]> git.saurik.com Git - apple/xnu.git/blob - osfmk/vm/vm_apple_protect.c
projects / apple / xnu.git / blob
? search:
summary | shortlog | log | commit | commitdiff | tree
blame | history | raw | HEAD
xnu-2050.7.9.tar.gz
[apple/xnu.git] / osfmk / vm / vm_apple_protect.c
1 /*
2 * Copyright (c) 2006 Apple Computer, Inc. All rights reserved.
3 *
4 * @APPLE_OSREFERENCE_LICENSE_HEADER_START@
5 *
6 * This file contains Original Code and/or Modifications of Original Code
7 * as defined in and that are subject to the Apple Public Source License
8 * Version 2.0 (the 'License'). You may not use this file except in
9 * compliance with the License. The rights granted to you under the License
10 * may not be used to create, or enable the creation or redistribution of,
11 * unlawful or unlicensed copies of an Apple operating system, or to
12 * circumvent, violate, or enable the circumvention or violation of, any
13 * terms of an Apple operating system software license agreement.
14 *
15 * Please obtain a copy of the License at
16 * http://www.opensource.apple.com/apsl/ and read it before using this file.
17 *
18 * The Original Code and all software distributed under the License are
19 * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
20 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
21 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
22 * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
23 * Please see the License for the specific language governing rights and
24 * limitations under the License.
25 *
26 * @APPLE_OSREFERENCE_LICENSE_HEADER_END@
27 */
28
29 #include <sys/errno.h>
30
31 #include <mach/mach_types.h>
32 #include <mach/mach_traps.h>
33 #include <mach/host_priv.h>
34 #include <mach/kern_return.h>
35 #include <mach/memory_object_control.h>
36 #include <mach/memory_object_types.h>
37 #include <mach/port.h>
38 #include <mach/policy.h>
39 #include <mach/upl.h>
40 #include <mach/thread_act.h>
41 #include <mach/mach_vm.h>
42
43 #include <kern/host.h>
44 #include <kern/kalloc.h>
45 #include <kern/page_decrypt.h>
46 #include <kern/queue.h>
47 #include <kern/thread.h>
48
49 #include <ipc/ipc_port.h>
50 #include <ipc/ipc_space.h>
51
52 #include <default_pager/default_pager_types.h>
53 #include <default_pager/default_pager_object_server.h>
54
55 #include <vm/vm_fault.h>
56 #include <vm/vm_map.h>
57 #include <vm/vm_pageout.h>
58 #include <vm/memory_object.h>
59 #include <vm/vm_pageout.h>
60 #include <vm/vm_protos.h>
61
62
63 /*
64 * APPLE PROTECT MEMORY PAGER
65 *
66 * This external memory manager (EMM) handles memory from the encrypted
67 * sections of some executables protected by the DSMOS kernel extension.
68 *
69 * It mostly handles page-in requests (from memory_object_data_request()) by
70 * getting the encrypted data from its backing VM object, itself backed by
71 * the encrypted file, decrypting it and providing it to VM.
72 *
73 * The decrypted pages will never be dirtied, so the memory manager doesn't
74 * need to handle page-out requests (from memory_object_data_return()). The
75 * pages need to be mapped copy-on-write, so that the originals stay clean.
76 *
77 * We don't expect to have to handle a large number of apple-protected
78 * binaries, so the data structures are very simple (simple linked list)
79 * for now.
80 */
81
82 /* forward declarations */
83 void apple_protect_pager_reference(memory_object_t mem_obj);
84 void apple_protect_pager_deallocate(memory_object_t mem_obj);
85 kern_return_t apple_protect_pager_init(memory_object_t mem_obj,
86 memory_object_control_t control,
87 memory_object_cluster_size_t pg_size);
88 kern_return_t apple_protect_pager_terminate(memory_object_t mem_obj);
89 kern_return_t apple_protect_pager_data_request(memory_object_t mem_obj,
90 memory_object_offset_t offset,
91 memory_object_cluster_size_t length,
92 vm_prot_t protection_required,
93 memory_object_fault_info_t fault_info);
94 kern_return_t apple_protect_pager_data_return(memory_object_t mem_obj,
95 memory_object_offset_t offset,
96 memory_object_cluster_size_t data_cnt,
97 memory_object_offset_t *resid_offset,
98 int *io_error,
99 boolean_t dirty,
100 boolean_t kernel_copy,
101 int upl_flags);
102 kern_return_t apple_protect_pager_data_initialize(memory_object_t mem_obj,
103 memory_object_offset_t offset,
104 memory_object_cluster_size_t data_cnt);
105 kern_return_t apple_protect_pager_data_unlock(memory_object_t mem_obj,
106 memory_object_offset_t offset,
107 memory_object_size_t size,
108 vm_prot_t desired_access);
109 kern_return_t apple_protect_pager_synchronize(memory_object_t mem_obj,
110 memory_object_offset_t offset,
111 memory_object_size_t length,
112 vm_sync_t sync_flags);
113 kern_return_t apple_protect_pager_map(memory_object_t mem_obj,
114 vm_prot_t prot);
115 kern_return_t apple_protect_pager_last_unmap(memory_object_t mem_obj);
116
117 /*
118 * Vector of VM operations for this EMM.
119 * These routines are invoked by VM via the memory_object_*() interfaces.
120 */
121 const struct memory_object_pager_ops apple_protect_pager_ops = {
122 apple_protect_pager_reference,
123 apple_protect_pager_deallocate,
124 apple_protect_pager_init,
125 apple_protect_pager_terminate,
126 apple_protect_pager_data_request,
127 apple_protect_pager_data_return,
128 apple_protect_pager_data_initialize,
129 apple_protect_pager_data_unlock,
130 apple_protect_pager_synchronize,
131 apple_protect_pager_map,
132 apple_protect_pager_last_unmap,
133 NULL, /* data_reclaim */
134 "apple protect pager"
135 };
136
137 /*
138 * The "apple_protect_pager" describes a memory object backed by
139 * the "apple protect" EMM.
140 */
141 typedef struct apple_protect_pager {
142 struct ipc_object_header pager_header; /* fake ip_kotype() */
143 memory_object_pager_ops_t pager_ops; /* == &apple_protect_pager_ops */
144 queue_chain_t pager_queue; /* next & prev pagers */
145 unsigned int ref_count; /* reference count */
146 boolean_t is_ready; /* is this pager ready ? */
147 boolean_t is_mapped; /* is this mem_obj mapped ? */
148 memory_object_control_t pager_control; /* mem object control handle */
149 vm_object_t backing_object; /* VM obj w/ encrypted data */
150 struct pager_crypt_info crypt;
151 } *apple_protect_pager_t;
152 #define APPLE_PROTECT_PAGER_NULL ((apple_protect_pager_t) NULL)
153 #define pager_ikot pager_header.io_bits
154
155 /*
156 * List of memory objects managed by this EMM.
157 * The list is protected by the "apple_protect_pager_lock" lock.
158 */
159 int apple_protect_pager_count = 0; /* number of pagers */
160 int apple_protect_pager_count_mapped = 0; /* number of unmapped pagers */
161 queue_head_t apple_protect_pager_queue;
162 decl_lck_mtx_data(,apple_protect_pager_lock)
163
164 /*
165 * Maximum number of unmapped pagers we're willing to keep around.
166 */
167 int apple_protect_pager_cache_limit = 10;
168
169 /*
170 * Statistics & counters.
171 */
172 int apple_protect_pager_count_max = 0;
173 int apple_protect_pager_count_unmapped_max = 0;
174 int apple_protect_pager_num_trim_max = 0;
175 int apple_protect_pager_num_trim_total = 0;
176
177
178 lck_grp_t apple_protect_pager_lck_grp;
179 lck_grp_attr_t apple_protect_pager_lck_grp_attr;
180 lck_attr_t apple_protect_pager_lck_attr;
181
182
183 /* internal prototypes */
184 apple_protect_pager_t apple_protect_pager_create(vm_object_t backing_object,
185 struct pager_crypt_info *crypt_info);
186 apple_protect_pager_t apple_protect_pager_lookup(memory_object_t mem_obj);
187 void apple_protect_pager_dequeue(apple_protect_pager_t pager);
188 void apple_protect_pager_deallocate_internal(apple_protect_pager_t pager,
189 boolean_t locked);
190 void apple_protect_pager_terminate_internal(apple_protect_pager_t pager);
191 void apple_protect_pager_trim(void);
192
193
194 #if DEBUG
195 int apple_protect_pagerdebug = 0;
196 #define PAGER_ALL 0xffffffff
197 #define PAGER_INIT 0x00000001
198 #define PAGER_PAGEIN 0x00000002
199
200 #define PAGER_DEBUG(LEVEL, A) \
201 MACRO_BEGIN \
202 if ((apple_protect_pagerdebug & LEVEL)==LEVEL) { \
203 printf A; \
204 } \
205 MACRO_END
206 #else
207 #define PAGER_DEBUG(LEVEL, A)
208 #endif
209
210
211 void
212 apple_protect_pager_bootstrap(void)
213 {
214 lck_grp_attr_setdefault(&apple_protect_pager_lck_grp_attr);
215 lck_grp_init(&apple_protect_pager_lck_grp, "apple_protect", &apple_protect_pager_lck_grp_attr);
216 lck_attr_setdefault(&apple_protect_pager_lck_attr);
217 lck_mtx_init(&apple_protect_pager_lock, &apple_protect_pager_lck_grp, &apple_protect_pager_lck_attr);
218 queue_init(&apple_protect_pager_queue);
219 }
220
221 /*
222 * apple_protect_pager_init()
223 *
224 * Initialize the memory object and makes it ready to be used and mapped.
225 */
226 kern_return_t
227 apple_protect_pager_init(
228 memory_object_t mem_obj,
229 memory_object_control_t control,
230 #if !DEBUG
231 __unused
232 #endif
233 memory_object_cluster_size_t pg_size)
234 {
235 apple_protect_pager_t pager;
236 kern_return_t kr;
237 memory_object_attr_info_data_t attributes;
238
239 PAGER_DEBUG(PAGER_ALL,
240 ("apple_protect_pager_init: %p, %p, %x\n",
241 mem_obj, control, pg_size));
242
243 if (control == MEMORY_OBJECT_CONTROL_NULL)
244 return KERN_INVALID_ARGUMENT;
245
246 pager = apple_protect_pager_lookup(mem_obj);
247
248 memory_object_control_reference(control);
249
250 pager->pager_control = control;
251
252 attributes.copy_strategy = MEMORY_OBJECT_COPY_DELAY;
253 /* attributes.cluster_size = (1 << (CLUSTER_SHIFT + PAGE_SHIFT));*/
254 attributes.cluster_size = (1 << (PAGE_SHIFT));
255 attributes.may_cache_object = FALSE;
256 attributes.temporary = TRUE;
257
258 kr = memory_object_change_attributes(
259 control,
260 MEMORY_OBJECT_ATTRIBUTE_INFO,
261 (memory_object_info_t) &attributes,
262 MEMORY_OBJECT_ATTR_INFO_COUNT);
263 if (kr != KERN_SUCCESS)
264 panic("apple_protect_pager_init: "
265 "memory_object_change_attributes() failed");
266
267 return KERN_SUCCESS;
268 }
269
270 /*
271 * apple_protect_data_return()
272 *
273 * Handles page-out requests from VM. This should never happen since
274 * the pages provided by this EMM are not supposed to be dirty or dirtied
275 * and VM should simply discard the contents and reclaim the pages if it
276 * needs to.
277 */
278 kern_return_t
279 apple_protect_pager_data_return(
280 __unused memory_object_t mem_obj,
281 __unused memory_object_offset_t offset,
282 __unused memory_object_cluster_size_t data_cnt,
283 __unused memory_object_offset_t *resid_offset,
284 __unused int *io_error,
285 __unused boolean_t dirty,
286 __unused boolean_t kernel_copy,
287 __unused int upl_flags)
288 {
289 panic("apple_protect_pager_data_return: should never get called");
290 return KERN_FAILURE;
291 }
292
293 kern_return_t
294 apple_protect_pager_data_initialize(
295 __unused memory_object_t mem_obj,
296 __unused memory_object_offset_t offset,
297 __unused memory_object_cluster_size_t data_cnt)
298 {
299 panic("apple_protect_pager_data_initialize: should never get called");
300 return KERN_FAILURE;
301 }
302
303 kern_return_t
304 apple_protect_pager_data_unlock(
305 __unused memory_object_t mem_obj,
306 __unused memory_object_offset_t offset,
307 __unused memory_object_size_t size,
308 __unused vm_prot_t desired_access)
309 {
310 return KERN_FAILURE;
311 }
312
313 /*
314 * apple_protect_pager_data_request()
315 *
316 * Handles page-in requests from VM.
317 */
318 kern_return_t
319 apple_protect_pager_data_request(
320 memory_object_t mem_obj,
321 memory_object_offset_t offset,
322 memory_object_cluster_size_t length,
323 #if !DEBUG
324 __unused
325 #endif
326 vm_prot_t protection_required,
327 memory_object_fault_info_t mo_fault_info)
328 {
329 apple_protect_pager_t pager;
330 memory_object_control_t mo_control;
331 upl_t upl;
332 int upl_flags;
333 upl_size_t upl_size;
334 upl_page_info_t *upl_pl;
335 unsigned int pl_count;
336 vm_object_t src_object, dst_object;
337 kern_return_t kr, retval;
338 vm_map_offset_t kernel_mapping;
339 vm_offset_t src_vaddr, dst_vaddr;
340 vm_offset_t cur_offset;
341 vm_map_entry_t map_entry;
342 kern_return_t error_code;
343 vm_prot_t prot;
344 vm_page_t src_page, top_page;
345 int interruptible;
346 struct vm_object_fault_info fault_info;
347 int ret;
348
349 PAGER_DEBUG(PAGER_ALL, ("apple_protect_pager_data_request: %p, %llx, %x, %x\n", mem_obj, offset, length, protection_required));
350
351 retval = KERN_SUCCESS;
352 src_object = VM_OBJECT_NULL;
353 kernel_mapping = 0;
354 upl = NULL;
355 upl_pl = NULL;
356 fault_info = *((struct vm_object_fault_info *) mo_fault_info);
357 fault_info.stealth = TRUE;
358 fault_info.io_sync = FALSE;
359 fault_info.mark_zf_absent = FALSE;
360 fault_info.batch_pmap_op = FALSE;
361 interruptible = fault_info.interruptible;
362
363 pager = apple_protect_pager_lookup(mem_obj);
364 assert(pager->is_ready);
365 assert(pager->ref_count > 1); /* pager is alive and mapped */
366
367 PAGER_DEBUG(PAGER_PAGEIN, ("apple_protect_pager_data_request: %p, %llx, %x, %x, pager %p\n", mem_obj, offset, length, protection_required, pager));
368
369 /*
370 * Gather in a UPL all the VM pages requested by VM.
371 */
372 mo_control = pager->pager_control;
373
374 upl_size = length;
375 upl_flags =
376 UPL_RET_ONLY_ABSENT |
377 UPL_SET_LITE |
378 UPL_NO_SYNC |
379 UPL_CLEAN_IN_PLACE | /* triggers UPL_CLEAR_DIRTY */
380 UPL_SET_INTERNAL;
381 pl_count = 0;
382 kr = memory_object_upl_request(mo_control,
383 offset, upl_size,
384 &upl, NULL, NULL, upl_flags);
385 if (kr != KERN_SUCCESS) {
386 retval = kr;
387 goto done;
388 }
389 dst_object = mo_control->moc_object;
390 assert(dst_object != VM_OBJECT_NULL);
391
392
393 /*
394 * Reserve 2 virtual pages in the kernel address space to map each
395 * source and destination physical pages when it's their turn to
396 * be processed.
397 */
398 vm_object_reference(kernel_object); /* ref. for mapping */
399 kr = vm_map_find_space(kernel_map,
400 &kernel_mapping,
401 2 * PAGE_SIZE_64,
402 0,
403 0,
404 &map_entry);
405 if (kr != KERN_SUCCESS) {
406 vm_object_deallocate(kernel_object);
407 retval = kr;
408 goto done;
409 }
410 map_entry->object.vm_object = kernel_object;
411 map_entry->offset = kernel_mapping;
412 vm_map_unlock(kernel_map);
413 src_vaddr = CAST_DOWN(vm_offset_t, kernel_mapping);
414 dst_vaddr = CAST_DOWN(vm_offset_t, kernel_mapping + PAGE_SIZE_64);
415
416 /*
417 * We'll map the encrypted data in the kernel address space from the
418 * backing VM object (itself backed by the encrypted file via
419 * the vnode pager).
420 */
421 src_object = pager->backing_object;
422 assert(src_object != VM_OBJECT_NULL);
423 vm_object_reference(src_object); /* to keep the source object alive */
424
425 /*
426 * Fill in the contents of the pages requested by VM.
427 */
428 upl_pl = UPL_GET_INTERNAL_PAGE_LIST(upl);
429 pl_count = length / PAGE_SIZE;
430 for (cur_offset = 0;
431 retval == KERN_SUCCESS && cur_offset < length;
432 cur_offset += PAGE_SIZE) {
433 ppnum_t dst_pnum;
434
435 if (!upl_page_present(upl_pl, (int)(cur_offset / PAGE_SIZE))) {
436 /* this page is not in the UPL: skip it */
437 continue;
438 }
439
440 /*
441 * Map the source (encrypted) page in the kernel's
442 * virtual address space.
443 * We already hold a reference on the src_object.
444 */
445 retry_src_fault:
446 vm_object_lock(src_object);
447 vm_object_paging_begin(src_object);
448 error_code = 0;
449 prot = VM_PROT_READ;
450 kr = vm_fault_page(src_object,
451 offset + cur_offset,
452 VM_PROT_READ,
453 FALSE,
454 &prot,
455 &src_page,
456 &top_page,
457 NULL,
458 &error_code,
459 FALSE,
460 FALSE,
461 &fault_info);
462 switch (kr) {
463 case VM_FAULT_SUCCESS:
464 break;
465 case VM_FAULT_RETRY:
466 goto retry_src_fault;
467 case VM_FAULT_MEMORY_SHORTAGE:
468 if (vm_page_wait(interruptible)) {
469 goto retry_src_fault;
470 }
471 /* fall thru */
472 case VM_FAULT_INTERRUPTED:
473 retval = MACH_SEND_INTERRUPTED;
474 goto done;
475 case VM_FAULT_SUCCESS_NO_VM_PAGE:
476 /* success but no VM page: fail */
477 vm_object_paging_end(src_object);
478 vm_object_unlock(src_object);
479 /*FALLTHROUGH*/
480 case VM_FAULT_MEMORY_ERROR:
481 /* the page is not there ! */
482 if (error_code) {
483 retval = error_code;
484 } else {
485 retval = KERN_MEMORY_ERROR;
486 }
487 goto done;
488 default:
489 panic("apple_protect_pager_data_request: "
490 "vm_fault_page() unexpected error 0x%x\n",
491 kr);
492 }
493 assert(src_page != VM_PAGE_NULL);
494 assert(src_page->busy);
495
496 if (!src_page->active &&
497 !src_page->inactive &&
498 !src_page->throttled) {
499 vm_page_lockspin_queues();
500 if (!src_page->active &&
501 !src_page->inactive &&
502 !src_page->throttled) {
503 vm_page_deactivate(src_page);
504 }
505 vm_page_unlock_queues();
506 }
507
508 /*
509 * Establish an explicit mapping of the source
510 * physical page.
511 */
512 pmap_enter(kernel_pmap,
513 kernel_mapping,
514 src_page->phys_page,
515 VM_PROT_READ,
516 VM_PROT_NONE,
517 0,
518 TRUE);
519 /*
520 * Establish an explicit pmap mapping of the destination
521 * physical page.
522 * We can't do a regular VM mapping because the VM page
523 * is "busy".
524 */
525 dst_pnum = (ppnum_t)
526 upl_phys_page(upl_pl, (int)(cur_offset / PAGE_SIZE));
527 assert(dst_pnum != 0);
528 pmap_enter(kernel_pmap,
529 kernel_mapping + PAGE_SIZE_64,
530 dst_pnum,
531 VM_PROT_READ | VM_PROT_WRITE,
532 VM_PROT_NONE,
533 0,
534 TRUE);
535
536 /*
537 * Decrypt the encrypted contents of the source page
538 * into the destination page.
539 */
540 ret = pager->crypt.page_decrypt((const void *) src_vaddr,
541 (void *) dst_vaddr,
542 offset+cur_offset,
543 pager->crypt.crypt_ops);
544 if (ret) {
545 /*
546 * Decryption failed. Abort the fault.
547 */
548 retval = KERN_ABORTED;
549 } else {
550 /*
551 * Validate the original page...
552 */
553 if (src_page->object->code_signed) {
554 vm_page_validate_cs_mapped(
555 src_page,
556 (const void *) src_vaddr);
557 }
558 /*
559 * ... and transfer the results to the destination page.
560 */
561 UPL_SET_CS_VALIDATED(upl_pl, cur_offset / PAGE_SIZE,
562 src_page->cs_validated);
563 UPL_SET_CS_TAINTED(upl_pl, cur_offset / PAGE_SIZE,
564 src_page->cs_tainted);
565 }
566
567 /*
568 * Remove the pmap mapping of the source and destination pages
569 * in the kernel.
570 */
571 pmap_remove(kernel_pmap,
572 (addr64_t) kernel_mapping,
573 (addr64_t) (kernel_mapping + (2 * PAGE_SIZE_64)));
574
575 /*
576 * Cleanup the result of vm_fault_page() of the source page.
577 */
578 PAGE_WAKEUP_DONE(src_page);
579 vm_object_paging_end(src_page->object);
580 vm_object_unlock(src_page->object);
581 if (top_page != VM_PAGE_NULL) {
582 vm_object_t top_object;
583
584 top_object = top_page->object;
585 vm_object_lock(top_object);
586 VM_PAGE_FREE(top_page);
587 vm_object_paging_end(top_object);
588 vm_object_unlock(top_object);
589 }
590 }
591
592 done:
593 if (upl != NULL) {
594 /* clean up the UPL */
595
596 /*
597 * The pages are currently dirty because we've just been
598 * writing on them, but as far as we're concerned, they're
599 * clean since they contain their "original" contents as
600 * provided by us, the pager.
601 * Tell the UPL to mark them "clean".
602 */
603 upl_clear_dirty(upl, TRUE);
604
605 /* abort or commit the UPL */
606 if (retval != KERN_SUCCESS) {
607 upl_abort(upl, 0);
608 if (retval == KERN_ABORTED) {
609 wait_result_t wait_result;
610
611 /*
612 * We aborted the fault and did not provide
613 * any contents for the requested pages but
614 * the pages themselves are not invalid, so
615 * let's return success and let the caller
616 * retry the fault, in case it might succeed
617 * later (when the decryption code is up and
618 * running in the kernel, for example).
619 */
620 retval = KERN_SUCCESS;
621 /*
622 * Wait a little bit first to avoid using
623 * too much CPU time retrying and failing
624 * the same fault over and over again.
625 */
626 wait_result = assert_wait_timeout(
627 (event_t) apple_protect_pager_data_request,
628 THREAD_UNINT,
629 10000, /* 10ms */
630 NSEC_PER_USEC);
631 assert(wait_result == THREAD_WAITING);
632 wait_result = thread_block(THREAD_CONTINUE_NULL);
633 assert(wait_result == THREAD_TIMED_OUT);
634 }
635 } else {
636 boolean_t empty;
637 upl_commit_range(upl, 0, upl->size,
638 UPL_COMMIT_CS_VALIDATED,
639 upl_pl, pl_count, &empty);
640 }
641
642 /* and deallocate the UPL */
643 upl_deallocate(upl);
644 upl = NULL;
645 }
646 if (kernel_mapping != 0) {
647 /* clean up the mapping of the source and destination pages */
648 kr = vm_map_remove(kernel_map,
649 kernel_mapping,
650 kernel_mapping + (2 * PAGE_SIZE_64),
651 VM_MAP_NO_FLAGS);
652 assert(kr == KERN_SUCCESS);
653 kernel_mapping = 0;
654 src_vaddr = 0;
655 dst_vaddr = 0;
656 }
657 if (src_object != VM_OBJECT_NULL) {
658 vm_object_deallocate(src_object);
659 }
660
661 return retval;
662 }
663
664 /*
665 * apple_protect_pager_reference()
666 *
667 * Get a reference on this memory object.
668 * For external usage only. Assumes that the initial reference count is not 0,
669 * i.e one should not "revive" a dead pager this way.
670 */
671 void
672 apple_protect_pager_reference(
673 memory_object_t mem_obj)
674 {
675 apple_protect_pager_t pager;
676
677 pager = apple_protect_pager_lookup(mem_obj);
678
679 lck_mtx_lock(&apple_protect_pager_lock);
680 assert(pager->ref_count > 0);
681 pager->ref_count++;
682 lck_mtx_unlock(&apple_protect_pager_lock);
683 }
684
685
686 /*
687 * apple_protect_pager_dequeue:
688 *
689 * Removes a pager from the list of pagers.
690 *
691 * The caller must hold "apple_protect_pager_lock".
692 */
693 void
694 apple_protect_pager_dequeue(
695 apple_protect_pager_t pager)
696 {
697 assert(!pager->is_mapped);
698
699 queue_remove(&apple_protect_pager_queue,
700 pager,
701 apple_protect_pager_t,
702 pager_queue);
703 pager->pager_queue.next = NULL;
704 pager->pager_queue.prev = NULL;
705
706 apple_protect_pager_count--;
707 }
708
709 /*
710 * apple_protect_pager_terminate_internal:
711 *
712 * Trigger the asynchronous termination of the memory object associated
713 * with this pager.
714 * When the memory object is terminated, there will be one more call
715 * to memory_object_deallocate() (i.e. apple_protect_pager_deallocate())
716 * to finish the clean up.
717 *
718 * "apple_protect_pager_lock" should not be held by the caller.
719 * We don't need the lock because the pager has already been removed from
720 * the pagers' list and is now ours exclusively.
721 */
722 void
723 apple_protect_pager_terminate_internal(
724 apple_protect_pager_t pager)
725 {
726 assert(pager->is_ready);
727 assert(!pager->is_mapped);
728
729 if (pager->backing_object != VM_OBJECT_NULL) {
730 vm_object_deallocate(pager->backing_object);
731 pager->backing_object = VM_OBJECT_NULL;
732 }
733
734 /* deallocate any crypt module data */
735 if(pager->crypt.crypt_end)
736 pager->crypt.crypt_end(pager->crypt.crypt_ops);
737
738 /* trigger the destruction of the memory object */
739 memory_object_destroy(pager->pager_control, 0);
740 }
741
742 /*
743 * apple_protect_pager_deallocate_internal()
744 *
745 * Release a reference on this pager and free it when the last
746 * reference goes away.
747 * Can be called with apple_protect_pager_lock held or not but always returns
748 * with it unlocked.
749 */
750 void
751 apple_protect_pager_deallocate_internal(
752 apple_protect_pager_t pager,
753 boolean_t locked)
754 {
755 boolean_t needs_trimming;
756 int count_unmapped;
757
758 if (! locked) {
759 lck_mtx_lock(&apple_protect_pager_lock);
760 }
761
762 count_unmapped = (apple_protect_pager_count -
763 apple_protect_pager_count_mapped);
764 if (count_unmapped > apple_protect_pager_cache_limit) {
765 /* we have too many unmapped pagers: trim some */
766 needs_trimming = TRUE;
767 } else {
768 needs_trimming = FALSE;
769 }
770
771 /* drop a reference on this pager */
772 pager->ref_count--;
773
774 if (pager->ref_count == 1) {
775 /*
776 * Only the "named" reference is left, which means that
777 * no one is really holding on to this pager anymore.
778 * Terminate it.
779 */
780 apple_protect_pager_dequeue(pager);
781 /* the pager is all ours: no need for the lock now */
782 lck_mtx_unlock(&apple_protect_pager_lock);
783 apple_protect_pager_terminate_internal(pager);
784 } else if (pager->ref_count == 0) {
785 /*
786 * Dropped the existence reference; the memory object has
787 * been terminated. Do some final cleanup and release the
788 * pager structure.
789 */
790 lck_mtx_unlock(&apple_protect_pager_lock);
791 if (pager->pager_control != MEMORY_OBJECT_CONTROL_NULL) {
792 memory_object_control_deallocate(pager->pager_control);
793 pager->pager_control = MEMORY_OBJECT_CONTROL_NULL;
794 }
795 kfree(pager, sizeof (*pager));
796 pager = APPLE_PROTECT_PAGER_NULL;
797 } else {
798 /* there are still plenty of references: keep going... */
799 lck_mtx_unlock(&apple_protect_pager_lock);
800 }
801
802 if (needs_trimming) {
803 apple_protect_pager_trim();
804 }
805 /* caution: lock is not held on return... */
806 }
807
808 /*
809 * apple_protect_pager_deallocate()
810 *
811 * Release a reference on this pager and free it when the last
812 * reference goes away.
813 */
814 void
815 apple_protect_pager_deallocate(
816 memory_object_t mem_obj)
817 {
818 apple_protect_pager_t pager;
819
820 PAGER_DEBUG(PAGER_ALL, ("apple_protect_pager_deallocate: %p\n", mem_obj));
821 pager = apple_protect_pager_lookup(mem_obj);
822 apple_protect_pager_deallocate_internal(pager, FALSE);
823 }
824
825 /*
826 *
827 */
828 kern_return_t
829 apple_protect_pager_terminate(
830 #if !DEBUG
831 __unused
832 #endif
833 memory_object_t mem_obj)
834 {
835 PAGER_DEBUG(PAGER_ALL, ("apple_protect_pager_terminate: %p\n", mem_obj));
836
837 return KERN_SUCCESS;
838 }
839
840 /*
841 *
842 */
843 kern_return_t
844 apple_protect_pager_synchronize(
845 memory_object_t mem_obj,
846 memory_object_offset_t offset,
847 memory_object_size_t length,
848 __unused vm_sync_t sync_flags)
849 {
850 apple_protect_pager_t pager;
851
852 PAGER_DEBUG(PAGER_ALL, ("apple_protect_pager_synchronize: %p\n", mem_obj));
853
854 pager = apple_protect_pager_lookup(mem_obj);
855
856 memory_object_synchronize_completed(pager->pager_control,
857 offset, length);
858
859 return KERN_SUCCESS;
860 }
861
862 /*
863 * apple_protect_pager_map()
864 *
865 * This allows VM to let us, the EMM, know that this memory object
866 * is currently mapped one or more times. This is called by VM each time
867 * the memory object gets mapped and we take one extra reference on the
868 * memory object to account for all its mappings.
869 */
870 kern_return_t
871 apple_protect_pager_map(
872 memory_object_t mem_obj,
873 __unused vm_prot_t prot)
874 {
875 apple_protect_pager_t pager;
876
877 PAGER_DEBUG(PAGER_ALL, ("apple_protect_pager_map: %p\n", mem_obj));
878
879 pager = apple_protect_pager_lookup(mem_obj);
880
881 lck_mtx_lock(&apple_protect_pager_lock);
882 assert(pager->is_ready);
883 assert(pager->ref_count > 0); /* pager is alive */
884 if (pager->is_mapped == FALSE) {
885 /*
886 * First mapping of this pager: take an extra reference
887 * that will remain until all the mappings of this pager
888 * are removed.
889 */
890 pager->is_mapped = TRUE;
891 pager->ref_count++;
892 apple_protect_pager_count_mapped++;
893 }
894 lck_mtx_unlock(&apple_protect_pager_lock);
895
896 return KERN_SUCCESS;
897 }
898
899 /*
900 * apple_protect_pager_last_unmap()
901 *
902 * This is called by VM when this memory object is no longer mapped anywhere.
903 */
904 kern_return_t
905 apple_protect_pager_last_unmap(
906 memory_object_t mem_obj)
907 {
908 apple_protect_pager_t pager;
909 int count_unmapped;
910
911 PAGER_DEBUG(PAGER_ALL,
912 ("apple_protect_pager_last_unmap: %p\n", mem_obj));
913
914 pager = apple_protect_pager_lookup(mem_obj);
915
916 lck_mtx_lock(&apple_protect_pager_lock);
917 if (pager->is_mapped) {
918 /*
919 * All the mappings are gone, so let go of the one extra
920 * reference that represents all the mappings of this pager.
921 */
922 apple_protect_pager_count_mapped--;
923 count_unmapped = (apple_protect_pager_count -
924 apple_protect_pager_count_mapped);
925 if (count_unmapped > apple_protect_pager_count_unmapped_max) {
926 apple_protect_pager_count_unmapped_max = count_unmapped;
927 }
928 pager->is_mapped = FALSE;
929 apple_protect_pager_deallocate_internal(pager, TRUE);
930 /* caution: deallocate_internal() released the lock ! */
931 } else {
932 lck_mtx_unlock(&apple_protect_pager_lock);
933 }
934
935 return KERN_SUCCESS;
936 }
937
938
939 /*
940 *
941 */
942 apple_protect_pager_t
943 apple_protect_pager_lookup(
944 memory_object_t mem_obj)
945 {
946 apple_protect_pager_t pager;
947
948 pager = (apple_protect_pager_t) mem_obj;
949 assert(pager->pager_ops == &apple_protect_pager_ops);
950 assert(pager->ref_count > 0);
951 return pager;
952 }
953
954 apple_protect_pager_t
955 apple_protect_pager_create(
956 vm_object_t backing_object,
957 struct pager_crypt_info *crypt_info)
958 {
959 apple_protect_pager_t pager, pager2;
960 memory_object_control_t control;
961 kern_return_t kr;
962
963 pager = (apple_protect_pager_t) kalloc(sizeof (*pager));
964 if (pager == APPLE_PROTECT_PAGER_NULL) {
965 return APPLE_PROTECT_PAGER_NULL;
966 }
967
968 /*
969 * The vm_map call takes both named entry ports and raw memory
970 * objects in the same parameter. We need to make sure that
971 * vm_map does not see this object as a named entry port. So,
972 * we reserve the first word in the object for a fake ip_kotype
973 * setting - that will tell vm_map to use it as a memory object.
974 */
975 pager->pager_ops = &apple_protect_pager_ops;
976 pager->pager_ikot = IKOT_MEMORY_OBJECT;
977 pager->is_ready = FALSE;/* not ready until it has a "name" */
978 pager->ref_count = 2; /* existence + setup reference */
979 pager->is_mapped = FALSE;
980 pager->pager_control = MEMORY_OBJECT_CONTROL_NULL;
981 pager->backing_object = backing_object;
982 pager->crypt = *crypt_info;
983
984 vm_object_reference(backing_object);
985
986 lck_mtx_lock(&apple_protect_pager_lock);
987 /* see if anyone raced us to create a pager for the same object */
988 queue_iterate(&apple_protect_pager_queue,
989 pager2,
990 apple_protect_pager_t,
991 pager_queue) {
992 if (pager2->backing_object == backing_object) {
993 break;
994 }
995 }
996 if (! queue_end(&apple_protect_pager_queue,
997 (queue_entry_t) pager2)) {
998 /* while we hold the lock, transfer our setup ref to winner */
999 pager2->ref_count++;
1000 /* we lost the race, down with the loser... */
1001 lck_mtx_unlock(&apple_protect_pager_lock);
1002 vm_object_deallocate(pager->backing_object);
1003 pager->backing_object = VM_OBJECT_NULL;
1004 kfree(pager, sizeof (*pager));
1005 /* ... and go with the winner */
1006 pager = pager2;
1007 /* let the winner make sure the pager gets ready */
1008 return pager;
1009 }
1010
1011 /* enter new pager at the head of our list of pagers */
1012 queue_enter_first(&apple_protect_pager_queue,
1013 pager,
1014 apple_protect_pager_t,
1015 pager_queue);
1016 apple_protect_pager_count++;
1017 if (apple_protect_pager_count > apple_protect_pager_count_max) {
1018 apple_protect_pager_count_max = apple_protect_pager_count;
1019 }
1020 lck_mtx_unlock(&apple_protect_pager_lock);
1021
1022 kr = memory_object_create_named((memory_object_t) pager,
1023 0,
1024 &control);
1025 assert(kr == KERN_SUCCESS);
1026
1027 lck_mtx_lock(&apple_protect_pager_lock);
1028 /* the new pager is now ready to be used */
1029 pager->is_ready = TRUE;
1030 lck_mtx_unlock(&apple_protect_pager_lock);
1031
1032 /* wakeup anyone waiting for this pager to be ready */
1033 thread_wakeup(&pager->is_ready);
1034
1035 return pager;
1036 }
1037
1038 /*
1039 * apple_protect_pager_setup()
1040 *
1041 * Provide the caller with a memory object backed by the provided
1042 * "backing_object" VM object. If such a memory object already exists,
1043 * re-use it, otherwise create a new memory object.
1044 */
1045 memory_object_t
1046 apple_protect_pager_setup(
1047 vm_object_t backing_object,
1048 struct pager_crypt_info *crypt_info)
1049 {
1050 apple_protect_pager_t pager;
1051
1052 lck_mtx_lock(&apple_protect_pager_lock);
1053
1054 queue_iterate(&apple_protect_pager_queue,
1055 pager,
1056 apple_protect_pager_t,
1057 pager_queue) {
1058 if (pager->backing_object == backing_object) {
1059 /* For the same object we must always use the same protection options */
1060 if (!((pager->crypt.page_decrypt == crypt_info->page_decrypt) &&
1061 (pager->crypt.crypt_ops == crypt_info->crypt_ops) )) {
1062 lck_mtx_unlock(&apple_protect_pager_lock);
1063 return MEMORY_OBJECT_NULL;
1064 }
1065 break;
1066 }
1067 }
1068 if (queue_end(&apple_protect_pager_queue,
1069 (queue_entry_t) pager)) {
1070 /* no existing pager for this backing object */
1071 pager = APPLE_PROTECT_PAGER_NULL;
1072 } else {
1073 /* make sure pager doesn't disappear */
1074 pager->ref_count++;
1075 }
1076
1077 lck_mtx_unlock(&apple_protect_pager_lock);
1078
1079 if (pager == APPLE_PROTECT_PAGER_NULL) {
1080 pager = apple_protect_pager_create(backing_object, crypt_info);
1081 if (pager == APPLE_PROTECT_PAGER_NULL) {
1082 return MEMORY_OBJECT_NULL;
1083 }
1084 }
1085
1086 lck_mtx_lock(&apple_protect_pager_lock);
1087 while (!pager->is_ready) {
1088 lck_mtx_sleep(&apple_protect_pager_lock,
1089 LCK_SLEEP_DEFAULT,
1090 &pager->is_ready,
1091 THREAD_UNINT);
1092 }
1093 lck_mtx_unlock(&apple_protect_pager_lock);
1094
1095 return (memory_object_t) pager;
1096 }
1097
1098 void
1099 apple_protect_pager_trim(void)
1100 {
1101 apple_protect_pager_t pager, prev_pager;
1102 queue_head_t trim_queue;
1103 int num_trim;
1104 int count_unmapped;
1105
1106 lck_mtx_lock(&apple_protect_pager_lock);
1107
1108 /*
1109 * We have too many pagers, try and trim some unused ones,
1110 * starting with the oldest pager at the end of the queue.
1111 */
1112 queue_init(&trim_queue);
1113 num_trim = 0;
1114
1115 for (pager = (apple_protect_pager_t)
1116 queue_last(&apple_protect_pager_queue);
1117 !queue_end(&apple_protect_pager_queue,
1118 (queue_entry_t) pager);
1119 pager = prev_pager) {
1120 /* get prev elt before we dequeue */
1121 prev_pager = (apple_protect_pager_t)
1122 queue_prev(&pager->pager_queue);
1123
1124 if (pager->ref_count == 2 &&
1125 pager->is_ready &&
1126 !pager->is_mapped) {
1127 /* this pager can be trimmed */
1128 num_trim++;
1129 /* remove this pager from the main list ... */
1130 apple_protect_pager_dequeue(pager);
1131 /* ... and add it to our trim queue */
1132 queue_enter_first(&trim_queue,
1133 pager,
1134 apple_protect_pager_t,
1135 pager_queue);
1136
1137 count_unmapped = (apple_protect_pager_count -
1138 apple_protect_pager_count_mapped);
1139 if (count_unmapped <= apple_protect_pager_cache_limit) {
1140 /* we have enough pagers to trim */
1141 break;
1142 }
1143 }
1144 }
1145 if (num_trim > apple_protect_pager_num_trim_max) {
1146 apple_protect_pager_num_trim_max = num_trim;
1147 }
1148 apple_protect_pager_num_trim_total += num_trim;
1149
1150 lck_mtx_unlock(&apple_protect_pager_lock);
1151
1152 /* terminate the trimmed pagers */
1153 while (!queue_empty(&trim_queue)) {
1154 queue_remove_first(&trim_queue,
1155 pager,
1156 apple_protect_pager_t,
1157 pager_queue);
1158 pager->pager_queue.next = NULL;
1159 pager->pager_queue.prev = NULL;
1160 assert(pager->ref_count == 2);
1161 /*
1162 * We can't call deallocate_internal() because the pager
1163 * has already been dequeued, but we still need to remove
1164 * a reference.
1165 */
1166 pager->ref_count--;
1167 apple_protect_pager_terminate_internal(pager);
1168 }
1169 }
mirror of XNU