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When writing C++ code for an embedded system with limited CPU and Memory resources, the common rule of thumb is to instantiate objects in the stack, and avoid using the heap unless it is really necessary. Doing this of course has many known benefits, but with the emergence of STL and folks recommending std::vectors as an efficient data structure, does it violate the rule of thumb that I mentioned, since the vector will be using the heap?

Example: In the old days, one would declare static arrays with known sizes that will satisfy the usage. Nowadays, one would just use vectors.

I'm not really comfortable with this transition, since there is always a possibility of the vector failing to allocate the required memory (reminder: this is for embedded systems with limited memory). Using arrays with known sizes in the stack guarantees that there will be space for allocation during compile-time.

Calling reserve() kind of helps, but this is done during run-time.

So, is this a cause for concern, or am I just being paranoid? It's definitely much more easier to use these vectors, but for an embedded environment, it might not be a good idea?

Note: This is not about dynamic vs fixed arrays, but more on how the data is allocated in memory, which is a big deal for my environment. As an example, some folks would do this: Say the array can grow or shrink between 1 to 10 elements. Some folks would create an array that covers this size in the stack, and NULL terminate depending on current size. This way, fragmentation is avoided, and we are guaranteed allocation during compile time. However, switching to vector made it much more cleaner, but at the expense of using the heap, and potentially having to deal with exceptions if allocation fails. This is what I am concerned about.

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If you know how many items will be in the vector (or at least a rough estimate) you can then reserve space for the data. – Joachim Pileborg Dec 30 '13 at 14:25
There's nothing wrong with a static or automatic array, if the size is known at compile time and you make sure the stack is big enough. Use vector when you specifically want a dynamic array. (These days, you can use std::array to make a fixed-size array look more STL-like, if you want.) – Mike Seymour Dec 30 '13 at 14:26
Stacks can blow just like heaps can be full. – Yakk Dec 30 '13 at 14:30
"Limited CPU and memory resources" means something different today than when rules of thumb like that were created. It depends on how limited your hardware really is. If you have memory measured in tens or hundreds of bytes and CPU speeds measured in kHz, then those rules still stand, but if you have megabytes of RAM and gigahertz of cycles, then you can often avoid worrying about optimization. – Kristopher Johnson Dec 30 '13 at 14:32
Kristopher Johnson, I beg to differ. The hardware that I am working on has 32MB of memory, and adhering to rule of thumbs enabled us to maintain this spec without having to create new hardware. With new programmers joining, the sudden surge in memory usage per feature dramatically increased. – Ryuu Dec 30 '13 at 14:40

I believe that you have forgotten one very important property of the STL containers: allocators.

A STL container (whether a vector or otherwise) obtain all its memory from its allocator (apart from the very basic stack footprint that you can check with sizeof). Therefore, it is perfectly suitable in embedded development to provide a dedicated allocator that:

  • will allocate from a pre-reserved memory area
  • will bound the maximum resource consumption to prevent OOM
  • ...

With the advent of C++11, you may even use stateful allocators, so that a single allocator type can point to different pools of memory.

Therefore, the use of std::vector, or even std::set or std::map, is not incompatible with a pre-allocation strategy; do remember though that apart from std::vector other STL containers generally have some per-item overhead which must be taken into account when sizing the memory area they should draw upon.

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Thanks, Matt. I'll look into allocators. – Ryuu Dec 30 '13 at 14:58

"Depends" may be an understatement here. By using reserve with vectors, you can efficiently allocate space for the data and prevent unnecessary copies. The vector data structure itself will boil down to a heap allocated array with a size if the compiler is good enough.

Also, note I said heap. If you would rather allocate the data to the stack, your stuck with fixed sized arrays (including std::array).

And it also depends heavily on the compiler how vector is put together. Older compilers may (big emphasis on may) be less efficient. This is why for embedded systems you really need to know the architecture and compiler before making sweeping generalizations about what is "good" and what is "bad" to use.

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std::vector should be used for dynamically resized arrays. If you know the size at compile time, you can use std::array instead.

If you know the only approximate size of array, since C++14 you may use std::dynarray. This array has fixed size which cannot be changed during object lifetime. When the std::dynarray without allocator is used additional optimisations are possible, the operator new may not be called and stack-based allocation will be used.

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Some folks would do this: Say the array can grow or shrink between 1 to 10 elements. Some folks would create an array that covers this size in the stack, and NULL terminate depending on current size. Switching to vector is much cleaner, but at the expense of using the heap. This is what I am concerned about – Ryuu Dec 30 '13 at 14:42
Cool, I'll look into std::dynarray. Thanks! – Ryuu Dec 30 '13 at 14:57
@Ryuu note that std::dynarray is available only since C++14. – fasked Dec 30 '13 at 15:00

A std::vector is just a pointer and two size_t when compiled with sufficient optimization flags. Now the memory for the size_t is a waste when your know the size of the vector in advance and it will never change.

I would say:

  • Fixed (small) size => simple array or std::array
  • Dynamic size or huge number of elements => std::vector

And as mentioned in the comments, you can use most of the functionality of e.g. <algorithms> on fixed size arrays by using pointers for the begin/end iterators.

For example:

int array[8] = { 1,2,3,4,5,6,7,8 };
std::random_shuffle(array, array+8);
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It's two pointers and a size_t, or equivalently (but AFAIK rarer in practice) a pointer and two size_ts. And it's not just about the size of the vector itself, the fact that its memory is allocated dynamically has consequences: There's allocator overhead (both in time and space), and there's the risk of fragmentation. – delnan Dec 30 '13 at 14:28
Why is there the risk of fragmentation? vector stores its elements in continuous memory. – Danvil Dec 30 '13 at 14:32
Well, other STL functionality is the reason for the transition. Examples include sorting, finding, etc without having to re-implement them. I know the STL's sort will work for arrays as well, but in general, STL provided much more functionality (or reduced the need to re-invent the wheel) – Ryuu Dec 30 '13 at 14:33
In an embedded system, you may want to include the use of vector to lower stack usage, especially on recursive function calls. – IdeaHat Dec 30 '13 at 14:33
@Ryuu Before you refactor all your code, you know you can use std::sort, ect on pointers of contiguous memory as well, right? – IdeaHat Dec 30 '13 at 14:34

Using arrays with known sizes in the stack guarantees that there will be space for allocation during compile-time.

Wrong assumption.

When your got a lot of call (not even recursive but a stack with a lot of level), you cannot be sure that there is enough space for your stack to hold the object that have to be created on.

There are basic checks (if the size of your object exceed size_t at least), but I do not even think they are made mandatory by the standard.

A -- somewhat excessive -- example is here:

#include <iostream>

template <unsigned long size>
struct BigObject
    unsigned long array[size * size];
    BigObject<size - 1> object;

template <>
struct BigObject<0>
    unsigned long array[1]; 

BigObject<900>& recurse(BigObject<900>& object1, unsigned long n)
    if (n == 0)
        return object1;

    BigObject<900> object;

    return recurse(object, n);

int main(int argc, char const *argv[])
    BigObject<900> object;
    recurse(object, 20);

    std::cout << sizeof(object) << std::endl;
    return 0;

It does crash. And it is not such a special case. I add the problem in a 32 bit desktop oriented application (so none of your memory constraint) allocating a too big array on the stack.

share|improve this answer
If the object/array is global, isn't it guaranteed? – Ryuu Dec 30 '13 at 14:51
Yes, it is guaranteed by th elinker. You have to check but I think you cannot make a program run out of memory if it use only objects stored in .data segment (unless you cannot load the library itself) – Johan Dec 30 '13 at 16:14

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