Abstract: According to one embodiment, a processor includes an instruction decoder to decode instruction and a execution unit to execute instructions, the execution unit being associated with a capture logic to periodically capture operating heuristics of the execution unit, a detection logic coupled to the execution unit to evaluate the captured operating heuristics to determine whether there is a need to adjust an operating point of the execution unit, and a control logic coupled to the detection logic and the execution unit to adjust the operating point of the execution unit based on the evaluation of the operating heuristics.

Abstract: An apparatus for determining an average current through an inductor of a regulator circuit is disclosed. A counter unit may be configured to receive a control signal, which includes a plurality of pulses, from a Power Management Unit (PMU), and determine a number of pulses received during a predetermined period of time. A pulse sampler unit may determine a duration of a given pulse of the plurality of pulses. Circuitry may be configured to determine the average current through the inductor during the predetermined period of time dependent upon the number of pulses received during the predetermined period of time and the duration of the given pulse.

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: 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: 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: In one embodiment, an integrated circuit includes a power management architecture in which one or more pipelines are actively powered and clocked when data is provided for processing, but which are clock gated and in retention when there is no data to be processed. When data is provided to the pipeline, supply voltage may be actively provided to initial stages of the pipeline and the clocks may be ungated when the voltage is stable enough for operation. Subsequent stages of the pipeline may be sequentially provided power and clocks as the data progresses through the pipeline. Initial stages may be clock gated and power may be deactivated when additional data is not provided for processing. Accordingly, when the pipeline is viewed as a whole, power may be seen as rolling forward ahead of the data processing, and power may be inhibited in a similar rolling fashion.

Abstract: According to one embodiment, a processor includes an instruction decoder to decode instruction and a execution unit to execute instructions, the execution unit being associated with a capture logic to periodically capture operating heuristics of the execution unit, a detection logic coupled to the execution unit to evaluate the captured operating heuristics to determine whether there is a need to adjust an operating point of the execution unit, and a control logic coupled to the detection logic and the execution unit to adjust the operating point of the execution unit based on the evaluation of the operating heuristics.

Abstract: A processor includes a first memory interface to be coupled to a plurality of dual in-line memory module (DIMM) sockets located off-package, a second memory interface to be coupled to a non-volatile memory (NVM) socket located off-package, and a multi-level memory controller (MLMC). The MLMC is to: control the DIMMs disposed in the plurality of DIMM sockets as main memory in a one-level memory (1LM) configuration; detect a switch from a 1LM mode of operation to a two-level memory (2LM) mode of operation in response to a basic input/output system (BIOS) detection of a low-power DIMM disposed in one of the DIMM sockets and a NVM device disposed in the NVM socket in a 2LM configuration; and control the low-power DIMM as cache in the 2LM configuration in response to detection of the switch from the 1LM mode of operation to the 2LM mode of operation.

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: In accordance with embodiments disclosed herein, there is provided systems and methods for managing shared resources between multiple processing devices. The processor may include a first processing device comprising a first non-coherent hardware block (hb) including a non-coherent data and a second processing device comprising a second non-coherent hb including the non-coherent data. The processor may also include a first hb in communication with the first non-coherent hb and the second non-coherent hb to track and share the non-coherent data between the first and the second processing devices.

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 apparatus for determining an average current through an inductor of a regulator circuit is disclosed. A counter unit may be configured to receive a control signal, which includes a plurality of pulses, from a Power Management Unit (PMU), and determine a number of pulses received during a predetermined period of time. A pulse sampler unit may determine a duration of a given pulse of the plurality of pulses. Circuitry may be configured to determine the average current through the inductor during the predetermined period of time dependent upon the number of pulses received during the predetermined period of time and the duration of the given pulse.

Abstract: Technologies for one-level memory (1LM) and two-level memory (2LM) configurations in a common platform are described. A processor includes a first memory interface coupled to a first memory device that is located off-package of the processor and a second memory interface coupled to a second memory device that is located off-package of the processor. The processor also includes a multi-level memory controller (MLMC) coupled to the first memory interface and the second memory interface. The MLMC includes a first configuration and a second configuration. The first memory device is a random access memory (RAM) of a one-level memory (1LM) architecture in the first configuration. The first memory device is a first-level RAM of a two-level memory (2LM) architecture in the second configuration and the second memory device is a second-level non-volatile memory (NVM) of the 2LM architecture in the second configuration.

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: In one embodiment, a processor includes a plurality of functional units each to independently execute instructions and a clock distribution circuit having a clock signal generator to generate a clock signal. The clock distribution circuit is coupled to receive a first operating voltage from a first voltage rail and the functional units are coupled to independently receive at least one second operating voltage from one or more second voltage rails. Other embodiments are described and claimed.

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: In an embodiment, a supply voltage envelope detector circuit is configured to detect a shape of the supply voltage over time and to compare the detected shape to expected shapes that indicate voltage droop events for which corrective action may be needed. The expected shapes may be predetermined based on one or more of: the design of the integrated circuit that includes the supply voltage envelope detector circuit; attributes of the power management unit (PMU) that is to generate the supply voltage for the integrated circuit; and/or attributes of the system that includes the integrated circuit. The shape of the voltage droop may experience little variation during use, and thus may be used to detect a droop event earlier and more accurately than a threshold-based mechanism, in some embodiments.

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: In an embodiment, a processor includes a plurality of cores to independently execute instructions, at least one graphics engine to independently execute graphics instructions, and a power controller including an alignment logic to cause at least one workload to be executed on a first core to be rescheduled to a different time to enable the plurality of cores to be active during an active time window and to be in a low power state during an idle time window. 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.