29e07dfa4e
This allows distro unbundling again for distros that ship Bullet 2.89+.
592 lines
23 KiB
C++
592 lines
23 KiB
C++
/*
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Written by Xuchen Han <xuchenhan2015@u.northwestern.edu>
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Bullet Continuous Collision Detection and Physics Library
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Copyright (c) 2019 Google Inc. http://bulletphysics.org
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This software is provided 'as-is', without any express or implied warranty.
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In no event will the authors be held liable for any damages arising from the use of this software.
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Permission is granted to anyone to use this software for any purpose,
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including commercial applications, and to alter it and redistribute it freely,
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subject to the following restrictions:
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1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required.
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2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
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3. This notice may not be removed or altered from any source distribution.
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*/
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#include "btDeformableContactConstraint.h"
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/* ================ Deformable Node Anchor =================== */
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btDeformableNodeAnchorConstraint::btDeformableNodeAnchorConstraint(const btSoftBody::DeformableNodeRigidAnchor& a)
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: m_anchor(&a)
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, btDeformableContactConstraint(a.m_cti.m_normal)
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{
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}
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btDeformableNodeAnchorConstraint::btDeformableNodeAnchorConstraint(const btDeformableNodeAnchorConstraint& other)
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: m_anchor(other.m_anchor)
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, btDeformableContactConstraint(other)
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{
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}
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btVector3 btDeformableNodeAnchorConstraint::getVa() const
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{
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const btSoftBody::sCti& cti = m_anchor->m_cti;
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btVector3 va(0, 0, 0);
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if (cti.m_colObj->hasContactResponse())
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{
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btRigidBody* rigidCol = 0;
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btMultiBodyLinkCollider* multibodyLinkCol = 0;
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// grab the velocity of the rigid body
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if (cti.m_colObj->getInternalType() == btCollisionObject::CO_RIGID_BODY)
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{
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rigidCol = (btRigidBody*)btRigidBody::upcast(cti.m_colObj);
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va = rigidCol ? (rigidCol->getVelocityInLocalPoint(m_anchor->m_c1)) : btVector3(0, 0, 0);
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}
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else if (cti.m_colObj->getInternalType() == btCollisionObject::CO_FEATHERSTONE_LINK)
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{
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multibodyLinkCol = (btMultiBodyLinkCollider*)btMultiBodyLinkCollider::upcast(cti.m_colObj);
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if (multibodyLinkCol)
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{
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const int ndof = multibodyLinkCol->m_multiBody->getNumDofs() + 6;
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const btScalar* J_n = &m_anchor->jacobianData_normal.m_jacobians[0];
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const btScalar* J_t1 = &m_anchor->jacobianData_t1.m_jacobians[0];
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const btScalar* J_t2 = &m_anchor->jacobianData_t2.m_jacobians[0];
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const btScalar* local_v = multibodyLinkCol->m_multiBody->getVelocityVector();
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const btScalar* local_dv = multibodyLinkCol->m_multiBody->getDeltaVelocityVector();
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// add in the normal component of the va
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btScalar vel = 0.0;
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for (int k = 0; k < ndof; ++k)
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{
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vel += (local_v[k]+local_dv[k]) * J_n[k];
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}
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va = cti.m_normal * vel;
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// add in the tangential components of the va
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vel = 0.0;
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for (int k = 0; k < ndof; ++k)
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{
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vel += (local_v[k]+local_dv[k]) * J_t1[k];
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}
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va += m_anchor->t1 * vel;
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vel = 0.0;
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for (int k = 0; k < ndof; ++k)
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{
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vel += (local_v[k]+local_dv[k]) * J_t2[k];
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}
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va += m_anchor->t2 * vel;
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}
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}
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}
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return va;
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}
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btScalar btDeformableNodeAnchorConstraint::solveConstraint()
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{
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const btSoftBody::sCti& cti = m_anchor->m_cti;
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btVector3 va = getVa();
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btVector3 vb = getVb();
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btVector3 vr = (vb - va);
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// + (m_anchor->m_node->m_x - cti.m_colObj->getWorldTransform() * m_anchor->m_local) * 10.0
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const btScalar dn = btDot(vr, cti.m_normal);
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// dn is the normal component of velocity diffrerence. Approximates the residual. // todo xuchenhan@: this prob needs to be scaled by dt
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btScalar residualSquare = dn*dn;
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btVector3 impulse = m_anchor->m_c0 * vr;
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// apply impulse to deformable nodes involved and change their velocities
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applyImpulse(impulse);
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// apply impulse to the rigid/multibodies involved and change their velocities
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if (cti.m_colObj->getInternalType() == btCollisionObject::CO_RIGID_BODY)
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{
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btRigidBody* rigidCol = 0;
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rigidCol = (btRigidBody*)btRigidBody::upcast(cti.m_colObj);
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if (rigidCol)
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{
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rigidCol->applyImpulse(impulse, m_anchor->m_c1);
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}
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}
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else if (cti.m_colObj->getInternalType() == btCollisionObject::CO_FEATHERSTONE_LINK)
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{
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btMultiBodyLinkCollider* multibodyLinkCol = 0;
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multibodyLinkCol = (btMultiBodyLinkCollider*)btMultiBodyLinkCollider::upcast(cti.m_colObj);
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if (multibodyLinkCol)
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{
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const btScalar* deltaV_normal = &m_anchor->jacobianData_normal.m_deltaVelocitiesUnitImpulse[0];
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// apply normal component of the impulse
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multibodyLinkCol->m_multiBody->applyDeltaVeeMultiDof2(deltaV_normal, impulse.dot(cti.m_normal));
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// apply tangential component of the impulse
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const btScalar* deltaV_t1 = &m_anchor->jacobianData_t1.m_deltaVelocitiesUnitImpulse[0];
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multibodyLinkCol->m_multiBody->applyDeltaVeeMultiDof2(deltaV_t1, impulse.dot(m_anchor->t1));
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const btScalar* deltaV_t2 = &m_anchor->jacobianData_t2.m_deltaVelocitiesUnitImpulse[0];
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multibodyLinkCol->m_multiBody->applyDeltaVeeMultiDof2(deltaV_t2, impulse.dot(m_anchor->t2));
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}
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}
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return residualSquare;
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}
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btVector3 btDeformableNodeAnchorConstraint::getVb() const
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{
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return m_anchor->m_node->m_v;
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}
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void btDeformableNodeAnchorConstraint::applyImpulse(const btVector3& impulse)
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{
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btVector3 dv = impulse * m_anchor->m_c2;
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m_anchor->m_node->m_v -= dv;
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}
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/* ================ Deformable vs. Rigid =================== */
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btDeformableRigidContactConstraint::btDeformableRigidContactConstraint(const btSoftBody::DeformableRigidContact& c)
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: m_contact(&c)
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, btDeformableContactConstraint(c.m_cti.m_normal)
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{
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m_total_normal_dv.setZero();
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m_total_tangent_dv.setZero();
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// penetration is non-positive. The magnitude of penetration is the depth of penetration.
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m_penetration = btMin(btScalar(0), c.m_cti.m_offset);
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}
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btDeformableRigidContactConstraint::btDeformableRigidContactConstraint(const btDeformableRigidContactConstraint& other)
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: m_contact(other.m_contact)
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, btDeformableContactConstraint(other)
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, m_penetration(other.m_penetration)
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{
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m_total_normal_dv = other.m_total_normal_dv;
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m_total_tangent_dv = other.m_total_tangent_dv;
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}
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btVector3 btDeformableRigidContactConstraint::getVa() const
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{
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const btSoftBody::sCti& cti = m_contact->m_cti;
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btVector3 va(0, 0, 0);
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if (cti.m_colObj->hasContactResponse())
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{
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btRigidBody* rigidCol = 0;
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btMultiBodyLinkCollider* multibodyLinkCol = 0;
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// grab the velocity of the rigid body
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if (cti.m_colObj->getInternalType() == btCollisionObject::CO_RIGID_BODY)
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{
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rigidCol = (btRigidBody*)btRigidBody::upcast(cti.m_colObj);
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va = rigidCol ? (rigidCol->getVelocityInLocalPoint(m_contact->m_c1)) : btVector3(0, 0, 0);
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}
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else if (cti.m_colObj->getInternalType() == btCollisionObject::CO_FEATHERSTONE_LINK)
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{
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multibodyLinkCol = (btMultiBodyLinkCollider*)btMultiBodyLinkCollider::upcast(cti.m_colObj);
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if (multibodyLinkCol)
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{
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const int ndof = multibodyLinkCol->m_multiBody->getNumDofs() + 6;
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const btScalar* J_n = &m_contact->jacobianData_normal.m_jacobians[0];
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const btScalar* J_t1 = &m_contact->jacobianData_t1.m_jacobians[0];
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const btScalar* J_t2 = &m_contact->jacobianData_t2.m_jacobians[0];
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const btScalar* local_v = multibodyLinkCol->m_multiBody->getVelocityVector();
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const btScalar* local_dv = multibodyLinkCol->m_multiBody->getDeltaVelocityVector();
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// add in the normal component of the va
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btScalar vel = 0.0;
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for (int k = 0; k < ndof; ++k)
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{
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vel += (local_v[k]+local_dv[k]) * J_n[k];
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}
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va = cti.m_normal * vel;
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// add in the tangential components of the va
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vel = 0.0;
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for (int k = 0; k < ndof; ++k)
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{
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vel += (local_v[k]+local_dv[k]) * J_t1[k];
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}
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va += m_contact->t1 * vel;
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vel = 0.0;
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for (int k = 0; k < ndof; ++k)
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{
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vel += (local_v[k]+local_dv[k]) * J_t2[k];
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}
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va += m_contact->t2 * vel;
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}
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}
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}
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return va;
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}
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btScalar btDeformableRigidContactConstraint::solveConstraint()
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{
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const btSoftBody::sCti& cti = m_contact->m_cti;
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btVector3 va = getVa();
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btVector3 vb = getVb();
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btVector3 vr = vb - va;
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const btScalar dn = btDot(vr, cti.m_normal);
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// dn is the normal component of velocity diffrerence. Approximates the residual. // todo xuchenhan@: this prob needs to be scaled by dt
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btScalar residualSquare = dn*dn;
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btVector3 impulse = m_contact->m_c0 * vr;
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const btVector3 impulse_normal = m_contact->m_c0 * (cti.m_normal * dn);
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btVector3 impulse_tangent = impulse - impulse_normal;
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btVector3 old_total_tangent_dv = m_total_tangent_dv;
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// m_c2 is the inverse mass of the deformable node/face
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m_total_normal_dv -= impulse_normal * m_contact->m_c2;
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m_total_tangent_dv -= impulse_tangent * m_contact->m_c2;
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if (m_total_normal_dv.dot(cti.m_normal) < 0)
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{
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// separating in the normal direction
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m_static = false;
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m_total_tangent_dv = btVector3(0,0,0);
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impulse_tangent.setZero();
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}
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else
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{
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if (m_total_normal_dv.norm() * m_contact->m_c3 < m_total_tangent_dv.norm())
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{
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// dynamic friction
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// with dynamic friction, the impulse are still applied to the two objects colliding, however, it does not pose a constraint in the cg solve, hence the change to dv merely serves to update velocity in the contact iterations.
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m_static = false;
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if (m_total_tangent_dv.safeNorm() < SIMD_EPSILON)
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{
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m_total_tangent_dv = btVector3(0,0,0);
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}
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else
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{
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m_total_tangent_dv = m_total_tangent_dv.normalized() * m_total_normal_dv.safeNorm() * m_contact->m_c3;
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}
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impulse_tangent = -btScalar(1)/m_contact->m_c2 * (m_total_tangent_dv - old_total_tangent_dv);
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}
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else
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{
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// static friction
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m_static = true;
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}
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}
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impulse = impulse_normal + impulse_tangent;
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// apply impulse to deformable nodes involved and change their velocities
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applyImpulse(impulse);
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// apply impulse to the rigid/multibodies involved and change their velocities
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if (cti.m_colObj->getInternalType() == btCollisionObject::CO_RIGID_BODY)
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{
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btRigidBody* rigidCol = 0;
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rigidCol = (btRigidBody*)btRigidBody::upcast(cti.m_colObj);
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if (rigidCol)
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{
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rigidCol->applyImpulse(impulse, m_contact->m_c1);
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}
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}
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else if (cti.m_colObj->getInternalType() == btCollisionObject::CO_FEATHERSTONE_LINK)
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{
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btMultiBodyLinkCollider* multibodyLinkCol = 0;
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multibodyLinkCol = (btMultiBodyLinkCollider*)btMultiBodyLinkCollider::upcast(cti.m_colObj);
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if (multibodyLinkCol)
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{
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const btScalar* deltaV_normal = &m_contact->jacobianData_normal.m_deltaVelocitiesUnitImpulse[0];
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// apply normal component of the impulse
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multibodyLinkCol->m_multiBody->applyDeltaVeeMultiDof2(deltaV_normal, impulse.dot(cti.m_normal));
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if (impulse_tangent.norm() > SIMD_EPSILON)
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{
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// apply tangential component of the impulse
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const btScalar* deltaV_t1 = &m_contact->jacobianData_t1.m_deltaVelocitiesUnitImpulse[0];
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multibodyLinkCol->m_multiBody->applyDeltaVeeMultiDof2(deltaV_t1, impulse.dot(m_contact->t1));
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const btScalar* deltaV_t2 = &m_contact->jacobianData_t2.m_deltaVelocitiesUnitImpulse[0];
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multibodyLinkCol->m_multiBody->applyDeltaVeeMultiDof2(deltaV_t2, impulse.dot(m_contact->t2));
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}
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}
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}
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return residualSquare;
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}
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btScalar btDeformableRigidContactConstraint::solveSplitImpulse(const btContactSolverInfo& infoGlobal)
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{
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const btSoftBody::sCti& cti = m_contact->m_cti;
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const btScalar dn = m_penetration;
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if (dn != 0)
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{
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const btVector3 impulse = (m_contact->m_c0 * (cti.m_normal * dn / infoGlobal.m_timeStep));
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// one iteration of the position impulse corrects all the position error at this timestep
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m_penetration -= dn;
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// apply impulse to deformable nodes involved and change their position
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applySplitImpulse(impulse);
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// apply impulse to the rigid/multibodies involved and change their position
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if (cti.m_colObj->getInternalType() == btCollisionObject::CO_RIGID_BODY)
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{
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btRigidBody* rigidCol = 0;
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rigidCol = (btRigidBody*)btRigidBody::upcast(cti.m_colObj);
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if (rigidCol)
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{
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rigidCol->applyPushImpulse(impulse, m_contact->m_c1);
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}
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}
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else if (cti.m_colObj->getInternalType() == btCollisionObject::CO_FEATHERSTONE_LINK)
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{
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// todo xuchenhan@
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}
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return (m_penetration/infoGlobal.m_timeStep) * (m_penetration/infoGlobal.m_timeStep);
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}
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return 0;
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}
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/* ================ Node vs. Rigid =================== */
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btDeformableNodeRigidContactConstraint::btDeformableNodeRigidContactConstraint(const btSoftBody::DeformableNodeRigidContact& contact)
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: m_node(contact.m_node)
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, btDeformableRigidContactConstraint(contact)
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{
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}
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btDeformableNodeRigidContactConstraint::btDeformableNodeRigidContactConstraint(const btDeformableNodeRigidContactConstraint& other)
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: m_node(other.m_node)
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, btDeformableRigidContactConstraint(other)
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{
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}
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btVector3 btDeformableNodeRigidContactConstraint::getVb() const
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{
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return m_node->m_v;
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}
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btVector3 btDeformableNodeRigidContactConstraint::getDv(const btSoftBody::Node* node) const
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{
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return m_total_normal_dv + m_total_tangent_dv;
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}
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void btDeformableNodeRigidContactConstraint::applyImpulse(const btVector3& impulse)
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{
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const btSoftBody::DeformableNodeRigidContact* contact = getContact();
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btVector3 dv = impulse * contact->m_c2;
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contact->m_node->m_v -= dv;
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}
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void btDeformableNodeRigidContactConstraint::applySplitImpulse(const btVector3& impulse)
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{
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const btSoftBody::DeformableNodeRigidContact* contact = getContact();
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btVector3 dv = impulse * contact->m_c2;
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contact->m_node->m_vsplit -= dv;
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};
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/* ================ Face vs. Rigid =================== */
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btDeformableFaceRigidContactConstraint::btDeformableFaceRigidContactConstraint(const btSoftBody::DeformableFaceRigidContact& contact)
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: m_face(contact.m_face)
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, btDeformableRigidContactConstraint(contact)
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{
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}
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btDeformableFaceRigidContactConstraint::btDeformableFaceRigidContactConstraint(const btDeformableFaceRigidContactConstraint& other)
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: m_face(other.m_face)
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, btDeformableRigidContactConstraint(other)
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{
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}
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btVector3 btDeformableFaceRigidContactConstraint::getVb() const
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{
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const btSoftBody::DeformableFaceRigidContact* contact = getContact();
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btVector3 vb = m_face->m_n[0]->m_v * contact->m_bary[0] + m_face->m_n[1]->m_v * contact->m_bary[1] + m_face->m_n[2]->m_v * contact->m_bary[2];
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return vb;
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}
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btVector3 btDeformableFaceRigidContactConstraint::getDv(const btSoftBody::Node* node) const
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{
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btVector3 face_dv = m_total_normal_dv + m_total_tangent_dv;
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const btSoftBody::DeformableFaceRigidContact* contact = getContact();
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if (m_face->m_n[0] == node)
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{
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return face_dv * contact->m_weights[0];
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}
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if (m_face->m_n[1] == node)
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{
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return face_dv * contact->m_weights[1];
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}
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btAssert(node == m_face->m_n[2]);
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return face_dv * contact->m_weights[2];
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}
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void btDeformableFaceRigidContactConstraint::applyImpulse(const btVector3& impulse)
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{
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const btSoftBody::DeformableFaceRigidContact* contact = getContact();
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btVector3 dv = impulse * contact->m_c2;
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btSoftBody::Face* face = contact->m_face;
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btVector3& v0 = face->m_n[0]->m_v;
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btVector3& v1 = face->m_n[1]->m_v;
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btVector3& v2 = face->m_n[2]->m_v;
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const btScalar& im0 = face->m_n[0]->m_im;
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const btScalar& im1 = face->m_n[1]->m_im;
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const btScalar& im2 = face->m_n[2]->m_im;
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|
if (im0 > 0)
|
|
v0 -= dv * contact->m_weights[0];
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|
if (im1 > 0)
|
|
v1 -= dv * contact->m_weights[1];
|
|
if (im2 > 0)
|
|
v2 -= dv * contact->m_weights[2];
|
|
|
|
// apply strain limiting to prevent undamped modes
|
|
btScalar m01 = (btScalar(1)/(im0 + im1));
|
|
btScalar m02 = (btScalar(1)/(im0 + im2));
|
|
btScalar m12 = (btScalar(1)/(im1 + im2));
|
|
|
|
btVector3 dv0 = im0 * (m01 * (v1-v0) + m02 * (v2-v0));
|
|
btVector3 dv1 = im1 * (m01 * (v0-v1) + m12 * (v2-v1));
|
|
btVector3 dv2 = im2 * (m12 * (v1-v2) + m02 * (v0-v2));
|
|
|
|
v0 += dv0;
|
|
v1 += dv1;
|
|
v2 += dv2;
|
|
}
|
|
|
|
void btDeformableFaceRigidContactConstraint::applySplitImpulse(const btVector3& impulse)
|
|
{
|
|
const btSoftBody::DeformableFaceRigidContact* contact = getContact();
|
|
btVector3 dv = impulse * contact->m_c2;
|
|
btSoftBody::Face* face = contact->m_face;
|
|
|
|
btVector3& v0 = face->m_n[0]->m_vsplit;
|
|
btVector3& v1 = face->m_n[1]->m_vsplit;
|
|
btVector3& v2 = face->m_n[2]->m_vsplit;
|
|
const btScalar& im0 = face->m_n[0]->m_im;
|
|
const btScalar& im1 = face->m_n[1]->m_im;
|
|
const btScalar& im2 = face->m_n[2]->m_im;
|
|
if (im0 > 0)
|
|
v0 -= dv * contact->m_weights[0];
|
|
if (im1 > 0)
|
|
v1 -= dv * contact->m_weights[1];
|
|
if (im2 > 0)
|
|
v2 -= dv * contact->m_weights[2];
|
|
}
|
|
|
|
/* ================ Face vs. Node =================== */
|
|
btDeformableFaceNodeContactConstraint::btDeformableFaceNodeContactConstraint(const btSoftBody::DeformableFaceNodeContact& contact)
|
|
: m_node(contact.m_node)
|
|
, m_face(contact.m_face)
|
|
, m_contact(&contact)
|
|
, btDeformableContactConstraint(contact.m_normal)
|
|
{
|
|
m_total_normal_dv.setZero();
|
|
m_total_tangent_dv.setZero();
|
|
}
|
|
|
|
btVector3 btDeformableFaceNodeContactConstraint::getVa() const
|
|
{
|
|
return m_node->m_v;
|
|
}
|
|
|
|
btVector3 btDeformableFaceNodeContactConstraint::getVb() const
|
|
{
|
|
const btSoftBody::DeformableFaceNodeContact* contact = getContact();
|
|
btVector3 vb = m_face->m_n[0]->m_v * contact->m_bary[0] + m_face->m_n[1]->m_v * contact->m_bary[1] + m_face->m_n[2]->m_v * contact->m_bary[2];
|
|
return vb;
|
|
}
|
|
|
|
btVector3 btDeformableFaceNodeContactConstraint::getDv(const btSoftBody::Node* n) const
|
|
{
|
|
btVector3 dv = m_total_normal_dv + m_total_tangent_dv;
|
|
if (n == m_node)
|
|
return dv;
|
|
const btSoftBody::DeformableFaceNodeContact* contact = getContact();
|
|
if (m_face->m_n[0] == n)
|
|
{
|
|
return dv * contact->m_weights[0];
|
|
}
|
|
if (m_face->m_n[1] == n)
|
|
{
|
|
return dv * contact->m_weights[1];
|
|
}
|
|
btAssert(n == m_face->m_n[2]);
|
|
return dv * contact->m_weights[2];
|
|
}
|
|
|
|
btScalar btDeformableFaceNodeContactConstraint::solveConstraint()
|
|
{
|
|
btVector3 va = getVa();
|
|
btVector3 vb = getVb();
|
|
btVector3 vr = vb - va;
|
|
const btScalar dn = btDot(vr, m_contact->m_normal);
|
|
// dn is the normal component of velocity diffrerence. Approximates the residual. // todo xuchenhan@: this prob needs to be scaled by dt
|
|
btScalar residualSquare = dn*dn;
|
|
btVector3 impulse = m_contact->m_c0 * vr;
|
|
const btVector3 impulse_normal = m_contact->m_c0 * (m_contact->m_normal * dn);
|
|
btVector3 impulse_tangent = impulse - impulse_normal;
|
|
|
|
btVector3 old_total_tangent_dv = m_total_tangent_dv;
|
|
// m_c2 is the inverse mass of the deformable node/face
|
|
if (m_node->m_im > 0)
|
|
{
|
|
m_total_normal_dv -= impulse_normal * m_node->m_im;
|
|
m_total_tangent_dv -= impulse_tangent * m_node->m_im;
|
|
}
|
|
else
|
|
{
|
|
m_total_normal_dv -= impulse_normal * m_contact->m_imf;
|
|
m_total_tangent_dv -= impulse_tangent * m_contact->m_imf;
|
|
}
|
|
|
|
if (m_total_normal_dv.dot(m_contact->m_normal) > 0)
|
|
{
|
|
// separating in the normal direction
|
|
m_static = false;
|
|
m_total_tangent_dv = btVector3(0,0,0);
|
|
impulse_tangent.setZero();
|
|
}
|
|
else
|
|
{
|
|
if (m_total_normal_dv.norm() * m_contact->m_friction < m_total_tangent_dv.norm())
|
|
{
|
|
// dynamic friction
|
|
// with dynamic friction, the impulse are still applied to the two objects colliding, however, it does not pose a constraint in the cg solve, hence the change to dv merely serves to update velocity in the contact iterations.
|
|
m_static = false;
|
|
if (m_total_tangent_dv.safeNorm() < SIMD_EPSILON)
|
|
{
|
|
m_total_tangent_dv = btVector3(0,0,0);
|
|
}
|
|
else
|
|
{
|
|
m_total_tangent_dv = m_total_tangent_dv.normalized() * m_total_normal_dv.safeNorm() * m_contact->m_friction;
|
|
}
|
|
impulse_tangent = -btScalar(1)/m_node->m_im * (m_total_tangent_dv - old_total_tangent_dv);
|
|
}
|
|
else
|
|
{
|
|
// static friction
|
|
m_static = true;
|
|
}
|
|
}
|
|
impulse = impulse_normal + impulse_tangent;
|
|
// apply impulse to deformable nodes involved and change their velocities
|
|
applyImpulse(impulse);
|
|
return residualSquare;
|
|
}
|
|
|
|
void btDeformableFaceNodeContactConstraint::applyImpulse(const btVector3& impulse)
|
|
{
|
|
const btSoftBody::DeformableFaceNodeContact* contact = getContact();
|
|
btVector3 dva = impulse * contact->m_node->m_im;
|
|
btVector3 dvb = impulse * contact->m_imf;
|
|
if (contact->m_node->m_im > 0)
|
|
{
|
|
contact->m_node->m_v += dva;
|
|
}
|
|
|
|
btSoftBody::Face* face = contact->m_face;
|
|
btVector3& v0 = face->m_n[0]->m_v;
|
|
btVector3& v1 = face->m_n[1]->m_v;
|
|
btVector3& v2 = face->m_n[2]->m_v;
|
|
const btScalar& im0 = face->m_n[0]->m_im;
|
|
const btScalar& im1 = face->m_n[1]->m_im;
|
|
const btScalar& im2 = face->m_n[2]->m_im;
|
|
if (im0 > 0)
|
|
{
|
|
v0 -= dvb * contact->m_weights[0];
|
|
}
|
|
if (im1 > 0)
|
|
{
|
|
v1 -= dvb * contact->m_weights[1];
|
|
}
|
|
if (im2 > 0)
|
|
{
|
|
v2 -= dvb * contact->m_weights[2];
|
|
}
|
|
// todo: Face node constraints needs more work
|
|
// btScalar m01 = (btScalar(1)/(im0 + im1));
|
|
// btScalar m02 = (btScalar(1)/(im0 + im2));
|
|
// btScalar m12 = (btScalar(1)/(im1 + im2));
|
|
//
|
|
// btVector3 dv0 = im0 * (m01 * (v1-v0) + m02 * (v2-v0));
|
|
// btVector3 dv1 = im1 * (m01 * (v0-v1) + m12 * (v2-v1));
|
|
// btVector3 dv2 = im2 * (m12 * (v1-v2) + m02 * (v0-v2));
|
|
// v0 += dv0;
|
|
// v1 += dv1;
|
|
// v2 += dv2;
|
|
}
|