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We all know the basic rules for static array:

int size = 20;
char myArray[size];

is not legal. And.

const int size = 20;
char myArray[size];

is OK.

But, what about this.

int f(const int size)
{
    char myArr[size];
}

void main()
{
   f(2);
   f(1024);
}

MSVC says it is an error, gcc seems to compile and execute it fine.

Obviously, it is not portable, but should it be accepted?

Which compiler does the right thing in that situation?

Also, if it is permited by the compiler, should it be permited by good programming standards/practice?

EDITED: The idea is that I would want stack allocation for the speed, but I would not know at compile time the size of the array. I know that there is some other solutions, and that stack alloc would probably not be a significative optimization, but I think it is an interesting usage.

share|improve this question
    
Your first two examples are character-for-character identical. – AlcubierreDrive Oct 22 '10 at 14:19
up vote 9 down vote accepted

No. C++ has no variable-length arrays. C99 does, and gcc allows it via extension.

Use a std::vector.


Assuming you have profiled your application and found this to be a bottleneck, write a custom allocator that allocates from the stack and use that. If not, there's not a problem.

Stack allocation is very fast, but this likely isn't going to be a main concern in a real application. (You should have a custom memory management scheme in place that will performance close in speed to stack allocation.)

share|improve this answer
    
It's not variable length array, the expression that fixes the size of the array is const. – jslap Oct 22 '10 at 15:08
    
@jslap: What do you mean? Can you give a more concrete example of what you're trying to do? In your code, myArr is a variable length array. The type might be const, that doesn't mean the value is a constant expression. Consider: f(rand());. – GManNickG Oct 22 '10 at 15:11
    
As I said in my edit, the purpose of the question is not to optimize a particular piece of code. I just want to know if it is an accepatable way of optimizing if I observe it does optimize. I sure know that early optimization is a curse. Actualy, I'm known in my team for saying it all the time. – jslap Oct 22 '10 at 15:11
1  
@GMan: Post a question "How to write a stack allocator?" and post your allocator as an answer. Just as with the copy-and-swap idiom. – sbi Oct 23 '10 at 14:59
1  
@jslap: I keep pointing people at y60.artcom.de/redmine/repositories/entry/y60/asl/base/…, which is a std::vector replacement storing a fixed max number of elements on the stack. – sbi Oct 23 '10 at 15:01

You can use std::array for this. std::array was added in the TR1 extensions and is available in the namespace std or std::tr1 depending on the compiler / standard library version you're using.

#incldue <array>
int main()
{
   std::tr1::array<int,25> myArray;
   //etc...
   myArray[2] = 42;
}

reread the question, regarding stack allocation...

If you want stack allocation, you can use alloca to allocate on the stack instead of malloc(all usual warnings apply).

If you want to a friendlier interface you can implement a custom stl allocator based on alloca and use a std::vector with this (you should read up before implementing).

e.g.:

#include <vector>
template <class T>
class MyStackAllocator
{ // implemented per std::allocator spec
...
}
int main()
{
//allocate a vector on the stack and reserve n items
vector<int, MyStackAllocator<T>> vecOnStack(25);
...
}
share|improve this answer
    
Thanks, but I don't know the size I need before execution. – jslap Oct 22 '10 at 14:40
    
see my latest edit. – Rick Oct 22 '10 at 14:45
    
+1 for alloca. It's unfortunately not part of the C++ standard, nor type-safe, but it is highly portable since it was standardized by BSD and then adopted by virtually all compilers after that. Still, how do you propose to wrap alloca with a friendlier interface so that the storage is still valid after the wrapper returns? – Ben Voigt Oct 22 '10 at 15:22

The variable length arrays (VLA) are supported by C99, but not by C++. gcc allows it through the extension.

std::vector is doing in C++ what VLA is doing in C99

share|improve this answer
    
How is this different than my answer? You even got the sentence count and layout the same. (Though you're incorrect in saying vector is a drop-in for VLA's; vector dynamically allocates, VLA's don't.) – GManNickG Oct 22 '10 at 15:01
1  
@GMan: More correct to say, vector dynamically allocates from the heap, VLAs dynamically allocate from automatic storage (which on most platforms means the call stack, but isn't actually required to be). – Ben Voigt Oct 22 '10 at 15:18
    
@Ben: Ah, right. I lose this time. – GManNickG Oct 22 '10 at 15:19
    
@GMan sorry, I started replying, and then I went away to do something. When I came back, I posted. Now I see it is the same response. – BЈовић Oct 22 '10 at 16:49

Correct answer was actually supplied in this thread, so I just want to provide more context to it.

You need to create custom allocator which uses alloca() (or _alloca() in Windows) function for dynamic stack allocation. It's very easy to create one, you can use a typical allocator boilerplate, change allocate() member function to return (pointer)(alloca(size * sizeof(T))); and make deallocate() function empty, because there is no manual stack deallocation. After that you can supply your allocator to the standard containers, e.g. vector<T, stack_allocator<T>>.

There are two caveats, though. Allocate-able stack size can vary significantly, often you have an option to set it at compile time. Visual Studio in 32-bit applications I believe limits it to 1MB by default. Other compilers may have different limits. In 64-bit applications there isn't really any problems as stack can be as large as heap. You will probably need to catch structured exception on stack overrun and convert it to C++ exception.

The second caveat, you should never copy the stack pointers outside of your function, so move semantics, for example, will not work if you pass stack allocated objects to/from the function.

And there is also one inconvenience, you cannot copy containers with incompatible allocators, but you can copy them element by element. E.g.

vector<int> vint;
vector<int, static_allocator<int>> vsint;

vint = vsint; // won't compile, different allocators
std::copy(vsint.begin(), vsint.end(), vint.begin()); // fine
share|improve this answer

What you really want isn't quite what you've asked. It seems that you really want a map of numbers to numbers, such that index 2042 holds the value 23, etc.

Since you don't actually know the upper bound of the highest number you might want to use, you will probably have to restructure you code in such a way that it uses a (mathematical) map, where instead of considering 2042 the index of an array holding, you consider 2042 the key to access the value 23.

---- Answer to the can we allocate a static array with an execute time constant below ---

If you want an execute time static array, the best option is to declare the array using the alternative pointer syntax, and then initialize it in a non-static init() like function at the start of the program execution.

If you attempt to allocate the array prior to the execution of main(...) you run the risk of not knowing which static blocks of code are going to be called in what order. Sometimes that makes little difference; but, in your case it seems you need the number to be computed at run time, so the order of the modules becomes important.

By using a non-static method, you esentially guarantee that all the static code is exercised prior to allocating the array.

share|improve this answer
    
This is not realy what I want to use it for. I want a temporary array in my function that is on the stack. Like for a dynamic programming algorithm for example. Also, see my clarifications about the stack alloc. – jslap Oct 22 '10 at 14:37
    
In that case, seems that you'll eventually be pushed into using the alternative pointer syntax for an array and allocating it on the heap. C's compiler was pretty strict about needing to know how much memory it has to lay out in the stack ahead of time (to see if it needed to actually lay it out in the heap as it might not fit in the stack's extra memory in the execution frame). C++ has the same strict standards for arrays too, and since it's a compile time check, it's going to be impossible to do it 100% at run time without some deep, scary magic. – Edwin Buck Oct 22 '10 at 14:44
    
@jslap: Like I said, it's an extension being adopted from C99. – GManNickG Oct 22 '10 at 15:02

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