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Are there guidelines on how one should write new container which will behave like any STL container?

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See the implementations of the existing standard containers, and try to understand them - the functions, the return types, operator overloads, nested types, memory management and all. – Nawaz Oct 13 '11 at 18:19
I usually start by copying the member function prototypes of whichever container is closest in concept to what I'm doing, either from msdn, or the standard. ( does not have C++11 functions, and doesn't match) – Mooing Duck Oct 13 '11 at 18:28
@Mooing Duck: you think msdn is closer to the standard than sgi? – Dani Oct 13 '11 at 18:36
It definitely is. MSDN is current - SGI is pre-Standard – Puppy Oct 13 '11 at 18:50
The best online reference (wrt completeness, correctness and especially usability) is by far It also explains a ton of language features aside from the library. And it's a wiki, so it should contain less errors than – rubenvb Aug 20 '13 at 17:47
up vote 129 down vote accepted

Here's a sequence pseudo-container I pieced together from § 23.2.1\4 Note that the iterator_category should be one of std::input_iterator_tag, std::output_iterator_tag,std::forward_iterator_tag,std::bidirectional_iterator_tag,std::random_access_iterator_tag. Also note that the below is technically more strict than required, but this is the idea. Note that the vast majority of the "standard" functions are technically optional, due to the awesomeness that is iterators.

template <class T, class A = std::allocator<T> >
class X {
    typedef A allocator_type;
    typedef typename A::value_type value_type; 
    typedef typename A::reference reference;
    typedef typename A::const_reference const_reference;
    typedef typename A::difference_type difference_type;
    typedef typename A::size_type size_type;

    class iterator { 
        typedef typename A::difference_type difference_type;
        typedef typename A::value_type value_type;
        typedef typename A::reference reference;
        typedef typename A::pointer pointer;
        typedef std::random_access_iterator_tag iterator_category; //or another tag

        iterator(const iterator&);

        iterator& operator=(const iterator&);
        bool operator==(const iterator&) const;
        bool operator!=(const iterator&) const;
        bool operator<(const iterator&) const; //optional
        bool operator>(const iterator&) const; //optional
        bool operator<=(const iterator&) const; //optional
        bool operator>=(const iterator&) const; //optional

        iterator& operator++();
        iterator operator++(int); //optional
        iterator& operator--(); //optional
        iterator operator--(int); //optional
        iterator& operator+=(size_type); //optional
        iterator operator+(size_type) const; //optional
        friend iterator operator+(size_type, const iterator&); //optional
        iterator& operator-=(size_type); //optional            
        iterator operator-(size_type) const; //optional
        difference_type operator-(iterator) const; //optional

        reference operator*() const;
        pointer operator->() const;
        reference operator[](size_type) const; //optional
    class const_iterator {
        typedef typename A::difference_type difference_type;
        typedef typename A::value_type value_type;
        typedef typename A::reference const_reference;
        typedef typename A::pointer const_pointer;
        typedef std::random_access_iterator_tag iterator_category; //or another tag

        const_iterator ();
        const_iterator (const const_iterator&);
        const_iterator (const iterator&);

        const_iterator& operator=(const const_iterator&);
        bool operator==(const const_iterator&) const;
        bool operator!=(const const_iterator&) const;
        bool operator<(const const_iterator&) const; //optional
        bool operator>(const const_iterator&) const; //optional
        bool operator<=(const const_iterator&) const; //optional
        bool operator>=(const const_iterator&) const; //optional

        const_iterator& operator++();
        const_iterator operator++(int); //optional
        const_iterator& operator--(); //optional
        const_iterator operator--(int); //optional
        const_iterator& operator+=(size_type); //optional
        const_iterator operator+(size_type) const; //optional
        friend const_iterator operator+(size_type, const const_iterator&); //optional
        const_iterator& operator-=(size_type); //optional            
        const_iterator operator-(size_type) const; //optional
        difference_type operator-(const_iterator) const; //optional

        const_reference operator*() const;
        const_pointer operator->() const;
        const_reference operator[](size_type) const; //optional

    typedef std::reverse_iterator<iterator> reverse_iterator; //optional
    typedef std::reverse_iterator<const_iterator> const_reverse_iterator; //optional

    X(const X&);

    X& operator=(const X&);
    bool operator==(const X&) const;
    bool operator!=(const X&) const;
    bool operator<(const X&) const; //optional
    bool operator>(const X&) const; //optional
    bool operator<=(const X&) const; //optional
    bool operator>=(const X&) const; //optional

    iterator begin();
    const_iterator begin() const;
    const_iterator cbegin() const;
    iterator end();
    const_iterator end() const;
    const_iterator cend() const;
    reverse_iterator rbegin(); //optional
    const_reverse_iterator rbegin() const; //optional
    const_reverse_iterator crbegin() const; //optional
    reverse_iterator rend(); //optional
    const_reverse_iterator rend() const; //optional
    const_reverse_iterator crend() const; //optional

    reference front(); //optional
    const_reference front() const; //optional
    reference back(); //optional
    const_reference back() const; //optional
    template<class ...Args>
    void emplace_front(Args...); //optional
    template<class ...Args>
    void emplace_back(Args...); //optional
    void push_front(const T&); //optional
    void push_front(T&&); //optional
    void push_back(const T&); //optional
    void push_back(T&&); //optional
    void pop_front(); //optional
    void pop_back(); //optional
    reference operator[](size_type); //optional
    const_reference operator[](size_type) const; //optional
    reference at(size_type); //optional
    const_reference at(size_type) const; //optional

    template<class ...Args>
    iterator emplace(const_iterator, Args...); //optional
    iterator insert(const_iterator, const T&); //optional
    iterator insert(const_iterator, T&&); //optional
    iterator insert(const_iterator, size_type, T&); //optional
    template<class iter>
    iterator insert(const_iterator, iter, iter); //optional
    iterator insert(const_iterator, std::initializer_list<T>); //optional
    iterator erase(const_iterator); //optional
    iterator erase(const_iterator, const_iterator); //optional
    void clear(); //optional
    template<class iter>
    void assign(iter, iter); //optional
    void assign(std::initializer_list<T>); //optional
    void assign(size_type, const T&); //optional

    void swap(X&);
    size_type size();
    size_type max_size();
    bool empty();

    A get_allocator(); //optional
template <class T, class A = std::allocator<T> >
void swap(X<T,A>&, X<T,A>&); //optional

Also, whenever I make a container, I test with a class more or less like this:

#include <cassert>
struct verify;
class tester {
    friend verify;
    static int livecount;
    const tester* self;
    tester() :self(this) {++livecount;}
    tester(const tester&) :self(this) {++livecount;}
    ~tester() {assert(self==this);--livecount;}
    tester& operator=(const tester& b) {
        assert(self==this && b.self == &b);
        return *this;
    void cfunction() const {assert(self==this);}
    void mfunction() {assert(self==this);}
int tester::livecount=0;
struct verify {
    ~verify() {assert(tester::livecount==0);}

Make containers of tester objects, and call each one's function() as you test your container. Do not make any global tester objects. If your container cheats anywhere, this tester class will assert and you'll know that you cheated accidentally somewhere.

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This is interesting. How does your tester work? There are several parse errors, which are trivial (missing ';') but not sure how that verify destructor works. Oh, you meant assert(tester::livecount == 0);. Mmmmm, still not sure how this tester framework works. Could you give an example? – Adrian Dec 24 '14 at 19:17
The tester has a single nonstatic member that's a pointer to itself, and the destructor and members are a way to check that no invalid memcpy happened. (test isn't foolproof, but it catches some). The livecount is a simple leak detector, to make sure your container called an equal number of constructors and destructors. – Mooing Duck Dec 24 '14 at 20:45
Ok, I see that, but how does that test your iterator? BTW, I think you meant verifier not varifier. – Adrian Dec 24 '14 at 21:14
@Adrian No no, you write your container, and then put a bunch of these in the container, and do things with the container, to verify that you didn't accidentally memcpy, and rememebered to call all the destructors. – Mooing Duck Dec 24 '14 at 22:12
Ah, I see. Makes sense. Thanks. :) – Adrian Dec 26 '14 at 2:59

You will need to read the C++ Standard section about Containers and requirements the C++ Standard imposes for container implementations.

The relevant chapter in C++03 standard is:

Section 23.1 Container Requirements

The relevant chapter in C++11 standard is:

Section 23.2 Container Requirements

The near-final draft of the C++11 standard is freely available here.

You might as well, read some excellent books which will help you understand the requirements from an perspective of user of the container. Two excellent books which struck my mind easily are:

Effective STL by Scott Meyers &
The C++ Standard Library: A Tutorial and Reference by Nicolai Josutils

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