A method for rebuilding data, comprising: obtaining, from a metadata node, a source file data layout for a source file and a target file data layout for a target file, wherein the source file is associated with a degraded mapped RAID group and the target file is associated with a new mapped RAID group; generating, by the client application node, a plurality of input/output (I/O) requests to read a portion of the data associated with the source file using the source file data layout; obtaining, in response to the plurality of I/O requests, the portion of the data associated with the source file; rebuilding a second portion of the data associated with source file using the portion of the data; and initiating, storage of at least the second portion of the data associated with the source file in the storage pool using the target file data layout.

Disclosed is a system including a memory device having a plurality of physical memory segments and a processing device to perform operations that include, responsive to detecting a failure of a memory operation associated with a physical memory segment of the plurality of physical memory segments, quarantining the physical memory segment, responsive to quarantining the physical memory segment, performing one or more scanning operations on the physical memory segment, and determining, based on results of the one or more scanning operations, a viability status of the physical memory segment, wherein the viability status indicates an ability of the physical memory segment to store data.

In one approach, filesets to be backed up are divided into partitions and snapshots are pulled for each partition. In one architecture, a data management and storage (DMS) cluster includes a plurality of peer DMS nodes and a distributed data store implemented across the peer DMS nodes. One of the peer DMS nodes receives fileset metadata for the fileset and defines a plurality of partitions for the fileset based on the fileset metadata. The peer DMS nodes operate autonomously to execute jobs to pull snapshots for each of the partitions and to store the snapshots of the partitions in the distributed data store.

In a method disclosed for writing data, a device receives data, divides the data into one or more data fragments, obtains a first parity fragment based on the one or more data fragments and a second parity fragment of a written data fragment in a stripe distributed across a plurality of nodes, stores the one or more data fragments and the first parity fragment in the stripe.

Software that may be implemented using a circuit is disclosed. The software may include an Application Programming Interface (API) to receive a request from an application relating to a key-value pair for a Key-Value Solid State Drive (KV-SSD). The key-value pair may include a key and a value; the application may be executed by a processor. The software may also include combiner software to combine the key with an index to produce an indexed key, and execution software to execute an operation on the KV-SSD using the indexed key and the value.

A method includes receiving a command to write data to a memory device and writing the data to a first memory tier of the memory device. The first memory tier of the memory device is a dynamic memory tier that utilizes single level cells (SLCs), multi-level cells (MLCs), and triple level cells (TLCs). The method further includes migrating the data from the first memory tier of the memory device to a second memory tier of the memory device. The second memory tier of the memory device is a static memory tier that utilizes quad level cells (QLCs).

A solid state drive (SSD) includes a first storage region classified as byte addressable NV storage region and a controller communicatively coupled to the first storage region by a bus. The controller detects a reduced storage capacity of the first storage region, and in response to the detection, reclassifies the first storage region as a block addressable NV storage region. The SSD dynamically changes byte addressable NV storage regions to block addressable NV storage regions as the byte addressable NV storage regions are degraded, thereby extending the longevity of the SSD.

An apparatus comprises a processing device configured to receive a request to restore one or more applications, the request specifying one of a set of remote copies of storage volumes that store data of the applications. The processing device is also configured to analyze the applications to identify (i) the storage volumes storing data for the applications and (ii) groups comprising the identified storage volumes. The processing device is also configured, responsive to determining that the identified groups are part of a group replication session, to select one of a set of different types of restore processes for performing the restore of the applications to the specified remote copy based at least in part on whether the identified groups comprise additional storage volumes other than the identified storage volumes and to perform the restore of the applications to the specified remote copy utilizing the selected restore process.

Systems, apparatuses and methods may provide for technology that detects a request to program a NAND memory containing a plurality of dies and programs the NAND memory on a stripe-by-stripe basis, wherein each stripe spans the plurality of dies and includes multiple types of pages. The multiple types of pages may reduce program time variability across the stripes and reduce the error susceptibility of the NAND memory.

Aspects of the present disclosure relate to asynchronous memory management. In embodiments, an input/output (IO) workload is received at a storage array. Further, one or more read-miss events corresponding to the IO workload are identified. Additionally, at least one of the storage array's cache slots is bound to a track identifier (TID) corresponding to the read-miss events based on one or more of the read-miss events' two-dimensional metrics.