dlib/examples/dnn_mmod_face_detection_ex.cpp

115 lines
4.6 KiB
C++

// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
/*
This example shows how to run a CNN based face detector using dlib. The
example loads a pretrained model and uses it to find faces in images. The
CNN model is much more accurate than the HOG based model shown in the
face_detection_ex.cpp example, but takes much more computational power to
run, and is meant to be executed on a GPU to attain reasonable speed. For
example, on a NVIDIA Titan X GPU, this example program processes images at
about the same speed as face_detection_ex.cpp.
Also, users who are just learning about dlib's deep learning API should read
the dnn_introduction_ex.cpp and dnn_introduction2_ex.cpp examples to learn
how the API works. For an introduction to the object detection method you
should read dnn_mmod_ex.cpp
TRAINING THE MODEL
Finally, users interested in how the face detector was trained should
read the dnn_mmod_ex.cpp example program. It should be noted that the
face detector used in this example uses a bigger training dataset and
larger CNN architecture than what is shown in dnn_mmod_ex.cpp, but
otherwise training is the same. If you compare the net_type statements
in this file and dnn_mmod_ex.cpp you will see that they are very similar
except that the number of parameters has been increased.
Additionally, the following training parameters were different during
training: The following lines in dnn_mmod_ex.cpp were changed from
mmod_options options(face_boxes_train, 40,40);
trainer.set_iterations_without_progress_threshold(300);
to the following when training the model used in this example:
mmod_options options(face_boxes_train, 80,80);
trainer.set_iterations_without_progress_threshold(8000);
Also, the random_cropper was left at its default settings, So we didn't
call these functions:
cropper.set_chip_dims(200, 200);
cropper.set_min_object_size(40,40);
The training data used to create the model is also available at
http://dlib.net/files/data/dlib_face_detection_dataset-2016-09-30.tar.gz
*/
#include <iostream>
#include <dlib/dnn.h>
#include <dlib/data_io.h>
#include <dlib/image_processing.h>
#include <dlib/gui_widgets.h>
using namespace std;
using namespace dlib;
// ----------------------------------------------------------------------------------------
template <long num_filters, typename SUBNET> using con5d = con<num_filters,5,5,2,2,SUBNET>;
template <long num_filters, typename SUBNET> using con5 = con<num_filters,5,5,1,1,SUBNET>;
template <typename SUBNET> using downsampler = relu<affine<con5d<32, relu<affine<con5d<32, relu<affine<con5d<16,SUBNET>>>>>>>>>;
template <typename SUBNET> using rcon5 = relu<affine<con5<45,SUBNET>>>;
using net_type = loss_mmod<con<1,9,9,1,1,rcon5<rcon5<rcon5<downsampler<input_rgb_image_pyramid<pyramid_down<6>>>>>>>>;
// ----------------------------------------------------------------------------------------
int main(int argc, char** argv) try
{
if (argc == 1)
{
cout << "Call this program like this:" << endl;
cout << "./dnn_mmod_face_detection_ex mmod_human_face_detector.dat faces/*.jpg" << endl;
cout << "\nYou can get the mmod_human_face_detector.dat file from:\n";
cout << "http://dlib.net/files/mmod_human_face_detector.dat.bz2" << endl;
return 0;
}
net_type net;
deserialize(argv[1]) >> net;
image_window win;
for (int i = 2; i < argc; ++i)
{
matrix<rgb_pixel> img;
load_image(img, argv[i]);
// Upsampling the image will allow us to detect smaller faces but will cause the
// program to use more RAM and run longer.
while(img.size() < 1800*1800)
pyramid_up(img);
// Note that you can process a bunch of images in a std::vector at once and it runs
// much faster, since this will form mini-batches of images and therefore get
// better parallelism out of your GPU hardware. However, all the images must be
// the same size. To avoid this requirement on images being the same size we
// process them individually in this example.
auto dets = net(img);
win.clear_overlay();
win.set_image(img);
for (auto&& d : dets)
win.add_overlay(d);
cout << "Hit enter to process the next image." << endl;
cin.get();
}
}
catch(std::exception& e)
{
cout << e.what() << endl;
}