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kernel: backport ntfs3 driver from 5.19

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Signed-off-by: Tianling Shen <cnsztl@immortalwrt.org>
This commit is contained in:
lean 2022-09-11 03:34:53 +08:00 committed by Tianling Shen
parent 2b92d89445
commit 2d32c19d1b
No known key found for this signature in database
GPG Key ID: 6850B6345C862176
30 changed files with 30771 additions and 0 deletions
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18
package/kernel/linux/modules/fs.mk
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@ -476,6 +476,24 @@ endef
$(eval $(call KernelPackage,fs-ntfs))
define KernelPackage/fs-ntfs3
SUBMENU:=$(FS_MENU)
TITLE:=NTFS3 Read-Write file system support
DEPENDS:=+kmod-nls-base
KCONFIG:= \
CONFIG_NTFS3_FS \
CONFIG_NTFS3_64BIT_CLUSTER=y \
CONFIG_NTFS3_LZX_XPRESS=y \
CONFIG_NTFS3_FS_POSIX_ACL=y
FILES:=$(LINUX_DIR)/fs/ntfs3/ntfs3.ko
AUTOLOAD:=$(call AutoLoad,30,ntfs3)
endef
define KernelPackage/fs-ntfs3/description
Kernel module for NTFS3 filesystem support
endef
$(eval $(call KernelPackage,fs-ntfs3))
define KernelPackage/fs-reiserfs
SUBMENU:=$(FS_MENU)
TITLE:=ReiserFS filesystem support

40
target/linux/generic/backport-5.4/500-v5.15-fs-ntfs3-Add-NTFS3-in-fs-Kconfig-and-fs-Makefile.patch Normal file
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@ -0,0 +1,40 @@
From e64a5b846cd19f86eae8d8f2708f2e483dc37feb Mon Sep 17 00:00:00 2003
From: Konstantin Komarov <almaz.alexandrovich@paragon-software.com>
Date: Thu, 28 Jan 2021 12:04:54 +0300
Subject: [PATCH 09/11] fs/ntfs3: Add NTFS3 in fs/Kconfig and fs/Makefile
This adds NTFS3 in fs/Kconfig and fs/Makefile
Signed-off-by: Konstantin Komarov <almaz.alexandrovich@paragon-software.com>
---
fs/Kconfig | 1 +
fs/Makefile | 1 +
2 files changed, 2 insertions(+)
diff --git a/fs/Kconfig b/fs/Kconfig
index da524c4d7b7e..0bbad356ab57 100644
--- a/fs/Kconfig
+++ b/fs/Kconfig
@@ -145,6 +145,7 @@ menu "DOS/FAT/EXFAT/NT Filesystems"
source "fs/fat/Kconfig"
source "fs/exfat/Kconfig"
source "fs/ntfs/Kconfig"
+source "fs/ntfs3/Kconfig"
endmenu
endif # BLOCK
diff --git a/fs/Makefile b/fs/Makefile
index 999d1a23f036..4f5242cdaee2 100644
--- a/fs/Makefile
+++ b/fs/Makefile
@@ -100,6 +100,7 @@ obj-$(CONFIG_SYSV_FS) += sysv/
obj-$(CONFIG_CIFS) += cifs/
obj-$(CONFIG_HPFS_FS) += hpfs/
obj-$(CONFIG_NTFS_FS) += ntfs/
+obj-$(CONFIG_NTFS3_FS) += ntfs3/
obj-$(CONFIG_UFS_FS) += ufs/
obj-$(CONFIG_EFS_FS) += efs/
obj-$(CONFIG_JFFS2_FS) += jffs2/
--
2.30.1

46
target/linux/generic/files-5.4/fs/ntfs3/Kconfig Normal file
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@ -0,0 +1,46 @@
# SPDX-License-Identifier: GPL-2.0-only
config NTFS3_FS
tristate "NTFS Read-Write file system support"
select NLS
help
Windows OS native file system (NTFS) support up to NTFS version 3.1.
Y or M enables the NTFS3 driver with full features enabled (read,
write, journal replaying, sparse/compressed files support).
File system type to use on mount is "ntfs3". Module name (M option)
is also "ntfs3".
Documentation: <file:Documentation/filesystems/ntfs3.rst>
config NTFS3_64BIT_CLUSTER
bool "64 bits per NTFS clusters"
depends on NTFS3_FS && 64BIT
help
Windows implementation of ntfs.sys uses 32 bits per clusters.
If activated 64 bits per clusters you will be able to use 4k cluster
for 16T+ volumes. Windows will not be able to mount such volumes.
It is recommended to say N here.
config NTFS3_LZX_XPRESS
bool "activate support of external compressions lzx/xpress"
depends on NTFS3_FS
help
In Windows 10 one can use command "compact" to compress any files.
4 possible variants of compression are: xpress4k, xpress8k, xpress16k and lzx.
If activated you will be able to read such files correctly.
It is recommended to say Y here.
config NTFS3_FS_POSIX_ACL
bool "NTFS POSIX Access Control Lists"
depends on NTFS3_FS
select FS_POSIX_ACL
help
POSIX Access Control Lists (ACLs) support additional access rights
for users and groups beyond the standard owner/group/world scheme,
and this option selects support for ACLs specifically for ntfs
filesystems.
NOTE: this is linux only feature. Windows will ignore these ACLs.
If you don't know what Access Control Lists are, say N.

45
target/linux/generic/files-5.4/fs/ntfs3/Makefile Normal file
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@ -0,0 +1,45 @@
# SPDX-License-Identifier: GPL-2.0
#
# Makefile for the ntfs3 filesystem support.
#
# to check robot warnings
ccflags-y += -Wint-to-pointer-cast \
$(call cc-option,-Wunused-but-set-variable,-Wunused-const-variable) \
$(call cc-option,-Wold-style-declaration,-Wout-of-line-declaration)
obj-$(CONFIG_NTFS3_FS) += ntfs3.o
ntfs3-y := attrib.o \
attrlist.o \
bitfunc.o \
bitmap.o \
dir.o \
fsntfs.o \
frecord.o \
file.o \
fslog.o \
inode.o \
index.o \
lznt.o \
namei.o \
record.o \
run.o \
super.o \
upcase.o \
xattr.o
ntfs3-$(CONFIG_NTFS3_LZX_XPRESS) += $(addprefix lib/,\
decompress_common.o \
lzx_decompress.o \
xpress_decompress.o \
)
ccflags-$(CONFIG_NTFS3_LZX_XPRESS) += -DCONFIG_NTFS3_LZX_XPRESS
ccflags-$(CONFIG_NTFS3_FS_POSIX_ACL) += -DCONFIG_NTFS3_FS_POSIX_ACL
all:
make -C /lib/modules/$(KVERSION)/build M=$(PWD) modules
clean:
make -C /lib/modules/$(KVERSION)/build M=$(PWD) clean

2083
target/linux/generic/files-5.4/fs/ntfs3/attrib.c Normal file
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File diff suppressed because it is too large Load Diff

457
target/linux/generic/files-5.4/fs/ntfs3/attrlist.c Normal file
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@ -0,0 +1,457 @@
// SPDX-License-Identifier: GPL-2.0
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
*/
#include <linux/fs.h>
#include "debug.h"
#include "ntfs.h"
#include "ntfs_fs.h"
/*
* al_is_valid_le
*
* Return: True if @le is valid.
*/
static inline bool al_is_valid_le(const struct ntfs_inode *ni,
struct ATTR_LIST_ENTRY *le)
{
if (!le || !ni->attr_list.le || !ni->attr_list.size)
return false;
return PtrOffset(ni->attr_list.le, le) + le16_to_cpu(le->size) <=
ni->attr_list.size;
}
void al_destroy(struct ntfs_inode *ni)
{
run_close(&ni->attr_list.run);
kfree(ni->attr_list.le);
ni->attr_list.le = NULL;
ni->attr_list.size = 0;
ni->attr_list.dirty = false;
}
/*
* ntfs_load_attr_list
*
* This method makes sure that the ATTRIB list, if present,
* has been properly set up.
*/
int ntfs_load_attr_list(struct ntfs_inode *ni, struct ATTRIB *attr)
{
int err;
size_t lsize;
void *le = NULL;
if (ni->attr_list.size)
return 0;
if (!attr->non_res) {
lsize = le32_to_cpu(attr->res.data_size);
le = kmalloc(al_aligned(lsize), GFP_NOFS);
if (!le) {
err = -ENOMEM;
goto out;
}
memcpy(le, resident_data(attr), lsize);
} else if (attr->nres.svcn) {
err = -EINVAL;
goto out;
} else {
u16 run_off = le16_to_cpu(attr->nres.run_off);
lsize = le64_to_cpu(attr->nres.data_size);
run_init(&ni->attr_list.run);
err = run_unpack_ex(&ni->attr_list.run, ni->mi.sbi, ni->mi.rno,
0, le64_to_cpu(attr->nres.evcn), 0,
Add2Ptr(attr, run_off),
le32_to_cpu(attr->size) - run_off);
if (err < 0)
goto out;
le = kmalloc(al_aligned(lsize), GFP_NOFS);
if (!le) {
err = -ENOMEM;
goto out;
}
err = ntfs_read_run_nb(ni->mi.sbi, &ni->attr_list.run, 0, le,
lsize, NULL);
if (err)
goto out;
}
ni->attr_list.size = lsize;
ni->attr_list.le = le;
return 0;
out:
ni->attr_list.le = le;
al_destroy(ni);
return err;
}
/*
* al_enumerate
*
* Return:
* * The next list le.
* * If @le is NULL then return the first le.
*/
struct ATTR_LIST_ENTRY *al_enumerate(struct ntfs_inode *ni,
struct ATTR_LIST_ENTRY *le)
{
size_t off;
u16 sz;
if (!le) {
le = ni->attr_list.le;
} else {
sz = le16_to_cpu(le->size);
if (sz < sizeof(struct ATTR_LIST_ENTRY)) {
/* Impossible 'cause we should not return such le. */
return NULL;
}
le = Add2Ptr(le, sz);
}
/* Check boundary. */
off = PtrOffset(ni->attr_list.le, le);
if (off + sizeof(struct ATTR_LIST_ENTRY) > ni->attr_list.size) {
/* The regular end of list. */
return NULL;
}
sz = le16_to_cpu(le->size);
/* Check le for errors. */
if (sz < sizeof(struct ATTR_LIST_ENTRY) ||
off + sz > ni->attr_list.size ||
sz < le->name_off + le->name_len * sizeof(short)) {
return NULL;
}
return le;
}
/*
* al_find_le
*
* Find the first le in the list which matches type, name and VCN.
*
* Return: NULL if not found.
*/
struct ATTR_LIST_ENTRY *al_find_le(struct ntfs_inode *ni,
struct ATTR_LIST_ENTRY *le,
const struct ATTRIB *attr)
{
CLST svcn = attr_svcn(attr);
return al_find_ex(ni, le, attr->type, attr_name(attr), attr->name_len,
&svcn);
}
/*
* al_find_ex
*
* Find the first le in the list which matches type, name and VCN.
*
* Return: NULL if not found.
*/
struct ATTR_LIST_ENTRY *al_find_ex(struct ntfs_inode *ni,
struct ATTR_LIST_ENTRY *le,
enum ATTR_TYPE type, const __le16 *name,
u8 name_len, const CLST *vcn)
{
struct ATTR_LIST_ENTRY *ret = NULL;
u32 type_in = le32_to_cpu(type);
while ((le = al_enumerate(ni, le))) {
u64 le_vcn;
int diff = le32_to_cpu(le->type) - type_in;
/* List entries are sorted by type, name and VCN. */
if (diff < 0)
continue;
if (diff > 0)
return ret;
if (le->name_len != name_len)
continue;
le_vcn = le64_to_cpu(le->vcn);
if (!le_vcn) {
/*
* Compare entry names only for entry with vcn == 0.
*/
diff = ntfs_cmp_names(le_name(le), name_len, name,
name_len, ni->mi.sbi->upcase,
true);
if (diff < 0)
continue;
if (diff > 0)
return ret;
}
if (!vcn)
return le;
if (*vcn == le_vcn)
return le;
if (*vcn < le_vcn)
return ret;
ret = le;
}
return ret;
}
/*
* al_find_le_to_insert
*
* Find the first list entry which matches type, name and VCN.
*/
static struct ATTR_LIST_ENTRY *al_find_le_to_insert(struct ntfs_inode *ni,
enum ATTR_TYPE type,
const __le16 *name,
u8 name_len, CLST vcn)
{
struct ATTR_LIST_ENTRY *le = NULL, *prev;
u32 type_in = le32_to_cpu(type);
/* List entries are sorted by type, name and VCN. */
while ((le = al_enumerate(ni, prev = le))) {
int diff = le32_to_cpu(le->type) - type_in;
if (diff < 0)
continue;
if (diff > 0)
return le;
if (!le->vcn) {
/*
* Compare entry names only for entry with vcn == 0.
*/
diff = ntfs_cmp_names(le_name(le), le->name_len, name,
name_len, ni->mi.sbi->upcase,
true);
if (diff < 0)
continue;
if (diff > 0)
return le;
}
if (le64_to_cpu(le->vcn) >= vcn)
return le;
}
return prev ? Add2Ptr(prev, le16_to_cpu(prev->size)) : ni->attr_list.le;
}
/*
* al_add_le
*
* Add an "attribute list entry" to the list.
*/
int al_add_le(struct ntfs_inode *ni, enum ATTR_TYPE type, const __le16 *name,
u8 name_len, CLST svcn, __le16 id, const struct MFT_REF *ref,
struct ATTR_LIST_ENTRY **new_le)
{
int err;
struct ATTRIB *attr;
struct ATTR_LIST_ENTRY *le;
size_t off;
u16 sz;
size_t asize, new_asize, old_size;
u64 new_size;
typeof(ni->attr_list) *al = &ni->attr_list;
/*
* Compute the size of the new 'le'
*/
sz = le_size(name_len);
old_size = al->size;
new_size = old_size + sz;
asize = al_aligned(old_size);
new_asize = al_aligned(new_size);
/* Scan forward to the point at which the new 'le' should be inserted. */
le = al_find_le_to_insert(ni, type, name, name_len, svcn);
off = PtrOffset(al->le, le);
if (new_size > asize) {
void *ptr = kmalloc(new_asize, GFP_NOFS);
if (!ptr)
return -ENOMEM;
memcpy(ptr, al->le, off);
memcpy(Add2Ptr(ptr, off + sz), le, old_size - off);
le = Add2Ptr(ptr, off);
kfree(al->le);
al->le = ptr;
} else {
memmove(Add2Ptr(le, sz), le, old_size - off);
}
*new_le = le;
al->size = new_size;
le->type = type;
le->size = cpu_to_le16(sz);
le->name_len = name_len;
le->name_off = offsetof(struct ATTR_LIST_ENTRY, name);
le->vcn = cpu_to_le64(svcn);
le->ref = *ref;
le->id = id;
memcpy(le->name, name, sizeof(short) * name_len);
err = attr_set_size(ni, ATTR_LIST, NULL, 0, &al->run, new_size,
&new_size, true, &attr);
if (err) {
/* Undo memmove above. */
memmove(le, Add2Ptr(le, sz), old_size - off);
al->size = old_size;
return err;
}
al->dirty = true;
if (attr && attr->non_res) {
err = ntfs_sb_write_run(ni->mi.sbi, &al->run, 0, al->le,
al->size, 0);
if (err)
return err;
al->dirty = false;
}
return 0;
}
/*
* al_remove_le - Remove @le from attribute list.
*/
bool al_remove_le(struct ntfs_inode *ni, struct ATTR_LIST_ENTRY *le)
{
u16 size;
size_t off;
typeof(ni->attr_list) *al = &ni->attr_list;
if (!al_is_valid_le(ni, le))
return false;
/* Save on stack the size of 'le' */
size = le16_to_cpu(le->size);
off = PtrOffset(al->le, le);
memmove(le, Add2Ptr(le, size), al->size - (off + size));
al->size -= size;
al->dirty = true;
return true;
}
/*
* al_delete_le - Delete first le from the list which matches its parameters.
*/
bool al_delete_le(struct ntfs_inode *ni, enum ATTR_TYPE type, CLST vcn,
const __le16 *name, size_t name_len,
const struct MFT_REF *ref)
{
u16 size;
struct ATTR_LIST_ENTRY *le;
size_t off;
typeof(ni->attr_list) *al = &ni->attr_list;
/* Scan forward to the first le that matches the input. */
le = al_find_ex(ni, NULL, type, name, name_len, &vcn);
if (!le)
return false;
off = PtrOffset(al->le, le);
next:
if (off >= al->size)
return false;
if (le->type != type)
return false;
if (le->name_len != name_len)
return false;
if (name_len && ntfs_cmp_names(le_name(le), name_len, name, name_len,
ni->mi.sbi->upcase, true))
return false;
if (le64_to_cpu(le->vcn) != vcn)
return false;
/*
* The caller specified a segment reference, so we have to
* scan through the matching entries until we find that segment
* reference or we run of matching entries.
*/
if (ref && memcmp(ref, &le->ref, sizeof(*ref))) {
off += le16_to_cpu(le->size);
le = Add2Ptr(al->le, off);
goto next;
}
/* Save on stack the size of 'le'. */
size = le16_to_cpu(le->size);
/* Delete the le. */
memmove(le, Add2Ptr(le, size), al->size - (off + size));
al->size -= size;
al->dirty = true;
return true;
}
int al_update(struct ntfs_inode *ni, int sync)
{
int err;
struct ATTRIB *attr;
typeof(ni->attr_list) *al = &ni->attr_list;
if (!al->dirty || !al->size)
return 0;
/*
* Attribute list increased on demand in al_add_le.
* Attribute list decreased here.
*/
err = attr_set_size(ni, ATTR_LIST, NULL, 0, &al->run, al->size, NULL,
false, &attr);
if (err)
goto out;
if (!attr->non_res) {
memcpy(resident_data(attr), al->le, al->size);
} else {
err = ntfs_sb_write_run(ni->mi.sbi, &al->run, 0, al->le,
al->size, sync);
if (err)
goto out;
attr->nres.valid_size = attr->nres.data_size;
}
ni->mi.dirty = true;
al->dirty = false;
out:
return err;
}

128
target/linux/generic/files-5.4/fs/ntfs3/bitfunc.c Normal file
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@ -0,0 +1,128 @@
// SPDX-License-Identifier: GPL-2.0
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
*/
#include <linux/types.h>
#include "ntfs_fs.h"
#define BITS_IN_SIZE_T (sizeof(size_t) * 8)
/*
* fill_mask[i] - first i bits are '1' , i = 0,1,2,3,4,5,6,7,8
* fill_mask[i] = 0xFF >> (8-i)
*/
static const u8 fill_mask[] = { 0x00, 0x01, 0x03, 0x07, 0x0F,
0x1F, 0x3F, 0x7F, 0xFF };
/*
* zero_mask[i] - first i bits are '0' , i = 0,1,2,3,4,5,6,7,8
* zero_mask[i] = 0xFF << i
*/
static const u8 zero_mask[] = { 0xFF, 0xFE, 0xFC, 0xF8, 0xF0,
0xE0, 0xC0, 0x80, 0x00 };
/*
* are_bits_clear
*
* Return: True if all bits [bit, bit+nbits) are zeros "0".
*/
bool are_bits_clear(const ulong *lmap, size_t bit, size_t nbits)
{
size_t pos = bit & 7;
const u8 *map = (u8 *)lmap + (bit >> 3);
if (pos) {
if (8 - pos >= nbits)
return !nbits || !(*map & fill_mask[pos + nbits] &
zero_mask[pos]);
if (*map++ & zero_mask[pos])
return false;
nbits -= 8 - pos;
}
pos = ((size_t)map) & (sizeof(size_t) - 1);
if (pos) {
pos = sizeof(size_t) - pos;
if (nbits >= pos * 8) {
for (nbits -= pos * 8; pos; pos--, map++) {
if (*map)
return false;
}
}
}
for (pos = nbits / BITS_IN_SIZE_T; pos; pos--, map += sizeof(size_t)) {
if (*((size_t *)map))
return false;
}
for (pos = (nbits % BITS_IN_SIZE_T) >> 3; pos; pos--, map++) {
if (*map)
return false;
}
pos = nbits & 7;
if (pos && (*map & fill_mask[pos]))
return false;
return true;
}
/*
* are_bits_set
*
* Return: True if all bits [bit, bit+nbits) are ones "1".
*/
bool are_bits_set(const ulong *lmap, size_t bit, size_t nbits)
{
u8 mask;
size_t pos = bit & 7;
const u8 *map = (u8 *)lmap + (bit >> 3);
if (pos) {
if (8 - pos >= nbits) {
mask = fill_mask[pos + nbits] & zero_mask[pos];
return !nbits || (*map & mask) == mask;
}
mask = zero_mask[pos];
if ((*map++ & mask) != mask)
return false;
nbits -= 8 - pos;
}
pos = ((size_t)map) & (sizeof(size_t) - 1);
if (pos) {
pos = sizeof(size_t) - pos;
if (nbits >= pos * 8) {
for (nbits -= pos * 8; pos; pos--, map++) {
if (*map != 0xFF)
return false;
}
}
}
for (pos = nbits / BITS_IN_SIZE_T; pos; pos--, map += sizeof(size_t)) {
if (*((size_t *)map) != MINUS_ONE_T)
return false;
}
for (pos = (nbits % BITS_IN_SIZE_T) >> 3; pos; pos--, map++) {
if (*map != 0xFF)
return false;
}
pos = nbits & 7;
if (pos) {
mask = fill_mask[pos];
if ((*map & mask) != mask)
return false;
}
return true;
}

1491
target/linux/generic/files-5.4/fs/ntfs3/bitmap.c Normal file
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55
target/linux/generic/files-5.4/fs/ntfs3/debug.h Normal file
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/* SPDX-License-Identifier: GPL-2.0 */
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
* Useful functions for debugging.
*
*/
// clang-format off
#ifndef _LINUX_NTFS3_DEBUG_H
#define _LINUX_NTFS3_DEBUG_H
struct super_block;
struct inode;
#ifndef Add2Ptr
#define Add2Ptr(P, I) ((void *)((u8 *)(P) + (I)))
#define PtrOffset(B, O) ((size_t)((size_t)(O) - (size_t)(B)))
#endif
#ifdef CONFIG_PRINTK
__printf(2, 3)
void ntfs_printk(const struct super_block *sb, const char *fmt, ...);
__printf(2, 3)
void ntfs_inode_printk(struct inode *inode, const char *fmt, ...);
#else
static inline __printf(2, 3)
void ntfs_printk(const struct super_block *sb, const char *fmt, ...)
{
}
static inline __printf(2, 3)
void ntfs_inode_printk(struct inode *inode, const char *fmt, ...)
{
}
#endif
/*
* Logging macros. Thanks Joe Perches <joe@perches.com> for implementation.
*/
#define ntfs_err(sb, fmt, ...) ntfs_printk(sb, KERN_ERR fmt, ##__VA_ARGS__)
#define ntfs_warn(sb, fmt, ...) ntfs_printk(sb, KERN_WARNING fmt, ##__VA_ARGS__)
#define ntfs_info(sb, fmt, ...) ntfs_printk(sb, KERN_INFO fmt, ##__VA_ARGS__)
#define ntfs_notice(sb, fmt, ...) \
ntfs_printk(sb, KERN_NOTICE fmt, ##__VA_ARGS__)
#define ntfs_inode_err(inode, fmt, ...) \
ntfs_inode_printk(inode, KERN_ERR fmt, ##__VA_ARGS__)
#define ntfs_inode_warn(inode, fmt, ...) \
ntfs_inode_printk(inode, KERN_WARNING fmt, ##__VA_ARGS__)
#endif /* _LINUX_NTFS3_DEBUG_H */
// clang-format on

593
target/linux/generic/files-5.4/fs/ntfs3/dir.c Normal file
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// SPDX-License-Identifier: GPL-2.0
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
* Directory handling functions for NTFS-based filesystems.
*
*/
#include <linux/fs.h>
#include <linux/nls.h>
#include "debug.h"
#include "ntfs.h"
#include "ntfs_fs.h"
/* Convert little endian UTF-16 to NLS string. */
int ntfs_utf16_to_nls(struct ntfs_sb_info *sbi, const __le16 *name, u32 len,
u8 *buf, int buf_len)
{
int ret, warn;
u8 *op;
struct nls_table *nls = sbi->options->nls;
static_assert(sizeof(wchar_t) == sizeof(__le16));
if (!nls) {
/* UTF-16 -> UTF-8 */
ret = utf16s_to_utf8s(name, len, UTF16_LITTLE_ENDIAN, buf,
buf_len);
buf[ret] = '\0';
return ret;
}
op = buf;
warn = 0;
while (len--) {
u16 ec;
int charlen;
char dump[5];
if (buf_len < NLS_MAX_CHARSET_SIZE) {
ntfs_warn(sbi->sb,
"filename was truncated while converting.");
break;
}
ec = le16_to_cpu(*name++);
charlen = nls->uni2char(ec, op, buf_len);
if (charlen > 0) {
op += charlen;
buf_len -= charlen;
continue;
}
*op++ = '_';
buf_len -= 1;
if (warn)
continue;
warn = 1;
hex_byte_pack(&dump[0], ec >> 8);
hex_byte_pack(&dump[2], ec);
dump[4] = 0;
ntfs_err(sbi->sb, "failed to convert \"%s\" to %s", dump,
nls->charset);
}
*op = '\0';
return op - buf;
}
// clang-format off
#define PLANE_SIZE 0x00010000
#define SURROGATE_PAIR 0x0000d800
#define SURROGATE_LOW 0x00000400
#define SURROGATE_BITS 0x000003ff
// clang-format on
/*
* put_utf16 - Modified version of put_utf16 from fs/nls/nls_base.c
*
* Function is sparse warnings free.
*/
static inline void put_utf16(wchar_t *s, unsigned int c,
enum utf16_endian endian)
{
static_assert(sizeof(wchar_t) == sizeof(__le16));
static_assert(sizeof(wchar_t) == sizeof(__be16));
switch (endian) {
default:
*s = (wchar_t)c;
break;
case UTF16_LITTLE_ENDIAN:
*(__le16 *)s = __cpu_to_le16(c);
break;
case UTF16_BIG_ENDIAN:
*(__be16 *)s = __cpu_to_be16(c);
break;
}
}
/*
* _utf8s_to_utf16s
*
* Modified version of 'utf8s_to_utf16s' allows to
* detect -ENAMETOOLONG without writing out of expected maximum.
*/
static int _utf8s_to_utf16s(const u8 *s, int inlen, enum utf16_endian endian,
wchar_t *pwcs, int maxout)
{
u16 *op;
int size;
unicode_t u;
op = pwcs;
while (inlen > 0 && *s) {
if (*s & 0x80) {
size = utf8_to_utf32(s, inlen, &u);
if (size < 0)
return -EINVAL;
s += size;
inlen -= size;
if (u >= PLANE_SIZE) {
if (maxout < 2)
return -ENAMETOOLONG;
u -= PLANE_SIZE;
put_utf16(op++,
SURROGATE_PAIR |
((u >> 10) & SURROGATE_BITS),
endian);
put_utf16(op++,
SURROGATE_PAIR | SURROGATE_LOW |
(u & SURROGATE_BITS),
endian);
maxout -= 2;
} else {
if (maxout < 1)
return -ENAMETOOLONG;
put_utf16(op++, u, endian);
maxout--;
}
} else {
if (maxout < 1)
return -ENAMETOOLONG;
put_utf16(op++, *s++, endian);
inlen--;
maxout--;
}
}
return op - pwcs;
}
/*
* ntfs_nls_to_utf16 - Convert input string to UTF-16.
* @name: Input name.
* @name_len: Input name length.
* @uni: Destination memory.
* @max_ulen: Destination memory.
* @endian: Endian of target UTF-16 string.
*
* This function is called:
* - to create NTFS name
* - to create symlink
*
* Return: UTF-16 string length or error (if negative).
*/
int ntfs_nls_to_utf16(struct ntfs_sb_info *sbi, const u8 *name, u32 name_len,
struct cpu_str *uni, u32 max_ulen,
enum utf16_endian endian)
{
int ret, slen;
const u8 *end;
struct nls_table *nls = sbi->options->nls;
u16 *uname = uni->name;
static_assert(sizeof(wchar_t) == sizeof(u16));
if (!nls) {
/* utf8 -> utf16 */
ret = _utf8s_to_utf16s(name, name_len, endian, uname, max_ulen);
uni->len = ret;
return ret;
}
for (ret = 0, end = name + name_len; name < end; ret++, name += slen) {
if (ret >= max_ulen)
return -ENAMETOOLONG;
slen = nls->char2uni(name, end - name, uname + ret);
if (!slen)
return -EINVAL;
if (slen < 0)
return slen;
}
#ifdef __BIG_ENDIAN
if (endian == UTF16_LITTLE_ENDIAN) {
int i = ret;
while (i--) {
__cpu_to_le16s(uname);
uname++;
}
}
#else
if (endian == UTF16_BIG_ENDIAN) {
int i = ret;
while (i--) {
__cpu_to_be16s(uname);
uname++;
}
}
#endif
uni->len = ret;
return ret;
}
/*
* dir_search_u - Helper function.
*/
struct inode *dir_search_u(struct inode *dir, const struct cpu_str *uni,
struct ntfs_fnd *fnd)
{
int err = 0;
struct super_block *sb = dir->i_sb;
struct ntfs_sb_info *sbi = sb->s_fs_info;
struct ntfs_inode *ni = ntfs_i(dir);
struct NTFS_DE *e;
int diff;
struct inode *inode = NULL;
struct ntfs_fnd *fnd_a = NULL;
if (!fnd) {
fnd_a = fnd_get();
if (!fnd_a) {
err = -ENOMEM;
goto out;
}
fnd = fnd_a;
}
err = indx_find(&ni->dir, ni, NULL, uni, 0, sbi, &diff, &e, fnd);
if (err)
goto out;
if (diff) {
err = -ENOENT;
goto out;
}
inode = ntfs_iget5(sb, &e->ref, uni);
if (!IS_ERR(inode) && is_bad_inode(inode)) {
iput(inode);
err = -EINVAL;
}
out:
fnd_put(fnd_a);
return err == -ENOENT ? NULL : err ? ERR_PTR(err) : inode;
}
static inline int ntfs_filldir(struct ntfs_sb_info *sbi, struct ntfs_inode *ni,
const struct NTFS_DE *e, u8 *name,
struct dir_context *ctx)
{
const struct ATTR_FILE_NAME *fname;
unsigned long ino;
int name_len;
u32 dt_type;
fname = Add2Ptr(e, sizeof(struct NTFS_DE));
if (fname->type == FILE_NAME_DOS)
return 0;
if (!mi_is_ref(&ni->mi, &fname->home))
return 0;
ino = ino_get(&e->ref);
if (ino == MFT_REC_ROOT)
return 0;
/* Skip meta files. Unless option to show metafiles is set. */
if (!sbi->options->showmeta && ntfs_is_meta_file(sbi, ino))
return 0;
if (sbi->options->nohidden && (fname->dup.fa & FILE_ATTRIBUTE_HIDDEN))
return 0;
name_len = ntfs_utf16_to_nls(sbi, fname->name, fname->name_len, name,
PATH_MAX);
if (name_len <= 0) {
ntfs_warn(sbi->sb, "failed to convert name for inode %lx.",
ino);
return 0;
}
dt_type = (fname->dup.fa & FILE_ATTRIBUTE_DIRECTORY) ? DT_DIR : DT_REG;
return !dir_emit(ctx, (s8 *)name, name_len, ino, dt_type);
}
/*
* ntfs_read_hdr - Helper function for ntfs_readdir().
*/
static int ntfs_read_hdr(struct ntfs_sb_info *sbi, struct ntfs_inode *ni,
const struct INDEX_HDR *hdr, u64 vbo, u64 pos,
u8 *name, struct dir_context *ctx)
{
int err;
const struct NTFS_DE *e;
u32 e_size;
u32 end = le32_to_cpu(hdr->used);
u32 off = le32_to_cpu(hdr->de_off);
for (;; off += e_size) {
if (off + sizeof(struct NTFS_DE) > end)
return -1;
e = Add2Ptr(hdr, off);
e_size = le16_to_cpu(e->size);
if (e_size < sizeof(struct NTFS_DE) || off + e_size > end)
return -1;
if (de_is_last(e))
return 0;
/* Skip already enumerated. */
if (vbo + off < pos)
continue;
if (le16_to_cpu(e->key_size) < SIZEOF_ATTRIBUTE_FILENAME)
return -1;
ctx->pos = vbo + off;
/* Submit the name to the filldir callback. */
err = ntfs_filldir(sbi, ni, e, name, ctx);
if (err)
return err;
}
}
/*
* ntfs_readdir - file_operations::iterate_shared
*
* Use non sorted enumeration.
* We have an example of broken volume where sorted enumeration
* counts each name twice.
*/
static int ntfs_readdir(struct file *file, struct dir_context *ctx)
{
const struct INDEX_ROOT *root;
u64 vbo;
size_t bit;
loff_t eod;
int err = 0;
struct inode *dir = file_inode(file);
struct ntfs_inode *ni = ntfs_i(dir);
struct super_block *sb = dir->i_sb;
struct ntfs_sb_info *sbi = sb->s_fs_info;
loff_t i_size = i_size_read(dir);
u32 pos = ctx->pos;
u8 *name = NULL;
struct indx_node *node = NULL;
u8 index_bits = ni->dir.index_bits;
/* Name is a buffer of PATH_MAX length. */
static_assert(NTFS_NAME_LEN * 4 < PATH_MAX);
eod = i_size + sbi->record_size;
if (pos >= eod)
return 0;
if (!dir_emit_dots(file, ctx))
return 0;
/* Allocate PATH_MAX bytes. */
name = __getname();
if (!name)
return -ENOMEM;
if (!ni->mi_loaded && ni->attr_list.size) {
/*
* Directory inode is locked for read.
* Load all subrecords to avoid 'write' access to 'ni' during
* directory reading.
*/
ni_lock(ni);
if (!ni->mi_loaded && ni->attr_list.size) {
err = ni_load_all_mi(ni);
if (!err)
ni->mi_loaded = true;
}
ni_unlock(ni);
if (err)
goto out;
}
root = indx_get_root(&ni->dir, ni, NULL, NULL);
if (!root) {
err = -EINVAL;
goto out;
}
if (pos >= sbi->record_size) {
bit = (pos - sbi->record_size) >> index_bits;
} else {
err = ntfs_read_hdr(sbi, ni, &root->ihdr, 0, pos, name, ctx);
if (err)
goto out;
bit = 0;
}
if (!i_size) {
ctx->pos = eod;
goto out;
}
for (;;) {
vbo = (u64)bit << index_bits;
if (vbo >= i_size) {
ctx->pos = eod;
goto out;
}
err = indx_used_bit(&ni->dir, ni, &bit);
if (err)
goto out;
if (bit == MINUS_ONE_T) {
ctx->pos = eod;
goto out;
}
vbo = (u64)bit << index_bits;
if (vbo >= i_size) {
ntfs_inode_err(dir, "Looks like your dir is corrupt");
err = -EINVAL;
goto out;
}
err = indx_read(&ni->dir, ni, bit << ni->dir.idx2vbn_bits,
&node);
if (err)
goto out;
err = ntfs_read_hdr(sbi, ni, &node->index->ihdr,
vbo + sbi->record_size, pos, name, ctx);
if (err)
goto out;
bit += 1;
}
out:
__putname(name);
put_indx_node(node);
if (err == -ENOENT) {
err = 0;
ctx->pos = pos;
}
return err;
}
static int ntfs_dir_count(struct inode *dir, bool *is_empty, size_t *dirs,
size_t *files)
{
int err = 0;
struct ntfs_inode *ni = ntfs_i(dir);
struct NTFS_DE *e = NULL;
struct INDEX_ROOT *root;
struct INDEX_HDR *hdr;
const struct ATTR_FILE_NAME *fname;
u32 e_size, off, end;
u64 vbo = 0;
size_t drs = 0, fles = 0, bit = 0;
loff_t i_size = ni->vfs_inode.i_size;
struct indx_node *node = NULL;
u8 index_bits = ni->dir.index_bits;
if (is_empty)
*is_empty = true;
root = indx_get_root(&ni->dir, ni, NULL, NULL);
if (!root)
return -EINVAL;
hdr = &root->ihdr;
for (;;) {
end = le32_to_cpu(hdr->used);
off = le32_to_cpu(hdr->de_off);
for (; off + sizeof(struct NTFS_DE) <= end; off += e_size) {
e = Add2Ptr(hdr, off);
e_size = le16_to_cpu(e->size);
if (e_size < sizeof(struct NTFS_DE) ||
off + e_size > end)
break;
if (de_is_last(e))
break;
fname = de_get_fname(e);
if (!fname)
continue;
if (fname->type == FILE_NAME_DOS)
continue;
if (is_empty) {
*is_empty = false;
if (!dirs && !files)
goto out;
}
if (fname->dup.fa & FILE_ATTRIBUTE_DIRECTORY)
drs += 1;
else
fles += 1;
}
if (vbo >= i_size)
goto out;
err = indx_used_bit(&ni->dir, ni, &bit);
if (err)
goto out;
if (bit == MINUS_ONE_T)
goto out;
vbo = (u64)bit << index_bits;
if (vbo >= i_size)
goto out;
err = indx_read(&ni->dir, ni, bit << ni->dir.idx2vbn_bits,
&node);
if (err)
goto out;
hdr = &node->index->ihdr;
bit += 1;
vbo = (u64)bit << ni->dir.idx2vbn_bits;
}
out:
put_indx_node(node);
if (dirs)
*dirs = drs;
if (files)
*files = fles;
return err;
}
bool dir_is_empty(struct inode *dir)
{
bool is_empty = false;
ntfs_dir_count(dir, &is_empty, NULL, NULL);
return is_empty;
}
// clang-format off
const struct file_operations ntfs_dir_operations = {
.llseek = generic_file_llseek,
.read = generic_read_dir,
.iterate_shared = ntfs_readdir,
.fsync = generic_file_fsync,
.open = ntfs_file_open,
};
// clang-format on

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// SPDX-License-Identifier: GPL-2.0-or-later
/*
* decompress_common.c - Code shared by the XPRESS and LZX decompressors
*
* Copyright (C) 2015 Eric Biggers
*/
#include "decompress_common.h"
/*
* make_huffman_decode_table() -
*
* Build a decoding table for a canonical prefix code, or "Huffman code".
*
* This is an internal function, not part of the library API!
*
* This takes as input the length of the codeword for each symbol in the
* alphabet and produces as output a table that can be used for fast
* decoding of prefix-encoded symbols using read_huffsym().
*
* Strictly speaking, a canonical prefix code might not be a Huffman
* code. But this algorithm will work either way; and in fact, since
* Huffman codes are defined in terms of symbol frequencies, there is no
* way for the decompressor to know whether the code is a true Huffman
* code or not until all symbols have been decoded.
*
* Because the prefix code is assumed to be "canonical", it can be
* reconstructed directly from the codeword lengths. A prefix code is
* canonical if and only if a longer codeword never lexicographically
* precedes a shorter codeword, and the lexicographic ordering of
* codewords of the same length is the same as the lexicographic ordering
* of the corresponding symbols. Consequently, we can sort the symbols
* primarily by codeword length and secondarily by symbol value, then
* reconstruct the prefix code by generating codewords lexicographically
* in that order.
*
* This function does not, however, generate the prefix code explicitly.
* Instead, it directly builds a table for decoding symbols using the
* code. The basic idea is this: given the next 'max_codeword_len' bits
* in the input, we can look up the decoded symbol by indexing a table
* containing 2**max_codeword_len entries. A codeword with length
* 'max_codeword_len' will have exactly one entry in this table, whereas
* a codeword shorter than 'max_codeword_len' will have multiple entries
* in this table. Precisely, a codeword of length n will be represented
* by 2**(max_codeword_len - n) entries in this table. The 0-based index
* of each such entry will contain the corresponding codeword as a prefix
* when zero-padded on the left to 'max_codeword_len' binary digits.
*
* That's the basic idea, but we implement two optimizations regarding
* the format of the decode table itself:
*
* - For many compression formats, the maximum codeword length is too
* long for it to be efficient to build the full decoding table
* whenever a new prefix code is used. Instead, we can build the table
* using only 2**table_bits entries, where 'table_bits' is some number
* less than or equal to 'max_codeword_len'. Then, only codewords of
* length 'table_bits' and shorter can be directly looked up. For
* longer codewords, the direct lookup instead produces the root of a
* binary tree. Using this tree, the decoder can do traditional
* bit-by-bit decoding of the remainder of the codeword. Child nodes
* are allocated in extra entries at the end of the table; leaf nodes
* contain symbols. Note that the long-codeword case is, in general,
* not performance critical, since in Huffman codes the most frequently
* used symbols are assigned the shortest codeword lengths.
*
* - When we decode a symbol using a direct lookup of the table, we still
* need to know its length so that the bitstream can be advanced by the
* appropriate number of bits. The simple solution is to simply retain
* the 'lens' array and use the decoded symbol as an index into it.
* However, this requires two separate array accesses in the fast path.
* The optimization is to store the length directly in the decode
* table. We use the bottom 11 bits for the symbol and the top 5 bits
* for the length. In addition, to combine this optimization with the
* previous one, we introduce a special case where the top 2 bits of
* the length are both set if the entry is actually the root of a
* binary tree.
*
* @decode_table:
* The array in which to create the decoding table. This must have
* a length of at least ((2**table_bits) + 2 * num_syms) entries.
*
* @num_syms:
* The number of symbols in the alphabet; also, the length of the
* 'lens' array. Must be less than or equal to 2048.
*
* @table_bits:
* The order of the decode table size, as explained above. Must be
* less than or equal to 13.
*
* @lens:
* An array of length @num_syms, indexable by symbol, that gives the
* length of the codeword, in bits, for that symbol. The length can
* be 0, which means that the symbol does not have a codeword
* assigned.
*
* @max_codeword_len:
* The longest codeword length allowed in the compression format.
* All entries in 'lens' must be less than or equal to this value.
* This must be less than or equal to 23.
*
* @working_space
* A temporary array of length '2 * (max_codeword_len + 1) +
* num_syms'.
*
* Returns 0 on success, or -1 if the lengths do not form a valid prefix
* code.
*/
int make_huffman_decode_table(u16 decode_table[], const u32 num_syms,
const u32 table_bits, const u8 lens[],
const u32 max_codeword_len,
u16 working_space[])
{
const u32 table_num_entries = 1 << table_bits;
u16 * const len_counts = &working_space[0];
u16 * const offsets = &working_space[1 * (max_codeword_len + 1)];
u16 * const sorted_syms = &working_space[2 * (max_codeword_len + 1)];
int left;
void *decode_table_ptr;
u32 sym_idx;
u32 codeword_len;
u32 stores_per_loop;
u32 decode_table_pos;
u32 len;
u32 sym;
/* Count how many symbols have each possible codeword length.
* Note that a length of 0 indicates the corresponding symbol is not
* used in the code and therefore does not have a codeword.
*/
for (len = 0; len <= max_codeword_len; len++)
len_counts[len] = 0;
for (sym = 0; sym < num_syms; sym++)
len_counts[lens[sym]]++;
/* We can assume all lengths are <= max_codeword_len, but we
* cannot assume they form a valid prefix code. A codeword of
* length n should require a proportion of the codespace equaling
* (1/2)^n. The code is valid if and only if the codespace is
* exactly filled by the lengths, by this measure.
*/
left = 1;
for (len = 1; len <= max_codeword_len; len++) {
left <<= 1;
left -= len_counts[len];
if (left < 0) {
/* The lengths overflow the codespace; that is, the code
* is over-subscribed.
*/
return -1;
}
}
if (left) {
/* The lengths do not fill the codespace; that is, they form an
* incomplete set.
*/
if (left == (1 << max_codeword_len)) {
/* The code is completely empty. This is arguably
* invalid, but in fact it is valid in LZX and XPRESS,
* so we must allow it. By definition, no symbols can
* be decoded with an empty code. Consequently, we
* technically don't even need to fill in the decode
* table. However, to avoid accessing uninitialized
* memory if the algorithm nevertheless attempts to
* decode symbols using such a code, we zero out the
* decode table.
*/
memset(decode_table, 0,
table_num_entries * sizeof(decode_table[0]));
return 0;
}
return -1;
}
/* Sort the symbols primarily by length and secondarily by symbol order.
*/
/* Initialize 'offsets' so that offsets[len] for 1 <= len <=
* max_codeword_len is the number of codewords shorter than 'len' bits.
*/
offsets[1] = 0;
for (len = 1; len < max_codeword_len; len++)
offsets[len + 1] = offsets[len] + len_counts[len];
/* Use the 'offsets' array to sort the symbols. Note that we do not
* include symbols that are not used in the code. Consequently, fewer
* than 'num_syms' entries in 'sorted_syms' may be filled.
*/
for (sym = 0; sym < num_syms; sym++)
if (lens[sym])
sorted_syms[offsets[lens[sym]]++] = sym;
/* Fill entries for codewords with length <= table_bits
* --- that is, those short enough for a direct mapping.
*
* The table will start with entries for the shortest codeword(s), which
* have the most entries. From there, the number of entries per
* codeword will decrease.
*/
decode_table_ptr = decode_table;
sym_idx = 0;
codeword_len = 1;
stores_per_loop = (1 << (table_bits - codeword_len));
for (; stores_per_loop != 0; codeword_len++, stores_per_loop >>= 1) {
u32 end_sym_idx = sym_idx + len_counts[codeword_len];
for (; sym_idx < end_sym_idx; sym_idx++) {
u16 entry;
u16 *p;
u32 n;
entry = ((u32)codeword_len << 11) | sorted_syms[sym_idx];
p = (u16 *)decode_table_ptr;
n = stores_per_loop;
do {
*p++ = entry;
} while (--n);
decode_table_ptr = p;
}
}
/* If we've filled in the entire table, we are done. Otherwise,
* there are codewords longer than table_bits for which we must
* generate binary trees.
*/
decode_table_pos = (u16 *)decode_table_ptr - decode_table;
if (decode_table_pos != table_num_entries) {
u32 j;
u32 next_free_tree_slot;
u32 cur_codeword;
/* First, zero out the remaining entries. This is
* necessary so that these entries appear as
* "unallocated" in the next part. Each of these entries
* will eventually be filled with the representation of
* the root node of a binary tree.
*/
j = decode_table_pos;
do {
decode_table[j] = 0;
} while (++j != table_num_entries);
/* We allocate child nodes starting at the end of the
* direct lookup table. Note that there should be
* 2*num_syms extra entries for this purpose, although
* fewer than this may actually be needed.
*/
next_free_tree_slot = table_num_entries;
/* Iterate through each codeword with length greater than
* 'table_bits', primarily in order of codeword length
* and secondarily in order of symbol.
*/
for (cur_codeword = decode_table_pos << 1;
codeword_len <= max_codeword_len;
codeword_len++, cur_codeword <<= 1) {
u32 end_sym_idx = sym_idx + len_counts[codeword_len];
for (; sym_idx < end_sym_idx; sym_idx++, cur_codeword++) {
/* 'sorted_sym' is the symbol represented by the
* codeword.
*/
u32 sorted_sym = sorted_syms[sym_idx];
u32 extra_bits = codeword_len - table_bits;
u32 node_idx = cur_codeword >> extra_bits;
/* Go through each bit of the current codeword
* beyond the prefix of length @table_bits and
* walk the appropriate binary tree, allocating
* any slots that have not yet been allocated.
*
* Note that the 'pointer' entry to the binary
* tree, which is stored in the direct lookup
* portion of the table, is represented
* identically to other internal (non-leaf)
* nodes of the binary tree; it can be thought
* of as simply the root of the tree. The
* representation of these internal nodes is
* simply the index of the left child combined
* with the special bits 0xC000 to distinguish
* the entry from direct mapping and leaf node
* entries.
*/
do {
/* At least one bit remains in the
* codeword, but the current node is an
* unallocated leaf. Change it to an
* internal node.
*/
if (decode_table[node_idx] == 0) {
decode_table[node_idx] =
next_free_tree_slot | 0xC000;
decode_table[next_free_tree_slot++] = 0;
decode_table[next_free_tree_slot++] = 0;
}
/* Go to the left child if the next bit
* in the codeword is 0; otherwise go to
* the right child.
*/
node_idx = decode_table[node_idx] & 0x3FFF;
--extra_bits;
node_idx += (cur_codeword >> extra_bits) & 1;
} while (extra_bits != 0);
/* We've traversed the tree using the entire
* codeword, and we're now at the entry where
* the actual symbol will be stored. This is
* distinguished from internal nodes by not
* having its high two bits set.
*/
decode_table[node_idx] = sorted_sym;
}
}
}
return 0;
}

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/* SPDX-License-Identifier: GPL-2.0-or-later */
/*
* decompress_common.h - Code shared by the XPRESS and LZX decompressors
*
* Copyright (C) 2015 Eric Biggers
*/
#ifndef _LINUX_NTFS3_LIB_DECOMPRESS_COMMON_H
#define _LINUX_NTFS3_LIB_DECOMPRESS_COMMON_H
#include <linux/string.h>
#include <linux/compiler.h>
#include <linux/types.h>
#include <linux/slab.h>
#include <asm/unaligned.h>
/* "Force inline" macro (not required, but helpful for performance) */
#define forceinline __always_inline
/* Enable whole-word match copying on selected architectures */
#if defined(__i386__) || defined(__x86_64__) || defined(__ARM_FEATURE_UNALIGNED)
# define FAST_UNALIGNED_ACCESS
#endif
/* Size of a machine word */
#define WORDBYTES (sizeof(size_t))
static forceinline void
copy_unaligned_word(const void *src, void *dst)
{
put_unaligned(get_unaligned((const size_t *)src), (size_t *)dst);
}
/* Generate a "word" with platform-dependent size whose bytes all contain the
* value 'b'.
*/
static forceinline size_t repeat_byte(u8 b)
{
size_t v;
v = b;
v |= v << 8;
v |= v << 16;
v |= v << ((WORDBYTES == 8) ? 32 : 0);
return v;
}
/* Structure that encapsulates a block of in-memory data being interpreted as a
* stream of bits, optionally with interwoven literal bytes. Bits are assumed
* to be stored in little endian 16-bit coding units, with the bits ordered high
* to low.
*/
struct input_bitstream {
/* Bits that have been read from the input buffer. The bits are
* left-justified; the next bit is always bit 31.
*/
u32 bitbuf;
/* Number of bits currently held in @bitbuf. */
u32 bitsleft;
/* Pointer to the next byte to be retrieved from the input buffer. */
const u8 *next;
/* Pointer to just past the end of the input buffer. */
const u8 *end;
};
/* Initialize a bitstream to read from the specified input buffer. */
static forceinline void init_input_bitstream(struct input_bitstream *is,
const void *buffer, u32 size)
{
is->bitbuf = 0;
is->bitsleft = 0;
is->next = buffer;
is->end = is->next + size;
}
/* Ensure the bit buffer variable for the bitstream contains at least @num_bits
* bits. Following this, bitstream_peek_bits() and/or bitstream_remove_bits()
* may be called on the bitstream to peek or remove up to @num_bits bits. Note
* that @num_bits must be <= 16.
*/
static forceinline void bitstream_ensure_bits(struct input_bitstream *is,
u32 num_bits)
{
if (is->bitsleft < num_bits) {
if (is->end - is->next >= 2) {
is->bitbuf |= (u32)get_unaligned_le16(is->next)
<< (16 - is->bitsleft);
is->next += 2;
}
is->bitsleft += 16;
}
}
/* Return the next @num_bits bits from the bitstream, without removing them.
* There must be at least @num_bits remaining in the buffer variable, from a
* previous call to bitstream_ensure_bits().
*/
static forceinline u32
bitstream_peek_bits(const struct input_bitstream *is, const u32 num_bits)
{
return (is->bitbuf >> 1) >> (sizeof(is->bitbuf) * 8 - num_bits - 1);
}
/* Remove @num_bits from the bitstream. There must be at least @num_bits
* remaining in the buffer variable, from a previous call to
* bitstream_ensure_bits().
*/
static forceinline void
bitstream_remove_bits(struct input_bitstream *is, u32 num_bits)
{
is->bitbuf <<= num_bits;
is->bitsleft -= num_bits;
}
/* Remove and return @num_bits bits from the bitstream. There must be at least
* @num_bits remaining in the buffer variable, from a previous call to
* bitstream_ensure_bits().
*/
static forceinline u32
bitstream_pop_bits(struct input_bitstream *is, u32 num_bits)
{
u32 bits = bitstream_peek_bits(is, num_bits);
bitstream_remove_bits(is, num_bits);
return bits;
}
/* Read and return the next @num_bits bits from the bitstream. */
static forceinline u32
bitstream_read_bits(struct input_bitstream *is, u32 num_bits)
{
bitstream_ensure_bits(is, num_bits);
return bitstream_pop_bits(is, num_bits);
}
/* Read and return the next literal byte embedded in the bitstream. */
static forceinline u8
bitstream_read_byte(struct input_bitstream *is)
{
if (unlikely(is->end == is->next))
return 0;
return *is->next++;
}
/* Read and return the next 16-bit integer embedded in the bitstream. */
static forceinline u16
bitstream_read_u16(struct input_bitstream *is)
{
u16 v;
if (unlikely(is->end - is->next < 2))
return 0;
v = get_unaligned_le16(is->next);
is->next += 2;
return v;
}
/* Read and return the next 32-bit integer embedded in the bitstream. */
static forceinline u32
bitstream_read_u32(struct input_bitstream *is)
{
u32 v;
if (unlikely(is->end - is->next < 4))
return 0;
v = get_unaligned_le32(is->next);
is->next += 4;
return v;
}
/* Read into @dst_buffer an array of literal bytes embedded in the bitstream.
* Return either a pointer to the byte past the last written, or NULL if the
* read overflows the input buffer.
*/
static forceinline void *bitstream_read_bytes(struct input_bitstream *is,
void *dst_buffer, size_t count)
{
if ((size_t)(is->end - is->next) < count)
return NULL;
memcpy(dst_buffer, is->next, count);
is->next += count;
return (u8 *)dst_buffer + count;
}
/* Align the input bitstream on a coding-unit boundary. */
static forceinline void bitstream_align(struct input_bitstream *is)
{
is->bitsleft = 0;
is->bitbuf = 0;
}
extern int make_huffman_decode_table(u16 decode_table[], const u32 num_syms,
const u32 num_bits, const u8 lens[],
const u32 max_codeword_len,
u16 working_space[]);
/* Reads and returns the next Huffman-encoded symbol from a bitstream. If the
* input data is exhausted, the Huffman symbol is decoded as if the missing bits
* are all zeroes.
*/
static forceinline u32 read_huffsym(struct input_bitstream *istream,
const u16 decode_table[],
u32 table_bits,
u32 max_codeword_len)
{
u32 entry;
u32 key_bits;
bitstream_ensure_bits(istream, max_codeword_len);
/* Index the decode table by the next table_bits bits of the input. */
key_bits = bitstream_peek_bits(istream, table_bits);
entry = decode_table[key_bits];
if (entry < 0xC000) {
/* Fast case: The decode table directly provided the
* symbol and codeword length. The low 11 bits are the
* symbol, and the high 5 bits are the codeword length.
*/
bitstream_remove_bits(istream, entry >> 11);
return entry & 0x7FF;
}
/* Slow case: The codeword for the symbol is longer than
* table_bits, so the symbol does not have an entry
* directly in the first (1 << table_bits) entries of the
* decode table. Traverse the appropriate binary tree
* bit-by-bit to decode the symbol.
*/
bitstream_remove_bits(istream, table_bits);
do {
key_bits = (entry & 0x3FFF) + bitstream_pop_bits(istream, 1);
} while ((entry = decode_table[key_bits]) >= 0xC000);
return entry;
}
/*
* Copy an LZ77 match at (dst - offset) to dst.
*
* The length and offset must be already validated --- that is, (dst - offset)
* can't underrun the output buffer, and (dst + length) can't overrun the output
* buffer. Also, the length cannot be 0.
*
* @bufend points to the byte past the end of the output buffer. This function
* won't write any data beyond this position.
*
* Returns dst + length.
*/
static forceinline u8 *lz_copy(u8 *dst, u32 length, u32 offset, const u8 *bufend,
u32 min_length)
{
const u8 *src = dst - offset;
/*
* Try to copy one machine word at a time. On i386 and x86_64 this is
* faster than copying one byte at a time, unless the data is
* near-random and all the matches have very short lengths. Note that
* since this requires unaligned memory accesses, it won't necessarily
* be faster on every architecture.
*
* Also note that we might copy more than the length of the match. For
* example, if a word is 8 bytes and the match is of length 5, then
* we'll simply copy 8 bytes. This is okay as long as we don't write
* beyond the end of the output buffer, hence the check for (bufend -
* end >= WORDBYTES - 1).
*/
#ifdef FAST_UNALIGNED_ACCESS
u8 * const end = dst + length;
if (bufend - end >= (ptrdiff_t)(WORDBYTES - 1)) {
if (offset >= WORDBYTES) {
/* The source and destination words don't overlap. */
/* To improve branch prediction, one iteration of this
* loop is unrolled. Most matches are short and will
* fail the first check. But if that check passes, then
* it becomes increasing likely that the match is long
* and we'll need to continue copying.
*/
copy_unaligned_word(src, dst);
src += WORDBYTES;
dst += WORDBYTES;
if (dst < end) {
do {
copy_unaligned_word(src, dst);
src += WORDBYTES;
dst += WORDBYTES;
} while (dst < end);
}
return end;
} else if (offset == 1) {
/* Offset 1 matches are equivalent to run-length
* encoding of the previous byte. This case is common
* if the data contains many repeated bytes.
*/
size_t v = repeat_byte(*(dst - 1));
do {
put_unaligned(v, (size_t *)dst);
src += WORDBYTES;
dst += WORDBYTES;
} while (dst < end);
return end;
}
/*
* We don't bother with special cases for other 'offset <
* WORDBYTES', which are usually rarer than 'offset == 1'. Extra
* checks will just slow things down. Actually, it's possible
* to handle all the 'offset < WORDBYTES' cases using the same
* code, but it still becomes more complicated doesn't seem any
* faster overall; it definitely slows down the more common
* 'offset == 1' case.
*/
}
#endif /* FAST_UNALIGNED_ACCESS */
/* Fall back to a bytewise copy. */
if (min_length >= 2) {
*dst++ = *src++;
length--;
}
if (min_length >= 3) {
*dst++ = *src++;
length--;
}
do {
*dst++ = *src++;
} while (--length);
return dst;
}
#endif /* _LINUX_NTFS3_LIB_DECOMPRESS_COMMON_H */

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/* SPDX-License-Identifier: GPL-2.0-or-later */
/*
* Adapted for linux kernel by Alexander Mamaev:
* - remove implementations of get_unaligned_
* - assume GCC is always defined
* - ISO C90
* - linux kernel code style
*/
#ifndef _LINUX_NTFS3_LIB_LIB_H
#define _LINUX_NTFS3_LIB_LIB_H
#include <linux/types.h>
/* globals from xpress_decompress.c */
struct xpress_decompressor *xpress_allocate_decompressor(void);
void xpress_free_decompressor(struct xpress_decompressor *d);
int xpress_decompress(struct xpress_decompressor *__restrict d,
const void *__restrict compressed_data,
size_t compressed_size,
void *__restrict uncompressed_data,
size_t uncompressed_size);
/* globals from lzx_decompress.c */
struct lzx_decompressor *lzx_allocate_decompressor(void);
void lzx_free_decompressor(struct lzx_decompressor *d);
int lzx_decompress(struct lzx_decompressor *__restrict d,
const void *__restrict compressed_data,
size_t compressed_size, void *__restrict uncompressed_data,
size_t uncompressed_size);
#endif /* _LINUX_NTFS3_LIB_LIB_H */

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// SPDX-License-Identifier: GPL-2.0-or-later
/*
* lzx_decompress.c - A decompressor for the LZX compression format, which can
* be used in "System Compressed" files. This is based on the code from wimlib.
* This code only supports a window size (dictionary size) of 32768 bytes, since
* this is the only size used in System Compression.
*
* Copyright (C) 2015 Eric Biggers
*/
#include "decompress_common.h"
#include "lib.h"
/* Number of literal byte values */
#define LZX_NUM_CHARS 256
/* The smallest and largest allowed match lengths */
#define LZX_MIN_MATCH_LEN 2
#define LZX_MAX_MATCH_LEN 257
/* Number of distinct match lengths that can be represented */
#define LZX_NUM_LENS (LZX_MAX_MATCH_LEN - LZX_MIN_MATCH_LEN + 1)
/* Number of match lengths for which no length symbol is required */
#define LZX_NUM_PRIMARY_LENS 7
#define LZX_NUM_LEN_HEADERS (LZX_NUM_PRIMARY_LENS + 1)
/* Valid values of the 3-bit block type field */
#define LZX_BLOCKTYPE_VERBATIM 1
#define LZX_BLOCKTYPE_ALIGNED 2
#define LZX_BLOCKTYPE_UNCOMPRESSED 3
/* Number of offset slots for a window size of 32768 */
#define LZX_NUM_OFFSET_SLOTS 30
/* Number of symbols in the main code for a window size of 32768 */
#define LZX_MAINCODE_NUM_SYMBOLS \
(LZX_NUM_CHARS + (LZX_NUM_OFFSET_SLOTS * LZX_NUM_LEN_HEADERS))
/* Number of symbols in the length code */
#define LZX_LENCODE_NUM_SYMBOLS (LZX_NUM_LENS - LZX_NUM_PRIMARY_LENS)
/* Number of symbols in the precode */
#define LZX_PRECODE_NUM_SYMBOLS 20
/* Number of bits in which each precode codeword length is represented */
#define LZX_PRECODE_ELEMENT_SIZE 4
/* Number of low-order bits of each match offset that are entropy-encoded in
* aligned offset blocks
*/
#define LZX_NUM_ALIGNED_OFFSET_BITS 3
/* Number of symbols in the aligned offset code */
#define LZX_ALIGNEDCODE_NUM_SYMBOLS (1 << LZX_NUM_ALIGNED_OFFSET_BITS)
/* Mask for the match offset bits that are entropy-encoded in aligned offset
* blocks
*/
#define LZX_ALIGNED_OFFSET_BITMASK ((1 << LZX_NUM_ALIGNED_OFFSET_BITS) - 1)
/* Number of bits in which each aligned offset codeword length is represented */
#define LZX_ALIGNEDCODE_ELEMENT_SIZE 3
/* Maximum lengths (in bits) of the codewords in each Huffman code */
#define LZX_MAX_MAIN_CODEWORD_LEN 16
#define LZX_MAX_LEN_CODEWORD_LEN 16
#define LZX_MAX_PRE_CODEWORD_LEN ((1 << LZX_PRECODE_ELEMENT_SIZE) - 1)
#define LZX_MAX_ALIGNED_CODEWORD_LEN ((1 << LZX_ALIGNEDCODE_ELEMENT_SIZE) - 1)
/* The default "filesize" value used in pre/post-processing. In the LZX format
* used in cabinet files this value must be given to the decompressor, whereas
* in the LZX format used in WIM files and system-compressed files this value is
* fixed at 12000000.
*/
#define LZX_DEFAULT_FILESIZE 12000000
/* Assumed block size when the encoded block size begins with a 0 bit. */
#define LZX_DEFAULT_BLOCK_SIZE 32768
/* Number of offsets in the recent (or "repeat") offsets queue. */
#define LZX_NUM_RECENT_OFFSETS 3
/* These values are chosen for fast decompression. */
#define LZX_MAINCODE_TABLEBITS 11
#define LZX_LENCODE_TABLEBITS 10
#define LZX_PRECODE_TABLEBITS 6
#define LZX_ALIGNEDCODE_TABLEBITS 7
#define LZX_READ_LENS_MAX_OVERRUN 50
/* Mapping: offset slot => first match offset that uses that offset slot.
*/
static const u32 lzx_offset_slot_base[LZX_NUM_OFFSET_SLOTS + 1] = {
0, 1, 2, 3, 4, /* 0 --- 4 */
6, 8, 12, 16, 24, /* 5 --- 9 */
32, 48, 64, 96, 128, /* 10 --- 14 */
192, 256, 384, 512, 768, /* 15 --- 19 */
1024, 1536, 2048, 3072, 4096, /* 20 --- 24 */
6144, 8192, 12288, 16384, 24576, /* 25 --- 29 */
32768, /* extra */
};
/* Mapping: offset slot => how many extra bits must be read and added to the
* corresponding offset slot base to decode the match offset.
*/
static const u8 lzx_extra_offset_bits[LZX_NUM_OFFSET_SLOTS] = {
0, 0, 0, 0, 1,
1, 2, 2, 3, 3,
4, 4, 5, 5, 6,
6, 7, 7, 8, 8,
9, 9, 10, 10, 11,
11, 12, 12, 13, 13,
};
/* Reusable heap-allocated memory for LZX decompression */
struct lzx_decompressor {
/* Huffman decoding tables, and arrays that map symbols to codeword
* lengths
*/
u16 maincode_decode_table[(1 << LZX_MAINCODE_TABLEBITS) +
(LZX_MAINCODE_NUM_SYMBOLS * 2)];
u8 maincode_lens[LZX_MAINCODE_NUM_SYMBOLS + LZX_READ_LENS_MAX_OVERRUN];
u16 lencode_decode_table[(1 << LZX_LENCODE_TABLEBITS) +
(LZX_LENCODE_NUM_SYMBOLS * 2)];
u8 lencode_lens[LZX_LENCODE_NUM_SYMBOLS + LZX_READ_LENS_MAX_OVERRUN];
u16 alignedcode_decode_table[(1 << LZX_ALIGNEDCODE_TABLEBITS) +
(LZX_ALIGNEDCODE_NUM_SYMBOLS * 2)];
u8 alignedcode_lens[LZX_ALIGNEDCODE_NUM_SYMBOLS];
u16 precode_decode_table[(1 << LZX_PRECODE_TABLEBITS) +
(LZX_PRECODE_NUM_SYMBOLS * 2)];
u8 precode_lens[LZX_PRECODE_NUM_SYMBOLS];
/* Temporary space for make_huffman_decode_table() */
u16 working_space[2 * (1 + LZX_MAX_MAIN_CODEWORD_LEN) +
LZX_MAINCODE_NUM_SYMBOLS];
};
static void undo_e8_translation(void *target, s32 input_pos)
{
s32 abs_offset, rel_offset;
abs_offset = get_unaligned_le32(target);
if (abs_offset >= 0) {
if (abs_offset < LZX_DEFAULT_FILESIZE) {
/* "good translation" */
rel_offset = abs_offset - input_pos;
put_unaligned_le32(rel_offset, target);
}
} else {
if (abs_offset >= -input_pos) {
/* "compensating translation" */
rel_offset = abs_offset + LZX_DEFAULT_FILESIZE;
put_unaligned_le32(rel_offset, target);
}
}
}
/*
* Undo the 'E8' preprocessing used in LZX. Before compression, the
* uncompressed data was preprocessed by changing the targets of suspected x86
* CALL instructions from relative offsets to absolute offsets. After
* match/literal decoding, the decompressor must undo the translation.
*/
static void lzx_postprocess(u8 *data, u32 size)
{
/*
* A worthwhile optimization is to push the end-of-buffer check into the
* relatively rare E8 case. This is possible if we replace the last six
* bytes of data with E8 bytes; then we are guaranteed to hit an E8 byte
* before reaching end-of-buffer. In addition, this scheme guarantees
* that no translation can begin following an E8 byte in the last 10
* bytes because a 4-byte offset containing E8 as its high byte is a
* large negative number that is not valid for translation. That is
* exactly what we need.
*/
u8 *tail;
u8 saved_bytes[6];
u8 *p;
if (size <= 10)
return;
tail = &data[size - 6];
memcpy(saved_bytes, tail, 6);
memset(tail, 0xE8, 6);
p = data;
for (;;) {
while (*p != 0xE8)
p++;
if (p >= tail)
break;
undo_e8_translation(p + 1, p - data);
p += 5;
}
memcpy(tail, saved_bytes, 6);
}
/* Read a Huffman-encoded symbol using the precode. */
static forceinline u32 read_presym(const struct lzx_decompressor *d,
struct input_bitstream *is)
{
return read_huffsym(is, d->precode_decode_table,
LZX_PRECODE_TABLEBITS, LZX_MAX_PRE_CODEWORD_LEN);
}
/* Read a Huffman-encoded symbol using the main code. */
static forceinline u32 read_mainsym(const struct lzx_decompressor *d,
struct input_bitstream *is)
{
return read_huffsym(is, d->maincode_decode_table,
LZX_MAINCODE_TABLEBITS, LZX_MAX_MAIN_CODEWORD_LEN);
}
/* Read a Huffman-encoded symbol using the length code. */
static forceinline u32 read_lensym(const struct lzx_decompressor *d,
struct input_bitstream *is)
{
return read_huffsym(is, d->lencode_decode_table,
LZX_LENCODE_TABLEBITS, LZX_MAX_LEN_CODEWORD_LEN);
}
/* Read a Huffman-encoded symbol using the aligned offset code. */
static forceinline u32 read_alignedsym(const struct lzx_decompressor *d,
struct input_bitstream *is)
{
return read_huffsym(is, d->alignedcode_decode_table,
LZX_ALIGNEDCODE_TABLEBITS,
LZX_MAX_ALIGNED_CODEWORD_LEN);
}
/*
* Read the precode from the compressed input bitstream, then use it to decode
* @num_lens codeword length values.
*
* @is: The input bitstream.
*
* @lens: An array that contains the length values from the previous time
* the codeword lengths for this Huffman code were read, or all 0's
* if this is the first time. This array must have at least
* (@num_lens + LZX_READ_LENS_MAX_OVERRUN) entries.
*
* @num_lens: Number of length values to decode.
*
* Returns 0 on success, or -1 if the data was invalid.
*/
static int lzx_read_codeword_lens(struct lzx_decompressor *d,
struct input_bitstream *is,
u8 *lens, u32 num_lens)
{
u8 *len_ptr = lens;
u8 *lens_end = lens + num_lens;
int i;
/* Read the lengths of the precode codewords. These are given
* explicitly.
*/
for (i = 0; i < LZX_PRECODE_NUM_SYMBOLS; i++) {
d->precode_lens[i] =
bitstream_read_bits(is, LZX_PRECODE_ELEMENT_SIZE);
}
/* Make the decoding table for the precode. */
if (make_huffman_decode_table(d->precode_decode_table,
LZX_PRECODE_NUM_SYMBOLS,
LZX_PRECODE_TABLEBITS,
d->precode_lens,
LZX_MAX_PRE_CODEWORD_LEN,
d->working_space))
return -1;
/* Decode the codeword lengths. */
do {
u32 presym;
u8 len;
/* Read the next precode symbol. */
presym = read_presym(d, is);
if (presym < 17) {
/* Difference from old length */
len = *len_ptr - presym;
if ((s8)len < 0)
len += 17;
*len_ptr++ = len;
} else {
/* Special RLE values */
u32 run_len;
if (presym == 17) {
/* Run of 0's */
run_len = 4 + bitstream_read_bits(is, 4);
len = 0;
} else if (presym == 18) {
/* Longer run of 0's */
run_len = 20 + bitstream_read_bits(is, 5);
len = 0;
} else {
/* Run of identical lengths */
run_len = 4 + bitstream_read_bits(is, 1);
presym = read_presym(d, is);
if (presym > 17)
return -1;
len = *len_ptr - presym;
if ((s8)len < 0)
len += 17;
}
do {
*len_ptr++ = len;
} while (--run_len);
/* Worst case overrun is when presym == 18,
* run_len == 20 + 31, and only 1 length was remaining.
* So LZX_READ_LENS_MAX_OVERRUN == 50.
*
* Overrun while reading the first half of maincode_lens
* can corrupt the previous values in the second half.
* This doesn't really matter because the resulting
* lengths will still be in range, and data that
* generates overruns is invalid anyway.
*/
}
} while (len_ptr < lens_end);
return 0;
}
/*
* Read the header of an LZX block and save the block type and (uncompressed)
* size in *block_type_ret and *block_size_ret, respectively.
*
* If the block is compressed, also update the Huffman decode @tables with the
* new Huffman codes. If the block is uncompressed, also update the match
* offset @queue with the new match offsets.
*
* Return 0 on success, or -1 if the data was invalid.
*/
static int lzx_read_block_header(struct lzx_decompressor *d,
struct input_bitstream *is,
int *block_type_ret,
u32 *block_size_ret,
u32 recent_offsets[])
{
int block_type;
u32 block_size;
int i;
bitstream_ensure_bits(is, 4);
/* The first three bits tell us what kind of block it is, and should be
* one of the LZX_BLOCKTYPE_* values.
*/
block_type = bitstream_pop_bits(is, 3);
/* Read the block size. */
if (bitstream_pop_bits(is, 1)) {
block_size = LZX_DEFAULT_BLOCK_SIZE;
} else {
block_size = 0;
block_size |= bitstream_read_bits(is, 8);
block_size <<= 8;
block_size |= bitstream_read_bits(is, 8);
}
switch (block_type) {
case LZX_BLOCKTYPE_ALIGNED:
/* Read the aligned offset code and prepare its decode table.
*/
for (i = 0; i < LZX_ALIGNEDCODE_NUM_SYMBOLS; i++) {
d->alignedcode_lens[i] =
bitstream_read_bits(is,
LZX_ALIGNEDCODE_ELEMENT_SIZE);
}
if (make_huffman_decode_table(d->alignedcode_decode_table,
LZX_ALIGNEDCODE_NUM_SYMBOLS,
LZX_ALIGNEDCODE_TABLEBITS,
d->alignedcode_lens,
LZX_MAX_ALIGNED_CODEWORD_LEN,
d->working_space))
return -1;
/* Fall though, since the rest of the header for aligned offset
* blocks is the same as that for verbatim blocks.
*/
fallthrough;
case LZX_BLOCKTYPE_VERBATIM:
/* Read the main code and prepare its decode table.
*
* Note that the codeword lengths in the main code are encoded
* in two parts: one part for literal symbols, and one part for
* match symbols.
*/
if (lzx_read_codeword_lens(d, is, d->maincode_lens,
LZX_NUM_CHARS))
return -1;
if (lzx_read_codeword_lens(d, is,
d->maincode_lens + LZX_NUM_CHARS,
LZX_MAINCODE_NUM_SYMBOLS - LZX_NUM_CHARS))
return -1;
if (make_huffman_decode_table(d->maincode_decode_table,
LZX_MAINCODE_NUM_SYMBOLS,
LZX_MAINCODE_TABLEBITS,
d->maincode_lens,
LZX_MAX_MAIN_CODEWORD_LEN,
d->working_space))
return -1;
/* Read the length code and prepare its decode table. */
if (lzx_read_codeword_lens(d, is, d->lencode_lens,
LZX_LENCODE_NUM_SYMBOLS))
return -1;
if (make_huffman_decode_table(d->lencode_decode_table,
LZX_LENCODE_NUM_SYMBOLS,
LZX_LENCODE_TABLEBITS,
d->lencode_lens,
LZX_MAX_LEN_CODEWORD_LEN,
d->working_space))
return -1;
break;
case LZX_BLOCKTYPE_UNCOMPRESSED:
/* Before reading the three recent offsets from the uncompressed
* block header, the stream must be aligned on a 16-bit
* boundary. But if the stream is *already* aligned, then the
* next 16 bits must be discarded.
*/
bitstream_ensure_bits(is, 1);
bitstream_align(is);
recent_offsets[0] = bitstream_read_u32(is);
recent_offsets[1] = bitstream_read_u32(is);
recent_offsets[2] = bitstream_read_u32(is);
/* Offsets of 0 are invalid. */
if (recent_offsets[0] == 0 || recent_offsets[1] == 0 ||
recent_offsets[2] == 0)
return -1;
break;
default:
/* Unrecognized block type. */
return -1;
}
*block_type_ret = block_type;
*block_size_ret = block_size;
return 0;
}
/* Decompress a block of LZX-compressed data. */
static int lzx_decompress_block(const struct lzx_decompressor *d,
struct input_bitstream *is,
int block_type, u32 block_size,
u8 * const out_begin, u8 *out_next,
u32 recent_offsets[])
{
u8 * const block_end = out_next + block_size;
u32 ones_if_aligned = 0U - (block_type == LZX_BLOCKTYPE_ALIGNED);
do {
u32 mainsym;
u32 match_len;
u32 match_offset;
u32 offset_slot;
u32 num_extra_bits;
mainsym = read_mainsym(d, is);
if (mainsym < LZX_NUM_CHARS) {
/* Literal */
*out_next++ = mainsym;
continue;
}
/* Match */
/* Decode the length header and offset slot. */
mainsym -= LZX_NUM_CHARS;
match_len = mainsym % LZX_NUM_LEN_HEADERS;
offset_slot = mainsym / LZX_NUM_LEN_HEADERS;
/* If needed, read a length symbol to decode the full length. */
if (match_len == LZX_NUM_PRIMARY_LENS)
match_len += read_lensym(d, is);
match_len += LZX_MIN_MATCH_LEN;
if (offset_slot < LZX_NUM_RECENT_OFFSETS) {
/* Repeat offset */
/* Note: This isn't a real LRU queue, since using the R2
* offset doesn't bump the R1 offset down to R2. This
* quirk allows all 3 recent offsets to be handled by
* the same code. (For R0, the swap is a no-op.)
*/
match_offset = recent_offsets[offset_slot];
recent_offsets[offset_slot] = recent_offsets[0];
recent_offsets[0] = match_offset;
} else {
/* Explicit offset */
/* Look up the number of extra bits that need to be read
* to decode offsets with this offset slot.
*/
num_extra_bits = lzx_extra_offset_bits[offset_slot];
/* Start with the offset slot base value. */
match_offset = lzx_offset_slot_base[offset_slot];
/* In aligned offset blocks, the low-order 3 bits of
* each offset are encoded using the aligned offset
* code. Otherwise, all the extra bits are literal.
*/
if ((num_extra_bits & ones_if_aligned) >= LZX_NUM_ALIGNED_OFFSET_BITS) {
match_offset +=
bitstream_read_bits(is, num_extra_bits -
LZX_NUM_ALIGNED_OFFSET_BITS)
<< LZX_NUM_ALIGNED_OFFSET_BITS;
match_offset += read_alignedsym(d, is);
} else {
match_offset += bitstream_read_bits(is, num_extra_bits);
}
/* Adjust the offset. */
match_offset -= (LZX_NUM_RECENT_OFFSETS - 1);
/* Update the recent offsets. */
recent_offsets[2] = recent_offsets[1];
recent_offsets[1] = recent_offsets[0];
recent_offsets[0] = match_offset;
}
/* Validate the match, then copy it to the current position. */
if (match_len > (size_t)(block_end - out_next))
return -1;
if (match_offset > (size_t)(out_next - out_begin))
return -1;
out_next = lz_copy(out_next, match_len, match_offset,
block_end, LZX_MIN_MATCH_LEN);
} while (out_next != block_end);
return 0;
}
/*
* lzx_allocate_decompressor - Allocate an LZX decompressor
*
* Return the pointer to the decompressor on success, or return NULL and set
* errno on failure.
*/
struct lzx_decompressor *lzx_allocate_decompressor(void)
{
return kmalloc(sizeof(struct lzx_decompressor), GFP_NOFS);
}
/*
* lzx_decompress - Decompress a buffer of LZX-compressed data
*
* @decompressor: A decompressor allocated with lzx_allocate_decompressor()
* @compressed_data: The buffer of data to decompress
* @compressed_size: Number of bytes of compressed data
* @uncompressed_data: The buffer in which to store the decompressed data
* @uncompressed_size: The number of bytes the data decompresses into
*
* Return 0 on success, or return -1 and set errno on failure.
*/
int lzx_decompress(struct lzx_decompressor *decompressor,
const void *compressed_data, size_t compressed_size,
void *uncompressed_data, size_t uncompressed_size)
{
struct lzx_decompressor *d = decompressor;
u8 * const out_begin = uncompressed_data;
u8 *out_next = out_begin;
u8 * const out_end = out_begin + uncompressed_size;
struct input_bitstream is;
u32 recent_offsets[LZX_NUM_RECENT_OFFSETS] = {1, 1, 1};
int e8_status = 0;
init_input_bitstream(&is, compressed_data, compressed_size);
/* Codeword lengths begin as all 0's for delta encoding purposes. */
memset(d->maincode_lens, 0, LZX_MAINCODE_NUM_SYMBOLS);
memset(d->lencode_lens, 0, LZX_LENCODE_NUM_SYMBOLS);
/* Decompress blocks until we have all the uncompressed data. */
while (out_next != out_end) {
int block_type;
u32 block_size;
if (lzx_read_block_header(d, &is, &block_type, &block_size,
recent_offsets))
goto invalid;
if (block_size < 1 || block_size > (size_t)(out_end - out_next))
goto invalid;
if (block_type != LZX_BLOCKTYPE_UNCOMPRESSED) {
/* Compressed block */
if (lzx_decompress_block(d,
&is,
block_type,
block_size,
out_begin,
out_next,
recent_offsets))
goto invalid;
e8_status |= d->maincode_lens[0xe8];
out_next += block_size;
} else {
/* Uncompressed block */
out_next = bitstream_read_bytes(&is, out_next,
block_size);
if (!out_next)
goto invalid;
if (block_size & 1)
bitstream_read_byte(&is);
e8_status = 1;
}
}
/* Postprocess the data unless it cannot possibly contain 0xe8 bytes. */
if (e8_status)
lzx_postprocess(uncompressed_data, uncompressed_size);
return 0;
invalid:
return -1;
}
/*
* lzx_free_decompressor - Free an LZX decompressor
*
* @decompressor: A decompressor that was allocated with
* lzx_allocate_decompressor(), or NULL.
*/
void lzx_free_decompressor(struct lzx_decompressor *decompressor)
{
kfree(decompressor);
}

142
target/linux/generic/files-5.4/fs/ntfs3/lib/xpress_decompress.c Normal file
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@ -0,0 +1,142 @@
// SPDX-License-Identifier: GPL-2.0-or-later
/*
* xpress_decompress.c - A decompressor for the XPRESS compression format
* (Huffman variant), which can be used in "System Compressed" files. This is
* based on the code from wimlib.
*
* Copyright (C) 2015 Eric Biggers
*/
#include "decompress_common.h"
#include "lib.h"
#define XPRESS_NUM_SYMBOLS 512
#define XPRESS_MAX_CODEWORD_LEN 15
#define XPRESS_MIN_MATCH_LEN 3
/* This value is chosen for fast decompression. */
#define XPRESS_TABLEBITS 12
/* Reusable heap-allocated memory for XPRESS decompression */
struct xpress_decompressor {
/* The Huffman decoding table */
u16 decode_table[(1 << XPRESS_TABLEBITS) + 2 * XPRESS_NUM_SYMBOLS];
/* An array that maps symbols to codeword lengths */
u8 lens[XPRESS_NUM_SYMBOLS];
/* Temporary space for make_huffman_decode_table() */
u16 working_space[2 * (1 + XPRESS_MAX_CODEWORD_LEN) +
XPRESS_NUM_SYMBOLS];
};
/*
* xpress_allocate_decompressor - Allocate an XPRESS decompressor
*
* Return the pointer to the decompressor on success, or return NULL and set
* errno on failure.
*/
struct xpress_decompressor *xpress_allocate_decompressor(void)
{
return kmalloc(sizeof(struct xpress_decompressor), GFP_NOFS);
}
/*
* xpress_decompress - Decompress a buffer of XPRESS-compressed data
*
* @decompressor: A decompressor that was allocated with
* xpress_allocate_decompressor()
* @compressed_data: The buffer of data to decompress
* @compressed_size: Number of bytes of compressed data
* @uncompressed_data: The buffer in which to store the decompressed data
* @uncompressed_size: The number of bytes the data decompresses into
*
* Return 0 on success, or return -1 and set errno on failure.
*/
int xpress_decompress(struct xpress_decompressor *decompressor,
const void *compressed_data, size_t compressed_size,
void *uncompressed_data, size_t uncompressed_size)
{
struct xpress_decompressor *d = decompressor;
const u8 * const in_begin = compressed_data;
u8 * const out_begin = uncompressed_data;
u8 *out_next = out_begin;
u8 * const out_end = out_begin + uncompressed_size;
struct input_bitstream is;
u32 i;
/* Read the Huffman codeword lengths. */
if (compressed_size < XPRESS_NUM_SYMBOLS / 2)
goto invalid;
for (i = 0; i < XPRESS_NUM_SYMBOLS / 2; i++) {
d->lens[i*2 + 0] = in_begin[i] & 0xF;
d->lens[i*2 + 1] = in_begin[i] >> 4;
}
/* Build a decoding table for the Huffman code. */
if (make_huffman_decode_table(d->decode_table, XPRESS_NUM_SYMBOLS,
XPRESS_TABLEBITS, d->lens,
XPRESS_MAX_CODEWORD_LEN,
d->working_space))
goto invalid;
/* Decode the matches and literals. */
init_input_bitstream(&is, in_begin + XPRESS_NUM_SYMBOLS / 2,
compressed_size - XPRESS_NUM_SYMBOLS / 2);
while (out_next != out_end) {
u32 sym;
u32 log2_offset;
u32 length;
u32 offset;
sym = read_huffsym(&is, d->decode_table,
XPRESS_TABLEBITS, XPRESS_MAX_CODEWORD_LEN);
if (sym < 256) {
/* Literal */
*out_next++ = sym;
} else {
/* Match */
length = sym & 0xf;
log2_offset = (sym >> 4) & 0xf;
bitstream_ensure_bits(&is, 16);
offset = ((u32)1 << log2_offset) |
bitstream_pop_bits(&is, log2_offset);
if (length == 0xf) {
length += bitstream_read_byte(&is);
if (length == 0xf + 0xff)
length = bitstream_read_u16(&is);
}
length += XPRESS_MIN_MATCH_LEN;
if (offset > (size_t)(out_next - out_begin))
goto invalid;
if (length > (size_t)(out_end - out_next))
goto invalid;
out_next = lz_copy(out_next, length, offset, out_end,
XPRESS_MIN_MATCH_LEN);
}
}
return 0;
invalid:
return -1;
}
/*
* xpress_free_decompressor - Free an XPRESS decompressor
*
* @decompressor: A decompressor that was allocated with
* xpress_allocate_decompressor(), or NULL.
*/
void xpress_free_decompressor(struct xpress_decompressor *decompressor)
{
kfree(decompressor);
}

453
target/linux/generic/files-5.4/fs/ntfs3/lznt.c Normal file
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@ -0,0 +1,453 @@
// SPDX-License-Identifier: GPL-2.0
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
*/
#include <linux/kernel.h>
#include <linux/slab.h>
#include <linux/stddef.h>
#include <linux/string.h>
#include <linux/types.h>
#include "debug.h"
#include "ntfs_fs.h"
// clang-format off
/* Src buffer is zero. */
#define LZNT_ERROR_ALL_ZEROS 1
#define LZNT_CHUNK_SIZE 0x1000
// clang-format on
struct lznt_hash {
const u8 *p1;
const u8 *p2;
};
struct lznt {
const u8 *unc;
const u8 *unc_end;
const u8 *best_match;
size_t max_len;
bool std;
struct lznt_hash hash[LZNT_CHUNK_SIZE];
};
static inline size_t get_match_len(const u8 *ptr, const u8 *end, const u8 *prev,
size_t max_len)
{
size_t len = 0;
while (ptr + len < end && ptr[len] == prev[len] && ++len < max_len)
;
return len;
}
static size_t longest_match_std(const u8 *src, struct lznt *ctx)
{
size_t hash_index;
size_t len1 = 0, len2 = 0;
const u8 **hash;
hash_index =
((40543U * ((((src[0] << 4) ^ src[1]) << 4) ^ src[2])) >> 4) &
(LZNT_CHUNK_SIZE - 1);
hash = &(ctx->hash[hash_index].p1);
if (hash[0] >= ctx->unc && hash[0] < src && hash[0][0] == src[0] &&
hash[0][1] == src[1] && hash[0][2] == src[2]) {
len1 = 3;
if (ctx->max_len > 3)
len1 += get_match_len(src + 3, ctx->unc_end,
hash[0] + 3, ctx->max_len - 3);
}
if (hash[1] >= ctx->unc && hash[1] < src && hash[1][0] == src[0] &&
hash[1][1] == src[1] && hash[1][2] == src[2]) {
len2 = 3;
if (ctx->max_len > 3)
len2 += get_match_len(src + 3, ctx->unc_end,
hash[1] + 3, ctx->max_len - 3);
}
/* Compare two matches and select the best one. */
if (len1 < len2) {
ctx->best_match = hash[1];
len1 = len2;
} else {
ctx->best_match = hash[0];
}
hash[1] = hash[0];
hash[0] = src;
return len1;
}
static size_t longest_match_best(const u8 *src, struct lznt *ctx)
{
size_t max_len;
const u8 *ptr;
if (ctx->unc >= src || !ctx->max_len)
return 0;
max_len = 0;
for (ptr = ctx->unc; ptr < src; ++ptr) {
size_t len =
get_match_len(src, ctx->unc_end, ptr, ctx->max_len);
if (len >= max_len) {
max_len = len;
ctx->best_match = ptr;
}
}
return max_len >= 3 ? max_len : 0;
}
static const size_t s_max_len[] = {
0x1002, 0x802, 0x402, 0x202, 0x102, 0x82, 0x42, 0x22, 0x12,
};
static const size_t s_max_off[] = {
0x10, 0x20, 0x40, 0x80, 0x100, 0x200, 0x400, 0x800, 0x1000,
};
static inline u16 make_pair(size_t offset, size_t len, size_t index)
{
return ((offset - 1) << (12 - index)) |
((len - 3) & (((1 << (12 - index)) - 1)));
}
static inline size_t parse_pair(u16 pair, size_t *offset, size_t index)
{
*offset = 1 + (pair >> (12 - index));
return 3 + (pair & ((1 << (12 - index)) - 1));
}
/*
* compress_chunk
*
* Return:
* * 0 - Ok, @cmpr contains @cmpr_chunk_size bytes of compressed data.
* * 1 - Input buffer is full zero.
* * -2 - The compressed buffer is too small to hold the compressed data.
*/
static inline int compress_chunk(size_t (*match)(const u8 *, struct lznt *),
const u8 *unc, const u8 *unc_end, u8 *cmpr,
u8 *cmpr_end, size_t *cmpr_chunk_size,
struct lznt *ctx)
{
size_t cnt = 0;
size_t idx = 0;
const u8 *up = unc;
u8 *cp = cmpr + 3;
u8 *cp2 = cmpr + 2;
u8 not_zero = 0;
/* Control byte of 8-bit values: ( 0 - means byte as is, 1 - short pair ). */
u8 ohdr = 0;
u8 *last;
u16 t16;
if (unc + LZNT_CHUNK_SIZE < unc_end)
unc_end = unc + LZNT_CHUNK_SIZE;
last = min(cmpr + LZNT_CHUNK_SIZE + sizeof(short), cmpr_end);
ctx->unc = unc;
ctx->unc_end = unc_end;
ctx->max_len = s_max_len[0];
while (up < unc_end) {
size_t max_len;
while (unc + s_max_off[idx] < up)
ctx->max_len = s_max_len[++idx];
/* Find match. */
max_len = up + 3 <= unc_end ? (*match)(up, ctx) : 0;
if (!max_len) {
if (cp >= last)
goto NotCompressed;
not_zero |= *cp++ = *up++;
} else if (cp + 1 >= last) {
goto NotCompressed;
} else {
t16 = make_pair(up - ctx->best_match, max_len, idx);
*cp++ = t16;
*cp++ = t16 >> 8;
ohdr |= 1 << cnt;
up += max_len;
}
cnt = (cnt + 1) & 7;
if (!cnt) {
*cp2 = ohdr;
ohdr = 0;
cp2 = cp;
cp += 1;
}
}
if (cp2 < last)
*cp2 = ohdr;
else
cp -= 1;
*cmpr_chunk_size = cp - cmpr;
t16 = (*cmpr_chunk_size - 3) | 0xB000;
cmpr[0] = t16;
cmpr[1] = t16 >> 8;
return not_zero ? 0 : LZNT_ERROR_ALL_ZEROS;
NotCompressed:
if ((cmpr + LZNT_CHUNK_SIZE + sizeof(short)) > last)
return -2;
/*
* Copy non cmpr data.
* 0x3FFF == ((LZNT_CHUNK_SIZE + 2 - 3) | 0x3000)
*/
cmpr[0] = 0xff;
cmpr[1] = 0x3f;
memcpy(cmpr + sizeof(short), unc, LZNT_CHUNK_SIZE);
*cmpr_chunk_size = LZNT_CHUNK_SIZE + sizeof(short);
return 0;
}
static inline ssize_t decompress_chunk(u8 *unc, u8 *unc_end, const u8 *cmpr,
const u8 *cmpr_end)
{
u8 *up = unc;
u8 ch = *cmpr++;
size_t bit = 0;
size_t index = 0;
u16 pair;
size_t offset, length;
/* Do decompression until pointers are inside range. */
while (up < unc_end && cmpr < cmpr_end) {
/* Correct index */
while (unc + s_max_off[index] < up)
index += 1;
/* Check the current flag for zero. */
if (!(ch & (1 << bit))) {
/* Just copy byte. */
*up++ = *cmpr++;
goto next;
}
/* Check for boundary. */
if (cmpr + 1 >= cmpr_end)
return -EINVAL;
/* Read a short from little endian stream. */
pair = cmpr[1];
pair <<= 8;
pair |= cmpr[0];
cmpr += 2;
/* Translate packed information into offset and length. */
length = parse_pair(pair, &offset, index);
/* Check offset for boundary. */
if (unc + offset > up)
return -EINVAL;
/* Truncate the length if necessary. */
if (up + length >= unc_end)
length = unc_end - up;
/* Now we copy bytes. This is the heart of LZ algorithm. */
for (; length > 0; length--, up++)
*up = *(up - offset);
next:
/* Advance flag bit value. */
bit = (bit + 1) & 7;
if (!bit) {
if (cmpr >= cmpr_end)
break;
ch = *cmpr++;
}
}
/* Return the size of uncompressed data. */
return up - unc;
}
/*
* get_lznt_ctx
* @level: 0 - Standard compression.
* !0 - Best compression, requires a lot of cpu.
*/
struct lznt *get_lznt_ctx(int level)
{
struct lznt *r = kzalloc(level ? offsetof(struct lznt, hash)
: sizeof(struct lznt),
GFP_NOFS);
if (r)
r->std = !level;
return r;
}
/*
* compress_lznt - Compresses @unc into @cmpr
*
* Return:
* * +x - Ok, @cmpr contains 'final_compressed_size' bytes of compressed data.
* * 0 - Input buffer is full zero.
*/
size_t compress_lznt(const void *unc, size_t unc_size, void *cmpr,
size_t cmpr_size, struct lznt *ctx)
{
int err;
size_t (*match)(const u8 *src, struct lznt *ctx);
u8 *p = cmpr;
u8 *end = p + cmpr_size;
const u8 *unc_chunk = unc;
const u8 *unc_end = unc_chunk + unc_size;
bool is_zero = true;
if (ctx->std) {
match = &longest_match_std;
memset(ctx->hash, 0, sizeof(ctx->hash));
} else {
match = &longest_match_best;
}
/* Compression cycle. */
for (; unc_chunk < unc_end; unc_chunk += LZNT_CHUNK_SIZE) {
cmpr_size = 0;
err = compress_chunk(match, unc_chunk, unc_end, p, end,
&cmpr_size, ctx);
if (err < 0)
return unc_size;
if (is_zero && err != LZNT_ERROR_ALL_ZEROS)
is_zero = false;
p += cmpr_size;
}
if (p <= end - 2)
p[0] = p[1] = 0;
return is_zero ? 0 : PtrOffset(cmpr, p);
}
/*
* decompress_lznt - Decompress @cmpr into @unc.
*/
ssize_t decompress_lznt(const void *cmpr, size_t cmpr_size, void *unc,
size_t unc_size)
{
const u8 *cmpr_chunk = cmpr;
const u8 *cmpr_end = cmpr_chunk + cmpr_size;
u8 *unc_chunk = unc;
u8 *unc_end = unc_chunk + unc_size;
u16 chunk_hdr;
if (cmpr_size < sizeof(short))
return -EINVAL;
/* Read chunk header. */
chunk_hdr = cmpr_chunk[1];
chunk_hdr <<= 8;
chunk_hdr |= cmpr_chunk[0];
/* Loop through decompressing chunks. */
for (;;) {
size_t chunk_size_saved;
size_t unc_use;
size_t cmpr_use = 3 + (chunk_hdr & (LZNT_CHUNK_SIZE - 1));
/* Check that the chunk actually fits the supplied buffer. */
if (cmpr_chunk + cmpr_use > cmpr_end)
return -EINVAL;
/* First make sure the chunk contains compressed data. */
if (chunk_hdr & 0x8000) {
/* Decompress a chunk and return if we get an error. */
ssize_t err =
decompress_chunk(unc_chunk, unc_end,
cmpr_chunk + sizeof(chunk_hdr),
cmpr_chunk + cmpr_use);
if (err < 0)
return err;
unc_use = err;
} else {
/* This chunk does not contain compressed data. */
unc_use = unc_chunk + LZNT_CHUNK_SIZE > unc_end
? unc_end - unc_chunk
: LZNT_CHUNK_SIZE;
if (cmpr_chunk + sizeof(chunk_hdr) + unc_use >
cmpr_end) {
return -EINVAL;
}
memcpy(unc_chunk, cmpr_chunk + sizeof(chunk_hdr),
unc_use);
}
/* Advance pointers. */
cmpr_chunk += cmpr_use;
unc_chunk += unc_use;
/* Check for the end of unc buffer. */
if (unc_chunk >= unc_end)
break;
/* Proceed the next chunk. */
if (cmpr_chunk > cmpr_end - 2)
break;
chunk_size_saved = LZNT_CHUNK_SIZE;
/* Read chunk header. */
chunk_hdr = cmpr_chunk[1];
chunk_hdr <<= 8;
chunk_hdr |= cmpr_chunk[0];
if (!chunk_hdr)
break;
/* Check the size of unc buffer. */
if (unc_use < chunk_size_saved) {
size_t t1 = chunk_size_saved - unc_use;
u8 *t2 = unc_chunk + t1;
/* 'Zero' memory. */
if (t2 >= unc_end)
break;
memset(unc_chunk, 0, t1);
unc_chunk = t2;
}
}
/* Check compression boundary. */
if (cmpr_chunk > cmpr_end)
return -EINVAL;
/*
* The unc size is just a difference between current
* pointer and original one.
*/
return PtrOffset(unc, unc_chunk);
}

387
target/linux/generic/files-5.4/fs/ntfs3/namei.c Normal file
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@ -0,0 +1,387 @@
// SPDX-License-Identifier: GPL-2.0
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
*/
#include <linux/fs.h>
#include <linux/nls.h>
#include "debug.h"
#include "ntfs.h"
#include "ntfs_fs.h"
/*
* fill_name_de - Format NTFS_DE in @buf.
*/
int fill_name_de(struct ntfs_sb_info *sbi, void *buf, const struct qstr *name,
const struct cpu_str *uni)
{
int err;
struct NTFS_DE *e = buf;
u16 data_size;
struct ATTR_FILE_NAME *fname = (struct ATTR_FILE_NAME *)(e + 1);
#ifndef CONFIG_NTFS3_64BIT_CLUSTER
e->ref.high = fname->home.high = 0;
#endif
if (uni) {
#ifdef __BIG_ENDIAN
int ulen = uni->len;
__le16 *uname = fname->name;
const u16 *name_cpu = uni->name;
while (ulen--)
*uname++ = cpu_to_le16(*name_cpu++);
#else
memcpy(fname->name, uni->name, uni->len * sizeof(u16));
#endif
fname->name_len = uni->len;
} else {
/* Convert input string to unicode. */
err = ntfs_nls_to_utf16(sbi, name->name, name->len,
(struct cpu_str *)&fname->name_len,
NTFS_NAME_LEN, UTF16_LITTLE_ENDIAN);
if (err < 0)
return err;
}
fname->type = FILE_NAME_POSIX;
data_size = fname_full_size(fname);
e->size = cpu_to_le16(ALIGN(data_size, 8) + sizeof(struct NTFS_DE));
e->key_size = cpu_to_le16(data_size);
e->flags = 0;
e->res = 0;
return 0;
}
/*
* ntfs_lookup - inode_operations::lookup
*/
static struct dentry *ntfs_lookup(struct inode *dir, struct dentry *dentry,
u32 flags)
{
struct ntfs_inode *ni = ntfs_i(dir);
struct cpu_str *uni = __getname();
struct inode *inode;
int err;
if (!uni)
inode = ERR_PTR(-ENOMEM);
else {
err = ntfs_nls_to_utf16(ni->mi.sbi, dentry->d_name.name,
dentry->d_name.len, uni, NTFS_NAME_LEN,
UTF16_HOST_ENDIAN);
if (err < 0)
inode = ERR_PTR(err);
else {
ni_lock(ni);
inode = dir_search_u(dir, uni, NULL);
ni_unlock(ni);
}
__putname(uni);
}
return d_splice_alias(inode, dentry);
}
/*
* ntfs_create - inode_operations::create
*/
static int ntfs_create(struct inode *dir,
struct dentry *dentry, umode_t mode, bool excl)
{
struct inode *inode;
inode = ntfs_create_inode(dir, dentry, NULL, S_IFREG | mode,
0, NULL, 0, NULL);
return IS_ERR(inode) ? PTR_ERR(inode) : 0;
}
/*
* ntfs_mknod
*
* inode_operations::mknod
*/
static int ntfs_mknod(struct inode *dir,
struct dentry *dentry, umode_t mode, dev_t rdev)
{
struct inode *inode;
inode = ntfs_create_inode(dir, dentry, NULL, mode, rdev,
NULL, 0, NULL);
return IS_ERR(inode) ? PTR_ERR(inode) : 0;
}
/*
* ntfs_link - inode_operations::link
*/
static int ntfs_link(struct dentry *ode, struct inode *dir, struct dentry *de)
{
int err;
struct inode *inode = d_inode(ode);
struct ntfs_inode *ni = ntfs_i(inode);
if (S_ISDIR(inode->i_mode))
return -EPERM;
if (inode->i_nlink >= NTFS_LINK_MAX)
return -EMLINK;
ni_lock_dir(ntfs_i(dir));
if (inode != dir)
ni_lock(ni);
inc_nlink(inode);
ihold(inode);
err = ntfs_link_inode(inode, de);
if (!err) {
dir->i_ctime = dir->i_mtime = inode->i_ctime =
current_time(dir);
mark_inode_dirty(inode);
mark_inode_dirty(dir);
d_instantiate(de, inode);
} else {
drop_nlink(inode);
iput(inode);
}
if (inode != dir)
ni_unlock(ni);
ni_unlock(ntfs_i(dir));
return err;
}
/*
* ntfs_unlink - inode_operations::unlink
*/
static int ntfs_unlink(struct inode *dir, struct dentry *dentry)
{
struct ntfs_inode *ni = ntfs_i(dir);
int err;
ni_lock_dir(ni);
err = ntfs_unlink_inode(dir, dentry);
ni_unlock(ni);
return err;
}
/*
* ntfs_symlink - inode_operations::symlink
*/
static int ntfs_symlink(struct inode *dir,
struct dentry *dentry, const char *symname)
{
u32 size = strlen(symname);
struct inode *inode;
inode = ntfs_create_inode(dir, dentry, NULL, S_IFLNK | 0777,
0, symname, size, NULL);
return IS_ERR(inode) ? PTR_ERR(inode) : 0;
}
/*
* ntfs_mkdir- inode_operations::mkdir
*/
static int ntfs_mkdir(struct inode *dir,
struct dentry *dentry, umode_t mode)
{
struct inode *inode;
inode = ntfs_create_inode(dir, dentry, NULL, S_IFDIR | mode,
0, NULL, 0, NULL);
return IS_ERR(inode) ? PTR_ERR(inode) : 0;
}
/*
* ntfs_rmdir - inode_operations::rm_dir
*/
static int ntfs_rmdir(struct inode *dir, struct dentry *dentry)
{
struct ntfs_inode *ni = ntfs_i(dir);
int err;
ni_lock_dir(ni);
err = ntfs_unlink_inode(dir, dentry);
ni_unlock(ni);
return err;
}
/*
* ntfs_rename - inode_operations::rename
*/
static int ntfs_rename(struct inode *dir,
struct dentry *dentry, struct inode *new_dir,
struct dentry *new_dentry, u32 flags)
{
int err;
struct super_block *sb = dir->i_sb;
struct ntfs_sb_info *sbi = sb->s_fs_info;
struct ntfs_inode *dir_ni = ntfs_i(dir);
struct ntfs_inode *new_dir_ni = ntfs_i(new_dir);
struct inode *inode = d_inode(dentry);
struct ntfs_inode *ni = ntfs_i(inode);
struct inode *new_inode = d_inode(new_dentry);
struct NTFS_DE *de, *new_de;
bool is_same, is_bad;
/*
* de - memory of PATH_MAX bytes:
* [0-1024) - original name (dentry->d_name)
* [1024-2048) - paired to original name, usually DOS variant of dentry->d_name
* [2048-3072) - new name (new_dentry->d_name)
*/
static_assert(SIZEOF_ATTRIBUTE_FILENAME_MAX + SIZEOF_RESIDENT < 1024);
static_assert(SIZEOF_ATTRIBUTE_FILENAME_MAX + sizeof(struct NTFS_DE) <
1024);
static_assert(PATH_MAX >= 4 * 1024);
if (flags & ~RENAME_NOREPLACE)
return -EINVAL;
is_same = dentry->d_name.len == new_dentry->d_name.len &&
!memcmp(dentry->d_name.name, new_dentry->d_name.name,
dentry->d_name.len);
if (is_same && dir == new_dir) {
/* Nothing to do. */
return 0;
}
if (ntfs_is_meta_file(sbi, inode->i_ino)) {
/* Should we print an error? */
return -EINVAL;
}
if (new_inode) {
/* Target name exists. Unlink it. */
dget(new_dentry);
ni_lock_dir(new_dir_ni);
err = ntfs_unlink_inode(new_dir, new_dentry);
ni_unlock(new_dir_ni);
dput(new_dentry);
if (err)
return err;
}
/* Allocate PATH_MAX bytes. */
de = __getname();
if (!de)
return -ENOMEM;
/* Translate dentry->d_name into unicode form. */
err = fill_name_de(sbi, de, &dentry->d_name, NULL);
if (err < 0)
goto out;
if (is_same) {
/* Reuse 'de'. */
new_de = de;
} else {
/* Translate new_dentry->d_name into unicode form. */
new_de = Add2Ptr(de, 2048);
err = fill_name_de(sbi, new_de, &new_dentry->d_name, NULL);
if (err < 0)
goto out;
}
ni_lock_dir(dir_ni);
ni_lock(ni);
is_bad = false;
err = ni_rename(dir_ni, new_dir_ni, ni, de, new_de, &is_bad);
if (is_bad) {
/* Restore after failed rename failed too. */
make_bad_inode(inode);
ntfs_inode_err(inode, "failed to undo rename");
ntfs_set_state(sbi, NTFS_DIRTY_ERROR);
} else if (!err) {
inode->i_ctime = dir->i_ctime = dir->i_mtime =
current_time(dir);
mark_inode_dirty(inode);
mark_inode_dirty(dir);
if (dir != new_dir) {
new_dir->i_mtime = new_dir->i_ctime = dir->i_ctime;
mark_inode_dirty(new_dir);
}
if (IS_DIRSYNC(dir))
ntfs_sync_inode(dir);
if (IS_DIRSYNC(new_dir))
ntfs_sync_inode(inode);
}
ni_unlock(ni);
ni_unlock(dir_ni);
out:
__putname(de);
return err;
}
struct dentry *ntfs3_get_parent(struct dentry *child)
{
struct inode *inode = d_inode(child);
struct ntfs_inode *ni = ntfs_i(inode);
struct ATTR_LIST_ENTRY *le = NULL;
struct ATTRIB *attr = NULL;
struct ATTR_FILE_NAME *fname;
while ((attr = ni_find_attr(ni, attr, &le, ATTR_NAME, NULL, 0, NULL,
NULL))) {
fname = resident_data_ex(attr, SIZEOF_ATTRIBUTE_FILENAME);
if (!fname)
continue;
return d_obtain_alias(
ntfs_iget5(inode->i_sb, &fname->home, NULL));
}
return ERR_PTR(-ENOENT);
}
// clang-format off
const struct inode_operations ntfs_dir_inode_operations = {
.lookup = ntfs_lookup,
.create = ntfs_create,
.link = ntfs_link,
.unlink = ntfs_unlink,
.symlink = ntfs_symlink,
.mkdir = ntfs_mkdir,
.rmdir = ntfs_rmdir,
.mknod = ntfs_mknod,
.rename = ntfs_rename,
.permission = ntfs_permission,
.get_acl = ntfs_get_acl,
.set_acl = ntfs_set_acl,
.setattr = ntfs3_setattr,
.getattr = ntfs_getattr,
.listxattr = ntfs_listxattr,
.fiemap = ntfs_fiemap,
};
const struct inode_operations ntfs_special_inode_operations = {
.setattr = ntfs3_setattr,
.getattr = ntfs_getattr,
.listxattr = ntfs_listxattr,
.get_acl = ntfs_get_acl,
.set_acl = ntfs_set_acl,
};
// clang-format on

1224
target/linux/generic/files-5.4/fs/ntfs3/ntfs.h Normal file
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File diff suppressed because it is too large Load Diff

1137
target/linux/generic/files-5.4/fs/ntfs3/ntfs_fs.h Normal file
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File diff suppressed because it is too large Load Diff

602
target/linux/generic/files-5.4/fs/ntfs3/record.c Normal file
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@ -0,0 +1,602 @@
// SPDX-License-Identifier: GPL-2.0
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
*/
#include <linux/fs.h>
#include "debug.h"
#include "ntfs.h"
#include "ntfs_fs.h"
static inline int compare_attr(const struct ATTRIB *left, enum ATTR_TYPE type,
const __le16 *name, u8 name_len,
const u16 *upcase)
{
/* First, compare the type codes. */
int diff = le32_to_cpu(left->type) - le32_to_cpu(type);
if (diff)
return diff;
/* They have the same type code, so we have to compare the names. */
return ntfs_cmp_names(attr_name(left), left->name_len, name, name_len,
upcase, true);
}
/*
* mi_new_attt_id
*
* Return: Unused attribute id that is less than mrec->next_attr_id.
*/
static __le16 mi_new_attt_id(struct mft_inode *mi)
{
u16 free_id, max_id, t16;
struct MFT_REC *rec = mi->mrec;
struct ATTRIB *attr;
__le16 id;
id = rec->next_attr_id;
free_id = le16_to_cpu(id);
if (free_id < 0x7FFF) {
rec->next_attr_id = cpu_to_le16(free_id + 1);
return id;
}
/* One record can store up to 1024/24 ~= 42 attributes. */
free_id = 0;
max_id = 0;
attr = NULL;
for (;;) {
attr = mi_enum_attr(mi, attr);
if (!attr) {
rec->next_attr_id = cpu_to_le16(max_id + 1);
mi->dirty = true;
return cpu_to_le16(free_id);
}
t16 = le16_to_cpu(attr->id);
if (t16 == free_id) {
free_id += 1;
attr = NULL;
} else if (max_id < t16)
max_id = t16;
}
}
int mi_get(struct ntfs_sb_info *sbi, CLST rno, struct mft_inode **mi)
{
int err;
struct mft_inode *m = kzalloc(sizeof(struct mft_inode), GFP_NOFS);
if (!m)
return -ENOMEM;
err = mi_init(m, sbi, rno);
if (err) {
kfree(m);
return err;
}
err = mi_read(m, false);
if (err) {
mi_put(m);
return err;
}
*mi = m;
return 0;
}
void mi_put(struct mft_inode *mi)
{
mi_clear(mi);
kfree(mi);
}
int mi_init(struct mft_inode *mi, struct ntfs_sb_info *sbi, CLST rno)
{
mi->sbi = sbi;
mi->rno = rno;
mi->mrec = kmalloc(sbi->record_size, GFP_NOFS);
if (!mi->mrec)
return -ENOMEM;
return 0;
}
/*
* mi_read - Read MFT data.
*/
int mi_read(struct mft_inode *mi, bool is_mft)
{
int err;
struct MFT_REC *rec = mi->mrec;
struct ntfs_sb_info *sbi = mi->sbi;
u32 bpr = sbi->record_size;
u64 vbo = (u64)mi->rno << sbi->record_bits;
struct ntfs_inode *mft_ni = sbi->mft.ni;
struct runs_tree *run = mft_ni ? &mft_ni->file.run : NULL;
struct rw_semaphore *rw_lock = NULL;
if (is_mounted(sbi)) {
if (!is_mft) {
rw_lock = &mft_ni->file.run_lock;
down_read(rw_lock);
}
}
err = ntfs_read_bh(sbi, run, vbo, &rec->rhdr, bpr, &mi->nb);
if (rw_lock)
up_read(rw_lock);
if (!err)
goto ok;
if (err == -E_NTFS_FIXUP) {
mi->dirty = true;
goto ok;
}
if (err != -ENOENT)
goto out;
if (rw_lock) {
ni_lock(mft_ni);
down_write(rw_lock);
}
err = attr_load_runs_vcn(mft_ni, ATTR_DATA, NULL, 0, &mft_ni->file.run,
vbo >> sbi->cluster_bits);
if (rw_lock) {
up_write(rw_lock);
ni_unlock(mft_ni);
}
if (err)
goto out;
if (rw_lock)
down_read(rw_lock);
err = ntfs_read_bh(sbi, run, vbo, &rec->rhdr, bpr, &mi->nb);
if (rw_lock)
up_read(rw_lock);
if (err == -E_NTFS_FIXUP) {
mi->dirty = true;
goto ok;
}
if (err)
goto out;
ok:
/* Check field 'total' only here. */
if (le32_to_cpu(rec->total) != bpr) {
err = -EINVAL;
goto out;
}
return 0;
out:
return err;
}
struct ATTRIB *mi_enum_attr(struct mft_inode *mi, struct ATTRIB *attr)
{
const struct MFT_REC *rec = mi->mrec;
u32 used = le32_to_cpu(rec->used);
u32 t32, off, asize;
u16 t16;
if (!attr) {
u32 total = le32_to_cpu(rec->total);
off = le16_to_cpu(rec->attr_off);
if (used > total)
return NULL;
if (off >= used || off < MFTRECORD_FIXUP_OFFSET_1 ||
!IS_ALIGNED(off, 4)) {
return NULL;
}
/* Skip non-resident records. */
if (!is_rec_inuse(rec))
return NULL;
attr = Add2Ptr(rec, off);
} else {
/* Check if input attr inside record. */
off = PtrOffset(rec, attr);
if (off >= used)
return NULL;
asize = le32_to_cpu(attr->size);
if (asize < SIZEOF_RESIDENT) {
/* Impossible 'cause we should not return such attribute. */
return NULL;
}
attr = Add2Ptr(attr, asize);
off += asize;
}
asize = le32_to_cpu(attr->size);
/* Can we use the first field (attr->type). */
if (off + 8 > used) {
static_assert(ALIGN(sizeof(enum ATTR_TYPE), 8) == 8);
return NULL;
}
if (attr->type == ATTR_END) {
/* End of enumeration. */
return NULL;
}
/* 0x100 is last known attribute for now. */
t32 = le32_to_cpu(attr->type);
if ((t32 & 0xf) || (t32 > 0x100))
return NULL;
/* Check boundary. */
if (off + asize > used)
return NULL;
/* Check size of attribute. */
if (!attr->non_res) {
if (asize < SIZEOF_RESIDENT)
return NULL;
t16 = le16_to_cpu(attr->res.data_off);
if (t16 > asize)
return NULL;
t32 = le32_to_cpu(attr->res.data_size);
if (t16 + t32 > asize)
return NULL;
return attr;
}
/* Check some nonresident fields. */
if (attr->name_len &&
le16_to_cpu(attr->name_off) + sizeof(short) * attr->name_len >
le16_to_cpu(attr->nres.run_off)) {
return NULL;
}
if (attr->nres.svcn || !is_attr_ext(attr)) {
if (asize + 8 < SIZEOF_NONRESIDENT)
return NULL;
if (attr->nres.c_unit)
return NULL;
} else if (asize + 8 < SIZEOF_NONRESIDENT_EX)
return NULL;
return attr;
}
/*
* mi_find_attr - Find the attribute by type and name and id.
*/
struct ATTRIB *mi_find_attr(struct mft_inode *mi, struct ATTRIB *attr,
enum ATTR_TYPE type, const __le16 *name,
size_t name_len, const __le16 *id)
{
u32 type_in = le32_to_cpu(type);
u32 atype;
next_attr:
attr = mi_enum_attr(mi, attr);
if (!attr)
return NULL;
atype = le32_to_cpu(attr->type);
if (atype > type_in)
return NULL;
if (atype < type_in)
goto next_attr;
if (attr->name_len != name_len)
goto next_attr;
if (name_len && memcmp(attr_name(attr), name, name_len * sizeof(short)))
goto next_attr;
if (id && *id != attr->id)
goto next_attr;
return attr;
}
int mi_write(struct mft_inode *mi, int wait)
{
struct MFT_REC *rec;
int err;
struct ntfs_sb_info *sbi;
if (!mi->dirty)
return 0;
sbi = mi->sbi;
rec = mi->mrec;
err = ntfs_write_bh(sbi, &rec->rhdr, &mi->nb, wait);
if (err)
return err;
if (mi->rno < sbi->mft.recs_mirr)
sbi->flags |= NTFS_FLAGS_MFTMIRR;
mi->dirty = false;
return 0;
}
int mi_format_new(struct mft_inode *mi, struct ntfs_sb_info *sbi, CLST rno,
__le16 flags, bool is_mft)
{
int err;
u16 seq = 1;
struct MFT_REC *rec;
u64 vbo = (u64)rno << sbi->record_bits;
err = mi_init(mi, sbi, rno);
if (err)
return err;
rec = mi->mrec;
if (rno == MFT_REC_MFT) {
;
} else if (rno < MFT_REC_FREE) {
seq = rno;
} else if (rno >= sbi->mft.used) {
;
} else if (mi_read(mi, is_mft)) {
;
} else if (rec->rhdr.sign == NTFS_FILE_SIGNATURE) {
/* Record is reused. Update its sequence number. */
seq = le16_to_cpu(rec->seq) + 1;
if (!seq)
seq = 1;
}
memcpy(rec, sbi->new_rec, sbi->record_size);
rec->seq = cpu_to_le16(seq);
rec->flags = RECORD_FLAG_IN_USE | flags;
mi->dirty = true;
if (!mi->nb.nbufs) {
struct ntfs_inode *ni = sbi->mft.ni;
bool lock = false;
if (is_mounted(sbi) && !is_mft) {
down_read(&ni->file.run_lock);
lock = true;
}
err = ntfs_get_bh(sbi, &ni->file.run, vbo, sbi->record_size,
&mi->nb);
if (lock)
up_read(&ni->file.run_lock);
}
return err;
}
/*
* mi_mark_free - Mark record as unused and marks it as free in bitmap.
*/
void mi_mark_free(struct mft_inode *mi)
{
CLST rno = mi->rno;
struct ntfs_sb_info *sbi = mi->sbi;
if (rno >= MFT_REC_RESERVED && rno < MFT_REC_FREE) {
ntfs_clear_mft_tail(sbi, rno, rno + 1);
mi->dirty = false;
return;
}
if (mi->mrec) {
clear_rec_inuse(mi->mrec);
mi->dirty = true;
mi_write(mi, 0);
}
ntfs_mark_rec_free(sbi, rno);
}
/*
* mi_insert_attr - Reserve space for new attribute.
*
* Return: Not full constructed attribute or NULL if not possible to create.
*/
struct ATTRIB *mi_insert_attr(struct mft_inode *mi, enum ATTR_TYPE type,
const __le16 *name, u8 name_len, u32 asize,
u16 name_off)
{
size_t tail;
struct ATTRIB *attr;
__le16 id;
struct MFT_REC *rec = mi->mrec;
struct ntfs_sb_info *sbi = mi->sbi;
u32 used = le32_to_cpu(rec->used);
const u16 *upcase = sbi->upcase;
int diff;
/* Can we insert mi attribute? */
if (used + asize > mi->sbi->record_size)
return NULL;
/*
* Scan through the list of attributes to find the point
* at which we should insert it.
*/
attr = NULL;
while ((attr = mi_enum_attr(mi, attr))) {
diff = compare_attr(attr, type, name, name_len, upcase);
if (diff > 0)
break;
if (diff < 0)
continue;
if (!is_attr_indexed(attr))
return NULL;
break;
}
if (!attr) {
tail = 8; /* Not used, just to suppress warning. */
attr = Add2Ptr(rec, used - 8);
} else {
tail = used - PtrOffset(rec, attr);
}
id = mi_new_attt_id(mi);
memmove(Add2Ptr(attr, asize), attr, tail);
memset(attr, 0, asize);
attr->type = type;
attr->size = cpu_to_le32(asize);
attr->name_len = name_len;
attr->name_off = cpu_to_le16(name_off);
attr->id = id;
memmove(Add2Ptr(attr, name_off), name, name_len * sizeof(short));
rec->used = cpu_to_le32(used + asize);
mi->dirty = true;
return attr;
}
/*
* mi_remove_attr - Remove the attribute from record.
*
* NOTE: The source attr will point to next attribute.
*/
bool mi_remove_attr(struct ntfs_inode *ni, struct mft_inode *mi,
struct ATTRIB *attr)
{
struct MFT_REC *rec = mi->mrec;
u32 aoff = PtrOffset(rec, attr);
u32 used = le32_to_cpu(rec->used);
u32 asize = le32_to_cpu(attr->size);
if (aoff + asize > used)
return false;
if (ni && is_attr_indexed(attr)) {
le16_add_cpu(&ni->mi.mrec->hard_links, -1);
ni->mi.dirty = true;
}
used -= asize;
memmove(attr, Add2Ptr(attr, asize), used - aoff);
rec->used = cpu_to_le32(used);
mi->dirty = true;
return true;
}
/* bytes = "new attribute size" - "old attribute size" */
bool mi_resize_attr(struct mft_inode *mi, struct ATTRIB *attr, int bytes)
{
struct MFT_REC *rec = mi->mrec;
u32 aoff = PtrOffset(rec, attr);
u32 total, used = le32_to_cpu(rec->used);
u32 nsize, asize = le32_to_cpu(attr->size);
u32 rsize = le32_to_cpu(attr->res.data_size);
int tail = (int)(used - aoff - asize);
int dsize;
char *next;
if (tail < 0 || aoff >= used)
return false;
if (!bytes)
return true;
total = le32_to_cpu(rec->total);
next = Add2Ptr(attr, asize);
if (bytes > 0) {
dsize = ALIGN(bytes, 8);
if (used + dsize > total)
return false;
nsize = asize + dsize;
/* Move tail */
memmove(next + dsize, next, tail);
memset(next, 0, dsize);
used += dsize;
rsize += dsize;
} else {
dsize = ALIGN(-bytes, 8);
if (dsize > asize)
return false;
nsize = asize - dsize;
memmove(next - dsize, next, tail);
used -= dsize;
rsize -= dsize;
}
rec->used = cpu_to_le32(used);
attr->size = cpu_to_le32(nsize);
if (!attr->non_res)
attr->res.data_size = cpu_to_le32(rsize);
mi->dirty = true;
return true;
}
int mi_pack_runs(struct mft_inode *mi, struct ATTRIB *attr,
struct runs_tree *run, CLST len)
{
int err = 0;
struct ntfs_sb_info *sbi = mi->sbi;
u32 new_run_size;
CLST plen;
struct MFT_REC *rec = mi->mrec;
CLST svcn = le64_to_cpu(attr->nres.svcn);
u32 used = le32_to_cpu(rec->used);
u32 aoff = PtrOffset(rec, attr);
u32 asize = le32_to_cpu(attr->size);
char *next = Add2Ptr(attr, asize);
u16 run_off = le16_to_cpu(attr->nres.run_off);
u32 run_size = asize - run_off;
u32 tail = used - aoff - asize;
u32 dsize = sbi->record_size - used;
/* Make a maximum gap in current record. */
memmove(next + dsize, next, tail);
/* Pack as much as possible. */
err = run_pack(run, svcn, len, Add2Ptr(attr, run_off), run_size + dsize,
&plen);
if (err < 0) {
memmove(next, next + dsize, tail);
return err;
}
new_run_size = ALIGN(err, 8);
memmove(next + new_run_size - run_size, next + dsize, tail);
attr->size = cpu_to_le32(asize + new_run_size - run_size);
attr->nres.evcn = cpu_to_le64(svcn + plen - 1);
rec->used = cpu_to_le32(used + new_run_size - run_size);
mi->dirty = true;
return 0;
}

1111
target/linux/generic/files-5.4/fs/ntfs3/run.c Normal file
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File diff suppressed because it is too large Load Diff

1511
target/linux/generic/files-5.4/fs/ntfs3/super.c Normal file
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File diff suppressed because it is too large Load Diff

104
target/linux/generic/files-5.4/fs/ntfs3/upcase.c Normal file
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@ -0,0 +1,104 @@
// SPDX-License-Identifier: GPL-2.0
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
*/
#include <linux/kernel.h>
#include <linux/types.h>
#include "ntfs_fs.h"
static inline u16 upcase_unicode_char(const u16 *upcase, u16 chr)
{
if (chr < 'a')
return chr;
if (chr <= 'z')
return chr - ('a' - 'A');
return upcase[chr];
}
/*
* ntfs_cmp_names
*
* Thanks Kari Argillander <kari.argillander@gmail.com> for idea and implementation 'bothcase'
*
* Straight way to compare names:
* - Case insensitive
* - If name equals and 'bothcases' then
* - Case sensitive
* 'Straight way' code scans input names twice in worst case.
* Optimized code scans input names only once.
*/
int ntfs_cmp_names(const __le16 *s1, size_t l1, const __le16 *s2, size_t l2,
const u16 *upcase, bool bothcase)
{
int diff1 = 0;
int diff2;
size_t len = min(l1, l2);
if (!bothcase && upcase)
goto case_insentive;
for (; len; s1++, s2++, len--) {
diff1 = le16_to_cpu(*s1) - le16_to_cpu(*s2);
if (diff1) {
if (bothcase && upcase)
goto case_insentive;
return diff1;
}
}
return l1 - l2;
case_insentive:
for (; len; s1++, s2++, len--) {
diff2 = upcase_unicode_char(upcase, le16_to_cpu(*s1)) -
upcase_unicode_char(upcase, le16_to_cpu(*s2));
if (diff2)
return diff2;
}
diff2 = l1 - l2;
return diff2 ? diff2 : diff1;
}
int ntfs_cmp_names_cpu(const struct cpu_str *uni1, const struct le_str *uni2,
const u16 *upcase, bool bothcase)
{
const u16 *s1 = uni1->name;
const __le16 *s2 = uni2->name;
size_t l1 = uni1->len;
size_t l2 = uni2->len;
size_t len = min(l1, l2);
int diff1 = 0;
int diff2;
if (!bothcase && upcase)
goto case_insentive;
for (; len; s1++, s2++, len--) {
diff1 = *s1 - le16_to_cpu(*s2);
if (diff1) {
if (bothcase && upcase)
goto case_insentive;
return diff1;
}
}
return l1 - l2;
case_insentive:
for (; len; s1++, s2++, len--) {
diff2 = upcase_unicode_char(upcase, *s1) -
upcase_unicode_char(upcase, le16_to_cpu(*s2));
if (diff2)
return diff2;
}
diff2 = l1 - l2;
return diff2 ? diff2 : diff1;
}

992
target/linux/generic/files-5.4/fs/ntfs3/xattr.c Normal file
View File

@ -0,0 +1,992 @@
// SPDX-License-Identifier: GPL-2.0
/*
*
* Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved.
*
*/
#include <linux/fs.h>
#include <linux/posix_acl.h>
#include <linux/posix_acl_xattr.h>
#include <linux/xattr.h>
#include "debug.h"
#include "ntfs.h"
#include "ntfs_fs.h"
// clang-format off
#define SYSTEM_DOS_ATTRIB "system.dos_attrib"
#define SYSTEM_NTFS_ATTRIB "system.ntfs_attrib"
#define SYSTEM_NTFS_SECURITY "system.ntfs_security"
// clang-format on
static inline size_t unpacked_ea_size(const struct EA_FULL *ea)
{
return ea->size ? le32_to_cpu(ea->size)
: ALIGN(struct_size(ea, name,
1 + ea->name_len +
le16_to_cpu(ea->elength)),
4);
}
static inline size_t packed_ea_size(const struct EA_FULL *ea)
{
return struct_size(ea, name,
1 + ea->name_len + le16_to_cpu(ea->elength)) -
offsetof(struct EA_FULL, flags);
}
/*
* find_ea
*
* Assume there is at least one xattr in the list.
*/
static inline bool find_ea(const struct EA_FULL *ea_all, u32 bytes,
const char *name, u8 name_len, u32 *off)
{
*off = 0;
if (!ea_all || !bytes)
return false;
for (;;) {
const struct EA_FULL *ea = Add2Ptr(ea_all, *off);
u32 next_off = *off + unpacked_ea_size(ea);
if (next_off > bytes)
return false;
if (ea->name_len == name_len &&
!memcmp(ea->name, name, name_len))
return true;
*off = next_off;
if (next_off >= bytes)
return false;
}
}
/*
* ntfs_read_ea - Read all extended attributes.
* @ea: New allocated memory.
* @info: Pointer into resident data.
*/
static int ntfs_read_ea(struct ntfs_inode *ni, struct EA_FULL **ea,
size_t add_bytes, const struct EA_INFO **info)
{
int err;
struct ntfs_sb_info *sbi = ni->mi.sbi;
struct ATTR_LIST_ENTRY *le = NULL;
struct ATTRIB *attr_info, *attr_ea;
void *ea_p;
u32 size;
static_assert(le32_to_cpu(ATTR_EA_INFO) < le32_to_cpu(ATTR_EA));
*ea = NULL;
*info = NULL;
attr_info =
ni_find_attr(ni, NULL, &le, ATTR_EA_INFO, NULL, 0, NULL, NULL);
attr_ea =
ni_find_attr(ni, attr_info, &le, ATTR_EA, NULL, 0, NULL, NULL);
if (!attr_ea || !attr_info)
return 0;
*info = resident_data_ex(attr_info, sizeof(struct EA_INFO));
if (!*info)
return -EINVAL;
/* Check Ea limit. */
size = le32_to_cpu((*info)->size);
if (size > sbi->ea_max_size)
return -EFBIG;
if (attr_size(attr_ea) > sbi->ea_max_size)
return -EFBIG;
/* Allocate memory for packed Ea. */
ea_p = kmalloc(size + add_bytes, GFP_NOFS);
if (!ea_p)
return -ENOMEM;
if (!size) {
;
} else if (attr_ea->non_res) {
struct runs_tree run;
run_init(&run);
err = attr_load_runs(attr_ea, ni, &run, NULL);
if (!err)
err = ntfs_read_run_nb(sbi, &run, 0, ea_p, size, NULL);
run_close(&run);
if (err)
goto out;
} else {
void *p = resident_data_ex(attr_ea, size);
if (!p) {
err = -EINVAL;
goto out;
}
memcpy(ea_p, p, size);
}
memset(Add2Ptr(ea_p, size), 0, add_bytes);
*ea = ea_p;
return 0;
out:
kfree(ea_p);
*ea = NULL;
return err;
}
/*
* ntfs_list_ea
*
* Copy a list of xattrs names into the buffer
* provided, or compute the buffer size required.
*
* Return:
* * Number of bytes used / required on
* * -ERRNO - on failure
*/
static ssize_t ntfs_list_ea(struct ntfs_inode *ni, char *buffer,
size_t bytes_per_buffer)
{
const struct EA_INFO *info;
struct EA_FULL *ea_all = NULL;
const struct EA_FULL *ea;
u32 off, size;
int err;
size_t ret;
err = ntfs_read_ea(ni, &ea_all, 0, &info);
if (err)
return err;
if (!info || !ea_all)
return 0;
size = le32_to_cpu(info->size);
/* Enumerate all xattrs. */
for (ret = 0, off = 0; off < size; off += unpacked_ea_size(ea)) {
ea = Add2Ptr(ea_all, off);
if (buffer) {
if (ret + ea->name_len + 1 > bytes_per_buffer) {
err = -ERANGE;
goto out;
}
memcpy(buffer + ret, ea->name, ea->name_len);
buffer[ret + ea->name_len] = 0;
}
ret += ea->name_len + 1;
}
out:
kfree(ea_all);
return err ? err : ret;
}
static int ntfs_get_ea(struct inode *inode, const char *name, size_t name_len,
void *buffer, size_t size, size_t *required)
{
struct ntfs_inode *ni = ntfs_i(inode);
const struct EA_INFO *info;
struct EA_FULL *ea_all = NULL;
const struct EA_FULL *ea;
u32 off, len;
int err;
if (!(ni->ni_flags & NI_FLAG_EA))
return -ENODATA;
if (!required)
ni_lock(ni);
len = 0;
if (name_len > 255) {
err = -ENAMETOOLONG;
goto out;
}
err = ntfs_read_ea(ni, &ea_all, 0, &info);
if (err)
goto out;
if (!info)
goto out;
/* Enumerate all xattrs. */
if (!find_ea(ea_all, le32_to_cpu(info->size), name, name_len, &off)) {
err = -ENODATA;
goto out;
}
ea = Add2Ptr(ea_all, off);
len = le16_to_cpu(ea->elength);
if (!buffer) {
err = 0;
goto out;
}
if (len > size) {
err = -ERANGE;
if (required)
*required = len;
goto out;
}
memcpy(buffer, ea->name + ea->name_len + 1, len);
err = 0;
out:
kfree(ea_all);
if (!required)
ni_unlock(ni);
return err ? err : len;
}
static noinline int ntfs_set_ea(struct inode *inode, const char *name,
size_t name_len, const void *value,
size_t val_size, int flags)
{
struct ntfs_inode *ni = ntfs_i(inode);
struct ntfs_sb_info *sbi = ni->mi.sbi;
int err;
struct EA_INFO ea_info;
const struct EA_INFO *info;
struct EA_FULL *new_ea;
struct EA_FULL *ea_all = NULL;
size_t add, new_pack;
u32 off, size;
__le16 size_pack;
struct ATTRIB *attr;
struct ATTR_LIST_ENTRY *le;
struct mft_inode *mi;
struct runs_tree ea_run;
u64 new_sz;
void *p;
ni_lock(ni);
run_init(&ea_run);
if (name_len > 255) {
err = -ENAMETOOLONG;
goto out;
}
add = ALIGN(struct_size(ea_all, name, 1 + name_len + val_size), 4);
err = ntfs_read_ea(ni, &ea_all, add, &info);
if (err)
goto out;
if (!info) {
memset(&ea_info, 0, sizeof(ea_info));
size = 0;
size_pack = 0;
} else {
memcpy(&ea_info, info, sizeof(ea_info));
size = le32_to_cpu(ea_info.size);
size_pack = ea_info.size_pack;
}
if (info && find_ea(ea_all, size, name, name_len, &off)) {
struct EA_FULL *ea;
size_t ea_sz;
if (flags & XATTR_CREATE) {
err = -EEXIST;
goto out;
}
ea = Add2Ptr(ea_all, off);
/*
* Check simple case when we try to insert xattr with the same value
* e.g. ntfs_save_wsl_perm
*/
if (val_size && le16_to_cpu(ea->elength) == val_size &&
!memcmp(ea->name + ea->name_len + 1, value, val_size)) {
/* xattr already contains the required value. */
goto out;
}
/* Remove current xattr. */
if (ea->flags & FILE_NEED_EA)
le16_add_cpu(&ea_info.count, -1);
ea_sz = unpacked_ea_size(ea);
le16_add_cpu(&ea_info.size_pack, 0 - packed_ea_size(ea));
memmove(ea, Add2Ptr(ea, ea_sz), size - off - ea_sz);
size -= ea_sz;
memset(Add2Ptr(ea_all, size), 0, ea_sz);
ea_info.size = cpu_to_le32(size);
if ((flags & XATTR_REPLACE) && !val_size) {
/* Remove xattr. */
goto update_ea;
}
} else {
if (flags & XATTR_REPLACE) {
err = -ENODATA;
goto out;
}
if (!ea_all) {
ea_all = kzalloc(add, GFP_NOFS);
if (!ea_all) {
err = -ENOMEM;
goto out;
}
}
}
/* Append new xattr. */
new_ea = Add2Ptr(ea_all, size);
new_ea->size = cpu_to_le32(add);
new_ea->flags = 0;
new_ea->name_len = name_len;
new_ea->elength = cpu_to_le16(val_size);
memcpy(new_ea->name, name, name_len);
new_ea->name[name_len] = 0;
memcpy(new_ea->name + name_len + 1, value, val_size);
new_pack = le16_to_cpu(ea_info.size_pack) + packed_ea_size(new_ea);
ea_info.size_pack = cpu_to_le16(new_pack);
/* New size of ATTR_EA. */
size += add;
ea_info.size = cpu_to_le32(size);
/*
* 1. Check ea_info.size_pack for overflow.
* 2. New attibute size must fit value from $AttrDef
*/
if (new_pack > 0xffff || size > sbi->ea_max_size) {
ntfs_inode_warn(
inode,
"The size of extended attributes must not exceed 64KiB");
err = -EFBIG; // -EINVAL?
goto out;
}
update_ea:
if (!info) {
/* Create xattr. */
if (!size) {
err = 0;
goto out;
}
err = ni_insert_resident(ni, sizeof(struct EA_INFO),
ATTR_EA_INFO, NULL, 0, NULL, NULL,
NULL);
if (err)
goto out;
err = ni_insert_resident(ni, 0, ATTR_EA, NULL, 0, NULL, NULL,
NULL);
if (err)
goto out;
}
new_sz = size;
err = attr_set_size(ni, ATTR_EA, NULL, 0, &ea_run, new_sz, &new_sz,
false, NULL);
if (err)
goto out;
le = NULL;
attr = ni_find_attr(ni, NULL, &le, ATTR_EA_INFO, NULL, 0, NULL, &mi);
if (!attr) {
err = -EINVAL;
goto out;
}
if (!size) {
/* Delete xattr, ATTR_EA_INFO */
ni_remove_attr_le(ni, attr, mi, le);
} else {
p = resident_data_ex(attr, sizeof(struct EA_INFO));
if (!p) {
err = -EINVAL;
goto out;
}
memcpy(p, &ea_info, sizeof(struct EA_INFO));
mi->dirty = true;
}
le = NULL;
attr = ni_find_attr(ni, NULL, &le, ATTR_EA, NULL, 0, NULL, &mi);
if (!attr) {
err = -EINVAL;
goto out;
}
if (!size) {
/* Delete xattr, ATTR_EA */
ni_remove_attr_le(ni, attr, mi, le);
} else if (attr->non_res) {
err = ntfs_sb_write_run(sbi, &ea_run, 0, ea_all, size, 0);
if (err)
goto out;
} else {
p = resident_data_ex(attr, size);
if (!p) {
err = -EINVAL;
goto out;
}
memcpy(p, ea_all, size);
mi->dirty = true;
}
/* Check if we delete the last xattr. */
if (size)
ni->ni_flags |= NI_FLAG_EA;
else
ni->ni_flags &= ~NI_FLAG_EA;
if (ea_info.size_pack != size_pack)
ni->ni_flags |= NI_FLAG_UPDATE_PARENT;
mark_inode_dirty(&ni->vfs_inode);
out:
ni_unlock(ni);
run_close(&ea_run);
kfree(ea_all);
return err;
}
#ifdef CONFIG_NTFS3_FS_POSIX_ACL
static struct posix_acl *ntfs_get_acl_ex(
struct inode *inode, int type,
int locked)
{
struct ntfs_inode *ni = ntfs_i(inode);
const char *name;
size_t name_len;
struct posix_acl *acl;
size_t req;
int err;
void *buf;
/* Allocate PATH_MAX bytes. */
buf = __getname();
if (!buf)
return ERR_PTR(-ENOMEM);
/* Possible values of 'type' was already checked above. */
if (type == ACL_TYPE_ACCESS) {
name = XATTR_NAME_POSIX_ACL_ACCESS;
name_len = sizeof(XATTR_NAME_POSIX_ACL_ACCESS) - 1;
} else {
name = XATTR_NAME_POSIX_ACL_DEFAULT;
name_len = sizeof(XATTR_NAME_POSIX_ACL_DEFAULT) - 1;
}
if (!locked)
ni_lock(ni);
err = ntfs_get_ea(inode, name, name_len, buf, PATH_MAX, &req);
if (!locked)
ni_unlock(ni);
/* Translate extended attribute to acl. */
if (err >= 0) {
acl = posix_acl_from_xattr(&init_user_ns, buf, err);
} else if (err == -ENODATA) {
acl = NULL;
} else {
acl = ERR_PTR(err);
}
if (!IS_ERR(acl))
set_cached_acl(inode, type, acl);
__putname(buf);
return acl;
}
/*
* ntfs_get_acl - inode_operations::get_acl
*/
struct posix_acl *ntfs_get_acl(struct inode *inode, int type)
{
/* TODO: init_user_ns? */
return ntfs_get_acl_ex(inode, type, 0);
}
static noinline int ntfs_set_acl_ex(
struct inode *inode, struct posix_acl *acl,
int type)
{
const char *name;
size_t size, name_len;
void *value = NULL;
int err = 0;
int flags;
if (S_ISLNK(inode->i_mode))
return -EOPNOTSUPP;
switch (type) {
case ACL_TYPE_ACCESS:
if (acl) {
umode_t mode = inode->i_mode;
err = posix_acl_update_mode(inode, &mode,
&acl);
if (err)
goto out;
if (inode->i_mode != mode) {
inode->i_mode = mode;
mark_inode_dirty(inode);
}
}
name = XATTR_NAME_POSIX_ACL_ACCESS;
name_len = sizeof(XATTR_NAME_POSIX_ACL_ACCESS) - 1;
break;
case ACL_TYPE_DEFAULT:
if (!S_ISDIR(inode->i_mode))
return acl ? -EACCES : 0;
name = XATTR_NAME_POSIX_ACL_DEFAULT;
name_len = sizeof(XATTR_NAME_POSIX_ACL_DEFAULT) - 1;
break;
default:
return -EINVAL;
}
if (!acl) {
/* Remove xattr if it can be presented via mode. */
size = 0;
value = NULL;
flags = XATTR_REPLACE;
} else {
size = posix_acl_xattr_size(acl->a_count);
value = kmalloc(size, GFP_NOFS);
if (!value)
return -ENOMEM;
err = posix_acl_to_xattr(&init_user_ns, acl, value, size);
if (err < 0)
goto out;
flags = 0;
}
err = ntfs_set_ea(inode, name, name_len, value, size, flags);
if (err == -ENODATA && !size)
err = 0; /* Removing non existed xattr. */
if (!err)
set_cached_acl(inode, type, acl);
out:
kfree(value);
return err;
}
/*
* ntfs_set_acl - inode_operations::set_acl
*/
int ntfs_set_acl(struct inode *inode,
struct posix_acl *acl, int type)
{
return ntfs_set_acl_ex(inode, acl, type);
}
/*
* ntfs_init_acl - Initialize the ACLs of a new inode.
*
* Called from ntfs_create_inode().
*/
int ntfs_init_acl(struct inode *inode,
struct inode *dir)
{
struct posix_acl *default_acl, *acl;
int err;
err = posix_acl_create(dir, &inode->i_mode, &default_acl, &acl);
if (err)
return err;
if (default_acl) {
err = ntfs_set_acl_ex(inode, default_acl,
ACL_TYPE_DEFAULT);
posix_acl_release(default_acl);
} else {
inode->i_default_acl = NULL;
}
if (!acl)
inode->i_acl = NULL;
else {
if (!err)
err = ntfs_set_acl_ex(inode, acl,
ACL_TYPE_ACCESS);
posix_acl_release(acl);
}
return err;
}
#endif
/*
* ntfs_acl_chmod - Helper for ntfs3_setattr().
*/
int ntfs_acl_chmod(struct inode *inode)
{
struct super_block *sb = inode->i_sb;
if (!(sb->s_flags & SB_POSIXACL))
return 0;
if (S_ISLNK(inode->i_mode))
return -EOPNOTSUPP;
return posix_acl_chmod(inode, inode->i_mode);
}
/*
* ntfs_permission - inode_operations::permission
*/
int ntfs_permission(struct inode *inode,
int mask)
{
if (ntfs_sb(inode->i_sb)->options->noacsrules) {
/* "No access rules" mode - Allow all changes. */
return 0;
}
return generic_permission(inode, mask);
}
/*
* ntfs_listxattr - inode_operations::listxattr
*/
ssize_t ntfs_listxattr(struct dentry *dentry, char *buffer, size_t size)
{
struct inode *inode = d_inode(dentry);
struct ntfs_inode *ni = ntfs_i(inode);
ssize_t ret;
if (!(ni->ni_flags & NI_FLAG_EA)) {
/* no xattr in file */
return 0;
}
ni_lock(ni);
ret = ntfs_list_ea(ni, buffer, size);
ni_unlock(ni);
return ret;
}
static int ntfs_getxattr(const struct xattr_handler *handler, struct dentry *de,
struct inode *inode, const char *name, void *buffer,
size_t size)
{
int err;
struct ntfs_inode *ni = ntfs_i(inode);
size_t name_len = strlen(name);
/* Dispatch request. */
if (name_len == sizeof(SYSTEM_DOS_ATTRIB) - 1 &&
!memcmp(name, SYSTEM_DOS_ATTRIB, sizeof(SYSTEM_DOS_ATTRIB))) {
/* system.dos_attrib */
if (!buffer) {
err = sizeof(u8);
} else if (size < sizeof(u8)) {
err = -ENODATA;
} else {
err = sizeof(u8);
*(u8 *)buffer = le32_to_cpu(ni->std_fa);
}
goto out;
}
if (name_len == sizeof(SYSTEM_NTFS_ATTRIB) - 1 &&
!memcmp(name, SYSTEM_NTFS_ATTRIB, sizeof(SYSTEM_NTFS_ATTRIB))) {
/* system.ntfs_attrib */
if (!buffer) {
err = sizeof(u32);
} else if (size < sizeof(u32)) {
err = -ENODATA;
} else {
err = sizeof(u32);
*(u32 *)buffer = le32_to_cpu(ni->std_fa);
}
goto out;
}
if (name_len == sizeof(SYSTEM_NTFS_SECURITY) - 1 &&
!memcmp(name, SYSTEM_NTFS_SECURITY, sizeof(SYSTEM_NTFS_SECURITY))) {
/* system.ntfs_security*/
struct SECURITY_DESCRIPTOR_RELATIVE *sd = NULL;
size_t sd_size = 0;
if (!is_ntfs3(ni->mi.sbi)) {
/* We should get nt4 security. */
err = -EINVAL;
goto out;
} else if (le32_to_cpu(ni->std_security_id) <
SECURITY_ID_FIRST) {
err = -ENOENT;
goto out;
}
err = ntfs_get_security_by_id(ni->mi.sbi, ni->std_security_id,
&sd, &sd_size);
if (err)
goto out;
if (!is_sd_valid(sd, sd_size)) {
ntfs_inode_warn(
inode,
"looks like you get incorrect security descriptor id=%u",
ni->std_security_id);
}
if (!buffer) {
err = sd_size;
} else if (size < sd_size) {
err = -ENODATA;
} else {
err = sd_size;
memcpy(buffer, sd, sd_size);
}
kfree(sd);
goto out;
}
/* Deal with NTFS extended attribute. */
err = ntfs_get_ea(inode, name, name_len, buffer, size, NULL);
out:
return err;
}
/*
* ntfs_setxattr - inode_operations::setxattr
*/
static noinline int ntfs_setxattr(const struct xattr_handler *handler,
struct dentry *de, struct inode *inode,
const char *name, const void *value,
size_t size, int flags)
{
int err = -EINVAL;
struct ntfs_inode *ni = ntfs_i(inode);
size_t name_len = strlen(name);
enum FILE_ATTRIBUTE new_fa;
/* Dispatch request. */
if (name_len == sizeof(SYSTEM_DOS_ATTRIB) - 1 &&
!memcmp(name, SYSTEM_DOS_ATTRIB, sizeof(SYSTEM_DOS_ATTRIB))) {
if (sizeof(u8) != size)
goto out;
new_fa = cpu_to_le32(*(u8 *)value);
goto set_new_fa;
}
if (name_len == sizeof(SYSTEM_NTFS_ATTRIB) - 1 &&
!memcmp(name, SYSTEM_NTFS_ATTRIB, sizeof(SYSTEM_NTFS_ATTRIB))) {
if (size != sizeof(u32))
goto out;
new_fa = cpu_to_le32(*(u32 *)value);
if (S_ISREG(inode->i_mode)) {
/* Process compressed/sparsed in special way. */
ni_lock(ni);
err = ni_new_attr_flags(ni, new_fa);
ni_unlock(ni);
if (err)
goto out;
}
set_new_fa:
/*
* Thanks Mark Harmstone:
* Keep directory bit consistency.
*/
if (S_ISDIR(inode->i_mode))
new_fa |= FILE_ATTRIBUTE_DIRECTORY;
else
new_fa &= ~FILE_ATTRIBUTE_DIRECTORY;
if (ni->std_fa != new_fa) {
ni->std_fa = new_fa;
if (new_fa & FILE_ATTRIBUTE_READONLY)
inode->i_mode &= ~0222;
else
inode->i_mode |= 0222;
/* Std attribute always in primary record. */
ni->mi.dirty = true;
mark_inode_dirty(inode);
}
err = 0;
goto out;
}
if (name_len == sizeof(SYSTEM_NTFS_SECURITY) - 1 &&
!memcmp(name, SYSTEM_NTFS_SECURITY, sizeof(SYSTEM_NTFS_SECURITY))) {
/* system.ntfs_security*/
__le32 security_id;
bool inserted;
struct ATTR_STD_INFO5 *std;
if (!is_ntfs3(ni->mi.sbi)) {
/*
* We should replace ATTR_SECURE.
* Skip this way cause it is nt4 feature.
*/
err = -EINVAL;
goto out;
}
if (!is_sd_valid(value, size)) {
err = -EINVAL;
ntfs_inode_warn(
inode,
"you try to set invalid security descriptor");
goto out;
}
err = ntfs_insert_security(ni->mi.sbi, value, size,
&security_id, &inserted);
if (err)
goto out;
ni_lock(ni);
std = ni_std5(ni);
if (!std) {
err = -EINVAL;
} else if (std->security_id != security_id) {
std->security_id = ni->std_security_id = security_id;
/* Std attribute always in primary record. */
ni->mi.dirty = true;
mark_inode_dirty(&ni->vfs_inode);
}
ni_unlock(ni);
goto out;
}
/* Deal with NTFS extended attribute. */
err = ntfs_set_ea(inode, name, name_len, value, size, flags);
out:
return err;
}
/*
* ntfs_save_wsl_perm
*
* save uid/gid/mode in xattr
*/
int ntfs_save_wsl_perm(struct inode *inode)
{
int err;
__le32 value;
/* TODO: refactor this, so we don't lock 4 times in ntfs_set_ea */
value = cpu_to_le32(i_uid_read(inode));
err = ntfs_set_ea(inode, "$LXUID", sizeof("$LXUID") - 1, &value,
sizeof(value), 0);
if (err)
goto out;
value = cpu_to_le32(i_gid_read(inode));
err = ntfs_set_ea(inode, "$LXGID", sizeof("$LXGID") - 1, &value,
sizeof(value), 0);
if (err)
goto out;
value = cpu_to_le32(inode->i_mode);
err = ntfs_set_ea(inode, "$LXMOD", sizeof("$LXMOD") - 1, &value,
sizeof(value), 0);
if (err)
goto out;
if (S_ISCHR(inode->i_mode) || S_ISBLK(inode->i_mode)) {
value = cpu_to_le32(inode->i_rdev);
err = ntfs_set_ea(inode, "$LXDEV", sizeof("$LXDEV") - 1, &value,
sizeof(value), 0);
if (err)
goto out;
}
out:
/* In case of error should we delete all WSL xattr? */
return err;
}
/*
* ntfs_get_wsl_perm
*
* get uid/gid/mode from xattr
* it is called from ntfs_iget5->ntfs_read_mft
*/
void ntfs_get_wsl_perm(struct inode *inode)
{
size_t sz;
__le32 value[3];
if (ntfs_get_ea(inode, "$LXUID", sizeof("$LXUID") - 1, &value[0],
sizeof(value[0]), &sz) == sizeof(value[0]) &&
ntfs_get_ea(inode, "$LXGID", sizeof("$LXGID") - 1, &value[1],
sizeof(value[1]), &sz) == sizeof(value[1]) &&
ntfs_get_ea(inode, "$LXMOD", sizeof("$LXMOD") - 1, &value[2],
sizeof(value[2]), &sz) == sizeof(value[2])) {
i_uid_write(inode, (uid_t)le32_to_cpu(value[0]));
i_gid_write(inode, (gid_t)le32_to_cpu(value[1]));
inode->i_mode = le32_to_cpu(value[2]);
if (ntfs_get_ea(inode, "$LXDEV", sizeof("$$LXDEV") - 1,
&value[0], sizeof(value),
&sz) == sizeof(value[0])) {
inode->i_rdev = le32_to_cpu(value[0]);
}
}
}
static bool ntfs_xattr_user_list(struct dentry *dentry)
{
return true;
}
// clang-format off
static const struct xattr_handler ntfs_xattr_handler = {
.prefix = "",
.get = ntfs_getxattr,
.set = ntfs_setxattr,
.list = ntfs_xattr_user_list,
};
const struct xattr_handler *ntfs_xattr_handlers[] = {
&ntfs_xattr_handler,
NULL,
};
// clang-format on