GLOSSARY
vxintro - introduction to the Veritas Volume Manager utilities
The Veritas Volume Manager (VxVM)
utilities provide a shell-level interface for use by
system administrators and high-level applications and scripts to
query and manipulate objects managed through VxVM.
Note: Some Veritas Volume Manager usage messages,
manual pages, and command output contain terms and descriptions
related to Veritas SANPoint Control 2.0 and SAN Access Layer (SAL).
These are not supported in this release, so you should ignore
options and fields that refer to SANPoint Control or SAL.
-
boot disk group
-
If the root disk is under VxVM control, this disk group contains the root
disk and the volumes on it that are used to boot the system.
By default, the name of the boot disk group is aliased to the
reserved disk group name, bootdg,
when the root disk is put under VxVM control.
-
concatenated plex
-
A plex whose subdisks are associated at
specific offsets within the address range of the plex, and extend into
the plex address range for the length of the subdisk. This layout allows
regions of one or more disks to create a plex, rather than a single
big region.
-
data change map
-
The data change map (DCM) is a bit-map which represents regions in the
volume. When a write to a region occurs, the corresponding bit in the
DCM is turned on. It is used by VVR for both log overflow protection
and automatic secondary synchronization.
-
data volume
-
A volume being used as a child of an RVG. For a primary RVG, a data
volume contains the primary copy of that volume data. For a secondary
RVG, a data volume contains a copy of the corresponding remote primary
data volume data. Secondary data volumes are only writable with updates
from the primary.
The secondary RVG must contain a data volume corresponding
to each primary data volume.
-
default disk group
-
Each system may have one special disk group, aliased to the
reserved name, defaultdg, which
is the default disk group for most utilities.
See the vxdg(1M) manual page for more information.
-
disk
-
Disks exist as two entities. One is the physical disk on
which all data is ultimately stored and which exhibits all the
behaviors of the underlying technology.
The other is the Veritas Volume Manager presentation of disks which,
while mapping one-to-one with the
physical disks, are just presentations of units from which allocations
of storage are made. As an example, a physical disk presents the image
of a device with a definable geometry with a definable number of
cylinders, heads, and so forth,
whereas a Veritas Volume Manager disk (VM disk) is simply a unit of
allocation with a name and a size.
-
disk access record
-
A configuration record that defines a pathway to a disk.
The list of all disk access
records stored in a system is used to find all disks attached to the
system. Disk access records do not identify particular physical
disks.
Disk access records are identified by their disk access names
(also known as DA names).
Through the use of disk IDs, VxVM allows disks to be
moved between controllers, or to different locations on a controller.
When a disk is moved, a different disk access record is used when
accessing the disk, although the disk media record continues to
track the actual physical disk.
On some systems, VxVM builds a list of disk access
records automatically, based on the list of all devices attached to
the system. On these systems, it is not necessary to define disk
access records explicitly. On other systems, disk access records must
be defined explicitly with the vxdisk define operation.
Specialty disks (such as RAM disks or floppy disks) are likely to
require explicit vxdisk define operations on all systems.
-
disk group
-
A group of disks that share a common configuration. A configuration
consists of a set of records describing objects (including
disks, volumes, plexes, and
subdisks) that are associated with one particular disk group. Each disk
group has an administrator-assigned name that can be used by the
administrator to reference that disk group. Each disk group has an
internally defined unique disk group ID, which is used to differentiate
two disk groups with the same administrator-assigned name.
Disk groups provide a method to partition the
configuration database, so that the database size is not too large and
so that database modifications do not affect too many drives. They
also allow VxVM to operate with groups of physical disk
media that can be moved between systems.
Disks and disk groups have a circular relationship: disk groups are
formed from disks, and disk group configurations are stored on disks.
All disks in a disk group are stamped with a disk group ID, which is a
unique identifier for naming disk groups. Some
or all disks in a disk group also store copies of the configuration
database of the disk group.
-
disk group configuration
-
A disk group configuration is a small database that contains all
volume, plex, subdisk, and disk media records. These configurations
are replicated onto some or all disks in the disk group, usually with
one copy on each disk. Because these databases are stored within
disk groups, record associations cannot span disk groups. Thus, a
subdisk defined on a disk in one disk group cannot be associated with
a volume in another disk group.
-
disk header
-
A block stored in a private region of a disk and that
defines several properties of the disk. The disk header defines the
size of the private region, the location and size of the public
region, the unique disk ID for the disk, the disk group ID and disk
group name (if the disk is currently associated with a disk group),
and the host ID for a host that has exclusive use of the disk.
-
disk ID
-
A 64-byte universally unique identifier that is assigned to a physical
disk when its private region is initialized with the vxdisk
init operation. The disk ID is stored in the disk media record so
that the physical disk can be related to the disk media record at
system startup.
-
disk media record
-
A reference to a physical disk
This
record can be thought of as
a physical disk identifier for the disk
Disk media records are configuration records
that provide a name with up to 31 characters (known as
the disk media name or DM name), which
you can use to reference a particular disk, independent of
its location on the system's various disk controllers. Disk media
records reference particular physical disks through a disk ID, which
is a unique identifier that is assigned to a disk when it is
initialized for use with VxVM.
Operations are provided to set or remove the disk ID stored in a disk
media record. Such operations have the effect of removing or replacing
disks, with any associated subdisks being removed or replaced along
with the disk.
-
host ID
-
A name, usually assigned by the administrator, that identifies a
particular host. Host IDs are used to assign ownership to particular
physical disks. When a disk is part of a disk group that is in
active use by a particular host, the disk is stamped with that host's
host ID. If another system attempts to access the disk, it
detects that the disk has a non-matching host ID and disallows
access until the first system discontinues use of the disk. To allow
for system failures that do not clear the host ID, the vxdisk
clearimport operation can be used to clear the host ID stored on a
disk.
If a disk is a member of a disk group and has a host ID that matches a
particular host, then that host imports the disk group as part of
system startup.
-
kernel log
-
A log kept in the private region on the disk and that is written
by the Veritas Volume Manager kernel.
The log contains records describing the
state of volumes in the disk group. This log provides a mechanism for the
kernel to persistently register state changes so that vxconfigd can
be guaranteed to detect the state changes even
in the event of a system failure.
-
layered volume
-
A virtual volume that is used and managed directly by VxVM,
not by a user.
Note that currently a layered volume provides storage for only
one upper-level volume.
Layered volumes allow VxVM to implement the
following features:
-
Striped mirrors and concatenated mirrors
are new types of volume layouts that are less likely to fail
and that provide faster recovery times because there
is less data to recover (one column or part of a column
versus the whole volume).
-
Online relayout lets you change the volume layout while
the volume is online.
See the vxassist(1M) and vxrelayout(1M) manual pages for
more information.
-
RAID-5 subdisk moves and RAID-5 snapshots (see vxassist(1M)).
-
plex
-
A copy of a volume's logical data address space, also called
a mirror. A volume can have up to 32 plexes associated with
it. Each plex is, at least conceptually, a copy of the volume that is
maintained consistently in the presence of volume I/O and
reconfigurations. Plexes represent the primary means of configuring
storage for a volume. Plexes can have a striped, concatenated, or
RAID-5 organization (layout).
-
plex consistency
-
If the plexes of a volume contain different data, then
the plexes are said to be inconsistent. This is only a problem if
VxVM is unaware of the inconsistencies, as the volume
can return differing results for consecutive reads. Plex inconsistency
is a serious
compromise of data integrity. This inconsistency can be caused by
write operations that start around the time of a system failure, if
parts of the write complete on one plex but not the other. Plexes can
also be inconsistent after creation of a mirrored volume, if the plexes
are not first synchronized to contain the same data. An important part
of Veritas Volume Manager operation is ensuring that consistent data is
returned to any application that reads a volume. This may require
that plex consistency of a volume be ``recovered'' by copying data
between plexes so that they have the same contents. Alternatively,
the volume can be put into a state such that reads from one plex are
automatically written back to the other plexes, thus making the data
consistent for that volume offset.
-
private region
-
Disks used by VxVM contain two special regions: a private
region and a public region.
The private region of a disk contains various on-disk structures that
are used by VxVM for various internal purposes. Each
private region begins with a disk header which identifies the disk and
its disk group. Private regions can also contain copies of a disk
group's configuration, and copies of the disk group's kernel log.
-
public region
-
The public region of a disk is the space reserved for allocating
subdisks. Subdisks are defined with offsets that are relative to the
beginning of the public region of a particular disk. Only one
contiguous region of disk can form the public region for a particular
disk.
-
RLINK
-
(remote link)
A representation of a communications link to a RVG hierarchy
at a remote replication site, which contains information about the link.
An RLINK is a primary RLINK if its parent RVG
is the primary RVG containing writable primary data
volumes. Alternatively, a RLINK is a secondary RLINK if its parent
RVG contains read-only data volumes (one for each data volume that
the primary RVG contains). The vxrlink(1M) command is used to
replicate a volume or volumes to any number of remote sites. The
primary RVG has one RLINK record associated with it for each
secondary site. A secondary RVG has only one RLINK record associated
with it, which represents and contains information about the
connection with the corresponding primary RLINK.
-
RVG
-
(replicated volume group)
A virtual device that hierarchically contains one or more data volume
records, a log volume record called a Storage Replicator Log (SRL),
and one (or more for primary RVGs)
RLINK records. It must be associated as a parent of the data volume
records in order for those data volumes to be replicated to other
sites which may be located across a LAN or WAN. In order to actively
replicate a data volume, an RVG must have at least one data volume
child (the volume to be replicated), exactly one SRL volume child (a
volume to SRL data volume writes before they are transmitted to
RLINKs), and at least one RLINK child (which represents a
connection to an RVG hierarchy at a remote replication site). An RVG
can be either a primary or a secondary, depending on whether its data
volumes are considered to contain the primary copies of data or
whether the data volumes are considered to be read-only copies of the
data. Secondary RVGs contain one SRL volume, one RLINK, and the same
number of data volumes as the primary RVG contains.
-
SRL volume
-
(storage replicator log volume)
A volume being used as a child of an RVG. The SRL volume contains
temporary copies of data intended to be written from (primary) or to
(secondary) sibling data volumes. The SRL volume also contains meta
data, such as connection information, about the RVG and RLINK with
which the SRL volume is associated. The primary SRL volume is used to
log SRL data while either in asynchronous mode, or during network outages
while in synchronous mode. A secondary RVG must also have an SRL volume
associated with it.
-
striped plex
-
A plex that distributes data evenly across each of its associated subdisks.
A plex has a characteristic number of stripe columns
(consisting of associated subdisks)
and a characteristic stripe unit size.
The stripe unit size defines how data with a particular
address is allocated to one of the associated subdisks.
Given a stripe unit size of 128 blocks and two stripe columns,
the first group of 128 blocks is allocated to the first subdisk,
the second group of 128 blocks is allocated to the second subdisk,
the third group to the first subdisk, and so on.
-
subdisk
-
A region of storage allocated on a disk for use with a volume.
Subdisks are associated to volumes through plexes. One or more
subdisks are laid out to form plexes based on the plex layout (striped,
concatenated, or RAID-5). Subdisks are defined relative to disk media
records.
-
volboot file
-
The volboot file is a special file (usually stored in
/etc/vx/volboot) that is used to define a system's host ID and
a system-wide default disk group. If the root disk is under VxVM control,
the volboot file is also used to define the name of the
boot disk group for the system.
-
volume
-
A virtual disk
device that looks to applications and file systems like a regular disk
device.
Volumes present block and raw device interfaces
that are compatible in their use with disk
devices.
However, a volume is a virtual device that can be mirrored, spanned
across disk drives, moved to use different storage, and striped using
administrative commands. The configuration of a volume can be
changed, using Veritas Volume Manager utilities, without causing
disruption to applications or file systems that are using the volume.
The Veritas Intelligent Storage Provisioning (ISP) feature introduces
rule-based allocation of storage to Veritas Volume Manager.
This feature is administered by using the vxassist and
vxvoladm commands, and the graphical user interface.
For a description of the concepts and functionality of the
Veritas Intelligent Storage Provisioning feature, see the
Veritas Storage Foundation Intelligent Storage Provisioning Administrator's
Guide and the manual pages relating to the ISP commands.
VxVM employs certain conventions
to provide a degree of similarity between various operations.
The conventions are used in the following areas:
-
Disk Group Selection
-
Standard Length Numbers
-
Command Syntax
Most commands operate upon only one disk group per invocation. Each disk
group has a separate configuration from every other disk group and it
is possible for two disk groups to contain two objects that have the
same name. This can happen, in particular, if a disk group is moved
from one system to another. However, most utilities make no attempt
to ensure that names between disk groups are unique, so name
collisions can occur.
System administrators who try to avoid name collisions should be
able to use most of the utilities without having to specify disk
groups except when creating objects. Administrators cannot use
single-command invocations that reference objects in more than one disk
group, but disk groups are selected automatically, based on objects
specified in the command.
The rules that commands use to select the disk group when this is
not specified are described on the vxdg(1M) manual page.
Many basic properties of objects that are managed by VxVM
require specification of lengths, either as a pure object
length or as an offset relative to some other object.
VxVM supports a volume length up to 256 terabytes (256TB)
for consistency with Veritas File System (VxFS) limits.
However, 32-bit legacy applications that use
system calls such as seek, lseek,
read and write are limited to a maximum offset
that is determined by the operating system.
This value is usually 2^31-1 bytes (1 byte less than 2 terabytes).
VxVM provides a
uniform syntax for representing large numbers, and uses suffixes to
provide convenient multipliers. Numbers can be specified in decimal,
octal, or hexadecimal.
For convenience, numbers can be specified as a sum of
several numbers.
A hexadecimal (base 16) number is introduced using a prefix of
0x. For example, 0xfff is the same as decimal 4095. An
octal (base 8) number is introduced using a prefix of 0. For
example, 0177777 is the same as decimal 65535.
A number can be followed by a single-character suffix
to indicate a multiplier for the number.
A length number with no suffix character
represents a count of standard disk sectors.
The length of a standard disk sector can vary between systems;
it is typically 512 bytes or 1024 bytes.
On systems where disks can have different sector sizes,
one of the sector sizes is chosen as the ``standard'' size.
Supported suffix characters are:
-
b
-
(Blocks) Multiply the length by 512 bytes.
-
g
-
(Gigabytes) Multiply the length by 1,073,741,824 (1024M) bytes.
-
k
-
(Kilobytes) Multiply the length by 1024 bytes.
-
m
-
(Megabytes) Multiply the length by 1,048,576 (1024K) bytes.
-
s
-
(Sectors) Multiply the length by the standard sector size. This is
the default unit if no suffix is specified.
-
t
-
(Terabytes) Multiply the length by 1,099,511,627,776 (1024G) bytes.
Numbers are represented internally as an integer number of sectors.
As a result, if the standard disk sector size is larger than 512
bytes, numbers can be specified that need to be rounded to a
sector. Rounding is always done to the next lowest, not the nearest,
multiple of the sector size.
Case is ignored in length specification. Hexadecimal numbers and
suffix characters can be specified using any reasonable combination of
uppercase and lowercase letters.
Because the letter b is a valid hexadecimal character, there is a
special case for the b suffix where a single blank character can
separate a number from the b suffix character. Use of a blank
within a number, when invoking commands from the shell, usually
requires quoting the number. For example:
vxassist make vol01 "0x1000 b"
Numbers can be added or subtracted by separating two or more numbers
by a plus or minus sign, respectively. A plus sign is optional. The
following is an example:
1023g+1023m+1023k+1
In output, VxVM reports lengths in
sectors, with no suffix character.
Most utilities in VxVM provide more than one operation,
with operations grouped into utilities primarily by object type.
Utilities that provide multiple operations are typically invoked with the
following form:
utility_name [ options ] keyword [ operands ]
utility_name is the name of the
Veritas Volume Manager command and keyword
specifies the specific operation to perform.
Any options
that are introduced in the standard -letter form precede the
operation keyword. This is in keeping with standard System V UNIX utility
syntax, which provides for a set of options as the first arguments to
a command, followed by any non-option operands. The keyword is
considered an operand under standard System V syntax.
All VM utilities provide an extended usage message that lists
all the options and operation keywords supported by the utility.
Most VM utilities also display a usage message if you enter an invalid option.
For utilities that are keyword-based,
you can display this extended usage message the keyword
help
or a question mark
(?).
Utilities that use operands for something other
than operation selection provide a reserved option of
-H
to
display the extended usage information.
Disk group configurations contain eight types of records:
-
Disk Access Records
-
Disk Group Records
-
Disk Media Records
-
Plex Records
-
RLINK Records
-
RVG Records
-
Subdisk Records
-
Volume Records
Disk access records define an address, or access path, that can be
used to access a disk. The list of all disk access records defines
the list of all disk addresses that VxVM can use to
locate physical disks. Disk access records do not define specific
physical disks, since physical disks can be moved on a system. When a
physical disk is moved, a different disk access record may be
necessary to locate it.
Usually VxVM can use the information provided by the operating system to
configure most, if not all, disk access records automatically.
Such auto-configured disk access records are not stored persistently on disk,
but are instead regenerated every time that VxVM starts up.
Disk access records that cannot be configured by
scanning the disks are stored in an ordinary file,
/etc/vx/darecs, which is located in the root file system.
(In releases prior to VxVM 4.0, such records were stored in the
volboot file.)
Unlike all other record types, the names of disk
access records can conflict with the names of other records. For
example, a specialty disk (such as a RAM disk) can use the same name
for both the disk access record and the disk media record that points
to it. It is typically advisable to use different names for the
access and media records, to avoid additional confusion if disks are
moved.
Disk access records have the following fundamental attributes:
-
disk access name
-
The name of the disk access record is typically a disk address.
VxVM 3.2 introduced an alternative enclosure-based naming scheme,
which uses disk access names of the form enclosurename_disk#
where enclosurename is the logical enclosure name, and disk# is
the number of the disk in the enclosure. For example, enc0_0 refers to
the first disk in the enclosure enc0.
Other systems are likely to have different conventions for disk
access name.
-
type
-
Each disk access record has a type, which identifies key
characteristics of VxVM's interaction with the disk.
The available types are
auto, simple, and nopriv.
Typically, most disks are configured with the
type auto and format cdsdisk (auto:cdsdisk)
to support the Cross-platform Data Sharing (CDS) feature.
See the vxdisk(1M) manual page for more information on disk types.
If the physical disk represented by the disk access record is
associated with a disk media record, then the following
fields are defined:
-
disk group name
-
The name of the disk group containing the disk media record.
-
disk media name
-
The name of the disk media record that points to the physical disk.
Additional attributes can be added, arbitrarily, by disk types. See
vxdisk(1M) for a list of additional attributes defined by the
standard disk types.
Disk group records define several different types of names for a disk
group. The different types of names are:
-
alias name
-
This is the standard name that the system uses when referencing the
disk group.
References to the disk group name usually mean the alias name.
Volume directories are structured into
subdirectories based on the disk group alias name.
Typically, the
disk group's alias name and real name are identical.
A local alias
can be useful for gaining access to a disk group with a name that
conflicts with other disk groups in the system.
The names bootdg, defaultdg and nodg are reserved.
-
disk group ID
-
A 64-byte identifier that represents the unique ID of the disk group.
All disk groups on all systems should have a different disk group ID,
even if they have the same real name. This identifier is stored in
the disk headers of all disks in the disk group. It is used to ensure
that VxVM does not confuse two disk groups which were
created with the same name.
-
real name
-
This is the name of the disk group, as defined on disk.
This name is stored in the disk group configuration, and is also
stored in the disk headers of all disks in the disk group.
Disk media records define a specific disk within a disk group. The
name of a disk media record (the disk media name)
is assigned when a disk is first added to
a disk group (using the vxdg adddisk operation). Disk media
records can be assigned to specific physical disks by associating the
disk media record with the current disk access record for the physical
disk.
Disk media records have the following fundamental attributes:
-
disk access name
-
The disk access name that is currently used to access the physical
disk referenced by the disk ID. If the disk ID is defined, but no
physical disk with that ID could be found, the disk access name is
clear. A disk where the physical disk could not be found is
considered to be in the NODAREC, or inaccessible, state.
A disk
can become inaccessible either because the indicated disk is not
currently attached to the system, or because I/O failures on the
physical disk prevented VxVM from identifying or using
the physical disk.
-
disk ID
-
A 64-byte unique identifier representing the physical disk to which
the media record is associated. This can be cleared to indicate that
the disk is considered in the removed state. A removed disk has
no current association with any physical disk.
A disk media record that has an active association with a physical
disk (both the disk ID and the disk access name attributes are
defined), inherits several properties from the underlying physical
disk. These attributes are taken from the disk header, which is
stored in the private region of the disk. These inherited
attributes are:
-
atomic I/O size
-
This is the fundamental I/O size for the disk,
in bytes,
also known as the sector size.
All I/O operations to this disk must be multiples of this size.
VxVM requires that all disks have the same sector size.
On most systems, this size is 512 bytes.
-
private length
-
The length of the region of the physical disk that is reserved for
storing private Veritas Volume Manager information.
-
public length
-
The length of the region of the physical disk that is available for
subdisk allocations.
Plex records define the characteristics of a particular plex of a
volume. A plex can be in either an associated state or a dissociated
state. In the dissociated state, the plex is not a part of a volume.
A dissociated plex cannot be accessed in any way. An associated plex
can be accessed through the volume.
Plexes have the following fundamental attributes:
-
comment
-
An administrator-assigned string of up to 40 characters that can be set
and changed using the vxedit utility. VxVM does
not interpret the comment field. The comment cannot contain newline
characters.
-
condition flags
-
Various condition flags are defined for the plex that define state
which is recognized automatically, rather than managed by the volume
usage type. Defined flags are:
-
IOFAIL
-
The plex was detached as a result of an I/O failure detected during
normal volume I/O. The plex is out-of-date with respect to the
volume, and in need of complete recovery. However, this condition
also indicates a likelihood that one of the disks in the system should
be replaced.
-
NODAREC
-
No physical disk was found for one of the subdisks in the plex. This
implies either that the physical disk failed, making it
unrecognizable, or that the physical disk is no longer attached
through a known access path.
-
NODEVICE
-
A physical device could not be found corresponding to the
disk ID in the disk media record for one of the subdisks associated
with the plex.
The plex cannot be used until this condition is fixed,
or the affected subdisk is dissociated.
-
RECOVER
-
A disk for one of the disk media records was replaced or was
reattached too late to prevent the plex from becoming out-of-date with
respect to the volume. The plex requires complete recovery from
another plex in the volume to synchronize the plex with the correct
contents of the volume.
-
REMOVED
-
One of the disk media records was put into the removed state through
explicit administrative action. The plex cannot be used until the
disk is replaced or the affected subdisk is dissociated.
-
contiguous length
-
The offset of the first block in the plex address space that is
not backed by a subdisk. If the plex has no holes, the
contiguous length matches the plex length. If the contiguous length
is equal to or greater than the length of the associated volume, the
plex is considered complete, otherwise it is sparse.
-
I/O mode
-
Each plex is in read-write, read-only, or write-only mode. This
mode affects read and write operations directed to the volume, if the
plex is enabled. For read-write and read-only modes, volume read
operations can be directed to the plex. For read-write and write-only
modes, volume write operations are directed to the plex.
Plexes are normally in read-write mode. Write-only mode is used to
recover a plex that failed, and whose contents have thus become
out-of-date with respect to the volume. It is also used when
attaching a new plex to a volume. In write-only mode, writes to the
volume update the plex, causing written regions to be up-to-date.
Typically, a set of special copy operations is used to update the
remainder of the plex.
-
layout
-
The organization of associated subdisks with respect to the plex
address space. The layout is striped, concatenated, or RAID-5.
-
length
-
The length of a plex is the offset of the last subdisk in the plex plus
the length of that subdisk. In other words, the length of the plex
is defined by the last block in the plex address space that is backed
by a subdisk. This value may or may not relate to the length of the
volume, depending on whether the plex is completely contiguously
allocated.
-
log subdisk
-
Each plex can have at most one associated log subdisk. A log subdisk
is used with the dirty region logging
feature to improve the time required to recover consistency of a
volume after a system failure.
-
plex kernel state
-
Each plex is either enabled, disabled, or detached. When enabled,
normal read and write operations from the volume can be directed to
the plex. When disabled, no I/O operations are applied to the
plex. When detached, normal volume I/O are not directed to the
plex.
I/O failures encountered during normal volume I/O may move the enabled
state for a plex directly from enabled to detached. See the
description of volume exception policies (earlier in this manual page)
for more information.
-
subdisks
-
Each plex has zero or more associated subdisks. Subdisks are
associated at offsets relative to the beginning of the plex address
space. Subdisks for concatenated plexes may not cover the entire
length of the plex,
in which case they leave holes in the plex. A plex that is not as
long as the volume to which it is associated is considered to have a
hole extending from
the end of the plex to the end of the volume. A plex
with a hole is considered incomplete, and is
sometimes called sparse.
-
usage-type state
-
Volume usage types maintain a private state field related to the
the operations that have been performed on the plex, or to
failure conditions that have been encountered. This state field
contains a string of up to 14 characters.
-
volatile state
-
A plex is considered to have ``volatile'' contents if the disk for any
of the plex's subdisks is considered to be volatile. The contents of
a volatile disk are not presumed to survive a system reboot. The
contents of a volatile plex are always considered out-of-date after a
recovery and in need of complete recovery from another plex.
RLINK records define the characteristics of a particular RLINK of an RVG.
An RLINK can be in either an associated or dissociated state. In the
dissociated state, the RLINK is not part of any RVG. An associated RLINK
can be accessed through the RVG.
RLINK have the following fundamental attributes:
-
usage type
-
RLINK are treated internally as if they have a usage-type of gen, but this
distinction is largely irrelevant and exists merely to be compatible with
pre-existing Veritas Volume Manager code.
-
rlink kernel state
-
Each primary RLINK is either enabled, disabled or detached. When enabled,
normal write operations are forwarded to the remote RLINK. When disabled,
no I/O operations on the RLINK are allowed. When detached, normal
RVG I/O are not directed to the RLINK, but certain ioctls can be issued
against the RLINK. An enabled RLINK can also be either connected or
disconnected, depending on whether the network connection between the RLINKs
on the primary and secondary nodes is currently open or not.
-
usage-type state
-
RLINKs are treated as having a gen usage-type, and its usage-type state is a
private state field indicating the state of operations that have been performed
on the RLINK, or failure conditions that have been encountered.
This state field contains a string of up to 14 characters.
-
synchronous
-
A field that indicates whether the RLINK should operate in synchronous or
asynchronous mode. In synchronous mode, a write request to a replicated
volume does not complete until the data has been recorded on the SRL and
reached the secondary node. In asynchronous mode, a write request completes
as soon as the data is recorded on the SRL. The field may have one of three
values:
-
off
-
mode is asynchronous
-
override
-
mode is synchronous, but automatically switches to asynchronous
if the rlink becomes inactive due to a disconnection
or administrative action
-
fail
-
mode is synchronous. If synchronous=fail is set and an administrator detaches
the Primary RLINK, writes to the RVG are not failed. However, if an RLINK
becomes inactive for
any other reason, including an administrative detach of the Secondary RLINK,
subsequent write requests are failed with an EIO error.
-
local_host
-
RLINKs have a host_name attribute that contains the name of the local host
machine. Needed to support private networks.
-
remote_host
-
RLINKs have a remote_host attribute that contains the name of the remote
host machine from (primary) or to (secondary) which replication takes place.
-
remote_dg
-
RLINKs have a remote_rlink attribute that contains the name of the diskgroup
on the remote machine.
-
remote_rlink
-
RLINKs have a remote_rlink attribute that contains the name of the RLINK
counterpart on the remote machine.
-
comment
-
An administrator-assigned string of up to 40 characters that can be set and
changed using the vxedit utility. VxVM does not interpret
the comment field. The comment cannot contain newline characters.
-
latencyprot
-
A field that indicates whether latency protection is enabled for the RLINK.
Latency protection prevents a RLINK from having more than a preset number
of outstanding requests. All requests which have not been written to the
remote data volume are counted as outstanding. If latency protection is
enabled, then when the number of outstanding requests reaches
latency_high_mark, throttling is enabled. This causes all new write
requests to stall until throttling is disabled. Throttling is not
disabled until
the number of outstanding requests is reduced to latency_low_mark.
The field may have one of three values:
-
off
-
latency protection is disabled
-
override
-
latency protection is enabled, but is automatically disabled
if the RLINK becomes inactive due to a disconnection
or administrative action
-
fail
-
latency protection is enabled. If the RLINK becomes inactive
for any reason, and the latency_high_mark is reached,
subsequent write requests are failed with an EIO error.
-
srlprot
-
A field that indicates whether SRL protection is enabled for the RLINK. SRL
protection prevents an RLINK from overflowing the SRL, which causes the
RLINK to disconnect. If the RLINK has SRL protection enabled, and the next
write request would cause the RLINK to overflow the SRL, then throttling is
enabled. This causes all new write requests to stall until throttling
is disabled.
Throttling is not disabled until a predetermined amount of space is
available on the SRL. The exception to this is when the autodcm mode is set,
in which case, DCM protection is enabled as soon as the SRL overflows and
incoming write requests are not stalled.
The field may have one of five values:
-
off
-
SRL protection is disabled
-
override
-
SRL protection is enabled, but will automatically be disabled
if the RLINK becomes inactive due to a disconnection or
administrative action
-
fail
-
SRL protection is enabled. If the RLINK becomes inactive for
any reason, and SRL overflow is imminent, subsequent write
requests are failed with an EIO error.
-
autodcm
-
SRL protection is enabled. This is the default option for srlprot.
If an RLINK begins to overflow the SRL, DCM protection is activated.
-
dcm
-
SRL protection is enabled. This differs from the "autodcm" protection
in that the DCM protection is activated only when the RLINKs disconnect.
When the RLINKs are connected, incoming writes are throttled as described
above.
Note: When DCM protection is activated, the DCMs are used to record the
regions that change on the data volumes. The vxrvg command can be
used to resynchronize the images when the RLINKs are connected.
It should be noted that using DCM to resynchronize an image makes the
image inconsistent until the resynchronization completes.
-
latency_high_mark
-
Maximum number of outstanding requests when latency protection is
enabled.
-
latency_low_mark
-
After latency throttling is enabled, the number of outstanding requests must
drop to this before it is disabled.
RVG records define the characteristics of particular RVG
devices. The name of an RVG record defines the node name used for
files in the /dev/vx/dsk and /dev/vx/rdsk directories. The block
device for a particular RVG (which is unused in the current
implementation) has the path:
/dev/vx/dsk/groupname/rvg
where groupname is the name assigned by the administrator to the disk group
containing
the RVG. Note that the block device for a child data volume, not the RVG
itself, can be used as an argument to the mount command (see
mount(2)). The raw
device for an RVG, typically used for issuing I/O control operations
(see ioctl(2)), has the path:
/dev/vx/rdsk/groupname/rvg
Accesses to a data volume associated with a primary RVG device are internally
directed to the RVG so that replication can take place. The RVG device
nodes do not support the read(2) and write(2) system calls.
RVGs have the following fundamental attributes:
-
usage type
-
RVGs are treated internally as if they have a usage-type of gen,
but this distinction
is largely irrelevant and exists merely to be compatible with pre-existing
Veritas Volume Manager code.
-
rvg kernel state
-
Each primary RVG is either enabled, disabled or detached. When enabled,
normal read and write operations are allowed on the child data volumes
(assuming the underlying data volumes themselves are enabled) and those
accesses are reflected to the data volumes as well as to any active
RLINKs.
When disabled, no access to the data volumes or any of its associated
RLINKs is allowed. When detached, some ioctls can be used by utilities to
operate on the RVG.
-
usage-type state
-
RVGs are treated as having a gen usage-type, and its usage-type state is a
private state field indicating the state of operations that have been
performed
on the RVG, or failure conditions that have been encountered. This
state field contains a string of up to 14 characters.
-
datavols
-
List of data volumes associated with the RVG.
-
srl
-
Each RVG has one associated SRL volume.
-
rlink
-
Each primary RVG has between zero and thirty-two associated RLINK. Each
secondary RVG can have no more than one associated RLINK.
-
comment
-
An administrator-assigned string of up to 40 characters that can be set and
changed using the vxedit utility. VxVM does not interpret
the comment field. The comment cannot contain newline characters.
-
user|group|mode
-
These attributes are the user, group and file permission modes used for the
RVG device nodes. The user and group are normally root. The mode usually
allows read and write permission to the owner, and no access by other
users.
Subdisk records define a region of disk, allocated from a disk's
public region. Subdisks have very little state associated with them,
other than the configuration state that defines which region of disk
the subdisk occupies. Subdisks cannot overlap each other, either in
their associations with plexes, or in their arrangement on disk public
regions.
Subdisks have the following fundamental attributes:
-
comment
-
An administrator-assigned string of up to 40 characters that can be
set and changed using the vxedit utility. VxVM
does not interpret the comment field. The comment cannot contain
newline characters.
-
disk media name
-
The name of the disk media record that the subdisk is defined on.
-
disk offset
-
The offset, from the beginning of the disk's public region, to the
start of the subdisk.
-
length
-
The length of the subdisk.
-
plex offset
-
For associated subdisks, this is the offset (from the beginning of the
plex) of the subdisk association. For subdisks associated with
striped plexes, the plex offset defines relative ordering of subdisks
in the plex, rather than actual offsets within the plex address space.
Volume records define the characteristics of particular volume
devices. The name of a volume record defines the node name used for
files in the /dev/vx/dsk and /dev/vx/rdsk directories. The
block device for a particular volume (which can be used as an argument
to the mount command (see mount(1M)) has the path:
/dev/vx/dsk/
groupname/volume
where groupname is the name assigned by the administrator to the
disk group containing the volume. The raw device for a volume,
typically used for application I/O and for issuing I/O control
operations (see ioctl(2)), has the path:
/dev/vx/rdsk/
groupname/volume
Reads to a volume device are directed to one of the read-write or
read-only plexes associated with the volume. Writes to the volume are
directed to all of the enabled read-write and write-only plexes
associated with the volume.
During a write operation, two plexes of a volume may become out of
sync with each other, due to the fact that writes directed to two
disks can complete at different times. This is not normally a
problem. However, if the system were to crash or lose power during a
write operation, the two plexes could have different contents.
Most applications and file systems are not written with the
presumption that two separate reads of a device can return different
contents without an intervening write operation. Since plexes with
different contents could cause such a situation where two read
operations of a block return different contents, VxVM
expends considerable effort to ensure that this is avoided.
Volumes have the following fundamental attributes:
-
comment
-
An administrator-assigned string of up to 40 characters that can be set
and changed using the vxedit utility.
VxVM does not interpret the comment field.
The comment cannot contain newline characters.
-
exception policy
-
There are several modes that can be set on the volume, by utilities
according to the usage type of the volume. These modes
affect operation of a volume in the presence of I/O failures.
Currently only one of these policies, called GEN_DET_SPARSE is
ever used. This policy tracks complete and incomplete plexes in a
volume (an incomplete plex does not have a backing subdisk for all
blocks in the volume). If an unrecoverable error occurs on an
incomplete plex, the plex is detached (disabled from receiving
regular volume I/O requests). If an unrecoverable error occurs on a
complete plex, the plex is detached unless it is the last complete
plex. If the plex is the last complete read-write plex, any
incomplete plexes that overlap with the error are detached but the
plex with the error remains attached.
This default policy is chosen to ensure that an I/O that fails on one
plex is not directed to that plex again unless
that plex is the last complete plex remaining attached to the volume.
In that case, the policy ensures that the volume returns the error
consistently, even in the presence of incomplete plexes.
-
length
-
Each volume has a length, which defines the limiting offset of read
and write operations. The length is assigned by the administrator,
and may or may not match the lengths of the associated plexes.
-
log type
-
A policy to use for logging changes to the volume, which can be
assigned by the administrator. Policies that can be specified are:
-
none
-
Do not perform any special actions when writing to the volume. Just
write the requested data to all read-write or write-only plexes.
-
dirty-region-log
-
A volume is divided into regions. A bitmap where each bit corresponds to a
region is maintained. When a write to a particular region occurs, the
respective bit is set to on. When the system is restarted after a crash, this
region bitmap is used to limit the amount of data copying that is
required to recover plex consistency for the volume. The region
changes are logged to special log subdisks associated with
each of the plexes associated with the volume. Use of
dirty region logging can greatly speed recovery of a volume, but it
also degrades performance of the volume under
normal operation.
-
dcm
-
A bit-map representing regions of a volume that is used to track
changes to that volume. it is used by VVR for srl overflow
protection and automatic secondary synchronization.
-
plexes
-
Each volume has between zero and 32 associated plexes.
-
primary_datavol
-
A name field. This field is only used with secondary volumes. The value
indicates the name of the data volume on the primary to which this data
volume corresponds.
-
read policy
-
A configurable policy for switching between plexes for volume reads.
When a volume has more than one enabled associated plex,
VxVM can distribute reads between the plexes to distribute the I/O
load and thus increase total possible bandwidth of reads through the
volume.
The read policy can be set by the administrator. Possible policies are:
-
preferred plex
-
This read policy specifies a particular named plex that is used to
satisfy read requests. In the event that a read request cannot be
satisfied by the preferred plex, this policy changes to round-robin.
-
round-robin
-
For every other read operation, distribute the operation
across all of the available plexes. Given three plexes, this
switches between each of the three plexes,
so each plex gets one third of the read requests.
-
select
-
This read policy is the default policy, and adjusts to use an
appropriate read policy based on the set of plexes associated with the
volume. If exactly one enabled read-write striped plex is associated
with the volume, then that plex is chosen automatically as the
preferred plex; otherwise, the round-robin policy is used. If a volume
has one striped plex and one non-striped plex, preferring the striped
plex often yields better throughput.
-
read/write-back recover mode
-
This is a mode that applies to the volume, which is managed by
utilities as part of plex consistency recovery. When this mode is
enabled, each read operation recovers plex consistency for the
region covered by the read. Plex consistency is recovered by reading
data from blocks of one plex and writing that data to all other
writable plexes. This ensures that a future read operation covering
the same range of blocks reads the same data.
-
start options
-
This is a string that is organized as a set of usage-type options to
apply when starting (enabling) a volume. See vxvol(1M) for
details.
-
usage type
-
Each volume has a usage type that defines a particular class of
rules for operating on the volume. The usage type is
typically based on the expected content of the volume.
Several Veritas Volume Manager utilities can apply extensions or
limitations that apply to volumes with a particular usage type.
Several basic usage types are included with VxVM:
fsgen, for use with volumes that contain file systems;
gen, for use with volumes that are used as swap devices or for
other applications that do not use file systems;
raid5, for use with RAID-5 volumes;
and special root and swap
usage types, which are specifically for use with the
root file system volume and the primary swap device.
-
usage-type state
-
Usage types maintain a private state field related to the volume that
relate to operations that have been performed on the volume, or to
failure conditions that have been encountered. This state field
contains a string of up to 14 characters.
-
user|group|mode
-
These attributes are the user, group, and file permission modes used for
the volume device nodes.
The user and group are normally root. The mode usually
allows read and write permission to the owner, and no access by other
users.
-
volume kernel state
-
Each volume is either enabled, disabled, or detached. When enabled,
normal read and write operations are allowed on the volume, and any file
system residing on the
volume can be mounted, or used in the usual way. When
disabled, no access to the volume or any of its associated plexes is
allowed.
-
write-back-on-read-failure mode
-
This is a mode that applies to the volume, which can be enabled or
disabled by the administrator using vxedit. If this mode is
enabled, then a read failure for a plex causes data to be read
from an alternate plex and then written back to the plex that got the
read failure. This usually fixes the error. Only if the writeback
fails is the plex detached for having an unrecoverable I/O
failure.
-
writecopy mode
-
This is a mode that applies to the volume, which can be enabled or
disabled by the administrator using vxedit. This mode takes
affect only if dirty region logging or RAID-5 logging
is in effect. When the operating
system hands off a write request to the volume driver, the operating
system may continue to change the memory that is being written to
disk. VxVM cannot detect that the memory is changing,
so it can inadvertently leave plexes with inconsistent contents.
This is not normally a problem, because the operating system ensures
that any such modified memory is rewritten to the volume before the
volume is closed (such as by a clean system shutdown). However, if the
system crashes, plexes may be inconsistent. Since the
logging feature prevents recovery of the entire volume,
it may not ensure that plexes are entirely consistent.
Turning on the writecopy mode (which is normally set by default)
often causes VxVM to copy the data for a write
request to a new section of memory before writing it to disk. Because
the write is done from the copied memory, it cannot change and so the
data written to each plex is guaranteed to be the same if the write
completes.
See the vxedit(1M) manual page for more information.
The usage type of a volume represents a class of rules for operating
on a volume. Each usage type is defined by a set of executables under
the directory /etc/vx/type/usage_type, where
usage_type is the name given to the usage type. The required
executables are: vxinfo, vxmake, vxmend,
vxplex, vxsd, and vxvol. These executables are
invoked by Veritas Volume Manager administrative utilities with the same
names. The executables under /etc/vx/type should not,
normally, be executed directly.
Five usage types are provided with VxVM:
gen,
fsgen, root, swap, and raid5.
It is possible for
third-party products to install additional usage types.
The usage types provided with VxVM store state
information in the RVG, RLINK, volume, and plex usage-type state fields.
The state fields defined for RVGs are:
-
EMPTY
-
The RVG is not yet initialized. This is the initial state for RVGs
created by vxmake.
-
CLEAN
-
The RVG has been stopped and contains consistent data.
-
ACTIVE
-
The RVG has been started and is running normally, or was running when
the system
was stopped. If the system stops in this state, then the RVG may require
RLINK recovery.
-
FAIL
-
Some problem has been detected with the RVG. It is disabled.
The state fields defined for RLINKs are:
-
UNASSOC
-
The RLINK is not fully initialized. This is the initial state for RLINKs
created by vxmake, or which are not currently associated with an RVG.
-
STALE
-
The RLINK is associated with an RVG, but it is not actively taking
part in replication.
RLINK requires a full resync before it is up to date, unless the RVG is
EMPTY.
-
ACTIVE
-
The RLINK is associated and actively replicating normally, or was when
the system was stopped.
-
PAUSING
-
The RLINK is transitioning to the PAUSE state, or was doing so when the
system
was stopped. If the system stops in this state, then the RLINK must be
reattached
to put it back into the proper PAUSE state.
-
PAUSE
-
The RLINK is paused. If it is a primary (secondary) RLINK and was paused by
the pause
command, vxrlink pause, then it is said to be primary-paused
(secondary-paused).
A secondary RLINK can also enter the secondary-paused state
if an error is detected with a secondary log or data volume.
-
RESTORING
-
Temporary state while RLINK is being restored (see vxrlink(1M)
restore sub-command).
-
RECOVER
-
Temporary state while RLINK is being recovered with the vxrecover
utility,
which calls vxrlink recover. This state indicates that recovery
is still needed.
-
FAIL
-
Some problem has been detected with the RLINK. It is disabled.
The state fields defined for volumes are:
-
ACTIVE
-
The volume has been started and is running normally, or was running
normally when the system was stopped. If the system crashes in this
state, then the volume may require plex consistency recovery.
-
CLEAN
-
The volume has been stopped and the contents for all plexes are
consistent.
-
EMPTY
-
The volume is not yet initialized. This is the initial state for
volumes created by vxmake.
-
INVALID
-
The contents of an instant snapshot volume no longer represent a
true point-in-time image of the original volume.
-
NEEDSYNC
-
The volume requires recovery. This is typically set after a system
failure to indicate that the plexes in the volume may be inconsistent,
so that they require recovery (see the resync operation in
vxvol(1M)).
-
SYNC
-
Plex consistency recovery is currently being done on the volume.
vxvol resync sets this state when it starts to recovery plex
consistency on a volume that was in the NEEDSYNC state.
The state fields defined for plexes are:
-
ACTIVE
-
The plex is running normally on a started volume. The plex condition
flags (NODAREC, REMOVED, RECOVER, and IOFAIL)
may apply if the system is rebooted and the volume restarted.
-
CLEAN
-
The plex was running normally when the volume was stopped. The plex
is enabled without requiring recovery when the volume is started.
-
DCOSNP
-
This state indicates that a data change object (DCO) plex
attached to a volume can be used by a snapshot plex to create
a DCO volume during a snapshot operation.
-
EMPTY
-
The plex is not yet initialized. This state is set when the volume
state is also EMPTY.
-
LOG
-
A dirty region logging (DRL) or RAID-5 log plex.
-
OFFLINE
-
The plex was disabled by the vxmend off operation. See
vxmend(1M) for more information.
-
SNAPATT
-
This is a snapshot plex that is being attached by the vxassist
snapstart operation. When the attach is complete, the state for
the plex is changed to SNAPDONE. If the system fails
before the attach completes, the plex and all of its subdisks are removed.
-
SNAPDIS
-
This is a snapshot plex created by vxplex snapstart that is
fully attached. A plex in this state can be turned into a snapshot
volume with vxplex snapshot. See vxplex(1M) for more
information. If the system fails before the attach completes, the plex
is dissociated from the volume.
-
SNAPDONE
-
This is a snapshot plex created by vxassist snapstart that is
fully attached. A plex in this state can be turned into a snapshot
volume with vxassist snapshot. See vxassist(1M) for more
information. If the system fails before the attach completes, the plex
and all of its subdisks are removed.
-
SNAPTMP
-
This is a snapshot plex being attached by the vxplex snapstart
operation. When the attach is complete, the state for the plex is
changed to SNAPDIS. If the system fails before the attach
completes, the plex is dissociated from the volume.
-
STALE
-
The plex was detached, either by vxplex det or by an I/O
failure. vxvol start changes the state for a plex to
STALE if any of the plex condition flags are set. STALE
plexes are reattached automatically, when starting a volume,
by calling vxplex att.
-
TEMP
-
This is a plex that is being associated and attached to a volume with
vxplex att. If the system fails before the attach completes,
the plex is dissociated from the volume.
-
TEMPRM
-
This is a plex that is being associated and attached to a volume with
vxplex att. If the system fails before the attach completes,
the plex is dissociated from the volume and removed. Any subdisks
in the plex are kept.
-
TEMPRMSD
-
This is a plex that is being associated and attached to a volume with
vxplex att. If the system fails before the attach completes,
the plex and its subdisks are dissociated from the volume and removed.
The majority of Veritas Volume Manager utilities use a common set of exit
codes, which can be used by shell scripts or other types of programs
to react to specific problems detected by the utilities.
The number
for each distinct exit
code is described below.
-
0
-
The utility is not reporting any error through the exit code.
-
1
-
Some command line arguments to the utility were invalid.
-
2
-
A syntax error occurred in a command or description, or a specified
record name is too long or contains invalid characters. This code is
returned only by utilities that implement a command or description
language. This code may also be returned for errors in search
patterns.
-
3
-
The volume daemon does not appear to be running.
-
4
-
An unexpected error was encountered while communicating with the
volume daemon.
-
5
-
An unexpected error was returned by a system call or by the C library.
This can also indicate that the utility ran out of memory.
-
6
-
The status for a commit was lost because the volume daemon was killed
and restarted during the commit of a transaction, but after restart
the volume daemon did not know whether the commit succeeded or failed.
-
7
-
The utility encountered an error that it should not have encountered.
This generally implies a condition that the utility should have tested
for but did not, or a condition that results from the volume daemon
returning a value that did not make sense.
-
8
-
The time required to complete a transaction exceeded 60 seconds,
causing the transaction locks to be lost. As most utilities
reattempt the transaction at least once if a timeout occurs, this
usually implies that a transaction timed out two or more times.
-
9
-
No disk group could be identified for an operation. This results
either from naming a disk group that does not exist, or from supplying
names on a command line that are in different disk groups or
in multiple disk groups.
-
10
-
A change made to the database by another process caused the utility to
stop. This code is also returned by a usage-type-dependent utility if
it is given a record that is associated with a different usage type.
If this situation occurs when the usage-type-dependent utility is
called from a switchout utility, then the database was changed after
the switchout utility determined the proper usage type to invoke.
-
11
-
A requested subdisk, plex, or volume record was not found in the
configuration database. This may also mean that a record was an
inappropriate type.
-
12
-
A name used to create a new configuration record matches the name of
an existing record.
-
13
-
A subdisk, plex, or volume is locked against concurrent access. This
code is used for inter-transaction locks associated with usage type
utilities. The code is also used for the dissociated plex or subdisk
lock convention, which writes a non-blank string to the tutil[0]
field in a plex or subdisk structure to indicate that the record is
being used.
-
14
-
No usage type could be determined for a utility that requires a usage
type.
-
15
-
An unknown or invalid usage type was specified.
-
16
-
A plex or subdisk is associated, but the operation requires a
dissociated record.
-
17
-
A plex or subdisk is dissociated, but the operation requires an
associated record. This code can also be used to indicate that a
subdisk or plex is not associated with a specific plex or volume.
-
18
-
A plex or subdisk was not dissociated because it was the last record
associated with a volume or plex.
-
19
-
Association of a plex or subdisk would surpass the maximum number that
can be associated to a volume or plex.
-
20
-
A specified operation is invalid within the parameters specified.
For example,
this code is returned when an attempt is made to split a
subdisk on a striped plex, or to use a split size that is greater than
the size of the plex.
-
21
-
An I/O error was encountered that caused the utility to abort an
operation.
-
22
-
A volume involved in an operation did not have any associated plexes,
although at least one was required.
-
23
-
A plex involved in an operation did not have any associated subdisks,
although at least one was required.
-
24
-
A volume could not be started by the vxvol start operation,
because the configuration of the volume and its plexes prevented the
operation.
-
25
-
A specified volume was already started.
-
26
-
A specified volume was not started. For example, this code is
returned by the vxvol stop operation if the operation is given
a volume that is not started.
-
27
-
A volume or plex involved in an operation is in the detached state,
thus preventing a successful operation.
-
28
-
A volume or plex involved in an operation is in the disabled state,
thus preventing a successful operation.
-
29
-
A volume or plex involved in an operation is in the enabled state,
thus preventing a successful operation.
-
30
-
An unknown error condition was encountered.
This code may be used, for example,
when the volume daemon returns an unrecognized error number.
-
31
-
An operation failed because a volume device was open or
mounted, or because a subdisk was associated with an open or mounted
volume or plex.
-
32
-
A problem occurred with multipath coordination.
-
33
-
An object was already reserved for use by the operating system.
-
35
-
An error occurred while communicating with a remote host.
-
39
-
An error occurred because the offset or length of a VxVM object is
not an integral multiple of the alignment value for the disk group.
-
65
-
An array-related API failed.
-
66
-
An array-specific guideline was violated.
-
67
-
Inconsistent configuration copies are present in a disk group.
This may indicate a serial split brain condition.
-
68
-
FastResync is not enabled on a volume.
-
69
-
A volume has a bad Data Change Object (DCO).
-
70
-
A snapshot volume is invalid.
-
71
-
A Replicated Volume Group (RVG) has not been started.
Exit codes greater than 32 are reserved for use by usage types.
Codes greater than 64 are reserved for use by specific utilities.
mount(1M),
vxassist(1M),
vxcache(1M),
vxcached(1M),
vxcdsconvert(1M),
vxcmdlog(1M),
vxconfigbackup(1M),
vxconfigbackupd(1M),
vxconfigd(1M),
vxconfigrestore(1M),
vxdctl(1M),
vxdco(1M),
vxddladm(1M),
vxdg(1M),
vxdisk(1M),
vxdiskadd(1M),
vxdiskadm(1M),
vxdisksetup(1M),
vxdiskunsetup(1M),
vxdmpadm(1M),
vxedit(1M),
vxevac(1M),
vxinfo(1M),
vxiod(1M),
vxlicinst(1),
vxlicrep(1),
vxmake(1M),
vxmend(1M),
vxmirror(1M),
vxnotify(1M),
vxplex(1M),
vxprint(1M),
vxr5check(1M),
vxreattach(1M),
vxrecover(1M),
vxrelayout(1M),
vxrelocd(1M),
vxresize(1M),
vxrlink(1M),
vxrvg(1M),
vxsd(1M),
vxsparecheck(1M),
vxsnap(1M),
vxsplitlines(1M),
vxstat(1M),
vxtask(1M),
vxtrace(1M),
vxtranslog(1M),
vxvol(1M),
vxvoladm(1M),
vxvset(1M)
ioctl(2)
vol_pattern(4),
vxmake(4)
vxio(7),
vxinfo(7)
For information about new features of VxVM, see the
Release Notes.
For information about VxVM features and administering VxVM, see the
Veritas Volume Manager Administrator's Guide and the
Veritas Storage Foundation Intelligent Storage Provisioning
Administrator's Guide.
Last updated: 18 Oct 2005
Copyright ©2009 Symantec Corporation
All rights reserved.