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Computer-Aided Design of Digital VLSI Circuits & Systems

Perspectives on Next-Generation Logic Synthesis. Computer-Aided Design of Digital VLSI Circuits & Systems. Priyank Kalla Dept. of Elec. & Comp. Engineering University of Utah,SLC. Logic Synthesis in VLSI Realization. Objective: Generate Optimal Designs. Specifications. Circuit Netlist.

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Computer-Aided Design of Digital VLSI Circuits & Systems

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  1. Perspectives on Next-Generation Logic Synthesis Computer-Aided Design of Digital VLSI Circuits & Systems Priyank Kalla Dept. of Elec. & Comp. Engineering University of Utah,SLC

  2. Logic Synthesis in VLSI Realization Objective: Generate Optimal Designs Specifications Circuit Netlist Sequential Optimization Optimized Netlist Tech. Mapping Cell Library Place & Route

  3. Semi-Custom Design Styles Semi-Custom Array-based Cell-based Std. Cells Macro cells Gate-Arrays MPGAs FPGAs PLA Memory Hierarchical Std. Cells

  4. Choice of Design Styles

  5. s1 s2 s0 s3 Design Representations Transformation: • F1 = (A-B)(A+B) • F2 = (C-D)(C+D) • F = x F1 + x’ F2 • Architectural • F1 = A*A – B*B • F2 = C*C – D*D • F = x F1 + x’ F2 • Behavioural Transformations s1 s4 s2 s0 s3

  6. Transformation Criteria • Architectural • Resource Optimization • Latency/Throughput Optimization • Computation Scheduling, Resource Binding • Testability and Verifiability • Behavioural • Logic Area • Gate Delay (timing performance) • Switching & Static Power Dissipation • Testability and Verifiability

  7. Minimization Versus Optimization Area… Delay… • Minimization versus Optimization Trade-offs • Minimize Logic Area, or Delay, or Power…. • Optimize Area within bounded Delays • Optimize Delay within bounded Area • Physical Synthesis: Optimize Area w.r.t. Reliability and Manufacturability

  8. What is Logic Synthesis? • Given: Logic Functions or Finite-State Machines • Automatically generate designs (synthesis) • Minimize or Optimize Logic w.r.t. constraints • Optimally map logic onto realistic gates • Problems and Challenges • Memory: Size! Size!SIZE! • Time: Computationally intensive operations • What kind of representations to use? • How to optimize logic to target the technology?

  9. When Technology was PLAs…. • Two-Level Logic Minimization: K-map type • F = a’bc + ab’c + abc’ + abc • F = ab + ac + bc • Fewer inputs = fewer transistors • Reduced Area AND Reduced Delay • Algorithmic Techniques: • Quine-McCluskey, Espresso, Signature-cubes

  10. Then came CMOS Technology…. • Salient Features: • Very high noise margins • Design Scalability • Enabled Standard Cell-based Design • Abstract Electrical Properties: Area-Delay • Fanout-Drive Scalability: X’sistor Sizing • Low (zero) Static Power Dissipation • Enabled Standard-Cell Place & Route • Estimates: Close to ~10% of actual layout • Cheap, Reliable, Scalable, low turn-aournd time

  11. Multi-Level Logic Synthesis • F = ab + bc + ac • F = b(a + c) + ac • F = ab + c(b + a) • Problem: Area and Delay became dependent • Problem: How do you factorize?

  12. Multi-Level Synthesis for CMOS • Synthesis Issues to consider • Objective: Minimize number of literals (area) • Delay: Depth of paths, fanouts, signal orders, arrival and required times…. • Area  Delay became dependent • Factorization: • Extract common subexpressions • Fanout problems • Routing Difficulties • Optimization (instead of minimization) became the dominant issue

  13. Don’t Cares came into Focus…. • F = a(b+c) • When a = 0, (b + c) = Don’t care • D.C. = a’(b + c)? Not really…. • How to “generate” D.C. set to optimize logic? • Problem: How do you factorize to create a good don’t care set ? • Problem: How to filter “bad” don’t care sets ?

  14. Don’t Cares Computations….. • How to efficiently compute D.C.s and simplify ckt? • Image computations • Controllability and observability DCs • Propagate DC set across the circuit Input DC Image of the DC

  15. Solution: Sequence of Optimizations • Script-based multi-level logic synthesis • Collapse the whole circuit into two-level logic • Apply K-map type two-level minimization • Perform Greedy Factorization • Compute Don’t Cares • Simplify with Don’t cares • Estimate area/delay, re-factorize if needed • Delay minimization: depth minimization, fanout adjustment, transistor sizing, buffer insertion….

  16. s1 s2 s0 s3 Sequential Optimization • Behavioural Transformations s1 s4 s2 s0 s3 • Behavioural Optimizations: • Code assignments: What is there effect on design? • S0 (00), s1(01), s2(10), s3(11) • S0(00), s1(10), s2(01), s3(11)

  17. a b c f 0 0 0 0 0 0 1 0 0 1 0 0 0 1 1 1 1 0 0 0 1 0 1 1 1 1 0 0 1 1 1 1 FPGA-based Logic Synthesis • Look-up Table based FPGAs Look-up Table • Optimizations Criteria: • Input-space Partitioning, Decomposition • Literal minimization does nothing here….. • Routing resources, congestion……

  18. The coming of age of Synthesis…. • Power of multi-level logic synthesis • Two-level minimization: solved! • Good factorization techniques found • Good Boolean Decomposition techniques • Good representations: ROBDDs….. • Don’t care theory well understood • Technological challenges well understood (CMOS, FPGA, PLA, Memories….)

  19. Some Problems Remain…… • Limitations of conventional synthesis techniques • Sequential Optimizations not well understood • Perhaps the problem has become redundant? • Technology specific decomposition still needs some work • Not much support for hierarchical synthesis • No support for across the boundary optimizations • Power optimization at logic-level: NO IDEA!! • Effect of factorization on Placement & routing

  20. New Challenges in Logic Synthesis • The problems of the future….. • Static CMOS: area-delay will become unacceptable • Layout is already becoming unsolvable • Static (leakage) power is increasing • Design granularity…. Large v/s small • Hierarchical synthesis will become a major issue • NOISE! Dynamic logic related….

  21. New Technologies to Synthesize • Dynamic Logic • Problems: Domino logic is monotonic • Charge Sharing, leakage, noise…. • Standard-cell based or macro-cell based? • Pass Transistor Logic (PTL) • All of the above problems • Signal degradation + restoration? s

  22. s1 s2 Need of the Hour: I think…… • Mixed Pass Transistor & Static CMOS Logic • Area reduction due to PTL • Delay reduction due to PTL & CMOS buffers • Signal degradation + restoration can be solved • Challenges: • Factorize to reduce noise • What to map on PTL and what to map on CMOS? CMOS Gate Large fanout

  23. Need of the Future: I think…… • For new technologies, “nano”-type • Area/Delay estimation Rethink • Sequential Optimization will bounce back! • Binary valued logic to Multi-values Logic • Power has to be handled at logic level • Memory no problem…. But computation time…. • Logic optimization for manufacturability….. • Structured Logic Decomposition for estimatable Placement and routing…. • How about “Synthesis for verifiablity” ?

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