2017-08-01 14:30:58 +02:00
# include "btMultiBodyConstraint.h"
# include "BulletDynamics/Dynamics/btRigidBody.h"
2019-01-03 14:26:51 +01:00
# include "btMultiBodyPoint2Point.h" //for testing (BTMBP2PCONSTRAINT_BLOCK_ANGULAR_MOTION_TEST macro)
2017-08-01 14:30:58 +02:00
2021-09-29 15:47:08 +02:00
btMultiBodyConstraint : : btMultiBodyConstraint ( btMultiBody * bodyA , btMultiBody * bodyB , int linkA , int linkB , int numRows , bool isUnilateral , int type )
2019-01-03 14:26:51 +01:00
: m_bodyA ( bodyA ) ,
m_bodyB ( bodyB ) ,
m_linkA ( linkA ) ,
m_linkB ( linkB ) ,
2021-09-29 15:47:08 +02:00
m_type ( type ) ,
2019-01-03 14:26:51 +01:00
m_numRows ( numRows ) ,
m_jacSizeA ( 0 ) ,
m_jacSizeBoth ( 0 ) ,
m_isUnilateral ( isUnilateral ) ,
m_numDofsFinalized ( - 1 ) ,
m_maxAppliedImpulse ( 100 )
2017-08-01 14:30:58 +02:00
{
}
void btMultiBodyConstraint : : updateJacobianSizes ( )
{
2019-01-03 14:26:51 +01:00
if ( m_bodyA )
2017-08-01 14:30:58 +02:00
{
m_jacSizeA = ( 6 + m_bodyA - > getNumDofs ( ) ) ;
}
2019-01-03 14:26:51 +01:00
if ( m_bodyB )
2017-08-01 14:30:58 +02:00
{
m_jacSizeBoth = m_jacSizeA + 6 + m_bodyB - > getNumDofs ( ) ;
}
else
m_jacSizeBoth = m_jacSizeA ;
}
void btMultiBodyConstraint : : allocateJacobiansMultiDof ( )
{
updateJacobianSizes ( ) ;
2019-01-03 14:26:51 +01:00
m_posOffset = ( ( 1 + m_jacSizeBoth ) * m_numRows ) ;
2017-08-01 14:30:58 +02:00
m_data . resize ( ( 2 + m_jacSizeBoth ) * m_numRows ) ;
}
btMultiBodyConstraint : : ~ btMultiBodyConstraint ( )
{
}
2019-01-03 14:26:51 +01:00
void btMultiBodyConstraint : : applyDeltaVee ( btMultiBodyJacobianData & data , btScalar * delta_vee , btScalar impulse , int velocityIndex , int ndof )
2017-08-01 14:30:58 +02:00
{
for ( int i = 0 ; i < ndof ; + + i )
2019-01-03 14:26:51 +01:00
data . m_deltaVelocities [ velocityIndex + i ] + = delta_vee [ i ] * impulse ;
2017-08-01 14:30:58 +02:00
}
2019-01-03 14:26:51 +01:00
btScalar btMultiBodyConstraint : : fillMultiBodyConstraint ( btMultiBodySolverConstraint & solverConstraint ,
btMultiBodyJacobianData & data ,
btScalar * jacOrgA , btScalar * jacOrgB ,
const btVector3 & constraintNormalAng ,
const btVector3 & constraintNormalLin ,
const btVector3 & posAworld , const btVector3 & posBworld ,
btScalar posError ,
const btContactSolverInfo & infoGlobal ,
btScalar lowerLimit , btScalar upperLimit ,
bool angConstraint ,
btScalar relaxation ,
2021-09-29 15:47:08 +02:00
bool isFriction , btScalar desiredVelocity , btScalar cfmSlip ,
btScalar damping )
2017-08-01 14:30:58 +02:00
{
2019-01-03 14:26:51 +01:00
solverConstraint . m_multiBodyA = m_bodyA ;
solverConstraint . m_multiBodyB = m_bodyB ;
solverConstraint . m_linkA = m_linkA ;
solverConstraint . m_linkB = m_linkB ;
btMultiBody * multiBodyA = solverConstraint . m_multiBodyA ;
btMultiBody * multiBodyB = solverConstraint . m_multiBodyB ;
btSolverBody * bodyA = multiBodyA ? 0 : & data . m_solverBodyPool - > at ( solverConstraint . m_solverBodyIdA ) ;
btSolverBody * bodyB = multiBodyB ? 0 : & data . m_solverBodyPool - > at ( solverConstraint . m_solverBodyIdB ) ;
btRigidBody * rb0 = multiBodyA ? 0 : bodyA - > m_originalBody ;
btRigidBody * rb1 = multiBodyB ? 0 : bodyB - > m_originalBody ;
btVector3 rel_pos1 , rel_pos2 ; //these two used to be inited to posAworld and posBworld (respectively) but it does not seem necessary
if ( bodyA )
rel_pos1 = posAworld - bodyA - > getWorldTransform ( ) . getOrigin ( ) ;
if ( bodyB )
rel_pos2 = posBworld - bodyB - > getWorldTransform ( ) . getOrigin ( ) ;
if ( multiBodyA )
{
if ( solverConstraint . m_linkA < 0 )
{
rel_pos1 = posAworld - multiBodyA - > getBasePos ( ) ;
}
else
{
rel_pos1 = posAworld - multiBodyA - > getLink ( solverConstraint . m_linkA ) . m_cachedWorldTransform . getOrigin ( ) ;
}
const int ndofA = multiBodyA - > getNumDofs ( ) + 6 ;
solverConstraint . m_deltaVelAindex = multiBodyA - > getCompanionId ( ) ;
if ( solverConstraint . m_deltaVelAindex < 0 )
{
solverConstraint . m_deltaVelAindex = data . m_deltaVelocities . size ( ) ;
multiBodyA - > setCompanionId ( solverConstraint . m_deltaVelAindex ) ;
data . m_deltaVelocities . resize ( data . m_deltaVelocities . size ( ) + ndofA ) ;
}
else
{
btAssert ( data . m_deltaVelocities . size ( ) > = solverConstraint . m_deltaVelAindex + ndofA ) ;
}
//determine jacobian of this 1D constraint in terms of multibodyA's degrees of freedom
//resize..
solverConstraint . m_jacAindex = data . m_jacobians . size ( ) ;
data . m_jacobians . resize ( data . m_jacobians . size ( ) + ndofA ) ;
//copy/determine
if ( jacOrgA )
{
for ( int i = 0 ; i < ndofA ; i + + )
data . m_jacobians [ solverConstraint . m_jacAindex + i ] = jacOrgA [ i ] ;
}
else
{
btScalar * jac1 = & data . m_jacobians [ solverConstraint . m_jacAindex ] ;
//multiBodyA->fillContactJacobianMultiDof(solverConstraint.m_linkA, posAworld, constraintNormalLin, jac1, data.scratch_r, data.scratch_v, data.scratch_m);
multiBodyA - > fillConstraintJacobianMultiDof ( solverConstraint . m_linkA , posAworld , constraintNormalAng , constraintNormalLin , jac1 , data . scratch_r , data . scratch_v , data . scratch_m ) ;
}
//determine the velocity response of multibodyA to reaction impulses of this constraint (i.e. A[i,i] for i=1,...n_con: multibody's inverse inertia with respect to this 1D constraint)
//resize..
data . m_deltaVelocitiesUnitImpulse . resize ( data . m_deltaVelocitiesUnitImpulse . size ( ) + ndofA ) ; //=> each constraint row has the constrained tree dofs allocated in m_deltaVelocitiesUnitImpulse
btAssert ( data . m_jacobians . size ( ) = = data . m_deltaVelocitiesUnitImpulse . size ( ) ) ;
btScalar * delta = & data . m_deltaVelocitiesUnitImpulse [ solverConstraint . m_jacAindex ] ;
//determine..
multiBodyA - > calcAccelerationDeltasMultiDof ( & data . m_jacobians [ solverConstraint . m_jacAindex ] , delta , data . scratch_r , data . scratch_v ) ;
btVector3 torqueAxis0 ;
if ( angConstraint )
{
torqueAxis0 = constraintNormalAng ;
}
else
{
torqueAxis0 = rel_pos1 . cross ( constraintNormalLin ) ;
}
solverConstraint . m_relpos1CrossNormal = torqueAxis0 ;
solverConstraint . m_contactNormal1 = constraintNormalLin ;
}
else //if(rb0)
{
btVector3 torqueAxis0 ;
if ( angConstraint )
{
torqueAxis0 = constraintNormalAng ;
}
else
{
torqueAxis0 = rel_pos1 . cross ( constraintNormalLin ) ;
}
solverConstraint . m_angularComponentA = rb0 ? rb0 - > getInvInertiaTensorWorld ( ) * torqueAxis0 * rb0 - > getAngularFactor ( ) : btVector3 ( 0 , 0 , 0 ) ;
solverConstraint . m_relpos1CrossNormal = torqueAxis0 ;
solverConstraint . m_contactNormal1 = constraintNormalLin ;
}
if ( multiBodyB )
{
if ( solverConstraint . m_linkB < 0 )
{
rel_pos2 = posBworld - multiBodyB - > getBasePos ( ) ;
}
else
{
rel_pos2 = posBworld - multiBodyB - > getLink ( solverConstraint . m_linkB ) . m_cachedWorldTransform . getOrigin ( ) ;
}
const int ndofB = multiBodyB - > getNumDofs ( ) + 6 ;
solverConstraint . m_deltaVelBindex = multiBodyB - > getCompanionId ( ) ;
if ( solverConstraint . m_deltaVelBindex < 0 )
{
solverConstraint . m_deltaVelBindex = data . m_deltaVelocities . size ( ) ;
multiBodyB - > setCompanionId ( solverConstraint . m_deltaVelBindex ) ;
data . m_deltaVelocities . resize ( data . m_deltaVelocities . size ( ) + ndofB ) ;
}
//determine jacobian of this 1D constraint in terms of multibodyB's degrees of freedom
//resize..
solverConstraint . m_jacBindex = data . m_jacobians . size ( ) ;
data . m_jacobians . resize ( data . m_jacobians . size ( ) + ndofB ) ;
//copy/determine..
if ( jacOrgB )
{
for ( int i = 0 ; i < ndofB ; i + + )
data . m_jacobians [ solverConstraint . m_jacBindex + i ] = jacOrgB [ i ] ;
}
else
{
//multiBodyB->fillContactJacobianMultiDof(solverConstraint.m_linkB, posBworld, -constraintNormalLin, &data.m_jacobians[solverConstraint.m_jacBindex], data.scratch_r, data.scratch_v, data.scratch_m);
multiBodyB - > fillConstraintJacobianMultiDof ( solverConstraint . m_linkB , posBworld , - constraintNormalAng , - constraintNormalLin , & data . m_jacobians [ solverConstraint . m_jacBindex ] , data . scratch_r , data . scratch_v , data . scratch_m ) ;
}
//determine velocity response of multibodyB to reaction impulses of this constraint (i.e. A[i,i] for i=1,...n_con: multibody's inverse inertia with respect to this 1D constraint)
//resize..
data . m_deltaVelocitiesUnitImpulse . resize ( data . m_deltaVelocitiesUnitImpulse . size ( ) + ndofB ) ;
btAssert ( data . m_jacobians . size ( ) = = data . m_deltaVelocitiesUnitImpulse . size ( ) ) ;
btScalar * delta = & data . m_deltaVelocitiesUnitImpulse [ solverConstraint . m_jacBindex ] ;
//determine..
multiBodyB - > calcAccelerationDeltasMultiDof ( & data . m_jacobians [ solverConstraint . m_jacBindex ] , delta , data . scratch_r , data . scratch_v ) ;
btVector3 torqueAxis1 ;
if ( angConstraint )
{
torqueAxis1 = constraintNormalAng ;
}
else
{
torqueAxis1 = rel_pos2 . cross ( constraintNormalLin ) ;
}
solverConstraint . m_relpos2CrossNormal = - torqueAxis1 ;
solverConstraint . m_contactNormal2 = - constraintNormalLin ;
}
else //if(rb1)
{
btVector3 torqueAxis1 ;
if ( angConstraint )
{
torqueAxis1 = constraintNormalAng ;
}
else
{
torqueAxis1 = rel_pos2 . cross ( constraintNormalLin ) ;
}
solverConstraint . m_angularComponentB = rb1 ? rb1 - > getInvInertiaTensorWorld ( ) * - torqueAxis1 * rb1 - > getAngularFactor ( ) : btVector3 ( 0 , 0 , 0 ) ;
solverConstraint . m_relpos2CrossNormal = - torqueAxis1 ;
solverConstraint . m_contactNormal2 = - constraintNormalLin ;
}
{
btVector3 vec ;
btScalar denom0 = 0.f ;
btScalar denom1 = 0.f ;
btScalar * jacB = 0 ;
btScalar * jacA = 0 ;
btScalar * deltaVelA = 0 ;
btScalar * deltaVelB = 0 ;
int ndofA = 0 ;
//determine the "effective mass" of the constrained multibodyA with respect to this 1D constraint (i.e. 1/A[i,i])
if ( multiBodyA )
{
ndofA = multiBodyA - > getNumDofs ( ) + 6 ;
jacA = & data . m_jacobians [ solverConstraint . m_jacAindex ] ;
deltaVelA = & data . m_deltaVelocitiesUnitImpulse [ solverConstraint . m_jacAindex ] ;
for ( int i = 0 ; i < ndofA ; + + i )
{
btScalar j = jacA [ i ] ;
btScalar l = deltaVelA [ i ] ;
denom0 + = j * l ;
}
}
else if ( rb0 )
{
vec = ( solverConstraint . m_angularComponentA ) . cross ( rel_pos1 ) ;
if ( angConstraint )
{
2018-09-07 16:11:04 +02:00
denom0 = constraintNormalAng . dot ( solverConstraint . m_angularComponentA ) ;
2019-01-03 14:26:51 +01:00
}
else
{
denom0 = rb0 - > getInvMass ( ) + constraintNormalLin . dot ( vec ) ;
}
}
//
if ( multiBodyB )
{
const int ndofB = multiBodyB - > getNumDofs ( ) + 6 ;
jacB = & data . m_jacobians [ solverConstraint . m_jacBindex ] ;
deltaVelB = & data . m_deltaVelocitiesUnitImpulse [ solverConstraint . m_jacBindex ] ;
for ( int i = 0 ; i < ndofB ; + + i )
{
btScalar j = jacB [ i ] ;
btScalar l = deltaVelB [ i ] ;
denom1 + = j * l ;
}
}
else if ( rb1 )
{
vec = ( - solverConstraint . m_angularComponentB ) . cross ( rel_pos2 ) ;
if ( angConstraint )
{
2018-09-07 16:11:04 +02:00
denom1 = constraintNormalAng . dot ( - solverConstraint . m_angularComponentB ) ;
2019-01-03 14:26:51 +01:00
}
else
{
denom1 = rb1 - > getInvMass ( ) + constraintNormalLin . dot ( vec ) ;
}
}
//
btScalar d = denom0 + denom1 ;
if ( d > SIMD_EPSILON )
{
solverConstraint . m_jacDiagABInv = relaxation / ( d ) ;
}
else
{
//disable the constraint row to handle singularity/redundant constraint
solverConstraint . m_jacDiagABInv = 0.f ;
}
}
//compute rhs and remaining solverConstraint fields
btScalar penetration = isFriction ? 0 : posError ;
btScalar rel_vel = 0.f ;
int ndofA = 0 ;
int ndofB = 0 ;
{
btVector3 vel1 , vel2 ;
if ( multiBodyA )
{
ndofA = multiBodyA - > getNumDofs ( ) + 6 ;
btScalar * jacA = & data . m_jacobians [ solverConstraint . m_jacAindex ] ;
for ( int i = 0 ; i < ndofA ; + + i )
rel_vel + = multiBodyA - > getVelocityVector ( ) [ i ] * jacA [ i ] ;
}
else if ( rb0 )
{
2018-09-07 16:11:04 +02:00
rel_vel + = rb0 - > getLinearVelocity ( ) . dot ( solverConstraint . m_contactNormal1 ) ;
rel_vel + = rb0 - > getAngularVelocity ( ) . dot ( solverConstraint . m_relpos1CrossNormal ) ;
2019-01-03 14:26:51 +01:00
}
if ( multiBodyB )
{
ndofB = multiBodyB - > getNumDofs ( ) + 6 ;
btScalar * jacB = & data . m_jacobians [ solverConstraint . m_jacBindex ] ;
for ( int i = 0 ; i < ndofB ; + + i )
rel_vel + = multiBodyB - > getVelocityVector ( ) [ i ] * jacB [ i ] ;
}
else if ( rb1 )
{
2018-09-07 16:11:04 +02:00
rel_vel + = rb1 - > getLinearVelocity ( ) . dot ( solverConstraint . m_contactNormal2 ) ;
rel_vel + = rb1 - > getAngularVelocity ( ) . dot ( solverConstraint . m_relpos2CrossNormal ) ;
2019-01-03 14:26:51 +01:00
}
solverConstraint . m_friction = 0.f ; //cp.m_combinedFriction;
}
solverConstraint . m_appliedImpulse = 0.f ;
solverConstraint . m_appliedPushImpulse = 0.f ;
{
btScalar positionalError = 0.f ;
2021-09-29 15:47:08 +02:00
btScalar velocityError = ( desiredVelocity - rel_vel ) * damping ;
2019-01-03 14:26:51 +01:00
btScalar erp = infoGlobal . m_erp2 ;
2017-08-01 14:30:58 +02:00
//split impulse is not implemented yet for btMultiBody*
//if (!infoGlobal.m_splitImpulse || (penetration > infoGlobal.m_splitImpulsePenetrationThreshold))
2019-01-03 14:26:51 +01:00
{
erp = infoGlobal . m_erp ;
}
positionalError = - penetration * erp / infoGlobal . m_timeStep ;
btScalar penetrationImpulse = positionalError * solverConstraint . m_jacDiagABInv ;
btScalar velocityImpulse = velocityError * solverConstraint . m_jacDiagABInv ;
2017-08-01 14:30:58 +02:00
//split impulse is not implemented yet for btMultiBody*
2019-01-03 14:26:51 +01:00
// if (!infoGlobal.m_splitImpulse || (penetration > infoGlobal.m_splitImpulsePenetrationThreshold))
{
//combine position and velocity into rhs
solverConstraint . m_rhs = penetrationImpulse + velocityImpulse ;
solverConstraint . m_rhsPenetration = 0.f ;
}
2017-08-01 14:30:58 +02:00
/*else
{
//split position and velocity into rhs and m_rhsPenetration
solverConstraint . m_rhs = velocityImpulse ;
solverConstraint . m_rhsPenetration = penetrationImpulse ;
}
*/
2019-01-03 14:26:51 +01:00
solverConstraint . m_cfm = 0.f ;
solverConstraint . m_lowerLimit = lowerLimit ;
solverConstraint . m_upperLimit = upperLimit ;
}
return rel_vel ;
2017-08-01 14:30:58 +02:00
}