//Fill the hole (or holes) in the mesh
        private static HashSet <Hole> FillHoles(HashSet <HalfEdge3> holeEdgesI, HashSet <HalfEdge3> holeEdgesO, OrientedPlane3 orientedCutPlane, Transform meshTrans, MyVector3 planeNormal)
        {
            if (holeEdgesI == null || holeEdgesI.Count == 0)
            {
                Debug.Log("This mesh has no hole");

                return(null);
            }


            //Find all separate holes
            HashSet <List <HalfEdge3> > allHoles = IdentifySeparateHoles(holeEdgesI);

            if (allHoles.Count == 0)
            {
                Debug.LogWarning("Couldn't identify any holes even though we have hole edges");

                return(null);
            }

            //Debug
            //foreach (List<HalfEdge3> hole in allHoles)
            //{
            //    foreach (HalfEdge3 e in hole)
            //    {
            //        Debug.DrawLine(meshTrans.TransformPoint(e.v.position.ToVector3()), Vector3.zero, Color.white, 5f);
            //    }
            //}


            //Fill the hole with a mesh
            HashSet <Hole> holeMeshes = new HashSet <Hole>();

            foreach (List <HalfEdge3> hole in allHoles)
            {
                HalfEdgeData3 holeMeshI = new HalfEdgeData3();
                HalfEdgeData3 holeMeshO = new HalfEdgeData3();

                //Transform vertices to local position of the cut plane to make it easier to triangulate with Ear Clipping
                //Ear CLipping wants vertices in 2d
                List <MyVector2> sortedEdges_2D = new List <MyVector2>();

                Transform planeTrans = orientedCutPlane.planeTrans;

                foreach (HalfEdge3 e in hole)
                {
                    MyVector3 pMeshSpace = e.v.position;

                    //Mesh space to Global space
                    Vector3 pGlobalSpace = meshTrans.TransformPoint(pMeshSpace.ToVector3());

                    //Global space to Plane space
                    Vector3 pPlaneSpace = planeTrans.InverseTransformPoint(pGlobalSpace);

                    //Y is normal direction so should be 0
                    MyVector2 p2D = new MyVector2(pPlaneSpace.x, pPlaneSpace.z);

                    sortedEdges_2D.Add(p2D);
                }


                //Triangulate with Ear Clipping
                HashSet <Triangle2> triangles = _EarClipping.Triangulate(sortedEdges_2D, null, optimizeTriangles: false);

                //Debug.Log($"Number of triangles from Ear Clipping: {triangles.Count}");

                //Transform vertices to mesh space and half-edge data structure
                foreach (Triangle2 t in triangles)
                {
                    //3d space
                    Vector3 p1 = new Vector3(t.p1.x, 0f, t.p1.y);
                    Vector3 p2 = new Vector3(t.p2.x, 0f, t.p2.y);
                    Vector3 p3 = new Vector3(t.p3.x, 0f, t.p3.y);

                    //Plane space to Global space
                    Vector3 p1Global = planeTrans.TransformPoint(p1);
                    Vector3 p2Global = planeTrans.TransformPoint(p2);
                    Vector3 p3Global = planeTrans.TransformPoint(p3);

                    //Global space to Mesh space
                    Vector3 p1Mesh = meshTrans.InverseTransformPoint(p1Global);
                    Vector3 p2Mesh = meshTrans.InverseTransformPoint(p2Global);
                    Vector3 p3Mesh = meshTrans.InverseTransformPoint(p3Global);

                    //For inside mesh
                    MyMeshVertex v1_I = new MyMeshVertex(p1Mesh.ToMyVector3(), planeNormal);
                    MyMeshVertex v2_I = new MyMeshVertex(p2Mesh.ToMyVector3(), planeNormal);
                    MyMeshVertex v3_I = new MyMeshVertex(p3Mesh.ToMyVector3(), planeNormal);

                    //For inside mesh
                    MyMeshVertex v1_O = new MyMeshVertex(p1Mesh.ToMyVector3(), -planeNormal);
                    MyMeshVertex v2_O = new MyMeshVertex(p2Mesh.ToMyVector3(), -planeNormal);
                    MyMeshVertex v3_O = new MyMeshVertex(p3Mesh.ToMyVector3(), -planeNormal);

                    //Now we can finally add this triangle to the half-edge data structure
                    AddTriangleToMesh(v1_I, v2_I, v3_I, holeMeshI, null);
                    AddTriangleToMesh(v1_O, v3_O, v2_O, holeMeshO, null);
                }

                //We also need an edge belonging to the mesh (not hole mesh) to easier merge mesh with hole
                //The hole edges were generated for the Inside mesh
                HalfEdge3 holeEdgeI = hole[0];

                //But we also need an edge for the Outside mesh
                bool foundCorrespondingEdge = false;

                MyVector3 eGoingTo   = holeEdgeI.v.position;
                MyVector3 eGoingFrom = holeEdgeI.prevEdge.v.position;

                foreach (HalfEdge3 holeEdgeO in holeEdgesO)
                {
                    MyVector3 eOppsiteGoingTo   = holeEdgeO.v.position;
                    MyVector3 eOppsiteGoingFrom = holeEdgeO.prevEdge.v.position;

                    if (eOppsiteGoingTo.Equals(eGoingFrom) && eOppsiteGoingFrom.Equals(eGoingTo))
                    {
                        Hole newHoleMesh = new Hole(holeMeshI, holeMeshO, holeEdgeI, holeEdgeO);

                        holeMeshes.Add(newHoleMesh);

                        foundCorrespondingEdge = true;

                        break;
                    }
                }

                if (!foundCorrespondingEdge)
                {
                    Debug.Log("Couldnt find opposite edge in hole, so no hole was added");
                }
            }

            return(holeMeshes);
        }
        //Should return null if the mesh couldn't be cut because it doesn't intersect with the plane
        //Otherwise it should return two new meshes
        //meshTrans is needed so we can transform the cut plane to the mesh's local space
        public static List <Mesh> CutMesh(Transform meshTrans, OrientedPlane3 orientedCutPlaneGlobal)
        {
            //Validate the input data
            if (meshTrans == null)
            {
                Debug.Log("There's transform to cut");

                return(null);
            }

            Mesh mesh = meshTrans.GetComponent <MeshFilter>().mesh;

            if (mesh == null)
            {
                Debug.Log("There's no mesh to cut");

                return(null);
            }


            //The plane with just a normal
            Plane3 cutPlaneGlobal = orientedCutPlaneGlobal.Plane3;

            //First check if the AABB of the mesh is intersecting with the plane
            //Otherwise we can't cut the mesh, so its a waste of time

            //To get the AABB in world space we need to use the mesh renderer
            MeshRenderer mr = meshTrans.GetComponent <MeshRenderer>();

            if (mr != null)
            {
                AABB3 aabb = new AABB3(mr.bounds);

                //The corners of this box
                HashSet <MyVector3> corners = aabb.GetCorners();

                if (corners != null && corners.Count > 1)
                {
                    //The points are in world space so use the plane in world space
                    if (ArePointsOnOneSideOfPlane(new List <MyVector3>(corners), cutPlaneGlobal))
                    {
                        Debug.Log("This mesh can't be cut because its AABB doesnt intersect with the plane");

                        return(null);
                    }
                }
            }



            //The two meshes we might end up with after the cut
            //One is in front of the plane and another is in back of the plane
            HalfEdgeData3 newMeshO = new HalfEdgeData3();
            HalfEdgeData3 newMeshI = new HalfEdgeData3();

            //The data belonging to the original mesh
            Vector3[] vertices  = mesh.vertices;
            int[]     triangles = mesh.triangles;
            Vector3[] normals   = mesh.normals;

            //Save the new edges we add when cutting triangles that intersects with the plane
            //Need to be edges so we can later connect them with each other to fill the hole
            //And to remove small triangles
            HashSet <HalfEdge3> newEdgesO = new HashSet <HalfEdge3>();
            HashSet <HalfEdge3> newEdgesI = new HashSet <HalfEdge3>();


            //Transform the plane from global space to local space of the mesh
            MyVector3 planePosLocal    = meshTrans.InverseTransformPoint(cutPlaneGlobal.pos.ToVector3()).ToMyVector3();
            MyVector3 planeNormalLocal = meshTrans.InverseTransformDirection(cutPlaneGlobal.normal.ToVector3()).ToMyVector3();

            Plane3 cutPlane = new Plane3(planePosLocal, planeNormalLocal);


            //Loop through all triangles in the original mesh
            for (int i = 0; i < triangles.Length; i += 3)
            {
                //Get the triangle data we need
                int triangleIndex1 = triangles[i + 0];
                int triangleIndex2 = triangles[i + 1];
                int triangleIndex3 = triangles[i + 2];

                //Positions
                Vector3 p1_unity = vertices[triangleIndex1];
                Vector3 p2_unity = vertices[triangleIndex2];
                Vector3 p3_unity = vertices[triangleIndex3];

                MyVector3 p1 = p1_unity.ToMyVector3();
                MyVector3 p2 = p2_unity.ToMyVector3();
                MyVector3 p3 = p3_unity.ToMyVector3();

                //Normals
                MyVector3 n1 = normals[triangleIndex1].ToMyVector3();
                MyVector3 n2 = normals[triangleIndex2].ToMyVector3();
                MyVector3 n3 = normals[triangleIndex3].ToMyVector3();

                //To make it easier to send data to methods
                MyMeshVertex v1 = new MyMeshVertex(p1, n1);
                MyMeshVertex v2 = new MyMeshVertex(p2, n2);
                MyMeshVertex v3 = new MyMeshVertex(p3, n3);


                //First check on which side of the plane these vertices are
                //If they are all on one side we dont have to cut the triangle
                bool is_p1_front = _Geometry.IsPointOutsidePlane(cutPlane, v1.position);
                bool is_p2_front = _Geometry.IsPointOutsidePlane(cutPlane, v2.position);
                bool is_p3_front = _Geometry.IsPointOutsidePlane(cutPlane, v3.position);


                //Build triangles belonging to respective mesh

                //All are outside the plane
                if (is_p1_front && is_p2_front && is_p3_front)
                {
                    AddTriangleToMesh(v1, v2, v3, newMeshO, newEdges: null);
                }
                //All are inside the plane
                else if (!is_p1_front && !is_p2_front && !is_p3_front)
                {
                    AddTriangleToMesh(v1, v2, v3, newMeshI, newEdges: null);
                }
                //The vertices are on different sides of the plane, so we need to cut the triangle into 3 new triangles
                else
                {
                    //We get 6 cases where each vertex is on its own in front or in the back of the plane

                    //p1 is outside
                    if (is_p1_front && !is_p2_front && !is_p3_front)
                    {
                        CutTriangleOneOutside(v1, v2, v3, newMeshO, newMeshI, newEdgesI, newEdgesO, cutPlane);
                    }
                    //p1 is inside
                    else if (!is_p1_front && is_p2_front && is_p3_front)
                    {
                        CutTriangleTwoOutside(v2, v3, v1, newMeshO, newMeshI, newEdgesI, newEdgesO, cutPlane);
                    }

                    //p2 is outside
                    else if (!is_p1_front && is_p2_front && !is_p3_front)
                    {
                        CutTriangleOneOutside(v2, v3, v1, newMeshO, newMeshI, newEdgesI, newEdgesO, cutPlane);
                    }
                    //p2 is inside
                    else if (is_p1_front && !is_p2_front && is_p3_front)
                    {
                        CutTriangleTwoOutside(v3, v1, v2, newMeshO, newMeshI, newEdgesI, newEdgesO, cutPlane);
                    }

                    //p3 is outside
                    else if (!is_p1_front && !is_p2_front && is_p3_front)
                    {
                        CutTriangleOneOutside(v3, v1, v2, newMeshO, newMeshI, newEdgesI, newEdgesO, cutPlane);
                    }
                    //p3 is inside
                    else if (is_p1_front && is_p2_front && !is_p3_front)
                    {
                        CutTriangleTwoOutside(v1, v2, v3, newMeshO, newMeshI, newEdgesI, newEdgesO, cutPlane);
                    }

                    //Something is strange if we end up here...
                    else
                    {
                        Debug.Log("No case was gound where we split triangle into 3 new triangles");
                    }
                }
            }


            //Generate the new meshes only needed the old mesh intersected with the plane
            if (newMeshO.verts.Count == 0 || newMeshI.verts.Count == 0)
            {
                return(null);
            }


            //Find opposite edges to each edge
            //This is a slow process, so should be done only if the mesh is intersecting with the plane
            newMeshO.ConnectAllEdges();
            newMeshI.ConnectAllEdges();

            //Display all edges which have no opposite
            DebugHalfEdge.DisplayEdgesWithNoOpposite(newMeshO.edges, meshTrans, Color.white);
            DebugHalfEdge.DisplayEdgesWithNoOpposite(newMeshI.edges, meshTrans, Color.white);


            //Remove small triangles at the seam where we did the cut because they will cause shading issues if the surface is smooth
            //RemoveSmallTriangles(F_Mesh, newEdges);


            //Split each mesh into separate meshes if the original mesh is not connected, meaning it has islands
            HashSet <HalfEdgeData3> newMeshesO = SeparateMeshIslands(newMeshO);
            HashSet <HalfEdgeData3> newMeshesI = SeparateMeshIslands(newMeshI);


            //Fill the holes in the mesh
            HashSet <Hole> allHoles = FillHoles(newEdgesI, newEdgesO, orientedCutPlaneGlobal, meshTrans, planeNormalLocal);


            //Connect the holes with respective mesh
            AddHolesToMeshes(newMeshesO, newMeshesI, allHoles);


            //Finally generate standardized Unity meshes
            List <Mesh> cuttedUnityMeshes = new List <Mesh>();

            foreach (HalfEdgeData3 meshData in newMeshesO)
            {
                Mesh unityMesh = meshData.ConvertToUnityMesh("Outside mesh", shareVertices: true, generateNormals: false);

                cuttedUnityMeshes.Add(unityMesh);
            }

            foreach (HalfEdgeData3 meshData in newMeshesI)
            {
                Mesh unityMesh = meshData.ConvertToUnityMesh("Inside mesh", shareVertices: true, generateNormals: false);

                cuttedUnityMeshes.Add(unityMesh);
            }



            return(cuttedUnityMeshes);
        }