dlib/examples/dnn_inception_ex.cpp

// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
/*
    This is an example illustrating the use of the deep learning tools from the
    dlib C++ Library.  I'm assuming you have already read the dnn_mnist_ex.cpp
    example.  So in this example program I'm going to go over a number of more
    advanced parts of the API, including:
        - Using grp layer for constructing inception layer

    Inception layer is a kind of NN architecture for running sevelar convolution types
    on the same input area and joining all convolution results into one output.
    For further reading refer http://www.cs.unc.edu/~wliu/papers/GoogLeNet.pdf
*/


#include <dlib/dnn.h>
#include <iostream>
#include <dlib/data_io.h>

using namespace std;
using namespace dlib;

// Inception layer has some different convolutions inside
// Here we define blocks as convolutions with different kernel size that we will use in
// inception layer block.
template <typename SUBNET> using block_a1 = relu<con<4,1,1,1,1,SUBNET>>;
template <typename SUBNET> using block_a2 = relu<con<4,3,3,1,1,relu<con<4,1,1,1,1,SUBNET>>>>;
template <typename SUBNET> using block_a3 = relu<con<4,5,5,1,1,relu<con<4,1,1,1,1,SUBNET>>>>;
template <typename SUBNET> using block_a4 = relu<con<4,1,1,1,1,max_pool<3,3,1,1,SUBNET>>>;

// Here is inception layer definition. It uses different blocks to process input and returns combined output
template <typename SUBNET> using incept_a = inception4<block_a1,block_a2,block_a3,block_a4, SUBNET>;

// Network can have inception layers of different structure.
// Here are blocks with different convolutions
template <typename SUBNET> using block_b1 = relu<con<8,1,1,1,1,SUBNET>>;
template <typename SUBNET> using block_b2 = relu<con<8,3,3,1,1,SUBNET>>;
template <typename SUBNET> using block_b3 = relu<con<8,1,1,1,1,max_pool<3,3,1,1,SUBNET>>>;

// Here is inception layer definition. It uses different blocks to process input and returns combined output
template <typename SUBNET> using incept_b = inception3<block_b1,block_b2,block_b3,SUBNET>;

// and then the network type is
using net_type = loss_multiclass_log<
        fc<10,
        relu<fc<32,
        max_pool<2,2,2,2,incept_b<
        max_pool<2,2,2,2,incept_a<
        input<matrix<unsigned char>>
        >>>>>>>>;

int main(int argc, char** argv) try
{
    // This example is going to run on the MNIST dataset.
    if (argc != 2)
    {
        cout << "This example needs the MNIST dataset to run!" << endl;
        cout << "You can get MNIST from http://yann.lecun.com/exdb/mnist/" << endl;
        cout << "Download the 4 files that comprise the dataset, decompress them, and" << endl;
        cout << "put them in a folder.  Then give that folder as input to this program." << endl;
        return 1;
    }


    std::vector<matrix<unsigned char>> training_images;
    std::vector<unsigned long>         training_labels;
    std::vector<matrix<unsigned char>> testing_images;
    std::vector<unsigned long>         testing_labels;
    load_mnist_dataset(argv[1], training_images, training_labels, testing_images, testing_labels);


    // The rest of the sample is identical to dnn_minst_ex
    // Create network of predefined type.
    net_type net;

    // And then train it using the MNIST data.  The code below uses mini-batch stochastic
    // gradient descent with an initial learning rate of 0.01 to accomplish this.
    dnn_trainer<net_type> trainer(net);
    trainer.set_learning_rate(0.01);
    trainer.set_min_learning_rate(0.00001);
    trainer.set_mini_batch_size(128);
    trainer.be_verbose();
    // Since DNN training can take a long time, we can ask the trainer to save its state to
    // a file named "mnist_sync" every 20 seconds.  This way, if we kill this program and
    // start it again it will begin where it left off rather than restarting the training
    // from scratch.  This is because, when the program restarts, this call to
    // set_synchronization_file() will automatically reload the settings from mnist_sync if
    // the file exists.
    trainer.set_synchronization_file("inception_sync", std::chrono::seconds(20));
    // Finally, this line begins training.  By default, it runs SGD with our specified
    // learning rate until the loss stops decreasing.  Then it reduces the learning rate by
    // a factor of 10 and continues running until the loss stops decreasing again.  It will
    // keep doing this until the learning rate has dropped below the min learning rate
    // defined above or the maximum number of epochs as been executed (defaulted to 10000).
    trainer.train(training_images, training_labels);

    // At this point our net object should have learned how to classify MNIST images.  But
    // before we try it out let's save it to disk.  Note that, since the trainer has been
    // running images through the network, net will have a bunch of state in it related to
    // the last batch of images it processed (e.g. outputs from each layer).  Since we
    // don't care about saving that kind of stuff to disk we can tell the network to forget
    // about that kind of transient data so that our file will be smaller.  We do this by
    // "cleaning" the network before saving it.
    net.clean();
    serialize("mnist_network_inception.dat") << net;
    // Now if we later wanted to recall the network from disk we can simply say:
    // deserialize("mnist_network.dat") >> net;


    // Now let's run the training images through the network.  This statement runs all the
    // images through it and asks the loss layer to convert the network's raw output into
    // labels.  In our case, these labels are the numbers between 0 and 9.
    std::vector<unsigned long> predicted_labels = net(training_images);
    int num_right = 0;
    int num_wrong = 0;
    // And then let's see if it classified them correctly.
    for (size_t i = 0; i < training_images.size(); ++i)
    {
        if (predicted_labels[i] == training_labels[i])
            ++num_right;
        else
            ++num_wrong;
        
    }
    cout << "training num_right: " << num_right << endl;
    cout << "training num_wrong: " << num_wrong << endl;
    cout << "training accuracy:  " << num_right/(double)(num_right+num_wrong) << endl;

    // Let's also see if the network can correctly classify the testing images.  Since
    // MNIST is an easy dataset, we should see at least 99% accuracy.
    predicted_labels = net(testing_images);
    num_right = 0;
    num_wrong = 0;
    for (size_t i = 0; i < testing_images.size(); ++i)
    {
        if (predicted_labels[i] == testing_labels[i])
            ++num_right;
        else
            ++num_wrong;
        
    }
    cout << "testing num_right: " << num_right << endl;
    cout << "testing num_wrong: " << num_wrong << endl;
    cout << "testing accuracy:  " << num_right/(double)(num_right+num_wrong) << endl;

}
catch(std::exception& e)
{
    cout << e.what() << endl;
}
Grouping layer added 8 years ago			`// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt`
			`/*`
			`This is an example illustrating the use of the deep learning tools from the`
			`dlib C++ Library. I'm assuming you have already read the dnn_mnist_ex.cpp`
			`example. So in this example program I'm going to go over a number of more`
			`advanced parts of the API, including:`
			`- Using grp layer for constructing inception layer`

			`Inception layer is a kind of NN architecture for running sevelar convolution types`
			`on the same input area and joining all convolution results into one output.`
			`For further reading refer http://www.cs.unc.edu/~wliu/papers/GoogLeNet.pdf`
			`*/`


			`#include <dlib/dnn.h>`
			`#include <iostream>`
			`#include <dlib/data_io.h>`

			`using namespace std;`
			`using namespace dlib;`

depth_group replaced with concat layer 8 years ago			`// Inception layer has some different convolutions inside`
			`// Here we define blocks as convolutions with different kernel size that we will use in`
			`// inception layer block.`
			`template <typename SUBNET> using block_a1 = relu<con<4,1,1,1,1,SUBNET>>;`
			`template <typename SUBNET> using block_a2 = relu<con<4,3,3,1,1,relu<con<4,1,1,1,1,SUBNET>>>>;`
			`template <typename SUBNET> using block_a3 = relu<con<4,5,5,1,1,relu<con<4,1,1,1,1,SUBNET>>>>;`
			`template <typename SUBNET> using block_a4 = relu<con<4,1,1,1,1,max_pool<3,3,1,1,SUBNET>>>;`

			`// Here is inception layer definition. It uses different blocks to process input and returns combined output`
			`template <typename SUBNET> using incept_a = inception4<block_a1,block_a2,block_a3,block_a4, SUBNET>;`

			`// Network can have inception layers of different structure.`
			`// Here are blocks with different convolutions`
			`template <typename SUBNET> using block_b1 = relu<con<8,1,1,1,1,SUBNET>>;`
			`template <typename SUBNET> using block_b2 = relu<con<8,3,3,1,1,SUBNET>>;`
			`template <typename SUBNET> using block_b3 = relu<con<8,1,1,1,1,max_pool<3,3,1,1,SUBNET>>>;`

			`// Here is inception layer definition. It uses different blocks to process input and returns combined output`
			`template <typename SUBNET> using incept_b = inception3<block_b1,block_b2,block_b3,SUBNET>;`

			`// and then the network type is`
			`using net_type = loss_multiclass_log<`
			`fc<10,`
			`relu<fc<32,`
			`max_pool<2,2,2,2,incept_b<`
			`max_pool<2,2,2,2,incept_a<`
			`input<matrix<unsigned char>>`
			`>>>>>>>>;`
Grouping layer added 8 years ago
			`int main(int argc, char** argv) try`
			`{`
depth_group replaced with concat layer 8 years ago			`// This example is going to run on the MNIST dataset.`
Grouping layer added 8 years ago			`if (argc != 2)`
			`{`
			`cout << "This example needs the MNIST dataset to run!" << endl;`
			`cout << "You can get MNIST from http://yann.lecun.com/exdb/mnist/" << endl;`
			`cout << "Download the 4 files that comprise the dataset, decompress them, and" << endl;`
			`cout << "put them in a folder. Then give that folder as input to this program." << endl;`
			`return 1;`
			`}`


			`std::vector<matrix<unsigned char>> training_images;`
			`std::vector<unsigned long> training_labels;`
			`std::vector<matrix<unsigned char>> testing_images;`
			`std::vector<unsigned long> testing_labels;`
			`load_mnist_dataset(argv[1], training_images, training_labels, testing_images, testing_labels);`


depth_group replaced with concat layer 8 years ago			`// The rest of the sample is identical to dnn_minst_ex`
			`// Create network of predefined type.`
Grouping layer added 8 years ago			`net_type net;`

			`// And then train it using the MNIST data. The code below uses mini-batch stochastic`
			`// gradient descent with an initial learning rate of 0.01 to accomplish this.`
			`dnn_trainer<net_type> trainer(net);`
			`trainer.set_learning_rate(0.01);`
			`trainer.set_min_learning_rate(0.00001);`
			`trainer.set_mini_batch_size(128);`
			`trainer.be_verbose();`
			`// Since DNN training can take a long time, we can ask the trainer to save its state to`
			`// a file named "mnist_sync" every 20 seconds. This way, if we kill this program and`
			`// start it again it will begin where it left off rather than restarting the training`
			`// from scratch. This is because, when the program restarts, this call to`
			`// set_synchronization_file() will automatically reload the settings from mnist_sync if`
			`// the file exists.`
depth_group replaced with concat layer 8 years ago			`trainer.set_synchronization_file("inception_sync", std::chrono::seconds(20));`
Grouping layer added 8 years ago			`// Finally, this line begins training. By default, it runs SGD with our specified`
			`// learning rate until the loss stops decreasing. Then it reduces the learning rate by`
			`// a factor of 10 and continues running until the loss stops decreasing again. It will`
			`// keep doing this until the learning rate has dropped below the min learning rate`
depth_group replaced with concat layer 8 years ago			`// defined above or the maximum number of epochs as been executed (defaulted to 10000).`
Grouping layer added 8 years ago			`trainer.train(training_images, training_labels);`

			`// At this point our net object should have learned how to classify MNIST images. But`
			`// before we try it out let's save it to disk. Note that, since the trainer has been`
			`// running images through the network, net will have a bunch of state in it related to`
			`// the last batch of images it processed (e.g. outputs from each layer). Since we`
			`// don't care about saving that kind of stuff to disk we can tell the network to forget`
			`// about that kind of transient data so that our file will be smaller. We do this by`
			`// "cleaning" the network before saving it.`
			`net.clean();`
depth_group replaced with concat layer 8 years ago			`serialize("mnist_network_inception.dat") << net;`
Grouping layer added 8 years ago			`// Now if we later wanted to recall the network from disk we can simply say:`
			`// deserialize("mnist_network.dat") >> net;`


			`// Now let's run the training images through the network. This statement runs all the`
			`// images through it and asks the loss layer to convert the network's raw output into`
			`// labels. In our case, these labels are the numbers between 0 and 9.`
			`std::vector<unsigned long> predicted_labels = net(training_images);`
			`int num_right = 0;`
			`int num_wrong = 0;`
			`// And then let's see if it classified them correctly.`
			`for (size_t i = 0; i < training_images.size(); ++i)`
			`{`
			`if (predicted_labels[i] == training_labels[i])`
			`++num_right;`
			`else`
			`++num_wrong;`

			`}`
			`cout << "training num_right: " << num_right << endl;`
			`cout << "training num_wrong: " << num_wrong << endl;`
			`cout << "training accuracy: " << num_right/(double)(num_right+num_wrong) << endl;`

			`// Let's also see if the network can correctly classify the testing images. Since`
			`// MNIST is an easy dataset, we should see at least 99% accuracy.`
			`predicted_labels = net(testing_images);`
			`num_right = 0;`
			`num_wrong = 0;`
			`for (size_t i = 0; i < testing_images.size(); ++i)`
			`{`
			`if (predicted_labels[i] == testing_labels[i])`
			`++num_right;`
			`else`
			`++num_wrong;`

			`}`
			`cout << "testing num_right: " << num_right << endl;`
			`cout << "testing num_wrong: " << num_wrong << endl;`
			`cout << "testing accuracy: " << num_right/(double)(num_right+num_wrong) << endl;`

			`}`
			`catch(std::exception& e)`
			`{`
			`cout << e.what() << endl;`
			`}`