Remove building with NOCRYPTO option
[minix.git] / minix / net / lwip / udpsock.c
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1 /* LWIP service - udpsock.c - UDP sockets */
3 #include "lwip.h"
4 #include "ifaddr.h"
5 #include "pktsock.h"
7 #include "lwip/udp.h"
9 #include <netinet/udp.h>
10 #include <netinet/ip_var.h>
11 #include <netinet/udp_var.h>
13 /* The number of UDP sockets. Inherited from the lwIP configuration. */
14 #define NR_UDPSOCK MEMP_NUM_UDP_PCB
17 * Outgoing packets are not getting buffered, so the send buffer size simply
18 * determines the maximum size for sent packets. The send buffer maximum is
19 * therefore limited to the maximum size of a single packet (64K-1 bytes),
20 * which is already enforced by lwIP's 16-bit length parameter to pbuf_alloc().
22 * The actual transmission may enforce a lower limit, though. The full packet
23 * size must not exceed the same 64K-1 limit, and that includes any headers
24 * that still have to be prepended to the given packet. The size of those
25 * headers depends on the socket type (IPv4/IPv6) and the IP_HDRINCL setting.
27 #define UDP_MAX_PAYLOAD (UINT16_MAX)
29 #define UDP_SNDBUF_MIN 1 /* minimum UDP send buffer size */
30 #define UDP_SNDBUF_DEF 8192 /* default UDP send buffer size */
31 #define UDP_SNDBUF_MAX UDP_MAX_PAYLOAD /* maximum UDP send buffer size */
32 #define UDP_RCVBUF_MIN MEMPOOL_BUFSIZE /* minimum UDP receive buffer size */
33 #define UDP_RCVBUF_DEF 32768 /* default UDP receive buffer size */
34 #define UDP_RCVBUF_MAX 65536 /* maximum UDP receive buffer size */
36 static struct udpsock {
37 struct pktsock udp_pktsock; /* pkt socket, MUST be first */
38 struct udp_pcb *udp_pcb; /* lwIP UDP control block */
39 SIMPLEQ_ENTRY(udpsock) udp_next; /* next in free list */
40 } udp_array[NR_UDPSOCK];
42 static SIMPLEQ_HEAD(, udpsock) udp_freelist; /* list of free UDP sockets */
44 static const struct sockevent_ops udpsock_ops;
46 #define udpsock_get_sock(udp) (ipsock_get_sock(udpsock_get_ipsock(udp)))
47 #define udpsock_get_ipsock(udp) (pktsock_get_ipsock(&(udp)->udp_pktsock))
48 #define udpsock_is_ipv6(udp) (ipsock_is_ipv6(udpsock_get_ipsock(udp)))
49 #define udpsock_is_conn(udp) \
50 (udp_flags((udp)->udp_pcb) & UDP_FLAGS_CONNECTED)
52 static ssize_t udpsock_pcblist(struct rmib_call *, struct rmib_node *,
53 struct rmib_oldp *, struct rmib_newp *);
55 /* The CTL_NET {PF_INET,PF_INET6} IPPROTO_UDP subtree. */
56 /* TODO: add many more and make some of them writable.. */
57 static struct rmib_node net_inet_udp_table[] = {
58 /* 1*/ [UDPCTL_CHECKSUM] = RMIB_INT(RMIB_RO, 1, "checksum",
59 "Compute UDP checksums"),
60 /* 2*/ [UDPCTL_SENDSPACE] = RMIB_INT(RMIB_RO, UDP_SNDBUF_DEF,
61 "sendspace",
62 "Default UDP send buffer size"),
63 /* 3*/ [UDPCTL_RECVSPACE] = RMIB_INT(RMIB_RO, UDP_RCVBUF_DEF,
64 "recvspace",
65 "Default UDP receive buffer size"),
66 /* 4*/ [UDPCTL_LOOPBACKCKSUM] = RMIB_FUNC(RMIB_RW | CTLTYPE_INT, sizeof(int),
67 loopif_cksum, "do_loopback_cksum",
68 "Perform UDP checksum on loopback"),
69 /*+0*/ [UDPCTL_MAXID] = RMIB_FUNC(RMIB_RO | CTLTYPE_NODE, 0,
70 udpsock_pcblist, "pcblist",
71 "UDP protocol control block list"),
74 static struct rmib_node net_inet_udp_node =
75 RMIB_NODE(RMIB_RO, net_inet_udp_table, "udp", "UDPv4 related settings");
76 static struct rmib_node net_inet6_udp6_node =
77 RMIB_NODE(RMIB_RO, net_inet_udp_table, "udp6", "UDPv6 related settings");
80 * Initialize the UDP sockets module.
82 void
83 udpsock_init(void)
85 unsigned int slot;
87 /* Initialize the list of free UDP sockets. */
88 SIMPLEQ_INIT(&udp_freelist);
90 for (slot = 0; slot < __arraycount(udp_array); slot++)
91 SIMPLEQ_INSERT_TAIL(&udp_freelist, &udp_array[slot], udp_next);
93 /* Register the net.inet.udp and net.inet6.udp6 RMIB subtrees. */
94 mibtree_register_inet(PF_INET, IPPROTO_UDP, &net_inet_udp_node);
95 mibtree_register_inet(PF_INET6, IPPROTO_UDP, &net_inet6_udp6_node);
99 * A packet has arrived on a UDP socket. We own the given packet buffer, and
100 * so we must free it if we do not want to keep it.
102 static void
103 udpsock_input(void * arg, struct udp_pcb * pcb __unused, struct pbuf * pbuf,
104 const ip_addr_t * ipaddr, uint16_t port)
106 struct udpsock *udp = (struct udpsock *)arg;
108 /* All UDP input processing is handled by pktsock. */
109 pktsock_input(&udp->udp_pktsock, pbuf, ipaddr, port);
113 * Create a UDP socket.
115 sockid_t
116 udpsock_socket(int domain, int protocol, struct sock ** sockp,
117 const struct sockevent_ops ** ops)
119 struct udpsock *udp;
120 unsigned int flags;
121 uint8_t ip_type;
123 switch (protocol) {
124 case 0:
125 case IPPROTO_UDP:
126 break;
128 /* NetBSD does not support IPPROTO_UDPLITE, even though lwIP does. */
129 default:
130 return EPROTONOSUPPORT;
133 if (SIMPLEQ_EMPTY(&udp_freelist))
134 return ENOBUFS;
136 udp = SIMPLEQ_FIRST(&udp_freelist);
138 ip_type = pktsock_socket(&udp->udp_pktsock, domain, UDP_SNDBUF_DEF,
139 UDP_RCVBUF_DEF, sockp);
141 /* We should have enough PCBs so this call should not fail.. */
142 if ((udp->udp_pcb = udp_new_ip_type(ip_type)) == NULL)
143 return ENOBUFS;
144 udp_recv(udp->udp_pcb, udpsock_input, (void *)udp);
146 /* By default, the multicast TTL is 1 and looping is enabled. */
147 udp_set_multicast_ttl(udp->udp_pcb, 1);
149 flags = udp_flags(udp->udp_pcb);
150 udp_setflags(udp->udp_pcb, flags | UDP_FLAGS_MULTICAST_LOOP);
152 SIMPLEQ_REMOVE_HEAD(&udp_freelist, udp_next);
154 *ops = &udpsock_ops;
155 return SOCKID_UDP | (sockid_t)(udp - udp_array);
159 * Bind a UDP socket to a local address.
161 static int
162 udpsock_bind(struct sock * sock, const struct sockaddr * addr,
163 socklen_t addr_len, endpoint_t user_endpt)
165 struct udpsock *udp = (struct udpsock *)sock;
166 ip_addr_t ipaddr;
167 uint16_t port;
168 err_t err;
169 int r;
171 if ((r = ipsock_get_src_addr(udpsock_get_ipsock(udp), addr, addr_len,
172 user_endpt, &udp->udp_pcb->local_ip, udp->udp_pcb->local_port,
173 TRUE /*allow_mcast*/, &ipaddr, &port)) != OK)
174 return r;
176 err = udp_bind(udp->udp_pcb, &ipaddr, port);
178 return util_convert_err(err);
182 * Connect a UDP socket to a remote address.
184 static int
185 udpsock_connect(struct sock * sock, const struct sockaddr * addr,
186 socklen_t addr_len, endpoint_t user_endpt __unused)
188 struct udpsock *udp = (struct udpsock *)sock;
189 struct ifdev *ifdev;
190 const ip_addr_t *src_addr;
191 ip_addr_t dst_addr;
192 uint16_t dst_port;
193 uint32_t ifindex, ifindex2;
194 err_t err;
195 int r;
198 * One may "unconnect" socket by providing an address with family
199 * AF_UNSPEC. Providing an <any>:0 address does not achieve the same.
201 if (addr_is_unspec(addr, addr_len)) {
202 udp_disconnect(udp->udp_pcb);
204 return OK;
207 if ((r = ipsock_get_dst_addr(udpsock_get_ipsock(udp), addr,
208 addr_len, &udp->udp_pcb->local_ip, &dst_addr, &dst_port)) != OK)
209 return r;
212 * Bind explicitly to a source address if the PCB is not bound to one
213 * yet. This is expected in the BSD socket API, but lwIP does not do
214 * it for us.
216 if (ip_addr_isany(&udp->udp_pcb->local_ip)) {
217 /* Help the multicast case a bit, if possible. */
218 ifdev = NULL;
220 if (ip_addr_ismulticast(&dst_addr)) {
221 ifindex = pktsock_get_ifindex(&udp->udp_pktsock);
222 ifindex2 = udp_get_multicast_netif_index(udp->udp_pcb);
223 if (ifindex == 0)
224 ifindex = ifindex2;
226 if (ifindex != 0) {
227 ifdev = ifdev_get_by_index(ifindex);
229 if (ifdev == NULL)
230 return ENXIO;
234 src_addr = ifaddr_select(&dst_addr, ifdev, NULL /*ifdevp*/);
236 if (src_addr == NULL)
237 return EHOSTUNREACH;
239 err = udp_bind(udp->udp_pcb, src_addr,
240 udp->udp_pcb->local_port);
242 if (err != ERR_OK)
243 return util_convert_err(err);
247 * Connecting a UDP socket serves two main purposes: 1) the socket uses
248 * the address as destination when sending, and 2) the socket receives
249 * packets from only the connected address.
251 err = udp_connect(udp->udp_pcb, &dst_addr, dst_port);
253 if (err != ERR_OK)
254 return util_convert_err(err);
256 return OK;
260 * Perform preliminary checks on a send request.
262 static int
263 udpsock_pre_send(struct sock * sock, size_t len, socklen_t ctl_len __unused,
264 const struct sockaddr * addr, socklen_t addr_len __unused,
265 endpoint_t user_endpt __unused, int flags)
267 struct udpsock *udp = (struct udpsock *)sock;
269 if ((flags & ~MSG_DONTROUTE) != 0)
270 return EOPNOTSUPP;
272 if (!udpsock_is_conn(udp) && addr == NULL)
273 return EDESTADDRREQ;
276 * This is only one part of the length check. The rest is done from
277 * udpsock_send(), once we have more information.
279 if (len > ipsock_get_sndbuf(udpsock_get_ipsock(udp)))
280 return EMSGSIZE;
282 return OK;
286 * Swap IP-level options between the UDP PCB and the packet options structure,
287 * for all options that have their flag set in the packet options structure.
288 * This function is called twice when sending a packet. The result is that the
289 * flagged options are overridden for only the packet being sent.
291 static void
292 udpsock_swap_opt(struct udpsock * udp, struct pktopt * pkto)
294 uint8_t tos, ttl, mcast_ttl;
296 if (pkto->pkto_flags & PKTOF_TOS) {
297 tos = udp->udp_pcb->tos;
298 udp->udp_pcb->tos = pkto->pkto_tos;
299 pkto->pkto_tos = tos;
302 if (pkto->pkto_flags & PKTOF_TTL) {
303 ttl = udp->udp_pcb->ttl;
304 mcast_ttl = udp_get_multicast_ttl(udp->udp_pcb);
305 udp->udp_pcb->ttl = pkto->pkto_ttl;
306 udp_set_multicast_ttl(udp->udp_pcb, pkto->pkto_mcast_ttl);
307 pkto->pkto_ttl = ttl;
308 pkto->pkto_mcast_ttl = mcast_ttl;
313 * Send a packet on a UDP socket.
315 static int
316 udpsock_send(struct sock * sock, const struct sockdriver_data * data,
317 size_t len, size_t * off, const struct sockdriver_data * ctl,
318 socklen_t ctl_len, socklen_t * ctl_off __unused,
319 const struct sockaddr * addr, socklen_t addr_len,
320 endpoint_t user_endpt __unused, int flags, size_t min __unused)
322 struct udpsock *udp = (struct udpsock *)sock;
323 struct pktopt pktopt;
324 struct pbuf *pbuf;
325 struct ifdev *ifdev;
326 struct netif *netif;
327 const ip_addr_t *src_addrp, *dst_addrp;
328 ip_addr_t src_addr, dst_addr; /* for storage only; not always used! */
329 uint16_t dst_port;
330 uint32_t ifindex;
331 size_t hdrlen;
332 err_t err;
333 int r;
335 /* Copy in and parse any packet options. */
336 pktopt.pkto_flags = 0;
338 if ((r = pktsock_get_ctl(&udp->udp_pktsock, ctl, ctl_len,
339 &pktopt)) != OK)
340 return r;
343 * The code below will both determine an outgoing interface and a
344 * source address for the packet. Even though lwIP could do this for
345 * us in some cases, there are other cases where we must do so
346 * ourselves, with as main reasons 1) the possibility that either or
347 * both have been provided through IPV6_PKTINFO, and 2) our intent to
348 * detect and stop zone violations for (combinations of) scoped IPv6
349 * addresses. As a result, it is easier to simply take over the
350 * selection tasks lwIP in their entirety.
352 * Much of the same applies to rawsock_send() as well. Functional
353 * differences (e.g. IP_HDRINCL support) as well as the PCB accesses in
354 * the code make it hard to merge the two into a single pktsock copy.
355 * Please do keep the two in sync as much as possible.
359 * Start by checking whether the source address and/or the outgoing
360 * interface are overridden using sticky and/or ancillary options. The
361 * call to pktsock_get_pktinfo(), if successful, will either set
362 * 'ifdev' to NULL, in which case there is no override, or it will set
363 * 'ifdev' to the outgoing interface to use, and (only) in that case
364 * also fill 'src_addr', with an address that may either be a locally
365 * owned unicast address or the unspecified ('any') address. If it is
366 * a unicast address, that is the source address to use for the packet.
367 * Otherwise, fall back to the address to which the socket is bound,
368 * which may also be the unspecified address or even a multicast
369 * address. In those case we will pick a source address further below.
371 if ((r = pktsock_get_pktinfo(&udp->udp_pktsock, &pktopt, &ifdev,
372 &src_addr)) != OK)
373 return r;
375 if (ifdev != NULL && !ip_addr_isany(&src_addr)) {
376 /* This is guaranteed to be a proper local unicast address. */
377 src_addrp = &src_addr;
378 } else {
379 src_addrp = &udp->udp_pcb->local_ip;
382 * If the socket is bound to a multicast address, use the
383 * unspecified ('any') address as source address instead, until
384 * we select a real source address (further below). This
385 * substitution keeps the rest of the code a bit simpler.
387 if (ip_addr_ismulticast(src_addrp))
388 src_addrp = IP46_ADDR_ANY(IP_GET_TYPE(src_addrp));
392 * Determine the destination address to use. If the socket is
393 * connected, always ignore any address provided in the send call.
395 if (!udpsock_is_conn(udp)) {
396 assert(addr != NULL); /* already checked in pre_send */
398 if ((r = ipsock_get_dst_addr(udpsock_get_ipsock(udp), addr,
399 addr_len, src_addrp, &dst_addr, &dst_port)) != OK)
400 return r;
402 dst_addrp = &dst_addr;
403 } else {
404 dst_addrp = &udp->udp_pcb->remote_ip;
405 dst_port = udp->udp_pcb->remote_port;
409 * If the destination is a multicast address, select the outgoing
410 * interface based on the multicast interface index, if one is set.
411 * This must be done here in order to allow the code further below to
412 * detect zone violations, because if we leave this selection to lwIP,
413 * it will not perform zone violation detection at all. Also note that
414 * this case must *not* override an interface index already specified
415 * using IPV6_PKTINFO, as per RFC 3542 Sec. 6.7.
417 if (ifdev == NULL && ip_addr_ismulticast(dst_addrp)) {
418 ifindex = udp_get_multicast_netif_index(udp->udp_pcb);
420 if (ifindex != NETIF_NO_INDEX)
421 ifdev = ifdev_get_by_index(ifindex); /* (may fail) */
425 * If an interface has been determined already now, the send operation
426 * will bypass routing. In that case, we must perform our own checks
427 * on address zone violations, because those will not be made anywhere
428 * else. Subsequent steps below will never introduce violations.
430 if (ifdev != NULL && IP_IS_V6(dst_addrp)) {
431 if (ifaddr_is_zone_mismatch(ip_2_ip6(dst_addrp), ifdev))
432 return EHOSTUNREACH;
434 if (IP_IS_V6(src_addrp) &&
435 ifaddr_is_zone_mismatch(ip_2_ip6(src_addrp), ifdev))
436 return EHOSTUNREACH;
440 * If we do not yet have an interface at this point, perform a route
441 * lookup to determine the outgoing interface. Unless MSG_DONTROUTE is
442 * set (which covers SO_DONTROUTE as well), in which case we look for a
443 * local subnet that matches the destination address.
445 if (ifdev == NULL) {
446 if (!(flags & MSG_DONTROUTE)) {
448 * ip_route() should never be called with an
449 * IPADDR_TYPE_ANY type address. This is a lwIP-
450 * internal requirement; while we override both routing
451 * functions, we do not deviate from it.
453 if (IP_IS_ANY_TYPE_VAL(*src_addrp))
454 src_addrp =
455 IP46_ADDR_ANY(IP_GET_TYPE(dst_addrp));
457 /* Perform the route lookup. */
458 if ((netif = ip_route(src_addrp, dst_addrp)) == NULL)
459 return EHOSTUNREACH;
461 ifdev = netif_get_ifdev(netif);
462 } else {
463 if ((ifdev = ifaddr_map_by_subnet(dst_addrp)) == NULL)
464 return EHOSTUNREACH;
469 * At this point we have an outgoing interface. If we do not have a
470 * source address yet, pick one now.
472 assert(ifdev != NULL);
474 if (ip_addr_isany(src_addrp)) {
475 src_addrp = ifaddr_select(dst_addrp, ifdev, NULL /*ifdevp*/);
477 if (src_addrp == NULL)
478 return EHOSTUNREACH;
482 * Now that we know the full conditions of what we are about to send,
483 * check whether the packet size leaves enough room for lwIP to prepend
484 * headers. If so, allocate a chain of pbufs for the packet.
486 assert(len <= UDP_MAX_PAYLOAD);
488 if (IP_IS_V6(dst_addrp))
489 hdrlen = IP6_HLEN + UDP_HLEN;
490 else
491 hdrlen = IP_HLEN + UDP_HLEN;
493 if (hdrlen + len > UDP_MAX_PAYLOAD)
494 return EMSGSIZE;
496 if ((pbuf = pchain_alloc(PBUF_TRANSPORT, len)) == NULL)
497 return ENOBUFS;
499 /* Copy in the packet data. */
500 if ((r = pktsock_get_data(&udp->udp_pktsock, data, len, pbuf)) != OK) {
501 pbuf_free(pbuf);
503 return r;
507 * Set broadcast/multicast flags for accounting purposes. Only the
508 * multicast flag is used for output accounting, but for loopback
509 * traffic, both flags are copied and used for input accounting and
510 * setting MSG_MCAST/MSG_BCAST.
512 if (ip_addr_ismulticast(dst_addrp))
513 pbuf->flags |= PBUF_FLAG_LLMCAST;
514 else if (ip_addr_isbroadcast(dst_addrp, ifdev_get_netif(ifdev)))
515 pbuf->flags |= PBUF_FLAG_LLBCAST;
517 /* Send the packet. */
518 udpsock_swap_opt(udp, &pktopt);
520 assert(!ip_addr_isany(src_addrp));
521 assert(!ip_addr_ismulticast(src_addrp));
523 err = udp_sendto_if_src(udp->udp_pcb, pbuf, dst_addrp, dst_port,
524 ifdev_get_netif(ifdev), src_addrp);
526 udpsock_swap_opt(udp, &pktopt);
528 /* Free the pbuf, as a copy has been made. */
529 pbuf_free(pbuf);
532 * On success, make sure to return the size of the sent packet as well.
533 * As an aside: ctl_off need not be updated, as it is not returned.
535 if ((r = util_convert_err(err)) == OK)
536 *off = len;
537 return r;
541 * Update the set of flag-type socket options on a UDP socket.
543 static void
544 udpsock_setsockmask(struct sock * sock, unsigned int mask)
546 struct udpsock *udp = (struct udpsock *)sock;
548 if (mask & SO_REUSEADDR)
549 ip_set_option(udp->udp_pcb, SOF_REUSEADDR);
550 else
551 ip_reset_option(udp->udp_pcb, SOF_REUSEADDR);
553 if (mask & SO_BROADCAST)
554 ip_set_option(udp->udp_pcb, SOF_BROADCAST);
555 else
556 ip_reset_option(udp->udp_pcb, SOF_BROADCAST);
560 * Prepare a helper structure for IP-level option processing.
562 static void
563 udpsock_get_ipopts(struct udpsock * udp, struct ipopts * ipopts)
566 ipopts->local_ip = &udp->udp_pcb->local_ip;
567 ipopts->remote_ip = &udp->udp_pcb->remote_ip;
568 ipopts->tos = &udp->udp_pcb->tos;
569 ipopts->ttl = &udp->udp_pcb->ttl;
570 ipopts->sndmin = UDP_SNDBUF_MIN;
571 ipopts->sndmax = UDP_SNDBUF_MAX;
572 ipopts->rcvmin = UDP_RCVBUF_MIN;
573 ipopts->rcvmax = UDP_RCVBUF_MAX;
577 * Set socket options on a UDP socket.
579 static int
580 udpsock_setsockopt(struct sock * sock, int level, int name,
581 const struct sockdriver_data * data, socklen_t len)
583 struct udpsock *udp = (struct udpsock *)sock;
584 struct ipopts ipopts;
585 ip_addr_t ipaddr;
586 struct in_addr in_addr;
587 struct ifdev *ifdev;
588 unsigned int flags;
589 uint32_t ifindex;
590 uint8_t byte;
591 int r, val;
594 * Unfortunately, we have to duplicate most of the multicast options
595 * rather than sharing them with rawsock at the pktsock level. The
596 * reason is that each of the PCBs have their own multicast abstraction
597 * functions and so we cannot merge the rest. Same for getsockopt.
600 switch (level) {
601 case IPPROTO_IP:
602 if (udpsock_is_ipv6(udp))
603 break;
605 switch (name) {
606 case IP_MULTICAST_IF:
607 pktsock_set_mcaware(&udp->udp_pktsock);
609 if ((r = sockdriver_copyin_opt(data, &in_addr,
610 sizeof(in_addr), len)) != OK)
611 return r;
613 ip_addr_set_ip4_u32(&ipaddr, in_addr.s_addr);
615 if ((ifdev = ifaddr_map_by_addr(&ipaddr)) == NULL)
616 return EADDRNOTAVAIL;
618 udp_set_multicast_netif_index(udp->udp_pcb,
619 ifdev_get_index(ifdev));
621 return OK;
623 case IP_MULTICAST_LOOP:
624 pktsock_set_mcaware(&udp->udp_pktsock);
626 if ((r = sockdriver_copyin_opt(data, &byte,
627 sizeof(byte), len)) != OK)
628 return r;
630 flags = udp_flags(udp->udp_pcb);
632 if (byte)
633 flags |= UDP_FLAGS_MULTICAST_LOOP;
634 else
635 flags &= ~UDP_FLAGS_MULTICAST_LOOP;
637 udp_setflags(udp->udp_pcb, flags);
639 return OK;
641 case IP_MULTICAST_TTL:
642 pktsock_set_mcaware(&udp->udp_pktsock);
644 if ((r = sockdriver_copyin_opt(data, &byte,
645 sizeof(byte), len)) != OK)
646 return r;
648 udp_set_multicast_ttl(udp->udp_pcb, byte);
650 return OK;
653 break;
655 case IPPROTO_IPV6:
656 if (!udpsock_is_ipv6(udp))
657 break;
659 switch (name) {
660 case IPV6_MULTICAST_IF:
661 pktsock_set_mcaware(&udp->udp_pktsock);
663 if ((r = sockdriver_copyin_opt(data, &val, sizeof(val),
664 len)) != OK)
665 return r;
667 if (val != 0) {
668 ifindex = (uint32_t)val;
670 ifdev = ifdev_get_by_index(ifindex);
672 if (ifdev == NULL)
673 return ENXIO;
674 } else
675 ifindex = NETIF_NO_INDEX;
677 udp_set_multicast_netif_index(udp->udp_pcb, ifindex);
679 return OK;
681 case IPV6_MULTICAST_LOOP:
682 pktsock_set_mcaware(&udp->udp_pktsock);
684 if ((r = sockdriver_copyin_opt(data, &val, sizeof(val),
685 len)) != OK)
686 return r;
688 if (val < 0 || val > 1)
689 return EINVAL;
691 flags = udp_flags(udp->udp_pcb);
693 if (val)
694 flags |= UDP_FLAGS_MULTICAST_LOOP;
695 else
696 flags &= ~UDP_FLAGS_MULTICAST_LOOP;
699 * lwIP's IPv6 functionality does not actually check
700 * this flag at all yet. We set it in the hope that
701 * one day this will magically start working.
703 udp_setflags(udp->udp_pcb, flags);
705 return OK;
707 case IPV6_MULTICAST_HOPS:
708 pktsock_set_mcaware(&udp->udp_pktsock);
710 if ((r = sockdriver_copyin_opt(data, &val, sizeof(val),
711 len)) != OK)
712 return r;
714 if (val < -1 || val > UINT8_MAX)
715 return EINVAL;
717 if (val == -1)
718 val = 1;
720 udp_set_multicast_ttl(udp->udp_pcb, val);
722 return OK;
725 break;
728 /* Handle all other options at the packet or IP level. */
729 udpsock_get_ipopts(udp, &ipopts);
731 return pktsock_setsockopt(&udp->udp_pktsock, level, name, data, len,
732 &ipopts);
736 * Retrieve socket options on a UDP socket.
738 static int
739 udpsock_getsockopt(struct sock * sock, int level, int name,
740 const struct sockdriver_data * data, socklen_t * len)
742 struct udpsock *udp = (struct udpsock *)sock;
743 struct ipopts ipopts;
744 const ip4_addr_t *ip4addr;
745 struct in_addr in_addr;
746 struct ifdev *ifdev;
747 unsigned int flags;
748 uint32_t ifindex;
749 uint8_t byte;
750 int val;
752 switch (level) {
753 case IPPROTO_IP:
754 if (udpsock_is_ipv6(udp))
755 break;
757 switch (name) {
758 case IP_MULTICAST_IF:
759 ifindex = udp_get_multicast_netif_index(udp->udp_pcb);
762 * Map back from the interface index to the IPv4
763 * address assigned to the corresponding interface.
764 * Should this not work out, return the 'any' address.
766 if (ifindex != NETIF_NO_INDEX &&
767 (ifdev = ifdev_get_by_index(ifindex)) != NULL) {
768 ip4addr =
769 netif_ip4_addr(ifdev_get_netif(ifdev));
771 in_addr.s_addr = ip4_addr_get_u32(ip4addr);
772 } else
773 in_addr.s_addr = PP_HTONL(INADDR_ANY);
775 return sockdriver_copyout_opt(data, &in_addr,
776 sizeof(in_addr), len);
778 case IP_MULTICAST_LOOP:
779 flags = udp_flags(udp->udp_pcb);
781 byte = !!(flags & UDP_FLAGS_MULTICAST_LOOP);
783 return sockdriver_copyout_opt(data, &byte,
784 sizeof(byte), len);
786 case IP_MULTICAST_TTL:
787 byte = udp_get_multicast_ttl(udp->udp_pcb);
789 return sockdriver_copyout_opt(data, &byte,
790 sizeof(byte), len);
793 break;
795 case IPPROTO_IPV6:
796 if (!udpsock_is_ipv6(udp))
797 break;
799 switch (name) {
800 case IPV6_MULTICAST_IF:
801 ifindex = udp_get_multicast_netif_index(udp->udp_pcb);
803 val = (int)ifindex;
805 return sockdriver_copyout_opt(data, &val, sizeof(val),
806 len);
808 case IPV6_MULTICAST_LOOP:
809 flags = udp_flags(udp->udp_pcb);
811 val = !!(flags & UDP_FLAGS_MULTICAST_LOOP);
813 return sockdriver_copyout_opt(data, &val, sizeof(val),
814 len);
816 case IPV6_MULTICAST_HOPS:
817 val = udp_get_multicast_ttl(udp->udp_pcb);
819 return sockdriver_copyout_opt(data, &val, sizeof(val),
820 len);
823 break;
826 /* Handle all other options at the packet or IP level. */
827 udpsock_get_ipopts(udp, &ipopts);
829 return pktsock_getsockopt(&udp->udp_pktsock, level, name, data, len,
830 &ipopts);
834 * Retrieve the local socket address of a UDP socket.
836 static int
837 udpsock_getsockname(struct sock * sock, struct sockaddr * addr,
838 socklen_t * addr_len)
840 struct udpsock *udp = (struct udpsock *)sock;
842 ipsock_put_addr(udpsock_get_ipsock(udp), addr, addr_len,
843 &udp->udp_pcb->local_ip, udp->udp_pcb->local_port);
845 return OK;
849 * Retrieve the remote socket address of a UDP socket.
851 static int
852 udpsock_getpeername(struct sock * sock, struct sockaddr * addr,
853 socklen_t * addr_len)
855 struct udpsock *udp = (struct udpsock *)sock;
857 if (!udpsock_is_conn(udp))
858 return ENOTCONN;
860 ipsock_put_addr(udpsock_get_ipsock(udp), addr, addr_len,
861 &udp->udp_pcb->remote_ip, udp->udp_pcb->remote_port);
863 return OK;
867 * Shut down a UDP socket for reading and/or writing.
869 static int
870 udpsock_shutdown(struct sock * sock, unsigned int mask)
872 struct udpsock *udp = (struct udpsock *)sock;
874 if (mask & SFL_SHUT_RD)
875 udp_recv(udp->udp_pcb, NULL, NULL);
877 pktsock_shutdown(&udp->udp_pktsock, mask);
879 return OK;
883 * Close a UDP socket.
885 static int
886 udpsock_close(struct sock * sock, int force __unused)
888 struct udpsock *udp = (struct udpsock *)sock;
890 udp_recv(udp->udp_pcb, NULL, NULL);
892 udp_remove(udp->udp_pcb);
893 udp->udp_pcb = NULL;
895 pktsock_close(&udp->udp_pktsock);
897 return OK;
901 * Free up a closed UDP socket.
903 static void
904 udpsock_free(struct sock * sock)
906 struct udpsock *udp = (struct udpsock *)sock;
908 assert(udp->udp_pcb == NULL);
910 SIMPLEQ_INSERT_HEAD(&udp_freelist, udp, udp_next);
914 * Fill the given kinfo_pcb sysctl(7) structure with information about the UDP
915 * PCB identified by the given pointer.
917 static void
918 udpsock_get_info(struct kinfo_pcb * ki, const void * ptr)
920 const struct udp_pcb *pcb = (const struct udp_pcb *)ptr;
921 struct udpsock *udp;
923 ki->ki_type = SOCK_DGRAM;
926 * All UDP sockets should be created by this module, but protect
927 * ourselves from the case that that is not true anyway.
929 if (pcb->recv_arg != NULL) {
930 udp = (struct udpsock *)pcb->recv_arg;
932 assert(udp >= udp_array &&
933 udp < &udp_array[__arraycount(udp_array)]);
934 } else
935 udp = NULL;
937 ipsock_get_info(ki, &pcb->local_ip, pcb->local_port, &pcb->remote_ip,
938 pcb->remote_port);
940 if (udp != NULL) {
941 /* TODO: change this so that sockstat(1) may work one day. */
942 ki->ki_sockaddr = (uint64_t)(uintptr_t)udpsock_get_sock(udp);
944 ki->ki_rcvq = pktsock_get_recvlen(&udp->udp_pktsock);
949 * Given either NULL or a previously returned UDP PCB pointer, return the first
950 * or next UDP PCB pointer, or NULL if there are no more. Skip UDP PCBs that
951 * are not bound to an address, as there is no use reporting them.
953 static const void *
954 udpsock_enum(const void * last)
956 const struct udp_pcb *pcb;
958 if (last != NULL)
959 pcb = (const void *)((const struct udp_pcb *)last)->next;
960 else
961 pcb = (const void *)udp_pcbs;
963 while (pcb != NULL && pcb->local_port == 0)
964 pcb = pcb->next;
966 return pcb;
970 * Obtain the list of UDP protocol control blocks, for sysctl(7).
972 static ssize_t
973 udpsock_pcblist(struct rmib_call * call, struct rmib_node * node __unused,
974 struct rmib_oldp * oldp, struct rmib_newp * newp __unused)
977 return util_pcblist(call, oldp, udpsock_enum, udpsock_get_info);
980 static const struct sockevent_ops udpsock_ops = {
981 .sop_bind = udpsock_bind,
982 .sop_connect = udpsock_connect,
983 .sop_pre_send = udpsock_pre_send,
984 .sop_send = udpsock_send,
985 .sop_pre_recv = pktsock_pre_recv,
986 .sop_recv = pktsock_recv,
987 .sop_test_recv = pktsock_test_recv,
988 .sop_ioctl = ifconf_ioctl,
989 .sop_setsockmask = udpsock_setsockmask,
990 .sop_setsockopt = udpsock_setsockopt,
991 .sop_getsockopt = udpsock_getsockopt,
992 .sop_getsockname = udpsock_getsockname,
993 .sop_getpeername = udpsock_getpeername,
994 .sop_shutdown = udpsock_shutdown,
995 .sop_close = udpsock_close,
996 .sop_free = udpsock_free