Virtual Trackball Orbiting via the Exponential Map

This is an alternative trackball technique using exponential map and parallel transport to preserve distances and angles for inducing coherent and intuitive trackball rotations. For instance, displacements on straight radial lines through the screen's center are carried to arcs of the same length on great circles of the trackball. This is in contrast to state-of-the-art techniques using orthogonal projection which distorts radial distances further away from the screen's center. This implementation strictly follows the recipe given in the paper of Stantchev, G.. “Virtual Trackball Modeling and the Exponential Map.” . S2CID 44199608.

• Common trackball operations split into several operation handlers.
• Coherent and intuitive orbiting via the exponential map, see Orbit operation handler.
• Identical C11 implementation for Orbit operation handler behind cc feature gate.
• Coherent First person view aka free look or mouse look wrt Orbit operation handler.
• Observer Frame with Frame::slide(), Frame::orbit(), Frame::scale() operations in world space and their local complements in camera space and with orbit and slide operations around arbitrary points in either world or camera space.
• Gliding Clamp operation handler trait ensuring boundary conditions of observer Frame. When Delta between initial and final Frame is not orthogonal to a boundary Plane, Delta is changed in such a way that the clamped movement glides along the plane.
• Bound implementing Clamp providing customizable orthogonal boundary conditions.
• Object inspection mode scaling clip plane distances by measuring from target instead of eye.
• Scale-preserving transitioning between orthographic and perspective projection mode.
• Converting between Fixed quantities wrt to field of view, see Scope::set_fov().
• Time-free Touch gesture recognition for slide, orbit, scale, and focus operations.

See the release history to keep track of the development.

A trackball camera mode implementation can be as easy as this by delegating events of your 3D graphics library of choice to the Orbit operation handler along with other handlers.

use trackball::{
	nalgebra::{Point2, Vector3},
	Frame, Image, Orbit,
};

/// Trackball camera mode.
pub struct Trackball {
	// Frame wrt camera eye and target.
	frame: Frame<f32>,
	// Image as projection of `Scope` wrt `Frame`.
	image: Image<f32>,
	// Orbit induced by displacement on screen.
	orbit: Orbit<f32>,
}

impl Trackball {
	// Usually, a cursor position event with left mouse button being pressed.
	fn handle_left_button_displacement(&mut self, pos: &Point2<f32>) {
		// Maximum position as screen's width and height.
		let max = self.image.max();
		// Induced rotation in camera space.
		let rot = self.orbit.compute(&pos, max).unwrap_or_default();
		// Apply induced rotation to local observer frame.
		self.frame.local_orbit(&rot);
	}
	// Event when left mouse button is released again.
	fn handle_left_button_release(&mut self) {
		// Can also or instead be invoked on `Self::handle_left_button_press()`.
		self.orbit.discard();
	}
}

Identical C11 implementation for Orbit operation handler behind cc feature gate:

[dependencies]
trackball = { version = "0.12.0", features = ["cc"] }

Copyright © 2021-2024 Rouven Spreckels rs@qu1x.dev

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• Apache License, Version 2.0, (LICENSES/Apache-2.0 or https://www.apache.org/licenses/LICENSE-2.0)
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