1. Buffered dynamic run-time profiling of arbitrary data for Virtual Machines which employ interpreter and Just-In-Time (JIT) compiler Compiler workshop ’08 Nikola Grcevski, IBM Canada Lab

2. Agenda The motivation and the importance of profiling Design and implementation of J9 VM interpreter profiler Performance results and start-up overhead

3. The static vs. dynamic compiler Static compilers can take their time to analyze the code - perform intra procedural analysis Dynamic Just-In-Time compilers don’t have this luxury, compilation happens during application runtime Can dynamic compilers ever produce quality optimized code comparable to static compilers?

4. Why profile? The whole category of speculative optimizations relies on some type of profiling information Opens up opportunities for new code and memory optimizations Critical for high performance dynamic compiler systems

5. What could we profile? Pretty much anything that we expect will provide repeatable information that we can use to optimize The profiling can be at the Java level or CPU level if the OS supports it.

6. What kind of profilers does J9 have JIT profiler –Instruments methods with various profiling hooks –Targeted only to methods that are very hot –Temporal and slows down execution Interpreter profiler –The topic of this presentation

7. What kinds of data we collect with the interpreter profiler? Branch direction Virtual/Interface call targets Switch statement index Instanceof and checkcast runtime types

8. Interpreter profiler design Buffered approach to data collection on the application threads ……. Application Thread 1 Application Thread N if vcall if vcall icall if switch mul add div

9. Interpreter profiler design Buffer full event triggers processing of the data by the JIT ……. Application Thread 1 if vcall if switch if Buffer full event JIT runtime

10. Interpreter profiler design JIT parses the application thread profiling buffer and builds internal profiling data structure JIT runtime JIT profiling hashtable data Bytecode program counter Profiling buffer Hash function based on bytecode PC

11. What’s in the data we collect? Bytecode program counter Variable size data packet –1 byte for branch direction –Word size for call targets and runtime types –4 bytes for switch index

12. Processing the buffered branch information We create an object to hold the bytecode PC and branch counts. We are using 4 bytes to store the branch information. pc; taken | not taken

13. What does the JIT do with the call information? We keep up to 3 call targets with their counts as well as residue count pc; Class A; Class B; Class C; count We use the same approach for checkcast and instanceof residue

14. What does the JIT do with the switch information? We create a data structure to hold the bytecode PC and counts for switch index. The index data is 8 bytes wide, split into 4 records: the top 3 and the rest. pc; record 1record 2record 3The rest count | index each record is split into 2 portions: 1 byte count and 1 byte switch index

15. Storing the profiling data Each data record is stored in global hashtable, using the PC for the hash function On subsequent encounters of the same PC with profiling data the records are updated. – Branch and switch counts are incremented – Call targets and runtime types are added and counts incremented.

16. Using the profiling information The profiler database only knows of bytecode PC At all points where the compiler is interested in profiling information it generates the bytecode pc from the method information and the bytecode index The compiler has to make sense out of the information in the hashtable

17. Interpreter profiler design JIT compiler consults the profiling hashtable in various stages of method compilation JIT profiling hashtable ……. Compilation Thread inliner order code codegen

18. Performance results Up to 30% improvement on various applications –EJB and other middleware applications benefit mostly from code ordering and devirtualization for the purpose of inlining –Benchmarks typically benefit from other optimization enabled by the ability to devirtualize virtual and interface calls With various tweaks we managed to drive the start-up over head to below 10%

19. How do we manage the profiling overhead? We turn the profiler off in –Xquickstart mode No locking on the hashtable We detect startup phase of the application and skip records to ease off the data collection overhead

20. Turning the profiler ON and OFF The profiler is ON by default The sampler thread turns the profiler OFF or back ON –Number of consecutive ticks in JIT generated code turns the profiler OFF –Number of consecutive ticks in interpreter turns the profiler back ON

21. Some of the problems we encountered Tuning for optimal balance between startup overhead and throughput performance wasn’t easy Application phase change detection wasn’t easy Class unloading created lots of problems

22. Summary Profiling is critical for performance of run-time systems Using buffered approach to data collection can help build efficient profilers Tuning for optimal balance of startup overhead and throughput performance is challenging