// 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 "lite/operators/unsqueeze_op.h" #include "lite/core/op_registry.h" namespace paddle { namespace lite { namespace operators { static DDim GetOutputShape(const std::vector &unsqz_dims, const DDim &in_dims) { int output_size = in_dims.size() + static_cast(unsqz_dims.size()); int cur_output_size = in_dims.size(); std::vector output_shape(output_size, 0); // Validate Check: rank range. CHECK_LE(output_size, 6) << "The output tensor's rank should be less than 6."; for (int axis : unsqz_dims) { int cur = axis < 0 ? axis + cur_output_size + 1 : axis; // Validate Check: the axis bound CHECK((cur >= 0) && (cur <= cur_output_size)) << "The unsqueeze dims must be within range of current rank."; // Move old axis, and insert new axis for (int i = cur_output_size; i >= cur; --i) { if (output_shape[i] == 1) { // Move axis output_shape[i + 1] = 1; output_shape[i] = 0; } } output_shape[cur] = 1; // Add the output size. cur_output_size++; } // Make output shape for (int in_idx = 0, out_idx = 0; out_idx < output_size; ++out_idx) { if (output_shape[out_idx] == 0) { output_shape[out_idx] = in_dims[in_idx++]; } } return DDim(output_shape); } bool UnsqueezeOp::CheckShape() const { CHECK_OR_FALSE(param_.X); CHECK_OR_FALSE(param_.Out); return true; } bool UnsqueezeOp::InferShape() const { std::vector unsqueeze_dims = param_.axes; DDim in_dims = param_.X->dims(); DDim out_dim = GetOutputShape(unsqueeze_dims, in_dims); param_.Out->Resize(out_dim); return true; } bool UnsqueezeOp::AttachImpl(const cpp::OpDesc &opdesc, lite::Scope *scope) { auto x_var = scope->FindVar(opdesc.Input("X").front()); auto output_var = scope->FindVar(opdesc.Output("Out").front()); CHECK(x_var); CHECK(output_var); param_.X = const_cast(&(x_var->Get())); param_.Out = output_var->GetMutable(); if (opdesc.HasAttr("axes")) { param_.axes = opdesc.GetAttr>("axes"); } CHECK(param_.X) << "Input(X) of UnsqueezeOp should not be null."; CHECK(param_.Out) << "Output(Out) of UnsqueezeOp should not be null."; return true; } bool Unsqueeze2Op::CheckShape() const { UnsqueezeOp::CheckShape(); CHECK_OR_FALSE(param_.XShape); return true; } bool Unsqueeze2Op::InferShape() const { UnsqueezeOp::InferShape(); auto x_dims = param_.X->dims(); std::vector xshape_dims(x_dims.size() + 1, 1); for (size_t i = 0; i < x_dims.size(); i++) { xshape_dims[i + 1] = x_dims[i]; } param_.XShape->Resize(DDim(xshape_dims)); return true; } bool Unsqueeze2Op::AttachImpl(const cpp::OpDesc &opdesc, lite::Scope *scope) { UnsqueezeOp::AttachImpl(opdesc, scope); auto xshape_var = scope->FindVar(opdesc.Output("XShape").front()); CHECK(xshape_var); param_.XShape = xshape_var->GetMutable(); CHECK(param_.XShape) << "Output(XShape) of Unsqueeze2Op should not be null."; return true; } } // namespace operators } // namespace lite } // namespace paddle REGISTER_LITE_OP(unsqueeze, paddle::lite::operators::UnsqueezeOp); REGISTER_LITE_OP(unsqueeze2, paddle::lite::operators::Unsqueeze2Op);