To prevent a bank conflict in a memory with respect to an access address interval of a wide range. In a plurality of memory modules, an address is provided in a circulation manner for each word. A plurality of access ports is input/output ports for accessing the plurality of memory modules. A plurality of address converting sections converts the address to rearrange an arrangement of the words in the plurality of memory modules by a transposing process for a square matrix of a predetermined size. A connecting section connects the plurality of memory modules and the plurality of access ports in accordance with a result of the address conversion.

Methods, apparatuses, and systems related to mapping a virtual address using a content addressable memory (CAM) are described. In a memory system including a memory and a content addressable memory (CAM), a select line of the CAM can be coupled to a corresponding select line of the memory, which allows the memory system to map a virtual address of a memory device directly to the corresponding select line of the memory. An example method can include receiving, from a host at a memory device comprising a memory array and a content addressable memory (CAM), a first virtual address to be searched among virtual addresses stored within the CAM, identifying, in response to receipt of the first virtual address, a select line of a plurality of select lines of the CAM associated with a second virtual address matching the first virtual address, and activating, in response to identifying the select line of the CAM, a corresponding select line of the memory coupled to the identified select line of the CAM.

A memory module includes first memory chips, each having a first input/output width, and configured to store data, a second memory chip having a second input/output width and configured to store an error correction code for correcting an error in the data, and a driver circuit configured to receive a clock signal, a command, and an address from a memory controller and to transmit the clock signal, the command, and the address to the first memory chips and the second memory chip. An address depth of each of the first memory chips and an address depth of the second memory chip are different from each other.

Techniques for setting a 2-level auto-close timer to access a memory device include examples of setting first and second time values for the 2-level auto-close timer to cause accessed rows to auto-close following a cache line access to a row of a bank of memory devices. For these examples, the cache line access is responsive to a multi-channel address interleaving policy that causes either successive or non-successive cache line accesses to the bank of memory devices.

A memory controller may be configured with command logic that is capable of sending a memory access command having incomplete address information via a command/address bus that connects the memory controller to memory modules. The memory controller may send the memory access command via the bus for accessing data stored at memory locations of the memory modules. The memory locations may correspond to different near-memory generated reflecting that the data is not address aligned across the memory modules. Nonetheless, because of the near-memory address generation, the memory controller can send the memory access command having incomplete address information for accessing the data stored at the different addresses, as opposed to having to send multiple memory access commands specifying complete address information on the bus for accessing the data at the different addresses, thereby conserving usage of the available bus bandwidth, reducing power consumption, and increasing compute throughput.

According to one embodiment, when receiving a write command including a first identifier of identifiers for accessing regions from a host, a memory system allocates one block of a common free block group shared by the regions as a write destination block for the region corresponding to the first identifier. When receiving a copy command including a block address of a copy source block of blocks belonging to the region corresponding to the first identifier, and an identifier of a copy destination target region indicative of the first identifier from the host, the memory system allocates one block as a copy destination block for the region corresponding to the first identifier, and copies data from the copy source block to the copy destination block.

A memory attachment and routing chip includes a single die having a set of external ports; at least one memory attachment interface comprising a memory controller to attach to external memory, and a fabric core in which routing logic is implemented. The routing logic can (i) receive a first packet of a first type from a first port of the set of ports, the first type of packet being a memory access packet with a memory address which lies in a range of memory addresses associated with the memory attachment and routing chip, detect the memory address and route the packet of the first type to the memory attachment interface. The routing logic can (ii) receive a second packet of a second type, the second type of packet being an inter-processor packet comprising a destination identifier identifying a processing chip external to the memory attachment.

According to one embodiment, when receiving a write command including a first identifier of identifiers for accessing regions from a host, a memory system allocates one block of a common free block group shared by the regions as a write destination block for the region corresponding to the first identifier. When receiving a copy command including a block address of a copy source block of blocks belonging to the region corresponding to the first identifier, and an identifier of a copy destination target region indicative of the first identifier from the host, the memory system allocates one block as a copy destination block for the region corresponding to the first identifier, and copies data from the copy source block to the copy destination block.

An unbalanced plane management method, an associated data storage device and the controller thereof are provided. The unbalanced plane management method may include: setting an unbalanced plane number; selecting at least one plane with a plane count calculated by subtracting the unbalanced plane number from a maximum plane number, and recording at least one set of blocks of the at least one plane to a block skip table; according to block numbers as indexes, combining blocks of unselected planes into superblocks, wherein said superblocks respectively correspond to said block numbers; and recording total capacity of all superblocks and the unbalanced plane number, to generate a latest record of records of multiple types of storage capacity, for further setting storage capacity configuration of the data storage device, wherein said all superblocks include said superblocks.

A cache memory includes a first cache area corresponding to even addresses, and a second cache area corresponding to odd addresses, wherein each of the first and second cache areas includes a plurality of cache sets, and each cache set includes a data set field suitable for storing data corresponding to an address among the even and odd addresses, and a pair field suitable for storing information on a location where data corresponding to an adjacent address which is adjacent to an address corresponding to the stored data is stored.