Abstract: Described are self-learning systems and methods for adaptive management of memory resources within a memory hierarchy. Memory allocations associated with different active functions are organized into blocks for placement in alternative levels in a memory hierarchy optimized for different metrics of e.g. cost and performance. A host processor monitors a performance metric of the active functions, such as the number of instructions per clock cycle, and reorganizes the function-specific blocks among the levels of the hierarchy. Over time, this process tends toward block organizations that improve the performance metric.

Abstract: The creation, maintenance, and accessing of page tables is done by a virtual machine monitor running on a computing system rather than the guest operating systems. This allows page table walks to be completed in fewer memory accesses when compared to the guest operating system's maintenance of the page tables. In addition, the virtual machine monitor may utilize additional resources to offload page table access and maintenance functions from the CPU to another device, such as a page table management device or page table management node. Offloading some or all page table access and maintenance functions to a specialized device or node enables the CPU to perform other tasks during page table walks and/or other page table maintenance functions.

Abstract: Computing devices, methods, and systems for switch-based free memory tracking in data center environments are disclosed. An exemplary switch integrated circuit (IC), which is used in a switched fabric or a network, can include a processing device and a tracking structure that is distributed with at least a second switch IC. The tracking structure tracks free memory units that are accessible in a first set of nodes by the second switch IC. The processing device receives a request for a number of free memory units. The processing device forwards the request to a node in the first set of nodes that has at least the number of free memory units or forwards the request to the second switch IC that has at least the number of free memory units or responds to the request with a response that indicates that the request could not be fulfilled.

Abstract: Memory pages are background-relocated from a low-latency local operating memory of a server computer to a higher-latency memory installation that enables high-resolution access monitoring and thus access-demand differentiation among the relocated memory pages. Higher access-demand memory pages are background-restored to the low-latency operating memory, while lower access-demand pages are maintained in the higher latency memory installation and yet-lower access-demand pages are optionally moved to yet higher-latency memory installation.

Abstract: A multi-path fabric interconnected system with many nodes and many communication paths from a given source node to a given destination node. A memory allocation device on an originating node (local node) requests an allocation of memory from a remote node (i.e., requests a remote allocation). The memory allocation device on the local node selects the remote node based on one or more performance indicators. The local memory allocation device may select the remote node to provide a remote allocation of memory based on one or more of: latency, availability, multi-path bandwidth, data access patterns (both local and remote), fabric congestion, allowed bandwidth limits, maximum latency limits, and, available memory on remote node.

Abstract: A memory allocation device on an originating node requests an allocation of memory from a remote node. In response, the memory allocation device on the remote node returns a global system address that can be used to access the remote allocation from the originating node. Concurrent with the memory allocation device assigning (associating) a local (to its node) physical address to be used to access the remote allocation, the remote node allocates local physical memory to fulfill the remote allocation request. In this manner, the remote node has already completed the overhead operations associated with the remote allocation requested by the time the remote allocation is accessed by the originating node.

Abstract: A memory allocation device for deployment within a host server computer includes control circuitry, a first interface to a local processing unit disposed within the host computer and local operating memory disposed within the host computer, and a second interface to a remote computer. The control circuitry allocates a first portion of the local memory to a first process executed by the local processing unit and transmits, to the remote computer via the second interface, a request to allocate to a second process executed by the local processing unit a first portion of a remote memory disposed within the remote computer. The control circuitry further receives instructions via the first interface to store data at a memory address within the first portion of the remote memory and transmits those instructions to the remote computer via the second interface.

Abstract: Described are self-learning systems and methods for adaptive management of memory resources within a memory hierarchy. Memory allocations associated with different active functions are organized into blocks for placement in alternative levels in a memory hierarchy optimized for different metrics of e.g. cost and performance. A host processor monitors a performance metric of the active functions, such as the number of instructions per clock cycle, and reorganizes the function-specific blocks among the levels of the hierarchy. Over time, this process tends toward block organizations that improve the performance metric.

Abstract: A sensing device projects near-field spatial modulations onto a closely spaced photodetector array. Due to physical properties of the grating, the point-spread response distributes spatial modulations over a relatively large area on the array. The spatial modulations are captured by the array, and photographs and other image information can be extracted from the resultant data. An image-change detector incorporating such a sensing device uses very little power because only a small number of active pixels are required to cover a visual field.

Abstract: A sensing device projects near-field spatial modulations onto a closely spaced photodetector array. Due to physical properties of the grating, the point-spread response distributes spatial modulations over a relatively large area on the array. The spatial modulations are captured by the array, and photographs and other image information can be extracted from the resultant data. An image-change detector incorporating such a sensing device uses very little power because only a small number of active pixels are required to cover a visual field.

Abstract: A memory device includes a stack of circuit layers, each circuit layer having formed thereon a memory circuit configured to store data and a redundant resources circuit configured to provide redundant circuitry to correct defective circuitry on at least one memory circuit formed on at least one layer in the stack. The redundant resources circuit includes a partial bank of redundant memory cells, wherein an aggregation of the partial bank of redundant memory cells in each of the circuit layers of the stack includes at least one full bank of redundant memory cells and wherein the redundant resources circuit is configured to replace at least one defective bank of memory cells formed on any of the circuit layers in the stack with at least a portion of the partial bank of redundant memory cells formed on any of the circuit layers in the stack.

Abstract: A memory device includes a stack of circuit layers, each circuit layer having formed thereon a memory circuit configured to store data and a redundant resources circuit configured to provide redundant circuitry to correct defective circuitry on at least one memory circuit formed on at least one layer in the stack. The redundant resources circuit includes a partial bank of redundant memory cells, wherein an aggregation of the partial bank of redundant memory cells in each of the circuit layers of the stack includes at least one full bank of redundant memory cells and wherein the redundant resources circuit is configured to replace at least one defective bank of memory cells formed on any of the circuit layers in the stack with at least a portion of the partial bank of redundant memory cells formed on any of the circuit layers in the stack.