JurassicParkTrespasser/jp2_pc/Inc/STL/iterator.h

/*
 *
 * Copyright (c) 1994
 * Hewlett-Packard Company
 *
 * Permission to use, copy, modify, distribute and sell this software
 * and its documentation for any purpose is hereby granted without fee,
 * provided that the above copyright notice appear in all copies and
 * that both that copyright notice and this permission notice appear
 * in supporting documentation.  Hewlett-Packard Company and Microsoft
 * Corporation make no representations about the suitability of this
 * software for any purpose.  It is provided "as is" without express or
 * implied warranty.
 *
 */

#ifndef ITERATOR_H
#define ITERATOR_H

#include <stddef.h>
#include <iostream.h>
#include <bool.h>
#include <function.h>

struct input_iterator_tag {};
struct output_iterator_tag {};
struct forward_iterator_tag {};
struct bidirectional_iterator_tag {};
struct random_access_iterator_tag {};

template <class T, class Distance> struct input_iterator {};
struct output_iterator {};
template <class T, class Distance> struct forward_iterator {};
template <class T, class Distance> struct bidirectional_iterator {};
template <class T, class Distance> struct random_access_iterator {};

template <class T, class Distance> 
inline input_iterator_tag 
iterator_category(const input_iterator<T, Distance>&) {
    return input_iterator_tag();
}

inline output_iterator_tag iterator_category(const output_iterator&) {
    return output_iterator_tag();
}

template <class T, class Distance> 
inline forward_iterator_tag
iterator_category(const forward_iterator<T, Distance>&) {
    return forward_iterator_tag();
}

template <class T, class Distance> 
inline bidirectional_iterator_tag
iterator_category(const bidirectional_iterator<T, Distance>&) {
    return bidirectional_iterator_tag();
}

template <class T, class Distance> 
inline random_access_iterator_tag
iterator_category(const random_access_iterator<T, Distance>&) {
    return random_access_iterator_tag();
}

template <class T>
inline random_access_iterator_tag iterator_category(const T*) {
    return random_access_iterator_tag();
}

template <class T, class Distance> 
inline T* value_type(const input_iterator<T, Distance>&) {
    return (T*)(0); 
}

template <class T, class Distance> 
inline T* value_type(const forward_iterator<T, Distance>&) {
    return (T*)(0);
}

template <class T, class Distance> 
inline T* value_type(const bidirectional_iterator<T, Distance>&) {
    return (T*)(0);
}

template <class T, class Distance> 
inline T* value_type(const random_access_iterator<T, Distance>&) {
    return (T*)(0);
}

template <class T>
inline T* value_type(const T*) { return (T*)(0); }

template <class T, class Distance> 
inline Distance* distance_type(const input_iterator<T, Distance>&) {
    return (Distance*)(0);
}

template <class T, class Distance> 
inline Distance* distance_type(const forward_iterator<T, Distance>&) {
    return (Distance*)(0);
}

template <class T, class Distance> 
inline Distance* 
distance_type(const bidirectional_iterator<T, Distance>&) {
    return (Distance*)(0);
}

template <class T, class Distance> 
inline Distance* 
distance_type(const random_access_iterator<T, Distance>&) {
    return (Distance*)(0);
}

template <class T>
inline ptrdiff_t* distance_type(const T*) { return (ptrdiff_t*)(0); }

template <class Container>
class back_insert_iterator : public output_iterator {
protected:
    Container& container;
public:
    back_insert_iterator(Container& x) : container(x) {}
    back_insert_iterator<Container>&
    operator=(const Container::value_type& value) { 
	container.push_back(value);
	return *this;
    }
    back_insert_iterator<Container>& operator*() { return *this; }
    back_insert_iterator<Container>& operator++() { return *this; }
    back_insert_iterator<Container>& operator++(int) { return *this; }
};

template <class Container>
back_insert_iterator<Container> back_inserter(Container& x) {
    return back_insert_iterator<Container>(x);
}

template <class Container>
class front_insert_iterator : public output_iterator {
protected:
    Container& container;
public:
    front_insert_iterator(Container& x) : container(x) {}
    front_insert_iterator<Container>&
    operator=(const Container::value_type& value) { 
	container.push_front(value);
	return *this;
    }
    front_insert_iterator<Container>& operator*() { return *this; }
    front_insert_iterator<Container>& operator++() { return *this; }
    front_insert_iterator<Container>& operator++(int) { return *this; }
};

template <class Container>
front_insert_iterator<Container> front_inserter(Container& x) {
    return front_insert_iterator<Container>(x);
}

template <class Container>
class insert_iterator : public output_iterator {
protected:
    Container& container;
    Container::iterator iter;
public:
    insert_iterator(Container& x, Container::iterator i) 
	: container(x), iter(i) {}
    insert_iterator<Container>&
    operator=(const Container::value_type& value) { 
	iter = container.insert(iter, value);
	++iter;
	return *this;
    }
    insert_iterator<Container>& operator*() { return *this; }
    insert_iterator<Container>& operator++() { return *this; }
    insert_iterator<Container>& operator++(int) { return *this; }
};

template <class Container, class Iterator>
insert_iterator<Container> inserter(Container& x, Iterator i) {
    return insert_iterator<Container>(x, Container::iterator(i));
}

template <class BidirectionalIterator, class T, class Reference, 
          class Distance> 
// Reference = T& 
// Distance = ptrdiff_t
class reverse_bidirectional_iterator 
    : public bidirectional_iterator<T, Distance> {
    typedef reverse_bidirectional_iterator<BidirectionalIterator, T, Reference,
                                           Distance> self;
    friend bool operator==(const self& x, const self& y);
protected:
    BidirectionalIterator current;
public:
    reverse_bidirectional_iterator() {}
    reverse_bidirectional_iterator(BidirectionalIterator x) : current(x) {}
    BidirectionalIterator base() { return current; }
    Reference operator*() const {
	BidirectionalIterator tmp = current;
	return *--tmp;
    }
    self& operator++() {
	--current;
	return *this;
    }
    self operator++(int) {
	self tmp = *this;
	--current;
	return tmp;
    }
    self& operator--() {
	++current;
	return *this;
    }
    self operator--(int) {
	self tmp = *this;
	++current;
	return tmp;
    }
};

template <class BidirectionalIterator, class T, class Reference,
          class Distance>
inline bool operator==(
    const reverse_bidirectional_iterator<BidirectionalIterator, T, Reference,
		                         Distance>& x, 
    const reverse_bidirectional_iterator<BidirectionalIterator, T, Reference,
		                         Distance>& y) {
    return x.current == y.current;
}

template <class RandomAccessIterator, class T, class Reference,
          class Distance> 
// Reference = T&
// Distance = ptrdiff_t
class reverse_iterator : public random_access_iterator<T, Distance> {
    typedef reverse_iterator<RandomAccessIterator, T, Reference, Distance>
	self;
    friend bool operator==(const self& x, const self& y);
    friend bool operator<(const self& x, const self& y);
    friend Distance operator-(const self& x, const self& y);
    friend self operator+(Distance n, const self& x);
protected:
    RandomAccessIterator current;
public:
    reverse_iterator() {}
    reverse_iterator(RandomAccessIterator x) : current(x) {}
    RandomAccessIterator base() { return current; }
    Reference operator*() const { return *(current - 1); }
    self& operator++() {
	--current;
	return *this;
    }
    self operator++(int) {
	self tmp = *this;
	--current;
	return tmp;
    }
    self& operator--() {
	++current;
	return *this;
    }
    self operator--(int) {
	self tmp = *this;
	++current;
	return tmp;
    }
    self operator+(Distance n) const {
	return self(current - n);
    }
    self& operator+=(Distance n) {
	current -= n;
	return *this;
    }
    self operator-(Distance n) const {
	return self(current + n);
    }
    self& operator-=(Distance n) {
	current += n;
	return *this;
    }
    Reference operator[](Distance n) { return *(*this + n); }
};

template <class RandomAccessIterator, class T, class Reference, class Distance>
inline bool operator==(const reverse_iterator<RandomAccessIterator, T,
		                              Reference, Distance>& x, 
		       const reverse_iterator<RandomAccessIterator, T,
		                              Reference, Distance>& y) {
    return x.current == y.current;
}

template <class RandomAccessIterator, class T, class Reference, class Distance>
inline bool operator<(const reverse_iterator<RandomAccessIterator, T,
		                             Reference, Distance>& x, 
		      const reverse_iterator<RandomAccessIterator, T,
		                             Reference, Distance>& y) {
    return y.current < x.current;
}

template <class RandomAccessIterator, class T, class Reference, class Distance>
inline Distance operator-(const reverse_iterator<RandomAccessIterator, T,
			                         Reference, Distance>& x, 
			  const reverse_iterator<RandomAccessIterator, T,
			                         Reference, Distance>& y) {
    return y.current - x.current;
}

template <class RandomAccessIterator, class T, class Reference, class Distance>
inline reverse_iterator<RandomAccessIterator, T, Reference, Distance> 
operator+(Distance n,
	  const reverse_iterator<RandomAccessIterator, T, Reference,
	                         Distance>& x) {
    return reverse_iterator<RandomAccessIterator, T, Reference, Distance>
	(x.current - n);
}


template <class OutputIterator, class T>
class raw_storage_iterator : public output_iterator {
protected:
    OutputIterator iter;
public:
    raw_storage_iterator(OutputIterator x) : iter(x) {}
    raw_storage_iterator<OutputIterator, T>& operator*() { return *this; }
    raw_storage_iterator<OutputIterator, T>& operator=(const T& element) {
	construct(iter, element);
	return *this;
    }        
    raw_storage_iterator<OutputIterator, T>& operator++() {
	++iter;
	return *this;
    }
    raw_storage_iterator<OutputIterator, T> operator++(int) {
	raw_storage_iterator<OutputIterator, T> tmp = *this;
	++iter;
	return tmp;
    }
};


template <class T, class Distance> // Distance == ptrdiff_t
class istream_iterator : public input_iterator<T, Distance> {
friend bool operator==(const istream_iterator<T, Distance>& x,
		       const istream_iterator<T, Distance>& y);
protected:
    istream* stream;
    T value;
    bool end_marker;
    void read() {
	end_marker = (*stream) ? true : false;
	if (end_marker) *stream >> value;
	end_marker = (*stream) ? true : false;
    }
public:
    istream_iterator() : stream(&cin), end_marker(false) {}
    istream_iterator(istream& s) : stream(&s) { read(); }
    const T& operator*() const { return value; }
    istream_iterator<T, Distance>& operator++() { 
	read(); 
	return *this;
    }
    istream_iterator<T, Distance> operator++(int)  {
	istream_iterator<T, Distance> tmp = *this;
	read();
	return tmp;
    }
};

template <class T, class Distance>
bool operator==(const istream_iterator<T, Distance>& x,
		const istream_iterator<T, Distance>& y) {
    return x.stream == y.stream && x.end_marker == y.end_marker ||
	x.end_marker == false && y.end_marker == false;
}

template <class T>
class ostream_iterator : public output_iterator {
protected:
    ostream* stream;
    char* string;
public:
    ostream_iterator(ostream& s) : stream(&s), string(0) {}
    ostream_iterator(ostream& s, char* c) : stream(&s), string(c)  {}
    ostream_iterator<T>& operator=(const T& value) { 
	*stream << value;
	if (string) *stream << string;
	return *this;
    }
    ostream_iterator<T>& operator*() { return *this; }
    ostream_iterator<T>& operator++() { return *this; } 
    ostream_iterator<T>& operator++(int) { return *this; } 
};

#endif