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Processor Pipelines and Static Worst-Case Execution Time Analysis

Processor Pipelines and Static Worst-Case Execution Time Analysis. PhD dissertation by: Jakob Egblom Presented by: Sibin Mohan. Introduction. Worst-Case Execution Time (WCET) Timing Analysis Experimental vs Static Analysis Processor Pipelines. Pipelines. Various types of pipelines:

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Processor Pipelines and Static Worst-Case Execution Time Analysis

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  1. Processor Pipelines and Static Worst-Case Execution Time Analysis PhD dissertation by: Jakob Egblom Presented by: Sibin Mohan Sibin Mohan : Systems Group Seminar

  2. Introduction • Worst-Case Execution Time (WCET) • Timing Analysis • Experimental vs Static Analysis • Processor Pipelines Sibin Mohan : Systems Group Seminar

  3. Pipelines • Various types of pipelines: • Simple scalar pipelines • Scalar pipelines • Superscalar in-order pipelines • VLIW ( Very Long Instruction Word ) • Superscalar out-of-order pipelines Sibin Mohan : Systems Group Seminar

  4. Goals of this work • Design a static WCET tool. • WCET tool must be : • Retargetable • Flexible • Efficient • Broad applicability • Correctness Sibin Mohan : Systems Group Seminar

  5. WCET Overview • Components of WCET Analysis: • Flow Analysis • Global low-level analysis • Local low-level analysis • Calculation Sibin Mohan : Systems Group Seminar

  6. Flow Analysis • Analyze source/object code • Determine possible flow in program • i.e. dynamic behavior of program • Computationally intractable • approximate analysis used. • Three stages : • flow determination • flow representation • preparation for calculation. Sibin Mohan : Systems Group Seminar

  7. Low Level Analysis • Global low-level analysis: • whole program/large parts of it • eg. : cache behaviour/branch prediction • approximate & safe analysis used • can integrate results in two ways: • assign execution time penalty • use as input to local low-level analysis. Sibin Mohan : Systems Group Seminar

  8. Low Level Analysis ( contd. ) • Local low-level analysis : • machine timing of single instructions • egs. : pipeline overlap/memory access • assign execution times to instructions • pipeline overlap -> negative times • overlaps between basic blocks • not necessarily neighbours. Sibin Mohan : Systems Group Seminar

  9. Calculation • Tree-based • Path-based • IPET ( Implicit Path Enumeration ) • Parameterized WCET calculation. Sibin Mohan : Systems Group Seminar

  10. Program Source Manual Annotations i/p data specs Scope Graph Compiler Flow Analysis WCET Calculation Global low-level Analysis Object Code Timing Model Local low-level Analysis WCET Tool Architecture Sibin Mohan : Systems Group Seminar

  11. Local low-level Analysis Scope Graph Object Code Construction of Timing Graph Timing Graph Timing Model CPU Simulator Pipeline Analysis WCET Tool Architecture (contd.) Sibin Mohan : Systems Group Seminar

  12. Timing Model • Abstract representation • Capture exec. time of program • Model timing effects of Pipeline • Compose from smaller parts • Store concrete execution times • Based on timing graph. Sibin Mohan : Systems Group Seminar

  13. Timing Model (contd.) I1…Im – sequence of instructions T( I1…Im ) – time for above instructions Let T(I) = tI – exec time of single instruction To capture pipeline effects, define: Timing effects, Hence, execution time, is: Sibin Mohan : Systems Group Seminar

  14. Timing Model ( contd. ) Sibin Mohan : Systems Group Seminar

  15. Pipeline Model • Single in-order pipeline • n pipeline stages • Each instruction, i, : • sequence of r1i…rni • rji corresponds to execution in stage j • One instruction per stage • All instructions use all stages Sibin Mohan : Systems Group Seminar

  16. Pipeline Model ( contd. ) • Consider execution of I1…Im • For instruction Ii, • let pji – point when Ii enters stage j • and pn+1i is when Ii leaves stage j • This can be modeled as: Sibin Mohan : Systems Group Seminar

  17. Pipeline Model ( contd. ) • Constraints represented as: • Weighted acyclic graph. Sibin Mohan : Systems Group Seminar

  18. Pipeline Model ( contd. ) : Branches and Data Dependences • Branch Instructions : • Data Dependences : Sibin Mohan : Systems Group Seminar

  19. Multiple Parallel Pipelines • Not all instructions use all stages • Each instruction will have: • points corresponding to its entry • points showing actual stages used • The following functions are used : • previ(i,j), nexti(i,j) • prev and next instructions using stage j • prevs(i,j), nexts(i,j) • prev and next stages used by I Sibin Mohan : Systems Group Seminar

  20. Multiple Parallel Pipelines ( contd. ) • Reformulated constraints : • Acyclic Graph : Sibin Mohan : Systems Group Seminar

  21. Prototype • No automatic flow analysis • No global low-level analysis • Two CPU Models : • V580E • ARM 9 • Two calculation modules : • IPET based • Path-based • Cache Analyse implemented • But, not used. • Generates WCET estimates. Sibin Mohan : Systems Group Seminar

  22. Results Sibin Mohan : Systems Group Seminar

  23. Results ( contd. ) Sibin Mohan : Systems Group Seminar

  24. Conclusions • Contributions : • Formal mathematical model • hardware models • low-level timing modeling scheme • Timing Analysis method • Overall Tool architecture Sibin Mohan : Systems Group Seminar

  25. Thank You ! Further Questions ? Sibin Mohan : Systems Group Seminar

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