// -*- c++ -*- // This file is part of the Collective Variables module (Colvars). // The original version of Colvars and its updates are located at: // https://github.com/colvars/colvars // Please update all Colvars source files before making any changes. // If you wish to distribute your changes, please submit them to the // Colvars repository at GitHub. #include "colvarmodule.h" #include "colvarvalue.h" #include "colvar.h" #include "colvarcomp.h" colvar::cvc::cvc() : sup_coeff(1.0), sup_np(1), b_periodic(false), b_try_scalable(true) { init_cvc_requires(); } colvar::cvc::cvc(std::string const &conf) : sup_coeff(1.0), sup_np(1), b_periodic(false), b_try_scalable(true) { if (cvm::debug()) cvm::log("Initializing cvc base object.\n"); init_cvc_requires(); if (get_keyval(conf, "name", this->name, std::string(""), parse_silent)) { // Temporary description until child object is initialized description = "cvc " + name; } else { description = "uninitialized cvc"; } get_keyval(conf, "componentCoeff", sup_coeff, 1.0); get_keyval(conf, "componentExp", sup_np, 1); get_keyval(conf, "period", period, 0.0); get_keyval(conf, "wrapAround", wrap_center, 0.0); get_keyval_feature((colvarparse *)this, conf, "debugGradients", f_cvc_debug_gradient, false, parse_silent); { bool b_no_PBC = false; get_keyval(conf, "forceNoPBC", b_no_PBC, false); if (b_no_PBC) { disable(f_cvc_pbc_minimum_image); } else { enable(f_cvc_pbc_minimum_image); } // this does not use get_keyval_feature() only for backward compatibility } // Attempt scalable calculations when in parallel? (By default yes, if available) get_keyval(conf, "scalable", b_try_scalable, true); if (cvm::debug()) cvm::log("Done initializing cvc base object.\n"); } int colvar::cvc::init_total_force_params(std::string const &conf) { if (cvm::get_error()) return COLVARS_ERROR; if (get_keyval_feature(this, conf, "oneSiteSystemForce", f_cvc_one_site_total_force, is_enabled(f_cvc_one_site_total_force))) { cvm::log("Warning: keyword \"oneSiteSystemForce\" is deprecated: " "please use \"oneSiteTotalForce\" instead.\n"); } if (get_keyval_feature(this, conf, "oneSiteTotalForce", f_cvc_one_site_total_force, is_enabled(f_cvc_one_site_total_force))) { cvm::log("Computing total force on group 1 only"); } if (! is_enabled(f_cvc_one_site_total_force)) { // check whether any of the other atom groups is dummy std::vector::iterator agi = atom_groups.begin(); agi++; for ( ; agi != atom_groups.end(); agi++) { if ((*agi)->b_dummy) { provide(f_cvc_inv_gradient, false); provide(f_cvc_Jacobian, false); } } } return COLVARS_OK; } cvm::atom_group *colvar::cvc::parse_group(std::string const &conf, char const *group_key, bool optional) { cvm::atom_group *group = NULL; std::string group_conf; if (key_lookup(conf, group_key, &group_conf)) { group = new cvm::atom_group(group_key); if (b_try_scalable) { if (is_available(f_cvc_scalable_com) && is_enabled(f_cvc_com_based) && !is_enabled(f_cvc_debug_gradient)) { enable(f_cvc_scalable_com); enable(f_cvc_scalable); // The CVC makes the feature available; // the atom group will enable it unless it needs to compute a rotational fit group->provide(f_ag_scalable_com); } // TODO check for other types of parallelism here } if (group_conf.size() == 0) { cvm::error("Error: atom group \""+group->key+ "\" is set, but has no definition.\n", INPUT_ERROR); return group; } cvm::increase_depth(); if (group->parse(group_conf) == COLVARS_OK) { register_atom_group(group); } group->check_keywords(group_conf, group_key); if (cvm::get_error()) { cvm::error("Error parsing definition for atom group \""+ std::string(group_key)+"\"\n.", INPUT_ERROR); } cvm::decrease_depth(); } else { if (! optional) { cvm::error("Error: definition for atom group \""+ std::string(group_key)+"\" not found.\n"); } } return group; } int colvar::cvc::setup() { description = "cvc " + name; return COLVARS_OK; } colvar::cvc::~cvc() { free_children_deps(); remove_all_children(); for (size_t i = 0; i < atom_groups.size(); i++) { if (atom_groups[i] != NULL) delete atom_groups[i]; } } void colvar::cvc::read_data() { size_t ig; for (ig = 0; ig < atom_groups.size(); ig++) { cvm::atom_group &atoms = *(atom_groups[ig]); atoms.reset_atoms_data(); atoms.read_positions(); atoms.calc_required_properties(); // each atom group will take care of its own fitting_group, if defined } //// Don't try to get atom velocities, as no back-end currently implements it // if (tasks[task_output_velocity] && !tasks[task_fdiff_velocity]) { // for (i = 0; i < cvcs.size(); i++) { // for (ig = 0; ig < cvcs[i]->atom_groups.size(); ig++) { // cvcs[i]->atom_groups[ig]->read_velocities(); // } // } // } } void colvar::cvc::calc_force_invgrads() { cvm::error("Error: calculation of inverse gradients is not implemented " "for colvar components of type \""+function_type+"\".\n", COLVARS_NOT_IMPLEMENTED); } void colvar::cvc::calc_Jacobian_derivative() { cvm::error("Error: calculation of inverse gradients is not implemented " "for colvar components of type \""+function_type+"\".\n", COLVARS_NOT_IMPLEMENTED); } void colvar::cvc::calc_fit_gradients() { for (size_t ig = 0; ig < atom_groups.size(); ig++) { atom_groups[ig]->calc_fit_gradients(); } } void colvar::cvc::debug_gradients() { // this function should work for any scalar cvc: // the only difference will be the name of the atom group (here, "group") // NOTE: this assumes that groups for this cvc are non-overlapping, // since atom coordinates are modified only within the current group cvm::log("Debugging gradients for " + description); for (size_t ig = 0; ig < atom_groups.size(); ig++) { cvm::atom_group *group = atom_groups[ig]; if (group->b_dummy) continue; cvm::rotation const rot_0 = group->rot; cvm::rotation const rot_inv = group->rot.inverse(); cvm::real x_0 = x.real_value; if ((x.type() == colvarvalue::type_vector) && (x.size() == 1)) x_0 = x[0]; // cvm::log("gradients = "+cvm::to_str (gradients)+"\n"); cvm::atom_group *group_for_fit = group->fitting_group ? group->fitting_group : group; cvm::atom_pos fit_gradient_sum, gradient_sum; // print the values of the fit gradients if (group->b_rotate || group->b_center) { if (group->is_enabled(f_ag_fit_gradients)) { size_t j; // fit_gradients are in the simulation frame: we should print them in the rotated frame cvm::log("Fit gradients:\n"); for (j = 0; j < group_for_fit->fit_gradients.size(); j++) { cvm::log((group->fitting_group ? std::string("refPosGroup") : group->key) + "[" + cvm::to_str(j) + "] = " + (group->b_rotate ? cvm::to_str(rot_0.rotate(group_for_fit->fit_gradients[j])) : cvm::to_str(group_for_fit->fit_gradients[j]))); } } } // debug the gradients for (size_t ia = 0; ia < group->size(); ia++) { // tests are best conducted in the unrotated (simulation) frame cvm::rvector const atom_grad = (group->b_rotate ? rot_inv.rotate((*group)[ia].grad) : (*group)[ia].grad); gradient_sum += atom_grad; for (size_t id = 0; id < 3; id++) { // (re)read original positions group->read_positions(); // change one coordinate (*group)[ia].pos[id] += cvm::debug_gradients_step_size; group->calc_required_properties(); calc_value(); cvm::real x_1 = x.real_value; if ((x.type() == colvarvalue::type_vector) && (x.size() == 1)) x_1 = x[0]; cvm::log("Atom "+cvm::to_str(ia)+", component "+cvm::to_str(id)+":\n"); cvm::log("dx(actual) = "+cvm::to_str(x_1 - x_0, 21, 14)+"\n"); cvm::real const dx_pred = (group->fit_gradients.size()) ? (cvm::debug_gradients_step_size * (atom_grad[id] + group->fit_gradients[ia][id])) : (cvm::debug_gradients_step_size * atom_grad[id]); cvm::log("dx(interp) = "+cvm::to_str(dx_pred, 21, 14)+"\n"); cvm::log("|dx(actual) - dx(interp)|/|dx(actual)| = "+ cvm::to_str(std::fabs(x_1 - x_0 - dx_pred) / std::fabs(x_1 - x_0), 12, 5)+"\n"); } } if ((group->is_enabled(f_ag_fit_gradients)) && (group->fitting_group != NULL)) { cvm::atom_group *ref_group = group->fitting_group; group->read_positions(); group->calc_required_properties(); for (size_t ia = 0; ia < ref_group->size(); ia++) { // fit gradients are in the unrotated (simulation) frame cvm::rvector const atom_grad = ref_group->fit_gradients[ia]; fit_gradient_sum += atom_grad; for (size_t id = 0; id < 3; id++) { // (re)read original positions group->read_positions(); ref_group->read_positions(); // change one coordinate (*ref_group)[ia].pos[id] += cvm::debug_gradients_step_size; group->calc_required_properties(); calc_value(); cvm::real const x_1 = x.real_value; cvm::log("refPosGroup atom "+cvm::to_str(ia)+", component "+cvm::to_str (id)+":\n"); cvm::log("dx(actual) = "+cvm::to_str (x_1 - x_0, 21, 14)+"\n"); cvm::real const dx_pred = cvm::debug_gradients_step_size * atom_grad[id]; cvm::log("dx(interp) = "+cvm::to_str (dx_pred, 21, 14)+"\n"); cvm::log ("|dx(actual) - dx(interp)|/|dx(actual)| = "+ cvm::to_str(std::fabs (x_1 - x_0 - dx_pred) / std::fabs (x_1 - x_0), 12, 5)+ ".\n"); } } } cvm::log("Gradient sum: " + cvm::to_str(gradient_sum) + " Fit gradient sum: " + cvm::to_str(fit_gradient_sum) + " Total " + cvm::to_str(gradient_sum + fit_gradient_sum)); } return; } cvm::real colvar::cvc::dist2(colvarvalue const &x1, colvarvalue const &x2) const { return x1.dist2(x2); } colvarvalue colvar::cvc::dist2_lgrad(colvarvalue const &x1, colvarvalue const &x2) const { return x1.dist2_grad(x2); } colvarvalue colvar::cvc::dist2_rgrad(colvarvalue const &x1, colvarvalue const &x2) const { return x2.dist2_grad(x1); } void colvar::cvc::wrap(colvarvalue &x) const { return; } // Static members std::vector colvar::cvc::cvc_features;