#include #include using namespace torch; using namespace torch::nn; using Catch::StartsWith; struct AGIUnit : nn::Module { variable_list forward(variable_list) { return {}; } }; namespace test { struct AGIUnit : nn::Module { variable_list forward(variable_list) { return {}; } }; struct AGIUnit2 : nn::Module { AGIUnit2() : nn::Module("Foo") {} variable_list forward(variable_list) { return {}; } }; } // namespace test bool pointer_equal(Tensor first, Tensor second) { return first.data() == second.data(); } TEST_CASE("module/training-mode") { auto model = Linear(3, 4).build(); REQUIRE(model->is_training()); SECTION("Enable eval mode") { model->eval(); REQUIRE(!model->is_training()); } SECTION("Enable train mode") { model->train(); REQUIRE(model->is_training()); } } TEST_CASE("module/zero-grad") { auto model = Linear(3, 4).build(); auto weight = Var(at::ones(at::CPU(at::kFloat), {8, 3})); auto loss = model->forward({weight}).front().sum(); loss.backward(); for (auto& parameter : model->parameters()) { Variable grad = parameter.second.grad(); REQUIRE(grad.defined()); REQUIRE(grad.sum().toCFloat() != 0); } model->zero_grad(); for (auto& parameter : model->parameters()) { Variable grad = parameter.second.grad(); REQUIRE(grad.defined()); REQUIRE(grad.sum().toCFloat() == 0); } } TEST_CASE("module/name") { // CHECK instead of REQUIRE because demangling may fail. AGIUnit agi; // Call it twice just to make sure there are no bugs in the lazy // initialization semantics. CHECK(agi.name() == "AGIUnit"); CHECK(agi.name() == "AGIUnit"); SECTION("correctly demangled") { CHECK(test::AGIUnit().name() == "test::AGIUnit"); CHECK(test::AGIUnit2().name() == "Foo"); } } TEST_CASE("module/conversions", "[cuda]") { auto model = LSTM(128, 64).layers(3).dropout(0.2).build(); SECTION("starts as float on CPU") { for (auto& parameter : model->parameters()) { REQUIRE(parameter.second.type().backend() == at::kCPU); REQUIRE(parameter.second.type().scalarType() == at::kFloat); } } SECTION("to(CUDA)") { model->cuda(); for (auto& parameter : model->parameters()) { REQUIRE(parameter.second.type().backend() == at::kCUDA); } } SECTION("to(CPU)") { model->to(at::kCPU); for (auto& parameter : model->parameters()) { REQUIRE(parameter.second.type().backend() == at::kCPU); } } SECTION("to(Int)") { model->to(at::kInt); for (auto& parameter : model->parameters()) { REQUIRE(parameter.second.type().scalarType() == at::kInt); } } SECTION("to(Double)") { model->to(at::kDouble); for (auto& parameter : model->parameters()) { REQUIRE(parameter.second.type().scalarType() == at::kDouble); } } SECTION("to(CUDA(Float))") { model->to(at::CUDA(at::kFloat)); for (auto& parameter : model->parameters()) { REQUIRE(parameter.second.type().backend() == at::kCUDA); REQUIRE(parameter.second.type().scalarType() == at::kFloat); } } } TEST_CASE("module/clone") { SECTION( "a module that does not override clone() throws when clone() is called") { struct UnCloneable : Module { variable_list forward(variable_list) override { return {}; } }; UnCloneable module; REQUIRE_THROWS_WITH( module.clone(), StartsWith("clone() has not been implemented")); } SECTION( "a module that overrides clone() does not throw when clone() is called ") { struct Cloneable : Module { variable_list forward(variable_list) override { return {}; } std::shared_ptr clone() const override { return nullptr; } }; Cloneable module; REQUIRE_NOTHROW(module.clone()); } SECTION("Cloning creates distinct parameters") { struct TestModel : public CloneableModule { TestModel() { register_module("l1", &TestModel::l1, Linear(10, 3).build()); register_module("l2", &TestModel::l2, Linear(3, 5).build()); register_module("l3", &TestModel::l3, Linear(5, 100).build()); } void reset() override {} variable_list forward(variable_list input) override { return input; } std::shared_ptr l1, l2, l3; }; auto model = TestModel().build(); auto model2 = model->clone(); auto m1param = model->parameters(); auto m2param = model2->parameters(); for (auto& param : m1param) { REQUIRE(!pointer_equal(param.second, m2param[param.first])); REQUIRE(param.second.allclose(m2param[param.first])); param.second.data().mul_(2); } for (auto& param : m1param) { REQUIRE(!param.second.allclose(m2param[param.first])); } } SECTION("Cloning preserves external references") { struct TestModel : public CloneableModule { void reset() { register_parameter( "weight", &TestModel::weight, at::ones(at::CPU(at::kFloat), {4, 4})); } variable_list forward(variable_list input) override { return input; } Variable weight; }; auto model = TestModel().build(); REQUIRE(pointer_equal(model->weight, model->param("weight"))); auto model2 = std::dynamic_pointer_cast( std::shared_ptr(model->clone())); REQUIRE(!pointer_equal(model2->weight, model->weight)); REQUIRE(pointer_equal(model2->weight, model2->param("weight"))); REQUIRE(!pointer_equal(model2->weight, model->param("weight"))); } } TEST_CASE("module/parameters") { struct TestModule : Module { TestModule() { register_parameter( "a", &TestModule::a, at::zeros(at::CPU(at::kFloat), {2, 2})); register_parameter( "b", &TestModule::b, at::ones(at::CPU(at::kFloat), {2, 2})); register_parameter( "c", &TestModule::c, at::ones(at::CPU(at::kFloat), {2, 2}) * 2); } variable_list forward(variable_list) override { return {}; } Variable a, b, c; }; TestModule module; SECTION("has correct number of parameters") { REQUIRE(module.parameters().size() == 3); } SECTION("contains parameters with the correct name") { auto parameters = module.parameters(); REQUIRE(parameters.count("a")); REQUIRE(parameters.count("b")); REQUIRE(parameters.count("c")); } }