/* Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved. 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/fluid/framework/program_processing.h" #include "gtest/gtest-message.h" #include "gtest/gtest-test-part.h" #include "gtest/gtest.h" #include "gtest/gtest_pred_impl.h" namespace paddle { namespace framework { TEST(ProgramDesc, GetInputsOutputsInBlock) { ProgramDesc program; auto* global_block = program.MutableBlock(0); auto* mul_1_x = global_block->Var("Mul_1_X"); mul_1_x->SetType(proto::VarType::LOD_TENSOR); mul_1_x->SetLoDLevel(0); mul_1_x->SetDataType(proto::VarType::FP32); mul_1_x->SetShape({1000, 784}); auto* mul_1_y = global_block->Var("Mul_1_Y"); mul_1_y->SetType(proto::VarType::LOD_TENSOR); mul_1_y->SetLoDLevel(0); mul_1_y->SetDataType(proto::VarType::FP32); mul_1_y->SetShape({784, 100}); auto* mul_1_out = global_block->Var("Mul_1_Out"); mul_1_out->SetType(proto::VarType::LOD_TENSOR); auto* mul_op_1 = global_block->AppendOp(); mul_op_1->SetType("mul"); mul_op_1->SetInput("X", {mul_1_x->Name()}); mul_op_1->SetInput("Y", {mul_1_y->Name()}); mul_op_1->SetOutput("Y", {mul_1_out->Name()}); // building cond op such as less_than auto* less_than_op_1 = global_block->AppendOp(); less_than_op_1->SetType("less_than"); auto* less_than_1_x = global_block->Var("Less_than_1_X"); less_than_1_x->SetType(proto::VarType::LOD_TENSOR); less_than_1_x->SetLoDLevel(0); less_than_1_x->SetDataType(proto::VarType::FP32); less_than_1_x->SetShape({1}); auto* less_than_1_y = global_block->Var("Less_than_1_Y"); less_than_1_y->SetType(proto::VarType::LOD_TENSOR); less_than_1_y->SetLoDLevel(0); less_than_1_y->SetDataType(proto::VarType::FP32); less_than_1_y->SetShape({1}); auto* less_than_1_out = global_block->Var("Less_than_1_Out"); less_than_1_out->SetType(proto::VarType::BOOL); less_than_op_1->SetInput("X", {less_than_1_x->Name()}); less_than_op_1->SetInput("Y", {less_than_1_y->Name()}); less_than_op_1->SetOutput("Out", {less_than_1_out->Name()}); BlockDesc* sub_block = program.AppendBlock(*global_block); std::vector sub_blocks; sub_blocks.push_back(sub_block); BlockDesc* sub_block2 = program.AppendBlock(*sub_block); // for testing nested case. sub_blocks.push_back(sub_block2); // building while op in sub_block auto* while_op = global_block->AppendOp(); while_op->SetType("while"); while_op->SetAttr("sub_block", sub_blocks[0]); auto* while_x = global_block->Var("While_X"); while_x->SetType(proto::VarType::LOD_TENSOR); while_x->SetLoDLevel(0); while_x->SetDataType(proto::VarType::FP32); while_x->SetShape({1}); while_op->SetInput("kX", {while_x->Name()}); while_op->SetInput("kCondition", {less_than_1_out->Name()}); auto* while_out = global_block->Var("While_Out"); while_out->SetType(proto::VarType::LOD_TENSOR); while_out->SetLoDLevel(0); while_out->SetDataType(proto::VarType::FP32); while_out->SetShape({1}); auto* steps = global_block->Var("StepScopes"); while_op->SetOutput("kOutputs", {while_out->Name()}); while_op->SetOutput("kStepScopes", {steps->Name()}); auto* mul_2_x = global_block->Var("Mul_2_X"); mul_2_x->SetType(proto::VarType::LOD_TENSOR); mul_2_x->SetLoDLevel(0); mul_2_x->SetDataType(proto::VarType::FP32); mul_2_x->SetShape({1000, 784}); auto* mul_2_y = global_block->Var("Mul_2_Y"); mul_2_y->SetType(proto::VarType::LOD_TENSOR); mul_2_y->SetLoDLevel(0); mul_2_y->SetDataType(proto::VarType::FP32); mul_2_y->SetShape({784, 100}); auto* mul_op_2 = sub_blocks[0]->AppendOp(); mul_op_2->SetType("mul"); mul_op_2->SetInput("X", {mul_2_x->Name()}); mul_op_2->SetInput("Y", {mul_2_y->Name()}); auto* mul_2_out = global_block->Var("Mul_2_Out"); mul_2_out->SetType(proto::VarType::LOD_TENSOR); mul_op_2->SetOutput("Y", {mul_2_out->Name()}); auto* less_than_op_2 = sub_blocks[0]->AppendOp(); less_than_op_2->SetType("less_than"); auto* less_than_2_x = global_block->Var("Less_than_2_X"); less_than_2_x->SetType(proto::VarType::LOD_TENSOR); less_than_2_x->SetLoDLevel(0); less_than_2_x->SetDataType(proto::VarType::FP32); less_than_2_x->SetShape({1}); auto* less_than_2_y = global_block->Var("Less_than_2_Y"); less_than_2_y->SetType(proto::VarType::LOD_TENSOR); less_than_2_y->SetLoDLevel(0); less_than_2_y->SetDataType(proto::VarType::FP32); less_than_2_y->SetShape({1}); less_than_op_2->SetInput("X", {less_than_2_x->Name()}); less_than_op_2->SetInput("Y", {less_than_2_y->Name()}); auto* less_than_2_out = global_block->Var("Less_than_2_Out"); less_than_2_out->SetType(proto::VarType::BOOL); less_than_op_2->SetOutput("Out", {less_than_2_out->Name()}); auto* cond_op = sub_blocks[0]->AppendOp(); cond_op->SetType("conditional_block"); cond_op->SetAttr("sub_block", sub_blocks[1]); auto* cond_x = sub_blocks[0]->Var("Cond_X"); cond_x->SetType(proto::VarType::LOD_TENSOR); cond_x->SetLoDLevel(0); cond_x->SetDataType(proto::VarType::FP32); cond_x->SetShape({1}); cond_op->SetInput("kInputs", {cond_x->Name()}); cond_op->SetInput("kCondition", {less_than_2_out->Name()}); auto* cond_out = sub_blocks[0]->Var("Cond_Out"); cond_out->SetType(proto::VarType::LOD_TENSOR); cond_out->SetLoDLevel(0); cond_out->SetDataType(proto::VarType::FP32); cond_out->SetShape({1}); auto* scope = sub_blocks[0]->Var("Scope"); scope->SetType(proto::VarType::STEP_SCOPES); cond_op->SetOutput("kOutputs", {cond_out->Name()}); cond_op->SetOutput("kScope", {scope->Name()}); auto* mul_3_x = global_block->Var("Mul_3_X"); mul_3_x->SetType(proto::VarType::LOD_TENSOR); mul_3_x->SetLoDLevel(0); mul_3_x->SetDataType(proto::VarType::FP32); mul_3_x->SetShape({1000, 784}); auto* mul_3_y = global_block->Var("Mul_3_Y"); mul_3_y->SetType(proto::VarType::LOD_TENSOR); mul_3_y->SetLoDLevel(0); mul_3_y->SetDataType(proto::VarType::FP32); mul_3_y->SetShape({784, 100}); auto* mul_3_out = global_block->Var("Mul_3_Out"); mul_3_out->SetType(proto::VarType::LOD_TENSOR); auto* mul_op_3 = sub_blocks[1]->AppendOp(); mul_op_3->SetType("mul"); mul_op_3->SetInput("X", {mul_3_x->Name()}); mul_op_3->SetInput("Y", {mul_3_y->Name()}); mul_op_3->SetOutput("Y", {mul_3_out->Name()}); ProgramProcessor program_processor; std::set inner_inputs; std::set inner_outputs; program_processor.GetInputsOutputsInBlock(*sub_blocks[0], &inner_inputs, &inner_outputs); VLOG(3) << "inner_inputs().size():" << inner_inputs.size(); VLOG(3) << "inner_outputs().size():" << inner_outputs.size(); ASSERT_EQ(5UL, inner_inputs.size()); ASSERT_EQ(2UL, inner_outputs.size()); // varible "Less_than_2_Out" is the input of cond_op, it also is the output of // less_than_op. std::set inner_inputs_{"Less_than_2_Out", "Less_than_2_X", "Less_than_2_Y", "Mul_2_X", "Mul_2_Y"}; std::set inner_outputs_{"Less_than_2_Out", "Mul_2_Out"}; ASSERT_EQ(inner_inputs, inner_inputs_); ASSERT_EQ(inner_outputs, inner_outputs_); // Test AddDepToBlockOp VLOG(3) << "Before AddDependency, while op's input kX size:" << while_op->Input("kX").size(); VLOG(3) << "Before AddDependency, while op's output kOutPuts size:" << while_op->Output("kOutputs").size(); program_processor.AddDepToBlockOp(*global_block); VLOG(3) << "After AddDependency, while op's input kX size:" << while_op->Input("kX").size(); VLOG(3) << "After AddDependency, while op's output kOutPuts size:" << while_op->Output("kOutputs").size(); ASSERT_EQ(8UL, while_op->Input("kX").size()); ASSERT_EQ(4UL, while_op->Output("kOutputs").size()); std::vector var_input_vec = { "While_X", "Less_than_2_Out", "Less_than_2_X", "Less_than_2_Y", "Mul_2_X", "Mul_2_Y", "Mul_3_X", "Mul_3_Y"}; std::vector var_output_vec = {"While_Out", "Less_than_2_Out", "Mul_2_Out", "Mul_3_Out"}; ASSERT_EQ(var_input_vec, while_op->Input("kX")); ASSERT_EQ(var_output_vec, while_op->Output("kOutputs")); } } // namespace framework } // namespace paddle