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Is there any mature C/C++ compiler, capable of optimizing malloc/free (or new/delete) pairs info alloca? In other words, convert from heap-based memory to stack-based (ONLY for some limited cases).

This optimization may be allowed only for pair of malloc/free when both functions are in the same function (or even in the same block of {}), and free is called every time when malloc is called. Also, lets consider that pointer to malloced memory is not saved in some global variable.

So, will GCC/LLVM+clang/Intel Compiler convert such block of code:

{
   char *carray;
   carray = malloc(100);          // or malloc(N)
   // some string-like work with carray
   free(carray);
}

into

{
    char*carray;
    carray = alloca(100);  // or if(N<const1) carray=alloca(N);else carray=malloc(N)
    // the same work
    // nothing                       // or if(N>=const1) free(carray)
}

This conversion may be not very useful for every program, but I think, there may be some special compiler option.

PS (update1) We can limit our discussion only to cases when compiler Knows that malloc and free is from libc (stdlib)

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1  
Year ago one man in llvm list said no and other man said yes and points to actual code –  osgx Apr 28 '12 at 16:00
3  
I think malloc is not an intrinsic. And it is quite dangerous to do so, since the compiler has no information about the run-time stack size. –  BlueWanderer Apr 28 '12 at 16:01
    
The transformation is unsafe if any other function of which the compiler cannot see the definition is called and is passed the result of malloc: the function might store the pointer somewhere and then skip the free by longjmp (C, usually) or an exception (C++). I suspect, keeping that in mind, that the transformation is less frequently useful than you imagine. –  hvd Apr 28 '12 at 16:37
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@osgx: the "actual code" relates to a malloc/free pair in which the allocated memory isn't used at all (but the pointer perhaps is compared with null). You're talking about something different, a malloc/free pair in which the allocated memory is accessed. –  Steve Jessop Apr 28 '12 at 16:58
2  
@osgx The 'other man said yes' to a different question. Neither that question nor the 'actual code' has anything to do with alloca(). –  EJP Apr 29 '12 at 1:03

3 Answers 3

In general, no compiler performs this optimization. That's good, because this thing can be potentially very harmful: bear in mind that the stack is usually very limited in its size. If a compiler optimized malloc+free into an alloca, the observable behavior of the code would change: for some inputs, it wouldn't crash with malloc+free, but it would with alloca (because the stack space got exhausted). Therefore, this optimization is unsafe (and illegal according to the standard, because it changes the observable behavior) and compilers don't even try to perform it.

That said, in some very specific circumstances, a compiler could perform it, but no compiler I'm aware of does.

The optimization performed by LLVM and mentioned in the comments is a different thing, it only optimizes out mallocs that are only compared to null and then freed.

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1  
Your argument assumes that the stack size can be exhausted in situations in which malloc would succeed. That isn't necessarily true. Systems may allow the stack size to expand as needed, or more rarely, they don't use a linear stack at all. –  hvd Apr 28 '12 at 16:42
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@Fanael: and there's even gcc -fsplit-stack to get a stack that can grow as long as memory is not exhausted. –  Matthieu M. Apr 28 '12 at 16:59
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@Voo, in Linux, stack growing is implemented in page fault handler (in kernel). When address of page fault looks like a stack address, stack grow function will check the rlimit for stack (line #L1637 in mm/mmap.c). So, limit is checked per first access to every new stack page (stack does not shrink); at most RLIMIT_STACK/PAGE_SIZE times. –  osgx Apr 29 '12 at 1:15
1  
@Voo: "for very large allocations we can run into the problem again even on *nix". If you're going to use a guard page to extend the stack, you generally combine it with a technique called "stack probing", which basically means that if a function lays down a frame larger than the page size, then it must first access memory at 1-page intervals all the way out to its end, to ensure it hits the guard page. I'd expect alloca to do the same. –  Steve Jessop Apr 29 '12 at 20:22
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@Voo: I sort of agree with you that code using a lot of stack is non-portable, but there's a fundamental problem that the standard doesn't defined "a lot of stack". You could write a conforming implementation with 128 bytes of stack (or a bit more to meet the recommended implementation quantities), but it doesn't follow that char buf[128]; should be considered non-portable. Unfortunately there doesn't exist a smallest n such that char buf[n]; should be considered non-portable. Things just become gradually less portable as they use more stack, in a way that's hard to predict. –  Steve Jessop Apr 29 '12 at 20:26

There's an off-shoot of LLVM called poolalloc that does this optimization. It's being maintained as part of SAFECode, and isn't in the mainline LLVM distribution.

It's described in Chris Lattner's PhD thesis and in this PLDI paper. The code is here.

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Technically, the compilers can optimize anything as long as they follow the As-If rule.
So, optimizing heap allocations to stack allocations would be possible but do to the compiler needs to be intelligent enough to probe the usage and determine that changing the allocation to stack won't affect the observable behavior of the program.

I am not aware of any compiler which does this.

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