Patent application number | Description | Published |
20130311760 | Multi Level Indirect Predictor using Confidence Counter and Program Counter Address Filter Scheme - The disclosure relates to predicting simple and polymorphic branch instructions. An embodiment of the disclosure detects that a program instruction is a branch instruction, determines whether a program counter for the branch instruction is stored in a program counter filter, and, if the program counter is stored in the program counter filter, prevents the program counter from being stored in a first level predictor. | 11-21-2013 |
20140006752 | Qualifying Software Branch-Target Hints with Hardware-Based Predictions | 01-02-2014 |
20140149726 | ESTABLISHING A BRANCH TARGET INSTRUCTION CACHE (BTIC) ENTRY FOR SUBROUTINE RETURNS TO REDUCE EXECUTION PIPELINE BUBBLES, AND RELATED SYSTEMS, METHODS, AND COMPUTER-READABLE MEDIA - Establishing a branch target instruction cache (BTIC) entry for subroutine returns to reduce pipeline bubbles, and related systems, methods, and computer-readable media are disclosed. In one embodiment, a method of establishing a BTIC entry includes detecting a subroutine call in an execution pipeline. In response, at least one instruction fetched sequential to the subroutine call is written as a branch target instruction in a BTIC entry for a subroutine return. A next instruction fetch address is calculated, and is written into a next instruction fetch address field in the BTIC entry. In this manner, the BTIC may provide correct branch target instruction and next instruction fetch address data for the subroutine return, even if the subroutine return is encountered for the first time or the subroutine is called from different calling locations. | 05-29-2014 |
20140281394 | METHOD TO IMPROVE SPEED OF EXECUTING RETURN BRANCH INSTRUCTIONS IN A PROCESSOR - An apparatus and method for executing call branch and return branch instructions in a processor by utilizing a link register stack. The processor includes a branch counter that is initialized to zero, and is set to zero each time the processor decodes a link register manipulating instruction other than a call branch instruction. The branch counter is incremented by one each time a call branch instruction is decoded and an address is pushed onto the link register stack. In response to decoding a return branch instruction and provided the branch counter is not zero, a target address for the decoded return branch instruction is popped off the link register stack, the branch counter is decremented, and there is no need to check the target address for correctness. | 09-18-2014 |
20140281405 | OPTIMIZING PERFORMANCE FOR CONTEXT-DEPENDENT INSTRUCTIONS - A processor includes a queue for storing instructions processed within the context of a current value of a register field, where for some embodiments the instruction is undefined or defined, depending upon the register field at time of processing. After a write instruction (an instruction that writes to the register field) executes, the queue is searched for any entries that contain instructions that depend upon the executed write instruction. Each such entry stores the value of the register field at the time the instruction in the entry was processed. If such an entry is found in the queue and its stored value of the register field does not match the value that the write instruction wrote to the register field, then the processor flushes the pipeline and restarts at a state so as to correctly execute the instruction. | 09-18-2014 |
20140281429 | ELIMINATING REDUNDANT SYNCHRONIZATION BARRIERS IN INSTRUCTION PROCESSING CIRCUITS, AND RELATED PROCESSOR SYSTEMS, METHODS, AND COMPUTER-READABLE MEDIA - Embodiments disclosed herein include eliminating redundant synchronization barriers from execution pipelines in instruction processing circuits. Related processor systems, methods, and computer-readable media are also disclosed. By tracking the occurrence of synchronization events, unnecessary software synchronization operations may be identified and eliminated, thus improving performance of a central processing unit (CPU). In one embodiment, a method for eliminating redundant synchronization barriers in an instruction stream is provided. The method comprises determining whether a next instruction comprises a synchronization barrier of a type corresponding to a first synchronization event. The method also comprises eliminating the next instruction from the instruction stream, responsive to determining that the next instruction comprises a synchronization barrier of a type corresponding to the first synchronization event. In this manner, the average number of instructions executed during each CPU clock cycle may be increased by avoiding unnecessary synchronization operations. | 09-18-2014 |