# Compare incomming video with known faces # Running in a local python instance to get around PATH issues # Import time so we can start timing asap import time # Start timing timings = { "st": time.time() } # Import required modules import sys import os import json import configparser import cv2 import dlib import numpy as np import _thread as thread from recorders.video_capture import VideoCapture def init_detector(lock): """Start face detector, encoder and predictor in a new thread""" global face_detector, pose_predictor, face_encoder # Test if at lest 1 of the data files is there and abort if it's not if not os.path.isfile(PATH + "/dlib-data/shape_predictor_5_face_landmarks.dat"): print("Data files have not been downloaded, please run the following commands:") print("\n\tcd " + PATH + "/dlib-data") print("\tsudo ./install.sh\n") lock.release() sys.exit(1) # Use the CNN detector if enabled if use_cnn: face_detector = dlib.cnn_face_detection_model_v1(PATH + "/dlib-data/mmod_human_face_detector.dat") else: face_detector = dlib.get_frontal_face_detector() # Start the others regardless pose_predictor = dlib.shape_predictor(PATH + "/dlib-data/shape_predictor_5_face_landmarks.dat") face_encoder = dlib.face_recognition_model_v1(PATH + "/dlib-data/dlib_face_recognition_resnet_model_v1.dat") # Note the time it took to initialize detectors timings["ll"] = time.time() - timings["ll"] lock.release() # Make sure we were given an username to tast against if len(sys.argv) < 2: sys.exit(12) # Get the absolute path to the current directory PATH = os.path.abspath(__file__ + "/..") # The username of the user being authenticated user = sys.argv[1] # The model file contents models = [] # Encoded face models encodings = [] # Amount of ingnored dark frames dark_tries = 0 # Total amount of frames captured frames = 0 # face recognition/detection instances face_detector = None pose_predictor = None face_encoder = None # Try to load the face model from the models folder try: models = json.load(open(PATH + "/models/" + user + ".dat")) for model in models: encodings += model["data"] except FileNotFoundError: sys.exit(10) # Check if the file contains a model if len(models) < 1: sys.exit(10) # Read config from disk config = configparser.ConfigParser() config.read(PATH + "/config.ini") # Get all config values needed use_cnn = config.getboolean("core", "use_cnn", fallback=False) timeout = config.getint("video", "timeout", fallback=5) dark_threshold = config.getfloat("video", "dark_threshold", fallback=50.0) video_certainty = config.getfloat("video", "certainty", fallback=3.5) / 10 end_report = config.getboolean("debug", "end_report", fallback=False) # Save the time needed to start the script timings["in"] = time.time() - timings["st"] # Import face recognition, takes some time timings["ll"] = time.time() # Start threading and wait for init to finish lock = thread.allocate_lock() lock.acquire() thread.start_new_thread(init_detector, (lock, )) # Start video capture on the IR camera timings["ic"] = time.time() video_capture = VideoCapture(config) # Read exposure from config to use in the main loop exposure = config.getint("video", "exposure", fallback=-1) # Note the time it took to open the camera timings["ic"] = time.time() - timings["ic"] # wait for thread to finish lock.acquire() lock.release() del lock # Fetch the max frame height max_height = config.getfloat("video", "max_height", fallback=0.0) # Get the height of the image height = video_capture.internal.get(cv2.CAP_PROP_FRAME_HEIGHT) or 1 # Calculate the amount the image has to shrink scaling_factor = (max_height / height) or 1 # Fetch config settings out of the loop timeout = config.getint("video", "timeout") dark_threshold = config.getfloat("video", "dark_threshold") end_report = config.getboolean("debug", "end_report") # Start the read loop frames = 0 timings["fr"] = time.time() while True: # Increment the frame count every loop frames += 1 # Stop if we've exceded the time limit if time.time() - timings["fr"] > timeout: sys.exit(11) # Grab a single frame of video frame, gsframe = video_capture.read_frame() # Create a histogram of the image with 8 values hist = cv2.calcHist([gsframe], [0], None, [8], [0, 256]) # All values combined for percentage calculation hist_total = np.sum(hist) # If the image is fully black or the frame exceeds threshold, # skip to the next frame if hist_total == 0 or (hist[0] / hist_total * 100 > dark_threshold): dark_tries += 1 continue # If the hight is too high if scaling_factor != 1: # Apply that factor to the frame frame = cv2.resize(frame, None, fx=scaling_factor, fy=scaling_factor, interpolation=cv2.INTER_AREA) gsframe = cv2.resize(gsframe, None, fx=scaling_factor, fy=scaling_factor, interpolation=cv2.INTER_AREA) # Get all faces from that frame as encodings # Upsamples 1 time face_locations = face_detector(gsframe, 1) # Loop through each face for fl in face_locations: if use_cnn: fl = fl.rect # Fetch the faces in the image face_landmark = pose_predictor(frame, fl) face_encoding = np.array(face_encoder.compute_face_descriptor(frame, face_landmark, 1)) # Match this found face against a known face matches = np.linalg.norm(encodings - face_encoding, axis=1) # Get best match match_index = np.argmin(matches) match = matches[match_index] # Check if a match that's confident enough if 0 < match < video_certainty: timings["tt"] = time.time() - timings["st"] timings["fr"] = time.time() - timings["fr"] # If set to true in the config, print debug text if end_report: def print_timing(label, k): """Helper function to print a timing from the list""" print(" %s: %dms" % (label, round(timings[k] * 1000))) # Print a nice timing report print("Time spent") print_timing("Starting up", "in") print(" Open cam + load libs: %dms" % (round(max(timings["ll"], timings["ic"]) * 1000, ))) print_timing(" Opening the camera", "ic") print_timing(" Importing recognition libs", "ll") print_timing("Searching for known face", "fr") print_timing("Total time", "tt") print("\nResolution") width = video_capture.fw or 1 print(" Native: %dx%d" % (height, width)) # Save the new size for diagnostics scale_height, scale_width = frame.shape[:2] print(" Used: %dx%d" % (scale_height, scale_width)) # Show the total number of frames and calculate the FPS by deviding it by the total scan time print("\nFrames searched: %d (%.2f fps)" % (frames, frames / timings["fr"])) print("Dark frames ignored: %d " % (dark_tries, )) print("Certainty of winning frame: %.3f" % (match * 10, )) print("Winning model: %d (\"%s\")" % (match_index, models[match_index]["label"])) # End peacefully sys.exit(0) if exposure != -1: # For a strange reason on some cameras (e.g. Lenoxo X1E) # setting manual exposure works only after a couple frames # are captured and even after a delay it does not # always work. Setting exposure at every frame is # reliable though. video_capture.intenal.set(cv2.CAP_PROP_AUTO_EXPOSURE, 1.0) # 1 = Manual video_capture.intenal.set(cv2.CAP_PROP_EXPOSURE, float(exposure))