Abstract: A high-performance, superscalar-based computer system with out-of-order instruction execution for enhanced resource utilization and performance throughput. The computer system fetches a plurality of fixed length instructions with a specified, sequential program order (in-order). The computer system includes an instruction execution unit including a register file, a plurality of functional units, and an instruction control unit for examining the instructions and scheduling the instructions for out-of-order execution by the functional units. The register file includes a set of temporary data registers that are utilized by the instruction execution control unit to receive data results generated by the functional units. The data results of each executed instruction are stored in the temporary data registers until all prior instructions have been executed, thereby retiring the executed instructions in-order.

Abstract: The high-performance, RISC core based microprocessor architecture includes an instruction fetch unit for fetching instruction sets from an instruction store and an execution unit that implements the concurrent execution of a plurality of instructions through a parallel array of functional units. The fetch unit generally maintains a predetermined number of instructions in an instruction buffer. The execution unit includes an instruction selection unit, coupled to the instruction buffer, for selecting instructions for execution, and a plurality of functional units for performing instruction specified functional operations. A unified instruction scheduler, within the instruction selection unit, initiates the processing of instructions through the functional units when instructions are determined to be available for execution and for which at least one of the functional units implementing a necessary computational function is available.

Abstract: A system and method for eliminating the critical path of a processor-based system by sending a signal to transition memory and/or I/O control units to a READ/WRITE state prior to the end of the complete instruction decode. If the decoding phase of the opcode of the instruction reveals that a read-write step is to be carried out wherein memory or an I/O device must be accessed, the processor immediately sends a read-write request to the memory control unit and the I/O control unit prior to decoding the balance of the instruction. Once the balance of the instruction has been decoded and the access location is determined to be in either memory or an I/O device, a cancellation process takes place. In this cancellation process, if the access location is in memory, the I/O unit transitions from the read-write state to an idle state. If, however, the access destination is determined to be an I/O device, the memory control unit transitions from the read-write state to the idle state.

Abstract: A high-performance, superscalar-based computer system with out-of-order instruction execution for enhanced resource utilization and performance throughput. The computer system fetches and stores program instruction sets. Each instruction set includes a plurality of fixed length instructions with a specified, sequential program order (in-order). The computer system includes an instruction execution unit including a register file, a plurality of functional units, and an instruction control unit for examining the instruction sets and scheduling the instructions for out-of-order execution by the functional units. The register file includes a set of temporary data registers which are utilized by the instruction execution control unit to receive data results generated by the functional units. The data results of each executed instruction are stored in the temporary data registers until all prior instructions have been executed, thereby retiring the executed instructions in-order.

Abstract: A system and method for extracting complex, variable length computer instructions from a stream of complex instructions each subdivided into a variable number of instructions bytes, and aligning instruction bytes of individual ones of the complex instructions. The system receives a portion of the stream of complex instructions and extracts a first set of instruction bytes starting with the first instruction bytes, using an extract shifter. The set of instruction bytes are then passed to an align latch where they are aligned and output to a next instruction detector. The next instruction detector determines the end of the first instruction based on said set of instruction bytes. An extract shifter is used to extract and provide the next set of instruction bytes to an align shifter which aligns and outputs the next instruction. The process is then repeated for the remaining instruction bytes in the stream of complex instructions.

Abstract: A high-performance, superscalar-based computer system with out-of-order instruction execution and concurrent results distribution for enhanced resource utilization and performance throughput. The computer system architecture includes an instruction fetch unit for fetching program instruction sets. Each instruction set includes a plurality of fixed length instructions with a prescribed program order (in-order). The architecture also includes an instruction execution unit for dynamically examining the instruction sets and scheduling instructions for execution, including out-of-order execution, among a plurality of functional units. The data results of the executed instructions are concurrently distributed to a temporary buffer and a register file array and managed by associated control logic, including a register renaming unit, a dependency checker unit, done control unit, and retirement control unit.

Abstract: A system and method for extracting complex, variable length computer instructions from a stream of complex instructions each subdivided into a variable number of instructions bytes, and aligning instruction bytes of individual ones of the complex instructions. The system receives a portion of the stream of complex instructions and extracts a first set of instruction bytes starting with the first instruction bytes, using an extract shifter. The set of instruction bytes are then passed to an align latch where they are aligned and output to a next instruction detector. The next instruction detector determines the end of the first instruction based on said set of instruction bytes. An extract shifter is used to extract and provide the next set of instruction bytes to an align shifter which aligns and outputs the next instruction. The process is then repeated for the remaining instruction bytes in the stream of complex instructions.

Abstract: A high-performance, superscalar-based computer system with out-of-order instruction execution for enhanced resource utilization and performance throughput. The computer system fetches and stores program instruction sets. Each instruction set includes a plurality of fixed length instructions with a specified, sequential program order (in-order). The computer system includes an instruction execution unit including a register file, a plurality of functional units, and an instruction control unit for examining the instruction sets and scheduling the instructions for out-of-order execution by the functional units. The register file includes a set of temporary data registers which are utilized by the instruction execution control unit to receive data results generated by the functional units. The data results of each executed instruction are stored in the temporary data registers until all prior instructions have been executed, thereby retiring the executed instructions in-order.

Abstract: Fast trap mechanism for a microprocessor, wherein a vector trap table is maintained which contains space for a plurality of instructions in each table entry. When a fast trap occurs, control is transferred directly into the table entry corresponding to the trap number. The trap handler can be located completely inside the table entry, or it can transfer control to additional handler code.

Abstract: A method for use in a microprocessor to return execution to a main program after processing an interruption to the sequential processing of instructions from the main instruction stream is disclosed. The method comprises fetching instructions from a main instruction stream to a main buffer section of a prefetch buffer and executing said fetched instructions. The method also provides for handling interruptions to the processing of the main instruction stream and allowing return to the main instruction stream without requiring prefetching of instructions already fetched. Similarly, the method provides for handling interruptions of the processing of interruptions of the processing of the main instruction stream.

Abstract: A system and method for extracting complex, variable length computer instructions from a stream of complex instructions each subdivided into a variable number of instructions bytes, and aligning instruction bytes of individual ones of the complex instructions. The system receives a portion of the stream of complex instructions and extracts a first set of instruction bytes starting with the first instruction bytes, using an extract shifter. The set of instruction bytes are then passed to an align latch where they are aligned and output to a next instruction detector. The next instruction detector determines the end of the first instruction based on said set of instruction bytes. An extract shifter is used to extract and provide the next set of instruction bytes to an align shifter which aligns and outputs the next instruction. The process is then repeated for the remaining instruction bytes in the stream of complex instructions.

Abstract: The present invention provides a reset circuit with two different threshold input voltages. The reset circuit of the present invention is located within a processor, and is designed to control the reset functions of both the processor and the chips located peripheral to the processor. The reset circuit includes a first buffer with a first threshold voltage level. The input of the first buffer is connected to a reset signal and the output of the first buffer is connected to control the reset function of at least one chip that is peripheral to the processor. A second buffer is provided with a second threshold voltage level that is higher than the first threshold voltage level. The input of the second buffer is connected to the reset signal and the output of the second buffer is connected to control the reset function of the processor. The reset circuit guarantees that the processor is reset after the peripheral chips subsequent to power up.