usr.sbin/ldpd/ldp_peer.c

1.16    kefren /* $NetBSD: ldp_peer.c,v 1.16 2013/08/02 07:29:56 kefren Exp $ */
 1.1    kefren
 1.5    kefren /*
 1.1    kefren  * Copyright (c) 2010 The NetBSD Foundation, Inc.
 1.1    kefren  * All rights reserved.
 1.1    kefren  *
 1.1    kefren  * This code is derived from software contributed to The NetBSD Foundation
 1.1    kefren  * by Mihai Chelaru <kefren (at) NetBSD.org>
 1.1    kefren  *
 1.1    kefren  * Redistribution and use in source and binary forms, with or without
 1.1    kefren  * modification, are permitted provided that the following conditions
 1.1    kefren  * are met:
 1.1    kefren  * 1. Redistributions of source code must retain the above copyright
 1.1    kefren  *    notice, this list of conditions and the following disclaimer.
 1.1    kefren  * 2. Redistributions in binary form must reproduce the above copyright
 1.1    kefren  *    notice, this list of conditions and the following disclaimer in the
 1.1    kefren  *    documentation and/or other materials provided with the distribution.
 1.1    kefren  *
 1.1    kefren  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.1    kefren  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.1    kefren  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.1    kefren  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.1    kefren  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1    kefren  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1    kefren  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1    kefren  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1    kefren  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1    kefren  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1    kefren  * POSSIBILITY OF SUCH DAMAGE.
 1.1    kefren  */
 1.1    kefren
 1.1    kefren #include <sys/types.h>
 1.1    kefren #include <sys/socket.h>
 1.1    kefren #include <netinet/in.h>
 1.3    kefren #include <netinet/tcp.h>
 1.1    kefren #include <netmpls/mpls.h>
 1.1    kefren #include <arpa/inet.h>
 1.1    kefren
 1.5    kefren #include <assert.h>
 1.5    kefren #include <errno.h>
1.15    kefren #include <fcntl.h>
 1.1    kefren #include <stdlib.h>
 1.1    kefren #include <strings.h>
1.16    kefren #include <stddef.h>
 1.1    kefren #include <stdio.h>
 1.1    kefren #include <unistd.h>
 1.3    kefren
 1.3    kefren #include "conffile.h"
 1.1    kefren #include "socketops.h"
 1.1    kefren #include "ldp_errors.h"
 1.1    kefren #include "ldp.h"
 1.1    kefren #include "tlv_stack.h"
 1.1    kefren #include "mpls_interface.h"
 1.1    kefren #include "notifications.h"
 1.1    kefren #include "ldp_peer.h"
 1.1    kefren
 1.3    kefren extern int ldp_holddown_time;
 1.3    kefren
1.16    kefren static struct label_mapping *ldp_peer_get_lm(struct ldp_peer *,
1.16    kefren     const struct sockaddr *, uint);
1.16    kefren
1.16    kefren static int mappings_compare(void *, const void *, const void *);
1.16    kefren static rb_tree_ops_t mappings_tree_ops = {
1.16    kefren 	.rbto_compare_nodes = mappings_compare,
1.16    kefren 	.rbto_compare_key = mappings_compare,
1.16    kefren 	.rbto_node_offset = offsetof(struct label_mapping, mappings_node),
1.16    kefren 	.rbto_context = NULL
1.16    kefren };
1.16    kefren
 1.1    kefren void
 1.1    kefren ldp_peer_init(void)
 1.1    kefren {
 1.1    kefren 	SLIST_INIT(&ldp_peer_head);
 1.1    kefren }
 1.1    kefren
1.10    kefren int
 1.5    kefren sockaddr_cmp(const struct sockaddr *a, const struct sockaddr *b)
 1.5    kefren {
1.11    kefren 	if (a == NULL || b == NULL || a->sa_len != b->sa_len ||
1.11    kefren 	    a->sa_family != b->sa_family)
 1.5    kefren 		return -1;
 1.9    kefren 	return memcmp(a, b, a->sa_len);
 1.5    kefren }
1.16    kefren
1.16    kefren static int
1.16    kefren mappings_compare(void *context, const void *node1, const void *node2)
1.16    kefren {
1.16    kefren 	const struct label_mapping *l1 = node1, *l2 = node2;
1.16    kefren 	int ret;
1.16    kefren
1.16    kefren 	if (__predict_false(l1->address.sa.sa_family !=
1.16    kefren 	    l2->address.sa.sa_family))
1.16    kefren 		return l1->address.sa.sa_family > l2->address.sa.sa_family ?
1.16    kefren 		    1 : -1;
1.16    kefren
1.16    kefren 	assert(l1->address.sa.sa_len == l2->address.sa.sa_len);
1.16    kefren 	if ((ret = memcmp(&l1->address.sa, &l2->address.sa, l1->address.sa.sa_len)) != 0)
1.16    kefren 		return ret;
1.16    kefren
1.16    kefren 	if (__predict_false(l1->prefix != l2->prefix))
1.16    kefren 		return l1->prefix > l2->prefix ? 1 : -1;
1.16    kefren
1.16    kefren 	return 0;
1.16    kefren }
1.16    kefren
 1.1    kefren /*
 1.1    kefren  * soc should be > 1 if there is already a TCP socket for this else we'll
 1.1    kefren  * initiate a new one
 1.1    kefren  */
 1.1    kefren struct ldp_peer *
1.12    kefren ldp_peer_new(const struct in_addr * ldp_id, const struct sockaddr * padd,
1.12    kefren 	     const struct sockaddr * tradd, uint16_t holdtime, int soc)
 1.1    kefren {
 1.1    kefren 	struct ldp_peer *p;
1.15    kefren 	int s = soc, sopts;
1.15    kefren 	union sockunion connecting_su;
 1.3    kefren 	struct conf_neighbour *cn;
 1.6    kefren
1.15    kefren 	assert(tradd == NULL || tradd->sa_family == padd->sa_family);
 1.1    kefren
 1.5    kefren 	if (soc < 1) {
 1.1    kefren 		s = socket(PF_INET, SOCK_STREAM, 0);
 1.5    kefren 		if (s < 0) {
 1.5    kefren 			fatalp("ldp_peer_new: cannot create socket\n");
 1.5    kefren 			return NULL;
 1.5    kefren 		}
1.12    kefren 		if (tradd != NULL) {
1.15    kefren 			assert(tradd->sa_len <= sizeof(connecting_su));
1.15    kefren 			memcpy(&connecting_su, tradd, tradd->sa_len);
1.12    kefren 		} else {
1.15    kefren 			assert(padd->sa_len <= sizeof(connecting_su));
1.15    kefren 			memcpy(&connecting_su, padd, padd->sa_len);
1.12    kefren 		}
 1.5    kefren
1.15    kefren 		assert(connecting_su.sa.sa_family == AF_INET ||
1.15    kefren 		    connecting_su.sa.sa_family == AF_INET6);
 1.5    kefren
1.15    kefren 		if (connecting_su.sa.sa_family == AF_INET)
1.15    kefren 			connecting_su.sin.sin_port = htons(LDP_PORT);
 1.1    kefren 		else
1.15    kefren 			connecting_su.sin6.sin6_port = htons(LDP_PORT);
 1.1    kefren
 1.1    kefren 		set_ttl(s);
 1.1    kefren 	}
 1.1    kefren
 1.3    kefren 	/* MD5 authentication needed ? */
 1.3    kefren 	SLIST_FOREACH(cn, &conei_head, neilist)
 1.6    kefren 		if (cn->authenticate != 0 &&
 1.6    kefren 		    ldp_id->s_addr == cn->address.s_addr) {
 1.3    kefren 			if (setsockopt(s, IPPROTO_TCP, TCP_MD5SIG, &(int){1},
 1.3    kefren 			    sizeof(int)) != 0)
 1.3    kefren 				fatalp("setsockopt TCP_MD5SIG: %s\n",
 1.3    kefren 				    strerror(errno));
 1.3    kefren 			break;
 1.3    kefren 		}
 1.6    kefren
 1.1    kefren 	/* Set the peer in CONNECTING/CONNECTED state */
 1.2  christos 	p = calloc(1, sizeof(*p));
 1.1    kefren
 1.1    kefren 	if (!p) {
 1.3    kefren 		fatalp("ldp_peer_new: calloc problem\n");
 1.1    kefren 		return NULL;
 1.2  christos 	}
 1.1    kefren
 1.1    kefren 	SLIST_INSERT_HEAD(&ldp_peer_head, p, peers);
 1.5    kefren 	p->address = (struct sockaddr *)malloc(padd->sa_len);
 1.5    kefren 	memcpy(p->address, padd, padd->sa_len);
 1.1    kefren 	memcpy(&p->ldp_id, ldp_id, sizeof(struct in_addr));
 1.7    kefren 	if (tradd != NULL) {
 1.7    kefren 		p->transport_address = (struct sockaddr *)malloc(tradd->sa_len);
 1.5    kefren 		memcpy(p->transport_address, tradd, tradd->sa_len);
 1.7    kefren 	} else {
 1.7    kefren 		p->transport_address = (struct sockaddr *)malloc(padd->sa_len);
 1.5    kefren 		memcpy(p->transport_address, padd, padd->sa_len);
 1.7    kefren 	}
 1.5    kefren 	p->holdtime=holdtime > ldp_holddown_time ? holdtime : ldp_holddown_time;
 1.1    kefren 	p->socket = s;
 1.1    kefren 	if (soc < 1) {
 1.1    kefren 		p->state = LDP_PEER_CONNECTING;
 1.1    kefren 		p->master = 1;
 1.1    kefren 	} else {
 1.1    kefren 		p->state = LDP_PEER_CONNECTED;
 1.1    kefren 		p->master = 0;
 1.1    kefren 		set_ttl(p->socket);
 1.1    kefren 	}
 1.1    kefren 	SLIST_INIT(&p->ldp_peer_address_head);
1.16    kefren 	rb_tree_init(&p->label_mapping_tree, &mappings_tree_ops);
 1.1    kefren 	p->timeout = p->holdtime;
 1.1    kefren
1.15    kefren 	sopts = fcntl(p->socket, F_GETFL);
1.15    kefren 	if (sopts >= 0) {
1.15    kefren 		sopts |= O_NONBLOCK;
1.15    kefren 		fcntl(p->socket, F_SETFL, &sopts);
1.15    kefren 	}
1.15    kefren
 1.1    kefren 	/* And connect to peer */
1.15    kefren 	if (soc < 1 &&
1.15    kefren 	    connect(s, &connecting_su.sa, connecting_su.sa.sa_len) == -1) {
1.15    kefren 		if (errno == EINTR || errno == EINPROGRESS)
1.15    kefren 			/* We take care of this in big_loop */
1.15    kefren 			return p;
1.15    kefren 		warnp("connect to %s failed: %s\n",
1.15    kefren 		    satos(&connecting_su.sa), strerror(errno));
1.15    kefren 		ldp_peer_holddown(p);
1.15    kefren 		return NULL;
1.15    kefren 	}
 1.1    kefren 	p->state = LDP_PEER_CONNECTED;
 1.1    kefren 	return p;
 1.1    kefren }
 1.1    kefren
 1.1    kefren void
 1.1    kefren ldp_peer_holddown(struct ldp_peer * p)
 1.1    kefren {
1.15    kefren
1.15    kefren 	if (!p || p->state == LDP_PEER_HOLDDOWN)
 1.1    kefren 		return;
1.15    kefren 	if (p->state == LDP_PEER_ESTABLISHED) {
1.15    kefren 		p->state = LDP_PEER_HOLDDOWN;
 1.1    kefren 		mpls_delete_ldp_peer(p);
1.15    kefren 	} else
1.15    kefren 		p->state = LDP_PEER_HOLDDOWN;
1.15    kefren 	p->timeout = p->holdtime;
 1.1    kefren 	shutdown(p->socket, SHUT_RDWR);
 1.1    kefren 	ldp_peer_delete_all_mappings(p);
 1.1    kefren 	del_all_ifaddr(p);
 1.1    kefren 	fatalp("LDP Neighbour %s is DOWN\n", inet_ntoa(p->ldp_id));
 1.1    kefren }
 1.1    kefren
 1.1    kefren void
 1.1    kefren ldp_peer_holddown_all()
 1.1    kefren {
 1.1    kefren 	struct ldp_peer *p;
 1.1    kefren
 1.1    kefren 	SLIST_FOREACH(p, &ldp_peer_head, peers) {
 1.1    kefren 		if ((p->state == LDP_PEER_ESTABLISHED) ||
 1.1    kefren 		    (p->state == LDP_PEER_CONNECTED))
 1.8    kefren 			send_notification(p, get_message_id(),
 1.8    kefren 			    NOTIF_FATAL | NOTIF_SHUTDOWN);
 1.1    kefren 		ldp_peer_holddown(p);
 1.1    kefren 	}
 1.1    kefren }
 1.1    kefren
 1.1    kefren void
 1.1    kefren ldp_peer_delete(struct ldp_peer * p)
 1.1    kefren {
 1.1    kefren
 1.1    kefren 	if (!p)
 1.1    kefren 		return;
 1.1    kefren
 1.1    kefren 	SLIST_REMOVE(&ldp_peer_head, p, ldp_peer, peers);
 1.1    kefren 	close(p->socket);
 1.1    kefren 	warnp("LDP Neighbor %s holddown timer expired\n", inet_ntoa(p->ldp_id));
 1.5    kefren 	free(p->address);
 1.5    kefren 	free(p->transport_address);
 1.1    kefren 	free(p);
 1.1    kefren }
 1.1    kefren
 1.1    kefren struct ldp_peer *
 1.5    kefren get_ldp_peer(const struct sockaddr * a)
 1.1    kefren {
 1.1    kefren 	struct ldp_peer *p;
 1.5    kefren 	const struct sockaddr_in *a_inet = (const struct sockaddr_in *)a;
 1.1    kefren
 1.1    kefren 	SLIST_FOREACH(p, &ldp_peer_head, peers) {
 1.5    kefren 		if (a->sa_family == AF_INET &&
 1.5    kefren 		    memcmp((const void *) &a_inet->sin_addr,
 1.5    kefren 		      (const void *) &p->ldp_id,
 1.5    kefren 		      sizeof(struct in_addr)) == 0)
 1.1    kefren 			return p;
1.11    kefren 		if (sockaddr_cmp(a, p->address) == 0 ||
1.11    kefren 		    sockaddr_cmp(a, p->transport_address) == 0 ||
1.11    kefren 		    check_ifaddr(p, a))
 1.1    kefren 			return p;
 1.1    kefren 	}
 1.1    kefren 	return NULL;
 1.1    kefren }
 1.1    kefren
 1.1    kefren struct ldp_peer *
 1.5    kefren get_ldp_peer_by_id(const struct in_addr *a)
 1.5    kefren {
 1.5    kefren 	struct ldp_peer *p;
 1.5    kefren
 1.5    kefren 	SLIST_FOREACH(p, &ldp_peer_head, peers)
 1.5    kefren 		if (memcmp((const void*)a,
 1.5    kefren 		    (const void*)&p->ldp_id, sizeof(*a)) == 0)
 1.5    kefren 			return p;
 1.5    kefren 	return NULL;
 1.5    kefren }
 1.5    kefren
 1.5    kefren struct ldp_peer *
 1.1    kefren get_ldp_peer_by_socket(int s)
 1.1    kefren {
 1.1    kefren 	struct ldp_peer *p;
 1.1    kefren
 1.1    kefren 	SLIST_FOREACH(p, &ldp_peer_head, peers)
 1.1    kefren 		if (p->socket == s)
 1.1    kefren 			return p;
 1.1    kefren 	return NULL;
 1.1    kefren }
 1.1    kefren
 1.1    kefren /*
 1.1    kefren  * Adds address list bounded to a specific peer
 1.1    kefren  * Returns the number of addresses inserted successfuly
 1.1    kefren  */
 1.1    kefren int
1.12    kefren add_ifaddresses(struct ldp_peer * p, const struct al_tlv * a)
 1.1    kefren {
 1.1    kefren 	int             i, c, n;
1.12    kefren 	const struct in_addr *ia;
 1.5    kefren 	struct sockaddr_in	ipa;
 1.1    kefren
 1.5    kefren 	memset(&ipa, 0, sizeof(ipa));
 1.5    kefren 	ipa.sin_len = sizeof(ipa);
 1.5    kefren 	ipa.sin_family = AF_INET;
 1.1    kefren 	/*
 1.1    kefren 	 * Check if tlv is Address type, if it's correct size (at least one
 1.1    kefren 	 * address) and if it's IPv4
 1.1    kefren 	 */
 1.1    kefren
 1.1    kefren 	if ((ntohs(a->type) != TLV_ADDRESS_LIST) ||
 1.1    kefren 	    (ntohs(a->length) < sizeof(a->af) + sizeof(struct in_addr)) ||
 1.1    kefren 	    (ntohs(a->af) != LDP_AF_INET))
 1.1    kefren 		return 0;
 1.1    kefren
 1.1    kefren 	/* Number of addresses to insert */
 1.1    kefren 	n = (ntohs(a->length) - sizeof(a->af)) / sizeof(struct in_addr);
 1.1    kefren
 1.1    kefren 	debugp("Trying to add %d addresses to peer %s ... \n", n,
 1.1    kefren 	    inet_ntoa(p->ldp_id));
 1.1    kefren
1.12    kefren 	for (ia = (const struct in_addr *) & a->address,c = 0,i = 0; i<n; i++) {
 1.5    kefren 		memcpy(&ipa.sin_addr, &ia[i], sizeof(ipa.sin_addr));
 1.5    kefren 		if (add_ifaddr(p, (struct sockaddr *)&ipa) == LDP_E_OK)
 1.1    kefren 			c++;
 1.1    kefren 	}
 1.1    kefren
 1.1    kefren 	debugp("Added %d addresses\n", c);
 1.1    kefren
 1.1    kefren 	return c;
 1.1    kefren }
 1.1    kefren
 1.1    kefren int
1.12    kefren del_ifaddresses(struct ldp_peer * p, const struct al_tlv * a)
 1.1    kefren {
 1.1    kefren 	int             i, c, n;
1.12    kefren 	const struct in_addr *ia;
 1.5    kefren 	struct sockaddr_in	ipa;
 1.1    kefren
 1.5    kefren 	memset(&ipa, 0, sizeof(ipa));
 1.5    kefren 	ipa.sin_len = sizeof(ipa);
 1.5    kefren 	ipa.sin_family = AF_INET;
 1.1    kefren 	/*
 1.1    kefren 	 * Check if tlv is Address type, if it's correct size (at least one
 1.1    kefren 	 * address) and if it's IPv4
 1.1    kefren 	 */
 1.1    kefren
 1.1    kefren 	if (ntohs(a->type) != TLV_ADDRESS_LIST ||
 1.1    kefren 	    ntohs(a->length) > sizeof(a->af) + sizeof(struct in_addr) ||
 1.1    kefren 	    ntohs(a->af) != LDP_AF_INET)
 1.1    kefren 		return -1;
 1.1    kefren
 1.1    kefren 	n = (ntohs(a->length) - sizeof(a->af)) / sizeof(struct in_addr);
 1.1    kefren
 1.1    kefren 	debugp("Trying to delete %d addresses from peer %s ... \n", n,
 1.1    kefren 	    inet_ntoa(p->ldp_id));
 1.1    kefren
1.12    kefren 	for (ia = (const struct in_addr *) & a[1], c = 0, i = 0; i < n; i++) {
 1.5    kefren 		memcpy(&ipa.sin_addr, &ia[i], sizeof(ipa.sin_addr));
 1.5    kefren 		if (del_ifaddr(p, (struct sockaddr *)&ipa) == LDP_E_OK)
 1.1    kefren 			c++;
 1.1    kefren 	}
 1.1    kefren
 1.1    kefren 	debugp("Deleted %d addresses\n", c);
 1.1    kefren
 1.1    kefren 	return c;
 1.1    kefren }
 1.1    kefren
 1.1    kefren
 1.5    kefren /* Adds a _SINGLE_ INET address to a specific peer */
 1.1    kefren int
1.12    kefren add_ifaddr(struct ldp_peer * p, const struct sockaddr * a)
 1.1    kefren {
 1.1    kefren 	struct ldp_peer_address *lpa;
 1.1    kefren
 1.1    kefren 	/* Is it already there ? */
 1.1    kefren 	if (check_ifaddr(p, a))
 1.1    kefren 		return LDP_E_ALREADY_DONE;
 1.1    kefren
 1.2  christos 	lpa = calloc(1, sizeof(*lpa));
 1.1    kefren
 1.1    kefren 	if (!lpa) {
 1.1    kefren 		fatalp("add_ifaddr: malloc problem\n");
 1.1    kefren 		return LDP_E_MEMORY;
 1.2  christos 	}
 1.1    kefren
 1.5    kefren 	assert(a->sa_len <= sizeof(union sockunion));
 1.5    kefren
 1.5    kefren 	memcpy(&lpa->address.sa, a, a->sa_len);
 1.1    kefren
 1.1    kefren 	SLIST_INSERT_HEAD(&p->ldp_peer_address_head, lpa, addresses);
 1.1    kefren 	return LDP_E_OK;
 1.1    kefren }
 1.1    kefren
 1.1    kefren /* Deletes an address bounded to a specific peer */
 1.1    kefren int
1.12    kefren del_ifaddr(struct ldp_peer * p, const struct sockaddr * a)
 1.1    kefren {
 1.1    kefren 	struct ldp_peer_address *wp;
 1.1    kefren
 1.1    kefren 	wp = check_ifaddr(p, a);
 1.1    kefren 	if (!wp)
 1.1    kefren 		return LDP_E_NOENT;
 1.1    kefren
 1.1    kefren 	SLIST_REMOVE(&p->ldp_peer_address_head, wp, ldp_peer_address,
 1.1    kefren 	    addresses);
 1.1    kefren 	free(wp);
 1.1    kefren 	return LDP_E_OK;
 1.1    kefren }
 1.1    kefren
 1.1    kefren /* Checks if an address is already bounded */
 1.1    kefren struct ldp_peer_address *
1.12    kefren check_ifaddr(const struct ldp_peer * p, const struct sockaddr * a)
 1.1    kefren {
 1.1    kefren 	struct ldp_peer_address *wp;
 1.1    kefren
 1.1    kefren 	SLIST_FOREACH(wp, &p->ldp_peer_address_head, addresses)
 1.5    kefren 		if (sockaddr_cmp(a, &wp->address.sa) == 0)
 1.1    kefren 			return wp;
 1.1    kefren 	return NULL;
 1.1    kefren }
 1.1    kefren
 1.1    kefren void
 1.1    kefren del_all_ifaddr(struct ldp_peer * p)
 1.1    kefren {
 1.1    kefren 	struct ldp_peer_address *wp;
 1.1    kefren
 1.1    kefren 	while (!SLIST_EMPTY(&p->ldp_peer_address_head)) {
 1.1    kefren 		wp = SLIST_FIRST(&p->ldp_peer_address_head);
 1.1    kefren 		SLIST_REMOVE_HEAD(&p->ldp_peer_address_head, addresses);
 1.1    kefren 		free(wp);
 1.1    kefren 	}
 1.1    kefren }
 1.1    kefren
 1.1    kefren void
1.12    kefren print_bounded_addresses(const struct ldp_peer * p)
 1.1    kefren {
 1.1    kefren 	struct ldp_peer_address *wp;
 1.7    kefren 	char abuf[512];
 1.1    kefren
 1.1    kefren 	snprintf(abuf, sizeof(abuf), "Addresses bounded to peer %s: ",
 1.7    kefren 	    satos(p->address));
 1.1    kefren 	SLIST_FOREACH(wp, &p->ldp_peer_address_head, addresses) {
 1.5    kefren 		strncat(abuf, satos(&wp->address.sa),
 1.5    kefren 			sizeof(abuf) -1);
 1.1    kefren 		strncat(abuf, " ", sizeof(abuf) -1);
 1.1    kefren 	}
 1.1    kefren 	warnp("%s\n", abuf);
 1.1    kefren }
 1.1    kefren
 1.1    kefren /* Adds a label and a prefix to a specific peer */
 1.1    kefren int
1.12    kefren ldp_peer_add_mapping(struct ldp_peer * p, const struct sockaddr * a,
1.12    kefren     int prefix, int label)
 1.1    kefren {
 1.1    kefren 	struct label_mapping *lma;
 1.1    kefren
 1.1    kefren 	if (!p)
 1.1    kefren 		return -1;
1.14    kefren 	if ((lma = ldp_peer_get_lm(p, a, prefix)) != NULL) {
1.14    kefren 		/* Change the current label */
1.14    kefren 		lma->label = label;
1.14    kefren 		return LDP_E_OK;
1.14    kefren 	}
 1.1    kefren
 1.2  christos 	lma = malloc(sizeof(*lma));
 1.1    kefren
 1.1    kefren 	if (!lma) {
 1.1    kefren 		fatalp("ldp_peer_add_mapping: malloc problem\n");
 1.1    kefren 		return LDP_E_MEMORY;
 1.1    kefren 	}
 1.1    kefren
 1.5    kefren 	memcpy(&lma->address, a, a->sa_len);
 1.1    kefren 	lma->prefix = prefix;
 1.1    kefren 	lma->label = label;
 1.1    kefren
1.16    kefren 	rb_tree_insert_node(&p->label_mapping_tree, lma);
 1.1    kefren
 1.1    kefren 	return LDP_E_OK;
 1.1    kefren }
 1.1    kefren
 1.1    kefren int
1.12    kefren ldp_peer_delete_mapping(struct ldp_peer * p, const struct sockaddr * a,
1.12    kefren     int prefix)
 1.1    kefren {
 1.1    kefren 	struct label_mapping *lma;
 1.1    kefren
1.16    kefren 	if (a == NULL || (lma = ldp_peer_get_lm(p, a, prefix)) == NULL)
1.15    kefren 		return LDP_E_NOENT;
 1.1    kefren
1.16    kefren 	rb_tree_remove_node(&p->label_mapping_tree, lma);
 1.1    kefren 	free(lma);
 1.1    kefren
 1.1    kefren 	return LDP_E_OK;
 1.1    kefren }
 1.1    kefren
1.16    kefren static struct label_mapping *
1.16    kefren ldp_peer_get_lm(struct ldp_peer * p, const struct sockaddr * a,
1.12    kefren     uint prefix)
 1.1    kefren {
1.16    kefren 	struct label_mapping rv;
 1.1    kefren
1.16    kefren 	assert(a->sa_len <= sizeof(union sockunion));
 1.1    kefren
1.16    kefren 	memset(&rv, 0, sizeof(rv));
1.16    kefren 	memcpy(&rv.address.sa, a, a->sa_len);
1.16    kefren 	rv.prefix = prefix;
 1.1    kefren
1.16    kefren 	return rb_tree_find_node(&p->label_mapping_tree, &rv);
 1.1    kefren }
 1.1    kefren
1.15    kefren void
 1.1    kefren ldp_peer_delete_all_mappings(struct ldp_peer * p)
 1.1    kefren {
 1.1    kefren 	struct label_mapping *lma;
 1.1    kefren
1.16    kefren 	while((lma = RB_TREE_MIN(&p->label_mapping_tree)) != NULL) {
1.16    kefren 		rb_tree_remove_node(&p->label_mapping_tree, lma);
 1.1    kefren 		free(lma);
 1.1    kefren 	}
 1.1    kefren }
 1.1    kefren
 1.1    kefren /* returns a mapping and its peer */
 1.1    kefren struct peer_map *
1.12    kefren ldp_test_mapping(const struct sockaddr * a, int prefix,
1.12    kefren     const struct sockaddr * gate)
 1.1    kefren {
 1.1    kefren 	struct ldp_peer *lpeer;
 1.1    kefren 	struct peer_map *rv = NULL;
 1.1    kefren 	struct label_mapping *lm = NULL;
 1.1    kefren
 1.1    kefren 	/* Checks if it's LPDID, else checks if it's an interface */
 1.1    kefren
 1.1    kefren 	lpeer = get_ldp_peer(gate);
 1.1    kefren 	if (!lpeer) {
 1.5    kefren 		debugp("ldp_test_mapping: Gateway is not an LDP peer\n");
 1.1    kefren 		return NULL;
 1.1    kefren 	}
 1.1    kefren 	if (lpeer->state != LDP_PEER_ESTABLISHED) {
 1.9    kefren 		fatalp("ldp_test_mapping: peer is down ?!\n");
 1.1    kefren 		return NULL;
 1.1    kefren 	}
 1.1    kefren 	lm = ldp_peer_get_lm(lpeer, a, prefix);
 1.1    kefren
 1.1    kefren 	if (!lm) {
 1.9    kefren 		debugp("Cannot match prefix %s/%d to the specified peer\n",
 1.9    kefren 		    satos(a), prefix);
 1.1    kefren 		return NULL;
 1.1    kefren 	}
 1.2  christos 	rv = malloc(sizeof(*rv));
 1.1    kefren
 1.1    kefren 	if (!rv) {
 1.1    kefren 		fatalp("ldp_test_mapping: malloc problem\n");
 1.1    kefren 		return NULL;
 1.1    kefren 	}
 1.1    kefren
 1.1    kefren 	rv->lm = lm;
 1.1    kefren 	rv->peer = lpeer;
 1.1    kefren
 1.1    kefren 	return rv;
 1.1    kefren }
 1.1    kefren
1.16    kefren struct label_mapping * ldp_peer_lm_right(struct ldp_peer *p,
1.16    kefren     struct label_mapping * map)
1.16    kefren {
1.16    kefren 	if (map == NULL)
1.16    kefren 		return RB_TREE_MIN(&p->label_mapping_tree);
1.16    kefren 	else
1.16    kefren 		return rb_tree_iterate(&p->label_mapping_tree, map,
1.16    kefren 		    RB_DIR_RIGHT);
1.16    kefren }
1.16    kefren
 1.1    kefren /* Name from state */
 1.1    kefren const char * ldp_state_to_name(int state)
 1.1    kefren {
 1.1    kefren 	switch(state) {
 1.1    kefren 		case LDP_PEER_CONNECTING:
 1.1    kefren 			return "CONNECTING";
 1.1    kefren 		case LDP_PEER_CONNECTED:
 1.1    kefren 			return "CONNECTED";
 1.1    kefren 		case LDP_PEER_ESTABLISHED:
 1.1    kefren 			return "ESTABLISHED";
 1.1    kefren 		case LDP_PEER_HOLDDOWN:
 1.1    kefren 			return "HOLDDOWN";
 1.1    kefren 	}
 1.1    kefren 	return "UNKNOWN";
 1.1    kefren }