sys/net/rtsock_shared.c

1.1.2.6  pgoyette /*	$NetBSD: rtsock_shared.c,v 1.1.2.6 2019/01/21 06:49:28 pgoyette Exp $	*/
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * Copyright (C) 1995, 1996, 1997, and 1998 WIDE Project.
1.1.2.1  pgoyette  * All rights reserved.
1.1.2.1  pgoyette  *
1.1.2.1  pgoyette  * Redistribution and use in source and binary forms, with or without
1.1.2.1  pgoyette  * modification, are permitted provided that the following conditions
1.1.2.1  pgoyette  * are met:
1.1.2.1  pgoyette  * 1. Redistributions of source code must retain the above copyright
1.1.2.1  pgoyette  *    notice, this list of conditions and the following disclaimer.
1.1.2.1  pgoyette  * 2. Redistributions in binary form must reproduce the above copyright
1.1.2.1  pgoyette  *    notice, this list of conditions and the following disclaimer in the
1.1.2.1  pgoyette  *    documentation and/or other materials provided with the distribution.
1.1.2.1  pgoyette  * 3. Neither the name of the project nor the names of its contributors
1.1.2.1  pgoyette  *    may be used to endorse or promote products derived from this software
1.1.2.1  pgoyette  *    without specific prior written permission.
1.1.2.1  pgoyette  *
1.1.2.1  pgoyette  * THIS SOFTWARE IS PROVIDED BY THE PROJECT AND CONTRIBUTORS ``AS IS'' AND
1.1.2.1  pgoyette  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1.2.1  pgoyette  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1.2.1  pgoyette  * ARE DISCLAIMED.  IN NO EVENT SHALL THE PROJECT OR CONTRIBUTORS BE LIABLE
1.1.2.1  pgoyette  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1.2.1  pgoyette  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1.2.1  pgoyette  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1.2.1  pgoyette  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1.2.1  pgoyette  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1.2.1  pgoyette  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1.2.1  pgoyette  * SUCH DAMAGE.
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * Copyright (c) 1988, 1991, 1993
1.1.2.1  pgoyette  *	The Regents of the University of California.  All rights reserved.
1.1.2.1  pgoyette  *
1.1.2.1  pgoyette  * Redistribution and use in source and binary forms, with or without
1.1.2.1  pgoyette  * modification, are permitted provided that the following conditions
1.1.2.1  pgoyette  * are met:
1.1.2.1  pgoyette  * 1. Redistributions of source code must retain the above copyright
1.1.2.1  pgoyette  *    notice, this list of conditions and the following disclaimer.
1.1.2.1  pgoyette  * 2. Redistributions in binary form must reproduce the above copyright
1.1.2.1  pgoyette  *    notice, this list of conditions and the following disclaimer in the
1.1.2.1  pgoyette  *    documentation and/or other materials provided with the distribution.
1.1.2.1  pgoyette  * 3. Neither the name of the University nor the names of its contributors
1.1.2.1  pgoyette  *    may be used to endorse or promote products derived from this software
1.1.2.1  pgoyette  *    without specific prior written permission.
1.1.2.1  pgoyette  *
1.1.2.1  pgoyette  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
1.1.2.1  pgoyette  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1.2.1  pgoyette  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1.2.1  pgoyette  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
1.1.2.1  pgoyette  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1.2.1  pgoyette  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1.2.1  pgoyette  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1.2.1  pgoyette  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1.2.1  pgoyette  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1.2.1  pgoyette  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1.2.1  pgoyette  * SUCH DAMAGE.
1.1.2.1  pgoyette  *
1.1.2.1  pgoyette  *	@(#)rtsock.c	8.7 (Berkeley) 10/12/95
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette
1.1.2.1  pgoyette #include <sys/cdefs.h>
1.1.2.6  pgoyette __KERNEL_RCSID(0, "$NetBSD: rtsock_shared.c,v 1.1.2.6 2019/01/21 06:49:28 pgoyette Exp $");
1.1.2.1  pgoyette
1.1.2.1  pgoyette #ifdef _KERNEL_OPT
1.1.2.1  pgoyette #include "opt_inet.h"
1.1.2.1  pgoyette #include "opt_net_mpsafe.h"
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette
1.1.2.1  pgoyette #include <sys/param.h>
1.1.2.1  pgoyette #include <sys/systm.h>
1.1.2.1  pgoyette #include <sys/proc.h>
1.1.2.1  pgoyette #include <sys/socket.h>
1.1.2.1  pgoyette #include <sys/socketvar.h>
1.1.2.1  pgoyette #include <sys/domain.h>
1.1.2.1  pgoyette #include <sys/protosw.h>
1.1.2.1  pgoyette #include <sys/sysctl.h>
1.1.2.1  pgoyette #include <sys/kauth.h>
1.1.2.1  pgoyette #include <sys/kmem.h>
1.1.2.1  pgoyette #include <sys/intr.h>
1.1.2.1  pgoyette #include <sys/condvar.h>
1.1.2.1  pgoyette #include <sys/compat_stub.h>
1.1.2.1  pgoyette
1.1.2.1  pgoyette #include <net/if.h>
1.1.2.1  pgoyette #include <net/if_llatbl.h>
1.1.2.1  pgoyette #include <net/if_types.h>
1.1.2.1  pgoyette #include <net/route.h>
1.1.2.1  pgoyette #include <net/raw_cb.h>
1.1.2.1  pgoyette
1.1.2.1  pgoyette #include <netinet/in_var.h>
1.1.2.1  pgoyette #include <netinet/if_inarp.h>
1.1.2.1  pgoyette
1.1.2.1  pgoyette #include <netmpls/mpls.h>
1.1.2.1  pgoyette
1.1.2.1  pgoyette #include <compat/net/if.h>
1.1.2.1  pgoyette #include <compat/net/route.h>
1.1.2.1  pgoyette
1.1.2.2  pgoyette #ifdef COMPAT_RTSOCK
1.1.2.2  pgoyette /*
1.1.2.2  pgoyette  * These are used when #include-d from compat/common/rtsock_50.c
1.1.2.2  pgoyette  */
1.1.2.1  pgoyette #define	RTM_XVERSION	RTM_OVERSION
1.1.2.1  pgoyette #define	RTM_XNEWADDR	RTM_ONEWADDR
1.1.2.1  pgoyette #define	RTM_XDELADDR	RTM_ODELADDR
1.1.2.1  pgoyette #define	RTM_XCHGADDR	RTM_OCHGADDR
1.1.2.1  pgoyette #define	RT_XADVANCE(a,b) RT_OADVANCE(a,b)
1.1.2.1  pgoyette #define	RT_XROUNDUP(n)	RT_OROUNDUP(n)
1.1.2.1  pgoyette #define	PF_XROUTE	PF_OROUTE
1.1.2.1  pgoyette #define	rt_xmsghdr	rt_msghdr50
1.1.2.1  pgoyette #define	if_xmsghdr	if_msghdr	/* if_msghdr50 is for RTM_OIFINFO */
1.1.2.1  pgoyette #define	ifa_xmsghdr	ifa_msghdr50
1.1.2.1  pgoyette #define	if_xannouncemsghdr	if_announcemsghdr50
1.1.2.1  pgoyette #define	COMPATNAME(x)	compat_50_ ## x
1.1.2.1  pgoyette #define	DOMAINNAME	"oroute"
1.1.2.2  pgoyette #define	COMPATCALL(name, args)	rtsock_50_ ## name ## _hook_call args
1.1.2.1  pgoyette #define	RTS_CTASSERT(x)	__nothing
1.1.2.1  pgoyette CTASSERT(sizeof(struct ifa_xmsghdr) == 20);
1.1.2.1  pgoyette DOMAIN_DEFINE(compat_50_routedomain); /* forward declare and add to link set */
1.1.2.2  pgoyette #else /* COMPAT_RTSOCK */
1.1.2.2  pgoyette /*
1.1.2.2  pgoyette  * These are used when #include-d from compat/common/rtsock_50.c
1.1.2.2  pgoyette  */
1.1.2.1  pgoyette #define	RTM_XVERSION	RTM_VERSION
1.1.2.1  pgoyette #define	RTM_XNEWADDR	RTM_NEWADDR
1.1.2.1  pgoyette #define	RTM_XDELADDR	RTM_DELADDR
1.1.2.1  pgoyette #define	RTM_XCHGADDR	RTM_CHGADDR
1.1.2.1  pgoyette #define	RT_XADVANCE(a,b) RT_ADVANCE(a,b)
1.1.2.1  pgoyette #define	RT_XROUNDUP(n)	RT_ROUNDUP(n)
1.1.2.1  pgoyette #define	PF_XROUTE	PF_ROUTE
1.1.2.1  pgoyette #define	rt_xmsghdr	rt_msghdr
1.1.2.1  pgoyette #define	if_xmsghdr	if_msghdr
1.1.2.1  pgoyette #define	ifa_xmsghdr	ifa_msghdr
1.1.2.1  pgoyette #define	if_xannouncemsghdr	if_announcemsghdr
1.1.2.1  pgoyette #define	COMPATNAME(x)	x
1.1.2.1  pgoyette #define	DOMAINNAME	"route"
1.1.2.2  pgoyette #define	COMPATCALL(name, args)	__nothing;
1.1.2.1  pgoyette #define	RTS_CTASSERT(x)	CTASSERT(x)
1.1.2.1  pgoyette CTASSERT(sizeof(struct ifa_xmsghdr) == 32);
1.1.2.1  pgoyette DOMAIN_DEFINE(routedomain); /* forward declare and add to link set */
1.1.2.1  pgoyette #endif /* COMPAT_RTSOCK */
1.1.2.1  pgoyette
1.1.2.1  pgoyette #ifdef RTSOCK_DEBUG
1.1.2.1  pgoyette #define RT_IN_PRINT(info, b, a) (in_print((b), sizeof(b), \
1.1.2.1  pgoyette     &((const struct sockaddr_in *)(info)->rti_info[(a)])->sin_addr), (b))
1.1.2.1  pgoyette #endif /* RTSOCK_DEBUG */
1.1.2.1  pgoyette
1.1.2.1  pgoyette struct route_info COMPATNAME(route_info) = {
1.1.2.1  pgoyette 	.ri_dst = { .sa_len = 2, .sa_family = PF_XROUTE, },
1.1.2.1  pgoyette 	.ri_src = { .sa_len = 2, .sa_family = PF_XROUTE, },
1.1.2.1  pgoyette 	.ri_maxqlen = IFQ_MAXLEN,
1.1.2.1  pgoyette };
1.1.2.1  pgoyette
1.1.2.1  pgoyette static void COMPATNAME(route_init)(void);
1.1.2.1  pgoyette static int COMPATNAME(route_output)(struct mbuf *, struct socket *);
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int rt_xaddrs(u_char, const char *, const char *, struct rt_addrinfo *);
1.1.2.1  pgoyette static struct mbuf *rt_makeifannouncemsg(struct ifnet *, int, int,
1.1.2.1  pgoyette     struct rt_addrinfo *);
1.1.2.1  pgoyette static int rt_msg2(int, struct rt_addrinfo *, void *, struct rt_walkarg *, int *);
1.1.2.1  pgoyette static void _rt_setmetrics(int, const struct rt_xmsghdr *, struct rtentry *);
1.1.2.1  pgoyette static void rtm_setmetrics(const struct rtentry *, struct rt_xmsghdr *);
1.1.2.1  pgoyette static void rt_adjustcount(int, int);
1.1.2.1  pgoyette
1.1.2.1  pgoyette static const struct protosw COMPATNAME(route_protosw)[];
1.1.2.1  pgoyette
1.1.2.1  pgoyette struct routecb {
1.1.2.1  pgoyette 	struct rawcb	rocb_rcb;
1.1.2.1  pgoyette 	unsigned int	rocb_msgfilter;
1.1.2.1  pgoyette #define	RTMSGFILTER(m)	(1U << (m))
1.1.2.1  pgoyette };
1.1.2.1  pgoyette #define sotoroutecb(so)	((struct routecb *)(so)->so_pcb)
1.1.2.1  pgoyette
1.1.2.1  pgoyette static struct rawcbhead rt_rawcb;
1.1.2.1  pgoyette #ifdef NET_MPSAFE
1.1.2.1  pgoyette static kmutex_t *rt_so_mtx;
1.1.2.1  pgoyette
1.1.2.1  pgoyette static bool rt_updating = false;
1.1.2.1  pgoyette static kcondvar_t rt_update_cv;
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette
1.1.2.1  pgoyette static void
1.1.2.1  pgoyette rt_adjustcount(int af, int cnt)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct route_cb * const cb = &COMPATNAME(route_info).ri_cb;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	cb->any_count += cnt;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	switch (af) {
1.1.2.1  pgoyette 	case AF_INET:
1.1.2.1  pgoyette 		cb->ip_count += cnt;
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette #ifdef INET6
1.1.2.1  pgoyette 	case AF_INET6:
1.1.2.1  pgoyette 		cb->ip6_count += cnt;
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 	case AF_MPLS:
1.1.2.1  pgoyette 		cb->mpls_count += cnt;
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_filter)(struct mbuf *m, struct sockproto *proto,
1.1.2.1  pgoyette     struct rawcb *rp)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct routecb *rop = (struct routecb *)rp;
1.1.2.1  pgoyette 	struct rt_xmsghdr *rtm;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(m != NULL);
1.1.2.1  pgoyette 	KASSERT(proto != NULL);
1.1.2.1  pgoyette 	KASSERT(rp != NULL);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	/* Wrong family for this socket. */
1.1.2.1  pgoyette 	if (proto->sp_family != PF_ROUTE)
1.1.2.1  pgoyette 		return ENOPROTOOPT;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	/* If no filter set, just return. */
1.1.2.1  pgoyette 	if (rop->rocb_msgfilter == 0)
1.1.2.1  pgoyette 		return 0;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	/* Ensure we can access rtm_type */
1.1.2.1  pgoyette 	if (m->m_len <
1.1.2.1  pgoyette 	    offsetof(struct rt_xmsghdr, rtm_type) + sizeof(rtm->rtm_type))
1.1.2.1  pgoyette 		return EINVAL;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	rtm = mtod(m, struct rt_xmsghdr *);
1.1.2.1  pgoyette 	/* If the rtm type is filtered out, return a positive. */
1.1.2.1  pgoyette 	if (!(rop->rocb_msgfilter & RTMSGFILTER(rtm->rtm_type)))
1.1.2.1  pgoyette 		return EEXIST;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	/* Passed the filter. */
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static void
1.1.2.1  pgoyette rt_pr_init(void)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	LIST_INIT(&rt_rawcb);
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_attach)(struct socket *so, int proto)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct rawcb *rp;
1.1.2.1  pgoyette 	struct routecb *rop;
1.1.2.1  pgoyette 	int s, error;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(sotorawcb(so) == NULL);
1.1.2.1  pgoyette 	rop = kmem_zalloc(sizeof(*rop), KM_SLEEP);
1.1.2.1  pgoyette 	rp = &rop->rocb_rcb;
1.1.2.1  pgoyette 	rp->rcb_len = sizeof(*rop);
1.1.2.1  pgoyette 	so->so_pcb = rp;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	s = splsoftnet();
1.1.2.1  pgoyette
1.1.2.1  pgoyette #ifdef NET_MPSAFE
1.1.2.1  pgoyette 	KASSERT(so->so_lock == NULL);
1.1.2.1  pgoyette 	mutex_obj_hold(rt_so_mtx);
1.1.2.1  pgoyette 	so->so_lock = rt_so_mtx;
1.1.2.1  pgoyette 	solock(so);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	if ((error = raw_attach(so, proto, &rt_rawcb)) == 0) {
1.1.2.1  pgoyette 		rt_adjustcount(rp->rcb_proto.sp_protocol, 1);
1.1.2.1  pgoyette 		rp->rcb_laddr = &COMPATNAME(route_info).ri_src;
1.1.2.1  pgoyette 		rp->rcb_faddr = &COMPATNAME(route_info).ri_dst;
1.1.2.1  pgoyette 		rp->rcb_filter = COMPATNAME(route_filter);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	splx(s);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	if (error) {
1.1.2.1  pgoyette 		kmem_free(rop, sizeof(*rop));
1.1.2.1  pgoyette 		so->so_pcb = NULL;
1.1.2.1  pgoyette 		return error;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	soisconnected(so);
1.1.2.1  pgoyette 	so->so_options |= SO_USELOOPBACK;
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return error;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static void
1.1.2.1  pgoyette COMPATNAME(route_detach)(struct socket *so)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct rawcb *rp = sotorawcb(so);
1.1.2.1  pgoyette 	int s;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(rp != NULL);
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	s = splsoftnet();
1.1.2.1  pgoyette 	rt_adjustcount(rp->rcb_proto.sp_protocol, -1);
1.1.2.1  pgoyette 	raw_detach(so);
1.1.2.1  pgoyette 	splx(s);
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_accept)(struct socket *so, struct sockaddr *nam)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	panic("route_accept");
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_bind)(struct socket *so, struct sockaddr *nam, struct lwp *l)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_listen)(struct socket *so, struct lwp *l)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_connect)(struct socket *so, struct sockaddr *nam, struct lwp *l)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_connect2)(struct socket *so, struct socket *so2)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_disconnect)(struct socket *so)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct rawcb *rp = sotorawcb(so);
1.1.2.1  pgoyette 	int s;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette 	KASSERT(rp != NULL);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	s = splsoftnet();
1.1.2.1  pgoyette 	soisdisconnected(so);
1.1.2.1  pgoyette 	raw_disconnect(rp);
1.1.2.1  pgoyette 	splx(s);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_shutdown)(struct socket *so)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	int s;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	/*
1.1.2.1  pgoyette 	 * Mark the connection as being incapable of further input.
1.1.2.1  pgoyette 	 */
1.1.2.1  pgoyette 	s = splsoftnet();
1.1.2.1  pgoyette 	socantsendmore(so);
1.1.2.1  pgoyette 	splx(s);
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_abort)(struct socket *so)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	panic("route_abort");
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_ioctl)(struct socket *so, u_long cmd, void *nam,
1.1.2.1  pgoyette     struct ifnet * ifp)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_stat)(struct socket *so, struct stat *ub)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_peeraddr)(struct socket *so, struct sockaddr *nam)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct rawcb *rp = sotorawcb(so);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette 	KASSERT(rp != NULL);
1.1.2.1  pgoyette 	KASSERT(nam != NULL);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	if (rp->rcb_faddr == NULL)
1.1.2.1  pgoyette 		return ENOTCONN;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	raw_setpeeraddr(rp, nam);
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_sockaddr)(struct socket *so, struct sockaddr *nam)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct rawcb *rp = sotorawcb(so);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette 	KASSERT(rp != NULL);
1.1.2.1  pgoyette 	KASSERT(nam != NULL);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	if (rp->rcb_faddr == NULL)
1.1.2.1  pgoyette 		return ENOTCONN;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	raw_setsockaddr(rp, nam);
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_rcvd)(struct socket *so, int flags, struct lwp *l)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_recvoob)(struct socket *so, struct mbuf *m, int flags)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_send)(struct socket *so, struct mbuf *m,
1.1.2.1  pgoyette     struct sockaddr *nam, struct mbuf *control, struct lwp *l)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	int error = 0;
1.1.2.1  pgoyette 	int s;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette 	KASSERT(so->so_proto == &COMPATNAME(route_protosw)[0]);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	s = splsoftnet();
1.1.2.1  pgoyette 	error = raw_send(so, m, nam, control, l, &COMPATNAME(route_output));
1.1.2.1  pgoyette 	splx(s);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return error;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_sendoob)(struct socket *so, struct mbuf *m,
1.1.2.1  pgoyette     struct mbuf *control)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	m_freem(m);
1.1.2.1  pgoyette 	m_freem(control);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette COMPATNAME(route_purgeif)(struct socket *so, struct ifnet *ifp)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	panic("route_purgeif");
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return EOPNOTSUPP;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette #if defined(INET) || defined(INET6)
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette route_get_sdl_index(struct rt_addrinfo *info, int *sdl_index)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct rtentry *nrt;
1.1.2.1  pgoyette 	int error;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	error = rtrequest1(RTM_GET, info, &nrt);
1.1.2.1  pgoyette 	if (error != 0)
1.1.2.1  pgoyette 		return error;
1.1.2.1  pgoyette 	/*
1.1.2.1  pgoyette 	 * nrt->rt_ifp->if_index may not be correct
1.1.2.1  pgoyette 	 * due to changing to ifplo0.
1.1.2.1  pgoyette 	 */
1.1.2.1  pgoyette 	*sdl_index = satosdl(nrt->rt_gateway)->sdl_index;
1.1.2.1  pgoyette 	rt_unref(nrt);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette
1.1.2.1  pgoyette static void
1.1.2.1  pgoyette route_get_sdl(const struct ifnet *ifp, const struct sockaddr *dst,
1.1.2.1  pgoyette     struct sockaddr_dl *sdl, int *flags)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct llentry *la;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(ifp != NULL);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	IF_AFDATA_RLOCK(ifp);
1.1.2.1  pgoyette 	switch (dst->sa_family) {
1.1.2.1  pgoyette 	case AF_INET:
1.1.2.1  pgoyette 		la = lla_lookup(LLTABLE(ifp), 0, dst);
1.1.2.1  pgoyette 		break;
1.1.2.1  pgoyette 	case AF_INET6:
1.1.2.1  pgoyette 		la = lla_lookup(LLTABLE6(ifp), 0, dst);
1.1.2.1  pgoyette 		break;
1.1.2.1  pgoyette 	default:
1.1.2.1  pgoyette 		la = NULL;
1.1.2.1  pgoyette 		KASSERTMSG(0, "Invalid AF=%d\n", dst->sa_family);
1.1.2.1  pgoyette 		break;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	IF_AFDATA_RUNLOCK(ifp);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	void *a = (LLE_IS_VALID(la) && (la->la_flags & LLE_VALID) == LLE_VALID)
1.1.2.1  pgoyette 	    ? &la->ll_addr : NULL;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	a = sockaddr_dl_init(sdl, sizeof(*sdl), ifp->if_index, ifp->if_type,
1.1.2.1  pgoyette 	    NULL, 0, a, ifp->if_addrlen);
1.1.2.1  pgoyette 	KASSERT(a != NULL);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	if (la != NULL) {
1.1.2.1  pgoyette 		*flags = la->la_flags;
1.1.2.1  pgoyette 		LLE_RUNLOCK(la);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette route_output_report(struct rtentry *rt, struct rt_addrinfo *info,
1.1.2.1  pgoyette     struct rt_xmsghdr *rtm, struct rt_xmsghdr **new_rtm)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	int len;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	if (rtm->rtm_addrs & (RTA_IFP | RTA_IFA)) {
1.1.2.1  pgoyette 		const struct ifaddr *rtifa;
1.1.2.1  pgoyette 		const struct ifnet *ifp = rt->rt_ifp;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 		info->rti_info[RTAX_IFP] = ifp->if_dl->ifa_addr;
1.1.2.1  pgoyette 		/* rtifa used to be simply rt->rt_ifa.
1.1.2.1  pgoyette 		 * If rt->rt_ifa != NULL, then
1.1.2.1  pgoyette 		 * rt_get_ifa() != NULL.  So this
1.1.2.1  pgoyette 		 * ought to still be safe. --dyoung
1.1.2.1  pgoyette 		 */
1.1.2.1  pgoyette 		rtifa = rt_get_ifa(rt);
1.1.2.1  pgoyette 		info->rti_info[RTAX_IFA] = rtifa->ifa_addr;
1.1.2.1  pgoyette #ifdef RTSOCK_DEBUG
1.1.2.1  pgoyette 		if (info->rti_info[RTAX_IFA]->sa_family == AF_INET) {
1.1.2.1  pgoyette 			char ibuf[INET_ADDRSTRLEN];
1.1.2.1  pgoyette 			char abuf[INET_ADDRSTRLEN];
1.1.2.1  pgoyette 			printf("%s: copying out RTAX_IFA %s "
1.1.2.1  pgoyette 			    "for info->rti_info[RTAX_DST] %s "
1.1.2.1  pgoyette 			    "ifa_getifa %p ifa_seqno %p\n",
1.1.2.1  pgoyette 			    __func__,
1.1.2.1  pgoyette 			    RT_IN_PRINT(info, ibuf, RTAX_IFA),
1.1.2.1  pgoyette 			    RT_IN_PRINT(info, abuf, RTAX_DST),
1.1.2.1  pgoyette 			    (void *)rtifa->ifa_getifa,
1.1.2.1  pgoyette 			    rtifa->ifa_seqno);
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette #endif /* RTSOCK_DEBUG */
1.1.2.1  pgoyette 		if (ifp->if_flags & IFF_POINTOPOINT)
1.1.2.1  pgoyette 			info->rti_info[RTAX_BRD] = rtifa->ifa_dstaddr;
1.1.2.1  pgoyette 		else
1.1.2.1  pgoyette 			info->rti_info[RTAX_BRD] = NULL;
1.1.2.1  pgoyette 		rtm->rtm_index = ifp->if_index;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	(void)rt_msg2(rtm->rtm_type, info, NULL, NULL, &len);
1.1.2.1  pgoyette 	if (len > rtm->rtm_msglen) {
1.1.2.1  pgoyette 		struct rt_xmsghdr *old_rtm = rtm;
1.1.2.1  pgoyette 		R_Malloc(*new_rtm, struct rt_xmsghdr *, len);
1.1.2.1  pgoyette 		if (*new_rtm == NULL)
1.1.2.1  pgoyette 			return ENOBUFS;
1.1.2.1  pgoyette 		(void)memcpy(*new_rtm, old_rtm, old_rtm->rtm_msglen);
1.1.2.1  pgoyette 		rtm = *new_rtm;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	(void)rt_msg2(rtm->rtm_type, info, rtm, NULL, 0);
1.1.2.1  pgoyette 	rtm->rtm_flags = rt->rt_flags;
1.1.2.1  pgoyette 	rtm_setmetrics(rt, rtm);
1.1.2.1  pgoyette 	rtm->rtm_addrs = info->rti_addrs;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*ARGSUSED*/
1.1.2.1  pgoyette int
1.1.2.1  pgoyette COMPATNAME(route_output)(struct mbuf *m, struct socket *so)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct sockproto proto = { .sp_family = PF_XROUTE, };
1.1.2.1  pgoyette 	struct rt_xmsghdr *rtm = NULL;
1.1.2.1  pgoyette 	struct rt_xmsghdr *old_rtm = NULL, *new_rtm = NULL;
1.1.2.1  pgoyette 	struct rtentry *rt = NULL;
1.1.2.1  pgoyette 	struct rtentry *saved_nrt = NULL;
1.1.2.1  pgoyette 	struct rt_addrinfo info;
1.1.2.1  pgoyette 	int len, error = 0;
1.1.2.1  pgoyette 	sa_family_t family;
1.1.2.1  pgoyette 	struct sockaddr_dl sdl;
1.1.2.1  pgoyette 	int bound = curlwp_bind();
1.1.2.1  pgoyette 	bool do_rt_free = false;
1.1.2.1  pgoyette 	struct sockaddr_storage netmask;
1.1.2.1  pgoyette
1.1.2.1  pgoyette #define senderr(e) do { error = e; goto flush;} while (/*CONSTCOND*/ 0)
1.1.2.1  pgoyette 	if (m == NULL || ((m->m_len < sizeof(int32_t)) &&
1.1.2.1  pgoyette 	   (m = m_pullup(m, sizeof(int32_t))) == NULL)) {
1.1.2.1  pgoyette 		error = ENOBUFS;
1.1.2.1  pgoyette 		goto out;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	if ((m->m_flags & M_PKTHDR) == 0)
1.1.2.1  pgoyette 		panic("%s", __func__);
1.1.2.1  pgoyette 	len = m->m_pkthdr.len;
1.1.2.1  pgoyette 	if (len < sizeof(*rtm) ||
1.1.2.1  pgoyette 	    len != mtod(m, struct rt_xmsghdr *)->rtm_msglen) {
1.1.2.1  pgoyette 		info.rti_info[RTAX_DST] = NULL;
1.1.2.1  pgoyette 		senderr(EINVAL);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	R_Malloc(rtm, struct rt_xmsghdr *, len);
1.1.2.1  pgoyette 	if (rtm == NULL) {
1.1.2.1  pgoyette 		info.rti_info[RTAX_DST] = NULL;
1.1.2.1  pgoyette 		senderr(ENOBUFS);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	m_copydata(m, 0, len, rtm);
1.1.2.1  pgoyette 	if (rtm->rtm_version != RTM_XVERSION) {
1.1.2.1  pgoyette 		info.rti_info[RTAX_DST] = NULL;
1.1.2.1  pgoyette 		senderr(EPROTONOSUPPORT);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	rtm->rtm_pid = curproc->p_pid;
1.1.2.1  pgoyette 	memset(&info, 0, sizeof(info));
1.1.2.1  pgoyette 	info.rti_addrs = rtm->rtm_addrs;
1.1.2.1  pgoyette 	if (rt_xaddrs(rtm->rtm_type, (const char *)(rtm + 1), len + (char *)rtm,
1.1.2.1  pgoyette 	    &info)) {
1.1.2.1  pgoyette 		senderr(EINVAL);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	info.rti_flags = rtm->rtm_flags;
1.1.2.1  pgoyette #ifdef RTSOCK_DEBUG
1.1.2.1  pgoyette 	if (info.rti_info[RTAX_DST]->sa_family == AF_INET) {
1.1.2.1  pgoyette 		char abuf[INET_ADDRSTRLEN];
1.1.2.1  pgoyette 		printf("%s: extracted info.rti_info[RTAX_DST] %s\n", __func__,
1.1.2.1  pgoyette 		    RT_IN_PRINT(&info, abuf, RTAX_DST));
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette #endif /* RTSOCK_DEBUG */
1.1.2.1  pgoyette 	if (info.rti_info[RTAX_DST] == NULL ||
1.1.2.1  pgoyette 	    (info.rti_info[RTAX_DST]->sa_family >= AF_MAX)) {
1.1.2.1  pgoyette 		senderr(EINVAL);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	if (info.rti_info[RTAX_GATEWAY] != NULL &&
1.1.2.1  pgoyette 	    (info.rti_info[RTAX_GATEWAY]->sa_family >= AF_MAX)) {
1.1.2.1  pgoyette 		senderr(EINVAL);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	/*
1.1.2.1  pgoyette 	 * Verify that the caller has the appropriate privilege; RTM_GET
1.1.2.1  pgoyette 	 * is the only operation the non-superuser is allowed.
1.1.2.1  pgoyette 	 */
1.1.2.1  pgoyette 	if (kauth_authorize_network(curlwp->l_cred, KAUTH_NETWORK_ROUTE,
1.1.2.1  pgoyette 	    0, rtm, NULL, NULL) != 0)
1.1.2.1  pgoyette 		senderr(EACCES);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	/*
1.1.2.1  pgoyette 	 * route(8) passes a sockaddr truncated with prefixlen.
1.1.2.1  pgoyette 	 * The kernel doesn't expect such sockaddr and need to
1.1.2.1  pgoyette 	 * use a buffer that is big enough for the sockaddr expected
1.1.2.1  pgoyette 	 * (padded with 0's). We keep the original length of the sockaddr.
1.1.2.1  pgoyette 	 */
1.1.2.1  pgoyette 	if (info.rti_info[RTAX_NETMASK]) {
1.1.2.1  pgoyette 		/*
1.1.2.1  pgoyette 		 * Use the family of RTAX_DST, because RTAX_NETMASK
1.1.2.1  pgoyette 		 * can have a zero family if it comes from the radix
1.1.2.1  pgoyette 		 * tree via rt_mask().
1.1.2.1  pgoyette 		 */
1.1.2.1  pgoyette 		socklen_t sa_len = sockaddr_getsize_by_family(
1.1.2.1  pgoyette 		    info.rti_info[RTAX_DST]->sa_family);
1.1.2.1  pgoyette 		socklen_t masklen = sockaddr_getlen(
1.1.2.1  pgoyette 		    info.rti_info[RTAX_NETMASK]);
1.1.2.1  pgoyette 		if (sa_len != 0 && sa_len > masklen) {
1.1.2.1  pgoyette 			KASSERT(sa_len <= sizeof(netmask));
1.1.2.1  pgoyette 			memcpy(&netmask, info.rti_info[RTAX_NETMASK], masklen);
1.1.2.1  pgoyette 			memset((char *)&netmask + masklen, 0, sa_len - masklen);
1.1.2.1  pgoyette 			info.rti_info[RTAX_NETMASK] = sstocsa(&netmask);
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	switch (rtm->rtm_type) {
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	case RTM_ADD:
1.1.2.1  pgoyette 		if (info.rti_info[RTAX_GATEWAY] == NULL) {
1.1.2.1  pgoyette 			senderr(EINVAL);
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette #if defined(INET) || defined(INET6)
1.1.2.1  pgoyette 		/* support for new ARP/NDP code with keeping backcompat */
1.1.2.1  pgoyette 		if (info.rti_info[RTAX_GATEWAY]->sa_family == AF_LINK) {
1.1.2.1  pgoyette 			const struct sockaddr_dl *sdlp =
1.1.2.1  pgoyette 			    satocsdl(info.rti_info[RTAX_GATEWAY]);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 			/* Allow routing requests by interface index */
1.1.2.1  pgoyette 			if (sdlp->sdl_nlen == 0 && sdlp->sdl_alen == 0
1.1.2.1  pgoyette 			    && sdlp->sdl_slen == 0)
1.1.2.1  pgoyette 				goto fallback;
1.1.2.1  pgoyette 			/*
1.1.2.1  pgoyette 			 * Old arp binaries don't set the sdl_index
1.1.2.1  pgoyette 			 * so we have to complement it.
1.1.2.1  pgoyette 			 */
1.1.2.1  pgoyette 			int sdl_index = sdlp->sdl_index;
1.1.2.1  pgoyette 			if (sdl_index == 0) {
1.1.2.1  pgoyette 				error = route_get_sdl_index(&info, &sdl_index);
1.1.2.1  pgoyette 				if (error != 0)
1.1.2.1  pgoyette 					goto fallback;
1.1.2.1  pgoyette 			} else if (
1.1.2.1  pgoyette 			    info.rti_info[RTAX_DST]->sa_family == AF_INET) {
1.1.2.1  pgoyette 				/*
1.1.2.1  pgoyette 				 * XXX workaround for SIN_PROXY case; proxy arp
1.1.2.1  pgoyette 				 * entry should be in an interface that has
1.1.2.1  pgoyette 				 * a network route including the destination,
1.1.2.1  pgoyette 				 * not a local (link) route that may not be a
1.1.2.1  pgoyette 				 * desired place, for example a tap.
1.1.2.1  pgoyette 				 */
1.1.2.1  pgoyette 				const struct sockaddr_inarp *sina =
1.1.2.1  pgoyette 				    (const struct sockaddr_inarp *)
1.1.2.1  pgoyette 				    info.rti_info[RTAX_DST];
1.1.2.1  pgoyette 				if (sina->sin_other & SIN_PROXY) {
1.1.2.1  pgoyette 					error = route_get_sdl_index(&info,
1.1.2.1  pgoyette 					    &sdl_index);
1.1.2.1  pgoyette 					if (error != 0)
1.1.2.1  pgoyette 						goto fallback;
1.1.2.1  pgoyette 				}
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 			error = lla_rt_output(rtm->rtm_type, rtm->rtm_flags,
1.1.2.1  pgoyette 			    rtm->rtm_rmx.rmx_expire, &info, sdl_index);
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 	fallback:
1.1.2.1  pgoyette #endif /* defined(INET) || defined(INET6) */
1.1.2.1  pgoyette 		error = rtrequest1(rtm->rtm_type, &info, &saved_nrt);
1.1.2.1  pgoyette 		if (error == 0) {
1.1.2.1  pgoyette 			_rt_setmetrics(rtm->rtm_inits, rtm, saved_nrt);
1.1.2.1  pgoyette 			rt_unref(saved_nrt);
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 		break;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	case RTM_DELETE:
1.1.2.1  pgoyette #if defined(INET) || defined(INET6)
1.1.2.1  pgoyette 		/* support for new ARP/NDP code */
1.1.2.1  pgoyette 		if (info.rti_info[RTAX_GATEWAY] &&
1.1.2.1  pgoyette 		    (info.rti_info[RTAX_GATEWAY]->sa_family == AF_LINK) &&
1.1.2.1  pgoyette 		    (rtm->rtm_flags & RTF_LLDATA) != 0) {
1.1.2.1  pgoyette 			const struct sockaddr_dl *sdlp =
1.1.2.1  pgoyette 			    satocsdl(info.rti_info[RTAX_GATEWAY]);
1.1.2.1  pgoyette 			error = lla_rt_output(rtm->rtm_type, rtm->rtm_flags,
1.1.2.1  pgoyette 			    rtm->rtm_rmx.rmx_expire, &info, sdlp->sdl_index);
1.1.2.1  pgoyette 			rtm->rtm_flags &= ~RTF_UP;
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 		error = rtrequest1(rtm->rtm_type, &info, &saved_nrt);
1.1.2.1  pgoyette 		if (error != 0)
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 		rt = saved_nrt;
1.1.2.1  pgoyette 		do_rt_free = true;
1.1.2.1  pgoyette 		info.rti_info[RTAX_DST] = rt_getkey(rt);
1.1.2.1  pgoyette 		info.rti_info[RTAX_GATEWAY] = rt->rt_gateway;
1.1.2.1  pgoyette 		info.rti_info[RTAX_NETMASK] = rt_mask(rt);
1.1.2.1  pgoyette 		info.rti_info[RTAX_TAG] = rt_gettag(rt);
1.1.2.1  pgoyette 		error = route_output_report(rt, &info, rtm, &new_rtm);
1.1.2.1  pgoyette 		if (error)
1.1.2.1  pgoyette 			senderr(error);
1.1.2.1  pgoyette 		if (new_rtm != NULL) {
1.1.2.1  pgoyette 			old_rtm = rtm;
1.1.2.1  pgoyette 			rtm = new_rtm;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 		break;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	case RTM_GET:
1.1.2.1  pgoyette 	case RTM_CHANGE:
1.1.2.1  pgoyette 	case RTM_LOCK:
1.1.2.1  pgoyette                 /* XXX This will mask info.rti_info[RTAX_DST] with
1.1.2.1  pgoyette 		 * info.rti_info[RTAX_NETMASK] before
1.1.2.1  pgoyette                  * searching.  It did not used to do that.  --dyoung
1.1.2.1  pgoyette 		 */
1.1.2.1  pgoyette 		rt = NULL;
1.1.2.1  pgoyette 		error = rtrequest1(RTM_GET, &info, &rt);
1.1.2.1  pgoyette 		if (error != 0)
1.1.2.1  pgoyette 			senderr(error);
1.1.2.1  pgoyette 		if (rtm->rtm_type != RTM_GET) {/* XXX: too grotty */
1.1.2.1  pgoyette 			if (memcmp(info.rti_info[RTAX_DST], rt_getkey(rt),
1.1.2.1  pgoyette 			    info.rti_info[RTAX_DST]->sa_len) != 0)
1.1.2.1  pgoyette 				senderr(ESRCH);
1.1.2.1  pgoyette 			if (info.rti_info[RTAX_NETMASK] == NULL &&
1.1.2.1  pgoyette 			    rt_mask(rt) != NULL)
1.1.2.1  pgoyette 				senderr(ETOOMANYREFS);
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 		/*
1.1.2.1  pgoyette 		 * XXX if arp/ndp requests an L2 entry, we have to obtain
1.1.2.1  pgoyette 		 * it from lltable while for the route command we have to
1.1.2.1  pgoyette 		 * return a route as it is. How to distinguish them?
1.1.2.1  pgoyette 		 * For newer arp/ndp, RTF_LLDATA flag set by arp/ndp
1.1.2.1  pgoyette 		 * indicates an L2 entry is requested. For old arp/ndp
1.1.2.1  pgoyette 		 * binaries, we check RTF_UP flag is NOT set; it works
1.1.2.1  pgoyette 		 * by the fact that arp/ndp don't set it while the route
1.1.2.1  pgoyette 		 * command sets it.
1.1.2.1  pgoyette 		 */
1.1.2.1  pgoyette 		if (((rtm->rtm_flags & RTF_LLDATA) != 0 ||
1.1.2.1  pgoyette 		     (rtm->rtm_flags & RTF_UP) == 0) &&
1.1.2.1  pgoyette 		    rtm->rtm_type == RTM_GET &&
1.1.2.1  pgoyette 		    sockaddr_cmp(rt_getkey(rt), info.rti_info[RTAX_DST]) != 0) {
1.1.2.1  pgoyette 			int ll_flags = 0;
1.1.2.1  pgoyette 			route_get_sdl(rt->rt_ifp, info.rti_info[RTAX_DST], &sdl,
1.1.2.1  pgoyette 			    &ll_flags);
1.1.2.1  pgoyette 			info.rti_info[RTAX_GATEWAY] = sstocsa(&sdl);
1.1.2.1  pgoyette 			error = route_output_report(rt, &info, rtm, &new_rtm);
1.1.2.1  pgoyette 			if (error)
1.1.2.1  pgoyette 				senderr(error);
1.1.2.1  pgoyette 			if (new_rtm != NULL) {
1.1.2.1  pgoyette 				old_rtm = rtm;
1.1.2.1  pgoyette 				rtm = new_rtm;
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 			rtm->rtm_flags |= RTF_LLDATA;
1.1.2.1  pgoyette 			rtm->rtm_flags &= ~RTF_CONNECTED;
1.1.2.1  pgoyette 			rtm->rtm_flags |= (ll_flags & LLE_STATIC) ? RTF_STATIC : 0;
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 		switch (rtm->rtm_type) {
1.1.2.1  pgoyette 		case RTM_GET:
1.1.2.1  pgoyette 			info.rti_info[RTAX_DST] = rt_getkey(rt);
1.1.2.1  pgoyette 			info.rti_info[RTAX_GATEWAY] = rt->rt_gateway;
1.1.2.1  pgoyette 			info.rti_info[RTAX_NETMASK] = rt_mask(rt);
1.1.2.1  pgoyette 			info.rti_info[RTAX_TAG] = rt_gettag(rt);
1.1.2.1  pgoyette 			error = route_output_report(rt, &info, rtm, &new_rtm);
1.1.2.1  pgoyette 			if (error)
1.1.2.1  pgoyette 				senderr(error);
1.1.2.1  pgoyette 			if (new_rtm != NULL) {
1.1.2.1  pgoyette 				old_rtm = rtm;
1.1.2.1  pgoyette 				rtm = new_rtm;
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 		case RTM_CHANGE:
1.1.2.1  pgoyette #ifdef NET_MPSAFE
1.1.2.1  pgoyette 			/*
1.1.2.1  pgoyette 			 * Release rt_so_mtx to avoid a deadlock with route_intr
1.1.2.1  pgoyette 			 * and also serialize updating routes to avoid another.
1.1.2.1  pgoyette 			 */
1.1.2.1  pgoyette 			if (rt_updating) {
1.1.2.1  pgoyette 				/* Release to allow the updater to proceed */
1.1.2.1  pgoyette 				rt_unref(rt);
1.1.2.1  pgoyette 				rt = NULL;
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 			while (rt_updating) {
1.1.2.1  pgoyette 				error = cv_wait_sig(&rt_update_cv, rt_so_mtx);
1.1.2.1  pgoyette 				if (error != 0)
1.1.2.1  pgoyette 					goto flush;
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 			if (rt == NULL) {
1.1.2.1  pgoyette 				error = rtrequest1(RTM_GET, &info, &rt);
1.1.2.1  pgoyette 				if (error != 0)
1.1.2.1  pgoyette 					goto flush;
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 			rt_updating = true;
1.1.2.1  pgoyette 			mutex_exit(rt_so_mtx);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 			error = rt_update_prepare(rt);
1.1.2.1  pgoyette 			if (error == 0) {
1.1.2.1  pgoyette 				error = rt_update(rt, &info, rtm);
1.1.2.1  pgoyette 				rt_update_finish(rt);
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 			mutex_enter(rt_so_mtx);
1.1.2.1  pgoyette 			rt_updating = false;
1.1.2.1  pgoyette 			cv_broadcast(&rt_update_cv);
1.1.2.1  pgoyette #else
1.1.2.1  pgoyette 			error = rt_update(rt, &info, rtm);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 			if (error != 0)
1.1.2.1  pgoyette 				goto flush;
1.1.2.1  pgoyette 			/*FALLTHROUGH*/
1.1.2.1  pgoyette 		case RTM_LOCK:
1.1.2.1  pgoyette 			rt->rt_rmx.rmx_locks &= ~(rtm->rtm_inits);
1.1.2.1  pgoyette 			rt->rt_rmx.rmx_locks |=
1.1.2.1  pgoyette 			    (rtm->rtm_inits & rtm->rtm_rmx.rmx_locks);
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 		break;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	default:
1.1.2.1  pgoyette 		senderr(EOPNOTSUPP);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette
1.1.2.1  pgoyette flush:
1.1.2.1  pgoyette 	if (rtm) {
1.1.2.1  pgoyette 		if (error)
1.1.2.1  pgoyette 			rtm->rtm_errno = error;
1.1.2.1  pgoyette 		else
1.1.2.1  pgoyette 			rtm->rtm_flags |= RTF_DONE;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	family = info.rti_info[RTAX_DST] ? info.rti_info[RTAX_DST]->sa_family :
1.1.2.1  pgoyette 	    0;
1.1.2.1  pgoyette 	/* We cannot free old_rtm until we have stopped using the
1.1.2.1  pgoyette 	 * pointers in info, some of which may point to sockaddrs
1.1.2.1  pgoyette 	 * in old_rtm.
1.1.2.1  pgoyette 	 */
1.1.2.1  pgoyette 	if (old_rtm != NULL)
1.1.2.1  pgoyette 		Free(old_rtm);
1.1.2.1  pgoyette 	if (rt) {
1.1.2.1  pgoyette 		if (do_rt_free) {
1.1.2.1  pgoyette #ifdef NET_MPSAFE
1.1.2.1  pgoyette 			/*
1.1.2.1  pgoyette 			 * Release rt_so_mtx to avoid a deadlock with
1.1.2.1  pgoyette 			 * route_intr.
1.1.2.1  pgoyette 			 */
1.1.2.1  pgoyette 			mutex_exit(rt_so_mtx);
1.1.2.1  pgoyette 			rt_free(rt);
1.1.2.1  pgoyette 			mutex_enter(rt_so_mtx);
1.1.2.1  pgoyette #else
1.1.2.1  pgoyette 			rt_free(rt);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 		} else
1.1.2.1  pgoyette 			rt_unref(rt);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette     {
1.1.2.1  pgoyette 	struct rawcb *rp = NULL;
1.1.2.1  pgoyette 	/*
1.1.2.1  pgoyette 	 * Check to see if we don't want our own messages.
1.1.2.1  pgoyette 	 */
1.1.2.1  pgoyette 	if ((so->so_options & SO_USELOOPBACK) == 0) {
1.1.2.1  pgoyette 		if (COMPATNAME(route_info).ri_cb.any_count <= 1) {
1.1.2.1  pgoyette 			if (rtm)
1.1.2.1  pgoyette 				Free(rtm);
1.1.2.1  pgoyette 			m_freem(m);
1.1.2.1  pgoyette 			goto out;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 		/* There is another listener, so construct message */
1.1.2.1  pgoyette 		rp = sotorawcb(so);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	if (rtm) {
1.1.2.1  pgoyette 		m_copyback(m, 0, rtm->rtm_msglen, rtm);
1.1.2.1  pgoyette 		if (m->m_pkthdr.len < rtm->rtm_msglen) {
1.1.2.1  pgoyette 			m_freem(m);
1.1.2.1  pgoyette 			m = NULL;
1.1.2.1  pgoyette 		} else if (m->m_pkthdr.len > rtm->rtm_msglen)
1.1.2.1  pgoyette 			m_adj(m, rtm->rtm_msglen - m->m_pkthdr.len);
1.1.2.1  pgoyette 		Free(rtm);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	if (rp)
1.1.2.1  pgoyette 		rp->rcb_proto.sp_family = 0; /* Avoid us */
1.1.2.1  pgoyette 	if (family)
1.1.2.1  pgoyette 		proto.sp_protocol = family;
1.1.2.1  pgoyette 	if (m)
1.1.2.1  pgoyette 		raw_input(m, &proto, &COMPATNAME(route_info).ri_src,
1.1.2.1  pgoyette 		    &COMPATNAME(route_info).ri_dst, &rt_rawcb);
1.1.2.1  pgoyette 	if (rp)
1.1.2.1  pgoyette 		rp->rcb_proto.sp_family = PF_XROUTE;
1.1.2.1  pgoyette     }
1.1.2.1  pgoyette out:
1.1.2.1  pgoyette 	curlwp_bindx(bound);
1.1.2.1  pgoyette 	return error;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette route_ctloutput(int op, struct socket *so, struct sockopt *sopt)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct routecb *rop = sotoroutecb(so);
1.1.2.1  pgoyette 	int error = 0;
1.1.2.1  pgoyette 	unsigned char *rtm_type;
1.1.2.1  pgoyette 	size_t len;
1.1.2.1  pgoyette 	unsigned int msgfilter;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(solocked(so));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	if (sopt->sopt_level != AF_ROUTE) {
1.1.2.1  pgoyette 		error = ENOPROTOOPT;
1.1.2.1  pgoyette 	} else switch (op) {
1.1.2.1  pgoyette 	case PRCO_SETOPT:
1.1.2.1  pgoyette 		switch (sopt->sopt_name) {
1.1.2.1  pgoyette 		case RO_MSGFILTER:
1.1.2.1  pgoyette 			msgfilter = 0;
1.1.2.1  pgoyette 			for (rtm_type = sopt->sopt_data, len = sopt->sopt_size;
1.1.2.1  pgoyette 			     len != 0;
1.1.2.1  pgoyette 			     rtm_type++, len -= sizeof(*rtm_type))
1.1.2.1  pgoyette 			{
1.1.2.1  pgoyette 				/* Guard against overflowing our storage. */
1.1.2.1  pgoyette 				if (*rtm_type >= sizeof(msgfilter) * CHAR_BIT) {
1.1.2.1  pgoyette 					error = EOVERFLOW;
1.1.2.1  pgoyette 					break;
1.1.2.1  pgoyette 				}
1.1.2.1  pgoyette 				msgfilter |= RTMSGFILTER(*rtm_type);
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 			if (error == 0)
1.1.2.1  pgoyette 				rop->rocb_msgfilter = msgfilter;
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		default:
1.1.2.1  pgoyette 			error = ENOPROTOOPT;
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 		break;
1.1.2.1  pgoyette 	case PRCO_GETOPT:
1.1.2.1  pgoyette 		switch (sopt->sopt_name) {
1.1.2.1  pgoyette 		case RO_MSGFILTER:
1.1.2.1  pgoyette 			error = ENOTSUP;
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		default:
1.1.2.1  pgoyette 			error = ENOPROTOOPT;
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	return error;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static void
1.1.2.1  pgoyette _rt_setmetrics(int which, const struct rt_xmsghdr *in, struct rtentry *out)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette #define metric(f, e) if (which & (f)) out->rt_rmx.e = in->rtm_rmx.e;
1.1.2.1  pgoyette 	metric(RTV_RPIPE, rmx_recvpipe);
1.1.2.1  pgoyette 	metric(RTV_SPIPE, rmx_sendpipe);
1.1.2.1  pgoyette 	metric(RTV_SSTHRESH, rmx_ssthresh);
1.1.2.1  pgoyette 	metric(RTV_RTT, rmx_rtt);
1.1.2.1  pgoyette 	metric(RTV_RTTVAR, rmx_rttvar);
1.1.2.1  pgoyette 	metric(RTV_HOPCOUNT, rmx_hopcount);
1.1.2.1  pgoyette 	metric(RTV_MTU, rmx_mtu);
1.1.2.1  pgoyette #undef metric
1.1.2.1  pgoyette 	if (which & RTV_EXPIRE) {
1.1.2.1  pgoyette 		out->rt_rmx.rmx_expire = in->rtm_rmx.rmx_expire ?
1.1.2.1  pgoyette 		    time_wall_to_mono(in->rtm_rmx.rmx_expire) : 0;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static void
1.1.2.1  pgoyette rtm_setmetrics(const struct rtentry *in, struct rt_xmsghdr *out)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette #define metric(e) out->rtm_rmx.e = in->rt_rmx.e;
1.1.2.1  pgoyette 	metric(rmx_recvpipe);
1.1.2.1  pgoyette 	metric(rmx_sendpipe);
1.1.2.1  pgoyette 	metric(rmx_ssthresh);
1.1.2.1  pgoyette 	metric(rmx_rtt);
1.1.2.1  pgoyette 	metric(rmx_rttvar);
1.1.2.1  pgoyette 	metric(rmx_hopcount);
1.1.2.1  pgoyette 	metric(rmx_mtu);
1.1.2.1  pgoyette 	metric(rmx_locks);
1.1.2.1  pgoyette #undef metric
1.1.2.1  pgoyette 	out->rtm_rmx.rmx_expire = in->rt_rmx.rmx_expire ?
1.1.2.1  pgoyette 	    time_mono_to_wall(in->rt_rmx.rmx_expire) : 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette rt_xaddrs(u_char rtmtype, const char *cp, const char *cplim,
1.1.2.1  pgoyette     struct rt_addrinfo *rtinfo)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	const struct sockaddr *sa = NULL;	/* Quell compiler warning */
1.1.2.1  pgoyette 	int i;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	for (i = 0; i < RTAX_MAX && cp < cplim; i++) {
1.1.2.1  pgoyette 		if ((rtinfo->rti_addrs & (1 << i)) == 0)
1.1.2.1  pgoyette 			continue;
1.1.2.1  pgoyette 		rtinfo->rti_info[i] = sa = (const struct sockaddr *)cp;
1.1.2.1  pgoyette 		RT_XADVANCE(cp, sa);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	/*
1.1.2.1  pgoyette 	 * Check for extra addresses specified, except RTM_GET asking
1.1.2.1  pgoyette 	 * for interface info.
1.1.2.1  pgoyette 	 */
1.1.2.1  pgoyette 	if (rtmtype == RTM_GET) {
1.1.2.1  pgoyette 		if (((rtinfo->rti_addrs &
1.1.2.1  pgoyette 		    (~((1 << RTAX_IFP) | (1 << RTAX_IFA)))) & (~0U << i)) != 0)
1.1.2.1  pgoyette 			return 1;
1.1.2.1  pgoyette 	} else if ((rtinfo->rti_addrs & (~0U << i)) != 0)
1.1.2.1  pgoyette 		return 1;
1.1.2.1  pgoyette 	/* Check for bad data length.  */
1.1.2.1  pgoyette 	if (cp != cplim) {
1.1.2.1  pgoyette 		if (i == RTAX_NETMASK + 1 && sa != NULL &&
1.1.2.1  pgoyette 		    cp - RT_XROUNDUP(sa->sa_len) + sa->sa_len == cplim)
1.1.2.1  pgoyette 			/*
1.1.2.1  pgoyette 			 * The last sockaddr was info.rti_info[RTAX_NETMASK].
1.1.2.1  pgoyette 			 * We accept this for now for the sake of old
1.1.2.1  pgoyette 			 * binaries or third party softwares.
1.1.2.1  pgoyette 			 */
1.1.2.1  pgoyette 			;
1.1.2.1  pgoyette 		else
1.1.2.1  pgoyette 			return 1;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette rt_getlen(int type)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	RTS_CTASSERT(__alignof(struct ifa_msghdr) >= sizeof(uint64_t));
1.1.2.1  pgoyette 	RTS_CTASSERT(__alignof(struct if_msghdr) >= sizeof(uint64_t));
1.1.2.1  pgoyette 	RTS_CTASSERT(__alignof(struct if_announcemsghdr) >= sizeof(uint64_t));
1.1.2.1  pgoyette 	RTS_CTASSERT(__alignof(struct rt_msghdr) >= sizeof(uint64_t));
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	switch (type) {
1.1.2.1  pgoyette 	case RTM_ODELADDR:
1.1.2.1  pgoyette 	case RTM_ONEWADDR:
1.1.2.1  pgoyette 	case RTM_OCHGADDR:
1.1.2.1  pgoyette 		if (rtsock_70_iflist_hook.hooked)
1.1.2.1  pgoyette 			return sizeof(struct ifa_msghdr70);
1.1.2.1  pgoyette 		else {
1.1.2.1  pgoyette #ifdef RTSOCK_DEBUG
1.1.2.1  pgoyette 			printf("%s: unsupported RTM type %d\n", __func__, type);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 			return -1;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	case RTM_DELADDR:
1.1.2.1  pgoyette 	case RTM_NEWADDR:
1.1.2.1  pgoyette 	case RTM_CHGADDR:
1.1.2.1  pgoyette 		return sizeof(struct ifa_xmsghdr);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	case RTM_OOIFINFO:
1.1.2.1  pgoyette 		if (rtsock_14_iflist_hook.hooked)
1.1.2.1  pgoyette 			return sizeof(struct if_msghdr14);
1.1.2.1  pgoyette 		else {
1.1.2.1  pgoyette #ifdef RTSOCK_DEBUG
1.1.2.1  pgoyette 			printf("%s: unsupported RTM type RTM_OOIFINFO\n",
1.1.2.1  pgoyette 			    __func__);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 			return -1;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	case RTM_OIFINFO:
1.1.2.1  pgoyette 		if (rtsock_50_iflist_hook.hooked)
1.1.2.1  pgoyette 			return sizeof(struct if_msghdr50);
1.1.2.1  pgoyette 		else {
1.1.2.1  pgoyette #ifdef RTSOCK_DEBUG
1.1.2.1  pgoyette 			printf("%s: unsupported RTM type RTM_OIFINFO\n",
1.1.2.1  pgoyette 			    __func__);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 			return -1;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	case RTM_IFINFO:
1.1.2.1  pgoyette 		return sizeof(struct if_xmsghdr);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	case RTM_IFANNOUNCE:
1.1.2.1  pgoyette 	case RTM_IEEE80211:
1.1.2.1  pgoyette 		return sizeof(struct if_xannouncemsghdr);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	default:
1.1.2.1  pgoyette 		return sizeof(struct rt_xmsghdr);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette
1.1.2.1  pgoyette struct mbuf *
1.1.2.1  pgoyette COMPATNAME(rt_msg1)(int type, struct rt_addrinfo *rtinfo, void *data, int datalen)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct rt_xmsghdr *rtm;
1.1.2.1  pgoyette 	struct mbuf *m;
1.1.2.1  pgoyette 	int i;
1.1.2.1  pgoyette 	const struct sockaddr *sa;
1.1.2.1  pgoyette 	int len, dlen;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	m = m_gethdr(M_DONTWAIT, MT_DATA);
1.1.2.1  pgoyette 	if (m == NULL)
1.1.2.1  pgoyette 		return m;
1.1.2.1  pgoyette 	MCLAIM(m, &COMPATNAME(routedomain).dom_mowner);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	if ((len = rt_getlen(type)) == -1)
1.1.2.1  pgoyette 		goto out;
1.1.2.1  pgoyette 	if (len > MHLEN + MLEN)
1.1.2.1  pgoyette 		panic("%s: message too long", __func__);
1.1.2.1  pgoyette 	else if (len > MHLEN) {
1.1.2.1  pgoyette 		m->m_next = m_get(M_DONTWAIT, MT_DATA);
1.1.2.1  pgoyette 		if (m->m_next == NULL)
1.1.2.1  pgoyette 			goto out;
1.1.2.1  pgoyette 		MCLAIM(m->m_next, m->m_owner);
1.1.2.1  pgoyette 		m->m_pkthdr.len = len;
1.1.2.1  pgoyette 		m->m_len = MHLEN;
1.1.2.1  pgoyette 		m->m_next->m_len = len - MHLEN;
1.1.2.1  pgoyette 	} else {
1.1.2.1  pgoyette 		m->m_pkthdr.len = m->m_len = len;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	m_reset_rcvif(m);
1.1.2.1  pgoyette 	m_copyback(m, 0, datalen, data);
1.1.2.1  pgoyette 	if (len > datalen)
1.1.2.1  pgoyette 		(void)memset(mtod(m, char *) + datalen, 0, len - datalen);
1.1.2.1  pgoyette 	rtm = mtod(m, struct rt_xmsghdr *);
1.1.2.1  pgoyette 	for (i = 0; i < RTAX_MAX; i++) {
1.1.2.1  pgoyette 		if ((sa = rtinfo->rti_info[i]) == NULL)
1.1.2.1  pgoyette 			continue;
1.1.2.1  pgoyette 		rtinfo->rti_addrs |= (1 << i);
1.1.2.1  pgoyette 		dlen = RT_XROUNDUP(sa->sa_len);
1.1.2.1  pgoyette 		m_copyback(m, len, sa->sa_len, sa);
1.1.2.1  pgoyette 		if (dlen != sa->sa_len) {
1.1.2.1  pgoyette 			/*
1.1.2.1  pgoyette 			 * Up to 7 + 1 nul's since roundup is to
1.1.2.1  pgoyette 			 * sizeof(uint64_t) (8 bytes)
1.1.2.1  pgoyette 			 */
1.1.2.1  pgoyette 			m_copyback(m, len + sa->sa_len,
1.1.2.1  pgoyette 			    dlen - sa->sa_len, "\0\0\0\0\0\0\0");
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 		len += dlen;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	if (m->m_pkthdr.len != len)
1.1.2.1  pgoyette 		goto out;
1.1.2.1  pgoyette 	rtm->rtm_msglen = len;
1.1.2.1  pgoyette 	rtm->rtm_version = RTM_XVERSION;
1.1.2.1  pgoyette 	rtm->rtm_type = type;
1.1.2.1  pgoyette 	return m;
1.1.2.1  pgoyette out:
1.1.2.1  pgoyette 	m_freem(m);
1.1.2.1  pgoyette 	return NULL;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * rt_msg2
1.1.2.1  pgoyette  *
1.1.2.1  pgoyette  *	 fills 'cp' or 'w'.w_tmem with the routing socket message and
1.1.2.1  pgoyette  *		returns the length of the message in 'lenp'.
1.1.2.1  pgoyette  *
1.1.2.1  pgoyette  * if walkarg is 0, cp is expected to be 0 or a buffer large enough to hold
1.1.2.1  pgoyette  *	the message
1.1.2.1  pgoyette  * otherwise walkarg's w_needed is updated and if the user buffer is
1.1.2.1  pgoyette  *	specified and w_needed indicates space exists the information is copied
1.1.2.1  pgoyette  *	into the temp space (w_tmem). w_tmem is [re]allocated if necessary,
1.1.2.1  pgoyette  *	if the allocation fails ENOBUFS is returned.
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette static int
1.1.2.1  pgoyette rt_msg2(int type, struct rt_addrinfo *rtinfo, void *cpv, struct rt_walkarg *w,
1.1.2.1  pgoyette 	int *lenp)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	int i;
1.1.2.1  pgoyette 	int len, dlen, second_time = 0;
1.1.2.1  pgoyette 	char *cp0, *cp = cpv;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	rtinfo->rti_addrs = 0;
1.1.2.1  pgoyette again:
1.1.2.1  pgoyette 	if ((len = rt_getlen(type)) == -1)
1.1.2.1  pgoyette 		return EINVAL;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	if ((cp0 = cp) != NULL)
1.1.2.1  pgoyette 		cp += len;
1.1.2.1  pgoyette 	for (i = 0; i < RTAX_MAX; i++) {
1.1.2.1  pgoyette 		const struct sockaddr *sa;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 		if ((sa = rtinfo->rti_info[i]) == NULL)
1.1.2.1  pgoyette 			continue;
1.1.2.1  pgoyette 		rtinfo->rti_addrs |= (1 << i);
1.1.2.1  pgoyette 		dlen = RT_XROUNDUP(sa->sa_len);
1.1.2.1  pgoyette 		if (cp) {
1.1.2.1  pgoyette 			int diff = dlen - sa->sa_len;
1.1.2.1  pgoyette 			(void)memcpy(cp, sa, (size_t)sa->sa_len);
1.1.2.1  pgoyette 			cp += sa->sa_len;
1.1.2.1  pgoyette 			if (diff > 0) {
1.1.2.1  pgoyette 				(void)memset(cp, 0, (size_t)diff);
1.1.2.1  pgoyette 				cp += diff;
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 		len += dlen;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	if (cp == NULL && w != NULL && !second_time) {
1.1.2.1  pgoyette 		struct rt_walkarg *rw = w;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 		rw->w_needed += len;
1.1.2.1  pgoyette 		if (rw->w_needed <= 0 && rw->w_where) {
1.1.2.1  pgoyette 			if (rw->w_tmemsize < len) {
1.1.2.1  pgoyette 				if (rw->w_tmem)
1.1.2.1  pgoyette 					kmem_free(rw->w_tmem, rw->w_tmemsize);
1.1.2.1  pgoyette 				rw->w_tmem = kmem_zalloc(len, KM_SLEEP);
1.1.2.1  pgoyette 				rw->w_tmemsize = len;
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 			if (rw->w_tmem) {
1.1.2.1  pgoyette 				cp = rw->w_tmem;
1.1.2.1  pgoyette 				second_time = 1;
1.1.2.1  pgoyette 				goto again;
1.1.2.1  pgoyette 			} else {
1.1.2.1  pgoyette 				rw->w_tmemneeded = len;
1.1.2.1  pgoyette 				return ENOBUFS;
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	if (cp) {
1.1.2.1  pgoyette 		struct rt_xmsghdr *rtm = (struct rt_xmsghdr *)cp0;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 		rtm->rtm_version = RTM_XVERSION;
1.1.2.1  pgoyette 		rtm->rtm_type = type;
1.1.2.1  pgoyette 		rtm->rtm_msglen = len;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	if (lenp)
1.1.2.1  pgoyette 		*lenp = len;
1.1.2.1  pgoyette 	return 0;
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * MODULE_HOOK glue for rtsock_14_oifmsg and rtsock_14_iflist
1.1.2.1  pgoyette  */
1.1.2.6  pgoyette MODULE_CALL_HOOK_DECL(rtsock_14_oifmsg_hook, void, (struct ifnet *ifp));
1.1.2.1  pgoyette
1.1.2.5  pgoyette MODULE_CALL_HOOK_DECL(rtsock_14_iflist_hook, int,
1.1.2.1  pgoyette     (struct ifnet *ifp, struct rt_walkarg *w, struct rt_addrinfo *info,
1.1.2.1  pgoyette      size_t len));
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * MODULE_HOOK glue for rtsock_50 ifaddr_list and various message routines
1.1.2.1  pgoyette  */
1.1.2.5  pgoyette MODULE_CALL_HOOK_DECL(rtsock_50_iflist_hook, int,
1.1.2.1  pgoyette     (struct ifnet *ifp, struct rt_walkarg *w, struct rt_addrinfo *info,
1.1.2.1  pgoyette      size_t len));
1.1.2.1  pgoyette
1.1.2.6  pgoyette MODULE_CALL_HOOK_DECL(rtsock_50_rt_missmsg_hook, void,
1.1.2.1  pgoyette     (int, const struct rt_addrinfo *, int, int));
1.1.2.1  pgoyette
1.1.2.6  pgoyette MODULE_CALL_HOOK_DECL(rtsock_50_rt_ifmsg_hook, void, (struct ifnet *));
1.1.2.1  pgoyette
1.1.2.6  pgoyette MODULE_CALL_HOOK_DECL(rtsock_50_rt_newaddrmsg_hook, void,
1.1.2.1  pgoyette     (int, struct ifaddr *, int, struct rtentry *));
1.1.2.1  pgoyette
1.1.2.6  pgoyette MODULE_CALL_HOOK_DECL(rtsock_50_rt_ifannouncemsg_hook, void,
1.1.2.1  pgoyette     (struct ifnet *, int what));
1.1.2.1  pgoyette
1.1.2.6  pgoyette MODULE_CALL_HOOK_DECL(rtsock_50_rt_ieee80211msg_hook, void,
1.1.2.1  pgoyette     (struct ifnet *, int, void *, size_t));
1.1.2.1  pgoyette
1.1.2.6  pgoyette MODULE_CALL_HOOK_DECL(rtsock_50_oifmsg_hook, void, (struct ifnet *ifp));
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * MODULE_HOOK glue for rtsock70_newaddrmsg1, rtsock70_ifaddr_listaddr,
1.1.2.1  pgoyette  * and rtsock70_ifaddr_listif
1.1.2.1  pgoyette  */
1.1.2.6  pgoyette MODULE_CALL_HOOK_DECL(rtsock_70_newaddr_hook, void, (int, struct ifaddr *));
1.1.2.1  pgoyette
1.1.2.5  pgoyette MODULE_CALL_HOOK_DECL(rtsock_70_iflist_hook, int,
1.1.2.1  pgoyette     (struct rt_walkarg *, struct ifaddr *, struct rt_addrinfo *));
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * This routine is called to generate a message from the routing
1.1.2.1  pgoyette  * socket indicating that a redirect has occurred, a routing lookup
1.1.2.1  pgoyette  * has failed, or that a protocol has detected timeouts to a particular
1.1.2.1  pgoyette  * destination.
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette void
1.1.2.1  pgoyette COMPATNAME(rt_missmsg)(int type, const struct rt_addrinfo *rtinfo, int flags,
1.1.2.1  pgoyette     int error)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct rt_xmsghdr rtm;
1.1.2.1  pgoyette 	struct mbuf *m;
1.1.2.1  pgoyette 	const struct sockaddr *sa = rtinfo->rti_info[RTAX_DST];
1.1.2.1  pgoyette 	struct rt_addrinfo info = *rtinfo;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	COMPATCALL(rt_missmsg, (type, rtinfo, flags, error));
1.1.2.1  pgoyette 	if (COMPATNAME(route_info).ri_cb.any_count == 0)
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	memset(&rtm, 0, sizeof(rtm));
1.1.2.1  pgoyette 	rtm.rtm_pid = curproc->p_pid;
1.1.2.1  pgoyette 	rtm.rtm_flags = RTF_DONE | flags;
1.1.2.1  pgoyette 	rtm.rtm_errno = error;
1.1.2.1  pgoyette 	m = COMPATNAME(rt_msg1)(type, &info, &rtm, sizeof(rtm));
1.1.2.1  pgoyette 	if (m == NULL)
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	mtod(m, struct rt_xmsghdr *)->rtm_addrs = info.rti_addrs;
1.1.2.1  pgoyette 	COMPATNAME(route_enqueue)(m, sa ? sa->sa_family : 0);
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * This routine is called to generate a message from the routing
1.1.2.1  pgoyette  * socket indicating that the status of a network interface has changed.
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette void
1.1.2.1  pgoyette COMPATNAME(rt_ifmsg)(struct ifnet *ifp)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct if_xmsghdr ifm;
1.1.2.1  pgoyette 	struct mbuf *m;
1.1.2.1  pgoyette 	struct rt_addrinfo info;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	COMPATCALL(rt_ifmsg, (ifp));
1.1.2.1  pgoyette 	if (COMPATNAME(route_info).ri_cb.any_count == 0)
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	(void)memset(&info, 0, sizeof(info));
1.1.2.1  pgoyette 	(void)memset(&ifm, 0, sizeof(ifm));
1.1.2.1  pgoyette 	ifm.ifm_index = ifp->if_index;
1.1.2.1  pgoyette 	ifm.ifm_flags = ifp->if_flags;
1.1.2.1  pgoyette 	ifm.ifm_data = ifp->if_data;
1.1.2.1  pgoyette 	ifm.ifm_addrs = 0;
1.1.2.1  pgoyette 	m = COMPATNAME(rt_msg1)(RTM_IFINFO, &info, &ifm, sizeof(ifm));
1.1.2.1  pgoyette 	if (m == NULL)
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	COMPATNAME(route_enqueue)(m, 0);
1.1.2.1  pgoyette 	rtsock_14_oifmsg_hook_call(ifp);
1.1.2.1  pgoyette 	rtsock_50_oifmsg_hook_call(ifp);
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * This is called to generate messages from the routing socket
1.1.2.1  pgoyette  * indicating a network interface has had addresses associated with it.
1.1.2.1  pgoyette  * if we ever reverse the logic and replace messages TO the routing
1.1.2.1  pgoyette  * socket indicate a request to configure interfaces, then it will
1.1.2.1  pgoyette  * be unnecessary as the routing socket will automatically generate
1.1.2.1  pgoyette  * copies of it.
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette void
1.1.2.1  pgoyette COMPATNAME(rt_newaddrmsg)(int cmd, struct ifaddr *ifa, int error,
1.1.2.1  pgoyette     struct rtentry *rt)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette #define	cmdpass(__cmd, __pass)	(((__cmd) << 2) | (__pass))
1.1.2.1  pgoyette 	struct rt_addrinfo info;
1.1.2.1  pgoyette 	const struct sockaddr *sa;
1.1.2.1  pgoyette 	int pass;
1.1.2.1  pgoyette 	struct mbuf *m;
1.1.2.1  pgoyette 	struct ifnet *ifp;
1.1.2.1  pgoyette 	struct rt_xmsghdr rtm;
1.1.2.1  pgoyette 	struct ifa_xmsghdr ifam;
1.1.2.1  pgoyette 	int ncmd;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	KASSERT(ifa != NULL);
1.1.2.1  pgoyette 	KASSERT(ifa->ifa_addr != NULL);
1.1.2.1  pgoyette 	ifp = ifa->ifa_ifp;
1.1.2.3  pgoyette 	if (cmd == RTM_ADD && vec_sctp_add_ip_address != NULL) {
1.1.2.3  pgoyette 		(*vec_sctp_add_ip_address)(ifa);
1.1.2.3  pgoyette 	} else if (cmd == RTM_DELETE && vec_sctp_delete_ip_address != NULL) {
1.1.2.3  pgoyette 		(*vec_sctp_delete_ip_address)(ifa);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	COMPATCALL(rt_newaddrmsg, (cmd, ifa, error, rt));
1.1.2.1  pgoyette 	if (COMPATNAME(route_info).ri_cb.any_count == 0)
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	for (pass = 1; pass < 3; pass++) {
1.1.2.1  pgoyette 		memset(&info, 0, sizeof(info));
1.1.2.1  pgoyette 		switch (cmdpass(cmd, pass)) {
1.1.2.1  pgoyette 		case cmdpass(RTM_ADD, 1):
1.1.2.1  pgoyette 		case cmdpass(RTM_CHANGE, 1):
1.1.2.1  pgoyette 		case cmdpass(RTM_DELETE, 2):
1.1.2.1  pgoyette 		case cmdpass(RTM_NEWADDR, 1):
1.1.2.1  pgoyette 		case cmdpass(RTM_DELADDR, 1):
1.1.2.1  pgoyette 		case cmdpass(RTM_CHGADDR, 1):
1.1.2.1  pgoyette 			switch (cmd) {
1.1.2.1  pgoyette 			case RTM_ADD:
1.1.2.1  pgoyette 				ncmd = RTM_XNEWADDR;
1.1.2.1  pgoyette 				break;
1.1.2.1  pgoyette 			case RTM_DELETE:
1.1.2.1  pgoyette 				ncmd = RTM_XDELADDR;
1.1.2.1  pgoyette 				break;
1.1.2.1  pgoyette 			case RTM_CHANGE:
1.1.2.1  pgoyette 				ncmd = RTM_XCHGADDR;
1.1.2.1  pgoyette 				break;
1.1.2.1  pgoyette 			case RTM_NEWADDR:
1.1.2.1  pgoyette 				ncmd = RTM_XNEWADDR;
1.1.2.1  pgoyette 				break;
1.1.2.1  pgoyette 			case RTM_DELADDR:
1.1.2.1  pgoyette 				ncmd = RTM_XDELADDR;
1.1.2.1  pgoyette 				break;
1.1.2.1  pgoyette 			case RTM_CHGADDR:
1.1.2.1  pgoyette 				ncmd = RTM_XCHGADDR;
1.1.2.1  pgoyette 				break;
1.1.2.1  pgoyette 			default:
1.1.2.1  pgoyette 				panic("%s: unknown command %d", __func__, cmd);
1.1.2.1  pgoyette 			}
1.1.2.1  pgoyette 			rtsock_70_newaddr_hook_call(ncmd, ifa);
1.1.2.1  pgoyette 			info.rti_info[RTAX_IFA] = sa = ifa->ifa_addr;
1.1.2.1  pgoyette 			KASSERT(ifp->if_dl != NULL);
1.1.2.1  pgoyette 			info.rti_info[RTAX_IFP] = ifp->if_dl->ifa_addr;
1.1.2.1  pgoyette 			info.rti_info[RTAX_NETMASK] = ifa->ifa_netmask;
1.1.2.1  pgoyette 			info.rti_info[RTAX_BRD] = ifa->ifa_dstaddr;
1.1.2.1  pgoyette 			memset(&ifam, 0, sizeof(ifam));
1.1.2.1  pgoyette 			ifam.ifam_index = ifp->if_index;
1.1.2.1  pgoyette 			ifam.ifam_metric = ifa->ifa_metric;
1.1.2.1  pgoyette 			ifam.ifam_flags = ifa->ifa_flags;
1.1.2.1  pgoyette #ifndef COMPAT_RTSOCK
1.1.2.1  pgoyette 			ifam.ifam_pid = curproc->p_pid;
1.1.2.1  pgoyette 			ifam.ifam_addrflags = if_addrflags(ifa);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 			m = COMPATNAME(rt_msg1)(ncmd, &info, &ifam, sizeof(ifam));
1.1.2.1  pgoyette 			if (m == NULL)
1.1.2.1  pgoyette 				continue;
1.1.2.1  pgoyette 			mtod(m, struct ifa_xmsghdr *)->ifam_addrs =
1.1.2.1  pgoyette 			    info.rti_addrs;
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		case cmdpass(RTM_ADD, 2):
1.1.2.1  pgoyette 		case cmdpass(RTM_CHANGE, 2):
1.1.2.1  pgoyette 		case cmdpass(RTM_DELETE, 1):
1.1.2.1  pgoyette 			if (rt == NULL)
1.1.2.1  pgoyette 				continue;
1.1.2.1  pgoyette 			info.rti_info[RTAX_NETMASK] = rt_mask(rt);
1.1.2.1  pgoyette 			info.rti_info[RTAX_DST] = sa = rt_getkey(rt);
1.1.2.1  pgoyette 			info.rti_info[RTAX_GATEWAY] = rt->rt_gateway;
1.1.2.1  pgoyette 			memset(&rtm, 0, sizeof(rtm));
1.1.2.1  pgoyette 			rtm.rtm_pid = curproc->p_pid;
1.1.2.1  pgoyette 			rtm.rtm_index = ifp->if_index;
1.1.2.1  pgoyette 			rtm.rtm_flags |= rt->rt_flags;
1.1.2.1  pgoyette 			rtm.rtm_errno = error;
1.1.2.1  pgoyette 			m = COMPATNAME(rt_msg1)(cmd, &info, &rtm, sizeof(rtm));
1.1.2.1  pgoyette 			if (m == NULL)
1.1.2.1  pgoyette 				continue;
1.1.2.1  pgoyette 			mtod(m, struct rt_xmsghdr *)->rtm_addrs = info.rti_addrs;
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		default:
1.1.2.1  pgoyette 			continue;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 		KASSERTMSG(m != NULL, "called with wrong command");
1.1.2.1  pgoyette 		COMPATNAME(route_enqueue)(m, sa ? sa->sa_family : 0);
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette #undef cmdpass
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static struct mbuf *
1.1.2.1  pgoyette rt_makeifannouncemsg(struct ifnet *ifp, int type, int what,
1.1.2.1  pgoyette     struct rt_addrinfo *info)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct if_xannouncemsghdr ifan;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	memset(info, 0, sizeof(*info));
1.1.2.1  pgoyette 	memset(&ifan, 0, sizeof(ifan));
1.1.2.1  pgoyette 	ifan.ifan_index = ifp->if_index;
1.1.2.1  pgoyette 	strlcpy(ifan.ifan_name, ifp->if_xname, sizeof(ifan.ifan_name));
1.1.2.1  pgoyette 	ifan.ifan_what = what;
1.1.2.1  pgoyette 	return COMPATNAME(rt_msg1)(type, info, &ifan, sizeof(ifan));
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * This is called to generate routing socket messages indicating
1.1.2.1  pgoyette  * network interface arrival and departure.
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette void
1.1.2.1  pgoyette COMPATNAME(rt_ifannouncemsg)(struct ifnet *ifp, int what)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct mbuf *m;
1.1.2.1  pgoyette 	struct rt_addrinfo info;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	COMPATCALL(rt_ifannouncemsg, (ifp, what));
1.1.2.1  pgoyette 	if (COMPATNAME(route_info).ri_cb.any_count == 0)
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	m = rt_makeifannouncemsg(ifp, RTM_IFANNOUNCE, what, &info);
1.1.2.1  pgoyette 	if (m == NULL)
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	COMPATNAME(route_enqueue)(m, 0);
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * This is called to generate routing socket messages indicating
1.1.2.1  pgoyette  * IEEE80211 wireless events.
1.1.2.1  pgoyette  * XXX we piggyback on the RTM_IFANNOUNCE msg format in a clumsy way.
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette void
1.1.2.1  pgoyette COMPATNAME(rt_ieee80211msg)(struct ifnet *ifp, int what, void *data,
1.1.2.1  pgoyette 	size_t data_len)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct mbuf *m;
1.1.2.1  pgoyette 	struct rt_addrinfo info;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	COMPATCALL(rt_ieee80211msg, (ifp, what, data, data_len));
1.1.2.1  pgoyette 	if (COMPATNAME(route_info).ri_cb.any_count == 0)
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	m = rt_makeifannouncemsg(ifp, RTM_IEEE80211, what, &info);
1.1.2.1  pgoyette 	if (m == NULL)
1.1.2.1  pgoyette 		return;
1.1.2.1  pgoyette 	/*
1.1.2.1  pgoyette 	 * Append the ieee80211 data.  Try to stick it in the
1.1.2.1  pgoyette 	 * mbuf containing the ifannounce msg; otherwise allocate
1.1.2.1  pgoyette 	 * a new mbuf and append.
1.1.2.1  pgoyette 	 *
1.1.2.1  pgoyette 	 * NB: we assume m is a single mbuf.
1.1.2.1  pgoyette 	 */
1.1.2.1  pgoyette 	if (data_len > M_TRAILINGSPACE(m)) {
1.1.2.1  pgoyette 		struct mbuf *n = m_get(M_NOWAIT, MT_DATA);
1.1.2.1  pgoyette 		if (n == NULL) {
1.1.2.1  pgoyette 			m_freem(m);
1.1.2.1  pgoyette 			return;
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 		(void)memcpy(mtod(n, void *), data, data_len);
1.1.2.1  pgoyette 		n->m_len = data_len;
1.1.2.1  pgoyette 		m->m_next = n;
1.1.2.1  pgoyette 	} else if (data_len > 0) {
1.1.2.1  pgoyette 		(void)memcpy(mtod(m, uint8_t *) + m->m_len, data, data_len);
1.1.2.1  pgoyette 		m->m_len += data_len;
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	if (m->m_flags & M_PKTHDR)
1.1.2.1  pgoyette 		m->m_pkthdr.len += data_len;
1.1.2.1  pgoyette 	mtod(m, struct if_xannouncemsghdr *)->ifan_msglen += data_len;
1.1.2.1  pgoyette 	COMPATNAME(route_enqueue)(m, 0);
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * Routing message software interrupt routine
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette static void
1.1.2.1  pgoyette COMPATNAME(route_intr)(void *cookie)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct sockproto proto = { .sp_family = PF_XROUTE, };
1.1.2.1  pgoyette 	struct route_info * const ri = &COMPATNAME(route_info);
1.1.2.1  pgoyette 	struct mbuf *m;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	SOFTNET_KERNEL_LOCK_UNLESS_NET_MPSAFE();
1.1.2.1  pgoyette 	for (;;) {
1.1.2.1  pgoyette 		IFQ_LOCK(&ri->ri_intrq);
1.1.2.1  pgoyette 		IF_DEQUEUE(&ri->ri_intrq, m);
1.1.2.1  pgoyette 		IFQ_UNLOCK(&ri->ri_intrq);
1.1.2.1  pgoyette 		if (m == NULL)
1.1.2.1  pgoyette 			break;
1.1.2.1  pgoyette 		proto.sp_protocol = M_GETCTX(m, uintptr_t);
1.1.2.1  pgoyette #ifdef NET_MPSAFE
1.1.2.1  pgoyette 		mutex_enter(rt_so_mtx);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 		raw_input(m, &proto, &ri->ri_src, &ri->ri_dst, &rt_rawcb);
1.1.2.1  pgoyette #ifdef NET_MPSAFE
1.1.2.1  pgoyette 		mutex_exit(rt_so_mtx);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette 	SOFTNET_KERNEL_UNLOCK_UNLESS_NET_MPSAFE();
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * Enqueue a message to the software interrupt routine.
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette void
1.1.2.1  pgoyette COMPATNAME(route_enqueue)(struct mbuf *m, int family)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct route_info * const ri = &COMPATNAME(route_info);
1.1.2.1  pgoyette 	int wasempty;
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	IFQ_LOCK(&ri->ri_intrq);
1.1.2.1  pgoyette 	if (IF_QFULL(&ri->ri_intrq)) {
1.1.2.1  pgoyette 		printf("%s: queue full, dropped message\n", __func__);
1.1.2.1  pgoyette 		IF_DROP(&ri->ri_intrq);
1.1.2.1  pgoyette 		IFQ_UNLOCK(&ri->ri_intrq);
1.1.2.1  pgoyette 		m_freem(m);
1.1.2.1  pgoyette 	} else {
1.1.2.1  pgoyette 		wasempty = IF_IS_EMPTY(&ri->ri_intrq);
1.1.2.1  pgoyette 		M_SETCTX(m, (uintptr_t)family);
1.1.2.1  pgoyette 		IF_ENQUEUE(&ri->ri_intrq, m);
1.1.2.1  pgoyette 		IFQ_UNLOCK(&ri->ri_intrq);
1.1.2.1  pgoyette 		if (wasempty) {
1.1.2.1  pgoyette 			kpreempt_disable();
1.1.2.1  pgoyette 			softint_schedule(ri->ri_sih);
1.1.2.1  pgoyette 			kpreempt_enable();
1.1.2.1  pgoyette 		}
1.1.2.1  pgoyette 	}
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette static void
1.1.2.1  pgoyette COMPATNAME(route_init)(void)
1.1.2.1  pgoyette {
1.1.2.1  pgoyette 	struct route_info * const ri = &COMPATNAME(route_info);
1.1.2.1  pgoyette
1.1.2.1  pgoyette #ifndef COMPAT_RTSOCK
1.1.2.1  pgoyette 	rt_init();
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette #ifdef NET_MPSAFE
1.1.2.1  pgoyette 	rt_so_mtx = mutex_obj_alloc(MUTEX_DEFAULT, IPL_NONE);
1.1.2.1  pgoyette
1.1.2.1  pgoyette 	cv_init(&rt_update_cv, "rtsock_cv");
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette
1.1.2.1  pgoyette #ifndef COMPAT_RTSOCK
1.1.2.1  pgoyette 	sysctl_net_route_setup(NULL);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette 	ri->ri_intrq.ifq_maxlen = ri->ri_maxqlen;
1.1.2.1  pgoyette 	ri->ri_sih = softint_establish(SOFTINT_NET | SOFTINT_MPSAFE,
1.1.2.1  pgoyette 	    COMPATNAME(route_intr), NULL);
1.1.2.1  pgoyette 	IFQ_LOCK_INIT(&ri->ri_intrq);
1.1.2.1  pgoyette }
1.1.2.1  pgoyette
1.1.2.1  pgoyette /*
1.1.2.1  pgoyette  * Definitions of protocols supported in the ROUTE domain.
1.1.2.1  pgoyette  */
1.1.2.1  pgoyette #ifndef COMPAT_RTSOCK
1.1.2.1  pgoyette PR_WRAP_USRREQS(route);
1.1.2.1  pgoyette #else
1.1.2.1  pgoyette PR_WRAP_USRREQS(compat_50_route);
1.1.2.1  pgoyette #endif
1.1.2.1  pgoyette
1.1.2.1  pgoyette static const struct pr_usrreqs route_usrreqs = {
1.1.2.1  pgoyette 	.pr_attach	= COMPATNAME(route_attach_wrapper),
1.1.2.1  pgoyette 	.pr_detach	= COMPATNAME(route_detach_wrapper),
1.1.2.1  pgoyette 	.pr_accept	= COMPATNAME(route_accept_wrapper),
1.1.2.1  pgoyette 	.pr_bind	= COMPATNAME(route_bind_wrapper),
1.1.2.1  pgoyette 	.pr_listen	= COMPATNAME(route_listen_wrapper),
1.1.2.1  pgoyette 	.pr_connect	= COMPATNAME(route_connect_wrapper),
1.1.2.1  pgoyette 	.pr_connect2	= COMPATNAME(route_connect2_wrapper),
1.1.2.1  pgoyette 	.pr_disconnect	= COMPATNAME(route_disconnect_wrapper),
1.1.2.1  pgoyette 	.pr_shutdown	= COMPATNAME(route_shutdown_wrapper),
1.1.2.1  pgoyette 	.pr_abort	= COMPATNAME(route_abort_wrapper),
1.1.2.1  pgoyette 	.pr_ioctl	= COMPATNAME(route_ioctl_wrapper),
1.1.2.1  pgoyette 	.pr_stat	= COMPATNAME(route_stat_wrapper),
1.1.2.1  pgoyette 	.pr_peeraddr	= COMPATNAME(route_peeraddr_wrapper),
1.1.2.1  pgoyette 	.pr_sockaddr	= COMPATNAME(route_sockaddr_wrapper),
1.1.2.1  pgoyette 	.pr_rcvd	= COMPATNAME(route_rcvd_wrapper),
1.1.2.1  pgoyette 	.pr_recvoob	= COMPATNAME(route_recvoob_wrapper),
1.1.2.1  pgoyette 	.pr_send	= COMPATNAME(route_send_wrapper),
1.1.2.1  pgoyette 	.pr_sendoob	= COMPATNAME(route_sendoob_wrapper),
1.1.2.1  pgoyette 	.pr_purgeif	= COMPATNAME(route_purgeif_wrapper),
1.1.2.1  pgoyette };
1.1.2.1  pgoyette
1.1.2.1  pgoyette static const struct protosw COMPATNAME(route_protosw)[] = {
1.1.2.1  pgoyette 	{
1.1.2.1  pgoyette 		.pr_type = SOCK_RAW,
1.1.2.1  pgoyette 		.pr_domain = &COMPATNAME(routedomain),
1.1.2.1  pgoyette 		.pr_flags = PR_ATOMIC|PR_ADDR,
1.1.2.1  pgoyette 		.pr_ctlinput = raw_ctlinput,
1.1.2.1  pgoyette 		.pr_ctloutput = route_ctloutput,
1.1.2.1  pgoyette 		.pr_usrreqs = &route_usrreqs,
1.1.2.1  pgoyette 		.pr_init = rt_pr_init,
1.1.2.1  pgoyette 	},
1.1.2.1  pgoyette };
1.1.2.1  pgoyette
1.1.2.1  pgoyette struct domain COMPATNAME(routedomain) = {
1.1.2.1  pgoyette 	.dom_family = PF_XROUTE,
1.1.2.1  pgoyette 	.dom_name = DOMAINNAME,
1.1.2.1  pgoyette 	.dom_init = COMPATNAME(route_init),
1.1.2.1  pgoyette 	.dom_protosw = COMPATNAME(route_protosw),
1.1.2.1  pgoyette 	.dom_protoswNPROTOSW =
1.1.2.1  pgoyette 	    &COMPATNAME(route_protosw)[__arraycount(COMPATNAME(route_protosw))],
1.1.2.1  pgoyette };