Abstract: In an embodiment, a processor includes at least one core, a first domain to operate at a first clock frequency, and a second domain to operate at a second clock frequency that is lower than the first clock frequency. The processor also includes phase locked loop (PLL) logic to generate a first signal having a first frequency corresponding to the first clock frequency and to provide the first signal to the first domain. The processor also includes a first clock to produce a first squash signal that is determined based at least in part on the second clock frequency, and also first logic to generate a second signal having a second frequency corresponding to the second clock frequency by gating the first signal with the first squash signal and to provide the second signal to the second domain. Other embodiments are described and claimed.

Abstract: In one embodiment, a processor includes cores to execute instructions. At least some of the cores include a telemetry data control logic to send a first telemetry data packet to a power controller according to a stagger schedule to prevent data collisions, and a global alignment counter to count a stagger alignment period. Other embodiments are described and claimed.

Abstract: A method and apparatus for flushing and restoring core memory content to and from, respectively, external memory are described. In one embodiment, the apparatus is an integrated circuit comprising a plurality of processor cores, the plurality of process cores including one core having a first memory operable to store data of the one core, the one core to store data from the first memory to a second memory located externally to the processor in response to receipt of a first indication that the one core is to transition from a first low power idle state to a second low power idle state and receipt of a second indication generated externally from the one core indicating that the one core is to store the data from the first memory to the second memory, locations in the second memory at which the data is stored being accessible by the one core and inaccessible by other processor cores in the IC; and a power management controller coupled to the plurality of cores and located outside the plurality of cores.

Abstract: A processor includes an execution engine and a power controller. The execution engine includes circuitry to determine an increased current for the execution engine. The power controller includes circuitry to determine a new dynamic capacitance for the execution engine based upon the increased current, calculate a new power consumption for the execution engine based upon the new dynamic capacitance, utilize the new power consumption to evaluate a new aggregate demand for power of a plurality of engines including the execution engine, and evaluate power provisioning of the processor based upon the new power consumption for the execution engine.

Abstract: In one embodiment, a processor includes: a plurality of cores, at least some having an advanced programmable interrupt controller (APIC) identifier associated therewith; a plurality of power management agents associated with the plurality of cores; and a power controller to receive an indication of an interrupt and a first APIC identifier and send a wake signal and the first APIC identifier to the plurality of power management agents to determine which of the plurality of cores is associated with the first APIC identifier. Other embodiments are described and claimed.

Abstract: Apparatuses, methods and storage medium associated with current control for a multicore processor are disclosed herein. In embodiments, a multicore processor may include a plurality of analog current comparators, each analog current comparator to measure current utilization by a corresponding one of the cores of the multicore processor. The multicore processor may include one or more processors, devices, and/or circuitry to cause the cores to individually throttle based on measurements from the corresponding analog current comparators. In some embodiments, a memory device of the multicore processor may store instructions executable to operate a plurality power management agents to determine whether to send throttle requests based on a plurality of histories of the current measurements of the cores, respectively.

Abstract: In an embodiment, a processor includes one or more cores including a first core operable at an operating voltage between a minimum operating voltage and a maximum operating voltage. The processor also includes a power control unit including first logic to enable coupling of ancillary logic to the first core responsive to the operating voltage being less than or equal to a threshold voltage, and to disable the coupling of the ancillary logic to the first core responsive to the operating voltage being greater than the threshold voltage. Other embodiments are described and claimed.

Abstract: In an embodiment, a processor includes multiple cores and a power controller. The power controller may include a hardware duty cycle (HDC) logic to cause at least one logical processor of one of the cores to enter into a forced idle state even though the logical processor has a workload to execute. In addition, the HDC logic may cause the logical processor to exit the forced idle state prior to an end of an idle period if at least one other logical processor is prevented from entry into the forced idle state. Other embodiments are described and claimed.

Abstract: Described is a processor with a data storage structure operative to store data and a first error correction code that corresponds to the data. The processor further includes circuitry to compare the first and second error correction codes to obtain a comparison result. There are no errors in the data when the comparison result is equal to zero and there is at least one error in the data when the comparison result is not equal to zero. The circuitry corrects a single bit error of the data when the comparison result matches one of the unique combination of bit values of one of the plurality of bit groups in the generator matrix and corrects two consecutive data bits of the data when the comparison result corresponds to a predefined number of values as a result of an exclusive-or (XOR) operation performed on two consecutive bit groups of the generator matrix.

Abstract: In one embodiment, a processor includes a core to execute instructions and a core perimeter logic coupled to the core. The core perimeter logic may include a fabric interface logic coupled to the core. In turn, the fabric interface logic may include a first storage to store state information of the core when the core is in a low power state, and enable an inter-die interconnect coupled between the core and an uncore to be maintained in an active state during entry of the core into a low power state. Other embodiments are described and claimed.

Abstract: In one embodiment, a processor includes cores to execute instructions. At least some of the cores include a telemetry data control logic to send a first telemetry data packet to a power controller according to a stagger schedule to prevent data collisions, and a global alignment counter to count a stagger alignment period. Other embodiments are described and claimed.

Abstract: A method and apparatus for performing current control for an integrated circuit are described. In one embodiment the apparatus comprises core logic coupled to receive a first current; a clock generator to generate a first clock signal; and a closed loop current controller coupled to the clock generator and coupled to provide a second clock signal to the core logic based on the first clock signal, the current controller to control an amount of the first current received by the core logic by changing the first clock signal to generate the second clock signal.

Abstract: A method for determining an inclusion policy includes determining a ratio of a capacity of a large cache to a capacity of a core cache in a cache subsystem of a processor and selecting an inclusive policy as the inclusion policy for the cache subsystem in response to the cache ratio exceeding an inclusion threshold. The method may further include selecting a non-inclusive policy in response to the cache ratio not exceeding the inclusion threshold and, responsive to a cache transaction resulting in a cache miss, performing an inclusion operation that invokes the inclusion policy.

Abstract: Methods and apparatus relating to techniques for processor core energy management are described. In an embodiment, energy management logic causes a modification to energy consumption by an electrical load (such as a processor core) based at least in part on comparison of an electrical current value and an operating current threshold value. The electrical current value is detected at an electrical current sensor coupled to the electrical load. Other embodiments are also disclosed and claimed.

Abstract: Hybrid threading in a processor is described. An integrated circuit that implements hybrid threading includes a power control unit (PCU), a first functional hardware unit coupled to the PCU, and a second functional hardware unit coupled to the PCU. The first functional hardware unit and the second functional hardware unit are heterogeneous functional hardware units. The PCU is configured to monitor at least one power attribute of the first and second functional hardware units. The PCU is further configured to calculate an aggregate power value based on the monitored at least one power attribute. Upon determining that the aggregate power value is below a power threshold, the PCU is also configured to calculate a first frequency for the first functional hardware unit and a second frequency for the second functional hardware unit that results in an updated aggregate power value that is closer to the power threshold.

Abstract: Techniques for enabling a rapid clock frequency transition are described. An example of a computing device includes a Central Processing Unit (CPU) that includes a core and noncore components. The computing device also includes a dual mode FIFO that processes data transactions between the core and noncore components. The computing device also includes a frequency control unit that can instruct the core to transition to a new clock frequency. During the transition to the new clock frequency, the dual mode FIFO continues to process data transactions between the core and noncore components.

Abstract: Techniques for enabling a rapid clock frequency transition are described. An example of a computing device includes a Central Processing Unit (CPU) that includes a core and noncore components. The computing device also includes a dual mode FIFO that processes data transactions between the core and noncore components. The computing device also includes a frequency control unit that can instruct the core to transition to a new clock frequency. During the transition to the new clock frequency, the dual mode FIFO continues to process data transactions between the core and noncore components.

Abstract: In an embodiment, a processor includes a plurality of cores including a first core. The first core includes a first plurality of accumulator logics, each accumulator logic of the first plurality of accumulator logics to store corresponding first core telemetry data. The processor also includes a power management unit (PMU) to request telemetry data from the first core and in response to receive the first core telemetry data stored in at least one accumulator logic of the first plurality of accumulator logics. Other embodiments are described and claimed.

Abstract: A method and apparatus for performing current control for an integrated circuit are described. In one embodiment the apparatus comprises core logic coupled to receive a first current; a clock generator to generate a first clock signal; and a closed loop current controller coupled to the clock generator and coupled to provide a second clock signal to the core logic based on the first clock signal, the current controller to control an amount of the first current received by the core logic by changing the first clock signal to generate the second clock signal.

Abstract: Described is a processor with a data storage structure operative to store data and a first error correction code that corresponds to the data. The processor further includes circuitry to compare the first and second error correction codes to obtain a comparison result. There are no errors in the data when the comparison result is equal to zero and there is at least one error in the data when the comparison result is not equal to zero. The circuitry corrects a single bit error of the data when the comparison result matches one of the unique combination of bit values of one of the plurality of bit groups in the generator matrix and corrects two consecutive data bits of the data when the comparison result corresponds to a predefined number of values as a result of an exclusive-or (XOR) operation performed on two consecutive bit groups of the generator matrix.