Abstract: In an embodiment, a processor includes a first chip of a multi-chip package (MCP). The first chip includes at least one core and first chip temperature control (TC) logic to assert a first power adjustment signal at a second chip of the MCP responsive to an indication that a first chip temperature of the first chip exceeds a first threshold. The processor also includes a conduit that includes a bi-directional pin to couple the first chip to the second chip within the MCP. The conduit is to transport the first power adjustment signal from the first chip to the second chip and the first power adjustment signal is to cause an adjustment of a second chip power consumption of the second chip. Other embodiments are described and claimed.

Abstract: In one embodiment, the present invention includes a processor having a core and a power controller to control power management features of the processor. The power controller can receive an energy performance bias (EPB) value from the core and access a power-performance tuning table based on the value. Using information from the table, at least one setting of a power management feature can be updated. Other embodiments are described and claimed.

Abstract: A processor may include a cause agnostic frequency dither filter (FD filter), which may cause reduction in the frequency transitions while maintaining the performance levels. The FD Filter may minimize the performance loss, which may otherwise accrue from these frequency transitions, while trying to maximize the peak frequency of the processor. The FD filter may determine a minimum and maximum limit, which may be used by a power management unit (PMU) to restrict the number of frequency transitions to be within a specified threshold. The FD filter may determine the maximum and minimum limits based on transition data stored in internal tables captured during one or more time windows (or observation windows). Based on an average system behavior, the PMU may either apply the minimum or the maximum limit over the subsequent time window.

Abstract: In one embodiment, the present invention includes a processor having a core and a power controller to control power management features of the processor. The power controller can receive an energy performance bias (EPB) value from the core and access a power-performance tuning table based on the value. Using information from the table, at least one setting of a power management feature can be updated. Other embodiments are described and claimed.

Abstract: A processor is described that includes a processing core and a plurality of counters for the processing core. The plurality of counters are to count a first value and a second value for each of multiple threads supported by the processing core. The first value reflects a number of cycles at which a non sleep state has been requested for the first value's corresponding thread, and, a second value that reflects a number of cycles at which a non sleep state and a highest performance state has been requested for the second value's corresponding thread. The first value's corresponding thread and the second value's corresponding thread being a same thread.

Abstract: In one embodiment, the present invention includes a processor having a core and a power controller to control power management features of the processor. The power controller can receive an energy performance bias (EPB) value from the core and access a power-performance tuning table based on the value. Using information from the table, at least one setting of a power management feature can be updated. Other embodiments are described and claimed.

Abstract: In an embodiment, a processor includes a plurality of cores each to independently execute instructions, a power delivery logic coupled to the plurality of cores, and a power controller including a first logic to cause a first core to enter into a first low power state of an operating system power management scheme independently of the OS, during execution of at least one thread on the first core. Other embodiments are described and claimed.

Abstract: In an embodiment, a processor includes a core to execute instructions, uncore logic coupled to the core, and a power controller to control a power consumption level. The power controller is configured to determine an activity level of the processor and responsive to this level, to generate a request for communication to a second processor coupled to the processor to request frequency coordination between the processors. Other embodiments are described and claimed.

Abstract: An apparatus and method for managing a frequency of a computer processor. The apparatus includes a power control unit (PCU) to manage power in a computer processor. The PCU includes a data collection module to obtain transaction rate data from a plurality of communication ports in the computer processor and a frequency control logic module coupled to the data collection module, the frequency control logic to calculate a minimum processor interconnect frequency for the plurality of communication ports to handle traffic without significant added latency and to override the processor interconnect frequency to meet the calculated minimum processor interconnect frequency.

Abstract: A processor is described that includes a processing core and a plurality of counters for the processing core. The plurality of counters are to count a first value and a second value for each of multiple threads supported by the processing core. The first value reflects a number of cycles at which a non sleep state has been requested for the first value's corresponding thread, and, a second value that reflects a number of cycles at which a non sleep state and a highest performance state has been requested for the second value's corresponding thread. The first value's corresponding thread and the second value's corresponding thread being a same thread.

Abstract: In one embodiment, the present invention includes a processor having a core and a power controller to control power management features of the processor. The power controller can receive an energy performance bias (EPB) value from the core and access a power-performance tuning table based on the value. Using information from the table, at least one setting of a power management feature can be updated. Other embodiments are described and claimed.

Abstract: Embodiments of the invention are generally directed to systems, methods, and apparatuses for clock enable (CKE) coordination. In some embodiments, a memory controller includes logic to predict whether a scheduled request will be issued to a rank. The memory controller may also include logic to predict whether a scheduled request will not be issued to the rank. In some embodiments, the clock enable (CKE) is asserted or de-asserted to a rank based, at least in part, on the predictions. Other embodiments are described and claimed.

Abstract: In one embodiment, the present invention includes a processor having a core and a power controller to control power management features of the processor. The power controller can receive an energy performance bias (EPB) value from the core and access a power-performance tuning table based on the value. Using information from the table, at least one setting of a power management feature can be updated. Other embodiments are described and claimed.

Abstract: In one embodiment, the present invention includes a multicore processor having a power controller with logic to dynamically switch a power management policy from a power biased policy to a performance biased policy when a utilization of the processor exceeds a threshold level. Thus at low utilizations, reduced power consumption can be realized, while at higher utilizations, greater performance can be realized. Other embodiments are described and claimed.

Abstract: In an embodiment, the method provides receiving a memory access request for a demanded cache line from a processor of a plurality of processors; accessing coherency information associated with the demanded cache line from a memory unit by bringing in from a memory page in which the demanded cache line is stored, the memory page also including a directory line having coherency information corresponding to the demanded cache line; reading data associated with the demanded cache line in accordance with the coherency information; and returning the data to the processor.

Abstract: Embodiments of the invention are generally directed to systems, methods, and apparatuses for rank coordination. In some embodiments, a host includes rank coordination logic. The rank coordination logic may include performance measurement logic to measure a performance of a memory channel and dwell period control logic to select a length of a dwell period based, at least in part, on the performance of the memory channel. Other embodiments are described and claimed.

Abstract: Embodiments of the invention are generally directed to systems, methods, and apparatuses for rank coordination. In some embodiments, a host includes rank coordination logic. The rank coordination logic may include performance measurement logic to measure a performance of a memory channel and dwell period control logic to select a length of a dwell period based, at least in part, on the performance of the memory channel. Other embodiments are described and claimed.

Abstract: In an embodiment, the method provides receiving a memory access request for a demanded cache line from a processor of a plurality of processors; accessing coherency information associated with the demanded cache line from a memory unit by bringing in from a memory page in which the demanded cache line is stored, the memory page also including a directory line having coherency information corresponding to the demanded cache line; reading data associated with the demanded cache line in accordance with the coherency information; and returning the data to the processor.

Abstract: Embodiments of the invention are generally directed to systems, methods, and apparatuses for clock enable (CKE) coordination. In some embodiments, a memory controller includes logic to predict whether a scheduled request will be issued to a rank. The memory controller may also include logic to predict whether a scheduled request will not be issued to the rank. In some embodiments, the clock enable (CKE) is asserted or de-asserted to a rank based, at least in part, on the predictions. Other embodiments are described and claimed.