gnu = self.data[offset:offset + 3]
offset += 3
if gnu != bytearray(b"GNU"):
raise PgpdumpException(
"S2K parsing error: expected 'GNU', got %s" % gnu)
mode = self.data[offset]
mode += 1000
offset += 1
if mode == 1001:
has_iv = False
elif mode == 1002:
has_iv = False
serial_len = self.data[offset]
if serial_len < 0:
raise PgpdumpException(
"Unexpected serial number length: %d" %
serial_len)
self.serial_number = get_hex_data(self.data, offset + 1,
serial_len)
else:
# TODO implement other modes?
raise PgpdumpException(
"Unsupported GnuPG S2K extension, encountered mode %d" % mode)
else:
raise PgpdumpException(
"Unsupported public key algorithm %d" % s2k_type_id)
if s2k_length != (offset - offset_before_s2k):
raise PgpdumpException(
"Error parsing string-to-key specifier, mismatched length")
if has_iv:
s2k_iv_len = self.lookup_sym_algorithm_iv(cipher_id)
self.s2k_iv = self.data[offset:offset + s2k_iv_len]
offset += s2k_iv_len
# TODO decrypt key data
# TODO parse checksum
return offset
def parse_private_key_material(self, offset):
if self.raw_pub_algorithm in (1, 2, 3):
self.pub_algorithm_type = "rsa"
# d, p, q, u
self.exponent_d, offset = get_mpi(self.data, offset)
self.prime_p, offset = get_mpi(self.data, offset)
self.prime_q, offset = get_mpi(self.data, offset)
self.multiplicative_inverse, offset = get_mpi(self.data, offset)
elif self.raw_pub_algorithm == 17:
self.pub_algorithm_type = "dsa"
# x
self.exponent_x, offset = get_mpi(self.data, offset)
elif self.raw_pub_algorithm in (16, 20):
self.pub_algorithm_type = "elg"
# x
self.exponent_x, offset = get_mpi(self.data, offset)
elif 100 <= self.raw_pub_algorithm <= 110:
# Private/Experimental algorithms, just move on
pass
else:
raise PgpdumpException("Unsupported public key algorithm %d" %
self.raw_pub_algorithm)
return offset
class SecretSubkeyPacket(SecretKeyPacket):
'''A Secret-Subkey packet (tag 7) has exactly the same format as a
Secret-Key packet, but denotes a subkey.'''
pass
class UserIDPacket(Packet):
'''A User ID packet consists of UTF-8 text that is intended to represent
the name and email address of the key holder. By convention, it includes an
RFC 2822 mail name-addr, but there are no restrictions on its content.'''
def __init__(self, *args, **kwargs):
self.user = None
self.user_name = None
self.user_email = None
super(UserIDPacket, self).__init__(*args, **kwargs)
user_re = re.compile(r'^([^<]+)? ?<([^>]*)>?')
def parse(self):
self.user = self.data.decode('utf8', 'replace')
matches = self.user_re.match(self.user)
if matches:
if matches.group(1):
self.user_name = matches.group(1).strip()
if matches.group(2):
self.user_email = matches.group(2).strip()
return self.length
def __repr__(self):
return "<%s: %r (%r), length %d>" % (
self.__class__.__name__, self.user_name, self.user_email,
self.length)
class UserAttributePacket(Packet):
def __init__(self, *args, **kwargs):
self.raw_image_format = None
self.image_format = None
self.image_data = None
super(UserAttributePacket, self).__init__(*args, **kwargs)
def parse(self):
offset = sub_offset = sub_len = 0
while offset + sub_len < self.length:
# each subpacket is [variable length] [subtype] [data]
sub_offset, sub_len, sub_part = new_tag_length(self.data, offset)
# sub_len includes the subtype single byte, knock that off
sub_len -= 1
# initial length bytes
offset += sub_offset
sub_type = self.data[offset]
offset += 1
# there is only one currently known type- images (1)
if sub_type == 1:
# the only little-endian encoded value in OpenPGP
hdr_size = self.data[offset] + (self.data[offset + 1] << 8)
hdr_version = self.data[offset + 2]
self.raw_image_format = self.data[offset + 3]
offset += hdr_size
self.image_data = self.data[offset:]
if self.raw_image_format == 1:
self.image_format = "jpeg"
else:
self.image_format = "unknown"
return self.length
class TrustPacket(Packet):
def __init__(self, *args, **kwargs):
self.trust = None
super(TrustPacket, self).__init__(*args, **kwargs)
def parse(self):
'''GnuPG public keyrings use a 2-byte trust value that appears to be
integer values into some internal enumeration.'''
if self.length == 2:
self.trust = get_int2(self.data, 0)
return 2
return 0
class PublicKeyEncryptedSessionKeyPacket(Packet, AlgoLookup):
def __init__(self, *args, **kwargs):
self.session_key_version = None
self.key_id = None
self.raw_pub_algorithm = None
self.pub_algorithm = None
super(PublicKeyEncryptedSessionKeyPacket, self).__init__(
*args, **kwargs)
def parse(self):
self.session_key_version = self.data[0]
if self.session_key_version == 3:
self.key_id = get_key_id(self.data, 1)
self.raw_pub_algorithm = self.data[9]
self.pub_algorithm = self.lookup_pub_algorithm(self.raw_pub_algorithm)
else:
raise PgpdumpException(
"Unsupported encrypted session key packet, version %d" %
self.session_key_version)
# this is hardcoded to work with the only known session key version
return 10
def __repr__(self):
return "<%s: 0x%s (%s), length %d>" % (
self.__class__.__name__, self.key_id, self.pub_algorithm,
self.length)
TAG_TYPES = {
# (Name, PacketType) tuples
0: ("Reserved", None),
1: ("Public-Key Encrypted Session Key Packet",
PublicKeyEncryptedSessionKeyPacket),
2: ("Signature Packet", SignaturePacket),
3: ("Symmetric-Key Encrypted Session Key Packet", None),
4: ("One-Pass Signature Packet", None),
5: ("Secret Key Packet", SecretKeyPacket),
6: ("Public Key Packet", PublicKeyPacket),
7: ("Secret Subkey Packet", SecretSubkeyPacket),
8: ("Compressed Data Packet", None),
9: ("Symmetrically Encrypted Data Packet", None),
10: ("Marker Packet", None),
11: ("Literal Data Packet", None),
12: ("Trust Packet", TrustPacket),
13: ("User ID Packet", UserIDPacket),
14: ("Public Subkey Packet", PublicSubkeyPacket),
17: ("User Attribute Packet", UserAttributePacket),
18: ("Symmetrically Encrypted and MDC Packet", None),
19: ("Modification Detection Code Packet", None),
60: ("Private", None),
61: ("Private", None),
62: ("Private", None),
63: ("Private", None),
}
def new_tag_length(data, start):
'''Takes a bytearray of data as input, as well as an offset of where to
look. Returns a derived (offset, length, partial) tuple.
Reference: http://tools.ietf.org/html/rfc4880#section-4.2.2
'''
first = data[start]
offset = length = 0
partial = False
# one-octet
if first < 192:
offset = 1
length = first
# two-octet
elif first < 224:
offset = 2
length = ((first - 192) << 8) + data[start + 1] + 192
# five-octet
elif first == 255:
offset = 5
length = get_int4(data, start + 1)
# Partial Body Length header, one octet long
else:
offset = 1
# partial length, 224 <= l < 255
length = 1 << (first & 0x1f)
partial = True
return (offset, length, partial)
def old_tag_length(data, start):
'''Takes a bytearray of data as input, as well as an offset of where to
look. Returns a derived (offset, length) tuple.'''
offset = length = 0
temp_len = data[start] & 0x03
if temp_len == 0:
offset = 1
length = data[start + 1]
elif temp_len == 1:
offset = 2
length = get_int2(data, start + 1)
elif temp_len == 2:
offset = 4
length = get_int4(data, start + 1)
elif temp_len == 3:
length = len(data) - start - 1
return (offset, length)
def construct_packet(data, header_start):
'''Returns a (length, packet) tuple constructed from 'data' at index
'header_start'. If there is a next packet, it will be found at
header_start + length.'''
# tag encoded in bits 5-0 (new packet format)
# 0x3f == 111111b
tag = data[header_start] & 0x3f
# the header is in new format if bit 7 is set
# 0x40 == 1000000b
new = bool(data[header_start] & 0x40)
if new:
# length is encoded in the second (and following) octet
data_offset, data_length, partial = new_tag_length(
data, header_start + 1)
else:
# tag encoded in bits 5-2, discard bits 1-0
tag >>= 2
data_offset, data_length = old_tag_length(data, header_start)
partial = False
name, PacketType = TAG_TYPES.get(tag, ("Unknown", None))
# Packet type not yet handled
if not PacketType:
PacketType = Packet
# first octet of the packet header handled
data_offset += 1
# data consumed to create new packet, consists of header and data
consumed = 0
packet_data = bytearray()
while (True):
consumed += data_offset
data_start = header_start + data_offset
header_start = data_start + data_length
packet_data += data[data_start:header_start]
consumed += data_length
# The new format might encode data with Partial Body Length headers.
# Then a packet consists of alternating header and data regions. The
# last header of a packet is not a Partial Body Length header.
if partial:
data_offset, data_length, partial = new_tag_length(
data, header_start)
else:
break
packet = PacketType(tag, name, new, packet_data)
return (consumed, packet)
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