// Copyright (C) 2011 Davis E. King (davis@dlib.net) // License: Boost Software License See LICENSE.txt for the full license. #include "tester.h" #include #include #include #include "create_iris_datafile.h" #include #include namespace { using namespace test; using namespace dlib; using namespace std; dlib::logger dlog("test.data_io"); class test_data_io : public tester { /*! WHAT THIS OBJECT REPRESENTS This object represents a unit test. When it is constructed it adds itself into the testing framework. !*/ public: test_data_io ( ) : tester ( "test_data_io", // the command line argument name for this test "Run tests on the data_io stuff.", // the command line argument description 0 // the number of command line arguments for this test ) { } template void run_test() { print_spinner(); typedef typename sample_type::value_type::second_type scalar_type; std::vector samples; std::vector labels; load_libsvm_formatted_data("iris.scale",samples, labels); save_libsvm_formatted_data("iris.scale2", samples, labels); DLIB_TEST(samples.size() == 150); DLIB_TEST(labels.size() == 150); DLIB_TEST(max_index_plus_one(samples) == 5); fix_nonzero_indexing(samples); DLIB_TEST(max_index_plus_one(samples) == 4); load_libsvm_formatted_data("iris.scale2",samples, labels); DLIB_TEST(samples.size() == 150); DLIB_TEST(labels.size() == 150); DLIB_TEST(max_index_plus_one(samples) == 5); fix_nonzero_indexing(samples); DLIB_TEST(max_index_plus_one(samples) == 4); one_vs_one_trainer,scalar_type> trainer; typedef sparse_linear_kernel kernel_type; trainer.set_trainer(krr_trainer()); randomize_samples(samples, labels); matrix cv = cross_validate_multiclass_trainer(trainer, samples, labels, 4); dlog << LINFO << "confusion matrix: \n" << cv; const scalar_type cv_accuracy = sum(diag(cv))/sum(cv); dlog << LINFO << "cv accuracy: " << cv_accuracy; DLIB_TEST(cv_accuracy > 0.97); { print_spinner(); typedef matrix dsample_type; std::vector dsamples = sparse_to_dense(samples); DLIB_TEST(dsamples.size() == 150); DLIB_TEST(dsamples[0].size() == 4); DLIB_TEST(max_index_plus_one(dsamples) == 4); one_vs_one_trainer,scalar_type> trainer; typedef linear_kernel kernel_type; trainer.set_trainer(rr_trainer()); cv = cross_validate_multiclass_trainer(trainer, dsamples, labels, 4); dlog << LINFO << "dense confusion matrix: \n" << cv; const scalar_type cv_accuracy = sum(diag(cv))/sum(cv); dlog << LINFO << "dense cv accuracy: " << cv_accuracy; DLIB_TEST(cv_accuracy > 0.97); } } void test_sparse_to_dense() { { std::map temp; matrix m, m2; m = sparse_to_dense(m); DLIB_TEST(m.size() == 0); m.set_size(2,1); m = 1, 2; m2 = sparse_to_dense(m); DLIB_TEST(m == m2); m2 = sparse_to_dense(m,1); DLIB_TEST(m2.size() == 1); DLIB_TEST(m2(0,0) == 1); m2 = sparse_to_dense(m,0); DLIB_TEST(m2.size() == 0); temp[3] = 2; temp[5] = 4; m2 = sparse_to_dense(temp); m.set_size(6); m = 0,0,0,2,0,4; DLIB_TEST(m2 == m); m2 = sparse_to_dense(temp, 5); m.set_size(5); m = 0,0,0,2,0; DLIB_TEST(m2 == m); m2 = sparse_to_dense(temp, 7); m.set_size(7); m = 0,0,0,2,0,4,0; DLIB_TEST(m2 == m); std::vector > > vects; std::vector > v; v.push_back(make_pair(5,2)); v.push_back(make_pair(3,1)); v.push_back(make_pair(5,2)); v.push_back(make_pair(3,1)); v = make_sparse_vector(v); vects.push_back(v); vects.push_back(v); vects.push_back(v); vects.push_back(v); DLIB_TEST(max_index_plus_one(v) == 6); m2 = sparse_to_dense(v); m.set_size(6); m = 0,0,0,2,0,4; DLIB_TEST_MSG(m2 == m, m2 << "\n\n" << m ); m2 = sparse_to_dense(v,7); m.set_size(7); m = 0,0,0,2,0,4,0; DLIB_TEST(m2 == m); m2 = sparse_to_dense(v,5); m.set_size(5); m = 0,0,0,2,0; DLIB_TEST(m2 == m); v.clear(); m2 = sparse_to_dense(v); DLIB_TEST(m2.size() == 0); std::vector > mvects = sparse_to_dense(vects); DLIB_TEST(mvects.size() == 4); m.set_size(6); m = 0,0,0,2,0,4; DLIB_TEST(mvects[0] == m); DLIB_TEST(mvects[1] == m); DLIB_TEST(mvects[2] == m); DLIB_TEST(mvects[3] == m); mvects = sparse_to_dense(vects, 7); DLIB_TEST(mvects.size() == 4); m.set_size(7); m = 0,0,0,2,0,4,0; DLIB_TEST(mvects[0] == m); DLIB_TEST(mvects[1] == m); DLIB_TEST(mvects[2] == m); DLIB_TEST(mvects[3] == m); mvects = sparse_to_dense(vects, 5); DLIB_TEST(mvects.size() == 4); m.set_size(5); m = 0,0,0,2,0; DLIB_TEST(mvects[0] == m); DLIB_TEST(mvects[1] == m); DLIB_TEST(mvects[2] == m); DLIB_TEST(mvects[3] == m); } } void perform_test ( ) { print_spinner(); create_iris_datafile(); test_sparse_to_dense(); run_test >(); run_test >(); run_test > >(); run_test > >(); } }; test_data_io a; }