pinocchio: cartesian-product.hpp Source File

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 //
 // Copyright (c) 2016-2020 CNRS CNRS
 //
 
 #ifndef __pinocchio_multibody_liegroup_cartesian_product_operation_hpp__
 #define __pinocchio_multibody_liegroup_cartesian_product_operation_hpp__
 
 #include <pinocchio/multibody/liegroup/liegroup-base.hpp>
 
 namespace pinocchio
 {
   template<int dim1, int dim2>
   struct eval_set_dim
   {
     enum { value = dim1 + dim2 };
   };
   
   template<int dim>
   struct eval_set_dim<dim,Eigen::Dynamic>
   {
     enum { value = Eigen::Dynamic };
   };
 
   template<int dim>
   struct eval_set_dim<Eigen::Dynamic,dim>
   {
     enum { value = Eigen::Dynamic };
   };
   
   template<typename LieGroup1, typename LieGroup2>
   struct CartesianProductOperation;
   
   template<typename LieGroup1, typename LieGroup2>
   struct traits<CartesianProductOperation<LieGroup1, LieGroup2> > {
     typedef typename traits<LieGroup1>::Scalar Scalar;
     enum {
       Options = traits<LieGroup1>::Options,
       NQ = eval_set_dim<LieGroup1::NQ,LieGroup2::NQ>::value,
       NV = eval_set_dim<LieGroup1::NV,LieGroup2::NV>::value
     };
   };
 
   template<typename LieGroup1, typename LieGroup2>
   struct CartesianProductOperation : public LieGroupBase <CartesianProductOperation<LieGroup1, LieGroup2> >
   {
     PINOCCHIO_LIE_GROUP_TPL_PUBLIC_INTERFACE(CartesianProductOperation);
 
     CartesianProductOperation () : lg1 (), lg2 ()
     {
     }
     // Get dimension of Lie Group vector representation
     //
     // For instance, for SO(3), the dimension of the vector representation is
     // 4 (quaternion) while the dimension of the tangent space is 3.
     Index nq () const
     {
       return lg1.nq () + lg2.nq ();
     }
     
     // Get dimension of Lie Group tangent space
     Index nv () const
     {
       return lg1.nv () + lg2.nv ();
     }
 
     ConfigVector_t neutral () const
     {
       ConfigVector_t n;
       n.resize (nq ());
       Qo1(n) = lg1.neutral ();
       Qo2(n) = lg2.neutral ();
       return n;
     }
 
     std::string name () const
     {
       std::ostringstream oss; oss << lg1.name () << "*" << lg2.name ();
       return oss.str ();
     }
 
     template <class ConfigL_t, class ConfigR_t, class Tangent_t>
     void difference_impl(const Eigen::MatrixBase<ConfigL_t> & q0,
                          const Eigen::MatrixBase<ConfigR_t> & q1,
                          const Eigen::MatrixBase<Tangent_t> & d) const
     {
       lg1.difference(Q1(q0), Q1(q1), Vo1(d));
       lg2.difference(Q2(q0), Q2(q1), Vo2(d));
     }
 
     template <ArgumentPosition arg, class ConfigL_t, class ConfigR_t, class JacobianOut_t>
     void dDifference_impl(const Eigen::MatrixBase<ConfigL_t> & q0,
                           const Eigen::MatrixBase<ConfigR_t> & q1,
                           const Eigen::MatrixBase<JacobianOut_t> & J) const
     {
       J12(J).setZero();
       J21(J).setZero();
 
       lg1.template dDifference<arg> (Q1(q0), Q1(q1), J11(J));
       lg2.template dDifference<arg> (Q2(q0), Q2(q1), J22(J));
     }
 
     template <class ConfigIn_t, class Velocity_t, class ConfigOut_t>
     void integrate_impl(const Eigen::MatrixBase<ConfigIn_t> & q,
                         const Eigen::MatrixBase<Velocity_t> & v,
                         const Eigen::MatrixBase<ConfigOut_t> & qout) const
     {
       lg1.integrate(Q1(q), V1(v), Qo1(qout));
       lg2.integrate(Q2(q), V2(v), Qo2(qout));
     }
     
     template <class Config_t, class Jacobian_t>
     void integrateCoeffWiseJacobian_impl(const Eigen::MatrixBase<Config_t> & q,
                                          const Eigen::MatrixBase<Jacobian_t> & J) const
     {
       assert(J.rows() == nq() && J.cols() == nv() && "J is not of the right dimension");
       Jacobian_t & J_ = PINOCCHIO_EIGEN_CONST_CAST(Jacobian_t,J);
       J_.topRightCorner(lg1.nq(),lg2.nv()).setZero();
       J_.bottomLeftCorner(lg2.nq(),lg1.nv()).setZero();
       
       lg1.integrateCoeffWiseJacobian(Q1(q),
                                       J_.topLeftCorner(lg1.nq(),lg1.nv()));
       lg2.integrateCoeffWiseJacobian(Q2(q), J_.bottomRightCorner(lg2.nq(),lg2.nv()));
     }
 
     template <class Config_t, class Tangent_t, class JacobianOut_t>
     void dIntegrate_dq_impl(const Eigen::MatrixBase<Config_t > & q,
                             const Eigen::MatrixBase<Tangent_t> & v,
                             const Eigen::MatrixBase<JacobianOut_t> & J,
                             const AssignmentOperatorType op=SETTO) const
     {
       switch(op)
         {
         case SETTO:
           J12(J).setZero();
           J21(J).setZero();
           // fallthrough
         case ADDTO:
         case RMTO:
           lg1.dIntegrate_dq(Q1(q), V1(v), J11(J),op);
           lg2.dIntegrate_dq(Q2(q), V2(v), J22(J),op);
           break;
         default:
           assert(false && "Wrong Op requesed value");
           break;
         }      
     }
 
     template <class Config_t, class Tangent_t, class JacobianOut_t>
     void dIntegrate_dv_impl(const Eigen::MatrixBase<Config_t > & q,
                             const Eigen::MatrixBase<Tangent_t> & v,
                             const Eigen::MatrixBase<JacobianOut_t> & J,
                             const AssignmentOperatorType op=SETTO) const
     {
       switch(op)
         {
         case SETTO:
           J12(J).setZero();
           J21(J).setZero();
           // fallthrough
         case ADDTO:
         case RMTO:
           lg1.dIntegrate_dv(Q1(q), V1(v), J11(J),op);
           lg2.dIntegrate_dv(Q2(q), V2(v), J22(J),op);
           break;
         default:
           assert(false && "Wrong Op requesed value");
           break;
         }
     }
 
     template <class Config_t, class Tangent_t, class JacobianIn_t, class JacobianOut_t>
     void dIntegrateTransport_dq_impl(const Eigen::MatrixBase<Config_t > & q,
                                      const Eigen::MatrixBase<Tangent_t> & v,
                                      const Eigen::MatrixBase<JacobianIn_t> & J_in,
                                      const Eigen::MatrixBase<JacobianOut_t> & J_out) const
     {
       JacobianOut_t& Jout = PINOCCHIO_EIGEN_CONST_CAST(JacobianOut_t,J_out);
       JacobianOut_t& Jin = PINOCCHIO_EIGEN_CONST_CAST(JacobianIn_t,J_in);
       lg1.dIntegrateTransport_dq(Q1(q), V1(v), Jin.template topRows<LieGroup1::NV>(),Jout.template topRows<LieGroup1::NV>());
       lg2.dIntegrateTransport_dq(Q2(q), V2(v), Jin.template bottomRows<LieGroup2::NV>(),Jout.template bottomRows<LieGroup2::NV>());
     }
 
     template <class Config_t, class Tangent_t, class JacobianIn_t, class JacobianOut_t>
     void dIntegrateTransport_dv_impl(const Eigen::MatrixBase<Config_t > & q,
                                      const Eigen::MatrixBase<Tangent_t> & v,
                                      const Eigen::MatrixBase<JacobianIn_t> & J_in,
                                      const Eigen::MatrixBase<JacobianOut_t> & J_out) const
     {
       JacobianOut_t& Jout = PINOCCHIO_EIGEN_CONST_CAST(JacobianOut_t,J_out);
       JacobianOut_t& Jin = PINOCCHIO_EIGEN_CONST_CAST(JacobianIn_t,J_in);
       lg1.dIntegrateTransport_dv(Q1(q), V1(v), Jin.template topRows<LieGroup1::NV>(),Jout.template topRows<LieGroup1::NV>());
       lg2.dIntegrateTransport_dv(Q2(q), V2(v), Jin.template bottomRows<LieGroup2::NV>(),Jout.template bottomRows<LieGroup2::NV>());
     }
     
 
     template <class Config_t, class Tangent_t, class Jacobian_t>
     void dIntegrateTransport_dq_impl(const Eigen::MatrixBase<Config_t > & q,
                                      const Eigen::MatrixBase<Tangent_t> & v,
                                      const Eigen::MatrixBase<Jacobian_t> & Jin) const
     {
       Jacobian_t& J = PINOCCHIO_EIGEN_CONST_CAST(Jacobian_t,Jin);
       lg1.dIntegrateTransport_dq(Q1(q), V1(v), J.template topRows<LieGroup1::NV>());
       lg2.dIntegrateTransport_dq(Q2(q), V2(v), J.template bottomRows<LieGroup2::NV>());
     }
 
     template <class Config_t, class Tangent_t, class Jacobian_t>
     void dIntegrateTransport_dv_impl(const Eigen::MatrixBase<Config_t > & q,
                                      const Eigen::MatrixBase<Tangent_t> & v,
                                      const Eigen::MatrixBase<Jacobian_t> & Jin) const
     {
       Jacobian_t& J = PINOCCHIO_EIGEN_CONST_CAST(Jacobian_t,Jin);
       lg1.dIntegrateTransport_dv(Q1(q), V1(v), J.template topRows<LieGroup1::NV>());
       lg2.dIntegrateTransport_dv(Q2(q), V2(v), J.template bottomRows<LieGroup2::NV>());
     }
 
     template <class ConfigL_t, class ConfigR_t>
     Scalar squaredDistance_impl(const Eigen::MatrixBase<ConfigL_t> & q0,
                                 const Eigen::MatrixBase<ConfigR_t> & q1) const
     {
       return lg1.squaredDistance(Q1(q0), Q1(q1))
         +    lg2.squaredDistance(Q2(q0), Q2(q1));
     }
     
     template <class Config_t>
     void normalize_impl (const Eigen::MatrixBase<Config_t>& qout) const
     {
       lg1.normalize(Qo1(qout));
       lg2.normalize(Qo2(qout));
     }
 
     template <class Config_t>
     bool isNormalized_impl (const Eigen::MatrixBase<Config_t>& qin, const Scalar& prec) const
     {
       return lg1.isNormalized(Qo1(qin), prec) && lg2.isNormalized(Qo2(qin), prec);
     }
 
     template <class Config_t>
     void random_impl (const Eigen::MatrixBase<Config_t>& qout) const
     {
       lg1.random(Qo1(qout));
       lg2.random(Qo2(qout));
     }
 
     template <class ConfigL_t, class ConfigR_t, class ConfigOut_t>
     void randomConfiguration_impl(const Eigen::MatrixBase<ConfigL_t> & lower,
                                   const Eigen::MatrixBase<ConfigR_t> & upper,
                                   const Eigen::MatrixBase<ConfigOut_t> & qout)
       const
     {
       lg1.randomConfiguration(Q1(lower), Q1(upper), Qo1(qout));
       lg2.randomConfiguration(Q2(lower), Q2(upper), Qo2(qout));
     }
 
     template <class ConfigL_t, class ConfigR_t>
     bool isSameConfiguration_impl(const Eigen::MatrixBase<ConfigL_t> & q0,
                                   const Eigen::MatrixBase<ConfigR_t> & q1,
                                   const Scalar & prec) const
     {
       return lg1.isSameConfiguration(Q1(q0), Q1(q1), prec)
         &&   lg2.isSameConfiguration(Q2(q0), Q2(q1), prec);
     }
 
     bool isEqual_impl (const CartesianProductOperation& other) const
     {
       return lg1 == other.lg1 && lg2 == other.lg2;
     }
 
     LieGroup1 lg1;
     LieGroup2 lg2;
 
   private:
     // VectorSpaceOperationTpl<-1> within CartesianProductOperation will not work
     // if Eigen version is lower than 3.2.1
 #if EIGEN_VERSION_AT_LEAST(3,2,1)
 # define REMOVE_IF_EIGEN_TOO_LOW(x) x
 #else
 # define REMOVE_IF_EIGEN_TOO_LOW(x)
 #endif
 
     template <typename Config > typename Config ::template ConstFixedSegmentReturnType<LieGroup1::NQ>::Type Q1 (const Eigen::MatrixBase<Config >& q) const { return q.derived().template head<LieGroup1::NQ>(REMOVE_IF_EIGEN_TOO_LOW(lg1.nq())); }
     template <typename Config > typename Config ::template ConstFixedSegmentReturnType<LieGroup2::NQ>::Type Q2 (const Eigen::MatrixBase<Config >& q) const { return q.derived().template tail<LieGroup2::NQ>(REMOVE_IF_EIGEN_TOO_LOW(lg2.nq())); }
     template <typename Tangent> typename Tangent::template ConstFixedSegmentReturnType<LieGroup1::NV>::Type V1 (const Eigen::MatrixBase<Tangent>& v) const { return v.derived().template head<LieGroup1::NV>(REMOVE_IF_EIGEN_TOO_LOW(lg1.nv())); }
     template <typename Tangent> typename Tangent::template ConstFixedSegmentReturnType<LieGroup2::NV>::Type V2 (const Eigen::MatrixBase<Tangent>& v) const { return v.derived().template tail<LieGroup2::NV>(REMOVE_IF_EIGEN_TOO_LOW(lg2.nv())); }
 
     template <typename Config > typename Config ::template      FixedSegmentReturnType<LieGroup1::NQ>::Type Qo1 (const Eigen::MatrixBase<Config >& q) const { return PINOCCHIO_EIGEN_CONST_CAST(Config,q).template head<LieGroup1::NQ>(REMOVE_IF_EIGEN_TOO_LOW(lg1.nq())); }
     template <typename Config > typename Config ::template      FixedSegmentReturnType<LieGroup2::NQ>::Type Qo2 (const Eigen::MatrixBase<Config >& q) const { return PINOCCHIO_EIGEN_CONST_CAST(Config,q).template tail<LieGroup2::NQ>(REMOVE_IF_EIGEN_TOO_LOW(lg2.nq())); }
     template <typename Tangent> typename Tangent::template      FixedSegmentReturnType<LieGroup1::NV>::Type Vo1 (const Eigen::MatrixBase<Tangent>& v) const { return PINOCCHIO_EIGEN_CONST_CAST(Tangent,v).template head<LieGroup1::NV>(REMOVE_IF_EIGEN_TOO_LOW(lg1.nv())); }
     template <typename Tangent> typename Tangent::template      FixedSegmentReturnType<LieGroup2::NV>::Type Vo2 (const Eigen::MatrixBase<Tangent>& v) const { return PINOCCHIO_EIGEN_CONST_CAST(Tangent,v).template tail<LieGroup2::NV>(REMOVE_IF_EIGEN_TOO_LOW(lg2.nv())); }
 
     template <typename Jac> Eigen::Block<Jac, LieGroup1::NV, LieGroup1::NV> J11 (const Eigen::MatrixBase<Jac>& J) const { return PINOCCHIO_EIGEN_CONST_CAST(Jac,J).template     topLeftCorner<LieGroup1::NV, LieGroup1::NV>(lg1.nv(),lg1.nv()); }
     template <typename Jac> Eigen::Block<Jac, LieGroup1::NV, LieGroup2::NV> J12 (const Eigen::MatrixBase<Jac>& J) const { return PINOCCHIO_EIGEN_CONST_CAST(Jac,J).template    topRightCorner<LieGroup1::NV, LieGroup2::NV>(lg1.nv(),lg2.nv()); }
     template <typename Jac> Eigen::Block<Jac, LieGroup2::NV, LieGroup1::NV> J21 (const Eigen::MatrixBase<Jac>& J) const { return PINOCCHIO_EIGEN_CONST_CAST(Jac,J).template  bottomLeftCorner<LieGroup2::NV, LieGroup1::NV>(lg2.nv(),lg1.nv()); }
     template <typename Jac> Eigen::Block<Jac, LieGroup2::NV, LieGroup2::NV> J22 (const Eigen::MatrixBase<Jac>& J) const { return PINOCCHIO_EIGEN_CONST_CAST(Jac,J).template bottomRightCorner<LieGroup2::NV, LieGroup2::NV>(lg2.nv(),lg2.nv()); }
 #undef REMOVE_IF_EIGEN_TOO_LOW
 
   }; // struct CartesianProductOperation
 
 } // namespace pinocchio
 
 #endif // ifndef __pinocchio_multibody_liegroup_cartesian_product_operation_hpp__