2 * Copyright (c) 2003,2004 The DragonFly Project. All rights reserved.
4 * This code is derived from software contributed to The DragonFly Project
5 * by Matthew Dillon <dillon@backplane.com>
7 * Redistribution and use in source and binary forms, with or without
8 * modification, are permitted provided that the following conditions
11 * 1. Redistributions of source code must retain the above copyright
12 * notice, this list of conditions and the following disclaimer.
13 * 2. Redistributions in binary form must reproduce the above copyright
14 * notice, this list of conditions and the following disclaimer in
15 * the documentation and/or other materials provided with the
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18 * contributors may be used to endorse or promote products derived
19 * from this software without specific, prior written permission.
21 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
22 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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24 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
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34 * $DragonFly: src/sys/kern/lwkt_ipiq.c,v 1.27 2008/05/18 20:57:56 nth Exp $
38 * This module implements IPI message queueing and the MI portion of IPI
44 #include <sys/param.h>
45 #include <sys/systm.h>
46 #include <sys/kernel.h>
48 #include <sys/rtprio.h>
49 #include <sys/queue.h>
50 #include <sys/thread2.h>
51 #include <sys/sysctl.h>
53 #include <sys/kthread.h>
54 #include <machine/cpu.h>
59 #include <vm/vm_param.h>
60 #include <vm/vm_kern.h>
61 #include <vm/vm_object.h>
62 #include <vm/vm_page.h>
63 #include <vm/vm_map.h>
64 #include <vm/vm_pager.h>
65 #include <vm/vm_extern.h>
66 #include <vm/vm_zone.h>
68 #include <machine/stdarg.h>
69 #include <machine/smp.h>
70 #include <machine/atomic.h>
73 static __int64_t ipiq_count; /* total calls to lwkt_send_ipiq*() */
74 static __int64_t ipiq_fifofull; /* number of fifo full conditions detected */
75 static __int64_t ipiq_avoided; /* interlock with target avoids cpu ipi */
76 static __int64_t ipiq_passive; /* passive IPI messages */
77 static __int64_t ipiq_cscount; /* number of cpu synchronizations */
78 static int ipiq_optimized = 1; /* XXX temporary sysctl */
79 static int ipiq_debug; /* set to 1 for debug */
81 static int panic_ipiq_cpu = -1;
82 static int panic_ipiq_count = 100;
87 SYSCTL_QUAD(_lwkt, OID_AUTO, ipiq_count, CTLFLAG_RW, &ipiq_count, 0,
88 "Number of IPI's sent");
89 SYSCTL_QUAD(_lwkt, OID_AUTO, ipiq_fifofull, CTLFLAG_RW, &ipiq_fifofull, 0,
90 "Number of fifo full conditions detected");
91 SYSCTL_QUAD(_lwkt, OID_AUTO, ipiq_avoided, CTLFLAG_RW, &ipiq_avoided, 0,
92 "Number of IPI's avoided by interlock with target cpu");
93 SYSCTL_QUAD(_lwkt, OID_AUTO, ipiq_passive, CTLFLAG_RW, &ipiq_passive, 0,
94 "Number of passive IPI messages sent");
95 SYSCTL_QUAD(_lwkt, OID_AUTO, ipiq_cscount, CTLFLAG_RW, &ipiq_cscount, 0,
96 "Number of cpu synchronizations");
97 SYSCTL_INT(_lwkt, OID_AUTO, ipiq_optimized, CTLFLAG_RW, &ipiq_optimized, 0,
99 SYSCTL_INT(_lwkt, OID_AUTO, ipiq_debug, CTLFLAG_RW, &ipiq_debug, 0,
102 SYSCTL_INT(_lwkt, OID_AUTO, panic_ipiq_cpu, CTLFLAG_RW, &panic_ipiq_cpu, 0, "");
103 SYSCTL_INT(_lwkt, OID_AUTO, panic_ipiq_count, CTLFLAG_RW, &panic_ipiq_count, 0, "");
106 #define IPIQ_STRING "func=%p arg1=%p arg2=%d scpu=%d dcpu=%d"
107 #define IPIQ_ARG_SIZE (sizeof(void *) * 2 + sizeof(int) * 3)
109 #if !defined(KTR_IPIQ)
110 #define KTR_IPIQ KTR_ALL
112 KTR_INFO_MASTER(ipiq);
113 KTR_INFO(KTR_IPIQ, ipiq, send_norm, 0, IPIQ_STRING, IPIQ_ARG_SIZE);
114 KTR_INFO(KTR_IPIQ, ipiq, send_pasv, 1, IPIQ_STRING, IPIQ_ARG_SIZE);
115 KTR_INFO(KTR_IPIQ, ipiq, send_nbio, 2, IPIQ_STRING, IPIQ_ARG_SIZE);
116 KTR_INFO(KTR_IPIQ, ipiq, send_fail, 3, IPIQ_STRING, IPIQ_ARG_SIZE);
117 KTR_INFO(KTR_IPIQ, ipiq, receive, 4, IPIQ_STRING, IPIQ_ARG_SIZE);
118 KTR_INFO(KTR_IPIQ, ipiq, sync_start, 5, "cpumask=%08x", sizeof(cpumask_t));
119 KTR_INFO(KTR_IPIQ, ipiq, sync_end, 6, "cpumask=%08x", sizeof(cpumask_t));
120 KTR_INFO(KTR_IPIQ, ipiq, cpu_send, 7, IPIQ_STRING, IPIQ_ARG_SIZE);
121 KTR_INFO(KTR_IPIQ, ipiq, send_end, 8, IPIQ_STRING, IPIQ_ARG_SIZE);
123 #define logipiq(name, func, arg1, arg2, sgd, dgd) \
124 KTR_LOG(ipiq_ ## name, func, arg1, arg2, sgd->gd_cpuid, dgd->gd_cpuid)
125 #define logipiq2(name, arg) \
126 KTR_LOG(ipiq_ ## name, arg)
132 static int lwkt_process_ipiq_core(globaldata_t sgd, lwkt_ipiq_t ip,
133 struct intrframe *frame);
134 static void lwkt_cpusync_remote1(lwkt_cpusync_t cs);
135 static void lwkt_cpusync_remote2(lwkt_cpusync_t cs);
138 * Send a function execution request to another cpu. The request is queued
139 * on the cpu<->cpu ipiq matrix. Each cpu owns a unique ipiq FIFO for every
140 * possible target cpu. The FIFO can be written.
142 * If the FIFO fills up we have to enable interrupts to avoid an APIC
143 * deadlock and process pending IPIQs while waiting for it to empty.
144 * Otherwise we may soft-deadlock with another cpu whos FIFO is also full.
146 * We can safely bump gd_intr_nesting_level because our crit_exit() at the
147 * end will take care of any pending interrupts.
149 * The actual hardware IPI is avoided if the target cpu is already processing
150 * the queue from a prior IPI. It is possible to pipeline IPI messages
151 * very quickly between cpus due to the FIFO hysteresis.
153 * Need not be called from a critical section.
156 lwkt_send_ipiq3(globaldata_t target, ipifunc3_t func, void *arg1, int arg2)
160 struct globaldata *gd = mycpu;
162 logipiq(send_norm, func, arg1, arg2, gd, target);
165 func(arg1, arg2, NULL);
166 logipiq(send_end, func, arg1, arg2, gd, target);
170 ++gd->gd_intr_nesting_level;
172 if (gd->gd_intr_nesting_level > 20)
173 panic("lwkt_send_ipiq: TOO HEAVILY NESTED!");
175 KKASSERT(curthread->td_critcount);
177 ip = &gd->gd_ipiq[target->gd_cpuid];
180 * Do not allow the FIFO to become full. Interrupts must be physically
181 * enabled while we liveloop to avoid deadlocking the APIC.
183 * The target ipiq may have gotten filled up due to passive IPIs and thus
184 * not be aware that its queue is too full, so be sure to issue an
185 * ipiq interrupt to the target cpu.
187 if (ip->ip_windex - ip->ip_rindex > MAXCPUFIFO / 2) {
188 #if defined(__i386__)
189 unsigned int eflags = read_eflags();
190 #elif defined(__x86_64__)
191 unsigned long rflags = read_rflags();
196 DEBUG_PUSH_INFO("send_ipiq3");
197 while (ip->ip_windex - ip->ip_rindex > MAXCPUFIFO / 4) {
198 if (atomic_poll_acquire_int(&ip->ip_npoll) || ipiq_optimized == 0) {
199 logipiq(cpu_send, func, arg1, arg2, gd, target);
200 cpu_send_ipiq(target->gd_cpuid);
202 KKASSERT(ip->ip_windex - ip->ip_rindex != MAXCPUFIFO - 1);
207 #if defined(__i386__)
208 write_eflags(eflags);
209 #elif defined(__x86_64__)
210 write_rflags(rflags);
215 * Queue the new message
217 windex = ip->ip_windex & MAXCPUFIFO_MASK;
218 ip->ip_func[windex] = func;
219 ip->ip_arg1[windex] = arg1;
220 ip->ip_arg2[windex] = arg2;
225 * signal the target cpu that there is work pending.
227 if (atomic_poll_acquire_int(&ip->ip_npoll) || ipiq_optimized == 0) {
228 logipiq(cpu_send, func, arg1, arg2, gd, target);
229 cpu_send_ipiq(target->gd_cpuid);
233 --gd->gd_intr_nesting_level;
235 logipiq(send_end, func, arg1, arg2, gd, target);
237 return(ip->ip_windex);
241 * Similar to lwkt_send_ipiq() but this function does not actually initiate
242 * the IPI to the target cpu unless the FIFO has become too full, so it is
245 * This function is used for non-critical IPI messages, such as memory
246 * deallocations. The queue will typically be flushed by the target cpu at
247 * the next clock interrupt.
249 * Need not be called from a critical section.
252 lwkt_send_ipiq3_passive(globaldata_t target, ipifunc3_t func,
253 void *arg1, int arg2)
257 struct globaldata *gd = mycpu;
259 KKASSERT(target != gd);
261 ++gd->gd_intr_nesting_level;
262 logipiq(send_pasv, func, arg1, arg2, gd, target);
264 if (gd->gd_intr_nesting_level > 20)
265 panic("lwkt_send_ipiq: TOO HEAVILY NESTED!");
267 KKASSERT(curthread->td_critcount);
270 ip = &gd->gd_ipiq[target->gd_cpuid];
273 * Do not allow the FIFO to become full. Interrupts must be physically
274 * enabled while we liveloop to avoid deadlocking the APIC.
276 if (ip->ip_windex - ip->ip_rindex > MAXCPUFIFO / 2) {
277 #if defined(__i386__)
278 unsigned int eflags = read_eflags();
279 #elif defined(__x86_64__)
280 unsigned long rflags = read_rflags();
285 DEBUG_PUSH_INFO("send_ipiq3_passive");
286 while (ip->ip_windex - ip->ip_rindex > MAXCPUFIFO / 4) {
287 if (atomic_poll_acquire_int(&ip->ip_npoll) || ipiq_optimized == 0) {
288 logipiq(cpu_send, func, arg1, arg2, gd, target);
289 cpu_send_ipiq(target->gd_cpuid);
291 KKASSERT(ip->ip_windex - ip->ip_rindex != MAXCPUFIFO - 1);
296 #if defined(__i386__)
297 write_eflags(eflags);
298 #elif defined(__x86_64__)
299 write_rflags(rflags);
304 * Queue the new message
306 windex = ip->ip_windex & MAXCPUFIFO_MASK;
307 ip->ip_func[windex] = func;
308 ip->ip_arg1[windex] = arg1;
309 ip->ip_arg2[windex] = arg2;
312 --gd->gd_intr_nesting_level;
315 * Do not signal the target cpu, it will pick up the IPI when it next
316 * polls (typically on the next tick).
319 logipiq(send_end, func, arg1, arg2, gd, target);
321 return(ip->ip_windex);
325 * Send an IPI request without blocking, return 0 on success, ENOENT on
326 * failure. The actual queueing of the hardware IPI may still force us
327 * to spin and process incoming IPIs but that will eventually go away
328 * when we've gotten rid of the other general IPIs.
331 lwkt_send_ipiq3_nowait(globaldata_t target, ipifunc3_t func,
332 void *arg1, int arg2)
336 struct globaldata *gd = mycpu;
338 logipiq(send_nbio, func, arg1, arg2, gd, target);
339 KKASSERT(curthread->td_critcount);
341 func(arg1, arg2, NULL);
342 logipiq(send_end, func, arg1, arg2, gd, target);
346 ++gd->gd_intr_nesting_level;
348 ip = &gd->gd_ipiq[target->gd_cpuid];
350 if (ip->ip_windex - ip->ip_rindex >= MAXCPUFIFO * 2 / 3) {
351 logipiq(send_fail, func, arg1, arg2, gd, target);
352 --gd->gd_intr_nesting_level;
356 windex = ip->ip_windex & MAXCPUFIFO_MASK;
357 ip->ip_func[windex] = func;
358 ip->ip_arg1[windex] = arg1;
359 ip->ip_arg2[windex] = arg2;
364 * This isn't a passive IPI, we still have to signal the target cpu.
366 if (atomic_poll_acquire_int(&ip->ip_npoll) || ipiq_optimized == 0) {
367 logipiq(cpu_send, func, arg1, arg2, gd, target);
368 cpu_send_ipiq(target->gd_cpuid);
372 --gd->gd_intr_nesting_level;
375 logipiq(send_end, func, arg1, arg2, gd, target);
380 * deprecated, used only by fast int forwarding.
383 lwkt_send_ipiq3_bycpu(int dcpu, ipifunc3_t func, void *arg1, int arg2)
385 return(lwkt_send_ipiq3(globaldata_find(dcpu), func, arg1, arg2));
389 * Send a message to several target cpus. Typically used for scheduling.
390 * The message will not be sent to stopped cpus.
393 lwkt_send_ipiq3_mask(cpumask_t mask, ipifunc3_t func, void *arg1, int arg2)
398 mask &= ~stopped_cpus;
400 cpuid = BSFCPUMASK(mask);
401 lwkt_send_ipiq3(globaldata_find(cpuid), func, arg1, arg2);
402 mask &= ~CPUMASK(cpuid);
409 * Wait for the remote cpu to finish processing a function.
411 * YYY we have to enable interrupts and process the IPIQ while waiting
412 * for it to empty or we may deadlock with another cpu. Create a CPU_*()
413 * function to do this! YYY we really should 'block' here.
415 * MUST be called from a critical section. This routine may be called
416 * from an interrupt (for example, if an interrupt wakes a foreign thread
420 lwkt_wait_ipiq(globaldata_t target, int seq)
423 int maxc = 100000000;
425 if (target != mycpu) {
426 ip = &mycpu->gd_ipiq[target->gd_cpuid];
427 if ((int)(ip->ip_xindex - seq) < 0) {
428 #if defined(__i386__)
429 unsigned int eflags = read_eflags();
430 #elif defined(__x86_64__)
431 unsigned long rflags = read_rflags();
434 DEBUG_PUSH_INFO("wait_ipiq");
435 while ((int)(ip->ip_xindex - seq) < 0) {
440 kprintf("LWKT_WAIT_IPIQ WARNING! %d wait %d (%d)\n", mycpu->gd_cpuid, target->gd_cpuid, ip->ip_xindex - seq);
442 panic("LWKT_WAIT_IPIQ");
444 * xindex may be modified by another cpu, use a load fence
445 * to ensure that the loop does not use a speculative value
446 * (which may improve performance).
451 #if defined(__i386__)
452 write_eflags(eflags);
453 #elif defined(__x86_64__)
454 write_rflags(rflags);
461 lwkt_seq_ipiq(globaldata_t target)
465 ip = &mycpu->gd_ipiq[target->gd_cpuid];
466 return(ip->ip_windex);
470 * Called from IPI interrupt (like a fast interrupt), which has placed
471 * us in a critical section. The MP lock may or may not be held.
472 * May also be called from doreti or splz, or be reentrantly called
473 * indirectly through the ip_func[] we run.
475 * There are two versions, one where no interrupt frame is available (when
476 * called from the send code and from splz, and one where an interrupt
477 * frame is available.
479 * When the current cpu is mastering a cpusync we do NOT internally loop
480 * on the cpusyncq poll. We also do not re-flag a pending ipi due to
481 * the cpusyncq poll because this can cause doreti/splz to loop internally.
482 * The cpusync master's own loop must be allowed to run to avoid a deadlock.
485 lwkt_process_ipiq(void)
487 globaldata_t gd = mycpu;
492 ++gd->gd_processing_ipiq;
494 for (n = 0; n < ncpus; ++n) {
495 if (n != gd->gd_cpuid) {
496 sgd = globaldata_find(n);
499 while (lwkt_process_ipiq_core(sgd, &ip[gd->gd_cpuid], NULL))
504 if (lwkt_process_ipiq_core(gd, &gd->gd_cpusyncq, NULL)) {
505 if (gd->gd_curthread->td_cscount == 0)
507 /* need_ipiq(); do not reflag */
509 --gd->gd_processing_ipiq;
513 lwkt_process_ipiq_frame(struct intrframe *frame)
515 globaldata_t gd = mycpu;
521 for (n = 0; n < ncpus; ++n) {
522 if (n != gd->gd_cpuid) {
523 sgd = globaldata_find(n);
526 while (lwkt_process_ipiq_core(sgd, &ip[gd->gd_cpuid], frame))
531 if (gd->gd_cpusyncq.ip_rindex != gd->gd_cpusyncq.ip_windex) {
532 if (lwkt_process_ipiq_core(gd, &gd->gd_cpusyncq, frame)) {
533 if (gd->gd_curthread->td_cscount == 0)
535 /* need_ipiq(); do not reflag */
541 static int iqticks[SMP_MAXCPU];
542 static int iqcount[SMP_MAXCPU];
545 static int iqterm[SMP_MAXCPU];
549 lwkt_process_ipiq_core(globaldata_t sgd, lwkt_ipiq_t ip,
550 struct intrframe *frame)
552 globaldata_t mygd = mycpu;
555 ipifunc3_t copy_func;
560 if (iqticks[mygd->gd_cpuid] != ticks) {
561 iqticks[mygd->gd_cpuid] = ticks;
562 iqcount[mygd->gd_cpuid] = 0;
564 if (++iqcount[mygd->gd_cpuid] > 3000000) {
565 kprintf("cpu %d ipiq maxed cscount %d spin %d\n",
567 mygd->gd_curthread->td_cscount,
568 mygd->gd_spinlocks_wr);
569 iqcount[mygd->gd_cpuid] = 0;
571 if (++iqterm[mygd->gd_cpuid] > 10)
572 panic("cpu %d ipiq maxed", mygd->gd_cpuid);
575 for (i = 0; i < ncpus; ++i) {
576 if (globaldata_find(i)->gd_infomsg)
577 kprintf(" %s", globaldata_find(i)->gd_infomsg);
584 * Obtain the current write index, which is modified by a remote cpu.
585 * Issue a load fence to prevent speculative reads of e.g. data written
586 * by the other cpu prior to it updating the index.
588 KKASSERT(curthread->td_critcount);
591 ++mygd->gd_intr_nesting_level;
594 * NOTE: xindex is only updated after we are sure the function has
595 * finished execution. Beware lwkt_process_ipiq() reentrancy!
596 * The function may send an IPI which may block/drain.
598 * NOTE: Due to additional IPI operations that the callback function
599 * may make, it is possible for both rindex and windex to advance and
600 * thus for rindex to advance passed our cached windex.
602 * NOTE: A load fence is required to prevent speculative loads prior
603 * to the loading of ip_rindex. Even though stores might be
604 * ordered, loads are probably not. A memory fence is required
605 * to prevent reordering of the loads after the ip_rindex update.
607 while (wi - (ri = ip->ip_rindex) > 0) {
608 ri &= MAXCPUFIFO_MASK;
610 copy_func = ip->ip_func[ri];
611 copy_arg1 = ip->ip_arg1[ri];
612 copy_arg2 = ip->ip_arg2[ri];
615 KKASSERT((ip->ip_rindex & MAXCPUFIFO_MASK) ==
616 ((ri + 1) & MAXCPUFIFO_MASK));
617 logipiq(receive, copy_func, copy_arg1, copy_arg2, sgd, mycpu);
619 if (ipiq_debug && (ip->ip_rindex & 0xFFFFFF) == 0) {
620 kprintf("cpu %d ipifunc %p %p %d (frame %p)\n",
622 copy_func, copy_arg1, copy_arg2,
623 #if defined(__i386__)
624 (frame ? (void *)frame->if_eip : NULL));
625 #elif defined(__amd64__)
626 (frame ? (void *)frame->if_rip : NULL));
632 copy_func(copy_arg1, copy_arg2, frame);
634 ip->ip_xindex = ip->ip_rindex;
638 * Simulate panics during the processing of an IPI
640 if (mycpu->gd_cpuid == panic_ipiq_cpu && panic_ipiq_count) {
641 if (--panic_ipiq_count == 0) {
643 Debugger("PANIC_DEBUG");
645 panic("PANIC_DEBUG");
651 --mygd->gd_intr_nesting_level;
654 * If the queue is empty release ip_npoll to enable the other cpu to
655 * send us an IPI interrupt again.
657 * Return non-zero if there is still more in the queue. Note that we
658 * must re-check the indexes after potentially releasing ip_npoll. The
659 * caller must loop or otherwise ensure that a loop will occur prior to
662 if (ip->ip_rindex == ip->ip_windex);
663 atomic_poll_release_int(&ip->ip_npoll);
665 return (ip->ip_rindex != ip->ip_windex);
669 lwkt_sync_ipiq(void *arg)
671 volatile cpumask_t *cpumask = arg;
673 atomic_clear_cpumask(cpumask, mycpu->gd_cpumask);
679 lwkt_synchronize_ipiqs(const char *wmesg)
681 volatile cpumask_t other_cpumask;
683 other_cpumask = mycpu->gd_other_cpus & smp_active_mask;
684 lwkt_send_ipiq_mask(other_cpumask, lwkt_sync_ipiq,
685 __DEVOLATILE(void *, &other_cpumask));
687 while (other_cpumask != 0) {
688 tsleep_interlock(&other_cpumask, 0);
689 if (other_cpumask != 0)
690 tsleep(&other_cpumask, PINTERLOCKED, wmesg, 0);
697 * CPU Synchronization Support
699 * lwkt_cpusync_interlock() - Place specified cpus in a quiescent state.
700 * The current cpu is placed in a hard critical
703 * lwkt_cpusync_deinterlock() - Execute cs_func on specified cpus, including
704 * current cpu if specified, then return.
707 lwkt_cpusync_simple(cpumask_t mask, cpusync_func_t func, void *arg)
709 struct lwkt_cpusync cs;
711 lwkt_cpusync_init(&cs, mask, func, arg);
712 lwkt_cpusync_interlock(&cs);
713 lwkt_cpusync_deinterlock(&cs);
718 lwkt_cpusync_interlock(lwkt_cpusync_t cs)
721 globaldata_t gd = mycpu;
725 * mask acknowledge (cs_mack): 0->mask for stage 1
727 * mack does not include the current cpu.
729 mask = cs->cs_mask & gd->gd_other_cpus & smp_active_mask;
731 crit_enter_id("cpusync");
733 DEBUG_PUSH_INFO("cpusync_interlock");
735 ++gd->gd_curthread->td_cscount;
736 lwkt_send_ipiq_mask(mask, (ipifunc1_t)lwkt_cpusync_remote1, cs);
737 logipiq2(sync_start, mask);
738 while (cs->cs_mack != mask) {
750 * Interlocked cpus have executed remote1 and are polling in remote2.
751 * To deinterlock we clear cs_mack and wait for the cpus to execute
752 * the func and set their bit in cs_mack again.
756 lwkt_cpusync_deinterlock(lwkt_cpusync_t cs)
758 globaldata_t gd = mycpu;
763 * mask acknowledge (cs_mack): mack->0->mack for stage 2
765 * Clearing cpu bits for polling cpus in cs_mack will cause them to
766 * execute stage 2, which executes the cs_func(cs_data) and then sets
767 * their bit in cs_mack again.
769 * mack does not include the current cpu.
774 if (cs->cs_func && (cs->cs_mask & gd->gd_cpumask))
775 cs->cs_func(cs->cs_data);
777 DEBUG_PUSH_INFO("cpusync_deinterlock");
778 while (cs->cs_mack != mask) {
784 * cpusyncq ipis may be left queued without the RQF flag set due to
785 * a non-zero td_cscount, so be sure to process any laggards after
786 * decrementing td_cscount.
788 --gd->gd_curthread->td_cscount;
790 logipiq2(sync_end, mask);
792 crit_exit_id("cpusync");
794 if (cs->cs_func && (cs->cs_mask & gd->gd_cpumask))
795 cs->cs_func(cs->cs_data);
802 * helper IPI remote messaging function.
804 * Called on remote cpu when a new cpu synchronization request has been
805 * sent to us. Execute the run function and adjust cs_count, then requeue
806 * the request so we spin on it.
809 lwkt_cpusync_remote1(lwkt_cpusync_t cs)
811 globaldata_t gd = mycpu;
813 atomic_set_cpumask(&cs->cs_mack, gd->gd_cpumask);
814 lwkt_cpusync_remote2(cs);
818 * helper IPI remote messaging function.
820 * Poll for the originator telling us to finish. If it hasn't, requeue
821 * our request so we spin on it.
824 lwkt_cpusync_remote2(lwkt_cpusync_t cs)
826 globaldata_t gd = mycpu;
828 if ((cs->cs_mack & gd->gd_cpumask) == 0) {
830 cs->cs_func(cs->cs_data);
831 atomic_set_cpumask(&cs->cs_mack, gd->gd_cpumask);
836 ip = &gd->gd_cpusyncq;
837 wi = ip->ip_windex & MAXCPUFIFO_MASK;
838 ip->ip_func[wi] = (ipifunc3_t)(ipifunc1_t)lwkt_cpusync_remote2;
839 ip->ip_arg1[wi] = cs;
843 if (ipiq_debug && (ip->ip_windex & 0xFFFFFF) == 0) {
844 kprintf("cpu %d cm=%016jx %016jx f=%p\n",
846 (intmax_t)cs->cs_mask, (intmax_t)cs->cs_mack,