import re
class IPAddress:
"""
A simple class encapsulating an ip-address. An IPAddress can be constructed by string, int and 4-element-list
(e.g. [8, 8, 8, 8]). This is a leightweight class as it only contains string-to-ip-and-reverse-conversion
and some convenience methods.
"""
# a number between 0 and 255, no leading zeros
_IP_NUMBER_REGEXP = r"(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)"
# 4 numbers between 0 and 255, joined together with dots
IP_REGEXP = r"{0}\.{0}\.{0}\.{0}".format(_IP_NUMBER_REGEXP)
def __init__(self, intlist: "list[int]") -> "IPAddress":
"""
Construct an ipv4-address with a list of 4 integers, e.g. to construct the ip 10.0.0.0 pass [10, 0, 0, 0]
"""
if not isinstance(intlist, list) or not all(isinstance(n, int) for n in intlist):
raise TypeError("The first constructor argument must be an list of ints")
if not len(intlist) == 4 or not all(0 <= n <= 255 for n in intlist):
raise ValueError("The integer list must contain 4 ints in range of 0 and 255, like an ip-address")
# For easier calculations store the ip as integer, e.g. 10.0.0.0 is 0x0a000000
self.ipnum = int.from_bytes(bytes(intlist), "big")
@staticmethod
def parse(ip: str) -> "IPAddress":
"""
Parse an ip-address-string. If the string does not comply to the ipv4-format a ValueError is raised
:param ip: A string-representation of an ip-address, e.g. "10.0.0.0"
:return: IPAddress-object describing the ip-address
"""
match = re.match("^" + IPAddress.IP_REGEXP + "$", ip)
if not match:
raise ValueError("%s is no ipv4-address" % ip)
# the matches we get are the numbers of the ip-address (match 0 is the whole ip-address)
numbers = [int(match.group(i)) for i in range(1, 5)]
return IPAddress(numbers)
@staticmethod
def from_int(numeric: int) -> "IPAddress":
if numeric not in range(1 << 32):
raise ValueError("numeric value must be in uint-range")
# to_bytes is the easiest way to split a 32-bit int into bytes
return IPAddress(list(numeric.to_bytes(4, "big")))
@staticmethod
def is_ipv4(ip: str) -> bool:
"""
Check if the supplied string is in ipv4-format
"""
match = re.match("^" + IPAddress.IP_REGEXP + "$", ip)
return True if match else False
def to_int(self) -> int:
"""
Convert the ip-address to a 32-bit uint, e.g. IPAddress.parse("10.0.0.255").to_int() returns 0x0a0000ff
"""
return self.ipnum
def is_private(self) -> bool:
"""
Returns a boolean indicating if the ip-address lies in the private ip-segments (see ReservedIPBlocks)
"""
return ReservedIPBlocks.is_private(self)
def get_private_segment(self) -> bool:
"""
Return the private ip-segment the ip-address belongs to (there are several)
If this ip does not belong to a private ip-segment a ValueError is raised
:return: IPAddressBlock
"""
return ReservedIPBlocks.get_private_segment(self)
def is_localhost(self) -> bool:
"""
Returns a boolean indicating if the ip-address lies in the localhost-segment
"""
return ReservedIPBlocks.is_localhost(self)
def is_multicast(self) -> bool:
"""
Returns a boolean indicating if the ip-address lies in the multicast-segment
"""
return ReservedIPBlocks.is_multicast(self)
def is_reserved(self) -> bool:
"""
Returns a boolean indicating if the ip-address lies in the reserved-segment
"""
return ReservedIPBlocks.is_reserved(self)
def is_zero_conf(self) -> bool:
"""
Returns a boolean indicating if the ip-address lies in the zeroconf-segment
"""
return ReservedIPBlocks.is_zero_conf(self)
def _tuple(self) -> (int,int,int,int):
return tuple(self.ipnum.to_bytes(4, "big"))
def __repr__(self) -> str:
"""
Following the python style guide, eval(repr(obj)) should equal obj
"""
return "IPAddress([%i, %i, %i, %i])" % self._tuple()
def __str__(self) -> str:
"""
Return the ip-address described by this object in ipv4-format
"""
return "%i.%i.%i.%i" % self._tuple()
def __hash__(self) -> int:
return self.ipnum
def __eq__(self, other) -> bool:
if other is None:
return False
return isinstance(other, IPAddress) and self.ipnum == other.ipnum
def __lt__(self, other) -> bool:
if other is None:
raise TypeError("Cannot compare to None")
if not isinstance(other, IPAddress):
raise NotImplemented # maybe other can compare to self
return self.ipnum < other.ipnum
def __int__(self) -> bool:
return self.ipnum
class IPAddressBlock:
"""
This class describes a block of IPv4-addresses, just as a string in CIDR-notation does.
It can be seen as a range of ip-addresses. To check if a block contains a ip-address
simply use "ip in ip_block"
"""
# this regex describes CIDR-notation (an ip-address plus "/XX", whereas XX is a number between 1 and 32)
CIDR_REGEXP = IPAddress.IP_REGEXP + r"(\/(3[0-2]|[12]?\d)|)?"
def __init__(self, ip: "Union(str, list, IPAddress)", netmask = 32) -> "IPAddressBlock":
"""
Construct a ip-block given a ip-address and a netmask. Given an ip and a netmask,
the constructed ip-block will describe the range ip/netmask (e.g. 127.0.0.1/8)
:param ip: An ip-address, represented as IPAddress, string or 4-element-list
"""
if isinstance(ip, str):
ip = IPAddress.parse(ip)
elif isinstance(ip, list):
ip = IPAddress(ip)
if not 1 <= netmask <= 32:
raise ValueError("netmask must lie between 1 and 32")
# clear the unnecessary bits in the base-ip, e.g. this will convert 10.0.0.255/24 to 10.0.0.0/24 which are equivalent
self.ipnum = ip.to_int() & self._bitmask(netmask)
self.netmask = netmask
@staticmethod
def parse(cidr: str) -> "IPAddressBlock":
"""
Parse a string in cidr-notation and return a IPAddressBlock describing the ip-segment
If the string is not in cidr-notation a ValueError is raised
"""
match = re.match("^" + IPAddressBlock.CIDR_REGEXP + "$", cidr)
if not match:
raise ValueError("%s is no valid cidr-notation" % cidr)
ip = [int(match.group(i)) for i in range(1, 5)]
suffix = 32 if not match.group(6) else int(match.group(6))
return IPAddressBlock(ip, suffix)
def block_size(self) -> int:
"""
Return the size of the ip-address-block. E.g. the size of someip/24 is 256
"""
return 2 ** (32 - self.netmask)
def first_address(self) -> IPAddress:
"""
Return the first ip-address of the ip-block
"""
return IPAddress.from_int(self.ipnum)
def last_address(self) -> IPAddress:
"""
Return the last ip-address of the ip-block
"""
return IPAddress.from_int(self.ipnum + self.block_size() - 1)
def _bitmask(self, netmask: int) -> int:
ones = lambda x: (1 << x) - 1
return ones(32) ^ ones(32 - netmask)
def __repr__(self) -> str:
"""
Conforming to python style-guide, eval(repr(obj)) equals obj
"""
return "IPAddressBlock(%s, %i)" % (repr(IPAddress.from_int(self.ipnum)), self.netmask)
def __str__(self) -> str:
"""
Return a string in cidr-notation
"""
return str(IPAddress.from_int(self.ipnum)) + "/" + str(self.netmask)
def __contains__(self, ip: IPAddress) -> bool:
return (ip.to_int() & self._bitmask(self.netmask)) == self.ipnum
class ReservedIPBlocks:
"""
To avoid magic values and save developers some research this class contains several constants
describing special network-segments and some is_-methods to check if an ip is in the specified segment.
"""
# a list of ip-addresses that can be used in private networks
PRIVATE_IP_SEGMENTS = [
IPAddressBlock.parse(block)
for block in
("10.0.0.0/8", "172.16.0.0/12", "192.168.0.0/16")
]
LOCALHOST_SEGMENT = IPAddressBlock.parse("127.0.0.0/8")
MULTICAST_SEGMENT = IPAddressBlock.parse("224.0.0.0/4")
RESERVED_SEGMENT = IPAddressBlock.parse("240.0.0.0/4")
ZERO_CONF_SEGMENT = IPAddressBlock.parse("169.254.0.0/16")
@staticmethod
def is_private(ip: IPAddress) -> bool:
return any(ip in block for block in ReservedIPBlocks.PRIVATE_IP_SEGMENTS)
@staticmethod
def get_private_segment(ip: IPAddress) -> "Optional[IPAddressBlock]":
if not ReservedIPBlocks.is_private(ip):
raise ValueError("%s is not part of a private IP segment" % ip)
for block in ReservedIPBlocks.PRIVATE_IP_SEGMENTS:
if ip in block:
return block
@staticmethod
def is_localhost(ip: IPAddress) -> bool:
return ip in ReservedIPBlocks.LOCALHOST_SEGMENT
@staticmethod
def is_multicast(ip: IPAddressBlock) -> bool:
return ip in ReservedIPBlocks.MULTICAST_SEGMENT
@staticmethod
def is_reserved(ip: IPAddress) -> bool:
return ip in ReservedIPBlocks.RESERVED_SEGMENT
@staticmethod
def is_zero_conf(ip: IPAddressBlock) -> bool:
return ip in ReservedIPBlocks.ZERO_CONF_SEGMENT