xref: /illumos-gate/usr/src/uts/common/disp/thread.c (revision 0245b61fd282e95735b173b8d95be0d6688163b4)
1 /*
2  * CDDL HEADER START
3  *
4  * The contents of this file are subject to the terms of the
5  * Common Development and Distribution License (the "License").
6  * You may not use this file except in compliance with the License.
7  *
8  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9  * or http://www.opensolaris.org/os/licensing.
10  * See the License for the specific language governing permissions
11  * and limitations under the License.
12  *
13  * When distributing Covered Code, include this CDDL HEADER in each
14  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15  * If applicable, add the following below this CDDL HEADER, with the
16  * fields enclosed by brackets "[]" replaced with your own identifying
17  * information: Portions Copyright [yyyy] [name of copyright owner]
18  *
19  * CDDL HEADER END
20  */
21 
22 /*
23  * Copyright (c) 1991, 2010, Oracle and/or its affiliates. All rights reserved.
24  * Copyright 2021 Joyent, Inc.
25  * Copyright 2021 Oxide Computer Company
26  */
27 
28 #include <sys/types.h>
29 #include <sys/param.h>
30 #include <sys/sysmacros.h>
31 #include <sys/signal.h>
32 #include <sys/stack.h>
33 #include <sys/pcb.h>
34 #include <sys/user.h>
35 #include <sys/systm.h>
36 #include <sys/sysinfo.h>
37 #include <sys/errno.h>
38 #include <sys/cmn_err.h>
39 #include <sys/cred.h>
40 #include <sys/resource.h>
41 #include <sys/task.h>
42 #include <sys/project.h>
43 #include <sys/proc.h>
44 #include <sys/debug.h>
45 #include <sys/disp.h>
46 #include <sys/class.h>
47 #include <vm/seg_kmem.h>
48 #include <vm/seg_kp.h>
49 #include <sys/machlock.h>
50 #include <sys/kmem.h>
51 #include <sys/varargs.h>
52 #include <sys/turnstile.h>
53 #include <sys/poll.h>
54 #include <sys/vtrace.h>
55 #include <sys/callb.h>
56 #include <c2/audit.h>
57 #include <sys/tnf.h>
58 #include <sys/sobject.h>
59 #include <sys/cpupart.h>
60 #include <sys/pset.h>
61 #include <sys/door.h>
62 #include <sys/spl.h>
63 #include <sys/copyops.h>
64 #include <sys/rctl.h>
65 #include <sys/brand.h>
66 #include <sys/pool.h>
67 #include <sys/zone.h>
68 #include <sys/tsol/label.h>
69 #include <sys/tsol/tndb.h>
70 #include <sys/cpc_impl.h>
71 #include <sys/sdt.h>
72 #include <sys/reboot.h>
73 #include <sys/kdi.h>
74 #include <sys/schedctl.h>
75 #include <sys/waitq.h>
76 #include <sys/cpucaps.h>
77 #include <sys/kiconv.h>
78 #include <sys/ctype.h>
79 #include <sys/smt.h>
80 
81 struct kmem_cache *thread_cache;	/* cache of free threads */
82 struct kmem_cache *lwp_cache;		/* cache of free lwps */
83 struct kmem_cache *turnstile_cache;	/* cache of free turnstiles */
84 
85 /*
86  * allthreads is only for use by kmem_readers.  All kernel loops can use
87  * the current thread as a start/end point.
88  */
89 kthread_t *allthreads = &t0;	/* circular list of all threads */
90 
91 static kcondvar_t reaper_cv;		/* synchronization var */
92 kthread_t	*thread_deathrow;	/* circular list of reapable threads */
93 kthread_t	*lwp_deathrow;		/* circular list of reapable threads */
94 kmutex_t	reaplock;		/* protects lwp and thread deathrows */
95 int	thread_reapcnt = 0;		/* number of threads on deathrow */
96 int	lwp_reapcnt = 0;		/* number of lwps on deathrow */
97 int	reaplimit = 16;			/* delay reaping until reaplimit */
98 
99 thread_free_lock_t	*thread_free_lock;
100 					/* protects tick thread from reaper */
101 
102 extern int nthread;
103 
104 /* System Scheduling classes. */
105 id_t	syscid;				/* system scheduling class ID */
106 id_t	sysdccid = CLASS_UNUSED;	/* reset when SDC loads */
107 
108 void	*segkp_thread;			/* cookie for segkp pool */
109 
110 int lwp_cache_sz = 32;
111 int t_cache_sz = 8;
112 static kt_did_t next_t_id = 1;
113 
114 /* Default mode for thread binding to CPUs and processor sets */
115 int default_binding_mode = TB_ALLHARD;
116 
117 /*
118  * Min/Max stack sizes for stack size parameters
119  */
120 #define	MAX_STKSIZE	(32 * DEFAULTSTKSZ)
121 #define	MIN_STKSIZE	DEFAULTSTKSZ
122 
123 /*
124  * default_stksize overrides lwp_default_stksize if it is set.
125  */
126 int	default_stksize;
127 int	lwp_default_stksize;
128 
129 static zone_key_t zone_thread_key;
130 
131 unsigned int kmem_stackinfo;		/* stackinfo feature on-off */
132 kmem_stkinfo_t *kmem_stkinfo_log;	/* stackinfo circular log */
133 static kmutex_t kmem_stkinfo_lock;	/* protects kmem_stkinfo_log */
134 
135 /*
136  * forward declarations for internal thread specific data (tsd)
137  */
138 static void *tsd_realloc(void *, size_t, size_t);
139 
140 void thread_reaper(void);
141 
142 /* forward declarations for stackinfo feature */
143 static void stkinfo_begin(kthread_t *);
144 static void stkinfo_end(kthread_t *);
145 static size_t stkinfo_percent(caddr_t, caddr_t, caddr_t);
146 
147 /*ARGSUSED*/
148 static int
149 turnstile_constructor(void *buf, void *cdrarg, int kmflags)
150 {
151 	bzero(buf, sizeof (turnstile_t));
152 	return (0);
153 }
154 
155 /*ARGSUSED*/
156 static void
157 turnstile_destructor(void *buf, void *cdrarg)
158 {
159 	turnstile_t *ts = buf;
160 
161 	ASSERT(ts->ts_free == NULL);
162 	ASSERT(ts->ts_waiters == 0);
163 	ASSERT(ts->ts_inheritor == NULL);
164 	ASSERT(ts->ts_sleepq[0].sq_first == NULL);
165 	ASSERT(ts->ts_sleepq[1].sq_first == NULL);
166 }
167 
168 void
169 thread_init(void)
170 {
171 	kthread_t *tp;
172 	extern char sys_name[];
173 	extern void idle();
174 	struct cpu *cpu = CPU;
175 	int i;
176 	kmutex_t *lp;
177 
178 	mutex_init(&reaplock, NULL, MUTEX_SPIN, (void *)ipltospl(DISP_LEVEL));
179 	thread_free_lock =
180 	    kmem_alloc(sizeof (thread_free_lock_t) * THREAD_FREE_NUM, KM_SLEEP);
181 	for (i = 0; i < THREAD_FREE_NUM; i++) {
182 		lp = &thread_free_lock[i].tf_lock;
183 		mutex_init(lp, NULL, MUTEX_DEFAULT, NULL);
184 	}
185 
186 #if defined(__x86)
187 	thread_cache = kmem_cache_create("thread_cache", sizeof (kthread_t),
188 	    PTR24_ALIGN, NULL, NULL, NULL, NULL, NULL, 0);
189 
190 	/*
191 	 * "struct _klwp" includes a "struct pcb", which includes a
192 	 * "struct fpu", which needs to be 64-byte aligned on amd64
193 	 * (and even on i386) for xsave/xrstor.
194 	 */
195 	lwp_cache = kmem_cache_create("lwp_cache", sizeof (klwp_t),
196 	    64, NULL, NULL, NULL, NULL, NULL, 0);
197 #else
198 	/*
199 	 * Allocate thread structures from static_arena.  This prevents
200 	 * issues where a thread tries to relocate its own thread
201 	 * structure and touches it after the mapping has been suspended.
202 	 */
203 	thread_cache = kmem_cache_create("thread_cache", sizeof (kthread_t),
204 	    PTR24_ALIGN, NULL, NULL, NULL, NULL, static_arena, 0);
205 
206 	lwp_stk_cache_init();
207 
208 	lwp_cache = kmem_cache_create("lwp_cache", sizeof (klwp_t),
209 	    0, NULL, NULL, NULL, NULL, NULL, 0);
210 #endif
211 
212 	turnstile_cache = kmem_cache_create("turnstile_cache",
213 	    sizeof (turnstile_t), 0,
214 	    turnstile_constructor, turnstile_destructor, NULL, NULL, NULL, 0);
215 
216 	label_init();
217 	cred_init();
218 
219 	/*
220 	 * Initialize various resource management facilities.
221 	 */
222 	rctl_init();
223 	cpucaps_init();
224 	/*
225 	 * Zone_init() should be called before project_init() so that project ID
226 	 * for the first project is initialized correctly.
227 	 */
228 	zone_init();
229 	project_init();
230 	brand_init();
231 	kiconv_init();
232 	task_init();
233 	tcache_init();
234 	pool_init();
235 
236 	curthread->t_ts = kmem_cache_alloc(turnstile_cache, KM_SLEEP);
237 
238 	/*
239 	 * Originally, we had two parameters to set default stack
240 	 * size: one for lwp's (lwp_default_stksize), and one for
241 	 * kernel-only threads (DEFAULTSTKSZ, a.k.a. _defaultstksz).
242 	 * Now we have a third parameter that overrides both if it is
243 	 * set to a legal stack size, called default_stksize.
244 	 */
245 
246 	if (default_stksize == 0) {
247 		default_stksize = DEFAULTSTKSZ;
248 	} else if (default_stksize % PAGESIZE != 0 ||
249 	    default_stksize > MAX_STKSIZE ||
250 	    default_stksize < MIN_STKSIZE) {
251 		cmn_err(CE_WARN, "Illegal stack size. Using %d",
252 		    (int)DEFAULTSTKSZ);
253 		default_stksize = DEFAULTSTKSZ;
254 	} else {
255 		lwp_default_stksize = default_stksize;
256 	}
257 
258 	if (lwp_default_stksize == 0) {
259 		lwp_default_stksize = default_stksize;
260 	} else if (lwp_default_stksize % PAGESIZE != 0 ||
261 	    lwp_default_stksize > MAX_STKSIZE ||
262 	    lwp_default_stksize < MIN_STKSIZE) {
263 		cmn_err(CE_WARN, "Illegal stack size. Using %d",
264 		    default_stksize);
265 		lwp_default_stksize = default_stksize;
266 	}
267 
268 	segkp_lwp = segkp_cache_init(segkp, lwp_cache_sz,
269 	    lwp_default_stksize,
270 	    (KPD_NOWAIT | KPD_HASREDZONE | KPD_LOCKED));
271 
272 	segkp_thread = segkp_cache_init(segkp, t_cache_sz,
273 	    default_stksize, KPD_HASREDZONE | KPD_LOCKED | KPD_NO_ANON);
274 
275 	(void) getcid(sys_name, &syscid);
276 	curthread->t_cid = syscid;	/* current thread is t0 */
277 
278 	/*
279 	 * Set up the first CPU's idle thread.
280 	 * It runs whenever the CPU has nothing worthwhile to do.
281 	 */
282 	tp = thread_create(NULL, 0, idle, NULL, 0, &p0, TS_STOPPED, -1);
283 	cpu->cpu_idle_thread = tp;
284 	tp->t_preempt = 1;
285 	tp->t_disp_queue = cpu->cpu_disp;
286 	ASSERT(tp->t_disp_queue != NULL);
287 	tp->t_bound_cpu = cpu;
288 	tp->t_affinitycnt = 1;
289 
290 	/*
291 	 * Registering a thread in the callback table is usually
292 	 * done in the initialization code of the thread. In this
293 	 * case, we do it right after thread creation to avoid
294 	 * blocking idle thread while registering itself. It also
295 	 * avoids the possibility of reregistration in case a CPU
296 	 * restarts its idle thread.
297 	 */
298 	CALLB_CPR_INIT_SAFE(tp, "idle");
299 
300 	/*
301 	 * Create the thread_reaper daemon. From this point on, exited
302 	 * threads will get reaped.
303 	 */
304 	(void) thread_create(NULL, 0, (void (*)())thread_reaper,
305 	    NULL, 0, &p0, TS_RUN, minclsyspri);
306 
307 	/*
308 	 * Finish initializing the kernel memory allocator now that
309 	 * thread_create() is available.
310 	 */
311 	kmem_thread_init();
312 
313 	if (boothowto & RB_DEBUG)
314 		kdi_dvec_thravail();
315 }
316 
317 /*
318  * Create a thread.
319  *
320  * thread_create() blocks for memory if necessary.  It never fails.
321  *
322  * If stk is NULL, the thread is created at the base of the stack
323  * and cannot be swapped.
324  */
325 kthread_t *
326 thread_create(
327 	caddr_t	stk,
328 	size_t	stksize,
329 	void	(*proc)(),
330 	void	*arg,
331 	size_t	len,
332 	proc_t	 *pp,
333 	int	state,
334 	pri_t	pri)
335 {
336 	kthread_t *t;
337 	extern struct classfuncs sys_classfuncs;
338 	turnstile_t *ts;
339 
340 	/*
341 	 * Every thread keeps a turnstile around in case it needs to block.
342 	 * The only reason the turnstile is not simply part of the thread
343 	 * structure is that we may have to break the association whenever
344 	 * more than one thread blocks on a given synchronization object.
345 	 * From a memory-management standpoint, turnstiles are like the
346 	 * "attached mblks" that hang off dblks in the streams allocator.
347 	 */
348 	ts = kmem_cache_alloc(turnstile_cache, KM_SLEEP);
349 
350 	if (stk == NULL) {
351 		/*
352 		 * alloc both thread and stack in segkp chunk
353 		 */
354 
355 		if (stksize < default_stksize)
356 			stksize = default_stksize;
357 
358 		if (stksize == default_stksize) {
359 			stk = (caddr_t)segkp_cache_get(segkp_thread);
360 		} else {
361 			stksize = roundup(stksize, PAGESIZE);
362 			stk = (caddr_t)segkp_get(segkp, stksize,
363 			    (KPD_HASREDZONE | KPD_NO_ANON | KPD_LOCKED));
364 		}
365 
366 		ASSERT(stk != NULL);
367 
368 		/*
369 		 * The machine-dependent mutex code may require that
370 		 * thread pointers (since they may be used for mutex owner
371 		 * fields) have certain alignment requirements.
372 		 * PTR24_ALIGN is the size of the alignment quanta.
373 		 * XXX - assumes stack grows toward low addresses.
374 		 */
375 		if (stksize <= sizeof (kthread_t) + PTR24_ALIGN)
376 			cmn_err(CE_PANIC, "thread_create: proposed stack size"
377 			    " too small to hold thread.");
378 #ifdef STACK_GROWTH_DOWN
379 		stksize -= SA(sizeof (kthread_t) + PTR24_ALIGN - 1);
380 		stksize &= -PTR24_ALIGN;	/* make thread aligned */
381 		t = (kthread_t *)(stk + stksize);
382 		bzero(t, sizeof (kthread_t));
383 		if (audit_active)
384 			audit_thread_create(t);
385 		t->t_stk = stk + stksize;
386 		t->t_stkbase = stk;
387 #else	/* stack grows to larger addresses */
388 		stksize -= SA(sizeof (kthread_t));
389 		t = (kthread_t *)(stk);
390 		bzero(t, sizeof (kthread_t));
391 		t->t_stk = stk + sizeof (kthread_t);
392 		t->t_stkbase = stk + stksize + sizeof (kthread_t);
393 #endif	/* STACK_GROWTH_DOWN */
394 		t->t_flag |= T_TALLOCSTK;
395 		t->t_swap = stk;
396 	} else {
397 		t = kmem_cache_alloc(thread_cache, KM_SLEEP);
398 		bzero(t, sizeof (kthread_t));
399 		ASSERT(((uintptr_t)t & (PTR24_ALIGN - 1)) == 0);
400 		if (audit_active)
401 			audit_thread_create(t);
402 		/*
403 		 * Initialize t_stk to the kernel stack pointer to use
404 		 * upon entry to the kernel
405 		 */
406 #ifdef STACK_GROWTH_DOWN
407 		t->t_stk = stk + stksize;
408 		t->t_stkbase = stk;
409 #else
410 		t->t_stk = stk;			/* 3b2-like */
411 		t->t_stkbase = stk + stksize;
412 #endif /* STACK_GROWTH_DOWN */
413 	}
414 
415 	if (kmem_stackinfo != 0) {
416 		stkinfo_begin(t);
417 	}
418 
419 	t->t_ts = ts;
420 
421 	/*
422 	 * p_cred could be NULL if it thread_create is called before cred_init
423 	 * is called in main.
424 	 */
425 	mutex_enter(&pp->p_crlock);
426 	if (pp->p_cred)
427 		crhold(t->t_cred = pp->p_cred);
428 	mutex_exit(&pp->p_crlock);
429 	t->t_start = gethrestime_sec();
430 	t->t_startpc = proc;
431 	t->t_procp = pp;
432 	t->t_clfuncs = &sys_classfuncs.thread;
433 	t->t_cid = syscid;
434 	t->t_pri = pri;
435 	t->t_stime = ddi_get_lbolt();
436 	t->t_schedflag = TS_LOAD | TS_DONT_SWAP;
437 	t->t_bind_cpu = PBIND_NONE;
438 	t->t_bindflag = (uchar_t)default_binding_mode;
439 	t->t_bind_pset = PS_NONE;
440 	t->t_plockp = &pp->p_lock;
441 	t->t_copyops = NULL;
442 	t->t_taskq = NULL;
443 	t->t_anttime = 0;
444 	t->t_hatdepth = 0;
445 
446 	t->t_dtrace_vtime = 1;	/* assure vtimestamp is always non-zero */
447 
448 	CPU_STATS_ADDQ(CPU, sys, nthreads, 1);
449 #ifndef NPROBE
450 	/* Kernel probe */
451 	tnf_thread_create(t);
452 #endif /* NPROBE */
453 	LOCK_INIT_CLEAR(&t->t_lock);
454 
455 	/*
456 	 * Callers who give us a NULL proc must do their own
457 	 * stack initialization.  e.g. lwp_create()
458 	 */
459 	if (proc != NULL) {
460 		t->t_stk = thread_stk_init(t->t_stk);
461 		thread_load(t, proc, arg, len);
462 	}
463 
464 	/*
465 	 * Put a hold on project0. If this thread is actually in a
466 	 * different project, then t_proj will be changed later in
467 	 * lwp_create().  All kernel-only threads must be in project 0.
468 	 */
469 	t->t_proj = project_hold(proj0p);
470 
471 	lgrp_affinity_init(&t->t_lgrp_affinity);
472 
473 	mutex_enter(&pidlock);
474 	nthread++;
475 	t->t_did = next_t_id++;
476 	t->t_prev = curthread->t_prev;
477 	t->t_next = curthread;
478 
479 	/*
480 	 * Add the thread to the list of all threads, and initialize
481 	 * its t_cpu pointer.  We need to block preemption since
482 	 * cpu_offline walks the thread list looking for threads
483 	 * with t_cpu pointing to the CPU being offlined.  We want
484 	 * to make sure that the list is consistent and that if t_cpu
485 	 * is set, the thread is on the list.
486 	 */
487 	kpreempt_disable();
488 	curthread->t_prev->t_next = t;
489 	curthread->t_prev = t;
490 
491 	/*
492 	 * We'll always create in the default partition since that's where
493 	 * kernel threads go (we'll change this later if needed, in
494 	 * lwp_create()).
495 	 */
496 	t->t_cpupart = &cp_default;
497 
498 	/*
499 	 * For now, affiliate this thread with the root lgroup.
500 	 * Since the kernel does not (presently) allocate its memory
501 	 * in a locality aware fashion, the root is an appropriate home.
502 	 * If this thread is later associated with an lwp, it will have
503 	 * its lgroup re-assigned at that time.
504 	 */
505 	lgrp_move_thread(t, &cp_default.cp_lgrploads[LGRP_ROOTID], 1);
506 
507 	/*
508 	 * If the current CPU is in the default cpupart, use it.  Otherwise,
509 	 * pick one that is; before entering the dispatcher code, we'll
510 	 * make sure to keep the invariant that ->t_cpu is set.  (In fact, we
511 	 * rely on this, in ht_should_run(), in the call tree of
512 	 * disp_lowpri_cpu().)
513 	 */
514 	if (CPU->cpu_part == &cp_default) {
515 		t->t_cpu = CPU;
516 	} else {
517 		t->t_cpu = cp_default.cp_cpulist;
518 		t->t_cpu = disp_lowpri_cpu(t->t_cpu, t, t->t_pri);
519 	}
520 
521 	t->t_disp_queue = t->t_cpu->cpu_disp;
522 	kpreempt_enable();
523 
524 	/*
525 	 * Initialize thread state and the dispatcher lock pointer.
526 	 * Need to hold onto pidlock to block allthreads walkers until
527 	 * the state is set.
528 	 */
529 	switch (state) {
530 	case TS_RUN:
531 		curthread->t_oldspl = splhigh();	/* get dispatcher spl */
532 		THREAD_SET_STATE(t, TS_STOPPED, &transition_lock);
533 		CL_SETRUN(t);
534 		thread_unlock(t);
535 		break;
536 
537 	case TS_ONPROC:
538 		THREAD_ONPROC(t, t->t_cpu);
539 		break;
540 
541 	case TS_FREE:
542 		/*
543 		 * Free state will be used for intr threads.
544 		 * The interrupt routine must set the thread dispatcher
545 		 * lock pointer (t_lockp) if starting on a CPU
546 		 * other than the current one.
547 		 */
548 		THREAD_FREEINTR(t, CPU);
549 		break;
550 
551 	case TS_STOPPED:
552 		THREAD_SET_STATE(t, TS_STOPPED, &stop_lock);
553 		break;
554 
555 	default:			/* TS_SLEEP, TS_ZOMB or TS_TRANS */
556 		cmn_err(CE_PANIC, "thread_create: invalid state %d", state);
557 	}
558 	mutex_exit(&pidlock);
559 	return (t);
560 }
561 
562 /*
563  * Move thread to project0 and take care of project reference counters.
564  */
565 void
566 thread_rele(kthread_t *t)
567 {
568 	kproject_t *kpj;
569 
570 	thread_lock(t);
571 
572 	ASSERT(t == curthread || t->t_state == TS_FREE || t->t_procp == &p0);
573 	kpj = ttoproj(t);
574 	t->t_proj = proj0p;
575 
576 	thread_unlock(t);
577 
578 	if (kpj != proj0p) {
579 		project_rele(kpj);
580 		(void) project_hold(proj0p);
581 	}
582 }
583 
584 void
585 thread_exit(void)
586 {
587 	kthread_t *t = curthread;
588 
589 	if ((t->t_proc_flag & TP_ZTHREAD) != 0)
590 		cmn_err(CE_PANIC, "thread_exit: zthread_exit() not called");
591 
592 	tsd_exit();		/* Clean up this thread's TSD */
593 
594 	kcpc_passivate();	/* clean up performance counter state */
595 
596 	/*
597 	 * No kernel thread should have called poll() without arranging
598 	 * calling pollcleanup() here.
599 	 */
600 	ASSERT(t->t_pollstate == NULL);
601 	ASSERT(t->t_schedctl == NULL);
602 	if (t->t_door)
603 		door_slam();	/* in case thread did an upcall */
604 
605 #ifndef NPROBE
606 	/* Kernel probe */
607 	if (t->t_tnf_tpdp)
608 		tnf_thread_exit();
609 #endif /* NPROBE */
610 
611 	thread_rele(t);
612 	t->t_preempt++;
613 
614 	/*
615 	 * remove thread from the all threads list so that
616 	 * death-row can use the same pointers.
617 	 */
618 	mutex_enter(&pidlock);
619 	t->t_next->t_prev = t->t_prev;
620 	t->t_prev->t_next = t->t_next;
621 	ASSERT(allthreads != t);	/* t0 never exits */
622 	cv_broadcast(&t->t_joincv);	/* wake up anyone in thread_join */
623 	mutex_exit(&pidlock);
624 
625 	if (t->t_ctx != NULL)
626 		exitctx(t);
627 	if (t->t_procp->p_pctx != NULL)
628 		exitpctx(t->t_procp);
629 
630 	if (kmem_stackinfo != 0) {
631 		stkinfo_end(t);
632 	}
633 
634 	t->t_state = TS_ZOMB;	/* set zombie thread */
635 
636 	swtch_from_zombie();	/* give up the CPU */
637 	/* NOTREACHED */
638 }
639 
640 /*
641  * Check to see if the specified thread is active (defined as being on
642  * the thread list).  This is certainly a slow way to do this; if there's
643  * ever a reason to speed it up, we could maintain a hash table of active
644  * threads indexed by their t_did.
645  */
646 static kthread_t *
647 did_to_thread(kt_did_t tid)
648 {
649 	kthread_t *t;
650 
651 	ASSERT(MUTEX_HELD(&pidlock));
652 	for (t = curthread->t_next; t != curthread; t = t->t_next) {
653 		if (t->t_did == tid)
654 			break;
655 	}
656 	if (t->t_did == tid)
657 		return (t);
658 	else
659 		return (NULL);
660 }
661 
662 /*
663  * Wait for specified thread to exit.  Returns immediately if the thread
664  * could not be found, meaning that it has either already exited or never
665  * existed.
666  */
667 void
668 thread_join(kt_did_t tid)
669 {
670 	kthread_t *t;
671 
672 	ASSERT(tid != curthread->t_did);
673 	ASSERT(tid != t0.t_did);
674 
675 	mutex_enter(&pidlock);
676 	/*
677 	 * Make sure we check that the thread is on the thread list
678 	 * before blocking on it; otherwise we could end up blocking on
679 	 * a cv that's already been freed.  In other words, don't cache
680 	 * the thread pointer across calls to cv_wait.
681 	 *
682 	 * The choice of loop invariant means that whenever a thread
683 	 * is taken off the allthreads list, a cv_broadcast must be
684 	 * performed on that thread's t_joincv to wake up any waiters.
685 	 * The broadcast doesn't have to happen right away, but it
686 	 * shouldn't be postponed indefinitely (e.g., by doing it in
687 	 * thread_free which may only be executed when the deathrow
688 	 * queue is processed.
689 	 */
690 	while (t = did_to_thread(tid))
691 		cv_wait(&t->t_joincv, &pidlock);
692 	mutex_exit(&pidlock);
693 }
694 
695 void
696 thread_free_prevent(kthread_t *t)
697 {
698 	kmutex_t *lp;
699 
700 	lp = &thread_free_lock[THREAD_FREE_HASH(t)].tf_lock;
701 	mutex_enter(lp);
702 }
703 
704 void
705 thread_free_allow(kthread_t *t)
706 {
707 	kmutex_t *lp;
708 
709 	lp = &thread_free_lock[THREAD_FREE_HASH(t)].tf_lock;
710 	mutex_exit(lp);
711 }
712 
713 static void
714 thread_free_barrier(kthread_t *t)
715 {
716 	kmutex_t *lp;
717 
718 	lp = &thread_free_lock[THREAD_FREE_HASH(t)].tf_lock;
719 	mutex_enter(lp);
720 	mutex_exit(lp);
721 }
722 
723 void
724 thread_free(kthread_t *t)
725 {
726 	boolean_t allocstk = (t->t_flag & T_TALLOCSTK);
727 	klwp_t *lwp = t->t_lwp;
728 	caddr_t swap = t->t_swap;
729 
730 	ASSERT(t != &t0 && t->t_state == TS_FREE);
731 	ASSERT(t->t_door == NULL);
732 	ASSERT(t->t_schedctl == NULL);
733 	ASSERT(t->t_pollstate == NULL);
734 
735 	t->t_pri = 0;
736 	t->t_pc = 0;
737 	t->t_sp = 0;
738 	t->t_wchan0 = NULL;
739 	t->t_wchan = NULL;
740 	if (t->t_cred != NULL) {
741 		crfree(t->t_cred);
742 		t->t_cred = 0;
743 	}
744 	if (t->t_pdmsg) {
745 		kmem_free(t->t_pdmsg, strlen(t->t_pdmsg) + 1);
746 		t->t_pdmsg = NULL;
747 	}
748 	if (audit_active)
749 		audit_thread_free(t);
750 #ifndef NPROBE
751 	if (t->t_tnf_tpdp)
752 		tnf_thread_free(t);
753 #endif /* NPROBE */
754 	if (t->t_cldata) {
755 		CL_EXITCLASS(t->t_cid, (caddr_t *)t->t_cldata);
756 	}
757 	if (t->t_rprof != NULL) {
758 		kmem_free(t->t_rprof, sizeof (*t->t_rprof));
759 		t->t_rprof = NULL;
760 	}
761 	t->t_lockp = NULL;	/* nothing should try to lock this thread now */
762 	if (lwp)
763 		lwp_freeregs(lwp, 0);
764 	if (t->t_ctx)
765 		freectx(t, 0);
766 	t->t_stk = NULL;
767 	if (lwp)
768 		lwp_stk_fini(lwp);
769 	lock_clear(&t->t_lock);
770 
771 	if (t->t_ts->ts_waiters > 0)
772 		panic("thread_free: turnstile still active");
773 
774 	kmem_cache_free(turnstile_cache, t->t_ts);
775 
776 	free_afd(&t->t_activefd);
777 
778 	/*
779 	 * Barrier for the tick accounting code.  The tick accounting code
780 	 * holds this lock to keep the thread from going away while it's
781 	 * looking at it.
782 	 */
783 	thread_free_barrier(t);
784 
785 	ASSERT(ttoproj(t) == proj0p);
786 	project_rele(ttoproj(t));
787 
788 	lgrp_affinity_free(&t->t_lgrp_affinity);
789 
790 	mutex_enter(&pidlock);
791 	nthread--;
792 	mutex_exit(&pidlock);
793 
794 	if (t->t_name != NULL) {
795 		kmem_free(t->t_name, THREAD_NAME_MAX);
796 		t->t_name = NULL;
797 	}
798 
799 	/*
800 	 * Free thread, lwp and stack.  This needs to be done carefully, since
801 	 * if T_TALLOCSTK is set, the thread is part of the stack.
802 	 */
803 	t->t_lwp = NULL;
804 	t->t_swap = NULL;
805 
806 	if (swap) {
807 		segkp_release(segkp, swap);
808 	}
809 	if (lwp) {
810 		kmem_cache_free(lwp_cache, lwp);
811 	}
812 	if (!allocstk) {
813 		kmem_cache_free(thread_cache, t);
814 	}
815 }
816 
817 /*
818  * Removes threads associated with the given zone from a deathrow queue.
819  * tp is a pointer to the head of the deathrow queue, and countp is a
820  * pointer to the current deathrow count.  Returns a linked list of
821  * threads removed from the list.
822  */
823 static kthread_t *
824 thread_zone_cleanup(kthread_t **tp, int *countp, zoneid_t zoneid)
825 {
826 	kthread_t *tmp, *list = NULL;
827 	cred_t *cr;
828 
829 	ASSERT(MUTEX_HELD(&reaplock));
830 	while (*tp != NULL) {
831 		if ((cr = (*tp)->t_cred) != NULL && crgetzoneid(cr) == zoneid) {
832 			tmp = *tp;
833 			*tp = tmp->t_forw;
834 			tmp->t_forw = list;
835 			list = tmp;
836 			(*countp)--;
837 		} else {
838 			tp = &(*tp)->t_forw;
839 		}
840 	}
841 	return (list);
842 }
843 
844 static void
845 thread_reap_list(kthread_t *t)
846 {
847 	kthread_t *next;
848 
849 	while (t != NULL) {
850 		next = t->t_forw;
851 		thread_free(t);
852 		t = next;
853 	}
854 }
855 
856 /* ARGSUSED */
857 static void
858 thread_zone_destroy(zoneid_t zoneid, void *unused)
859 {
860 	kthread_t *t, *l;
861 
862 	mutex_enter(&reaplock);
863 	/*
864 	 * Pull threads and lwps associated with zone off deathrow lists.
865 	 */
866 	t = thread_zone_cleanup(&thread_deathrow, &thread_reapcnt, zoneid);
867 	l = thread_zone_cleanup(&lwp_deathrow, &lwp_reapcnt, zoneid);
868 	mutex_exit(&reaplock);
869 
870 	/*
871 	 * Guard against race condition in mutex_owner_running:
872 	 *	thread=owner(mutex)
873 	 *	<interrupt>
874 	 *				thread exits mutex
875 	 *				thread exits
876 	 *				thread reaped
877 	 *				thread struct freed
878 	 * cpu = thread->t_cpu <- BAD POINTER DEREFERENCE.
879 	 * A cross call to all cpus will cause the interrupt handler
880 	 * to reset the PC if it is in mutex_owner_running, refreshing
881 	 * stale thread pointers.
882 	 */
883 	mutex_sync();   /* sync with mutex code */
884 
885 	/*
886 	 * Reap threads
887 	 */
888 	thread_reap_list(t);
889 
890 	/*
891 	 * Reap lwps
892 	 */
893 	thread_reap_list(l);
894 }
895 
896 /*
897  * cleanup zombie threads that are on deathrow.
898  */
899 void
900 thread_reaper()
901 {
902 	kthread_t *t, *l;
903 	callb_cpr_t cprinfo;
904 
905 	/*
906 	 * Register callback to clean up threads when zone is destroyed.
907 	 */
908 	zone_key_create(&zone_thread_key, NULL, NULL, thread_zone_destroy);
909 
910 	CALLB_CPR_INIT(&cprinfo, &reaplock, callb_generic_cpr, "t_reaper");
911 	for (;;) {
912 		mutex_enter(&reaplock);
913 		while (thread_deathrow == NULL && lwp_deathrow == NULL) {
914 			CALLB_CPR_SAFE_BEGIN(&cprinfo);
915 			cv_wait(&reaper_cv, &reaplock);
916 			CALLB_CPR_SAFE_END(&cprinfo, &reaplock);
917 		}
918 		/*
919 		 * mutex_sync() needs to be called when reaping, but
920 		 * not too often.  We limit reaping rate to once
921 		 * per second.  Reaplimit is max rate at which threads can
922 		 * be freed. Does not impact thread destruction/creation.
923 		 */
924 		t = thread_deathrow;
925 		l = lwp_deathrow;
926 		thread_deathrow = NULL;
927 		lwp_deathrow = NULL;
928 		thread_reapcnt = 0;
929 		lwp_reapcnt = 0;
930 		mutex_exit(&reaplock);
931 
932 		/*
933 		 * Guard against race condition in mutex_owner_running:
934 		 *	thread=owner(mutex)
935 		 *	<interrupt>
936 		 *				thread exits mutex
937 		 *				thread exits
938 		 *				thread reaped
939 		 *				thread struct freed
940 		 * cpu = thread->t_cpu <- BAD POINTER DEREFERENCE.
941 		 * A cross call to all cpus will cause the interrupt handler
942 		 * to reset the PC if it is in mutex_owner_running, refreshing
943 		 * stale thread pointers.
944 		 */
945 		mutex_sync();   /* sync with mutex code */
946 		/*
947 		 * Reap threads
948 		 */
949 		thread_reap_list(t);
950 
951 		/*
952 		 * Reap lwps
953 		 */
954 		thread_reap_list(l);
955 		delay(hz);
956 	}
957 }
958 
959 /*
960  * This is called by lwpcreate, etc.() to put a lwp_deathrow thread onto
961  * thread_deathrow. The thread's state is changed already TS_FREE to indicate
962  * that is reapable. The thread already holds the reaplock, and was already
963  * freed.
964  */
965 void
966 reapq_move_lq_to_tq(kthread_t *t)
967 {
968 	ASSERT(t->t_state == TS_FREE);
969 	ASSERT(MUTEX_HELD(&reaplock));
970 	t->t_forw = thread_deathrow;
971 	thread_deathrow = t;
972 	thread_reapcnt++;
973 	if (lwp_reapcnt + thread_reapcnt > reaplimit)
974 		cv_signal(&reaper_cv);  /* wake the reaper */
975 }
976 
977 /*
978  * This is called by resume() to put a zombie thread onto deathrow.
979  * The thread's state is changed to TS_FREE to indicate that is reapable.
980  * This is called from the idle thread so it must not block - just spin.
981  */
982 void
983 reapq_add(kthread_t *t)
984 {
985 	mutex_enter(&reaplock);
986 
987 	/*
988 	 * lwp_deathrow contains threads with lwp linkage and
989 	 * swappable thread stacks which have the default stacksize.
990 	 * These threads' lwps and stacks may be reused by lwp_create().
991 	 *
992 	 * Anything else goes on thread_deathrow(), where it will eventually
993 	 * be thread_free()d.
994 	 */
995 	if (t->t_flag & T_LWPREUSE) {
996 		ASSERT(ttolwp(t) != NULL);
997 		t->t_forw = lwp_deathrow;
998 		lwp_deathrow = t;
999 		lwp_reapcnt++;
1000 	} else {
1001 		t->t_forw = thread_deathrow;
1002 		thread_deathrow = t;
1003 		thread_reapcnt++;
1004 	}
1005 	if (lwp_reapcnt + thread_reapcnt > reaplimit)
1006 		cv_signal(&reaper_cv);	/* wake the reaper */
1007 	t->t_state = TS_FREE;
1008 	lock_clear(&t->t_lock);
1009 
1010 	/*
1011 	 * Before we return, we need to grab and drop the thread lock for
1012 	 * the dead thread.  At this point, the current thread is the idle
1013 	 * thread, and the dead thread's CPU lock points to the current
1014 	 * CPU -- and we must grab and drop the lock to synchronize with
1015 	 * a racing thread walking a blocking chain that the zombie thread
1016 	 * was recently in.  By this point, that blocking chain is (by
1017 	 * definition) stale:  the dead thread is not holding any locks, and
1018 	 * is therefore not in any blocking chains -- but if we do not regrab
1019 	 * our lock before freeing the dead thread's data structures, the
1020 	 * thread walking the (stale) blocking chain will die on memory
1021 	 * corruption when it attempts to drop the dead thread's lock.  We
1022 	 * only need do this once because there is no way for the dead thread
1023 	 * to ever again be on a blocking chain:  once we have grabbed and
1024 	 * dropped the thread lock, we are guaranteed that anyone that could
1025 	 * have seen this thread in a blocking chain can no longer see it.
1026 	 */
1027 	thread_lock(t);
1028 	thread_unlock(t);
1029 
1030 	mutex_exit(&reaplock);
1031 }
1032 
1033 static struct ctxop *
1034 ctxop_find_by_tmpl(kthread_t *t, const struct ctxop_template *ct, void *arg)
1035 {
1036 	struct ctxop *ctx, *head;
1037 
1038 	ASSERT(MUTEX_HELD(&t->t_ctx_lock));
1039 	ASSERT(curthread->t_preempt > 0);
1040 
1041 	if (t->t_ctx == NULL) {
1042 		return (NULL);
1043 	}
1044 
1045 	ctx = head = t->t_ctx;
1046 	do {
1047 		if (ctx->save_op == ct->ct_save &&
1048 		    ctx->restore_op == ct->ct_restore &&
1049 		    ctx->fork_op == ct->ct_fork &&
1050 		    ctx->lwp_create_op == ct->ct_lwp_create &&
1051 		    ctx->exit_op == ct->ct_exit &&
1052 		    ctx->free_op == ct->ct_free &&
1053 		    ctx->arg == arg) {
1054 			return (ctx);
1055 		}
1056 
1057 		ctx = ctx->next;
1058 	} while (ctx != head);
1059 
1060 	return (NULL);
1061 }
1062 
1063 static void
1064 ctxop_detach_chain(kthread_t *t, struct ctxop *ctx)
1065 {
1066 	ASSERT(t != NULL);
1067 	ASSERT(t->t_ctx != NULL);
1068 	ASSERT(ctx != NULL);
1069 	ASSERT(ctx->next != NULL && ctx->prev != NULL);
1070 
1071 	ctx->prev->next = ctx->next;
1072 	ctx->next->prev = ctx->prev;
1073 	if (ctx->next == ctx) {
1074 		/* last remaining item */
1075 		t->t_ctx = NULL;
1076 	} else if (ctx == t->t_ctx) {
1077 		/* fix up head of list */
1078 		t->t_ctx = ctx->next;
1079 	}
1080 	ctx->next = ctx->prev = NULL;
1081 }
1082 
1083 struct ctxop *
1084 ctxop_allocate(const struct ctxop_template *ct, void *arg)
1085 {
1086 	struct ctxop *ctx;
1087 
1088 	/*
1089 	 * No changes have been made to the interface yet, so we expect all
1090 	 * callers to use the original revision.
1091 	 */
1092 	VERIFY3U(ct->ct_rev, ==, CTXOP_TPL_REV);
1093 
1094 	ctx = kmem_alloc(sizeof (struct ctxop), KM_SLEEP);
1095 	ctx->save_op = ct->ct_save;
1096 	ctx->restore_op = ct->ct_restore;
1097 	ctx->fork_op = ct->ct_fork;
1098 	ctx->lwp_create_op = ct->ct_lwp_create;
1099 	ctx->exit_op = ct->ct_exit;
1100 	ctx->free_op = ct->ct_free;
1101 	ctx->arg = arg;
1102 	ctx->save_ts = 0;
1103 	ctx->restore_ts = 0;
1104 	ctx->next = ctx->prev = NULL;
1105 
1106 	return (ctx);
1107 }
1108 
1109 void
1110 ctxop_free(struct ctxop *ctx)
1111 {
1112 	if (ctx->free_op != NULL)
1113 		(ctx->free_op)(ctx->arg, 0);
1114 
1115 	kmem_free(ctx, sizeof (struct ctxop));
1116 }
1117 
1118 void
1119 ctxop_attach(kthread_t *t, struct ctxop *ctx)
1120 {
1121 	ASSERT(ctx->next == NULL && ctx->prev == NULL);
1122 
1123 	/*
1124 	 * Keep ctxops in a doubly-linked list to allow traversal in both
1125 	 * directions.  Using only the newest-to-oldest ordering was adequate
1126 	 * previously, but reversing the order for restore_op actions is
1127 	 * necessary if later-added ctxops depends on earlier ones.
1128 	 *
1129 	 * One example of such a dependency:  Hypervisor software handling the
1130 	 * guest FPU expects that it save FPU state prior to host FPU handling
1131 	 * and consequently handle the guest logic _after_ the host FPU has
1132 	 * been restored.
1133 	 *
1134 	 * The t_ctx member points to the most recently added ctxop or is NULL
1135 	 * if no ctxops are associated with the thread.  The 'next' pointers
1136 	 * form a loop of the ctxops in newest-to-oldest order.  The 'prev'
1137 	 * pointers form a loop in the reverse direction, where t_ctx->prev is
1138 	 * the oldest entry associated with the thread.
1139 	 *
1140 	 * The protection of kpreempt_disable is required to safely perform the
1141 	 * list insertion, since there are inconsistent states between some of
1142 	 * the pointer assignments.
1143 	 */
1144 	kpreempt_disable();
1145 	if (t->t_ctx == NULL) {
1146 		ctx->next = ctx;
1147 		ctx->prev = ctx;
1148 	} else {
1149 		struct ctxop *head = t->t_ctx, *tail = t->t_ctx->prev;
1150 
1151 		ctx->next = head;
1152 		ctx->prev = tail;
1153 		head->prev = ctx;
1154 		tail->next = ctx;
1155 	}
1156 	t->t_ctx = ctx;
1157 	kpreempt_enable();
1158 }
1159 
1160 void
1161 ctxop_detach(kthread_t *t, struct ctxop *ctx)
1162 {
1163 	/*
1164 	 * The incoming kthread_t (which is the thread for which the
1165 	 * context ops will be detached) should be one of the following:
1166 	 *
1167 	 * a) the current thread,
1168 	 *
1169 	 * b) a thread of a process that's being forked (SIDL),
1170 	 *
1171 	 * c) a thread that belongs to the same process as the current
1172 	 *    thread and for which the current thread is the agent thread,
1173 	 *
1174 	 * d) a thread that is TS_STOPPED which is indicative of it
1175 	 *    being (if curthread is not an agent) a thread being created
1176 	 *    as part of an lwp creation.
1177 	 */
1178 	ASSERT(t == curthread || ttoproc(t)->p_stat == SIDL ||
1179 	    ttoproc(t)->p_agenttp == curthread || t->t_state == TS_STOPPED);
1180 
1181 	/*
1182 	 * Serialize modifications to t->t_ctx to prevent the agent thread
1183 	 * and the target thread from racing with each other during lwp exit.
1184 	 */
1185 	mutex_enter(&t->t_ctx_lock);
1186 	kpreempt_disable();
1187 
1188 	VERIFY(t->t_ctx != NULL);
1189 
1190 #ifdef	DEBUG
1191 	/* Check that provided `ctx` is actually present in the t_ctx chain */
1192 	struct ctxop *head, *cur;
1193 	head = cur = t->t_ctx;
1194 	for (;;) {
1195 		if (cur == ctx) {
1196 			break;
1197 		}
1198 		cur = cur->next;
1199 		/* If we wrap, having not found `ctx`, this assert will fail */
1200 		ASSERT3P(cur, !=, head);
1201 	}
1202 #endif /* DEBUG */
1203 
1204 	ctxop_detach_chain(t, ctx);
1205 
1206 	mutex_exit(&t->t_ctx_lock);
1207 	kpreempt_enable();
1208 }
1209 
1210 void
1211 ctxop_install(kthread_t *t, const struct ctxop_template *ct, void *arg)
1212 {
1213 	ctxop_attach(t, ctxop_allocate(ct, arg));
1214 }
1215 
1216 int
1217 ctxop_remove(kthread_t *t, const struct ctxop_template *ct, void *arg)
1218 {
1219 	struct ctxop *ctx;
1220 
1221 	/*
1222 	 * ctxop_remove() shares the same requirements for the acted-upon thread
1223 	 * as ctxop_detach()
1224 	 */
1225 	ASSERT(t == curthread || ttoproc(t)->p_stat == SIDL ||
1226 	    ttoproc(t)->p_agenttp == curthread || t->t_state == TS_STOPPED);
1227 
1228 	/*
1229 	 * Serialize modifications to t->t_ctx to prevent the agent thread
1230 	 * and the target thread from racing with each other during lwp exit.
1231 	 */
1232 	mutex_enter(&t->t_ctx_lock);
1233 	kpreempt_disable();
1234 
1235 	ctx = ctxop_find_by_tmpl(t, ct, arg);
1236 	if (ctx != NULL) {
1237 		ctxop_detach_chain(t, ctx);
1238 		ctxop_free(ctx);
1239 	}
1240 
1241 	mutex_exit(&t->t_ctx_lock);
1242 	kpreempt_enable();
1243 
1244 	if (ctx != NULL) {
1245 		return (1);
1246 	}
1247 	return (0);
1248 }
1249 
1250 void
1251 savectx(kthread_t *t)
1252 {
1253 	ASSERT(t == curthread);
1254 
1255 	if (t->t_ctx != NULL) {
1256 		struct ctxop *ctx, *head;
1257 
1258 		/* Forward traversal */
1259 		ctx = head = t->t_ctx;
1260 		do {
1261 			if (ctx->save_op != NULL) {
1262 				ctx->save_ts = gethrtime_unscaled();
1263 				(ctx->save_op)(ctx->arg);
1264 			}
1265 			ctx = ctx->next;
1266 		} while (ctx != head);
1267 	}
1268 }
1269 
1270 void
1271 restorectx(kthread_t *t)
1272 {
1273 	ASSERT(t == curthread);
1274 
1275 	if (t->t_ctx != NULL) {
1276 		struct ctxop *ctx, *tail;
1277 
1278 		/* Backward traversal (starting at the tail) */
1279 		ctx = tail = t->t_ctx->prev;
1280 		do {
1281 			if (ctx->restore_op != NULL) {
1282 				ctx->restore_ts = gethrtime_unscaled();
1283 				(ctx->restore_op)(ctx->arg);
1284 			}
1285 			ctx = ctx->prev;
1286 		} while (ctx != tail);
1287 	}
1288 }
1289 
1290 void
1291 forkctx(kthread_t *t, kthread_t *ct)
1292 {
1293 	if (t->t_ctx != NULL) {
1294 		struct ctxop *ctx, *head;
1295 
1296 		/* Forward traversal */
1297 		ctx = head = t->t_ctx;
1298 		do {
1299 			if (ctx->fork_op != NULL) {
1300 				(ctx->fork_op)(t, ct);
1301 			}
1302 			ctx = ctx->next;
1303 		} while (ctx != head);
1304 	}
1305 }
1306 
1307 /*
1308  * Note that this operator is only invoked via the _lwp_create
1309  * system call.  The system may have other reasons to create lwps
1310  * e.g. the agent lwp or the doors unreferenced lwp.
1311  */
1312 void
1313 lwp_createctx(kthread_t *t, kthread_t *ct)
1314 {
1315 	if (t->t_ctx != NULL) {
1316 		struct ctxop *ctx, *head;
1317 
1318 		/* Forward traversal */
1319 		ctx = head = t->t_ctx;
1320 		do {
1321 			if (ctx->lwp_create_op != NULL) {
1322 				(ctx->lwp_create_op)(t, ct);
1323 			}
1324 			ctx = ctx->next;
1325 		} while (ctx != head);
1326 	}
1327 }
1328 
1329 /*
1330  * exitctx is called from thread_exit() and lwp_exit() to perform any actions
1331  * needed when the thread/LWP leaves the processor for the last time. This
1332  * routine is not intended to deal with freeing memory; freectx() is used for
1333  * that purpose during thread_free(). This routine is provided to allow for
1334  * clean-up that can't wait until thread_free().
1335  */
1336 void
1337 exitctx(kthread_t *t)
1338 {
1339 	if (t->t_ctx != NULL) {
1340 		struct ctxop *ctx, *head;
1341 
1342 		/* Forward traversal */
1343 		ctx = head = t->t_ctx;
1344 		do {
1345 			if (ctx->exit_op != NULL) {
1346 				(ctx->exit_op)(t);
1347 			}
1348 			ctx = ctx->next;
1349 		} while (ctx != head);
1350 	}
1351 }
1352 
1353 /*
1354  * freectx is called from thread_free() and exec() to get
1355  * rid of old thread context ops.
1356  */
1357 void
1358 freectx(kthread_t *t, int isexec)
1359 {
1360 	kpreempt_disable();
1361 	if (t->t_ctx != NULL) {
1362 		struct ctxop *ctx, *head;
1363 
1364 		ctx = head = t->t_ctx;
1365 		t->t_ctx = NULL;
1366 		do {
1367 			struct ctxop *next = ctx->next;
1368 
1369 			if (ctx->free_op != NULL) {
1370 				(ctx->free_op)(ctx->arg, isexec);
1371 			}
1372 			kmem_free(ctx, sizeof (struct ctxop));
1373 			ctx = next;
1374 		} while (ctx != head);
1375 	}
1376 	kpreempt_enable();
1377 }
1378 
1379 /*
1380  * freectx_ctx is called from lwp_create() when lwp is reused from
1381  * lwp_deathrow and its thread structure is added to thread_deathrow.
1382  * The thread structure to which this ctx was attached may be already
1383  * freed by the thread reaper so free_op implementations shouldn't rely
1384  * on thread structure to which this ctx was attached still being around.
1385  */
1386 void
1387 freectx_ctx(struct ctxop *ctx)
1388 {
1389 	struct ctxop *head = ctx;
1390 
1391 	ASSERT(ctx != NULL);
1392 
1393 	kpreempt_disable();
1394 
1395 	head = ctx;
1396 	do {
1397 		struct ctxop *next = ctx->next;
1398 
1399 		if (ctx->free_op != NULL) {
1400 			(ctx->free_op)(ctx->arg, 0);
1401 		}
1402 		kmem_free(ctx, sizeof (struct ctxop));
1403 		ctx = next;
1404 	} while (ctx != head);
1405 	kpreempt_enable();
1406 }
1407 
1408 /*
1409  * Set the thread running; arrange for it to be swapped in if necessary.
1410  */
1411 void
1412 setrun_locked(kthread_t *t)
1413 {
1414 	ASSERT(THREAD_LOCK_HELD(t));
1415 	if (t->t_state == TS_SLEEP) {
1416 		/*
1417 		 * Take off sleep queue.
1418 		 */
1419 		SOBJ_UNSLEEP(t->t_sobj_ops, t);
1420 	} else if (t->t_state & (TS_RUN | TS_ONPROC)) {
1421 		/*
1422 		 * Already on dispatcher queue.
1423 		 */
1424 		return;
1425 	} else if (t->t_state == TS_WAIT) {
1426 		waitq_setrun(t);
1427 	} else if (t->t_state == TS_STOPPED) {
1428 		/*
1429 		 * All of the sending of SIGCONT (TC_XSTART) and /proc
1430 		 * (TC_PSTART) and lwp_continue() (TC_CSTART) must have
1431 		 * requested that the thread be run.
1432 		 * Just calling setrun() is not sufficient to set a stopped
1433 		 * thread running.  TP_TXSTART is always set if the thread
1434 		 * is not stopped by a jobcontrol stop signal.
1435 		 * TP_TPSTART is always set if /proc is not controlling it.
1436 		 * TP_TCSTART is always set if lwp_suspend() didn't stop it.
1437 		 * The thread won't be stopped unless one of these
1438 		 * three mechanisms did it.
1439 		 *
1440 		 * These flags must be set before calling setrun_locked(t).
1441 		 * They can't be passed as arguments because the streams
1442 		 * code calls setrun() indirectly and the mechanism for
1443 		 * doing so admits only one argument.  Note that the
1444 		 * thread must be locked in order to change t_schedflags.
1445 		 */
1446 		if ((t->t_schedflag & TS_ALLSTART) != TS_ALLSTART)
1447 			return;
1448 		/*
1449 		 * Process is no longer stopped (a thread is running).
1450 		 */
1451 		t->t_whystop = 0;
1452 		t->t_whatstop = 0;
1453 		/*
1454 		 * Strictly speaking, we do not have to clear these
1455 		 * flags here; they are cleared on entry to stop().
1456 		 * However, they are confusing when doing kernel
1457 		 * debugging or when they are revealed by ps(1).
1458 		 */
1459 		t->t_schedflag &= ~TS_ALLSTART;
1460 		THREAD_TRANSITION(t);	/* drop stopped-thread lock */
1461 		ASSERT(t->t_lockp == &transition_lock);
1462 		ASSERT(t->t_wchan0 == NULL && t->t_wchan == NULL);
1463 		/*
1464 		 * Let the class put the process on the dispatcher queue.
1465 		 */
1466 		CL_SETRUN(t);
1467 	}
1468 }
1469 
1470 void
1471 setrun(kthread_t *t)
1472 {
1473 	thread_lock(t);
1474 	setrun_locked(t);
1475 	thread_unlock(t);
1476 }
1477 
1478 /*
1479  * Unpin an interrupted thread.
1480  *	When an interrupt occurs, the interrupt is handled on the stack
1481  *	of an interrupt thread, taken from a pool linked to the CPU structure.
1482  *
1483  *	When swtch() is switching away from an interrupt thread because it
1484  *	blocked or was preempted, this routine is called to complete the
1485  *	saving of the interrupted thread state, and returns the interrupted
1486  *	thread pointer so it may be resumed.
1487  *
1488  *	Called by swtch() only at high spl.
1489  */
1490 kthread_t *
1491 thread_unpin()
1492 {
1493 	kthread_t	*t = curthread;	/* current thread */
1494 	kthread_t	*itp;		/* interrupted thread */
1495 	int		i;		/* interrupt level */
1496 	extern int	intr_passivate();
1497 
1498 	ASSERT(t->t_intr != NULL);
1499 
1500 	itp = t->t_intr;		/* interrupted thread */
1501 	t->t_intr = NULL;		/* clear interrupt ptr */
1502 
1503 	smt_end_intr();
1504 
1505 	/*
1506 	 * Get state from interrupt thread for the one
1507 	 * it interrupted.
1508 	 */
1509 
1510 	i = intr_passivate(t, itp);
1511 
1512 	TRACE_5(TR_FAC_INTR, TR_INTR_PASSIVATE,
1513 	    "intr_passivate:level %d curthread %p (%T) ithread %p (%T)",
1514 	    i, t, t, itp, itp);
1515 
1516 	/*
1517 	 * Dissociate the current thread from the interrupted thread's LWP.
1518 	 */
1519 	t->t_lwp = NULL;
1520 
1521 	/*
1522 	 * Interrupt handlers above the level that spinlocks block must
1523 	 * not block.
1524 	 */
1525 #if DEBUG
1526 	if (i < 0 || i > LOCK_LEVEL)
1527 		cmn_err(CE_PANIC, "thread_unpin: ipl out of range %x", i);
1528 #endif
1529 
1530 	/*
1531 	 * Compute the CPU's base interrupt level based on the active
1532 	 * interrupts.
1533 	 */
1534 	ASSERT(CPU->cpu_intr_actv & (1 << i));
1535 	set_base_spl();
1536 
1537 	return (itp);
1538 }
1539 
1540 /*
1541  * Create and initialize an interrupt thread.
1542  *	Returns non-zero on error.
1543  *	Called at spl7() or better.
1544  */
1545 void
1546 thread_create_intr(struct cpu *cp)
1547 {
1548 	kthread_t *tp;
1549 
1550 	tp = thread_create(NULL, 0,
1551 	    (void (*)())thread_create_intr, NULL, 0, &p0, TS_ONPROC, 0);
1552 
1553 	/*
1554 	 * Set the thread in the TS_FREE state.  The state will change
1555 	 * to TS_ONPROC only while the interrupt is active.  Think of these
1556 	 * as being on a private free list for the CPU.  Being TS_FREE keeps
1557 	 * inactive interrupt threads out of debugger thread lists.
1558 	 *
1559 	 * We cannot call thread_create with TS_FREE because of the current
1560 	 * checks there for ONPROC.  Fix this when thread_create takes flags.
1561 	 */
1562 	THREAD_FREEINTR(tp, cp);
1563 
1564 	/*
1565 	 * Nobody should ever reference the credentials of an interrupt
1566 	 * thread so make it NULL to catch any such references.
1567 	 */
1568 	tp->t_cred = NULL;
1569 	tp->t_flag |= T_INTR_THREAD;
1570 	tp->t_cpu = cp;
1571 	tp->t_bound_cpu = cp;
1572 	tp->t_disp_queue = cp->cpu_disp;
1573 	tp->t_affinitycnt = 1;
1574 	tp->t_preempt = 1;
1575 
1576 	/*
1577 	 * Don't make a user-requested binding on this thread so that
1578 	 * the processor can be offlined.
1579 	 */
1580 	tp->t_bind_cpu = PBIND_NONE;	/* no USER-requested binding */
1581 	tp->t_bind_pset = PS_NONE;
1582 
1583 #if defined(__x86)
1584 	tp->t_stk -= STACK_ALIGN;
1585 	*(tp->t_stk) = 0;		/* terminate intr thread stack */
1586 #endif
1587 
1588 	/*
1589 	 * Link onto CPU's interrupt pool.
1590 	 */
1591 	tp->t_link = cp->cpu_intr_thread;
1592 	cp->cpu_intr_thread = tp;
1593 }
1594 
1595 /*
1596  * TSD -- THREAD SPECIFIC DATA
1597  */
1598 static kmutex_t		tsd_mutex;	 /* linked list spin lock */
1599 static uint_t		tsd_nkeys;	 /* size of destructor array */
1600 /* per-key destructor funcs */
1601 static void		(**tsd_destructor)(void *);
1602 /* list of tsd_thread's */
1603 static struct tsd_thread	*tsd_list;
1604 
1605 /*
1606  * Default destructor
1607  *	Needed because NULL destructor means that the key is unused
1608  */
1609 /* ARGSUSED */
1610 void
1611 tsd_defaultdestructor(void *value)
1612 {}
1613 
1614 /*
1615  * Create a key (index into per thread array)
1616  *	Locks out tsd_create, tsd_destroy, and tsd_exit
1617  *	May allocate memory with lock held
1618  */
1619 void
1620 tsd_create(uint_t *keyp, void (*destructor)(void *))
1621 {
1622 	int	i;
1623 	uint_t	nkeys;
1624 
1625 	/*
1626 	 * if key is allocated, do nothing
1627 	 */
1628 	mutex_enter(&tsd_mutex);
1629 	if (*keyp) {
1630 		mutex_exit(&tsd_mutex);
1631 		return;
1632 	}
1633 	/*
1634 	 * find an unused key
1635 	 */
1636 	if (destructor == NULL)
1637 		destructor = tsd_defaultdestructor;
1638 
1639 	for (i = 0; i < tsd_nkeys; ++i)
1640 		if (tsd_destructor[i] == NULL)
1641 			break;
1642 
1643 	/*
1644 	 * if no unused keys, increase the size of the destructor array
1645 	 */
1646 	if (i == tsd_nkeys) {
1647 		if ((nkeys = (tsd_nkeys << 1)) == 0)
1648 			nkeys = 1;
1649 		tsd_destructor =
1650 		    (void (**)(void *))tsd_realloc((void *)tsd_destructor,
1651 		    (size_t)(tsd_nkeys * sizeof (void (*)(void *))),
1652 		    (size_t)(nkeys * sizeof (void (*)(void *))));
1653 		tsd_nkeys = nkeys;
1654 	}
1655 
1656 	/*
1657 	 * allocate the next available unused key
1658 	 */
1659 	tsd_destructor[i] = destructor;
1660 	*keyp = i + 1;
1661 	mutex_exit(&tsd_mutex);
1662 }
1663 
1664 /*
1665  * Destroy a key -- this is for unloadable modules
1666  *
1667  * Assumes that the caller is preventing tsd_set and tsd_get
1668  * Locks out tsd_create, tsd_destroy, and tsd_exit
1669  * May free memory with lock held
1670  */
1671 void
1672 tsd_destroy(uint_t *keyp)
1673 {
1674 	uint_t key;
1675 	struct tsd_thread *tsd;
1676 
1677 	/*
1678 	 * protect the key namespace and our destructor lists
1679 	 */
1680 	mutex_enter(&tsd_mutex);
1681 	key = *keyp;
1682 	*keyp = 0;
1683 
1684 	ASSERT(key <= tsd_nkeys);
1685 
1686 	/*
1687 	 * if the key is valid
1688 	 */
1689 	if (key != 0) {
1690 		uint_t k = key - 1;
1691 		/*
1692 		 * for every thread with TSD, call key's destructor
1693 		 */
1694 		for (tsd = tsd_list; tsd; tsd = tsd->ts_next) {
1695 			/*
1696 			 * no TSD for key in this thread
1697 			 */
1698 			if (key > tsd->ts_nkeys)
1699 				continue;
1700 			/*
1701 			 * call destructor for key
1702 			 */
1703 			if (tsd->ts_value[k] && tsd_destructor[k])
1704 				(*tsd_destructor[k])(tsd->ts_value[k]);
1705 			/*
1706 			 * reset value for key
1707 			 */
1708 			tsd->ts_value[k] = NULL;
1709 		}
1710 		/*
1711 		 * actually free the key (NULL destructor == unused)
1712 		 */
1713 		tsd_destructor[k] = NULL;
1714 	}
1715 
1716 	mutex_exit(&tsd_mutex);
1717 }
1718 
1719 /*
1720  * Quickly return the per thread value that was stored with the specified key
1721  * Assumes the caller is protecting key from tsd_create and tsd_destroy
1722  */
1723 void *
1724 tsd_get(uint_t key)
1725 {
1726 	return (tsd_agent_get(curthread, key));
1727 }
1728 
1729 /*
1730  * Set a per thread value indexed with the specified key
1731  */
1732 int
1733 tsd_set(uint_t key, void *value)
1734 {
1735 	return (tsd_agent_set(curthread, key, value));
1736 }
1737 
1738 /*
1739  * Like tsd_get(), except that the agent lwp can get the tsd of
1740  * another thread in the same process (the agent thread only runs when the
1741  * process is completely stopped by /proc), or syslwp is creating a new lwp.
1742  */
1743 void *
1744 tsd_agent_get(kthread_t *t, uint_t key)
1745 {
1746 	struct tsd_thread *tsd = t->t_tsd;
1747 
1748 	ASSERT(t == curthread ||
1749 	    ttoproc(t)->p_agenttp == curthread || t->t_state == TS_STOPPED);
1750 
1751 	if (key && tsd != NULL && key <= tsd->ts_nkeys)
1752 		return (tsd->ts_value[key - 1]);
1753 	return (NULL);
1754 }
1755 
1756 /*
1757  * Like tsd_set(), except that the agent lwp can set the tsd of
1758  * another thread in the same process, or syslwp can set the tsd
1759  * of a thread it's in the middle of creating.
1760  *
1761  * Assumes the caller is protecting key from tsd_create and tsd_destroy
1762  * May lock out tsd_destroy (and tsd_create), may allocate memory with
1763  * lock held
1764  */
1765 int
1766 tsd_agent_set(kthread_t *t, uint_t key, void *value)
1767 {
1768 	struct tsd_thread *tsd = t->t_tsd;
1769 
1770 	ASSERT(t == curthread ||
1771 	    ttoproc(t)->p_agenttp == curthread || t->t_state == TS_STOPPED);
1772 
1773 	if (key == 0)
1774 		return (EINVAL);
1775 	if (tsd == NULL)
1776 		tsd = t->t_tsd = kmem_zalloc(sizeof (*tsd), KM_SLEEP);
1777 	if (key <= tsd->ts_nkeys) {
1778 		tsd->ts_value[key - 1] = value;
1779 		return (0);
1780 	}
1781 
1782 	ASSERT(key <= tsd_nkeys);
1783 
1784 	/*
1785 	 * lock out tsd_destroy()
1786 	 */
1787 	mutex_enter(&tsd_mutex);
1788 	if (tsd->ts_nkeys == 0) {
1789 		/*
1790 		 * Link onto list of threads with TSD
1791 		 */
1792 		if ((tsd->ts_next = tsd_list) != NULL)
1793 			tsd_list->ts_prev = tsd;
1794 		tsd_list = tsd;
1795 	}
1796 
1797 	/*
1798 	 * Allocate thread local storage and set the value for key
1799 	 */
1800 	tsd->ts_value = tsd_realloc(tsd->ts_value,
1801 	    tsd->ts_nkeys * sizeof (void *),
1802 	    key * sizeof (void *));
1803 	tsd->ts_nkeys = key;
1804 	tsd->ts_value[key - 1] = value;
1805 	mutex_exit(&tsd_mutex);
1806 
1807 	return (0);
1808 }
1809 
1810 
1811 /*
1812  * Return the per thread value that was stored with the specified key
1813  *	If necessary, create the key and the value
1814  *	Assumes the caller is protecting *keyp from tsd_destroy
1815  */
1816 void *
1817 tsd_getcreate(uint_t *keyp, void (*destroy)(void *), void *(*allocate)(void))
1818 {
1819 	void *value;
1820 	uint_t key = *keyp;
1821 	struct tsd_thread *tsd = curthread->t_tsd;
1822 
1823 	if (tsd == NULL)
1824 		tsd = curthread->t_tsd = kmem_zalloc(sizeof (*tsd), KM_SLEEP);
1825 	if (key && key <= tsd->ts_nkeys && (value = tsd->ts_value[key - 1]))
1826 		return (value);
1827 	if (key == 0)
1828 		tsd_create(keyp, destroy);
1829 	(void) tsd_set(*keyp, value = (*allocate)());
1830 
1831 	return (value);
1832 }
1833 
1834 /*
1835  * Called from thread_exit() to run the destructor function for each tsd
1836  *	Locks out tsd_create and tsd_destroy
1837  *	Assumes that the destructor *DOES NOT* use tsd
1838  */
1839 void
1840 tsd_exit(void)
1841 {
1842 	int i;
1843 	struct tsd_thread *tsd = curthread->t_tsd;
1844 
1845 	if (tsd == NULL)
1846 		return;
1847 
1848 	if (tsd->ts_nkeys == 0) {
1849 		kmem_free(tsd, sizeof (*tsd));
1850 		curthread->t_tsd = NULL;
1851 		return;
1852 	}
1853 
1854 	/*
1855 	 * lock out tsd_create and tsd_destroy, call
1856 	 * the destructor, and mark the value as destroyed.
1857 	 */
1858 	mutex_enter(&tsd_mutex);
1859 
1860 	for (i = 0; i < tsd->ts_nkeys; i++) {
1861 		if (tsd->ts_value[i] && tsd_destructor[i])
1862 			(*tsd_destructor[i])(tsd->ts_value[i]);
1863 		tsd->ts_value[i] = NULL;
1864 	}
1865 
1866 	/*
1867 	 * remove from linked list of threads with TSD
1868 	 */
1869 	if (tsd->ts_next)
1870 		tsd->ts_next->ts_prev = tsd->ts_prev;
1871 	if (tsd->ts_prev)
1872 		tsd->ts_prev->ts_next = tsd->ts_next;
1873 	if (tsd_list == tsd)
1874 		tsd_list = tsd->ts_next;
1875 
1876 	mutex_exit(&tsd_mutex);
1877 
1878 	/*
1879 	 * free up the TSD
1880 	 */
1881 	kmem_free(tsd->ts_value, tsd->ts_nkeys * sizeof (void *));
1882 	kmem_free(tsd, sizeof (struct tsd_thread));
1883 	curthread->t_tsd = NULL;
1884 }
1885 
1886 /*
1887  * realloc
1888  */
1889 static void *
1890 tsd_realloc(void *old, size_t osize, size_t nsize)
1891 {
1892 	void *new;
1893 
1894 	new = kmem_zalloc(nsize, KM_SLEEP);
1895 	if (old) {
1896 		bcopy(old, new, osize);
1897 		kmem_free(old, osize);
1898 	}
1899 	return (new);
1900 }
1901 
1902 /*
1903  * Return non-zero if an interrupt is being serviced.
1904  */
1905 int
1906 servicing_interrupt()
1907 {
1908 	int onintr = 0;
1909 
1910 	/* Are we an interrupt thread */
1911 	if (curthread->t_flag & T_INTR_THREAD)
1912 		return (1);
1913 	/* Are we servicing a high level interrupt? */
1914 	if (CPU_ON_INTR(CPU)) {
1915 		kpreempt_disable();
1916 		onintr = CPU_ON_INTR(CPU);
1917 		kpreempt_enable();
1918 	}
1919 	return (onintr);
1920 }
1921 
1922 
1923 /*
1924  * Change the dispatch priority of a thread in the system.
1925  * Used when raising or lowering a thread's priority.
1926  * (E.g., priority inheritance)
1927  *
1928  * Since threads are queued according to their priority, we
1929  * we must check the thread's state to determine whether it
1930  * is on a queue somewhere. If it is, we've got to:
1931  *
1932  *	o Dequeue the thread.
1933  *	o Change its effective priority.
1934  *	o Enqueue the thread.
1935  *
1936  * Assumptions: The thread whose priority we wish to change
1937  * must be locked before we call thread_change_(e)pri().
1938  * The thread_change(e)pri() function doesn't drop the thread
1939  * lock--that must be done by its caller.
1940  */
1941 void
1942 thread_change_epri(kthread_t *t, pri_t disp_pri)
1943 {
1944 	uint_t	state;
1945 
1946 	ASSERT(THREAD_LOCK_HELD(t));
1947 
1948 	/*
1949 	 * If the inherited priority hasn't actually changed,
1950 	 * just return.
1951 	 */
1952 	if (t->t_epri == disp_pri)
1953 		return;
1954 
1955 	state = t->t_state;
1956 
1957 	/*
1958 	 * If it's not on a queue, change the priority with impunity.
1959 	 */
1960 	if ((state & (TS_SLEEP | TS_RUN | TS_WAIT)) == 0) {
1961 		t->t_epri = disp_pri;
1962 		if (state == TS_ONPROC) {
1963 			cpu_t *cp = t->t_disp_queue->disp_cpu;
1964 
1965 			if (t == cp->cpu_dispthread)
1966 				cp->cpu_dispatch_pri = DISP_PRIO(t);
1967 		}
1968 	} else if (state == TS_SLEEP) {
1969 		/*
1970 		 * Take the thread out of its sleep queue.
1971 		 * Change the inherited priority.
1972 		 * Re-enqueue the thread.
1973 		 * Each synchronization object exports a function
1974 		 * to do this in an appropriate manner.
1975 		 */
1976 		SOBJ_CHANGE_EPRI(t->t_sobj_ops, t, disp_pri);
1977 	} else if (state == TS_WAIT) {
1978 		/*
1979 		 * Re-enqueue a thread on the wait queue if its
1980 		 * effective priority needs to change.
1981 		 */
1982 		if (disp_pri != t->t_epri)
1983 			waitq_change_pri(t, disp_pri);
1984 	} else {
1985 		/*
1986 		 * The thread is on a run queue.
1987 		 * Note: setbackdq() may not put the thread
1988 		 * back on the same run queue where it originally
1989 		 * resided.
1990 		 */
1991 		(void) dispdeq(t);
1992 		t->t_epri = disp_pri;
1993 		setbackdq(t);
1994 	}
1995 	schedctl_set_cidpri(t);
1996 }
1997 
1998 /*
1999  * Function: Change the t_pri field of a thread.
2000  * Side Effects: Adjust the thread ordering on a run queue
2001  *		 or sleep queue, if necessary.
2002  * Returns: 1 if the thread was on a run queue, else 0.
2003  */
2004 int
2005 thread_change_pri(kthread_t *t, pri_t disp_pri, int front)
2006 {
2007 	uint_t	state;
2008 	int	on_rq = 0;
2009 
2010 	ASSERT(THREAD_LOCK_HELD(t));
2011 
2012 	state = t->t_state;
2013 	THREAD_WILLCHANGE_PRI(t, disp_pri);
2014 
2015 	/*
2016 	 * If it's not on a queue, change the priority with impunity.
2017 	 */
2018 	if ((state & (TS_SLEEP | TS_RUN | TS_WAIT)) == 0) {
2019 		t->t_pri = disp_pri;
2020 
2021 		if (state == TS_ONPROC) {
2022 			cpu_t *cp = t->t_disp_queue->disp_cpu;
2023 
2024 			if (t == cp->cpu_dispthread)
2025 				cp->cpu_dispatch_pri = DISP_PRIO(t);
2026 		}
2027 	} else if (state == TS_SLEEP) {
2028 		/*
2029 		 * If the priority has changed, take the thread out of
2030 		 * its sleep queue and change the priority.
2031 		 * Re-enqueue the thread.
2032 		 * Each synchronization object exports a function
2033 		 * to do this in an appropriate manner.
2034 		 */
2035 		if (disp_pri != t->t_pri)
2036 			SOBJ_CHANGE_PRI(t->t_sobj_ops, t, disp_pri);
2037 	} else if (state == TS_WAIT) {
2038 		/*
2039 		 * Re-enqueue a thread on the wait queue if its
2040 		 * priority needs to change.
2041 		 */
2042 		if (disp_pri != t->t_pri)
2043 			waitq_change_pri(t, disp_pri);
2044 	} else {
2045 		/*
2046 		 * The thread is on a run queue.
2047 		 * Note: setbackdq() may not put the thread
2048 		 * back on the same run queue where it originally
2049 		 * resided.
2050 		 *
2051 		 * We still requeue the thread even if the priority
2052 		 * is unchanged to preserve round-robin (and other)
2053 		 * effects between threads of the same priority.
2054 		 */
2055 		on_rq = dispdeq(t);
2056 		ASSERT(on_rq);
2057 		t->t_pri = disp_pri;
2058 		if (front) {
2059 			setfrontdq(t);
2060 		} else {
2061 			setbackdq(t);
2062 		}
2063 	}
2064 	schedctl_set_cidpri(t);
2065 	return (on_rq);
2066 }
2067 
2068 /*
2069  * Tunable kmem_stackinfo is set, fill the kernel thread stack with a
2070  * specific pattern.
2071  */
2072 static void
2073 stkinfo_begin(kthread_t *t)
2074 {
2075 	caddr_t	start;	/* stack start */
2076 	caddr_t	end;	/* stack end  */
2077 	uint64_t *ptr;	/* pattern pointer */
2078 
2079 	/*
2080 	 * Stack grows up or down, see thread_create(),
2081 	 * compute stack memory area start and end (start < end).
2082 	 */
2083 	if (t->t_stk > t->t_stkbase) {
2084 		/* stack grows down */
2085 		start = t->t_stkbase;
2086 		end = t->t_stk;
2087 	} else {
2088 		/* stack grows up */
2089 		start = t->t_stk;
2090 		end = t->t_stkbase;
2091 	}
2092 
2093 	/*
2094 	 * Stackinfo pattern size is 8 bytes. Ensure proper 8 bytes
2095 	 * alignement for start and end in stack area boundaries
2096 	 * (protection against corrupt t_stkbase/t_stk data).
2097 	 */
2098 	if ((((uintptr_t)start) & 0x7) != 0) {
2099 		start = (caddr_t)((((uintptr_t)start) & (~0x7)) + 8);
2100 	}
2101 	end = (caddr_t)(((uintptr_t)end) & (~0x7));
2102 
2103 	if ((end <= start) || (end - start) > (1024 * 1024)) {
2104 		/* negative or stack size > 1 meg, assume bogus */
2105 		return;
2106 	}
2107 
2108 	/* fill stack area with a pattern (instead of zeros) */
2109 	ptr = (uint64_t *)((void *)start);
2110 	while (ptr < (uint64_t *)((void *)end)) {
2111 		*ptr++ = KMEM_STKINFO_PATTERN;
2112 	}
2113 }
2114 
2115 
2116 /*
2117  * Tunable kmem_stackinfo is set, create stackinfo log if doesn't already exist,
2118  * compute the percentage of kernel stack really used, and set in the log
2119  * if it's the latest highest percentage.
2120  */
2121 static void
2122 stkinfo_end(kthread_t *t)
2123 {
2124 	caddr_t	start;	/* stack start */
2125 	caddr_t	end;	/* stack end  */
2126 	uint64_t *ptr;	/* pattern pointer */
2127 	size_t stksz;	/* stack size */
2128 	size_t smallest = 0;
2129 	size_t percent = 0;
2130 	uint_t index = 0;
2131 	uint_t i;
2132 	static size_t smallest_percent = (size_t)-1;
2133 	static uint_t full = 0;
2134 
2135 	/* create the stackinfo log, if doesn't already exist */
2136 	mutex_enter(&kmem_stkinfo_lock);
2137 	if (kmem_stkinfo_log == NULL) {
2138 		kmem_stkinfo_log = (kmem_stkinfo_t *)
2139 		    kmem_zalloc(KMEM_STKINFO_LOG_SIZE *
2140 		    (sizeof (kmem_stkinfo_t)), KM_NOSLEEP);
2141 		if (kmem_stkinfo_log == NULL) {
2142 			mutex_exit(&kmem_stkinfo_lock);
2143 			return;
2144 		}
2145 	}
2146 	mutex_exit(&kmem_stkinfo_lock);
2147 
2148 	/*
2149 	 * Stack grows up or down, see thread_create(),
2150 	 * compute stack memory area start and end (start < end).
2151 	 */
2152 	if (t->t_stk > t->t_stkbase) {
2153 		/* stack grows down */
2154 		start = t->t_stkbase;
2155 		end = t->t_stk;
2156 	} else {
2157 		/* stack grows up */
2158 		start = t->t_stk;
2159 		end = t->t_stkbase;
2160 	}
2161 
2162 	/* stack size as found in kthread_t */
2163 	stksz = end - start;
2164 
2165 	/*
2166 	 * Stackinfo pattern size is 8 bytes. Ensure proper 8 bytes
2167 	 * alignement for start and end in stack area boundaries
2168 	 * (protection against corrupt t_stkbase/t_stk data).
2169 	 */
2170 	if ((((uintptr_t)start) & 0x7) != 0) {
2171 		start = (caddr_t)((((uintptr_t)start) & (~0x7)) + 8);
2172 	}
2173 	end = (caddr_t)(((uintptr_t)end) & (~0x7));
2174 
2175 	if ((end <= start) || (end - start) > (1024 * 1024)) {
2176 		/* negative or stack size > 1 meg, assume bogus */
2177 		return;
2178 	}
2179 
2180 	/* search until no pattern in the stack */
2181 	if (t->t_stk > t->t_stkbase) {
2182 		/* stack grows down */
2183 #if defined(__x86)
2184 		/*
2185 		 * 6 longs are pushed on stack, see thread_load(). Skip
2186 		 * them, so if kthread has never run, percent is zero.
2187 		 * 8 bytes alignement is preserved for a 32 bit kernel,
2188 		 * 6 x 4 = 24, 24 is a multiple of 8.
2189 		 *
2190 		 */
2191 		end -= (6 * sizeof (long));
2192 #endif
2193 		ptr = (uint64_t *)((void *)start);
2194 		while (ptr < (uint64_t *)((void *)end)) {
2195 			if (*ptr != KMEM_STKINFO_PATTERN) {
2196 				percent = stkinfo_percent(end,
2197 				    start, (caddr_t)ptr);
2198 				break;
2199 			}
2200 			ptr++;
2201 		}
2202 	} else {
2203 		/* stack grows up */
2204 		ptr = (uint64_t *)((void *)end);
2205 		ptr--;
2206 		while (ptr >= (uint64_t *)((void *)start)) {
2207 			if (*ptr != KMEM_STKINFO_PATTERN) {
2208 				percent = stkinfo_percent(start,
2209 				    end, (caddr_t)ptr);
2210 				break;
2211 			}
2212 			ptr--;
2213 		}
2214 	}
2215 
2216 	DTRACE_PROBE3(stack__usage, kthread_t *, t,
2217 	    size_t, stksz, size_t, percent);
2218 
2219 	if (percent == 0) {
2220 		return;
2221 	}
2222 
2223 	mutex_enter(&kmem_stkinfo_lock);
2224 	if (full == KMEM_STKINFO_LOG_SIZE && percent < smallest_percent) {
2225 		/*
2226 		 * The log is full and already contains the highest values
2227 		 */
2228 		mutex_exit(&kmem_stkinfo_lock);
2229 		return;
2230 	}
2231 
2232 	/* keep a log of the highest used stack */
2233 	for (i = 0; i < KMEM_STKINFO_LOG_SIZE; i++) {
2234 		if (kmem_stkinfo_log[i].percent == 0) {
2235 			index = i;
2236 			full++;
2237 			break;
2238 		}
2239 		if (smallest == 0) {
2240 			smallest = kmem_stkinfo_log[i].percent;
2241 			index = i;
2242 			continue;
2243 		}
2244 		if (kmem_stkinfo_log[i].percent < smallest) {
2245 			smallest = kmem_stkinfo_log[i].percent;
2246 			index = i;
2247 		}
2248 	}
2249 
2250 	if (percent >= kmem_stkinfo_log[index].percent) {
2251 		kmem_stkinfo_log[index].kthread = (caddr_t)t;
2252 		kmem_stkinfo_log[index].t_startpc = (caddr_t)t->t_startpc;
2253 		kmem_stkinfo_log[index].start = start;
2254 		kmem_stkinfo_log[index].stksz = stksz;
2255 		kmem_stkinfo_log[index].percent = percent;
2256 		kmem_stkinfo_log[index].t_tid = t->t_tid;
2257 		kmem_stkinfo_log[index].cmd[0] = '\0';
2258 		if (t->t_tid != 0) {
2259 			stksz = strlen((t->t_procp)->p_user.u_comm);
2260 			if (stksz >= KMEM_STKINFO_STR_SIZE) {
2261 				stksz = KMEM_STKINFO_STR_SIZE - 1;
2262 				kmem_stkinfo_log[index].cmd[stksz] = '\0';
2263 			} else {
2264 				stksz += 1;
2265 			}
2266 			(void) memcpy(kmem_stkinfo_log[index].cmd,
2267 			    (t->t_procp)->p_user.u_comm, stksz);
2268 		}
2269 		if (percent < smallest_percent) {
2270 			smallest_percent = percent;
2271 		}
2272 	}
2273 	mutex_exit(&kmem_stkinfo_lock);
2274 }
2275 
2276 /*
2277  * Tunable kmem_stackinfo is set, compute stack utilization percentage.
2278  */
2279 static size_t
2280 stkinfo_percent(caddr_t t_stk, caddr_t t_stkbase, caddr_t sp)
2281 {
2282 	size_t percent;
2283 	size_t s;
2284 
2285 	if (t_stk > t_stkbase) {
2286 		/* stack grows down */
2287 		if (sp > t_stk) {
2288 			return (0);
2289 		}
2290 		if (sp < t_stkbase) {
2291 			return (100);
2292 		}
2293 		percent = t_stk - sp + 1;
2294 		s = t_stk - t_stkbase + 1;
2295 	} else {
2296 		/* stack grows up */
2297 		if (sp < t_stk) {
2298 			return (0);
2299 		}
2300 		if (sp > t_stkbase) {
2301 			return (100);
2302 		}
2303 		percent = sp - t_stk + 1;
2304 		s = t_stkbase - t_stk + 1;
2305 	}
2306 	percent = ((100 * percent) / s) + 1;
2307 	if (percent > 100) {
2308 		percent = 100;
2309 	}
2310 	return (percent);
2311 }
2312 
2313 /*
2314  * NOTE: This will silently truncate a name > THREAD_NAME_MAX - 1 characters
2315  * long.  It is expected that callers (acting on behalf of userland clients)
2316  * will perform any required checks to return the correct error semantics.
2317  * It is also expected callers on behalf of userland clients have done
2318  * any necessary permission checks.
2319  */
2320 int
2321 thread_setname(kthread_t *t, const char *name)
2322 {
2323 	char *buf = NULL;
2324 
2325 	/*
2326 	 * We optimistically assume that a thread's name will only be set
2327 	 * once and so allocate memory in preparation of setting t_name.
2328 	 * If it turns out a name has already been set, we just discard (free)
2329 	 * the buffer we just allocated and reuse the current buffer
2330 	 * (as all should be THREAD_NAME_MAX large).
2331 	 *
2332 	 * Such an arrangement means over the lifetime of a kthread_t, t_name
2333 	 * is either NULL or has one value (the address of the buffer holding
2334 	 * the current thread name).   The assumption is that most kthread_t
2335 	 * instances will not have a name assigned, so dynamically allocating
2336 	 * the memory should minimize the footprint of this feature, but by
2337 	 * having the buffer persist for the life of the thread, it simplifies
2338 	 * usage in highly constrained situations (e.g. dtrace).
2339 	 */
2340 	if (name != NULL && name[0] != '\0') {
2341 		for (size_t i = 0; name[i] != '\0'; i++) {
2342 			if (!isprint(name[i]))
2343 				return (EINVAL);
2344 		}
2345 
2346 		buf = kmem_zalloc(THREAD_NAME_MAX, KM_SLEEP);
2347 		(void) strlcpy(buf, name, THREAD_NAME_MAX);
2348 	}
2349 
2350 	mutex_enter(&ttoproc(t)->p_lock);
2351 	if (t->t_name == NULL) {
2352 		t->t_name = buf;
2353 	} else {
2354 		if (buf != NULL) {
2355 			(void) strlcpy(t->t_name, name, THREAD_NAME_MAX);
2356 			kmem_free(buf, THREAD_NAME_MAX);
2357 		} else {
2358 			bzero(t->t_name, THREAD_NAME_MAX);
2359 		}
2360 	}
2361 	mutex_exit(&ttoproc(t)->p_lock);
2362 	return (0);
2363 }
2364 
2365 int
2366 thread_vsetname(kthread_t *t, const char *fmt, ...)
2367 {
2368 	char name[THREAD_NAME_MAX];
2369 	va_list va;
2370 	int rc;
2371 
2372 	va_start(va, fmt);
2373 	rc = vsnprintf(name, sizeof (name), fmt, va);
2374 	va_end(va);
2375 
2376 	if (rc < 0)
2377 		return (EINVAL);
2378 
2379 	if (rc >= sizeof (name))
2380 		return (ENAMETOOLONG);
2381 
2382 	return (thread_setname(t, name));
2383 }
2384