Preventing applications from overconsuming shared storage resources, including: identifying one or more sub-regions of data stored on a storage device that are associated with an application of a known application type; compiling information describing the application's utilization of a storage system; determining that a storage system objective has not been met; and initiating, based on the information describing the application's utilization of the storage system, remediation actions.

A memory sub-system configured to schedule the transfer of data from a host system for write commands to reduce the amount and time of data being buffered in the memory sub-system. For example, after receiving a plurality of streams of write commands from a host system, the memory sub-system identifies a plurality of media units in the memory sub-system for concurrent execution of a plurality of write commands respectively. In response to the plurality of commands being identified for concurrent execution in the plurality of media units respectively, the memory sub-system initiates communication of the data of the write commands from the host system to a local buffer memory of the memory sub-system. The memory sub-system has capacity to buffer write commands in a queue, for possible out of order execution, but limited capacity for buffering only the data of a portion of the write commands that are about to be executed.

A storage system includes a NAND storage media and a nonvolatile storage media as a write buffer for the NAND storage media. The write buffer is partitioned, where the partitions are to buffer write data based on a classification of a received write request. Write requests are placed in the write buffer partition with other write requests of the same classification. The partitions have a size at least equal to the size of an erase unit of the NAND storage media. The write buffer flushes a partition once it has an amount of write data equal to the size of the erase unit.

A temperature control method, a memory storage apparatus, and a memory control circuit unit are disclosed. The method includes: detecting a system parameter of the memory storage apparatus, and the system parameter reflects wear of a rewritable non-volatile memory module in the memory storage apparatus; determining a temperature control threshold value according to the system parameter; and performing a temperature reducing operation in response to a temperature of the memory storage apparatus reaching the temperature control threshold value to reduce the temperature of the memory storage apparatus.

A system and method is disclosed for managing data in a non-volatile memory. The system may include a non-volatile memory having multiple non-volatile memory sub-drives. A controller of the memory system is configured to route incoming host data to a desired sub-drive, keep data within the same sub-drive as its source during a garbage collection operation, and re-map data between sub-drives, separate from any garbage collection operation, when a sub-drive overflows its designated amount logical address space. The method may include initial data sorting of host writes into sub-drives based on any number of hot/cold sorting functions. In one implementation, the initial host write data sorting may be based on a host list of recently written blocks for each sub-drive and a second write to a logical address encompassed by the list may trigger routing the host write to a hotter sub-drive than the current sub-drive.

Several embodiments of memory devices and systems having a variable logical memory capacity are disclosed herein. In one embodiment, a memory device can include a plurality of memory regions that collectively define a physical memory capacity and a controller operably coupled to the plurality of memory regions. The controller is configured to advertise a first logical memory capacity to a host device, determine that at least one of the memory regions is at or near end of life, and in response to the determination—send a notification to the host device that a logical memory capacity of the memory device will be reduced and then retire the at least one of the memory regions.

The various embodiments disclose an electronic device including: a storage including a non-volatile memory having a buffer space and a storage space, a storage device controller, and a storage interface, and a processor. According to various embodiments, the processor may be configured to perform control to determine whether the storage supports a high speed data storage mode using a buffer space of a non-volatile memory of the storage, activate a function of writing data buffered in the buffer space of the non-volatile memory into a storage space of the non-volatile memory based on the storage interface operating in a first state based on the storage supporting the high speed data storage mode, and transition the storage interface of the storage to the first state based on no request to the storage being generated during a predetermined time period based on the storage interface operating in a second state.

A memory system which stores a journal including mapping change information, either in a first memory area or a second memory area, depending on available space of a memory device included in the memory system, being greater than a threshold.

A solid state drive management solution is provided, and includes: detecting that a usage status of a first storage space of an SSD meets a preset condition, where the first storage space works in a first mode; and enabling, based on the detection result, the first storage space to work in a second mode to obtain a second storage space, where a quantity of bits that can be stored in a cell in the first storage space is greater than a quantity of bits that can be stored in a cell in the second storage space.

An example method includes maintaining a first data structure comprising logical address to physical address mappings for managed units corresponding to a memory, and maintaining a second data structure whose entries correspond to respective physical managed unit addresses. Each entry of the second data structure comprises an activity counter field corresponding to the respective physical managed unit address and a number of additional fields indicating whether the respective physical managed unit address is in one or more of a number of additional data structures. The one or more additional data structures are accessed in association with performing at least one of a wear leveling operation on the respective physical managed unit address, and a neighbor disturb mitigation operation on physical managed unit addresses corresponding to neighbors of the respective physical managed unit address.