uvm_page.c revision 1.169
1/* $OpenBSD: uvm_page.c,v 1.169 2022/08/01 14:15:46 mpi Exp $ */ 2/* $NetBSD: uvm_page.c,v 1.44 2000/11/27 08:40:04 chs Exp $ */ 3 4/* 5 * Copyright (c) 1997 Charles D. Cranor and Washington University. 6 * Copyright (c) 1991, 1993, The Regents of the University of California. 7 * 8 * All rights reserved. 9 * 10 * This code is derived from software contributed to Berkeley by 11 * The Mach Operating System project at Carnegie-Mellon University. 12 * 13 * Redistribution and use in source and binary forms, with or without 14 * modification, are permitted provided that the following conditions 15 * are met: 16 * 1. Redistributions of source code must retain the above copyright 17 * notice, this list of conditions and the following disclaimer. 18 * 2. Redistributions in binary form must reproduce the above copyright 19 * notice, this list of conditions and the following disclaimer in the 20 * documentation and/or other materials provided with the distribution. 21 * 3. Neither the name of the University nor the names of its contributors 22 * may be used to endorse or promote products derived from this software 23 * without specific prior written permission. 24 * 25 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 26 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 27 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 28 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 29 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 30 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 31 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 32 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 33 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 34 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 35 * SUCH DAMAGE. 36 * 37 * @(#)vm_page.c 8.3 (Berkeley) 3/21/94 38 * from: Id: uvm_page.c,v 1.1.2.18 1998/02/06 05:24:42 chs Exp 39 * 40 * 41 * Copyright (c) 1987, 1990 Carnegie-Mellon University. 42 * All rights reserved. 43 * 44 * Permission to use, copy, modify and distribute this software and 45 * its documentation is hereby granted, provided that both the copyright 46 * notice and this permission notice appear in all copies of the 47 * software, derivative works or modified versions, and any portions 48 * thereof, and that both notices appear in supporting documentation. 49 * 50 * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" 51 * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND 52 * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. 53 * 54 * Carnegie Mellon requests users of this software to return to 55 * 56 * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU 57 * School of Computer Science 58 * Carnegie Mellon University 59 * Pittsburgh PA 15213-3890 60 * 61 * any improvements or extensions that they make and grant Carnegie the 62 * rights to redistribute these changes. 63 */ 64 65/* 66 * uvm_page.c: page ops. 67 */ 68 69#include <sys/param.h> 70#include <sys/systm.h> 71#include <sys/sched.h> 72#include <sys/vnode.h> 73#include <sys/mount.h> 74#include <sys/proc.h> 75#include <sys/smr.h> 76 77#include <uvm/uvm.h> 78 79/* 80 * for object trees 81 */ 82RBT_GENERATE(uvm_objtree, vm_page, objt, uvm_pagecmp); 83 84int 85uvm_pagecmp(const struct vm_page *a, const struct vm_page *b) 86{ 87 return a->offset < b->offset ? -1 : a->offset > b->offset; 88} 89 90/* 91 * global vars... XXXCDC: move to uvm. structure. 92 */ 93/* 94 * physical memory config is stored in vm_physmem. 95 */ 96struct vm_physseg vm_physmem[VM_PHYSSEG_MAX]; /* XXXCDC: uvm.physmem */ 97int vm_nphysseg = 0; /* XXXCDC: uvm.nphysseg */ 98 99/* 100 * Some supported CPUs in a given architecture don't support all 101 * of the things necessary to do idle page zero'ing efficiently. 102 * We therefore provide a way to disable it from machdep code here. 103 */ 104 105/* 106 * local variables 107 */ 108/* 109 * these variables record the values returned by vm_page_bootstrap, 110 * for debugging purposes. The implementation of uvm_pageboot_alloc 111 * and pmap_startup here also uses them internally. 112 */ 113static vaddr_t virtual_space_start; 114static vaddr_t virtual_space_end; 115 116/* 117 * local prototypes 118 */ 119static void uvm_pageinsert(struct vm_page *); 120static void uvm_pageremove(struct vm_page *); 121int uvm_page_owner_locked_p(struct vm_page *); 122 123/* 124 * inline functions 125 */ 126/* 127 * uvm_pageinsert: insert a page in the object 128 * 129 * => caller must lock object 130 * => call should have already set pg's object and offset pointers 131 * and bumped the version counter 132 */ 133inline static void 134uvm_pageinsert(struct vm_page *pg) 135{ 136 struct vm_page *dupe; 137 138 KASSERT(UVM_OBJ_IS_DUMMY(pg->uobject) || 139 rw_write_held(pg->uobject->vmobjlock)); 140 KASSERT((pg->pg_flags & PG_TABLED) == 0); 141 142 dupe = RBT_INSERT(uvm_objtree, &pg->uobject->memt, pg); 143 /* not allowed to insert over another page */ 144 KASSERT(dupe == NULL); 145 atomic_setbits_int(&pg->pg_flags, PG_TABLED); 146 pg->uobject->uo_npages++; 147} 148 149/* 150 * uvm_page_remove: remove page from object 151 * 152 * => caller must lock object 153 */ 154static inline void 155uvm_pageremove(struct vm_page *pg) 156{ 157 KASSERT(UVM_OBJ_IS_DUMMY(pg->uobject) || 158 rw_write_held(pg->uobject->vmobjlock)); 159 KASSERT(pg->pg_flags & PG_TABLED); 160 161 RBT_REMOVE(uvm_objtree, &pg->uobject->memt, pg); 162 163 atomic_clearbits_int(&pg->pg_flags, PG_TABLED); 164 pg->uobject->uo_npages--; 165 pg->uobject = NULL; 166 pg->pg_version++; 167} 168 169/* 170 * uvm_page_init: init the page system. called from uvm_init(). 171 * 172 * => we return the range of kernel virtual memory in kvm_startp/kvm_endp 173 */ 174void 175uvm_page_init(vaddr_t *kvm_startp, vaddr_t *kvm_endp) 176{ 177 vsize_t freepages, pagecount, n; 178 vm_page_t pagearray, curpg; 179 int lcv, i; 180 paddr_t paddr, pgno; 181 struct vm_physseg *seg; 182 183 /* 184 * init the page queues and page queue locks 185 */ 186 187 TAILQ_INIT(&uvm.page_active); 188 TAILQ_INIT(&uvm.page_inactive); 189 mtx_init(&uvm.pageqlock, IPL_VM); 190 mtx_init(&uvm.fpageqlock, IPL_VM); 191 uvm_pmr_init(); 192 193 /* 194 * allocate vm_page structures. 195 */ 196 197 /* 198 * sanity check: 199 * before calling this function the MD code is expected to register 200 * some free RAM with the uvm_page_physload() function. our job 201 * now is to allocate vm_page structures for this memory. 202 */ 203 204 if (vm_nphysseg == 0) 205 panic("uvm_page_bootstrap: no memory pre-allocated"); 206 207 /* 208 * first calculate the number of free pages... 209 * 210 * note that we use start/end rather than avail_start/avail_end. 211 * this allows us to allocate extra vm_page structures in case we 212 * want to return some memory to the pool after booting. 213 */ 214 215 freepages = 0; 216 for (lcv = 0, seg = vm_physmem; lcv < vm_nphysseg ; lcv++, seg++) 217 freepages += (seg->end - seg->start); 218 219 /* 220 * we now know we have (PAGE_SIZE * freepages) bytes of memory we can 221 * use. for each page of memory we use we need a vm_page structure. 222 * thus, the total number of pages we can use is the total size of 223 * the memory divided by the PAGE_SIZE plus the size of the vm_page 224 * structure. we add one to freepages as a fudge factor to avoid 225 * truncation errors (since we can only allocate in terms of whole 226 * pages). 227 */ 228 229 pagecount = (((paddr_t)freepages + 1) << PAGE_SHIFT) / 230 (PAGE_SIZE + sizeof(struct vm_page)); 231 pagearray = (vm_page_t)uvm_pageboot_alloc(pagecount * 232 sizeof(struct vm_page)); 233 memset(pagearray, 0, pagecount * sizeof(struct vm_page)); 234 235 /* init the vm_page structures and put them in the correct place. */ 236 for (lcv = 0, seg = vm_physmem; lcv < vm_nphysseg ; lcv++, seg++) { 237 n = seg->end - seg->start; 238 if (n > pagecount) { 239 panic("uvm_page_init: lost %ld page(s) in init", 240 (long)(n - pagecount)); 241 /* XXXCDC: shouldn't happen? */ 242 /* n = pagecount; */ 243 } 244 245 /* set up page array pointers */ 246 seg->pgs = pagearray; 247 pagearray += n; 248 pagecount -= n; 249 seg->lastpg = seg->pgs + (n - 1); 250 251 /* init and free vm_pages (we've already zeroed them) */ 252 pgno = seg->start; 253 paddr = ptoa(pgno); 254 for (i = 0, curpg = seg->pgs; i < n; 255 i++, curpg++, pgno++, paddr += PAGE_SIZE) { 256 curpg->phys_addr = paddr; 257 VM_MDPAGE_INIT(curpg); 258 if (pgno >= seg->avail_start && 259 pgno < seg->avail_end) { 260 uvmexp.npages++; 261 } 262 } 263 264 /* Add pages to free pool. */ 265 uvm_pmr_freepages(&seg->pgs[seg->avail_start - seg->start], 266 seg->avail_end - seg->avail_start); 267 } 268 269 /* 270 * pass up the values of virtual_space_start and 271 * virtual_space_end (obtained by uvm_pageboot_alloc) to the upper 272 * layers of the VM. 273 */ 274 275 *kvm_startp = round_page(virtual_space_start); 276 *kvm_endp = trunc_page(virtual_space_end); 277 278 /* init locks for kernel threads */ 279 mtx_init(&uvm.aiodoned_lock, IPL_BIO); 280 281 /* 282 * init reserve thresholds 283 * XXXCDC - values may need adjusting 284 */ 285 uvmexp.reserve_pagedaemon = 4; 286 uvmexp.reserve_kernel = 8; 287 uvmexp.anonminpct = 10; 288 uvmexp.vnodeminpct = 10; 289 uvmexp.vtextminpct = 5; 290 uvmexp.anonmin = uvmexp.anonminpct * 256 / 100; 291 uvmexp.vnodemin = uvmexp.vnodeminpct * 256 / 100; 292 uvmexp.vtextmin = uvmexp.vtextminpct * 256 / 100; 293 294 uvm.page_init_done = TRUE; 295} 296 297/* 298 * uvm_setpagesize: set the page size 299 * 300 * => sets page_shift and page_mask from uvmexp.pagesize. 301 */ 302void 303uvm_setpagesize(void) 304{ 305 if (uvmexp.pagesize == 0) 306 uvmexp.pagesize = DEFAULT_PAGE_SIZE; 307 uvmexp.pagemask = uvmexp.pagesize - 1; 308 if ((uvmexp.pagemask & uvmexp.pagesize) != 0) 309 panic("uvm_setpagesize: page size not a power of two"); 310 for (uvmexp.pageshift = 0; ; uvmexp.pageshift++) 311 if ((1 << uvmexp.pageshift) == uvmexp.pagesize) 312 break; 313} 314 315/* 316 * uvm_pageboot_alloc: steal memory from physmem for bootstrapping 317 */ 318vaddr_t 319uvm_pageboot_alloc(vsize_t size) 320{ 321#if defined(PMAP_STEAL_MEMORY) 322 vaddr_t addr; 323 324 /* 325 * defer bootstrap allocation to MD code (it may want to allocate 326 * from a direct-mapped segment). pmap_steal_memory should round 327 * off virtual_space_start/virtual_space_end. 328 */ 329 330 addr = pmap_steal_memory(size, &virtual_space_start, 331 &virtual_space_end); 332 333 return addr; 334 335#else /* !PMAP_STEAL_MEMORY */ 336 337 static boolean_t initialized = FALSE; 338 vaddr_t addr, vaddr; 339 paddr_t paddr; 340 341 /* round to page size */ 342 size = round_page(size); 343 344 /* on first call to this function, initialize ourselves. */ 345 if (initialized == FALSE) { 346 pmap_virtual_space(&virtual_space_start, &virtual_space_end); 347 348 /* round it the way we like it */ 349 virtual_space_start = round_page(virtual_space_start); 350 virtual_space_end = trunc_page(virtual_space_end); 351 352 initialized = TRUE; 353 } 354 355 /* allocate virtual memory for this request */ 356 if (virtual_space_start == virtual_space_end || 357 (virtual_space_end - virtual_space_start) < size) 358 panic("uvm_pageboot_alloc: out of virtual space"); 359 360 addr = virtual_space_start; 361 362#ifdef PMAP_GROWKERNEL 363 /* 364 * If the kernel pmap can't map the requested space, 365 * then allocate more resources for it. 366 */ 367 if (uvm_maxkaddr < (addr + size)) { 368 uvm_maxkaddr = pmap_growkernel(addr + size); 369 if (uvm_maxkaddr < (addr + size)) 370 panic("uvm_pageboot_alloc: pmap_growkernel() failed"); 371 } 372#endif 373 374 virtual_space_start += size; 375 376 /* allocate and mapin physical pages to back new virtual pages */ 377 for (vaddr = round_page(addr) ; vaddr < addr + size ; 378 vaddr += PAGE_SIZE) { 379 if (!uvm_page_physget(&paddr)) 380 panic("uvm_pageboot_alloc: out of memory"); 381 382 /* 383 * Note this memory is no longer managed, so using 384 * pmap_kenter is safe. 385 */ 386 pmap_kenter_pa(vaddr, paddr, PROT_READ | PROT_WRITE); 387 } 388 pmap_update(pmap_kernel()); 389 return addr; 390#endif /* PMAP_STEAL_MEMORY */ 391} 392 393#if !defined(PMAP_STEAL_MEMORY) 394/* 395 * uvm_page_physget: "steal" one page from the vm_physmem structure. 396 * 397 * => attempt to allocate it off the end of a segment in which the "avail" 398 * values match the start/end values. if we can't do that, then we 399 * will advance both values (making them equal, and removing some 400 * vm_page structures from the non-avail area). 401 * => return false if out of memory. 402 */ 403 404boolean_t 405uvm_page_physget(paddr_t *paddrp) 406{ 407 int lcv; 408 struct vm_physseg *seg; 409 410 /* pass 1: try allocating from a matching end */ 411#if (VM_PHYSSEG_STRAT == VM_PSTRAT_BIGFIRST) || \ 412 (VM_PHYSSEG_STRAT == VM_PSTRAT_BSEARCH) 413 for (lcv = vm_nphysseg - 1, seg = vm_physmem + lcv; lcv >= 0; 414 lcv--, seg--) 415#else 416 for (lcv = 0, seg = vm_physmem; lcv < vm_nphysseg ; lcv++, seg++) 417#endif 418 { 419 if (uvm.page_init_done == TRUE) 420 panic("uvm_page_physget: called _after_ bootstrap"); 421 422 /* try from front */ 423 if (seg->avail_start == seg->start && 424 seg->avail_start < seg->avail_end) { 425 *paddrp = ptoa(seg->avail_start); 426 seg->avail_start++; 427 seg->start++; 428 /* nothing left? nuke it */ 429 if (seg->avail_start == seg->end) { 430 if (vm_nphysseg == 1) 431 panic("uvm_page_physget: out of memory!"); 432 vm_nphysseg--; 433 for (; lcv < vm_nphysseg; lcv++, seg++) 434 /* structure copy */ 435 seg[0] = seg[1]; 436 } 437 return TRUE; 438 } 439 440 /* try from rear */ 441 if (seg->avail_end == seg->end && 442 seg->avail_start < seg->avail_end) { 443 *paddrp = ptoa(seg->avail_end - 1); 444 seg->avail_end--; 445 seg->end--; 446 /* nothing left? nuke it */ 447 if (seg->avail_end == seg->start) { 448 if (vm_nphysseg == 1) 449 panic("uvm_page_physget: out of memory!"); 450 vm_nphysseg--; 451 for (; lcv < vm_nphysseg ; lcv++, seg++) 452 /* structure copy */ 453 seg[0] = seg[1]; 454 } 455 return TRUE; 456 } 457 } 458 459 /* pass2: forget about matching ends, just allocate something */ 460#if (VM_PHYSSEG_STRAT == VM_PSTRAT_BIGFIRST) || \ 461 (VM_PHYSSEG_STRAT == VM_PSTRAT_BSEARCH) 462 for (lcv = vm_nphysseg - 1, seg = vm_physmem + lcv; lcv >= 0; 463 lcv--, seg--) 464#else 465 for (lcv = 0, seg = vm_physmem; lcv < vm_nphysseg ; lcv++, seg++) 466#endif 467 { 468 469 /* any room in this bank? */ 470 if (seg->avail_start >= seg->avail_end) 471 continue; /* nope */ 472 473 *paddrp = ptoa(seg->avail_start); 474 seg->avail_start++; 475 /* truncate! */ 476 seg->start = seg->avail_start; 477 478 /* nothing left? nuke it */ 479 if (seg->avail_start == seg->end) { 480 if (vm_nphysseg == 1) 481 panic("uvm_page_physget: out of memory!"); 482 vm_nphysseg--; 483 for (; lcv < vm_nphysseg ; lcv++, seg++) 484 /* structure copy */ 485 seg[0] = seg[1]; 486 } 487 return TRUE; 488 } 489 490 return FALSE; /* whoops! */ 491} 492 493#endif /* PMAP_STEAL_MEMORY */ 494 495/* 496 * uvm_page_physload: load physical memory into VM system 497 * 498 * => all args are PFs 499 * => all pages in start/end get vm_page structures 500 * => areas marked by avail_start/avail_end get added to the free page pool 501 * => we are limited to VM_PHYSSEG_MAX physical memory segments 502 */ 503 504void 505uvm_page_physload(paddr_t start, paddr_t end, paddr_t avail_start, 506 paddr_t avail_end, int flags) 507{ 508 int preload, lcv; 509 psize_t npages; 510 struct vm_page *pgs; 511 struct vm_physseg *ps, *seg; 512 513#ifdef DIAGNOSTIC 514 if (uvmexp.pagesize == 0) 515 panic("uvm_page_physload: page size not set!"); 516 517 if (start >= end) 518 panic("uvm_page_physload: start >= end"); 519#endif 520 521 /* do we have room? */ 522 if (vm_nphysseg == VM_PHYSSEG_MAX) { 523 printf("uvm_page_physload: unable to load physical memory " 524 "segment\n"); 525 printf("\t%d segments allocated, ignoring 0x%llx -> 0x%llx\n", 526 VM_PHYSSEG_MAX, (long long)start, (long long)end); 527 printf("\tincrease VM_PHYSSEG_MAX\n"); 528 return; 529 } 530 531 /* 532 * check to see if this is a "preload" (i.e. uvm_mem_init hasn't been 533 * called yet, so malloc is not available). 534 */ 535 for (lcv = 0, seg = vm_physmem; lcv < vm_nphysseg; lcv++, seg++) { 536 if (seg->pgs) 537 break; 538 } 539 preload = (lcv == vm_nphysseg); 540 541 /* if VM is already running, attempt to malloc() vm_page structures */ 542 if (!preload) { 543 /* 544 * XXXCDC: need some sort of lockout for this case 545 * right now it is only used by devices so it should be alright. 546 */ 547 paddr_t paddr; 548 549 npages = end - start; /* # of pages */ 550 551 pgs = km_alloc(round_page(npages * sizeof(*pgs)), 552 &kv_any, &kp_zero, &kd_waitok); 553 if (pgs == NULL) { 554 printf("uvm_page_physload: can not malloc vm_page " 555 "structs for segment\n"); 556 printf("\tignoring 0x%lx -> 0x%lx\n", start, end); 557 return; 558 } 559 /* init phys_addr and free pages, XXX uvmexp.npages */ 560 for (lcv = 0, paddr = ptoa(start); lcv < npages; 561 lcv++, paddr += PAGE_SIZE) { 562 pgs[lcv].phys_addr = paddr; 563 VM_MDPAGE_INIT(&pgs[lcv]); 564 if (atop(paddr) >= avail_start && 565 atop(paddr) < avail_end) { 566 if (flags & PHYSLOAD_DEVICE) { 567 atomic_setbits_int(&pgs[lcv].pg_flags, 568 PG_DEV); 569 pgs[lcv].wire_count = 1; 570 } else { 571#if defined(VM_PHYSSEG_NOADD) 572 panic("uvm_page_physload: tried to add RAM after vm_mem_init"); 573#endif 574 } 575 } 576 } 577 578 /* Add pages to free pool. */ 579 if ((flags & PHYSLOAD_DEVICE) == 0) { 580 uvm_pmr_freepages(&pgs[avail_start - start], 581 avail_end - avail_start); 582 } 583 584 /* XXXCDC: need hook to tell pmap to rebuild pv_list, etc... */ 585 } else { 586 /* gcc complains if these don't get init'd */ 587 pgs = NULL; 588 npages = 0; 589 590 } 591 592 /* now insert us in the proper place in vm_physmem[] */ 593#if (VM_PHYSSEG_STRAT == VM_PSTRAT_RANDOM) 594 /* random: put it at the end (easy!) */ 595 ps = &vm_physmem[vm_nphysseg]; 596#elif (VM_PHYSSEG_STRAT == VM_PSTRAT_BSEARCH) 597 { 598 int x; 599 /* sort by address for binary search */ 600 for (lcv = 0, seg = vm_physmem; lcv < vm_nphysseg; lcv++, seg++) 601 if (start < seg->start) 602 break; 603 ps = seg; 604 /* move back other entries, if necessary ... */ 605 for (x = vm_nphysseg, seg = vm_physmem + x - 1; x > lcv; 606 x--, seg--) 607 /* structure copy */ 608 seg[1] = seg[0]; 609 } 610#elif (VM_PHYSSEG_STRAT == VM_PSTRAT_BIGFIRST) 611 { 612 int x; 613 /* sort by largest segment first */ 614 for (lcv = 0, seg = vm_physmem; lcv < vm_nphysseg; lcv++, seg++) 615 if ((end - start) > 616 (seg->end - seg->start)) 617 break; 618 ps = &vm_physmem[lcv]; 619 /* move back other entries, if necessary ... */ 620 for (x = vm_nphysseg, seg = vm_physmem + x - 1; x > lcv; 621 x--, seg--) 622 /* structure copy */ 623 seg[1] = seg[0]; 624 } 625#else 626 panic("uvm_page_physload: unknown physseg strategy selected!"); 627#endif 628 629 ps->start = start; 630 ps->end = end; 631 ps->avail_start = avail_start; 632 ps->avail_end = avail_end; 633 if (preload) { 634 ps->pgs = NULL; 635 } else { 636 ps->pgs = pgs; 637 ps->lastpg = pgs + npages - 1; 638 } 639 vm_nphysseg++; 640 641 return; 642} 643 644#ifdef DDB /* XXXCDC: TMP TMP TMP DEBUG DEBUG DEBUG */ 645 646void uvm_page_physdump(void); /* SHUT UP GCC */ 647 648/* call from DDB */ 649void 650uvm_page_physdump(void) 651{ 652 int lcv; 653 struct vm_physseg *seg; 654 655 printf("uvm_page_physdump: physical memory config [segs=%d of %d]:\n", 656 vm_nphysseg, VM_PHYSSEG_MAX); 657 for (lcv = 0, seg = vm_physmem; lcv < vm_nphysseg ; lcv++, seg++) 658 printf("0x%llx->0x%llx [0x%llx->0x%llx]\n", 659 (long long)seg->start, 660 (long long)seg->end, 661 (long long)seg->avail_start, 662 (long long)seg->avail_end); 663 printf("STRATEGY = "); 664 switch (VM_PHYSSEG_STRAT) { 665 case VM_PSTRAT_RANDOM: printf("RANDOM\n"); break; 666 case VM_PSTRAT_BSEARCH: printf("BSEARCH\n"); break; 667 case VM_PSTRAT_BIGFIRST: printf("BIGFIRST\n"); break; 668 default: printf("<<UNKNOWN>>!!!!\n"); 669 } 670} 671#endif 672 673void 674uvm_shutdown(void) 675{ 676#ifdef UVM_SWAP_ENCRYPT 677 uvm_swap_finicrypt_all(); 678#endif 679 smr_flush(); 680} 681 682/* 683 * Perform insert of a given page in the specified anon of obj. 684 * This is basically, uvm_pagealloc, but with the page already given. 685 */ 686void 687uvm_pagealloc_pg(struct vm_page *pg, struct uvm_object *obj, voff_t off, 688 struct vm_anon *anon) 689{ 690 int flags; 691 692 KASSERT(obj == NULL || anon == NULL); 693 KASSERT(anon == NULL || off == 0); 694 KASSERT(off == trunc_page(off)); 695 KASSERT(obj == NULL || UVM_OBJ_IS_DUMMY(obj) || 696 rw_write_held(obj->vmobjlock)); 697 KASSERT(anon == NULL || anon->an_lock == NULL || 698 rw_write_held(anon->an_lock)); 699 700 flags = PG_BUSY | PG_FAKE; 701 pg->offset = off; 702 pg->uobject = obj; 703 pg->uanon = anon; 704 KASSERT(uvm_page_owner_locked_p(pg)); 705 if (anon) { 706 anon->an_page = pg; 707 flags |= PQ_ANON; 708 } else if (obj) 709 uvm_pageinsert(pg); 710 atomic_setbits_int(&pg->pg_flags, flags); 711#if defined(UVM_PAGE_TRKOWN) 712 pg->owner_tag = NULL; 713#endif 714 UVM_PAGE_OWN(pg, "new alloc"); 715} 716 717/* 718 * uvm_pglistalloc: allocate a list of pages 719 * 720 * => allocated pages are placed at the tail of rlist. rlist is 721 * assumed to be properly initialized by caller. 722 * => returns 0 on success or errno on failure 723 * => doesn't take into account clean non-busy pages on inactive list 724 * that could be used(?) 725 * => params: 726 * size the size of the allocation, rounded to page size. 727 * low the low address of the allowed allocation range. 728 * high the high address of the allowed allocation range. 729 * alignment memory must be aligned to this power-of-two boundary. 730 * boundary no segment in the allocation may cross this 731 * power-of-two boundary (relative to zero). 732 * => flags: 733 * UVM_PLA_NOWAIT fail if allocation fails 734 * UVM_PLA_WAITOK wait for memory to become avail 735 * UVM_PLA_ZERO return zeroed memory 736 */ 737int 738uvm_pglistalloc(psize_t size, paddr_t low, paddr_t high, paddr_t alignment, 739 paddr_t boundary, struct pglist *rlist, int nsegs, int flags) 740{ 741 KASSERT((alignment & (alignment - 1)) == 0); 742 KASSERT((boundary & (boundary - 1)) == 0); 743 KASSERT(!(flags & UVM_PLA_WAITOK) ^ !(flags & UVM_PLA_NOWAIT)); 744 745 if (size == 0) 746 return EINVAL; 747 size = atop(round_page(size)); 748 749 /* 750 * XXX uvm_pglistalloc is currently only used for kernel 751 * objects. Unlike the checks in uvm_pagealloc, below, here 752 * we are always allowed to use the kernel reserve. 753 */ 754 flags |= UVM_PLA_USERESERVE; 755 756 if ((high & PAGE_MASK) != PAGE_MASK) { 757 printf("uvm_pglistalloc: Upper boundary 0x%lx " 758 "not on pagemask.\n", (unsigned long)high); 759 } 760 761 /* 762 * Our allocations are always page granularity, so our alignment 763 * must be, too. 764 */ 765 if (alignment < PAGE_SIZE) 766 alignment = PAGE_SIZE; 767 768 low = atop(roundup(low, alignment)); 769 /* 770 * high + 1 may result in overflow, in which case high becomes 0x0, 771 * which is the 'don't care' value. 772 * The only requirement in that case is that low is also 0x0, or the 773 * low<high assert will fail. 774 */ 775 high = atop(high + 1); 776 alignment = atop(alignment); 777 if (boundary < PAGE_SIZE && boundary != 0) 778 boundary = PAGE_SIZE; 779 boundary = atop(boundary); 780 781 return uvm_pmr_getpages(size, low, high, alignment, boundary, nsegs, 782 flags, rlist); 783} 784 785/* 786 * uvm_pglistfree: free a list of pages 787 * 788 * => pages should already be unmapped 789 */ 790void 791uvm_pglistfree(struct pglist *list) 792{ 793 uvm_pmr_freepageq(list); 794} 795 796/* 797 * interface used by the buffer cache to allocate a buffer at a time. 798 * The pages are allocated wired in DMA accessible memory 799 */ 800int 801uvm_pagealloc_multi(struct uvm_object *obj, voff_t off, vsize_t size, 802 int flags) 803{ 804 struct pglist plist; 805 struct vm_page *pg; 806 int i, r; 807 808 KASSERT(UVM_OBJ_IS_BUFCACHE(obj)); 809 KERNEL_ASSERT_LOCKED(); 810 811 TAILQ_INIT(&plist); 812 r = uvm_pglistalloc(size, dma_constraint.ucr_low, 813 dma_constraint.ucr_high, 0, 0, &plist, atop(round_page(size)), 814 flags); 815 if (r == 0) { 816 i = 0; 817 while ((pg = TAILQ_FIRST(&plist)) != NULL) { 818 pg->wire_count = 1; 819 atomic_setbits_int(&pg->pg_flags, PG_CLEAN | PG_FAKE); 820 KASSERT((pg->pg_flags & PG_DEV) == 0); 821 TAILQ_REMOVE(&plist, pg, pageq); 822 uvm_pagealloc_pg(pg, obj, off + ptoa(i++), NULL); 823 } 824 } 825 return r; 826} 827 828/* 829 * interface used by the buffer cache to reallocate a buffer at a time. 830 * The pages are reallocated wired outside the DMA accessible region. 831 * 832 */ 833int 834uvm_pagerealloc_multi(struct uvm_object *obj, voff_t off, vsize_t size, 835 int flags, struct uvm_constraint_range *where) 836{ 837 struct pglist plist; 838 struct vm_page *pg, *tpg; 839 int i, r; 840 voff_t offset; 841 842 KASSERT(UVM_OBJ_IS_BUFCACHE(obj)); 843 KERNEL_ASSERT_LOCKED(); 844 845 TAILQ_INIT(&plist); 846 if (size == 0) 847 panic("size 0 uvm_pagerealloc"); 848 r = uvm_pglistalloc(size, where->ucr_low, where->ucr_high, 0, 849 0, &plist, atop(round_page(size)), flags); 850 if (r == 0) { 851 i = 0; 852 while((pg = TAILQ_FIRST(&plist)) != NULL) { 853 offset = off + ptoa(i++); 854 tpg = uvm_pagelookup(obj, offset); 855 KASSERT(tpg != NULL); 856 pg->wire_count = 1; 857 atomic_setbits_int(&pg->pg_flags, PG_CLEAN | PG_FAKE); 858 KASSERT((pg->pg_flags & PG_DEV) == 0); 859 TAILQ_REMOVE(&plist, pg, pageq); 860 uvm_pagecopy(tpg, pg); 861 KASSERT(tpg->wire_count == 1); 862 tpg->wire_count = 0; 863 uvm_lock_pageq(); 864 uvm_pagefree(tpg); 865 uvm_unlock_pageq(); 866 uvm_pagealloc_pg(pg, obj, offset, NULL); 867 } 868 } 869 return r; 870} 871 872/* 873 * uvm_pagealloc: allocate vm_page from a particular free list. 874 * 875 * => return null if no pages free 876 * => wake up pagedaemon if number of free pages drops below low water mark 877 * => only one of obj or anon can be non-null 878 * => caller must activate/deactivate page if it is not wired. 879 */ 880 881struct vm_page * 882uvm_pagealloc(struct uvm_object *obj, voff_t off, struct vm_anon *anon, 883 int flags) 884{ 885 struct vm_page *pg; 886 struct pglist pgl; 887 int pmr_flags; 888 889 KASSERT(obj == NULL || anon == NULL); 890 KASSERT(anon == NULL || off == 0); 891 KASSERT(off == trunc_page(off)); 892 KASSERT(obj == NULL || UVM_OBJ_IS_DUMMY(obj) || 893 rw_write_held(obj->vmobjlock)); 894 KASSERT(anon == NULL || anon->an_lock == NULL || 895 rw_write_held(anon->an_lock)); 896 897 pmr_flags = UVM_PLA_NOWAIT; 898 899 /* 900 * We're allowed to use the kernel reserve if the page is 901 * being allocated to a kernel object. 902 */ 903 if ((flags & UVM_PGA_USERESERVE) || 904 (obj != NULL && UVM_OBJ_IS_KERN_OBJECT(obj))) 905 pmr_flags |= UVM_PLA_USERESERVE; 906 907 if (flags & UVM_PGA_ZERO) 908 pmr_flags |= UVM_PLA_ZERO; 909 TAILQ_INIT(&pgl); 910 if (uvm_pmr_getpages(1, 0, 0, 1, 0, 1, pmr_flags, &pgl) != 0) 911 goto fail; 912 913 pg = TAILQ_FIRST(&pgl); 914 KASSERT(pg != NULL && TAILQ_NEXT(pg, pageq) == NULL); 915 916 uvm_pagealloc_pg(pg, obj, off, anon); 917 KASSERT((pg->pg_flags & PG_DEV) == 0); 918 if (flags & UVM_PGA_ZERO) 919 atomic_clearbits_int(&pg->pg_flags, PG_CLEAN); 920 else 921 atomic_setbits_int(&pg->pg_flags, PG_CLEAN); 922 923 return pg; 924 925fail: 926 return NULL; 927} 928 929/* 930 * uvm_pagerealloc: reallocate a page from one object to another 931 */ 932 933void 934uvm_pagerealloc(struct vm_page *pg, struct uvm_object *newobj, voff_t newoff) 935{ 936 937 /* remove it from the old object */ 938 if (pg->uobject) { 939 uvm_pageremove(pg); 940 } 941 942 /* put it in the new object */ 943 if (newobj) { 944 pg->uobject = newobj; 945 pg->offset = newoff; 946 pg->pg_version++; 947 uvm_pageinsert(pg); 948 } 949} 950 951/* 952 * uvm_pageclean: clean page 953 * 954 * => erase page's identity (i.e. remove from object) 955 * => caller must lock page queues if `pg' is managed 956 * => assumes all valid mappings of pg are gone 957 */ 958void 959uvm_pageclean(struct vm_page *pg) 960{ 961 u_int flags_to_clear = 0; 962 963 if ((pg->pg_flags & (PG_TABLED|PQ_ACTIVE|PQ_INACTIVE)) && 964 (pg->uobject == NULL || !UVM_OBJ_IS_PMAP(pg->uobject))) 965 MUTEX_ASSERT_LOCKED(&uvm.pageqlock); 966 967#ifdef DEBUG 968 if (pg->uobject == (void *)0xdeadbeef && 969 pg->uanon == (void *)0xdeadbeef) { 970 panic("uvm_pagefree: freeing free page %p", pg); 971 } 972#endif 973 974 KASSERT((pg->pg_flags & PG_DEV) == 0); 975 KASSERT(pg->uobject == NULL || UVM_OBJ_IS_DUMMY(pg->uobject) || 976 rw_write_held(pg->uobject->vmobjlock)); 977 KASSERT(pg->uobject != NULL || pg->uanon == NULL || 978 rw_write_held(pg->uanon->an_lock)); 979 980 /* 981 * if the page was an object page (and thus "TABLED"), remove it 982 * from the object. 983 */ 984 if (pg->pg_flags & PG_TABLED) 985 uvm_pageremove(pg); 986 987 /* 988 * now remove the page from the queues 989 */ 990 uvm_pagedequeue(pg); 991 992 /* 993 * if the page was wired, unwire it now. 994 */ 995 if (pg->wire_count) { 996 pg->wire_count = 0; 997 uvmexp.wired--; 998 } 999 if (pg->uanon) { 1000 pg->uanon->an_page = NULL; 1001 pg->uanon = NULL; 1002 } 1003 1004 /* Clean page state bits. */ 1005 flags_to_clear |= PQ_ANON|PQ_AOBJ|PQ_ENCRYPT|PG_ZERO|PG_FAKE|PG_BUSY| 1006 PG_RELEASED|PG_CLEAN|PG_CLEANCHK; 1007 atomic_clearbits_int(&pg->pg_flags, flags_to_clear); 1008 1009#ifdef DEBUG 1010 pg->uobject = (void *)0xdeadbeef; 1011 pg->offset = 0xdeadbeef; 1012 pg->uanon = (void *)0xdeadbeef; 1013#endif 1014} 1015 1016/* 1017 * uvm_pagefree: free page 1018 * 1019 * => erase page's identity (i.e. remove from object) 1020 * => put page on free list 1021 * => caller must lock page queues if `pg' is managed 1022 * => assumes all valid mappings of pg are gone 1023 */ 1024void 1025uvm_pagefree(struct vm_page *pg) 1026{ 1027 if ((pg->pg_flags & (PG_TABLED|PQ_ACTIVE|PQ_INACTIVE)) && 1028 (pg->uobject == NULL || !UVM_OBJ_IS_PMAP(pg->uobject))) 1029 MUTEX_ASSERT_LOCKED(&uvm.pageqlock); 1030 1031 uvm_pageclean(pg); 1032 uvm_pmr_freepages(pg, 1); 1033} 1034 1035/* 1036 * uvm_page_unbusy: unbusy an array of pages. 1037 * 1038 * => pages must either all belong to the same object, or all belong to anons. 1039 * => if pages are anon-owned, anons must have 0 refcount. 1040 */ 1041void 1042uvm_page_unbusy(struct vm_page **pgs, int npgs) 1043{ 1044 struct vm_page *pg; 1045 struct uvm_object *uobj; 1046 int i; 1047 1048 for (i = 0; i < npgs; i++) { 1049 pg = pgs[i]; 1050 1051 if (pg == NULL || pg == PGO_DONTCARE) { 1052 continue; 1053 } 1054 1055#if notyet 1056 /* 1057 * XXX swap case in uvm_aio_aiodone() is not holding the lock. 1058 * 1059 * This isn't compatible with the PG_RELEASED anon case below. 1060 */ 1061 KASSERT(uvm_page_owner_locked_p(pg)); 1062#endif 1063 KASSERT(pg->pg_flags & PG_BUSY); 1064 1065 if (pg->pg_flags & PG_WANTED) { 1066 wakeup(pg); 1067 } 1068 if (pg->pg_flags & PG_RELEASED) { 1069 uobj = pg->uobject; 1070 if (uobj != NULL) { 1071 uvm_lock_pageq(); 1072 pmap_page_protect(pg, PROT_NONE); 1073 /* XXX won't happen right now */ 1074 if (pg->pg_flags & PQ_AOBJ) 1075 uao_dropswap(uobj, 1076 pg->offset >> PAGE_SHIFT); 1077 uvm_pagefree(pg); 1078 uvm_unlock_pageq(); 1079 } else { 1080 rw_enter(pg->uanon->an_lock, RW_WRITE); 1081 uvm_anon_release(pg->uanon); 1082 } 1083 } else { 1084 atomic_clearbits_int(&pg->pg_flags, PG_WANTED|PG_BUSY); 1085 UVM_PAGE_OWN(pg, NULL); 1086 } 1087 } 1088} 1089 1090/* 1091 * uvm_pagewait: wait for a busy page 1092 * 1093 * => page must be known PG_BUSY 1094 * => object must be locked 1095 * => object will be unlocked on return 1096 */ 1097void 1098uvm_pagewait(struct vm_page *pg, struct rwlock *lock, const char *wmesg) 1099{ 1100 KASSERT(rw_lock_held(lock)); 1101 KASSERT((pg->pg_flags & PG_BUSY) != 0); 1102 1103 atomic_setbits_int(&pg->pg_flags, PG_WANTED); 1104 rwsleep_nsec(pg, lock, PVM | PNORELOCK, wmesg, INFSLP); 1105} 1106 1107#if defined(UVM_PAGE_TRKOWN) 1108/* 1109 * uvm_page_own: set or release page ownership 1110 * 1111 * => this is a debugging function that keeps track of who sets PG_BUSY 1112 * and where they do it. it can be used to track down problems 1113 * such a thread setting "PG_BUSY" and never releasing it. 1114 * => if "tag" is NULL then we are releasing page ownership 1115 */ 1116void 1117uvm_page_own(struct vm_page *pg, char *tag) 1118{ 1119 /* gain ownership? */ 1120 if (tag) { 1121 if (pg->owner_tag) { 1122 printf("uvm_page_own: page %p already owned " 1123 "by thread %d [%s]\n", pg, 1124 pg->owner, pg->owner_tag); 1125 panic("uvm_page_own"); 1126 } 1127 pg->owner = (curproc) ? curproc->p_tid : (pid_t) -1; 1128 pg->owner_tag = tag; 1129 return; 1130 } 1131 1132 /* drop ownership */ 1133 if (pg->owner_tag == NULL) { 1134 printf("uvm_page_own: dropping ownership of an non-owned " 1135 "page (%p)\n", pg); 1136 panic("uvm_page_own"); 1137 } 1138 pg->owner_tag = NULL; 1139 return; 1140} 1141#endif 1142 1143/* 1144 * when VM_PHYSSEG_MAX is 1, we can simplify these functions 1145 */ 1146 1147#if VM_PHYSSEG_MAX > 1 1148/* 1149 * vm_physseg_find: find vm_physseg structure that belongs to a PA 1150 */ 1151int 1152vm_physseg_find(paddr_t pframe, int *offp) 1153{ 1154 struct vm_physseg *seg; 1155 1156#if (VM_PHYSSEG_STRAT == VM_PSTRAT_BSEARCH) 1157 /* binary search for it */ 1158 int start, len, try; 1159 1160 /* 1161 * if try is too large (thus target is less than than try) we reduce 1162 * the length to trunc(len/2) [i.e. everything smaller than "try"] 1163 * 1164 * if the try is too small (thus target is greater than try) then 1165 * we set the new start to be (try + 1). this means we need to 1166 * reduce the length to (round(len/2) - 1). 1167 * 1168 * note "adjust" below which takes advantage of the fact that 1169 * (round(len/2) - 1) == trunc((len - 1) / 2) 1170 * for any value of len we may have 1171 */ 1172 1173 for (start = 0, len = vm_nphysseg ; len != 0 ; len = len / 2) { 1174 try = start + (len / 2); /* try in the middle */ 1175 seg = vm_physmem + try; 1176 1177 /* start past our try? */ 1178 if (pframe >= seg->start) { 1179 /* was try correct? */ 1180 if (pframe < seg->end) { 1181 if (offp) 1182 *offp = pframe - seg->start; 1183 return try; /* got it */ 1184 } 1185 start = try + 1; /* next time, start here */ 1186 len--; /* "adjust" */ 1187 } else { 1188 /* 1189 * pframe before try, just reduce length of 1190 * region, done in "for" loop 1191 */ 1192 } 1193 } 1194 return -1; 1195 1196#else 1197 /* linear search for it */ 1198 int lcv; 1199 1200 for (lcv = 0, seg = vm_physmem; lcv < vm_nphysseg ; lcv++, seg++) { 1201 if (pframe >= seg->start && pframe < seg->end) { 1202 if (offp) 1203 *offp = pframe - seg->start; 1204 return lcv; /* got it */ 1205 } 1206 } 1207 return -1; 1208 1209#endif 1210} 1211 1212/* 1213 * PHYS_TO_VM_PAGE: find vm_page for a PA. used by MI code to get vm_pages 1214 * back from an I/O mapping (ugh!). used in some MD code as well. 1215 */ 1216struct vm_page * 1217PHYS_TO_VM_PAGE(paddr_t pa) 1218{ 1219 paddr_t pf = atop(pa); 1220 int off; 1221 int psi; 1222 1223 psi = vm_physseg_find(pf, &off); 1224 1225 return (psi == -1) ? NULL : &vm_physmem[psi].pgs[off]; 1226} 1227#endif /* VM_PHYSSEG_MAX > 1 */ 1228 1229/* 1230 * uvm_pagelookup: look up a page 1231 */ 1232struct vm_page * 1233uvm_pagelookup(struct uvm_object *obj, voff_t off) 1234{ 1235 /* XXX if stack is too much, handroll */ 1236 struct vm_page pg; 1237 1238 pg.offset = off; 1239 return RBT_FIND(uvm_objtree, &obj->memt, &pg); 1240} 1241 1242/* 1243 * uvm_pagewire: wire the page, thus removing it from the daemon's grasp 1244 * 1245 * => caller must lock page queues 1246 */ 1247void 1248uvm_pagewire(struct vm_page *pg) 1249{ 1250 KASSERT(uvm_page_owner_locked_p(pg)); 1251 MUTEX_ASSERT_LOCKED(&uvm.pageqlock); 1252 1253 if (pg->wire_count == 0) { 1254 uvm_pagedequeue(pg); 1255 uvmexp.wired++; 1256 } 1257 pg->wire_count++; 1258} 1259 1260/* 1261 * uvm_pageunwire: unwire the page. 1262 * 1263 * => activate if wire count goes to zero. 1264 * => caller must lock page queues 1265 */ 1266void 1267uvm_pageunwire(struct vm_page *pg) 1268{ 1269 KASSERT(uvm_page_owner_locked_p(pg)); 1270 MUTEX_ASSERT_LOCKED(&uvm.pageqlock); 1271 1272 pg->wire_count--; 1273 if (pg->wire_count == 0) { 1274 uvm_pageactivate(pg); 1275 uvmexp.wired--; 1276 } 1277} 1278 1279/* 1280 * uvm_pagedeactivate: deactivate page -- no pmaps have access to page 1281 * 1282 * => caller must lock page queues 1283 * => caller must check to make sure page is not wired 1284 * => object that page belongs to must be locked (so we can adjust pg->flags) 1285 */ 1286void 1287uvm_pagedeactivate(struct vm_page *pg) 1288{ 1289 KASSERT(uvm_page_owner_locked_p(pg)); 1290 MUTEX_ASSERT_LOCKED(&uvm.pageqlock); 1291 1292 if (pg->pg_flags & PQ_ACTIVE) { 1293 TAILQ_REMOVE(&uvm.page_active, pg, pageq); 1294 atomic_clearbits_int(&pg->pg_flags, PQ_ACTIVE); 1295 uvmexp.active--; 1296 } 1297 if ((pg->pg_flags & PQ_INACTIVE) == 0) { 1298 KASSERT(pg->wire_count == 0); 1299 TAILQ_INSERT_TAIL(&uvm.page_inactive, pg, pageq); 1300 atomic_setbits_int(&pg->pg_flags, PQ_INACTIVE); 1301 uvmexp.inactive++; 1302 pmap_clear_reference(pg); 1303 /* 1304 * update the "clean" bit. this isn't 100% 1305 * accurate, and doesn't have to be. we'll 1306 * re-sync it after we zap all mappings when 1307 * scanning the inactive list. 1308 */ 1309 if ((pg->pg_flags & PG_CLEAN) != 0 && 1310 pmap_is_modified(pg)) 1311 atomic_clearbits_int(&pg->pg_flags, PG_CLEAN); 1312 } 1313} 1314 1315/* 1316 * uvm_pageactivate: activate page 1317 * 1318 * => caller must lock page queues 1319 */ 1320void 1321uvm_pageactivate(struct vm_page *pg) 1322{ 1323 KASSERT(uvm_page_owner_locked_p(pg)); 1324 MUTEX_ASSERT_LOCKED(&uvm.pageqlock); 1325 1326 uvm_pagedequeue(pg); 1327 if (pg->wire_count == 0) { 1328 TAILQ_INSERT_TAIL(&uvm.page_active, pg, pageq); 1329 atomic_setbits_int(&pg->pg_flags, PQ_ACTIVE); 1330 uvmexp.active++; 1331 1332 } 1333} 1334 1335/* 1336 * uvm_pagedequeue: remove a page from any paging queue 1337 */ 1338void 1339uvm_pagedequeue(struct vm_page *pg) 1340{ 1341 if (pg->pg_flags & PQ_ACTIVE) { 1342 TAILQ_REMOVE(&uvm.page_active, pg, pageq); 1343 atomic_clearbits_int(&pg->pg_flags, PQ_ACTIVE); 1344 uvmexp.active--; 1345 } 1346 if (pg->pg_flags & PQ_INACTIVE) { 1347 TAILQ_REMOVE(&uvm.page_inactive, pg, pageq); 1348 atomic_clearbits_int(&pg->pg_flags, PQ_INACTIVE); 1349 uvmexp.inactive--; 1350 } 1351} 1352/* 1353 * uvm_pagezero: zero fill a page 1354 */ 1355void 1356uvm_pagezero(struct vm_page *pg) 1357{ 1358 atomic_clearbits_int(&pg->pg_flags, PG_CLEAN); 1359 pmap_zero_page(pg); 1360} 1361 1362/* 1363 * uvm_pagecopy: copy a page 1364 */ 1365void 1366uvm_pagecopy(struct vm_page *src, struct vm_page *dst) 1367{ 1368 atomic_clearbits_int(&dst->pg_flags, PG_CLEAN); 1369 pmap_copy_page(src, dst); 1370} 1371 1372/* 1373 * uvm_page_owner_locked_p: return true if object associated with page is 1374 * locked. this is a weak check for runtime assertions only. 1375 */ 1376int 1377uvm_page_owner_locked_p(struct vm_page *pg) 1378{ 1379 if (pg->uobject != NULL) { 1380 if (UVM_OBJ_IS_DUMMY(pg->uobject)) 1381 return 1; 1382 return rw_write_held(pg->uobject->vmobjlock); 1383 } 1384 if (pg->uanon != NULL) { 1385 return rw_write_held(pg->uanon->an_lock); 1386 } 1387 return 1; 1388} 1389 1390/* 1391 * uvm_pagecount: count the number of physical pages in the address range. 1392 */ 1393psize_t 1394uvm_pagecount(struct uvm_constraint_range* constraint) 1395{ 1396 int lcv; 1397 psize_t sz; 1398 paddr_t low, high; 1399 paddr_t ps_low, ps_high; 1400 1401 /* Algorithm uses page numbers. */ 1402 low = atop(constraint->ucr_low); 1403 high = atop(constraint->ucr_high); 1404 1405 sz = 0; 1406 for (lcv = 0; lcv < vm_nphysseg; lcv++) { 1407 ps_low = MAX(low, vm_physmem[lcv].avail_start); 1408 ps_high = MIN(high, vm_physmem[lcv].avail_end); 1409 if (ps_low < ps_high) 1410 sz += ps_high - ps_low; 1411 } 1412 return sz; 1413} 1414