Abstract: A method performed in a memory controller for maintaining segmented counters split into primary and secondary memories, the primary memory faster. Events occur that require incrementing one of the segmented counters and the memory controller responds by incrementing a corresponding primary part in the primary memory. Each time a primary part is rolling over the memory controller determines that a secondary part should be updated. Also, the memory controller periodically determines that the secondary part of a segmented counter should be opportunistically updated. The opportunistic update is based on a probability function and a random number. The secondary part includes at least all of bits of the segmented counter not in the primary part and is stored in the secondary memory. Each time an update to the secondary part occurs, both the secondary part and primary part of the segmented counter must be updated.

Abstract: A method performed in a memory controller for maintaining segmented counters split into primary and secondary memories, the primary memory faster. Events occur that require incrementing one of the segmented counters and the memory controller responds by incrementing a corresponding primary part in the primary memory. Each time a primary part is rolling over the memory controller determines that a secondary part should be updated. Also, the memory controller periodically determines that the secondary part of a segmented counter should be opportunistically updated. The opportunistic update is based on a probability function and a random number. The secondary part includes at least all of bits of the segmented counter not in the primary part and is stored in the secondary memory. Each time an update to the secondary part occurs, both the secondary part and primary part of the segmented counter must be updated.

Abstract: The present invention generally relates to synchronization of multiple threads in an out-of-order microprocessor utilizing the insertion of a trap. In one embodiment, while synchronizing multiple running threads, an instruction within a first running thread is identified. Upon identification of this instruction, a trap is inserted into a second running thread. All instructions within the instructional pipeline that are scheduled for execution prior to this trapped instruction must retire before the subsequent execution of the synchronizing instruction. Following the execution of the synchronizing instruction, all instructions within the instruction pipeline slated for execution after the trapped instruction in the remaining threads are flushed and refetched.

Abstract: The present invention generally relates to synchronization of multiple threads in an out-of-order microprocessor utilizing the insertion of a trap. In one embodiment, while synchronizing multiple running threads, an instruction within a first running thread is identified. Upon identification of this instruction, a trap is inserted into a second running thread. All instructions within the instructional pipeline that are scheduled for execution prior to this trapped instruction must retire before the subsequent execution of the synchronizing instruction. Following the execution of the synchronizing instruction, all instructions within the instruction pipeline slated for execution after the trapped instruction in the remaining threads are flushed and refetched.