Abstract: In one embodiment, a processor includes: a plurality of cores to execute instructions; at least one monitor coupled to the plurality of cores to measure at least one of power information, temperature information, or scalability information; and a control circuit coupled to the at least one monitor. Based at least in part on the at least one of the power information, the temperature information, or the scalability information, the control circuit is to notify an operating system that one or more of the plurality of cores are to transition to a forced idle state in which non-affinitized workloads are prevented from being scheduled. Other embodiments are described and claimed.

Abstract: Systems, methods, and apparatuses relating to hardware control of processor performance levels are described. In one embodiment, a processor includes a plurality of logical processing elements; and a power management circuit to change a highest non-guaranteed performance level and a highest guaranteed performance level for each of the plurality of logical processing elements, and set a notification in a status register when the highest non-guaranteed performance level is changed to a new highest non-guaranteed performance level.

Abstract: Systems, methods, and apparatuses relating to hardware control of processor performance levels are described. In one embodiment, a processor includes a plurality of logical processing elements; and a power management circuit to change a highest non-guaranteed performance level and a highest guaranteed performance level for each of the plurality of logical processing elements, and set a notification in a status register when the highest non-guaranteed performance level is changed to a new highest non-guaranteed performance level.

Abstract: In an embodiment, a processor includes multiple processing engines and a power control unit. The power control unit is to: maintain a first utilization metric for a first processing engine; detect a thread transfer from a first processing engine to a second processing engine; and generate, using the first utilization metric for the first processing engine, a second utilization metric for a second processing engine. Other embodiments are described and claimed.

Abstract: An apparatus, method and system is described herein for efficiently balancing performance and power between processing elements based on measured workloads. If a workload of a processing element indicates that it is a bottleneck, then its performance may be increased. However, if a platform or integrated circuit including the processing element is already operating at a power or thermal limit, the increase in performance is counterbalanced by a reduction or cap in another processing elements performance to maintain compliance with the power or thermal limit. As a result, bottlenecks are identified and alleviated by balancing power allocation, even when multiple processing elements are operating at a power or thermal limit.

Abstract: Systems, methods, and apparatuses relating to hardware control of processor performance levels are described. In one embodiment, a processor includes a plurality of logical processing elements; and a power management circuit to change a highest non-guaranteed performance level and a highest guaranteed performance level for each of the plurality of logical processing elements, and set a notification in a status register when the highest non-guaranteed performance level is changed to a new highest non-guaranteed performance level.

Abstract: Dynamic interrupt steering remaps the handling of interrupts away from processor units executing important workloads. During the operation of a computing system, important workload utilization rates for processor units handling interrupts are determined and those processor units with utilization rates about a threshold value are made unavailable for handling interrupts. Interrupts are dynamically remapped to processor units available for interrupt handling based on processor unit idle state and, in the case of heterogeneous computing systems, processor unit type. Processor units are capable of idle state demotion by, in response to receiving a request to enter into a deep idle state, determining if its interrupt handling rate is greater than a threshold value, and if so, placing itself into a shallower idle state than requested. This avoids the computing system from incurring the expensive idle state exit latency and power costs associated with exiting from a deep idle state.

Abstract: An apparatus, method and system is described herein for efficiently balancing performance and power between processing elements based on measured workloads. If a workload of a processing element indicates that it is a bottleneck, then its performance may be increased. However, if a platform or integrated circuit including the processing element is already operating at a power or thermal limit, the increase in performance is counterbalanced by a reduction or cap in another processing elements performance to maintain compliance with the power or thermal limit. As a result, bottlenecks are identified and alleviated by balancing power allocation, even when multiple processing elements are operating at a power or thermal limit.

Abstract: In an embodiment, a processor includes multiple processing engines and a power control unit. The power control unit is to: maintain a first utilization metric for a first processing engine; detect a thread transfer from a first processing engine to a second processing engine; and generate, using the first utilization metric for the first processing engine, a second utilization metric for a second processing engine. Other embodiments are described and claimed.

Abstract: In an embodiment, a processor includes a plurality of processing engines (PEs) to execute threads, and a guide unit. The guide unit is to: monitor execution characteristics of the plurality of PEs and the threads; generate a plurality of PE rankings, each PE ranking including the plurality of PEs in a particular order; and store the plurality of PE rankings in a memory to be provided to a scheduler, the scheduler to schedule the threads on the plurality of PEs using the plurality of PE rankings. Other embodiments are described and claimed.

Abstract: In an embodiment, a processor includes a plurality of processing engines (PEs) to execute threads, and a guide unit. The guide unit is to: monitor execution characteristics of the plurality of PEs and the threads; generate a plurality of PE rankings, each PE ranking including the plurality of PEs in a particular order; and store the plurality of PE rankings in a memory to be provided to a scheduler, the scheduler to schedule the threads on the plurality of PEs using the plurality of PE rankings. Other embodiments are described and claimed.

Abstract: Technologies are provided in embodiments to dynamically bias performance of logical processors in a core of a processor. One embodiment includes identifying a first logical processor associated with a first thread of an application and a second logical processor associated with a second thread, obtaining first and second thread preference indicators associated with the first and second threads, respectively, computing a first relative performance bias value for the first logical processor based, at least in part, on a relativeness of the first and second thread preference indicators, and adjusting a performance bias of the first logical processor based on the first relative performance bias value. Embodiments can further include increasing the performance bias of the first logical processor based, at least in part, on the first relative performance bias value indicating a first performance preference that is higher than a second performance preference.

Abstract: An apparatus, method and system is described herein for efficiently balancing performance and power between processing elements based on measured workloads. If a workload of a processing element indicates that it is a bottleneck, then its performance may be increased. However, if a platform or integrated circuit including the processing element is already operating at a power or thermal limit, the increase in performance is counterbalanced by a reduction or cap in another processing elements performance to maintain compliance with the power or thermal limit. As a result, bottlenecks are identified and alleviated by balancing power allocation, even when multiple processing elements are operating at a power or thermal limit.

Abstract: Apparatuses, methods and storage medium associated with scheduling of threads and/or virtual machines, are disclosed herein. In embodiments, an apparatus is provided with a scheduler of an operating system and/or a virtual machine monitor. The scheduler is to retrieve or receive capabilities of the cores of one or more multi-core processors of the apparatus with diverse capabilities, and schedule a plurality of threads for execution on selected one or ones of the cores, based at least in part on the capabilities of the cores and characteristics of the plurality of threads. The virtual machine monitor is to retrieve or receive capabilities of the cores, and schedule a plurality of virtual machines for execution on selected one or ones of the cores, based at least in part on the capabilities of the cores and respective priorities of the virtual machines. Other embodiments may be described and/or claimed.

Abstract: An apparatus, method and system is described herein for efficiently balancing performance and power between processing elements based on measured workloads. If a workload of a processing element indicates that it is a bottleneck, then its performance may be increased. However, if a platform or integrated circuit including the processing element is already operating at a power or thermal limit, the increase in performance is counterbalanced by a reduction or cap in another processing elements performance to maintain compliance with the power or thermal limit. As a result, bottlenecks are identified and alleviated by balancing power allocation, even when multiple processing elements are operating at a power or thermal limit.

Abstract: In an embodiment, a processor includes multiple processing engines and a power control unit. The power control unit is to: maintain a first utilization metric for a first processing engine; detect a thread transfer from a first processing engine to a second processing engine; and generate, using the first utilization metric for the first processing engine, a second utilization metric for a second processing engine. Other embodiments are described and claimed.

Abstract: In an embodiment, a processor includes a plurality of processing engines (PEs) to execute threads, and a guide unit. The guide unit is to: monitor execution characteristics of the plurality of PEs and the threads; generate a plurality of PE rankings, each PE ranking including the plurality of PEs in a particular order; and store the plurality of PE rankings in a memory to be provided to a scheduler, the scheduler to schedule the threads on the plurality of PEs using the plurality of PE rankings. Other embodiments are described and claimed.

Abstract: Technologies are provided in embodiments to dynamically bias performance of logical processors in a core of a processor. One embodiment includes identifying a first logical processor associated with a first thread of an application and a second logical processor associated with a second thread, obtaining first and second thread preference indicators associated with the first and second threads, respectively, computing a first relative performance bias value for the first logical processor based, at least in part, on a relativeness of the first and second thread preference indicators, and adjusting a performance bias of the first logical processor based on the first relative performance bias value. Embodiments can further include increasing the performance bias of the first logical processor based, at least in part, on the first relative performance bias value indicating a first performance preference that is higher than a second performance preference.

Abstract: A processor of an aspect includes at least one lower processing capability and lower power consumption physical compute element and at least one higher processing capability and higher power consumption physical compute element. Migration performance benefit evaluation logic is to evaluate a performance benefit of a migration of a workload from the at least one lower processing capability compute element to the at least one higher processing capability compute element, and to determine whether or not to allow the migration based on the evaluated performance benefit. Available energy and thermal budget evaluation logic is to evaluate available energy and thermal budgets and to determine to allow the migration if the migration fits within the available energy and thermal budgets. Workload migration logic is to perform the migration when allowed by both the migration performance benefit evaluation logic and the available energy and thermal budget evaluation logic.

Abstract: Embodiments of processors, methods, and systems for dynamic offlining and onlining of processor cores are described. In an embodiment, a processor includes a plurality of cores, a core status storage location, and a core tracker. Core status information for at least one of the plurality of cores is the be stored in the core status storage location. The core status information is to include a core state to be used by a software scheduler. The core state is to be one of a plurality of core state values including an online value, a requesting-to-go-offline value, and an offline value. The core tracker is to track usage of the at least one core and to change the core state from the online value to the requesting-to-go-offline value in response to determining that usage has reached a predetermined threshold.