// 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/kernels/apu/bridges/utility.h" #include #include "lite/kernels/apu/bridges/graph.h" namespace paddle { namespace lite { namespace subgraph { namespace apu { bool HasInputArg(const OpInfo* op_info, const Scope* scope, const std::string& argname) { auto iarg_names = op_info->input_argnames(); if (std::find(iarg_names.begin(), iarg_names.end(), argname) != iarg_names.end()) { auto inputs = op_info->Input(argname); if (inputs.empty()) { return false; } auto var_name = inputs.front(); auto var = scope->FindVar(var_name); return var != nullptr; } else { return false; } } void insert_transpose_node(void* ctx, const std::string& input_name, const std::string& output_name, std::vector input_shape, std::vector output_shape, std::vector axis, float scale, int32_t zeroPoint) { int neuron_errCode; auto graph = static_cast(ctx); auto model = graph->model(); // Add input NeuronOperandType inType; inType.type = NEURON_TENSOR_QUANT8_ASYMM; inType.scale = scale; inType.zeroPoint = zeroPoint; inType.dimensionCount = input_shape.size(); inType.dimensions = &input_shape[0]; std::shared_ptr input_node = nullptr; if (graph->Has(input_name)) { VLOG(3) << "Has " << input_name; input_node = graph->Get(input_name); } else { neuron_errCode = NeuronModel_addOperand(model, &inType); // input if (NEURON_NO_ERROR != neuron_errCode) { LOG(WARNING) << "Insert transpose op fail!"; return; } VLOG(3) << "Add " << input_name; input_node = graph->Add(input_name, input_shape); } // Add perm NeuronOperandType permsType; permsType.type = NEURON_TENSOR_INT32; permsType.dimensionCount = 1; uint32_t dims_perms[1] = {4}; permsType.dimensions = dims_perms; neuron_errCode = NeuronModel_addOperand(model, &permsType); // perm if (NEURON_NO_ERROR != neuron_errCode) { LOG(WARNING) << "Insert transpose op fail!"; return; } std::shared_ptr perms_node = nullptr; perms_node = graph->Add(input_name + "_perms", {4}); VLOG(3) << "axis :" << axis[0] << ":" << axis[1] << ":" << axis[2] << ":" << axis[3]; // &axis[0], sizeof(int32_t) * axis.size()); neuron_errCode = NeuronModel_setOperandValue( model, perms_node->index(), &axis[0], sizeof(int32_t) * axis.size()); if (NEURON_NO_ERROR != neuron_errCode) { LOG(WARNING) << "Insert transpose op fail!"; return; } // Add output NeuronOperandType outType; outType.type = NEURON_TENSOR_QUANT8_ASYMM; outType.scale = scale; outType.zeroPoint = zeroPoint; outType.dimensionCount = output_shape.size(); outType.dimensions = &output_shape[0]; NeuronModel_addOperand(model, &outType); // output std::shared_ptr output_node = nullptr; output_node = graph->Add(output_name, output_shape); std::vector addInIndex = {input_node->index(), // 0: input perms_node->index()}; // 1: perm std::vector addOutIndex = {output_node->index()}; neuron_errCode = NeuronModel_addOperation(model, NEURON_TRANSPOSE, addInIndex.size(), &addInIndex[0], addOutIndex.size(), &addOutIndex[0]); if (NEURON_NO_ERROR != neuron_errCode) { LOG(WARNING) << "Insert transpose op fail!"; } } void transpose(const int8_t* input_data, uint8_t* output_data, std::vector input_shape, std::vector axis) { int old_index = -1; int new_index = -1; int dim[4] = {0}; std::vector shape = input_shape; VLOG(3) << input_shape[0] << ":" << input_shape[1] << ":" << input_shape[2] << ":" << input_shape[3]; VLOG(3) << axis[0] << ":" << axis[1] << ":" << axis[2] << ":" << axis[3]; for (dim[0] = 0; dim[0] < input_shape[0]; dim[0]++) { for (dim[1] = 0; dim[1] < input_shape[1]; dim[1]++) { for (dim[2] = 0; dim[2] < input_shape[2]; dim[2]++) { for (dim[3] = 0; dim[3] < input_shape[3]; dim[3]++) { old_index = dim[0] * shape[1] * shape[2] * shape[3] + dim[1] * shape[2] * shape[3] + dim[2] * shape[3] + dim[3]; new_index = dim[axis[0]] * shape[axis[1]] * shape[axis[2]] * shape[axis[3]] + dim[axis[1]] * shape[axis[2]] * shape[axis[3]] + dim[axis[2]] * shape[axis[3]] + dim[axis[3]]; output_data[new_index] = input_data[old_index]; } } } } } void transposeAsym(const int8_t* input_data, uint8_t* output_data, std::vector input_shape, std::vector axis) { int old_index = -1; int new_index = -1; int dim[4] = {0}; std::vector shape = input_shape; VLOG(3) << input_shape[0] << ":" << input_shape[1] << ":" << input_shape[2] << ":" << input_shape[3]; VLOG(3) << axis[0] << ":" << axis[1] << ":" << axis[2] << ":" << axis[3]; for (dim[0] = 0; dim[0] < input_shape[0]; dim[0]++) { for (dim[1] = 0; dim[1] < input_shape[1]; dim[1]++) { for (dim[2] = 0; dim[2] < input_shape[2]; dim[2]++) { for (dim[3] = 0; dim[3] < input_shape[3]; dim[3]++) { old_index = dim[0] * shape[1] * shape[2] * shape[3] + dim[1] * shape[2] * shape[3] + dim[2] * shape[3] + dim[3]; new_index = dim[axis[0]] * shape[axis[1]] * shape[axis[2]] * shape[axis[3]] + dim[axis[1]] * shape[axis[2]] * shape[axis[3]] + dim[axis[2]] * shape[axis[3]] + dim[axis[3]]; output_data[new_index] = input_data[old_index] + 128; // per layer } } } } } void float2int32(const float* bias_data, float input_scale, std::vector weight_scale, int32_t* int32_bias_data) { for (int i = 0; i < weight_scale.size(); i++) { int32_bias_data[i] = bias_data[i] / (input_scale * weight_scale[i]); } } } // namespace apu } // namespace subgraph } // namespace lite } // namespace paddle