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rnn.cpp
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rnn.cpp
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#include <gtest/gtest.h>
#include <torch/torch.h>
#include <test/cpp/api/support.h>
using namespace torch::nn;
using namespace torch::test;
template <typename R, typename Func>
bool test_RNN_xor(Func&& model_maker, bool cuda = false) {
torch::manual_seed(0);
auto nhid = 32;
auto model = std::make_shared<SimpleContainer>();
auto l1 = model->add(Linear(1, nhid), "l1");
auto rnn_model = model_maker(nhid);
auto rnn = model->add(rnn_model, "rnn");
auto nout = nhid;
if (rnn_model.get()->options_base.proj_size() > 0) {
nout = rnn_model.get()->options_base.proj_size();
}
auto lo = model->add(Linear(nout, 1), "lo");
torch::optim::Adam optimizer(model->parameters(), 1e-2);
auto forward_op = [&](torch::Tensor x) {
auto T = x.size(0);
auto B = x.size(1);
x = x.view({T * B, 1});
x = l1->forward(x).view({T, B, nhid}).tanh_();
x = std::get<0>(rnn->forward(x))[T - 1];
x = lo->forward(x);
return x;
};
if (cuda) {
model->to(torch::kCUDA);
}
float running_loss = 1;
int epoch = 0;
auto max_epoch = 1500;
while (running_loss > 1e-2) {
auto bs = 16U;
auto nlen = 5U;
const auto backend = cuda ? torch::kCUDA : torch::kCPU;
auto inputs =
torch::rand({nlen, bs, 1}, backend).round().to(torch::kFloat32);
auto labels = inputs.sum(0).detach();
inputs.set_requires_grad(true);
auto outputs = forward_op(inputs);
torch::Tensor loss = torch::mse_loss(outputs, labels);
optimizer.zero_grad();
loss.backward();
optimizer.step();
// NOLINTNEXTLINE(cppcoreguidelines-narrowing-conversions,cppcoreguidelines-avoid-magic-numbers,bugprone-narrowing-conversions)
running_loss = running_loss * 0.99 + loss.item<float>() * 0.01;
if (epoch > max_epoch) {
return false;
}
epoch++;
}
return true;
};
void check_lstm_sizes(
std::tuple<torch::Tensor, std::tuple<torch::Tensor, torch::Tensor>>
lstm_output) {
// Expect the LSTM to have 64 outputs and 3 layers, with an input of batch
// 10 and 16 time steps (10 x 16 x n)
torch::Tensor output = std::get<0>(lstm_output);
std::tuple<torch::Tensor, torch::Tensor> state = std::get<1>(lstm_output);
torch::Tensor hx = std::get<0>(state);
torch::Tensor cx = std::get<1>(state);
ASSERT_EQ(output.ndimension(), 3);
ASSERT_EQ(output.size(0), 10);
ASSERT_EQ(output.size(1), 16);
ASSERT_EQ(output.size(2), 64);
ASSERT_EQ(hx.ndimension(), 3);
ASSERT_EQ(hx.size(0), 3); // layers
ASSERT_EQ(hx.size(1), 16); // Batchsize
ASSERT_EQ(hx.size(2), 64); // 64 hidden dims
ASSERT_EQ(cx.ndimension(), 3);
ASSERT_EQ(cx.size(0), 3); // layers
ASSERT_EQ(cx.size(1), 16); // Batchsize
ASSERT_EQ(cx.size(2), 64); // 64 hidden dims
// Something is in the hiddens
ASSERT_GT(hx.norm().item<float>(), 0);
ASSERT_GT(cx.norm().item<float>(), 0);
}
void check_lstm_sizes_proj(
std::tuple<torch::Tensor, std::tuple<torch::Tensor, torch::Tensor>>
lstm_output) {
// Expect the LSTM to have 32 outputs and 3 layers, with an input of batch
// 10 and 16 time steps (10 x 16 x n)
torch::Tensor output = std::get<0>(lstm_output);
std::tuple<torch::Tensor, torch::Tensor> state = std::get<1>(lstm_output);
torch::Tensor hx = std::get<0>(state);
torch::Tensor cx = std::get<1>(state);
ASSERT_EQ(output.ndimension(), 3);
ASSERT_EQ(output.size(0), 10);
ASSERT_EQ(output.size(1), 16);
ASSERT_EQ(output.size(2), 32);
ASSERT_EQ(hx.ndimension(), 3);
ASSERT_EQ(hx.size(0), 3); // layers
ASSERT_EQ(hx.size(1), 16); // Batchsize
ASSERT_EQ(hx.size(2), 32); // 32 hidden dims
ASSERT_EQ(cx.ndimension(), 3);
ASSERT_EQ(cx.size(0), 3); // layers
ASSERT_EQ(cx.size(1), 16); // Batchsize
ASSERT_EQ(cx.size(2), 64); // 64 cell dims
// Something is in the hiddens
ASSERT_GT(hx.norm().item<float>(), 0);
ASSERT_GT(cx.norm().item<float>(), 0);
}
struct RNNTest : torch::test::SeedingFixture {};
TEST_F(RNNTest, CheckOutputSizes) {
LSTM model(LSTMOptions(128, 64).num_layers(3).dropout(0.2));
// Input size is: sequence length, batch size, input size
auto x = torch::randn({10, 16, 128}, torch::requires_grad());
auto output = model->forward(x);
auto y = x.mean();
y.backward();
check_lstm_sizes(output);
auto next = model->forward(x, std::get<1>(output));
check_lstm_sizes(next);
auto output_hx = std::get<0>(std::get<1>(output));
auto output_cx = std::get<1>(std::get<1>(output));
auto next_hx = std::get<0>(std::get<1>(next));
auto next_cx = std::get<1>(std::get<1>(next));
torch::Tensor diff =
torch::cat({next_hx, next_cx}, 0) - torch::cat({output_hx, output_cx}, 0);
// Hiddens changed
ASSERT_GT(diff.abs().sum().item<float>(), 1e-3);
}
TEST_F(RNNTest, CheckOutputSizesProj) {
LSTM model(LSTMOptions(128, 64).num_layers(3).dropout(0.2).proj_size(32));
// Input size is: sequence length, batch size, input size
auto x = torch::randn({10, 16, 128}, torch::requires_grad());
auto output = model->forward(x);
auto y = x.mean();
y.backward();
check_lstm_sizes_proj(output);
auto next = model->forward(x, std::get<1>(output));
check_lstm_sizes_proj(next);
auto output_hx = std::get<0>(std::get<1>(output));
auto output_cx = std::get<1>(std::get<1>(output));
auto next_hx = std::get<0>(std::get<1>(next));
auto next_cx = std::get<1>(std::get<1>(next));
torch::Tensor diff = next_hx - output_hx;
// Hiddens changed
ASSERT_GT(diff.abs().sum().item<float>(), 1e-3);
diff = next_cx - output_cx;
ASSERT_GT(diff.abs().sum().item<float>(), 1e-3);
}
TEST_F(RNNTest, CheckOutputValuesMatchPyTorch) {
torch::manual_seed(0);
// Make sure the outputs match pytorch outputs
LSTM model(2, 2);
for (auto& v : model->parameters()) {
float size = v.numel();
auto p = static_cast<float*>(v.storage().mutable_data());
for (size_t i = 0; i < size; i++) {
p[i] = i / size;
}
}
auto x = torch::empty({3, 4, 2}, torch::requires_grad());
float size = x.numel();
auto p = static_cast<float*>(x.storage().mutable_data());
for (size_t i = 0; i < size; i++) {
p[i] = (size - i) / size;
}
auto out = model->forward(x);
ASSERT_EQ(std::get<0>(out).ndimension(), 3);
ASSERT_EQ(std::get<0>(out).size(0), 3);
ASSERT_EQ(std::get<0>(out).size(1), 4);
ASSERT_EQ(std::get<0>(out).size(2), 2);
auto flat = std::get<0>(out).view(3 * 4 * 2);
// NOLINTNEXTLINE(cppcoreguidelines-avoid-magic-numbers,modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
float c_out[] = {0.4391, 0.5402, 0.4330, 0.5324, 0.4261, 0.5239,
0.4183, 0.5147, 0.6822, 0.8064, 0.6726, 0.7968,
0.6620, 0.7860, 0.6501, 0.7741, 0.7889, 0.9003,
0.7769, 0.8905, 0.7635, 0.8794, 0.7484, 0.8666};
for (size_t i = 0; i < 3 * 4 * 2; i++) {
ASSERT_LT(std::abs(flat[i].item<float>() - c_out[i]), 1e-3);
}
auto hx = std::get<0>(std::get<1>(out));
auto cx = std::get<1>(std::get<1>(out));
ASSERT_EQ(hx.ndimension(), 3); // layers x B x 2
ASSERT_EQ(hx.size(0), 1);
ASSERT_EQ(hx.size(1), 4);
ASSERT_EQ(hx.size(2), 2);
ASSERT_EQ(cx.ndimension(), 3); // layers x B x 2
ASSERT_EQ(cx.size(0), 1);
ASSERT_EQ(cx.size(1), 4);
ASSERT_EQ(cx.size(2), 2);
flat = torch::cat({hx, cx}, 0).view(16);
// NOLINTNEXTLINE(cppcoreguidelines-avoid-magic-numbers,modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
float h_out[] = {
0.7889,
0.9003,
0.7769,
0.8905,
0.7635,
0.8794,
0.7484,
0.8666,
1.1647,
1.6106,
1.1425,
1.5726,
1.1187,
1.5329,
1.0931,
1.4911};
for (size_t i = 0; i < 16; i++) {
ASSERT_LT(std::abs(flat[i].item<float>() - h_out[i]), 1e-3);
}
}
TEST_F(RNNTest, EndToEndLSTM) {
ASSERT_TRUE(test_RNN_xor<LSTM>(
[](int s) { return LSTM(LSTMOptions(s, s).num_layers(2)); }));
}
TEST_F(RNNTest, EndToEndLSTMProj) {
ASSERT_TRUE(test_RNN_xor<LSTM>([](int s) {
return LSTM(LSTMOptions(s, s).num_layers(2).proj_size(s / 2));
}));
}
TEST_F(RNNTest, EndToEndGRU) {
ASSERT_TRUE(test_RNN_xor<GRU>(
[](int s) { return GRU(GRUOptions(s, s).num_layers(2)); }));
}
TEST_F(RNNTest, EndToEndRNNRelu) {
ASSERT_TRUE(test_RNN_xor<RNN>([](int s) {
return RNN(RNNOptions(s, s).nonlinearity(torch::kReLU).num_layers(2));
}));
}
TEST_F(RNNTest, EndToEndRNNTanh) {
ASSERT_TRUE(test_RNN_xor<RNN>([](int s) {
return RNN(RNNOptions(s, s).nonlinearity(torch::kTanh).num_layers(2));
}));
}
TEST_F(RNNTest, Sizes_CUDA) {
torch::manual_seed(0);
LSTM model(LSTMOptions(128, 64).num_layers(3).dropout(0.2));
model->to(torch::kCUDA);
auto x =
torch::randn({10, 16, 128}, torch::requires_grad().device(torch::kCUDA));
auto output = model->forward(x);
auto y = x.mean();
y.backward();
check_lstm_sizes(output);
auto next = model->forward(x, std::get<1>(output));
check_lstm_sizes(next);
auto output_hx = std::get<0>(std::get<1>(output));
auto output_cx = std::get<1>(std::get<1>(output));
auto next_hx = std::get<0>(std::get<1>(next));
auto next_cx = std::get<1>(std::get<1>(next));
torch::Tensor diff =
torch::cat({next_hx, next_cx}, 0) - torch::cat({output_hx, output_cx}, 0);
// Hiddens changed
ASSERT_GT(diff.abs().sum().item<float>(), 1e-3);
}
TEST_F(RNNTest, SizesProj_CUDA) {
torch::manual_seed(0);
LSTM model(LSTMOptions(128, 64).num_layers(3).dropout(0.2).proj_size(32));
model->to(torch::kCUDA);
auto x =
torch::randn({10, 16, 128}, torch::requires_grad().device(torch::kCUDA));
auto output = model->forward(x);
auto y = x.mean();
y.backward();
check_lstm_sizes_proj(output);
auto next = model->forward(x, std::get<1>(output));
check_lstm_sizes_proj(next);
auto output_hx = std::get<0>(std::get<1>(output));
auto output_cx = std::get<1>(std::get<1>(output));
auto next_hx = std::get<0>(std::get<1>(next));
auto next_cx = std::get<1>(std::get<1>(next));
torch::Tensor diff = next_hx - output_hx;
// Hiddens changed
ASSERT_GT(diff.abs().sum().item<float>(), 1e-3);
diff = next_cx - output_cx;
ASSERT_GT(diff.abs().sum().item<float>(), 1e-3);
}
TEST_F(RNNTest, EndToEndLSTM_CUDA) {
ASSERT_TRUE(test_RNN_xor<LSTM>(
[](int s) { return LSTM(LSTMOptions(s, s).num_layers(2)); }, true));
}
TEST_F(RNNTest, EndToEndLSTMProj_CUDA) {
ASSERT_TRUE(test_RNN_xor<LSTM>(
[](int s) {
return LSTM(LSTMOptions(s, s).num_layers(2).proj_size(s / 2));
},
true));
}
TEST_F(RNNTest, EndToEndGRU_CUDA) {
ASSERT_TRUE(test_RNN_xor<GRU>(
[](int s) { return GRU(GRUOptions(s, s).num_layers(2)); }, true));
}
TEST_F(RNNTest, EndToEndRNNRelu_CUDA) {
ASSERT_TRUE(test_RNN_xor<RNN>(
[](int s) {
return RNN(RNNOptions(s, s).nonlinearity(torch::kReLU).num_layers(2));
},
true));
}
TEST_F(RNNTest, EndToEndRNNTanh_CUDA) {
ASSERT_TRUE(test_RNN_xor<RNN>(
[](int s) {
return RNN(RNNOptions(s, s).nonlinearity(torch::kTanh).num_layers(2));
},
true));
}
TEST_F(RNNTest, PrettyPrintRNNs) {
ASSERT_EQ(
c10::str(LSTM(LSTMOptions(128, 64).num_layers(3).dropout(0.2))),
"torch::nn::LSTM(input_size=128, hidden_size=64, num_layers=3, bias=true, batch_first=false, dropout=0.2, bidirectional=false)");
ASSERT_EQ(
c10::str(
LSTM(LSTMOptions(128, 64).num_layers(3).dropout(0.2).proj_size(32))),
"torch::nn::LSTM(input_size=128, hidden_size=64, num_layers=3, bias=true, batch_first=false, dropout=0.2, bidirectional=false, proj_size=32)");
ASSERT_EQ(
c10::str(GRU(GRUOptions(128, 64).num_layers(3).dropout(0.5))),
"torch::nn::GRU(input_size=128, hidden_size=64, num_layers=3, bias=true, batch_first=false, dropout=0.5, bidirectional=false)");
ASSERT_EQ(
c10::str(RNN(RNNOptions(128, 64).num_layers(3).dropout(0.2).nonlinearity(
torch::kTanh))),
"torch::nn::RNN(input_size=128, hidden_size=64, num_layers=3, bias=true, batch_first=false, dropout=0.2, bidirectional=false)");
}
// This test assures that flatten_parameters does not crash,
// when bidirectional is set to true
// https://github.com/pytorch/pytorch/issues/19545
TEST_F(RNNTest, BidirectionalFlattenParameters) {
GRU gru(GRUOptions(100, 256).num_layers(2).bidirectional(true));
gru->flatten_parameters();
}
template <typename Impl>
void copyParameters(
torch::nn::ModuleHolder<Impl>& target,
std::string t_suffix,
const torch::nn::ModuleHolder<Impl>& source,
std::string s_suffix) {
at::NoGradGuard guard;
target->named_parameters()["weight_ih_l" + t_suffix].copy_(
source->named_parameters()["weight_ih_l" + s_suffix]);
target->named_parameters()["weight_hh_l" + t_suffix].copy_(
source->named_parameters()["weight_hh_l" + s_suffix]);
target->named_parameters()["bias_ih_l" + t_suffix].copy_(
source->named_parameters()["bias_ih_l" + s_suffix]);
target->named_parameters()["bias_hh_l" + t_suffix].copy_(
source->named_parameters()["bias_hh_l" + s_suffix]);
}
std::tuple<torch::Tensor, torch::Tensor> gru_output_to_device(
std::tuple<torch::Tensor, torch::Tensor> gru_output,
torch::Device device) {
return std::make_tuple(
std::get<0>(gru_output).to(device), std::get<1>(gru_output).to(device));
}
std::tuple<torch::Tensor, std::tuple<torch::Tensor, torch::Tensor>>
lstm_output_to_device(
std::tuple<torch::Tensor, std::tuple<torch::Tensor, torch::Tensor>>
lstm_output,
torch::Device device) {
auto hidden_states = std::get<1>(lstm_output);
return std::make_tuple(
std::get<0>(lstm_output).to(device),
std::make_tuple(
std::get<0>(hidden_states).to(device),
std::get<1>(hidden_states).to(device)));
}
// This test is a port of python code introduced here:
// https://towardsdatascience.com/understanding-bidirectional-rnn-in-pytorch-5bd25a5dd66
// Reverse forward of bidirectional GRU should act
// as regular forward of unidirectional GRU
void BidirectionalGRUReverseForward(bool cuda) {
auto opt = torch::TensorOptions()
.dtype(torch::kFloat32)
.requires_grad(false)
.device(cuda ? torch::kCUDA : torch::kCPU);
auto input = torch::tensor({1, 2, 3, 4, 5}, opt).reshape({5, 1, 1});
auto input_reversed = torch::tensor({5, 4, 3, 2, 1}, opt).reshape({5, 1, 1});
auto gru_options = GRUOptions(1, 1).num_layers(1).batch_first(false);
GRU bi_grus{gru_options.bidirectional(true)};
GRU reverse_gru{gru_options.bidirectional(false)};
if (cuda) {
bi_grus->to(torch::kCUDA);
reverse_gru->to(torch::kCUDA);
}
// Now make sure the weights of the reverse gru layer match
// ones of the (reversed) bidirectional's:
copyParameters(reverse_gru, "0", bi_grus, "0_reverse");
auto bi_output = bi_grus->forward(input);
auto reverse_output = reverse_gru->forward(input_reversed);
if (cuda) {
bi_output = gru_output_to_device(bi_output, torch::kCPU);
reverse_output = gru_output_to_device(reverse_output, torch::kCPU);
}
ASSERT_EQ(
std::get<0>(bi_output).size(0), std::get<0>(reverse_output).size(0));
auto size = std::get<0>(bi_output).size(0);
for (int i = 0; i < size; i++) {
ASSERT_EQ(
std::get<0>(bi_output)[i][0][1].item<float>(),
std::get<0>(reverse_output)[size - 1 - i][0][0].item<float>());
}
// The hidden states of the reversed GRUs sits
// in the odd indices in the first dimension.
ASSERT_EQ(
std::get<1>(bi_output)[1][0][0].item<float>(),
std::get<1>(reverse_output)[0][0][0].item<float>());
}
TEST_F(RNNTest, BidirectionalGRUReverseForward) {
BidirectionalGRUReverseForward(false);
}
TEST_F(RNNTest, BidirectionalGRUReverseForward_CUDA) {
BidirectionalGRUReverseForward(true);
}
// Reverse forward of bidirectional LSTM should act
// as regular forward of unidirectional LSTM
void BidirectionalLSTMReverseForwardTest(bool cuda) {
auto opt = torch::TensorOptions()
.dtype(torch::kFloat32)
.requires_grad(false)
.device(cuda ? torch::kCUDA : torch::kCPU);
auto input = torch::tensor({1, 2, 3, 4, 5}, opt).reshape({5, 1, 1});
auto input_reversed = torch::tensor({5, 4, 3, 2, 1}, opt).reshape({5, 1, 1});
auto lstm_opt = LSTMOptions(1, 1).num_layers(1).batch_first(false);
LSTM bi_lstm{lstm_opt.bidirectional(true)};
LSTM reverse_lstm{lstm_opt.bidirectional(false)};
if (cuda) {
bi_lstm->to(torch::kCUDA);
reverse_lstm->to(torch::kCUDA);
}
// Now make sure the weights of the reverse lstm layer match
// ones of the (reversed) bidirectional's:
copyParameters(reverse_lstm, "0", bi_lstm, "0_reverse");
auto bi_output = bi_lstm->forward(input);
auto reverse_output = reverse_lstm->forward(input_reversed);
if (cuda) {
bi_output = lstm_output_to_device(bi_output, torch::kCPU);
reverse_output = lstm_output_to_device(reverse_output, torch::kCPU);
}
ASSERT_EQ(
std::get<0>(bi_output).size(0), std::get<0>(reverse_output).size(0));
auto size = std::get<0>(bi_output).size(0);
for (int i = 0; i < size; i++) {
ASSERT_EQ(
std::get<0>(bi_output)[i][0][1].item<float>(),
std::get<0>(reverse_output)[size - 1 - i][0][0].item<float>());
}
// The hidden states of the reversed LSTM sits
// in the odd indices in the first dimension.
ASSERT_EQ(
std::get<0>(std::get<1>(bi_output))[1][0][0].item<float>(),
std::get<0>(std::get<1>(reverse_output))[0][0][0].item<float>());
ASSERT_EQ(
std::get<1>(std::get<1>(bi_output))[1][0][0].item<float>(),
std::get<1>(std::get<1>(reverse_output))[0][0][0].item<float>());
}
TEST_F(RNNTest, BidirectionalLSTMReverseForward) {
BidirectionalLSTMReverseForwardTest(false);
}
TEST_F(RNNTest, BidirectionalLSTMReverseForward_CUDA) {
BidirectionalLSTMReverseForwardTest(true);
}
TEST_F(RNNTest, BidirectionalMultilayerGRU_CPU_vs_CUDA) {
// Create two GRUs with the same options
auto opt =
GRUOptions(2, 4).num_layers(3).batch_first(false).bidirectional(true);
GRU gru_cpu{opt};
GRU gru_cuda{opt};
// Copy weights and biases from CPU GRU to CUDA GRU
{
at::NoGradGuard guard;
for (const auto& param : gru_cpu->named_parameters(/*recurse=*/false)) {
gru_cuda->named_parameters()[param.key()].copy_(
gru_cpu->named_parameters()[param.key()]);
}
}
gru_cpu->flatten_parameters();
gru_cuda->flatten_parameters();
// Move GRU to CUDA
gru_cuda->to(torch::kCUDA);
// Create the same inputs
auto input_opt =
torch::TensorOptions().dtype(torch::kFloat32).requires_grad(false);
auto input_cpu =
torch::tensor({1, 2, 3, 4, 5, 6}, input_opt).reshape({3, 1, 2});
auto input_cuda = torch::tensor({1, 2, 3, 4, 5, 6}, input_opt)
.reshape({3, 1, 2})
.to(torch::kCUDA);
// Call forward on both GRUs
auto output_cpu = gru_cpu->forward(input_cpu);
auto output_cuda = gru_cuda->forward(input_cuda);
output_cpu = gru_output_to_device(output_cpu, torch::kCPU);
// Assert that the output and state are equal on CPU and CUDA
ASSERT_EQ(std::get<0>(output_cpu).dim(), std::get<0>(output_cuda).dim());
for (int i = 0; i < std::get<0>(output_cpu).dim(); i++) {
ASSERT_EQ(
std::get<0>(output_cpu).size(i), std::get<0>(output_cuda).size(i));
}
for (int i = 0; i < std::get<0>(output_cpu).size(0); i++) {
for (int j = 0; j < std::get<0>(output_cpu).size(1); j++) {
for (int k = 0; k < std::get<0>(output_cpu).size(2); k++) {
ASSERT_NEAR(
std::get<0>(output_cpu)[i][j][k].item<float>(),
std::get<0>(output_cuda)[i][j][k].item<float>(),
1e-5);
}
}
}
}
TEST_F(RNNTest, BidirectionalMultilayerLSTM_CPU_vs_CUDA) {
// Create two LSTMs with the same options
auto opt =
LSTMOptions(2, 4).num_layers(3).batch_first(false).bidirectional(true);
LSTM lstm_cpu{opt};
LSTM lstm_cuda{opt};
// Copy weights and biases from CPU LSTM to CUDA LSTM
{
at::NoGradGuard guard;
for (const auto& param : lstm_cpu->named_parameters(/*recurse=*/false)) {
lstm_cuda->named_parameters()[param.key()].copy_(
lstm_cpu->named_parameters()[param.key()]);
}
}
lstm_cpu->flatten_parameters();
lstm_cuda->flatten_parameters();
// Move LSTM to CUDA
lstm_cuda->to(torch::kCUDA);
auto options =
torch::TensorOptions().dtype(torch::kFloat32).requires_grad(false);
auto input_cpu =
torch::tensor({1, 2, 3, 4, 5, 6}, options).reshape({3, 1, 2});
auto input_cuda = torch::tensor({1, 2, 3, 4, 5, 6}, options)
.reshape({3, 1, 2})
.to(torch::kCUDA);
// Call forward on both LSTMs
auto output_cpu = lstm_cpu->forward(input_cpu);
auto output_cuda = lstm_cuda->forward(input_cuda);
output_cpu = lstm_output_to_device(output_cpu, torch::kCPU);
// Assert that the output and state are equal on CPU and CUDA
ASSERT_EQ(std::get<0>(output_cpu).dim(), std::get<0>(output_cuda).dim());
for (int i = 0; i < std::get<0>(output_cpu).dim(); i++) {
ASSERT_EQ(
std::get<0>(output_cpu).size(i), std::get<0>(output_cuda).size(i));
}
for (int i = 0; i < std::get<0>(output_cpu).size(0); i++) {
for (int j = 0; j < std::get<0>(output_cpu).size(1); j++) {
for (int k = 0; k < std::get<0>(output_cpu).size(2); k++) {
ASSERT_NEAR(
std::get<0>(output_cpu)[i][j][k].item<float>(),
std::get<0>(output_cuda)[i][j][k].item<float>(),
1e-5);
}
}
}
}
TEST_F(RNNTest, BidirectionalMultilayerLSTMProj_CPU_vs_CUDA) {
// Create two LSTMs with the same options
auto opt = LSTMOptions(2, 4)
.num_layers(3)
.batch_first(false)
.bidirectional(true)
.proj_size(2);
LSTM lstm_cpu{opt};
LSTM lstm_cuda{opt};
// Copy weights and biases from CPU LSTM to CUDA LSTM
{
at::NoGradGuard guard;
for (const auto& param : lstm_cpu->named_parameters(/*recurse=*/false)) {
lstm_cuda->named_parameters()[param.key()].copy_(
lstm_cpu->named_parameters()[param.key()]);
}
}
lstm_cpu->flatten_parameters();
lstm_cuda->flatten_parameters();
// Move LSTM to CUDA
lstm_cuda->to(torch::kCUDA);
auto options =
torch::TensorOptions().dtype(torch::kFloat32).requires_grad(false);
auto input_cpu =
torch::tensor({1, 2, 3, 4, 5, 6}, options).reshape({3, 1, 2});
auto input_cuda = torch::tensor({1, 2, 3, 4, 5, 6}, options)
.reshape({3, 1, 2})
.to(torch::kCUDA);
// Call forward on both LSTMs
auto output_cpu = lstm_cpu->forward(input_cpu);
auto output_cuda = lstm_cuda->forward(input_cuda);
output_cpu = lstm_output_to_device(output_cpu, torch::kCPU);
// Assert that the output and state are equal on CPU and CUDA
ASSERT_EQ(std::get<0>(output_cpu).dim(), std::get<0>(output_cuda).dim());
for (int i = 0; i < std::get<0>(output_cpu).dim(); i++) {
ASSERT_EQ(
std::get<0>(output_cpu).size(i), std::get<0>(output_cuda).size(i));
}
for (int i = 0; i < std::get<0>(output_cpu).size(0); i++) {
for (int j = 0; j < std::get<0>(output_cpu).size(1); j++) {
for (int k = 0; k < std::get<0>(output_cpu).size(2); k++) {
ASSERT_NEAR(
std::get<0>(output_cpu)[i][j][k].item<float>(),
std::get<0>(output_cuda)[i][j][k].item<float>(),
1e-5);
}
}
}
}
TEST_F(RNNTest, UsePackedSequenceAsInput) {
{
torch::manual_seed(0);
auto m = RNN(2, 3);
torch::nn::utils::rnn::PackedSequence packed_input =
torch::nn::utils::rnn::pack_sequence({torch::ones({3, 2})});
auto rnn_output = m->forward_with_packed_input(packed_input);
auto expected_output = torch::tensor(
{{-0.0645, -0.7274, 0.4531},
{-0.3970, -0.6950, 0.6009},
{-0.3877, -0.7310, 0.6806}});
ASSERT_TRUE(torch::allclose(
std::get<0>(rnn_output).data(), expected_output, 1e-05, 2e-04));
// Test passing optional argument to `RNN::forward_with_packed_input`
rnn_output = m->forward_with_packed_input(packed_input, torch::Tensor());
ASSERT_TRUE(torch::allclose(
std::get<0>(rnn_output).data(), expected_output, 1e-05, 2e-04));
}
{
torch::manual_seed(0);
auto m = LSTM(2, 3);
torch::nn::utils::rnn::PackedSequence packed_input =
torch::nn::utils::rnn::pack_sequence({torch::ones({3, 2})});
auto rnn_output = m->forward_with_packed_input(packed_input);
auto expected_output = torch::tensor(
{{-0.2693, -0.1240, 0.0744},
{-0.3889, -0.1919, 0.1183},
{-0.4425, -0.2314, 0.1386}});
ASSERT_TRUE(torch::allclose(
std::get<0>(rnn_output).data(), expected_output, 1e-05, 2e-04));
// Test passing optional argument to `LSTM::forward_with_packed_input`
rnn_output = m->forward_with_packed_input(packed_input, torch::nullopt);
ASSERT_TRUE(torch::allclose(
std::get<0>(rnn_output).data(), expected_output, 1e-05, 2e-04));
}
{
torch::manual_seed(0);
auto m = GRU(2, 3);
torch::nn::utils::rnn::PackedSequence packed_input =
torch::nn::utils::rnn::pack_sequence({torch::ones({3, 2})});
auto rnn_output = m->forward_with_packed_input(packed_input);
auto expected_output = torch::tensor(
{{-0.1134, 0.0467, 0.2336},
{-0.1189, 0.0502, 0.2960},
{-0.1138, 0.0484, 0.3110}});
ASSERT_TRUE(torch::allclose(
std::get<0>(rnn_output).data(), expected_output, 1e-05, 2e-04));
// Test passing optional argument to `GRU::forward_with_packed_input`
rnn_output = m->forward_with_packed_input(packed_input, torch::Tensor());
ASSERT_TRUE(torch::allclose(
std::get<0>(rnn_output).data(), expected_output, 1e-05, 2e-04));
}
}
TEST_F(RNNTest, CheckErrorInfos) {
{
auto options = torch::nn::RNNOptions(1, 0).num_layers(1);
ASSERT_THROWS_WITH(RNN(options), "hidden_size must be greater than zero");
options = torch::nn::RNNOptions(1, 1).num_layers(0);
ASSERT_THROWS_WITH(RNN(options), "num_layers must be greater than zero");
}
{
auto options = torch::nn::LSTMOptions(1, 0).num_layers(1);
ASSERT_THROWS_WITH(LSTM(options), "hidden_size must be greater than zero");
options = torch::nn::LSTMOptions(1, 1).num_layers(0);
ASSERT_THROWS_WITH(LSTM(options), "num_layers must be greater than zero");
}
{
auto options = torch::nn::GRUOptions(1, 0).num_layers(1);
ASSERT_THROWS_WITH(GRU(options), "hidden_size must be greater than zero");
options = torch::nn::GRUOptions(1, 1).num_layers(0);
ASSERT_THROWS_WITH(GRU(options), "num_layers must be greater than zero");
}
}