According to one embodiment, an information processing apparatus includes a storage device, a volatile memory, and a processor. The storage device includes a controller, a first nonvolatile storage module, and a second nonvolatile storage module whose access speed is higher than an access speed of the first nonvolatile storage module. The processor is configured to execute an operating system and a cache driver that are loaded into the volatile memory. The cache driver uses at least part of an area in the second nonvolatile storage module as a cache for the first nonvolatile storage module.

According to one embodiment, an information processing apparatus includes a storage device, a volatile memory, and a processor. The storage device includes a controller, a first nonvolatile storage module, and a second nonvolatile storage module whose access speed is higher than an access speed of the first nonvolatile storage module. The processor is configured to execute an operating system and a cache driver that are loaded into the volatile memory. The cache driver uses at least part of an area in the second nonvolatile storage module as a cache for the first nonvolatile storage module.

A computer system stores metadata that is used to identify physical memory devices that store randomly-accessible data for memory of the computer system. In one approach, access to memory in an address space is maintained by an operating system of the computer system. Stored metadata associates a first address range of the address space with a first memory device, and a second address range of the address space with a second memory device. The operating system manages processes running on the computer system by accessing the stored metadata. This management includes allocating memory based on the stored metadata so that data for a first process is stored in the first memory device, and data for a second process is stored in the second memory device.

A memory system having a plurality of memory components and a controller, operatively coupled to the plurality of memory components to: store data in the memory components; communicate with a host system via a bus; service the data to the host system via communications over the bus; communicate with a processing device that is separate from the host system using a message passing interface over the bus; and provide data access to the processing device through communications made using the message passing interface over the bus.

Data is stored at a cache portion of a cache memory of a memory sub-system responsive to a request to perform a write operation to write the data. A duplicate copy of the data is stored at a write buffer portion of the cache memory. The cache memory is partitioned into the cache portion and the write buffer portion. An entry that maps a location of the duplicate copy of the data stored at the write buffer portion of the cache memory to a location of the data stored at the cache portion of the cache memory is recorded in a write buffer record.

Memory controllers, devices, modules, systems and associated methods are disclosed. In one embodiment, a memory system is disclosed. The memory system includes volatile memory configured as a cache. The cache stores first data at first storage locations. Backing storage media couples to the cache. The backing storage media stores second data in second storage locations corresponding to the first data. Logic uses a presence or status of first data in the first storage locations to cease maintenance operations to the stored second data in the second storage locations.

A memory module according to some embodiments is operable in a computer system, and comprises a volatile memory subsystem and a module controller coupled to the volatile memory subsystem. The volatile memory subsystem is configurable to be coupled to a memory channel including a data bus, and includes dynamic random access memory (DRAM) devices. The memory module allows independent control of strobe paths and data paths between the DRAM devices and the data bus, and is configurable to perform a memory write operation during which write data is provided to the volatile memory subsystem together with write strobes transmitted via first strobe paths between the DRAM devices and the data bus, and a memory read operation during which read data from the volatile memory subsystem is output onto the data bus together with read strobes transmitted via second strobe paths between the module controller and the data bus.

A method of optimising a service rate of a buffer in a computer system having memory stores of first and second type is described. The method selectively services the buffer by routing data to each of the memory store of the first type and the second type based on read/write capacity of the memory store of the first type.

Methods, systems, and devices for usage level identification for memory device addresses are described. Systems, techniques, and devices are described herein in which a memory device may determine where to store data according to a level of usage of the data. The memory device may receive a write command indicating data to be written, a type of the data, and a logical address of a memory array for writing the data. The memory device may identify an entry associated with the logical address in a table that maps the logical address to a physical address of the memory array. The entry may include a field configured to maintain a level of usage for the logical address. The memory device may update the level of usage value according to a process and write the data to a physical address of the memory array based on the level of usage value.

Various embodiments provide for one or more processor instructions and memory instructions that enable a memory sub-system to copy, move, or swap data across (e.g., between) different memory tiers of the memory sub-system, where each of the memory tiers is associated with different memory locations (e.g., different physical memory locations) on one or more memory devices of the memory sub-system.