ctl

NAME

ctl — CAM Target Layer

To compile this driver into the kernel, place the following line in your kernel configuration file:

device ctl

Alternatively, to load the driver as a module at boot time, place the following line in loader.conf(5):

ctl_load="YES"

The ctl subsystem provides SCSI target devices emulation. It supports features such as:

Disk, CD-ROM and processor device emulation
Tagged queueing
SCSI task attribute support (ordered, head of queue, simple tags)
SCSI implicit command ordering support
Full task management support (abort, query, reset, etc.)
Support for multiple ports, initiators, targets and backing stores
Support for VMWare VAAI and Microsoft ODX offload (COMPARE AND WRITE, XCOPY, POPULATE TOKEN/WRITE USING TOKEN, WRITE SAME and UNMAP)
Persistent reservation support
Extensive VPD/mode/log pages support
Featured error reporting, error injection and basic SMART support
High Availability clustering support with ALUA
All I/O handled in-kernel, no userland context switch overhead

The ctl subsystem includes multiple frontends to provide access using different transport protocols and implementations:

camsim: Provides access for local system via virtual initiator mode CAM(4) SIM.
camtgt: Provides access for remote systems via target mode CAM(4) SIMs, such as Fibre Channel isp(4) and mpt(4).
cfumass: Provides access for remote systems via USB Mass Storage Class Bulk Only (BBB) Transport.
ha: Internal frontend used to receive requests from other node ports in High Availability cluster.
ioctl: Provides access for local user-level applications via ioctl(2) based API.
iscsi: Provides access for remote systems via the iSCSI protocol using cfiscsi(4).
tpc: Internal frontend used to receive requests from Third Party Copy engine, implementing copy offload operations.

The ctl subsystem includes two backends to create logical units using different kinds of backing stores:

block: Stores data in ZFS ZVOLs, files or raw block devices.
ramdisk: Stores data in RAM, that makes it mostly useful for performance testing. Depending on configured capacity can work as black hole, thin or thick provisioned disk.

The following variables are available as both sysctl(8) variables and loader(8) tunables:

kern.cam.ctl.debug: Bit mask of enabled CTL log levels: Defaults to 0.
kern.cam.ctl.ha_id: Specifies unique position of this node within High Availability cluster. Default is 0 -- no HA, 1 and 2 -- HA enabled at specified position.
kern.cam.ctl.ha_mode: Specifies High Availability cluster operation mode: All above modes require established connection between HA cluster nodes. If connection is not configured, secondary node will report Unavailable state; if configured but not established -- Transitioning state. Defaults to 0.
kern.cam.ctl.ha_peer: String value, specifying method to establish connection to peer HA node. Can be "listen IP:port", "connect IP:port" or empty.
kern.cam.ctl.ha_link: Reports present state of connection between HA cluster nodes:
kern.cam.ctl.ha_role: Specifies default role of this node: This role can be overridden on per-LUN basis using "ha_role" LUN option, so that for one LUN one node is primary, while for another -- another. Role change from primary to secondary for HA modes 0 and 2 closes backends, the opposite change -- opens. If there is no primary node (both nodes are secondary, or secondary node has no connection to primary one), secondary node(s) report Transitioning state. State with two primary nodes is illegal (split brain condition).

The following variables are available as loader(8) tunables:

kern.cam.ctl.max_luns: Specifies the maximum number of LUNs we support, must be a power of 2. The default value is 1024.
kern.cam.ctl.max_ports: Specifies the maximum number of ports we support, must be a power of 2. The default value is 256.

The ctl subsystem first appeared in FreeBSD 9.1.

The ctl subsystem was originally written by Kenneth Merry <[email protected]>. Later work was done by
Alexander Motin <[email protected]>.

March 29, 2017

Debian