Abstract: Power consumption reduction control circuitry external and coupled to a processor used to execute instructions for data processing. A power management control signal is provided to the processor in accordance with conditions associated with the processor being operated in normal and reduced power consumption modes of operation, and an acknowledgement signal indicative of such reduced power consumption mode of operation is returned in correspondence with the power management control signal.

Abstract: A processing unit includes a plurality of subcircuits and circuitry for generating clock signals thereto. Detection circuitry detects the assertion of a control signal and disabling circuitry is operable to disable the clock signals to one or more of the subcircuits responsive to the control signal.

Abstract: A technique for invoking a low power operational mode in response to a halt instruction is used in a computer system that includes a processor coupled to external logic. The processor includes at least (i) a pipeline subcircuit to execute programmed instructions, including halt instructions, (ii) an interrupt handling subcircuit to handle interrupts generated by external interrupt logic, and (iii) clock generator circuitry that supplies clock signals to the pipeline and interrupt handling subcircuits. In response to execution of a halt instruction, the processor (i) enters the low power operational mode in which power consumption is reduced at least for the pipeline subcircuit, but without stopping the supply of clock signals to the interrupt handling subcircuit, and (ii) generates an acknowledgement signal to the external logic indicating that the clock signals to the pipeline subcircuit are being stopped, thereby entering the low power operational mode.

Abstract: A superscalar superpipelined microprocessor having a write buffer located between the core and cache is disclosed. The write buffer is controlled to store the results of write operations to memory until such time as the cache becomes available, such as when no high-priority reads are to be performed. The write buffer includes multiple entries that are split into two circular buffer sections for facilitating the interaction with the two pipelines of the core; cross-dependency tables are provided for each write buffer entry to ensure that the data is written from the write buffer to memory in program order, considering the possibility of prior data present in the opposite section. Non-cacheable reads form memory are also ordered in program order with the writing of data from the write buffer. Features for handling speculative execution, detecting and handling data dependencies and exceptions, and performing special write functions (misaligned writes and gathered writes) are also disclosed.

Abstract: A microprocessor comprises a plurality of instruction pipelines having a plurality of stages for processing a stream of instructions, circuitry for simultaneously issuing instructions into two or more of the pipelines without regard to whether one of the simultaneously issued instructions has a data dependency on other of the simultaneously issued instructions, detecting circuitry for detecting dependencies between instructions in the pipelines and circuitry for controlling the flow of instructions through the pipelines such that an instruction is not delayed due to a data dependency on another instruction unless the data dependency must be resolved for proper processing of the instruction in its current stage.

Abstract: A technique for invoking a low power operational mode in response to a halt instruction is used in a computer system that includes a processor coupled to external logic. The processor includes at least (i) a pipeline subcircuit to execute programmed instructions, including halt instructions, (ii) an interrupt handling subcircuit to handle interrupts generated by external interrupt logic, and (iii) clock generator circuitry that supplies clock signals to the pipeline and interrupt handling subcircuits. In response to execution of a halt instruction, the processor (i) stops the clock generator circuitry from supplying clock signals to the pipeline subcircuit, but not to the interrupt handling subcircuit, and (ii) generates an acknowledgement signal to the external logic indicating that the clock signals to the pipeline subcircuit are being stopped, thereby entering the low power operational mode.

Abstract: A superscalar superpipelined microprocessor having a write buffer located between the core and cache is disclosed. The write buffer is controlled to store the results of write operations to memory until such time as the cache becomes available, such as when no high-priority reads are to be performed. The write buffer includes multiple entries that are split into two circular buffer sections for facilitating the interaction with the two pipelines of the core; cross-dependency tables are provided for each write buffer entry to ensure that the data is written from the write buffer to memory in program order, considering the possibility of prior data present in the opposite section. Non-cacheable reads from memory are also ordered in program order with the writing of data from the write buffer. Features for handling speculative execution, detecting and handling data dependencies and exceptions, and performing special write functions (misaligned writes and gathered writes). are also disclosed.

Abstract: A write-back coherency system is used, in an exemplary embodiment, to implement write-back caching in an x86 processor installed in a multi-master computer system that does not support a write-back protocol for maintaining coherency between an internal cache and main memory during DMA operations. The write-back coherency system interrupts the normal bus arbitration operation to allow export of dirty data. In response to an arbitration-request (such as HOLD), if the internal cache contains dirty data, the processor is inhibited from providing arbitration-acknowledge (such as HLDA) until the dirty data is exported (the cache is dynamically switched to write-through mode to prevent data in the cache from being made dirty while the bus is arbitrated away). While the requesting bus master is accessing memory, bus snooping is performed and invalidation logic invalidates at least those cache locations corresponding to locations in memory that are affected by the requesting bus master.

Abstract: A system and method of readily identifying and handling self-modifying variable length instructions in a pipelined processor is disclosed employing index tags associated with each stage of the execution pipeline wherein the index tags identify the cache line numbers in the instruction cache from which the instructions originate.

Abstract: In a pipelined processor having at least one execution pipeline for executing instructions, the execution pipeline including ID (decode), AC (address calculation), and EX (execution) processing stages, the processor capable of addressing segments of system memory coupled thereto, a circuit for, and method of, setting a segment access indicator associated with a segment of the system memory being accessed by the processor. The circuit includes: (a) exception generating circuitry to generate an exception when the segment access indicator requires setting and (b) exception handling circuitry, invoked by the processor in response to generation of the exception, to flush the execution pipeline of instructions following a segment load instruction, set the segment access indicator and load an address pointer of the processor with an address corresponding to a specified location within the segment.

Abstract: An address translation unit is disclosed employing a direct-mapped translation lookaside buffer and a relatively small, associative victim translation lookaside buffer for translating linear addresses to physical addresses expediently and avoiding thrashing, without requiring large amounts of hardware and space.

Abstract: A write-back coherency system, including FLUSH/INVAL and LOCK protocols, is used, in an exemplary embodiment, in a microprocessor used in a computer system that selectively provides to the processor FLUSH and INVAL signals to implement a limited write-back protocol. The FLUSH/INVAL protocol is used by the computer system to control export and invalidate operations. In response to a FLUSH signal, the microprocessor exports dirty data from the cache. If INVAL is also asserted, the cache is also invalidated (i.e., if FLUSH is asserted and INVAL is not asserted, no invalidation is performed). With the LOCK protocol, LOCKed reads are serviced out of the cache for read hits--however, to maintain compatibility with computer systems that expect a LOCK operation to involve a read followed by a write access to external memory, the microprocessor will still run the external LOCKed read cycle, ignoring the returned data.

Abstract: A processor includes storage circuitry for storing an instruction and memory circuitry addressable by a microaddress for outputting a microinstruction in response to the microaddress. The processor further includes sequencing circuitry coupled to provide the microaddress to the memory circuitry. Finally, the processor includes decode circuitry coupled to the storage circuitry for detecting whether the instruction stored in the storage circuitry comprises a single clock instruction before the memory circuit outputs the microinstruction, and for indicating to the sequencing circuitry in response to detecting whether the instruction stored in the storage circuitry comprises a single clock instruction.

Abstract: A processing unit includes a plurality of subcircuits and circuitry for generating clock signals thereto. Detecting circuitry detects the assertion of a first signal indicative of a request for suspending operation of the processing unit and the assertion of a second signal indicating the state of operation of a coprocessing unit. Disabling circuitry is operable to disable clock signals to one or more of the subcircuits responsive to the first and second control signals.

Abstract: A processing unit includes a plurality of subcircuits and circuitry for generating clock signals thereto. Detection circuitry detects the assertion of a control signal and disabling circuitry is operable to disable the clock signals to one or more of the subcircuits responsive to the control signal.

Abstract: A superscalar superpipelined microprocessor having a write buffer located between the core and cache is disclosed. The write buffer is controlled to store the results of write operations to memory until such time as the cache becomes available, such as when no high-priority reads are to be performed. The write buffer includes multiple entries that are split into two circular buffer sections for facilitating the interaction with the two pipelines of the core; cross-dependency tables are provided for each write buffer entry to ensure that the data is written from the write buffer to memory in program order, considering the possibility of prior data present in the opposite section. Non-cacheable reads from memory are also ordered in program order with the writing of data from the write buffer. Features for handling speculative execution, detecting and handling data dependencies and exceptions, and performing special write functions (misaligned writes and gathered writes) are also disclosed.

Abstract: In a processor having a protected mode of operation in which a computer memory associated with the processor contains global and local descriptor tables addressed by a combination of a base address and an index, the processor having (i) global and local base address registers alternatively to provide the base address and (ii) a selector for containing the index and a table indicator (TI) bit indicating which of the global and local base address registers is to provide the base address, the processor requiring a time to derive the index and a value of the TI bit and a further time to combine the index and the base address, a base address register predicting circuit to predict, and a method of predicting, which of the global and local base address registers is to provide the base address without having to wait for the processor to derive the value of the TI bit.

Abstract: A superscalar superpipelined microprocessor having a write buffer located between the core and cache is disclosed. The write buffer is controlled to store the results of write operations to memory until such time as the cache becomes available, such as when no high-priority reads are to be performed. The write buffer includes multiple entries that are split into two circular buffer sections for facilitating the interaction with the two pipelines of the core; cross-dependency tables are provided for each write buffer entry to ensure that the data is written from the write buffer to memory in program order, considering the possibility of prior data present in the opposite section. Non-cacheable reads from memory are also ordered in program order with the writing of data from the write buffer. Features for handling speculative execution, detecting and handling data dependencies and exceptions, and performing special write functions (misaligned writes and gathered writes) are also disclosed.

Abstract: Shift-based control logic is used, in an exemplary embodiment, to implement in a microprocessor a circular prefetch queue that stores variable length instructions and transfers four instruction bytes at a time to an instruction decoder. The prefetch queue (10) includes a 16 byte sequential prefetch buffer (12). Access to the buffer is controlled by the shift-based control logic (14) which includes shifter logic that defines a four byte transfer window corresponding to an index byte together with the next three bytes in sequence. For each four-byte transfer operation, the shifter logic enables the four bytes within the transfer window to be read out for transfer to the instruction decoder (20). A transfer operation is initiated by the decoder, which presents the shift-based control logic with a bytes-used indicator, or shift increment. The shift increment denotes the number of bytes used by the previous four byte transfer via a four bit, one-hot selection.

Abstract: A write-back coherency system is used, in an exemplary embodiment, to implement write-back caching in an x86 processor installed in a multi-master computer system that does not support a write-back protocol for maintaining coherency between an internal cache and main memory during DMA operations. The write-back coherency system interrupts the normal bus arbitration operation to allow export of dirty data, and includes an X%DIRTY latency-control function. In response to an arbitration-request (such as HOLD), if the internal cache contains dirty data, the processor is inhibited from providing arbitration-acknowledge (such as HLDA) until the dirty data is exported (the cache is dynamically switched to write-through mode to prevent data in the cache from being made dirty while the bus is arbitrated away).