added some more docs, split up the lib file

2022-09-18 12:06:45 +02:00 · 2022-09-18 12:06:45 +02:00 · ea5ddbf099
commit ea5ddbf099
parent fa3ee3d0ff
2 changed files with 185 additions and 176 deletions
--- a/src/lib.rs
+++ b/src/lib.rs
@ -1,13 +1,14 @@
 use bevy::ecs::query::QueryEntityError;
 use bevy::prelude::*;
 use bevy::transform::TransformSystem;
 #[cfg(feature = "debug_lines")]
 use bevy_prototype_debug_lines::{DebugLines, DebugLinesPlugin};
 mod solver;
 /// The inverse kinematics plugin.
 /// Should be added to your app if you want to use this crate.
 pub struct InverseKinematicsPlugin;
 /// Inverse kintematics constraint to be added to the tail joint of
-/// the bone chain that should be constrained.
+/// a chain of bones. The solver will attempt to match the global translation of
 /// of this entity to that of the target.
 #[derive(Component)]
 pub struct IkConstraint {
    /// How many bones are included in the IK constraint.
@ -17,184 +18,22 @@ pub struct IkConstraint {
    /// Target entity. The target must have a `Transform` and `GlobalTransform`.
    pub target: Entity,
    /// Target entity for pole rotation.
    /// If this would be a person's arm, this is the direction that the elbow will point.
    pub pole_target: Option<Entity>,
-    /// Offset for pole rotation in radians.
+    /// Pole target roll offset.
    /// If a pole target is set, the bone will roll toward the pole target.
    /// This angle is the offset to apply to the roll.
    pub pole_angle: f32,
 }
 struct PoleTarget {
    origin: Vec3,
    tangent: Vec3,
    normal: Vec3,
    angle: f32,
 }
 pub fn inverse_kinematics_solver_system(
    query: Query<(Entity, &IkConstraint)>,
    parents: Query<&Parent>,
    mut transforms: Query<(&mut Transform, &mut GlobalTransform)>,
    #[cfg(feature = "debug_lines")] mut debug_lines: ResMut<DebugLines>,
 ) {
    for (entity, constraint) in query.iter() {
        if let Err(e) = constraint.solve(
            entity,
            &parents,
            &mut transforms,
            #[cfg(feature = "debug_lines")]
            &mut debug_lines,
        ) {
            bevy::log::warn!("Failed to solve IK constraint: {e}");
        }
    }
 }
 impl IkConstraint {
    fn solve(
        &self,
        entity: Entity,
        parents: &Query<&Parent>,
        transforms: &mut Query<(&mut Transform, &mut GlobalTransform)>,
        #[cfg(feature = "debug_lines")] debug_lines: &mut DebugLines,
    ) -> Result<(), QueryEntityError> {
        if self.chain_length == 0 {
            return Ok(());
        }
        let mut joints = Vec::with_capacity(self.chain_length + 2);
        joints.push(entity);
        for i in 0..self.chain_length + 1 {
            joints.push(parents.get(joints[i])?.get());
        }
        let target = transforms.get(self.target)?.1.translation();
        let normal = transforms.get(joints[0])?.0.translation;
        let pole_target = if let Some(pole_target) = self.pole_target {
            let start = transforms.get(joints[self.chain_length])?.1.translation();
            let pole_target = transforms.get(pole_target)?.1.translation();
            let tangent = (target - start).normalize();
            let axis = (pole_target - start).cross(tangent);
            let normal = tangent.cross(axis).normalize();
            Some(PoleTarget {
                origin: start,
                tangent,
                normal,
                angle: self.pole_angle,
            })
        } else {
            None
        };
        for _ in 0..self.iterations {
            let result = Self::solve_recursive(
                &joints[1..],
                normal,
                target,
                pole_target.as_ref(),
                transforms,
                #[cfg(feature = "debug_lines")]
                debug_lines,
            )?;
            if result.mul_vec3(normal).distance_squared(target) < 0.001 {
                return Ok(());
            }
        }
        Ok(())
    }
    fn solve_recursive(
        chain: &[Entity],
        normal: Vec3,
        target: Vec3,
        pole_target: Option<&PoleTarget>,
        transforms: &mut Query<(&mut Transform, &mut GlobalTransform)>,
        #[cfg(feature = "debug_lines")] debug_lines: &mut DebugLines,
    ) -> Result<GlobalTransform, QueryEntityError> {
        let (&transform, &global_transform) = transforms.get(chain[0])?;
        if chain.len() == 1 {
            return Ok(global_transform);
        }
        let parent_normal = transform.translation;
        // determine absolute rotation and translation for this bone where the tail touches the
        // target.
        let rotation = if let Some(pt) = pole_target {
            let on_pole = pt.origin
                + (global_transform.translation() - pt.origin).project_onto_normalized(pt.tangent);
            let distance = on_pole.distance(global_transform.translation());
            let from_position = on_pole + pt.normal * distance;
            let base = Quat::from_rotation_arc(normal.normalize(), Vec3::Z);
            let forward = (target - from_position).normalize();
            let up = forward.cross(pt.normal).normalize();
            let right = up.cross(forward);
            let orientation = Mat3::from_cols(right, up, forward) * Mat3::from_rotation_z(pt.angle);
            (Quat::from_mat3(&orientation) * base).normalize()
        } else {
            Quat::from_rotation_arc(
                normal.normalize(),
                (target - global_transform.translation()).normalize(),
            )
            .normalize()
        };
        let translation = target - rotation.mul_vec3(normal);
        #[cfg(feature = "debug_lines")]
        {
            let p = translation;
            debug_lines.line_colored(p, p + rotation.mul_vec3(Vec3::X * 0.1), 0.0, Color::RED);
            debug_lines.line_colored(p, p + rotation.mul_vec3(Vec3::Y * 0.1), 0.0, Color::GREEN);
            debug_lines.line_colored(p, p + rotation.mul_vec3(Vec3::Z * 0.1), 0.0, Color::BLUE);
            debug_lines.line_colored(p, p + rotation.mul_vec3(normal), 0.0, Color::YELLOW);
        }
        // recurse to target the parent towards the current translation
        let parent_global_transform = Self::solve_recursive(
            &chain[1..],
            parent_normal,
            translation,
            pole_target,
            transforms,
            #[cfg(feature = "debug_lines")]
            debug_lines,
        )?;
        // apply constraints on the way back from recursing
        let (mut transform, mut global_transform) = transforms.get_mut(chain[0]).unwrap();
        transform.rotation = Quat::from_affine3(&parent_global_transform.affine())
            .inverse()
            .normalize()
            * rotation;
        *global_transform = parent_global_transform.mul_transform(*transform);
        #[cfg(feature = "debug_lines")]
        debug_lines.line_colored(
            global_transform.translation(),
            global_transform.mul_vec3(normal),
            0.0,
            Color::CYAN,
        );
        Ok(*global_transform)
    }
 }
 impl Plugin for InverseKinematicsPlugin {
    fn build(&self, app: &mut App) {
        #[cfg(feature = "debug_lines")]
        app.add_plugin(DebugLinesPlugin::default());
-
+        app.add_system_to_stage(
-        // app.add_system_to_stage(
+            CoreStage::PostUpdate,
-        //     CoreStage::PostUpdate,
+            solver::inverse_kinematics_system
-        //     inverse_kinematics_solver_system.after(TransformSystem::TransformPropagate),
+                .after(bevy::transform::TransformSystem::TransformPropagate),
-        // );
+        );
        app.add_system(inverse_kinematics_solver_system);
    }
 }
--- a/src/solver.rs
+++ b/src/solver.rs
@ -0,0 +1,170 @@
 use bevy::prelude::*;
 use bevy::ecs::query::QueryEntityError;
 #[cfg(feature = "debug_lines")]
 use bevy_prototype_debug_lines::{DebugLines, DebugLinesPlugin};
 use super::IkConstraint;
 struct PoleTarget {
    origin: Vec3,
    tangent: Vec3,
    normal: Vec3,
    angle: f32,
 }
 pub fn inverse_kinematics_system(
    query: Query<(Entity, &IkConstraint)>,
    parents: Query<&Parent>,
    mut transforms: Query<(&mut Transform, &mut GlobalTransform)>,
    #[cfg(feature = "debug_lines")] mut debug_lines: ResMut<DebugLines>,
 ) {
    for (entity, constraint) in query.iter() {
        if let Err(e) = constraint.solve(
            entity,
            &parents,
            &mut transforms,
            #[cfg(feature = "debug_lines")]
            &mut debug_lines,
        ) {
            bevy::log::warn!("Failed to solve IK constraint: {e}");
        }
    }
 }
 impl IkConstraint {
    pub fn solve(
        &self,
        entity: Entity,
        parents: &Query<&Parent>,
        transforms: &mut Query<(&mut Transform, &mut GlobalTransform)>,
        #[cfg(feature = "debug_lines")] debug_lines: &mut DebugLines,
    ) -> Result<(), QueryEntityError> {
        if self.chain_length == 0 {
            return Ok(());
        }
        let mut joints = Vec::with_capacity(self.chain_length + 2);
        joints.push(entity);
        for i in 0..self.chain_length + 1 {
            joints.push(parents.get(joints[i])?.get());
        }
        let target = transforms.get(self.target)?.1.translation();
        let normal = transforms.get(joints[0])?.0.translation;
        let pole_target = if let Some(pole_target) = self.pole_target {
            let start = transforms.get(joints[self.chain_length])?.1.translation();
            let pole_target = transforms.get(pole_target)?.1.translation();
            let tangent = (target - start).normalize();
            let axis = (pole_target - start).cross(tangent);
            let normal = tangent.cross(axis).normalize();
            Some(PoleTarget {
                origin: start,
                tangent,
                normal,
                angle: self.pole_angle,
            })
        } else {
            None
        };
        for _ in 0..self.iterations {
            let result = Self::solve_recursive(
                &joints[1..],
                normal,
                target,
                pole_target.as_ref(),
                transforms,
                #[cfg(feature = "debug_lines")]
                debug_lines,
            )?;
            if result.mul_vec3(normal).distance_squared(target) < 0.001 {
                return Ok(());
            }
        }
        Ok(())
    }
    fn solve_recursive(
        chain: &[Entity],
        normal: Vec3,
        target: Vec3,
        pole_target: Option<&PoleTarget>,
        transforms: &mut Query<(&mut Transform, &mut GlobalTransform)>,
        #[cfg(feature = "debug_lines")] debug_lines: &mut DebugLines,
    ) -> Result<GlobalTransform, QueryEntityError> {
        let (&transform, &global_transform) = transforms.get(chain[0])?;
        if chain.len() == 1 {
            return Ok(global_transform);
        }
        let parent_normal = transform.translation;
        // determine absolute rotation and translation for this bone where the tail touches the
        // target.
        let rotation = if let Some(pt) = pole_target {
            let on_pole = pt.origin
                + (global_transform.translation() - pt.origin).project_onto_normalized(pt.tangent);
            let distance = on_pole.distance(global_transform.translation());
            let from_position = on_pole + pt.normal * distance;
            let base = Quat::from_rotation_arc(normal.normalize(), Vec3::Z);
            let forward = (target - from_position).normalize();
            let up = forward.cross(pt.normal).normalize();
            let right = up.cross(forward);
            let orientation = Mat3::from_cols(right, up, forward) * Mat3::from_rotation_z(pt.angle);
            (Quat::from_mat3(&orientation) * base).normalize()
        } else {
            Quat::from_rotation_arc(
                normal.normalize(),
                (target - global_transform.translation()).normalize(),
            )
            .normalize()
        };
        let translation = target - rotation.mul_vec3(normal);
        #[cfg(feature = "debug_lines")]
        {
            let p = translation;
            debug_lines.line_colored(p, p + rotation.mul_vec3(Vec3::X * 0.1), 0.0, Color::RED);
            debug_lines.line_colored(p, p + rotation.mul_vec3(Vec3::Y * 0.1), 0.0, Color::GREEN);
            debug_lines.line_colored(p, p + rotation.mul_vec3(Vec3::Z * 0.1), 0.0, Color::BLUE);
            debug_lines.line_colored(p, p + rotation.mul_vec3(normal), 0.0, Color::YELLOW);
        }
        // recurse to target the parent towards the current translation
        let parent_global_transform = Self::solve_recursive(
            &chain[1..],
            parent_normal,
            translation,
            pole_target,
            transforms,
            #[cfg(feature = "debug_lines")]
            debug_lines,
        )?;
        // apply constraints on the way back from recursing
        let (mut transform, mut global_transform) = transforms.get_mut(chain[0]).unwrap();
        transform.rotation = Quat::from_affine3(&parent_global_transform.affine())
            .inverse()
            .normalize()
            * rotation;
        *global_transform = parent_global_transform.mul_transform(*transform);
        #[cfg(feature = "debug_lines")]
        debug_lines.line_colored(
            global_transform.translation(),
            global_transform.mul_vec3(normal),
            0.0,
            Color::CYAN,
        );
        Ok(*global_transform)
    }
 }