You can not select more than 25 topics
Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
816 lines
36 KiB
816 lines
36 KiB
# Copyright (c) 2022 Pieter Wuille
|
|
# Distributed under the MIT software license, see the accompanying
|
|
# file LICENSE or http://www.opensource.org/licenses/mit-license.php.
|
|
|
|
"""
|
|
This module provides the ASNEntry and ASMap classes.
|
|
"""
|
|
|
|
import copy
|
|
import ipaddress
|
|
import random
|
|
import unittest
|
|
from enum import Enum
|
|
from functools import total_ordering
|
|
from typing import Callable, Dict, Iterable, List, Optional, Tuple, Union, overload
|
|
|
|
def net_to_prefix(net: Union[ipaddress.IPv4Network,ipaddress.IPv6Network]) -> List[bool]:
|
|
"""
|
|
Convert an IPv4 or IPv6 network to a prefix represented as a list of bits.
|
|
|
|
IPv4 ranges are remapped to their IPv4-mapped IPv6 range (::ffff:0:0/96).
|
|
"""
|
|
num_bits = net.prefixlen
|
|
netrange = int.from_bytes(net.network_address.packed, 'big')
|
|
|
|
# Map an IPv4 prefix into IPv6 space.
|
|
if isinstance(net, ipaddress.IPv4Network):
|
|
num_bits += 96
|
|
netrange += 0xffff00000000
|
|
|
|
# Strip unused bottom bits.
|
|
assert (netrange & ((1 << (128 - num_bits)) - 1)) == 0
|
|
return [((netrange >> (127 - i)) & 1) != 0 for i in range(num_bits)]
|
|
|
|
def prefix_to_net(prefix: List[bool]) -> Union[ipaddress.IPv4Network,ipaddress.IPv6Network]:
|
|
"""The reverse operation of net_to_prefix."""
|
|
# Convert to number
|
|
netrange = sum(b << (127 - i) for i, b in enumerate(prefix))
|
|
num_bits = len(prefix)
|
|
assert num_bits <= 128
|
|
|
|
# Return IPv4 range if in ::ffff:0:0/96
|
|
if num_bits >= 96 and (netrange >> 32) == 0xffff:
|
|
return ipaddress.IPv4Network((netrange & 0xffffffff, num_bits - 96), True)
|
|
|
|
# Return IPv6 range otherwise.
|
|
return ipaddress.IPv6Network((netrange, num_bits), True)
|
|
|
|
# Shortcut for (prefix, ASN) entries.
|
|
ASNEntry = Tuple[List[bool], int]
|
|
|
|
# Shortcut for (prefix, old ASN, new ASN) entries.
|
|
ASNDiff = Tuple[List[bool], int, int]
|
|
|
|
class _VarLenCoder:
|
|
"""
|
|
A class representing a custom variable-length binary encoder/decoder for
|
|
integers. Each object represents a different coder, with different parameters
|
|
minval and clsbits.
|
|
|
|
The encoding is easiest to describe using an example. Let's say minval=100 and
|
|
clsbits=[4,2,2,3]. In that case:
|
|
- x in [100..115]: encoded as [0] + [4-bit BE encoding of (x-100)].
|
|
- x in [116..119]: encoded as [1,0] + [2-bit BE encoding of (x-116)].
|
|
- x in [120..123]: encoded as [1,1,0] + [2-bit BE encoding of (x-120)].
|
|
- x in [124..131]: encoded as [1,1,1] + [3-bit BE encoding of (x-124)].
|
|
|
|
In general, every number is encoded as:
|
|
- First, k "1"-bits, where k is the class the number falls in (there is one class
|
|
per element of clsbits).
|
|
- Then, a "0"-bit, unless k is the highest class, in which case there is nothing.
|
|
- Lastly, clsbits[k] bits encoding in big endian the position in its class that
|
|
number falls into.
|
|
- Every class k consists of 2^clsbits[k] consecutive integers. k=0 starts at minval,
|
|
other classes start one past the last element of the class before it.
|
|
"""
|
|
|
|
def __init__(self, minval: int, clsbits: List[int]):
|
|
"""Construct a new _VarLenCoder."""
|
|
self._minval = minval
|
|
self._clsbits = clsbits
|
|
self._maxval = minval + sum(1 << b for b in clsbits) - 1
|
|
|
|
def can_encode(self, val: int) -> bool:
|
|
"""Check whether value val is in the range this coder supports."""
|
|
return self._minval <= val <= self._maxval
|
|
|
|
def encode(self, val: int, ret: List[int]) -> None:
|
|
"""Append encoding of val onto integer list ret."""
|
|
|
|
assert self._minval <= val <= self._maxval
|
|
val -= self._minval
|
|
bits = 0
|
|
for k, bits in enumerate(self._clsbits):
|
|
if val >> bits:
|
|
# If the value will not fit in class k, subtract its range from v,
|
|
# emit a "1" bit and continue with the next class.
|
|
val -= 1 << bits
|
|
ret.append(1)
|
|
else:
|
|
if k + 1 < len(self._clsbits):
|
|
# Unless we're in the last class, emit a "0" bit.
|
|
ret.append(0)
|
|
break
|
|
# And then encode v (now the position within the class) in big endian.
|
|
ret.extend((val >> (bits - 1 - b)) & 1 for b in range(bits))
|
|
|
|
def encode_size(self, val: int) -> int:
|
|
"""Compute how many bits are needed to encode val."""
|
|
assert self._minval <= val <= self._maxval
|
|
val -= self._minval
|
|
ret = 0
|
|
bits = 0
|
|
for k, bits in enumerate(self._clsbits):
|
|
if val >> bits:
|
|
val -= 1 << bits
|
|
ret += 1
|
|
else:
|
|
ret += k + 1 < len(self._clsbits)
|
|
break
|
|
return ret + bits
|
|
|
|
def decode(self, stream, bitpos) -> Tuple[int,int]:
|
|
"""Decode a number starting at bitpos in stream, returning value and new bitpos."""
|
|
val = self._minval
|
|
bits = 0
|
|
for k, bits in enumerate(self._clsbits):
|
|
bit = 0
|
|
if k + 1 < len(self._clsbits):
|
|
bit = stream[bitpos]
|
|
bitpos += 1
|
|
if not bit:
|
|
break
|
|
val += 1 << bits
|
|
for i in range(bits):
|
|
bit = stream[bitpos]
|
|
bitpos += 1
|
|
val += bit << (bits - 1 - i)
|
|
return val, bitpos
|
|
|
|
# Variable-length encoders used in the binary asmap format.
|
|
_CODER_INS = _VarLenCoder(0, [0, 0, 1])
|
|
_CODER_ASN = _VarLenCoder(1, list(range(15, 25)))
|
|
_CODER_MATCH = _VarLenCoder(2, list(range(1, 9)))
|
|
_CODER_JUMP = _VarLenCoder(17, list(range(5, 31)))
|
|
|
|
class _Instruction(Enum):
|
|
"""One instruction in the binary asmap format."""
|
|
# A return instruction, encoded as [0], returns a constant ASN. It is followed by
|
|
# an integer using the ASN encoding.
|
|
RETURN = 0
|
|
# A jump instruction, encoded as [1,0] inspects the next unused bit in the input
|
|
# and either continues execution (if 0), or skips a specified number of bits (if 1).
|
|
# It is followed by an integer, and then two subprograms. The integer uses jump encoding
|
|
# and corresponds to the length of the first subprogram (so it can be skipped).
|
|
JUMP = 1
|
|
# A match instruction, encoded as [1,1,0] inspects 1 or more of the next unused bits
|
|
# in the input with its argument. If they all match, execution continues. If they do
|
|
# not, failure is returned. If a default instruction has been executed before, instead
|
|
# of failure the default instruction's argument is returned. It is followed by an
|
|
# integer in match encoding, and a subprogram. That value is at least 2 bits and at
|
|
# most 9 bits. An n-bit value signifies matching (n-1) bits in the input with the lower
|
|
# (n-1) bits in the match value.
|
|
MATCH = 2
|
|
# A default instruction, encoded as [1,1,1] sets the default variable to its argument,
|
|
# and continues execution. It is followed by an integer in ASN encoding, and a subprogram.
|
|
DEFAULT = 3
|
|
# Not an actual instruction, but a way to encode the empty program that fails. In the
|
|
# encoder, it is used more generally to represent the failure case inside MATCH instructions,
|
|
# which may (if used inside the context of a DEFAULT instruction) actually correspond to
|
|
# a successful return. In this usage, they're always converted to an actual MATCH or RETURN
|
|
# before the top level is reached (see make_default below).
|
|
END = 4
|
|
|
|
class _BinNode:
|
|
"""A class representing a (node of) the parsed binary asmap format."""
|
|
|
|
@overload
|
|
def __init__(self, ins: _Instruction): ...
|
|
@overload
|
|
def __init__(self, ins: _Instruction, arg1: int): ...
|
|
@overload
|
|
def __init__(self, ins: _Instruction, arg1: "_BinNode", arg2: "_BinNode"): ...
|
|
@overload
|
|
def __init__(self, ins: _Instruction, arg1: int, arg2: "_BinNode"): ...
|
|
|
|
def __init__(self, ins: _Instruction, arg1=None, arg2=None):
|
|
"""
|
|
Construct a new asmap node. Possibilities are:
|
|
- _BinNode(_Instruction.RETURN, asn)
|
|
- _BinNode(_Instruction.JUMP, node_0, node_1)
|
|
- _BinNode(_Instruction.MATCH, val, node)
|
|
- _BinNode(_Instruction.DEFAULT, asn, node)
|
|
- _BinNode(_Instruction.END)
|
|
"""
|
|
self.ins = ins
|
|
self.arg1 = arg1
|
|
self.arg2 = arg2
|
|
if ins == _Instruction.RETURN:
|
|
assert isinstance(arg1, int)
|
|
assert arg2 is None
|
|
self.size = _CODER_INS.encode_size(ins.value) + _CODER_ASN.encode_size(arg1)
|
|
elif ins == _Instruction.JUMP:
|
|
assert isinstance(arg1, _BinNode)
|
|
assert isinstance(arg2, _BinNode)
|
|
self.size = (_CODER_INS.encode_size(ins.value) + _CODER_JUMP.encode_size(arg1.size) +
|
|
arg1.size + arg2.size)
|
|
elif ins == _Instruction.DEFAULT:
|
|
assert isinstance(arg1, int)
|
|
assert isinstance(arg2, _BinNode)
|
|
self.size = _CODER_INS.encode_size(ins.value) + _CODER_ASN.encode_size(arg1) + arg2.size
|
|
elif ins == _Instruction.MATCH:
|
|
assert isinstance(arg1, int)
|
|
assert isinstance(arg2, _BinNode)
|
|
self.size = (_CODER_INS.encode_size(ins.value) + _CODER_MATCH.encode_size(arg1)
|
|
+ arg2.size)
|
|
elif ins == _Instruction.END:
|
|
assert arg1 is None
|
|
assert arg2 is None
|
|
self.size = 0
|
|
else:
|
|
assert False
|
|
|
|
@staticmethod
|
|
def make_end() -> "_BinNode":
|
|
"""Constructor for a _BinNode with just an END instruction."""
|
|
return _BinNode(_Instruction.END)
|
|
|
|
@staticmethod
|
|
def make_leaf(val: int) -> "_BinNode":
|
|
"""Constructor for a _BinNode of just a RETURN instruction."""
|
|
assert val is not None and val > 0
|
|
return _BinNode(_Instruction.RETURN, val)
|
|
|
|
@staticmethod
|
|
def make_branch(node0: "_BinNode", node1: "_BinNode") -> "_BinNode":
|
|
"""
|
|
Construct a _BinNode corresponding to running either the node0 or node1 subprogram,
|
|
based on the next input bit. It exploits shortcuts that are possible in the encoding,
|
|
and uses either a JUMP, MATCH, or END instruction.
|
|
"""
|
|
if node0.ins == _Instruction.END and node1.ins == _Instruction.END:
|
|
return node0
|
|
if node0.ins == _Instruction.END:
|
|
if node1.ins == _Instruction.MATCH and node1.arg1 <= 0xFF:
|
|
return _BinNode(node1.ins, node1.arg1 + (1 << node1.arg1.bit_length()), node1.arg2)
|
|
return _BinNode(_Instruction.MATCH, 3, node1)
|
|
if node1.ins == _Instruction.END:
|
|
if node0.ins == _Instruction.MATCH and node0.arg1 <= 0xFF:
|
|
return _BinNode(node0.ins, node0.arg1 + (1 << (node0.arg1.bit_length() - 1)),
|
|
node0.arg2)
|
|
return _BinNode(_Instruction.MATCH, 2, node0)
|
|
return _BinNode(_Instruction.JUMP, node0, node1)
|
|
|
|
@staticmethod
|
|
def make_default(val: int, sub: "_BinNode") -> "_BinNode":
|
|
"""
|
|
Construct a _BinNode that corresponds to the specified subprogram, with the specified
|
|
default value. It exploits shortcuts that are possible in the encoding, and will use
|
|
either a DEFAULT or a RETURN instruction."""
|
|
assert val is not None and val > 0
|
|
if sub.ins == _Instruction.END:
|
|
return _BinNode(_Instruction.RETURN, val)
|
|
if sub.ins in (_Instruction.RETURN, _Instruction.DEFAULT):
|
|
return sub
|
|
return _BinNode(_Instruction.DEFAULT, val, sub)
|
|
|
|
@total_ordering
|
|
class ASMap:
|
|
"""
|
|
A class whose objects represent a mapping from subnets to ASNs.
|
|
|
|
Internally the mapping is stored as a binary trie, but can be converted
|
|
from/to a list of ASNEntry objects, and from/to the binary asmap file format.
|
|
|
|
In the trie representation, nodes are represented as bare lists for efficiency
|
|
and ease of manipulation:
|
|
- [0] means an unassigned subnet (no ASN mapping for it is present)
|
|
- [int] means a subnet mapped entirely to the specified ASN.
|
|
- [node,node] means a subnet whose lower half and upper half have different
|
|
- mappings, represented by new trie nodes.
|
|
"""
|
|
|
|
def update(self, prefix: List[bool], asn: int) -> None:
|
|
"""Update this ASMap object to map prefix to the specified asn."""
|
|
assert asn == 0 or _CODER_ASN.can_encode(asn)
|
|
|
|
def recurse(node: List, offset: int) -> None:
|
|
if offset == len(prefix):
|
|
# Reached the end of prefix; overwrite this node.
|
|
node.clear()
|
|
node.append(asn)
|
|
return
|
|
if len(node) == 1:
|
|
# Need to descend into a leaf node; split it up.
|
|
oldasn = node[0]
|
|
node.clear()
|
|
node.append([oldasn])
|
|
node.append([oldasn])
|
|
# Descend into the node.
|
|
recurse(node[prefix[offset]], offset + 1)
|
|
# If the result is two identical leaf children, merge them.
|
|
if len(node[0]) == 1 and len(node[1]) == 1 and node[0] == node[1]:
|
|
oldasn = node[0][0]
|
|
node.clear()
|
|
node.append(oldasn)
|
|
recurse(self._trie, 0)
|
|
|
|
def update_multi(self, entries: List[Tuple[List[bool], int]]) -> None:
|
|
"""Apply multiple update operations, where longer prefixes take precedence."""
|
|
entries.sort(key=lambda entry: len(entry[0]))
|
|
for prefix, asn in entries:
|
|
self.update(prefix, asn)
|
|
|
|
def _set_trie(self, trie) -> None:
|
|
"""Set trie directly. Internal use only."""
|
|
def recurse(node: List) -> None:
|
|
if len(node) < 2:
|
|
return
|
|
recurse(node[0])
|
|
recurse(node[1])
|
|
if len(node[0]) == 2:
|
|
return
|
|
if node[0] == node[1]:
|
|
if len(node[0]) == 0:
|
|
node.clear()
|
|
else:
|
|
asn = node[0][0]
|
|
node.clear()
|
|
node.append(asn)
|
|
recurse(trie)
|
|
self._trie = trie
|
|
|
|
def __init__(self, entries: Optional[Iterable[ASNEntry]] = None) -> None:
|
|
"""Construct an ASMap object from an optional list of entries."""
|
|
self._trie = [0]
|
|
if entries is not None:
|
|
def entry_key(entry):
|
|
"""Sort function that places shorter prefixes first."""
|
|
prefix, asn = entry
|
|
return len(prefix), prefix, asn
|
|
for prefix, asn in sorted(entries, key=entry_key):
|
|
self.update(prefix, asn)
|
|
|
|
def lookup(self, prefix: List[bool]) -> Optional[int]:
|
|
"""Look up a prefix. Returns ASN, or 0 if unassigned, or None if indeterminate."""
|
|
node = self._trie
|
|
for bit in prefix:
|
|
if len(node) == 1:
|
|
break
|
|
node = node[bit]
|
|
if len(node) == 1:
|
|
return node[0]
|
|
return None
|
|
|
|
def _to_entries_flat(self, fill: bool = False) -> List[ASNEntry]:
|
|
"""Convert an ASMap object to a list of non-overlapping (prefix, asn) objects."""
|
|
prefix : List[bool] = []
|
|
|
|
def recurse(node: List) -> List[ASNEntry]:
|
|
ret = []
|
|
if len(node) == 1:
|
|
if node[0] > 0:
|
|
ret = [(list(prefix), node[0])]
|
|
elif len(node) == 2:
|
|
prefix.append(False)
|
|
ret = recurse(node[0])
|
|
prefix[-1] = True
|
|
ret += recurse(node[1])
|
|
prefix.pop()
|
|
if fill and len(ret) > 1:
|
|
asns = set(x[1] for x in ret)
|
|
if len(asns) == 1:
|
|
ret = [(list(prefix), list(asns)[0])]
|
|
return ret
|
|
return recurse(self._trie)
|
|
|
|
def _to_entries_minimal(self, fill: bool = False) -> List[ASNEntry]:
|
|
"""Convert a trie to a minimal list of ASNEntry objects, exploiting overlap."""
|
|
prefix : List[bool] = []
|
|
|
|
def recurse(node: List) -> (Tuple[Dict[Optional[int], List[ASNEntry]], bool]):
|
|
if len(node) == 1 and node[0] == 0:
|
|
return {None if fill else 0: []}, True
|
|
if len(node) == 1:
|
|
return {node[0]: [], None: [(list(prefix), node[0])]}, False
|
|
ret: Dict[Optional[int], List[ASNEntry]] = {}
|
|
prefix.append(False)
|
|
left, lhole = recurse(node[0])
|
|
prefix[-1] = True
|
|
right, rhole = recurse(node[1])
|
|
prefix.pop()
|
|
hole = not fill and (lhole or rhole)
|
|
def candidate(ctx: Optional[int], res0: Optional[List[ASNEntry]],
|
|
res1: Optional[List[ASNEntry]]):
|
|
if res0 is not None and res1 is not None:
|
|
if ctx not in ret or len(res0) + len(res1) < len(ret[ctx]):
|
|
ret[ctx] = res0 + res1
|
|
for ctx in set(left) | set(right):
|
|
candidate(ctx, left.get(ctx), right.get(ctx))
|
|
candidate(ctx, left.get(None), right.get(ctx))
|
|
candidate(ctx, left.get(ctx), right.get(None))
|
|
if not hole:
|
|
for ctx in list(ret):
|
|
if ctx is not None:
|
|
candidate(None, [(list(prefix), ctx)], ret[ctx])
|
|
if None in ret:
|
|
ret = {ctx:entries for ctx, entries in ret.items()
|
|
if ctx is None or len(entries) < len(ret[None])}
|
|
if hole:
|
|
ret = {ctx:entries for ctx, entries in ret.items() if ctx is None or ctx == 0}
|
|
return ret, hole
|
|
res, _ = recurse(self._trie)
|
|
return res[0] if 0 in res else res[None]
|
|
|
|
def __str__(self) -> str:
|
|
"""Convert this ASMap object to a string containing Python code constructing it."""
|
|
return f"ASMap({self._trie})"
|
|
|
|
def to_entries(self, overlapping: bool = True, fill: bool = False) -> List[ASNEntry]:
|
|
"""
|
|
Convert the mappings in this ASMap object to a list of ASNEntry objects.
|
|
|
|
Arguments:
|
|
overlapping: Permit the subnets in the resulting ASNEntry to overlap.
|
|
Setting this can result in a shorter list.
|
|
fill: Permit the resulting ASNEntry objects to cover subnets that
|
|
are unassigned in this ASMap object. Setting this can
|
|
result in a shorter list.
|
|
"""
|
|
if overlapping:
|
|
return self._to_entries_minimal(fill)
|
|
return self._to_entries_flat(fill)
|
|
|
|
@staticmethod
|
|
def from_random(num_leaves: int = 10, max_asn: int = 6,
|
|
unassigned_prob: float = 0.5) -> "ASMap":
|
|
"""
|
|
Construct a random ASMap object, with specified:
|
|
- Number of leaves in its trie (at least 1)
|
|
- Maximum ASN value (at least 1)
|
|
- Probability for leaf nodes to be unassigned
|
|
|
|
The number of leaves in the resulting object may be less than what is
|
|
requested. This method is mostly intended for testing.
|
|
"""
|
|
assert num_leaves >= 1
|
|
assert max_asn >= 1 or unassigned_prob == 1
|
|
assert _CODER_ASN.can_encode(max_asn)
|
|
assert 0.0 <= unassigned_prob <= 1.0
|
|
trie: List = []
|
|
leaves = [trie]
|
|
ret = ASMap()
|
|
for i in range(1, num_leaves):
|
|
idx = random.randrange(i)
|
|
leaf = leaves[idx]
|
|
lastleaf = leaves.pop()
|
|
if idx + 1 < i:
|
|
leaves[idx] = lastleaf
|
|
leaf.append([])
|
|
leaf.append([])
|
|
leaves.append(leaf[0])
|
|
leaves.append(leaf[1])
|
|
for leaf in leaves:
|
|
if random.random() >= unassigned_prob:
|
|
leaf.append(random.randrange(1, max_asn + 1))
|
|
else:
|
|
leaf.append(0)
|
|
#pylint: disable=protected-access
|
|
ret._set_trie(trie)
|
|
return ret
|
|
|
|
def _to_binnode(self, fill: bool = False) -> _BinNode:
|
|
"""Convert a trie to a _BinNode object."""
|
|
def recurse(node: List) -> Tuple[Dict[Optional[int], _BinNode], bool]:
|
|
if len(node) == 1 and node[0] == 0:
|
|
return {(None if fill else 0): _BinNode.make_end()}, True
|
|
if len(node) == 1:
|
|
return {None: _BinNode.make_leaf(node[0]), node[0]: _BinNode.make_end()}, False
|
|
ret: Dict[Optional[int], _BinNode] = {}
|
|
left, lhole = recurse(node[0])
|
|
right, rhole = recurse(node[1])
|
|
hole = (lhole or rhole) and not fill
|
|
|
|
def candidate(ctx: Optional[int], arg1, arg2, func: Callable):
|
|
if arg1 is not None and arg2 is not None:
|
|
cand = func(arg1, arg2)
|
|
if ctx not in ret or cand.size < ret[ctx].size:
|
|
ret[ctx] = cand
|
|
|
|
for ctx in set(left) | set(right):
|
|
candidate(ctx, left.get(ctx), right.get(ctx), _BinNode.make_branch)
|
|
candidate(ctx, left.get(None), right.get(ctx), _BinNode.make_branch)
|
|
candidate(ctx, left.get(ctx), right.get(None), _BinNode.make_branch)
|
|
if not hole:
|
|
for ctx in set(ret) - set([None]):
|
|
candidate(None, ctx, ret[ctx], _BinNode.make_default)
|
|
if None in ret:
|
|
ret = {ctx:enc for ctx, enc in ret.items()
|
|
if ctx is None or enc.size < ret[None].size}
|
|
if hole:
|
|
ret = {ctx:enc for ctx, enc in ret.items() if ctx is None or ctx == 0}
|
|
return ret, hole
|
|
res, _ = recurse(self._trie)
|
|
return res[0] if 0 in res else res[None]
|
|
|
|
@staticmethod
|
|
def _from_binnode(binnode: _BinNode) -> "ASMap":
|
|
"""Construct an ASMap object from a _BinNode. Internal use only."""
|
|
def recurse(node: _BinNode, default: int) -> List:
|
|
if node.ins == _Instruction.RETURN:
|
|
return [node.arg1]
|
|
if node.ins == _Instruction.JUMP:
|
|
return [recurse(node.arg1, default), recurse(node.arg2, default)]
|
|
if node.ins == _Instruction.MATCH:
|
|
val = node.arg1
|
|
sub = recurse(node.arg2, default)
|
|
while val >= 2:
|
|
bit = val & 1
|
|
val >>= 1
|
|
if bit:
|
|
sub = [[default], sub]
|
|
else:
|
|
sub = [sub, [default]]
|
|
return sub
|
|
assert node.ins == _Instruction.DEFAULT
|
|
return recurse(node.arg2, node.arg1)
|
|
ret = ASMap()
|
|
if binnode.ins != _Instruction.END:
|
|
#pylint: disable=protected-access
|
|
ret._set_trie(recurse(binnode, 0))
|
|
return ret
|
|
|
|
def to_binary(self, fill: bool = False) -> bytes:
|
|
"""
|
|
Convert this ASMap object to binary.
|
|
|
|
Argument:
|
|
fill: permit the resulting binary encoder to contain mappers for
|
|
unassigned subnets in this ASMap object. Doing so may
|
|
reduce the size of the encoding.
|
|
Returns:
|
|
A bytes object with the encoding of this ASMap object.
|
|
"""
|
|
bits: List[int] = []
|
|
|
|
def recurse(node: _BinNode) -> None:
|
|
_CODER_INS.encode(node.ins.value, bits)
|
|
if node.ins == _Instruction.RETURN:
|
|
_CODER_ASN.encode(node.arg1, bits)
|
|
elif node.ins == _Instruction.JUMP:
|
|
_CODER_JUMP.encode(node.arg1.size, bits)
|
|
recurse(node.arg1)
|
|
recurse(node.arg2)
|
|
elif node.ins == _Instruction.DEFAULT:
|
|
_CODER_ASN.encode(node.arg1, bits)
|
|
recurse(node.arg2)
|
|
else:
|
|
assert node.ins == _Instruction.MATCH
|
|
_CODER_MATCH.encode(node.arg1, bits)
|
|
recurse(node.arg2)
|
|
|
|
binnode = self._to_binnode(fill)
|
|
if binnode.ins != _Instruction.END:
|
|
recurse(binnode)
|
|
|
|
val = 0
|
|
nbits = 0
|
|
ret = []
|
|
for bit in bits:
|
|
val += (bit << nbits)
|
|
nbits += 1
|
|
if nbits == 8:
|
|
ret.append(val)
|
|
val = 0
|
|
nbits = 0
|
|
if nbits:
|
|
ret.append(val)
|
|
return bytes(ret)
|
|
|
|
@staticmethod
|
|
def from_binary(bindata: bytes) -> Optional["ASMap"]:
|
|
"""Decode an ASMap object from the provided binary encoding."""
|
|
|
|
bits: List[int] = []
|
|
for byte in bindata:
|
|
bits.extend((byte >> i) & 1 for i in range(8))
|
|
|
|
def recurse(bitpos: int) -> Tuple[_BinNode, int]:
|
|
insval, bitpos = _CODER_INS.decode(bits, bitpos)
|
|
ins = _Instruction(insval)
|
|
if ins == _Instruction.RETURN:
|
|
asn, bitpos = _CODER_ASN.decode(bits, bitpos)
|
|
return _BinNode(ins, asn), bitpos
|
|
if ins == _Instruction.JUMP:
|
|
jump, bitpos = _CODER_JUMP.decode(bits, bitpos)
|
|
left, bitpos1 = recurse(bitpos)
|
|
if bitpos1 != bitpos + jump:
|
|
raise ValueError("Inconsistent jump")
|
|
right, bitpos = recurse(bitpos1)
|
|
return _BinNode(ins, left, right), bitpos
|
|
if ins == _Instruction.MATCH:
|
|
match, bitpos = _CODER_MATCH.decode(bits, bitpos)
|
|
sub, bitpos = recurse(bitpos)
|
|
return _BinNode(ins, match, sub), bitpos
|
|
assert ins == _Instruction.DEFAULT
|
|
asn, bitpos = _CODER_ASN.decode(bits, bitpos)
|
|
sub, bitpos = recurse(bitpos)
|
|
return _BinNode(ins, asn, sub), bitpos
|
|
|
|
if len(bits) == 0:
|
|
binnode = _BinNode(_Instruction.END)
|
|
else:
|
|
try:
|
|
binnode, bitpos = recurse(0)
|
|
except (ValueError, IndexError):
|
|
return None
|
|
if bitpos < len(bits) - 7:
|
|
return None
|
|
if not all(bit == 0 for bit in bits[bitpos:]):
|
|
return None
|
|
|
|
return ASMap._from_binnode(binnode)
|
|
|
|
def __lt__(self, other: "ASMap") -> bool:
|
|
return self._trie < other._trie
|
|
|
|
def __eq__(self, other: object) -> bool:
|
|
if isinstance(other, ASMap):
|
|
return self._trie == other._trie
|
|
return False
|
|
|
|
def extends(self, req: "ASMap") -> bool:
|
|
"""Determine whether this matches req for all subranges where req is assigned."""
|
|
def recurse(actual: List, require: List) -> bool:
|
|
if len(require) == 1 and require[0] == 0:
|
|
return True
|
|
if len(require) == 1:
|
|
if len(actual) == 1:
|
|
return bool(require[0] == actual[0])
|
|
return recurse(actual[0], require) and recurse(actual[1], require)
|
|
if len(actual) == 2:
|
|
return recurse(actual[0], require[0]) and recurse(actual[1], require[1])
|
|
return recurse(actual, require[0]) and recurse(actual, require[1])
|
|
assert isinstance(req, ASMap)
|
|
#pylint: disable=protected-access
|
|
return recurse(self._trie, req._trie)
|
|
|
|
def diff(self, other: "ASMap") -> List[ASNDiff]:
|
|
"""Compute the diff from self to other."""
|
|
prefix: List[bool] = []
|
|
ret: List[ASNDiff] = []
|
|
|
|
def recurse(old_node: List, new_node: List):
|
|
if len(old_node) == 1 and len(new_node) == 1:
|
|
if old_node[0] != new_node[0]:
|
|
ret.append((list(prefix), old_node[0], new_node[0]))
|
|
else:
|
|
old_left: List = old_node if len(old_node) == 1 else old_node[0]
|
|
old_right: List = old_node if len(old_node) == 1 else old_node[1]
|
|
new_left: List = new_node if len(new_node) == 1 else new_node[0]
|
|
new_right: List = new_node if len(new_node) == 1 else new_node[1]
|
|
prefix.append(False)
|
|
recurse(old_left, new_left)
|
|
prefix[-1] = True
|
|
recurse(old_right, new_right)
|
|
prefix.pop()
|
|
assert isinstance(other, ASMap)
|
|
#pylint: disable=protected-access
|
|
recurse(self._trie, other._trie)
|
|
return ret
|
|
|
|
def __copy__(self) -> "ASMap":
|
|
"""Construct a copy of this ASMap object. Its state will not be shared."""
|
|
ret = ASMap()
|
|
#pylint: disable=protected-access
|
|
ret._set_trie(copy.deepcopy(self._trie))
|
|
return ret
|
|
|
|
def __deepcopy__(self, _) -> "ASMap":
|
|
# ASMap objects do not allow sharing of the _trie member, so we don't need the memoization.
|
|
return self.__copy__()
|
|
|
|
|
|
class TestASMap(unittest.TestCase):
|
|
"""Unit tests for this module."""
|
|
|
|
def test_ipv6_prefix_roundtrips(self) -> None:
|
|
"""Test that random IPv6 network ranges roundtrip through prefix encoding."""
|
|
for _ in range(20):
|
|
net_bits = random.getrandbits(128)
|
|
for prefix_len in range(0, 129):
|
|
masked_bits = (net_bits >> (128 - prefix_len)) << (128 - prefix_len)
|
|
net = ipaddress.IPv6Network((masked_bits.to_bytes(16, 'big'), prefix_len))
|
|
prefix = net_to_prefix(net)
|
|
self.assertTrue(len(prefix) <= 128)
|
|
net2 = prefix_to_net(prefix)
|
|
self.assertEqual(net, net2)
|
|
|
|
def test_ipv4_prefix_roundtrips(self) -> None:
|
|
"""Test that random IPv4 network ranges roundtrip through prefix encoding."""
|
|
for _ in range(100):
|
|
net_bits = random.getrandbits(32)
|
|
for prefix_len in range(0, 33):
|
|
masked_bits = (net_bits >> (32 - prefix_len)) << (32 - prefix_len)
|
|
net = ipaddress.IPv4Network((masked_bits.to_bytes(4, 'big'), prefix_len))
|
|
prefix = net_to_prefix(net)
|
|
self.assertTrue(32 <= len(prefix) <= 128)
|
|
net2 = prefix_to_net(prefix)
|
|
self.assertEqual(net, net2)
|
|
|
|
def test_asmap_roundtrips(self) -> None:
|
|
"""Test case that verifies random ASMap objects roundtrip to/from entries/binary."""
|
|
# Iterate over the number of leaves the random test ASMap objects have.
|
|
for leaves in range(1, 20):
|
|
# Iterate over the number of bits in the AS numbers used.
|
|
for asnbits in range(0, 24):
|
|
# Iterate over the probability that leaves are unassigned.
|
|
for pct in range(101):
|
|
# Construct a random ASMap object according to the above parameters.
|
|
asmap = ASMap.from_random(num_leaves=leaves, max_asn=1 + (1 << asnbits),
|
|
unassigned_prob=0.01 * pct)
|
|
# Run tests for to_entries and construction from those entries, both
|
|
# for overlapping and non-overlapping ones.
|
|
for overlapping in [False, True]:
|
|
entries = asmap.to_entries(overlapping=overlapping, fill=False)
|
|
random.shuffle(entries)
|
|
asmap2 = ASMap(entries)
|
|
assert asmap2 is not None
|
|
self.assertEqual(asmap2, asmap)
|
|
entries = asmap.to_entries(overlapping=overlapping, fill=True)
|
|
random.shuffle(entries)
|
|
asmap2 = ASMap(entries)
|
|
assert asmap2 is not None
|
|
self.assertTrue(asmap2.extends(asmap))
|
|
|
|
# Run tests for to_binary and construction from binary.
|
|
enc = asmap.to_binary(fill=False)
|
|
asmap3 = ASMap.from_binary(enc)
|
|
assert asmap3 is not None
|
|
self.assertEqual(asmap3, asmap)
|
|
enc = asmap.to_binary(fill=True)
|
|
asmap3 = ASMap.from_binary(enc)
|
|
assert asmap3 is not None
|
|
self.assertTrue(asmap3.extends(asmap))
|
|
|
|
def test_patching(self) -> None:
|
|
"""Test behavior of update, lookup, extends, and diff."""
|
|
#pylint: disable=too-many-locals,too-many-nested-blocks
|
|
# Iterate over the number of leaves the random test ASMap objects have.
|
|
for leaves in range(1, 20):
|
|
# Iterate over the number of bits in the AS numbers used.
|
|
for asnbits in range(0, 10):
|
|
# Iterate over the probability that leaves are unassigned.
|
|
for pct in range(0, 101):
|
|
# Construct a random ASMap object according to the above parameters.
|
|
asmap = ASMap.from_random(num_leaves=leaves, max_asn=1 + (1 << asnbits),
|
|
unassigned_prob=0.01 * pct)
|
|
# Make a copy of that asmap object to which patches will be applied.
|
|
# It starts off being equal to asmap.
|
|
patched = copy.copy(asmap)
|
|
# Keep a list of patches performed.
|
|
patches: List[ASNEntry] = []
|
|
# Initially there cannot be any difference.
|
|
self.assertEqual(asmap.diff(patched), [])
|
|
# Make 5 patches, each building on top of the previous ones.
|
|
for _ in range(0, 5):
|
|
# Construct a random path and new ASN to assign it to, apply it to patched,
|
|
# and remember it in patches.
|
|
pathlen = random.randrange(5)
|
|
path = [random.getrandbits(1) != 0 for _ in range(pathlen)]
|
|
newasn = random.randrange(1 + (1 << asnbits))
|
|
patched.update(path, newasn)
|
|
patches = [(path, newasn)] + patches
|
|
|
|
# Compute the diff, and whether asmap extends patched, and the other way
|
|
# around.
|
|
diff = asmap.diff(patched)
|
|
self.assertEqual(asmap == patched, len(diff) == 0)
|
|
extends = asmap.extends(patched)
|
|
back_extends = patched.extends(asmap)
|
|
# Determine whether those extends results are consistent with the diff
|
|
# result.
|
|
self.assertEqual(extends, all(d[2] == 0 for d in diff))
|
|
self.assertEqual(back_extends, all(d[1] == 0 for d in diff))
|
|
# For every diff found:
|
|
for path, old_asn, new_asn in diff:
|
|
# Verify asmap and patched actually differ there.
|
|
self.assertTrue(old_asn != new_asn)
|
|
self.assertEqual(asmap.lookup(path), old_asn)
|
|
self.assertEqual(patched.lookup(path), new_asn)
|
|
for _ in range(2):
|
|
# Extend the path far enough that it's smaller than any mapped
|
|
# range, and check the lookup holds there too.
|
|
spec_path = list(path)
|
|
while len(spec_path) < 32:
|
|
spec_path.append(random.getrandbits(1) != 0)
|
|
self.assertEqual(asmap.lookup(spec_path), old_asn)
|
|
self.assertEqual(patched.lookup(spec_path), new_asn)
|
|
# Search through the list of performed patches to find the last one
|
|
# applying to the extended path (note that patches is in reverse
|
|
# order, so the first match should work).
|
|
found = False
|
|
for patch_path, patch_asn in patches:
|
|
if spec_path[:len(patch_path)] == patch_path:
|
|
# When found, it must match whatever the result was patched
|
|
# to.
|
|
self.assertEqual(new_asn, patch_asn)
|
|
found = True
|
|
break
|
|
# And such a patch must exist.
|
|
self.assertTrue(found)
|
|
|
|
if __name__ == '__main__':
|
|
unittest.main()
|