/* Copyright (c) 2016 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 "gtest/gtest.h" #include "paddle/fluid/framework/op_info.h" #include "paddle/fluid/framework/op_registry.h" #include "paddle/fluid/framework/operator.h" #include "paddle/fluid/platform/init.h" namespace paddle { namespace framework { static int op_run_num = 0; class OpWithoutKernelTest : public OperatorBase { public: OpWithoutKernelTest(const std::string& type, const VariableNameMap& inputs, const VariableNameMap& outputs, const AttributeMap& attrs) : OperatorBase(type, inputs, outputs, attrs), x(1) {} private: void RunImpl(const Scope& scope, const platform::Place& place) const override { ++op_run_num; ASSERT_EQ(static_cast(inputs_.size()), 1); ASSERT_EQ(static_cast(outputs_.size()), 1); ASSERT_EQ(scope.FindVar(inputs_.at("input")[0]), nullptr); ASSERT_EQ(x, 1); ASSERT_NE(scope.FindVar(outputs_.at("output")[0]), nullptr); } public: int x{0}; }; class OpWithoutKernelCheckerMaker : public OpProtoAndCheckerMaker { public: void Make() { AddInput("input", "input of test op"); AddOutput("output", "output of test op"); AddAttr("scale", "scale of cosine op"); AddAttr("kernel_sub_type", "kernels with different implementations.") .SetDefault(0); AddComment("This is test op"); } }; } // namespace framework } // namespace paddle static void BuildVar(const std::string& param_name, std::initializer_list arguments, paddle::framework::proto::OpDesc::Var* var) { var->set_parameter(param_name); for (auto& arg_name : arguments) { *var->mutable_arguments()->Add() = arg_name; } } REGISTER_OP_WITHOUT_GRADIENT(test_operator, paddle::framework::OpWithoutKernelTest, paddle::framework::OpWithoutKernelCheckerMaker); TEST(OperatorBase, all) { paddle::framework::InitDevices(true); paddle::framework::proto::OpDesc op_desc; op_desc.set_type("test_operator"); BuildVar("input", {"IN1"}, op_desc.add_inputs()); BuildVar("output", {"OUT1"}, op_desc.add_outputs()); auto attr = op_desc.mutable_attrs()->Add(); attr->set_name("scale"); attr->set_type(paddle::framework::proto::AttrType::FLOAT); attr->set_f(3.14); paddle::platform::CPUPlace cpu_place; paddle::framework::Scope scope; auto op = paddle::framework::OpRegistry::CreateOp(op_desc); scope.Var("OUT1"); ASSERT_EQ(paddle::framework::op_run_num, 0); op->Run(scope, cpu_place); ASSERT_EQ(paddle::framework::op_run_num, 1); } namespace paddle { namespace framework { static int special_type_value = 1; class OpKernelTestProtoAndCheckerMaker : public OpProtoAndCheckerMaker { public: void Make() { AddInput("x", "input of test op"); AddOutput("y", "output of test op"); AddAttr("scale", "scale of cosine op") .SetDefault(1.0) .GreaterThan(0.0); AddAttr("kernel_sub_type", "kernels with different implementations.") .SetDefault(0); AddComment("This is test op"); } }; static int cpu_kernel_run_num = 0; static int cpu_kernel2_run_num = 0; class OpWithKernelTest : public OperatorWithKernel { public: using OperatorWithKernel::OperatorWithKernel; protected: void InferShape(framework::InferShapeContext* ctx) const override {} OpKernelType GetExpectedKernelType( const ExecutionContext& ctx) const override { int sub_type = ctx.Attr("kernel_sub_type"); return OpKernelType(proto::VarType::FP32, ctx.GetPlace(), framework::DataLayout::kAnyLayout, framework::LibraryType::kPlain, sub_type); } }; template class CPUKernelTest : public OpKernel { public: void Compute(const ExecutionContext& ctx) const { std::cout << ctx.op().DebugString() << std::endl; cpu_kernel_run_num++; ASSERT_EQ(ctx.op().Input("x"), "IN1"); ASSERT_EQ(ctx.op().Output("y"), "OUT1"); } }; template class CPUKernel2Test : public OpKernel { public: void Compute(const ExecutionContext& ctx) const { std::cout << ctx.op().DebugString() << std::endl; cpu_kernel2_run_num++; ASSERT_EQ(ctx.op().Input("x"), "IN1"); ASSERT_EQ(ctx.op().Output("y"), "OUT1"); } }; class OpKernelTestMultiInputsProtoAndCheckerMaker : public OpProtoAndCheckerMaker { public: void Make() { AddInput("xs", "inputs of test op").AsDuplicable(); AddInput("k", "input of test op"); AddOutput("ys", "outputs of test op").AsDuplicable(); AddAttr("scale", "scale of cosine op") .SetDefault(1.0) .GreaterThan(0.0); AddAttr("kernel_sub_type", "kernels with different implementations.") .SetDefault(0); AddComment("This is test op"); } }; class CPUKernalMultiInputsTest : public OpKernel { public: void Compute(const ExecutionContext& ctx) const { auto xs = ctx.op().Inputs("xs"); ASSERT_EQ(xs.size(), 3UL); ASSERT_EQ(xs[0], "x0"); ASSERT_EQ(xs[1], "x1"); ASSERT_EQ(xs[2], "x2"); auto inVar0 = ctx.MultiInputVar("xs"); ASSERT_EQ(inVar0.size(), 3U); auto intVar1 = ctx.InputVar("k"); ASSERT_NE(intVar1, nullptr); auto outVar0 = ctx.MultiOutputVar("ys"); ASSERT_EQ(outVar0.size(), 2U); auto inTensor0 = ctx.MultiInput("xs"); ASSERT_EQ(inTensor0.size(), 3U); auto intTensor1 = ctx.Input("k"); ASSERT_NE(intTensor1, nullptr); auto outTensor0 = ctx.MultiOutput("ys"); ASSERT_EQ(outTensor0.size(), 2U); auto k = ctx.op().Input("k"); ASSERT_EQ(k, "k0"); auto ys = ctx.op().Outputs("ys"); ASSERT_EQ(ys.size(), 2UL); ASSERT_EQ(ys[0], "y0"); ASSERT_EQ(ys[1], "y1"); } }; } // namespace framework } // namespace paddle REGISTER_OP_WITHOUT_GRADIENT( op_with_kernel, paddle::framework::OpWithKernelTest, paddle::framework::OpKernelTestProtoAndCheckerMaker); REGISTER_OP_CPU_KERNEL(op_with_kernel, paddle::framework::CPUKernelTest); REGISTER_OP_KERNEL_WITH_CUSTOM_TYPE( op_with_kernel, CPU, paddle::platform::CPUPlace, MY_SPECIAL_NAME, paddle::framework::special_type_value, paddle::framework::CPUKernel2Test); // test with single input TEST(OpKernel, all) { paddle::framework::InitDevices(true); paddle::framework::proto::OpDesc op_desc; op_desc.set_type("op_with_kernel"); BuildVar("x", {"IN1"}, op_desc.add_inputs()); BuildVar("y", {"OUT1"}, op_desc.add_outputs()); auto attr = op_desc.mutable_attrs()->Add(); attr->set_name("scale"); attr->set_type(paddle::framework::proto::AttrType::FLOAT); attr->set_f(3.14); paddle::platform::CPUPlace cpu_place; paddle::framework::Scope scope; auto op = paddle::framework::OpRegistry::CreateOp(op_desc); ASSERT_EQ(paddle::framework::cpu_kernel_run_num, 0); op->Run(scope, cpu_place); // kerne_sub_type = 0, hence cpu_kernel is called, cpu_kernel2 is not called. ASSERT_EQ(paddle::framework::cpu_kernel_run_num, 1); ASSERT_EQ(paddle::framework::cpu_kernel2_run_num, 0); attr = op_desc.mutable_attrs()->Add(); attr->set_name("kernel_sub_type"); attr->set_type(paddle::framework::proto::AttrType::INT); attr->set_i(1); auto op2 = paddle::framework::OpRegistry::CreateOp(op_desc); op2->Run(scope, cpu_place); // kerne_sub_type = 1, hence cpu_kernel2 is called, cpu_kernel is not called. ASSERT_EQ(paddle::framework::cpu_kernel_run_num, 1); ASSERT_EQ(paddle::framework::cpu_kernel2_run_num, 1); } REGISTER_OP_WITHOUT_GRADIENT( op_multi_inputs_with_kernel, paddle::framework::OpWithKernelTest, paddle::framework::OpKernelTestMultiInputsProtoAndCheckerMaker); REGISTER_OP_CPU_KERNEL(op_multi_inputs_with_kernel, paddle::framework::CPUKernalMultiInputsTest); // test with multi inputs TEST(OpKernel, multi_inputs) { paddle::framework::InitDevices(true); paddle::framework::proto::OpDesc op_desc; op_desc.set_type("op_multi_inputs_with_kernel"); BuildVar("xs", {"x0", "x1", "x2"}, op_desc.add_inputs()); BuildVar("k", {"k0"}, op_desc.add_inputs()); BuildVar("ys", {"y0", "y1"}, op_desc.add_outputs()); auto attr = op_desc.mutable_attrs()->Add(); attr->set_name("scale"); attr->set_type(paddle::framework::proto::AttrType::FLOAT); attr->set_f(3.14); paddle::platform::CPUPlace cpu_place; paddle::framework::Scope scope; scope.Var("x0")->GetMutable(); scope.Var("x1")->GetMutable(); scope.Var("x2")->GetMutable(); scope.Var("k0")->GetMutable(); scope.Var("y0")->GetMutable(); scope.Var("y1")->GetMutable(); auto op = paddle::framework::OpRegistry::CreateOp(op_desc); op->Run(scope, cpu_place); } TEST(VarNameTest, all) { std::string var_name("X"); std::string grad_var_name = paddle::framework::GradVarName(var_name); ASSERT_EQ(grad_var_name, "X@GRAD"); std::string original_var_name = paddle::framework::GradOriginalVarName(grad_var_name); ASSERT_EQ(original_var_name, "X"); original_var_name = paddle::framework::GradOriginalVarName(original_var_name); ASSERT_EQ(original_var_name, "X"); std::string var_name_2("XYZ"); grad_var_name = paddle::framework::GradVarName(var_name_2); ASSERT_EQ(grad_var_name, "XYZ@GRAD"); original_var_name = paddle::framework::GradOriginalVarName(grad_var_name); ASSERT_EQ(original_var_name, "XYZ"); original_var_name = paddle::framework::GradOriginalVarName(original_var_name); ASSERT_EQ(original_var_name, "XYZ"); std::string var_name_3(""); grad_var_name = paddle::framework::GradVarName(var_name_3); ASSERT_EQ(grad_var_name, "@GRAD"); original_var_name = paddle::framework::GradOriginalVarName(grad_var_name); ASSERT_EQ(original_var_name, ""); original_var_name = paddle::framework::GradOriginalVarName(original_var_name); ASSERT_EQ(original_var_name, ""); }