Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

What the differences between classical compilation model (C, C++, etc.) and the Java compilation model?

share|improve this question
1  
Well, do you know C or C++? –  Kerrek SB Nov 28 '11 at 15:08
    
what? you mean the difference between compiling to machine code vs compiling to jvm bytecode? elaborate. –  MK. Nov 28 '11 at 15:08
5  
Is this homework? It looks as though you've stopped in the middle of your sentence, and starting typing a new one, i.e. copied from a question list. –  Doug Moscrop Nov 28 '11 at 15:09
4  
@iMohammad: you got it backwards. C is the backbone of programming, used on every machine to provide the fundamentals. Java is only available on a small subset of computers. –  Cheers and hth. - Alf Nov 28 '11 at 15:13
1  
@iMohammad: Java actually does not run on "every kind of machine on Earth." In order for Java to run on a particular platform, there needs to be a Virtual Machine written for that platform, or a Java compiler capable of creating machine code from Java byte code for that platform. –  John Dibling Nov 28 '11 at 15:29
show 7 more comments

7 Answers

up vote 10 down vote accepted

A proper answer to your question could take several hundred pages to answer, but I'll try to sum it up in a few paragraphs.

Basically, the "classic compilation model" you refer to takes as input human-written source code and emits machine code, which can be loaded and run without further translation of the machine code. One ramification of this is that the resulting machine code can only be run on compatible hardware and can only be run within a compatible operating system.

The Java compilation model takes human-written source code as input and emits not machine code, but so-called "byte code". Byte code cannot be directly executed on a machine. Instead, it needs to be translated once again by another compiler to machine code, or interpreted on-the-fly by a device that executes instructions on the machine that correspond to the instructions in the byte code. The latter device is often referred to as a Virtual Machine. One ramification of this model is that the byte code can be "run" on any platform that has either a byte code compiler or virtual machine written for it. This gives Java the appearance and effect of complete portability, where there is no such portability implied by the machine code emitted by a C++ compiler stack.

share|improve this answer
5  
How wise of you not to discuss any performance effects of byte code vs. machine code compilation ;) –  larsmans Nov 28 '11 at 15:16
1  
@larsmans: Yeah, I definitely did not want to go down that road. :) –  John Dibling Nov 28 '11 at 15:18
1  
@JohnDibling Not really. There are some special tools that generate machine code, but those are rarely used. The usual java compilers (javac, eclipse,..) can't generate anything other than bytecode and aren't very sophisticated at all. Also since the result of those java->native compilers isn't a valid java program afterwards, I'm not sure "java compiler" really fits. Hmm. –  Voo Nov 28 '11 at 15:30
1  
There are such compilers, don't know if they're all obsolete, and there were also chips to run bytecode on hardware, which are also obsolete. The fad is over and the language still retains a huge niche, but Sun explored every avenue. –  Potatoswatter Nov 28 '11 at 15:36
2  
@iMohammad: Java is not the only language that utilizes a compilation model that results in Byte Code and employs virtual machines. All the .NET languages use a very similar technique. Conversely, C++ is not the only language that compiles directly to machine code. FORTRAN is another. (gah! did I just date myself?) –  John Dibling Nov 28 '11 at 20:33
show 8 more comments

Two aspects play into the C (and C++) compilation model. One is its longer history than Java, meaning that it caters to very low-powered compilers and machines. The second is the compilation target, which is usually low-level machine code.

To target low-memory compiler environments, C code must be readable from top to bottom, with no backtracking. This means that you have to follow a strict discipline for the order of declarations. (C++ relaxes this a little bit for class definitions.) Further more, each source file must be compilable as an independent translation unit which need not know anything about other source files.

Second, because C targets low-level machine code, this means that each translation unit contains essentially no metadata, in stark contrast to Java class files. This necessitates a stronger coding discipline in which each translation unit must be provided with the necessary declarations. The compiler cannot just scan all the other files in order to get the required information; it is up to the user to supply it. (C++ enforces this more rigidly, in C you can get away with nasty errors by forgetting a declaration.)

Bear in mind that a C program has to be fully compiled and linked at compile time, so a lot of information has to be available already at that point. Java programs can load classes at runtime, and Java execution generally performs more "fitting" operations (casting, essentially, as opposed to static linking in C) at runtime. The more sophisticated runtime environment of Java allows for a more flexible and modular compilation model.

share|improve this answer
    
I think this response adds valuable input. –  John Dibling Nov 28 '11 at 15:21
    
"Bear in mind that a C program has to be fully compiled and linked at compile time" Not absolutely true, since we can do loading at runtime in C/C++ as well. Also clang shows that you can work around some of the mentioned limitations, but it's probably save to assume "classical compilation" really means the conventional approach. +1 still, good summary - if we wanted to cover everything possible here that'd take way too much space. –  Voo Nov 28 '11 at 15:27
    
@Voo: well, it's of course possible to write an entirely different compiler that has a different compilation model. That said, the C standard does mandate quite a bit of the behaviour I describe. Runtime linking doesn't really matter for the discussion, I'd say, as it isn't related to the compilation model. (E.g. see this post.) –  Kerrek SB Nov 28 '11 at 15:29
    
@Kerrek Fair enough, this gets into a rather esoteric area but I see your point. –  Voo Nov 28 '11 at 15:39
    
@Voo: Another way to see why dynamic linking is not pertinent: DL is an opaque library-provided service that you invoke explicitly. It's not transparent. The only things that matter for the compilation model are the different ways in which a compiler can take the same piece of source code and produce a running program (e.g. compile-time vs load-time linking). –  Kerrek SB Nov 28 '11 at 15:41
show 2 more comments

I am going to be brave and compare performance. ;)

The Java compiler javac does little optimisation preferring to syntax check code. It does all the reasonable checks required to ensure it will run on a JVM, and some constant evaluation and that's about it.

Most of the smart compilation is done by the JIT which can perform dynamic complication based on how the program is used. This allows it to inline "virtual" methods, for example, even if the caller and callee are in different libraries.

The C/C++ compiler performs significant static analysis up front. This means a program will run at almost full speed right from the start. The CPU performs some dynamic optimisation with instruction re-ordering and branch prediction. While C/C++ lacks dynamic optimisation, it gains from by making low level access to the system much easier. (Its usually not impossible in Java, but low level operations which are trivial in C/C++ can be complex and obscure in Java) It also provides more ways to do the same thing allowing you to choose the optimal solution to your problem.

When Java is likely to be faster.

  • If your style of programming suits Java and you only use the sort of features Java supports, Java is likely to be marginally faster (due to dynamic compilation) i.e. you wouldn't use C/C++ to their full potential anyway.
  • If your code contains lots of dead code (possibly only known to be dead at run time) Java does a good job at eliminating this. (IMHO A high percentage of micro-benchmarks which suggest Java is faster than C++ are of this type)
  • You have a very limited time and/or resources to implement your application. (In which case an even higher level language might be better) i.e. You don't have time to optimise your code much and you need to write safe abstracted code.

When C/C++ is likely to be faster.

  • If you use most of the functionality C/C++ provides. Something more advanced programmers tend to do.
  • If startup time matters.
  • If you need to be creative about algorithms or data structures.
  • If you can exploit a low level hardware feature, like direct access to devices.
share|improve this answer
add comment

For short, "classical" compilation (which is a temp term provided by the material because they don't have a real word for it), is basically compiling against a real device (in our case a machine with a physical processor). Instead, Java compiles to code against a virtual device, which is software installed on a machine. The virtual device is what changes and targets the real machine.

In this way your hardware is abstracted. This is why Java can work on "any" machine.

share|improve this answer
    
I'm not sure any of these answers actually address the compilation model -- we're all talking about what the compilers emit. Surely by model, we're also referring to the process by which emission occurs, such as the difference in compilation units? Not to mention that a certain Java compiler can emit machine code if it wants. –  Doug Moscrop Nov 28 '11 at 15:19
    
@Doug I'm certain the material that he collected this question from (by referring to "classical vs. Java" is exactly concerned with machine vs. virtual code. The fact that you pointed out that a Java compiler can emit machine code, pretty much validates my point. –  Lee Louviere Nov 28 '11 at 15:22
add comment

Basically, there are two kinds of magic. Machine magic is only understood by certain wizards. JVM Bytecode magic is understood by a special kind of wizard that you have to hire in order to make the machine wizard able to cast spells that make your computer do things. C and C++ compilers generally emit the machine kind, whereas Java compilers emit JVM Bytecode.

share|improve this answer
1  
-1 For targeting idiots. You inadvertently targeted less people by using references to stuff some people won't know about. –  Lee Louviere Nov 28 '11 at 15:16
1  
I was trying to add some fun to everyone's Monday morning. I'm sorry that I offended you. I will up your answer as a penance for my sins against SeriousBusiness(tm) –  Doug Moscrop Nov 28 '11 at 15:22
    
Didn't offend me. It just doesn't need to be anywhere near the top. I wish I could neg vote without affected your rep. Now that a proper answer has 6 votes –  Lee Louviere Nov 28 '11 at 15:26
    
Edit and I'll undo if it'll let me. –  Lee Louviere Nov 28 '11 at 15:29
add comment

C/C++ gets compiled before execution.

Java gets compiled while executing.

Of course, neither language mandates a certain way of being compiled.

share|improve this answer
    
I believe that the statement "Java gets compiled while executed" is not strictly true. Can Java not be compiled all the way down to the platform? –  John Dibling Nov 28 '11 at 15:24
    
@JohnDibling See 3rd sentence. I don't think languages should be tied to compilation methods and so I generalized the answer. –  Pubby Nov 28 '11 at 15:26
add comment

There is no difference. Both convert source code that a human understands, to a machine code that some machine understands. In Java's case it targets a virtual machine, i.e. a program instead of a piece of silicon.

Of course there's nothing to prevent a piece of silicon from understanding JVM byte code (in which case you could rename it from 'byte code' to 'machine code'). And conversely, there's nothing to prevent a compiler from converting C/C++ code to JVM byte code.

Both have a runtime and both require you to tell it which parts of the runtime you intend to use.

I really think you intended to ask a different question.

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.