// // Copyright © 2020, 2023 Arm Ltd and Contributors. All rights reserved. // SPDX-License-Identifier: MIT // #pragma once #include "TestUtils.hpp" #include #include #include #include #include #include #include namespace { template std::vector CreateFullyConnectedTfLiteModel(tflite::TensorType tensorType, tflite::ActivationFunctionType activationType, const std::vector & inputTensorShape, const std::vector & weightsTensorShape, const std::vector & biasTensorShape, std::vector & outputTensorShape, std::vector & weightsData, bool constantWeights = true, float quantScale = 1.0f, int quantOffset = 0, float outputQuantScale = 2.0f, int outputQuantOffset = 0) { using namespace tflite; flatbuffers::FlatBufferBuilder flatBufferBuilder; std::array, 5> buffers; buffers[0] = CreateBuffer(flatBufferBuilder); buffers[1] = CreateBuffer(flatBufferBuilder); auto biasTensorType = ::tflite::TensorType_FLOAT32; if (tensorType == ::tflite::TensorType_INT8) { biasTensorType = ::tflite::TensorType_INT32; } if (constantWeights) { buffers[2] = CreateBuffer(flatBufferBuilder, flatBufferBuilder.CreateVector(reinterpret_cast(weightsData.data()), sizeof(T) * weightsData.size())); if (tensorType == ::tflite::TensorType_INT8) { std::vector biasData = { 10 }; buffers[3] = CreateBuffer(flatBufferBuilder, flatBufferBuilder.CreateVector(reinterpret_cast(biasData.data()), sizeof(int32_t) * biasData.size())); } else { std::vector biasData = { 10 }; buffers[3] = CreateBuffer(flatBufferBuilder, flatBufferBuilder.CreateVector(reinterpret_cast(biasData.data()), sizeof(float) * biasData.size())); } } else { buffers[2] = CreateBuffer(flatBufferBuilder); buffers[3] = CreateBuffer(flatBufferBuilder); } buffers[4] = CreateBuffer(flatBufferBuilder); auto quantizationParameters = CreateQuantizationParameters(flatBufferBuilder, 0, 0, flatBufferBuilder.CreateVector({ quantScale }), flatBufferBuilder.CreateVector({ quantOffset })); auto outputQuantizationParameters = CreateQuantizationParameters(flatBufferBuilder, 0, 0, flatBufferBuilder.CreateVector({ outputQuantScale }), flatBufferBuilder.CreateVector({ outputQuantOffset })); std::array, 4> tensors; tensors[0] = CreateTensor(flatBufferBuilder, flatBufferBuilder.CreateVector(inputTensorShape.data(), inputTensorShape.size()), tensorType, 1, flatBufferBuilder.CreateString("input_0"), quantizationParameters); tensors[1] = CreateTensor(flatBufferBuilder, flatBufferBuilder.CreateVector(weightsTensorShape.data(), weightsTensorShape.size()), tensorType, 2, flatBufferBuilder.CreateString("weights"), quantizationParameters); tensors[2] = CreateTensor(flatBufferBuilder, flatBufferBuilder.CreateVector(biasTensorShape.data(), biasTensorShape.size()), biasTensorType, 3, flatBufferBuilder.CreateString("bias"), quantizationParameters); tensors[3] = CreateTensor(flatBufferBuilder, flatBufferBuilder.CreateVector(outputTensorShape.data(), outputTensorShape.size()), tensorType, 4, flatBufferBuilder.CreateString("output"), outputQuantizationParameters); // create operator tflite::BuiltinOptions operatorBuiltinOptionsType = BuiltinOptions_FullyConnectedOptions; flatbuffers::Offset operatorBuiltinOptions = CreateFullyConnectedOptions(flatBufferBuilder, activationType, FullyConnectedOptionsWeightsFormat_DEFAULT, false).Union(); const std::vector operatorInputs{0, 1, 2}; const std::vector operatorOutputs{3}; flatbuffers::Offset fullyConnectedOperator = CreateOperator(flatBufferBuilder, 0, flatBufferBuilder.CreateVector(operatorInputs.data(), operatorInputs.size()), flatBufferBuilder.CreateVector(operatorOutputs.data(), operatorOutputs.size()), operatorBuiltinOptionsType, operatorBuiltinOptions); const std::vector subgraphInputs{0, 1, 2}; const std::vector subgraphOutputs{3}; flatbuffers::Offset subgraph = CreateSubGraph(flatBufferBuilder, flatBufferBuilder.CreateVector(tensors.data(), tensors.size()), flatBufferBuilder.CreateVector(subgraphInputs.data(), subgraphInputs.size()), flatBufferBuilder.CreateVector(subgraphOutputs.data(), subgraphOutputs.size()), flatBufferBuilder.CreateVector(&fullyConnectedOperator, 1)); flatbuffers::Offset modelDescription = flatBufferBuilder.CreateString("ArmnnDelegate: FullyConnected Operator Model"); flatbuffers::Offset operatorCode = CreateOperatorCode(flatBufferBuilder, tflite::BuiltinOperator_FULLY_CONNECTED); flatbuffers::Offset flatbufferModel = CreateModel(flatBufferBuilder, TFLITE_SCHEMA_VERSION, flatBufferBuilder.CreateVector(&operatorCode, 1), flatBufferBuilder.CreateVector(&subgraph, 1), modelDescription, flatBufferBuilder.CreateVector(buffers.data(), buffers.size())); flatBufferBuilder.Finish(flatbufferModel, armnnDelegate::FILE_IDENTIFIER); return std::vector(flatBufferBuilder.GetBufferPointer(), flatBufferBuilder.GetBufferPointer() + flatBufferBuilder.GetSize()); } template void FullyConnectedTest(std::vector& backends, tflite::TensorType tensorType, tflite::ActivationFunctionType activationType, const std::vector & inputTensorShape, const std::vector & weightsTensorShape, const std::vector & biasTensorShape, std::vector & outputTensorShape, std::vector & inputValues, std::vector & expectedOutputValues, std::vector & weightsData, bool constantWeights = true, float quantScale = 1.0f, int quantOffset = 0) { using namespace delegateTestInterpreter; std::vector modelBuffer = CreateFullyConnectedTfLiteModel(tensorType, activationType, inputTensorShape, weightsTensorShape, biasTensorShape, outputTensorShape, weightsData, constantWeights, quantScale, quantOffset); // Setup interpreter with just TFLite Runtime. auto tfLiteInterpreter = DelegateTestInterpreter(modelBuffer); CHECK(tfLiteInterpreter.AllocateTensors() == kTfLiteOk); // Setup interpreter with Arm NN Delegate applied. auto armnnInterpreter = DelegateTestInterpreter(modelBuffer, backends); CHECK(armnnInterpreter.AllocateTensors() == kTfLiteOk); CHECK(tfLiteInterpreter.FillInputTensor(inputValues, 0) == kTfLiteOk); CHECK(armnnInterpreter.FillInputTensor(inputValues, 0) == kTfLiteOk); if (!constantWeights) { CHECK(tfLiteInterpreter.FillInputTensor(weightsData, 1) == kTfLiteOk); CHECK(armnnInterpreter.FillInputTensor(weightsData, 1) == kTfLiteOk); if (tensorType == ::tflite::TensorType_INT8) { std::vector biasData = {10}; CHECK(tfLiteInterpreter.FillInputTensor(biasData, 2) == kTfLiteOk); CHECK(armnnInterpreter.FillInputTensor(biasData, 2) == kTfLiteOk); } else { std::vector biasData = {10}; CHECK(tfLiteInterpreter.FillInputTensor(biasData, 2) == kTfLiteOk); CHECK(armnnInterpreter.FillInputTensor(biasData, 2) == kTfLiteOk); } } CHECK(tfLiteInterpreter.Invoke() == kTfLiteOk); std::vector tfLiteOutputValues = tfLiteInterpreter.GetOutputResult(0); std::vector tfLiteOutputShape = tfLiteInterpreter.GetOutputShape(0); CHECK(armnnInterpreter.Invoke() == kTfLiteOk); std::vector armnnOutputValues = armnnInterpreter.GetOutputResult(0); std::vector armnnOutputShape = armnnInterpreter.GetOutputShape(0); armnnDelegate::CompareOutputData(tfLiteOutputValues, armnnOutputValues, expectedOutputValues); armnnDelegate::CompareOutputShape(tfLiteOutputShape, armnnOutputShape, outputTensorShape); tfLiteInterpreter.Cleanup(); armnnInterpreter.Cleanup(); } } // anonymous namespace