/* * IPv4/v6 address functions. * Copyright (C) 2017 by Harald Welte * * The contents of this file may be used under the terms of the GNU * General Public License Version 2, provided that the above copyright * notice and this permission notice is included in all copies or * substantial portions of the software. * */ #include "../lib/in46_addr.h" #include "../gtp/pdp.h" #include #include #include #include #include #include #include #include /*! Return the address family of given \reff in46_addr argument */ int in46a_to_af(const struct in46_addr *in) { switch (in->len) { case 4: return AF_INET; case 8: case 16: return AF_INET6; default: OSMO_ASSERT(0); return -1; } } /*! Convert \ref in46_addr to sockaddr_storage */ int in46a_to_sas(struct sockaddr_storage *out, const struct in46_addr *in) { struct sockaddr_in *sin = (struct sockaddr_in *)out; struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *)out; switch (in->len) { case 4: sin->sin_family = AF_INET; sin->sin_addr = in->v4; break; case 16: sin6->sin6_family = AF_INET6; sin6->sin6_addr = in->v6; break; default: OSMO_ASSERT(0); return -1; } return 0; } /*! Convenience wrapper around inet_ntop() for in46_addr. * \param[in] in the in46_addr to print * \param[out] dst destination buffer where string representation of the address is stored * \param[out] dst_size size dst. Usually it should be at least INET6_ADDRSTRLEN. * \return address of dst on success, NULL on error */ const char *in46a_ntop(const struct in46_addr *in, char *dst, socklen_t dst_size) { int af; if (!in || in->len == 0) { strncpy(dst, "UNDEFINED", dst_size); return dst; } af = in46a_to_af(in); if (af < 0) return NULL; return inet_ntop(af, (const void *) &in->v4, dst, dst_size); } /* like inet_ntoa() */ const char *in46a_ntoa(const struct in46_addr *in46) { static char addrstr_buf[256]; if (in46a_ntop(in46, addrstr_buf, sizeof(addrstr_buf)) < 0) return "INVALID"; else return addrstr_buf; } const char *in46p_ntoa(const struct in46_prefix *in46p) { static char addrstr_buf[256]; snprintf(addrstr_buf, sizeof(addrstr_buf), "%s/%u", in46a_ntoa(&in46p->addr), in46p->prefixlen); return addrstr_buf; } /*! Determine if two in46_addr are equal or not * \returns 1 in case they are equal; 0 otherwise */ int in46a_equal(const struct in46_addr *a, const struct in46_addr *b) { if (a->len == b->len && !memcmp(&a->v6, &b->v6, a->len)) return 1; else return 0; } /*! Determine if two in46_addr prefix are equal or not * The prefix length is determined by the shortest of the prefixes of a and b * \returns 1 in case the common prefix are equal; 0 otherwise */ int in46a_prefix_equal(const struct in46_addr *a, const struct in46_addr *b) { unsigned int len; if (a->len > b->len) len = b->len; else len = a->len; if (!memcmp(&a->v6, &b->v6, len)) return 1; else return 0; } /*! Match if IPv6 addr1 + addr2 are within same \a mask */ static int ipv6_within_mask(const struct in6_addr *addr1, const struct in6_addr *addr2, const struct in6_addr *mask) { struct in6_addr masked = *addr2; #if defined(__linux__) masked.s6_addr32[0] &= mask->s6_addr32[0]; masked.s6_addr32[1] &= mask->s6_addr32[1]; masked.s6_addr32[2] &= mask->s6_addr32[2]; masked.s6_addr32[3] &= mask->s6_addr32[3]; #else masked.__u6_addr.__u6_addr32[0] &= mask->__u6_addr.__u6_addr32[0]; masked.__u6_addr.__u6_addr32[1] &= mask->__u6_addr.__u6_addr32[1]; masked.__u6_addr.__u6_addr32[2] &= mask->__u6_addr.__u6_addr32[2]; masked.__u6_addr.__u6_addr32[3] &= mask->__u6_addr.__u6_addr32[3]; #endif if (!memcmp(addr1, &masked, sizeof(struct in6_addr))) return 1; else return 0; } /*! Create an IPv6 netmask from the given prefix length */ static void create_ipv6_netmask(struct in6_addr *netmask, int prefixlen) { uint32_t *p_netmask; memset(netmask, 0, sizeof(struct in6_addr)); if (prefixlen < 0) prefixlen = 0; else if (128 < prefixlen) prefixlen = 128; #if defined(__linux__) p_netmask = &netmask->s6_addr32[0]; #else p_netmask = &netmask->__u6_addr.__u6_addr32[0]; #endif while (32 < prefixlen) { *p_netmask = 0xffffffff; p_netmask++; prefixlen -= 32; } if (prefixlen != 0) { *p_netmask = htonl(0xFFFFFFFF << (32 - prefixlen)); } } /*! Determine if given \a addr is within given \a net + \a prefixlen * Builds the netmask from \a net + \a prefixlen and matches it to \a addr * \returns 1 in case of a match, 0 otherwise */ int in46a_within_mask(const struct in46_addr *addr, const struct in46_addr *net, size_t prefixlen) { struct in_addr netmask; struct in6_addr netmask6; if (addr->len != net->len) return 0; switch (addr->len) { case 4: netmask.s_addr = htonl(0xFFFFFFFF << (32 - prefixlen)); if ((addr->v4.s_addr & netmask.s_addr) == net->v4.s_addr) return 1; else return 0; case 16: create_ipv6_netmask(&netmask6, prefixlen); return ipv6_within_mask(&addr->v6, &net->v6, &netmask6); default: OSMO_ASSERT(0); return 0; } } static unsigned int ipv4_netmasklen(const struct in_addr *netmask) { uint32_t bits = netmask->s_addr; uint8_t *b = (uint8_t*) &bits; unsigned int i, prefix = 0; for (i = 0; i < 4; i++) { while (b[i] & 0x80) { prefix++; b[i] = b[i] << 1; } } return prefix; } static unsigned int ipv6_netmasklen(const struct in6_addr *netmask) { #if defined(__linux__) #define ADDRFIELD(i) s6_addr32[i] #else #define ADDRFIELD(i) __u6_addr.__u6_addr32[i] #endif unsigned int i, j, prefix = 0; for (j = 0; j < 4; j++) { uint32_t bits = netmask->ADDRFIELD(j); uint8_t *b = (uint8_t*) &bits; for (i = 0; i < 4; i++) { while (b[i] & 0x80) { prefix++; b[i] = b[i] << 1; } } } #undef ADDRFIELD return prefix; } /*! Convert netmask to prefix length representation * \param[in] netmask in46_addr containing a netmask (consecutive list of 1-bit followed by consecutive list of 0-bit) * \returns prefix length representation of the netmask (count of 1-bit from the start of the netmask) */ unsigned int in46a_netmasklen(const struct in46_addr *netmask) { switch (netmask->len) { case 4: return ipv4_netmasklen(&netmask->v4); case 16: return ipv6_netmasklen(&netmask->v6); default: OSMO_ASSERT(0); return 0; } } /*! Convert given array of in46_addr to PDP End User Address * \param[in] src Array containing 1 or 2 in46_addr * \param[out] eua End User Address structure to fill * \returns 0 on success; negative on error * * In case size is 2, this function expects to find exactly one IPv4 and one * IPv6 addresses in src. */ int in46a_to_eua(const struct in46_addr *src, unsigned int size, struct ul66_t *eua) { const struct in46_addr *src_v4, *src_v6; if (size == 1) { switch (src->len) { case 4: eua->l = 6; eua->v[0] = PDP_EUA_ORG_IETF; eua->v[1] = PDP_EUA_TYPE_v4; memcpy(&eua->v[2], &src->v4, 4); /* Copy a 4 byte address */ break; case 8: case 16: eua->l = 18; eua->v[0] = PDP_EUA_ORG_IETF; eua->v[1] = PDP_EUA_TYPE_v6; memcpy(&eua->v[2], &src->v6, 16); /* Copy a 16 byte address */ break; default: OSMO_ASSERT(0); return -1; } return 0; } if (src[0].len == src[1].len) return -1; /* we should have a v4 and a v6 address */ src_v4 = (src[0].len == 4) ? &src[0] : &src[1]; src_v6 = (src[0].len == 4) ? &src[1] : &src[0]; eua->l = 22; eua->v[0] = PDP_EUA_ORG_IETF; eua->v[1] = PDP_EUA_TYPE_v4v6; memcpy(&eua->v[2], &src_v4->v4, 4); memcpy(&eua->v[6], &src_v6->v6, 16); return 0; } /*! Convert given PDP End User Address to an array of in46_addr * \param[in] eua End User Address structure to parse * \param[out] dst Array containing 2 in46_addr * \returns number of parsed addresses (1 or 2) on success; negative on error * * This function expects to receive an End User Address struct together with an * array of 2 zeroed in46_addr structs. The in46_addr structs are filled in * order, hence if the function returns 1 the parsed address will be stored in * the first struct and the second one will be left intact. If 2 is returned, it * is guaranteed that one of them is an IPv4 and the other one is an IPv6, but * the order in which they are presented is not specified and must be * discovered for instance by checking the len field of each address. */ int in46a_from_eua(const struct ul66_t *eua, struct in46_addr *dst) { if (eua->l < 2) goto default_to_dyn_v4; if (eua->v[0] != 0xf1) return -1; switch (eua->v[1]) { case PDP_EUA_TYPE_v4: dst->len = 4; if (eua->l >= 6) memcpy(&dst->v4, &eua->v[2], 4); /* Copy a 4 byte address */ else dst->v4.s_addr = 0; return 1; case PDP_EUA_TYPE_v6: dst->len = 16; if (eua->l >= 18) memcpy(&dst->v6, &eua->v[2], 16); /* Copy a 16 byte address */ else memset(&dst->v6, 0, 16); return 1; case PDP_EUA_TYPE_v4v6: /* 3GPP TS 29.060, section 7.7.27 */ switch (eua->l) { case 2: /* v4 & v6 dynamic */ dst[0].v4.s_addr = 0; memset(&dst[1].v6, 0, 16); break; case 6: /* v4 static, v6 dynamic */ memcpy(&dst[0].v4, &eua->v[2], 4); memset(&dst[1].v6, 0, 16); break; case 18: /* v4 dynamic, v6 static */ dst[0].v4.s_addr = 0; memcpy(&dst[1].v6, &eua->v[2], 16); break; case 22: /* v4 & v6 static */ memcpy(&dst[0].v4, &eua->v[2], 4); memcpy(&dst[1].v6, &eua->v[6], 16); break; default: return -1; } dst[0].len = 4; dst[1].len = 16; return 2; default: return -1; } default_to_dyn_v4: /* assume dynamic IPv4 by default */ dst->len = 4; dst->v4.s_addr = 0; return 1; } void in46a_from_gsna(const struct ul16_t *in, struct in46_addr *dst) { dst->len = in->l; OSMO_ASSERT(in->l <= sizeof(dst->v6)); memcpy(&dst->v6, in->v, in->l); }