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/* |
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************************************************************ |
/******************************************************* |
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* Copyright 2006 by ACcESS MNRF * |
* |
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* * |
* Copyright (c) 2003-2010 by University of Queensland |
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* http://www.access.edu.au * |
* Earth Systems Science Computational Center (ESSCC) |
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* Primary Business: Queensland, Australia * |
* http://www.uq.edu.au/esscc |
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* Licensed under the Open Software License version 3.0 * |
* |
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* http://www.opensource.org/licenses/osl-3.0.php * |
* Primary Business: Queensland, Australia |
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* * |
* Licensed under the Open Software License version 3.0 |
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************************************************************ |
* http://www.opensource.org/licenses/osl-3.0.php |
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*/ |
* |
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*******************************************************/ |
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/**************************************************************/ |
/**************************************************************/ |
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/**************************************************************/ |
/**************************************************************/ |
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/* Author: gross@access.edu.au */ |
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/* Version: $Id$ */ |
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/**************************************************************/ |
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#include "RectangularMesh.h" |
#include "RectangularMesh.h" |
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/**************************************************************/ |
Finley_Mesh* Finley_RectangularMesh_Hex8(dim_t* numElements, |
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double* Length, |
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#ifdef PASO_MPI |
bool_t* periodic, |
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/* get the number of nodes/elements for domain with rank=rank, of size processors |
index_t order, |
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where n is the total number of nodes/elements in the global domain */ |
index_t reduced_order, |
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static index_t domain_MODdim( index_t rank, index_t size, index_t n ) |
bool_t useElementsOnFace, |
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{ |
bool_t useFullElementOrder, |
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rank = size-rank-1; |
bool_t optimize) |
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if( rank < n%size ) |
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return (index_t)floor(n/size)+1; |
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return (index_t)floor(n/size); |
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} |
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/* Determines the number of nodes/elements etc along an axis which is numElementsGlobal long for domain rank */ |
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/* A bit messy, but it only has to be done once... */ |
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static void domain_calculateDimension( index_t rank, dim_t size, dim_t numElementsGlobal, bool_t periodic, dim_t *numNodesLocal, dim_t *numDOFLocal, dim_t *numElementsLocal, dim_t *numElementsInternal, dim_t *firstNode, dim_t *nodesExternal, dim_t *DOFExternal, dim_t *numNodesExternal, bool_t *periodicLocal ) |
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{ |
{ |
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index_t i0; |
#define N_PER_E 1 |
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dim_t numNodesGlobal = numElementsGlobal+1; |
#define DIM 3 |
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dim_t N0,N1,N2,NE0,NE1,NE2,i0,i1,i2,k,Nstride0=0, Nstride1=0,Nstride2=0, local_NE0, local_NE1, local_NE2, local_N0=0, local_N1=0, local_N2=0; |
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dim_t totalNECount,faceNECount,NDOF0=0,NDOF1=0,NDOF2=0,NFaceElements=0, NN; |
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index_t node0, myRank, e_offset2, e_offset1, e_offset0=0, offset1=0, offset2=0, offset0=0, global_i0, global_i1, global_i2; |
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Finley_ReferenceElementSet *refPoints=NULL, *refContactElements=NULL, *refFaceElements=NULL, *refElements=NULL; |
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Finley_Mesh* out; |
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Paso_MPIInfo *mpi_info = NULL; |
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char name[50]; |
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#ifdef Finley_TRACE |
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double time0=Finley_timer(); |
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#endif |
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(*numNodesLocal) = domain_MODdim( rank, size, numNodesGlobal ); |
/* get MPI information */ |
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mpi_info = Paso_MPIInfo_alloc( MPI_COMM_WORLD ); |
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numElementsLocal[0] = numNodesLocal[0]+1; |
if (! Finley_noError()) { |
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periodicLocal[0] = periodicLocal[1] = FALSE; |
return NULL; |
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nodesExternal[0] = nodesExternal[1] = 1; |
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if( periodic ) |
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{ |
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if( size==1 ) |
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{ |
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numElementsLocal[0] = numElementsGlobal; |
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nodesExternal[0] = nodesExternal[1] = 0; |
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periodicLocal[0] = periodicLocal[1] = TRUE; |
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} |
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else |
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{ |
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if( rank==0 ) |
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{ |
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periodicLocal[0] = TRUE; |
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numNodesLocal[0]++; |
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} |
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if( rank==(size-1) ) |
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{ |
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periodicLocal[1] = TRUE; |
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numNodesLocal[0]--; |
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numElementsLocal[0]--; |
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} |
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} |
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} |
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else if( !periodic ) |
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{ |
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if( rank==0 ){ |
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nodesExternal[0]--; |
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numElementsLocal[0]--; |
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} |
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if( rank==(size-1) ) |
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{ |
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nodesExternal[1]--; |
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numElementsLocal[0]--; |
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} |
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} |
} |
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numNodesExternal[0] = nodesExternal[0]+nodesExternal[1]; |
myRank=mpi_info->rank; |
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numElementsInternal[0] = numElementsLocal[0]; |
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if( (rank==0) && (rank==size-1) ); |
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else if( !periodic && ( (rank==0) ^ (rank==size-1) ) ) |
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numElementsInternal[0] -= 1; |
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else |
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numElementsInternal[0] -= 2; |
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firstNode[0] = 0; |
/* set up the global dimensions of the mesh */ |
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for( i0=0; i0<rank; i0++ ) |
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firstNode[0] += domain_MODdim( i0, size, numNodesGlobal ); |
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numDOFLocal[0] = numNodesLocal[0]; |
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if( periodicLocal[0] ) |
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{ |
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numDOFLocal[0]--; |
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} |
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DOFExternal[0] = nodesExternal[0]; |
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DOFExternal[1] = nodesExternal[1]; |
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} |
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#endif |
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#ifdef PASO_MPI |
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Finley_Mesh* Finley_RectangularMesh_Hex8_singleCPU(dim_t* numElements,double* Length,bool_t* periodic, index_t order,bool_t useElementsOnFace,Paso_MPIInfo *mpi_info) |
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#else |
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Finley_Mesh* Finley_RectangularMesh_Hex8(dim_t* numElements,double* Length,bool_t* periodic, index_t order,bool_t useElementsOnFace) |
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#endif |
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{ |
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dim_t N0,N1,N2,NE0,NE1,NE2,i0,i1,i2,k,totalNECount,faceNECount,NDOF0,NDOF1,NDOF2,NFaceElements,NUMNODES,M0,M1,M2; |
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index_t node0; |
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Finley_Mesh* out; |
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char name[50]; |
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double time0=Finley_timer(); |
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NE0=MAX(1,numElements[0]); |
NE0=MAX(1,numElements[0]); |
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NE1=MAX(1,numElements[1]); |
NE1=MAX(1,numElements[1]); |
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NE2=MAX(1,numElements[2]); |
NE2=MAX(1,numElements[2]); |
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N0=NE0+1; |
N0=N_PER_E*NE0+1; |
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N1=NE1+1; |
N1=N_PER_E*NE1+1; |
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N2=NE2+1; |
N2=N_PER_E*NE2+1; |
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if (N0<=MIN(N1,N2)) { |
/* allocate mesh: */ |
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if (N1 <= N2) { |
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M0=1; |
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M1=N0; |
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M2=N0*N1; |
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} else { |
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M0=1; |
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M2=N0; |
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M1=N0*N2; |
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} |
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} else if (N1<=MIN(N2,N0)) { |
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if (N2 <= N0) { |
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M1=1; |
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M2=N1; |
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M0=N2*N1; |
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} else { |
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M1=1; |
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M0=N1; |
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M2=N1*N0; |
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} |
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} else { |
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if (N0 <= N1) { |
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M2=1; |
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M0=N2; |
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M1=N2*N0; |
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} else { |
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M2=1; |
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M1=N2; |
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M0=N1*N2; |
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} |
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} |
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NFaceElements=0; |
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if (!periodic[0]) { |
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NDOF0=N0; |
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NFaceElements+=2*NE1*NE2; |
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} else { |
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NDOF0=N0-1; |
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} |
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if (!periodic[1]) { |
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NDOF1=N1; |
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NFaceElements+=2*NE0*NE2; |
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} else { |
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NDOF1=N1-1; |
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} |
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if (!periodic[2]) { |
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NDOF2=N2; |
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NFaceElements+=2*NE0*NE1; |
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} else { |
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NDOF2=N2-1; |
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} |
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/* allocate mesh: */ |
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sprintf(name,"Rectangular %d x %d x %d mesh",N0,N1,N2); |
sprintf(name,"Rectangular %d x %d x %d mesh",N0,N1,N2); |
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out=Finley_Mesh_alloc(name,DIM, mpi_info); |
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#ifndef PASO_MPI |
if (! Finley_noError()) { |
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out=Finley_Mesh_alloc(name,3,order); |
Paso_MPIInfo_free( mpi_info ); |
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#else |
return NULL; |
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out=Finley_Mesh_alloc(name,3,order,mpi_info); |
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#endif |
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if (! Finley_noError()) return NULL; |
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#ifdef PASO_MPI |
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out->Elements=Finley_ElementFile_alloc(Hex8,out->order,mpi_info); |
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if (useElementsOnFace) { |
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out->FaceElements=Finley_ElementFile_alloc(Hex8Face,out->order,mpi_info); |
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out->ContactElements=Finley_ElementFile_alloc(Hex8Face_Contact,out->order,mpi_info); |
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} else { |
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out->FaceElements=Finley_ElementFile_alloc(Rec4,out->order,mpi_info); |
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out->ContactElements=Finley_ElementFile_alloc(Rec4_Contact,out->order,mpi_info); |
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} |
} |
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out->Points=Finley_ElementFile_alloc(Point1,out->order,mpi_info); |
refElements= Finley_ReferenceElementSet_alloc(Hex8,order,reduced_order); |
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#else |
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out->Elements=Finley_ElementFile_alloc(Hex8,out->order); |
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if (useElementsOnFace) { |
if (useElementsOnFace) { |
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out->FaceElements=Finley_ElementFile_alloc(Hex8Face,out->order); |
refFaceElements=Finley_ReferenceElementSet_alloc(Hex8Face, order, reduced_order); |
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out->ContactElements=Finley_ElementFile_alloc(Hex8Face_Contact,out->order); |
refContactElements=Finley_ReferenceElementSet_alloc(Hex8Face_Contact, order, reduced_order); |
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} else { |
} else { |
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out->FaceElements=Finley_ElementFile_alloc(Rec4,out->order); |
refFaceElements=Finley_ReferenceElementSet_alloc(Rec4, order, reduced_order); |
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out->ContactElements=Finley_ElementFile_alloc(Rec4_Contact,out->order); |
refContactElements=Finley_ReferenceElementSet_alloc(Rec4_Contact, order, reduced_order); |
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} |
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out->Points=Finley_ElementFile_alloc(Point1,out->order); |
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#endif |
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if (! Finley_noError()) { |
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Finley_Mesh_dealloc(out); |
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return NULL; |
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} |
} |
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refPoints=Finley_ReferenceElementSet_alloc(Point1, order, reduced_order); |
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/* allocate tables: */ |
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Finley_NodeFile_allocTable(out->Nodes,N0*N1*N2); |
if ( Finley_noError()) { |
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#ifdef PASO_MPI |
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Finley_NodeDistribution_allocTable( out->Nodes->degreeOfFreedomDistribution, NDOF0*NDOF1*NDOF2, 0, 0 ); |
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#endif |
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Finley_ElementFile_allocTable(out->Elements,NE0*NE1*NE2); |
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Finley_ElementFile_allocTable(out->FaceElements,NFaceElements); |
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if (! Finley_noError()) { |
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Finley_Mesh_dealloc(out); |
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return NULL; |
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} |
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/* set nodes: */ |
Finley_Mesh_setPoints(out,Finley_ElementFile_alloc(refPoints, mpi_info)); |
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Finley_Mesh_setContactElements(out,Finley_ElementFile_alloc(refContactElements, mpi_info)); |
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#pragma omp parallel for private(i0,i1,i2,k) |
Finley_Mesh_setFaceElements(out,Finley_ElementFile_alloc(refFaceElements, mpi_info)); |
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for (i2=0;i2<N2;i2++) { |
Finley_Mesh_setElements(out,Finley_ElementFile_alloc(refElements, mpi_info)); |
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for (i1=0;i1<N1;i1++) { |
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for (i0=0;i0<N0;i0++) { |
/* work out the largest dimension */ |
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k=M0*i0+M1*i1+M2*i2; |
if (N2==MAX3(N0,N1,N2)) { |
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out->Nodes->Coordinates[INDEX2(0,k,3)]=DBLE(i0)/DBLE(N0-1)*Length[0]; |
Nstride0=1; |
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out->Nodes->Coordinates[INDEX2(1,k,3)]=DBLE(i1)/DBLE(N1-1)*Length[1]; |
Nstride1=N0; |
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out->Nodes->Coordinates[INDEX2(2,k,3)]=DBLE(i2)/DBLE(N2-1)*Length[2]; |
Nstride2=N0*N1; |
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out->Nodes->Id[k]=i0+N0*i1+N0*N1*i2; |
local_NE0=NE0; |
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out->Nodes->Tag[k]=0; |
e_offset0=0; |
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out->Nodes->degreeOfFreedom[k]=M0*(i0%NDOF0) +M1*(i1%NDOF1) +M2*(i2%NDOF2); |
local_NE1=NE1; |
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#ifdef PASO_MPI |
e_offset1=0; |
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out->Nodes->Dom[k]=NODE_INTERNAL; |
Paso_MPIInfo_Split(mpi_info,NE2,&local_NE2,&e_offset2); |
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#endif |
} else if (N1==MAX3(N0,N1,N2)) { |
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} |
Nstride0=N2; |
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} |
Nstride1=N0*N2; |
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Nstride2=1; |
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local_NE0=NE0; |
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e_offset0=0; |
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Paso_MPIInfo_Split(mpi_info,NE1,&local_NE1,&e_offset1); |
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local_NE2=NE2; |
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e_offset2=0; |
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} else { |
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Nstride0=N1*N2; |
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Nstride1=1; |
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Nstride2=N1; |
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Paso_MPIInfo_Split(mpi_info,NE0,&local_NE0,&e_offset0); |
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local_NE1=NE1; |
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e_offset1=0; |
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local_NE2=NE2; |
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e_offset2=0; |
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} |
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offset0=e_offset0*N_PER_E; |
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offset1=e_offset1*N_PER_E; |
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offset2=e_offset2*N_PER_E; |
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local_N0=local_NE0>0 ? local_NE0*N_PER_E+1 : 0; |
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local_N1=local_NE1>0 ? local_NE1*N_PER_E+1 : 0; |
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local_N2=local_NE2>0 ? local_NE2*N_PER_E+1 : 0; |
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/* get the number of surface elements */ |
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NFaceElements=0; |
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if (!periodic[2] && (local_NE2>0)) { |
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NDOF2=N2; |
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if (offset2==0) NFaceElements+=local_NE1*local_NE0; |
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if (local_NE2+e_offset2 == NE2) NFaceElements+=local_NE1*local_NE0; |
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} else { |
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NDOF2=N2-1; |
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} |
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if (!periodic[0] && (local_NE0>0)) { |
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NDOF0=N0; |
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if (e_offset0 == 0) NFaceElements+=local_NE1*local_NE2; |
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if (local_NE0+e_offset0 == NE0) NFaceElements+=local_NE1*local_NE2; |
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} else { |
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NDOF0=N0-1; |
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} |
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if (!periodic[1] && (local_NE1>0)) { |
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NDOF1=N1; |
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if (e_offset1 == 0) NFaceElements+=local_NE0*local_NE2; |
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if (local_NE1+e_offset1 == NE1) NFaceElements+=local_NE0*local_NE2; |
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} else { |
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NDOF1=N1-1; |
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} |
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} |
} |
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/* tags for the faces: */ |
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/* tags for the faces: */ |
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if (!periodic[2]) { |
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for (i1=0;i1<N1;i1++) { |
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for (i0=0;i0<N0;i0++) { |
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out->Nodes->Tag[M0*i0+M1*i1+M2*0]+=100; |
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out->Nodes->Tag[M0*i0+M1*i1+M2*(N2-1)]+=200; |
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} |
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} |
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} |
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if (!periodic[1]) { |
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for (i2=0;i2<N2;i2++) { |
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for (i0=0;i0<N0;i0++) { |
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out->Nodes->Tag[M0*i0+M1*0+M2*i2]+=10; |
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out->Nodes->Tag[M0*i0+M1*(N1-1)+M2*i2]+=20; |
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} |
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} |
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} |
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if (!periodic[0]) { |
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for (i2=0;i2<N2;i2++) { |
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for (i1=0;i1<N1;i1++) { |
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out->Nodes->Tag[M0*0+M1*i1+M2*i2]+=1; |
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out->Nodes->Tag[M0*(N0-1)+M1*i1+M2*i2]+=2; |
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} |
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} |
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} |
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/* set the elements: */ |
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#pragma omp parallel for private(i0,i1,i2,k,node0) |
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for (i2=0;i2<NE2;i2++) { |
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for (i1=0;i1<NE1;i1++) { |
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for (i0=0;i0<NE0;i0++) { |
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k=i0+NE0*i1+NE0*NE1*i2; |
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node0=i0+i1*N0+N0*N1*i2; |
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out->Elements->Id[k]=k; |
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out->Elements->Tag[k]=0; |
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out->Elements->Color[k]=COLOR_MOD(i0)+3*COLOR_MOD(i1)+9*COLOR_MOD(i2);; |
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#ifdef PASO_MPI |
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out->Elements->Dom[k]=ELEMENT_INTERNAL; |
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#endif |
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out->Elements->Nodes[INDEX2(0,k,8)]=node0; |
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out->Elements->Nodes[INDEX2(1,k,8)]=node0+1; |
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out->Elements->Nodes[INDEX2(2,k,8)]=node0+N0+1; |
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out->Elements->Nodes[INDEX2(3,k,8)]=node0+N0; |
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out->Elements->Nodes[INDEX2(4,k,8)]=node0+N0*N1; |
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out->Elements->Nodes[INDEX2(5,k,8)]=node0+N0*N1+1; |
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out->Elements->Nodes[INDEX2(6,k,8)]=node0+N0*N1+N0+1; |
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out->Elements->Nodes[INDEX2(7,k,8)]=node0+N0*N1+N0; |
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} |
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} |
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} |
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out->Elements->minColor=0; |
|
|
out->Elements->maxColor=COLOR_MOD(0)+3*COLOR_MOD(0)+9*COLOR_MOD(0); |
|
|
|
|
|
/* face elements: */ |
|
|
|
|
|
if (useElementsOnFace) { |
|
|
NUMNODES=8; |
|
|
} else { |
|
|
NUMNODES=4; |
|
|
} |
|
|
totalNECount=NE0*NE1*NE2; |
|
|
faceNECount=0; |
|
| 153 |
|
|
| 154 |
/* these are the quadrilateral elements on boundary 1 (x3=0): */ |
/* allocate tables: */ |
| 155 |
if (!periodic[2]) { |
if (Finley_noError()) { |
|
/* ** elements on boundary 100 (x3=0): */ |
|
|
|
|
|
#pragma omp parallel for private(i0,i1,k,node0) |
|
|
for (i1=0;i1<NE1;i1++) { |
|
|
for (i0=0;i0<NE0;i0++) { |
|
|
k=i0+NE0*i1+faceNECount; |
|
|
node0=i0+i1*N0; |
|
|
|
|
|
out->FaceElements->Id[k]=i0+NE0*i1+totalNECount; |
|
|
out->FaceElements->Tag[k]=100; |
|
|
out->FaceElements->Color[k]=(i0%2)+2*(i1%2); |
|
|
#ifdef PASO_MPI |
|
|
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
|
|
#endif |
|
| 156 |
|
|
| 157 |
if (useElementsOnFace) { |
Finley_NodeFile_allocTable(out->Nodes,local_N0*local_N1*local_N2); |
| 158 |
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0; |
Finley_ElementFile_allocTable(out->Elements,local_NE0*local_NE1*local_NE2); |
| 159 |
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+N0; |
Finley_ElementFile_allocTable(out->FaceElements,NFaceElements); |
| 160 |
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N0+1; |
} |
| 161 |
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+1; |
|
| 162 |
out->FaceElements->Nodes[INDEX2(4,k,NUMNODES)]=node0+N0*N1; |
if (Finley_noError()) { |
| 163 |
out->FaceElements->Nodes[INDEX2(5,k,NUMNODES)]=node0+N0*N1+N0; |
/* create nodes */ |
| 164 |
out->FaceElements->Nodes[INDEX2(6,k,NUMNODES)]=node0+N0*N1+N0+1; |
|
| 165 |
out->FaceElements->Nodes[INDEX2(7,k,NUMNODES)]=node0+N0*N1+1; |
#pragma omp parallel for private(i0,i1,i2,k,global_i0,global_i1,global_i2) |
| 166 |
} else { |
for (i2=0;i2<local_N2;i2++) { |
| 167 |
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0; |
for (i1=0;i1<local_N1;i1++) { |
| 168 |
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+N0; |
for (i0=0;i0<local_N0;i0++) { |
| 169 |
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N0+1; |
k=i0+local_N0*i1+local_N0*local_N1*i2; |
| 170 |
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+1; |
global_i0=i0+offset0; |
| 171 |
|
global_i1=i1+offset1; |
| 172 |
|
global_i2=i2+offset2; |
| 173 |
|
out->Nodes->Coordinates[INDEX2(0,k,DIM)]=DBLE(global_i0)/DBLE(N0-1)*Length[0]; |
| 174 |
|
out->Nodes->Coordinates[INDEX2(1,k,DIM)]=DBLE(global_i1)/DBLE(N1-1)*Length[1]; |
| 175 |
|
out->Nodes->Coordinates[INDEX2(2,k,DIM)]=DBLE(global_i2)/DBLE(N2-1)*Length[2]; |
| 176 |
|
out->Nodes->Id[k]=Nstride0*global_i0+Nstride1*global_i1+Nstride2*global_i2; |
| 177 |
|
out->Nodes->Tag[k]=0; |
| 178 |
|
out->Nodes->globalDegreesOfFreedom[k]=Nstride0*(global_i0%NDOF0) |
| 179 |
|
+Nstride1*(global_i1%NDOF1) |
| 180 |
|
+Nstride2*(global_i2%NDOF2); |
| 181 |
} |
} |
| 182 |
} |
} |
| 183 |
} |
} |
| 184 |
totalNECount+=NE1*NE0; |
/* set the elements: */ |
| 185 |
faceNECount+=NE1*NE0; |
NN=out->Elements->numNodes; |
| 186 |
|
#pragma omp parallel for private(i0,i1,i2,k,node0) |
| 187 |
/* ** elements on boundary 200 (x3=1) */ |
for (i2=0;i2<local_NE2;i2++) { |
| 188 |
|
for (i1=0;i1<local_NE1;i1++) { |
| 189 |
#pragma omp parallel for private(i0,i1,k,node0) |
for (i0=0;i0<local_NE0;i0++) { |
| 190 |
for (i1=0;i1<NE1;i1++) { |
|
| 191 |
for (i0=0;i0<NE0;i0++) { |
k=i0+local_NE0*i1+local_NE0*local_NE1*i2; |
| 192 |
k=i0+NE0*i1+faceNECount; |
node0=Nstride0*N_PER_E*(i0+e_offset0)+Nstride1*N_PER_E*(i1+e_offset1)+Nstride2*N_PER_E*(i2+e_offset2); |
| 193 |
node0=i0+i1*N0+N0*N1*(NE2-1); |
|
| 194 |
|
out->Elements->Id[k]=(i0+e_offset0)+NE0*(i1+e_offset1)+NE0*NE1*(i2+e_offset2); |
| 195 |
out->FaceElements->Id[k]=i0+NE0*i1+totalNECount; |
out->Elements->Tag[k]=0; |
| 196 |
out->FaceElements->Tag[k]=200; |
out->Elements->Owner[k]=myRank; |
| 197 |
out->FaceElements->Color[k]=(i0%2)+2*(i1%2)+4; |
|
| 198 |
#ifdef PASO_MPI |
out->Elements->Nodes[INDEX2(0,k,NN)] =node0 ; |
| 199 |
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
out->Elements->Nodes[INDEX2(1,k,NN)] =node0+ Nstride0; |
| 200 |
#endif |
out->Elements->Nodes[INDEX2(2,k,NN)] =node0+ Nstride1+Nstride0; |
| 201 |
|
out->Elements->Nodes[INDEX2(3,k,NN)] =node0+ Nstride1; |
| 202 |
if (useElementsOnFace) { |
out->Elements->Nodes[INDEX2(4,k,NN)] =node0+Nstride2 ; |
| 203 |
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0+ N0 * N1; |
out->Elements->Nodes[INDEX2(5,k,NN)] =node0+Nstride2 +Nstride0; |
| 204 |
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+ N0 * N1+1; |
out->Elements->Nodes[INDEX2(6,k,NN)] =node0+Nstride2+Nstride1+Nstride0; |
| 205 |
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+ N0 * N1+N0+1; |
out->Elements->Nodes[INDEX2(7,k,NN)] =node0+Nstride2+Nstride1 ; |
|
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+ N0 * N1+N0; |
|
|
out->FaceElements->Nodes[INDEX2(4,k,NUMNODES)]=node0; |
|
|
out->FaceElements->Nodes[INDEX2(5,k,NUMNODES)]=node0+1; |
|
|
out->FaceElements->Nodes[INDEX2(6,k,NUMNODES)]=node0+N0+1; |
|
|
out->FaceElements->Nodes[INDEX2(7,k,NUMNODES)]=node0+N0; |
|
|
} else { |
|
|
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0+ N0 * N1; |
|
|
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+ N0 * N1+1; |
|
|
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+ N0 * N1+N0+1; |
|
|
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+ N0 * N1+N0; |
|
| 206 |
} |
} |
|
|
|
|
|
|
| 207 |
} |
} |
| 208 |
} |
} |
| 209 |
totalNECount+=NE1*NE0; |
/* face elements */ |
| 210 |
faceNECount+=NE1*NE0; |
NN=out->FaceElements->numNodes; |
| 211 |
} |
totalNECount=NE0*NE1*NE2; |
| 212 |
if (!periodic[0]) { |
faceNECount=0; |
| 213 |
/* ** elements on boundary 001 (x1=0): */ |
/* these are the quadrilateral elements on boundary 1 (x3=0): */ |
| 214 |
|
if (!periodic[2] && (local_NE2>0)) { |
| 215 |
#pragma omp parallel for private(i1,i2,k,node0) |
/* ** elements on boundary 100 (x3=0): */ |
| 216 |
for (i2=0;i2<NE2;i2++) { |
if (e_offset2==0) { |
| 217 |
for (i1=0;i1<NE1;i1++) { |
#pragma omp parallel for private(i0,i1,k,node0) |
| 218 |
k=i1+NE1*i2+faceNECount; |
for (i1=0;i1<local_NE1;i1++) { |
| 219 |
node0=i1*N0+N0*N1*i2; |
for (i0=0;i0<local_NE0;i0++) { |
| 220 |
|
|
| 221 |
out->FaceElements->Id[k]=i1+NE1*i2+totalNECount; |
k=i0+local_NE0*i1+faceNECount; |
| 222 |
out->FaceElements->Tag[k]=1; |
node0=Nstride0*N_PER_E*(i0+e_offset0)+Nstride1*N_PER_E*(i1+e_offset1); |
| 223 |
out->FaceElements->Color[k]=(i2%2)+2*(i1%2)+8; |
|
| 224 |
#ifdef PASO_MPI |
out->FaceElements->Id[k]=(i0+e_offset0)+NE0*(i1+e_offset1)+totalNECount; |
| 225 |
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
out->FaceElements->Tag[k]=100; |
| 226 |
#endif |
out->FaceElements->Owner[k]=myRank; |
| 227 |
|
|
| 228 |
if (useElementsOnFace) { |
if (useElementsOnFace) { |
| 229 |
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0; |
out->FaceElements->Nodes[INDEX2(0,k,NN)] =node0 ; |
| 230 |
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+N0*N1; |
out->FaceElements->Nodes[INDEX2(1,k,NN)] =node0 +Nstride1 ; |
| 231 |
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N0*N1+N0; |
out->FaceElements->Nodes[INDEX2(2,k,NN)] =node0 +Nstride1+Nstride0; |
| 232 |
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+N0; |
out->FaceElements->Nodes[INDEX2(3,k,NN)] =node0+ Nstride0 ; |
| 233 |
out->FaceElements->Nodes[INDEX2(4,k,NUMNODES)]=node0+1; |
out->FaceElements->Nodes[INDEX2(4,k,NN)] =node0+Nstride2 ; |
| 234 |
out->FaceElements->Nodes[INDEX2(5,k,NUMNODES)]=node0+N0*N1+1; |
out->FaceElements->Nodes[INDEX2(5,k,NN)] =node0+Nstride2+Nstride1 ; |
| 235 |
out->FaceElements->Nodes[INDEX2(6,k,NUMNODES)]=node0+N0*N1+N0+1; |
out->FaceElements->Nodes[INDEX2(6,k,NN)] =node0+Nstride2+Nstride1+Nstride0; |
| 236 |
out->FaceElements->Nodes[INDEX2(7,k,NUMNODES)]=node0+N0+1; |
out->FaceElements->Nodes[INDEX2(7,k,NN)] =node0+Nstride2 +Nstride0; |
| 237 |
} else { |
} else { |
| 238 |
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0; |
out->FaceElements->Nodes[INDEX2(0,k,NN)] =node0 ; |
| 239 |
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+N0*N1; |
out->FaceElements->Nodes[INDEX2(1,k,NN)] =node0+ Nstride1 ; |
| 240 |
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N0*N1+N0; |
out->FaceElements->Nodes[INDEX2(2,k,NN)] =node0+ Nstride1+Nstride0; |
| 241 |
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+N0; |
out->FaceElements->Nodes[INDEX2(3,k,NN)] =node0+ Nstride0; |
| 242 |
} |
} |
| 243 |
|
} |
| 244 |
|
} |
| 245 |
|
faceNECount+=local_NE1*local_NE0; |
| 246 |
|
} |
| 247 |
|
totalNECount+=NE1*NE0; |
| 248 |
|
/* ** elements on boundary 200 (x3=1) */ |
| 249 |
|
if (local_NE2+e_offset2 == NE2) { |
| 250 |
|
#pragma omp parallel for private(i0,i1,k,node0) |
| 251 |
|
for (i1=0;i1<local_NE1;i1++) { |
| 252 |
|
for (i0=0;i0<local_NE0;i0++) { |
| 253 |
|
|
| 254 |
|
k=i0+local_NE0*i1+faceNECount; |
| 255 |
|
node0=Nstride0*N_PER_E*(i0+e_offset0)+Nstride1*N_PER_E*(i1+e_offset1)+Nstride2*N_PER_E*(NE2-1); |
| 256 |
|
|
| 257 |
|
out->FaceElements->Id[k]=(i0+e_offset0)+NE0*(i1+e_offset1)+totalNECount; |
| 258 |
|
out->FaceElements->Tag[k]=200; |
| 259 |
|
out->FaceElements->Owner[k]=myRank; |
| 260 |
|
if (useElementsOnFace) { |
| 261 |
|
out->FaceElements->Nodes[INDEX2(0,k,NN)] =node0+Nstride2 ; |
| 262 |
|
out->FaceElements->Nodes[INDEX2(1,k,NN)] =node0+Nstride2+ Nstride0; |
| 263 |
|
out->FaceElements->Nodes[INDEX2(2,k,NN)] =node0+Nstride2+Nstride1+Nstride0; |
| 264 |
|
out->FaceElements->Nodes[INDEX2(3,k,NN)] =node0+Nstride2+Nstride1 ; |
| 265 |
|
|
| 266 |
|
out->FaceElements->Nodes[INDEX2(4,k,NN)] =node0 ; |
| 267 |
|
out->FaceElements->Nodes[INDEX2(5,k,NN)] =node0+Nstride0 ; |
| 268 |
|
out->FaceElements->Nodes[INDEX2(6,k,NN)] =node0+ Nstride1+Nstride0; |
| 269 |
|
out->FaceElements->Nodes[INDEX2(7,k,NN)] =node0+ Nstride1; |
| 270 |
|
} else { |
| 271 |
|
out->FaceElements->Nodes[INDEX2(0,k,NN)] =node0+Nstride2 ; |
| 272 |
|
out->FaceElements->Nodes[INDEX2(1,k,NN)] =node0+Nstride2 +Nstride0; |
| 273 |
|
out->FaceElements->Nodes[INDEX2(2,k,NN)] =node0+Nstride2+Nstride1+Nstride0; |
| 274 |
|
out->FaceElements->Nodes[INDEX2(3,k,NN)] =node0+Nstride2+Nstride1 ; |
| 275 |
|
} |
| 276 |
|
} |
| 277 |
|
} |
| 278 |
|
faceNECount+=local_NE1*local_NE0; |
| 279 |
} |
} |
| 280 |
|
totalNECount+=NE1*NE0; |
| 281 |
} |
} |
| 282 |
totalNECount+=NE1*NE2; |
if (!periodic[0] && (local_NE0>0)) { |
| 283 |
faceNECount+=NE1*NE2; |
/* ** elements on boundary 001 (x1=0): */ |
| 284 |
|
|
| 285 |
/* ** elements on boundary 002 (x1=1): */ |
if (e_offset0 == 0) { |
| 286 |
|
#pragma omp parallel for private(i1,i2,k,node0) |
| 287 |
#pragma omp parallel for private(i1,i2,k,node0) |
for (i2=0;i2<local_NE2;i2++) { |
| 288 |
for (i2=0;i2<NE2;i2++) { |
for (i1=0;i1<local_NE1;i1++) { |
| 289 |
for (i1=0;i1<NE1;i1++) { |
|
| 290 |
k=i1+NE1*i2+faceNECount; |
k=i1+local_NE1*i2+faceNECount; |
| 291 |
node0=(NE0-1)+i1*N0+N0*N1*i2 ; |
node0=Nstride1*N_PER_E*(i1+e_offset1)+Nstride2*N_PER_E*(i2+e_offset2); |
| 292 |
|
out->FaceElements->Id[k]=(i1+e_offset1)+NE1*(i2+e_offset2)+totalNECount; |
| 293 |
out->FaceElements->Id[k]=i1+NE1*i2+totalNECount; |
out->FaceElements->Tag[k]=1; |
| 294 |
out->FaceElements->Tag[k]=2; |
out->FaceElements->Owner[k]=myRank; |
| 295 |
out->FaceElements->Color[k]=(i2%2)+2*(i1%2)+12; |
|
| 296 |
#ifdef PASO_MPI |
if (useElementsOnFace) { |
| 297 |
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
out->FaceElements->Nodes[INDEX2(0,k,NN)] =node0 ; |
| 298 |
#endif |
out->FaceElements->Nodes[INDEX2(1,k,NN)] =node0+Nstride2 ; |
| 299 |
|
out->FaceElements->Nodes[INDEX2(2,k,NN)] =node0+Nstride2+Nstride1 ; |
| 300 |
if (useElementsOnFace) { |
out->FaceElements->Nodes[INDEX2(3,k,NN)] =node0+Nstride1 ; |
| 301 |
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0+1; |
out->FaceElements->Nodes[INDEX2(4,k,NN)] =node0+Nstride0 ; |
| 302 |
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+N0+1; |
out->FaceElements->Nodes[INDEX2(5,k,NN)] =node0+Nstride2+Nstride0 ; |
| 303 |
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N0*N1+N0+1; |
out->FaceElements->Nodes[INDEX2(6,k,NN)] =node0+Nstride2+Nstride1+Nstride0; |
| 304 |
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+N0*N1+1; |
out->FaceElements->Nodes[INDEX2(7,k,NN)] =node0+Nstride1+Nstride0 ; |
| 305 |
out->FaceElements->Nodes[INDEX2(4,k,NUMNODES)]=node0; |
} else { |
| 306 |
out->FaceElements->Nodes[INDEX2(5,k,NUMNODES)]=node0+N0; |
out->FaceElements->Nodes[INDEX2(0,k,NN)] =node0 ; |
| 307 |
out->FaceElements->Nodes[INDEX2(6,k,NUMNODES)]=node0+N0*N1+N0; |
out->FaceElements->Nodes[INDEX2(1,k,NN)] =node0+Nstride2 ; |
| 308 |
out->FaceElements->Nodes[INDEX2(7,k,NUMNODES)]=node0+N0*N1; |
out->FaceElements->Nodes[INDEX2(2,k,NN)] =node0+Nstride2+Nstride1 ; |
| 309 |
} else { |
out->FaceElements->Nodes[INDEX2(3,k,NN)] =node0+ Nstride1 ; |
| 310 |
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0+1; |
} |
| 311 |
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+N0+1; |
} |
| 312 |
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N0*N1+N0+1; |
} |
| 313 |
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+N0*N1+1; |
faceNECount+=local_NE1*local_NE2; |
| 314 |
|
} |
| 315 |
|
totalNECount+=NE1*NE2; |
| 316 |
|
/* ** elements on boundary 002 (x1=1): */ |
| 317 |
|
if (local_NE0+e_offset0 == NE0) { |
| 318 |
|
#pragma omp parallel for private(i1,i2,k,node0) |
| 319 |
|
for (i2=0;i2<local_NE2;i2++) { |
| 320 |
|
for (i1=0;i1<local_NE1;i1++) { |
| 321 |
|
k=i1+local_NE1*i2+faceNECount; |
| 322 |
|
node0=Nstride0*N_PER_E*(NE0-1)+Nstride1*N_PER_E*(i1+e_offset1)+Nstride2*N_PER_E*(i2+e_offset2); |
| 323 |
|
out->FaceElements->Id[k]=(i1+e_offset1)+NE1*(i2+e_offset2)+totalNECount; |
| 324 |
|
out->FaceElements->Tag[k]=2; |
| 325 |
|
out->FaceElements->Owner[k]=myRank; |
| 326 |
|
|
| 327 |
|
if (useElementsOnFace) { |
| 328 |
|
out->FaceElements->Nodes[INDEX2(0,k,NN)]=node0+ Nstride0; |
| 329 |
|
out->FaceElements->Nodes[INDEX2(1,k,NN)]=node0+ Nstride1+Nstride0; |
| 330 |
|
out->FaceElements->Nodes[INDEX2(2,k,NN)]=node0+Nstride2+Nstride1+Nstride0; |
| 331 |
|
out->FaceElements->Nodes[INDEX2(3,k,NN)]=node0+Nstride2+ Nstride0; |
| 332 |
|
|
| 333 |
|
out->FaceElements->Nodes[INDEX2(4,k,NN)]=node0 ; |
| 334 |
|
out->FaceElements->Nodes[INDEX2(5,k,NN)]=node0+ Nstride1 ; |
| 335 |
|
out->FaceElements->Nodes[INDEX2(6,k,NN)]=node0+Nstride2+Nstride1 ; |
| 336 |
|
out->FaceElements->Nodes[INDEX2(7,k,NN)]=node0+Nstride2 ; |
| 337 |
|
|
| 338 |
|
} else { |
| 339 |
|
out->FaceElements->Nodes[INDEX2(0,k,NN)]=node0 +Nstride0; |
| 340 |
|
out->FaceElements->Nodes[INDEX2(1,k,NN)]=node0+ Nstride1+Nstride0; |
| 341 |
|
out->FaceElements->Nodes[INDEX2(2,k,NN)]=node0+Nstride2+Nstride1+Nstride0; |
| 342 |
|
out->FaceElements->Nodes[INDEX2(3,k,NN)]=node0+Nstride2+ Nstride0; |
| 343 |
|
} |
| 344 |
|
|
| 345 |
|
} |
| 346 |
|
} |
| 347 |
|
faceNECount+=local_NE1*local_NE2; |
| 348 |
} |
} |
| 349 |
} |
totalNECount+=NE1*NE2; |
| 350 |
} |
} |
| 351 |
totalNECount+=NE1*NE2; |
if (!periodic[1] && (local_NE1>0)) { |
| 352 |
faceNECount+=NE1*NE2; |
/* ** elements on boundary 010 (x2=0): */ |
| 353 |
|
if (e_offset1 == 0) { |
| 354 |
|
#pragma omp parallel for private(i0,i2,k,node0) |
| 355 |
|
for (i2=0;i2<local_NE2;i2++) { |
| 356 |
|
for (i0=0;i0<local_NE0;i0++) { |
| 357 |
|
k=i0+local_NE0*i2+faceNECount; |
| 358 |
|
node0=Nstride0*N_PER_E*(i0+e_offset0)+Nstride2*N_PER_E*(i2+e_offset2); |
| 359 |
|
|
| 360 |
|
out->FaceElements->Id[k]=(i2+e_offset2)+NE2*(e_offset0+i0)+totalNECount; |
| 361 |
|
out->FaceElements->Tag[k]=10; |
| 362 |
|
out->FaceElements->Owner[k]=myRank; |
| 363 |
|
if (useElementsOnFace) { |
| 364 |
|
out->FaceElements->Nodes[INDEX2(0,k,NN)]=node0 ; |
| 365 |
|
out->FaceElements->Nodes[INDEX2(1,k,NN)]=node0+ Nstride0; |
| 366 |
|
out->FaceElements->Nodes[INDEX2(2,k,NN)]=node0+Nstride2 +Nstride0; |
| 367 |
|
out->FaceElements->Nodes[INDEX2(3,k,NN)]=node0+Nstride2 ; |
| 368 |
|
|
| 369 |
|
out->FaceElements->Nodes[INDEX2(4,k,NN)]=node0+ Nstride1 ; |
| 370 |
|
out->FaceElements->Nodes[INDEX2(5,k,NN)]=node0+Nstride1+ Nstride0; |
| 371 |
|
out->FaceElements->Nodes[INDEX2(6,k,NN)]=node0+Nstride2+Nstride1+Nstride0; |
| 372 |
|
out->FaceElements->Nodes[INDEX2(7,k,NN)]=node0+Nstride2+Nstride1 ; |
| 373 |
|
} else { |
| 374 |
|
out->FaceElements->Nodes[INDEX2(0,k,NN)]=node0 ; |
| 375 |
|
out->FaceElements->Nodes[INDEX2(1,k,NN)]=node0+ Nstride0; |
| 376 |
|
out->FaceElements->Nodes[INDEX2(2,k,NN)]=node0+Nstride2+ Nstride0; |
| 377 |
|
out->FaceElements->Nodes[INDEX2(3,k,NN)]=node0+Nstride2 ; |
| 378 |
|
} |
| 379 |
|
} |
| 380 |
|
} |
| 381 |
|
faceNECount+=local_NE0*local_NE2; |
| 382 |
|
} |
| 383 |
|
totalNECount+=NE0*NE2; |
| 384 |
|
/* ** elements on boundary 020 (x2=1): */ |
| 385 |
|
if (local_NE1+e_offset1 == NE1) { |
| 386 |
|
#pragma omp parallel for private(i0,i2,k,node0) |
| 387 |
|
for (i2=0;i2<local_NE2;i2++) { |
| 388 |
|
for (i0=0;i0<local_NE0;i0++) { |
| 389 |
|
k=i0+local_NE0*i2+faceNECount; |
| 390 |
|
node0=Nstride0*N_PER_E*(i0+e_offset0)+Nstride1*N_PER_E*(NE1-1)+Nstride2*N_PER_E*(i2+e_offset2); |
| 391 |
|
|
| 392 |
|
out->FaceElements->Id[k]=(i2+e_offset2)+NE2*(i0+e_offset0)+totalNECount; |
| 393 |
|
out->FaceElements->Tag[k]=20; |
| 394 |
|
out->FaceElements->Owner[k]=myRank; |
| 395 |
|
|
| 396 |
|
if (useElementsOnFace) { |
| 397 |
|
out->FaceElements->Nodes[INDEX2(0,k,NN)]=node0+ Nstride1 ; |
| 398 |
|
out->FaceElements->Nodes[INDEX2(1,k,NN)]=node0+Nstride2+Nstride1 ; |
| 399 |
|
out->FaceElements->Nodes[INDEX2(2,k,NN)]=node0+Nstride2+Nstride1+Nstride0; |
| 400 |
|
out->FaceElements->Nodes[INDEX2(3,k,NN)]=node0+Nstride1+Nstride0 ; |
| 401 |
|
|
| 402 |
|
out->FaceElements->Nodes[INDEX2(4,k,NN)]=node0 ; |
| 403 |
|
out->FaceElements->Nodes[INDEX2(5,k,NN)]=node0+Nstride2 ; |
| 404 |
|
out->FaceElements->Nodes[INDEX2(6,k,NN)]=node0+Nstride2+ Nstride0; |
| 405 |
|
out->FaceElements->Nodes[INDEX2(7,k,NN)]=node0+ Nstride0; |
| 406 |
|
} else { |
| 407 |
|
out->FaceElements->Nodes[INDEX2(0,k,NN)]=node0+ Nstride1 ; |
| 408 |
|
out->FaceElements->Nodes[INDEX2(1,k,NN)]=node0+Nstride2+Nstride1 ; |
| 409 |
|
out->FaceElements->Nodes[INDEX2(2,k,NN)]=node0+Nstride2+Nstride1+Nstride0; |
| 410 |
|
out->FaceElements->Nodes[INDEX2(3,k,NN)]=node0+ Nstride1+Nstride0; |
| 411 |
|
} |
| 412 |
|
} |
| 413 |
|
} |
| 414 |
|
faceNECount+=local_NE0*local_NE2; |
| 415 |
|
} |
| 416 |
|
totalNECount+=NE0*NE2; |
| 417 |
|
} |
| 418 |
|
} |
| 419 |
|
if (Finley_noError()) { |
| 420 |
|
/* add tag names */ |
| 421 |
|
Finley_Mesh_addTagMap(out,"top", 200); |
| 422 |
|
Finley_Mesh_addTagMap(out,"bottom", 100); |
| 423 |
|
Finley_Mesh_addTagMap(out,"left", 1); |
| 424 |
|
Finley_Mesh_addTagMap(out,"right", 2); |
| 425 |
|
Finley_Mesh_addTagMap(out,"front", 10); |
| 426 |
|
Finley_Mesh_addTagMap(out,"back", 20); |
| 427 |
} |
} |
|
if (!periodic[1]) { |
|
|
/* ** elements on boundary 010 (x2=0): */ |
|
|
|
|
|
#pragma omp parallel for private(i0,i2,k,node0) |
|
|
for (i2=0;i2<NE2;i2++) { |
|
|
for (i0=0;i0<NE0;i0++) { |
|
|
k=i0+NE0*i2+faceNECount; |
|
|
node0=i0+N0*N1*i2; |
|
|
|
|
|
out->FaceElements->Id[k]=i2+NE2*i0+totalNECount; |
|
|
out->FaceElements->Tag[k]=10; |
|
|
out->FaceElements->Color[k]=(i0%2)+2*(i2%2)+16; |
|
|
#ifdef PASO_MPI |
|
|
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
|
|
#endif |
|
|
|
|
|
if (useElementsOnFace) { |
|
|
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0; |
|
|
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+1; |
|
|
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N1*N0+1; |
|
|
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+N1*N0; |
|
|
out->FaceElements->Nodes[INDEX2(4,k,NUMNODES)]=node0+N0; |
|
|
out->FaceElements->Nodes[INDEX2(5,k,NUMNODES)]=node0+N0+1; |
|
|
out->FaceElements->Nodes[INDEX2(6,k,NUMNODES)]=node0+N1*N0+N0+1; |
|
|
out->FaceElements->Nodes[INDEX2(7,k,NUMNODES)]=node0+N1*N0+N0; |
|
|
} else { |
|
|
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0; |
|
|
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+1; |
|
|
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N1*N0+1; |
|
|
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+N1*N0; |
|
|
} |
|
|
} |
|
|
} |
|
|
totalNECount+=NE0*NE2; |
|
|
faceNECount+=NE0*NE2; |
|
|
|
|
|
/* ** elements on boundary 020 (x2=1): */ |
|
|
|
|
|
#pragma omp parallel for private(i0,i2,k,node0) |
|
|
for (i2=0;i2<NE2;i2++) { |
|
|
for (i0=0;i0<NE0;i0++) { |
|
|
k=i0+NE0*i2+faceNECount; |
|
|
node0=i0+(NE1-1)*N0+N0*N1*i2; |
|
|
|
|
|
out->FaceElements->Tag[k]=20; |
|
|
out->FaceElements->Id[k]=i2+NE2*i0+totalNECount; |
|
|
out->FaceElements->Color[k]=(i0%2)+2*(i2%2)+20; |
|
|
#ifdef PASO_MPI |
|
|
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
|
|
#endif |
|
|
|
|
|
if (useElementsOnFace) { |
|
|
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0+N0; |
|
|
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+N0*N1+N0; |
|
|
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N0*N1+N0+1; |
|
|
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+N0+1; |
|
|
out->FaceElements->Nodes[INDEX2(4,k,NUMNODES)]=node0; |
|
|
out->FaceElements->Nodes[INDEX2(5,k,NUMNODES)]=node0+N0*N1; |
|
|
out->FaceElements->Nodes[INDEX2(6,k,NUMNODES)]=node0+N0*N1+1; |
|
|
out->FaceElements->Nodes[INDEX2(7,k,NUMNODES)]=node0+1; |
|
|
} else { |
|
|
out->FaceElements->Nodes[INDEX2(0,k,NUMNODES)]=node0+N0; |
|
|
out->FaceElements->Nodes[INDEX2(1,k,NUMNODES)]=node0+N0*N1+N0; |
|
|
out->FaceElements->Nodes[INDEX2(2,k,NUMNODES)]=node0+N0*N1+N0+1; |
|
|
out->FaceElements->Nodes[INDEX2(3,k,NUMNODES)]=node0+N0+1; |
|
|
} |
|
|
|
|
|
} |
|
|
} |
|
|
totalNECount+=NE0*NE2; |
|
|
faceNECount+=NE0*NE2; |
|
|
} |
|
|
out->FaceElements->minColor=0; |
|
|
out->FaceElements->maxColor=23; |
|
|
|
|
|
#ifdef PASO_MPI |
|
|
Finley_ElementFile_setDomainFlags( out->Elements ); |
|
|
Finley_ElementFile_setDomainFlags( out->FaceElements ); |
|
|
Finley_ElementFile_setDomainFlags( out->ContactElements ); |
|
|
Finley_ElementFile_setDomainFlags( out->Points ); |
|
|
|
|
|
/* reorder the degrees of freedom */ |
|
|
Finley_Mesh_resolveDegreeOfFreedomOrder( out, TRUE ); |
|
|
#endif |
|
|
|
|
|
/* condense the nodes: */ |
|
|
Finley_Mesh_resolveNodeIds(out); |
|
|
|
|
| 428 |
/* prepare mesh for further calculatuions:*/ |
/* prepare mesh for further calculatuions:*/ |
| 429 |
Finley_Mesh_prepare(out) ; |
if (Finley_noError()) { |
| 430 |
|
Finley_Mesh_resolveNodeIds(out); |
|
#ifdef Finley_TRACE |
|
|
printf("timing: mesh generation: %.4e sec\n",Finley_timer()-time0); |
|
|
#endif |
|
|
|
|
|
if (! Finley_noError()) { |
|
|
Finley_Mesh_dealloc(out); |
|
|
return NULL; |
|
| 431 |
} |
} |
| 432 |
return out; |
if (Finley_noError()) { |
| 433 |
} |
Finley_Mesh_prepare(out, optimize); |
|
|
|
|
#ifdef PASO_MPI |
|
|
Finley_Mesh* Finley_RectangularMesh_Hex8(dim_t* numElements,double* Length,bool_t* periodic, index_t order,bool_t useElementsOnFace) |
|
|
{ |
|
|
dim_t N0,N1,N2,N0t,NDOF0t,NE0,NE1,NE2,i0,i1,i2,kk,k,totalNECount,faceNECount,NDOF0,NDOF1,NDOF2,NFaceElements,NUMNODES;//,M0,M1,M2; |
|
|
dim_t idCount, NE0_local, numNodesLocal, numDOFLocal, numElementsLocal, numElementsInternal, nodesExternal[2], DOFExternal[2], numNodesExternal; |
|
|
bool_t dom_left, dom_right, dom_internal; |
|
|
index_t firstNode=0, DOFcount=0, node0, node1, node2; |
|
|
index_t targetDomain=-1, firstNodeConstruct, j; |
|
|
bool_t periodicLocal[2], domLeft=FALSE, domRight=FALSE, domInternal=FALSE, boundaryLeft=FALSE, boundaryRight=FALSE; |
|
|
index_t *indexBackward=NULL, *indexForward=NULL,*facePerm=NULL, *forwardDOF=NULL, *backwardDOF=NULL; |
|
|
Finley_Mesh* out; |
|
|
|
|
|
char name[50]; |
|
|
Paso_MPIInfo *mpi_info = NULL; |
|
|
double time0=Finley_timer(); |
|
|
|
|
|
index_t face0[] = {3, 0, 4, 7, 2, 1, 5, 6}; |
|
|
index_t face1[] = {1, 2, 6, 5, 0, 3, 7, 4}; |
|
|
index_t face2[] = {0, 3, 2, 1, 4, 7, 6, 5}; |
|
|
index_t face3[] = {4, 5, 6, 7, 0, 1, 2, 3}; |
|
|
index_t face4[] = {0, 1, 5, 4, 3, 2, 6, 7}; |
|
|
index_t face5[] = {3, 7, 6, 2, 0, 4, 5, 1}; |
|
|
NE0=MAX(1,numElements[0]); |
|
|
NE1=MAX(1,numElements[1]); |
|
|
NE2=MAX(1,numElements[2]); |
|
|
N0=NE0+1; |
|
|
N1=NE1+1; |
|
|
N2=NE2+1; |
|
|
|
|
|
|
|
|
/* get MPI information */ |
|
|
mpi_info = Paso_MPIInfo_alloc( MPI_COMM_WORLD ); |
|
|
if (! Finley_noError()) |
|
|
return NULL; |
|
|
|
|
|
/* use the serial version to generate the mesh for the 1-CPU case */ |
|
|
if( mpi_info->size==1 ) |
|
|
{ |
|
|
out = Finley_RectangularMesh_Hex8_singleCPU( numElements, Length, periodic, order, useElementsOnFace, mpi_info ); |
|
|
return out; |
|
|
} |
|
|
|
|
|
if( mpi_info->rank==0 ) |
|
|
domLeft = TRUE; |
|
|
if( mpi_info->rank==mpi_info->size-1 ) |
|
|
domRight = TRUE; |
|
|
if( mpi_info->rank>0 && mpi_info->rank<mpi_info->size-1 ) |
|
|
domInternal = TRUE; |
|
|
|
|
|
/* dimensions of the local subdomain */ |
|
|
domain_calculateDimension( mpi_info->rank, mpi_info->size, NE0, periodic[0], &numNodesLocal, &numDOFLocal, &numElementsLocal, &numElementsInternal, &firstNode, nodesExternal, DOFExternal, &numNodesExternal, periodicLocal ); |
|
|
|
|
|
/* count Degrees of Freedom along each axis */ |
|
|
NDOF0 = N0 - periodic[0]; |
|
|
NDOF1 = N1 - periodic[1]; |
|
|
NDOF2 = N2 - periodic[2]; |
|
|
|
|
|
/* count face elements */ |
|
|
/* internal face elements */ |
|
|
NFaceElements = 0; |
|
|
if( !periodic[0] ) |
|
|
NFaceElements += (domLeft+domRight)*NE1*NE2; |
|
|
if( !periodic[1] ) |
|
|
NFaceElements += 2*numElementsLocal*NE2; |
|
|
if( !periodic[2] ) |
|
|
NFaceElements += 2*numElementsLocal*NE1; |
|
|
|
|
|
boundaryLeft = !domLeft || periodicLocal[0]; |
|
|
boundaryRight = !domRight || periodicLocal[1]; |
|
|
N0t = numNodesLocal + boundaryRight + boundaryLeft; |
|
|
NDOF0t = numDOFLocal + boundaryRight + boundaryLeft; |
|
|
firstNodeConstruct = firstNode - boundaryLeft; |
|
|
firstNodeConstruct = firstNodeConstruct<0 ? N0-2 : firstNodeConstruct; |
|
|
|
|
|
/* allocate mesh: */ |
|
|
sprintf(name,"Rectangular %d x %d x %d mesh",N0,N1,N2); |
|
|
|
|
|
out=Finley_Mesh_alloc(name,3,order,mpi_info); |
|
|
if (! Finley_noError()) return NULL; |
|
|
|
|
|
out->Elements=Finley_ElementFile_alloc(Hex8,out->order,mpi_info); |
|
|
if (useElementsOnFace) { |
|
|
out->FaceElements=Finley_ElementFile_alloc(Hex8Face,out->order,mpi_info); |
|
|
out->ContactElements=Finley_ElementFile_alloc(Hex8Face_Contact,out->order,mpi_info); |
|
|
} else { |
|
|
out->FaceElements=Finley_ElementFile_alloc(Rec4,out->order,mpi_info); |
|
|
out->ContactElements=Finley_ElementFile_alloc(Rec4_Contact,out->order,mpi_info); |
|
| 434 |
} |
} |
|
out->Points=Finley_ElementFile_alloc(Point1,out->order,mpi_info); |
|
| 435 |
|
|
| 436 |
if (! Finley_noError()) { |
if (!Finley_noError()) { |
| 437 |
Finley_Mesh_dealloc(out); |
Finley_Mesh_free(out); |
| 438 |
return NULL; |
} |
| 439 |
} |
/* free up memory */ |
| 440 |
|
Finley_ReferenceElementSet_dealloc(refPoints); |
| 441 |
/* allocate tables: */ |
Finley_ReferenceElementSet_dealloc(refContactElements); |
| 442 |
Finley_NodeFile_allocTable(out->Nodes,N0t*N1*N2); |
Finley_ReferenceElementSet_dealloc(refFaceElements); |
| 443 |
Finley_NodeDistribution_allocTable( out->Nodes->degreeOfFreedomDistribution, numDOFLocal*NDOF1*NDOF2, NDOF1*NDOF2*2, 0 ); |
Finley_ReferenceElementSet_dealloc(refElements); |
| 444 |
Finley_ElementFile_allocTable(out->Elements,(numElementsLocal)*NE1*NE2); |
Paso_MPIInfo_free( mpi_info ); |
|
Finley_ElementFile_allocTable(out->FaceElements,NFaceElements); |
|
|
if (! Finley_noError()) { |
|
|
Finley_Mesh_dealloc(out); |
|
|
return NULL; |
|
|
} |
|
|
|
|
|
/* set nodes: */ |
|
|
/* INTERNAL/BOUNDARY NODES */ |
|
|
k=0; |
|
|
#pragma omp parallel for private(i0,i1,i2,k) |
|
|
for (i2=0;i2<N2;i2++) { |
|
|
for (i1=0;i1<N1;i1++) { |
|
|
for (i0=0;i0<N0t;i0++,k++) { |
|
|
out->Nodes->Coordinates[INDEX2(0,k,3)]=DBLE((i0+firstNodeConstruct) % N0)/DBLE(N0-1)*Length[0]; |
|
|
out->Nodes->Coordinates[INDEX2(1,k,3)]=DBLE(i1)/DBLE(N1-1)*Length[1]; |
|
|
out->Nodes->Coordinates[INDEX2(2,k,3)]=DBLE(i2)/DBLE(N2-1)*Length[2]; |
|
|
out->Nodes->Id[k]=k; |
|
|
out->Nodes->Tag[k]=0; |
|
|
out->Nodes->degreeOfFreedom[k]=i0 + (i1%NDOF1)*N0t + (i2%NDOF2)*N0t*N1; |
|
|
out->Nodes->Dom[k]=NODE_INTERNAL; |
|
|
} |
|
|
} |
|
|
} |
|
| 445 |
|
|
| 446 |
/* mark the nodes that reference external and boundary DOF as such */ |
return out; |
|
if( boundaryLeft ){ |
|
|
for( i1=0; i1<N1; i1++ ) |
|
|
for( i2=0; i2<N2; i2++ ) { |
|
|
out->Nodes->Dom[N1*N0t*i2+N0t*i1] = NODE_EXTERNAL; |
|
|
out->Nodes->Dom[N1*N0t*i2+N0t*i1+1] = NODE_BOUNDARY; |
|
|
} |
|
|
} |
|
|
if( boundaryRight ){ |
|
|
for( i1=0; i1<N1; i1++ ) |
|
|
for( i2=0; i2<N2; i2++ ) { |
|
|
out->Nodes->Dom[N1*N0t*i2+N0t*(i1+1)-1] = NODE_EXTERNAL; |
|
|
out->Nodes->Dom[N1*N0t*i2+N0t*(i1+1)-2] = NODE_BOUNDARY; |
|
|
} |
|
|
} |
|
|
if( periodicLocal[0] ){ |
|
|
for( i1=0; i1<N1; i1++ ) |
|
|
for( i2=0; i2<N2; i2++ ) { |
|
|
out->Nodes->degreeOfFreedom[N1*N0t*i2+i1*N0t+3] = out->Nodes->degreeOfFreedom[N1*N0t*i2+i1*N0t+2]; |
|
|
out->Nodes->Dom[N1*N0t*i2+N0t*i1+3] = NODE_BOUNDARY; |
|
|
} |
|
|
} |
|
|
|
|
|
/* tag Nodes that are referenced by face elements */ |
|
|
if (!periodic[2]) { |
|
|
for (i1=0;i1<N1;i1++) { |
|
|
for (i0=0;i0<N0t;i0++) { |
|
|
out->Nodes->Tag[i0 + N0t*i1]+=100; |
|
|
out->Nodes->Tag[i0 + N0t*i1 + N0t*N1*(N2-1)]+=200; |
|
|
} |
|
|
} |
|
|
} |
|
|
if (!periodic[1]) { |
|
|
for (i2=0;i2<N2;i2++) { |
|
|
for (i0=0;i0<N0t;i0++) { |
|
|
out->Nodes->Tag[i0 + i2*N1*N0t]+=10; |
|
|
out->Nodes->Tag[i0 + (i2+1)*N1*N0t-N0t]+=20; |
|
|
} |
|
|
} |
|
|
} |
|
|
if (!periodic[0] && !domInternal ) { |
|
|
for (i2=0;i2<N2;i2++) { |
|
|
for (i1=0;i1<N1;i1++) { |
|
|
if( domLeft ) |
|
|
out->Nodes->Tag[i1*N0t + i2*N0t*N1]+=1; |
|
|
if( domRight ) |
|
|
out->Nodes->Tag[(i1+1)*N0t-1 + i2*N0t*N1]+=2; |
|
|
} |
|
|
} |
|
|
} |
|
|
|
|
|
/* form the boudary communication information */ |
|
|
forwardDOF = MEMALLOC(NDOF1*NDOF2,index_t); |
|
|
backwardDOF = MEMALLOC(NDOF1*NDOF2,index_t); |
|
|
if( !(mpi_info->size==2 && periodicLocal[0])){ |
|
|
if( boundaryLeft ) { |
|
|
targetDomain = mpi_info->rank-1 < 0 ? mpi_info->size-1 : mpi_info->rank-1; |
|
|
for( i2=0; i2<NDOF2; i2++ ){ |
|
|
for( i1=0; i1<NDOF1; i1++ ){ |
|
|
forwardDOF[i1+i2*NDOF1] = out->Nodes->degreeOfFreedom[i2*N0t*N1+i1*N0t+1]; |
|
|
backwardDOF[i1+i2*NDOF1] = out->Nodes->degreeOfFreedom[i2*N0t*N1+i1*N0t]; |
|
|
} |
|
|
} |
|
|
Finley_NodeDistribution_addForward( out->Nodes->degreeOfFreedomDistribution, targetDomain, NDOF1*NDOF2, forwardDOF ); |
|
|
Finley_NodeDistribution_addBackward( out->Nodes->degreeOfFreedomDistribution, targetDomain, NDOF1*NDOF2, backwardDOF ); |
|
|
} |
|
|
if( boundaryRight ) { |
|
|
targetDomain = mpi_info->rank+1 > mpi_info->size-1 ? 0 : mpi_info->rank+1; |
|
|
for( i2=0; i2<NDOF2; i2++ ){ |
|
|
for( i1=0; i1<NDOF1; i1++ ){ |
|
|
forwardDOF[i1+i2*NDOF1] = out->Nodes->degreeOfFreedom[i2*N0t*N1+(i1+1)*N0t-2]; |
|
|
backwardDOF[i1+i2*NDOF1] = out->Nodes->degreeOfFreedom[i2*N0t*N1+(i1+1)*N0t-1]; |
|
|
} |
|
|
} |
|
|
Finley_NodeDistribution_addForward( out->Nodes->degreeOfFreedomDistribution, targetDomain, NDOF1*NDOF2, forwardDOF ); |
|
|
Finley_NodeDistribution_addBackward( out->Nodes->degreeOfFreedomDistribution, targetDomain, NDOF1*NDOF2, backwardDOF ); |
|
|
} |
|
|
} else{ |
|
|
/* periodic boundary conditions with 2 domains, need to change the order in which domain 0 passes boundary data */ |
|
|
targetDomain = 1; |
|
|
|
|
|
for( i2=0; i2<NDOF2; i2++ ){ |
|
|
for( i1=0; i1<NDOF1; i1++ ){ |
|
|
forwardDOF[i1+i2*NDOF1] = out->Nodes->degreeOfFreedom[i2*N0t*N1+(i1+1)*N0t-2]; |
|
|
backwardDOF[i1+i2*NDOF1] = out->Nodes->degreeOfFreedom[i2*N0t*N1+(i1+1)*N0t-1]; |
|
|
} |
|
|
} |
|
|
Finley_NodeDistribution_addForward( out->Nodes->degreeOfFreedomDistribution, targetDomain, NDOF1*NDOF2, forwardDOF ); |
|
|
Finley_NodeDistribution_addBackward( out->Nodes->degreeOfFreedomDistribution, targetDomain, NDOF1*NDOF2, backwardDOF ); |
|
|
|
|
|
for( i2=0; i2<NDOF2; i2++ ){ |
|
|
for( i1=0; i1<NDOF1; i1++ ){ |
|
|
forwardDOF[i1+i2*NDOF1] = out->Nodes->degreeOfFreedom[i2*N0t*N1+i1*N0t+1]; |
|
|
backwardDOF[i1+i2*NDOF1] = out->Nodes->degreeOfFreedom[i2*N0t*N1+i1*N0t]; |
|
|
} |
|
|
} |
|
|
Finley_NodeDistribution_addForward( out->Nodes->degreeOfFreedomDistribution, targetDomain, NDOF1*NDOF2, forwardDOF ); |
|
|
Finley_NodeDistribution_addBackward( out->Nodes->degreeOfFreedomDistribution, targetDomain, NDOF1*NDOF2, backwardDOF ); |
|
|
} |
|
|
MEMFREE( forwardDOF ); |
|
|
MEMFREE( backwardDOF ); |
|
|
/* set the elements: */ |
|
|
|
|
|
/* INTERNAL elements */ |
|
|
k = 0; |
|
|
#pragma omp parallel for private(i0,i1,i2,k,node0) |
|
|
for (i2=0;i2<NE2;i2++) { |
|
|
for (i1=0;i1<NE1;i1++) { |
|
|
for (i0=0;i0<numElementsLocal;i0++,k++) { |
|
|
node0 = (periodicLocal[0] && !i0) ? i1*N0t + i2*N1*N0t : i1*N0t + i2*N1*N0t + i0 + periodicLocal[0]; |
|
|
|
|
|
out->Elements->Id[k]=((firstNodeConstruct+i0)%NE0)*NE1*NE2 + NE1*i2 + i1; |
|
|
out->Elements->Tag[k]=0; |
|
|
out->Elements->Color[k]=COLOR_MOD(i0)+3*COLOR_MOD(i1)+9*COLOR_MOD(i2);; |
|
|
out->Elements->Dom[k]=ELEMENT_INTERNAL; |
|
|
|
|
|
out->Elements->Nodes[INDEX2(0,k,8)]=node0; |
|
|
out->Elements->Nodes[INDEX2(1,k,8)]=node0+1; |
|
|
out->Elements->Nodes[INDEX2(2,k,8)]=node0+N0t+1; |
|
|
out->Elements->Nodes[INDEX2(3,k,8)]=node0+N0t; |
|
|
out->Elements->Nodes[INDEX2(4,k,8)]=node0+N0t*N1; |
|
|
out->Elements->Nodes[INDEX2(5,k,8)]=node0+N0t*N1+1; |
|
|
out->Elements->Nodes[INDEX2(6,k,8)]=node0+N0t*N1+N0t+1; |
|
|
out->Elements->Nodes[INDEX2(7,k,8)]=node0+N0t*N1+N0t; |
|
|
|
|
|
} |
|
|
} |
|
|
} |
|
|
out->Elements->minColor=0; |
|
|
out->Elements->maxColor=COLOR_MOD(0)+3*COLOR_MOD(0)+9*COLOR_MOD(0); |
|
|
if( boundaryLeft ) |
|
|
for( i2=0; i2<NE2; i2++ ) |
|
|
for( i1=0; i1<NE1; i1++ ) |
|
|
out->Elements->Dom[i2*NE1*numElementsLocal+i1*numElementsLocal]=ELEMENT_BOUNDARY; |
|
|
if( boundaryRight ) |
|
|
for( i2=0; i2<NE2; i2++ ) |
|
|
for( i1=0; i1<NE1; i1++ ) |
|
|
out->Elements->Dom[i2*NE1*numElementsLocal+(i1+1)*numElementsLocal-1]=ELEMENT_BOUNDARY; |
|
|
|
|
|
Finley_ElementFile_setDomainFlags( out->Elements ); |
|
|
|
|
|
/* face elements: */ |
|
|
if (useElementsOnFace) { |
|
|
NUMNODES=8; |
|
|
} else { |
|
|
NUMNODES=4; |
|
|
} |
|
|
totalNECount=out->Elements->numElements; |
|
|
faceNECount=0; |
|
|
idCount = totalNECount; |
|
|
|
|
|
/* these are the quadrilateral elements on boundary 1 (x3=0): */ |
|
|
numElementsInternal = numElementsLocal-nodesExternal[0]-nodesExternal[1]; |
|
|
if (!periodic[2]) { |
|
|
/* elements on boundary 100 (x3=0): */ |
|
|
|
|
|
#pragma omp parallel for private(i0,i1,k) |
|
|
for (i1=0;i1<NE1;i1++) { |
|
|
for (i0=0; i0<numElementsLocal; i0++) { |
|
|
k=i0+numElementsLocal*i1+faceNECount; |
|
|
kk=i0 + i1*numElementsLocal; |
|
|
facePerm = face2; |
|
|
|
|
|
out->FaceElements->Id[k]=idCount++; |
|
|
out->FaceElements->Tag[k]=100; |
|
|
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
|
|
out->FaceElements->Color[k]=(i0%2)+2*(i1%2); |
|
|
|
|
|
for( j=0; j<NUMNODES; j++ ) |
|
|
out->FaceElements->Nodes[INDEX2(j,k,NUMNODES)]=out->Elements->Nodes[INDEX2(facePerm[j],kk,8)]; |
|
|
} |
|
|
} |
|
|
if( boundaryLeft ){ |
|
|
for( i1=0; i1<NE1; i1++ ) |
|
|
out->FaceElements->Dom[faceNECount+i1*numElementsLocal]=ELEMENT_BOUNDARY; |
|
|
if( periodicLocal[0] ) |
|
|
for( i1=0; i1<NE1; i1++ ) |
|
|
out->FaceElements->Dom[faceNECount+i1*numElementsLocal+1]=ELEMENT_BOUNDARY; |
|
|
} |
|
|
if( boundaryRight ) |
|
|
for( i1=0; i1<NE1; i1++ ) |
|
|
out->FaceElements->Dom[faceNECount+(i1+1)*numElementsLocal-1]=ELEMENT_BOUNDARY; |
|
|
totalNECount+=NE1*numElementsLocal; |
|
|
faceNECount+=NE1*numElementsLocal; |
|
|
|
|
|
/* ** elements on boundary 200 (x3=1) */ |
|
|
|
|
|
#pragma omp parallel for private(i0,i1,k) |
|
|
for (i1=0;i1<NE1;i1++) { |
|
|
for (i0=0;i0<numElementsLocal;i0++) { |
|
|
k=i0+numElementsLocal*i1+faceNECount; |
|
|
kk=i0+i1*numElementsLocal+numElementsLocal*NE1*(NE2-1); |
|
|
facePerm = face3; |
|
|
|
|
|
out->FaceElements->Id[k]=idCount++; |
|
|
out->FaceElements->Tag[k]=200; |
|
|
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
|
|
out->FaceElements->Color[k]=(i0%2)+2*(i1%2)+4; |
|
|
|
|
|
for( j=0; j<NUMNODES; j++ ) |
|
|
out->FaceElements->Nodes[INDEX2(j,k,NUMNODES)]=out->Elements->Nodes[INDEX2(facePerm[j],kk,8)]; |
|
|
} |
|
|
} |
|
|
if( boundaryLeft ){ |
|
|
for( i1=0; i1<NE1; i1++ ) |
|
|
out->FaceElements->Dom[faceNECount+i1*numElementsLocal]=ELEMENT_BOUNDARY; |
|
|
if( periodicLocal[0] ) |
|
|
for( i1=0; i1<NE1; i1++ ) |
|
|
out->FaceElements->Dom[faceNECount+i1*numElementsLocal+1]=ELEMENT_BOUNDARY; |
|
|
} |
|
|
if( boundaryRight ) |
|
|
for( i1=0; i1<NE1; i1++ ) |
|
|
out->FaceElements->Dom[faceNECount+(i1+1)*numElementsLocal-1]=ELEMENT_BOUNDARY; |
|
|
totalNECount+=NE1*numElementsLocal; |
|
|
faceNECount+=NE1*numElementsLocal; |
|
|
} |
|
|
if (!periodic[0] && !domInternal) { |
|
|
/* ** elements on boundary 001 (x1=0): */ |
|
|
if( domLeft ){ |
|
|
#pragma omp parallel for private(i1,i2,k) |
|
|
for (i2=0;i2<NE2;i2++) { |
|
|
for (i1=0;i1<NE1;i1++) { |
|
|
k=i1+NE1*i2+faceNECount; |
|
|
kk=i1*numElementsLocal + i2*numElementsLocal*NE1; |
|
|
facePerm = face0; |
|
|
|
|
|
out->FaceElements->Id[k]=idCount++; |
|
|
out->FaceElements->Tag[k]=1; |
|
|
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
|
|
out->FaceElements->Color[k]=(i2%2)+2*(i1%2)+8; |
|
|
|
|
|
for( j=0; j<NUMNODES; j++ ) |
|
|
out->FaceElements->Nodes[INDEX2(j,k,NUMNODES)]=out->Elements->Nodes[INDEX2(facePerm[j],kk,8)]; |
|
|
} |
|
|
} |
|
|
totalNECount+=NE1*NE2; |
|
|
faceNECount+=NE1*NE2; |
|
|
} |
|
|
/* ** elements on boundary 002 (x1=1): */ |
|
|
if( domRight ) { |
|
|
#pragma omp parallel for private(i1,i2,k) |
|
|
for (i2=0;i2<NE2;i2++) { |
|
|
for (i1=0;i1<NE1;i1++) { |
|
|
k=i1+NE1*i2+faceNECount; |
|
|
kk=(i1+1)*numElementsLocal + i2*numElementsLocal*NE1 - 1; |
|
|
facePerm = face1; |
|
|
|
|
|
out->FaceElements->Id[k]=idCount++; |
|
|
out->FaceElements->Tag[k]=2; |
|
|
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
|
|
out->FaceElements->Color[k]=(i2%2)+2*(i1%2)+12; |
|
|
|
|
|
for( j=0; j<NUMNODES; j++ ) |
|
|
out->FaceElements->Nodes[INDEX2(j,k,NUMNODES)]=out->Elements->Nodes[INDEX2(facePerm[j],kk,8)]; |
|
|
} |
|
|
} |
|
|
totalNECount+=NE1*NE2; |
|
|
faceNECount+=NE1*NE2; |
|
|
} |
|
|
} |
|
|
if (!periodic[1]) { |
|
|
/* ** elements on boundary 010 (x2=0): */ |
|
|
|
|
|
#pragma omp parallel for private(i0,i2,k) |
|
|
for (i2=0;i2<NE2;i2++) { |
|
|
for (i0=0;i0<numElementsLocal;i0++) { |
|
|
k=i0+numElementsLocal*i2+faceNECount; |
|
|
kk=i0+numElementsLocal*NE1*i2; |
|
|
facePerm = face4; |
|
|
|
|
|
out->FaceElements->Id[k]=idCount++; |
|
|
out->FaceElements->Tag[k]=10; |
|
|
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
|
|
out->FaceElements->Color[k]=(i0%2)+2*(i2%2)+16; |
|
|
|
|
|
for( j=0; j<NUMNODES; j++ ) |
|
|
out->FaceElements->Nodes[INDEX2(j,k,NUMNODES)]=out->Elements->Nodes[INDEX2(facePerm[j],kk,8)]; |
|
|
} |
|
|
} |
|
|
if( boundaryLeft ){ |
|
|
for( i2=0; i2<NE2; i2++ ) |
|
|
out->FaceElements->Dom[faceNECount+i2*numElementsLocal]=ELEMENT_BOUNDARY; |
|
|
if( periodicLocal[0] ) |
|
|
for( i2=0; i2<NE2; i2++ ) |
|
|
out->FaceElements->Dom[faceNECount+i2*numElementsLocal+1]=ELEMENT_BOUNDARY; |
|
|
} |
|
|
if( boundaryRight ) |
|
|
for( i2=0; i2<NE2; i2++ ) |
|
|
out->FaceElements->Dom[faceNECount+(i2+1)*numElementsLocal-1]=ELEMENT_BOUNDARY; |
|
|
totalNECount+=numElementsLocal*NE2; |
|
|
faceNECount+=numElementsLocal*NE2; |
|
|
|
|
|
/* ** elements on boundary 020 (x2=1): */ |
|
|
|
|
|
#pragma omp parallel for private(i0,i2,k) |
|
|
for (i2=0;i2<NE2;i2++) { |
|
|
for (i0=0;i0<numElementsLocal;i0++) { |
|
|
k=i0+numElementsLocal*i2+faceNECount; |
|
|
kk=i0+numElementsLocal*NE1*(i2+1)-numElementsLocal; |
|
|
facePerm = face5; |
|
|
|
|
|
out->FaceElements->Tag[k]=20; |
|
|
out->FaceElements->Id[k]=idCount++; |
|
|
out->FaceElements->Dom[k]=ELEMENT_INTERNAL; |
|
|
out->FaceElements->Color[k]=(i0%2)+2*(i2%2)+20; |
|
|
|
|
|
for( j=0; j<NUMNODES; j++ ) |
|
|
out->FaceElements->Nodes[INDEX2(j,k,NUMNODES)]=out->Elements->Nodes[INDEX2(facePerm[j],kk,8)]; |
|
|
} |
|
|
} |
|
|
if( boundaryLeft ){ |
|
|
for( i2=0; i2<NE2; i2++ ) |
|
|
out->FaceElements->Dom[faceNECount+i2*numElementsLocal]=ELEMENT_BOUNDARY; |
|
|
if( periodicLocal[0] ) |
|
|
for( i2=0; i2<NE2; i2++ ) |
|
|
out->FaceElements->Dom[faceNECount+i2*numElementsLocal+1]=ELEMENT_BOUNDARY; |
|
|
} |
|
|
if( boundaryRight ) |
|
|
for( i2=0; i2<NE2; i2++ ) |
|
|
out->FaceElements->Dom[faceNECount+(i2+1)*numElementsLocal-1]=ELEMENT_BOUNDARY; |
|
|
totalNECount+=numElementsLocal*NE2; |
|
|
faceNECount+=numElementsLocal*NE2; |
|
|
} |
|
|
out->FaceElements->elementDistribution->numInternal = faceNECount; |
|
|
|
|
|
out->FaceElements->minColor=0; |
|
|
out->FaceElements->maxColor=23; |
|
|
out->FaceElements->numElements=faceNECount; |
|
|
|
|
|
Finley_ElementFile_setDomainFlags( out->FaceElements ); |
|
|
|
|
|
/* setup distribution info for other elements */ |
|
|
Finley_ElementFile_setDomainFlags( out->ContactElements ); |
|
|
Finley_ElementFile_setDomainFlags( out->Points ); |
|
|
|
|
|
/* reorder the degrees of freedom */ |
|
|
Finley_Mesh_resolveDegreeOfFreedomOrder( out, TRUE ); |
|
|
|
|
|
/* condense the nodes: */ |
|
|
Finley_Mesh_resolveNodeIds(out); |
|
|
if( !Finley_MPI_noError(mpi_info) ) |
|
|
{ |
|
|
Paso_MPIInfo_dealloc( mpi_info ); |
|
|
Finley_Mesh_dealloc(out); |
|
|
return NULL; |
|
|
} |
|
|
|
|
|
/* prepare mesh for further calculatuions:*/ |
|
|
Finley_Mesh_prepare(out); |
|
|
if( !Finley_MPI_noError(mpi_info) ) |
|
|
{ |
|
|
Paso_MPIInfo_dealloc( mpi_info ); |
|
|
Finley_Mesh_dealloc(out); |
|
|
return NULL; |
|
|
} |
|
|
|
|
|
/* free up memory */ |
|
|
Paso_MPIInfo_dealloc( mpi_info ); |
|
|
|
|
|
#ifdef Finley_TRACE |
|
|
printf("timing: mesh generation: %.4e sec\n",Finley_timer()-time0); |
|
|
#endif |
|
|
|
|
|
return out; |
|
| 447 |
} |
} |
|
#endif |
|
|
|
|
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| 
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