/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserve. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ #include "paddle/operators/recurrent_op.h" #include #include #include "paddle/framework/ddim.h" #include "paddle/framework/op_registry.h" #include "paddle/framework/operator.h" #include "paddle/framework/tensor.h" #include "paddle/operators/net_op.h" namespace paddle { namespace operators { using framework::make_ddim; using framework::DDim; using framework::Tensor; using framework::Variable; using framework::Scope; using framework::OpRegistry; class RecurrentOpTest : public ::testing::Test { protected: virtual void SetUp() override { CreateGlobalVariables(); CreateStepNet(); CreateRNNOp(); } virtual void TearDown() override {} void CreateGlobalVariables() { // create input, and init content LOG(INFO) << "create global variable x"; for (auto inlink : std::vector{"x", "x0", "x1", "h"}) { Variable* x = scope_.NewVar(inlink); DDim dims = make_ddim(std::vector{ 10 /*sent size*/, 20 /*batch size*/, 30 /*input dim*/}); x->GetMutable()->mutable_data(dims, platform::CPUPlace()); } // create output alias just for test for (auto inlink : std::vector{"h@alias"}) { Variable* x = scope_.NewVar(inlink); DDim dims = make_ddim(std::vector{20 /*batch size*/, 30 /*input dim*/}); x->GetMutable()->mutable_data(dims, platform::CPUPlace()); } LOG(INFO) << "create global variable w"; Variable* w = scope_.NewVar("rnn/w"); w->GetMutable()->mutable_data( make_ddim(std::vector{30, 30}), platform::CPUPlace()); for (auto boot : std::vector{"h_boot"}) { LOG(INFO) << "create global variable " << boot; Variable* h_boot = scope_.NewVar(boot); h_boot->GetMutable()->mutable_data( make_ddim(std::vector{20 /*batch size*/, 30 /*input dim*/}), platform::CPUPlace()); } LOG(INFO) << "create variable step_scopes"; scope_.NewVar("step_scopes"); LOG(INFO) << "create variable h"; scope_.NewVar("h"); } void CreateRNNOp() { framework::OpDesc op_desc; op_desc.set_type("recurrent_op"); // inlinks 0 op_desc.add_inputs("x"); op_desc.add_inputs("x0"); op_desc.add_inputs("x1"); // boot_memories 3 op_desc.add_inputs("h_boot"); // step net 5 op_desc.add_inputs("step_net"); // outlinks 6 op_desc.add_outputs("h"); // step scopes 7 op_desc.add_outputs("step_scopes"); auto _input_format = std::vector{ 0, // in_link 3, // memories 4 // step_net }; auto input_format = op_desc.add_attrs(); input_format->set_name("input_format"); input_format->set_type(paddle::framework::AttrType::INTS); for (auto i : _input_format) { input_format->add_ints(i); } auto output_format = op_desc.add_attrs(); output_format->set_name("output_format"); output_format->set_type(paddle::framework::AttrType::INTS); for (auto i : std::vector{0, 1, 2}) { output_format->add_ints(i); } auto inlink_alias = op_desc.add_attrs(); inlink_alias->set_name("inlink_alias"); inlink_alias->set_type(paddle::framework::AttrType::STRINGS); auto outlink_alias = op_desc.add_attrs(); outlink_alias->set_name("outlink_alias"); outlink_alias->set_type(paddle::framework::AttrType::STRINGS); auto pre_memories = op_desc.add_attrs(); pre_memories->set_name("pre_memories"); pre_memories->set_type(paddle::framework::AttrType::STRINGS); auto memories = op_desc.add_attrs(); memories->set_name("memories"); memories->set_type(paddle::framework::AttrType::STRINGS); // create inlink_alias for (const auto& item : std::vector{"x@alias", "x0@alias", "x1@alias"}) { inlink_alias->add_strings(item); } // pre memories for (const auto& item : std::vector{"rnn/h@pre"}) { pre_memories->add_strings(item); } // memories for (const auto& item : std::vector{"rnn/h"}) { memories->add_strings(item); } // output alias for (const auto& item : std::vector{"h@alias"}) { outlink_alias->add_strings(item); } rnn_op_ = OpRegistry::CreateOp(op_desc); LOG(INFO) << "rnn_op finish init"; } void CreateStepNet() { LOG(INFO) << "create variable step_net"; Variable* var = scope_.NewVar("step_net"); auto net = var->GetMutable(); net->AddOp( OpRegistry::CreateOp("mul", {"rnn/h@pre", "rnn/w"}, {"rnn/s"}, {})); net->AddOp( OpRegistry::CreateOp("add_two", {"x@alias", "rnn/s"}, {"rnn/h"}, {})); net->CompleteAddOp(); } // father scope Scope scope_; std::shared_ptr rnn_op_; }; TEST_F(RecurrentOpTest, Run) { platform::CPUDeviceContext ctx; rnn_op_->InferShape(scope_); rnn_op_->Run(scope_, ctx); } class RecurrentGradientAlgorithmTest : public ::testing::Test { protected: virtual void SetUp() override { CreateGlobalVariables(); CreateStepScopes(); CreateStepNet(); CreateRNNGradientAlgorithm(); // segment inputs SegmentInputs(); // link forward memories LinkeMemories(); } virtual void TearDown() override {} void CreateGlobalVariables() { // inputs: x LOG(INFO) << "create global variable x"; Variable* x = scope_.NewVar("x"); DDim dims = make_ddim({10 /*sent size*/, 20 /*batch size*/, 30 /*input dim*/}); x->GetMutable()->mutable_data(dims, platform::CPUPlace()); // inputs: h_boot LOG(INFO) << "create global variable h_boot"; Variable* h_boot = scope_.NewVar("h_boot"); h_boot->GetMutable()->mutable_data( make_ddim({20 /*batch size*/, 30 /*input dim*/}), platform::CPUPlace()); // inputs: w LOG(INFO) << "create global variable w"; Variable* w = scope_.NewVar("rnn/w"); w->GetMutable()->mutable_data(make_ddim({30, 30}), platform::CPUPlace()); // inputs: h_grad LOG(INFO) << "create variable h_grad"; Variable* dh = scope_.NewVar("h_grad"); dh->GetMutable()->mutable_data(make_ddim({10, 20, 30}), platform::CPUPlace()); // inputs: step_scopes LOG(INFO) << "create variable step_scopes"; scope_.NewVar("step_scopes"); // inputs: step_net LOG(INFO) << "create variable step_net"; scope_.NewVar("step_net"); // outputs: w_grad LOG(INFO) << "create global variable w_grad"; scope_.NewVar("rnn/w_grad"); // outputs: x_grad LOG(INFO) << "create global variable x_grad"; scope_.NewVar("x_grad"); // outputs: h_boot_grad LOG(INFO) << "create global variable h_boot_grad"; scope_.NewVar("h_boot_grad"); } void CreateStepScopes() { auto step_scopes = scope_.FindVar("step_scopes")->GetMutable>(); for (int i = 0; i < 10; ++i) { auto& scope = scope_.NewScope(); auto pre_t = scope.NewVar("rnn/pre_h")->GetMutable(); pre_t->mutable_data({20, 30}, platform::CPUPlace()); auto tensor = scope.NewVar("rnn/h")->GetMutable(); tensor->mutable_data({20, 30}, platform::CPUPlace()); // for unit test of ConcatOutputs auto xg = scope.NewVar("rnn/x_grad")->GetMutable(); xg->mutable_data({20, 30}, platform::CPUPlace()); step_scopes->emplace_back(&scope); } // last time step auto g = (*step_scopes)[9]->NewVar("rnn/h_pre_grad")->GetMutable(); g->mutable_data({20, 30}, platform::CPUPlace()); } void CreateRNNGradientAlgorithm() { std::unique_ptr arg(new rnn::Argument()); arg->step_net = "step_net"; arg->step_scopes = "step_scopes"; rnn::Link inlink; inlink.external = "h_grad"; inlink.internal = "rnn/h_grad"; arg->inlinks = std::vector{inlink}; rnn::Link outlink; outlink.external = "x_grad"; outlink.internal = "rnn/x_grad"; arg->outlinks = std::vector{outlink}; rnn::MemoryAttr mem_attr; mem_attr.pre_var = "rnn/h_pre_grad"; mem_attr.var = "rnn/h_grad"; mem_attr.boot_var = "h_boot_grad"; arg->memories = std::vector{mem_attr}; rnn_grad_algo_.Init(std::move(arg)); } void CreateStepNet() { LOG(INFO) << "create variable step_net"; Variable* var = scope_.NewVar("step_net"); auto net = var->GetMutable(); net->AddOp(OpRegistry::CreateOp("mul", {"rnn/h_pre", "rnn/w", "rnn/s_grad"}, {"rnn/h_pre_grad", "rnn/w_grad"}, {})); net->AddOp(OpRegistry::CreateOp("add_two", {"rnn/h_grad"}, {"rnn/x_grad", "rnn/s_grad"}, {})); net->CompleteAddOp(); } void SegmentInputs() { LOG(INFO) << "segment inputs"; std::vector inlinks = {"x"}; std::vector inlinks_alias = {"rnn/x"}; rnn::Link inlink; inlink.external = "x"; inlink.internal = "rnn/x"; auto step_scopes = scope_.FindVar("step_scopes")->GetMutable>(); rnn::SegmentInputs(*step_scopes, std::vector{inlink}, 10, true /*infer_shape_mode*/); } void LinkeMemories() { LOG(INFO) << "link memories"; rnn::MemoryAttr mem_attr; mem_attr.pre_var = "rnn/h_pre"; mem_attr.var = "rnn/h"; mem_attr.boot_var = "boot_h"; std::vector memories; memories.push_back(mem_attr); auto step_scopes = scope_.FindVar("step_scopes")->GetMutable>(); for (int i = 1; i < 10; ++i) { rnn::LinkMemories(*step_scopes, memories, i, -1, true /*infer_shape_mode*/); } } Scope scope_; RecurrentGradientAlgorithm rnn_grad_algo_; }; // TEST_F(RecurrentGradientAlgorithmTest, Run) { // platform::CPUDeviceContext ctx; // rnn_grad_algo_.Run(scope_, ctx); // } } // namespace operators } // namespace paddle TEST(RecurrentOp, LinkMemories) { using namespace paddle::framework; using namespace paddle::platform; using namespace paddle::operators; // create and init step scopes size_t len = 10; std::vector step_scopes; for (size_t i = 0; i < len; ++i) { auto scope = new Scope(); scope->NewVar("pre_h"); auto tensor = scope->NewVar("h")->GetMutable(); float* data = tensor->mutable_data({15, 20}, CPUPlace()); for (size_t j = 0; j < 15 * 20; ++j) { data[j] = rand() * (1. / (double)RAND_MAX); } step_scopes.push_back(scope); } // create MemoryAttr rnn::MemoryAttr mem_attr; mem_attr.pre_var = "pre_h"; mem_attr.var = "h"; mem_attr.boot_var = "boot_h"; std::vector memories; memories.push_back(mem_attr); for (size_t i = 1; i < len; ++i) { rnn::LinkMemories(step_scopes, memories, i, -1, false /*infer_shape_mode*/); } // check for (size_t i = 0; i < len - 1; ++i) { const float* a = step_scopes[i]->FindVar("h")->GetMutable()->data(); const float* b = step_scopes[i + 1] ->FindVar("pre_h") ->GetMutable() ->data(); for (size_t j = 0; j < 15 * 20; ++j) { ASSERT_FLOAT_EQ(a[j], b[j]); } } for (int i = len - 2; i >= 0; --i) { rnn::LinkMemories(step_scopes, memories, i, 1, false /*infer_shape_mode*/); } // check for (int i = len - 2; i >= 0; --i) { const float* a = step_scopes[i]->FindVar("pre_h")->GetMutable()->data(); const float* b = step_scopes[i + 1]->FindVar("h")->GetMutable()->data(); for (size_t j = 0; j < 15 * 20; ++j) { ASSERT_FLOAT_EQ(a[j], b[j]); } } for (auto s : step_scopes) { delete s; } } USE_OP(add_two); USE_OP(mul); USE_OP_WITHOUT_KERNEL(recurrent_op);