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moduledict.cpp
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moduledict.cpp
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#include <gtest/gtest.h>
#include <torch/torch.h>
#include <algorithm>
#include <memory>
#include <vector>
#include <test/cpp/api/support.h>
using namespace torch::nn;
using namespace torch::test;
struct ModuleDictTest : torch::test::SeedingFixture {};
TEST_F(ModuleDictTest, ConstructsFromList) {
struct M : Module {
explicit M(int value_) : value(value_) {}
int value;
};
std::vector<std::pair<std::string, std::shared_ptr<Module>>> list = {
{"module_1", std::make_shared<M>(1)},
{"module_2", std::make_shared<M>(2)},
{"module_3", std::make_shared<M>(3)}};
ModuleDict dict(list);
ASSERT_EQ(dict->size(), 3);
}
TEST_F(ModuleDictTest, ConstructsFromordereddict) {
struct M : Module {
explicit M(int value_) : value(value_) {}
int value;
};
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"module_1", std::make_shared<M>(1)},
{"module_2", std::make_shared<M>(2)},
{"module_3", std::make_shared<M>(3)},
};
ModuleDict dict(ordereddict);
ASSERT_EQ(dict->size(), 3);
}
TEST_F(ModuleDictTest, UpdatePopClearContains) {
struct M : Module {
explicit M(int value_) : value(value_) {}
int value;
};
ModuleDict dict;
ASSERT_TRUE(dict->empty());
// Update by List
std::vector<std::pair<std::string, std::shared_ptr<Module>>> list1 = {
{"module_1", std::make_shared<M>(1)}};
dict->update(list1);
ASSERT_EQ(dict->size(), 1);
ASSERT_TRUE(dict->contains("module_1"));
// Update by OrderedDict
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"module_2", std::make_shared<M>(2)}};
dict->update(ordereddict);
ASSERT_EQ(dict->size(), 2);
ASSERT_TRUE(dict->contains("module_2"));
// Update by another ModuleDict
std::vector<std::pair<std::string, std::shared_ptr<Module>>> list2 = {
{"module_3", std::make_shared<M>(3)}};
ModuleDict updatedict(list2);
dict->update(*updatedict);
ASSERT_EQ(dict->size(), 3);
ASSERT_TRUE(dict->contains("module_3"));
// Pop
dict->pop("module_1");
ASSERT_EQ(dict->size(), 2);
// Pop unexist
ASSERT_THROWS_WITH(dict->pop("module_4"), " 'module_4' is not defined");
// Clear
dict->clear();
ASSERT_EQ(dict->size(), 0);
}
TEST_F(ModuleDictTest, UpdateExist) {
struct M : Module {
explicit M(int value_) : value(value_) {}
int value;
};
std::vector<std::pair<std::string, std::shared_ptr<Module>>> list1 = {
{"module_1", std::make_shared<M>(1)},
{"module_2", std::make_shared<M>(2)}};
ModuleDict dict(list1);
ASSERT_EQ(dict->at<M>("module_2").value, 2);
// Update by list
std::vector<std::pair<std::string, std::shared_ptr<Module>>> list2 = {
{"module_2", std::make_shared<M>(0)},
{"module_3", std::make_shared<M>(3)}};
dict->update(list2);
ASSERT_EQ(dict->size(), 3);
ASSERT_EQ(dict->at<M>("module_2").value, 0);
// Update by ordereddict
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"module_3", std::make_shared<M>(0)},
{"module_4", std::make_shared<M>(4)}};
dict->update(ordereddict);
ASSERT_EQ(dict->size(), 4);
ASSERT_EQ(dict->at<M>("module_3").value, 0);
// Update by ModuleDict
std::vector<std::pair<std::string, std::shared_ptr<Module>>> list3 = {
{"module_4", std::make_shared<M>(0)},
{"module_1", std::make_shared<M>(0)}};
ModuleDict dict2(list3);
dict->update(*dict2);
ASSERT_EQ(dict->size(), 4);
ASSERT_EQ(dict->at<M>("module_1").value, 0);
ASSERT_EQ(dict->at<M>("module_4").value, 0);
}
TEST_F(ModuleDictTest, Keys) {
struct M : Module {
explicit M(int value_) : value(value_) {}
int value;
};
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"linear", Linear(10, 3).ptr()},
{"conv", Conv2d(1, 2, 3).ptr()},
{"dropout", Dropout(0.5).ptr()},
};
ModuleDict dict(ordereddict);
const auto& keys = dict->keys();
std::vector<std::string> expected{"linear", "conv", "dropout"};
ASSERT_EQ(keys, expected);
ASSERT_THROWS_WITH(dict["batch"], " 'batch' is not defined");
ASSERT_TRUE(dict["linear"]->as<Linear>());
ASSERT_TRUE(dict["conv"]->as<Conv2d>());
ASSERT_TRUE(dict["dropout"]->as<Dropout>());
}
TEST_F(ModuleDictTest, Values) {
struct M : Module {
explicit M(int value_) : value(value_) {}
int value;
};
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"module_1", std::make_shared<M>(1)},
{"module_2", std::make_shared<M>(2)},
};
ModuleDict dict(ordereddict);
const auto& values = dict->values();
const auto& expected = ordereddict.values();
ASSERT_EQ(values, expected);
ASSERT_TRUE(std::equal(
dict->begin(),
dict->end(),
ordereddict.begin(),
[](const auto& lhs, const auto& rhs) {
return lhs.value().get() == rhs.value().get();
}));
}
TEST_F(ModuleDictTest, SanityCheckForHoldingStandardModules) {
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"linear", Linear(10, 3).ptr()},
{"conv", Conv2d(1, 2, 3).ptr()},
{"dropout", Dropout(0.5).ptr()},
{"batch", BatchNorm2d(5).ptr()},
{"embedding", Embedding(4, 10).ptr()},
{"lstm", LSTM(4, 5).ptr()}};
ModuleDict dict(ordereddict);
}
TEST_F(ModuleDictTest, HasReferenceSemantics) {
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"linear1", Linear(2, 3).ptr()},
{"linear2", Linear(3, 4).ptr()},
{"linear3", Linear(4, 5).ptr()},
};
ModuleDict first(ordereddict);
ModuleDict second(ordereddict);
ASSERT_EQ(first->size(), second->size());
ASSERT_TRUE(std::equal(
first->begin(),
first->end(),
second->begin(),
[](const auto& lhs, const auto& rhs) {
return lhs.value().get() == rhs.value().get();
}));
}
void iscloneable_helper(torch::Device device) {
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"linear", Linear(2, 3).ptr()},
{"relu", Functional(torch::relu).ptr()},
{"batch", BatchNorm1d(3).ptr()},
};
ModuleDict dict(ordereddict);
dict->to(device);
ModuleDict clone =
std::dynamic_pointer_cast<ModuleDictImpl>(dict->clone(device));
ASSERT_EQ(dict->size(), clone->size());
for (auto it = dict->begin(), it_c = clone->begin(); it != dict->end();
++it, ++it_c) {
// The key should be same
ASSERT_EQ(it->key(), it_c->key());
// The modules should be the same kind (type).
ASSERT_EQ(it->value()->name(), it_c->value()->name());
// But not pointer-equal (distinct objects).
ASSERT_NE(it->value(), it_c->value());
}
// Verify that the clone is deep, i.e. parameters of modules are cloned too.
torch::NoGradGuard no_grad;
auto params1 = dict->named_parameters();
auto params2 = clone->named_parameters();
ASSERT_EQ(params1.size(), params2.size());
for (auto& param : params1) {
ASSERT_FALSE(pointer_equal(param.value(), params2[param.key()]));
ASSERT_EQ(param->device(), params2[param.key()].device());
ASSERT_TRUE(param->allclose(params2[param.key()]));
param->add_(2);
}
for (auto& param : params1) {
ASSERT_FALSE(param->allclose(params2[param.key()]));
}
}
TEST_F(ModuleDictTest, IsCloneable) {
iscloneable_helper(torch::kCPU);
}
TEST_F(ModuleDictTest, IsCloneable_CUDA) {
iscloneable_helper({torch::kCUDA, 0});
}
TEST_F(ModuleDictTest, RegistersElementsAsSubmodules) {
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict1 = {
{"linear", Linear(10, 3).ptr()},
{"conv", Conv2d(1, 2, 3).ptr()},
{"test", Dropout(0.5).ptr()},
};
ModuleDict dict(ordereddict1);
auto modules = dict->children();
ASSERT_TRUE(modules[0]->as<Linear>());
ASSERT_TRUE(modules[1]->as<Conv2d>());
ASSERT_TRUE(modules[2]->as<Dropout>());
// Update Existing
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict2 = {
{"lstm", LSTM(4, 5).ptr()}, {"test", BatchNorm2d(5).ptr()}};
dict->update(ordereddict2);
modules = dict->children();
ASSERT_TRUE(modules[0]->as<Linear>());
ASSERT_TRUE(modules[1]->as<Conv2d>());
// Keep Order
ASSERT_TRUE(modules[2]->as<BatchNorm2d>());
ASSERT_TRUE(modules[3]->as<LSTM>());
}
TEST_F(ModuleDictTest, CloneToDevice_CUDA) {
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"linear", Linear(2, 3).ptr()},
{"relu", Functional(torch::relu).ptr()},
{"batch", BatchNorm1d(3).ptr()},
};
ModuleDict dict(ordereddict);
torch::Device device(torch::kCUDA, 0);
ModuleDict clone =
std::dynamic_pointer_cast<ModuleDictImpl>(dict->clone(device));
for (const auto& p : clone->parameters()) {
ASSERT_EQ(p.device(), device);
}
for (const auto& b : clone->buffers()) {
ASSERT_EQ(b.device(), device);
}
}
TEST_F(ModuleDictTest, PrettyPrintModuleDict) {
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"linear", Linear(10, 3).ptr()},
{"conv", Conv2d(1, 2, 3).ptr()},
{"dropout", Dropout(0.5).ptr()},
{"batch", BatchNorm2d(5).ptr()},
{"embedding", Embedding(4, 10).ptr()},
{"lstm", LSTM(4, 5).ptr()}};
ModuleDict dict(ordereddict);
ASSERT_EQ(
c10::str(dict),
"torch::nn::ModuleDict(\n"
" (linear): torch::nn::Linear(in_features=10, out_features=3, bias=true)\n"
" (conv): torch::nn::Conv2d(1, 2, kernel_size=[3, 3], stride=[1, 1])\n"
" (dropout): torch::nn::Dropout(p=0.5, inplace=false)\n"
" (batch): torch::nn::BatchNorm2d(5, eps=1e-05, momentum=0.1, affine=true, track_running_stats=true)\n"
" (embedding): torch::nn::Embedding(num_embeddings=4, embedding_dim=10)\n"
" (lstm): torch::nn::LSTM(input_size=4, hidden_size=5, num_layers=1, bias=true, batch_first=false, dropout=0, bidirectional=false)\n"
")");
}
TEST_F(ModuleDictTest, InvalidAt) {
torch::OrderedDict<std::string, std::shared_ptr<Module>> ordereddict = {
{"linear", Linear(10, 3).ptr()}};
ModuleDict dict(ordereddict);
ASSERT_THROWS_WITH(
dict->at<torch::nn::Dropout2dImpl>("linear"), "Unable to cast module");
}