/// Adds a new point to a triangle buffer, using the format defined for that MeshGenerator /// @param buffer the triangle buffer to update /// @param position the position of the new point /// @param normal the normal of the new point /// @param uv the uv texcoord of the new point // //ORIGINAL LINE: inline void addPoint(TriangleBuffer& buffer, const Ogre::Vector3& position, const Ogre::Vector3& normal, const Ogre::Vector2& uv) const protected void addPoint(ref TriangleBuffer buffer, Vector3 position, Vector3 normal, Vector2 uv) { if (mTransform) { buffer.position(mPosition + mOrientation * (mScale * position)); } else { buffer.position(position); } if (mEnableNormals) { if (mTransform) { buffer.normal(mOrientation * normal); } else { buffer.normal(normal); } } if (mSwitchUV) { for (byte i = 0; i < mNumTexCoordSet; i++) { buffer.textureCoord(mUVOrigin.x + uv.y * mUTile, mUVOrigin.y + uv.x * mVTile); } } else { for (byte i = 0; i < mNumTexCoordSet; i++) { buffer.textureCoord(mUVOrigin.x + uv.x * mUTile, mUVOrigin.y + uv.y * mVTile); } } }
//----------------------------------------------------------------------- public static void _retriangulate(ref TriangleBuffer newMesh, TriangleBuffer inputMesh, std_vector <Intersect> intersectionList, bool first) { std_vector <TriangleBuffer.Vertex> vec = inputMesh.getVertices(); std_vector <int> ind = inputMesh.getIndices(); // Triangulate // Group intersections by triangle indice std_map <int, std_vector <Segment3D> > meshIntersects = new std_map <int, std_vector <Segment3D> >(); //for (List<Intersect>.Enumerator it = intersectionList.GetEnumerator(); it.MoveNext(); ++it) foreach (var it in intersectionList) { int it2_find; if (first) { it2_find = meshIntersects.find(it.mTri1); } else { it2_find = meshIntersects.find(it.mTri2); } if (it2_find != -1) { std_pair <int, std_vector <Segment3D> > it2 = meshIntersects.get((uint)it2_find); it2.second.push_back(it.mSeg); } else { std_vector <Segment3D> vec2 = new std_vector <Segment3D>(); vec2.push_back(it.mSeg); if (first) { meshIntersects[it.mTri1] = vec2; } else { meshIntersects[it.mTri2] = vec2; } } } // Build a new TriangleBuffer holding non-intersected triangles and retriangulated-intersected triangles //for (List<TriangleBuffer.Vertex>.Enumerator it = vec.GetEnumerator(); it.MoveNext(); ++it) foreach (var it in vec) { newMesh.vertex(it); } //for (int i = 0; i < (int)ind.Count / 3; i++) // if (meshIntersects.find(i) == meshIntersects.end()) // newMesh.triangle(ind[i * 3], ind[i * 3 + 1], ind[i * 3 + 2]); for (int i = 0; i < (int)ind.size() / 3; i++) { if (meshIntersects.find(i) == -1) { newMesh.triangle(ind[i * 3], ind[i * 3 + 1], ind[i * 3 + 2]); } } int numNonIntersected1 = newMesh.getIndices().size(); //for (std.map<int, List<Segment3D> >.Enumerator it = meshIntersects.begin(); it.MoveNext(); ++it) foreach (var it in meshIntersects) { std_vector <Segment3D> segments = it.Value; int triIndex = it.Key; Vector3 v1 = vec[ind[triIndex * 3]].mPosition; Vector3 v2 = vec[ind[triIndex * 3 + 1]].mPosition; Vector3 v3 = vec[ind[triIndex * 3 + 2]].mPosition; Vector3 triNormal = ((v2 - v1).CrossProduct(v3 - v1)).NormalisedCopy; Vector3 xAxis = triNormal.Perpendicular; Vector3 yAxis = triNormal.CrossProduct(xAxis); Vector3 planeOrigin = vec[ind[triIndex * 3]].mPosition; // Project intersection segments onto triangle plane std_vector <Segment2D> segments2 = new std_vector <Segment2D>(); //for (List<Segment3D>.Enumerator it2 = segments.GetEnumerator(); it2.MoveNext(); it2++) // segments2.Add(projectOnAxis(it2.Current, planeOrigin, xAxis, yAxis)); foreach (var it2 in segments) { segments2.push_back(projectOnAxis(it2, planeOrigin, xAxis, yAxis)); } //for (List<Segment2D>.Enumerator it2 = segments2.GetEnumerator(); it2.MoveNext();) int it2_c = segments2.Count; for (int j = it2_c - 1; j >= 0; j--) { Segment2D it2 = segments2[j]; if ((it2.mA - it2.mB).SquaredLength < 1e-5) { //C++ TO C# CONVERTER TODO TASK: There is no direct equivalent to the STL vector 'erase' method in C#: //it2 = segments2.erase(it2); segments2.RemoveAt(j); } //else } // Triangulate Triangulator t = new Triangulator(); //Triangle2D[[]] tri = new Triangle2D[ind[triIndex * 3]](projectOnAxis(vec.mPosition, planeOrigin, xAxis, yAxis), projectOnAxis(vec[ind[triIndex * 3 + 1]].mPosition, planeOrigin, xAxis, yAxis), projectOnAxis(vec[ind[triIndex * 3 + 2]].mPosition, planeOrigin, xAxis, yAxis)); Triangle2D tri = new Triangle2D(projectOnAxis(vec[ind[triIndex * 3]].mPosition, planeOrigin, xAxis, yAxis), projectOnAxis(vec[ind[triIndex * 3 + 1]].mPosition, planeOrigin, xAxis, yAxis), projectOnAxis(vec[ind[triIndex * 3 + 2]].mPosition, planeOrigin, xAxis, yAxis)); std_vector <Vector2> outPointList = new std_vector <Vector2>();//PointList outPointList; std_vector <int> outIndice = new std_vector <int>(); t.setManualSuperTriangle(tri).setRemoveOutside(false).setSegmentListToTriangulate(ref segments2).triangulate(outIndice, outPointList); // Deproject and add to triangleBuffer newMesh.rebaseOffset(); //for (List<int>.Enumerator it = outIndice.GetEnumerator(); it.MoveNext(); ++it) // newMesh.index(it.Current); foreach (var oindex in outIndice) { newMesh.index(oindex); } float x1 = tri.mPoints[0].x; float y1 = tri.mPoints[0].y; Vector2 uv1 = vec[ind[triIndex * 3]].mUV; float x2 = tri.mPoints[1].x; float y2 = tri.mPoints[1].y; Vector2 uv2 = vec[ind[triIndex * 3 + 1]].mUV; float x3 = tri.mPoints[2].x; float y3 = tri.mPoints[2].y; Vector2 uv3 = vec[ind[triIndex * 3 + 2]].mUV; float DET = x1 * y2 - x2 * y1 + x2 * y3 - x3 * y2 + x3 * y1 - x1 * y3; Vector2 A = ((y2 - y3) * uv1 + (y3 - y1) * uv2 + (y1 - y2) * uv3) / DET; Vector2 B = ((x3 - x2) * uv1 + (x1 - x3) * uv2 + (x2 - x1) * uv3) / DET; Vector2 C = ((x2 * y3 - x3 * y2) * uv1 + (x3 * y1 - x1 * y3) * uv2 + (x1 * y2 - x2 * y1) * uv3) / DET; //for (List<Vector2>.Enumerator it = outPointList.GetEnumerator(); it.MoveNext(); ++it) foreach (var it2 in outPointList) { Vector2 uv = A * it2.x + B * it2.y + C; newMesh.position(deprojectOnAxis(it2, planeOrigin, xAxis, yAxis)); newMesh.normal(triNormal); newMesh.textureCoord(uv); } } }