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.

A method disclosed herein may include receiving a portal group from a node of a distributed storage system, the portal group comprising a plurality of network portals for accessing a storage unit, and transmitting data of the portal group to a first client and to a second client, wherein data transmitted to the first client and data transmitted to the second client each identify the plurality of network portals and indicate a different preferred network portal. The method may further include receiving a request from the first client to initiate a storage session that uses one of the plurality of network portals, establishing the storage session, wherein the storage session comprises multiple paths to the storage unit over at least two of the plurality of network portals, and providing data of the storage unit to the first client using the storage session.

Apparatuses of systems that provide Safety Integration Levels (SILs) and Hardware Fault Tolerance (HFT) include a first die, the first die including first processing logic connected to a first connection and the first connection connected to second processing logic of a second die. The first die may further include a second connection to an input/output (I/O) channel where the second connection is coupled to the first processing logic. The apparatuses may further include a second die, the second die including second processing logic and a third connection from a secondary device coupled to the second processing logic. The secondary device is outside the system. The second processing logic is configured to select among three configurations based on signals from the second processing logic and the secondary device: sending first output data on the I/O output channel, sending second output data on the I/O output channel, or de-energizing the I/O channel.

A computer-implemented method for seamlessly performing a maintenance operation on a stateful system includes mapping a network address of the stateful system to a primary server that uses a primary database to respond to incoming data requests. In response to receiving a maintenance request, the primary database is replicated to a secondary database of a secondary server. The secondary server is updated according to the maintenance request. The method further includes caching, in a replay buffer of the primary server, incoming data requests during the replicating. After the replicating, the data requests from the replay buffer are executed by the secondary server. Write operations to the primary server are disabled during the replicating, and the network address of the stateful system is mapped to the secondary server. Subsequently, the primary server is updated and reinstated by mapping the network address, and enabling the write operations.

A storage system is provided. The storage system includes a backplane; a plurality of single port storage devices; and a plurality of controllers, wherein the backplane routes a plurality of interconnection lanes between the plurality of controllers and the plurality of single port storage devices, wherein the plurality of controllers is configured to: enable at least one second interconnection lane of the plurality of interconnection lanes when a first controller of the plurality of controllers has failed, wherein a first interconnection lane of the plurality of interconnection lanes is between the first controller and a first single port storage device of the plurality of single port storage devices, wherein the at least one second interconnection lane is between a second controller of the plurality of controllers and the first single port storage device.

Non-volatile memory over fabric (NVMe-oF) is used to stream video, computer games, and the like to client devices from network storage embodied by solid state storage devices (SSDs). To provide for redundancy, multiple copies of a single piece of content, e.g., a computer game or video file, are stored on multiple SSDs. To provide information to address the block-level storage based on a client demand for the content, a data structure correlates each content with the SSDs and related block numbers at which the content is stored. Sourcing of the content as it is being streamed may be dynamically switched between SSDs to provide for load balancing or loss of a SSD.

In one embodiment, a system for managing communication connections in a virtualization environment includes a plurality of host machines implementing a virtualization environment, wherein each of the host machines includes a hypervisor, at least one user virtual machine (user VM), and a distributed file server that includes file server virtual machines (FSVMs) and associated local storage devices. Each FSVM and associated local storage device are local to a corresponding one of the host machines, and the FSVMs conduct I/O transactions with their associated local storage devices based on I/O requests received from the user VMs. Each of the user VMs on each host machine sends each of its representative I/O requests to an FSVM that is selected by one or more of the FSVMs for each I/O request based on a lookup table that maps a storage item referenced by the I/O request to the selected one of the FSVMs.

A storage system includes a host including a host queue storing a plurality of commands and a storage device including a storage queue exchanging commands with the host through a first port or a second port, and storing the exchanged commands, wherein the storage device is configured to, when a communication error has occurred through the first port, transfer information about a command stored in the storage queue before the error occurrence to the host through the second port.

Secure cloud-based storage system management that includes: establishing, within a cloud-based services provider and based on one or more user credentials, a cloud-based user session to execute one or more commands on a remote storage system that includes physical storage devices; extending, based on using an access token based on the one or more user credentials to securely issue the one or more data storage operations to the remote storage system, the cloud-based user session to the remote storage system.

A media agent is configured to perform substantially autonomously to initiate, continue, and manage information management operations such as a backup job of a certain client's primary data, manage the operations, and generate and store resultant system-level metadata from the operations, etc. The media agent is configured to do this even when out of communication with the storage manager that manages the information management system. When communications are restored, the media agent reports the relevant metadata to the storage manager. The storage manager comprises corresponding enhancements, including specialized logic for identifying the media agent as an intelligent media agent capable of some autonomous functionality, for transmitting management parameters thereto, and for seamlessly integrating the received metadata into the storage manager's associated management infrastructure such as a management database.