Abstract: A method for adjusting a frequency of a processor is disclosed herein. In one embodiment, the method includes determining a total current and a temperature of the multi-core processor and estimating a leakage current for the multi-core processor. The method also includes calculating a switching current by subtracting the leakage current from the total current. The method also includes calculating an effective switching capacitance based at least in part on the switching current. The method also includes calculating a workload activity factor by dividing the effective switching capacitance by a predetermined effective switching capacitance stored in vital product data, and enforcing a turbo frequency limit of the multi-core processor based on the workload activity factor.

Abstract: A method includes monitoring power usage for a storage system that includes a set storage units at a first level of storage granularity and a set of storage sub-units at a second level of storage granularity, wherein the second level of storage granularity is finer than the first level of storage granularity. The method further includes assigning a non-uniform power budget to the set of storage units and adjusting a power budget for the storage sub-units according to the non-uniform power budget assigned to the storage units. A corresponding computer program product and computer system are also disclosed herein.

Abstract: A method, system, and computer program product for controlling power supplied to a processor is disclosed. A voltage regulator is set to a first voltage regulator set point, wherein the first voltage regulator set point provides a first load line for operation of the processor. A change in an operation of the processor from a first operating condition along the first load line to a second operating condition along the first load line is determined. The voltage regulator is the set to a second voltage regulator set point and the processor is operated at a third operating condition on a second load line corresponding to the second voltage regulator set point.

Abstract: A method includes monitoring power usage for a storage system that includes a set storage units at a first level of storage granularity and a set of storage sub-units at a second level of storage granularity, wherein the second level of storage granularity is finer than the first level of storage granularity. The method further includes assigning a non-uniform power budget to the set of storage units and adjusting a power budget for the storage sub-units according to the non-uniform power budget assigned to the storage units. A corresponding computer program product and computer system are also disclosed herein.

Abstract: Adaptive power capping in a chip that includes a plurality of cores in a processing system is provided. An active power demand for the chip is dynamically determined based on observed events of the cores. An average temperature of the chip is computed using one or more on-chip thermal sensors in the cores to estimate leakage power of the chip. A power capping threshold that incorporates the estimate of leakage power is determined based on the average temperature of the chip. Power capping is performed by throttling the cores based on determining that the active power demand for the chip exceeds the power capping threshold.

Abstract: A method, system, and computer program product for controlling power supplied to a processor is disclosed. A voltage regulator is set to a first voltage regulator set point, wherein the first voltage regulator set point provides a first load line for operation of the processor. A change in an operation of the processor from a first operating condition along the first load line to a second operating condition along the first load line is determined. The voltage regulator is the set to a second voltage regulator set point and the processor is operated at a third operating condition on a second load line corresponding to the second voltage regulator set point.

Abstract: A method includes monitoring power usage for a storage system that includes a set storage units at a first level of storage granularity and a set of storage sub-units at a second level of storage granularity, wherein the second level of storage granularity is finer than the first level of storage granularity. The method further includes assigning a non-uniform power budget to the set of storage units and adjusting a power budget for the storage sub-units according to the non-uniform power budget assigned to the storage units. A corresponding computer program product and computer system are also disclosed herein.

Abstract: A method includes monitoring power usage for a storage system that includes a set storage units at a first level of storage granularity and a set of storage sub-units at a second level of storage granularity, wherein the second level of storage granularity is finer than the first level of storage granularity. The method further includes assigning a non-uniform power budget to the set of storage units and adjusting a power budget for the storage sub-units according to the non-uniform power budget assigned to the storage units. A corresponding computer program product and computer system are also disclosed herein.

Abstract: A method includes monitoring power usage for a storage system that includes a set storage units at a first level of storage granularity and a set of storage sub-units at a second level of storage granularity, wherein the second level of storage granularity is finer than the first level of storage granularity. The method further includes assigning a non-uniform power budget to the set of storage units and adjusting a power budget for the storage sub-units according to the non-uniform power budget assigned to the storage units. A corresponding computer program product and computer system are also disclosed herein.

Abstract: A system for adjusting a frequency of a processor is disclosed herein. The system includes a processor and a memory. The memory stores program code, which, when executed on the processor, performs an operation for adjusting a frequency of a processor. The operation includes inhibiting one or more processor cores from exiting an idle state. The operation further includes determining a number of processor cores requesting exit from the idle state and a number of non-idle processor cores. The operation also includes selecting a maximum frequency for the inhibited and non-idle processor cores based on the number of inhibited processor cores requesting exit from the idle state and the number of non-idle processor cores. The operation includes setting the maximum frequency for both the inhibited and the non-idle processor cores, and then uninhibiting the processor cores requesting exit from the idle state.

Abstract: A system for adjusting a frequency of a processor is disclosed herein. The system includes a processor and a memory. The memory stores program code, which, when executed on the processor, performs an operation for adjusting a frequency of a processor. The operation includes inhibiting one or more processor cores from exiting an idle state. The operation further includes determining a number of processor cores requesting exit from the idle state and a number of non-idle processor cores. The operation also includes selecting a maximum frequency for the inhibited and non-idle processor cores based on the number of inhibited processor cores requesting exit from the idle state and the number of non-idle processor cores. The operation includes setting the maximum frequency for both the inhibited and the non-idle processor cores, and then uninhibiting the processor cores requesting exit from the idle state.

Abstract: A method for adjusting a frequency of a processor is disclosed herein. In one embodiment, the method includes determining a total current and a temperature of the multi-core processor and estimating a leakage current for the multi-core processor. The method also includes calculating a switching current by subtracting the leakage current from the total current. The method also includes calculating an effective switching capacitance based at least in part on the switching current. The method also includes calculating a workload activity factor by dividing the effective switching capacitance by a predetermined effective switching capacitance stored in vital product data, and enforcing a turbo frequency limit of the multi-core processor based on the workload activity factor.

Abstract: A system for adjusting a frequency of a processor is disclosed herein. The system includes a processor and a memory, where the memory includes a program configured to adjust a frequency of a multi-core processor. The operations include determining a total current and a temperature of the multi-core processor and estimating a leakage current for the multi-core processor. The operations also include calculating a switching current by subtracting the leakage current from the total current and calculating an effective switching capacitance based at least in part on the switching current. The operations also include calculating a workload activity factor by dividing the effective switching capacitance by a predetermined effective switching capacitance stored in vital product data, and enforcing a turbo frequency limit of the multi-core processor based on the workload activity factor.

Abstract: A method for adjusting a frequency of a processor is disclosed herein. In one embodiment, the method includes inhibiting one or more processor cores from exiting an idle state. The method further includes determining a number of processor cores requesting exit from the idle state and a number of non-idle processor cores. The method also includes selecting a maximum frequency for the inhibited and non-idle processor cores based on the number of inhibited processor cores requesting exit from the idle state and the number of non-idle processor cores. The method includes setting the maximum frequency for both the inhibited and the non-idle processor cores, and then uninhibiting the processor cores requesting exit from the idle state.

Abstract: A system for post-silicon leakage characterization is configured to apply a rail voltage to a hardware component; cause the hardware component to operate at a particular frequency; cause a cooling device, coupled to the hardware component, to operate at a cooling capacity; run a workload on the hardware component after applying the rail voltage, causing the hardware component to operate at a particular frequency, and causing the cooling device to operate at a particular cooling capacity; discontinue the workload and clocks of the hardware component after a temperature of the hardware component has reached a steady high point; continuously measure temperature and leakage power of the hardware component after discontinuing the workload until the temperature of the hardware component has reached a steady low point; and adjust a power management procedure for the hardware component based on measured temperature and measured leakage power of the hardware component.

Abstract: A mechanism is provided for dynamic power and thermal capping in a flash storage system. A set of measurement values are received for the flash storage system, the set of measurement values comprising one or more of a set of current (I) measurement values, a set of voltage (V) measurement values, or a set of temperature (T) measurement values. An average current (Iavg) value from the set of current (I) measurements and, responsive to the average current (Iavg) value being greater than a predetermined maximum current (Imax) value, a determination is made as to whether a rate at which erase operations are performed for the flash storage system is greater than a predetermined minimum erase rate. Responsive to the rate at which erase operations are performed for the flash storage system being greater than the predetermined minimum erase rate, the rate at which erase operations are performed for the flash storage system are decreased by a predetermined value.

Abstract: A mechanism is provided for determining a modeled age of a set of interconnect groups in a set of cores in a set of multi-core processors. For each interconnect group in the set of interconnect groups in the set of cores on the set of multi-core processors, a determination is made of a current modeled age of the interconnect group. A determination is then made as to whether at least one current modeled age of the interconnect group for the set of interconnect groups is greater than an end-of-life value. Responsive to at least one current modeled age of the interconnect group being greater than the end-of-life value, an indication to take corrective action with the at least one associated interconnect group is sent.

Abstract: A mechanism is provided for implementing an operational parameter change within the data processing system based on an identified degradation. One or more degradations existing in the data processing system are identified based on a set of degradation values obtained from a set of degradation sensors. A determination is made as to whether one or more operational parameters need to be modified based on the one or more identified degradations. Responsive to determining that the one or more operational parameters need to be modified based on the one or more identified degradations, an input change is implemented to a one or more control devices in order that the one or more operational parameters are modified.

Abstract: A mechanism is provided for implementing an operational parameter change within the data processing system based on an identified degradation. One or more degradations existing in the data processing system are identified based on a set of degradation values obtained from a set of degradation sensors. A determination is made as to whether one or more operational parameters need to be modified based on the one or more identified degradations. Responsive to determining that the one or more operational parameters need to be modified based on the one or more identified degradations, an input change is implemented to a one or more control devices in order that the one or more operational parameters are modified.

Abstract: A method includes monitoring power usage for a storage system that includes a set storage units at a first level of storage granularity and a set of storage sub-units at a second level of storage granularity, wherein the second level of storage granularity is finer than the first level of storage granularity. The method further includes assigning a non-uniform power budget to the set of storage units and adjusting a power budget for the storage sub-units according to the non-uniform power budget assigned to the storage units. A corresponding computer program product and computer system are also disclosed herein.