Consider a CPU with Two Parallel Fetch-Execute Pipelines for Superscalar Processing

CPU Performance Improvement with Parallel Pipelines

A CPU with two parallel fetch-execute pipelines can significantly improve performance compared to scalar pipeline or no-pipeline processing. With three pipeline stages (fetch, decode, execute) and a 50 instruction sequence, the impact on clock cycles is significant.

Performance Comparison:

No pipelining would require 300 clock cycles
A scalar pipeline would require 100 clock cycles
A superscalar pipeline with two parallel units would require 50 clock cycles

Final Answer:

A CPU with two parallel fetch-execute pipelines can significantly improve performance compared to scalar pipeline or no-pipeline processing. With three pipeline stages, a 50 instruction sequence would require 300 clock cycles without pipelining, 100 clock cycles in a scalar pipeline, and only 50 clock cycles in a superscalar pipeline with two parallel units.

Explanation:

A CPU that implements two parallel fetch-execute pipelines for superscalar processing can significantly improve performance compared to scalar pipeline or no-pipeline processing. In a no-pipeline scenario, each instruction would require multiple clock cycles, including fetch, decode, and execute, resulting in a higher total number of clock cycles for a sequence of instructions. For example, if each stage takes one, two, and three clock cycles, a 50 instruction sequence would require 300 clock cycles without pipelining.

In a scalar pipeline, instructions are executed one after the other, but pipeline stages can overlap to improve efficiency. With three pipeline stages as described, each instruction would still require three clock cycles to complete, but multiple instructions can be processed simultaneously in different stages. This reduces the number of clock cycles required for a 50 instruction sequence to 100.

In a superscalar pipeline with two parallel units, instructions can be fetched, decoded, and executed simultaneously in two separate pipelines. This allows for even greater overlap and parallelism, resulting in improved performance. With two pipeline units, the 50 instruction sequence would require 50 clock cycles, which is the most efficient of the three scenarios.

Consider a CPU that implements two parallel fetch-execute pipelines for superscalar processing. Show the performance improvement over scalar pipeline processing and no-pipeline processing, assuming an instruction cycle similar to the figure below · a one clock cycle fetch · a two clock cycle decode · a three clock cycle execute and a 50 instruction sequence: Show your work. No pipelining would require 300 clock cycles
A scalar pipeline would require 100 clock cycles
A superscalar pipeline with two parallel units would require 50 clock cycles
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