corelib/include/ebcl/inline/MultiArrays.hh

/******************************************************************************/
/* ARRAYS - INLINE CODE *******************************************************/
/******************************************************************************/

#ifndef _H_EBCL_INLINE_MULTIARRAYS
#define _H_EBCL_INLINE_MULTIARRAYS
#include <ebcl/MultiArrays.hh>
namespace ebcl {


/*= T_MultiArray ============================================================-*/

template< typename T >
inline void swap( T_MultiArray< T >& lhs , T_MultiArray< T >& rhs )
{
	using std::swap;
	swap( lhs.meta_ , rhs.meta_ );
	swap( lhs.values_ , rhs.values_ );
}

/*----------------------------------------------------------------------------*/

template< typename T >
inline void T_MultiArray< T >::next( )
{
	const auto sz( meta_.size( ) );
	const auto first( ( sz == 0 ) ? 0 : ( meta_[ sz - 2 ] + meta_[ sz - 1 ] ) );
	meta_ << first << 0;
}

template< typename T >
inline void T_MultiArray< T >::add( T value )
{
	if ( meta_.size( ) == 0 ) {
		meta_ << 0 << 1;
	} else {
		meta_[ meta_.size( ) - 1 ] ++;
	}
	values_ << value;
}

template< typename T >
template<
	typename Q ,
	typename... Args ,
	typename >
inline Q& T_MultiArray< T >::addNew( Args&& ... args )
{
	if ( meta_.size( ) == 0 ) {
		meta_ << 0 << 1;
	} else {
		meta_[ meta_.size( ) - 1 ] ++;
	}
	return values_.addNew( std::forward< Args >( args ) ... );
}

template< typename T >
inline void T_MultiArray< T >::copyFrom( T_Array< T > const& source )
{
	values_.addAll( source );
	if ( meta_.size( ) == 0 ) {
		meta_ << 0 << source.size( );
	} else {
		meta_[ meta_.size( ) - 1 ] += source.size( );
	}
}

/*----------------------------------------------------------------------------*/

template< typename T >
inline uint32_t T_MultiArray< T >::size( ) const noexcept
{
	return meta_.size( ) >> 1;
}

template< typename T >
inline uint32_t T_MultiArray< T >::firstOf( uint32_t item ) const noexcept
{
	return meta_[ item * 2 ];
}

template< typename T >
inline uint32_t T_MultiArray< T >::sizeOf( uint32_t item ) const noexcept
{
	return meta_[ item * 2 + 1 ];
}

template< typename T >
inline uint32_t T_MultiArray< T >::values( ) const noexcept
{
	return values_.size( );
}

/*----------------------------------------------------------------------------*/

template< typename T >
inline T const& T_MultiArray< T >::get( uint32_t item , uint32_t sub ) const
{
	assert( sub < meta_[ item * 2 + 1 ] );
	return values_[ meta_[ item * 2 ] + sub ];
}

template< typename T >
inline T& T_MultiArray< T >::get( uint32_t item , uint32_t sub )
{
	assert( sub < meta_[ item * 2 + 1 ] );
	return values_[ meta_[ item * 2 ] + sub ];
}

/*----------------------------------------------------------------------------*/

template< typename T >
inline T const& T_MultiArray< T >::operator[] ( uint32_t index ) const
{
	return values_[ index ];
}

template< typename T >
inline T& T_MultiArray< T >::operator[] ( uint32_t index )
{
	return values_[ index ];
}

/*----------------------------------------------------------------------------*/

template< typename T >
inline bool T_MultiArray< T >::contains( uint32_t index , T const& value ) const
{
	const auto first( firstOf( index ) );
	const auto end( first + sizeOf( index ) );
	for ( uint32_t i = first ; i < end ; i ++ ) {
		if ( values_[ i ] == value ) {
			return true;
		}
	}
	return false;
}

/*----------------------------------------------------------------------------*/

template< typename T >
inline void T_MultiArray< T >::clear( )
{
	meta_.clear( );
	values_.clear( );
}

template< typename T >
inline void T_MultiArray< T >::free( )
{
	meta_.free( );
	values_.free( );
}

/*----------------------------------------------------------------------------*/

template< typename T >
inline void T_MultiArray< T >::copyFrom( uint32_t index )
{
	copyFrom( *this , index );
}

template< typename T >
inline void T_MultiArray< T >::copyFrom(
					T_MultiArray< T > const& other , uint32_t index )
{
	const auto size( other.sizeOf( index ) );
	if ( size == 0 ) {
		return;
	}

	const auto first( other.firstOf( index ) );
	T const* ptr( &( other[ first ] ) );
	for ( uint32_t i = 0 ; i < size ; i ++ , ptr ++ ) {
		values_ << *ptr;
	}
	if ( meta_.size( ) == 0 ) {
		meta_ << 0 << size;
	} else {
		meta_[ meta_.size( ) - 1 ] += size;
	}
}

/*----------------------------------------------------------------------------*/

template< typename T >
inline void T_MultiArray< T >::copyUnique( uint32_t index )
{
	copyUnique( *this , index );
}

template< typename T >
inline void T_MultiArray< T >::copyUnique( T_MultiArray< T > const& other , uint32_t index )
{
	const auto oSize( other.sizeOf( index ) );
	if ( oSize == 0 ) {
		return;
	}

	const auto ms( meta_.size( ) );
	const auto tSize( ms == 0 ? 0 : meta_[ ms - 1 ] );
	const auto tFirst( ms == 0 ? 0 : meta_[ ms - 2 ] );

	const auto oFirst( other.firstOf( index ) );
	T const* ptr( &( other[ oFirst ] ) );

	uint32_t added = 0;
	for ( uint32_t i = 0 ; i < oSize ; i ++ , ptr ++ ) {
		bool found = false;
		if ( tSize != 0 ) {
			T const* pCheck( &values_[ tFirst ] );
			for ( uint32_t j = 0 ; j < tSize ; j ++ , pCheck ++ ) {
				if ( *pCheck == *ptr ) {
					found = true;
					break;
				}
			}
		}
		if ( !found ) {
			values_ << *ptr;
			added ++;
		}
	}
	if ( ms == 0 ) {
		meta_ << 0 << added;
	} else {
		meta_[ ms - 1 ] += added;
	}
}

/*----------------------------------------------------------------------------*/

template< typename T >
inline void T_MultiArray< T >::sort( uint32_t index , F_Comparator< T > cmp )
{
	values_.sort( meta_[ index * 2 ] , meta_[ index * 2 + 1 ] , cmp );
}


} // namespace
#endif // _H_EBCL_INLINE_MULTIARRAYS