uvm_fault.c revision 1.31
1 1.31 thorpej /* $NetBSD: uvm_fault.c,v 1.31 1999/05/28 20:49:51 thorpej Exp $ */ 2 1.1 mrg 3 1.1 mrg /* 4 1.1 mrg * 5 1.1 mrg * Copyright (c) 1997 Charles D. Cranor and Washington University. 6 1.1 mrg * All rights reserved. 7 1.1 mrg * 8 1.1 mrg * Redistribution and use in source and binary forms, with or without 9 1.1 mrg * modification, are permitted provided that the following conditions 10 1.1 mrg * are met: 11 1.1 mrg * 1. Redistributions of source code must retain the above copyright 12 1.1 mrg * notice, this list of conditions and the following disclaimer. 13 1.1 mrg * 2. Redistributions in binary form must reproduce the above copyright 14 1.1 mrg * notice, this list of conditions and the following disclaimer in the 15 1.1 mrg * documentation and/or other materials provided with the distribution. 16 1.1 mrg * 3. All advertising materials mentioning features or use of this software 17 1.1 mrg * must display the following acknowledgement: 18 1.1 mrg * This product includes software developed by Charles D. Cranor and 19 1.1 mrg * Washington University. 20 1.1 mrg * 4. The name of the author may not be used to endorse or promote products 21 1.1 mrg * derived from this software without specific prior written permission. 22 1.1 mrg * 23 1.1 mrg * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 24 1.1 mrg * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 25 1.1 mrg * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 26 1.1 mrg * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 27 1.1 mrg * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 28 1.1 mrg * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 29 1.1 mrg * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 30 1.1 mrg * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 31 1.1 mrg * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF 32 1.1 mrg * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 33 1.4 mrg * 34 1.4 mrg * from: Id: uvm_fault.c,v 1.1.2.23 1998/02/06 05:29:05 chs Exp 35 1.1 mrg */ 36 1.1 mrg 37 1.6 mrg #include "opt_uvmhist.h" 38 1.6 mrg 39 1.1 mrg /* 40 1.1 mrg * uvm_fault.c: fault handler 41 1.1 mrg */ 42 1.1 mrg 43 1.1 mrg #include <sys/param.h> 44 1.1 mrg #include <sys/systm.h> 45 1.1 mrg #include <sys/kernel.h> 46 1.1 mrg #include <sys/proc.h> 47 1.1 mrg #include <sys/malloc.h> 48 1.1 mrg #include <sys/mman.h> 49 1.9 chuck #include <sys/user.h> 50 1.1 mrg 51 1.1 mrg #include <vm/vm.h> 52 1.1 mrg #include <vm/vm_page.h> 53 1.1 mrg #include <vm/vm_kern.h> 54 1.1 mrg 55 1.1 mrg #include <uvm/uvm.h> 56 1.1 mrg 57 1.1 mrg /* 58 1.1 mrg * 59 1.1 mrg * a word on page faults: 60 1.1 mrg * 61 1.1 mrg * types of page faults we handle: 62 1.1 mrg * 63 1.1 mrg * CASE 1: upper layer faults CASE 2: lower layer faults 64 1.1 mrg * 65 1.1 mrg * CASE 1A CASE 1B CASE 2A CASE 2B 66 1.1 mrg * read/write1 write>1 read/write +-cow_write/zero 67 1.1 mrg * | | | | 68 1.1 mrg * +--|--+ +--|--+ +-----+ + | + | +-----+ 69 1.1 mrg * amap | V | | ----------->new| | | | ^ | 70 1.1 mrg * +-----+ +-----+ +-----+ + | + | +--|--+ 71 1.1 mrg * | | | 72 1.1 mrg * +-----+ +-----+ +--|--+ | +--|--+ 73 1.1 mrg * uobj | d/c | | d/c | | V | +----| | 74 1.1 mrg * +-----+ +-----+ +-----+ +-----+ 75 1.1 mrg * 76 1.1 mrg * d/c = don't care 77 1.1 mrg * 78 1.1 mrg * case [0]: layerless fault 79 1.1 mrg * no amap or uobj is present. this is an error. 80 1.1 mrg * 81 1.1 mrg * case [1]: upper layer fault [anon active] 82 1.1 mrg * 1A: [read] or [write with anon->an_ref == 1] 83 1.1 mrg * I/O takes place in top level anon and uobj is not touched. 84 1.1 mrg * 1B: [write with anon->an_ref > 1] 85 1.1 mrg * new anon is alloc'd and data is copied off ["COW"] 86 1.1 mrg * 87 1.1 mrg * case [2]: lower layer fault [uobj] 88 1.1 mrg * 2A: [read on non-NULL uobj] or [write to non-copy_on_write area] 89 1.1 mrg * I/O takes place directly in object. 90 1.1 mrg * 2B: [write to copy_on_write] or [read on NULL uobj] 91 1.1 mrg * data is "promoted" from uobj to a new anon. 92 1.1 mrg * if uobj is null, then we zero fill. 93 1.1 mrg * 94 1.1 mrg * we follow the standard UVM locking protocol ordering: 95 1.1 mrg * 96 1.1 mrg * MAPS => AMAP => UOBJ => ANON => PAGE QUEUES (PQ) 97 1.1 mrg * we hold a PG_BUSY page if we unlock for I/O 98 1.1 mrg * 99 1.1 mrg * 100 1.1 mrg * the code is structured as follows: 101 1.1 mrg * 102 1.1 mrg * - init the "IN" params in the ufi structure 103 1.1 mrg * ReFault: 104 1.1 mrg * - do lookups [locks maps], check protection, handle needs_copy 105 1.1 mrg * - check for case 0 fault (error) 106 1.1 mrg * - establish "range" of fault 107 1.1 mrg * - if we have an amap lock it and extract the anons 108 1.1 mrg * - if sequential advice deactivate pages behind us 109 1.1 mrg * - at the same time check pmap for unmapped areas and anon for pages 110 1.1 mrg * that we could map in (and do map it if found) 111 1.1 mrg * - check object for resident pages that we could map in 112 1.1 mrg * - if (case 2) goto Case2 113 1.1 mrg * - >>> handle case 1 114 1.1 mrg * - ensure source anon is resident in RAM 115 1.1 mrg * - if case 1B alloc new anon and copy from source 116 1.1 mrg * - map the correct page in 117 1.1 mrg * Case2: 118 1.1 mrg * - >>> handle case 2 119 1.1 mrg * - ensure source page is resident (if uobj) 120 1.1 mrg * - if case 2B alloc new anon and copy from source (could be zero 121 1.1 mrg * fill if uobj == NULL) 122 1.1 mrg * - map the correct page in 123 1.1 mrg * - done! 124 1.1 mrg * 125 1.1 mrg * note on paging: 126 1.1 mrg * if we have to do I/O we place a PG_BUSY page in the correct object, 127 1.1 mrg * unlock everything, and do the I/O. when I/O is done we must reverify 128 1.1 mrg * the state of the world before assuming that our data structures are 129 1.1 mrg * valid. [because mappings could change while the map is unlocked] 130 1.1 mrg * 131 1.1 mrg * alternative 1: unbusy the page in question and restart the page fault 132 1.1 mrg * from the top (ReFault). this is easy but does not take advantage 133 1.1 mrg * of the information that we already have from our previous lookup, 134 1.1 mrg * although it is possible that the "hints" in the vm_map will help here. 135 1.1 mrg * 136 1.1 mrg * alternative 2: the system already keeps track of a "version" number of 137 1.1 mrg * a map. [i.e. every time you write-lock a map (e.g. to change a 138 1.1 mrg * mapping) you bump the version number up by one...] so, we can save 139 1.1 mrg * the version number of the map before we release the lock and start I/O. 140 1.1 mrg * then when I/O is done we can relock and check the version numbers 141 1.1 mrg * to see if anything changed. this might save us some over 1 because 142 1.1 mrg * we don't have to unbusy the page and may be less compares(?). 143 1.1 mrg * 144 1.1 mrg * alternative 3: put in backpointers or a way to "hold" part of a map 145 1.1 mrg * in place while I/O is in progress. this could be complex to 146 1.1 mrg * implement (especially with structures like amap that can be referenced 147 1.1 mrg * by multiple map entries, and figuring out what should wait could be 148 1.1 mrg * complex as well...). 149 1.1 mrg * 150 1.1 mrg * given that we are not currently multiprocessor or multithreaded we might 151 1.1 mrg * as well choose alternative 2 now. maybe alternative 3 would be useful 152 1.1 mrg * in the future. XXX keep in mind for future consideration//rechecking. 153 1.1 mrg */ 154 1.1 mrg 155 1.1 mrg /* 156 1.1 mrg * local data structures 157 1.1 mrg */ 158 1.1 mrg 159 1.1 mrg struct uvm_advice { 160 1.7 mrg int advice; 161 1.7 mrg int nback; 162 1.7 mrg int nforw; 163 1.1 mrg }; 164 1.1 mrg 165 1.1 mrg /* 166 1.1 mrg * page range array: 167 1.1 mrg * note: index in array must match "advice" value 168 1.1 mrg * XXX: borrowed numbers from freebsd. do they work well for us? 169 1.1 mrg */ 170 1.1 mrg 171 1.1 mrg static struct uvm_advice uvmadvice[] = { 172 1.7 mrg { MADV_NORMAL, 3, 4 }, 173 1.7 mrg { MADV_RANDOM, 0, 0 }, 174 1.7 mrg { MADV_SEQUENTIAL, 8, 7}, 175 1.1 mrg }; 176 1.1 mrg 177 1.1 mrg #define UVM_MAXRANGE 16 /* must be max() of nback+nforw+1 */ 178 1.1 mrg 179 1.1 mrg /* 180 1.1 mrg * private prototypes 181 1.1 mrg */ 182 1.1 mrg 183 1.1 mrg static void uvmfault_amapcopy __P((struct uvm_faultinfo *)); 184 1.1 mrg static __inline void uvmfault_anonflush __P((struct vm_anon **, int)); 185 1.1 mrg 186 1.1 mrg /* 187 1.1 mrg * inline functions 188 1.1 mrg */ 189 1.1 mrg 190 1.1 mrg /* 191 1.1 mrg * uvmfault_anonflush: try and deactivate pages in specified anons 192 1.1 mrg * 193 1.1 mrg * => does not have to deactivate page if it is busy 194 1.1 mrg */ 195 1.1 mrg 196 1.7 mrg static __inline void 197 1.7 mrg uvmfault_anonflush(anons, n) 198 1.7 mrg struct vm_anon **anons; 199 1.7 mrg int n; 200 1.1 mrg { 201 1.7 mrg int lcv; 202 1.7 mrg struct vm_page *pg; 203 1.7 mrg 204 1.7 mrg for (lcv = 0 ; lcv < n ; lcv++) { 205 1.7 mrg if (anons[lcv] == NULL) 206 1.7 mrg continue; 207 1.7 mrg simple_lock(&anons[lcv]->an_lock); 208 1.7 mrg pg = anons[lcv]->u.an_page; 209 1.7 mrg if (pg && (pg->flags & PG_BUSY) == 0 && pg->loan_count == 0) { 210 1.7 mrg uvm_lock_pageq(); 211 1.7 mrg if (pg->wire_count == 0) { 212 1.7 mrg pmap_page_protect(PMAP_PGARG(pg), VM_PROT_NONE); 213 1.7 mrg uvm_pagedeactivate(pg); 214 1.7 mrg } 215 1.7 mrg uvm_unlock_pageq(); 216 1.7 mrg } 217 1.7 mrg simple_unlock(&anons[lcv]->an_lock); 218 1.7 mrg } 219 1.1 mrg } 220 1.1 mrg 221 1.1 mrg /* 222 1.1 mrg * normal functions 223 1.1 mrg */ 224 1.1 mrg 225 1.1 mrg /* 226 1.1 mrg * uvmfault_amapcopy: clear "needs_copy" in a map. 227 1.1 mrg * 228 1.1 mrg * => called with VM data structures unlocked (usually, see below) 229 1.1 mrg * => we get a write lock on the maps and clear needs_copy for a VA 230 1.1 mrg * => if we are out of RAM we sleep (waiting for more) 231 1.1 mrg */ 232 1.1 mrg 233 1.7 mrg static void 234 1.7 mrg uvmfault_amapcopy(ufi) 235 1.7 mrg struct uvm_faultinfo *ufi; 236 1.1 mrg { 237 1.1 mrg 238 1.7 mrg /* 239 1.7 mrg * while we haven't done the job 240 1.7 mrg */ 241 1.1 mrg 242 1.7 mrg while (1) { 243 1.1 mrg 244 1.7 mrg /* 245 1.7 mrg * no mapping? give up. 246 1.7 mrg */ 247 1.1 mrg 248 1.7 mrg if (uvmfault_lookup(ufi, TRUE) == FALSE) 249 1.7 mrg return; 250 1.1 mrg 251 1.7 mrg /* 252 1.7 mrg * copy if needed. 253 1.7 mrg */ 254 1.1 mrg 255 1.7 mrg if (UVM_ET_ISNEEDSCOPY(ufi->entry)) 256 1.13 chuck amap_copy(ufi->map, ufi->entry, M_NOWAIT, TRUE, 257 1.13 chuck ufi->orig_rvaddr, ufi->orig_rvaddr + 1); 258 1.1 mrg 259 1.7 mrg /* 260 1.7 mrg * didn't work? must be out of RAM. unlock and sleep. 261 1.7 mrg */ 262 1.7 mrg 263 1.7 mrg if (UVM_ET_ISNEEDSCOPY(ufi->entry)) { 264 1.7 mrg uvmfault_unlockmaps(ufi, TRUE); 265 1.7 mrg uvm_wait("fltamapcopy"); 266 1.7 mrg continue; 267 1.7 mrg } 268 1.7 mrg 269 1.7 mrg /* 270 1.7 mrg * got it! unlock and return. 271 1.7 mrg */ 272 1.7 mrg 273 1.7 mrg uvmfault_unlockmaps(ufi, TRUE); 274 1.7 mrg return; 275 1.7 mrg } 276 1.7 mrg /*NOTREACHED*/ 277 1.1 mrg } 278 1.1 mrg 279 1.1 mrg /* 280 1.1 mrg * uvmfault_anonget: get data in an anon into a non-busy, non-released 281 1.1 mrg * page in that anon. 282 1.1 mrg * 283 1.1 mrg * => maps, amap, and anon locked by caller. 284 1.1 mrg * => if we fail (result != VM_PAGER_OK) we unlock everything. 285 1.1 mrg * => if we are successful, we return with everything still locked. 286 1.1 mrg * => we don't move the page on the queues [gets moved later] 287 1.1 mrg * => if we allocate a new page [we_own], it gets put on the queues. 288 1.1 mrg * either way, the result is that the page is on the queues at return time 289 1.1 mrg * => for pages which are on loan from a uvm_object (and thus are not 290 1.1 mrg * owned by the anon): if successful, we return with the owning object 291 1.1 mrg * locked. the caller must unlock this object when it unlocks everything 292 1.1 mrg * else. 293 1.1 mrg */ 294 1.1 mrg 295 1.1 mrg int uvmfault_anonget(ufi, amap, anon) 296 1.7 mrg struct uvm_faultinfo *ufi; 297 1.7 mrg struct vm_amap *amap; 298 1.7 mrg struct vm_anon *anon; 299 1.7 mrg { 300 1.7 mrg boolean_t we_own; /* we own anon's page? */ 301 1.7 mrg boolean_t locked; /* did we relock? */ 302 1.7 mrg struct vm_page *pg; 303 1.7 mrg int result; 304 1.7 mrg UVMHIST_FUNC("uvmfault_anonget"); UVMHIST_CALLED(maphist); 305 1.7 mrg 306 1.7 mrg result = 0; /* XXX shut up gcc */ 307 1.9 chuck uvmexp.fltanget++; 308 1.9 chuck /* bump rusage counters */ 309 1.9 chuck if (anon->u.an_page) 310 1.9 chuck curproc->p_addr->u_stats.p_ru.ru_minflt++; 311 1.9 chuck else 312 1.9 chuck curproc->p_addr->u_stats.p_ru.ru_majflt++; 313 1.7 mrg 314 1.7 mrg /* 315 1.7 mrg * loop until we get it, or fail. 316 1.7 mrg */ 317 1.7 mrg 318 1.7 mrg while (1) { 319 1.1 mrg 320 1.7 mrg we_own = FALSE; /* TRUE if we set PG_BUSY on a page */ 321 1.7 mrg pg = anon->u.an_page; 322 1.1 mrg 323 1.7 mrg /* 324 1.7 mrg * if there is a resident page and it is loaned, then anon 325 1.7 mrg * may not own it. call out to uvm_anon_lockpage() to ensure 326 1.7 mrg * the real owner of the page has been identified and locked. 327 1.7 mrg */ 328 1.7 mrg 329 1.7 mrg if (pg && pg->loan_count) 330 1.13 chuck pg = uvm_anon_lockloanpg(anon); 331 1.7 mrg 332 1.7 mrg /* 333 1.7 mrg * page there? make sure it is not busy/released. 334 1.7 mrg */ 335 1.7 mrg 336 1.7 mrg if (pg) { 337 1.7 mrg 338 1.7 mrg /* 339 1.7 mrg * at this point, if the page has a uobject [meaning 340 1.7 mrg * we have it on loan], then that uobject is locked 341 1.7 mrg * by us! if the page is busy, we drop all the 342 1.7 mrg * locks (including uobject) and try again. 343 1.7 mrg */ 344 1.7 mrg 345 1.7 mrg if ((pg->flags & (PG_BUSY|PG_RELEASED)) == 0) { 346 1.7 mrg UVMHIST_LOG(maphist, "<- OK",0,0,0,0); 347 1.17 mrg return (VM_PAGER_OK); 348 1.7 mrg } 349 1.7 mrg pg->flags |= PG_WANTED; 350 1.7 mrg uvmexp.fltpgwait++; 351 1.7 mrg 352 1.7 mrg /* 353 1.7 mrg * the last unlock must be an atomic unlock+wait on 354 1.7 mrg * the owner of page 355 1.7 mrg */ 356 1.7 mrg if (pg->uobject) { /* owner is uobject ? */ 357 1.7 mrg uvmfault_unlockall(ufi, amap, NULL, anon); 358 1.7 mrg UVMHIST_LOG(maphist, " unlock+wait on uobj",0, 359 1.7 mrg 0,0,0); 360 1.7 mrg UVM_UNLOCK_AND_WAIT(pg, 361 1.7 mrg &pg->uobject->vmobjlock, 362 1.7 mrg FALSE, "anonget1",0); 363 1.7 mrg } else { 364 1.7 mrg /* anon owns page */ 365 1.7 mrg uvmfault_unlockall(ufi, amap, NULL, NULL); 366 1.7 mrg UVMHIST_LOG(maphist, " unlock+wait on anon",0, 367 1.7 mrg 0,0,0); 368 1.7 mrg UVM_UNLOCK_AND_WAIT(pg,&anon->an_lock,0, 369 1.7 mrg "anonget2",0); 370 1.7 mrg } 371 1.7 mrg /* ready to relock and try again */ 372 1.7 mrg 373 1.7 mrg } else { 374 1.7 mrg 375 1.7 mrg /* 376 1.7 mrg * no page, we must try and bring it in. 377 1.7 mrg */ 378 1.28 chs pg = uvm_pagealloc(NULL, 0, anon, 0); 379 1.7 mrg 380 1.7 mrg if (pg == NULL) { /* out of RAM. */ 381 1.7 mrg 382 1.7 mrg uvmfault_unlockall(ufi, amap, NULL, anon); 383 1.7 mrg uvmexp.fltnoram++; 384 1.7 mrg UVMHIST_LOG(maphist, " noram -- UVM_WAIT",0, 385 1.7 mrg 0,0,0); 386 1.7 mrg uvm_wait("flt_noram1"); 387 1.7 mrg /* ready to relock and try again */ 388 1.1 mrg 389 1.7 mrg } else { 390 1.1 mrg 391 1.7 mrg /* we set the PG_BUSY bit */ 392 1.7 mrg we_own = TRUE; 393 1.7 mrg uvmfault_unlockall(ufi, amap, NULL, anon); 394 1.7 mrg 395 1.7 mrg /* 396 1.7 mrg * we are passing a PG_BUSY+PG_FAKE+PG_CLEAN 397 1.7 mrg * page into the uvm_swap_get function with 398 1.18 chuck * all data structures unlocked. note that 399 1.18 chuck * it is ok to read an_swslot here because 400 1.18 chuck * we hold PG_BUSY on the page. 401 1.7 mrg */ 402 1.7 mrg uvmexp.pageins++; 403 1.7 mrg result = uvm_swap_get(pg, anon->an_swslot, 404 1.7 mrg PGO_SYNCIO); 405 1.7 mrg 406 1.7 mrg /* 407 1.7 mrg * we clean up after the i/o below in the 408 1.7 mrg * "we_own" case 409 1.7 mrg */ 410 1.7 mrg /* ready to relock and try again */ 411 1.7 mrg } 412 1.7 mrg } 413 1.7 mrg 414 1.7 mrg /* 415 1.7 mrg * now relock and try again 416 1.7 mrg */ 417 1.7 mrg 418 1.7 mrg locked = uvmfault_relock(ufi); 419 1.7 mrg if (locked) { 420 1.19 chuck amap_lock(amap); 421 1.7 mrg } 422 1.7 mrg if (locked || we_own) 423 1.7 mrg simple_lock(&anon->an_lock); 424 1.7 mrg 425 1.7 mrg /* 426 1.7 mrg * if we own the page (i.e. we set PG_BUSY), then we need 427 1.7 mrg * to clean up after the I/O. there are three cases to 428 1.7 mrg * consider: 429 1.7 mrg * [1] page released during I/O: free anon and ReFault. 430 1.7 mrg * [2] I/O not OK. free the page and cause the fault 431 1.7 mrg * to fail. 432 1.7 mrg * [3] I/O OK! activate the page and sync with the 433 1.7 mrg * non-we_own case (i.e. drop anon lock if not locked). 434 1.7 mrg */ 435 1.7 mrg 436 1.7 mrg if (we_own) { 437 1.7 mrg 438 1.7 mrg if (pg->flags & PG_WANTED) { 439 1.7 mrg /* still holding object lock */ 440 1.7 mrg thread_wakeup(pg); 441 1.7 mrg } 442 1.7 mrg /* un-busy! */ 443 1.7 mrg pg->flags &= ~(PG_WANTED|PG_BUSY|PG_FAKE); 444 1.7 mrg UVM_PAGE_OWN(pg, NULL); 445 1.7 mrg 446 1.7 mrg /* 447 1.7 mrg * if we were RELEASED during I/O, then our anon is 448 1.7 mrg * no longer part of an amap. we need to free the 449 1.7 mrg * anon and try again. 450 1.7 mrg */ 451 1.7 mrg if (pg->flags & PG_RELEASED) { 452 1.7 mrg pmap_page_protect(PMAP_PGARG(pg), 453 1.7 mrg VM_PROT_NONE); /* to be safe */ 454 1.16 chs simple_unlock(&anon->an_lock); 455 1.7 mrg uvm_anfree(anon); /* frees page for us */ 456 1.7 mrg if (locked) 457 1.7 mrg uvmfault_unlockall(ufi, amap, NULL, NULL); 458 1.7 mrg uvmexp.fltpgrele++; 459 1.7 mrg UVMHIST_LOG(maphist, "<- REFAULT", 0,0,0,0); 460 1.17 mrg return (VM_PAGER_REFAULT); /* refault! */ 461 1.7 mrg } 462 1.1 mrg 463 1.7 mrg if (result != VM_PAGER_OK) { 464 1.1 mrg #ifdef DIAGNOSTIC 465 1.7 mrg if (result == VM_PAGER_PEND) 466 1.7 mrg panic("uvmfault_anonget: got PENDING for non-async I/O"); 467 1.1 mrg #endif 468 1.7 mrg /* remove page from anon */ 469 1.7 mrg anon->u.an_page = NULL; 470 1.1 mrg 471 1.7 mrg /* 472 1.7 mrg * note: page was never !PG_BUSY, so it 473 1.7 mrg * can't be mapped and thus no need to 474 1.7 mrg * pmap_page_protect it... 475 1.7 mrg */ 476 1.7 mrg uvm_lock_pageq(); 477 1.7 mrg uvm_pagefree(pg); 478 1.7 mrg uvm_unlock_pageq(); 479 1.7 mrg 480 1.7 mrg if (locked) 481 1.7 mrg uvmfault_unlockall(ufi, amap, NULL, 482 1.7 mrg anon); 483 1.7 mrg else 484 1.7 mrg simple_unlock(&anon->an_lock); 485 1.7 mrg UVMHIST_LOG(maphist, "<- ERROR", 0,0,0,0); 486 1.17 mrg return (VM_PAGER_ERROR); 487 1.7 mrg } 488 1.7 mrg 489 1.7 mrg /* 490 1.7 mrg * must be OK, clear modify (already PG_CLEAN) 491 1.7 mrg * and activate 492 1.7 mrg */ 493 1.7 mrg pmap_clear_modify(PMAP_PGARG(pg)); 494 1.7 mrg uvm_lock_pageq(); 495 1.7 mrg uvm_pageactivate(pg); 496 1.7 mrg uvm_unlock_pageq(); 497 1.7 mrg if (!locked) 498 1.7 mrg simple_unlock(&anon->an_lock); 499 1.7 mrg } 500 1.7 mrg 501 1.7 mrg /* 502 1.7 mrg * we were not able to relock. restart fault. 503 1.7 mrg */ 504 1.7 mrg 505 1.7 mrg if (!locked) { 506 1.7 mrg UVMHIST_LOG(maphist, "<- REFAULT", 0,0,0,0); 507 1.17 mrg return (VM_PAGER_REFAULT); 508 1.7 mrg } 509 1.7 mrg 510 1.7 mrg /* 511 1.7 mrg * verify no one has touched the amap and moved the anon on us. 512 1.7 mrg */ 513 1.1 mrg 514 1.7 mrg if (amap_lookup(&ufi->entry->aref, 515 1.13 chuck ufi->orig_rvaddr - ufi->entry->start) != anon) { 516 1.7 mrg 517 1.7 mrg uvmfault_unlockall(ufi, amap, NULL, anon); 518 1.7 mrg UVMHIST_LOG(maphist, "<- REFAULT", 0,0,0,0); 519 1.17 mrg return (VM_PAGER_REFAULT); 520 1.7 mrg } 521 1.7 mrg 522 1.7 mrg /* 523 1.7 mrg * try it again! 524 1.7 mrg */ 525 1.1 mrg 526 1.7 mrg uvmexp.fltanretry++; 527 1.7 mrg continue; 528 1.7 mrg 529 1.7 mrg } /* while (1) */ 530 1.7 mrg 531 1.7 mrg /*NOTREACHED*/ 532 1.1 mrg } 533 1.1 mrg 534 1.1 mrg /* 535 1.1 mrg * F A U L T - m a i n e n t r y p o i n t 536 1.1 mrg */ 537 1.1 mrg 538 1.1 mrg /* 539 1.1 mrg * uvm_fault: page fault handler 540 1.1 mrg * 541 1.1 mrg * => called from MD code to resolve a page fault 542 1.1 mrg * => VM data structures usually should be unlocked. however, it is 543 1.1 mrg * possible to call here with the main map locked if the caller 544 1.1 mrg * gets a write lock, sets it recusive, and then calls us (c.f. 545 1.1 mrg * uvm_map_pageable). this should be avoided because it keeps 546 1.1 mrg * the map locked off during I/O. 547 1.1 mrg */ 548 1.1 mrg 549 1.24 mycroft #define MASK(entry) (UVM_ET_ISCOPYONWRITE(entry) ? \ 550 1.24 mycroft ~VM_PROT_WRITE : VM_PROT_ALL) 551 1.24 mycroft 552 1.7 mrg int 553 1.7 mrg uvm_fault(orig_map, vaddr, fault_type, access_type) 554 1.7 mrg vm_map_t orig_map; 555 1.12 eeh vaddr_t vaddr; 556 1.7 mrg vm_fault_t fault_type; 557 1.7 mrg vm_prot_t access_type; 558 1.1 mrg { 559 1.7 mrg struct uvm_faultinfo ufi; 560 1.7 mrg vm_prot_t enter_prot; 561 1.7 mrg boolean_t wired, narrow, promote, locked, shadowed; 562 1.7 mrg int npages, nback, nforw, centeridx, result, lcv, gotpages; 563 1.13 chuck vaddr_t startva, objaddr, currva, offset; 564 1.12 eeh paddr_t pa; 565 1.7 mrg struct vm_amap *amap; 566 1.7 mrg struct uvm_object *uobj; 567 1.7 mrg struct vm_anon *anons_store[UVM_MAXRANGE], **anons, *anon, *oanon; 568 1.7 mrg struct vm_page *pages[UVM_MAXRANGE], *pg, *uobjpage; 569 1.7 mrg UVMHIST_FUNC("uvm_fault"); UVMHIST_CALLED(maphist); 570 1.1 mrg 571 1.7 mrg UVMHIST_LOG(maphist, "(map=0x%x, vaddr=0x%x, ft=%d, at=%d)", 572 1.1 mrg orig_map, vaddr, fault_type, access_type); 573 1.1 mrg 574 1.7 mrg anon = NULL; /* XXX: shut up gcc */ 575 1.1 mrg 576 1.7 mrg uvmexp.faults++; /* XXX: locking? */ 577 1.7 mrg 578 1.7 mrg /* 579 1.7 mrg * init the IN parameters in the ufi 580 1.7 mrg */ 581 1.1 mrg 582 1.7 mrg ufi.orig_map = orig_map; 583 1.7 mrg ufi.orig_rvaddr = trunc_page(vaddr); 584 1.7 mrg ufi.orig_size = PAGE_SIZE; /* can't get any smaller than this */ 585 1.7 mrg if (fault_type == VM_FAULT_WIRE) 586 1.7 mrg narrow = TRUE; /* don't look for neighborhood 587 1.7 mrg * pages on wire */ 588 1.7 mrg else 589 1.7 mrg narrow = FALSE; /* normal fault */ 590 1.7 mrg 591 1.7 mrg /* 592 1.7 mrg * "goto ReFault" means restart the page fault from ground zero. 593 1.7 mrg */ 594 1.1 mrg ReFault: 595 1.1 mrg 596 1.7 mrg /* 597 1.7 mrg * lookup and lock the maps 598 1.7 mrg */ 599 1.7 mrg 600 1.7 mrg if (uvmfault_lookup(&ufi, FALSE) == FALSE) { 601 1.7 mrg UVMHIST_LOG(maphist, "<- no mapping @ 0x%x", vaddr, 0,0,0); 602 1.17 mrg return (KERN_INVALID_ADDRESS); 603 1.7 mrg } 604 1.7 mrg /* locked: maps(read) */ 605 1.7 mrg 606 1.7 mrg /* 607 1.7 mrg * check protection 608 1.7 mrg */ 609 1.7 mrg 610 1.7 mrg if ((ufi.entry->protection & access_type) != access_type) { 611 1.7 mrg UVMHIST_LOG(maphist, 612 1.7 mrg "<- protection failure (prot=0x%x, access=0x%x)", 613 1.7 mrg ufi.entry->protection, access_type, 0, 0); 614 1.7 mrg uvmfault_unlockmaps(&ufi, FALSE); 615 1.17 mrg return (KERN_PROTECTION_FAILURE); 616 1.7 mrg } 617 1.7 mrg 618 1.7 mrg /* 619 1.7 mrg * "enter_prot" is the protection we want to enter the page in at. 620 1.7 mrg * for certain pages (e.g. copy-on-write pages) this protection can 621 1.7 mrg * be more strict than ufi.entry->protection. "wired" means either 622 1.7 mrg * the entry is wired or we are fault-wiring the pg. 623 1.7 mrg */ 624 1.7 mrg 625 1.7 mrg enter_prot = ufi.entry->protection; 626 1.7 mrg wired = (ufi.entry->wired_count != 0) || (fault_type == VM_FAULT_WIRE); 627 1.7 mrg if (wired) 628 1.7 mrg access_type = enter_prot; /* full access for wired */ 629 1.7 mrg 630 1.7 mrg /* 631 1.7 mrg * handle "needs_copy" case. if we need to copy the amap we will 632 1.7 mrg * have to drop our readlock and relock it with a write lock. (we 633 1.7 mrg * need a write lock to change anything in a map entry [e.g. 634 1.7 mrg * needs_copy]). 635 1.7 mrg */ 636 1.7 mrg 637 1.7 mrg if (UVM_ET_ISNEEDSCOPY(ufi.entry)) { 638 1.7 mrg if ((access_type & VM_PROT_WRITE) || 639 1.7 mrg (ufi.entry->object.uvm_obj == NULL)) { 640 1.7 mrg /* need to clear */ 641 1.7 mrg UVMHIST_LOG(maphist, 642 1.7 mrg " need to clear needs_copy and refault",0,0,0,0); 643 1.7 mrg uvmfault_unlockmaps(&ufi, FALSE); 644 1.7 mrg uvmfault_amapcopy(&ufi); 645 1.7 mrg uvmexp.fltamcopy++; 646 1.7 mrg goto ReFault; 647 1.7 mrg 648 1.7 mrg } else { 649 1.7 mrg 650 1.7 mrg /* 651 1.7 mrg * ensure that we pmap_enter page R/O since 652 1.7 mrg * needs_copy is still true 653 1.7 mrg */ 654 1.23 mycroft enter_prot &= ~VM_PROT_WRITE; 655 1.7 mrg 656 1.7 mrg } 657 1.7 mrg } 658 1.7 mrg 659 1.7 mrg /* 660 1.7 mrg * identify the players 661 1.7 mrg */ 662 1.7 mrg 663 1.7 mrg amap = ufi.entry->aref.ar_amap; /* top layer */ 664 1.7 mrg uobj = ufi.entry->object.uvm_obj; /* bottom layer */ 665 1.7 mrg 666 1.7 mrg /* 667 1.7 mrg * check for a case 0 fault. if nothing backing the entry then 668 1.7 mrg * error now. 669 1.7 mrg */ 670 1.7 mrg 671 1.7 mrg if (amap == NULL && uobj == NULL) { 672 1.7 mrg uvmfault_unlockmaps(&ufi, FALSE); 673 1.7 mrg UVMHIST_LOG(maphist,"<- no backing store, no overlay",0,0,0,0); 674 1.17 mrg return (KERN_INVALID_ADDRESS); 675 1.7 mrg } 676 1.1 mrg 677 1.7 mrg /* 678 1.7 mrg * establish range of interest based on advice from mapper 679 1.7 mrg * and then clip to fit map entry. note that we only want 680 1.7 mrg * to do this the first time through the fault. if we 681 1.7 mrg * ReFault we will disable this by setting "narrow" to true. 682 1.7 mrg */ 683 1.1 mrg 684 1.7 mrg if (narrow == FALSE) { 685 1.7 mrg 686 1.7 mrg /* wide fault (!narrow) */ 687 1.1 mrg #ifdef DIAGNOSTIC 688 1.7 mrg if (uvmadvice[ufi.entry->advice].advice != ufi.entry->advice) 689 1.7 mrg panic("fault: advice mismatch!"); 690 1.1 mrg #endif 691 1.7 mrg nback = min(uvmadvice[ufi.entry->advice].nback, 692 1.15 chs (ufi.orig_rvaddr - ufi.entry->start) >> PAGE_SHIFT); 693 1.15 chs startva = ufi.orig_rvaddr - (nback << PAGE_SHIFT); 694 1.7 mrg nforw = min(uvmadvice[ufi.entry->advice].nforw, 695 1.15 chs ((ufi.entry->end - ufi.orig_rvaddr) >> 696 1.15 chs PAGE_SHIFT) - 1); 697 1.7 mrg /* 698 1.7 mrg * note: "-1" because we don't want to count the 699 1.7 mrg * faulting page as forw 700 1.7 mrg */ 701 1.7 mrg npages = nback + nforw + 1; 702 1.7 mrg centeridx = nback; 703 1.7 mrg 704 1.7 mrg narrow = FALSE; /* ensure only once per-fault */ 705 1.7 mrg 706 1.7 mrg } else { 707 1.7 mrg 708 1.7 mrg /* narrow fault! */ 709 1.7 mrg nback = nforw = 0; 710 1.13 chuck startva = ufi.orig_rvaddr; 711 1.7 mrg npages = 1; 712 1.7 mrg centeridx = 0; 713 1.1 mrg 714 1.7 mrg } 715 1.1 mrg 716 1.7 mrg /* locked: maps(read) */ 717 1.13 chuck UVMHIST_LOG(maphist, " narrow=%d, back=%d, forw=%d, startva=0x%x", 718 1.16 chs narrow, nback, nforw, startva); 719 1.7 mrg UVMHIST_LOG(maphist, " entry=0x%x, amap=0x%x, obj=0x%x", ufi.entry, 720 1.16 chs amap, uobj, 0); 721 1.1 mrg 722 1.7 mrg /* 723 1.7 mrg * if we've got an amap, lock it and extract current anons. 724 1.7 mrg */ 725 1.7 mrg 726 1.7 mrg if (amap) { 727 1.19 chuck amap_lock(amap); 728 1.7 mrg anons = anons_store; 729 1.7 mrg amap_lookups(&ufi.entry->aref, startva - ufi.entry->start, 730 1.7 mrg anons, npages); 731 1.7 mrg } else { 732 1.7 mrg anons = NULL; /* to be safe */ 733 1.7 mrg } 734 1.7 mrg 735 1.7 mrg /* locked: maps(read), amap(if there) */ 736 1.7 mrg 737 1.7 mrg /* 738 1.7 mrg * for MADV_SEQUENTIAL mappings we want to deactivate the back pages 739 1.7 mrg * now and then forget about them (for the rest of the fault). 740 1.7 mrg */ 741 1.7 mrg 742 1.7 mrg if (ufi.entry->advice == MADV_SEQUENTIAL) { 743 1.7 mrg 744 1.7 mrg UVMHIST_LOG(maphist, " MADV_SEQUENTIAL: flushing backpages", 745 1.7 mrg 0,0,0,0); 746 1.7 mrg /* flush back-page anons? */ 747 1.7 mrg if (amap) 748 1.7 mrg uvmfault_anonflush(anons, nback); 749 1.7 mrg 750 1.7 mrg /* flush object? */ 751 1.7 mrg if (uobj) { 752 1.7 mrg objaddr = 753 1.7 mrg (startva - ufi.entry->start) + ufi.entry->offset; 754 1.7 mrg simple_lock(&uobj->vmobjlock); 755 1.7 mrg (void) uobj->pgops->pgo_flush(uobj, objaddr, objaddr + 756 1.15 chs (nback << PAGE_SHIFT), PGO_DEACTIVATE); 757 1.7 mrg simple_unlock(&uobj->vmobjlock); 758 1.7 mrg } 759 1.7 mrg 760 1.7 mrg /* now forget about the backpages */ 761 1.7 mrg if (amap) 762 1.7 mrg anons += nback; 763 1.15 chs startva = startva + (nback << PAGE_SHIFT); 764 1.7 mrg npages -= nback; 765 1.7 mrg nback = centeridx = 0; 766 1.7 mrg } 767 1.7 mrg 768 1.7 mrg /* locked: maps(read), amap(if there) */ 769 1.1 mrg 770 1.7 mrg /* 771 1.7 mrg * map in the backpages and frontpages we found in the amap in hopes 772 1.7 mrg * of preventing future faults. we also init the pages[] array as 773 1.7 mrg * we go. 774 1.7 mrg */ 775 1.7 mrg 776 1.13 chuck currva = startva; 777 1.7 mrg shadowed = FALSE; 778 1.7 mrg for (lcv = 0 ; lcv < npages ; lcv++, currva += PAGE_SIZE) { 779 1.7 mrg 780 1.7 mrg /* 781 1.7 mrg * dont play with VAs that are already mapped 782 1.13 chuck * except for center) 783 1.7 mrg * XXX: return value of pmap_extract disallows PA 0 784 1.7 mrg */ 785 1.7 mrg if (lcv != centeridx) { 786 1.7 mrg pa = pmap_extract(ufi.orig_map->pmap, currva); 787 1.7 mrg if (pa != NULL) { 788 1.7 mrg pages[lcv] = PGO_DONTCARE; 789 1.7 mrg continue; 790 1.7 mrg } 791 1.7 mrg } 792 1.7 mrg 793 1.7 mrg /* 794 1.7 mrg * unmapped or center page. check if any anon at this level. 795 1.7 mrg */ 796 1.7 mrg if (amap == NULL || anons[lcv] == NULL) { 797 1.7 mrg pages[lcv] = NULL; 798 1.7 mrg continue; 799 1.7 mrg } 800 1.7 mrg 801 1.7 mrg /* 802 1.7 mrg * check for present page and map if possible. re-activate it. 803 1.7 mrg */ 804 1.7 mrg 805 1.7 mrg pages[lcv] = PGO_DONTCARE; 806 1.7 mrg if (lcv == centeridx) { /* save center for later! */ 807 1.7 mrg shadowed = TRUE; 808 1.7 mrg continue; 809 1.7 mrg } 810 1.7 mrg anon = anons[lcv]; 811 1.7 mrg simple_lock(&anon->an_lock); 812 1.7 mrg /* ignore loaned pages */ 813 1.7 mrg if (anon->u.an_page && anon->u.an_page->loan_count == 0 && 814 1.7 mrg (anon->u.an_page->flags & (PG_RELEASED|PG_BUSY)) == 0) { 815 1.7 mrg uvm_lock_pageq(); 816 1.7 mrg uvm_pageactivate(anon->u.an_page); /* reactivate */ 817 1.7 mrg uvm_unlock_pageq(); 818 1.7 mrg UVMHIST_LOG(maphist, 819 1.7 mrg " MAPPING: n anon: pm=0x%x, va=0x%x, pg=0x%x", 820 1.7 mrg ufi.orig_map->pmap, currva, anon->u.an_page, 0); 821 1.7 mrg uvmexp.fltnamap++; 822 1.7 mrg pmap_enter(ufi.orig_map->pmap, currva, 823 1.7 mrg VM_PAGE_TO_PHYS(anon->u.an_page), 824 1.25 mycroft (anon->an_ref > 1) ? (enter_prot & ~VM_PROT_WRITE) : 825 1.25 mycroft enter_prot, 826 1.23 mycroft (ufi.entry->wired_count != 0), 0); 827 1.7 mrg } 828 1.7 mrg simple_unlock(&anon->an_lock); 829 1.7 mrg } 830 1.7 mrg 831 1.7 mrg /* locked: maps(read), amap(if there) */ 832 1.7 mrg /* (shadowed == TRUE) if there is an anon at the faulting address */ 833 1.7 mrg UVMHIST_LOG(maphist, " shadowed=%d, will_get=%d", shadowed, 834 1.17 mrg (uobj && shadowed == FALSE),0,0); 835 1.1 mrg 836 1.7 mrg /* 837 1.7 mrg * note that if we are really short of RAM we could sleep in the above 838 1.7 mrg * call to pmap_enter with everything locked. bad? 839 1.7 mrg * XXXCDC: this is fixed in PMAP_NEW (no sleep alloc's in pmap) 840 1.7 mrg */ 841 1.7 mrg 842 1.7 mrg /* 843 1.7 mrg * if the desired page is not shadowed by the amap and we have a 844 1.7 mrg * backing object, then we check to see if the backing object would 845 1.7 mrg * prefer to handle the fault itself (rather than letting us do it 846 1.7 mrg * with the usual pgo_get hook). the backing object signals this by 847 1.7 mrg * providing a pgo_fault routine. 848 1.7 mrg */ 849 1.1 mrg 850 1.7 mrg if (uobj && shadowed == FALSE && uobj->pgops->pgo_fault != NULL) { 851 1.1 mrg 852 1.7 mrg simple_lock(&uobj->vmobjlock); 853 1.1 mrg 854 1.7 mrg /* locked: maps(read), amap (if there), uobj */ 855 1.7 mrg result = uobj->pgops->pgo_fault(&ufi, startva, pages, npages, 856 1.1 mrg centeridx, fault_type, access_type, 857 1.1 mrg PGO_LOCKED); 858 1.7 mrg /* locked: nothing, pgo_fault has unlocked everything */ 859 1.7 mrg 860 1.7 mrg if (result == VM_PAGER_OK) 861 1.17 mrg return (KERN_SUCCESS); /* pgo_fault did pmap enter */ 862 1.7 mrg else if (result == VM_PAGER_REFAULT) 863 1.7 mrg goto ReFault; /* try again! */ 864 1.7 mrg else 865 1.17 mrg return (KERN_PROTECTION_FAILURE); 866 1.7 mrg } 867 1.7 mrg 868 1.7 mrg /* 869 1.7 mrg * now, if the desired page is not shadowed by the amap and we have 870 1.7 mrg * a backing object that does not have a special fault routine, then 871 1.7 mrg * we ask (with pgo_get) the object for resident pages that we care 872 1.7 mrg * about and attempt to map them in. we do not let pgo_get block 873 1.7 mrg * (PGO_LOCKED). 874 1.7 mrg * 875 1.7 mrg * ("get" has the option of doing a pmap_enter for us) 876 1.7 mrg */ 877 1.7 mrg 878 1.7 mrg if (uobj && shadowed == FALSE) { 879 1.7 mrg simple_lock(&uobj->vmobjlock); 880 1.1 mrg 881 1.7 mrg /* locked (!shadowed): maps(read), amap (if there), uobj */ 882 1.7 mrg /* 883 1.7 mrg * the following call to pgo_get does _not_ change locking state 884 1.7 mrg */ 885 1.7 mrg 886 1.7 mrg uvmexp.fltlget++; 887 1.7 mrg gotpages = npages; 888 1.7 mrg result = uobj->pgops->pgo_get(uobj, ufi.entry->offset + 889 1.1 mrg (startva - ufi.entry->start), 890 1.1 mrg pages, &gotpages, centeridx, 891 1.24 mycroft access_type & MASK(ufi.entry), 892 1.1 mrg ufi.entry->advice, PGO_LOCKED); 893 1.1 mrg 894 1.7 mrg /* 895 1.7 mrg * check for pages to map, if we got any 896 1.7 mrg */ 897 1.7 mrg 898 1.7 mrg uobjpage = NULL; 899 1.7 mrg 900 1.7 mrg if (gotpages) { 901 1.13 chuck currva = startva; 902 1.7 mrg for (lcv = 0 ; lcv < npages ; 903 1.7 mrg lcv++, currva += PAGE_SIZE) { 904 1.7 mrg 905 1.7 mrg if (pages[lcv] == NULL || 906 1.7 mrg pages[lcv] == PGO_DONTCARE) 907 1.7 mrg continue; 908 1.1 mrg 909 1.1 mrg #ifdef DIAGNOSTIC 910 1.7 mrg /* 911 1.7 mrg * pager sanity check: pgo_get with 912 1.7 mrg * PGO_LOCKED should never return a 913 1.7 mrg * released page to us. 914 1.7 mrg */ 915 1.7 mrg if (pages[lcv]->flags & PG_RELEASED) 916 1.7 mrg panic("uvm_fault: pgo_get PGO_LOCKED gave us a RELEASED page"); 917 1.1 mrg #endif 918 1.1 mrg 919 1.7 mrg /* 920 1.7 mrg * if center page is resident and not 921 1.7 mrg * PG_BUSY|PG_RELEASED then pgo_get 922 1.7 mrg * made it PG_BUSY for us and gave 923 1.7 mrg * us a handle to it. remember this 924 1.7 mrg * page as "uobjpage." (for later use). 925 1.7 mrg */ 926 1.7 mrg 927 1.7 mrg if (lcv == centeridx) { 928 1.7 mrg uobjpage = pages[lcv]; 929 1.7 mrg UVMHIST_LOG(maphist, " got uobjpage (0x%x) with locked get", 930 1.7 mrg uobjpage, 0,0,0); 931 1.7 mrg continue; 932 1.7 mrg } 933 1.1 mrg 934 1.7 mrg /* 935 1.7 mrg * note: calling pgo_get with locked data 936 1.7 mrg * structures returns us pages which are 937 1.7 mrg * neither busy nor released, so we don't 938 1.7 mrg * need to check for this. we can just 939 1.7 mrg * directly enter the page (after moving it 940 1.7 mrg * to the head of the active queue [useful?]). 941 1.7 mrg */ 942 1.7 mrg 943 1.7 mrg uvm_lock_pageq(); 944 1.7 mrg uvm_pageactivate(pages[lcv]); /* reactivate */ 945 1.7 mrg uvm_unlock_pageq(); 946 1.7 mrg UVMHIST_LOG(maphist, 947 1.7 mrg " MAPPING: n obj: pm=0x%x, va=0x%x, pg=0x%x", 948 1.7 mrg ufi.orig_map->pmap, currva, pages[lcv], 0); 949 1.7 mrg uvmexp.fltnomap++; 950 1.7 mrg pmap_enter(ufi.orig_map->pmap, currva, 951 1.7 mrg VM_PAGE_TO_PHYS(pages[lcv]), 952 1.27 mycroft enter_prot & MASK(ufi.entry), wired, 0); 953 1.7 mrg 954 1.7 mrg /* 955 1.7 mrg * NOTE: page can't be PG_WANTED or PG_RELEASED 956 1.7 mrg * because we've held the lock the whole time 957 1.7 mrg * we've had the handle. 958 1.7 mrg */ 959 1.7 mrg pages[lcv]->flags &= ~(PG_BUSY); /* un-busy! */ 960 1.7 mrg UVM_PAGE_OWN(pages[lcv], NULL); 961 1.1 mrg 962 1.7 mrg /* done! */ 963 1.7 mrg } /* for "lcv" loop */ 964 1.7 mrg } /* "gotpages" != 0 */ 965 1.7 mrg 966 1.7 mrg /* note: object still _locked_ */ 967 1.7 mrg } else { 968 1.7 mrg 969 1.7 mrg uobjpage = NULL; 970 1.7 mrg 971 1.7 mrg } 972 1.7 mrg 973 1.7 mrg /* locked (shadowed): maps(read), amap */ 974 1.7 mrg /* locked (!shadowed): maps(read), amap(if there), 975 1.7 mrg uobj(if !null), uobjpage(if !null) */ 976 1.7 mrg 977 1.7 mrg /* 978 1.7 mrg * note that at this point we are done with any front or back pages. 979 1.7 mrg * we are now going to focus on the center page (i.e. the one we've 980 1.7 mrg * faulted on). if we have faulted on the top (anon) layer 981 1.7 mrg * [i.e. case 1], then the anon we want is anons[centeridx] (we have 982 1.7 mrg * not touched it yet). if we have faulted on the bottom (uobj) 983 1.7 mrg * layer [i.e. case 2] and the page was both present and available, 984 1.7 mrg * then we've got a pointer to it as "uobjpage" and we've already 985 1.8 chuck * made it BUSY. 986 1.7 mrg */ 987 1.7 mrg 988 1.7 mrg /* 989 1.7 mrg * there are four possible cases we must address: 1A, 1B, 2A, and 2B 990 1.7 mrg */ 991 1.7 mrg 992 1.7 mrg /* 993 1.7 mrg * redirect case 2: if we are not shadowed, go to case 2. 994 1.7 mrg */ 995 1.7 mrg 996 1.7 mrg if (shadowed == FALSE) 997 1.7 mrg goto Case2; 998 1.7 mrg 999 1.7 mrg /* locked: maps(read), amap */ 1000 1.7 mrg 1001 1.7 mrg /* 1002 1.7 mrg * handle case 1: fault on an anon in our amap 1003 1.7 mrg */ 1004 1.7 mrg 1005 1.7 mrg anon = anons[centeridx]; 1006 1.7 mrg UVMHIST_LOG(maphist, " case 1 fault: anon=0x%x", anon, 0,0,0); 1007 1.7 mrg simple_lock(&anon->an_lock); 1008 1.7 mrg 1009 1.7 mrg /* locked: maps(read), amap, anon */ 1010 1.7 mrg 1011 1.7 mrg /* 1012 1.7 mrg * no matter if we have case 1A or case 1B we are going to need to 1013 1.7 mrg * have the anon's memory resident. ensure that now. 1014 1.7 mrg */ 1015 1.7 mrg 1016 1.7 mrg /* 1017 1.7 mrg * let uvmfault_anonget do the dirty work. if it fails (!OK) it will 1018 1.7 mrg * unlock for us. if it is OK, locks are still valid and locked. 1019 1.7 mrg * also, if it is OK, then the anon's page is on the queues. 1020 1.7 mrg * if the page is on loan from a uvm_object, then anonget will 1021 1.7 mrg * lock that object for us if it does not fail. 1022 1.7 mrg */ 1023 1.7 mrg 1024 1.7 mrg result = uvmfault_anonget(&ufi, amap, anon); 1025 1.7 mrg 1026 1.7 mrg if (result == VM_PAGER_REFAULT) 1027 1.7 mrg goto ReFault; 1028 1.7 mrg 1029 1.7 mrg if (result == VM_PAGER_AGAIN) { 1030 1.7 mrg tsleep((caddr_t)&lbolt, PVM, "fltagain1", 0); 1031 1.7 mrg goto ReFault; 1032 1.1 mrg } 1033 1.7 mrg 1034 1.7 mrg if (result != VM_PAGER_OK) 1035 1.17 mrg return (KERN_PROTECTION_FAILURE); /* XXX??? */ 1036 1.7 mrg 1037 1.7 mrg /* 1038 1.7 mrg * uobj is non null if the page is on loan from an object (i.e. uobj) 1039 1.7 mrg */ 1040 1.7 mrg 1041 1.7 mrg uobj = anon->u.an_page->uobject; /* locked by anonget if !NULL */ 1042 1.7 mrg 1043 1.7 mrg /* locked: maps(read), amap, anon, uobj(if one) */ 1044 1.7 mrg 1045 1.7 mrg /* 1046 1.7 mrg * special handling for loaned pages 1047 1.7 mrg */ 1048 1.7 mrg if (anon->u.an_page->loan_count) { 1049 1.7 mrg 1050 1.7 mrg if ((access_type & VM_PROT_WRITE) == 0) { 1051 1.7 mrg 1052 1.7 mrg /* 1053 1.7 mrg * for read faults on loaned pages we just cap the 1054 1.7 mrg * protection at read-only. 1055 1.7 mrg */ 1056 1.7 mrg 1057 1.7 mrg enter_prot = enter_prot & ~VM_PROT_WRITE; 1058 1.7 mrg 1059 1.7 mrg } else { 1060 1.7 mrg /* 1061 1.7 mrg * note that we can't allow writes into a loaned page! 1062 1.7 mrg * 1063 1.7 mrg * if we have a write fault on a loaned page in an 1064 1.7 mrg * anon then we need to look at the anon's ref count. 1065 1.7 mrg * if it is greater than one then we are going to do 1066 1.7 mrg * a normal copy-on-write fault into a new anon (this 1067 1.7 mrg * is not a problem). however, if the reference count 1068 1.7 mrg * is one (a case where we would normally allow a 1069 1.7 mrg * write directly to the page) then we need to kill 1070 1.7 mrg * the loan before we continue. 1071 1.7 mrg */ 1072 1.7 mrg 1073 1.7 mrg /* >1 case is already ok */ 1074 1.7 mrg if (anon->an_ref == 1) { 1075 1.7 mrg 1076 1.7 mrg /* get new un-owned replacement page */ 1077 1.28 chs pg = uvm_pagealloc(NULL, 0, NULL, 0); 1078 1.7 mrg if (pg == NULL) { 1079 1.7 mrg uvmfault_unlockall(&ufi, amap, uobj, 1080 1.7 mrg anon); 1081 1.7 mrg uvm_wait("flt_noram2"); 1082 1.7 mrg goto ReFault; 1083 1.7 mrg } 1084 1.7 mrg 1085 1.7 mrg /* 1086 1.7 mrg * copy data, kill loan, and drop uobj lock 1087 1.7 mrg * (if any) 1088 1.7 mrg */ 1089 1.7 mrg /* copy old -> new */ 1090 1.7 mrg uvm_pagecopy(anon->u.an_page, pg); 1091 1.7 mrg 1092 1.7 mrg /* force reload */ 1093 1.7 mrg pmap_page_protect(PMAP_PGARG(anon->u.an_page), 1094 1.7 mrg VM_PROT_NONE); 1095 1.7 mrg uvm_lock_pageq(); /* KILL loan */ 1096 1.7 mrg if (uobj) 1097 1.7 mrg /* if we were loaning */ 1098 1.7 mrg anon->u.an_page->loan_count--; 1099 1.7 mrg anon->u.an_page->uanon = NULL; 1100 1.7 mrg /* in case we owned */ 1101 1.7 mrg anon->u.an_page->pqflags &= ~PQ_ANON; 1102 1.7 mrg uvm_unlock_pageq(); 1103 1.7 mrg if (uobj) { 1104 1.7 mrg simple_unlock(&uobj->vmobjlock); 1105 1.7 mrg uobj = NULL; 1106 1.7 mrg } 1107 1.7 mrg 1108 1.7 mrg /* install new page in anon */ 1109 1.7 mrg anon->u.an_page = pg; 1110 1.7 mrg pg->uanon = anon; 1111 1.7 mrg pg->pqflags |= PQ_ANON; 1112 1.7 mrg pg->flags &= ~(PG_BUSY|PG_FAKE); 1113 1.7 mrg UVM_PAGE_OWN(pg, NULL); 1114 1.7 mrg 1115 1.7 mrg /* done! */ 1116 1.7 mrg } /* ref == 1 */ 1117 1.7 mrg } /* write fault */ 1118 1.7 mrg } /* loan count */ 1119 1.7 mrg 1120 1.7 mrg /* 1121 1.7 mrg * if we are case 1B then we will need to allocate a new blank 1122 1.7 mrg * anon to transfer the data into. note that we have a lock 1123 1.7 mrg * on anon, so no one can busy or release the page until we are done. 1124 1.7 mrg * also note that the ref count can't drop to zero here because 1125 1.7 mrg * it is > 1 and we are only dropping one ref. 1126 1.7 mrg * 1127 1.7 mrg * in the (hopefully very rare) case that we are out of RAM we 1128 1.7 mrg * will unlock, wait for more RAM, and refault. 1129 1.7 mrg * 1130 1.7 mrg * if we are out of anon VM we kill the process (XXX: could wait?). 1131 1.7 mrg */ 1132 1.7 mrg 1133 1.7 mrg if ((access_type & VM_PROT_WRITE) != 0 && anon->an_ref > 1) { 1134 1.7 mrg 1135 1.7 mrg UVMHIST_LOG(maphist, " case 1B: COW fault",0,0,0,0); 1136 1.7 mrg uvmexp.flt_acow++; 1137 1.7 mrg oanon = anon; /* oanon = old, locked anon */ 1138 1.7 mrg anon = uvm_analloc(); 1139 1.7 mrg if (anon) 1140 1.28 chs pg = uvm_pagealloc(NULL, 0, anon, 0); 1141 1.14 tv #ifdef __GNUC__ 1142 1.7 mrg else 1143 1.7 mrg pg = NULL; /* XXX: gcc */ 1144 1.1 mrg #endif 1145 1.1 mrg 1146 1.7 mrg /* check for out of RAM */ 1147 1.7 mrg if (anon == NULL || pg == NULL) { 1148 1.7 mrg if (anon) 1149 1.7 mrg uvm_anfree(anon); 1150 1.7 mrg uvmfault_unlockall(&ufi, amap, uobj, oanon); 1151 1.22 chs #ifdef DIAGNOSTIC 1152 1.22 chs if (uvmexp.swpgonly > uvmexp.swpages) { 1153 1.22 chs panic("uvmexp.swpgonly botch"); 1154 1.22 chs } 1155 1.22 chs #endif 1156 1.22 chs if (anon == NULL || uvmexp.swpgonly == uvmexp.swpages) { 1157 1.7 mrg UVMHIST_LOG(maphist, 1158 1.7 mrg "<- failed. out of VM",0,0,0,0); 1159 1.7 mrg uvmexp.fltnoanon++; 1160 1.17 mrg return (KERN_RESOURCE_SHORTAGE); 1161 1.7 mrg } 1162 1.22 chs 1163 1.7 mrg uvmexp.fltnoram++; 1164 1.7 mrg uvm_wait("flt_noram3"); /* out of RAM, wait for more */ 1165 1.7 mrg goto ReFault; 1166 1.7 mrg } 1167 1.7 mrg 1168 1.7 mrg /* got all resources, replace anon with nanon */ 1169 1.7 mrg 1170 1.7 mrg uvm_pagecopy(oanon->u.an_page, pg); /* pg now !PG_CLEAN */ 1171 1.7 mrg pg->flags &= ~(PG_BUSY|PG_FAKE); /* un-busy! new page */ 1172 1.7 mrg UVM_PAGE_OWN(pg, NULL); 1173 1.13 chuck amap_add(&ufi.entry->aref, ufi.orig_rvaddr - ufi.entry->start, 1174 1.7 mrg anon, 1); 1175 1.7 mrg 1176 1.7 mrg /* deref: can not drop to zero here by defn! */ 1177 1.7 mrg oanon->an_ref--; 1178 1.7 mrg 1179 1.7 mrg /* 1180 1.7 mrg * note: oanon still locked. anon is _not_ locked, but we 1181 1.7 mrg * have the sole references to in from amap which _is_ locked. 1182 1.7 mrg * thus, no one can get at it until we are done with it. 1183 1.7 mrg */ 1184 1.7 mrg 1185 1.7 mrg } else { 1186 1.7 mrg 1187 1.7 mrg uvmexp.flt_anon++; 1188 1.7 mrg oanon = anon; /* old, locked anon is same as anon */ 1189 1.7 mrg pg = anon->u.an_page; 1190 1.7 mrg if (anon->an_ref > 1) /* disallow writes to ref > 1 anons */ 1191 1.7 mrg enter_prot = enter_prot & ~VM_PROT_WRITE; 1192 1.7 mrg 1193 1.7 mrg } 1194 1.7 mrg 1195 1.7 mrg /* locked: maps(read), amap, anon */ 1196 1.7 mrg 1197 1.7 mrg /* 1198 1.7 mrg * now map the page in ... 1199 1.7 mrg * XXX: old fault unlocks object before pmap_enter. this seems 1200 1.7 mrg * suspect since some other thread could blast the page out from 1201 1.7 mrg * under us between the unlock and the pmap_enter. 1202 1.7 mrg */ 1203 1.7 mrg 1204 1.7 mrg UVMHIST_LOG(maphist, " MAPPING: anon: pm=0x%x, va=0x%x, pg=0x%x", 1205 1.7 mrg ufi.orig_map->pmap, ufi.orig_rvaddr, pg, 0); 1206 1.7 mrg pmap_enter(ufi.orig_map->pmap, ufi.orig_rvaddr, VM_PAGE_TO_PHYS(pg), 1207 1.23 mycroft enter_prot, wired, access_type); 1208 1.7 mrg 1209 1.7 mrg /* 1210 1.7 mrg * ... and update the page queues. 1211 1.7 mrg */ 1212 1.7 mrg 1213 1.7 mrg uvm_lock_pageq(); 1214 1.7 mrg 1215 1.7 mrg if (fault_type == VM_FAULT_WIRE) { 1216 1.8 chuck uvm_pagewire(pg); 1217 1.29 chs 1218 1.29 chs /* 1219 1.29 chs * since the now-wired page cannot be paged out, 1220 1.29 chs * release its swap resources for others to use. 1221 1.29 chs * since an anon with no swap cannot be PG_CLEAN, 1222 1.29 chs * clear its clean flag now. 1223 1.29 chs */ 1224 1.29 chs 1225 1.29 chs pg->flags &= ~(PG_CLEAN); 1226 1.22 chs uvm_anon_dropswap(anon); 1227 1.7 mrg } else { 1228 1.7 mrg /* activate it */ 1229 1.7 mrg uvm_pageactivate(pg); 1230 1.7 mrg } 1231 1.7 mrg 1232 1.7 mrg uvm_unlock_pageq(); 1233 1.7 mrg 1234 1.7 mrg /* 1235 1.7 mrg * done case 1! finish up by unlocking everything and returning success 1236 1.7 mrg */ 1237 1.1 mrg 1238 1.7 mrg uvmfault_unlockall(&ufi, amap, uobj, oanon); 1239 1.17 mrg return (KERN_SUCCESS); 1240 1.1 mrg 1241 1.1 mrg 1242 1.1 mrg Case2: 1243 1.7 mrg /* 1244 1.7 mrg * handle case 2: faulting on backing object or zero fill 1245 1.7 mrg */ 1246 1.7 mrg 1247 1.7 mrg /* 1248 1.7 mrg * locked: 1249 1.7 mrg * maps(read), amap(if there), uobj(if !null), uobjpage(if !null) 1250 1.7 mrg */ 1251 1.7 mrg 1252 1.7 mrg /* 1253 1.7 mrg * note that uobjpage can not be PGO_DONTCARE at this point. we now 1254 1.7 mrg * set uobjpage to PGO_DONTCARE if we are doing a zero fill. if we 1255 1.7 mrg * have a backing object, check and see if we are going to promote 1256 1.7 mrg * the data up to an anon during the fault. 1257 1.7 mrg */ 1258 1.7 mrg 1259 1.7 mrg if (uobj == NULL) { 1260 1.7 mrg uobjpage = PGO_DONTCARE; 1261 1.7 mrg promote = TRUE; /* always need anon here */ 1262 1.7 mrg } else { 1263 1.7 mrg /* assert(uobjpage != PGO_DONTCARE) */ 1264 1.7 mrg promote = (access_type & VM_PROT_WRITE) && 1265 1.7 mrg UVM_ET_ISCOPYONWRITE(ufi.entry); 1266 1.7 mrg } 1267 1.7 mrg UVMHIST_LOG(maphist, " case 2 fault: promote=%d, zfill=%d", 1268 1.1 mrg promote, (uobj == NULL), 0,0); 1269 1.1 mrg 1270 1.7 mrg /* 1271 1.9 chuck * if uobjpage is not null then we do not need to do I/O to get the 1272 1.9 chuck * uobjpage. 1273 1.9 chuck * 1274 1.7 mrg * if uobjpage is null, then we need to unlock and ask the pager to 1275 1.7 mrg * get the data for us. once we have the data, we need to reverify 1276 1.7 mrg * the state the world. we are currently not holding any resources. 1277 1.7 mrg */ 1278 1.1 mrg 1279 1.9 chuck if (uobjpage) { 1280 1.9 chuck /* update rusage counters */ 1281 1.9 chuck curproc->p_addr->u_stats.p_ru.ru_minflt++; 1282 1.9 chuck } else { 1283 1.9 chuck /* update rusage counters */ 1284 1.9 chuck curproc->p_addr->u_stats.p_ru.ru_majflt++; 1285 1.7 mrg 1286 1.7 mrg /* locked: maps(read), amap(if there), uobj */ 1287 1.7 mrg uvmfault_unlockall(&ufi, amap, NULL, NULL); 1288 1.7 mrg /* locked: uobj */ 1289 1.7 mrg 1290 1.7 mrg uvmexp.fltget++; 1291 1.7 mrg gotpages = 1; 1292 1.7 mrg result = uobj->pgops->pgo_get(uobj, 1293 1.13 chuck (ufi.orig_rvaddr - ufi.entry->start) + ufi.entry->offset, 1294 1.7 mrg &uobjpage, &gotpages, 0, 1295 1.24 mycroft access_type & MASK(ufi.entry), 1296 1.7 mrg ufi.entry->advice, 0); 1297 1.7 mrg 1298 1.7 mrg /* locked: uobjpage(if result OK) */ 1299 1.7 mrg 1300 1.7 mrg /* 1301 1.7 mrg * recover from I/O 1302 1.7 mrg */ 1303 1.1 mrg 1304 1.7 mrg if (result != VM_PAGER_OK) { 1305 1.7 mrg 1306 1.1 mrg #ifdef DIAGNOSTIC 1307 1.7 mrg if (result == VM_PAGER_PEND) 1308 1.1 mrg panic("uvm_fault: pgo_get got PENDing on non-async I/O"); 1309 1.1 mrg #endif 1310 1.1 mrg 1311 1.7 mrg if (result == VM_PAGER_AGAIN) { 1312 1.1 mrg UVMHIST_LOG(maphist, " pgo_get says TRY AGAIN!",0,0,0,0); 1313 1.7 mrg tsleep((caddr_t)&lbolt, PVM, "fltagain2", 0); 1314 1.1 mrg goto ReFault; 1315 1.7 mrg } 1316 1.1 mrg 1317 1.7 mrg UVMHIST_LOG(maphist, "<- pgo_get failed (code %d)", 1318 1.7 mrg result, 0,0,0); 1319 1.17 mrg return (KERN_PROTECTION_FAILURE); /* XXX i/o error */ 1320 1.7 mrg } 1321 1.7 mrg 1322 1.7 mrg /* locked: uobjpage */ 1323 1.7 mrg 1324 1.7 mrg /* 1325 1.7 mrg * re-verify the state of the world by first trying to relock 1326 1.7 mrg * the maps. always relock the object. 1327 1.7 mrg */ 1328 1.7 mrg 1329 1.7 mrg locked = uvmfault_relock(&ufi); 1330 1.7 mrg if (locked && amap) 1331 1.19 chuck amap_lock(amap); 1332 1.7 mrg simple_lock(&uobj->vmobjlock); 1333 1.7 mrg 1334 1.7 mrg /* locked(locked): maps(read), amap(if !null), uobj, uobjpage */ 1335 1.7 mrg /* locked(!locked): uobj, uobjpage */ 1336 1.7 mrg 1337 1.7 mrg /* 1338 1.7 mrg * verify that the page has not be released and re-verify 1339 1.7 mrg * that amap slot is still free. if there is a problem, 1340 1.7 mrg * we unlock and clean up. 1341 1.7 mrg */ 1342 1.7 mrg 1343 1.7 mrg if ((uobjpage->flags & PG_RELEASED) != 0 || 1344 1.7 mrg (locked && amap && 1345 1.7 mrg amap_lookup(&ufi.entry->aref, 1346 1.13 chuck ufi.orig_rvaddr - ufi.entry->start))) { 1347 1.7 mrg if (locked) 1348 1.7 mrg uvmfault_unlockall(&ufi, amap, NULL, NULL); 1349 1.7 mrg locked = FALSE; 1350 1.7 mrg } 1351 1.7 mrg 1352 1.7 mrg /* 1353 1.7 mrg * didn't get the lock? release the page and retry. 1354 1.7 mrg */ 1355 1.7 mrg 1356 1.7 mrg if (locked == FALSE) { 1357 1.7 mrg 1358 1.7 mrg UVMHIST_LOG(maphist, 1359 1.7 mrg " wasn't able to relock after fault: retry", 1360 1.7 mrg 0,0,0,0); 1361 1.7 mrg if (uobjpage->flags & PG_WANTED) 1362 1.7 mrg /* still holding object lock */ 1363 1.7 mrg thread_wakeup(uobjpage); 1364 1.1 mrg 1365 1.7 mrg if (uobjpage->flags & PG_RELEASED) { 1366 1.7 mrg uvmexp.fltpgrele++; 1367 1.1 mrg #ifdef DIAGNOSTIC 1368 1.7 mrg if (uobj->pgops->pgo_releasepg == NULL) 1369 1.7 mrg panic("uvm_fault: object has no releasepg function"); 1370 1.1 mrg #endif 1371 1.7 mrg /* frees page */ 1372 1.7 mrg if (uobj->pgops->pgo_releasepg(uobjpage,NULL)) 1373 1.7 mrg /* unlock if still alive */ 1374 1.7 mrg simple_unlock(&uobj->vmobjlock); 1375 1.7 mrg goto ReFault; 1376 1.7 mrg } 1377 1.7 mrg 1378 1.7 mrg uvm_lock_pageq(); 1379 1.7 mrg /* make sure it is in queues */ 1380 1.7 mrg uvm_pageactivate(uobjpage); 1381 1.7 mrg 1382 1.7 mrg uvm_unlock_pageq(); 1383 1.7 mrg uobjpage->flags &= ~(PG_BUSY|PG_WANTED); 1384 1.7 mrg UVM_PAGE_OWN(uobjpage, NULL); 1385 1.7 mrg simple_unlock(&uobj->vmobjlock); 1386 1.7 mrg goto ReFault; 1387 1.7 mrg 1388 1.7 mrg } 1389 1.7 mrg 1390 1.7 mrg /* 1391 1.7 mrg * we have the data in uobjpage which is PG_BUSY and 1392 1.7 mrg * !PG_RELEASED. we are holding object lock (so the page 1393 1.7 mrg * can't be released on us). 1394 1.7 mrg */ 1395 1.7 mrg 1396 1.7 mrg /* locked: maps(read), amap(if !null), uobj, uobjpage */ 1397 1.1 mrg 1398 1.7 mrg } 1399 1.1 mrg 1400 1.1 mrg /* 1401 1.7 mrg * locked: 1402 1.7 mrg * maps(read), amap(if !null), uobj(if !null), uobjpage(if uobj) 1403 1.1 mrg */ 1404 1.1 mrg 1405 1.7 mrg /* 1406 1.7 mrg * notes: 1407 1.7 mrg * - at this point uobjpage can not be NULL 1408 1.7 mrg * - at this point uobjpage can not be PG_RELEASED (since we checked 1409 1.7 mrg * for it above) 1410 1.7 mrg * - at this point uobjpage could be PG_WANTED (handle later) 1411 1.7 mrg */ 1412 1.7 mrg 1413 1.7 mrg if (promote == FALSE) { 1414 1.1 mrg 1415 1.7 mrg /* 1416 1.7 mrg * we are not promoting. if the mapping is COW ensure that we 1417 1.7 mrg * don't give more access than we should (e.g. when doing a read 1418 1.7 mrg * fault on a COPYONWRITE mapping we want to map the COW page in 1419 1.7 mrg * R/O even though the entry protection could be R/W). 1420 1.7 mrg * 1421 1.7 mrg * set "pg" to the page we want to map in (uobjpage, usually) 1422 1.7 mrg */ 1423 1.7 mrg 1424 1.7 mrg uvmexp.flt_obj++; 1425 1.7 mrg if (UVM_ET_ISCOPYONWRITE(ufi.entry)) 1426 1.24 mycroft enter_prot &= ~VM_PROT_WRITE; 1427 1.7 mrg pg = uobjpage; /* map in the actual object */ 1428 1.7 mrg 1429 1.7 mrg /* assert(uobjpage != PGO_DONTCARE) */ 1430 1.7 mrg 1431 1.7 mrg /* 1432 1.7 mrg * we are faulting directly on the page. be careful 1433 1.7 mrg * about writing to loaned pages... 1434 1.7 mrg */ 1435 1.7 mrg if (uobjpage->loan_count) { 1436 1.7 mrg 1437 1.7 mrg if ((access_type & VM_PROT_WRITE) == 0) { 1438 1.7 mrg /* read fault: cap the protection at readonly */ 1439 1.7 mrg /* cap! */ 1440 1.7 mrg enter_prot = enter_prot & ~VM_PROT_WRITE; 1441 1.7 mrg } else { 1442 1.7 mrg /* write fault: must break the loan here */ 1443 1.7 mrg 1444 1.7 mrg /* alloc new un-owned page */ 1445 1.28 chs pg = uvm_pagealloc(NULL, 0, NULL, 0); 1446 1.7 mrg 1447 1.7 mrg if (pg == NULL) { 1448 1.7 mrg /* 1449 1.7 mrg * drop ownership of page, it can't 1450 1.7 mrg * be released 1451 1.7 mrg * */ 1452 1.7 mrg if (uobjpage->flags & PG_WANTED) 1453 1.7 mrg thread_wakeup(uobjpage); 1454 1.7 mrg uobjpage->flags &= ~(PG_BUSY|PG_WANTED); 1455 1.7 mrg UVM_PAGE_OWN(uobjpage, NULL); 1456 1.7 mrg 1457 1.7 mrg uvm_lock_pageq(); 1458 1.7 mrg /* activate: we will need it later */ 1459 1.7 mrg uvm_pageactivate(uobjpage); 1460 1.7 mrg 1461 1.7 mrg uvm_unlock_pageq(); 1462 1.7 mrg uvmfault_unlockall(&ufi, amap, uobj, 1463 1.7 mrg NULL); 1464 1.7 mrg UVMHIST_LOG(maphist, 1465 1.20 mrg " out of RAM breaking loan, waiting", 1466 1.20 mrg 0,0,0,0); 1467 1.7 mrg uvmexp.fltnoram++; 1468 1.7 mrg uvm_wait("flt_noram4"); 1469 1.7 mrg goto ReFault; 1470 1.7 mrg } 1471 1.7 mrg 1472 1.7 mrg /* 1473 1.7 mrg * copy the data from the old page to the new 1474 1.7 mrg * one and clear the fake/clean flags on the 1475 1.7 mrg * new page (keep it busy). force a reload 1476 1.7 mrg * of the old page by clearing it from all 1477 1.7 mrg * pmaps. then lock the page queues to 1478 1.7 mrg * rename the pages. 1479 1.7 mrg */ 1480 1.7 mrg uvm_pagecopy(uobjpage, pg); /* old -> new */ 1481 1.7 mrg pg->flags &= ~(PG_FAKE|PG_CLEAN); 1482 1.7 mrg pmap_page_protect(PMAP_PGARG(uobjpage), 1483 1.7 mrg VM_PROT_NONE); 1484 1.7 mrg if (uobjpage->flags & PG_WANTED) 1485 1.7 mrg thread_wakeup(uobjpage); 1486 1.7 mrg /* uobj still locked */ 1487 1.7 mrg uobjpage->flags &= ~(PG_WANTED|PG_BUSY); 1488 1.7 mrg UVM_PAGE_OWN(uobjpage, NULL); 1489 1.7 mrg 1490 1.7 mrg uvm_lock_pageq(); 1491 1.7 mrg offset = uobjpage->offset; 1492 1.7 mrg /* remove old page */ 1493 1.7 mrg uvm_pagerealloc(uobjpage, NULL, 0); 1494 1.7 mrg 1495 1.7 mrg /* 1496 1.7 mrg * at this point we have absolutely no 1497 1.7 mrg * control over uobjpage 1498 1.7 mrg */ 1499 1.7 mrg /* install new page */ 1500 1.7 mrg uvm_pagerealloc(pg, uobj, offset); 1501 1.7 mrg uvm_unlock_pageq(); 1502 1.7 mrg 1503 1.7 mrg /* 1504 1.7 mrg * done! loan is broken and "pg" is 1505 1.7 mrg * PG_BUSY. it can now replace uobjpage. 1506 1.7 mrg */ 1507 1.7 mrg 1508 1.7 mrg uobjpage = pg; 1509 1.7 mrg 1510 1.7 mrg } /* write fault case */ 1511 1.7 mrg } /* if loan_count */ 1512 1.7 mrg 1513 1.7 mrg } else { 1514 1.7 mrg 1515 1.7 mrg /* 1516 1.7 mrg * if we are going to promote the data to an anon we 1517 1.7 mrg * allocate a blank anon here and plug it into our amap. 1518 1.7 mrg */ 1519 1.1 mrg #if DIAGNOSTIC 1520 1.7 mrg if (amap == NULL) 1521 1.7 mrg panic("uvm_fault: want to promote data, but no anon"); 1522 1.1 mrg #endif 1523 1.1 mrg 1524 1.7 mrg anon = uvm_analloc(); 1525 1.7 mrg if (anon) 1526 1.28 chs pg = uvm_pagealloc(NULL, 0, anon, 0); 1527 1.14 tv #ifdef __GNUC__ 1528 1.7 mrg else 1529 1.7 mrg pg = NULL; /* XXX: gcc */ 1530 1.1 mrg #endif 1531 1.1 mrg 1532 1.7 mrg /* 1533 1.7 mrg * out of memory resources? 1534 1.7 mrg */ 1535 1.7 mrg if (anon == NULL || pg == NULL) { 1536 1.7 mrg 1537 1.7 mrg /* 1538 1.7 mrg * arg! must unbusy our page and fail or sleep. 1539 1.7 mrg */ 1540 1.7 mrg if (uobjpage != PGO_DONTCARE) { 1541 1.7 mrg if (uobjpage->flags & PG_WANTED) 1542 1.7 mrg /* still holding object lock */ 1543 1.7 mrg thread_wakeup(uobjpage); 1544 1.7 mrg 1545 1.7 mrg uvm_lock_pageq(); 1546 1.7 mrg /* make sure it is in queues */ 1547 1.7 mrg uvm_pageactivate(uobjpage); 1548 1.7 mrg uvm_unlock_pageq(); 1549 1.7 mrg /* un-busy! (still locked) */ 1550 1.7 mrg uobjpage->flags &= ~(PG_BUSY|PG_WANTED); 1551 1.7 mrg UVM_PAGE_OWN(uobjpage, NULL); 1552 1.7 mrg } 1553 1.7 mrg 1554 1.7 mrg /* unlock and fail ... */ 1555 1.7 mrg uvmfault_unlockall(&ufi, amap, uobj, NULL); 1556 1.22 chs #ifdef DIAGNOSTIC 1557 1.22 chs if (uvmexp.swpgonly > uvmexp.swpages) { 1558 1.22 chs panic("uvmexp.swpgonly botch"); 1559 1.22 chs } 1560 1.22 chs #endif 1561 1.22 chs if (anon == NULL || uvmexp.swpgonly == uvmexp.swpages) { 1562 1.7 mrg UVMHIST_LOG(maphist, " promote: out of VM", 1563 1.7 mrg 0,0,0,0); 1564 1.7 mrg uvmexp.fltnoanon++; 1565 1.17 mrg return (KERN_RESOURCE_SHORTAGE); 1566 1.7 mrg } 1567 1.22 chs 1568 1.7 mrg UVMHIST_LOG(maphist, " out of RAM, waiting for more", 1569 1.7 mrg 0,0,0,0); 1570 1.7 mrg uvm_anfree(anon); 1571 1.7 mrg uvmexp.fltnoram++; 1572 1.7 mrg uvm_wait("flt_noram5"); 1573 1.7 mrg goto ReFault; 1574 1.7 mrg } 1575 1.7 mrg 1576 1.7 mrg /* 1577 1.7 mrg * fill in the data 1578 1.7 mrg */ 1579 1.7 mrg 1580 1.7 mrg if (uobjpage != PGO_DONTCARE) { 1581 1.7 mrg uvmexp.flt_prcopy++; 1582 1.7 mrg /* copy page [pg now dirty] */ 1583 1.7 mrg uvm_pagecopy(uobjpage, pg); 1584 1.7 mrg 1585 1.7 mrg /* 1586 1.7 mrg * promote to shared amap? make sure all sharing 1587 1.7 mrg * procs see it 1588 1.7 mrg */ 1589 1.19 chuck if ((amap_flags(amap) & AMAP_SHARED) != 0) { 1590 1.7 mrg pmap_page_protect(PMAP_PGARG(uobjpage), 1591 1.7 mrg VM_PROT_NONE); 1592 1.7 mrg } 1593 1.7 mrg 1594 1.7 mrg /* 1595 1.7 mrg * dispose of uobjpage. it can't be PG_RELEASED 1596 1.7 mrg * since we still hold the object lock. drop 1597 1.7 mrg * handle to uobj as well. 1598 1.7 mrg */ 1599 1.7 mrg 1600 1.7 mrg if (uobjpage->flags & PG_WANTED) 1601 1.7 mrg /* still have the obj lock */ 1602 1.7 mrg thread_wakeup(uobjpage); 1603 1.7 mrg uobjpage->flags &= ~(PG_BUSY|PG_WANTED); 1604 1.7 mrg UVM_PAGE_OWN(uobjpage, NULL); 1605 1.7 mrg uvm_lock_pageq(); 1606 1.7 mrg uvm_pageactivate(uobjpage); /* put it back */ 1607 1.7 mrg uvm_unlock_pageq(); 1608 1.7 mrg simple_unlock(&uobj->vmobjlock); 1609 1.7 mrg uobj = NULL; 1610 1.7 mrg UVMHIST_LOG(maphist, 1611 1.7 mrg " promote uobjpage 0x%x to anon/page 0x%x/0x%x", 1612 1.7 mrg uobjpage, anon, pg, 0); 1613 1.7 mrg 1614 1.7 mrg } else { 1615 1.7 mrg uvmexp.flt_przero++; 1616 1.7 mrg uvm_pagezero(pg); /* zero page [pg now dirty] */ 1617 1.7 mrg UVMHIST_LOG(maphist," zero fill anon/page 0x%x/0%x", 1618 1.7 mrg anon, pg, 0, 0); 1619 1.7 mrg } 1620 1.7 mrg 1621 1.13 chuck amap_add(&ufi.entry->aref, ufi.orig_rvaddr - ufi.entry->start, 1622 1.7 mrg anon, 0); 1623 1.7 mrg 1624 1.7 mrg } 1625 1.7 mrg 1626 1.7 mrg /* 1627 1.7 mrg * locked: 1628 1.7 mrg * maps(read), amap(if !null), uobj(if !null), uobjpage(if uobj) 1629 1.7 mrg * 1630 1.7 mrg * note: pg is either the uobjpage or the new page in the new anon 1631 1.7 mrg */ 1632 1.7 mrg 1633 1.7 mrg /* 1634 1.7 mrg * all resources are present. we can now map it in and free our 1635 1.7 mrg * resources. 1636 1.7 mrg */ 1637 1.7 mrg 1638 1.7 mrg UVMHIST_LOG(maphist, 1639 1.7 mrg " MAPPING: case2: pm=0x%x, va=0x%x, pg=0x%x, promote=%d", 1640 1.7 mrg ufi.orig_map->pmap, ufi.orig_rvaddr, pg, promote); 1641 1.7 mrg pmap_enter(ufi.orig_map->pmap, ufi.orig_rvaddr, VM_PAGE_TO_PHYS(pg), 1642 1.23 mycroft enter_prot, wired, access_type); 1643 1.1 mrg 1644 1.1 mrg uvm_lock_pageq(); 1645 1.7 mrg 1646 1.7 mrg if (fault_type == VM_FAULT_WIRE) { 1647 1.8 chuck uvm_pagewire(pg); 1648 1.22 chs if (pg->pqflags & PQ_AOBJ) { 1649 1.29 chs 1650 1.29 chs /* 1651 1.29 chs * since the now-wired page cannot be paged out, 1652 1.29 chs * release its swap resources for others to use. 1653 1.29 chs * since an aobj page with no swap cannot be PG_CLEAN, 1654 1.29 chs * clear its clean flag now. 1655 1.29 chs */ 1656 1.29 chs 1657 1.29 chs pg->flags &= ~(PG_CLEAN); 1658 1.22 chs uao_dropswap(uobj, pg->offset >> PAGE_SHIFT); 1659 1.22 chs } 1660 1.7 mrg } else { 1661 1.7 mrg /* activate it */ 1662 1.7 mrg uvm_pageactivate(pg); 1663 1.7 mrg } 1664 1.7 mrg 1665 1.1 mrg uvm_unlock_pageq(); 1666 1.7 mrg 1667 1.7 mrg if (pg->flags & PG_WANTED) 1668 1.7 mrg thread_wakeup(pg); /* lock still held */ 1669 1.7 mrg 1670 1.7 mrg /* 1671 1.7 mrg * note that pg can't be PG_RELEASED since we did not drop the object 1672 1.7 mrg * lock since the last time we checked. 1673 1.7 mrg */ 1674 1.1 mrg 1675 1.7 mrg pg->flags &= ~(PG_BUSY|PG_FAKE|PG_WANTED); 1676 1.7 mrg UVM_PAGE_OWN(pg, NULL); 1677 1.7 mrg uvmfault_unlockall(&ufi, amap, uobj, NULL); 1678 1.1 mrg 1679 1.7 mrg UVMHIST_LOG(maphist, "<- done (SUCCESS!)",0,0,0,0); 1680 1.17 mrg return (KERN_SUCCESS); 1681 1.1 mrg } 1682 1.1 mrg 1683 1.1 mrg 1684 1.1 mrg /* 1685 1.1 mrg * uvm_fault_wire: wire down a range of virtual addresses in a map. 1686 1.1 mrg * 1687 1.1 mrg * => map should be locked by caller? If so how can we call 1688 1.1 mrg * uvm_fault? WRONG. 1689 1.1 mrg * => XXXCDC: locking here is all screwed up!!! start with 1690 1.1 mrg * uvm_map_pageable and fix it. 1691 1.1 mrg */ 1692 1.1 mrg 1693 1.7 mrg int 1694 1.30 thorpej uvm_fault_wire(map, start, end, access_type) 1695 1.7 mrg vm_map_t map; 1696 1.12 eeh vaddr_t start, end; 1697 1.30 thorpej vm_prot_t access_type; 1698 1.7 mrg { 1699 1.12 eeh vaddr_t va; 1700 1.7 mrg pmap_t pmap; 1701 1.7 mrg int rv; 1702 1.7 mrg 1703 1.7 mrg pmap = vm_map_pmap(map); 1704 1.7 mrg 1705 1.7 mrg /* 1706 1.7 mrg * call pmap pageable: this tells the pmap layer to lock down these 1707 1.7 mrg * page tables. 1708 1.7 mrg */ 1709 1.1 mrg 1710 1.7 mrg pmap_pageable(pmap, start, end, FALSE); 1711 1.7 mrg 1712 1.7 mrg /* 1713 1.7 mrg * now fault it in page at a time. if the fault fails then we have 1714 1.7 mrg * to undo what we have done. note that in uvm_fault VM_PROT_NONE 1715 1.7 mrg * is replaced with the max protection if fault_type is VM_FAULT_WIRE. 1716 1.7 mrg */ 1717 1.1 mrg 1718 1.7 mrg for (va = start ; va < end ; va += PAGE_SIZE) { 1719 1.30 thorpej rv = uvm_fault(map, va, VM_FAULT_WIRE, access_type); 1720 1.7 mrg if (rv) { 1721 1.7 mrg if (va != start) { 1722 1.31 thorpej uvm_fault_unwire(map, start, va); 1723 1.7 mrg } 1724 1.17 mrg return (rv); 1725 1.7 mrg } 1726 1.7 mrg } 1727 1.1 mrg 1728 1.17 mrg return (KERN_SUCCESS); 1729 1.1 mrg } 1730 1.1 mrg 1731 1.1 mrg /* 1732 1.1 mrg * uvm_fault_unwire(): unwire range of virtual space. 1733 1.1 mrg */ 1734 1.1 mrg 1735 1.7 mrg void 1736 1.31 thorpej uvm_fault_unwire(map, start, end) 1737 1.31 thorpej vm_map_t map; 1738 1.12 eeh vaddr_t start, end; 1739 1.7 mrg { 1740 1.31 thorpej pmap_t pmap = vm_map_pmap(map); 1741 1.12 eeh vaddr_t va; 1742 1.12 eeh paddr_t pa; 1743 1.7 mrg struct vm_page *pg; 1744 1.31 thorpej 1745 1.31 thorpej #ifdef DIAGNOSTIC 1746 1.31 thorpej if (map->flags & VM_MAP_INTRSAFE) 1747 1.31 thorpej panic("uvm_fault_unwire: intrsafe map"); 1748 1.31 thorpej #endif 1749 1.7 mrg 1750 1.7 mrg /* 1751 1.7 mrg * we assume that the area we are unwiring has actually been wired 1752 1.7 mrg * in the first place. this means that we should be able to extract 1753 1.7 mrg * the PAs from the pmap. we also lock out the page daemon so that 1754 1.7 mrg * we can call uvm_pageunwire. 1755 1.7 mrg */ 1756 1.7 mrg 1757 1.7 mrg uvm_lock_pageq(); 1758 1.7 mrg 1759 1.7 mrg for (va = start; va < end ; va += PAGE_SIZE) { 1760 1.7 mrg pa = pmap_extract(pmap, va); 1761 1.1 mrg 1762 1.7 mrg /* XXX: assumes PA 0 cannot be in map */ 1763 1.12 eeh if (pa == (paddr_t) 0) { 1764 1.7 mrg panic("uvm_fault_unwire: unwiring non-wired memory"); 1765 1.7 mrg } 1766 1.7 mrg pmap_change_wiring(pmap, va, FALSE); /* tell the pmap */ 1767 1.7 mrg pg = PHYS_TO_VM_PAGE(pa); 1768 1.7 mrg if (pg) 1769 1.7 mrg uvm_pageunwire(pg); 1770 1.7 mrg } 1771 1.1 mrg 1772 1.7 mrg uvm_unlock_pageq(); 1773 1.1 mrg 1774 1.7 mrg /* 1775 1.7 mrg * now we call pmap_pageable to let the pmap know that the page tables 1776 1.7 mrg * in this space no longer need to be wired. 1777 1.7 mrg */ 1778 1.1 mrg 1779 1.7 mrg pmap_pageable(pmap, start, end, TRUE); 1780 1.1 mrg 1781 1.1 mrg } 1782
Indexes created Sat Sep 20 22:09:52 GMT 2025