ref: feb6d6f0a32e5dac88d1ef46bbc4396ec44ce40b
dir: /sys/man/2/ip/
.TH IP 2 .SH NAME eipfmt, parseip, parseipmask, parseipandmask, v4parseip, parseether, myipaddr, myetheraddr, maskip, equivip4, equivip6, defmask, isv4, v4tov6, v6tov4, nhgetv, nhgetl, nhgets, hnputv, hnputl, hnputs, ptclbsum, readipifc \- Internet Protocol addressing .SH SYNOPSIS .B #include <u.h> .br .B #include <libc.h> .br .B #include <ip.h> .PP .B int eipfmt(Fmt*) .PP .B vlong parseip(uchar *ipaddr, char *str) .PP .B vlong parseipmask(uchar *ipaddr, char *str, int v4) .PP .B vlong parseipandmask(uchar *ipaddr, uchar *ipmask, char *ipstr, char *maskstr) .PP .B char* v4parseip(uchar *ipaddr, char *str) .PP .B int parseether(uchar *eaddr, char *str) .PP .B int myetheraddr(uchar *eaddr, char *dev) .PP .B int myipaddr(uchar *ipaddr, char *net) .PP .B void maskip(uchar *from, uchar *mask, uchar *to) .PP .B int equivip4(uchar *ipaddr1, uchar *ipaddr2) .PP .B int equivip6(uchar *ipaddr1, uchar *ipaddr2) .PP .B uchar* defmask(uchar *ipaddr) .PP .B int isv4(uchar *ipaddr) .PP .B void v4tov6(uchar *ipv6, uchar *ipv4) .PP .B int v6tov4(uchar *ipv4, uchar *ipv6) .PP .B ushort nhgets(void *p) .PP .B uint nhgetl(void *p) .PP .B uvlong nhgetv(void *p) .PP .B void hnputs(void *p, ushort v) .PP .B void hnputl(void *p, uint v) .PP .B void hnputv(void *p, uvlong v) .PP .B ushort ptclbsum(uchar *a, int n) .PP .B Ipifc* readipifc(char *net, Ipifc *ifc, int index) .PP .B uchar IPv4bcast[IPaddrlen]; .PP .B uchar IPv4allsys[IPaddrlen]; .PP .B uchar IPv4allrouter[IPaddrlen]; .PP .B uchar IPallbits[IPaddrlen]; .PP .B uchar IPnoaddr[IPaddrlen]; .PP .B uchar v4prefix[IPaddrlen]; .SH DESCRIPTION These routines are used by Internet Protocol (IP) programs to manipulate IP and Ethernet addresses. Plan 9, by default, uses V6 format IP addresses. Since V4 addresses fit into the V6 space, all IP addresses can be represented. IP addresses are stored as a string of 16 .B unsigned .BR chars , Ethernet addresses as 6 .B unsigned .BR chars . Either V4 or V6 string representation can be used for IP addresses. For V4 addresses, the representation can be (up to) 4 decimal integers from 0 to 255 separated by periods. For V6 addresses, the representation is (up to) 8 hex integers from 0x0 to 0xFFFF separated by colons. Strings of 0 integers can be elided using two colons. For example, .B FFFF::1111 is equivalent to .BR FFFF:0:0:0:0:0:0:1111 . The string representation for IP masks is a superset of the address representation. It includes slash notation that indicates the number of leading 1 bits in the mask. Thus, a V4 class C mask can be represented as .BR FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FF00 , .BR 255.255.255.0 , or .BR /120. The string representation of Ethernet addresses is exactly 12 hexadecimal digits. .PP .I Eipfmt is a .IR print (2) formatter for Ethernet (verb .BR E ) addresses, IP V6 (verb .BR I ) addresses, IP V4 (verb .BR V ) addresses, and IP V6 (verb .BR M ) masks. .PP .I Parseip converts a string pointed to by .I str to a 16-byte IP address starting at .IR ipaddr . As a concession to backwards compatibility, if the string is a V4 address, the return value is an unsigned long integer containing the big-endian V4 address. If not, the return value is 6. .PP .I Parseipmask converts a string pointed to by .I str to a 16-byte IP mask starting at .IR ipaddr . It too returns an unsigned long big-endian V4 address or 6. .I Parseipmask accepts a mask in .BI / prefixlen slash notation. When the .IR v4 argument is non-zero, then .I prefixlen in range [0..32] is offset by 96 to yield a mask for a V4 address. .PP .I Parseipandmask combines .I parseip and .I parseipmask into a single call, interpreting the mask in context of the supplied IP address type. The returned IP mask is .B /128 when .I maskstr is .BR nil . .PP All three functions return -1 on errors. .PP .I V4parseip converts a string pointed to by .I str to a 4-byte V4 IP address starting at .IR ipaddr . .PP .I Myipaddr returns the first valid IP address in the IP stack rooted at .IR net . .PP .I Parseether converts a string pointed to by .I str to a 6-byte Ethernet address starting at .IR eaddr . .I Myetheraddr reads the Ethernet address string from file .IB dev /addr and parses it into .IR eaddr . Both routines return a negative number on errors. .PP .I Maskip places the bit-wise AND of the IP addresses pointed to by its first two arguments into the buffer pointed to by the third. .PP .I Equivip returns non-zero if the IP addresses pointed to by its two arguments are equal. .I Equivip4 operates on v4 addresses, .I equivip6 operates on v6 addresses. .PP .I Defmask returns the standard class A, B, or C mask for .I ipaddr . .PP .I Isv4 returns non-zero if the V6 address is in the V4 space, that is, if it starts with .BR 0:0:0:0:0:0:FFFF . .I V4tov6 converts the 4-byte V4 address, .IR v4ip , to a V6 address and puts the result in .IR v6ip . .I V6tov4 converts the V6 address, .IR v6ip , to a 4-byte V4 address and puts the result in .IR v4ip . .PP .IR Hnputs , .I hnputl and .I hnputv are used to store 16-bit, 32-bit, and 64-bit integers, respectively, into IP big-endian form. .IR Nhgets , .I nhgetl and .I nhgetv convert big-endian 2, 4 and 8 byte quantities into integers (or .IR uvlong s). .PP .I Pctlbsum returns the one's complement checksum used in IP protocols, typically invoked as .IP .EX hnputs(hdr->cksum, ~ptclbsum(data, len) & 0xffff); .EE .PP A number of standard IP addresses in V6 format are also defined. They are: .TF IPv4allrouter .TP .B IPv4bcast the V4 broadcast address .TP .B IPv4allsys the V4 all systems multicast address .TP .B IPv4allrouter the V4 all routers multicast address .TP .B IPallbits the V6 all bits on address .TP .B IPnoaddr the V6 null address, all zeros .TP .B v4prefix the IP V6 prefix to all embedded V4 addresses .PD .PP .I Readipifc returns information about a particular interface .RI ( index >= 0) or all IP interfaces .RI ( index < 0) configured under a mount point .IR net , default .BR /net . Each interface is described by one .I Ipifc structure which in turn points to a linked list of .IR Iplifc structures describing the addresses assigned to this interface. If the list .IR ifc is supplied, that list is freed. Thus, subsequent calls can be used to free the list returned by the previous call. .I Ipifc is: .PP .EX typedef struct Ipifc { Ipifc *next; Iplifc *lifc; /* local addressses */ /* per ip interface */ int index; /* number of interface in ipifc dir */ char dev[64]; /* associated physical device */ int mtu; /* max transfer unit */ uchar sendra6; /* on == send router adv */ uchar recvra6; /* on == rcv router adv */ ulong pktin; /* packets read */ ulong pktout; /* packets written */ ulong errin; /* read errors */ ulong errout; /* write errors */ Ipv6rp rp; /* route advertisement params */ } Ipifc; .EE .PP .I Iplifc is: .PP .EX struct Iplifc { Iplifc *next; uchar ip[IPaddrlen]; uchar mask[IPaddrlen]; uchar net[IPaddrlen]; /* ip & mask */ ulong preflt; /* preferred lifetime */ ulong validlt; /* valid lifetime */ }; .EE .PP .I Ipv6rp is: .PP .EX struct Ipv6rp { int mflag; int oflag; int maxraint; /* max route adv interval */ int minraint; /* min route adv interval */ int linkmtu; int reachtime; int rxmitra; int ttl; int routerlt; }; .EE .PP .I Dev contains the first 64 bytes of the device configured with this interface. .I Net is .IB ip & mask if the network is multipoint or the remote address if the network is point to point. .SH SOURCE .B /sys/src/libip .SH SEE ALSO .IR print (2), .IR ip (3)