use super::{
AnyVelocityConstraint, DeltaVel, VelocityGroundConstraintElement,
VelocityGroundConstraintNormalPart,
};
use crate::math::{Point, Real, Vector, DIM, MAX_MANIFOLD_POINTS};
#[cfg(feature = "dim2")]
use crate::utils::WBasis;
use crate::utils::{self, WAngularInertia, WCross, WDot};
use crate::dynamics::{IntegrationParameters, RigidBodySet, RigidBodyVelocity};
use crate::geometry::{ContactManifold, ContactManifoldIndex};
#[derive(Copy, Clone, Debug)]
pub(crate) struct VelocityGroundConstraint {
pub mj_lambda2: usize,
pub dir1: Vector<Real>, #[cfg(feature = "dim3")]
pub tangent1: Vector<Real>, pub im2: Vector<Real>,
pub cfm_factor: Real,
pub limit: Real,
pub elements: [VelocityGroundConstraintElement<Real>; MAX_MANIFOLD_POINTS],
pub manifold_id: ContactManifoldIndex,
pub manifold_contact_id: [u8; MAX_MANIFOLD_POINTS],
pub num_contacts: u8,
}
impl VelocityGroundConstraint {
pub fn generate(
params: &IntegrationParameters,
manifold_id: ContactManifoldIndex,
manifold: &ContactManifold,
bodies: &RigidBodySet,
out_constraints: &mut Vec<AnyVelocityConstraint>,
insert_at: Option<usize>,
) {
let cfm_factor = params.cfm_factor();
let inv_dt = params.inv_dt();
let erp_inv_dt = params.erp_inv_dt();
let mut handle1 = manifold.data.rigid_body1;
let mut handle2 = manifold.data.rigid_body2;
let flipped = manifold.data.relative_dominance < 0;
let (force_dir1, flipped_multiplier) = if flipped {
std::mem::swap(&mut handle1, &mut handle2);
(manifold.data.normal, -1.0)
} else {
(-manifold.data.normal, 1.0)
};
let (vels1, world_com1) = if let Some(handle1) = handle1 {
let rb1 = &bodies[handle1];
(rb1.vels, rb1.mprops.world_com)
} else {
(RigidBodyVelocity::zero(), Point::origin())
};
let rb2 = &bodies[handle2.unwrap()];
let vels2 = &rb2.vels;
let mprops2 = &rb2.mprops;
#[cfg(feature = "dim2")]
let tangents1 = force_dir1.orthonormal_basis();
#[cfg(feature = "dim3")]
let tangents1 =
super::compute_tangent_contact_directions(&force_dir1, &vels1.linvel, &vels2.linvel);
let mj_lambda2 = rb2.ids.active_set_offset;
for (_l, manifold_points) in manifold
.data
.solver_contacts
.chunks(MAX_MANIFOLD_POINTS)
.enumerate()
{
#[cfg(not(target_arch = "wasm32"))]
let mut constraint = VelocityGroundConstraint {
dir1: force_dir1,
#[cfg(feature = "dim3")]
tangent1: tangents1[0],
elements: [VelocityGroundConstraintElement::zero(); MAX_MANIFOLD_POINTS],
im2: mprops2.effective_inv_mass,
cfm_factor,
limit: 0.0,
mj_lambda2,
manifold_id,
manifold_contact_id: [0; MAX_MANIFOLD_POINTS],
num_contacts: manifold_points.len() as u8,
};
#[cfg(target_arch = "wasm32")]
let constraint = if insert_at.is_none() {
let new_len = out_constraints.len() + 1;
unsafe {
#[allow(invalid_value)]
out_constraints.resize_with(new_len, || {
AnyVelocityConstraint::NongroupedGround(
std::mem::MaybeUninit::uninit().assume_init(),
)
});
}
out_constraints
.last_mut()
.unwrap()
.as_nongrouped_ground_mut()
.unwrap()
} else {
unreachable!(); };
#[cfg(target_arch = "wasm32")]
{
constraint.dir1 = force_dir1;
#[cfg(feature = "dim3")]
{
constraint.tangent1 = tangents1[0];
}
constraint.im2 = mprops2.effective_inv_mass;
constraint.cfm_factor = cfm_factor;
constraint.limit = 0.0;
constraint.mj_lambda2 = mj_lambda2;
constraint.manifold_id = manifold_id;
constraint.manifold_contact_id = [0; MAX_MANIFOLD_POINTS];
constraint.num_contacts = manifold_points.len() as u8;
}
let mut is_fast_contact = false;
for k in 0..manifold_points.len() {
let manifold_point = &manifold_points[k];
let dp2 = manifold_point.point - mprops2.world_com;
let dp1 = manifold_point.point - world_com1;
let vel1 = vels1.linvel + vels1.angvel.gcross(dp1);
let vel2 = vels2.linvel + vels2.angvel.gcross(dp2);
constraint.limit = manifold_point.friction;
constraint.manifold_contact_id[k] = manifold_point.contact_id;
{
let gcross2 = mprops2
.effective_world_inv_inertia_sqrt
.transform_vector(dp2.gcross(-force_dir1));
let projected_mass = utils::inv(
force_dir1.dot(&mprops2.effective_inv_mass.component_mul(&force_dir1))
+ gcross2.gdot(gcross2),
);
let is_bouncy = manifold_point.is_bouncy() as u32 as Real;
let is_resting = 1.0 - is_bouncy;
let dvel = (vel1 - vel2).dot(&force_dir1);
let mut rhs_wo_bias = (1.0 + is_bouncy * manifold_point.restitution) * dvel;
rhs_wo_bias += manifold_point.dist.max(0.0) * inv_dt;
rhs_wo_bias *= is_bouncy + is_resting;
let rhs_bias = erp_inv_dt
* (manifold_point.dist + params.allowed_linear_error).clamp(-params.max_penetration_correction, 0.0);
let rhs = rhs_wo_bias + rhs_bias;
is_fast_contact =
is_fast_contact || (-rhs * params.dt > rb2.ccd.ccd_thickness * 0.5);
constraint.elements[k].normal_part = VelocityGroundConstraintNormalPart {
gcross2,
rhs,
rhs_wo_bias,
impulse: na::zero(),
r: projected_mass,
};
}
{
constraint.elements[k].tangent_part.impulse = na::zero();
for j in 0..DIM - 1 {
let gcross2 = mprops2
.effective_world_inv_inertia_sqrt
.transform_vector(dp2.gcross(-tangents1[j]));
let r = tangents1[j]
.dot(&mprops2.effective_inv_mass.component_mul(&tangents1[j]))
+ gcross2.gdot(gcross2);
let rhs = (vel1 - vel2
+ flipped_multiplier * manifold_point.tangent_velocity)
.dot(&tangents1[j]);
constraint.elements[k].tangent_part.gcross2[j] = gcross2;
constraint.elements[k].tangent_part.rhs[j] = rhs;
constraint.elements[k].tangent_part.r[j] = if cfg!(feature = "dim2") {
utils::inv(r)
} else {
r
};
}
#[cfg(feature = "dim3")]
{
constraint.elements[k].tangent_part.r[2] = 2.0
* constraint.elements[k].tangent_part.gcross2[0]
.gdot(constraint.elements[k].tangent_part.gcross2[1]);
}
}
}
constraint.cfm_factor = if is_fast_contact { 1.0 } else { cfm_factor };
#[cfg(not(target_arch = "wasm32"))]
if let Some(at) = insert_at {
out_constraints[at + _l] = AnyVelocityConstraint::NongroupedGround(constraint);
} else {
out_constraints.push(AnyVelocityConstraint::NongroupedGround(constraint));
}
}
}
pub fn solve(
&mut self,
mj_lambdas: &mut [DeltaVel<Real>],
solve_normal: bool,
solve_friction: bool,
) {
let mut mj_lambda2 = mj_lambdas[self.mj_lambda2 as usize];
VelocityGroundConstraintElement::solve_group(
self.cfm_factor,
&mut self.elements[..self.num_contacts as usize],
&self.dir1,
#[cfg(feature = "dim3")]
&self.tangent1,
&self.im2,
self.limit,
&mut mj_lambda2,
solve_normal,
solve_friction,
);
mj_lambdas[self.mj_lambda2 as usize] = mj_lambda2;
}
pub fn writeback_impulses(&self, manifolds_all: &mut [&mut ContactManifold]) {
let manifold = &mut manifolds_all[self.manifold_id];
for k in 0..self.num_contacts as usize {
let contact_id = self.manifold_contact_id[k];
let active_contact = &mut manifold.points[contact_id as usize];
active_contact.data.impulse = self.elements[k].normal_part.impulse;
#[cfg(feature = "dim2")]
{
active_contact.data.tangent_impulse = self.elements[k].tangent_part.impulse[0];
}
#[cfg(feature = "dim3")]
{
active_contact.data.tangent_impulse = self.elements[k].tangent_part.impulse;
}
}
}
pub fn remove_cfm_and_bias_from_rhs(&mut self) {
self.cfm_factor = 1.0;
for elt in &mut self.elements {
elt.normal_part.rhs = elt.normal_part.rhs_wo_bias;
}
}
}