Techniques for block storage using a hybrid memory device are described. In at least some embodiments, a hybrid memory device includes a volatile memory portion, such as dynamic random access memory (DRAM). The hybrid memory device further includes non-volatile memory portion, such as flash memory. In at least some embodiments, the hybrid memory device can be embodied as a non-volatile dual in-line memory module, or NVDIMM. Techniques discussed herein employ various functionalities to enable the hybrid memory device to be exposed to various entities as an available block storage device.

The present disclosure relates to a location-aware data storage device. The data storage device may record previous locations of the data storage device and may identify a pattern of use based on the previous locations. The data storage device may determine a predicted location based on the pattern of use and may activate a storage medium when the data storage device is within a predetermined proximity to the predicted location.

Embodiments of the present disclosure provide a method of storage management, a storage system and a computer program product. The method comprises determining whether a number of I/O requests for a first page in a disk of a storage system exceeds a first threshold. The method further comprises: in response to determining that the number exceeds the first threshold, caching data in the first page to a first cache of the storage system; and storing metadata associated with the first page in a Non-Volatile Dual-In-Line Memory Module (NVDIMM) of the storage system.

Applications may allocate and deallocate persistent objects within transactions used to access persistent data. An allocator's persistent metadata may be lazily persisted when the enclosing transaction commits. An allocator's metadata may be divided into persistent and nonpersistent portions while the heap may be divided into shared and thread-private superblocks. The persisting of the effects of allocation/deallocation calls may be lazily performed and bundled with the enclosing transaction's commit operation related persist barriers. A transaction may maintain an allocation log of the allocation/deallocation calls made by the transaction. An allocation log may be hosted in persistent memory and updated during allocation/deallocation calls. No persist barriers may be used during allocation/deallocation calls. Before a transaction commits, its updates and allocation log may be persisted. Once the transaction has been committed, the allocation log may be applied to the heap's corresponding metadata.

An allocation instruction is received that includes a target data operand and a storage medium operand indicating a storage medium for storing the target data. A data dependency is identified that specifies metadata that includes access control information specifying which users have permission to perform a write operation to the file that includes the target data. In response to determining that the allocation instruction allocates the target data from a first storage medium to a second storage medium having a faster data IO rate, the allocation instruction is modified to also allocate the metadata specified in the data dependency to the second storage medium. In another aspect, the allocation instruction is modified to also allocate the metadata identified in the data dependencies to one or more storage mediums with data IO rates that are at least as fast as the second storage medium.

Embodiments of the present disclosure relate to managing volatile and non-volatile memory. A set of volatile memory sensor data may be obtained. A set of non-volatile memory sensor data may be obtained. The set of volatile memory sensor data and the set of non-volatile memory sensor data may be analyzed. A memory condition may be determined to exist based on the analysis. In response to determining that the memory condition exists, one or more memory actions may be issued.

A data management device includes a buffer and a processor. The processor may select an unprocessed full key and generate a buffer entry based on a difference between an entry of a local snapshot specified by the unprocessed full key and an entry of a previous local snapshot specified by the unprocessed full key. The processor may make a first determination that a lookup key entry associated with the unprocessed full key is different than a lookup key entry associated with a processed full key. The process may add the generated buffer entry to the buffer after processing the buffer in response to the first determination.

A control plane for controlling transfer of data to a data plane is disclosed. In one aspect, the control plane comprises memory cells for storing a digitally coded parameter value and having a data input electrode, a data output electrode and a control electrode, n data input terminals that receive a data input value and apply it to the data input electrode of an associated memory cell, and n data output terminals coupled to a data output electrode of an associated memory cell. The control plane further comprise a first delay line having delay elements and arranged for receiving a stream of control bit values, and a second delay line having delay elements and arranged for receiving a signal for enabling the control bit values in the first delay line, wherein data is transferred in a controlled and synchronized fashion to an output electrode.

Embodiments of the present disclosure relate to managing volatile and non-volatile memory. A set of volatile memory sensor data may be obtained. A set of non-volatile memory sensor data may be obtained. The set of volatile memory sensor data and the set of non-volatile memory sensor data may be analyzed. A memory condition may be determined to exist based on the analysis. In response to determining that the memory condition exists, one or more memory actions may be issued.

Embodiments of the present disclosure relate to managing volatile and non-volatile memory. A set of volatile memory sensor data may be obtained. A set of non-volatile memory sensor data may be obtained. The set of volatile memory sensor data and the set of non-volatile memory sensor data may be analyzed. A memory condition may be determined to exist based on the analysis. In response to determining that the memory condition exists, one or more memory actions may be issued.