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/*
render/camera.cc
This file is part of the Osirion project and is distributed under
the terms and conditions of the GNU General Public License version 2
*/
#include "core/core.h"
#include "math/mathlib.h"
#include "math/matrix4f.h"
#include "render/camera.h"
#include "render/gl.h"
#include "sys/sys.h"
using math::degrees360f;
using math::degrees180f;
namespace render
{
const float MIN_DELTA = 10e-10;
const float pitch_track = -15.0f;
const float pitch_overview = -75.0f;
float Camera::camera_aspect = 1.0f;
math::Vector3f Camera::camera_eye;
math::Vector3f Camera::camera_target;
math::Axis Camera::camera_axis;
Camera::Mode Camera::camera_mode;
// current and target yaw angle in XZ plane, positive is looking left
float Camera::direction_current;
float Camera::direction_target;
float Camera::target_direction;
// current and target pitch angle in XY, positive is looking up
float Camera::pitch_current;
float Camera::pitch_target;
float Camera::target_pitch;
float Camera::distance;
void Camera::init()
{
camera_aspect = 1.0f;
direction_current = 0;
direction_target = 0;
pitch_current = pitch_track * 2;
pitch_target = pitch_track;
target_pitch = 0.0f;
target_direction = 0.0f;
distance = 0.4f;
set_mode(Track);
camera_axis.clear();
camera_eye.clear();
camera_target.clear();
}
void Camera::shutdown()
{
}
void Camera::set_aspect(float aspect)
{
camera_aspect = aspect;
}
void Camera::set_mode(Mode newmode) {
direction_target = 0;
direction_current = direction_target;
pitch_target = pitch_track;
pitch_current = pitch_target;
target_direction = 0.0f;
target_pitch = 0.0f;
distance = 0.4f;
camera_axis.clear();
switch(newmode) {
case Track:
// switch camera to Track mode
camera_mode = Track;
if (core::localcontrol()) {
if (core::localcontrol()->state())
camera_axis.assign(core::localcontrol()->state()->axis());
else
camera_axis.assign(core::localcontrol()->axis());
}
break;
case Free:
// switch camera to Free mode
camera_mode = Free;
pitch_target = 2.0 * pitch_track;
pitch_current = pitch_target;
break;
case Cockpit:
camera_mode = Cockpit;
break;
case Overview:
// switch camera to Overview mode
camera_mode = Overview;
default:
break;
}
}
void Camera::next_mode()
{
if (!core::localcontrol()) {
set_mode(Overview);
return;
}
switch(camera_mode) {
case Free:
// switch camera to Track mode
set_mode(Track);
core::application()->notify_message(std::string("view: track"));
break;
case Track:
// switch camera to Cockpit mode
set_mode(Cockpit);
core::application()->notify_message(std::string("view: cockpit"));
break;
case Cockpit:
// switch camera to Free mode
set_mode(Free);
core::application()->notify_message(std::string("view: free"));
break;
default:
break;
}
}
void Camera::draw(float seconds)
{
math::Matrix4f matrix;
math::Axis target_axis;
float d = 0;
if (!core::localcontrol()) {
if (camera_mode != Overview) {
set_mode(Overview);
}
camera_eye.clear();
camera_target.clear();
camera_axis.clear();
pitch_current = pitch_overview;
camera_axis.change_pitch(pitch_current);
distance = 20.0f;
} else {
if (mode() == Overview)
set_mode(Track);
if (core::localcontrol()->state()) {
camera_target.assign(core::localcontrol()->state()->location());
target_axis.assign(core::localcontrol()->state()->axis());
} else {
camera_target.assign(core::localcontrol()->location());
target_axis.assign(core::localcontrol()->axis());
}
if (core::localcontrol()->model()) {
distance = core::localcontrol()->model()->radius();
} else {
distance = 1.0f;
}
if (mode() == Track) {
float cosangle;
float angle;
float side;
float u;
//const float camspeed = 90.0f * seconds; // 180 degrees per second
math::Vector3f n;
math::Vector3f p;
// camera axis: pitch
// project target_axis.up() into the plane with axis->left() normal
n = camera_axis.left();
p = target_axis.up();
u = p[0]*n[0] + p[1]*n[1] + p[2]*n[2] / (-n[0]*n[0] - n[1]*n[1] - n[2] * n[2]);
p = target_axis.up() + u * n;
side = camera_axis.forward().x * p.x +
camera_axis.forward().y * p.y +
camera_axis.forward().z * p.z;
if ((fabs(side) - MIN_DELTA > 0)) {
cosangle = math::dotproduct(p, camera_axis.up());
if (fabs(cosangle) + MIN_DELTA < 1 ) {
angle = acos(cosangle) * 180.0f / M_PI;
angle = math::sgnf(side) * angle * seconds;
camera_axis.change_pitch(-angle);
}
}
// camera axis: direction
// project target_axis.forward() into the plane with axis.up() normal
n = camera_axis.up();
p = target_axis.forward();
u = p[0]*n[0] + p[1]*n[1] + p[2]*n[2] / (-n[0]*n[0] - n[1]*n[1] - n[2] * n[2]);
p = target_axis.forward() + u * n;
side = camera_axis.left().x * p.x +
camera_axis.left().y * p.y +
camera_axis.left().z * p.z;
if ((fabs(side) - MIN_DELTA > 0)) {
cosangle = math::dotproduct(p, camera_axis.forward());
if (fabs(cosangle) + MIN_DELTA < 1 ) {
angle = acos(cosangle) * 180.0f / M_PI;
angle = math::sgnf(side) * angle * seconds;
camera_axis.change_direction(angle);
}
}
// camera axis: roll
// project target_axis.up() into the plane with axis.forward() normal
n = camera_axis.forward();
p = target_axis.up();
u = p[0]*n[0] + p[1]*n[1] + p[2]*n[2] / (-n[0]*n[0] - n[1]*n[1] - n[2] * n[2]);
p = target_axis.up() + u * n;
side = camera_axis.left().x * p.x +
camera_axis.left().y * p.y +
camera_axis.left().z * p.z;
if ((fabs(side) - MIN_DELTA > 0)) {
cosangle = math::dotproduct(p, camera_axis.up());
if (fabs(cosangle) + MIN_DELTA < 1 ) {
angle = acos(cosangle) * 180.0f / M_PI;
angle = math::sgnf(side) * angle * seconds;
camera_axis.change_roll(angle);
}
}
/* if (core::localcontrol()->model()) {
camera_target -= (core::localcontrol()->model()->maxbbox().x + 0.1f) * camera_axis.forward();
camera_target += (core::localcontrol()->model()->maxbbox().z + 0.1f ) * camera_axis.up();
}
*/
} else if (mode() == Free) {
camera_axis.assign(target_axis);
direction_target = direction_current - 90 * target_direction;
pitch_target = pitch_current - 90 * target_pitch;
// adjust direction
d = degrees180f(direction_current - direction_target);
direction_current = degrees360f( direction_current - d * seconds);
camera_axis.change_direction(direction_current);
// adjust pitch
d = degrees180f(pitch_current - pitch_target);
pitch_current = degrees360f(pitch_current - d * seconds);
camera_axis.change_pitch(pitch_current);
} else if (mode() == Cockpit) {
camera_axis.assign(target_axis);
if (core::localcontrol()->state()) {
if (core::localcontrol()->model()) {
camera_target += (core::localcontrol()->model()->maxbbox().x+0.05) *
core::localcontrol()->state()->axis().forward();
} else {
camera_target += (core::localcontrol()->radius() + 0.05) *
core::localcontrol()->state()->axis().forward();
}
}
distance = 0.0f;
}
}
// Change to the projection matrix and set our viewing volume.
gl::matrixmode(GL_PROJECTION);
gl::loadidentity();
const float frustum_size = 0.5f;
const float frustum_front = 1.0f;
distance += frustum_front;
gl::frustum(-frustum_size*aspect(), frustum_size*aspect(), -frustum_size, frustum_size, frustum_front, 1024.0f);
// model view
gl::matrixmode(GL_MODELVIEW);
gl::loadidentity();
// map world coordinates to opengl coordinates
gl::rotate(90.0f, 0, 1.0, 0);
gl::rotate(-90.0f, 1.0f , 0, 0);
// assign transformation matrix
matrix.assign(camera_axis);
// apply the transpose of the axis transformation (the axis is orhtonormal)
gl::multmatrix(matrix.transpose());
// match the camera with the current target
gl::translate(-1.0f * camera_target);
// apply camera offset
gl::translate(distance * camera_axis.forward());
// calculate eye position
camera_eye = camera_target - (distance * camera_axis.forward());
}
void Camera::set_direction(float direction)
{
target_direction = direction;
math::clamp(target_direction, -1.0f, 1.0f);
}
void Camera::set_pitch(float pitch)
{
target_pitch = pitch;
math::clamp(target_pitch, -1.0f, 1.0f);
}
void Camera::reset()
{
set_mode(camera_mode);
}
}
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