/** * Copyright 2017 The Android Open Source Project * * 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 "run_tflite.h" #include "tensorflow/lite/delegates/nnapi/nnapi_delegate.h" #include "tensorflow/lite/kernels/register.h" #include #include #include #include #define LOG_TAG "NN_BENCHMARK" #define FATAL(fmt, ...) \ do { \ __android_log_print(ANDROID_LOG_FATAL, LOG_TAG, fmt, ##__VA_ARGS__); \ assert(false); \ } while (0) namespace { long long currentTimeInUsec() { timeval tv; gettimeofday(&tv, NULL); return ((tv.tv_sec * 1000000L) + tv.tv_usec); } // Workaround for build systems that make difficult to pick the correct NDK API // level. NDK tracing methods are dynamically loaded from libandroid.so. typedef void* (*fp_ATrace_beginSection)(const char* sectionName); typedef void* (*fp_ATrace_endSection)(); struct TraceFunc { fp_ATrace_beginSection ATrace_beginSection; fp_ATrace_endSection ATrace_endSection; }; TraceFunc setupTraceFunc() { void* lib = dlopen("libandroid.so", RTLD_NOW | RTLD_LOCAL); if (lib == nullptr) { FATAL("unable to open libandroid.so"); } return { reinterpret_cast( dlsym(lib, "ATrace_beginSection")), reinterpret_cast(dlsym(lib, "ATrace_endSection"))}; } static TraceFunc kTraceFunc{setupTraceFunc()}; } // namespace BenchmarkModel* BenchmarkModel::create(const char* modelfile, bool use_nnapi, bool enable_intermediate_tensors_dump, const char* nnapi_device_name) { BenchmarkModel* model = new BenchmarkModel(); if (!model->init(modelfile, use_nnapi, enable_intermediate_tensors_dump, nnapi_device_name)) { delete model; return nullptr; } return model; } bool BenchmarkModel::init(const char* modelfile, bool use_nnapi, bool enable_intermediate_tensors_dump, const char* nnapi_device_name) { __android_log_print(ANDROID_LOG_INFO, LOG_TAG, "BenchmarkModel %s", modelfile); // Memory map the model. NOTE this needs lifetime greater than or equal // to interpreter context. mTfliteModel = tflite::FlatBufferModel::BuildFromFile(modelfile); if (!mTfliteModel) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Failed to load model %s", modelfile); return false; } tflite::ops::builtin::BuiltinOpResolver resolver; tflite::InterpreterBuilder(*mTfliteModel, resolver)(&mTfliteInterpreter); if (!mTfliteInterpreter) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Failed to create TFlite interpreter"); return false; } if (enable_intermediate_tensors_dump) { // Make output of every op a model output. This way we will be able to // fetch each intermediate tensor when running with delegates. std::vector outputs; for (size_t node = 0; node < mTfliteInterpreter->nodes_size(); ++node) { auto node_outputs = mTfliteInterpreter->node_and_registration(node)->first.outputs; outputs.insert(outputs.end(), node_outputs->data, node_outputs->data + node_outputs->size); } mTfliteInterpreter->SetOutputs(outputs); } // Allow Fp16 precision for all models mTfliteInterpreter->SetAllowFp16PrecisionForFp32(true); if (use_nnapi) { if (nnapi_device_name != nullptr) { __android_log_print(ANDROID_LOG_INFO, LOG_TAG, "Running NNAPI on device %s", nnapi_device_name); } if (mTfliteInterpreter->ModifyGraphWithDelegate( tflite::NnApiDelegate(nnapi_device_name)) != kTfLiteOk) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Failed to initialize NNAPI Delegate"); return false; } } return true; } BenchmarkModel::BenchmarkModel() {} BenchmarkModel::~BenchmarkModel() {} bool BenchmarkModel::setInput(const uint8_t* dataPtr, size_t length) { int input = mTfliteInterpreter->inputs()[0]; auto* input_tensor = mTfliteInterpreter->tensor(input); switch (input_tensor->type) { case kTfLiteFloat32: case kTfLiteUInt8: { void* raw = input_tensor->data.raw; memcpy(raw, dataPtr, length); break; } default: __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Input tensor type not supported"); return false; } return true; } void BenchmarkModel::saveInferenceOutput(InferenceResult* result, int output_index) { int output = mTfliteInterpreter->outputs()[output_index]; auto* output_tensor = mTfliteInterpreter->tensor(output); auto& sink = result->inferenceOutputs[output_index]; sink.insert(sink.end(), output_tensor->data.uint8, output_tensor->data.uint8 + output_tensor->bytes); } void BenchmarkModel::getOutputError(const uint8_t* expected_data, size_t length, InferenceResult* result, int output_index) { int output = mTfliteInterpreter->outputs()[output_index]; auto* output_tensor = mTfliteInterpreter->tensor(output); if (output_tensor->bytes != length) { FATAL("Wrong size of output tensor, expected %zu, is %zu", output_tensor->bytes, length); } size_t elements_count = 0; float err_sum = 0.0; float max_error = 0.0; switch (output_tensor->type) { case kTfLiteUInt8: { uint8_t* output_raw = mTfliteInterpreter->typed_tensor(output); elements_count = output_tensor->bytes; for (size_t i = 0; i < output_tensor->bytes; ++i) { float err = ((float)output_raw[i]) - ((float)expected_data[i]); if (err > max_error) max_error = err; err_sum += err * err; } break; } case kTfLiteFloat32: { const float* expected = reinterpret_cast(expected_data); float* output_raw = mTfliteInterpreter->typed_tensor(output); elements_count = output_tensor->bytes / sizeof(float); for (size_t i = 0; i < output_tensor->bytes / sizeof(float); ++i) { float err = output_raw[i] - expected[i]; if (err > max_error) max_error = err; err_sum += err * err; } break; } default: FATAL("Output sensor type %d not supported", output_tensor->type); } result->meanSquareErrors[output_index] = err_sum / elements_count; result->maxSingleErrors[output_index] = max_error; } bool BenchmarkModel::resizeInputTensors(std::vector shape) { // The benchmark only expects single input tensor, hardcoded as 0. int input = mTfliteInterpreter->inputs()[0]; mTfliteInterpreter->ResizeInputTensor(input, shape); if (mTfliteInterpreter->AllocateTensors() != kTfLiteOk) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Failed to allocate tensors!"); return false; } return true; } bool BenchmarkModel::runInference() { auto status = mTfliteInterpreter->Invoke(); if (status != kTfLiteOk) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Failed to invoke: %d!", (int)status); return false; } return true; } bool BenchmarkModel::resetStates() { auto status = mTfliteInterpreter->ResetVariableTensors(); if (status != kTfLiteOk) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Failed to reset variable tensors: %d!", (int)status); return false; } return true; } bool BenchmarkModel::benchmark( const std::vector& inOutData, int seqInferencesMaxCount, float timeout, int flags, std::vector* results) { if (inOutData.empty()) { FATAL("Input/output vector is empty"); } float inferenceTotal = 0.0; for (int seqInferenceIndex = 0; seqInferenceIndex < seqInferencesMaxCount; ++seqInferenceIndex) { resetStates(); const int inputOutputSequenceIndex = seqInferenceIndex % inOutData.size(); const InferenceInOutSequence& seq = inOutData[inputOutputSequenceIndex]; for (int i = 0; i < seq.size(); ++i) { const InferenceInOut& data = seq[i]; // For NNAPI systrace usage documentation, see // frameworks/ml/nn/common/include/Tracing.h. kTraceFunc.ATrace_beginSection("[NN_LA_PE]BenchmarkModel::benchmark"); kTraceFunc.ATrace_beginSection("[NN_LA_PIO]BenchmarkModel::input"); if (data.input) { setInput(data.input, data.input_size); } else { int input = mTfliteInterpreter->inputs()[0]; auto* input_tensor = mTfliteInterpreter->tensor(input); if (!data.createInput((uint8_t*)input_tensor->data.raw, input_tensor->bytes)) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Input creation %d failed", i); return false; } } kTraceFunc.ATrace_endSection(); long long startTime = currentTimeInUsec(); const bool success = runInference(); kTraceFunc.ATrace_endSection(); long long endTime = currentTimeInUsec(); if (!success) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Inference %d failed", i); return false; } float inferenceTime = static_cast(endTime - startTime) / 1000000.0f; size_t outputsCount = mTfliteInterpreter->outputs().size(); InferenceResult result{ inferenceTime, {}, {}, {}, inputOutputSequenceIndex, i}; result.meanSquareErrors.resize(outputsCount); result.maxSingleErrors.resize(outputsCount); result.inferenceOutputs.resize(outputsCount); if ((flags & FLAG_IGNORE_GOLDEN_OUTPUT) == 0) { if (outputsCount != data.outputs.size()) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Golden/actual outputs (%zu/%zu) count mismatch", data.outputs.size(), outputsCount); return false; } for (int j = 0; j < outputsCount; ++j) { getOutputError(data.outputs[j].ptr, data.outputs[j].size, &result, j); } } if ((flags & FLAG_DISCARD_INFERENCE_OUTPUT) == 0) { for (int j = 0; j < outputsCount; ++j) { saveInferenceOutput(&result, j); } } results->push_back(result); inferenceTotal += inferenceTime; } // Timeout? if (timeout > 0.001 && inferenceTotal > timeout) { return true; } } return true; } bool BenchmarkModel::dumpAllLayers( const char* path, const std::vector& inOutData) { if (inOutData.empty()) { FATAL("Input/output vector is empty"); } for (int seqInferenceIndex = 0; seqInferenceIndex < inOutData.size(); ++seqInferenceIndex) { resetStates(); const InferenceInOutSequence& seq = inOutData[seqInferenceIndex]; for (int i = 0; i < seq.size(); ++i) { const InferenceInOut& data = seq[i]; setInput(data.input, data.input_size); const bool success = runInference(); if (!success) { __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, "Inference %d failed", i); return false; } for (int tensor = 0; tensor < mTfliteInterpreter->tensors_size(); ++tensor) { auto* output_tensor = mTfliteInterpreter->tensor(tensor); if (output_tensor->data.raw == nullptr) { continue; } char fullpath[1024]; snprintf(fullpath, 1024, "%s/dump_%.3d_seq_%.3d_tensor_%.3d", path, seqInferenceIndex, i, tensor); FILE* f = fopen(fullpath, "wb"); fwrite(output_tensor->data.raw, output_tensor->bytes, 1, f); fclose(f); } } } return true; }