mirror of https://github.com/davisking/dlib.git
199 lines
8.5 KiB
C++
199 lines
8.5 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 program shows how to use dlib's implementation of the paper:
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One Millisecond Face Alignment with an Ensemble of Regression Trees by
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Vahid Kazemi and Josephine Sullivan, CVPR 2014
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In particular, we will train a face landmarking model based on a small dataset
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and then evaluate it. If you want to visualize the output of the trained
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model on some images then you can run the face_landmark_detection_ex.cpp
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example program with sp.dat as the input model.
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It should also be noted that this kind of model, while often used for face
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landmarking, is quite general and can be used for a variety of shape
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prediction tasks. But here we demonstrate it only on a simple face
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landmarking task.
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*/
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#include <dlib/image_processing.h>
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#include <dlib/data_io.h>
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#include <iostream>
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using namespace dlib;
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using namespace std;
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// ----------------------------------------------------------------------------------------
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std::vector<std::vector<double> > get_interocular_distances (
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const std::vector<std::vector<full_object_detection> >& objects
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);
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/*!
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ensures
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- returns an object D such that:
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- D[i][j] == the distance, in pixels, between the eyes for the face represented
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by objects[i][j].
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!*/
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// ----------------------------------------------------------------------------------------
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int main(int argc, char** argv)
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{
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try
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{
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// In this example we are going to train a shape_predictor based on the
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// small faces dataset in the examples/faces directory. So the first
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// thing we do is load that dataset. This means you need to supply the
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// path to this faces folder as a command line argument so we will know
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// where it is.
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if (argc != 2)
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{
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cout << "Give the path to the examples/faces directory as the argument to this" << endl;
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cout << "program. For example, if you are in the examples folder then execute " << endl;
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cout << "this program by running: " << endl;
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cout << " ./train_shape_predictor_ex faces" << endl;
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cout << endl;
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return 0;
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}
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const std::string faces_directory = argv[1];
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// The faces directory contains a training dataset and a separate
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// testing dataset. The training data consists of 4 images, each
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// annotated with rectangles that bound each human face along with 68
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// face landmarks on each face. The idea is to use this training data
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// to learn to identify the position of landmarks on human faces in new
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// images.
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//
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// Once you have trained a shape_predictor it is always important to
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// test it on data it wasn't trained on. Therefore, we will also load
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// a separate testing set of 5 images. Once we have a shape_predictor
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// created from the training data we will see how well it works by
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// running it on the testing images.
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//
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// So here we create the variables that will hold our dataset.
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// images_train will hold the 4 training images and faces_train holds
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// the locations and poses of each face in the training images. So for
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// example, the image images_train[0] has the faces given by the
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// full_object_detections in faces_train[0].
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dlib::array<array2d<unsigned char> > images_train, images_test;
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std::vector<std::vector<full_object_detection> > faces_train, faces_test;
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// Now we load the data. These XML files list the images in each
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// dataset and also contain the positions of the face boxes and
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// landmarks (called parts in the XML file). Obviously you can use any
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// kind of input format you like so long as you store the data into
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// images_train and faces_train. But for convenience dlib comes with
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// tools for creating and loading XML image dataset files. Here you see
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// how to load the data. To create the XML files you can use the imglab
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// tool which can be found in the tools/imglab folder. It is a simple
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// graphical tool for labeling objects in images. To see how to use it
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// read the tools/imglab/README.txt file.
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load_image_dataset(images_train, faces_train, faces_directory+"/training_with_face_landmarks.xml");
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load_image_dataset(images_test, faces_test, faces_directory+"/testing_with_face_landmarks.xml");
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// Now make the object responsible for training the model.
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shape_predictor_trainer trainer;
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// This algorithm has a bunch of parameters you can mess with. The
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// documentation for the shape_predictor_trainer explains all of them.
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// You should also read Kazemi's paper which explains all the parameters
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// in great detail. However, here I'm just setting three of them
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// differently than their default values. I'm doing this because we
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// have a very small dataset. In particular, setting the oversampling
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// to a high amount (300) effectively boosts the training set size, so
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// that helps this example.
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trainer.set_oversampling_amount(300);
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// I'm also reducing the capacity of the model by explicitly increasing
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// the regularization (making nu smaller) and by using trees with
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// smaller depths.
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trainer.set_nu(0.05);
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trainer.set_tree_depth(2);
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// some parts of training process can be parallelized.
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// Trainer will use this count of threads when possible
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trainer.set_num_threads(2);
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// Tell the trainer to print status messages to the console so we can
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// see how long the training will take.
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trainer.be_verbose();
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// Now finally generate the shape model
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shape_predictor sp = trainer.train(images_train, faces_train);
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// Now that we have a model we can test it. This function measures the
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// average distance between a face landmark output by the
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// shape_predictor and where it should be according to the truth data.
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// Note that there is an optional 4th argument that lets us rescale the
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// distances. Here we are causing the output to scale each face's
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// distances by the interocular distance, as is customary when
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// evaluating face landmarking systems.
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cout << "mean training error: "<<
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test_shape_predictor(sp, images_train, faces_train, get_interocular_distances(faces_train)) << endl;
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// The real test is to see how well it does on data it wasn't trained
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// on. We trained it on a very small dataset so the accuracy is not
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// extremely high, but it's still doing quite good. Moreover, if you
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// train it on one of the large face landmarking datasets you will
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// obtain state-of-the-art results, as shown in the Kazemi paper.
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cout << "mean testing error: "<<
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test_shape_predictor(sp, images_test, faces_test, get_interocular_distances(faces_test)) << endl;
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// Finally, we save the model to disk so we can use it later.
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serialize("sp.dat") << sp;
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}
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catch (exception& e)
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{
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cout << "\nexception thrown!" << endl;
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cout << e.what() << endl;
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}
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}
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// ----------------------------------------------------------------------------------------
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double interocular_distance (
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const full_object_detection& det
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)
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{
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dlib::vector<double,2> l, r;
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double cnt = 0;
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// Find the center of the left eye by averaging the points around
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// the eye.
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for (unsigned long i = 36; i <= 41; ++i)
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{
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l += det.part(i);
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++cnt;
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}
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l /= cnt;
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// Find the center of the right eye by averaging the points around
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// the eye.
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cnt = 0;
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for (unsigned long i = 42; i <= 47; ++i)
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{
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r += det.part(i);
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++cnt;
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}
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r /= cnt;
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// Now return the distance between the centers of the eyes
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return length(l-r);
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}
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std::vector<std::vector<double> > get_interocular_distances (
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const std::vector<std::vector<full_object_detection> >& objects
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)
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{
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std::vector<std::vector<double> > temp(objects.size());
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for (unsigned long i = 0; i < objects.size(); ++i)
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{
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for (unsigned long j = 0; j < objects[i].size(); ++j)
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{
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temp[i].push_back(interocular_distance(objects[i][j]));
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}
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}
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return temp;
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}
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// ----------------------------------------------------------------------------------------
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