18 Managing Multipath I/O for Devices #
This section describes how to manage failover and path load balancing for multiple paths between the servers and block storage devices by using Multipath I/O (MPIO).
18.1 Understanding Multipath I/O #
Multipathing is the ability of a server to communicate with the same physical or logical block storage device across multiple physical paths between the host bus adapters in the server and the storage controllers for the device, typically in Fibre Channel (FC) or iSCSI SAN environments.
Linux multipathing provides connection fault tolerance and can provide load balancing across the active connections. When multipathing is configured and running, it automatically isolates and identifies device connection failures, and reroutes I/O to alternate connections.
Multipathing provides fault tolerance against connection failures, but not against failures of the storage device itself. The latter is achieved with complementary techniques like mirroring.
18.1.1 Multipath terminology #
- Storage array
A hardware device with many disks and multiple fabrics connections (controllers) that provides SAN storage to clients. Storage arrays typically have RAID and failover features and support multipathing. Historically, active/passive (failover) and active/active (load-balancing) storage array configurations were distinguished. These concepts still exist but they are merely special cases of the concepts of path groups and access states supported by modern hardware.
- Host, host system
The computer running SUSE Linux Enterprise Server which acts as a client system for a storage array.
- Multipath map, multipath device
A set of path devices. It represents a storage volume on a storage array and is seen as a single block device by the host system.
- Path device
A member of a multipath map, typically a SCSI device. Each path device represents a unique connection between the host computer and the actual storage volume, for example, a logical unit from an iSCSI session.
- WWID
“World Wide Identifier”.
multipath-tools
uses the WWID to determine which low-level devices should be assembled into a multipath map. The WWID must be distinguished from the configurable map name (see Section 18.12, “Multipath device names and WWIDs”).- uevent, udev event
An event sent by the kernel to user space and processed by the
udev
subsystem. Uevents are generated when devices are added, removed, or change their properties.- Device mapper
A framework in the Linux kernel for creating virtual block devices. I/O operations to mapped devices are redirected to the underlying block devices. Device mappings may be stacked. The device mapper implements its own event signaling, also known as “device mapper events” or “dm events”.
- initramfs
The initial RAM file system, also referred to as “initial RAM disk” (initrd) for historical reasons (see Section 12.1, “Terminology”).
- ALUA
“Asymmetric Logical Unit Access”, a concept introduced with the SCSI standard SCSI-3. Storage volumes can be accessed via multiple ports, which are organized in port groups with different states (active, standby, etc.). ALUA defines SCSI commands to query the port groups and their states and change the state of a port group. Modern storage arrays that support SCSI usually support ALUA, too.
18.2 Hardware Support #
The multipathing drivers and tools are available on all architectures supported by SUSE Linux Enterprise Server. The generic, protocol-agnostic driver works with most multipath-capable storage hardware on the market. Some storage array vendors provide their own multipathing management tools. Consult the vendor’s hardware documentation to determine what settings are required.
18.2.1 Multipath implementations: device mapper and NVMe #
The traditional, generic implementation of multipathing under Linux uses the device mapper framework. For most device types like SCSI devices, device mapper multipathing is the only available implementation. Device mapper multipath is highly configurable and flexible.
The Linux NVM Express (NVMe) kernel subsystem implements multipathing natively in the kernel. This implementation creates less computational overhead for NVMe devices, which are typically fast devices with very low latencies. Native NVMe multipathing requires no user space component. Since SLE 15, native multipathing has been the default for NVMe multipath devices. For details, refer to Section 17.2.4, “Multipathing”.
This chapter documents device mapper multipath and its user-space
component, multipath-tools
.
multipath-tools
also has limited support for
native NVMe multipathing (see
Section 18.13, “Miscellaneous options”).
18.2.2 Storage array autodetection for multipathing #
Device mapper multipath is a generic technology. Multipath device detection requires only that the low-level (for example, SCSI) devices are detected by the kernel, and that device properties reliably identify multiple low-level devices as being different “paths” to the same volume rather than actually different devices.
The multipath-tools
package detects storage arrays by
their vendor and product names. It provides built-in configuration defaults
for a large variety of storage products. Consult the hardware documentation
of your storage array: some vendors provide specific recommendations for
Linux multipathing configuration.
If you need to apply changes to the built-in configuration for your storage array, read Section 18.8, “Multipath configuration”.
multipath-tools
has built-in presets for many storage
arrays. The existence of such presets for a given storage product
does not imply that the vendor of the storage product
has tested the product with dm-multipath
, nor
that the vendor endorses or supports the use of
dm-multipath
with the product. Always consult the
original vendor documentation for support-related questions.
18.2.3 Storage Arrays that Require Specific Hardware Handlers #
Some storage arrays require special commands for failover from one path to the other, or non-standard error-handling methods. These special commands and methods are implemented by hardware handlers in the Linux kernel. Modern SCSI storage arrays support the “Asymmetric Logical Unit Access” (ALUA) hardware handler defined in the SCSI standard. Besides ALUA, the SLE kernel contains hardware handlers for Netapp E-Series (RDAC), the Dell/EMC CLARiiON CX family of arrays, and legacy arrays from HP.
Since Linux kernel 4.4, the Linux kernel has automatically detected
hardware handlers for most arrays, including all arrays supporting ALUA.
The only requirement is that the device handler modules are loaded at the
time the respective devices are probed. The
multipath-tools
package ensures this by installing
appropriate configuration files. Once a device handler is attached to a
given device, it cannot be changed anymore.
18.3 Planning for Multipathing #
Use the guidelines in this section when planning your multipath I/O solution.
18.3.1 Prerequisites #
The storage array you use for the multipathed device must support multipathing. For more information, see Section 18.2, “Hardware Support”.
You need to configure multipathing only if multiple physical paths exist between host bus adapters in the server and host bus controllers for the block storage device.
For some storage arrays, the vendor provides its own multipathing software to manage multipathing for the array’s physical and logical devices. In this case, you should follow the vendor’s instructions for configuring multipathing for those devices.
When using multipathing in a virtualization environment, the multipathing is controlled in the host server environment. Configure multipathing for the device before you assign it to a virtual guest machine.
18.3.2 Multipath installation types #
We distinguish installation types by the way the root device is handled. Section 18.4, “Installing SUSE Linux Enterprise Server on multipath systems” describes how the different setups are created during and after installation.
18.3.2.1 Root file system on multipath (SAN-boot) #
The root file system is on a multipath device. This is typically the case for diskless servers that use SAN storage exclusively. On such systems, multipath support is required for booting, and multipathing must be enabled in the initramfs.
18.3.2.2 Root file system on a local disk #
The root file system (and possibly some other file systems) is on local storage, for example, on a directly attached SATA disk or local RAID, but the system additionally uses file systems in the multipath SAN storage. This system type can be configured in three different ways:
- Multipath setup for local disk
All block devices are part of multipath maps, including the local disk. The root device appears as a degraded multipath map with just one path. This configuration is created if multipathing was enabled during the initial system installation with YaST.
- Local disk is excluded from multipath
In this configuration, multipathing is enabled in the initramfs, but the root device is explicitly excluded from multipath (see Section 18.11.1, “The
blacklist
section inmultipath.conf
”). Procedure 18.1, “Disabling multipathing for the root disk after installation” describes how to set up this configuration.- Multipath disabled in the initramfs
This setup is created if multipathing was not enabled during the initial system installation with YaST. This configuration is rather fragile; consider using one of the other options instead.
18.3.3 Disk Management Tasks #
Use third-party SAN array management tools or the user interface of your storage array to create logical devices and assign them to hosts. Make sure to configure the host credentials correctly on both sides.
You can add or remove volumes to a running host, but detecting the changes may require rescanning SCSI targets and reconfiguring multipathing on the host. See Section 18.14.6, “Scanning for new devices without rebooting”.
On some disk arrays, the storage array manages the traffic through storage processors. One processor is active and the other one is passive until there is a failure. If you are connected to the passive storage processor, you might not see the expected LUNs, or you might see the LUNs but encounter I/O errors when you try to access them.
If a disk array has more than one storage processor, ensure that the SAN switch has a connection to the active storage processor that owns the LUNs you want to access.
18.3.4 Software RAID and complex storage stacks #
Multipathing is set up on top of basic storage devices such as SCSI disks. In a multi-layered storage stack, multipathing is always the bottom layer. Other layers such as software RAID, Logical Volume Management, block device encryption, etc. are layered on top of it. Therefore, for each device that has multiple I/O paths and that you plan to use in a software RAID, you must configure the device for multipathing before you attempt to create the software RAID device.
18.3.5 High-Availability Solutions #
High-availability solutions for clustering storage resources run on top of
the multipathing service on each node. Make sure that the configuration
settings in the /etc/multipath.conf
file on each node
are consistent across the cluster.
Make sure that multipath devices have the same name across all devices. Refer to Section 18.12, “Multipath device names and WWIDs” for details.
The Distributed Replicated Block Device (DRBD) high-availability solution for mirroring devices across a LAN runs on top of multipathing. For each device that has multiple I/O paths and that you plan to use in a DRDB solution, you must configure the device for multipathing before you configure DRBD.
Special care must be taken when using multipathing together with clustering
software that relies on shared storage for fencing, such as
pacemaker
with sbd
. See
Section 18.9.2, “Queuing policy on clustered servers” for details.
18.4 Installing SUSE Linux Enterprise Server on multipath systems #
No special installation parameters are required for the installation of SUSE Linux Enterprise Server on systems with multipath hardware.
18.4.1 Installing without connected multipath devices #
You may want to perform installation on a local disk, without configuring
the fabric and the storage first, with the intention to add multipath SAN
devices to the system later. In this case, the installation will proceed
like on a non-multipath system. After installation,
multipath-tools
will be installed, but the
systemd
service multipathd.service
will be disabled.
The system will be configured as described in
Multipath disabled in the initramfs in
Section 18.3.2.2, “Root file system on a local disk”. Before adding SAN
hardware, you will need to enable and start
multipathd.service
. We recommend creating a
blacklist
entry in the
/etc/multipath.conf
for the root device (see
Section 18.11.1, “The blacklist
section in multipath.conf
”).
18.4.2 Installing with connected multipath devices #
If multipath devices are connected to the system at installation time, YaST will detect them and display a pop-up window asking you whether multipath should be enabled before entering the partitioning stage.
If you select “No” at this prompt (not recommended), the installation will proceed as in Section 18.4.1, “Installing without connected multipath devices”. In the partitioning stage, do not use/edit devices that will later be part of a multipath map.
If you select “Yes” at the multipath prompt,
multipathd
will run during the installation. No device
will be added to the blacklist
section of
/etc/multipath.conf
, thus all SCSI and DASD devices,
including local disks, will appear as multipath devices in the partitioning
dialogs. After installation, all SCSI and DASD devices will be multipath
devices, as described in
Section 18.3.2.1, “Root file system on multipath (SAN-boot)”.
This procedure assumes that you installed on a local disk and enabled multipathing during installation, so that the root device is on multipath now, but you prefer to set up the system as described in Local disk is excluded from multipath in Section 18.3.2.2, “Root file system on a local disk”.
Check your system for
/dev/mapper/...
references to your local root device, and replace them with references that will still work if the device is not a multipath map anymore (see Section 18.12.4, “Referring to multipath maps”). If the following command finds no references, you do not need to apply changes:>
sudo
grep -rl /dev/mapper/ /etcSwitch to
by-uuid
persistent device policy fordracut
(see Section 18.7.4.2, “Persistent device names in the initramfs”):>
echo 'persistent_policy="by-uuid"' | \ sudo tee /etc/dracut.conf.d/10-persistent-policy.confDetermine the WWID of the root device:
>
multipathd show paths format "%i %d %w %s" 0:2:0:0 sda 3600605b009e7ed501f0e45370aaeb77f IBM,ServeRAID M5210 ...This command prints all paths devices with their WWIDs and vendor/product information. You will be able to identify the root device (here, the ServeRAID device) and note the WWID.
Create a blacklist entry in
/etc/multipath.conf
(see Section 18.11.1, “Theblacklist
section inmultipath.conf
”) with the WWID you just determined (do not apply these settings just yet):blacklist { wwid 3600605b009e7ed501f0e45370aaeb77f }
Rebuild the initramfs:
>
sudo
dracut -fReboot. Your system should boot with a non-multipath root disk.
18.5 Updating SLE on multipath systems #
When updating your system online, you can proceed as described in Chapter 5, Upgrading Online.
The offline update of your system is similar to the fresh installation as
described in Section 18.4, “Installing SUSE Linux Enterprise Server on multipath systems”. There is no
blacklist
, thus if the user selects to enable multipath,
the root device will appear as a multipath device, even if it is normally
not. When dracut
builds the initramfs during the update
procedure, it sees a different storage stack as it would see on the booted
system. See Section 18.7.4.2, “Persistent device names in the initramfs” and
Section 18.12.4, “Referring to multipath maps”.
18.6 Multipath management tools #
The multipathing support in SUSE Linux Enterprise Server is based on the Device Mapper
Multipath module of the Linux kernel and the
multipath-tools
user space package.
The generic multipathing capability is handled by the Device Mapper Multipath (DM-MP) module. For details, refer to Section 18.6.1, “Device Mapper Multipath Module”.
The packages multipath-tools
and
kpartx
provide tools that handle
automatic path discovery and grouping. The tools are the following:
multipathd
The daemon to set up and monitor multipath maps, and a command-line client to communicate with the daemon process. See Section 18.6.2, “The
multipathd
daemon”.multipath
The command-line tool for multipath operations. See Section 18.6.3, “The
multipath
command”.kpartx
The command-line tool for managing “partitions” on multipath devices. See Section 18.7.3, “Partitions on multipath devices and
kpartx
”.mpathpersist
The command-line tool for managing SCSI persistent reservations. See Section 18.6.4, “SCSI persistent reservations and
mpathpersist
”.
18.6.1 Device Mapper Multipath Module #
The Device Mapper Multipath (DM-MP) module
dm-multipath.ko
provides the generic multipathing
capability for Linux. DM-MPIO is the preferred solution for multipathing on
SUSE Linux Enterprise Server for SCSI and DASD devices, and can be used for NVMe devices
as well.
Since SUSE Linux Enterprise Server 15, native NVMe multipathing (see
Section 18.2.1, “Multipath implementations: device mapper and NVMe”) has been
recommended for NVMe and used by default. To disable native NVMe
multipathing and use device mapper multipath instead (not
recommended), boot with the kernel parameter
nvme-core.multipath=0
.
The Device Mapper Multipath module handles the following tasks:
Distributing load over multiple paths inside the active path group.
Noticing I/O errors on path devices, and marking these as failed, so that no I/O will be sent to them.
Switching path groups when all paths in the active path group have failed.
Either failing or queuing I/O on the multipath device if all paths have failed, depending on configuration.
The following tasks are handled by the user-space components in the
multipath-tools
package, not by the Device Mapper
Multipath module:
Discovering devices representing different paths to the same storage device and assembling multipath maps from them.
Collecting path devices with similar properties into path groups.
Monitoring path devices actively for failure or reinstantiation.
Monitoring of addition and removal of path devices.
The Device Mapper Multipath module does not provide an easy-to-use user interface for setup and configuration.
For details about the components from the
multipath-tools
package, refer to
Section 18.6.2, “The multipathd
daemon”.
DM-MPIO protects against failures in the paths to the device, and not failures in the device itself, such as media errors. The latter kind of errors must be prevented by other means, such as replication.
18.6.2 The multipathd
daemon #
multipathd
is the most important part of a modern Linux
device mapper multipath setup. It is normally started through the systemd
service multipathd.service
(see
Section 18.7.1, “Enabling, starting, and stopping multipath services”).
multipathd
serves the following tasks (some of them
depend on the configuration):
On startup, detects path devices and sets up multipath maps from detected devices.
Monitors uevents and device mapper events, adding or removing path mappings to multipath maps as necessary and initiating failover or failback operations.
Sets up new maps on the fly when new path devices are discovered.
Checks path devices at regular intervals to detect failure, and tests failed paths to reinstate them if they become operational again.
When all paths fail,
multipathd
either fails the map, or switches the map device to queuing mode for a given time interval.Handles path state changes and switches path groups or regroups paths, as necessary.
Tests paths for “marginal” state, i.e. shaky fabrics conditions that cause path state flipping between operational and non-operational.
Handles SCSI persistent reservation keys for path devices if configured. See Section 18.6.4, “SCSI persistent reservations and
mpathpersist
”.
multipathd
also serves as a command-line client to
process interactive commands by sending them to the running daemon. The
general syntax to send commands to the daemon is as follows:
>
sudo
multipathd COMMAND
or
>
sudo
multipathd -k'COMMAND'
There is also an interactive mode that allows sending multiple subsequent commands:
>
sudo
multipathd -k
Many multipathd
commands have
multipath
equivalents. For example, multipathd
show topology
does the same thing as multipath
-ll
. The notable difference is that the multipathd command
inquires the internal state of the running multipathd
daemon, whereas multipath obtains information directly from the kernel and
I/O operations.
If the multipath daemon is running, we recommend making modifications to
the system by using the multipathd
commands. Otherwise,
the daemon may notice configuration changes and react to them. In some
situations, the daemon might even try to undo the applied changes.
multipath
automatically delegates certain possibly
dangerous commands, like destroying and flushing maps, to
multipathd
if a running daemon is detected.
The list below describes frequently used multipathd
commands:
- show topology
Shows the current map topology and properties. See Section 18.14.2, “Interpreting multipath I/O status”.
- show paths
Shows the currently known path devices.
- show paths format "FORMAT STRING"
Shows the currently known path devices using a format string. Use
show wildcards
to see a list of supported format specifiers.- show maps
Shows the currently configured map devices.
- show maps format FORMAT STRING
Shows the currently configured map devices using a format string. Use
show wildcards
to see a list of supported format specifiers.- show config local
Shows the current configuration that multipathd is using.
- reconfigure
Rereads configuration files, rescans devices, and sets up maps again. This is basically equivalent to a restart of
multipathd
. A few options cannot be modified without a restart. They are mentioned in the man pagemultipath.conf(5)
. Thereconfigure
command reloads only map devices that have changed in some way.- del map MAP DEVICE NAME
Unconfigure and delete the given map device and its partitions. MAP DEVICE NAME can be a device node name like
dm-0
, a WWID, or a map name. The command fails if the device is in use.- switchgroup map MAP DEVICE NAME group N
Switch to the path group with the given numeric index (starting at 1). This is useful for maps with manual failback (see Section 18.9, “Configuring policies for failover, queuing, and failback”).
Additional commands are available to modify path states, enable or disable
queuing, and more. See multipathd(8)
for details.
18.6.3 The multipath
command #
Even though multipath setup is mostly automatic and handled by
multipathd
, multipath
is still useful
for some administration tasks. Several examples of the command usage
follow:
- multipath
Detects path devices and and configures all multipath maps that it finds.
- multipath -d
Similar to
multipath
, but does not set up any maps (“dry run”).- multipath DEVICENAME
Configures a specific multipath device. DEVICENAME can denote a member path device by its device node name (
/dev/sdb
) or device number inmajor:minor
format. Alternatively, it can be the WWID or name of a multipath map.- multipath -f DEVICENAME
Unconfigures ("flushes") a multipath map and its partition mappings. The command will fail if the map or one of its partitions is in use. See above for possible values of DEVICENAME.
- multipath -F
Unconfigures ("flushes") all multipath maps and their partition mappings. The command will fail for maps in use.
- multipath -ll
Displays the status and topology of all currently configured multipath devices. See Section 18.14.2, “Interpreting multipath I/O status”.
- multipath -ll DEVICENAME
Displays the status of a specified multipath device. See above for possible values of DEVICENAME.
- multipath -t
Shows the internal hardware table and the active configuration of multipath. Refer to
multipath.conf(5)
for details about the configuration parameters.- multipath -T
Has a similar function as the
multipath -t
command but shows only hardware entries matching the hardware detected on the host.
The option -v
controls the verbosity of the output. The
provided value overrides the verbosity
option in
/etc/multipath.conf
. See
Section 18.13, “Miscellaneous options”.
18.6.4 SCSI persistent reservations and mpathpersist
#
The mpathpersist
utility is used to manage SCSI
persistent reservations on Device Mapper Multipath devices. Persistent
reservations serve to restrict access to SCSI Logical Units to certain SCSI
initiators. In multipath configurations, it is important to use the same
reservation keys for all I_T nexuses (paths) for a given volume; otherwise,
creating a reservation on one path device would cause I/O errors on other
paths.
Use this utility with the reservation_key
attribute in
the /etc/multipath.conf
file to set persistent
reservations for SCSI devices. If (and only if) this option is set, the
multipathd
daemon checks persistent reservations for
newly discovered paths or reinstated paths.
You can add the attribute to the defaults
section or the
multipaths
section of
multipath.conf
. For example:
multipaths { multipath { wwid 3600140508dbcf02acb448188d73ec97d alias yellow reservation_key 0x123abc } }
After setting the reservation_key
parameter for all
mpath devices applicable for persistent management, reload the
configuration using multipathd reconfigure
.
reservation_key file
”
If the special value reservation_key file
is used in
the defaults
section of
multipath.conf
, reservation keys can be managed
dynamically in the file /etc/multipath/prkeys
using
mpathpersist
.
This is the recommended way to handle persistent reservations with multipath maps. It is available from SUSE Linux Enterprise Server 12 SP4.
Use the command mpathpersist
to query and set persistent
reservations for multipath maps consisting of SCSI devices. Refer to the
manual page mpathpersist(8)
for details. The
command-line options are the same as those of the
sg_persist
from the sg3_utils
package. The sg_persist(8)
manual page explains
the semantics of the options in detail.
In the following examples, DEVICE denotes a
device mapper multipath device like
/dev/mapper/mpatha
. The commands below are listed with
long options for better readability. All options have single-letter
replacements, like in mpathpersist -oGS 123abc
DEVICE
.
- mpathpersist --in --read-keys DEVICE
Read the registered reservation keys for the device.
- mpathpersist --in --read-reservation DEVICE
Show existing reservations for the device.
- mpathpersist --out --register --param-sark=123abc DEVICE
Register a reservation key for the device. This will add the reservation key for all I_T nexuses (path devices) on the host.
- mpathpersist --out --reserve --param-rk=123abc --prout-type=5 DEVICE
Create a reservation of type 5 (“write exclusive - registrants only”) for the device, using the previously registered key.
- mpathpersist --out --release --param-rk=123abc --prout-type=5 DEVICE
Release a reservation of type 5 for the device.
- mpathpersist --out --register-ignore --param-sark=0 DEVICE
Delete a previously existing reservation key from the device.
18.7 Configuring the System for Multipathing #
18.7.1 Enabling, starting, and stopping multipath services #
To enable multipath services to start at boot time, run the following command:
>
sudo
systemctl enable multipathd
To manually start the service in the running system, enter:
>
sudo
systemctl start multipathd
To restart the service, enter:
>
sudo
systemctl restart multipathd
In most situations, restarting the service is not necessary. To simply have
multipathd
reload its configuration, run:
>
sudo
systemctl reload multipathd
To check the status of the service, enter:
>
sudo
systemctl status multipathd
To stop the multipath services in the current session, run:
>
sudo
systemctl stop multipathd multipathd.socket
Stopping the service does not remove existing multipath maps. To remove unused maps, run:
>
sudo
multipath -F
multipathd.service
enabled
We strongly recommend keeping multipathd.service
always enabled and running on systems with multipath hardware. The service
does support systemd
's socket activation mechanism, but
it is discouraged to rely on that. Multipath maps will not be set up
during boot if the service is disabled.
If you need to disable multipath despite the warning above, for example, because a third-party multipathing software is going to be deployed, proceed as follows. Be sure that the system uses no hard-coded references to multipath devices (see Section 18.15.2, “Understanding device referencing issues”).
To disable multipathing just for a single system
boot, use the kernel parameter
multipath=off
. This affects both the booted system and
the initramfs, which does not need to be rebuilt in this case.
To disable multipathd services permanently, so that they will not be started on future system boots, run the following commands:
>
sudo
systemctl disable multipathd multipathd.socket>
sudo
dracut --force --omit multipath
(Whenever you disable or enable the multipath services, rebuild the
initramfs
. See
Section 18.7.4, “Keeping the initramfs synchronized”.)
If you want to make sure multipath devices do not get set up,
even when running multipath
manually, add the following lines at the end of
/etc/multipath.conf
before rebuilding the initramfs:
blacklist { wwid .* }
18.7.2 Preparing SAN Devices for Multipathing #
Before configuring multipath I/O for your SAN devices, prepare the SAN devices, as necessary, by doing the following:
Configure and zone the SAN with the vendor’s tools.
Configure permissions for host LUNs on the storage arrays with the vendor’s tools.
If SUSE Linux Enterprise Server ships no driver for the host bus adapter (HBA), install a Linux driver from the HBA vendor. See the vendor’s specific instructions for more details.
If multipath devices are detected and
multipathd.service
is enabled, multipath maps should
be created automatically. If this does not happen,
Section 18.15.3, “Troubleshooting steps in emergency mode”
lists some shell commands that can be used to examine the situation. When
the LUNs are not seen by the HBA driver, check the zoning setup in the SAN.
In particular, check whether LUN masking is active and whether the LUNs are
correctly assigned to the server.
If the HBA driver can see LUNs, but no corresponding block devices are created, additional kernel parameters may be needed. See TID 3955167: Troubleshooting SCSI (LUN) Scanning Issues in the SUSE Knowledge base at https://www.suse.com/support/kb/doc.php?id=3955167.
18.7.3 Partitions on multipath devices and kpartx
#
Multipath maps can have partitions like their path devices. Partition table
scanning and device node creation for partitions is done in user space by
the kpartx
tool. kpartx
is
automatically invoked by udev rules; there is usually no need to run it
manually. See Section 18.12.4, “Referring to multipath maps” for ways to refer
to multipath partitions.
kpartx
The skip_kpartx
option in
/etc/multipath.conf
can be used to disable invocation
of kpartx
on selected multipath maps. This may be
useful on virtualization hosts, for example.
Partition tables and partitions on multipath devices can be manipulated as
usual, using YaST or tools like fdisk
or
parted
. Changes applied to the partition table will be
noted by the system when the partitioning tool exits. If this does not work
(usually because a device is busy), try multipathd
reconfigure
, or reboot the system.
18.7.4 Keeping the initramfs synchronized #
Make sure that the initial RAM file system (initramfs) and the booted system behave consistently regarding the use of multipathing for all block devices. Rebuild the initramfs after applying multipath configuration changes.
If multipathing is enabled in the system, it also needs to be enabled in
the initramfs
and vice versa. The only exception to
this rule is the option
Multipath disabled in the initramfs in
Section 18.3.2.2, “Root file system on a local disk”.
The multipath configuration must be synchronized between the booted system
and the initramfs. Therefore, if you change any of the files:
/etc/multipath.conf
,
/etc/multipath/wwids
,
/etc/multipath/bindings
, or other configuration files,
or udev rules related to device identification, rebuild initramfs using the
command:
>
sudo
dracut -f
If the initramfs
and the system are not synchronized,
the system will not boot properly, and the start-up procedure may result in
an emergency shell. See Section 18.15, “Troubleshooting MPIO” for
instructions on how to avoid or repair such a scenario.
18.7.4.1 Enabling or disabling multipathing in the initramfs #
Special care must be taken if the initramfs is rebuilt in non-standard
situations, for example, from a rescue system or after booting with the
kernel parameter multipath=off
.
dracut
will automatically include multipathing support
in the initramfs if and only if it detects that the root file system is on
a multipath device while the initramfs is being built. In such cases, it
is necessary to enable or disable multipathing explicitly.
To enable multipath support in the initramfs
, run the
command:
>
sudo
dracut --force --add multipath
To disable multipath support in initramfs
, run the
command:
>
sudo
dracut --force --omit multipath
18.7.4.2 Persistent device names in the initramfs #
When dracut
generates the initramfs, it must refer to
disks and partitions to be mounted in a persistent manner, to make sure
the system will boot correctly. When dracut
detects
multipath devices, it will use the DM-MP device names such as
/dev/mapper/3600a098000aad73f00000a3f5a275dc8-part1
for this purpose by default. This is good if the system
always runs in multipath mode. But if the system is
started without multipathing, as described in
Section 18.7.4.1, “Enabling or disabling multipathing in the initramfs”, booting with such an
initramfs will fail, because the /dev/mapper
devices
will not exist. See Section 18.12.4, “Referring to multipath maps” for another
possible problem scenario, and some background information.
To prevent this from happening, change dracut
's
persistent device naming policy by using the
--persistent-policy
option. We recommend setting the
by-uuid
use policy:
>
sudo
dracut --force --omit multipath --persistent-policy=by-uuid
See also Procedure 18.1, “Disabling multipathing for the root disk after installation” and Section 18.15.2, “Understanding device referencing issues”.
18.8 Multipath configuration #
The built-in multipath-tools
defaults work well for
most setups. If customizations are needed, a configuration file needs to be
created. The main configuration file is
/etc/multipath.conf
. In addition, files in
/etc/multipath/conf.d/
are taken into account. See
Section 18.8.2.1, “Additional configuration files and precedence rules” for additional
information.
Some storage vendors publish recommended values for multipath options in their documentation. These values often represent what the vendor has tested in their environment and found most suitable for the storage product. See the disclaimer in Section 18.2.2, “Storage array autodetection for multipathing”.
multipath-tools
has built-in defaults for many
storage arrays that are derived from the published vendor recommendations.
Run multipath -T
to see the current settings for your
devices and compare them to vendor recommendations.
18.8.1 Creating /etc/multipath.conf
#
It is recommended that you create a minimal
/etc/multipath.conf
that just contains those settings
you want to change. In many cases, you do not need to create
/etc/multipath.conf
at all.
If you prefer working with a configuration template that contains all possible configuration directives, run:
multipath -T >/etc/multipath.conf
See also Section 18.14.1, “Best practices for configuration”.
18.8.2 multipath.conf
syntax #
The /etc/multipath.conf
file uses a hierarchy of
sections, subsections, and option/value pairs.
White space separates tokens. Consecutive white space characters are collapsed into a single space, unless quoted (see below).
The hash (
#
) and exclamation mark (!
) characters cause the rest of the line to be discarded as a comment.Sections and subsections are started with a section name and an opening brace (
{
) on the same line, and end with a closing brace (}
) on a line on its own.Options and values are written on one line. Line continuations are unsupported.
Options and section names must be keywords. The allowed keywords are documented in
multipath.conf(5)
.Values may be enclosed in double quotes (
"
). They must be enclosed in quotes if they contain white space or comment characters. A double quote character inside a value is represented by a pair of double quotes (""
).The values of some options are POSIX regular expressions (see
regex(7)
). They are case sensitive and not anchored, so “bar
” matches “rhabarber
”, but not “Barbie”.
The following example illustrates the syntax:
section { subsection { option1 value option2 "complex value!" option3 "value with ""quoted"" word" } ! subsection end } # section end
18.8.2.1 Additional configuration files and precedence rules #
After /etc/multipath.conf
, the tools read files
matching the pattern /etc/multipath.conf.d/*.conf
.
The additional files follow the same syntax rules as
/etc/multipath.conf
. Sections and options can occur
multiple times. If the same option in the same
section is set in multiple files, or on multiple lines in the
same file, the last value takes precedence. Separate precedence rules
apply between multipath.conf
sections, see below.
18.8.3 multipath.conf
sections #
The /etc/multipath.conf
file is organized into the
following sections. Some options can occur in more than one section. See
multipath.conf(5)
for details.
- defaults
General default settings.
Important: Overriding built-in device propertiesBuilt-in hardware-specific device properties take precedence over the settings in the
defaults
section. Changes must therefore be made in thedevices
section or in theoverrides
section.- blacklist
Lists devices to ignore. See Section 18.11.1, “The
blacklist
section inmultipath.conf
”.- blacklist_exceptions
Lists devices to be multipathed even though they are matched by the blacklist. See Section 18.11.1, “The
blacklist
section inmultipath.conf
”.- devices
Settings specific to the storage controller. This section is a collection of
device
subsections. Values in this section override values for the same options in thedefaults
section, and the built-in settings ofmultipath-tools
.device
entries in thedevices
section are matched against the vendor and product of a device using regular expressions. These entries will be “merged”, setting all options from matching sections for the device. If the same option is set in multiple matchingdevice
sections, the last device entry takes precedence, even if it is less “specific” than preceding entries. This applies also if the matching entries appear in different configuration files (see Section 18.8.2.1, “Additional configuration files and precedence rules”). In the following example, a deviceSOMECORP STORAGE
will usefast_io_fail_tmo 15
.devices { device { vendor SOMECORP product STOR fast_io_fail_tmo 10 } device { vendor SOMECORP product .* fast_io_fail_tmo 15 } }
- multipaths
Settings for individual multipath devices. This section is a list of
multipath
subsections. Values override thedefaults
anddevices
sections.- overrides
Settings that override values from all other sections.
18.8.4 Applying multipath.conf
modifications #
To apply the configuration changes, run:
>
sudo
multipathd reconfigure
Do not forget to synchronize with the configuration in the initramfs. See Section 18.7.4, “Keeping the initramfs synchronized”.
multipath
Do not apply new settings with the multipath
command
while multipathd
is running. This may result in an
inconsistent and possibly broken setup.
It is possible to test modified settings first before they are applied, by running:
>
sudo
multipath -d -v2
This command shows new maps to be created with the proposed topology, but not whether maps will be removed/flushed. To obtain more information, run with increased verbosity:
>
sudo
multipath -d -v3 2>&1 | less
18.9 Configuring policies for failover, queuing, and failback #
The goal of multipath I/O is to provide connectivity fault tolerance between the storage system and the server. The desired default behavior depends on whether the server is a stand-alone server or a node in a high-availability cluster.
This section discusses the most important
multipath-tools
configuration parameters for
achieving fault tolerance.
- polling_interval
The time interval (in seconds) between health checks for path devices. The default is 5 seconds. Failed devices are checked at this time interval. For healthy devices, the time interval may be increased up to
max_polling_interval
seconds.- detect_checker
If this is set to
yes
(default, recommended),multipathd
automatically detects the best path checking algorithm.- path_checker
The algorithm used to check path state. If you need to enable the checker, disable
detect_checker
as follows:defaults { detect_checker no }
The following list contains only the most important algorithms. See
multipath.conf(5)
for the full list.- tur
Send TEST UNIT READY command. This is the default for SCSI devices with ALUA support.
- directio
Read a device sector using asynchronous I/O (aio).
- rdac
Device-specific checker for NetAPP E-Series and similar arrays.
- none
No path checking is performed.
- checker_timeout
If a device does not respond to a path checker command in the given time, it is considered failed. The default is the kernel's SCSI command timeout for the device (usually 30 seconds).
- fast_io_fail_tmo
If an error on the SCSI transport layer is detected (for example on a Fibre Channel remote port), the kernel transport layer waits for this amount of time (in seconds) for the transport to recover. After that, the path device fails with “transport offline” state. This is very useful for multipath, because it allows a quick path failover for a frequently occurring class of errors. The value must match typical time scale for reconfiguration in the fabric. The default value of 5 seconds works well for Fibre Channel. Other transports, like iSCSI, may require longer timeouts.
- dev_loss_tmo
If a SCSI transport endpoint (for example a Fibre Channel remote port) is not reachable any more, the kernel waits for this amount of time (in seconds) for the port to reappear until it removes the SCSI device node for good. Device node removal is a complex operation which is prone to race conditions or deadlocks and should best be avoided. We therefore recommend setting this to a high value. The special value
infinity
is supported. The default is 10 minutes. To avoid deadlock situations,multipathd
ensures that I/O queuing (seeno_path_retry
) is stopped beforedev_loss_tmo
expires.- no_path_retry
Determine what happens if all paths of a given multipath map have failed. The possible values are:
- fail
Fail I/O on the multipath map. This will cause I/O errors in upper layers such as mounted file systems. The affected file systems, and possibly the entire host, will enter degraded mode.
- queue
I/O on the multipath map is queued in the device mapper layer and sent to the device when path devices become available again. This is the safest option to avoid losing data, but it can have negative effects if the path devices do not get reinstated for a long time. Processes reading from the device will hang in uninterruptible sleep (
D
) state. Queued data occupies memory, which becomes unavailable for processes. Eventually, memory will be exhausted.- N
N is a positive integer. Keep the map device in queuing mode for N polling intervals. When the time elapses,
multipathd
fails the map device. Ifpolling_interval
is 5 seconds andno_path_retry
is 6,multipathd
will queue I/O for approximately 6 * 5s = 30s before failing I/O on the map device.
- flush_on_last_del
If set to
yes
and all path devices of a map are deleted (as opposed to just failed), fail all I/O in the map before removing it. The default isno
.- deferred_remove
If set to
yes
and all path devices of a map are deleted, wait for holders to close the file descriptors for the map device before flushing and removing it. If paths reappear before the last holder closed the map, the deferred remove operation will be cancelled. The default isno
.- failback
If a failed path device in an inactive path group recovers,
multipathd
reevaluates the path group priorities of all path groups (see Section 18.10, “Configuring path grouping and priorities”). After the reevaluation, the highest-priority path group may be one of the currently inactive path groups. This parameter determines what happens in this situation.Important: Observe vendor recommendationsThe optimal failback policy depends on the property of the storage device. It is therefore strongly encouraged to verify
failback
settings with the storage vendor.- manual
Nothing happens unless the administrator runs a
multipathd switchgroup
(see Section 18.6.2, “Themultipathd
daemon”).- immediate
The highest-priority path group is activated immediately. This is often beneficial for performance, especially on stand-alone servers, but it should not be used for arrays on which the change of the path group is a costly operation.
- followover
Like
immediate
, but only perform failback when the path that has just become active is the only healthy path in its path group. This is useful for cluster configurations: It keeps a node from automatically failing back when another node requested a failover before.- N
N is a positive integer. Wait for N polling intervals before activating the highest priority path group. If the priorities change again during this time, the wait period starts anew.
- eh_deadline
Set an approximate upper limit for the time (in seconds) spent in SCSI error handling if devices are unresponsive and SCSI commands time out without error response. When the deadline has elapsed, the kernel will perform a full HBA reset.
After modifying the /etc/multipath.conf
file, apply
your settings as described in
Section 18.8.4, “Applying multipath.conf
modifications”.
18.9.1 Queuing policy on stand-alone servers #
When you configure multipath I/O for a stand-alone server, a
no_path_retry
setting with value
queue
protects the server operating system from
receiving I/O errors as long as possible. It queues messages until a
multipath failover occurs. If “infinite” queuing is not desired
(see above), select a numeric value that is deemed high enough for the
storage paths to recover under ordinary circumstances (see above).
18.9.2 Queuing policy on clustered servers #
When you configure multipath I/O for a node in a high-availability cluster,
you want multipath to report the I/O failure to trigger the resource
failover instead of waiting for a multipath failover to be resolved. In
cluster environments, you must modify the no_path_retry
setting so that the cluster node receives an I/O error in
relation to the cluster verification process (recommended to be 50% of the
heartbeat tolerance) if the connection is lost to the storage system. In
addition, you want the multipath failback
to be set to
manual
or followover
to avoid a
ping-pong of resources because of path failures.
18.10 Configuring path grouping and priorities #
Path devices in multipath maps are grouped in path
groups, also called priority groups. Only
one path group receives I/O at any given time. multipathd
assigns priorities to path groups. Out of the path
groups with active paths, the group with the highest priority is activated
according to the configured failback policy for the map (see
Section 18.9, “Configuring policies for failover, queuing, and failback”).
The priority of a path group is the average of the priorities of the active
path devices in the path group. The priority of a path device is an integer
value calculated from the device properties (see the description of the
prio
option below).
This section describes the multipath.conf
configuration
parameters relevant for priority determination and path grouping.
- path_grouping_policy
Specifies the method used to combine paths into groups. Only the most important policies are listed here; see
multipath.conf(5)
for other less frequently used values.- failover
One path per path group. This setting is useful for traditional “active/passive” storage arrays.
- multibus
All paths in one path group. This is useful for traditional “active/active” arrays.
- group_by_prio
Path devices with the same path priority are grouped together. This option is useful for modern arrays that support asymmetric access states, like ALUA. Combined with the
alua
orsysfs
priority algorithms, the priority groups set up bymultipathd
will match the primary target port groups that the storage array reports through ALUA-related SCSI commands.
Using the same policy names, the path grouping policy for a multipath map can be changed temporarily with the command:
>
sudo
multipath -p POLICY_NAME MAP_NAME- marginal_pathgroups
If set to
on
orfpin
, “marginal” path devices are sorted into a separate path group. This is independent of the path grouping algorithm in use. See Section 18.13.1, “Handling unreliable (“marginal”) path devices”.- detect_prio
If this is set to
yes
(default, recommended),multipathd
automatically detects the best algorithm to set the priority for a storage device and ignores theprio
setting. In practice, this means using thesysfs
prio algorithm if ALUA support is detected.- prio
Determines the method to derive priorities for path devices. If you override this, disable
detect_prio
as follows:defaults { detect_prio no }
The following list contains only the most important methods. Several other methods are available, mainly to support legacy hardware. See
multipath.conf(5)
for the full list.- alua
Uses SCSI-3 ALUA access states to derive path priority values. The optional
exclusive_pref_bit
argument can be used to change the behavior for devices that have the ALUA “preferred primary target port group” (PREF) bit set:prio alua prio_args exclusive_pref_bit
If this option is set, “preferred” paths get a priority bonus over other active/optimized paths. Otherwise, all active/optimized paths are assigned the same priority.
- sysfs
Like
alua
, but instead of sending SCSI commands to the device, it obtains the access states fromsysfs
. This causes less I/O load thanalua
, but is not suitable for all storage arrays with ALUA support.- const
Uses a constant value for all paths.
- path_latency
Measures I/O latency (time from I/O submission to completion) on path devices, and assigns higher priority to devices with lower latency. See
multipath.conf(5)
for details. This algorithm is still experimental.- weightedpath
Assigns a priority to paths based on their name, serial number, Host:Bus:Target:Lun ID (HBTL), or Fibre Channel WWN. The priority value does not change over time. The method requires a
prio_args
argument, seemultipath.conf(5)
for details. For example:prio weightedpath prio_args "hbtl 2:.*:.*:.* 10 hbtl 3:.*:.*:.* 20 hbtl .* 1"
This assigns devices on SCSI host 3 a higher priority than devices on SCSI host 2, and all others a lower priority.
- prio_args
Some
prio
algorithms require extra arguments. These are specified in this option, with syntax depending on the algorithm. See above.- hardware_handler
The name of a kernel module that the kernel uses to activate path devices when switching path groups. This option has no effect with recent kernels because hardware handlers are autodetected. See Section 18.2.3, “Storage Arrays that Require Specific Hardware Handlers”.
- path_selector
The name of a kernel module that is used for load balancing between the paths of the active path group. The available choices depend on the kernel configuration. For historical reasons, the name must always be enclosed in quotes and followed by a “0” in
multipath.conf
, like this:path_selector "queue-length 0"
- service-time
Estimates the time pending I/O will need to complete on all paths, and selects the path with the lowest value. This is the default.
- historical-service-time
Estimates future service time based on the historical service time (about which it keeps a moving average) and the number of outstanding requests. Estimates the time pending I/O will need to complete on all paths, and selects the path with the lowest value.
- queue-length
Selects the path with the lowest number of currently pending I/O requests.
- round-robin
Switches paths in round-robin fashion. The number of requests submitted to a path before switching to the next one can be adjusted with the options
rr_min_io_rq
andrr_weight
.- io-affinity
This path selector currently does not work with
multipath-tools
.
After modifying the /etc/multipath.conf
file, apply
your settings as described in
Section 18.8.4, “Applying multipath.conf
modifications”.
18.11 Selecting devices for multipathing #
On systems with multipath devices, you might want to avoid setting up
multipath maps on some devices (typically local disks).
multipath-tools
offers various means for
configuring which devices should be considered multipath path devices.
In general, there is nothing wrong with setting up “degraded” multipath maps with just a single device on top of local disks. It works fine and requires no extra configuration. However, some administrators find this confusing or generally oppose this sort of unnecessary multipathing. Also, the multipath layer causes a slight performance overhead. See also Section 18.3.2.2, “Root file system on a local disk”.
After modifying the /etc/multipath.conf
file, apply
your settings as described in
Section 18.8.4, “Applying multipath.conf
modifications”.
18.11.1 The blacklist
section in multipath.conf
#
The /etc/multipath.conf
file can contain a
blacklist
section that lists all devices that should be
ignored by multipathd
and multipath
.
The following example illustrates possible ways of excluding devices:
blacklist { wwid 3600605b009e7ed501f0e45370aaeb77f 1 device { 2 vendor ATA product .* } protocol scsi:sas 3 property SCSI_IDENT_LUN_T10 4 devnode "!^dasd[a-z]*" 5 }
| |
This | |
Excluding by
This form is supported since SLES 15 SP1 and SLES 12 SP5. | |
This | |
Excluding devices by
The example illustrates special syntax that is only supported in the
|
By default, multipath-tools
ignores all devices
except SCSI, DASD, or NVMe. Technically, the built-in devnode exclude list
is this negated regular expression:
devnode !^(sd[a-z]|dasd[a-z]|nvme[0-9])
18.11.2 The blacklist exceptions
section in multipath.conf
#
Sometimes it is desired to configure only very specific devices for
multipathing. In this case, devices are excluded by default, and exceptions
are defined for devices that should be part of a multipath map. The
blacklist_exceptions
section exists for this purpose. It
is typically used like in the following example, which excludes everything
except storage with product string “NETAPP”:
blacklist { wwid .* } blacklist_exceptions { device { vendor ^NETAPP$ product .* } }
The blacklist_exceptions
section supports all methods
described for the blacklist
section above.
The property
directive in
blacklist_exceptions
is mandatory because every device
must have at least one of the “allowed”
udev properties to be considered a path device for multipath (the value of
the property does not matter). The built-in default for
property
is
property (SCSI_IDENT_|ID_WWN)
Only devices that have at least one udev property matching this regular expression will be included.
18.11.3 Other options affecting device selection #
Besides the blacklist
options, there are several other
settings in /etc/multipath.conf
that affect which
devices are considered multipath path devices.
- find_multipaths
This option controls the behavior of
multipath
andmultipathd
when a device that is not excluded is first encountered. The possible values are:- greedy
Every device non-excluded by
blacklist
in/etc/multipath.conf
is included. This is the default on SUSE Linux Enterprise. If this setting is active, the only way to prevent devices from being added to multipath maps is setting them as excluded.- strict
Every device is excluded, even if it is not present in the
blacklist
section of/etc/multipath.conf
, unless its WWID is listed in the file/etc/multipath/wwids
. It requires manual maintenance of the WWIDs file (see note below).- yes
Devices are included if they meet the conditions for
strict
, or if at least one other device with the same WWID exists in the system.- smart
If a new WWID is first encountered, it is temporarily marked as multipath path device.
multipathd
waits for some time for additional paths with the same WWID to appear. If this happens, the multipath map is set up as usual. Otherwise, when the timeout expires, the single device is released to the system as non-multipath device. The timeout is configurable with the optionfind_multipaths_timeout
.This option depends on
systemd
features which are only available on SUSE Linux Enterprise Server 15.
Note: Maintaining/etc/multipath/wwids
multipath-tools
keeps a record of previously setup multipath maps in the file/etc/multipath/wwids
(the “WWIDs file”). Devices with WWIDs listed in this file are considered multipath path devices. The file is important for multipath device selection for all values offind_multipaths
exceptgreedy
.If
find_multipaths
is set toyes
orsmart
,multipathd
adds WWIDs to/etc/multipath/wwids
after setting up new maps, so that these maps will be detected more quickly in the future.The WWIDs file can be manually modified:
>
sudo
multipath -a 3600a098000aad1e3000064e45f2c2355 1>
sudo
multipath -w /dev/sdf 2In the
strict
mode, this is the only way to add new multipath devices. After modifying the WWIDs file, runmultipathd reconfigure
to apply the changes. We recommend rebuilding the initramfs after applying changes to the WWIDs file (see Section 18.7.4, “Keeping the initramfs synchronized”).- allow_usb_devices
If this option is set to
yes
, USB storage devices are considered for multipathing. The default isno
.
18.12 Multipath device names and WWIDs #
multipathd
and multipath
internally
use WWIDs to identify devices. WWIDs are also used as map names by default.
For convenience, multipath-tools
supports assigning
simpler, easier memorizable names to multipath devices.
18.12.1 WWIDs and device Identification #
It is crucial for multipath operation to reliably detect devices that
represent paths to the same storage volume.
multipath-tools
uses the device's World Wide
Identification (WWID) for this purpose (sometimes also referred to as
Universally Unique ID (UUID) or Unique ID (UID — do not confuse with
“User ID”). The WWID of a map device is always the same as the
WWID of its path devices.
By default, WWIDs of path devices are inferred from udev properties of the devices, which are determined in udev rules, either by reading device attributes from the sysfs file system or by using specific I/O commands. To see the udev properties of a device, run:
>
udevadm info /dev/sdx
The udev properties used by multipath-tools
to
derive WWIDs are:
ID_SERIAL
for SCSI devices (do not confuse this with the device's “serial number”)ID_UID
for DASD devicesID_WWN
for NVMe devices
It is impossible to change the WWID of a multipath map which is in use. If the WWID of mapped path devices changes because of a configuration change, the map needs to be destroyed, and a new map needs to be set up with the new WWID. This cannot be done while the old map is in use. In extreme cases, data corruption may result from WWID changes. It must therefore be strictly avoided to apply configuration changes that would cause map WWIDs to change.
It is allowed to enable the uid_attrs
option in
/etc/multipath.conf
, see
Section 18.13, “Miscellaneous options”.
18.12.2 Setting aliases for multipath maps #
Arbitrary map names can be set in the multipaths
section
of /etc/multipath.conf
as follows:
multipaths { multipath { wwid 3600a098000aad1e3000064e45f2c2355 alias postgres } }
Aliases are expressive, but they need to be assigned to each map individually, which may be cumbersome on large systems.
18.12.3 Using autogenerated user-friendly names #
multipath-tools
also supports autogenerated
aliases, so-called “user-friendly names”. The naming scheme of
the aliases follows the pattern: mpathINDEX,
where INDEX is a lower case letter (starting
with a
). So the first autogenerated alias is
mpatha
, the next one is mpathb
,
mpathc
to mpathz
. After that follows
mpathaa
, mpathab
, and so on.
Map names are only useful if they are persistent.
multipath-tools
keeps track of the assigned names
in the file /etc/multipath/bindings
(the
“bindings file”). When a new map is created, the WWID is first
looked up in this file. If it is not found, the lowest available
user-friendly name is assigned to it.
Explicit aliases as discussed in Section 18.12.2, “Setting aliases for multipath maps” take precedence over user-friendly names.
The following options in /etc/multipath.conf
affect
user-friendly names:
- user_friendly_names
If set to
yes
, user-friendly names are assigned and used. Otherwise, the WWID is used as a map name unless an alias is configured.- alias_prefix
The prefix used to create user-friendly names,
mpath
by default.
For cluster operations, device names must be identical across all nodes in
the cluster. The multipath-tools
configuration
must be kept synchronized between nodes. If
user_friendly_names
is used,
multipathd
may modify the
/etc/multipath/bindings
file at runtime. Such
modifications must be replicated dynamically to all nodes. The same
applies to /etc/multipath/wwids
(see
Section 18.11.3, “Other options affecting device selection”).
It is possible to change map names at runtime. Use any of the methods
described in this section and run multipathd
reconfigure
, and the map names will change without disrupting
the system operation.
18.12.4 Referring to multipath maps #
Technically, multipath maps are Device Mapper devices, which have generic
names of the form /dev/dm-n
with an integer number n. These names are not
persistent. They should never be used to refer to the
multipath maps. udev
creates various symbolic links to
these devices, which are more suitable as persistent references. These
links differ with respect to their invariance against certain configuration
changes. The following typical example shows various symlinks all pointing
to the same device.
/dev/disk/by-id/dm-name-mpathb1 -> ../../dm-1 /dev/disk/by-id/dm-uuid-mpath-3600a098000aad73f00000a3f5a275dc82 -> ../../dm-1 /dev/disk/by-id/scsi-3600a098000aad73f00000a3f5a275dc83 -> ../../dm-1 /dev/disk/by-id/wwn-0x600a098000aad73f00000a3f5a275dc84 -> ../../dm-1 /dev/mapper/mpathb5 -> ../dm-1
These two links use the map name to refer to the map. Thus, the links will change if the map name changes, for example, if you enable or disable user-friendly names. | |
This link uses the device mapper UUID, which is the WWID used by
The device mapper UUID is the preferred form to ensure that
only multipath devices are referenced. For example,
the following line in filter = [ "a|/dev/disk/by-id/dm-uuid-mpath-.*|", "r|.*|" ] | |
These are links that would normally point to path devices. The multipath
device took them over, because it has a higher udev link priority (see
|
For partitions on multipath maps created
by the kpartx
tool, there are similar symbolic links,
derived from the parent device name or WWID and the partition number:
/dev/disk/by-id/dm-name-mpatha-part2 -> ../../dm-5 /dev/disk/by-id/dm-uuid-part2-mpath-3600a098000aad1e300000b4b5a275d45 -> ../../dm-5 /dev/disk/by-id/scsi-3600a098000aad1e300000b4b5a275d45-part2 -> ../../dm-5 /dev/disk/by-id/wwn-0x600a098000aad1e300000b4b5a275d45-part2 -> ../../dm-5 /dev/disk/by-partuuid/1c2f70e0-fb91-49f5-8260-38eacaf7992b -> ../../dm-5 /dev/disk/by-uuid/f67c49e9-3cf2-4bb7-8991-63568cb840a4 -> ../../dm-5 /dev/mapper/mpatha-part2 -> ../dm-5
Note that partitions often have by-uuid
links, too,
referring not to the device itself but to the file system it contains.
These links are often preferable. They are invariant even if the file
system is copied to a different device or partition.
When dracut
builds an initramfs, it creates hard-coded
references to devices in the initramfs, using
/dev/mapper/$MAP_NAME
references by default. These
hard-coded references will not be found during boot if the map names used
in the initramfs do not match the names used during building the
initramfs, causing boot failure. Normally this will not happen, because
dracut
will add all multipath configuration files to
the initramfs. But problems can occur if the initramfs is built from a
different environment, for example, in the rescue system or during an
offline update. To prevent this boot failure, change
dracut
's persistent_policy
setting,
as explained in Section 18.7.4.2, “Persistent device names in the initramfs”.
18.13 Miscellaneous options #
This section lists some useful multipath.conf
options
that were not mentioned so far. See
multipath.conf(5)
for a full list.
- verbosity
Controls the log verbosity of both
multipath
andmultipathd
. The command-line option-v
overrides this setting for both commands. The value can be between 0 (only fatal errors) and 4 (verbose logging). The default is 2.- uid_attrs
This option enables an optimization for processing udev events, so-called “uevent merging”. It is useful in environments in which hundreds of path devices may fail or reappear simultaneously. In order to make sure that path WWIDs do not change (see Section 18.12.1, “WWIDs and device Identification”), the value should be set exactly like this:
defaults { uid_attrs "sd:ID_SERIAL dasd:ID_UID nvme:ID_WWN" }
- skip_kpartx
If set to
yes
for a multipath device (default isno
), do not create partition devices on top of the given device (see Section 18.7.3, “Partitions on multipath devices andkpartx
”). Useful for multipath devices used by virtual machines. Previous SUSE Linux Enterprise Server releases achieved the same effect with the parameter “features 1 no_partitions
”.- max_sectors_kb
Limits the maximum amount of data sent in a single I/O request for all path devices of the multipath map.
- ghost_delay
On active/passive arrays, it can happen that passive paths (in “ghost” state) are probed before active paths. If the map was activated immediately and I/O was sent, this would cause a possibly costly path activation. This parameter specifies the time (in seconds) to wait for active paths of the map to appear before activating the map. The default is
no
(no ghost delay).- recheck_wwid
If set to
yes
(default isno
), double-checks the WWID of restored paths after failure, and removes them if the WWID has changed. This is a safety measure against data corruption.- enable_foreign
multipath-tools
provides a plugin API for other multipathing backends than Device Mapper multipath. The API supports monitoring and displaying information about the multipath topology using standard commands likemultipath -ll
. Modifying the topology is unsupported.The value of
enable_foreign
is a regular expression to match against foreign library names. The default value is “NONE
”.SUSE Linux Enterprise Server ships the
nvme
plugin, which adds support for the native NVMe multipathing (see Section 18.2.1, “Multipath implementations: device mapper and NVMe”). To enable thenvme
plugin, setdefaults { enable_foreign nvme }
18.13.1 Handling unreliable (“marginal”) path devices #
Unstable conditions in the fabric can cause path devices to behave
erratically. They exhibit frequent I/O errors, recover, and fail again.
Such path devices are also denoted “marginal” or
“shaky” paths. This section summarizes the options that
multipath-tools
provides to deal with this
problem.
If a path device exhibits a second failure (good → bad transition) before
marginal_path_double_failed_time
elapses after the
first failure, multipathd
starts monitoring the path at
a rate of 10 requests per second, for a monitoring period of
marginal_path_err_sample_time
. If the error rate during
the monitoring period exceeds
marginal_path_err_rate_threshold
, the path is
classified as marginal. After
marginal_path_err_recheck_gap_time
, the path
transitions to normal state again.
This algorithm is used if all four numeric
marginal_path_
parameters are set to a positive value,
and marginal_pathgroups
is not set to
fpin
. It is available since SUSE Linux Enterprise Server 15 SP1 and
SUSE Linux Enterprise Server 12 SP5.
- marginal_path_double_failed_time
Maximum time (in seconds) between two path failures that triggers path monitoring.
- marginal_path_err_sample_time
Length (in seconds) of the path monitoring interval.
- marginal_path_err_rate_threshold
Minimum error rate (per thousand I/Os).
- marginal_path_err_recheck_gap_time
Time (in seconds) to keep the path in marginal state.
A simpler algorithm using the parameters
san_path_err_threshold
,
san_path_err_forget_rate
, and
san_path_err_recovery time
is also available and
recommended for SUSE Linux Enterprise Server 15 (GA). See the “Shaky paths
detection” section in multipath.conf(5)
.
18.14 Best Practice #
18.14.1 Best practices for configuration #
The large number of configuration directives is daunting at first. Usually, you can get good results with an empty configuration, unless you are in a clustering environment.
Here are some general recommendations for stand-alone servers. They are not mandatory. See the documentation of the respective parameters in the previous sections for background information.
defaults { deferred_remove yes find_multipaths smart enable_foreign nvme marginal_pathgroups fpin # 15.4 only, if supported by fabric } devices { # A catch-all device entry. device { vendor .* product .* dev_loss_tmo infinity no_path_retry 60 # 5 minutes path_grouping_policy group_by_prio path_selector "historical-service-time 0" reservation_key file # if using SCSI persistent reservations } # Follow up with specific device entries below, they will take precedence. }
After modifying the /etc/multipath.conf
file, apply
your settings as described in
Section 18.8.4, “Applying multipath.conf
modifications”.
18.14.2 Interpreting multipath I/O status #
For a quick overview of the multipath subsystem, use multipath
-ll
or multipathd show topology
. The output of
these commands has the same format. The former command reads the kernel
state, while the latter prints the status of the multipath daemon. Normally
both states are equal. Here is an example of the output:
>
sudo
multipathd show topology mpatha1 (3600a098000aad1e300000b4b5a275d452) dm-03 NETAPP,INF-01-004 size=64G features='3 queue_if_no_path pg_init_retries 50'5 hwhandler='1 alua'6 wp=rw7 |-+- 8policy='historical-service-time 2'9 prio=5010 status=active11 | |-12 3:0:0:113 sdb 8:1614 active15 ready16 running17 | `- 4:0:0:1 sdf 8:80 active ready running `-+- policy='historical-service-time 2' prio=10 status=enabled `- 4:0:1:1 sdj 8:144 active ready running
The map name. | |
The map WWID (if different from the map name). | |
The device node name of the map device. | |
The vendor and product name. | |
A path group. The indented lines below the path group list the path devices that belong to it. | |
The path selector algorithm used by the path group. The "2" can be ignored. | |
The priority of the path group. | |
The status of the path group ( | |
A path device. | |
The bus ID of the device (here, a SCSI Host:Bus:Target:Lun ID). | |
The device node name and major/minor number of the path device. | |
The kernel device mapper state of the path ( | |
The multipath path device state (see below). | |
The state of the path device in the kernel. This is a device-type
specific value. For SCSI, it is either |
The multipath path device states are:
|
The path is healthy and up |
|
A passive path in an active/passive array |
|
The path is down or unreachable |
|
A checker command timed out |
|
Waiting for the completion of a path checker command |
|
Path reinstantiation is delayed to avoid "flapping" |
|
An unreliable path (emc path checker only) |
18.14.3 Using LVM2 on multipath devices #
LVM2 has built-in support for detecting multipath devices. It is activated
by default in /etc/lvm/lvm.conf
:
multipath_component_detection=1
This works reliably only if LVM2 is also configured to obtain information about device properties from udev:
external_device_info_source="udev"
It is also possible (although normally not necessary) to create a filter expression for LVM2 to ignore all devices except multipath devices. See Section 18.12.4, “Referring to multipath maps”.
18.14.4 Resolving Stalled I/O #
If all paths fail concurrently and I/O is queued, applications may stall for a long time. To resolve this, you can use the following procedure:
Enter the following command at a terminal prompt:
>
sudo
multipathd disablequeueing map MAPNAMEReplace
MAPNAME
with the correct WWID or mapped alias name for the device.This command immediately causes all queued I/O to fail and propagates the error to the calling application. File systems will observe I/O errors and switch to read-only mode.
Reactivate queuing by entering the following command:
>
sudo
multipathd restorequeueing MAPNAME
18.14.5 MD RAID on multipath devices #
MD RAID arrays on top of multipathing are set up automatically by the
system's udev rules. No special configuration in
/etc/mdadm.conf
is necessary.
18.14.6 Scanning for new devices without rebooting #
If your system has already been configured for multipathing and you need to
add storage to the SAN, you can use the
rescan-scsi-bus.sh
script to scan for the new devices.
The general syntax for the command follows:
>
sudo
rescan-scsi-bus.sh [-a] [-r] --hosts=2-3,5
Where the options have the following meaning:
- -a
the option ensures that all SCSI targets are scanned, otherwise only already existing targets will be scanned for new LUNs.
- -r
the option enables the removal of devices which have been removed on the storage side.
- --hosts
the option specifies the list of host bus adapters to scan (the default is to scan all).
Run rescan-scsi-bus.sh --help
for help on additional
options.
If multipathd
is running and new SAN devices are
discovered, they should be automatically set up as multipath maps according
to the configuration described in
Section 18.11, “Selecting devices for multipathing”.
In EMC PowerPath environments, do not use the
rescan-scsi-bus.sh
utility provided with the
operating system or the HBA vendor scripts for scanning the SCSI buses. To
avoid potential file system corruption, EMC requires that you follow the
procedure provided in the vendor documentation for EMC PowerPath for
Linux.
18.15 Troubleshooting MPIO #
If a system runs into emergency mode on a system with multipath, printing messages about missing devices, the reason is almost always one of these:
Inconsistent configuration of multipath device selection
Use of non-existing device references
18.15.1 Understanding device selection issues #
A block device can only either be part of a multipath map or be used
directly (mounted as file system, used as swap, LVM physical volume, or
otherwise). If a device is already mounted, an attempt by multipathd to
make it part of a multipath map will fail with a “Device or resource
busy” error. Vice-versa, the same error results if
systemd
attempts to mount a device which has already
been made part of a multipath map.
Storage device activation during boot is handled by a complex interaction
between systemd
, udev
,
multipathd
and some other tools.
udev
rules play a central role. They set device
properties that indicate to other subsystems how a device should be used.
The multipath-related udev rules set the following properties for devices
that are selected for multipathing:
SYSTEMD_READY=0 DM_MULTIPATH_DEVICE_PATH=1
Partition devices inherit these properties from their parents.
If these properties are not set correctly, if some tool does not respect
them, or if they get set too late, a race condition between
multipathd
and some other subsystem may result. Only one
of the contenders can win the race; the other one will see a “Device
or resource busy” error.
One problem in this context is that the tools of the LVM2 suite do not evaluate udev properties by default. They rely on their own logic for determining whether a device is a multipath component, which sometimes does not match the logic of the rest of the system. A workaround for this is described in Section 18.14.3, “Using LVM2 on multipath devices”.
Consider a system with multipathing where the root device is not
multipathed, and no devices are excluded from multipath (see
Multipath disabled in the initramfs in
Section 18.3.2.2, “Root file system on a local disk”). The root file
system is mounted in the initramfs. systemd
switches to
the root file system and multipathd
starts up. Because
the device is already mounted, multipathd
fails to set
up the multipath map for it. Because the root device is not configured in
blacklist
, it is considered a multipath device, and
SYSTEMD_READY=0
is set for it.
Later in the boot process, the system attempts to mount additional file
systems like /var
and /home
.
Usually, these file systems will be on the same device as the root file
system, by default as BTRFS subvolumes of the root file system itself. But
systemd cannot mount them because of SYSTEMD_READY=0
.
We are in a deadlock: The dm-multipath device cannot
be created, and the underlying device is blocked for systemd. The
additional file systems cannot be mounted, resulting in boot failure.
A solution to this problem already
exists. multipathd
detects this situation
and releases the device to systemd
which can then
proceed mounting the file system. However, it is important to understand
the general problem, which can still occur in more subtle ways.
18.15.2 Understanding device referencing issues #
An example of a device referencing issue has been given in
Section 18.7.4.2, “Persistent device names in the initramfs”. Typically, there are
multiple symbolic links pointing to a device node (see
Section 18.12.4, “Referring to multipath maps”). But these links do not always
exist; udev
creates them according to the current udev
rules. For example, if multipathing is off, symbolic links under
/dev/mapper/
for multipath devices will be missing.
Thus, any reference to a /dev/mapper/
device will
fail.
Such references can appear in various places, notably in
/etc/fstab
and /etc/crypttab
, in
the initramfs, or even on the kernel command line.
The safest way to circumvent this problem is to avoid using the kind of
device references that are not persistent between boots or depend on system
configuration. We generally recommend referring to file systems (and
similar entities like swap space) by properties of the file system itself
(like UUID or label) rather than the containing device. If such references
are not available and device references are required, for example, in
/etc/crypttab
, the options should be evaluated
carefully. For example, in Section 18.12.4, “Referring to multipath maps”, the
best option might be the /dev/disk/by-id/wwn-
link
because it would also work with multipath=off
.
18.15.3 Troubleshooting steps in emergency mode #
As there are many error situations that differ in subtle ways, it is impossible to provide a step-by-step recovery guide. But with the background knowledge from the previous subsections, you should be able to figure out the problem if a system runs into emergency mode because of multipathing issues. Before you begin debugging, make sure you have checked the following questions:
Is the multipath service enabled?
Is the multipath dracut module included in the initramfs?
Is my root device configured as a multipath device? If not, is the root device properly excluded from multipath as described in Section 18.11.1, “The
blacklist
section inmultipath.conf
”, or are you relying on the absence of the multipath module in the initramfs (see Section 18.3.2.2, “Root file system on a local disk”)?Does the system enter emergency mode before or after switching to the real root file system?
If you are unsure with respect to the last question, here is a sample dracut emergency prompt as it would be printed before switching root:
Generating "/run/initramfs/rdsosreport.txt" Entering emergency mode. Exit the shell to continue. Type "journalctl" to view system logs. You might want to save "/run/initramfs/rdsosreport.txt" to a USB stick or /boot after mounting them and attach it to a bug report. Give root password for maintenance (or press Control-D to continue):
The mention of rdsosreport.txt
is a clear indication
that the system is still running from the initramfs. If you are still
uncertain, log in and check for the existence of the file
/etc/initrd-release
. This file exists only in an
initramfs environment.
If emergency mode is entered after switching root, the emergency prompt
looks similar, but rdsosreport.txt
is not mentioned:
Timed out waiting for device dev-disk-by\x2duuid-c4a...cfef77d.device. [DEPEND] Dependency failed for Local File Systems. [DEPEND] Dependency failed for Postfix Mail Transport Agent. Welcome to emergency shell Give root password for maintenance (or press Control-D to continue):
Try to figure out what failed by examining failed systemd units and the journal.
#
systemctl --failed#
journalctl -b -o short-monotonicWhen looking at the journal, determine the first failed unit. When you have found the first failure, examine the messages before and around that point in time very carefully. Are there any warnings or other suspicious messages?
Watch out for the root switch ("
Switching root.
") and for messages about SCSI devices, device mapper, multipath, and LVM2. Look forsystemd
messages about devices and file systems ("Found device
…", "Mounting
…", "Mounted
…").Examine the existing devices, both low-level devices and device mapper devices (note that some of the commands below may not be available in the initramfs):
#
cat /proc/partitions#
ls -l /sys/class/block#
ls -l /dev/disk/by-id/* /dev/mapper/*#
dmsetup ls --tree#
lsblk#
lsscsiFrom the output of the commands above, you should get an idea whether the low-level devices were successfully probed, and whether any multipath maps and multipath partitions were set up.
If the device mapper multipath setup is not as you expect, examine the udev properties, in particular,
SYSTEMD_READY
(see above)#
udevadm info -eIf the previous step showed unexpected udev properties, something may have gone wrong during udev rule processing. Check other properties, in particular, those used for device identification (see Section 18.12.1, “WWIDs and device Identification”). If the udev properties are correct, check the journal for
multipathd
messages again. Look for "Device or resource busy
" messages.If the system failed to mount or otherwise activate a device, it is often helpful to try activating this device manually:
#
mount /var#
swapon -a#
vgchange -a yMostly, the manual activation will succeed and allow to proceed with system boot (usually by simply logging out from the emergency shell) and examine the situation further in the booted system.
If manual activation fails, you will probably see error messages that provide clues about what is going wrong. You can also try the commands again with increased verbosity.
At this point, you should have some idea what went wrong (if not, contact SUSE support and be prepared to answer most of the questions raised above).
You should be able to correct the situation with a few shell commands, exit the emergency shell, and boot successfully. You will still need to adjust your configuration to make sure the same problem will not occur again in the future.
Otherwise, you will need to boot the rescue system, set up the devices manually to
chroot
into the real root file system, and attempt to fix the problem based on the insight you got in the previous steps. Be aware that in this situation, the storage stack for the root file system may differ from normal. Depending on your setup, you may have force addition or omission of dracut modules when building a new initramfs. See also Section 18.7.4.1, “Enabling or disabling multipathing in the initramfs”.If the problem occurs frequently or even on every boot attempt, try booting with increased verbosity in order to get more information about the failure. The following kernel parameters, or a combination of them, are often helpful:
udev.log-priority=debug1 systemd.log_level=debug2 scsi_mod.scsi_logging_level=0204003 rd.debug4
In addition, it may make sense to enable logging for certain drivers and configure a serial console to capture the output during boot.
18.15.4 Technical Information Documents #
For more information about troubleshooting multipath I/O issues on SUSE Linux Enterprise Server, see the following Technical Information Documents (TIDs) in the SUSE Knowledgebase: