// Copyright (c) 2019 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 #include "lite/api/paddle_use_kernels.h" #include "lite/api/paddle_use_ops.h" #include "lite/core/arena/framework.h" namespace paddle { namespace lite { class SqueezeComputeTester : public arena::TestCase { protected: // common attributes for this op. std::string x_ = "X"; std::string out_ = "Out"; std::vector axes_; DDim dims_; public: SqueezeComputeTester(const Place& place, const std::string& alias, const std::vector& axes, DDim dims) : TestCase(place, alias), axes_(axes), dims_(dims) {} void RunBaseline(Scope* scope) override { const auto* input = scope->FindTensor(x_); CHECK(input); auto* out = scope->NewTensor(out_); CHECK(out); DDim in_dims(dims_); size_t num_squeeze_dims = axes_.size(); int cnt_squeezed_dims = 0; bool should_squeeze[9] = {false}; if (num_squeeze_dims == 0) { for (size_t idx = 0; idx < in_dims.size(); ++idx) { if (in_dims[idx] == 1) { should_squeeze[idx] = true; ++cnt_squeezed_dims; } } } else { for (size_t idx = 0; idx < num_squeeze_dims; ++idx) { int current = axes_[idx] < 0 ? axes_[idx] + in_dims.size() : axes_[idx]; // Check current index, the upper limit has been checked. CHECK_GE(current, 0) << "Invalid axis, the negative axis is out of range."; CHECK_EQ(in_dims[current], 1) << "Invalid axis index, the axis that " "will be squeezed should be equal " "to 1."; if (!(should_squeeze[current])) { ++cnt_squeezed_dims; } should_squeeze[current] = true; } } std::vector output_shape(in_dims.size() - cnt_squeezed_dims, 0); for (size_t in_idx = 0, out_idx = 0; in_idx < in_dims.size(); ++in_idx) { if (!should_squeeze[in_idx]) { output_shape[out_idx++] = in_dims[in_idx]; } } out->Resize(DDim(output_shape)); LOG(INFO) << "baseline out size: " << out->dims(); auto* input_data = input->data(); auto* out_data = out->mutable_data(); memcpy(out_data, input_data, sizeof(float) * dims_.production()); } void PrepareOpDesc(cpp::OpDesc* op_desc) { op_desc->SetType("squeeze"); op_desc->SetInput("X", {x_}); op_desc->SetOutput("Out", {out_}); op_desc->SetAttr("axes", axes_); } void PrepareData() override { std::vector in_data(dims_.production()); for (int i = 0; i < dims_.production(); ++i) { in_data[i] = i; } SetCommonTensor(x_, dims_, in_data.data()); } }; class Squeeze2ComputeTester : public arena::TestCase { protected: // common attributes for this op. std::string x_ = "X"; std::string out_ = "Out"; std::string xshape_ = "XShape"; std::vector axes_; DDim dims_; public: Squeeze2ComputeTester(const Place& place, const std::string& alias, const std::vector& axes, DDim dims) : TestCase(place, alias), axes_(axes), dims_(dims) {} void RunBaseline(Scope* scope) override { const auto* input = scope->FindTensor(x_); CHECK(input); auto* out = scope->NewTensor(out_); CHECK(out); auto* xshape = scope->NewTensor(xshape_); CHECK(xshape); std::vector xshape_sp(dims_.size() + 1, 1); for (size_t i = 0; i < dims_.size(); ++i) { xshape_sp[i + 1] = dims_[i]; } xshape->Resize(DDim(xshape_sp)); DDim in_dims(dims_); size_t num_squeeze_dims = axes_.size(); int cnt_squeezed_dims = 0; bool should_squeeze[9] = {false}; if (num_squeeze_dims == 0) { for (size_t idx = 0; idx < in_dims.size(); ++idx) { if (in_dims[idx] == 1) { should_squeeze[idx] = true; ++cnt_squeezed_dims; } } } else { for (size_t idx = 0; idx < num_squeeze_dims; ++idx) { int current = axes_[idx] < 0 ? axes_[idx] + in_dims.size() : axes_[idx]; // Check current index, the upper limit has been checked. CHECK_GE(current, 0) << "Invalid axis, the negative axis is out of range."; CHECK_EQ(in_dims[current], 1) << "Invalid axis index, the axis that " "will be squeezed should be equal " "to 1."; if (!(should_squeeze[current])) { ++cnt_squeezed_dims; } should_squeeze[current] = true; } } std::vector output_shape(in_dims.size() - cnt_squeezed_dims, 0); for (size_t in_idx = 0, out_idx = 0; in_idx < in_dims.size(); ++in_idx) { if (!should_squeeze[in_idx]) { output_shape[out_idx++] = in_dims[in_idx]; } } out->Resize(DDim(output_shape)); auto* input_data = input->data(); auto* out_data = out->mutable_data(); auto* xshape_data = xshape->mutable_data(); memcpy(out_data, input_data, sizeof(float) * dims_.production()); memcpy(xshape_data, input_data, sizeof(float) * dims_.production()); } void PrepareOpDesc(cpp::OpDesc* op_desc) { op_desc->SetType("squeeze2"); op_desc->SetInput("X", {x_}); op_desc->SetOutput("Out", {out_}); op_desc->SetOutput("XShape", {xshape_}); op_desc->SetAttr("axes", axes_); } void PrepareData() override { std::vector in_data(dims_.production()); for (int i = 0; i < dims_.production(); ++i) { in_data[i] = i; } SetCommonTensor(x_, dims_, in_data.data()); } }; void test_squeeze(Place place) { for (std::vector axes : {std::vector({}), std::vector({0, 2}), std::vector({0, -2})}) { for (int N : {1}) { for (int C : {3}) { for (int H : {1}) { for (int W : {5}) { std::unique_ptr tester(new SqueezeComputeTester( place, "def", axes, DDim({N, C, H, W}))); arena::Arena arena(std::move(tester), place, 2e-5); arena.TestPrecision(); } } } } } } void test_squeeze2(Place place) { for (std::vector axes : {std::vector({}), std::vector({0, 2}), std::vector({0, -2})}) { for (int N : {1}) { for (int C : {3}) { for (int H : {1}) { for (int W : {5}) { std::unique_ptr tester(new Squeeze2ComputeTester( place, "def", axes, DDim({N, C, H, W}))); arena::Arena arena(std::move(tester), place, 2e-5); arena.TestPrecision(); } } } } } } TEST(squeeze, precision) { #ifdef LITE_WITH_X86 Place place(TARGET(kX86)); #endif #ifdef LITE_WITH_ARM Place place(TARGET(kARM)); test_squeeze(place); #endif } TEST(squeeze2, precision) { #ifdef LITE_WITH_X86 Place place(TARGET(kX86)); #endif #ifdef LITE_WITH_ARM Place place(TARGET(kARM)); test_squeeze2(place); #endif } } // namespace lite } // namespace paddle