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Capriccio: Scalable Threads for Internet Services

Capriccio: Scalable Threads for Internet Services. Rob von Behren, Jeremy Condit, Feng Zhou, Geroge Necula and Eric Brewer University of California at Berkeley Presenter: Olusanya Soyannwo. Outline. Motivation Background Goals Approach Experiments Results Related work

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Capriccio: Scalable Threads for Internet Services

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  1. Capriccio: Scalable Threads for Internet Services Rob von Behren, Jeremy Condit, Feng Zhou, Geroge Necula and Eric Brewer University of California at Berkeley Presenter: Olusanya Soyannwo

  2. Outline • Motivation • Background • Goals • Approach • Experiments • Results • Related work • Conclusion & Future work EECS Advanced Operating Systems Northwestern University

  3. Motivation • Increasing scalability demands for Internet services • Hardware improvements are limited by existing software • Current implementations are event based EECS Advanced Operating Systems Northwestern University

  4. Background : Event Based Systems - Drawbacks • Events systems hide the control flow • Difficult to understand and debug • Programmers need to match related events • Burdens programmers EECS Advanced Operating Systems Northwestern University

  5. Goals: Capriccio • Support for existing thread API • Scalability to hundreds of thousands of threads • Automate application-specific customization EECS Advanced Operating Systems Northwestern University

  6. Approach: Capriccio • Thread package • Cooperative scheduling • Linked stacks • Address the problem of stack allocation for large numbers of threads • Combination of compile-time and run-time analysis • Resource-aware scheduler EECS Advanced Operating Systems Northwestern University

  7. Approach: User Level Thread – The Choice • POSIX API (-)Complex preemption (-)Bad interaction with Kernel scheduler • Performance • Ease thread synchronization overhead • No kernel crossing for preemptive threading • More efficient memory management at user level • Flexibility • Decoupling user and kernel threads allows faster innovation • Can use new kernel thread features without changing application code • Scheduler tailored for applications EECS Advanced Operating Systems Northwestern University

  8. Approach: User Level Thread – Disadvantages • Additional Overhead • Replacing blocking calls with non-blocking calls • Multiple CPU synchronization EECS Advanced Operating Systems Northwestern University

  9. Approach: User Level Thread – Implementation • Context Switches • Built on top of Edgar Toernig’s coroutine library • Fast context switches when threads voluntarily yield • I/O • Capriccio intercepts blocking I/O calls • Uses epoll for asynchronous I/O • Scheduling • Very much like an event-driven application • Events are hidden from programmers • Synchronization • Supports cooperative threading on single-CPU machines • Requires only Boolean checks EECS Advanced Operating Systems Northwestern University

  10. Approach: Linked Stack • The problem: fixed stacks • Overflow vs. wasted space • Limits thread numbers • The solution: linked stacks • Allocate space as needed • Compiler analysis • Add runtime checkpoints • Guarantee enough space until next check Fixed Stacks Linked Stack EECS Advanced Operating Systems Northwestern University

  11. Approach: Linked Stack • Parameters • MaxPath • MinChunk • Steps • Break cycles • Trace back • Special Cases • Function pointers • External calls 3 3 2 5 2 4 3 6 MaxPath = 8 EECS Advanced Operating Systems Northwestern University

  12. Approach: Linked Stack • Parameters • MaxPath • MinChunk • Steps • Break cycles • Trace back • Special Cases • Function pointers • External calls 3 3 2 5 2 4 3 6 MaxPath = 8 EECS Advanced Operating Systems Northwestern University

  13. Approach: Linked Stack • Parameters • MaxPath • MinChunk • Steps • Break cycles • Trace back • Special Cases • Function pointers • External calls 3 3 2 5 2 4 3 6 MaxPath = 8 EECS Advanced Operating Systems Northwestern University

  14. Approach: Linked Stack • Parameters • MaxPath • MinChunk • Steps • Break cycles • Trace back • Special Cases • Function pointers • External calls 3 3 5 2 2 4 3 6 MaxPath = 8 EECS Advanced Operating Systems Northwestern University

  15. Approach: Linked Stack • Parameters • MaxPath • MinChunk • Steps • Break cycles • Trace back • Special Cases • Function pointers • External calls 3 3 2 3 2 4 3 6 MaxPath = 8 EECS Advanced Operating Systems Northwestern University

  16. Approach: Scheduling • Advantages of event-based scheduling • Tailored for applications • With event handlers • Events provide two important pieces of information for scheduling • Whether a process is close to completion • Whether a system is overloaded EECS Advanced Operating Systems Northwestern University

  17. Approach: Scheduling -The Blocking Graph • Thread-based • View applications as sequence of stages, separated by blocking calls • Analogous to event-based scheduler Sleep Read Write Close Main Threadcreate Write EECS Advanced Operating Systems Northwestern University

  18. Approach: Resource-aware Scheduling • Track resources used along BG edges • Memory, file descriptors, CPU • Predict future from the past • Algorithm • Increase use when underutilized • Decrease use near saturation • Advantages • Operate near the knee w/o thrashing • Automatic admission control EECS Advanced Operating Systems Northwestern University

  19. Experiment: Threading Microbenchmarks • SMP, two 2.4 GHz Xeon processors • 1 GB memory • two 10 K RPM SCSI Ultra II hard drives • Linux 2.5.70 • Compared Capriccio, LinuxThreads, and Native POSIX Threads for Linux EECS Advanced Operating Systems Northwestern University

  20. Experiment: Thread Scalability • Producer-consumer microbenchmark • LinuxThreads begin to degrade after 20 threads • NPTL degrades after 100 • Capriccio scales to 32K producers and consumers (64K threads total) EECS Advanced Operating Systems Northwestern University

  21. Results: Thread Primitive - Latency EECS Advanced Operating Systems Northwestern University

  22. Results: Thread Scalability EECS Advanced Operating Systems Northwestern University

  23. Results: I/O performance • Network performance • Token passing among pipes • Simulates the effect of slow client links • 10% overhead compared to epoll • Twice as fast as both LinuxThreads and NPTL when more than 1000 threads • Disk I/O comparable to kernel threads EECS Advanced Operating Systems Northwestern University

  24. Results: Runtime Overhead • Tested Apache 2.0.44 • Stack linking • 73% slowdown for null call • 3-4% overall • Resource statistics • 2% (on all the time) • 0.1% (with sampling) • Stack traces • 8% overhead EECS Advanced Operating Systems Northwestern University

  25. Results: Web Server Performance EECS Advanced Operating Systems Northwestern University

  26. Related Work • Programming Model of high concurrency • Event based models are a result of poor thread implementations • User-Level Threads • Capriccio is unique • Kernel Threads • NPTL • Application Specific Optimization • SPIN & Exokernel • Burden on programmers • Portability • Asynchronous I/O • Stack Management • Using heap requires a garbage collector (ML of NJ) EECS Advanced Operating Systems Northwestern University

  27. Related Work (cont’d) • Resource Aware Scheduling • Several similar to capriccio

  28. Future Work • Threading • Multi-CPU support • Kernel interface • (enabled) Compile-time techniques • Variations on linked stacks • Static blocking graph • Scheduling • More sophisticated prediction EECS Advanced Operating Systems Northwestern University

  29. Conclusion • Capriccio simplifies high concurrency • Scalable & high performance • Control over concurrency model • Stack safety • Resource-aware scheduling • Enables compiler support, invariants • Issues • Additional burden to programmer • Resource controlled sched.? What hysteresis? EECS Advanced Operating Systems Northwestern University

  30. OTHER GRAPHS

  31. OTHER GRAPHS

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