void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[]) { if (nrhs < 2 || nlhs < 2) { mexErrMsgIdAndTxt( "Drake:jointLimitConstraintsmex:InvalidCall", "Usage: [phi, J] = jointLimitConstraintsmex(mex_model_ptr, q) "); } RigidBodyTree *model = (RigidBodyTree *)getDrakeMexPointer(prhs[0]); if (mxGetNumberOfElements(prhs[1]) != model->number_of_positions()) { mexErrMsgIdAndTxt( "Drake:jointLimitConstraintsmex:InvalidPositionVectorLength", "q contains the wrong number of elements"); } Map<VectorXd> q(mxGetPrSafe(prhs[1]), model->number_of_positions()); size_t numJointConstraints = model->getNumJointLimitConstraints(); plhs[0] = mxCreateDoubleMatrix(numJointConstraints, 1, mxREAL); plhs[1] = mxCreateDoubleMatrix(numJointConstraints, model->number_of_positions(), mxREAL); Map<VectorXd> phi(mxGetPrSafe(plhs[0]), numJointConstraints); Map<MatrixXd> J(mxGetPrSafe(plhs[1]), numJointConstraints, model->number_of_positions()); model->jointLimitConstraints(q, phi, J); }
//[z, Mvn, wvn] = setupLCPmex(mex_model_ptr, cache_ptr, u, phiC, n, D, h, z_inactive_guess_tol) void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[] ) { if (nlhs != 5 || nrhs != 13) { mexErrMsgIdAndTxt("Drake:setupLCPmex:InvalidUsage","Usage: [z, Mvn, wvn, zqp] = setupLCPmex(mex_model_ptr, cache_ptr, u, phiC, n, D, h, z_inactive_guess_tol, z_cached, H, C, B)"); } static unique_ptr<MexWrapper> lcp_mex = unique_ptr<MexWrapper>(new MexWrapper(PATHLCP_MEXFILE)); int arg_num = 0; RigidBodyTree *model = static_cast<RigidBodyTree *>(getDrakeMexPointer(prhs[arg_num++])); KinematicsCache<double>& cache = fromMex(prhs[arg_num++], static_cast<KinematicsCache<double>*>(nullptr)); cache.checkCachedKinematicsSettings(true, true, "solveLCPmex"); const int nq = model->num_positions; const int nv = model->num_velocities; //input mappings const mxArray* u_array = prhs[arg_num++]; const mxArray* phiC_array = prhs[arg_num++]; const mxArray* n_array = prhs[arg_num++]; const mxArray* D_array = prhs[arg_num++]; const mxArray* h_array = prhs[arg_num++]; const mxArray* inactive_guess_array = prhs[arg_num++]; const mxArray* z_cached_array = prhs[arg_num++]; const mxArray* H_array = prhs[arg_num++]; const mxArray* C_array = prhs[arg_num++]; const mxArray* B_array = prhs[arg_num++]; const mxArray* enable_fastqp_array = prhs[arg_num++]; const size_t num_z_cached = mxGetNumberOfElements(z_cached_array); const size_t num_contact_pairs = mxGetNumberOfElements(phiC_array); const size_t mC = mxGetNumberOfElements(D_array); const double z_inactive_guess_tol = mxGetScalar(inactive_guess_array); const double h = mxGetScalar(h_array); const auto& q = cache.getQ(); const auto& v = cache.getV(); const Map<VectorXd> u(mxGetPrSafe(u_array), mxGetNumberOfElements(u_array)); const Map<VectorXd> phiC(mxGetPrSafe(phiC_array), num_contact_pairs); const Map<MatrixXd> n(mxGetPrSafe(n_array), num_contact_pairs, nq); const Map<VectorXd> z_cached(mxGetPrSafe(z_cached_array), num_z_cached); const Map<MatrixXd> H(mxGetPrSafe(H_array), nv, nv); const Map<VectorXd> C(mxGetPrSafe(C_array), nv); const Map<MatrixXd> B(mxGetPrSafe(B_array), mxGetM(B_array), mxGetN(B_array)); const bool enable_fastqp = mxIsLogicalScalarTrue(enable_fastqp_array); VectorXd phiL, phiL_possible, phiC_possible, phiL_check, phiC_check; MatrixXd JL, JL_possible, n_possible, JL_check, n_check; auto phiP = model->positionConstraints(cache); auto JP = model->positionConstraintsJacobian(cache); model->jointLimitConstraints(q, phiL, JL); const size_t nP = phiP.size(); //Convert jacobians to velocity mappings const MatrixXd n_velocity = cache.transformPositionDotMappingToVelocityMapping(n); const MatrixXd JL_velocity = cache.transformPositionDotMappingToVelocityMapping(JL); const auto JP_velocity = cache.transformPositionDotMappingToVelocityMapping(JP); plhs[2] = mxCreateDoubleMatrix(nv, 1, mxREAL); Map<VectorXd> wvn(mxGetPrSafe(plhs[2]), nv); LLT<MatrixXd> H_cholesky(H); // compute the Cholesky decomposition of H wvn = H_cholesky.solve(B * u - C); wvn *= h; wvn += v; //use forward euler step in joint space as //initial guess for active constraints vector<bool> possible_contact; vector<bool> possible_jointlimit; vector<bool> z_inactive; getThresholdInclusion((phiC + h * n_velocity * v).eval(), z_inactive_guess_tol, possible_contact); getThresholdInclusion((phiL + h * JL_velocity * v).eval(), z_inactive_guess_tol, possible_jointlimit); while (true) { //continue from here if our inactive guess fails const size_t nC = getNumTrue(possible_contact); const size_t nL = getNumTrue(possible_jointlimit); const size_t lcp_size = nL + nP + (mC + 2) * nC; plhs[0] = mxCreateDoubleMatrix(lcp_size, 1, mxREAL); plhs[1] = mxCreateDoubleMatrix(nv, lcp_size, mxREAL); Map<VectorXd> z(mxGetPrSafe(plhs[0]), lcp_size); Map<MatrixXd> Mvn(mxGetPrSafe(plhs[1]), nv, lcp_size); if (lcp_size == 0) { plhs[3] = mxCreateDoubleMatrix(1, possible_contact.size(), mxREAL); plhs[4] = mxCreateDoubleMatrix(1, possible_jointlimit.size(), mxREAL); return; } z = VectorXd::Zero(lcp_size); vector<size_t> possible_contact_indices; getInclusionIndices(possible_contact, possible_contact_indices, true); partitionVector(possible_contact, phiC, phiC_possible, phiC_check); partitionVector(possible_jointlimit, phiL, phiL_possible, phiL_check); partitionMatrix(possible_contact, n_velocity, n_possible, n_check); partitionMatrix(possible_jointlimit, JL_velocity, JL_possible, JL_check); MatrixXd D_possible(mC * nC, nv); for (size_t i = 0; i < mC ; i++) { Map<MatrixXd> D_i(mxGetPrSafe(mxGetCell(D_array, i)), num_contact_pairs , nq); MatrixXd D_i_possible, D_i_exclude; filterByIndices(possible_contact_indices, D_i, D_i_possible); D_possible.block(nC * i, 0, nC, nv) = cache.transformPositionDotMappingToVelocityMapping(D_i_possible); } // J in velocity coordinates MatrixXd J(lcp_size, nv); J << JL_possible, JP_velocity, n_possible, D_possible, MatrixXd::Zero(nC, nv); Mvn = H_cholesky.solve(J.transpose()); //solve LCP problem //TODO: call path from C++ (currently only 32-bit C libraries available) mxArray* mxw = mxCreateDoubleMatrix(lcp_size, 1, mxREAL); mxArray* mxlb = mxCreateDoubleMatrix(lcp_size, 1, mxREAL); mxArray* mxub = mxCreateDoubleMatrix(lcp_size, 1, mxREAL); Map<VectorXd> lb(mxGetPrSafe(mxlb), lcp_size); Map<VectorXd> ub(mxGetPrSafe(mxub), lcp_size); lb << VectorXd::Zero(nL), -BIG * VectorXd::Ones(nP), VectorXd::Zero(nC + mC * nC + nC); ub = BIG * VectorXd::Ones(lcp_size); MatrixXd M(lcp_size, lcp_size); Map<VectorXd> w(mxGetPrSafe(mxw), lcp_size); //build LCP matrix M << h * JL_possible * Mvn, h * JP_velocity * Mvn, h * n_possible * Mvn, D_possible * Mvn, MatrixXd::Zero(nC, lcp_size); if (nC > 0) { for (size_t i = 0; i < mC ; i++) { M.block(nL + nP + nC + nC * i, nL + nP + nC + mC * nC, nC, nC) = MatrixXd::Identity(nC, nC); M.block(nL + nP + nC + mC*nC, nL + nP + nC + nC * i, nC, nC) = -MatrixXd::Identity(nC, nC); } double mu = 1.0; //TODO: pull this from contactConstraints M.block(nL + nP + nC + mC * nC, nL + nP, nC, nC) = mu * MatrixXd::Identity(nC, nC); } //build LCP vector w << phiL_possible + h * JL_possible * wvn, phiP + h * JP_velocity * wvn, phiC_possible + h * n_possible * wvn, D_possible * wvn, VectorXd::Zero(nC); //try fastQP first bool qp_failed = true; if (enable_fastqp) { if (num_z_cached != lcp_size) { z_inactive.clear(); for (int i = 0; i < lcp_size; i++) { z_inactive.push_back(true); } } else { getThresholdInclusion((lb - z_cached).eval(), -SMALL, z_inactive); } qp_failed = !callFastQP(M, w, lb, z_inactive, nL+nP+nC, z); } int nnz; mxArray* mxM_sparse = eigenToMatlabSparse(M, nnz); mxArray* mxnnzJ = mxCreateDoubleScalar(static_cast<double>(nnz)); mxArray* mxn = mxCreateDoubleScalar(static_cast<double>(lcp_size)); mxArray* mxz = mxCreateDoubleMatrix(lcp_size, 1, mxREAL); mxArray *lhs[2]; mxArray *rhs[] = {mxn, mxnnzJ, mxz, mxlb, mxub, mxM_sparse, mxw}; Map<VectorXd> z_path(mxGetPr(mxz), lcp_size); z_path = VectorXd::Zero(lcp_size); //fall back to pathlcp if(qp_failed) { lcp_mex->mexFunction(2, lhs, 7, const_cast<const mxArray**>(rhs)); z = z_path; mxDestroyArray(lhs[0]); mxDestroyArray(lhs[1]); } mxDestroyArray(mxz); mxDestroyArray(mxn); mxDestroyArray(mxnnzJ); mxDestroyArray(mxub); mxDestroyArray(mxlb); mxDestroyArray(mxw); mxDestroyArray(mxM_sparse); VectorXd vn = Mvn * z + wvn; vector<size_t> impossible_contact_indices, impossible_limit_indices; getInclusionIndices(possible_contact, impossible_contact_indices, false); getInclusionIndices(possible_jointlimit, impossible_limit_indices, false); vector<bool> penetrating_joints, penetrating_contacts; getThresholdInclusion((phiL_check + h * JL_check * vn).eval(), 0.0, penetrating_joints); getThresholdInclusion((phiC_check + h * n_check * vn).eval(), 0.0, penetrating_contacts); const size_t num_penetrating_joints = getNumTrue(penetrating_joints); const size_t num_penetrating_contacts = getNumTrue(penetrating_contacts); const size_t penetrations = num_penetrating_joints + num_penetrating_contacts; //check nonpenetration assumptions if (penetrations > 0) { //revise joint limit active set for (size_t i = 0; i < impossible_limit_indices.size(); i++) { if (penetrating_joints[i]) { possible_jointlimit[impossible_limit_indices[i]] = true; } } //revise contact constraint active set for (size_t i = 0; i < impossible_contact_indices.size(); i++) { if (penetrating_contacts[i]) { possible_contact[impossible_contact_indices[i]] = true; } } //throw away our old solution and try again mxDestroyArray(plhs[0]); mxDestroyArray(plhs[1]); continue; } //our initial guess was correct. we're done break; } plhs[3] = mxCreateDoubleMatrix(1, possible_contact.size(), mxREAL); plhs[4] = mxCreateDoubleMatrix(1, possible_jointlimit.size(), mxREAL); Map<VectorXd> possible_contact_map(mxGetPrSafe(plhs[3]), possible_contact.size()); Map<VectorXd> possible_jointlimit_map(mxGetPrSafe(plhs[4]), possible_jointlimit.size()); for (size_t i = 0; i < possible_contact.size(); i++) { possible_contact_map[i] = static_cast<double>(possible_contact[i]); } for (size_t i = 0; i < possible_jointlimit.size(); i++) { possible_jointlimit_map[i] = static_cast<double>(possible_jointlimit[i]); } }