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use crate::dynamics::solver::DeltaVel;
use crate::dynamics::{
BallJoint, IntegrationParameters, JointGraphEdge, JointIndex, JointParams, RigidBody,
};
use crate::math::{SdpMatrix, Vector};
use crate::utils::{WAngularInertia, WCross, WCrossMatrix};
#[derive(Debug)]
pub(crate) struct BallVelocityConstraint {
mj_lambda1: usize,
mj_lambda2: usize,
joint_id: JointIndex,
rhs: Vector<f32>,
pub(crate) impulse: Vector<f32>,
gcross1: Vector<f32>,
gcross2: Vector<f32>,
inv_lhs: SdpMatrix<f32>,
im1: f32,
im2: f32,
}
impl BallVelocityConstraint {
pub fn from_params(
params: &IntegrationParameters,
joint_id: JointIndex,
rb1: &RigidBody,
rb2: &RigidBody,
cparams: &BallJoint,
) -> Self {
let anchor1 = rb1.position * cparams.local_anchor1 - rb1.world_com;
let anchor2 = rb2.position * cparams.local_anchor2 - rb2.world_com;
let vel1 = rb1.linvel + rb1.angvel.gcross(anchor1);
let vel2 = rb2.linvel + rb2.angvel.gcross(anchor2);
let im1 = rb1.mass_properties.inv_mass;
let im2 = rb2.mass_properties.inv_mass;
let rhs = -(vel1 - vel2);
let lhs;
let cmat1 = anchor1.gcross_matrix();
let cmat2 = anchor2.gcross_matrix();
#[cfg(feature = "dim3")]
{
lhs = rb2
.world_inv_inertia_sqrt
.squared()
.quadform(&cmat2)
.add_diagonal(im2)
+ rb1
.world_inv_inertia_sqrt
.squared()
.quadform(&cmat1)
.add_diagonal(im1);
}
#[cfg(feature = "dim2")]
{
let ii1 = rb1.world_inv_inertia_sqrt.squared();
let ii2 = rb2.world_inv_inertia_sqrt.squared();
let m11 = im1 + im2 + cmat1.x * cmat1.x * ii1 + cmat2.x * cmat2.x * ii2;
let m12 = cmat1.x * cmat1.y * ii1 + cmat2.x * cmat2.y * ii2;
let m22 = im1 + im2 + cmat1.y * cmat1.y * ii1 + cmat2.y * cmat2.y * ii2;
lhs = SdpMatrix::new(m11, m12, m22)
}
let gcross1 = rb1.world_inv_inertia_sqrt.transform_lin_vector(anchor1);
let gcross2 = rb2.world_inv_inertia_sqrt.transform_lin_vector(anchor2);
let inv_lhs = lhs.inverse_unchecked();
BallVelocityConstraint {
joint_id,
mj_lambda1: rb1.active_set_offset,
mj_lambda2: rb2.active_set_offset,
im1,
im2,
impulse: cparams.impulse * params.warmstart_coeff,
gcross1,
gcross2,
rhs,
inv_lhs,
}
}
pub fn warmstart(&self, mj_lambdas: &mut [DeltaVel<f32>]) {
let mut mj_lambda1 = mj_lambdas[self.mj_lambda1 as usize];
let mut mj_lambda2 = mj_lambdas[self.mj_lambda2 as usize];
mj_lambda1.linear += self.im1 * self.impulse;
mj_lambda1.angular += self.gcross1.gcross(self.impulse);
mj_lambda2.linear -= self.im2 * self.impulse;
mj_lambda2.angular -= self.gcross2.gcross(self.impulse);
mj_lambdas[self.mj_lambda1 as usize] = mj_lambda1;
mj_lambdas[self.mj_lambda2 as usize] = mj_lambda2;
}
pub fn solve(&mut self, mj_lambdas: &mut [DeltaVel<f32>]) {
let mut mj_lambda1 = mj_lambdas[self.mj_lambda1 as usize];
let mut mj_lambda2 = mj_lambdas[self.mj_lambda2 as usize];
let vel1 = mj_lambda1.linear + mj_lambda1.angular.gcross(self.gcross1);
let vel2 = mj_lambda2.linear + mj_lambda2.angular.gcross(self.gcross2);
let dvel = -vel1 + vel2 + self.rhs;
let impulse = self.inv_lhs * dvel;
self.impulse += impulse;
mj_lambda1.linear += self.im1 * impulse;
mj_lambda1.angular += self.gcross1.gcross(impulse);
mj_lambda2.linear -= self.im2 * impulse;
mj_lambda2.angular -= self.gcross2.gcross(impulse);
mj_lambdas[self.mj_lambda1 as usize] = mj_lambda1;
mj_lambdas[self.mj_lambda2 as usize] = mj_lambda2;
}
pub fn writeback_impulses(&self, joints_all: &mut [JointGraphEdge]) {
let joint = &mut joints_all[self.joint_id].weight;
if let JointParams::BallJoint(ball) = &mut joint.params {
ball.impulse = self.impulse
}
}
}
#[derive(Debug)]
pub(crate) struct BallVelocityGroundConstraint {
mj_lambda2: usize,
joint_id: JointIndex,
rhs: Vector<f32>,
impulse: Vector<f32>,
gcross2: Vector<f32>,
inv_lhs: SdpMatrix<f32>,
im2: f32,
}
impl BallVelocityGroundConstraint {
pub fn from_params(
params: &IntegrationParameters,
joint_id: JointIndex,
rb1: &RigidBody,
rb2: &RigidBody,
cparams: &BallJoint,
flipped: bool,
) -> Self {
let (anchor1, anchor2) = if flipped {
(
rb1.position * cparams.local_anchor2 - rb1.world_com,
rb2.position * cparams.local_anchor1 - rb2.world_com,
)
} else {
(
rb1.position * cparams.local_anchor1 - rb1.world_com,
rb2.position * cparams.local_anchor2 - rb2.world_com,
)
};
let im2 = rb2.mass_properties.inv_mass;
let vel1 = rb1.linvel + rb1.angvel.gcross(anchor1);
let vel2 = rb2.linvel + rb2.angvel.gcross(anchor2);
let rhs = vel2 - vel1;
let cmat2 = anchor2.gcross_matrix();
let gcross2 = rb2.world_inv_inertia_sqrt.transform_lin_vector(anchor2);
let lhs;
#[cfg(feature = "dim3")]
{
lhs = rb2
.world_inv_inertia_sqrt
.squared()
.quadform(&cmat2)
.add_diagonal(im2);
}
#[cfg(feature = "dim2")]
{
let ii2 = rb2.world_inv_inertia_sqrt.squared();
let m11 = im2 + cmat2.x * cmat2.x * ii2;
let m12 = cmat2.x * cmat2.y * ii2;
let m22 = im2 + cmat2.y * cmat2.y * ii2;
lhs = SdpMatrix::new(m11, m12, m22)
}
let inv_lhs = lhs.inverse_unchecked();
BallVelocityGroundConstraint {
joint_id,
mj_lambda2: rb2.active_set_offset,
im2,
impulse: cparams.impulse * params.warmstart_coeff,
gcross2,
rhs,
inv_lhs,
}
}
pub fn warmstart(&self, mj_lambdas: &mut [DeltaVel<f32>]) {
let mut mj_lambda2 = mj_lambdas[self.mj_lambda2 as usize];
mj_lambda2.linear -= self.im2 * self.impulse;
mj_lambda2.angular -= self.gcross2.gcross(self.impulse);
mj_lambdas[self.mj_lambda2 as usize] = mj_lambda2;
}
pub fn solve(&mut self, mj_lambdas: &mut [DeltaVel<f32>]) {
let mut mj_lambda2 = mj_lambdas[self.mj_lambda2 as usize];
let vel2 = mj_lambda2.linear + mj_lambda2.angular.gcross(self.gcross2);
let dvel = vel2 + self.rhs;
let impulse = self.inv_lhs * dvel;
self.impulse += impulse;
mj_lambda2.linear -= self.im2 * impulse;
mj_lambda2.angular -= self.gcross2.gcross(impulse);
mj_lambdas[self.mj_lambda2 as usize] = mj_lambda2;
}
pub fn writeback_impulses(&self, joints_all: &mut [JointGraphEdge]) {
let joint = &mut joints_all[self.joint_id].weight;
if let JointParams::BallJoint(ball) = &mut joint.params {
ball.impulse = self.impulse
}
}
}