/elec/propeller-clock

/*	Copyright (C) 2004 Garrett A. Kajmowicz

	This file is part of the uClibc++ Library.

	This library is free software; you can redistribute it and/or

	modify it under the terms of the GNU Lesser General Public

	License as published by the Free Software Foundation; either

	version 2.1 of the License, or (at your option) any later version.

	This library is distributed in the hope that it will be useful,

	but WITHOUT ANY WARRANTY; without even the implied warranty of

	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU

	Lesser General Public License for more details.

	You should have received a copy of the GNU Lesser General Public

	License along with this library; if not, write to the Free Software

	Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA

*/

#include <basic_definitions>

#include <memory>

#include <iterator>

#include <func_exception>

#include <algorithm>

#include <type_traits>

#ifndef __STD_HEADER_VECTOR

#define __STD_HEADER_VECTOR

#pragma GCC visibility push(default)

namespace std{

	template <class T, class Allocator = allocator<T> > class vector;

	template <class T, class Allocator> bool operator==(const vector<T,Allocator>& x, const vector<T,Allocator>& y);

	template <class T, class Allocator> bool operator< (const vector<T,Allocator>& x, const vector<T,Allocator>& y);

	template <class T, class Allocator> bool operator!=(const vector<T,Allocator>& x, const vector<T,Allocator>& y);

	template <class T, class Allocator> bool operator> (const vector<T,Allocator>& x, const vector<T,Allocator>& y);

	template <class T, class Allocator> bool operator>=(const vector<T,Allocator>& x, const vector<T,Allocator>& y);

	template <class T, class Allocator> bool operator<=(const vector<T,Allocator>& x, const vector<T,Allocator>& y);

	template <class T, class Allocator> void swap(vector<T,Allocator>& x, vector<T,Allocator>& y);

	template <class T, class Allocator> class _UCXXEXPORT vector {

	public:

		typedef typename Allocator::reference reference;

		typedef typename Allocator::const_reference const_reference;

		typedef typename Allocator::size_type size_type;

		typedef typename Allocator::difference_type difference_type;

		typedef typename Allocator::pointer pointer;

		typedef typename Allocator::const_pointer const_pointer;

		typedef T* iterator;

		typedef const T* const_iterator;

		typedef T value_type;

		typedef Allocator allocator_type;

		typedef std::reverse_iterator<iterator> reverse_iterator;

		typedef std::reverse_iterator<const_iterator> const_reverse_iterator;

		explicit _UCXXEXPORT vector(const Allocator& al= Allocator()): data(0), //defaultValue(T()), 

			data_size(__UCLIBCXX_STL_BUFFER_SIZE__), elements(0), a(al)

		{

			data = a.allocate(data_size);

		}

		explicit _UCXXEXPORT vector(size_type n, const T& value = T(), const Allocator& al= Allocator()) : 

			data(0), data_size(0), elements(0), a(al)

		{

			data_size = n + __UCLIBCXX_STL_BUFFER_SIZE__;

			data = a.allocate(data_size);

			resize(n, value);

		}

		template <class InputIterator> _UCXXEXPORT 

			vector(InputIterator first, InputIterator last, const Allocator& al = Allocator()):

			data(0), data_size(__UCLIBCXX_STL_BUFFER_SIZE__), elements(0), a(al)

		{

			data = a.allocate(data_size);

			assign(first, last);

		}

		_UCXXEXPORT vector(const vector<T,Allocator>& x){

			a = x.a;

			elements  = x.elements;

			data_size = elements + __UCLIBCXX_STL_BUFFER_SIZE__;

			data = a.allocate(data_size);

			for(size_type i = 0; i < elements; i++){

				a.construct(data+i, x.data[i]);

			}	

		}

		_UCXXEXPORT ~vector();	//Below

		_UCXXEXPORT vector<T,Allocator>& operator=(const vector<T,Allocator>& x){

			if(&x == this){

				return *this;

			}

			reserve(x.elements);	//Make sure that we have enough actual memory

			//Copy as many elements as possible

			size_t minElements = elements;

			if(minElements > x.elements){

				minElements = x.elements;

			}

			for(size_t i = 0; i < minElements; ++i){

				data[i] = x.data[i];

			}

			//If we need to add new elements

			if(elements < x.elements){

				for(size_t i = elements; i< x.elements; ++i){

					a.construct(data+i, x.data[i]);

					++elements;

				}

			}

			if(elements > x.elements){

				downsize(x.elements);

			}

			return *this;

		}

		template <class InputIterator> _UCXXEXPORT void assign(InputIterator first, InputIterator last){

			clear();

			insert(begin(), first, last);

		}

		template <class Size, class U> _UCXXEXPORT void assign(Size n, const U& u = U()){

			clear();

			resize(n, u);

		}

		inline allocator_type get_allocator() const{

			return a;

		}

		inline iterator begin(){

			return data;

		}

		inline const_iterator begin() const{

			return data;

		}

		inline iterator end(){

			return (data + elements);

		}

		inline const_iterator end() const{

			return (data + elements);

		}

		inline reverse_iterator rbegin(){

			return reverse_iterator(end());

		}

		inline const_reverse_iterator rbegin() const{

			return const_reverse_iterator(end());

		}

		inline reverse_iterator rend(){

			return reverse_iterator(begin());

		}

		inline const_reverse_iterator rend() const{

			return const_reverse_iterator(begin());

		}

		inline size_type size() const{

			return elements;

		}

		_UCXXEXPORT size_type max_size() const{

			return ((size_type)(-1)) / sizeof(T);

		}

		void downsize(size_type sz);

		void resize(size_type sz, const T & c = T());

		inline size_type capacity() const{

			return data_size;

		}

		inline bool empty() const{

			return (size() == 0);

		}

		void reserve(size_type n);

		inline reference operator[](size_type n){

			return data[n];

		}

		inline const_reference operator[](size_type n) const{

			return data[n];

		}

		_UCXXEXPORT const_reference at(size_type n) const{

			if(n >= elements){

				__throw_out_of_range("Invalid subscript");

			}

			return data[n];

		}

		_UCXXEXPORT reference at(size_type n){

			if(n >= elements){

				__throw_out_of_range("Invalid subscript");

			}

			return data[n];

		}

		inline reference front(){

			return data[0];

		}

		inline const_reference front() const{

			return data[0];

		}

		inline reference back(){

			return data[ size() - 1];

		}

		inline const_reference back() const{

			return data[ size() - 1 ];

		}

		inline void push_back(const T& x){

			resize( size() + 1, x);

		}

		inline void pop_back(){

			downsize(size() - 1);

		}

		_UCXXEXPORT iterator insert(iterator position, const T& x = T()){

			size_type index = position - data;

			resize(size() + 1, x);

			for(size_type i = elements - 1; i > index; --i){

				data[i] = data[i-1];

			}

			data[index] = x;

			return (data + index);

		}

		_UCXXEXPORT void _insert_fill(iterator position, size_type n, const T & x){

			size_type index = position - data;

			resize(size() + n, x);

			for(size_type i = elements -1; (i > (index+n-1)); --i){

				data[i] = data[i-n];

			}

			for(size_type i = 0; i < n; i++){

				data[i + index]  = x;

			}

		}

		template <class InputIterator> _UCXXEXPORT 

			void _insert_from_iterator(iterator position, InputIterator first, InputIterator last)

		{

			T temp;

			while(first !=last){

				temp = *first;

				position = insert(position, temp);

				++position;

				++first;

			}

		}

		template <class InputIterator>

			inline void _dispatch_insert(iterator position, InputIterator first, InputIterator last, __true_type)

		{

			_insert_fill(position, first, last);

		}

		template <class InputIterator>

			inline void _dispatch_insert(iterator position, InputIterator first, InputIterator last, __false_type)

		{

				_insert_from_iterator(position, first, last);

		}

		inline void insert(iterator position, size_type n, const T& x ){

			_insert_fill(position, n, x);

		}

		template <class InputIterator> inline void insert(iterator position, InputIterator first, InputIterator last){

			typedef typename __is_integer<InputIterator>::value __some_type;

			_dispatch_insert(position, first, last, __some_type());

		}

		_UCXXEXPORT iterator erase(iterator position){

			size_type index = position - data;

			for(size_type i = index; i < (elements - 1); ++i){

				data[i] = data[i+1];

			}

			downsize(size() - 1);

			return (data + index);

		}

		_UCXXEXPORT iterator erase(iterator first, iterator last){

			size_type index = first - data;

			size_type width = last - first;

			for(size_type i = index; i < (elements - width) ;++i){

				data[i] = data[i+width];

			}

			downsize(size() - width);

			return (data + index);

		}

		_UCXXEXPORT void swap(vector<T,Allocator>& v){

			if(this == &v){		//Avoid dv.swap(v)

				return;

			}

			T* ptr;

			size_type temp;

			//Swap pointers first

			ptr = data;

			data = v.data;

			v.data  = ptr;

			//Swap element counts

			temp = elements;

			elements = v.elements;

			v.elements = temp;

			//Swap data size

			temp = data_size;

			data_size = v.data_size;

			v.data_size = temp;

		}

		_UCXXEXPORT void clear(){

			downsize(0);

		}

	protected:

		T* data;

		size_type data_size;

		size_type elements;

		Allocator a;

	};

	//Here go template instantiations

	template<class T, class Allocator> _UCXXEXPORT vector<T, Allocator>::~vector(){

		for(size_t i = 0; i < elements; ++i){

			a.destroy(data + i);

		}

		a.deallocate(data, data_size);

	}

	template<class T, class Allocator> _UCXXEXPORT void vector<T, Allocator>::reserve(size_type n){

		if(n > data_size){              //We never shrink...

			T * temp_ptr = data;

			size_type temp_size = data_size;

			data_size = n;

			data = a.allocate(data_size);

			for(size_type i = 0; i<elements; ++i){

				a.construct(data+i, temp_ptr[i]);

				a.destroy(temp_ptr+i);

			}

			a.deallocate(temp_ptr, temp_size);

		}

	}

	template<class T, class Allocator> _UCXXEXPORT void vector<T, Allocator>::resize(size_type sz, const T & c){

		if(sz > elements){      //Need to actually call constructor

			if(sz > data_size){

				reserve(sz + __UCLIBCXX_STL_BUFFER_SIZE__);

			}

			for(size_type i = elements; i<sz ; ++i){

				a.construct(data+i, c);

			}

			elements = sz;

		}else{

			downsize(sz);

		}

	}

	template<class T, class Allocator> _UCXXEXPORT void vector<T, Allocator>::downsize(size_type sz){

		if(sz < elements){      //Actually are downsizing

			for(size_t i = sz; i< elements; ++i){

				a.destroy(data+i);

			}

			elements = sz;

		}

	}

#ifndef __UCLIBCXX_COMPILE_VECTOR__

#ifdef __UCLIBCXX_EXPAND_VECTOR_BASIC__

#ifdef __UCLIBCXX_EXPAND_CONSTRUCTORS_DESTRUCTORS__

	template<> _UCXXEXPORT vector<char, allocator<char> >::vector(const allocator<char>& al);

	template<> _UCXXEXPORT vector<char, allocator<char> >::vector(size_type n, const char & value, const allocator<char> & al);

	template<> _UCXXEXPORT vector<char, allocator<char> >::~vector();

	template<> _UCXXEXPORT vector<unsigned char, allocator<unsigned char> >::~vector();

#endif //__UCLIBCXX_EXPAND_CONSTRUCTORS_DESTRUCTORS__

	template<> _UCXXEXPORT void vector<char, allocator<char> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<unsigned char, allocator<unsigned char> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<short int, allocator<short int> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<unsigned short int, allocator<unsigned short int> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<int, allocator<int> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<unsigned int, allocator<unsigned int> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<long int, allocator<long int> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<unsigned long int, allocator<unsigned long int> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<float, allocator<float> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<double, allocator<double> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<bool, allocator<bool> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<char, allocator<char> >::resize(size_type sz, const char & c);

	template<> _UCXXEXPORT void

		vector<unsigned char, allocator<unsigned char> >::resize(size_type sz, const unsigned char & c);

	template<> _UCXXEXPORT void vector<short int, allocator<short int> >::resize(size_type sz, const short & c);

	template<> _UCXXEXPORT void

		vector<unsigned short int, allocator<unsigned short int> >::resize(size_type sz, const unsigned short int & c);

	template<> _UCXXEXPORT void vector<int, allocator<int> >::resize(size_type sz, const int & c);

	template<> _UCXXEXPORT void vector<unsigned int, allocator<unsigned int> >::resize(size_type sz, const unsigned int & c);

	template<> _UCXXEXPORT void vector<long int, allocator<long int> >::resize(size_type sz, const long int & c);

	template<> _UCXXEXPORT void

		vector<unsigned long int, allocator<unsigned long int> >::resize(size_type sz, const unsigned long int & c);

	template<> _UCXXEXPORT void vector<float, allocator<float> >::resize(size_type sz, const float & c);

	template<> _UCXXEXPORT void vector<double, allocator<double> >::resize(size_type sz, const double & c);

	template<> _UCXXEXPORT void vector<bool, allocator<bool> >::resize(size_type sz, const bool & c);

#elif defined __UCLIBCXX_EXPAND_STRING_CHAR__

#ifdef __UCLIBCXX_EXPAND_CONSTRUCTORS_DESTRUCTORS__

	template<> _UCXXEXPORT vector<char, allocator<char> >::vector(const allocator<char>& al);

	template<> _UCXXEXPORT vector<char, allocator<char> >::vector(size_type n, const char & value, const allocator<char> & al);

	template<> _UCXXEXPORT vector<char, allocator<char> >::~vector();

#endif

	template<> _UCXXEXPORT void vector<char, allocator<char> >::reserve(size_type n);

	template<> _UCXXEXPORT void vector<char, allocator<char> >::resize(size_type sz, const char & c);

#endif

#endif

	template <class T, class Allocator> _UCXXEXPORT bool

		operator==(const vector<T,Allocator>& x, const vector<T,Allocator>& y)

	{

		if(x.size() !=y.size() ){

			return false;

		}

		for(size_t i = 0; i < x.size(); ++i){

			if(x[i] != y[i]){

				return false;

			}

		}

		return true;

	}

	template <class T, class Allocator> _UCXXEXPORT bool

		operator< (const vector<T,Allocator>& x, const vector<T,Allocator>& y)

	{

		less<typename iterator_traits<typename vector<T,Allocator>::iterator >::value_type> c;

                return lexicographical_compare(x.begin(), x.end(), y.begin(), y.end(), c);

	}

	template <class T, class Allocator> _UCXXEXPORT bool

		operator!=(const vector<T,Allocator>& x, const vector<T,Allocator>& y)

	{

		return !(x == y);

	}

	template <class T, class Allocator> _UCXXEXPORT bool

		operator> (const vector<T,Allocator>& x, const vector<T,Allocator>& y)

	{

		greater<typename iterator_traits<typename vector<T,Allocator>::iterator >::value_type> c;

                return lexicographical_compare(x.begin(), x.end(), y.begin(), y.end(), c);

	}

	template <class T, class Allocator> _UCXXEXPORT bool

		operator>=(const vector<T,Allocator>& x, const vector<T,Allocator>& y)

	{

		greater_equal<typename iterator_traits<typename vector<T,Allocator>::iterator >::value_type> c;

                return lexicographical_compare(x.begin(), x.end(), y.begin(), y.end(), c);

	}

	template <class T, class Allocator> _UCXXEXPORT bool

		operator<=(const vector<T,Allocator>& x, const vector<T,Allocator>& y)

	{

		less_equal<typename iterator_traits<typename vector<T,Allocator>::iterator >::value_type> c;

                return lexicographical_compare(x.begin(), x.end(), y.begin(), y.end(), c);

	}

	template <class T, class Allocator> _UCXXEXPORT void swap(vector<T,Allocator>& x, vector<T,Allocator>& y){

		x.swap(y);

	}

}

#pragma GCC visibility pop

#endif