Java Virtual Machine

A Java Virtual Machine (JVM) is a set of computer software programs and data structures which implements a specific virtual machine model. This model accepts a form of computer intermediate language, commonly referred to as Java bytecode, which conceptually represents the instruction set of a stack-oriented, capability architecture. This code is most often generated by Java language compilers, although the JVM can also be targeted by compilers of other languages. JVMs using the "Java" trademark may be developed by other companies as long as they adhere to the JVM specification published by Sun (and related contractual obligations). The JVM is a crucial component of the Java Platform. Because JVMs are available for many hardware and software platforms, Java can be both middleware and a platform in its own right — hence the expression "write once, run anywhere." The use of the same bytecode for all platforms allows Java to be described as "compile once, run anywhere", as opposed to "write once, compile anywhere", which describes cross-platform compiled languages. The JVM also enables such unique features as Automated Exception Handling which provides 'root-cause' debugging information for every software error (exception) independent of the source code. The JVM is distributed along with a set of standard class libraries which implement the Java API (Application Programming Interface). The virtual machine and API have to be consistent with each other and are therefore bundled together as the Java Runtime Environment.

Contents 1 Execution environment 2 Bytecode verifier 3 Bytecode instructions 4 Secure execution of remote code 5 C to bytecode compilers 6 Licensing 7 See also 8 Notes 9 References 10 External links

Execution environment

Programs intended to run on a JVM must be compiled into a standardized portable binary format, which typically comes in the form of .class files. A program may consist of many classes in different files. For easier distribution of large programs, multiple class files may be packaged together in a .jar file (short for Java archive). The JVM runtime executes .class or .jar files, emulating the JVM instruction set by interpreting it, or using a just-in-time compiler (JIT) such as Sun's HotSpot. JIT compiling, not interpreting, is used in most JVMs today to achieve greater speed. Like most virtual machines, the Java Virtual Machine has a stack-based architecture

Bytecode verifier

A basic philosophy of Java is that it is inherently "safe" from the standpoint that no user program can "crash" the host machine or otherwise interfere inappropriately with other operations on the host machine, and that it is possible to protect certain functions and data structures belonging to "trusted" code from access or corruption by "untrusted" code executing within the same JVM. Furthermore, common programmer errors that often lead to data corruption or unpredictable behavior (accessing off the end of an array, using an uninitialized pointer, etc) are not allowed to occur. Several features of Java combine to provide this safety, including the class model, the garbage-collected heap, and the verifier. The JVM verifies all bytecode before it is executed. This verification consists primarily of three types of checks:

• Branches are always to valid locations
• Data is always initialized and references are always type-safe
• Access to "private" or "package" data and methods is rigidly controlled.

The first two of these checks take place primarily during the "verification" step which occurs when a class is loaded and made eligible for use. The third is primarily performed dynamically, when data items or methods of a class are first accessed by another class. The verifier permits only some bytecode sequences in valid programs, e.g. a jump (branch) instruction can only target an instruction within the same function or method. Because of this, the fact that JVM is a stack architecture does not imply a speed penalty for emulation on register-based architectures when using a JIT compiler. In the face of the code-verified JVM architecture, it makes no difference to a JIT compiler whether it gets named imaginary registers or imaginary stack positions that need to be allocated to the target architecture's registers. In fact, code verification makes the JVM different from a classic stack architecture whose efficient emulation with a JIT compiler is more complicated and typically carried out by a slower interpreter. Code verification also ensures that arbitrary bit patterns cannot get used as an address. Memory protection is achieved without the need for a MMU. Thus, JVM is an efficient way of getting memory protection on simple architectures that lack a MMU. This is analogous to managed code in Microsoft's .NET CLR, and conceptually similar to capability architectures such as the Plessey 250, and IBM System/38.

Bytecode instructions

Main article: Java bytecode

The JVM has instructions for the following groups of tasks:

• Load and store
• Arithmetic
• Type conversion
• Object creation and manipulation
• Operand stack management (push / pop)
• Control transfer (branching)
• Method invocation and return
• Throwing exceptions
• Monitor-based concurrency

The aim is binary compatibility. Each particular host operating system needs its own implementation of the JVM and runtime. These JVMs interpret the byte code semantically the same way, but the actual implementation may be different. More complicated than just the emulation of bytecode is compatible and efficient implementation of the Java core API which has to be mapped to each host operating system.

Secure execution of remote code

A virtual machine architecture allows very fine-grained control over the actions that code within the machine is permitted to take. This is designed to allow safe execution of untrusted code from remote sources, a model used by Java applets. Applets run within a VM incorporated into a user's browser, executing code downloaded from a remote HTTP server. The remote code runs in a restricted "sandbox", which is designed to protect the user from misbehaving or malicious code. Publishers can purchase a certificate with which to digitally sign applets as "safe", giving them permission to ask the user to break out of the sandbox and access the local file system and network...

C to bytecode compilers

Compilers exist that can translate C code to Java bytecode so that it can be run on a JVM. The Java Virtual Machine was originally designed to execute programs written in the Java language. However, the JVM provides an execution environment in the form of a bytecode instruction set and a runtime system that is general enough that it can be used as the target of for compilers of other languages. Because of its close association with Java the JVM performs the runtime checks mandated by the Java specification. This can make it technically difficult to translate C code (which is much more lax with regard to runtime checking) to the JVM and expect it to run without issuing any warnings. Compilers for hundreds of languages other than C exist, including Ada, and COBOL, allowing program written in these languages to run on the JVM.

Licensing

Starting with J2SE 5.0, changes to the JVM specification have been developed under the Java Community Process as JSR 924^[1]. As of 2006, changes to specification to support changes proposed to the class file format (JSR 202^[2]) are being done as a maintenance release of JSR 924. The specification for the JVM is published in book form,^[3] known as "blue book". The preface states:

We intend that this specification should sufficiently document the Java Virtual Machine to make possible compatible clean-room implementations. Sun provides tests which verify the proper operation of implementations of the Java Virtual Machine.

Sun's JVM is called HotSpot. Clean-room Java implementations include Kaffe and IBM J9. Sun retains control over the Java trademark, which it uses to certify implementation suites as fully compatible with Sun's specification.

See also

• HotSpot
• List of Java virtual machines
• Java Runtime Environment
• Automated Exception Handling
• Common Language Runtime
• Parrot virtual machine
• Java bytecode
• Class (file format)
• Java performance
• List of compilers

Notes

References

External links

• The Java Virtual Machine Specification
• Java-Virtual-Machine.net - All about Java Virtual Machines!
• List of languages which compile to the Java virtual machine.
• A decade after Java arrived, there have been improvements in the runtime performance of platform-independent virtual-machine based software.
• Kaffe.org - the Kaffe project
• JamVM - The Jam Virtual Machine
• The lean, mean, virtual machine - An introduction to the basic structure and functionality of the Java Virtual Machine
• Java Glossary - installing Java useful tips for installing Java for users and developers
• Test your Java Virtual Machine
• A list of Java VM-s used in mobile devices
• Languages for the JVM
• More Languages for the JVM

•  • e Java Virtual Machines
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•  • e Java
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