/* SPDX-License-Identifier: LGPL-2.1+ */ #include "alloc-util.h" #include "escape.h" #include "ether-addr-util.h" #include "hexdecoct.h" #include "in-addr-util.h" #include "lldp-internal.h" #include "lldp-neighbor.h" #include "missing.h" #include "unaligned.h" #include "util.h" static void lldp_neighbor_id_hash_func(const LLDPNeighborID *id, struct siphash *state) { siphash24_compress(id->chassis_id, id->chassis_id_size, state); siphash24_compress(&id->chassis_id_size, sizeof(id->chassis_id_size), state); siphash24_compress(id->port_id, id->port_id_size, state); siphash24_compress(&id->port_id_size, sizeof(id->port_id_size), state); } int lldp_neighbor_id_compare_func(const LLDPNeighborID *x, const LLDPNeighborID *y) { return memcmp_nn(x->chassis_id, x->chassis_id_size, y->chassis_id, y->chassis_id_size) ?: memcmp_nn(x->port_id, x->port_id_size, y->port_id, y->port_id_size); } DEFINE_HASH_OPS_WITH_VALUE_DESTRUCTOR(lldp_neighbor_hash_ops, LLDPNeighborID, lldp_neighbor_id_hash_func, lldp_neighbor_id_compare_func, sd_lldp_neighbor, lldp_neighbor_unlink); int lldp_neighbor_prioq_compare_func(const void *a, const void *b) { const sd_lldp_neighbor *x = a, *y = b; return CMP(x->until, y->until); } _public_ sd_lldp_neighbor *sd_lldp_neighbor_ref(sd_lldp_neighbor *n) { if (!n) return NULL; assert(n->n_ref > 0 || n->lldp); n->n_ref++; return n; } static void lldp_neighbor_free(sd_lldp_neighbor *n) { assert(n); free(n->id.port_id); free(n->id.chassis_id); free(n->port_description); free(n->system_name); free(n->system_description); free(n->chassis_id_as_string); free(n->port_id_as_string); free(n); } _public_ sd_lldp_neighbor *sd_lldp_neighbor_unref(sd_lldp_neighbor *n) { /* Drops one reference from the neighbor. Note that the object is not freed unless it is already unlinked from * the sd_lldp object. */ if (!n) return NULL; assert(n->n_ref > 0); n->n_ref--; if (n->n_ref <= 0 && !n->lldp) lldp_neighbor_free(n); return NULL; } sd_lldp_neighbor *lldp_neighbor_unlink(sd_lldp_neighbor *n) { /* Removes the neighbor object from the LLDP object, and frees it if it also has no other reference. */ if (!n) return NULL; if (!n->lldp) return NULL; /* Only remove the neighbor object from the hash table if it's in there, don't complain if it isn't. This is * because we are used as destructor call for hashmap_clear() and thus sometimes are called to de-register * ourselves from the hashtable and sometimes are called after we already are de-registered. */ (void) hashmap_remove_value(n->lldp->neighbor_by_id, &n->id, n); assert_se(prioq_remove(n->lldp->neighbor_by_expiry, n, &n->prioq_idx) >= 0); n->lldp = NULL; if (n->n_ref <= 0) lldp_neighbor_free(n); return NULL; } sd_lldp_neighbor *lldp_neighbor_new(size_t raw_size) { sd_lldp_neighbor *n; n = malloc0(ALIGN(sizeof(sd_lldp_neighbor)) + raw_size); if (!n) return NULL; n->raw_size = raw_size; n->n_ref = 1; return n; } static int parse_string(char **s, const void *q, size_t n) { const char *p = q; char *k; assert(s); assert(p || n == 0); if (*s) { log_lldp("Found duplicate string, ignoring field."); return 0; } /* Strip trailing NULs, just to be nice */ while (n > 0 && p[n-1] == 0) n--; if (n <= 0) /* Ignore empty strings */ return 0; /* Look for inner NULs */ if (memchr(p, 0, n)) { log_lldp("Found inner NUL in string, ignoring field."); return 0; } /* Let's escape weird chars, for security reasons */ k = cescape_length(p, n); if (!k) return -ENOMEM; free(*s); *s = k; return 1; } int lldp_neighbor_parse(sd_lldp_neighbor *n) { struct ether_header h; const uint8_t *p; size_t left; int r; assert(n); if (n->raw_size < sizeof(struct ether_header)) { log_lldp("Received truncated packet, ignoring."); return -EBADMSG; } memcpy(&h, LLDP_NEIGHBOR_RAW(n), sizeof(h)); if (h.ether_type != htobe16(ETHERTYPE_LLDP)) { log_lldp("Received packet with wrong type, ignoring."); return -EBADMSG; } if (h.ether_dhost[0] != 0x01 || h.ether_dhost[1] != 0x80 || h.ether_dhost[2] != 0xc2 || h.ether_dhost[3] != 0x00 || h.ether_dhost[4] != 0x00 || !IN_SET(h.ether_dhost[5], 0x00, 0x03, 0x0e)) { log_lldp("Received packet with wrong destination address, ignoring."); return -EBADMSG; } memcpy(&n->source_address, h.ether_shost, sizeof(struct ether_addr)); memcpy(&n->destination_address, h.ether_dhost, sizeof(struct ether_addr)); p = (const uint8_t*) LLDP_NEIGHBOR_RAW(n) + sizeof(struct ether_header); left = n->raw_size - sizeof(struct ether_header); for (;;) { uint8_t type; uint16_t length; if (left < 2) { log_lldp("TLV lacks header, ignoring."); return -EBADMSG; } type = p[0] >> 1; length = p[1] + (((uint16_t) (p[0] & 1)) << 8); p += 2, left -= 2; if (left < length) { log_lldp("TLV truncated, ignoring datagram."); return -EBADMSG; } switch (type) { case SD_LLDP_TYPE_END: if (length != 0) { log_lldp("End marker TLV not zero-sized, ignoring datagram."); return -EBADMSG; } /* Note that after processing the SD_LLDP_TYPE_END left could still be > 0 * as the message may contain padding (see IEEE 802.1AB-2016, sec. 8.5.12) */ goto end_marker; case SD_LLDP_TYPE_CHASSIS_ID: if (length < 2 || length > 256) { /* includes the chassis subtype, hence one extra byte */ log_lldp("Chassis ID field size out of range, ignoring datagram."); return -EBADMSG; } if (n->id.chassis_id) { log_lldp("Duplicate chassis ID field, ignoring datagram."); return -EBADMSG; } n->id.chassis_id = memdup(p, length); if (!n->id.chassis_id) return -ENOMEM; n->id.chassis_id_size = length; break; case SD_LLDP_TYPE_PORT_ID: if (length < 2 || length > 256) { /* includes the port subtype, hence one extra byte */ log_lldp("Port ID field size out of range, ignoring datagram."); return -EBADMSG; } if (n->id.port_id) { log_lldp("Duplicate port ID field, ignoring datagram."); return -EBADMSG; } n->id.port_id = memdup(p, length); if (!n->id.port_id) return -ENOMEM; n->id.port_id_size = length; break; case SD_LLDP_TYPE_TTL: if (length != 2) { log_lldp("TTL field has wrong size, ignoring datagram."); return -EBADMSG; } if (n->has_ttl) { log_lldp("Duplicate TTL field, ignoring datagram."); return -EBADMSG; } n->ttl = unaligned_read_be16(p); n->has_ttl = true; break; case SD_LLDP_TYPE_PORT_DESCRIPTION: r = parse_string(&n->port_description, p, length); if (r < 0) return r; break; case SD_LLDP_TYPE_SYSTEM_NAME: r = parse_string(&n->system_name, p, length); if (r < 0) return r; break; case SD_LLDP_TYPE_SYSTEM_DESCRIPTION: r = parse_string(&n->system_description, p, length); if (r < 0) return r; break; case SD_LLDP_TYPE_SYSTEM_CAPABILITIES: if (length != 4) log_lldp("System capabilities field has wrong size, ignoring."); else { n->system_capabilities = unaligned_read_be16(p); n->enabled_capabilities = unaligned_read_be16(p + 2); n->has_capabilities = true; } break; case SD_LLDP_TYPE_PRIVATE: if (length < 4) log_lldp("Found private TLV that is too short, ignoring."); break; } p += length, left -= length; } end_marker: if (!n->id.chassis_id || !n->id.port_id || !n->has_ttl) { log_lldp("One or more mandatory TLV missing in datagram. Ignoring."); return -EBADMSG; } n->rindex = sizeof(struct ether_header); return 0; } void lldp_neighbor_start_ttl(sd_lldp_neighbor *n) { assert(n); if (n->ttl > 0) { usec_t base; /* Use the packet's timestamp if there is one known */ base = triple_timestamp_by_clock(&n->timestamp, clock_boottime_or_monotonic()); if (base <= 0 || base == USEC_INFINITY) base = now(clock_boottime_or_monotonic()); /* Otherwise, take the current time */ n->until = usec_add(base, n->ttl * USEC_PER_SEC); } else n->until = 0; if (n->lldp) prioq_reshuffle(n->lldp->neighbor_by_expiry, n, &n->prioq_idx); } bool lldp_neighbor_equal(const sd_lldp_neighbor *a, const sd_lldp_neighbor *b) { if (a == b) return true; if (!a || !b) return false; if (a->raw_size != b->raw_size) return false; return memcmp(LLDP_NEIGHBOR_RAW(a), LLDP_NEIGHBOR_RAW(b), a->raw_size) == 0; } _public_ int sd_lldp_neighbor_get_source_address(sd_lldp_neighbor *n, struct ether_addr* address) { assert_return(n, -EINVAL); assert_return(address, -EINVAL); *address = n->source_address; return 0; } _public_ int sd_lldp_neighbor_get_destination_address(sd_lldp_neighbor *n, struct ether_addr* address) { assert_return(n, -EINVAL); assert_return(address, -EINVAL); *address = n->destination_address; return 0; } _public_ int sd_lldp_neighbor_get_raw(sd_lldp_neighbor *n, const void **ret, size_t *size) { assert_return(n, -EINVAL); assert_return(ret, -EINVAL); assert_return(size, -EINVAL); *ret = LLDP_NEIGHBOR_RAW(n); *size = n->raw_size; return 0; } _public_ int sd_lldp_neighbor_get_chassis_id(sd_lldp_neighbor *n, uint8_t *type, const void **ret, size_t *size) { assert_return(n, -EINVAL); assert_return(type, -EINVAL); assert_return(ret, -EINVAL); assert_return(size, -EINVAL); assert(n->id.chassis_id_size > 0); *type = *(uint8_t*) n->id.chassis_id; *ret = (uint8_t*) n->id.chassis_id + 1; *size = n->id.chassis_id_size - 1; return 0; } static int format_mac_address(const void *data, size_t sz, char **ret) { struct ether_addr a; char *k; assert(data || sz <= 0); if (sz != 7) return 0; memcpy(&a, (uint8_t*) data + 1, sizeof(a)); k = new(char, ETHER_ADDR_TO_STRING_MAX); if (!k) return -ENOMEM; *ret = ether_addr_to_string(&a, k); return 1; } static int format_network_address(const void *data, size_t sz, char **ret) { union in_addr_union a; int family, r; if (sz == 6 && ((uint8_t*) data)[1] == 1) { memcpy(&a.in, (uint8_t*) data + 2, sizeof(a.in)); family = AF_INET; } else if (sz == 18 && ((uint8_t*) data)[1] == 2) { memcpy(&a.in6, (uint8_t*) data + 2, sizeof(a.in6)); family = AF_INET6; } else return 0; r = in_addr_to_string(family, &a, ret); if (r < 0) return r; return 1; } _public_ int sd_lldp_neighbor_get_chassis_id_as_string(sd_lldp_neighbor *n, const char **ret) { char *k; int r; assert_return(n, -EINVAL); assert_return(ret, -EINVAL); if (n->chassis_id_as_string) { *ret = n->chassis_id_as_string; return 0; } assert(n->id.chassis_id_size > 0); switch (*(uint8_t*) n->id.chassis_id) { case SD_LLDP_CHASSIS_SUBTYPE_CHASSIS_COMPONENT: case SD_LLDP_CHASSIS_SUBTYPE_INTERFACE_ALIAS: case SD_LLDP_CHASSIS_SUBTYPE_PORT_COMPONENT: case SD_LLDP_CHASSIS_SUBTYPE_INTERFACE_NAME: case SD_LLDP_CHASSIS_SUBTYPE_LOCALLY_ASSIGNED: k = cescape_length((char*) n->id.chassis_id + 1, n->id.chassis_id_size - 1); if (!k) return -ENOMEM; goto done; case SD_LLDP_CHASSIS_SUBTYPE_MAC_ADDRESS: r = format_mac_address(n->id.chassis_id, n->id.chassis_id_size, &k); if (r < 0) return r; if (r > 0) goto done; break; case SD_LLDP_CHASSIS_SUBTYPE_NETWORK_ADDRESS: r = format_network_address(n->id.chassis_id, n->id.chassis_id_size, &k); if (r < 0) return r; if (r > 0) goto done; break; } /* Generic fallback */ k = hexmem(n->id.chassis_id, n->id.chassis_id_size); if (!k) return -ENOMEM; done: *ret = n->chassis_id_as_string = k; return 0; } _public_ int sd_lldp_neighbor_get_port_id(sd_lldp_neighbor *n, uint8_t *type, const void **ret, size_t *size) { assert_return(n, -EINVAL); assert_return(type, -EINVAL); assert_return(ret, -EINVAL); assert_return(size, -EINVAL); assert(n->id.port_id_size > 0); *type = *(uint8_t*) n->id.port_id; *ret = (uint8_t*) n->id.port_id + 1; *size = n->id.port_id_size - 1; return 0; } _public_ int sd_lldp_neighbor_get_port_id_as_string(sd_lldp_neighbor *n, const char **ret) { char *k; int r; assert_return(n, -EINVAL); assert_return(ret, -EINVAL); if (n->port_id_as_string) { *ret = n->port_id_as_string; return 0; } assert(n->id.port_id_size > 0); switch (*(uint8_t*) n->id.port_id) { case SD_LLDP_PORT_SUBTYPE_INTERFACE_ALIAS: case SD_LLDP_PORT_SUBTYPE_PORT_COMPONENT: case SD_LLDP_PORT_SUBTYPE_INTERFACE_NAME: case SD_LLDP_PORT_SUBTYPE_LOCALLY_ASSIGNED: k = cescape_length((char*) n->id.port_id + 1, n->id.port_id_size - 1); if (!k) return -ENOMEM; goto done; case SD_LLDP_PORT_SUBTYPE_MAC_ADDRESS: r = format_mac_address(n->id.port_id, n->id.port_id_size, &k); if (r < 0) return r; if (r > 0) goto done; break; case SD_LLDP_PORT_SUBTYPE_NETWORK_ADDRESS: r = format_network_address(n->id.port_id, n->id.port_id_size, &k); if (r < 0) return r; if (r > 0) goto done; break; } /* Generic fallback */ k = hexmem(n->id.port_id, n->id.port_id_size); if (!k) return -ENOMEM; done: *ret = n->port_id_as_string = k; return 0; } _public_ int sd_lldp_neighbor_get_ttl(sd_lldp_neighbor *n, uint16_t *ret_sec) { assert_return(n, -EINVAL); assert_return(ret_sec, -EINVAL); *ret_sec = n->ttl; return 0; } _public_ int sd_lldp_neighbor_get_system_name(sd_lldp_neighbor *n, const char **ret) { assert_return(n, -EINVAL); assert_return(ret, -EINVAL); if (!n->system_name) return -ENODATA; *ret = n->system_name; return 0; } _public_ int sd_lldp_neighbor_get_system_description(sd_lldp_neighbor *n, const char **ret) { assert_return(n, -EINVAL); assert_return(ret, -EINVAL); if (!n->system_description) return -ENODATA; *ret = n->system_description; return 0; } _public_ int sd_lldp_neighbor_get_port_description(sd_lldp_neighbor *n, const char **ret) { assert_return(n, -EINVAL); assert_return(ret, -EINVAL); if (!n->port_description) return -ENODATA; *ret = n->port_description; return 0; } _public_ int sd_lldp_neighbor_get_system_capabilities(sd_lldp_neighbor *n, uint16_t *ret) { assert_return(n, -EINVAL); assert_return(ret, -EINVAL); if (!n->has_capabilities) return -ENODATA; *ret = n->system_capabilities; return 0; } _public_ int sd_lldp_neighbor_get_enabled_capabilities(sd_lldp_neighbor *n, uint16_t *ret) { assert_return(n, -EINVAL); assert_return(ret, -EINVAL); if (!n->has_capabilities) return -ENODATA; *ret = n->enabled_capabilities; return 0; } _public_ int sd_lldp_neighbor_from_raw(sd_lldp_neighbor **ret, const void *raw, size_t raw_size) { _cleanup_(sd_lldp_neighbor_unrefp) sd_lldp_neighbor *n = NULL; int r; assert_return(ret, -EINVAL); assert_return(raw || raw_size <= 0, -EINVAL); n = lldp_neighbor_new(raw_size); if (!n) return -ENOMEM; memcpy(LLDP_NEIGHBOR_RAW(n), raw, raw_size); r = lldp_neighbor_parse(n); if (r < 0) return r; *ret = TAKE_PTR(n); return r; } _public_ int sd_lldp_neighbor_tlv_rewind(sd_lldp_neighbor *n) { assert_return(n, -EINVAL); assert(n->raw_size >= sizeof(struct ether_header)); n->rindex = sizeof(struct ether_header); return n->rindex < n->raw_size; } _public_ int sd_lldp_neighbor_tlv_next(sd_lldp_neighbor *n) { size_t length; assert_return(n, -EINVAL); if (n->rindex == n->raw_size) /* EOF */ return -ESPIPE; if (n->rindex + 2 > n->raw_size) /* Truncated message */ return -EBADMSG; length = LLDP_NEIGHBOR_TLV_LENGTH(n); if (n->rindex + 2 + length > n->raw_size) return -EBADMSG; n->rindex += 2 + length; return n->rindex < n->raw_size; } _public_ int sd_lldp_neighbor_tlv_get_type(sd_lldp_neighbor *n, uint8_t *type) { assert_return(n, -EINVAL); assert_return(type, -EINVAL); if (n->rindex == n->raw_size) /* EOF */ return -ESPIPE; if (n->rindex + 2 > n->raw_size) return -EBADMSG; *type = LLDP_NEIGHBOR_TLV_TYPE(n); return 0; } _public_ int sd_lldp_neighbor_tlv_is_type(sd_lldp_neighbor *n, uint8_t type) { uint8_t k; int r; assert_return(n, -EINVAL); r = sd_lldp_neighbor_tlv_get_type(n, &k); if (r < 0) return r; return type == k; } _public_ int sd_lldp_neighbor_tlv_get_oui(sd_lldp_neighbor *n, uint8_t oui[_SD_ARRAY_STATIC 3], uint8_t *subtype) { const uint8_t *d; size_t length; int r; assert_return(n, -EINVAL); assert_return(oui, -EINVAL); assert_return(subtype, -EINVAL); r = sd_lldp_neighbor_tlv_is_type(n, SD_LLDP_TYPE_PRIVATE); if (r < 0) return r; if (r == 0) return -ENXIO; length = LLDP_NEIGHBOR_TLV_LENGTH(n); if (length < 4) return -EBADMSG; if (n->rindex + 2 + length > n->raw_size) return -EBADMSG; d = LLDP_NEIGHBOR_TLV_DATA(n); memcpy(oui, d, 3); *subtype = d[3]; return 0; } _public_ int sd_lldp_neighbor_tlv_is_oui(sd_lldp_neighbor *n, const uint8_t oui[_SD_ARRAY_STATIC 3], uint8_t subtype) { uint8_t k[3], st; int r; r = sd_lldp_neighbor_tlv_get_oui(n, k, &st); if (r == -ENXIO) return 0; if (r < 0) return r; return memcmp(k, oui, 3) == 0 && st == subtype; } _public_ int sd_lldp_neighbor_tlv_get_raw(sd_lldp_neighbor *n, const void **ret, size_t *size) { size_t length; assert_return(n, -EINVAL); assert_return(ret, -EINVAL); assert_return(size, -EINVAL); /* Note that this returns the full TLV, including the TLV header */ if (n->rindex + 2 > n->raw_size) return -EBADMSG; length = LLDP_NEIGHBOR_TLV_LENGTH(n); if (n->rindex + 2 + length > n->raw_size) return -EBADMSG; *ret = (uint8_t*) LLDP_NEIGHBOR_RAW(n) + n->rindex; *size = length + 2; return 0; } _public_ int sd_lldp_neighbor_get_timestamp(sd_lldp_neighbor *n, clockid_t clock, uint64_t *ret) { assert_return(n, -EINVAL); assert_return(TRIPLE_TIMESTAMP_HAS_CLOCK(clock), -EOPNOTSUPP); assert_return(clock_supported(clock), -EOPNOTSUPP); assert_return(ret, -EINVAL); if (!triple_timestamp_is_set(&n->timestamp)) return -ENODATA; *ret = triple_timestamp_by_clock(&n->timestamp, clock); return 0; }