/* * Copyright (c) 1990 University of Utah. * Copyright (c) 1991, 1993 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * the Systems Programming Group of the University of Utah Computer * Science Department. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: Utah $Hdr: swap_pager.c 1.4 91/04/30$ * * @(#)swap_pager.c 8.9 (Berkeley) 3/21/94 */ /* * Quick hack to page to dedicated partition(s). * TODO: * Add multiprocessor locks * Deal with async writes in a better fashion */ #include #include #include #include #include #include #include #include #include #include #include #include #define NSWSIZES 16 /* size of swtab */ #define MAXDADDRS 64 /* max # of disk addrs for fixed allocations */ #ifndef NPENDINGIO #define NPENDINGIO 64 /* max # of pending cleans */ #endif #ifdef DEBUG int swpagerdebug = 0x100; #define SDB_FOLLOW 0x001 #define SDB_INIT 0x002 #define SDB_ALLOC 0x004 #define SDB_IO 0x008 #define SDB_WRITE 0x010 #define SDB_FAIL 0x020 #define SDB_ALLOCBLK 0x040 #define SDB_FULL 0x080 #define SDB_ANOM 0x100 #define SDB_ANOMPANIC 0x200 #define SDB_CLUSTER 0x400 #define SDB_PARANOIA 0x800 #endif TAILQ_HEAD(swpclean, swpagerclean); struct swpagerclean { TAILQ_ENTRY(swpagerclean) spc_list; int spc_flags; struct buf *spc_bp; sw_pager_t spc_swp; vm_offset_t spc_kva; vm_page_t spc_m; int spc_npages; } swcleanlist[NPENDINGIO]; typedef struct swpagerclean *swp_clean_t; /* spc_flags values */ #define SPC_FREE 0x00 #define SPC_BUSY 0x01 #define SPC_DONE 0x02 #define SPC_ERROR 0x04 struct swtab { vm_size_t st_osize; /* size of object (bytes) */ int st_bsize; /* vs. size of swap block (DEV_BSIZE units) */ #ifdef DEBUG u_long st_inuse; /* number in this range in use */ u_long st_usecnt; /* total used of this size */ #endif } swtab[NSWSIZES+1]; #ifdef DEBUG int swap_pager_poip; /* pageouts in progress */ int swap_pager_piip; /* pageins in progress */ #endif int swap_pager_maxcluster; /* maximum cluster size */ int swap_pager_npendingio; /* number of pager clean structs */ struct swpclean swap_pager_inuse; /* list of pending page cleans */ struct swpclean swap_pager_free; /* list of free pager clean structs */ struct pagerlst swap_pager_list; /* list of "named" anon regions */ static void swap_pager_init __P((void)); static vm_pager_t swap_pager_alloc __P((caddr_t, vm_size_t, vm_prot_t, vm_offset_t)); static void swap_pager_clean __P((int)); #ifdef DEBUG static void swap_pager_clean_check __P((vm_page_t *, int, int)); #endif static void swap_pager_cluster __P((vm_pager_t, vm_offset_t, vm_offset_t *, vm_offset_t *)); static void swap_pager_dealloc __P((vm_pager_t)); static int swap_pager_getpage __P((vm_pager_t, vm_page_t *, int, boolean_t)); static boolean_t swap_pager_haspage __P((vm_pager_t, vm_offset_t)); static int swap_pager_io __P((sw_pager_t, vm_page_t *, int, int)); static void swap_pager_iodone __P((struct buf *)); static int swap_pager_putpage __P((vm_pager_t, vm_page_t *, int, boolean_t)); struct pagerops swappagerops = { swap_pager_init, swap_pager_alloc, swap_pager_dealloc, swap_pager_getpage, swap_pager_putpage, swap_pager_haspage, swap_pager_cluster }; static void swap_pager_init() { register swp_clean_t spc; register int i, bsize; extern int dmmin, dmmax; int maxbsize; #ifdef DEBUG if (swpagerdebug & (SDB_FOLLOW|SDB_INIT)) printf("swpg_init()\n"); #endif dfltpagerops = &swappagerops; TAILQ_INIT(&swap_pager_list); /* * Allocate async IO structures. * * XXX it would be nice if we could do this dynamically based on * the value of nswbuf (since we are ultimately limited by that) * but neither nswbuf or malloc has been initialized yet. So the * structs are statically allocated above. */ swap_pager_npendingio = NPENDINGIO; /* * Initialize clean lists */ TAILQ_INIT(&swap_pager_inuse); TAILQ_INIT(&swap_pager_free); for (i = 0, spc = swcleanlist; i < swap_pager_npendingio; i++, spc++) { TAILQ_INSERT_TAIL(&swap_pager_free, spc, spc_list); spc->spc_flags = SPC_FREE; } /* * Calculate the swap allocation constants. */ if (dmmin == 0) { dmmin = DMMIN; if (dmmin < CLBYTES/DEV_BSIZE) dmmin = CLBYTES/DEV_BSIZE; } if (dmmax == 0) dmmax = DMMAX; /* * Fill in our table of object size vs. allocation size */ bsize = btodb(PAGE_SIZE); if (bsize < dmmin) bsize = dmmin; maxbsize = btodb(sizeof(sw_bm_t) * NBBY * PAGE_SIZE); if (maxbsize > dmmax) maxbsize = dmmax; for (i = 0; i < NSWSIZES; i++) { swtab[i].st_osize = (vm_size_t) (MAXDADDRS * dbtob(bsize)); swtab[i].st_bsize = bsize; if (bsize <= btodb(MAXPHYS)) swap_pager_maxcluster = dbtob(bsize); #ifdef DEBUG if (swpagerdebug & SDB_INIT) printf("swpg_init: ix %d, size %x, bsize %x\n", i, swtab[i].st_osize, swtab[i].st_bsize); #endif if (bsize >= maxbsize) break; bsize *= 2; } swtab[i].st_osize = 0; swtab[i].st_bsize = bsize; } /* * Allocate a pager structure and associated resources. * Note that if we are called from the pageout daemon (handle == NULL) * we should not wait for memory as it could resulting in deadlock. */ static vm_pager_t swap_pager_alloc(handle, size, prot, foff) caddr_t handle; register vm_size_t size; vm_prot_t prot; vm_offset_t foff; { register vm_pager_t pager; register sw_pager_t swp; struct swtab *swt; int waitok; #ifdef DEBUG if (swpagerdebug & (SDB_FOLLOW|SDB_ALLOC)) printf("swpg_alloc(%x, %x, %x)\n", handle, size, prot); #endif /* * If this is a "named" anonymous region, look it up and * return the appropriate pager if it exists. */ if (handle) { pager = vm_pager_lookup(&swap_pager_list, handle); if (pager != NULL) { /* * Use vm_object_lookup to gain a reference * to the object and also to remove from the * object cache. */ if (vm_object_lookup(pager) == NULL) panic("swap_pager_alloc: bad object"); return(pager); } } /* * Pager doesn't exist, allocate swap management resources * and initialize. */ waitok = handle ? M_WAITOK : M_NOWAIT; pager = (vm_pager_t)malloc(sizeof *pager, M_VMPAGER, waitok); if (pager == NULL) return(NULL); swp = (sw_pager_t)malloc(sizeof *swp, M_VMPGDATA, waitok); if (swp == NULL) { #ifdef DEBUG if (swpagerdebug & SDB_FAIL) printf("swpg_alloc: swpager malloc failed\n"); #endif free((caddr_t)pager, M_VMPAGER); return(NULL); } size = round_page(size); for (swt = swtab; swt->st_osize; swt++) if (size <= swt->st_osize) break; #ifdef DEBUG swt->st_inuse++; swt->st_usecnt++; #endif swp->sw_osize = size; swp->sw_bsize = swt->st_bsize; swp->sw_nblocks = (btodb(size) + swp->sw_bsize - 1) / swp->sw_bsize; swp->sw_blocks = (sw_blk_t) malloc(swp->sw_nblocks*sizeof(*swp->sw_blocks), M_VMPGDATA, M_NOWAIT); if (swp->sw_blocks == NULL) { free((caddr_t)swp, M_VMPGDATA); free((caddr_t)pager, M_VMPAGER); #ifdef DEBUG if (swpagerdebug & SDB_FAIL) printf("swpg_alloc: sw_blocks malloc failed\n"); swt->st_inuse--; swt->st_usecnt--; #endif return(FALSE); } bzero((caddr_t)swp->sw_blocks, swp->sw_nblocks * sizeof(*swp->sw_blocks)); swp->sw_poip = 0; if (handle) { vm_object_t object; swp->sw_flags = SW_NAMED; TAILQ_INSERT_TAIL(&swap_pager_list, pager, pg_list); /* * Consistant with other pagers: return with object * referenced. Can't do this with handle == NULL * since it might be the pageout daemon calling. */ object = vm_object_allocate(size); vm_object_enter(object, pager); vm_object_setpager(object, pager, 0, FALSE); } else { swp->sw_flags = 0; pager->pg_list.tqe_next = NULL; pager->pg_list.tqe_prev = NULL; } pager->pg_handle = handle; pager->pg_ops = &swappagerops; pager->pg_type = PG_SWAP; pager->pg_flags = PG_CLUSTERPUT; pager->pg_data = swp; #ifdef DEBUG if (swpagerdebug & SDB_ALLOC) printf("swpg_alloc: pg_data %x, %x of %x at %x\n", swp, swp->sw_nblocks, swp->sw_bsize, swp->sw_blocks); #endif return(pager); } static void swap_pager_dealloc(pager) vm_pager_t pager; { register int i; register sw_blk_t bp; register sw_pager_t swp; struct swtab *swt; int s; #ifdef DEBUG /* save panic time state */ if ((swpagerdebug & SDB_ANOMPANIC) && panicstr) return; if (swpagerdebug & (SDB_FOLLOW|SDB_ALLOC)) printf("swpg_dealloc(%x)\n", pager); #endif /* * Remove from list right away so lookups will fail if we * block for pageout completion. */ swp = (sw_pager_t) pager->pg_data; if (swp->sw_flags & SW_NAMED) { TAILQ_REMOVE(&swap_pager_list, pager, pg_list); swp->sw_flags &= ~SW_NAMED; } #ifdef DEBUG for (swt = swtab; swt->st_osize; swt++) if (swp->sw_osize <= swt->st_osize) break; swt->st_inuse--; #endif /* * Wait for all pageouts to finish and remove * all entries from cleaning list. */ s = splbio(); while (swp->sw_poip) { swp->sw_flags |= SW_WANTED; (void) tsleep(swp, PVM, "swpgdealloc", 0); } splx(s); swap_pager_clean(B_WRITE); /* * Free left over swap blocks */ for (i = 0, bp = swp->sw_blocks; i < swp->sw_nblocks; i++, bp++) if (bp->swb_block) { #ifdef DEBUG if (swpagerdebug & (SDB_ALLOCBLK|SDB_FULL)) printf("swpg_dealloc: blk %x\n", bp->swb_block); #endif rmfree(swapmap, swp->sw_bsize, bp->swb_block); } /* * Free swap management resources */ free((caddr_t)swp->sw_blocks, M_VMPGDATA); free((caddr_t)swp, M_VMPGDATA); free((caddr_t)pager, M_VMPAGER); } static int swap_pager_getpage(pager, mlist, npages, sync) vm_pager_t pager; vm_page_t *mlist; int npages; boolean_t sync; { #ifdef DEBUG if (swpagerdebug & SDB_FOLLOW) printf("swpg_getpage(%x, %x, %x, %x)\n", pager, mlist, npages, sync); #endif return(swap_pager_io((sw_pager_t)pager->pg_data, mlist, npages, B_READ)); } static int swap_pager_putpage(pager, mlist, npages, sync) vm_pager_t pager; vm_page_t *mlist; int npages; boolean_t sync; { int flags; #ifdef DEBUG if (swpagerdebug & SDB_FOLLOW) printf("swpg_putpage(%x, %x, %x, %x)\n", pager, mlist, npages, sync); #endif if (pager == NULL) { swap_pager_clean(B_WRITE); return (VM_PAGER_OK); /* ??? */ } flags = B_WRITE; if (!sync) flags |= B_ASYNC; return(swap_pager_io((sw_pager_t)pager->pg_data, mlist, npages, flags)); } static boolean_t swap_pager_haspage(pager, offset) vm_pager_t pager; vm_offset_t offset; { register sw_pager_t swp; register sw_blk_t swb; int ix; #ifdef DEBUG if (swpagerdebug & (SDB_FOLLOW|SDB_ALLOCBLK)) printf("swpg_haspage(%x, %x) ", pager, offset); #endif swp = (sw_pager_t) pager->pg_data; ix = offset / dbtob(swp->sw_bsize); if (swp->sw_blocks == NULL || ix >= swp->sw_nblocks) { #ifdef DEBUG if (swpagerdebug & (SDB_FAIL|SDB_FOLLOW|SDB_ALLOCBLK)) printf("swpg_haspage: %x bad offset %x, ix %x\n", swp->sw_blocks, offset, ix); #endif return(FALSE); } swb = &swp->sw_blocks[ix]; if (swb->swb_block) ix = atop(offset % dbtob(swp->sw_bsize)); #ifdef DEBUG if (swpagerdebug & SDB_ALLOCBLK) printf("%x blk %x+%x ", swp->sw_blocks, swb->swb_block, ix); if (swpagerdebug & (SDB_FOLLOW|SDB_ALLOCBLK)) printf("-> %c\n", "FT"[swb->swb_block && (swb->swb_mask & (1 << ix))]); #endif if (swb->swb_block && (swb->swb_mask & (1 << ix))) return(TRUE); return(FALSE); } static void swap_pager_cluster(pager, offset, loffset, hoffset) vm_pager_t pager; vm_offset_t offset; vm_offset_t *loffset; vm_offset_t *hoffset; { sw_pager_t swp; register int bsize; vm_offset_t loff, hoff; #ifdef DEBUG if (swpagerdebug & (SDB_FOLLOW|SDB_CLUSTER)) printf("swpg_cluster(%x, %x) ", pager, offset); #endif swp = (sw_pager_t) pager->pg_data; bsize = dbtob(swp->sw_bsize); if (bsize > swap_pager_maxcluster) bsize = swap_pager_maxcluster; loff = offset - (offset % bsize); if (loff >= swp->sw_osize) panic("swap_pager_cluster: bad offset"); hoff = loff + bsize; if (hoff > swp->sw_osize) hoff = swp->sw_osize; *loffset = loff; *hoffset = hoff; #ifdef DEBUG if (swpagerdebug & (SDB_FOLLOW|SDB_CLUSTER)) printf("returns [%x-%x]\n", loff, hoff); #endif } /* * Scaled down version of swap(). * Assumes that PAGE_SIZE < MAXPHYS; i.e. only one operation needed. * BOGUS: lower level IO routines expect a KVA so we have to map our * provided physical page into the KVA to keep them happy. */ static int swap_pager_io(swp, mlist, npages, flags) register sw_pager_t swp; vm_page_t *mlist; int npages; int flags; { register struct buf *bp; register sw_blk_t swb; register int s; int ix, mask; boolean_t rv; vm_offset_t kva, off; swp_clean_t spc; vm_page_t m; #ifdef DEBUG /* save panic time state */ if ((swpagerdebug & SDB_ANOMPANIC) && panicstr) return (VM_PAGER_FAIL); /* XXX: correct return? */ if (swpagerdebug & (SDB_FOLLOW|SDB_IO)) printf("swpg_io(%x, %x, %x, %x)\n", swp, mlist, npages, flags); if (flags & B_READ) { if (flags & B_ASYNC) panic("swap_pager_io: cannot do ASYNC reads"); if (npages != 1) panic("swap_pager_io: cannot do clustered reads"); } #endif /* * First determine if the page exists in the pager if this is * a sync read. This quickly handles cases where we are * following shadow chains looking for the top level object * with the page. */ m = *mlist; off = m->offset + m->object->paging_offset; ix = off / dbtob(swp->sw_bsize); if (swp->sw_blocks == NULL || ix >= swp->sw_nblocks) { #ifdef DEBUG if ((flags & B_READ) == 0 && (swpagerdebug & SDB_ANOM)) { printf("swap_pager_io: no swap block on write\n"); return(VM_PAGER_BAD); } #endif return(VM_PAGER_FAIL); } swb = &swp->sw_blocks[ix]; off = off % dbtob(swp->sw_bsize); if ((flags & B_READ) && (swb->swb_block == 0 || (swb->swb_mask & (1 << atop(off))) == 0)) return(VM_PAGER_FAIL); /* * For reads (pageins) and synchronous writes, we clean up * all completed async pageouts. */ if ((flags & B_ASYNC) == 0) { s = splbio(); swap_pager_clean(flags&B_READ); #ifdef DEBUG if (swpagerdebug & SDB_PARANOIA) swap_pager_clean_check(mlist, npages, flags&B_READ); #endif splx(s); } /* * For async writes (pageouts), we cleanup completed pageouts so * that all available resources are freed. Also tells us if this * page is already being cleaned. If it is, or no resources * are available, we try again later. */ else { swap_pager_clean(B_WRITE); #ifdef DEBUG if (swpagerdebug & SDB_PARANOIA) swap_pager_clean_check(mlist, npages, B_WRITE); #endif if (swap_pager_free.tqh_first == NULL) { #ifdef DEBUG if (swpagerdebug & SDB_FAIL) printf("%s: no available io headers\n", "swap_pager_io"); #endif return(VM_PAGER_AGAIN); } } /* * Allocate a swap block if necessary. */ if (swb->swb_block == 0) { swb->swb_block = rmalloc(swapmap, swp->sw_bsize); if (swb->swb_block == 0) { #ifdef DEBUG if (swpagerdebug & SDB_FAIL) printf("swpg_io: rmalloc of %x failed\n", swp->sw_bsize); #endif /* * XXX this is technically a resource shortage that * should return AGAIN, but the situation isn't likely * to be remedied just by delaying a little while and * trying again (the pageout daemon's current response * to AGAIN) so we just return FAIL. */ return(VM_PAGER_FAIL); } #ifdef DEBUG if (swpagerdebug & (SDB_FULL|SDB_ALLOCBLK)) printf("swpg_io: %x alloc blk %x at ix %x\n", swp->sw_blocks, swb->swb_block, ix); #endif } /* * Allocate a kernel virtual address and initialize so that PTE * is available for lower level IO drivers. */ kva = vm_pager_map_pages(mlist, npages, !(flags & B_ASYNC)); if (kva == NULL) { #ifdef DEBUG if (swpagerdebug & SDB_FAIL) printf("%s: no KVA space to map pages\n", "swap_pager_io"); #endif return(VM_PAGER_AGAIN); } /* * Get a swap buffer header and initialize it. */ s = splbio(); while (bswlist.b_actf == NULL) { #ifdef DEBUG if (swpagerdebug & SDB_ANOM) printf("swap_pager_io: wait on swbuf for %x (%d)\n", m, flags); #endif bswlist.b_flags |= B_WANTED; tsleep((caddr_t)&bswlist, PSWP+1, "swpgiobuf", 0); } bp = bswlist.b_actf; bswlist.b_actf = bp->b_actf; splx(s); bp->b_flags = B_BUSY | (flags & B_READ); bp->b_proc = &proc0; /* XXX (but without B_PHYS set this is ok) */ bp->b_data = (caddr_t)kva; bp->b_blkno = swb->swb_block + btodb(off); VHOLD(swapdev_vp); bp->b_vp = swapdev_vp; if (swapdev_vp->v_type == VBLK) bp->b_dev = swapdev_vp->v_rdev; bp->b_bcount = npages * PAGE_SIZE; /* * For writes we set up additional buffer fields, record a pageout * in progress and mark that these swap blocks are now allocated. */ if ((bp->b_flags & B_READ) == 0) { bp->b_dirtyoff = 0; bp->b_dirtyend = npages * PAGE_SIZE; swapdev_vp->v_numoutput++; s = splbio(); swp->sw_poip++; splx(s); mask = (~(~0 << npages)) << atop(off); #ifdef DEBUG swap_pager_poip++; if (swpagerdebug & SDB_WRITE) printf("swpg_io: write: bp=%x swp=%x poip=%d\n", bp, swp, swp->sw_poip); if ((swpagerdebug & SDB_ALLOCBLK) && (swb->swb_mask & mask) != mask) printf("swpg_io: %x write %d pages at %x+%x\n", swp->sw_blocks, npages, swb->swb_block, atop(off)); if (swpagerdebug & SDB_CLUSTER) printf("swpg_io: off=%x, npg=%x, mask=%x, bmask=%x\n", off, npages, mask, swb->swb_mask); #endif swb->swb_mask |= mask; } /* * If this is an async write we set up still more buffer fields * and place a "cleaning" entry on the inuse queue. */ if ((flags & (B_READ|B_ASYNC)) == B_ASYNC) { #ifdef DEBUG if (swap_pager_free.tqh_first == NULL) panic("swpg_io: lost spc"); #endif spc = swap_pager_free.tqh_first; TAILQ_REMOVE(&swap_pager_free, spc, spc_list); #ifdef DEBUG if (spc->spc_flags != SPC_FREE) panic("swpg_io: bad free spc"); #endif spc->spc_flags = SPC_BUSY; spc->spc_bp = bp; spc->spc_swp = swp; spc->spc_kva = kva; /* * Record the first page. This allows swap_pager_clean * to efficiently handle the common case of a single page. * For clusters, it allows us to locate the object easily * and we then reconstruct the rest of the mlist from spc_kva. */ spc->spc_m = m; spc->spc_npages = npages; bp->b_flags |= B_CALL; bp->b_iodone = swap_pager_iodone; s = splbio(); TAILQ_INSERT_TAIL(&swap_pager_inuse, spc, spc_list); splx(s); } /* * Finally, start the IO operation. * If it is async we are all done, otherwise we must wait for * completion and cleanup afterwards. */ #ifdef DEBUG if (swpagerdebug & SDB_IO) printf("swpg_io: IO start: bp %x, db %x, va %x, pa %x\n", bp, swb->swb_block+btodb(off), kva, VM_PAGE_TO_PHYS(m)); #endif VOP_STRATEGY(bp); if ((flags & (B_READ|B_ASYNC)) == B_ASYNC) { #ifdef DEBUG if (swpagerdebug & SDB_IO) printf("swpg_io: IO started: bp %x\n", bp); #endif return(VM_PAGER_PEND); } s = splbio(); #ifdef DEBUG if (flags & B_READ) swap_pager_piip++; else swap_pager_poip++; #endif while ((bp->b_flags & B_DONE) == 0) (void) tsleep(bp, PVM, "swpgio", 0); if ((flags & B_READ) == 0) --swp->sw_poip; #ifdef DEBUG if (flags & B_READ) --swap_pager_piip; else --swap_pager_poip; #endif rv = (bp->b_flags & B_ERROR) ? VM_PAGER_ERROR : VM_PAGER_OK; bp->b_flags &= ~(B_BUSY|B_WANTED|B_PHYS|B_PAGET|B_UAREA|B_DIRTY); bp->b_actf = bswlist.b_actf; bswlist.b_actf = bp; if (bp->b_vp) brelvp(bp); if (bswlist.b_flags & B_WANTED) { bswlist.b_flags &= ~B_WANTED; wakeup(&bswlist); } if ((flags & B_READ) == 0 && rv == VM_PAGER_OK) { m->flags |= PG_CLEAN; pmap_clear_modify(VM_PAGE_TO_PHYS(m)); } splx(s); #ifdef DEBUG if (swpagerdebug & SDB_IO) printf("swpg_io: IO done: bp %x, rv %d\n", bp, rv); if ((swpagerdebug & SDB_FAIL) && rv == VM_PAGER_ERROR) printf("swpg_io: IO error\n"); #endif vm_pager_unmap_pages(kva, npages); return(rv); } static void swap_pager_clean(rw) int rw; { register swp_clean_t spc; register int s, i; vm_object_t object; vm_page_t m; #ifdef DEBUG /* save panic time state */ if ((swpagerdebug & SDB_ANOMPANIC) && panicstr) return; if (swpagerdebug & SDB_FOLLOW) printf("swpg_clean(%x)\n", rw); #endif for (;;) { /* * Look up and removal from inuse list must be done * at splbio() to avoid conflicts with swap_pager_iodone. */ s = splbio(); for (spc = swap_pager_inuse.tqh_first; spc != NULL; spc = spc->spc_list.tqe_next) { /* * If the operation is done, remove it from the * list and process it. * * XXX if we can't get the object lock we also * leave it on the list and try again later. * Is there something better we could do? */ if ((spc->spc_flags & SPC_DONE) && vm_object_lock_try(spc->spc_m->object)) { TAILQ_REMOVE(&swap_pager_inuse, spc, spc_list); break; } } splx(s); /* * No operations done, thats all we can do for now. */ if (spc == NULL) break; /* * Found a completed operation so finish it off. * Note: no longer at splbio since entry is off the list. */ m = spc->spc_m; object = m->object; /* * Process each page in the cluster. * The first page is explicitly kept in the cleaning * entry, others must be reconstructed from the KVA. */ for (i = 0; i < spc->spc_npages; i++) { if (i) m = vm_pager_atop(spc->spc_kva + ptoa(i)); /* * If no error mark as clean and inform the pmap * system. If there was an error, mark as dirty * so we will try again. * * XXX could get stuck doing this, should give up * after awhile. */ if (spc->spc_flags & SPC_ERROR) { printf("%s: clean of page %x failed\n", "swap_pager_clean", VM_PAGE_TO_PHYS(m)); m->flags |= PG_LAUNDRY; } else { m->flags |= PG_CLEAN; pmap_clear_modify(VM_PAGE_TO_PHYS(m)); } m->flags &= ~PG_BUSY; PAGE_WAKEUP(m); } /* * Done with the object, decrement the paging count * and unlock it. */ if (--object->paging_in_progress == 0) wakeup(object); vm_object_unlock(object); /* * Free up KVM used and put the entry back on the list. */ vm_pager_unmap_pages(spc->spc_kva, spc->spc_npages); spc->spc_flags = SPC_FREE; TAILQ_INSERT_TAIL(&swap_pager_free, spc, spc_list); #ifdef DEBUG if (swpagerdebug & SDB_WRITE) printf("swpg_clean: free spc %x\n", spc); #endif } } #ifdef DEBUG static void swap_pager_clean_check(mlist, npages, rw) vm_page_t *mlist; int npages; int rw; { register swp_clean_t spc; boolean_t bad; int i, j, s; vm_page_t m; if (panicstr) return; bad = FALSE; s = splbio(); for (spc = swap_pager_inuse.tqh_first; spc != NULL; spc = spc->spc_list.tqe_next) { for (j = 0; j < spc->spc_npages; j++) { m = vm_pager_atop(spc->spc_kva + ptoa(j)); for (i = 0; i < npages; i++) if (m == mlist[i]) { if (swpagerdebug & SDB_ANOM) printf( "swpg_clean_check: %s: page %x on list, flags %x\n", rw == B_WRITE ? "write" : "read", mlist[i], spc->spc_flags); bad = TRUE; } } } splx(s); if (bad) panic("swpg_clean_check"); } #endif static void swap_pager_iodone(bp) register struct buf *bp; { register swp_clean_t spc; daddr_t blk; int s; #ifdef DEBUG /* save panic time state */ if ((swpagerdebug & SDB_ANOMPANIC) && panicstr) return; if (swpagerdebug & SDB_FOLLOW) printf("swpg_iodone(%x)\n", bp); #endif s = splbio(); for (spc = swap_pager_inuse.tqh_first; spc != NULL; spc = spc->spc_list.tqe_next) if (spc->spc_bp == bp) break; #ifdef DEBUG if (spc == NULL) panic("swap_pager_iodone: bp not found"); #endif spc->spc_flags &= ~SPC_BUSY; spc->spc_flags |= SPC_DONE; if (bp->b_flags & B_ERROR) spc->spc_flags |= SPC_ERROR; spc->spc_bp = NULL; blk = bp->b_blkno; #ifdef DEBUG --swap_pager_poip; if (swpagerdebug & SDB_WRITE) printf("swpg_iodone: bp=%x swp=%x flags=%x spc=%x poip=%x\n", bp, spc->spc_swp, spc->spc_swp->sw_flags, spc, spc->spc_swp->sw_poip); #endif spc->spc_swp->sw_poip--; if (spc->spc_swp->sw_flags & SW_WANTED) { spc->spc_swp->sw_flags &= ~SW_WANTED; wakeup(spc->spc_swp); } bp->b_flags &= ~(B_BUSY|B_WANTED|B_PHYS|B_PAGET|B_UAREA|B_DIRTY); bp->b_actf = bswlist.b_actf; bswlist.b_actf = bp; if (bp->b_vp) brelvp(bp); if (bswlist.b_flags & B_WANTED) { bswlist.b_flags &= ~B_WANTED; wakeup(&bswlist); } wakeup(&vm_pages_needed); splx(s); }