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-rw-r--r--src/dynamics/solver/joint_constraint/any_joint_constraint.rs2
-rw-r--r--src/dynamics/solver/joint_constraint/joint_constraint_builder.rs1096
-rw-r--r--src/dynamics/solver/joint_constraint/joint_constraint_helper.rs141
-rw-r--r--src/dynamics/solver/joint_constraint/joint_constraint_helper_simd.rs19
-rw-r--r--src/dynamics/solver/joint_constraint/joint_constraint_helper_template.rs966
-rw-r--r--src/dynamics/solver/joint_constraint/joint_generic_constraint.rs24
-rw-r--r--src/dynamics/solver/joint_constraint/joint_generic_constraint_builder.rs110
-rw-r--r--src/dynamics/solver/joint_constraint/joint_velocity_constraint.rs106
-rw-r--r--src/dynamics/solver/joint_constraint/mod.rs8
9 files changed, 1266 insertions, 1206 deletions
diff --git a/src/dynamics/solver/joint_constraint/any_joint_constraint.rs b/src/dynamics/solver/joint_constraint/any_joint_constraint.rs
index 8cbd438..44f7431 100644
--- a/src/dynamics/solver/joint_constraint/any_joint_constraint.rs
+++ b/src/dynamics/solver/joint_constraint/any_joint_constraint.rs
@@ -6,7 +6,7 @@ use crate::dynamics::solver::joint_constraint::joint_velocity_constraint::{
};
use crate::dynamics::solver::{AnyConstraintMut, ConstraintTypes};
use crate::dynamics::JointGraphEdge;
-use crate::math::Real;
+use crate::math::*;
use na::DVector;
use crate::dynamics::solver::joint_constraint::joint_generic_constraint_builder::{
diff --git a/src/dynamics/solver/joint_constraint/joint_constraint_builder.rs b/src/dynamics/solver/joint_constraint/joint_constraint_builder.rs
index 00bead1..6bd61e3 100644
--- a/src/dynamics/solver/joint_constraint/joint_constraint_builder.rs
+++ b/src/dynamics/solver/joint_constraint/joint_constraint_builder.rs
@@ -1,22 +1,12 @@
use crate::dynamics::solver::joint_constraint::joint_velocity_constraint::{
- JointFixedSolverBody, JointOneBodyConstraint, JointTwoBodyConstraint, WritebackId,
+ JointFixedSolverBody, JointOneBodyConstraint, JointTwoBodyConstraint,
};
use crate::dynamics::solver::joint_constraint::JointSolverBody;
use crate::dynamics::solver::solver_body::SolverBody;
use crate::dynamics::solver::ConstraintsCounts;
-use crate::dynamics::solver::MotorParameters;
use crate::dynamics::{GenericJoint, ImpulseJoint, IntegrationParameters, JointIndex};
-use crate::math::{AngVector, Isometry, Matrix, Point, Real, Rotation, Vector, ANG_DIM, DIM};
+use crate::math::*;
use crate::prelude::RigidBodySet;
-use crate::utils;
-use crate::utils::{IndexMut2, SimdCrossMatrix, SimdDot, SimdQuat, SimdRealCopy};
-use na::SMatrix;
-
-#[cfg(feature = "dim3")]
-use crate::utils::SimdBasis;
-
-#[cfg(feature = "simd-is-enabled")]
-use crate::math::{SimdReal, SIMD_WIDTH};
pub struct JointTwoBodyConstraintBuilder {
body1: usize,
@@ -95,8 +85,8 @@ pub struct JointTwoBodyConstraintBuilderSimd {
joint_body1: JointSolverBody<SimdReal, SIMD_WIDTH>,
joint_body2: JointSolverBody<SimdReal, SIMD_WIDTH>,
joint_id: [JointIndex; SIMD_WIDTH],
- local_frame1: Isometry<SimdReal>,
- local_frame2: Isometry<SimdReal>,
+ local_frame1: SimdIsometry,
+ local_frame2: SimdIsometry,
locked_axes: u8,
constraint_id: usize,
}
@@ -119,13 +109,13 @@ impl JointTwoBodyConstraintBuilderSimd {
let joint_body1 = JointSolverBody {
im: gather![|ii| rb1[ii].mprops.effective_inv_mass].into(),
sqrt_ii: gather![|ii| rb1[ii].mprops.effective_world_inv_inertia_sqrt].into(),
- world_com: Point::origin(),
+ world_com: SimdPoint::origin(),
solver_vel: body1,
};
let joint_body2 = JointSolverBody {
im: gather![|ii| rb2[ii].mprops.effective_inv_mass].into(),
sqrt_ii: gather![|ii| rb2[ii].mprops.effective_world_inv_inertia_sqrt].into(),
- world_com: Point::origin(),
+ world_com: SimdPoint::origin(),
solver_vel: body2,
};
@@ -156,8 +146,8 @@ impl JointTwoBodyConstraintBuilderSimd {
let rb1 = gather![|ii| &bodies[self.body1[ii]]];
let rb2 = gather![|ii| &bodies[self.body2[ii]]];
- let frame1 = Isometry::from(gather![|ii| rb1[ii].position]) * self.local_frame1;
- let frame2 = Isometry::from(gather![|ii| rb2[ii].position]) * self.local_frame2;
+ let frame1 = SimdIsometry::from(gather![|ii| rb1[ii].position]) * self.local_frame1;
+ let frame2 = SimdIsometry::from(gather![|ii| rb2[ii].position]) * self.local_frame2;
self.joint_body1.world_com = gather![|ii| rb1[ii].world_com].into();
self.joint_body2.world_com = gather![|ii| rb2[ii].world_com].into();
@@ -176,7 +166,7 @@ impl JointTwoBodyConstraintBuilderSimd {
pub struct JointOneBodyConstraintBuilder {
body1: JointFixedSolverBody<Real>,
- frame1: Isometry<Real>,
+ frame1: Isometry,
body2: usize,
joint_id: JointIndex,
joint: GenericJoint,
@@ -259,10 +249,10 @@ impl JointOneBodyConstraintBuilder {
#[cfg(feature = "simd-is-enabled")]
pub struct JointOneBodyConstraintBuilderSimd {
body1: JointFixedSolverBody<SimdReal>,
- frame1: Isometry<SimdReal>,
+ frame1: SimdIsometry,
body2: [usize; SIMD_WIDTH],
joint_id: [JointIndex; SIMD_WIDTH],
- local_frame2: Isometry<SimdReal>,
+ local_frame2: SimdIsometry,
locked_axes: u8,
constraint_id: usize,
}
@@ -288,7 +278,7 @@ impl JointOneBodyConstraintBuilderSimd {
}
}
- let poss1 = Isometry::from(gather![|ii| rb1[ii].pos.position]);
+ let poss1 = SimdIsometry::from(gather![|ii| rb1[ii].pos.position]);
let joint_body1 = JointFixedSolverBody {
linvel: gather![|ii| rb1[ii].vels.linvel].into(),
@@ -300,7 +290,7 @@ impl JointOneBodyConstraintBuilderSimd {
body1: joint_body1,
body2: gather![|ii| rb2[ii].ids.active_set_offset],
joint_id,
- frame1: poss1 * Isometry::from(local_frame1),
+ frame1: poss1 * SimdIsometry::from(local_frame1),
local_frame2: local_frame2.into(),
locked_axes: joint[0].data.locked_axes.bits(),
constraint_id: *out_constraint_id,
@@ -320,7 +310,7 @@ impl JointOneBodyConstraintBuilderSimd {
// constraints. Could we make this more incremental?
let rb2 = gather![|ii| &bodies[self.body2[ii]]];
- let frame2 = Isometry::from(gather![|ii| rb2[ii].position]) * self.local_frame2;
+ let frame2 = SimdIsometry::from(gather![|ii| rb2[ii].position]) * self.local_frame2;
let joint_body2 = JointSolverBody {
im: gather![|ii| rb2[ii].im].into(),
@@ -341,1061 +331,3 @@ impl JointOneBodyConstraintBuilderSimd {
);
}
}
-
-#[derive(Debug, Copy, Clone)]
-pub struct JointTwoBodyConstraintHelper<N: SimdRealCopy> {
- pub basis: Matrix<N>,
- pub basis2: Matrix<N>, // TODO: used for angular coupling. Can we avoid storing this?
- pub cmat1_basis: SMatrix<N, ANG_DIM, DIM>,
- pub cmat2_basis: SMatrix<N, ANG_DIM, DIM>,
- pub ang_basis: SMatrix<N, ANG_DIM, ANG_DIM>,
- pub lin_err: Vector<N>,
- pub ang_err: Rotation<N>,
-}
-
-impl<N: SimdRealCopy> JointTwoBodyConstraintHelper<N> {
- pub fn new(
- frame1: &Isometry<N>,
- frame2: &Isometry<N>,
- world_com1: &Point<N>,
- world_com2: &Point<N>,
- locked_lin_axes: u8,
- ) -> Self {
- let mut frame1 = *frame1;
- let basis = frame1.rotation.to_rotation_matrix().into_inner();
- let lin_err = frame2.translation.vector - frame1.translation.vector;
-
- // Adjust the point of application of the force for the first body,
- // by snapping free axes to the second frame’s center (to account for
- // the allowed relative movement).
- {
- let mut new_center1 = frame2.translation.vector; // First, assume all dofs are free.
-
- // Then snap the locked ones.
- for i in 0..DIM {
- if locked_lin_axes & (1 << i) != 0 {
- let axis = basis.column(i);
- new_center1 -= axis * lin_err.dot(&axis);
- }
- }
- frame1.translation.vector = new_center1;
- }
-
- let r1 = frame1.translation.vector - world_com1.coords;
- let r2 = frame2.translation.vector - world_com2.coords;
-
- let cmat1 = r1.gcross_matrix();
- let cmat2 = r2.gcross_matrix();
-
- #[allow(unused_mut)] // The mut is needed for 3D
- let mut ang_basis = frame1.rotation.diff_conj1_2(&frame2.rotation).transpose();
- #[allow(unused_mut)] // The mut is needed for 3D
- let mut ang_err = frame1.rotation.inverse() * frame2.rotation;
-
- #[cfg(feature = "dim3")]
- {
- let sgn = N::one().simd_copysign(frame1.rotation.dot(&frame2.rotation));
- ang_basis *= sgn;
- *ang_err.as_mut_unchecked() *= sgn;
- }
-
- Self {
- basis,
- basis2: frame2.rotation.to_rotation_matrix().into_inner(),
- cmat1_basis: cmat1 * basis,
- cmat2_basis: cmat2 * basis,
- ang_basis,
- lin_err,
- ang_err,
- }
- }
-
- pub fn limit_linear<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointSolverBody<N, LANES>,
- body2: &JointSolverBody<N, LANES>,
- limited_axis: usize,
- limits: [N; 2],
- writeback_id: WritebackId,
- ) -> JointTwoBodyConstraint<N, LANES> {
- let zero = N::zero();
- let mut constraint =
- self.lock_linear(params, joint_id, body1, body2, limited_axis, writeback_id);
-
- let dist = self.lin_err.dot(&constraint.lin_jac);
- let min_enabled = dist.simd_le(limits[0]);
- let max_enabled = limits[1].simd_le(dist);
-
- let erp_inv_dt = N::splat(params.joint_erp_inv_dt());
- let cfm_coeff = N::splat(params.joint_cfm_coeff());
- let rhs_bias =
- ((dist - limits[1]).simd_max(zero) - (limits[0] - dist).simd_max(zero)) * erp_inv_dt;
- constraint.rhs = constraint.rhs_wo_bias + rhs_bias;
- constraint.cfm_coeff = cfm_coeff;
- constraint.impulse_bounds = [
- N::splat(-Real::INFINITY).select(min_enabled, zero),
- N::splat(Real::INFINITY).select(max_enabled, zero),
- ];
-
- constraint
- }
-
- pub fn limit_linear_coupled<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointSolverBody<N, LANES>,
- body2: &JointSolverBody<N, LANES>,
- coupled_axes: u8,
- limits: [N; 2],
- writeback_id: WritebackId,
- ) -> JointTwoBodyConstraint<N, LANES> {
- let zero = N::zero();
- let mut lin_jac = Vector::zeros();
- let mut ang_jac1: AngVector<N> = na::zero();
- let mut ang_jac2: AngVector<N> = na::zero();
-
- for i in 0..DIM {
- if coupled_axes & (1 << i) != 0 {
- let coeff = self.basis.column(i).dot(&self.lin_err);
- lin_jac += self.basis.column(i) * coeff;
- #[cfg(feature = "dim2")]
- {
- ang_jac1 += self.cmat1_basis[i] * coeff;
- ang_jac2 += self.cmat2_basis[i] * coeff;
- }
- #[cfg(feature = "dim3")]
- {
- ang_jac1 += self.cmat1_basis.column(i) * coeff;
- ang_jac2 += self.cmat2_basis.column(i) * coeff;
- }
- }
- }
-
- // FIXME: handle min limit too.
-
- let dist = lin_jac.norm();
- let inv_dist = crate::utils::simd_inv(dist);
- lin_jac *= inv_dist;
- ang_jac1 *= inv_dist;
- ang_jac2 *= inv_dist;
-
- let rhs_wo_bias = (dist - limits[1]).simd_min(zero) * N::splat(params.inv_dt());
-
- ang_jac1 = body1.sqrt_ii * ang_jac1;
- ang_jac2 = body2.sqrt_ii * ang_jac2;
-
- let erp_inv_dt = N::splat(params.joint_erp_inv_dt());
- let cfm_coeff = N::splat(params.joint_cfm_coeff());
- let rhs_bias = (dist - limits[1]).simd_max(zero) * erp_inv_dt;
- let rhs = rhs_wo_bias + rhs_bias;
- let impulse_bounds = [N::zero(), N::splat(Real::INFINITY)];
-
- JointTwoBodyConstraint {
- joint_id,
- solver_vel1: body1.solver_vel,
- solver_vel2: body2.solver_vel,
- im1: body1.im,
- im2: body2.im,
- impulse: N::zero(),
- impulse_bounds,
- lin_jac,
- ang_jac1,
- ang_jac2,
- inv_lhs: N::zero(), // Will be set during ortogonalization.
- cfm_coeff,
- cfm_gain: N::zero(),
- rhs,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- pub fn motor_linear<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointSolverBody<N, LANES>,
- body2: &JointSolverBody<N, LANES>,
- motor_axis: usize,
- motor_params: &MotorParameters<N>,
- limits: Option<[N; 2]>,
- writeback_id: WritebackId,
- ) -> JointTwoBodyConstraint<N, LANES> {
- let inv_dt = N::splat(params.inv_dt());
- let mut constraint =
- self.lock_linear(params, joint_id, body1, body2, motor_axis, writeback_id);
-
- let mut rhs_wo_bias = N::zero();
- if motor_params.erp_inv_dt != N::zero() {
- let dist = self.lin_err.dot(&constraint.lin_jac);
- rhs_wo_bias += (dist - motor_params.target_pos) * motor_params.erp_inv_dt;
- }
-
- let mut target_vel = motor_params.target_vel;
- if let Some(limits) = limits {
- let dist = self.lin_err.dot(&constraint.lin_jac);
- target_vel =
- target_vel.simd_clamp((limits[0] - dist) * inv_dt, (limits[1] - dist) * inv_dt);
- };
-
- rhs_wo_bias += -target_vel;
-
- constraint.cfm_coeff = motor_params.cfm_coeff;
- constraint.cfm_gain = motor_params.cfm_gain;
- constraint.impulse_bounds = [-motor_params.max_impulse, motor_params.max_impulse];
- constraint.rhs = rhs_wo_bias;
- constraint.rhs_wo_bias = rhs_wo_bias;
- constraint
- }
-
- pub fn lock_linear<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointSolverBody<N, LANES>,
- body2: &JointSolverBody<N, LANES>,
- locked_axis: usize,
- writeback_id: WritebackId,
- ) -> JointTwoBodyConstraint<N, LANES> {
- let lin_jac = self.basis.column(locked_axis).into_owned();
- #[cfg(feature = "dim2")]
- let mut ang_jac1 = self.cmat1_basis[locked_axis];
- #[cfg(feature = "dim2")]
- let mut ang_jac2 = self.cmat2_basis[locked_axis];
- #[cfg(feature = "dim3")]
- let mut ang_jac1 = self.cmat1_basis.column(locked_axis).into_owned();
- #[cfg(feature = "dim3")]
- let mut ang_jac2 = self.cmat2_basis.column(locked_axis).into_owned();
-
- let rhs_wo_bias = N::zero();
- let erp_inv_dt = N::splat(params.joint_erp_inv_dt());
- let cfm_coeff = N::splat(params.joint_cfm_coeff());
- let rhs_bias = lin_jac.dot(&self.lin_err) * erp_inv_dt;
-
- ang_jac1 = body1.sqrt_ii * ang_jac1;
- ang_jac2 = body2.sqrt_ii * ang_jac2;
-
- JointTwoBodyConstraint {
- joint_id,
- solver_vel1: body1.solver_vel,
- solver_vel2: body2.solver_vel,
- im1: body1.im,
- im2: body2.im,
- impulse: N::zero(),
- impulse_bounds: [-N::splat(Real::MAX), N::splat(Real::MAX)],
- lin_jac,
- ang_jac1,
- ang_jac2,
- inv_lhs: N::zero(), // Will be set during ortogonalization.
- cfm_coeff,
- cfm_gain: N::zero(),
- rhs: rhs_wo_bias + rhs_bias,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- pub fn limit_angular<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointSolverBody<N, LANES>,
- body2: &JointSolverBody<N, LANES>,
- _limited_axis: usize,
- limits: [N; 2],
- writeback_id: WritebackId,
- ) -> JointTwoBodyConstraint<N, LANES> {
- let zero = N::zero();
- let half = N::splat(0.5);
- let s_limits = [(limits[0] * half).simd_sin(), (limits[1] * half).simd_sin()];
- #[cfg(feature = "dim2")]
- let s_ang = (self.ang_err.angle() * half).simd_sin();
- #[cfg(feature = "dim3")]
- let s_ang = self.ang_err.imag()[_limited_axis];
- let min_enabled = s_ang.simd_le(s_limits[0]);
- let max_enabled = s_limits[1].simd_le(s_ang);
-
- let impulse_bounds = [
- N::splat(-Real::INFINITY).select(min_enabled, zero),
- N::splat(Real::INFINITY).select(max_enabled, zero),
- ];
-
- #[cfg(feature = "dim2")]
- let ang_jac = N::one();
- #[cfg(feature = "dim3")]
- let ang_jac = self.ang_basis.column(_limited_axis).into_owned();
- let rhs_wo_bias = N::zero();
- let erp_inv_dt = N::splat(params.joint_erp_inv_dt());
- let cfm_coeff = N::splat(params.joint_cfm_coeff());
- let rhs_bias = ((s_ang - s_limits[1]).simd_max(zero)
- - (s_limits[0] - s_ang).simd_max(zero))
- * erp_inv_dt;
-
- let ang_jac1 = body1.sqrt_ii * ang_jac;
- let ang_jac2 = body2.sqrt_ii * ang_jac;
-
- JointTwoBodyConstraint {
- joint_id,
- solver_vel1: body1.solver_vel,
- solver_vel2: body2.solver_vel,
- im1: body1.im,
- im2: body2.im,
- impulse: N::zero(),
- impulse_bounds,
- lin_jac: na::zero(),
- ang_jac1,
- ang_jac2,
- inv_lhs: N::zero(), // Will be set during ortogonalization.
- cfm_coeff,
- cfm_gain: N::zero(),
- rhs: rhs_wo_bias + rhs_bias,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- pub fn motor_angular<const LANES: usize>(
- &self,
- joint_id: [JointIndex; LANES],
- body1: &JointSolverBody<N, LANES>,
- body2: &JointSolverBody<N, LANES>,
- _motor_axis: usize,
- motor_params: &MotorParameters<N>,
- writeback_id: WritebackId,
- ) -> JointTwoBodyConstraint<N, LANES> {
- #[cfg(feature = "dim2")]
- let ang_jac = N::one();
- #[cfg(feature = "dim3")]
- let ang_jac = self.basis.column(_motor_axis).into_owned();
-
- let mut rhs_wo_bias = N::zero();
- if motor_params.erp_inv_dt != N::zero() {
- #[cfg(feature = "dim2")]
- let ang_dist = self.ang_err.angle();
- #[cfg(feature = "dim3")]
- let ang_dist = self.ang_err.imag()[_motor_axis].simd_asin() * N::splat(2.0);
- let target_ang = motor_params.target_pos;
- rhs_wo_bias += utils::smallest_abs_diff_between_angles(ang_dist, target_ang)
- * motor_params.erp_inv_dt;
- }
-
- rhs_wo_bias += -motor_params.target_vel;
-
- let ang_jac1 = body1.sqrt_ii * ang_jac;
- let ang_jac2 = body2.sqrt_ii * ang_jac;
-
- JointTwoBodyConstraint {
- joint_id,
- solver_vel1: body1.solver_vel,
- solver_vel2: body2.solver_vel,
- im1: body1.im,
- im2: body2.im,
- impulse: N::zero(),
- impulse_bounds: [-motor_params.max_impulse, motor_params.max_impulse],
- lin_jac: na::zero(),
- ang_jac1,
- ang_jac2,
- inv_lhs: N::zero(), // Will be set during ortogonalization.
- cfm_coeff: motor_params.cfm_coeff,
- cfm_gain: motor_params.cfm_gain,
- rhs: rhs_wo_bias,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- pub fn lock_angular<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointSolverBody<N, LANES>,
- body2: &JointSolverBody<N, LANES>,
- _locked_axis: usize,
- writeback_id: WritebackId,
- ) -> JointTwoBodyConstraint<N, LANES> {
- #[cfg(feature = "dim2")]
- let ang_jac = N::one();
- #[cfg(feature = "dim3")]
- let ang_jac = self.ang_basis.column(_locked_axis).into_owned();
-
- let rhs_wo_bias = N::zero();
- let erp_inv_dt = N::splat(params.joint_erp_inv_dt());
- let cfm_coeff = N::splat(params.joint_cfm_coeff());
- #[cfg(feature = "dim2")]
- let rhs_bias = self.ang_err.im * erp_inv_dt;
- #[cfg(feature = "dim3")]
- let rhs_bias = self.ang_err.imag()[_locked_axis] * erp_inv_dt;
-
- let ang_jac1 = body1.sqrt_ii * ang_jac;
- let ang_jac2 = body2.sqrt_ii * ang_jac;
-
- JointTwoBodyConstraint {
- joint_id,
- solver_vel1: body1.solver_vel,
- solver_vel2: body2.solver_vel,
- im1: body1.im,
- im2: body2.im,
- impulse: N::zero(),
- impulse_bounds: [-N::splat(Real::MAX), N::splat(Real::MAX)],
- lin_jac: na::zero(),
- ang_jac1,
- ang_jac2,
- inv_lhs: N::zero(), // Will be set during ortogonalization.
- cfm_coeff,
- cfm_gain: N::zero(),
- rhs: rhs_wo_bias + rhs_bias,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- /// Orthogonalize the constraints and set their inv_lhs field.
- pub fn finalize_constraints<const LANES: usize>(
- constraints: &mut [JointTwoBodyConstraint<N, LANES>],
- ) {
- let len = constraints.len();
-
- if len == 0 {
- return;
- }
-
- let imsum = constraints[0].im1 + constraints[0].im2;
-
- // Use the modified Gram-Schmidt orthogonalization.
- for j in 0..len {
- let c_j = &mut constraints[j];
- let dot_jj = c_j.lin_jac.dot(&imsum.component_mul(&c_j.lin_jac))
- + c_j.ang_jac1.gdot(c_j.ang_jac1)
- + c_j.ang_jac2.gdot(c_j.ang_jac2);
- let cfm_gain = dot_jj * c_j.cfm_coeff + c_j.cfm_gain;
- let inv_dot_jj = crate::utils::simd_inv(dot_jj);
- c_j.inv_lhs = crate::utils::simd_inv(dot_jj + cfm_gain); // Don’t forget to update the inv_lhs.
- c_j.cfm_gain = cfm_gain;
-
- if c_j.impulse_bounds != [-N::splat(Real::MAX), N::splat(Real::MAX)] {
- // Don't remove constraints with limited forces from the others
- // because they may not deliver the necessary forces to fulfill
- // the removed parts of other constraints.
- continue;
- }
-
- for i in (j + 1)..len {
- let (c_i, c_j) = constraints.index_mut_const(i, j);
-
- let dot_ij = c_i.lin_jac.dot(&imsum.component_mul(&c_j.lin_jac))
- + c_i.ang_jac1.gdot(c_j.ang_jac1)
- + c_i.ang_jac2.gdot(c_j.ang_jac2);
- let coeff = dot_ij * inv_dot_jj;
-
- c_i.lin_jac -= c_j.lin_jac * coeff;
- c_i.ang_jac1 -= c_j.ang_jac1 * coeff;
- c_i.ang_jac2 -= c_j.ang_jac2 * coeff;
- c_i.rhs_wo_bias -= c_j.rhs_wo_bias * coeff;
- c_i.rhs -= c_j.rhs * coeff;
- }
- }
- }
-
- pub fn limit_linear_one_body<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointFixedSolverBody<N>,
- body2: &JointSolverBody<N, LANES>,
- limited_axis: usize,
- limits: [N; 2],
- writeback_id: WritebackId,
- ) -> JointOneBodyConstraint<N, LANES> {
- let zero = N::zero();
- let lin_jac = self.basis.column(limited_axis).into_owned();
- let dist = self.lin_err.dot(&lin_jac);
-
- let min_enabled = dist.simd_le(limits[0]);
- let max_enabled = limits[1].simd_le(dist);
-
- let impulse_bounds = [
- N::splat(-Real::INFINITY).select(min_enabled, zero),
- N::splat(Real::INFINITY).select(max_enabled, zero),
- ];
-
- let ang_jac1 = self.cmat1_basis.column(limited_axis).into_owned();
- #[cfg(feature = "dim2")]
- let mut ang_jac2 = self.cmat2_basis[limited_axis];
- #[cfg(feature = "dim3")]
- let mut ang_jac2 = self.cmat2_basis.column(limited_axis).into_owned();
-
- let rhs_wo_bias = -lin_jac.dot(&body1.linvel) - ang_jac1.gdot(body1.angvel);
- let erp_inv_dt = N::splat(params.joint_erp_inv_dt());
- let cfm_coeff = N::splat(params.joint_cfm_coeff());
- let rhs_bias =
- ((dist - limits[1]).simd_max(zero) - (limits[0] - dist).simd_max(zero)) * erp_inv_dt;
-
- ang_jac2 = body2.sqrt_ii * ang_jac2;
-
- JointOneBodyConstraint {
- joint_id,
- solver_vel2: body2.solver_vel,
- im2: body2.im,
- impulse: zero,
- impulse_bounds,
- lin_jac,
- ang_jac2,
- inv_lhs: zero, // Will be set during ortogonalization.
- cfm_coeff,
- cfm_gain: N::zero(),
- rhs: rhs_wo_bias + rhs_bias,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- pub fn limit_linear_coupled_one_body<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointFixedSolverBody<N>,
- body2: &JointSolverBody<N, LANES>,
- coupled_axes: u8,
- limits: [N; 2],
- writeback_id: WritebackId,
- ) -> JointOneBodyConstraint<N, LANES> {
- let zero = N::zero();
- let mut lin_jac = Vector::zeros();
- let mut ang_jac1: AngVector<N> = na::zero();
- let mut ang_jac2: AngVector<N> = na::zero();
-
- for i in 0..DIM {
- if coupled_axes & (1 << i) != 0 {
- let coeff = self.basis.column(i).dot(&self.lin_err);
- lin_jac += self.basis.column(i) * coeff;
- #[cfg(feature = "dim2")]
- {
- ang_jac1 += self.cmat1_basis[i] * coeff;
- ang_jac2 += self.cmat2_basis[i] * coeff;
- }
- #[cfg(feature = "dim3")]
- {
- ang_jac1 += self.cmat1_basis.column(i) * coeff;
- ang_jac2 += self.cmat2_basis.column(i) * coeff;
- }
- }
- }
-
- let dist = lin_jac.norm();
- let inv_dist = crate::utils::simd_inv(dist);
- lin_jac *= inv_dist;
- ang_jac1 *= inv_dist;
- ang_jac2 *= inv_dist;
-
- // FIXME: handle min limit too.
- let proj_vel1 = -lin_jac.dot(&body1.linvel) - ang_jac1.gdot(body1.angvel);
- let rhs_wo_bias = proj_vel1 + (dist - limits[1]).simd_min(zero) * N::splat(params.inv_dt());
-
- ang_jac2 = body2.sqrt_ii * ang_jac2;
-
- let erp_inv_dt = N::splat(params.joint_erp_inv_dt());
- let cfm_coeff = N::splat(params.joint_cfm_coeff());
- let rhs_bias = (dist - limits[1]).simd_max(zero) * erp_inv_dt;
- let rhs = rhs_wo_bias + rhs_bias;
- let impulse_bounds = [N::zero(), N::splat(Real::INFINITY)];
-
- JointOneBodyConstraint {
- joint_id,
- solver_vel2: body2.solver_vel,
- im2: body2.im,
- impulse: N::zero(),
- impulse_bounds,
- lin_jac,
- ang_jac2,
- inv_lhs: N::zero(), // Will be set during ortogonalization.
- cfm_coeff,
- cfm_gain: N::zero(),
- rhs,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- pub fn motor_linear_one_body<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointFixedSolverBody<N>,
- body2: &JointSolverBody<N, LANES>,
- motor_axis: usize,
- motor_params: &MotorParameters<N>,
- limits: Option<[N; 2]>,
- writeback_id: WritebackId,
- ) -> JointOneBodyConstraint<N, LANES> {
- let inv_dt = N::splat(params.inv_dt());
-
- let lin_jac = self.basis.column(motor_axis).into_owned();
- let ang_jac1 = self.cmat1_basis.column(motor_axis).into_owned();
- #[cfg(feature = "dim2")]
- let mut ang_jac2 = self.cmat2_basis[motor_axis];
- #[cfg(feature = "dim3")]
- let mut ang_jac2 = self.cmat2_basis.column(motor_axis).into_owned();
-
- let mut rhs_wo_bias = N::zero();
- if motor_params.erp_inv_dt != N::zero() {
- let dist = self.lin_err.dot(&lin_jac);
- rhs_wo_bias += (dist - motor_params.target_pos) * motor_params.erp_inv_dt;
- }
-
- let mut target_vel = motor_params.target_vel;
- if let Some(limits) = limits {
- let dist = self.lin_err.dot(&lin_jac);
- target_vel =
- target_vel.simd_clamp((limits[0] - dist) * inv_dt, (limits[1] - dist) * inv_dt);
- };
-
- let proj_vel1 = -lin_jac.dot(&body1.linvel) - ang_jac1.gdot(body1.angvel);
- rhs_wo_bias += proj_vel1 - target_vel;
-
- ang_jac2 = body2.sqrt_ii * ang_jac2;
-
- JointOneBodyConstraint {
- joint_id,
- solver_vel2: body2.solver_vel,
- im2: body2.im,
- impulse: N::zero(),
- impulse_bounds: [-motor_params.max_impulse, motor_params.max_impulse],
- lin_jac,
- ang_jac2,
- inv_lhs: N::zero(), // Will be set during ortogonalization.
- cfm_coeff: motor_params.cfm_coeff,
- cfm_gain: motor_params.cfm_gain,
- rhs: rhs_wo_bias,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- pub fn motor_linear_coupled_one_body<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointFixedSolverBody<N>,
- body2: &JointSolverBody<N, LANES>,
- coupled_axes: u8,
- motor_params: &MotorParameters<N>,
- limits: Option<[N; 2]>,
- writeback_id: WritebackId,
- ) -> JointOneBodyConstraint<N, LANES> {
- let inv_dt = N::splat(params.inv_dt());
-
- let mut lin_jac = Vector::zeros();
- let mut ang_jac1: AngVector<N> = na::zero();
- let mut ang_jac2: AngVector<N> = na::zero();
-
- for i in 0..DIM {
- if coupled_axes & (1 << i) != 0 {
- let coeff = self.basis.column(i).dot(&self.lin_err);
- lin_jac += self.basis.column(i) * coeff;
- #[cfg(feature = "dim2")]
- {
- ang_jac1 += self.cmat1_basis[i] * coeff;
- ang_jac2 += self.cmat2_basis[i] * coeff;
- }
- #[cfg(feature = "dim3")]
- {
- ang_jac1 += self.cmat1_basis.column(i) * coeff;
- ang_jac2 += self.cmat2_basis.column(i) * coeff;
- }
- }
- }
-
- let dist = lin_jac.norm();
- let inv_dist = crate::utils::simd_inv(dist);
- lin_jac *= inv_dist;
- ang_jac1 *= inv_dist;
- ang_jac2 *= inv_dist;
-
- let mut rhs_wo_bias = N::zero();
- if motor_params.erp_inv_dt != N::zero() {
- rhs_wo_bias += (dist - motor_params.target_pos) * motor_params.erp_inv_dt;
- }
-
- let mut target_vel = motor_params.target_vel;
- if let Some(limits) = limits {
- target_vel =
- target_vel.simd_clamp((limits[0] - dist) * inv_dt, (limits[1] - dist) * inv_dt);
- };
-
- let proj_vel1 = -lin_jac.dot(&body1.linvel) - ang_jac1.gdot(body1.angvel);
- rhs_wo_bias += proj_vel1 - target_vel;
-
- ang_jac2 = body2.sqrt_ii * ang_jac2;
-
- JointOneBodyConstraint {
- joint_id,
- solver_vel2: body2.solver_vel,
- im2: body2.im,
- impulse: N::zero(),
- impulse_bounds: [-motor_params.max_impulse, motor_params.max_impulse],
- lin_jac,
- ang_jac2,
- inv_lhs: N::zero(), // Will be set during ortogonalization.
- cfm_coeff: motor_params.cfm_coeff,
- cfm_gain: motor_params.cfm_gain,
- rhs: rhs_wo_bias,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- pub fn lock_linear_one_body<const LANES: usize>(
- &self,
- params: &IntegrationParameters,
- joint_id: [JointIndex; LANES],
- body1: &JointFixedSolverBody<N>,
- body2: &JointSolverBody<N, LANES>,
- locked_axis: usize,
- writeback_id: WritebackId,
- ) -> JointOneBodyConstraint<N, LANES> {
- let lin_jac = self.basis.column(locked_axis).into_owned();
- let ang_jac1 = self.cmat1_basis.column(locked_axis).into_owned();
- #[cfg(feature = "dim2")]
- let mut ang_jac2 = self.cmat2_basis[locked_axis];
- #[cfg(feature = "dim3")]
- let mut ang_jac2 = self.cmat2_basis.column(locked_axis).into_owned();
-
- let rhs_wo_bias = -lin_jac.dot(&body1.linvel) - ang_jac1.gdot(body1.angvel);
-
- let erp_inv_dt = N::splat(params.joint_erp_inv_dt());
- let cfm_coeff = N::splat(params.joint_cfm_coeff());
- let rhs_bias = lin_jac.dot(&self.lin_err) * erp_inv_dt;
-
- ang_jac2 = body2.sqrt_ii * ang_jac2;
-
- JointOneBodyConstraint {
- joint_id,
- solver_vel2: body2.solver_vel,
- im2: body2.im,
- impulse: N::zero(),
- impulse_bounds: [-N::splat(Real::MAX), N::splat(Real::MAX)],
- lin_jac,
- ang_jac2,
- inv_lhs: N::zero(), // Will be set during ortogonalization.
- cfm_coeff,
- cfm_gain: N::zero(),
- rhs: rhs_wo_bias + rhs_bias,
- rhs_wo_bias,
- writeback_id,
- }
- }
-
- pub fn motor_angular_one_body<const LANES: usize>(
- &self,
- joint_id: [JointIndex; LANES],
- body1: &JointFixedSolverBody<N>,
- body2: &JointSolverBody<N, LANES>,
- _motor_axis: usize,
- motor_params: &MotorParameters<N>,
- writeback_id: WritebackId,
- ) -> JointOneBodyConstraint<N, LANES> {
- #[cfg(feature = "dim2")]
- let ang_jac = N::one();
- #[cfg(feature = "dim3")]
- let ang_jac = self.basis.column(_motor_axis).into_owned();
-
- let mut rhs_wo_bias = N::zero();
- if motor_params.erp_inv_dt != N::zero() {
- #[cfg(feature = "dim2")]
- let ang_dist = self.ang_err.angle();
- #[cfg(feature = "dim3")]
- let ang_dist = self.ang_err.imag()[_motor_axis].simd_asin() * N::splat(2.0);
- let target_ang = motor_params.target_pos;
- rhs_wo_bias += utils::smallest_abs_diff_between_angles(ang_dist, target_ang)
- * motor_params.erp_inv_dt;
- }
-
- let proj_vel1 = -ang_jac.gdot(body1.angvel);