A storage device according to an embodiment of the present invention has a plurality of storage nodes, each of which has a plurality of logical ports having send and receive queues for a communication request and an identification number, and an internal network for connecting the plurality of storage nodes with one another. The storage nodes each have, as the logical ports, a data communication logical port used for data communication with other storage nodes and an error communication logical port used to notify the other storage nodes of a state of the data communication logical port. When detecting an occurrence of transition of the data communication logical port to an error state, the storage node uses the error communication logical port to notify the other storage nodes of the identification number and the state of the data communication logical port.

A method of transparently inserting a virtual storage layer into a Fibre channel based storage area network (SAN) while maintaining continuous I/O operations is provided. A device is inserted between a host entity and a first storage device. The device identifies a plurality of first paths between the host entity and the first storage device, and defines a plurality of second paths by defining, for each first path among the plurality of first paths, a corresponding second path between the host entity and a second storage device. The device determines, for each of the plurality of first paths, a respective first state. The device establishes, for each of the second paths among the plurality of second paths, a second state based on the first state of the corresponding first path. The device redirects, to the second storage device, communications directed from the host entity to the first storage device, via the plurality of second paths.

A memory controller controls a memory device including memory blocks, and can equalize wear levels of cores for controlling memory devices. The memory controller includes: cores for controlling the zones; a reset information controller for generating reset count values representing a number of reset requests input with respect to the zones, in response to a reset request, and generating reset count sum values obtained by summing reset count values of zones controlled by each of the cores; and a wear level manager for controlling the cores such that a core that is different from a first core having a highest reset count sum value from among the cores controls some of zones controlled by the first core according to whether a difference value between the highest reset count sum value and a lowest reset count sum value from among the reset count sum values exceeds a threshold difference value.

An aspect of validating vHBA fabric zoning in a SAN includes receiving, by a computer processor, a request for data corresponding to zones in a storage area network to which an initiator in a host system computer has access; instantiating, by the computer processor, a virtual host bus adapter interface on the host system computer; and transmitting, via the virtual host bus adapter interface, the request to a fabric controller in the storage area network. An aspect also includes receiving a current active zone set from the fabric controller; parsing the current active zone set for the initiator; identifying, from the parsing, each of the zones in the current active zone set to which the initiator is indicated; and displaying the identified zones via the computer processor.

A memory sub-system configured to dynamically determine input/output sizes of write commands based on a media physical layout of a memory sub-system. The memory sub-system can identify, dynamically in response to write commands being selected for execution in media units of the memory sub-system, a portion of a media layout that maps from logical addresses identified by the write commands in the logical address space to physical addresses of memory units in the media units. Based on the media layout, an input/output size for a next write command is identified and transmitted to the host system in a response. The host system generates the next write command and configures the amount of data to be written through the next write command based on based on the input/output size identified in the response.

A storage network processing system includes a processor, a network interface and memory that stores operational instructions. The operation instructions enable the processor to receive a data object for storage and dispersed error encode the data object in accordance with dispersed error encoding parameters to produce a plurality of encoded data slices. The operation instructions further enable the processor to generate to determine a plurality of site slice sets from the plurality of encoded data slices, where each site slice set of the plurality of site slice sets includes a number of unique encoded data slices of the plurality of encoded data slices that is greater than or equal to a site write threshold value. The operation instructions further enable the processor to a designate one of a plurality of storage sites for each of the plurality of site slice sets and transmit each of the plurality of site slice sets to a corresponding designated one of the plurality of storage sites via the network.

An array controller for connection between a solid state drive controller and multiple non-volatile storage units is provided. The array controller comprises a plurality of enable outputs, each of which is connected to an enable input of one of the non-volatile storage units, and a buffer in which data to be written into or read from the non-volatile storage units is stored. The array controller further comprises a control unit configured to enable a communication path between the solid state drive controller and one of the non-volatile storage units according to an address received from the solid state drive controller.

As described herein, an apparatus may include a memory that includes a first portion, a second portion, and a third portion. The apparatus may also include a memory controller that includes a first logical-to-physical table stored in a buffer memory. The memory controller may determine that the first portion is accessed sequential to the second portion and may adjust the first logical-to-physical table to cause a memory transaction performed by the memory controller to access the third portion as opposed to the first portion.

Disclosed are systems and methods for node management performed by a client driver of a client device comprising receiving cluster topology data from the cluster system; transmitting, a data request to each of a plurality of nodes in a cluster system; receiving a reply from each of the nodes that are responsive; assigning, by the client driver, based on the received replies, a responsive status for each of the nodes that are responsive or a non-responsive status for each of nodes that are non-responsive; updating a listing of management data, wherein the management data includes: an identification of each of the plurality of nodes, and a current status of each of the plurality of nodes; and routing, by the client driver, a client request to one of the plurality of nodes that are responsive based on the cluster topology data.

A storage system includes a switch and a plurality of storage nodes. The switch is configured to receive a first request from a client. The first request includes an identifier of a storage partition. The switch queries an entry in a forwarding table based on the identifier to determine a target storage node in the plurality of storage nodes. The entry includes a mapping relationship between the identifier and the target storage node. The switch sends the first request to the target storage node. The target storage node is configured to receive the first request from the switch.