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First public release of Rapier.

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This commit is contained in:
Sébastien Crozet
2020-08-25 22:10:25 +02:00
commit 754a48b7ff
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src/dynamics/solver/joint_constraint/revolute_velocity_constraint_wide.rs Normal file
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use simba::simd::SimdValue;
use crate::dynamics::solver::DeltaVel;
use crate::dynamics::{
IntegrationParameters, JointGraphEdge, JointIndex, JointParams, RevoluteJoint, RigidBody,
};
use crate::math::{AngVector, AngularInertia, Isometry, Point, SimdFloat, Vector, SIMD_WIDTH};
use crate::utils::{WAngularInertia, WCross, WCrossMatrix};
use na::{Cholesky, Matrix3x2, Matrix5, Vector5, U2, U3};
#[derive(Debug)]
pub(crate) struct WRevoluteVelocityConstraint {
mj_lambda1: [usize; SIMD_WIDTH],
mj_lambda2: [usize; SIMD_WIDTH],
joint_id: [JointIndex; SIMD_WIDTH],
r1: Vector<SimdFloat>,
r2: Vector<SimdFloat>,
inv_lhs: Matrix5<SimdFloat>,
rhs: Vector5<SimdFloat>,
impulse: Vector5<SimdFloat>,
basis1: Matrix3x2<SimdFloat>,
im1: SimdFloat,
im2: SimdFloat,
ii1_sqrt: AngularInertia<SimdFloat>,
ii2_sqrt: AngularInertia<SimdFloat>,
}
impl WRevoluteVelocityConstraint {
pub fn from_params(
params: &IntegrationParameters,
joint_id: [JointIndex; SIMD_WIDTH],
rbs1: [&RigidBody; SIMD_WIDTH],
rbs2: [&RigidBody; SIMD_WIDTH],
cparams: [&RevoluteJoint; SIMD_WIDTH],
) -> Self {
let position1 = Isometry::from(array![|ii| rbs1[ii].position; SIMD_WIDTH]);
let linvel1 = Vector::from(array![|ii| rbs1[ii].linvel; SIMD_WIDTH]);
let angvel1 = AngVector::<SimdFloat>::from(array![|ii| rbs1[ii].angvel; SIMD_WIDTH]);
let world_com1 = Point::from(array![|ii| rbs1[ii].world_com; SIMD_WIDTH]);
let im1 = SimdFloat::from(array![|ii| rbs1[ii].mass_properties.inv_mass; SIMD_WIDTH]);
let ii1_sqrt = AngularInertia::<SimdFloat>::from(
array![|ii| rbs1[ii].world_inv_inertia_sqrt; SIMD_WIDTH],
);
let mj_lambda1 = array![|ii| rbs1[ii].active_set_offset; SIMD_WIDTH];
let position2 = Isometry::from(array![|ii| rbs2[ii].position; SIMD_WIDTH]);
let linvel2 = Vector::from(array![|ii| rbs2[ii].linvel; SIMD_WIDTH]);
let angvel2 = AngVector::<SimdFloat>::from(array![|ii| rbs2[ii].angvel; SIMD_WIDTH]);
let world_com2 = Point::from(array![|ii| rbs2[ii].world_com; SIMD_WIDTH]);
let im2 = SimdFloat::from(array![|ii| rbs2[ii].mass_properties.inv_mass; SIMD_WIDTH]);
let ii2_sqrt = AngularInertia::<SimdFloat>::from(
array![|ii| rbs2[ii].world_inv_inertia_sqrt; SIMD_WIDTH],
);
let mj_lambda2 = array![|ii| rbs2[ii].active_set_offset; SIMD_WIDTH];
let local_anchor1 = Point::from(array![|ii| cparams[ii].local_anchor1; SIMD_WIDTH]);
let local_anchor2 = Point::from(array![|ii| cparams[ii].local_anchor2; SIMD_WIDTH]);
let local_basis1 = [
Vector::from(array![|ii| cparams[ii].basis1[0]; SIMD_WIDTH]),
Vector::from(array![|ii| cparams[ii].basis1[1]; SIMD_WIDTH]),
];
let impulse = Vector5::from(array![|ii| cparams[ii].impulse; SIMD_WIDTH]);
let anchor1 = position1 * local_anchor1;
let anchor2 = position2 * local_anchor2;
let basis1 =
Matrix3x2::from_columns(&[position1 * local_basis1[0], position1 * local_basis1[1]]);
// let r21 = Rotation::rotation_between_axis(&axis1, &axis2)
// .unwrap_or(Rotation::identity())
// .to_rotation_matrix()
// .into_inner();
// let basis2 = r21 * basis1;
// NOTE: to simplify, we use basis2 = basis1.
// Though we may want to test if that does not introduce any instability.
let ii1 = ii1_sqrt.squared();
let r1 = anchor1 - world_com1;
let r1_mat = r1.gcross_matrix();
let ii2 = ii2_sqrt.squared();
let r2 = anchor2 - world_com2;
let r2_mat = r2.gcross_matrix();
let mut lhs = Matrix5::zeros();
let lhs00 =
ii2.quadform(&r2_mat).add_diagonal(im2) + ii1.quadform(&r1_mat).add_diagonal(im1);
let lhs10 = basis1.tr_mul(&(ii2 * r2_mat + ii1 * r1_mat));
let lhs11 = (ii1 + ii2).quadform3x2(&basis1).into_matrix();
// Note that cholesky won't read the upper-right part
// of lhs so we don't have to fill it.
lhs.fixed_slice_mut::<U3, U3>(0, 0)
.copy_from(&lhs00.into_matrix());
lhs.fixed_slice_mut::<U2, U3>(3, 0).copy_from(&lhs10);
lhs.fixed_slice_mut::<U2, U2>(3, 3).copy_from(&lhs11);
let inv_lhs = Cholesky::new_unchecked(lhs).inverse();
let lin_rhs = linvel2 + angvel2.gcross(r2) - linvel1 - angvel1.gcross(r1);
let ang_rhs = basis1.tr_mul(&(angvel2 - angvel1));
let rhs = Vector5::new(lin_rhs.x, lin_rhs.y, lin_rhs.z, ang_rhs.x, ang_rhs.y);
WRevoluteVelocityConstraint {
joint_id,
mj_lambda1,
mj_lambda2,
im1,
ii1_sqrt,
basis1,
im2,
ii2_sqrt,
impulse: impulse * SimdFloat::splat(params.warmstart_coeff),
inv_lhs,
rhs,
r1,
r2,
}
}
pub fn warmstart(&self, mj_lambdas: &mut [DeltaVel<f32>]) {
let mut mj_lambda1 = DeltaVel {
linear: Vector::from(
array![|ii| mj_lambdas[self.mj_lambda1[ii] as usize].linear; SIMD_WIDTH],
),
angular: AngVector::from(
array![|ii| mj_lambdas[self.mj_lambda1[ii] as usize].angular; SIMD_WIDTH],
),
};
let mut mj_lambda2 = DeltaVel {
linear: Vector::from(
array![|ii| mj_lambdas[self.mj_lambda2[ii] as usize].linear; SIMD_WIDTH],
),
angular: AngVector::from(
array![|ii| mj_lambdas[self.mj_lambda2[ii] as usize].angular; SIMD_WIDTH],
),
};
let lin_impulse = self.impulse.fixed_rows::<U3>(0).into_owned();
let ang_impulse = self.basis1 * self.impulse.fixed_rows::<U2>(3).into_owned();
mj_lambda1.linear += lin_impulse * self.im1;
mj_lambda1.angular += self
.ii1_sqrt
.transform_vector(ang_impulse + self.r1.gcross(lin_impulse));
mj_lambda2.linear -= lin_impulse * self.im2;
mj_lambda2.angular -= self
.ii2_sqrt
.transform_vector(ang_impulse + self.r2.gcross(lin_impulse));
for ii in 0..SIMD_WIDTH {
mj_lambdas[self.mj_lambda1[ii] as usize].linear = mj_lambda1.linear.extract(ii);
mj_lambdas[self.mj_lambda1[ii] as usize].angular = mj_lambda1.angular.extract(ii);
}
for ii in 0..SIMD_WIDTH {
mj_lambdas[self.mj_lambda2[ii] as usize].linear = mj_lambda2.linear.extract(ii);
mj_lambdas[self.mj_lambda2[ii] as usize].angular = mj_lambda2.angular.extract(ii);
}
}
pub fn solve(&mut self, mj_lambdas: &mut [DeltaVel<f32>]) {
let mut mj_lambda1 = DeltaVel {
linear: Vector::from(
array![|ii| mj_lambdas[self.mj_lambda1[ii] as usize].linear; SIMD_WIDTH],
),
angular: AngVector::from(
array![|ii| mj_lambdas[self.mj_lambda1[ii] as usize].angular; SIMD_WIDTH],
),
};
let mut mj_lambda2 = DeltaVel {
linear: Vector::from(
array![|ii| mj_lambdas[self.mj_lambda2[ii] as usize].linear; SIMD_WIDTH],
),
angular: AngVector::from(
array![|ii| mj_lambdas[self.mj_lambda2[ii] as usize].angular; SIMD_WIDTH],
),
};
let ang_vel1 = self.ii1_sqrt.transform_vector(mj_lambda1.angular);
let ang_vel2 = self.ii2_sqrt.transform_vector(mj_lambda2.angular);
let lin_dvel = mj_lambda2.linear + ang_vel2.gcross(self.r2)
- mj_lambda1.linear
- ang_vel1.gcross(self.r1);
let ang_dvel = self.basis1.tr_mul(&(ang_vel2 - ang_vel1));
let rhs =
Vector5::new(lin_dvel.x, lin_dvel.y, lin_dvel.z, ang_dvel.x, ang_dvel.y) + self.rhs;
let impulse = self.inv_lhs * rhs;
self.impulse += impulse;
let lin_impulse = impulse.fixed_rows::<U3>(0).into_owned();
let ang_impulse = self.basis1 * impulse.fixed_rows::<U2>(3).into_owned();
mj_lambda1.linear += lin_impulse * self.im1;
mj_lambda1.angular += self
.ii1_sqrt
.transform_vector(ang_impulse + self.r1.gcross(lin_impulse));
mj_lambda2.linear -= lin_impulse * self.im2;
mj_lambda2.angular -= self
.ii2_sqrt
.transform_vector(ang_impulse + self.r2.gcross(lin_impulse));
for ii in 0..SIMD_WIDTH {
mj_lambdas[self.mj_lambda1[ii] as usize].linear = mj_lambda1.linear.extract(ii);
mj_lambdas[self.mj_lambda1[ii] as usize].angular = mj_lambda1.angular.extract(ii);
}
for ii in 0..SIMD_WIDTH {
mj_lambdas[self.mj_lambda2[ii] as usize].linear = mj_lambda2.linear.extract(ii);
mj_lambdas[self.mj_lambda2[ii] as usize].angular = mj_lambda2.angular.extract(ii);
}
}
pub fn writeback_impulses(&self, joints_all: &mut [JointGraphEdge]) {
for ii in 0..SIMD_WIDTH {
let joint = &mut joints_all[self.joint_id[ii]].weight;
if let JointParams::RevoluteJoint(rev) = &mut joint.params {
rev.impulse = self.impulse.extract(ii)
}
}
}
}
#[derive(Debug)]
pub(crate) struct WRevoluteVelocityGroundConstraint {
mj_lambda2: [usize; SIMD_WIDTH],
joint_id: [JointIndex; SIMD_WIDTH],
r2: Vector<SimdFloat>,
inv_lhs: Matrix5<SimdFloat>,
rhs: Vector5<SimdFloat>,
impulse: Vector5<SimdFloat>,
basis1: Matrix3x2<SimdFloat>,
im2: SimdFloat,
ii2_sqrt: AngularInertia<SimdFloat>,
}
impl WRevoluteVelocityGroundConstraint {
pub fn from_params(
params: &IntegrationParameters,
joint_id: [JointIndex; SIMD_WIDTH],
rbs1: [&RigidBody; SIMD_WIDTH],
rbs2: [&RigidBody; SIMD_WIDTH],
cparams: [&RevoluteJoint; SIMD_WIDTH],
flipped: [bool; SIMD_WIDTH],
) -> Self {
let position1 = Isometry::from(array![|ii| rbs1[ii].position; SIMD_WIDTH]);
let linvel1 = Vector::from(array![|ii| rbs1[ii].linvel; SIMD_WIDTH]);
let angvel1 = AngVector::<SimdFloat>::from(array![|ii| rbs1[ii].angvel; SIMD_WIDTH]);
let world_com1 = Point::from(array![|ii| rbs1[ii].world_com; SIMD_WIDTH]);
let position2 = Isometry::from(array![|ii| rbs2[ii].position; SIMD_WIDTH]);
let linvel2 = Vector::from(array![|ii| rbs2[ii].linvel; SIMD_WIDTH]);
let angvel2 = AngVector::<SimdFloat>::from(array![|ii| rbs2[ii].angvel; SIMD_WIDTH]);
let world_com2 = Point::from(array![|ii| rbs2[ii].world_com; SIMD_WIDTH]);
let im2 = SimdFloat::from(array![|ii| rbs2[ii].mass_properties.inv_mass; SIMD_WIDTH]);
let ii2_sqrt = AngularInertia::<SimdFloat>::from(
array![|ii| rbs2[ii].world_inv_inertia_sqrt; SIMD_WIDTH],
);
let mj_lambda2 = array![|ii| rbs2[ii].active_set_offset; SIMD_WIDTH];
let impulse = Vector5::from(array![|ii| cparams[ii].impulse; SIMD_WIDTH]);
let local_anchor1 = Point::from(
array![|ii| if flipped[ii] { cparams[ii].local_anchor2 } else { cparams[ii].local_anchor1 }; SIMD_WIDTH],
);
let local_anchor2 = Point::from(
array![|ii| if flipped[ii] { cparams[ii].local_anchor1 } else { cparams[ii].local_anchor2 }; SIMD_WIDTH],
);
let basis1 = Matrix3x2::from_columns(&[
position1
* Vector::from(
array![|ii| if flipped[ii] { cparams[ii].basis2[0] } else { cparams[ii].basis1[0] }; SIMD_WIDTH],
),
position1
* Vector::from(
array![|ii| if flipped[ii] { cparams[ii].basis2[1] } else { cparams[ii].basis1[1] }; SIMD_WIDTH],
),
]);
let anchor1 = position1 * local_anchor1;
let anchor2 = position2 * local_anchor2;
// let r21 = Rotation::rotation_between_axis(&axis1, &axis2)
// .unwrap_or(Rotation::identity())
// .to_rotation_matrix()
// .into_inner();
// let basis2 = /*r21 * */ basis1;
let ii2 = ii2_sqrt.squared();
let r1 = anchor1 - world_com1;
let r2 = anchor2 - world_com2;
let r2_mat = r2.gcross_matrix();
let mut lhs = Matrix5::zeros();
let lhs00 = ii2.quadform(&r2_mat).add_diagonal(im2);
let lhs10 = basis1.tr_mul(&(ii2 * r2_mat));
let lhs11 = ii2.quadform3x2(&basis1).into_matrix();
// Note that cholesky won't read the upper-right part
// of lhs so we don't have to fill it.
lhs.fixed_slice_mut::<U3, U3>(0, 0)
.copy_from(&lhs00.into_matrix());
lhs.fixed_slice_mut::<U2, U3>(3, 0).copy_from(&lhs10);
lhs.fixed_slice_mut::<U2, U2>(3, 3).copy_from(&lhs11);
let inv_lhs = Cholesky::new_unchecked(lhs).inverse();
let lin_rhs = linvel2 + angvel2.gcross(r2) - linvel1 - angvel1.gcross(r1);
let ang_rhs = basis1.tr_mul(&(angvel2 - angvel1));
let rhs = Vector5::new(lin_rhs.x, lin_rhs.y, lin_rhs.z, ang_rhs.x, ang_rhs.y);
WRevoluteVelocityGroundConstraint {
joint_id,
mj_lambda2,
im2,
ii2_sqrt,
impulse: impulse * SimdFloat::splat(params.warmstart_coeff),
basis1,
inv_lhs,
rhs,
r2,
}
}
pub fn warmstart(&self, mj_lambdas: &mut [DeltaVel<f32>]) {
let mut mj_lambda2 = DeltaVel {
linear: Vector::from(
array![|ii| mj_lambdas[self.mj_lambda2[ii] as usize].linear; SIMD_WIDTH],
),
angular: AngVector::from(
array![|ii| mj_lambdas[self.mj_lambda2[ii] as usize].angular; SIMD_WIDTH],
),
};
let lin_impulse = self.impulse.fixed_rows::<U3>(0).into_owned();
let ang_impulse = self.basis1 * self.impulse.fixed_rows::<U2>(3).into_owned();
mj_lambda2.linear -= lin_impulse * self.im2;
mj_lambda2.angular -= self
.ii2_sqrt
.transform_vector(ang_impulse + self.r2.gcross(lin_impulse));
for ii in 0..SIMD_WIDTH {
mj_lambdas[self.mj_lambda2[ii] as usize].linear = mj_lambda2.linear.extract(ii);
mj_lambdas[self.mj_lambda2[ii] as usize].angular = mj_lambda2.angular.extract(ii);
}
}
pub fn solve(&mut self, mj_lambdas: &mut [DeltaVel<f32>]) {
let mut mj_lambda2 = DeltaVel {
linear: Vector::from(
array![|ii| mj_lambdas[self.mj_lambda2[ii] as usize].linear; SIMD_WIDTH],
),
angular: AngVector::from(
array![|ii| mj_lambdas[self.mj_lambda2[ii] as usize].angular; SIMD_WIDTH],
),
};
let ang_vel2 = self.ii2_sqrt.transform_vector(mj_lambda2.angular);
let lin_dvel = mj_lambda2.linear + ang_vel2.gcross(self.r2);
let ang_dvel = self.basis1.tr_mul(&ang_vel2);
let rhs =
Vector5::new(lin_dvel.x, lin_dvel.y, lin_dvel.z, ang_dvel.x, ang_dvel.y) + self.rhs;
let impulse = self.inv_lhs * rhs;
self.impulse += impulse;
let lin_impulse = impulse.fixed_rows::<U3>(0).into_owned();
let ang_impulse = self.basis1 * impulse.fixed_rows::<U2>(3).into_owned();
mj_lambda2.linear -= lin_impulse * self.im2;
mj_lambda2.angular -= self
.ii2_sqrt
.transform_vector(ang_impulse + self.r2.gcross(lin_impulse));
for ii in 0..SIMD_WIDTH {
mj_lambdas[self.mj_lambda2[ii] as usize].linear = mj_lambda2.linear.extract(ii);
mj_lambdas[self.mj_lambda2[ii] as usize].angular = mj_lambda2.angular.extract(ii);
}
}
// FIXME: duplicated code with the non-ground constraint.
pub fn writeback_impulses(&self, joints_all: &mut [JointGraphEdge]) {
for ii in 0..SIMD_WIDTH {
let joint = &mut joints_all[self.joint_id[ii]].weight;
if let JointParams::RevoluteJoint(rev) = &mut joint.params {
rev.impulse = self.impulse.extract(ii)
}
}
}
}