dlib/examples/dnn_imagenet_ex.cpp

// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
/*
    This example shows how to classify an image into one of the 1000 imagenet
    categories using the deep learning tools from the dlib C++ Library.  We will
    use the pretrained ResNet34 model available on the dlib website.

    The ResNet34 architecture is from the paper Deep Residual Learning for Image
    Recognition by He, Zhang, Ren, and Sun.  The model file that comes with dlib
    was trained using the dnn_imagenet_train_ex.cpp program on a Titan X for
    about 2 weeks.  This pretrained model has a top5 error of 7.572% on the 2012
    imagenet validation dataset.

    For an introduction to dlib's DNN module read the dnn_introduction_ex.cpp and
    dnn_introduction2_ex.cpp example programs.

    
    Finally, these tools will use CUDA and cuDNN to drastically accelerate
    network training and testing.  CMake should automatically find them if they
    are installed and configure things appropriately.  If not, the program will
    still run but will be much slower to execute.
*/


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

using namespace std;
using namespace dlib;
 
// ----------------------------------------------------------------------------------------

// This block of statements defines the resnet-34 network

template <template <int,template<typename>class,int,typename> class block, int N, template<typename>class BN, typename SUBNET>
using residual = add_prev1<block<N,BN,1,tag1<SUBNET>>>;

template <template <int,template<typename>class,int,typename> class block, int N, template<typename>class BN, typename SUBNET>
using residual_down = add_prev2<avg_pool<2,2,2,2,skip1<tag2<block<N,BN,2,tag1<SUBNET>>>>>>;

template <int N, template <typename> class BN, int stride, typename SUBNET> 
using block  = BN<con<N,3,3,1,1,relu<BN<con<N,3,3,stride,stride,SUBNET>>>>>;

template <int N, typename SUBNET> using ares      = relu<residual<block,N,affine,SUBNET>>;
template <int N, typename SUBNET> using ares_down = relu<residual_down<block,N,affine,SUBNET>>;

template <typename SUBNET> using level1 = ares<512,ares<512,ares_down<512,SUBNET>>>;
template <typename SUBNET> using level2 = ares<256,ares<256,ares<256,ares<256,ares<256,ares_down<256,SUBNET>>>>>>;
template <typename SUBNET> using level3 = ares<128,ares<128,ares<128,ares_down<128,SUBNET>>>>;
template <typename SUBNET> using level4 = ares<64,ares<64,ares<64,SUBNET>>>;

using anet_type = loss_multiclass_log<fc<1000,avg_pool_everything<
                            level1<
                            level2<
                            level3<
                            level4<
                            max_pool<3,3,2,2,relu<affine<con<64,7,7,2,2,
                            input_rgb_image_sized<227>
                            >>>>>>>>>>>;

// ----------------------------------------------------------------------------------------

rectangle make_random_cropping_rect_resnet(
    const matrix<rgb_pixel>& img,
    dlib::rand& rnd
)
{
    // figure out what rectangle we want to crop from the image
    double mins = 0.466666666, maxs = 0.875;
    auto scale = mins + rnd.get_random_double()*(maxs-mins);
    auto size = scale*std::min(img.nr(), img.nc());
    rectangle rect(size, size);
    // randomly shift the box around
    point offset(rnd.get_random_32bit_number()%(img.nc()-rect.width()),
                 rnd.get_random_32bit_number()%(img.nr()-rect.height()));
    return move_rect(rect, offset);
}

// ----------------------------------------------------------------------------------------

void randomly_crop_images (
    const matrix<rgb_pixel>& img,
    dlib::array<matrix<rgb_pixel>>& crops,
    dlib::rand& rnd,
    long num_crops
)
{
    std::vector<chip_details> dets;
    for (long i = 0; i < num_crops; ++i)
    {
        auto rect = make_random_cropping_rect_resnet(img, rnd);
        dets.push_back(chip_details(rect, chip_dims(227,227)));
    }

    extract_image_chips(img, dets, crops);

    for (auto&& img : crops)
    {
        // Also randomly flip the image
        if (rnd.get_random_double() > 0.5)
            img = fliplr(img);

        // And then randomly adjust the colors.
        apply_random_color_offset(img, rnd);
    }
}

// ----------------------------------------------------------------------------------------

int main(int argc, char** argv) try
{
    if (argc == 1)
    {
        cout << "Give this program image files as command line arguments.\n" << endl;
        cout << "You will also need a copy of the file resnet34_1000_imagenet_classifier.dnn " << endl;
        cout << "available at http://dlib.net/files/resnet34_1000_imagenet_classifier.dnn.bz2" << endl;
        cout << endl;
        return 1;
    }

    std::vector<string> labels;
    anet_type net;
    deserialize("resnet34_1000_imagenet_classifier.dnn") >> net >> labels;

    // Make a network with softmax as the final layer.  We don't have to do this
    // if we just want to output the single best prediction, since the anet_type
    // already does this.  But if we instead want to get the probability of each
    // class as output we need to replace the last layer of the network with a
    // softmax layer, which we do as follows:
    softmax<anet_type::subnet_type> snet; 
    snet.subnet() = net.subnet();

    dlib::array<matrix<rgb_pixel>> images;
    matrix<rgb_pixel> img, crop;

    dlib::rand rnd;
    image_window win;

    // Read images from the command prompt and print the top 5 best labels for each.
    for (int i = 1; i < argc; ++i)
    {
        load_image(img, argv[i]);
        const int num_crops = 16;
        // Grab 16 random crops from the image.  We will run all of them through the
        // network and average the results.
        randomly_crop_images(img, images, rnd, num_crops);
        // p(i) == the probability the image contains object of class i.
        matrix<float,1,1000> p = sum_rows(mat(snet(images.begin(), images.end())))/num_crops;

        win.set_image(img);
        // Print the 5 most probable labels
        for (int k = 0; k < 5; ++k)
        {
            unsigned long predicted_label = index_of_max(p);
            cout << p(predicted_label) << ": " << labels[predicted_label] << endl;
            p(predicted_label) = 0;
        }

        cout << "Hit enter to process the next image";
        cin.get();
    }

}
catch(std::exception& e)
{
    cout << e.what() << endl;
}
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt`
			`/*`
Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`This example shows how to classify an image into one of the 1000 imagenet`
			`categories using the deep learning tools from the dlib C++ Library. We will`
			`use the pretrained ResNet34 model available on the dlib website.`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00
Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`The ResNet34 architecture is from the paper Deep Residual Learning for Image`
			`Recognition by He, Zhang, Ren, and Sun. The model file that comes with dlib`
			`was trained using the dnn_imagenet_train_ex.cpp program on a Titan X for`
			`about 2 weeks. This pretrained model has a top5 error of 7.572% on the 2012`
			`imagenet validation dataset.`

Updated examples to refer to the correct file names. 2016-06-25 21:40:11 +08:00			`For an introduction to dlib's DNN module read the dnn_introduction_ex.cpp and`
			`dnn_introduction2_ex.cpp example programs.`
Added some comments 2016-06-23 10:30:45 +08:00
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00
Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`Finally, these tools will use CUDA and cuDNN to drastically accelerate`
			`network training and testing. CMake should automatically find them if they`
			`are installed and configure things appropriately. If not, the program will`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`still run but will be much slower to execute.`
			`*/`



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

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

			`// ----------------------------------------------------------------------------------------`

Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`// This block of statements defines the resnet-34 network`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00
			`template <template <int,template<typename>class,int,typename> class block, int N, template<typename>class BN, typename SUBNET>`
			`using residual = add_prev1<block<N,BN,1,tag1<SUBNET>>>;`

			`template <template <int,template<typename>class,int,typename> class block, int N, template<typename>class BN, typename SUBNET>`
			`using residual_down = add_prev2<avg_pool<2,2,2,2,skip1<tag2<block<N,BN,2,tag1<SUBNET>>>>>>;`

			`template <int N, template <typename> class BN, int stride, typename SUBNET>`
			`using block = BN<con<N,3,3,1,1,relu<BN<con<N,3,3,stride,stride,SUBNET>>>>>;`

			`template <int N, typename SUBNET> using ares = relu<residual<block,N,affine,SUBNET>>;`
			`template <int N, typename SUBNET> using ares_down = relu<residual_down<block,N,affine,SUBNET>>;`

Evgeniy Fominov's changes that avoid compiler bugs in Visual Studio. 2016-10-09 02:27:34 +08:00			`template <typename SUBNET> using level1 = ares<512,ares<512,ares_down<512,SUBNET>>>;`
			`template <typename SUBNET> using level2 = ares<256,ares<256,ares<256,ares<256,ares<256,ares_down<256,SUBNET>>>>>>;`
			`template <typename SUBNET> using level3 = ares<128,ares<128,ares<128,ares_down<128,SUBNET>>>>;`
			`template <typename SUBNET> using level4 = ares<64,ares<64,ares<64,SUBNET>>>;`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00
Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`using anet_type = loss_multiclass_log<fc<1000,avg_pool_everything<`
Evgeniy Fominov's changes that avoid compiler bugs in Visual Studio. 2016-10-09 02:27:34 +08:00			`level1<`
			`level2<`
			`level3<`
			`level4<`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`max_pool<3,3,2,2,relu<affine<con<64,7,7,2,2,`
			`input_rgb_image_sized<227>`
Evgeniy Fominov's changes that avoid compiler bugs in Visual Studio. 2016-10-09 02:27:34 +08:00			`>>>>>>>>>>>;`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00
			`// ----------------------------------------------------------------------------------------`

			`rectangle make_random_cropping_rect_resnet(`
			`const matrix<rgb_pixel>& img,`
			`dlib::rand& rnd`
			`)`
			`{`
			`// figure out what rectangle we want to crop from the image`
			`double mins = 0.466666666, maxs = 0.875;`
			`auto scale = mins + rnd.get_random_double()*(maxs-mins);`
			`auto size = scale*std::min(img.nr(), img.nc());`
			`rectangle rect(size, size);`
			`// randomly shift the box around`
			`point offset(rnd.get_random_32bit_number()%(img.nc()-rect.width()),`
			`rnd.get_random_32bit_number()%(img.nr()-rect.height()));`
			`return move_rect(rect, offset);`
			`}`

			`// ----------------------------------------------------------------------------------------`

			`void randomly_crop_images (`
			`const matrix<rgb_pixel>& img,`
			`dlib::array<matrix<rgb_pixel>>& crops,`
			`dlib::rand& rnd,`
			`long num_crops`
			`)`
			`{`
			`std::vector<chip_details> dets;`
			`for (long i = 0; i < num_crops; ++i)`
			`{`
			`auto rect = make_random_cropping_rect_resnet(img, rnd);`
			`dets.push_back(chip_details(rect, chip_dims(227,227)));`
			`}`

			`extract_image_chips(img, dets, crops);`

			`for (auto&& img : crops)`
			`{`
			`// Also randomly flip the image`
			`if (rnd.get_random_double() > 0.5)`
			`img = fliplr(img);`

			`// And then randomly adjust the colors.`
			`apply_random_color_offset(img, rnd);`
			`}`
			`}`

			`// ----------------------------------------------------------------------------------------`

			`int main(int argc, char** argv) try`
			`{`
Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`if (argc == 1)`
			`{`
			`cout << "Give this program image files as command line arguments.\n" << endl;`
Minor formatting cleanup 2016-06-25 21:47:36 +08:00			`cout << "You will also need a copy of the file resnet34_1000_imagenet_classifier.dnn " << endl;`
			`cout << "available at http://dlib.net/files/resnet34_1000_imagenet_classifier.dnn.bz2" << endl;`
Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`cout << endl;`
			`return 1;`
			`}`

Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`std::vector<string> labels;`
			`anet_type net;`
			`deserialize("resnet34_1000_imagenet_classifier.dnn") >> net >> labels;`

Added some more comments 2016-06-26 06:31:21 +08:00			`// Make a network with softmax as the final layer. We don't have to do this`
			`// if we just want to output the single best prediction, since the anet_type`
			`// already does this. But if we instead want to get the probability of each`
			`// class as output we need to replace the last layer of the network with a`
			`// softmax layer, which we do as follows:`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`softmax<anet_type::subnet_type> snet;`
			`snet.subnet() = net.subnet();`

			`dlib::array<matrix<rgb_pixel>> images;`
			`matrix<rgb_pixel> img, crop;`

			`dlib::rand rnd;`
			`image_window win;`

Added some more comments 2016-06-26 06:31:21 +08:00			`// Read images from the command prompt and print the top 5 best labels for each.`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`for (int i = 1; i < argc; ++i)`
			`{`
			`load_image(img, argv[i]);`
			`const int num_crops = 16;`
Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`// Grab 16 random crops from the image. We will run all of them through the`
			`// network and average the results.`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`randomly_crop_images(img, images, rnd, num_crops);`
Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`// p(i) == the probability the image contains object of class i.`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`matrix<float,1,1000> p = sum_rows(mat(snet(images.begin(), images.end())))/num_crops;`

			`win.set_image(img);`
Added some more comments 2016-06-26 06:31:21 +08:00			`// Print the 5 most probable labels`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`for (int k = 0; k < 5; ++k)`
			`{`
			`unsigned long predicted_label = index_of_max(p);`
			`cout << p(predicted_label) << ": " << labels[predicted_label] << endl;`
			`p(predicted_label) = 0;`
			`}`

Added the program that made the resnet model. 2016-06-25 21:26:51 +08:00			`cout << "Hit enter to process the next image";`
Added an example showing how to classify imagenet images. 2016-06-23 10:26:48 +08:00			`cin.get();`
			`}`

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