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Alta Operating System: Enhancing Java Virtual Machine Process Management and Resource Sharing

The Alta Operating System is designed to operate within the Java Virtual Machine, enabling efficient management of multiple applications on a single JVM. It implements the Fluke OS nested process model, allowing for safe and controlled process interactions. The thesis explores how to redefine protection mechanisms in an OS and facilitate reliable sharing among Java processes. By maintaining the illusion of a complete JVM while providing flexible type spaces and inter-process communication, Alta aims to enhance resource management and performance while ensuring backward compatibility with existing Java applications.

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Alta Operating System: Enhancing Java Virtual Machine Process Management and Resource Sharing

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  1. The Alta Operating System Patrick Tullmann Masters Thesis Defense University of Utah

  2. Alta • Alta is an operating system in aJava Virtual Machine • Manages multiple applications on a single JVM • Supports the Fluke OS nested process model (NPM)

  3. Research Goals • Can I change the protection mechanism in an OS model? • Can I provide safe, controlled sharing between Java processes?

  4. UT NV Uniglobe Morris Public Area Registered Agents Airline Database Motivation: Servlet Engine

  5. Motivation • Java Virtual Machine provides: • Safety • Platform independence • Java-based systems need: • Multiple “user” management • Resource management • Flexible & extensible control

  6. Approach • Traditional OS a good model • Hardware provides safety mechanism • OS provides management • Fluke OS nested process model

  7. Fluke Background • Microkernel • Threads, mutexes, IPC, … • Manages CPU and memory • User-level services • File, Network, … • Nested process model • Structured • Well defined

  8. 1 2 Child A Child B Parent Process Nested Process Model • A model of how processes interact • Hierarchical: parent process provides resources

  9. Mapping an OS into Java • Type safety replaces hardware page protections • Bytecodes replace simple instructions • Native methods replace privileged instructions • All higher-level abstractions are equivalent

  10. Goals for Alta • Support Fluke features for process management • Mimic Fluke structure • Provide parent process with control • Acceptable performance • Maintain backwards compatibility • Existing Java apps should work

  11. Design of Alta • Four design aspects (really seven) • Maintain “whole JVM” illusion • Per-process, flexible typespaces • Inter-process sharing • Sharing & resource control • IPC-based interfaces • Exportable kernel state • Kernel implementation

  12. Design of Alta • Four design aspects • Maintain “whole JVM” illusion • Per-process, flexible typespaces • Inter-process sharing • Sharing & resource control

  13. Design of Alta • Four design aspects • Maintain “whole JVM” illusion • Per-process, flexible typespaces • Inter-process sharing • Sharing & resource control

  14. Per-process Typespaces • Typespace: Set of name to class bindings in a process • Extension of the NPM to Java • Parent process resolves all class names • Enables access controls • Enables code control in child process • Problems with native methods • Poses problems for sharing

  15. Per-process Typespaces • Implies class has no fixed name • Implies there can be inconsistencies • Different notion of ‘File’ • Same notion of ‘Directory’

  16. Design of Alta • Four design aspects • Maintain “whole JVM” illusion • Per-process, flexible typespaces • Inter-process sharing • Sharing & resource control

  17. Inter-process Sharing • Alta allows limited inter-process sharing • Initial sharing via IPC • Sharing through other shared objects • Processes can have inconsistent types • Inter-process type inconsistencies can destroy a JVM • pointer forging

  18. Inter-process Type Checking • Alta ensures equivalent types for all shared objects • Effective limits on shareable types: • Completely consistent field types • Only allows non-polymorphic fields

  19. Design of Alta • Four design aspects • Maintain “whole JVM” illusion • Per-process, flexible typespaces • Inter-process sharing • Sharing & resource control

  20. Sharing & Resource Control • Sharing complicates resource control • Termination of process that has “exported” objects • Alta lets applications control sharing • Nested process model enables constrained sharing

  21. User-level Shared Objects • Child allocates -> Parent references • Harmless. If parent dies then child dies • Useful. Child can pass IPC arguments • Sibling allocates -> Sibling references • Allowable. Parent trades communication costs for separation • Parent allocates -> Child references • Standard server behavior • Cannot deallocate without child’s cooperation

  22. Results & Evaluation • Micro-benchmark measurements • Comparison with Fluke • Structure • Performance

  23. Platform • Base system • Kaffe Java virtual machine • Platform • Measurements from a 300 Mhz PII • Java code is JIT compiled

  24. Micro-benchmarks • Alta vs. Kaffe • Basic VM operations are ~ unchanged • 50-100 cycle overhead on object allocation • Kaffe/Alta vs. Microsoft JVM • Three (or more) times slower

  25. Alta vs. Fluke: Structure • Use similar internal organization • Both implement a “red line” [Back 1999] • Fully preemptible kernel • Alta allows kernel / user data sharing • Alta’s kernel is almost malloc-less • Except some JVM-internal structures

  26. Alta vs. Fluke: Performance • Alta wins: • Null system call • 192 cycles (vs. 302 in Fluke) • Optimal thread switch • 185 cycles (vs. 519 in Fluke) • Fluke wins everything else, e.g., • Null IPC round trip • 18,524 cycles (64 µs) vs. 7,519 cycles in Fluke • Process creation: • ~11.9M cycles (39 ms) vs. 1M cycles in Fluke

  27. Performance Evaluation • Alta hampered by poor JIT compiler • GCJ will improve this • Alta kernel is C-like • HotSpot, etc provide interesting opportunities • Alta can be optimized, too • Static definition of a typespace • Better kernel synchronization • Incorporate recent Fluke optimizations

  28. Related Work: Java • [Balfanz 1998], [Bernadat 1998], [Sun 1998] • J-Kernel [Hawblitzel 1998] • Pure Java • No inter-process sharing • KaffeOS [Back 1999] • More restrictive sharing • Resource management focus • Per-process heaps • GC time accounting • ...

  29. Related Work: OS • Pilot / Cedar / Mesa [Redell 1980], [Swinehart 1986] • Oberon / Juice [Franz 1996] • Inferno [Dorward 1998] • SPIN [Bershad 1995] • Vino [Seltzer 1996]

  30. Future Work • Resource accounting & GC • Formal analysis of Alta type system • Fluke & Alta integration • Alta-specific applications

  31. Contributions • Alta demonstrates applicability of OS abstractions to Java • The Fluke NPM with a different protection mechanism • Multiple application support in a JVM • Type-safe sharing between inconsistent typespaces

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