A flash memory storage management method includes: providing a flash memory module including single-level-cell (SLC) blocks and at least one multiple-level-cell block such as MLC block, TLC block, or QLC block; classifying data to be programmed into groups of data; respectively executing SLC programming and RAID-like error code encoding to generate corresponding parity check codes, to program the groups of data and corresponding parity check codes to the SLC blocks; when completing program of the SLC blocks, performing an internal copy to program the at least one multiple-level-cell block by sequentially reading and writing the groups of data and corresponding parity check codes from the SLC blocks to the multiple-level-cell block according to a storage order of the SLC blocks.

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.

A method for accessing a flash memory module is provide. 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 one super block of the flash memory chips; and allocating a buffer memory space to store a plurality of temporary parities generated when data is written into the at least one first super 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.

Methods, systems, and devices for enhanced data reliability in multi-level memory cells are described. For a write operation, a host device may identify a first set of data to be stored by a set of memory cells at a memory device. Based on a quantity of bits within the first set of data being less than a storage capacity of the set of memory cells, the host device may generate a second set of data and transmit a write command including the first and second sets of data to the memory device. For a read operation, the host device may receive a first set of data from the memory device in response to transmitting a read command. The memory device may extract a second set of data from the first set of data and validate a portion of the first set of data using the second set of data.

Low-density parity-check (LDPC) coding based on memory cell voltage distribution (CVD) in data storage devices. In one embodiment, a memory controller includes a memory interface configured to interface with a non-volatile memory; and a controller. The controller is configured to receive a plurality of data pages to be stored in the non-volatile memory, and transform the plurality of data pages into a plurality of transformed data pages. The controller is further configured to determine a plurality of parity bits based on the plurality of transformed data pages, and store the plurality of data pages and the plurality of parity bits in the non-volatile memory.

A storage system and method for recovering data corrupted in a host memory buffer are provided. In one embodiment, a storage system is provided comprising a non-volatile memory and a controller in communication with the non-volatile memory. The controller is configured to receive a logical-to-physical map from a volatile memory of a host for storage in the storage system's non-volatile memory; determine if there is an error in an entry in the logical-to-physical map; in response to determining that there is no error in the logical-to-physical map, store the logical-to-physical map in the non-volatile memory; and in response to determining that there is an error in an entry in the logical-to-physical map, attempt to recover the entry from a location in the storage system before storing the logical-to-physical map in the non-volatile memory. Other embodiments are provided.

A memory device includes a memory including memory cells, each of the memory cells being configured to store multiple bits of data. The memory device includes a controller configured to map the levels of the memory cells to bits such that a first half of the levels have a bit with a first binary value in a desired bit position and a second half of the levels have a bit with a second binary value in the desired bit position. The first half of the levels are a first group of consecutive levels, and the second half of the levels are a second group of consecutive levels. The controller is configured to generate a distribution for writing the data to the memory cells based on the mapping, and write the data to the memory cells based on the determined distribution.

A memory device includes a memory cell array and a memory controller. The memory cell array includes a plurality of memory blocks. Each of the memory blocks includes a plurality of word lines. A plurality of memory chunks is coupled to at least one of the word lines. The memory controller is configured to program data to a particular memory chunk of the plurality of memory chunks by performing a chunk operation that includes selecting a particular word line from the plurality of word lines, selecting a particular memory chunk from the plurality of memory chunks that are coupled to the particular word line, and applying a program voltage to a particular memory block corresponding to the particular memory chunk to program data to the particular memory chunk.