Enum ipnet::IpNet[−][src]

pub enum IpNet {
    V4(Ipv4Net),
    V6(Ipv6Net),
}

Expand description

An IP network address, either IPv4 or IPv6.

This enum can contain either an Ipv4Net or an Ipv6Net. A From implementation is provided to convert these into an IpNet.

Textual representation

IpNet provides a FromStr implementation for parsing network addresses represented in CIDR notation. See IETF RFC 4632 for the CIDR notation.

Examples

use std::net::IpAddr;
use ipnet::IpNet;

let net: IpNet = "10.1.1.0/24".parse().unwrap();
assert_eq!(Ok(net.network()), "10.1.1.0".parse());

let net: IpNet = "fd00::/32".parse().unwrap();
assert_eq!(Ok(net.network()), "fd00::".parse());

Variants

`V4(Ipv4Net)`

Tuple Fields

0: Ipv4Net

`V6(Ipv6Net)`

Tuple Fields

0: Ipv6Net

Implementations

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impl IpNet

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pub fn new(ip: IpAddr, prefix_len: u8) -> Result<IpNet, PrefixLenError>

Creates a new IP network address from an IpAddr and prefix length.

Examples

use std::net::Ipv6Addr;
use ipnet::{IpNet, PrefixLenError};

let net = IpNet::new(Ipv6Addr::LOCALHOST.into(), 48);
assert!(net.is_ok());
 
let bad_prefix_len = IpNet::new(Ipv6Addr::LOCALHOST.into(), 129);
assert_eq!(bad_prefix_len, Err(PrefixLenError));

[src]

pub fn trunc(&self) -> IpNet

Returns a copy of the network with the address truncated to the prefix length.

Examples

assert_eq!(
    "192.168.12.34/16".parse::<IpNet>().unwrap().trunc(),
    "192.168.0.0/16".parse().unwrap()
);

assert_eq!(
    "fd00::1:2:3:4/16".parse::<IpNet>().unwrap().trunc(),
    "fd00::/16".parse().unwrap()
);

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pub fn addr(&self) -> IpAddr

Returns the address.

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pub fn prefix_len(&self) -> u8

Returns the prefix length.

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pub fn max_prefix_len(&self) -> u8

Returns the maximum valid prefix length.

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pub fn netmask(&self) -> IpAddr

Returns the network mask.

Examples

let net: IpNet = "10.1.0.0/20".parse().unwrap();
assert_eq!(Ok(net.netmask()), "255.255.240.0".parse());

let net: IpNet = "fd00::/24".parse().unwrap();
assert_eq!(Ok(net.netmask()), "ffff:ff00::".parse());

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pub fn hostmask(&self) -> IpAddr

Returns the host mask.

Examples

let net: IpNet = "10.1.0.0/20".parse().unwrap();
assert_eq!(Ok(net.hostmask()), "0.0.15.255".parse());

let net: IpNet = "fd00::/24".parse().unwrap();
assert_eq!(Ok(net.hostmask()), "::ff:ffff:ffff:ffff:ffff:ffff:ffff".parse());

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pub fn network(&self) -> IpAddr

Returns the network address.

Examples

let net: IpNet = "172.16.123.123/16".parse().unwrap();
assert_eq!(Ok(net.network()), "172.16.0.0".parse());

let net: IpNet = "fd00:1234:5678::/24".parse().unwrap();
assert_eq!(Ok(net.network()), "fd00:1200::".parse());

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pub fn broadcast(&self) -> IpAddr

Returns the broadcast address.

Examples

let net: IpNet = "172.16.0.0/22".parse().unwrap();
assert_eq!(Ok(net.broadcast()), "172.16.3.255".parse());

let net: IpNet = "fd00:1234:5678::/24".parse().unwrap();
assert_eq!(Ok(net.broadcast()), "fd00:12ff:ffff:ffff:ffff:ffff:ffff:ffff".parse());

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pub fn supernet(&self) -> Option<IpNet>

Returns the IpNet that contains this one.

Examples

let n1: IpNet = "172.16.1.0/24".parse().unwrap();
let n2: IpNet = "172.16.0.0/23".parse().unwrap();
let n3: IpNet = "172.16.0.0/0".parse().unwrap();

assert_eq!(n1.supernet().unwrap(), n2);
assert_eq!(n3.supernet(), None);

let n1: IpNet = "fd00:ff00::/24".parse().unwrap();
let n2: IpNet = "fd00:fe00::/23".parse().unwrap();
let n3: IpNet = "fd00:fe00::/0".parse().unwrap();

assert_eq!(n1.supernet().unwrap(), n2);
assert_eq!(n3.supernet(), None);

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pub fn is_sibling(&self, other: &IpNet) -> bool

Returns true if this network and the given network are children of the same supernet.

Examples

let n4_1: IpNet = "10.1.0.0/24".parse().unwrap();
let n4_2: IpNet = "10.1.1.0/24".parse().unwrap();
let n4_3: IpNet = "10.1.2.0/24".parse().unwrap();
let n6_1: IpNet = "fd00::/18".parse().unwrap();
let n6_2: IpNet = "fd00:4000::/18".parse().unwrap();
let n6_3: IpNet = "fd00:8000::/18".parse().unwrap();

assert!( n4_1.is_sibling(&n4_2));
assert!(!n4_2.is_sibling(&n4_3));
assert!( n6_1.is_sibling(&n6_2));
assert!(!n6_2.is_sibling(&n6_3));
assert!(!n4_1.is_sibling(&n6_2));

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pub fn hosts(&self) -> IpAddrRangeⓘ
Notable traits for IpAddrRange
`impl Iterator for IpAddrRange type Item = IpAddr;`

Return an Iterator over the host addresses in this network.

Examples

let net: IpNet = "10.0.0.0/30".parse().unwrap();
assert_eq!(net.hosts().collect::<Vec<IpAddr>>(), vec![
    "10.0.0.1".parse::<IpAddr>().unwrap(),
    "10.0.0.2".parse().unwrap(),
]);

let net: IpNet = "10.0.0.0/31".parse().unwrap();
assert_eq!(net.hosts().collect::<Vec<IpAddr>>(), vec![
    "10.0.0.0".parse::<IpAddr>().unwrap(),
    "10.0.0.1".parse().unwrap(),
]);

let net: IpNet = "fd00::/126".parse().unwrap();
assert_eq!(net.hosts().collect::<Vec<IpAddr>>(), vec![
    "fd00::".parse::<IpAddr>().unwrap(),
    "fd00::1".parse().unwrap(),
    "fd00::2".parse().unwrap(),
    "fd00::3".parse().unwrap(),
]);

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pub fn subnets(&self, new_prefix_len: u8) -> Result<IpSubnets, PrefixLenError>

Returns an Iterator over the subnets of this network with the given prefix length.

Examples

let net: IpNet = "10.0.0.0/24".parse().unwrap();
assert_eq!(net.subnets(26).unwrap().collect::<Vec<IpNet>>(), vec![
    "10.0.0.0/26".parse::<IpNet>().unwrap(),
    "10.0.0.64/26".parse().unwrap(),
    "10.0.0.128/26".parse().unwrap(),
    "10.0.0.192/26".parse().unwrap(),
]);

let net: IpNet = "fd00::/16".parse().unwrap();
assert_eq!(net.subnets(18).unwrap().collect::<Vec<IpNet>>(), vec![
    "fd00::/18".parse::<IpNet>().unwrap(),
    "fd00:4000::/18".parse().unwrap(),
    "fd00:8000::/18".parse().unwrap(),
    "fd00:c000::/18".parse().unwrap(),
]);

let net: IpNet = "10.0.0.0/24".parse().unwrap();
assert_eq!(net.subnets(23), Err(PrefixLenError));

let net: IpNet = "10.0.0.0/24".parse().unwrap();
assert_eq!(net.subnets(33), Err(PrefixLenError));

let net: IpNet = "fd00::/16".parse().unwrap();
assert_eq!(net.subnets(15), Err(PrefixLenError));

let net: IpNet = "fd00::/16".parse().unwrap();
assert_eq!(net.subnets(129), Err(PrefixLenError));

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pub fn contains<T>(&self, other: T) -> bool where
Self: Contains<T>,

Test if a network address contains either another network address or an IP address.

Examples

let net4: IpNet = "192.168.0.0/24".parse().unwrap();
let net4_yes: IpNet = "192.168.0.0/25".parse().unwrap();
let net4_no: IpNet = "192.168.0.0/23".parse().unwrap();
let ip4_yes: IpAddr = "192.168.0.1".parse().unwrap();
let ip4_no: IpAddr = "192.168.1.0".parse().unwrap();

assert!(net4.contains(&net4));
assert!(net4.contains(&net4_yes));
assert!(!net4.contains(&net4_no));
assert!(net4.contains(&ip4_yes));
assert!(!net4.contains(&ip4_no));


let net6: IpNet = "fd00::/16".parse().unwrap();
let net6_yes: IpNet = "fd00::/17".parse().unwrap();
let net6_no: IpNet = "fd00::/15".parse().unwrap();
let ip6_yes: IpAddr = "fd00::1".parse().unwrap();
let ip6_no: IpAddr = "fd01::".parse().unwrap();

assert!(net6.contains(&net6));
assert!(net6.contains(&net6_yes));
assert!(!net6.contains(&net6_no));
assert!(net6.contains(&ip6_yes));
assert!(!net6.contains(&ip6_no));

assert!(!net4.contains(&net6));
assert!(!net6.contains(&net4));
assert!(!net4.contains(&ip6_no));
assert!(!net6.contains(&ip4_no));

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pub fn aggregate(networks: &Vec<IpNet>) -> Vec<IpNet>

Aggregate a Vec of IpNets and return the result as a new Vec.

Examples

let nets = vec![
    "10.0.0.0/24".parse::<IpNet>().unwrap(),
    "10.0.1.0/24".parse().unwrap(),
    "10.0.2.0/24".parse().unwrap(),
    "fd00::/18".parse().unwrap(),
    "fd00:4000::/18".parse().unwrap(),
    "fd00:8000::/18".parse().unwrap(),
];

assert_eq!(IpNet::aggregate(&nets), vec![
    "10.0.0.0/23".parse::<IpNet>().unwrap(),
    "10.0.2.0/24".parse().unwrap(),
    "fd00::/17".parse().unwrap(),
    "fd00:8000::/18".parse().unwrap(),
]);