mirror of https://github.com/davisking/dlib.git
173 lines
6.3 KiB
C++
173 lines
6.3 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 do semantic segmentation on an image using net pretrained
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on the PASCAL VOC2012 dataset. For an introduction to what segmentation is, see the
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accompanying header file dnn_semantic_segmentation_ex.h.
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Instructions how to run the example:
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1. Download the PASCAL VOC2012 data, and untar it somewhere.
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http://host.robots.ox.ac.uk/pascal/VOC/voc2012/VOCtrainval_11-May-2012.tar
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2. Build the dnn_semantic_segmentation_train_ex example program.
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3. Run:
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./dnn_semantic_segmentation_train_ex /path/to/VOC2012
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4. Wait while the network is being trained.
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5. Build the dnn_semantic_segmentation_ex example program.
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6. Run:
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./dnn_semantic_segmentation_ex /path/to/VOC2012-or-other-images
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An alternative to steps 2-4 above is to download a pre-trained network
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from here: http://dlib.net/files/semantic_segmentation_voc2012net_v2.dnn
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It would be a good idea to become familiar with dlib's DNN tooling before reading this
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example. So you should read dnn_introduction_ex.cpp and dnn_introduction2_ex.cpp
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before reading this example program.
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*/
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#include "dnn_semantic_segmentation_ex.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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using namespace std;
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using namespace dlib;
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// ----------------------------------------------------------------------------------------
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// The PASCAL VOC2012 dataset contains 20 ground-truth classes + background. Each class
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// is represented using an RGB color value. We associate each class also to an index in the
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// range [0, 20], used internally by the network. To generate nice RGB representations of
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// inference results, we need to be able to convert the index values to the corresponding
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// RGB values.
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// Given an index in the range [0, 20], find the corresponding PASCAL VOC2012 class
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// (e.g., 'dog').
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const Voc2012class& find_voc2012_class(const uint16_t& index_label)
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{
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return find_voc2012_class(
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[&index_label](const Voc2012class& voc2012class)
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{
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return index_label == voc2012class.index;
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}
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);
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}
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// Convert an index in the range [0, 20] to a corresponding RGB class label.
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inline rgb_pixel index_label_to_rgb_label(uint16_t index_label)
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{
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return find_voc2012_class(index_label).rgb_label;
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}
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// Convert an image containing indexes in the range [0, 20] to a corresponding
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// image containing RGB class labels.
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void index_label_image_to_rgb_label_image(
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const matrix<uint16_t>& index_label_image,
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matrix<rgb_pixel>& rgb_label_image
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)
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{
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const long nr = index_label_image.nr();
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const long nc = index_label_image.nc();
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rgb_label_image.set_size(nr, nc);
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for (long r = 0; r < nr; ++r)
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{
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for (long c = 0; c < nc; ++c)
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{
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rgb_label_image(r, c) = index_label_to_rgb_label(index_label_image(r, c));
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}
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}
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}
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// Find the most prominent class label from amongst the per-pixel predictions.
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std::string get_most_prominent_non_background_classlabel(const matrix<uint16_t>& index_label_image)
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{
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const long nr = index_label_image.nr();
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const long nc = index_label_image.nc();
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std::vector<unsigned int> counters(class_count);
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for (long r = 0; r < nr; ++r)
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{
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for (long c = 0; c < nc; ++c)
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{
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const uint16_t label = index_label_image(r, c);
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++counters[label];
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}
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}
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const auto max_element = std::max_element(counters.begin() + 1, counters.end());
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const uint16_t most_prominent_index_label = max_element - counters.begin();
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return find_voc2012_class(most_prominent_index_label).classlabel;
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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 != 2)
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{
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cout << "You call this program like this: " << endl;
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cout << "./dnn_semantic_segmentation_train_ex /path/to/images" << endl;
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cout << endl;
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cout << "You will also need a trained '" << semantic_segmentation_net_filename << "' file." << endl;
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cout << "You can either train it yourself (see example program" << endl;
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cout << "dnn_semantic_segmentation_train_ex), or download a" << endl;
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cout << "copy from here: http://dlib.net/files/" << semantic_segmentation_net_filename << endl;
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return 1;
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}
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// Read the file containing the trained network from the working directory.
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anet_type net;
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deserialize(semantic_segmentation_net_filename) >> net;
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// Show inference results in a window.
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image_window win;
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matrix<rgb_pixel> input_image;
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matrix<uint16_t> index_label_image;
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matrix<rgb_pixel> rgb_label_image;
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// Find supported image files.
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const std::vector<file> files = dlib::get_files_in_directory_tree(argv[1],
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dlib::match_endings(".jpeg .jpg .png"));
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cout << "Found " << files.size() << " images, processing..." << endl;
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for (const file& file : files)
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{
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// Load the input image.
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load_image(input_image, file.full_name());
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// Create predictions for each pixel. At this point, the type of each prediction
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// is an index (a value between 0 and 20). Note that the net may return an image
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// that is not exactly the same size as the input.
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const matrix<uint16_t> temp = net(input_image);
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// Crop the returned image to be exactly the same size as the input.
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const chip_details chip_details(
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centered_rect(temp.nc() / 2, temp.nr() / 2, input_image.nc(), input_image.nr()),
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chip_dims(input_image.nr(), input_image.nc())
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);
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extract_image_chip(temp, chip_details, index_label_image, interpolate_nearest_neighbor());
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// Convert the indexes to RGB values.
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index_label_image_to_rgb_label_image(index_label_image, rgb_label_image);
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// Show the input image on the left, and the predicted RGB labels on the right.
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win.set_image(join_rows(input_image, rgb_label_image));
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// Find the most prominent class label from amongst the per-pixel predictions.
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const std::string classlabel = get_most_prominent_non_background_classlabel(index_label_image);
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cout << file.name() << " : " << classlabel << " - 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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