BoxElemFixture.hpp
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Created: Tue, Nov 5, 19:08

BoxElemFixture.hpp
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	/*
	//@HEADER
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	//
	// Kokkos v. 2.0
	// Copyright (2014) Sandia Corporation
	//
	// Under the terms of Contract DE-AC04-94AL85000 with Sandia Corporation,
	// the U.S. Government retains certain rights in this software.
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	#ifndef KOKKOS_EXAMPLE_BOXELEMFIXTURE_HPP
	#define KOKKOS_EXAMPLE_BOXELEMFIXTURE_HPP

	#include <stdio.h>
	#include <utility>

	#include <Kokkos_Core.hpp>

	#include <HexElement.hpp>
	#include <BoxElemPart.hpp>

	//----------------------------------------------------------------------------

	namespace Kokkos {
	namespace Example {

	/** \brief Map a grid onto a unit cube with smooth nonlinear grading
	* of the map.
	*/
	struct MapGridUnitCube {

	const float m_a ;
	const float m_b ;
	const float m_c ;
	const size_t m_max_x ;
	const size_t m_max_y ;
	const size_t m_max_z ;

	MapGridUnitCube( const size_t grid_max_x ,
	const size_t grid_max_y ,
	const size_t grid_max_z ,
	const float bubble_x ,
	const float bubble_y ,
	const float bubble_z )
	: m_a( bubble_x )
	, m_b( bubble_y )
	, m_c( bubble_z )
	, m_max_x( grid_max_x )
	, m_max_y( grid_max_y )
	, m_max_z( grid_max_z )
	{}

	template< typename Scalar >
	KOKKOS_INLINE_FUNCTION
	void operator()( int grid_x ,
	int grid_y ,
	int grid_z ,
	Scalar & coord_x ,
	Scalar & coord_y ,
	Scalar & coord_z ) const
	{
	// Map to a unit cube [0,1]^3

	const double x = double(grid_x) / double(m_max_x);
	const double y = double(grid_y) / double(m_max_y);
	const double z = double(grid_z) / double(m_max_z);

	coord_x = x + x * x * ( x - 1 ) * ( x - 1 ) * m_a ;
	coord_y = y + y * y * ( y - 1 ) * ( y - 1 ) * m_b ;
	coord_z = z + z * z * ( z - 1 ) * ( z - 1 ) * m_c ;
	}
	};

	} // namespace Example
	} // namespace Kokkos

	//----------------------------------------------------------------------------

	namespace Kokkos {
	namespace Example {

	/** \brief Generate a distributed unstructured finite element mesh
	* from a partitioned NXNYNZ box of elements.
	*
	* Order owned nodes first followed by off-process nodes
	* grouped by owning process.
	*/
	template< class Device ,
	BoxElemPart::ElemOrder Order ,
	class CoordinateMap = MapGridUnitCube >
	class BoxElemFixture {
	public:

	typedef Device execution_space ;

	enum { SpaceDim = 3 };
	enum { ElemNode = Order == BoxElemPart::ElemLinear ? 8 :
	Order == BoxElemPart::ElemQuadratic ? 27 : 0 };

	private:

	typedef Kokkos::Example::HexElement_TensorData< ElemNode > hex_data ;

	Kokkos::Example::BoxElemPart m_box_part ;
	CoordinateMap m_coord_map ;

	Kokkos::View< double *[SpaceDim] , Device > m_node_coord ;
	Kokkos::View< size_t *[SpaceDim] , Device > m_node_grid ;
	Kokkos::View< size_t *[ElemNode] , Device > m_elem_node ;
	Kokkos::View< size_t *[2] , Device > m_recv_node ;
	Kokkos::View< size_t *[2] , Device > m_send_node ;
	Kokkos::View< size_t * , Device > m_send_node_id ;

	unsigned char m_elem_node_local[ ElemNode ][4] ;

	public:

	typedef Kokkos::View< const size_t * [ElemNode], Device > elem_node_type ;
	typedef Kokkos::View< const double * [SpaceDim], Device > node_coord_type ;
	typedef Kokkos::View< const size_t * [SpaceDim], Device > node_grid_type ;
	typedef Kokkos::View< const size_t * [2] , Device > comm_list_type ;
	typedef Kokkos::View< const size_t * , Device > send_nodeid_type ;

	inline bool ok() const { return m_box_part.ok(); }

	KOKKOS_INLINE_FUNCTION
	size_t node_count() const { return m_node_grid.dimension_0(); }

	KOKKOS_INLINE_FUNCTION
	size_t node_count_owned() const { return m_box_part.owns_node_count(); }

	KOKKOS_INLINE_FUNCTION
	size_t node_count_global() const { return m_box_part.global_node_count(); }

	KOKKOS_INLINE_FUNCTION
	size_t elem_count() const { return m_elem_node.dimension_0(); }

	KOKKOS_INLINE_FUNCTION
	size_t elem_count_global() const { return m_box_part.global_elem_count(); }

	KOKKOS_INLINE_FUNCTION
	size_t elem_node_local( size_t inode , int k ) const
	{ return m_elem_node_local[inode][k] ; }

	KOKKOS_INLINE_FUNCTION
	size_t node_grid( size_t inode , int iaxis ) const
	{ return m_node_grid(inode,iaxis); }

	KOKKOS_INLINE_FUNCTION
	size_t node_global_index( size_t local ) const
	{
	const size_t tmp_node_grid[SpaceDim] =
	{ m_node_grid(local,0) , m_node_grid(local,1) , m_node_grid(local,2) };
	return m_box_part.global_node_id( tmp_node_grid );
	}

	KOKKOS_INLINE_FUNCTION
	double node_coord( size_t inode , int iaxis ) const
	{ return m_node_coord(inode,iaxis); }

	KOKKOS_INLINE_FUNCTION
	size_t node_grid_max( int iaxis ) const
	{ return m_box_part.global_coord_max(iaxis); }

	KOKKOS_INLINE_FUNCTION
	size_t elem_node( size_t ielem , size_t inode ) const
	{ return m_elem_node(ielem,inode); }

	elem_node_type elem_node() const { return m_elem_node ; }
	node_coord_type node_coord() const { return m_node_coord ; }
	node_grid_type node_grid() const { return m_node_grid ; }
	comm_list_type recv_node() const { return m_recv_node ; }
	comm_list_type send_node() const { return m_send_node ; }
	send_nodeid_type send_nodeid() const { return m_send_node_id ; }

	KOKKOS_INLINE_FUNCTION
	BoxElemFixture( const BoxElemFixture & rhs )
	: m_box_part( rhs.m_box_part )
	, m_coord_map( rhs.m_coord_map )
	, m_node_coord( rhs.m_node_coord )
	, m_node_grid( rhs.m_node_grid )
	, m_elem_node( rhs.m_elem_node )
	, m_recv_node( rhs.m_recv_node )
	, m_send_node( rhs.m_send_node )
	, m_send_node_id( rhs.m_send_node_id )
	{
	for ( int i = 0 ; i < ElemNode ; ++i ) {
	m_elem_node_local[i][0] = rhs.m_elem_node_local[i][0] ;
	m_elem_node_local[i][1] = rhs.m_elem_node_local[i][1] ;
	m_elem_node_local[i][2] = rhs.m_elem_node_local[i][2] ;
	m_elem_node_local[i][3] = 0 ;
	}
	}

	BoxElemFixture & operator = ( const BoxElemFixture & rhs )
	{
	m_box_part = rhs.m_box_part ;
	m_coord_map = rhs.m_coord_map ;
	m_node_coord = rhs.m_node_coord ;
	m_node_grid = rhs.m_node_grid ;
	m_elem_node = rhs.m_elem_node ;
	m_recv_node = rhs.m_recv_node ;
	m_send_node = rhs.m_send_node ;
	m_send_node_id = rhs.m_send_node_id ;

	for ( int i = 0 ; i < ElemNode ; ++i ) {
	m_elem_node_local[i][0] = rhs.m_elem_node_local[i][0] ;
	m_elem_node_local[i][1] = rhs.m_elem_node_local[i][1] ;
	m_elem_node_local[i][2] = rhs.m_elem_node_local[i][2] ;
	m_elem_node_local[i][3] = 0 ;
	}
	return *this ;
	}

	BoxElemFixture( const BoxElemPart::Decompose decompose ,
	const size_t global_size ,
	const size_t global_rank ,
	const size_t elem_nx ,
	const size_t elem_ny ,
	const size_t elem_nz ,
	const float bubble_x = 1.1f ,
	const float bubble_y = 1.2f ,
	const float bubble_z = 1.3f )
	: m_box_part( Order , decompose , global_size , global_rank , elem_nx , elem_ny , elem_nz )
	, m_coord_map( m_box_part.global_coord_max(0) ,
	m_box_part.global_coord_max(1) ,
	m_box_part.global_coord_max(2) ,
	bubble_x ,
	bubble_y ,
	bubble_z )
	, m_node_coord( "fixture_node_coord" , m_box_part.uses_node_count() )
	, m_node_grid( "fixture_node_grid" , m_box_part.uses_node_count() )
	, m_elem_node( "fixture_elem_node" , m_box_part.uses_elem_count() )
	, m_recv_node( "fixture_recv_node" , m_box_part.recv_node_msg_count() )
	, m_send_node( "fixture_send_node" , m_box_part.send_node_msg_count() )
	, m_send_node_id( "fixture_send_node_id" , m_box_part.send_node_id_count() )
	{
	{
	const hex_data elem_data ;

	for ( int i = 0 ; i < ElemNode ; ++i ) {
	m_elem_node_local[i][0] = elem_data.eval_map[i][0] ;
	m_elem_node_local[i][1] = elem_data.eval_map[i][1] ;
	m_elem_node_local[i][2] = elem_data.eval_map[i][2] ;
	m_elem_node_local[i][3] = 0 ;
	}
	}

	const size_t nwork =
	std::max( m_recv_node.dimension_0() ,
	std::max( m_send_node.dimension_0() ,
	std::max( m_send_node_id.dimension_0() ,
	std::max( m_node_grid.dimension_0() ,
	m_elem_node.dimension_0() * m_elem_node.dimension_1() ))));

	Kokkos::parallel_for( nwork , *this );
	}


	// Initialization:

	KOKKOS_INLINE_FUNCTION
	void operator()( size_t i ) const
	{
	if ( i < m_elem_node.dimension_0() * m_elem_node.dimension_1() ) {

	const size_t ielem = i / ElemNode ;
	const size_t inode = i % ElemNode ;

	size_t elem_grid[SpaceDim] ;
	size_t tmp_node_grid[SpaceDim] ;

	m_box_part.uses_elem_coord( ielem , elem_grid );

	enum { elem_node_scale = Order == BoxElemPart::ElemLinear ? 1 :
	Order == BoxElemPart::ElemQuadratic ? 2 : 0 };

	tmp_node_grid[0] = elem_node_scale * elem_grid[0] + m_elem_node_local[inode][0] ;
	tmp_node_grid[1] = elem_node_scale * elem_grid[1] + m_elem_node_local[inode][1] ;
	tmp_node_grid[2] = elem_node_scale * elem_grid[2] + m_elem_node_local[inode][2] ;

	m_elem_node(ielem,inode) = m_box_part.local_node_id( tmp_node_grid );
	}

	if ( i < m_node_grid.dimension_0() ) {
	size_t tmp_node_grid[SpaceDim] ;
	m_box_part.local_node_coord( i , tmp_node_grid );
	m_node_grid(i,0) = tmp_node_grid[0] ;
	m_node_grid(i,1) = tmp_node_grid[1] ;
	m_node_grid(i,2) = tmp_node_grid[2] ;

	m_coord_map( tmp_node_grid[0] ,
	tmp_node_grid[1] ,
	tmp_node_grid[2] ,
	m_node_coord(i,0) ,
	m_node_coord(i,1) ,
	m_node_coord(i,2) );
	}

	if ( i < m_recv_node.dimension_0() ) {
	m_recv_node(i,0) = m_box_part.recv_node_rank(i);
	m_recv_node(i,1) = m_box_part.recv_node_count(i);
	}

	if ( i < m_send_node.dimension_0() ) {
	m_send_node(i,0) = m_box_part.send_node_rank(i);
	m_send_node(i,1) = m_box_part.send_node_count(i);
	}

	if ( i < m_send_node_id.dimension_0() ) {
	m_send_node_id(i) = m_box_part.send_node_id(i);
	}
	}
	};

	} // namespace Example
	} // namespace Kokkos

	//----------------------------------------------------------------------------

	#endif /* #ifndef KOKKOS_EXAMPLE_BOXELEMFIXTURE_HPP */

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