An arithmetic processor includes a memory access controller configured to control access of a memory based on a memory access request. The memory access controller includes a shift register configured to shift a resource number and a memory access request from a first stage to a subsequent stage of the first stage at a timing according to the operation mode, the first stage is received a resource number and a memory access request. The memory access controller includes a plurality of memory access transmitting circuits configured to receive the resource number and the memory access request held by the plurality of stage. Each of the plurality of access transmitting circuits provided corresponding to the plurality of resource number, and output, to the memory, an access command corresponding to the memory access request when the received resource number matches a resource number of a memory access transmitting circuit.

A system includes a bus, at least one processor coupled to the bus, and a storage device coupled to the bus. The storage device includes storage class memory, a buffer; and a controller. The controller is configured to receive an instruction to provide data to the bus. Responsive to receiving the instruction to provide data to the bus, the controller is configured to retrieve data from the storage class memory, update the buffer to represent the data retrieved from the storage class memory, and output, at the bus, an indication that data responsive to the instruction to provide data to the bus is available at the buffer. The at least one processor is configured to refrain from modifying local data corresponding to the instruction to provide data to the bus after the controller receives the instruction to provide data to the bus and before the controller outputs the indication.

In one embodiment, a computer-implemented method includes issuing, to a DRAM with EIP, a first group of two or more load requests to load data from a hash table constructed from hashed join-key values of a dimension table for a hash-join procedure. A second group of two or more load requests is issued. First response data is received, responsive to the first group of load requests. The first response data is processed while awaiting second response data responsive to the second group. Processing the first response data includes identifying matches between the join-key values corresponding to entries in the load requests of the first group and one or more hash buckets in the first response data. The size of the second group of load requests is selected such that a time for processing the first response data is approximately equal to the latency in receiving the second response data.

A memory device includes receivers that use CMOS signaling levels (or other relatively large signal swing levels) on its command/address and data interfaces. The memory device also includes an asynchronous timing input that causes the reception of command and address information from the CMOS level receivers to be decoded and forwarded to the memory core (which is self-timed) without the need for a clock signal on the memory device's primary clock input. Thus, an activate row command can be received and initiated by the memory core before the memory device has finished exiting the low power state. Because the row operation is begun before the exit wait time has elapsed, the latency of one or more accesses (or other operations) following the exit from the low power state is reduced.

An interface circuit of a memory device including a plurality of memory dies including a plurality of registers corresponding to the plurality of memory dies, respectively, the plurality of registers each configured to store command information related to a data operation command, a demultiplexer circuit configured to provide input command information to a selected register from among the plurality of registers according to at least one of a first address or a first chip selection signal, the input command information being received from outside the interface circuit, and a multiplexer circuit configured to receive output command information from the selected register from among the plurality of registers and output the output command information according to at least one of a second address or a second chip selection signal may be provided.

An arithmetic processor includes a memory access controller configured to control access of a memory based on a memory access request. The memory access controller includes a shift register configured to shift a resource number and a memory access request from a first stage to a subsequent stage of the first stage at a timing according to the operation mode, the first stage is received a resource number and a memory access request. The memory access controller includes a plurality of memory access transmitting circuits configured to receive the resource number and the memory access request held by the plurality of stage. Each of the plurality of access transmitting circuits provided corresponding to the plurality of resource number, and output, to the memory, an access command corresponding to the memory access request when the received resource number matches a resource number of a memory access transmitting circuit.

A first master receives a first virtual address in a virtual memory, the first virtual address in the virtual memory corresponding, according to a mapping function, to a first physical address of a first physical memory bank which is to be accessed by the first master. The first master accesses the first physical address to perform a first memory operation in the first memory bank. A second master receives a second virtual address in a virtual memory, the second virtual address in the virtual memory corresponding, according to the mapping function, to a second physical address of a second physical memory bank which is to be accessed by the second master. Concurrently with access by the first master to the first physical address, the second master accesses the second physical address to perform a second memory operation in the second physical memory bank.

A data pipeline circuit includes an upstream interface circuit that receives sequential data and a downstream interface circuit that transfers the sequential data to a downstream circuit. A ready signal indicates the downstream circuit is ready to receive the sequential data. The data pipeline circuit includes a first data latch, a second data latch and a first status latch. The first data latch receives the sequential data. The first status latch generates an available signal that is asserted to indicate the second data latch is available to receive the sequential data. The second data latch receives the sequential data in response on the available signal being asserted and the ready signal indicating the downstream circuit is not ready to receive the sequential data on the data output. Limiting conditions in which the sequential data is stored in the second data latch significantly reduces power consumption of the data pipeline circuit.

Dynamic random access memory (DRAM) data may be accessed by a memory controller using a broadcast mode or a non-broadcast mode. In the broadcast mode, a first portion of data that is the subject of an access request and a second portion of the data that is the subject of the access request may be accessed concurrently via first and second pseudo-channels, respectively. In the non-broadcast mode, data that is the subject of the access request may be accessed via a selected one of the first and second pseudo-channels.

Techniques for implementing and/or operating an apparatus, which includes a memory system coupled to a processing system via a memory bus. The memory system includes hierarchical memory levels and a memory controller. The memory controller receives a memory access request at least in part by receiving an address parameter indicative of a memory address associated with a data block from the memory bus during a first clock cycle and receiving a context parameter indicative of context information associated with current targeting of the data block from the memory bus during a second clock cycle, instructs the memory system to output the data block to the memory bus based on the memory address indicated in the address parameter, and predictively controls data storage in the hierarchical memory levels based at least in part on the context information indicated in the context parameter of the memory access request.