Example implementations relate to a method of tracking data in a non-volatile memory device (NVM) device. A meta-data block from the NVM device is obtained, where the meta-data block includes meta-data. The meta-data block from the NVM device is used to track an associated data object, meta-data in the data block, a user data block, a meta-data block, or an additional data block. The meta-data block from the NVM device is used to point to the associated data object, the meta-data in the data block, the user data block, the meta-data block, or the additional data block. The meta-data block from the NVM device is further used to link the associated data object, the meta-data in the data block, the user data block, the meta-data block, or the additional data block.

A method for accessing a flash memory module is provided. The flash memory module is a 3D flash memory module including a plurality of flash memory chips, each flash memory chip includes a plurality of blocks, each block includes a plurality of pages, and the method includes: configuring the flash memory chips to set at least a first super block and at least a second super block of the flash memory chips; and allocating the second super block to store a plurality of temporary parities generated when data is written into the first super block.

This disclosure provides for improvements in managing multi-drive, multi-die or multi-plane NAND flash memory. In one embodiment, the host directly assigns physical addresses and performs logical-to-physical address translation in a manner that reduces or eliminates the need for a memory controller to handle these functions, and initiates functions such as wear leveling in a manner that avoids competition with host data accesses. A memory controller optionally educates the host on array composition, capabilities and addressing restrictions. Host software can therefore interleave write and read requests across dies in a manner unencumbered by memory controller address translation. For multi-plane designs, the host writes related data in a manner consistent with multi-plane device addressing limitations. The host is therefore able to “plan ahead” in a manner supporting host issuance of true multi-plane read commands.

A method for operating a multi-transaction memory system, the method includes: storing Logical Block Address (LBA) information changed in response to a request from a host and a transaction identification (ID) of the request into one page of a memory block; and performing a transaction commit in response to a transaction commit request including the transaction ID from the host, wherein the performing of the transaction commit includes: changing a valid block bitmap in a controller of the multi-transaction memory system based on the LBA information.

An example memory subsystem includes a memory component and a processing device, operatively coupled to the memory component. The processing device is configured to receive a plurality of logical-to-physical (L2P) records, wherein an L2P record of the plurality of L2P records maps a logical block address to a physical address of a memory block on the memory component; determine a sequential assist value specifying a number of logical block addresses that are mapped to consecutive physical addresses sequentially following the physical address specified by the L2P record; generate a security token encoding the sequential assist value; and associate the security token with the L2P record.

A computer program product, according to one embodiment, includes a computer readable storage medium having program instructions embodied therewith, the program instructions executable by a computer to cause the computer to: receive, by the computer, a data set allocation request; determine, by the computer, whether a size of the data set is greater than a threshold; use, by the computer, first key values in a first index to select a volume in response to determining that the size of the data set is greater than the threshold; use, by the computer, second key values in a second index to select a volume in response to determining that the size of the data set is less than the threshold; perform, by the computer, the allocation request in the selected volume; and store, by the computer, control data about the data set in the control data set corresponding to the selected volume.

An operating method of a storage device and a nonvolatile memory device determine whether a nonvolatile memory device performs a program operation on at least one of a plurality of pages. Either a program time stamp table, managed with program elapsed times of the plurality of pages, or an update count of the program time stamp table is updated, based on the determination result.

A memory controller includes a meta data memory configured to store mapping information of data stored in a plurality of memory blocks included in a memory device and valid data information indicating whether the data stored in the plurality of memory blocks is valid data, and a migration controller configured to control the memory device to perform a migration operation of moving a plurality of valid data stored in a source memory block among the plurality of memory blocks from the source memory block to a target memory block based on the mapping information and the valid data information.

A memory apparatus includes at least one non-volatile memory element, which includes a plurality of physical blocks. A method for managing the memory apparatus includes: obtaining a first host address from a received first access command; linking the first host address to a first page of the physical block; obtaining a second host address from a received second access command; linking the second host address to a second page of the physical block; and selectively erasing a portion of the blocks according to a valid/invalid page count of the physical block corresponding to accessing pages of the physical block. A difference value of the first host address and the second host address is greater than a number of pages of the physical block.

A data storage device and method for preventing data loss during an ungraceful shutdown are provided. In one embodiment, a data storage device is provided comprising a volatile memory; a non-volatile memory; and a controller. The controller is configured to detect an ungraceful shutdown; and in response to detecting the ungraceful shutdown: generate a reduced set of parity bits for data stored in the volatile memory, wherein the reduced set of parity bits comprises fewer parity bits than a full set of parity bits used in a graceful shutdown; and store the data and the reduced set of parity bits in the non-volatile memory. Other embodiments are possible, and each of the embodiments can be used alone or together in combination.