ThePhD/fixed_vector.c++

## fixed_vector.c++
#pragma once

#include <cstddef>
#include <type_traits>
#include <initializer_list>
#include <algorithm>

namespace Furrovine {

	template <typename T, std::size_t n, std::size_t a = std::alignment_of<T>::value>
	class fixed_vector {
	public:
		typedef T value_type;
		typedef T& reference;
		typedef const T& const_reference;
		typedef T* pointer_type;
		typedef std::size_t size_type;
		typedef std::ptrdiff_t difference_type;
		typedef pointer_type iterator;
		typedef const pointer_type const_iterator;

	private:
		typename std::aligned_storage<sizeof( T ) * n, a>::type items;
		std::size_t len;

		T* ptrat ( std::size_t idx ) {
			return static_cast<T*>( static_cast<void*>( &items ) ) + idx;
		}

		const T* ptrat( std::size_t idx ) const {
			return static_cast<const T*>( static_cast<const void*>( &items ) ) + idx;
		}

		T& refat ( std::size_t idx ) {
			return *ptrat( idx );
		}

		const T& refat ( std::size_t idx ) const {
			return *ptrat( idx );
		}

	public:
		static const std::size_t max_size () {
			return n;
		}

		fixed_vector( ) : len( 0 ) {

		}

		fixed_vector( std::size_t capacity ) : len( std::min( n, capacity ) ) {

		}

		template <std::size_t c>
		fixed_vector( const T( &arr )[ c ] ) : len( c ) {
			static_assert( c < n, "Array too large to initialize fixed_vector" );
			std::copy( std::addressof( arr[ 0 ] ), std::addressof( arr[ c ] ), data( ) );
		}

		fixed_vector( std::initializer_list<T> initializer ) : len( std::min( n, initializer.size( ) ) ) {
			std::copy( initializer.begin( ), initializer.begin( ) + len, data( ) );
		}

		bool empty () const {
			return len < 1;
		}

		bool not_empty () const {
			return len > 0;
		}

		bool full () const {
			return len >= n;
		}

		void push_back ( const T& item ) {
			new( ptrat( len++ ) ) T( item );
		}

		void push_back ( T&& item ) {
			new( ptrat( len++ ) ) T( std::move( item ) );
		}

		template <typename ...Tn>
		void emplace_back ( Tn&&... argn ) {
			new( ptrat( len++ ) ) T( std::forward<Tn>( argn )... );
		}

		void pop_back ( ) {
			T& addr = refat( --len );
			addr.~T();
		}

		void clear () {
			for ( ; len > 0; ) {
				pop_back();
			}
		}

		std::size_t size () const {
			return len;
		}

		std::size_t capacity () const {
			return n;
		}

		void resize ( std::size_t sz ) {
			len = std::min( sz, n );
		}

		T* data () {
			return ptrat( 0 );
		}

		const T* data () const {
			return ptrat( 0 );
		}

		T& operator[] ( std::size_t idx ) {
			return refat( idx );
		}

		const T& operator[] ( std::size_t idx ) const {
			return refat( idx );
		}

		T& front () {
			return refat( 0 );
		}

		T& back () {
			return refat( len - 1 );
		}

		const T& front () const {
			return refat( 0 );
		}

		const T& back () const {
			return refat( len - 1 );
		}

		T* begin () {
			return data();
		}

		const T* cbegin () {
			return data();
		}

		const T* begin () const {
			return data();
		}

		const T* cbegin () const {
			return data();
		}

		T* end () {
			return data() + len;
		}

		const T* cend () {
			return data() + len;
		}

		const T* end () const {
			return data() + len;
		}

		const T* cend () const {
			return data() + len;
		}
	};

}
	#pragma once

	#include <cstddef>
	#include <type_traits>
	#include <initializer_list>
	#include <algorithm>

	namespace Furrovine {

	template <typename T, std::size_t n, std::size_t a = std::alignment_of<T>::value>
	class fixed_vector {
	public:
	typedef T value_type;
	typedef T& reference;
	typedef const T& const_reference;
	typedef T* pointer_type;
	typedef std::size_t size_type;
	typedef std::ptrdiff_t difference_type;
	typedef pointer_type iterator;
	typedef const pointer_type const_iterator;

	private:
	typename std::aligned_storage<sizeof( T ) * n, a>::type items;
	std::size_t len;

	T* ptrat ( std::size_t idx ) {
	return static_cast<T>( static_cast<void>( &items ) ) + idx;
	}

	const T* ptrat( std::size_t idx ) const {
	return static_cast<const T>( static_cast<const void>( &items ) ) + idx;
	}

	T& refat ( std::size_t idx ) {
	return *ptrat( idx );
	}

	const T& refat ( std::size_t idx ) const {
	return *ptrat( idx );
	}

	public:
	static const std::size_t max_size () {
	return n;
	}

	fixed_vector( ) : len( 0 ) {

	}

	fixed_vector( std::size_t capacity ) : len( std::min( n, capacity ) ) {

	}

	template <std::size_t c>
	fixed_vector( const T( &arr )[ c ] ) : len( c ) {
	static_assert( c < n, "Array too large to initialize fixed_vector" );
	std::copy( std::addressof( arr[ 0 ] ), std::addressof( arr[ c ] ), data( ) );
	}

	fixed_vector( std::initializer_list<T> initializer ) : len( std::min( n, initializer.size( ) ) ) {
	std::copy( initializer.begin( ), initializer.begin( ) + len, data( ) );
	}

	bool empty () const {
	return len < 1;
	}

	bool not_empty () const {
	return len > 0;
	}

	bool full () const {
	return len >= n;
	}

	void push_back ( const T& item ) {
	new( ptrat( len++ ) ) T( item );
	}

	void push_back ( T&& item ) {
	new( ptrat( len++ ) ) T( std::move( item ) );
	}

	template <typename ...Tn>
	void emplace_back ( Tn&&... argn ) {
	new( ptrat( len++ ) ) T( std::forward<Tn>( argn )... );
	}

	void pop_back ( ) {
	T& addr = refat( --len );
	addr.~T();
	}

	void clear () {
	for ( ; len > 0; ) {
	pop_back();
	}
	}

	std::size_t size () const {
	return len;
	}

	std::size_t capacity () const {
	return n;
	}

	void resize ( std::size_t sz ) {
	len = std::min( sz, n );
	}

	T* data () {
	return ptrat( 0 );
	}

	const T* data () const {
	return ptrat( 0 );
	}

	T& operator[] ( std::size_t idx ) {
	return refat( idx );
	}

	const T& operator[] ( std::size_t idx ) const {
	return refat( idx );
	}

	T& front () {
	return refat( 0 );
	}

	T& back () {
	return refat( len - 1 );
	}

	const T& front () const {
	return refat( 0 );
	}

	const T& back () const {
	return refat( len - 1 );
	}

	T* begin () {
	return data();
	}

	const T* cbegin () {
	return data();
	}

	const T* begin () const {
	return data();
	}

	const T* cbegin () const {
	return data();
	}

	T* end () {
	return data() + len;
	}

	const T* cend () {
	return data() + len;
	}

	const T* end () const {
	return data() + len;
	}

	const T* cend () const {
	return data() + len;
	}
	};

	}