Refactor grid classes and add summary of tasks at the end
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@@ -18,234 +18,16 @@ namespace platform {
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explicit GridExperiment(struct ConfigGrid& config);
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~GridExperiment() = default;
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json loadResults();
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void go(struct ConfigMPI& config_mpi);
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static inline std::string NO_CONTINUE() { return "NO_CONTINUE"; }
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private:
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void save(json& results);
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json initializeResults();
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json build_tasks();
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};
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/* *************************************************************************************************************
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//
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// MPI Experiment Functions
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//
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************************************************************************************************************* */
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class MPI_EXPERIMENT :public MPI_Base {
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public:
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static json producer(std::vector<std::string>& names, json& tasks, struct ConfigMPI& config_mpi, MPI_Datatype& MPI_Result)
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{
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Task_Result result;
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json results;
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int num_tasks = tasks.size();
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//
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// 2a.1 Producer will loop to send all the tasks to the consumers and receive the results
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//
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for (int i = 0; i < num_tasks; ++i) {
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MPI_Status status;
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MPI_Recv(&result, 1, MPI_Result, MPI_ANY_SOURCE, MPI_ANY_TAG, MPI_COMM_WORLD, &status);
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if (status.MPI_TAG == TAG_RESULT) {
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//Store result
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store_result(names, result, results);
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}
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MPI_Send(&i, 1, MPI_INT, status.MPI_SOURCE, TAG_TASK, MPI_COMM_WORLD);
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}
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//
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// 2a.2 Producer will send the end message to all the consumers
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//
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for (int i = 0; i < config_mpi.n_procs - 1; ++i) {
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MPI_Status status;
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MPI_Recv(&result, 1, MPI_Result, MPI_ANY_SOURCE, MPI_ANY_TAG, MPI_COMM_WORLD, &status);
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if (status.MPI_TAG == TAG_RESULT) {
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//Store result
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store_result(names, result, results);
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}
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MPI_Send(&i, 1, MPI_INT, status.MPI_SOURCE, TAG_END, MPI_COMM_WORLD);
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}
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return results;
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}
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static void consumer(Datasets& datasets, json& tasks, struct ConfigGrid& config, struct ConfigMPI& config_mpi, MPI_Datatype& MPI_Result)
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{
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Task_Result result;
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//
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// 2b.1 Consumers announce to the producer that they are ready to receive a task
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//
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MPI_Send(&result, 1, MPI_Result, config_mpi.manager, TAG_QUERY, MPI_COMM_WORLD);
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int task;
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while (true) {
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MPI_Status status;
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//
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// 2b.2 Consumers receive the task from the producer and process it
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//
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MPI_Recv(&task, 1, MPI_INT, config_mpi.manager, MPI_ANY_TAG, MPI_COMM_WORLD, &status);
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if (status.MPI_TAG == TAG_END) {
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break;
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}
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consumer_go(config, config_mpi, tasks, task, datasets, &result);
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//
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// 2b.3 Consumers send the result to the producer
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//
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MPI_Send(&result, 1, MPI_Result, config_mpi.manager, TAG_RESULT, MPI_COMM_WORLD);
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}
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}
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static void select_best_results_folds(json& results, json& all_results, std::string& model)
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{
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Timer timer;
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auto grid = GridData(Paths::grid_input(model));
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//
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// Select the best result of the computed outer folds
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//
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for (const auto& result : all_results.items()) {
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// each result has the results of all the outer folds as each one were a different task
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double best_score = 0.0;
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json best;
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for (const auto& result_fold : result.value()) {
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double score = result_fold["score"].get<double>();
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if (score > best_score) {
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best_score = score;
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best = result_fold;
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}
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}
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auto dataset = result.key();
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auto combinations = grid.getGrid(dataset);
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json json_best = {
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{ "score", best_score },
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{ "hyperparameters", combinations[best["combination"].get<int>()] },
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{ "date", get_date() + " " + get_time() },
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{ "grid", grid.getInputGrid(dataset) },
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{ "duration", timer.translate2String(best["time"].get<double>()) }
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};
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results[dataset] = json_best;
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}
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}
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static json store_result(std::vector<std::string>& names, Task_Result& result, json& results)
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{
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json json_result = {
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{ "score", result.score },
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{ "combination", result.idx_combination },
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{ "fold", result.n_fold },
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{ "time", result.time },
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{ "dataset", result.idx_dataset }
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};
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auto name = names[result.idx_dataset];
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if (!results.contains(name)) {
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results[name] = json::array();
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}
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results[name].push_back(json_result);
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return results;
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}
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static void consumer_go(struct ConfigGrid& config, struct ConfigMPI& config_mpi, json& tasks, int n_task, Datasets& datasets, Task_Result* result)
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{
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//
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// initialize
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//
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Timer timer;
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timer.start();
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json task = tasks[n_task];
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auto model = config.model;
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auto grid = GridData(Paths::grid_input(model));
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auto dataset_name = task["dataset"].get<std::string>();
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auto idx_dataset = task["idx_dataset"].get<int>();
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auto seed = task["seed"].get<int>();
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auto n_fold = task["fold"].get<int>();
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bool stratified = config.stratified;
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bayesnet::Smoothing_t smooth;
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if (config.smooth_strategy == "ORIGINAL")
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smooth = bayesnet::Smoothing_t::ORIGINAL;
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else if (config.smooth_strategy == "LAPLACE")
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smooth = bayesnet::Smoothing_t::LAPLACE;
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else if (config.smooth_strategy == "CESTNIK")
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smooth = bayesnet::Smoothing_t::CESTNIK;
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//
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// Generate the hyperparameters combinations
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//
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auto& dataset = datasets.getDataset(dataset_name);
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auto combinations = grid.getGrid(dataset_name);
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dataset.load();
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auto [X, y] = dataset.getTensors();
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auto features = dataset.getFeatures();
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auto className = dataset.getClassName();
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//
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// Start working on task
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//
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folding::Fold* fold;
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if (stratified)
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fold = new folding::StratifiedKFold(config.n_folds, y, seed);
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else
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fold = new folding::KFold(config.n_folds, y.size(0), seed);
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auto [train, test] = fold->getFold(n_fold);
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auto [X_train, X_test, y_train, y_test] = dataset.getTrainTestTensors(train, test);
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auto states = dataset.getStates(); // Get the states of the features Once they are discretized
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float best_fold_score = 0.0;
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int best_idx_combination = -1;
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json best_fold_hyper;
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for (int idx_combination = 0; idx_combination < combinations.size(); ++idx_combination) {
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auto hyperparam_line = combinations[idx_combination];
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auto hyperparameters = platform::HyperParameters(datasets.getNames(), hyperparam_line);
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folding::Fold* nested_fold;
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if (config.stratified)
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nested_fold = new folding::StratifiedKFold(config.nested, y_train, seed);
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else
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nested_fold = new folding::KFold(config.nested, y_train.size(0), seed);
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double score = 0.0;
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for (int n_nested_fold = 0; n_nested_fold < config.nested; n_nested_fold++) {
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//
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// Nested level fold
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//
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auto [train_nested, test_nested] = nested_fold->getFold(n_nested_fold);
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auto train_nested_t = torch::tensor(train_nested);
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auto test_nested_t = torch::tensor(test_nested);
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auto X_nested_train = X_train.index({ "...", train_nested_t });
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auto y_nested_train = y_train.index({ train_nested_t });
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auto X_nested_test = X_train.index({ "...", test_nested_t });
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auto y_nested_test = y_train.index({ test_nested_t });
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//
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// Build Classifier with selected hyperparameters
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//
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auto clf = Models::instance()->create(config.model);
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auto valid = clf->getValidHyperparameters();
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hyperparameters.check(valid, dataset_name);
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clf->setHyperparameters(hyperparameters.get(dataset_name));
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//
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// Train model
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//
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clf->fit(X_nested_train, y_nested_train, features, className, states, smooth);
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//
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// Test model
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//
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score += clf->score(X_nested_test, y_nested_test);
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}
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delete nested_fold;
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score /= config.nested;
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if (score > best_fold_score) {
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best_fold_score = score;
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best_idx_combination = idx_combination;
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best_fold_hyper = hyperparam_line;
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}
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}
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delete fold;
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//
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// Build Classifier with the best hyperparameters to obtain the best score
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//
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auto hyperparameters = platform::HyperParameters(datasets.getNames(), best_fold_hyper);
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auto clf = Models::instance()->create(config.model);
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auto valid = clf->getValidHyperparameters();
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hyperparameters.check(valid, dataset_name);
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clf->setHyperparameters(best_fold_hyper);
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clf->fit(X_train, y_train, features, className, states, smooth);
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best_fold_score = clf->score(X_test, y_test);
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//
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// Return the result
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//
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result->idx_dataset = task["idx_dataset"].get<int>();
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result->idx_combination = best_idx_combination;
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result->score = best_fold_score;
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result->n_fold = n_fold;
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result->time = timer.getDuration();
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//
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// Update progress bar
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//
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std::cout << get_color_rank(config_mpi.rank) << std::flush;
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}
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std::vector<std::string> filterDatasets(Datasets& datasets) const;
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json producer(std::vector<std::string>& names, json& tasks, struct ConfigMPI& config_mpi, MPI_Datatype& MPI_Result);
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void consumer(Datasets& datasets, json& tasks, struct ConfigGrid& config, struct ConfigMPI& config_mpi, MPI_Datatype& MPI_Result);
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void select_best_results_folds(json& results, json& all_results, std::string& model);
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json store_result(std::vector<std::string>& names, Task_Result& result, json& results);
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void consumer_go(struct ConfigGrid& config, struct ConfigMPI& config_mpi, json& tasks, int n_task, Datasets& datasets, Task_Result* result);
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};
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} /* namespace platform */
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#endif
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