Exemplo n.º 1
0
        public bool ClosestPtPointTriangle(TSVector a, TSVector b, TSVector c,
                                           ref SubSimplexClosestResult result)
        {
            result.usedVertices.Reset();

            FP v, w;

            // Check if P in vertex region outside A
            TSVector ab = b - a;
            TSVector ac = c - a;
            FP       d1 = TSVector.Dot(ab, a);
            FP       d2 = TSVector.Dot(ac, a);

            if (d1 >= FP.Zero && d2 >= FP.Zero)
            {
                result.closestPointOnSimplex    = a;
                result.usedVertices.UsedVertexA = true;
                result.SetBarycentricCoordinates(FP.One, FP.Zero, FP.Zero, FP.Zero);
                return(true); // a; // barycentric coordinates (1,0,0)
            }

            // Check if P in vertex region outside B
            FP d3 = TSVector.Dot(ab, b);
            FP d4 = TSVector.Dot(ac, b);

            if (d3 <= FP.Zero && d4 >= d3)
            {
                result.closestPointOnSimplex    = b;
                result.usedVertices.UsedVertexB = true;
                result.SetBarycentricCoordinates(FP.Zero, FP.One, FP.Zero, FP.Zero);

                return(true); // b; // barycentric coordinates (0,1,0)
            }
            // Check if P in edge region of AB, if so return projection of P onto AB
            FP vc = d1 * d4 - d3 * d2;

            if (vc <= FP.Zero && d1 >= FP.Zero && d3 <= FP.Zero)
            {
                v = d1 / (d1 - d3);
                result.closestPointOnSimplex    = a + v * ab;
                result.usedVertices.UsedVertexA = true;
                result.usedVertices.UsedVertexB = true;
                result.SetBarycentricCoordinates(FP.One - v, v, FP.Zero, FP.Zero);
                return(true);
                //return a + v * ab; // barycentric coordinates (1-v,v,0)
            }

            // Check if P in vertex region outside C
            FP d5 = TSVector.Dot(ab, c);
            FP d6 = TSVector.Dot(ac, c);

            if (d6 <= FP.Zero && d5 >= d6)
            {
                result.closestPointOnSimplex    = c;
                result.usedVertices.UsedVertexC = true;
                result.SetBarycentricCoordinates(FP.Zero, FP.Zero, FP.One, FP.Zero);
                return(true);//c; // barycentric coordinates (0,0,1)
            }

            // Check if P in edge region of AC, if so return projection of P onto AC
            FP vb = d5 * d2 - d1 * d6;

            if (vb <= FP.Zero && d2 >= FP.Zero && d6 <= FP.Zero)
            {
                w = d2 / (d2 - d6);
                result.closestPointOnSimplex    = a + w * ac;
                result.usedVertices.UsedVertexA = true;
                result.usedVertices.UsedVertexC = true;
                result.SetBarycentricCoordinates(FP.One - w, FP.Zero, w, FP.Zero);
                return(true);
                //return a + w * ac; // barycentric coordinates (1-w,0,w)
            }

            // Check if P in edge region of BC, if so return projection of P onto BC
            FP va  = d3 * d6 - d5 * d4;
            FP d34 = d4 - d3;
            FP d65 = d5 - d6;

            if (va <= FP.Zero && d34 >= FP.Zero && d65 >= FP.Zero)
            {
                w = d34 / (d34 + d65);

                result.closestPointOnSimplex    = b + w * (c - b);
                result.usedVertices.UsedVertexB = true;
                result.usedVertices.UsedVertexC = true;
                result.SetBarycentricCoordinates(FP.Zero, FP.One - w, w, FP.Zero);
                return(true);
                // return b + w * (c - b); // barycentric coordinates (0,1-w,w)
            }

            // P inside face region. Compute Q through its barycentric coordinates (u,v,w)
            FP denom = FP.One / (va + vb + vc);

            v = vb * denom;
            w = vc * denom;

            result.closestPointOnSimplex    = a + ab * v + ac * w;
            result.usedVertices.UsedVertexA = true;
            result.usedVertices.UsedVertexB = true;
            result.usedVertices.UsedVertexC = true;
            result.SetBarycentricCoordinates(FP.One - v - w, v, w, FP.Zero);

            return(true);
        }
Exemplo n.º 2
0
        public bool ClosestPtPointTetrahedron(TSVector a, TSVector b, TSVector c, TSVector d,
                                              ref SubSimplexClosestResult finalResult)
        {
            tempResult.Reset();

            // Start out assuming point inside all halfspaces, so closest to itself
            finalResult.closestPointOnSimplex = TSVector.zero;
            finalResult.usedVertices.Reset();
            finalResult.usedVertices.UsedVertexA = true;
            finalResult.usedVertices.UsedVertexB = true;
            finalResult.usedVertices.UsedVertexC = true;
            finalResult.usedVertices.UsedVertexD = true;

            int pointOutsideABC = PointOutsideOfPlane(a, b, c, d);
            int pointOutsideACD = PointOutsideOfPlane(a, c, d, b);
            int pointOutsideADB = PointOutsideOfPlane(a, d, b, c);
            int pointOutsideBDC = PointOutsideOfPlane(b, d, c, a);

            if (pointOutsideABC < 0 || pointOutsideACD < 0 || pointOutsideADB < 0 || pointOutsideBDC < 0)
            {
                finalResult.degenerate = true;
                return(false);
            }

            if (pointOutsideABC == 0 && pointOutsideACD == 0 && pointOutsideADB == 0 && pointOutsideBDC == 0)
            {
                return(false);
            }

            FP bestSqDist = FP.MaxValue;

            // If point outside face abc then compute closest point on abc
            if (pointOutsideABC != 0)
            {
                ClosestPtPointTriangle(a, b, c, ref tempResult);
                TSVector q = tempResult.closestPointOnSimplex;

                FP sqDist = q.sqrMagnitude;
                // Update best closest point if (squared) distance is less than current best
                if (sqDist < bestSqDist)
                {
                    bestSqDist = sqDist;
                    finalResult.closestPointOnSimplex = q;
                    //convert result bitmask!
                    finalResult.usedVertices.Reset();
                    finalResult.usedVertices.UsedVertexA = tempResult.usedVertices.UsedVertexA;
                    finalResult.usedVertices.UsedVertexB = tempResult.usedVertices.UsedVertexB;
                    finalResult.usedVertices.UsedVertexC = tempResult.usedVertices.UsedVertexC;
                    finalResult.SetBarycentricCoordinates(
                        tempResult.barycentricCoords[VertexA],
                        tempResult.barycentricCoords[VertexB],
                        tempResult.barycentricCoords[VertexC],
                        FP.Zero);
                }
            }

            // Repeat test for face acd
            if (pointOutsideACD != 0)
            {
                ClosestPtPointTriangle(a, c, d, ref tempResult);
                TSVector q = tempResult.closestPointOnSimplex;
                //convert result bitmask!

                FP sqDist = q.sqrMagnitude;
                if (sqDist < bestSqDist)
                {
                    bestSqDist = sqDist;
                    finalResult.closestPointOnSimplex = q;
                    finalResult.usedVertices.Reset();
                    finalResult.usedVertices.UsedVertexA = tempResult.usedVertices.UsedVertexA;
                    finalResult.usedVertices.UsedVertexC = tempResult.usedVertices.UsedVertexB;
                    finalResult.usedVertices.UsedVertexD = tempResult.usedVertices.UsedVertexC;
                    finalResult.SetBarycentricCoordinates(
                        tempResult.barycentricCoords[VertexA],
                        FP.Zero,
                        tempResult.barycentricCoords[VertexB],
                        tempResult.barycentricCoords[VertexC]);
                }
            }
            // Repeat test for face adb

            if (pointOutsideADB != 0)
            {
                ClosestPtPointTriangle(a, d, b, ref tempResult);
                TSVector q = tempResult.closestPointOnSimplex;
                //convert result bitmask!

                FP sqDist = q.sqrMagnitude;
                if (sqDist < bestSqDist)
                {
                    bestSqDist = sqDist;
                    finalResult.closestPointOnSimplex = q;
                    finalResult.usedVertices.Reset();
                    finalResult.usedVertices.UsedVertexA = tempResult.usedVertices.UsedVertexA;
                    finalResult.usedVertices.UsedVertexD = tempResult.usedVertices.UsedVertexB;
                    finalResult.usedVertices.UsedVertexB = tempResult.usedVertices.UsedVertexC;
                    finalResult.SetBarycentricCoordinates(
                        tempResult.barycentricCoords[VertexA],
                        tempResult.barycentricCoords[VertexC],
                        FP.Zero,
                        tempResult.barycentricCoords[VertexB]);
                }
            }
            // Repeat test for face bdc

            if (pointOutsideBDC != 0)
            {
                ClosestPtPointTriangle(b, d, c, ref tempResult);
                TSVector q = tempResult.closestPointOnSimplex;
                //convert result bitmask!
                FP sqDist = q.sqrMagnitude;
                if (sqDist < bestSqDist)
                {
                    bestSqDist = sqDist;
                    finalResult.closestPointOnSimplex = q;
                    finalResult.usedVertices.Reset();
                    finalResult.usedVertices.UsedVertexB = tempResult.usedVertices.UsedVertexA;
                    finalResult.usedVertices.UsedVertexD = tempResult.usedVertices.UsedVertexB;
                    finalResult.usedVertices.UsedVertexC = tempResult.usedVertices.UsedVertexC;

                    finalResult.SetBarycentricCoordinates(
                        FP.Zero,
                        tempResult.barycentricCoords[VertexA],
                        tempResult.barycentricCoords[VertexC],
                        tempResult.barycentricCoords[VertexB]);
                }
            }

            //help! we ended up full !

            if (finalResult.usedVertices.UsedVertexA &&
                finalResult.usedVertices.UsedVertexB &&
                finalResult.usedVertices.UsedVertexC &&
                finalResult.usedVertices.UsedVertexD)
            {
                return(true);
            }

            return(true);
        }
Exemplo n.º 3
0
        public bool UpdateClosestVectorAndPoints()
        {
            if (_needsUpdate)
            {
                _cachedBC.Reset();
                _needsUpdate = false;

                TSVector p, a, b, c, d;
                switch (NumVertices)
                {
                case 0:
                    _cachedValidClosest = false;
                    break;

                case 1:
                    _cachedPA = _simplexPointsP[0];
                    _cachedPB = _simplexPointsQ[0];
                    _cachedV  = _cachedPA - _cachedPB;
                    _cachedBC.Reset();
                    _cachedBC.SetBarycentricCoordinates(FP.One, FP.Zero, FP.Zero, FP.Zero);
                    _cachedValidClosest = _cachedBC.IsValid;
                    break;

                case 2:
                    //closest point origin from line segment
                    TSVector from = _simplexVectorW[0];
                    TSVector to   = _simplexVectorW[1];
                    //TSVector nearest;

                    TSVector diff = TSVector.Negate(from);
                    TSVector v    = to - from;
                    FP       t    = TSVector.Dot(v, diff);

                    if (t > FP.Zero)
                    {
                        FP dotVV = v.sqrMagnitude;
                        if (t < dotVV)
                        {
                            t    /= dotVV;
                            diff -= t * v;
                            _cachedBC.usedVertices.UsedVertexA = true;
                            _cachedBC.usedVertices.UsedVertexB = true;
                        }
                        else
                        {
                            t     = FP.One;
                            diff -= v;
                            //reduce to 1 point
                            _cachedBC.usedVertices.UsedVertexB = true;
                        }
                    }
                    else
                    {
                        t = FP.Zero;
                        //reduce to 1 point
                        _cachedBC.usedVertices.UsedVertexA = true;
                    }

                    _cachedBC.SetBarycentricCoordinates(FP.One - t, t, FP.Zero, FP.Zero);
                    //nearest = from + t * v;

                    _cachedPA = _simplexPointsP[0] + t * (_simplexPointsP[1] - _simplexPointsP[0]);
                    _cachedPB = _simplexPointsQ[0] + t * (_simplexPointsQ[1] - _simplexPointsQ[0]);
                    _cachedV  = _cachedPA - _cachedPB;

                    ReduceVertices(_cachedBC.usedVertices);

                    _cachedValidClosest = _cachedBC.IsValid;
                    break;

                case 3:
                    //closest point origin from triangle
                    a = _simplexVectorW[0];
                    b = _simplexVectorW[1];
                    c = _simplexVectorW[2];

                    ClosestPtPointTriangle(a, b, c, ref _cachedBC);
                    _cachedPA = _simplexPointsP[0] * _cachedBC.barycentricCoords[0] +
                                _simplexPointsP[1] * _cachedBC.barycentricCoords[1] +
                                _simplexPointsP[2] * _cachedBC.barycentricCoords[2];

                    _cachedPB = _simplexPointsQ[0] * _cachedBC.barycentricCoords[0] +
                                _simplexPointsQ[1] * _cachedBC.barycentricCoords[1] +
                                _simplexPointsQ[2] * _cachedBC.barycentricCoords[2];

                    _cachedV = _cachedPA - _cachedPB;

                    ReduceVertices(_cachedBC.usedVertices);
                    _cachedValidClosest = _cachedBC.IsValid;
                    break;

                case 4:
                    a = _simplexVectorW[0];
                    b = _simplexVectorW[1];
                    c = _simplexVectorW[2];
                    d = _simplexVectorW[3];

                    bool hasSeparation = ClosestPtPointTetrahedron(a, b, c, d, ref _cachedBC);

                    if (hasSeparation)
                    {
                        _cachedPA = _simplexPointsP[0] * _cachedBC.barycentricCoords[0] +
                                    _simplexPointsP[1] * _cachedBC.barycentricCoords[1] +
                                    _simplexPointsP[2] * _cachedBC.barycentricCoords[2] +
                                    _simplexPointsP[3] * _cachedBC.barycentricCoords[3];

                        _cachedPB = _simplexPointsQ[0] * _cachedBC.barycentricCoords[0] +
                                    _simplexPointsQ[1] * _cachedBC.barycentricCoords[1] +
                                    _simplexPointsQ[2] * _cachedBC.barycentricCoords[2] +
                                    _simplexPointsQ[3] * _cachedBC.barycentricCoords[3];

                        _cachedV = _cachedPA - _cachedPB;
                        ReduceVertices(_cachedBC.usedVertices);
                    }
                    else
                    {
                        if (_cachedBC.degenerate)
                        {
                            _cachedValidClosest = false;
                        }
                        else
                        {
                            _cachedValidClosest = true;
                            //degenerate case == false, penetration = true + zero
                            _cachedV.x = _cachedV.y = _cachedV.z = FP.Zero;
                        }
                        break;     // !!!!!!!!!!!! proverit na vsakiy sluchai
                    }

                    _cachedValidClosest = _cachedBC.IsValid;

                    //closest point origin from tetrahedron
                    break;

                default:
                    _cachedValidClosest = false;
                    break;
                }
            }

            return(_cachedValidClosest);
        }