MonsterDefense/lib/eastl/include/EASTL/internal/generic_iterator.h

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///////////////////////////////////////////////////////////////////////////////
// EASTL/internal/generic_iterator.h
//
// Written and maintained by Paul Pedriana - 2005.
///////////////////////////////////////////////////////////////////////////////

///////////////////////////////////////////////////////////////////////////////
// Implements a generic iterator from a given iteratable type, such as a pointer.
// We cannot put this file into our own iterator.h file because we need to 
// still be able to use this file when we have our iterator.h disabled.
//
///////////////////////////////////////////////////////////////////////////////


#ifndef EASTL_INTERNAL_GENERIC_ITERATOR_H
#define EASTL_INTERNAL_GENERIC_ITERATOR_H


#include <EASTL/internal/config.h>
#include <EASTL/iterator.h>
#include <EASTL/type_traits.h>


#ifdef _MSC_VER
    #pragma warning(push)           // VC++ generates a bogus warning that you cannot code away.
    #pragma warning(disable: 4619)  // There is no warning number 'number'.
    #pragma warning(disable: 4217)  // Member template functions cannot be used for copy-assignment or copy-construction.
#endif


namespace eastl
{

    /// generic_iterator
    ///
    /// Converts something which can be iterated into a formal iterator.
    /// While this class' primary purpose is to allow the conversion of 
    /// a pointer to an iterator, you can convert anything else to an 
    /// iterator by defining an iterator_traits<> specialization for that
    /// object type. See EASTL iterator.h for this.
    ///
    /// Example usage:
    ///     typedef generic_iterator<int*>       IntArrayIterator;
    ///     typedef generic_iterator<int*, char> IntArrayIteratorOther;
    ///
    template <typename Iterator, typename Container = void>
    class generic_iterator
    {
    protected:
        Iterator mIterator;

    public:
        typedef typename eastl::iterator_traits<Iterator>::iterator_category iterator_category;
        typedef typename eastl::iterator_traits<Iterator>::value_type        value_type;
        typedef typename eastl::iterator_traits<Iterator>::difference_type   difference_type;
        typedef typename eastl::iterator_traits<Iterator>::reference         reference;
        typedef typename eastl::iterator_traits<Iterator>::pointer           pointer;
        typedef Iterator                                                     iterator_type;
        typedef Container                                                    container_type;
        typedef generic_iterator<Iterator, Container>                        this_type;

        generic_iterator()
            : mIterator(iterator_type()) { }

        explicit generic_iterator(const iterator_type& x)
            : mIterator(x) { }

        this_type& operator=(const iterator_type& x)
            { mIterator = x; return *this; }

        template <typename Iterator2>
        generic_iterator(const generic_iterator<Iterator2, Container>& x)
            : mIterator(x.base()) { }

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

        pointer operator->() const
            { return mIterator; }

        this_type& operator++()
            { ++mIterator; return *this; }

        this_type operator++(int)
            { return this_type(mIterator++); }

        this_type& operator--()
            { --mIterator; return *this; }

        this_type operator--(int)
            { return this_type(mIterator--); }

        reference operator[](const difference_type& n) const
            { return mIterator[n]; }

        this_type& operator+=(const difference_type& n)
            { mIterator += n; return *this; }

        this_type operator+(const difference_type& n) const
            { return this_type(mIterator + n); }

        this_type& operator-=(const difference_type& n)
            { mIterator -= n; return *this; }

        this_type operator-(const difference_type& n) const
            { return this_type(mIterator - n); }

        const iterator_type& base() const
            { return mIterator; }

    }; // class generic_iterator





    template <typename IteratorL, typename IteratorR, typename Container>
    inline bool operator==(const generic_iterator<IteratorL, Container>& lhs, const generic_iterator<IteratorR, Container>& rhs)
        { return lhs.base() == rhs.base(); }

    template <typename Iterator, typename Container>
    inline bool operator==(const generic_iterator<Iterator, Container>& lhs, const generic_iterator<Iterator, Container>& rhs)
        { return lhs.base() == rhs.base(); }

    template <typename IteratorL, typename IteratorR, typename Container>
    inline bool operator!=(const generic_iterator<IteratorL, Container>& lhs, const generic_iterator<IteratorR, Container>& rhs)
        { return lhs.base() != rhs.base(); }

    template <typename Iterator, typename Container>
    inline bool operator!=(const generic_iterator<Iterator, Container>& lhs, const generic_iterator<Iterator, Container>& rhs)
        { return lhs.base() != rhs.base(); }

    template <typename IteratorL, typename IteratorR, typename Container>
    inline bool operator<(const generic_iterator<IteratorL, Container>& lhs, const generic_iterator<IteratorR, Container>& rhs)
        { return lhs.base() < rhs.base(); }

    template <typename Iterator, typename Container>
    inline bool operator<(const generic_iterator<Iterator, Container>& lhs, const generic_iterator<Iterator, Container>& rhs)
        { return lhs.base() < rhs.base(); }

    template <typename IteratorL, typename IteratorR, typename Container>
    inline bool operator>(const generic_iterator<IteratorL, Container>& lhs, const generic_iterator<IteratorR, Container>& rhs)
        { return lhs.base() > rhs.base(); }

    template <typename Iterator, typename Container>
    inline bool operator>(const generic_iterator<Iterator, Container>& lhs, const generic_iterator<Iterator, Container>& rhs)
        { return lhs.base() > rhs.base(); }

    template <typename IteratorL, typename IteratorR, typename Container>
    inline bool operator<=(const generic_iterator<IteratorL, Container>& lhs, const generic_iterator<IteratorR, Container>& rhs)
        { return lhs.base() <= rhs.base(); }

    template <typename Iterator, typename Container>
    inline bool operator<=(const generic_iterator<Iterator, Container>& lhs, const generic_iterator<Iterator, Container>& rhs)
        { return lhs.base() <= rhs.base(); }

    template <typename IteratorL, typename IteratorR, typename Container>
    inline bool operator>=(const generic_iterator<IteratorL, Container>& lhs, const generic_iterator<IteratorR, Container>& rhs)
        { return lhs.base() >= rhs.base(); }

    template <typename Iterator, typename Container>
    inline bool operator>=(const generic_iterator<Iterator, Container>& lhs, const generic_iterator<Iterator, Container>& rhs)
        { return lhs.base() >= rhs.base(); }

    template <typename IteratorL, typename IteratorR, typename Container>
    inline typename generic_iterator<IteratorL, Container>::difference_type
    operator-(const generic_iterator<IteratorL, Container>& lhs, const generic_iterator<IteratorR, Container>& rhs)
        { return lhs.base() - rhs.base(); }

    template <typename Iterator, typename Container>
    inline generic_iterator<Iterator, Container>
    operator+(typename generic_iterator<Iterator, Container>::difference_type n, const generic_iterator<Iterator, Container>& x)
        { return generic_iterator<Iterator, Container>(x.base() + n); }



    /// is_generic_iterator
    ///
    /// Tells if an iterator is one of these generic_iterators. This is useful if you want to 
    /// write code that uses miscellaneous iterators but wants to tell if they are generic_iterators.
    /// A primary reason to do so is that you can get at the pointer within the generic_iterator.
    ///
    template <typename Iterator>
    struct is_generic_iterator : public false_type { };

    template <typename Iterator, typename Container>
    struct is_generic_iterator<generic_iterator<Iterator, Container> > : public true_type { };


} // namespace eastl


#ifdef _MSC_VER
    #pragma warning(pop)
#endif


#endif // Header include guard