Abstract: Methods and apparatus related to management and/or support of metadata for PCMS (Phase Change Memory with Switch) devices are described. In one embodiment, a PCMS controller allows access to a PCMS device based on metadata. The metadata may be used to provide efficiency, endurance, error correction, etc. as discussed in the disclosure. Other embodiments are also disclosed and claimed.

Abstract: A system and method are described for flushing a specified region of a memory side cache (MSC) within a multi-level memory hierarchy. For example, a computer system according to one embodiment comprises: a memory subsystem comprised of a non-volatile system memory and a volatile memory side cache (MSC) for caching portions of the non-volatile system memory; and a flush engine for flushing a specified region of the MSC to the non-volatile system memory in response to a deactivation condition associated with the specified region of the MSC.

Abstract: Systems and methods for implementing transactional memory access. An example method may comprise initiating a memory access transaction; executing a transactional read operation, using a first buffer associated with a memory access tracking logic, with respect to a first memory location, and/or a transactional write operation, using a second buffer associated with the memory access tracking logic, with respect to a second memory location; executing a non-transactional read operation with respect to a third memory location, and/or a non-transactional write operation with respect to a fourth memory location; responsive to detecting, by the memory access tracking logic, access by a device other than the processor to the first memory location or the second memory location, aborting the memory access transaction; and completing, irrespectively of the state of the third memory location and the fourth memory location, the memory access transaction responsive to failing to detect a transaction aborting condition.

Abstract: A processor of an aspect includes decode logic to receive a first instruction and to determine that the first instruction is to be emulated. The processor also includes emulation mode aware post-decode instruction processor logic coupled with the decode logic. The emulation mode aware post-decode instruction processor logic is to process one or more control signals decoded from an instruction. The instruction is one of a set of one or more instructions used to emulate the first instruction. The one or more control signals are to be processed differently by the emulation mode aware post-decode instruction processor logic when in an emulation mode than when not in the emulation mode. Other apparatus are also disclosed as well as methods and systems.

Abstract: A redundant multithreading processor is presented. In one embodiment, the processor performs execution of a thread and its duplicate thread in parallel and determines, when in a redundant multithreading mode, whether or not to synchronize an operation of the thread and an operation of the duplicate thread.

Abstract: A system includes a non-volatile random access memory (NVRAM) device and controller logic that detects a bad block within the device, retires the bad block and replaces the bad block with a replacement block by assigning the address of the bad block to the replacement block.

Abstract: Embodiments of the invention describe a system main memory comprising two levels of memory that include cached subsets of system disk level storage. This main memory includes “near memory” comprising memory made of volatile memory, and “far memory” comprising volatile or nonvolatile memory storage that is larger and slower than the near memory. The far memory is presented as “main memory” to the host OS while the near memory is a cache for the far memory that is transparent to the OS, thus appearing to the OS the same as prior art main memory solutions. The management of the two-level memory may be done by a combination of logic and modules executed via the host CPU. Near memory may be coupled to the host system CPU via high bandwidth, low latency means for efficient processing. Far memory may be coupled to the CPU via low bandwidth, high latency means.

Abstract: A system and method are described for integrating a memory and storage hierarchy including a non-volatile memory tier within a computer system. In one embodiment, PCMS memory devices are used as one tier in the hierarchy, sometimes referred to as “far memory.” Higher performance memory devices such as DRAM placed in front of the far memory and are used to mask some of the performance limitations of the far memory. These higher performance memory devices are referred to as “near memory.” In one embodiment, the “near memory” is configured to operate in a plurality of different modes of operation including (but not limited to) a first mode in which the near memory operates as a memory cache for the far memory and a second mode in which the near memory is allocated a first address range of a system address space with the far memory being allocated a second address range of the system address space, wherein the first range and second range represent the entire system address space.

Abstract: Examples are disclosed for establishing a window for a queue structure maintained in a cache for a processing element for a network device. The processing element may be configured to operate in cooperation with an input/output device such as a network interface card. In some of these examples, the window may include portions of the queue structure having identifiers to active allocated buffers maintained in memory for the network device. The active allocated buffers may be configured to maintain or store data received or to be forwarded by the input/output device. For these examples, the window may be adjusted based on information gathered while the identifiers are read from or written to the portions of the queue structure.

Abstract: When transitioning from sleep mode to active mode, a processing system loads first stage resume content and second stage resume content into a volatile memory of the processing system. The first stage resume content may contain contextual data for a first program that was in use before the processing system transitioned to sleep mode. The second stage resume content may contain contextual data for another program that was in use before the processing system transitioned to sleep mode. The processing system may provide a user interface for the first program before all of the second stage resume content has been loaded into the volatile memory. Other embodiments are described and claimed.

Abstract: Embodiments of the invention describe a system main memory comprising two levels of memory that include cached subsets of system disk level storage. This main memory includes “near memory” comprising memory made of volatile memory, and “far memory” comprising volatile or nonvolatile memory storage that is larger and slower than the near memory. The far memory is presented as “main memory” to the host OS while the near memory is a cache for the far memory that is transparent to the OS, thus appearing to the OS the same as prior art main memory solutions. The management of the two-level memory may be done by a combination of logic and modules executed via the host CPU. Near memory may be coupled to the host system CPU via high bandwidth, low latency means for efficient processing. Far memory may be coupled to the CPU via low bandwidth, high latency means.

Abstract: A method and system to perform caching based at least on one or more file-level heuristics. The caching of a storage medium in a caching device is performed by a cache policy engine. The cache policy engine receives file-level information of input/output access of data of the storage medium and caches or evicts the data of the storage medium in the caching device based on the received file-level information. By utilizing information about the files and file operations associated with the disk sectors or logical block addresses of the storage medium, the cache policy engine can make a better decision on the data selection of the storage medium to be cached in or evicted from the caching device in one embodiment of the invention. Higher cache hit rates can be achieved and the performance of the system utilizing the cache policy engine is improved.

Abstract: A processor including a first execution core section clocked to perform execution operations at a first clock frequency, and a second execution core section clocked to perform execution operations at a second clock frequency which is different than the first clock frequency. The second execution core section runs faster and includes a data cache and critical ALU functions, while the first execution core section includes latency-tolerant functions such as instruction fetch and decode units and non-critical ALU functions. The processor may further include an I/O ring which may be still slower than the first execution core section. Optionally, the first execution core section may include a third execution core section whose clock rate is between that of the first and second execution core sections. Clock multipliers/dividers may be used between the various sections to derive their clocks from a single source, such as the I/O clock.

Abstract: A redundant multithreading processor is presented. In one embodiment, the processor performs execution of a thread and its duplicate thread in parallel and determines, when in a redundant multithreading mode, whether or not to synchronize an operation of the thread and an operation of the duplicate thread.

Abstract: A method and system to perform caching based at least on one or more file-level heuristics. The caching of a storage medium in a caching device is performed by a cache policy engine. The cache policy engine receives file-level information of input/output access of data of the storage medium and caches or evicts the data of the storage medium in the caching device based on the received file-level information. By utilizing information about the files and file operations associated with the disk sectors or logical block addresses of the storage medium, the cache policy engine can make a better decision on the data selection of the storage medium to be cached in or evicted from the caching device in one embodiment of the invention. Higher cache hit rates can be achieved and the performance of the system utilizing the cache policy engine is improved.

Abstract: In one embodiment, the present invention includes a method for providing a cache block in an exclusive state to a first cache and providing the same cache block in the exclusive state to a second cache when cores accessing the two caches are executing redundant threads. Other embodiments are described and claimed.

Abstract: In one embodiment, the present invention includes a method for controlling redundant execution such that if an exceptional event occurs, the redundant execution is stopped, non-redundant execution is performed in one of the threads until the exceptional event has been-resolved, after which a state of the threads is synchronized, and redundant execution is continued. Other embodiments are described and claimed.

Abstract: When transitioning from sleep mode to active mode, a processing system loads first stage resume content and second stage resume content into a volatile memory of the processing system. The first stage resume content may contain contextual data for a first program that was in use before the processing system transitioned to sleep mode. The second stage resume content may contain contextual data for another program that was in use before the processing system transitioned to sleep mode. The processing system may provide a user interface for the first program before all of the second stage resume content has been loaded into the volatile memory. Other embodiments are described and claimed.

Abstract: When transitioning from sleep mode to active mode, a processing system loads first stage resume content and second stage resume content into a volatile memory of the processing system. The first stage resume content may contain contextual data for a first program that was in use before the processing system transitioned to sleep mode. The second stage resume content may contain contextual data for another program that was in use before the processing system transitioned to sleep mode. The processing system may provide a user interface for the first program before all of the second stage resume content has been loaded into the volatile memory. Other embodiments are described and claimed.

Abstract: A processor including a first execution core section clocked to perform execution operations at a first clock frequency, and a second execution core section clocked to perform execution operations at a second clock frequency which is different than the first clock frequency. The second execution core section runs faster and includes a data cache and critical ALU functions, while the first execution core section includes latency-tolerant functions such as instruction fetch and decode units and non-critical ALU functions. The processor may further include an I/O ring which may be still slower than the first execution core section. Optionally, the first execution core section may include a third execution core section whose clock rate is between that of the first and second execution core sections. Clock multipliers/dividers may be used between the various sections to derive their clocks from a single source, such as the I/O clock.