Implementing Device Training Based On C++ Interface

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MindSpore has unified the end-to-side cloud inference API. If you want to continue to use the MindSpore Lite independent API for training, you can refer to here.

Overview

This tutorial is based on LeNet training example code and demonstrates training a LeNet on an Android device .

The completed training procedure is as follows:

  1. Constructing your training model based on MindSpore Lite Architecture and Export it into MindIR model file.

  2. Converting MindIR model file to the MS ToD model file by using MindSpore Lite Converter tool.

  3. Loading MS model file and executing model training by calling MindSpore Lite training API.

Details will be told after environment deployed and model training by running prepared shell scripts.

Environment Preparing

Ubuntu 18.04 64-bit operating system on x86 platform is recommended.

Environment Requirements

  • The compilation environment supports Linux x86_64 only. Ubuntu 18.04.02LTS is recommended.

  • Software dependency

    • GCC >= 7.3.0

    • CMake >= 3.18.3

    • Git >= 2.28.0

    • Android_NDK >= r20

      • Configure environment variables: export ANDROID_NDK=NDK path.

Downloading the Dataset

The MNIST dataset used in this example consists of 10 classes of 28 x 28 pixels grayscale images. It has a training set of 60,000 examples, and a test set of 10,000 examples.

Download the MNIST dataset at http://yann.lecun.com/exdb/mnist/. This page provides four download links of dataset files. The first two links are training dataset and training label, while the last two links are test dataset and test label.

Download and decompress the files to /PATH/MNIST_Data/train and /PATH/MNIST_Data/test separately.

The directory structure is as follows:

./MNIST_Data/
├── test
│   ├── t10k-images-idx3-ubyte
│   └── t10k-labels-idx1-ubyte
└── train
    ├── train-images-idx3-ubyte
    └── train-labels-idx1-ubyte

Installing MindSpore

MindSpore can be installed by source code or using pip.

Downloading and Installing MindSpore Lite

Use git to clone the source code, the command in Linux is as follows:

git clone https://gitee.com/mindspore/mindspore.git -b {version}
cd ./mindspore

The mindspore/lite/examples/train_lenet_cpp directory relative to the MindSpore Lite source code contains this demo’s source code. The version is consistent with that of MindSpore Lite Download Page below. If -b the master is specified, you need to obtain the corresponding installation package through compile from source.

Go to the MindSpore Lite Download Page to download the mindspore-lite-{version}-linux-x64.tar.gz and mindspore-lite-{version}-android-aarch64.tar.gz. The mindspore-lite-{version}-linux-x64.tar.gz is the MindSpore Lite install package for x86 platform, it contains the converter tool converter_lite, this demo uses it to converte MIDIR model to .ms which is supported by MindSpore Lite; The mindspore-lite-{version}-android-aarch64.tar.gz is the MindSpore Lite install package for Android, it contains training runtime library libmindspore-lite.so, this demo uses it to train model. Then put the files to the output directory relative to MindSpore Lite source code (if there is no output directory,you should create it).

Suppose these packags are downloaded in /Downloads directory, Linux commands for operations above is as follows:

mkdir output
cp /Downloads/mindspore-lite-{version}-linux-x64.tar.gz output/mindspore-lite-{version}-linux-x64.tar.gz
cp /Downloads/mindspore-lite-{version}-android-aarch64.tar.gz output/mindspore-lite-{version}-android-aarch64.tar.gz

You can also compile from source to generate the training package for x86 platform mindspore-lite-{version}-linux-x64.tar.gz and for Andorid platform mindspore-lite-{version}-android-aarch64.tar.gz. These packages will directly generated in output directory and you should make sure that in the output directory both the two packages exist.

Connecting Android Device

Prepare an Android device and connect it properly to the working computer via USB. The phone needs to turn on “USB debugging mode”, and Huawei phone usually turns on “USB debugging mode” in Settings->System and Updates->Developer Options->USB debugging.

This example uses the adb tool to communicate with an Android device to remotely control the mobile device from a work computer. If you don’t have the adb tool installed, you can run apt install adb.

Model Training and Evaluation

Enter the target directory and run the training bash script. The Linux command is as follows:

cd mindspore/lite/examples/train_lenet_cpp
bash prepare_and_run.sh -D /PATH/MNIST_Data -t arm64

/PATH/MNIST_Data is the absolute mnist dataset path in your machine, -t arm64 represents that we will train and run the model on an Android device, if the work computer is connected to multiple mobile devices, you can use -i devices_id to specify the running device.

The script prepare_and_run.sh has done the following works:

  1. Export the lenet_tod.mindir model file.

  2. Calling the converter tool in the last section and convert the MINDIR file to the ms file.

  3. Push the lenet.ms model file, MNIST dataset and the related library files to your Android device.

  4. Train, save and infer the model.

The model will be trained on your device and print training loss and accuracy value every epoch. The trained model will be saved as ‘lenet_tod.ms’ file. The 10 epochs training result of lenet is shown below (the classification accuracy varies in devices):

======Training Locally=========
1.100:  Loss is 1.19449
1.200:  Loss is 0.477986
1.300:  Loss is 0.440362
1.400:  Loss is 0.165605
1.500:  Loss is 0.368853
1.600:  Loss is 0.179764
1.700:  Loss is 0.173386
1.800:  Loss is 0.0767713
1.900:  Loss is 0.493
1.1000: Loss is 0.460352
1.1100: Loss is 0.262044
1.1200: Loss is 0.222022
1.1300: Loss is 0.058006
1.1400: Loss is 0.0794117
1.1500: Loss is 0.0241433
1.1600: Loss is 0.127109
1.1700: Loss is 0.0557566
1.1800: Loss is 0.0698758
Epoch (1):      Loss is 0.384778
Epoch (1):      Training Accuracy is 0.8702
2.100:  Loss is 0.0538642
2.200:  Loss is 0.444504
2.300:  Loss is 0.0806976
2.400:  Loss is 0.0495807
2.500:  Loss is 0.178903
2.600:  Loss is 0.265705
2.700:  Loss is 0.0933796
2.800:  Loss is 0.0880472
2.900:  Loss is 0.0480734
2.1000: Loss is 0.241272
2.1100: Loss is 0.0920451
2.1200: Loss is 0.371406
2.1300: Loss is 0.0365746
2.1400: Loss is 0.0784372
2.1500: Loss is 0.207537
2.1600: Loss is 0.442626
2.1700: Loss is 0.0814725
2.1800: Loss is 0.12081
Epoch (2):      Loss is 0.176118
Epoch (2):      Training Accuracy is 0.94415
......
10.1000:        Loss is 0.0984653
10.1100:        Loss is 0.189702
10.1200:        Loss is 0.0896037
10.1300:        Loss is 0.0138191
10.1400:        Loss is 0.0152357
10.1500:        Loss is 0.12785
10.1600:        Loss is 0.026495
10.1700:        Loss is 0.436495
10.1800:        Loss is 0.157564
Epoch (5):     Loss is 0.102652
Epoch (5):     Training Accuracy is 0.96805
AvgRunTime: 18980.5 ms
Total allocation: 125829120
Accuracy is 0.965244

===Evaluating trained Model=====
Total allocation: 20971520
Accuracy is 0.965244

===Running Inference Model=====
There are 1 input tensors with sizes:
tensor 0: shape is [32 32 32 1]
There are 1 output tensors with sizes:
tensor 0: shape is [32 10]
The predicted classes are:
4, 0, 2, 8, 9, 4, 5, 6, 3, 5, 2, 1, 4, 6, 8, 0, 5, 7, 3, 5, 8, 3, 4, 1, 9, 8, 7, 3, 0, 2, 3, 6,

If the Android device is not available on your hand, you could also exectute bash prepare_and_run.sh -D /PATH/MNIST_Data -t x86 and run it on the x86 platform.

Demo Project Details

Demo Project Folder Structure

train_lenet_cpp/
  ├── model
  │   ├── lenet_export.py
  │   ├── prepare_model.sh
  │   └── train_utils.py
  │
  ├── scripts
  │   ├── batch_of32.dat
  │   ├── eval.sh
  │   ├── infer.sh
  │   └── train.sh
  │
  ├── src
  │   ├── inference.cc
  │   ├── net_runner.cc
  │   ├── net_runner.h
  │   └── utils.h
  │
  ├── Makefile
  ├── README.md
  ├── README_CN.md
  └── prepare_and_run.sh

Model Exporting

Whether it is an off-the-shelf prepared model, or a custom written model, the model needs to be exported to a .mindir file. Here we use the already-implemented LeNet model.

This summary is exported using the MindSpore cloud side feature. For more information, please refer to MindSpore Tutorial.

import numpy as np
import mindspore as ms
from lenet import LeNet5
from train_utils import TrainWrap

n = LeNet5()
n.set_train()
ms.set_context(mode=ms.GRAPH_MODE, device_target="CPU", save_graphs=False)

Then define the input and label tensor sizes:

BATCH_SIZE = 32
x = ms.Tensor(np.ones((BATCH_SIZE, 1, 32, 32)), ms.float32)
label = ms.Tensor(np.zeros([BATCH_SIZE]).astype(np.int32))
net = TrainWrap(n)

Define the loss function, network trainable parameters, optimizer, and enable single-step training, implemented by the TrainWrap function.

from mindspore import nn
import mindspore as ms

def train_wrap(net, loss_fn=None, optimizer=None, weights=None):
    """
    train_wrap
    """
    if loss_fn is None:
        loss_fn = nn.SoftmaxCrossEntropyWithLogits(reduction='mean', sparse=True)
    loss_net = nn.WithLossCell(net, loss_fn)
    loss_net.set_train()
    if weights is None:
        weights = ms.ParameterTuple(net.trainable_params())
    if optimizer is None:
        optimizer = nn.Adam(weights, learning_rate=0.003, beta1=0.9, beta2=0.999, eps=1e-5, use_locking=False, use_nesterov=False, weight_decay=4e-5, loss_scale=1.0)
    train_net = nn.TrainOneStepCell(loss_net, optimizer)
    return train_net

Wrapping the network with a loss layer and an optimizer and export it to a MindIR file. TrainWrap is provided in the example as:

ms.export(net, x, label, file_name="lenet_tod", file_format='MINDIR')
print("finished exporting")

If the output finished exporting indicates that the export was successful, the generated lenet_tod.mindir file is in the ... /train_lenet_cpp/model directory. See lenet_export.py and train_utils.py for the complete code.

Model Transferring

Convert lenet_tod.mindir to ms model file using MindSpore Lite converter_lite tool in prepare_model.sh by executing the command as follows:

./converter_lite --fmk=MINDIR --trainModel=true --modelFile=lenet_tod.mindir --outputFile=lenet_tod

After successful conversion, the lenet_tod.ms model file is generated in the current directory.

See training model conversion for more usage.

Model Training

The model training progress is in net_runner.cc.

The main code continues as follows:

int NetRunner::Main() {
  // Load model and create session
  InitAndFigureInputs();
  // initialize the dataset
  InitDB();
  // Execute the training
  TrainLoop();
  // Evaluate the trained model
  CalculateAccuracy();

  if (epochs_ > 0) {
    auto trained_fn = ms_file_.substr(0, ms_file_.find_last_of('.')) + "_trained.ms";
    mindspore::Serialization::ExportModel(*model_, mindspore::kMindIR, trained_fn, mindspore::kNoQuant, false);
    trained_fn = ms_file_.substr(0, ms_file_.find_last_of('.')) + "_infer.ms";
    mindspore::Serialization::ExportModel(*model_, mindspore::kMindIR, trained_fn, mindspore::kNoQuant, true);
  }
  return 0;
}
  1. Loading Model

    InitAndFigureInputs creates the TrainSession instance from the .ms file, then sets the input tensors indices for the .ms model.

    void NetRunner::InitAndFigureInputs() {
      auto context = std::make_shared<mindspore::Context>();
      auto cpu_context = std::make_shared<mindspore::CPUDeviceInfo>();
      cpu_context->SetEnableFP16(enable_fp16_);
      context->MutableDeviceInfo().push_back(cpu_context);
    
      graph_ = new mindspore::Graph();
      auto status = mindspore::Serialization::Load(ms_file_, mindspore::kMindIR, graph_);
      if (status != mindspore::kSuccess) {
        std::cout << "Error " << status << " during serialization of graph " << ms_file_;
        MS_ASSERT(status != mindspore::kSuccess);
      }
    
      auto cfg = std::make_shared<mindspore::TrainCfg>();
      if (enable_fp16_) {
        cfg.get()->optimization_level_ = mindspore::kO2;
      }
    
      model_ = new mindspore::Model();
      status = model_->Build(mindspore::GraphCell(*graph_), context, cfg);
      if (status != mindspore::kSuccess) {
        std::cout << "Error " << status << " during build of model " << ms_file_;
        MS_ASSERT(status != mindspore::kSuccess);
      }
    
      acc_metrics_ = std::shared_ptr<AccuracyMetrics>(new AccuracyMetrics);
      model_->InitMetrics({acc_metrics_.get()});
    
      auto inputs = model_->GetInputs();
      MS_ASSERT(inputs.size() >= 1);
      auto nhwc_input_dims = inputs.at(0).Shape();
    
      batch_size_ = nhwc_input_dims.at(0);
      h_ = nhwc_input_dims.at(1);
      w_ = nhwc_input_dims.at(2);
    }
    
  2. Dataset Processing

    InitDB initializes the MNIST dataset and loads it into the memory. MindData has provided the data preprocessing API, the user could refer to the C++ API Docs for more details.

    int NetRunner::InitDB() {
      train_ds_ = Mnist(data_dir_ + "/train", "all", std::make_shared<SequentialSampler>(0, 0));
    
      TypeCast typecast_f(mindspore::DataType::kNumberTypeFloat32);
      Resize resize({h_, w_});
      train_ds_ = train_ds_->Map({&resize, &typecast_f}, {"image"});
    
      TypeCast typecast(mindspore::DataType::kNumberTypeInt32);
      train_ds_ = train_ds_->Map({&typecast}, {"label"});
    
      train_ds_ = train_ds_->Batch(batch_size_, true);
    
      if (verbose_) {
        std::cout << "DatasetSize is " << train_ds_->GetDatasetSize() << std::endl;
      }
      if (train_ds_->GetDatasetSize() == 0) {
        std::cout << "No relevant data was found in " << data_dir_ << std::endl;
        MS_ASSERT(train_ds_->GetDatasetSize() != 0);
      }
      return 0;
    }
    
  3. Execute Training

    First create pointers to an array of training callback class objects (e.g., LRScheduler, LossMonitor, TrainAccuracy, and CkptSaver); then call the Train function of the TrainLoop class to set the model into training mode; and finally iterate through the execution of functions corresponding to the callback class objects during training and outputs the training log. CkptSaver saves the CheckPoint model for the current session according to the set training step value. The CheckPoint model contains the updated weights, so that the CheckPoint model can be loaded directly when the application crashes or the device malfunctions, and training can continue.

    int NetRunner::TrainLoop() {
      mindspore::LossMonitor lm(100);
      mindspore::TrainAccuracy am(1);
    
      mindspore::CkptSaver cs(kSaveEpochs, std::string("lenet"));
      Rescaler rescale(kScalePoint);
      Measurement measure(epochs_);
    
      if (virtual_batch_ > 0) {
        model_->Train(epochs_, train_ds_, {&rescale, &lm, &cs, &measure});
      } else {
        struct mindspore::StepLRLambda step_lr_lambda(1, kGammaFactor);
        mindspore::LRScheduler step_lr_sched(mindspore::StepLRLambda, static_cast<void *>(&step_lr_lambda), 1);
        model_->Train(epochs_, train_ds_, {&rescale, &lm, &cs, &am, &step_lr_sched, &measure});
      }
    
      return 0;
    }
    
  4. Execute Evaluating

    To eval the model accuracy, the CalculateAccuracy method is being called. Within which, the model is switched to Eval mode, and the method runs a cycle of test tensors through the trained network to measure the current accuracy rate.

    float NetRunner::CalculateAccuracy(int max_tests) {
      test_ds_ = Mnist(data_dir_ + "/test", "all");
      TypeCast typecast_f(mindspore::DataType::kNumberTypeFloat32);
      Resize resize({h_, w_});
      test_ds_ = test_ds_->Map({&resize, &typecast_f}, {"image"});
    
      TypeCast typecast(mindspore::DataType::kNumberTypeInt32);
      test_ds_ = test_ds_->Map({&typecast}, {"label"});
      test_ds_ = test_ds_->Batch(batch_size_, true);
    
      model_->Evaluate(test_ds_, {});
      std::cout << "Accuracy is " << acc_metrics_->Eval() << std::endl;
    
      return 0.0;
    }