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5042 stop using deprecated atomic functions
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--- old/usr/src/uts/common/vm/seg_kp.c
+++ new/usr/src/uts/common/vm/seg_kp.c
1 1 /*
2 2 * CDDL HEADER START
3 3 *
4 4 * The contents of this file are subject to the terms of the
5 5 * Common Development and Distribution License (the "License").
6 6 * You may not use this file except in compliance with the License.
7 7 *
8 8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9 9 * or http://www.opensolaris.org/os/licensing.
10 10 * See the License for the specific language governing permissions
11 11 * and limitations under the License.
12 12 *
13 13 * When distributing Covered Code, include this CDDL HEADER in each
14 14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15 15 * If applicable, add the following below this CDDL HEADER, with the
16 16 * fields enclosed by brackets "[]" replaced with your own identifying
17 17 * information: Portions Copyright [yyyy] [name of copyright owner]
18 18 *
19 19 * CDDL HEADER END
20 20 */
21 21 /*
22 22 * Copyright (c) 1991, 2010, Oracle and/or its affiliates. All rights reserved.
23 23 */
24 24
25 25 /* Copyright (c) 1984, 1986, 1987, 1988, 1989 AT&T */
26 26 /* All Rights Reserved */
27 27
28 28 /*
29 29 * Portions of this source code were derived from Berkeley 4.3 BSD
30 30 * under license from the Regents of the University of California.
31 31 */
32 32
33 33 /*
34 34 * segkp is a segment driver that administers the allocation and deallocation
35 35 * of pageable variable size chunks of kernel virtual address space. Each
36 36 * allocated resource is page-aligned.
37 37 *
38 38 * The user may specify whether the resource should be initialized to 0,
39 39 * include a redzone, or locked in memory.
40 40 */
41 41
42 42 #include <sys/types.h>
43 43 #include <sys/t_lock.h>
44 44 #include <sys/thread.h>
45 45 #include <sys/param.h>
46 46 #include <sys/errno.h>
47 47 #include <sys/sysmacros.h>
48 48 #include <sys/systm.h>
49 49 #include <sys/buf.h>
50 50 #include <sys/mman.h>
51 51 #include <sys/vnode.h>
52 52 #include <sys/cmn_err.h>
53 53 #include <sys/swap.h>
54 54 #include <sys/tuneable.h>
55 55 #include <sys/kmem.h>
56 56 #include <sys/vmem.h>
57 57 #include <sys/cred.h>
58 58 #include <sys/dumphdr.h>
59 59 #include <sys/debug.h>
60 60 #include <sys/vtrace.h>
61 61 #include <sys/stack.h>
62 62 #include <sys/atomic.h>
63 63 #include <sys/archsystm.h>
64 64 #include <sys/lgrp.h>
65 65
66 66 #include <vm/as.h>
67 67 #include <vm/seg.h>
68 68 #include <vm/seg_kp.h>
69 69 #include <vm/seg_kmem.h>
70 70 #include <vm/anon.h>
71 71 #include <vm/page.h>
72 72 #include <vm/hat.h>
73 73 #include <sys/bitmap.h>
74 74
75 75 /*
76 76 * Private seg op routines
77 77 */
78 78 static void segkp_badop(void);
79 79 static void segkp_dump(struct seg *seg);
80 80 static int segkp_checkprot(struct seg *seg, caddr_t addr, size_t len,
81 81 uint_t prot);
82 82 static int segkp_kluster(struct seg *seg, caddr_t addr, ssize_t delta);
83 83 static int segkp_pagelock(struct seg *seg, caddr_t addr, size_t len,
84 84 struct page ***page, enum lock_type type,
85 85 enum seg_rw rw);
86 86 static void segkp_insert(struct seg *seg, struct segkp_data *kpd);
87 87 static void segkp_delete(struct seg *seg, struct segkp_data *kpd);
88 88 static caddr_t segkp_get_internal(struct seg *seg, size_t len, uint_t flags,
89 89 struct segkp_data **tkpd, struct anon_map *amp);
90 90 static void segkp_release_internal(struct seg *seg,
91 91 struct segkp_data *kpd, size_t len);
92 92 static int segkp_unlock(struct hat *hat, struct seg *seg, caddr_t vaddr,
93 93 size_t len, struct segkp_data *kpd, uint_t flags);
94 94 static int segkp_load(struct hat *hat, struct seg *seg, caddr_t vaddr,
95 95 size_t len, struct segkp_data *kpd, uint_t flags);
96 96 static struct segkp_data *segkp_find(struct seg *seg, caddr_t vaddr);
97 97 static int segkp_getmemid(struct seg *seg, caddr_t addr, memid_t *memidp);
98 98 static lgrp_mem_policy_info_t *segkp_getpolicy(struct seg *seg,
99 99 caddr_t addr);
100 100 static int segkp_capable(struct seg *seg, segcapability_t capability);
101 101
102 102 /*
103 103 * Lock used to protect the hash table(s) and caches.
104 104 */
105 105 static kmutex_t segkp_lock;
106 106
107 107 /*
108 108 * The segkp caches
109 109 */
110 110 static struct segkp_cache segkp_cache[SEGKP_MAX_CACHE];
111 111
112 112 #define SEGKP_BADOP(t) (t(*)())segkp_badop
113 113
114 114 /*
115 115 * When there are fewer than red_minavail bytes left on the stack,
116 116 * segkp_map_red() will map in the redzone (if called). 5000 seems
117 117 * to work reasonably well...
118 118 */
119 119 long red_minavail = 5000;
120 120
121 121 /*
122 122 * will be set to 1 for 32 bit x86 systems only, in startup.c
123 123 */
124 124 int segkp_fromheap = 0;
125 125 ulong_t *segkp_bitmap;
126 126
127 127 /*
128 128 * If segkp_map_red() is called with the redzone already mapped and
129 129 * with less than RED_DEEP_THRESHOLD bytes available on the stack,
130 130 * then the stack situation has become quite serious; if much more stack
131 131 * is consumed, we have the potential of scrogging the next thread/LWP
132 132 * structure. To help debug the "can't happen" panics which may
133 133 * result from this condition, we record hrestime and the calling thread
134 134 * in red_deep_hires and red_deep_thread respectively.
135 135 */
136 136 #define RED_DEEP_THRESHOLD 2000
137 137
138 138 hrtime_t red_deep_hires;
139 139 kthread_t *red_deep_thread;
140 140
141 141 uint32_t red_nmapped;
142 142 uint32_t red_closest = UINT_MAX;
143 143 uint32_t red_ndoubles;
144 144
145 145 pgcnt_t anon_segkp_pages_locked; /* See vm/anon.h */
146 146 pgcnt_t anon_segkp_pages_resv; /* anon reserved by seg_kp */
147 147
148 148 static struct seg_ops segkp_ops = {
149 149 SEGKP_BADOP(int), /* dup */
150 150 SEGKP_BADOP(int), /* unmap */
151 151 SEGKP_BADOP(void), /* free */
152 152 segkp_fault,
153 153 SEGKP_BADOP(faultcode_t), /* faulta */
154 154 SEGKP_BADOP(int), /* setprot */
155 155 segkp_checkprot,
156 156 segkp_kluster,
157 157 SEGKP_BADOP(size_t), /* swapout */
158 158 SEGKP_BADOP(int), /* sync */
159 159 SEGKP_BADOP(size_t), /* incore */
160 160 SEGKP_BADOP(int), /* lockop */
161 161 SEGKP_BADOP(int), /* getprot */
162 162 SEGKP_BADOP(u_offset_t), /* getoffset */
163 163 SEGKP_BADOP(int), /* gettype */
164 164 SEGKP_BADOP(int), /* getvp */
165 165 SEGKP_BADOP(int), /* advise */
166 166 segkp_dump, /* dump */
167 167 segkp_pagelock, /* pagelock */
168 168 SEGKP_BADOP(int), /* setpgsz */
169 169 segkp_getmemid, /* getmemid */
170 170 segkp_getpolicy, /* getpolicy */
171 171 segkp_capable, /* capable */
172 172 };
173 173
174 174
175 175 static void
176 176 segkp_badop(void)
177 177 {
178 178 panic("segkp_badop");
179 179 /*NOTREACHED*/
180 180 }
181 181
182 182 static void segkpinit_mem_config(struct seg *);
183 183
184 184 static uint32_t segkp_indel;
185 185
186 186 /*
187 187 * Allocate the segment specific private data struct and fill it in
188 188 * with the per kp segment mutex, anon ptr. array and hash table.
189 189 */
190 190 int
191 191 segkp_create(struct seg *seg)
192 192 {
193 193 struct segkp_segdata *kpsd;
194 194 size_t np;
195 195
196 196 ASSERT(seg != NULL && seg->s_as == &kas);
197 197 ASSERT(RW_WRITE_HELD(&seg->s_as->a_lock));
198 198
199 199 if (seg->s_size & PAGEOFFSET) {
200 200 panic("Bad segkp size");
201 201 /*NOTREACHED*/
202 202 }
203 203
204 204 kpsd = kmem_zalloc(sizeof (struct segkp_segdata), KM_SLEEP);
205 205
206 206 /*
207 207 * Allocate the virtual memory for segkp and initialize it
208 208 */
209 209 if (segkp_fromheap) {
210 210 np = btop(kvseg.s_size);
211 211 segkp_bitmap = kmem_zalloc(BT_SIZEOFMAP(np), KM_SLEEP);
212 212 kpsd->kpsd_arena = vmem_create("segkp", NULL, 0, PAGESIZE,
213 213 vmem_alloc, vmem_free, heap_arena, 5 * PAGESIZE, VM_SLEEP);
214 214 } else {
215 215 segkp_bitmap = NULL;
216 216 np = btop(seg->s_size);
217 217 kpsd->kpsd_arena = vmem_create("segkp", seg->s_base,
218 218 seg->s_size, PAGESIZE, NULL, NULL, NULL, 5 * PAGESIZE,
219 219 VM_SLEEP);
220 220 }
221 221
222 222 kpsd->kpsd_anon = anon_create(np, ANON_SLEEP | ANON_ALLOC_FORCE);
223 223
224 224 kpsd->kpsd_hash = kmem_zalloc(SEGKP_HASHSZ * sizeof (struct segkp *),
225 225 KM_SLEEP);
226 226 seg->s_data = (void *)kpsd;
227 227 seg->s_ops = &segkp_ops;
228 228 segkpinit_mem_config(seg);
229 229 return (0);
230 230 }
231 231
232 232
233 233 /*
234 234 * Find a free 'freelist' and initialize it with the appropriate attributes
235 235 */
236 236 void *
237 237 segkp_cache_init(struct seg *seg, int maxsize, size_t len, uint_t flags)
238 238 {
239 239 int i;
240 240
241 241 if ((flags & KPD_NO_ANON) && !(flags & KPD_LOCKED))
242 242 return ((void *)-1);
243 243
244 244 mutex_enter(&segkp_lock);
245 245 for (i = 0; i < SEGKP_MAX_CACHE; i++) {
246 246 if (segkp_cache[i].kpf_inuse)
247 247 continue;
248 248 segkp_cache[i].kpf_inuse = 1;
249 249 segkp_cache[i].kpf_max = maxsize;
250 250 segkp_cache[i].kpf_flags = flags;
251 251 segkp_cache[i].kpf_seg = seg;
252 252 segkp_cache[i].kpf_len = len;
253 253 mutex_exit(&segkp_lock);
254 254 return ((void *)(uintptr_t)i);
255 255 }
256 256 mutex_exit(&segkp_lock);
257 257 return ((void *)-1);
258 258 }
259 259
260 260 /*
261 261 * Free all the cache resources.
262 262 */
263 263 void
264 264 segkp_cache_free(void)
265 265 {
266 266 struct segkp_data *kpd;
267 267 struct seg *seg;
268 268 int i;
269 269
270 270 mutex_enter(&segkp_lock);
271 271 for (i = 0; i < SEGKP_MAX_CACHE; i++) {
272 272 if (!segkp_cache[i].kpf_inuse)
273 273 continue;
274 274 /*
275 275 * Disconnect the freelist and process each element
276 276 */
277 277 kpd = segkp_cache[i].kpf_list;
278 278 seg = segkp_cache[i].kpf_seg;
279 279 segkp_cache[i].kpf_list = NULL;
280 280 segkp_cache[i].kpf_count = 0;
281 281 mutex_exit(&segkp_lock);
282 282
283 283 while (kpd != NULL) {
284 284 struct segkp_data *next;
285 285
286 286 next = kpd->kp_next;
287 287 segkp_release_internal(seg, kpd, kpd->kp_len);
288 288 kpd = next;
289 289 }
290 290 mutex_enter(&segkp_lock);
291 291 }
292 292 mutex_exit(&segkp_lock);
293 293 }
294 294
295 295 /*
296 296 * There are 2 entries into segkp_get_internal. The first includes a cookie
297 297 * used to access a pool of cached segkp resources. The second does not
298 298 * use the cache.
299 299 */
300 300 caddr_t
301 301 segkp_get(struct seg *seg, size_t len, uint_t flags)
302 302 {
303 303 struct segkp_data *kpd = NULL;
304 304
305 305 if (segkp_get_internal(seg, len, flags, &kpd, NULL) != NULL) {
306 306 kpd->kp_cookie = -1;
307 307 return (stom(kpd->kp_base, flags));
308 308 }
309 309 return (NULL);
310 310 }
311 311
312 312 /*
313 313 * Return a 'cached' segkp address
314 314 */
315 315 caddr_t
316 316 segkp_cache_get(void *cookie)
317 317 {
318 318 struct segkp_cache *freelist = NULL;
319 319 struct segkp_data *kpd = NULL;
320 320 int index = (int)(uintptr_t)cookie;
321 321 struct seg *seg;
322 322 size_t len;
323 323 uint_t flags;
324 324
325 325 if (index < 0 || index >= SEGKP_MAX_CACHE)
326 326 return (NULL);
327 327 freelist = &segkp_cache[index];
328 328
329 329 mutex_enter(&segkp_lock);
330 330 seg = freelist->kpf_seg;
331 331 flags = freelist->kpf_flags;
332 332 if (freelist->kpf_list != NULL) {
333 333 kpd = freelist->kpf_list;
334 334 freelist->kpf_list = kpd->kp_next;
335 335 freelist->kpf_count--;
336 336 mutex_exit(&segkp_lock);
337 337 kpd->kp_next = NULL;
338 338 segkp_insert(seg, kpd);
339 339 return (stom(kpd->kp_base, flags));
340 340 }
341 341 len = freelist->kpf_len;
342 342 mutex_exit(&segkp_lock);
343 343 if (segkp_get_internal(seg, len, flags, &kpd, NULL) != NULL) {
344 344 kpd->kp_cookie = index;
345 345 return (stom(kpd->kp_base, flags));
346 346 }
347 347 return (NULL);
348 348 }
349 349
350 350 caddr_t
351 351 segkp_get_withanonmap(
352 352 struct seg *seg,
353 353 size_t len,
354 354 uint_t flags,
355 355 struct anon_map *amp)
356 356 {
357 357 struct segkp_data *kpd = NULL;
358 358
359 359 ASSERT(amp != NULL);
360 360 flags |= KPD_HASAMP;
361 361 if (segkp_get_internal(seg, len, flags, &kpd, amp) != NULL) {
362 362 kpd->kp_cookie = -1;
363 363 return (stom(kpd->kp_base, flags));
364 364 }
365 365 return (NULL);
366 366 }
367 367
368 368 /*
369 369 * This does the real work of segkp allocation.
370 370 * Return to client base addr. len must be page-aligned. A null value is
371 371 * returned if there are no more vm resources (e.g. pages, swap). The len
372 372 * and base recorded in the private data structure include the redzone
373 373 * and the redzone length (if applicable). If the user requests a redzone
374 374 * either the first or last page is left unmapped depending whether stacks
375 375 * grow to low or high memory.
376 376 *
377 377 * The client may also specify a no-wait flag. If that is set then the
378 378 * request will choose a non-blocking path when requesting resources.
379 379 * The default is make the client wait.
380 380 */
381 381 static caddr_t
382 382 segkp_get_internal(
383 383 struct seg *seg,
384 384 size_t len,
385 385 uint_t flags,
386 386 struct segkp_data **tkpd,
387 387 struct anon_map *amp)
388 388 {
389 389 struct segkp_segdata *kpsd = (struct segkp_segdata *)seg->s_data;
390 390 struct segkp_data *kpd;
391 391 caddr_t vbase = NULL; /* always first virtual, may not be mapped */
392 392 pgcnt_t np = 0; /* number of pages in the resource */
393 393 pgcnt_t segkpindex;
394 394 long i;
395 395 caddr_t va;
396 396 pgcnt_t pages = 0;
397 397 ulong_t anon_idx = 0;
398 398 int kmflag = (flags & KPD_NOWAIT) ? KM_NOSLEEP : KM_SLEEP;
399 399 caddr_t s_base = (segkp_fromheap) ? kvseg.s_base : seg->s_base;
400 400
401 401 if (len & PAGEOFFSET) {
402 402 panic("segkp_get: len is not page-aligned");
403 403 /*NOTREACHED*/
404 404 }
405 405
406 406 ASSERT(((flags & KPD_HASAMP) == 0) == (amp == NULL));
407 407
408 408 /* Only allow KPD_NO_ANON if we are going to lock it down */
409 409 if ((flags & (KPD_LOCKED|KPD_NO_ANON)) == KPD_NO_ANON)
410 410 return (NULL);
411 411
412 412 if ((kpd = kmem_zalloc(sizeof (struct segkp_data), kmflag)) == NULL)
413 413 return (NULL);
414 414 /*
415 415 * Fix up the len to reflect the REDZONE if applicable
416 416 */
417 417 if (flags & KPD_HASREDZONE)
418 418 len += PAGESIZE;
419 419 np = btop(len);
420 420
421 421 vbase = vmem_alloc(SEGKP_VMEM(seg), len, kmflag | VM_BESTFIT);
422 422 if (vbase == NULL) {
423 423 kmem_free(kpd, sizeof (struct segkp_data));
424 424 return (NULL);
425 425 }
426 426
427 427 /* If locking, reserve physical memory */
428 428 if (flags & KPD_LOCKED) {
429 429 pages = btop(SEGKP_MAPLEN(len, flags));
430 430 if (page_resv(pages, kmflag) == 0) {
431 431 vmem_free(SEGKP_VMEM(seg), vbase, len);
432 432 kmem_free(kpd, sizeof (struct segkp_data));
433 433 return (NULL);
434 434 }
435 435 if ((flags & KPD_NO_ANON) == 0)
436 436 atomic_add_long(&anon_segkp_pages_locked, pages);
437 437 }
438 438
439 439 /*
440 440 * Reserve sufficient swap space for this vm resource. We'll
441 441 * actually allocate it in the loop below, but reserving it
442 442 * here allows us to back out more gracefully than if we
443 443 * had an allocation failure in the body of the loop.
444 444 *
445 445 * Note that we don't need swap space for the red zone page.
446 446 */
447 447 if (amp != NULL) {
448 448 /*
449 449 * The swap reservation has been done, if required, and the
450 450 * anon_hdr is separate.
451 451 */
452 452 anon_idx = 0;
453 453 kpd->kp_anon_idx = anon_idx;
454 454 kpd->kp_anon = amp->ahp;
455 455
456 456 TRACE_5(TR_FAC_VM, TR_ANON_SEGKP, "anon segkp:%p %p %lu %u %u",
457 457 kpd, vbase, len, flags, 1);
458 458
459 459 } else if ((flags & KPD_NO_ANON) == 0) {
460 460 if (anon_resv_zone(SEGKP_MAPLEN(len, flags), NULL) == 0) {
461 461 if (flags & KPD_LOCKED) {
462 462 atomic_add_long(&anon_segkp_pages_locked,
463 463 -pages);
464 464 page_unresv(pages);
465 465 }
466 466 vmem_free(SEGKP_VMEM(seg), vbase, len);
467 467 kmem_free(kpd, sizeof (struct segkp_data));
468 468 return (NULL);
469 469 }
470 470 atomic_add_long(&anon_segkp_pages_resv,
471 471 btop(SEGKP_MAPLEN(len, flags)));
472 472 anon_idx = ((uintptr_t)(vbase - s_base)) >> PAGESHIFT;
473 473 kpd->kp_anon_idx = anon_idx;
474 474 kpd->kp_anon = kpsd->kpsd_anon;
475 475
476 476 TRACE_5(TR_FAC_VM, TR_ANON_SEGKP, "anon segkp:%p %p %lu %u %u",
477 477 kpd, vbase, len, flags, 1);
478 478 } else {
479 479 kpd->kp_anon = NULL;
480 480 kpd->kp_anon_idx = 0;
481 481 }
482 482
483 483 /*
484 484 * Allocate page and anon resources for the virtual address range
485 485 * except the redzone
486 486 */
487 487 if (segkp_fromheap)
488 488 segkpindex = btop((uintptr_t)(vbase - kvseg.s_base));
489 489 for (i = 0, va = vbase; i < np; i++, va += PAGESIZE) {
490 490 page_t *pl[2];
491 491 struct vnode *vp;
492 492 anoff_t off;
493 493 int err;
494 494 page_t *pp = NULL;
495 495
496 496 /*
497 497 * Mark this page to be a segkp page in the bitmap.
498 498 */
499 499 if (segkp_fromheap) {
500 500 BT_ATOMIC_SET(segkp_bitmap, segkpindex);
501 501 segkpindex++;
502 502 }
503 503
504 504 /*
505 505 * If this page is the red zone page, we don't need swap
506 506 * space for it. Note that we skip over the code that
507 507 * establishes MMU mappings, so that the page remains
508 508 * invalid.
509 509 */
510 510 if ((flags & KPD_HASREDZONE) && KPD_REDZONE(kpd) == i)
511 511 continue;
512 512
513 513 if (kpd->kp_anon != NULL) {
514 514 struct anon *ap;
515 515
516 516 ASSERT(anon_get_ptr(kpd->kp_anon, anon_idx + i)
517 517 == NULL);
518 518 /*
519 519 * Determine the "vp" and "off" of the anon slot.
520 520 */
521 521 ap = anon_alloc(NULL, 0);
522 522 if (amp != NULL)
523 523 ANON_LOCK_ENTER(&->a_rwlock, RW_WRITER);
524 524 (void) anon_set_ptr(kpd->kp_anon, anon_idx + i,
525 525 ap, ANON_SLEEP);
526 526 if (amp != NULL)
527 527 ANON_LOCK_EXIT(&->a_rwlock);
528 528 swap_xlate(ap, &vp, &off);
529 529
530 530 /*
531 531 * Create a page with the specified identity. The
532 532 * page is returned with the "shared" lock held.
533 533 */
534 534 err = VOP_GETPAGE(vp, (offset_t)off, PAGESIZE,
535 535 NULL, pl, PAGESIZE, seg, va, S_CREATE,
536 536 kcred, NULL);
537 537 if (err) {
538 538 /*
539 539 * XXX - This should not fail.
540 540 */
541 541 panic("segkp_get: no pages");
542 542 /*NOTREACHED*/
543 543 }
544 544 pp = pl[0];
545 545 } else {
546 546 ASSERT(page_exists(&kvp,
547 547 (u_offset_t)(uintptr_t)va) == NULL);
548 548
549 549 if ((pp = page_create_va(&kvp,
550 550 (u_offset_t)(uintptr_t)va, PAGESIZE,
551 551 (flags & KPD_NOWAIT ? 0 : PG_WAIT) | PG_EXCL |
552 552 PG_NORELOC, seg, va)) == NULL) {
553 553 /*
554 554 * Legitimize resource; then destroy it.
555 555 * Easier than trying to unwind here.
556 556 */
557 557 kpd->kp_flags = flags;
558 558 kpd->kp_base = vbase;
559 559 kpd->kp_len = len;
560 560 segkp_release_internal(seg, kpd, va - vbase);
561 561 return (NULL);
562 562 }
563 563 page_io_unlock(pp);
564 564 }
565 565
566 566 if (flags & KPD_ZERO)
567 567 pagezero(pp, 0, PAGESIZE);
568 568
569 569 /*
570 570 * Load and lock an MMU translation for the page.
571 571 */
572 572 hat_memload(seg->s_as->a_hat, va, pp, (PROT_READ|PROT_WRITE),
573 573 ((flags & KPD_LOCKED) ? HAT_LOAD_LOCK : HAT_LOAD));
574 574
575 575 /*
576 576 * Now, release lock on the page.
577 577 */
578 578 if (flags & KPD_LOCKED) {
579 579 /*
580 580 * Indicate to page_retire framework that this
581 581 * page can only be retired when it is freed.
582 582 */
583 583 PP_SETRAF(pp);
584 584 page_downgrade(pp);
585 585 } else
586 586 page_unlock(pp);
587 587 }
588 588
589 589 kpd->kp_flags = flags;
590 590 kpd->kp_base = vbase;
591 591 kpd->kp_len = len;
592 592 segkp_insert(seg, kpd);
593 593 *tkpd = kpd;
594 594 return (stom(kpd->kp_base, flags));
595 595 }
596 596
597 597 /*
598 598 * Release the resource to cache if the pool(designate by the cookie)
599 599 * has less than the maximum allowable. If inserted in cache,
600 600 * segkp_delete insures element is taken off of active list.
601 601 */
602 602 void
603 603 segkp_release(struct seg *seg, caddr_t vaddr)
604 604 {
605 605 struct segkp_cache *freelist;
606 606 struct segkp_data *kpd = NULL;
607 607
608 608 if ((kpd = segkp_find(seg, vaddr)) == NULL) {
609 609 panic("segkp_release: null kpd");
610 610 /*NOTREACHED*/
611 611 }
612 612
613 613 if (kpd->kp_cookie != -1) {
614 614 freelist = &segkp_cache[kpd->kp_cookie];
615 615 mutex_enter(&segkp_lock);
616 616 if (!segkp_indel && freelist->kpf_count < freelist->kpf_max) {
617 617 segkp_delete(seg, kpd);
618 618 kpd->kp_next = freelist->kpf_list;
619 619 freelist->kpf_list = kpd;
620 620 freelist->kpf_count++;
621 621 mutex_exit(&segkp_lock);
622 622 return;
623 623 } else {
624 624 mutex_exit(&segkp_lock);
625 625 kpd->kp_cookie = -1;
626 626 }
627 627 }
628 628 segkp_release_internal(seg, kpd, kpd->kp_len);
629 629 }
630 630
631 631 /*
632 632 * Free the entire resource. segkp_unlock gets called with the start of the
633 633 * mapped portion of the resource. The length is the size of the mapped
634 634 * portion
635 635 */
636 636 static void
637 637 segkp_release_internal(struct seg *seg, struct segkp_data *kpd, size_t len)
638 638 {
639 639 caddr_t va;
640 640 long i;
641 641 long redzone;
642 642 size_t np;
643 643 page_t *pp;
644 644 struct vnode *vp;
645 645 anoff_t off;
646 646 struct anon *ap;
647 647 pgcnt_t segkpindex;
648 648
649 649 ASSERT(kpd != NULL);
650 650 ASSERT((kpd->kp_flags & KPD_HASAMP) == 0 || kpd->kp_cookie == -1);
651 651 np = btop(len);
652 652
653 653 /* Remove from active hash list */
654 654 if (kpd->kp_cookie == -1) {
655 655 mutex_enter(&segkp_lock);
656 656 segkp_delete(seg, kpd);
657 657 mutex_exit(&segkp_lock);
658 658 }
659 659
660 660 /*
661 661 * Precompute redzone page index.
662 662 */
663 663 redzone = -1;
664 664 if (kpd->kp_flags & KPD_HASREDZONE)
665 665 redzone = KPD_REDZONE(kpd);
666 666
667 667
668 668 va = kpd->kp_base;
669 669
670 670 hat_unload(seg->s_as->a_hat, va, (np << PAGESHIFT),
671 671 ((kpd->kp_flags & KPD_LOCKED) ? HAT_UNLOAD_UNLOCK : HAT_UNLOAD));
672 672 /*
673 673 * Free up those anon resources that are quiescent.
674 674 */
675 675 if (segkp_fromheap)
676 676 segkpindex = btop((uintptr_t)(va - kvseg.s_base));
677 677 for (i = 0; i < np; i++, va += PAGESIZE) {
678 678
679 679 /*
680 680 * Clear the bit for this page from the bitmap.
681 681 */
682 682 if (segkp_fromheap) {
683 683 BT_ATOMIC_CLEAR(segkp_bitmap, segkpindex);
684 684 segkpindex++;
685 685 }
686 686
687 687 if (i == redzone)
688 688 continue;
689 689 if (kpd->kp_anon) {
690 690 /*
691 691 * Free up anon resources and destroy the
692 692 * associated pages.
693 693 *
694 694 * Release the lock if there is one. Have to get the
695 695 * page to do this, unfortunately.
696 696 */
697 697 if (kpd->kp_flags & KPD_LOCKED) {
698 698 ap = anon_get_ptr(kpd->kp_anon,
699 699 kpd->kp_anon_idx + i);
700 700 swap_xlate(ap, &vp, &off);
701 701 /* Find the shared-locked page. */
702 702 pp = page_find(vp, (u_offset_t)off);
703 703 if (pp == NULL) {
704 704 panic("segkp_release: "
705 705 "kp_anon: no page to unlock ");
706 706 /*NOTREACHED*/
707 707 }
708 708 if (PP_ISRAF(pp))
709 709 PP_CLRRAF(pp);
710 710
711 711 page_unlock(pp);
712 712 }
713 713 if ((kpd->kp_flags & KPD_HASAMP) == 0) {
714 714 anon_free(kpd->kp_anon, kpd->kp_anon_idx + i,
715 715 PAGESIZE);
716 716 anon_unresv_zone(PAGESIZE, NULL);
717 717 atomic_add_long(&anon_segkp_pages_resv,
718 718 -1);
719 719 }
720 720 TRACE_5(TR_FAC_VM,
721 721 TR_ANON_SEGKP, "anon segkp:%p %p %lu %u %u",
722 722 kpd, va, PAGESIZE, 0, 0);
723 723 } else {
724 724 if (kpd->kp_flags & KPD_LOCKED) {
725 725 pp = page_find(&kvp, (u_offset_t)(uintptr_t)va);
726 726 if (pp == NULL) {
727 727 panic("segkp_release: "
728 728 "no page to unlock");
729 729 /*NOTREACHED*/
730 730 }
731 731 if (PP_ISRAF(pp))
732 732 PP_CLRRAF(pp);
733 733 /*
734 734 * We should just upgrade the lock here
735 735 * but there is no upgrade that waits.
736 736 */
737 737 page_unlock(pp);
738 738 }
739 739 pp = page_lookup(&kvp, (u_offset_t)(uintptr_t)va,
740 740 SE_EXCL);
741 741 if (pp != NULL)
742 742 page_destroy(pp, 0);
743 743 }
744 744 }
745 745
746 746 /* If locked, release physical memory reservation */
747 747 if (kpd->kp_flags & KPD_LOCKED) {
748 748 pgcnt_t pages = btop(SEGKP_MAPLEN(kpd->kp_len, kpd->kp_flags));
749 749 if ((kpd->kp_flags & KPD_NO_ANON) == 0)
750 750 atomic_add_long(&anon_segkp_pages_locked, -pages);
751 751 page_unresv(pages);
752 752 }
753 753
754 754 vmem_free(SEGKP_VMEM(seg), kpd->kp_base, kpd->kp_len);
755 755 kmem_free(kpd, sizeof (struct segkp_data));
756 756 }
757 757
758 758 /*
759 759 * segkp_map_red() will check the current frame pointer against the
760 760 * stack base. If the amount of stack remaining is questionable
761 761 * (less than red_minavail), then segkp_map_red() will map in the redzone
762 762 * and return 1. Otherwise, it will return 0. segkp_map_red() can
763 763 * _only_ be called when:
764 764 *
765 765 * - it is safe to sleep on page_create_va().
766 766 * - the caller is non-swappable.
767 767 *
768 768 * It is up to the caller to remember whether segkp_map_red() successfully
769 769 * mapped the redzone, and, if so, to call segkp_unmap_red() at a later
770 770 * time. Note that the caller must _remain_ non-swappable until after
771 771 * calling segkp_unmap_red().
772 772 *
773 773 * Currently, this routine is only called from pagefault() (which necessarily
774 774 * satisfies the above conditions).
775 775 */
776 776 #if defined(STACK_GROWTH_DOWN)
777 777 int
778 778 segkp_map_red(void)
779 779 {
780 780 uintptr_t fp = STACK_BIAS + (uintptr_t)getfp();
781 781 #ifndef _LP64
782 782 caddr_t stkbase;
783 783 #endif
784 784
785 785 ASSERT(curthread->t_schedflag & TS_DONT_SWAP);
786 786
787 787 /*
788 788 * Optimize for the common case where we simply return.
789 789 */
790 790 if ((curthread->t_red_pp == NULL) &&
791 791 (fp - (uintptr_t)curthread->t_stkbase >= red_minavail))
792 792 return (0);
793 793
794 794 #if defined(_LP64)
795 795 /*
796 796 * XXX We probably need something better than this.
797 797 */
798 798 panic("kernel stack overflow");
799 799 /*NOTREACHED*/
800 800 #else /* _LP64 */
801 801 if (curthread->t_red_pp == NULL) {
802 802 page_t *red_pp;
803 803 struct seg kseg;
804 804
805 805 caddr_t red_va = (caddr_t)
806 806 (((uintptr_t)curthread->t_stkbase & (uintptr_t)PAGEMASK) -
807 807 PAGESIZE);
808 808
809 809 ASSERT(page_exists(&kvp, (u_offset_t)(uintptr_t)red_va) ==
810 810 NULL);
811 811
812 812 /*
813 813 * Allocate the physical for the red page.
814 814 */
815 815 /*
816 816 * No PG_NORELOC here to avoid waits. Unlikely to get
817 817 * a relocate happening in the short time the page exists
818 818 * and it will be OK anyway.
819 819 */
820 820
821 821 kseg.s_as = &kas;
822 822 red_pp = page_create_va(&kvp, (u_offset_t)(uintptr_t)red_va,
823 823 PAGESIZE, PG_WAIT | PG_EXCL, &kseg, red_va);
824 824 ASSERT(red_pp != NULL);
825 825
826 826 /*
827 827 * So we now have a page to jam into the redzone...
828 828 */
829 829 page_io_unlock(red_pp);
830 830
831 831 hat_memload(kas.a_hat, red_va, red_pp,
832 832 (PROT_READ|PROT_WRITE), HAT_LOAD_LOCK);
↓ open down ↓ |
832 lines elided |
↑ open up ↑ |
833 833 page_downgrade(red_pp);
834 834
835 835 /*
836 836 * The page is left SE_SHARED locked so we can hold on to
837 837 * the page_t pointer.
838 838 */
839 839 curthread->t_red_pp = red_pp;
840 840
841 841 atomic_add_32(&red_nmapped, 1);
842 842 while (fp - (uintptr_t)curthread->t_stkbase < red_closest) {
843 - (void) cas32(&red_closest, red_closest,
843 + (void) atomic_cas_32(&red_closest, red_closest,
844 844 (uint32_t)(fp - (uintptr_t)curthread->t_stkbase));
845 845 }
846 846 return (1);
847 847 }
848 848
849 849 stkbase = (caddr_t)(((uintptr_t)curthread->t_stkbase &
850 850 (uintptr_t)PAGEMASK) - PAGESIZE);
851 851
852 852 atomic_add_32(&red_ndoubles, 1);
853 853
854 854 if (fp - (uintptr_t)stkbase < RED_DEEP_THRESHOLD) {
855 855 /*
856 856 * Oh boy. We're already deep within the mapped-in
857 857 * redzone page, and the caller is trying to prepare
858 858 * for a deep stack run. We're running without a
859 859 * redzone right now: if the caller plows off the
860 860 * end of the stack, it'll plow another thread or
861 861 * LWP structure. That situation could result in
862 862 * a very hard-to-debug panic, so, in the spirit of
863 863 * recording the name of one's killer in one's own
864 864 * blood, we're going to record hrestime and the calling
865 865 * thread.
866 866 */
867 867 red_deep_hires = hrestime.tv_nsec;
868 868 red_deep_thread = curthread;
869 869 }
870 870
871 871 /*
872 872 * If this is a DEBUG kernel, and we've run too deep for comfort, toss.
873 873 */
874 874 ASSERT(fp - (uintptr_t)stkbase >= RED_DEEP_THRESHOLD);
875 875 return (0);
876 876 #endif /* _LP64 */
877 877 }
878 878
879 879 void
880 880 segkp_unmap_red(void)
881 881 {
882 882 page_t *pp;
883 883 caddr_t red_va = (caddr_t)(((uintptr_t)curthread->t_stkbase &
884 884 (uintptr_t)PAGEMASK) - PAGESIZE);
885 885
886 886 ASSERT(curthread->t_red_pp != NULL);
887 887 ASSERT(curthread->t_schedflag & TS_DONT_SWAP);
888 888
889 889 /*
890 890 * Because we locked the mapping down, we can't simply rely
891 891 * on page_destroy() to clean everything up; we need to call
892 892 * hat_unload() to explicitly unlock the mapping resources.
893 893 */
894 894 hat_unload(kas.a_hat, red_va, PAGESIZE, HAT_UNLOAD_UNLOCK);
895 895
896 896 pp = curthread->t_red_pp;
897 897
898 898 ASSERT(pp == page_find(&kvp, (u_offset_t)(uintptr_t)red_va));
899 899
900 900 /*
901 901 * Need to upgrade the SE_SHARED lock to SE_EXCL.
902 902 */
903 903 if (!page_tryupgrade(pp)) {
904 904 /*
905 905 * As there is now wait for upgrade, release the
906 906 * SE_SHARED lock and wait for SE_EXCL.
907 907 */
908 908 page_unlock(pp);
909 909 pp = page_lookup(&kvp, (u_offset_t)(uintptr_t)red_va, SE_EXCL);
910 910 /* pp may be NULL here, hence the test below */
911 911 }
912 912
913 913 /*
914 914 * Destroy the page, with dontfree set to zero (i.e. free it).
915 915 */
916 916 if (pp != NULL)
917 917 page_destroy(pp, 0);
918 918 curthread->t_red_pp = NULL;
919 919 }
920 920 #else
921 921 #error Red stacks only supported with downwards stack growth.
922 922 #endif
923 923
924 924 /*
925 925 * Handle a fault on an address corresponding to one of the
926 926 * resources in the segkp segment.
927 927 */
928 928 faultcode_t
929 929 segkp_fault(
930 930 struct hat *hat,
931 931 struct seg *seg,
932 932 caddr_t vaddr,
933 933 size_t len,
934 934 enum fault_type type,
935 935 enum seg_rw rw)
936 936 {
937 937 struct segkp_data *kpd = NULL;
938 938 int err;
939 939
940 940 ASSERT(seg->s_as == &kas && RW_READ_HELD(&seg->s_as->a_lock));
941 941
942 942 /*
943 943 * Sanity checks.
944 944 */
945 945 if (type == F_PROT) {
946 946 panic("segkp_fault: unexpected F_PROT fault");
947 947 /*NOTREACHED*/
948 948 }
949 949
950 950 if ((kpd = segkp_find(seg, vaddr)) == NULL)
951 951 return (FC_NOMAP);
952 952
953 953 mutex_enter(&kpd->kp_lock);
954 954
955 955 if (type == F_SOFTLOCK) {
956 956 ASSERT(!(kpd->kp_flags & KPD_LOCKED));
957 957 /*
958 958 * The F_SOFTLOCK case has more stringent
959 959 * range requirements: the given range must exactly coincide
960 960 * with the resource's mapped portion. Note reference to
961 961 * redzone is handled since vaddr would not equal base
962 962 */
963 963 if (vaddr != stom(kpd->kp_base, kpd->kp_flags) ||
964 964 len != SEGKP_MAPLEN(kpd->kp_len, kpd->kp_flags)) {
965 965 mutex_exit(&kpd->kp_lock);
966 966 return (FC_MAKE_ERR(EFAULT));
967 967 }
968 968
969 969 if ((err = segkp_load(hat, seg, vaddr, len, kpd, KPD_LOCKED))) {
970 970 mutex_exit(&kpd->kp_lock);
971 971 return (FC_MAKE_ERR(err));
972 972 }
973 973 kpd->kp_flags |= KPD_LOCKED;
974 974 mutex_exit(&kpd->kp_lock);
975 975 return (0);
976 976 }
977 977
978 978 if (type == F_INVAL) {
979 979 ASSERT(!(kpd->kp_flags & KPD_NO_ANON));
980 980
981 981 /*
982 982 * Check if we touched the redzone. Somewhat optimistic
983 983 * here if we are touching the redzone of our own stack
984 984 * since we wouldn't have a stack to get this far...
985 985 */
986 986 if ((kpd->kp_flags & KPD_HASREDZONE) &&
987 987 btop((uintptr_t)(vaddr - kpd->kp_base)) == KPD_REDZONE(kpd))
988 988 panic("segkp_fault: accessing redzone");
989 989
990 990 /*
991 991 * This fault may occur while the page is being F_SOFTLOCK'ed.
992 992 * Return since a 2nd segkp_load is unnecessary and also would
993 993 * result in the page being locked twice and eventually
994 994 * hang the thread_reaper thread.
995 995 */
996 996 if (kpd->kp_flags & KPD_LOCKED) {
997 997 mutex_exit(&kpd->kp_lock);
998 998 return (0);
999 999 }
1000 1000
1001 1001 err = segkp_load(hat, seg, vaddr, len, kpd, kpd->kp_flags);
1002 1002 mutex_exit(&kpd->kp_lock);
1003 1003 return (err ? FC_MAKE_ERR(err) : 0);
1004 1004 }
1005 1005
1006 1006 if (type == F_SOFTUNLOCK) {
1007 1007 uint_t flags;
1008 1008
1009 1009 /*
1010 1010 * Make sure the addr is LOCKED and it has anon backing
1011 1011 * before unlocking
1012 1012 */
1013 1013 if ((kpd->kp_flags & (KPD_LOCKED|KPD_NO_ANON)) != KPD_LOCKED) {
1014 1014 panic("segkp_fault: bad unlock");
1015 1015 /*NOTREACHED*/
1016 1016 }
1017 1017
1018 1018 if (vaddr != stom(kpd->kp_base, kpd->kp_flags) ||
1019 1019 len != SEGKP_MAPLEN(kpd->kp_len, kpd->kp_flags)) {
1020 1020 panic("segkp_fault: bad range");
1021 1021 /*NOTREACHED*/
1022 1022 }
1023 1023
1024 1024 if (rw == S_WRITE)
1025 1025 flags = kpd->kp_flags | KPD_WRITEDIRTY;
1026 1026 else
1027 1027 flags = kpd->kp_flags;
1028 1028 err = segkp_unlock(hat, seg, vaddr, len, kpd, flags);
1029 1029 kpd->kp_flags &= ~KPD_LOCKED;
1030 1030 mutex_exit(&kpd->kp_lock);
1031 1031 return (err ? FC_MAKE_ERR(err) : 0);
1032 1032 }
1033 1033 mutex_exit(&kpd->kp_lock);
1034 1034 panic("segkp_fault: bogus fault type: %d\n", type);
1035 1035 /*NOTREACHED*/
1036 1036 }
1037 1037
1038 1038 /*
1039 1039 * Check that the given protections suffice over the range specified by
1040 1040 * vaddr and len. For this segment type, the only issue is whether or
1041 1041 * not the range lies completely within the mapped part of an allocated
1042 1042 * resource.
1043 1043 */
1044 1044 /* ARGSUSED */
1045 1045 static int
1046 1046 segkp_checkprot(struct seg *seg, caddr_t vaddr, size_t len, uint_t prot)
1047 1047 {
1048 1048 struct segkp_data *kpd = NULL;
1049 1049 caddr_t mbase;
1050 1050 size_t mlen;
1051 1051
1052 1052 if ((kpd = segkp_find(seg, vaddr)) == NULL)
1053 1053 return (EACCES);
1054 1054
1055 1055 mutex_enter(&kpd->kp_lock);
1056 1056 mbase = stom(kpd->kp_base, kpd->kp_flags);
1057 1057 mlen = SEGKP_MAPLEN(kpd->kp_len, kpd->kp_flags);
1058 1058 if (len > mlen || vaddr < mbase ||
1059 1059 ((vaddr + len) > (mbase + mlen))) {
1060 1060 mutex_exit(&kpd->kp_lock);
1061 1061 return (EACCES);
1062 1062 }
1063 1063 mutex_exit(&kpd->kp_lock);
1064 1064 return (0);
1065 1065 }
1066 1066
1067 1067
1068 1068 /*
1069 1069 * Check to see if it makes sense to do kluster/read ahead to
1070 1070 * addr + delta relative to the mapping at addr. We assume here
1071 1071 * that delta is a signed PAGESIZE'd multiple (which can be negative).
1072 1072 *
1073 1073 * For seg_u we always "approve" of this action from our standpoint.
1074 1074 */
1075 1075 /*ARGSUSED*/
1076 1076 static int
1077 1077 segkp_kluster(struct seg *seg, caddr_t addr, ssize_t delta)
1078 1078 {
1079 1079 return (0);
1080 1080 }
1081 1081
1082 1082 /*
1083 1083 * Load and possibly lock intra-slot resources in the range given by
1084 1084 * vaddr and len.
1085 1085 */
1086 1086 static int
1087 1087 segkp_load(
1088 1088 struct hat *hat,
1089 1089 struct seg *seg,
1090 1090 caddr_t vaddr,
1091 1091 size_t len,
1092 1092 struct segkp_data *kpd,
1093 1093 uint_t flags)
1094 1094 {
1095 1095 caddr_t va;
1096 1096 caddr_t vlim;
1097 1097 ulong_t i;
1098 1098 uint_t lock;
1099 1099
1100 1100 ASSERT(MUTEX_HELD(&kpd->kp_lock));
1101 1101
1102 1102 len = P2ROUNDUP(len, PAGESIZE);
1103 1103
1104 1104 /* If locking, reserve physical memory */
1105 1105 if (flags & KPD_LOCKED) {
1106 1106 pgcnt_t pages = btop(len);
1107 1107 if ((kpd->kp_flags & KPD_NO_ANON) == 0)
1108 1108 atomic_add_long(&anon_segkp_pages_locked, pages);
1109 1109 (void) page_resv(pages, KM_SLEEP);
1110 1110 }
1111 1111
1112 1112 /*
1113 1113 * Loop through the pages in the given range.
1114 1114 */
1115 1115 va = (caddr_t)((uintptr_t)vaddr & (uintptr_t)PAGEMASK);
1116 1116 vaddr = va;
1117 1117 vlim = va + len;
1118 1118 lock = flags & KPD_LOCKED;
1119 1119 i = ((uintptr_t)(va - kpd->kp_base)) >> PAGESHIFT;
1120 1120 for (; va < vlim; va += PAGESIZE, i++) {
1121 1121 page_t *pl[2]; /* second element NULL terminator */
1122 1122 struct vnode *vp;
1123 1123 anoff_t off;
1124 1124 int err;
1125 1125 struct anon *ap;
1126 1126
1127 1127 /*
1128 1128 * Summon the page. If it's not resident, arrange
1129 1129 * for synchronous i/o to pull it in.
1130 1130 */
1131 1131 ap = anon_get_ptr(kpd->kp_anon, kpd->kp_anon_idx + i);
1132 1132 swap_xlate(ap, &vp, &off);
1133 1133
1134 1134 /*
1135 1135 * The returned page list will have exactly one entry,
1136 1136 * which is returned to us already kept.
1137 1137 */
1138 1138 err = VOP_GETPAGE(vp, (offset_t)off, PAGESIZE, NULL,
1139 1139 pl, PAGESIZE, seg, va, S_READ, kcred, NULL);
1140 1140
1141 1141 if (err) {
1142 1142 /*
1143 1143 * Back out of what we've done so far.
1144 1144 */
1145 1145 (void) segkp_unlock(hat, seg, vaddr,
1146 1146 (va - vaddr), kpd, flags);
1147 1147 return (err);
1148 1148 }
1149 1149
1150 1150 /*
1151 1151 * Load an MMU translation for the page.
1152 1152 */
1153 1153 hat_memload(hat, va, pl[0], (PROT_READ|PROT_WRITE),
1154 1154 lock ? HAT_LOAD_LOCK : HAT_LOAD);
1155 1155
1156 1156 if (!lock) {
1157 1157 /*
1158 1158 * Now, release "shared" lock on the page.
1159 1159 */
1160 1160 page_unlock(pl[0]);
1161 1161 }
1162 1162 }
1163 1163 return (0);
1164 1164 }
1165 1165
1166 1166 /*
1167 1167 * At the very least unload the mmu-translations and unlock the range if locked
1168 1168 * Can be called with the following flag value KPD_WRITEDIRTY which specifies
1169 1169 * any dirty pages should be written to disk.
1170 1170 */
1171 1171 static int
1172 1172 segkp_unlock(
1173 1173 struct hat *hat,
1174 1174 struct seg *seg,
1175 1175 caddr_t vaddr,
1176 1176 size_t len,
1177 1177 struct segkp_data *kpd,
1178 1178 uint_t flags)
1179 1179 {
1180 1180 caddr_t va;
1181 1181 caddr_t vlim;
1182 1182 ulong_t i;
1183 1183 struct page *pp;
1184 1184 struct vnode *vp;
1185 1185 anoff_t off;
1186 1186 struct anon *ap;
1187 1187
1188 1188 #ifdef lint
1189 1189 seg = seg;
1190 1190 #endif /* lint */
1191 1191
1192 1192 ASSERT(MUTEX_HELD(&kpd->kp_lock));
1193 1193
1194 1194 /*
1195 1195 * Loop through the pages in the given range. It is assumed
1196 1196 * segkp_unlock is called with page aligned base
1197 1197 */
1198 1198 va = vaddr;
1199 1199 vlim = va + len;
1200 1200 i = ((uintptr_t)(va - kpd->kp_base)) >> PAGESHIFT;
1201 1201 hat_unload(hat, va, len,
1202 1202 ((flags & KPD_LOCKED) ? HAT_UNLOAD_UNLOCK : HAT_UNLOAD));
1203 1203 for (; va < vlim; va += PAGESIZE, i++) {
1204 1204 /*
1205 1205 * Find the page associated with this part of the
1206 1206 * slot, tracking it down through its associated swap
1207 1207 * space.
1208 1208 */
1209 1209 ap = anon_get_ptr(kpd->kp_anon, kpd->kp_anon_idx + i);
1210 1210 swap_xlate(ap, &vp, &off);
1211 1211
1212 1212 if (flags & KPD_LOCKED) {
1213 1213 if ((pp = page_find(vp, off)) == NULL) {
1214 1214 if (flags & KPD_LOCKED) {
1215 1215 panic("segkp_softunlock: missing page");
1216 1216 /*NOTREACHED*/
1217 1217 }
1218 1218 }
1219 1219 } else {
1220 1220 /*
1221 1221 * Nothing to do if the slot is not locked and the
1222 1222 * page doesn't exist.
1223 1223 */
1224 1224 if ((pp = page_lookup(vp, off, SE_SHARED)) == NULL)
1225 1225 continue;
1226 1226 }
1227 1227
1228 1228 /*
1229 1229 * If the page doesn't have any translations, is
1230 1230 * dirty and not being shared, then push it out
1231 1231 * asynchronously and avoid waiting for the
1232 1232 * pageout daemon to do it for us.
1233 1233 *
1234 1234 * XXX - Do we really need to get the "exclusive"
1235 1235 * lock via an upgrade?
1236 1236 */
1237 1237 if ((flags & KPD_WRITEDIRTY) && !hat_page_is_mapped(pp) &&
1238 1238 hat_ismod(pp) && page_tryupgrade(pp)) {
1239 1239 /*
1240 1240 * Hold the vnode before releasing the page lock to
1241 1241 * prevent it from being freed and re-used by some
1242 1242 * other thread.
1243 1243 */
1244 1244 VN_HOLD(vp);
1245 1245 page_unlock(pp);
1246 1246
1247 1247 /*
1248 1248 * Want most powerful credentials we can get so
1249 1249 * use kcred.
1250 1250 */
1251 1251 (void) VOP_PUTPAGE(vp, (offset_t)off, PAGESIZE,
1252 1252 B_ASYNC | B_FREE, kcred, NULL);
1253 1253 VN_RELE(vp);
1254 1254 } else {
1255 1255 page_unlock(pp);
1256 1256 }
1257 1257 }
1258 1258
1259 1259 /* If unlocking, release physical memory */
1260 1260 if (flags & KPD_LOCKED) {
1261 1261 pgcnt_t pages = btopr(len);
1262 1262 if ((kpd->kp_flags & KPD_NO_ANON) == 0)
1263 1263 atomic_add_long(&anon_segkp_pages_locked, -pages);
1264 1264 page_unresv(pages);
1265 1265 }
1266 1266 return (0);
1267 1267 }
1268 1268
1269 1269 /*
1270 1270 * Insert the kpd in the hash table.
1271 1271 */
1272 1272 static void
1273 1273 segkp_insert(struct seg *seg, struct segkp_data *kpd)
1274 1274 {
1275 1275 struct segkp_segdata *kpsd = (struct segkp_segdata *)seg->s_data;
1276 1276 int index;
1277 1277
1278 1278 /*
1279 1279 * Insert the kpd based on the address that will be returned
1280 1280 * via segkp_release.
1281 1281 */
1282 1282 index = SEGKP_HASH(stom(kpd->kp_base, kpd->kp_flags));
1283 1283 mutex_enter(&segkp_lock);
1284 1284 kpd->kp_next = kpsd->kpsd_hash[index];
1285 1285 kpsd->kpsd_hash[index] = kpd;
1286 1286 mutex_exit(&segkp_lock);
1287 1287 }
1288 1288
1289 1289 /*
1290 1290 * Remove kpd from the hash table.
1291 1291 */
1292 1292 static void
1293 1293 segkp_delete(struct seg *seg, struct segkp_data *kpd)
1294 1294 {
1295 1295 struct segkp_segdata *kpsd = (struct segkp_segdata *)seg->s_data;
1296 1296 struct segkp_data **kpp;
1297 1297 int index;
1298 1298
1299 1299 ASSERT(MUTEX_HELD(&segkp_lock));
1300 1300
1301 1301 index = SEGKP_HASH(stom(kpd->kp_base, kpd->kp_flags));
1302 1302 for (kpp = &kpsd->kpsd_hash[index];
1303 1303 *kpp != NULL; kpp = &((*kpp)->kp_next)) {
1304 1304 if (*kpp == kpd) {
1305 1305 *kpp = kpd->kp_next;
1306 1306 return;
1307 1307 }
1308 1308 }
1309 1309 panic("segkp_delete: unable to find element to delete");
1310 1310 /*NOTREACHED*/
1311 1311 }
1312 1312
1313 1313 /*
1314 1314 * Find the kpd associated with a vaddr.
1315 1315 *
1316 1316 * Most of the callers of segkp_find will pass the vaddr that
1317 1317 * hashes to the desired index, but there are cases where
1318 1318 * this is not true in which case we have to (potentially) scan
1319 1319 * the whole table looking for it. This should be very rare
1320 1320 * (e.g. a segkp_fault(F_INVAL) on an address somewhere in the
1321 1321 * middle of the segkp_data region).
1322 1322 */
1323 1323 static struct segkp_data *
1324 1324 segkp_find(struct seg *seg, caddr_t vaddr)
1325 1325 {
1326 1326 struct segkp_segdata *kpsd = (struct segkp_segdata *)seg->s_data;
1327 1327 struct segkp_data *kpd;
1328 1328 int i;
1329 1329 int stop;
1330 1330
1331 1331 i = stop = SEGKP_HASH(vaddr);
1332 1332 mutex_enter(&segkp_lock);
1333 1333 do {
1334 1334 for (kpd = kpsd->kpsd_hash[i]; kpd != NULL;
1335 1335 kpd = kpd->kp_next) {
1336 1336 if (vaddr >= kpd->kp_base &&
1337 1337 vaddr < kpd->kp_base + kpd->kp_len) {
1338 1338 mutex_exit(&segkp_lock);
1339 1339 return (kpd);
1340 1340 }
1341 1341 }
1342 1342 if (--i < 0)
1343 1343 i = SEGKP_HASHSZ - 1; /* Wrap */
1344 1344 } while (i != stop);
1345 1345 mutex_exit(&segkp_lock);
1346 1346 return (NULL); /* Not found */
1347 1347 }
1348 1348
1349 1349 /*
1350 1350 * returns size of swappable area.
1351 1351 */
1352 1352 size_t
1353 1353 swapsize(caddr_t v)
1354 1354 {
1355 1355 struct segkp_data *kpd;
1356 1356
1357 1357 if ((kpd = segkp_find(segkp, v)) != NULL)
1358 1358 return (SEGKP_MAPLEN(kpd->kp_len, kpd->kp_flags));
1359 1359 else
1360 1360 return (NULL);
1361 1361 }
1362 1362
1363 1363 /*
1364 1364 * Dump out all the active segkp pages
1365 1365 */
1366 1366 static void
1367 1367 segkp_dump(struct seg *seg)
1368 1368 {
1369 1369 int i;
1370 1370 struct segkp_data *kpd;
1371 1371 struct segkp_segdata *kpsd = (struct segkp_segdata *)seg->s_data;
1372 1372
1373 1373 for (i = 0; i < SEGKP_HASHSZ; i++) {
1374 1374 for (kpd = kpsd->kpsd_hash[i];
1375 1375 kpd != NULL; kpd = kpd->kp_next) {
1376 1376 pfn_t pfn;
1377 1377 caddr_t addr;
1378 1378 caddr_t eaddr;
1379 1379
1380 1380 addr = kpd->kp_base;
1381 1381 eaddr = addr + kpd->kp_len;
1382 1382 while (addr < eaddr) {
1383 1383 ASSERT(seg->s_as == &kas);
1384 1384 pfn = hat_getpfnum(seg->s_as->a_hat, addr);
1385 1385 if (pfn != PFN_INVALID)
1386 1386 dump_addpage(seg->s_as, addr, pfn);
1387 1387 addr += PAGESIZE;
1388 1388 dump_timeleft = dump_timeout;
1389 1389 }
1390 1390 }
1391 1391 }
1392 1392 }
1393 1393
1394 1394 /*ARGSUSED*/
1395 1395 static int
1396 1396 segkp_pagelock(struct seg *seg, caddr_t addr, size_t len,
1397 1397 struct page ***ppp, enum lock_type type, enum seg_rw rw)
1398 1398 {
1399 1399 return (ENOTSUP);
1400 1400 }
1401 1401
1402 1402 /*ARGSUSED*/
1403 1403 static int
1404 1404 segkp_getmemid(struct seg *seg, caddr_t addr, memid_t *memidp)
1405 1405 {
1406 1406 return (ENODEV);
1407 1407 }
1408 1408
1409 1409 /*ARGSUSED*/
1410 1410 static lgrp_mem_policy_info_t *
1411 1411 segkp_getpolicy(struct seg *seg, caddr_t addr)
1412 1412 {
1413 1413 return (NULL);
1414 1414 }
1415 1415
1416 1416 /*ARGSUSED*/
1417 1417 static int
1418 1418 segkp_capable(struct seg *seg, segcapability_t capability)
1419 1419 {
1420 1420 return (0);
1421 1421 }
1422 1422
1423 1423 #include <sys/mem_config.h>
1424 1424
1425 1425 /*ARGSUSED*/
1426 1426 static void
1427 1427 segkp_mem_config_post_add(void *arg, pgcnt_t delta_pages)
1428 1428 {}
1429 1429
1430 1430 /*
1431 1431 * During memory delete, turn off caches so that pages are not held.
1432 1432 * A better solution may be to unlock the pages while they are
1433 1433 * in the cache so that they may be collected naturally.
1434 1434 */
1435 1435
1436 1436 /*ARGSUSED*/
1437 1437 static int
1438 1438 segkp_mem_config_pre_del(void *arg, pgcnt_t delta_pages)
1439 1439 {
1440 1440 atomic_add_32(&segkp_indel, 1);
1441 1441 segkp_cache_free();
1442 1442 return (0);
1443 1443 }
1444 1444
1445 1445 /*ARGSUSED*/
1446 1446 static void
1447 1447 segkp_mem_config_post_del(void *arg, pgcnt_t delta_pages, int cancelled)
1448 1448 {
1449 1449 atomic_add_32(&segkp_indel, -1);
1450 1450 }
1451 1451
1452 1452 static kphysm_setup_vector_t segkp_mem_config_vec = {
1453 1453 KPHYSM_SETUP_VECTOR_VERSION,
1454 1454 segkp_mem_config_post_add,
1455 1455 segkp_mem_config_pre_del,
1456 1456 segkp_mem_config_post_del,
1457 1457 };
1458 1458
1459 1459 static void
1460 1460 segkpinit_mem_config(struct seg *seg)
1461 1461 {
1462 1462 int ret;
1463 1463
1464 1464 ret = kphysm_setup_func_register(&segkp_mem_config_vec, (void *)seg);
1465 1465 ASSERT(ret == 0);
1466 1466 }
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