The next stream predictor is an accurate branch predictor that provides stream level sequencing. Every stream prediction contains a full stream of instructions, that is, a sequence of instructions from the target of a taken branch to the next taken branch, potentially containing multiple basic blocks. The long size of instruction streams makes it possible for the stream predictor to provide high fetch bandwidth and to tolerate the prediction table access latency. Therefore, an excellent way for improving the behavior of the next stream predictor is to enlarge instruction streams. In this paper, we provide a comprehensive analysis of dynamic instruction streams, showing that focusing on particular kinds of stream is not a good strategy du...
High-performance superscalar processors examine a large pool of speculative instructions, called the...
Fetch engine performance is seriously limited by the branch prediction table access latency. This fa...
Modern processors use branch prediction to predict branch outcomes, in order to fetch ahead in the i...
The next stream predictor is an accurate branch predictor that provides stream level sequencing. Eve...
This work presents several techniques for enlarging instruction streams. We call stream to a sequenc...
The stream fetch engine is a high-performance fetch architecture based on the concept of an instruct...
A basic rule in computer architecture is that a processor cannot execute an application faster than ...
textPerformance of modern pipelined processor depends on steady flow of useful instructions for proc...
A sequence of branch instructions in the dynamic instruction stream forms a branch sequence if at mo...
Modern superscalar processors rely on branch predictors to sustain a high instruction fetch throughp...
As the issue width and depth of pipelining of high performance superscalar processors increase, the ...
Accurate branch prediction can be seen as a mechanism for enabling design decisions. When short pipe...
The access latency of branch predictors is a well known problem of fetch engine design. Prediction o...
. Two-level predictors improve branch prediction accuracy by allowing predictor tables to hold multi...
High-performance superscalar processors examine a large pool of speculative instructions, called the...
Fetch engine performance is seriously limited by the branch prediction table access latency. This fa...
Modern processors use branch prediction to predict branch outcomes, in order to fetch ahead in the i...
The next stream predictor is an accurate branch predictor that provides stream level sequencing. Eve...
This work presents several techniques for enlarging instruction streams. We call stream to a sequenc...
The stream fetch engine is a high-performance fetch architecture based on the concept of an instruct...
A basic rule in computer architecture is that a processor cannot execute an application faster than ...
textPerformance of modern pipelined processor depends on steady flow of useful instructions for proc...
A sequence of branch instructions in the dynamic instruction stream forms a branch sequence if at mo...
Modern superscalar processors rely on branch predictors to sustain a high instruction fetch throughp...
As the issue width and depth of pipelining of high performance superscalar processors increase, the ...
Accurate branch prediction can be seen as a mechanism for enabling design decisions. When short pipe...
The access latency of branch predictors is a well known problem of fetch engine design. Prediction o...
. Two-level predictors improve branch prediction accuracy by allowing predictor tables to hold multi...
High-performance superscalar processors examine a large pool of speculative instructions, called the...
Fetch engine performance is seriously limited by the branch prediction table access latency. This fa...
Modern processors use branch prediction to predict branch outcomes, in order to fetch ahead in the i...