Added a bunch of tests from ScaLBL
This commit is contained in:
557
tests/TestColorMassBounceback.cpp
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557
tests/TestColorMassBounceback.cpp
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//*************************************************************************
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// Lattice Boltzmann Simulator for Single Phase Flow in Porous Media
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// James E. McCLure
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//*************************************************************************
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#include <stdio.h>
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#include <iostream>
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#include <fstream>
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#include "common/ScaLBL.h"
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#include "common/MPI_Helpers.h"
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using namespace std;
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//***************************************************************************************
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int main(int argc, char **argv)
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{
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//*****************************************
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// ***** MPI STUFF ****************
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//*****************************************
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// Initialize MPI
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int rank,nprocs;
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MPI_Init(&argc,&argv);
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MPI_Comm comm = MPI_COMM_WORLD;
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MPI_Comm_rank(comm,&rank);
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MPI_Comm_size(comm,&nprocs);
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int check;
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{
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// parallel domain size (# of sub-domains)
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int nprocx,nprocy,nprocz;
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int iproc,jproc,kproc;
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if (rank == 0){
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printf("********************************************************\n");
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printf("Running Color Model: TestColor \n");
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printf("********************************************************\n");
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}
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// BGK Model parameters
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string FILENAME;
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unsigned int nBlocks, nthreads;
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int timestepMax, interval;
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double Fx,Fy,Fz,tol;
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// Domain variables
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double Lx,Ly,Lz;
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int nspheres;
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int Nx,Ny,Nz;
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int i,j,k,n;
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int dim = 3;
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//if (rank == 0) printf("dim=%d\n",dim);
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int timestep = 0;
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int timesteps = 100;
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int centralNode = 2;
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double tauA = 1.0;
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double tauB = 1.0;
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double rhoA = 1.0;
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double rhoB = 1.0;
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double alpha = 0.005;
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double beta = 0.95;
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double tau = 1.0;
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double mu=(tau-0.5)/3.0;
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double rlx_setA=1.0/tau;
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double rlx_setB = 8.f*(2.f-rlx_setA)/(8.f-rlx_setA);
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Fx = Fy = 0.f;
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Fz = 0.f;
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if (rank==0){
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//.......................................................................
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// Reading the domain information file
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//.......................................................................
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ifstream domain("Domain.in");
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if (domain.good()){
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domain >> nprocx;
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domain >> nprocy;
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domain >> nprocz;
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domain >> Nx;
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domain >> Ny;
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domain >> Nz;
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domain >> nspheres;
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domain >> Lx;
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domain >> Ly;
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domain >> Lz;
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}
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else if (nprocs==1){
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nprocx=nprocy=nprocz=1;
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Nx=Ny=Nz=3;
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nspheres=0;
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Lx=Ly=Lz=1;
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}
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else if (nprocs==2){
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nprocx=2; nprocy=1;
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nprocz=1;
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Nx=Ny=Nz=dim;
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Nx = dim; Ny = dim; Nz = dim;
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nspheres=0;
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Lx=Ly=Lz=1;
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}
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else if (nprocs==4){
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nprocx=nprocy=2;
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nprocz=1;
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Nx=Ny=Nz=dim;
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nspheres=0;
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Lx=Ly=Lz=1;
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}
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else if (nprocs==8){
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nprocx=nprocy=nprocz=2;
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Nx=Ny=Nz=dim;
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nspheres=0;
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Lx=Ly=Lz=1;
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}
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//.......................................................................
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}
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// **************************************************************
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// Broadcast simulation parameters from rank 0 to all other procs
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MPI_Barrier(comm);
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//.................................................
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MPI_Bcast(&Nx,1,MPI_INT,0,comm);
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MPI_Bcast(&Ny,1,MPI_INT,0,comm);
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MPI_Bcast(&Nz,1,MPI_INT,0,comm);
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MPI_Bcast(&nprocx,1,MPI_INT,0,comm);
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MPI_Bcast(&nprocy,1,MPI_INT,0,comm);
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MPI_Bcast(&nprocz,1,MPI_INT,0,comm);
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MPI_Bcast(&nspheres,1,MPI_INT,0,comm);
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MPI_Bcast(&Lx,1,MPI_DOUBLE,0,comm);
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MPI_Bcast(&Ly,1,MPI_DOUBLE,0,comm);
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MPI_Bcast(&Lz,1,MPI_DOUBLE,0,comm);
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//.................................................
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MPI_Barrier(comm);
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// **************************************************************
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// **************************************************************
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if (nprocs != nprocx*nprocy*nprocz){
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printf("nprocx = %i \n",nprocx);
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printf("nprocy = %i \n",nprocy);
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printf("nprocz = %i \n",nprocz);
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INSIST(nprocs == nprocx*nprocy*nprocz,"Fatal error in processor count!");
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}
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if (rank==0){
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printf("********************************************************\n");
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printf("Sub-domain size = %i x %i x %i\n",Nx,Ny,Nz);
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printf("********************************************************\n");
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}
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MPI_Barrier(comm);
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double iVol_global = 1.0/Nx/Ny/Nz/nprocx/nprocy/nprocz;
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int BoundaryCondition=0;
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Domain Dm(Nx,Ny,Nz,rank,nprocx,nprocy,nprocz,Lx,Ly,Lz,BoundaryCondition);
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Nx += 2;
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Ny += 2;
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Nz += 2;
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int N = Nx*Ny*Nz;
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int Np=0; // number of local pore nodes
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double *PhaseLabel;
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PhaseLabel = new double[N];
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//.......................................................................
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for (k=0;k<Nz;k++){
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for (j=0;j<Ny;j++){
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for (i=0;i<Nx;i++){
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n = k*Nx*Ny+j*Nx+i;
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Dm.id[n]=0;
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}
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}
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}
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for (k=1;k<Nz-1;k++){
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for (j=1;j<Ny-1;j++){
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for (i=1;i<Nx-1;i++){
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n = k*Nx*Ny+j*Nx+i;
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Dm.id[n]=1;
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Np++;
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// constant color
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PhaseLabel[n]= -1.0;
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}
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}
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}
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Dm.CommInit(comm);
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MPI_Barrier(comm);
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if (rank == 0) cout << "Domain set." << endl;
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if (rank==0) printf ("Create ScaLBL_Communicator \n");
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//Create a second communicator based on the regular data layout
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ScaLBL_Communicator ScaLBL_Comm_Regular(Dm);
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ScaLBL_Communicator ScaLBL_Comm(Dm);
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// LBM variables
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if (rank==0) printf ("Set up the neighborlist \n");
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int neighborSize=18*Np*sizeof(int);
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int *neighborList;
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IntArray Map(Nx,Ny,Nz);
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neighborList= new int[18*Np];
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ScaLBL_Comm.MemoryOptimizedLayoutAA(Map,neighborList,Dm.id,Np);
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MPI_Barrier(comm);
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//......................device distributions.................................
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int dist_mem_size = Np*sizeof(double);
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if (rank==0) printf ("Allocating distributions \n");
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int *NeighborList;
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int *dvcMap;
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// double *f_even,*f_odd;
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double *fq, *Aq, *Bq;
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double *Den, *Phi;
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double *ColorGrad;
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double *Vel;
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double *Pressure;
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//...........................................................................
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ScaLBL_AllocateDeviceMemory((void **) &NeighborList, neighborSize);
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ScaLBL_AllocateDeviceMemory((void **) &dvcMap, sizeof(int)*Np);
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ScaLBL_AllocateDeviceMemory((void **) &fq, 19*dist_mem_size);
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ScaLBL_AllocateDeviceMemory((void **) &Aq, 7*dist_mem_size);
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ScaLBL_AllocateDeviceMemory((void **) &Bq, 7*dist_mem_size);
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ScaLBL_AllocateDeviceMemory((void **) &Den, 2*dist_mem_size);
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ScaLBL_AllocateDeviceMemory((void **) &Phi, sizeof(double)*Nx*Ny*Nz);
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ScaLBL_AllocateDeviceMemory((void **) &Pressure, sizeof(double)*Np);
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ScaLBL_AllocateDeviceMemory((void **) &Vel, 3*sizeof(double)*Np);
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ScaLBL_AllocateDeviceMemory((void **) &ColorGrad, 3*sizeof(double)*Np);
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//...........................................................................
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// Update GPU data structures
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if (rank==0) printf ("Setting up device map and neighbor list \n");
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int *TmpMap;
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TmpMap=new int[Np*sizeof(int)];
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for (k=1; k<Nz-1; k++){
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for (j=1; j<Ny-1; j++){
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for (i=1; i<Nx-1; i++){
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int idx=Map(i,j,k);
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if (!(idx < 0))
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TmpMap[idx] = k*Nx*Ny+j*Nx+i;
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}
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}
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}
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ScaLBL_CopyToDevice(dvcMap, TmpMap, sizeof(int)*Np);
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ScaLBL_DeviceBarrier();
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delete [] TmpMap;
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// copy the neighbor list
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ScaLBL_CopyToDevice(NeighborList, neighborList, neighborSize);
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//...........................................................................
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// Distributions / densities for checking
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double nA,nB;
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double *DIST;
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DIST= new double [7*Np];
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double *DENSITY;
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DENSITY= new double [2*Np];
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int SIZE;
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int errc_odd_a=0;
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int errc_even_a=0;
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int errc_odd_b=0;
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int errc_even_b=0;
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//*******************Component A*******************
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// initialize phi based on PhaseLabel (include solid component labels)
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for (k=1;k<Nz-1;k++){
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for (j=1;j<Ny-1;j++){
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for (i=1;i<Nx-1;i++){
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n = k*Nx*Ny+j*Nx+i;
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// constant color
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PhaseLabel[n]= 1.0;
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}
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}
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}
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ScaLBL_CopyToDevice(Phi, PhaseLabel, N*sizeof(double));
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if (rank==0) printf ("Initializing distributions \n");
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// Initialize the phase field and variables
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ScaLBL_D3Q19_Init(fq, Np);
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if (rank==0) printf ("Initializing phase field \n");
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ScaLBL_PhaseField_Init(dvcMap, Phi, Den, Aq, Bq, Np);
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// *************ODD TIMESTEP*************
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// Compute the Phase indicator field
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// Read for Aq, Bq happens in this routine (requires communication)
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ScaLBL_Comm.BiSendD3Q7AA(Aq,Bq); //READ FROM NORMAL
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ScaLBL_D3Q7_AAodd_PhaseField(NeighborList, dvcMap, Aq, Bq, Den, Phi, ScaLBL_Comm.next, Np, Np);
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ScaLBL_Comm.BiRecvD3Q7AA(Aq,Bq); //WRITE INTO OPPOSITE
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ScaLBL_D3Q7_AAodd_PhaseField(NeighborList, dvcMap, Aq, Bq, Den, Phi, 0, ScaLBL_Comm.next, Np);
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// Halo exchange for phase field
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ScaLBL_Comm_Regular.SendHalo(Phi);
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ScaLBL_Comm_Regular.RecvHalo(Phi);
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// Perform the collision operation
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ScaLBL_Comm.SendD3Q19AA(fq); //READ FROM NORMAL
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ScaLBL_D3Q19_AAodd_Color(NeighborList, dvcMap, fq, Aq, Bq, Den, Phi, Vel, rhoA, rhoB, tauA, tauB,
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alpha, beta, Fx, Fy, Fz, Nx, Nx*Ny, ScaLBL_Comm.next, Np, Np);
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ScaLBL_Comm.RecvD3Q19AA(fq); //WRITE INTO OPPOSITE
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ScaLBL_D3Q19_AAodd_Color(NeighborList, dvcMap, fq, Aq, Bq, Den, Phi, Vel, rhoA, rhoB, tauA, tauB,
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alpha, beta, Fx, Fy, Fz, Nx, Nx*Ny, 0, ScaLBL_Comm.next, Np);
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ScaLBL_DeviceBarrier(); MPI_Barrier(comm);
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timestep++;
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printf("Check after odd time \n");
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SIZE=2*Np*sizeof(double);
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ScaLBL_CopyToHost(&DENSITY[0],&Den[0],SIZE);
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// Check the distributions
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SIZE=7*Np*sizeof(double);
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ScaLBL_CopyToHost(&DIST[0],&Aq[0],SIZE);
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for (k=1;k<Nz-1;k++){
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for (j=1;j<Ny-1;j++){
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for (i=1;i<Nx-1;i++){
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n = k*Nx*Ny+j*Nx+i;
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if (Dm.id[n] > 0){
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int idx = Map(i,j,k);
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nA=DENSITY[idx];
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nB=DENSITY[Np+idx];
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//printf("i,j,k=%i,%i,%i \n",i,j,k);
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//printf(" nA=%f, nB=%f \n",nA,nB);
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double val=DIST[idx];
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double error = fabs(val - 0.3333333333333333*nA);
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if (error > 1.0e-12) {
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printf(" q=0, Aq=%f \n",val);
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errc_odd_b++;
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}
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for (int q=1; q<7; q++){
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val=DIST[q*Np+idx];
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error = fabs(val - 0.1111111111111111*nA);
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if (error > 1.0e-12) {
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printf(" q=%i, Aq=%f \n",q,val);
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errc_odd_b++;
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}
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}
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}
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}
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}
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}
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// *************EVEN TIMESTEP*************
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// Compute the Phase indicator field
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ScaLBL_Comm.BiSendD3Q7AA(Aq,Bq); //READ FROM NORMAL
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ScaLBL_D3Q7_AAeven_PhaseField(dvcMap, Aq, Bq, Den, Phi, ScaLBL_Comm.next, Np, Np);
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ScaLBL_Comm.BiRecvD3Q7AA(Aq,Bq); //WRITE INTO OPPOSITE
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ScaLBL_D3Q7_AAeven_PhaseField(dvcMap, Aq, Bq, Den, Phi, 0, ScaLBL_Comm.next, Np);
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// Halo exchange for phase field
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ScaLBL_Comm_Regular.SendHalo(Phi);
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ScaLBL_Comm_Regular.RecvHalo(Phi);
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// Perform the collision operation
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ScaLBL_Comm.SendD3Q19AA(fq); //READ FORM NORMAL
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ScaLBL_D3Q19_AAeven_Color(dvcMap, fq, Aq, Bq, Den, Phi, Vel, rhoA, rhoB, tauA, tauB,
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alpha, beta, Fx, Fy, Fz, Nx, Nx*Ny, ScaLBL_Comm.next, Np, Np);
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ScaLBL_Comm.RecvD3Q19AA(fq); //WRITE INTO OPPOSITE
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ScaLBL_D3Q19_AAeven_Color(dvcMap, fq, Aq, Bq, Den, Phi, Vel, rhoA, rhoB, tauA, tauB,
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alpha, beta, Fx, Fy, Fz, Nx, Nx*Ny, 0, ScaLBL_Comm.next, Np);
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ScaLBL_DeviceBarrier(); MPI_Barrier(comm);
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timestep++;
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printf("Check after even time \n");
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SIZE=2*Np*sizeof(double);
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ScaLBL_CopyToHost(&DENSITY[0],&Den[0],SIZE);
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// Check the distributions
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SIZE=7*Np*sizeof(double);
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ScaLBL_CopyToHost(&DIST[0],&Aq[0],SIZE);
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for (k=1;k<Nz-1;k++){
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for (j=1;j<Ny-1;j++){
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for (i=1;i<Nx-1;i++){
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n = k*Nx*Ny+j*Nx+i;
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if (Dm.id[n] > 0){
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int idx = Map(i,j,k);
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nA=DENSITY[idx];
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nB=DENSITY[Np+idx];
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//printf("i,j,k=%i,%i,%i \n",i,j,k);
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//printf(" nA=%f, nB=%f \n",nA,nB);
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double val=DIST[idx];
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double error = fabs(val - 0.3333333333333333*nA);
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if (error > 1.0e-12) {
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printf(" q=0, Aq=%f \n",val);
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errc_even_b++;
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}
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for (int q=1; q<7; q++){
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val=DIST[q*Np+idx];
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error = fabs(val - 0.1111111111111111*nA);
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if (error > 1.0e-12) {
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printf(" q=%i, Aq=%f \n",q,val);
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errc_even_b++;
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}
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}
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}
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}
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}
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}
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//*******************Component B*******************
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// initialize phi based on PhaseLabel (include solid component labels)
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for (k=1;k<Nz-1;k++){
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for (j=1;j<Ny-1;j++){
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for (i=1;i<Nx-1;i++){
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n = k*Nx*Ny+j*Nx+i;
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// constant color
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PhaseLabel[n]= -1.0;
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}
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}
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}
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ScaLBL_CopyToDevice(Phi, PhaseLabel, N*sizeof(double));
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if (rank==0) printf ("Initializing distributions \n");
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// Initialize the phase field and variables
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ScaLBL_D3Q19_Init(fq, Np);
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if (rank==0) printf ("Initializing phase field \n");
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ScaLBL_PhaseField_Init(dvcMap, Phi, Den, Aq, Bq, Np);
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// *************ODD TIMESTEP*************
|
||||
// Compute the Phase indicator field
|
||||
// Read for Aq, Bq happens in this routine (requires communication)
|
||||
ScaLBL_Comm.BiSendD3Q7AA(Aq,Bq); //READ FROM NORMAL
|
||||
ScaLBL_D3Q7_AAodd_PhaseField(NeighborList, dvcMap, Aq, Bq, Den, Phi, ScaLBL_Comm.next, Np, Np);
|
||||
ScaLBL_Comm.BiRecvD3Q7AA(Aq,Bq); //WRITE INTO OPPOSITE
|
||||
ScaLBL_D3Q7_AAodd_PhaseField(NeighborList, dvcMap, Aq, Bq, Den, Phi, 0, ScaLBL_Comm.next, Np);
|
||||
|
||||
// Halo exchange for phase field
|
||||
ScaLBL_Comm_Regular.SendHalo(Phi);
|
||||
ScaLBL_Comm_Regular.RecvHalo(Phi);
|
||||
|
||||
// Perform the collision operation
|
||||
ScaLBL_Comm.SendD3Q19AA(fq); //READ FROM NORMAL
|
||||
ScaLBL_D3Q19_AAodd_Color(NeighborList, dvcMap, fq, Aq, Bq, Den, Phi, Vel, rhoA, rhoB, tauA, tauB,
|
||||
alpha, beta, Fx, Fy, Fz, Nx, Nx*Ny, ScaLBL_Comm.next, Np, Np);
|
||||
ScaLBL_Comm.RecvD3Q19AA(fq); //WRITE INTO OPPOSITE
|
||||
|
||||
ScaLBL_D3Q19_AAodd_Color(NeighborList, dvcMap, fq, Aq, Bq, Den, Phi, Vel, rhoA, rhoB, tauA, tauB,
|
||||
alpha, beta, Fx, Fy, Fz, Nx, Nx*Ny, 0, ScaLBL_Comm.next, Np);
|
||||
ScaLBL_DeviceBarrier(); MPI_Barrier(comm);
|
||||
timestep++;
|
||||
|
||||
|
||||
printf("Check after odd time \n");
|
||||
SIZE=2*Np*sizeof(double);
|
||||
ScaLBL_CopyToHost(&DENSITY[0],&Den[0],SIZE);
|
||||
|
||||
// Check the distributions
|
||||
SIZE=7*Np*sizeof(double);
|
||||
ScaLBL_CopyToHost(&DIST[0],&Bq[0],SIZE);
|
||||
|
||||
for (k=1;k<Nz-1;k++){
|
||||
for (j=1;j<Ny-1;j++){
|
||||
for (i=1;i<Nx-1;i++){
|
||||
n = k*Nx*Ny+j*Nx+i;
|
||||
if (Dm.id[n] > 0){
|
||||
int idx = Map(i,j,k);
|
||||
nA=DENSITY[idx];
|
||||
nB=DENSITY[Np+idx];
|
||||
//printf("i,j,k=%i,%i,%i \n",i,j,k);
|
||||
//printf(" nA=%f, nB=%f \n",nA,nB);
|
||||
double val=DIST[idx];
|
||||
double error = fabs(val - 0.3333333333333333*nB);
|
||||
if (error > 1.0e-12) {
|
||||
printf(" q=0, Bq=%f \n",val);
|
||||
errc_odd_b++;
|
||||
}
|
||||
for (int q=1; q<7; q++){
|
||||
val=DIST[q*Np+idx];
|
||||
error = fabs(val - 0.1111111111111111*nB);
|
||||
if (error > 1.0e-12) {
|
||||
printf(" q=%i, Bq=%f \n",q,val);
|
||||
errc_odd_b++;
|
||||
}
|
||||
}
|
||||
}
|
||||
}
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
// *************EVEN TIMESTEP*************
|
||||
// Compute the Phase indicator field
|
||||
ScaLBL_Comm.BiSendD3Q7AA(Aq,Bq); //READ FROM NORMAL
|
||||
ScaLBL_D3Q7_AAeven_PhaseField(dvcMap, Aq, Bq, Den, Phi, ScaLBL_Comm.next, Np, Np);
|
||||
ScaLBL_Comm.BiRecvD3Q7AA(Aq,Bq); //WRITE INTO OPPOSITE
|
||||
ScaLBL_D3Q7_AAeven_PhaseField(dvcMap, Aq, Bq, Den, Phi, 0, ScaLBL_Comm.next, Np);
|
||||
|
||||
// Halo exchange for phase field
|
||||
ScaLBL_Comm_Regular.SendHalo(Phi);
|
||||
ScaLBL_Comm_Regular.RecvHalo(Phi);
|
||||
|
||||
// Perform the collision operation
|
||||
ScaLBL_Comm.SendD3Q19AA(fq); //READ FORM NORMAL
|
||||
ScaLBL_D3Q19_AAeven_Color(dvcMap, fq, Aq, Bq, Den, Phi, Vel, rhoA, rhoB, tauA, tauB,
|
||||
alpha, beta, Fx, Fy, Fz, Nx, Nx*Ny, ScaLBL_Comm.next, Np, Np);
|
||||
ScaLBL_Comm.RecvD3Q19AA(fq); //WRITE INTO OPPOSITE
|
||||
|
||||
ScaLBL_D3Q19_AAeven_Color(dvcMap, fq, Aq, Bq, Den, Phi, Vel, rhoA, rhoB, tauA, tauB,
|
||||
alpha, beta, Fx, Fy, Fz, Nx, Nx*Ny, 0, ScaLBL_Comm.next, Np);
|
||||
ScaLBL_DeviceBarrier(); MPI_Barrier(comm);
|
||||
timestep++;
|
||||
printf("Check after even time \n");
|
||||
|
||||
SIZE=2*Np*sizeof(double);
|
||||
ScaLBL_CopyToHost(&DENSITY[0],&Den[0],SIZE);
|
||||
|
||||
// Check the distributions
|
||||
SIZE=7*Np*sizeof(double);
|
||||
ScaLBL_CopyToHost(&DIST[0],&Bq[0],SIZE);
|
||||
|
||||
for (k=1;k<Nz-1;k++){
|
||||
for (j=1;j<Ny-1;j++){
|
||||
for (i=1;i<Nx-1;i++){
|
||||
n = k*Nx*Ny+j*Nx+i;
|
||||
if (Dm.id[n] > 0){
|
||||
int idx = Map(i,j,k);
|
||||
nA=DENSITY[idx];
|
||||
nB=DENSITY[Np+idx];
|
||||
//printf("i,j,k=%i,%i,%i \n",i,j,k);
|
||||
//printf(" nA=%f, nB=%f \n",nA,nB);
|
||||
double val=DIST[idx];
|
||||
double error = fabs(val - 0.3333333333333333*nB);
|
||||
if (error > 1.0e-12) {
|
||||
printf(" q=0, Bq=%f \n",val);
|
||||
errc_even_b++;
|
||||
}
|
||||
for (int q=1; q<7; q++){
|
||||
val=DIST[q*Np+idx];
|
||||
error = fabs(val - 0.1111111111111111*nB);
|
||||
if (error > 1.0e-12) {
|
||||
printf(" q=%i, Bq=%f \n",q,val);
|
||||
errc_even_b++;
|
||||
}
|
||||
}
|
||||
}
|
||||
}
|
||||
}
|
||||
}
|
||||
printf("Error counts: A even=%i, A odd=%i, B even=%i, B odd=%i \n",errc_even_a,errc_odd_a,errc_even_b,errc_odd_b);
|
||||
int errc_total=errc_even_a+errc_odd_a+errc_even_b+errc_odd_b;
|
||||
if (errc_total>0) check=1;
|
||||
else check=0;
|
||||
|
||||
}
|
||||
// ****************************************************
|
||||
MPI_Barrier(comm);
|
||||
MPI_Finalize();
|
||||
// ****************************************************
|
||||
|
||||
return check;
|
||||
}
|
||||
|
||||
Reference in New Issue
Block a user