218

I have a custom container class for which I'd like to write the iterator and const_iterator classes.

I never did this before and I failed to find an appropriate how-to. What are the guidelines regarding iterator creation, and what should I be aware of ?

I'd also like to avoid code duplication (I feel that const_iterator and iterator share many things; should one subclass the other ?).

Foot note: I'm pretty sure Boost has something to ease this but I can't use it here, for many stupid reasons.

149
  • Choose type of iterator which fits your container: input, output, forward etc.
  • Use base iterator classes from standard library. For example, std::iterator with random_access_iterator_tag.These base classes define all type definitions required by STL and do other work.
  • To avoid code duplication iterator class should be a template class and be parametrized by "value type", "pointer type", "reference type" or all of them (depends on implementation). For example:

    // iterator class is parametrized by pointer type
    template <typename PointerType> class MyIterator {
        // iterator class definition goes here
    };
    
    typedef MyIterator<int*> iterator_type;
    typedef MyIterator<const int*> const_iterator_type;
    

    Notice iterator_type and const_iterator_type type definitions: they are types for your non-const and const iterators.

See Also: standard library reference

EDIT: std::iterator is deprecated since C++17. See a relating discussion here.

  • @Andrey Could you explain the distinction between value type, pointer type, and reference type? – radicalmatt Jul 26 '12 at 19:52
  • 8
    @Potatoswatter: Have not downvoted this, but, hey, random_access_iterator is not in the standard and the answer does not handle the mutable to const conversion. You probably want to inherit from, e.g. std::iterator<random_access_iterator_tag, value_type, ... optional arguments ...> though. – ybungalobill Oct 8 '12 at 14:55
  • 2
    Yeah, I'm not quite sure how this works. If I have the method RefType operator*() { ... }, I'm one step closer -- but it doesn't help, because I still need RefType operator*() const { ... }. – Doctor Mohawk Sep 5 '13 at 5:42
  • 30
    std::iterator is proposed for deprecation in C++17. – TypeIA Jul 14 '16 at 2:26
  • 18
    std::iterator has been deprecated – diapir Feb 14 '18 at 8:25
49

I'm going to show you how you can easily define iterators for your custom containers, but just in case I have created a c++11 library that allows you to easily create custom iterators with custom behavior for any type of container, contiguous or non-constiguous.

You can find it on github at https://github.com/navyenzo/blIteratorAPI

Here are the simple steps to creating and using custom iterators:

  1. Create your "custom iterator" class.
  2. Define typedefs in your "custom container" class.
    • For ex: typedef blRawIterator< Type > iterator;
    • For ex: typedef blRawIterator< const Type > const_iterator;
  3. Define "begin" "end" functions
    • For ex: iterator begin(){return iterator(&m_data[0]);};
    • For ex: const_iterator cbegin()const{return const_iterator(&m_data[0]);};
  4. We're Done!!!

Finally, onto defining our custom iterator classes:

NOTE: When defining custom iterators, we derive from the standard iterator categories to let STL algorithms know the type of iterator we've made

In this example, I define a random access iterator and a reverse random access iterator:

1.

//-------------------------------------------------------------------
// Raw iterator with random access
//-------------------------------------------------------------------
template<typename blDataType>
class blRawIterator
{
public:

    using iterator_category = std::random_access_iterator_tag;
    using value_type = blDataType;
    using difference_type = ptrdiff_t;
    using pointer = blDataType*;
    using reference = blDataType&;

public:

    blRawIterator(blDataType* ptr = nullptr){m_ptr = ptr;}
    blRawIterator(const blRawIterator<blDataType>& rawIterator) = default;
    ~blRawIterator(){}

    blRawIterator<blDataType>&                  operator=(const blRawIterator<blDataType>& rawIterator) = default;
    blRawIterator<blDataType>&                  operator=(blDataType* ptr){m_ptr = ptr;return (*this);}

    operator                                    bool()const
    {
        if(m_ptr)
            return true;
        else
            return false;
    }

    bool                                        operator==(const blRawIterator<blDataType>& rawIterator)const{return (m_ptr == rawIterator.getConstPtr());}
    bool                                        operator!=(const blRawIterator<blDataType>& rawIterator)const{return (m_ptr != rawIterator.getConstPtr());}

    blRawIterator<blDataType>&                  operator+=(const ptrdiff_t& movement){m_ptr += movement;return (*this);}
    blRawIterator<blDataType>&                  operator-=(const ptrdiff_t& movement){m_ptr -= movement;return (*this);}
    blRawIterator<blDataType>&                  operator++(){++m_ptr;return (*this);}
    blRawIterator<blDataType>&                  operator--(){--m_ptr;return (*this);}
    blRawIterator<blDataType>                   operator++(ptrdiff_t){auto temp(*this);++m_ptr;return temp;}
    blRawIterator<blDataType>                   operator--(ptrdiff_t){auto temp(*this);--m_ptr;return temp;}
    blRawIterator<blDataType>                   operator+(const ptrdiff_t& movement){auto oldPtr = m_ptr;m_ptr+=movement;auto temp(*this);m_ptr = oldPtr;return temp;}
    blRawIterator<blDataType>                   operator-(const ptrdiff_t& movement){auto oldPtr = m_ptr;m_ptr-=movement;auto temp(*this);m_ptr = oldPtr;return temp;}

    ptrdiff_t                                   operator-(const blRawIterator<blDataType>& rawIterator){return std::distance(rawIterator.getPtr(),this->getPtr());}

    blDataType&                                 operator*(){return *m_ptr;}
    const blDataType&                           operator*()const{return *m_ptr;}
    blDataType*                                 operator->(){return m_ptr;}

    blDataType*                                 getPtr()const{return m_ptr;}
    const blDataType*                           getConstPtr()const{return m_ptr;}

protected:

    blDataType*                                 m_ptr;
};
//-------------------------------------------------------------------

2.

//-------------------------------------------------------------------
// Raw reverse iterator with random access
//-------------------------------------------------------------------
template<typename blDataType>
class blRawReverseIterator : public blRawIterator<blDataType>
{
public:

    blRawReverseIterator(blDataType* ptr = nullptr):blRawIterator<blDataType>(ptr){}
    blRawReverseIterator(const blRawIterator<blDataType>& rawIterator){this->m_ptr = rawIterator.getPtr();}
    blRawReverseIterator(const blRawReverseIterator<blDataType>& rawReverseIterator) = default;
    ~blRawReverseIterator(){}

    blRawReverseIterator<blDataType>&           operator=(const blRawReverseIterator<blDataType>& rawReverseIterator) = default;
    blRawReverseIterator<blDataType>&           operator=(const blRawIterator<blDataType>& rawIterator){this->m_ptr = rawIterator.getPtr();return (*this);}
    blRawReverseIterator<blDataType>&           operator=(blDataType* ptr){this->setPtr(ptr);return (*this);}

    blRawReverseIterator<blDataType>&           operator+=(const ptrdiff_t& movement){this->m_ptr -= movement;return (*this);}
    blRawReverseIterator<blDataType>&           operator-=(const ptrdiff_t& movement){this->m_ptr += movement;return (*this);}
    blRawReverseIterator<blDataType>&           operator++(){--this->m_ptr;return (*this);}
    blRawReverseIterator<blDataType>&           operator--(){++this->m_ptr;return (*this);}
    blRawReverseIterator<blDataType>            operator++(ptrdiff_t){auto temp(*this);--this->m_ptr;return temp;}
    blRawReverseIterator<blDataType>            operator--(ptrdiff_t){auto temp(*this);++this->m_ptr;return temp;}
    blRawReverseIterator<blDataType>            operator+(const int& movement){auto oldPtr = this->m_ptr;this->m_ptr-=movement;auto temp(*this);this->m_ptr = oldPtr;return temp;}
    blRawReverseIterator<blDataType>            operator-(const int& movement){auto oldPtr = this->m_ptr;this->m_ptr+=movement;auto temp(*this);this->m_ptr = oldPtr;return temp;}

    ptrdiff_t                                   operator-(const blRawReverseIterator<blDataType>& rawReverseIterator){return std::distance(this->getPtr(),rawReverseIterator.getPtr());}

    blRawIterator<blDataType>                   base(){blRawIterator<blDataType> forwardIterator(this->m_ptr); ++forwardIterator; return forwardIterator;}
};
//-------------------------------------------------------------------

Now somewhere in your custom container class:

template<typename blDataType>
class blCustomContainer
{
public: // The typedefs

    typedef blRawIterator<blDataType>              iterator;
    typedef blRawIterator<const blDataType>        const_iterator;

    typedef blRawReverseIterator<blDataType>       reverse_iterator;
    typedef blRawReverseIterator<const blDataType> const_reverse_iterator;

                            .
                            .
                            .

public:  // The begin/end functions

    iterator                                       begin(){return iterator(&m_data[0]);}
    iterator                                       end(){return iterator(&m_data[m_size]);}

    const_iterator                                 cbegin(){return const_iterator(&m_data[0]);}
    const_iterator                                 cend(){return const_iterator(&m_data[m_size]);}

    reverse_iterator                               rbegin(){return reverse_iterator(&m_data[m_size - 1]);}
    reverse_iterator                               rend(){return reverse_iterator(&m_data[-1]);}

    const_reverse_iterator                         crbegin(){return const_reverse_iterator(&m_data[m_size - 1]);}
    const_reverse_iterator                         crend(){return const_reverse_iterator(&m_data[-1]);}

                            .
                            .
                            .
    // This is the pointer to the
    // beginning of the data
    // This allows the container
    // to either "view" data owned
    // by other containers or to
    // own its own data
    // You would implement a "create"
    // method for owning the data
    // and a "wrap" method for viewing
    // data owned by other containers

    blDataType*                                    m_data;
};

GOOD LUCK!!!

  • I think the operator+ and operator- may have the operations backwards. It looks like operator+ is subtracting movement from the pointer not adding and operator- is adding it. This seems backwards – Beached Jun 18 '17 at 1:13
  • It's for the reverse iterator, operator+ should go backwards and operator- should go forward – Enzo Sep 6 '17 at 18:39
  • 1
    Awesome. The accepted answer is too high level. This is awesome. Thank you Enzo. – FernandoZ Nov 19 '17 at 21:11
  • You need to edit your answer. Assuming m_data was allocated with m_size elements you get Undefined Behavior: m_data[m_size] is UB. You can simply fix it by replacing it with m_data+m_size. For reverse iterators, both m_data[-1] and m_data-1 are incorrect (UB). To fix reverse_iterators you will need to use the "pointers to next element trick". – Arnaud Jun 11 '18 at 14:55
  • Arnaud, I just added the pointer member to the custom container class that better shows what I meant. – Enzo Jun 11 '18 at 15:28
23

Boost has something to help: the Boost.Iterator library.

More precisely this page: boost::iterator_adaptor.

What's very interesting is the Tutorial Example which shows a complete implementation, from scratch, for a custom type.

template <class Value>
class node_iter
  : public boost::iterator_adaptor<
        node_iter<Value>                // Derived
      , Value*                          // Base
      , boost::use_default              // Value
      , boost::forward_traversal_tag    // CategoryOrTraversal
    >
{
 private:
    struct enabler {};  // a private type avoids misuse

 public:
    node_iter()
      : node_iter::iterator_adaptor_(0) {}

    explicit node_iter(Value* p)
      : node_iter::iterator_adaptor_(p) {}

    // iterator convertible to const_iterator, not vice-versa
    template <class OtherValue>
    node_iter(
        node_iter<OtherValue> const& other
      , typename boost::enable_if<
            boost::is_convertible<OtherValue*,Value*>
          , enabler
        >::type = enabler()
    )
      : node_iter::iterator_adaptor_(other.base()) {}

 private:
    friend class boost::iterator_core_access;
    void increment() { this->base_reference() = this->base()->next(); }
};

The main point, as has been cited already, is to use a single template implementation and typedef it.

  • Can you explain the meaning of this comment? // a private type avoids misuse – kevinarpe Feb 7 '17 at 6:39
  • @kevinarpe: enabler is never intended to be provider by the caller, so my guess is that they make it private to avoid people accidentally attempting to pass it. I don't think, off hand, that it could create any issue to actually pass it, since the protection lies in enable_if. – Matthieu M. Feb 7 '17 at 7:25
22

They often forget that iterator must convert to const_iterator but not the other way around. Here is a way to do that:

template<class T, class Tag = void>
class IntrusiveSlistIterator
   : public std::iterator<std::forward_iterator_tag, T>
{
    typedef SlistNode<Tag> Node;
    Node* node_;

public:
    IntrusiveSlistIterator(Node* node);

    T& operator*() const;
    T* operator->() const;

    IntrusiveSlistIterator& operator++();
    IntrusiveSlistIterator operator++(int);

    friend bool operator==(IntrusiveSlistIterator a, IntrusiveSlistIterator b);
    friend bool operator!=(IntrusiveSlistIterator a, IntrusiveSlistIterator b);

    // one way conversion: iterator -> const_iterator
    operator IntrusiveSlistIterator<T const, Tag>() const;
};

In the above notice how IntrusiveSlistIterator<T> converts to IntrusiveSlistIterator<T const>. If T is already const this conversion never gets used.

  • Actually, you can also do it the other way around by defining a copy constructor that is template, it won't compile if you try to cast the underlying type from const to non-const. – Matthieu M. Aug 27 '10 at 9:48
  • Won't you end up with an invalid IntrusiveSlistIterator<T const, void>::operator IntrusiveSlistIterator<T const, void>() const? – Potatoswatter Aug 27 '10 at 9:56
  • Ah, it is valid, but Comeau gives a warning and I suspect a lot of others will as well. An enable_if might fix it, but… – Potatoswatter Aug 27 '10 at 9:59
  • I did not bother with enable_if because the compiler disables it anyway, although some compilers give a warning (g++ being a good boy does not warn). – Maxim Egorushkin Aug 27 '10 at 10:05
  • 1
    @Matthieu: If one goes with a template constructor, when converting const_iterator to iterator the compiler produces an error inside the constructor, making the user scratch his head in confusion and utter wtf. With the conversion operator I posted, the compiler just says that there is no suitable conversion from const_iterator to iterator, which, IMO, is more clear. – Maxim Egorushkin Aug 27 '10 at 10:08
16

I don't know if Boost has anything that would help.

My preferred pattern is simple: take a template argument which is equal to value_type, either const qualified or not. If necessary, also a node type. Then, well, everything kind of falls into place.

Just remember to parameterize (template-ize) everything that needs to be, including the copy constructor and operator==. For the most part, the semantics of const will create correct behavior.

template< class ValueType, class NodeType >
struct my_iterator
 : std::iterator< std::bidirectional_iterator_tag, T > {
    ValueType &operator*() { return cur->payload; }

    template< class VT2, class NT2 >
    friend bool operator==
        ( my_iterator const &lhs, my_iterator< VT2, NT2 > const &rhs );

    // etc.

private:
    NodeType *cur;

    friend class my_container;
    my_iterator( NodeType * ); // private constructor for begin, end
};

typedef my_iterator< T, my_node< T > > iterator;
typedef my_iterator< T const, my_node< T > const > const_iterator;
  • Note: it looks like your conversions iterator->const_iterator and back are broken. – Maxim Egorushkin Aug 27 '10 at 9:41
  • @Maxim: Yes, I can't actually find any examples of using my technique :vP . I'm not sure what you mean the conversions are broken, since I simply didn't illustrate them, but there might be an issue accessing cur from the iterator of opposite constness. The solution that comes to mind is friend my_container::const_iterator; friend my_container::iterator;, but I don't think that's how I did it before… anyway this general outline works. – Potatoswatter Aug 27 '10 at 9:52
  • 1
    * make that friend class in both cases. – Potatoswatter Aug 27 '10 at 10:01
  • It's been some time, but I recall now that the conversions should be predicated (by SFINAE) on the well-formedness of the underlying member initializations. This follows the SCARY pattern (but this post predates that terminology). – Potatoswatter Sep 24 '13 at 0:02
9

There are plenty of good answers but I created a template header I use that is quite concise and easy to use.

To add an iterator to your class it is only necessary to write a small class to represent the state of the iterator with 7 small functions, of which 2 are optional:

#include <iostream>
#include <vector>
#include "iterator_tpl.h"

struct myClass {
  std::vector<float> vec;

  // Add some sane typedefs for STL compliance:
  STL_TYPEDEFS(float);

  struct it_state {
    int pos;
    inline void begin(const myClass* ref) { pos = 0; }
    inline void next(const myClass* ref) { ++pos; }
    inline void end(const myClass* ref) { pos = ref->vec.size(); }
    inline float& get(myClass* ref) { return ref->vec[pos]; }
    inline bool cmp(const it_state& s) const { return pos != s.pos; }

    // Optional to allow operator--() and reverse iterators:
    inline void prev(const myClass* ref) { --pos; }
    // Optional to allow `const_iterator`:
    inline const float& get(const myClass* ref) const { return ref->vec[pos]; }
  };
  // Declare typedef ... iterator;, begin() and end() functions:
  SETUP_ITERATORS(myClass, float&, it_state);
  // Declare typedef ... reverse_iterator;, rbegin() and rend() functions:
  SETUP_REVERSE_ITERATORS(myClass, float&, it_state);
};

Then you can use it as you would expect from an STL iterator:

int main() {
  myClass c1;
  c1.vec.push_back(1.0);
  c1.vec.push_back(2.0);
  c1.vec.push_back(3.0);

  std::cout << "iterator:" << std::endl;
  for (float& val : c1) {
    std::cout << val << " "; // 1.0 2.0 3.0
  }

  std::cout << "reverse iterator:" << std::endl;
  for (auto it = c1.rbegin(); it != c1.rend(); ++it) {
    std::cout << *it << " "; // 3.0 2.0 1.0
  }
}

I hope it helps.

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