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test_lite_trainer.cpp
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test_lite_trainer.cpp
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#include <test/cpp/jit/test_utils.h>
#include <gtest/gtest.h>
#include <c10/core/TensorOptions.h>
#include <torch/csrc/autograd/generated/variable_factories.h>
#include <torch/csrc/jit/api/module.h>
#include <torch/csrc/jit/mobile/import.h>
#include <torch/csrc/jit/mobile/import_data.h>
#include <torch/csrc/jit/mobile/module.h>
#include <torch/csrc/jit/mobile/train/export_data.h>
#include <torch/csrc/jit/mobile/train/optim/sgd.h>
#include <torch/csrc/jit/mobile/train/random.h>
#include <torch/csrc/jit/mobile/train/sequential.h>
#include <torch/csrc/jit/serialization/import.h>
#include <torch/data/dataloader.h>
#include <torch/torch.h>
// Tests go in torch::jit
namespace torch {
namespace jit {
TEST(LiteTrainerTest, Params) {
Module m("m");
m.register_parameter("foo", torch::ones({1}, at::requires_grad()), false);
m.define(R"(
def forward(self, x):
b = 1.0
return self.foo * x + b
)");
double learning_rate = 0.1, momentum = 0.1;
int n_epoc = 10;
// init: y = x + 1;
// target: y = 2 x + 1
std::vector<std::pair<Tensor, Tensor>> trainData{
{1 * torch::ones({1}), 3 * torch::ones({1})},
};
// Reference: Full jit
std::stringstream ms;
m.save(ms);
auto mm = load(ms);
// mm.train();
std::vector<::at::Tensor> parameters;
for (auto parameter : mm.parameters()) {
parameters.emplace_back(parameter);
}
::torch::optim::SGD optimizer(
parameters, ::torch::optim::SGDOptions(learning_rate).momentum(momentum));
for (int epoc = 0; epoc < n_epoc; ++epoc) {
for (auto& data : trainData) {
auto source = data.first, targets = data.second;
optimizer.zero_grad();
std::vector<IValue> train_inputs{source};
auto output = mm.forward(train_inputs).toTensor();
auto loss = ::torch::l1_loss(output, targets);
loss.backward();
optimizer.step();
}
}
std::stringstream ss;
m._save_for_mobile(ss);
mobile::Module bc = _load_for_mobile(ss);
std::vector<::at::Tensor> bc_parameters = bc.parameters();
::torch::optim::SGD bc_optimizer(
bc_parameters,
::torch::optim::SGDOptions(learning_rate).momentum(momentum));
for (int epoc = 0; epoc < n_epoc; ++epoc) {
for (auto& data : trainData) {
auto source = data.first, targets = data.second;
bc_optimizer.zero_grad();
std::vector<IValue> train_inputs{source};
auto output = bc.forward(train_inputs).toTensor();
auto loss = ::torch::l1_loss(output, targets);
loss.backward();
bc_optimizer.step();
}
}
AT_ASSERT(parameters[0].item<float>() == bc_parameters[0].item<float>());
}
// TODO Renable these tests after parameters are correctly loaded on mobile
/*
TEST(MobileTest, NamedParameters) {
Module m("m");
m.register_parameter("foo", torch::ones({}), false);
m.define(R"(
def add_it(self, x):
b = 4
return self.foo + x + b
)");
Module child("m2");
child.register_parameter("foo", 4 * torch::ones({}), false);
child.register_parameter("bar", 4 * torch::ones({}), false);
m.register_module("child1", child);
m.register_module("child2", child.clone());
std::stringstream ss;
m._save_for_mobile(ss);
mobile::Module bc = _load_for_mobile(ss);
auto full_params = m.named_parameters();
auto mobile_params = bc.named_parameters();
AT_ASSERT(full_params.size() == mobile_params.size());
for (const auto& e : full_params) {
AT_ASSERT(e.value.item().toInt() ==
mobile_params[e.name].item().toInt());
}
}
TEST(MobileTest, SaveLoadParameters) {
Module m("m");
m.register_parameter("foo", torch::ones({}), false);
m.define(R"(
def add_it(self, x):
b = 4
return self.foo + x + b
)");
Module child("m2");
child.register_parameter("foo", 4 * torch::ones({}), false);
child.register_parameter("bar", 3 * torch::ones({}), false);
m.register_module("child1", child);
m.register_module("child2", child.clone());
auto full_params = m.named_parameters();
std::stringstream ss;
std::stringstream ss_data;
m._save_for_mobile(ss);
// load mobile module, save mobile named parameters
mobile::Module bc = _load_for_mobile(ss);
_save_parameters(bc.named_parameters(), ss_data);
// load back the named parameters, compare to full-jit Module's
auto mobile_params = _load_parameters(ss_data);
AT_ASSERT(full_params.size() == mobile_params.size());
for (const auto& e : full_params) {
AT_ASSERT(e.value.item<int>() == mobile_params[e.name].item<int>());
}
}
*/
TEST(MobileTest, SaveLoadParametersEmpty) {
Module m("m");
m.define(R"(
def add_it(self, x):
b = 4
return x + b
)");
Module child("m2");
m.register_module("child1", child);
m.register_module("child2", child.clone());
std::stringstream ss;
std::stringstream ss_data;
m._save_for_mobile(ss);
// load mobile module, save mobile named parameters
mobile::Module bc = _load_for_mobile(ss);
_save_parameters(bc.named_parameters(), ss_data);
// load back the named parameters, test is empty
auto mobile_params = _load_parameters(ss_data);
AT_ASSERT(mobile_params.size() == 0);
}
TEST(MobileTest, SaveParametersDefaultsToZip) {
// Save some empty parameters.
std::map<std::string, at::Tensor> empty_parameters;
std::stringstream ss_data;
_save_parameters(empty_parameters, ss_data);
// Verify that parameters were serialized to a ZIP container.
EXPECT_GE(ss_data.str().size(), 4);
EXPECT_EQ(ss_data.str()[0], 'P');
EXPECT_EQ(ss_data.str()[1], 'K');
EXPECT_EQ(ss_data.str()[2], '\x03');
EXPECT_EQ(ss_data.str()[3], '\x04');
}
TEST(MobileTest, SaveParametersCanUseFlatbuffer) {
// Save some empty parameters using flatbuffer.
std::map<std::string, at::Tensor> empty_parameters;
std::stringstream ss_data;
_save_parameters(empty_parameters, ss_data, /*use_flatbuffer=*/true);
// Verify that parameters were serialized to a flatbuffer. The flatbuffer
// magic bytes should be at offsets 4..7. The first four bytes contain an
// offset to the actual flatbuffer data.
EXPECT_GE(ss_data.str().size(), 8);
EXPECT_EQ(ss_data.str()[4], 'P');
EXPECT_EQ(ss_data.str()[5], 'T');
EXPECT_EQ(ss_data.str()[6], 'M');
EXPECT_EQ(ss_data.str()[7], 'F');
}
TEST(MobileTest, SaveLoadParametersUsingFlatbuffers) {
// Create some simple parameters to save.
std::map<std::string, at::Tensor> input_params;
input_params["four_by_ones"] = 4 * torch::ones({});
input_params["three_by_ones"] = 3 * torch::ones({});
// Serialize them using flatbuffers.
std::stringstream data;
_save_parameters(input_params, data, /*use_flatbuffer=*/true);
// The flatbuffer magic bytes should be at offsets 4..7.
EXPECT_EQ(data.str()[4], 'P');
EXPECT_EQ(data.str()[5], 'T');
EXPECT_EQ(data.str()[6], 'M');
EXPECT_EQ(data.str()[7], 'F');
// Read them back and check that they survived the trip.
auto output_params = _load_parameters(data);
EXPECT_EQ(output_params.size(), 2);
{
auto four_by_ones = 4 * torch::ones({});
EXPECT_EQ(
output_params["four_by_ones"].item<int>(), four_by_ones.item<int>());
}
{
auto three_by_ones = 3 * torch::ones({});
EXPECT_EQ(
output_params["three_by_ones"].item<int>(), three_by_ones.item<int>());
}
}
TEST(MobileTest, LoadParametersUnexpectedFormatShouldThrow) {
// Manually create some data that doesn't look like a ZIP or Flatbuffer file.
// Make sure it's longer than 8 bytes, since getFileFormat() needs that much
// data to detect the type.
std::stringstream bad_data;
bad_data << "abcd"
<< "efgh"
<< "ijkl";
// Loading parameters from it should throw an exception.
EXPECT_ANY_THROW(_load_parameters(bad_data));
}
TEST(MobileTest, LoadParametersEmptyDataShouldThrow) {
// Loading parameters from an empty data stream should throw an exception.
std::stringstream empty;
EXPECT_ANY_THROW(_load_parameters(empty));
}
TEST(MobileTest, LoadParametersMalformedFlatbuffer) {
// Manually create some data with Flatbuffer header.
std::stringstream bad_data;
bad_data << "PK\x03\x04PTMF\x00\x00"
<< "*}NV\xb3\xfa\xdf\x00pa";
// Loading parameters from it should throw an exception.
ASSERT_THROWS_WITH_MESSAGE(
_load_parameters(bad_data), "Malformed Flatbuffer module");
}
TEST(LiteTrainerTest, SGD) {
Module m("m");
m.register_parameter("foo", torch::ones({1}, at::requires_grad()), false);
m.define(R"(
def forward(self, x):
b = 1.0
return self.foo * x + b
)");
double learning_rate = 0.1, momentum = 0.1;
int n_epoc = 10;
// init: y = x + 1;
// target: y = 2 x + 1
std::vector<std::pair<Tensor, Tensor>> trainData{
{1 * torch::ones({1}), 3 * torch::ones({1})},
};
// Reference: Full jit and torch::optim::SGD
std::stringstream ms;
m.save(ms);
auto mm = load(ms);
std::vector<::at::Tensor> parameters;
for (auto parameter : mm.parameters()) {
parameters.emplace_back(parameter);
}
::torch::optim::SGD optimizer(
parameters, ::torch::optim::SGDOptions(learning_rate).momentum(momentum));
for (int epoc = 0; epoc < n_epoc; ++epoc) {
for (auto& data : trainData) {
auto source = data.first, targets = data.second;
optimizer.zero_grad();
std::vector<IValue> train_inputs{source};
auto output = mm.forward(train_inputs).toTensor();
auto loss = ::torch::l1_loss(output, targets);
loss.backward();
optimizer.step();
}
}
// Test: lite interpreter and torch::jit::mobile::SGD
std::stringstream ss;
m._save_for_mobile(ss);
mobile::Module bc = _load_for_mobile(ss);
std::vector<::at::Tensor> bc_parameters = bc.parameters();
::torch::jit::mobile::SGD bc_optimizer(
bc_parameters,
::torch::jit::mobile::SGDOptions(learning_rate).momentum(momentum));
for (int epoc = 0; epoc < n_epoc; ++epoc) {
for (auto& data : trainData) {
auto source = data.first, targets = data.second;
bc_optimizer.zero_grad();
std::vector<IValue> train_inputs{source};
auto output = bc.forward(train_inputs).toTensor();
auto loss = ::torch::l1_loss(output, targets);
loss.backward();
bc_optimizer.step();
}
}
AT_ASSERT(parameters[0].item<float>() == bc_parameters[0].item<float>());
}
namespace {
struct DummyDataset : torch::data::datasets::Dataset<DummyDataset, int> {
explicit DummyDataset(size_t size = 100) : size_(size) {}
int get(size_t index) override {
// NOLINTNEXTLINE(bugprone-narrowing-conversions,cppcoreguidelines-narrowing-conversions)
return 1 + index;
}
std::optional<size_t> size() const override {
return size_;
}
size_t size_;
};
} // namespace
TEST(LiteTrainerTest, SequentialSampler) {
// test that sampler can be used with dataloader
const int kBatchSize = 10;
auto data_loader = torch::data::make_data_loader<mobile::SequentialSampler>(
DummyDataset(25), kBatchSize);
int i = 1;
for (const auto& batch : *data_loader) {
for (const auto& example : batch) {
AT_ASSERT(i == example);
i++;
}
}
}
TEST(LiteTrainerTest, RandomSamplerReturnsIndicesInCorrectRange) {
mobile::RandomSampler sampler(10);
std::vector<size_t> indices = sampler.next(3).value();
for (auto i : indices) {
AT_ASSERT(i < 10);
}
indices = sampler.next(5).value();
for (auto i : indices) {
AT_ASSERT(i < 10);
}
indices = sampler.next(2).value();
for (auto i : indices) {
AT_ASSERT(i < 10);
}
AT_ASSERT(sampler.next(10).has_value() == false);
}
TEST(LiteTrainerTest, RandomSamplerReturnsLessValuesForLastBatch) {
mobile::RandomSampler sampler(5);
AT_ASSERT(sampler.next(3).value().size() == 3);
AT_ASSERT(sampler.next(100).value().size() == 2);
AT_ASSERT(sampler.next(2).has_value() == false);
}
TEST(LiteTrainerTest, RandomSamplerResetsWell) {
mobile::RandomSampler sampler(5);
AT_ASSERT(sampler.next(5).value().size() == 5);
AT_ASSERT(sampler.next(2).has_value() == false);
sampler.reset();
AT_ASSERT(sampler.next(5).value().size() == 5);
AT_ASSERT(sampler.next(2).has_value() == false);
}
TEST(LiteTrainerTest, RandomSamplerResetsWithNewSizeWell) {
mobile::RandomSampler sampler(5);
AT_ASSERT(sampler.next(5).value().size() == 5);
AT_ASSERT(sampler.next(2).has_value() == false);
sampler.reset(7);
AT_ASSERT(sampler.next(7).value().size() == 7);
AT_ASSERT(sampler.next(2).has_value() == false);
sampler.reset(3);
AT_ASSERT(sampler.next(3).value().size() == 3);
AT_ASSERT(sampler.next(2).has_value() == false);
}
} // namespace jit
} // namespace torch