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Are there scenarios where JIT compiler is faster than other compilers like C++?

Do you think in the future JIT compiler will just see minor optimizations, features but follow a similar performance, or will there be breakthroughs that will make it infinitely superior to other compilers?

It looks like the multi core paradigm has some promise but it's not universal magic.

Any insights?

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10 Answers 10

up vote 42 down vote accepted

Yes, there certainly are such scenarios.

  • JIT compilation can use runtime profiling to optimize specific cases based on measurement of the characteristics of what the code is actually doing at the moment, and can recompile "hot" code as necessary. That's not theoretical; Java's HotSpot actually does this.
  • JITters can optimize for the specific CPU and memory configuration in use on the actual hardware where the program happens to be executing. For example, many .NET applications will run in either 32-bit or 64-bit code, depending upon where they are JITted. On 64 bit hardware they will use more registers, memory, and a better instruction set.
  • Virtual method calls inside of a tight loop can be replaced with static calls based on runtime knowledge of the type of the reference.

I think there will be breakthroughs in the future. In particular, I think that the combination of JIT compilation and dynamic typing will be significantly improved. We are already seeing this in the JavaScript space with Chrome's V8 and TraceMonkey. I expect to see other improvements of similar magnitude in the not-too-distant future. This is important because even so-called "statically typed" languages tend to have a number of dynamic features.

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You only mention what a JIT compiler can do, not what it actually does. JIT'ing is generally constrained by having to be fast. It's ok for an offline compiler to take a long time to optimize the code, but a JIT compiler has to be done in a second or two, at most. So both have their advantages. – jalf Feb 11 '09 at 19:30
As I clearly indicated in the post, HotSpot actually does dynamic, profile-guided recompilation, and .NET actually does CPU-specific compilation. I doubt either affects startup speed one bit (think about it). Virtual call optimization? Look at V8. I agree both have advantages. – Craig Stuntz Feb 11 '09 at 20:01
Not only can a JIT compiler optimize code based on how the runtime observes the code being used, it can also use more aggressive ("dangerous") optimizations because it can deoptimize the code by throwing away the compiled code when the optimization assumptions are no longer valid. Hotspot does this. – Ken Bloom Jul 11 '10 at 4:53
Not only can virtual method calls be replaced with static calls based on runtime characteristics, they can also be inlined based on the same runtime characteristics. – Ken Bloom Jul 11 '10 at 4:54

Yes, JIT compilers can produce faster Machine Code optimized for the current environment. But practically VM programs are slower than Native programs because JITing itself consumes time (more Optimization == more time), and for many methods JITing them may consume more time than executing them. And that's why GAC is introduced in .NET

A side effect for JITing is large memory consumption. However that's not related to computation speed, it may slow down the whole program execution, because large memory consumption increases the probability that your code will be paged out to the secondary storage.

Excuse me for my bad English.

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I think you mean NGEN, not GAC. – Craig Stuntz Feb 11 '09 at 18:41
GAC = GLobal Assembly Cache ngen is the tool used to add an assembly to it – Bahaa Zaid Feb 11 '09 at 18:51
Often with JITers, instead of paging compiled code out, it will just drop the least recently used compiled code and recompile it later when needed. – Eclipse Feb 11 '09 at 18:53
Yes, and that is worst – Bahaa Zaid Feb 11 '09 at 18:55
@Bahaa: no, gacutil is used to add assemblies to the GAC. NGEN is used to add assemblies to the native images cache. – Dave Van den Eynde Nov 8 '10 at 7:38

JIT has advantages, but I don't see it taking over completely. Conventional compilers can spend more time optimizing, while a JIT needs to strike a balance between too much optimization (taking more time than is saved by optimization) and too little (taking too much time in straight execution).

The obvious answer is to use each where it's superior. JITs can take advantage of run-time profiling more easily than conventional optimizers (although there are compilers that can take run-time profiles as input to guide optimization), and can generally afford to do more CPU-specific optimizations (again, lots of conventional compilers do this, but if you expect to run the executable on different systems they can't take full advantage of it). Conventional compilers can spend more time, and do it in different ways.

Therefore, the language system of the future will have good optimizing compilers that will emit executable code designed for use by good optimizing JIT compilers. (This is also, for many people, the language system of the present.) (The language system of the future will also support everything from modern Python/VB scripting to the ugliest high-speed number crunching.)

As with many things, this was foreshadowed by Lisp. Quite some time ago, some Lisp systems (can't really say many, there haven't been all that many Common Lisp implementations) interpreted Lisp functions by compiling them on the fly. Lisp S-expressions (what code is written in) are fairly straightforward descriptions of parse trees, so compilation could go pretty fast. In the meantime, an optimizing Lisp compiler could crunch the code where performance was really important ahead of time.

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+1 for hybrids. FWIW, NGEN mostly does what you're describing. – Craig Stuntz Feb 11 '09 at 20:02

Basically, JIT compilers has a chance to actually profile the application being run, and do some hinting based on that information. "offline" compilers will not be able to determine how often a branch jumps and how often it falls through, without inserting special code, ask the dev to run the program, put it through its paces, and recompile.

Why does this matter?

//code before
  //error handling
//code after

Gets converted into something like:

//code before
Branch if not error to Code After
//error handling
Code After:
//Code After

And x86 processors would not predict a conditional jump ahead in the absence of information from the branch prediction unit. That means that it predicts the error handling code to run, and the processor's going to have to flush the pipeline when it figures out that the error condition didn't occur.

A JIT compiler could see that, and insert a hint for the branch, so that the CPU would predict in the correct direction. Granted, offline compilers can structure the code in a way that would avoid the mispredict, but if you ever need to look at the assembly, you might not like it jumping around everywhere....

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static compilers can do profile guided optimizations as well... – Nils Pipenbrinck Feb 11 '09 at 19:46
I know that - "offline compilers ... without inserting special code, ask the dev to run the program, put it through its paces, and recompile." – Calyth Feb 11 '09 at 20:42
Nils, JIT compiler can profile live dataset on the fly whereas static is still limited to static dataset – kchoi Nov 17 '14 at 18:17

Another thing that was skipped in this conversation is that when you JIT a piece of code it can be compiled to a free spot in memory. In a language like C++ if the DLL is based such that that piece of memory is not available it will have to go through the expensive process of rebasing. It is faster to JIT code into an unused address then rebase a compiled DLL into a free memory space. To make things worse, a rebased DLL can no longer be shared. (see

I haven't been very impressed with some of the optimizations in C# 3.5 JIT code. Simple things like bit twiddling that is necessary for compression are horribly inefficient (it refused to cache values in a CPU register and instead went to memory for every operation). I don't know why it would do this but it makes a huge difference and there is nothing I can do about it.

Personally I think a good solution would be an Optimization Level (1-100) that you could set to tell JIT compiler how much time you think it ought to spend optimizing your code. The only other solution would be an AOT (Ahead of Time) compiler and then you lose many of the advantages of JIT code.

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rebasing is not as slow as you make it out to be. Slower than loading at preferred address, absolutely. Slower than JIT, doubtful. And since JITted code is never shared, that's another case where AOT is a win, until you have a load address conflict. – Ben Voigt Oct 3 '11 at 17:34

Lots of people answered maybe I am skimming (maybe I have have the wrong end of the stick) but for me they are two different things:

AFAIK there is nothing stopping you JIT'ing compiled c++ for example project Dynamo JIT'ed machine code:

And it did actually provide speed improvements under certain circumstances.

Compiling code, in the sense of a c++ compiler means taking code written in a language and turning it into a set of instructions (or in some cases another language to then be compiled again) that can be executed by some kind of logical device.

e.g. c++ compiling to assembly (I think ;-) or c# compiling to IL or Java compiling to byte code

JIT is a process that happens during execution. The machine executing the code analyses it to see if it can improve it. Java and C# are able to make use of both as the compiler prepares commands for the VM and then the VM has the opportunity at least to have another go at optimising it.

Some programs are not compiled they are interpreted, meaning the machine that runs them reads the exact code you wrote. These machines have the oppourtunity to do some JIT, but remember they can also be statically compiled, potentially be a third party vendor in ways that the original designer of the language never intended.

So to answer your question I don't think JIT will replace static compilers. I think there will always (as long as there is programming at least) be a place for taking a representation of a program and converting that into an set of instructions for a machine of some type. (potentially optimising while it does it)

HOWEVER, I do think that JIT may become a bigger part of the story, as the Java run time and .net run time evolve I am sure JIT will get better and given things like project Dynamo I guess there is scope for hardware taking up JIT too, so that everything your processor does is re-optimised based on run time environment.

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JIT compilers know more of the systems then static compilers. Adding multitheading on the fly specific to the machine can be a gigantic speed improvement once they get it working.

JIT compilers in general have a bit of startup latency where the first run of the program/code can be much slower then precompiled code. The cold start disadvantage.

Another big advantage of JIT compilation is that the compiler can be updated after your program has been build and gain new compiler tricks without needing a complete new program deployment.

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One advantage of JITing which has not yet been mentioned is that it's possible for a program to define an infinite number of generic types. For example:

interface IGenericAction { bool Act<T>(); }

struct Blah<T>
  public static void ActUpon(IGenericAction action)
     if (action.Act<T>())

Calling Blah<Int32>.ActUpon(act) will call act.Act<Int32>(). If that method returns true, it will call Blah<Blah<Int32>>.ActUpon(act), which will in turn call act.Act<Blah<Int32>>(). If that returns true, more calls will be performed with an even more-deeply-nested type. Generating code for all the ActUpon methods that could be called would be impossible, but fortunately it's not necessary. Types don't need to be generated until they are used. If action<Blah<...50 levels deep...>>.Act() returns false, then Blah<Blah<...50 levels deep...>>.ActUpon won't call Blah<Blah<...51 levels deep...>>.ActUpon and the latter type won't need to be created.

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A point not yet mentioned which favors "off-line" compilers is that such compilers can usefully target platforms with small amounts of RAM--even as few as sixteen BYTES. To be sure, anything that's even remotely PC compatible is apt to have (literally) millions of times more RAM than that, but I think it will be awhile before one can find a machine with many megs of RAM that costs less than $0.50 and consumes less than a milliwatt of power during operation.

Note that the 16 bytes of RAM isn't quite so feeble as it sounds, since the chips with such small RAM don't store code in RAM--have a separate non-volatile area of memory to hold code (384 bytes is the smallest I know of). That's not a lot, of course, but it's enough to allow a $0.25 processor to perform functions that would otherwise require $1.00 worth of discrete components.

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JIT compilers have more data they can use to influence optimizations. Of course, someone actually has to write code to use that data, so it's not a simple as that.

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