4.7/tmop__pa__tc3_8cpp_source.html

// Copyright (c) 2010-2024, Lawrence Livermore National Security, LLC. Produced

// at the Lawrence Livermore National Laboratory. All Rights reserved. See files

// LICENSE and NOTICE for details. LLNL-CODE-806117.

//

// This file is part of the MFEM library. For more information and source code

// availability visit https://mfem.org.

//

// MFEM is free software; you can redistribute it and/or modify it under the

// terms of the BSD-3 license. We welcome feedback and contributions, see file

// CONTRIBUTING.md for details.


#include "../tmop.hpp"

#include "tmop_pa.hpp"

#include "../gridfunc.hpp"

#include "../../general/forall.hpp"

#include "../../linalg/kernels.hpp"


using namespace mfem;


namespace mfem

{


MFEM_REGISTER_TMOP_KERNELS(bool, TC_IDEAL_SHAPE_UNIT_SIZE_3D_KERNEL,

                           const int NE,

                           const DenseMatrix &w_,

                           DenseTensor &j_,

                           const int d1d,

                           const int q1d)

{

   constexpr int DIM = 3;


   const int Q1D = T_Q1D ? T_Q1D : q1d;


   const auto W = Reshape(w_.Read(), DIM,DIM);

   auto J = Reshape(j_.Write(), DIM,DIM, Q1D,Q1D,Q1D, NE);


   mfem::forall_3D(NE, Q1D, Q1D, Q1D, [=] MFEM_HOST_DEVICE (int e)

   {

      const int Q1D = T_Q1D ? T_Q1D : q1d;

      MFEM_FOREACH_THREAD(qy,y,Q1D)

      {

         MFEM_FOREACH_THREAD(qx,x,Q1D)

         {

            MFEM_FOREACH_THREAD(qz,z,Q1D)

            {

               kernels::Set(DIM,DIM, 1.0, &W(0,0), &J(0,0,qx,qy,qz,e));

            }

         }

      }

   });

   return true;

}


MFEM_REGISTER_TMOP_KERNELS(bool, TC_IDEAL_SHAPE_GIVEN_SIZE_3D_KERNEL,

                           const int NE,

                           const Array<real_t> &b_,

                           const Array<real_t> &g_,

                           const DenseMatrix &w_,

                           const Vector &x_,

                           DenseTensor &j_,

                           const int d1d,

                           const int q1d)

{

   constexpr int DIM = 3;


   const real_t detW = w_.Det();

   const int D1D = T_D1D ? T_D1D : d1d;

   const int Q1D = T_Q1D ? T_Q1D : q1d;


   const auto b = Reshape(b_.Read(), Q1D, D1D);

   const auto g = Reshape(g_.Read(), Q1D, D1D);

   const auto W = Reshape(w_.Read(), DIM,DIM);

   const auto X = Reshape(x_.Read(), D1D, D1D, D1D, DIM, NE);

   auto J = Reshape(j_.Write(), DIM,DIM, Q1D,Q1D,Q1D, NE);


   mfem::forall_3D(NE, Q1D, Q1D, Q1D, [=] MFEM_HOST_DEVICE (int e)

   {

      const int D1D = T_D1D ? T_D1D : d1d;

      const int Q1D = T_Q1D ? T_Q1D : q1d;


      constexpr int MQ1 = T_Q1D ? T_Q1D : T_MAX;

      constexpr int MD1 = T_D1D ? T_D1D : T_MAX;


      MFEM_SHARED real_t BG[2][MQ1*MD1];

      MFEM_SHARED real_t DDD[3][MD1*MD1*MD1];

      MFEM_SHARED real_t DDQ[6][MD1*MD1*MQ1];

      MFEM_SHARED real_t DQQ[9][MD1*MQ1*MQ1];

      MFEM_SHARED real_t QQQ[9][MQ1*MQ1*MQ1];


      kernels::internal::LoadX<MD1>(e,D1D,X,DDD);

      kernels::internal::LoadBG<MD1,MQ1>(D1D,Q1D,b,g,BG);


      kernels::internal::GradX<MD1,MQ1>(D1D,Q1D,BG,DDD,DDQ);

      kernels::internal::GradY<MD1,MQ1>(D1D,Q1D,BG,DDQ,DQQ);

      kernels::internal::GradZ<MD1,MQ1>(D1D,Q1D,BG,DQQ,QQQ);


      MFEM_FOREACH_THREAD(qz,z,Q1D)

      {

         MFEM_FOREACH_THREAD(qy,y,Q1D)

         {

            MFEM_FOREACH_THREAD(qx,x,Q1D)

            {

               real_t Jtr[9];

               const real_t *Wid = &W(0,0);

               kernels::internal::PullGrad<MQ1>(Q1D,qx,qy,qz,QQQ,Jtr);

               const real_t detJ = kernels::Det<3>(Jtr);

               const real_t alpha = std::pow(detJ/detW,1./3);

               kernels::Set(DIM,DIM,alpha,Wid,&J(0,0,qx,qy,qz,e));

            }

         }

      }

   });

   return true;

}


template<> bool

TargetConstructor::ComputeAllElementTargets<3>(const FiniteElementSpace &fes,

                                               const IntegrationRule &ir,

                                               const Vector &,

                                               DenseTensor &Jtr) const

{

   MFEM_ASSERT(target_type == IDEAL_SHAPE_UNIT_SIZE || nodes != nullptr, "");

   const Mesh *mesh = fes.GetMesh();

   const int NE = mesh->GetNE();

   // Quick return for empty processors:

   if (NE == 0) { return true; }

   const int dim = mesh->Dimension();

   MFEM_VERIFY(mesh->GetNumGeometries(dim) <= 1,

               "mixed meshes are not supported");

   MFEM_VERIFY(!fes.IsVariableOrder(), "variable orders are not supported");

   const FiniteElement &fe = *fes.GetFE(0);

   MFEM_VERIFY(fe.GetGeomType() == Geometry::CUBE, "");

   const DenseMatrix &W = Geometries.GetGeomToPerfGeomJac(Geometry::CUBE);

   const DofToQuad::Mode mode = DofToQuad::TENSOR;

   const DofToQuad &maps = fe.GetDofToQuad(ir, mode);

   const Array<real_t> &B = maps.B;

   const Array<real_t> &G = maps.G;

   const int D1D = maps.ndof;

   const int Q1D = maps.nqpt;

   const int id = (D1D << 4 ) | Q1D;


   switch (target_type)

   {

      case IDEAL_SHAPE_UNIT_SIZE: // Jtr(i) = Wideal;

      {

         MFEM_LAUNCH_TMOP_KERNEL(TC_IDEAL_SHAPE_UNIT_SIZE_3D_KERNEL,

                                 id,NE,W,Jtr);

      }

      case IDEAL_SHAPE_EQUAL_SIZE: return false;

      case IDEAL_SHAPE_GIVEN_SIZE:

      {

         MFEM_VERIFY(nodes, "");

         const ElementDofOrdering ordering = ElementDofOrdering::LEXICOGRAPHIC;

         const Operator *R = fes.GetElementRestriction(ordering);

         Vector X(R->Height(), Device::GetDeviceMemoryType());

         X.UseDevice(true);

         R->Mult(*nodes, X);

         MFEM_ASSERT(nodes->FESpace()->GetVDim() == 3, "");

         MFEM_LAUNCH_TMOP_KERNEL(TC_IDEAL_SHAPE_GIVEN_SIZE_3D_KERNEL,

                                 id,NE,B,G,W,X,Jtr);

      }

      case GIVEN_SHAPE_AND_SIZE: return false;

      default: return false;

   }

   return false;

}


} // namespace mfem

mfem::Array
Definition array.hpp:46

mfem::Array::Read
const T * Read(bool on_dev=true) const
Shortcut for mfem::Read(a.GetMemory(), a.Size(), on_dev).
Definition array.hpp:317

mfem::DenseMatrix
Data type dense matrix using column-major storage.
Definition densemat.hpp:24

mfem::DenseMatrix::Read
const real_t * Read(bool on_dev=true) const
Shortcut for mfem::Read( GetMemory(), TotalSize(), on_dev).
Definition densemat.hpp:466

mfem::DenseMatrix::Det
real_t Det() const
Definition densemat.cpp:535

mfem::DenseTensor
Rank 3 tensor (array of matrices)
Definition densemat.hpp:1104

mfem::DenseTensor::Write
real_t * Write(bool on_dev=true)
Shortcut for mfem::Write(GetMemory(), TotalSize(), on_dev).
Definition densemat.hpp:1245

mfem::Device::GetDeviceMemoryType
static MemoryType GetDeviceMemoryType()
Get the current Device MemoryType. This is the MemoryType used by most MFEM classes when allocating m...
Definition device.hpp:274

mfem::DofToQuad
Structure representing the matrices/tensors needed to evaluate (in reference space) the values,...
Definition fe_base.hpp:137

mfem::DofToQuad::G
Array< real_t > G
Gradients/divergences/curls of basis functions evaluated at quadrature points.
Definition fe_base.hpp:210

mfem::DofToQuad::Mode
Mode
Type of data stored in the arrays B, Bt, G, and Gt.
Definition fe_base.hpp:150

mfem::DofToQuad::TENSOR
@ TENSOR
Tensor product representation using 1D matrices/tensors with dimensions using 1D number of quadrature...
Definition fe_base.hpp:161

mfem::DofToQuad::B
Array< real_t > B
Basis functions evaluated at quadrature points.
Definition fe_base.hpp:189

mfem::DofToQuad::ndof
int ndof
Number of degrees of freedom = number of basis functions. When mode is TENSOR, this is the 1D number.
Definition fe_base.hpp:174

mfem::DofToQuad::nqpt
int nqpt
Number of quadrature points. When mode is TENSOR, this is the 1D number.
Definition fe_base.hpp:178

mfem::FiniteElementSpace
Class FiniteElementSpace - responsible for providing FEM view of the mesh, mainly managing the set of...
Definition fespace.hpp:220

mfem::FiniteElementSpace::IsVariableOrder
bool IsVariableOrder() const
Returns true if the space contains elements of varying polynomial orders.
Definition fespace.hpp:581

mfem::FiniteElementSpace::GetFE
virtual const FiniteElement * GetFE(int i) const
Returns pointer to the FiniteElement in the FiniteElementCollection associated with i'th element in t...
Definition fespace.cpp:3168

mfem::FiniteElementSpace::GetElementRestriction
const ElementRestrictionOperator * GetElementRestriction(ElementDofOrdering e_ordering) const
Return an Operator that converts L-vectors to E-vectors.
Definition fespace.cpp:1336

mfem::FiniteElementSpace::GetMesh
Mesh * GetMesh() const
Returns the mesh.
Definition fespace.hpp:559

mfem::FiniteElementSpace::GetVDim
int GetVDim() const
Returns vector dimension.
Definition fespace.hpp:706

mfem::FiniteElement
Abstract class for all finite elements.
Definition fe_base.hpp:239

mfem::FiniteElement::GetDofToQuad
virtual const DofToQuad & GetDofToQuad(const IntegrationRule &ir, DofToQuad::Mode mode) const
Return a DofToQuad structure corresponding to the given IntegrationRule using the given DofToQuad::Mo...
Definition fe_base.cpp:365

mfem::FiniteElement::GetGeomType
Geometry::Type GetGeomType() const
Returns the Geometry::Type of the reference element.
Definition fe_base.hpp:326

mfem::Geometry::CUBE
@ CUBE
Definition geom.hpp:38

mfem::Geometry::GetGeomToPerfGeomJac
const DenseMatrix & GetGeomToPerfGeomJac(int GeomType) const
Definition geom.hpp:98

mfem::GridFunction::FESpace
FiniteElementSpace * FESpace()
Definition gridfunc.hpp:696

mfem::IntegrationRule
Class for an integration rule - an Array of IntegrationPoint.
Definition intrules.hpp:100

mfem::Mesh
Mesh data type.
Definition mesh.hpp:56

mfem::Mesh::GetNE
int GetNE() const
Returns number of elements.
Definition mesh.hpp:1226

mfem::Mesh::Dimension
int Dimension() const
Dimension of the reference space used within the elements.
Definition mesh.hpp:1160

mfem::Mesh::GetNumGeometries
int GetNumGeometries(int dim) const
Return the number of geometries of the given dimension present in the mesh.
Definition mesh.cpp:6961

mfem::Operator
Abstract operator.
Definition operator.hpp:25

mfem::Operator::Height
int Height() const
Get the height (size of output) of the Operator. Synonym with NumRows().
Definition operator.hpp:66

mfem::Operator::Mult
virtual void Mult(const Vector &x, Vector &y) const =0
Operator application: y=A(x).

mfem::TargetConstructor::target_type
const TargetType target_type
Definition tmop.hpp:1360

mfem::TargetConstructor::nodes
const GridFunction * nodes
Definition tmop.hpp:1357

mfem::TargetConstructor::IDEAL_SHAPE_UNIT_SIZE
@ IDEAL_SHAPE_UNIT_SIZE
Definition tmop.hpp:1339

mfem::TargetConstructor::IDEAL_SHAPE_EQUAL_SIZE
@ IDEAL_SHAPE_EQUAL_SIZE
Definition tmop.hpp:1341

mfem::TargetConstructor::IDEAL_SHAPE_GIVEN_SIZE
@ IDEAL_SHAPE_GIVEN_SIZE
Definition tmop.hpp:1345

mfem::TargetConstructor::GIVEN_SHAPE_AND_SIZE
@ GIVEN_SHAPE_AND_SIZE
Definition tmop.hpp:1348

mfem::TargetConstructor::ComputeAllElementTargets
bool ComputeAllElementTargets(const FiniteElementSpace &fes, const IntegrationRule &ir, const Vector &xe, DenseTensor &Jtr) const

mfem::Vector
Vector data type.
Definition vector.hpp:80

mfem::Vector::Read
virtual const real_t * Read(bool on_dev=true) const
Shortcut for mfem::Read(vec.GetMemory(), vec.Size(), on_dev).
Definition vector.hpp:474

mfem::Vector::UseDevice
virtual void UseDevice(bool use_dev) const
Enable execution of Vector operations using the mfem::Device.
Definition vector.hpp:136

alpha
const real_t alpha
Definition ex15.cpp:369

dim
int dim
Definition ex24.cpp:53

forall.hpp

gridfunc.hpp

kernels.hpp

b
real_t b
Definition lissajous.cpp:42

DIM
constexpr int DIM
Definition minimal-surface.cpp:72

mfem::kernels::Set
MFEM_HOST_DEVICE void Set(const int height, const int width, const real_t alpha, const TA *Adata, TB *Bdata)
Compute B = alpha*A, where the matrices A and B are of size height x width with data Adata and Bdata.
Definition kernels.hpp:326

mfem::kernels::Det
MFEM_HOST_DEVICE T Det(const T *data)
Compute the determinant of a square matrix of size dim with given data.
Definition kernels.hpp:237

mfem
Definition CodeDocumentation.dox:1

mfem::MFEM_REGISTER_TMOP_KERNELS
MFEM_REGISTER_TMOP_KERNELS(void, DatcSize, const int NE, const int ncomp, const int sizeidx, const real_t input_min_size, const DenseMatrix &w_, const Array< real_t > &b_, const Vector &x_, const Vector &nc_reduce, DenseTensor &j_, const int d1d, const int q1d)
Definition tmop_pa_da3.cpp:20

mfem::Geometries
Geometry Geometries
Definition fe.cpp:49

mfem::Reshape
MFEM_HOST_DEVICE DeviceTensor< sizeof...(Dims), T > Reshape(T *ptr, Dims... dims)
Wrap a pointer as a DeviceTensor with automatically deduced template parameters.
Definition dtensor.hpp:131

mfem::forall_3D
void forall_3D(int N, int X, int Y, int Z, lambda &&body)
Definition forall.hpp:775

mfem::real_t
float real_t
Definition config.hpp:43

mfem::ElementDofOrdering
ElementDofOrdering
Constants describing the possible orderings of the DOFs in one element.
Definition fespace.hpp:75

mfem::ElementDofOrdering::LEXICOGRAPHIC
@ LEXICOGRAPHIC
Lexicographic ordering for tensor-product FiniteElements.

tmop.hpp

tmop_pa.hpp