dlib/python_examples/train_shape_predictor.py

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Python
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#!/usr/bin/python
# The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
#
# This example program shows how to use dlib's implementation of the paper:
# One Millisecond Face Alignment with an Ensemble of Regression Trees by
# Vahid Kazemi and Josephine Sullivan, CVPR 2014
#
# In particular, we will train a face landmarking model based on a small
# dataset and then evaluate it. If you want to visualize the output of the
# trained model on some images then you can run the
# face_landmark_detection.py example program with predictor.dat as the input
# model.
#
# It should also be noted that this kind of model, while often used for face
# landmarking, is quite general and can be used for a variety of shape
# prediction tasks. But here we demonstrate it only on a simple face
# landmarking task.
#
# COMPILING/INSTALLING THE DLIB PYTHON INTERFACE
# You can install dlib using the command:
# pip install dlib
#
# Alternatively, if you want to compile dlib yourself then go into the dlib
# root folder and run:
# python setup.py install
#
# Compiling dlib should work on any operating system so long as you have
# CMake installed. On Ubuntu, this can be done easily by running the
# command:
# sudo apt-get install cmake
#
# Also note that this example requires Numpy which can be installed
# via the command:
# pip install numpy
import os
import sys
import glob
import dlib
# In this example we are going to train a face detector based on the small
# faces dataset in the examples/faces directory. This means you need to supply
# the path to this faces folder as a command line argument so we will know
# where it is.
if len(sys.argv) != 2:
print(
"Give the path to the examples/faces directory as the argument to this "
"program. For example, if you are in the python_examples folder then "
"execute this program by running:\n"
" ./train_shape_predictor.py ../examples/faces")
exit()
faces_folder = sys.argv[1]
options = dlib.shape_predictor_training_options()
# Now make the object responsible for training the model.
# This algorithm has a bunch of parameters you can mess with. The
# documentation for the shape_predictor_trainer explains all of them.
# You should also read Kazemi's paper which explains all the parameters
# in great detail. However, here I'm just setting three of them
# differently than their default values. I'm doing this because we
# have a very small dataset. In particular, setting the oversampling
# to a high amount (300) effectively boosts the training set size, so
# that helps this example.
options.oversampling_amount = 300
# I'm also reducing the capacity of the model by explicitly increasing
# the regularization (making nu smaller) and by using trees with
# smaller depths.
options.nu = 0.05
options.tree_depth = 2
options.be_verbose = True
# dlib.train_shape_predictor() does the actual training. It will save the
# final predictor to predictor.dat. The input is an XML file that lists the
# images in the training dataset and also contains the positions of the face
# parts.
training_xml_path = os.path.join(faces_folder, "training_with_face_landmarks.xml")
dlib.train_shape_predictor(training_xml_path, "predictor.dat", options)
# Now that we have a model we can test it. dlib.test_shape_predictor()
# measures the average distance between a face landmark output by the
# shape_predictor and where it should be according to the truth data.
print("\nTraining accuracy: {}".format(
dlib.test_shape_predictor(training_xml_path, "predictor.dat")))
# The real test is to see how well it does on data it wasn't trained on. We
# trained it on a very small dataset so the accuracy is not extremely high, but
# it's still doing quite good. Moreover, if you train it on one of the large
# face landmarking datasets you will obtain state-of-the-art results, as shown
# in the Kazemi paper.
testing_xml_path = os.path.join(faces_folder, "testing_with_face_landmarks.xml")
print("Testing accuracy: {}".format(
dlib.test_shape_predictor(testing_xml_path, "predictor.dat")))
# Now let's use it as you would in a normal application. First we will load it
# from disk. We also need to load a face detector to provide the initial
# estimate of the facial location.
predictor = dlib.shape_predictor("predictor.dat")
detector = dlib.get_frontal_face_detector()
# Now let's run the detector and shape_predictor over the images in the faces
# folder and display the results.
print("Showing detections and predictions on the images in the faces folder...")
win = dlib.image_window()
for f in glob.glob(os.path.join(faces_folder, "*.jpg")):
print("Processing file: {}".format(f))
img = dlib.load_rgb_image(f)
win.clear_overlay()
win.set_image(img)
# Ask the detector to find the bounding boxes of each face. The 1 in the
# second argument indicates that we should upsample the image 1 time. This
# will make everything bigger and allow us to detect more faces.
dets = detector(img, 1)
print("Number of faces detected: {}".format(len(dets)))
for k, d in enumerate(dets):
print("Detection {}: Left: {} Top: {} Right: {} Bottom: {}".format(
k, d.left(), d.top(), d.right(), d.bottom()))
# Get the landmarks/parts for the face in box d.
shape = predictor(img, d)
print("Part 0: {}, Part 1: {} ...".format(shape.part(0),
shape.part(1)))
# Draw the face landmarks on the screen.
win.add_overlay(shape)
win.add_overlay(dets)
dlib.hit_enter_to_continue()