Before I write my own I will ask all y'all.

I'm looking for a C++ class that is almost exactly like a STL vector but stores data into an array on the stack. Some kind of STL allocator class would work also, but I am trying to avoid any kind of heap, even static allocated per-thread heaps (although one of those is my second choice). The stack is just more efficient.

It needs to be almost a drop in replacement for current code that uses a vector.

For what I was about to write myself I was thinking of something like this:

char buffer[4096];
stack_vector<match_item> matches(buffer, sizeof(buffer));

Or the class could have buffer space allocated internally. Then it would look like:

stack_vector<match_item, 256> matches;

I was thinking it would throw std::bad_alloc if it runs out of space, although that should not ever happen.


Using Chromium's stack_container.h works great!

The reason I hadn't thought of doing it this way myself is that I have always overlooked the allocator object parameter to the STL collection constructors. I have used the template parameter a few times to do static pools but I'd never seen code or written any that actually used the object parameter. I learned something new. Very cool!

The code is a bit messy and for some reason GCC forced me to declare the allocator as an actual item instead of constructing it into vector's allocator parameter. It went from something like this:

typedef std::pair< const char *, const char * > comp_list_item;
typedef std::vector< comp_list_item > comp_list_type;

comp_list_type match_list;

To this:

static const size_t comp_list_alloc_size = 128;
typedef std::pair< const char *, const char * > comp_list_item;
typedef StackAllocator< comp_list_item, comp_list_alloc_size > comp_list_alloc_type;
typedef std::vector< comp_list_item, comp_list_alloc_type > comp_list_type;

comp_list_alloc_type::Source match_list_buffer;
comp_list_alloc_type match_list_alloc( &match_list_buffer );
comp_list_type match_list( match_list_alloc );
match_list.reserve( comp_list_alloc_size );

And I have to repeat that whenever I declare a new one. But it works just like I wanted.

I noticed that stack_container.h has a StackVector defined and I tried using it. But it doesn't inherit from vector or define the same methods so it wasn't a drop-in replacement. I didn't want to rewrite all the code using the vector so I gave up on it.

  • Just to clarify, you want something that is essentially a vector, but with a fixed capacity as part of the template arguments? – Greg Rogers Dec 9 '08 at 22:22
  • 1
    StackVector has a method to give you the actual std::vector. just do StackVector<T, 128>::ContainerType & v = stack_vector.container(); to get it. v then is an actual std::vector. also better use the union trick i explained in the comment to my answer. – Johannes Schaub - litb Dec 10 '08 at 1:06
  • otherwise, you may get severe performance issues if you use the vector often and on some platforms (many non-x86) it may even crash. – Johannes Schaub - litb Dec 10 '08 at 1:07
  • Yes, I also build on an Itanium system in order to catch bugs like that. I have modified the code in stack_container.h, it didn't compile as-is anyway. – Zan Lynx Dec 10 '08 at 1:19

10 Answers 10


You don't have to write a completely new container class. You can stick with your STL containers, but change the second parameter of for example std::vector to give it your custom allocator which allocates from a stack-buffer. The chromium authors wrote an allocator just for this:


It works by allocating a buffer where you say how big it is. You create the container and call container.reserve(buffer_size);. If you overflow that size, the allocator will automatically get elements from the heap (since it is derived from std::allocator, it will in that case just use the facilities of the standard allocator). I haven't tried it, but it looks like it's from google so i think it's worth a try.

Usage is like this:

StackVector<int, 128> s;
s->push_back(42); // overloaded operator->

// to get the real std::vector. 
StackVector<int, 128>::ContainerType & v = s.container();
std::cout << v[0] << " " << v[1] << std::endl;
  • Slight worry in that stack_container.h: "IMPORTANT: Take care to ensure that stack_buffer_ is aligned since it is used to mimic an array of T. Be careful while declaring any unaligned types (like bool) before stack_buffer_." Eek! Order of automatics on the stack is not defined IIRC. – Steve Jessop Dec 9 '08 at 22:43
  • yeah that sounds naughty. better we create an union around it with the largest possible primitive type. only idea i get now: union { unsigned long _a; double long _b; char stack_buffer_[sizeof(T[stack_capacity])]; }; and hope they will make the alignment good enough – Johannes Schaub - litb Dec 9 '08 at 22:48
  • otherwise, we still have atttribute weapons and whatever visual c++ provides us :D – Johannes Schaub - litb Dec 9 '08 at 22:50
  • 1
    i've recently read about boost::type_with_alignment<N>::type, which could solve your exact problem. – Johannes Schaub - litb Jan 4 '09 at 18:32
  • 1
    The link to Chromium's stack_container.h is dead. Here's an updated one: src.chromium.org/viewvc/chrome/trunk/src/base/containers/… – Arto Bendiken Jul 31 '13 at 23:39

It seems that boost::static_vector is what you are searching. From the documentation:

static_vector is an hybrid between vector and array: like vector, it's a sequence container with contiguous storage that can change in size, along with the static allocation, low overhead, and fixed capacity of array. static_vector is based on Adam Wulkiewicz and Andrew Hundt's high-performance varray class.

The number of elements in a static_vector may vary dynamically up to a fixed capacity because elements are stored within the object itself similarly to an array.


Some options you may want to look at:

STLSoft by Matthew Wilson (author of Imperfect C++) has an auto_buffer template class that puts a default array on the stack but if it grows larger than the stack allocation will grab the memory from the heap. I like this class - if you know that your container sizes are generally going to be bounded by a rather low limit, then you get the speed of a local, stack allocated array. However, for the corner cases where you need more memory, it all still works properly.


Note that the implementation I use myself is not STLSoft's, but an implementation that borrows heavily from it.

"The Lazy Programmer" did a post for an implementation of a container that uses alloca() for the storage. I'm not a fan of this technique, but I'll let you decide for yourself if it's what you want:


Then there's boost::array which has none of the dynamic sizing behavior of the first two, but gives you more of the vector interface than just using pointers as iterators that you get with built-in arrays (ie., you get begin(), end(), size(), etc.):


  • 1
    alloca is awesome, but on some platforms you may not be able to detect allocation failure until you receive SIGSEGV. I believe this is the case on Linux. – Tom Dec 10 '08 at 5:00

If speed matters, I see run times

  • 4 ns int[10], fixed size on the stack
  • 40 ns <vector>
  • 1300 ns <stlsoft/containers/pod_vector.hpp>

for one stupid test below -- just 2 push, v[0] v[1], 2 pop, on one platform, mac ppc, gcc-4.2 -O3 only. (I have no idea if Apple have optimized their stl.)

Don't accept any timings you haven't faked yourself. And of course every usage pattern is different. Nonetheless factors > 2 surprise me.

(If mems, memory accesses, are the dominant factor in runtimes, what are all the extra mems in the various implementations ?)

#include <stlsoft/containers/pod_vector.hpp>
#include <stdio.h>
using namespace std;

int main( int argc, char* argv[] )
        // times for 2 push, v[0] v[1], 2 pop, mac g4 ppc gcc-4.2 -O3 --
    // Vecint10 v;  // stack int[10]: 4 ns
    vector<int> v;  // 40 ns
    // stlsoft::pod_vector<int> v;  // 1300 ns
    // stlsoft::pod_vector<int, std::allocator<int>, 64> v;

    int n = (argv[1] ? atoi( argv[1] ) : 10) * 1000000;
    int sum = 0;

    while( --n >= 0 ){
        v.push_back( n );
        v.push_back( n );
        sum += v[0] + v[1];
    printf( "sum: %d\n", sum );


You can use your own allocator for std::vector and have it allocate chunks of your stack-based storage, similar to your example. The allocator class is the second part of the template.

Edit: I've never tried this, and looking at the documentation further leads me to believe you can't write your own allocator. I'm still looking into it.

  • 1
    Bumped you because you were close to right. I didn't realize it either, but you can make an allocator do this. – Zan Lynx Dec 10 '08 at 0:58

tr1::array partially matches your description. It lacks things like push___back(), etc., but it might be worth taking a look at as a starting point. Wrapping it and adding an index to the "back" to support push_back(), etc. should be fairly easy.


Why do you want to put it on the stack particularly? If you have an implementation of alloca(), you could buld a class allocator using that instead of malloc(), but your idea of using a statically allocated array is even better: it's just as fast on most architectures, and you don't risk stack corruption of you mess up.

  • On the stack because the program is multi-threaded and multi-architecture and I don't want to mess with all the different ways to get TLS storage. Not on the heap because of thread contention on the heap lock. – Zan Lynx Dec 9 '08 at 22:38
  • Allocate per-thread block on the heap and use it the same way as stack-allocated block? – user3458 Dec 9 '08 at 23:08
  • Requires TLS, to store the pointer to "this thread's" allocated block. – Steve Jessop Dec 9 '08 at 23:24

It may be the case that you are using Qt. Then You might want to go for QVarLengthArray (docs). It sits basically between std::vector and std::array, allocating statically for a certain amount and falling back to heap allocation if necessary.

I'd prefer the boost version if I was using it though.

  • Not a bad idea if I was using Qt. I wonder why you say "chances are?" Qt is nice enough, but having a gigantic dependency I'd have to compile on MacOS, Windows, Linux (5 types) and BSD (3 types) for x86, x64, ARM, MIPS is just not on. – Zan Lynx May 13 '14 at 20:41
  • My bad, I had hardwired a different meaning for "chances are" in my mind. Actually meant "it may be the case". – Sebastian Graf May 14 '14 at 9:14

Boost have this. Its called small_vector

small_vector is a vector-like container optimized for the case when it contains few elements. It contains some preallocated elements in-place, which allows it to avoid the use of dynamic storage allocation when the actual number of elements is below that preallocated threshold. small_vector is inspired by LLVM's SmallVector container. Unlike static_vector, small_vector's capacity can grow beyond the initial preallocated capacity.

small_vector is convertible to small_vector_base, a type that is independent from the preallocated element count, allowing client code that does not need to be templated on that N argument. small_vector inherits all vector's member functions so it supports all standard features like emplacement, stateful allocators, etc.

  • boost::static_vector is probably more simple and semantic for the OP, since they said "I am trying to avoid any kind of heap", so they don't need or want the ability of boost::small_vector to exceed its stack count and start allocating from the heap. I didn't investigate it, but it might be the case that static_vector gains some efficiency from not having to account for this. – underscore_d Nov 25 '17 at 11:58

If you would like to allocate on the stack but do not want to pre-define a maximum size at compile-time, you can use StackVector, a small implementation that can be used like this:

new_stack_vector(Type, name, size)

where Type is the type of element in the vector, name is the variable name of the vector, and size is the maximum number of elements to allow in the vector.

size can be variable and does not need to be a compile-time constant! :D


new_stack_vector(int, vec, 100); //like vector<int> vec; vec.reserve(100); but on the stack :)
vec.push_back(10); //added "10" as the first item in the vector

...and that's all!

Disclaimer: Never use very large array sizes on the stack in general. Like you should not use int var[9999999], you should similarly not use new_stack_vector(int, vec, 9999999)! Use responsibly.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.