foam-extend4.1-coherent-io/applications/solvers/solidMechanics/elasticAcpSolidFoam/createCrack.H

    label cohesivePatchID = -1;

   solidCohesiveFvPatchVectorField* cohesivePatchUPtr = NULL;
   solidCohesiveFixedModeMixFvPatchVectorField* cohesivePatchUFixedModePtr = NULL;

    forAll (U.boundaryField(), patchI)
    {
      if (isA<solidCohesiveFvPatchVectorField>(U.boundaryField()[patchI]))
        {
	  cohesivePatchID = patchI;
	  cohesivePatchUPtr =
	    &refCast<solidCohesiveFvPatchVectorField>
	    (
	     U.boundaryField()[cohesivePatchID]
	     );
	  break;
        }
      else if (isA<solidCohesiveFixedModeMixFvPatchVectorField>(U.boundaryField()[patchI]))
	{
	  cohesivePatchID = patchI;
	  cohesivePatchUFixedModePtr =
	    &refCast<solidCohesiveFixedModeMixFvPatchVectorField>
	    (
	     U.boundaryField()[cohesivePatchID]
	     );
	  break;
	}
    }

    if(cohesivePatchID == -1)
    {
        FatalErrorIn(args.executable())
            << "Can't find cohesiveLawFvPatch" << nl
	    << "One of the boundary patches in " << U.name() << ".boundaryField() "
	    << "should be of type " << solidCohesiveFvPatchVectorField::typeName
	    << "or " << solidCohesiveFixedModeMixFvPatchVectorField::typeName
	    << abort(FatalError);
    }

    // solidCohesiveFvPatchVectorField& cohesivePatchU =
    // 	refCast<solidCohesiveFvPatchVectorField>
    // 	(
    // 	 U.boundaryField()[cohesivePatchID]
    //     );

   // philipc: I have moved cohesive stuff to constitutiveModel

   // cohesiveZone is an index field
   // which allows the user to limit the crack to certain areas at runtime
   // 1 for faces within cohesiveZone
   // 0 for faces outside cohesiveZone
    surfaceScalarField cohesiveZone
    (
        IOobject
        (
            "cohesiveZone",
            runTime.timeName(),
            mesh,
            IOobject::READ_IF_PRESENT,
            IOobject::AUTO_WRITE
        ),
        mesh,
        dimensionedScalar("zero", dimless, 0.0)
     );

    // limit crack to specified boxes
    {
      const dictionary& stressControl =
	mesh.solutionDict().subDict("solidMechanics");

      List<boundBox> userBoxes(stressControl.lookup("crackLimitingBoxes"));
      const surfaceVectorField& Cf = mesh.Cf();
      forAll(cohesiveZone.internalField(), faceI)
	{
	  bool faceInsideBox = false;

	  forAll(userBoxes, boxi)
	    {
	      if(userBoxes[boxi].contains(Cf.internalField()[faceI])) faceInsideBox = true;
	    }

	  if(faceInsideBox)
	    {
	      cohesiveZone.internalField()[faceI] = 1.0;
	    }
	}

      forAll(cohesiveZone.boundaryField(), patchI)
	{
	  // cracks may go along proc boundaries
	  if(mesh.boundaryMesh()[patchI].type() == processorPolyPatch::typeName)
	    {
	      forAll(cohesiveZone.boundaryField()[patchI], faceI)
		{
		  bool faceInsideBox = false;

		  forAll(userBoxes, boxi)
		    {
		      if(userBoxes[boxi].contains(Cf.boundaryField()[patchI][faceI])) faceInsideBox = true;
		    }

		  if(faceInsideBox)
		    {
		      cohesiveZone.boundaryField()[patchI][faceI] = 1.0;
		    }
		}
	    }
	}

      Info << "\nThere are " << gSum(cohesiveZone.internalField()) << " potential internal crack faces" << nl << endl;
      Info << "\nThere are " << gSum(cohesiveZone.boundaryField())/2 << " potential coupled boundary crack faces" << nl << endl;

      // write field for visualisation
      volScalarField cohesiveZoneVol
	(
	 IOobject
	 (
	  "cohesiveZoneVol",
	  runTime.timeName(),
	  mesh,
	  IOobject::NO_READ,
	  IOobject::AUTO_WRITE
	  ),
	 mesh,
	 dimensionedScalar("zero", dimless, 0.0)
	 );
      forAll(cohesiveZone.internalField(), facei)
	{
	  if(cohesiveZone.internalField()[facei])
	    {
	      cohesiveZoneVol.internalField()[mesh.owner()[facei]] = 1.0;
	      cohesiveZoneVol.internalField()[mesh.neighbour()[facei]] = 1.0;
	    }
	}
      forAll(cohesiveZone.boundaryField(), patchi)
	{
	  forAll(cohesiveZone.boundaryField()[patchi], facei)
	    {
	      if(cohesiveZone.boundaryField()[patchi][facei] > 0.0)
		{
		  cohesiveZoneVol.boundaryField()[patchi][facei] = 1.0;
		}
	    }
	}
      Info << "Writing cohesiveZone field" << endl;
      cohesiveZoneVol.write();
    }


    Switch initialiseSolution(false);

    if
    (
        mesh.solutionDict().subDict("solidMechanics")
       .found("initialiseSolution")
    )
    {
        initialiseSolution =
            Switch
            (
                mesh.solutionDict().subDict("solidMechanics").lookup
                (
                    "initialiseSolution"
                )
            );
    }


    Switch breakOnlyOneFacePerTopologyChange(true);

    if
    (
        mesh.solutionDict().subDict("solidMechanics")
       .found("breakOnlyOneFacePerTopologyChange")
    )
    {
        breakOnlyOneFacePerTopologyChange =
            Switch
            (
                mesh.solutionDict().subDict("solidMechanics").lookup
                (
                    "breakOnlyOneFacePerTopologyChange"
                )
            );
    }


    Switch crackPropagationFromSpecifiedPatches
    (
        mesh.solutionDict().subDict("solidMechanics").lookup
        (
            "crackPropagationFromSpecifiedPatches"
        )
    );

    wordList crackPropagationPatchNames
    (
        mesh.solutionDict().subDict("solidMechanics").lookup
        (
            "crackPropagationPatches"
        )
    );

    labelList crackPropagationPatches(crackPropagationPatchNames.size(), -1);

    forAll(crackPropagationPatchNames, patchI)
    {
        crackPropagationPatches[patchI] =
            mesh.boundaryMesh().findPatchID
            (
                crackPropagationPatchNames[patchI]
            );

        if(crackPropagationPatches[patchI] == -1)
        {
            FatalErrorIn(args.executable())
                << "Can't find " << crackPropagationPatchNames[patchI]
                << " patch" << abort(FatalError);
        }
    }

    // Internal faces next to selected crack propagation patches
    labelList crackPropagationPatchesInternalFaces;

#   include "updateCrackPropagationPatchesInternalFaces.H"