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168 lines
6.2 KiB
C++
168 lines
6.2 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 example shows how to classify an image into one of the 1000 imagenet
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categories using the deep learning tools from the dlib C++ Library. We will
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use the pretrained ResNet34 model available on the dlib website.
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The ResNet34 architecture is from the paper Deep Residual Learning for Image
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Recognition by He, Zhang, Ren, and Sun. The model file that comes with dlib
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was trained using the dnn_imagenet_train_ex.cpp program on a Titan X for
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about 2 weeks. This pretrained model has a top5 error of 7.572% on the 2012
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imagenet validation dataset.
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For an introduction to dlib's DNN module read the dnn_introduction_ex.cpp and
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dnn_introduction2_ex.cpp example programs.
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Finally, these tools will use CUDA and cuDNN to drastically accelerate
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network training and testing. CMake should automatically find them if they
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are 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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#include <dlib/gui_widgets.h>
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#include <dlib/image_transforms.h>
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using namespace std;
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using namespace dlib;
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// ----------------------------------------------------------------------------------------
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// This block of statements defines the resnet-34 network
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template <template <int,template<typename>class,int,typename> class block, int N, template<typename>class BN, typename SUBNET>
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using residual = add_prev1<block<N,BN,1,tag1<SUBNET>>>;
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template <template <int,template<typename>class,int,typename> class block, int N, template<typename>class BN, typename SUBNET>
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using residual_down = add_prev2<avg_pool<2,2,2,2,skip1<tag2<block<N,BN,2,tag1<SUBNET>>>>>>;
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template <int N, template <typename> class BN, int stride, typename SUBNET>
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using block = BN<con<N,3,3,1,1,relu<BN<con<N,3,3,stride,stride,SUBNET>>>>>;
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template <int N, typename SUBNET> using ares = relu<residual<block,N,affine,SUBNET>>;
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template <int N, typename SUBNET> using ares_down = relu<residual_down<block,N,affine,SUBNET>>;
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using anet_type = loss_multiclass_log<fc<1000,avg_pool_everything<
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ares<512,ares<512,ares_down<512,
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ares<256,ares<256,ares<256,ares<256,ares<256,ares_down<256,
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ares<128,ares<128,ares<128,ares_down<128,
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ares<64,ares<64,ares<64,
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max_pool<3,3,2,2,relu<affine<con<64,7,7,2,2,
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input_rgb_image_sized<227>
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>>>>>>>>>>>>>>>>>>>>>>>;
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// ----------------------------------------------------------------------------------------
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rectangle make_random_cropping_rect_resnet(
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const matrix<rgb_pixel>& img,
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dlib::rand& rnd
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)
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{
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// figure out what rectangle we want to crop from the image
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double mins = 0.466666666, maxs = 0.875;
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auto scale = mins + rnd.get_random_double()*(maxs-mins);
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auto size = scale*std::min(img.nr(), img.nc());
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rectangle rect(size, size);
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// randomly shift the box around
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point offset(rnd.get_random_32bit_number()%(img.nc()-rect.width()),
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rnd.get_random_32bit_number()%(img.nr()-rect.height()));
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return move_rect(rect, offset);
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}
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// ----------------------------------------------------------------------------------------
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void randomly_crop_images (
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const matrix<rgb_pixel>& img,
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dlib::array<matrix<rgb_pixel>>& crops,
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dlib::rand& rnd,
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long num_crops
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)
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{
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std::vector<chip_details> dets;
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for (long i = 0; i < num_crops; ++i)
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{
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auto rect = make_random_cropping_rect_resnet(img, rnd);
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dets.push_back(chip_details(rect, chip_dims(227,227)));
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}
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extract_image_chips(img, dets, crops);
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for (auto&& img : crops)
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{
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// Also randomly flip the image
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if (rnd.get_random_double() > 0.5)
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img = fliplr(img);
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// And then randomly adjust the colors.
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apply_random_color_offset(img, rnd);
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}
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}
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// ----------------------------------------------------------------------------------------
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int main(int argc, char** argv) try
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{
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if (argc == 1)
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{
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cout << "Give this program image files as command line arguments.\n" << endl;
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cout << "You will also need a copy of the file resnet34_1000_imagenet_classifier.dnn " << endl;
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cout << "available at http://dlib.net/files/resnet34_1000_imagenet_classifier.dnn.bz2" << endl;
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cout << endl;
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return 1;
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}
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std::vector<string> labels;
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anet_type net;
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deserialize("resnet34_1000_imagenet_classifier.dnn") >> net >> labels;
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// Make a network with softmax as the final layer. We don't have to do this
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// if we just want to output the single best prediction, since the anet_type
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// already does this. But if we instead want to get the probability of each
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// class as output we need to replace the last layer of the network with a
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// softmax layer, which we do as follows:
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softmax<anet_type::subnet_type> snet;
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snet.subnet() = net.subnet();
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dlib::array<matrix<rgb_pixel>> images;
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matrix<rgb_pixel> img, crop;
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dlib::rand rnd;
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image_window win;
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// Read images from the command prompt and print the top 5 best labels for each.
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for (int i = 1; i < argc; ++i)
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{
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load_image(img, argv[i]);
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const int num_crops = 16;
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// Grab 16 random crops from the image. We will run all of them through the
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// network and average the results.
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randomly_crop_images(img, images, rnd, num_crops);
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// p(i) == the probability the image contains object of class i.
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matrix<float,1,1000> p = sum_rows(mat(snet(images.begin(), images.end())))/num_crops;
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win.set_image(img);
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// Print the 5 most probable labels
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for (int k = 0; k < 5; ++k)
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{
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unsigned long predicted_label = index_of_max(p);
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cout << p(predicted_label) << ": " << labels[predicted_label] << endl;
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p(predicted_label) = 0;
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}
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cout << "Hit enter to process the next image";
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cin.get();
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}
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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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