Abstract: Systems, apparatuses, and methods for virtualizing a micro-operation cache are disclosed. A processor includes at least a micro-operation cache, a conventional cache subsystem, a decode unit, and control logic. The decode unit decodes instructions into micro-operations which are then stored in the micro-operation cache. The micro-operation cache has limited capacity for storing micro-operations. When new micro-operations are decoded from pending instructions, existing micro-operations are evicted from the micro-operation cache to make room for the new micro-operations. Rather than being discarded, micro-operations evicted from the micro-operation cache are stored in the conventional cache subsystem. This prevents the original instruction from having to be decoded again on subsequent executions.

Abstract: A method of operating a cache in a computing device includes, in response to receiving a memory access request at the cache, determining compressibility of data specified by the request, selecting in the cache a destination portion for storing the data based on the compressibility of the data and a persistent fault history of the destination portion, and storing a compressed copy of the data in a non-faulted subportion of the destination portion, wherein the persistent fault history indicates that the non-faulted subportion excludes any persistent faults.

Abstract: A computer processing device transitions among a plurality of power management states and at least one power management sub-state. From a first state, it is determined whether an entry condition for a third state is satisfied. If the entry condition for the third state is satisfied, the third state is entered. If the entry condition for the third state is not satisfied, it is determined whether an entry condition for the first sub-state is satisfied. If the entry condition for the first sub-state is determined to be satisfied, the first sub-state is entered, a first sub-state residency timer is started, and after expiry of the first sub-state residency timer, the first sub-state is exited, the first state is re-entered, and it is re-determined whether the entry condition for the third state is satisfied.

Abstract: A technique for manipulating a generic tensor is provided. The technique includes receiving a first request to perform a first operation on a generic tensor descriptor associated with the generic tensor, responsive to the first request, performing the first operation on the generic tensor descriptor, receiving a second request to perform a second operation on generic tensor raw data associated with the generic tensor, and responsive to the second request, performing the second operation on the generic tensor raw data.

Abstract: A method operates a first-in-first-out (FIFO) buffer with a first clock, and operates one of a read pointer or a write pointer of the FIFO buffer with the first clock while operating the other one of the read pointer or write pointer with a second clock. One of a serializer fed from the FIFO buffer output, or a de-serializer feeding the FIFO buffer input, is operated with the second clock. Timing pulses indicate that the pointer operating with the second clock has reached a predetermined point in its cycle. The phase of the second clock is adjusted based on a relationship between the timing pulses and an advance period of the pointer operating with the first clock. The pointer operating with the first clock is reset to achieve a desired value for the relationship. A skew created from adjusting the phase of the second clock is corrected.

Abstract: Techniques for generating a model for predicting when different hybrid prefetcher configurations should be used are disclosed. Techniques for using the model to predict when different hybrid prefetcher configurations should be used are also disclosed. The techniques for generating the model include obtaining a set of input data, and generating trees based on the training data. Each tree is associated with a different hybrid prefetcher configuration and the trees output certainty scores for the associated hybrid prefetcher configuration based on hardware feature measurements. To decide on a hybrid prefetcher configuration to use, a prefetcher traverses multiple trees to obtain certainty scores for different hybrid prefetcher configurations and identifies a hybrid prefetcher configuration to used based on a comparison of the certainty scores.

Abstract: Described herein are techniques for reducing divergence of control flow in a single-instruction-multiple-data processor. The method includes, at a point of divergent control flow, identifying control flow targets for different execution items, sorting the execution items based on the control flow targets, reorganizing the execution items based on the sorting, and executing after the point of divergent control flow, with the reorganized execution items.

Abstract: A method and apparatus for servicing a task in a computer system includes receiving the task and if the task is serviceable without waking the fabric, servicing the task by a first service stage entity. If the task is not serviceable by the first service stage entity, the task is serviced by a first processing unit without waking a second processing unit. If the task is not serviceable by the first processing unit, the task is serviced by the second processing unit.

Abstract: Virtual Reality (VR) processing devices and methods are provided for transmitting user feedback information comprising at least one of user position information and user orientation information, receiving encoded audio-video (A/V) data, which is generated based on the transmitted user feedback information, separating the A/V data into video data and audio data corresponding to a portion of a next frame of a sequence of frames of the video data to be displayed, decoding the portion of a next frame of the video data and the corresponding audio data, providing the audio data for aural presentation and controlling the portion of the next frame of the video data to be displayed in synchronization with the corresponding audio data.

Abstract: A method and system for partial wavefront merger is described. Vector processing machines employ the partial wavefront merger to merge partial wavefronts into one or more wavefronts. The system includes a partial wavefront manager and unified registers. The partial wavefront manager detects wavefronts in different single-instruction-multiple-data (“SIMD”) units which contain inactive work items and active work items (hereinafter referred to as “partial wavefronts”), moves the partial wavefronts into one or more SIMD unit(s) and merges the partial wavefronts into one or more wavefront(s). The unified register allows each active work item in the one or more merged wavefront(s) to access the previously allocated registers in the originating SIMD units. Consequently, the contents of the unified registers do not have to be copied to the SIMD unit(s) executing the one or merged wavefront(s).

Abstract: A circuit includes a repeating series of first circuits and a repeating series of second circuits placed next to the repeating series of first circuits and interacts with corresponding portions of the first circuits in the series. The repeating series of second circuits is formed in diffusion regions and diffusion wells which extend along the direction in which the second circuits repeat. The repeating series of the first and second circuits is interrupted by at least one dummy circuit region, which occupies the space of one or more instances of the first and second repeating series. The dummy circuit region also includes taps for biasing the diffusion regions and diffusion wells of the second circuits.

Abstract: A method of and device for removing a processor from a low power mode. The method includes and the device provides for performing multiple processor start-up tasks in parallel. Memory interface training between the processor and memory and restoration and initialization of the processor are performed in parallel with each other and with a serial bus controller entering serial bus training to facilitate communication between the processor and a system controller.

Abstract: Systems, apparatuses, and methods for implementing a deskewing method for a physical layer interface on a multi-chip module are disclosed. A circuit connected to a plurality of communication lanes trains each lane to synchronize a local clock of the lane with a corresponding global clock at a beginning of a timing window. Next, the circuit symbol rotates each lane by a single step responsive to determining that all of the plurality of lanes have an incorrect symbol alignment. Responsive to determining that some but not all of the plurality of lanes have a correct symbol alignment, the circuit symbol rotates lanes which have an incorrect symbol alignment by a single step. When the end of the timing window has been reached, the circuit symbol rotates lanes which have a correct symbol alignment and adjusts a phase of a corresponding global clock to compensate for missed symbol rotations.

Abstract: Systems, apparatuses, and methods for implementing a dual-purpose millimeter-wave frequency band transmitter are disclosed. A system includes a dual-purpose transmitter sending a video stream over a wireless link to a receiver. In some embodiments, the video stream is generated as part of an augmented reality (AR) or virtual reality (VR) application. The transmitter operates in a first mode to scan and map an environment of the transmitter and receiver. The transmitter generates radio frequency (RF) signals in a first frequency range while operating in the first mode. Additionally, the transmitter operates in a second mode to send video data to the receiver, and the transmitter generates RF signals in the first frequency range while operating in the second mode.

Abstract: In at least one embodiment, an integrated circuit product includes a redistribution layer, an integrated circuit die disposed above the redistribution layer, and a discrete device disposed laterally with respect to the integrated circuit die and disposed above the redistribution layer. The integrated circuit product may include encapsulant mechanically coupling the redistribution layer, the integrated circuit die, and the discrete device. The integrated circuit product may include first conductive vias through the redistribution layer and second conductive vias through the redistribution layer. The first conductive vias may be electrically coupled to the integrated circuit die and the second conductive vias being electrically coupled to the discrete device. The discrete device may include a discrete capacitor device made from a ceramic material, electrolytic materials, or electrochemical materials.

Abstract: An electronic device acquires, from program code, two or more program code loops having specified data dependencies. The electronic device places each of the program code loops into a corresponding blocking loop, each blocking loop including at least one blocking loop induction variable that is incremented by a corresponding block size and used to specify a number of iterations for at least one internal loop induction variable of the respective program code loop. The electronic device fuses the blocking loops into a fused loop by placing all of the blocking loops in the fused loop and replacing the blocking loop induction variables of the blocking loops with a fused loop induction variable that is incremented by the corresponding block size and used to specify the number of iterations for respective internal loop induction variables in the blocking loops.

Abstract: A method of managing memory access includes receiving, at an input output memory management unit, a memory access request from a device. The memory access request includes a virtual steering tag associate associated with a virtual machine. The method further includes translating the virtual steering tag to a physical steering tag directing memory access of a cache memory associated with a processor core of a plurality of processor cores. The virtual machine is implemented on the processor core. The method also includes accessing the cache memory to implement the memory access request.

Abstract: A cluster compute server stores different types of data at different storage volumes in order to reduce data duplication at the storage volumes. The storage volumes are categorized into two classes: common storage volumes and dedicated storage volumes, wherein the common storage volumes store data to be accessed and used by multiple compute nodes (or multiple virtual servers) of the cluster compute server. The dedicated storage volumes, in contrast, store data to be accessed only by a corresponding compute node (or virtual server).

Abstract: A system and method for protecting memory instructions against faults are described. The system and method include converting the slave instructions to dummy operations, modifying memory arbiter to issue up to N master and N slave global/shared memory instructions per cycle, sending master memory requests to memory system, using slave requests for error checking, entering master requests to the GM/LM FIFO, storing slave requests in a register, and comparing the entered master requests with the stored slave requests.

Abstract: Systems, apparatuses, and methods for implementing dynamic control of a multi-region fabric are disclosed. A system includes at least one or more processing units, one or more memory devices, and a communication fabric coupled to the processing unit(s) and memory device(s). The system partitions the fabric into multiple regions based on different traffic types and/or periodicities of the clients connected to the regions. For example, the system partitions the fabric into a stutter region for predictable, periodic clients and a non-stutter region for unpredictable, non-periodic clients. The system power-gates the entirety of the fabric in response to detecting a low activity condition. After power-gating the entirety of the fabric, the system periodically wakes up one or more stutter regions while keeping the other non-stutter regions in power-gated mode. Each stutter region monitors stutter client(s) for activity and processes any requests before going back into power-gated mode.