// // Created by Иван Ильин on 05.02.2021. // #include "RigidBody.h" #include "../Plane.h" #include "../utils/Log.h" #include "../utils/Time.h" #include #include Point4D RigidBody::_findFurthestPoint(const Point4D& direction) { Point4D maxPoint = {}; auto maxDistance = (double)-INFINITY; for(auto& tri : triangles()){ for(int i = 0; i < 3; i++){ Point4D point = tri[i]; point = point + position(); double distance = point.dot(direction); if(distance > maxDistance) { maxDistance = distance; maxPoint = point; } } } return maxPoint; } Point4D RigidBody::_support(std::shared_ptr obj, const Point4D& direction) { Point4D p1 = _findFurthestPoint(direction); Point4D p2 = obj->_findFurthestPoint(-direction); return p1 - p2; } bool RigidBody::_nextSimplex(Simplex &points, Point4D &direction) { switch (points.size()) { case 2: return _line(points, direction); case 3: return _triangle(points, direction); case 4: return _tetrahedron(points, direction); } // never should be here return false; } bool RigidBody::_line(Simplex& points, Point4D& direction) { Point4D a = points[0]; Point4D b = points[1]; Point4D ab = b - a; Point4D ao = - a; if (ab.dot(ao) > 0) { direction = ab.cross3D(ao).cross3D(ab); } else { points = { a }; direction = ao; } return false; } bool RigidBody::_triangle(Simplex &points, Point4D &direction) { Point4D a = points[0]; Point4D b = points[1]; Point4D c = points[2]; Point4D ab = b - a; Point4D ac = c - a; Point4D ao = - a; Point4D abc = ab.cross3D(ac); if (abc.cross3D(ac).dot(ao) > 0) { if (ac.dot(ao) > 0) { points = { a, c }; direction = ac.cross3D(ao).cross3D(ac); } else { return _line(points = { a, b }, direction); } } else { if (ab.cross3D(abc).dot(ao) > 0) { return _line(points = { a, b }, direction); } else { if (abc.dot(ao) > 0) { direction = abc; } else { points = { a, c, b }; direction = -abc; } } } return false; } bool RigidBody::_tetrahedron(Simplex &points, Point4D &direction) { Point4D a = points[0]; Point4D b = points[1]; Point4D c = points[2]; Point4D d = points[3]; Point4D ab = b - a; Point4D ac = c - a; Point4D ad = d - a; Point4D ao = - a; Point4D abc = ab.cross3D(ac); Point4D acd = ac.cross3D(ad); Point4D adb = ad.cross3D(ab); if (abc.dot(ao) > 0) { return _triangle(points = { a, b, c }, direction); } if (acd.dot(ao) > 0) { return _triangle(points = { a, c, d }, direction); } if (adb.dot(ao) > 0) { return _triangle(points = { a, d, b }, direction); } return true; } std::pair RigidBody::checkGJKCollision(std::shared_ptr obj) { // Get initial support point in any direction Point4D support = _support(obj, Point4D{1, 0, 0}); // Simplex is an array of points, max count is 4 Simplex points; points.push_front(support); // New direction is towards the origin Point4D direction = -support; int iterations = 0; while (iterations < 50) { support = _support(obj, direction); if (support.dot(direction) <= 0) return std::make_pair(false, points); // no collision points.push_front(support); if (_nextSimplex(points, direction)) { if(obj->isCollider()) _inCollision = true; return std::make_pair(true, points); } iterations++; } return std::make_pair(false, points); // no collision } CollisionPoint RigidBody::EPA(const Simplex& simplex, std::shared_ptr obj) { std::vector polytope(simplex.begin(), simplex.end()); std::vector faces = { 0, 1, 2, 0, 3, 1, 0, 2, 3, 1, 3, 2 }; // list: vector4(normal, distance), index: min distance auto [normals, minFace] = GetFaceNormals(polytope, faces); Point4D minNormal; double minDistance = INFINITY; int iterations = 0; while ((minDistance == INFINITY) && (iterations < 50)) { minNormal = Point4D{normals[minFace].x(), normals[minFace].y(), normals[minFace].z()}; minDistance = normals[minFace].w(); Point4D support = _support(obj, minNormal); double sDistance = minNormal.dot(support); if (std::abs(sDistance - minDistance) > 0.0001) { minDistance = INFINITY; std::vector> uniqueEdges; for (size_t i = 0; i < normals.size(); i++) { if (normals[i].dot(support) > 0) { size_t f = i * 3; AddIfUniqueEdge(uniqueEdges, faces, f, f + 1); AddIfUniqueEdge(uniqueEdges, faces, f + 1, f + 2); AddIfUniqueEdge(uniqueEdges, faces, f + 2, f ); faces[f + 2] = faces.back(); faces.pop_back(); faces[f + 1] = faces.back(); faces.pop_back(); faces[f ] = faces.back(); faces.pop_back(); normals[i] = normals.back(); normals.pop_back(); i--; } } std::vector newFaces; for (auto [edgeIndex1, edgeIndex2] : uniqueEdges) { newFaces.push_back(edgeIndex1); newFaces.push_back(edgeIndex2); newFaces.push_back(polytope.size()); } polytope.push_back(support); auto [newNormals, newMinFace] = GetFaceNormals(polytope, newFaces); if(newNormals.empty()) break; double oldMinDistance = INFINITY; for (size_t i = 0; i < normals.size(); i++) { if (normals[i].w() < oldMinDistance) { oldMinDistance = normals[i].w(); minFace = i; } } if (newNormals[newMinFace].w() < oldMinDistance) { minFace = newMinFace + normals.size(); } faces .insert(faces .end(), newFaces .begin(), newFaces .end()); normals.insert(normals.end(), newNormals.begin(), newNormals.end()); } iterations++; } CollisionPoint point; point.normal = minNormal; point.depth = minDistance + 0.0001; point.hasCollision = minDistance < INFINITY; _collisionNormal = minNormal; return point; } std::pair, size_t> RigidBody::GetFaceNormals(const std::vector& polytope, const std::vector& faces) { std::vector normals; size_t minTriangle = 0; double minDistance = INFINITY; for (size_t i = 0; i < faces.size(); i += 3) { Point4D a = polytope[faces[i ]]; Point4D b = polytope[faces[i + 1]]; Point4D c = polytope[faces[i + 2]]; Point4D normal = (b - a).cross3D(c - a).normalized(); double distance = normal.dot(a); if (distance < 0) { normal = -normal; distance *= -1; } normal = Point4D{normal.x(), normal.y(), normal.z(), distance}; normals.emplace_back(normal); if (distance < minDistance) { minTriangle = i / 3; minDistance = distance; } } return { normals, minTriangle }; } void RigidBody::AddIfUniqueEdge(std::vector>& edges, const std::vector& faces, size_t a, size_t b) { auto reverse = std::find( // 0--<--3 edges.begin(), // / \ B / A: 2-0 edges.end(), // / A \ / B: 0-2 std::make_pair(faces[b], faces[a]) // 1-->--2 ); if (reverse != edges.end()) { edges.erase(reverse); } else { edges.emplace_back(faces[a], faces[b]); } } void RigidBody::updatePhysicsState() { translate(_velocity * Time::deltaTime()); _velocity = _velocity + _acceleration * Time::deltaTime(); } void RigidBody::setVelocity(const Point4D& velocity) { _velocity = velocity; } void RigidBody::addVelocity(const Point4D &velocity) { _velocity = _velocity + velocity; } void RigidBody::setAcceleration(const Point4D& acceleration) { _acceleration = acceleration; } RigidBody::RigidBody(const Mesh &mesh) : Mesh(mesh) { }