DGtal: testPolygonalCalculus.cpp File Reference

#include <iostream>
#include "DGtal/base/Common.h"
#include "ConfigTest.h"
#include "DGtalCatch.h"
#include "DGtal/helpers/StdDefs.h"
#include "DGtal/dec/PolygonalCalculus.h"
#include "DGtal/shapes/SurfaceMesh.h"
#include "DGtal/shapes/MeshHelpers.h"
#include "DGtal/helpers/Shortcuts.h"
#include "DGtal/math/linalg/DirichletConditions.h"

Include dependency graph for testPolygonalCalculus.cpp:

Go to the source code of this file.

Functions
RealPoint	vecToRealPoint (PolygonalCalculus< RealPoint, RealPoint >::Vector &v)

	TEST_CASE ("Testing PolygonalCalculus")

	TEST_CASE ("Testing PolygonalCalculus and DirichletConditions")

Detailed Description

This program is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version.

This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.

You should have received a copy of the GNU General Public License along with this program. If not, see http://www.gnu.org/licenses/.

Author: David Coeurjolly (david.nosp@m..coe.nosp@m.urjol.nosp@m.ly@l.nosp@m.iris..nosp@m.cnrs.nosp@m..fr ) Laboratoire d'InfoRmatique en Image et Systemes d'information - LIRIS (CNRS, UMR 5205), CNRS, France; Jacques-Olivier Lachaud (jacqu.nosp@m.es-o.nosp@m.livie.nosp@m.r.la.nosp@m.chaud.nosp@m.@uni.nosp@m.v-sav.nosp@m.oie..nosp@m.fr ) Laboratory of Mathematics (CNRS, UMR 5127), University of Savoie, France

Date: 2021/09/02

Functions for testing class PolygonalCalculus.

This file is part of the DGtal library.

Definition in file testPolygonalCalculus.cpp.

Function Documentation

◆ TEST_CASE() [1/2]

TEST_CASE ( "Testing PolygonalCalculus and DirichletConditions" )

Definition at line 280 of file testPolygonalCalculus.cpp.

 {
   typedef Shortcuts< KSpace >                SH3;
   typedef SurfaceMesh< RealPoint,RealPoint > Mesh;
   typedef Mesh::Index                        Index;
   typedef PolygonalCalculus< RealPoint,RealVector > PolyDEC;
   typedef DirichletConditions< EigenLinearAlgebraBackend > DC;
  
   // Build a more complex surface.
   auto params = SH3::defaultParameters();
   
   params( "polynomial", "0.1*y*y -0.1*x*x - 2.0*z" )( "gridstep", 2.0 );
   auto implicit_shape  = SH3::makeImplicitShape3D  ( params );
   auto digitized_shape = SH3::makeDigitizedImplicitShape3D( implicit_shape, params );
   auto K               = SH3::getKSpace( params );
   auto binary_image    = SH3::makeBinaryImage( digitized_shape, params );
   auto surface         = SH3::makeDigitalSurface( binary_image, K, params );
   auto primalSurface   = SH3::makePrimalSurfaceMesh(surface);
   
   std::vector<std::vector< Index > > faces;
   std::vector<RealPoint> positions = primalSurface->positions();
   for( PolygonalCalculus< RealPoint,RealVector >::MySurfaceMesh::Index face= 0 ; face < primalSurface->nbFaces(); ++face)
     faces.push_back(primalSurface->incidentVertices( face ));
   
   Mesh surfmesh = Mesh( positions.begin(), positions.end(),
                             faces.begin(),     faces.end() );
   auto boundaryEdges = surfmesh.computeManifoldBoundaryEdges();
   
   // Builds calculus and solve a Poisson problem with Dirichlet boundary conditions
   PolyDEC calculus( surfmesh );
   // Laplace opeartor
   PolyDEC::SparseMatrix L = calculus.globalLaplaceBeltrami();
   // value on boundary
   PolyDEC::Vector g = calculus.form0();
   // characteristic set of boundary
   DC::IntegerVector b = DC::IntegerVector::Zero( g.rows() );
  
   SECTION("Solve Poisson problem with boundary Dirichlet conditions")
     {
       for ( double scale = 0.1; scale < 2.0; scale *= 2.0 )
         {
           std::cout << "scale=" << scale << std::endl;
           auto phi = [&]( Index v)
           {
             return cos(scale*(surfmesh.position(v)[0]))
               * (scale*surfmesh.position(v)[1]);
           };
           
           for(auto &e: boundaryEdges)
             {
               auto adjVertices = surfmesh.edgeVertices(e);
               auto v1 = adjVertices.first;
               auto v2 = adjVertices.second;
               g(v1) = phi(v1);
               g(v2) = phi(v2);
               b(v1) = 1;
               b(v2) = 1;
             }
           // Solve Δu=0 with g as boundary conditions
           PolyDEC::Solver solver;
           PolyDEC::SparseMatrix L_dirichlet = DC::dirichletOperator( L, b );
           solver.compute( L_dirichlet );
           REQUIRE( solver.info() == Eigen::Success );
           PolyDEC::Vector g_dirichlet = DC::dirichletVector( L, g, b, g );
           PolyDEC::Vector x_dirichlet = solver.solve( g_dirichlet );
           REQUIRE( solver.info() == Eigen::Success );
           PolyDEC::Vector u = DC::dirichletSolution( x_dirichlet, b, g );
           double min_phi = 0.0;
           double max_phi = 0.0;
           double min_u   = 0.0;
           double max_u   = 0.0;
           double min_i_u = 0.0;
           double max_i_u = 0.0;
           for (  PolygonalCalculus< RealPoint,RealVector >::MySurfaceMesh::Index v = 0; v < surfmesh.nbVertices(); ++v )
             {
               min_phi = std::min( min_phi, phi( v ) );
               max_phi = std::max( max_phi, phi( v ) );
               min_u   = std::min( min_u  , u  ( v ) );
               max_u   = std::max( max_u  , u  ( v ) );
               if ( b( v ) == 0.0 )
                 {
                   min_i_u = std::min( min_i_u, u  ( v ) );
                   max_i_u = std::max( max_i_u, u  ( v ) );
                 }
             }
           REQUIRE( min_phi <= min_u );
           REQUIRE( max_phi >= max_u );
           REQUIRE( min_phi <  min_i_u );
           REQUIRE( max_phi >  max_i_u );
         } //   for ( double scale = 0.1; scale < 2.0; scale *= 2.0 )
     }
 };

References binary_image, calculus, DGtal::SurfaceMesh< TRealPoint, TRealVector >::computeManifoldBoundaryEdges(), DGtal::SurfaceMesh< TRealPoint, TRealVector >::edgeVertices(), DGtal::PolygonalCalculus< TRealPoint, TRealVector >::form0(), DGtal::PolygonalCalculus< TRealPoint, TRealVector >::globalLaplaceBeltrami(), K, DGtal::L, max(), DGtal::SurfaceMesh< TRealPoint, TRealVector >::nbVertices(), phi(), DGtal::SurfaceMesh< TRealPoint, TRealVector >::position(), REQUIRE(), SECTION(), surface, and surfmesh.

◆ TEST_CASE() [2/2]

TEST_CASE ( "Testing PolygonalCalculus" )

Definition at line 59 of file testPolygonalCalculus.cpp.

 {
   typedef SurfaceMesh< RealPoint,RealPoint > Mesh;
   std::vector<RealPoint> positions = { RealPoint( 0, 0, 0 ) ,
     RealPoint( 1, 0, 0 ) ,
     RealPoint( 0, 1, 0 ) ,
     RealPoint( 1, 1, 0 ) ,
     RealPoint( 0, 0, 1 ) ,
     RealPoint( 1, 0, 1 ) ,
     RealPoint( 0, 1, 1 ) ,
     RealPoint( 1, 1, 1 ) ,
     RealPoint( 1, 0, 2 ) ,
     RealPoint( 0, 0, 2 ) };
   std::vector<Mesh::Vertices> faces = { { 1, 0, 2, 3 },
     { 0, 1, 5, 4 } ,
     { 1, 3, 7, 5 } ,
     { 3, 2, 6, 7 } ,
     { 2, 0, 4, 6 } ,
     { 4, 5, 8, 9 } };
   
   Mesh box(positions.cbegin(), positions.cend(),
            faces.cbegin(), faces.cend());
   
   PolygonalCalculus< RealPoint,RealVector > boxCalculus(box);
   
   SECTION("Construction and basic operators")
     {
       REQUIRE( boxCalculus.isValid() );
       REQUIRE( boxCalculus.nbVertices() == positions.size() );
  
       PolygonalCalculus< RealPoint,RealVector >::Face f = 0;
       auto x = boxCalculus.X(f);
       auto d = boxCalculus.D(f);
       auto a = boxCalculus.A(f);
       
       //Checking X
       PolygonalCalculus< RealPoint,RealVector >::Vector vec = x.row(0);
       REQUIRE( vecToRealPoint(vec ) == positions[1]);
       vec = x.row(1);
       REQUIRE( vecToRealPoint(vec ) == positions[0]);
       vec = x.row(2);
       REQUIRE( vecToRealPoint(vec ) == positions[2]);
       vec = x.row(3);
       REQUIRE( vecToRealPoint(vec ) == positions[3]);
  
       trace.info()<< boxCalculus <<std::endl;
       
       //Some D and A
       REQUIRE( d(1,1) == -1 );
       REQUIRE( d(0,1) == 1 );
       REQUIRE( d(0,2) == 0 );
  
       REQUIRE( a(1,1) == 0.5 );
       REQUIRE( a(0,1) == 0.5 );
       REQUIRE( a(0,2) == 0 );
       
       auto vectorArea = boxCalculus.vectorArea(f);
       
       //Without correction, this should match
       for(auto ff=0; ff<6; ++ff)
         REQUIRE( boxCalculus.faceArea(ff) == box.faceArea(ff) );
      
       box.computeFaceNormalsFromPositions();
       for(auto ff=0; ff<6; ++ff)
       {
         auto cn = boxCalculus.faceNormalAsDGtalVector(ff);
         auto n = box.faceNormal(ff);
         REQUIRE(  cn == n  );
       }
       
       RealPoint c = boxCalculus.centroidAsDGtalPoint(f);
       RealPoint expected(0.5,0.5,0.0);
       REQUIRE(c == expected);
     }
   
   SECTION("Derivatives")
   {
     PolygonalCalculus< RealPoint,RealVector >::Face f = 0;
     auto d = boxCalculus.D(f);
     
     auto nf = boxCalculus.faceDegree(f);
     PolygonalCalculus< RealPoint,RealVector >::Vector phi(nf),expected(nf);
     phi << 1.0, 3.0, 2.0, 6.0;
     expected << 2,-1,4,-5;
     auto dphi = d*phi;  // n_f x 1 matrix
     REQUIRE(dphi == expected);
     
   }
   
   SECTION("Structural propertes")
   {
     PolygonalCalculus< RealPoint,RealVector >::Face f = 0;
     auto nf =  boxCalculus.faceDegree(f);
     PolygonalCalculus< RealPoint,RealVector >::Vector phi(nf);
     phi << 1.0, 3.0, 2.0, 6.0;
     
     auto G = boxCalculus.gradient(f);
     auto gphi = G*phi;
     auto coG = boxCalculus.coGradient(f);
     auto cogphi = coG*phi;
     
     // grad . cograd == 0
     REQUIRE( gphi.dot(cogphi) == 0.0);
         
     //    Gf = Uf Df
     REQUIRE( G == boxCalculus.sharp(f)*boxCalculus.D(f));
     
     //    UV = I - nn^t (lemma4)
     PolygonalCalculus< RealPoint,RealVector >::Vector n = boxCalculus.faceNormal(f);
     REQUIRE( boxCalculus.sharp(f)*boxCalculus.flat(f) == PolygonalCalculus< RealPoint,RealVector >::DenseMatrix::Identity(3,3) - n*n.transpose() );
     
     //    P^2 = P (lemma6)
     auto P = boxCalculus.P(f);
     REQUIRE( P*P == P);
     
     //    PV=0 (lemma5)
     REQUIRE( (P*boxCalculus.flat(f)).norm() == 0.0);
   }
   
   SECTION("Div / Curl")
   {
     PolygonalCalculus< RealPoint,RealVector >::Face f = 0;
     auto curl = boxCalculus.curl(f);
     //Not a great test BTW
     REQUIRE(curl.norm() == 2.0);
   }
   
   SECTION("Local Laplace-Beltrami")
   {
     PolygonalCalculus< RealPoint,RealVector >::Face f = 0;
     auto nf = box.incidentVertices(f).size();
     
     auto L = boxCalculus.laplaceBeltrami(f);
     PolygonalCalculus< RealPoint,RealVector >::Vector phi(nf),expected(nf);
     phi << 1.0, 1.0, 1.0, 1.0;
     expected << 0,0,0,0;
     auto lphi = L*phi;
     REQUIRE( lphi == expected);
   }
  
   SECTION("Local Connection-Laplace-Beltrami")
   {
     PolygonalCalculus< RealPoint,RealVector >::Face f = 0;
     auto nf = box.incidentVertices(f).size();
  
     auto L = boxCalculus.connectionLaplacian(f);
     PolygonalCalculus< RealPoint,RealVector >::Vector phi(2*nf);
     phi << 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0;
     //since connection laplacian transports the phi vectors to the face,
     //it's not expected to have 0 since these vectors aren't actually the same
     auto lphi = L*phi;
     //but we can still check that L is semi-definite
     double det = L.determinant()+1.;
     REQUIRE( det == Approx(1.0));
     REQUIRE( lphi[2] == Approx(-3.683));
   }
   
   SECTION("Covariant Operators")
   {
     PolygonalCalculus< RealPoint,RealVector >::Face f = 0;
     auto nf = box.incidentVertices(f).size();
  
     PolygonalCalculus< RealPoint,RealVector >::Vector phi(2*nf);
     phi << 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0;
     auto CG = boxCalculus.covariantGradient(f,phi);
     auto CP = boxCalculus.covariantProjection(f,phi);
  
     //check sizes
     REQUIRE( CG.rows() == 2);
     REQUIRE( CG.cols() == 2);
     REQUIRE( CP.rows() == (Eigen::Index)faces[f].size());
     REQUIRE( CP.cols() == 2);
  
     REQUIRE( CG(0,0) == Approx(0.707106));
     REQUIRE( CP(0,0) == Approx(1.224744));
   }
   SECTION("Check lumped mass matrix")
   {
     PolygonalCalculus< RealPoint,RealVector >::SparseMatrix M = boxCalculus.globalLumpedMassMatrix();
     double a=0.0;
     for( PolygonalCalculus< RealPoint,RealVector >::MySurfaceMesh::Index v=0; v < box.nbVertices(); ++v )
       a += M.coeffRef(v,v);
     
     double fa=0.0;
     for( PolygonalCalculus< RealPoint,RealVector >::MySurfaceMesh::Index f=0; f < box.nbFaces(); ++f )
       fa += box.faceArea(f);
     REQUIRE( a == fa );
   }
   
   SECTION("Checking cache")
   {
     auto cacheU = boxCalculus.getOperatorCacheMatrix( [&](const PolygonalCalculus< RealPoint,RealVector >::Face f){ return boxCalculus.sharp(f);} );
     REQUIRE( cacheU.size() == 6 );
     
     auto cacheC = boxCalculus.getOperatorCacheVector( [&](const PolygonalCalculus< RealPoint,RealVector >::Face f){ return boxCalculus.centroid(f);} );
     REQUIRE( cacheC.size() == 6 );
   }
   
   SECTION("Internal cache")
   {
     PolygonalCalculus< RealPoint,RealVector > boxCalculusCached(box,true);
     trace.info()<< boxCalculusCached <<std::endl;
     
     trace.beginBlock("Without cache");
     PolygonalCalculus< RealPoint,RealVector >::SparseMatrix L(box.nbVertices(),box.nbVertices());
     for(auto i=0; i < 1000 ; ++i)
       L += i*boxCalculus.globalLaplaceBeltrami();
     auto tps = trace.endBlock();
     
     trace.beginBlock("With cache");
     PolygonalCalculus< RealPoint,RealVector >::SparseMatrix LC(box.nbVertices(),box.nbVertices());
     for(auto i=0; i < 1000 ; ++i)
       LC += i*boxCalculusCached.globalLaplaceBeltrami();
     auto tpsC = trace.endBlock();
     REQUIRE(tpsC < tps);
     REQUIRE(L.norm() == Approx(LC.norm()));
     
   }
   
 }

◆ vecToRealPoint()

RealPoint vecToRealPoint ( PolygonalCalculus< RealPoint, RealPoint >::Vector & v )

Definition at line 54 of file testPolygonalCalculus.cpp.

 {
   return RealPoint(v(0),v(1),v(2));
 }

Referenced by TEST_CASE().