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I have a class TContainer that is an aggregate of several stl collections pointers to TItems class.

I need to create an Iterator to traverse the elements in all the collections in my TContainer class abstracting the client of the inner workings.

What would be a good way to do this?. Should I crate a class that extends an iterator (if so, what iterator class should I extend), should I create an iterator class that is an aggregate of iterators?

I only need a FORWARD_ONLY iterator.

I.E, If this is my container:

typedef std::vector <TItem*> ItemVector;
class TContainer {
   std::vector <ItemVector *> m_Items;
};

What would be a good Iterator to traverse all the items contained in the vectors of the m_Items member variable.

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Can you tell us more about your container and iterator? For example, is the iterator bi-directional? –  joshdick May 8 '09 at 14:13
    
Thanks, I edited my question to clarify your question. –  Sugar May 8 '09 at 14:21
    
You really want m_items to be a vector of pointers? Why not just a vector of ItemVector? –  Loki Astari May 8 '09 at 17:45
    
See also: stackoverflow.com/questions/1724009/… Instead of deriving from std::iterator I would recommend taking the std::iterator_traits route :) –  legends2k Sep 22 '11 at 20:18
    
Why using std::iterator traits is considered better than deriving from the std::iterator interface? –  SasQ Dec 13 '12 at 5:43
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6 Answers 6

up vote 24 down vote accepted

When I did my own iterator (a while ago now) I inherited from std::iterator and specified the type as the first template parameter. Hope that helps.

For forward iterators user forward_iterator_tag rather than input_iterator_tag in the following code.

This class was originally taken from istream_iterator class (and modified for my own use so it may not resemble the istram_iterator any more).

template<typename T>
class <PLOP>_iterator
         :public std::iterator<std::input_iterator_tag,       // type of iterator
                               T,ptrdiff_t,const T*,const T&> // Info about iterator
{
    public:
        const T& operator*() const;
        const T* operator->() const;
        <PLOP>__iterator& operator++();
        <PLOP>__iterator operator++(int);
        bool equal(<PLOP>__iterator const& rhs) const;
};

template<typename T>
inline bool operator==(<PLOP>__iterator<T> const& lhs,<PLOP>__iterator<T> const& rhs)
{
    return lhs.equal(rhs);
}

Check this documentation on iterator tags:
http://www.sgi.com/tech/stl/iterator_tags.html

Having just re-read the information on iterators:
http://www.sgi.com/tech/stl/iterator_traits.html

This is the old way of doing things (iterator_tags) the more modern approach is to set up iterator_traits<> for your iterator to make it fully compatible with the STL.

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3  
How is your own iterator_traits specialization more compatible with the STL than inheriting from std::iterator? –  Roger Pate Feb 20 '10 at 21:45
7  
std::iterator has default arguments for reference and pointer types, so you don't have to type them in your example. And making your class inherit from std::iterator automatically specializes the iterator_traits for you, so it is the modern way of writing iterators. –  Alexandre C. Jul 19 '10 at 16:26
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If you have access to Boost, using iterator_facade is the most robust solution, and it's pretty simple to use.

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First let's generalize a little bit:

typedef int value_type;
typedef std::vector<value_type*> inner_range;
typedef std::vector<inner_range*> outer_range;

Now the iterator:

struct my_iterator : std::iterator_traits<inner_range::iterator> 
{
    typedef std::forward_iterator_tag iterator_category;

    my_iterator(outer_range::iterator const & outer_iterator, 
                outer_range::iterator const & outer_end)
    : outer_iterator(outer_iterator), outer_end(outer_end)
    { 
        update();
    }

    my_iterator & operator++()
    {
        ++inner_iterator;
        if(inner_iterator == inner_end)
        {
            ++outer_iterator;
            update();
        }
        return *this;
    }

    reference operator*() const
    {   
        return *inner_iterator;
    }

    bool operator==(my_iterator const & rhs) const
    {   
        bool lhs_end = outer_iterator == outer_end;
        bool rhs_end = rhs.outer_iterator == rhs.outer_end;
        if(lhs_end && rhs_end)
            return true;
        if(lhs_end != rhs_end)
            return false;
        return outer_iterator == rhs.outer_iterator 
            && inner_iterator == rhs.inner_iterator;
    }

private:

    outer_range::iterator outer_iterator, outer_end;
    inner_range::iterator inner_iterator, inner_end;

    void update()
    {
        while(outer_iterator != outer_end)
        {
            inner_iterator = (*outer_iterator)->begin();
            inner_end = (*outer_iterator)->end();
            if(inner_iterator == inner_end)
                ++outer_iterator;
            else
                break;
        }
    }    
};

This class assumes than the outer iterators contain pointers to the inner ranges, which was a requirement in your question. This is reflected in the update member, in the arrows before begin() and end(). You can replace these arrows with dots if you want to use this class in the more common situation where the outer iterator contains the inner ranges by value. Note BTW that this class is agnostic to the fact that the inner range contains pointers, only clients of the class will need to know that.

The code could be shorter if we use boost::iterator_facade but it's not necessary to add a boost dependency for something so simple. Besides, the only tricky parts are the equality and increment operations, and we have to code those anyway.

I've left the following boiler-plate members as "exercises for the reader":

  • postfix increment iterator
  • operator!=
  • default constructor
  • operator->

Another interesting exercise is to turn this into a template which works with arbitrary containers. The code is basically the same except that you have to add typename annotations in a few places.

Example of use:

int main()
{
    outer_type outer;
    int a = 0, b = 1, c = 2;
    inner_type inner1, inner2;
    inner1.push_back(&a);
    inner1.push_back(&b);
    inner2.push_back(&c);
    outer.push_back(&inner1);
    outer.push_back(&inner2);

    my_iterator it(outer.begin(), outer.end());
                e(outer.end(), outer.end());
    for(; it != e; ++it)
        std::cout << **it << "\n";
}

Which prints:

0 1 2

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+1. Clear, concise answer. Thanks! –  viksit Apr 8 '10 at 3:45
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An iterator is just a class that supports a certain interface. At minimum, you will want to be able to:

  • increment and/or decrement it
  • dereference it to get the object it "points" to
  • test it for equality and inequality
  • copy and assign it

Once you have a class that can do that sensibly for your collection, you will need to modify the collection to have functions that return iterators. At minimum you will want

  • a begin() function that returns an instance of your new iterator type positioned at the first element
  • an end() function that returns an iterator which is (possibly notionally) positioned at one past the end of the items in your container
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Its a bit more complicated than that. Add Iterator_traits<> to your list and you are done. –  Loki Astari May 8 '09 at 14:41
1  
You can use iterators without the traits. –  anon May 8 '09 at 14:46
    
I know - but lots of people never use those algorithms. I think it's better for people to build a non-template version first, not inheriting from std::iterator, and then templatising it after they get everything working. Others may disagree, of course. –  anon May 8 '09 at 15:54
    
The keyword there is 'You', but the STL relies on the traits when you use iterators in any of the non trivial algorithms (and even a lot of the trivial ones). The Iterator by-itself is not actually defined it is just a laymen term to describe the 6 iterator concepts defined by the standard. Each of these concepts has a requirement of specific type information being available. –  Loki Astari May 8 '09 at 16:01
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Check the Views Template Library.

Especially check

  1. Union View presenting two containers concatenated.
  2. Concatenation View presenting a collection of containers concatenated.
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This is the simplest code I was able to produce (for custom iterators). Note that I'm only beginning to explore this area. This calls built-in upper_bound function to perform binary search on an integer function, x^2 as an example.

#include <algorithm>
#include <iostream>

using namespace std;

class Iter
{
  public:
  int x;
  Iter() { x = -1; }
  Iter(int a) { x = a; }

  bool operator!=(Iter &i2) const { return x != i2.x; }
  void operator++() { x++; }
  void operator+=(int b) { x += b; }
  int operator-(const Iter &i2) const { return x - i2.x; }
  int operator*() const {
    cout << "calculating for x " << x << endl;
    return x*x;
  }

  typedef random_access_iterator_tag iterator_category;
  typedef int value_type;
  typedef int difference_type;
  typedef int* pointer;
  typedef int& reference;
};

main ()
{
  ios::sync_with_stdio(false);
  cout << upper_bound(Iter(0), Iter(100), 40).x << endl;
}

// :collapseFolds=1:folding=explicit:

And this is how the output looks like:

calculating for x 50
calculating for x 25
calculating for x 12
calculating for x 6
calculating for x 9
calculating for x 8
calculating for x 7
7
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