bd3cde4571
Add primary cache management feature to libminixfs as mfs and ext2 currently do separately, remove cache code from mfs and ext2, and make them use the libminixfs interface. This makes all fields of the buf struct private to libminixfs and FS clients aren't supposed to access them at all. Only the opaque 'void *data' field (the FS block contents, used to be called bp) is to be accessed by the FS client. The main purpose is to implement the interface to the 2ndary vm cache just once, get rid of some code duplication, and add a little abstraction to reduce the code inertia of the whole caching business. Some minor sanity checking and prohibition done by mfs in this code as removed from the generic primary cache code as a result: - checking all inodes are not in use when allocating/resizing the cache - checking readonly filesystems aren't written to - checking the superblock isn't written to on mounted filesystems The minixfslib code relies on fs_blockstats() in the client filesystem to return some FS usage information.
475 lines
13 KiB
C
475 lines
13 KiB
C
/* This files manages inodes allocation and deallocation.
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*
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* The entry points into this file are:
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* alloc_inode: allocate a new, unused inode.
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* free_inode: mark an inode as available for a new file.
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*
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* Created (alloc_inode/free_inode/wipe_inode are from MFS):
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* June 2010 (Evgeniy Ivanov)
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*/
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#include "fs.h"
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#include <string.h>
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#include <stdlib.h>
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#include <minix/com.h>
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#include <minix/u64.h>
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#include "buf.h"
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#include "inode.h"
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#include "super.h"
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#include "const.h"
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static bit_t alloc_inode_bit(struct super_block *sp, struct inode
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*parent, int is_dir);
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static void free_inode_bit(struct super_block *sp, bit_t bit_returned,
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int is_dir);
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static void wipe_inode(struct inode *rip);
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/*===========================================================================*
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* alloc_inode *
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*===========================================================================*/
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struct inode *alloc_inode(struct inode *parent, mode_t bits)
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{
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/* Allocate a free inode on parent's dev, and return a pointer to it. */
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register struct inode *rip;
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register struct super_block *sp;
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int inumb;
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bit_t b;
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static int print_oos_msg = 1;
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sp = get_super(parent->i_dev); /* get pointer to super_block */
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if (sp->s_rd_only) { /* can't allocate an inode on a read only device. */
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err_code = EROFS;
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return(NULL);
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}
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/* Acquire an inode from the bit map. */
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b = alloc_inode_bit(sp, parent, (bits & I_TYPE) == I_DIRECTORY);
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if (b == NO_BIT) {
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err_code = ENOSPC;
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if (print_oos_msg)
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ext2_debug("Out of i-nodes on device %d/%d\n",
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major(sp->s_dev), minor(sp->s_dev));
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print_oos_msg = 0; /* Don't repeat message */
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return(NULL);
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}
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print_oos_msg = 1;
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inumb = (int) b; /* be careful not to pass unshort as param */
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/* Try to acquire a slot in the inode table. */
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if ((rip = get_inode(NO_DEV, inumb)) == NULL) {
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/* No inode table slots available. Free the inode just allocated. */
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free_inode_bit(sp, b, (bits & I_TYPE) == I_DIRECTORY);
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} else {
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/* An inode slot is available. Put the inode just allocated into it. */
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rip->i_mode = bits; /* set up RWX bits */
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rip->i_links_count = NO_LINK; /* initial no links */
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rip->i_uid = caller_uid; /* file's uid is owner's */
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rip->i_gid = caller_gid; /* ditto group id */
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rip->i_dev = parent->i_dev; /* mark which device it is on */
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rip->i_sp = sp; /* pointer to super block */
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/* Fields not cleared already are cleared in wipe_inode(). They have
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* been put there because truncate() needs to clear the same fields if
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* the file happens to be open while being truncated. It saves space
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* not to repeat the code twice.
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*/
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wipe_inode(rip);
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}
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return(rip);
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}
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/*===========================================================================*
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* free_inode *
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*===========================================================================*/
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void free_inode(
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register struct inode *rip /* inode to free */
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)
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{
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/* Return an inode to the pool of unallocated inodes. */
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register struct super_block *sp;
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dev_t dev = rip->i_dev;
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bit_t b = rip->i_num;
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u16_t mode = rip->i_mode;
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/* Locate the appropriate super_block. */
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sp = get_super(dev);
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if (b <= NO_ENTRY || b > sp->s_inodes_count)
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return;
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free_inode_bit(sp, b, (mode & I_TYPE) == I_DIRECTORY);
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rip->i_mode = I_NOT_ALLOC; /* clear I_TYPE field */
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}
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static int find_group_dir(struct super_block *sp);
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static int find_group_hashalloc(struct super_block *sp, struct inode
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*parent);
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static int find_group_any(struct super_block *sp);
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static int find_group_orlov(struct super_block *sp, struct inode
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*parent);
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/*===========================================================================*
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* alloc_inode_bit *
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*===========================================================================*/
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static bit_t alloc_inode_bit(sp, parent, is_dir)
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struct super_block *sp; /* the filesystem to allocate from */
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struct inode *parent; /* parent of newly allocated inode */
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int is_dir; /* inode will be a directory if it is TRUE */
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{
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int group;
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ino_t inumber = NO_BIT;
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bit_t bit;
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struct buf *bp;
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struct group_desc *gd;
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if (sp->s_rd_only)
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panic("can't alloc inode on read-only filesys.");
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if (opt.mfsalloc) {
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group = find_group_any(sp);
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} else {
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if (is_dir) {
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if (opt.use_orlov) {
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group = find_group_orlov(sp, parent);
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} else {
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group = find_group_dir(sp);
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}
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} else {
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group = find_group_hashalloc(sp, parent);
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}
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}
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/* Check if we have a group where to allocate an inode */
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if (group == -1)
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return(NO_BIT); /* no bit could be allocated */
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gd = get_group_desc(group);
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if (gd == NULL)
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panic("can't get group_desc to alloc block");
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/* find_group_* should always return either a group with
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* a free inode slot or -1, which we checked earlier.
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*/
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ASSERT(gd->free_inodes_count);
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bp = get_block(sp->s_dev, gd->inode_bitmap, NORMAL);
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bit = setbit(b_bitmap(bp), sp->s_inodes_per_group, 0);
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ASSERT(bit != -1); /* group definitly contains free inode */
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inumber = group * sp->s_inodes_per_group + bit + 1;
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/* Extra checks before real allocation.
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* Only major bug can cause problems. Since setbit changed
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* bp->b_bitmap there is no way to recover from this bug.
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* Should never happen.
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*/
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if (inumber > sp->s_inodes_count) {
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panic("ext2: allocator returned inum greater, than\
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total number of inodes.\n");
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}
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if (inumber < EXT2_FIRST_INO(sp)) {
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panic("ext2: allocator tryed to use reserved inode.\n");
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}
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lmfs_markdirty(bp);
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put_block(bp, MAP_BLOCK);
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gd->free_inodes_count--;
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sp->s_free_inodes_count--;
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if (is_dir) {
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gd->used_dirs_count++;
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sp->s_dirs_counter++;
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}
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group_descriptors_dirty = 1;
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/* Almost the same as previous 'group' ASSERT */
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ASSERT(inumber != NO_BIT);
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return inumber;
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}
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/*===========================================================================*
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* free_inode_bit *
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*===========================================================================*/
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static void free_inode_bit(struct super_block *sp, bit_t bit_returned,
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int is_dir)
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{
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/* Return an inode by turning off its bitmap bit. */
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int group; /* group number of bit_returned */
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int bit; /* bit_returned number within its group */
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struct buf *bp;
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struct group_desc *gd;
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if (sp->s_rd_only)
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panic("can't free bit on read-only filesys.");
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/* At first search group, to which bit_returned belongs to
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* and figure out in what word bit is stored.
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*/
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if (bit_returned > sp->s_inodes_count ||
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bit_returned < EXT2_FIRST_INO(sp))
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panic("trying to free inode %d beyond inodes scope.", bit_returned);
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group = (bit_returned - 1) / sp->s_inodes_per_group;
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bit = (bit_returned - 1) % sp->s_inodes_per_group; /* index in bitmap */
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gd = get_group_desc(group);
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if (gd == NULL)
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panic("can't get group_desc to alloc block");
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bp = get_block(sp->s_dev, gd->inode_bitmap, NORMAL);
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if (unsetbit(b_bitmap(bp), bit))
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panic("Tried to free unused inode", bit_returned);
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lmfs_markdirty(bp);
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put_block(bp, MAP_BLOCK);
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gd->free_inodes_count++;
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sp->s_free_inodes_count++;
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if (is_dir) {
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gd->used_dirs_count--;
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sp->s_dirs_counter--;
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}
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group_descriptors_dirty = 1;
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if (group < sp->s_igsearch)
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sp->s_igsearch = group;
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}
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/* it's implemented very close to the linux' find_group_dir() */
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static int find_group_dir(struct super_block *sp)
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{
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int avefreei = sp->s_free_inodes_count / sp->s_groups_count;
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struct group_desc *gd, *best_gd = NULL;
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int group, best_group = -1;
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for (group = 0; group < sp->s_groups_count; ++group) {
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gd = get_group_desc(group);
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if (gd == NULL)
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panic("can't get group_desc to alloc inode");
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if (gd->free_inodes_count == 0)
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continue;
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if (gd->free_inodes_count < avefreei)
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continue;
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if (!best_gd ||
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gd->free_blocks_count > best_gd->free_blocks_count) {
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best_gd = gd;
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best_group = group;
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}
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}
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return best_group; /* group or -1 */
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}
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/* Analog of ffs_hashalloc() from *BSD.
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* 1) Check parent's for free inodes and blocks.
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* 2) Quadradically rehash on the group number.
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* 3) Make a linear search for free inode.
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*/
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static int find_group_hashalloc(struct super_block *sp, struct inode *parent)
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{
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int ngroups = sp->s_groups_count;
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struct group_desc *gd;
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int group, i;
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int parent_group = (parent->i_num - 1) / sp->s_inodes_per_group;
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/* Try to place new inode in its parent group */
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gd = get_group_desc(parent_group);
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if (gd == NULL)
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panic("can't get group_desc to alloc inode");
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if (gd->free_inodes_count && gd->free_blocks_count)
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return parent_group;
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/* We can't allocate inode in the parent's group.
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* Now we will try to place it in another blockgroup.
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* The main idea is still to keep files from the same
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* directory together and use different blockgroups for
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* files from another directory, which lives in the same
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* blockgroup as our parent.
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* Thus we will spread things on the disk.
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*/
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group = (parent_group + parent->i_num) % ngroups;
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/* Make quadratic probing to find a group with free inodes and blocks. */
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for (i = 1; i < ngroups; i <<= 1) {
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group += i;
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if (group >= ngroups)
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group -= ngroups;
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gd = get_group_desc(group);
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if (gd == NULL)
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panic("can't get group_desc to alloc inode");
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if (gd->free_inodes_count && gd->free_blocks_count)
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return group;
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}
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/* Still no group for new inode, try linear search.
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* Also check parent again (but for free inodes only).
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*/
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group = parent_group;
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for (i = 0; i < ngroups; i++, group++) {
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if (group >= ngroups)
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group = 0;
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gd = get_group_desc(group);
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if (gd == NULL)
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panic("can't get group_desc to alloc inode");
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if (gd->free_inodes_count)
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return group;
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}
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return -1;
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}
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/* Find first group which has free inode slot.
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* This is similar to what MFS does.
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*/
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static int find_group_any(struct super_block *sp)
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{
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int ngroups = sp->s_groups_count;
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struct group_desc *gd;
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int group = sp->s_igsearch;
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for (; group < ngroups; group++) {
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gd = get_group_desc(group);
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if (gd == NULL)
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panic("can't get group_desc to alloc inode");
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if (gd->free_inodes_count) {
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sp->s_igsearch = group;
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return group;
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}
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}
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return -1;
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}
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/* We try to spread first-level directories (i.e. directories in the root
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* or in the directory marked as TOPDIR).
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* If there are blockgroups with counts for blocks and inodes less than average
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* we return a group with lowest directory count. Otherwise we either
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* return a group with good free inodes and blocks counts or just a group
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* with free inode.
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*
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* For other directories we try to find a 'good' group, we consider a group as
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* a 'good' if it has enough blocks and inodes (greater than min_blocks and
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* min_inodes).
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*
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*/
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static int find_group_orlov(struct super_block *sp, struct inode *parent)
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{
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int avefreei = sp->s_free_inodes_count / sp->s_groups_count;
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int avefreeb = sp->s_free_blocks_count / sp->s_groups_count;
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int group = -1;
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int fallback_group = -1; /* Group with at least 1 free inode */
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struct group_desc *gd;
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int i;
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if (parent->i_num == ROOT_INODE ||
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parent->i_flags & EXT2_TOPDIR_FL) {
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int best_group = -1;
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int best_avefree_group = -1; /* Best value of avefreei/avefreeb */
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int best_ndir = sp->s_inodes_per_group;
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group = (unsigned int)random();
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for (i = 0; i < sp->s_groups_count; i++, group++) {
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if (group >= sp->s_groups_count)
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group = 0;
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gd = get_group_desc(group);
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if (gd == NULL)
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panic("can't get group_desc to alloc inode");
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if (gd->free_inodes_count == 0)
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continue;
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fallback_group = group;
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if (gd->free_inodes_count < avefreei ||
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gd->free_blocks_count < avefreeb)
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continue;
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best_avefree_group = group;
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if (gd->used_dirs_count >= best_ndir)
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continue;
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best_ndir = gd->used_dirs_count;
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best_group = group;
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}
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if (best_group >= 0)
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return best_group;
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if (best_avefree_group >= 0)
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return best_avefree_group;
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return fallback_group;
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} else {
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int parent_group = (parent->i_num - 1) / sp->s_inodes_per_group;
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/* 2 is kind of random thing for now,
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* but performance results are still good.
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*/
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int min_blocks = avefreeb / 2;
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int min_inodes = avefreei / 2;
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group = parent_group;
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for (i = 0; i < sp->s_groups_count; i++, group++) {
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if (group >= sp->s_groups_count)
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group = 0;
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gd = get_group_desc(group);
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if (gd == NULL)
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panic("can't get group_desc to alloc inode");
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if (gd->free_inodes_count == 0)
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continue;
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fallback_group = group;
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if (gd->free_inodes_count >= min_inodes &&
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gd->free_blocks_count >= min_blocks)
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return group;
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}
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return fallback_group;
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}
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return -1;
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}
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/*===========================================================================*
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* wipe_inode *
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*===========================================================================*/
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static void wipe_inode(
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register struct inode *rip /* the inode to be erased */
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)
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{
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/* Erase some fields in the inode. This function is called from alloc_inode()
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* when a new inode is to be allocated, and from truncate(), when an existing
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* inode is to be truncated.
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*/
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register int i;
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rip->i_size = 0;
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rip->i_update = ATIME | CTIME | MTIME; /* update all times later */
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rip->i_blocks = 0;
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rip->i_flags = 0;
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rip->i_generation = 0;
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rip->i_file_acl = 0;
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rip->i_dir_acl = 0;
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rip->i_faddr = 0;
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for (i = 0; i < EXT2_N_BLOCKS; i++)
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rip->i_block[i] = NO_BLOCK;
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rip->i_block[0] = NO_BLOCK;
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rip->i_dirt = IN_DIRTY;
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}
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