blakeblackshear.frigate/frigate/video.py

import os
import time
import datetime
import cv2
import threading
import ctypes
import multiprocessing as mp
import numpy as np
from object_detection.utils import visualization_utils as vis_util
from . util import tonumpyarray
from . object_detection import FramePrepper
from . objects import ObjectCleaner, BestPersonFrame
from . mqtt import MqttObjectPublisher

# fetch the frames as fast a possible and store current frame in a shared memory array
def fetch_frames(shared_arr, shared_frame_time, frame_lock, frame_ready, frame_shape, rtsp_url):
    # convert shared memory array into numpy and shape into image array
    arr = tonumpyarray(shared_arr).reshape(frame_shape)

    # start the video capture
    video = cv2.VideoCapture()
    video.open(rtsp_url)
    print("Opening the RTSP Url...")
    # keep the buffer small so we minimize old data
    video.set(cv2.CAP_PROP_BUFFERSIZE,1)

    bad_frame_counter = 0
    while True:
        # check if the video stream is still open, and reopen if needed
        if not video.isOpened():
            success = video.open(rtsp_url)
            if not success:
                time.sleep(1)
                continue
        # grab the frame, but dont decode it yet
        ret = video.grab()
        # snapshot the time the frame was grabbed
        frame_time = datetime.datetime.now()
        if ret:
            # go ahead and decode the current frame
            ret, frame = video.retrieve()
            if ret:
                # Lock access and update frame
                with frame_lock:
                    arr[:] = frame
                    shared_frame_time.value = frame_time.timestamp()
                # Notify with the condition that a new frame is ready
                with frame_ready:
                    frame_ready.notify_all()
                bad_frame_counter = 0
            else:
                print("Unable to decode frame")
                bad_frame_counter += 1
        else:
            print("Unable to grab a frame")
            bad_frame_counter += 1
        
        if bad_frame_counter > 100:
            video.release()
    
    video.release()

# Stores 2 seconds worth of frames when motion is detected so they can be used for other threads
class FrameTracker(threading.Thread):
    def __init__(self, shared_frame, frame_time, frame_ready, frame_lock, recent_frames):
        threading.Thread.__init__(self)
        self.shared_frame = shared_frame
        self.frame_time = frame_time
        self.frame_ready = frame_ready
        self.frame_lock = frame_lock
        self.recent_frames = recent_frames

    def run(self):
        frame_time = 0.0
        while True:
            now = datetime.datetime.now().timestamp()
            # wait for a frame
            with self.frame_ready:
                # if there isnt a frame ready for processing or it is old, wait for a signal
                if self.frame_time.value == frame_time or (now - self.frame_time.value) > 0.5:
                    self.frame_ready.wait()
            
            # lock and make a copy of the frame
            with self.frame_lock: 
                frame = self.shared_frame.copy()
                frame_time = self.frame_time.value
            
            # add the frame to recent frames
            self.recent_frames[frame_time] = frame

            # delete any old frames
            stored_frame_times = list(self.recent_frames.keys())
            for k in stored_frame_times:
                if (now - k) > 2:
                    del self.recent_frames[k]

def get_frame_shape(rtsp_url):
    # capture a single frame and check the frame shape so the correct array
    # size can be allocated in memory
    video = cv2.VideoCapture(rtsp_url)
    ret, frame = video.read()
    frame_shape = frame.shape
    video.release()
    return frame_shape

def get_rtsp_url(rtsp_config):
    if (rtsp_config['password'].startswith('$')):
        rtsp_config['password'] = os.getenv(rtsp_config['password'][1:])
    return 'rtsp://{}:{}@{}:{}{}'.format(rtsp_config['user'], 
        rtsp_config['password'], rtsp_config['host'], rtsp_config['port'],
        rtsp_config['path'])

class CameraWatchdog(threading.Thread):
    def __init__(self, camera):
        threading.Thread.__init__(self)
        self.camera = camera

    def run(self):

        while True:
            # wait a bit before checking
            time.sleep(60)

            if (datetime.datetime.now().timestamp() - self.camera.shared_frame_time.value) > 2:
                print("last frame is more than 2 seconds old, restarting camera capture...")
                self.camera.start_or_restart_capture()
                time.sleep(5)

class Camera:
    def __init__(self, name, config, prepped_frame_queue, mqtt_client, mqtt_prefix):
        self.name = name
        self.config = config
        self.detected_objects = []
        self.recent_frames = {}
        self.rtsp_url = get_rtsp_url(self.config['rtsp'])
        self.regions = self.config['regions']
        self.frame_shape = get_frame_shape(self.rtsp_url)
        self.mqtt_client = mqtt_client
        self.mqtt_topic_prefix = '{}/{}'.format(mqtt_prefix, self.name)

        # compute the flattened array length from the shape of the frame
        flat_array_length = self.frame_shape[0] * self.frame_shape[1] * self.frame_shape[2]
        # create shared array for storing the full frame image data
        self.shared_frame_array = mp.Array(ctypes.c_uint8, flat_array_length)
        # create shared value for storing the frame_time
        self.shared_frame_time = mp.Value('d', 0.0)
        # Lock to control access to the frame
        self.frame_lock = mp.Lock()
        # Condition for notifying that a new frame is ready
        self.frame_ready = mp.Condition()
        # Condition for notifying that objects were parsed
        self.objects_parsed = mp.Condition()

        # shape current frame so it can be treated as a numpy image
        self.shared_frame_np = tonumpyarray(self.shared_frame_array).reshape(self.frame_shape)

        self.capture_process = None

        # for each region, create a separate thread to resize the region and prep for detection
        self.detection_prep_threads = []
        for region in self.config['regions']:
            # set a default threshold of 0.5 if not defined
            if not 'threshold' in region:
                region['threshold'] = 0.5
            if not isinstance(region['threshold'], float):
                print('Threshold is not a float. Setting to 0.5 default.')
                region['threshold'] = 0.5
            self.detection_prep_threads.append(FramePrepper(
                self.name,
                self.shared_frame_np,
                self.shared_frame_time,
                self.frame_ready,
                self.frame_lock,
                region['size'], region['x_offset'], region['y_offset'], region['threshold'],
                prepped_frame_queue
            ))
        
        # start a thread to store recent motion frames for processing
        self.frame_tracker = FrameTracker(self.shared_frame_np, self.shared_frame_time, 
            self.frame_ready, self.frame_lock, self.recent_frames)
        self.frame_tracker.start()

        # start a thread to store the highest scoring recent person frame
        self.best_person_frame = BestPersonFrame(self.objects_parsed, self.recent_frames, self.detected_objects)
        self.best_person_frame.start()

        # start a thread to expire objects from the detected objects list
        self.object_cleaner = ObjectCleaner(self.objects_parsed, self.detected_objects)
        self.object_cleaner.start()

        # start a thread to publish object scores (currently only person)
        mqtt_publisher = MqttObjectPublisher(self.mqtt_client, self.mqtt_topic_prefix, self.objects_parsed, self.detected_objects)
        mqtt_publisher.start()

        # create a watchdog thread for capture process
        self.watchdog = CameraWatchdog(self)

        # load in the mask for person detection
        if 'mask' in self.config:
            self.mask = cv2.imread("/config/{}".format(self.config['mask']), cv2.IMREAD_GRAYSCALE)
        else:
            self.mask = np.zeros((self.frame_shape[0], self.frame_shape[1], 1), np.uint8)
            self.mask[:] = 255


    def start_or_restart_capture(self):
        if not self.capture_process is None:
            print("Terminating the existing capture process...")
            self.capture_process.terminate()
            del self.capture_process
            self.capture_process = None
            
        # create the process to capture frames from the RTSP stream and store in a shared array
        print("Creating a new capture process...")
        self.capture_process = mp.Process(target=fetch_frames, args=(self.shared_frame_array, 
            self.shared_frame_time, self.frame_lock, self.frame_ready, self.frame_shape, self.rtsp_url))
        self.capture_process.daemon = True
        print("Starting a new capture process...")
        self.capture_process.start()
    
    def start(self):
        self.start_or_restart_capture()
        # start the object detection prep threads
        for detection_prep_thread in self.detection_prep_threads:
            detection_prep_thread.start()
        self.watchdog.start()
    
    def join(self):
        self.capture_process.join()
    
    def get_capture_pid(self):
        return self.capture_process.pid
    
    def add_objects(self, objects):
        if len(objects) == 0:
            return

        for obj in objects:
            if obj['name'] == 'person':
                person_area = (obj['xmax']-obj['xmin'])*(obj['ymax']-obj['ymin'])
                # find the matching region
                region = None
                for r in self.regions:
                    if (
                            obj['xmin'] >= r['x_offset'] and
                            obj['ymin'] >= r['y_offset'] and
                            obj['xmax'] <= r['x_offset']+r['size'] and
                            obj['ymax'] <= r['y_offset']+r['size']
                        ): 
                        region = r
                        break
                
                # if the min person area is larger than the
                # detected person, don't add it to detected objects
                if region and region['min_person_area'] > person_area:
                    continue
            
                # compute the coordinates of the person and make sure
                # the location isnt outide the bounds of the image (can happen from rounding)
                y_location = min(int(obj['ymax']), len(self.mask)-1)
                x_location = min(int((obj['xmax']-obj['xmin'])/2.0), len(self.mask[0])-1)

                # if the person is in a masked location, continue
                if self.mask[y_location][x_location] == [0]:
                    continue

            self.detected_objects.append(obj)

        with self.objects_parsed:
            self.objects_parsed.notify_all()

    def get_best_person(self):
        return self.best_person_frame.best_frame
    
    def get_current_frame_with_objects(self):
        # make a copy of the current detected objects
        detected_objects = self.detected_objects.copy()
        # lock and make a copy of the current frame
        with self.frame_lock:
            frame = self.shared_frame_np.copy()

        # convert to RGB for drawing
        frame = cv2.cvtColor(frame, cv2.COLOR_BGR2RGB)
        # draw the bounding boxes on the screen
        for obj in detected_objects:
            vis_util.draw_bounding_box_on_image_array(frame,
                obj['ymin'],
                obj['xmin'],
                obj['ymax'],
                obj['xmax'],
                color='red',
                thickness=2,
                display_str_list=["{}: {}%".format(obj['name'],int(obj['score']*100))],
                use_normalized_coordinates=False)

        for region in self.regions:
            color = (255,255,255)
            cv2.rectangle(frame, (region['x_offset'], region['y_offset']), 
                (region['x_offset']+region['size'], region['y_offset']+region['size']), 
                color, 2)

        # convert back to BGR
        frame = cv2.cvtColor(frame, cv2.COLOR_RGB2BGR)

        return frame
WIP: convert to camera class 2019-03-30 02:49:27 +01:00			`import os`
initial refactoring 2019-02-26 03:27:02 +01:00			`import time`
			`import datetime`
			`import cv2`
manage 2 seconds worth of motion frames for processing 2019-02-27 03:29:52 +01:00			`import threading`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00			`import ctypes`
			`import multiprocessing as mp`
fix missing import 2019-05-10 13:19:39 +02:00			`import numpy as np`
add back flask endpoints 2019-03-30 03:02:40 +01:00			`from object_detection.utils import visualization_utils as vis_util`
initial refactoring 2019-02-26 03:27:02 +01:00			`from . util import tonumpyarray`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00			`from . object_detection import FramePrepper`
cleanup and update readme 2019-03-30 13:58:31 +01:00			`from . objects import ObjectCleaner, BestPersonFrame`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00			`from . mqtt import MqttObjectPublisher`
initial refactoring 2019-02-26 03:27:02 +01:00
cleanup and update readme 2019-03-30 13:58:31 +01:00			`# fetch the frames as fast a possible and store current frame in a shared memory array`
initial refactoring 2019-02-26 03:27:02 +01:00			`def fetch_frames(shared_arr, shared_frame_time, frame_lock, frame_ready, frame_shape, rtsp_url):`
			`# convert shared memory array into numpy and shape into image array`
			`arr = tonumpyarray(shared_arr).reshape(frame_shape)`

			`# start the video capture`
			`video = cv2.VideoCapture()`
			`video.open(rtsp_url)`
add a watchdog to the capture process to detect silent failures. fixes #27 2019-05-11 14:16:15 +02:00			`print("Opening the RTSP Url...")`
initial refactoring 2019-02-26 03:27:02 +01:00			`# keep the buffer small so we minimize old data`
			`video.set(cv2.CAP_PROP_BUFFERSIZE,1)`

store the best recent person image and reconnect the RTSP stream if unable to grab several consecutive frames 2019-02-28 03:55:07 +01:00			`bad_frame_counter = 0`
initial refactoring 2019-02-26 03:27:02 +01:00			`while True:`
			`# check if the video stream is still open, and reopen if needed`
			`if not video.isOpened():`
			`success = video.open(rtsp_url)`
			`if not success:`
			`time.sleep(1)`
			`continue`
			`# grab the frame, but dont decode it yet`
			`ret = video.grab()`
			`# snapshot the time the frame was grabbed`
			`frame_time = datetime.datetime.now()`
			`if ret:`
			`# go ahead and decode the current frame`
			`ret, frame = video.retrieve()`
			`if ret:`
			`# Lock access and update frame`
			`with frame_lock:`
			`arr[:] = frame`
			`shared_frame_time.value = frame_time.timestamp()`
			`# Notify with the condition that a new frame is ready`
			`with frame_ready:`
			`frame_ready.notify_all()`
store the best recent person image and reconnect the RTSP stream if unable to grab several consecutive frames 2019-02-28 03:55:07 +01:00			`bad_frame_counter = 0`
			`else:`
			`print("Unable to decode frame")`
			`bad_frame_counter += 1`
			`else:`
			`print("Unable to grab a frame")`
			`bad_frame_counter += 1`

			`if bad_frame_counter > 100:`
			`video.release()`
initial refactoring 2019-02-26 03:27:02 +01:00
manage 2 seconds worth of motion frames for processing 2019-02-27 03:29:52 +01:00			`video.release()`

store the best recent person image and reconnect the RTSP stream if unable to grab several consecutive frames 2019-02-28 03:55:07 +01:00			`# Stores 2 seconds worth of frames when motion is detected so they can be used for other threads`
manage 2 seconds worth of motion frames for processing 2019-02-27 03:29:52 +01:00			`class FrameTracker(threading.Thread):`
removing motion detection 2019-03-27 12:17:00 +01:00			`def __init__(self, shared_frame, frame_time, frame_ready, frame_lock, recent_frames):`
manage 2 seconds worth of motion frames for processing 2019-02-27 03:29:52 +01:00			`threading.Thread.__init__(self)`
			`self.shared_frame = shared_frame`
			`self.frame_time = frame_time`
			`self.frame_ready = frame_ready`
			`self.frame_lock = frame_lock`
			`self.recent_frames = recent_frames`

			`def run(self):`
			`frame_time = 0.0`
			`while True:`
removing motion detection 2019-03-27 12:17:00 +01:00			`now = datetime.datetime.now().timestamp()`
			`# wait for a frame`
			`with self.frame_ready:`
			`# if there isnt a frame ready for processing or it is old, wait for a signal`
			`if self.frame_time.value == frame_time or (now - self.frame_time.value) > 0.5:`
			`self.frame_ready.wait()`

			`# lock and make a copy of the frame`
			`with self.frame_lock:`
			`frame = self.shared_frame.copy()`
			`frame_time = self.frame_time.value`

			`# add the frame to recent frames`
			`self.recent_frames[frame_time] = frame`
manage 2 seconds worth of motion frames for processing 2019-02-27 03:29:52 +01:00
removing motion detection 2019-03-27 12:17:00 +01:00			`# delete any old frames`
			`stored_frame_times = list(self.recent_frames.keys())`
			`for k in stored_frame_times:`
			`if (now - k) > 2:`
			`del self.recent_frames[k]`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00
			`def get_frame_shape(rtsp_url):`
			`# capture a single frame and check the frame shape so the correct array`
			`# size can be allocated in memory`
			`video = cv2.VideoCapture(rtsp_url)`
			`ret, frame = video.read()`
			`frame_shape = frame.shape`
			`video.release()`
			`return frame_shape`

			`def get_rtsp_url(rtsp_config):`
			`if (rtsp_config['password'].startswith('$')):`
			`rtsp_config['password'] = os.getenv(rtsp_config['password'][1:])`
			`return 'rtsp://{}:{}@{}:{}{}'.format(rtsp_config['user'],`
			`rtsp_config['password'], rtsp_config['host'], rtsp_config['port'],`
			`rtsp_config['path'])`

add a watchdog to the capture process to detect silent failures. fixes #27 2019-05-11 14:16:15 +02:00			`class CameraWatchdog(threading.Thread):`
			`def __init__(self, camera):`
			`threading.Thread.__init__(self)`
			`self.camera = camera`

			`def run(self):`

			`while True:`
			`# wait a bit before checking`
			`time.sleep(60)`

			`if (datetime.datetime.now().timestamp() - self.camera.shared_frame_time.value) > 2:`
			`print("last frame is more than 2 seconds old, restarting camera capture...")`
			`self.camera.start_or_restart_capture()`
			`time.sleep(5)`

WIP: convert to camera class 2019-03-30 02:49:27 +01:00			`class Camera:`
			`def __init__(self, name, config, prepped_frame_queue, mqtt_client, mqtt_prefix):`
			`self.name = name`
			`self.config = config`
			`self.detected_objects = []`
			`self.recent_frames = {}`
			`self.rtsp_url = get_rtsp_url(self.config['rtsp'])`
			`self.regions = self.config['regions']`
			`self.frame_shape = get_frame_shape(self.rtsp_url)`
			`self.mqtt_client = mqtt_client`
			`self.mqtt_topic_prefix = '{}/{}'.format(mqtt_prefix, self.name)`

			`# compute the flattened array length from the shape of the frame`
			`flat_array_length = self.frame_shape[0] * self.frame_shape[1] * self.frame_shape[2]`
			`# create shared array for storing the full frame image data`
			`self.shared_frame_array = mp.Array(ctypes.c_uint8, flat_array_length)`
			`# create shared value for storing the frame_time`
			`self.shared_frame_time = mp.Value('d', 0.0)`
			`# Lock to control access to the frame`
			`self.frame_lock = mp.Lock()`
			`# Condition for notifying that a new frame is ready`
			`self.frame_ready = mp.Condition()`
			`# Condition for notifying that objects were parsed`
			`self.objects_parsed = mp.Condition()`

			`# shape current frame so it can be treated as a numpy image`
			`self.shared_frame_np = tonumpyarray(self.shared_frame_array).reshape(self.frame_shape)`

add a watchdog to the capture process to detect silent failures. fixes #27 2019-05-11 14:16:15 +02:00			`self.capture_process = None`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00
			`# for each region, create a separate thread to resize the region and prep for detection`
			`self.detection_prep_threads = []`
			`for region in self.config['regions']:`
make the threshold configurable per region. fixes #31 2019-05-11 14:39:27 +02:00			`# set a default threshold of 0.5 if not defined`
			`if not 'threshold' in region:`
			`region['threshold'] = 0.5`
			`if not isinstance(region['threshold'], float):`
			`print('Threshold is not a float. Setting to 0.5 default.')`
			`region['threshold'] = 0.5`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00			`self.detection_prep_threads.append(FramePrepper(`
			`self.name,`
			`self.shared_frame_np,`
			`self.shared_frame_time,`
			`self.frame_ready,`
			`self.frame_lock,`
make the threshold configurable per region. fixes #31 2019-05-11 14:39:27 +02:00			`region['size'], region['x_offset'], region['y_offset'], region['threshold'],`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00			`prepped_frame_queue`
			`))`

			`# start a thread to store recent motion frames for processing`
			`self.frame_tracker = FrameTracker(self.shared_frame_np, self.shared_frame_time,`
			`self.frame_ready, self.frame_lock, self.recent_frames)`
			`self.frame_tracker.start()`

			`# start a thread to store the highest scoring recent person frame`
			`self.best_person_frame = BestPersonFrame(self.objects_parsed, self.recent_frames, self.detected_objects)`
			`self.best_person_frame.start()`

			`# start a thread to expire objects from the detected objects list`
			`self.object_cleaner = ObjectCleaner(self.objects_parsed, self.detected_objects)`
			`self.object_cleaner.start()`

			`# start a thread to publish object scores (currently only person)`
			`mqtt_publisher = MqttObjectPublisher(self.mqtt_client, self.mqtt_topic_prefix, self.objects_parsed, self.detected_objects)`
			`mqtt_publisher.start()`
add the ability to mask the standing location of a person 2019-04-14 18:58:02 +02:00
add a watchdog to the capture process to detect silent failures. fixes #27 2019-05-11 14:16:15 +02:00			`# create a watchdog thread for capture process`
			`self.watchdog = CameraWatchdog(self)`

add the ability to mask the standing location of a person 2019-04-14 18:58:02 +02:00			`# load in the mask for person detection`
			`if 'mask' in self.config:`
			`self.mask = cv2.imread("/config/{}".format(self.config['mask']), cv2.IMREAD_GRAYSCALE)`
			`else:`
			`self.mask = np.zeros((self.frame_shape[0], self.frame_shape[1], 1), np.uint8)`
			`self.mask[:] = 255`
add a watchdog to the capture process to detect silent failures. fixes #27 2019-05-11 14:16:15 +02:00

			`def start_or_restart_capture(self):`
			`if not self.capture_process is None:`
			`print("Terminating the existing capture process...")`
			`self.capture_process.terminate()`
			`del self.capture_process`
			`self.capture_process = None`

			`# create the process to capture frames from the RTSP stream and store in a shared array`
			`print("Creating a new capture process...")`
			`self.capture_process = mp.Process(target=fetch_frames, args=(self.shared_frame_array,`
			`self.shared_frame_time, self.frame_lock, self.frame_ready, self.frame_shape, self.rtsp_url))`
			`self.capture_process.daemon = True`
			`print("Starting a new capture process...")`
			`self.capture_process.start()`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00
			`def start(self):`
add a watchdog to the capture process to detect silent failures. fixes #27 2019-05-11 14:16:15 +02:00			`self.start_or_restart_capture()`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00			`# start the object detection prep threads`
			`for detection_prep_thread in self.detection_prep_threads:`
			`detection_prep_thread.start()`
add a watchdog to the capture process to detect silent failures. fixes #27 2019-05-11 14:16:15 +02:00			`self.watchdog.start()`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00
			`def join(self):`
			`self.capture_process.join()`

			`def get_capture_pid(self):`
			`return self.capture_process.pid`

			`def add_objects(self, objects):`
			`if len(objects) == 0:`
			`return`

			`for obj in objects:`
			`if obj['name'] == 'person':`
			`person_area = (obj['xmax']-obj['xmin'])*(obj['ymax']-obj['ymin'])`
			`# find the matching region`
			`region = None`
			`for r in self.regions:`
			`if (`
			`obj['xmin'] >= r['x_offset'] and`
			`obj['ymin'] >= r['y_offset'] and`
			`obj['xmax'] <= r['x_offset']+r['size'] and`
			`obj['ymax'] <= r['y_offset']+r['size']`
			`):`
			`region = r`
			`break`

			`# if the min person area is larger than the`
			`# detected person, don't add it to detected objects`
			`if region and region['min_person_area'] > person_area:`
			`continue`
add the ability to mask the standing location of a person 2019-04-14 18:58:02 +02:00
			`# compute the coordinates of the person and make sure`
			`# the location isnt outide the bounds of the image (can happen from rounding)`
			`y_location = min(int(obj['ymax']), len(self.mask)-1)`
			`x_location = min(int((obj['xmax']-obj['xmin'])/2.0), len(self.mask[0])-1)`

			`# if the person is in a masked location, continue`
			`if self.mask[y_location][x_location] == [0]:`
			`continue`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00
			`self.detected_objects.append(obj)`

			`with self.objects_parsed:`
			`self.objects_parsed.notify_all()`

			`def get_best_person(self):`
			`return self.best_person_frame.best_frame`
add back flask endpoints 2019-03-30 03:02:40 +01:00
			`def get_current_frame_with_objects(self):`
			`# make a copy of the current detected objects`
			`detected_objects = self.detected_objects.copy()`
			`# lock and make a copy of the current frame`
			`with self.frame_lock:`
			`frame = self.shared_frame_np.copy()`

			`# convert to RGB for drawing`
			`frame = cv2.cvtColor(frame, cv2.COLOR_BGR2RGB)`
			`# draw the bounding boxes on the screen`
			`for obj in detected_objects:`
			`vis_util.draw_bounding_box_on_image_array(frame,`
			`obj['ymin'],`
			`obj['xmin'],`
			`obj['ymax'],`
			`obj['xmax'],`
			`color='red',`
			`thickness=2,`
			`display_str_list=["{}: {}%".format(obj['name'],int(obj['score']*100))],`
			`use_normalized_coordinates=False)`

			`for region in self.regions:`
			`color = (255,255,255)`
			`cv2.rectangle(frame, (region['x_offset'], region['y_offset']),`
			`(region['x_offset']+region['size'], region['y_offset']+region['size']),`
			`color, 2)`

			`# convert back to BGR`
			`frame = cv2.cvtColor(frame, cv2.COLOR_RGB2BGR)`

			`return frame`
WIP: convert to camera class 2019-03-30 02:49:27 +01:00