from abc import ABC, abstractmethod import datetime import time import signal import traceback import collections import numpy as np import cv2 import threading import matplotlib.pyplot as plt import hashlib from multiprocessing import shared_memory from typing import AnyStr def draw_box_with_label(frame, x_min, y_min, x_max, y_max, label, info, thickness=2, color=None, position='ul'): if color is None: color = (0,0,255) display_text = "{}: {}".format(label, info) cv2.rectangle(frame, (x_min, y_min), (x_max, y_max), color, thickness) font_scale = 0.5 font = cv2.FONT_HERSHEY_SIMPLEX # get the width and height of the text box size = cv2.getTextSize(display_text, font, fontScale=font_scale, thickness=2) text_width = size[0][0] text_height = size[0][1] line_height = text_height + size[1] # set the text start position if position == 'ul': text_offset_x = x_min text_offset_y = 0 if y_min < line_height else y_min - (line_height+8) elif position == 'ur': text_offset_x = x_max - (text_width+8) text_offset_y = 0 if y_min < line_height else y_min - (line_height+8) elif position == 'bl': text_offset_x = x_min text_offset_y = y_max elif position == 'br': text_offset_x = x_max - (text_width+8) text_offset_y = y_max # make the coords of the box with a small padding of two pixels textbox_coords = ((text_offset_x, text_offset_y), (text_offset_x + text_width + 2, text_offset_y + line_height)) cv2.rectangle(frame, textbox_coords[0], textbox_coords[1], color, cv2.FILLED) cv2.putText(frame, display_text, (text_offset_x, text_offset_y + line_height - 3), font, fontScale=font_scale, color=(0, 0, 0), thickness=2) def calculate_region(frame_shape, xmin, ymin, xmax, ymax, multiplier=2): # size is larger than longest edge size = int(max(xmax-xmin, ymax-ymin)*multiplier) # dont go any smaller than 300 if size < 300: size = 300 # if the size is too big to fit in the frame if size > min(frame_shape[0], frame_shape[1]): size = min(frame_shape[0], frame_shape[1]) # x_offset is midpoint of bounding box minus half the size x_offset = int((xmax-xmin)/2.0+xmin-size/2.0) # if outside the image if x_offset < 0: x_offset = 0 elif x_offset > (frame_shape[1]-size): x_offset = (frame_shape[1]-size) # y_offset is midpoint of bounding box minus half the size y_offset = int((ymax-ymin)/2.0+ymin-size/2.0) # if outside the image if y_offset < 0: y_offset = 0 elif y_offset > (frame_shape[0]-size): y_offset = (frame_shape[0]-size) return (x_offset, y_offset, x_offset+size, y_offset+size) def yuv_region_2_rgb(frame, region): height = frame.shape[0]//3*2 width = frame.shape[1] # make sure the size is a multiple of 4 size = (region[3] - region[1])//4*4 x1 = region[0] y1 = region[1] uv_x1 = x1//2 uv_y1 = y1//4 uv_width = size//2 uv_height = size//4 u_y_start = height v_y_start = height + height//4 two_x_offset = width//2 yuv_cropped_frame = np.zeros((size+size//2, size), np.uint8) # y channel yuv_cropped_frame[0:size, 0:size] = frame[y1:y1+size, x1:x1+size] # u channel yuv_cropped_frame[size:size+uv_height, 0:uv_width] = frame[uv_y1+u_y_start:uv_y1+u_y_start+uv_height, uv_x1:uv_x1+uv_width] yuv_cropped_frame[size:size+uv_height, uv_width:size] = frame[uv_y1+u_y_start:uv_y1+u_y_start+uv_height, uv_x1+two_x_offset:uv_x1+two_x_offset+uv_width] # v channel yuv_cropped_frame[size+uv_height:size+uv_height*2, 0:uv_width] = frame[uv_y1+v_y_start:uv_y1+v_y_start+uv_height, uv_x1:uv_x1+uv_width] yuv_cropped_frame[size+uv_height:size+uv_height*2, uv_width:size] = frame[uv_y1+v_y_start:uv_y1+v_y_start+uv_height, uv_x1+two_x_offset:uv_x1+two_x_offset+uv_width] return cv2.cvtColor(yuv_cropped_frame, cv2.COLOR_YUV2RGB_I420) def intersection(box_a, box_b): return ( max(box_a[0], box_b[0]), max(box_a[1], box_b[1]), min(box_a[2], box_b[2]), min(box_a[3], box_b[3]) ) def area(box): return (box[2]-box[0] + 1)*(box[3]-box[1] + 1) def intersection_over_union(box_a, box_b): # determine the (x, y)-coordinates of the intersection rectangle intersect = intersection(box_a, box_b) # compute the area of intersection rectangle inter_area = max(0, intersect[2] - intersect[0] + 1) * max(0, intersect[3] - intersect[1] + 1) if inter_area == 0: return 0.0 # compute the area of both the prediction and ground-truth # rectangles box_a_area = (box_a[2] - box_a[0] + 1) * (box_a[3] - box_a[1] + 1) box_b_area = (box_b[2] - box_b[0] + 1) * (box_b[3] - box_b[1] + 1) # compute the intersection over union by taking the intersection # area and dividing it by the sum of prediction + ground-truth # areas - the interesection area iou = inter_area / float(box_a_area + box_b_area - inter_area) # return the intersection over union value return iou def clipped(obj, frame_shape): # if the object is within 5 pixels of the region border, and the region is not on the edge # consider the object to be clipped box = obj[2] region = obj[4] if ((region[0] > 5 and box[0]-region[0] <= 5) or (region[1] > 5 and box[1]-region[1] <= 5) or (frame_shape[1]-region[2] > 5 and region[2]-box[2] <= 5) or (frame_shape[0]-region[3] > 5 and region[3]-box[3] <= 5)): return True else: return False class EventsPerSecond: def __init__(self, max_events=1000): self._start = None self._max_events = max_events self._timestamps = [] def start(self): self._start = datetime.datetime.now().timestamp() def update(self): if self._start is None: self.start() self._timestamps.append(datetime.datetime.now().timestamp()) # truncate the list when it goes 100 over the max_size if len(self._timestamps) > self._max_events+100: self._timestamps = self._timestamps[(1-self._max_events):] def eps(self, last_n_seconds=10): if self._start is None: self.start() # compute the (approximate) events in the last n seconds now = datetime.datetime.now().timestamp() seconds = min(now-self._start, last_n_seconds) return len([t for t in self._timestamps if t > (now-last_n_seconds)]) / seconds def print_stack(sig, frame): traceback.print_stack(frame) def listen(): signal.signal(signal.SIGUSR1, print_stack) class FrameManager(ABC): @abstractmethod def create(self, name, size) -> AnyStr: pass @abstractmethod def get(self, name, timeout_ms=0): pass @abstractmethod def close(self, name): pass @abstractmethod def delete(self, name): pass class DictFrameManager(FrameManager): def __init__(self): self.frames = {} def create(self, name, size) -> AnyStr: mem = bytearray(size) self.frames[name] = mem return mem def get(self, name, shape): mem = self.frames[name] return np.ndarray(shape, dtype=np.uint8, buffer=mem) def close(self, name): pass def delete(self, name): del self.frames[name] class SharedMemoryFrameManager(FrameManager): def __init__(self): self.shm_store = {} def create(self, name, size) -> AnyStr: shm = shared_memory.SharedMemory(name=name, create=True, size=size) self.shm_store[name] = shm return shm.buf def get(self, name, shape): if name in self.shm_store: shm = self.shm_store[name] else: shm = shared_memory.SharedMemory(name=name) self.shm_store[name] = shm return np.ndarray(shape, dtype=np.uint8, buffer=shm.buf) def close(self, name): if name in self.shm_store: self.shm_store[name].close() del self.shm_store[name] def delete(self, name): if name in self.shm_store: self.shm_store[name].close() self.shm_store[name].unlink() del self.shm_store[name]