A processor memory mapped boot system includes a processing system having a processor memory subsystem, and a memory system having at least one memory device. A Basic Input/Output System (BIOS) engine is coupled to the processing system and the memory system, and is configured to begin boot operations and detect a boot memory mode setting for the processor memory subsystem. The BIOS engine configures a memory space that includes the at least one memory device and the processor memory subsystem. In response to detecting the boot memory mode setting, the BIOS engine will configured the processor memory subsystem to provide a first memory region of the memory space. The BIOS engine will then complete boot operations utilizing the processor memory subsystem providing the first memory region of the memory space.

Various embodiments are generally directed to virtualized systems. A first guest memory page may be identified based at least in part on a number of accesses to a page table entry for the first guest memory page in a page table by an application executing in a virtual machine (VM) on the processor, the first guest memory page corresponding to a first byte-addressable memory. The execution of the VM and the application on the processor may be paused. The first guest memory page may be migrated to a target memory page in a second byte-addressable memory, the target memory page comprising one of a target host memory page and a target guest memory page, the second byte-addressable memory having an access speed faster than an access speed of the first byte-addressable memory.

A method includes identifying an ahead-of-time (AOT) native-image application to be compiled and during AOT compilation of the AOT native-image application; bypassing an operating system page cache corresponding to the AOT native-image application; and accessing, by a processing device, the native-image application from an in-memory cache shared using inter-process-communication.

A memory module includes a first type memory, a second type memory, a serial presence detect device and a controller. The serial presence detect device is configured to transfer capacity information of the second type memory to an external host device, during an initialization operation. The controller is configured to transfer a training command for the second type memory received from the external host device to the first type memory, during a training operation, which follows in time the initialization operation.

Subject matter disclosed herein relates to management of a memory device.

According to one embodiment, a storage server includes first tiered storage devices, a network interface and a processor. The network interface communicates with each of a client and another storage server through a network. The other storage server includes second tiered storage devices. The processor reads, when a read request is received from the client, data designated by the read request from the first tiered storage devices, and transmits the read data to the client. The processor relocates data among the first tiered storage devices and transmits information indicative of data placement in the first tiered storage devices after the relocation of the data as a hint for data relocation among the second tiered storage devices, to the other storage server.

The present disclosure includes apparatuses and methods for a cache architecture. An example apparatus that includes a cache architecture according to the present disclosure can include an array of memory cells configured to store multiple cache entries per page of memory cells; and sense circuitry configured to determine whether cache data corresponding to a request from a cache controller is located at a location in the array corresponding to the request, and return a response to the cache controller indicating whether cache data is located at the location in the array corresponding to the request.

A nonvolatile memory device includes a nonvolatile memory, a volatile memory being a cache memory of the nonvolatile memory, and a first controller configured to control the nonvolatile memory. The nonvolatile memory device further includes a second controller configured to receive a device write command and an address, and transmit, to the volatile memory through a first bus, a first read command and the address and a first write command and the address sequentially, and transmit a second write command and the address to the first controller through a second bus, in response to the reception of the device write command and the address.

Devices, systems, and methods for transferring data between the memory domain and the storage domain are described. Transferring data between domains can comprise changing the validity of the block address of the data from one domain to the other, and updating a memory domain map and a storage domain map to reflect the transfer.

A three-dimensional stacked (3DS) memory module includes multiple memory chips physically integrated with a data I/O chip. The data I/O chip includes multiple data interfaces and multiple respectively corresponding data buffers. A memory controller routes data traffic through all available data interfaces for maximum bandwidth. In some circumstances, the memory controller directs the data I/O chip to de-activate one or more of the data interfaces (for example, to reduce power consumption). All subsequent data traffic to and from the memory module is routed through the remaining active interfaces. All physical addresses in the 3DS memory module are addressable through the remaining active interfaces. In some circumstances, the memory controller directs the data I/O chip to re-activate some or all of the de-activated data interfaces. Once re-activated, subsequent data traffic to and from the memory module can again be routed through all active interfaces.