uvm_swap.c revision 1.27.4.1
1 1.27.4.1 chs /* $NetBSD: uvm_swap.c,v 1.27.4.1 1999/06/07 04:25:38 chs Exp $ */ 2 1.1 mrg 3 1.1 mrg /* 4 1.1 mrg * Copyright (c) 1995, 1996, 1997 Matthew R. Green 5 1.1 mrg * All rights reserved. 6 1.1 mrg * 7 1.1 mrg * Redistribution and use in source and binary forms, with or without 8 1.1 mrg * modification, are permitted provided that the following conditions 9 1.1 mrg * are met: 10 1.1 mrg * 1. Redistributions of source code must retain the above copyright 11 1.1 mrg * notice, this list of conditions and the following disclaimer. 12 1.1 mrg * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 mrg * notice, this list of conditions and the following disclaimer in the 14 1.1 mrg * documentation and/or other materials provided with the distribution. 15 1.1 mrg * 3. The name of the author may not be used to endorse or promote products 16 1.1 mrg * derived from this software without specific prior written permission. 17 1.1 mrg * 18 1.1 mrg * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 19 1.1 mrg * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 20 1.1 mrg * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 21 1.1 mrg * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 22 1.1 mrg * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, 23 1.1 mrg * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; 24 1.1 mrg * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED 25 1.1 mrg * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, 26 1.1 mrg * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 27 1.1 mrg * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 28 1.1 mrg * SUCH DAMAGE. 29 1.3 mrg * 30 1.3 mrg * from: NetBSD: vm_swap.c,v 1.52 1997/12/02 13:47:37 pk Exp 31 1.3 mrg * from: Id: uvm_swap.c,v 1.1.2.42 1998/02/02 20:38:06 chuck Exp 32 1.1 mrg */ 33 1.5 mrg 34 1.6 thorpej #include "fs_nfs.h" 35 1.5 mrg #include "opt_uvmhist.h" 36 1.16 mrg #include "opt_compat_netbsd.h" 37 1.1 mrg 38 1.1 mrg #include <sys/param.h> 39 1.1 mrg #include <sys/systm.h> 40 1.1 mrg #include <sys/buf.h> 41 1.1 mrg #include <sys/proc.h> 42 1.1 mrg #include <sys/namei.h> 43 1.1 mrg #include <sys/disklabel.h> 44 1.1 mrg #include <sys/errno.h> 45 1.1 mrg #include <sys/kernel.h> 46 1.1 mrg #include <sys/malloc.h> 47 1.1 mrg #include <sys/vnode.h> 48 1.1 mrg #include <sys/file.h> 49 1.1 mrg #include <sys/extent.h> 50 1.1 mrg #include <sys/mount.h> 51 1.12 pk #include <sys/pool.h> 52 1.1 mrg #include <sys/syscallargs.h> 53 1.17 mrg #include <sys/swap.h> 54 1.1 mrg 55 1.1 mrg #include <vm/vm.h> 56 1.1 mrg #include <vm/vm_conf.h> 57 1.1 mrg 58 1.1 mrg #include <uvm/uvm.h> 59 1.1 mrg 60 1.1 mrg #include <miscfs/specfs/specdev.h> 61 1.1 mrg 62 1.1 mrg /* 63 1.1 mrg * uvm_swap.c: manage configuration and i/o to swap space. 64 1.1 mrg */ 65 1.1 mrg 66 1.1 mrg /* 67 1.1 mrg * swap space is managed in the following way: 68 1.1 mrg * 69 1.1 mrg * each swap partition or file is described by a "swapdev" structure. 70 1.1 mrg * each "swapdev" structure contains a "swapent" structure which contains 71 1.1 mrg * information that is passed up to the user (via system calls). 72 1.1 mrg * 73 1.1 mrg * each swap partition is assigned a "priority" (int) which controls 74 1.1 mrg * swap parition usage. 75 1.1 mrg * 76 1.1 mrg * the system maintains a global data structure describing all swap 77 1.1 mrg * partitions/files. there is a sorted LIST of "swappri" structures 78 1.1 mrg * which describe "swapdev"'s at that priority. this LIST is headed 79 1.1 mrg * by the "swap_priority" global var. each "swappri" contains a 80 1.1 mrg * CIRCLEQ of "swapdev" structures at that priority. 81 1.1 mrg * 82 1.1 mrg * the system maintains a fixed pool of "swapbuf" structures for use 83 1.1 mrg * at swap i/o time. a swapbuf includes a "buf" structure and an 84 1.1 mrg * "aiodone" [we want to avoid malloc()'ing anything at swapout time 85 1.1 mrg * since memory may be low]. 86 1.1 mrg * 87 1.1 mrg * locking: 88 1.1 mrg * - swap_syscall_lock (sleep lock): this lock serializes the swapctl 89 1.1 mrg * system call and prevents the swap priority list from changing 90 1.1 mrg * while we are in the middle of a system call (e.g. SWAP_STATS). 91 1.26 chs * - uvm.swap_data_lock (simple_lock): this lock protects all swap data 92 1.1 mrg * structures including the priority list, the swapdev structures, 93 1.1 mrg * and the swapmap extent. 94 1.1 mrg * - swap_buf_lock (simple_lock): this lock protects the free swapbuf 95 1.1 mrg * pool. 96 1.1 mrg * 97 1.1 mrg * each swap device has the following info: 98 1.1 mrg * - swap device in use (could be disabled, preventing future use) 99 1.1 mrg * - swap enabled (allows new allocations on swap) 100 1.1 mrg * - map info in /dev/drum 101 1.1 mrg * - vnode pointer 102 1.1 mrg * for swap files only: 103 1.1 mrg * - block size 104 1.1 mrg * - max byte count in buffer 105 1.1 mrg * - buffer 106 1.1 mrg * - credentials to use when doing i/o to file 107 1.1 mrg * 108 1.1 mrg * userland controls and configures swap with the swapctl(2) system call. 109 1.1 mrg * the sys_swapctl performs the following operations: 110 1.1 mrg * [1] SWAP_NSWAP: returns the number of swap devices currently configured 111 1.1 mrg * [2] SWAP_STATS: given a pointer to an array of swapent structures 112 1.1 mrg * (passed in via "arg") of a size passed in via "misc" ... we load 113 1.1 mrg * the current swap config into the array. 114 1.1 mrg * [3] SWAP_ON: given a pathname in arg (could be device or file) and a 115 1.1 mrg * priority in "misc", start swapping on it. 116 1.1 mrg * [4] SWAP_OFF: as SWAP_ON, but stops swapping to a device 117 1.1 mrg * [5] SWAP_CTL: changes the priority of a swap device (new priority in 118 1.1 mrg * "misc") 119 1.1 mrg */ 120 1.1 mrg 121 1.1 mrg /* 122 1.1 mrg * SWAP_TO_FILES: allows swapping to plain files. 123 1.1 mrg */ 124 1.1 mrg 125 1.1 mrg #define SWAP_TO_FILES 126 1.1 mrg 127 1.1 mrg /* 128 1.1 mrg * swapdev: describes a single swap partition/file 129 1.1 mrg * 130 1.1 mrg * note the following should be true: 131 1.1 mrg * swd_inuse <= swd_nblks [number of blocks in use is <= total blocks] 132 1.1 mrg * swd_nblks <= swd_mapsize [because mapsize includes miniroot+disklabel] 133 1.1 mrg */ 134 1.1 mrg struct swapdev { 135 1.16 mrg struct oswapent swd_ose; 136 1.16 mrg #define swd_dev swd_ose.ose_dev /* device id */ 137 1.16 mrg #define swd_flags swd_ose.ose_flags /* flags:inuse/enable/fake */ 138 1.16 mrg #define swd_priority swd_ose.ose_priority /* our priority */ 139 1.16 mrg /* also: swd_ose.ose_nblks, swd_ose.ose_inuse */ 140 1.16 mrg char *swd_path; /* saved pathname of device */ 141 1.16 mrg int swd_pathlen; /* length of pathname */ 142 1.16 mrg int swd_npages; /* #pages we can use */ 143 1.16 mrg int swd_npginuse; /* #pages in use */ 144 1.16 mrg int swd_drumoffset; /* page0 offset in drum */ 145 1.16 mrg int swd_drumsize; /* #pages in drum */ 146 1.16 mrg struct extent *swd_ex; /* extent for this swapdev */ 147 1.16 mrg struct vnode *swd_vp; /* backing vnode */ 148 1.16 mrg CIRCLEQ_ENTRY(swapdev) swd_next; /* priority circleq */ 149 1.1 mrg 150 1.1 mrg #ifdef SWAP_TO_FILES 151 1.16 mrg int swd_bsize; /* blocksize (bytes) */ 152 1.16 mrg int swd_maxactive; /* max active i/o reqs */ 153 1.16 mrg struct buf swd_tab; /* buffer list */ 154 1.16 mrg struct ucred *swd_cred; /* cred for file access */ 155 1.1 mrg #endif 156 1.1 mrg }; 157 1.1 mrg 158 1.1 mrg /* 159 1.1 mrg * swap device priority entry; the list is kept sorted on `spi_priority'. 160 1.1 mrg */ 161 1.1 mrg struct swappri { 162 1.1 mrg int spi_priority; /* priority */ 163 1.1 mrg CIRCLEQ_HEAD(spi_swapdev, swapdev) spi_swapdev; 164 1.1 mrg /* circleq of swapdevs at this priority */ 165 1.1 mrg LIST_ENTRY(swappri) spi_swappri; /* global list of pri's */ 166 1.1 mrg }; 167 1.1 mrg 168 1.1 mrg /* 169 1.1 mrg * swapbuf, swapbuffer plus async i/o info 170 1.1 mrg */ 171 1.1 mrg struct swapbuf { 172 1.1 mrg struct buf sw_buf; /* a buffer structure */ 173 1.1 mrg struct uvm_aiodesc sw_aio; /* aiodesc structure, used if ASYNC */ 174 1.1 mrg }; 175 1.1 mrg 176 1.1 mrg /* 177 1.1 mrg * The following two structures are used to keep track of data transfers 178 1.1 mrg * on swap devices associated with regular files. 179 1.1 mrg * NOTE: this code is more or less a copy of vnd.c; we use the same 180 1.1 mrg * structure names here to ease porting.. 181 1.1 mrg */ 182 1.1 mrg struct vndxfer { 183 1.1 mrg struct buf *vx_bp; /* Pointer to parent buffer */ 184 1.1 mrg struct swapdev *vx_sdp; 185 1.1 mrg int vx_error; 186 1.1 mrg int vx_pending; /* # of pending aux buffers */ 187 1.1 mrg int vx_flags; 188 1.1 mrg #define VX_BUSY 1 189 1.1 mrg #define VX_DEAD 2 190 1.1 mrg }; 191 1.1 mrg 192 1.1 mrg struct vndbuf { 193 1.1 mrg struct buf vb_buf; 194 1.1 mrg struct vndxfer *vb_xfer; 195 1.1 mrg }; 196 1.1 mrg 197 1.12 pk 198 1.1 mrg /* 199 1.12 pk * We keep a of pool vndbuf's and vndxfer structures. 200 1.1 mrg */ 201 1.12 pk struct pool *vndxfer_pool; 202 1.12 pk struct pool *vndbuf_pool; 203 1.1 mrg 204 1.12 pk #define getvndxfer(vnx) do { \ 205 1.12 pk int s = splbio(); \ 206 1.12 pk vnx = (struct vndxfer *) \ 207 1.12 pk pool_get(vndxfer_pool, PR_MALLOCOK|PR_WAITOK); \ 208 1.12 pk splx(s); \ 209 1.12 pk } while (0) 210 1.12 pk 211 1.12 pk #define putvndxfer(vnx) { \ 212 1.12 pk pool_put(vndxfer_pool, (void *)(vnx)); \ 213 1.12 pk } 214 1.12 pk 215 1.12 pk #define getvndbuf(vbp) do { \ 216 1.12 pk int s = splbio(); \ 217 1.12 pk vbp = (struct vndbuf *) \ 218 1.12 pk pool_get(vndbuf_pool, PR_MALLOCOK|PR_WAITOK); \ 219 1.12 pk splx(s); \ 220 1.12 pk } while (0) 221 1.1 mrg 222 1.12 pk #define putvndbuf(vbp) { \ 223 1.12 pk pool_put(vndbuf_pool, (void *)(vbp)); \ 224 1.12 pk } 225 1.1 mrg 226 1.1 mrg 227 1.1 mrg /* 228 1.1 mrg * local variables 229 1.1 mrg */ 230 1.1 mrg static struct extent *swapmap; /* controls the mapping of /dev/drum */ 231 1.1 mrg SIMPLEQ_HEAD(swapbufhead, swapbuf); 232 1.12 pk struct pool *swapbuf_pool; 233 1.1 mrg 234 1.1 mrg /* list of all active swap devices [by priority] */ 235 1.1 mrg LIST_HEAD(swap_priority, swappri); 236 1.1 mrg static struct swap_priority swap_priority; 237 1.1 mrg 238 1.1 mrg /* locks */ 239 1.1 mrg lock_data_t swap_syscall_lock; 240 1.1 mrg 241 1.1 mrg /* 242 1.1 mrg * prototypes 243 1.1 mrg */ 244 1.1 mrg static void swapdrum_add __P((struct swapdev *, int)); 245 1.1 mrg static struct swapdev *swapdrum_getsdp __P((int)); 246 1.1 mrg 247 1.1 mrg static struct swapdev *swaplist_find __P((struct vnode *, int)); 248 1.1 mrg static void swaplist_insert __P((struct swapdev *, 249 1.1 mrg struct swappri *, int)); 250 1.1 mrg static void swaplist_trim __P((void)); 251 1.1 mrg 252 1.1 mrg static int swap_on __P((struct proc *, struct swapdev *)); 253 1.1 mrg static int swap_off __P((struct proc *, struct swapdev *)); 254 1.1 mrg 255 1.1 mrg #ifdef SWAP_TO_FILES 256 1.1 mrg static void sw_reg_strategy __P((struct swapdev *, struct buf *, int)); 257 1.1 mrg static void sw_reg_iodone __P((struct buf *)); 258 1.1 mrg static void sw_reg_start __P((struct swapdev *)); 259 1.1 mrg #endif 260 1.1 mrg 261 1.1 mrg static void uvm_swap_aiodone __P((struct uvm_aiodesc *)); 262 1.1 mrg static void uvm_swap_bufdone __P((struct buf *)); 263 1.1 mrg static int uvm_swap_io __P((struct vm_page **, int, int, int)); 264 1.1 mrg 265 1.1 mrg /* 266 1.1 mrg * uvm_swap_init: init the swap system data structures and locks 267 1.1 mrg * 268 1.1 mrg * => called at boot time from init_main.c after the filesystems 269 1.1 mrg * are brought up (which happens after uvm_init()) 270 1.1 mrg */ 271 1.1 mrg void 272 1.1 mrg uvm_swap_init() 273 1.1 mrg { 274 1.1 mrg UVMHIST_FUNC("uvm_swap_init"); 275 1.1 mrg 276 1.1 mrg UVMHIST_CALLED(pdhist); 277 1.1 mrg /* 278 1.1 mrg * first, init the swap list, its counter, and its lock. 279 1.1 mrg * then get a handle on the vnode for /dev/drum by using 280 1.1 mrg * the its dev_t number ("swapdev", from MD conf.c). 281 1.1 mrg */ 282 1.1 mrg 283 1.1 mrg LIST_INIT(&swap_priority); 284 1.1 mrg uvmexp.nswapdev = 0; 285 1.1 mrg lockinit(&swap_syscall_lock, PVM, "swapsys", 0, 0); 286 1.26 chs simple_lock_init(&uvm.swap_data_lock); 287 1.12 pk 288 1.1 mrg if (bdevvp(swapdev, &swapdev_vp)) 289 1.1 mrg panic("uvm_swap_init: can't get vnode for swap device"); 290 1.1 mrg 291 1.1 mrg /* 292 1.1 mrg * create swap block resource map to map /dev/drum. the range 293 1.1 mrg * from 1 to INT_MAX allows 2 gigablocks of swap space. note 294 1.1 mrg * that block 0 is reserved (used to indicate an allocation 295 1.1 mrg * failure, or no allocation). 296 1.1 mrg */ 297 1.1 mrg swapmap = extent_create("swapmap", 1, INT_MAX, 298 1.1 mrg M_VMSWAP, 0, 0, EX_NOWAIT); 299 1.1 mrg if (swapmap == 0) 300 1.1 mrg panic("uvm_swap_init: extent_create failed"); 301 1.1 mrg 302 1.1 mrg /* 303 1.1 mrg * allocate our private pool of "swapbuf" structures (includes 304 1.1 mrg * a "buf" structure). ["nswbuf" comes from param.c and can 305 1.1 mrg * be adjusted by MD code before we get here]. 306 1.1 mrg */ 307 1.1 mrg 308 1.12 pk swapbuf_pool = 309 1.12 pk pool_create(sizeof(struct swapbuf), 0, 0, 0, "swp buf", 0, 310 1.12 pk NULL, NULL, 0); 311 1.12 pk if (swapbuf_pool == NULL) 312 1.12 pk panic("swapinit: pool_create failed"); 313 1.12 pk /* XXX - set a maximum on swapbuf_pool? */ 314 1.12 pk 315 1.12 pk vndxfer_pool = 316 1.12 pk pool_create(sizeof(struct vndxfer), 0, 0, 0, "swp vnx", 0, 317 1.12 pk NULL, NULL, 0); 318 1.12 pk if (vndxfer_pool == NULL) 319 1.12 pk panic("swapinit: pool_create failed"); 320 1.12 pk 321 1.12 pk vndbuf_pool = 322 1.12 pk pool_create(sizeof(struct vndbuf), 0, 0, 0, "swp vnd", 0, 323 1.12 pk NULL, NULL, 0); 324 1.12 pk if (vndbuf_pool == NULL) 325 1.12 pk panic("swapinit: pool_create failed"); 326 1.1 mrg /* 327 1.1 mrg * done! 328 1.1 mrg */ 329 1.1 mrg UVMHIST_LOG(pdhist, "<- done", 0, 0, 0, 0); 330 1.1 mrg } 331 1.1 mrg 332 1.1 mrg /* 333 1.1 mrg * swaplist functions: functions that operate on the list of swap 334 1.1 mrg * devices on the system. 335 1.1 mrg */ 336 1.1 mrg 337 1.1 mrg /* 338 1.1 mrg * swaplist_insert: insert swap device "sdp" into the global list 339 1.1 mrg * 340 1.26 chs * => caller must hold both swap_syscall_lock and uvm.swap_data_lock 341 1.1 mrg * => caller must provide a newly malloc'd swappri structure (we will 342 1.1 mrg * FREE it if we don't need it... this it to prevent malloc blocking 343 1.1 mrg * here while adding swap) 344 1.1 mrg */ 345 1.1 mrg static void 346 1.1 mrg swaplist_insert(sdp, newspp, priority) 347 1.1 mrg struct swapdev *sdp; 348 1.1 mrg struct swappri *newspp; 349 1.1 mrg int priority; 350 1.1 mrg { 351 1.1 mrg struct swappri *spp, *pspp; 352 1.1 mrg UVMHIST_FUNC("swaplist_insert"); UVMHIST_CALLED(pdhist); 353 1.1 mrg 354 1.1 mrg /* 355 1.1 mrg * find entry at or after which to insert the new device. 356 1.1 mrg */ 357 1.1 mrg for (pspp = NULL, spp = swap_priority.lh_first; spp != NULL; 358 1.1 mrg spp = spp->spi_swappri.le_next) { 359 1.1 mrg if (priority <= spp->spi_priority) 360 1.1 mrg break; 361 1.1 mrg pspp = spp; 362 1.1 mrg } 363 1.1 mrg 364 1.1 mrg /* 365 1.1 mrg * new priority? 366 1.1 mrg */ 367 1.1 mrg if (spp == NULL || spp->spi_priority != priority) { 368 1.1 mrg spp = newspp; /* use newspp! */ 369 1.1 mrg UVMHIST_LOG(pdhist, "created new swappri = %d", priority, 0, 0, 0); 370 1.1 mrg 371 1.1 mrg spp->spi_priority = priority; 372 1.1 mrg CIRCLEQ_INIT(&spp->spi_swapdev); 373 1.1 mrg 374 1.1 mrg if (pspp) 375 1.1 mrg LIST_INSERT_AFTER(pspp, spp, spi_swappri); 376 1.1 mrg else 377 1.1 mrg LIST_INSERT_HEAD(&swap_priority, spp, spi_swappri); 378 1.1 mrg } else { 379 1.1 mrg /* we don't need a new priority structure, free it */ 380 1.1 mrg FREE(newspp, M_VMSWAP); 381 1.1 mrg } 382 1.1 mrg 383 1.1 mrg /* 384 1.1 mrg * priority found (or created). now insert on the priority's 385 1.1 mrg * circleq list and bump the total number of swapdevs. 386 1.1 mrg */ 387 1.1 mrg sdp->swd_priority = priority; 388 1.1 mrg CIRCLEQ_INSERT_TAIL(&spp->spi_swapdev, sdp, swd_next); 389 1.1 mrg uvmexp.nswapdev++; 390 1.1 mrg 391 1.1 mrg /* 392 1.1 mrg * done! 393 1.1 mrg */ 394 1.1 mrg } 395 1.1 mrg 396 1.1 mrg /* 397 1.1 mrg * swaplist_find: find and optionally remove a swap device from the 398 1.1 mrg * global list. 399 1.1 mrg * 400 1.26 chs * => caller must hold both swap_syscall_lock and uvm.swap_data_lock 401 1.1 mrg * => we return the swapdev we found (and removed) 402 1.1 mrg */ 403 1.1 mrg static struct swapdev * 404 1.1 mrg swaplist_find(vp, remove) 405 1.1 mrg struct vnode *vp; 406 1.1 mrg boolean_t remove; 407 1.1 mrg { 408 1.1 mrg struct swapdev *sdp; 409 1.1 mrg struct swappri *spp; 410 1.1 mrg 411 1.1 mrg /* 412 1.1 mrg * search the lists for the requested vp 413 1.1 mrg */ 414 1.1 mrg for (spp = swap_priority.lh_first; spp != NULL; 415 1.1 mrg spp = spp->spi_swappri.le_next) { 416 1.1 mrg for (sdp = spp->spi_swapdev.cqh_first; 417 1.1 mrg sdp != (void *)&spp->spi_swapdev; 418 1.1 mrg sdp = sdp->swd_next.cqe_next) 419 1.1 mrg if (sdp->swd_vp == vp) { 420 1.1 mrg if (remove) { 421 1.1 mrg CIRCLEQ_REMOVE(&spp->spi_swapdev, 422 1.1 mrg sdp, swd_next); 423 1.1 mrg uvmexp.nswapdev--; 424 1.1 mrg } 425 1.1 mrg return(sdp); 426 1.1 mrg } 427 1.1 mrg } 428 1.1 mrg return (NULL); 429 1.1 mrg } 430 1.1 mrg 431 1.1 mrg 432 1.1 mrg /* 433 1.1 mrg * swaplist_trim: scan priority list for empty priority entries and kill 434 1.1 mrg * them. 435 1.1 mrg * 436 1.26 chs * => caller must hold both swap_syscall_lock and uvm.swap_data_lock 437 1.1 mrg */ 438 1.1 mrg static void 439 1.1 mrg swaplist_trim() 440 1.1 mrg { 441 1.1 mrg struct swappri *spp, *nextspp; 442 1.1 mrg 443 1.1 mrg for (spp = swap_priority.lh_first; spp != NULL; spp = nextspp) { 444 1.1 mrg nextspp = spp->spi_swappri.le_next; 445 1.1 mrg if (spp->spi_swapdev.cqh_first != (void *)&spp->spi_swapdev) 446 1.1 mrg continue; 447 1.1 mrg LIST_REMOVE(spp, spi_swappri); 448 1.1 mrg free((caddr_t)spp, M_VMSWAP); 449 1.1 mrg } 450 1.1 mrg } 451 1.1 mrg 452 1.1 mrg /* 453 1.1 mrg * swapdrum_add: add a "swapdev"'s blocks into /dev/drum's area. 454 1.1 mrg * 455 1.1 mrg * => caller must hold swap_syscall_lock 456 1.26 chs * => uvm.swap_data_lock should be unlocked (we may sleep) 457 1.1 mrg */ 458 1.1 mrg static void 459 1.1 mrg swapdrum_add(sdp, npages) 460 1.1 mrg struct swapdev *sdp; 461 1.1 mrg int npages; 462 1.1 mrg { 463 1.1 mrg u_long result; 464 1.1 mrg 465 1.1 mrg if (extent_alloc(swapmap, npages, EX_NOALIGN, EX_NOBOUNDARY, 466 1.1 mrg EX_WAITOK, &result)) 467 1.1 mrg panic("swapdrum_add"); 468 1.1 mrg 469 1.1 mrg sdp->swd_drumoffset = result; 470 1.1 mrg sdp->swd_drumsize = npages; 471 1.1 mrg } 472 1.1 mrg 473 1.1 mrg /* 474 1.1 mrg * swapdrum_getsdp: given a page offset in /dev/drum, convert it back 475 1.1 mrg * to the "swapdev" that maps that section of the drum. 476 1.1 mrg * 477 1.1 mrg * => each swapdev takes one big contig chunk of the drum 478 1.26 chs * => caller must hold uvm.swap_data_lock 479 1.1 mrg */ 480 1.1 mrg static struct swapdev * 481 1.1 mrg swapdrum_getsdp(pgno) 482 1.1 mrg int pgno; 483 1.1 mrg { 484 1.1 mrg struct swapdev *sdp; 485 1.1 mrg struct swappri *spp; 486 1.1 mrg 487 1.1 mrg for (spp = swap_priority.lh_first; spp != NULL; 488 1.1 mrg spp = spp->spi_swappri.le_next) 489 1.1 mrg for (sdp = spp->spi_swapdev.cqh_first; 490 1.1 mrg sdp != (void *)&spp->spi_swapdev; 491 1.1 mrg sdp = sdp->swd_next.cqe_next) 492 1.1 mrg if (pgno >= sdp->swd_drumoffset && 493 1.1 mrg pgno < (sdp->swd_drumoffset + sdp->swd_drumsize)) { 494 1.1 mrg return sdp; 495 1.1 mrg } 496 1.1 mrg return NULL; 497 1.1 mrg } 498 1.1 mrg 499 1.1 mrg 500 1.1 mrg /* 501 1.1 mrg * sys_swapctl: main entry point for swapctl(2) system call 502 1.1 mrg * [with two helper functions: swap_on and swap_off] 503 1.1 mrg */ 504 1.1 mrg int 505 1.1 mrg sys_swapctl(p, v, retval) 506 1.1 mrg struct proc *p; 507 1.1 mrg void *v; 508 1.1 mrg register_t *retval; 509 1.1 mrg { 510 1.1 mrg struct sys_swapctl_args /* { 511 1.1 mrg syscallarg(int) cmd; 512 1.1 mrg syscallarg(void *) arg; 513 1.1 mrg syscallarg(int) misc; 514 1.1 mrg } */ *uap = (struct sys_swapctl_args *)v; 515 1.1 mrg struct vnode *vp; 516 1.1 mrg struct nameidata nd; 517 1.1 mrg struct swappri *spp; 518 1.1 mrg struct swapdev *sdp; 519 1.1 mrg struct swapent *sep; 520 1.16 mrg char userpath[PATH_MAX + 1]; 521 1.18 enami size_t len; 522 1.18 enami int count, error, misc; 523 1.1 mrg int priority; 524 1.1 mrg UVMHIST_FUNC("sys_swapctl"); UVMHIST_CALLED(pdhist); 525 1.1 mrg 526 1.1 mrg misc = SCARG(uap, misc); 527 1.1 mrg 528 1.1 mrg /* 529 1.1 mrg * ensure serialized syscall access by grabbing the swap_syscall_lock 530 1.1 mrg */ 531 1.7 fvdl lockmgr(&swap_syscall_lock, LK_EXCLUSIVE, (void *)0); 532 1.24 mrg 533 1.1 mrg /* 534 1.1 mrg * we handle the non-priv NSWAP and STATS request first. 535 1.1 mrg * 536 1.1 mrg * SWAP_NSWAP: return number of config'd swap devices 537 1.1 mrg * [can also be obtained with uvmexp sysctl] 538 1.1 mrg */ 539 1.1 mrg if (SCARG(uap, cmd) == SWAP_NSWAP) { 540 1.8 mrg UVMHIST_LOG(pdhist, "<- done SWAP_NSWAP=%d", uvmexp.nswapdev, 541 1.8 mrg 0, 0, 0); 542 1.1 mrg *retval = uvmexp.nswapdev; 543 1.16 mrg error = 0; 544 1.16 mrg goto out; 545 1.1 mrg } 546 1.1 mrg 547 1.1 mrg /* 548 1.1 mrg * SWAP_STATS: get stats on current # of configured swap devs 549 1.1 mrg * 550 1.1 mrg * note that the swap_priority list can't change as long 551 1.1 mrg * as we are holding the swap_syscall_lock. we don't want 552 1.26 chs * to grab the uvm.swap_data_lock because we may fault&sleep during 553 1.1 mrg * copyout() and we don't want to be holding that lock then! 554 1.1 mrg */ 555 1.16 mrg if (SCARG(uap, cmd) == SWAP_STATS 556 1.16 mrg #if defined(COMPAT_13) 557 1.16 mrg || SCARG(uap, cmd) == SWAP_OSTATS 558 1.16 mrg #endif 559 1.16 mrg ) { 560 1.1 mrg sep = (struct swapent *)SCARG(uap, arg); 561 1.1 mrg count = 0; 562 1.1 mrg 563 1.1 mrg for (spp = swap_priority.lh_first; spp != NULL; 564 1.1 mrg spp = spp->spi_swappri.le_next) { 565 1.1 mrg for (sdp = spp->spi_swapdev.cqh_first; 566 1.1 mrg sdp != (void *)&spp->spi_swapdev && misc-- > 0; 567 1.1 mrg sdp = sdp->swd_next.cqe_next) { 568 1.16 mrg /* 569 1.16 mrg * backwards compatibility for system call. 570 1.16 mrg * note that we use 'struct oswapent' as an 571 1.16 mrg * overlay into both 'struct swapdev' and 572 1.16 mrg * the userland 'struct swapent', as we 573 1.16 mrg * want to retain backwards compatibility 574 1.16 mrg * with NetBSD 1.3. 575 1.16 mrg */ 576 1.16 mrg sdp->swd_ose.ose_inuse = 577 1.20 chs btodb(sdp->swd_npginuse << PAGE_SHIFT); 578 1.16 mrg error = copyout((caddr_t)&sdp->swd_ose, 579 1.16 mrg (caddr_t)sep, sizeof(struct oswapent)); 580 1.16 mrg 581 1.16 mrg /* now copy out the path if necessary */ 582 1.16 mrg #if defined(COMPAT_13) 583 1.16 mrg if (error == 0 && SCARG(uap, cmd) == SWAP_STATS) 584 1.16 mrg #else 585 1.16 mrg if (error == 0) 586 1.16 mrg #endif 587 1.16 mrg error = copyout((caddr_t)sdp->swd_path, 588 1.16 mrg (caddr_t)&sep->se_path, 589 1.16 mrg sdp->swd_pathlen); 590 1.16 mrg 591 1.16 mrg if (error) 592 1.16 mrg goto out; 593 1.1 mrg count++; 594 1.16 mrg #if defined(COMPAT_13) 595 1.16 mrg if (SCARG(uap, cmd) == SWAP_OSTATS) 596 1.16 mrg ((struct oswapent *)sep)++; 597 1.16 mrg else 598 1.16 mrg #endif 599 1.16 mrg sep++; 600 1.1 mrg } 601 1.1 mrg } 602 1.1 mrg 603 1.16 mrg UVMHIST_LOG(pdhist, "<- done SWAP_STATS", 0, 0, 0, 0); 604 1.1 mrg 605 1.1 mrg *retval = count; 606 1.16 mrg error = 0; 607 1.16 mrg goto out; 608 1.1 mrg } 609 1.1 mrg 610 1.1 mrg /* 611 1.1 mrg * all other requests require superuser privs. verify. 612 1.1 mrg */ 613 1.16 mrg if ((error = suser(p->p_ucred, &p->p_acflag))) 614 1.16 mrg goto out; 615 1.1 mrg 616 1.1 mrg /* 617 1.1 mrg * at this point we expect a path name in arg. we will 618 1.1 mrg * use namei() to gain a vnode reference (vref), and lock 619 1.1 mrg * the vnode (VOP_LOCK). 620 1.1 mrg * 621 1.1 mrg * XXX: a NULL arg means use the root vnode pointer (e.g. for 622 1.16 mrg * miniroot) 623 1.1 mrg */ 624 1.1 mrg if (SCARG(uap, arg) == NULL) { 625 1.1 mrg vp = rootvp; /* miniroot */ 626 1.7 fvdl if (vget(vp, LK_EXCLUSIVE)) { 627 1.16 mrg error = EBUSY; 628 1.16 mrg goto out; 629 1.1 mrg } 630 1.16 mrg if (SCARG(uap, cmd) == SWAP_ON && 631 1.16 mrg copystr("miniroot", userpath, sizeof userpath, &len)) 632 1.16 mrg panic("swapctl: miniroot copy failed"); 633 1.1 mrg } else { 634 1.16 mrg int space; 635 1.16 mrg char *where; 636 1.16 mrg 637 1.16 mrg if (SCARG(uap, cmd) == SWAP_ON) { 638 1.16 mrg if ((error = copyinstr(SCARG(uap, arg), userpath, 639 1.16 mrg sizeof userpath, &len))) 640 1.16 mrg goto out; 641 1.16 mrg space = UIO_SYSSPACE; 642 1.16 mrg where = userpath; 643 1.16 mrg } else { 644 1.16 mrg space = UIO_USERSPACE; 645 1.16 mrg where = (char *)SCARG(uap, arg); 646 1.1 mrg } 647 1.16 mrg NDINIT(&nd, LOOKUP, FOLLOW|LOCKLEAF, space, where, p); 648 1.16 mrg if ((error = namei(&nd))) 649 1.16 mrg goto out; 650 1.1 mrg vp = nd.ni_vp; 651 1.1 mrg } 652 1.1 mrg /* note: "vp" is referenced and locked */ 653 1.1 mrg 654 1.1 mrg error = 0; /* assume no error */ 655 1.1 mrg switch(SCARG(uap, cmd)) { 656 1.24 mrg case SWAP_DUMPDEV: 657 1.24 mrg if (vp->v_type != VBLK) { 658 1.24 mrg error = ENOTBLK; 659 1.24 mrg goto out; 660 1.24 mrg } 661 1.24 mrg dumpdev = vp->v_rdev; 662 1.24 mrg 663 1.24 mrg break; 664 1.24 mrg 665 1.1 mrg case SWAP_CTL: 666 1.1 mrg /* 667 1.1 mrg * get new priority, remove old entry (if any) and then 668 1.1 mrg * reinsert it in the correct place. finally, prune out 669 1.1 mrg * any empty priority structures. 670 1.1 mrg */ 671 1.1 mrg priority = SCARG(uap, misc); 672 1.1 mrg spp = (struct swappri *) 673 1.1 mrg malloc(sizeof *spp, M_VMSWAP, M_WAITOK); 674 1.26 chs simple_lock(&uvm.swap_data_lock); 675 1.1 mrg if ((sdp = swaplist_find(vp, 1)) == NULL) { 676 1.1 mrg error = ENOENT; 677 1.1 mrg } else { 678 1.1 mrg swaplist_insert(sdp, spp, priority); 679 1.1 mrg swaplist_trim(); 680 1.1 mrg } 681 1.26 chs simple_unlock(&uvm.swap_data_lock); 682 1.1 mrg if (error) 683 1.1 mrg free(spp, M_VMSWAP); 684 1.1 mrg break; 685 1.1 mrg 686 1.1 mrg case SWAP_ON: 687 1.1 mrg /* 688 1.1 mrg * check for duplicates. if none found, then insert a 689 1.1 mrg * dummy entry on the list to prevent someone else from 690 1.1 mrg * trying to enable this device while we are working on 691 1.1 mrg * it. 692 1.1 mrg */ 693 1.1 mrg priority = SCARG(uap, misc); 694 1.26 chs simple_lock(&uvm.swap_data_lock); 695 1.1 mrg if ((sdp = swaplist_find(vp, 0)) != NULL) { 696 1.1 mrg error = EBUSY; 697 1.26 chs simple_unlock(&uvm.swap_data_lock); 698 1.16 mrg break; 699 1.1 mrg } 700 1.1 mrg sdp = (struct swapdev *) 701 1.1 mrg malloc(sizeof *sdp, M_VMSWAP, M_WAITOK); 702 1.1 mrg spp = (struct swappri *) 703 1.1 mrg malloc(sizeof *spp, M_VMSWAP, M_WAITOK); 704 1.14 perry memset(sdp, 0, sizeof(*sdp)); 705 1.1 mrg sdp->swd_flags = SWF_FAKE; /* placeholder only */ 706 1.1 mrg sdp->swd_vp = vp; 707 1.1 mrg sdp->swd_dev = (vp->v_type == VBLK) ? vp->v_rdev : NODEV; 708 1.1 mrg #ifdef SWAP_TO_FILES 709 1.1 mrg /* 710 1.1 mrg * XXX Is NFS elaboration necessary? 711 1.1 mrg */ 712 1.1 mrg if (vp->v_type == VREG) 713 1.1 mrg sdp->swd_cred = crdup(p->p_ucred); 714 1.1 mrg #endif 715 1.1 mrg swaplist_insert(sdp, spp, priority); 716 1.26 chs simple_unlock(&uvm.swap_data_lock); 717 1.1 mrg 718 1.16 mrg sdp->swd_pathlen = len; 719 1.16 mrg sdp->swd_path = malloc(sdp->swd_pathlen, M_VMSWAP, M_WAITOK); 720 1.19 pk if (copystr(userpath, sdp->swd_path, sdp->swd_pathlen, 0) != 0) 721 1.19 pk panic("swapctl: copystr"); 722 1.1 mrg /* 723 1.1 mrg * we've now got a FAKE placeholder in the swap list. 724 1.1 mrg * now attempt to enable swap on it. if we fail, undo 725 1.1 mrg * what we've done and kill the fake entry we just inserted. 726 1.1 mrg * if swap_on is a success, it will clear the SWF_FAKE flag 727 1.1 mrg */ 728 1.1 mrg if ((error = swap_on(p, sdp)) != 0) { 729 1.26 chs simple_lock(&uvm.swap_data_lock); 730 1.8 mrg (void) swaplist_find(vp, 1); /* kill fake entry */ 731 1.1 mrg swaplist_trim(); 732 1.26 chs simple_unlock(&uvm.swap_data_lock); 733 1.1 mrg #ifdef SWAP_TO_FILES 734 1.1 mrg if (vp->v_type == VREG) 735 1.1 mrg crfree(sdp->swd_cred); 736 1.1 mrg #endif 737 1.19 pk free(sdp->swd_path, M_VMSWAP); 738 1.1 mrg free((caddr_t)sdp, M_VMSWAP); 739 1.1 mrg break; 740 1.1 mrg } 741 1.1 mrg 742 1.1 mrg /* 743 1.1 mrg * got it! now add a second reference to vp so that 744 1.1 mrg * we keep a reference to the vnode after we return. 745 1.1 mrg */ 746 1.1 mrg vref(vp); 747 1.1 mrg break; 748 1.1 mrg 749 1.1 mrg case SWAP_OFF: 750 1.27.4.1 chs #if 1 751 1.1 mrg /* 752 1.1 mrg * find the entry of interest and ensure it is enabled. 753 1.1 mrg */ 754 1.26 chs simple_lock(&uvm.swap_data_lock); 755 1.1 mrg if ((sdp = swaplist_find(vp, 0)) == NULL) { 756 1.26 chs simple_unlock(&uvm.swap_data_lock); 757 1.1 mrg error = ENXIO; 758 1.1 mrg break; 759 1.1 mrg } 760 1.1 mrg /* 761 1.1 mrg * If a device isn't in use or enabled, we 762 1.1 mrg * can't stop swapping from it (again). 763 1.1 mrg */ 764 1.1 mrg if ((sdp->swd_flags & (SWF_INUSE|SWF_ENABLE)) == 0) { 765 1.26 chs simple_unlock(&uvm.swap_data_lock); 766 1.1 mrg error = EBUSY; 767 1.16 mrg break; 768 1.1 mrg } 769 1.27.4.1 chs 770 1.27.4.1 chs /* 771 1.27.4.1 chs * do the real work. 772 1.27.4.1 chs */ 773 1.1 mrg /* XXXCDC: should we call with list locked or unlocked? */ 774 1.1 mrg if ((error = swap_off(p, sdp)) != 0) 775 1.1 mrg /* XXXCDC: might need relock here */ 776 1.27.4.1 chs goto out; 777 1.1 mrg 778 1.1 mrg /* 779 1.1 mrg * now we can kill the entry. 780 1.1 mrg */ 781 1.1 mrg if ((sdp = swaplist_find(vp, 1)) == NULL) { 782 1.1 mrg error = ENXIO; 783 1.1 mrg break; 784 1.1 mrg } 785 1.26 chs simple_unlock(&uvm.swap_data_lock); 786 1.1 mrg free((caddr_t)sdp, M_VMSWAP); 787 1.1 mrg #else 788 1.1 mrg error = EINVAL; 789 1.1 mrg #endif 790 1.1 mrg break; 791 1.1 mrg 792 1.1 mrg default: 793 1.1 mrg error = EINVAL; 794 1.1 mrg } 795 1.1 mrg 796 1.1 mrg /* 797 1.1 mrg * done! use vput to drop our reference and unlock 798 1.1 mrg */ 799 1.1 mrg vput(vp); 800 1.16 mrg out: 801 1.7 fvdl lockmgr(&swap_syscall_lock, LK_RELEASE, (void *)0); 802 1.1 mrg 803 1.1 mrg UVMHIST_LOG(pdhist, "<- done! error=%d", error, 0, 0, 0); 804 1.1 mrg return (error); 805 1.1 mrg } 806 1.1 mrg 807 1.1 mrg /* 808 1.1 mrg * swap_on: attempt to enable a swapdev for swapping. note that the 809 1.1 mrg * swapdev is already on the global list, but disabled (marked 810 1.1 mrg * SWF_FAKE). 811 1.1 mrg * 812 1.1 mrg * => we avoid the start of the disk (to protect disk labels) 813 1.1 mrg * => we also avoid the miniroot, if we are swapping to root. 814 1.26 chs * => caller should leave uvm.swap_data_lock unlocked, we may lock it 815 1.1 mrg * if needed. 816 1.1 mrg */ 817 1.1 mrg static int 818 1.1 mrg swap_on(p, sdp) 819 1.1 mrg struct proc *p; 820 1.1 mrg struct swapdev *sdp; 821 1.1 mrg { 822 1.1 mrg static int count = 0; /* static */ 823 1.1 mrg struct vnode *vp; 824 1.1 mrg int error, npages, nblocks, size; 825 1.1 mrg long addr; 826 1.1 mrg #ifdef SWAP_TO_FILES 827 1.1 mrg struct vattr va; 828 1.1 mrg #endif 829 1.1 mrg #ifdef NFS 830 1.1 mrg extern int (**nfsv2_vnodeop_p) __P((void *)); 831 1.1 mrg #endif /* NFS */ 832 1.1 mrg dev_t dev; 833 1.1 mrg char *name; 834 1.1 mrg UVMHIST_FUNC("swap_on"); UVMHIST_CALLED(pdhist); 835 1.1 mrg 836 1.1 mrg /* 837 1.1 mrg * we want to enable swapping on sdp. the swd_vp contains 838 1.1 mrg * the vnode we want (locked and ref'd), and the swd_dev 839 1.1 mrg * contains the dev_t of the file, if it a block device. 840 1.1 mrg */ 841 1.1 mrg 842 1.1 mrg vp = sdp->swd_vp; 843 1.1 mrg dev = sdp->swd_dev; 844 1.1 mrg 845 1.1 mrg /* 846 1.1 mrg * open the swap file (mostly useful for block device files to 847 1.1 mrg * let device driver know what is up). 848 1.1 mrg * 849 1.1 mrg * we skip the open/close for root on swap because the root 850 1.1 mrg * has already been opened when root was mounted (mountroot). 851 1.1 mrg */ 852 1.1 mrg if (vp != rootvp) { 853 1.1 mrg if ((error = VOP_OPEN(vp, FREAD|FWRITE, p->p_ucred, p))) 854 1.1 mrg return (error); 855 1.1 mrg } 856 1.1 mrg 857 1.1 mrg /* XXX this only works for block devices */ 858 1.1 mrg UVMHIST_LOG(pdhist, " dev=%d, major(dev)=%d", dev, major(dev), 0,0); 859 1.1 mrg 860 1.1 mrg /* 861 1.1 mrg * we now need to determine the size of the swap area. for 862 1.1 mrg * block specials we can call the d_psize function. 863 1.1 mrg * for normal files, we must stat [get attrs]. 864 1.1 mrg * 865 1.1 mrg * we put the result in nblks. 866 1.1 mrg * for normal files, we also want the filesystem block size 867 1.1 mrg * (which we get with statfs). 868 1.1 mrg */ 869 1.1 mrg switch (vp->v_type) { 870 1.1 mrg case VBLK: 871 1.1 mrg if (bdevsw[major(dev)].d_psize == 0 || 872 1.1 mrg (nblocks = (*bdevsw[major(dev)].d_psize)(dev)) == -1) { 873 1.1 mrg error = ENXIO; 874 1.1 mrg goto bad; 875 1.1 mrg } 876 1.1 mrg break; 877 1.1 mrg 878 1.1 mrg #ifdef SWAP_TO_FILES 879 1.1 mrg case VREG: 880 1.1 mrg if ((error = VOP_GETATTR(vp, &va, p->p_ucred, p))) 881 1.1 mrg goto bad; 882 1.1 mrg nblocks = (int)btodb(va.va_size); 883 1.1 mrg if ((error = 884 1.1 mrg VFS_STATFS(vp->v_mount, &vp->v_mount->mnt_stat, p)) != 0) 885 1.1 mrg goto bad; 886 1.1 mrg 887 1.1 mrg sdp->swd_bsize = vp->v_mount->mnt_stat.f_iosize; 888 1.1 mrg /* 889 1.1 mrg * limit the max # of outstanding I/O requests we issue 890 1.1 mrg * at any one time. take it easy on NFS servers. 891 1.1 mrg */ 892 1.1 mrg #ifdef NFS 893 1.1 mrg if (vp->v_op == nfsv2_vnodeop_p) 894 1.1 mrg sdp->swd_maxactive = 2; /* XXX */ 895 1.1 mrg else 896 1.1 mrg #endif /* NFS */ 897 1.1 mrg sdp->swd_maxactive = 8; /* XXX */ 898 1.1 mrg break; 899 1.1 mrg #endif 900 1.1 mrg 901 1.1 mrg default: 902 1.1 mrg error = ENXIO; 903 1.1 mrg goto bad; 904 1.1 mrg } 905 1.1 mrg 906 1.1 mrg /* 907 1.1 mrg * save nblocks in a safe place and convert to pages. 908 1.1 mrg */ 909 1.1 mrg 910 1.16 mrg sdp->swd_ose.ose_nblks = nblocks; 911 1.20 chs npages = dbtob((u_int64_t)nblocks) >> PAGE_SHIFT; 912 1.1 mrg 913 1.1 mrg /* 914 1.1 mrg * for block special files, we want to make sure that leave 915 1.1 mrg * the disklabel and bootblocks alone, so we arrange to skip 916 1.1 mrg * over them (randomly choosing to skip PAGE_SIZE bytes). 917 1.1 mrg * note that because of this the "size" can be less than the 918 1.1 mrg * actual number of blocks on the device. 919 1.1 mrg */ 920 1.1 mrg if (vp->v_type == VBLK) { 921 1.1 mrg /* we use pages 1 to (size - 1) [inclusive] */ 922 1.1 mrg size = npages - 1; 923 1.1 mrg addr = 1; 924 1.1 mrg } else { 925 1.1 mrg /* we use pages 0 to (size - 1) [inclusive] */ 926 1.1 mrg size = npages; 927 1.1 mrg addr = 0; 928 1.1 mrg } 929 1.1 mrg 930 1.1 mrg /* 931 1.1 mrg * make sure we have enough blocks for a reasonable sized swap 932 1.1 mrg * area. we want at least one page. 933 1.1 mrg */ 934 1.1 mrg 935 1.1 mrg if (size < 1) { 936 1.1 mrg UVMHIST_LOG(pdhist, " size <= 1!!", 0, 0, 0, 0); 937 1.1 mrg error = EINVAL; 938 1.1 mrg goto bad; 939 1.1 mrg } 940 1.1 mrg 941 1.1 mrg UVMHIST_LOG(pdhist, " dev=%x: size=%d addr=%ld\n", dev, size, addr, 0); 942 1.1 mrg 943 1.1 mrg /* 944 1.1 mrg * now we need to allocate an extent to manage this swap device 945 1.1 mrg */ 946 1.1 mrg name = malloc(12, M_VMSWAP, M_WAITOK); 947 1.1 mrg sprintf(name, "swap0x%04x", count++); 948 1.1 mrg 949 1.1 mrg /* note that extent_create's 3rd arg is inclusive, thus "- 1" */ 950 1.1 mrg sdp->swd_ex = extent_create(name, 0, npages - 1, M_VMSWAP, 951 1.12 pk 0, 0, EX_WAITOK); 952 1.1 mrg /* allocate the `saved' region from the extent so it won't be used */ 953 1.1 mrg if (addr) { 954 1.1 mrg if (extent_alloc_region(sdp->swd_ex, 0, addr, EX_WAITOK)) 955 1.1 mrg panic("disklabel region"); 956 1.1 mrg sdp->swd_npginuse += addr; 957 1.26 chs simple_lock(&uvm.swap_data_lock); 958 1.1 mrg uvmexp.swpginuse += addr; 959 1.26 chs uvmexp.swpgonly += addr; 960 1.26 chs simple_unlock(&uvm.swap_data_lock); 961 1.1 mrg } 962 1.1 mrg 963 1.1 mrg /* 964 1.1 mrg * if the vnode we are swapping to is the root vnode 965 1.1 mrg * (i.e. we are swapping to the miniroot) then we want 966 1.1 mrg * to make sure we don't overwrite it. do a statfs to 967 1.1 mrg * find its size and skip over it. 968 1.1 mrg */ 969 1.1 mrg if (vp == rootvp) { 970 1.1 mrg struct mount *mp; 971 1.1 mrg struct statfs *sp; 972 1.1 mrg int rootblocks, rootpages; 973 1.1 mrg 974 1.1 mrg mp = rootvnode->v_mount; 975 1.1 mrg sp = &mp->mnt_stat; 976 1.1 mrg rootblocks = sp->f_blocks * btodb(sp->f_bsize); 977 1.20 chs rootpages = round_page(dbtob(rootblocks)) >> PAGE_SHIFT; 978 1.1 mrg if (rootpages > npages) 979 1.1 mrg panic("swap_on: miniroot larger than swap?"); 980 1.1 mrg 981 1.1 mrg if (extent_alloc_region(sdp->swd_ex, addr, 982 1.1 mrg rootpages, EX_WAITOK)) 983 1.1 mrg panic("swap_on: unable to preserve miniroot"); 984 1.1 mrg 985 1.26 chs simple_lock(&uvm.swap_data_lock); 986 1.1 mrg sdp->swd_npginuse += (rootpages - addr); 987 1.1 mrg uvmexp.swpginuse += (rootpages - addr); 988 1.26 chs uvmexp.swpgonly += (rootpages - addr); 989 1.26 chs simple_unlock(&uvm.swap_data_lock); 990 1.1 mrg 991 1.27.4.1 chs size -= rootpages; 992 1.1 mrg printf("Preserved %d pages of miniroot ", rootpages); 993 1.27.4.1 chs printf("leaving %d pages of swap\n", size); 994 1.1 mrg } 995 1.1 mrg 996 1.27.4.1 chs /* 997 1.27.4.1 chs * add anons to reflect the new swap space 998 1.27.4.1 chs */ 999 1.27.4.1 chs uvm_anon_add(size); 1000 1.27.4.1 chs 1001 1.1 mrg /* 1002 1.1 mrg * now add the new swapdev to the drum and enable. 1003 1.1 mrg */ 1004 1.26 chs simple_lock(&uvm.swap_data_lock); 1005 1.1 mrg swapdrum_add(sdp, npages); 1006 1.27.4.1 chs sdp->swd_npages = size; 1007 1.1 mrg sdp->swd_flags &= ~SWF_FAKE; /* going live */ 1008 1.1 mrg sdp->swd_flags |= (SWF_INUSE|SWF_ENABLE); 1009 1.26 chs simple_unlock(&uvm.swap_data_lock); 1010 1.1 mrg uvmexp.swpages += npages; 1011 1.1 mrg 1012 1.12 pk #if 0 1013 1.12 pk /* 1014 1.12 pk * At this point we could arrange to reserve memory for the 1015 1.12 pk * swap buffer pools. 1016 1.12 pk * 1017 1.12 pk * I don't think this is necessary, since swapping starts well 1018 1.12 pk * ahead of serious memory deprivation and the memory resource 1019 1.12 pk * pools hold on to actively used memory. This should ensure 1020 1.12 pk * we always have some resources to continue operation. 1021 1.12 pk */ 1022 1.12 pk 1023 1.12 pk int s = splbio(); 1024 1.12 pk int n = 8 * sdp->swd_maxactive; 1025 1.12 pk 1026 1.12 pk (void)pool_prime(swapbuf_pool, n, 0); 1027 1.12 pk 1028 1.12 pk if (vp->v_type == VREG) { 1029 1.12 pk /* Allocate additional vnx and vnd buffers */ 1030 1.12 pk /* 1031 1.12 pk * Allocation Policy: 1032 1.12 pk * (8 * swd_maxactive) vnx headers per swap dev 1033 1.12 pk * (16 * swd_maxactive) vnd buffers per swap dev 1034 1.12 pk */ 1035 1.12 pk 1036 1.12 pk n = 8 * sdp->swd_maxactive; 1037 1.12 pk (void)pool_prime(vndxfer_pool, n, 0); 1038 1.12 pk 1039 1.12 pk n = 16 * sdp->swd_maxactive; 1040 1.12 pk (void)pool_prime(vndbuf_pool, n, 0); 1041 1.12 pk } 1042 1.12 pk splx(s); 1043 1.12 pk #endif 1044 1.12 pk 1045 1.1 mrg return (0); 1046 1.1 mrg 1047 1.1 mrg bad: 1048 1.1 mrg /* 1049 1.1 mrg * failure: close device if necessary and return error. 1050 1.1 mrg */ 1051 1.1 mrg if (vp != rootvp) 1052 1.1 mrg (void)VOP_CLOSE(vp, FREAD|FWRITE, p->p_ucred, p); 1053 1.1 mrg return (error); 1054 1.1 mrg } 1055 1.1 mrg 1056 1.1 mrg /* 1057 1.1 mrg * swap_off: stop swapping on swapdev 1058 1.1 mrg * 1059 1.27.4.1 chs * => swap data should be locked, we will unlock. 1060 1.1 mrg */ 1061 1.1 mrg static int 1062 1.1 mrg swap_off(p, sdp) 1063 1.1 mrg struct proc *p; 1064 1.1 mrg struct swapdev *sdp; 1065 1.1 mrg { 1066 1.27.4.1 chs return 0; 1067 1.1 mrg } 1068 1.1 mrg 1069 1.1 mrg /* 1070 1.1 mrg * /dev/drum interface and i/o functions 1071 1.1 mrg */ 1072 1.1 mrg 1073 1.1 mrg /* 1074 1.1 mrg * swread: the read function for the drum (just a call to physio) 1075 1.1 mrg */ 1076 1.1 mrg /*ARGSUSED*/ 1077 1.1 mrg int 1078 1.1 mrg swread(dev, uio, ioflag) 1079 1.1 mrg dev_t dev; 1080 1.1 mrg struct uio *uio; 1081 1.1 mrg int ioflag; 1082 1.1 mrg { 1083 1.1 mrg UVMHIST_FUNC("swread"); UVMHIST_CALLED(pdhist); 1084 1.1 mrg 1085 1.1 mrg UVMHIST_LOG(pdhist, " dev=%x offset=%qx", dev, uio->uio_offset, 0, 0); 1086 1.1 mrg return (physio(swstrategy, NULL, dev, B_READ, minphys, uio)); 1087 1.1 mrg } 1088 1.1 mrg 1089 1.1 mrg /* 1090 1.1 mrg * swwrite: the write function for the drum (just a call to physio) 1091 1.1 mrg */ 1092 1.1 mrg /*ARGSUSED*/ 1093 1.1 mrg int 1094 1.1 mrg swwrite(dev, uio, ioflag) 1095 1.1 mrg dev_t dev; 1096 1.1 mrg struct uio *uio; 1097 1.1 mrg int ioflag; 1098 1.1 mrg { 1099 1.1 mrg UVMHIST_FUNC("swwrite"); UVMHIST_CALLED(pdhist); 1100 1.1 mrg 1101 1.1 mrg UVMHIST_LOG(pdhist, " dev=%x offset=%qx", dev, uio->uio_offset, 0, 0); 1102 1.1 mrg return (physio(swstrategy, NULL, dev, B_WRITE, minphys, uio)); 1103 1.1 mrg } 1104 1.1 mrg 1105 1.1 mrg /* 1106 1.1 mrg * swstrategy: perform I/O on the drum 1107 1.1 mrg * 1108 1.1 mrg * => we must map the i/o request from the drum to the correct swapdev. 1109 1.1 mrg */ 1110 1.1 mrg void 1111 1.1 mrg swstrategy(bp) 1112 1.1 mrg struct buf *bp; 1113 1.1 mrg { 1114 1.1 mrg struct swapdev *sdp; 1115 1.1 mrg struct vnode *vp; 1116 1.25 chs int s, pageno, bn; 1117 1.1 mrg UVMHIST_FUNC("swstrategy"); UVMHIST_CALLED(pdhist); 1118 1.1 mrg 1119 1.1 mrg /* 1120 1.1 mrg * convert block number to swapdev. note that swapdev can't 1121 1.1 mrg * be yanked out from under us because we are holding resources 1122 1.1 mrg * in it (i.e. the blocks we are doing I/O on). 1123 1.1 mrg */ 1124 1.20 chs pageno = dbtob(bp->b_blkno) >> PAGE_SHIFT; 1125 1.26 chs simple_lock(&uvm.swap_data_lock); 1126 1.1 mrg sdp = swapdrum_getsdp(pageno); 1127 1.26 chs simple_unlock(&uvm.swap_data_lock); 1128 1.1 mrg if (sdp == NULL) { 1129 1.1 mrg bp->b_error = EINVAL; 1130 1.1 mrg bp->b_flags |= B_ERROR; 1131 1.1 mrg biodone(bp); 1132 1.1 mrg UVMHIST_LOG(pdhist, " failed to get swap device", 0, 0, 0, 0); 1133 1.1 mrg return; 1134 1.1 mrg } 1135 1.1 mrg 1136 1.1 mrg /* 1137 1.1 mrg * convert drum page number to block number on this swapdev. 1138 1.1 mrg */ 1139 1.1 mrg 1140 1.27.4.1 chs pageno -= sdp->swd_drumoffset; /* page # on swapdev */ 1141 1.20 chs bn = btodb(pageno << PAGE_SHIFT); /* convert to diskblock */ 1142 1.1 mrg 1143 1.1 mrg UVMHIST_LOG(pdhist, " %s: mapoff=%x bn=%x bcount=%ld\n", 1144 1.1 mrg ((bp->b_flags & B_READ) == 0) ? "write" : "read", 1145 1.1 mrg sdp->swd_drumoffset, bn, bp->b_bcount); 1146 1.1 mrg 1147 1.1 mrg /* 1148 1.1 mrg * for block devices we finish up here. 1149 1.27.4.1 chs * for regular files we have to do more work which we delegate 1150 1.1 mrg * to sw_reg_strategy(). 1151 1.1 mrg */ 1152 1.1 mrg 1153 1.1 mrg switch (sdp->swd_vp->v_type) { 1154 1.1 mrg default: 1155 1.1 mrg panic("swstrategy: vnode type 0x%x", sdp->swd_vp->v_type); 1156 1.1 mrg case VBLK: 1157 1.1 mrg 1158 1.1 mrg /* 1159 1.1 mrg * must convert "bp" from an I/O on /dev/drum to an I/O 1160 1.1 mrg * on the swapdev (sdp). 1161 1.1 mrg */ 1162 1.25 chs s = splbio(); 1163 1.1 mrg bp->b_blkno = bn; /* swapdev block number */ 1164 1.1 mrg vp = sdp->swd_vp; /* swapdev vnode pointer */ 1165 1.1 mrg bp->b_dev = sdp->swd_dev; /* swapdev dev_t */ 1166 1.1 mrg VHOLD(vp); /* "hold" swapdev vp for i/o */ 1167 1.1 mrg 1168 1.1 mrg /* 1169 1.1 mrg * if we are doing a write, we have to redirect the i/o on 1170 1.1 mrg * drum's v_numoutput counter to the swapdevs. 1171 1.1 mrg */ 1172 1.1 mrg if ((bp->b_flags & B_READ) == 0) { 1173 1.1 mrg vwakeup(bp); /* kills one 'v_numoutput' on drum */ 1174 1.1 mrg vp->v_numoutput++; /* put it on swapdev */ 1175 1.1 mrg } 1176 1.1 mrg 1177 1.1 mrg /* 1178 1.1 mrg * dissassocate buffer with /dev/drum vnode 1179 1.1 mrg * [could be null if buf was from physio] 1180 1.1 mrg */ 1181 1.1 mrg if (bp->b_vp != NULLVP) 1182 1.1 mrg brelvp(bp); 1183 1.1 mrg 1184 1.1 mrg /* 1185 1.1 mrg * finally plug in swapdev vnode and start I/O 1186 1.1 mrg */ 1187 1.1 mrg bp->b_vp = vp; 1188 1.25 chs splx(s); 1189 1.1 mrg VOP_STRATEGY(bp); 1190 1.1 mrg return; 1191 1.1 mrg #ifdef SWAP_TO_FILES 1192 1.1 mrg case VREG: 1193 1.1 mrg /* 1194 1.1 mrg * deligate to sw_reg_strategy function. 1195 1.1 mrg */ 1196 1.1 mrg sw_reg_strategy(sdp, bp, bn); 1197 1.1 mrg return; 1198 1.1 mrg #endif 1199 1.1 mrg } 1200 1.1 mrg /* NOTREACHED */ 1201 1.1 mrg } 1202 1.1 mrg 1203 1.1 mrg #ifdef SWAP_TO_FILES 1204 1.1 mrg /* 1205 1.1 mrg * sw_reg_strategy: handle swap i/o to regular files 1206 1.1 mrg */ 1207 1.1 mrg static void 1208 1.1 mrg sw_reg_strategy(sdp, bp, bn) 1209 1.1 mrg struct swapdev *sdp; 1210 1.1 mrg struct buf *bp; 1211 1.1 mrg int bn; 1212 1.1 mrg { 1213 1.1 mrg struct vnode *vp; 1214 1.1 mrg struct vndxfer *vnx; 1215 1.9 mrg daddr_t nbn, byteoff; 1216 1.1 mrg caddr_t addr; 1217 1.9 mrg int s, off, nra, error, sz, resid; 1218 1.1 mrg UVMHIST_FUNC("sw_reg_strategy"); UVMHIST_CALLED(pdhist); 1219 1.1 mrg 1220 1.1 mrg /* 1221 1.1 mrg * allocate a vndxfer head for this transfer and point it to 1222 1.1 mrg * our buffer. 1223 1.1 mrg */ 1224 1.12 pk getvndxfer(vnx); 1225 1.1 mrg vnx->vx_flags = VX_BUSY; 1226 1.1 mrg vnx->vx_error = 0; 1227 1.1 mrg vnx->vx_pending = 0; 1228 1.1 mrg vnx->vx_bp = bp; 1229 1.1 mrg vnx->vx_sdp = sdp; 1230 1.1 mrg 1231 1.1 mrg /* 1232 1.1 mrg * setup for main loop where we read filesystem blocks into 1233 1.1 mrg * our buffer. 1234 1.1 mrg */ 1235 1.1 mrg error = 0; 1236 1.1 mrg bp->b_resid = bp->b_bcount; /* nothing transfered yet! */ 1237 1.1 mrg addr = bp->b_data; /* current position in buffer */ 1238 1.9 mrg byteoff = dbtob(bn); 1239 1.1 mrg 1240 1.1 mrg for (resid = bp->b_resid; resid; resid -= sz) { 1241 1.1 mrg struct vndbuf *nbp; 1242 1.1 mrg 1243 1.1 mrg /* 1244 1.1 mrg * translate byteoffset into block number. return values: 1245 1.1 mrg * vp = vnode of underlying device 1246 1.1 mrg * nbn = new block number (on underlying vnode dev) 1247 1.1 mrg * nra = num blocks we can read-ahead (excludes requested 1248 1.1 mrg * block) 1249 1.1 mrg */ 1250 1.1 mrg nra = 0; 1251 1.1 mrg error = VOP_BMAP(sdp->swd_vp, byteoff / sdp->swd_bsize, 1252 1.1 mrg &vp, &nbn, &nra); 1253 1.1 mrg 1254 1.23 marc if (error == 0 && (long)nbn == -1) { 1255 1.23 marc /* 1256 1.23 marc * this used to just set error, but that doesn't 1257 1.23 marc * do the right thing. Instead, it causes random 1258 1.23 marc * memory errors. The panic() should remain until 1259 1.23 marc * this condition doesn't destabilize the system. 1260 1.23 marc */ 1261 1.23 marc #if 1 1262 1.23 marc panic("sw_reg_strategy: swap to sparse file"); 1263 1.23 marc #else 1264 1.1 mrg error = EIO; /* failure */ 1265 1.23 marc #endif 1266 1.23 marc } 1267 1.1 mrg 1268 1.1 mrg /* 1269 1.1 mrg * punt if there was an error or a hole in the file. 1270 1.1 mrg * we must wait for any i/o ops we have already started 1271 1.1 mrg * to finish before returning. 1272 1.1 mrg * 1273 1.1 mrg * XXX we could deal with holes here but it would be 1274 1.1 mrg * a hassle (in the write case). 1275 1.1 mrg */ 1276 1.1 mrg if (error) { 1277 1.1 mrg s = splbio(); 1278 1.1 mrg vnx->vx_error = error; /* pass error up */ 1279 1.1 mrg goto out; 1280 1.1 mrg } 1281 1.1 mrg 1282 1.1 mrg /* 1283 1.1 mrg * compute the size ("sz") of this transfer (in bytes). 1284 1.1 mrg * XXXCDC: ignores read-ahead for non-zero offset 1285 1.1 mrg */ 1286 1.1 mrg if ((off = (byteoff % sdp->swd_bsize)) != 0) 1287 1.1 mrg sz = sdp->swd_bsize - off; 1288 1.1 mrg else 1289 1.1 mrg sz = (1 + nra) * sdp->swd_bsize; 1290 1.1 mrg 1291 1.1 mrg if (resid < sz) 1292 1.1 mrg sz = resid; 1293 1.1 mrg 1294 1.9 mrg UVMHIST_LOG(pdhist, "sw_reg_strategy: vp %p/%p offset 0x%x/0x%x", 1295 1.9 mrg sdp->swd_vp, vp, byteoff, nbn); 1296 1.1 mrg 1297 1.1 mrg /* 1298 1.1 mrg * now get a buf structure. note that the vb_buf is 1299 1.1 mrg * at the front of the nbp structure so that you can 1300 1.1 mrg * cast pointers between the two structure easily. 1301 1.1 mrg */ 1302 1.12 pk getvndbuf(nbp); 1303 1.1 mrg nbp->vb_buf.b_flags = bp->b_flags | B_CALL; 1304 1.1 mrg nbp->vb_buf.b_bcount = sz; 1305 1.12 pk #if 0 1306 1.1 mrg nbp->vb_buf.b_bufsize = bp->b_bufsize; /* XXXCDC: really? */ 1307 1.12 pk #endif 1308 1.12 pk nbp->vb_buf.b_bufsize = sz; 1309 1.1 mrg nbp->vb_buf.b_error = 0; 1310 1.1 mrg nbp->vb_buf.b_data = addr; 1311 1.1 mrg nbp->vb_buf.b_blkno = nbn + btodb(off); 1312 1.1 mrg nbp->vb_buf.b_proc = bp->b_proc; 1313 1.1 mrg nbp->vb_buf.b_iodone = sw_reg_iodone; 1314 1.1 mrg nbp->vb_buf.b_vp = NULLVP; 1315 1.12 pk nbp->vb_buf.b_vnbufs.le_next = NOLIST; 1316 1.1 mrg nbp->vb_buf.b_rcred = sdp->swd_cred; 1317 1.1 mrg nbp->vb_buf.b_wcred = sdp->swd_cred; 1318 1.1 mrg 1319 1.1 mrg /* 1320 1.12 pk * set b_dirtyoff/end and b_validoff/end. this is 1321 1.1 mrg * required by the NFS client code (otherwise it will 1322 1.1 mrg * just discard our I/O request). 1323 1.1 mrg */ 1324 1.1 mrg if (bp->b_dirtyend == 0) { 1325 1.1 mrg nbp->vb_buf.b_dirtyoff = 0; 1326 1.1 mrg nbp->vb_buf.b_dirtyend = sz; 1327 1.1 mrg } else { 1328 1.1 mrg nbp->vb_buf.b_dirtyoff = 1329 1.1 mrg max(0, bp->b_dirtyoff - (bp->b_bcount-resid)); 1330 1.1 mrg nbp->vb_buf.b_dirtyend = 1331 1.1 mrg min(sz, 1332 1.1 mrg max(0, bp->b_dirtyend - (bp->b_bcount-resid))); 1333 1.1 mrg } 1334 1.1 mrg if (bp->b_validend == 0) { 1335 1.1 mrg nbp->vb_buf.b_validoff = 0; 1336 1.1 mrg nbp->vb_buf.b_validend = sz; 1337 1.1 mrg } else { 1338 1.1 mrg nbp->vb_buf.b_validoff = 1339 1.1 mrg max(0, bp->b_validoff - (bp->b_bcount-resid)); 1340 1.1 mrg nbp->vb_buf.b_validend = 1341 1.1 mrg min(sz, 1342 1.1 mrg max(0, bp->b_validend - (bp->b_bcount-resid))); 1343 1.1 mrg } 1344 1.1 mrg 1345 1.1 mrg nbp->vb_xfer = vnx; /* patch it back in to vnx */ 1346 1.1 mrg 1347 1.1 mrg /* 1348 1.1 mrg * Just sort by block number 1349 1.1 mrg */ 1350 1.1 mrg nbp->vb_buf.b_cylinder = nbp->vb_buf.b_blkno; 1351 1.1 mrg s = splbio(); 1352 1.1 mrg if (vnx->vx_error != 0) { 1353 1.1 mrg putvndbuf(nbp); 1354 1.1 mrg goto out; 1355 1.1 mrg } 1356 1.1 mrg vnx->vx_pending++; 1357 1.1 mrg 1358 1.1 mrg /* assoc new buffer with underlying vnode */ 1359 1.1 mrg bgetvp(vp, &nbp->vb_buf); 1360 1.1 mrg 1361 1.1 mrg /* sort it in and start I/O if we are not over our limit */ 1362 1.1 mrg disksort(&sdp->swd_tab, &nbp->vb_buf); 1363 1.1 mrg sw_reg_start(sdp); 1364 1.1 mrg splx(s); 1365 1.1 mrg 1366 1.1 mrg /* 1367 1.1 mrg * advance to the next I/O 1368 1.1 mrg */ 1369 1.9 mrg byteoff += sz; 1370 1.1 mrg addr += sz; 1371 1.1 mrg } 1372 1.1 mrg 1373 1.1 mrg s = splbio(); 1374 1.1 mrg 1375 1.1 mrg out: /* Arrive here at splbio */ 1376 1.1 mrg vnx->vx_flags &= ~VX_BUSY; 1377 1.1 mrg if (vnx->vx_pending == 0) { 1378 1.1 mrg if (vnx->vx_error != 0) { 1379 1.1 mrg bp->b_error = vnx->vx_error; 1380 1.1 mrg bp->b_flags |= B_ERROR; 1381 1.1 mrg } 1382 1.1 mrg putvndxfer(vnx); 1383 1.1 mrg biodone(bp); 1384 1.1 mrg } 1385 1.1 mrg splx(s); 1386 1.1 mrg } 1387 1.1 mrg 1388 1.1 mrg /* 1389 1.1 mrg * sw_reg_start: start an I/O request on the requested swapdev 1390 1.1 mrg * 1391 1.1 mrg * => reqs are sorted by disksort (above) 1392 1.1 mrg */ 1393 1.1 mrg static void 1394 1.1 mrg sw_reg_start(sdp) 1395 1.1 mrg struct swapdev *sdp; 1396 1.1 mrg { 1397 1.1 mrg struct buf *bp; 1398 1.1 mrg UVMHIST_FUNC("sw_reg_start"); UVMHIST_CALLED(pdhist); 1399 1.1 mrg 1400 1.8 mrg /* recursion control */ 1401 1.1 mrg if ((sdp->swd_flags & SWF_BUSY) != 0) 1402 1.1 mrg return; 1403 1.1 mrg 1404 1.1 mrg sdp->swd_flags |= SWF_BUSY; 1405 1.1 mrg 1406 1.1 mrg while (sdp->swd_tab.b_active < sdp->swd_maxactive) { 1407 1.1 mrg bp = sdp->swd_tab.b_actf; 1408 1.1 mrg if (bp == NULL) 1409 1.1 mrg break; 1410 1.1 mrg sdp->swd_tab.b_actf = bp->b_actf; 1411 1.1 mrg sdp->swd_tab.b_active++; 1412 1.1 mrg 1413 1.1 mrg UVMHIST_LOG(pdhist, 1414 1.1 mrg "sw_reg_start: bp %p vp %p blkno %p cnt %lx", 1415 1.1 mrg bp, bp->b_vp, bp->b_blkno, bp->b_bcount); 1416 1.1 mrg if ((bp->b_flags & B_READ) == 0) 1417 1.1 mrg bp->b_vp->v_numoutput++; 1418 1.1 mrg VOP_STRATEGY(bp); 1419 1.1 mrg } 1420 1.1 mrg sdp->swd_flags &= ~SWF_BUSY; 1421 1.1 mrg } 1422 1.1 mrg 1423 1.1 mrg /* 1424 1.1 mrg * sw_reg_iodone: one of our i/o's has completed and needs post-i/o cleanup 1425 1.1 mrg * 1426 1.1 mrg * => note that we can recover the vndbuf struct by casting the buf ptr 1427 1.1 mrg */ 1428 1.1 mrg static void 1429 1.1 mrg sw_reg_iodone(bp) 1430 1.1 mrg struct buf *bp; 1431 1.1 mrg { 1432 1.1 mrg struct vndbuf *vbp = (struct vndbuf *) bp; 1433 1.1 mrg struct vndxfer *vnx = vbp->vb_xfer; 1434 1.1 mrg struct buf *pbp = vnx->vx_bp; /* parent buffer */ 1435 1.1 mrg struct swapdev *sdp = vnx->vx_sdp; 1436 1.1 mrg int s, resid; 1437 1.1 mrg UVMHIST_FUNC("sw_reg_iodone"); UVMHIST_CALLED(pdhist); 1438 1.1 mrg 1439 1.1 mrg UVMHIST_LOG(pdhist, " vbp=%p vp=%p blkno=%x addr=%p", 1440 1.1 mrg vbp, vbp->vb_buf.b_vp, vbp->vb_buf.b_blkno, vbp->vb_buf.b_data); 1441 1.1 mrg UVMHIST_LOG(pdhist, " cnt=%lx resid=%lx", 1442 1.1 mrg vbp->vb_buf.b_bcount, vbp->vb_buf.b_resid, 0, 0); 1443 1.1 mrg 1444 1.1 mrg /* 1445 1.1 mrg * protect vbp at splbio and update. 1446 1.1 mrg */ 1447 1.1 mrg 1448 1.1 mrg s = splbio(); 1449 1.1 mrg resid = vbp->vb_buf.b_bcount - vbp->vb_buf.b_resid; 1450 1.1 mrg pbp->b_resid -= resid; 1451 1.1 mrg vnx->vx_pending--; 1452 1.1 mrg 1453 1.1 mrg if (vbp->vb_buf.b_error) { 1454 1.1 mrg UVMHIST_LOG(pdhist, " got error=%d !", 1455 1.1 mrg vbp->vb_buf.b_error, 0, 0, 0); 1456 1.1 mrg 1457 1.1 mrg /* pass error upward */ 1458 1.1 mrg vnx->vx_error = vbp->vb_buf.b_error; 1459 1.1 mrg } 1460 1.1 mrg 1461 1.1 mrg /* 1462 1.1 mrg * drop "hold" reference to vnode (if one) 1463 1.1 mrg * XXXCDC: always set to NULLVP, this is useless, right? 1464 1.1 mrg */ 1465 1.1 mrg if (vbp->vb_buf.b_vp != NULLVP) 1466 1.1 mrg brelvp(&vbp->vb_buf); 1467 1.1 mrg 1468 1.1 mrg /* 1469 1.1 mrg * kill vbp structure 1470 1.1 mrg */ 1471 1.1 mrg putvndbuf(vbp); 1472 1.1 mrg 1473 1.1 mrg /* 1474 1.1 mrg * wrap up this transaction if it has run to completion or, in 1475 1.1 mrg * case of an error, when all auxiliary buffers have returned. 1476 1.1 mrg */ 1477 1.1 mrg if (vnx->vx_error != 0) { 1478 1.1 mrg /* pass error upward */ 1479 1.1 mrg pbp->b_flags |= B_ERROR; 1480 1.1 mrg pbp->b_error = vnx->vx_error; 1481 1.1 mrg if ((vnx->vx_flags & VX_BUSY) == 0 && vnx->vx_pending == 0) { 1482 1.1 mrg putvndxfer(vnx); 1483 1.1 mrg biodone(pbp); 1484 1.1 mrg } 1485 1.11 pk } else if (pbp->b_resid == 0) { 1486 1.1 mrg #ifdef DIAGNOSTIC 1487 1.1 mrg if (vnx->vx_pending != 0) 1488 1.8 mrg panic("sw_reg_iodone: vnx pending: %d",vnx->vx_pending); 1489 1.1 mrg #endif 1490 1.1 mrg 1491 1.1 mrg if ((vnx->vx_flags & VX_BUSY) == 0) { 1492 1.8 mrg UVMHIST_LOG(pdhist, " iodone error=%d !", 1493 1.8 mrg pbp, vnx->vx_error, 0, 0); 1494 1.8 mrg putvndxfer(vnx); 1495 1.1 mrg biodone(pbp); 1496 1.1 mrg } 1497 1.1 mrg } 1498 1.1 mrg 1499 1.1 mrg /* 1500 1.1 mrg * done! start next swapdev I/O if one is pending 1501 1.1 mrg */ 1502 1.1 mrg sdp->swd_tab.b_active--; 1503 1.1 mrg sw_reg_start(sdp); 1504 1.1 mrg 1505 1.1 mrg splx(s); 1506 1.1 mrg } 1507 1.1 mrg #endif /* SWAP_TO_FILES */ 1508 1.1 mrg 1509 1.1 mrg 1510 1.1 mrg /* 1511 1.1 mrg * uvm_swap_alloc: allocate space on swap 1512 1.1 mrg * 1513 1.1 mrg * => allocation is done "round robin" down the priority list, as we 1514 1.1 mrg * allocate in a priority we "rotate" the circle queue. 1515 1.1 mrg * => space can be freed with uvm_swap_free 1516 1.1 mrg * => we return the page slot number in /dev/drum (0 == invalid slot) 1517 1.26 chs * => we lock uvm.swap_data_lock 1518 1.1 mrg * => XXXMRG: "LESSOK" INTERFACE NEEDED TO EXTENT SYSTEM 1519 1.1 mrg */ 1520 1.1 mrg int 1521 1.1 mrg uvm_swap_alloc(nslots, lessok) 1522 1.1 mrg int *nslots; /* IN/OUT */ 1523 1.1 mrg boolean_t lessok; 1524 1.1 mrg { 1525 1.1 mrg struct swapdev *sdp; 1526 1.1 mrg struct swappri *spp; 1527 1.1 mrg u_long result; 1528 1.1 mrg UVMHIST_FUNC("uvm_swap_alloc"); UVMHIST_CALLED(pdhist); 1529 1.1 mrg 1530 1.1 mrg /* 1531 1.1 mrg * no swap devices configured yet? definite failure. 1532 1.1 mrg */ 1533 1.1 mrg if (uvmexp.nswapdev < 1) 1534 1.1 mrg return 0; 1535 1.1 mrg 1536 1.1 mrg /* 1537 1.1 mrg * lock data lock, convert slots into blocks, and enter loop 1538 1.1 mrg */ 1539 1.26 chs simple_lock(&uvm.swap_data_lock); 1540 1.1 mrg 1541 1.1 mrg ReTry: /* XXXMRG */ 1542 1.1 mrg for (spp = swap_priority.lh_first; spp != NULL; 1543 1.1 mrg spp = spp->spi_swappri.le_next) { 1544 1.1 mrg for (sdp = spp->spi_swapdev.cqh_first; 1545 1.1 mrg sdp != (void *)&spp->spi_swapdev; 1546 1.1 mrg sdp = sdp->swd_next.cqe_next) { 1547 1.1 mrg /* if it's not enabled, then we can't swap from it */ 1548 1.1 mrg if ((sdp->swd_flags & SWF_ENABLE) == 0) 1549 1.1 mrg continue; 1550 1.1 mrg if (sdp->swd_npginuse + *nslots > sdp->swd_npages) 1551 1.1 mrg continue; 1552 1.1 mrg if (extent_alloc(sdp->swd_ex, *nslots, EX_NOALIGN, 1553 1.1 mrg EX_NOBOUNDARY, EX_MALLOCOK|EX_NOWAIT, 1554 1.1 mrg &result) != 0) { 1555 1.1 mrg continue; 1556 1.1 mrg } 1557 1.1 mrg 1558 1.1 mrg /* 1559 1.1 mrg * successful allocation! now rotate the circleq. 1560 1.1 mrg */ 1561 1.1 mrg CIRCLEQ_REMOVE(&spp->spi_swapdev, sdp, swd_next); 1562 1.1 mrg CIRCLEQ_INSERT_TAIL(&spp->spi_swapdev, sdp, swd_next); 1563 1.1 mrg sdp->swd_npginuse += *nslots; 1564 1.1 mrg uvmexp.swpginuse += *nslots; 1565 1.26 chs simple_unlock(&uvm.swap_data_lock); 1566 1.1 mrg /* done! return drum slot number */ 1567 1.1 mrg UVMHIST_LOG(pdhist, 1568 1.1 mrg "success! returning %d slots starting at %d", 1569 1.1 mrg *nslots, result + sdp->swd_drumoffset, 0, 0); 1570 1.1 mrg return(result + sdp->swd_drumoffset); 1571 1.1 mrg } 1572 1.1 mrg } 1573 1.1 mrg 1574 1.1 mrg /* XXXMRG: BEGIN HACK */ 1575 1.1 mrg if (*nslots > 1 && lessok) { 1576 1.1 mrg *nslots = 1; 1577 1.1 mrg goto ReTry; /* XXXMRG: ugh! extent should support this for us */ 1578 1.1 mrg } 1579 1.1 mrg /* XXXMRG: END HACK */ 1580 1.1 mrg 1581 1.26 chs simple_unlock(&uvm.swap_data_lock); 1582 1.1 mrg return 0; /* failed */ 1583 1.1 mrg } 1584 1.1 mrg 1585 1.1 mrg /* 1586 1.1 mrg * uvm_swap_free: free swap slots 1587 1.1 mrg * 1588 1.1 mrg * => this can be all or part of an allocation made by uvm_swap_alloc 1589 1.26 chs * => we lock uvm.swap_data_lock 1590 1.1 mrg */ 1591 1.1 mrg void 1592 1.1 mrg uvm_swap_free(startslot, nslots) 1593 1.1 mrg int startslot; 1594 1.1 mrg int nslots; 1595 1.1 mrg { 1596 1.1 mrg struct swapdev *sdp; 1597 1.1 mrg UVMHIST_FUNC("uvm_swap_free"); UVMHIST_CALLED(pdhist); 1598 1.1 mrg 1599 1.1 mrg UVMHIST_LOG(pdhist, "freeing %d slots starting at %d", nslots, 1600 1.1 mrg startslot, 0, 0); 1601 1.1 mrg /* 1602 1.1 mrg * convert drum slot offset back to sdp, free the blocks 1603 1.1 mrg * in the extent, and return. must hold pri lock to do 1604 1.1 mrg * lookup and access the extent. 1605 1.1 mrg */ 1606 1.26 chs simple_lock(&uvm.swap_data_lock); 1607 1.1 mrg sdp = swapdrum_getsdp(startslot); 1608 1.1 mrg 1609 1.1 mrg #ifdef DIAGNOSTIC 1610 1.1 mrg if (uvmexp.nswapdev < 1) 1611 1.1 mrg panic("uvm_swap_free: uvmexp.nswapdev < 1\n"); 1612 1.1 mrg if (sdp == NULL) { 1613 1.1 mrg printf("uvm_swap_free: startslot %d, nslots %d\n", startslot, 1614 1.1 mrg nslots); 1615 1.1 mrg panic("uvm_swap_free: unmapped address\n"); 1616 1.1 mrg } 1617 1.1 mrg #endif 1618 1.12 pk if (extent_free(sdp->swd_ex, startslot - sdp->swd_drumoffset, nslots, 1619 1.12 pk EX_MALLOCOK|EX_NOWAIT) != 0) 1620 1.12 pk printf("warning: resource shortage: %d slots of swap lost\n", 1621 1.12 pk nslots); 1622 1.12 pk 1623 1.1 mrg sdp->swd_npginuse -= nslots; 1624 1.1 mrg uvmexp.swpginuse -= nslots; 1625 1.1 mrg #ifdef DIAGNOSTIC 1626 1.1 mrg if (sdp->swd_npginuse < 0) 1627 1.1 mrg panic("uvm_swap_free: inuse < 0"); 1628 1.1 mrg #endif 1629 1.26 chs simple_unlock(&uvm.swap_data_lock); 1630 1.1 mrg } 1631 1.1 mrg 1632 1.1 mrg /* 1633 1.1 mrg * uvm_swap_put: put any number of pages into a contig place on swap 1634 1.1 mrg * 1635 1.1 mrg * => can be sync or async 1636 1.1 mrg * => XXXMRG: consider making it an inline or macro 1637 1.1 mrg */ 1638 1.1 mrg int 1639 1.1 mrg uvm_swap_put(swslot, ppsp, npages, flags) 1640 1.1 mrg int swslot; 1641 1.1 mrg struct vm_page **ppsp; 1642 1.1 mrg int npages; 1643 1.1 mrg int flags; 1644 1.1 mrg { 1645 1.1 mrg int result; 1646 1.1 mrg 1647 1.1 mrg #if 0 1648 1.1 mrg flags |= PGO_SYNCIO; /* XXXMRG: tmp, force sync */ 1649 1.1 mrg #endif 1650 1.1 mrg 1651 1.1 mrg result = uvm_swap_io(ppsp, swslot, npages, B_WRITE | 1652 1.1 mrg ((flags & PGO_SYNCIO) ? 0 : B_ASYNC)); 1653 1.1 mrg 1654 1.1 mrg return (result); 1655 1.1 mrg } 1656 1.1 mrg 1657 1.1 mrg /* 1658 1.1 mrg * uvm_swap_get: get a single page from swap 1659 1.1 mrg * 1660 1.1 mrg * => usually a sync op (from fault) 1661 1.1 mrg * => XXXMRG: consider making it an inline or macro 1662 1.1 mrg */ 1663 1.1 mrg int 1664 1.1 mrg uvm_swap_get(page, swslot, flags) 1665 1.1 mrg struct vm_page *page; 1666 1.1 mrg int swslot, flags; 1667 1.1 mrg { 1668 1.1 mrg int result; 1669 1.1 mrg 1670 1.1 mrg uvmexp.nswget++; 1671 1.1 mrg #ifdef DIAGNOSTIC 1672 1.1 mrg if ((flags & PGO_SYNCIO) == 0) 1673 1.1 mrg printf("uvm_swap_get: ASYNC get requested?\n"); 1674 1.1 mrg #endif 1675 1.1 mrg 1676 1.26 chs /* 1677 1.26 chs * this page is (about to be) no longer only in swap. 1678 1.26 chs */ 1679 1.26 chs simple_lock(&uvm.swap_data_lock); 1680 1.26 chs uvmexp.swpgonly--; 1681 1.26 chs simple_unlock(&uvm.swap_data_lock); 1682 1.26 chs 1683 1.1 mrg result = uvm_swap_io(&page, swslot, 1, B_READ | 1684 1.1 mrg ((flags & PGO_SYNCIO) ? 0 : B_ASYNC)); 1685 1.26 chs 1686 1.26 chs if (result != VM_PAGER_OK && result != VM_PAGER_PEND) { 1687 1.26 chs /* 1688 1.26 chs * oops, the read failed so it really is still only in swap. 1689 1.26 chs */ 1690 1.26 chs simple_lock(&uvm.swap_data_lock); 1691 1.26 chs uvmexp.swpgonly++; 1692 1.26 chs simple_unlock(&uvm.swap_data_lock); 1693 1.26 chs } 1694 1.1 mrg 1695 1.1 mrg return (result); 1696 1.1 mrg } 1697 1.1 mrg 1698 1.1 mrg /* 1699 1.1 mrg * uvm_swap_io: do an i/o operation to swap 1700 1.1 mrg */ 1701 1.1 mrg 1702 1.1 mrg static int 1703 1.1 mrg uvm_swap_io(pps, startslot, npages, flags) 1704 1.1 mrg struct vm_page **pps; 1705 1.1 mrg int startslot, npages, flags; 1706 1.1 mrg { 1707 1.1 mrg daddr_t startblk; 1708 1.1 mrg struct swapbuf *sbp; 1709 1.1 mrg struct buf *bp; 1710 1.15 eeh vaddr_t kva; 1711 1.12 pk int result, s, waitf, pflag; 1712 1.1 mrg UVMHIST_FUNC("uvm_swap_io"); UVMHIST_CALLED(pdhist); 1713 1.1 mrg 1714 1.1 mrg UVMHIST_LOG(pdhist, "<- called, startslot=%d, npages=%d, flags=%d", 1715 1.1 mrg startslot, npages, flags, 0); 1716 1.1 mrg /* 1717 1.1 mrg * convert starting drum slot to block number 1718 1.1 mrg */ 1719 1.20 chs startblk = btodb(startslot << PAGE_SHIFT); 1720 1.1 mrg 1721 1.1 mrg /* 1722 1.1 mrg * first, map the pages into the kernel (XXX: currently required 1723 1.1 mrg * by buffer system). note that we don't let pagermapin alloc 1724 1.1 mrg * an aiodesc structure because we don't want to chance a malloc. 1725 1.1 mrg * we've got our own pool of aiodesc structures (in swapbuf). 1726 1.1 mrg */ 1727 1.1 mrg waitf = (flags & B_ASYNC) ? M_NOWAIT : M_WAITOK; 1728 1.1 mrg kva = uvm_pagermapin(pps, npages, NULL, waitf); 1729 1.1 mrg if (kva == NULL) 1730 1.1 mrg return (VM_PAGER_AGAIN); 1731 1.1 mrg 1732 1.1 mrg /* 1733 1.1 mrg * now allocate a swap buffer off of freesbufs 1734 1.1 mrg * [make sure we don't put the pagedaemon to sleep...] 1735 1.1 mrg */ 1736 1.1 mrg s = splbio(); 1737 1.12 pk pflag = ((flags & B_ASYNC) != 0 || curproc == uvm.pagedaemon_proc) 1738 1.12 pk ? 0 1739 1.12 pk : PR_WAITOK; 1740 1.12 pk sbp = pool_get(swapbuf_pool, pflag); 1741 1.1 mrg splx(s); /* drop splbio */ 1742 1.1 mrg 1743 1.1 mrg /* 1744 1.1 mrg * if we failed to get a swapbuf, return "try again" 1745 1.1 mrg */ 1746 1.1 mrg if (sbp == NULL) 1747 1.1 mrg return (VM_PAGER_AGAIN); 1748 1.1 mrg 1749 1.1 mrg /* 1750 1.1 mrg * fill in the bp/sbp. we currently route our i/o through 1751 1.1 mrg * /dev/drum's vnode [swapdev_vp]. 1752 1.1 mrg */ 1753 1.1 mrg bp = &sbp->sw_buf; 1754 1.21 mycroft bp->b_flags = B_BUSY | B_NOCACHE | (flags & (B_READ|B_ASYNC)); 1755 1.1 mrg bp->b_proc = &proc0; /* XXX */ 1756 1.12 pk bp->b_rcred = bp->b_wcred = proc0.p_ucred; 1757 1.12 pk bp->b_vnbufs.le_next = NOLIST; 1758 1.1 mrg bp->b_data = (caddr_t)kva; 1759 1.1 mrg bp->b_blkno = startblk; 1760 1.25 chs s = splbio(); 1761 1.1 mrg VHOLD(swapdev_vp); 1762 1.1 mrg bp->b_vp = swapdev_vp; 1763 1.25 chs splx(s); 1764 1.1 mrg /* XXXCDC: isn't swapdev_vp always a VCHR? */ 1765 1.1 mrg /* XXXMRG: probably -- this is obviously something inherited... */ 1766 1.1 mrg if (swapdev_vp->v_type == VBLK) 1767 1.1 mrg bp->b_dev = swapdev_vp->v_rdev; 1768 1.20 chs bp->b_bcount = npages << PAGE_SHIFT; 1769 1.1 mrg 1770 1.1 mrg /* 1771 1.1 mrg * for pageouts we must set "dirtyoff" [NFS client code needs it]. 1772 1.1 mrg * and we bump v_numoutput (counter of number of active outputs). 1773 1.1 mrg */ 1774 1.1 mrg if ((bp->b_flags & B_READ) == 0) { 1775 1.1 mrg bp->b_dirtyoff = 0; 1776 1.20 chs bp->b_dirtyend = npages << PAGE_SHIFT; 1777 1.1 mrg s = splbio(); 1778 1.1 mrg swapdev_vp->v_numoutput++; 1779 1.1 mrg splx(s); 1780 1.1 mrg } 1781 1.1 mrg 1782 1.1 mrg /* 1783 1.1 mrg * for async ops we must set up the aiodesc and setup the callback 1784 1.1 mrg * XXX: we expect no async-reads, but we don't prevent it here. 1785 1.1 mrg */ 1786 1.1 mrg if (flags & B_ASYNC) { 1787 1.1 mrg sbp->sw_aio.aiodone = uvm_swap_aiodone; 1788 1.1 mrg sbp->sw_aio.kva = kva; 1789 1.1 mrg sbp->sw_aio.npages = npages; 1790 1.1 mrg sbp->sw_aio.pd_ptr = sbp; /* backpointer */ 1791 1.27.4.1 chs /* XXX pagedaemon */ 1792 1.27.4.1 chs sbp->sw_aio.flags = (curproc == uvm.pagedaemon_proc) ? 1793 1.27.4.1 chs UVM_AIO_PAGEDAEMON : 0; 1794 1.1 mrg bp->b_flags |= B_CALL; /* set callback */ 1795 1.1 mrg bp->b_iodone = uvm_swap_bufdone;/* "buf" iodone function */ 1796 1.1 mrg UVMHIST_LOG(pdhist, "doing async!", 0, 0, 0, 0); 1797 1.1 mrg } 1798 1.1 mrg UVMHIST_LOG(pdhist, 1799 1.1 mrg "about to start io: data = 0x%p blkno = 0x%x, bcount = %ld", 1800 1.1 mrg bp->b_data, bp->b_blkno, bp->b_bcount, 0); 1801 1.1 mrg 1802 1.1 mrg /* 1803 1.1 mrg * now we start the I/O, and if async, return. 1804 1.1 mrg */ 1805 1.1 mrg VOP_STRATEGY(bp); 1806 1.1 mrg if (flags & B_ASYNC) 1807 1.1 mrg return (VM_PAGER_PEND); 1808 1.1 mrg 1809 1.1 mrg /* 1810 1.1 mrg * must be sync i/o. wait for it to finish 1811 1.1 mrg */ 1812 1.1 mrg bp->b_error = biowait(bp); 1813 1.1 mrg result = (bp->b_flags & B_ERROR) ? VM_PAGER_ERROR : VM_PAGER_OK; 1814 1.1 mrg 1815 1.1 mrg /* 1816 1.1 mrg * kill the pager mapping 1817 1.1 mrg */ 1818 1.1 mrg uvm_pagermapout(kva, npages); 1819 1.1 mrg 1820 1.1 mrg /* 1821 1.1 mrg * now dispose of the swap buffer 1822 1.1 mrg */ 1823 1.1 mrg s = splbio(); 1824 1.1 mrg if (bp->b_vp) 1825 1.1 mrg brelvp(bp); 1826 1.12 pk 1827 1.12 pk pool_put(swapbuf_pool, sbp); 1828 1.1 mrg splx(s); 1829 1.1 mrg 1830 1.1 mrg /* 1831 1.1 mrg * finally return. 1832 1.1 mrg */ 1833 1.1 mrg UVMHIST_LOG(pdhist, "<- done (sync) result=%d", result, 0, 0, 0); 1834 1.1 mrg return (result); 1835 1.1 mrg } 1836 1.1 mrg 1837 1.1 mrg /* 1838 1.1 mrg * uvm_swap_bufdone: called from the buffer system when the i/o is done 1839 1.1 mrg */ 1840 1.1 mrg static void 1841 1.1 mrg uvm_swap_bufdone(bp) 1842 1.1 mrg struct buf *bp; 1843 1.1 mrg { 1844 1.1 mrg struct swapbuf *sbp = (struct swapbuf *) bp; 1845 1.1 mrg int s = splbio(); 1846 1.1 mrg UVMHIST_FUNC("uvm_swap_bufdone"); UVMHIST_CALLED(pdhist); 1847 1.1 mrg 1848 1.1 mrg UVMHIST_LOG(pdhist, "cleaning buf %p", buf, 0, 0, 0); 1849 1.1 mrg #ifdef DIAGNOSTIC 1850 1.1 mrg /* 1851 1.1 mrg * sanity check: swapbufs are private, so they shouldn't be wanted 1852 1.1 mrg */ 1853 1.1 mrg if (bp->b_flags & B_WANTED) 1854 1.1 mrg panic("uvm_swap_bufdone: private buf wanted"); 1855 1.1 mrg #endif 1856 1.1 mrg 1857 1.1 mrg /* 1858 1.25 chs * drop the buffer's reference to the vnode. 1859 1.1 mrg */ 1860 1.1 mrg if (bp->b_vp) 1861 1.1 mrg brelvp(bp); 1862 1.1 mrg 1863 1.1 mrg /* 1864 1.1 mrg * now put the aio on the uvm.aio_done list and wake the 1865 1.1 mrg * pagedaemon (which will finish up our job in its context). 1866 1.1 mrg */ 1867 1.27.4.1 chs simple_lock(&uvm.aiodoned_lock); /* locks uvm.aio_done */ 1868 1.1 mrg TAILQ_INSERT_TAIL(&uvm.aio_done, &sbp->sw_aio, aioq); 1869 1.27.4.1 chs simple_unlock(&uvm.aiodoned_lock); 1870 1.1 mrg 1871 1.27.4.1 chs wakeup(&uvm.aiodoned); 1872 1.1 mrg splx(s); 1873 1.1 mrg } 1874 1.1 mrg 1875 1.1 mrg /* 1876 1.1 mrg * uvm_swap_aiodone: aiodone function for anonymous memory 1877 1.1 mrg * 1878 1.1 mrg * => this is called in the context of the pagedaemon (but with the 1879 1.1 mrg * page queues unlocked!) 1880 1.1 mrg * => our "aio" structure must be part of a "swapbuf" 1881 1.1 mrg */ 1882 1.1 mrg static void 1883 1.1 mrg uvm_swap_aiodone(aio) 1884 1.1 mrg struct uvm_aiodesc *aio; 1885 1.1 mrg { 1886 1.1 mrg struct swapbuf *sbp = aio->pd_ptr; 1887 1.20 chs struct vm_page *pps[MAXBSIZE >> PAGE_SHIFT]; 1888 1.1 mrg int lcv, s; 1889 1.15 eeh vaddr_t addr; 1890 1.1 mrg UVMHIST_FUNC("uvm_swap_aiodone"); UVMHIST_CALLED(pdhist); 1891 1.8 mrg 1892 1.1 mrg UVMHIST_LOG(pdhist, "done with aio %p", aio, 0, 0, 0); 1893 1.1 mrg #ifdef DIAGNOSTIC 1894 1.1 mrg /* 1895 1.1 mrg * sanity check 1896 1.1 mrg */ 1897 1.20 chs if (aio->npages > (MAXBSIZE >> PAGE_SHIFT)) 1898 1.1 mrg panic("uvm_swap_aiodone: aio too big!"); 1899 1.1 mrg #endif 1900 1.1 mrg 1901 1.1 mrg /* 1902 1.1 mrg * first, we have to recover the page pointers (pps) by poking in the 1903 1.1 mrg * kernel pmap (XXX: should be saved in the buf structure). 1904 1.1 mrg */ 1905 1.1 mrg for (addr = aio->kva, lcv = 0 ; lcv < aio->npages ; 1906 1.1 mrg addr += PAGE_SIZE, lcv++) { 1907 1.1 mrg pps[lcv] = uvm_pageratop(addr); 1908 1.1 mrg } 1909 1.1 mrg 1910 1.1 mrg /* 1911 1.1 mrg * now we can dispose of the kernel mappings of the buffer 1912 1.1 mrg */ 1913 1.1 mrg uvm_pagermapout(aio->kva, aio->npages); 1914 1.1 mrg 1915 1.1 mrg /* 1916 1.1 mrg * now we can dispose of the pages by using the dropcluster function 1917 1.1 mrg * [note that we have no "page of interest" so we pass in null] 1918 1.1 mrg */ 1919 1.1 mrg uvm_pager_dropcluster(NULL, NULL, pps, &aio->npages, 1920 1.1 mrg PGO_PDFREECLUST, 0); 1921 1.1 mrg 1922 1.1 mrg /* 1923 1.1 mrg * finally, we can dispose of the swapbuf 1924 1.1 mrg */ 1925 1.1 mrg s = splbio(); 1926 1.12 pk pool_put(swapbuf_pool, sbp); 1927 1.1 mrg splx(s); 1928 1.1 mrg } 1929
Indexes created Wed Oct 22 00:09:40 GMT 2025