Embodiments of processors, methods, and systems for a processor core supporting processor identification instruction spoofing are described. In an embodiment, a processor includes an instruction decoder and processor identification instruction spoofing logic. The processor identification spoofing logic is to respond to a processor identification instruction by reporting processor identification information from a processor identification spoofing data structure. The processor identification spoofing data structure is to include processor identification information of one or more other processors.

The present disclosure discloses an instruction execution device, a processor including the instruction execution device, a system on chip, and a method for executing a data storage instruction in the processor. The method includes: splitting the data storage instruction into a first split instruction and a second split instruction, wherein the first split instruction is associated with an address operand of the data storage instruction, and the second split instruction is associated with a data operand of the data storage instruction; executing the first split instruction to determine a data storage address corresponding to the address operand; executing the second split instruction to acquire data content corresponding to the data operand; and storing the acquired data content to the determined data storage address in a data storage region. The present disclosure further discloses a corresponding instruction execution device, a processor including the execution device and a system on chip.

An instruction offload manager receives, by a processing device, a first request to execute a program, identifies one or more instructions of the program to be offloaded to a second processing device, where the second processing device includes a same instruction set architecture as the processing device, and provides the one or more instructions to a memory module comprising the second processing device. Responsive to detecting an indication to execute the one or more instructions, the instruction offload manager provides an indication to the second processing device to cause the second processing device to execute the one or more instructions, the one or more instructions to update a portion of a memory space associated with the memory module.

In one example, an integrated circuit comprises: a memory configured to store a first mapping between a first opcode and first control information and a second mapping between the first opcode and second control information; a processing engine configured to perform processing operations based on the control information; and a controller configured to: at a first time, provide the first opcode to the memory to, based on the first mapping stored in the memory, fetch the first control information for the processing engine, to enable the processing engine to perform a first processing operation based on the first control information; and at a second time, provide the first opcode to the memory to, based on the second mapping stored in the memory, fetch the second control information for the processing engine, to enable the processing engine to perform a second processing operation based on the second control information.

A streaming engine employed in a digital data processor specifies a fixed read only data stream defined by plural nested loops. An address generator produces address of data elements for the nested loops. A steam head register stores data elements next to be supplied to functional units for use as operands. A stream template specifies loop count and loop dimension for each nested loop. A format definition field in the stream template specifies the number of loops and the stream template bits devoted to the loop counts and loop dimensions. This permits the same bits of the stream template to be interpreted differently enabling trade off between the number of loops supported and the size of the loop counts and loop dimensions.

A processing circuitry having a secure domain and a less secure domain. A control storage location stores a domain transition disable configuration parameter specifying whether domain transitions between the secure domain and the less secure domain are enabled or disabled in at least one mode of the process-ing circuitry. In the at least one mode of the processing circuitry, when the domain transition disable configuration parameter specifies that said domain transitions are disabled in said at least one mode, a disabled domain transition fault is signalled in response to an attempt to transition between domains in either direction. This can help support lazy configuration of resources for the secure domain or less secure domain for a thread expected only to need the other domain.

Methods and apparatus relating to loop driven region based frontend translation control for performant and secure data-space guided micro-sequencing are described. In an embodiment, Data-space Translation Logic (DTL) circuitry receives a static input and a dynamic input and generates one or more outputs based at least in part on the static input and the dynamic input. A frontend counter generates a count value for the dynamic input based at least in part on an incremented/decremented counter value and a next counter value from the DTL circuitry. The DTL circuitry is capable to receive a new dynamic input prior to consumption of the one or more outputs. Other embodiments are also disclosed and claimed.

Methods and apparatus relating to issue, execution, and backend driven frontend translation control for performant and secure data-space guided micro-sequencing are described. In an embodiment, Data-space Translation Logic (DTL) circuitry receives a static input and a dynamic input, and generates one or more outputs based at least in part on the static input and the dynamic input. The DTL circuitry generates the one or more outputs prior to commencement of speculation operations in a processor. Other embodiments are also disclosed and claimed.

Systems, apparatuses, and methods for virtualizing a micro-operation cache are disclosed. A processor includes at least a micro-operation cache, a conventional cache subsystem, a decode unit, and control logic. The decode unit decodes instructions into micro-operations which are then stored in the micro-operation cache. The micro-operation cache has limited capacity for storing micro-operations. When new micro-operations are decoded from pending instructions, existing micro-operations are evicted from the micro-operation cache to make room for the new micro-operations. Rather than being discarded, micro-operations evicted from the micro-operation cache are stored in the conventional cache subsystem. This prevents the original instruction from having to be decoded again on subsequent executions. When the control logic determines that micro-operations for one or more fetched instructions are stored in either the micro-operation cache or the conventional cache subsystem, the control logic causes the decode unit to transition to a reduced-power state.

The present invention provides a method for detecting a flash memory module and an associated SoC. The method reads data in a flash memory module with a specific data format, and then determining a plurality of characteristic parameters of the flash memory module and a size of a page by decoding and checking the data. Therefore, the SoC does not need to design a one-time-programmable memory or strap pins, so as to reduce the manufacturing cost of the SoC.