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lvm2/libdm/libdevmapper.h

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/*
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* Copyright (C) 2001-2004 Sistina Software, Inc. All rights reserved.
* Copyright (C) 2004-2011 Red Hat, Inc. All rights reserved.
*
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* This file is part of the device-mapper userspace tools.
*
* This copyrighted material is made available to anyone wishing to use,
* modify, copy, or redistribute it subject to the terms and conditions
* of the GNU Lesser General Public License v.2.1.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#ifndef LIB_DEVICE_MAPPER_H
#define LIB_DEVICE_MAPPER_H
#include <inttypes.h>
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#include <stdarg.h>
#include <sys/types.h>
#include <sys/stat.h>
#ifdef linux
# include <linux/types.h>
#endif
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#include <limits.h>
#include <string.h>
#include <stdlib.h>
#include <stdio.h>
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#ifndef __GNUC__
# define __typeof__ typeof
#endif
#ifdef __cplusplus
extern "C" {
#endif
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/*****************************************************************
* The first section of this file provides direct access to the
* individual device-mapper ioctls. Since it is quite laborious to
* build the ioctl arguments for the device-mapper, people are
* encouraged to use this library.
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****************************************************************/
/*
* The library user may wish to register their own
* logging function. By default errors go to stderr.
* Use dm_log_with_errno_init(NULL) to restore the default log fn.
*/
typedef void (*dm_log_with_errno_fn) (int level, const char *file, int line,
int dm_errno, const char *f, ...)
__attribute__ ((format(printf, 5, 6)));
void dm_log_with_errno_init(dm_log_with_errno_fn fn);
void dm_log_init_verbose(int level);
/*
* Original version of this function.
* dm_errno is set to 0.
*
* Deprecated: Use the _with_errno_ versions above instead.
*/
typedef void (*dm_log_fn) (int level, const char *file, int line,
const char *f, ...)
__attribute__ ((format(printf, 4, 5)));
void dm_log_init(dm_log_fn fn);
/*
* For backward-compatibility, indicate that dm_log_init() was used
* to set a non-default value of dm_log().
*/
int dm_log_is_non_default(void);
/*
* Number of devices currently in suspended state (via the library).
*/
int dm_get_suspended_counter(void);
enum {
DM_DEVICE_CREATE,
DM_DEVICE_RELOAD,
DM_DEVICE_REMOVE,
DM_DEVICE_REMOVE_ALL,
DM_DEVICE_SUSPEND,
DM_DEVICE_RESUME,
DM_DEVICE_INFO,
DM_DEVICE_DEPS,
DM_DEVICE_RENAME,
DM_DEVICE_VERSION,
DM_DEVICE_STATUS,
DM_DEVICE_TABLE,
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DM_DEVICE_WAITEVENT,
DM_DEVICE_LIST,
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DM_DEVICE_CLEAR,
DM_DEVICE_MKNODES,
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DM_DEVICE_LIST_VERSIONS,
DM_DEVICE_TARGET_MSG,
DM_DEVICE_SET_GEOMETRY
};
/*
* You will need to build a struct dm_task for
* each ioctl command you want to execute.
*/
struct dm_task;
struct dm_task *dm_task_create(int type);
void dm_task_destroy(struct dm_task *dmt);
int dm_task_set_name(struct dm_task *dmt, const char *name);
int dm_task_set_uuid(struct dm_task *dmt, const char *uuid);
/*
* Retrieve attributes after an info.
*/
struct dm_info {
int exists;
int suspended;
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int live_table;
int inactive_table;
int32_t open_count;
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uint32_t event_nr;
uint32_t major;
uint32_t minor; /* minor device number */
int read_only; /* 0:read-write; 1:read-only */
int32_t target_count;
};
struct dm_deps {
uint32_t count;
uint32_t filler;
uint64_t device[0];
};
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struct dm_names {
uint64_t dev;
uint32_t next; /* Offset to next struct from start of this struct */
char name[0];
};
struct dm_versions {
uint32_t next; /* Offset to next struct from start of this struct */
uint32_t version[3];
char name[0];
};
int dm_get_library_version(char *version, size_t size);
int dm_task_get_driver_version(struct dm_task *dmt, char *version, size_t size);
int dm_task_get_info(struct dm_task *dmt, struct dm_info *dmi);
/*
* This function returns dm device's UUID based on the value
* of the mangling mode set during preceding dm_task_run call:
* - unmangled name for DM_STRING_MANGLING_{AUTO, HEX},
* - name without any changes for DM_STRING_MANGLING_NONE.
*
* To get mangled or unmangled form of the name directly, use
* dm_task_get_uuid_mangled or dm_task_get_uuid_unmangled function.
*/
const char *dm_task_get_uuid(const struct dm_task *dmt);
struct dm_deps *dm_task_get_deps(struct dm_task *dmt);
struct dm_versions *dm_task_get_versions(struct dm_task *dmt);
/*
* These functions return device-mapper names based on the value
* of the mangling mode set during preceding dm_task_run call:
* - unmangled name for DM_STRING_MANGLING_{AUTO, HEX},
* - name without any changes for DM_STRING_MANGLING_NONE.
*
* To get mangled or unmangled form of the name directly, use
* dm_task_get_name_mangled or dm_task_get_name_unmangled function.
*/
const char *dm_task_get_name(const struct dm_task *dmt);
struct dm_names *dm_task_get_names(struct dm_task *dmt);
int dm_task_set_ro(struct dm_task *dmt);
int dm_task_set_newname(struct dm_task *dmt, const char *newname);
int dm_task_set_newuuid(struct dm_task *dmt, const char *newuuid);
int dm_task_set_minor(struct dm_task *dmt, int minor);
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int dm_task_set_major(struct dm_task *dmt, int major);
int dm_task_set_major_minor(struct dm_task *dmt, int major, int minor, int allow_default_major_fallback);
int dm_task_set_uid(struct dm_task *dmt, uid_t uid);
int dm_task_set_gid(struct dm_task *dmt, gid_t gid);
int dm_task_set_mode(struct dm_task *dmt, mode_t mode);
int dm_task_set_cookie(struct dm_task *dmt, uint32_t *cookie, uint16_t flags);
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int dm_task_set_event_nr(struct dm_task *dmt, uint32_t event_nr);
int dm_task_set_geometry(struct dm_task *dmt, const char *cylinders, const char *heads, const char *sectors, const char *start);
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int dm_task_set_message(struct dm_task *dmt, const char *message);
int dm_task_set_sector(struct dm_task *dmt, uint64_t sector);
int dm_task_no_flush(struct dm_task *dmt);
int dm_task_no_open_count(struct dm_task *dmt);
int dm_task_skip_lockfs(struct dm_task *dmt);
int dm_task_query_inactive_table(struct dm_task *dmt);
int dm_task_suppress_identical_reload(struct dm_task *dmt);
int dm_task_secure_data(struct dm_task *dmt);
int dm_task_retry_remove(struct dm_task *dmt);
/*
* Enable checks for common mistakes such as issuing ioctls in an unsafe order.
*/
int dm_task_enable_checks(struct dm_task *dmt);
typedef enum {
DM_ADD_NODE_ON_RESUME, /* add /dev/mapper node with dmsetup resume */
DM_ADD_NODE_ON_CREATE /* add /dev/mapper node with dmsetup create */
} dm_add_node_t;
int dm_task_set_add_node(struct dm_task *dmt, dm_add_node_t add_node);
/*
* Control read_ahead.
*/
#define DM_READ_AHEAD_AUTO UINT32_MAX /* Use kernel default readahead */
#define DM_READ_AHEAD_NONE 0 /* Disable readahead */
#define DM_READ_AHEAD_MINIMUM_FLAG 0x1 /* Value supplied is minimum */
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/*
* Read ahead is set with DM_DEVICE_CREATE with a table or DM_DEVICE_RESUME.
*/
int dm_task_set_read_ahead(struct dm_task *dmt, uint32_t read_ahead,
uint32_t read_ahead_flags);
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uint32_t dm_task_get_read_ahead(const struct dm_task *dmt,
uint32_t *read_ahead);
/*
* Use these to prepare for a create or reload.
*/
int dm_task_add_target(struct dm_task *dmt,
uint64_t start,
uint64_t size, const char *ttype, const char *params);
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/*
* Format major/minor numbers correctly for input to driver.
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*/
#define DM_FORMAT_DEV_BUFSIZE 13 /* Minimum bufsize to handle worst case. */
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int dm_format_dev(char *buf, int bufsize, uint32_t dev_major, uint32_t dev_minor);
/* Use this to retrive target information returned from a STATUS call */
void *dm_get_next_target(struct dm_task *dmt,
void *next, uint64_t *start, uint64_t *length,
char **target_type, char **params);
/* Parse params from STATUS call for thin_pool target */
struct dm_pool;
struct dm_status_thin_pool {
uint64_t transaction_id;
uint64_t used_metadata_blocks;
uint64_t total_metadata_blocks;
uint64_t used_data_blocks;
uint64_t total_data_blocks;
uint64_t held_metadata_root;
};
int dm_get_status_thin_pool(struct dm_pool *mem, const char *params,
struct dm_status_thin_pool **status);
/* Parse params from STATUS call for thin target */
struct dm_status_thin {
uint64_t mapped_sectors;
uint64_t highest_mapped_sector;
};
int dm_get_status_thin(struct dm_pool *mem, const char *params,
struct dm_status_thin **status);
/*
* Call this to actually run the ioctl.
*/
int dm_task_run(struct dm_task *dmt);
/*
* Call this to make or remove the device nodes associated with previously
* issued commands.
*/
void dm_task_update_nodes(void);
/*
* Mangling support
*
* Character whitelist: 0-9, A-Z, a-z, #+-.:=@_
* HEX mangling format: \xNN, NN being the hex value of the character.
* (whitelist and format supported by udev)
*/
typedef enum {
DM_STRING_MANGLING_NONE, /* do not mangle at all */
DM_STRING_MANGLING_AUTO, /* mangle only if not already mangled with hex, error when mixed */
DM_STRING_MANGLING_HEX /* always mangle with hex encoding, no matter what the input is */
} dm_string_mangling_t;
/*
* Set/get mangling mode used for device-mapper names and uuids.
*/
int dm_set_name_mangling_mode(dm_string_mangling_t name_mangling);
dm_string_mangling_t dm_get_name_mangling_mode(void);
/*
* Get mangled/unmangled form of the device-mapper name or uuid
* irrespective of the global setting (set by dm_set_name_mangling_mode).
* The name or uuid returned needs to be freed after use by calling dm_free!
*/
char *dm_task_get_name_mangled(const struct dm_task *dmt);
char *dm_task_get_name_unmangled(const struct dm_task *dmt);
char *dm_task_get_uuid_mangled(const struct dm_task *dmt);
char *dm_task_get_uuid_unmangled(const struct dm_task *dmt);
/*
* Configure the device-mapper directory
*/
int dm_set_dev_dir(const char *dir);
const char *dm_dir(void);
/*
* Configure sysfs directory, /sys by default
*/
int dm_set_sysfs_dir(const char *dir);
const char *dm_sysfs_dir(void);
/*
* Configure default UUID prefix string.
* Conventionally this is a short capitalised prefix indicating the subsystem
* that is managing the devices, e.g. "LVM-" or "MPATH-".
* To support stacks of devices from different subsystems, recursive functions
* stop recursing if they reach a device with a different prefix.
*/
int dm_set_uuid_prefix(const char *uuid_prefix);
const char *dm_uuid_prefix(void);
/*
* Determine whether a major number belongs to device-mapper or not.
*/
int dm_is_dm_major(uint32_t major);
/*
* Get associated device name for given major and minor number by reading
* the sysfs content. If this is a dm device, get associated dm name, the one
* that appears in /dev/mapper. DM names could be resolved this way only if
* kernel used >= 2.6.29, kernel name is found otherwise (e.g. dm-0).
* If prefer_kernel_name is set, the kernel name is always preferred over
* device-mapper name for dm devices no matter what the kernel version is.
* For non-dm devices, we always get associated kernel name, e.g sda, md0 etc.
* Returns 0 on error or if sysfs is not used (or configured incorrectly),
* otherwise returns 1 and the supplied buffer holds the device name.
*/
int dm_device_get_name(uint32_t major, uint32_t minor,
int prefer_kernel_name,
char *buf, size_t buf_size);
/*
* Determine whether a device has any holders (devices
* using this device). If sysfs is not used (or configured
* incorrectly), returns 0.
*/
int dm_device_has_holders(uint32_t major, uint32_t minor);
/*
* Determine whether a device contains mounted filesystem.
* If sysfs is not used (or configured incorrectly), returns 0.
*/
int dm_device_has_mounted_fs(uint32_t major, uint32_t minor);
/*
* Initialise library
*/
void dm_lib_init(void) __attribute__((constructor));
/*
* Release library resources
*/
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void dm_lib_release(void);
void dm_lib_exit(void) __attribute__((destructor));
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/*
* Use NULL for all devices.
*/
int dm_mknodes(const char *name);
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int dm_driver_version(char *version, size_t size);
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/******************************************************
* Functions to build and manipulate trees of devices *
******************************************************/
struct dm_tree;
struct dm_tree_node;
/*
* Initialise an empty dependency tree.
*
* The tree consists of a root node together with one node for each mapped
* device which has child nodes for each device referenced in its table.
*
* Every node in the tree has one or more children and one or more parents.
*
* The root node is the parent/child of every node that doesn't have other
* parents/children.
*/
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struct dm_tree *dm_tree_create(void);
void dm_tree_free(struct dm_tree *tree);
/*
* Add nodes to the tree for a given device and all the devices it uses.
*/
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int dm_tree_add_dev(struct dm_tree *tree, uint32_t major, uint32_t minor);
int dm_tree_add_dev_with_udev_flags(struct dm_tree *tree, uint32_t major,
uint32_t minor, uint16_t udev_flags);
/*
* Add a new node to the tree if it doesn't already exist.
*/
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struct dm_tree_node *dm_tree_add_new_dev(struct dm_tree *tree,
const char *name,
const char *uuid,
uint32_t major, uint32_t minor,
int read_only,
int clear_inactive,
void *context);
struct dm_tree_node *dm_tree_add_new_dev_with_udev_flags(struct dm_tree *tree,
const char *name,
const char *uuid,
uint32_t major,
uint32_t minor,
int read_only,
int clear_inactive,
void *context,
uint16_t udev_flags);
/*
* Search for a node in the tree.
* Set major and minor to 0 or uuid to NULL to get the root node.
*/
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struct dm_tree_node *dm_tree_find_node(struct dm_tree *tree,
uint32_t major,
uint32_t minor);
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struct dm_tree_node *dm_tree_find_node_by_uuid(struct dm_tree *tree,
const char *uuid);
/*
* Use this to walk through all children of a given node.
* Set handle to NULL in first call.
* Returns NULL after the last child.
* Set inverted to use inverted tree.
*/
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struct dm_tree_node *dm_tree_next_child(void **handle,
const struct dm_tree_node *parent,
uint32_t inverted);
/*
* Get properties of a node.
*/
const char *dm_tree_node_get_name(const struct dm_tree_node *node);
const char *dm_tree_node_get_uuid(const struct dm_tree_node *node);
const struct dm_info *dm_tree_node_get_info(const struct dm_tree_node *node);
void *dm_tree_node_get_context(const struct dm_tree_node *node);
int dm_tree_node_size_changed(const struct dm_tree_node *dnode);
/*
* Returns the number of children of the given node (excluding the root node).
* Set inverted for the number of parents.
*/
int dm_tree_node_num_children(const struct dm_tree_node *node, uint32_t inverted);
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/*
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* Deactivate a device plus all dependencies.
* Ignores devices that don't have a uuid starting with uuid_prefix.
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*/
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int dm_tree_deactivate_children(struct dm_tree_node *dnode,
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const char *uuid_prefix,
size_t uuid_prefix_len);
/*
* Preload/create a device plus all dependencies.
* Ignores devices that don't have a uuid starting with uuid_prefix.
*/
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int dm_tree_preload_children(struct dm_tree_node *dnode,
const char *uuid_prefix,
size_t uuid_prefix_len);
/*
* Resume a device plus all dependencies.
* Ignores devices that don't have a uuid starting with uuid_prefix.
*/
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int dm_tree_activate_children(struct dm_tree_node *dnode,
const char *uuid_prefix,
size_t uuid_prefix_len);
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/*
* Suspend a device plus all dependencies.
* Ignores devices that don't have a uuid starting with uuid_prefix.
*/
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int dm_tree_suspend_children(struct dm_tree_node *dnode,
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const char *uuid_prefix,
size_t uuid_prefix_len);
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/*
* Skip the filesystem sync when suspending.
* Does nothing with other functions.
* Use this when no snapshots are involved.
*/
void dm_tree_skip_lockfs(struct dm_tree_node *dnode);
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/*
* Set the 'noflush' flag when suspending devices.
* If the kernel supports it, instead of erroring outstanding I/O that
* cannot be completed, the I/O is queued and resubmitted when the
* device is resumed. This affects multipath devices when all paths
* have failed and queue_if_no_path is set, and mirror devices when
* block_on_error is set and the mirror log has failed.
*/
void dm_tree_use_no_flush_suspend(struct dm_tree_node *dnode);
/*
* Retry removal of each device if not successful.
*/
void dm_tree_retry_remove(struct dm_tree_node *dnode);
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/*
* Is the uuid prefix present in the tree?
* Only returns 0 if every node was checked successfully.
* Returns 1 if the tree walk has to be aborted.
*/
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int dm_tree_children_use_uuid(struct dm_tree_node *dnode,
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const char *uuid_prefix,
size_t uuid_prefix_len);
/*
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* Construct tables for new nodes before activating them.
*/
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int dm_tree_node_add_snapshot_origin_target(struct dm_tree_node *dnode,
uint64_t size,
const char *origin_uuid);
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int dm_tree_node_add_snapshot_target(struct dm_tree_node *node,
uint64_t size,
const char *origin_uuid,
const char *cow_uuid,
int persistent,
uint32_t chunk_size);
int dm_tree_node_add_snapshot_merge_target(struct dm_tree_node *node,
uint64_t size,
const char *origin_uuid,
const char *cow_uuid,
const char *merge_uuid,
uint32_t chunk_size);
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int dm_tree_node_add_error_target(struct dm_tree_node *node,
uint64_t size);
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int dm_tree_node_add_zero_target(struct dm_tree_node *node,
uint64_t size);
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int dm_tree_node_add_linear_target(struct dm_tree_node *node,
uint64_t size);
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int dm_tree_node_add_striped_target(struct dm_tree_node *node,
uint64_t size,
uint32_t stripe_size);
#define DM_CRYPT_IV_DEFAULT UINT64_C(-1) /* iv_offset == seg offset */
/*
* Function accepts one string in cipher specification
* (chainmode and iv should be NULL because included in cipher string)
* or
* separate arguments which will be joined to "cipher-chainmode-iv"
*/
int dm_tree_node_add_crypt_target(struct dm_tree_node *node,
uint64_t size,
const char *cipher,
const char *chainmode,
const char *iv,
uint64_t iv_offset,
const char *key);
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int dm_tree_node_add_mirror_target(struct dm_tree_node *node,
uint64_t size);
/* Mirror log flags */
#define DM_NOSYNC 0x00000001 /* Known already in sync */
#define DM_FORCESYNC 0x00000002 /* Force resync */
#define DM_BLOCK_ON_ERROR 0x00000004 /* On error, suspend I/O */
#define DM_CORELOG 0x00000008 /* In-memory log */
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int dm_tree_node_add_mirror_target_log(struct dm_tree_node *node,
uint32_t region_size,
unsigned clustered,
const char *log_uuid,
unsigned area_count,
uint32_t flags);
int dm_tree_node_add_raid_target(struct dm_tree_node *node,
uint64_t size,
const char *raid_type,
uint32_t region_size,
uint32_t stripe_size,
uint64_t rebuilds,
uint64_t flags);
/*
* Replicator operation mode
* Note: API for Replicator is not yet stable
*/
typedef enum {
DM_REPLICATOR_SYNC, /* Synchronous replication */
DM_REPLICATOR_ASYNC_WARN, /* Warn if async replicator is slow */
DM_REPLICATOR_ASYNC_STALL, /* Stall replicator if not fast enough */
DM_REPLICATOR_ASYNC_DROP, /* Drop sites out of sync */
DM_REPLICATOR_ASYNC_FAIL, /* Fail replicator if slow */
NUM_DM_REPLICATOR_MODES
} dm_replicator_mode_t;
int dm_tree_node_add_replicator_target(struct dm_tree_node *node,
uint64_t size,
const char *rlog_uuid,
const char *rlog_type,
unsigned rsite_index,
dm_replicator_mode_t mode,
uint32_t async_timeout,
uint64_t fall_behind_data,
uint32_t fall_behind_ios);
int dm_tree_node_add_replicator_dev_target(struct dm_tree_node *node,
uint64_t size,
const char *replicator_uuid, /* Replicator control device */
uint64_t rdevice_index,
const char *rdev_uuid, /* Rimage device name/uuid */
unsigned rsite_index,
const char *slog_uuid,
uint32_t slog_flags, /* Mirror log flags */
uint32_t slog_region_size);
/* End of Replicator API */
/*
* FIXME: Defines bellow are based on kernel's dm-thin.c defines
* DATA_DEV_BLOCK_SIZE_MIN_SECTORS (64 * 1024 >> SECTOR_SHIFT)
* DATA_DEV_BLOCK_SIZE_MAX_SECTORS (1024 * 1024 * 1024 >> SECTOR_SHIFT)
*/
#define DM_THIN_MIN_DATA_BLOCK_SIZE (UINT32_C(128))
#define DM_THIN_MAX_DATA_BLOCK_SIZE (UINT32_C(2097152))
int dm_tree_node_add_thin_pool_target(struct dm_tree_node *node,
uint64_t size,
uint64_t transaction_id,
const char *metadata_uuid,
const char *pool_uuid,
uint32_t data_block_size,
uint64_t low_water_mark,
unsigned skip_block_zeroing);
/* Supported messages for thin provision target */
typedef enum {
DM_THIN_MESSAGE_CREATE_SNAP, /* device_id, origin_id */
DM_THIN_MESSAGE_CREATE_THIN, /* device_id */
DM_THIN_MESSAGE_DELETE, /* device_id */
DM_THIN_MESSAGE_SET_TRANSACTION_ID, /* current_id, new_id */
DM_THIN_MESSAGE_RESERVE_METADATA_SNAP, /* target version >= 1.1 */
DM_THIN_MESSAGE_RELEASE_METADATA_SNAP, /* target version >= 1.1 */
} dm_thin_message_t;
int dm_tree_node_add_thin_pool_message(struct dm_tree_node *node,
dm_thin_message_t type,
uint64_t id1, uint64_t id2);
/*
* Set thin pool discard features
* ignore - Disable support for discards
* no_passdown - Don't pass discards down to underlying data device,
* just remove the mapping
* Feature is available since version 1.1 of the thin target.
*/
int dm_tree_node_set_thin_pool_discard(struct dm_tree_node *node,
unsigned ignore,
unsigned no_passdown);
/*
* FIXME: Defines bellow are based on kernel's dm-thin.c defines
* MAX_DEV_ID ((1 << 24) - 1)
*/
#define DM_THIN_MAX_DEVICE_ID (UINT32_C((1 << 24) - 1))
int dm_tree_node_add_thin_target(struct dm_tree_node *node,
uint64_t size,
const char *pool_uuid,
uint32_t device_id);
int dm_tree_node_set_thin_external_origin(struct dm_tree_node *node,
const char *external_uuid);
This patch fixes issues with improper udev flags on sub-LVs. The current code does not always assign proper udev flags to sub-LVs (e.g. mirror images and log LVs). This shows up especially during a splitmirror operation in which an image is split off from a mirror to form a new LV. A mirror with a disk log is actually composed of 4 different LVs: the 2 mirror images, the log, and the top-level LV that "glues" them all together. When a 2-way mirror is split into two linear LVs, two of those LVs must be removed. The segments of the image which is not split off to form the new LV are transferred to the top-level LV. This is done so that the original LV can maintain its major/minor, UUID, and name. The sub-lv from which the segments were transferred gets an error segment as a transitory process before it is eventually removed. (Note that if the error target was not put in place, a resume_lv would result in two LVs pointing to the same segment! If the machine crashes before the eventual removal of the sub-LV, the result would be a residual LV with the same mapping as the original (now linear) LV.) So, the two LVs that need to be removed are now the log device and the sub-LV with the error segment. If udev_flags are not properly set, a resume will cause the error LV to come up and be scanned by udev. This causes I/O errors. Additionally, when udev scans sub-LVs (or former sub-LVs), it can cause races when we are trying to remove those LVs. This is especially bad during failure conditions. When the mirror is suspended, the top-level along with its sub-LVs are suspended. The changes (now 2 linear devices and the yet-to-be-removed log and error LV) are committed. When the resume takes place on the original LV, there are no longer links to the other sub-lvs through the LVM metadata. The links are implicitly handled by querying the kernel for a list of dependencies. This is done in the '_add_dev' function (which is recursively called for each dependency found) - called through the following chain: _add_dev dm_tree_add_dev_with_udev_flags <*** DM / LVM divide ***> _add_dev_to_dtree _add_lv_to_dtree _create_partial_dtree _tree_action dev_manager_activate _lv_activate_lv _lv_resume lv_resume_if_active When udev flags are calculated by '_get_udev_flags', it is done by referencing the 'logical_volume' structure. Those flags are then passed down into 'dm_tree_add_dev_with_udev_flags', which in turn passes them to '_add_dev'. Unfortunately, when '_add_dev' is finding the dependencies, it has no way to calculate their proper udev_flags. This is because it is below the DM/LVM divide - it doesn't have access to the logical_volume structure. In fact, '_add_dev' simply reuses the udev_flags given for the initial device! This virtually guarentees the udev_flags are wrong for all the dependencies unless they are reset by some other mechanism. The current code provides no such mechanism. Even if '_add_new_lv_to_dtree' were called on the sub-devices - which it isn't - entries already in the tree are simply passed over, failing to reset any udev_flags. The solution must retain its implicit nature of discovering dependencies and be able to go back over the dependencies found to properly set the udev_flags. My solution simply calls a new function before leaving '_add_new_lv_to_dtree' that iterates over the dtree nodes to properly reset the udev_flags of any children. It is important that this function occur after the '_add_dev' has done its job of querying the kernel for a list of dependencies. It is this list of children that we use to look up their respective LVs and properly calculate the udev_flags. This solution has worked for single machine, cluster, and cluster w/ exclusive activation.
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void dm_tree_node_set_udev_flags(struct dm_tree_node *node, uint16_t udev_flags);
void dm_tree_node_set_presuspend_node(struct dm_tree_node *node,
struct dm_tree_node *presuspend_node);
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int dm_tree_node_add_target_area(struct dm_tree_node *node,
const char *dev_name,
const char *dlid,
uint64_t offset);
2011-08-19 20:26:02 +04:00
/*
* Only for temporarily-missing raid devices where changes are tracked.
*/
Add the ability to split an image from the mirror and track changes. ~> lvconvert --splitmirrors 1 --trackchanges vg/lv The '--trackchanges' option allows a user the ability to use an image of a RAID1 array for the purposes of temporary read-only access. The image can be merged back into the array at a later time and only the blocks that have changed in the array since the split will be resync'ed. This operation can be thought of as a partial split. The image is never completely extracted from the array, in that the array reserves the position the device occupied and tracks the differences between the array and the split image via a bitmap. The image itself is rendered read-only and the name (<LV>_rimage_*) cannot be changed. The user can complete the split (permanently splitting the image from the array) by re-issuing the 'lvconvert' command without the '--trackchanges' argument and specifying the '--name' argument. ~> lvconvert --splitmirrors 1 --name my_split vg/lv Merging the tracked image back into the array is done with the '--merge' option (included in a follow-on patch). ~> lvconvert --merge vg/lv_rimage_<n> The internal mechanics of this are relatively simple. The 'raid' device- mapper target allows for the specification of an empty slot in an array via '- -'. This is what will be used if a partial activation of an array is ever required. (It would also be possible to use 'error' targets in place of the '- -'.) If a RAID image is found to be both read-only and visible, then it is considered separate from the array and '- -' is used to hold it's position in the array. So, all that needs to be done to temporarily split an image from the array /and/ cause the kernel target's bitmap to track (aka "mark") changes made is to make the specified image visible and read-only. To merge the device back into the array, the image needs to be returned to the read/write state of the top-level LV and made invisible.
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int dm_tree_node_add_null_area(struct dm_tree_node *node, uint64_t offset);
/*
* Set readahead (in sectors) after loading the node.
*/
void dm_tree_node_set_read_ahead(struct dm_tree_node *dnode,
uint32_t read_ahead,
uint32_t read_ahead_flags);
/*
* Set node callback hook before de/activation.
* Callback is called before 'activation' of node for activation tree,
* or 'deactivation' of node for deactivation tree.
*/
typedef enum {
DM_NODE_CALLBACK_PRELOADED, /* Node has preload deps */
DM_NODE_CALLBACK_DEACTIVATED, /* Node is deactivated */
} dm_node_callback_t;
typedef int (*dm_node_callback_fn) (struct dm_tree_node *node,
dm_node_callback_t type, void *cb_data);
void dm_tree_node_set_callback(struct dm_tree_node *node,
dm_node_callback_fn cb, void *cb_data);
void dm_tree_set_cookie(struct dm_tree_node *node, uint32_t cookie);
uint32_t dm_tree_get_cookie(struct dm_tree_node *node);
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/*****************************************************************************
* Library functions
*****************************************************************************/
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/*******************
* Memory management
*******************/
void *dm_malloc_aux(size_t s, const char *file, int line)
__attribute__((malloc)) __attribute__((__warn_unused_result__));
void *dm_malloc_aux_debug(size_t s, const char *file, int line)
__attribute__((__warn_unused_result__));
void *dm_zalloc_aux(size_t s, const char *file, int line)
__attribute__((malloc)) __attribute__((__warn_unused_result__));
void *dm_zalloc_aux_debug(size_t s, const char *file, int line)
__attribute__((__warn_unused_result__));
char *dm_strdup_aux(const char *str, const char *file, int line)
__attribute__((malloc)) __attribute__((__warn_unused_result__));
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void dm_free_aux(void *p);
void *dm_realloc_aux(void *p, unsigned int s, const char *file, int line)
__attribute__((__warn_unused_result__));
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int dm_dump_memory_debug(void);
void dm_bounds_check_debug(void);
#ifdef DEBUG_MEM
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# define dm_malloc(s) dm_malloc_aux_debug((s), __FILE__, __LINE__)
# define dm_zalloc(s) dm_zalloc_aux_debug((s), __FILE__, __LINE__)
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# define dm_strdup(s) dm_strdup_aux((s), __FILE__, __LINE__)
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# define dm_free(p) dm_free_aux(p)
# define dm_realloc(p, s) dm_realloc_aux(p, s, __FILE__, __LINE__)
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# define dm_dump_memory() dm_dump_memory_debug()
# define dm_bounds_check() dm_bounds_check_debug()
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#else
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# define dm_malloc(s) dm_malloc_aux((s), __FILE__, __LINE__)
# define dm_zalloc(s) dm_zalloc_aux((s), __FILE__, __LINE__)
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# define dm_strdup(s) strdup(s)
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# define dm_free(p) free(p)
# define dm_realloc(p, s) realloc(p, s)
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# define dm_dump_memory() {}
# define dm_bounds_check() {}
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#endif
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/*
* The pool allocator is useful when you are going to allocate
* lots of memory, use the memory for a bit, and then free the
* memory in one go. A surprising amount of code has this usage
* profile.
*
* You should think of the pool as an infinite, contiguous chunk
* of memory. The front of this chunk of memory contains
* allocated objects, the second half is free. dm_pool_alloc grabs
* the next 'size' bytes from the free half, in effect moving it
* into the allocated half. This operation is very efficient.
*
* dm_pool_free frees the allocated object *and* all objects
* allocated after it. It is important to note this semantic
* difference from malloc/free. This is also extremely
* efficient, since a single dm_pool_free can dispose of a large
* complex object.
*
* dm_pool_destroy frees all allocated memory.
*
* eg, If you are building a binary tree in your program, and
* know that you are only ever going to insert into your tree,
* and not delete (eg, maintaining a symbol table for a
* compiler). You can create yourself a pool, allocate the nodes
* from it, and when the tree becomes redundant call dm_pool_destroy
* (no nasty iterating through the tree to free nodes).
*
* eg, On the other hand if you wanted to repeatedly insert and
* remove objects into the tree, you would be better off
* allocating the nodes from a free list; you cannot free a
* single arbitrary node with pool.
*/
struct dm_pool;
/* constructor and destructor */
struct dm_pool *dm_pool_create(const char *name, size_t chunk_hint)
__attribute__((__warn_unused_result__));
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void dm_pool_destroy(struct dm_pool *p);
/* simple allocation/free routines */
void *dm_pool_alloc(struct dm_pool *p, size_t s)
__attribute__((__warn_unused_result__));
void *dm_pool_alloc_aligned(struct dm_pool *p, size_t s, unsigned alignment)
__attribute__((__warn_unused_result__));
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void dm_pool_empty(struct dm_pool *p);
void dm_pool_free(struct dm_pool *p, void *ptr);
/*
* To aid debugging, a pool can be locked. Any modifications made
* to the content of the pool while it is locked can be detected.
* Default compilation is using a crc checksum to notice modifications.
* The pool locking is using the mprotect with the compilation flag
* DEBUG_ENFORCE_POOL_LOCKING to enforce the memory protection.
*/
/* query pool lock status */
int dm_pool_locked(struct dm_pool *p);
/* mark pool as locked */
int dm_pool_lock(struct dm_pool *p, int crc)
__attribute__((__warn_unused_result__));
/* mark pool as unlocked */
int dm_pool_unlock(struct dm_pool *p, int crc)
__attribute__((__warn_unused_result__));
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/*
* Object building routines:
*
* These allow you to 'grow' an object, useful for
* building strings, or filling in dynamic
* arrays.
*
* It's probably best explained with an example:
*
* char *build_string(struct dm_pool *mem)
* {
* int i;
* char buffer[16];
*
* if (!dm_pool_begin_object(mem, 128))
* return NULL;
*
* for (i = 0; i < 50; i++) {
* snprintf(buffer, sizeof(buffer), "%d, ", i);
* if (!dm_pool_grow_object(mem, buffer, 0))
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* goto bad;
* }
*
* // add null
* if (!dm_pool_grow_object(mem, "\0", 1))
* goto bad;
*
* return dm_pool_end_object(mem);
*
* bad:
*
* dm_pool_abandon_object(mem);
* return NULL;
*}
*
* So start an object by calling dm_pool_begin_object
* with a guess at the final object size - if in
* doubt make the guess too small.
*
* Then append chunks of data to your object with
* dm_pool_grow_object. Finally get your object with
* a call to dm_pool_end_object.
*
* Setting delta to 0 means it will use strlen(extra).
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*/
int dm_pool_begin_object(struct dm_pool *p, size_t hint);
int dm_pool_grow_object(struct dm_pool *p, const void *extra, size_t delta);
void *dm_pool_end_object(struct dm_pool *p);
void dm_pool_abandon_object(struct dm_pool *p);
/* utilities */
char *dm_pool_strdup(struct dm_pool *p, const char *str)
__attribute__((__warn_unused_result__));
char *dm_pool_strndup(struct dm_pool *p, const char *str, size_t n)
__attribute__((__warn_unused_result__));
void *dm_pool_zalloc(struct dm_pool *p, size_t s)
__attribute__((__warn_unused_result__));
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/******************
* bitset functions
******************/
typedef uint32_t *dm_bitset_t;
dm_bitset_t dm_bitset_create(struct dm_pool *mem, unsigned num_bits);
void dm_bitset_destroy(dm_bitset_t bs);
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int dm_bitset_equal(dm_bitset_t in1, dm_bitset_t in2);
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void dm_bit_and(dm_bitset_t out, dm_bitset_t in1, dm_bitset_t in2);
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void dm_bit_union(dm_bitset_t out, dm_bitset_t in1, dm_bitset_t in2);
int dm_bit_get_first(dm_bitset_t bs);
int dm_bit_get_next(dm_bitset_t bs, int last_bit);
#define DM_BITS_PER_INT (sizeof(int) * CHAR_BIT)
#define dm_bit(bs, i) \
((bs)[((i) / DM_BITS_PER_INT) + 1] & (0x1 << ((i) & (DM_BITS_PER_INT - 1))))
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#define dm_bit_set(bs, i) \
((bs)[((i) / DM_BITS_PER_INT) + 1] |= (0x1 << ((i) & (DM_BITS_PER_INT - 1))))
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#define dm_bit_clear(bs, i) \
((bs)[((i) / DM_BITS_PER_INT) + 1] &= ~(0x1 << ((i) & (DM_BITS_PER_INT - 1))))
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#define dm_bit_set_all(bs) \
memset((bs) + 1, -1, ((*(bs) / DM_BITS_PER_INT) + 1) * sizeof(int))
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#define dm_bit_clear_all(bs) \
memset((bs) + 1, 0, ((*(bs) / DM_BITS_PER_INT) + 1) * sizeof(int))
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#define dm_bit_copy(bs1, bs2) \
memcpy((bs1) + 1, (bs2) + 1, ((*(bs1) / DM_BITS_PER_INT) + 1) * sizeof(int))
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/* Returns number of set bits */
static inline unsigned hweight32(uint32_t i)
{
unsigned r = (i & 0x55555555) + ((i >> 1) & 0x55555555);
r = (r & 0x33333333) + ((r >> 2) & 0x33333333);
r = (r & 0x0F0F0F0F) + ((r >> 4) & 0x0F0F0F0F);
r = (r & 0x00FF00FF) + ((r >> 8) & 0x00FF00FF);
return (r & 0x0000FFFF) + ((r >> 16) & 0x0000FFFF);
}
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/****************
* hash functions
****************/
struct dm_hash_table;
struct dm_hash_node;
typedef void (*dm_hash_iterate_fn) (void *data);
struct dm_hash_table *dm_hash_create(unsigned size_hint)
__attribute__((__warn_unused_result__));
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void dm_hash_destroy(struct dm_hash_table *t);
void dm_hash_wipe(struct dm_hash_table *t);
void *dm_hash_lookup(struct dm_hash_table *t, const char *key);
int dm_hash_insert(struct dm_hash_table *t, const char *key, void *data);
void dm_hash_remove(struct dm_hash_table *t, const char *key);
void *dm_hash_lookup_binary(struct dm_hash_table *t, const void *key, uint32_t len);
int dm_hash_insert_binary(struct dm_hash_table *t, const void *key, uint32_t len,
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void *data);
void dm_hash_remove_binary(struct dm_hash_table *t, const void *key, uint32_t len);
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unsigned dm_hash_get_num_entries(struct dm_hash_table *t);
void dm_hash_iter(struct dm_hash_table *t, dm_hash_iterate_fn f);
char *dm_hash_get_key(struct dm_hash_table *t, struct dm_hash_node *n);
void *dm_hash_get_data(struct dm_hash_table *t, struct dm_hash_node *n);
struct dm_hash_node *dm_hash_get_first(struct dm_hash_table *t);
struct dm_hash_node *dm_hash_get_next(struct dm_hash_table *t, struct dm_hash_node *n);
#define dm_hash_iterate(v, h) \
for (v = dm_hash_get_first((h)); v; \
v = dm_hash_get_next((h), v))
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/****************
* list functions
****************/
/*
* A list consists of a list head plus elements.
* Each element has 'next' and 'previous' pointers.
* The list head's pointers point to the first and the last element.
*/
struct dm_list {
struct dm_list *n, *p;
};
/*
* Initialise a list before use.
* The list head's next and previous pointers point back to itself.
*/
#define DM_LIST_INIT(name) struct dm_list name = { &(name), &(name) }
void dm_list_init(struct dm_list *head);
/*
* Insert an element before 'head'.
* If 'head' is the list head, this adds an element to the end of the list.
*/
void dm_list_add(struct dm_list *head, struct dm_list *elem);
/*
* Insert an element after 'head'.
* If 'head' is the list head, this adds an element to the front of the list.
*/
void dm_list_add_h(struct dm_list *head, struct dm_list *elem);
/*
* Delete an element from its list.
* Note that this doesn't change the element itself - it may still be safe
* to follow its pointers.
*/
void dm_list_del(struct dm_list *elem);
/*
* Remove an element from existing list and insert before 'head'.
*/
void dm_list_move(struct dm_list *head, struct dm_list *elem);
/*
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* Join 'head1' to the end of 'head'.
*/
void dm_list_splice(struct dm_list *head, struct dm_list *head1);
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/*
* Is the list empty?
*/
int dm_list_empty(const struct dm_list *head);
/*
* Is this the first element of the list?
*/
int dm_list_start(const struct dm_list *head, const struct dm_list *elem);
/*
* Is this the last element of the list?
*/
int dm_list_end(const struct dm_list *head, const struct dm_list *elem);
/*
* Return first element of the list or NULL if empty
*/
struct dm_list *dm_list_first(const struct dm_list *head);
/*
* Return last element of the list or NULL if empty
*/
struct dm_list *dm_list_last(const struct dm_list *head);
/*
* Return the previous element of the list, or NULL if we've reached the start.
*/
struct dm_list *dm_list_prev(const struct dm_list *head, const struct dm_list *elem);
/*
* Return the next element of the list, or NULL if we've reached the end.
*/
struct dm_list *dm_list_next(const struct dm_list *head, const struct dm_list *elem);
/*
* Given the address v of an instance of 'struct dm_list' called 'head'
* contained in a structure of type t, return the containing structure.
*/
#define dm_list_struct_base(v, t, head) \
((t *)((const char *)(v) - (const char *)&((t *) 0)->head))
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/*
* Given the address v of an instance of 'struct dm_list list' contained in
* a structure of type t, return the containing structure.
*/
#define dm_list_item(v, t) dm_list_struct_base((v), t, list)
/*
* Given the address v of one known element e in a known structure of type t,
* return another element f.
*/
#define dm_struct_field(v, t, e, f) \
(((t *)((uintptr_t)(v) - (uintptr_t)&((t *) 0)->e))->f)
/*
* Given the address v of a known element e in a known structure of type t,
* return the list head 'list'
*/
#define dm_list_head(v, t, e) dm_struct_field(v, t, e, list)
/*
* Set v to each element of a list in turn.
*/
#define dm_list_iterate(v, head) \
for (v = (head)->n; v != head; v = v->n)
/*
* Set v to each element in a list in turn, starting from the element
* in front of 'start'.
* You can use this to 'unwind' a list_iterate and back out actions on
* already-processed elements.
* If 'start' is 'head' it walks the list backwards.
*/
#define dm_list_uniterate(v, head, start) \
for (v = (start)->p; v != head; v = v->p)
/*
* A safe way to walk a list and delete and free some elements along
* the way.
* t must be defined as a temporary variable of the same type as v.
*/
#define dm_list_iterate_safe(v, t, head) \
for (v = (head)->n, t = v->n; v != head; v = t, t = v->n)
/*
* Walk a list, setting 'v' in turn to the containing structure of each item.
* The containing structure should be the same type as 'v'.
* The 'struct dm_list' variable within the containing structure is 'field'.
*/
#define dm_list_iterate_items_gen(v, head, field) \
for (v = dm_list_struct_base((head)->n, __typeof__(*v), field); \
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&v->field != (head); \
v = dm_list_struct_base(v->field.n, __typeof__(*v), field))
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/*
* Walk a list, setting 'v' in turn to the containing structure of each item.
* The containing structure should be the same type as 'v'.
* The list should be 'struct dm_list list' within the containing structure.
*/
#define dm_list_iterate_items(v, head) dm_list_iterate_items_gen(v, (head), list)
/*
* Walk a list, setting 'v' in turn to the containing structure of each item.
* The containing structure should be the same type as 'v'.
* The 'struct dm_list' variable within the containing structure is 'field'.
* t must be defined as a temporary variable of the same type as v.
*/
#define dm_list_iterate_items_gen_safe(v, t, head, field) \
for (v = dm_list_struct_base((head)->n, __typeof__(*v), field), \
t = dm_list_struct_base(v->field.n, __typeof__(*v), field); \
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&v->field != (head); \
v = t, t = dm_list_struct_base(v->field.n, __typeof__(*v), field))
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/*
* Walk a list, setting 'v' in turn to the containing structure of each item.
* The containing structure should be the same type as 'v'.
* The list should be 'struct dm_list list' within the containing structure.
* t must be defined as a temporary variable of the same type as v.
*/
#define dm_list_iterate_items_safe(v, t, head) \
dm_list_iterate_items_gen_safe(v, t, (head), list)
/*
* Walk a list backwards, setting 'v' in turn to the containing structure
* of each item.
* The containing structure should be the same type as 'v'.
* The 'struct dm_list' variable within the containing structure is 'field'.
*/
#define dm_list_iterate_back_items_gen(v, head, field) \
for (v = dm_list_struct_base((head)->p, __typeof__(*v), field); \
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&v->field != (head); \
v = dm_list_struct_base(v->field.p, __typeof__(*v), field))
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/*
* Walk a list backwards, setting 'v' in turn to the containing structure
* of each item.
* The containing structure should be the same type as 'v'.
* The list should be 'struct dm_list list' within the containing structure.
*/
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#define dm_list_iterate_back_items(v, head) dm_list_iterate_back_items_gen(v, (head), list)
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/*
* Return the number of elements in a list by walking it.
*/
unsigned int dm_list_size(const struct dm_list *head);
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/*********
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* selinux
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*********/
/*
* Obtain SELinux security context assigned for the path and set this
* context for creating a new file system object. This security context
* is global and it is used until reset to default policy behaviour
* by calling 'dm_prepare_selinux_context(NULL, 0)'.
*/
int dm_prepare_selinux_context(const char *path, mode_t mode);
/*
* Set SELinux context for existing file system object.
*/
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int dm_set_selinux_context(const char *path, mode_t mode);
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/*********************
* string manipulation
*********************/
/*
* Break up the name of a mapped device into its constituent
* Volume Group, Logical Volume and Layer (if present).
* If mem is supplied, the result is allocated from the mempool.
* Otherwise the strings are changed in situ.
*/
int dm_split_lvm_name(struct dm_pool *mem, const char *dmname,
char **vgname, char **lvname, char **layer);
/*
* Destructively split buffer into NULL-separated words in argv.
* Returns number of words.
*/
int dm_split_words(char *buffer, unsigned max,
unsigned ignore_comments, /* Not implemented */
char **argv);
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/*
* Returns -1 if buffer too small
*/
int dm_snprintf(char *buf, size_t bufsize, const char *format, ...)
__attribute__ ((format(printf, 3, 4)));
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/*
* Returns pointer to the last component of the path.
*/
const char *dm_basename(const char *path);
/*
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* Returns number of occurrences of 'c' in 'str' of length 'size'.
*/
unsigned dm_count_chars(const char *str, size_t len, const int c);
/*
* Length of string after escaping double quotes and backslashes.
*/
size_t dm_escaped_len(const char *str);
/*
* <vg>-<lv>-<layer> or if !layer just <vg>-<lv>.
*/
char *dm_build_dm_name(struct dm_pool *mem, const char *vgname,
const char *lvname, const char *layer);
char *dm_build_dm_uuid(struct dm_pool *mem, const char *prefix, const char *lvid, const char *layer);
/*
* Copies a string, quoting double quotes with backslashes.
*/
char *dm_escape_double_quotes(char *out, const char *src);
/*
* Undo quoting in situ.
*/
void dm_unescape_double_quotes(char *src);
/*
* Unescape colons and "at" signs in situ and save the substrings
* starting at the position of the first unescaped colon and the
* first unescaped "at" sign. This is normally used to unescape
* device names used as PVs.
*/
void dm_unescape_colons_and_at_signs(char *src,
char **substr_first_unquoted_colon,
char **substr_first_unquoted_at_sign);
/*
* Replacement for strncpy() function.
*
* Copies no more than n bytes from string pointed by src to the buffer
* pointed by dest and ensure string is finished with '\0'.
* Returns 0 if the whole string does not fit.
*/
int dm_strncpy(char *dest, const char *src, size_t n);
/**************************
* file/stream manipulation
**************************/
/*
* Create a directory (with parent directories if necessary).
* Returns 1 on success, 0 on failure.
*/
int dm_create_dir(const char *dir);
int dm_is_empty_dir(const char *dir);
/*
* Close a stream, with nicer error checking than fclose's.
* Derived from gnulib's close-stream.c.
*
* Close "stream". Return 0 if successful, and EOF (setting errno)
* otherwise. Upon failure, set errno to 0 if the error number
* cannot be determined. Useful mainly for writable streams.
*/
int dm_fclose(FILE *stream);
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/*
* Returns size of a buffer which is allocated with dm_malloc.
* Pointer to the buffer is stored in *buf.
* Returns -1 on failure leaving buf undefined.
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*/
int dm_asprintf(char **buf, const char *format, ...)
__attribute__ ((format(printf, 2, 3)));
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int dm_vasprintf(char **buf, const char *format, va_list ap);
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/*
* create lockfile (pidfile) - create and lock a lock file
* @lockfile: location of lock file
*
* Returns: 1 on success, 0 otherwise, errno is handled internally
*/
int dm_create_lockfile(const char* lockfile);
/*
* Query whether a daemon is running based on its lockfile
*
* Returns: 1 if running, 0 if not
*/
int dm_daemon_is_running(const char* lockfile);
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/*********************
* regular expressions
*********************/
struct dm_regex;
/*
* Initialise an array of num patterns for matching.
* Uses memory from mem.
*/
struct dm_regex *dm_regex_create(struct dm_pool *mem, const char * const *patterns,
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unsigned num_patterns);
/*
* Match string s against the patterns.
* Returns the index of the highest pattern in the array that matches,
* or -1 if none match.
*/
int dm_regex_match(struct dm_regex *regex, const char *s);
/*
* This is useful for regression testing only. The idea is if two
* fingerprints are different, then the two dfas are certainly not
* isomorphic. If two fingerprints _are_ the same then it's very likely
* that the dfas are isomorphic.
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*
* This function must be called before any matching is done.
*/
uint32_t dm_regex_fingerprint(struct dm_regex *regex);
/*********************
* reporting functions
*********************/
struct dm_report_object_type {
uint32_t id; /* Powers of 2 */
const char *desc;
const char *prefix; /* field id string prefix (optional) */
void *(*data_fn)(void *object); /* callback from report_object() */
};
struct dm_report_field;
/*
* dm_report_field_type flags
*/
#define DM_REPORT_FIELD_MASK 0x000000FF
#define DM_REPORT_FIELD_ALIGN_MASK 0x0000000F
#define DM_REPORT_FIELD_ALIGN_LEFT 0x00000001
#define DM_REPORT_FIELD_ALIGN_RIGHT 0x00000002
#define DM_REPORT_FIELD_TYPE_MASK 0x000000F0
#define DM_REPORT_FIELD_TYPE_STRING 0x00000010
#define DM_REPORT_FIELD_TYPE_NUMBER 0x00000020
#define DM_REPORT_FIELD_TYPE_ID_LEN 32
#define DM_REPORT_FIELD_TYPE_HEADING_LEN 32
struct dm_report;
struct dm_report_field_type {
uint32_t type; /* object type id */
uint32_t flags; /* DM_REPORT_FIELD_* */
uint32_t offset; /* byte offset in the object */
int32_t width; /* default width */
/* string used to specify the field */
const char id[DM_REPORT_FIELD_TYPE_ID_LEN];
/* string printed in header */
const char heading[DM_REPORT_FIELD_TYPE_HEADING_LEN];
int (*report_fn)(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field, const void *data,
void *private_data);
const char *desc; /* description of the field */
};
/*
* dm_report_init output_flags
*/
#define DM_REPORT_OUTPUT_MASK 0x000000FF
#define DM_REPORT_OUTPUT_ALIGNED 0x00000001
#define DM_REPORT_OUTPUT_BUFFERED 0x00000002
#define DM_REPORT_OUTPUT_HEADINGS 0x00000004
#define DM_REPORT_OUTPUT_FIELD_NAME_PREFIX 0x00000008
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#define DM_REPORT_OUTPUT_FIELD_UNQUOTED 0x00000010
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#define DM_REPORT_OUTPUT_COLUMNS_AS_ROWS 0x00000020
struct dm_report *dm_report_init(uint32_t *report_types,
const struct dm_report_object_type *types,
const struct dm_report_field_type *fields,
const char *output_fields,
const char *output_separator,
uint32_t output_flags,
const char *sort_keys,
void *private_data);
int dm_report_object(struct dm_report *rh, void *object);
int dm_report_output(struct dm_report *rh);
void dm_report_free(struct dm_report *rh);
/*
* Prefix added to each field name with DM_REPORT_OUTPUT_FIELD_NAME_PREFIX
*/
int dm_report_set_output_field_name_prefix(struct dm_report *rh,
const char *report_prefix);
/*
* Report functions are provided for simple data types.
* They take care of allocating copies of the data.
*/
int dm_report_field_string(struct dm_report *rh, struct dm_report_field *field,
const char *const *data);
int dm_report_field_int32(struct dm_report *rh, struct dm_report_field *field,
const int32_t *data);
int dm_report_field_uint32(struct dm_report *rh, struct dm_report_field *field,
const uint32_t *data);
int dm_report_field_int(struct dm_report *rh, struct dm_report_field *field,
const int *data);
int dm_report_field_uint64(struct dm_report *rh, struct dm_report_field *field,
const uint64_t *data);
/*
* For custom fields, allocate the data in 'mem' and use
* dm_report_field_set_value().
* 'sortvalue' may be NULL if it matches 'value'
*/
void dm_report_field_set_value(struct dm_report_field *field, const void *value,
const void *sortvalue);
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/*************************
* config file parse/print
*************************/
typedef enum {
DM_CFG_INT,
DM_CFG_FLOAT,
DM_CFG_STRING,
DM_CFG_EMPTY_ARRAY
} dm_config_value_type_t;
struct dm_config_value {
dm_config_value_type_t type;
union {
int64_t i;
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float f;
double d; /* Unused. */
const char *str;
} v;
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struct dm_config_value *next; /* For arrays */
};
struct dm_config_node {
const char *key;
struct dm_config_node *parent, *sib, *child;
struct dm_config_value *v;
};
struct dm_config_tree {
struct dm_config_node *root;
struct dm_config_tree *cascade;
struct dm_pool *mem;
void *custom;
};
struct dm_config_tree *dm_config_create(void);
struct dm_config_tree *dm_config_from_string(const char *config_settings);
int dm_config_parse(struct dm_config_tree *cft, const char *start, const char *end);
void *dm_config_get_custom(struct dm_config_tree *cft);
void dm_config_set_custom(struct dm_config_tree *cft, void *custom);
/*
* When searching, first_cft is checked before second_cft.
*/
struct dm_config_tree *dm_config_insert_cascaded_tree(struct dm_config_tree *first_cft, struct dm_config_tree *second_cft);
/*
* If there's a cascaded dm_config_tree, remove the top layer
* and return the layer below. Otherwise return NULL.
*/
struct dm_config_tree *dm_config_remove_cascaded_tree(struct dm_config_tree *cft);
void dm_config_destroy(struct dm_config_tree *cft);
typedef int (*dm_putline_fn)(const char *line, void *baton);
/* Write the node and any subsequent siblings it has. */
int dm_config_write_node(const struct dm_config_node *cn, dm_putline_fn putline, void *baton);
/* Write given node only without subsequent siblings. */
int dm_config_write_one_node(const struct dm_config_node *cn, dm_putline_fn putline, void *baton);
struct dm_config_node *dm_config_find_node(const struct dm_config_node *cn, const char *path);
int dm_config_has_node(const struct dm_config_node *cn, const char *path);
const char *dm_config_find_str(const struct dm_config_node *cn, const char *path, const char *fail);
const char *dm_config_find_str_allow_empty(const struct dm_config_node *cn, const char *path, const char *fail);
int dm_config_find_int(const struct dm_config_node *cn, const char *path, int fail);
int64_t dm_config_find_int64(const struct dm_config_node *cn, const char *path, int64_t fail);
float dm_config_find_float(const struct dm_config_node *cn, const char *path, float fail);
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const struct dm_config_node *dm_config_tree_find_node(const struct dm_config_tree *cft, const char *path);
const char *dm_config_tree_find_str(const struct dm_config_tree *cft, const char *path, const char *fail);
const char *dm_config_tree_find_str_allow_empty(const struct dm_config_tree *cft, const char *path, const char *fail);
int dm_config_tree_find_int(const struct dm_config_tree *cft, const char *path, int fail);
int64_t dm_config_tree_find_int64(const struct dm_config_tree *cft, const char *path, int64_t fail);
float dm_config_tree_find_float(const struct dm_config_tree *cft, const char *path, float fail);
int dm_config_tree_find_bool(const struct dm_config_tree *cft, const char *path, int fail);
/*
* Understands (0, ~0), (y, n), (yes, no), (on,
* off), (true, false).
*/
int dm_config_find_bool(const struct dm_config_node *cn, const char *path, int fail);
int dm_config_get_uint32(const struct dm_config_node *cn, const char *path, uint32_t *result);
int dm_config_get_uint64(const struct dm_config_node *cn, const char *path, uint64_t *result);
int dm_config_get_str(const struct dm_config_node *cn, const char *path, const char **result);
int dm_config_get_list(const struct dm_config_node *cn, const char *path, const struct dm_config_value **result);
int dm_config_get_section(const struct dm_config_node *cn, const char *path, const struct dm_config_node **result);
unsigned dm_config_maybe_section(const char *str, unsigned len);
const char *dm_config_parent_name(const struct dm_config_node *n);
struct dm_config_node *dm_config_clone_node_with_mem(struct dm_pool *mem, const struct dm_config_node *node, int siblings);
struct dm_config_node *dm_config_create_node(struct dm_config_tree *cft, const char *key);
struct dm_config_value *dm_config_create_value(struct dm_config_tree *cft);
struct dm_config_node *dm_config_clone_node(struct dm_config_tree *cft, const struct dm_config_node *cn, int siblings);
struct dm_pool *dm_config_memory(struct dm_config_tree *cft);
/* Udev device directory. */
#define DM_UDEV_DEV_DIR "/dev/"
/* Cookie prefixes.
*
* The cookie value consists of a prefix (16 bits) and a base (16 bits).
* We can use the prefix to store the flags. These flags are sent to
* kernel within given dm task. When returned back to userspace in
* DM_COOKIE udev environment variable, we can control several aspects
* of udev rules we use by decoding the cookie prefix. When doing the
* notification, we replace the cookie prefix with DM_COOKIE_MAGIC,
* so we notify the right semaphore.
*
* It is still possible to use cookies for passing the flags to udev
* rules even when udev_sync is disabled. The base part of the cookie
* will be zero (there's no notification semaphore) and prefix will be
* set then. However, having udev_sync enabled is highly recommended.
*/
#define DM_COOKIE_MAGIC 0x0D4D
#define DM_UDEV_FLAGS_MASK 0xFFFF0000
#define DM_UDEV_FLAGS_SHIFT 16
/*
* DM_UDEV_DISABLE_DM_RULES_FLAG is set in case we need to disable
* basic device-mapper udev rules that create symlinks in /dev/<DM_DIR>
* directory. However, we can't reliably prevent creating default
* nodes by udev (commonly /dev/dm-X, where X is a number).
*/
#define DM_UDEV_DISABLE_DM_RULES_FLAG 0x0001
/*
* DM_UDEV_DISABLE_SUBSYTEM_RULES_FLAG is set in case we need to disable
* subsystem udev rules, but still we need the general DM udev rules to
* be applied (to create the nodes and symlinks under /dev and /dev/disk).
*/
#define DM_UDEV_DISABLE_SUBSYSTEM_RULES_FLAG 0x0002
/*
* DM_UDEV_DISABLE_DISK_RULES_FLAG is set in case we need to disable
* general DM rules that set symlinks in /dev/disk directory.
*/
#define DM_UDEV_DISABLE_DISK_RULES_FLAG 0x0004
/*
* DM_UDEV_DISABLE_OTHER_RULES_FLAG is set in case we need to disable
* all the other rules that are not general device-mapper nor subsystem
* related (the rules belong to other software or packages). All foreign
* rules should check this flag directly and they should ignore further
* rule processing for such event.
*/
#define DM_UDEV_DISABLE_OTHER_RULES_FLAG 0x0008
/*
* DM_UDEV_LOW_PRIORITY_FLAG is set in case we need to instruct the
* udev rules to give low priority to the device that is currently
* processed. For example, this provides a way to select which symlinks
* could be overwritten by high priority ones if their names are equal.
* Common situation is a name based on FS UUID while using origin and
* snapshot devices.
*/
#define DM_UDEV_LOW_PRIORITY_FLAG 0x0010
/*
* DM_UDEV_DISABLE_LIBRARY_FALLBACK is set in case we need to disable
* libdevmapper's node management. We will rely on udev completely
* and there will be no fallback action provided by libdevmapper if
* udev does something improperly.
*/
#define DM_UDEV_DISABLE_LIBRARY_FALLBACK 0x0020
/*
* DM_UDEV_PRIMARY_SOURCE_FLAG is automatically appended by
* libdevmapper for all ioctls generating udev uevents. Once used in
* udev rules, we know if this is a real "primary sourced" event or not.
* We need to distinguish real events originated in libdevmapper from
* any spurious events to gather all missing information (e.g. events
* generated as a result of "udevadm trigger" command or as a result
* of the "watch" udev rule).
*/
#define DM_UDEV_PRIMARY_SOURCE_FLAG 0x0040
int dm_cookie_supported(void);
/*
* Udev synchronisation functions.
*/
void dm_udev_set_sync_support(int sync_with_udev);
int dm_udev_get_sync_support(void);
void dm_udev_set_checking(int checking);
int dm_udev_get_checking(void);
/*
* Default value to get new auto generated cookie created
*/
#define DM_COOKIE_AUTO_CREATE 0
int dm_udev_create_cookie(uint32_t *cookie);
int dm_udev_complete(uint32_t cookie);
int dm_udev_wait(uint32_t cookie);
#define DM_DEV_DIR_UMASK 0022
#define DM_CONTROL_NODE_UMASK 0177
#ifdef __cplusplus
}
#endif
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#endif /* LIB_DEVICE_MAPPER_H */