Abstract: Methods and apparatus relating to advanced graphics Power State management are described. In one embodiment, measurement logic detects information about idle transitions and active transitions of a power-well of a processor. In turn, determination logic determines performance loss and/or energy gain based at least in part on the detected information and power-on latency of the power-well of the processor. Other embodiments are also disclosed and claimed.

Abstract: Methods and apparatus relating to techniques for power management. In an example, an apparatus comprises logic, at least partially comprising hardware logic, to generate a voltage/frequency curve for at least one of a core or a sub-core in a processor and manage an operating voltage level of the at least one of a core or a sub-core using the voltage/frequency curve. Other embodiments are also disclosed and claimed.

Abstract: Embodiments of systems, apparatuses, and methods for energy efficiency and energy conservation including enabling autonomous hardware-based deep power down of devices are described. In one embodiment, a system includes a device, a static memory, and a power control unit coupled with the device and the static memory. The system further includes a deep power down logic of the power control unit to monitor a status of the device, and to transfer the device to a deep power down state when the device is idle. In the system, the device consumes less power when in the deep power down state than in the idle state.

Abstract: Embodiments described herein provide techniques enable a compute unit to continue processing operations when all dispatched threads are blocked. One embodiment provides for a graphics processor comprising a compute unit to execute multiple concurrent threads and a memory coupled with and on a same package as the compute unit. The memory can store thread state for a suspended thread and the compute unit can detect that multiple concurrent threads of the compute unit are blocked from execution. Upon detection, the compute unit can select a victim thread from the multiple concurrent threads, suspend the victim thread, store thread state of the victim thread to the memory, and select an additional thread to be executed. The compute unit can then replace the victim thread with an additional thread to be executed. The additional thread to be executed can be based on a blocking event for the additional thread.

Abstract: Embodiments described herein provide techniques enable a compute unit to continue processing operations when all dispatched threads are blocked. One embodiment provides for an apparatus comprising a thread dispatcher to dispatch a thread for execution; a compute unit having a single instruction, multiple thread architecture, the compute unit to execute multiple concurrent threads; and a memory coupled with the compute unit, the memory to store thread state for a suspended thread, wherein the compute unit is to: detect that all threads on the compute unit are blocked from execution, select a victim thread from the multiple concurrent threads, suspend the victim thread, store thread state of the victim thread to the memory, and replace the victim thread with an additional thread to be executed.

Abstract: Methods and apparatus relating to techniques for power management. In an example, an apparatus comprises logic, at least partially comprising hardware logic, to generate a voltage/frequency curve for at least one of a core or a sub-core in a processor and manage an operating voltage level of the at least one of a core or a sub-core using the voltage/frequency curve. Other embodiments are also disclosed and claimed.

Abstract: Methods and apparatus relating to advanced graphics Power State management are described. In one embodiment, measurement logic detects information about idle transitions and active transitions of a power-well of a processor. In turn, determination logic determines performance loss and/or energy gain based at least in part on the detected information and power-on latency of the power-well of the processor. Other embodiments are also disclosed and claimed.

Abstract: In one embodiment an apparatus includes a multiplicity of processor components; one or more device components communicatively coupled to one or more processor components of the multiplicity of processor components; and a controller comprising logic at least a portion of which is in hardware, the logic to schedule one or more forced idle periods interspersed with one or more active periods, a forced idle period spanning a duration during which the multiplicity of processor components and the one or more device components are simultaneously placed in respective idle states that define a forced idle power state during isolated sub-periods of the forced idle period. Other embodiments are disclosed and claimed.

Abstract: Methods and apparatus relating to techniques for determining idle power state are described. In an embodiment, power configuration logic determines a power state configuration for a portion of a processor. The power state configuration corresponds to a plurality of settings for operation of the portion of the processor during an idle period. Moreover, the power configuration logic determines the power state configuration based at least in part on one or more (e.g., runtime) workload measurements. Other embodiments are also disclosed and claimed.

Abstract: Power gating a portion of a graphics processor may be used to improve performance or to achieve a power budget. A processor granularity, such as a slice or subslice, may be gated.

Abstract: Power gating a portion of a graphics processor may be used to improve performance or to achieve a power budget. A processor granularity, such as a slice or subslice, may be gated.

Abstract: Methods and apparatus relating to advanced graphics Power State management are described. In one embodiment, measurement logic detects information about idle transitions and active transitions of a power-well of a processor. In turn, determination logic determines performance loss and/or energy gain based at least in part on the detected information and power-on latency of the power-well of the processor. Other embodiments are also disclosed and claimed.

Abstract: In one embodiment an apparatus includes a multiplicity of processor components; one or more device components communicatively coupled to one or more processor components of the multiplicity of processor components; and a controller comprising logic at least a portion of which is in hardware, the logic to schedule one or more forced idle periods interspersed with one or more active periods, a forced idle period spanning a duration during which the multiplicity of processor components and the one or more device components are simultaneously placed in respective idle states that define a forced idle power state during isolated sub-periods of the forced idle period. Other embodiments are disclosed and claimed.

Abstract: Embodiments described herein provide techniques enable a compute unit to continue processing operations when all dispatched threads are blocked. One embodiment provides for an apparatus comprising a thread dispatcher to dispatch a thread for execution; a compute unit having a single instruction, multiple thread architecture, the compute unit to execute multiple concurrent threads; and a memory coupled with the compute unit, the memory to store thread state for a suspended thread, wherein the compute unit is to: detect that all threads on the compute unit are blocked from execution, select a victim thread from the multiple concurrent threads, suspend the victim thread, store thread state of the victim thread to the memory, and replace the victim thread with an additional thread to be executed.

Abstract: A mechanism is described for facilitating multi-level scheduling of workloads in computing devices. A method of embodiments, as described herein, includes facilitating multiple levels of scheduling for processing of workloads using multiple levels of queues, where the workloads are associated with a device including a processor of a computing device.

Abstract: An apparatus to facilitate data prefetching is disclosed. The apparatus includes a memory, one or more execution units (EUs) to execute a plurality of processing threads and prefetch logic to prefetch pages of data from the memory to assist in the execution of the plurality of processing threads.

Abstract: Methods and apparatus relating to techniques for reference voltage control based on error detection are described. In an embodiment, modification to a reference voltage (to be supplied to one or more components of a processor) is based at least in part on error detection to be detected for a reference circuit. In another embodiment, modification is made to a power characteristic of a processor in response to a determination that the processor is to execute a safety critical application. The modification may include adjustment to an operating frequency and/or an operating voltage of the processor. Other embodiments are also disclosed and claimed.

Abstract: Methods and apparatus relating to techniques for power management. In an example, an apparatus comprises logic, at least partially comprising hardware logic, to generate a voltage/frequency curve for at least one of a core or a sub-core in a processor and manage an operating voltage level of the at least one of a core or a sub-core using the voltage/frequency curve. Other embodiments are also disclosed and claimed.

Abstract: Embodiments of systems, apparatuses, and methods for energy efficiency and energy conservation including enabling autonomous hardware-based deep power down of devices are described. In one embodiment, a system includes a device, a static memory, and a power control unit coupled with the device and the static memory. The system further includes a deep power down logic of the power control unit to monitor a status of the device, and to transfer the device to a deep power down state when the device is idle. In the system, the device consumes less power when in the deep power down state than in the idle state.

Abstract: One embodiment provides for a general-purpose graphics processing unit comprising a compute cluster including multiple compute units, a stall notification module to detect that one or more compute units in the compute cluster are stalled and send stall notification, and a rebalance module to receive the stall notification, the rebalance module to migrate a first workload from one or more stalled compute units in response to the stall notification.