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1# Copyright 2007 Google Inc.
2# Licensed to PSF under a Contributor Agreement.
3
4"""A fast, lightweight IPv4/IPv6 manipulation library in Python.
5
6This library is used to create/poke/manipulate IPv4 and IPv6 addresses
7and networks.
8
9"""
10
11from __future__ import unicode_literals
12
13
14import itertools
15import struct
16
17__version__ = '1.0.19'
18
19# Compatibility functions
20_compat_int_types = (int,)
21try:
22 _compat_int_types = (int, long)
23except NameError:
24 pass
25try:
26 _compat_str = unicode
27except NameError:
28 _compat_str = str
29 assert bytes != str
30if b'\0'[0] == 0: # Python 3 semantics
31 def _compat_bytes_to_byte_vals(byt):
32 return byt
33else:
34 def _compat_bytes_to_byte_vals(byt):
35 return [struct.unpack(b'!B', b)[0] for b in byt]
36try:
37 _compat_int_from_byte_vals = int.from_bytes
38except AttributeError:
39 def _compat_int_from_byte_vals(bytvals, endianess):
40 assert endianess == 'big'
41 res = 0
42 for bv in bytvals:
43 assert isinstance(bv, _compat_int_types)
44 res = (res << 8) + bv
45 return res
46
47
48def _compat_to_bytes(intval, length, endianess):
49 assert isinstance(intval, _compat_int_types)
50 assert endianess == 'big'
51 if length == 4:
52 if intval < 0 or intval >= 2 ** 32:
53 raise struct.error("integer out of range for 'I' format code")
54 return struct.pack(b'!I', intval)
55 elif length == 16:
56 if intval < 0 or intval >= 2 ** 128:
57 raise struct.error("integer out of range for 'QQ' format code")
58 return struct.pack(b'!QQ', intval >> 64, intval & 0xffffffffffffffff)
59 else:
60 raise NotImplementedError()
61
62
63if hasattr(int, 'bit_length'):
64 # Not int.bit_length , since that won't work in 2.7 where long exists
65 def _compat_bit_length(i):
66 return i.bit_length()
67else:
68 def _compat_bit_length(i):
69 for res in itertools.count():
70 if i >> res == 0:
71 return res
72
73
74def _compat_range(start, end, step=1):
75 assert step > 0
76 i = start
77 while i < end:
78 yield i
79 i += step
80
81
82class _TotalOrderingMixin(object):
83 __slots__ = ()
84
85 # Helper that derives the other comparison operations from
86 # __lt__ and __eq__
87 # We avoid functools.total_ordering because it doesn't handle
88 # NotImplemented correctly yet (http://bugs.python.org/issue10042)
89 def __eq__(self, other):
90 raise NotImplementedError
91
92 def __ne__(self, other):
93 equal = self.__eq__(other)
94 if equal is NotImplemented:
95 return NotImplemented
96 return not equal
97
98 def __lt__(self, other):
99 raise NotImplementedError
100
101 def __le__(self, other):
102 less = self.__lt__(other)
103 if less is NotImplemented or not less:
104 return self.__eq__(other)
105 return less
106
107 def __gt__(self, other):
108 less = self.__lt__(other)
109 if less is NotImplemented:
110 return NotImplemented
111 equal = self.__eq__(other)
112 if equal is NotImplemented:
113 return NotImplemented
114 return not (less or equal)
115
116 def __ge__(self, other):
117 less = self.__lt__(other)
118 if less is NotImplemented:
119 return NotImplemented
120 return not less
121
122
123IPV4LENGTH = 32
124IPV6LENGTH = 128
125
126
127class AddressValueError(ValueError):
128 """A Value Error related to the address."""
129
130
131class NetmaskValueError(ValueError):
132 """A Value Error related to the netmask."""
133
134
135def ip_address(address):
136 """Take an IP string/int and return an object of the correct type.
137
138 Args:
139 address: A string or integer, the IP address. Either IPv4 or
140 IPv6 addresses may be supplied; integers less than 2**32 will
141 be considered to be IPv4 by default.
142
143 Returns:
144 An IPv4Address or IPv6Address object.
145
146 Raises:
147 ValueError: if the *address* passed isn't either a v4 or a v6
148 address
149
150 """
151 try:
152 return IPv4Address(address)
153 except (AddressValueError, NetmaskValueError):
154 pass
155
156 try:
157 return IPv6Address(address)
158 except (AddressValueError, NetmaskValueError):
159 pass
160
161 if isinstance(address, bytes):
162 raise AddressValueError(
163 '%r does not appear to be an IPv4 or IPv6 address. '
164 'Did you pass in a bytes (str in Python 2) instead of'
165 ' a unicode object?' % address)
166
167 raise ValueError('%r does not appear to be an IPv4 or IPv6 address' %
168 address)
169
170
171def ip_network(address, strict=True):
172 """Take an IP string/int and return an object of the correct type.
173
174 Args:
175 address: A string or integer, the IP network. Either IPv4 or
176 IPv6 networks may be supplied; integers less than 2**32 will
177 be considered to be IPv4 by default.
178
179 Returns:
180 An IPv4Network or IPv6Network object.
181
182 Raises:
183 ValueError: if the string passed isn't either a v4 or a v6
184 address. Or if the network has host bits set.
185
186 """
187 try:
188 return IPv4Network(address, strict)
189 except (AddressValueError, NetmaskValueError):
190 pass
191
192 try:
193 return IPv6Network(address, strict)
194 except (AddressValueError, NetmaskValueError):
195 pass
196
197 if isinstance(address, bytes):
198 raise AddressValueError(
199 '%r does not appear to be an IPv4 or IPv6 network. '
200 'Did you pass in a bytes (str in Python 2) instead of'
201 ' a unicode object?' % address)
202
203 raise ValueError('%r does not appear to be an IPv4 or IPv6 network' %
204 address)
205
206
207def ip_interface(address):
208 """Take an IP string/int and return an object of the correct type.
209
210 Args:
211 address: A string or integer, the IP address. Either IPv4 or
212 IPv6 addresses may be supplied; integers less than 2**32 will
213 be considered to be IPv4 by default.
214
215 Returns:
216 An IPv4Interface or IPv6Interface object.
217
218 Raises:
219 ValueError: if the string passed isn't either a v4 or a v6
220 address.
221
222 Notes:
223 The IPv?Interface classes describe an Address on a particular
224 Network, so they're basically a combination of both the Address
225 and Network classes.
226
227 """
228 try:
229 return IPv4Interface(address)
230 except (AddressValueError, NetmaskValueError):
231 pass
232
233 try:
234 return IPv6Interface(address)
235 except (AddressValueError, NetmaskValueError):
236 pass
237
238 raise ValueError('%r does not appear to be an IPv4 or IPv6 interface' %
239 address)
240
241
242def v4_int_to_packed(address):
243 """Represent an address as 4 packed bytes in network (big-endian) order.
244
245 Args:
246 address: An integer representation of an IPv4 IP address.
247
248 Returns:
249 The integer address packed as 4 bytes in network (big-endian) order.
250
251 Raises:
252 ValueError: If the integer is negative or too large to be an
253 IPv4 IP address.
254
255 """
256 try:
257 return _compat_to_bytes(address, 4, 'big')
258 except (struct.error, OverflowError):
259 raise ValueError("Address negative or too large for IPv4")
260
261
262def v6_int_to_packed(address):
263 """Represent an address as 16 packed bytes in network (big-endian) order.
264
265 Args:
266 address: An integer representation of an IPv6 IP address.
267
268 Returns:
269 The integer address packed as 16 bytes in network (big-endian) order.
270
271 """
272 try:
273 return _compat_to_bytes(address, 16, 'big')
274 except (struct.error, OverflowError):
275 raise ValueError("Address negative or too large for IPv6")
276
277
278def _split_optional_netmask(address):
279 """Helper to split the netmask and raise AddressValueError if needed"""
280 addr = _compat_str(address).split('/')
281 if len(addr) > 2:
282 raise AddressValueError("Only one '/' permitted in %r" % address)
283 return addr
284
285
286def _find_address_range(addresses):
287 """Find a sequence of sorted deduplicated IPv#Address.
288
289 Args:
290 addresses: a list of IPv#Address objects.
291
292 Yields:
293 A tuple containing the first and last IP addresses in the sequence.
294
295 """
296 it = iter(addresses)
297 first = last = next(it)
298 for ip in it:
299 if ip._ip != last._ip + 1:
300 yield first, last
301 first = ip
302 last = ip
303 yield first, last
304
305
306def _count_righthand_zero_bits(number, bits):
307 """Count the number of zero bits on the right hand side.
308
309 Args:
310 number: an integer.
311 bits: maximum number of bits to count.
312
313 Returns:
314 The number of zero bits on the right hand side of the number.
315
316 """
317 if number == 0:
318 return bits
319 return min(bits, _compat_bit_length(~number & (number - 1)))
320
321
322def summarize_address_range(first, last):
323 """Summarize a network range given the first and last IP addresses.
324
325 Example:
326 >>> list(summarize_address_range(IPv4Address('192.0.2.0'),
327 ... IPv4Address('192.0.2.130')))
328 ... #doctest: +NORMALIZE_WHITESPACE
329 [IPv4Network('192.0.2.0/25'), IPv4Network('192.0.2.128/31'),
330 IPv4Network('192.0.2.130/32')]
331
332 Args:
333 first: the first IPv4Address or IPv6Address in the range.
334 last: the last IPv4Address or IPv6Address in the range.
335
336 Returns:
337 An iterator of the summarized IPv(4|6) network objects.
338
339 Raise:
340 TypeError:
341 If the first and last objects are not IP addresses.
342 If the first and last objects are not the same version.
343 ValueError:
344 If the last object is not greater than the first.
345 If the version of the first address is not 4 or 6.
346
347 """
348 if (not (isinstance(first, _BaseAddress) and
349 isinstance(last, _BaseAddress))):
350 raise TypeError('first and last must be IP addresses, not networks')
351 if first.version != last.version:
352 raise TypeError("%s and %s are not of the same version" % (
353 first, last))
354 if first > last:
355 raise ValueError('last IP address must be greater than first')
356
357 if first.version == 4:
358 ip = IPv4Network
359 elif first.version == 6:
360 ip = IPv6Network
361 else:
362 raise ValueError('unknown IP version')
363
364 ip_bits = first._max_prefixlen
365 first_int = first._ip
366 last_int = last._ip
367 while first_int <= last_int:
368 nbits = min(_count_righthand_zero_bits(first_int, ip_bits),
369 _compat_bit_length(last_int - first_int + 1) - 1)
370 net = ip((first_int, ip_bits - nbits))
371 yield net
372 first_int += 1 << nbits
373 if first_int - 1 == ip._ALL_ONES:
374 break
375
376
377def _collapse_addresses_internal(addresses):
378 """Loops through the addresses, collapsing concurrent netblocks.
379
380 Example:
381
382 ip1 = IPv4Network('192.0.2.0/26')
383 ip2 = IPv4Network('192.0.2.64/26')
384 ip3 = IPv4Network('192.0.2.128/26')
385 ip4 = IPv4Network('192.0.2.192/26')
386
387 _collapse_addresses_internal([ip1, ip2, ip3, ip4]) ->
388 [IPv4Network('192.0.2.0/24')]
389
390 This shouldn't be called directly; it is called via
391 collapse_addresses([]).
392
393 Args:
394 addresses: A list of IPv4Network's or IPv6Network's
395
396 Returns:
397 A list of IPv4Network's or IPv6Network's depending on what we were
398 passed.
399
400 """
401 # First merge
402 to_merge = list(addresses)
403 subnets = {}
404 while to_merge:
405 net = to_merge.pop()
406 supernet = net.supernet()
407 existing = subnets.get(supernet)
408 if existing is None:
409 subnets[supernet] = net
410 elif existing != net:
411 # Merge consecutive subnets
412 del subnets[supernet]
413 to_merge.append(supernet)
414 # Then iterate over resulting networks, skipping subsumed subnets
415 last = None
416 for net in sorted(subnets.values()):
417 if last is not None:
418 # Since they are sorted,
419 # last.network_address <= net.network_address is a given.
420 if last.broadcast_address >= net.broadcast_address:
421 continue
422 yield net
423 last = net
424
425
426def collapse_addresses(addresses):
427 """Collapse a list of IP objects.
428
429 Example:
430 collapse_addresses([IPv4Network('192.0.2.0/25'),
431 IPv4Network('192.0.2.128/25')]) ->
432 [IPv4Network('192.0.2.0/24')]
433
434 Args:
435 addresses: An iterator of IPv4Network or IPv6Network objects.
436
437 Returns:
438 An iterator of the collapsed IPv(4|6)Network objects.
439
440 Raises:
441 TypeError: If passed a list of mixed version objects.
442
443 """
444 addrs = []
445 ips = []
446 nets = []
447
448 # split IP addresses and networks
449 for ip in addresses:
450 if isinstance(ip, _BaseAddress):
451 if ips and ips[-1]._version != ip._version:
452 raise TypeError("%s and %s are not of the same version" % (
453 ip, ips[-1]))
454 ips.append(ip)
455 elif ip._prefixlen == ip._max_prefixlen:
456 if ips and ips[-1]._version != ip._version:
457 raise TypeError("%s and %s are not of the same version" % (
458 ip, ips[-1]))
459 try:
460 ips.append(ip.ip)
461 except AttributeError:
462 ips.append(ip.network_address)
463 else:
464 if nets and nets[-1]._version != ip._version:
465 raise TypeError("%s and %s are not of the same version" % (
466 ip, nets[-1]))
467 nets.append(ip)
468
469 # sort and dedup
470 ips = sorted(set(ips))
471
472 # find consecutive address ranges in the sorted sequence and summarize them
473 if ips:
474 for first, last in _find_address_range(ips):
475 addrs.extend(summarize_address_range(first, last))
476
477 return _collapse_addresses_internal(addrs + nets)
478
479
480def get_mixed_type_key(obj):
481 """Return a key suitable for sorting between networks and addresses.
482
483 Address and Network objects are not sortable by default; they're
484 fundamentally different so the expression
485
486 IPv4Address('192.0.2.0') <= IPv4Network('192.0.2.0/24')
487
488 doesn't make any sense. There are some times however, where you may wish
489 to have ipaddress sort these for you anyway. If you need to do this, you
490 can use this function as the key= argument to sorted().
491
492 Args:
493 obj: either a Network or Address object.
494 Returns:
495 appropriate key.
496
497 """
498 if isinstance(obj, _BaseNetwork):
499 return obj._get_networks_key()
500 elif isinstance(obj, _BaseAddress):
501 return obj._get_address_key()
502 return NotImplemented
503
504
505class _IPAddressBase(_TotalOrderingMixin):
506
507 """The mother class."""
508
509 __slots__ = ()
510
511 @property
512 def exploded(self):
513 """Return the longhand version of the IP address as a string."""
514 return self._explode_shorthand_ip_string()
515
516 @property
517 def compressed(self):
518 """Return the shorthand version of the IP address as a string."""
519 return _compat_str(self)
520
521 @property
522 def reverse_pointer(self):
523 """The name of the reverse DNS pointer for the IP address, e.g.:
524 >>> ipaddress.ip_address("127.0.0.1").reverse_pointer
525 '1.0.0.127.in-addr.arpa'
526 >>> ipaddress.ip_address("2001:db8::1").reverse_pointer
527 '1.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.8.b.d.0.1.0.0.2.ip6.arpa'
528
529 """
530 return self._reverse_pointer()
531
532 @property
533 def version(self):
534 msg = '%200s has no version specified' % (type(self),)
535 raise NotImplementedError(msg)
536
537 def _check_int_address(self, address):
538 if address < 0:
539 msg = "%d (< 0) is not permitted as an IPv%d address"
540 raise AddressValueError(msg % (address, self._version))
541 if address > self._ALL_ONES:
542 msg = "%d (>= 2**%d) is not permitted as an IPv%d address"
543 raise AddressValueError(msg % (address, self._max_prefixlen,
544 self._version))
545
546 def _check_packed_address(self, address, expected_len):
547 address_len = len(address)
548 if address_len != expected_len:
549 msg = (
550 '%r (len %d != %d) is not permitted as an IPv%d address. '
551 'Did you pass in a bytes (str in Python 2) instead of'
552 ' a unicode object?')
553 raise AddressValueError(msg % (address, address_len,
554 expected_len, self._version))
555
556 @classmethod
557 def _ip_int_from_prefix(cls, prefixlen):
558 """Turn the prefix length into a bitwise netmask
559
560 Args:
561 prefixlen: An integer, the prefix length.
562
563 Returns:
564 An integer.
565
566 """
567 return cls._ALL_ONES ^ (cls._ALL_ONES >> prefixlen)
568
569 @classmethod
570 def _prefix_from_ip_int(cls, ip_int):
571 """Return prefix length from the bitwise netmask.
572
573 Args:
574 ip_int: An integer, the netmask in expanded bitwise format
575
576 Returns:
577 An integer, the prefix length.
578
579 Raises:
580 ValueError: If the input intermingles zeroes & ones
581 """
582 trailing_zeroes = _count_righthand_zero_bits(ip_int,
583 cls._max_prefixlen)
584 prefixlen = cls._max_prefixlen - trailing_zeroes
585 leading_ones = ip_int >> trailing_zeroes
586 all_ones = (1 << prefixlen) - 1
587 if leading_ones != all_ones:
588 byteslen = cls._max_prefixlen // 8
589 details = _compat_to_bytes(ip_int, byteslen, 'big')
590 msg = 'Netmask pattern %r mixes zeroes & ones'
591 raise ValueError(msg % details)
592 return prefixlen
593
594 @classmethod
595 def _report_invalid_netmask(cls, netmask_str):
596 msg = '%r is not a valid netmask' % netmask_str
597 raise NetmaskValueError(msg)
598
599 @classmethod
600 def _prefix_from_prefix_string(cls, prefixlen_str):
601 """Return prefix length from a numeric string
602
603 Args:
604 prefixlen_str: The string to be converted
605
606 Returns:
607 An integer, the prefix length.
608
609 Raises:
610 NetmaskValueError: If the input is not a valid netmask
611 """
612 # int allows a leading +/- as well as surrounding whitespace,
613 # so we ensure that isn't the case
614 if not _BaseV4._DECIMAL_DIGITS.issuperset(prefixlen_str):
615 cls._report_invalid_netmask(prefixlen_str)
616 try:
617 prefixlen = int(prefixlen_str)
618 except ValueError:
619 cls._report_invalid_netmask(prefixlen_str)
620 if not (0 <= prefixlen <= cls._max_prefixlen):
621 cls._report_invalid_netmask(prefixlen_str)
622 return prefixlen
623
624 @classmethod
625 def _prefix_from_ip_string(cls, ip_str):
626 """Turn a netmask/hostmask string into a prefix length
627
628 Args:
629 ip_str: The netmask/hostmask to be converted
630
631 Returns:
632 An integer, the prefix length.
633
634 Raises:
635 NetmaskValueError: If the input is not a valid netmask/hostmask
636 """
637 # Parse the netmask/hostmask like an IP address.
638 try:
639 ip_int = cls._ip_int_from_string(ip_str)
640 except AddressValueError:
641 cls._report_invalid_netmask(ip_str)
642
643 # Try matching a netmask (this would be /1*0*/ as a bitwise regexp).
644 # Note that the two ambiguous cases (all-ones and all-zeroes) are
645 # treated as netmasks.
646 try:
647 return cls._prefix_from_ip_int(ip_int)
648 except ValueError:
649 pass
650
651 # Invert the bits, and try matching a /0+1+/ hostmask instead.
652 ip_int ^= cls._ALL_ONES
653 try:
654 return cls._prefix_from_ip_int(ip_int)
655 except ValueError:
656 cls._report_invalid_netmask(ip_str)
657
658 def __reduce__(self):
659 return self.__class__, (_compat_str(self),)
660
661
662class _BaseAddress(_IPAddressBase):
663
664 """A generic IP object.
665
666 This IP class contains the version independent methods which are
667 used by single IP addresses.
668 """
669
670 __slots__ = ()
671
672 def __int__(self):
673 return self._ip
674
675 def __eq__(self, other):
676 try:
677 return (self._ip == other._ip and
678 self._version == other._version)
679 except AttributeError:
680 return NotImplemented
681
682 def __lt__(self, other):
683 if not isinstance(other, _IPAddressBase):
684 return NotImplemented
685 if not isinstance(other, _BaseAddress):
686 raise TypeError('%s and %s are not of the same type' % (
687 self, other))
688 if self._version != other._version:
689 raise TypeError('%s and %s are not of the same version' % (
690 self, other))
691 if self._ip != other._ip:
692 return self._ip < other._ip
693 return False
694
695 # Shorthand for Integer addition and subtraction. This is not
696 # meant to ever support addition/subtraction of addresses.
697 def __add__(self, other):
698 if not isinstance(other, _compat_int_types):
699 return NotImplemented
700 return self.__class__(int(self) + other)
701
702 def __sub__(self, other):
703 if not isinstance(other, _compat_int_types):
704 return NotImplemented
705 return self.__class__(int(self) - other)
706
707 def __repr__(self):
708 return '%s(%r)' % (self.__class__.__name__, _compat_str(self))
709
710 def __str__(self):
711 return _compat_str(self._string_from_ip_int(self._ip))
712
713 def __hash__(self):
714 return hash(hex(int(self._ip)))
715
716 def _get_address_key(self):
717 return (self._version, self)
718
719 def __reduce__(self):
720 return self.__class__, (self._ip,)
721
722
723class _BaseNetwork(_IPAddressBase):
724
725 """A generic IP network object.
726
727 This IP class contains the version independent methods which are
728 used by networks.
729
730 """
731 def __init__(self, address):
732 self._cache = {}
733
734 def __repr__(self):
735 return '%s(%r)' % (self.__class__.__name__, _compat_str(self))
736
737 def __str__(self):
738 return '%s/%d' % (self.network_address, self.prefixlen)
739
740 def hosts(self):
741 """Generate Iterator over usable hosts in a network.
742
743 This is like __iter__ except it doesn't return the network
744 or broadcast addresses.
745
746 """
747 network = int(self.network_address)
748 broadcast = int(self.broadcast_address)
749 for x in _compat_range(network + 1, broadcast):
750 yield self._address_class(x)
751
752 def __iter__(self):
753 network = int(self.network_address)
754 broadcast = int(self.broadcast_address)
755 for x in _compat_range(network, broadcast + 1):
756 yield self._address_class(x)
757
758 def __getitem__(self, n):
759 network = int(self.network_address)
760 broadcast = int(self.broadcast_address)
761 if n >= 0:
762 if network + n > broadcast:
763 raise IndexError('address out of range')
764 return self._address_class(network + n)
765 else:
766 n += 1
767 if broadcast + n < network:
768 raise IndexError('address out of range')
769 return self._address_class(broadcast + n)
770
771 def __lt__(self, other):
772 if not isinstance(other, _IPAddressBase):
773 return NotImplemented
774 if not isinstance(other, _BaseNetwork):
775 raise TypeError('%s and %s are not of the same type' % (
776 self, other))
777 if self._version != other._version:
778 raise TypeError('%s and %s are not of the same version' % (
779 self, other))
780 if self.network_address != other.network_address:
781 return self.network_address < other.network_address
782 if self.netmask != other.netmask:
783 return self.netmask < other.netmask
784 return False
785
786 def __eq__(self, other):
787 try:
788 return (self._version == other._version and
789 self.network_address == other.network_address and
790 int(self.netmask) == int(other.netmask))
791 except AttributeError:
792 return NotImplemented
793
794 def __hash__(self):
795 return hash(int(self.network_address) ^ int(self.netmask))
796
797 def __contains__(self, other):
798 # always false if one is v4 and the other is v6.
799 if self._version != other._version:
800 return False
801 # dealing with another network.
802 if isinstance(other, _BaseNetwork):
803 return False
804 # dealing with another address
805 else:
806 # address
807 return (int(self.network_address) <= int(other._ip) <=
808 int(self.broadcast_address))
809
810 def overlaps(self, other):
811 """Tell if self is partly contained in other."""
812 return self.network_address in other or (
813 self.broadcast_address in other or (
814 other.network_address in self or (
815 other.broadcast_address in self)))
816
817 @property
818 def broadcast_address(self):
819 x = self._cache.get('broadcast_address')
820 if x is None:
821 x = self._address_class(int(self.network_address) |
822 int(self.hostmask))
823 self._cache['broadcast_address'] = x
824 return x
825
826 @property
827 def hostmask(self):
828 x = self._cache.get('hostmask')
829 if x is None:
830 x = self._address_class(int(self.netmask) ^ self._ALL_ONES)
831 self._cache['hostmask'] = x
832 return x
833
834 @property
835 def with_prefixlen(self):
836 return '%s/%d' % (self.network_address, self._prefixlen)
837
838 @property
839 def with_netmask(self):
840 return '%s/%s' % (self.network_address, self.netmask)
841
842 @property
843 def with_hostmask(self):
844 return '%s/%s' % (self.network_address, self.hostmask)
845
846 @property
847 def num_addresses(self):
848 """Number of hosts in the current subnet."""
849 return int(self.broadcast_address) - int(self.network_address) + 1
850
851 @property
852 def _address_class(self):
853 # Returning bare address objects (rather than interfaces) allows for
854 # more consistent behaviour across the network address, broadcast
855 # address and individual host addresses.
856 msg = '%200s has no associated address class' % (type(self),)
857 raise NotImplementedError(msg)
858
859 @property
860 def prefixlen(self):
861 return self._prefixlen
862
863 def address_exclude(self, other):
864 """Remove an address from a larger block.
865
866 For example:
867
868 addr1 = ip_network('192.0.2.0/28')
869 addr2 = ip_network('192.0.2.1/32')
870 list(addr1.address_exclude(addr2)) =
871 [IPv4Network('192.0.2.0/32'), IPv4Network('192.0.2.2/31'),
872 IPv4Network('192.0.2.4/30'), IPv4Network('192.0.2.8/29')]
873
874 or IPv6:
875
876 addr1 = ip_network('2001:db8::1/32')
877 addr2 = ip_network('2001:db8::1/128')
878 list(addr1.address_exclude(addr2)) =
879 [ip_network('2001:db8::1/128'),
880 ip_network('2001:db8::2/127'),
881 ip_network('2001:db8::4/126'),
882 ip_network('2001:db8::8/125'),
883 ...
884 ip_network('2001:db8:8000::/33')]
885
886 Args:
887 other: An IPv4Network or IPv6Network object of the same type.
888
889 Returns:
890 An iterator of the IPv(4|6)Network objects which is self
891 minus other.
892
893 Raises:
894 TypeError: If self and other are of differing address
895 versions, or if other is not a network object.
896 ValueError: If other is not completely contained by self.
897
898 """
899 if not self._version == other._version:
900 raise TypeError("%s and %s are not of the same version" % (
901 self, other))
902
903 if not isinstance(other, _BaseNetwork):
904 raise TypeError("%s is not a network object" % other)
905
906 if not other.subnet_of(self):
907 raise ValueError('%s not contained in %s' % (other, self))
908 if other == self:
909 return
910
911 # Make sure we're comparing the network of other.
912 other = other.__class__('%s/%s' % (other.network_address,
913 other.prefixlen))
914
915 s1, s2 = self.subnets()
916 while s1 != other and s2 != other:
917 if other.subnet_of(s1):
918 yield s2
919 s1, s2 = s1.subnets()
920 elif other.subnet_of(s2):
921 yield s1
922 s1, s2 = s2.subnets()
923 else:
924 # If we got here, there's a bug somewhere.
925 raise AssertionError('Error performing exclusion: '
926 's1: %s s2: %s other: %s' %
927 (s1, s2, other))
928 if s1 == other:
929 yield s2
930 elif s2 == other:
931 yield s1
932 else:
933 # If we got here, there's a bug somewhere.
934 raise AssertionError('Error performing exclusion: '
935 's1: %s s2: %s other: %s' %
936 (s1, s2, other))
937
938 def compare_networks(self, other):
939 """Compare two IP objects.
940
941 This is only concerned about the comparison of the integer
942 representation of the network addresses. This means that the
943 host bits aren't considered at all in this method. If you want
944 to compare host bits, you can easily enough do a
945 'HostA._ip < HostB._ip'
946
947 Args:
948 other: An IP object.
949
950 Returns:
951 If the IP versions of self and other are the same, returns:
952
953 -1 if self < other:
954 eg: IPv4Network('192.0.2.0/25') < IPv4Network('192.0.2.128/25')
955 IPv6Network('2001:db8::1000/124') <
956 IPv6Network('2001:db8::2000/124')
957 0 if self == other
958 eg: IPv4Network('192.0.2.0/24') == IPv4Network('192.0.2.0/24')
959 IPv6Network('2001:db8::1000/124') ==
960 IPv6Network('2001:db8::1000/124')
961 1 if self > other
962 eg: IPv4Network('192.0.2.128/25') > IPv4Network('192.0.2.0/25')
963 IPv6Network('2001:db8::2000/124') >
964 IPv6Network('2001:db8::1000/124')
965
966 Raises:
967 TypeError if the IP versions are different.
968
969 """
970 # does this need to raise a ValueError?
971 if self._version != other._version:
972 raise TypeError('%s and %s are not of the same type' % (
973 self, other))
974 # self._version == other._version below here:
975 if self.network_address < other.network_address:
976 return -1
977 if self.network_address > other.network_address:
978 return 1
979 # self.network_address == other.network_address below here:
980 if self.netmask < other.netmask:
981 return -1
982 if self.netmask > other.netmask:
983 return 1
984 return 0
985
986 def _get_networks_key(self):
987 """Network-only key function.
988
989 Returns an object that identifies this address' network and
990 netmask. This function is a suitable "key" argument for sorted()
991 and list.sort().
992
993 """
994 return (self._version, self.network_address, self.netmask)
995
996 def subnets(self, prefixlen_diff=1, new_prefix=None):
997 """The subnets which join to make the current subnet.
998
999 In the case that self contains only one IP
1000 (self._prefixlen == 32 for IPv4 or self._prefixlen == 128
1001 for IPv6), yield an iterator with just ourself.
1002
1003 Args:
1004 prefixlen_diff: An integer, the amount the prefix length
1005 should be increased by. This should not be set if
1006 new_prefix is also set.
1007 new_prefix: The desired new prefix length. This must be a
1008 larger number (smaller prefix) than the existing prefix.
1009 This should not be set if prefixlen_diff is also set.
1010
1011 Returns:
1012 An iterator of IPv(4|6) objects.
1013
1014 Raises:
1015 ValueError: The prefixlen_diff is too small or too large.
1016 OR
1017 prefixlen_diff and new_prefix are both set or new_prefix
1018 is a smaller number than the current prefix (smaller
1019 number means a larger network)
1020
1021 """
1022 if self._prefixlen == self._max_prefixlen:
1023 yield self
1024 return
1025
1026 if new_prefix is not None:
1027 if new_prefix < self._prefixlen:
1028 raise ValueError('new prefix must be longer')
1029 if prefixlen_diff != 1:
1030 raise ValueError('cannot set prefixlen_diff and new_prefix')
1031 prefixlen_diff = new_prefix - self._prefixlen
1032
1033 if prefixlen_diff < 0:
1034 raise ValueError('prefix length diff must be > 0')
1035 new_prefixlen = self._prefixlen + prefixlen_diff
1036
1037 if new_prefixlen > self._max_prefixlen:
1038 raise ValueError(
1039 'prefix length diff %d is invalid for netblock %s' % (
1040 new_prefixlen, self))
1041
1042 start = int(self.network_address)
1043 end = int(self.broadcast_address) + 1
1044 step = (int(self.hostmask) + 1) >> prefixlen_diff
1045 for new_addr in _compat_range(start, end, step):
1046 current = self.__class__((new_addr, new_prefixlen))
1047 yield current
1048
1049 def supernet(self, prefixlen_diff=1, new_prefix=None):
1050 """The supernet containing the current network.
1051
1052 Args:
1053 prefixlen_diff: An integer, the amount the prefix length of
1054 the network should be decreased by. For example, given a
1055 /24 network and a prefixlen_diff of 3, a supernet with a
1056 /21 netmask is returned.
1057
1058 Returns:
1059 An IPv4 network object.
1060
1061 Raises:
1062 ValueError: If self.prefixlen - prefixlen_diff < 0. I.e., you have
1063 a negative prefix length.
1064 OR
1065 If prefixlen_diff and new_prefix are both set or new_prefix is a
1066 larger number than the current prefix (larger number means a
1067 smaller network)
1068
1069 """
1070 if self._prefixlen == 0:
1071 return self
1072
1073 if new_prefix is not None:
1074 if new_prefix > self._prefixlen:
1075 raise ValueError('new prefix must be shorter')
1076 if prefixlen_diff != 1:
1077 raise ValueError('cannot set prefixlen_diff and new_prefix')
1078 prefixlen_diff = self._prefixlen - new_prefix
1079
1080 new_prefixlen = self.prefixlen - prefixlen_diff
1081 if new_prefixlen < 0:
1082 raise ValueError(
1083 'current prefixlen is %d, cannot have a prefixlen_diff of %d' %
1084 (self.prefixlen, prefixlen_diff))
1085 return self.__class__((
1086 int(self.network_address) & (int(self.netmask) << prefixlen_diff),
1087 new_prefixlen))
1088
1089 @property
1090 def is_multicast(self):
1091 """Test if the address is reserved for multicast use.
1092
1093 Returns:
1094 A boolean, True if the address is a multicast address.
1095 See RFC 2373 2.7 for details.
1096
1097 """
1098 return (self.network_address.is_multicast and
1099 self.broadcast_address.is_multicast)
1100
1101 @staticmethod
1102 def _is_subnet_of(a, b):
1103 try:
1104 # Always false if one is v4 and the other is v6.
1105 if a._version != b._version:
1106 raise TypeError("%s and %s are not of the same version" (a, b))
1107 return (b.network_address <= a.network_address and
1108 b.broadcast_address >= a.broadcast_address)
1109 except AttributeError:
1110 raise TypeError("Unable to test subnet containment "
1111 "between %s and %s" % (a, b))
1112
1113 def subnet_of(self, other):
1114 """Return True if this network is a subnet of other."""
1115 return self._is_subnet_of(self, other)
1116
1117 def supernet_of(self, other):
1118 """Return True if this network is a supernet of other."""
1119 return self._is_subnet_of(other, self)
1120
1121 @property
1122 def is_reserved(self):
1123 """Test if the address is otherwise IETF reserved.
1124
1125 Returns:
1126 A boolean, True if the address is within one of the
1127 reserved IPv6 Network ranges.
1128
1129 """
1130 return (self.network_address.is_reserved and
1131 self.broadcast_address.is_reserved)
1132
1133 @property
1134 def is_link_local(self):
1135 """Test if the address is reserved for link-local.
1136
1137 Returns:
1138 A boolean, True if the address is reserved per RFC 4291.
1139
1140 """
1141 return (self.network_address.is_link_local and
1142 self.broadcast_address.is_link_local)
1143
1144 @property
1145 def is_private(self):
1146 """Test if this address is allocated for private networks.
1147
1148 Returns:
1149 A boolean, True if the address is reserved per
1150 iana-ipv4-special-registry or iana-ipv6-special-registry.
1151
1152 """
1153 return (self.network_address.is_private and
1154 self.broadcast_address.is_private)
1155
1156 @property
1157 def is_global(self):
1158 """Test if this address is allocated for public networks.
1159
1160 Returns:
1161 A boolean, True if the address is not reserved per
1162 iana-ipv4-special-registry or iana-ipv6-special-registry.
1163
1164 """
1165 return not self.is_private
1166
1167 @property
1168 def is_unspecified(self):
1169 """Test if the address is unspecified.
1170
1171 Returns:
1172 A boolean, True if this is the unspecified address as defined in
1173 RFC 2373 2.5.2.
1174
1175 """
1176 return (self.network_address.is_unspecified and
1177 self.broadcast_address.is_unspecified)
1178
1179 @property
1180 def is_loopback(self):
1181 """Test if the address is a loopback address.
1182
1183 Returns:
1184 A boolean, True if the address is a loopback address as defined in
1185 RFC 2373 2.5.3.
1186
1187 """
1188 return (self.network_address.is_loopback and
1189 self.broadcast_address.is_loopback)
1190
1191
1192class _BaseV4(object):
1193
1194 """Base IPv4 object.
1195
1196 The following methods are used by IPv4 objects in both single IP
1197 addresses and networks.
1198
1199 """
1200
1201 __slots__ = ()
1202 _version = 4
1203 # Equivalent to 255.255.255.255 or 32 bits of 1's.
1204 _ALL_ONES = (2 ** IPV4LENGTH) - 1
1205 _DECIMAL_DIGITS = frozenset('0123456789')
1206
1207 # the valid octets for host and netmasks. only useful for IPv4.
1208 _valid_mask_octets = frozenset([255, 254, 252, 248, 240, 224, 192, 128, 0])
1209
1210 _max_prefixlen = IPV4LENGTH
1211 # There are only a handful of valid v4 netmasks, so we cache them all
1212 # when constructed (see _make_netmask()).
1213 _netmask_cache = {}
1214
1215 def _explode_shorthand_ip_string(self):
1216 return _compat_str(self)
1217
1218 @classmethod
1219 def _make_netmask(cls, arg):
1220 """Make a (netmask, prefix_len) tuple from the given argument.
1221
1222 Argument can be:
1223 - an integer (the prefix length)
1224 - a string representing the prefix length (e.g. "24")
1225 - a string representing the prefix netmask (e.g. "255.255.255.0")
1226 """
1227 if arg not in cls._netmask_cache:
1228 if isinstance(arg, _compat_int_types):
1229 prefixlen = arg
1230 else:
1231 try:
1232 # Check for a netmask in prefix length form
1233 prefixlen = cls._prefix_from_prefix_string(arg)
1234 except NetmaskValueError:
1235 # Check for a netmask or hostmask in dotted-quad form.
1236 # This may raise NetmaskValueError.
1237 prefixlen = cls._prefix_from_ip_string(arg)
1238 netmask = IPv4Address(cls._ip_int_from_prefix(prefixlen))
1239 cls._netmask_cache[arg] = netmask, prefixlen
1240 return cls._netmask_cache[arg]
1241
1242 @classmethod
1243 def _ip_int_from_string(cls, ip_str):
1244 """Turn the given IP string into an integer for comparison.
1245
1246 Args:
1247 ip_str: A string, the IP ip_str.
1248
1249 Returns:
1250 The IP ip_str as an integer.
1251
1252 Raises:
1253 AddressValueError: if ip_str isn't a valid IPv4 Address.
1254
1255 """
1256 if not ip_str:
1257 raise AddressValueError('Address cannot be empty')
1258
1259 octets = ip_str.split('.')
1260 if len(octets) != 4:
1261 raise AddressValueError("Expected 4 octets in %r" % ip_str)
1262
1263 try:
1264 return _compat_int_from_byte_vals(
1265 map(cls._parse_octet, octets), 'big')
1266 except ValueError as exc:
1267 raise AddressValueError("%s in %r" % (exc, ip_str))
1268
1269 @classmethod
1270 def _parse_octet(cls, octet_str):
1271 """Convert a decimal octet into an integer.
1272
1273 Args:
1274 octet_str: A string, the number to parse.
1275
1276 Returns:
1277 The octet as an integer.
1278
1279 Raises:
1280 ValueError: if the octet isn't strictly a decimal from [0..255].
1281
1282 """
1283 if not octet_str:
1284 raise ValueError("Empty octet not permitted")
1285 # Whitelist the characters, since int() allows a lot of bizarre stuff.
1286 if not cls._DECIMAL_DIGITS.issuperset(octet_str):
1287 msg = "Only decimal digits permitted in %r"
1288 raise ValueError(msg % octet_str)
1289 # We do the length check second, since the invalid character error
1290 # is likely to be more informative for the user
1291 if len(octet_str) > 3:
1292 msg = "At most 3 characters permitted in %r"
1293 raise ValueError(msg % octet_str)
1294 # Convert to integer (we know digits are legal)
1295 octet_int = int(octet_str, 10)
1296 # Any octets that look like they *might* be written in octal,
1297 # and which don't look exactly the same in both octal and
1298 # decimal are rejected as ambiguous
1299 if octet_int > 7 and octet_str[0] == '0':
1300 msg = "Ambiguous (octal/decimal) value in %r not permitted"
1301 raise ValueError(msg % octet_str)
1302 if octet_int > 255:
1303 raise ValueError("Octet %d (> 255) not permitted" % octet_int)
1304 return octet_int
1305
1306 @classmethod
1307 def _string_from_ip_int(cls, ip_int):
1308 """Turns a 32-bit integer into dotted decimal notation.
1309
1310 Args:
1311 ip_int: An integer, the IP address.
1312
1313 Returns:
1314 The IP address as a string in dotted decimal notation.
1315
1316 """
1317 return '.'.join(_compat_str(struct.unpack(b'!B', b)[0]
1318 if isinstance(b, bytes)
1319 else b)
1320 for b in _compat_to_bytes(ip_int, 4, 'big'))
1321
1322 def _is_hostmask(self, ip_str):
1323 """Test if the IP string is a hostmask (rather than a netmask).
1324
1325 Args:
1326 ip_str: A string, the potential hostmask.
1327
1328 Returns:
1329 A boolean, True if the IP string is a hostmask.
1330
1331 """
1332 bits = ip_str.split('.')
1333 try:
1334 parts = [x for x in map(int, bits) if x in self._valid_mask_octets]
1335 except ValueError:
1336 return False
1337 if len(parts) != len(bits):
1338 return False
1339 if parts[0] < parts[-1]:
1340 return True
1341 return False
1342
1343 def _reverse_pointer(self):
1344 """Return the reverse DNS pointer name for the IPv4 address.
1345
1346 This implements the method described in RFC1035 3.5.
1347
1348 """
1349 reverse_octets = _compat_str(self).split('.')[::-1]
1350 return '.'.join(reverse_octets) + '.in-addr.arpa'
1351
1352 @property
1353 def max_prefixlen(self):
1354 return self._max_prefixlen
1355
1356 @property
1357 def version(self):
1358 return self._version
1359
1360
1361class IPv4Address(_BaseV4, _BaseAddress):
1362
1363 """Represent and manipulate single IPv4 Addresses."""
1364
1365 __slots__ = ('_ip', '__weakref__')
1366
1367 def __init__(self, address):
1368
1369 """
1370 Args:
1371 address: A string or integer representing the IP
1372
1373 Additionally, an integer can be passed, so
1374 IPv4Address('192.0.2.1') == IPv4Address(3221225985).
1375 or, more generally
1376 IPv4Address(int(IPv4Address('192.0.2.1'))) ==
1377 IPv4Address('192.0.2.1')
1378
1379 Raises:
1380 AddressValueError: If ipaddress isn't a valid IPv4 address.
1381
1382 """
1383 # Efficient constructor from integer.
1384 if isinstance(address, _compat_int_types):
1385 self._check_int_address(address)
1386 self._ip = address
1387 return
1388
1389 # Constructing from a packed address
1390 if isinstance(address, bytes):
1391 self._check_packed_address(address, 4)
1392 bvs = _compat_bytes_to_byte_vals(address)
1393 self._ip = _compat_int_from_byte_vals(bvs, 'big')
1394 return
1395
1396 # Assume input argument to be string or any object representation
1397 # which converts into a formatted IP string.
1398 addr_str = _compat_str(address)
1399 if '/' in addr_str:
1400 raise AddressValueError("Unexpected '/' in %r" % address)
1401 self._ip = self._ip_int_from_string(addr_str)
1402
1403 @property
1404 def packed(self):
1405 """The binary representation of this address."""
1406 return v4_int_to_packed(self._ip)
1407
1408 @property
1409 def is_reserved(self):
1410 """Test if the address is otherwise IETF reserved.
1411
1412 Returns:
1413 A boolean, True if the address is within the
1414 reserved IPv4 Network range.
1415
1416 """
1417 return self in self._constants._reserved_network
1418
1419 @property
1420 def is_private(self):
1421 """Test if this address is allocated for private networks.
1422
1423 Returns:
1424 A boolean, True if the address is reserved per
1425 iana-ipv4-special-registry.
1426
1427 """
1428 return any(self in net for net in self._constants._private_networks)
1429
1430 @property
1431 def is_global(self):
1432 return (
1433 self not in self._constants._public_network and
1434 not self.is_private)
1435
1436 @property
1437 def is_multicast(self):
1438 """Test if the address is reserved for multicast use.
1439
1440 Returns:
1441 A boolean, True if the address is multicast.
1442 See RFC 3171 for details.
1443
1444 """
1445 return self in self._constants._multicast_network
1446
1447 @property
1448 def is_unspecified(self):
1449 """Test if the address is unspecified.
1450
1451 Returns:
1452 A boolean, True if this is the unspecified address as defined in
1453 RFC 5735 3.
1454
1455 """
1456 return self == self._constants._unspecified_address
1457
1458 @property
1459 def is_loopback(self):
1460 """Test if the address is a loopback address.
1461
1462 Returns:
1463 A boolean, True if the address is a loopback per RFC 3330.
1464
1465 """
1466 return self in self._constants._loopback_network
1467
1468 @property
1469 def is_link_local(self):
1470 """Test if the address is reserved for link-local.
1471
1472 Returns:
1473 A boolean, True if the address is link-local per RFC 3927.
1474
1475 """
1476 return self in self._constants._linklocal_network
1477
1478
1479class IPv4Interface(IPv4Address):
1480
1481 def __init__(self, address):
1482 if isinstance(address, (bytes, _compat_int_types)):
1483 IPv4Address.__init__(self, address)
1484 self.network = IPv4Network(self._ip)
1485 self._prefixlen = self._max_prefixlen
1486 return
1487
1488 if isinstance(address, tuple):
1489 IPv4Address.__init__(self, address[0])
1490 if len(address) > 1:
1491 self._prefixlen = int(address[1])
1492 else:
1493 self._prefixlen = self._max_prefixlen
1494
1495 self.network = IPv4Network(address, strict=False)
1496 self.netmask = self.network.netmask
1497 self.hostmask = self.network.hostmask
1498 return
1499
1500 addr = _split_optional_netmask(address)
1501 IPv4Address.__init__(self, addr[0])
1502
1503 self.network = IPv4Network(address, strict=False)
1504 self._prefixlen = self.network._prefixlen
1505
1506 self.netmask = self.network.netmask
1507 self.hostmask = self.network.hostmask
1508
1509 def __str__(self):
1510 return '%s/%d' % (self._string_from_ip_int(self._ip),
1511 self.network.prefixlen)
1512
1513 def __eq__(self, other):
1514 address_equal = IPv4Address.__eq__(self, other)
1515 if not address_equal or address_equal is NotImplemented:
1516 return address_equal
1517 try:
1518 return self.network == other.network
1519 except AttributeError:
1520 # An interface with an associated network is NOT the
1521 # same as an unassociated address. That's why the hash
1522 # takes the extra info into account.
1523 return False
1524
1525 def __lt__(self, other):
1526 address_less = IPv4Address.__lt__(self, other)
1527 if address_less is NotImplemented:
1528 return NotImplemented
1529 try:
1530 return (self.network < other.network or
1531 self.network == other.network and address_less)
1532 except AttributeError:
1533 # We *do* allow addresses and interfaces to be sorted. The
1534 # unassociated address is considered less than all interfaces.
1535 return False
1536
1537 def __hash__(self):
1538 return self._ip ^ self._prefixlen ^ int(self.network.network_address)
1539
1540 __reduce__ = _IPAddressBase.__reduce__
1541
1542 @property
1543 def ip(self):
1544 return IPv4Address(self._ip)
1545
1546 @property
1547 def with_prefixlen(self):
1548 return '%s/%s' % (self._string_from_ip_int(self._ip),
1549 self._prefixlen)
1550
1551 @property
1552 def with_netmask(self):
1553 return '%s/%s' % (self._string_from_ip_int(self._ip),
1554 self.netmask)
1555
1556 @property
1557 def with_hostmask(self):
1558 return '%s/%s' % (self._string_from_ip_int(self._ip),
1559 self.hostmask)
1560
1561
1562class IPv4Network(_BaseV4, _BaseNetwork):
1563
1564 """This class represents and manipulates 32-bit IPv4 network + addresses..
1565
1566 Attributes: [examples for IPv4Network('192.0.2.0/27')]
1567 .network_address: IPv4Address('192.0.2.0')
1568 .hostmask: IPv4Address('0.0.0.31')
1569 .broadcast_address: IPv4Address('192.0.2.32')
1570 .netmask: IPv4Address('255.255.255.224')
1571 .prefixlen: 27
1572
1573 """
1574 # Class to use when creating address objects
1575 _address_class = IPv4Address
1576
1577 def __init__(self, address, strict=True):
1578
1579 """Instantiate a new IPv4 network object.
1580
1581 Args:
1582 address: A string or integer representing the IP [& network].
1583 '192.0.2.0/24'
1584 '192.0.2.0/255.255.255.0'
1585 '192.0.0.2/0.0.0.255'
1586 are all functionally the same in IPv4. Similarly,
1587 '192.0.2.1'
1588 '192.0.2.1/255.255.255.255'
1589 '192.0.2.1/32'
1590 are also functionally equivalent. That is to say, failing to
1591 provide a subnetmask will create an object with a mask of /32.
1592
1593 If the mask (portion after the / in the argument) is given in
1594 dotted quad form, it is treated as a netmask if it starts with a
1595 non-zero field (e.g. /255.0.0.0 == /8) and as a hostmask if it
1596 starts with a zero field (e.g. 0.255.255.255 == /8), with the
1597 single exception of an all-zero mask which is treated as a
1598 netmask == /0. If no mask is given, a default of /32 is used.
1599
1600 Additionally, an integer can be passed, so
1601 IPv4Network('192.0.2.1') == IPv4Network(3221225985)
1602 or, more generally
1603 IPv4Interface(int(IPv4Interface('192.0.2.1'))) ==
1604 IPv4Interface('192.0.2.1')
1605
1606 Raises:
1607 AddressValueError: If ipaddress isn't a valid IPv4 address.
1608 NetmaskValueError: If the netmask isn't valid for
1609 an IPv4 address.
1610 ValueError: If strict is True and a network address is not
1611 supplied.
1612
1613 """
1614 _BaseNetwork.__init__(self, address)
1615
1616 # Constructing from a packed address or integer
1617 if isinstance(address, (_compat_int_types, bytes)):
1618 self.network_address = IPv4Address(address)
1619 self.netmask, self._prefixlen = self._make_netmask(
1620 self._max_prefixlen)
1621 # fixme: address/network test here.
1622 return
1623
1624 if isinstance(address, tuple):
1625 if len(address) > 1:
1626 arg = address[1]
1627 else:
1628 # We weren't given an address[1]
1629 arg = self._max_prefixlen
1630 self.network_address = IPv4Address(address[0])
1631 self.netmask, self._prefixlen = self._make_netmask(arg)
1632 packed = int(self.network_address)
1633 if packed & int(self.netmask) != packed:
1634 if strict:
1635 raise ValueError('%s has host bits set' % self)
1636 else:
1637 self.network_address = IPv4Address(packed &
1638 int(self.netmask))
1639 return
1640
1641 # Assume input argument to be string or any object representation
1642 # which converts into a formatted IP prefix string.
1643 addr = _split_optional_netmask(address)
1644 self.network_address = IPv4Address(self._ip_int_from_string(addr[0]))
1645
1646 if len(addr) == 2:
1647 arg = addr[1]
1648 else:
1649 arg = self._max_prefixlen
1650 self.netmask, self._prefixlen = self._make_netmask(arg)
1651
1652 if strict:
1653 if (IPv4Address(int(self.network_address) & int(self.netmask)) !=
1654 self.network_address):
1655 raise ValueError('%s has host bits set' % self)
1656 self.network_address = IPv4Address(int(self.network_address) &
1657 int(self.netmask))
1658
1659 if self._prefixlen == (self._max_prefixlen - 1):
1660 self.hosts = self.__iter__
1661
1662 @property
1663 def is_global(self):
1664 """Test if this address is allocated for public networks.
1665
1666 Returns:
1667 A boolean, True if the address is not reserved per
1668 iana-ipv4-special-registry.
1669
1670 """
1671 return (not (self.network_address in IPv4Network('100.64.0.0/10') and
1672 self.broadcast_address in IPv4Network('100.64.0.0/10')) and
1673 not self.is_private)
1674
1675
1676class _IPv4Constants(object):
1677
1678 _linklocal_network = IPv4Network('169.254.0.0/16')
1679
1680 _loopback_network = IPv4Network('127.0.0.0/8')
1681
1682 _multicast_network = IPv4Network('224.0.0.0/4')
1683
1684 _public_network = IPv4Network('100.64.0.0/10')
1685
1686 _private_networks = [
1687 IPv4Network('0.0.0.0/8'),
1688 IPv4Network('10.0.0.0/8'),
1689 IPv4Network('127.0.0.0/8'),
1690 IPv4Network('169.254.0.0/16'),
1691 IPv4Network('172.16.0.0/12'),
1692 IPv4Network('192.0.0.0/29'),
1693 IPv4Network('192.0.0.170/31'),
1694 IPv4Network('192.0.2.0/24'),
1695 IPv4Network('192.168.0.0/16'),
1696 IPv4Network('198.18.0.0/15'),
1697 IPv4Network('198.51.100.0/24'),
1698 IPv4Network('203.0.113.0/24'),
1699 IPv4Network('240.0.0.0/4'),
1700 IPv4Network('255.255.255.255/32'),
1701 ]
1702
1703 _reserved_network = IPv4Network('240.0.0.0/4')
1704
1705 _unspecified_address = IPv4Address('0.0.0.0')
1706
1707
1708IPv4Address._constants = _IPv4Constants
1709
1710
1711class _BaseV6(object):
1712
1713 """Base IPv6 object.
1714
1715 The following methods are used by IPv6 objects in both single IP
1716 addresses and networks.
1717
1718 """
1719
1720 __slots__ = ()
1721 _version = 6
1722 _ALL_ONES = (2 ** IPV6LENGTH) - 1
1723 _HEXTET_COUNT = 8
1724 _HEX_DIGITS = frozenset('0123456789ABCDEFabcdef')
1725 _max_prefixlen = IPV6LENGTH
1726
1727 # There are only a bunch of valid v6 netmasks, so we cache them all
1728 # when constructed (see _make_netmask()).
1729 _netmask_cache = {}
1730
1731 @classmethod
1732 def _make_netmask(cls, arg):
1733 """Make a (netmask, prefix_len) tuple from the given argument.
1734
1735 Argument can be:
1736 - an integer (the prefix length)
1737 - a string representing the prefix length (e.g. "24")
1738 - a string representing the prefix netmask (e.g. "255.255.255.0")
1739 """
1740 if arg not in cls._netmask_cache:
1741 if isinstance(arg, _compat_int_types):
1742 prefixlen = arg
1743 else:
1744 prefixlen = cls._prefix_from_prefix_string(arg)
1745 netmask = IPv6Address(cls._ip_int_from_prefix(prefixlen))
1746 cls._netmask_cache[arg] = netmask, prefixlen
1747 return cls._netmask_cache[arg]
1748
1749 @classmethod
1750 def _ip_int_from_string(cls, ip_str):
1751 """Turn an IPv6 ip_str into an integer.
1752
1753 Args:
1754 ip_str: A string, the IPv6 ip_str.
1755
1756 Returns:
1757 An int, the IPv6 address
1758
1759 Raises:
1760 AddressValueError: if ip_str isn't a valid IPv6 Address.
1761
1762 """
1763 if not ip_str:
1764 raise AddressValueError('Address cannot be empty')
1765
1766 parts = ip_str.split(':')
1767
1768 # An IPv6 address needs at least 2 colons (3 parts).
1769 _min_parts = 3
1770 if len(parts) < _min_parts:
1771 msg = "At least %d parts expected in %r" % (_min_parts, ip_str)
1772 raise AddressValueError(msg)
1773
1774 # If the address has an IPv4-style suffix, convert it to hexadecimal.
1775 if '.' in parts[-1]:
1776 try:
1777 ipv4_int = IPv4Address(parts.pop())._ip
1778 except AddressValueError as exc:
1779 raise AddressValueError("%s in %r" % (exc, ip_str))
1780 parts.append('%x' % ((ipv4_int >> 16) & 0xFFFF))
1781 parts.append('%x' % (ipv4_int & 0xFFFF))
1782
1783 # An IPv6 address can't have more than 8 colons (9 parts).
1784 # The extra colon comes from using the "::" notation for a single
1785 # leading or trailing zero part.
1786 _max_parts = cls._HEXTET_COUNT + 1
1787 if len(parts) > _max_parts:
1788 msg = "At most %d colons permitted in %r" % (
1789 _max_parts - 1, ip_str)
1790 raise AddressValueError(msg)
1791
1792 # Disregarding the endpoints, find '::' with nothing in between.
1793 # This indicates that a run of zeroes has been skipped.
1794 skip_index = None
1795 for i in _compat_range(1, len(parts) - 1):
1796 if not parts[i]:
1797 if skip_index is not None:
1798 # Can't have more than one '::'
1799 msg = "At most one '::' permitted in %r" % ip_str
1800 raise AddressValueError(msg)
1801 skip_index = i
1802
1803 # parts_hi is the number of parts to copy from above/before the '::'
1804 # parts_lo is the number of parts to copy from below/after the '::'
1805 if skip_index is not None:
1806 # If we found a '::', then check if it also covers the endpoints.
1807 parts_hi = skip_index
1808 parts_lo = len(parts) - skip_index - 1
1809 if not parts[0]:
1810 parts_hi -= 1
1811 if parts_hi:
1812 msg = "Leading ':' only permitted as part of '::' in %r"
1813 raise AddressValueError(msg % ip_str) # ^: requires ^::
1814 if not parts[-1]:
1815 parts_lo -= 1
1816 if parts_lo:
1817 msg = "Trailing ':' only permitted as part of '::' in %r"
1818 raise AddressValueError(msg % ip_str) # :$ requires ::$
1819 parts_skipped = cls._HEXTET_COUNT - (parts_hi + parts_lo)
1820 if parts_skipped < 1:
1821 msg = "Expected at most %d other parts with '::' in %r"
1822 raise AddressValueError(msg % (cls._HEXTET_COUNT - 1, ip_str))
1823 else:
1824 # Otherwise, allocate the entire address to parts_hi. The
1825 # endpoints could still be empty, but _parse_hextet() will check
1826 # for that.
1827 if len(parts) != cls._HEXTET_COUNT:
1828 msg = "Exactly %d parts expected without '::' in %r"
1829 raise AddressValueError(msg % (cls._HEXTET_COUNT, ip_str))
1830 if not parts[0]:
1831 msg = "Leading ':' only permitted as part of '::' in %r"
1832 raise AddressValueError(msg % ip_str) # ^: requires ^::
1833 if not parts[-1]:
1834 msg = "Trailing ':' only permitted as part of '::' in %r"
1835 raise AddressValueError(msg % ip_str) # :$ requires ::$
1836 parts_hi = len(parts)
1837 parts_lo = 0
1838 parts_skipped = 0
1839
1840 try:
1841 # Now, parse the hextets into a 128-bit integer.
1842 ip_int = 0
1843 for i in range(parts_hi):
1844 ip_int <<= 16
1845 ip_int |= cls._parse_hextet(parts[i])
1846 ip_int <<= 16 * parts_skipped
1847 for i in range(-parts_lo, 0):
1848 ip_int <<= 16
1849 ip_int |= cls._parse_hextet(parts[i])
1850 return ip_int
1851 except ValueError as exc:
1852 raise AddressValueError("%s in %r" % (exc, ip_str))
1853
1854 @classmethod
1855 def _parse_hextet(cls, hextet_str):
1856 """Convert an IPv6 hextet string into an integer.
1857
1858 Args:
1859 hextet_str: A string, the number to parse.
1860
1861 Returns:
1862 The hextet as an integer.
1863
1864 Raises:
1865 ValueError: if the input isn't strictly a hex number from
1866 [0..FFFF].
1867
1868 """
1869 # Whitelist the characters, since int() allows a lot of bizarre stuff.
1870 if not cls._HEX_DIGITS.issuperset(hextet_str):
1871 raise ValueError("Only hex digits permitted in %r" % hextet_str)
1872 # We do the length check second, since the invalid character error
1873 # is likely to be more informative for the user
1874 if len(hextet_str) > 4:
1875 msg = "At most 4 characters permitted in %r"
1876 raise ValueError(msg % hextet_str)
1877 # Length check means we can skip checking the integer value
1878 return int(hextet_str, 16)
1879
1880 @classmethod
1881 def _compress_hextets(cls, hextets):
1882 """Compresses a list of hextets.
1883
1884 Compresses a list of strings, replacing the longest continuous
1885 sequence of "0" in the list with "" and adding empty strings at
1886 the beginning or at the end of the string such that subsequently
1887 calling ":".join(hextets) will produce the compressed version of
1888 the IPv6 address.
1889
1890 Args:
1891 hextets: A list of strings, the hextets to compress.
1892
1893 Returns:
1894 A list of strings.
1895
1896 """
1897 best_doublecolon_start = -1
1898 best_doublecolon_len = 0
1899 doublecolon_start = -1
1900 doublecolon_len = 0
1901 for index, hextet in enumerate(hextets):
1902 if hextet == '0':
1903 doublecolon_len += 1
1904 if doublecolon_start == -1:
1905 # Start of a sequence of zeros.
1906 doublecolon_start = index
1907 if doublecolon_len > best_doublecolon_len:
1908 # This is the longest sequence of zeros so far.
1909 best_doublecolon_len = doublecolon_len
1910 best_doublecolon_start = doublecolon_start
1911 else:
1912 doublecolon_len = 0
1913 doublecolon_start = -1
1914
1915 if best_doublecolon_len > 1:
1916 best_doublecolon_end = (best_doublecolon_start +
1917 best_doublecolon_len)
1918 # For zeros at the end of the address.
1919 if best_doublecolon_end == len(hextets):
1920 hextets += ['']
1921 hextets[best_doublecolon_start:best_doublecolon_end] = ['']
1922 # For zeros at the beginning of the address.
1923 if best_doublecolon_start == 0:
1924 hextets = [''] + hextets
1925
1926 return hextets
1927
1928 @classmethod
1929 def _string_from_ip_int(cls, ip_int=None):
1930 """Turns a 128-bit integer into hexadecimal notation.
1931
1932 Args:
1933 ip_int: An integer, the IP address.
1934
1935 Returns:
1936 A string, the hexadecimal representation of the address.
1937
1938 Raises:
1939 ValueError: The address is bigger than 128 bits of all ones.
1940
1941 """
1942 if ip_int is None:
1943 ip_int = int(cls._ip)
1944
1945 if ip_int > cls._ALL_ONES:
1946 raise ValueError('IPv6 address is too large')
1947
1948 hex_str = '%032x' % ip_int
1949 hextets = ['%x' % int(hex_str[x:x + 4], 16) for x in range(0, 32, 4)]
1950
1951 hextets = cls._compress_hextets(hextets)
1952 return ':'.join(hextets)
1953
1954 def _explode_shorthand_ip_string(self):
1955 """Expand a shortened IPv6 address.
1956
1957 Args:
1958 ip_str: A string, the IPv6 address.
1959
1960 Returns:
1961 A string, the expanded IPv6 address.
1962
1963 """
1964 if isinstance(self, IPv6Network):
1965 ip_str = _compat_str(self.network_address)
1966 elif isinstance(self, IPv6Interface):
1967 ip_str = _compat_str(self.ip)
1968 else:
1969 ip_str = _compat_str(self)
1970
1971 ip_int = self._ip_int_from_string(ip_str)
1972 hex_str = '%032x' % ip_int
1973 parts = [hex_str[x:x + 4] for x in range(0, 32, 4)]
1974 if isinstance(self, (_BaseNetwork, IPv6Interface)):
1975 return '%s/%d' % (':'.join(parts), self._prefixlen)
1976 return ':'.join(parts)
1977
1978 def _reverse_pointer(self):
1979 """Return the reverse DNS pointer name for the IPv6 address.
1980
1981 This implements the method described in RFC3596 2.5.
1982
1983 """
1984 reverse_chars = self.exploded[::-1].replace(':', '')
1985 return '.'.join(reverse_chars) + '.ip6.arpa'
1986
1987 @property
1988 def max_prefixlen(self):
1989 return self._max_prefixlen
1990
1991 @property
1992 def version(self):
1993 return self._version
1994
1995
1996class IPv6Address(_BaseV6, _BaseAddress):
1997
1998 """Represent and manipulate single IPv6 Addresses."""
1999
2000 __slots__ = ('_ip', '__weakref__')
2001
2002 def __init__(self, address):
2003 """Instantiate a new IPv6 address object.
2004
2005 Args:
2006 address: A string or integer representing the IP
2007
2008 Additionally, an integer can be passed, so
2009 IPv6Address('2001:db8::') ==
2010 IPv6Address(42540766411282592856903984951653826560)
2011 or, more generally
2012 IPv6Address(int(IPv6Address('2001:db8::'))) ==
2013 IPv6Address('2001:db8::')
2014
2015 Raises:
2016 AddressValueError: If address isn't a valid IPv6 address.
2017
2018 """
2019 # Efficient constructor from integer.
2020 if isinstance(address, _compat_int_types):
2021 self._check_int_address(address)
2022 self._ip = address
2023 return
2024
2025 # Constructing from a packed address
2026 if isinstance(address, bytes):
2027 self._check_packed_address(address, 16)
2028 bvs = _compat_bytes_to_byte_vals(address)
2029 self._ip = _compat_int_from_byte_vals(bvs, 'big')
2030 return
2031
2032 # Assume input argument to be string or any object representation
2033 # which converts into a formatted IP string.
2034 addr_str = _compat_str(address)
2035 if '/' in addr_str:
2036 raise AddressValueError("Unexpected '/' in %r" % address)
2037 self._ip = self._ip_int_from_string(addr_str)
2038
2039 @property
2040 def packed(self):
2041 """The binary representation of this address."""
2042 return v6_int_to_packed(self._ip)
2043
2044 @property
2045 def is_multicast(self):
2046 """Test if the address is reserved for multicast use.
2047
2048 Returns:
2049 A boolean, True if the address is a multicast address.
2050 See RFC 2373 2.7 for details.
2051
2052 """
2053 return self in self._constants._multicast_network
2054
2055 @property
2056 def is_reserved(self):
2057 """Test if the address is otherwise IETF reserved.
2058
2059 Returns:
2060 A boolean, True if the address is within one of the
2061 reserved IPv6 Network ranges.
2062
2063 """
2064 return any(self in x for x in self._constants._reserved_networks)
2065
2066 @property
2067 def is_link_local(self):
2068 """Test if the address is reserved for link-local.
2069
2070 Returns:
2071 A boolean, True if the address is reserved per RFC 4291.
2072
2073 """
2074 return self in self._constants._linklocal_network
2075
2076 @property
2077 def is_site_local(self):
2078 """Test if the address is reserved for site-local.
2079
2080 Note that the site-local address space has been deprecated by RFC 3879.
2081 Use is_private to test if this address is in the space of unique local
2082 addresses as defined by RFC 4193.
2083
2084 Returns:
2085 A boolean, True if the address is reserved per RFC 3513 2.5.6.
2086
2087 """
2088 return self in self._constants._sitelocal_network
2089
2090 @property
2091 def is_private(self):
2092 """Test if this address is allocated for private networks.
2093
2094 Returns:
2095 A boolean, True if the address is reserved per
2096 iana-ipv6-special-registry.
2097
2098 """
2099 return any(self in net for net in self._constants._private_networks)
2100
2101 @property
2102 def is_global(self):
2103 """Test if this address is allocated for public networks.
2104
2105 Returns:
2106 A boolean, true if the address is not reserved per
2107 iana-ipv6-special-registry.
2108
2109 """
2110 return not self.is_private
2111
2112 @property
2113 def is_unspecified(self):
2114 """Test if the address is unspecified.
2115
2116 Returns:
2117 A boolean, True if this is the unspecified address as defined in
2118 RFC 2373 2.5.2.
2119
2120 """
2121 return self._ip == 0
2122
2123 @property
2124 def is_loopback(self):
2125 """Test if the address is a loopback address.
2126
2127 Returns:
2128 A boolean, True if the address is a loopback address as defined in
2129 RFC 2373 2.5.3.
2130
2131 """
2132 return self._ip == 1
2133
2134 @property
2135 def ipv4_mapped(self):
2136 """Return the IPv4 mapped address.
2137
2138 Returns:
2139 If the IPv6 address is a v4 mapped address, return the
2140 IPv4 mapped address. Return None otherwise.
2141
2142 """
2143 if (self._ip >> 32) != 0xFFFF:
2144 return None
2145 return IPv4Address(self._ip & 0xFFFFFFFF)
2146
2147 @property
2148 def teredo(self):
2149 """Tuple of embedded teredo IPs.
2150
2151 Returns:
2152 Tuple of the (server, client) IPs or None if the address
2153 doesn't appear to be a teredo address (doesn't start with
2154 2001::/32)
2155
2156 """
2157 if (self._ip >> 96) != 0x20010000:
2158 return None
2159 return (IPv4Address((self._ip >> 64) & 0xFFFFFFFF),
2160 IPv4Address(~self._ip & 0xFFFFFFFF))
2161
2162 @property
2163 def sixtofour(self):
2164 """Return the IPv4 6to4 embedded address.
2165
2166 Returns:
2167 The IPv4 6to4-embedded address if present or None if the
2168 address doesn't appear to contain a 6to4 embedded address.
2169
2170 """
2171 if (self._ip >> 112) != 0x2002:
2172 return None
2173 return IPv4Address((self._ip >> 80) & 0xFFFFFFFF)
2174
2175
2176class IPv6Interface(IPv6Address):
2177
2178 def __init__(self, address):
2179 if isinstance(address, (bytes, _compat_int_types)):
2180 IPv6Address.__init__(self, address)
2181 self.network = IPv6Network(self._ip)
2182 self._prefixlen = self._max_prefixlen
2183 return
2184 if isinstance(address, tuple):
2185 IPv6Address.__init__(self, address[0])
2186 if len(address) > 1:
2187 self._prefixlen = int(address[1])
2188 else:
2189 self._prefixlen = self._max_prefixlen
2190 self.network = IPv6Network(address, strict=False)
2191 self.netmask = self.network.netmask
2192 self.hostmask = self.network.hostmask
2193 return
2194
2195 addr = _split_optional_netmask(address)
2196 IPv6Address.__init__(self, addr[0])
2197 self.network = IPv6Network(address, strict=False)
2198 self.netmask = self.network.netmask
2199 self._prefixlen = self.network._prefixlen
2200 self.hostmask = self.network.hostmask
2201
2202 def __str__(self):
2203 return '%s/%d' % (self._string_from_ip_int(self._ip),
2204 self.network.prefixlen)
2205
2206 def __eq__(self, other):
2207 address_equal = IPv6Address.__eq__(self, other)
2208 if not address_equal or address_equal is NotImplemented:
2209 return address_equal
2210 try:
2211 return self.network == other.network
2212 except AttributeError:
2213 # An interface with an associated network is NOT the
2214 # same as an unassociated address. That's why the hash
2215 # takes the extra info into account.
2216 return False
2217
2218 def __lt__(self, other):
2219 address_less = IPv6Address.__lt__(self, other)
2220 if address_less is NotImplemented:
2221 return NotImplemented
2222 try:
2223 return (self.network < other.network or
2224 self.network == other.network and address_less)
2225 except AttributeError:
2226 # We *do* allow addresses and interfaces to be sorted. The
2227 # unassociated address is considered less than all interfaces.
2228 return False
2229
2230 def __hash__(self):
2231 return self._ip ^ self._prefixlen ^ int(self.network.network_address)
2232
2233 __reduce__ = _IPAddressBase.__reduce__
2234
2235 @property
2236 def ip(self):
2237 return IPv6Address(self._ip)
2238
2239 @property
2240 def with_prefixlen(self):
2241 return '%s/%s' % (self._string_from_ip_int(self._ip),
2242 self._prefixlen)
2243
2244 @property
2245 def with_netmask(self):
2246 return '%s/%s' % (self._string_from_ip_int(self._ip),
2247 self.netmask)
2248
2249 @property
2250 def with_hostmask(self):
2251 return '%s/%s' % (self._string_from_ip_int(self._ip),
2252 self.hostmask)
2253
2254 @property
2255 def is_unspecified(self):
2256 return self._ip == 0 and self.network.is_unspecified
2257
2258 @property
2259 def is_loopback(self):
2260 return self._ip == 1 and self.network.is_loopback
2261
2262
2263class IPv6Network(_BaseV6, _BaseNetwork):
2264
2265 """This class represents and manipulates 128-bit IPv6 networks.
2266
2267 Attributes: [examples for IPv6('2001:db8::1000/124')]
2268 .network_address: IPv6Address('2001:db8::1000')
2269 .hostmask: IPv6Address('::f')
2270 .broadcast_address: IPv6Address('2001:db8::100f')
2271 .netmask: IPv6Address('ffff:ffff:ffff:ffff:ffff:ffff:ffff:fff0')
2272 .prefixlen: 124
2273
2274 """
2275
2276 # Class to use when creating address objects
2277 _address_class = IPv6Address
2278
2279 def __init__(self, address, strict=True):
2280 """Instantiate a new IPv6 Network object.
2281
2282 Args:
2283 address: A string or integer representing the IPv6 network or the
2284 IP and prefix/netmask.
2285 '2001:db8::/128'
2286 '2001:db8:0000:0000:0000:0000:0000:0000/128'
2287 '2001:db8::'
2288 are all functionally the same in IPv6. That is to say,
2289 failing to provide a subnetmask will create an object with
2290 a mask of /128.
2291
2292 Additionally, an integer can be passed, so
2293 IPv6Network('2001:db8::') ==
2294 IPv6Network(42540766411282592856903984951653826560)
2295 or, more generally
2296 IPv6Network(int(IPv6Network('2001:db8::'))) ==
2297 IPv6Network('2001:db8::')
2298
2299 strict: A boolean. If true, ensure that we have been passed
2300 A true network address, eg, 2001:db8::1000/124 and not an
2301 IP address on a network, eg, 2001:db8::1/124.
2302
2303 Raises:
2304 AddressValueError: If address isn't a valid IPv6 address.
2305 NetmaskValueError: If the netmask isn't valid for
2306 an IPv6 address.
2307 ValueError: If strict was True and a network address was not
2308 supplied.
2309
2310 """
2311 _BaseNetwork.__init__(self, address)
2312
2313 # Efficient constructor from integer or packed address
2314 if isinstance(address, (bytes, _compat_int_types)):
2315 self.network_address = IPv6Address(address)
2316 self.netmask, self._prefixlen = self._make_netmask(
2317 self._max_prefixlen)
2318 return
2319
2320 if isinstance(address, tuple):
2321 if len(address) > 1:
2322 arg = address[1]
2323 else:
2324 arg = self._max_prefixlen
2325 self.netmask, self._prefixlen = self._make_netmask(arg)
2326 self.network_address = IPv6Address(address[0])
2327 packed = int(self.network_address)
2328 if packed & int(self.netmask) != packed:
2329 if strict:
2330 raise ValueError('%s has host bits set' % self)
2331 else:
2332 self.network_address = IPv6Address(packed &
2333 int(self.netmask))
2334 return
2335
2336 # Assume input argument to be string or any object representation
2337 # which converts into a formatted IP prefix string.
2338 addr = _split_optional_netmask(address)
2339
2340 self.network_address = IPv6Address(self._ip_int_from_string(addr[0]))
2341
2342 if len(addr) == 2:
2343 arg = addr[1]
2344 else:
2345 arg = self._max_prefixlen
2346 self.netmask, self._prefixlen = self._make_netmask(arg)
2347
2348 if strict:
2349 if (IPv6Address(int(self.network_address) & int(self.netmask)) !=
2350 self.network_address):
2351 raise ValueError('%s has host bits set' % self)
2352 self.network_address = IPv6Address(int(self.network_address) &
2353 int(self.netmask))
2354
2355 if self._prefixlen == (self._max_prefixlen - 1):
2356 self.hosts = self.__iter__
2357
2358 def hosts(self):
2359 """Generate Iterator over usable hosts in a network.
2360
2361 This is like __iter__ except it doesn't return the
2362 Subnet-Router anycast address.
2363
2364 """
2365 network = int(self.network_address)
2366 broadcast = int(self.broadcast_address)
2367 for x in _compat_range(network + 1, broadcast + 1):
2368 yield self._address_class(x)
2369
2370 @property
2371 def is_site_local(self):
2372 """Test if the address is reserved for site-local.
2373
2374 Note that the site-local address space has been deprecated by RFC 3879.
2375 Use is_private to test if this address is in the space of unique local
2376 addresses as defined by RFC 4193.
2377
2378 Returns:
2379 A boolean, True if the address is reserved per RFC 3513 2.5.6.
2380
2381 """
2382 return (self.network_address.is_site_local and
2383 self.broadcast_address.is_site_local)
2384
2385
2386class _IPv6Constants(object):
2387
2388 _linklocal_network = IPv6Network('fe80::/10')
2389
2390 _multicast_network = IPv6Network('ff00::/8')
2391
2392 _private_networks = [
2393 IPv6Network('::1/128'),
2394 IPv6Network('::/128'),
2395 IPv6Network('::ffff:0:0/96'),
2396 IPv6Network('100::/64'),
2397 IPv6Network('2001::/23'),
2398 IPv6Network('2001:2::/48'),
2399 IPv6Network('2001:db8::/32'),
2400 IPv6Network('2001:10::/28'),
2401 IPv6Network('fc00::/7'),
2402 IPv6Network('fe80::/10'),
2403 ]
2404
2405 _reserved_networks = [
2406 IPv6Network('::/8'), IPv6Network('100::/8'),
2407 IPv6Network('200::/7'), IPv6Network('400::/6'),
2408 IPv6Network('800::/5'), IPv6Network('1000::/4'),
2409 IPv6Network('4000::/3'), IPv6Network('6000::/3'),
2410 IPv6Network('8000::/3'), IPv6Network('A000::/3'),
2411 IPv6Network('C000::/3'), IPv6Network('E000::/4'),
2412 IPv6Network('F000::/5'), IPv6Network('F800::/6'),
2413 IPv6Network('FE00::/9'),
2414 ]
2415
2416 _sitelocal_network = IPv6Network('fec0::/10')
2417
2418
2419IPv6Address._constants = _IPv6Constants
generated by cgit v1.2.3 (git 2.25.1) at 2025-12-17 04:54:54 +0000