shared_table_data_set(const data_set<Ty,Tx>& rhs) { data_vec.resize(rhs.size()); for(int i=0;i<data_vec.size();++i) { data_vec[i](rhs.get_data(i)); } }
tree::tree(data_set& train_set, int max_leafs, int max_depth) : max_leafs(max_leafs) { std::set<int> features; for (size_t i = 0; i < train_set[0].features.size(); i++) { features.insert(i); } leafs = 1; int depth = 0; root = new node(0); root->data_begin = train_set.begin(); root->data_end = train_set.end(); root->calc_avg(); root->node_mse = calc_mse(root->data_begin, root->data_end, root->output_value, root->size); std::vector<node*> layer; layer.push_back(root); layers.push_back(layer); while (leafs < max_leafs && depth < max_depth && !features.empty()) { float min_error = INF; int best_feature = -1; make_layer(depth); for (std::set<int>::iterator cur_split_feature = features.begin(); cur_split_feature != features.end(); cur_split_feature++) //choose best split feature at current depth { float cur_error = 0; for (size_t i = 0; i < layers[depth].size(); i++) { cur_error += layers[depth][i]->split(*cur_split_feature); } if (cur_error < min_error) { min_error = cur_error; best_feature = *cur_split_feature; } } for (size_t i = 0; i < layers[depth].size(); i++) { layers[depth][i]->split(best_feature); } feature_id_at_depth.push_back(best_feature); features.erase(best_feature); depth++; //std::cout << "level " << depth << " created. training error: " << min_error << " best feat: " << best_feature << " split_val: " //<< root->split_value << std::endl; } for (size_t i = 0; i < layers.back().size(); i++) { layers.back()[i]->is_leaf = true; } //std::cout << "leafs before pruning: " << leafs << std::endl; //prune(root); //std::cout << "new tree! leafs after pruning: " << leafs << std::endl; while (layers.back().empty()) { layers.pop_back(); } }
float tree::calculate_error(data_set& test_set) { float error = 0; for (data_set::iterator cur_test = test_set.begin(); cur_test != test_set.end(); cur_test++) { float ans = calculate_anwser(*cur_test); error += ((ans - cur_test->anwser) * (ans - cur_test->anwser)); } error /= (1.0 * test_set.size()); return error; }