A storage system includes a first storage control device including a first memory being a volatile memory and a first processor, and a second storage control device including a second memory being a non-volatile memory and a second processor, wherein the second processor is configured to receive a first write request to write first data into a first storage device, store the first data into the second memory, and transmit the first data to the first storage control device, the first processor is configured to store the first data into the first memory, and transmit a first notification to the second storage control device, and the second processor is configured to receive the first notification, transmit a first completion notification in response to the first write request, and execute processing to write the first data, stored in the second memory, into the first storage device.

A processor of a storage controller stores a parameter according to a command that has been transferred from a front-end unit to a first area in a first memory area and issues notification to the front-end unit regarding an address of a second area in a second memory area which is mapped to the first area, the front-end unit generates a data packet whose destination is the notified address and stores the generated data packet at the address of the second memory area, and an interface unit reads the parameter stored in the first area in the first memory area which is mapped to the second area of the address based on the destination address stored in a header of the data packet which has been stored in the second memory area and executes processing of the system function according to the command.

A circuit is provided. The circuit includes a ferroelectric tunneling junction (FTJ) coupled in series with a YR read line. The circuit also includes a pull-up circuit having a write line YW as a first input with an output in series with the FTJ, and a pull-down circuit having the write line YW as a first input with an output in series with the second side of the FTJ.

Systems and methods for replicating data from a first site to a second site remote from said first site are described. An embodiment includes storing compressed data on a hard disk appliance, reading said data without decompressing said data, sending said data over a wide-area-network (WAN) in a compressed state, and storing said data on a second hard disk appliance remote from said first hard disk appliance in its compressed state without performing an additional compression operation.

A data storage device includes a memory device and a memory controller. The memory controller maintains a write count for each sub-region of the memory device. When the memory controller has selected one or more sub-regions to perform a data rearrangement procedure, the memory controller further determines whether a selected sub-region is a hot-write sub-region according to the write count corresponding to the selected sub-region. When the memory controller determines that the selected sub-region is not a hot-write sub-region, the memory controller performs the data rearrangement procedure on the selected sub-region to move data corresponding to logical addresses belonging to the selected sub-region to a memory space of the memory device having continuous physical addresses. When the memory controller determines that the selected sub-region is a hot-write sub-region, the memory controller does not perform the data rearrangement procedure on the selected sub-region.

An illustrative method includes receiving a request to create a storage volume; identifying, based on the request and on a configuration file propagated among a plurality of storage nodes in a cluster, status indicators of the storage nodes; identifying, based on the request, a size of the storage volume; identifying, based on the request, a replication factor representing a number of storage nodes that are to be replicated within a cluster for the storage volume; identifying, based on one or more characteristics associated with the storage volume, a traffic priority for the storage volume, the traffic priority representing a hierarchy that determines and prioritizes which traffic is allocated to available hardware and network resources in a particular order; creating, based on the status indicators, the size, the replication factor, and the traffic priority, the storage volume on one or more of the plurality of storage nodes.

A method for managing a data record in a computer system comprises: at least one computing server for hosting a computer session running with an operating system having a deduplication index and managing access to a session storage space; a shared storage space; an administration server for administering the shared storage space, executing a data management program; the computer session executing an interception program implementing the following steps: intercepting a read call to read at least one data record transmitted in the session; accessing the deduplication index and determining whether the data record is recorded in the shared storage space; if so, reading, from the deduplication index, the address of the data record in the shared storage space and redirecting the read call to this address; if not, overlooking the read call so that it is processed by the operating system.

A method is described. The method includes performing the following as part of a process for storing an object into an object storage system: assigning chunks of the object to different servers of the object storage system and constructing a graph for the object that describes which of the chunks of the object are being stored in which of the servers; recognizing a stuck condition in which a server with available storage space to store one of the chunks of the object cannot be found; in response to the recognizing, expanding the graph with information from graphs of other objects that are stored in the object storage system to identify other servers in the object storage system to help resolve the stuck condition; processing the expanded graph information to recognize a predefined graphical pattern; applying a predefined solution for the predefined graphical pattern to the expanded graph information to resolve the stuck situation including modifying at least some of the information from the graphs of the other objects; and, moving chunks of one of the other objects affected by the modifying over a network to a new server within the object storage system.

A system is provided including a first server storing a first data file for a first user, a second server storing a second data file for a second user, a first data card of the first user registered with the first server and locally storing a portion of the first data file, and a second data card of the second user registered with the second server and associated with the second data file. The first data card detects a pairing gesture between the first and second data cards, and in response, establishes a peer-to-peer connection between the data cards.

This application provides a data backup method. The method includes: obtaining, by a first node, an identifier of a backup execution node from a storage device; and backing up data of the first node in the storage device responsive to determining that an ID of the first node is the same as the ID of the backup execution node. The embodiments of this application can improve reliability of the data stored by the first node, and prevent a plurality of nodes from redundantly backing up duplicate data in the storage device. The techniques disclosed herein reduce resource consumption.