380 lines
12 KiB
C
380 lines
12 KiB
C
/* This file manages the super block table and the related data structures,
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* namely, the bit maps that keep track of which zones and which inodes are
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* allocated and which are free. When a new inode or zone is needed, the
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* appropriate bit map is searched for a free entry.
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*
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* The entry points into this file are
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* alloc_bit: somebody wants to allocate a zone or inode; find one
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* free_bit: indicate that a zone or inode is available for allocation
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* get_super: search the 'superblock' table for a device
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* mounted: tells if file inode is on mounted (or ROOT) file system
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* read_super: read a superblock
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*/
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#include "fs.h"
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#include <string.h>
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#include <assert.h>
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#include <minix/com.h>
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#include <minix/u64.h>
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#include <minix/bdev.h>
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#include <machine/param.h>
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#include <machine/vmparam.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 u32_t used_blocks = 0;
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/*===========================================================================*
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* alloc_bit *
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*===========================================================================*/
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bit_t alloc_bit(sp, map, origin)
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struct super_block *sp; /* the filesystem to allocate from */
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int map; /* IMAP (inode map) or ZMAP (zone map) */
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bit_t origin; /* number of bit to start searching at */
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{
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/* Allocate a bit from a bit map and return its bit number. */
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block_t start_block; /* first bit block */
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block_t block;
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bit_t map_bits; /* how many bits are there in the bit map? */
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short bit_blocks; /* how many blocks are there in the bit map? */
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unsigned word, bcount;
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struct buf *bp;
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bitchunk_t *wptr, *wlim, k;
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bit_t i, b;
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if (sp->s_rd_only)
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panic("can't allocate bit on read-only filesys");
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if (map == IMAP) {
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start_block = START_BLOCK;
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map_bits = (bit_t) (sp->s_ninodes + 1);
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bit_blocks = sp->s_imap_blocks;
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} else {
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start_block = START_BLOCK + sp->s_imap_blocks;
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map_bits = (bit_t) (sp->s_zones - (sp->s_firstdatazone - 1));
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bit_blocks = sp->s_zmap_blocks;
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}
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/* Figure out where to start the bit search (depends on 'origin'). */
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if (origin >= map_bits) origin = 0; /* for robustness */
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/* Locate the starting place. */
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block = (block_t) (origin / FS_BITS_PER_BLOCK(sp->s_block_size));
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word = (origin % FS_BITS_PER_BLOCK(sp->s_block_size)) / FS_BITCHUNK_BITS;
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/* Iterate over all blocks plus one, because we start in the middle. */
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bcount = bit_blocks + 1;
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do {
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bp = get_block(sp->s_dev, start_block + block, NORMAL);
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wlim = &b_bitmap(bp)[FS_BITMAP_CHUNKS(sp->s_block_size)];
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/* Iterate over the words in block. */
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for (wptr = &b_bitmap(bp)[word]; wptr < wlim; wptr++) {
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/* Does this word contain a free bit? */
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if (*wptr == (bitchunk_t) ~0) continue;
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/* Find and allocate the free bit. */
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k = (bitchunk_t) conv4(sp->s_native, (int) *wptr);
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for (i = 0; (k & (1 << i)) != 0; ++i) {}
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/* Bit number from the start of the bit map. */
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b = ((bit_t) block * FS_BITS_PER_BLOCK(sp->s_block_size))
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+ (wptr - &b_bitmap(bp)[0]) * FS_BITCHUNK_BITS
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+ i;
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/* Don't allocate bits beyond the end of the map. */
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if (b >= map_bits) break;
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/* Allocate and return bit number. */
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k |= 1 << i;
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*wptr = (bitchunk_t) conv4(sp->s_native, (int) k);
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MARKDIRTY(bp);
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put_block(bp, MAP_BLOCK);
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if(map == ZMAP) {
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used_blocks++;
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lmfs_blockschange(sp->s_dev, 1);
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}
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return(b);
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}
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put_block(bp, MAP_BLOCK);
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if (++block >= (unsigned int) bit_blocks) /* last block, wrap around */
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block = 0;
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word = 0;
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} while (--bcount > 0);
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return(NO_BIT); /* no bit could be allocated */
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}
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/*===========================================================================*
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* free_bit *
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*===========================================================================*/
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void free_bit(sp, map, bit_returned)
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struct super_block *sp; /* the filesystem to operate on */
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int map; /* IMAP (inode map) or ZMAP (zone map) */
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bit_t bit_returned; /* number of bit to insert into the map */
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{
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/* Return a zone or inode by turning off its bitmap bit. */
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unsigned block, word, bit;
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struct buf *bp;
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bitchunk_t k, mask;
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block_t start_block;
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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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if (map == IMAP) {
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start_block = START_BLOCK;
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} else {
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start_block = START_BLOCK + sp->s_imap_blocks;
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}
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block = bit_returned / FS_BITS_PER_BLOCK(sp->s_block_size);
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word = (bit_returned % FS_BITS_PER_BLOCK(sp->s_block_size))
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/ FS_BITCHUNK_BITS;
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bit = bit_returned % FS_BITCHUNK_BITS;
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mask = 1 << bit;
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bp = get_block(sp->s_dev, start_block + block, NORMAL);
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k = (bitchunk_t) conv4(sp->s_native, (int) b_bitmap(bp)[word]);
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if (!(k & mask)) {
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if (map == IMAP) panic("tried to free unused inode");
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else panic("tried to free unused block: %u", bit_returned);
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}
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k &= ~mask;
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b_bitmap(bp)[word] = (bitchunk_t) conv4(sp->s_native, (int) k);
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MARKDIRTY(bp);
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put_block(bp, MAP_BLOCK);
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if(map == ZMAP) {
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used_blocks--;
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lmfs_blockschange(sp->s_dev, -1);
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}
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}
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/*===========================================================================*
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* get_super *
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*===========================================================================*/
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struct super_block *get_super(
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dev_t dev /* device number whose super_block is sought */
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)
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{
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if (dev == NO_DEV)
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panic("request for super_block of NO_DEV");
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if(superblock.s_dev != dev)
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panic("wrong superblock: 0x%x", (int) dev);
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return(&superblock);
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}
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/*===========================================================================*
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* get_block_size *
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*===========================================================================*/
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unsigned int get_block_size(dev_t dev)
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{
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if (dev == NO_DEV)
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panic("request for block size of NO_DEV");
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return(lmfs_fs_block_size());
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}
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/*===========================================================================*
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* rw_super *
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*===========================================================================*/
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static int rw_super(struct super_block *sp, int writing)
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{
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/* Read/write a superblock. */
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int r;
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dev_t save_dev = sp->s_dev;
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struct buf *bp;
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char *sbbuf;
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/* To keep the 1kb on disk clean, only read/write up to and including
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* this field.
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*/
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#define LAST_ONDISK_FIELD s_disk_version
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int ondisk_bytes = (int) ((char *) &sp->LAST_ONDISK_FIELD - (char *) sp)
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+ sizeof(sp->LAST_ONDISK_FIELD);
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assert(ondisk_bytes > 0);
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assert(ondisk_bytes < PAGE_SIZE);
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assert(ondisk_bytes < sizeof(struct super_block));
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if (sp->s_dev == NO_DEV)
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panic("request for super_block of NO_DEV");
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/* we rely on the cache blocksize, before reading the
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* superblock, being big enough that our complete superblock
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* is in block 0.
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*
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* copy between the disk block and the superblock buffer (depending
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* on direction). mark the disk block dirty if the copy is into the
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* disk block.
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*/
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assert(lmfs_fs_block_size() >= sizeof(struct super_block) + SUPER_BLOCK_BYTES);
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assert(SUPER_BLOCK_BYTES >= sizeof(struct super_block));
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assert(SUPER_BLOCK_BYTES >= ondisk_bytes);
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if(!(bp = get_block(sp->s_dev, 0, NORMAL)))
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panic("get_block of superblock failed");
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/* sbbuf points to the disk block at the superblock offset */
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sbbuf = (char *) b_data(bp) + SUPER_BLOCK_BYTES;
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if(writing) {
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memset(b_data(bp), 0, lmfs_fs_block_size());
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memcpy(sbbuf, sp, ondisk_bytes);
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lmfs_markdirty(bp);
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} else {
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memset(sp, 0, sizeof(*sp));
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memcpy(sp, sbbuf, ondisk_bytes);
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sp->s_dev = save_dev;
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}
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put_block(bp, FULL_DATA_BLOCK);
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lmfs_flushall();
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return OK;
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}
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/*===========================================================================*
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* read_super *
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*===========================================================================*/
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int read_super(struct super_block *sp)
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{
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unsigned int magic;
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block_t offset;
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int version, native, r;
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if((r=rw_super(sp, 0)) != OK)
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return r;
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magic = sp->s_magic; /* determines file system type */
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if(magic == SUPER_V2 || magic == SUPER_MAGIC) {
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printf("MFS: only supports V3 filesystems.\n");
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return EINVAL;
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}
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/* Get file system version and type - only support v3. */
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if(magic != SUPER_V3) {
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return EINVAL;
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}
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version = V3;
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native = 1;
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/* If the super block has the wrong byte order, swap the fields; the magic
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* number doesn't need conversion. */
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sp->s_ninodes = (ino_t) conv4(native, (int) sp->s_ninodes);
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sp->s_nzones = (zone1_t) conv2(native, (int) sp->s_nzones);
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sp->s_imap_blocks = (short) conv2(native, (int) sp->s_imap_blocks);
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sp->s_zmap_blocks = (short) conv2(native, (int) sp->s_zmap_blocks);
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sp->s_firstdatazone_old =(zone1_t)conv2(native,(int)sp->s_firstdatazone_old);
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sp->s_log_zone_size = (short) conv2(native, (int) sp->s_log_zone_size);
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sp->s_max_size = (off_t) conv4(native, sp->s_max_size);
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sp->s_zones = (zone_t)conv4(native, sp->s_zones);
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/* Calculate some other numbers that depend on the version here too, to
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* hide some of the differences.
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*/
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assert(version == V3);
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sp->s_block_size = (unsigned short) conv2(native,(int) sp->s_block_size);
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if (sp->s_block_size < PAGE_SIZE) {
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return EINVAL;
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}
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sp->s_inodes_per_block = V2_INODES_PER_BLOCK(sp->s_block_size);
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sp->s_ndzones = V2_NR_DZONES;
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sp->s_nindirs = V2_INDIRECTS(sp->s_block_size);
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/* For even larger disks, a similar problem occurs with s_firstdatazone.
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* If the on-disk field contains zero, we assume that the value was too
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* large to fit, and compute it on the fly.
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*/
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if (sp->s_firstdatazone_old == 0) {
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offset = START_BLOCK + sp->s_imap_blocks + sp->s_zmap_blocks;
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offset += (sp->s_ninodes + sp->s_inodes_per_block - 1) /
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sp->s_inodes_per_block;
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sp->s_firstdatazone = (offset + (1 << sp->s_log_zone_size) - 1) >>
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sp->s_log_zone_size;
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} else {
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sp->s_firstdatazone = (zone_t) sp->s_firstdatazone_old;
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}
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if (sp->s_block_size < PAGE_SIZE)
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return(EINVAL);
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if ((sp->s_block_size % 512) != 0)
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return(EINVAL);
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if (SUPER_SIZE > sp->s_block_size)
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return(EINVAL);
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if ((sp->s_block_size % V2_INODE_SIZE) != 0) {
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return(EINVAL);
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}
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/* Limit s_max_size to LONG_MAX */
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if ((unsigned long)sp->s_max_size > LONG_MAX)
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sp->s_max_size = LONG_MAX;
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sp->s_isearch = 0; /* inode searches initially start at 0 */
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sp->s_zsearch = 0; /* zone searches initially start at 0 */
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sp->s_version = version;
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sp->s_native = native;
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/* Make a few basic checks to see if super block looks reasonable. */
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if (sp->s_imap_blocks < 1 || sp->s_zmap_blocks < 1
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|| sp->s_ninodes < 1 || sp->s_zones < 1
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|| sp->s_firstdatazone <= 4
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|| sp->s_firstdatazone >= sp->s_zones
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|| (unsigned) sp->s_log_zone_size > 4) {
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printf("not enough imap or zone map blocks, \n");
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printf("or not enough inodes, or not enough zones, \n"
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"or invalid first data zone, or zone size too large\n");
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return(EINVAL);
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}
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/* Check any flags we don't understand but are required to. Currently
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* these don't exist so all such unknown bits are fatal.
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*/
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if(sp->s_flags & MFSFLAG_MANDATORY_MASK) {
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printf("MFS: unsupported feature flags on this FS.\n"
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"Please use a newer MFS to mount it.\n");
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return(EINVAL);
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}
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return(OK);
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}
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/*===========================================================================*
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* write_super *
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*===========================================================================*/
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int write_super(struct super_block *sp)
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{
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if(sp->s_rd_only)
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panic("can't write superblock of readonly filesystem");
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return rw_super(sp, 1);
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}
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static int blocks_known = 0;
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u32_t get_used_blocks(struct super_block *sp)
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{
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if(!blocks_known) {
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/* how many blocks are in use? */
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used_blocks = sp->s_zones - count_free_bits(sp, ZMAP);
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blocks_known = 1;
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}
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return used_blocks;
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}
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