Abstract: In one embodiment an apparatus includes a multiplicity of processor components; one or more device components communicatively coupled to one or more processor components of the multiplicity of processor components; and a controller comprising logic at least a portion of which is in hardware, the logic to schedule one or more forced idle periods interspersed with one or more active periods, a forced idle period spanning a duration during which the multiplicity of processor components and the one or more device components are simultaneously placed in respective idle states that define a forced idle power state during isolated sub-periods of the forced idle period. Other embodiments are disclosed and claimed.

Abstract: In an embodiment, a processor includes a plurality of cores and power management logic. The power management logic may be to, in response to a first break event during a reduced power state in the processor, set an exit timer based on a platform latency tolerance, block a first plurality of break events from interrupting the reduced power state, and in response to a expiration of the exit timer, terminate the reduced power state. Other embodiments are described and claimed.

Abstract: Methods and apparatus relating to generic host-based controller latency are described. In one embodiment, latency information, corresponding to one or more devices, is detected from a host controller that controls access to the one or more devices. Detection of the latency information is performed in response to one or more transactions that are initiated by the host controller. Other embodiments are also claimed and disclosed.

Abstract: With embodiments of the invention, a more robust solution is provided using a storage driver that may already be used for the platforms operating system. This is efficient because the storage driver typically already monitors storage drive access requests, and thus knows when traffic is outstanding (performance may be critical) or when it's not outstanding (and power may be saved).

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: For one disclosed embodiment, data corresponding to an idle duration for one or more downstream devices may be received. Power may be managed based at least in part on the received data. Other embodiments are also disclosed.

Abstract: In one embodiment an apparatus includes a multiplicity of processor components; one or more device components communicatively coupled to one or more processor components of the multiplicity of processor components; and a controller comprising logic at least a portion of which is in hardware, the logic to schedule one or more forced idle periods interspersed with one or more active periods, a forced idle period spanning a duration during which the multiplicity of processor components and the one or more device components are simultaneously placed in respective idle states that define a forced idle power state during isolated sub-periods of the forced idle period. Other embodiments are disclosed and claimed.

Abstract: Fast platform hibernation and resumption for computing systems. An embodiment of an apparatus includes a volatile system memory, a nonvolatile memory, and a processor to operate according to an operating system, the processor to transition the apparatus to a first reduced power state upon receipt of a request, the transition to the first reduced power state including the processor to store context information for the computer in the volatile system memory.

Abstract: In one embodiment, a system includes: a plurality of compute nodes to couple in a chassis; a first shared power supply to provide a baseline power level to the plurality of compute nodes; and an auxiliary power source to provide power to one or more of the plurality of compute nodes during operation at a higher power level than the baseline power level. Other embodiments are described and claimed.

Abstract: In one embodiment, a processor includes at least one core to execute instructions and a power control logic to receive power capability information from a plurality of devices to couple to the processor and allocate a platform power budget to the devices, set a first power level for the devices at which the corresponding device is allocated to be powered, communicate the first power level to the devices, and dynamically reduce a first power to be allocated to a first device and increase a second power to be allocated to a second device responsive to a request from the second device for a higher power level. Other embodiments are described and claimed.

Abstract: Particular embodiments described herein can offer a method that includes receiving a signal indicating whether at least one device is in a low power mode, determining that the at least one device is in a first thermally benign state based, at least in part, on the signal, and performing a first operation associated with a reduced thermal remediation power consumption.

Abstract: In an embodiment, a processor includes a plurality of cores and power management logic. The power management logic may be to, in response to a first break event during a reduced power state in the processor, set an exit timer based on a platform latency tolerance, block a first plurality of break events from interrupting the reduced power state, and in response to a expiration of the exit timer, terminate the reduced power state. Other embodiments are described and claimed.

Abstract: A method and apparatus for intelligent power management for low power link states. Some embodiments include methods, apparatuses, and systems for a device coupled to a controller via a link; a link power management engine to alter a power state of the link based on a transaction and some knowledge of future transactions between the device and the controller; and a memory or logic to store the link power management engine. In some embodiments, the memory stores information about at least one of the following: the power state of the link, the device buffering, the controller or device state or a history of transactions. In some embodiments, the device is a peripheral of a computer system. In some embodiments, the method may include transitioning the device to various link states. Other embodiments are described.

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: In an embodiment, a processor includes a plurality of cores and power management logic. The power management logic may be to, in response to a first break event during a reduced power state in the processor, set an exit timer based on a platform latency tolerance, block a first plurality of break events from interrupting the reduced power state, and in response to a expiration of the exit timer, terminate the reduced power state. Other embodiments are described and claimed.

Abstract: In at least one embodiment described herein, an apparatus is provided that can include means for communicating a latency tolerance value for a device connected to a platform from a software latency register if a software latency tolerance register mode is active. The apparatus may also include means for communicating the latency tolerance value from a hardware latency register if a host controller is active. The latency tolerance value can be sent to a power management controller. More specific examples can include means for communicating a latency tolerance value from the software latency register if the software latency tolerance register mode is not active and the host controller is not active. The apparatus can also include means for mapping a resource space in the software latency register for the device using a BIOS/platform driver. The mapping can be achieved using an advanced configuration and power interface device description.

Abstract: Various embodiments are generally directed to an apparatus, method and other techniques for receiving information to invoke a transition from a first operating system to a second operating system, copying a system context for the second operating system from a location of a non-volatile memory to a volatile memory, the location associated with the second operating system and transitioning from the first operating system to the second operating system using the system context for the second operating system.

Abstract: For one disclosed embodiment, a transition from a first state to a second, different state for at least a portion of a downstream device may be identified. The first and second states may correspond to different levels relating to activity for at least a portion of the downstream device. Data corresponding to a service latency may be transmitted to an upstream device in response to the identified transition for one or more upstream devices to manage power based at least in part on the service latency. Other embodiments are also disclosed.

Abstract: In one embodiment an apparatus includes a multiplicity of processor components; one or more device components communicatively coupled to one or more processor components of the multiplicity of processor components; and a controller comprising logic at least a portion of which is in hardware, the logic to schedule one or more forced idle periods interspersed with one or more active periods, a forced idle period spanning a duration during which the multiplicity of processor components and the one or more device components are simultaneously placed in respective idle states that define a forced idle power state during isolated sub-periods of the forced idle period. Other embodiments are disclosed and claimed.

Abstract: An electronic device may be provided that includes a first controller, a second controller, and a bus to connect between the first controller and the second controller. The electronic device may also include a first signal line between the first controller and the second controller, and the first controller to provide a first signal on the first signal line to the second controller to wake up the second controller from a low power mode.