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As far as I understand, JIT (just-in-time compilation) refers to a run-time process where bytecode is compiled (translated) to native code to improve run-time performance.

On the other hand, compile-time evaluation is a common practice towards generic programming or run-time optimization. Again, as far as I understand, in this case the compiler interprets source code to evaluate an expression (producing e.g. either a value or a type). In this case the compile time often increases significantly.

Is there a compile-time JIT process where a compiler translates source code to native for more efficient compile-time evaluation? I find it very natural, but does any compiler do that in any language?

If I were to do this in my own compiler, would it be a good idea? What extra difficulties would I have comparing to run-time JIT?

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Do you mean compiling bytecode to native ahead-of-time? If so, there's plenty of programs that do that all over the internet. Because "Compile-time JIT" makes no sense. "Compile time" is "before the user runs it." and "JIT" is "as/after the user starts running it". There can't really be a hybrid. Compilation is either before or as/after the user starts the code. – Mooing Duck May 22 '14 at 23:43
Oh wait, do you mean where the compiler generates native code, and then executes the native code during static compilation? I'd expect C++ constexpr works on exactly this concept, though I doubt anything else in C++ would. Compile-time evaluation for constants and types in C++ is usually not executing "code" so much as "looking stuff up in tables". (I do C++ obviously, and cannot speak as to other languages) – Mooing Duck May 22 '14 at 23:47
@MooingDuck Yes, I meant what you say in your second comment. C++ constexpr does all its evaluations at compile time, but I don't know how. I read that D does this by interpreting the code, which is 1-2 orders of magnitude slower than running native code. Just measuring compile times (clang or especially gcc), I don't think that C++ does any better in practice. – iavr May 23 '14 at 21:36

There wouldn't be any point. The compiler is already compiling code. Constant-expression evaluation only happens once. The Java HotSpot JVM for example only finds it beneficial to compile a method to native code after it has been executed thousands times.

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Constant-expression evaluation only happens once at every change in the source code. That is, depending on what you're trying to code, it may well happen once every minute, and last for 30 seconds. – iavr May 23 '14 at 21:29
C++ allows you to write functions that the compiler executes during compilation, I think that's what he's referring to, if those are interpreted or compiled and then executed. – Mooing Duck May 23 '14 at 21:44
@MooingDuck Exactly, thanks. – iavr May 23 '14 at 21:48
For that matter, tools like lex and yacc that precompute tokenizing and parsing tables for input grammars could be considered a form of computation in advance. Making it transparent to the programmer in the general case requires partial evaluation. – Jeffrey Hantin May 23 '14 at 21:59

I think what you're talking about — performing code generation in advance when the default behavior would be either interpretation or just-in-time code generation — is called out as ahead-of-time (AOT) compilation.


  • Lower startup latencies, if reading the native image is faster than translating a usually smaller intermediate-language image
  • Shared pages of translated native code between multiple instances of one process may reduce main memory footprint, but only if multiple instances run concurrently


  • Harder to optimize based on runtime characteristics; HotSpot's dynamic profile-directed whole-program optimization may compile the same method differently in different programs depending on how it's used
  • Total program storage footprint usually increases, since native images are often larger than intermediate code and the intermediate code often cannot be removed after native image generation

You could conceivably do profile-directed whole-program optimization on AOT-compiled code, but then you would end up with something resembling a "preheated" version of the HotSpot runtime, trading back the shared memory on methods hot enough to merit reworking their translation.

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Jeffrey Hantin, Can you name some AOTs, like ART runtime in newest 4.4 Androids, Excelsior JET and GCJ for Java?.. – osgx May 23 '14 at 2:33
@osgx, I've been in CLR-land for so long that Mono AOT and Microsoft NGen were all that came to mind. – Jeffrey Hantin May 23 '14 at 2:36
Thanks for the pointer, but this isn't what I meant. What I meant is, the compiler sees an expression that can be evaluated at compile time, like fibonacci(15); it compiles fibonacci, generating native code for it; it calls this function and computes the result; it inserts the result as a constant, replacing the expression; it compiles the rest of the code normally, generating native code or intermediate code or whatever; at run-time, no computation is needed at all for this expression. I hope this is clearer. – iavr May 23 '14 at 21:45
@iavr Oh! That's somewhere between constant folding and partial evaluation. Constant folding is just one optimization that could fall under the purview of partial evaluation. – Jeffrey Hantin May 23 '14 at 21:52
@JeffreyHantin Exactly, sorry I thought compile-time evaluation was also clear. Anyhow, I know that this happens routinely at least in C++ (constexpr) and D, it just makes compilation so slow, hence my question. – iavr May 23 '14 at 22:00

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