dust3d/third_party/libigl/include/igl/Camera.h

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// This file is part of libigl, a simple c++ geometry processing library.
//
// Copyright (C) 2013 Alec Jacobson <alecjacobson@gmail.com>
//
// 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/.
#ifndef IGL_CAMERA_H
#define IGL_CAMERA_H
// you're idiot, M$!
#if defined(_WIN32)
#undef far
#undef near
#endif
#include <Eigen/Geometry>
#include <Eigen/Core>
#include "PI.h"
#define IGL_CAMERA_MIN_ANGLE 5.0
namespace igl
{
// A simple camera class. The camera stores projection parameters (field of
// view angle, aspect ratio, near and far clips) as well as a rigid
// transformation *of the camera as if it were also a scene object*. Thus, the
// **inverse** of this rigid transformation is the modelview transformation.
class Camera
{
public:
// On windows you might need: -fno-delayed-template-parsing
//static constexpr double IGL_CAMERA_MIN_ANGLE = 5.;
// m_angle Field of view angle in degrees {45}
// m_aspect Aspect ratio {1}
// m_near near clipping plane {1e-2}
// m_far far clipping plane {100}
// m_at_dist distance of looking at point {1}
// m_orthographic whether to use othrographic projection {false}
// m_rotation_conj Conjugate of rotation part of rigid transformation of
// camera {identity}. Note: we purposefully store the conjugate because
// this is what TW_TYPE_QUAT4D is expecting.
// m_translation Translation part of rigid transformation of camera
// {(0,0,1)}
double m_angle, m_aspect, m_near, m_far, m_at_dist;
bool m_orthographic;
Eigen::Quaterniond m_rotation_conj;
Eigen::Vector3d m_translation;
public:
inline Camera();
inline virtual ~Camera(){}
// Return projection matrix that takes relative camera coordinates and
// transforms it to viewport coordinates
//
// Note:
//
// if(m_angle > 0)
// {
// gluPerspective(m_angle,m_aspect,m_near,m_at_dist+m_far);
// }else
// {
// gluOrtho(-0.5*aspect,0.5*aspect,-0.5,0.5,m_at_dist+m_near,m_far);
// }
//
// Is equivalent to
//
// glMultMatrixd(projection().data());
//
inline Eigen::Matrix4d projection() const;
// Return an Affine transformation (rigid actually) that
// takes relative coordinates and tramsforms them into world 3d
// coordinates: moves the camera into the scene.
inline Eigen::Affine3d affine() const;
// Return an Affine transformation (rigid actually) that puts the takes a
// world 3d coordinate and transforms it into the relative camera
// coordinates: moves the scene in front of the camera.
//
// Note:
//
// gluLookAt(
// eye()(0), eye()(1), eye()(2),
// at()(0), at()(1), at()(2),
// up()(0), up()(1), up()(2));
//
// Is equivalent to
//
// glMultMatrixd(camera.inverse().matrix().data());
//
// See also: affine, eye, at, up
inline Eigen::Affine3d inverse() const;
// Returns world coordinates position of center or "eye" of camera.
inline Eigen::Vector3d eye() const;
// Returns world coordinate position of a point "eye" is looking at.
inline Eigen::Vector3d at() const;
// Returns world coordinate unit vector of "up" vector
inline Eigen::Vector3d up() const;
// Return top right corner of unit plane in relative coordinates, that is
// (w/2,h/2,1)
inline Eigen::Vector3d unit_plane() const;
// Move dv in the relative coordinate frame of the camera (move the FPS)
//
// Inputs:
// dv (x,y,z) displacement vector
//
inline void dolly(const Eigen::Vector3d & dv);
// "Scale zoom": Move `eye`, but leave `at`
//
// Input:
// s amount to scale distance to at
inline void push_away(const double s);
// Aka "Hitchcock", "Vertigo", "Spielberg" or "Trombone" zoom:
// simultaneously dolly while changing angle so that `at` not only stays
// put in relative coordinates but also projected coordinates. That is
//
// Inputs:
// da change in angle in degrees
inline void dolly_zoom(const double da);
// Turn around eye so that rotation is now q
//
// Inputs:
// q new rotation as quaternion
inline void turn_eye(const Eigen::Quaterniond & q);
// Orbit around at so that rotation is now q
//
// Inputs:
// q new rotation as quaternion
inline void orbit(const Eigen::Quaterniond & q);
// Rotate and translate so that camera is situated at "eye" looking at "at"
// with "up" pointing up.
//
// Inputs:
// eye (x,y,z) coordinates of eye position
// at (x,y,z) coordinates of at position
// up (x,y,z) coordinates of up vector
inline void look_at(
const Eigen::Vector3d & eye,
const Eigen::Vector3d & at,
const Eigen::Vector3d & up);
// Needed any time Eigen Structures are used as class members
// http://eigen.tuxfamily.org/dox-devel/group__TopicStructHavingEigenMembers.html
public:
EIGEN_MAKE_ALIGNED_OPERATOR_NEW
};
}
// Implementation
#include "PI.h"
#include "EPS.h"
#include <cmath>
#include <iostream>
#include <cassert>
inline igl::Camera::Camera():
m_angle(45.0),m_aspect(1),m_near(1e-2),m_far(100),m_at_dist(1),
m_orthographic(false),
m_rotation_conj(1,0,0,0),
m_translation(0,0,1)
{
}
inline Eigen::Matrix4d igl::Camera::projection() const
{
Eigen::Matrix4d P;
using namespace std;
const double far = m_at_dist + m_far;
const double near = m_near;
// http://stackoverflow.com/a/3738696/148668
if(m_orthographic)
{
const double f = 0.5;
const double left = -f*m_aspect;
const double right = f*m_aspect;
const double bottom = -f;
const double top = f;
const double tx = (right+left)/(right-left);
const double ty = (top+bottom)/(top-bottom);
const double tz = (far+near)/(far-near);
const double z_fix = 0.5 /m_at_dist / tan(m_angle*0.5 * (igl::PI/180.) );
P<<
z_fix*2./(right-left), 0, 0, -tx,
0, z_fix*2./(top-bottom), 0, -ty,
0, 0, -z_fix*2./(far-near), -tz,
0, 0, 0, 1;
}else
{
const double yScale = tan(PI*0.5 - 0.5*m_angle*PI/180.);
// http://stackoverflow.com/a/14975139/148668
const double xScale = yScale/m_aspect;
P<<
xScale, 0, 0, 0,
0, yScale, 0, 0,
0, 0, -(far+near)/(far-near), -1,
0, 0, -2.*near*far/(far-near), 0;
P = P.transpose().eval();
}
return P;
}
inline Eigen::Affine3d igl::Camera::affine() const
{
using namespace Eigen;
Affine3d t = Affine3d::Identity();
t.rotate(m_rotation_conj.conjugate());
t.translate(m_translation);
return t;
}
inline Eigen::Affine3d igl::Camera::inverse() const
{
using namespace Eigen;
Affine3d t = Affine3d::Identity();
t.translate(-m_translation);
t.rotate(m_rotation_conj);
return t;
}
inline Eigen::Vector3d igl::Camera::eye() const
{
using namespace Eigen;
return affine() * Vector3d(0,0,0);
}
inline Eigen::Vector3d igl::Camera::at() const
{
using namespace Eigen;
return affine() * (Vector3d(0,0,-1)*m_at_dist);
}
inline Eigen::Vector3d igl::Camera::up() const
{
using namespace Eigen;
Affine3d t = Affine3d::Identity();
t.rotate(m_rotation_conj.conjugate());
return t * Vector3d(0,1,0);
}
inline Eigen::Vector3d igl::Camera::unit_plane() const
{
// Distance of center pixel to eye
const double d = 1.0;
const double a = m_aspect;
const double theta = m_angle*PI/180.;
const double w =
2.*sqrt(-d*d/(a*a*pow(tan(0.5*theta),2.)-1.))*a*tan(0.5*theta);
const double h = w/a;
return Eigen::Vector3d(w*0.5,h*0.5,-d);
}
inline void igl::Camera::dolly(const Eigen::Vector3d & dv)
{
m_translation += dv;
}
inline void igl::Camera::push_away(const double s)
{
using namespace Eigen;
#ifndef NDEBUG
Vector3d old_at = at();
#endif
const double old_at_dist = m_at_dist;
m_at_dist = old_at_dist * s;
dolly(Vector3d(0,0,1)*(m_at_dist - old_at_dist));
assert((old_at-at()).squaredNorm() < DOUBLE_EPS);
}
inline void igl::Camera::dolly_zoom(const double da)
{
using namespace std;
using namespace Eigen;
#ifndef NDEBUG
Vector3d old_at = at();
#endif
const double old_angle = m_angle;
if(old_angle + da < IGL_CAMERA_MIN_ANGLE)
{
m_orthographic = true;
}else if(old_angle + da > IGL_CAMERA_MIN_ANGLE)
{
m_orthographic = false;
}
if(!m_orthographic)
{
m_angle += da;
m_angle = min(89.,max(IGL_CAMERA_MIN_ANGLE,m_angle));
// change in distance
const double s =
(2.*tan(old_angle/2./180.*igl::PI)) /
(2.*tan(m_angle/2./180.*igl::PI)) ;
const double old_at_dist = m_at_dist;
m_at_dist = old_at_dist * s;
dolly(Vector3d(0,0,1)*(m_at_dist - old_at_dist));
assert((old_at-at()).squaredNorm() < DOUBLE_EPS);
}
}
inline void igl::Camera::turn_eye(const Eigen::Quaterniond & q)
{
using namespace Eigen;
Vector3d old_eye = eye();
// eye should be fixed
//
// eye_1 = R_1 * t_1 = eye_0
// t_1 = R_1' * eye_0
m_rotation_conj = q.conjugate();
m_translation = m_rotation_conj * old_eye;
assert((old_eye - eye()).squaredNorm() < DOUBLE_EPS);
}
inline void igl::Camera::orbit(const Eigen::Quaterniond & q)
{
using namespace Eigen;
Vector3d old_at = at();
// at should be fixed
//
// at_1 = R_1 * t_1 - R_1 * z = at_0
// t_1 = R_1' * (at_0 + R_1 * z)
m_rotation_conj = q.conjugate();
m_translation =
m_rotation_conj *
(old_at +
m_rotation_conj.conjugate() * Vector3d(0,0,1) * m_at_dist);
assert((old_at - at()).squaredNorm() < DOUBLE_EPS);
}
inline void igl::Camera::look_at(
const Eigen::Vector3d & eye,
const Eigen::Vector3d & at,
const Eigen::Vector3d & up)
{
using namespace Eigen;
using namespace std;
// http://www.opengl.org/sdk/docs/man2/xhtml/gluLookAt.xml
// Normalize vector from at to eye
Vector3d F = eye-at;
m_at_dist = F.norm();
F.normalize();
// Project up onto plane orthogonal to F and normalize
assert(up.cross(F).norm() > DOUBLE_EPS && "(eye-at) x up ≈ 0");
const Vector3d proj_up = (up-(up.dot(F))*F).normalized();
Quaterniond a,b;
a.setFromTwoVectors(Vector3d(0,0,-1),-F);
b.setFromTwoVectors(a*Vector3d(0,1,0),proj_up);
m_rotation_conj = (b*a).conjugate();
m_translation = m_rotation_conj * eye;
//cout<<"m_at_dist: "<<m_at_dist<<endl;
//cout<<"proj_up: "<<proj_up.transpose()<<endl;
//cout<<"F: "<<F.transpose()<<endl;
//cout<<"eye(): "<<this->eye().transpose()<<endl;
//cout<<"at(): "<<this->at().transpose()<<endl;
//cout<<"eye()-at(): "<<(this->eye()-this->at()).normalized().transpose()<<endl;
//cout<<"eye-this->eye(): "<<(eye-this->eye()).squaredNorm()<<endl;
assert( (eye-this->eye()).squaredNorm() < DOUBLE_EPS);
//assert((F-(this->eye()-this->at()).normalized()).squaredNorm() <
// DOUBLE_EPS);
assert( (at-this->at()).squaredNorm() < DOUBLE_EPS);
//assert( (proj_up-this->up()).squaredNorm() < DOUBLE_EPS);
}
#endif