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Jython is an implementation of the high-level, dynamic, object-oriented
language Python written in 100% Pure Java, and seamlessly integrated with
the Java platform. It thus allows you to run Python on any Java platform.
#!/usr/bin/python
#
# Copyright 2007 Google Inc.
# Licensed to PSF under a Contributor Agreement.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
# implied. See the License for the specific language governing
# permissions and limitations under the License.
"""A fast, lightweight IPv4/IPv6 manipulation library in Python.
This library is used to create/poke/manipulate IPv4 and IPv6 addresses
and networks.
"""
__version__ = 'trunk'
import struct
IPV4LENGTH = 32
IPV6LENGTH = 128
class AddressValueError(ValueError):
"""A Value Error related to the address."""
class NetmaskValueError(ValueError):
"""A Value Error related to the netmask."""
def IPAddress(address, version=None):
"""Take an IP string/int and return an object of the correct type.
Args:
address: A string or integer, the IP address. Either IPv4 or
IPv6 addresses may be supplied; integers less than 2**32 will
be considered to be IPv4 by default.
version: An Integer, 4 or 6. If set, don't try to automatically
determine what the IP address type is. important for things
like IPAddress(1), which could be IPv4, '0.0.0.1', or IPv6,
'::1'.
Returns:
An IPv4Address or IPv6Address object.
Raises:
ValueError: if the string passed isn't either a v4 or a v6
address.
"""
if version:
if version == 4:
return IPv4Address(address)
elif version == 6:
return IPv6Address(address)
try:
return IPv4Address(address)
except (AddressValueError, NetmaskValueError):
pass
try:
return IPv6Address(address)
except (AddressValueError, NetmaskValueError):
pass
raise ValueError('%r does not appear to be an IPv4 or IPv6 address' %
address)
def IPNetwork(address, version=None, strict=False):
"""Take an IP string/int and return an object of the correct type.
Args:
address: A string or integer, the IP address. Either IPv4 or
IPv6 addresses may be supplied; integers less than 2**32 will
be considered to be IPv4 by default.
version: An Integer, if set, don't try to automatically
determine what the IP address type is. important for things
like IPNetwork(1), which could be IPv4, '0.0.0.1/32', or IPv6,
'::1/128'.
Returns:
An IPv4Network or IPv6Network object.
Raises:
ValueError: if the string passed isn't either a v4 or a v6
address. Or if a strict network was requested and a strict
network wasn't given.
"""
if version:
if version == 4:
return IPv4Network(address, strict)
elif version == 6:
return IPv6Network(address, strict)
try:
return IPv4Network(address, strict)
except (AddressValueError, NetmaskValueError):
pass
try:
return IPv6Network(address, strict)
except (AddressValueError, NetmaskValueError):
pass
raise ValueError('%r does not appear to be an IPv4 or IPv6 network' %
address)
def v4_int_to_packed(address):
"""The binary representation of this address.
Args:
address: An integer representation of an IPv4 IP address.
Returns:
The binary representation of this address.
Raises:
ValueError: If the integer is too large to be an IPv4 IP
address.
"""
if address > _BaseV4._ALL_ONES:
raise ValueError('Address too large for IPv4')
return struct.pack('!I', address)
def v6_int_to_packed(address):
"""The binary representation of this address.
Args:
address: An integer representation of an IPv4 IP address.
Returns:
The binary representation of this address.
"""
return struct.pack('!QQ', address >> 64, address & (2**64 - 1))
def _find_address_range(addresses):
"""Find a sequence of addresses.
Args:
addresses: a list of IPv4 or IPv6 addresses.
Returns:
A tuple containing the first and last IP addresses in the sequence.
"""
first = last = addresses[0]
for ip in addresses[1:]:
if ip._ip == last._ip + 1:
last = ip
else:
break
return (first, last)
def _get_prefix_length(number1, number2, bits):
"""Get the number of leading bits that are same for two numbers.
Args:
number1: an integer.
number2: another integer.
bits: the maximum number of bits to compare.
Returns:
The number of leading bits that are the same for two numbers.
"""
for i in range(bits):
if number1 >> i == number2 >> i:
return bits - i
return 0
def _count_righthand_zero_bits(number, bits):
"""Count the number of zero bits on the right hand side.
Args:
number: an integer.
bits: maximum number of bits to count.
Returns:
The number of zero bits on the right hand side of the number.
"""
if number == 0:
return bits
for i in range(bits):
if (number >> i) % 2:
return i
def summarize_address_range(first, last):
"""Summarize a network range given the first and last IP addresses.
Example:
>>> summarize_address_range(IPv4Address('1.1.1.0'),
IPv4Address('1.1.1.130'))
[IPv4Network('1.1.1.0/25'), IPv4Network('1.1.1.128/31'),
IPv4Network('1.1.1.130/32')]
Args:
first: the first IPv4Address or IPv6Address in the range.
last: the last IPv4Address or IPv6Address in the range.
Returns:
The address range collapsed to a list of IPv4Network's or
IPv6Network's.
Raise:
TypeError:
If the first and last objects are not IP addresses.
If the first and last objects are not the same version.
ValueError:
If the last object is not greater than the first.
If the version is not 4 or 6.
"""
if not (isinstance(first, _BaseIP) and isinstance(last, _BaseIP)):
raise TypeError('first and last must be IP addresses, not networks')
if first.version != last.version:
raise TypeError("%s and %s are not of the same version" % (
str(first), str(last)))
if first > last:
raise ValueError('last IP address must be greater than first')
networks = []
if first.version == 4:
ip = IPv4Network
elif first.version == 6:
ip = IPv6Network
else:
raise ValueError('unknown IP version')
ip_bits = first._max_prefixlen
first_int = first._ip
last_int = last._ip
while first_int <= last_int:
nbits = _count_righthand_zero_bits(first_int, ip_bits)
current = None
while nbits >= 0:
addend = 2**nbits - 1
current = first_int + addend
nbits -= 1
if current <= last_int:
break
prefix = _get_prefix_length(first_int, current, ip_bits)
net = ip('%s/%d' % (str(first), prefix))
networks.append(net)
if current == ip._ALL_ONES:
break
first_int = current + 1
first = IPAddress(first_int, version=first._version)
return networks
def _collapse_address_list_recursive(addresses):
"""Loops through the addresses, collapsing concurrent netblocks.
Example:
ip1 = IPv4Network('1.1.0.0/24')
ip2 = IPv4Network('1.1.1.0/24')
ip3 = IPv4Network('1.1.2.0/24')
ip4 = IPv4Network('1.1.3.0/24')
ip5 = IPv4Network('1.1.4.0/24')
ip6 = IPv4Network('1.1.0.1/22')
_collapse_address_list_recursive([ip1, ip2, ip3, ip4, ip5, ip6]) ->
[IPv4Network('1.1.0.0/22'), IPv4Network('1.1.4.0/24')]
This shouldn't be called directly; it is called via
collapse_address_list([]).
Args:
addresses: A list of IPv4Network's or IPv6Network's
Returns:
A list of IPv4Network's or IPv6Network's depending on what we were
passed.
"""
ret_array = []
optimized = False
for cur_addr in addresses:
if not ret_array:
ret_array.append(cur_addr)
continue
if cur_addr in ret_array[-1]:
optimized = True
elif cur_addr == ret_array[-1].supernet().subnet()[1]:
ret_array.append(ret_array.pop().supernet())
optimized = True
else:
ret_array.append(cur_addr)
if optimized:
return _collapse_address_list_recursive(ret_array)
return ret_array
def collapse_address_list(addresses):
"""Collapse a list of IP objects.
Example:
collapse_address_list([IPv4('1.1.0.0/24'), IPv4('1.1.1.0/24')]) ->
[IPv4('1.1.0.0/23')]
Args:
addresses: A list of IPv4Network or IPv6Network objects.
Returns:
A list of IPv4Network or IPv6Network objects depending on what we
were passed.
Raises:
TypeError: If passed a list of mixed version objects.
"""
i = 0
addrs = []
ips = []
nets = []
# split IP addresses and networks
for ip in addresses:
if isinstance(ip, _BaseIP):
if ips and ips[-1]._version != ip._version:
raise TypeError("%s and %s are not of the same version" % (
str(ip), str(ips[-1])))
ips.append(ip)
elif ip._prefixlen == ip._max_prefixlen:
if ips and ips[-1]._version != ip._version:
raise TypeError("%s and %s are not of the same version" % (
str(ip), str(ips[-1])))
ips.append(ip.ip)
else:
if nets and nets[-1]._version != ip._version:
raise TypeError("%s and %s are not of the same version" % (
str(ip), str(ips[-1])))
nets.append(ip)
# sort and dedup
ips = sorted(set(ips))
nets = sorted(set(nets))
while i < len(ips):
(first, last) = _find_address_range(ips[i:])
i = ips.index(last) + 1
addrs.extend(summarize_address_range(first, last))
return _collapse_address_list_recursive(sorted(
addrs + nets, key=_BaseNet._get_networks_key))
# backwards compatibility
CollapseAddrList = collapse_address_list
# Test whether this Python implementation supports byte objects that
# are not identical to str ones.
# We need to exclude platforms where bytes == str so that we can
# distinguish between packed representations and strings, for example
# b'12::' (the IPv4 address 49.50.58.58) and '12::' (an IPv6 address).
try:
_compat_has_real_bytes = bytes is not str
except NameError: # other._ip
return False
# Shorthand for Integer addition and subtraction. This is not
# meant to ever support addition/subtraction of addresses.
def __add__(self, other):
if not isinstance(other, int):
return NotImplemented
return IPAddress(int(self) + other, version=self._version)
def __sub__(self, other):
if not isinstance(other, int):
return NotImplemented
return IPAddress(int(self) - other, version=self._version)
def __repr__(self):
return '%s(%r)' % (self.__class__.__name__, str(self))
def __str__(self):
return '%s' % self._string_from_ip_int(self._ip)
def __hash__(self):
return hash(hex(long(self._ip)))
def _get_address_key(self):
return (self._version, self)
@property
def version(self):
raise NotImplementedError('BaseIP has no version')
class _BaseNet(_IPAddrBase):
"""A generic IP object.
This IP class contains the version independent methods which are
used by networks.
"""
def __init__(self, address):
self._cache = {}
def __repr__(self):
return '%s(%r)' % (self.__class__.__name__, str(self))
def iterhosts(self):
"""Generate Iterator over usable hosts in a network.
This is like __iter__ except it doesn't return the network
or broadcast addresses.
"""
cur = int(self.network) + 1
bcast = int(self.broadcast) - 1
while cur <= bcast:
cur += 1
yield IPAddress(cur - 1, version=self._version)
def __iter__(self):
cur = int(self.network)
bcast = int(self.broadcast)
while cur <= bcast:
cur += 1
yield IPAddress(cur - 1, version=self._version)
def __getitem__(self, n):
network = int(self.network)
broadcast = int(self.broadcast)
if n >= 0:
if network + n > broadcast:
raise IndexError
return IPAddress(network + n, version=self._version)
else:
n += 1
if broadcast + n < network:
raise IndexError
return IPAddress(broadcast + n, version=self._version)
def __lt__(self, other):
if self._version != other._version:
raise TypeError('%s and %s are not of the same version' % (
str(self), str(other)))
if not isinstance(other, _BaseNet):
raise TypeError('%s and %s are not of the same type' % (
str(self), str(other)))
if self.network != other.network:
return self.network < other.network
if self.netmask != other.netmask:
return self.netmask < other.netmask
return False
def __gt__(self, other):
if self._version != other._version:
raise TypeError('%s and %s are not of the same version' % (
str(self), str(other)))
if not isinstance(other, _BaseNet):
raise TypeError('%s and %s are not of the same type' % (
str(self), str(other)))
if self.network != other.network:
return self.network > other.network
if self.netmask != other.netmask:
return self.netmask > other.netmask
return False
def __le__(self, other):
gt = self.__gt__(other)
if gt is NotImplemented:
return NotImplemented
return not gt
def __ge__(self, other):
lt = self.__lt__(other)
if lt is NotImplemented:
return NotImplemented
return not lt
def __eq__(self, other):
try:
return (self._version == other._version
and self.network == other.network
and int(self.netmask) == int(other.netmask))
except AttributeError:
if isinstance(other, _BaseIP):
return (self._version == other._version
and self._ip == other._ip)
def __ne__(self, other):
eq = self.__eq__(other)
if eq is NotImplemented:
return NotImplemented
return not eq
def __str__(self):
return '%s/%s' % (str(self.ip),
str(self._prefixlen))
def __hash__(self):
return hash(int(self.network) ^ int(self.netmask))
def __contains__(self, other):
# always false if one is v4 and the other is v6.
if self._version != other._version:
return False
# dealing with another network.
if isinstance(other, _BaseNet):
return (self.network <= other.network and
self.broadcast >= other.broadcast)
# dealing with another address
else:
return (int(self.network) <= int(other._ip) <=
int(self.broadcast))
def overlaps(self, other):
"""Tell if self is partly contained in other."""
return self.network in other or self.broadcast in other or (
other.network in self or other.broadcast in self)
@property
def network(self):
x = self._cache.get('network')
if x is None:
x = IPAddress(self._ip & int(self.netmask), version=self._version)
self._cache['network'] = x
return x
@property
def broadcast(self):
x = self._cache.get('broadcast')
if x is None:
x = IPAddress(self._ip | int(self.hostmask), version=self._version)
self._cache['broadcast'] = x
return x
@property
def hostmask(self):
x = self._cache.get('hostmask')
if x is None:
x = IPAddress(int(self.netmask) ^ self._ALL_ONES,
version=self._version)
self._cache['hostmask'] = x
return x
@property
def with_prefixlen(self):
return '%s/%d' % (str(self.ip), self._prefixlen)
@property
def with_netmask(self):
return '%s/%s' % (str(self.ip), str(self.netmask))
@property
def with_hostmask(self):
return '%s/%s' % (str(self.ip), str(self.hostmask))
@property
def numhosts(self):
"""Number of hosts in the current subnet."""
return int(self.broadcast) - int(self.network) + 1
@property
def version(self):
raise NotImplementedError('BaseNet has no version')
@property
def prefixlen(self):
return self._prefixlen
def address_exclude(self, other):
"""Remove an address from a larger block.
For example:
addr1 = IPNetwork('10.1.1.0/24')
addr2 = IPNetwork('10.1.1.0/26')
addr1.address_exclude(addr2) =
[IPNetwork('10.1.1.64/26'), IPNetwork('10.1.1.128/25')]
or IPv6:
addr1 = IPNetwork('::1/32')
addr2 = IPNetwork('::1/128')
addr1.address_exclude(addr2) = [IPNetwork('::0/128'),
IPNetwork('::2/127'),
IPNetwork('::4/126'),
IPNetwork('::8/125'),
...
IPNetwork('0:0:8000::/33')]
Args:
other: An IPvXNetwork object of the same type.
Returns:
A sorted list of IPvXNetwork objects addresses which is self
minus other.
Raises:
TypeError: If self and other are of difffering address
versions, or if other is not a network object.
ValueError: If other is not completely contained by self.
"""
if not self._version == other._version:
raise TypeError("%s and %s are not of the same version" % (
str(self), str(other)))
if not isinstance(other, _BaseNet):
raise TypeError("%s is not a network object" % str(other))
if other not in self:
raise ValueError('%s not contained in %s' % (str(other),
str(self)))
if other == self:
return []
ret_addrs = []
# Make sure we're comparing the network of other.
other = IPNetwork('%s/%s' % (str(other.network), str(other.prefixlen)),
version=other._version)
s1, s2 = self.subnet()
while s1 != other and s2 != other:
if other in s1:
ret_addrs.append(s2)
s1, s2 = s1.subnet()
elif other in s2:
ret_addrs.append(s1)
s1, s2 = s2.subnet()
else:
# If we got here, there's a bug somewhere.
assert True == False, ('Error performing exclusion: '
's1: %s s2: %s other: %s' %
(str(s1), str(s2), str(other)))
if s1 == other:
ret_addrs.append(s2)
elif s2 == other:
ret_addrs.append(s1)
else:
# If we got here, there's a bug somewhere.
assert True == False, ('Error performing exclusion: '
's1: %s s2: %s other: %s' %
(str(s1), str(s2), str(other)))
return sorted(ret_addrs, key=_BaseNet._get_networks_key)
def compare_networks(self, other):
"""Compare two IP objects.
This is only concerned about the comparison of the integer
representation of the network addresses. This means that the
host bits aren't considered at all in this method. If you want
to compare host bits, you can easily enough do a
'HostA._ip < HostB._ip'
Args:
other: An IP object.
Returns:
If the IP versions of self and other are the same, returns:
-1 if self < other:
eg: IPv4('1.1.1.0/24') < IPv4('1.1.2.0/24')
IPv6('1080::200C:417A') < IPv6('1080::200B:417B')
0 if self == other
eg: IPv4('1.1.1.1/24') == IPv4('1.1.1.2/24')
IPv6('1080::200C:417A/96') == IPv6('1080::200C:417B/96')
1 if self > other
eg: IPv4('1.1.1.0/24') > IPv4('1.1.0.0/24')
IPv6('1080::1:200C:417A/112') >
IPv6('1080::0:200C:417A/112')
If the IP versions of self and other are different, returns:
-1 if self._version < other._version
eg: IPv4('10.0.0.1/24') < IPv6('::1/128')
1 if self._version > other._version
eg: IPv6('::1/128') > IPv4('255.255.255.0/24')
"""
if self._version < other._version:
return -1
if self._version > other._version:
return 1
# self._version == other._version below here:
if self.network < other.network:
return -1
if self.network > other.network:
return 1
# self.network == other.network below here:
if self.netmask < other.netmask:
return -1
if self.netmask > other.netmask:
return 1
# self.network == other.network and self.netmask == other.netmask
return 0
def _get_networks_key(self):
"""Network-only key function.
Returns an object that identifies this address' network and
netmask. This function is a suitable "key" argument for sorted()
and list.sort().
"""
return (self._version, self.network, self.netmask)
def _ip_int_from_prefix(self, prefixlen=None):
"""Turn the prefix length netmask into a int for comparison.
Args:
prefixlen: An integer, the prefix length.
Returns:
An integer.
"""
if not prefixlen and prefixlen != 0:
prefixlen = self._prefixlen
return self._ALL_ONES ^ (self._ALL_ONES >> prefixlen)
def _prefix_from_ip_int(self, ip_int, mask=32):
"""Return prefix length from the decimal netmask.
Args:
ip_int: An integer, the IP address.
mask: The netmask. Defaults to 32.
Returns:
An integer, the prefix length.
"""
while mask:
if ip_int & 1 == 1:
break
ip_int >>= 1
mask -= 1
return mask
def _ip_string_from_prefix(self, prefixlen=None):
"""Turn a prefix length into a dotted decimal string.
Args:
prefixlen: An integer, the netmask prefix length.
Returns:
A string, the dotted decimal netmask string.
"""
if not prefixlen:
prefixlen = self._prefixlen
return self._string_from_ip_int(self._ip_int_from_prefix(prefixlen))
def iter_subnets(self, prefixlen_diff=1, new_prefix=None):
"""The subnets which join to make the current subnet.
In the case that self contains only one IP
(self._prefixlen == 32 for IPv4 or self._prefixlen == 128
for IPv6), return a list with just ourself.
Args:
prefixlen_diff: An integer, the amount the prefix length
should be increased by. This should not be set if
new_prefix is also set.
new_prefix: The desired new prefix length. This must be a
larger number (smaller prefix) than the existing prefix.
This should not be set if prefixlen_diff is also set.
Returns:
An iterator of IPv(4|6) objects.
Raises:
ValueError: The prefixlen_diff is too small or too large.
OR
prefixlen_diff and new_prefix are both set or new_prefix
is a smaller number than the current prefix (smaller
number means a larger network)
"""
if self._prefixlen == self._max_prefixlen:
yield self
return
if new_prefix is not None:
if new_prefix < self._prefixlen:
raise ValueError('new prefix must be longer')
if prefixlen_diff != 1:
raise ValueError('cannot set prefixlen_diff and new_prefix')
prefixlen_diff = new_prefix - self._prefixlen
if prefixlen_diff < 0:
raise ValueError('prefix length diff must be > 0')
new_prefixlen = self._prefixlen + prefixlen_diff
if not self._is_valid_netmask(str(new_prefixlen)):
raise ValueError(
'prefix length diff %d is invalid for netblock %s' % (
new_prefixlen, str(self)))
first = IPNetwork('%s/%s' % (str(self.network),
str(self._prefixlen + prefixlen_diff)),
version=self._version)
yield first
current = first
while True:
broadcast = current.broadcast
if broadcast == self.broadcast:
return
new_addr = IPAddress(int(broadcast) + 1, version=self._version)
current = IPNetwork('%s/%s' % (str(new_addr), str(new_prefixlen)),
version=self._version)
yield current
def masked(self):
"""Return the network object with the host bits masked out."""
return IPNetwork('%s/%d' % (self.network, self._prefixlen),
version=self._version)
def subnet(self, prefixlen_diff=1, new_prefix=None):
"""Return a list of subnets, rather than an iterator."""
return list(self.iter_subnets(prefixlen_diff, new_prefix))
def supernet(self, prefixlen_diff=1, new_prefix=None):
"""The supernet containing the current network.
Args:
prefixlen_diff: An integer, the amount the prefix length of
the network should be decreased by. For example, given a
/24 network and a prefixlen_diff of 3, a supernet with a
/21 netmask is returned.
Returns:
An IPv4 network object.
Raises:
ValueError: If self.prefixlen - prefixlen_diff < 0. I.e., you have a
negative prefix length.
OR
If prefixlen_diff and new_prefix are both set or new_prefix is a
larger number than the current prefix (larger number means a
smaller network)
"""
if self._prefixlen == 0:
return self
if new_prefix is not None:
if new_prefix > self._prefixlen:
raise ValueError('new prefix must be shorter')
if prefixlen_diff != 1:
raise ValueError('cannot set prefixlen_diff and new_prefix')
prefixlen_diff = self._prefixlen - new_prefix
if self.prefixlen - prefixlen_diff < 0:
raise ValueError(
'current prefixlen is %d, cannot have a prefixlen_diff of %d' %
(self.prefixlen, prefixlen_diff))
return IPNetwork('%s/%s' % (str(self.network),
str(self.prefixlen - prefixlen_diff)),
version=self._version)
# backwards compatibility
Subnet = subnet
Supernet = supernet
AddressExclude = address_exclude
CompareNetworks = compare_networks
Contains = __contains__
class _BaseV4(object):
"""Base IPv4 object.
The following methods are used by IPv4 objects in both single IP
addresses and networks.
"""
# Equivalent to 255.255.255.255 or 32 bits of 1's.
_ALL_ONES = (2**IPV4LENGTH) - 1
_DECIMAL_DIGITS = frozenset('0123456789')
def __init__(self, address):
self._version = 4
self._max_prefixlen = IPV4LENGTH
def _explode_shorthand_ip_string(self, ip_str=None):
if not ip_str:
ip_str = str(self)
return ip_str
def _ip_int_from_string(self, ip_str):
"""Turn the given IP string into an integer for comparison.
Args:
ip_str: A string, the IP ip_str.
Returns:
The IP ip_str as an integer.
Raises:
AddressValueError: if ip_str isn't a valid IPv4 Address.
"""
octets = ip_str.split('.')
if len(octets) != 4:
raise AddressValueError(ip_str)
packed_ip = 0
for oc in octets:
try:
packed_ip = (packed_ip << 8) | self._parse_octet(oc)
except ValueError:
raise AddressValueError(ip_str)
return packed_ip
def _parse_octet(self, octet_str):
"""Convert a decimal octet into an integer.
Args:
octet_str: A string, the number to parse.
Returns:
The octet as an integer.
Raises:
ValueError: if the octet isn't strictly a decimal from [0..255].
"""
# Whitelist the characters, since int() allows a lot of bizarre stuff.
if not self._DECIMAL_DIGITS.issuperset(octet_str):
raise ValueError
octet_int = int(octet_str, 10)
# Disallow leading zeroes, because no clear standard exists on
# whether these should be interpreted as decimal or octal.
if octet_int > 255 or (octet_str[0] == '0' and len(octet_str) > 1):
raise ValueError
return octet_int
def _string_from_ip_int(self, ip_int):
"""Turns a 32-bit integer into dotted decimal notation.
Args:
ip_int: An integer, the IP address.
Returns:
The IP address as a string in dotted decimal notation.
"""
octets = []
for _ in xrange(4):
octets.insert(0, str(ip_int & 0xFF))
ip_int >>= 8
return '.'.join(octets)
@property
def max_prefixlen(self):
return self._max_prefixlen
@property
def packed(self):
"""The binary representation of this address."""
return v4_int_to_packed(self._ip)
@property
def version(self):
return self._version
@property
def is_reserved(self):
"""Test if the address is otherwise IETF reserved.
Returns:
A boolean, True if the address is within the
reserved IPv4 Network range.
"""
return self in IPv4Network('240.0.0.0/4')
@property
def is_private(self):
"""Test if this address is allocated for private networks.
Returns:
A boolean, True if the address is reserved per RFC 1918.
"""
return (self in IPv4Network('10.0.0.0/8') or
self in IPv4Network('172.16.0.0/12') or
self in IPv4Network('192.168.0.0/16'))
@property
def is_multicast(self):
"""Test if the address is reserved for multicast use.
Returns:
A boolean, True if the address is multicast.
See RFC 3171 for details.
"""
return self in IPv4Network('224.0.0.0/4')
@property
def is_unspecified(self):
"""Test if the address is unspecified.
Returns:
A boolean, True if this is the unspecified address as defined in
RFC 5735 3.
"""
return self in IPv4Network('0.0.0.0')
@property
def is_loopback(self):
"""Test if the address is a loopback address.
Returns:
A boolean, True if the address is a loopback per RFC 3330.
"""
return self in IPv4Network('127.0.0.0/8')
@property
def is_link_local(self):
"""Test if the address is reserved for link-local.
Returns:
A boolean, True if the address is link-local per RFC 3927.
"""
return self in IPv4Network('169.254.0.0/16')
class IPv4Address(_BaseV4, _BaseIP):
"""Represent and manipulate single IPv4 Addresses."""
def __init__(self, address):
"""
Args:
address: A string or integer representing the IP
'192.168.1.1'
Additionally, an integer can be passed, so
IPv4Address('192.168.1.1') == IPv4Address(3232235777).
or, more generally
IPv4Address(int(IPv4Address('192.168.1.1'))) ==
IPv4Address('192.168.1.1')
Raises:
AddressValueError: If ipaddr isn't a valid IPv4 address.
"""
_BaseIP.__init__(self, address)
_BaseV4.__init__(self, address)
# Efficient constructor from integer.
if isinstance(address, (int, long)):
self._ip = address
if address < 0 or address > self._ALL_ONES:
raise AddressValueError(address)
return
# Constructing from a packed address
if _compat_has_real_bytes:
if isinstance(address, bytes) and len(address) == 4:
self._ip = struct.unpack('!I', address)[0]
return
# Assume input argument to be string or any object representation
# which converts into a formatted IP string.
addr_str = str(address)
self._ip = self._ip_int_from_string(addr_str)
class IPv4Network(_BaseV4, _BaseNet):
"""This class represents and manipulates 32-bit IPv4 networks.
Attributes: [examples for IPv4Network('1.2.3.4/27')]
._ip: 16909060
.ip: IPv4Address('1.2.3.4')
.network: IPv4Address('1.2.3.0')
.hostmask: IPv4Address('0.0.0.31')
.broadcast: IPv4Address('1.2.3.31')
.netmask: IPv4Address('255.255.255.224')
.prefixlen: 27
"""
# the valid octets for host and netmasks. only useful for IPv4.
_valid_mask_octets = set((255, 254, 252, 248, 240, 224, 192, 128, 0))
def __init__(self, address, strict=False):
"""Instantiate a new IPv4 network object.
Args:
address: A string or integer representing the IP [& network].
'192.168.1.1/24'
'192.168.1.1/255.255.255.0'
'192.168.1.1/0.0.0.255'
are all functionally the same in IPv4. Similarly,
'192.168.1.1'
'192.168.1.1/255.255.255.255'
'192.168.1.1/32'
are also functionaly equivalent. That is to say, failing to
provide a subnetmask will create an object with a mask of /32.
If the mask (portion after the / in the argument) is given in
dotted quad form, it is treated as a netmask if it starts with a
non-zero field (e.g. /255.0.0.0 == /8) and as a hostmask if it
starts with a zero field (e.g. 0.255.255.255 == /8), with the
single exception of an all-zero mask which is treated as a
netmask == /0. If no mask is given, a default of /32 is used.
Additionally, an integer can be passed, so
IPv4Network('192.168.1.1') == IPv4Network(3232235777).
or, more generally
IPv4Network(int(IPv4Network('192.168.1.1'))) ==
IPv4Network('192.168.1.1')
strict: A boolean. If true, ensure that we have been passed
A true network address, eg, 192.168.1.0/24 and not an
IP address on a network, eg, 192.168.1.1/24.
Raises:
AddressValueError: If ipaddr isn't a valid IPv4 address.
NetmaskValueError: If the netmask isn't valid for
an IPv4 address.
ValueError: If strict was True and a network address was not
supplied.
"""
_BaseNet.__init__(self, address)
_BaseV4.__init__(self, address)
# Efficient constructor from integer.
if isinstance(address, (int, long)):
self._ip = address
self.ip = IPv4Address(self._ip)
self._prefixlen = self._max_prefixlen
self.netmask = IPv4Address(self._ALL_ONES)
if address < 0 or address > self._ALL_ONES:
raise AddressValueError(address)
return
# Constructing from a packed address
if _compat_has_real_bytes:
if isinstance(address, bytes) and len(address) == 4:
self._ip = struct.unpack('!I', address)[0]
self.ip = IPv4Address(self._ip)
self._prefixlen = self._max_prefixlen
self.netmask = IPv4Address(self._ALL_ONES)
return
# Assume input argument to be string or any object representation
# which converts into a formatted IP prefix string.
addr = str(address).split('/')
if len(addr) > 2:
raise AddressValueError(address)
self._ip = self._ip_int_from_string(addr[0])
self.ip = IPv4Address(self._ip)
if len(addr) == 2:
mask = addr[1].split('.')
if len(mask) == 4:
# We have dotted decimal netmask.
if self._is_valid_netmask(addr[1]):
self.netmask = IPv4Address(self._ip_int_from_string(
addr[1]))
elif self._is_hostmask(addr[1]):
self.netmask = IPv4Address(
self._ip_int_from_string(addr[1]) ^ self._ALL_ONES)
else:
raise NetmaskValueError('%s is not a valid netmask'
% addr[1])
self._prefixlen = self._prefix_from_ip_int(int(self.netmask))
else:
# We have a netmask in prefix length form.
if not self._is_valid_netmask(addr[1]):
raise NetmaskValueError(addr[1])
self._prefixlen = int(addr[1])
self.netmask = IPv4Address(self._ip_int_from_prefix(
self._prefixlen))
else:
self._prefixlen = self._max_prefixlen
self.netmask = IPv4Address(self._ip_int_from_prefix(
self._prefixlen))
if strict:
if self.ip != self.network:
raise ValueError('%s has host bits set' %
self.ip)
def _is_hostmask(self, ip_str):
"""Test if the IP string is a hostmask (rather than a netmask).
Args:
ip_str: A string, the potential hostmask.
Returns:
A boolean, True if the IP string is a hostmask.
"""
bits = ip_str.split('.')
try:
parts = [int(x) for x in bits if int(x) in self._valid_mask_octets]
except ValueError:
return False
if len(parts) != len(bits):
return False
if parts[0] < parts[-1]:
return True
return False
def _is_valid_netmask(self, netmask):
"""Verify that the netmask is valid.
Args:
netmask: A string, either a prefix or dotted decimal
netmask.
Returns:
A boolean, True if the prefix represents a valid IPv4
netmask.
"""
mask = netmask.split('.')
if len(mask) == 4:
if [x for x in mask if int(x) not in self._valid_mask_octets]:
return False
if [y for idx, y in enumerate(mask) if idx > 0 and
y > mask[idx - 1]]:
return False
return True
try:
netmask = int(netmask)
except ValueError:
return False
return 0 <= netmask <= self._max_prefixlen
# backwards compatibility
IsRFC1918 = lambda self: self.is_private
IsMulticast = lambda self: self.is_multicast
IsLoopback = lambda self: self.is_loopback
IsLinkLocal = lambda self: self.is_link_local
class _BaseV6(object):
"""Base IPv6 object.
The following methods are used by IPv6 objects in both single IP
addresses and networks.
"""
_ALL_ONES = (2**IPV6LENGTH) - 1
_HEXTET_COUNT = 8
_HEX_DIGITS = frozenset('0123456789ABCDEFabcdef')
def __init__(self, address):
self._version = 6
self._max_prefixlen = IPV6LENGTH
def _ip_int_from_string(self, ip_str):
"""Turn an IPv6 ip_str into an integer.
Args:
ip_str: A string, the IPv6 ip_str.
Returns:
A long, the IPv6 ip_str.
Raises:
AddressValueError: if ip_str isn't a valid IPv6 Address.
"""
parts = ip_str.split(':')
# An IPv6 address needs at least 2 colons (3 parts).
if len(parts) < 3:
raise AddressValueError(ip_str)
# If the address has an IPv4-style suffix, convert it to hexadecimal.
if '.' in parts[-1]:
ipv4_int = IPv4Address(parts.pop())._ip
parts.append('%x' % ((ipv4_int >> 16) & 0xFFFF))
parts.append('%x' % (ipv4_int & 0xFFFF))
# An IPv6 address can't have more than 8 colons (9 parts).
if len(parts) > self._HEXTET_COUNT + 1:
raise AddressValueError(ip_str)
# Disregarding the endpoints, find '::' with nothing in between.
# This indicates that a run of zeroes has been skipped.
try:
skip_index, = (
[i for i in xrange(1, len(parts) - 1) if not parts[i]] or
[None])
except ValueError:
# Can't have more than one '::'
raise AddressValueError(ip_str)
# parts_hi is the number of parts to copy from above/before the '::'
# parts_lo is the number of parts to copy from below/after the '::'
if skip_index is not None:
# If we found a '::', then check if it also covers the endpoints.
parts_hi = skip_index
parts_lo = len(parts) - skip_index - 1
if not parts[0]:
parts_hi -= 1
if parts_hi:
raise AddressValueError(ip_str) # ^: requires ^::
if not parts[-1]:
parts_lo -= 1
if parts_lo:
raise AddressValueError(ip_str) # :$ requires ::$
parts_skipped = self._HEXTET_COUNT - (parts_hi + parts_lo)
if parts_skipped < 1:
raise AddressValueError(ip_str)
else:
# Otherwise, allocate the entire address to parts_hi. The endpoints
# could still be empty, but _parse_hextet() will check for that.
if len(parts) != self._HEXTET_COUNT:
raise AddressValueError(ip_str)
parts_hi = len(parts)
parts_lo = 0
parts_skipped = 0
try:
# Now, parse the hextets into a 128-bit integer.
ip_int = 0L
for i in xrange(parts_hi):
ip_int <<= 16
ip_int |= self._parse_hextet(parts[i])
ip_int <<= 16 * parts_skipped
for i in xrange(-parts_lo, 0):
ip_int <<= 16
ip_int |= self._parse_hextet(parts[i])
return ip_int
except ValueError:
raise AddressValueError(ip_str)
def _parse_hextet(self, hextet_str):
"""Convert an IPv6 hextet string into an integer.
Args:
hextet_str: A string, the number to parse.
Returns:
The hextet as an integer.
Raises:
ValueError: if the input isn't strictly a hex number from [0..FFFF].
"""
# Whitelist the characters, since int() allows a lot of bizarre stuff.
if not self._HEX_DIGITS.issuperset(hextet_str):
raise ValueError
hextet_int = int(hextet_str, 16)
if hextet_int > 0xFFFF:
raise ValueError
return hextet_int
def _compress_hextets(self, hextets):
"""Compresses a list of hextets.
Compresses a list of strings, replacing the longest continuous
sequence of "0" in the list with "" and adding empty strings at
the beginning or at the end of the string such that subsequently
calling ":".join(hextets) will produce the compressed version of
the IPv6 address.
Args:
hextets: A list of strings, the hextets to compress.
Returns:
A list of strings.
"""
best_doublecolon_start = -1
best_doublecolon_len = 0
doublecolon_start = -1
doublecolon_len = 0
for index in range(len(hextets)):
if hextets[index] == '0':
doublecolon_len += 1
if doublecolon_start == -1:
# Start of a sequence of zeros.
doublecolon_start = index
if doublecolon_len > best_doublecolon_len:
# This is the longest sequence of zeros so far.
best_doublecolon_len = doublecolon_len
best_doublecolon_start = doublecolon_start
else:
doublecolon_len = 0
doublecolon_start = -1
if best_doublecolon_len > 1:
best_doublecolon_end = (best_doublecolon_start +
best_doublecolon_len)
# For zeros at the end of the address.
if best_doublecolon_end == len(hextets):
hextets += ['']
hextets[best_doublecolon_start:best_doublecolon_end] = ['']
# For zeros at the beginning of the address.
if best_doublecolon_start == 0:
hextets = [''] + hextets
return hextets
def _string_from_ip_int(self, ip_int=None):
"""Turns a 128-bit integer into hexadecimal notation.
Args:
ip_int: An integer, the IP address.
Returns:
A string, the hexadecimal representation of the address.
Raises:
ValueError: The address is bigger than 128 bits of all ones.
"""
if not ip_int and ip_int != 0:
ip_int = int(self._ip)
if ip_int > self._ALL_ONES:
raise ValueError('IPv6 address is too large')
hex_str = '%032x' % ip_int
hextets = []
for x in range(0, 32, 4):
hextets.append('%x' % int(hex_str[x:x+4], 16))
hextets = self._compress_hextets(hextets)
return ':'.join(hextets)
def _explode_shorthand_ip_string(self, ip_str=None):
"""Expand a shortened IPv6 address.
Args:
ip_str: A string, the IPv6 address.
Returns:
A string, the expanded IPv6 address.
"""
if not ip_str:
ip_str = str(self)
if isinstance(self, _BaseNet):
ip_str = str(self.ip)
ip_int = self._ip_int_from_string(ip_str)
parts = []
for i in xrange(self._HEXTET_COUNT):
parts.append('%04x' % (ip_int & 0xFFFF))
ip_int >>= 16
parts.reverse()
return ':'.join(parts)
@property
def max_prefixlen(self):
return self._max_prefixlen
@property
def packed(self):
"""The binary representation of this address."""
return v6_int_to_packed(self._ip)
@property
def version(self):
return self._version
@property
def is_multicast(self):
"""Test if the address is reserved for multicast use.
Returns:
A boolean, True if the address is a multicast address.
See RFC 2373 2.7 for details.
"""
return self in IPv6Network('ff00::/8')
@property
def is_reserved(self):
"""Test if the address is otherwise IETF reserved.
Returns:
A boolean, True if the address is within one of the
reserved IPv6 Network ranges.
"""
return (self in IPv6Network('::/8') or
self in IPv6Network('100::/8') or
self in IPv6Network('200::/7') or
self in IPv6Network('400::/6') or
self in IPv6Network('800::/5') or
self in IPv6Network('1000::/4') or
self in IPv6Network('4000::/3') or
self in IPv6Network('6000::/3') or
self in IPv6Network('8000::/3') or
self in IPv6Network('A000::/3') or
self in IPv6Network('C000::/3') or
self in IPv6Network('E000::/4') or
self in IPv6Network('F000::/5') or
self in IPv6Network('F800::/6') or
self in IPv6Network('FE00::/9'))
@property
def is_unspecified(self):
"""Test if the address is unspecified.
Returns:
A boolean, True if this is the unspecified address as defined in
RFC 2373 2.5.2.
"""
return self._ip == 0 and getattr(self, '_prefixlen', 128) == 128
@property
def is_loopback(self):
"""Test if the address is a loopback address.
Returns:
A boolean, True if the address is a loopback address as defined in
RFC 2373 2.5.3.
"""
return self._ip == 1 and getattr(self, '_prefixlen', 128) == 128
@property
def is_link_local(self):
"""Test if the address is reserved for link-local.
Returns:
A boolean, True if the address is reserved per RFC 4291.
"""
return self in IPv6Network('fe80::/10')
@property
def is_site_local(self):
"""Test if the address is reserved for site-local.
Note that the site-local address space has been deprecated by RFC 3879.
Use is_private to test if this address is in the space of unique local
addresses as defined by RFC 4193.
Returns:
A boolean, True if the address is reserved per RFC 3513 2.5.6.
"""
return self in IPv6Network('fec0::/10')
@property
def is_private(self):
"""Test if this address is allocated for private networks.
Returns:
A boolean, True if the address is reserved per RFC 4193.
"""
return self in IPv6Network('fc00::/7')
@property
def ipv4_mapped(self):
"""Return the IPv4 mapped address.
Returns:
If the IPv6 address is a v4 mapped address, return the
IPv4 mapped address. Return None otherwise.
"""
if (self._ip >> 32) != 0xFFFF:
return None
return IPv4Address(self._ip & 0xFFFFFFFF)
@property
def teredo(self):
"""Tuple of embedded teredo IPs.
Returns:
Tuple of the (server, client) IPs or None if the address
doesn't appear to be a teredo address (doesn't start with
2001::/32)
"""
if (self._ip >> 96) != 0x20010000:
return None
return (IPv4Address((self._ip >> 64) & 0xFFFFFFFF),
IPv4Address(~self._ip & 0xFFFFFFFF))
@property
def sixtofour(self):
"""Return the IPv4 6to4 embedded address.
Returns:
The IPv4 6to4-embedded address if present or None if the
address doesn't appear to contain a 6to4 embedded address.
"""
if (self._ip >> 112) != 0x2002:
return None
return IPv4Address((self._ip >> 80) & 0xFFFFFFFF)
class IPv6Address(_BaseV6, _BaseIP):
"""Represent and manipulate single IPv6 Addresses.
"""
def __init__(self, address):
"""Instantiate a new IPv6 address object.
Args:
address: A string or integer representing the IP
Additionally, an integer can be passed, so
IPv6Address('2001:4860::') ==
IPv6Address(42541956101370907050197289607612071936L).
or, more generally
IPv6Address(IPv6Address('2001:4860::')._ip) ==
IPv6Address('2001:4860::')
Raises:
AddressValueError: If address isn't a valid IPv6 address.
"""
_BaseIP.__init__(self, address)
_BaseV6.__init__(self, address)
# Efficient constructor from integer.
if isinstance(address, (int, long)):
self._ip = address
if address < 0 or address > self._ALL_ONES:
raise AddressValueError(address)
return
# Constructing from a packed address
if _compat_has_real_bytes:
if isinstance(address, bytes) and len(address) == 16:
tmp = struct.unpack('!QQ', address)
self._ip = (tmp[0] << 64) | tmp[1]
return
# Assume input argument to be string or any object representation
# which converts into a formatted IP string.
addr_str = str(address)
if not addr_str:
raise AddressValueError('')
self._ip = self._ip_int_from_string(addr_str)
class IPv6Network(_BaseV6, _BaseNet):
"""This class represents and manipulates 128-bit IPv6 networks.
Attributes: [examples for IPv6('2001:658:22A:CAFE:200::1/64')]
.ip: IPv6Address('2001:658:22a:cafe:200::1')
.network: IPv6Address('2001:658:22a:cafe::')
.hostmask: IPv6Address('::ffff:ffff:ffff:ffff')
.broadcast: IPv6Address('2001:658:22a:cafe:ffff:ffff:ffff:ffff')
.netmask: IPv6Address('ffff:ffff:ffff:ffff::')
.prefixlen: 64
"""
def __init__(self, address, strict=False):
"""Instantiate a new IPv6 Network object.
Args:
address: A string or integer representing the IPv6 network or the IP
and prefix/netmask.
'2001:4860::/128'
'2001:4860:0000:0000:0000:0000:0000:0000/128'
'2001:4860::'
are all functionally the same in IPv6. That is to say,
failing to provide a subnetmask will create an object with
a mask of /128.
Additionally, an integer can be passed, so
IPv6Network('2001:4860::') ==
IPv6Network(42541956101370907050197289607612071936L).
or, more generally
IPv6Network(IPv6Network('2001:4860::')._ip) ==
IPv6Network('2001:4860::')
strict: A boolean. If true, ensure that we have been passed
A true network address, eg, 192.168.1.0/24 and not an
IP address on a network, eg, 192.168.1.1/24.
Raises:
AddressValueError: If address isn't a valid IPv6 address.
NetmaskValueError: If the netmask isn't valid for
an IPv6 address.
ValueError: If strict was True and a network address was not
supplied.
"""
_BaseNet.__init__(self, address)
_BaseV6.__init__(self, address)
# Efficient constructor from integer.
if isinstance(address, (int, long)):
self._ip = address
self.ip = IPv6Address(self._ip)
self._prefixlen = self._max_prefixlen
self.netmask = IPv6Address(self._ALL_ONES)
if address < 0 or address > self._ALL_ONES:
raise AddressValueError(address)
return
# Constructing from a packed address
if _compat_has_real_bytes:
if isinstance(address, bytes) and len(address) == 16:
tmp = struct.unpack('!QQ', address)
self._ip = (tmp[0] << 64) | tmp[1]
self.ip = IPv6Address(self._ip)
self._prefixlen = self._max_prefixlen
self.netmask = IPv6Address(self._ALL_ONES)
return
# Assume input argument to be string or any object representation
# which converts into a formatted IP prefix string.
addr = str(address).split('/')
if len(addr) > 2:
raise AddressValueError(address)
self._ip = self._ip_int_from_string(addr[0])
self.ip = IPv6Address(self._ip)
if len(addr) == 2:
if self._is_valid_netmask(addr[1]):
self._prefixlen = int(addr[1])
else:
raise NetmaskValueError(addr[1])
else:
self._prefixlen = self._max_prefixlen
self.netmask = IPv6Address(self._ip_int_from_prefix(self._prefixlen))
if strict:
if self.ip != self.network:
raise ValueError('%s has host bits set' %
self.ip)
def _is_valid_netmask(self, prefixlen):
"""Verify that the netmask/prefixlen is valid.
Args:
prefixlen: A string, the netmask in prefix length format.
Returns:
A boolean, True if the prefix represents a valid IPv6
netmask.
"""
try:
prefixlen = int(prefixlen)
except ValueError:
return False
return 0 <= prefixlen <= self._max_prefixlen
@property
def with_netmask(self):
return self.with_prefixlen