2 * Copyright (c) 2003, 2004 Matthew Dillon. All rights reserved.
3 * Copyright (c) 2003, 2004 Jeffrey M. Hsu. All rights reserved.
4 * Copyright (c) 2003 Jonathan Lemon. All rights reserved.
5 * Copyright (c) 2003, 2004 The DragonFly Project. All rights reserved.
7 * This code is derived from software contributed to The DragonFly Project
8 * by Jonathan Lemon, Jeffrey M. Hsu, and Matthew Dillon.
10 * Jonathan Lemon gave Jeffrey Hsu permission to combine his copyright
11 * into this one around July 8 2004.
13 * Redistribution and use in source and binary forms, with or without
14 * modification, are permitted provided that the following conditions
16 * 1. Redistributions of source code must retain the above copyright
17 * notice, this list of conditions and the following disclaimer.
18 * 2. Redistributions in binary form must reproduce the above copyright
19 * notice, this list of conditions and the following disclaimer in the
20 * documentation and/or other materials provided with the distribution.
21 * 3. Neither the name of The DragonFly Project nor the names of its
22 * contributors may be used to endorse or promote products derived
23 * from this software without specific, prior written permission.
25 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
26 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
27 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
28 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
29 * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
30 * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING,
31 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
32 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
33 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
34 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
35 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
39 #include <sys/param.h>
40 #include <sys/systm.h>
41 #include <sys/kernel.h>
42 #include <sys/malloc.h>
43 #include <sys/msgport.h>
45 #include <sys/interrupt.h>
46 #include <sys/socket.h>
47 #include <sys/sysctl.h>
48 #include <sys/socketvar.h>
50 #include <net/if_var.h>
51 #include <net/netisr.h>
52 #include <machine/cpufunc.h>
53 #include <machine/smp.h>
55 #include <sys/thread2.h>
56 #include <sys/msgport2.h>
57 #include <net/netmsg2.h>
58 #include <sys/mplock2.h>
60 static void netmsg_sync_func(netmsg_t msg);
61 static void netmsg_service_loop(void *arg);
62 static void cpu0_cpufn(struct mbuf **mp, int hoff);
63 static void netisr_nohashck(struct mbuf *, const struct pktinfo *);
65 struct netmsg_port_registration {
66 TAILQ_ENTRY(netmsg_port_registration) npr_entry;
70 struct netmsg_rollup {
71 TAILQ_ENTRY(netmsg_rollup) ru_entry;
75 struct netmsg_barrier {
76 struct netmsg_base base;
77 volatile cpumask_t *br_cpumask;
78 volatile uint32_t br_done;
81 #define NETISR_BR_NOTDONE 0x1
82 #define NETISR_BR_WAITDONE 0x80000000
84 struct netisr_barrier {
85 struct netmsg_barrier *br_msgs[MAXCPU];
89 static struct netisr netisrs[NETISR_MAX];
90 static TAILQ_HEAD(,netmsg_port_registration) netreglist;
91 static TAILQ_HEAD(,netmsg_rollup) netrulist;
93 /* Per-CPU thread to handle any protocol. */
94 static struct thread netisr_cpu[MAXCPU];
95 lwkt_port netisr_afree_rport;
96 lwkt_port netisr_afree_free_so_rport;
97 lwkt_port netisr_adone_rport;
98 lwkt_port netisr_apanic_rport;
99 lwkt_port netisr_sync_port;
101 static int (*netmsg_fwd_port_fn)(lwkt_port_t, lwkt_msg_t);
103 SYSCTL_NODE(_net, OID_AUTO, netisr, CTLFLAG_RW, 0, "netisr");
106 * netisr_afree_rport replymsg function, only used to handle async
107 * messages which the sender has abandoned to their fate.
110 netisr_autofree_reply(lwkt_port_t port, lwkt_msg_t msg)
112 kfree(msg, M_LWKTMSG);
116 netisr_autofree_free_so_reply(lwkt_port_t port, lwkt_msg_t msg)
118 sofree(((netmsg_t)msg)->base.nm_so);
119 kfree(msg, M_LWKTMSG);
123 * We need a custom putport function to handle the case where the
124 * message target is the current thread's message port. This case
125 * can occur when the TCP or UDP stack does a direct callback to NFS and NFS
126 * then turns around and executes a network operation synchronously.
128 * To prevent deadlocking, we must execute these self-referential messages
129 * synchronously, effectively turning the message into a glorified direct
130 * procedure call back into the protocol stack. The operation must be
131 * complete on return or we will deadlock, so panic if it isn't.
133 * However, the target function is under no obligation to immediately
134 * reply the message. It may forward it elsewhere.
137 netmsg_put_port(lwkt_port_t port, lwkt_msg_t lmsg)
139 netmsg_base_t nmsg = (void *)lmsg;
141 if ((lmsg->ms_flags & MSGF_SYNC) && port == &curthread->td_msgport) {
142 nmsg->nm_dispatch((netmsg_t)nmsg);
145 return(netmsg_fwd_port_fn(port, lmsg));
150 * UNIX DOMAIN sockets still have to run their uipc functions synchronously,
151 * because they depend on the user proc context for a number of things
152 * (like creds) which we have not yet incorporated into the message structure.
154 * However, we maintain or message/port abstraction. Having a special
155 * synchronous port which runs the commands synchronously gives us the
156 * ability to serialize operations in one place later on when we start
160 netmsg_sync_putport(lwkt_port_t port, lwkt_msg_t lmsg)
162 netmsg_base_t nmsg = (void *)lmsg;
164 KKASSERT((lmsg->ms_flags & MSGF_DONE) == 0);
166 lmsg->ms_target_port = port; /* required for abort */
167 nmsg->nm_dispatch((netmsg_t)nmsg);
176 TAILQ_INIT(&netreglist);
177 TAILQ_INIT(&netrulist);
180 * Create default per-cpu threads for generic protocol handling.
182 for (i = 0; i < ncpus; ++i) {
183 lwkt_create(netmsg_service_loop, NULL, NULL,
184 &netisr_cpu[i], TDF_STOPREQ, i,
186 netmsg_service_port_init(&netisr_cpu[i].td_msgport);
187 lwkt_schedule(&netisr_cpu[i]);
191 * The netisr_afree_rport is a special reply port which automatically
192 * frees the replied message. The netisr_adone_rport simply marks
193 * the message as being done. The netisr_apanic_rport panics if
194 * the message is replied to.
196 lwkt_initport_replyonly(&netisr_afree_rport, netisr_autofree_reply);
197 lwkt_initport_replyonly(&netisr_afree_free_so_rport,
198 netisr_autofree_free_so_reply);
199 lwkt_initport_replyonly_null(&netisr_adone_rport);
200 lwkt_initport_panic(&netisr_apanic_rport);
203 * The netisr_syncport is a special port which executes the message
204 * synchronously and waits for it if EASYNC is returned.
206 lwkt_initport_putonly(&netisr_sync_port, netmsg_sync_putport);
209 SYSINIT(netisr, SI_SUB_PRE_DRIVERS, SI_ORDER_FIRST, netisr_init, NULL);
212 * Finish initializing the message port for a netmsg service. This also
213 * registers the port for synchronous cleanup operations such as when an
214 * ifnet is being destroyed. There is no deregistration API yet.
217 netmsg_service_port_init(lwkt_port_t port)
219 struct netmsg_port_registration *reg;
222 * Override the putport function. Our custom function checks for
223 * self-references and executes such commands synchronously.
225 if (netmsg_fwd_port_fn == NULL)
226 netmsg_fwd_port_fn = port->mp_putport;
227 KKASSERT(netmsg_fwd_port_fn == port->mp_putport);
228 port->mp_putport = netmsg_put_port;
231 * Keep track of ports using the netmsg API so we can synchronize
232 * certain operations (such as freeing an ifnet structure) across all
235 reg = kmalloc(sizeof(*reg), M_TEMP, M_WAITOK|M_ZERO);
236 reg->npr_port = port;
237 TAILQ_INSERT_TAIL(&netreglist, reg, npr_entry);
241 * This function synchronizes the caller with all netmsg services. For
242 * example, if an interface is being removed we must make sure that all
243 * packets related to that interface complete processing before the structure
244 * can actually be freed. This sort of synchronization is an alternative to
245 * ref-counting the netif, removing the ref counting overhead in favor of
246 * placing additional overhead in the netif freeing sequence (where it is
250 netmsg_service_sync(void)
252 struct netmsg_port_registration *reg;
253 struct netmsg_base smsg;
255 netmsg_init(&smsg, NULL, &curthread->td_msgport, 0, netmsg_sync_func);
257 TAILQ_FOREACH(reg, &netreglist, npr_entry) {
258 lwkt_domsg(reg->npr_port, &smsg.lmsg, 0);
263 * The netmsg function simply replies the message. API semantics require
264 * EASYNC to be returned if the netmsg function disposes of the message.
267 netmsg_sync_func(netmsg_t msg)
269 lwkt_replymsg(&msg->lmsg, 0);
273 * Generic netmsg service loop. Some protocols may roll their own but all
274 * must do the basic command dispatch function call done here.
277 netmsg_service_loop(void *arg)
279 struct netmsg_rollup *ru;
281 thread_t td = curthread;;
284 while ((msg = lwkt_waitport(&td->td_msgport, 0))) {
286 * Run up to 512 pending netmsgs.
290 KASSERT(msg->nm_dispatch != NULL,
291 ("netmsg_service isr %d badmsg\n",
292 msg->lmsg.u.ms_result));
294 msg->nm_so->so_port != &td->td_msgport) {
296 * Sockets undergoing connect or disconnect
297 * ops can change ports on us. Chase the
300 kprintf("netmsg_service_loop: Warning, "
301 "port changed so=%p\n", msg->nm_so);
302 lwkt_forwardmsg(msg->nm_so->so_port,
306 * We are on the correct port, dispatch it.
308 msg->nm_dispatch((netmsg_t)msg);
312 } while ((msg = lwkt_getport(&td->td_msgport)) != NULL);
315 * Run all registered rollup functions for this cpu
316 * (e.g. tcp_willblock()).
318 TAILQ_FOREACH(ru, &netrulist, ru_entry)
324 * Forward a packet to a netisr service function.
326 * If the packet has not been assigned to a protocol thread we call
327 * the port characterization function to assign it. The caller must
328 * clear M_HASH (or not have set it in the first place) if the caller
329 * wishes the packet to be recharacterized.
332 netisr_queue(int num, struct mbuf *m)
335 struct netmsg_packet *pmsg;
338 KASSERT((num > 0 && num <= NELEM(netisrs)),
339 ("Bad isr %d", num));
342 if (ni->ni_handler == NULL) {
343 kprintf("Unregistered isr %d\n", num);
349 * Figure out which protocol thread to send to. This does not
350 * have to be perfect but performance will be really good if it
351 * is correct. Major protocol inputs such as ip_input() will
352 * re-characterize the packet as necessary.
354 if ((m->m_flags & M_HASH) == 0) {
360 if ((m->m_flags & M_HASH) == 0) {
361 kprintf("netisr_queue(%d): packet hash failed\n", num);
368 * Get the protocol port based on the packet hash, initialize
369 * the netmsg, and send it off.
371 port = cpu_portfn(m->m_pkthdr.hash);
372 pmsg = &m->m_hdr.mh_netmsg;
373 netmsg_init(&pmsg->base, NULL, &netisr_apanic_rport,
376 pmsg->base.lmsg.u.ms_result = num;
377 lwkt_sendmsg(port, &pmsg->base.lmsg);
383 * Run a netisr service function on the packet.
385 * The packet must have been correctly characterized!
388 netisr_handle(int num, struct mbuf *m)
391 struct netmsg_packet *pmsg;
395 * Get the protocol port based on the packet hash
397 KASSERT((m->m_flags & M_HASH), ("packet not characterized\n"));
398 port = cpu_portfn(m->m_pkthdr.hash);
399 KASSERT(&curthread->td_msgport == port, ("wrong msgport\n"));
401 KASSERT((num > 0 && num <= NELEM(netisrs)), ("bad isr %d", num));
403 if (ni->ni_handler == NULL) {
404 kprintf("unregistered isr %d\n", num);
410 * Initialize the netmsg, and run the handler directly.
412 pmsg = &m->m_hdr.mh_netmsg;
413 netmsg_init(&pmsg->base, NULL, &netisr_apanic_rport,
416 pmsg->base.lmsg.u.ms_result = num;
417 ni->ni_handler((netmsg_t)&pmsg->base);
423 * Pre-characterization of a deeper portion of the packet for the
426 * The base of the ISR type (e.g. IP) that we want to characterize is
427 * at (hoff) relative to the beginning of the mbuf. This allows
428 * e.g. ether_input_chain() to not have to adjust the m_data/m_len.
431 netisr_characterize(int num, struct mbuf **mp, int hoff)
442 if (num < 0 || num >= NETISR_MAX) {
443 if (num == NETISR_MAX) {
444 m->m_flags |= M_HASH;
445 m->m_pkthdr.hash = 0;
448 panic("Bad isr %d", num);
455 if (ni->ni_handler == NULL) {
456 kprintf("Unregistered isr %d\n", num);
462 * Characterize the packet
464 if ((m->m_flags & M_HASH) == 0) {
465 ni->ni_cpufn(mp, hoff);
467 if (m && (m->m_flags & M_HASH) == 0)
468 kprintf("netisr_queue(%d): packet hash failed\n", num);
473 netisr_register(int num, netisr_fn_t handler, netisr_cpufn_t cpufn)
477 KASSERT((num > 0 && num <= NELEM(netisrs)),
478 ("netisr_register: bad isr %d", num));
479 KKASSERT(handler != NULL);
486 ni->ni_handler = handler;
487 ni->ni_hashck = netisr_nohashck;
488 ni->ni_cpufn = cpufn;
489 netmsg_init(&ni->ni_netmsg, NULL, &netisr_adone_rport, 0, NULL);
493 netisr_register_hashcheck(int num, netisr_hashck_t hashck)
497 KASSERT((num > 0 && num <= NELEM(netisrs)),
498 ("netisr_register: bad isr %d", num));
501 ni->ni_hashck = hashck;
505 netisr_register_rollup(netisr_ru_t ru_func)
507 struct netmsg_rollup *ru;
509 ru = kmalloc(sizeof(*ru), M_TEMP, M_WAITOK|M_ZERO);
510 ru->ru_func = ru_func;
511 TAILQ_INSERT_TAIL(&netrulist, ru, ru_entry);
515 * Return the message port for the general protocol message servicing
516 * thread for a particular cpu.
521 KKASSERT(cpu >= 0 && cpu < ncpus);
522 return (&netisr_cpu[cpu].td_msgport);
526 * Return the current cpu's network protocol thread.
531 return(cpu_portfn(mycpu->gd_cpuid));
535 * Return a default protocol control message processing thread port
538 cpu0_ctlport(int cmd __unused, struct sockaddr *sa __unused,
539 void *extra __unused)
541 return (&netisr_cpu[0].td_msgport);
545 * This is a default netisr packet characterization function which
546 * sets M_HASH. If a netisr is registered with a NULL cpufn function
547 * this one is assigned.
549 * This function makes no attempt to validate the packet.
552 cpu0_cpufn(struct mbuf **mp, int hoff __unused)
554 struct mbuf *m = *mp;
556 m->m_flags |= M_HASH;
557 m->m_pkthdr.hash = 0;
561 * schednetisr() is used to call the netisr handler from the appropriate
562 * netisr thread for polling and other purposes.
564 * This function may be called from a hard interrupt or IPI and must be
565 * MP SAFE and non-blocking. We use a fixed per-cpu message instead of
566 * trying to allocate one. We must get ourselves onto the target cpu
567 * to safely check the MSGF_DONE bit on the message but since the message
568 * will be sent to that cpu anyway this does not add any extra work beyond
569 * what lwkt_sendmsg() would have already had to do to schedule the target
573 schednetisr_remote(void *data)
575 int num = (int)(intptr_t)data;
576 struct netisr *ni = &netisrs[num];
577 lwkt_port_t port = &netisr_cpu[0].td_msgport;
580 pmsg = &netisrs[num].ni_netmsg;
581 if (pmsg->lmsg.ms_flags & MSGF_DONE) {
582 netmsg_init(pmsg, NULL, &netisr_adone_rport, 0, ni->ni_handler);
583 pmsg->lmsg.u.ms_result = num;
584 lwkt_sendmsg(port, &pmsg->lmsg);
591 KASSERT((num > 0 && num <= NELEM(netisrs)),
592 ("schednetisr: bad isr %d", num));
593 KKASSERT(netisrs[num].ni_handler != NULL);
595 if (mycpu->gd_cpuid != 0) {
596 lwkt_send_ipiq(globaldata_find(0),
597 schednetisr_remote, (void *)(intptr_t)num);
600 schednetisr_remote((void *)(intptr_t)num);
605 schednetisr_remote((void *)(intptr_t)num);
613 netisr_barrier_dispatch(netmsg_t nmsg)
615 struct netmsg_barrier *msg = (struct netmsg_barrier *)nmsg;
617 atomic_clear_cpumask(msg->br_cpumask, mycpu->gd_cpumask);
618 if (*msg->br_cpumask == 0)
619 wakeup(msg->br_cpumask);
622 uint32_t done = msg->br_done;
625 if ((done & NETISR_BR_NOTDONE) == 0)
628 tsleep_interlock(&msg->br_done, 0);
629 if (atomic_cmpset_int(&msg->br_done,
630 done, done | NETISR_BR_WAITDONE))
631 tsleep(&msg->br_done, PINTERLOCKED, "nbrdsp", 0);
634 lwkt_replymsg(&nmsg->lmsg, 0);
639 struct netisr_barrier *
640 netisr_barrier_create(void)
642 struct netisr_barrier *br;
644 br = kmalloc(sizeof(*br), M_LWKTMSG, M_WAITOK | M_ZERO);
649 netisr_barrier_set(struct netisr_barrier *br)
652 volatile cpumask_t other_cpumask;
655 KKASSERT(&curthread->td_msgport == cpu_portfn(0));
656 KKASSERT(!br->br_isset);
658 other_cpumask = mycpu->gd_other_cpus & smp_active_mask;
661 for (i = 0; i < ncpus; ++i) {
662 struct netmsg_barrier *msg;
667 msg = kmalloc(sizeof(struct netmsg_barrier),
668 M_LWKTMSG, M_WAITOK);
669 netmsg_init(&msg->base, NULL, &netisr_afree_rport,
670 MSGF_PRIORITY, netisr_barrier_dispatch);
671 msg->br_cpumask = &other_cpumask;
672 msg->br_done = NETISR_BR_NOTDONE;
674 KKASSERT(br->br_msgs[i] == NULL);
675 br->br_msgs[i] = msg;
678 for (i = 0; i < ncpus; ++i) {
681 lwkt_sendmsg(cpu_portfn(i), &br->br_msgs[i]->base.lmsg);
684 while (other_cpumask != 0) {
685 tsleep_interlock(&other_cpumask, 0);
686 if (other_cpumask != 0)
687 tsleep(&other_cpumask, PINTERLOCKED, "nbrset", 0);
694 netisr_barrier_rem(struct netisr_barrier *br)
699 KKASSERT(&curthread->td_msgport == cpu_portfn(0));
700 KKASSERT(br->br_isset);
703 for (i = 0; i < ncpus; ++i) {
704 struct netmsg_barrier *msg = br->br_msgs[i];
707 msg = br->br_msgs[i];
708 br->br_msgs[i] = NULL;
713 done = atomic_swap_int(&msg->br_done, 0);
714 if (done & NETISR_BR_WAITDONE)
715 wakeup(&msg->br_done);
722 netisr_nohashck(struct mbuf *m, const struct pktinfo *pi __unused)
724 m->m_flags &= ~M_HASH;
728 netisr_hashcheck(int num, struct mbuf *m, const struct pktinfo *pi)
732 if (num < 0 || num >= NETISR_MAX)
733 panic("Bad isr %d", num);
739 if (ni->ni_handler == NULL)
740 panic("Unregistered isr %d\n", num);
742 ni->ni_hashck(m, pi);