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#include "CoarsenIO.H"
using namespace amrex;
void
CoarsenIO::Loop ( MultiFab& mf_dst,
const MultiFab& mf_src,
const int dcomp,
const int scomp,
const int ncomp,
const IntVect ngrowvect,
const IntVect crse_ratio )
{
// Staggering of source fine MultiFab and destination coarse MultiFab
const IntVect stag_src = mf_src.boxArray().ixType().toIntVect();
const IntVect stag_dst = mf_dst.boxArray().ixType().toIntVect();
if ( crse_ratio > IntVect(1) ) AMREX_ALWAYS_ASSERT_WITH_MESSAGE( ngrowvect == IntVect(0),
"option of filling guard cells of destination MultiFab with coarsening not supported for this interpolation" );
AMREX_ALWAYS_ASSERT_WITH_MESSAGE( mf_src.nGrowVect() >= stag_dst-stag_src+ngrowvect,
"source fine MultiFab does not have enough guard cells for this interpolation" );
// Auxiliary integer arrays (always 3D)
GpuArray<int,3> sf; // staggering of source fine MultiFab
GpuArray<int,3> sc; // staggering of destination coarse MultiFab
GpuArray<int,3> cr; // coarsening ratio
sf[0] = stag_src[0];
sf[1] = stag_src[1];
#if (AMREX_SPACEDIM == 2)
sf[2] = 0;
#elif (AMREX_SPACEDIM == 3)
sf[2] = stag_src[2];
#endif
sc[0] = stag_dst[0];
sc[1] = stag_dst[1];
#if (AMREX_SPACEDIM == 2)
sc[2] = 0;
#elif (AMREX_SPACEDIM == 3)
sc[2] = stag_dst[2];
#endif
cr[0] = crse_ratio[0];
cr[1] = crse_ratio[1];
#if (AMREX_SPACEDIM == 2)
cr[2] = 1;
#elif (AMREX_SPACEDIM == 3)
cr[2] = crse_ratio[2];
#endif
#ifdef AMREX_USE_OMP
#pragma omp parallel if (Gpu::notInLaunchRegion())
#endif
// Loop over boxes (or tiles if not on GPU)
for (MFIter mfi( mf_dst, TilingIfNotGPU() ); mfi.isValid(); ++mfi)
{
// Tiles defined at the coarse level
const Box& bx = mfi.growntilebox( ngrowvect );
Array4<Real> const& arr_dst = mf_dst.array( mfi );
Array4<Real const> const& arr_src = mf_src.const_array( mfi );
ParallelFor( bx, ncomp,
[=] AMREX_GPU_DEVICE( int i, int j, int k, int n )
{
arr_dst(i,j,k,n+dcomp) = CoarsenIO::Interp(
arr_src, sf, sc, cr, i, j, k, n+scomp );
} );
}
}
void
CoarsenIO::Coarsen ( MultiFab& mf_dst,
const MultiFab& mf_src,
const int dcomp,
const int scomp,
const int ncomp,
const int ngrow,
const IntVect crse_ratio )
{
amrex::IntVect ngrowvect(ngrow);
Coarsen(mf_dst,
mf_src,
dcomp,
scomp,
ncomp,
ngrowvect,
crse_ratio);
}
void
CoarsenIO::Coarsen ( MultiFab& mf_dst,
const MultiFab& mf_src,
const int dcomp,
const int scomp,
const int ncomp,
const IntVect ngrowvect,
const IntVect crse_ratio )
{
BL_PROFILE("CoarsenIO::Coarsen()");
// Convert BoxArray of source MultiFab to staggering of destination MultiFab and coarsen it
BoxArray ba_tmp = amrex::convert( mf_src.boxArray(), mf_dst.ixType().toIntVect() );
AMREX_ALWAYS_ASSERT_WITH_MESSAGE( ba_tmp.coarsenable( crse_ratio ),
"source MultiFab converted to staggering of destination MultiFab is not coarsenable" );
ba_tmp.coarsen( crse_ratio );
if ( ba_tmp == mf_dst.boxArray() and mf_src.DistributionMap() == mf_dst.DistributionMap() )
CoarsenIO::Loop( mf_dst, mf_src, dcomp, scomp, ncomp, ngrowvect, crse_ratio );
else
{
// Cannot coarsen into MultiFab with different BoxArray or DistributionMapping:
// 1) create temporary MultiFab on coarsened version of source BoxArray with same DistributionMapping
MultiFab mf_tmp( ba_tmp, mf_src.DistributionMap(), ncomp, 0, MFInfo(), FArrayBoxFactory() );
// 2) interpolate from mf_src to mf_tmp (start writing into component 0)
CoarsenIO::Loop( mf_tmp, mf_src, 0, scomp, ncomp, ngrowvect, crse_ratio );
// 3) copy from mf_tmp to mf_dst (with different BoxArray or DistributionMapping)
mf_dst.copy( mf_tmp, 0, dcomp, ncomp );
}
}
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