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171 lines
8.4 KiB
C++
171 lines
8.4 KiB
C++
// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
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/*
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This is an example illustrating the use of the deep learning tools from the
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dlib C++ Library. In it, we will train the venerable LeNet convolutional
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neural network to recognize hand written digits. The network will take as
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input a small image and classify it as one of the 10 numeric digits between
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0 and 9.
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The specific network we will run is from the paper
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LeCun, Yann, et al. "Gradient-based learning applied to document recognition."
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Proceedings of the IEEE 86.11 (1998): 2278-2324.
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except that we replace the sigmoid non-linearities with rectified linear units.
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These tools will use CUDA and cuDNN to drastically accelerate network
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training and testing. CMake should automatically find them if they are
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installed and configure things appropriately. If not, the program will
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still run but will be much slower to execute.
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*/
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#include <dlib/dnn.h>
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#include <iostream>
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#include <dlib/data_io.h>
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using namespace std;
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using namespace dlib;
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int main(int argc, char** argv) try
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{
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// This example is going to run on the MNIST dataset.
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if (argc != 2)
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{
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cout << "This example needs the MNIST dataset to run!" << endl;
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cout << "You can get MNIST from http://yann.lecun.com/exdb/mnist/" << endl;
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cout << "Download the 4 files that comprise the dataset, decompress them, and" << endl;
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cout << "put them in a folder. Then give that folder as input to this program." << endl;
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return 1;
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}
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// MNIST is broken into two parts, a training set of 60000 images and a test set of
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// 10000 images. Each image is labeled so that we know what hand written digit is
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// depicted. These next statements load the dataset into memory.
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std::vector<matrix<unsigned char>> training_images;
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std::vector<unsigned long> training_labels;
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std::vector<matrix<unsigned char>> testing_images;
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std::vector<unsigned long> testing_labels;
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load_mnist_dataset(argv[1], training_images, training_labels, testing_images, testing_labels);
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// Now let's define the LeNet. Broadly speaking, there are 3 parts to a network
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// definition. The loss layer, a bunch of computational layers, and then an input
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// layer. You can see these components in the network definition below.
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//
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// The input layer here says the network expects to be given matrix<unsigned char>
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// objects as input. In general, you can use any dlib image or matrix type here, or
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// even define your own types by creating custom input layers.
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//
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// Then the middle layers define the computation the network will do to transform the
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// input into whatever we want. Here we run the image through multiple convolutions,
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// ReLU units, max pooling operations, and then finally a fully connected layer that
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// converts the whole thing into just 10 numbers.
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//
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// Finally, the loss layer defines the relationship between the network outputs, our 10
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// numbers, and the labels in our dataset. Since we selected loss_multiclass_log it
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// means we want to do multiclass classification with our network. Moreover, the
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// number of network outputs (i.e. 10) is the number of possible labels. Whichever
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// network output is largest is the predicted label. So for example, if the first
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// network output is largest then the predicted digit is 0, if the last network output
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// is largest then the predicted digit is 9.
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using net_type = loss_multiclass_log<
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fc<10,
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relu<fc<84,
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relu<fc<120,
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max_pool<2,2,2,2,relu<con<16,5,5,1,1,
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max_pool<2,2,2,2,relu<con<6,5,5,1,1,
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input<matrix<unsigned char>>
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>>>>>>>>>>>>;
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// This net_type defines the entire network architecture. For example, the block
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// relu<fc<84,SUBNET>> means we take the output from the subnetwork, pass it through a
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// fully connected layer with 84 outputs, then apply ReLU. Similarly, a block of
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// max_pool<2,2,2,2,relu<con<16,5,5,1,1,SUBNET>>> means we apply 16 convolutions with a
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// 5x5 filter size and 1x1 stride to the output of a subnetwork, then apply ReLU, then
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// perform max pooling with a 2x2 window and 2x2 stride.
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// So with that out of the way, we can make a network instance.
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net_type net;
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// And then train it using the MNIST data. The code below uses mini-batch stochastic
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// gradient descent with an initial learning rate of 0.01 to accomplish this.
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dnn_trainer<net_type> trainer(net);
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trainer.set_learning_rate(0.01);
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trainer.set_min_learning_rate(0.00001);
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trainer.set_mini_batch_size(128);
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trainer.be_verbose();
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// Since DNN training can take a long time, we can ask the trainer to save its state to
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// a file named "mnist_sync" every 20 seconds. This way, if we kill this program and
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// start it again it will begin where it left off rather than restarting the training
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// from scratch. This is because, when the program restarts, this call to
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// set_synchronization_file() will automatically reload the settings from mnist_sync if
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// the file exists.
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trainer.set_synchronization_file("mnist_sync", std::chrono::seconds(20));
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// Finally, this line begins training. By default, it runs SGD with our specified
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// learning rate until the loss stops decreasing. Then it reduces the learning rate by
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// a factor of 10 and continues running until the loss stops decreasing again. It will
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// keep doing this until the learning rate has dropped below the min learning rate
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// defined above or the maximum number of epochs as been executed (defaulted to 10000).
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trainer.train(training_images, training_labels);
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// At this point our net object should have learned how to classify MNIST images. But
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// before we try it out let's save it to disk. Note that, since the trainer has been
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// running images through the network, net will have a bunch of state in it related to
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// the last batch of images it processed (e.g. outputs from each layer). Since we
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// don't care about saving that kind of stuff to disk we can tell the network to forget
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// about that kind of transient data so that our file will be smaller. We do this by
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// "cleaning" the network before saving it.
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net.clean();
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serialize("mnist_network.dat") << net;
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// Now if we later wanted to recall the network from disk we can simply say:
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// deserialize("mnist_network.dat") >> net;
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// Now let's run the training images through the network. This statement runs all the
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// images through it and asks the loss layer to convert the network's raw output into
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// labels. In our case, these labels are the numbers between 0 and 9.
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std::vector<unsigned long> predicted_labels = net(training_images);
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int num_right = 0;
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int num_wrong = 0;
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// And then let's see if it classified them correctly.
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for (size_t i = 0; i < training_images.size(); ++i)
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{
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if (predicted_labels[i] == training_labels[i])
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++num_right;
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else
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++num_wrong;
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}
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cout << "training num_right: " << num_right << endl;
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cout << "training num_wrong: " << num_wrong << endl;
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cout << "training accuracy: " << num_right/(double)(num_right+num_wrong) << endl;
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// Let's also see if the network can correctly classify the testing images. Since
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// MNIST is an easy dataset, we should see at least 99% accuracy.
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predicted_labels = net(testing_images);
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num_right = 0;
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num_wrong = 0;
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for (size_t i = 0; i < testing_images.size(); ++i)
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{
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if (predicted_labels[i] == testing_labels[i])
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++num_right;
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else
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++num_wrong;
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}
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cout << "testing num_right: " << num_right << endl;
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cout << "testing num_wrong: " << num_wrong << endl;
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cout << "testing accuracy: " << num_right/(double)(num_right+num_wrong) << endl;
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// Finally, you can also save network parameters to XML files if you want to do
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// something with the network in another tool. For example, you could use dlib's
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// tools/convert_dlib_nets_to_caffe to convert the network to a caffe model.
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net_to_xml(net, "lenet.xml");
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}
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catch(std::exception& e)
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{
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cout << e.what() << endl;
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}
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