model-converter/src/controls.rs

//! This models contains structs that help move the camera in a user-friendly way.

const EPSILON: f32 = 0.001;

use glium::glutin::{
    Event,
    WindowEvent,
    ElementState,
    MouseButton,
    MouseScrollDelta,
    KeyboardInput,
    VirtualKeyCode,
    MouseCursor,
};

use math::vector::{Vector2, Vector3};
use camera::Camera;
use renderer::Renderer;
use model::Model;

/// The trait that all controls should implement.
pub trait Controls {

    /// Modifies the camera depending on the event.
    fn manage_event(&mut self, event: &Event, camera: &mut Camera, renderer: &Renderer);

    /// Updates the camera depending on time.
    fn update(&mut self, camera: &mut Camera, renderer: &Renderer);
}

/// An orbit controls allowing to orbit around an object.
///
/// Only object centered are supported.
pub struct OrbitControls {
    /// The last position of the mouse.
    mouse_position: Vector2<f32>,

    /// Wether the left click of the mouse is pressed or not.
    pressed: bool,

    /// The theta angle of the position of the camera in spheric coordinates.
    theta: f32,

    /// The phi angle of the position of the camera in spheric coordinates.
    phi: f32,

    /// The distance between the camera and the origin.
    distance: f32,

    /// The sensitiviy of the rotation of the mouse.
    sensitivity: f32,

    /// The center of the object.
    center: Vector3<f32>,
}

impl OrbitControls {

    /// Creates a new orbit controls, and initializes the camera.
    pub fn new(center: Vector3<f32>, distance: f32, camera: &mut Camera) -> OrbitControls {
        let controls = OrbitControls {
            mouse_position: Vector2::new(0.0, 0.0),
            pressed: false,
            theta: 0.0,
            phi: 0.0,
            distance: distance,
            sensitivity: 200.0,
            center: center,
        };

        *camera.position.x_mut() = controls.distance * controls.theta.cos();
        *camera.position.y_mut() = 0.0;
        *camera.position.z_mut() = controls.distance * controls.phi.sin();
        camera.position += controls.center;
        camera.target = controls.center;

        controls
    }

    /// Creates orbit controls that are mode to rotate around a model.
    pub fn around(model: &Model, camera: &mut Camera) -> OrbitControls {
        // Compute bounding box
        let bounding_box = model.bounding_box();
        let center = (bounding_box.min() + bounding_box.max()) / 2.0;
        let distance = (bounding_box.max() - bounding_box.min()).norm();

        OrbitControls::new(
            Vector3::new(center.x() as f32, center.y() as f32, center.z() as f32),
            distance as f32,
            camera
        )

    }
}

impl Controls for OrbitControls {
    fn manage_event(&mut self, event: &Event, camera: &mut Camera, _: &Renderer) {
        match *event {

            Event::WindowEvent {
                event: WindowEvent::MouseInput {
                    button: MouseButton::Left,
                    state, ..
                }, ..
            } => {
                self.pressed = state == ElementState::Pressed;
            },

            Event::WindowEvent {
                event: WindowEvent::Resized(width, height), ..
            } => {
                camera.aspect_ratio = width as f32 / height as f32;
            },

            Event::WindowEvent {
                event: WindowEvent::MouseWheel {
                    delta: MouseScrollDelta::LineDelta(_, y), ..
                }, ..
            } => {
                self.distance -= y / self.sensitivity;

                *camera.position.x_mut() = self.distance * self.phi.cos() * self.theta.cos();
                *camera.position.y_mut() = self.distance * self.phi.sin();
                *camera.position.z_mut() = self.distance * self.phi.cos() * self.theta.sin();

                camera.position += self.center;
                camera.target = self.center;
            },

            Event::WindowEvent{
                event: WindowEvent::CursorMoved {
                    position: (x, y), ..
                }, ..
            } => {
                let current_position = Vector2::new(x as f32, y as f32);

                if self.pressed {
                    let difference = (current_position - self.mouse_position) / self.sensitivity;

                    self.theta += difference.x();
                    self.phi   += difference.y();

                    use std::f32::consts::PI;
                    self.phi = self.phi.max(- PI/2.0 + EPSILON);
                    self.phi = self.phi.min(  PI/2.0 - EPSILON);

                    *camera.position.x_mut() = self.distance * self.phi.cos() * self.theta.cos();
                    *camera.position.y_mut() = self.distance * self.phi.sin();
                    *camera.position.z_mut() = self.distance * self.phi.cos() * self.theta.sin();

                    camera.position += self.center;
                    camera.target = self.center;

                }

                // Record new position
                self.mouse_position = current_position;
            },

            _ => (),
        }
    }

    fn update(&mut self, _: &mut Camera, _: &Renderer) {

    }
}

/// First person controls, just like in video games.
pub struct FirstPersonControls {

    /// Theta angle of the spheric coordinates of the direction of the camera.
    theta: f32,

    /// Phi angle of the spheric coordinates of the direction of the camera.
    phi: f32,

    /// Current position of the camera.
    position: Vector3<f32>,

    /// Vector indicating the direction of the camera.
    forward: Vector3<f32>,

    /// Vector indicating the left of the camera.
    left: Vector3<f32>,

    /// Speed of the camera.
    speed: f32,

    /// Sensitivity of the mouse.
    sensitivity: f32,

    /// Wether the forward button is pressed or not.
    forward_pressed: bool,

    /// Wether the backward button is pressed or not.
    backward_pressed: bool,

    /// Wether the left button is pressed or not.
    left_pressed: bool,

    /// Wether the right button is pressed or not.
    right_pressed: bool,

    /// Wether the boost is active or not.
    boost: bool,
}

impl FirstPersonControls {
    /// Creates a new default first person controls.
    pub fn new() -> FirstPersonControls {
        FirstPersonControls {
            theta: 0.0,
            phi: 0.0,
            position: Vector3::new(0.0, 0.0, 0.0),
            forward: Vector3::new(0.0, 0.0, 1.0),
            left: Vector3::new(1.0, 0.0, 0.0),
            speed: 0.001,
            forward_pressed: false,
            backward_pressed: false,
            left_pressed: false,
            right_pressed: false,
            boost: false,
            sensitivity: 500.0,
        }
    }

    /// Updates the camera according to the state of the controls.
    pub fn update_camera(&self, camera: &mut Camera) {
        camera.position = self.position;
        camera.target = self.position + self.forward;
    }
}

impl Controls for FirstPersonControls {

    fn manage_event(&mut self, event: &Event, camera: &mut Camera, renderer: &Renderer) {
        match *event {

            // On resize window
            Event::WindowEvent {
                event: WindowEvent::Resized(width, height), ..
            } => {
                camera.aspect_ratio = width as f32 / height as f32;
            },

            // On Z pressed
            Event::WindowEvent {
                event: WindowEvent::KeyboardInput {
                    input: KeyboardInput {
                        virtual_keycode: Some(VirtualKeyCode::Z), state, ..
                    }, ..
                }, ..
            } => {
                self.forward_pressed = state == ElementState::Pressed;
            },

            // On S pressed
            Event::WindowEvent {
                event: WindowEvent::KeyboardInput {
                    input: KeyboardInput {
                        virtual_keycode: Some(VirtualKeyCode::S), state, ..
                    }, ..
                }, ..
            } => {
                self.backward_pressed = state == ElementState::Pressed;
            },

            // On Q pressed
            Event::WindowEvent {
                event: WindowEvent::KeyboardInput {
                    input: KeyboardInput {
                        virtual_keycode: Some(VirtualKeyCode::Q), state, ..
                    }, ..
                }, ..
            } => {
                self.left_pressed = state == ElementState::Pressed;
            },

            // On D pressed
            Event::WindowEvent {
                event: WindowEvent::KeyboardInput {
                    input: KeyboardInput {
                        virtual_keycode: Some(VirtualKeyCode::D), state, ..
                    }, ..
                }, ..
            } => {
                self.right_pressed = state == ElementState::Pressed;
            },

            // On Space pressed
            Event::WindowEvent {
                event: WindowEvent::KeyboardInput {
                    input: KeyboardInput {
                        virtual_keycode: Some(VirtualKeyCode::Space), state, ..
                    }, ..
                }, ..
            } => {
                self.boost = state == ElementState::Pressed;
            },

            // On mouse move
            Event::WindowEvent {
                event: WindowEvent::CursorMoved {
                    position: (x, y), ..
                }, ..
            } => {

                let size = renderer.gl_window().window().get_inner_size().unwrap();
                let center = Vector2::new(size.0 as f32 / 2.0, size.1 as f32 / 2.0);
                let current_position = Vector2::new(x as f32, y as f32);
                let difference = (current_position - center) / self.sensitivity;

                self.theta += difference.x();
                self.phi   -= difference.y();

                use std::f32::consts::PI;
                self.phi = self.phi.max(- PI/2.0 + EPSILON);
                self.phi = self.phi.min(  PI/2.0 - EPSILON);

                self.forward = Vector3::new(
                    self.phi.cos() * self.theta.cos(),
                    self.phi.sin(),
                    self.phi.cos() * self.theta.sin(),
                );

                self.left = Vector3::new(0.0, 1.0, 0.0).cross_product(self.forward).normalized();

                // Move the cursor back to the center
                renderer
                    .gl_window()
                    .window()
                    .set_cursor_position(size.0 as i32 / 2, size.1 as i32/ 2)
                    .unwrap();

            },


            _ => (),

        }

        self.update_camera(camera);
    }

    fn update(&mut self, camera: &mut Camera, renderer: &Renderer) {

        renderer.gl_window().window().set_cursor(MouseCursor::NoneCursor);

        let mut speed = Vector3::new(0.0, 0.0, 0.0);

        if self.forward_pressed {
            speed += self.forward * self.speed;
        }

        if self.backward_pressed {
            speed -= self.forward * self.speed;
        }

        if self.left_pressed {
            speed += self.left * self.speed;
        }

        if self.right_pressed {
            speed -= self.left * self.speed;
        }

        if self.boost {
            speed *= 10.0;
        }

        self.position += speed;

        self.update_camera(camera);
    }
}