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One is * the hash list of the inode, used for lookups. The * other linked list is the "type" list: * "in_use" - valid inode, hashed if i_nlink > 0 * "dirty" - valid inode, hashed if i_nlink > 0, dirty. * "unused" - ready to be re-used. Not hashed. * * A "dirty" list is maintained for each super block, * allowing for low-overhead inode sync() operations. */ LIST_HEAD(inode_in_use); static LIST_HEAD(inode_unused); static struct list_head inode_hashtable[HASH_SIZE]; /* * A simple spinlock to protect the list manipulations. * * NOTE! You also have to own the lock if you change * the i_state of an inode while it is in use.. */ spinlock_t inode_lock = SPIN_LOCK_UNLOCKED; /* * Statistics gathering.. */ struct { int nr_inodes; int nr_free_inodes; int dummy[5]; } inodes_stat = {0, 0,}; int max_inodes; /* * Put the inode on the super block's dirty list. * * CAREFUL! We mark it dirty unconditionally, but * move it onto the dirty list only if it is hashed. * If it was not hashed, it will never be added to * the dirty list even if it is later hashed, as it * will have been marked dirty already. * * In short, make sure you hash any inodes _before_ * you start marking them dirty.. */ void __mark_inode_dirty(struct inode *inode) { struct super_block * sb = inode->i_sb; if (sb) { spin_lock(&inode_lock); if (!(inode->i_state & I_DIRTY)) { inode->i_state |= I_DIRTY; /* Only add valid (ie hashed) inodes to the dirty list */ if (!list_empty(&inode->i_hash)) { list_del(&inode->i_list); list_add(&inode->i_list, &sb->s_dirty); } } spin_unlock(&inode_lock); } } static void __wait_on_inode(struct inode * inode) { struct wait_queue wait = { current, NULL }; add_wait_queue(&inode->i_wait, &wait); repeat: current->state = TASK_UNINTERRUPTIBLE; if (inode->i_state & I_LOCK) { schedule(); goto repeat; } remove_wait_queue(&inode->i_wait, &wait); current->state = TASK_RUNNING; } static inline void wait_on_inode(struct inode *inode) { if (inode->i_state & I_LOCK) __wait_on_inode(inode); } /* * These are initializations that only need to be done * once, because the fields are idempotent across use * of the inode.. */ static inline void init_once(struct inode * inode) { memset(inode, 0, sizeof(*inode)); init_waitqueue(&inode->i_wait); INIT_LIST_HEAD(&inode->i_hash); INIT_LIST_HEAD(&inode->i_dentry); sema_init(&inode->i_sem, 1); sema_init(&inode->i_atomic_write, 1); } static inline void write_inode(struct inode *inode) { if (inode->i_sb && inode->i_sb->s_op && inode->i_sb->s_op->write_inode) inode->i_sb->s_op->write_inode(inode); } static inline void sync_one(struct inode *inode) { if (inode->i_state & I_LOCK) { spin_unlock(&inode_lock); __wait_on_inode(inode); spin_lock(&inode_lock); } else { list_del(&inode->i_list); list_add(&inode->i_list, &inode_in_use); /* Set I_LOCK, reset I_DIRTY */ inode->i_state ^= I_DIRTY | I_LOCK; spin_unlock(&inode_lock); write_inode(inode); spin_lock(&inode_lock); inode->i_state &= ~I_LOCK; wake_up(&inode->i_wait); } } static inline void sync_list(struct list_head *head) { struct list_head * tmp; while ((tmp = head->prev) != head) sync_one(list_entry(tmp, struct inode, i_list)); } /* * "sync_inodes()" goes through the super block's dirty list, * writes them out, and puts them back on the normal list. */ void sync_inodes(kdev_t dev) { struct super_block * sb = sb_entry(super_blocks.next); /* * Search the super_blocks array for the device(s) to sync. */ spin_lock(&inode_lock); for (; sb != sb_entry(&super_blocks); sb = sb_entry(sb->s_list.next)) { if (!sb->s_dev) continue; if (dev && sb->s_dev != dev) continue; sync_list(&sb->s_dirty); if (dev) break; } spin_unlock(&inode_lock); } /* * Called with the spinlock already held.. */ static void sync_all_inodes(void) { struct super_block * sb = sb_entry(super_blocks.next); for (; sb != sb_entry(&super_blocks); sb = sb_entry(sb->s_list.next)) { if (!sb->s_dev) continue; sync_list(&sb->s_dirty); } } /* * Needed by knfsd */ void write_inode_now(struct inode *inode) { struct super_block * sb = inode->i_sb; if (sb) { spin_lock(&inode_lock); while (inode->i_state & I_DIRTY) sync_one(inode); spin_unlock(&inode_lock); } else printk("write_inode_now: no super block\n"); } /* * This is called by the filesystem to tell us * that the inode is no longer useful. We just * terminate it with extreme prejudice. */ void clear_inode(struct inode *inode) { if (inode->i_nrpages) truncate_inode_pages(inode, 0); wait_on_inode(inode); if (IS_QUOTAINIT(inode)) DQUOT_DROP(inode); if (inode->i_sb && inode->i_sb->s_op && inode->i_sb->s_op->clear_inode) inode->i_sb->s_op->clear_inode(inode); inode->i_state = 0; } /* * Dispose-list gets a local list, so it doesn't need to * worry about list corruption. It releases the inode lock * while clearing the inodes. */ static void dispose_list(struct list_head * head) { struct list_head *next; int count = 0; spin_unlock(&inode_lock); next = head->next; for (;;) { struct list_head * tmp = next; struct inode * inode; next = next->next; if (tmp == head) break; inode = list_entry(tmp, struct inode, i_list); clear_inode(inode); count++; } /* Add them all to the unused list in one fell swoop */ spin_lock(&inode_lock); list_splice(head, &inode_unused); inodes_stat.nr_free_inodes += count; } /* * Invalidate all inodes for a device. */ static int invalidate_list(struct list_head *head, struct super_block * sb, struct list_head * dispose) { struct list_head *next; int busy = 0; next = head->next; for (;;) { struct list_head * tmp = next; struct inode * inode; next = next->next; if (tmp == head) break; inode = list_entry(tmp, struct inode, i_list); if (inode->i_sb != sb) continue; if (!inode->i_count) { list_del(&inode->i_hash); INIT_LIST_HEAD(&inode->i_hash); list_del(&inode->i_list); list_add(&inode->i_list, dispose); inode->i_state |= I_FREEING; continue; } busy = 1; } return busy; } /* * This is a two-stage process. First we collect all * offending inodes onto the throw-away list, and in * the second stage we actually dispose of them. This * is because we don't want to sleep while messing * with the global lists.. */ int invalidate_inodes(struct super_block * sb) { int busy; LIST_HEAD(throw_away); spin_lock(&inode_lock); busy = invalidate_list(&inode_in_use, sb, &throw_away); busy |= invalidate_list(&sb->s_dirty, sb, &throw_away); dispose_list(&throw_away); spin_unlock(&inode_lock); return busy; } /* * This is called with the inode lock held. It searches * the in-use for freeable inodes, which are moved to a * temporary list and then placed on the unused list by * dispose_list. * * We don't expect to have to call this very often. * * N.B. The spinlock is released during the call to * dispose_list. */ #define CAN_UNUSE(inode) \ (((inode)->i_count | (inode)->i_state) == 0) #define INODE(entry) (list_entry(entry, struct inode, i_list)) static int free_inodes(void) { struct list_head list, *entry, *freeable = &list; int found = 0; INIT_LIST_HEAD(freeable); entry = inode_in_use.next; while (entry != &inode_in_use) { struct list_head *tmp = entry; entry = entry->next; if (!CAN_UNUSE(INODE(tmp))) continue; list_del(tmp); list_del(&INODE(tmp)->i_hash); INIT_LIST_HEAD(&INODE(tmp)->i_hash); list_add(tmp, freeable); list_entry(tmp, struct inode, i_list)->i_state = I_FREEING; found = 1; } if (found) dispose_list(freeable); return found; } /* * Searches the inodes list for freeable inodes, * shrinking the dcache before (and possible after, * if we're low) */ static void try_to_free_inodes(int goal) { /* * First stry to just get rid of unused inodes. * * If we can't reach our goal that way, we'll have * to try to shrink the dcache and sync existing * inodes.. */ free_inodes(); goal -= inodes_stat.nr_free_inodes; if (goal > 0) { spin_unlock(&inode_lock); select_dcache(goal, 0); prune_dcache(goal); spin_lock(&inode_lock); sync_all_inodes(); free_inodes(); } } /* * This is the externally visible routine for * inode memory management. */ void free_inode_memory(int goal) { spin_lock(&inode_lock); free_inodes(); spin_unlock(&inode_lock); } /* * This is called with the spinlock held, but releases * the lock when freeing or allocating inodes. * Look out! This returns with the inode lock held if * it got an inode.. * * We do inode allocations two pages at a time to reduce * fragmentation. */ #define INODE_PAGE_ORDER 1 #define INODE_ALLOCATION_SIZE (PAGE_SIZE << INODE_PAGE_ORDER) #define INODES_PER_ALLOCATION (INODE_ALLOCATION_SIZE/sizeof(struct inode)) static struct inode * grow_inodes(void) { struct inode * inode; /* * Check whether to restock the unused list. */ if (inodes_stat.nr_inodes > max_inodes) { struct list_head *tmp; try_to_free_inodes(inodes_stat.nr_inodes >> 2); tmp = inode_unused.next; if (tmp != &inode_unused) { inodes_stat.nr_free_inodes--; list_del(tmp); inode = list_entry(tmp, struct inode, i_list); return inode; } } spin_unlock(&inode_lock); inode = (struct inode *)__get_free_pages(GFP_KERNEL,INODE_PAGE_ORDER); if (inode) { int size; struct inode * tmp; size = INODE_ALLOCATION_SIZE - 2*sizeof(struct inode); tmp = inode; spin_lock(&inode_lock); do { tmp++; init_once(tmp); list_add(&tmp->i_list, &inode_unused); size -= sizeof(struct inode); } while (size >= 0); init_once(inode); /* * Update the inode statistics */ inodes_stat.nr_inodes += INODES_PER_ALLOCATION; inodes_stat.nr_free_inodes += INODES_PER_ALLOCATION - 1; return inode; } /* * If the allocation failed, do an extensive pruning of * the dcache and then try again to free some inodes. */ prune_dcache(inodes_stat.nr_inodes >> 2); spin_lock(&inode_lock); free_inodes(); { struct list_head *tmp = inode_unused.next; if (tmp != &inode_unused) { inodes_stat.nr_free_inodes--; list_del(tmp); inode = list_entry(tmp, struct inode, i_list); return inode; } } spin_unlock(&inode_lock); printk("grow_inodes: allocation failed\n"); return NULL; } /* * Called with the inode lock held. */ static struct inode * find_inode(struct super_block * sb, unsigned long ino, struct list_head *head) { struct list_head *tmp; struct inode * inode; tmp = head; for (;;) { tmp = tmp->next; inode = NULL; if (tmp == head) break; inode = list_entry(tmp, struct inode, i_hash); if (inode->i_sb != sb) continue; if (inode->i_ino != ino) continue; inode->i_count++; break; } return inode; } /* * This just initializes the inode fields * to known values before returning the inode.. * * i_sb, i_ino, i_count, i_state and the lists have * been initialized elsewhere.. */ void clean_inode(struct inode *inode) { memset(&inode->u, 0, sizeof(inode->u)); inode->i_sock = 0; inode->i_op = NULL; inode->i_nlink = 1; inode->i_writecount = 0; inode->i_size = 0; inode->i_generation = 0; memset(&inode->i_dquot, 0, sizeof(inode->i_dquot)); sema_init(&inode->i_sem, 1); } /* * This is called by things like the networking layer * etc that want to get an inode without any inode * number, or filesystems that allocate new inodes with * no pre-existing information. */ struct inode * get_empty_inode(void) { static unsigned long last_ino = 0; struct inode * inode; struct list_head * tmp; spin_lock(&inode_lock); tmp = inode_unused.next; if (tmp != &inode_unused) { list_del(tmp); inodes_stat.nr_free_inodes--; inode = list_entry(tmp, struct inode, i_list); add_new_inode: list_add(&inode->i_list, &inode_in_use); inode->i_sb = NULL; inode->i_dev = 0; inode->i_ino = ++last_ino; inode->i_flags = 0; inode->i_count = 1; inode->i_state = 0; spin_unlock(&inode_lock); clean_inode(inode); return inode; } /* * Warning: if this succeeded, we will now * return with the inode lock. */ inode = grow_inodes(); if (inode) goto add_new_inode; return inode; } /* * This is called with the inode lock held.. Be careful. * * We no longer cache the sb_flags in i_flags - see fs.h * -- rmk@arm.uk.linux.org */ static struct inode * get_new_inode(struct super_block *sb, unsigned long ino, struct list_head *head) { struct inode * inode; struct list_head * tmp = inode_unused.next; if (tmp != &inode_unused) { list_del(tmp); inodes_stat.nr_free_inodes--; inode = list_entry(tmp, struct inode, i_list); add_new_inode: list_add(&inode->i_list, &inode_in_use); list_add(&inode->i_hash, head); inode->i_sb = sb; inode->i_dev = sb->s_dev; inode->i_ino = ino; inode->i_flags = 0; inode->i_count = 1; inode->i_state = I_LOCK; spin_unlock(&inode_lock); clean_inode(inode); sb->s_op->read_inode(inode); /* * This is special! We do not need the spinlock * when clearing I_LOCK, because we're guaranteed * that nobody else tries to do anything about the * state of the inode when it is locked, as we * just created it (so there can be no old holders * that haven't tested I_LOCK). */ inode->i_state &= ~I_LOCK; wake_up(&inode->i_wait); return inode; } /* * We need to expand. Note that "grow_inodes()" will * release the spinlock, but will return with the lock * held again if the allocation succeeded. */ inode = grow_inodes(); if (inode) { /* We released the lock, so.. */ struct inode * old = find_inode(sb, ino, head); if (!old) goto add_new_inode; list_add(&inode->i_list, &inode_unused); inodes_stat.nr_free_inodes++; spin_unlock(&inode_lock); wait_on_inode(old); return old; } return inode; } static inline unsigned long hash(struct super_block *sb, unsigned long i_ino) { unsigned long tmp = i_ino | (unsigned long) sb; tmp = tmp + (tmp >> HASH_BITS) + (tmp >> HASH_BITS*2); return tmp & HASH_MASK; } /* Yeah, I know about quadratic hash. Maybe, later. */ ino_t iunique(struct super_block *sb, ino_t max_reserved) { static ino_t counter = 0; struct inode *inode; struct list_head * head; ino_t res; spin_lock(&inode_lock); retry: if (counter > max_reserved) { head = inode_hashtable + hash(sb,counter); inode = find_inode(sb, res = counter++, head); if (!inode) { spin_unlock(&inode_lock); return res; } inode->i_count--; /* compensate find_inode() */ } else { counter = max_reserved + 1; } goto retry; } struct inode *igrab(struct inode *inode) { spin_lock(&inode_lock); if (inode->i_state & I_FREEING) inode = NULL; else inode->i_count++; spin_unlock(&inode_lock); if (inode) wait_on_inode(inode); return inode; } struct inode *iget(struct super_block *sb, unsigned long ino) { struct list_head * head = inode_hashtable + hash(sb,ino); struct inode * inode; spin_lock(&inode_lock); inode = find_inode(sb, ino, head); if (inode) { spin_unlock(&inode_lock); wait_on_inode(inode); return inode; } /* * get_new_inode() will do the right thing, releasing * the inode lock and re-trying the search in case it * had to block at any point. */ return get_new_inode(sb, ino, head); } void insert_inode_hash(struct inode *inode) { struct list_head *head = inode_hashtable + hash(inode->i_sb, inode->i_ino); spin_lock(&inode_lock); list_add(&inode->i_hash, head); spin_unlock(&inode_lock); } void remove_inode_hash(struct inode *inode) { spin_lock(&inode_lock); list_del(&inode->i_hash); INIT_LIST_HEAD(&inode->i_hash); spin_unlock(&inode_lock); } void iput(struct inode *inode) { if (inode) { struct super_operations *op = NULL; if (inode->i_sb && inode->i_sb->s_op) op = inode->i_sb->s_op; if (op && op->put_inode) op->put_inode(inode); spin_lock(&inode_lock); if (!--inode->i_count) { if (!inode->i_nlink) { list_del(&inode->i_hash); INIT_LIST_HEAD(&inode->i_hash); list_del(&inode->i_list); INIT_LIST_HEAD(&inode->i_list); inode->i_state|=I_FREEING; if (op && op->delete_inode) { void (*delete)(struct inode *) = op->delete_inode; spin_unlock(&inode_lock); delete(inode); spin_lock(&inode_lock); } } if (list_empty(&inode->i_hash)) { list_del(&inode->i_list); INIT_LIST_HEAD(&inode->i_list); inode->i_state|=I_FREEING; spin_unlock(&inode_lock); clear_inode(inode); spin_lock(&inode_lock); list_add(&inode->i_list, &inode_unused); inodes_stat.nr_free_inodes++; } else if (!(inode->i_state & I_DIRTY)) { list_del(&inode->i_list); list_add(&inode->i_list, &inode_in_use); } #ifdef INODE_PARANOIA if (inode->i_flock) printk(KERN_ERR "iput: inode %s/%ld still has locks!\n", kdevname(inode->i_dev), inode->i_ino); if (!list_empty(&inode->i_dentry)) printk(KERN_ERR "iput: device %s inode %ld still has aliases!\n", kdevname(inode->i_dev), inode->i_ino); if (inode->i_count) printk(KERN_ERR "iput: device %s inode %ld count changed, count=%d\n", kdevname(inode->i_dev), inode->i_ino, inode->i_count); if (atomic_read(&inode->i_sem.count) != 1) printk(KERN_ERR "iput: Aieee, semaphore in use inode %s/%ld, count=%d\n", kdevname(inode->i_dev), inode->i_ino, atomic_read(&inode->i_sem.count)); if (atomic_read(&inode->i_atomic_write.count) != 1) printk(KERN_ERR "iput: Aieee, atomic write semaphore in use inode %s/%ld, count=%d\n", kdevname(inode->i_dev), inode->i_ino, atomic_read(&inode->i_sem.count)); #endif } if (inode->i_count > (1<<31)) { printk(KERN_ERR "iput: inode %s/%ld count wrapped\n", kdevname(inode->i_dev), inode->i_ino); } spin_unlock(&inode_lock); } } int bmap(struct inode * inode, int block) { if (inode->i_op && inode->i_op->bmap) return inode->i_op->bmap(inode, block); return 0; } /* * Initialize the hash tables and default * value for max inodes */ #define MAX_INODE (16384) void __init inode_init(void) { int i, max; struct list_head *head = inode_hashtable; i = HASH_SIZE; do { INIT_LIST_HEAD(head); head++; i--; } while (i); /* Initial guess at reasonable inode number */ max = num_physpages >> 1; if (max > MAX_INODE) max = MAX_INODE; max_inodes = max; } /* This belongs in file_table.c, not here... */ int fs_may_remount_ro(struct super_block *sb) { struct file *file; /* Check that no files are currently opened for writing. */ for (file = inuse_filps; file; file = file->f_next) { struct inode *inode; if (!file->f_dentry) continue; inode = file->f_dentry->d_inode; if (!inode || inode->i_sb != sb) continue; /* File with pending delete? */ if (inode->i_nlink == 0) return 0; /* Writable file? */ if (S_ISREG(inode->i_mode) && (file->f_mode & FMODE_WRITE)) return 0; } return 1; /* Tis' cool bro. */ } void update_atime (struct inode *inode) { if ( IS_NOATIME (inode) ) return; if ( IS_NODIRATIME (inode) && S_ISDIR (inode->i_mode) ) return; if ( IS_RDONLY (inode) ) return; inode->i_atime = CURRENT_TIME; mark_inode_dirty (inode); } /* End Function update_atime */ |