"""Handle outputting birdseye frames via jsmpeg and go2rtc.""" import datetime import glob import logging import math import multiprocessing as mp import os import queue import subprocess as sp import threading import traceback import cv2 import numpy as np from frigate.comms.config_updater import ConfigSubscriber from frigate.config import BirdseyeModeEnum, FrigateConfig from frigate.const import BASE_DIR, BIRDSEYE_PIPE from frigate.util.image import ( SharedMemoryFrameManager, copy_yuv_to_position, get_yuv_crop, ) logger = logging.getLogger(__name__) def get_standard_aspect_ratio(width: int, height: int) -> tuple[int, int]: """Ensure that only standard aspect ratios are used.""" # it is important that all ratios have the same scale known_aspects = [ (16, 9), (9, 16), (20, 10), (16, 3), # max wide camera (16, 6), # reolink duo 2 (32, 9), # panoramic cameras (12, 9), (9, 12), (22, 15), # Amcrest, NTSC DVT (1, 1), # fisheye ] # aspects are scaled to have common relative size known_aspects_ratios = list( map(lambda aspect: aspect[0] / aspect[1], known_aspects) ) closest = min( known_aspects_ratios, key=lambda x: abs(x - (width / height)), ) return known_aspects[known_aspects_ratios.index(closest)] def get_canvas_shape(width: int, height: int) -> tuple[int, int]: """Get birdseye canvas shape.""" canvas_width = width canvas_height = height a_w, a_h = get_standard_aspect_ratio(width, height) if round(a_w / a_h, 2) != round(width / height, 2): canvas_width = int(width // 4 * 4) canvas_height = int((canvas_width / a_w * a_h) // 4 * 4) logger.warning( f"The birdseye resolution is a non-standard aspect ratio, forcing birdseye resolution to {canvas_width} x {canvas_height}" ) return (canvas_width, canvas_height) class Canvas: def __init__( self, canvas_width: int, canvas_height: int, scaling_factor: int, ) -> None: self.scaling_factor = scaling_factor gcd = math.gcd(canvas_width, canvas_height) self.aspect = get_standard_aspect_ratio( (canvas_width / gcd), (canvas_height / gcd) ) self.width = canvas_width self.height = (self.width * self.aspect[1]) / self.aspect[0] self.coefficient_cache: dict[int, int] = {} self.aspect_cache: dict[str, tuple[int, int]] = {} def get_aspect(self, coefficient: int) -> tuple[int, int]: return (self.aspect[0] * coefficient, self.aspect[1] * coefficient) def get_coefficient(self, camera_count: int) -> int: return self.coefficient_cache.get(camera_count, self.scaling_factor) def set_coefficient(self, camera_count: int, coefficient: int) -> None: self.coefficient_cache[camera_count] = coefficient def get_camera_aspect( self, cam_name: str, camera_width: int, camera_height: int ) -> tuple[int, int]: cached = self.aspect_cache.get(cam_name) if cached: return cached gcd = math.gcd(camera_width, camera_height) camera_aspect = get_standard_aspect_ratio( camera_width / gcd, camera_height / gcd ) self.aspect_cache[cam_name] = camera_aspect return camera_aspect class FFMpegConverter(threading.Thread): def __init__( self, camera: str, input_queue: queue.Queue, stop_event: mp.Event, in_width: int, in_height: int, out_width: int, out_height: int, quality: int, birdseye_rtsp: bool = False, ): threading.Thread.__init__(self) self.name = f"{camera}_output_converter" self.camera = camera self.input_queue = input_queue self.stop_event = stop_event self.bd_pipe = None if birdseye_rtsp: self.recreate_birdseye_pipe() ffmpeg_cmd = [ "ffmpeg", "-threads", "1", "-f", "rawvideo", "-pix_fmt", "yuv420p", "-video_size", f"{in_width}x{in_height}", "-i", "pipe:", "-threads", "1", "-f", "mpegts", "-s", f"{out_width}x{out_height}", "-codec:v", "mpeg1video", "-q", f"{quality}", "-bf", "0", "pipe:", ] self.process = sp.Popen( ffmpeg_cmd, stdout=sp.PIPE, stderr=sp.DEVNULL, stdin=sp.PIPE, start_new_session=True, ) def recreate_birdseye_pipe(self) -> None: if self.bd_pipe: os.close(self.bd_pipe) if os.path.exists(BIRDSEYE_PIPE): os.remove(BIRDSEYE_PIPE) os.mkfifo(BIRDSEYE_PIPE, mode=0o777) stdin = os.open(BIRDSEYE_PIPE, os.O_RDONLY | os.O_NONBLOCK) self.bd_pipe = os.open(BIRDSEYE_PIPE, os.O_WRONLY) os.close(stdin) self.reading_birdseye = False def __write(self, b) -> None: self.process.stdin.write(b) if self.bd_pipe: try: os.write(self.bd_pipe, b) self.reading_birdseye = True except BrokenPipeError: if self.reading_birdseye: # we know the pipe was being read from and now it is not # so we should recreate the pipe to ensure no partially-read # frames exist logger.debug( "Recreating the birdseye pipe because it was read from and now is not" ) self.recreate_birdseye_pipe() return def read(self, length): try: return self.process.stdout.read1(length) except ValueError: return False def exit(self): if self.bd_pipe: os.close(self.bd_pipe) self.process.terminate() try: self.process.communicate(timeout=30) except sp.TimeoutExpired: self.process.kill() self.process.communicate() def run(self) -> None: while not self.stop_event.is_set(): try: frame = self.input_queue.get(True, timeout=1) self.__write(frame) except queue.Empty: pass self.exit() class BroadcastThread(threading.Thread): def __init__( self, camera: str, converter: FFMpegConverter, websocket_server, stop_event: mp.Event, ): super(BroadcastThread, self).__init__() self.camera = camera self.converter = converter self.websocket_server = websocket_server self.stop_event = stop_event def run(self): while not self.stop_event.is_set(): buf = self.converter.read(65536) if buf: manager = self.websocket_server.manager with manager.lock: websockets = manager.websockets.copy() ws_iter = iter(websockets.values()) for ws in ws_iter: if ( not ws.terminated and ws.environ["PATH_INFO"] == f"/{self.camera}" ): try: ws.send(buf, binary=True) except ValueError: pass except (BrokenPipeError, ConnectionResetError) as e: logger.debug(f"Websocket unexpectedly closed {e}") elif self.converter.process.poll() is not None: break class BirdsEyeFrameManager: def __init__( self, config: FrigateConfig, frame_manager: SharedMemoryFrameManager, stop_event: mp.Event, ): self.config = config self.mode = config.birdseye.mode self.frame_manager = frame_manager width, height = get_canvas_shape(config.birdseye.width, config.birdseye.height) self.frame_shape = (height, width) self.yuv_shape = (height * 3 // 2, width) self.frame = np.ndarray(self.yuv_shape, dtype=np.uint8) self.canvas = Canvas(width, height, config.birdseye.layout.scaling_factor) self.stop_event = stop_event self.inactivity_threshold = config.birdseye.inactivity_threshold if config.birdseye.layout.max_cameras: self.last_refresh_time = 0 # initialize the frame as black and with the Frigate logo self.blank_frame = np.zeros(self.yuv_shape, np.uint8) self.blank_frame[:] = 128 self.blank_frame[0 : self.frame_shape[0], 0 : self.frame_shape[1]] = 16 # find and copy the logo on the blank frame birdseye_logo = None custom_logo_files = glob.glob(f"{BASE_DIR}/custom.png") if len(custom_logo_files) > 0: birdseye_logo = cv2.imread(custom_logo_files[0], cv2.IMREAD_UNCHANGED) if birdseye_logo is None: logo_files = glob.glob("/opt/frigate/frigate/images/birdseye.png") if len(logo_files) > 0: birdseye_logo = cv2.imread(logo_files[0], cv2.IMREAD_UNCHANGED) if birdseye_logo is not None: transparent_layer = birdseye_logo[:, :, 3] y_offset = height // 2 - transparent_layer.shape[0] // 2 x_offset = width // 2 - transparent_layer.shape[1] // 2 self.blank_frame[ y_offset : y_offset + transparent_layer.shape[1], x_offset : x_offset + transparent_layer.shape[0], ] = transparent_layer else: logger.warning("Unable to read Frigate logo") self.frame[:] = self.blank_frame self.cameras = {} for camera, settings in self.config.cameras.items(): # precalculate the coordinates for all the channels y, u1, u2, v1, v2 = get_yuv_crop( settings.frame_shape_yuv, ( 0, 0, settings.frame_shape[1], settings.frame_shape[0], ), ) self.cameras[camera] = { "dimensions": [settings.detect.width, settings.detect.height], "last_active_frame": 0.0, "current_frame": 0.0, "layout_frame": 0.0, "channel_dims": { "y": y, "u1": u1, "u2": u2, "v1": v1, "v2": v2, }, } self.camera_layout = [] self.active_cameras = set() self.last_output_time = 0.0 def clear_frame(self): logger.debug("Clearing the birdseye frame") self.frame[:] = self.blank_frame def copy_to_position(self, position, camera=None, frame_time=None): if camera is None: frame = None channel_dims = None else: frame = self.frame_manager.get( f"{camera}{frame_time}", self.config.cameras[camera].frame_shape_yuv ) if frame is None: logger.debug(f"Unable to copy frame {camera}{frame_time} to birdseye.") return channel_dims = self.cameras[camera]["channel_dims"] copy_yuv_to_position( self.frame, [position[1], position[0]], [position[3], position[2]], frame, channel_dims, ) def camera_active(self, mode, object_box_count, motion_box_count): if mode == BirdseyeModeEnum.continuous: return True if mode == BirdseyeModeEnum.motion and motion_box_count > 0: return True if mode == BirdseyeModeEnum.objects and object_box_count > 0: return True def update_frame(self): """Update to a new frame for birdseye.""" # determine how many cameras are tracking objects within the last inactivity_threshold seconds active_cameras: set[str] = set( [ cam for cam, cam_data in self.cameras.items() if self.config.cameras[cam].birdseye.enabled and cam_data["last_active_frame"] > 0 and cam_data["current_frame"] - cam_data["last_active_frame"] < self.inactivity_threshold ] ) max_cameras = self.config.birdseye.layout.max_cameras max_camera_refresh = False if max_cameras: now = datetime.datetime.now().timestamp() if len(active_cameras) == max_cameras and now - self.last_refresh_time < 10: # don't refresh cameras too often active_cameras = self.active_cameras else: limited_active_cameras = sorted( active_cameras, key=lambda active_camera: ( self.cameras[active_camera]["current_frame"] - self.cameras[active_camera]["last_active_frame"] ), ) active_cameras = limited_active_cameras[ : self.config.birdseye.layout.max_cameras ] max_camera_refresh = True self.last_refresh_time = now # if there are no active cameras if len(active_cameras) == 0: # if the layout is already cleared if len(self.camera_layout) == 0: return False # if the layout needs to be cleared else: self.camera_layout = [] self.active_cameras = set() self.clear_frame() return True # check if we need to reset the layout because there is a different number of cameras if len(self.active_cameras) - len(active_cameras) == 0: if len(self.active_cameras) == 1 and self.active_cameras != active_cameras: reset_layout = True elif max_camera_refresh: reset_layout = True else: reset_layout = False else: reset_layout = True # reset the layout if it needs to be different if reset_layout: logger.debug("Added new cameras, resetting layout...") self.clear_frame() self.active_cameras = active_cameras # this also converts added_cameras from a set to a list since we need # to pop elements in order active_cameras_to_add = sorted( active_cameras, # sort cameras by order and by name if the order is the same key=lambda active_camera: ( self.config.cameras[active_camera].birdseye.order, active_camera, ), ) if len(active_cameras) == 1: # show single camera as fullscreen camera = active_cameras_to_add[0] camera_dims = self.cameras[camera]["dimensions"].copy() scaled_width = int(self.canvas.height * camera_dims[0] / camera_dims[1]) # center camera view in canvas and ensure that it fits if scaled_width < self.canvas.width: coefficient = 1 x_offset = int((self.canvas.width - scaled_width) / 2) else: coefficient = self.canvas.width / scaled_width x_offset = int( (self.canvas.width - (scaled_width * coefficient)) / 2 ) self.camera_layout = [ [ ( camera, ( x_offset, 0, int(scaled_width * coefficient), int(self.canvas.height * coefficient), ), ) ] ] else: # calculate optimal layout coefficient = self.canvas.get_coefficient(len(active_cameras)) calculating = True # decrease scaling coefficient until height of all cameras can fit into the birdseye canvas while calculating: if self.stop_event.is_set(): return layout_candidate = self.calculate_layout( active_cameras_to_add, coefficient, ) if not layout_candidate: if coefficient < 10: coefficient += 1 continue else: logger.error("Error finding appropriate birdseye layout") return calculating = False self.canvas.set_coefficient(len(active_cameras), coefficient) self.camera_layout = layout_candidate for row in self.camera_layout: for position in row: self.copy_to_position( position[1], position[0], self.cameras[position[0]]["current_frame"] ) return True def calculate_layout( self, cameras_to_add: list[str], coefficient: float, ) -> tuple[any]: """Calculate the optimal layout for 2+ cameras.""" def map_layout(camera_layout: list[list[any]], row_height: int): """Map the calculated layout.""" candidate_layout = [] starting_x = 0 x = 0 max_width = 0 y = 0 for row in camera_layout: final_row = [] max_width = max(max_width, x) x = starting_x for cameras in row: camera_dims = self.cameras[cameras[0]]["dimensions"].copy() camera_aspect = cameras[1] if camera_dims[1] > camera_dims[0]: scaled_height = int(row_height * 2) scaled_width = int(scaled_height * camera_aspect) starting_x = scaled_width else: scaled_height = row_height scaled_width = int(scaled_height * camera_aspect) # layout is too large if ( x + scaled_width > self.canvas.width or y + scaled_height > self.canvas.height ): return x + scaled_width, y + scaled_height, None final_row.append((cameras[0], (x, y, scaled_width, scaled_height))) x += scaled_width y += row_height candidate_layout.append(final_row) if max_width == 0: max_width = x return max_width, y, candidate_layout canvas_aspect_x, canvas_aspect_y = self.canvas.get_aspect(coefficient) camera_layout: list[list[any]] = [] camera_layout.append([]) starting_x = 0 x = starting_x y = 0 y_i = 0 max_y = 0 for camera in cameras_to_add: camera_dims = self.cameras[camera]["dimensions"].copy() camera_aspect_x, camera_aspect_y = self.canvas.get_camera_aspect( camera, camera_dims[0], camera_dims[1] ) if camera_dims[1] > camera_dims[0]: portrait = True else: portrait = False if (x + camera_aspect_x) <= canvas_aspect_x: # insert if camera can fit on current row camera_layout[y_i].append( ( camera, camera_aspect_x / camera_aspect_y, ) ) if portrait: starting_x = camera_aspect_x else: max_y = max( max_y, camera_aspect_y, ) x += camera_aspect_x else: # move on to the next row and insert y += max_y y_i += 1 camera_layout.append([]) x = starting_x if x + camera_aspect_x > canvas_aspect_x: return None camera_layout[y_i].append( ( camera, camera_aspect_x / camera_aspect_y, ) ) x += camera_aspect_x if y + max_y > canvas_aspect_y: return None row_height = int(self.canvas.height / coefficient) total_width, total_height, standard_candidate_layout = map_layout( camera_layout, row_height ) if not standard_candidate_layout: # if standard layout didn't work # try reducing row_height by the % overflow scale_down_percent = max( total_width / self.canvas.width, total_height / self.canvas.height, ) row_height = int(row_height / scale_down_percent) total_width, total_height, standard_candidate_layout = map_layout( camera_layout, row_height ) if not standard_candidate_layout: return None # layout can't be optimized more if total_width / self.canvas.width >= 0.99: return standard_candidate_layout scale_up_percent = min( 1 / (total_width / self.canvas.width), 1 / (total_height / self.canvas.height), ) row_height = int(row_height * scale_up_percent) _, _, scaled_layout = map_layout(camera_layout, row_height) if scaled_layout: return scaled_layout else: return standard_candidate_layout def update(self, camera, object_count, motion_count, frame_time, frame) -> bool: # don't process if birdseye is disabled for this camera camera_config = self.config.cameras[camera].birdseye if not camera_config.enabled: return False # disabling birdseye is a little tricky if not camera_config.enabled: # if we've rendered a frame (we have a value for last_active_frame) # then we need to set it to zero if self.cameras[camera]["last_active_frame"] > 0: self.cameras[camera]["last_active_frame"] = 0 return False # update the last active frame for the camera self.cameras[camera]["current_frame"] = frame_time if self.camera_active(camera_config.mode, object_count, motion_count): self.cameras[camera]["last_active_frame"] = frame_time now = datetime.datetime.now().timestamp() # limit output to 10 fps if (now - self.last_output_time) < 1 / 10: return False try: updated_frame = self.update_frame() except Exception: updated_frame = False self.active_cameras = [] self.camera_layout = [] print(traceback.format_exc()) # if the frame was updated or the fps is too low, send frame if updated_frame or (now - self.last_output_time) > 1: self.last_output_time = now return True return False class Birdseye: def __init__( self, config: FrigateConfig, frame_manager: SharedMemoryFrameManager, stop_event: mp.Event, websocket_server, ) -> None: self.config = config self.input = queue.Queue(maxsize=10) self.converter = FFMpegConverter( "birdseye", self.input, stop_event, config.birdseye.width, config.birdseye.height, config.birdseye.width, config.birdseye.height, config.birdseye.quality, config.birdseye.restream, ) self.broadcaster = BroadcastThread( "birdseye", self.converter, websocket_server, stop_event ) self.birdseye_manager = BirdsEyeFrameManager(config, frame_manager, stop_event) self.config_subscriber = ConfigSubscriber("config/birdseye/") if config.birdseye.restream: self.birdseye_buffer = frame_manager.create( "birdseye", self.birdseye_manager.yuv_shape[0] * self.birdseye_manager.yuv_shape[1], ) self.converter.start() self.broadcaster.start() def write_data( self, camera: str, current_tracked_objects: list[dict[str, any]], motion_boxes: list[list[int]], frame_time: float, frame, ) -> None: # check if there is an updated config while True: ( updated_topic, updated_birdseye_config, ) = self.config_subscriber.check_for_update() if not updated_topic: break camera_name = updated_topic.rpartition("/")[-1] self.config.cameras[camera_name].birdseye = updated_birdseye_config if self.birdseye_manager.update( camera, len([o for o in current_tracked_objects if not o["stationary"]]), len(motion_boxes), frame_time, frame, ): frame_bytes = self.birdseye_manager.frame.tobytes() if self.config.birdseye.restream: self.birdseye_buffer[:] = frame_bytes try: self.input.put_nowait(frame_bytes) except queue.Full: # drop frames if queue is full pass def stop(self) -> None: self.config_subscriber.stop() self.converter.join() self.broadcaster.join()