/* * PostgreSQL type definitions for the INET type. This * is for IP V4 CIDR notation, but prepared for V6: just * add the necessary bits where the comments indicate. * * $Id: network.c,v 1.9 1999/05/25 16:12:11 momjian Exp $ * Jon Postel RIP 16 Oct 1998 */ #include #include #include #include #include #include #include #include #include #include #include static int v4bitncmp(unsigned int a1, unsigned int a2, int bits); /* * Access macros. Add IPV6 support. */ #define ip_addrsize(inetptr) \ (((inet_struct *)VARDATA(inetptr))->family == AF_INET ? 4 : -1) #define ip_family(inetptr) \ (((inet_struct *)VARDATA(inetptr))->family) #define ip_bits(inetptr) \ (((inet_struct *)VARDATA(inetptr))->bits) #define ip_type(inetptr) \ (((inet_struct *)VARDATA(inetptr))->type) #define ip_v4addr(inetptr) \ (((inet_struct *)VARDATA(inetptr))->addr.ipv4_addr) /* Common input routine */ static inet * network_in(char *src, int type) { int bits; inet *dst; if (!src) return NULL; dst = palloc(VARHDRSZ + sizeof(inet_struct)); if (dst == NULL) elog(ERROR, "unable to allocate memory in network_in()"); /* First, try for an IP V4 address: */ ip_family(dst) = AF_INET; bits = inet_net_pton(ip_family(dst), src, &ip_v4addr(dst), type ? ip_addrsize(dst) : -1); if ((bits < 0) || (bits > 32)) /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "could not parse \"%s\"", src); VARSIZE(dst) = VARHDRSZ + ((char *) &ip_v4addr(dst) - (char *) VARDATA(dst)) + ip_addrsize(dst); ip_bits(dst) = bits; ip_type(dst) = type; return dst; } /* INET address reader. */ inet * inet_in(char *src) { return network_in(src, 0); } /* CIDR address reader. */ inet * cidr_in(char *src) { return network_in(src, 1); } /* * INET address output function. */ char * inet_out(inet *src) { char *dst, tmp[sizeof("255.255.255.255/32")]; if (ip_family(src) == AF_INET) { /* It's an IP V4 address: */ if (ip_type(src)) dst = inet_cidr_ntop(AF_INET, &ip_v4addr(src), ip_bits(src), tmp, sizeof(tmp)); else dst = inet_net_ntop(AF_INET, &ip_v4addr(src), ip_bits(src), tmp, sizeof(tmp)); if (dst == NULL) elog(ERROR, "unable to print address (%s)", strerror(errno)); } else /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "unknown address family (%d)", ip_family(src)); dst = palloc(strlen(tmp) + 1); if (dst == NULL) elog(ERROR, "unable to allocate memory in inet_out()"); strcpy(dst, tmp); return dst; } /* just a stub */ char * cidr_out(inet *src) { return inet_out(src); } /* * Boolean tests for magnitude. Add V4/V6 testing! */ bool network_lt(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; if ((ip_family(a1) == AF_INET) && (ip_family(a2) == AF_INET)) { int order = v4bitncmp(ip_v4addr(a1), ip_v4addr(a2), ip_bits(a2)); return ((order < 0) || ((order == 0) && (ip_bits(a1) < ip_bits(a2)))); } else { /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "cannot compare address families %d and %d", ip_family(a1), ip_family(a2)); return FALSE; } } bool network_le(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; return (network_lt(a1, a2) || network_eq(a1, a2)); } bool network_eq(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; if ((ip_family(a1) == AF_INET) && (ip_family(a2) == AF_INET)) { return ((ip_bits(a1) == ip_bits(a2)) && (v4bitncmp(ip_v4addr(a1), ip_v4addr(a2), ip_bits(a1)) == 0)); } else { /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "cannot compare address families %d and %d", ip_family(a1), ip_family(a2)); return FALSE; } } bool network_ge(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; return (network_gt(a1, a2) || network_eq(a1, a2)); } bool network_gt(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; if ((ip_family(a1) == AF_INET) && (ip_family(a2) == AF_INET)) { int order = v4bitncmp(ip_v4addr(a1), ip_v4addr(a2), ip_bits(a2)); return ((order > 0) || ((order == 0) && (ip_bits(a1) > ip_bits(a2)))); } else { /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "cannot compare address families %d and %d", ip_family(a1), ip_family(a2)); return FALSE; } } bool network_ne(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; return (!network_eq(a1, a2)); } bool network_sub(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; if ((ip_family(a1) == AF_INET) && (ip_family(a2) == AF_INET)) { return ((ip_bits(a1) > ip_bits(a2)) && (v4bitncmp(ip_v4addr(a1), ip_v4addr(a2), ip_bits(a2)) == 0)); } else { /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "cannot compare address families %d and %d", ip_family(a1), ip_family(a2)); return FALSE; } } bool network_subeq(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; if ((ip_family(a1) == AF_INET) && (ip_family(a2) == AF_INET)) { return ((ip_bits(a1) >= ip_bits(a2)) && (v4bitncmp(ip_v4addr(a1), ip_v4addr(a2), ip_bits(a2)) == 0)); } else { /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "cannot compare address families %d and %d", ip_family(a1), ip_family(a2)); return FALSE; } } bool network_sup(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; if ((ip_family(a1) == AF_INET) && (ip_family(a2) == AF_INET)) { return ((ip_bits(a1) < ip_bits(a2)) && (v4bitncmp(ip_v4addr(a1), ip_v4addr(a2), ip_bits(a1)) == 0)); } else { /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "cannot compare address families %d and %d", ip_family(a1), ip_family(a2)); return FALSE; } } bool network_supeq(inet *a1, inet *a2) { if (!PointerIsValid(a1) || !PointerIsValid(a2)) return FALSE; if ((ip_family(a1) == AF_INET) && (ip_family(a2) == AF_INET)) { return ((ip_bits(a1) <= ip_bits(a2)) && (v4bitncmp(ip_v4addr(a1), ip_v4addr(a2), ip_bits(a1)) == 0)); } else { /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "cannot compare address families %d and %d", ip_family(a1), ip_family(a2)); return FALSE; } } /* * Comparison function for sorting. Add V4/V6 testing! */ int4 network_cmp(inet *a1, inet *a2) { if (ntohl(ip_v4addr(a1)) < ntohl(ip_v4addr(a2))) return (-1); else if (ntohl(ip_v4addr(a1)) > ntohl(ip_v4addr(a2))) return (1); return 0; } text * network_host(inet *ip) { text *ret; int len; char *ptr, tmp[sizeof("255.255.255.255/32")]; if (!PointerIsValid(ip)) return NULL; if (ip_type(ip)) elog(ERROR, "CIDR type has no host part"); if (ip_family(ip) == AF_INET) { /* It's an IP V4 address: */ if (inet_net_ntop(AF_INET, &ip_v4addr(ip), 32, tmp, sizeof(tmp)) == NULL) elog(ERROR, "unable to print host (%s)", strerror(errno)); } else /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "unknown address family (%d)", ip_family(ip)); if ((ptr = strchr(tmp, '/')) != NULL) *ptr = 0; len = VARHDRSZ + strlen(tmp) + 1; ret = palloc(len); if (ret == NULL) elog(ERROR, "unable to allocate memory in network_host()"); VARSIZE(ret) = len; strcpy(VARDATA(ret), tmp); return (ret); } int4 network_masklen(inet *ip) { if (!PointerIsValid(ip)) return 0; return ip_bits(ip); } text * network_broadcast(inet *ip) { text *ret; int len; char *ptr, tmp[sizeof("255.255.255.255/32")]; if (!PointerIsValid(ip)) return NULL; if (ip_family(ip) == AF_INET) { /* It's an IP V4 address: */ int addr; unsigned long mask = 0xffffffff; if (ip_bits(ip) < 32) mask >>= ip_bits(ip); addr = htonl(ntohl(ip_v4addr(ip)) | mask); if (inet_net_ntop(AF_INET, &addr, 32, tmp, sizeof(tmp)) == NULL) elog(ERROR, "unable to print address (%s)", strerror(errno)); } else /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "unknown address family (%d)", ip_family(ip)); if ((ptr = strchr(tmp, '/')) != NULL) *ptr = 0; len = VARHDRSZ + strlen(tmp) + 1; ret = palloc(len); if (ret == NULL) elog(ERROR, "unable to allocate memory in network_broadcast()"); VARSIZE(ret) = len; strcpy(VARDATA(ret), tmp); return (ret); } text * network_network(inet *ip) { text *ret; int len; char tmp[sizeof("255.255.255.255/32")]; if (!PointerIsValid(ip)) return NULL; if (ip_family(ip) == AF_INET) { /* It's an IP V4 address: */ int addr = htonl(ntohl(ip_v4addr(ip)) & (0xffffffff << (32 - ip_bits(ip)))); if (inet_cidr_ntop(AF_INET, &addr, ip_bits(ip), tmp, sizeof(tmp)) == NULL) elog(ERROR, "unable to print network (%s)", strerror(errno)); } else /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "unknown address family (%d)", ip_family(ip)); len = VARHDRSZ + strlen(tmp) + 1; ret = palloc(len); if (ret == NULL) elog(ERROR, "unable to allocate memory in network_network()"); VARSIZE(ret) = len; strcpy(VARDATA(ret), tmp); return (ret); } text * network_netmask(inet *ip) { text *ret; int len; char *ptr, tmp[sizeof("255.255.255.255/32")]; if (!PointerIsValid(ip)) return NULL; if (ip_family(ip) == AF_INET) { /* It's an IP V4 address: */ int addr = htonl((-1 << (32 - ip_bits(ip))) & 0xffffffff); if (inet_net_ntop(AF_INET, &addr, 32, tmp, sizeof(tmp)) == NULL) elog(ERROR, "unable to print netmask (%s)", strerror(errno)); } else /* Go for an IPV6 address here, before faulting out: */ elog(ERROR, "unknown address family (%d)", ip_family(ip)); if ((ptr = strchr(tmp, '/')) != NULL) *ptr = 0; len = VARHDRSZ + strlen(tmp) + 1; ret = palloc(len); if (ret == NULL) elog(ERROR, "unable to allocate memory in network_netmask()"); VARSIZE(ret) = len; strcpy(VARDATA(ret), tmp); return (ret); } /* * Bitwise comparison for V4 addresses. Add V6 implementation! */ static int v4bitncmp(unsigned int a1, unsigned int a2, int bits) { unsigned long mask = 0; int i; for (i = 0; i < bits; i++) mask = (mask >> 1) | 0x80000000; a1 = ntohl(a1); a2 = ntohl(a2); if ((a1 & mask) < (a2 & mask)) return (-1); else if ((a1 & mask) > (a2 & mask)) return (1); return (0); }