/*******************************************************************************
Tree Container Library: Generic container library to store data in tree-like structures.
Copyright (c) 2006 Mitchel Haas
This software is provided 'as-is', without any express or implied warranty.
In no event will the author be held liable for any damages arising from
the use of this software.
Permission is granted to anyone to use this software for any purpose,
including commercial applications, and to alter it and redistribute it freely,
subject to the following restrictions:
1. The origin of this software must not be misrepresented;
you must not claim that you wrote the original software.
If you use this software in a product, an acknowledgment in the product
documentation would be appreciated but is not required.
2. Altered source versions must be plainly marked as such,
and must not be misrepresented as being the original software.
3. The above copyright notice and this permission notice may not be removed
or altered from any source distribution.
For complete documentation on this library, see http://www.datasoftsolutions.net
Email questions, comments or suggestions to mhaas@datasoftsolutions.net
*******************************************************************************/
#pragma once
#include <set>
#include <stack>
#include <queue>
#include <algorithm>
#include <iterator>
/************************************************************************/
/* associative tree child iterators */
/************************************************************************/
// forward declaration
template<typename stored_type, typename tree_type, typename container_type> class basic_tree;
template<typename stored_type> class sequential_tree;
template<typename stored_type, typename tree_type, typename container_type> class associative_tree;
template<typename stored_type, typename tree_type, typename container_type> class associative_reverse_iterator;
template<typename stored_type, typename tree_type, typename container_type> class sequential_reverse_iterator;
template<typename stored_type, typename tree_type, typename container_type, typename tree_category_type> class const_pre_order_descendant_iterator;
template<typename stored_type, typename tree_type, typename container_type, typename tree_category_type> class const_post_order_descendant_iterator;
template<typename stored_type, typename tree_type, typename container_type>
class const_associative_iterator : public std::iterator<std::bidirectional_iterator_tag, stored_type>
{
// typedefs & friends
friend class basic_tree<stored_type, tree_type, container_type>;
friend class associative_tree<stored_type, tree_type, container_type>;
friend class const_pre_order_descendant_iterator<stored_type, tree_type, container_type, associative_tree<stored_type, tree_type, container_type> >;
friend class const_post_order_descendant_iterator<stored_type, tree_type, container_type, associative_tree<stored_type, tree_type, container_type> >;
public:
// constructors/destructor
const_associative_iterator() : pIt_parent(0) {}
protected:
explicit const_associative_iterator(typename container_type::const_iterator it_, const associative_tree<stored_type, tree_type, container_type>* pParent_) : it(it_), pIt_parent(pParent_) {}
// destructor, copy constructor, and assignment operator will be compiler generated correctly
public:
// overloaded operators
bool operator == (const const_associative_iterator& rhs ) const { return pIt_parent == rhs.pIt_parent && it == rhs.it; }
bool operator != (const const_associative_iterator& rhs ) const { return !(*this == rhs); }
const stored_type& operator*() const { return *(*it)->get(); }
const stored_type* operator->() const { return (*it)->get(); }
const_associative_iterator& operator ++() { ++it; return *this; }
const_associative_iterator operator ++(int) { const_associative_iterator old(*this); ++*this; return old; }
const_associative_iterator& operator --() { --it; return *this; }
const_associative_iterator operator --(int) { const_associative_iterator old(*this); --*this; return old; }
// public interface
const tree_type* node() const { return *it; }
// data
protected:
typename container_type::const_iterator it;
const associative_tree<stored_type, tree_type, container_type>* pIt_parent;
};
template<typename stored_type, typename tree_type, typename container_type>
class associative_iterator : public const_associative_iterator<stored_type, tree_type, container_type>
{
private:
// typedefs
using const_associative_iterator<stored_type, tree_type, container_type>::it;
friend class associative_tree<stored_type, tree_type, container_type>;
friend class associative_reverse_iterator<stored_type, tree_type, container_type>;
public:
// constructors/destructor
associative_iterator() : const_associative_iterator<stored_type, tree_type, container_type>() {}
private:
explicit associative_iterator(typename container_type::iterator it_, associative_tree<stored_type, tree_type, container_type>* pParent_) : const_associative_iterator<stored_type, tree_type, container_type>(it_, pParent_) {}
// destructor, copy constructor, and assignment operator will be compiler generated correctly
public:
// overloaded operators
stored_type& operator*() { return *(*it)->get(); }
stored_type* operator->() { return (*it)->get(); }
associative_iterator& operator ++() { ++it; return *this; }
associative_iterator operator ++(int) { associative_iterator old(*this); ++*this; return old; }
associative_iterator& operator --() { --it; return *this; }
associative_iterator operator --(int) { associative_iterator old(*this); --*this; return old; }
// public interface
tree_type* node() const { return *it; }
};
/************************************************************************/
/* sequential tree child iterators */
/************************************************************************/
template<typename stored_type, typename tree_type, typename container_type>
class const_sequential_iterator : public std::iterator<std::random_access_iterator_tag, stored_type>
{
public:
// typedefs & friends
#if defined(_MSC_VER) && _MSC_VER < 1300
typedef std::iterator_traits<std::iterator<std::random_access_iterator_tag, stored_type> >::distance_type difference_type;
#else
typedef typename std::iterator_traits<const_sequential_iterator>::difference_type difference_type;
#endif
typedef size_t size_type;
friend class sequential_tree<stored_type>;
friend class const_pre_order_descendant_iterator<stored_type, tree_type, container_type, sequential_tree<stored_type> >;
friend class const_post_order_descendant_iterator<stored_type, tree_type, container_type, sequential_tree<stored_type> >;
// constructors/destructor
const_sequential_iterator() : pIt_parent(0) {}
protected:
explicit const_sequential_iterator(typename container_type::const_iterator it_, const tree_type* pParent_) : it(it_), pIt_parent(pParent_) {}
// destructor, copy constructor, and assignment operator will be compiler generated correctly
public:
// overloaded operators
bool operator == (const const_sequential_iterator& rhs ) const { return pIt_parent == rhs.pIt_parent && it == rhs.it; }
bool operator != (const const_sequential_iterator& rhs ) const { return !(*this == rhs); }
bool operator < (const const_sequential_iterator& rhs) const { return it < rhs.it; }
bool operator <= (const const_sequential_iterator& rhs) const { return it <= rhs.it; }
bool operator > (const const_sequential_iterator& rhs) const { return it > rhs.it; }
bool operator >= (const const_sequential_iterator& rhs) const { return it >= rhs.it; }
const stored_type& operator*() const { return *(*it)->get(); }
const stored_type* operator->() const { return (*it)->get(); }
const_sequential_iterator& operator ++() { ++it; return *this; }
const_sequential_iterator operator ++(int) { const_sequential_iterator old(*this); ++*this; return old; }
const_sequential_iterator& operator --() { --it; return *this; }
const_sequential_iterator operator --(int) { const_sequential_iterator old(*this); --*this; return old; }
const_sequential_iterator& operator +=(size_type n) { it += n; return *this; }
const_sequential_iterator& operator -=(size_type n) { it -= n; return *this; }
difference_type operator -(const const_sequential_iterator& rhs) const { return it - rhs.it; }
// public interface
const tree_type* node() const { return *it; }
// data
protected:
typename container_type::const_iterator it;
const tree_type* pIt_parent;
};
template<typename stored_type, typename tree_type, typename container_type>
class sequential_iterator : public const_sequential_iterator<stored_type, tree_type, container_type>
{
private:
friend class sequential_tree<stored_type>;
friend class sequential_reverse_iterator<stored_type, tree_type, container_type>;
using const_sequential_iterator<stored_type, tree_type, container_type>::it;
public:
// constructors/destructor
sequential_iterator() : const_sequential_iterator<stored_type, tree_type, container_type>() {}
private:
explicit sequential_iterator(typename container_type::iterator it_, tree_type* pParent_) : const_sequential_iterator<stored_type, tree_type, container_type>(it_, pParent_) {}
// destructor, copy constructor, and assignment operator will be compiler generated correctly
public:
// overloaded operators
stored_type& operator*() { return *(*it)->get(); }
stored_type* operator->() const { return (*it)->get(); }
sequential_iterator& operator ++() { ++it; return *this; }
sequential_iterator operator ++(int) { sequential_iterator old(*this); ++*this; return old; }
sequential_iterator& operator --() { --it; return *this; }
sequential_iterator operator --(int) { sequential_iterator old(*this); --*this; return old; }
// public interface
tree_type* node() const { return *it; }
};