/*-
* Routine: inode_allocblk
*
* Purpose:
* Reserva un bloque de datos para el inodo dado.
* Conditions:
* dev debe corresponder a un gnordofs válido.
* sb debe apuntar a un superbloque válido.
* inode debe apuntar a un inodo válido.
* blk debe ser un valor no negativo y dentro del rango permitido.
* Returns:
* El número de bloque absoluto.
* -1 on error
*
*/
long
inode_allocblk(int dev, superblock_t * const sb,
inode_t * inode, long blk)
{
int i;
block_t *block;
long ablk, iblk;
if (blk < 0 | blk >= BLOCKS_PER_INODE)
return -1;
ablk = allocblk(dev, sb);
if (blk < N_DIRECT_BLOCKS)
inode->direct_blocks[blk] = ablk;
blk -= N_DIRECT_BLOCKS;
if (blk < N_SINGLE_INDIRECT_BLOCKS)
{
/* Asignar bloque indirecto si no lo está. */
iblk = inode->single_indirect_blocks;
if (unassigned_p(iblk))
{
iblk = allocblk(dev, sb);
if (iblk < 0)
{
freeblk(dev, sb, ablk);
return -1;
}
/* Marcar todas las entradas del indirecto como BLK_UNASSIGNED. */
block = getblk(dev, sb, iblk);
if (block < 0)
{
freeblk(dev, sb, ablk);
freeblk(dev, sb, iblk);
return -1;
}
for (i=0; i<N_SINGLE_INDIRECT_BLOCKS; i++)
*(long *) &(block->data[i*sizeof(long)]) = BLK_UNASSIGNED;
/* ¡Y salvar el maldito iblk! (¡¬¬)*/
writeblk(dev, sb, iblk, block);
inode->single_indirect_blocks = iblk;
}
/* Leer bloque indirecto. */
block = getblk(dev, sb, iblk);
if (block < 0)
return -1;
/* Escribir nueva referencia en el bloque indirecto. */
*(long *) &(block->data[blk*sizeof(long)]) = ablk;
writeblk(dev, sb, iblk, block);
free(block);
}
return ablk;
}
/*-
* Routine: ifree
*
* Purpose:
* Libera un inodo y lo añade a la lista de inodos libres.
* Si este inodo referencia a algún bloque de datos, también
* lo libera y lo añade a su lista correspondiente
* Conditions:
* dev debe corresponder a un gnordofs válido.
* sb debe apuntar a un superbloque válido.
* inode debe apuntar a un inodo.
* Returns:
* -1 on error.
*
*/
int
ifree(int dev, superblock_t * const sb, inode_t *inode)
{
int i, block;
DEBUG_VERBOSE(">> ifree(inode->n = %d)\n", inode->n);
for (i=0; i < N_DIRECT_BLOCKS; i++)
{
block = inode_getblk(dev, sb, inode, i);
if (!unassigned_p(block))
freeblk(dev, sb, block);
}
if (!unassigned_p(inode->single_indirect_blocks))
{
for (i=N_DIRECT_BLOCKS;
i < N_DIRECT_BLOCKS+N_SINGLE_INDIRECT_BLOCKS;
i++)
{
block = inode_getblk(dev, sb, inode, i);
if (!unassigned_p(block))
freeblk(dev, sb, block);
}
freeblk(dev, sb, inode->single_indirect_blocks);
}
if (sb->free_inode_index == FREE_INODE_LIST_SIZE)
{
DEBUG_VERBOSE(">> ialloc >> Lista de inodos libres llena...");
/* Si la lista está vacía y el nuevo inodo libre es anterior al
primero de esta lista, insertarlo (reemplazando) en dicha posición. */
if (sb->free_inode_list[0] > inode->n)
{
DEBUG_VERBOSE(" reemplazando primera entrada.");
sb->free_inode_list[0] = inode->n;
}
}
else
{
/* Si no, añadirlo a ella e incrementar el índice. */
sb->free_inode_list[sb->free_inode_index] = inode->n;
sb->free_inode_index++;
}
inode->type = I_FREE;
iput(dev, sb, inode);
/* Incrementar contador de inodos libres. */
sb->free_inodes++;
return 0;
}
/*
* Attempt to expand the size of a directory
*/
static int
expanddir(struct ext2fs_dinode *dp, char *name)
{
daddr_t lastbn, newblk;
struct bufarea *bp;
char *firstblk;
lastbn = lblkno(&sblock, inosize(dp));
if (lastbn >= NDADDR - 1 || fs2h32(dp->e2di_blocks[lastbn]) == 0 ||
inosize(dp) == 0) {
return (0);
}
if ((newblk = allocblk()) == 0) {
return (0);
}
dp->e2di_blocks[lastbn + 1] = dp->e2di_blocks[lastbn];
dp->e2di_blocks[lastbn] = h2fs32(newblk);
inossize(dp, inosize(dp) + sblock.e2fs_bsize);
dp->e2di_nblock = h2fs32(fs2h32(dp->e2di_nblock) + 1);
bp = getdirblk(fs2h32(dp->e2di_blocks[lastbn + 1]),
sblock.e2fs_bsize);
if (bp->b_errs)
goto bad;
if ((firstblk = malloc(sblock.e2fs_bsize)) == NULL)
err(8, "cannot allocate first block");
memcpy(firstblk, bp->b_un.b_buf, sblock.e2fs_bsize);
bp = getdirblk(newblk, sblock.e2fs_bsize);
if (bp->b_errs) {
free(firstblk);
goto bad;
}
memcpy(bp->b_un.b_buf, firstblk, sblock.e2fs_bsize);
free(firstblk);
dirty(bp);
bp = getdirblk(fs2h32(dp->e2di_blocks[lastbn + 1]),
sblock.e2fs_bsize);
if (bp->b_errs)
goto bad;
emptydir.dot_reclen = h2fs16(sblock.e2fs_bsize);
memcpy(bp->b_un.b_buf, &emptydir, sizeof emptydir);
pwarn("NO SPACE LEFT IN %s", name);
if (preen)
printf(" (EXPANDED)\n");
else if (reply("EXPAND") == 0)
goto bad;
dirty(bp);
inodirty();
return (1);
bad:
dp->e2di_blocks[lastbn] = dp->e2di_blocks[lastbn + 1];
dp->e2di_blocks[lastbn + 1] = 0;
inossize(dp, inosize(dp) - sblock.e2fs_bsize);
dp->e2di_nblock = h2fs32(fs2h32(dp->e2di_nblock) - 1);
freeblk(newblk);
return (0);
}
/*
* Attempt to expand the size of a directory
*/
static int
expanddir(union dinode *dp, char *name)
{
ufs2_daddr_t lastbn, newblk;
struct bufarea *bp;
char *cp, firstblk[DIRBLKSIZ];
lastbn = lblkno(&sblock, DIP(dp, di_size));
if (lastbn >= NDADDR - 1 || DIP(dp, di_db[lastbn]) == 0 ||
DIP(dp, di_size) == 0)
return (0);
if ((newblk = allocblk(sblock.fs_frag)) == 0)
return (0);
DIP_SET(dp, di_db[lastbn + 1], DIP(dp, di_db[lastbn]));
DIP_SET(dp, di_db[lastbn], newblk);
DIP_SET(dp, di_size, DIP(dp, di_size) + sblock.fs_bsize);
DIP_SET(dp, di_blocks, DIP(dp, di_blocks) + btodb(sblock.fs_bsize));
bp = getdirblk(DIP(dp, di_db[lastbn + 1]),
sblksize(&sblock, DIP(dp, di_size), lastbn + 1));
if (bp->b_errs)
goto bad;
memmove(firstblk, bp->b_un.b_buf, DIRBLKSIZ);
bp = getdirblk(newblk, sblock.fs_bsize);
if (bp->b_errs)
goto bad;
memmove(bp->b_un.b_buf, firstblk, DIRBLKSIZ);
for (cp = &bp->b_un.b_buf[DIRBLKSIZ];
cp < &bp->b_un.b_buf[sblock.fs_bsize];
cp += DIRBLKSIZ)
memmove(cp, &emptydir, sizeof emptydir);
dirty(bp);
bp = getdirblk(DIP(dp, di_db[lastbn + 1]),
sblksize(&sblock, DIP(dp, di_size), lastbn + 1));
if (bp->b_errs)
goto bad;
memmove(bp->b_un.b_buf, &emptydir, sizeof emptydir);
pwarn("NO SPACE LEFT IN %s", name);
if (preen)
printf(" (EXPANDED)\n");
else if (reply("EXPAND") == 0)
goto bad;
dirty(bp);
inodirty();
return (1);
bad:
DIP_SET(dp, di_db[lastbn], DIP(dp, di_db[lastbn + 1]));
DIP_SET(dp, di_db[lastbn + 1], 0);
DIP_SET(dp, di_size, DIP(dp, di_size) - sblock.fs_bsize);
DIP_SET(dp, di_blocks, DIP(dp, di_blocks) - btodb(sblock.fs_bsize));
freeblk(newblk, sblock.fs_frag);
return (0);
}
/* F_trunc frees all the blocks associated with the file, if it
* is a disk file.
*/
void f_trunc(inoptr ino)
{
uint16_t dev;
int8_t j;
dev = ino->c_dev;
/* First deallocate the double indirect blocks */
freeblk(dev, ino->c_node.i_addr[19], 2);
/* Also deallocate the indirect blocks */
freeblk(dev, ino->c_node.i_addr[18], 1);
/* Finally, free the direct blocks */
for(j=17; j >= 0; --j)
freeblk(dev, ino->c_node.i_addr[j], 0);
memset((char *)ino->c_node.i_addr, 0, sizeof(ino->c_node.i_addr));
ino->c_dirty = true;
ino->c_node.i_size = 0;
}
/*
* Attempt to expand the size of a directory
*/
static int
expanddir(struct ufs1_dinode *dp, char *name)
{
ufs_daddr_t lastbn, newblk;
struct bufarea *bp;
char *cp, firstblk[DIRBLKSIZ];
lastbn = lblkno(&sblock, dp->di_size);
if (lastbn >= NDADDR - 1 || dp->di_db[lastbn] == 0 || dp->di_size == 0)
return (0);
if ((newblk = allocblk(sblock.fs_frag)) == 0)
return (0);
dp->di_db[lastbn + 1] = dp->di_db[lastbn];
dp->di_db[lastbn] = newblk;
dp->di_size += sblock.fs_bsize;
dp->di_blocks += btodb(sblock.fs_bsize);
bp = getdirblk(dp->di_db[lastbn + 1],
(long)dblksize(&sblock, dp, lastbn + 1));
if (bp->b_errs)
goto bad;
memmove(firstblk, bp->b_un.b_buf, DIRBLKSIZ);
bp = getdirblk(newblk, sblock.fs_bsize);
if (bp->b_errs)
goto bad;
memmove(bp->b_un.b_buf, firstblk, DIRBLKSIZ);
for (cp = &bp->b_un.b_buf[DIRBLKSIZ];
cp < &bp->b_un.b_buf[sblock.fs_bsize];
cp += DIRBLKSIZ)
memmove(cp, &emptydir, sizeof emptydir);
dirty(bp);
bp = getdirblk(dp->di_db[lastbn + 1],
(long)dblksize(&sblock, dp, lastbn + 1));
if (bp->b_errs)
goto bad;
memmove(bp->b_un.b_buf, &emptydir, sizeof emptydir);
pwarn("NO SPACE LEFT IN %s", name);
if (preen)
printf(" (EXPANDED)\n");
else if (reply("EXPAND") == 0)
goto bad;
dirty(bp);
inodirty();
return (1);
bad:
dp->di_db[lastbn] = dp->di_db[lastbn + 1];
dp->di_db[lastbn + 1] = 0;
dp->di_size -= sblock.fs_bsize;
dp->di_blocks -= btodb(sblock.fs_bsize);
freeblk(newblk, sblock.fs_frag);
return (0);
}
/* Companion function to f_trunc(). */
void freeblk(uint16_t dev, blkno_t blk, uint8_t level)
{
blkno_t *buf;
int8_t j;
if(!blk)
return;
if(level){
buf = (blkno_t *)bread(dev, blk, 0);
for(j=255; j >= 0; --j)
freeblk(dev, buf[j], level-1);
brelse((char *)buf);
}
blk_free(dev, blk);
}
/*-
* Routine: inode_truncate
*
* Purpose:
* Trunca un archivo a partir de su inodo.
* Conditions:
* dev debe corresponder a un gnordofs válido.
* sb debe apuntar a un superbloque válido.
* inode debe apuntar a un inodo válido.
* size debe ser no-negativo.
* Returns:
* -1 on error.
*
*/
int
inode_truncate(int dev, superblock_t * const sb, inode_t *inode, int size)
{
int blk, last_blk;
int absolute_blk;
if (size < 0)
return -1;
/* Para truncar al alza, tan sólo hay que tocar el campo size del inodo. */
if (size >= inode->size)
{
if (size > inode->size)
inode->size = size;
return 0;
}
/* Para truncar de toda la vida, hay que liberar los bloques que quedan fuera
tras meter las tijeras. */
/* Calcular último bloque interno que hay que liberar. */
last_blk = (inode->size-1) / sizeof(struct block);
/* Calcular primer bloque interno que hay que liberar. */
blk = size ? (size-1)/sizeof(struct block) : 0;
while (blk <= last_blk)
{
absolute_blk = inode_getblk(dev, sb, inode, blk);
if (absolute_blk == -1)
return -1;
if (!unassigned_p(absolute_blk))
{
if (freeblk(dev, sb, absolute_blk) < 0)
return -1;
inode_freeblk(dev, sb, inode, blk);
}
blk++;
}
inode->size = size;
return 0;
}
/*
* Scan each entry in a directory block.
*/
int
dirscan(struct inodesc *idesc)
{
struct direct *dp;
struct bufarea *bp;
int dsize, n;
long blksiz;
#if DIRBLKSIZ > APPLEUFS_DIRBLKSIZ
char dbuf[DIRBLKSIZ];
#else
char dbuf[APPLEUFS_DIRBLKSIZ];
#endif
if (idesc->id_type != DATA)
errexit("wrong type to dirscan %d", idesc->id_type);
if (idesc->id_entryno == 0 &&
(idesc->id_filesize & (dirblksiz - 1)) != 0)
idesc->id_filesize = roundup(idesc->id_filesize, dirblksiz);
blksiz = idesc->id_numfrags * sblock->fs_fsize;
if (chkrange(idesc->id_blkno, idesc->id_numfrags)) {
idesc->id_filesize -= blksiz;
return (SKIP);
}
/*
* If we are are swapping byte order in directory entries, just swap
* this block and return.
*/
if (do_dirswap) {
int off;
bp = getdirblk(idesc->id_blkno, blksiz);
for (off = 0; off < blksiz; off += iswap16(dp->d_reclen)) {
dp = (struct direct *)(bp->b_un.b_buf + off);
dp->d_ino = bswap32(dp->d_ino);
dp->d_reclen = bswap16(dp->d_reclen);
if (!newinofmt) {
u_int8_t tmp = dp->d_namlen;
dp->d_namlen = dp->d_type;
dp->d_type = tmp;
}
if (dp->d_reclen == 0)
break;
}
dirty(bp);
idesc->id_filesize -= blksiz;
return (idesc->id_filesize > 0 ? KEEPON : STOP);
}
idesc->id_loc = 0;
for (dp = fsck_readdir(idesc); dp != NULL; dp = fsck_readdir(idesc)) {
dsize = iswap16(dp->d_reclen);
if (dsize > sizeof dbuf)
dsize = sizeof dbuf;
memmove(dbuf, dp, (size_t)dsize);
# if (BYTE_ORDER == LITTLE_ENDIAN)
if (!newinofmt && !needswap) {
# else
if (!newinofmt && needswap) {
# endif
struct direct *tdp = (struct direct *)dbuf;
u_char tmp;
tmp = tdp->d_namlen;
tdp->d_namlen = tdp->d_type;
tdp->d_type = tmp;
}
idesc->id_dirp = (struct direct *)dbuf;
if ((n = (*idesc->id_func)(idesc)) & ALTERED) {
# if (BYTE_ORDER == LITTLE_ENDIAN)
if (!newinofmt && !doinglevel2 && !needswap) {
# else
if (!newinofmt && !doinglevel2 && needswap) {
# endif
struct direct *tdp;
u_char tmp;
tdp = (struct direct *)dbuf;
tmp = tdp->d_namlen;
tdp->d_namlen = tdp->d_type;
tdp->d_type = tmp;
}
bp = getdirblk(idesc->id_blkno, blksiz);
memmove(bp->b_un.b_buf + idesc->id_loc - dsize, dbuf,
(size_t)dsize);
dirty(bp);
sbdirty();
}
if (n & STOP)
return (n);
}
return (idesc->id_filesize > 0 ? KEEPON : STOP);
}
/*
* get next entry in a directory.
*/
static struct direct *
fsck_readdir(struct inodesc *idesc)
{
struct direct *dp, *ndp;
struct bufarea *bp;
long size, blksiz, fix, dploc;
blksiz = idesc->id_numfrags * sblock->fs_fsize;
bp = getdirblk(idesc->id_blkno, blksiz);
if (idesc->id_loc % dirblksiz == 0 && idesc->id_filesize > 0 &&
idesc->id_loc < blksiz) {
dp = (struct direct *)(bp->b_un.b_buf + idesc->id_loc);
if (dircheck(idesc, dp))
goto dpok;
if (idesc->id_fix == IGNORE)
return (0);
fix = dofix(idesc, "DIRECTORY CORRUPTED");
bp = getdirblk(idesc->id_blkno, blksiz);
dp = (struct direct *)(bp->b_un.b_buf + idesc->id_loc);
dp->d_reclen = iswap16(dirblksiz);
dp->d_ino = 0;
dp->d_type = 0;
dp->d_namlen = 0;
dp->d_name[0] = '\0';
if (fix)
dirty(bp);
else
markclean = 0;
idesc->id_loc += dirblksiz;
idesc->id_filesize -= dirblksiz;
return (dp);
}
dpok:
if (idesc->id_filesize <= 0 || idesc->id_loc >= blksiz)
return NULL;
dploc = idesc->id_loc;
dp = (struct direct *)(bp->b_un.b_buf + dploc);
idesc->id_loc += iswap16(dp->d_reclen);
idesc->id_filesize -= iswap16(dp->d_reclen);
if ((idesc->id_loc % dirblksiz) == 0)
return (dp);
ndp = (struct direct *)(bp->b_un.b_buf + idesc->id_loc);
if (idesc->id_loc < blksiz && idesc->id_filesize > 0 &&
dircheck(idesc, ndp) == 0) {
size = dirblksiz - (idesc->id_loc % dirblksiz);
idesc->id_loc += size;
idesc->id_filesize -= size;
if (idesc->id_fix == IGNORE)
return (0);
fix = dofix(idesc, "DIRECTORY CORRUPTED");
bp = getdirblk(idesc->id_blkno, blksiz);
dp = (struct direct *)(bp->b_un.b_buf + dploc);
dp->d_reclen = iswap16(iswap16(dp->d_reclen) + size);
if (fix)
dirty(bp);
else
markclean = 0;
}
return (dp);
}
/*
* Verify that a directory entry is valid.
* This is a superset of the checks made in the kernel.
*/
static int
dircheck(struct inodesc *idesc, struct direct *dp)
{
int size;
char *cp;
u_char namlen, type;
int spaceleft;
spaceleft = dirblksiz - (idesc->id_loc % dirblksiz);
if (iswap32(dp->d_ino) >= maxino ||
dp->d_reclen == 0 ||
iswap16(dp->d_reclen) > spaceleft ||
(iswap16(dp->d_reclen) & 0x3) != 0)
return (0);
if (dp->d_ino == 0)
return (1);
size = DIRSIZ(!newinofmt, dp, needswap);
# if (BYTE_ORDER == LITTLE_ENDIAN)
if (!newinofmt && !needswap) {
# else
if (!newinofmt && needswap) {
# endif
type = dp->d_namlen;
namlen = dp->d_type;
} else {
namlen = dp->d_namlen;
type = dp->d_type;
}
if (iswap16(dp->d_reclen) < size ||
idesc->id_filesize < size ||
/* namlen > MAXNAMLEN || */
type > 15)
return (0);
for (cp = dp->d_name, size = 0; size < namlen; size++)
if (*cp == '\0' || (*cp++ == '/'))
return (0);
if (*cp != '\0')
return (0);
return (1);
}
void
direrror(ino_t ino, const char *errmesg)
{
fileerror(ino, ino, errmesg);
}
void
fileerror(ino_t cwd, ino_t ino, const char *errmesg)
{
union dinode *dp;
char pathbuf[MAXPATHLEN + 1];
uint16_t mode;
pwarn("%s ", errmesg);
pinode(ino);
printf("\n");
getpathname(pathbuf, sizeof(pathbuf), cwd, ino);
if (ino < ROOTINO || ino > maxino) {
pfatal("NAME=%s\n", pathbuf);
return;
}
dp = ginode(ino);
if (ftypeok(dp)) {
mode = DIP(dp, mode);
pfatal("%s=%s\n",
(iswap16(mode) & IFMT) == IFDIR ? "DIR" : "FILE", pathbuf);
}
else
pfatal("NAME=%s\n", pathbuf);
}
void
adjust(struct inodesc *idesc, int lcnt)
{
union dinode *dp;
int16_t nlink;
int saveresolved;
dp = ginode(idesc->id_number);
nlink = iswap16(DIP(dp, nlink));
if (nlink == lcnt) {
/*
* If we have not hit any unresolved problems, are running
* in preen mode, and are on a file system using soft updates,
* then just toss any partially allocated files.
*/
if (resolved && preen && usedsoftdep) {
clri(idesc, "UNREF", 1);
return;
} else {
/*
* The file system can be marked clean even if
* a file is not linked up, but is cleared.
* Hence, resolved should not be cleared when
* linkup is answered no, but clri is answered yes.
*/
saveresolved = resolved;
if (linkup(idesc->id_number, (ino_t)0, NULL) == 0) {
resolved = saveresolved;
clri(idesc, "UNREF", 0);
return;
}
/*
* Account for the new reference created by linkup().
*/
dp = ginode(idesc->id_number);
lcnt--;
}
}
if (lcnt != 0) {
pwarn("LINK COUNT %s", (lfdir == idesc->id_number) ? lfname :
((iswap16(DIP(dp, mode)) & IFMT) == IFDIR ?
"DIR" : "FILE"));
pinode(idesc->id_number);
printf(" COUNT %d SHOULD BE %d",
nlink, nlink - lcnt);
if (preen || usedsoftdep) {
if (lcnt < 0) {
printf("\n");
pfatal("LINK COUNT INCREASING");
}
if (preen)
printf(" (ADJUSTED)\n");
}
if (preen || reply("ADJUST") == 1) {
DIP_SET(dp, nlink, iswap16(nlink - lcnt));
inodirty();
} else
markclean = 0;
}
}
static int
mkentry(struct inodesc *idesc)
{
struct direct *dirp = idesc->id_dirp;
struct direct newent;
int newlen, oldlen;
newent.d_namlen = strlen(idesc->id_name);
newlen = DIRSIZ(0, &newent, 0);
if (dirp->d_ino != 0)
oldlen = DIRSIZ(0, dirp, 0);
else
oldlen = 0;
if (iswap16(dirp->d_reclen) - oldlen < newlen)
return (KEEPON);
newent.d_reclen = iswap16(iswap16(dirp->d_reclen) - oldlen);
dirp->d_reclen = iswap16(oldlen);
dirp = (struct direct *)(((char *)dirp) + oldlen);
/* ino to be entered is in id_parent */
dirp->d_ino = iswap32(idesc->id_parent);
dirp->d_reclen = newent.d_reclen;
if (newinofmt)
dirp->d_type = inoinfo(idesc->id_parent)->ino_type;
else
dirp->d_type = 0;
dirp->d_namlen = newent.d_namlen;
memmove(dirp->d_name, idesc->id_name, (size_t)newent.d_namlen + 1);
# if (BYTE_ORDER == LITTLE_ENDIAN)
/*
* If the entry was split, dirscan() will only reverse the byte
* order of the original entry, and not the new one, before
* writing it back out. So, we reverse the byte order here if
* necessary.
*/
if (oldlen != 0 && !newinofmt && !doinglevel2 && !needswap) {
# else
if (oldlen != 0 && !newinofmt && !doinglevel2 && needswap) {
# endif
u_char tmp;
tmp = dirp->d_namlen;
dirp->d_namlen = dirp->d_type;
dirp->d_type = tmp;
}
return (ALTERED|STOP);
}
static int
chgino(struct inodesc *idesc)
{
struct direct *dirp = idesc->id_dirp;
if (memcmp(dirp->d_name, idesc->id_name, (int)dirp->d_namlen + 1))
return (KEEPON);
dirp->d_ino = iswap32(idesc->id_parent);
if (newinofmt)
dirp->d_type = inoinfo(idesc->id_parent)->ino_type;
else
dirp->d_type = 0;
return (ALTERED|STOP);
}
int
linkup(ino_t orphan, ino_t parentdir, char *name)
{
union dinode *dp;
int lostdir;
ino_t oldlfdir;
struct inodesc idesc;
char tempname[BUFSIZ];
int16_t nlink;
uint16_t mode;
memset(&idesc, 0, sizeof(struct inodesc));
dp = ginode(orphan);
mode = iswap16(DIP(dp, mode));
nlink = iswap16(DIP(dp, nlink));
lostdir = (mode & IFMT) == IFDIR;
pwarn("UNREF %s ", lostdir ? "DIR" : "FILE");
pinode(orphan);
if (preen && DIP(dp, size) == 0)
return (0);
if (preen)
printf(" (RECONNECTED)\n");
else
if (reply("RECONNECT") == 0) {
markclean = 0;
return (0);
}
if (parentdir != 0)
inoinfo(parentdir)->ino_linkcnt++;
if (lfdir == 0) {
dp = ginode(ROOTINO);
idesc.id_name = lfname;
idesc.id_type = DATA;
idesc.id_func = findino;
idesc.id_number = ROOTINO;
if ((ckinode(dp, &idesc) & FOUND) != 0) {
lfdir = idesc.id_parent;
} else {
pwarn("NO lost+found DIRECTORY");
if (preen || reply("CREATE")) {
lfdir = allocdir(ROOTINO, (ino_t)0, lfmode);
if (lfdir != 0) {
if (makeentry(ROOTINO, lfdir, lfname) != 0) {
numdirs++;
if (preen)
printf(" (CREATED)\n");
} else {
freedir(lfdir, ROOTINO);
lfdir = 0;
if (preen)
printf("\n");
}
}
if (lfdir != 0) {
reparent(lfdir, ROOTINO);
}
}
}
if (lfdir == 0) {
pfatal("SORRY. CANNOT CREATE lost+found DIRECTORY\n\n");
markclean = 0;
return (0);
}
}
dp = ginode(lfdir);
mode = DIP(dp, mode);
mode = iswap16(mode);
if ((mode & IFMT) != IFDIR) {
pfatal("lost+found IS NOT A DIRECTORY");
if (reply("REALLOCATE") == 0) {
markclean = 0;
return (0);
}
oldlfdir = lfdir;
lfdir = allocdir(ROOTINO, (ino_t)0, lfmode);
if (lfdir == 0) {
pfatal("SORRY. CANNOT CREATE lost+found DIRECTORY\n\n");
markclean = 0;
return (0);
}
if ((changeino(ROOTINO, lfname, lfdir) & ALTERED) == 0) {
pfatal("SORRY. CANNOT CREATE lost+found DIRECTORY\n\n");
markclean = 0;
return (0);
}
inodirty();
reparent(lfdir, ROOTINO);
idesc.id_type = ADDR;
idesc.id_func = pass4check;
idesc.id_number = oldlfdir;
adjust(&idesc, inoinfo(oldlfdir)->ino_linkcnt + 1);
inoinfo(oldlfdir)->ino_linkcnt = 0;
dp = ginode(lfdir);
}
if (inoinfo(lfdir)->ino_state != DFOUND) {
pfatal("SORRY. NO lost+found DIRECTORY\n\n");
markclean = 0;
return (0);
}
(void)lftempname(tempname, orphan);
if (makeentry(lfdir, orphan, (name ? name : tempname)) == 0) {
pfatal("SORRY. NO SPACE IN lost+found DIRECTORY");
printf("\n\n");
markclean = 0;
return (0);
}
inoinfo(orphan)->ino_linkcnt--;
if (lostdir) {
if ((changeino(orphan, "..", lfdir) & ALTERED) == 0 &&
parentdir != (ino_t)-1)
(void)makeentry(orphan, lfdir, "..");
dp = ginode(lfdir);
nlink = DIP(dp, nlink);
DIP_SET(dp, nlink, iswap16(iswap16(nlink) + 1));
inodirty();
inoinfo(lfdir)->ino_linkcnt++;
reparent(orphan, lfdir);
pwarn("DIR I=%llu CONNECTED. ", (unsigned long long)orphan);
if (parentdir != (ino_t)-1)
printf("PARENT WAS I=%llu\n",
(unsigned long long)parentdir);
if (preen == 0)
printf("\n");
}
return (1);
}
/*
* fix an entry in a directory.
*/
int
changeino(ino_t dir, const char *name, ino_t newnum)
{
struct inodesc idesc;
memset(&idesc, 0, sizeof(struct inodesc));
idesc.id_type = DATA;
idesc.id_func = chgino;
idesc.id_number = dir;
idesc.id_fix = DONTKNOW;
idesc.id_name = name;
idesc.id_parent = newnum; /* new value for name */
return (ckinode(ginode(dir), &idesc));
}
/*
* make an entry in a directory
*/
int
makeentry(ino_t parent, ino_t ino, const char *name)
{
union dinode *dp;
struct inodesc idesc;
char pathbuf[MAXPATHLEN + 1];
if (parent < ROOTINO || parent >= maxino ||
ino < ROOTINO || ino >= maxino)
return (0);
memset(&idesc, 0, sizeof(struct inodesc));
idesc.id_type = DATA;
idesc.id_func = mkentry;
idesc.id_number = parent;
idesc.id_parent = ino; /* this is the inode to enter */
idesc.id_fix = DONTKNOW;
idesc.id_name = name;
dp = ginode(parent);
if (iswap64(DIP(dp, size)) % dirblksiz) {
DIP_SET(dp, size,
iswap64(roundup(iswap64(DIP(dp, size)), dirblksiz)));
inodirty();
}
if ((ckinode(dp, &idesc) & ALTERED) != 0)
return (1);
getpathname(pathbuf, sizeof(pathbuf), parent, parent);
dp = ginode(parent);
if (expanddir(dp, pathbuf) == 0)
return (0);
return (ckinode(dp, &idesc) & ALTERED);
}
/*
* Attempt to expand the size of a directory
*/
static int
expanddir(union dinode *dp, char *name)
{
daddr_t lastbn, newblk, dirblk;
struct bufarea *bp;
char *cp;
#if DIRBLKSIZ > APPLEUFS_DIRBLKSIZ
char firstblk[DIRBLKSIZ];
#else
char firstblk[APPLEUFS_DIRBLKSIZ];
#endif
struct ufs1_dinode *dp1 = NULL;
struct ufs2_dinode *dp2 = NULL;
if (is_ufs2)
dp2 = &dp->dp2;
else
dp1 = &dp->dp1;
lastbn = lblkno(sblock, iswap64(DIP(dp, size)));
if (lastbn >= NDADDR - 1 || DIP(dp, db[lastbn]) == 0 ||
DIP(dp, size) == 0)
return (0);
if ((newblk = allocblk(sblock->fs_frag)) == 0)
return (0);
if (is_ufs2) {
dp2->di_db[lastbn + 1] = dp2->di_db[lastbn];
dp2->di_db[lastbn] = iswap64(newblk);
dp2->di_size = iswap64(iswap64(dp2->di_size)+sblock->fs_bsize);
dp2->di_blocks = iswap64(iswap64(dp2->di_blocks) +
btodb(sblock->fs_bsize));
dirblk = iswap64(dp2->di_db[lastbn + 1]);
} else {
dp1->di_db[lastbn + 1] = dp1->di_db[lastbn];
dp1->di_db[lastbn] = iswap32((int32_t)newblk);
dp1->di_size = iswap64(iswap64(dp1->di_size)+sblock->fs_bsize);
dp1->di_blocks = iswap32(iswap32(dp1->di_blocks) +
btodb(sblock->fs_bsize));
dirblk = iswap32(dp1->di_db[lastbn + 1]);
}
bp = getdirblk(dirblk, sblksize(sblock, DIP(dp, size), lastbn + 1));
if (bp->b_errs)
goto bad;
memmove(firstblk, bp->b_un.b_buf, dirblksiz);
bp = getdirblk(newblk, sblock->fs_bsize);
if (bp->b_errs)
goto bad;
memmove(bp->b_un.b_buf, firstblk, dirblksiz);
emptydir.dot_reclen = iswap16(dirblksiz);
for (cp = &bp->b_un.b_buf[dirblksiz];
cp < &bp->b_un.b_buf[sblock->fs_bsize];
cp += dirblksiz)
memmove(cp, &emptydir, sizeof emptydir);
dirty(bp);
bp = getdirblk(dirblk, sblksize(sblock, DIP(dp, size), lastbn + 1));
if (bp->b_errs)
goto bad;
memmove(bp->b_un.b_buf, &emptydir, sizeof emptydir);
pwarn("NO SPACE LEFT IN %s", name);
if (preen)
printf(" (EXPANDED)\n");
else if (reply("EXPAND") == 0)
goto bad;
dirty(bp);
inodirty();
return (1);
bad:
if (is_ufs2) {
dp2->di_db[lastbn] = dp2->di_db[lastbn + 1];
dp2->di_db[lastbn + 1] = 0;
dp2->di_size = iswap64(iswap64(dp2->di_size)-sblock->fs_bsize);
dp2->di_blocks = iswap64(iswap64(dp2->di_blocks) -
btodb(sblock->fs_bsize));
} else {
dp1->di_db[lastbn] = dp1->di_db[lastbn + 1];
dp1->di_db[lastbn + 1] = 0;
dp1->di_size = iswap64(iswap64(dp1->di_size)-sblock->fs_bsize);
dp1->di_blocks = iswap32(iswap32(dp1->di_blocks) -
btodb(sblock->fs_bsize));
}
freeblk(newblk, sblock->fs_frag);
markclean = 0;
return (0);
}
/*
* allocate a new directory
*/
ino_t
allocdir(ino_t parent, ino_t request, int mode)
{
ino_t ino;
char *cp;
union dinode *dp;
struct bufarea *bp;
struct inoinfo *inp;
struct dirtemplate *dirp;
daddr_t dirblk;
ino = allocino(request, IFDIR|mode);
if (ino < ROOTINO)
return 0;
dirhead.dot_reclen = iswap16(12);
dirhead.dotdot_reclen = iswap16(dirblksiz - 12);
odirhead.dot_reclen = iswap16(12);
odirhead.dotdot_reclen = iswap16(dirblksiz - 12);
odirhead.dot_namlen = iswap16(1);
odirhead.dotdot_namlen = iswap16(2);
if (newinofmt)
dirp = &dirhead;
else
dirp = (struct dirtemplate *)&odirhead;
dirp->dot_ino = iswap32(ino);
dirp->dotdot_ino = iswap32(parent);
dp = ginode(ino);
dirblk = is_ufs2 ? iswap64(dp->dp2.di_db[0])
: iswap32(dp->dp1.di_db[0]);
bp = getdirblk(dirblk, sblock->fs_fsize);
if (bp->b_errs) {
freeino(ino);
return (0);
}
memmove(bp->b_un.b_buf, dirp, sizeof(struct dirtemplate));
emptydir.dot_reclen = iswap16(dirblksiz);
for (cp = &bp->b_un.b_buf[dirblksiz];
cp < &bp->b_un.b_buf[sblock->fs_fsize];
cp += dirblksiz)
memmove(cp, &emptydir, sizeof emptydir);
dirty(bp);
DIP_SET(dp, nlink, iswap16(2));
inodirty();
if (ino == ROOTINO) {
inoinfo(ino)->ino_linkcnt = iswap16(DIP(dp, nlink));
cacheino(dp, ino);
return(ino);
}
if (inoinfo(parent)->ino_state != DSTATE &&
inoinfo(parent)->ino_state != DFOUND) {
freeino(ino);
return (0);
}
cacheino(dp, ino);
inp = getinoinfo(ino);
inp->i_parent = parent;
inp->i_dotdot = parent;
inoinfo(ino)->ino_state = inoinfo(parent)->ino_state;
if (inoinfo(ino)->ino_state == DSTATE) {
inoinfo(ino)->ino_linkcnt = iswap16(DIP(dp, nlink));
inoinfo(parent)->ino_linkcnt++;
}
dp = ginode(parent);
DIP_SET(dp, nlink, iswap16(iswap16(DIP(dp, nlink)) + 1));
inodirty();
return (ino);
}
