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Background Motivation Implementation Conclusion 2.

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Presentation on theme: "Background Motivation Implementation Conclusion 2."— Presentation transcript:

1

2 Background Motivation Implementation Conclusion 2

3 Unlike FPGA, XOR Gate in ASIC Design has more delay and more area than other gates. We should reduce the number of XOR. 3 Gate Level FPGAASIC Logic Synthesis FPGAASIC RTL Level # of XOR ↑ # of XOR ↓

4 4 Which is the last area where people still manually optimize circuits, even though logic synthesis has made enormous progress. Is domination of a good arithmetic, however it contains a LARGE number of XORs.

5 5 But… Synthesizer seldom rewrites XORs… Automatically rewriting XORs is necessary for synthesizer! It is time to find a solution!

6 Why not rewrite all XORs? 6 1.Increase size of input expression exponentially. Only being used when number of XORs is small.

7 Why not rewrite all XORs? 7 2. Not all XORs are suitable for expansion: Before: D: 0.37ns A: 138.2um 2 After: D:0.26ns A: 146.9um 2 30% Faster! A Small Area Cost. Before: D: 0.22ns A: 58.8um 2 After: D:0.27ns A: 221.2um 2 Both Delay and Area Increases!

8 8 Local Correlation Global Correlation

9 9 Local Correlation Two Extreme Cases: AB=0=> A ⊕ B=A+B A+B=1 => A ⊕ B=AB So we consider AB and (A+B) as two important factors. We evaluate the delay and area of these two factors.

10 10 Local Correlation

11 11 Global Correlation

12 12 Global Correlation Much Faster Less Area Optimized Result

13 13 2 Correlations Merged Optimisation results for all benchmarks

14 14 2 Correlations Merged Comparison of bitwise delays of the multiplier Less Delay

15 15

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