linux/fs/ntfs3/index.c

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// SPDX-License-Identifier: GPL-2.0
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
*/
#include <linux/blkdev.h>
#include <linux/buffer_head.h>
#include <linux/fs.h>
#include <linux/kernel.h>
#include "debug.h"
#include "ntfs.h"
#include "ntfs_fs.h"
static const struct INDEX_NAMES {
const __le16 *name;
u8 name_len;
} s_index_names[INDEX_MUTEX_TOTAL] = {
{ I30_NAME, ARRAY_SIZE(I30_NAME) }, { SII_NAME, ARRAY_SIZE(SII_NAME) },
{ SDH_NAME, ARRAY_SIZE(SDH_NAME) }, { SO_NAME, ARRAY_SIZE(SO_NAME) },
{ SQ_NAME, ARRAY_SIZE(SQ_NAME) }, { SR_NAME, ARRAY_SIZE(SR_NAME) },
};
/*
* cmp_fnames - Compare two names in index.
*
* if l1 != 0
* Both names are little endian on-disk ATTR_FILE_NAME structs.
* else
* key1 - cpu_str, key2 - ATTR_FILE_NAME
*/
static int cmp_fnames(const void *key1, size_t l1, const void *key2, size_t l2,
const void *data)
{
const struct ATTR_FILE_NAME *f2 = key2;
const struct ntfs_sb_info *sbi = data;
const struct ATTR_FILE_NAME *f1;
u16 fsize2;
bool both_case;
if (l2 <= offsetof(struct ATTR_FILE_NAME, name))
return -1;
fsize2 = fname_full_size(f2);
if (l2 < fsize2)
return -1;
both_case = f2->type != FILE_NAME_DOS /*&& !sbi->options.nocase*/;
if (!l1) {
const struct le_str *s2 = (struct le_str *)&f2->name_len;
/*
* If names are equal (case insensitive)
* try to compare it case sensitive.
*/
return ntfs_cmp_names_cpu(key1, s2, sbi->upcase, both_case);
}
f1 = key1;
return ntfs_cmp_names(f1->name, f1->name_len, f2->name, f2->name_len,
sbi->upcase, both_case);
}
/*
* cmp_uint - $SII of $Secure and $Q of Quota
*/
static int cmp_uint(const void *key1, size_t l1, const void *key2, size_t l2,
const void *data)
{
const u32 *k1 = key1;
const u32 *k2 = key2;
if (l2 < sizeof(u32))
return -1;
if (*k1 < *k2)
return -1;
if (*k1 > *k2)
return 1;
return 0;
}
/*
* cmp_sdh - $SDH of $Secure
*/
static int cmp_sdh(const void *key1, size_t l1, const void *key2, size_t l2,
const void *data)
{
const struct SECURITY_KEY *k1 = key1;
const struct SECURITY_KEY *k2 = key2;
u32 t1, t2;
if (l2 < sizeof(struct SECURITY_KEY))
return -1;
t1 = le32_to_cpu(k1->hash);
t2 = le32_to_cpu(k2->hash);
/* First value is a hash value itself. */
if (t1 < t2)
return -1;
if (t1 > t2)
return 1;
/* Second value is security Id. */
if (data) {
t1 = le32_to_cpu(k1->sec_id);
t2 = le32_to_cpu(k2->sec_id);
if (t1 < t2)
return -1;
if (t1 > t2)
return 1;
}
return 0;
}
/*
* cmp_uints - $O of ObjId and "$R" for Reparse.
*/
static int cmp_uints(const void *key1, size_t l1, const void *key2, size_t l2,
const void *data)
{
const __le32 *k1 = key1;
const __le32 *k2 = key2;
size_t count;
if ((size_t)data == 1) {
/*
* ni_delete_all -> ntfs_remove_reparse ->
* delete all with this reference.
* k1, k2 - pointers to REPARSE_KEY
*/
k1 += 1; // Skip REPARSE_KEY.ReparseTag
k2 += 1; // Skip REPARSE_KEY.ReparseTag
if (l2 <= sizeof(int))
return -1;
l2 -= sizeof(int);
if (l1 <= sizeof(int))
return 1;
l1 -= sizeof(int);
}
if (l2 < sizeof(int))
return -1;
for (count = min(l1, l2) >> 2; count > 0; --count, ++k1, ++k2) {
u32 t1 = le32_to_cpu(*k1);
u32 t2 = le32_to_cpu(*k2);
if (t1 > t2)
return 1;
if (t1 < t2)
return -1;
}
if (l1 > l2)
return 1;
if (l1 < l2)
return -1;
return 0;
}
static inline NTFS_CMP_FUNC get_cmp_func(const struct INDEX_ROOT *root)
{
switch (root->type) {
case ATTR_NAME:
if (root->rule == NTFS_COLLATION_TYPE_FILENAME)
return &cmp_fnames;
break;
case ATTR_ZERO:
switch (root->rule) {
case NTFS_COLLATION_TYPE_UINT:
return &cmp_uint;
case NTFS_COLLATION_TYPE_SECURITY_HASH:
return &cmp_sdh;
case NTFS_COLLATION_TYPE_UINTS:
return &cmp_uints;
default:
break;
}
break;
default:
break;
}
return NULL;
}
struct bmp_buf {
struct ATTRIB *b;
struct mft_inode *mi;
struct buffer_head *bh;
ulong *buf;
size_t bit;
u32 nbits;
u64 new_valid;
};
static int bmp_buf_get(struct ntfs_index *indx, struct ntfs_inode *ni,
size_t bit, struct bmp_buf *bbuf)
{
struct ATTRIB *b;
size_t data_size, valid_size, vbo, off = bit >> 3;
struct ntfs_sb_info *sbi = ni->mi.sbi;
CLST vcn = off >> sbi->cluster_bits;
struct ATTR_LIST_ENTRY *le = NULL;
struct buffer_head *bh;
struct super_block *sb;
u32 blocksize;
const struct INDEX_NAMES *in = &s_index_names[indx->type];
bbuf->bh = NULL;
b = ni_find_attr(ni, NULL, &le, ATTR_BITMAP, in->name, in->name_len,
&vcn, &bbuf->mi);
bbuf->b = b;
if (!b)
return -EINVAL;
if (!b->non_res) {
data_size = le32_to_cpu(b->res.data_size);
if (off >= data_size)
return -EINVAL;
bbuf->buf = (ulong *)resident_data(b);
bbuf->bit = 0;
bbuf->nbits = data_size * 8;
return 0;
}
data_size = le64_to_cpu(b->nres.data_size);
if (WARN_ON(off >= data_size)) {
/* Looks like filesystem error. */
return -EINVAL;
}
valid_size = le64_to_cpu(b->nres.valid_size);
bh = ntfs_bread_run(sbi, &indx->bitmap_run, off);
if (!bh)
return -EIO;
if (IS_ERR(bh))
return PTR_ERR(bh);
bbuf->bh = bh;
if (buffer_locked(bh))
__wait_on_buffer(bh);
lock_buffer(bh);
sb = sbi->sb;
blocksize = sb->s_blocksize;
vbo = off & ~(size_t)sbi->block_mask;
bbuf->new_valid = vbo + blocksize;
if (bbuf->new_valid <= valid_size)
bbuf->new_valid = 0;
else if (bbuf->new_valid > data_size)
bbuf->new_valid = data_size;
if (vbo >= valid_size) {
memset(bh->b_data, 0, blocksize);
} else if (vbo + blocksize > valid_size) {
u32 voff = valid_size & sbi->block_mask;
memset(bh->b_data + voff, 0, blocksize - voff);
}
bbuf->buf = (ulong *)bh->b_data;
bbuf->bit = 8 * (off & ~(size_t)sbi->block_mask);
bbuf->nbits = 8 * blocksize;
return 0;
}
static void bmp_buf_put(struct bmp_buf *bbuf, bool dirty)
{
struct buffer_head *bh = bbuf->bh;
struct ATTRIB *b = bbuf->b;
if (!bh) {
if (b && !b->non_res && dirty)
bbuf->mi->dirty = true;
return;
}
if (!dirty)
goto out;
if (bbuf->new_valid) {
b->nres.valid_size = cpu_to_le64(bbuf->new_valid);
bbuf->mi->dirty = true;
}
set_buffer_uptodate(bh);
mark_buffer_dirty(bh);
out:
unlock_buffer(bh);
put_bh(bh);
}
/*
* indx_mark_used - Mark the bit @bit as used.
*/
static int indx_mark_used(struct ntfs_index *indx, struct ntfs_inode *ni,
size_t bit)
{
int err;
struct bmp_buf bbuf;
err = bmp_buf_get(indx, ni, bit, &bbuf);
if (err)
return err;
__set_bit(bit - bbuf.bit, bbuf.buf);
bmp_buf_put(&bbuf, true);
return 0;
}
/*
* indx_mark_free - Mark the bit @bit as free.
*/
static int indx_mark_free(struct ntfs_index *indx, struct ntfs_inode *ni,
size_t bit)
{
int err;
struct bmp_buf bbuf;
err = bmp_buf_get(indx, ni, bit, &bbuf);
if (err)
return err;
__clear_bit(bit - bbuf.bit, bbuf.buf);
bmp_buf_put(&bbuf, true);
return 0;
}
/*
* scan_nres_bitmap
*
* If ntfs_readdir calls this function (indx_used_bit -> scan_nres_bitmap),
* inode is shared locked and no ni_lock.
* Use rw_semaphore for read/write access to bitmap_run.
*/
static int scan_nres_bitmap(struct ntfs_inode *ni, struct ATTRIB *bitmap,
struct ntfs_index *indx, size_t from,
bool (*fn)(const ulong *buf, u32 bit, u32 bits,
size_t *ret),
size_t *ret)
{
struct ntfs_sb_info *sbi = ni->mi.sbi;
struct super_block *sb = sbi->sb;
struct runs_tree *run = &indx->bitmap_run;
struct rw_semaphore *lock = &indx->run_lock;
u32 nbits = sb->s_blocksize * 8;
u32 blocksize = sb->s_blocksize;
u64 valid_size = le64_to_cpu(bitmap->nres.valid_size);
u64 data_size = le64_to_cpu(bitmap->nres.data_size);
sector_t eblock = bytes_to_block(sb, data_size);
size_t vbo = from >> 3;
sector_t blk = (vbo & sbi->cluster_mask) >> sb->s_blocksize_bits;
sector_t vblock = vbo >> sb->s_blocksize_bits;
sector_t blen, block;
CLST lcn, clen, vcn, vcn_next;
size_t idx;
struct buffer_head *bh;
bool ok;
*ret = MINUS_ONE_T;
if (vblock >= eblock)
return 0;
from &= nbits - 1;
vcn = vbo >> sbi->cluster_bits;
down_read(lock);
ok = run_lookup_entry(run, vcn, &lcn, &clen, &idx);
up_read(lock);
next_run:
if (!ok) {
int err;
const struct INDEX_NAMES *name = &s_index_names[indx->type];
down_write(lock);
err = attr_load_runs_vcn(ni, ATTR_BITMAP, name->name,
name->name_len, run, vcn);
up_write(lock);
if (err)
return err;
down_read(lock);
ok = run_lookup_entry(run, vcn, &lcn, &clen, &idx);
up_read(lock);
if (!ok)
return -EINVAL;
}
blen = (sector_t)clen * sbi->blocks_per_cluster;
block = (sector_t)lcn * sbi->blocks_per_cluster;
for (; blk < blen; blk++, from = 0) {
bh = ntfs_bread(sb, block + blk);
if (!bh)
return -EIO;
vbo = (u64)vblock << sb->s_blocksize_bits;
if (vbo >= valid_size) {
memset(bh->b_data, 0, blocksize);
} else if (vbo + blocksize > valid_size) {
u32 voff = valid_size & sbi->block_mask;
memset(bh->b_data + voff, 0, blocksize - voff);
}
if (vbo + blocksize > data_size)
nbits = 8 * (data_size - vbo);
ok = nbits > from ? (*fn)((ulong *)bh->b_data, from, nbits, ret)
: false;
put_bh(bh);
if (ok) {
*ret += 8 * vbo;
return 0;
}
if (++vblock >= eblock) {
*ret = MINUS_ONE_T;
return 0;
}
}
blk = 0;
vcn_next = vcn + clen;
down_read(lock);
ok = run_get_entry(run, ++idx, &vcn, &lcn, &clen) && vcn == vcn_next;
if (!ok)
vcn = vcn_next;
up_read(lock);
goto next_run;
}
static bool scan_for_free(const ulong *buf, u32 bit, u32 bits, size_t *ret)
{
size_t pos = find_next_zero_bit(buf, bits, bit);
if (pos >= bits)
return false;
*ret = pos;
return true;
}
/*
* indx_find_free - Look for free bit.
*
* Return: -1 if no free bits.
*/
static int indx_find_free(struct ntfs_index *indx, struct ntfs_inode *ni,
size_t *bit, struct ATTRIB **bitmap)
{
struct ATTRIB *b;
struct ATTR_LIST_ENTRY *le = NULL;
const struct INDEX_NAMES *in = &s_index_names[indx->type];
int err;
b = ni_find_attr(ni, NULL, &le, ATTR_BITMAP, in->name, in->name_len,
NULL, NULL);
if (!b)
return -ENOENT;
*bitmap = b;
*bit = MINUS_ONE_T;
if (!b->non_res) {
u32 nbits = 8 * le32_to_cpu(b->res.data_size);
size_t pos = find_next_zero_bit(resident_data(b), nbits, 0);
if (pos < nbits)
*bit = pos;
} else {
err = scan_nres_bitmap(ni, b, indx, 0, &scan_for_free, bit);
if (err)
return err;
}
return 0;
}
static bool scan_for_used(const ulong *buf, u32 bit, u32 bits, size_t *ret)
{
size_t pos = find_next_bit(buf, bits, bit);
if (pos >= bits)
return false;
*ret = pos;
return true;
}
/*
* indx_used_bit - Look for used bit.
*
* Return: MINUS_ONE_T if no used bits.
*/
int indx_used_bit(struct ntfs_index *indx, struct ntfs_inode *ni, size_t *bit)
{
struct ATTRIB *b;
struct ATTR_LIST_ENTRY *le = NULL;
size_t from = *bit;
const struct INDEX_NAMES *in = &s_index_names[indx->type];
int err;
b = ni_find_attr(ni, NULL, &le, ATTR_BITMAP, in->name, in->name_len,
NULL, NULL);
if (!b)
return -ENOENT;
*bit = MINUS_ONE_T;
if (!b->non_res) {
u32 nbits = le32_to_cpu(b->res.data_size) * 8;
size_t pos = find_next_bit(resident_data(b), nbits, from);
if (pos < nbits)
*bit = pos;
} else {
err = scan_nres_bitmap(ni, b, indx, from, &scan_for_used, bit);
if (err)
return err;
}
return 0;
}
/*
* hdr_find_split
*
* Find a point at which the index allocation buffer would like to be split.
* NOTE: This function should never return 'END' entry NULL returns on error.
*/
static const struct NTFS_DE *hdr_find_split(const struct INDEX_HDR *hdr)
{
size_t o;
const struct NTFS_DE *e = hdr_first_de(hdr);
u32 used_2 = le32_to_cpu(hdr->used) >> 1;
u16 esize;
if (!e || de_is_last(e))
return NULL;
esize = le16_to_cpu(e->size);
for (o = le32_to_cpu(hdr->de_off) + esize; o < used_2; o += esize) {
const struct NTFS_DE *p = e;
e = Add2Ptr(hdr, o);
/* We must not return END entry. */
if (de_is_last(e))
return p;
esize = le16_to_cpu(e->size);
}
return e;
}
/*
* hdr_insert_head - Insert some entries at the beginning of the buffer.
*
* It is used to insert entries into a newly-created buffer.
*/
static const struct NTFS_DE *hdr_insert_head(struct INDEX_HDR *hdr,
const void *ins, u32 ins_bytes)
{
u32 to_move;
struct NTFS_DE *e = hdr_first_de(hdr);
u32 used = le32_to_cpu(hdr->used);
if (!e)
return NULL;
/* Now we just make room for the inserted entries and jam it in. */
to_move = used - le32_to_cpu(hdr->de_off);
memmove(Add2Ptr(e, ins_bytes), e, to_move);
memcpy(e, ins, ins_bytes);
hdr->used = cpu_to_le32(used + ins_bytes);
return e;
}
void fnd_clear(struct ntfs_fnd *fnd)
{
int i;
for (i = 0; i < fnd->level; i++) {
struct indx_node *n = fnd->nodes[i];
if (!n)
continue;
put_indx_node(n);
fnd->nodes[i] = NULL;
}
fnd->level = 0;
fnd->root_de = NULL;
}
static int fnd_push(struct ntfs_fnd *fnd, struct indx_node *n,
struct NTFS_DE *e)
{
int i;
i = fnd->level;
if (i < 0 || i >= ARRAY_SIZE(fnd->nodes))
return -EINVAL;
fnd->nodes[i] = n;
fnd->de[i] = e;
fnd->level += 1;
return 0;
}
static struct indx_node *fnd_pop(struct ntfs_fnd *fnd)
{
struct indx_node *n;
int i = fnd->level;
i -= 1;
n = fnd->nodes[i];
fnd->nodes[i] = NULL;
fnd->level = i;
return n;
}
static bool fnd_is_empty(struct ntfs_fnd *fnd)
{
if (!fnd->level)
return !fnd->root_de;
return !fnd->de[fnd->level - 1];
}
/*
* hdr_find_e - Locate an entry the index buffer.
*
* If no matching entry is found, it returns the first entry which is greater
* than the desired entry If the search key is greater than all the entries the
* buffer, it returns the 'end' entry. This function does a binary search of the
* current index buffer, for the first entry that is <= to the search value.
*
* Return: NULL if error.
*/
static struct NTFS_DE *hdr_find_e(const struct ntfs_index *indx,
const struct INDEX_HDR *hdr, const void *key,
size_t key_len, const void *ctx, int *diff)
{
struct NTFS_DE *e, *found = NULL;
NTFS_CMP_FUNC cmp = indx->cmp;
int min_idx = 0, mid_idx, max_idx = 0;
int diff2;
int table_size = 8;
u32 e_size, e_key_len;
u32 end = le32_to_cpu(hdr->used);
u32 off = le32_to_cpu(hdr->de_off);
u16 offs[128];
fill_table:
if (off + sizeof(struct NTFS_DE) > end)
return NULL;
e = Add2Ptr(hdr, off);
e_size = le16_to_cpu(e->size);
if (e_size < sizeof(struct NTFS_DE) || off + e_size > end)
return NULL;
if (!de_is_last(e)) {
offs[max_idx] = off;
off += e_size;
max_idx++;
if (max_idx < table_size)
goto fill_table;
max_idx--;
}
binary_search:
e_key_len = le16_to_cpu(e->key_size);
diff2 = (*cmp)(key, key_len, e + 1, e_key_len, ctx);
if (diff2 > 0) {
if (found) {
min_idx = mid_idx + 1;
} else {
if (de_is_last(e))
return NULL;
max_idx = 0;
table_size = min(table_size * 2,
(int)ARRAY_SIZE(offs));
goto fill_table;
}
} else if (diff2 < 0) {
if (found)
max_idx = mid_idx - 1;
else
max_idx--;
found = e;
} else {
*diff = 0;
return e;
}
if (min_idx > max_idx) {
*diff = -1;
return found;
}
mid_idx = (min_idx + max_idx) >> 1;
e = Add2Ptr(hdr, offs[mid_idx]);
goto binary_search;
}
/*
* hdr_insert_de - Insert an index entry into the buffer.
*
* 'before' should be a pointer previously returned from hdr_find_e.
*/
static struct NTFS_DE *hdr_insert_de(const struct ntfs_index *indx,
struct INDEX_HDR *hdr,
const struct NTFS_DE *de,
struct NTFS_DE *before, const void *ctx)
{
int diff;
size_t off = PtrOffset(hdr, before);
u32 used = le32_to_cpu(hdr->used);
u32 total = le32_to_cpu(hdr->total);
u16 de_size = le16_to_cpu(de->size);
/* First, check to see if there's enough room. */
if (used + de_size > total)
return NULL;
/* We know there's enough space, so we know we'll succeed. */
if (before) {
/* Check that before is inside Index. */
if (off >= used || off < le32_to_cpu(hdr->de_off) ||
off + le16_to_cpu(before->size) > total) {
return NULL;
}
goto ok;
}
/* No insert point is applied. Get it manually. */
before = hdr_find_e(indx, hdr, de + 1, le16_to_cpu(de->key_size), ctx,
&diff);
if (!before)
return NULL;
off = PtrOffset(hdr, before);
ok:
/* Now we just make room for the entry and jam it in. */
memmove(Add2Ptr(before, de_size), before, used - off);
hdr->used = cpu_to_le32(used + de_size);
memcpy(before, de, de_size);
return before;
}
/*
* hdr_delete_de - Remove an entry from the index buffer.
*/
static inline struct NTFS_DE *hdr_delete_de(struct INDEX_HDR *hdr,
struct NTFS_DE *re)
{
u32 used = le32_to_cpu(hdr->used);
u16 esize = le16_to_cpu(re->size);
u32 off = PtrOffset(hdr, re);
int bytes = used - (off + esize);
if (off >= used || esize < sizeof(struct NTFS_DE) ||
bytes < sizeof(struct NTFS_DE))
return NULL;
hdr->used = cpu_to_le32(used - esize);
memmove(re, Add2Ptr(re, esize), bytes);
return re;
}
void indx_clear(struct ntfs_index *indx)
{
run_close(&indx->alloc_run);
run_close(&indx->bitmap_run);
}
int indx_init(struct ntfs_index *indx, struct ntfs_sb_info *sbi,
const struct ATTRIB *attr, enum index_mutex_classed type)
{
u32 t32;
const struct INDEX_ROOT *root = resident_data(attr);
/* Check root fields. */
if (!root->index_block_clst)
return -EINVAL;
indx->type = type;
indx->idx2vbn_bits = __ffs(root->index_block_clst);
t32 = le32_to_cpu(root->index_block_size);
indx->index_bits = blksize_bits(t32);
/* Check index record size. */
if (t32 < sbi->cluster_size) {
/* Index record is smaller than a cluster, use 512 blocks. */
if (t32 != root->index_block_clst * SECTOR_SIZE)
return -EINVAL;
/* Check alignment to a cluster. */
if ((sbi->cluster_size >> SECTOR_SHIFT) &
(root->index_block_clst - 1)) {
return -EINVAL;
}
indx->vbn2vbo_bits = SECTOR_SHIFT;
} else {
/* Index record must be a multiple of cluster size. */
if (t32 != root->index_block_clst << sbi->cluster_bits)
return -EINVAL;
indx->vbn2vbo_bits = sbi->cluster_bits;
}
init_rwsem(&indx->run_lock);
indx->cmp = get_cmp_func(root);
return indx->cmp ? 0 : -EINVAL;
}
static struct indx_node *indx_new(struct ntfs_index *indx,
struct ntfs_inode *ni, CLST vbn,
const __le64 *sub_vbn)
{
int err;
struct NTFS_DE *e;
struct indx_node *r;
struct INDEX_HDR *hdr;
struct INDEX_BUFFER *index;
u64 vbo = (u64)vbn << indx->vbn2vbo_bits;
u32 bytes = 1u << indx->index_bits;
u16 fn;
u32 eo;
r = kzalloc(sizeof(struct indx_node), GFP_NOFS);
if (!r)
return ERR_PTR(-ENOMEM);
index = kzalloc(bytes, GFP_NOFS);
if (!index) {
kfree(r);
return ERR_PTR(-ENOMEM);
}
err = ntfs_get_bh(ni->mi.sbi, &indx->alloc_run, vbo, bytes, &r->nb);
if (err) {
kfree(index);
kfree(r);
return ERR_PTR(err);
}
/* Create header. */
index->rhdr.sign = NTFS_INDX_SIGNATURE;
index->rhdr.fix_off = cpu_to_le16(sizeof(struct INDEX_BUFFER)); // 0x28
fn = (bytes >> SECTOR_SHIFT) + 1; // 9
index->rhdr.fix_num = cpu_to_le16(fn);
index->vbn = cpu_to_le64(vbn);
hdr = &index->ihdr;
fs/ntfs3: Use kernel ALIGN macros over driver specific The static checkers (Smatch) were complaining because QuadAlign() was buggy. If you try to align something higher than UINT_MAX it got truncated to a u32. Smatch warning was: fs/ntfs3/attrib.c:383 attr_set_size_res() warn: was expecting a 64 bit value instead of '~7' So that this will not happen again we will change all these macros to kernel made ones. This can also help some other static analyzing tools to give us better warnings. Patch was generated with Coccinelle script and after that some style issue was hand fixed. Coccinelle script: virtual patch @alloc depends on patch@ expression x; @@ ( - #define QuadAlign(n) (((n) + 7u) & (~7u)) | - QuadAlign(x) + ALIGN(x, 8) | - #define IsQuadAligned(n) (!((size_t)(n)&7u)) | - IsQuadAligned(x) + IS_ALIGNED(x, 8) | - #define Quad2Align(n) (((n) + 15u) & (~15u)) | - Quad2Align(x) + ALIGN(x, 16) | - #define IsQuad2Aligned(n) (!((size_t)(n)&15u)) | - IsQuad2Aligned(x) + IS_ALIGNED(x, 16) | - #define Quad4Align(n) (((n) + 31u) & (~31u)) | - Quad4Align(x) + ALIGN(x, 32) | - #define IsSizeTAligned(n) (!((size_t)(n) & (sizeof(size_t) - 1))) | - IsSizeTAligned(x) + IS_ALIGNED(x, sizeof(size_t)) | - #define DwordAlign(n) (((n) + 3u) & (~3u)) | - DwordAlign(x) + ALIGN(x, 4) | - #define IsDwordAligned(n) (!((size_t)(n)&3u)) | - IsDwordAligned(x) + IS_ALIGNED(x, 4) | - #define WordAlign(n) (((n) + 1u) & (~1u)) | - WordAlign(x) + ALIGN(x, 2) | - #define IsWordAligned(n) (!((size_t)(n)&1u)) | - IsWordAligned(x) + IS_ALIGNED(x, 2) | ) Reported-by: Dan Carpenter <dan.carpenter@oracle.com> Signed-off-by: Kari Argillander <kari.argillander@gmail.com> Signed-off-by: Konstantin Komarov <almaz.alexandrovich@paragon-software.com>
2021-08-26 08:56:29 +00:00
eo = ALIGN(sizeof(struct INDEX_BUFFER) + fn * sizeof(short), 8);
hdr->de_off = cpu_to_le32(eo);
e = Add2Ptr(hdr, eo);
if (sub_vbn) {
e->flags = NTFS_IE_LAST | NTFS_IE_HAS_SUBNODES;
e->size = cpu_to_le16(sizeof(struct NTFS_DE) + sizeof(u64));
hdr->used =
cpu_to_le32(eo + sizeof(struct NTFS_DE) + sizeof(u64));
de_set_vbn_le(e, *sub_vbn);
hdr->flags = 1;
} else {
e->size = cpu_to_le16(sizeof(struct NTFS_DE));
hdr->used = cpu_to_le32(eo + sizeof(struct NTFS_DE));
e->flags = NTFS_IE_LAST;
}
hdr->total = cpu_to_le32(bytes - offsetof(struct INDEX_BUFFER, ihdr));
r->index = index;
return r;
}
struct INDEX_ROOT *indx_get_root(struct ntfs_index *indx, struct ntfs_inode *ni,
struct ATTRIB **attr, struct mft_inode **mi)
{
struct ATTR_LIST_ENTRY *le = NULL;
struct ATTRIB *a;
const struct INDEX_NAMES *in = &s_index_names[indx->type];
a = ni_find_attr(ni, NULL, &le, ATTR_ROOT, in->name, in->name_len, NULL,
mi);
if (!a)
return NULL;
if (attr)
*attr = a;
return resident_data_ex(a, sizeof(struct INDEX_ROOT));
}
static int indx_write(struct ntfs_index *indx, struct ntfs_inode *ni,
struct indx_node *node, int sync)
{
struct INDEX_BUFFER *ib = node->index;
return ntfs_write_bh(ni->mi.sbi, &ib->rhdr, &node->nb, sync);
}
/*
* indx_read
*
* If ntfs_readdir calls this function
* inode is shared locked and no ni_lock.
* Use rw_semaphore for read/write access to alloc_run.
*/
int indx_read(struct ntfs_index *indx, struct ntfs_inode *ni, CLST vbn,
struct indx_node **node)
{
int err;
struct INDEX_BUFFER *ib;
struct runs_tree *run = &indx->alloc_run;
struct rw_semaphore *lock = &indx->run_lock;
u64 vbo = (u64)vbn << indx->vbn2vbo_bits;
u32 bytes = 1u << indx->index_bits;
struct indx_node *in = *node;
const struct INDEX_NAMES *name;
if (!in) {
in = kzalloc(sizeof(struct indx_node), GFP_NOFS);
if (!in)
return -ENOMEM;
} else {
nb_put(&in->nb);
}
ib = in->index;
if (!ib) {
ib = kmalloc(bytes, GFP_NOFS);
if (!ib) {
err = -ENOMEM;
goto out;
}
}
down_read(lock);
err = ntfs_read_bh(ni->mi.sbi, run, vbo, &ib->rhdr, bytes, &in->nb);
up_read(lock);
if (!err)
goto ok;
if (err == -E_NTFS_FIXUP)
goto ok;
if (err != -ENOENT)
goto out;
name = &s_index_names[indx->type];
down_write(lock);
err = attr_load_runs_range(ni, ATTR_ALLOC, name->name, name->name_len,
run, vbo, vbo + bytes);
up_write(lock);
if (err)
goto out;
down_read(lock);
err = ntfs_read_bh(ni->mi.sbi, run, vbo, &ib->rhdr, bytes, &in->nb);
up_read(lock);
if (err == -E_NTFS_FIXUP)
goto ok;
if (err)
goto out;
ok:
if (err == -E_NTFS_FIXUP) {
ntfs_write_bh(ni->mi.sbi, &ib->rhdr, &in->nb, 0);
err = 0;
}
in->index = ib;
*node = in;
out:
if (ib != in->index)
kfree(ib);
if (*node != in) {
nb_put(&in->nb);
kfree(in);
}
return err;
}
/*
* indx_find - Scan NTFS directory for given entry.
*/
int indx_find(struct ntfs_index *indx, struct ntfs_inode *ni,
const struct INDEX_ROOT *root, const void *key, size_t key_len,
const void *ctx, int *diff, struct NTFS_DE **entry,
struct ntfs_fnd *fnd)
{
int err;
struct NTFS_DE *e;
const struct INDEX_HDR *hdr;
struct indx_node *node;
if (!root)
root = indx_get_root(&ni->dir, ni, NULL, NULL);
if (!root) {
err = -EINVAL;
goto out;
}
hdr = &root->ihdr;
/* Check cache. */
e = fnd->level ? fnd->de[fnd->level - 1] : fnd->root_de;
if (e && !de_is_last(e) &&
!(*indx->cmp)(key, key_len, e + 1, le16_to_cpu(e->key_size), ctx)) {
*entry = e;
*diff = 0;
return 0;
}
/* Soft finder reset. */
fnd_clear(fnd);
/* Lookup entry that is <= to the search value. */
e = hdr_find_e(indx, hdr, key, key_len, ctx, diff);
if (!e)
return -EINVAL;
if (fnd)
fnd->root_de = e;
err = 0;
for (;;) {
node = NULL;
if (*diff >= 0 || !de_has_vcn_ex(e)) {
*entry = e;
goto out;
}
/* Read next level. */
err = indx_read(indx, ni, de_get_vbn(e), &node);
if (err)
goto out;
/* Lookup entry that is <= to the search value. */
e = hdr_find_e(indx, &node->index->ihdr, key, key_len, ctx,
diff);
if (!e) {
err = -EINVAL;
put_indx_node(node);
goto out;
}
fnd_push(fnd, node, e);
}
out:
return err;
}
int indx_find_sort(struct ntfs_index *indx, struct ntfs_inode *ni,
const struct INDEX_ROOT *root, struct NTFS_DE **entry,
struct ntfs_fnd *fnd)
{
int err;
struct indx_node *n = NULL;
struct NTFS_DE *e;
size_t iter = 0;
int level = fnd->level;
if (!*entry) {
/* Start find. */
e = hdr_first_de(&root->ihdr);
if (!e)
return 0;
fnd_clear(fnd);
fnd->root_de = e;
} else if (!level) {
if (de_is_last(fnd->root_de)) {
*entry = NULL;
return 0;
}
e = hdr_next_de(&root->ihdr, fnd->root_de);
if (!e)
return -EINVAL;
fnd->root_de = e;
} else {
n = fnd->nodes[level - 1];
e = fnd->de[level - 1];
if (de_is_last(e))
goto pop_level;
e = hdr_next_de(&n->index->ihdr, e);
if (!e)
return -EINVAL;
fnd->de[level - 1] = e;
}
/* Just to avoid tree cycle. */
next_iter:
if (iter++ >= 1000)
return -EINVAL;
while (de_has_vcn_ex(e)) {
if (le16_to_cpu(e->size) <
sizeof(struct NTFS_DE) + sizeof(u64)) {
if (n) {
fnd_pop(fnd);
kfree(n);
}
return -EINVAL;
}
/* Read next level. */
err = indx_read(indx, ni, de_get_vbn(e), &n);
if (err)
return err;
/* Try next level. */
e = hdr_first_de(&n->index->ihdr);
if (!e) {
kfree(n);
return -EINVAL;
}
fnd_push(fnd, n, e);
}
if (le16_to_cpu(e->size) > sizeof(struct NTFS_DE)) {
*entry = e;
return 0;
}
pop_level:
for (;;) {
if (!de_is_last(e))
goto next_iter;
/* Pop one level. */
if (n) {
fnd_pop(fnd);
kfree(n);
}
level = fnd->level;
if (level) {
n = fnd->nodes[level - 1];
e = fnd->de[level - 1];
} else if (fnd->root_de) {
n = NULL;
e = fnd->root_de;
fnd->root_de = NULL;
} else {
*entry = NULL;
return 0;
}
if (le16_to_cpu(e->size) > sizeof(struct NTFS_DE)) {
*entry = e;
if (!fnd->root_de)
fnd->root_de = e;
return 0;
}
}
}
int indx_find_raw(struct ntfs_index *indx, struct ntfs_inode *ni,
const struct INDEX_ROOT *root, struct NTFS_DE **entry,
size_t *off, struct ntfs_fnd *fnd)
{
int err;
struct indx_node *n = NULL;
struct NTFS_DE *e = NULL;
struct NTFS_DE *e2;
size_t bit;
CLST next_used_vbn;
CLST next_vbn;
u32 record_size = ni->mi.sbi->record_size;
/* Use non sorted algorithm. */
if (!*entry) {
/* This is the first call. */
e = hdr_first_de(&root->ihdr);
if (!e)
return 0;
fnd_clear(fnd);
fnd->root_de = e;
/* The first call with setup of initial element. */
if (*off >= record_size) {
next_vbn = (((*off - record_size) >> indx->index_bits))
<< indx->idx2vbn_bits;
/* Jump inside cycle 'for'. */
goto next;
}
/* Start enumeration from root. */
*off = 0;
} else if (!fnd->root_de)
return -EINVAL;
for (;;) {
/* Check if current entry can be used. */
if (e && le16_to_cpu(e->size) > sizeof(struct NTFS_DE))
goto ok;
if (!fnd->level) {
/* Continue to enumerate root. */
if (!de_is_last(fnd->root_de)) {
e = hdr_next_de(&root->ihdr, fnd->root_de);
if (!e)
return -EINVAL;
fnd->root_de = e;
continue;
}
/* Start to enumerate indexes from 0. */
next_vbn = 0;
} else {
/* Continue to enumerate indexes. */
e2 = fnd->de[fnd->level - 1];
n = fnd->nodes[fnd->level - 1];
if (!de_is_last(e2)) {
e = hdr_next_de(&n->index->ihdr, e2);
if (!e)
return -EINVAL;
fnd->de[fnd->level - 1] = e;
continue;
}
/* Continue with next index. */
next_vbn = le64_to_cpu(n->index->vbn) +
root->index_block_clst;
}
next:
/* Release current index. */
if (n) {
fnd_pop(fnd);
put_indx_node(n);
n = NULL;
}
/* Skip all free indexes. */
bit = next_vbn >> indx->idx2vbn_bits;
err = indx_used_bit(indx, ni, &bit);
if (err == -ENOENT || bit == MINUS_ONE_T) {
/* No used indexes. */
*entry = NULL;
return 0;
}
next_used_vbn = bit << indx->idx2vbn_bits;
/* Read buffer into memory. */
err = indx_read(indx, ni, next_used_vbn, &n);
if (err)
return err;
e = hdr_first_de(&n->index->ihdr);
fnd_push(fnd, n, e);
if (!e)
return -EINVAL;
}
ok:
/* Return offset to restore enumerator if necessary. */
if (!n) {
/* 'e' points in root, */
*off = PtrOffset(&root->ihdr, e);
} else {
/* 'e' points in index, */
*off = (le64_to_cpu(n->index->vbn) << indx->vbn2vbo_bits) +
record_size + PtrOffset(&n->index->ihdr, e);
}
*entry = e;
return 0;
}
/*
* indx_create_allocate - Create "Allocation + Bitmap" attributes.
*/
static int indx_create_allocate(struct ntfs_index *indx, struct ntfs_inode *ni,
CLST *vbn)
{
int err;
struct ntfs_sb_info *sbi = ni->mi.sbi;
struct ATTRIB *bitmap;
struct ATTRIB *alloc;
u32 data_size = 1u << indx->index_bits;
u32 alloc_size = ntfs_up_cluster(sbi, data_size);
CLST len = alloc_size >> sbi->cluster_bits;
const struct INDEX_NAMES *in = &s_index_names[indx->type];
CLST alen;
struct runs_tree run;
run_init(&run);
err = attr_allocate_clusters(sbi, &run, 0, 0, len, NULL, 0, &alen, 0,
NULL);
if (err)
goto out;
err = ni_insert_nonresident(ni, ATTR_ALLOC, in->name, in->name_len,
&run, 0, len, 0, &alloc, NULL);
if (err)
goto out1;
alloc->nres.valid_size = alloc->nres.data_size = cpu_to_le64(data_size);
err = ni_insert_resident(ni, bitmap_size(1), ATTR_BITMAP, in->name,
in->name_len, &bitmap, NULL, NULL);
if (err)
goto out2;
if (in->name == I30_NAME) {
ni->vfs_inode.i_size = data_size;
inode_set_bytes(&ni->vfs_inode, alloc_size);
}
memcpy(&indx->alloc_run, &run, sizeof(run));
*vbn = 0;
return 0;
out2:
mi_remove_attr(NULL, &ni->mi, alloc);
out1:
run_deallocate(sbi, &run, false);
out:
return err;
}
/*
* indx_add_allocate - Add clusters to index.
*/
static int indx_add_allocate(struct ntfs_index *indx, struct ntfs_inode *ni,
CLST *vbn)
{
int err;
size_t bit;
u64 data_size;
u64 bmp_size, bmp_size_v;
struct ATTRIB *bmp, *alloc;
struct mft_inode *mi;
const struct INDEX_NAMES *in = &s_index_names[indx->type];
err = indx_find_free(indx, ni, &bit, &bmp);
if (err)
goto out1;
if (bit != MINUS_ONE_T) {
bmp = NULL;
} else {
if (bmp->non_res) {
bmp_size = le64_to_cpu(bmp->nres.data_size);
bmp_size_v = le64_to_cpu(bmp->nres.valid_size);
} else {
bmp_size = bmp_size_v = le32_to_cpu(bmp->res.data_size);
}
bit = bmp_size << 3;
}
data_size = (u64)(bit + 1) << indx->index_bits;
if (bmp) {
/* Increase bitmap. */
err = attr_set_size(ni, ATTR_BITMAP, in->name, in->name_len,
&indx->bitmap_run, bitmap_size(bit + 1),
NULL, true, NULL);
if (err)
goto out1;
}
alloc = ni_find_attr(ni, NULL, NULL, ATTR_ALLOC, in->name, in->name_len,
NULL, &mi);
if (!alloc) {
err = -EINVAL;
if (bmp)
goto out2;
goto out1;
}
/* Increase allocation. */
err = attr_set_size(ni, ATTR_ALLOC, in->name, in->name_len,
&indx->alloc_run, data_size, &data_size, true,
NULL);
if (err) {
if (bmp)
goto out2;
goto out1;
}
*vbn = bit << indx->idx2vbn_bits;
return 0;
out2:
/* Ops. No space? */
attr_set_size(ni, ATTR_BITMAP, in->name, in->name_len,
&indx->bitmap_run, bmp_size, &bmp_size_v, false, NULL);
out1:
return err;
}
/*
* indx_insert_into_root - Attempt to insert an entry into the index root.
*
* @undo - True if we undoing previous remove.
* If necessary, it will twiddle the index b-tree.
*/
static int indx_insert_into_root(struct ntfs_index *indx, struct ntfs_inode *ni,
const struct NTFS_DE *new_de,
struct NTFS_DE *root_de, const void *ctx,
struct ntfs_fnd *fnd, bool undo)
{
int err = 0;
struct NTFS_DE *e, *e0, *re;
struct mft_inode *mi;
struct ATTRIB *attr;
struct INDEX_HDR *hdr;
struct indx_node *n;
CLST new_vbn;
__le64 *sub_vbn, t_vbn;
u16 new_de_size;
u32 hdr_used, hdr_total, asize, to_move;
u32 root_size, new_root_size;
struct ntfs_sb_info *sbi;
int ds_root;
struct INDEX_ROOT *root, *a_root;
/* Get the record this root placed in. */
root = indx_get_root(indx, ni, &attr, &mi);
if (!root)
return -EINVAL;
/*
* Try easy case:
* hdr_insert_de will succeed if there's
* room the root for the new entry.
*/
hdr = &root->ihdr;
sbi = ni->mi.sbi;
new_de_size = le16_to_cpu(new_de->size);
hdr_used = le32_to_cpu(hdr->used);
hdr_total = le32_to_cpu(hdr->total);
asize = le32_to_cpu(attr->size);
root_size = le32_to_cpu(attr->res.data_size);
ds_root = new_de_size + hdr_used - hdr_total;
/* If 'undo' is set then reduce requirements. */
if ((undo || asize + ds_root < sbi->max_bytes_per_attr) &&
mi_resize_attr(mi, attr, ds_root)) {
hdr->total = cpu_to_le32(hdr_total + ds_root);
e = hdr_insert_de(indx, hdr, new_de, root_de, ctx);
WARN_ON(!e);
fnd_clear(fnd);
fnd->root_de = e;
return 0;
}
/* Make a copy of root attribute to restore if error. */
a_root = kmemdup(attr, asize, GFP_NOFS);
if (!a_root)
return -ENOMEM;
/*
* Copy all the non-end entries from
* the index root to the new buffer.
*/
to_move = 0;
e0 = hdr_first_de(hdr);
/* Calculate the size to copy. */
for (e = e0;; e = hdr_next_de(hdr, e)) {
if (!e) {
err = -EINVAL;
goto out_free_root;
}
if (de_is_last(e))
break;
to_move += le16_to_cpu(e->size);
}
if (!to_move) {
re = NULL;
} else {
re = kmemdup(e0, to_move, GFP_NOFS);
if (!re) {
err = -ENOMEM;
goto out_free_root;
}
}
sub_vbn = NULL;
if (de_has_vcn(e)) {
t_vbn = de_get_vbn_le(e);
sub_vbn = &t_vbn;
}
new_root_size = sizeof(struct INDEX_ROOT) + sizeof(struct NTFS_DE) +
sizeof(u64);
ds_root = new_root_size - root_size;
if (ds_root > 0 && asize + ds_root > sbi->max_bytes_per_attr) {
/* Make root external. */
err = -EOPNOTSUPP;
goto out_free_re;
}
if (ds_root)
mi_resize_attr(mi, attr, ds_root);
/* Fill first entry (vcn will be set later). */
e = (struct NTFS_DE *)(root + 1);
memset(e, 0, sizeof(struct NTFS_DE));
e->size = cpu_to_le16(sizeof(struct NTFS_DE) + sizeof(u64));
e->flags = NTFS_IE_HAS_SUBNODES | NTFS_IE_LAST;
hdr->flags = 1;
hdr->used = hdr->total =
cpu_to_le32(new_root_size - offsetof(struct INDEX_ROOT, ihdr));
fnd->root_de = hdr_first_de(hdr);
mi->dirty = true;
/* Create alloc and bitmap attributes (if not). */
err = run_is_empty(&indx->alloc_run)
? indx_create_allocate(indx, ni, &new_vbn)
: indx_add_allocate(indx, ni, &new_vbn);
/* Layout of record may be changed, so rescan root. */
root = indx_get_root(indx, ni, &attr, &mi);
if (!root) {
/* Bug? */
ntfs_set_state(sbi, NTFS_DIRTY_ERROR);
err = -EINVAL;
goto out_free_re;
}
if (err) {
/* Restore root. */
if (mi_resize_attr(mi, attr, -ds_root))
memcpy(attr, a_root, asize);
else {
/* Bug? */
ntfs_set_state(sbi, NTFS_DIRTY_ERROR);
}
goto out_free_re;
}
e = (struct NTFS_DE *)(root + 1);
*(__le64 *)(e + 1) = cpu_to_le64(new_vbn);
mi->dirty = true;
/* Now we can create/format the new buffer and copy the entries into. */
n = indx_new(indx, ni, new_vbn, sub_vbn);
if (IS_ERR(n)) {
err = PTR_ERR(n);
goto out_free_re;
}
hdr = &n->index->ihdr;
hdr_used = le32_to_cpu(hdr->used);
hdr_total = le32_to_cpu(hdr->total);
/* Copy root entries into new buffer. */
hdr_insert_head(hdr, re, to_move);
/* Update bitmap attribute. */
indx_mark_used(indx, ni, new_vbn >> indx->idx2vbn_bits);
/* Check if we can insert new entry new index buffer. */
if (hdr_used + new_de_size > hdr_total) {
/*
* This occurs if MFT record is the same or bigger than index
* buffer. Move all root new index and have no space to add
* new entry classic case when MFT record is 1K and index
* buffer 4K the problem should not occurs.
*/
kfree(re);
indx_write(indx, ni, n, 0);
put_indx_node(n);
fnd_clear(fnd);
err = indx_insert_entry(indx, ni, new_de, ctx, fnd, undo);
goto out_free_root;
}
/*
* Now root is a parent for new index buffer.
* Insert NewEntry a new buffer.
*/
e = hdr_insert_de(indx, hdr, new_de, NULL, ctx);
if (!e) {
err = -EINVAL;
goto out_put_n;
}
fnd_push(fnd, n, e);
/* Just write updates index into disk. */
indx_write(indx, ni, n, 0);
n = NULL;
out_put_n:
put_indx_node(n);
out_free_re:
kfree(re);
out_free_root:
kfree(a_root);
return err;
}
/*
* indx_insert_into_buffer
*
* Attempt to insert an entry into an Index Allocation Buffer.
* If necessary, it will split the buffer.
*/
static int
indx_insert_into_buffer(struct ntfs_index *indx, struct ntfs_inode *ni,
struct INDEX_ROOT *root, const struct NTFS_DE *new_de,
const void *ctx, int level, struct ntfs_fnd *fnd)
{
int err;
const struct NTFS_DE *sp;
struct NTFS_DE *e, *de_t, *up_e = NULL;
struct indx_node *n2 = NULL;
struct indx_node *n1 = fnd->nodes[level];
struct INDEX_HDR *hdr1 = &n1->index->ihdr;
struct INDEX_HDR *hdr2;
u32 to_copy, used;
CLST new_vbn;
__le64 t_vbn, *sub_vbn;
u16 sp_size;
/* Try the most easy case. */
e = fnd->level - 1 == level ? fnd->de[level] : NULL;
e = hdr_insert_de(indx, hdr1, new_de, e, ctx);
fnd->de[level] = e;
if (e) {
/* Just write updated index into disk. */
indx_write(indx, ni, n1, 0);
return 0;
}
/*
* No space to insert into buffer. Split it.
* To split we:
* - Save split point ('cause index buffers will be changed)
* - Allocate NewBuffer and copy all entries <= sp into new buffer
* - Remove all entries (sp including) from TargetBuffer
* - Insert NewEntry into left or right buffer (depending on sp <=>
* NewEntry)
* - Insert sp into parent buffer (or root)
* - Make sp a parent for new buffer
*/
sp = hdr_find_split(hdr1);
if (!sp)
return -EINVAL;
sp_size = le16_to_cpu(sp->size);
up_e = kmalloc(sp_size + sizeof(u64), GFP_NOFS);
if (!up_e)
return -ENOMEM;
memcpy(up_e, sp, sp_size);
if (!hdr1->flags) {
up_e->flags |= NTFS_IE_HAS_SUBNODES;
up_e->size = cpu_to_le16(sp_size + sizeof(u64));
sub_vbn = NULL;
} else {
t_vbn = de_get_vbn_le(up_e);
sub_vbn = &t_vbn;
}
/* Allocate on disk a new index allocation buffer. */
err = indx_add_allocate(indx, ni, &new_vbn);
if (err)
goto out;
/* Allocate and format memory a new index buffer. */
n2 = indx_new(indx, ni, new_vbn, sub_vbn);
if (IS_ERR(n2)) {
err = PTR_ERR(n2);
goto out;
}
hdr2 = &n2->index->ihdr;
/* Make sp a parent for new buffer. */
de_set_vbn(up_e, new_vbn);
/* Copy all the entries <= sp into the new buffer. */
de_t = hdr_first_de(hdr1);
to_copy = PtrOffset(de_t, sp);
hdr_insert_head(hdr2, de_t, to_copy);
/* Remove all entries (sp including) from hdr1. */
used = le32_to_cpu(hdr1->used) - to_copy - sp_size;
memmove(de_t, Add2Ptr(sp, sp_size), used - le32_to_cpu(hdr1->de_off));
hdr1->used = cpu_to_le32(used);
/*
* Insert new entry into left or right buffer
* (depending on sp <=> new_de).
*/
hdr_insert_de(indx,
(*indx->cmp)(new_de + 1, le16_to_cpu(new_de->key_size),
up_e + 1, le16_to_cpu(up_e->key_size),
ctx) < 0
? hdr2
: hdr1,
new_de, NULL, ctx);
indx_mark_used(indx, ni, new_vbn >> indx->idx2vbn_bits);
indx_write(indx, ni, n1, 0);
indx_write(indx, ni, n2, 0);
put_indx_node(n2);
/*
* We've finished splitting everybody, so we are ready to
* insert the promoted entry into the parent.
*/
if (!level) {
/* Insert in root. */
err = indx_insert_into_root(indx, ni, up_e, NULL, ctx, fnd, 0);
if (err)
goto out;
} else {
/*
* The target buffer's parent is another index buffer.
* TODO: Remove recursion.
*/
err = indx_insert_into_buffer(indx, ni, root, up_e, ctx,
level - 1, fnd);
if (err)
goto out;
}
out:
kfree(up_e);
return err;
}
/*
* indx_insert_entry - Insert new entry into index.
*
* @undo - True if we undoing previous remove.
*/
int indx_insert_entry(struct ntfs_index *indx, struct ntfs_inode *ni,
const struct NTFS_DE *new_de, const void *ctx,
struct ntfs_fnd *fnd, bool undo)
{
int err;
int diff;
struct NTFS_DE *e;
struct ntfs_fnd *fnd_a = NULL;
struct INDEX_ROOT *root;
if (!fnd) {
fnd_a = fnd_get();
if (!fnd_a) {
err = -ENOMEM;
goto out1;
}
fnd = fnd_a;
}
root = indx_get_root(indx, ni, NULL, NULL);
if (!root) {
err = -EINVAL;
goto out;
}
if (fnd_is_empty(fnd)) {
/*
* Find the spot the tree where we want to
* insert the new entry.
*/
err = indx_find(indx, ni, root, new_de + 1,
le16_to_cpu(new_de->key_size), ctx, &diff, &e,
fnd);
if (err)
goto out;
if (!diff) {
err = -EEXIST;
goto out;
}
}
if (!fnd->level) {
/*
* The root is also a leaf, so we'll insert the
* new entry into it.
*/
err = indx_insert_into_root(indx, ni, new_de, fnd->root_de, ctx,
fnd, undo);
if (err)
goto out;
} else {
/*
* Found a leaf buffer, so we'll insert the new entry into it.
*/
err = indx_insert_into_buffer(indx, ni, root, new_de, ctx,
fnd->level - 1, fnd);
if (err)
goto out;
}
out:
fnd_put(fnd_a);
out1:
return err;
}
/*
* indx_find_buffer - Locate a buffer from the tree.
*/
static struct indx_node *indx_find_buffer(struct ntfs_index *indx,
struct ntfs_inode *ni,
const struct INDEX_ROOT *root,
__le64 vbn, struct indx_node *n)
{
int err;
const struct NTFS_DE *e;
struct indx_node *r;
const struct INDEX_HDR *hdr = n ? &n->index->ihdr : &root->ihdr;
/* Step 1: Scan one level. */
for (e = hdr_first_de(hdr);; e = hdr_next_de(hdr, e)) {
if (!e)
return ERR_PTR(-EINVAL);
if (de_has_vcn(e) && vbn == de_get_vbn_le(e))
return n;
if (de_is_last(e))
break;
}
/* Step2: Do recursion. */
e = Add2Ptr(hdr, le32_to_cpu(hdr->de_off));
for (;;) {
if (de_has_vcn_ex(e)) {
err = indx_read(indx, ni, de_get_vbn(e), &n);
if (err)
return ERR_PTR(err);
r = indx_find_buffer(indx, ni, root, vbn, n);
if (r)
return r;
}
if (de_is_last(e))
break;
e = Add2Ptr(e, le16_to_cpu(e->size));
}
return NULL;
}
/*
* indx_shrink - Deallocate unused tail indexes.
*/
static int indx_shrink(struct ntfs_index *indx, struct ntfs_inode *ni,
size_t bit)
{
int err = 0;
u64 bpb, new_data;
size_t nbits;
struct ATTRIB *b;
struct ATTR_LIST_ENTRY *le = NULL;
const struct INDEX_NAMES *in = &s_index_names[indx->type];
b = ni_find_attr(ni, NULL, &le, ATTR_BITMAP, in->name, in->name_len,
NULL, NULL);
if (!b)
return -ENOENT;
if (!b->non_res) {
unsigned long pos;
const unsigned long *bm = resident_data(b);
nbits = (size_t)le32_to_cpu(b->res.data_size) * 8;
if (bit >= nbits)
return 0;
pos = find_next_bit(bm, nbits, bit);
if (pos < nbits)
return 0;
} else {
size_t used = MINUS_ONE_T;
nbits = le64_to_cpu(b->nres.data_size) * 8;
if (bit >= nbits)
return 0;
err = scan_nres_bitmap(ni, b, indx, bit, &scan_for_used, &used);
if (err)
return err;
if (used != MINUS_ONE_T)
return 0;
}
new_data = (u64)bit << indx->index_bits;
err = attr_set_size(ni, ATTR_ALLOC, in->name, in->name_len,
&indx->alloc_run, new_data, &new_data, false, NULL);
if (err)
return err;
bpb = bitmap_size(bit);
if (bpb * 8 == nbits)
return 0;
err = attr_set_size(ni, ATTR_BITMAP, in->name, in->name_len,
&indx->bitmap_run, bpb, &bpb, false, NULL);
return err;
}
static int indx_free_children(struct ntfs_index *indx, struct ntfs_inode *ni,
const struct NTFS_DE *e, bool trim)
{
int err;
struct indx_node *n;
struct INDEX_HDR *hdr;
CLST vbn = de_get_vbn(e);
size_t i;
err = indx_read(indx, ni, vbn, &n);
if (err)
return err;
hdr = &n->index->ihdr;
/* First, recurse into the children, if any. */
if (hdr_has_subnode(hdr)) {
for (e = hdr_first_de(hdr); e; e = hdr_next_de(hdr, e)) {
indx_free_children(indx, ni, e, false);
if (de_is_last(e))
break;
}
}
put_indx_node(n);
i = vbn >> indx->idx2vbn_bits;
/*
* We've gotten rid of the children; add this buffer to the free list.
*/
indx_mark_free(indx, ni, i);
if (!trim)
return 0;
/*
* If there are no used indexes after current free index
* then we can truncate allocation and bitmap.
* Use bitmap to estimate the case.
*/
indx_shrink(indx, ni, i + 1);
return 0;
}
/*
* indx_get_entry_to_replace
*
* Find a replacement entry for a deleted entry.
* Always returns a node entry:
* NTFS_IE_HAS_SUBNODES is set the flags and the size includes the sub_vcn.
*/
static int indx_get_entry_to_replace(struct ntfs_index *indx,
struct ntfs_inode *ni,
const struct NTFS_DE *de_next,
struct NTFS_DE **de_to_replace,
struct ntfs_fnd *fnd)
{
int err;
int level = -1;
CLST vbn;
struct NTFS_DE *e, *te, *re;
struct indx_node *n;
struct INDEX_BUFFER *ib;
*de_to_replace = NULL;
/* Find first leaf entry down from de_next. */
vbn = de_get_vbn(de_next);
for (;;) {
n = NULL;
err = indx_read(indx, ni, vbn, &n);
if (err)
goto out;
e = hdr_first_de(&n->index->ihdr);
fnd_push(fnd, n, e);
if (!de_is_last(e)) {
/*
* This buffer is non-empty, so its first entry
* could be used as the replacement entry.
*/
level = fnd->level - 1;
}
if (!de_has_vcn(e))
break;
/* This buffer is a node. Continue to go down. */
vbn = de_get_vbn(e);
}
if (level == -1)
goto out;
n = fnd->nodes[level];
te = hdr_first_de(&n->index->ihdr);
/* Copy the candidate entry into the replacement entry buffer. */
re = kmalloc(le16_to_cpu(te->size) + sizeof(u64), GFP_NOFS);
if (!re) {
err = -ENOMEM;
goto out;
}
*de_to_replace = re;
memcpy(re, te, le16_to_cpu(te->size));
if (!de_has_vcn(re)) {
/*
* The replacement entry we found doesn't have a sub_vcn.
* increase its size to hold one.
*/
le16_add_cpu(&re->size, sizeof(u64));
re->flags |= NTFS_IE_HAS_SUBNODES;
} else {
/*
* The replacement entry we found was a node entry, which
* means that all its child buffers are empty. Return them
* to the free pool.
*/
indx_free_children(indx, ni, te, true);
}
/*
* Expunge the replacement entry from its former location,
* and then write that buffer.
*/
ib = n->index;
e = hdr_delete_de(&ib->ihdr, te);
fnd->de[level] = e;
indx_write(indx, ni, n, 0);
/* Check to see if this action created an empty leaf. */
if (ib_is_leaf(ib) && ib_is_empty(ib))
return 0;
out:
fnd_clear(fnd);
return err;
}
/*
* indx_delete_entry - Delete an entry from the index.
*/
int indx_delete_entry(struct ntfs_index *indx, struct ntfs_inode *ni,
const void *key, u32 key_len, const void *ctx)
{
int err, diff;
struct INDEX_ROOT *root;
struct INDEX_HDR *hdr;
struct ntfs_fnd *fnd, *fnd2;
struct INDEX_BUFFER *ib;
struct NTFS_DE *e, *re, *next, *prev, *me;
struct indx_node *n, *n2d = NULL;
__le64 sub_vbn;
int level, level2;
struct ATTRIB *attr;
struct mft_inode *mi;
u32 e_size, root_size, new_root_size;
size_t trim_bit;
const struct INDEX_NAMES *in;
fnd = fnd_get();
if (!fnd) {
err = -ENOMEM;
goto out2;
}
fnd2 = fnd_get();
if (!fnd2) {
err = -ENOMEM;
goto out1;
}
root = indx_get_root(indx, ni, &attr, &mi);
if (!root) {
err = -EINVAL;
goto out;
}
/* Locate the entry to remove. */
err = indx_find(indx, ni, root, key, key_len, ctx, &diff, &e, fnd);
if (err)
goto out;
if (!e || diff) {
err = -ENOENT;
goto out;
}
level = fnd->level;
if (level) {
n = fnd->nodes[level - 1];
e = fnd->de[level - 1];
ib = n->index;
hdr = &ib->ihdr;
} else {
hdr = &root->ihdr;
e = fnd->root_de;
n = NULL;
}
e_size = le16_to_cpu(e->size);
if (!de_has_vcn_ex(e)) {
/* The entry to delete is a leaf, so we can just rip it out. */
hdr_delete_de(hdr, e);
if (!level) {
hdr->total = hdr->used;
/* Shrink resident root attribute. */
mi_resize_attr(mi, attr, 0 - e_size);
goto out;
}
indx_write(indx, ni, n, 0);
/*
* Check to see if removing that entry made
* the leaf empty.
*/
if (ib_is_leaf(ib) && ib_is_empty(ib)) {
fnd_pop(fnd);
fnd_push(fnd2, n, e);
}
} else {
/*
* The entry we wish to delete is a node buffer, so we
* have to find a replacement for it.
*/
next = de_get_next(e);
err = indx_get_entry_to_replace(indx, ni, next, &re, fnd2);
if (err)
goto out;
if (re) {
de_set_vbn_le(re, de_get_vbn_le(e));
hdr_delete_de(hdr, e);
err = level ? indx_insert_into_buffer(indx, ni, root,
re, ctx,
fnd->level - 1,
fnd)
: indx_insert_into_root(indx, ni, re, e,
ctx, fnd, 0);
kfree(re);
if (err)
goto out;
} else {
/*
* There is no replacement for the current entry.
* This means that the subtree rooted at its node
* is empty, and can be deleted, which turn means
* that the node can just inherit the deleted
* entry sub_vcn.
*/
indx_free_children(indx, ni, next, true);
de_set_vbn_le(next, de_get_vbn_le(e));
hdr_delete_de(hdr, e);
if (level) {
indx_write(indx, ni, n, 0);
} else {
hdr->total = hdr->used;
/* Shrink resident root attribute. */
mi_resize_attr(mi, attr, 0 - e_size);
}
}
}
/* Delete a branch of tree. */
if (!fnd2 || !fnd2->level)
goto out;
/* Reinit root 'cause it can be changed. */
root = indx_get_root(indx, ni, &attr, &mi);
if (!root) {
err = -EINVAL;
goto out;
}
n2d = NULL;
sub_vbn = fnd2->nodes[0]->index->vbn;
level2 = 0;
level = fnd->level;
hdr = level ? &fnd->nodes[level - 1]->index->ihdr : &root->ihdr;
/* Scan current level. */
for (e = hdr_first_de(hdr);; e = hdr_next_de(hdr, e)) {
if (!e) {
err = -EINVAL;
goto out;
}
if (de_has_vcn(e) && sub_vbn == de_get_vbn_le(e))
break;
if (de_is_last(e)) {
e = NULL;
break;
}
}
if (!e) {
/* Do slow search from root. */
struct indx_node *in;
fnd_clear(fnd);
in = indx_find_buffer(indx, ni, root, sub_vbn, NULL);
if (IS_ERR(in)) {
err = PTR_ERR(in);
goto out;
}
if (in)
fnd_push(fnd, in, NULL);
}
/* Merge fnd2 -> fnd. */
for (level = 0; level < fnd2->level; level++) {
fnd_push(fnd, fnd2->nodes[level], fnd2->de[level]);
fnd2->nodes[level] = NULL;
}
fnd2->level = 0;
hdr = NULL;
for (level = fnd->level; level; level--) {
struct indx_node *in = fnd->nodes[level - 1];
ib = in->index;
if (ib_is_empty(ib)) {
sub_vbn = ib->vbn;
} else {
hdr = &ib->ihdr;
n2d = in;
level2 = level;
break;
}
}
if (!hdr)
hdr = &root->ihdr;
e = hdr_first_de(hdr);
if (!e) {
err = -EINVAL;
goto out;
}
if (hdr != &root->ihdr || !de_is_last(e)) {
prev = NULL;
while (!de_is_last(e)) {
if (de_has_vcn(e) && sub_vbn == de_get_vbn_le(e))
break;
prev = e;
e = hdr_next_de(hdr, e);
if (!e) {
err = -EINVAL;
goto out;
}
}
if (sub_vbn != de_get_vbn_le(e)) {
/*
* Didn't find the parent entry, although this buffer
* is the parent trail. Something is corrupt.
*/
err = -EINVAL;
goto out;
}
if (de_is_last(e)) {
/*
* Since we can't remove the end entry, we'll remove
* its predecessor instead. This means we have to
* transfer the predecessor's sub_vcn to the end entry.
* Note: This index block is not empty, so the
* predecessor must exist.
*/
if (!prev) {
err = -EINVAL;
goto out;
}
if (de_has_vcn(prev)) {
de_set_vbn_le(e, de_get_vbn_le(prev));
} else if (de_has_vcn(e)) {
le16_sub_cpu(&e->size, sizeof(u64));
e->flags &= ~NTFS_IE_HAS_SUBNODES;
le32_sub_cpu(&hdr->used, sizeof(u64));
}
e = prev;
}
/*
* Copy the current entry into a temporary buffer (stripping
* off its down-pointer, if any) and delete it from the current
* buffer or root, as appropriate.
*/
e_size = le16_to_cpu(e->size);
me = kmemdup(e, e_size, GFP_NOFS);
if (!me) {
err = -ENOMEM;
goto out;
}
if (de_has_vcn(me)) {
me->flags &= ~NTFS_IE_HAS_SUBNODES;
le16_sub_cpu(&me->size, sizeof(u64));
}
hdr_delete_de(hdr, e);
if (hdr == &root->ihdr) {
level = 0;
hdr->total = hdr->used;
/* Shrink resident root attribute. */
mi_resize_attr(mi, attr, 0 - e_size);
} else {
indx_write(indx, ni, n2d, 0);
level = level2;
}
/* Mark unused buffers as free. */
trim_bit = -1;
for (; level < fnd->level; level++) {
ib = fnd->nodes[level]->index;
if (ib_is_empty(ib)) {
size_t k = le64_to_cpu(ib->vbn) >>
indx->idx2vbn_bits;
indx_mark_free(indx, ni, k);
if (k < trim_bit)
trim_bit = k;
}
}
fnd_clear(fnd);
/*fnd->root_de = NULL;*/
/*
* Re-insert the entry into the tree.
* Find the spot the tree where we want to insert the new entry.
*/
err = indx_insert_entry(indx, ni, me, ctx, fnd, 0);
kfree(me);
if (err)
goto out;
if (trim_bit != -1)
indx_shrink(indx, ni, trim_bit);
} else {
/*
* This tree needs to be collapsed down to an empty root.
* Recreate the index root as an empty leaf and free all
* the bits the index allocation bitmap.
*/
fnd_clear(fnd);
fnd_clear(fnd2);
in = &s_index_names[indx->type];
err = attr_set_size(ni, ATTR_ALLOC, in->name, in->name_len,
&indx->alloc_run, 0, NULL, false, NULL);
err = ni_remove_attr(ni, ATTR_ALLOC, in->name, in->name_len,
false, NULL);
run_close(&indx->alloc_run);
err = attr_set_size(ni, ATTR_BITMAP, in->name, in->name_len,
&indx->bitmap_run, 0, NULL, false, NULL);
err = ni_remove_attr(ni, ATTR_BITMAP, in->name, in->name_len,
false, NULL);
run_close(&indx->bitmap_run);
root = indx_get_root(indx, ni, &attr, &mi);
if (!root) {
err = -EINVAL;
goto out;
}
root_size = le32_to_cpu(attr->res.data_size);
new_root_size =
sizeof(struct INDEX_ROOT) + sizeof(struct NTFS_DE);
if (new_root_size != root_size &&
!mi_resize_attr(mi, attr, new_root_size - root_size)) {
err = -EINVAL;
goto out;
}
/* Fill first entry. */
e = (struct NTFS_DE *)(root + 1);
e->ref.low = 0;
e->ref.high = 0;
e->ref.seq = 0;
e->size = cpu_to_le16(sizeof(struct NTFS_DE));
e->flags = NTFS_IE_LAST; // 0x02
e->key_size = 0;
e->res = 0;
hdr = &root->ihdr;
hdr->flags = 0;
hdr->used = hdr->total = cpu_to_le32(
new_root_size - offsetof(struct INDEX_ROOT, ihdr));
mi->dirty = true;
}
out:
fnd_put(fnd2);
out1:
fnd_put(fnd);
out2:
return err;
}
/*
* Update duplicated information in directory entry
* 'dup' - info from MFT record
*/
int indx_update_dup(struct ntfs_inode *ni, struct ntfs_sb_info *sbi,
const struct ATTR_FILE_NAME *fname,
const struct NTFS_DUP_INFO *dup, int sync)
{
int err, diff;
struct NTFS_DE *e = NULL;
struct ATTR_FILE_NAME *e_fname;
struct ntfs_fnd *fnd;
struct INDEX_ROOT *root;
struct mft_inode *mi;
struct ntfs_index *indx = &ni->dir;
fnd = fnd_get();
if (!fnd)
return -ENOMEM;
root = indx_get_root(indx, ni, NULL, &mi);
if (!root) {
err = -EINVAL;
goto out;
}
/* Find entry in directory. */
err = indx_find(indx, ni, root, fname, fname_full_size(fname), sbi,
&diff, &e, fnd);
if (err)
goto out;
if (!e) {
err = -EINVAL;
goto out;
}
if (diff) {
err = -EINVAL;
goto out;
}
e_fname = (struct ATTR_FILE_NAME *)(e + 1);
if (!memcmp(&e_fname->dup, dup, sizeof(*dup))) {
/*
* Nothing to update in index! Try to avoid this call.
*/
goto out;
}
memcpy(&e_fname->dup, dup, sizeof(*dup));
if (fnd->level) {
/* Directory entry in index. */
err = indx_write(indx, ni, fnd->nodes[fnd->level - 1], sync);
} else {
/* Directory entry in directory MFT record. */
mi->dirty = true;
if (sync)
err = mi_write(mi, 1);
else
mark_inode_dirty(&ni->vfs_inode);
}
out:
fnd_put(fnd);
return err;
}