Abstract: A processor saves micro-architectural contexts to increase the efficiency of code execution and power management. A save instruction is executed to store a micro-architectural state and an architectural state of a processor in a common buffer of a memory upon a context switch that suspends the execution of a process. The micro-architectural state contains performance data resulting from the execution of the process. A restore instruction is executed to retrieve the micro-architectural state and the architectural state from the common buffer upon a resumed execution of the process. Power management hardware then uses the micro-architectural state as an intermediate starting point for the resumed execution.

Abstract: An asymmetric multiprocessor system (ASMP) may comprise computational cores implementing different instruction set architectures and having different power requirements. Program code executing on the ASMP is analyzed by a binary analysis unit to determine what functions are called by the program code and select which of the cores are to execute the program code, or a code segment thereof. Selection may be made to provide for native execution of the program code, to minimize power consumption, and so forth. Control operations based on this selection may then be inserted into the program code, forming instrumented program code. The instrumented program code is then executed by the ASMP.

Abstract: A processor includes a core with locally-gated circuitry, a decode unit, a local power gate (LPG) coupled to the locally-gated circuitry, and an execution unit. The decode unit includes logic to decode a store broadcast instruction of a specified width. The LPG includes logic to selectively provide power to the locally-gated circuitry, activate power to a first portion of the locally-gated circuitry for execution of full cache-line memory operations, and deactivate power to a second portion of the locally-gated circuitry the locally-gated circuitry. The execution unit includes logic to execute, by the first portion of the locally-gated circuitry for execution of full cache-line memory operations, the store broadcast instruction, the store broadcast instruction to store data of the specified width to storage of the processor.

Abstract: Remapping technologies for execution context swap between heterogeneous functional hardware units are described. A computing system includes multiple registers configured to store remote contexts of functional units. A mapping table maps the remote context to the functional units. An execution unit is configured to execute a remapping tool that intercepts an operation to access a remote context of a first functional unit of the plurality of functional units that is taken offline. The remapping tool determines that the first functional unit is remapped to a second functional unit using the mapping table. The operation is performed to access the remote context that is remapped to the second functional unit. The first functional unit and the second functional unit may be heterogeneous functional units.

Abstract: A processor of an aspect includes a decode unit to decode a thread pause instruction from a first thread. A back-end portion of the processor is coupled with the decode unit. The back-end portion of the processor, in response to the thread pause instruction, is to pause processing of subsequent instructions of the first thread for execution. The subsequent instructions occur after the thread pause instruction in program order. The back-end portion, in response to the thread pause instruction, is also to keep at least a majority of the back-end portion of the processor, empty of instructions of the first thread, except for the thread pause instruction, for a predetermined period of time. The majority may include a plurality of execution units and an instruction queue unit.

Abstract: An apparatus and method for determining thread execution parallelism. For example, a processor in accordance with one embodiment comprises: a plurality of cores to execute a plurality of threads; a plurality of counters to collect data related to the execution of the plurality of threads on the plurality of cores; a dependency analysis module to analyze the data related to the execution of the threads and responsively determine a level of inter-thread dependency; and a control module to responsively adjust operation of the plurality of cores based on the determined level of inter-thread dependency.

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: A mechanism is described for facilitating faster suspend/resume operations in computing systems according to one embodiment of the invention. A method of embodiments of the invention includes initiating an entrance process into a first sleep state in response to a sleep call at a computing system, transforming from the first sleep state to a second sleep state. The transforming may include preserving at least a portion of processor context at a local memory associated with one or more processor cores of a processor at the computing system. The method may further include entering the second sleep state.

Abstract: Technologies for local power gate (LPG) interfaces for power-aware operations are described. A processor includes locally-gated circuitry of a core, main core circuitry of the core, the main core, and local power gate (LPG) hardware. The LPG hardware is to power gate the locally-gated circuitry according to local power states of the LPG hardware. The main core decodes a first instruction of a set of instructions to perform a first power-aware operation of a specified length, including computing an execution code path for execution. The main core monitors a current local power state of the LPG hardware, selects one of the code paths based on the current local power state, the specified length, and a specified threshold, and issues a hint to the LPG hardware to power up the locally-gated circuitry and continues execution of the first power-aware operation without waiting for the locally-gated circuitry to be powered up.

Abstract: In some disclosed embodiments instruction execution logic provides conditional memory fault assist suppression. Some embodiments of processors comprise a decode stage to decode one or more instruction specifying: a set of memory operations, one or more register, and one or more memory address. One or more execution units, responsive to the one or more decoded instruction, generate said one or more memory address for the set of memory operations. Instruction execution logic records one or more fault suppress bits to indicate whether one or more portion of the set of memory operations are masked. Fault generation logic is suppressed from considering a memory fault corresponding to a faulting one of the set of memory operations when said faulting one of the set of memory operations corresponds to a portion of the set of memory operations that is indicated as masked by said one or more fault suppress bits.

Abstract: Extended features such as registers and functions within processors are made available to operating systems (OS) using an extended-state driver and by modifying instruction set extensions, such as XSAVE. A map-table designates a correspondence between memory locations for storing data relating to extended features not supported by the OS and called by an application. As a result, applications may utilize processor resources which are unsupported by the OS.

Abstract: Embodiments of an invention related to compacted context state management are disclosed. In one embodiment, a processor includes instruction hardware and state management logic. The instruction hardware is to receive a first save instruction and a second save instruction. The state management logic is to, in response to the first save instruction, save context state in an un-compacted format in a first save area. The state management logic is also to, in response to the second save instruction, save a compaction mask and context state in a compacted format in a second save area and set a compacted-save indicator in the second save area. The state management logic is also to, in response to a single restore instruction, determine, based on the compacted-save indicator, whether to restore context from the un-compacted format in the first save area or from the compacted format in the second save area.

Abstract: In one embodiment, the present invention includes an instruction decoder that can receive an incoming instruction and a path select signal and decode the incoming instruction into a first instruction code or a second instruction code responsive to the path select signal. The two different instruction codes, both representing the same incoming instruction may be used by an execution unit to perform an operation optimized for different data lengths. Other embodiments are described and claimed.

Abstract: An error recovery unit that may include error logic to detect an error in a dispatch port and timestamp logic configured to generate a timestamp for the error. The error recovery unit may also include check logic to determine if an instruction associated with the error has been retired based on the timestamp. If the instruction has been retired, a machine check error logic may be initiated. If the instruction has not been retired, an error correction logic may be initiated to recover the error and to re-execute the instruction. Thus, speculative errors may be recovered without the need for calling the machine check error, which is undesirable because of its catastrophic nature. Therefore, machine check errors may be significantly reduced.

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: Remapping technologies for execution context swap between heterogeneous functional hardware units are described. A computing system includes multiple registers configured to store remote contexts of functional units. A mapping table maps the remote context to the functional units. An execution unit is configured to execute a remapping tool that intercepts an operation to access a remote context of a first functional unit of the plurality of functional units that is taken offline. The remapping tool determines that the first functional unit is remapped to a second functional unit using the mapping table. The operation is performed to access the remote context that is remapped to the second functional unit. The first functional unit and the second functional unit may be heterogeneous functional units.

Abstract: An apparatus and method are described for detecting and correcting data fetch errors within a processor core. For example, one embodiment of an instruction processing apparatus for detecting and recovering from data fetch errors comprises: at least one processor core having a plurality of instruction processing stages including a data fetch stage and a retirement stage; and error processing logic in communication with the processing stages to perform the operations of: detecting an error associated with data in response to a data fetch operation performed by the data fetch stage; and responsively performing one or more operations to ensure that the error does not corrupt an architectural state of the processor core within the retirement stage.

Abstract: In one embodiment, the present invention includes a multicore processor having first and second cores to independently execute instructions, the first core visible to an operating system (OS) and the second core transparent to the OS and heterogeneous from the first core. A task controller, which may be included in or coupled to the multicore processor, can cause dynamic migration of a first process scheduled by the OS to the first core to the second core transparently to the OS. Other embodiments are described and claimed.

Abstract: In one embodiment, the present invention includes a multicore processor with first and second groups of cores. The second group can be of a different instruction set architecture (ISA) than the first group or of the same ISA set but having different power and performance support level, and is transparent to an operating system (OS). The processor further includes a migration unit that handles migration requests for a number of different scenarios and causes a context switch to dynamically migrate a process from the second core to a first core of the first group. This dynamic hardware-based context switch can be transparent to the OS. Other embodiments are described and claimed.

Abstract: Embodiments of an invention related to context state management based on processor features are disclosed. In one embodiment, a processor includes instruction logic and state management logic. The instruction logic is to receive a state management instruction having a parameter to identify a subset of the features supported by the processor. The state management logic is to perform a state management operation specified by the state management instruction.