/* Pager for ext2fs Copyright (C) 1994, 1995 Free Software Foundation, Inc. Converted for ext2fs by Miles Bader This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include #include "ext2fs.h" spin_lock_t pager_list_lock = SPIN_LOCK_INITIALIZER; struct user_pager_info *file_pager_list; spin_lock_t node_to_page_lock = SPIN_LOCK_INITIALIZER; #ifdef DONT_CACHE_MEMORY_OBJECTS #define MAY_CACHE 0 #else #define MAY_CACHE 1 #endif /* ---------------------------------------------------------------- */ /* Find the location on disk of page OFFSET in NODE. Return the disk block in BLOCK (if unallocated, then return 0). If *LOCK is 0, then it a reader lock is aquired on NODE's ALLOC_LOCK before doing anything, and left locked after return -- even if an error is returned. 0 on success or an error code otherwise is returned. */ static error_t find_block (struct node *node, vm_offset_t offset, block_t *block, struct rwlock **lock) { error_t err; if (!*lock) { *lock = &node->dn->alloc_lock; rwlock_reader_lock (*lock); } if (offset + block_size > node->allocsize) return EIO; err = ext2_getblk (node, offset >> log2_block_size, 0, block); if (err == EINVAL) /* Don't barf yet if the node is unallocated. */ { *block = 0; err = 0; } return err; } /* ---------------------------------------------------------------- */ /* Read one page for the pager backing NODE at offset PAGE, into BUF. This may need to read several filesystem blocks to satisfy one page, and tries to consolidate the i/o if possible. */ static error_t file_pager_read_page (struct node *node, vm_offset_t page, vm_address_t *buf, int *writelock) { error_t err; int offs = 0; struct rwlock *lock = NULL; int left = vm_page_size; block_t pending_blocks = 0; int num_pending_blocks = 0; /* Read the NUM_PENDING_BLOCKS blocks in PENDING_BLOCKS, into the buffer pointed to by BUF (allocating it if necessary) at offset OFFS. OFFS in adjusted by the amount read, and NUM_PENDING_BLOCKS is zeroed. Any read error is returned. */ error_t do_pending_reads () { if (num_pending_blocks > 0) { block_t dev_block = pending_blocks << log2_dev_blocks_per_fs_block; int length = num_pending_blocks << log2_block_size; vm_address_t new_buf; err = dev_read_sync (dev_block, &new_buf, length); if (err) return err; if (offs == 0) /* First read, make the returned page be our buffer. */ *buf = new_buf; else /* We've already got some buffer, so copy into it. */ bcopy ((char *)*buf + offs, (char *)new_buf, length); offs += length; num_pending_blocks = 0; } return 0; } if (page + left > node->allocsize) left = node->allocsize - page; while (left > 0) { block_t block; err = find_block (node, page, &block, &lock); if (err) break; if (block != pending_blocks + num_pending_blocks) { err = do_pending_reads (); if (err) break; pending_blocks = block; } if (block == 0) /* Reading unallocate block, just make a zero-filled one. */ { *writelock = 1; if (offs == 0) /* No page allocated to read into yet. */ { err = vm_allocate (mach_task_self (), buf, vm_page_size, 1); if (err) break; } bzero ((char *)*buf + offs, block_size); offs += block_size; } else num_pending_blocks++; page += block_size; left -= block_size; } if (!err && num_pending_blocks > 0) do_pending_reads(); if (lock) rwlock_reader_unlock (lock); return err; } /* ---------------------------------------------------------------- */ struct pending_blocks { /* The block number of the first of the blocks. */ block_t block; /* How many blocks we have. */ int num; /* A (page-aligned) buffer pointing to the data we're dealing with. */ vm_address_t buf; /* And an offset into BUF. */ int offs; }; /* Write the any pending blocks in PB. */ static error_t pending_blocks_write (struct pending_blocks *pb) { if (pb->num > 0) { error_t err; block_t dev_block = pb->block << log2_dev_blocks_per_fs_block; int length = pb->num << log2_block_size; ext2_debug ("Writing block %lu[%d]", pb->block, pb->num); if (pb->offs > 0) /* Put what we're going to write into a page-aligned buffer. */ { vm_address_t page_buf = get_page_buf (); bcopy ((char *)pb->buf + pb->offs, (void *)page_buf, length); err = dev_write_sync (dev_block, page_buf, length); free_page_buf (page_buf); } else err = dev_write_sync (dev_block, pb->buf, length); if (err) return err; pb->offs += length; pb->num = 0; } return 0; } static void pending_blocks_init (struct pending_blocks *pb, vm_address_t buf) { pb->buf = buf; pb->block = 0; pb->num = 0; pb->offs = 0; } /* Skip writing the next block in PB's buffer (writing out any previous blocks if necessary). */ static error_t pending_blocks_skip (struct pending_blocks *pb) { error_t err = pending_blocks_write (pb); pb->offs += block_size; return err; } /* Add the disk block BLOCK to the list of destination disk blocks pending in PB. */ static error_t pending_blocks_add (struct pending_blocks *pb, block_t block) { if (block != pb->block + pb->num) { error_t err = pending_blocks_write (pb); if (err) return err; pb->block = block; } pb->num++; return 0; } /* ---------------------------------------------------------------- */ /* Write one page for the pager backing NODE, at offset PAGE, into BUF. This may need to write several filesystem blocks to satisfy one page, and tries to consolidate the i/o if possible. */ static error_t file_pager_write_page (struct node *node, vm_offset_t offset, vm_address_t buf) { error_t err = 0; struct pending_blocks pb; struct rwlock *lock = 0; u32 block; int left = vm_page_size; pending_blocks_init (&pb, buf); if (offset + left > node->allocsize) left = node->allocsize - offset; ext2_debug ("Writing inode %d page %d[%d]", node->dn->number, offset, left); while (left > 0) { err = find_block (node, offset, &block, &lock); if (err) break; assert (block); pending_blocks_add (&pb, block); offset += block_size; left -= block_size; } if (!err) pending_blocks_write (&pb); if (lock) rwlock_reader_unlock (lock); return err; } /* ---------------------------------------------------------------- */ static error_t disk_pager_read_page (vm_offset_t page, vm_address_t *buf, int *writelock) { error_t err; int length = vm_page_size; if (page + vm_page_size > device_size) length = device_size - page; err = dev_read_sync (page / device_block_size, (void *)buf, length); if (!err && length != vm_page_size) bzero ((void *)(*buf + length), vm_page_size - length); *writelock = 0; return err; } static error_t disk_pager_write_page (vm_offset_t page, vm_address_t buf) { error_t err = 0; int length = vm_page_size; if (page + vm_page_size > device_size) length = device_size - page; ext2_debug ("Writing disk page %d[%d]", page, length); if (modified_global_blocks) /* Be picky about which blocks in a page that we write. */ { vm_offset_t offs = page; struct pending_blocks pb; pending_blocks_init (&pb, buf); while (length > 0 && !err) { int modified; block_t block = boffs_block (offs); spin_lock (&modified_global_blocks_lock); modified = clear_bit (block, modified_global_blocks); spin_unlock (&modified_global_blocks_lock); if (modified) /* This block's been modified, so write it out. */ err = pending_blocks_add (&pb, block); else /* Otherwise just skip it. */ err = pending_blocks_skip (&pb); offs += block_size; length -= block_size; } if (!err) err = pending_blocks_write (&pb); } else err = dev_write_sync (page / device_block_size, buf, length); return err; } /* ---------------------------------------------------------------- */ /* Satisfy a pager read request for either the disk pager or file pager PAGER, to the page at offset PAGE into BUF. WRITELOCK should be set if the pager should make the page writeable. */ error_t pager_read_page (struct user_pager_info *pager, vm_offset_t page, vm_address_t *buf, int *writelock) { if (pager->type == DISK) return disk_pager_read_page (page, buf, writelock); else return file_pager_read_page (pager->node, page, buf, writelock); } /* Satisfy a pager write request for either the disk pager or file pager PAGER, from the page at offset PAGE from BUF. */ error_t pager_write_page (struct user_pager_info *pager, vm_offset_t page, vm_address_t buf) { if (pager->type == DISK) return disk_pager_write_page (page, buf); else return file_pager_write_page (pager->node, page, buf); } /* ---------------------------------------------------------------- */ /* Make page PAGE writable, at least up to ALLOCSIZE. This function and diskfs_grow are the only places that blocks are actually added to the file. */ error_t pager_unlock_page (struct user_pager_info *pager, vm_offset_t page) { if (pager->type == DISK) return 0; else { error_t err; block_t block = page >> log2_block_size; struct node *node = pager->node; struct disknode *dn = node->dn; rwlock_writer_lock (&dn->alloc_lock); err = diskfs_catch_exception (); if (!err) { int left = vm_page_size; if (page + left > node->allocsize) /* Only actually create blocks up to allocsize; diskfs_grow will allocate the rest if called. */ { left = node->allocsize - page; dn->last_page_partially_writable = 1; } while (left > 0) { block_t disk_block; err = ext2_getblk(node, block++, 1, &disk_block); if (err) break; left -= block_size; } if (page + vm_page_size >= node->allocsize) dn->last_block_allocated = 1; #ifdef EXT2FS_DEBUG if (dn->last_page_partially_writable) ext2_debug ("made page %u[%u] in inode %d partially writable", page, node->allocsize - page, dn->number); else ext2_debug ("made page %u[%u] in inode %d writable", page, vm_page_size, dn->number); #endif } diskfs_end_catch_exception (); rwlock_writer_unlock (&dn->alloc_lock); return err; } } /* ---------------------------------------------------------------- */ /* Grow the disk allocated to locked node NODE to be at least SIZE bytes, and set NODE->allocsize to the actual allocated size. (If the allocated size is already SIZE bytes, do nothing.) CRED identifies the user responsible for the call. */ error_t diskfs_grow (struct node *node, off_t size, struct protid *cred) { assert (!diskfs_readonly); if (size > node->allocsize) { error_t err; struct disknode *dn = node->dn; vm_offset_t old_size = node->allocsize; vm_offset_t new_size = trunc_block (size) + block_size; ext2_debug ("growing inode %d to %u bytes (from %u)", dn->number, new_size, old_size); rwlock_writer_lock (&dn->alloc_lock); err = diskfs_catch_exception (); if (!err) { if (dn->last_page_partially_writable) /* pager_unlock_page has been called on the last page of the file, but only part of the page was created, as the rest went past the end of the file. As a result, we have to create the rest of the page to preserve the fact that blocks are only created by explicitly making them writable. */ { block_t block = old_size >> log2_block_size; int count = trunc_page (old_size) + vm_page_size - old_size; if (old_size + count < new_size) /* The page we're unlocking (and therefore creating) doesn't extend all the way to the end of the file, so there's some unallocated space left there. */ dn->last_block_allocated = 0; if (old_size + count > new_size) /* This growth won't create the whole of the last page. */ count = new_size - old_size; else /* This will take care the whole page. */ dn->last_page_partially_writable = 0; ext2_debug ("extending writable page %u by %d bytes" "; first new block = %lu", trunc_page (old_size), count, block); while (count > 0) { block_t disk_block; err = ext2_getblk(node, block++, 1, &disk_block); if (err) break; count -= block_size; } ext2_debug ("new state: page %s, last block %sallocated", dn->last_page_partially_writable ? "still partial" : "completely allocated", dn->last_block_allocated ? "" : "now un"); } node->allocsize = new_size; } diskfs_end_catch_exception (); rwlock_writer_unlock (&dn->alloc_lock); return err; } else return 0; } /* ---------------------------------------------------------------- */ /* This syncs a single file (NODE) to disk. Wait for all I/O to complete if WAIT is set. NODE->lock must be held. */ void diskfs_file_update (struct node *node, int wait) { struct user_pager_info *upi; if (!node->dn->last_block_allocated) /* Allocate the last block in the file to maintain consistency with the file size. */ { rwlock_writer_lock (&node->dn->alloc_lock); if (!node->dn->last_block_allocated) /* check again with the lock */ { block_t disk_block; block_t block = (node->allocsize >> log2_block_size) - 1; ext2_debug ("allocating final block %lu", block); if (ext2_getblk (node, block, 1, &disk_block) == 0) node->dn->last_block_allocated = 1; } rwlock_writer_unlock (&node->dn->alloc_lock); } spin_lock (&node_to_page_lock); upi = node->dn->fileinfo; if (upi) pager_reference (upi->p); spin_unlock (&node_to_page_lock); if (upi) { pager_sync (upi->p, wait); pager_unreference (upi->p); } pokel_sync (&node->dn->indir_pokel, wait); diskfs_node_update (node, wait); } /* ---------------------------------------------------------------- */ /* Return in *OFFSET and *SIZE the minimum valid address the pager will accept and the size of the object. */ inline error_t pager_report_extent (struct user_pager_info *pager, vm_address_t *offset, vm_size_t *size) { assert (pager->type == DISK || pager->type == FILE_DATA); *offset = 0; if (pager->type == DISK) *size = device_size; else *size = pager->node->allocsize; return 0; } /* This is called when a pager is being deallocated after all extant send rights have been destroyed. */ void pager_clear_user_data (struct user_pager_info *upi) { if (upi->type == FILE_DATA) { spin_lock (&node_to_page_lock); upi->node->dn->fileinfo = 0; spin_unlock (&node_to_page_lock); diskfs_nrele_light (upi->node); *upi->prevp = upi->next; if (upi->next) upi->next->prevp = upi->prevp; free (upi); } } /* ---------------------------------------------------------------- */ /* Create a the DISK pager, initializing DISKPAGER, and DISKPAGERPORT */ void create_disk_pager () { disk_pager = malloc (sizeof (struct user_pager_info)); disk_pager->type = DISK; disk_pager->node = 0; disk_pager->p = pager_create (disk_pager, MAY_CACHE, MEMORY_OBJECT_COPY_NONE); disk_pager_port = pager_get_port (disk_pager->p); mach_port_insert_right (mach_task_self (), disk_pager_port, disk_pager_port, MACH_MSG_TYPE_MAKE_SEND); } /* Call this to create a FILE_DATA pager and return a send right. NODE must be locked. */ mach_port_t diskfs_get_filemap (struct node *node) { struct user_pager_info *upi; mach_port_t right; assert (S_ISDIR (node->dn_stat.st_mode) || S_ISREG (node->dn_stat.st_mode) || (S_ISLNK (node->dn_stat.st_mode))); spin_lock (&node_to_page_lock); if (!node->dn->fileinfo) { upi = malloc (sizeof (struct user_pager_info)); upi->type = FILE_DATA; upi->node = node; diskfs_nref_light (node); upi->p = pager_create (upi, MAY_CACHE, MEMORY_OBJECT_COPY_DELAY); node->dn->fileinfo = upi; spin_lock (&pager_list_lock); upi->next = file_pager_list; upi->prevp = &file_pager_list; if (upi->next) upi->next->prevp = &upi->next; file_pager_list = upi; spin_unlock (&pager_list_lock); } right = pager_get_port (node->dn->fileinfo->p); spin_unlock (&node_to_page_lock); mach_port_insert_right (mach_task_self (), right, right, MACH_MSG_TYPE_MAKE_SEND); return right; } /* Call this when we should turn off caching so that unused memory object ports get freed. */ void drop_pager_softrefs (struct node *node) { struct user_pager_info *upi; spin_lock (&node_to_page_lock); upi = node->dn->fileinfo; if (upi) pager_reference (upi->p); spin_unlock (&node_to_page_lock); if (MAY_CACHE && upi) pager_change_attributes (upi->p, 0, MEMORY_OBJECT_COPY_DELAY, 0); if (upi) pager_unreference (upi->p); } /* Call this when we should turn on caching because it's no longer important for unused memory object ports to get freed. */ void allow_pager_softrefs (struct node *node) { struct user_pager_info *upi; spin_lock (&node_to_page_lock); upi = node->dn->fileinfo; if (upi) pager_reference (upi->p); spin_unlock (&node_to_page_lock); if (MAY_CACHE && upi) pager_change_attributes (upi->p, 1, MEMORY_OBJECT_COPY_DELAY, 0); if (upi) pager_unreference (upi->p); } /* Call this to find out the struct pager * corresponding to the FILE_DATA pager of inode IP. This should be used *only* as a subsequent argument to register_memory_fault_area, and will be deleted when the kernel interface is fixed. NODE must be locked. */ struct pager * diskfs_get_filemap_pager_struct (struct node *node) { /* This is safe because fileinfo can't be cleared; there must be an active mapping for this to be called. */ return node->dn->fileinfo->p; } /* Call function FUNC (which takes one argument, a pager) on each pager, with all file pagers being processed before the disk pager. Make the calls while holding no locks. */ static void pager_traverse (void (*func)(struct user_pager_info *)) { struct user_pager_info *p; struct item {struct item *next; struct user_pager_info *p;} *list = 0; struct item *i; spin_lock (&pager_list_lock); for (p = file_pager_list; p; p = p->next) { i = alloca (sizeof (struct item)); i->next = list; list = i; pager_reference (p->p); i->p = p; } spin_unlock (&pager_list_lock); for (i = list; i; i = i->next) { (*func)(i->p); pager_unreference (i->p->p); } (*func)(disk_pager); } /* Shutdown all the pagers. */ void diskfs_shutdown_pager () { void shutdown_one (struct user_pager_info *p) { pager_shutdown (p->p); } write_all_disknodes (); pager_traverse (shutdown_one); } /* Sync all the pagers. */ void diskfs_sync_everything (int wait) { void sync_one (struct user_pager_info *p) { if (p != disk_pager) pager_sync (p->p, wait); else pokel_sync (&global_pokel, wait); } write_all_disknodes (); pager_traverse (sync_one); }