Abstract: A processor of an aspect includes a first heterogeneous physical compute element having a first set of supported instructions and architectural features, and a second heterogeneous physical compute element having a second set of supported instructions and architectural features. The second set of supported instructions and architectural features is different than the first set of supported instructions and architectural features. The processor also includes a workload and architectural state migration module coupled with the first and second heterogeneous physical compute elements. The workload and state migration module is operable to migrate a workload and associated architectural state from the first heterogeneous physical compute element to the second heterogeneous physical compute element in response to an attempt by the workload to perform at least one of an unsupported instruction and an unsupported architectural feature on the first heterogeneous physical compute element.

Abstract: In one embodiment, a processor includes a plurality of domains each to operate at an independently controllable voltage and frequency, a plurality of linear regulators each to receive a first voltage from an off-chip source and controllable to provide a regulated voltage to at least one of the plurality of domains, and a plurality of selectors each coupled to one of the domains, where each selector is configured to provide a regulated voltage from one of the linear regulators or a bypass voltage to a corresponding domain. Other embodiments are described and claimed.

Abstract: In one embodiment, the present invention includes a processor having multiple domains including at least a core domain and a non-core domain that is transparent to an operating system (OS). The non-core domain can be controlled by a driver. In turn, the processor further includes a memory interconnect to interconnect the core domain and the non-core domain to a memory coupled to the processor. Still further, a power controller, which may be within the processor, can control a frequency of the memory interconnect based on memory boundedness of a workload being executed on the non-core domain. Other embodiments are described and claimed.

Abstract: Embodiments of systems, apparatuses, and methods for energy efficiency and energy conservation including enhanced temperature based voltage control are described. In one embodiment, an apparatus includes a processor and a controller coupled with the processor. In one embodiment, the controller receives a temperature measurement corresponding to a current temperature of the processor. In one embodiment, the controller further determines an adjustment to a voltage being applied to the processor based at least in part on the temperature measurement and a plurality of internal limits of the processor, wherein the determined adjustment to the voltage is based on an inverse temperature dependence relationship between at least one of an operating frequency and a voltage of the processor, and temperature. In one embodiment, the controller provides the determined adjustment to the voltage to a voltage regulator interface.

Abstract: A heterogeneous processor architecture and a method of booting a heterogeneous processor is described. A processor according to one embodiment comprises: a set of large physical processor cores; a set of small physical processor cores having relatively lower performance processing capabilities and relatively lower power usage relative to the large physical processor cores; and a package unit, to enable a bootstrap processor. The bootstrap processor initializes the homogeneous physical processor cores, while the heterogeneous processor presents the appearance of a homogeneous processor to a system firmware interface.

Abstract: Remapping technologies for execution context swap between heterogeneous functional hardware units are described. A computing system includes multiple registers configured to store remote contexts of functional units. A mapping table maps the remote context to the functional units. An execution unit is configured to execute a remapping tool that intercepts an operation to access a remote context of a first functional unit of the plurality of functional units that is taken offline. The remapping tool determines that the first functional unit is remapped to a second functional unit using the mapping table. The operation is performed to access the remote context that is remapped to the second functional unit. The first functional unit and the second functional unit may be heterogeneous functional units.

Abstract: In an embodiment, a processor includes a core domain with a plurality of cores and a power controller having a first logic to receive a first request to increase an operating voltage of a first core of the core domain to a second voltage, to instruct a voltage regulator to increase the operating voltage to an interim voltage, and to thereafter instruct the voltage regulator to increase the operating voltage to the second voltage. Other embodiments are described and claimed.

Abstract: In one embodiment, the present invention includes a processor having multiple domains including at least a core domain and a non-core domain that is transparent to an operating system (OS). The non-core domain can be controlled by a driver. In turn, the processor further includes a memory interconnect to interconnect the core domain and the non-core domain to a memory coupled to the processor. Still further, a power controller, which may be within the processor, can control a frequency of the memory interconnect based on memory boundedness of a workload being executed on the non-core domain. Other embodiments are described and claimed.

Abstract: Embodiments of the invention relate to improving exit latency from computing device processor core deep power down. Processor state data may be maintained during deep power down mode by providing a secondary uninterrupted voltage supply to always on keeper circuits that reside within critical state registers of the processor. When these registers receive a control signal indicating that the processor power state is going to be reduced from an active processor power state to a zero processor power state, they write critical state data from the critical state register latches to the keeper circuits that are supplied with the uninterrupted power. Then, when a register receives a control signal indicating that a processor power state of the processor is going to be increased back to an active processor power state, the critical state data stored in the keeper circuits is written back to the critical state register latches.

Abstract: A processor includes multiple physical cores that support multiple logical cores of different core types, where the core types include a big core type and a small core type. A multi-threaded application includes multiple software threads are concurrently executed by a first subset of logical cores in a first time slot. Based on data gathered from monitoring the execution in the first time slot, the processor selects a second subset of logical cores for concurrent execution of the software threads in a second time slot. Each logical core in the second subset has one of the core types that matches the characteristics of one of the software threads.

Abstract: A heterogeneous processor architecture is described.

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: A heterogeneous processor architecture is described. For example, a processor according to one embodiment of the invention comprises: a set of large physical processor cores; a set of small physical processor cores having relatively lower performance processing capabilities and relatively lower power usage relative to the large physical processor cores; virtual-to-physical (V-P) mapping logic to expose the set of large physical processor cores to software through a corresponding set of virtual cores and to hide the set of small physical processor core from the software.

Abstract: According to one embodiment, a processor includes a plurality of processor cores for executing a plurality of threads, a shared storage communicatively coupled to the plurality of processor cores, a power control unit (PCU) communicatively coupled to the plurality of processors to determine, without any software (SW) intervention, if a thread being performed by a first processor core should be migrated to a second processor core, and a migration unit, in response to receiving an instruction from the PCU to migrate the thread, to store at least a portion of architectural state of the first processor core in the shared storage and to migrate the thread to the second processor core, without any SW intervention, such that the second processor core can continue executing the thread based on the architectural state from the shared storage without knowledge of the SW.

Abstract: Embodiments described herein vary an amount of cache available for use by a processor, and an amount of power supplied to the cache and to the processor, based on the amount of cache actually being used by the processor to process data. For example, a power control unit (PCU) may monitor a last level cache (LLC) to identify if the size or amount of the cache being used by a processor to process data and to determine heuristics based on that amount. Based on the monitored amount of cache being used and the heuristics, the PCU causes a corresponding decrease or increase in an amount of the cache available for use by the processor, and a corresponding decrease or increase in an amount of power supplied to the cache and to the processor.

Abstract: Power gating control architectures. A memory device having at least a memory array and input/output (I/O) lines terminated on the memory device with termination circuitry coupled to receive a termination supply voltage (Vtt) with power gating circuitry to selectively gate the termination supply voltage in response to a power gating control signal (VttControl) is coupled with a processing core coupled with the memory device, the processing core to selectively assert and deassert the VttControl signal.

Abstract: A method and apparatus for dynamic power limit sharing among the modules in the platform. In one embodiment of the invention, the platform comprises a processor and memory modules. By expanding the power domain to include the processor and the memory modules, dynamic sharing of the power budget of the platform between the processor and the memory modules is enabled. For low-bandwidth workloads, the dynamic sharing of the power budget offers significant opportunity for the processor to increase its frequency by using the headroom in the memory power and vice versa. This enables higher peak performance for the same total platform power budget in one embodiment of the invention.

Abstract: I/O logic can be separated into critical and non-critical portions, with the non-critical portions being powered down during processor idle. The I/O logic is separated into gate logic and ungated logic, where the ungated logic continues to be powered during a processor deep sleep state, and the gated logic is powered off during the deep sleep state. A power control unit can trigger the shutting down of the I/O logic.

Abstract: In one embodiment, the present invention includes a processor having multiple domains including at least a core domain and a non-core domain that is transparent to an operating system (OS). The non-core domain can be controlled by a driver. In turn, the processor further includes a memory interconnect to interconnect the core domain and the non-core domain to a memory coupled to the processor. Still further, a power controller, which may be within the processor, can control a frequency of the memory interconnect based on memory boundedness of a workload being executed on the non-core domain. Other embodiments are described and claimed.

Abstract: An electronic device comprises a central processing unit, a graphics processing unit, and a power control unit comprising logic to develop a predictive model of power states for a central processing unit in the electronic device, and use the predictive model to synchronize activity of a graphics processing unit in the electronic device with periods of activity in the central processing unit. Other embodiments may be described.