impl Ipv4Addr

const fn new(a: u8, b: u8, c: u8, d: u8) -> Ipv4Addr

Creates a new IPv4 address from four eight-bit octets.

The result will represent the IP address a.b.c.d.

Examples

use std::net::Ipv4Addr;

let addr = Ipv4Addr::new(127, 0, 0, 1);

const fn to_bits(self: Self) -> u32

Converts an IPv4 address into a u32 representation using native byte order.

Although IPv4 addresses are big-endian, the u32 value will use the target platform's native byte order. That is, the u32 value is an integer representation of the IPv4 address and not an integer interpretation of the IPv4 address's big-endian bitstring. This means that the u32 value masked with 0xffffff00 will set the last octet in the address to 0, regardless of the target platform's endianness.

Examples

use std::net::Ipv4Addr;

let addr = Ipv4Addr::new(0x12, 0x34, 0x56, 0x78);
assert_eq!(0x12345678, addr.to_bits());

use std::net::Ipv4Addr;

let addr = Ipv4Addr::new(0x12, 0x34, 0x56, 0x78);
let addr_bits = addr.to_bits() & 0xffffff00;
assert_eq!(Ipv4Addr::new(0x12, 0x34, 0x56, 0x00), Ipv4Addr::from_bits(addr_bits));

const fn from_bits(bits: u32) -> Ipv4Addr

Converts a native byte order u32 into an IPv4 address.

See Ipv4Addr::to_bits for an explanation on endianness.

Examples

use std::net::Ipv4Addr;

let addr = Ipv4Addr::from_bits(0x12345678);
assert_eq!(Ipv4Addr::new(0x12, 0x34, 0x56, 0x78), addr);

const fn octets(self: &Self) -> [u8; 4]

Returns the four eight-bit integers that make up this address.

Examples

use std::net::Ipv4Addr;

let addr = Ipv4Addr::new(127, 0, 0, 1);
assert_eq!(addr.octets(), [127, 0, 0, 1]);

const fn from_octets(octets: [u8; 4]) -> Ipv4Addr

Creates an Ipv4Addr from a four element byte array.

Examples

use std::net::Ipv4Addr;

let addr = Ipv4Addr::from_octets([13u8, 12u8, 11u8, 10u8]);
assert_eq!(Ipv4Addr::new(13, 12, 11, 10), addr);

const fn as_octets(self: &Self) -> &[u8; 4]

Returns the four eight-bit integers that make up this address as a slice.

Examples

#![feature(ip_as_octets)]

use std::net::Ipv4Addr;

let addr = Ipv4Addr::new(127, 0, 0, 1);
assert_eq!(addr.as_octets(), &[127, 0, 0, 1]);

const fn is_unspecified(self: &Self) -> bool

Returns true for the special 'unspecified' address (0.0.0.0).

This property is defined in UNIX Network Programming, Second Edition, W. Richard Stevens, p. 891; see also ip7.

Examples

use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(0, 0, 0, 0).is_unspecified(), true);
assert_eq!(Ipv4Addr::new(45, 22, 13, 197).is_unspecified(), false);

const fn is_loopback(self: &Self) -> bool

Returns true if this is a loopback address (127.0.0.0/8).

This property is defined by IETF RFC 1122.

Examples

use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(127, 0, 0, 1).is_loopback(), true);
assert_eq!(Ipv4Addr::new(45, 22, 13, 197).is_loopback(), false);

const fn is_private(self: &Self) -> bool

Returns true if this is a private address.

The private address ranges are defined in IETF RFC 1918 and include:

• 10.0.0.0/8
• 172.16.0.0/12
• 192.168.0.0/16

Examples

use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(10, 0, 0, 1).is_private(), true);
assert_eq!(Ipv4Addr::new(10, 10, 10, 10).is_private(), true);
assert_eq!(Ipv4Addr::new(172, 16, 10, 10).is_private(), true);
assert_eq!(Ipv4Addr::new(172, 29, 45, 14).is_private(), true);
assert_eq!(Ipv4Addr::new(172, 32, 0, 2).is_private(), false);
assert_eq!(Ipv4Addr::new(192, 168, 0, 2).is_private(), true);
assert_eq!(Ipv4Addr::new(192, 169, 0, 2).is_private(), false);

const fn is_link_local(self: &Self) -> bool

Returns true if the address is link-local (169.254.0.0/16).

This property is defined by IETF RFC 3927.

Examples

use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(169, 254, 0, 0).is_link_local(), true);
assert_eq!(Ipv4Addr::new(169, 254, 10, 65).is_link_local(), true);
assert_eq!(Ipv4Addr::new(16, 89, 10, 65).is_link_local(), false);

const fn is_global(self: &Self) -> bool

Returns true if the address appears to be globally reachable as specified by the IANA IPv4 Special-Purpose Address Registry.

Whether or not an address is practically reachable will depend on your network configuration. Most IPv4 addresses are globally reachable, unless they are specifically defined as not globally reachable.

Non-exhaustive list of notable addresses that are not globally reachable:

• The unspecified address (is_unspecified)
• Addresses reserved for private use (is_private)
• Addresses in the shared address space (is_shared)
• Loopback addresses (is_loopback)
• Link-local addresses (is_link_local)
• Addresses reserved for documentation (is_documentation)
• Addresses reserved for benchmarking (is_benchmarking)
• Reserved addresses (is_reserved)
• The broadcast address (is_broadcast)

For the complete overview of which addresses are globally reachable, see the table at the IANA IPv4 Special-Purpose Address Registry.

Examples

#![feature(ip)]

use std::net::Ipv4Addr;

// Most IPv4 addresses are globally reachable:
assert_eq!(Ipv4Addr::new(80, 9, 12, 3).is_global(), true);

// However some addresses have been assigned a special meaning
// that makes them not globally reachable. Some examples are:

// The unspecified address (`0.0.0.0`)
assert_eq!(Ipv4Addr::UNSPECIFIED.is_global(), false);

// Addresses reserved for private use (`10.0.0.0/8`, `172.16.0.0/12`, 192.168.0.0/16)
assert_eq!(Ipv4Addr::new(10, 254, 0, 0).is_global(), false);
assert_eq!(Ipv4Addr::new(192, 168, 10, 65).is_global(), false);
assert_eq!(Ipv4Addr::new(172, 16, 10, 65).is_global(), false);

// Addresses in the shared address space (`100.64.0.0/10`)
assert_eq!(Ipv4Addr::new(100, 100, 0, 0).is_global(), false);

// The loopback addresses (`127.0.0.0/8`)
assert_eq!(Ipv4Addr::LOCALHOST.is_global(), false);

// Link-local addresses (`169.254.0.0/16`)
assert_eq!(Ipv4Addr::new(169, 254, 45, 1).is_global(), false);

// Addresses reserved for documentation (`192.0.2.0/24`, `198.51.100.0/24`, `203.0.113.0/24`)
assert_eq!(Ipv4Addr::new(192, 0, 2, 255).is_global(), false);
assert_eq!(Ipv4Addr::new(198, 51, 100, 65).is_global(), false);
assert_eq!(Ipv4Addr::new(203, 0, 113, 6).is_global(), false);

// Addresses reserved for benchmarking (`198.18.0.0/15`)
assert_eq!(Ipv4Addr::new(198, 18, 0, 0).is_global(), false);

// Reserved addresses (`240.0.0.0/4`)
assert_eq!(Ipv4Addr::new(250, 10, 20, 30).is_global(), false);

// The broadcast address (`255.255.255.255`)
assert_eq!(Ipv4Addr::BROADCAST.is_global(), false);

// For a complete overview see the IANA IPv4 Special-Purpose Address Registry.

const fn is_shared(self: &Self) -> bool

Returns true if this address is part of the Shared Address Space defined in IETF RFC 6598 (100.64.0.0/10).

Examples

#![feature(ip)]
use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(100, 64, 0, 0).is_shared(), true);
assert_eq!(Ipv4Addr::new(100, 127, 255, 255).is_shared(), true);
assert_eq!(Ipv4Addr::new(100, 128, 0, 0).is_shared(), false);

const fn is_benchmarking(self: &Self) -> bool

Returns true if this address part of the 198.18.0.0/15 range, which is reserved for network devices benchmarking.

This range is defined in IETF RFC 2544 as 192.18.0.0 through 198.19.255.255 but errata 423 corrects it to 198.18.0.0/15.

Examples

#![feature(ip)]
use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(198, 17, 255, 255).is_benchmarking(), false);
assert_eq!(Ipv4Addr::new(198, 18, 0, 0).is_benchmarking(), true);
assert_eq!(Ipv4Addr::new(198, 19, 255, 255).is_benchmarking(), true);
assert_eq!(Ipv4Addr::new(198, 20, 0, 0).is_benchmarking(), false);

const fn is_reserved(self: &Self) -> bool

Returns true if this address is reserved by IANA for future use.

IETF RFC 1112 defines the block of reserved addresses as 240.0.0.0/4. This range normally includes the broadcast address 255.255.255.255, but this implementation explicitly excludes it, since it is obviously not reserved for future use.

Warning

As IANA assigns new addresses, this method will be updated. This may result in non-reserved addresses being treated as reserved in code that relies on an outdated version of this method.

Examples

#![feature(ip)]
use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(240, 0, 0, 0).is_reserved(), true);
assert_eq!(Ipv4Addr::new(255, 255, 255, 254).is_reserved(), true);

assert_eq!(Ipv4Addr::new(239, 255, 255, 255).is_reserved(), false);
// The broadcast address is not considered as reserved for future use by this implementation
assert_eq!(Ipv4Addr::new(255, 255, 255, 255).is_reserved(), false);

const fn is_multicast(self: &Self) -> bool

Returns true if this is a multicast address (224.0.0.0/4).

Multicast addresses have a most significant octet between 224 and 239, and is defined by IETF RFC 5771.

Examples

use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(224, 254, 0, 0).is_multicast(), true);
assert_eq!(Ipv4Addr::new(236, 168, 10, 65).is_multicast(), true);
assert_eq!(Ipv4Addr::new(172, 16, 10, 65).is_multicast(), false);

const fn is_broadcast(self: &Self) -> bool

Returns true if this is a broadcast address (255.255.255.255).

A broadcast address has all octets set to 255 as defined in IETF RFC 919.

Examples

use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(255, 255, 255, 255).is_broadcast(), true);
assert_eq!(Ipv4Addr::new(236, 168, 10, 65).is_broadcast(), false);

const fn is_documentation(self: &Self) -> bool

Returns true if this address is in a range designated for documentation.

This is defined in IETF RFC 5737:

• 192.0.2.0/24 (TEST-NET-1)
• 198.51.100.0/24 (TEST-NET-2)
• 203.0.113.0/24 (TEST-NET-3)

Examples

use std::net::Ipv4Addr;

assert_eq!(Ipv4Addr::new(192, 0, 2, 255).is_documentation(), true);
assert_eq!(Ipv4Addr::new(198, 51, 100, 65).is_documentation(), true);
assert_eq!(Ipv4Addr::new(203, 0, 113, 6).is_documentation(), true);
assert_eq!(Ipv4Addr::new(193, 34, 17, 19).is_documentation(), false);

const fn to_ipv6_compatible(self: &Self) -> Ipv6Addr

Converts this address to an IPv4-compatible IPv6 address.

a.b.c.d becomes ::a.b.c.d

Note that IPv4-compatible addresses have been officially deprecated. If you don't explicitly need an IPv4-compatible address for legacy reasons, consider using to_ipv6_mapped instead.

Examples

use std::net::{Ipv4Addr, Ipv6Addr};

assert_eq!(
    Ipv4Addr::new(192, 0, 2, 255).to_ipv6_compatible(),
    Ipv6Addr::new(0, 0, 0, 0, 0, 0, 0xc000, 0x2ff)
);

const fn to_ipv6_mapped(self: &Self) -> Ipv6Addr

Converts this address to an IPv4-mapped IPv6 address.

a.b.c.d becomes ::ffff:a.b.c.d

Examples

use std::net::{Ipv4Addr, Ipv6Addr};

assert_eq!(Ipv4Addr::new(192, 0, 2, 255).to_ipv6_mapped(),
           Ipv6Addr::new(0, 0, 0, 0, 0, 0xffff, 0xc000, 0x2ff));

impl Ipv4Addr

fn parse_ascii(b: &[u8]) -> Result<Self, AddrParseError>

Parse an IPv4 address from a slice of bytes.

#![feature(addr_parse_ascii)]

use std::net::Ipv4Addr;

let localhost = Ipv4Addr::new(127, 0, 0, 1);

assert_eq!(Ipv4Addr::parse_ascii(b"127.0.0.1"), Ok(localhost));

impl BitAnd for Ipv4Addr

fn bitand(self: Self, rhs: Ipv4Addr) -> Ipv4Addr

impl BitAnd for Ipv4Addr

fn bitand(self: Self, rhs: &Ipv4Addr) -> Ipv4Addr

impl BitAndAssign for Ipv4Addr

fn bitand_assign(self: &mut Self, rhs: Ipv4Addr)

impl BitAndAssign for Ipv4Addr

fn bitand_assign(self: &mut Self, rhs: &Ipv4Addr)

impl BitOr for Ipv4Addr

fn bitor(self: Self, rhs: Ipv4Addr) -> Ipv4Addr

impl BitOr for Ipv4Addr

fn bitor(self: Self, rhs: &Ipv4Addr) -> Ipv4Addr

impl BitOrAssign for Ipv4Addr

fn bitor_assign(self: &mut Self, rhs: Ipv4Addr)

impl BitOrAssign for Ipv4Addr

fn bitor_assign(self: &mut Self, rhs: &Ipv4Addr)

impl Clone for Ipv4Addr

fn clone(self: &Self) -> Ipv4Addr

impl Copy for Ipv4Addr

impl Debug for Ipv4Addr

fn fmt(self: &Self, fmt: &mut Formatter<'_>) -> Result

impl Display for Ipv4Addr

fn fmt(self: &Self, fmt: &mut Formatter<'_>) -> Result

impl Eq for Ipv4Addr

impl Freeze for Ipv4Addr

impl From for Ipv4Addr

fn from(ip: u32) -> Ipv4Addr

Uses Ipv4Addr::from_bits to convert a host byte order u32 into an IPv4 address.

impl From for Ipv4Addr

fn from(octets: [u8; 4]) -> Ipv4Addr

Creates an Ipv4Addr from a four element byte array.

Examples

use std::net::Ipv4Addr;

let addr = Ipv4Addr::from([13u8, 12u8, 11u8, 10u8]);
assert_eq!(Ipv4Addr::new(13, 12, 11, 10), addr);

impl FromStr for Ipv4Addr

fn from_str(s: &str) -> Result<Ipv4Addr, AddrParseError>

impl Hash for Ipv4Addr

fn hash<H: Hasher>(self: &Self, state: &mut H)

impl Not for Ipv4Addr

fn not(self: Self) -> Ipv4Addr

impl Ord for Ipv4Addr

fn cmp(self: &Self, other: &Ipv4Addr) -> Ordering

impl PartialEq for Ipv4Addr

fn eq(self: &Self, other: &IpAddr) -> bool

impl PartialEq for Ipv4Addr

fn eq(self: &Self, other: &Ipv4Addr) -> bool

impl PartialOrd for Ipv4Addr

fn partial_cmp(self: &Self, other: &Ipv4Addr) -> Option<Ordering>

impl PartialOrd for Ipv4Addr

fn partial_cmp(self: &Self, other: &IpAddr) -> Option<Ordering>

impl RefUnwindSafe for Ipv4Addr

impl Send for Ipv4Addr

impl Step for Ipv4Addr

fn steps_between(start: &Ipv4Addr, end: &Ipv4Addr) -> (usize, Option<usize>)

fn forward_checked(start: Ipv4Addr, count: usize) -> Option<Ipv4Addr>

fn backward_checked(start: Ipv4Addr, count: usize) -> Option<Ipv4Addr>

unsafe fn forward_unchecked(start: Ipv4Addr, count: usize) -> Ipv4Addr

unsafe fn backward_unchecked(start: Ipv4Addr, count: usize) -> Ipv4Addr

impl StructuralPartialEq for Ipv4Addr

impl Sync for Ipv4Addr

impl TrustedStep for Ipv4Addr

impl Unpin for Ipv4Addr

impl UnsafeUnpin for Ipv4Addr

impl UnwindSafe for Ipv4Addr

impl<T> Any for Ipv4Addr

fn type_id(self: &Self) -> TypeId

impl<T> Borrow for Ipv4Addr

fn borrow(self: &Self) -> &T

impl<T> BorrowMut for Ipv4Addr

fn borrow_mut(self: &mut Self) -> &mut T

impl<T> CloneToUninit for Ipv4Addr

unsafe fn clone_to_uninit(self: &Self, dest: *mut u8)

impl<T> From for Ipv4Addr

fn from(t: T) -> T

Returns the argument unchanged.

impl<T, U> Into for Ipv4Addr

fn into(self: Self) -> U

Calls U::from(self).

That is, this conversion is whatever the implementation of [From]<T> for U chooses to do.

impl<T, U> TryFrom for Ipv4Addr

fn try_from(value: U) -> Result<T, <T as TryFrom<U>>::Error>

impl<T, U> TryInto for Ipv4Addr

fn try_into(self: Self) -> Result<U, <U as TryFrom<T>>::Error>