// // Created by Иван Ильин on 15.03.2021. // #include "Object.h" #include "Matrix4x4.h" #include "utils/Log.h" void Object::translate(const Vec3D &dv) { _position = std::make_unique(*_position + dv); for(auto &[attachedName, attachedObject] : _attachedObjects) attachedObject->translate(dv); } void Object::scale(const Vec3D &s) { for(auto &[attachedName, attachedObject] : _attachedObjects) attachedObject->scale(s); } void Object::rotate(const Vec3D &r) { _angle = std::make_unique(*_angle + r); Matrix4x4 rotationMatrix = Matrix4x4::RotationZ(r.z())*Matrix4x4::RotationY(r.y())*Matrix4x4::RotationX(r.z()); _left = std::make_unique(rotationMatrix * *_left); _up = std::make_unique(rotationMatrix * *_up); _lookAt = std::make_unique(rotationMatrix * *_lookAt); for(auto &[attachedName, attachedObject] : _attachedObjects) attachedObject->rotateRelativePoint(position(), r); } void Object::rotate(const Vec3D &v, double rv) { Matrix4x4 rotationMatrix = Matrix4x4::Rotation(v, rv); _left = std::make_unique(rotationMatrix * *_left); _up = std::make_unique(rotationMatrix * *_up); _lookAt = std::make_unique(rotationMatrix * *_lookAt); for(auto &[attachedName, attachedObject] : _attachedObjects) attachedObject->rotateRelativePoint(position(), v, rv); } void Object::rotateRelativePoint(const Vec3D &s, const Vec3D &r) { _angle = std::make_unique(*_angle + r); // Translate XYZ by vector r1 Vec3D r1(*_position - s); // In translated coordinate system we rotate body and position Matrix4x4 rotationMatrix = Matrix4x4::Rotation(r); Vec3D r2(rotationMatrix*r1); _left = std::make_unique(rotationMatrix * *_left); _up = std::make_unique(rotationMatrix * *_up); _lookAt = std::make_unique(rotationMatrix * *_lookAt); // After rotation we translate XYZ by vector -r2 and recalculate position _position = std::make_unique(s + r2); for(auto &[attachedName, attachedObject] : _attachedObjects) attachedObject->rotateRelativePoint(s, r); } void Object::rotateRelativePoint(const Vec3D &s, const Vec3D &v, double r) { // Translate XYZ by vector r1 Vec3D r1(*_position - s); // In translated coordinate system we rotate body and position Matrix4x4 rotationMatrix = Matrix4x4::Rotation(v, r); Vec3D r2 = rotationMatrix*r1; _left = std::make_unique(rotationMatrix * *_left); _up = std::make_unique(rotationMatrix * *_up); _lookAt = std::make_unique(rotationMatrix * *_lookAt); // After rotation we translate XYZ by vector -r2 and recalculate position _position = std::make_unique(s + r2); for(auto &[attachedName, attachedObject] : _attachedObjects) attachedObject->rotateRelativePoint(s, v, r); } void Object::rotateLeft(double rl) { _angleLeftUpLookAt = std::make_unique(Vec3D{_angleLeftUpLookAt->x() + rl, _angleLeftUpLookAt->y(), _angleLeftUpLookAt->z()}); rotate(Vec3D(*_left), rl); } void Object::rotateUp(double ru) { _angleLeftUpLookAt = std::make_unique(Vec3D{_angleLeftUpLookAt->x(), _angleLeftUpLookAt->y() + ru, _angleLeftUpLookAt->z()}); rotate(Vec3D(*_up), ru); } void Object::rotateLookAt(double rlAt) { _angleLeftUpLookAt = std::make_unique(Vec3D{_angleLeftUpLookAt->x(), _angleLeftUpLookAt->y(), _angleLeftUpLookAt->z() + rlAt}); rotate(Vec3D(*_lookAt), rlAt); } void Object::translateToPoint(const Vec3D &point) { translate(point - *_position); } void Object::rotateToAngle(const Vec3D &v) { rotate(v - *_angle); } std::shared_ptr Object::attached(const ObjectNameTag& tag) { if(_attachedObjects.count(tag) == 0) return nullptr; return _attachedObjects.find(tag)->second; } void Object::attach(std::shared_ptr object, const ObjectNameTag& tag) { // TODO: solve problem with possible infinite recursive call chains if(this != object.get()) _attachedObjects.emplace(tag, object); else throw std::invalid_argument{"Object::attach: You cannot attach object to itself"}; } void Object::unattach(const ObjectNameTag& tag) { _attachedObjects.erase(tag); } Object::~Object() { _attachedObjects.clear(); }