use crate :: cmp :: Ordering ; use crate :: fmt :: { self , Write as FmtWrite } ; use crate :: hash ; use crate :: io :: Write as IoWrite ; use crate :: mem :: transmute ; use crate :: sys :: net :: netc as c ; use crate :: sys_common :: { AsInner , FromInner , IntoInner } ; # [derive (Copy , Clone , Eq , PartialEq , Hash , PartialOrd , Ord)] pub enum IpAddr { V4 (Ipv4Addr) , V6 (Ipv6Addr) , } # [derive (Copy)] pub struct Ipv4Addr { inner : c :: in_addr , } # [derive (Copy)] pub struct Ipv6Addr { inner : c :: in6_addr , } # [derive (Copy , PartialEq , Eq , Clone , Hash , Debug)] # [non_exhaustive] pub enum Ipv6MulticastScope { InterfaceLocal , LinkLocal , RealmLocal , AdminLocal , SiteLocal , OrganizationLocal , Global , } impl IpAddr { pub const fn is_unspecified (& self) -> bool { match self { IpAddr :: V4 (ip) => ip . is_unspecified () , IpAddr :: V6 (ip) => ip . is_unspecified () , } } pub const fn is_loopback (& self) -> bool { match self { IpAddr :: V4 (ip) => ip . is_loopback () , IpAddr :: V6 (ip) => ip . is_loopback () , } } pub const fn is_global (& self) -> bool { match self { IpAddr :: V4 (ip) => ip . is_global () , IpAddr :: V6 (ip) => ip . is_global () , } } pub const fn is_multicast (& self) -> bool { match self { IpAddr :: V4 (ip) => ip . is_multicast () , IpAddr :: V6 (ip) => ip . is_multicast () , } } pub const fn is_documentation (& self) -> bool { match self { IpAddr :: V4 (ip) => ip . is_documentation () , IpAddr :: V6 (ip) => ip . is_documentation () , } } pub const fn is_benchmarking (& self) -> bool { match self { IpAddr :: V4 (ip) => ip . is_benchmarking () , IpAddr :: V6 (ip) => ip . is_benchmarking () , } } pub const fn is_ipv4 (& self) -> bool { matches ! (self , IpAddr :: V4 (_)) } pub const fn is_ipv6 (& self) -> bool { matches ! (self , IpAddr :: V6 (_)) } pub const fn to_canonical (& self) -> IpAddr { match self { & v4 @ IpAddr :: V4 (_) => v4 , IpAddr :: V6 (v6) => v6 . to_canonical () , } } } impl Ipv4Addr { pub const fn new (a : u8 , b : u8 , c : u8 , d : u8) -> Ipv4Addr { Ipv4Addr { inner : c :: in_addr { s_addr : u32 :: from_ne_bytes ([a , b , c , d]) } } } pub const LOCALHOST : Self = Ipv4Addr :: new (127 , 0 , 0 , 1) ; # [doc (alias = "INADDR_ANY")] pub const UNSPECIFIED : Self = Ipv4Addr :: new (0 , 0 , 0 , 0) ; pub const BROADCAST : Self = Ipv4Addr :: new (255 , 255 , 255 , 255) ; pub const fn octets (& self) -> [u8 ; 4] { self . inner . s_addr . to_ne_bytes () } pub const fn is_unspecified (& self) -> bool { self . inner . s_addr == 0 } pub const fn is_loopback (& self) -> bool { self . octets () [0] == 127 } pub const fn is_private (& self) -> bool { match self . octets () { [10 , ..] => true , [172 , b , ..] if b >= 16 && b <= 31 => true , [192 , 168 , ..] => true , _ => false , } } pub const fn is_link_local (& self) -> bool { matches ! (self . octets () , [169 , 254 , ..]) } pub const fn is_global (& self) -> bool { if u32 :: from_be_bytes (self . octets ()) == 0xc0000009 || u32 :: from_be_bytes (self . octets ()) == 0xc000000a { return true ; } ! self . is_private () && ! self . is_loopback () && ! self . is_link_local () && ! self . is_broadcast () && ! self . is_documentation () && ! self . is_shared () && ! (self . octets () [0] == 192 && self . octets () [1] == 0 && self . octets () [2] == 0) && ! self . is_reserved () && ! self . is_benchmarking () && self . octets () [0] != 0 } pub const fn is_shared (& self) -> bool { self . octets () [0] == 100 && (self . octets () [1] & 0b1100_0000 == 0b0100_0000) } pub const fn is_benchmarking (& self) -> bool { self . octets () [0] == 198 && (self . octets () [1] & 0xfe) == 18 } pub const fn is_reserved (& self) -> bool { self . octets () [0] & 240 == 240 && ! self . is_broadcast () } pub const fn is_multicast (& self) -> bool { self . octets () [0] >= 224 && self . octets () [0] <= 239 } pub const fn is_broadcast (& self) -> bool { u32 :: from_be_bytes (self . octets ()) == u32 :: from_be_bytes (Self :: BROADCAST . octets ()) } pub const fn is_documentation (& self) -> bool { matches ! (self . octets () , [192 , 0 , 2 , _] | [198 , 51 , 100 , _] | [203 , 0 , 113 , _]) } pub const fn to_ipv6_compatible (& self) -> Ipv6Addr { let [a , b , c , d] = self . octets () ; Ipv6Addr { inner : c :: in6_addr { s6_addr : [0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , a , b , c , d] } , } } pub const fn to_ipv6_mapped (& self) -> Ipv6Addr { let [a , b , c , d] = self . octets () ; Ipv6Addr { inner : c :: in6_addr { s6_addr : [0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0xFF , 0xFF , a , b , c , d] } , } } } impl fmt :: Display for IpAddr { fn fmt (& self , fmt : & mut fmt :: Formatter < '_ >) -> fmt :: Result { match self { IpAddr :: V4 (ip) => ip . fmt (fmt) , IpAddr :: V6 (ip) => ip . fmt (fmt) , } } } impl fmt :: Debug for IpAddr { fn fmt (& self , fmt : & mut fmt :: Formatter < '_ >) -> fmt :: Result { fmt :: Display :: fmt (self , fmt) } } impl From < Ipv4Addr > for IpAddr { fn from (ipv4 : Ipv4Addr) -> IpAddr { IpAddr :: V4 (ipv4) } } impl From < Ipv6Addr > for IpAddr { fn from (ipv6 : Ipv6Addr) -> IpAddr { IpAddr :: V6 (ipv6) } } impl fmt :: Display for Ipv4Addr { fn fmt (& self , fmt : & mut fmt :: Formatter < '_ >) -> fmt :: Result { let octets = self . octets () ; if fmt . precision () . is_none () && fmt . width () . is_none () { write ! (fmt , "{}.{}.{}.{}" , octets [0] , octets [1] , octets [2] , octets [3]) } else { const IPV4_BUF_LEN : usize = 15 ; let mut buf = [0u8 ; IPV4_BUF_LEN] ; let mut buf_slice = & mut buf [..] ; write ! (buf_slice , "{}.{}.{}.{}" , octets [0] , octets [1] , octets [2] , octets [3]) . unwrap () ; let len = IPV4_BUF_LEN - buf_slice . len () ; let buf = unsafe { crate :: str :: from_utf8_unchecked (& buf [.. len]) } ; fmt . pad (buf) } } } impl fmt :: Debug for Ipv4Addr { fn fmt (& self , fmt : & mut fmt :: Formatter < '_ >) -> fmt :: Result { fmt :: Display :: fmt (self , fmt) } } impl Clone for Ipv4Addr { fn clone (& self) -> Ipv4Addr { * self } } impl PartialEq for Ipv4Addr { fn eq (& self , other : & Ipv4Addr) -> bool { self . inner . s_addr == other . inner . s_addr } } impl PartialEq < Ipv4Addr > for IpAddr { fn eq (& self , other : & Ipv4Addr) -> bool { match self { IpAddr :: V4 (v4) => v4 == other , IpAddr :: V6 (_) => false , } } } impl PartialEq < IpAddr > for Ipv4Addr { fn eq (& self , other : & IpAddr) -> bool { match other { IpAddr :: V4 (v4) => self == v4 , IpAddr :: V6 (_) => false , } } } impl Eq for Ipv4Addr { } impl hash :: Hash for Ipv4Addr { fn hash < H : hash :: Hasher > (& self , s : & mut H) { { self . inner . s_addr } . hash (s) } } impl PartialOrd for Ipv4Addr { fn partial_cmp (& self , other : & Ipv4Addr) -> Option < Ordering > { Some (self . cmp (other)) } } impl PartialOrd < Ipv4Addr > for IpAddr { fn partial_cmp (& self , other : & Ipv4Addr) -> Option < Ordering > { match self { IpAddr :: V4 (v4) => v4 . partial_cmp (other) , IpAddr :: V6 (_) => Some (Ordering :: Greater) , } } } impl PartialOrd < IpAddr > for Ipv4Addr { fn partial_cmp (& self , other : & IpAddr) -> Option < Ordering > { match other { IpAddr :: V4 (v4) => self . partial_cmp (v4) , IpAddr :: V6 (_) => Some (Ordering :: Less) , } } } impl Ord for Ipv4Addr { fn cmp (& self , other : & Ipv4Addr) -> Ordering { u32 :: from_be (self . inner . s_addr) . cmp (& u32 :: from_be (other . inner . s_addr)) } } impl IntoInner < c :: in_addr > for Ipv4Addr { fn into_inner (self) -> c :: in_addr { self . inner } } impl From < Ipv4Addr > for u32 { fn from (ip : Ipv4Addr) -> u32 { let ip = ip . octets () ; u32 :: from_be_bytes (ip) } } impl From < u32 > for Ipv4Addr { fn from (ip : u32) -> Ipv4Addr { Ipv4Addr :: from (ip . to_be_bytes ()) } } impl From < [u8 ; 4] > for Ipv4Addr { fn from (octets : [u8 ; 4]) -> Ipv4Addr { Ipv4Addr :: new (octets [0] , octets [1] , octets [2] , octets [3]) } } impl From < [u8 ; 4] > for IpAddr { fn from (octets : [u8 ; 4]) -> IpAddr { IpAddr :: V4 (Ipv4Addr :: from (octets)) } } impl Ipv6Addr { pub const fn new (a : u16 , b : u16 , c : u16 , d : u16 , e : u16 , f : u16 , g : u16 , h : u16) -> Ipv6Addr { let addr16 = [a . to_be () , b . to_be () , c . to_be () , d . to_be () , e . to_be () , f . to_be () , g . to_be () , h . to_be () ,] ; Ipv6Addr { inner : c :: in6_addr { s6_addr : unsafe { transmute :: < _ , [u8 ; 16] > (addr16) } , } , } } pub const LOCALHOST : Self = Ipv6Addr :: new (0 , 0 , 0 , 0 , 0 , 0 , 0 , 1) ; pub const UNSPECIFIED : Self = Ipv6Addr :: new (0 , 0 , 0 , 0 , 0 , 0 , 0 , 0) ; pub const fn segments (& self) -> [u16 ; 8] { let [a , b , c , d , e , f , g , h] = unsafe { transmute :: < _ , [u16 ; 8] > (self . inner . s6_addr) } ; [u16 :: from_be (a) , u16 :: from_be (b) , u16 :: from_be (c) , u16 :: from_be (d) , u16 :: from_be (e) , u16 :: from_be (f) , u16 :: from_be (g) , u16 :: from_be (h) ,] } pub const fn is_unspecified (& self) -> bool { u128 :: from_be_bytes (self . octets ()) == u128 :: from_be_bytes (Ipv6Addr :: UNSPECIFIED . octets ()) } pub const fn is_loopback (& self) -> bool { u128 :: from_be_bytes (self . octets ()) == u128 :: from_be_bytes (Ipv6Addr :: LOCALHOST . octets ()) } pub const fn is_global (& self) -> bool { match self . multicast_scope () { Some (Ipv6MulticastScope :: Global) => true , None => self . is_unicast_global () , _ => false , } } pub const fn is_unique_local (& self) -> bool { (self . segments () [0] & 0xfe00) == 0xfc00 } pub const fn is_unicast (& self) -> bool { ! self . is_multicast () } pub const fn is_unicast_link_local (& self) -> bool { (self . segments () [0] & 0xffc0) == 0xfe80 } pub const fn is_documentation (& self) -> bool { (self . segments () [0] == 0x2001) && (self . segments () [1] == 0xdb8) } pub const fn is_benchmarking (& self) -> bool { (self . segments () [0] == 0x2001) && (self . segments () [1] == 0x2) && (self . segments () [2] == 0) } pub const fn is_unicast_global (& self) -> bool { self . is_unicast () && ! self . is_loopback () && ! self . is_unicast_link_local () && ! self . is_unique_local () && ! self . is_unspecified () && ! self . is_documentation () } pub const fn multicast_scope (& self) -> Option < Ipv6MulticastScope > { if self . is_multicast () { match self . segments () [0] & 0x000f { 1 => Some (Ipv6MulticastScope :: InterfaceLocal) , 2 => Some (Ipv6MulticastScope :: LinkLocal) , 3 => Some (Ipv6MulticastScope :: RealmLocal) , 4 => Some (Ipv6MulticastScope :: AdminLocal) , 5 => Some (Ipv6MulticastScope :: SiteLocal) , 8 => Some (Ipv6MulticastScope :: OrganizationLocal) , 14 => Some (Ipv6MulticastScope :: Global) , _ => None , } } else { None } } pub const fn is_multicast (& self) -> bool { (self . segments () [0] & 0xff00) == 0xff00 } pub const fn to_ipv4_mapped (& self) -> Option < Ipv4Addr > { match self . octets () { [0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0xff , 0xff , a , b , c , d] => { Some (Ipv4Addr :: new (a , b , c , d)) } _ => None , } } pub const fn to_ipv4 (& self) -> Option < Ipv4Addr > { if let [0 , 0 , 0 , 0 , 0 , 0 | 0xffff , ab , cd] = self . segments () { let [a , b] = ab . to_be_bytes () ; let [c , d] = cd . to_be_bytes () ; Some (Ipv4Addr :: new (a , b , c , d)) } else { None } } pub const fn to_canonical (& self) -> IpAddr { if let Some (mapped) = self . to_ipv4_mapped () { return IpAddr :: V4 (mapped) ; } IpAddr :: V6 (* self) } pub const fn octets (& self) -> [u8 ; 16] { self . inner . s6_addr } } impl fmt :: Display for Ipv6Addr { fn fmt (& self , f : & mut fmt :: Formatter < '_ >) -> fmt :: Result { if f . precision () . is_none () && f . width () . is_none () { let segments = self . segments () ; if self . is_unspecified () { f . write_str ("::") } else if self . is_loopback () { f . write_str ("::1") } else if let Some (ipv4) = self . to_ipv4 () { match segments [5] { 0 => write ! (f , "::{}" , ipv4) , 0xffff => write ! (f , "::ffff:{}" , ipv4) , _ => unreachable ! () , } } else { # [derive (Copy , Clone , Default)] struct Span { start : usize , len : usize , } let zeroes = { let mut longest = Span :: default () ; let mut current = Span :: default () ; for (i , & segment) in segments . iter () . enumerate () { if segment == 0 { if current . len == 0 { current . start = i ; } current . len += 1 ; if current . len > longest . len { longest = current ; } } else { current = Span :: default () ; } } longest } ; # [doc = " Write a colon-separated part of the address"] # [inline] fn fmt_subslice (f : & mut fmt :: Formatter < '_ > , chunk : & [u16]) -> fmt :: Result { if let Some ((first , tail)) = chunk . split_first () { write ! (f , "{:x}" , first) ? ; for segment in tail { f . write_char (':') ? ; write ! (f , "{:x}" , segment) ? ; } } Ok (()) } if zeroes . len > 1 { fmt_subslice (f , & segments [.. zeroes . start]) ? ; f . write_str ("::") ? ; fmt_subslice (f , & segments [zeroes . start + zeroes . len ..]) } else { fmt_subslice (f , & segments) } } } else { const IPV6_BUF_LEN : usize = (4 * 8) + 7 ; let mut buf = [0u8 ; IPV6_BUF_LEN] ; let mut buf_slice = & mut buf [..] ; write ! (buf_slice , "{}" , self) . unwrap () ; let len = IPV6_BUF_LEN - buf_slice . len () ; let buf = unsafe { crate :: str :: from_utf8_unchecked (& buf [.. len]) } ; f . pad (buf) } } } impl fmt :: Debug for Ipv6Addr { fn fmt (& self , fmt : & mut fmt :: Formatter < '_ >) -> fmt :: Result { fmt :: Display :: fmt (self , fmt) } } impl Clone for Ipv6Addr { fn clone (& self) -> Ipv6Addr { * self } } impl PartialEq for Ipv6Addr { fn eq (& self , other : & Ipv6Addr) -> bool { self . inner . s6_addr == other . inner . s6_addr } } impl PartialEq < IpAddr > for Ipv6Addr { fn eq (& self , other : & IpAddr) -> bool { match other { IpAddr :: V4 (_) => false , IpAddr :: V6 (v6) => self == v6 , } } } impl PartialEq < Ipv6Addr > for IpAddr { fn eq (& self , other : & Ipv6Addr) -> bool { match self { IpAddr :: V4 (_) => false , IpAddr :: V6 (v6) => v6 == other , } } } impl Eq for Ipv6Addr { } impl hash :: Hash for Ipv6Addr { fn hash < H : hash :: Hasher > (& self , s : & mut H) { self . inner . s6_addr . hash (s) } } impl PartialOrd for Ipv6Addr { fn partial_cmp (& self , other : & Ipv6Addr) -> Option < Ordering > { Some (self . cmp (other)) } } impl PartialOrd < Ipv6Addr > for IpAddr { fn partial_cmp (& self , other : & Ipv6Addr) -> Option < Ordering > { match self { IpAddr :: V4 (_) => Some (Ordering :: Less) , IpAddr :: V6 (v6) => v6 . partial_cmp (other) , } } } impl PartialOrd < IpAddr > for Ipv6Addr { fn partial_cmp (& self , other : & IpAddr) -> Option < Ordering > { match other { IpAddr :: V4 (_) => Some (Ordering :: Greater) , IpAddr :: V6 (v6) => self . partial_cmp (v6) , } } } impl Ord for Ipv6Addr { fn cmp (& self , other : & Ipv6Addr) -> Ordering { self . segments () . cmp (& other . segments ()) } } impl AsInner < c :: in6_addr > for Ipv6Addr { fn as_inner (& self) -> & c :: in6_addr { & self . inner } } impl FromInner < c :: in6_addr > for Ipv6Addr { fn from_inner (addr : c :: in6_addr) -> Ipv6Addr { Ipv6Addr { inner : addr } } } impl From < Ipv6Addr > for u128 { fn from (ip : Ipv6Addr) -> u128 { let ip = ip . octets () ; u128 :: from_be_bytes (ip) } } impl From < u128 > for Ipv6Addr { fn from (ip : u128) -> Ipv6Addr { Ipv6Addr :: from (ip . to_be_bytes ()) } } impl From < [u8 ; 16] > for Ipv6Addr { fn from (octets : [u8 ; 16]) -> Ipv6Addr { let inner = c :: in6_addr { s6_addr : octets } ; Ipv6Addr :: from_inner (inner) } } impl From < [u16 ; 8] > for Ipv6Addr { fn from (segments : [u16 ; 8]) -> Ipv6Addr { let [a , b , c , d , e , f , g , h] = segments ; Ipv6Addr :: new (a , b , c , d , e , f , g , h) } } impl From < [u8 ; 16] > for IpAddr { fn from (octets : [u8 ; 16]) -> IpAddr { IpAddr :: V6 (Ipv6Addr :: from (octets)) } } impl From < [u16 ; 8] > for IpAddr { fn from (segments : [u16 ; 8]) -> IpAddr { IpAddr :: V6 (Ipv6Addr :: from (segments)) } }