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While refactoring, I wanted to change an array where entries are added to an std::vector, but for compatibility (persistency, downgrading,...), it still needs to have an upper limit.
What is the best way (elegant, stl-like, limited extra code) to have an stl-like container which is limited in size, so you know that inserting an entry fails?

To clarify: I would like an stl-like container, that starts empty, that you can fill with entries and possibly remove entries and that iterate over the filled-in entries, but that doesn't allow to put in more than e.g. 50 entries, so almost like a sequential contrainer, but with an upper-limit.

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Is it okay to have a constant-sized array? You could use std::array from C++ tr1 - open-std.org/jtc1/sc22/wg21/docs/papers/2003/n1479.html –  Merlyn Morgan-Graham Aug 25 '10 at 7:19
std::array doesn't have the add/delete functionality, so this should be added then. And there still needs to be a way to check whether adding has failed. –  stefaanv Aug 25 '10 at 7:45
Are you looking for a circular buffer? –  John Dibling Aug 25 '10 at 12:54
@John: a circular buffer tends to overwrite the oldest entry (default in boost). I need to stop when it is full. –  stefaanv Aug 25 '10 at 13:15
@stefaanv: So what happens if the user pushes a new element in to a full container? –  John Dibling Aug 25 '10 at 15:04

6 Answers 6

up vote 5 down vote accepted

A simple solution would be encapsulating a vector inside your own limited size container. You could use private composition or private inheritance --note that private inheritance models implemented in terms of and does not have some of the shortcomings of public inheritance.

EDIT: Sketch of the solution with private inheritance

template <typename T, unsigned int N>
class fixed_vector : std::vector<T>
    typedef std::vector<T> vector_type;
    typedef typename vector_type::reference reference;
    typedef typename vector_type::const_reference const_reference;
    typedef typename vector_type::iterator iterator;
    typedef typename vector_type::const_iterator const_iterator;
    typedef typename vector_type::value_type value_type;
    typedef typename vector_type::size_type size_type;

    fixed_vector() : vector_type() {}
    fixed_vector( size_type size, value_type const & value = value_type() )
       : vector_type(size,value)

    void push_back( value_type v ) {
        vector_type::push_back( v );
    iterator insert( iterator position, value_type const & v ) {
        vector_type::insert( position, v );
    void reserve( size_type size ) {
        if ( size > N ) throw std::invalid_argument();
        vector_type::reserve( size );
    size_type capacity() const {
        // In case the default implementation acquires by default 
        // more than N elements, or the vector grows to a higher capacity
        return std::min( vector_type::capacity(), N );
    // provide other insert methods if required, with the same pattern
    using vector_type::begin;
    using vector_type::end;
    using vector_type::operator[];
    using vector_type::erase;
    using vector_type::size;
    using vector_type::empty;
    void ensure_can_grow() const {
        // probably a different exception would make sense here: 
        if ( this->size() == N ) throw std::bad_alloc();

There is quite a bit of hand-waving there... std::vector take more arguments that could be added to the façade. If you need any of the other methods or typedefs, you can just bring them into scope with a using declaration, redefine the typedef, or implement the adaptor with your particular test.

Also, in this implementation the size is a compile time constant, but it would be really simple to modify it into a constructor parameter.

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+1: brilliant idea! –  Chubsdad Aug 25 '10 at 9:26
Private inheritance is well and good, but the container interface is inconveniently large. See the list of requirements, and optional requirements, and then vector adds more… –  Potatoswatter Aug 25 '10 at 12:12
The user requirements seem lesser: fill entries, remove, iterate. You can implement a non-standard container that only offers what is required en probably less than 50 lines (including all the appropriate typedefs). –  David Rodríguez - dribeas Aug 25 '10 at 13:19
Note: this sketch is already 47 lines, and it is quite bare. Contrast the restrictions of this class with the single requirement to call reserve after constructing an object as in my solution. –  Potatoswatter Aug 25 '10 at 20:31
@Potatoswatter: The sketch goes beyond the requirements established in the question. Using a limited allocator is wrong as the way that containers grow is undefined. Note also that simply constructing a vector (without actually inserting elements into it) may already trigger an allocation. There is no way of controlling the capacity before the vector is created, and there is no guarantee that once it is created it is not too late already. –  David Rodríguez - dribeas Aug 25 '10 at 23:03

Customize the vector class to impose an upper limit. Probably, you can have a new api exposed which will check the size against the upper limit and return false if exceeds otherwise call the regular insertion method.

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So the question has moved to: what is the best way to customize a vector to impose an upper limit? Is inheritance a good idea in this case? –  stefaanv Aug 25 '10 at 7:46
@Hemant: How? Do you have any code snippet to illustrate your point? You may want to look at stackoverflow.com/questions/922248/… –  Chubsdad Aug 25 '10 at 7:46
The STL containers are not designed to be derived from. You can tell this because their destructors are not virtual. –  Loki Astari Aug 25 '10 at 7:51
@stefaanv: Not only is it not encouraged, it's a rather bad idea for containers. You have to duplicate all the constructors, including two which alias each other in a tricky way. –  Potatoswatter Aug 25 '10 at 8:00
People often overstate the problems with deriving from STL containers. You don't need a virtual destructor if you're not adding data members, and unless the ownership of the derived containers themselves (as distinct from their elements) is complex then there are no issues with accidental destruction via base pointer anyway. 95% of the time you're making this kind of design decision, it's obvious that it's safe. You often don't need all the constructor's either. If you're providing a library with a drop-in vector for arbitrary client usage you should worry more :-). –  Tony D Aug 25 '10 at 8:10

Have a look at this static_vector implementation which I found a while ago. I think it does exactly what you want.

It's distributed under the very liberal boost license, so you're allowed to do just about anything with it.

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It probably would be the best thing, because it would give a complete container, but taking over code, even with liberal licenses requires approvals, so I'm going for the own implementation starting from a vector. –  stefaanv Aug 26 '10 at 6:59
@stefaanv: Uh oh, corporate headaches. IANAL, but would it be a problem to incorporate your code in your company's? Because if not, that code's license is liberal enough for you to rip the code out of that header and put it into your own header, with whatever copyright you'd like to use. You'd then only face the supposedly smaller hurdle of getting your own code approved. That somewhat beats a bureaucratic system with its own weapons. :) –  sbi Aug 26 '10 at 9:43
thanks for the tip, but for the moment, I'm happy with my implementation (similar to dribeas suggestion) –  stefaanv Aug 26 '10 at 11:04

Take a look at Boost.Array

As replacement for ordinary arrays, the STL provides class std::vector. However, std::vector<> provides the semantics of dynamic arrays. Thus, it manages data to be able to change the number of elements. This results in some overhead in case only arrays with static size are needed.

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If your upper limit is very low, that is. –  Viktor Sehr Aug 25 '10 at 7:23
So, I still need to customize the array to provide add/remove functionality? –  stefaanv Aug 25 '10 at 7:51

Take a look at boost::array

Edit: for add/delete boost::optional can be used as a element type of boost::array.

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You would still also need an iterator into the array. –  Potatoswatter Aug 25 '10 at 12:08

You can create a custom allocator (e.g. derived from std::allocator) that refuses to allocate an array larger than a given size.

Note that you need to call reserve( vector_max ) on the resulting object before adding things to it. I'm filing a defect against the C++ standard, as the requirement should be unnecessary (and it is, on recent versions of GCC).

template< typename T, size_t N >
struct limited_alloc : std::allocator< T > {
    size_t max_size() const { return N; }
    typename std::allocator<T>::pointer allocate( size_t n ) {
        if ( n < N ) return std::allocator<T>::allocate( n );
        throw std::length_error( "array too large" );

    limited_alloc() {} // silly cruft for standard requirements:
    template< typename T2 >
    limited_alloc( limited_alloc<T2,N> const & ) {}
    template< typename T2 >
    struct rebind { typedef limited_alloc<T2,N> other; };

enum { vector_max = 40 };

template< typename T >
struct limited_vector {
    typedef std::vector< T, limited_alloc< T, vector_max > > type;

void f() {
    limited_vector< int >::type x;
    x.reserve( vector_max );
    x.assign( vector_max + 1, 3 ); // throws.
share|improve this answer
The way vectors grow their capacity is distinct from their in-use size (for example, a single push_back may trigger a request to double capacity) seems to prevent this approach: you're putting a cap on capacity, but that may be hit before size() reaches the intended limit. –  Tony D Aug 25 '10 at 7:31
@Tony: fair nuff, although reserve could solve that problem, or simply making the limit double the upper bound. –  Potatoswatter Aug 25 '10 at 7:33
The Standard doesn't guarantee it'll double each time... e.g. may allocate a memory page of objects the first time or two, then double afterwards. reserve() is a pretty strong request not to pad out the allocation though.... –  Tony D Aug 25 '10 at 7:45
@Tony: Yep, although most implementations double or less. Actually, max_size provides enough information to vector that a good implementation shouldn't need to exceed it. vector could and should catch the bad_alloc and retry the allocation with max_size. However, GNU doesn't do this, it only uses max_size if the size overflows, which is kind of bizarre. As with everything allocator-related, the standard is discombobulated on the issue. –  Potatoswatter Aug 25 '10 at 7:46
@Potatoswatter: I like the allocator-idea, but in my case the limit needs to be the size of the current array, so I have no choice. Is an allocator that owns a fixed array an option? –  stefaanv Aug 25 '10 at 7:49

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