demos/opengl/quaternion_demo.cpp - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #include "quaternion_demo.h"
 #include "icosphere.h"

 #include <Eigen/Geometry>
 #include <Eigen/QR>
 #include <Eigen/LU>

 #include <iostream>
 #include <QEvent>
 #include <QMouseEvent>
 #include <QInputDialog>
 #include <QGridLayout>
 #include <QButtonGroup>
 #include <QRadioButton>
 #include <QDockWidget>
 #include <QPushButton>
 #include <QGroupBox>

 using namespace Eigen;

 class FancySpheres {
  public:
   EIGEN_MAKE_ALIGNED_OPERATOR_NEW

   FancySpheres() {
     const int levels = 4;
     const float scale = 0.33;
     float radius = 100;
     std::vector<int> parents;

     // leval 0
     mCenters.push_back(Vector3f::Zero());
     parents.push_back(-1);
     mRadii.push_back(radius);

     // generate level 1 using icosphere vertices
     radius *= 0.45;
     {
       float dist = mRadii[0] * 0.9;
       for (int i = 0; i < 12; ++i) {
         mCenters.push_back(mIcoSphere.vertices()[i] * dist);
         mRadii.push_back(radius);
         parents.push_back(0);
       }
     }

     static const float angles[10] = {0, 0, M_PI, 0. * M_PI, M_PI, 0.5 * M_PI, M_PI, 1. * M_PI, M_PI, 1.5 * M_PI};

     // generate other levels
     int start = 1;
     for (int l = 1; l < levels; l++) {
       radius *= scale;
       int end = mCenters.size();
       for (int i = start; i < end; ++i) {
         Vector3f c = mCenters[i];
         Vector3f ax0 = (c - mCenters[parents[i]]).normalized();
         Vector3f ax1 = ax0.unitOrthogonal();
         Quaternionf q;
         q.setFromTwoVectors(Vector3f::UnitZ(), ax0);
         Affine3f t = Translation3f(c) * q * Scaling(mRadii[i] + radius);
         for (int j = 0; j < 5; ++j) {
           Vector3f newC =
               c + ((AngleAxisf(angles[j * 2 + 1], ax0) * AngleAxisf(angles[j * 2 + 0] * (l == 1 ? 0.35 : 0.5), ax1)) *
                    ax0) *
                       (mRadii[i] + radius * 0.8);
           mCenters.push_back(newC);
           mRadii.push_back(radius);
           parents.push_back(i);
         }
       }
       start = end;
     }
   }

   void draw() {
     int end = mCenters.size();
     glEnable(GL_NORMALIZE);
     for (int i = 0; i < end; ++i) {
       Affine3f t = Translation3f(mCenters[i]) * Scaling(mRadii[i]);
       gpu.pushMatrix(GL_MODELVIEW);
       gpu.multMatrix(t.matrix(), GL_MODELVIEW);
       mIcoSphere.draw(2);
       gpu.popMatrix(GL_MODELVIEW);
     }
     glDisable(GL_NORMALIZE);
   }

  protected:
   std::vector<Vector3f> mCenters;
   std::vector<float> mRadii;
   IcoSphere mIcoSphere;
 };

 // generic linear interpolation method
 template <typename T>
 T lerp(float t, const T& a, const T& b) {
   return a * (1 - t) + b * t;
 }

 // quaternion slerp
 template <>
 Quaternionf lerp(float t, const Quaternionf& a, const Quaternionf& b) {
   return a.slerp(t, b);
 }

 // linear interpolation of a frame using the type OrientationType
 // to perform the interpolation of the orientations
 template <typename OrientationType>
 inline static Frame lerpFrame(float alpha, const Frame& a, const Frame& b) {
   return Frame(lerp(alpha, a.position, b.position),
                Quaternionf(lerp(alpha, OrientationType(a.orientation), OrientationType(b.orientation))));
 }

 template <typename Scalar_>
 class EulerAngles {
  public:
   enum { Dim = 3 };
   typedef Scalar_ Scalar;
   typedef Matrix<Scalar, 3, 3> Matrix3;
   typedef Matrix<Scalar, 3, 1> Vector3;
   typedef Quaternion<Scalar> QuaternionType;

  protected:
   Vector3 m_angles;

  public:
   EulerAngles() {}
   inline EulerAngles(Scalar a0, Scalar a1, Scalar a2) : m_angles(a0, a1, a2) {}
   inline EulerAngles(const QuaternionType& q) { *this = q; }

   const Vector3& coeffs() const { return m_angles; }
   Vector3& coeffs() { return m_angles; }

   EulerAngles& operator=(const QuaternionType& q) {
     Matrix3 m = q.toRotationMatrix();
     return *this = m;
   }

   EulerAngles& operator=(const Matrix3& m) {
     // mat =  cy*cz          -cy*sz           sy
     //        cz*sx*sy+cx*sz  cx*cz-sx*sy*sz -cy*sx
     //       -cx*cz*sy+sx*sz  cz*sx+cx*sy*sz  cx*cy
     m_angles.coeffRef(1) = std::asin(m.coeff(0, 2));
     m_angles.coeffRef(0) = std::atan2(-m.coeff(1, 2), m.coeff(2, 2));
     m_angles.coeffRef(2) = std::atan2(-m.coeff(0, 1), m.coeff(0, 0));
     return *this;
   }

   Matrix3 toRotationMatrix(void) const {
     Vector3 c = m_angles.array().cos();
     Vector3 s = m_angles.array().sin();
     Matrix3 res;
     res << c.y() * c.z(), -c.y() * s.z(), s.y(), c.z() * s.x() * s.y() + c.x() * s.z(),
         c.x() * c.z() - s.x() * s.y() * s.z(), -c.y() * s.x(), -c.x() * c.z() * s.y() + s.x() * s.z(),
         c.z() * s.x() + c.x() * s.y() * s.z(), c.x() * c.y();
     return res;
   }

   operator QuaternionType() { return QuaternionType(toRotationMatrix()); }
 };

 // Euler angles slerp
 template <>
 EulerAngles<float> lerp(float t, const EulerAngles<float>& a, const EulerAngles<float>& b) {
   EulerAngles<float> res;
   res.coeffs() = lerp(t, a.coeffs(), b.coeffs());
   return res;
 }

 RenderingWidget::RenderingWidget() {
   mAnimate = false;
   mCurrentTrackingMode = TM_NO_TRACK;
   mNavMode = NavTurnAround;
   mLerpMode = LerpQuaternion;
   mRotationMode = RotationStable;
   mTrackball.setCamera(&mCamera);

   // required to capture key press events
   setFocusPolicy(Qt::ClickFocus);
 }

 void RenderingWidget::grabFrame(void) {
   // ask user for a time
   bool ok = false;
   double t = 0;
   if (!m_timeline.empty()) t = (--m_timeline.end())->first + 1.;
   t = QInputDialog::getDouble(this, "Eigen's RenderingWidget", "time value: ", t, 0, 1e3, 1, &ok);
   if (ok) {
     Frame aux;
     aux.orientation = mCamera.viewMatrix().linear();
     aux.position = mCamera.viewMatrix().translation();
     m_timeline[t] = aux;
   }
 }

 void RenderingWidget::drawScene() {
   static FancySpheres sFancySpheres;
   float length = 50;
   gpu.drawVector(Vector3f::Zero(), length * Vector3f::UnitX(), Color(1, 0, 0, 1));
   gpu.drawVector(Vector3f::Zero(), length * Vector3f::UnitY(), Color(0, 1, 0, 1));
   gpu.drawVector(Vector3f::Zero(), length * Vector3f::UnitZ(), Color(0, 0, 1, 1));

   // draw the fractal object
   float sqrt3 = std::sqrt(3.);
   glLightfv(GL_LIGHT0, GL_AMBIENT, Vector4f(0.5, 0.5, 0.5, 1).data());
   glLightfv(GL_LIGHT0, GL_DIFFUSE, Vector4f(0.5, 1, 0.5, 1).data());
   glLightfv(GL_LIGHT0, GL_SPECULAR, Vector4f(1, 1, 1, 1).data());
   glLightfv(GL_LIGHT0, GL_POSITION, Vector4f(-sqrt3, -sqrt3, sqrt3, 0).data());

   glLightfv(GL_LIGHT1, GL_AMBIENT, Vector4f(0, 0, 0, 1).data());
   glLightfv(GL_LIGHT1, GL_DIFFUSE, Vector4f(1, 0.5, 0.5, 1).data());
   glLightfv(GL_LIGHT1, GL_SPECULAR, Vector4f(1, 1, 1, 1).data());
   glLightfv(GL_LIGHT1, GL_POSITION, Vector4f(-sqrt3, sqrt3, -sqrt3, 0).data());

   glMaterialfv(GL_FRONT_AND_BACK, GL_AMBIENT, Vector4f(0.7, 0.7, 0.7, 1).data());
   glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, Vector4f(0.8, 0.75, 0.6, 1).data());
   glMaterialfv(GL_FRONT_AND_BACK, GL_SPECULAR, Vector4f(1, 1, 1, 1).data());
   glMaterialf(GL_FRONT_AND_BACK, GL_SHININESS, 64);

   glEnable(GL_LIGHTING);
   glEnable(GL_LIGHT0);
   glEnable(GL_LIGHT1);

   sFancySpheres.draw();
   glVertexPointer(3, GL_FLOAT, 0, mVertices[0].data());
   glNormalPointer(GL_FLOAT, 0, mNormals[0].data());
   glEnableClientState(GL_VERTEX_ARRAY);
   glEnableClientState(GL_NORMAL_ARRAY);
   glDrawArrays(GL_TRIANGLES, 0, mVertices.size());
   glDisableClientState(GL_VERTEX_ARRAY);
   glDisableClientState(GL_NORMAL_ARRAY);

   glDisable(GL_LIGHTING);
 }

 void RenderingWidget::animate() {
   m_alpha += double(m_timer.interval()) * 1e-3;

   TimeLine::const_iterator hi = m_timeline.upper_bound(m_alpha);
   TimeLine::const_iterator lo = hi;
   --lo;

   Frame currentFrame;

   if (hi == m_timeline.end()) {
     // end
     currentFrame = lo->second;
     stopAnimation();
   } else if (hi == m_timeline.begin()) {
     // start
     currentFrame = hi->second;
   } else {
     float s = (m_alpha - lo->first) / (hi->first - lo->first);
     if (mLerpMode == LerpEulerAngles)
       currentFrame = ::lerpFrame<EulerAngles<float> >(s, lo->second, hi->second);
     else if (mLerpMode == LerpQuaternion)
       currentFrame = ::lerpFrame<Eigen::Quaternionf>(s, lo->second, hi->second);
     else {
       std::cerr << "Invalid rotation interpolation mode (abort)\n";
       exit(2);
     }
     currentFrame.orientation.coeffs().normalize();
   }

   currentFrame.orientation = currentFrame.orientation.inverse();
   currentFrame.position = -(currentFrame.orientation * currentFrame.position);
   mCamera.setFrame(currentFrame);

   updateGL();
 }

 void RenderingWidget::keyPressEvent(QKeyEvent* e) {
   switch (e->key()) {
     case Qt::Key_Up:
       mCamera.zoom(2);
       break;
     case Qt::Key_Down:
       mCamera.zoom(-2);
       break;
     // add a frame
     case Qt::Key_G:
       grabFrame();
       break;
     // clear the time line
     case Qt::Key_C:
       m_timeline.clear();
       break;
     // move the camera to initial pos
     case Qt::Key_R:
       resetCamera();
       break;
     // start/stop the animation
     case Qt::Key_A:
       if (mAnimate) {
         stopAnimation();
       } else {
         m_alpha = 0;
         connect(&m_timer, SIGNAL(timeout()), this, SLOT(animate()));
         m_timer.start(1000 / 30);
         mAnimate = true;
       }
       break;
     default:
       break;
   }

   updateGL();
 }

 void RenderingWidget::stopAnimation() {
   disconnect(&m_timer, SIGNAL(timeout()), this, SLOT(animate()));
   m_timer.stop();
   mAnimate = false;
   m_alpha = 0;
 }

 void RenderingWidget::mousePressEvent(QMouseEvent* e) {
   mMouseCoords = Vector2i(e->pos().x(), e->pos().y());
   bool fly = (mNavMode == NavFly) || (e->modifiers() & Qt::ControlModifier);
   switch (e->button()) {
     case Qt::LeftButton:
       if (fly) {
         mCurrentTrackingMode = TM_LOCAL_ROTATE;
         mTrackball.start(Trackball::Local);
       } else {
         mCurrentTrackingMode = TM_ROTATE_AROUND;
         mTrackball.start(Trackball::Around);
       }
       mTrackball.track(mMouseCoords);
       break;
     case Qt::MidButton:
       if (fly)
         mCurrentTrackingMode = TM_FLY_Z;
       else
         mCurrentTrackingMode = TM_ZOOM;
       break;
     case Qt::RightButton:
       mCurrentTrackingMode = TM_FLY_PAN;
       break;
     default:
       break;
   }
 }
 void RenderingWidget::mouseReleaseEvent(QMouseEvent*) {
   mCurrentTrackingMode = TM_NO_TRACK;
   updateGL();
 }

 void RenderingWidget::mouseMoveEvent(QMouseEvent* e) {
   // tracking
   if (mCurrentTrackingMode != TM_NO_TRACK) {
     float dx = float(e->x() - mMouseCoords.x()) / float(mCamera.vpWidth());
     float dy = -float(e->y() - mMouseCoords.y()) / float(mCamera.vpHeight());

     // speedup the transformations
     if (e->modifiers() & Qt::ShiftModifier) {
       dx *= 10.;
       dy *= 10.;
     }

     switch (mCurrentTrackingMode) {
       case TM_ROTATE_AROUND:
       case TM_LOCAL_ROTATE:
         if (mRotationMode == RotationStable) {
           // use the stable trackball implementation mapping
           // the 2D coordinates to 3D points on a sphere.
           mTrackball.track(Vector2i(e->pos().x(), e->pos().y()));
         } else {
           // standard approach mapping the x and y displacements as rotations
           // around the camera's X and Y axes.
           Quaternionf q = AngleAxisf(dx * M_PI, Vector3f::UnitY()) * AngleAxisf(-dy * M_PI, Vector3f::UnitX());
           if (mCurrentTrackingMode == TM_LOCAL_ROTATE)
             mCamera.localRotate(q);
           else
             mCamera.rotateAroundTarget(q);
         }
         break;
       case TM_ZOOM:
         mCamera.zoom(dy * 100);
         break;
       case TM_FLY_Z:
         mCamera.localTranslate(Vector3f(0, 0, -dy * 200));
         break;
       case TM_FLY_PAN:
         mCamera.localTranslate(Vector3f(dx * 200, dy * 200, 0));
         break;
       default:
         break;
     }

     updateGL();
   }

   mMouseCoords = Vector2i(e->pos().x(), e->pos().y());
 }

 void RenderingWidget::paintGL() {
   glEnable(GL_DEPTH_TEST);
   glDisable(GL_CULL_FACE);
   glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
   glDisable(GL_COLOR_MATERIAL);
   glDisable(GL_BLEND);
   glDisable(GL_ALPHA_TEST);
   glDisable(GL_TEXTURE_1D);
   glDisable(GL_TEXTURE_2D);
   glDisable(GL_TEXTURE_3D);

   // Clear buffers
   glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);

   mCamera.activateGL();

   drawScene();
 }

 void RenderingWidget::initializeGL() {
   glClearColor(1., 1., 1., 0.);
   glLightModeli(GL_LIGHT_MODEL_LOCAL_VIEWER, 1);
   glDepthMask(GL_TRUE);
   glColorMask(GL_TRUE, GL_TRUE, GL_TRUE, GL_TRUE);

   mCamera.setPosition(Vector3f(-200, -200, -200));
   mCamera.setTarget(Vector3f(0, 0, 0));
   mInitFrame.orientation = mCamera.orientation().inverse();
   mInitFrame.position = mCamera.viewMatrix().translation();
 }

 void RenderingWidget::resizeGL(int width, int height) { mCamera.setViewport(width, height); }

 void RenderingWidget::setNavMode(int m) { mNavMode = NavMode(m); }

 void RenderingWidget::setLerpMode(int m) { mLerpMode = LerpMode(m); }

 void RenderingWidget::setRotationMode(int m) { mRotationMode = RotationMode(m); }

 void RenderingWidget::resetCamera() {
   if (mAnimate) stopAnimation();
   m_timeline.clear();
   Frame aux0 = mCamera.frame();
   aux0.orientation = aux0.orientation.inverse();
   aux0.position = mCamera.viewMatrix().translation();
   m_timeline[0] = aux0;

   Vector3f currentTarget = mCamera.target();
   mCamera.setTarget(Vector3f::Zero());

   // compute the rotation duration to move the camera to the target
   Frame aux1 = mCamera.frame();
   aux1.orientation = aux1.orientation.inverse();
   aux1.position = mCamera.viewMatrix().translation();
   float duration = aux0.orientation.angularDistance(aux1.orientation) * 0.9;
   if (duration < 0.1) duration = 0.1;

   // put the camera at that time step:
   aux1 = aux0.lerp(duration / 2, mInitFrame);
   // and make it look at the target again
   aux1.orientation = aux1.orientation.inverse();
   aux1.position = -(aux1.orientation * aux1.position);
   mCamera.setFrame(aux1);
   mCamera.setTarget(Vector3f::Zero());

   // add this camera keyframe
   aux1.orientation = aux1.orientation.inverse();
   aux1.position = mCamera.viewMatrix().translation();
   m_timeline[duration] = aux1;

   m_timeline[2] = mInitFrame;
   m_alpha = 0;
   animate();
   connect(&m_timer, SIGNAL(timeout()), this, SLOT(animate()));
   m_timer.start(1000 / 30);
   mAnimate = true;
 }

 QWidget* RenderingWidget::createNavigationControlWidget() {
   QWidget* panel = new QWidget();
   QVBoxLayout* layout = new QVBoxLayout();

   {
     QPushButton* but = new QPushButton("reset");
     but->setToolTip("move the camera to initial position (with animation)");
     layout->addWidget(but);
     connect(but, SIGNAL(clicked()), this, SLOT(resetCamera()));
   }
   {
     // navigation mode
     QGroupBox* box = new QGroupBox("navigation mode");
     QVBoxLayout* boxLayout = new QVBoxLayout;
     QButtonGroup* group = new QButtonGroup(panel);
     QRadioButton* but;
     but = new QRadioButton("turn around");
     but->setToolTip("look around an object");
     group->addButton(but, NavTurnAround);
     boxLayout->addWidget(but);
     but = new QRadioButton("fly");
     but->setToolTip("free navigation like a spaceship\n(this mode can also be enabled pressing the \"shift\" key)");
     group->addButton(but, NavFly);
     boxLayout->addWidget(but);
     group->button(mNavMode)->setChecked(true);
     connect(group, SIGNAL(buttonClicked(int)), this, SLOT(setNavMode(int)));
     box->setLayout(boxLayout);
     layout->addWidget(box);
   }
   {
     // track ball, rotation mode
     QGroupBox* box = new QGroupBox("rotation mode");
     QVBoxLayout* boxLayout = new QVBoxLayout;
     QButtonGroup* group = new QButtonGroup(panel);
     QRadioButton* but;
     but = new QRadioButton("stable trackball");
     group->addButton(but, RotationStable);
     boxLayout->addWidget(but);
     but->setToolTip("use the stable trackball implementation mapping\nthe 2D coordinates to 3D points on a sphere");
     but = new QRadioButton("standard rotation");
     group->addButton(but, RotationStandard);
     boxLayout->addWidget(but);
     but->setToolTip(
         "standard approach mapping the x and y displacements\nas rotations around the camera's X and Y axes");
     group->button(mRotationMode)->setChecked(true);
     connect(group, SIGNAL(buttonClicked(int)), this, SLOT(setRotationMode(int)));
     box->setLayout(boxLayout);
     layout->addWidget(box);
   }
   {
     // interpolation mode
     QGroupBox* box = new QGroupBox("spherical interpolation");
     QVBoxLayout* boxLayout = new QVBoxLayout;
     QButtonGroup* group = new QButtonGroup(panel);
     QRadioButton* but;
     but = new QRadioButton("quaternion slerp");
     group->addButton(but, LerpQuaternion);
     boxLayout->addWidget(but);
     but->setToolTip("use quaternion spherical interpolation\nto interpolate orientations");
     but = new QRadioButton("euler angles");
     group->addButton(but, LerpEulerAngles);
     boxLayout->addWidget(but);
     but->setToolTip("use Euler angles to interpolate orientations");
     group->button(mNavMode)->setChecked(true);
     connect(group, SIGNAL(buttonClicked(int)), this, SLOT(setLerpMode(int)));
     box->setLayout(boxLayout);
     layout->addWidget(box);
   }
   layout->addItem(new QSpacerItem(0, 0, QSizePolicy::Minimum, QSizePolicy::Expanding));
   panel->setLayout(layout);
   return panel;
 }

 QuaternionDemo::QuaternionDemo() {
   mRenderingWidget = new RenderingWidget();
   setCentralWidget(mRenderingWidget);

   QDockWidget* panel = new QDockWidget("navigation", this);
   panel->setAllowedAreas((QFlags<Qt::DockWidgetArea>)(Qt::RightDockWidgetArea | Qt::LeftDockWidgetArea));
   addDockWidget(Qt::RightDockWidgetArea, panel);
   panel->setWidget(mRenderingWidget->createNavigationControlWidget());
 }

 int main(int argc, char* argv[]) {
   std::cout << "Navigation:\n";
   std::cout << "  left button:           rotate around the target\n";
   std::cout << "  middle button:         zoom\n";
   std::cout << "  left button + ctrl     quake rotate (rotate around camera position)\n";
   std::cout << "  middle button + ctrl   walk (progress along camera's z direction)\n";
   std::cout << "  left button:           pan (translate in the XY camera's plane)\n\n";
   std::cout << "R : move the camera to initial position\n";
   std::cout << "A : start/stop animation\n";
   std::cout << "C : clear the animation\n";
   std::cout << "G : add a key frame\n";

   QApplication app(argc, argv);
   QuaternionDemo demo;
   demo.resize(600, 500);
   demo.show();
   return app.exec();
 }

 #include "quaternion_demo.moc"
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#include "quaternion_demo.h"
	#include "icosphere.h"

	#include <Eigen/Geometry>
	#include <Eigen/QR>
	#include <Eigen/LU>

	#include <iostream>
	#include <QEvent>
	#include <QMouseEvent>
	#include <QInputDialog>
	#include <QGridLayout>
	#include <QButtonGroup>
	#include <QRadioButton>
	#include <QDockWidget>
	#include <QPushButton>
	#include <QGroupBox>

	using namespace Eigen;

	class FancySpheres {
	public:
	EIGEN_MAKE_ALIGNED_OPERATOR_NEW

	FancySpheres() {
	const int levels = 4;
	const float scale = 0.33;
	float radius = 100;
	std::vector<int> parents;

	// leval 0
	mCenters.push_back(Vector3f::Zero());
	parents.push_back(-1);
	mRadii.push_back(radius);

	// generate level 1 using icosphere vertices
	radius *= 0.45;
	{
	float dist = mRadii[0] * 0.9;
	for (int i = 0; i < 12; ++i) {
	mCenters.push_back(mIcoSphere.vertices()[i] * dist);
	mRadii.push_back(radius);
	parents.push_back(0);
	}
	}

	static const float angles[10] = {0, 0, M_PI, 0. * M_PI, M_PI, 0.5 * M_PI, M_PI, 1. * M_PI, M_PI, 1.5 * M_PI};

	// generate other levels
	int start = 1;
	for (int l = 1; l < levels; l++) {
	radius *= scale;
	int end = mCenters.size();
	for (int i = start; i < end; ++i) {
	Vector3f c = mCenters[i];
	Vector3f ax0 = (c - mCenters[parents[i]]).normalized();
	Vector3f ax1 = ax0.unitOrthogonal();
	Quaternionf q;
	q.setFromTwoVectors(Vector3f::UnitZ(), ax0);
	Affine3f t = Translation3f(c) * q * Scaling(mRadii[i] + radius);
	for (int j = 0; j < 5; ++j) {
	Vector3f newC =
	c + ((AngleAxisf(angles[j * 2 + 1], ax0) * AngleAxisf(angles[j * 2 + 0] * (l == 1 ? 0.35 : 0.5), ax1)) *
	ax0) *
	(mRadii[i] + radius * 0.8);
	mCenters.push_back(newC);
	mRadii.push_back(radius);
	parents.push_back(i);
	}
	}
	start = end;
	}
	}

	void draw() {
	int end = mCenters.size();
	glEnable(GL_NORMALIZE);
	for (int i = 0; i < end; ++i) {
	Affine3f t = Translation3f(mCenters[i]) * Scaling(mRadii[i]);
	gpu.pushMatrix(GL_MODELVIEW);
	gpu.multMatrix(t.matrix(), GL_MODELVIEW);
	mIcoSphere.draw(2);
	gpu.popMatrix(GL_MODELVIEW);
	}
	glDisable(GL_NORMALIZE);
	}

	protected:
	std::vector<Vector3f> mCenters;
	std::vector<float> mRadii;
	IcoSphere mIcoSphere;
	};

	// generic linear interpolation method
	template <typename T>
	T lerp(float t, const T& a, const T& b) {
	return a * (1 - t) + b * t;
	}

	// quaternion slerp
	template <>
	Quaternionf lerp(float t, const Quaternionf& a, const Quaternionf& b) {
	return a.slerp(t, b);
	}

	// linear interpolation of a frame using the type OrientationType
	// to perform the interpolation of the orientations
	template <typename OrientationType>
	inline static Frame lerpFrame(float alpha, const Frame& a, const Frame& b) {
	return Frame(lerp(alpha, a.position, b.position),
	Quaternionf(lerp(alpha, OrientationType(a.orientation), OrientationType(b.orientation))));
	}

	template <typename Scalar_>
	class EulerAngles {
	public:
	enum { Dim = 3 };
	typedef Scalar_ Scalar;
	typedef Matrix<Scalar, 3, 3> Matrix3;
	typedef Matrix<Scalar, 3, 1> Vector3;
	typedef Quaternion<Scalar> QuaternionType;

	protected:
	Vector3 m_angles;

	public:
	EulerAngles() {}
	inline EulerAngles(Scalar a0, Scalar a1, Scalar a2) : m_angles(a0, a1, a2) {}
	inline EulerAngles(const QuaternionType& q) { *this = q; }

	const Vector3& coeffs() const { return m_angles; }
	Vector3& coeffs() { return m_angles; }

	EulerAngles& operator=(const QuaternionType& q) {
	Matrix3 m = q.toRotationMatrix();
	return *this = m;
	}

	EulerAngles& operator=(const Matrix3& m) {
	// mat = cycz -cysz sy
	// czsxsy+cxsz cxcz-sxsysz -cy*sx
	// -cxczsy+sxsz czsx+cxsysz cx*cy
	m_angles.coeffRef(1) = std::asin(m.coeff(0, 2));
	m_angles.coeffRef(0) = std::atan2(-m.coeff(1, 2), m.coeff(2, 2));
	m_angles.coeffRef(2) = std::atan2(-m.coeff(0, 1), m.coeff(0, 0));
	return *this;
	}

	Matrix3 toRotationMatrix(void) const {
	Vector3 c = m_angles.array().cos();
	Vector3 s = m_angles.array().sin();
	Matrix3 res;
	res << c.y() * c.z(), -c.y() * s.z(), s.y(), c.z() * s.x() * s.y() + c.x() * s.z(),
	c.x() * c.z() - s.x() * s.y() * s.z(), -c.y() * s.x(), -c.x() * c.z() * s.y() + s.x() * s.z(),
	c.z() * s.x() + c.x() * s.y() * s.z(), c.x() * c.y();
	return res;
	}

	operator QuaternionType() { return QuaternionType(toRotationMatrix()); }
	};

	// Euler angles slerp
	template <>
	EulerAngles<float> lerp(float t, const EulerAngles<float>& a, const EulerAngles<float>& b) {
	EulerAngles<float> res;
	res.coeffs() = lerp(t, a.coeffs(), b.coeffs());
	return res;
	}

	RenderingWidget::RenderingWidget() {
	mAnimate = false;
	mCurrentTrackingMode = TM_NO_TRACK;
	mNavMode = NavTurnAround;
	mLerpMode = LerpQuaternion;
	mRotationMode = RotationStable;
	mTrackball.setCamera(&mCamera);

	// required to capture key press events
	setFocusPolicy(Qt::ClickFocus);
	}

	void RenderingWidget::grabFrame(void) {
	// ask user for a time
	bool ok = false;
	double t = 0;
	if (!m_timeline.empty()) t = (--m_timeline.end())->first + 1.;
	t = QInputDialog::getDouble(this, "Eigen's RenderingWidget", "time value: ", t, 0, 1e3, 1, &ok);
	if (ok) {
	Frame aux;
	aux.orientation = mCamera.viewMatrix().linear();
	aux.position = mCamera.viewMatrix().translation();
	m_timeline[t] = aux;
	}
	}

	void RenderingWidget::drawScene() {
	static FancySpheres sFancySpheres;
	float length = 50;
	gpu.drawVector(Vector3f::Zero(), length * Vector3f::UnitX(), Color(1, 0, 0, 1));
	gpu.drawVector(Vector3f::Zero(), length * Vector3f::UnitY(), Color(0, 1, 0, 1));
	gpu.drawVector(Vector3f::Zero(), length * Vector3f::UnitZ(), Color(0, 0, 1, 1));

	// draw the fractal object
	float sqrt3 = std::sqrt(3.);
	glLightfv(GL_LIGHT0, GL_AMBIENT, Vector4f(0.5, 0.5, 0.5, 1).data());
	glLightfv(GL_LIGHT0, GL_DIFFUSE, Vector4f(0.5, 1, 0.5, 1).data());
	glLightfv(GL_LIGHT0, GL_SPECULAR, Vector4f(1, 1, 1, 1).data());
	glLightfv(GL_LIGHT0, GL_POSITION, Vector4f(-sqrt3, -sqrt3, sqrt3, 0).data());

	glLightfv(GL_LIGHT1, GL_AMBIENT, Vector4f(0, 0, 0, 1).data());
	glLightfv(GL_LIGHT1, GL_DIFFUSE, Vector4f(1, 0.5, 0.5, 1).data());
	glLightfv(GL_LIGHT1, GL_SPECULAR, Vector4f(1, 1, 1, 1).data());
	glLightfv(GL_LIGHT1, GL_POSITION, Vector4f(-sqrt3, sqrt3, -sqrt3, 0).data());

	glMaterialfv(GL_FRONT_AND_BACK, GL_AMBIENT, Vector4f(0.7, 0.7, 0.7, 1).data());
	glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, Vector4f(0.8, 0.75, 0.6, 1).data());
	glMaterialfv(GL_FRONT_AND_BACK, GL_SPECULAR, Vector4f(1, 1, 1, 1).data());
	glMaterialf(GL_FRONT_AND_BACK, GL_SHININESS, 64);

	glEnable(GL_LIGHTING);
	glEnable(GL_LIGHT0);
	glEnable(GL_LIGHT1);

	sFancySpheres.draw();
	glVertexPointer(3, GL_FLOAT, 0, mVertices[0].data());
	glNormalPointer(GL_FLOAT, 0, mNormals[0].data());
	glEnableClientState(GL_VERTEX_ARRAY);
	glEnableClientState(GL_NORMAL_ARRAY);
	glDrawArrays(GL_TRIANGLES, 0, mVertices.size());
	glDisableClientState(GL_VERTEX_ARRAY);
	glDisableClientState(GL_NORMAL_ARRAY);

	glDisable(GL_LIGHTING);
	}

	void RenderingWidget::animate() {
	m_alpha += double(m_timer.interval()) * 1e-3;

	TimeLine::const_iterator hi = m_timeline.upper_bound(m_alpha);
	TimeLine::const_iterator lo = hi;
	--lo;

	Frame currentFrame;

	if (hi == m_timeline.end()) {
	// end
	currentFrame = lo->second;
	stopAnimation();
	} else if (hi == m_timeline.begin()) {
	// start
	currentFrame = hi->second;
	} else {
	float s = (m_alpha - lo->first) / (hi->first - lo->first);
	if (mLerpMode == LerpEulerAngles)
	currentFrame = ::lerpFrame<EulerAngles<float> >(s, lo->second, hi->second);
	else if (mLerpMode == LerpQuaternion)
	currentFrame = ::lerpFrame<Eigen::Quaternionf>(s, lo->second, hi->second);
	else {
	std::cerr << "Invalid rotation interpolation mode (abort)\n";
	exit(2);
	}
	currentFrame.orientation.coeffs().normalize();
	}

	currentFrame.orientation = currentFrame.orientation.inverse();
	currentFrame.position = -(currentFrame.orientation * currentFrame.position);
	mCamera.setFrame(currentFrame);

	updateGL();
	}

	void RenderingWidget::keyPressEvent(QKeyEvent* e) {
	switch (e->key()) {
	case Qt::Key_Up:
	mCamera.zoom(2);
	break;
	case Qt::Key_Down:
	mCamera.zoom(-2);
	break;
	// add a frame
	case Qt::Key_G:
	grabFrame();
	break;
	// clear the time line
	case Qt::Key_C:
	m_timeline.clear();
	break;
	// move the camera to initial pos
	case Qt::Key_R:
	resetCamera();
	break;
	// start/stop the animation
	case Qt::Key_A:
	if (mAnimate) {
	stopAnimation();
	} else {
	m_alpha = 0;
	connect(&m_timer, SIGNAL(timeout()), this, SLOT(animate()));
	m_timer.start(1000 / 30);
	mAnimate = true;
	}
	break;
	default:
	break;
	}

	updateGL();
	}

	void RenderingWidget::stopAnimation() {
	disconnect(&m_timer, SIGNAL(timeout()), this, SLOT(animate()));
	m_timer.stop();
	mAnimate = false;
	m_alpha = 0;
	}

	void RenderingWidget::mousePressEvent(QMouseEvent* e) {
	mMouseCoords = Vector2i(e->pos().x(), e->pos().y());
	bool fly = (mNavMode == NavFly) \|\| (e->modifiers() & Qt::ControlModifier);
	switch (e->button()) {
	case Qt::LeftButton:
	if (fly) {
	mCurrentTrackingMode = TM_LOCAL_ROTATE;
	mTrackball.start(Trackball::Local);
	} else {
	mCurrentTrackingMode = TM_ROTATE_AROUND;
	mTrackball.start(Trackball::Around);
	}
	mTrackball.track(mMouseCoords);
	break;
	case Qt::MidButton:
	if (fly)
	mCurrentTrackingMode = TM_FLY_Z;
	else
	mCurrentTrackingMode = TM_ZOOM;
	break;
	case Qt::RightButton:
	mCurrentTrackingMode = TM_FLY_PAN;
	break;
	default:
	break;
	}
	}
	void RenderingWidget::mouseReleaseEvent(QMouseEvent*) {
	mCurrentTrackingMode = TM_NO_TRACK;
	updateGL();
	}

	void RenderingWidget::mouseMoveEvent(QMouseEvent* e) {
	// tracking
	if (mCurrentTrackingMode != TM_NO_TRACK) {
	float dx = float(e->x() - mMouseCoords.x()) / float(mCamera.vpWidth());
	float dy = -float(e->y() - mMouseCoords.y()) / float(mCamera.vpHeight());

	// speedup the transformations
	if (e->modifiers() & Qt::ShiftModifier) {
	dx *= 10.;
	dy *= 10.;
	}

	switch (mCurrentTrackingMode) {
	case TM_ROTATE_AROUND:
	case TM_LOCAL_ROTATE:
	if (mRotationMode == RotationStable) {
	// use the stable trackball implementation mapping
	// the 2D coordinates to 3D points on a sphere.
	mTrackball.track(Vector2i(e->pos().x(), e->pos().y()));
	} else {
	// standard approach mapping the x and y displacements as rotations
	// around the camera's X and Y axes.
	Quaternionf q = AngleAxisf(dx * M_PI, Vector3f::UnitY()) * AngleAxisf(-dy * M_PI, Vector3f::UnitX());
	if (mCurrentTrackingMode == TM_LOCAL_ROTATE)
	mCamera.localRotate(q);
	else
	mCamera.rotateAroundTarget(q);
	}
	break;
	case TM_ZOOM:
	mCamera.zoom(dy * 100);
	break;
	case TM_FLY_Z:
	mCamera.localTranslate(Vector3f(0, 0, -dy * 200));
	break;
	case TM_FLY_PAN:
	mCamera.localTranslate(Vector3f(dx * 200, dy * 200, 0));
	break;
	default:
	break;
	}

	updateGL();
	}

	mMouseCoords = Vector2i(e->pos().x(), e->pos().y());
	}

	void RenderingWidget::paintGL() {
	glEnable(GL_DEPTH_TEST);
	glDisable(GL_CULL_FACE);
	glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
	glDisable(GL_COLOR_MATERIAL);
	glDisable(GL_BLEND);
	glDisable(GL_ALPHA_TEST);
	glDisable(GL_TEXTURE_1D);
	glDisable(GL_TEXTURE_2D);
	glDisable(GL_TEXTURE_3D);

	// Clear buffers
	glClear(GL_COLOR_BUFFER_BIT \| GL_DEPTH_BUFFER_BIT);

	mCamera.activateGL();

	drawScene();
	}

	void RenderingWidget::initializeGL() {
	glClearColor(1., 1., 1., 0.);
	glLightModeli(GL_LIGHT_MODEL_LOCAL_VIEWER, 1);
	glDepthMask(GL_TRUE);
	glColorMask(GL_TRUE, GL_TRUE, GL_TRUE, GL_TRUE);

	mCamera.setPosition(Vector3f(-200, -200, -200));
	mCamera.setTarget(Vector3f(0, 0, 0));
	mInitFrame.orientation = mCamera.orientation().inverse();
	mInitFrame.position = mCamera.viewMatrix().translation();
	}

	void RenderingWidget::resizeGL(int width, int height) { mCamera.setViewport(width, height); }

	void RenderingWidget::setNavMode(int m) { mNavMode = NavMode(m); }

	void RenderingWidget::setLerpMode(int m) { mLerpMode = LerpMode(m); }

	void RenderingWidget::setRotationMode(int m) { mRotationMode = RotationMode(m); }

	void RenderingWidget::resetCamera() {
	if (mAnimate) stopAnimation();
	m_timeline.clear();
	Frame aux0 = mCamera.frame();
	aux0.orientation = aux0.orientation.inverse();
	aux0.position = mCamera.viewMatrix().translation();
	m_timeline[0] = aux0;

	Vector3f currentTarget = mCamera.target();
	mCamera.setTarget(Vector3f::Zero());

	// compute the rotation duration to move the camera to the target
	Frame aux1 = mCamera.frame();
	aux1.orientation = aux1.orientation.inverse();
	aux1.position = mCamera.viewMatrix().translation();
	float duration = aux0.orientation.angularDistance(aux1.orientation) * 0.9;
	if (duration < 0.1) duration = 0.1;

	// put the camera at that time step:
	aux1 = aux0.lerp(duration / 2, mInitFrame);
	// and make it look at the target again
	aux1.orientation = aux1.orientation.inverse();
	aux1.position = -(aux1.orientation * aux1.position);
	mCamera.setFrame(aux1);
	mCamera.setTarget(Vector3f::Zero());

	// add this camera keyframe
	aux1.orientation = aux1.orientation.inverse();
	aux1.position = mCamera.viewMatrix().translation();
	m_timeline[duration] = aux1;

	m_timeline[2] = mInitFrame;
	m_alpha = 0;
	animate();
	connect(&m_timer, SIGNAL(timeout()), this, SLOT(animate()));
	m_timer.start(1000 / 30);
	mAnimate = true;
	}

	QWidget* RenderingWidget::createNavigationControlWidget() {
	QWidget* panel = new QWidget();
	QVBoxLayout* layout = new QVBoxLayout();

	{
	QPushButton* but = new QPushButton("reset");
	but->setToolTip("move the camera to initial position (with animation)");
	layout->addWidget(but);
	connect(but, SIGNAL(clicked()), this, SLOT(resetCamera()));
	}
	{
	// navigation mode
	QGroupBox* box = new QGroupBox("navigation mode");
	QVBoxLayout* boxLayout = new QVBoxLayout;
	QButtonGroup* group = new QButtonGroup(panel);
	QRadioButton* but;
	but = new QRadioButton("turn around");
	but->setToolTip("look around an object");
	group->addButton(but, NavTurnAround);
	boxLayout->addWidget(but);
	but = new QRadioButton("fly");
	but->setToolTip("free navigation like a spaceship\n(this mode can also be enabled pressing the \"shift\" key)");
	group->addButton(but, NavFly);
	boxLayout->addWidget(but);
	group->button(mNavMode)->setChecked(true);
	connect(group, SIGNAL(buttonClicked(int)), this, SLOT(setNavMode(int)));
	box->setLayout(boxLayout);
	layout->addWidget(box);
	}
	{
	// track ball, rotation mode
	QGroupBox* box = new QGroupBox("rotation mode");
	QVBoxLayout* boxLayout = new QVBoxLayout;
	QButtonGroup* group = new QButtonGroup(panel);
	QRadioButton* but;
	but = new QRadioButton("stable trackball");
	group->addButton(but, RotationStable);
	boxLayout->addWidget(but);
	but->setToolTip("use the stable trackball implementation mapping\nthe 2D coordinates to 3D points on a sphere");
	but = new QRadioButton("standard rotation");
	group->addButton(but, RotationStandard);
	boxLayout->addWidget(but);
	but->setToolTip(
	"standard approach mapping the x and y displacements\nas rotations around the camera's X and Y axes");
	group->button(mRotationMode)->setChecked(true);
	connect(group, SIGNAL(buttonClicked(int)), this, SLOT(setRotationMode(int)));
	box->setLayout(boxLayout);
	layout->addWidget(box);
	}
	{
	// interpolation mode
	QGroupBox* box = new QGroupBox("spherical interpolation");
	QVBoxLayout* boxLayout = new QVBoxLayout;
	QButtonGroup* group = new QButtonGroup(panel);
	QRadioButton* but;
	but = new QRadioButton("quaternion slerp");
	group->addButton(but, LerpQuaternion);
	boxLayout->addWidget(but);
	but->setToolTip("use quaternion spherical interpolation\nto interpolate orientations");
	but = new QRadioButton("euler angles");
	group->addButton(but, LerpEulerAngles);
	boxLayout->addWidget(but);
	but->setToolTip("use Euler angles to interpolate orientations");
	group->button(mNavMode)->setChecked(true);
	connect(group, SIGNAL(buttonClicked(int)), this, SLOT(setLerpMode(int)));
	box->setLayout(boxLayout);
	layout->addWidget(box);
	}
	layout->addItem(new QSpacerItem(0, 0, QSizePolicy::Minimum, QSizePolicy::Expanding));
	panel->setLayout(layout);
	return panel;
	}

	QuaternionDemo::QuaternionDemo() {
	mRenderingWidget = new RenderingWidget();
	setCentralWidget(mRenderingWidget);

	QDockWidget* panel = new QDockWidget("navigation", this);
	panel->setAllowedAreas((QFlags<Qt::DockWidgetArea>)(Qt::RightDockWidgetArea \| Qt::LeftDockWidgetArea));
	addDockWidget(Qt::RightDockWidgetArea, panel);
	panel->setWidget(mRenderingWidget->createNavigationControlWidget());
	}

	int main(int argc, char* argv[]) {
	std::cout << "Navigation:\n";
	std::cout << " left button: rotate around the target\n";
	std::cout << " middle button: zoom\n";
	std::cout << " left button + ctrl quake rotate (rotate around camera position)\n";
	std::cout << " middle button + ctrl walk (progress along camera's z direction)\n";
	std::cout << " left button: pan (translate in the XY camera's plane)\n\n";
	std::cout << "R : move the camera to initial position\n";
	std::cout << "A : start/stop animation\n";
	std::cout << "C : clear the animation\n";
	std::cout << "G : add a key frame\n";

	QApplication app(argc, argv);
	QuaternionDemo demo;
	demo.resize(600, 500);
	demo.show();
	return app.exec();
	}

	#include "quaternion_demo.moc"