../vm/vm_fault.c

Bug Summary

File:	obj-scan-build/../vm/vm_fault.c
Location:	line 724, column 5
Description:	Value stored to 'offset' is never read

Annotated Source Code

1	/*
2	* Mach Operating System
3	* Copyright (c) 1994,1990,1989,1988,1987 Carnegie Mellon University.
4	* Copyright (c) 1993,1994 The University of Utah and
5	* the Computer Systems Laboratory (CSL).
6	* All rights reserved.
7	*
8	* Permission to use, copy, modify and distribute this software and its
9	* documentation is hereby granted, provided that both the copyright
10	* notice and this permission notice appear in all copies of the
11	* software, derivative works or modified versions, and any portions
12	* thereof, and that both notices appear in supporting documentation.
13	*
14	* CARNEGIE MELLON, THE UNIVERSITY OF UTAH AND CSL ALLOW FREE USE OF
15	* THIS SOFTWARE IN ITS "AS IS" CONDITION, AND DISCLAIM ANY LIABILITY
16	* OF ANY KIND FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF
17	* THIS SOFTWARE.
18	*
19	* Carnegie Mellon requests users of this software to return to
20	*
21	* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
22	* School of Computer Science
23	* Carnegie Mellon University
24	* Pittsburgh PA 15213-3890
25	*
26	* any improvements or extensions that they make and grant Carnegie Mellon
27	* the rights to redistribute these changes.
28	*/
29	/*
30	* File: vm_fault.c
31	* Author: Avadis Tevanian, Jr., Michael Wayne Young
32	*
33	* Page fault handling module.
34	*/
35
36	#include <kern/printf.h>
37	#include <vm/vm_fault.h>
38	#include <mach/kern_return.h>
39	#include <mach/message.h> /* for error codes */
40	#include <kern/counters.h>
41	#include <kern/debug.h>
42	#include <kern/thread.h>
43	#include <kern/sched_prim.h>
44	#include <vm/vm_map.h>
45	#include <vm/vm_object.h>
46	#include <vm/vm_page.h>
47	#include <vm/pmap.h>
48	#include <mach/vm_statistics.h>
49	#include <vm/vm_pageout.h>
50	#include <mach/vm_param.h>
51	#include <mach/memory_object.h>
52	#include <vm/memory_object_user.user.h>
53	/* For memory_object_data_{request,unlock} */
54	#include <kern/macro_help.h>
55	#include <kern/slab.h>
56
57	#if MACH_PCSAMPLE1
58	#include <kern/pc_sample.h>
59	#endif
60
61
62
63	/*
64	* State needed by vm_fault_continue.
65	* This is a little hefty to drop directly
66	* into the thread structure.
67	*/
68	typedef struct vm_fault_state {
69	struct vm_map *vmf_map;
70	vm_offset_t vmf_vaddr;
71	vm_prot_t vmf_fault_type;
72	boolean_t vmf_change_wiring;
73	void (*vmf_continuation)();
74	vm_map_version_t vmf_version;
75	boolean_t vmf_wired;
76	struct vm_object *vmf_object;
77	vm_offset_t vmf_offset;
78	vm_prot_t vmf_prot;
79
80	boolean_t vmfp_backoff;
81	struct vm_object *vmfp_object;
82	vm_offset_t vmfp_offset;
83	struct vm_page *vmfp_first_m;
84	vm_prot_t vmfp_access;
85	} vm_fault_state_t;
86
87	struct kmem_cache vm_fault_state_cache;
88
89	int vm_object_absent_max = 50;
90
91	boolean_t vm_fault_dirty_handling = FALSE((boolean_t) 0);
92	boolean_t vm_fault_interruptible = TRUE((boolean_t) 1);
93
94	boolean_t software_reference_bits = TRUE((boolean_t) 1);
95
96	#if MACH_KDB0
97	extern struct db_watchpoint *db_watchpoint_list;
98	#endif /* MACH_KDB */
99
100	/*
101	* Routine: vm_fault_init
102	* Purpose:
103	* Initialize our private data structures.
104	*/
105	void vm_fault_init(void)
106	{
107	kmem_cache_init(&vm_fault_state_cache, "vm_fault_state",
108	sizeof(vm_fault_state_t), 0, NULL((void ) 0), NULL((void ) 0), NULL((void *) 0), 0);
109	}
110
111	/*
112	* Routine: vm_fault_cleanup
113	* Purpose:
114	* Clean up the result of vm_fault_page.
115	* Results:
116	* The paging reference for "object" is released.
117	* "object" is unlocked.
118	* If "top_page" is not null, "top_page" is
119	* freed and the paging reference for the object
120	* containing it is released.
121	*
122	* In/out conditions:
123	* "object" must be locked.
124	*/
125	void
126	vm_fault_cleanup(object, top_page)
127	vm_object_t object;
128	vm_page_t top_page;
129	{
130	vm_object_paging_end(object)({ ({ if (!((object)->paging_in_progress != 0)) Assert("(object)->paging_in_progress != 0" , "../vm/vm_fault.c", 130); }); if (--(object)->paging_in_progress == 0) { ({ if ((object)->all_wanted & (1 << (2) )) thread_wakeup_prim(((event_t)(((vm_offset_t) object) + (2) )), ((boolean_t) 0), 0); (object)->all_wanted &= ~(1 << (2)); }); } });
131	vm_object_unlock(object)((void)(&(object)->Lock));
132
133	if (top_page != VM_PAGE_NULL((vm_page_t) 0)) {
134	object = top_page->object;
135	vm_object_lock(object);
136	VM_PAGE_FREE(top_page)({ ; vm_page_free(top_page); ((void)(&vm_page_queue_lock) ); });
137	vm_object_paging_end(object)({ ({ if (!((object)->paging_in_progress != 0)) Assert("(object)->paging_in_progress != 0" , "../vm/vm_fault.c", 137); }); if (--(object)->paging_in_progress == 0) { ({ if ((object)->all_wanted & (1 << (2) )) thread_wakeup_prim(((event_t)(((vm_offset_t) object) + (2) )), ((boolean_t) 0), 0); (object)->all_wanted &= ~(1 << (2)); }); } });
138	vm_object_unlock(object)((void)(&(object)->Lock));
139	}
140	}
141
142
143	#if MACH_PCSAMPLE1
144	/*
145	* Do PC sampling on current thread, assuming
146	* that it is the thread taking this page fault.
147	*
148	* Must check for THREAD_NULL, since faults
149	* can occur before threads are running.
150	*/
151
152	#define vm_stat_sample(flavor)({ thread_t _thread_ = (active_threads[(0)]); if (_thread_ != ((thread_t) 0)) ({ task_t task; if ((_thread_)->pc_sample .sampletypes & ((flavor))) take_pc_sample((_thread_), & (_thread_)->pc_sample, ((flavor))); task = (_thread_)-> task; if (task->pc_sample.sampletypes & ((flavor))) take_pc_sample ((_thread_), &task->pc_sample, ((flavor))); }); }) \
153	MACRO_BEGIN({ \
154	thread_t _thread_ = current_thread()(active_threads[(0)]); \
155	\
156	if (_thread_ != THREAD_NULL((thread_t) 0)) \
157	take_pc_sample_macro(_thread_, (flavor))({ task_t task; if ((_thread_)->pc_sample.sampletypes & ((flavor))) take_pc_sample((_thread_), &(_thread_)->pc_sample , ((flavor))); task = (_thread_)->task; if (task->pc_sample .sampletypes & ((flavor))) take_pc_sample((_thread_), & task->pc_sample, ((flavor))); }); \
158	MACRO_END})
159
160	#else
161	#define vm_stat_sample(x)({ thread_t _thread_ = (active_threads[(0)]); if (_thread_ != ((thread_t) 0)) ({ task_t task; if ((_thread_)->pc_sample .sampletypes & ((x))) take_pc_sample((_thread_), &(_thread_ )->pc_sample, ((x))); task = (_thread_)->task; if (task ->pc_sample.sampletypes & ((x))) take_pc_sample((_thread_ ), &task->pc_sample, ((x))); }); })
162	#endif /* MACH_PCSAMPLE */
163
164
165
166	/*
167	* Routine: vm_fault_page
168	* Purpose:
169	* Find the resident page for the virtual memory
170	* specified by the given virtual memory object
171	* and offset.
172	* Additional arguments:
173	* The required permissions for the page is given
174	* in "fault_type". Desired permissions are included
175	* in "protection".
176	*
177	* If the desired page is known to be resident (for
178	* example, because it was previously wired down), asserting
179	* the "unwiring" parameter will speed the search.
180	*
181	* If the operation can be interrupted (by thread_abort
182	* or thread_terminate), then the "interruptible"
183	* parameter should be asserted.
184	*
185	* Results:
186	* The page containing the proper data is returned
187	* in "result_page".
188	*
189	* In/out conditions:
190	* The source object must be locked and referenced,
191	* and must donate one paging reference. The reference
192	* is not affected. The paging reference and lock are
193	* consumed.
194	*
195	* If the call succeeds, the object in which "result_page"
196	* resides is left locked and holding a paging reference.
197	* If this is not the original object, a busy page in the
198	* original object is returned in "top_page", to prevent other
199	* callers from pursuing this same data, along with a paging
200	* reference for the original object. The "top_page" should
201	* be destroyed when this guarantee is no longer required.
202	* The "result_page" is also left busy. It is not removed
203	* from the pageout queues.
204	*/
205	vm_fault_return_t vm_fault_page(first_object, first_offset,
206	fault_type, must_be_resident, interruptible,
207	protection,
208	result_page, top_page,
209	resume, continuation)
210	/* Arguments: */
211	vm_object_t first_object; /* Object to begin search */
212	vm_offset_t first_offset; /* Offset into object */
213	vm_prot_t fault_type; /* What access is requested */
214	boolean_t must_be_resident;/* Must page be resident? */
215	boolean_t interruptible; /* May fault be interrupted? */
216	/* Modifies in place: */
217	vm_prot_t protection; / Protection for mapping */
218	/* Returns: */
219	vm_page_t result_page; / Page found, if successful */
220	vm_page_t top_page; / Page in top object, if
221	* not result_page.
222	*/
223	/* More arguments: */
224	boolean_t resume; /* We are restarting. */
225	void (continuation)(); / Continuation for blocking. */
226	{
227	vm_page_t m;
228	vm_object_t object;
229	vm_offset_t offset;
230	vm_page_t first_m;
231	vm_object_t next_object;
232	vm_object_t copy_object;
233	boolean_t look_for_page;
234	vm_prot_t access_required;
235
236	if (resume) {
237	vm_fault_state_t *state =
238	(vm_fault_state_t *) current_thread()(active_threads[(0)])->ith_othersaved.other;
239
240	if (state->vmfp_backoff)
241	goto after_block_and_backoff;
242
243	object = state->vmfp_object;
244	offset = state->vmfp_offset;
245	first_m = state->vmfp_first_m;
246	access_required = state->vmfp_access;
247	goto after_thread_block;
248	}
249
250	vm_stat_sample(SAMPLED_PC_VM_FAULTS_ANY)({ thread_t _thread_ = (active_threads[(0)]); if (_thread_ != ((thread_t) 0)) ({ task_t task; if ((_thread_)->pc_sample .sampletypes & ((0x100))) take_pc_sample((_thread_), & (_thread_)->pc_sample, ((0x100))); task = (_thread_)->task ; if (task->pc_sample.sampletypes & ((0x100))) take_pc_sample ((_thread_), &task->pc_sample, ((0x100))); }); });
251	vm_stat.faults++; /* needs lock XXX */
252	current_task()((active_threads[(0)])->task)->faults++;
253
254	/*
255	* Recovery actions
256	*/
257	#define RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); } \
258	MACRO_BEGIN({ \
259	PAGE_WAKEUP_DONE(m)({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m)-> wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t) m)), ((boolean_t) 0), 0); } }); \
260	vm_page_lock_queues(); \
261	if (!m->active && !m->inactive) \
262	vm_page_activate(m); \
263	vm_page_unlock_queues()((void)(&vm_page_queue_lock)); \
264	MACRO_END})
265
266	if (vm_fault_dirty_handling
267	#if MACH_KDB0
268	/*
269	* If there are watchpoints set, then
270	* we don't want to give away write permission
271	* on a read fault. Make the task write fault,
272	* so that the watchpoint code notices the access.
273	*/
274	\|\| db_watchpoint_list
275	#endif /* MACH_KDB */
276	) {
277	/*
278	* If we aren't asking for write permission,
279	* then don't give it away. We're using write
280	* faults to set the dirty bit.
281	*/
282	if (!(fault_type & VM_PROT_WRITE((vm_prot_t) 0x02)))
283	*protection &= ~VM_PROT_WRITE((vm_prot_t) 0x02);
284	}
285
286	if (!vm_fault_interruptible)
287	interruptible = FALSE((boolean_t) 0);
288
289	/*
290	* INVARIANTS (through entire routine):
291	*
292	* 1) At all times, we must either have the object
293	* lock or a busy page in some object to prevent
294	* some other thread from trying to bring in
295	* the same page.
296	*
297	* Note that we cannot hold any locks during the
298	* pager access or when waiting for memory, so
299	* we use a busy page then.
300	*
301	* Note also that we aren't as concerned about more than
302	* one thread attempting to memory_object_data_unlock
303	* the same page at once, so we don't hold the page
304	* as busy then, but do record the highest unlock
305	* value so far. [Unlock requests may also be delivered
306	* out of order.]
307	*
308	* 2) To prevent another thread from racing us down the
309	* shadow chain and entering a new page in the top
310	* object before we do, we must keep a busy page in
311	* the top object while following the shadow chain.
312	*
313	* 3) We must increment paging_in_progress on any object
314	* for which we have a busy page, to prevent
315	* vm_object_collapse from removing the busy page
316	* without our noticing.
317	*
318	* 4) We leave busy pages on the pageout queues.
319	* If the pageout daemon comes across a busy page,
320	* it will remove the page from the pageout queues.
321	*/
322
323	/*
324	* Search for the page at object/offset.
325	*/
326
327	object = first_object;
328	offset = first_offset;
329	first_m = VM_PAGE_NULL((vm_page_t) 0);
330	access_required = fault_type;
331
332	/*
333	* See whether this page is resident
334	*/
335
336	while (TRUE((boolean_t) 1)) {
337	m = vm_page_lookup(object, offset);
338	if (m != VM_PAGE_NULL((vm_page_t) 0)) {
339	/*
340	* If the page is being brought in,
341	* wait for it and then retry.
342	*
343	* A possible optimization: if the page
344	* is known to be resident, we can ignore
345	* pages that are absent (regardless of
346	* whether they're busy).
347	*/
348
349	if (m->busy) {
350	kern_return_t wait_result;
351
352	PAGE_ASSERT_WAIT(m, interruptible)({ (m)->wanted = ((boolean_t) 1); assert_wait((event_t) (m ), (interruptible)); });
353	vm_object_unlock(object)((void)(&(object)->Lock));
354	if (continuation != (void (*)()) 0) {
355	vm_fault_state_t *state =
356	(vm_fault_state_t *) current_thread()(active_threads[(0)])->ith_othersaved.other;
357
358	/*
359	* Save variables in case
360	* thread_block discards
361	* our kernel stack.
362	*/
363
364	state->vmfp_backoff = FALSE((boolean_t) 0);
365	state->vmfp_object = object;
366	state->vmfp_offset = offset;
367	state->vmfp_first_m = first_m;
368	state->vmfp_access =
369	access_required;
370	state->vmf_prot = *protection;
371
372	counter(c_vm_fault_page_block_busy_user++);
373	thread_block(continuation);
374	} else
375	{
376	counter(c_vm_fault_page_block_busy_kernel++);
377	thread_block((void (*)()) 0);
378	}
379	after_thread_block:
380	wait_result = current_thread()(active_threads[(0)])->wait_result;
381	vm_object_lock(object);
382	if (wait_result != THREAD_AWAKENED0) {
383	vm_fault_cleanup(object, first_m);
384	if (wait_result == THREAD_RESTART3)
385	return(VM_FAULT_RETRY1);
386	else
387	return(VM_FAULT_INTERRUPTED2);
388	}
389	continue;
390	}
391
392	/*
393	* If the page is in error, give up now.
394	*/
395
396	if (m->error) {
397	VM_PAGE_FREE(m)({ ; vm_page_free(m); ((void)(&vm_page_queue_lock)); });
398	vm_fault_cleanup(object, first_m);
399	return(VM_FAULT_MEMORY_ERROR5);
400	}
401
402	/*
403	* If the page isn't busy, but is absent,
404	* then it was deemed "unavailable".
405	*/
406
407	if (m->absent) {
408	/*
409	* Remove the non-existent page (unless it's
410	* in the top object) and move on down to the
411	* next object (if there is one).
412	*/
413
414	offset += object->shadow_offset;
415	access_required = VM_PROT_READ((vm_prot_t) 0x01);
416	next_object = object->shadow;
417	if (next_object == VM_OBJECT_NULL((vm_object_t) 0)) {
418	vm_page_t real_m;
419
420	assert(!must_be_resident)({ if (!(!must_be_resident)) Assert("!must_be_resident", "../vm/vm_fault.c" , 420); });
421
422	/*
423	* Absent page at bottom of shadow
424	* chain; zero fill the page we left
425	* busy in the first object, and flush
426	* the absent page. But first we
427	* need to allocate a real page.
428	*/
429
430	real_m = vm_page_grab(!object->internal);
431	if (real_m == VM_PAGE_NULL((vm_page_t) 0)) {
432	vm_fault_cleanup(object, first_m);
433	return(VM_FAULT_MEMORY_SHORTAGE3);
434	}
435
436	if (object != first_object) {
437	VM_PAGE_FREE(m)({ ; vm_page_free(m); ((void)(&vm_page_queue_lock)); });
438	vm_object_paging_end(object)({ ({ if (!((object)->paging_in_progress != 0)) Assert("(object)->paging_in_progress != 0" , "../vm/vm_fault.c", 438); }); if (--(object)->paging_in_progress == 0) { ({ if ((object)->all_wanted & (1 << (2) )) thread_wakeup_prim(((event_t)(((vm_offset_t) object) + (2) )), ((boolean_t) 0), 0); (object)->all_wanted &= ~(1 << (2)); }); } });
439	vm_object_unlock(object)((void)(&(object)->Lock));
440	object = first_object;
441	offset = first_offset;
442	m = first_m;
443	first_m = VM_PAGE_NULL((vm_page_t) 0);
444	vm_object_lock(object);
445	}
446
447	VM_PAGE_FREE(m)({ ; vm_page_free(m); ((void)(&vm_page_queue_lock)); });
448	assert(real_m->busy)({ if (!(real_m->busy)) Assert("real_m->busy", "../vm/vm_fault.c" , 448); });
449	vm_page_lock_queues();
450	vm_page_insert(real_m, object, offset);
451	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
452	m = real_m;
453
454	/*
455	* Drop the lock while zero filling
456	* page. Then break because this
457	* is the page we wanted. Checking
458	* the page lock is a waste of time;
459	* this page was either absent or
460	* newly allocated -- in both cases
461	* it can't be page locked by a pager.
462	*/
463	vm_object_unlock(object)((void)(&(object)->Lock));
464
465	vm_page_zero_fill(m);
466
467	vm_stat_sample(SAMPLED_PC_VM_ZFILL_FAULTS)({ thread_t _thread_ = (active_threads[(0)]); if (_thread_ != ((thread_t) 0)) ({ task_t task; if ((_thread_)->pc_sample .sampletypes & ((0x10))) take_pc_sample((_thread_), & (_thread_)->pc_sample, ((0x10))); task = (_thread_)->task ; if (task->pc_sample.sampletypes & ((0x10))) take_pc_sample ((_thread_), &task->pc_sample, ((0x10))); }); });
468
469	vm_stat.zero_fill_count++;
470	current_task()((active_threads[(0)])->task)->zero_fills++;
471	vm_object_lock(object);
472	pmap_clear_modify(m->phys_addr);
473	break;
474	} else {
475	if (must_be_resident) {
476	vm_object_paging_end(object)({ ({ if (!((object)->paging_in_progress != 0)) Assert("(object)->paging_in_progress != 0" , "../vm/vm_fault.c", 476); }); if (--(object)->paging_in_progress == 0) { ({ if ((object)->all_wanted & (1 << (2) )) thread_wakeup_prim(((event_t)(((vm_offset_t) object) + (2) )), ((boolean_t) 0), 0); (object)->all_wanted &= ~(1 << (2)); }); } });
477	} else if (object != first_object) {
478	vm_object_paging_end(object)({ ({ if (!((object)->paging_in_progress != 0)) Assert("(object)->paging_in_progress != 0" , "../vm/vm_fault.c", 478); }); if (--(object)->paging_in_progress == 0) { ({ if ((object)->all_wanted & (1 << (2) )) thread_wakeup_prim(((event_t)(((vm_offset_t) object) + (2) )), ((boolean_t) 0), 0); (object)->all_wanted &= ~(1 << (2)); }); } });
479	VM_PAGE_FREE(m)({ ; vm_page_free(m); ((void)(&vm_page_queue_lock)); });
480	} else {
481	first_m = m;
482	m->absent = FALSE((boolean_t) 0);
483	vm_object_absent_release(object)({ (object)->absent_count--; ({ if (((object))->all_wanted & (1 << (3))) thread_wakeup_prim(((event_t)(((vm_offset_t ) (object)) + (3))), ((boolean_t) 0), 0); ((object))->all_wanted &= ~(1 << (3)); }); });
484	m->busy = TRUE((boolean_t) 1);
485
486	vm_page_lock_queues();
487	VM_PAGE_QUEUES_REMOVE(m)({ if (m->active) { { queue_entry_t next, prev; next = (m) ->pageq.next; prev = (m)->pageq.prev; if ((&vm_page_queue_active ) == next) (&vm_page_queue_active)->prev = prev; else ( (vm_page_t)next)->pageq.prev = prev; if ((&vm_page_queue_active ) == prev) (&vm_page_queue_active)->next = next; else ( (vm_page_t)prev)->pageq.next = next; }; m->active = ((boolean_t ) 0); vm_page_active_count--; } if (m->inactive) { { queue_entry_t next, prev; next = (m)->pageq.next; prev = (m)->pageq. prev; if ((&vm_page_queue_inactive) == next) (&vm_page_queue_inactive )->prev = prev; else ((vm_page_t)next)->pageq.prev = prev ; if ((&vm_page_queue_inactive) == prev) (&vm_page_queue_inactive )->next = next; else ((vm_page_t)prev)->pageq.next = next ; }; m->inactive = ((boolean_t) 0); vm_page_inactive_count --; } });
488	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
489	}
490	vm_object_lock(next_object);
491	vm_object_unlock(object)((void)(&(object)->Lock));
492	object = next_object;
493	vm_object_paging_begin(object)((object)->paging_in_progress++);
494	continue;
495	}
496	}
497
498	/*
499	* If the desired access to this page has
500	* been locked out, request that it be unlocked.
501	*/
502
503	if (access_required & m->page_lock) {
504	if ((access_required & m->unlock_request) != access_required) {
505	vm_prot_t new_unlock_request;
506	kern_return_t rc;
507
508	if (!object->pager_ready) {
509	vm_object_assert_wait(object,({ (object)->all_wanted \|= 1 << (1); assert_wait((event_t )(((vm_offset_t) object) + (1)), (interruptible)); })
510	VM_OBJECT_EVENT_PAGER_READY,({ (object)->all_wanted \|= 1 << (1); assert_wait((event_t )(((vm_offset_t) object) + (1)), (interruptible)); })
511	interruptible)({ (object)->all_wanted \|= 1 << (1); assert_wait((event_t )(((vm_offset_t) object) + (1)), (interruptible)); });
512	goto block_and_backoff;
513	}
514
515	new_unlock_request = m->unlock_request =
516	(access_required \| m->unlock_request);
517	vm_object_unlock(object)((void)(&(object)->Lock));
518	if ((rc = memory_object_data_unlock(
519	object->pager,
520	object->pager_request,
521	offset + object->paging_offset,
522	PAGE_SIZE(1 << 12),
523	new_unlock_request))
524	!= KERN_SUCCESS0) {
525	printf("vm_fault: memory_object_data_unlock failed\n");
526	vm_object_lock(object);
527	vm_fault_cleanup(object, first_m);
528	return((rc == MACH_SEND_INTERRUPTED0x10000007) ?
529	VM_FAULT_INTERRUPTED2 :
530	VM_FAULT_MEMORY_ERROR5);
531	}
532	vm_object_lock(object);
533	continue;
534	}
535
536	PAGE_ASSERT_WAIT(m, interruptible)({ (m)->wanted = ((boolean_t) 1); assert_wait((event_t) (m ), (interruptible)); });
537	goto block_and_backoff;
538	}
539
540	/*
541	* We mark the page busy and leave it on
542	* the pageout queues. If the pageout
543	* deamon comes across it, then it will
544	* remove the page.
545	*/
546
547	if (!software_reference_bits) {
548	vm_page_lock_queues();
549	if (m->inactive) {
550	vm_stat_sample(SAMPLED_PC_VM_REACTIVATION_FAULTS)({ thread_t _thread_ = (active_threads[(0)]); if (_thread_ != ((thread_t) 0)) ({ task_t task; if ((_thread_)->pc_sample .sampletypes & ((0x20))) take_pc_sample((_thread_), & (_thread_)->pc_sample, ((0x20))); task = (_thread_)->task ; if (task->pc_sample.sampletypes & ((0x20))) take_pc_sample ((_thread_), &task->pc_sample, ((0x20))); }); });
551	vm_stat.reactivations++;
552	current_task()((active_threads[(0)])->task)->reactivations++;
553	}
554
555	VM_PAGE_QUEUES_REMOVE(m)({ if (m->active) { { queue_entry_t next, prev; next = (m) ->pageq.next; prev = (m)->pageq.prev; if ((&vm_page_queue_active ) == next) (&vm_page_queue_active)->prev = prev; else ( (vm_page_t)next)->pageq.prev = prev; if ((&vm_page_queue_active ) == prev) (&vm_page_queue_active)->next = next; else ( (vm_page_t)prev)->pageq.next = next; }; m->active = ((boolean_t ) 0); vm_page_active_count--; } if (m->inactive) { { queue_entry_t next, prev; next = (m)->pageq.next; prev = (m)->pageq. prev; if ((&vm_page_queue_inactive) == next) (&vm_page_queue_inactive )->prev = prev; else ((vm_page_t)next)->pageq.prev = prev ; if ((&vm_page_queue_inactive) == prev) (&vm_page_queue_inactive )->next = next; else ((vm_page_t)prev)->pageq.next = next ; }; m->inactive = ((boolean_t) 0); vm_page_inactive_count --; } });
556	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
557	}
558
559	assert(!m->busy)({ if (!(!m->busy)) Assert("!m->busy", "../vm/vm_fault.c" , 559); });
560	m->busy = TRUE((boolean_t) 1);
561	assert(!m->absent)({ if (!(!m->absent)) Assert("!m->absent", "../vm/vm_fault.c" , 561); });
562	break;
563	}
564
565	look_for_page =
566	(object->pager_created)
567	#if MACH_PAGEMAP1
568	&& (vm_external_state_get(object->existence_info, offset + object->paging_offset)(((object->existence_info) != ((vm_external_t) 0)) ? _vm_external_state_get (object->existence_info, offset + object->paging_offset ) : 2) !=
569	VM_EXTERNAL_STATE_ABSENT3)
570	#endif /* MACH_PAGEMAP */
571	;
572
573	if ((look_for_page \|\| (object == first_object))
574	&& !must_be_resident) {
575	/*
576	* Allocate a new page for this object/offset
577	* pair.
578	*/
579
580	m = vm_page_grab_fictitious();
581	if (m == VM_PAGE_NULL((vm_page_t) 0)) {
582	vm_fault_cleanup(object, first_m);
583	return(VM_FAULT_FICTITIOUS_SHORTAGE4);
584	}
585
586	vm_page_lock_queues();
587	vm_page_insert(m, object, offset);
588	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
589	}
590
591	if (look_for_page && !must_be_resident) {
592	kern_return_t rc;
593
594	/*
595	* If the memory manager is not ready, we
596	* cannot make requests.
597	*/
598	if (!object->pager_ready) {
599	vm_object_assert_wait(object,({ (object)->all_wanted \|= 1 << (1); assert_wait((event_t )(((vm_offset_t) object) + (1)), (interruptible)); })
600	VM_OBJECT_EVENT_PAGER_READY,({ (object)->all_wanted \|= 1 << (1); assert_wait((event_t )(((vm_offset_t) object) + (1)), (interruptible)); })
601	interruptible)({ (object)->all_wanted \|= 1 << (1); assert_wait((event_t )(((vm_offset_t) object) + (1)), (interruptible)); });
602	VM_PAGE_FREE(m)({ ; vm_page_free(m); ((void)(&vm_page_queue_lock)); });
603	goto block_and_backoff;
604	}
605
606	if (object->internal) {
607	/*
608	* Requests to the default pager
609	* must reserve a real page in advance,
610	* because the pager's data-provided
611	* won't block for pages.
612	*/
613
614	if (m->fictitious && !vm_page_convert(m, FALSE((boolean_t) 0))) {
615	VM_PAGE_FREE(m)({ ; vm_page_free(m); ((void)(&vm_page_queue_lock)); });
616	vm_fault_cleanup(object, first_m);
617	return(VM_FAULT_MEMORY_SHORTAGE3);
618	}
619	} else if (object->absent_count >
620	vm_object_absent_max) {
621	/*
622	* If there are too many outstanding page
623	* requests pending on this object, we
624	* wait for them to be resolved now.
625	*/
626
627	vm_object_absent_assert_wait(object, interruptible)({ ({ ((object))->all_wanted \|= 1 << (3); assert_wait ((event_t)(((vm_offset_t) (object)) + (3)), ((interruptible)) ); }); });
628	VM_PAGE_FREE(m)({ ; vm_page_free(m); ((void)(&vm_page_queue_lock)); });
629	goto block_and_backoff;
630	}
631
632	/*
633	* Indicate that the page is waiting for data
634	* from the memory manager.
635	*/
636
637	m->absent = TRUE((boolean_t) 1);
638	object->absent_count++;
639
640	/*
641	* We have a busy page, so we can
642	* release the object lock.
643	*/
644	vm_object_unlock(object)((void)(&(object)->Lock));
645
646	/*
647	* Call the memory manager to retrieve the data.
648	*/
649
650	vm_stat.pageins++;
651	vm_stat_sample(SAMPLED_PC_VM_PAGEIN_FAULTS)({ thread_t _thread_ = (active_threads[(0)]); if (_thread_ != ((thread_t) 0)) ({ task_t task; if ((_thread_)->pc_sample .sampletypes & ((0x40))) take_pc_sample((_thread_), & (_thread_)->pc_sample, ((0x40))); task = (_thread_)->task ; if (task->pc_sample.sampletypes & ((0x40))) take_pc_sample ((_thread_), &task->pc_sample, ((0x40))); }); });
652	current_task()((active_threads[(0)])->task)->pageins++;
653
654	if ((rc = memory_object_data_request(object->pager,
655	object->pager_request,
656	m->offset + object->paging_offset,
657	PAGE_SIZE(1 << 12), access_required)) != KERN_SUCCESS0) {
658	if (rc != MACH_SEND_INTERRUPTED0x10000007)
659	printf("%s(0x%p, 0x%p, 0x%lx, 0x%x, 0x%x) failed, %x\n",
660	"memory_object_data_request",
661	object->pager,
662	object->pager_request,
663	m->offset + object->paging_offset,
664	PAGE_SIZE(1 << 12), access_required, rc);
665	/*
666	* Don't want to leave a busy page around,
667	* but the data request may have blocked,
668	* so check if it's still there and busy.
669	*/
670	vm_object_lock(object);
671	if (m == vm_page_lookup(object,offset) &&
672	m->absent && m->busy)
673	VM_PAGE_FREE(m)({ ; vm_page_free(m); ((void)(&vm_page_queue_lock)); });
674	vm_fault_cleanup(object, first_m);
675	return((rc == MACH_SEND_INTERRUPTED0x10000007) ?
676	VM_FAULT_INTERRUPTED2 :
677	VM_FAULT_MEMORY_ERROR5);
678	}
679
680	/*
681	* Retry with same object/offset, since new data may
682	* be in a different page (i.e., m is meaningless at
683	* this point).
684	*/
685	vm_object_lock(object);
686	continue;
687	}
688
689	/*
690	* For the XP system, the only case in which we get here is if
691	* object has no pager (or unwiring). If the pager doesn't
692	* have the page this is handled in the m->absent case above
693	* (and if you change things here you should look above).
694	*/
695	if (object == first_object)
696	first_m = m;
697	else
698	{
699	assert(m == VM_PAGE_NULL)({ if (!(m == ((vm_page_t) 0))) Assert("m == VM_PAGE_NULL", "../vm/vm_fault.c" , 699); });
700	}
701
702	/*
703	* Move on to the next object. Lock the next
704	* object before unlocking the current one.
705	*/
706	access_required = VM_PROT_READ((vm_prot_t) 0x01);
707
708	offset += object->shadow_offset;
709	next_object = object->shadow;
710	if (next_object == VM_OBJECT_NULL((vm_object_t) 0)) {
711	assert(!must_be_resident)({ if (!(!must_be_resident)) Assert("!must_be_resident", "../vm/vm_fault.c" , 711); });
712
713	/*
714	* If there's no object left, fill the page
715	* in the top object with zeros. But first we
716	* need to allocate a real page.
717	*/
718
719	if (object != first_object) {
720	vm_object_paging_end(object)({ ({ if (!((object)->paging_in_progress != 0)) Assert("(object)->paging_in_progress != 0" , "../vm/vm_fault.c", 720); }); if (--(object)->paging_in_progress == 0) { ({ if ((object)->all_wanted & (1 << (2) )) thread_wakeup_prim(((event_t)(((vm_offset_t) object) + (2) )), ((boolean_t) 0), 0); (object)->all_wanted &= ~(1 << (2)); }); } });
721	vm_object_unlock(object)((void)(&(object)->Lock));
722
723	object = first_object;
724	offset = first_offset;
	Value stored to 'offset' is never read
725	vm_object_lock(object);
726	}
727
728	m = first_m;
729	assert(m->object == object)({ if (!(m->object == object)) Assert("m->object == object" , "../vm/vm_fault.c", 729); });
730	first_m = VM_PAGE_NULL((vm_page_t) 0);
731
732	if (m->fictitious && !vm_page_convert(m, !object->internal)) {
733	VM_PAGE_FREE(m)({ ; vm_page_free(m); ((void)(&vm_page_queue_lock)); });
734	vm_fault_cleanup(object, VM_PAGE_NULL((vm_page_t) 0));
735	return(VM_FAULT_MEMORY_SHORTAGE3);
736	}
737
738	vm_object_unlock(object)((void)(&(object)->Lock));
739	vm_page_zero_fill(m);
740	vm_stat_sample(SAMPLED_PC_VM_ZFILL_FAULTS)({ thread_t _thread_ = (active_threads[(0)]); if (_thread_ != ((thread_t) 0)) ({ task_t task; if ((_thread_)->pc_sample .sampletypes & ((0x10))) take_pc_sample((_thread_), & (_thread_)->pc_sample, ((0x10))); task = (_thread_)->task ; if (task->pc_sample.sampletypes & ((0x10))) take_pc_sample ((_thread_), &task->pc_sample, ((0x10))); }); });
741	vm_stat.zero_fill_count++;
742	current_task()((active_threads[(0)])->task)->zero_fills++;
743	vm_object_lock(object);
744	pmap_clear_modify(m->phys_addr);
745	break;
746	}
747	else {
748	vm_object_lock(next_object);
749	if ((object != first_object) \|\| must_be_resident)
750	vm_object_paging_end(object)({ ({ if (!((object)->paging_in_progress != 0)) Assert("(object)->paging_in_progress != 0" , "../vm/vm_fault.c", 750); }); if (--(object)->paging_in_progress == 0) { ({ if ((object)->all_wanted & (1 << (2) )) thread_wakeup_prim(((event_t)(((vm_offset_t) object) + (2) )), ((boolean_t) 0), 0); (object)->all_wanted &= ~(1 << (2)); }); } });
751	vm_object_unlock(object)((void)(&(object)->Lock));
752	object = next_object;
753	vm_object_paging_begin(object)((object)->paging_in_progress++);
754	}
755	}
756
757	/*
758	* PAGE HAS BEEN FOUND.
759	*
760	* This page (m) is:
761	* busy, so that we can play with it;
762	* not absent, so that nobody else will fill it;
763	* possibly eligible for pageout;
764	*
765	* The top-level page (first_m) is:
766	* VM_PAGE_NULL if the page was found in the
767	* top-level object;
768	* busy, not absent, and ineligible for pageout.
769	*
770	* The current object (object) is locked. A paging
771	* reference is held for the current and top-level
772	* objects.
773	*/
774
775	#if EXTRA_ASSERTIONS
776	assert(m->busy && !m->absent)({ if (!(m->busy && !m->absent)) Assert("m->busy && !m->absent" , "../vm/vm_fault.c", 776); });
777	assert((first_m == VM_PAGE_NULL) \|\|({ if (!((first_m == ((vm_page_t) 0)) \|\| (first_m->busy && !first_m->absent && !first_m->active && !first_m->inactive))) Assert("(first_m == VM_PAGE_NULL) \|\| (first_m->busy && !first_m->absent && !first_m->active && !first_m->inactive)" , "../vm/vm_fault.c", 779); })
778	(first_m->busy && !first_m->absent &&({ if (!((first_m == ((vm_page_t) 0)) \|\| (first_m->busy && !first_m->absent && !first_m->active && !first_m->inactive))) Assert("(first_m == VM_PAGE_NULL) \|\| (first_m->busy && !first_m->absent && !first_m->active && !first_m->inactive)" , "../vm/vm_fault.c", 779); })
779	!first_m->active && !first_m->inactive))({ if (!((first_m == ((vm_page_t) 0)) \|\| (first_m->busy && !first_m->absent && !first_m->active && !first_m->inactive))) Assert("(first_m == VM_PAGE_NULL) \|\| (first_m->busy && !first_m->absent && !first_m->active && !first_m->inactive)" , "../vm/vm_fault.c", 779); });
780	#endif /* EXTRA_ASSERTIONS */
781
782	/*
783	* If the page is being written, but isn't
784	* already owned by the top-level object,
785	* we have to copy it into a new page owned
786	* by the top-level object.
787	*/
788
789	if (object != first_object) {
790	/*
791	* We only really need to copy if we
792	* want to write it.
793	*/
794
795	if (fault_type & VM_PROT_WRITE((vm_prot_t) 0x02)) {
796	vm_page_t copy_m;
797
798	assert(!must_be_resident)({ if (!(!must_be_resident)) Assert("!must_be_resident", "../vm/vm_fault.c" , 798); });
799
800	/*
801	* If we try to collapse first_object at this
802	* point, we may deadlock when we try to get
803	* the lock on an intermediate object (since we
804	* have the bottom object locked). We can't
805	* unlock the bottom object, because the page
806	* we found may move (by collapse) if we do.
807	*
808	* Instead, we first copy the page. Then, when
809	* we have no more use for the bottom object,
810	* we unlock it and try to collapse.
811	*
812	* Note that we copy the page even if we didn't
813	* need to... that's the breaks.
814	*/
815
816	/*
817	* Allocate a page for the copy
818	*/
819	copy_m = vm_page_grab(!first_object->internal);
820	if (copy_m == VM_PAGE_NULL((vm_page_t) 0)) {
821	RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); };
822	vm_fault_cleanup(object, first_m);
823	return(VM_FAULT_MEMORY_SHORTAGE3);
824	}
825
826	vm_object_unlock(object)((void)(&(object)->Lock));
827	vm_page_copy(m, copy_m);
828	vm_object_lock(object);
829
830	/*
831	* If another map is truly sharing this
832	* page with us, we have to flush all
833	* uses of the original page, since we
834	* can't distinguish those which want the
835	* original from those which need the
836	* new copy.
837	*
838	* XXXO If we know that only one map has
839	* access to this page, then we could
840	* avoid the pmap_page_protect() call.
841	*/
842
843	vm_page_lock_queues();
844	vm_page_deactivate(m);
845	pmap_page_protect(m->phys_addr, VM_PROT_NONE((vm_prot_t) 0x00));
846	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
847
848	/*
849	* We no longer need the old page or object.
850	*/
851
852	PAGE_WAKEUP_DONE(m)({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m)-> wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t) m)), ((boolean_t) 0), 0); } });
853	vm_object_paging_end(object)({ ({ if (!((object)->paging_in_progress != 0)) Assert("(object)->paging_in_progress != 0" , "../vm/vm_fault.c", 853); }); if (--(object)->paging_in_progress == 0) { ({ if ((object)->all_wanted & (1 << (2) )) thread_wakeup_prim(((event_t)(((vm_offset_t) object) + (2) )), ((boolean_t) 0), 0); (object)->all_wanted &= ~(1 << (2)); }); } });
854	vm_object_unlock(object)((void)(&(object)->Lock));
855
856	vm_stat.cow_faults++;
857	vm_stat_sample(SAMPLED_PC_VM_COW_FAULTS)({ thread_t _thread_ = (active_threads[(0)]); if (_thread_ != ((thread_t) 0)) ({ task_t task; if ((_thread_)->pc_sample .sampletypes & ((0x80))) take_pc_sample((_thread_), & (_thread_)->pc_sample, ((0x80))); task = (_thread_)->task ; if (task->pc_sample.sampletypes & ((0x80))) take_pc_sample ((_thread_), &task->pc_sample, ((0x80))); }); });
858	current_task()((active_threads[(0)])->task)->cow_faults++;
859	object = first_object;
860	offset = first_offset;
861
862	vm_object_lock(object);
863	VM_PAGE_FREE(first_m)({ ; vm_page_free(first_m); ((void)(&vm_page_queue_lock)) ; });
864	first_m = VM_PAGE_NULL((vm_page_t) 0);
865	assert(copy_m->busy)({ if (!(copy_m->busy)) Assert("copy_m->busy", "../vm/vm_fault.c" , 865); });
866	vm_page_lock_queues();
867	vm_page_insert(copy_m, object, offset);
868	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
869	m = copy_m;
870
871	/*
872	* Now that we've gotten the copy out of the
873	* way, let's try to collapse the top object.
874	* But we have to play ugly games with
875	* paging_in_progress to do that...
876	*/
877
878	vm_object_paging_end(object)({ ({ if (!((object)->paging_in_progress != 0)) Assert("(object)->paging_in_progress != 0" , "../vm/vm_fault.c", 878); }); if (--(object)->paging_in_progress == 0) { ({ if ((object)->all_wanted & (1 << (2) )) thread_wakeup_prim(((event_t)(((vm_offset_t) object) + (2) )), ((boolean_t) 0), 0); (object)->all_wanted &= ~(1 << (2)); }); } });
879	vm_object_collapse(object);
880	vm_object_paging_begin(object)((object)->paging_in_progress++);
881	}
882	else {
883	*protection &= (~VM_PROT_WRITE((vm_prot_t) 0x02));
884	}
885	}
886
887	/*
888	* Now check whether the page needs to be pushed into the
889	* copy object. The use of asymmetric copy on write for
890	* shared temporary objects means that we may do two copies to
891	* satisfy the fault; one above to get the page from a
892	* shadowed object, and one here to push it into the copy.
893	*/
894
895	while ((copy_object = first_object->copy) != VM_OBJECT_NULL((vm_object_t) 0)) {
896	vm_offset_t copy_offset;
897	vm_page_t copy_m;
898
899	/*
900	* If the page is being written, but hasn't been
901	* copied to the copy-object, we have to copy it there.
902	*/
903
904	if ((fault_type & VM_PROT_WRITE((vm_prot_t) 0x02)) == 0) {
905	*protection &= ~VM_PROT_WRITE((vm_prot_t) 0x02);
906	break;
907	}
908
909	/*
910	* If the page was guaranteed to be resident,
911	* we must have already performed the copy.
912	*/
913
914	if (must_be_resident)
915	break;
916
917	/*
918	* Try to get the lock on the copy_object.
919	*/
920	if (!vm_object_lock_try(copy_object)(((boolean_t) 1))) {
921	vm_object_unlock(object)((void)(&(object)->Lock));
922
923	simple_lock_pause(); /* wait a bit */
924
925	vm_object_lock(object);
926	continue;
927	}
928
929	/*
930	* Make another reference to the copy-object,
931	* to keep it from disappearing during the
932	* copy.
933	*/
934	assert(copy_object->ref_count > 0)({ if (!(copy_object->ref_count > 0)) Assert("copy_object->ref_count > 0" , "../vm/vm_fault.c", 934); });
935	copy_object->ref_count++;
936
937	/*
938	* Does the page exist in the copy?
939	*/
940	copy_offset = first_offset - copy_object->shadow_offset;
941	copy_m = vm_page_lookup(copy_object, copy_offset);
942	if (copy_m != VM_PAGE_NULL((vm_page_t) 0)) {
943	if (copy_m->busy) {
944	/*
945	* If the page is being brought
946	* in, wait for it and then retry.
947	*/
948	PAGE_ASSERT_WAIT(copy_m, interruptible)({ (copy_m)->wanted = ((boolean_t) 1); assert_wait((event_t ) (copy_m), (interruptible)); });
949	RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); };
950	copy_object->ref_count--;
951	assert(copy_object->ref_count > 0)({ if (!(copy_object->ref_count > 0)) Assert("copy_object->ref_count > 0" , "../vm/vm_fault.c", 951); });
952	vm_object_unlock(copy_object)((void)(&(copy_object)->Lock));
953	goto block_and_backoff;
954	}
955	}
956	else {
957	/*
958	* Allocate a page for the copy
959	*/
960	copy_m = vm_page_alloc(copy_object, copy_offset);
961	if (copy_m == VM_PAGE_NULL((vm_page_t) 0)) {
962	RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); };
963	copy_object->ref_count--;
964	assert(copy_object->ref_count > 0)({ if (!(copy_object->ref_count > 0)) Assert("copy_object->ref_count > 0" , "../vm/vm_fault.c", 964); });
965	vm_object_unlock(copy_object)((void)(&(copy_object)->Lock));
966	vm_fault_cleanup(object, first_m);
967	return(VM_FAULT_MEMORY_SHORTAGE3);
968	}
969
970	/*
971	* Must copy page into copy-object.
972	*/
973
974	vm_page_copy(m, copy_m);
975
976	/*
977	* If the old page was in use by any users
978	* of the copy-object, it must be removed
979	* from all pmaps. (We can't know which
980	* pmaps use it.)
981	*/
982
983	vm_page_lock_queues();
984	pmap_page_protect(m->phys_addr, VM_PROT_NONE((vm_prot_t) 0x00));
985	copy_m->dirty = TRUE((boolean_t) 1);
986	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
987
988	/*
989	* If there's a pager, then immediately
990	* page out this page, using the "initialize"
991	* option. Else, we use the copy.
992	*/
993
994	if (!copy_object->pager_created) {
995	vm_page_lock_queues();
996	vm_page_activate(copy_m);
997	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
998	PAGE_WAKEUP_DONE(copy_m)({ (copy_m)->busy = ((boolean_t) 0); if ((copy_m)->wanted ) { (copy_m)->wanted = ((boolean_t) 0); thread_wakeup_prim ((((event_t) copy_m)), ((boolean_t) 0), 0); } });
999	} else {
1000	/*
1001	* The page is already ready for pageout:
1002	* not on pageout queues and busy.
1003	* Unlock everything except the
1004	* copy_object itself.
1005	*/
1006
1007	vm_object_unlock(object)((void)(&(object)->Lock));
1008
1009	/*
1010	* Write the page to the copy-object,
1011	* flushing it from the kernel.
1012	*/
1013
1014	vm_pageout_page(copy_m, TRUE((boolean_t) 1), TRUE((boolean_t) 1));
1015
1016	/*
1017	* Since the pageout may have
1018	* temporarily dropped the
1019	* copy_object's lock, we
1020	* check whether we'll have
1021	* to deallocate the hard way.
1022	*/
1023
1024	if ((copy_object->shadow != object) \|\|
1025	(copy_object->ref_count == 1)) {
1026	vm_object_unlock(copy_object)((void)(&(copy_object)->Lock));
1027	vm_object_deallocate(copy_object);
1028	vm_object_lock(object);
1029	continue;
1030	}
1031
1032	/*
1033	* Pick back up the old object's
1034	* lock. [It is safe to do so,
1035	* since it must be deeper in the
1036	* object tree.]
1037	*/
1038
1039	vm_object_lock(object);
1040	}
1041
1042	/*
1043	* Because we're pushing a page upward
1044	* in the object tree, we must restart
1045	* any faults that are waiting here.
1046	* [Note that this is an expansion of
1047	* PAGE_WAKEUP that uses the THREAD_RESTART
1048	* wait result]. Can't turn off the page's
1049	* busy bit because we're not done with it.
1050	*/
1051
1052	if (m->wanted) {
1053	m->wanted = FALSE((boolean_t) 0);
1054	thread_wakeup_with_result((event_t) m,thread_wakeup_prim(((event_t) m), ((boolean_t) 0), (3))
1055	THREAD_RESTART)thread_wakeup_prim(((event_t) m), ((boolean_t) 0), (3));
1056	}
1057	}
1058
1059	/*
1060	* The reference count on copy_object must be
1061	* at least 2: one for our extra reference,
1062	* and at least one from the outside world
1063	* (we checked that when we last locked
1064	* copy_object).
1065	*/
1066	copy_object->ref_count--;
1067	assert(copy_object->ref_count > 0)({ if (!(copy_object->ref_count > 0)) Assert("copy_object->ref_count > 0" , "../vm/vm_fault.c", 1067); });
1068	vm_object_unlock(copy_object)((void)(&(copy_object)->Lock));
1069
1070	break;
1071	}
1072
1073	*result_page = m;
1074	*top_page = first_m;
1075
1076	/*
1077	* If the page can be written, assume that it will be.
1078	* [Earlier, we restrict the permission to allow write
1079	* access only if the fault so required, so we don't
1080	* mark read-only data as dirty.]
1081	*/
1082
1083	if (vm_fault_dirty_handling && (*protection & VM_PROT_WRITE((vm_prot_t) 0x02)))
1084	m->dirty = TRUE((boolean_t) 1);
1085
1086	return(VM_FAULT_SUCCESS0);
1087
1088	block_and_backoff:
1089	vm_fault_cleanup(object, first_m);
1090
1091	if (continuation != (void (*)()) 0) {
1092	vm_fault_state_t *state =
1093	(vm_fault_state_t *) current_thread()(active_threads[(0)])->ith_othersaved.other;
1094
1095	/*
1096	* Save variables in case we must restart.
1097	*/
1098
1099	state->vmfp_backoff = TRUE((boolean_t) 1);
1100	state->vmf_prot = *protection;
1101
1102	counter(c_vm_fault_page_block_backoff_user++);
1103	thread_block(continuation);
1104	} else
1105	{
1106	counter(c_vm_fault_page_block_backoff_kernel++);
1107	thread_block((void (*)()) 0);
1108	}
1109	after_block_and_backoff:
1110	if (current_thread()(active_threads[(0)])->wait_result == THREAD_AWAKENED0)
1111	return VM_FAULT_RETRY1;
1112	else
1113	return VM_FAULT_INTERRUPTED2;
1114
1115	#undef RELEASE_PAGE
1116	}
1117
1118	/*
1119	* Routine: vm_fault
1120	* Purpose:
1121	* Handle page faults, including pseudo-faults
1122	* used to change the wiring status of pages.
1123	* Returns:
1124	* If an explicit (expression) continuation is supplied,
1125	* then we call the continuation instead of returning.
1126	* Implementation:
1127	* Explicit continuations make this a little icky,
1128	* because it hasn't been rewritten to embrace CPS.
1129	* Instead, we have resume arguments for vm_fault and
1130	* vm_fault_page, to let continue the fault computation.
1131	*
1132	* vm_fault and vm_fault_page save mucho state
1133	* in the moral equivalent of a closure. The state
1134	* structure is allocated when first entering vm_fault
1135	* and deallocated when leaving vm_fault.
1136	*/
1137
1138	void
1139	vm_fault_continue(void)
1140	{
1141	vm_fault_state_t *state =
1142	(vm_fault_state_t *) current_thread()(active_threads[(0)])->ith_othersaved.other;
1143
1144	(void) vm_fault(state->vmf_map,
1145	state->vmf_vaddr,
1146	state->vmf_fault_type,
1147	state->vmf_change_wiring,
1148	TRUE((boolean_t) 1), state->vmf_continuation);
1149	/NOTREACHED/
1150	}
1151
1152	kern_return_t vm_fault(map, vaddr, fault_type, change_wiring,
1153	resume, continuation)
1154	vm_map_t map;
1155	vm_offset_t vaddr;
1156	vm_prot_t fault_type;
1157	boolean_t change_wiring;
1158	boolean_t resume;
1159	void (*continuation)();
1160	{
1161	vm_map_version_t version; /* Map version for verificiation */
1162	boolean_t wired; /* Should mapping be wired down? */
1163	vm_object_t object; /* Top-level object */
1164	vm_offset_t offset; /* Top-level offset */
1165	vm_prot_t prot; /* Protection for mapping */
1166	vm_object_t old_copy_object; /* Saved copy object */
1167	vm_page_t result_page; /* Result of vm_fault_page */
1168	vm_page_t top_page; /* Placeholder page */
1169	kern_return_t kr;
1170
1171	vm_page_t m; /* Fast access to result_page */
1172
1173	if (resume) {
1174	vm_fault_state_t *state =
1175	(vm_fault_state_t *) current_thread()(active_threads[(0)])->ith_othersaved.other;
1176
1177	/*
1178	* Retrieve cached variables and
1179	* continue vm_fault_page.
1180	*/
1181
1182	object = state->vmf_object;
1183	if (object == VM_OBJECT_NULL((vm_object_t) 0))
1184	goto RetryFault;
1185	version = state->vmf_version;
1186	wired = state->vmf_wired;
1187	offset = state->vmf_offset;
1188	prot = state->vmf_prot;
1189
1190	kr = vm_fault_page(object, offset, fault_type,
1191	(change_wiring && !wired), !change_wiring,
1192	&prot, &result_page, &top_page,
1193	TRUE((boolean_t) 1), vm_fault_continue);
1194	goto after_vm_fault_page;
1195	}
1196
1197	if (continuation != (void (*)()) 0) {
1198	/*
1199	* We will probably need to save state.
1200	*/
1201
1202	char * state;
1203
1204	/*
1205	* if this assignment stmt is written as
1206	* 'active_threads[cpu_number()] = kmem_cache_alloc()',
1207	* cpu_number may be evaluated before kmem_cache_alloc;
1208	* if kmem_cache_alloc blocks, cpu_number will be wrong
1209	*/
1210
1211	state = (char *) kmem_cache_alloc(&vm_fault_state_cache);
1212	current_thread()(active_threads[(0)])->ith_othersaved.other = state;
1213
1214	}
1215
1216	RetryFault: ;
1217
1218	/*
1219	* Find the backing store object and offset into
1220	* it to begin the search.
1221	*/
1222
1223	if ((kr = vm_map_lookup(&map, vaddr, fault_type, &version,
1224	&object, &offset,
1225	&prot, &wired)) != KERN_SUCCESS0) {
1226	goto done;
1227	}
1228
1229	/*
1230	* If the page is wired, we must fault for the current protection
1231	* value, to avoid further faults.
1232	*/
1233
1234	if (wired)
1235	fault_type = prot;
1236
1237	/*
1238	* Make a reference to this object to
1239	* prevent its disposal while we are messing with
1240	* it. Once we have the reference, the map is free
1241	* to be diddled. Since objects reference their
1242	* shadows (and copies), they will stay around as well.
1243	*/
1244
1245	assert(object->ref_count > 0)({ if (!(object->ref_count > 0)) Assert("object->ref_count > 0" , "../vm/vm_fault.c", 1245); });
1246	object->ref_count++;
1247	vm_object_paging_begin(object)((object)->paging_in_progress++);
1248
1249	if (continuation != (void (*)()) 0) {
1250	vm_fault_state_t *state =
1251	(vm_fault_state_t *) current_thread()(active_threads[(0)])->ith_othersaved.other;
1252
1253	/*
1254	* Save variables, in case vm_fault_page discards
1255	* our kernel stack and we have to restart.
1256	*/
1257
1258	state->vmf_map = map;
1259	state->vmf_vaddr = vaddr;
1260	state->vmf_fault_type = fault_type;
1261	state->vmf_change_wiring = change_wiring;
1262	state->vmf_continuation = continuation;
1263
1264	state->vmf_version = version;
1265	state->vmf_wired = wired;
1266	state->vmf_object = object;
1267	state->vmf_offset = offset;
1268	state->vmf_prot = prot;
1269
1270	kr = vm_fault_page(object, offset, fault_type,
1271	(change_wiring && !wired), !change_wiring,
1272	&prot, &result_page, &top_page,
1273	FALSE((boolean_t) 0), vm_fault_continue);
1274	} else
1275	{
1276	kr = vm_fault_page(object, offset, fault_type,
1277	(change_wiring && !wired), !change_wiring,
1278	&prot, &result_page, &top_page,
1279	FALSE((boolean_t) 0), (void (*)()) 0);
1280	}
1281	after_vm_fault_page:
1282
1283	/*
1284	* If we didn't succeed, lose the object reference immediately.
1285	*/
1286
1287	if (kr != VM_FAULT_SUCCESS0)
1288	vm_object_deallocate(object);
1289
1290	/*
1291	* See why we failed, and take corrective action.
1292	*/
1293
1294	switch (kr) {
1295	case VM_FAULT_SUCCESS0:
1296	break;
1297	case VM_FAULT_RETRY1:
1298	goto RetryFault;
1299	case VM_FAULT_INTERRUPTED2:
1300	kr = KERN_SUCCESS0;
1301	goto done;
1302	case VM_FAULT_MEMORY_SHORTAGE3:
1303	if (continuation != (void (*)()) 0) {
1304	vm_fault_state_t *state =
1305	(vm_fault_state_t *) current_thread()(active_threads[(0)])->ith_othersaved.other;
1306
1307	/*
1308	* Save variables in case VM_PAGE_WAIT
1309	* discards our kernel stack.
1310	*/
1311
1312	state->vmf_map = map;
1313	state->vmf_vaddr = vaddr;
1314	state->vmf_fault_type = fault_type;
1315	state->vmf_change_wiring = change_wiring;
1316	state->vmf_continuation = continuation;
1317	state->vmf_object = VM_OBJECT_NULL((vm_object_t) 0);
1318
1319	VM_PAGE_WAIT(vm_fault_continue)vm_page_wait(vm_fault_continue);
1320	} else
1321	VM_PAGE_WAIT((void ()()) 0)vm_page_wait((void ()()) 0);
1322	goto RetryFault;
1323	case VM_FAULT_FICTITIOUS_SHORTAGE4:
1324	vm_page_more_fictitious();
1325	goto RetryFault;
1326	case VM_FAULT_MEMORY_ERROR5:
1327	kr = KERN_MEMORY_ERROR10;
1328	goto done;
1329	}
1330
1331	m = result_page;
1332
1333	assert((change_wiring && !wired) ?({ if (!((change_wiring && !wired) ? (top_page == ((vm_page_t ) 0)) : ((top_page == ((vm_page_t) 0)) == (m->object == object )))) Assert("(change_wiring && !wired) ? (top_page == VM_PAGE_NULL) : ((top_page == VM_PAGE_NULL) == (m->object == object))" , "../vm/vm_fault.c", 1335); })
1334	(top_page == VM_PAGE_NULL) :({ if (!((change_wiring && !wired) ? (top_page == ((vm_page_t ) 0)) : ((top_page == ((vm_page_t) 0)) == (m->object == object )))) Assert("(change_wiring && !wired) ? (top_page == VM_PAGE_NULL) : ((top_page == VM_PAGE_NULL) == (m->object == object))" , "../vm/vm_fault.c", 1335); })
1335	((top_page == VM_PAGE_NULL) == (m->object == object)))({ if (!((change_wiring && !wired) ? (top_page == ((vm_page_t ) 0)) : ((top_page == ((vm_page_t) 0)) == (m->object == object )))) Assert("(change_wiring && !wired) ? (top_page == VM_PAGE_NULL) : ((top_page == VM_PAGE_NULL) == (m->object == object))" , "../vm/vm_fault.c", 1335); });
1336
1337	/*
1338	* How to clean up the result of vm_fault_page. This
1339	* happens whether the mapping is entered or not.
1340	*/
1341
1342	#define UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); } \
1343	MACRO_BEGIN({ \
1344	vm_fault_cleanup(m->object, top_page); \
1345	vm_object_deallocate(object); \
1346	MACRO_END})
1347
1348	/*
1349	* What to do with the resulting page from vm_fault_page
1350	* if it doesn't get entered into the physical map:
1351	*/
1352
1353	#define RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); } \
1354	MACRO_BEGIN({ \
1355	PAGE_WAKEUP_DONE(m)({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m)-> wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t) m)), ((boolean_t) 0), 0); } }); \
1356	vm_page_lock_queues(); \
1357	if (!m->active && !m->inactive) \
1358	vm_page_activate(m); \
1359	vm_page_unlock_queues()((void)(&vm_page_queue_lock)); \
1360	MACRO_END})
1361
1362	/*
1363	* We must verify that the maps have not changed
1364	* since our last lookup.
1365	*/
1366
1367	old_copy_object = m->object->copy;
1368
1369	vm_object_unlock(m->object)((void)(&(m->object)->Lock));
1370	while (!vm_map_verify(map, &version)) {
1371	vm_object_t retry_object;
1372	vm_offset_t retry_offset;
1373	vm_prot_t retry_prot;
1374
1375	/*
1376	* To avoid trying to write_lock the map while another
1377	* thread has it read_locked (in vm_map_pageable), we
1378	* do not try for write permission. If the page is
1379	* still writable, we will get write permission. If it
1380	* is not, or has been marked needs_copy, we enter the
1381	* mapping without write permission, and will merely
1382	* take another fault.
1383	*/
1384	kr = vm_map_lookup(&map, vaddr,
1385	fault_type & ~VM_PROT_WRITE((vm_prot_t) 0x02), &version,
1386	&retry_object, &retry_offset, &retry_prot,
1387	&wired);
1388
1389	if (kr != KERN_SUCCESS0) {
1390	vm_object_lock(m->object);
1391	RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); };
1392	UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); };
1393	goto done;
1394	}
1395
1396	vm_object_unlock(retry_object)((void)(&(retry_object)->Lock));
1397	vm_object_lock(m->object);
1398
1399	if ((retry_object != object) \|\|
1400	(retry_offset != offset)) {
1401	RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); };
1402	UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); };
1403	goto RetryFault;
1404	}
1405
1406	/*
1407	* Check whether the protection has changed or the object
1408	* has been copied while we left the map unlocked.
1409	*/
1410	prot &= retry_prot;
1411	vm_object_unlock(m->object)((void)(&(m->object)->Lock));
1412	}
1413	vm_object_lock(m->object);
1414
1415	/*
1416	* If the copy object changed while the top-level object
1417	* was unlocked, then we must take away write permission.
1418	*/
1419
1420	if (m->object->copy != old_copy_object)
1421	prot &= ~VM_PROT_WRITE((vm_prot_t) 0x02);
1422
1423	/*
1424	* If we want to wire down this page, but no longer have
1425	* adequate permissions, we must start all over.
1426	*/
1427
1428	if (wired && (prot != fault_type)) {
1429	vm_map_verify_done(map, &version)(lock_done(&(map)->lock));
1430	RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); };
1431	UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); };
1432	goto RetryFault;
1433	}
1434
1435	/*
1436	* It's critically important that a wired-down page be faulted
1437	* only once in each map for which it is wired.
1438	*/
1439
1440	vm_object_unlock(m->object)((void)(&(m->object)->Lock));
1441
1442	/*
1443	* Put this page into the physical map.
1444	* We had to do the unlock above because pmap_enter
1445	* may cause other faults. The page may be on
1446	* the pageout queues. If the pageout daemon comes
1447	* across the page, it will remove it from the queues.
1448	*/
1449
1450	PMAP_ENTER(map->pmap, vaddr, m, prot, wired)({ pmap_enter( (map->pmap), (vaddr), (m)->phys_addr, (prot ) & ~(m)->page_lock, (wired) ); });
1451
1452	/*
1453	* If the page is not wired down and isn't already
1454	* on a pageout queue, then put it where the
1455	* pageout daemon can find it.
1456	*/
1457	vm_object_lock(m->object);
1458	vm_page_lock_queues();
1459	if (change_wiring) {
1460	if (wired)
1461	vm_page_wire(m);
1462	else
1463	vm_page_unwire(m);
1464	} else if (software_reference_bits) {
1465	if (!m->active && !m->inactive)
1466	vm_page_activate(m);
1467	m->reference = TRUE((boolean_t) 1);
1468	} else {
1469	vm_page_activate(m);
1470	}
1471	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
1472
1473	/*
1474	* Unlock everything, and return
1475	*/
1476
1477	vm_map_verify_done(map, &version)(lock_done(&(map)->lock));
1478	PAGE_WAKEUP_DONE(m)({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m)-> wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t) m)), ((boolean_t) 0), 0); } });
1479	kr = KERN_SUCCESS0;
1480	UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); };
1481
1482	#undef UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); }
1483	#undef RELEASE_PAGE
1484
1485	done:
1486	if (continuation != (void (*)()) 0) {
1487	vm_fault_state_t *state =
1488	(vm_fault_state_t *) current_thread()(active_threads[(0)])->ith_othersaved.other;
1489
1490	kmem_cache_free(&vm_fault_state_cache, (vm_offset_t) state);
1491	(*continuation)(kr);
1492	/NOTREACHED/
1493	}
1494
1495	return(kr);
1496	}
1497
1498	/*
1499	* vm_fault_wire:
1500	*
1501	* Wire down a range of virtual addresses in a map.
1502	*/
1503	void vm_fault_wire(map, entry)
1504	vm_map_t map;
1505	vm_map_entry_t entry;
1506	{
1507
1508	vm_offset_t va;
1509	pmap_t pmap;
1510	vm_offset_t end_addr = entry->vme_endlinks.end;
1511
1512	pmap = vm_map_pmap(map)((map)->pmap);
1513
1514	/*
1515	* Inform the physical mapping system that the
1516	* range of addresses may not fault, so that
1517	* page tables and such can be locked down as well.
1518	*/
1519
1520	pmap_pageable(pmap, entry->vme_startlinks.start, end_addr, FALSE((boolean_t) 0));
1521
1522	/*
1523	* We simulate a fault to get the page and enter it
1524	* in the physical map.
1525	*/
1526
1527	for (va = entry->vme_startlinks.start; va < end_addr; va += PAGE_SIZE(1 << 12)) {
1528	if (vm_fault_wire_fast(map, va, entry) != KERN_SUCCESS0)
1529	(void) vm_fault(map, va, VM_PROT_NONE((vm_prot_t) 0x00), TRUE((boolean_t) 1),
1530	FALSE((boolean_t) 0), (void (*)()) 0);
1531	}
1532	}
1533
1534	/*
1535	* vm_fault_unwire:
1536	*
1537	* Unwire a range of virtual addresses in a map.
1538	*/
1539	void vm_fault_unwire(map, entry)
1540	vm_map_t map;
1541	vm_map_entry_t entry;
1542	{
1543	vm_offset_t va;
1544	pmap_t pmap;
1545	vm_offset_t end_addr = entry->vme_endlinks.end;
1546	vm_object_t object;
1547
1548	pmap = vm_map_pmap(map)((map)->pmap);
1549
1550	object = (entry->is_sub_map)
1551	? VM_OBJECT_NULL((vm_object_t) 0) : entry->object.vm_object;
1552
1553	/*
1554	* Since the pages are wired down, we must be able to
1555	* get their mappings from the physical map system.
1556	*/
1557
1558	for (va = entry->vme_startlinks.start; va < end_addr; va += PAGE_SIZE(1 << 12)) {
1559	pmap_change_wiring(pmap, va, FALSE((boolean_t) 0));
1560
1561	if (object == VM_OBJECT_NULL((vm_object_t) 0)) {
1562	vm_map_lock_set_recursive(map)lock_set_recursive(&(map)->lock);
1563	(void) vm_fault(map, va, VM_PROT_NONE((vm_prot_t) 0x00), TRUE((boolean_t) 1),
1564	FALSE((boolean_t) 0), (void (*)()) 0);
1565	vm_map_lock_clear_recursive(map)lock_clear_recursive(&(map)->lock);
1566	} else {
1567	vm_prot_t prot;
1568	vm_page_t result_page;
1569	vm_page_t top_page;
1570	vm_fault_return_t result;
1571
1572	do {
1573	prot = VM_PROT_NONE((vm_prot_t) 0x00);
1574
1575	vm_object_lock(object);
1576	vm_object_paging_begin(object)((object)->paging_in_progress++);
1577	result = vm_fault_page(object,
1578	entry->offset +
1579	(va - entry->vme_startlinks.start),
1580	VM_PROT_NONE((vm_prot_t) 0x00), TRUE((boolean_t) 1),
1581	FALSE((boolean_t) 0), &prot,
1582	&result_page,
1583	&top_page,
1584	FALSE((boolean_t) 0), (void (*)()) 0);
1585	} while (result == VM_FAULT_RETRY1);
1586
1587	if (result != VM_FAULT_SUCCESS0)
1588	panic("vm_fault_unwire: failure");
1589
1590	vm_page_lock_queues();
1591	vm_page_unwire(result_page);
1592	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
1593	PAGE_WAKEUP_DONE(result_page)({ (result_page)->busy = ((boolean_t) 0); if ((result_page )->wanted) { (result_page)->wanted = ((boolean_t) 0); thread_wakeup_prim ((((event_t) result_page)), ((boolean_t) 0), 0); } });
1594
1595	vm_fault_cleanup(result_page->object, top_page);
1596	}
1597	}
1598
1599	/*
1600	* Inform the physical mapping system that the range
1601	* of addresses may fault, so that page tables and
1602	* such may be unwired themselves.
1603	*/
1604
1605	pmap_pageable(pmap, entry->vme_startlinks.start, end_addr, TRUE((boolean_t) 1));
1606	}
1607
1608	/*
1609	* vm_fault_wire_fast:
1610	*
1611	* Handle common case of a wire down page fault at the given address.
1612	* If successful, the page is inserted into the associated physical map.
1613	* The map entry is passed in to avoid the overhead of a map lookup.
1614	*
1615	* NOTE: the given address should be truncated to the
1616	* proper page address.
1617	*
1618	* KERN_SUCCESS is returned if the page fault is handled; otherwise,
1619	* a standard error specifying why the fault is fatal is returned.
1620	*
1621	* The map in question must be referenced, and remains so.
1622	* Caller has a read lock on the map.
1623	*
1624	* This is a stripped version of vm_fault() for wiring pages. Anything
1625	* other than the common case will return KERN_FAILURE, and the caller
1626	* is expected to call vm_fault().
1627	*/
1628	kern_return_t vm_fault_wire_fast(map, va, entry)
1629	vm_map_t map;
1630	vm_offset_t va;
1631	vm_map_entry_t entry;
1632	{
1633	vm_object_t object;
1634	vm_offset_t offset;
1635	vm_page_t m;
1636	vm_prot_t prot;
1637
1638	vm_stat.faults++; /* needs lock XXX */
1639	current_task()((active_threads[(0)])->task)->faults++;
1640	/*
1641	* Recovery actions
1642	*/
1643
1644	#undef RELEASE_PAGE
1645	#define RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); } { \
1646	PAGE_WAKEUP_DONE(m)({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m)-> wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t) m)), ((boolean_t) 0), 0); } }); \
1647	vm_page_lock_queues(); \
1648	vm_page_unwire(m); \
1649	vm_page_unlock_queues()((void)(&vm_page_queue_lock)); \
1650	}
1651
1652
1653	#undef UNLOCK_THINGS{ object->paging_in_progress--; ((void)(&(object)-> Lock)); }
1654	#define UNLOCK_THINGS{ object->paging_in_progress--; ((void)(&(object)-> Lock)); } { \
1655	object->paging_in_progress--; \
1656	vm_object_unlock(object)((void)(&(object)->Lock)); \
1657	}
1658
1659	#undef UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); }
1660	#define UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); } { \
1661	UNLOCK_THINGS{ object->paging_in_progress--; ((void)(&(object)-> Lock)); }; \
1662	vm_object_deallocate(object); \
1663	}
1664	/*
1665	* Give up and have caller do things the hard way.
1666	*/
1667
1668	#define GIVE_UP{ { { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); }; return(5); } { \
1669	UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); }; \
1670	return(KERN_FAILURE5); \
1671	}
1672
1673
1674	/*
1675	* If this entry is not directly to a vm_object, bail out.
1676	*/
1677	if (entry->is_sub_map)
1678	return(KERN_FAILURE5);
1679
1680	/*
1681	* Find the backing store object and offset into it.
1682	*/
1683
1684	object = entry->object.vm_object;
1685	offset = (va - entry->vme_startlinks.start) + entry->offset;
1686	prot = entry->protection;
1687
1688	/*
1689	* Make a reference to this object to prevent its
1690	* disposal while we are messing with it.
1691	*/
1692
1693	vm_object_lock(object);
1694	assert(object->ref_count > 0)({ if (!(object->ref_count > 0)) Assert("object->ref_count > 0" , "../vm/vm_fault.c", 1694); });
1695	object->ref_count++;
1696	object->paging_in_progress++;
1697
1698	/*
1699	* INVARIANTS (through entire routine):
1700	*
1701	* 1) At all times, we must either have the object
1702	* lock or a busy page in some object to prevent
1703	* some other thread from trying to bring in
1704	* the same page.
1705	*
1706	* 2) Once we have a busy page, we must remove it from
1707	* the pageout queues, so that the pageout daemon
1708	* will not grab it away.
1709	*
1710	*/
1711
1712	/*
1713	* Look for page in top-level object. If it's not there or
1714	* there's something going on, give up.
1715	*/
1716	m = vm_page_lookup(object, offset);
1717	if ((m == VM_PAGE_NULL((vm_page_t) 0)) \|\| (m->error) \|\|
1718	(m->busy) \|\| (m->absent) \|\| (prot & m->page_lock)) {
1719	GIVE_UP{ { { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); }; return(5); };
1720	}
1721
1722	/*
1723	* Wire the page down now. All bail outs beyond this
1724	* point must unwire the page.
1725	*/
1726
1727	vm_page_lock_queues();
1728	vm_page_wire(m);
1729	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
1730
1731	/*
1732	* Mark page busy for other threads.
1733	*/
1734	assert(!m->busy)({ if (!(!m->busy)) Assert("!m->busy", "../vm/vm_fault.c" , 1734); });
1735	m->busy = TRUE((boolean_t) 1);
1736	assert(!m->absent)({ if (!(!m->absent)) Assert("!m->absent", "../vm/vm_fault.c" , 1736); });
1737
1738	/*
1739	* Give up if the page is being written and there's a copy object
1740	*/
1741	if ((object->copy != VM_OBJECT_NULL((vm_object_t) 0)) && (prot & VM_PROT_WRITE((vm_prot_t) 0x02))) {
1742	RELEASE_PAGE(m){ ({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m )->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) m)), ((boolean_t) 0), 0); } }); ; vm_page_unwire(m); ((void )(&vm_page_queue_lock)); };
1743	GIVE_UP{ { { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); }; return(5); };
1744	}
1745
1746	/*
1747	* Put this page into the physical map.
1748	* We have to unlock the object because pmap_enter
1749	* may cause other faults.
1750	*/
1751	vm_object_unlock(object)((void)(&(object)->Lock));
1752
1753	PMAP_ENTER(map->pmap, va, m, prot, TRUE)({ pmap_enter( (map->pmap), (va), (m)->phys_addr, (prot ) & ~(m)->page_lock, (((boolean_t) 1)) ); });
1754
1755	/*
1756	* Must relock object so that paging_in_progress can be cleared.
1757	*/
1758	vm_object_lock(object);
1759
1760	/*
1761	* Unlock everything, and return
1762	*/
1763
1764	PAGE_WAKEUP_DONE(m)({ (m)->busy = ((boolean_t) 0); if ((m)->wanted) { (m)-> wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t) m)), ((boolean_t) 0), 0); } });
1765	UNLOCK_AND_DEALLOCATE{ { object->paging_in_progress--; ((void)(&(object)-> Lock)); }; vm_object_deallocate(object); };
1766
1767	return(KERN_SUCCESS0);
1768
1769	}
1770
1771	/*
1772	* Routine: vm_fault_copy_cleanup
1773	* Purpose:
1774	* Release a page used by vm_fault_copy.
1775	*/
1776
1777	void vm_fault_copy_cleanup(page, top_page)
1778	vm_page_t page;
1779	vm_page_t top_page;
1780	{
1781	vm_object_t object = page->object;
1782
1783	vm_object_lock(object);
1784	PAGE_WAKEUP_DONE(page)({ (page)->busy = ((boolean_t) 0); if ((page)->wanted) { (page)->wanted = ((boolean_t) 0); thread_wakeup_prim((((event_t ) page)), ((boolean_t) 0), 0); } });
1785	vm_page_lock_queues();
1786	if (!page->active && !page->inactive)
1787	vm_page_activate(page);
1788	vm_page_unlock_queues()((void)(&vm_page_queue_lock));
1789	vm_fault_cleanup(object, top_page);
1790	}
1791
1792	/*
1793	* Routine: vm_fault_copy
1794	*
1795	* Purpose:
1796	* Copy pages from one virtual memory object to another --
1797	* neither the source nor destination pages need be resident.
1798	*
1799	* Before actually copying a page, the version associated with
1800	* the destination address map wil be verified.
1801	*
1802	* In/out conditions:
1803	* The caller must hold a reference, but not a lock, to
1804	* each of the source and destination objects and to the
1805	* destination map.
1806	*
1807	* Results:
1808	* Returns KERN_SUCCESS if no errors were encountered in
1809	* reading or writing the data. Returns KERN_INTERRUPTED if
1810	* the operation was interrupted (only possible if the
1811	* "interruptible" argument is asserted). Other return values
1812	* indicate a permanent error in copying the data.
1813	*
1814	* The actual amount of data copied will be returned in the
1815	* "copy_size" argument. In the event that the destination map
1816	* verification failed, this amount may be less than the amount
1817	* requested.
1818	*/
1819	kern_return_t vm_fault_copy(
1820	src_object,
1821	src_offset,
1822	src_size,
1823	dst_object,
1824	dst_offset,
1825	dst_map,
1826	dst_version,
1827	interruptible
1828	)
1829	vm_object_t src_object;
1830	vm_offset_t src_offset;
1831	vm_size_t src_size; / INOUT */
1832	vm_object_t dst_object;
1833	vm_offset_t dst_offset;
1834	vm_map_t dst_map;
1835	vm_map_version_t *dst_version;
1836	boolean_t interruptible;
1837	{
1838	vm_page_t result_page;
1839	vm_prot_t prot;
1840
1841	vm_page_t src_page;
1842	vm_page_t src_top_page;
1843
1844	vm_page_t dst_page;
1845	vm_page_t dst_top_page;
1846
1847	vm_size_t amount_done;
1848	vm_object_t old_copy_object;
1849
1850	#define RETURN(x) \
1851	MACRO_BEGIN({ \
1852	*src_size = amount_done; \
1853	MACRO_RETURNif (((boolean_t) 1)) return(x); \
1854	MACRO_END})
1855
1856	amount_done = 0;
1857	do { /* while (amount_done != src_size) /
1858
1859	RetrySourceFault: ;
1860
1861	if (src_object == VM_OBJECT_NULL((vm_object_t) 0)) {
1862	/*
1863	* No source object. We will just
1864	* zero-fill the page in dst_object.
1865	*/
1866
1867	src_page = VM_PAGE_NULL((vm_page_t) 0);
1868	} else {
1869	prot = VM_PROT_READ((vm_prot_t) 0x01);
1870
1871	vm_object_lock(src_object);
1872	vm_object_paging_begin(src_object)((src_object)->paging_in_progress++);
1873
1874	switch (vm_fault_page(src_object, src_offset,
1875	VM_PROT_READ((vm_prot_t) 0x01), FALSE((boolean_t) 0), interruptible,
1876	&prot, &result_page, &src_top_page,
1877	FALSE((boolean_t) 0), (void (*)()) 0)) {
1878
1879	case VM_FAULT_SUCCESS0:
1880	break;
1881	case VM_FAULT_RETRY1:
1882	goto RetrySourceFault;
1883	case VM_FAULT_INTERRUPTED2:
1884	RETURN(MACH_SEND_INTERRUPTED0x10000007);
1885	case VM_FAULT_MEMORY_SHORTAGE3:
1886	VM_PAGE_WAIT((void ()()) 0)vm_page_wait((void ()()) 0);
1887	goto RetrySourceFault;
1888	case VM_FAULT_FICTITIOUS_SHORTAGE4:
1889	vm_page_more_fictitious();
1890	goto RetrySourceFault;
1891	case VM_FAULT_MEMORY_ERROR5:
1892	return(KERN_MEMORY_ERROR10);
1893	}
1894
1895	src_page = result_page;
1896
1897	assert((src_top_page == VM_PAGE_NULL) ==({ if (!((src_top_page == ((vm_page_t) 0)) == (src_page->object == src_object))) Assert("(src_top_page == VM_PAGE_NULL) == (src_page->object == src_object)" , "../vm/vm_fault.c", 1898); })
1898	(src_page->object == src_object))({ if (!((src_top_page == ((vm_page_t) 0)) == (src_page->object == src_object))) Assert("(src_top_page == VM_PAGE_NULL) == (src_page->object == src_object)" , "../vm/vm_fault.c", 1898); });
1899
1900	assert ((prot & VM_PROT_READ) != VM_PROT_NONE)({ if (!((prot & ((vm_prot_t) 0x01)) != ((vm_prot_t) 0x00 ))) Assert("(prot & VM_PROT_READ) != VM_PROT_NONE", "../vm/vm_fault.c" , 1900); });
1901
1902	vm_object_unlock(src_page->object)((void)(&(src_page->object)->Lock));
1903	}
1904
1905	RetryDestinationFault: ;
1906
1907	prot = VM_PROT_WRITE((vm_prot_t) 0x02);
1908
1909	vm_object_lock(dst_object);
1910	vm_object_paging_begin(dst_object)((dst_object)->paging_in_progress++);
1911
1912	switch (vm_fault_page(dst_object, dst_offset, VM_PROT_WRITE((vm_prot_t) 0x02),
1913	FALSE((boolean_t) 0), FALSE((boolean_t) 0) /* interruptible */,
1914	&prot, &result_page, &dst_top_page,
1915	FALSE((boolean_t) 0), (void (*)()) 0)) {
1916
1917	case VM_FAULT_SUCCESS0:
1918	break;
1919	case VM_FAULT_RETRY1:
1920	goto RetryDestinationFault;
1921	case VM_FAULT_INTERRUPTED2:
1922	if (src_page != VM_PAGE_NULL((vm_page_t) 0))
1923	vm_fault_copy_cleanup(src_page,
1924	src_top_page);
1925	RETURN(MACH_SEND_INTERRUPTED0x10000007);
1926	case VM_FAULT_MEMORY_SHORTAGE3:
1927	VM_PAGE_WAIT((void ()()) 0)vm_page_wait((void ()()) 0);
1928	goto RetryDestinationFault;
1929	case VM_FAULT_FICTITIOUS_SHORTAGE4:
1930	vm_page_more_fictitious();
1931	goto RetryDestinationFault;
1932	case VM_FAULT_MEMORY_ERROR5:
1933	if (src_page != VM_PAGE_NULL((vm_page_t) 0))
1934	vm_fault_copy_cleanup(src_page,
1935	src_top_page);
1936	return(KERN_MEMORY_ERROR10);
1937	}
1938	assert ((prot & VM_PROT_WRITE) != VM_PROT_NONE)({ if (!((prot & ((vm_prot_t) 0x02)) != ((vm_prot_t) 0x00 ))) Assert("(prot & VM_PROT_WRITE) != VM_PROT_NONE", "../vm/vm_fault.c" , 1938); });
1939
1940	dst_page = result_page;
1941
1942	old_copy_object = dst_page->object->copy;
1943
1944	vm_object_unlock(dst_page->object)((void)(&(dst_page->object)->Lock));
1945
1946	if (!vm_map_verify(dst_map, dst_version)) {
1947
1948	BailOut: ;
1949
1950	if (src_page != VM_PAGE_NULL((vm_page_t) 0))
1951	vm_fault_copy_cleanup(src_page, src_top_page);
1952	vm_fault_copy_cleanup(dst_page, dst_top_page);
1953	break;
1954	}
1955
1956
1957	vm_object_lock(dst_page->object);
1958	if (dst_page->object->copy != old_copy_object) {
1959	vm_object_unlock(dst_page->object)((void)(&(dst_page->object)->Lock));
1960	vm_map_verify_done(dst_map, dst_version)(lock_done(&(dst_map)->lock));
1961	goto BailOut;
1962	}
1963	vm_object_unlock(dst_page->object)((void)(&(dst_page->object)->Lock));
1964
1965	/*
1966	* Copy the page, and note that it is dirty
1967	* immediately.
1968	*/
1969
1970	if (src_page == VM_PAGE_NULL((vm_page_t) 0))
1971	vm_page_zero_fill(dst_page);
1972	else
1973	vm_page_copy(src_page, dst_page);
1974	dst_page->dirty = TRUE((boolean_t) 1);
1975
1976	/*
1977	* Unlock everything, and return
1978	*/
1979
1980	vm_map_verify_done(dst_map, dst_version)(lock_done(&(dst_map)->lock));
1981
1982	if (src_page != VM_PAGE_NULL((vm_page_t) 0))
1983	vm_fault_copy_cleanup(src_page, src_top_page);
1984	vm_fault_copy_cleanup(dst_page, dst_top_page);
1985
1986	amount_done += PAGE_SIZE(1 << 12);
1987	src_offset += PAGE_SIZE(1 << 12);
1988	dst_offset += PAGE_SIZE(1 << 12);
1989
1990	} while (amount_done != *src_size);
1991
1992	RETURN(KERN_SUCCESS0);
1993	#undef RETURN
1994
1995	/NOTREACHED/
1996	}
1997
1998
1999
2000
2001
2002	#ifdef notdef
2003
2004	/*
2005	* Routine: vm_fault_page_overwrite
2006	*
2007	* Description:
2008	* A form of vm_fault_page that assumes that the
2009	* resulting page will be overwritten in its entirety,
2010	* making it unnecessary to obtain the correct contents
2011	* of the page.
2012	*
2013	* Implementation:
2014	* XXX Untested. Also unused. Eventually, this technology
2015	* could be used in vm_fault_copy() to advantage.
2016	*/
2017	vm_fault_return_t vm_fault_page_overwrite(dst_object, dst_offset, result_page)
2018	vm_object_t dst_object;
2019	vm_offset_t dst_offset;
2020	vm_page_t result_page; / OUT */
2021	{
2022	vm_page_t dst_page;
2023
2024	#define interruptible FALSE((boolean_t) 0) /* XXX */
2025
2026	while (TRUE((boolean_t) 1)) {
2027	/*
2028	* Look for a page at this offset
2029	*/
2030
2031	while ((dst_page = vm_page_lookup(dst_object, dst_offset))
2032	== VM_PAGE_NULL((vm_page_t) 0)) {
2033	/*
2034	* No page, no problem... just allocate one.
2035	*/
2036
2037	dst_page = vm_page_alloc(dst_object, dst_offset);
2038	if (dst_page == VM_PAGE_NULL((vm_page_t) 0)) {
2039	vm_object_unlock(dst_object)((void)(&(dst_object)->Lock));
2040	VM_PAGE_WAIT((void ()()) 0)vm_page_wait((void ()()) 0);
2041	vm_object_lock(dst_object);
2042	continue;
2043	}
2044
2045	/*
2046	* Pretend that the memory manager
2047	* write-protected the page.
2048	*
2049	* Note that we will be asking for write
2050	* permission without asking for the data
2051	* first.
2052	*/
2053
2054	dst_page->overwriting = TRUE((boolean_t) 1);
2055	dst_page->page_lock = VM_PROT_WRITE((vm_prot_t) 0x02);
2056	dst_page->absent = TRUE((boolean_t) 1);
2057	dst_object->absent_count++;
2058
2059	break;
2060
2061	/*
2062	* When we bail out, we might have to throw
2063	* away the page created here.
2064	*/
2065
2066	#define DISCARD_PAGE \
2067	MACRO_BEGIN({ \
2068	vm_object_lock(dst_object); \
2069	dst_page = vm_page_lookup(dst_object, dst_offset); \
2070	if ((dst_page != VM_PAGE_NULL((vm_page_t) 0)) && dst_page->overwriting) \
2071	VM_PAGE_FREE(dst_page)({ ; vm_page_free(dst_page); ((void)(&vm_page_queue_lock) ); }); \
2072	vm_object_unlock(dst_object)((void)(&(dst_object)->Lock)); \
2073	MACRO_END})
2074	}
2075
2076	/*
2077	* If the page is write-protected...
2078	*/
2079
2080	if (dst_page->page_lock & VM_PROT_WRITE((vm_prot_t) 0x02)) {
2081	/*
2082	* ... and an unlock request hasn't been sent
2083	*/
2084
2085	if ( ! (dst_page->unlock_request & VM_PROT_WRITE((vm_prot_t) 0x02))) {
2086	vm_prot_t u;
2087	kern_return_t rc;
2088
2089	/*
2090	* ... then send one now.
2091	*/
2092
2093	if (!dst_object->pager_ready) {
2094	vm_object_assert_wait(dst_object,({ (dst_object)->all_wanted \|= 1 << (1); assert_wait ((event_t)(((vm_offset_t) dst_object) + (1)), (interruptible) ); })
2095	VM_OBJECT_EVENT_PAGER_READY,({ (dst_object)->all_wanted \|= 1 << (1); assert_wait ((event_t)(((vm_offset_t) dst_object) + (1)), (interruptible) ); })
2096	interruptible)({ (dst_object)->all_wanted \|= 1 << (1); assert_wait ((event_t)(((vm_offset_t) dst_object) + (1)), (interruptible) ); });
2097	vm_object_unlock(dst_object)((void)(&(dst_object)->Lock));
2098	thread_block((void (*)()) 0);
2099	if (current_thread()(active_threads[(0)])->wait_result !=
2100	THREAD_AWAKENED0) {
2101	DISCARD_PAGE;
2102	return(VM_FAULT_INTERRUPTED2);
2103	}
2104	continue;
2105	}
2106
2107	u = dst_page->unlock_request \|= VM_PROT_WRITE((vm_prot_t) 0x02);
2108	vm_object_unlock(dst_object)((void)(&(dst_object)->Lock));
2109
2110	if ((rc = memory_object_data_unlock(
2111	dst_object->pager,
2112	dst_object->pager_request,
2113	dst_offset + dst_object->paging_offset,
2114	PAGE_SIZE(1 << 12),
2115	u)) != KERN_SUCCESS0) {
2116	printf("vm_object_overwrite: memory_object_data_unlock failed\n");
2117	DISCARD_PAGE;
2118	return((rc == MACH_SEND_INTERRUPTED0x10000007) ?
2119	VM_FAULT_INTERRUPTED2 :
2120	VM_FAULT_MEMORY_ERROR5);
2121	}
2122	vm_object_lock(dst_object);
2123	continue;
2124	}
2125
2126	/* ... fall through to wait below */
2127	} else {
2128	/*
2129	* If the page isn't being used for other
2130	* purposes, then we're done.
2131	*/
2132	if ( ! (dst_page->busy \|\| dst_page->absent \|\| dst_page->error) )
2133	break;
2134	}
2135
2136	PAGE_ASSERT_WAIT(dst_page, interruptible)({ (dst_page)->wanted = ((boolean_t) 1); assert_wait((event_t ) (dst_page), (interruptible)); });
2137	vm_object_unlock(dst_object)((void)(&(dst_object)->Lock));
2138	thread_block((void (*)()) 0);
2139	if (current_thread()(active_threads[(0)])->wait_result != THREAD_AWAKENED0) {
2140	DISCARD_PAGE;
2141	return(VM_FAULT_INTERRUPTED2);
2142	}
2143	}
2144
2145	*result_page = dst_page;
2146	return(VM_FAULT_SUCCESS0);
2147
2148	#undef interruptible
2149	#undef DISCARD_PAGE
2150	}
2151
2152	#endif /* notdef */