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Is there any way or tool to apply GPU acceleration on compiling programs with gcc compiler. Right now I have created a program to compile the given list of programs iteratively. It takes a few minutes. I know of a few programs like Pyrit which helps to apply GPU acceleration for Precomputing hashes.

If there are no such tools available, Please advice on whether to use OpenCL or anything else to reprogram my code.

Your Help will be highly appreciated. Thank you.

share|improve this question
Rather unclear, at least to me. Are you looking for a compiler that automatically "GPU-accelerates" your code, or a GPU-accelerated compiler? – unwind Dec 7 '11 at 14:40
I'm pretty sure he means a GPU-accelerated compiler. – RCE Dec 7 '11 at 14:44
I rather doubt that compilation will benefit from running on a GPU. Could you be more specific about (1) what you are trying to accomplish and (2) what you've done to identify the bottlenecks in your existing process. – dmckee Dec 7 '11 at 18:52
Im trying to implement something similar to.. ACOVEA. But ACOVEA is very slow. I was just wondering if there is a way to accelerate this program performance with GPU acceleration. Im sry if I'm blabbering blunders. I dont know much about GPU acceleration. – T0X1C Dec 7 '11 at 20:55
In this case it is not ACOVEA that is slow, but the individual builds. That's not surprising, a lot of builds are inefficient and a lot of ink has been spilled about how that might be improved, but none of that is in the control of ACOVEA nor will it be in your control. I think you're just out of luck. What this process could benefit from is parallelizing the individual builds across many cores (or better separate machines with their own IO infrastructure). Still, the tests have to be run locally no matter what. – dmckee Dec 8 '11 at 15:12

A. In an imperative programming language, statements are executed in sequence, and each statement may change the program's state. So analyzing translation units is inherently sequential.

An example: Check out how constant propagation might work -

a = 5;
b = a + 7;
c = a + b + 9;

You need to go through those statements sequentially before you figure out that the values assigned to b and c are constants at compile time.

(However separate basic blocks may possibly be compiled and optimized in parallel with each other.)

B. On top of this, different passes need to execute sequentially as well, and affect each other.

An example: Based on a schedule of instructions, you allocate registers, then you find that you need to spill a register to memory, so you need to generate new instructions. This changes the schedule again.

So you can't execute 'passes' like 'register allocation' and 'scheduling' in parallel either (actually, I think there are articles where computer scientists/mathematicians have tried to solve these two problems together, but lets not go into that).

(Again, one can achieve some parallelism by pipelining passes.)

Moreover, GPUs especially don't fit because:

  1. GPUs are good at floating point math. Something compilers don't need or use much (except when optimizing floating point arithmetic in the program)

  2. GPUs are good at SIMD. i.e. performing the same operation on multiple inputs. This is again, not something a compiler needs to do. There may be a benefit if the compiler needs to, say, optimize several hundred floating point operations away (A wild example would be: the programmer defined several large FP arrays, assigned constants to them, and then wrote code to operate on these. A very badly written program indeed.)

So apart from parallelizing compilation of basic blocks and pipelining passes, there is not much parallelism to be had at the level of 'within compilation of a C file'. But parallelism is possible, easy to implement, and constantly used at a higher level. GNU Make, for example, has the -j=N argument. Which basically means: As long as it finds N independent jobs (usually, compiling a bunch of files is what GNU Make is used for anyway), it spawns N processes (or N instances of gcc compiling different files in parallel).

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You seem to suggest that compilation cannot be parallelized; projects like distcc seem to be clear evidence to the contrary. Parallizing compilation is standard practice these days. Regardless, I don't doubt that GPU acceleration of compilation may remain infeasible -- there are many limiting factors like bus throughput, etc. – Frank Farmer Feb 5 '13 at 18:50
@FrankFarmer - I am not sure if you read my entire answer. I haven't used distcc, but a glance at this shows me that distcc runs at the file granularity. It preprocesses stuff on the host machine, and sends out entire files to hosts to process. i.e. each file by itself is still compiled serially. This is pretty much the same level of granularity as GNU Make does with the -j option. – ArjunShankar Feb 6 '13 at 10:20
@FrankFarmer - If you look at the last paragraph in the answer, you'll see where distcc fits in. – ArjunShankar Feb 6 '13 at 10:23
Are all passes in compiler considered sequential in nature? How about localized IL reductions? Also if user code uses floating point, so does the compiler. Anything that compiler can resolve at compile time, it will do so during compilation. That means const floating point, vector, SIMD math can potentially benefit from exploiting parallelism – kchoi Dec 19 '14 at 20:59
@ArjunShankar, "some passes operating on independent blocks of code can be parallelised" is what I meant. You're correct in that most of the compiler logic is sequential in nature. To add to ones you've already listed, most dataflow based optimizations are sequential. There is some benefit to parallelizing actual compilation itself, for JIT compilers. Compiler may also not deal frequently with const float/vector ops, but who knows what user writes. You could argue that user could improve his program, but there may be more to gain from doing this. – kchoi Dec 19 '14 at 21:55

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