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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) 2004-2017 Red Hat, Inc. All rights reserved.
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* Copyright (C) 2006 Rackable Systems 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,
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 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
/* Macros to make string defines */
#define DM_TO_STRING_EXP(A) #A
#define DM_TO_STRING(A) DM_TO_STRING_EXP(A)
#define DM_ARRAY_SIZE(a) (sizeof(a) / sizeof((a)[0]))
#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.
* Error messages may have a non-zero errno.
* Debug messages may have a non-zero class.
* Aborts on internal error when env DM_ABORT_ON_INTERNAL_ERRORS is 1
*/
typedef void (*dm_log_with_errno_fn) (int level, const char *file, int line,
int dm_errno_or_class, 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,
DM_DEVICE_ARM_POLL,
DM_GET_TARGET_VERSION
};
/*
* You will need to build a struct dm_task for
* each ioctl command you want to execute.
*/
struct dm_pool;
struct dm_task;
struct dm_timestamp;
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;
int deferred_remove;
int internal_suspend;
};
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:
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* - unmangled UUID for DM_STRING_MANGLING_{AUTO, HEX},
* - UUID without any changes for DM_STRING_MANGLING_NONE.
*
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* To get mangled or unmangled form of the UUID 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);
const char *dm_task_get_message_response(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);
/* See also description for DM_UDEV_DISABLE_LIBRARY_FALLBACK flag! */
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);
int dm_task_deferred_remove(struct dm_task *dmt);
/*
* Record timestamp immediately after the ioctl returns.
*/
int dm_task_set_record_timestamp(struct dm_task *dmt);
struct dm_timestamp *dm_task_get_ioctl_timestamp(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);
/*
* Following dm_get_status_* functions will allocate approriate status structure
* from passed mempool together with the necessary character arrays.
* Destroying the mempool will release all asociated allocation.
*/
/* Parse params from STATUS call for mirror target */
typedef enum {
DM_STATUS_MIRROR_ALIVE = 'A',/* No failures */
DM_STATUS_MIRROR_FLUSH_FAILED = 'F',/* Mirror out-of-sync */
DM_STATUS_MIRROR_WRITE_FAILED = 'D',/* Mirror out-of-sync */
DM_STATUS_MIRROR_SYNC_FAILED = 'S',/* Mirror out-of-sync */
DM_STATUS_MIRROR_READ_FAILED = 'R',/* Mirror data unaffected */
DM_STATUS_MIRROR_UNCLASSIFIED = 'U' /* Bug */
} dm_status_mirror_health_t;
struct dm_status_mirror {
uint64_t total_regions;
uint64_t insync_regions;
uint32_t dev_count; /* # of devs[] elements (<= 8) */
struct {
dm_status_mirror_health_t health;
uint32_t major;
uint32_t minor;
} *devs; /* array with individual legs */
const char *log_type; /* core, disk,.... */
uint32_t log_count; /* # of logs[] elements */
struct {
dm_status_mirror_health_t health;
uint32_t major;
uint32_t minor;
} *logs; /* array with individual logs */
};
int dm_get_status_mirror(struct dm_pool *mem, const char *params,
struct dm_status_mirror **status);
/* Parse params from STATUS call for raid target */
struct dm_status_raid {
uint64_t reserved;
uint64_t total_regions; /* sectors */
uint64_t insync_regions; /* sectors */
uint64_t mismatch_count;
uint32_t dev_count;
char *raid_type;
/* A - alive, a - alive not in-sync, D - dead/failed */
char *dev_health;
/* idle, frozen, resync, recover, check, repair */
char *sync_action;
lvconvert: add infrastructure for RaidLV reshaping support In order to support striped raid5/6/10 LV reshaping (change of LV type, stripesize or number of legs), this patch introduces infrastructure prerequisites to be used by raid_manip.c extensions in followup patches. This base is needed for allocation of out-of-place reshape space required by the MD raid personalities to avoid writing over data in-place when reading off the current RAID layout or number of legs and writing out the new layout or to a different number of legs (i.e. restripe) Changes: - add members reshape_len to 'struct lv_segment' to store out-of-place reshape length per component rimage - add member data_copies to struct lv_segment to support more than 2 raid10 data copies - make alloc_lv_segment() aware of both reshape_len and data_copies - adjust all alloc_lv_segment() callers to the new API - add functions to retrieve the current data offset (needed for out-of-place reshaping space allocation) and the devices count from the kernel - make libdm deptree code aware of reshape_len - add LV flags for disk add/remove reshaping - support import/export of the new 'struct lv_segment' members - enhance lv_extend/_lv_reduce to cope with reshape_len - add seg_is_*/segtype_is_* macros related to reshaping - add target version check for reshaping - grow rebuilds/writemostly bitmaps to 246 bit to support kernel maximal - enhance libdm deptree code to support data_offset (out-of-place reshaping) and delta_disk (legs add/remove reshaping) target arguments Related: rhbz834579 Related: rhbz1191935 Related: rhbz1191978
2017-02-24 02:50:00 +03:00
uint64_t data_offset; /* RAID out-of-place reshaping */
};
int dm_get_status_raid(struct dm_pool *mem, const char *params,
struct dm_status_raid **status);
/* Parse params from STATUS call for cache target */
struct dm_status_cache {
uint64_t version; /* zero for now */
uint32_t metadata_block_size; /* in 512B sectors */
uint32_t block_size; /* AKA 'chunk_size' */
uint64_t metadata_used_blocks;
uint64_t metadata_total_blocks;
uint64_t used_blocks;
uint64_t dirty_blocks;
uint64_t total_blocks;
uint64_t read_hits;
uint64_t read_misses;
uint64_t write_hits;
uint64_t write_misses;
uint64_t demotions;
uint64_t promotions;
uint64_t feature_flags; /* DM_CACHE_FEATURE_? */
int core_argc;
char **core_argv;
char *policy_name;
int policy_argc;
char **policy_argv;
unsigned error : 1; /* detected error (switches to fail soon) */
unsigned fail : 1; /* all I/O fails */
unsigned needs_check : 1; /* metadata needs check */
unsigned read_only : 1; /* metadata may not be changed */
uint32_t reserved : 28;
};
int dm_get_status_cache(struct dm_pool *mem, const char *params,
struct dm_status_cache **status);
/*
* Parse params from STATUS call for snapshot target
*
* Snapshot target's format:
* <= 1.7.0: <used_sectors>/<total_sectors>
* >= 1.8.0: <used_sectors>/<total_sectors> <metadata_sectors>
*/
struct dm_status_snapshot {
uint64_t used_sectors; /* in 512b units */
uint64_t total_sectors;
uint64_t metadata_sectors;
unsigned has_metadata_sectors : 1; /* set when metadata_sectors is present */
unsigned invalid : 1; /* set when snapshot is invalidated */
unsigned merge_failed : 1; /* set when snapshot merge failed */
unsigned overflow : 1; /* set when snapshot overflows */
};
int dm_get_status_snapshot(struct dm_pool *mem, const char *params,
struct dm_status_snapshot **status);
/* Parse params from STATUS call for thin_pool target */
typedef enum {
DM_THIN_DISCARDS_IGNORE,
DM_THIN_DISCARDS_NO_PASSDOWN,
DM_THIN_DISCARDS_PASSDOWN
} dm_thin_discards_t;
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;
uint32_t read_only; /* metadata may not be changed */
dm_thin_discards_t discards;
uint32_t fail : 1; /* all I/O fails */
uint32_t error_if_no_space : 1; /* otherwise queue_if_no_space */
uint32_t out_of_data_space : 1; /* metadata may be changed, but data may not be allocated (no rw) */
uint32_t needs_check : 1; /* metadata needs check */
uint32_t error : 1; /* detected error (switches to fail soon) */
uint32_t reserved : 27;
};
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;
uint32_t fail : 1; /* Thin volume fails I/O */
uint32_t reserved : 31;
};
int dm_get_status_thin(struct dm_pool *mem, const char *params,
struct dm_status_thin **status);
/*
* device-mapper statistics support
*/
/*
* Statistics handle.
*
* Operations on dm_stats objects include managing statistics regions
* and obtaining and manipulating current counter values from the
* kernel. Methods are provided to return baisc count values and to
* derive time-based metrics when a suitable interval estimate is
* provided.
*
* Internally the dm_stats handle contains a pointer to a table of one
* or more dm_stats_region objects representing the regions registered
* with the dm_stats_create_region() method. These in turn point to a
* table of one or more dm_stats_counters objects containing the
* counter sets for each defined area within the region:
*
* dm_stats->dm_stats_region[nr_regions]->dm_stats_counters[nr_areas]
*
* This structure is private to the library and may change in future
* versions: all users should make use of the public interface and treat
* the dm_stats type as an opaque handle.
*
* Regions and counter sets are stored in order of increasing region_id.
* Depending on region specifications and the sequence of create and
* delete operations this may not correspond to increasing sector
* number: users of the library should not assume that this is the case
* unless region creation is deliberately managed to ensure this (by
* always creating regions in strict order of ascending sector address).
*
* Regions may also overlap so the same sector range may be included in
* more than one region or area: applications should be prepared to deal
* with this or manage regions such that it does not occur.
*/
struct dm_stats;
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
/*
* Histogram handle.
*
* A histogram object represents the latency histogram values and bin
* boundaries of the histogram associated with a particular area.
*
* Operations on the handle allow the number of bins, bin boundaries,
* counts and relative proportions to be obtained as well as the
* conversion of a histogram or its bounds to a compact string
* representation.
*/
struct dm_histogram;
/*
* Allocate a dm_stats handle to use for subsequent device-mapper
* statistics operations. A program_id may be specified and will be
* used by default for subsequent operations on this handle.
*
* If program_id is NULL or the empty string a program_id will be
* automatically set to the value contained in /proc/self/comm.
*/
struct dm_stats *dm_stats_create(const char *program_id);
/*
* Bind a dm_stats handle to the specified device major and minor
* values. Any previous binding is cleared and any preexisting counter
* data contained in the handle is released.
*/
int dm_stats_bind_devno(struct dm_stats *dms, int major, int minor);
/*
* Bind a dm_stats handle to the specified device name.
* Any previous binding is cleared and any preexisting counter
* data contained in the handle is released.
*/
int dm_stats_bind_name(struct dm_stats *dms, const char *name);
/*
* Bind a dm_stats handle to the specified device UUID.
* Any previous binding is cleared and any preexisting counter
* data contained in the handle is released.
*/
int dm_stats_bind_uuid(struct dm_stats *dms, const char *uuid);
/*
* Bind a dm_stats handle to the device backing the file referenced
* by the specified file descriptor.
*
* File descriptor fd must reference a regular file, open for reading,
* in a local file system, backed by a device-mapper device, that
* supports the FIEMAP ioctl, and that returns data describing the
* physical location of extents.
*/
int dm_stats_bind_from_fd(struct dm_stats *dms, int fd);
/*
* Test whether the running kernel supports the precise_timestamps
* feature. Presence of this feature also implies histogram support.
* The library will check this call internally and fails any attempt
* to use nanosecond counters or histograms on kernels that fail to
* meet this check.
*/
int dm_message_supports_precise_timestamps(void);
/*
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
* Precise timetamps and histogram support.
*
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
* Test for the presence of precise_timestamps and histogram support.
*/
int dm_stats_driver_supports_precise(void);
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
int dm_stats_driver_supports_histogram(void);
/*
* Returns 1 if the specified region has the precise_timestamps feature
* enabled (i.e. produces nanosecond-precision counter values) or 0 for
* a region using the default milisecond precision.
*/
int dm_stats_get_region_precise_timestamps(const struct dm_stats *dms,
uint64_t region_id);
/*
* Returns 1 if the region at the current cursor location has the
* precise_timestamps feature enabled (i.e. produces
* nanosecond-precision counter values) or 0 for a region using the
* default milisecond precision.
*/
int dm_stats_get_current_region_precise_timestamps(const struct dm_stats *dms);
#define DM_STATS_ALL_PROGRAMS ""
/*
* Parse the response from a @stats_list message. dm_stats_list will
* allocate the necessary dm_stats and dm_stats region structures from
* the embedded dm_pool. No counter data will be obtained (the counters
* members of dm_stats_region objects are set to NULL).
*
* A program_id may optionally be supplied; if the argument is non-NULL
* only regions with a matching program_id value will be considered. If
* the argument is NULL then the default program_id associated with the
* dm_stats handle will be used. Passing the special value
* DM_STATS_ALL_PROGRAMS will cause all regions to be queried
* regardless of region program_id.
*/
int dm_stats_list(struct dm_stats *dms, const char *program_id);
#define DM_STATS_REGIONS_ALL UINT64_MAX
/*
* Populate a dm_stats object with statistics for one or more regions of
* the specified device.
*
* A program_id may optionally be supplied; if the argument is non-NULL
* only regions with a matching program_id value will be considered. If
* the argument is NULL then the default program_id associated with the
* dm_stats handle will be used. Passing the special value
* DM_STATS_ALL_PROGRAMS will cause all regions to be queried
* regardless of region program_id.
*
* Passing the special value DM_STATS_REGIONS_ALL as the region_id
* argument will attempt to retrieve all regions selected by the
* program_id argument.
*
* If region_id is used to request a single region_id to be populated
* the program_id is ignored.
*/
int dm_stats_populate(struct dm_stats *dms, const char *program_id,
uint64_t region_id);
/*
* Create a new statistics region on the device bound to dms.
*
* start and len specify the region start and length in 512b sectors.
* Passing zero for both start and len will create a region spanning
* the entire device.
*
* Step determines how to subdivide the region into discrete counter
* sets: a positive value specifies the size of areas into which the
* region should be split while a negative value will split the region
* into a number of areas equal to the absolute value of step:
*
* - a region with one area spanning the entire device:
*
* dm_stats_create_region(dms, 0, 0, -1, p, a);
*
* - a region with areas of 1MiB:
*
* dm_stats_create_region(dms, 0, 0, 1 << 11, p, a);
*
* - one 1MiB region starting at 1024 sectors with two areas:
*
* dm_stats_create_region(dms, 1024, 1 << 11, -2, p, a);
*
* If precise is non-zero attempt to create a region with nanosecond
* precision counters using the kernel precise_timestamps feature.
*
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
* precise - A flag to request nanosecond precision counters
* to be used for this region.
*
* histogram_bounds - specify the boundaries of a latency histogram to
* be tracked for the region. The values are expressed as an array of
* uint64_t terminated with a zero. Values must be in order of ascending
* magnitude and specify the upper bounds of successive histogram bins
* in nanoseconds (with an implicit lower bound of zero on the first bin
* and an implicit upper bound of infinity on the final bin). For
* example:
*
* uint64_t bounds_ary[] = { 1000, 2000, 3000, 0 };
*
* Specifies a histogram with four bins: 0-1000ns, 1000-2000ns,
* 2000-3000ns and >3000ns.
*
* The smallest latency value that can be tracked for a region not using
* precise_timestamps is 1ms: attempting to create a region with
* histogram boundaries < 1ms will cause the precise_timestamps feature
* to be enabled for that region automatically if it was not requested
* explicitly.
*
* program_id is an optional string argument that identifies the
* program creating the region. If program_id is NULL or the empty
* string the default program_id stored in the handle will be used.
*
* user_data is an optional string argument that is added to the
* content of the aux_data field stored with the statistics region by
* the kernel.
*
* The library may also use this space internally, for example, to
* store a group descriptor or other metadata: in this case the
* library will strip any internal data fields from the value before
* it is returned via a call to dm_stats_get_region_aux_data().
*
* The user data stored is not accessed by the library or kernel and
* may be used to store an arbitrary data word (embedded whitespace is
* not permitted).
*
* An application using both the library and direct access to the
* @stats_list device-mapper message may see the internal values stored
* in this field by the library. In such cases any string up to and
* including the first '#' in the field must be treated as an opaque
* value and preserved across any external modification of aux_data.
*
* The region_id of the newly-created region is returned in *region_id
* if it is non-NULL.
*/
int dm_stats_create_region(struct dm_stats *dms, uint64_t *region_id,
uint64_t start, uint64_t len, int64_t step,
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
int precise, struct dm_histogram *bounds,
const char *program_id, const char *user_data);
/*
* Delete the specified statistics region. This will also mark the
* region as not-present and discard any existing statistics data.
*/
int dm_stats_delete_region(struct dm_stats *dms, uint64_t region_id);
/*
* Clear the specified statistics region. This requests the kernel to
* zero all counter values (except in-flight I/O). Note that this
* operation is not atomic with respect to reads of the counters; any IO
* events occurring between the last print operation and the clear will
* be lost. This can be avoided by using the atomic print-and-clear
* function of the dm_stats_print_region() call or by using the higher
* level dm_stats_populate() interface.
*/
int dm_stats_clear_region(struct dm_stats *dms, uint64_t region_id);
/*
* Print the current counter values for the specified statistics region
* and return them as a string. The memory for the string buffer will
* be allocated from the dm_stats handle's private pool and should be
* returned by calling dm_stats_buffer_destroy() when no longer
* required. The pointer will become invalid following any call that
* clears or reinitializes the handle (destroy, list, populate, bind).
*
* This allows applications that wish to access the raw message response
* to obtain it via a dm_stats handle; no parsing of the textual counter
* data is carried out by this function.
*
* Most users are recommended to use the dm_stats_populate() call
* instead since this will automatically parse the statistics data into
* numeric form accessible via the dm_stats_get_*() counter access
* methods.
*
* A subset of the data lines may be requested by setting the
* start_line and num_lines parameters. If both are zero all data
* lines are returned.
*
* If the clear parameter is non-zero the operation will also
* atomically reset all counter values to zero (except in-flight IO).
*/
char *dm_stats_print_region(struct dm_stats *dms, uint64_t region_id,
unsigned start_line, unsigned num_lines,
unsigned clear);
/*
* Destroy a statistics response buffer obtained from a call to
* dm_stats_print_region().
*/
void dm_stats_buffer_destroy(struct dm_stats *dms, char *buffer);
/*
* Determine the number of regions contained in a dm_stats handle
* following a dm_stats_list() or dm_stats_populate() call.
*
* The value returned is the number of registered regions visible with the
* progam_id value used for the list or populate operation and may not be
* equal to the highest present region_id (either due to program_id
* filtering or gaps in the sequence of region_id values).
*
* Always returns zero on an empty handle.
*/
uint64_t dm_stats_get_nr_regions(const struct dm_stats *dms);
/*
* Determine the number of groups contained in a dm_stats handle
* following a dm_stats_list() or dm_stats_populate() call.
*
* The value returned is the number of registered groups visible with the
* progam_id value used for the list or populate operation and may not be
* equal to the highest present group_id (either due to program_id
* filtering or gaps in the sequence of group_id values).
*
* Always returns zero on an empty handle.
*/
uint64_t dm_stats_get_nr_groups(const struct dm_stats *dms);
/*
* Test whether region_id is present in this dm_stats handle.
*/
int dm_stats_region_present(const struct dm_stats *dms, uint64_t region_id);
/*
* Returns the number of areas (counter sets) contained in the specified
* region_id of the supplied dm_stats handle.
*/
uint64_t dm_stats_get_region_nr_areas(const struct dm_stats *dms,
uint64_t region_id);
/*
* Returns the total number of areas (counter sets) in all regions of the
* given dm_stats object.
*/
uint64_t dm_stats_get_nr_areas(const struct dm_stats *dms);
/*
* Test whether group_id is present in this dm_stats handle.
*/
int dm_stats_group_present(const struct dm_stats *dms, uint64_t group_id);
/*
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
* Return the number of bins in the histogram configuration for the
* specified region or zero if no histogram specification is configured.
* Valid following a dm_stats_list() or dm_stats_populate() operation.
*/
int dm_stats_get_region_nr_histogram_bins(const struct dm_stats *dms,
uint64_t region_id);
/*
* Parse a histogram string with optional unit suffixes into a
* dm_histogram bounds description.
*
* A histogram string is a string of numbers "n1,n2,n3,..." that
* represent the boundaries of a histogram. The first and final bins
* have implicit lower and upper bounds of zero and infinity
* respectively and boundary values must occur in order of ascending
* magnitude. Unless a unit suffix is given all values are specified in
* nanoseconds.
*
* For example, if bounds_str="300,600,900", the region will be created
* with a histogram containing four bins. Each report will include four
* numbers a:b:c:d. a is the number of requests that took between 0 and
* 300ns to complete, b is the number of requests that took 300-600ns to
* complete, c is the number of requests that took 600-900ns to complete
* and d is the number of requests that took more than 900ns to
* complete.
*
* An optional unit suffix of 's', 'ms', 'us', or 'ns' may be used to
* specify units of seconds, miliseconds, microseconds, or nanoseconds:
*
* bounds_str="1ns,1us,1ms,1s"
* bounds_str="500us,1ms,1500us,2ms"
* bounds_str="200ms,400ms,600ms,800ms,1s"
*
* The smallest valid unit of time for a histogram specification depends
* on whether the region uses precise timestamps: for a region with the
* default milisecond precision the smallest possible histogram boundary
* magnitude is one milisecond: attempting to use a histogram with a
* boundary less than one milisecond when creating a region will cause
* the region to be created with the precise_timestamps feature enabled.
*
* On sucess a pointer to the struct dm_histogram representing the
* bounds values is returned, or NULL in the case of error. The returned
* pointer should be freed using dm_free() when no longer required.
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
*/
struct dm_histogram *dm_histogram_bounds_from_string(const char *bounds_str);
/*
* Parse a zero terminated array of uint64_t into a dm_histogram bounds
* description.
*
* Each value in the array specifies the upper bound of a bin in the
* latency histogram in nanoseconds. Values must appear in ascending
* order of magnitude.
*
* The smallest valid unit of time for a histogram specification depends
* on whether the region uses precise timestamps: for a region with the
* default milisecond precision the smallest possible histogram boundary
* magnitude is one milisecond: attempting to use a histogram with a
* boundary less than one milisecond when creating a region will cause
* the region to be created with the precise_timestamps feature enabled.
*/
struct dm_histogram *dm_histogram_bounds_from_uint64(const uint64_t *bounds);
/*
* Destroy the histogram bounds array obtained from a call to
* dm_histogram_bounds_from_string().
*/
void dm_histogram_bounds_destroy(struct dm_histogram *bounds);
/*
* Destroy a dm_stats object and all associated regions, counter
* sets and histograms.
*/
void dm_stats_destroy(struct dm_stats *dms);
/*
* Counter sampling interval
*/
/*
* Set the sampling interval for counter data to the specified value in
* either nanoseconds or milliseconds.
*
* The interval is used to calculate time-based metrics from the basic
* counter data: an interval must be set before calling any of the
* metric methods.
*
* For best accuracy the duration should be measured and updated at the
* end of each interval.
*
* All values are stored internally with nanosecond precision and are
* converted to or from ms when the millisecond interfaces are used.
*/
void dm_stats_set_sampling_interval_ns(struct dm_stats *dms,
uint64_t interval_ns);
void dm_stats_set_sampling_interval_ms(struct dm_stats *dms,
uint64_t interval_ms);
/*
* Retrieve the configured sampling interval in either nanoseconds or
* milliseconds.
*/
uint64_t dm_stats_get_sampling_interval_ns(const struct dm_stats *dms);
uint64_t dm_stats_get_sampling_interval_ms(const struct dm_stats *dms);
/*
* Override program_id. This may be used to change the default
* program_id value for an existing handle. If the allow_empty argument
* is non-zero a NULL or empty program_id is permitted.
*
* Use with caution! Most users of the library should set a valid,
* non-NULL program_id for every statistics region created. Failing to
* do so may result in confusing state when multiple programs are
* creating and managing statistics regions.
*
* All users of the library are encouraged to choose an unambiguous,
* unique program_id: this could be based on PID (for programs that
* create, report, and delete regions in a single process), session id,
* executable name, or some other distinguishing string.
*
* Use of the empty string as a program_id does not simplify use of the
* library or the command line tools and use of this value is strongly
* discouraged.
*/
int dm_stats_set_program_id(struct dm_stats *dms, int allow_empty,
const char *program_id);
/*
* Region properties: size, length & area_len.
*
* Region start and length are returned in units of 512b as specified
* at region creation time. The area_len value gives the size of areas
* into which the region has been subdivided. For regions with a single
* area spanning the range this value is equal to the region length.
*
* For regions created with a specified number of areas the value
* represents the size of the areas into which the kernel divided the
* region excluding any rounding of the last area size. The number of
* areas may be obtained using the dm_stats_nr_areas_region() call.
*
* All values are returned in units of 512b sectors.
*/
int dm_stats_get_region_start(const struct dm_stats *dms, uint64_t *start,
uint64_t region_id);
int dm_stats_get_region_len(const struct dm_stats *dms, uint64_t *len,
uint64_t region_id);
int dm_stats_get_region_area_len(const struct dm_stats *dms,
uint64_t *len, uint64_t region_id);
/*
* Area properties: start, offset and length.
*
* The area length is always equal to the area length of the region
* that contains it and is obtained from dm_stats_get_region_area_len().
*
* The start of an area is a function of the area_id and the containing
* region's start and area length: it gives the absolute offset into the
* containing device of the beginning of the area.
*
* The offset expresses the area's relative offset into the current
* region. I.e. the area start minus the start offset of the containing
* region.
*
* All values are returned in units of 512b sectors.
*/
int dm_stats_get_area_start(const struct dm_stats *dms, uint64_t *start,
uint64_t region_id, uint64_t area_id);
int dm_stats_get_area_offset(const struct dm_stats *dms, uint64_t *offset,
uint64_t region_id, uint64_t area_id);
/*
* Retrieve program_id and user aux_data for a specific region.
*
* Only valid following a call to dm_stats_list().
*/
/*
* Retrieve program_id for the specified region.
*
* The returned pointer does not need to be freed separately from the
* dm_stats handle but will become invalid after a dm_stats_destroy(),
* dm_stats_list(), dm_stats_populate(), or dm_stats_bind*() of the
* handle from which it was obtained.
*/
const char *dm_stats_get_region_program_id(const struct dm_stats *dms,
uint64_t region_id);
/*
* Retrieve user aux_data set for the specified region. This function
* will return any stored user aux_data as a string in the memory
* pointed to by the aux_data argument.
*
* Any library internal aux_data fields, such as DMS_GROUP descriptors,
* are stripped before the value is returned.
*
* The returned pointer does not need to be freed separately from the
* dm_stats handle but will become invalid after a dm_stats_destroy(),
* dm_stats_list(), dm_stats_populate(), or dm_stats_bind*() of the
* handle from which it was obtained.
*/
const char *dm_stats_get_region_aux_data(const struct dm_stats *dms,
uint64_t region_id);
typedef enum {
DM_STATS_OBJECT_TYPE_NONE,
DM_STATS_OBJECT_TYPE_AREA,
DM_STATS_OBJECT_TYPE_REGION,
DM_STATS_OBJECT_TYPE_GROUP
} dm_stats_obj_type_t;
/*
* Statistics cursor
*
* A dm_stats handle maintains an optional cursor into the statistics
* tables that it stores. Iterators are provided to visit each region,
* area, or group in a handle and accessor methods are provided to
* obtain properties and values for the object at the current cursor
* position.
*
* Using the cursor simplifies walking all regions or groups when
* the tables are sparse (i.e. contains some present and some
* non-present region_id or group_id values either due to program_id
* filtering or the ordering of region and group creation and deletion).
*
* Simple macros are provided to visit each area, region, or group,
* contained in a handle and applications are encouraged to use these
* where possible.
*/
/*
* Walk flags are used to initialise a dm_stats handle's cursor control
* and to select region or group aggregation when calling a metric or
* counter property method with immediate group, region, and area ID
* values.
*
* Walk flags are stored in the uppermost word of a uint64_t so that
* a region_id or group_id may be encoded in the lower bits. This
* allows an aggregate region_id or group_id to be specified when
* retrieving counter or metric values.
*
* Flags may be ORred together when used to initialise a dm_stats_walk:
* the resulting walk will visit instance of each type specified by
* the flag combination.
*/
#define DM_STATS_WALK_AREA 0x1000000000000ULL
#define DM_STATS_WALK_REGION 0x2000000000000ULL
#define DM_STATS_WALK_GROUP 0x4000000000000ULL
#define DM_STATS_WALK_ALL 0x7000000000000ULL
#define DM_STATS_WALK_DEFAULT (DM_STATS_WALK_AREA | DM_STATS_WALK_REGION)
/*
* Skip regions from a DM_STATS_WALK_REGION that contain only a single
* area: in this case the region's aggregate values are identical to
* the values of the single contained area. Setting this flag will
* suppress these duplicate entries during a dm_stats_walk_* with the
* DM_STATS_WALK_REGION flag set.
*/
#define DM_STATS_WALK_SKIP_SINGLE_AREA 0x8000000000000ULL
/*
* Initialise the cursor control of a dm_stats handle for the specified
* walk type(s). Including a walk flag in the flags argument will cause
* any subsequent walk to visit that type of object (until the next
* call to dm_stats_walk_init()).
*/
int dm_stats_walk_init(struct dm_stats *dms, uint64_t flags);
/*
* Set the cursor of a dm_stats handle to address the first present
* group, region, or area of the currently configured walk. It is
* valid to attempt to walk a NULL stats handle or a handle containing
* no present regions; in this case any call to dm_stats_walk_next()
* becomes a no-op and all calls to dm_stats_walk_end() return true.
*/
void dm_stats_walk_start(struct dm_stats *dms);
/*
* Advance the statistics cursor to the next area, or to the next
* present region if at the end of the current region. If the end of
* the region, area, or group tables is reached a subsequent call to
* dm_stats_walk_end() will return 1 and dm_stats_object_type() called
* on the location will return DM_STATS_OBJECT_TYPE_NONE,
*/
void dm_stats_walk_next(struct dm_stats *dms);
/*
* Force the statistics cursor to advance to the next region. This will
* stop any in-progress area walk (by clearing DM_STATS_WALK_AREA) and
* advance the cursor to the next present region, the first present
* group (if DM_STATS_GROUP_WALK is set), or to the end. In this case a
* subsequent call to dm_stats_walk_end() will return 1 and a call to
* dm_stats_object_type() for the location will return
* DM_STATS_OBJECT_TYPE_NONE.
*/
void dm_stats_walk_next_region(struct dm_stats *dms);
/*
* Test whether the end of a statistics walk has been reached.
*/
int dm_stats_walk_end(struct dm_stats *dms);
/*
* Return the type of object at the location specified by region_id
* and area_id. If either region_id or area_id uses one of the special
* values DM_STATS_REGION_CURRENT or DM_STATS_AREA_CURRENT the
* corresponding region or area identifier will be taken from the
* current cursor location. If the cursor location or the value encoded
* by region_id and area_id indicates an aggregate region or group,
* this will be reflected in the value returned.
*/
dm_stats_obj_type_t dm_stats_object_type(const struct dm_stats *dms,
uint64_t region_id,
uint64_t area_id);
/*
* Return the type of object at the current stats cursor location.
*/
dm_stats_obj_type_t dm_stats_current_object_type(const struct dm_stats *dms);
/*
* Stats iterators
*
* C 'for' and 'do'/'while' style iterators for dm_stats data.
*
* It is not safe to call any function that modifies the region table
* within the loop body (i.e. dm_stats_list(), dm_stats_populate(),
* dm_stats_init(), or dm_stats_destroy()).
*
* All counter and property (dm_stats_get_*) access methods, as well as
* dm_stats_populate_region() can be safely called from loops.
*
*/
/*
* Iterate over the regions table visiting each region.
*
* If the region table is empty or unpopulated the loop body will not be
* executed.
*/
#define dm_stats_foreach_region(dms) \
for (dm_stats_walk_init((dms), DM_STATS_WALK_REGION), \
dm_stats_walk_start((dms)); \
!dm_stats_walk_end((dms)); dm_stats_walk_next_region((dms)))
/*
* Iterate over the regions table visiting each area.
*
* If the region table is empty or unpopulated the loop body will not
* be executed.
*/
#define dm_stats_foreach_area(dms) \
for (dm_stats_walk_init((dms), DM_STATS_WALK_AREA), \
dm_stats_walk_start((dms)); \
!dm_stats_walk_end((dms)); dm_stats_walk_next((dms)))
/*
* Iterate over the regions table visiting each group. Metric and
* counter methods will return values for the group.
*
* If the group table is empty or unpopulated the loop body will not
* be executed.
*/
#define dm_stats_foreach_group(dms) \
for (dm_stats_walk_init((dms), DM_STATS_WALK_GROUP), \
dm_stats_walk_start(dms); \
!dm_stats_walk_end(dms); \
dm_stats_walk_next(dms))
/*
* Start a walk iterating over the regions contained in dm_stats handle
* 'dms'.
*
* The body of the loop should call dm_stats_walk_next() or
* dm_stats_walk_next_region() to advance to the next element.
*
* The loop body is executed at least once even if the stats handle is
* empty.
*/
#define dm_stats_walk_do(dms) \
do { \
dm_stats_walk_start((dms)); \
do
/*
* Start a 'while' style loop or end a 'do..while' loop iterating over the
* regions contained in dm_stats handle 'dms'.
*/
#define dm_stats_walk_while(dms) \
while(!dm_stats_walk_end((dms))); \
} while (0)
/*
* Cursor relative property methods
*
* Calls with the prefix dm_stats_get_current_* operate relative to the
* current cursor location, returning properties for the current region
* or area of the supplied dm_stats handle.
*
*/
/*
* Returns the number of areas (counter sets) contained in the current
* region of the supplied dm_stats handle.
*/
uint64_t dm_stats_get_current_nr_areas(const struct dm_stats *dms);
/*
* Retrieve the current values of the stats cursor.
*/
uint64_t dm_stats_get_current_region(const struct dm_stats *dms);
uint64_t dm_stats_get_current_area(const struct dm_stats *dms);
/*
* Current region properties: size, length & area_len.
*
* See the comments for the equivalent dm_stats_get_* versions for a
* complete description of these methods.
*
* All values are returned in units of 512b sectors.
*/
int dm_stats_get_current_region_start(const struct dm_stats *dms,
uint64_t *start);
int dm_stats_get_current_region_len(const struct dm_stats *dms,
uint64_t *len);
int dm_stats_get_current_region_area_len(const struct dm_stats *dms,
uint64_t *area_len);
/*
* Current area properties: start and length.
*
* See the comments for the equivalent dm_stats_get_* versions for a
* complete description of these methods.
*
* All values are returned in units of 512b sectors.
*/
int dm_stats_get_current_area_start(const struct dm_stats *dms,
uint64_t *start);
int dm_stats_get_current_area_offset(const struct dm_stats *dms,
uint64_t *offset);
int dm_stats_get_current_area_len(const struct dm_stats *dms,
uint64_t *start);
/*
* Return a pointer to the program_id string for region at the current
* cursor location.
*/
const char *dm_stats_get_current_region_program_id(const struct dm_stats *dms);
/*
* Return a pointer to the user aux_data string for the region at the
* current cursor location.
*/
const char *dm_stats_get_current_region_aux_data(const struct dm_stats *dms);
/*
* Statistics groups and data aggregation.
*/
/*
* Create a new group in stats handle dms from the group descriptor
* passed in group. The group descriptor is a string containing a list
* of region_id values that will be included in the group. The first
* region_id found will be the group leader. Ranges of identifiers may
* be expressed as "M-N", where M and N are the start and end region_id
* values for the range.
*/
int dm_stats_create_group(struct dm_stats *dms, const char *group,
const char *alias, uint64_t *group_id);
/*
* Remove the specified group_id. If the remove argument is zero the
* group will be removed but the regions that it contained will remain.
* If remove is non-zero then all regions that belong to the group will
* also be removed.
*/
int dm_stats_delete_group(struct dm_stats *dms, uint64_t group_id, int remove);
/*
* Set an alias for this group or region. The alias will be returned
* instead of the normal dm-stats name for this region or group.
*/
int dm_stats_set_alias(struct dm_stats *dms, uint64_t group_id,
const char *alias);
/*
* Returns a pointer to the currently configured alias for id, or the
* name of the dm device the handle is bound to if no alias has been
* set. The pointer will be freed automatically when a new alias is set
* or when the stats handle is cleared.
*/
const char *dm_stats_get_alias(const struct dm_stats *dms, uint64_t id);
#define DM_STATS_GROUP_NONE UINT64_MAX
/*
* Return the group_id that the specified region_id belongs to, or the
* special value DM_STATS_GROUP_NONE if the region does not belong
* to any group.
*/
uint64_t dm_stats_get_group_id(const struct dm_stats *dms, uint64_t region_id);
/*
* Store a pointer to a string describing the regions that are members
* of the group specified by group_id in the memory pointed to by buf.
* The string is in the same format as the 'group' argument to
* dm_stats_create_group().
*
* The pointer does not need to be freed explicitly by the caller: it
* will become invalid following a subsequent dm_stats_list(),
* dm_stats_populate() or dm_stats_destroy() of the corresponding
* dm_stats handle.
*/
int dm_stats_get_group_descriptor(const struct dm_stats *dms,
uint64_t group_id, char **buf);
/*
* Create regions that correspond to the extents of a file in the
* filesystem and optionally place them into a group.
*
* File descriptor fd must reference a regular file, open for reading,
* in a local file system that supports the FIEMAP ioctl, and that
* returns data describing the physical location of extents.
*
* The file descriptor can be closed by the caller following the call
* to dm_stats_create_regions_from_fd().
*
* Unless nogroup is non-zero the regions will be placed into a group
* and the group alias set to the value supplied (if alias is NULL no
* group alias will be assigned).
*
* On success the function returns a pointer to an array of uint64_t
* containing the IDs of the newly created regions. The region_id
* array is terminated by the value DM_STATS_REGION_NOT_PRESENT and
* should be freed using dm_free() when no longer required.
*
* On error NULL is returned.
*
* Following a call to dm_stats_create_regions_from_fd() the handle
* is guaranteed to be in a listed state, and to contain any region
* and group identifiers created by the operation.
*
* The group_id for the new group is equal to the region_id value in
* the first array element.
*/
uint64_t *dm_stats_create_regions_from_fd(struct dm_stats *dms, int fd,
int group, int precise,
struct dm_histogram *bounds,
const char *alias);
/*
* Update a group of regions that correspond to the extents of a file
* in the filesystem, adding and removing regions to account for
* allocation changes in the underlying file.
*
* File descriptor fd must reference a regular file, open for reading,
* in a local file system that supports the FIEMAP ioctl, and that
* returns data describing the physical location of extents.
*
* The file descriptor can be closed by the caller following the call
* to dm_stats_update_regions_from_fd().
*
* On success the function returns a pointer to an array of uint64_t
* containing the IDs of the updated regions (including any existing
* regions that were not modified by the call).
*
* The region_id array is terminated by the special value
* DM_STATS_REGION_NOT_PRESENT and should be freed using dm_free()
* when no longer required.
*
* On error NULL is returned.
*
* Following a call to dm_stats_update_regions_from_fd() the handle
* is guaranteed to be in a listed state, and to contain any region
* and group identifiers created by the operation.
*
* This function cannot be used with file mapped regions that are
* not members of a group: either group the regions, or remove them
* and re-map them with dm_stats_create_regions_from_fd().
*/
uint64_t *dm_stats_update_regions_from_fd(struct dm_stats *dms, int fd,
uint64_t group_id);
daemons: add dmfilemapd Add a daemon that can be launched to monitor a group of regions corresponding to the extents of a file, and to update the regions as the file's allocation changes. The daemon is intended to be started from a library interface, but can also be run from the command line: dmfilemapd <fd> <group_id> <path> <mode> [<foreground>[<log_level>]] Where fd is a file descriptor open on the mapped file, group_id is the group identifier of the mapped group and mode is either "inode" or "path". E.g.: # dmfilemapd 3 0 vm.img inode 1 3 3<vm.img ... If foreground is non-zero, the daemon will not fork to run in the background. If verbose is non-zero, libdm and daemon log messages will be printed. It is possible for the group identifier to change when regions are re-mapped: this occurs when the group leader is deleted (regroup=1 in dm_stats_update_regions_from_fd()), and another region is created before the daemon has a chance to recreate the leader region. The operation is inherently racey since there is currently no way to atomically move or resize a dm_stats region while retaining its region_id. Detect this condition and update the group_id value stored in the filemap monitor. A function is also provided in the the stats API to launch the filemap monitoring daemon: int dm_stats_start_filemapd(int fd, uint64_t group_id, const char *path, dm_filemapd_mode_t mode, unsigned foreground, unsigned verbose); This carries out the first fork and execs dmfilemapd with the arguments specified. A dm_filemapd_mode_t value is specified by the mode argument: either DM_FILEMAPD_FOLLOW_INODE, or DM_FILEMAPD_FOLLOW_PATH. A helper function, dm_filemapd_mode_from_string(), is provided to parse a string containing a valid mode name into the appropriate dm_filemapd_mode_t value.
2016-12-15 23:10:27 +03:00
/*
* The file map monitoring daemon can monitor files in two distinct
* ways: the mode affects the behaviour of the daemon when a file
* under monitoring is renamed or unlinked, and the conditions which
* cause the daemon to terminate.
*
* In both modes, the daemon will always shut down when the group
* being monitored is deleted.
*
* Follow inode:
* The daemon follows the inode of the file, as it was at the time the
* daemon started. The file descriptor referencing the file is kept
* open at all times, and the daemon will exit when it detects that
* the file has been unlinked and it is the last holder of a reference
* to the file.
*
* This mode is useful if the file is expected to be renamed, or moved
* within the file system, while it is being monitored.
*
* Follow path:
* The daemon follows the path that was given on the daemon command
* line. The file descriptor referencing the file is re-opened on each
* iteration of the daemon, and the daemon will exit if no file exists
* at this location (a tolerance is allowed so that a brief delay
* between unlink() and creat() is permitted).
*
* This mode is useful if the file is updated by unlinking the original
* and placing a new file at the same path.
*/
typedef enum {
DM_FILEMAPD_FOLLOW_INODE,
DM_FILEMAPD_FOLLOW_PATH,
DM_FILEMAPD_FOLLOW_NONE
} dm_filemapd_mode_t;
/*
* Parse a string representation of a dmfilemapd mode.
*
* Returns a valid dm_filemapd_mode_t value on success, or
* DM_FILEMAPD_FOLLOW_NONE on error.
*/
dm_filemapd_mode_t dm_filemapd_mode_from_string(const char *mode_str);
/*
* Start the dmfilemapd filemap monitoring daemon for the specified
* file descriptor, group, and file system path. The daemon will
* monitor the file for allocation changes, and when a change is
* detected, call dm_stats_update_regions_from_fd() to update the
* mapped regions for the file.
*
* The path provided to dm_stats_start_filemapd() must be an absolute
* path, and should reflect the path of 'fd' at the time that it was
* opened.
*
daemons: add dmfilemapd Add a daemon that can be launched to monitor a group of regions corresponding to the extents of a file, and to update the regions as the file's allocation changes. The daemon is intended to be started from a library interface, but can also be run from the command line: dmfilemapd <fd> <group_id> <path> <mode> [<foreground>[<log_level>]] Where fd is a file descriptor open on the mapped file, group_id is the group identifier of the mapped group and mode is either "inode" or "path". E.g.: # dmfilemapd 3 0 vm.img inode 1 3 3<vm.img ... If foreground is non-zero, the daemon will not fork to run in the background. If verbose is non-zero, libdm and daemon log messages will be printed. It is possible for the group identifier to change when regions are re-mapped: this occurs when the group leader is deleted (regroup=1 in dm_stats_update_regions_from_fd()), and another region is created before the daemon has a chance to recreate the leader region. The operation is inherently racey since there is currently no way to atomically move or resize a dm_stats region while retaining its region_id. Detect this condition and update the group_id value stored in the filemap monitor. A function is also provided in the the stats API to launch the filemap monitoring daemon: int dm_stats_start_filemapd(int fd, uint64_t group_id, const char *path, dm_filemapd_mode_t mode, unsigned foreground, unsigned verbose); This carries out the first fork and execs dmfilemapd with the arguments specified. A dm_filemapd_mode_t value is specified by the mode argument: either DM_FILEMAPD_FOLLOW_INODE, or DM_FILEMAPD_FOLLOW_PATH. A helper function, dm_filemapd_mode_from_string(), is provided to parse a string containing a valid mode name into the appropriate dm_filemapd_mode_t value.
2016-12-15 23:10:27 +03:00
* The mode parameter controls the behaviour of the daemon when the
* file being monitored is unlinked or moved: see the comments for
* dm_filemapd_mode_t for a full description and possible values.
*
* The daemon can be stopped at any time by sending SIGTERM to the
* daemon pid.
*/
int dm_stats_start_filemapd(int fd, uint64_t group_id, const char *path,
dm_filemapd_mode_t mode, unsigned foreground,
unsigned verbose);
/*
* Call this to actually run the ioctl.
*/
int dm_task_run(struct dm_task *dmt);
/*
* The errno from the last device-mapper ioctl performed by dm_task_run.
*/
int dm_task_get_errno(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);
/*
* Callback is invoked for individal mountinfo lines,
* minor, major and mount target are parsed and unmangled.
*/
typedef int (*dm_mountinfo_line_callback_fn) (char *line, unsigned maj, unsigned min,
char *target, void *cb_data);
/*
* Read all lines from /proc/self/mountinfo,
* for each line calls read_fn callback.
*/
int dm_mountinfo_read(dm_mountinfo_line_callback_fn read_fn, void *cb_data);
/*
* 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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/* An optimisation for clients making repeated calls involving dm ioctls */
void dm_hold_control_dev(int hold_open);
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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);
2005-10-17 02:57:20 +04:00
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/******************************************************
* Functions to build and manipulate trees of devices *
******************************************************/
struct dm_tree;
struct dm_tree_node;
/*
* Initialise an empty dependency tree.
*
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* 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.
*
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* 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);
/*
* List of suffixes to be ignored when matching uuids against existing devices.
*/
void dm_tree_set_optional_uuid_suffixes(struct dm_tree *dtree, const char **optional_uuid_suffixes);
/*
* 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,
2014-02-14 23:46:55 +04:00
uint32_t major,
uint32_t minor);
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struct dm_tree_node *dm_tree_find_node_by_uuid(struct dm_tree *tree,
2014-02-14 23:46:55 +04:00
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.
*/
2005-11-09 17:10:50 +03:00
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);
/*
* Returns 0 when node size and its children is unchanged.
* Returns 1 when node or any of its children has increased size.
* Rerurns -1 when node or any of its children has reduced size.
*/
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.
2005-10-18 16:37:53 +04:00
*/
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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);
2005-10-18 16:37:53 +04:00
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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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2006-01-31 02:36:04 +03:00
/*
* Skip the filesystem sync when suspending.
* Does nothing with other functions.
* Use this when no snapshots are involved.
2015-08-05 07:21:58 +03:00
*/
2006-01-31 02:36:04 +03:00
void dm_tree_skip_lockfs(struct dm_tree_node *dnode);
2007-01-09 22:44:07 +03:00
/*
* 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);
2005-10-25 23:09:41 +04:00
/*
* 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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/*
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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,
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uint64_t size,
const char *origin_uuid);
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int dm_tree_node_add_snapshot_target(struct dm_tree_node *node,
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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,
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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,
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uint64_t size);
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int dm_tree_node_add_zero_target(struct dm_tree_node *node,
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uint64_t size);
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int dm_tree_node_add_linear_target(struct dm_tree_node *node,
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uint64_t size);
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int dm_tree_node_add_striped_target(struct dm_tree_node *node,
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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,
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uint64_t size);
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/* 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,
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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);
/*
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* Defines below are based on kernel's dm-cache.c defines
* DM_CACHE_MIN_DATA_BLOCK_SIZE (32 * 1024 >> SECTOR_SHIFT)
* DM_CACHE_MAX_DATA_BLOCK_SIZE (1024 * 1024 * 1024 >> SECTOR_SHIFT)
*/
#define DM_CACHE_MIN_DATA_BLOCK_SIZE (UINT32_C(64))
#define DM_CACHE_MAX_DATA_BLOCK_SIZE (UINT32_C(2097152))
/*
* Max supported size for cache pool metadata device.
* Limitation is hardcoded into the kernel and bigger device sizes
* are not accepted.
*
* Limit defined in drivers/md/dm-cache-metadata.h
*/
#define DM_CACHE_METADATA_MAX_SECTORS DM_THIN_METADATA_MAX_SECTORS
/*
* Define number of elements in rebuild and writemostly arrays
* 'of struct dm_tree_node_raid_params'.
*/
lvconvert: add infrastructure for RaidLV reshaping support In order to support striped raid5/6/10 LV reshaping (change of LV type, stripesize or number of legs), this patch introduces infrastructure prerequisites to be used by raid_manip.c extensions in followup patches. This base is needed for allocation of out-of-place reshape space required by the MD raid personalities to avoid writing over data in-place when reading off the current RAID layout or number of legs and writing out the new layout or to a different number of legs (i.e. restripe) Changes: - add members reshape_len to 'struct lv_segment' to store out-of-place reshape length per component rimage - add member data_copies to struct lv_segment to support more than 2 raid10 data copies - make alloc_lv_segment() aware of both reshape_len and data_copies - adjust all alloc_lv_segment() callers to the new API - add functions to retrieve the current data offset (needed for out-of-place reshaping space allocation) and the devices count from the kernel - make libdm deptree code aware of reshape_len - add LV flags for disk add/remove reshaping - support import/export of the new 'struct lv_segment' members - enhance lv_extend/_lv_reduce to cope with reshape_len - add seg_is_*/segtype_is_* macros related to reshaping - add target version check for reshaping - grow rebuilds/writemostly bitmaps to 246 bit to support kernel maximal - enhance libdm deptree code to support data_offset (out-of-place reshaping) and delta_disk (legs add/remove reshaping) target arguments Related: rhbz834579 Related: rhbz1191935 Related: rhbz1191978
2017-02-24 02:50:00 +03:00
RAID: Add writemostly/writebehind support for RAID1 'lvchange' is used to alter a RAID 1 logical volume's write-mostly and write-behind characteristics. The '--writemostly' parameter takes a PV as an argument with an optional trailing character to specify whether to set ('y'), unset ('n'), or toggle ('t') the value. If no trailing character is given, it will set the flag. Synopsis: lvchange [--writemostly <PV>:{t|y|n}] [--writebehind <count>] vg/lv Example: lvchange --writemostly /dev/sdb1:y --writebehind 512 vg/raid1_lv The last character in the 'lv_attr' field is used to show whether a device has the WriteMostly flag set. It is signified with a 'w'. If the device has failed, the 'p'artial flag has priority. Example ("nosync" raid1 with mismatch_cnt and writemostly): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg Rwi---r-m 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-w 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-- 1 linear 4.00m Example (raid1 with mismatch_cnt, writemostly - but failed drive): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg rwi---r-p 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-p 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-p 1 linear 4.00m A new reportable field has been added for writebehind as well. If write-behind has not been set or the LV is not RAID1, the field will be blank. Example (writebehind is set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- 512 [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor-- Example (writebehind is not set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor--
2013-04-15 22:59:46 +04:00
struct dm_tree_node_raid_params {
const char *raid_type;
uint32_t stripes;
uint32_t mirrors;
uint32_t region_size;
uint32_t stripe_size;
/*
* 'rebuilds' and 'writemostly' are bitfields that signify
* which devices in the array are to be rebuilt or marked
* writemostly. The kernel supports up to 253 legs.
* We limit ourselves by choosing a lower value
* for DEFAULT_RAID{1}_MAX_IMAGES in defaults.h.
*/
uint64_t rebuilds;
uint64_t writemostly;
uint32_t writebehind; /* I/Os (kernel default COUNTER_MAX / 2) */
uint32_t sync_daemon_sleep; /* ms (kernel default = 5sec) */
uint32_t max_recovery_rate; /* kB/sec/disk */
uint32_t min_recovery_rate; /* kB/sec/disk */
uint32_t stripe_cache; /* sectors */
uint64_t flags; /* [no]sync */
uint32_t reserved2;
};
/*
* Version 2 of above node raid params struct to keeep API compatibility.
*
* Extended for more than 64 legs (max 253 in the MD kernel runtime!),
* delta_disks for disk add/remove reshaping,
* data_offset for out-of-place reshaping
* and data_copies for odd number of raid10 legs.
*/
#define RAID_BITMAP_SIZE 4 /* 4 * 64 bit elements in rebuilds/writemostly arrays */
struct dm_tree_node_raid_params_v2 {
const char *raid_type;
uint32_t stripes;
uint32_t mirrors;
uint32_t region_size;
uint32_t stripe_size;
lvconvert: add infrastructure for RaidLV reshaping support In order to support striped raid5/6/10 LV reshaping (change of LV type, stripesize or number of legs), this patch introduces infrastructure prerequisites to be used by raid_manip.c extensions in followup patches. This base is needed for allocation of out-of-place reshape space required by the MD raid personalities to avoid writing over data in-place when reading off the current RAID layout or number of legs and writing out the new layout or to a different number of legs (i.e. restripe) Changes: - add members reshape_len to 'struct lv_segment' to store out-of-place reshape length per component rimage - add member data_copies to struct lv_segment to support more than 2 raid10 data copies - make alloc_lv_segment() aware of both reshape_len and data_copies - adjust all alloc_lv_segment() callers to the new API - add functions to retrieve the current data offset (needed for out-of-place reshaping space allocation) and the devices count from the kernel - make libdm deptree code aware of reshape_len - add LV flags for disk add/remove reshaping - support import/export of the new 'struct lv_segment' members - enhance lv_extend/_lv_reduce to cope with reshape_len - add seg_is_*/segtype_is_* macros related to reshaping - add target version check for reshaping - grow rebuilds/writemostly bitmaps to 246 bit to support kernel maximal - enhance libdm deptree code to support data_offset (out-of-place reshaping) and delta_disk (legs add/remove reshaping) target arguments Related: rhbz834579 Related: rhbz1191935 Related: rhbz1191978
2017-02-24 02:50:00 +03:00
int delta_disks; /* +/- number of disks to add/remove (reshaping) */
int data_offset; /* data offset to set (out-of-place reshaping) */
RAID: Add writemostly/writebehind support for RAID1 'lvchange' is used to alter a RAID 1 logical volume's write-mostly and write-behind characteristics. The '--writemostly' parameter takes a PV as an argument with an optional trailing character to specify whether to set ('y'), unset ('n'), or toggle ('t') the value. If no trailing character is given, it will set the flag. Synopsis: lvchange [--writemostly <PV>:{t|y|n}] [--writebehind <count>] vg/lv Example: lvchange --writemostly /dev/sdb1:y --writebehind 512 vg/raid1_lv The last character in the 'lv_attr' field is used to show whether a device has the WriteMostly flag set. It is signified with a 'w'. If the device has failed, the 'p'artial flag has priority. Example ("nosync" raid1 with mismatch_cnt and writemostly): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg Rwi---r-m 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-w 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-- 1 linear 4.00m Example (raid1 with mismatch_cnt, writemostly - but failed drive): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg rwi---r-p 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-p 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-p 1 linear 4.00m A new reportable field has been added for writebehind as well. If write-behind has not been set or the LV is not RAID1, the field will be blank. Example (writebehind is set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- 512 [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor-- Example (writebehind is not set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor--
2013-04-15 22:59:46 +04:00
/*
* 'rebuilds' and 'writemostly' are bitfields that signify
* which devices in the array are to be rebuilt or marked
lvconvert: add infrastructure for RaidLV reshaping support In order to support striped raid5/6/10 LV reshaping (change of LV type, stripesize or number of legs), this patch introduces infrastructure prerequisites to be used by raid_manip.c extensions in followup patches. This base is needed for allocation of out-of-place reshape space required by the MD raid personalities to avoid writing over data in-place when reading off the current RAID layout or number of legs and writing out the new layout or to a different number of legs (i.e. restripe) Changes: - add members reshape_len to 'struct lv_segment' to store out-of-place reshape length per component rimage - add member data_copies to struct lv_segment to support more than 2 raid10 data copies - make alloc_lv_segment() aware of both reshape_len and data_copies - adjust all alloc_lv_segment() callers to the new API - add functions to retrieve the current data offset (needed for out-of-place reshaping space allocation) and the devices count from the kernel - make libdm deptree code aware of reshape_len - add LV flags for disk add/remove reshaping - support import/export of the new 'struct lv_segment' members - enhance lv_extend/_lv_reduce to cope with reshape_len - add seg_is_*/segtype_is_* macros related to reshaping - add target version check for reshaping - grow rebuilds/writemostly bitmaps to 246 bit to support kernel maximal - enhance libdm deptree code to support data_offset (out-of-place reshaping) and delta_disk (legs add/remove reshaping) target arguments Related: rhbz834579 Related: rhbz1191935 Related: rhbz1191978
2017-02-24 02:50:00 +03:00
* writemostly. The kernel supports up to 253 legs.
* We limit ourselvs by choosing a lower value
* for DEFAULT_RAID_MAX_IMAGES.
RAID: Add writemostly/writebehind support for RAID1 'lvchange' is used to alter a RAID 1 logical volume's write-mostly and write-behind characteristics. The '--writemostly' parameter takes a PV as an argument with an optional trailing character to specify whether to set ('y'), unset ('n'), or toggle ('t') the value. If no trailing character is given, it will set the flag. Synopsis: lvchange [--writemostly <PV>:{t|y|n}] [--writebehind <count>] vg/lv Example: lvchange --writemostly /dev/sdb1:y --writebehind 512 vg/raid1_lv The last character in the 'lv_attr' field is used to show whether a device has the WriteMostly flag set. It is signified with a 'w'. If the device has failed, the 'p'artial flag has priority. Example ("nosync" raid1 with mismatch_cnt and writemostly): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg Rwi---r-m 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-w 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-- 1 linear 4.00m Example (raid1 with mismatch_cnt, writemostly - but failed drive): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg rwi---r-p 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-p 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-p 1 linear 4.00m A new reportable field has been added for writebehind as well. If write-behind has not been set or the LV is not RAID1, the field will be blank. Example (writebehind is set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- 512 [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor-- Example (writebehind is not set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor--
2013-04-15 22:59:46 +04:00
*/
lvconvert: add infrastructure for RaidLV reshaping support In order to support striped raid5/6/10 LV reshaping (change of LV type, stripesize or number of legs), this patch introduces infrastructure prerequisites to be used by raid_manip.c extensions in followup patches. This base is needed for allocation of out-of-place reshape space required by the MD raid personalities to avoid writing over data in-place when reading off the current RAID layout or number of legs and writing out the new layout or to a different number of legs (i.e. restripe) Changes: - add members reshape_len to 'struct lv_segment' to store out-of-place reshape length per component rimage - add member data_copies to struct lv_segment to support more than 2 raid10 data copies - make alloc_lv_segment() aware of both reshape_len and data_copies - adjust all alloc_lv_segment() callers to the new API - add functions to retrieve the current data offset (needed for out-of-place reshaping space allocation) and the devices count from the kernel - make libdm deptree code aware of reshape_len - add LV flags for disk add/remove reshaping - support import/export of the new 'struct lv_segment' members - enhance lv_extend/_lv_reduce to cope with reshape_len - add seg_is_*/segtype_is_* macros related to reshaping - add target version check for reshaping - grow rebuilds/writemostly bitmaps to 246 bit to support kernel maximal - enhance libdm deptree code to support data_offset (out-of-place reshaping) and delta_disk (legs add/remove reshaping) target arguments Related: rhbz834579 Related: rhbz1191935 Related: rhbz1191978
2017-02-24 02:50:00 +03:00
uint64_t rebuilds[RAID_BITMAP_SIZE];
uint64_t writemostly[RAID_BITMAP_SIZE];
uint32_t writebehind; /* I/Os (kernel default COUNTER_MAX / 2) */
uint32_t data_copies; /* RAID # of data copies */
RAID: Add writemostly/writebehind support for RAID1 'lvchange' is used to alter a RAID 1 logical volume's write-mostly and write-behind characteristics. The '--writemostly' parameter takes a PV as an argument with an optional trailing character to specify whether to set ('y'), unset ('n'), or toggle ('t') the value. If no trailing character is given, it will set the flag. Synopsis: lvchange [--writemostly <PV>:{t|y|n}] [--writebehind <count>] vg/lv Example: lvchange --writemostly /dev/sdb1:y --writebehind 512 vg/raid1_lv The last character in the 'lv_attr' field is used to show whether a device has the WriteMostly flag set. It is signified with a 'w'. If the device has failed, the 'p'artial flag has priority. Example ("nosync" raid1 with mismatch_cnt and writemostly): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg Rwi---r-m 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-w 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-- 1 linear 4.00m Example (raid1 with mismatch_cnt, writemostly - but failed drive): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg rwi---r-p 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-p 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-p 1 linear 4.00m A new reportable field has been added for writebehind as well. If write-behind has not been set or the LV is not RAID1, the field will be blank. Example (writebehind is set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- 512 [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor-- Example (writebehind is not set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor--
2013-04-15 22:59:46 +04:00
uint32_t sync_daemon_sleep; /* ms (kernel default = 5sec) */
uint32_t max_recovery_rate; /* kB/sec/disk */
uint32_t min_recovery_rate; /* kB/sec/disk */
uint32_t stripe_cache; /* sectors */
uint64_t flags; /* [no]sync */
};
int dm_tree_node_add_raid_target_with_params(struct dm_tree_node *node,
uint64_t size,
const struct dm_tree_node_raid_params *p);
RAID: Add writemostly/writebehind support for RAID1 'lvchange' is used to alter a RAID 1 logical volume's write-mostly and write-behind characteristics. The '--writemostly' parameter takes a PV as an argument with an optional trailing character to specify whether to set ('y'), unset ('n'), or toggle ('t') the value. If no trailing character is given, it will set the flag. Synopsis: lvchange [--writemostly <PV>:{t|y|n}] [--writebehind <count>] vg/lv Example: lvchange --writemostly /dev/sdb1:y --writebehind 512 vg/raid1_lv The last character in the 'lv_attr' field is used to show whether a device has the WriteMostly flag set. It is signified with a 'w'. If the device has failed, the 'p'artial flag has priority. Example ("nosync" raid1 with mismatch_cnt and writemostly): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg Rwi---r-m 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-w 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-- 1 linear 4.00m Example (raid1 with mismatch_cnt, writemostly - but failed drive): [~]# lvs -a --segment vg LV VG Attr #Str Type SSize raid1 vg rwi---r-p 2 raid1 500.00m [raid1_rimage_0] vg Iwi---r-- 1 linear 500.00m [raid1_rimage_1] vg Iwi---r-p 1 linear 500.00m [raid1_rmeta_0] vg ewi---r-- 1 linear 4.00m [raid1_rmeta_1] vg ewi---r-p 1 linear 4.00m A new reportable field has been added for writebehind as well. If write-behind has not been set or the LV is not RAID1, the field will be blank. Example (writebehind is set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- 512 [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor-- Example (writebehind is not set): [~]# lvs -a -o name,attr,writebehind vg LV Attr WBehind lv rwi-a-r-- [lv_rimage_0] iwi-aor-w [lv_rimage_1] iwi-aor-- [lv_rmeta_0] ewi-aor-- [lv_rmeta_1] ewi-aor--
2013-04-15 22:59:46 +04:00
/* Version 2 API function taking dm_tree_node_raid_params_v2 for aforementioned extensions. */
int dm_tree_node_add_raid_target_with_params_v2(struct dm_tree_node *node,
uint64_t size,
const struct dm_tree_node_raid_params_v2 *p);
/* Cache feature_flags */
#define DM_CACHE_FEATURE_WRITEBACK 0x00000001
#define DM_CACHE_FEATURE_WRITETHROUGH 0x00000002
#define DM_CACHE_FEATURE_PASSTHROUGH 0x00000004
#define DM_CACHE_FEATURE_METADATA2 0x00000008 /* cache v1.10 */
#define DM_CACHE_FEATURE_NO_DISCARD_PASSDOWN 0x00000010
struct dm_config_node;
/*
* Use for passing cache policy and all its args e.g.:
*
* policy_settings {
* migration_threshold=2048
* sequention_threashold=100
* ...
* }
*
* For policy without any parameters use NULL.
*/
int dm_tree_node_add_cache_target(struct dm_tree_node *node,
uint64_t size,
uint64_t feature_flags, /* DM_CACHE_FEATURE_* */
const char *metadata_uuid,
const char *data_uuid,
const char *origin_uuid,
const char *policy_name,
const struct dm_config_node *policy_settings,
uint32_t data_block_size);
/*
2014-11-11 17:13:00 +03:00
* FIXME Add individual cache policy pairs <key> = value, like:
* int dm_tree_node_add_cache_policy_arg(struct dm_tree_node *dnode,
* const char *key, uint64_t value);
*/
/*
* 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))
/*
* Max supported size for thin pool metadata device (17112760320 bytes)
* Limitation is hardcoded into the kernel and bigger device size
* is not accepted.
* drivers/md/dm-thin-metadata.h THIN_METADATA_MAX_SECTORS
*/
#define DM_THIN_MAX_METADATA_SIZE (UINT64_C(255) * (1 << 14) * (4096 / (1 << 9)) - 256 * 1024)
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);
/*
* Set error if no space, instead of queueing for thin pool.
*/
int dm_tree_node_set_thin_pool_error_if_no_space(struct dm_tree_node *node,
unsigned error_if_no_space);
/* Start thin pool with metadata in read-only mode */
int dm_tree_node_set_thin_pool_read_only(struct dm_tree_node *node,
unsigned read_only);
/*
* 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.
2011-10-06 18:45:40 +04:00
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);
2005-11-09 17:10:50 +03:00
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.
2011-08-18 23:38:26 +04:00
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);
2005-10-17 02:57:20 +04:00
/*****************************************************************************
* Library functions
*****************************************************************************/
2005-11-09 17:10:50 +03:00
/*******************
* Memory management
*******************/
/*
* Never use these functions directly - use the macros following instead.
*/
void *dm_malloc_wrapper(size_t s, const char *file, int line)
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__attribute__((__malloc__)) __attribute__((__warn_unused_result__));
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void *dm_malloc_aligned_wrapper(size_t s, size_t a, const char *file, int line)
__attribute__((__malloc__)) __attribute__((__warn_unused_result__));
void *dm_zalloc_wrapper(size_t s, const char *file, int line)
2013-02-04 23:29:59 +04:00
__attribute__((__malloc__)) __attribute__((__warn_unused_result__));
void *dm_realloc_wrapper(void *p, unsigned int s, const char *file, int line)
__attribute__((__warn_unused_result__));
void dm_free_wrapper(void *ptr);
char *dm_strdup_wrapper(const char *s, const char *file, int line)
__attribute__((__warn_unused_result__));
int dm_dump_memory_wrapper(void);
void dm_bounds_check_wrapper(void);
#define dm_malloc(s) dm_malloc_wrapper((s), __FILE__, __LINE__)
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#define dm_malloc_aligned(s, a) dm_malloc_aligned_wrapper((s), (a), __FILE__, __LINE__)
#define dm_zalloc(s) dm_zalloc_wrapper((s), __FILE__, __LINE__)
#define dm_strdup(s) dm_strdup_wrapper((s), __FILE__, __LINE__)
#define dm_free(p) dm_free_wrapper(p)
#define dm_realloc(p, s) dm_realloc_wrapper((p), (s), __FILE__, __LINE__)
#define dm_dump_memory() dm_dump_memory_wrapper()
#define dm_bounds_check() dm_bounds_check_wrapper()
2005-11-10 19:33:04 +03:00
2005-10-17 02:57:20 +04:00
/*
* 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).
2005-10-17 02:57:20 +04:00
*/
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__));
2005-10-17 02:57:20 +04:00
/******************
* 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);
int dm_bit_get_last(dm_bitset_t bs);
int dm_bit_get_prev(dm_bitset_t bs, int last_bit);
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#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, ((*(bs2) / DM_BITS_PER_INT) + 1) * sizeof(int))
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/*
* Parse a string representation of a bitset into a dm_bitset_t. The
* notation used is identical to the kernel bitmap parser (cpuset etc.)
* and supports both lists ("1,2,3") and ranges ("1-2,5-8"). If the mem
* parameter is NULL memory for the bitset will be allocated using
* dm_malloc(). Otherwise the bitset will be allocated using the supplied
* dm_pool.
*/
dm_bitset_t dm_bitset_parse_list(const char *str, struct dm_pool *mem,
size_t min_num_bits);
/* 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,
2014-02-14 23:46:55 +04:00
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);
/*
* dm_hash_insert() replaces the value of an existing
* entry with a matching key if one exists. Otherwise
* it adds a new entry.
*
* dm_hash_insert_with_val() inserts a new entry if
* another entry with the same key already exists.
* val_len is the size of the data being inserted.
*
* If two entries with the same key exist,
* (added using dm_hash_insert_allow_multiple), then:
* . dm_hash_lookup() returns the first one it finds, and
* dm_hash_lookup_with_val() returns the one with a matching
* val_len/val.
* . dm_hash_remove() removes the first one it finds, and
* dm_hash_remove_with_val() removes the one with a matching
* val_len/val.
*
* If a single entry with a given key exists, and it has
* zero val_len, then:
* . dm_hash_lookup() returns it
* . dm_hash_lookup_with_val(val_len=0) returns it
* . dm_hash_remove() removes it
* . dm_hash_remove_with_val(val_len=0) removes it
*
* dm_hash_lookup_with_count() is a single call that will
* both lookup a key's value and check if there is more
* than one entry with the given key.
*
* (It is not meant to retrieve all the entries with the
* given key. In the common case where a single entry exists
* for the key, it is useful to have a single call that will
* both look up the value and indicate if multiple values
* exist for the key.)
*
* dm_hash_lookup_with_count:
* . If no entries exist, the function returns NULL, and
* the count is set to 0.
* . If only one entry exists, the value of that entry is
* returned and count is set to 1.
* . If N entries exists, the value of the first entry is
* returned and count is set to N.
*/
void *dm_hash_lookup_with_val(struct dm_hash_table *t, const char *key,
const void *val, uint32_t val_len);
void dm_hash_remove_with_val(struct dm_hash_table *t, const char *key,
const void *val, uint32_t val_len);
int dm_hash_insert_allow_multiple(struct dm_hash_table *t, const char *key,
const void *val, uint32_t val_len);
void *dm_hash_lookup_with_count(struct dm_hash_table *t, const char *key, int *count);
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#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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2008-11-04 17:57:06 +03:00
/****************
* 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;
};
/*
* String list.
*/
struct dm_str_list {
struct dm_list list;
const char *str;
};
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/*
* Initialise a list before use.
* The list head's next and previous pointers point back to itself.
*/
#define DM_LIST_HEAD_INIT(name) { &(name), &(name) }
#define DM_LIST_INIT(name) struct dm_list name = DM_LIST_HEAD_INIT(name)
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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);
/*
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* Given the address v of an instance of 'struct dm_list' called 'head'
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* 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)
/*
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* Set v to each element in a list in turn, starting from the element
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* 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)
/*
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* Walk a list backwards, setting 'v' in turn to the containing structure
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* 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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/*
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* Walk a list backwards, setting 'v' in turn to the containing structure
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* 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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/*
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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);
/*
* Recognize unit specifier in the 'units' arg and return a factor
* representing that unit. If the 'units' contains a prefix with digits,
* the 'units' is considered to be a custom unit.
*
* Also, set 'unit_type' output arg to the character that represents
* the unit specified. The 'unit_type' character equals to the unit
* character itself recognized in the 'units' arg for canonical units.
* Otherwise, the 'unit_type' character is set to 'U' for custom unit.
*
* An example for k/K canonical units and 8k/8K custom units:
*
* units unit_type return value (factor)
* k k 1024
* K K 1000
* 8k U 1024*8
* 8K U 1000*8
* etc...
*
* Recognized units:
*
* h/H - human readable (returns 1 for both)
* b/B - byte (returns 1 for both)
* s/S - sector (returns 512 for both)
* k/K - kilo (returns 1024/1000 respectively)
* m/M - mega (returns 1024^2/1000^2 respectively)
* g/G - giga (returns 1024^3/1000^3 respectively)
* t/T - tera (returns 1024^4/1000^4 respectively)
* p/P - peta (returns 1024^5/1000^5 respectively)
* e/E - exa (returns 1024^6/1000^6 respectively)
*
* Only one units character is allowed in the 'units' arg
* if strict mode is enabled by 'strict' arg.
*
* The 'endptr' output arg, if not NULL, saves the pointer
* in the 'units' string which follows the unit specifier
* recognized (IOW the position where the parsing of the
* unit specifier stopped).
*
* Returns the unit factor or 0 if no unit is recognized.
*/
uint64_t dm_units_to_factor(const char *units, char *unit_type,
int strict, const char **endptr);
/*
* Type of unit specifier used by dm_size_to_string().
*/
typedef enum {
DM_SIZE_LONG = 0, /* Megabyte */
DM_SIZE_SHORT = 1, /* MB or MiB */
DM_SIZE_UNIT = 2 /* M or m */
} dm_size_suffix_t;
/*
* Convert a size (in 512-byte sectors) into a printable string using units of unit_type.
* An upper-case unit_type indicates output units based on powers of 1000 are
* required; a lower-case unit_type indicates powers of 1024.
* For correct operation, unit_factor must be one of:
* 0 - the correct value will be calculated internally;
* or the output from dm_units_to_factor() corresponding to unit_type;
* or 'u' or 'U', an arbitrary number of bytes to use as the power base.
* Set include_suffix to 1 to include a suffix of suffix_type.
* Set use_si_units to 0 for suffixes that don't distinguish between 1000 and 1024.
* Set use_si_units to 1 for a suffix that does distinguish.
*/
const char *dm_size_to_string(struct dm_pool *mem, uint64_t size,
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char unit_type, int use_si_units,
uint64_t unit_factor, int include_suffix,
dm_size_suffix_t suffix_type);
/**************************
* 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.
2007-01-12 00:54:53 +03:00
*/
int dm_asprintf(char **buf, const char *format, ...)
__attribute__ ((format(printf, 2, 3)));
int dm_vasprintf(char **buf, const char *format, va_list ap)
__attribute__ ((format(printf, 2, 0)));
2007-01-12 00:54:53 +03:00
/*
* 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);
2007-04-27 22:40:23 +04:00
/*********************
* 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.
2010-07-21 16:09:12 +04:00
*
* This function must be called before any matching is done.
*/
uint32_t dm_regex_fingerprint(struct dm_regex *regex);
/******************
* percent handling
******************/
/*
* A fixed-point representation of percent values. One percent equals to
* DM_PERCENT_1 as defined below. Values that are not multiples of DM_PERCENT_1
* represent fractions, with precision of 1/1000000 of a percent. See
* dm_percent_to_float for a conversion to a floating-point representation.
*
* You should always use dm_make_percent when building dm_percent_t values. The
* implementation of dm_make_percent is biased towards the middle: it ensures that
* the result is DM_PERCENT_0 or DM_PERCENT_100 if and only if this is the actual
* value -- it never rounds any intermediate value (> 0 or < 100) to either 0
* or 100.
*/
#define DM_PERCENT_CHAR '%'
typedef enum {
DM_PERCENT_0 = 0,
DM_PERCENT_1 = 1000000,
DM_PERCENT_100 = 100 * DM_PERCENT_1,
DM_PERCENT_INVALID = -1,
DM_PERCENT_FAILED = -2
} dm_percent_range_t;
typedef int32_t dm_percent_t;
float dm_percent_to_float(dm_percent_t percent);
/*
* Return adjusted/rounded float for better percent value printing.
* Function ensures for given precision of digits:
* 100.0% returns only when the value is DM_PERCENT_100
* for close smaller values rounds to nearest smaller value
* 0.0% returns only for value DM_PERCENT_0
* for close bigger values rounds to nearest bigger value
* In all other cases returns same value as dm_percent_to_float()
*/
float dm_percent_to_round_float(dm_percent_t percent, unsigned digits);
dm_percent_t dm_make_percent(uint64_t numerator, uint64_t denominator);
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/********************
* timestamp handling
********************/
/*
* Create a dm_timestamp object to use with dm_timestamp_get.
*/
struct dm_timestamp *dm_timestamp_alloc(void);
/*
* Update dm_timestamp object to represent the current time.
*/
int dm_timestamp_get(struct dm_timestamp *ts);
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/*
* Copy a timestamp from ts_old to ts_new.
*/
void dm_timestamp_copy(struct dm_timestamp *ts_new, struct dm_timestamp *ts_old);
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/*
* Compare two timestamps.
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*
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* Return: -1 if ts1 is less than ts2
* 0 if ts1 is equal to ts2
* 1 if ts1 is greater than ts2
*/
int dm_timestamp_compare(struct dm_timestamp *ts1, struct dm_timestamp *ts2);
/*
* Return the absolute difference in nanoseconds between
* the dm_timestamp objects ts1 and ts2.
*
* Callers that need to know whether ts1 is before, equal to, or after ts2
* in addition to the magnitude should use dm_timestamp_compare.
*/
uint64_t dm_timestamp_delta(struct dm_timestamp *ts1, struct dm_timestamp *ts2);
/*
* Destroy a dm_timestamp object.
*/
void dm_timestamp_destroy(struct dm_timestamp *ts);
/*********************
* reporting functions
*********************/
struct dm_report_object_type {
uint32_t id; /* Powers of 2 */
const char *desc;
const char *prefix; /* field id string prefix (optional) */
/* FIXME: convert to proper usage of const pointers here */
void *(*data_fn)(void *object); /* callback from report_object() */
};
struct dm_report_field;
/*
* dm_report_field_type flags
*/
#define DM_REPORT_FIELD_MASK 0x00000FFF
#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 0x00000FF0
#define DM_REPORT_FIELD_TYPE_NONE 0x00000000
#define DM_REPORT_FIELD_TYPE_STRING 0x00000010
#define DM_REPORT_FIELD_TYPE_NUMBER 0x00000020
#define DM_REPORT_FIELD_TYPE_SIZE 0x00000040
#define DM_REPORT_FIELD_TYPE_PERCENT 0x00000080
#define DM_REPORT_FIELD_TYPE_STRING_LIST 0x00000100
report: add support for time (basic) This patch adds support for time values used in reporting fields. The raw values are always stored as number of seconds since epoch. The support that comes with this patch is the basic one which allows only for recognition of strictly formatted date and time in selection criteria (the format follows a subset of formats defined by ISO 8601): date time timezone date: YYYY-MM-DD (or shortly YYYYMMDD) YYYY-MM (shortly YYYYMM), auto DD=1 YYYY, auto MM=01 and DD=01 time: hh:mm:ss (or shortly hhmmss) hh:mm (or shortly hhmm), auto ss=0 hh (or shortly hh), auto mm=0, auto ss=0 timezone (always with + or - sign): +hh:mm or -hh:mm (or shortly +hhmm or -hhmm) +hh or -hh Or directly the time (number of seconds) since Epoch (1970-01-01 00:00:00 UTC) when the number value is prefixed by "@": @number_of_seconds_since_epoch This patch also adds aliases for comparison operators used together with time values which are more intuitive to use: since (as alias for >=) after (as alias for >) until (as alias for <=) before (as alias for <) For example: $ lvmconfig --type full report/time_format time_format="%Y-%m-%d %T %z %Z [%s]" $ lvs -o name,time vg LV Time lvol0 2015-06-28 21:25:41 +0200 CEST [1435519541] lvol1 2015-06-30 03:25:43 +0200 CEST [1435627543] lvol2 2015-04-26 14:52:20 +0200 CEST [1430052740] lvol3 2015-06-30 14:52:23 +0200 CEST [1435668743] $ lvs vg -o name,time -S 'time since "2015-04-26 15:00" && time until "2015-06-30"' LV Time lvol0 2015-06-28 21:25:41 +0200 CEST [1435519541] lvol1 2015-06-30 03:25:43 +0200 CEST [1435627543] lvol3 2015-06-30 14:52:23 +0200 CEST [1435668743] $ lvs vg -o name,time -S 'time since "2015-04-26 15:00" && time until "2015-06-30 6:00"' LV Time lvol0 2015-06-28 21:25:41 +0200 CEST [1435519541] lvol1 2015-06-30 03:25:43 +0200 CEST [1435627543] $ lvs vg -o name,time -S 'time since @1435519541' LV Time lvol0 2015-06-28 21:25:41 +0200 CEST [1435519541] lvol1 2015-06-30 03:25:43 +0200 CEST [1435627543] lvol3 2015-06-30 14:52:23 +0200 CEST [1435668743] This is basic time recognition support that is directly a part of libdevmapper. Recognition of more free-form expressions will be a part of subsequent patches.
2015-05-21 16:19:03 +03:00
#define DM_REPORT_FIELD_TYPE_TIME 0x00000200
/* For use with reserved values only! */
#define DM_REPORT_FIELD_RESERVED_VALUE_MASK 0x0000000F
#define DM_REPORT_FIELD_RESERVED_VALUE_NAMED 0x00000001 /* only named value, less strict form of reservation */
#define DM_REPORT_FIELD_RESERVED_VALUE_RANGE 0x00000002 /* value is range - low and high value defined */
report: add infrastructure to recognize fuzzy reserved names and returning dynamic reserved values With fuzzy names we mean the names for which it's hard or even impossible to enumerate all possible variations of the name - the name needs to be evaluated. An example of fuzzy name is a name which has a base (substring) which matches and it can contain arbitrary variations around this base. We can cover human language better with fuzzy names as people may use several different names (or sentences) to denote the same thing. With dynamic values we mean the values which are not constants and they need to be evaluated in runtime. An example of dynamic value is a value which depends on current system state (e.g. time, current configuration or any other state which may change and it needs runtime evaluation). There's a handler that can be registered with reporting/selection using dm_report_reserved_handler instance. This is a central point in which the computation/evaluation happens when processing reserved values. Currently, there are two actions declared: DM_REPORT_RESERVED_PARSE_FUZZY_NAME (translates fuzzy name into canonical name) DM_REPORT_RESERVED_GET_DYNAMIC_VALUE (gets value for canonical name) The handler is then registered as value in struct dm_report_reserved_value (see explaining comments besided the struct dm_report_reserved_value in libdevmapper.h). Also, this patch provides support for simple caching of values used during report/selection via dm_report_value_cache_{set,get}. This is supposed to be used mainly in the dm_report_reserved_handler instances to save values among calls so all the handler calls work with the same base value used in computation/evaluation and/or possibly to save resources if the evaluation is more time-consuming. The cache is attached to the dm_report handle and so the cache is dropped one dm_report is dropped.
2015-05-19 14:01:48 +03:00
#define DM_REPORT_FIELD_RESERVED_VALUE_DYNAMIC_VALUE 0x00000004 /* value is computed in runtime */
#define DM_REPORT_FIELD_RESERVED_VALUE_FUZZY_NAMES 0x00000008 /* value names are recognized in runtime */
#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 */
};
/*
* Per-field reserved value.
*/
struct dm_report_field_reserved_value {
/* field_num is the position of the field in 'fields'
array passed to dm_report_init_with_selection */
uint32_t field_num;
/* the value is of the same type as the field
identified by field_num */
const void *value;
};
/*
report: add infrastructure to recognize fuzzy reserved names and returning dynamic reserved values With fuzzy names we mean the names for which it's hard or even impossible to enumerate all possible variations of the name - the name needs to be evaluated. An example of fuzzy name is a name which has a base (substring) which matches and it can contain arbitrary variations around this base. We can cover human language better with fuzzy names as people may use several different names (or sentences) to denote the same thing. With dynamic values we mean the values which are not constants and they need to be evaluated in runtime. An example of dynamic value is a value which depends on current system state (e.g. time, current configuration or any other state which may change and it needs runtime evaluation). There's a handler that can be registered with reporting/selection using dm_report_reserved_handler instance. This is a central point in which the computation/evaluation happens when processing reserved values. Currently, there are two actions declared: DM_REPORT_RESERVED_PARSE_FUZZY_NAME (translates fuzzy name into canonical name) DM_REPORT_RESERVED_GET_DYNAMIC_VALUE (gets value for canonical name) The handler is then registered as value in struct dm_report_reserved_value (see explaining comments besided the struct dm_report_reserved_value in libdevmapper.h). Also, this patch provides support for simple caching of values used during report/selection via dm_report_value_cache_{set,get}. This is supposed to be used mainly in the dm_report_reserved_handler instances to save values among calls so all the handler calls work with the same base value used in computation/evaluation and/or possibly to save resources if the evaluation is more time-consuming. The cache is attached to the dm_report handle and so the cache is dropped one dm_report is dropped.
2015-05-19 14:01:48 +03:00
* Reserved value is a 'value' that is used directly if any of the 'names' is hit
* or in case of fuzzy names, if such fuzzy name matches.
*
* If type is any of DM_REPORT_FIELD_TYPE_*, the reserved value is recognized
* for all fields of that type.
*
* If type is DM_REPORT_FIELD_TYPE_NONE, the reserved value is recognized
* for the exact field specified - hence the type of the value is automatically
* the same as the type of the field itself.
*
* The array of reserved values is used to initialize reporting with
* selection enabled (see also dm_report_init_with_selection function).
*/
report: select: add support for reserved value recognition in report selection string - add struct dm_report_reserved_value Make dm_report_init_with_selection to accept an argument with an array of reserved values where each element contains a triple: {dm report field type, reserved value, array of strings representing this value} When the selection is parsed, we always check whether a string representation of some reserved value is not hit and if it is, we use the reserved value assigned for this string instead of trying to parse it as a value of certain field type. This makes it possible to define selections like: ... --select lv_major=undefined (or -1 or unknown or undef or whatever string representations are registered for this reserved value in the future) ... --select lv_read_ahead=auto ... --select vg_mda_copies=unmanaged With this, each time the field value of certain type is hit and when we compare it with the selection, we use the proper value for comparison. For now, register these reserved values that are used at the moment (also more descriptive names are used for the values): const uint64_t _reserved_number_undef_64 = UINT64_MAX; const uint64_t _reserved_number_unmanaged_64 = UINT64_MAX - 1; const uint64_t _reserved_size_auto_64 = UINT64_MAX; { {DM_REPORT_FIELD_TYPE_NUMBER, _reserved_number_undef_64, {"-1", "undefined", "undef", "unknown", NULL}}, {DM_REPORT_FIELD_TYPE_NUMBER, _reserved_number_unmanaged_64, {"unmanaged", NULL}}, {DM_REPORT_FIELD_TYPE_SIZE, _reserved_size_auto_64, {"auto", NULL}}, NULL } Same reserved value of different field types do not collide. All arrays are null-terminated. The list of reserved values is automatically displayed within selection help output: Selection operands ------------------ ... Reserved values --------------- -1, undefined, undef, unknown - Reserved value for undefined numeric value. [number] unmanaged - Reserved value for unmanaged number of metadata copies in VG. [number] auto - Reserved value for size that is automatically calculated. [size] Selection operators ------------------- ...
2014-05-30 17:02:21 +04:00
struct dm_report_reserved_value {
const uint32_t type; /* DM_REPORT_FIELD_RESERVED_VALUE_* and DM_REPORT_FIELD_TYPE_* */
const void *value; /* reserved value:
report: select: add support for reserved value recognition in report selection string - add struct dm_report_reserved_value Make dm_report_init_with_selection to accept an argument with an array of reserved values where each element contains a triple: {dm report field type, reserved value, array of strings representing this value} When the selection is parsed, we always check whether a string representation of some reserved value is not hit and if it is, we use the reserved value assigned for this string instead of trying to parse it as a value of certain field type. This makes it possible to define selections like: ... --select lv_major=undefined (or -1 or unknown or undef or whatever string representations are registered for this reserved value in the future) ... --select lv_read_ahead=auto ... --select vg_mda_copies=unmanaged With this, each time the field value of certain type is hit and when we compare it with the selection, we use the proper value for comparison. For now, register these reserved values that are used at the moment (also more descriptive names are used for the values): const uint64_t _reserved_number_undef_64 = UINT64_MAX; const uint64_t _reserved_number_unmanaged_64 = UINT64_MAX - 1; const uint64_t _reserved_size_auto_64 = UINT64_MAX; { {DM_REPORT_FIELD_TYPE_NUMBER, _reserved_number_undef_64, {"-1", "undefined", "undef", "unknown", NULL}}, {DM_REPORT_FIELD_TYPE_NUMBER, _reserved_number_unmanaged_64, {"unmanaged", NULL}}, {DM_REPORT_FIELD_TYPE_SIZE, _reserved_size_auto_64, {"auto", NULL}}, NULL } Same reserved value of different field types do not collide. All arrays are null-terminated. The list of reserved values is automatically displayed within selection help output: Selection operands ------------------ ... Reserved values --------------- -1, undefined, undef, unknown - Reserved value for undefined numeric value. [number] unmanaged - Reserved value for unmanaged number of metadata copies in VG. [number] auto - Reserved value for size that is automatically calculated. [size] Selection operators ------------------- ...
2014-05-30 17:02:21 +04:00
uint64_t for DM_REPORT_FIELD_TYPE_NUMBER
uint64_t for DM_REPORT_FIELD_TYPE_SIZE (number of 512-byte sectors)
uint64_t for DM_REPORT_FIELD_TYPE_PERCENT
report: add infrastructure to recognize fuzzy reserved names and returning dynamic reserved values With fuzzy names we mean the names for which it's hard or even impossible to enumerate all possible variations of the name - the name needs to be evaluated. An example of fuzzy name is a name which has a base (substring) which matches and it can contain arbitrary variations around this base. We can cover human language better with fuzzy names as people may use several different names (or sentences) to denote the same thing. With dynamic values we mean the values which are not constants and they need to be evaluated in runtime. An example of dynamic value is a value which depends on current system state (e.g. time, current configuration or any other state which may change and it needs runtime evaluation). There's a handler that can be registered with reporting/selection using dm_report_reserved_handler instance. This is a central point in which the computation/evaluation happens when processing reserved values. Currently, there are two actions declared: DM_REPORT_RESERVED_PARSE_FUZZY_NAME (translates fuzzy name into canonical name) DM_REPORT_RESERVED_GET_DYNAMIC_VALUE (gets value for canonical name) The handler is then registered as value in struct dm_report_reserved_value (see explaining comments besided the struct dm_report_reserved_value in libdevmapper.h). Also, this patch provides support for simple caching of values used during report/selection via dm_report_value_cache_{set,get}. This is supposed to be used mainly in the dm_report_reserved_handler instances to save values among calls so all the handler calls work with the same base value used in computation/evaluation and/or possibly to save resources if the evaluation is more time-consuming. The cache is attached to the dm_report handle and so the cache is dropped one dm_report is dropped.
2015-05-19 14:01:48 +03:00
const char* for DM_REPORT_FIELD_TYPE_STRING
struct dm_report_field_reserved_value for DM_REPORT_FIELD_TYPE_NONE
dm_report_reserved_handler* if DM_REPORT_FIELD_RESERVED_VALUE_{DYNAMIC_VALUE,FUZZY_NAMES} is used */
const char **names; /* null-terminated array of static names for this reserved value */
report: select: add support for reserved value recognition in report selection string - add struct dm_report_reserved_value Make dm_report_init_with_selection to accept an argument with an array of reserved values where each element contains a triple: {dm report field type, reserved value, array of strings representing this value} When the selection is parsed, we always check whether a string representation of some reserved value is not hit and if it is, we use the reserved value assigned for this string instead of trying to parse it as a value of certain field type. This makes it possible to define selections like: ... --select lv_major=undefined (or -1 or unknown or undef or whatever string representations are registered for this reserved value in the future) ... --select lv_read_ahead=auto ... --select vg_mda_copies=unmanaged With this, each time the field value of certain type is hit and when we compare it with the selection, we use the proper value for comparison. For now, register these reserved values that are used at the moment (also more descriptive names are used for the values): const uint64_t _reserved_number_undef_64 = UINT64_MAX; const uint64_t _reserved_number_unmanaged_64 = UINT64_MAX - 1; const uint64_t _reserved_size_auto_64 = UINT64_MAX; { {DM_REPORT_FIELD_TYPE_NUMBER, _reserved_number_undef_64, {"-1", "undefined", "undef", "unknown", NULL}}, {DM_REPORT_FIELD_TYPE_NUMBER, _reserved_number_unmanaged_64, {"unmanaged", NULL}}, {DM_REPORT_FIELD_TYPE_SIZE, _reserved_size_auto_64, {"auto", NULL}}, NULL } Same reserved value of different field types do not collide. All arrays are null-terminated. The list of reserved values is automatically displayed within selection help output: Selection operands ------------------ ... Reserved values --------------- -1, undefined, undef, unknown - Reserved value for undefined numeric value. [number] unmanaged - Reserved value for unmanaged number of metadata copies in VG. [number] auto - Reserved value for size that is automatically calculated. [size] Selection operators ------------------- ...
2014-05-30 17:02:21 +04:00
const char *description; /* description of the reserved value */
};
report: add infrastructure to recognize fuzzy reserved names and returning dynamic reserved values With fuzzy names we mean the names for which it's hard or even impossible to enumerate all possible variations of the name - the name needs to be evaluated. An example of fuzzy name is a name which has a base (substring) which matches and it can contain arbitrary variations around this base. We can cover human language better with fuzzy names as people may use several different names (or sentences) to denote the same thing. With dynamic values we mean the values which are not constants and they need to be evaluated in runtime. An example of dynamic value is a value which depends on current system state (e.g. time, current configuration or any other state which may change and it needs runtime evaluation). There's a handler that can be registered with reporting/selection using dm_report_reserved_handler instance. This is a central point in which the computation/evaluation happens when processing reserved values. Currently, there are two actions declared: DM_REPORT_RESERVED_PARSE_FUZZY_NAME (translates fuzzy name into canonical name) DM_REPORT_RESERVED_GET_DYNAMIC_VALUE (gets value for canonical name) The handler is then registered as value in struct dm_report_reserved_value (see explaining comments besided the struct dm_report_reserved_value in libdevmapper.h). Also, this patch provides support for simple caching of values used during report/selection via dm_report_value_cache_{set,get}. This is supposed to be used mainly in the dm_report_reserved_handler instances to save values among calls so all the handler calls work with the same base value used in computation/evaluation and/or possibly to save resources if the evaluation is more time-consuming. The cache is attached to the dm_report handle and so the cache is dropped one dm_report is dropped.
2015-05-19 14:01:48 +03:00
/*
* Available actions for dm_report_reserved_value_handler.
*/
typedef enum {
DM_REPORT_RESERVED_PARSE_FUZZY_NAME,
DM_REPORT_RESERVED_GET_DYNAMIC_VALUE,
} dm_report_reserved_action_t;
/*
* Generic reserved value handler to process reserved value names and/or values.
*
* Actions and their input/output:
*
* DM_REPORT_RESERVED_PARSE_FUZZY_NAME
* data_in: const char *fuzzy_name
* data_out: const char *canonical_name, NULL if fuzzy_name not recognized
*
* DM_REPORT_RESERVED_GET_DYNAMIC_VALUE
* data_in: const char *canonical_name
* data_out: void *value, NULL if canonical_name not recognized
*
* All actions return:
*
* -1 if action not implemented
* 0 on error
* 1 on success
*/
typedef int (*dm_report_reserved_handler) (struct dm_report *rh,
struct dm_pool *mem,
uint32_t field_num,
dm_report_reserved_action_t action,
const void *data_in,
const void **data_out);
/*
* The dm_report_value_cache_{set,get} are helper functions to store and retrieve
* various values used during reporting (dm_report_field_type.report_fn) and/or
* selection processing (dm_report_reserved_handler instances) to avoid
* recalculation of these values or to share values among calls.
*/
int dm_report_value_cache_set(struct dm_report *rh, const char *name, const void *data);
const void *dm_report_value_cache_get(struct dm_report *rh, const char *name);
/*
* 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
2008-06-25 00:16:47 +04:00
#define DM_REPORT_OUTPUT_FIELD_UNQUOTED 0x00000010
2008-06-25 02:53:48 +04:00
#define DM_REPORT_OUTPUT_COLUMNS_AS_ROWS 0x00000020
#define DM_REPORT_OUTPUT_MULTIPLE_TIMES 0x00000040
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);
struct dm_report *dm_report_init_with_selection(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,
const char *selection,
report: select: add support for reserved value recognition in report selection string - add struct dm_report_reserved_value Make dm_report_init_with_selection to accept an argument with an array of reserved values where each element contains a triple: {dm report field type, reserved value, array of strings representing this value} When the selection is parsed, we always check whether a string representation of some reserved value is not hit and if it is, we use the reserved value assigned for this string instead of trying to parse it as a value of certain field type. This makes it possible to define selections like: ... --select lv_major=undefined (or -1 or unknown or undef or whatever string representations are registered for this reserved value in the future) ... --select lv_read_ahead=auto ... --select vg_mda_copies=unmanaged With this, each time the field value of certain type is hit and when we compare it with the selection, we use the proper value for comparison. For now, register these reserved values that are used at the moment (also more descriptive names are used for the values): const uint64_t _reserved_number_undef_64 = UINT64_MAX; const uint64_t _reserved_number_unmanaged_64 = UINT64_MAX - 1; const uint64_t _reserved_size_auto_64 = UINT64_MAX; { {DM_REPORT_FIELD_TYPE_NUMBER, _reserved_number_undef_64, {"-1", "undefined", "undef", "unknown", NULL}}, {DM_REPORT_FIELD_TYPE_NUMBER, _reserved_number_unmanaged_64, {"unmanaged", NULL}}, {DM_REPORT_FIELD_TYPE_SIZE, _reserved_size_auto_64, {"auto", NULL}}, NULL } Same reserved value of different field types do not collide. All arrays are null-terminated. The list of reserved values is automatically displayed within selection help output: Selection operands ------------------ ... Reserved values --------------- -1, undefined, undef, unknown - Reserved value for undefined numeric value. [number] unmanaged - Reserved value for unmanaged number of metadata copies in VG. [number] auto - Reserved value for size that is automatically calculated. [size] Selection operators ------------------- ...
2014-05-30 17:02:21 +04:00
const struct dm_report_reserved_value reserved_values[],
void *private_data);
/*
* Report an object, pass it through the selection criteria if they
* are present and display the result on output if it passes the criteria.
*/
int dm_report_object(struct dm_report *rh, void *object);
/*
* The same as dm_report_object, but display the result on output only if
* 'do_output' arg is set. Also, save the result of selection in 'selected'
* arg if it's not NULL (either 1 if the object passes, otherwise 0).
*/
int dm_report_object_is_selected(struct dm_report *rh, void *object, int do_output, int *selected);
/*
* Compact report output so that if field value is empty for all rows in
* the report, drop the field from output completely (including headers).
* Compact output is applicable only if report is buffered, otherwise
* this function has no effect.
*/
int dm_report_compact_fields(struct dm_report *rh);
/*
* The same as dm_report_compact_fields, but for selected fields only.
* The "fields" arg is comma separated list of field names (the same format
* as used for "output_fields" arg in dm_report_init fn).
*/
int dm_report_compact_given_fields(struct dm_report *rh, const char *fields);
/*
* Returns 1 if there is no data waiting to be output.
*/
int dm_report_is_empty(struct dm_report *rh);
/*
* Destroy report content without doing output.
*/
void dm_report_destroy_rows(struct dm_report *rh);
int dm_report_output(struct dm_report *rh);
/*
* Output the report headings for a columns-based report, even if they
* have already been shown. Useful for repeating reports that wish to
* issue a periodic reminder of the column headings.
*/
int dm_report_column_headings(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);
int dm_report_set_selection(struct dm_report *rh, const char *selection);
/*
* 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_string_list(struct dm_report *rh, struct dm_report_field *field,
const struct dm_list *data, const char *delimiter);
int dm_report_field_string_list_unsorted(struct dm_report *rh, struct dm_report_field *field,
const struct dm_list *data, const char *delimiter);
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);
int dm_report_field_percent(struct dm_report *rh, struct dm_report_field *field,
const dm_percent_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);
libdm: report: introduce dm_report_group This patch introduces DM report group (represented by dm_report_group structure) that is used to group several reports to make a whole. As a whole, all the reports in the group follow the same settings and/or formatting used on output and it controls that the output is properly ordered (e.g. the output from different reports is not interleaved which would break readability and/or syntax of target output format used for the whole group). To support this feature, there are 4 new functions: - dm_report_group_create - dm_report_group_push - dm_report_group_pop - dm_report_group_destroy From the naming used (dm_report_group_push/pop), it's clear the reports are pushed onto a stack. The rule then is that only the report on top of the stack can be reported (that means calling dm_report_output). This way we make sure that the output is not interleaved and provides determinism and control over the output. Different formats may allow or disallow some of the existing report flags controlling output itself (DM_REPORT_OUTPUT_*) to be set or not so once the report is pushed to a group, the grouping code makes sure that all the reports have compatible flags set and then these flags are restored once each report is popped from the report group stack. We also allow to push/pop non-report item in which case such an item creates a structure (e.g. to put several reports together with any opening and/or closing lines needed on output which pose as extra formatting structure besides formatting the reports). The dm_report_group_push function accepts an argument to pass any format-specific data needed (e.g. handle, name, structures passed along while working with reports...). We can call dm_report_output directly anytime we need (with the only restriction that we can call dm_report_output only for the report that is currently on top of the group's stack). Or we don't need to call dm_report_output explicitly in which case all the reports in a stack are reported on output automatically once we call dm_report_group_destroy.
2016-05-02 15:21:05 +03:00
/*
* Report group support.
*/
struct dm_report_group;
typedef enum {
DM_REPORT_GROUP_SINGLE,
DM_REPORT_GROUP_BASIC,
DM_REPORT_GROUP_JSON
libdm: report: introduce dm_report_group This patch introduces DM report group (represented by dm_report_group structure) that is used to group several reports to make a whole. As a whole, all the reports in the group follow the same settings and/or formatting used on output and it controls that the output is properly ordered (e.g. the output from different reports is not interleaved which would break readability and/or syntax of target output format used for the whole group). To support this feature, there are 4 new functions: - dm_report_group_create - dm_report_group_push - dm_report_group_pop - dm_report_group_destroy From the naming used (dm_report_group_push/pop), it's clear the reports are pushed onto a stack. The rule then is that only the report on top of the stack can be reported (that means calling dm_report_output). This way we make sure that the output is not interleaved and provides determinism and control over the output. Different formats may allow or disallow some of the existing report flags controlling output itself (DM_REPORT_OUTPUT_*) to be set or not so once the report is pushed to a group, the grouping code makes sure that all the reports have compatible flags set and then these flags are restored once each report is popped from the report group stack. We also allow to push/pop non-report item in which case such an item creates a structure (e.g. to put several reports together with any opening and/or closing lines needed on output which pose as extra formatting structure besides formatting the reports). The dm_report_group_push function accepts an argument to pass any format-specific data needed (e.g. handle, name, structures passed along while working with reports...). We can call dm_report_output directly anytime we need (with the only restriction that we can call dm_report_output only for the report that is currently on top of the group's stack). Or we don't need to call dm_report_output explicitly in which case all the reports in a stack are reported on output automatically once we call dm_report_group_destroy.
2016-05-02 15:21:05 +03:00
} dm_report_group_type_t;
struct dm_report_group *dm_report_group_create(dm_report_group_type_t type, void *data);
int dm_report_group_push(struct dm_report_group *group, struct dm_report *report, void *data);
int dm_report_group_pop(struct dm_report_group *group);
int dm_report_group_output_and_pop_all(struct dm_report_group *group);
libdm: report: introduce dm_report_group This patch introduces DM report group (represented by dm_report_group structure) that is used to group several reports to make a whole. As a whole, all the reports in the group follow the same settings and/or formatting used on output and it controls that the output is properly ordered (e.g. the output from different reports is not interleaved which would break readability and/or syntax of target output format used for the whole group). To support this feature, there are 4 new functions: - dm_report_group_create - dm_report_group_push - dm_report_group_pop - dm_report_group_destroy From the naming used (dm_report_group_push/pop), it's clear the reports are pushed onto a stack. The rule then is that only the report on top of the stack can be reported (that means calling dm_report_output). This way we make sure that the output is not interleaved and provides determinism and control over the output. Different formats may allow or disallow some of the existing report flags controlling output itself (DM_REPORT_OUTPUT_*) to be set or not so once the report is pushed to a group, the grouping code makes sure that all the reports have compatible flags set and then these flags are restored once each report is popped from the report group stack. We also allow to push/pop non-report item in which case such an item creates a structure (e.g. to put several reports together with any opening and/or closing lines needed on output which pose as extra formatting structure besides formatting the reports). The dm_report_group_push function accepts an argument to pass any format-specific data needed (e.g. handle, name, structures passed along while working with reports...). We can call dm_report_output directly anytime we need (with the only restriction that we can call dm_report_output only for the report that is currently on top of the group's stack). Or we don't need to call dm_report_output explicitly in which case all the reports in a stack are reported on output automatically once we call dm_report_group_destroy.
2016-05-02 15:21:05 +03:00
int dm_report_group_destroy(struct dm_report_group *group);
/*
* Stats counter access methods
*
* Each method returns the corresponding stats counter value from the
* supplied dm_stats handle for the specified region_id and area_id.
* If either region_id or area_id uses one of the special values
* DM_STATS_REGION_CURRENT or DM_STATS_AREA_CURRENT then the region
* or area is selected according to the current state of the dm_stats
* handle's embedded cursor.
*
* Two methods are provided to access counter values: a named function
* for each available counter field and a single function that accepts
* an enum value specifying the required field. New code is encouraged
* to use the enum based interface as calls to the named functions are
* implemented using the enum method internally.
*
* See the kernel documentation for complete descriptions of each
* counter field:
*
* Documentation/device-mapper/statistics.txt
* Documentation/iostats.txt
*
* reads: the number of reads completed
* reads_merged: the number of reads merged
* read_sectors: the number of sectors read
* read_nsecs: the number of nanoseconds spent reading
* writes: the number of writes completed
* writes_merged: the number of writes merged
* write_sectors: the number of sectors written
* write_nsecs: the number of nanoseconds spent writing
* io_in_progress: the number of I/Os currently in progress
* io_nsecs: the number of nanoseconds spent doing I/Os
* weighted_io_nsecs: the weighted number of nanoseconds spent doing I/Os
* total_read_nsecs: the total time spent reading in nanoseconds
* total_write_nsecs: the total time spent writing in nanoseconds
*/
#define DM_STATS_REGION_CURRENT UINT64_MAX
#define DM_STATS_AREA_CURRENT UINT64_MAX
typedef enum {
DM_STATS_READS_COUNT,
DM_STATS_READS_MERGED_COUNT,
DM_STATS_READ_SECTORS_COUNT,
DM_STATS_READ_NSECS,
DM_STATS_WRITES_COUNT,
DM_STATS_WRITES_MERGED_COUNT,
DM_STATS_WRITE_SECTORS_COUNT,
DM_STATS_WRITE_NSECS,
DM_STATS_IO_IN_PROGRESS_COUNT,
DM_STATS_IO_NSECS,
DM_STATS_WEIGHTED_IO_NSECS,
DM_STATS_TOTAL_READ_NSECS,
DM_STATS_TOTAL_WRITE_NSECS,
DM_STATS_NR_COUNTERS
} dm_stats_counter_t;
uint64_t dm_stats_get_counter(const struct dm_stats *dms,
dm_stats_counter_t counter,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_reads(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_reads_merged(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_read_sectors(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_read_nsecs(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_writes(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_writes_merged(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_write_sectors(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_write_nsecs(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_io_in_progress(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_io_nsecs(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_weighted_io_nsecs(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_total_read_nsecs(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
uint64_t dm_stats_get_total_write_nsecs(const struct dm_stats *dms,
uint64_t region_id, uint64_t area_id);
/*
* Derived statistics access methods
*
* Each method returns the corresponding value calculated from the
* counters stored in the supplied dm_stats handle for the specified
* region_id and area_id. If either region_id or area_id uses one of the
* special values DM_STATS_REGION_CURRENT or DM_STATS_AREA_CURRENT then
* the region or area is selected according to the current state of the
* dm_stats handle's embedded cursor.
*
* The set of metrics is based on the fields provided by the Linux
* iostats program.
*
* rd_merges_per_sec: the number of reads merged per second
* wr_merges_per_sec: the number of writes merged per second
* reads_per_sec: the number of reads completed per second
* writes_per_sec: the number of writes completed per second
* read_sectors_per_sec: the number of sectors read per second
* write_sectors_per_sec: the number of sectors written per second
* average_request_size: the average size of requests submitted
* service_time: the average service time (in ns) for requests issued
* average_queue_size: the average queue length
* average_wait_time: the average time for requests to be served (in ns)
* average_rd_wait_time: the average read wait time
* average_wr_wait_time: the average write wait time
*/
typedef enum {
DM_STATS_RD_MERGES_PER_SEC,
DM_STATS_WR_MERGES_PER_SEC,
DM_STATS_READS_PER_SEC,
DM_STATS_WRITES_PER_SEC,
DM_STATS_READ_SECTORS_PER_SEC,
DM_STATS_WRITE_SECTORS_PER_SEC,
DM_STATS_AVERAGE_REQUEST_SIZE,
DM_STATS_AVERAGE_QUEUE_SIZE,
DM_STATS_AVERAGE_WAIT_TIME,
DM_STATS_AVERAGE_RD_WAIT_TIME,
DM_STATS_AVERAGE_WR_WAIT_TIME,
DM_STATS_SERVICE_TIME,
DM_STATS_THROUGHPUT,
DM_STATS_UTILIZATION,
DM_STATS_NR_METRICS
} dm_stats_metric_t;
int dm_stats_get_metric(const struct dm_stats *dms, int metric,
uint64_t region_id, uint64_t area_id, double *value);
int dm_stats_get_rd_merges_per_sec(const struct dm_stats *dms, double *rrqm,
uint64_t region_id, uint64_t area_id);
int dm_stats_get_wr_merges_per_sec(const struct dm_stats *dms, double *rrqm,
uint64_t region_id, uint64_t area_id);
int dm_stats_get_reads_per_sec(const struct dm_stats *dms, double *rd_s,
uint64_t region_id, uint64_t area_id);
int dm_stats_get_writes_per_sec(const struct dm_stats *dms, double *wr_s,
uint64_t region_id, uint64_t area_id);
int dm_stats_get_read_sectors_per_sec(const struct dm_stats *dms,
double *rsec_s, uint64_t region_id,
uint64_t area_id);
int dm_stats_get_write_sectors_per_sec(const struct dm_stats *dms,
double *wr_s, uint64_t region_id,
uint64_t area_id);
int dm_stats_get_average_request_size(const struct dm_stats *dms,
double *arqsz, uint64_t region_id,
uint64_t area_id);
int dm_stats_get_service_time(const struct dm_stats *dms, double *svctm,
uint64_t region_id, uint64_t area_id);
int dm_stats_get_average_queue_size(const struct dm_stats *dms, double *qusz,
uint64_t region_id, uint64_t area_id);
int dm_stats_get_average_wait_time(const struct dm_stats *dms, double *await,
uint64_t region_id, uint64_t area_id);
int dm_stats_get_average_rd_wait_time(const struct dm_stats *dms,
double *await, uint64_t region_id,
uint64_t area_id);
int dm_stats_get_average_wr_wait_time(const struct dm_stats *dms,
double *await, uint64_t region_id,
uint64_t area_id);
int dm_stats_get_throughput(const struct dm_stats *dms, double *tput,
uint64_t region_id, uint64_t area_id);
int dm_stats_get_utilization(const struct dm_stats *dms, dm_percent_t *util,
uint64_t region_id, uint64_t area_id);
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
/*
* Statistics histogram access methods.
*
* Methods to access latency histograms for regions that have them
* enabled. Each histogram contains a configurable number of bins
* spanning a user defined latency interval.
*
* The bin count, upper and lower bin bounds, and bin values are
* made available via the following area methods.
*
* Methods to obtain a simple string representation of the histogram
* and its bounds are also provided.
*/
/*
* Retrieve a pointer to the histogram associated with the specified
* area. If the area does not have a histogram configured this function
* returns NULL.
*
* The pointer does not need to be freed explicitly by the caller: it
* will become invalid following a subsequent dm_stats_list(),
* dm_stats_populate() or dm_stats_destroy() of the corresponding
* dm_stats handle.
*
* If region_id or area_id is one of the special values
* DM_STATS_REGION_CURRENT or DM_STATS_AREA_CURRENT the current cursor
* value is used to select the region or area.
*/
struct dm_histogram *dm_stats_get_histogram(const struct dm_stats *dms,
uint64_t region_id,
uint64_t area_id);
/*
* Return the number of bins in the specified histogram handle.
*/
int dm_histogram_get_nr_bins(const struct dm_histogram *dmh);
/*
* Get the lower bound of the specified bin of the histogram for the
* area specified by region_id and area_id. The value is returned in
* nanoseconds.
*/
uint64_t dm_histogram_get_bin_lower(const struct dm_histogram *dmh, int bin);
/*
* Get the upper bound of the specified bin of the histogram for the
* area specified by region_id and area_id. The value is returned in
* nanoseconds.
*/
uint64_t dm_histogram_get_bin_upper(const struct dm_histogram *dmh, int bin);
/*
* Get the width of the specified bin of the histogram for the area
* specified by region_id and area_id. The width is equal to the bin
* upper bound minus the lower bound and yields the range of latency
* values covered by this bin. The value is returned in nanoseconds.
*/
uint64_t dm_histogram_get_bin_width(const struct dm_histogram *dmh, int bin);
/*
* Get the value of the specified bin of the histogram for the area
* specified by region_id and area_id.
*/
uint64_t dm_histogram_get_bin_count(const struct dm_histogram *dmh, int bin);
/*
* Get the percentage (relative frequency) of the specified bin of the
* histogram for the area specified by region_id and area_id.
*/
dm_percent_t dm_histogram_get_bin_percent(const struct dm_histogram *dmh,
int bin);
/*
* Return the total observations (sum of bin counts) for the histogram
* of the area specified by region_id and area_id.
*/
uint64_t dm_histogram_get_sum(const struct dm_histogram *dmh);
/*
* Histogram formatting flags.
*/
#define DM_HISTOGRAM_SUFFIX 0x1
#define DM_HISTOGRAM_VALUES 0x2
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
#define DM_HISTOGRAM_PERCENT 0X4
#define DM_HISTOGRAM_BOUNDS_LOWER 0x10
#define DM_HISTOGRAM_BOUNDS_UPPER 0x20
#define DM_HISTOGRAM_BOUNDS_RANGE 0x30
/*
* Return a string representation of the supplied histogram's values and
* bin boundaries.
*
* The bin argument selects the bin to format. If this argument is less
* than zero all bins will be included in the resulting string.
*
* width specifies a minimum width for the field in characters; if it is
* zero the width will be determined automatically based on the options
* selected for formatting. A value less than zero disables field width
* control: bin boundaries and values will be output with a minimum
* amount of whitespace.
*
libdm: add latency histogram support Add support for creating, parsing, and reporting dm-stats latency histograms on kernels that support precise_timestamps. Histograms are specified as a series of time values that give the boundaries of the bins into which I/O counts accumulate (with implicit lower and upper bounds on the first and last bins). A new type, struct dm_histogram, is introduced to represent histogram values and bin boundaries. The boundary values may be given as either a string of values (with optional unit suffixes) or as a zero terminated array of uint64_t values expressing boundary times in nanoseconds. A new bounds argument is added to dm_stats_create_region() which accepts a pointer to a struct dm_histogram initialised with bounds values. Histogram data associated with a region is parsed during a call to dm_stats_populate() and used to build a table of histogram values that are pointed to from the containing area's counter set. The histogram for a specified area may then be obtained and interogated for values and properties. This relies on kernel support to provide the boundary values in a @stats_list response: this will be present in 4.3 and 4.2-stable. A check for a minimum driver version of 4.33.0 is implemented to ensure that this is present (4.32.0 has the necessary precise_timestamps and histogram features but is unable to report these via @stats_list). Access methods are provided to retrieve histogram values and bounds as well as simple string representations of the counts and bin boundaries. Methods are also available to return the total count for a histogram and the relative value (as a dm_percent_t) of a specified bin.
2015-08-19 22:39:10 +03:00
* flags is a collection of flag arguments that control the string format:
*
* DM_HISTOGRAM_VALUES - Include bin values in the string.
* DM_HISTOGRAM_SUFFIX - Include time unit suffixes when printing bounds.
* DM_HISTOGRAM_PERCENT - Format bin values as a percentage.
*
* DM_HISTOGRAM_BOUNDS_LOWER - Include the lower bound of each bin.
* DM_HISTOGRAM_BOUNDS_UPPER - Include the upper bound of each bin.
* DM_HISTOGRAM_BOUNDS_RANGE - Show the span of each bin as "lo-up".
*
* The returned pointer does not need to be freed explicitly by the
* caller: it will become invalid following a subsequent
* dm_stats_list(), dm_stats_populate() or dm_stats_destroy() of the
* corresponding dm_stats handle.
*/
const char *dm_histogram_to_string(const struct dm_histogram *dmh, int bin,
int width, int flags);
2011-09-02 01:04:14 +04:00
/*************************
* 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;
2011-09-02 01:04:14 +04:00
float f;
double d; /* Unused. */
const char *str;
} v;
2011-09-02 01:04:14 +04:00
struct dm_config_value *next; /* For arrays */
uint32_t format_flags;
};
struct dm_config_node {
const char *key;
struct dm_config_node *parent, *sib, *child;
struct dm_config_value *v;
int id;
};
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);
int dm_config_parse_without_dup_node_check(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);
/*
* Create a new, uncascaded config tree equivalent to the input cascade.
*/
struct dm_config_tree *dm_config_flatten(struct dm_config_tree *cft);
void dm_config_destroy(struct dm_config_tree *cft);
config: add support for enhanced config node output There's a possibility to interconnect the dm_config_node with an ID, which in our case is used to reference the configuration definition ID from config_settings.h. So simply interconnecting struct dm_config_node with struct cfg_def_item. This patch also adds support for enhanced config node output besides existing "output line by line". This patch adds a possibility to register a callback that gets called *before* the config node is processed line by line (for example to include any headers on output) and *after* the config node is processed line by line (to include any footers on output). Also, it adds the config node reference itself as the callback arg in addition to have a possibility to extract more information from the config node itself if needed when processing the output callback (e.g. the key name, the id, or whether this is a section or a value etc...). If the config node from lvm.conf/--config tree is recognized and valid, it's always coupled with the config node definition ID from config_settings.h: struct dm_config_node { int id; const char *key; struct dm_config_node *parent, *sib, *child; struct dm_config_value *v; } For example if the dm_config_node *cn holds "devices/dev" configuration, then the cn->id holds "devices_dev_CFG" ID from config_settings.h, -1 if not found in config_settings.h and 0 if matching has not yet been done. To support the enhanced config node output, a new structure has been defined in libdevmapper to register it: struct dm_config_node_out_spec { dm_config_node_out_fn prefix_fn; /* called before processing config node lines */ dm_config_node_out_fn line_fn; /* called for each config node line */ dm_config_node_out_fn suffix_fn; /* called after processing config node lines */ }; Where dm_config_node_out_fn is: typedef int (*dm_config_node_out_fn)(const struct dm_config_node *cn, const char *line, void *baton); (so in comparison to existing callbacks for config node output, it has an extra dm_config_node *cn arg in addition) This patch also adds these functions to libdevmapper: - dm_config_write_node_out - dm_config_write_one_node_out ...which have exactly the same functionality as their counterparts without the "out" suffix. The "*_out" functions adds the extra hooks for enhanced config output (prefix_fn and suffix_fn mentioned above). One can still use the old interface for config node output, this is just an enhancement for those who'd like to modify the output more extensively.
2013-03-05 21:02:13 +04:00
/* Simple output line by line. */
typedef int (*dm_putline_fn)(const char *line, void *baton);
config: add support for enhanced config node output There's a possibility to interconnect the dm_config_node with an ID, which in our case is used to reference the configuration definition ID from config_settings.h. So simply interconnecting struct dm_config_node with struct cfg_def_item. This patch also adds support for enhanced config node output besides existing "output line by line". This patch adds a possibility to register a callback that gets called *before* the config node is processed line by line (for example to include any headers on output) and *after* the config node is processed line by line (to include any footers on output). Also, it adds the config node reference itself as the callback arg in addition to have a possibility to extract more information from the config node itself if needed when processing the output callback (e.g. the key name, the id, or whether this is a section or a value etc...). If the config node from lvm.conf/--config tree is recognized and valid, it's always coupled with the config node definition ID from config_settings.h: struct dm_config_node { int id; const char *key; struct dm_config_node *parent, *sib, *child; struct dm_config_value *v; } For example if the dm_config_node *cn holds "devices/dev" configuration, then the cn->id holds "devices_dev_CFG" ID from config_settings.h, -1 if not found in config_settings.h and 0 if matching has not yet been done. To support the enhanced config node output, a new structure has been defined in libdevmapper to register it: struct dm_config_node_out_spec { dm_config_node_out_fn prefix_fn; /* called before processing config node lines */ dm_config_node_out_fn line_fn; /* called for each config node line */ dm_config_node_out_fn suffix_fn; /* called after processing config node lines */ }; Where dm_config_node_out_fn is: typedef int (*dm_config_node_out_fn)(const struct dm_config_node *cn, const char *line, void *baton); (so in comparison to existing callbacks for config node output, it has an extra dm_config_node *cn arg in addition) This patch also adds these functions to libdevmapper: - dm_config_write_node_out - dm_config_write_one_node_out ...which have exactly the same functionality as their counterparts without the "out" suffix. The "*_out" functions adds the extra hooks for enhanced config output (prefix_fn and suffix_fn mentioned above). One can still use the old interface for config node output, this is just an enhancement for those who'd like to modify the output more extensively.
2013-03-05 21:02:13 +04:00
/* More advaced output with config node reference. */
typedef int (*dm_config_node_out_fn)(const struct dm_config_node *cn, const char *line, void *baton);
/*
* Specification for advanced config node output.
*/
struct dm_config_node_out_spec {
dm_config_node_out_fn prefix_fn; /* called before processing config node lines */
dm_config_node_out_fn line_fn; /* called for each config node line */
dm_config_node_out_fn suffix_fn; /* called after processing config node lines */
};
/* 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);
config: add support for enhanced config node output There's a possibility to interconnect the dm_config_node with an ID, which in our case is used to reference the configuration definition ID from config_settings.h. So simply interconnecting struct dm_config_node with struct cfg_def_item. This patch also adds support for enhanced config node output besides existing "output line by line". This patch adds a possibility to register a callback that gets called *before* the config node is processed line by line (for example to include any headers on output) and *after* the config node is processed line by line (to include any footers on output). Also, it adds the config node reference itself as the callback arg in addition to have a possibility to extract more information from the config node itself if needed when processing the output callback (e.g. the key name, the id, or whether this is a section or a value etc...). If the config node from lvm.conf/--config tree is recognized and valid, it's always coupled with the config node definition ID from config_settings.h: struct dm_config_node { int id; const char *key; struct dm_config_node *parent, *sib, *child; struct dm_config_value *v; } For example if the dm_config_node *cn holds "devices/dev" configuration, then the cn->id holds "devices_dev_CFG" ID from config_settings.h, -1 if not found in config_settings.h and 0 if matching has not yet been done. To support the enhanced config node output, a new structure has been defined in libdevmapper to register it: struct dm_config_node_out_spec { dm_config_node_out_fn prefix_fn; /* called before processing config node lines */ dm_config_node_out_fn line_fn; /* called for each config node line */ dm_config_node_out_fn suffix_fn; /* called after processing config node lines */ }; Where dm_config_node_out_fn is: typedef int (*dm_config_node_out_fn)(const struct dm_config_node *cn, const char *line, void *baton); (so in comparison to existing callbacks for config node output, it has an extra dm_config_node *cn arg in addition) This patch also adds these functions to libdevmapper: - dm_config_write_node_out - dm_config_write_one_node_out ...which have exactly the same functionality as their counterparts without the "out" suffix. The "*_out" functions adds the extra hooks for enhanced config output (prefix_fn and suffix_fn mentioned above). One can still use the old interface for config node output, this is just an enhancement for those who'd like to modify the output more extensively.
2013-03-05 21:02:13 +04:00
int dm_config_write_node_out(const struct dm_config_node *cn, const struct dm_config_node_out_spec *out_spec, 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);
config: add support for enhanced config node output There's a possibility to interconnect the dm_config_node with an ID, which in our case is used to reference the configuration definition ID from config_settings.h. So simply interconnecting struct dm_config_node with struct cfg_def_item. This patch also adds support for enhanced config node output besides existing "output line by line". This patch adds a possibility to register a callback that gets called *before* the config node is processed line by line (for example to include any headers on output) and *after* the config node is processed line by line (to include any footers on output). Also, it adds the config node reference itself as the callback arg in addition to have a possibility to extract more information from the config node itself if needed when processing the output callback (e.g. the key name, the id, or whether this is a section or a value etc...). If the config node from lvm.conf/--config tree is recognized and valid, it's always coupled with the config node definition ID from config_settings.h: struct dm_config_node { int id; const char *key; struct dm_config_node *parent, *sib, *child; struct dm_config_value *v; } For example if the dm_config_node *cn holds "devices/dev" configuration, then the cn->id holds "devices_dev_CFG" ID from config_settings.h, -1 if not found in config_settings.h and 0 if matching has not yet been done. To support the enhanced config node output, a new structure has been defined in libdevmapper to register it: struct dm_config_node_out_spec { dm_config_node_out_fn prefix_fn; /* called before processing config node lines */ dm_config_node_out_fn line_fn; /* called for each config node line */ dm_config_node_out_fn suffix_fn; /* called after processing config node lines */ }; Where dm_config_node_out_fn is: typedef int (*dm_config_node_out_fn)(const struct dm_config_node *cn, const char *line, void *baton); (so in comparison to existing callbacks for config node output, it has an extra dm_config_node *cn arg in addition) This patch also adds these functions to libdevmapper: - dm_config_write_node_out - dm_config_write_one_node_out ...which have exactly the same functionality as their counterparts without the "out" suffix. The "*_out" functions adds the extra hooks for enhanced config output (prefix_fn and suffix_fn mentioned above). One can still use the old interface for config node output, this is just an enhancement for those who'd like to modify the output more extensively.
2013-03-05 21:02:13 +04:00
int dm_config_write_one_node_out(const struct dm_config_node *cn, const struct dm_config_node_out_spec *out_spec, 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);
int dm_config_remove_node(struct dm_config_node *parent, struct dm_config_node *remove);
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);
2011-09-02 01:04:14 +04:00
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_value_is_bool(const struct dm_config_value *v);
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);
/*
* Common formatting flags applicable to all config node types (lower 16 bits).
*/
#define DM_CONFIG_VALUE_FMT_COMMON_ARRAY 0x00000001 /* value is array */
#define DM_CONFIG_VALUE_FMT_COMMON_EXTRA_SPACES 0x00000002 /* add spaces in "key = value" pairs in constrast to "key=value" for better readability */
/*
* Type-related config node formatting flags (higher 16 bits).
*/
/* int-related formatting flags */
#define DM_CONFIG_VALUE_FMT_INT_OCTAL 0x00010000 /* print number in octal form */
/* string-related formatting flags */
#define DM_CONFIG_VALUE_FMT_STRING_NO_QUOTES 0x00010000 /* do not print quotes around string value */
void dm_config_value_set_format_flags(struct dm_config_value *cv, uint32_t format_flags);
uint32_t dm_config_value_get_format_flags(struct dm_config_value *cv);
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. Using the library fallback code has
* a consequence that you need to take into account: any device node
* or symlink created without udev is not recorded in udev database
* which other applications may read to get complete list of devices.
* For this reason, use of DM_UDEV_DISABLE_LIBRARY_FALLBACK is
* recommended on systems where udev is used. Keep library fallback
* enabled just for exceptional cases where you need to debug udev-related
* problems. If you hit such problems, please contact us through upstream
* LVM2 development mailing list (see also README file). This flag is
* currently not set by default in libdevmapper so you need to set it
* explicitly if you're sure that udev is behaving correctly on your
* setups.
*/
#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
/*
* Udev flags reserved for use by any device-mapper subsystem.
*/
#define DM_SUBSYSTEM_UDEV_FLAG0 0x0100
#define DM_SUBSYSTEM_UDEV_FLAG1 0x0200
#define DM_SUBSYSTEM_UDEV_FLAG2 0x0400
#define DM_SUBSYSTEM_UDEV_FLAG3 0x0800
#define DM_SUBSYSTEM_UDEV_FLAG4 0x1000
#define DM_SUBSYSTEM_UDEV_FLAG5 0x2000
#define DM_SUBSYSTEM_UDEV_FLAG6 0x4000
#define DM_SUBSYSTEM_UDEV_FLAG7 0x8000
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);
/*
* dm_dev_wait_immediate
* If *ready is 1 on return, the wait is complete.
* If *ready is 0 on return, the wait is incomplete and either
* this function or dm_udev_wait() must be called again.
* Returns 0 on error, when neither function should be called again.
*/
int dm_udev_wait_immediate(uint32_t cookie, int *ready);
#define DM_DEV_DIR_UMASK 0022
#define DM_CONTROL_NODE_UMASK 0177
#ifdef __cplusplus
}
#endif
2006-01-04 19:05:44 +03:00
#endif /* LIB_DEVICE_MAPPER_H */