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Partial Method Compilation using Dynamic Profile Information

Partial Method Compilation using Dynamic Profile Information. John Whaley Stanford University October 17, 2001. Outline. Background and Overview Dynamic Compilation System Partial Method Compilation Technique Optimizations Experimental Results Related Work Conclusion.

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Partial Method Compilation using Dynamic Profile Information

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  1. Partial Method Compilationusing Dynamic Profile Information John Whaley Stanford University October 17, 2001

  2. Outline • Background and Overview • Dynamic Compilation System • Partial Method Compilation Technique • Optimizations • Experimental Results • Related Work • Conclusion

  3. Dynamic Compilation • We want code performance comparable to static compilation techniques • However, we want to avoid long startup delays and slow responsiveness • Dynamic compiler should be fast AND good

  4. Traditional approach • Interpreter plus optimizing compiler • Switch from interpreter to optimizing compiler via some heuristic • Problems: • Interpreter is too slow! (10x to 100x)

  5. Another approach • Simple compiler plus optimizing compiler (Jalapeno, JUDO, Microsoft) • Switch from simple to optimizing compiler via some heuristic • Problems: • Code from simple compiler is still too slow! (30% to 100% slower than optimizing) • Memory footprint problems (Suganuma et al., OOPSLA’01)

  6. Yet another approach • Multi-level compilation (Jalapeno, HotSpot) • Use multiple compiled versions to slowly “accelerate” into optimized execution • Problems: • This simply increases the delay before the program runs at full speed!

  7. Problem with compilation • Compilation takes time proportional to the amount of code being compiled • Many optimizations are superlinear in the size of the code • Compilation of large amounts of code is the cause of undesirably long compilation times

  8. Methods can be large • All of these techniques operate at method boundaries • Methods can be large, especially after inlining • Cutting inlining too much hurts performance considerably (Arnold et al., Dynamo’00) • Even when being frugal about inlining, methods can still become very large

  9. Methods are poor boundaries • Method boundaries do not correspond very well to the code that would most benefit from optimization • Even “hot” methods typically contain some code that is rarely or never executed

  10. Example: SpecJVM db void read_db(String fn) { int n = 0, act = 0; byte buffer[] = null; try { FileInputStream sif = new FileInputStream(fn); buffer = new byte[n]; while ((b = sif.read(buffer, act, n-act))>0) { act = act + b; } sif.close(); if (act != n) { /* lots of error handling code, rare */ } } catch (IOException ioe) { /* lots of error handling code, rare */ } } Hot loop

  11. Example: SpecJVM db void read_db(String fn) { int n = 0, act = 0; byte buffer[] = null; try { FileInputStream sif = new FileInputStream(fn); buffer = new byte[n]; while ((b = sif.read(buffer, act, n-act))>0) { act = act + b; } sif.close(); if (act != n) { /* lots of error handling code, rare */ } } catch (IOException ioe) { /* lots of error handling code, rare */ } } Lots of rare code!

  12. Hot “regions”, not methods • The regions that are important to compile have nothing to do with the method boundaries • Using a method granularity causes the compiler to waste time optimizing large pieces of code that do not matter

  13. Overview of our technique Increase the precision of selective compilation to operate at a sub-method granularity • Collect basic block level profile data for hot methods • Recompile using the profile data, replacing rare code entry points with branches into the interpreter

  14. Overview of our technique • Takes advantage of the well-known fact that a large amount of code is rarely or never executed • Simple to understand and implement, yet highly effective • Beneficial secondary effect of improving optimization opportunities on the common paths

  15. Overview of Dynamic Compilation System

  16. interpreted code Stage 1: when execution count = t1 compiled code Stage 2: when execution count = t2 fully optimized code Stage 3:

  17. Identifying rare code • Simple technique: any basic block executed during Stage 2 is said to be hot • Effectively ignores initialization • Add instrumentation to the targets of conditional forward branches • Better techniques exist, but using this we saw no performance degradation • Enable/disable profiling is implicitly handled by stage transitions

  18. Method-at-a-time strategy % of basic blocks execution threshold

  19. Actual basic blocks executed % of basic blocks execution threshold

  20. Partial method compilation technique

  21. Technique • Based on profile data, determine the set of rare blocks. • Use code coverage information from the first compiled version

  22. Technique • Perform live variable analysis. • Determine the set of live variables at rare block entry points live: x,y,z

  23. Technique • Redirect the control flow edges that targeted rare blocks, and remove the rare blocks. to interpreter…

  24. Technique • Perform compilation normally. • Analyses treat the interpreter transfer point as an unanalyzable method call.

  25. Technique • Record a map for each interpreter transfer point. • In code generation, generate a map that specifies the location, in registers or memory, of each of the live variables. • Maps are typically < 100 bytes live: x,y,z x: sp - 4 y: R1 z: sp - 8

  26. Optimizations

  27. Partial dead code elimination • Modified dead code elimination to treat rare blocks specially • Move computation that is only live on a rare path into the rare block, saving computation in the common case

  28. Partial dead code elimination • Optimistic approach on SSA form • Mark all instructions that compute essential values, recursively • Eliminate all non-essential instructions

  29. Partial dead code elimination • Calculate necessary code, ignoring all rare blocks • For each rare block, calculate the instructions that are necessary for that rare block, but not necessary in non-rare blocks • If these instructions are recomputable at the point of the rare block, they can be safely copied there

  30. Partial dead code example x = 0; if (rare branch 1) { ... z = x + y; ... } if (rare branch 2) { ... a = x + z; ... }

  31. Partial dead code example if (rare branch 1) { x = 0; ... z = x + y; ... } if (rare branch 2) { x = 0; ... a = x + z; ... }

  32. Pointer and escape analysis • Treating an entrance to the rare path as a method call is a conservative assumption • Typically does not matter because there are no merges back into the common path • However, this conservativeness hurts pointer and escape analysis because a single unanalyzed call kills all information

  33. Pointer and escape analysis • Stack allocate objects that don’t escape in the common blocks • Eliminate synchronization on objects that don’t escape the common blocks • If a branch to a rare block is taken: • Copy stack-allocated objects to the heap and update pointers • Reapply eliminated synchronizations

  34. Copying from stack to heap Heap copy stack object stack object rewrite

  35. Reconstructing interpreter state • We use a runtime “glue” routine • Construct a set of interpreter stack frames, initialized with their corresponding method and bytecode pointers • Iterate through each location pair in the map, and copy the value at the location to its corresponding position in the interpreter stack frame • Branch into the interpreter, and continue execution

  36. Experimental Results

  37. Experimental Methodology • Fully implemented in a proprietary system • Unfortunately, cannot publish those numbers! • Proof-of-concept implementation in thejoeq virtual machine http://joeq.sourceforge.net • Unfortunately, joeq does not perform significant optimizations!

  38. Experimental Methodology • Also implemented as an offline step, using refactored class files • Use offline profile information to split methods into “hot” and “cold” parts • We then rely on the virtual machine’s default method-at-a-time strategy • Provides a reasonable approximation of the effectiveness of this technique • Can also be used as a standalone optimizer • Available under LGPL as part of joeq release

  39. Experimental Methodology • IBM JDK 1.3 cx130-20010626 on RedHat Linux 7.1 • Pentium 3 600 mhz, 512 MB RAM • Thresholds: t1 = 2000, t2 = 25000 • Benchmarks: SpecJVM, SwingSet, Linpack, JavaLex, JavaCup

  40. Run time improvement First bar: original Second bar: PMC Third bar: PMC + my opts Blue: optimized execution

  41. Related Work Dynamic techniques • Dynamo (Bala et al., PLDI’00) • Self (Chambers et al., OOPSLA’91) • HotSpot (JVM’01) • IBM JDK (Ishizaki et al., OOPSLA’00)

  42. Related Work Static techniques • Trace scheduling (Fisher, 1981) • Superblock scheduling (IMPACT compiler) • Partial redundancy elimination with cost-benefit analysis (Horspool, 1997) • Optimal compilation unit shapes (Bruening, FDDO’00) • Profile-guided code placement strategies

  43. Conclusion • Partial method compilation technique is simple to implement, yet very effective • Compile times reduced drastically • Overall run times improved by an average of 10%, and up to 32% • System is available under LGPL at: http://joeq.sourceforge.net

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