A storage control system receives a first write request and a second write request following the first write request. The first and second write requests comprise respective first and second data items for storage to a primary storage. First and second cache write operations are performed in parallel to write the first and second data items a persistent write cache. The first cache write operation comprises a split write operation which comprises writing a parsing header for the first data item to the write cache, and writing a payload of the first data item to the write cache. The second cache write operation comprises storing the second data item and associated metadata in the write cache, and waiting for an acknowledgment that the parsing header for the first data item has been successfully stored in the write cache before returning an acknowledgment indicating successful storage of the second data item.

The present disclosure includes apparatuses and methods related to data transfer in memory. An example apparatus can include a first number of memory devices coupled to a host via a first number of ports and a second number of memory devices coupled to the first number of memory device via a second number of ports, wherein a first number of commands are executed to transfer data between the first number of memory devices and the host via the first number of ports and a second number of commands are executed to transfer data between the first number of memory device and the second number of memory device via the second number of ports.

A data storage system includes multiple head nodes and multiple data storage sleds mounted in a rack. For a particular volume or volume partition one of the head nodes is designated as a primary head node for the volume or volume partition. The primary head node is configured to store data for the volume in a data storage of the primary head node and cause the data to be replicated to a secondary head node. The primary head node is also configured to cause the data for the volume to be stored in a plurality of respective mass storage devices each in different ones of the plurality of data storage sleds of the data storage system.

Disclosed in some examples are memory devices which feature customizable Single Level Cell (SLC) and Multiple Level Cell (MLC) configurations. The configuration (e.g., the size and position) of the SLC cache may have an impact on power consumption, speed, and other performance of the memory device. An operating system of an electronic device to which the memory device is installed may wish to achieve different performance of the device based upon certain conditions detectable by the operating system. In this way, the performance of the memory device can be customized by the operating system through adjustments of the performance characteristics of the SLC cache.

A storage device that includes a nonvolatile memory device is described. The storage device includes areas and a controller. The controller receives a write command and data from an external host device. The controller then preferentially writes the data in an area associated with a turbo write based on a turbo write policy, or in an area not associated with a turbo write based on a normal write policy. The controller also receives a move command from the external host device and moves data stored in the area to a different area based on the move command.

Methods, systems, and devices for configurable flush operation speed are described. Before executing a flush operation at a first portion of a cache including single-level cells (SLCs), a memory system may communicate parameters associated with data stored in the first portion of the cache to a host system. The host system may then identify another portion of the cache (e.g., including either SLCs or multi-level cells (MLCs)) for the flush operation based on the parameters and a speed of a flush operation associated with the other portions of the cache. The host system may indicate the identified portion of the cache to the memory system and the memory system may execute a flush operation at the first portion of the cache. For example, the memory system may write a subset of the data stored at the first portion of the cache to a second portion of the cache.

A Data Storage Device (DSD) includes at least one Non-Volatile Memory (NVM) configured to store data and a Non-Volatile Cache (NVC). Write data is stored in a volatile memory in preparation for writing the write data in the at least one NVM. In response to a power loss of the DSD, at least a portion of the data stored in the volatile memory is transferred from the volatile memory to the NVC and one or more parameters are determined for deriving a margin representing an additional amount of data for transfer from the volatile memory to the NVC using a remaining power following a power loss. A size of the NVC is adjusted based at least in part on the derived margin.

The present embodiments provide a cache data determining method and apparatus, and pertain to the field of computer technologies. The method includes: acquiring a data identifier of read cache miss data; selecting, based on the acquired data identifier, a data identifier of to-be-determined data; recording data identifiers by groups; collecting statistics on quantities of occurrence times, in each group, of the data identifiers; and selecting target to-be-determined data according to the quantities of occurrence times, and determining the target to-be-determined data as cache miss data to be written into a cache memory. Data identifiers are recorded by groups, and after statistics on quantities of occurrence times, in each group, of the data identifiers is collected, target to-be-determined data is selected according to the quantities of occurrence times, and the target to-be-determined data is determined as cache miss data to be written into a cache memory.

The various embodiments described herein include methods, systems, and devices for optimizing media read times. In one aspect, a method is performed at a device at a storage device with one or more processors and memory coupled to the one or more processors. The method includes: (i) predicting a read frequency for particular data; (ii) based on the predicted read frequency, determining one or more preferred storage locations within the memory; and (iii) storing the particular data in a preferred storage location of the one or more preferred storage locations.

Embodiments disclosed herein provide systems, methods, and computer-readable media to implement an object store with removable storage media. In a particular embodiment, a method provides identifying first data for storage on a first removable storage medium and designating at least a portion of the first data to a first data object. The method further provides determining a first location where to store the first data object in a first value store partition of the first removable storage medium and writing the first data object to the first location. Also, the method provides writing a first key that identifies the first data object and indicates the first location to a first key store partition of the first removable storage medium.