A data storage network is provided. The network includes a client connected to the data storage network; a plurality nodes on the data storage network, wherein each data node has two or more RAID controllers, wherein a first RAID controller of a first node is configured to receive a data storage request from the client and to generate RAID parity data on a data set received from the client, and to store all of the generated RAID parity data on a single node of the plurality of nodes.

Various embodiments are generally directed to techniques for preparing to respond to failures in performing a data access command to modify client device data in a storage cluster system. An apparatus may include a processor component of a first node coupled to a first storage device; an access component to perform a command on the first storage device; a replication component to exchange a replica of the command with the second node via a communications session formed between the first and second nodes to enable at least a partially parallel performance of the command by the first and second nodes; and a multipath component to change a state of the communications session from inactive to active to enable the exchange of the replica based on an indication of a failure within a third node that precludes performance of the command by the third node. Other embodiments are described and claimed.

One or more performance parameters associated with data stored at a storage device of a plurality of storage devices are received by a storage controller. A first number of blocks of the storage device to a high resiliency portion and a second number of blocks of the storage device to a low resiliency portion of the storage device are allocated based on the one or more performance parameters.

An access point IHS group controller failover system includes a first access point IHS group controller that controls a first access point IHS group that includes plurality of access point IHSs. Following a failure of the first access point IHS group controller, the first access point IHS broadcasts a first access point IHS identifier to a first subset of the plurality of access point IHSs. The first access point IHS then registers the first subset of the plurality of access point IHSs as members of a second access point IHS group, and controls at least some functions of the second access point IHS group. When the first access point IHS detects activity from the first access point IHS group controller, it instructs the first subset of the plurality of access point IHSs in the second access point IHS group to reconnect to the first access point IHS group controller.

The system monitors a wireless device, detects when the device has failed or is not operating properly, and is able to remotely reset the device. The device may be reset remotely without a technician required to physically attend to the device. This out of band management allows for quicker, cheaper and more efficient handling of undesired states of a device, such as failure to operate. For a modem, the system may detect that the modem is not broadcasting a signal or is not communicating with the Internet or other network. The reset may be implemented through an access point in communication with the malfunctioning modem. For an access point, the system may detect that the access point is not communicating with a modem or another access point. The reset may be implemented by a neighboring access point or modem.

A method of failure detection in a storage system is performed by the storage system. The method includes detecting a failure in a nonvolatile random access memory device that is in or coupled to a storage device having storage memory. The storage system has multiple NVRAM devices and multiple storage devices that have storage memory. The method includes taking a portion or all of the NVRAM device offline. Taking a portion or all of the NVRAM device offline is responsive to detecting the failure. Taking a portion or all of the NVRAM device off-line is while keeping online the storage memory of the storage device, sufficient ones of the NVRAM devices, and sufficient ones of the storage devices to provide reliable access to data and metadata in the storage system.

A computer system has a storage system including a first port and a second port, and a relay apparatus which couples the first port to an initiator apparatus. The storage apparatus stores relay apparatus information indicating a relay apparatus, and initiator information indicating an initiator apparatus. The storage apparatus establishes communications between the first port and a first relay apparatus, and based on communications with the relay apparatus recognizes the initiator apparatus with which the first relay apparatus has established communications. The storage apparatus also stores, in pathway information, a first pathway containing the first port, the first relay apparatus and the initiator apparatus. The storage apparatus creates a virtual port, which is a virtual port to which the first port is allocated, and when an initiator apparatus establishes communications with the virtual port, this apparatus adds a first virtual port associated pathway, in which the virtual port is associated with the first pathway, to the pathway information.

System and method for fault identification and fault handling in MPSD are provided. The system includes: a multi-port power sourcing device including multiple ports, a master is configured to: send a slave discovery request to multiple slave ports, receive a slave discovery response from the multiple slave ports; reset the watchdog timer in the multiple ports by sending watchdog refresh instruction periodically; each of the multiple ports experience watchdog timer timeout upon failing to receive the watchdog refresh instruction, generate their corresponding port reset upon watchdog timer timeout, to resolve one or more faults associated with the corresponding port; the multiple ports include a role change staggered timer which is triggered upon the corresponding watchdog timer timeout, and reset upon receiving the watchdog refresh instruction from master; the slave ports for which role change staggered timer times out first, changes the role to start functioning as the new master port.

A redundant system for processing at least one signal is described wherein the redundant system has N+1 devices include N operational devices and one reserve device. The N operational devices and the reserve device are interconnected with each other. The redundant system includes a system control integrated within one of the devices of the redundant system. The redundant system further includes switches that are associated with the operational devices. In case of a failure of a respective operational device, the system control is configured to cause at least one of the devices to operate the switch associated with the respective operational device having the failure. Further, a method of operating a redundant system for processing at least one signal is described.

Embodiments are described for systems and methods that facilitate control of virtual endpoint failover/failback during an administrative SCSI target port disable or enable operation. In this case, SCSI target virtual endpoints may failover to a secondary SCSI target port when the primary port fails. When the primary port is corrected and enabled by the administrator the failover method pulls virtual endpoints on secondary ports back to the primary port under administrator control; and if an administrator wishes to manually disable a SCSI target port the failover operation pushes (failover) all virtual endpoints currently using the port as a primary to a secondary port.