/* * Copyright (c) Contributors, http://opensimulator.org/ * See CONTRIBUTORS.TXT for a full list of copyright holders. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of the OpenSim Project nor the * names of its contributors may be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE DEVELOPERS ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE CONTRIBUTORS BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ using System; using System.Collections.Generic; using OpenSim.Framework; using OpenSim.Region.Physics.Manager; namespace OpenSim.Region.Physics.Meshing { public class MeshmerizerPlugin : IMeshingPlugin { public MeshmerizerPlugin() { } public string GetName() { return "Meshmerizer"; } public IMesher GetMesher() { return new Meshmerizer(); } } public class Meshmerizer : IMesher { //private static readonly log4net.ILog m_log = log4net.LogManager.GetLogger(System.Reflection.MethodBase.GetCurrentMethod().DeclaringType); // Setting baseDir to a path will enable the dumping of raw files // raw files can be imported by blender so a visual inspection of the results can be done // const string baseDir = "rawFiles"; private const string baseDir = null; //"rawFiles"; private const float DEG_TO_RAD = 0.01745329238f; // TODO: unused // private static void IntersectionParameterPD(PhysicsVector p1, PhysicsVector r1, PhysicsVector p2, // PhysicsVector r2, ref float lambda, ref float mu) // { // // p1, p2, points on the straight // // r1, r2, directional vectors of the straight. Not necessarily of length 1! // // note, that l, m can be scaled such, that the range 0..1 is mapped to the area between two points, // // thus allowing to decide whether an intersection is between two points // float r1x = r1.X; // float r1y = r1.Y; // float r2x = r2.X; // float r2y = r2.Y; // float denom = r1y*r2x - r1x*r2y; // if (denom == 0.0) // { // lambda = Single.NaN; // mu = Single.NaN; // return; // } // float p1x = p1.X; // float p1y = p1.Y; // float p2x = p2.X; // float p2y = p2.Y; // lambda = (-p2x*r2y + p1x*r2y + (p2y - p1y)*r2x)/denom; // mu = (-p2x*r1y + p1x*r1y + (p2y - p1y)*r1x)/denom; // } private static List FindInfluencedTriangles(List triangles, Vertex v) { List influenced = new List(); foreach (Triangle t in triangles) { if (t.isInCircle(v.X, v.Y)) { influenced.Add(t); } } return influenced; } private static void InsertVertices(List vertices, int usedForSeed, List triangles) { // This is a variant of the delaunay algorithm // each time a new vertex is inserted, all triangles that are influenced by it are deleted // and replaced by new ones including the new vertex // It is not very time efficient but easy to implement. int iCurrentVertex; int iMaxVertex = vertices.Count; for (iCurrentVertex = usedForSeed; iCurrentVertex < iMaxVertex; iCurrentVertex++) { // Background: A triangle mesh fulfills the delaunay condition if (iff!) // each circumlocutory circle (i.e. the circle that touches all three corners) // of each triangle is empty of other vertices. // Obviously a single (seeding) triangle fulfills this condition. // If we now add one vertex, we need to reconstruct all triangles, that // do not fulfill this condition with respect to the new triangle // Find the triangles that are influenced by the new vertex Vertex v = vertices[iCurrentVertex]; if (v == null) continue; // Null is polygon stop marker. Ignore it List influencedTriangles = FindInfluencedTriangles(triangles, v); List simplices = new List(); // Reconstruction phase. First step, dissolve each triangle into it's simplices, // i.e. it's "border lines" // Goal is to find "inner" borders and delete them, while the hull gets conserved. // Inner borders are special in the way that they always come twice, which is how we detect them foreach (Triangle t in influencedTriangles) { List newSimplices = t.GetSimplices(); simplices.AddRange(newSimplices); triangles.Remove(t); } // Now sort the simplices. That will make identical ones reside side by side in the list simplices.Sort(); // Look for duplicate simplices here. // Remember, they are directly side by side in the list right now, // So we only check directly neighbours int iSimplex; List innerSimplices = new List(); for (iSimplex = 1; iSimplex < simplices.Count; iSimplex++) // Startindex=1, so we can refer backwards { if (simplices[iSimplex - 1].CompareTo(simplices[iSimplex]) == 0) { innerSimplices.Add(simplices[iSimplex - 1]); innerSimplices.Add(simplices[iSimplex]); } } foreach (Simplex s in innerSimplices) { simplices.Remove(s); } // each simplex still in the list belongs to the hull of the region in question // The new vertex (yes, we still deal with verices here :-)) forms a triangle // with each of these simplices. Build the new triangles and add them to the list foreach (Simplex s in simplices) { Triangle t = new Triangle(s.v1, s.v2, vertices[iCurrentVertex]); if (!t.isDegraded()) { triangles.Add(t); } } } } private static SimpleHull BuildHoleHull(PrimitiveBaseShape pbs, ProfileShape pshape, HollowShape hshape, UInt16 hollowFactor) { // Tackle HollowShape.Same float fhollowFactor = (float)hollowFactor; switch (pshape) { case ProfileShape.Square: if (hshape == HollowShape.Same) hshape= HollowShape.Square; break; case ProfileShape.EquilateralTriangle: fhollowFactor = ((float)hollowFactor / 1.9f); if (hshape == HollowShape.Same) { hshape = HollowShape.Triangle; } break; case ProfileShape.HalfCircle: case ProfileShape.Circle: if (pbs.PathCurve == (byte)Extrusion.Straight) { if (hshape == HollowShape.Same) { hshape = HollowShape.Circle; } } break; default: if (hshape == HollowShape.Same) hshape= HollowShape.Square; break; } SimpleHull holeHull = null; if (hshape == HollowShape.Square) { float hollowFactorF = (float)fhollowFactor / (float)50000; Vertex IMM; Vertex IPM; Vertex IPP; Vertex IMP; if (pshape == ProfileShape.Circle) { // square cutout in cylinder is 45 degress rotated IMM = new Vertex(0.0f, -0.707f * hollowFactorF, 0.0f); IPM = new Vertex(0.707f * hollowFactorF, 0.0f, 0.0f); IPP = new Vertex(0.0f, 0.707f * hollowFactorF, 0.0f); IMP = new Vertex(-0.707f * hollowFactorF, 0.0f, 0.0f); } else if (pshape == ProfileShape.EquilateralTriangle) { IMM = new Vertex(0.0f, -0.667f * hollowFactorF, 0.0f); IPM = new Vertex(0.667f * hollowFactorF, 0.0f, 0.0f); IPP = new Vertex(0.0f, 0.667f * hollowFactorF, 0.0f); IMP = new Vertex(-0.667f * hollowFactorF, 0.0f, 0.0f); } else { IMM = new Vertex(-0.5f * hollowFactorF, -0.5f * hollowFactorF, 0.0f); IPM = new Vertex(+0.5f * hollowFactorF, -0.5f * hollowFactorF, 0.0f); IPP = new Vertex(+0.5f * hollowFactorF, +0.5f * hollowFactorF, 0.0f); IMP = new Vertex(-0.5f * hollowFactorF, +0.5f * hollowFactorF, 0.0f); } holeHull = new SimpleHull(); holeHull.AddVertex(IMM); holeHull.AddVertex(IMP); holeHull.AddVertex(IPP); holeHull.AddVertex(IPM); } if (hshape == HollowShape.Circle && pbs.PathCurve == (byte)Extrusion.Straight) { float hollowFactorF = (float)fhollowFactor / (float)50000; //Vertex IQ1Q15 = new Vertex(-0.35f * hollowFactorF, -0.35f * hollowFactorF, 0.0f); //Vertex IQ1Q16 = new Vertex(-0.30f * hollowFactorF, -0.40f * hollowFactorF, 0.0f); //Vertex IQ1Q17 = new Vertex(-0.24f * hollowFactorF, -0.43f * hollowFactorF, 0.0f); //Vertex IQ1Q18 = new Vertex(-0.18f * hollowFactorF, -0.46f * hollowFactorF, 0.0f); //Vertex IQ1Q19 = new Vertex(-0.11f * hollowFactorF, -0.48f * hollowFactorF, 0.0f); //Vertex IQ2Q10 = new Vertex(+0.0f * hollowFactorF, -0.50f * hollowFactorF, 0.0f); //Vertex IQ2Q11 = new Vertex(+0.11f * hollowFactorF, -0.48f * hollowFactorF, 0.0f); //Vertex IQ2Q12 = new Vertex(+0.18f * hollowFactorF, -0.46f * hollowFactorF, 0.0f); //Vertex IQ2Q13 = new Vertex(+0.24f * hollowFactorF, -0.43f * hollowFactorF, 0.0f); //Vertex IQ2Q14 = new Vertex(+0.30f * hollowFactorF, -0.40f * hollowFactorF, 0.0f); //Vertex IQ2Q15 = new Vertex(+0.35f * hollowFactorF, -0.35f * hollowFactorF, 0.0f); //Vertex IQ2Q16 = new Vertex(+0.40f * hollowFactorF, -0.30f * hollowFactorF, 0.0f); //Vertex IQ2Q17 = new Vertex(+0.43f * hollowFactorF, -0.24f * hollowFactorF, 0.0f); //Vertex IQ2Q18 = new Vertex(+0.46f * hollowFactorF, -0.18f * hollowFactorF, 0.0f); //Vertex IQ2Q19 = new Vertex(+0.48f * hollowFactorF, -0.11f * hollowFactorF, 0.0f); //Vertex IQ2Q20 = new Vertex(+0.50f * hollowFactorF, +0.0f * hollowFactorF, 0.0f); //Vertex IQ2Q21 = new Vertex(+0.48f * hollowFactorF, +0.11f * hollowFactorF, 0.0f); //Vertex IQ2Q22 = new Vertex(+0.46f * hollowFactorF, +0.18f * hollowFactorF, 0.0f); //Vertex IQ2Q23 = new Vertex(+0.43f * hollowFactorF, +0.24f * hollowFactorF, 0.0f); //Vertex IQ2Q24 = new Vertex(+0.40f * hollowFactorF, +0.30f * hollowFactorF, 0.0f); //Vertex IQ2Q25 = new Vertex(+0.35f * hollowFactorF, +0.35f * hollowFactorF, 0.0f); //Vertex IQ2Q26 = new Vertex(+0.30f * hollowFactorF, +0.40f * hollowFactorF, 0.0f); //Vertex IQ2Q27 = new Vertex(+0.24f * hollowFactorF, +0.43f * hollowFactorF, 0.0f); //Vertex IQ2Q28 = new Vertex(+0.18f * hollowFactorF, +0.46f * hollowFactorF, 0.0f); //Vertex IQ2Q29 = new Vertex(+0.11f * hollowFactorF, +0.48f * hollowFactorF, 0.0f); //Vertex IQ1Q20 = new Vertex(+0.0f * hollowFactorF, +0.50f * hollowFactorF, 0.0f); //Vertex IQ1Q21 = new Vertex(-0.11f * hollowFactorF, +0.48f * hollowFactorF, 0.0f); //Vertex IQ1Q22 = new Vertex(-0.18f * hollowFactorF, +0.46f * hollowFactorF, 0.0f); //Vertex IQ1Q23 = new Vertex(-0.24f * hollowFactorF, +0.43f * hollowFactorF, 0.0f); //Vertex IQ1Q24 = new Vertex(-0.30f * hollowFactorF, +0.40f * hollowFactorF, 0.0f); //Vertex IQ1Q25 = new Vertex(-0.35f * hollowFactorF, +0.35f * hollowFactorF, 0.0f); //Vertex IQ1Q26 = new Vertex(-0.40f * hollowFactorF, +0.30f * hollowFactorF, 0.0f); //Vertex IQ1Q27 = new Vertex(-0.43f * hollowFactorF, +0.24f * hollowFactorF, 0.0f); //Vertex IQ1Q28 = new Vertex(-0.46f * hollowFactorF, +0.18f * hollowFactorF, 0.0f); //Vertex IQ1Q29 = new Vertex(-0.48f * hollowFactorF, +0.11f * hollowFactorF, 0.0f); //Vertex IQ1Q10 = new Vertex(-0.50f * hollowFactorF, +0.0f * hollowFactorF, 0.0f); //Vertex IQ1Q11 = new Vertex(-0.48f * hollowFactorF, -0.11f * hollowFactorF, 0.0f); //Vertex IQ1Q12 = new Vertex(-0.46f * hollowFactorF, -0.18f * hollowFactorF, 0.0f); //Vertex IQ1Q13 = new Vertex(-0.43f * hollowFactorF, -0.24f * hollowFactorF, 0.0f); //Vertex IQ1Q14 = new Vertex(-0.40f * hollowFactorF, -0.30f * hollowFactorF, 0.0f); //Counter clockwise around the quadrants holeHull = new SimpleHull(); //holeHull.AddVertex(IQ1Q15); //holeHull.AddVertex(IQ1Q14); //holeHull.AddVertex(IQ1Q13); //holeHull.AddVertex(IQ1Q12); //holeHull.AddVertex(IQ1Q11); //holeHull.AddVertex(IQ1Q10); //holeHull.AddVertex(IQ1Q29); //holeHull.AddVertex(IQ1Q28); //holeHull.AddVertex(IQ1Q27); //holeHull.AddVertex(IQ1Q26); //holeHull.AddVertex(IQ1Q25); //holeHull.AddVertex(IQ1Q24); //holeHull.AddVertex(IQ1Q23); //holeHull.AddVertex(IQ1Q22); //holeHull.AddVertex(IQ1Q21); //holeHull.AddVertex(IQ1Q20); //holeHull.AddVertex(IQ2Q29); //holeHull.AddVertex(IQ2Q28); //holeHull.AddVertex(IQ2Q27); //holeHull.AddVertex(IQ2Q26); //holeHull.AddVertex(IQ2Q25); //holeHull.AddVertex(IQ2Q24); //holeHull.AddVertex(IQ2Q23); //holeHull.AddVertex(IQ2Q22); //holeHull.AddVertex(IQ2Q21); //holeHull.AddVertex(IQ2Q20); //holeHull.AddVertex(IQ2Q19); //holeHull.AddVertex(IQ2Q18); //holeHull.AddVertex(IQ2Q17); //holeHull.AddVertex(IQ2Q16); //holeHull.AddVertex(IQ2Q15); //holeHull.AddVertex(IQ2Q14); //holeHull.AddVertex(IQ2Q13); //holeHull.AddVertex(IQ2Q12); //holeHull.AddVertex(IQ2Q11); //holeHull.AddVertex(IQ2Q10); //holeHull.AddVertex(IQ1Q19); //holeHull.AddVertex(IQ1Q18); //holeHull.AddVertex(IQ1Q17); //holeHull.AddVertex(IQ1Q16); holeHull.AddVertex(new Vertex(0.353553f * hollowFactorF, 0.353553f * hollowFactorF, 0.0f)); // 45 degrees holeHull.AddVertex(new Vertex(0.433013f * hollowFactorF, 0.250000f * hollowFactorF, 0.0f)); // 30 degrees holeHull.AddVertex(new Vertex(0.482963f * hollowFactorF, 0.129410f * hollowFactorF, 0.0f)); // 15 degrees holeHull.AddVertex(new Vertex(0.500000f * hollowFactorF, 0.000000f * hollowFactorF, 0.0f)); // 0 degrees holeHull.AddVertex(new Vertex(0.482963f * hollowFactorF, -0.129410f * hollowFactorF, 0.0f)); // 345 degrees holeHull.AddVertex(new Vertex(0.433013f * hollowFactorF, -0.250000f * hollowFactorF, 0.0f)); // 330 degrees holeHull.AddVertex(new Vertex(0.353553f * hollowFactorF, -0.353553f * hollowFactorF, 0.0f)); // 315 degrees holeHull.AddVertex(new Vertex(0.250000f * hollowFactorF, -0.433013f * hollowFactorF, 0.0f)); // 300 degrees holeHull.AddVertex(new Vertex(0.129410f * hollowFactorF, -0.482963f * hollowFactorF, 0.0f)); // 285 degrees holeHull.AddVertex(new Vertex(0.000000f * hollowFactorF, -0.500000f * hollowFactorF, 0.0f)); // 270 degrees holeHull.AddVertex(new Vertex(-0.129410f * hollowFactorF, -0.482963f * hollowFactorF, 0.0f)); // 255 degrees holeHull.AddVertex(new Vertex(-0.250000f * hollowFactorF, -0.433013f * hollowFactorF, 0.0f)); // 240 degrees holeHull.AddVertex(new Vertex(-0.353553f * hollowFactorF, -0.353553f * hollowFactorF, 0.0f)); // 225 degrees holeHull.AddVertex(new Vertex(-0.433013f * hollowFactorF, -0.250000f * hollowFactorF, 0.0f)); // 210 degrees holeHull.AddVertex(new Vertex(-0.482963f * hollowFactorF, -0.129410f * hollowFactorF, 0.0f)); // 195 degrees holeHull.AddVertex(new Vertex(-0.500000f * hollowFactorF, 0.000000f * hollowFactorF, 0.0f)); // 180 degrees holeHull.AddVertex(new Vertex(-0.482963f * hollowFactorF, 0.129410f * hollowFactorF, 0.0f)); // 165 degrees holeHull.AddVertex(new Vertex(-0.433013f * hollowFactorF, 0.250000f * hollowFactorF, 0.0f)); // 150 degrees holeHull.AddVertex(new Vertex(-0.353553f * hollowFactorF, 0.353553f * hollowFactorF, 0.0f)); // 135 degrees holeHull.AddVertex(new Vertex(-0.250000f * hollowFactorF, 0.433013f * hollowFactorF, 0.0f)); // 120 degrees holeHull.AddVertex(new Vertex(-0.129410f * hollowFactorF, 0.482963f * hollowFactorF, 0.0f)); // 105 degrees holeHull.AddVertex(new Vertex(0.000000f * hollowFactorF, 0.500000f * hollowFactorF, 0.0f)); // 90 degrees holeHull.AddVertex(new Vertex(0.129410f * hollowFactorF, 0.482963f * hollowFactorF, 0.0f)); // 75 degrees holeHull.AddVertex(new Vertex(0.250000f * hollowFactorF, 0.433013f * hollowFactorF, 0.0f)); // 60 degrees holeHull.AddVertex(new Vertex(0.353553f * hollowFactorF, 0.353553f * hollowFactorF, 0.0f)); // 45 degrees } if (hshape == HollowShape.Triangle) { float hollowFactorF = (float)fhollowFactor / (float)50000; Vertex IMM; Vertex IPM; Vertex IPP; if (pshape == ProfileShape.Square) { // corner points are at 345, 105, and 225 degrees for the triangle within a box //IMM = new Vertex(((float)Math.Cos(345.0 * DEG_TO_RAD) * 0.5f) * hollowFactorF, ((float)Math.Sin(345.0 * DEG_TO_RAD) * 0.5f) * hollowFactorF, 0.0f); //IPM = new Vertex(((float)Math.Cos(105.0 * DEG_TO_RAD) * 0.5f) * hollowFactorF, ((float)Math.Sin(105.0 * DEG_TO_RAD) * 0.5f) * hollowFactorF, 0.0f); //IPP = new Vertex(((float)Math.Cos(225.0 * DEG_TO_RAD) * 0.5f) * hollowFactorF, ((float)Math.Sin(225.0 * DEG_TO_RAD) * 0.5f) * hollowFactorF, 0.0f); // hard coded here for speed, the equations are in the commented out lines above IMM = new Vertex(0.48296f * hollowFactorF, -0.12941f * hollowFactorF, 0.0f); IPM = new Vertex(-0.12941f * hollowFactorF, 0.48296f * hollowFactorF, 0.0f); IPP = new Vertex(-0.35355f * hollowFactorF, -0.35355f * hollowFactorF, 0.0f); } else { IMM = new Vertex(-0.25f * hollowFactorF, -0.45f * hollowFactorF, 0.0f); IPM = new Vertex(+0.5f * hollowFactorF, +0f * hollowFactorF, 0.0f); IPP = new Vertex(-0.25f * hollowFactorF, +0.45f * hollowFactorF, 0.0f); } holeHull = new SimpleHull(); holeHull.AddVertex(IMM); holeHull.AddVertex(IPP); holeHull.AddVertex(IPM); } return holeHull; } private static Mesh CreateBoxMesh(String primName, PrimitiveBaseShape primShape, PhysicsVector size) // Builds the z (+ and -) surfaces of a box shaped prim { UInt16 hollowFactor = primShape.ProfileHollow; UInt16 profileBegin = primShape.ProfileBegin; UInt16 profileEnd = primShape.ProfileEnd; UInt16 taperX = primShape.PathScaleX; UInt16 taperY = primShape.PathScaleY; UInt16 pathShearX = primShape.PathShearX; UInt16 pathShearY = primShape.PathShearY; Int16 twistTop = primShape.PathTwistBegin; Int16 twistBot = primShape.PathTwist; //m_log.Error("pathShear:" + primShape.PathShearX.ToString() + "," + primShape.PathShearY.ToString()); //m_log.Error("pathTaper:" + primShape.PathTaperX.ToString() + "," + primShape.PathTaperY.ToString()); //m_log.Error("ProfileBegin:" + primShape.ProfileBegin.ToString() + "," + primShape.ProfileBegin.ToString()); //m_log.Error("PathScale:" + primShape.PathScaleX.ToString() + "," + primShape.PathScaleY.ToString()); // Procedure: This is based on the fact that the upper (plus) and lower (minus) Z-surface // of a block are basically the same // They may be warped differently but the shape is identical // So we only create one surface as a model and derive both plus and minus surface of the block from it // This is done in a model space where the block spans from -.5 to +.5 in X and Y // The mapping to Scene space is done later during the "extrusion" phase // Base Vertex MM = new Vertex(-0.5f, -0.5f, 0.0f); Vertex PM = new Vertex(+0.5f, -0.5f, 0.0f); Vertex PP = new Vertex(+0.5f, +0.5f, 0.0f); Vertex MP = new Vertex(-0.5f, +0.5f, 0.0f); SimpleHull outerHull = new SimpleHull(); //outerHull.AddVertex(MM); //outerHull.AddVertex(PM); //outerHull.AddVertex(PP); //outerHull.AddVertex(MP); outerHull.AddVertex(PP); outerHull.AddVertex(MP); outerHull.AddVertex(MM); outerHull.AddVertex(PM); // Deal with cuts now if ((profileBegin != 0) || (profileEnd != 0)) { double fProfileBeginAngle = profileBegin/50000.0*360.0; // In degree, for easier debugging and understanding fProfileBeginAngle -= (90.0 + 45.0); // for some reasons, the SL client counts from the corner -X/-Y double fProfileEndAngle = 360.0 - profileEnd/50000.0*360.0; // Pathend comes as complement to 1.0 fProfileEndAngle -= (90.0 + 45.0); if (fProfileBeginAngle < fProfileEndAngle) fProfileEndAngle -= 360.0; // Note, that we don't want to cut out a triangle, even if this is a // good approximation for small cuts. Indeed we want to cut out an arc // and we approximate this arc by a polygon chain // Also note, that these vectors are of length 1.0 and thus their endpoints lay outside the model space // So it can easily be subtracted from the outer hull int iSteps = (int) (((fProfileBeginAngle - fProfileEndAngle)/45.0) + .5); // how many steps do we need with approximately 45 degree double dStepWidth = (fProfileBeginAngle - fProfileEndAngle)/iSteps; Vertex origin = new Vertex(0.0f, 0.0f, 0.0f); // Note the sequence of vertices here. It's important to have the other rotational sense than in outerHull SimpleHull cutHull = new SimpleHull(); cutHull.AddVertex(origin); for (int i = 0; i < iSteps; i++) { double angle = fProfileBeginAngle - i*dStepWidth; // we count against the angle orientation!!!! Vertex v = Vertex.FromAngle(angle*Math.PI/180.0); cutHull.AddVertex(v); } Vertex legEnd = Vertex.FromAngle(fProfileEndAngle*Math.PI/180.0); // Calculated separately to avoid errors cutHull.AddVertex(legEnd); //m_log.DebugFormat("Starting cutting of the hollow shape from the prim {1}", 0, primName); SimpleHull cuttedHull = SimpleHull.SubtractHull(outerHull, cutHull); outerHull = cuttedHull; } // Deal with the hole here if (hollowFactor > 0) { SimpleHull holeHull = BuildHoleHull(primShape, primShape.ProfileShape, primShape.HollowShape, hollowFactor); if (holeHull != null) { SimpleHull hollowedHull = SimpleHull.SubtractHull(outerHull, holeHull); outerHull = hollowedHull; } } Mesh m = new Mesh(); Vertex Seed1 = new Vertex(0.0f, -10.0f, 0.0f); Vertex Seed2 = new Vertex(-10.0f, 10.0f, 0.0f); Vertex Seed3 = new Vertex(10.0f, 10.0f, 0.0f); m.Add(Seed1); m.Add(Seed2); m.Add(Seed3); m.Add(new Triangle(Seed1, Seed2, Seed3)); m.Add(outerHull.getVertices()); InsertVertices(m.vertices, 3, m.triangles); m.DumpRaw(baseDir, primName, "Proto first Mesh"); m.Remove(Seed1); m.Remove(Seed2); m.Remove(Seed3); m.DumpRaw(baseDir, primName, "Proto seeds removed"); m.RemoveTrianglesOutside(outerHull); m.DumpRaw(baseDir, primName, "Proto outsides removed"); foreach (Triangle t in m.triangles) { PhysicsVector n = t.getNormal(); if (n.Z < 0.0) t.invertNormal(); } Extruder extr = new Extruder(); extr.size = size; if (taperX != 100) { if (taperX > 100) { extr.taperTopFactorX = 1.0f - ((float)taperX / 200); //m_log.Warn("taperTopFactorX: " + extr.taperTopFactorX.ToString()); } else { extr.taperBotFactorX = 1.0f - ((100 - (float)taperX) / 100); //m_log.Warn("taperBotFactorX: " + extr.taperBotFactorX.ToString()); } } if (taperY != 100) { if (taperY > 100) { extr.taperTopFactorY = 1.0f - ((float)taperY / 200); //m_log.Warn("taperTopFactorY: " + extr.taperTopFactorY.ToString()); } else { extr.taperBotFactorY = 1.0f - ((100 - (float)taperY) / 100); //m_log.Warn("taperBotFactorY: " + extr.taperBotFactorY.ToString()); } } if (pathShearX != 0) { if (pathShearX > 50) { // Complimentary byte. Negative values wrap around the byte. Positive values go up to 50 extr.pushX = (((float)(256 - pathShearX) / 100) * -1f); // m_log.Warn("pushX: " + extr.pushX); } else { extr.pushX = (float)pathShearX / 100; // m_log.Warn("pushX: " + extr.pushX); } } if (pathShearY != 0) { if (pathShearY > 50) { // Complimentary byte. Negative values wrap around the byte. Positive values go up to 50 extr.pushY = (((float)(256 - pathShearY) / 100) * -1f); //m_log.Warn("pushY: " + extr.pushY); } else { extr.pushY = (float)pathShearY / 100; //m_log.Warn("pushY: " + extr.pushY); } } if (twistTop != 0) { extr.twistTop = 180 * ((float)twistTop / 100); if (extr.twistTop > 0) { extr.twistTop = 360 - (-1 * extr.twistTop); } extr.twistTop = (float)(extr.twistTop * DEG_TO_RAD); } float twistMid = ((twistTop + twistBot) * 0.5f); if (twistMid != 0) { extr.twistMid = 180 * ((float)twistMid / 100); if (extr.twistMid > 0) { extr.twistMid = 360 - (-1 * extr.twistMid); } extr.twistMid = (float)(extr.twistMid * DEG_TO_RAD); } if (twistBot != 0) { extr.twistBot = 180 * ((float)twistBot / 100); if (extr.twistBot > 0) { extr.twistBot = 360 - (-1 * extr.twistBot); } extr.twistBot = (float)(extr.twistBot * DEG_TO_RAD); } Mesh result = extr.Extrude(m); result.DumpRaw(baseDir, primName, "Z extruded"); return result; } private static Mesh CreateCyllinderMesh(String primName, PrimitiveBaseShape primShape, PhysicsVector size) // Builds the z (+ and -) surfaces of a box shaped prim { UInt16 hollowFactor = primShape.ProfileHollow; UInt16 profileBegin = primShape.ProfileBegin; UInt16 profileEnd = primShape.ProfileEnd; UInt16 taperX = primShape.PathScaleX; UInt16 taperY = primShape.PathScaleY; UInt16 pathShearX = primShape.PathShearX; UInt16 pathShearY = primShape.PathShearY; Int16 twistBot = primShape.PathTwist; Int16 twistTop = primShape.PathTwistBegin; // Procedure: This is based on the fact that the upper (plus) and lower (minus) Z-surface // of a block are basically the same // They may be warped differently but the shape is identical // So we only create one surface as a model and derive both plus and minus surface of the block from it // This is done in a model space where the block spans from -.5 to +.5 in X and Y // The mapping to Scene space is done later during the "extrusion" phase // Base // Q1Q15 = Quadrant 1, Quadrant1, Vertex 5 //Vertex Q1Q15 = new Vertex(-0.35f, -0.35f, 0.0f); //Vertex Q1Q16 = new Vertex(-0.30f, -0.40f, 0.0f); //Vertex Q1Q17 = new Vertex(-0.24f, -0.43f, 0.0f); //Vertex Q1Q18 = new Vertex(-0.18f, -0.46f, 0.0f); //Vertex Q1Q19 = new Vertex(-0.11f, -0.48f, 0.0f); //Vertex Q2Q10 = new Vertex(+0.0f, -0.50f, 0.0f); //Vertex Q2Q11 = new Vertex(+0.11f, -0.48f, 0.0f); //Vertex Q2Q12 = new Vertex(+0.18f, -0.46f, 0.0f); //Vertex Q2Q13 = new Vertex(+0.24f, -0.43f, 0.0f); //Vertex Q2Q14 = new Vertex(+0.30f, -0.40f, 0.0f); //Vertex Q2Q15 = new Vertex(+0.35f, -0.35f, 0.0f); //Vertex Q2Q16 = new Vertex(+0.40f, -0.30f, 0.0f); //Vertex Q2Q17 = new Vertex(+0.43f, -0.24f, 0.0f); //Vertex Q2Q18 = new Vertex(+0.46f, -0.18f, 0.0f); //Vertex Q2Q19 = new Vertex(+0.48f, -0.11f, 0.0f); //Vertex Q2Q20 = new Vertex(+0.50f, +0.0f, 0.0f); //Vertex Q2Q21 = new Vertex(+0.48f, +0.11f, 0.0f); //Vertex Q2Q22 = new Vertex(+0.46f, +0.18f, 0.0f); //Vertex Q2Q23 = new Vertex(+0.43f, +0.24f, 0.0f); //Vertex Q2Q24 = new Vertex(+0.40f, +0.30f, 0.0f); //Vertex Q2Q25 = new Vertex(+0.35f, +0.35f, 0.0f); //Vertex Q2Q26 = new Vertex(+0.30f, +0.40f, 0.0f); //Vertex Q2Q27 = new Vertex(+0.24f, +0.43f, 0.0f); //Vertex Q2Q28 = new Vertex(+0.18f, +0.46f, 0.0f); //Vertex Q2Q29 = new Vertex(+0.11f, +0.48f, 0.0f); //Vertex Q1Q20 = new Vertex(+0.0f, +0.50f, 0.0f); //Vertex Q1Q21 = new Vertex(-0.11f, +0.48f, 0.0f); //Vertex Q1Q22 = new Vertex(-0.18f, +0.46f, 0.0f); //Vertex Q1Q23 = new Vertex(-0.24f, +0.43f, 0.0f); //Vertex Q1Q24 = new Vertex(-0.30f, +0.40f, 0.0f); //Vertex Q1Q25 = new Vertex(-0.35f, +0.35f, 0.0f); //Vertex Q1Q26 = new Vertex(-0.40f, +0.30f, 0.0f); //Vertex Q1Q27 = new Vertex(-0.43f, +0.24f, 0.0f); //Vertex Q1Q28 = new Vertex(-0.46f, +0.18f, 0.0f); //Vertex Q1Q29 = new Vertex(-0.48f, +0.11f, 0.0f); //Vertex Q1Q10 = new Vertex(-0.50f, +0.0f, 0.0f); //Vertex Q1Q11 = new Vertex(-0.48f, -0.11f, 0.0f); //Vertex Q1Q12 = new Vertex(-0.46f, -0.18f, 0.0f); //Vertex Q1Q13 = new Vertex(-0.43f, -0.24f, 0.0f); //Vertex Q1Q14 = new Vertex(-0.40f, -0.30f, 0.0f); SimpleHull outerHull = new SimpleHull(); //Clockwise around the quadrants //outerHull.AddVertex(Q1Q15); //outerHull.AddVertex(Q1Q16); //outerHull.AddVertex(Q1Q17); //outerHull.AddVertex(Q1Q18); //outerHull.AddVertex(Q1Q19); //outerHull.AddVertex(Q2Q10); //outerHull.AddVertex(Q2Q11); //outerHull.AddVertex(Q2Q12); //outerHull.AddVertex(Q2Q13); //outerHull.AddVertex(Q2Q14); //outerHull.AddVertex(Q2Q15); //outerHull.AddVertex(Q2Q16); //outerHull.AddVertex(Q2Q17); //outerHull.AddVertex(Q2Q18); //outerHull.AddVertex(Q2Q19); //outerHull.AddVertex(Q2Q20); //outerHull.AddVertex(Q2Q21); //outerHull.AddVertex(Q2Q22); //outerHull.AddVertex(Q2Q23); //outerHull.AddVertex(Q2Q24); //outerHull.AddVertex(Q2Q25); //outerHull.AddVertex(Q2Q26); //outerHull.AddVertex(Q2Q27); //outerHull.AddVertex(Q2Q28); //outerHull.AddVertex(Q2Q29); //outerHull.AddVertex(Q1Q20); //outerHull.AddVertex(Q1Q21); //outerHull.AddVertex(Q1Q22); //outerHull.AddVertex(Q1Q23); //outerHull.AddVertex(Q1Q24); //outerHull.AddVertex(Q1Q25); //outerHull.AddVertex(Q1Q26); //outerHull.AddVertex(Q1Q27); //outerHull.AddVertex(Q1Q28); //outerHull.AddVertex(Q1Q29); //outerHull.AddVertex(Q1Q10); //outerHull.AddVertex(Q1Q11); //outerHull.AddVertex(Q1Q12); //outerHull.AddVertex(Q1Q13); //outerHull.AddVertex(Q1Q14); // counter-clockwise around the quadrants, start at 45 degrees outerHull.AddVertex(new Vertex(0.353553f, 0.353553f, 0.0f)); // 45 degrees outerHull.AddVertex(new Vertex(0.250000f, 0.433013f, 0.0f)); // 60 degrees outerHull.AddVertex(new Vertex(0.129410f, 0.482963f, 0.0f)); // 75 degrees outerHull.AddVertex(new Vertex(0.000000f, 0.500000f, 0.0f)); // 90 degrees outerHull.AddVertex(new Vertex(-0.129410f, 0.482963f, 0.0f)); // 105 degrees outerHull.AddVertex(new Vertex(-0.250000f, 0.433013f, 0.0f)); // 120 degrees outerHull.AddVertex(new Vertex(-0.353553f, 0.353553f, 0.0f)); // 135 degrees outerHull.AddVertex(new Vertex(-0.433013f, 0.250000f, 0.0f)); // 150 degrees outerHull.AddVertex(new Vertex(-0.482963f, 0.129410f, 0.0f)); // 165 degrees outerHull.AddVertex(new Vertex(-0.500000f, 0.000000f, 0.0f)); // 180 degrees outerHull.AddVertex(new Vertex(-0.482963f, -0.129410f, 0.0f)); // 195 degrees outerHull.AddVertex(new Vertex(-0.433013f, -0.250000f, 0.0f)); // 210 degrees outerHull.AddVertex(new Vertex(-0.353553f, -0.353553f, 0.0f)); // 225 degrees outerHull.AddVertex(new Vertex(-0.250000f, -0.433013f, 0.0f)); // 240 degrees outerHull.AddVertex(new Vertex(-0.129410f, -0.482963f, 0.0f)); // 255 degrees outerHull.AddVertex(new Vertex(0.000000f, -0.500000f, 0.0f)); // 270 degrees outerHull.AddVertex(new Vertex(0.129410f, -0.482963f, 0.0f)); // 285 degrees outerHull.AddVertex(new Vertex(0.250000f, -0.433013f, 0.0f)); // 300 degrees outerHull.AddVertex(new Vertex(0.353553f, -0.353553f, 0.0f)); // 315 degrees outerHull.AddVertex(new Vertex(0.433013f, -0.250000f, 0.0f)); // 330 degrees outerHull.AddVertex(new Vertex(0.482963f, -0.129410f, 0.0f)); // 345 degrees outerHull.AddVertex(new Vertex(0.500000f, 0.000000f, 0.0f)); // 0 degrees outerHull.AddVertex(new Vertex(0.482963f, 0.129410f, 0.0f)); // 15 degrees outerHull.AddVertex(new Vertex(0.433013f, 0.250000f, 0.0f)); // 30 degrees // Deal with cuts now if ((profileBegin != 0) || (profileEnd != 0)) { double fProfileBeginAngle = profileBegin / 50000.0 * 360.0; // In degree, for easier debugging and understanding //fProfileBeginAngle -= (90.0 + 45.0); // for some reasons, the SL client counts from the corner -X/-Y double fProfileEndAngle = 360.0 - profileEnd / 50000.0 * 360.0; // Pathend comes as complement to 1.0 //fProfileEndAngle -= (90.0 + 45.0); if (fProfileBeginAngle < fProfileEndAngle) fProfileEndAngle -= 360.0; // Note, that we don't want to cut out a triangle, even if this is a // good approximation for small cuts. Indeed we want to cut out an arc // and we approximate this arc by a polygon chain // Also note, that these vectors are of length 1.0 and thus their endpoints lay outside the model space // So it can easily be subtracted from the outer hull int iSteps = (int)(((fProfileBeginAngle - fProfileEndAngle) / 45.0) + .5); // how many steps do we need with approximately 45 degree double dStepWidth = (fProfileBeginAngle - fProfileEndAngle) / iSteps; Vertex origin = new Vertex(0.0f, 0.0f, 0.0f); // Note the sequence of vertices here. It's important to have the other rotational sense than in outerHull SimpleHull cutHull = new SimpleHull(); cutHull.AddVertex(origin); for (int i = 0; i < iSteps; i++) { double angle = fProfileBeginAngle - i * dStepWidth; // we count against the angle orientation!!!! Vertex v = Vertex.FromAngle(angle * Math.PI / 180.0); cutHull.AddVertex(v); } Vertex legEnd = Vertex.FromAngle(fProfileEndAngle * Math.PI / 180.0); // Calculated separately to avoid errors cutHull.AddVertex(legEnd); // m_log.DebugFormat("Starting cutting of the hollow shape from the prim {1}", 0, primName); SimpleHull cuttedHull = SimpleHull.SubtractHull(outerHull, cutHull); outerHull = cuttedHull; } // Deal with the hole here if (hollowFactor > 0) { SimpleHull holeHull = BuildHoleHull(primShape, primShape.ProfileShape, primShape.HollowShape, hollowFactor); if (holeHull != null) { SimpleHull hollowedHull = SimpleHull.SubtractHull(outerHull, holeHull); outerHull = hollowedHull; } } Mesh m = new Mesh(); Vertex Seed1 = new Vertex(0.0f, -10.0f, 0.0f); Vertex Seed2 = new Vertex(-10.0f, 10.0f, 0.0f); Vertex Seed3 = new Vertex(10.0f, 10.0f, 0.0f); m.Add(Seed1); m.Add(Seed2); m.Add(Seed3); m.Add(new Triangle(Seed1, Seed2, Seed3)); m.Add(outerHull.getVertices()); InsertVertices(m.vertices, 3, m.triangles); m.DumpRaw(baseDir, primName, "Proto first Mesh"); m.Remove(Seed1); m.Remove(Seed2); m.Remove(Seed3); m.DumpRaw(baseDir, primName, "Proto seeds removed"); m.RemoveTrianglesOutside(outerHull); m.DumpRaw(baseDir, primName, "Proto outsides removed"); foreach (Triangle t in m.triangles) { PhysicsVector n = t.getNormal(); if (n.Z < 0.0) t.invertNormal(); } Extruder extr = new Extruder(); extr.size = size; //System.Console.WriteLine("taperFactorX: " + taperX.ToString()); //System.Console.WriteLine("taperFactorY: " + taperY.ToString()); if (taperX != 100) { if (taperX > 100) { extr.taperTopFactorX = 1.0f - ((float)(taperX - 100) / 100); //System.Console.WriteLine("taperTopFactorX: " + extr.taperTopFactorX.ToString()); } else { extr.taperBotFactorX = 1.0f - ((100 - (float)taperX) / 100); //System.Console.WriteLine("taperBotFactorX: " + extr.taperBotFactorX.ToString()); } } if (taperY != 100) { if (taperY > 100) { extr.taperTopFactorY = 1.0f - ((float)(taperY - 100) / 200); // System.Console.WriteLine("taperTopFactorY: " + extr.taperTopFactorY.ToString()); } else { extr.taperBotFactorY = 1.0f - ((100 - (float)taperY) / 100); //System.Console.WriteLine("taperBotFactorY: " + extr.taperBotFactorY.ToString()); } } if (pathShearX != 0) { if (pathShearX > 50) { // Complimentary byte. Negative values wrap around the byte. Positive values go up to 50 extr.pushX = (((float)(256 - pathShearX) / 100) * -1f); //m_log.Warn("pushX: " + extr.pushX); } else { extr.pushX = (float)pathShearX / 100; //m_log.Warn("pushX: " + extr.pushX); } } if (pathShearY != 0) { if (pathShearY > 50) { // Complimentary byte. Negative values wrap around the byte. Positive values go up to 50 extr.pushY = (((float)(256 - pathShearY) / 100) * -1f); //m_log.Warn("pushY: " + extr.pushY); } else { extr.pushY = (float)pathShearY / 100; //m_log.Warn("pushY: " + extr.pushY); } } if (twistTop != 0) { extr.twistTop = 180 * ((float)twistTop / 100); if (extr.twistTop > 0) { extr.twistTop = 360 - (-1 * extr.twistTop); } extr.twistTop = (float)(extr.twistTop * DEG_TO_RAD); } float twistMid = ((twistTop + twistBot) * 0.5f); if (twistMid != 0) { extr.twistMid = 180 * ((float)twistMid / 100); if (extr.twistMid > 0) { extr.twistMid = 360 - (-1 * extr.twistMid); } extr.twistMid = (float)(extr.twistMid * DEG_TO_RAD); } if (twistBot != 0) { extr.twistBot = 180 * ((float)twistBot / 100); if (extr.twistBot > 0) { extr.twistBot = 360 - (-1 * extr.twistBot); } extr.twistBot = (float)(extr.twistBot * DEG_TO_RAD); } //System.Console.WriteLine("[MESH]: twistTop = " + twistTop.ToString() + "|" + extr.twistTop.ToString() + ", twistMid = " + twistMid.ToString() + "|" + extr.twistMid.ToString() + ", twistbot = " + twistBot.ToString() + "|" + extr.twistBot.ToString()); Mesh result = extr.Extrude(m); result.DumpRaw(baseDir, primName, "Z extruded"); return result; } private static Mesh CreatePrismMesh(String primName, PrimitiveBaseShape primShape, PhysicsVector size) // Builds the z (+ and -) surfaces of a box shaped prim { UInt16 hollowFactor = primShape.ProfileHollow; UInt16 profileBegin = primShape.ProfileBegin; UInt16 profileEnd = primShape.ProfileEnd; UInt16 taperX = primShape.PathScaleX; UInt16 taperY = primShape.PathScaleY; UInt16 pathShearX = primShape.PathShearX; UInt16 pathShearY = primShape.PathShearY; Int16 twistTop = primShape.PathTwistBegin; Int16 twistBot = primShape.PathTwist; //m_log.Error("pathShear:" + primShape.PathShearX.ToString() + "," + primShape.PathShearY.ToString()); //m_log.Error("pathTaper:" + primShape.PathTaperX.ToString() + "," + primShape.PathTaperY.ToString()); //m_log.Error("ProfileBegin:" + primShape.ProfileBegin.ToString() + "," + primShape.ProfileBegin.ToString()); //m_log.Error("PathScale:" + primShape.PathScaleX.ToString() + "," + primShape.PathScaleY.ToString()); // Procedure: This is based on the fact that the upper (plus) and lower (minus) Z-surface // of a block are basically the same // They may be warped differently but the shape is identical // So we only create one surface as a model and derive both plus and minus surface of the block from it // This is done in a model space where the block spans from -.5 to +.5 in X and Y // The mapping to Scene space is done later during the "extrusion" phase // Base Vertex MM = new Vertex(-0.25f, -0.45f, 0.0f); Vertex PM = new Vertex(+0.5f, 0f, 0.0f); Vertex PP = new Vertex(-0.25f, +0.45f, 0.0f); SimpleHull outerHull = new SimpleHull(); //outerHull.AddVertex(MM); //outerHull.AddVertex(PM); //outerHull.AddVertex(PP); outerHull.AddVertex(PP); outerHull.AddVertex(MM); outerHull.AddVertex(PM); // Deal with cuts now if ((profileBegin != 0) || (profileEnd != 0)) { double fProfileBeginAngle = profileBegin / 50000.0 * 360.0; // In degree, for easier debugging and understanding //fProfileBeginAngle -= (90.0 + 45.0); // for some reasons, the SL client counts from the corner -X/-Y double fProfileEndAngle = 360.0 - profileEnd / 50000.0 * 360.0; // Pathend comes as complement to 1.0 //fProfileEndAngle -= (90.0 + 45.0); if (fProfileBeginAngle < fProfileEndAngle) fProfileEndAngle -= 360.0; // Note, that we don't want to cut out a triangle, even if this is a // good approximation for small cuts. Indeed we want to cut out an arc // and we approximate this arc by a polygon chain // Also note, that these vectors are of length 1.0 and thus their endpoints lay outside the model space // So it can easily be subtracted from the outer hull int iSteps = (int)(((fProfileBeginAngle - fProfileEndAngle) / 45.0) + .5); // how many steps do we need with approximately 45 degree double dStepWidth = (fProfileBeginAngle - fProfileEndAngle) / iSteps; Vertex origin = new Vertex(0.0f, 0.0f, 0.0f); // Note the sequence of vertices here. It's important to have the other rotational sense than in outerHull SimpleHull cutHull = new SimpleHull(); cutHull.AddVertex(origin); for (int i = 0; i < iSteps; i++) { double angle = fProfileBeginAngle - i * dStepWidth; // we count against the angle orientation!!!! Vertex v = Vertex.FromAngle(angle * Math.PI / 180.0); cutHull.AddVertex(v); } Vertex legEnd = Vertex.FromAngle(fProfileEndAngle * Math.PI / 180.0); // Calculated separately to avoid errors cutHull.AddVertex(legEnd); //m_log.DebugFormat("Starting cutting of the hollow shape from the prim {1}", 0, primName); SimpleHull cuttedHull = SimpleHull.SubtractHull(outerHull, cutHull); outerHull = cuttedHull; } // Deal with the hole here if (hollowFactor > 0) { SimpleHull holeHull = BuildHoleHull(primShape, primShape.ProfileShape, primShape.HollowShape, hollowFactor); if (holeHull != null) { SimpleHull hollowedHull = SimpleHull.SubtractHull(outerHull, holeHull); outerHull = hollowedHull; } } Mesh m = new Mesh(); Vertex Seed1 = new Vertex(0.0f, -10.0f, 0.0f); Vertex Seed2 = new Vertex(-10.0f, 10.0f, 0.0f); Vertex Seed3 = new Vertex(10.0f, 10.0f, 0.0f); m.Add(Seed1); m.Add(Seed2); m.Add(Seed3); m.Add(new Triangle(Seed1, Seed2, Seed3)); m.Add(outerHull.getVertices()); InsertVertices(m.vertices, 3, m.triangles); m.DumpRaw(baseDir, primName, "Proto first Mesh"); m.Remove(Seed1); m.Remove(Seed2); m.Remove(Seed3); m.DumpRaw(baseDir, primName, "Proto seeds removed"); m.RemoveTrianglesOutside(outerHull); m.DumpRaw(baseDir, primName, "Proto outsides removed"); foreach (Triangle t in m.triangles) { PhysicsVector n = t.getNormal(); if (n.Z < 0.0) t.invertNormal(); } Extruder extr = new Extruder(); extr.size = size; if (taperX != 100) { if (taperX > 100) { extr.taperTopFactorX = 1.0f - ((float)taperX / 200); //System.Console.WriteLine("taperTopFactorX: " + extr.taperTopFactorX.ToString()); } else { extr.taperBotFactorX = 1.0f - ((100 - (float)taperX) / 100); //System.Console.WriteLine("taperBotFactorX: " + extr.taperBotFactorX.ToString()); } } if (taperY != 100) { if (taperY > 100) { extr.taperTopFactorY = 1.0f - ((float)taperY / 200); //System.Console.WriteLine("taperTopFactorY: " + extr.taperTopFactorY.ToString()); } else { extr.taperBotFactorY = 1.0f - ((100 - (float)taperY) / 100); //System.Console.WriteLine("taperBotFactorY: " + extr.taperBotFactorY.ToString()); } } if (pathShearX != 0) { if (pathShearX > 50) { // Complimentary byte. Negative values wrap around the byte. Positive values go up to 50 extr.pushX = (((float)(256 - pathShearX) / 100) * -1f); // m_log.Warn("pushX: " + extr.pushX); } else { extr.pushX = (float)pathShearX / 100; // m_log.Warn("pushX: " + extr.pushX); } } if (pathShearY != 0) { if (pathShearY > 50) { // Complimentary byte. Negative values wrap around the byte. Positive values go up to 50 extr.pushY = (((float)(256 - pathShearY) / 100) * -1f); //m_log.Warn("pushY: " + extr.pushY); } else { extr.pushY = (float)pathShearY / 100; //m_log.Warn("pushY: " + extr.pushY); } } if (twistTop != 0) { extr.twistTop = 180 * ((float)twistTop / 100); if (extr.twistTop > 0) { extr.twistTop = 360 - (-1 * extr.twistTop); } extr.twistTop = (float)(extr.twistTop * DEG_TO_RAD); } float twistMid = ((twistTop + twistBot) * 0.5f); if (twistMid != 0) { extr.twistMid = 180 * ((float)twistMid / 100); if (extr.twistMid > 0) { extr.twistMid = 360 - (-1 * extr.twistMid); } extr.twistMid = (float)(extr.twistMid * DEG_TO_RAD); } if (twistBot != 0) { extr.twistBot = 180 * ((float)twistBot / 100); if (extr.twistBot > 0) { extr.twistBot = 360 - (-1 * extr.twistBot); } extr.twistBot = (float)(extr.twistBot * DEG_TO_RAD); } Mesh result = extr.Extrude(m); result.DumpRaw(baseDir, primName, "Z extruded"); return result; } private static Mesh CreateSphereMesh(String primName, PrimitiveBaseShape primShape, PhysicsVector size) { // Builds an icosahedral geodesic sphere // based on an article by Paul Bourke // http://local.wasp.uwa.edu.au/~pbourke/ // articles: // http://local.wasp.uwa.edu.au/~pbourke/geometry/polygonmesh/ // and // http://local.wasp.uwa.edu.au/~pbourke/geometry/polyhedra/index.html // Still have more to do here. UInt16 hollowFactor = primShape.ProfileHollow; UInt16 profileBegin = primShape.ProfileBegin; UInt16 profileEnd = primShape.ProfileEnd; UInt16 taperX = primShape.PathScaleX; UInt16 taperY = primShape.PathScaleY; UInt16 pathShearX = primShape.PathShearX; UInt16 pathShearY = primShape.PathShearY; Mesh m = new Mesh(); float LOD = 0.2f; float diameter = 0.5f;// Our object will result in -0.5 to 0.5 float sq5 = (float) Math.Sqrt(5.0); float phi = (1 + sq5) * 0.5f; float rat = (float) Math.Sqrt(10f + (2f * sq5)) / (4f * phi); float a = (diameter / rat) * 0.5f; float b = (diameter / rat) / (2.0f * phi); // 12 Icosahedron vertexes Vertex v1 = new Vertex(0f, b, -a); Vertex v2 = new Vertex(b, a, 0f); Vertex v3 = new Vertex(-b, a, 0f); Vertex v4 = new Vertex(0f, b, a); Vertex v5 = new Vertex(0f, -b, a); Vertex v6 = new Vertex(-a, 0f, b); Vertex v7 = new Vertex(0f, -b, -a); Vertex v8 = new Vertex(a, 0f, -b); Vertex v9 = new Vertex(a, 0f, b); Vertex v10 = new Vertex(-a, 0f, -b); Vertex v11 = new Vertex(b, -a, 0); Vertex v12 = new Vertex(-b, -a, 0); // Base Faces of the Icosahedron (20) SphereLODTriangle(v1, v2, v3, diameter, LOD, m); SphereLODTriangle(v4, v3, v2, diameter, LOD, m); SphereLODTriangle(v4, v5, v6, diameter, LOD, m); SphereLODTriangle(v4, v9, v5, diameter, LOD, m); SphereLODTriangle(v1, v7, v8, diameter, LOD, m); SphereLODTriangle(v1, v10, v7, diameter, LOD, m); SphereLODTriangle(v5, v11, v12, diameter, LOD, m); SphereLODTriangle(v7, v12, v11, diameter, LOD, m); SphereLODTriangle(v3, v6, v10, diameter, LOD, m); SphereLODTriangle(v12, v10, v6, diameter, LOD, m); SphereLODTriangle(v2, v8, v9, diameter, LOD, m); SphereLODTriangle(v11, v9, v8, diameter, LOD, m); SphereLODTriangle(v4, v6, v3, diameter, LOD, m); SphereLODTriangle(v4, v2, v9, diameter, LOD, m); SphereLODTriangle(v1, v3, v10, diameter, LOD, m); SphereLODTriangle(v1, v8, v2, diameter, LOD, m); SphereLODTriangle(v7, v10, v12, diameter, LOD, m); SphereLODTriangle(v7, v11, v8, diameter, LOD, m); SphereLODTriangle(v5, v12, v6, diameter, LOD, m); SphereLODTriangle(v5, v9, v11, diameter, LOD, m); // Scale the mesh based on our prim scale foreach (Vertex v in m.vertices) { v.X *= size.X; v.Y *= size.Y; v.Z *= size.Z; } // This was built with the normals pointing inside.. // therefore we have to invert the normals foreach (Triangle t in m.triangles) { t.invertNormal(); } // Dump the faces for visualization in blender. m.DumpRaw(baseDir, primName, "Icosahedron"); return m; } private SculptMesh CreateSculptMesh(string primName, PrimitiveBaseShape primShape, PhysicsVector size) { SculptMesh sm = new SculptMesh(primShape.SculptData); // Scale the mesh based on our prim scale foreach (Vertex v in sm.vertices) { v.X *= 0.5f; v.Y *= 0.5f; v.Z *= 0.5f; v.X *= size.X; v.Y *= size.Y; v.Z *= size.Z; } // This was built with the normals pointing inside.. // therefore we have to invert the normals foreach (Triangle t in sm.triangles) { t.invertNormal(); } sm.DumpRaw(baseDir, primName, "Sculpt"); return sm; } public static void CalcNormals(Mesh mesh) { int iTriangles = mesh.triangles.Count; mesh.normals = new float[iTriangles*3]; int i = 0; foreach (Triangle t in mesh.triangles) { float ux, uy, uz; float vx, vy, vz; float wx, wy, wz; ux = t.v1.X; uy = t.v1.Y; uz = t.v1.Z; vx = t.v2.X; vy = t.v2.Y; vz = t.v2.Z; wx = t.v3.X; wy = t.v3.Y; wz = t.v3.Z; // Vectors for edges float e1x, e1y, e1z; float e2x, e2y, e2z; e1x = ux - vx; e1y = uy - vy; e1z = uz - vz; e2x = ux - wx; e2y = uy - wy; e2z = uz - wz; // Cross product for normal float nx, ny, nz; nx = e1y*e2z - e1z*e2y; ny = e1z*e2x - e1x*e2z; nz = e1x*e2y - e1y*e2x; // Length float l = (float) Math.Sqrt(nx*nx + ny*ny + nz*nz); // Normalized "normal" nx /= l; ny /= l; nz /= l; mesh.normals[i] = nx; mesh.normals[i + 1] = ny; mesh.normals[i + 2] = nz; i += 3; } } public static Vertex midUnitRadialPoint(Vertex a, Vertex b, float radius) { Vertex midpoint = new Vertex(a + b) * 0.5f; return (midpoint.normalize() * radius); } public static void SphereLODTriangle(Vertex a, Vertex b, Vertex c, float diameter, float LOD, Mesh m) { Vertex aa = a - b; Vertex ba = b - c; Vertex da = c - a; if (((aa.length() < LOD) && (ba.length() < LOD) && (da.length() < LOD))) { // We don't want duplicate verticies. Duplicates cause the scale algorithm to produce a spikeball // spikes are novel, but we want ellipsoids. if (!m.vertices.Contains(a)) m.Add(a); if (!m.vertices.Contains(b)) m.Add(b); if (!m.vertices.Contains(c)) m.Add(c); // Add the triangle to the mesh Triangle t = new Triangle(a, b, c); m.Add(t); } else { Vertex ab = midUnitRadialPoint(a, b, diameter); Vertex bc = midUnitRadialPoint(b, c, diameter); Vertex ca = midUnitRadialPoint(c, a, diameter); // Recursive! Splits the triangle up into 4 smaller triangles SphereLODTriangle(a, ab, ca, diameter, LOD, m); SphereLODTriangle(ab, b, bc, diameter, LOD, m); SphereLODTriangle(ca, bc, c, diameter, LOD, m); SphereLODTriangle(ab, bc, ca, diameter, LOD, m); } } public IMesh CreateMesh(String primName, PrimitiveBaseShape primShape, PhysicsVector size) { Mesh mesh = null; if (primShape.SculptEntry && primShape.SculptType != (byte)0 && primShape.SculptData.Length > 0) { SculptMesh smesh = CreateSculptMesh(primName, primShape, size); mesh = (Mesh)smesh; CalcNormals(mesh); } else { switch (primShape.ProfileShape) { case ProfileShape.Square: mesh = CreateBoxMesh(primName, primShape, size); CalcNormals(mesh); break; case ProfileShape.Circle: if (primShape.PathCurve == (byte)Extrusion.Straight) { mesh = CreateCyllinderMesh(primName, primShape, size); CalcNormals(mesh); } break; case ProfileShape.HalfCircle: if (primShape.PathCurve == (byte)Extrusion.Curve1) { mesh = CreateSphereMesh(primName, primShape, size); CalcNormals(mesh); } break; case ProfileShape.EquilateralTriangle: mesh = CreatePrismMesh(primName, primShape, size); CalcNormals(mesh); break; default: mesh = CreateBoxMesh(primName, primShape, size); CalcNormals(mesh); //Set default mesh to cube otherwise it'll return // null and crash on the 'setMesh' method in the physics plugins. //mesh = null; break; } } return mesh; } } }