Methods, systems, and devices for reduced pin status register are described. An apparatus may include a first memory die and a second memory die each coupled with a data bus. The apparatus may further include a controller coupled with the first memory die and the second memory die via the data bus that is configured to transmit a first command associated with a first operation to the first memory die and a second command associated with a second operation to the second memory die. The controller may further transmit a third command concurrently to the first memory die and the second memory die, the third command requesting a first status of the first operation and a second status of the second operation. The controller may receive the first status and the second status concurrently via the data bus from the first memory die and the second memory die.

The present disclosure includes apparatuses and methods related to a memory protocol. An example apparatus can execute a read command that includes a first chunk of data and a second chunk of data by assigning a first read identification (RID) number to the first chunk of data and a second RID number to the second chunk of data, sending the first chunk of data and the first RID number to a host, and sending the second chunk of data and the second RID number to the host. The apparatus can be a non-volatile dual in-line memory module (NVDIMM) device.

A first command is scheduled on a command bus, where the first command requires use of a data bus resource at a first time period after scheduling the first command. Prior to the first time period, a second command is identified according to a scheduling policy. A determination is made whether scheduling the second command on the command bus will cause a conflict in usage of the at least one data bus resource. In response to determining that scheduling the second command will cause the conflict in usage, a third lower-priority command is identified for which scheduling on the command bus will not cause the conflict in usage. The third command is scheduled on the command bus prior to scheduling the second command, even though it has lower priority than the second command.

A method for direct memory access includes: receiving a direct memory access request designating addresses in a data block to be accessed in a memory; randomizing an order of the addresses the data block is accessed; and accessing the memory at addresses in the randomized order. A system for direct memory access is disclosed.

Systems and methods are directed to managing access to a shared memory. A request received at a memory controller, for access to the shared memory from a client of one or more clients configured to access the shared memory, is placed in at least one queue in the memory controller. A series of one or more timeout values is assigned to the request, based, at least in part on a priority associated with the client which generated the request. The priority may be fixed or based on a Quality-of-Service (QoS) class of the client. A timer is incremented while the request remains in the first queue. As the timer traverses each one of the one or more timeout values in the series, a criticality level of the request is incremented. A request with a higher criticality level may be prioritized for servicing over a request with a lower criticality level.

Methods, systems, and devices for memory device access techniques are described. Memory systems may be enabled to allow device-controlled access to a portion of volatile memory at a host system. By enabling the memory system to access volatile memory at the host system, the memory system may perform access operations which may reduce a quantity of messages exchanged between the memory system to the host system. The host system may allocate a list of memory resources in volatile memory associated with a first access command. The host system may allocate the same memory resources for a second access command. By allocating the same memory resources, the memory device may transmit a Ready To Transfer (RTT) message for multiple access commands, rather than for each command. In some cases, reducing the quantity of RTT messages may reduce latency and improve performance at the memory system.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for processing data on a memory controller. One of the methods comprises obtaining a first request and a second request to access respective data corresponding to the first and second requests at a first memory device of the plurality of memory devices; and initiating interleaved processing of the respective data; receiving an indication to stop processing requests to access data at the first memory device and to initiate processing requests to access data at a second memory device, determining that the respective data corresponding to the first and second requests have not yet been fully processed at the time of receiving the indication, and in response, storing, in memory accessible to the memory controller, data corresponding to the requests which have not yet been fully processed.

A memory control circuit includes an access storage unit configured to store access requests for a memory, a status management unit configured to, based on the access requests stored in the access storage unit, perform priority access type switching between two access types obtained by classifying the access requests, and an access selection unit configured to select and execute an access request stored in the storage unit. The access selection unit performs, if the priority access type switching is in progress and there is time for executing an access request of a priority access type before the priority access type switching, selecting the access request of the priority access type before the priority access type switching, and if the priority access type switching is not in progress, selecting an access request of the priority access type.

A data processor includes a staging buffer, a command queue, a picker, and an arbiter. The staging buffer receives and stores first memory access requests. The command queue stores second memory access requests, each indicating one of a plurality of ranks of a memory system. The picker picks among the first memory access requests in the staging buffer and provides selected ones of the first memory access requests to the command queue. The arbiter selects among the second memory access requests from the command queue based on at least a preference for accesses to a current rank of the memory system. The picker picks accesses to the current rank among the first memory access requests of the staging buffer and provides the selected ones of the first memory access requests to the command queue.

Systems and methods for invalidating page translation entries are described. A processing element may apply a delay to a drain cycle of a store reorder queue (SRQ) of a processing element. The processing element may drain the SRQ under the delayed drain cycle. The processing element may receive a translation lookaside buffer invalidation (TLBI) instruction from an interconnect connecting the plurality of processing elements. The TLBI instruction may be an instruction to invalidate a translation lookaside buffer (TLB) entry corresponding to at least one of a virtual memory page and a physical memory frame. The TLBI instruction may be broadcasted by another processing element. The application of the delay to the drain cycle of the SRQ may decrease a difference between the drain cycle of the SRQ and an invalidation cycle associated with the TLBI.