person_detection/person_detection.py - person-detection-app - Gitiles

 """
 SPDX-FileCopyrightText: 2020-present Open Networking Foundation <info@opennetworking.org>
 SPDX-License-Identifier: LicenseRef-ONF-Member-1.01
 """

 from __future__ import print_function

 import cv2
 import logging as log
 import os
 import sys
 import time
 from argparse import ArgumentParser, SUPPRESS
 from imutils import build_montages
 from openvino.inference_engine import IECore
 from base_camera import BaseCamera


 def build_argparser():
     parser = ArgumentParser(add_help=False)
     args = parser.add_argument_group('Options')
     args.add_argument('-h', '--help', action='help', default=SUPPRESS, help='Show this help message and exit.')
     args.add_argument("-m", "--model", help="Required. Path to an .xml file with a trained model.",
                       required=True, type=str)
     args.add_argument("-i", "--input",
                       help="Required. Path to video file or image. 'cam' for capturing video stream from camera",
                       required=True, type=str)
     args.add_argument("-l", "--cpu_extension",
                       help="Optional. Required for CPU custom layers. Absolute path to a shared library with the "
                            "kernels implementations.", type=str, default=None)
     args.add_argument("-pp", "--plugin_dir", help="Optional. Path to a plugin folder", type=str, default=None)
     args.add_argument("-d", "--device",
                       help="Optional. Specify the target device to infer on; CPU, GPU, FPGA, HDDL or MYRIAD is "
                            "acceptable. The demo will look for a suitable plugin for device specified. "
                            "Default value is CPU", default="CPU", type=str)
     args.add_argument("--labels", help="Optional. Path to labels mapping file", default=None, type=str)
     args.add_argument("-pt", "--prob_threshold", help="Optional. Probability threshold for detections filtering",
                       default=0.5, type=float)
     args.add_argument("-ns", help='No show output', action='store_true')

     return parser


 class Camera(BaseCamera):

     def __init__(self, args):
         log.basicConfig(format="[ %(levelname)s ] %(message)s", level=log.INFO, stream=sys.stdout)
         model_xml = args.model
         model_bin = os.path.splitext(model_xml)[0] + ".bin"

         # Read IR
         log.info("Reading IR...")
         net = IECore().read_network(model=model_xml, weights=model_bin)

         assert len(net.inputs.keys()) == 1, "Demo supports only single input topologies"
         assert len(net.outputs) == 1, "Demo supports only single output topologies"
         self.input_blob = next(iter(net.inputs))
         self.out_blob = next(iter(net.outputs))

         log.info("Loading IR to the plugin...")
         self.exec_net = IECore().load_network(network=net, device_name=args.device, num_requests=2)
         # Read and pre-process input image
         self.n, self.c, self.h, self.w = net.inputs[self.input_blob].shape
         del net
         if args.input == 'cam':
             self.input_stream = 0
         elif args.input == 'gstreamer':
             # gst rtp sink
             self.input_stream = 'udpsrc port=5000 caps = " application/x-rtp, encoding-name=JPEG,payload=26" ! rtpjpegdepay ! decodebin ! videoconvert ! appsink'
             #self.input_stream = 'udpsrc port=5000 caps = "application/x-rtp, media=(string)video, clock-rate=(int)90000, encoding-name=(string)H264, payload=(int)96" ! rtph264depay ! decodebin ! videoconvert ! appsink'
         else:
             input_stream = args.input
             assert os.path.isfile(args.input), "Specified input file doesn't exist"

         if args.labels:
             with open(args.labels, 'r') as f:
                 self.labels_map = [x.strip() for x in f]
         else:
             self.labels_map = None

         self.args = args

         super(Camera, self).__init__()

     def __del__(self):
         self.cap.release()
         cv2.destroyAllWindows()

     def frames(self):

         if self.input_stream == 'gstreamer':
             self.cap = cv2.VideoCapture(self.input_stream, cv2.CAP_GSTREAMER)
         else:
             self.cap = cv2.VideoCapture(self.input_stream)

         cur_request_id = 0
         next_request_id = 1

         log.info("Starting inference in async mode...")
         log.info("To switch between sync and async modes press Tab button")
         log.info("To stop the demo execution press Esc button")

         # Async doesn't work if True
         # Request issues = Runtime Error: [REQUEST BUSY]
         self.is_async_mode = False
         #is_async_mode = True
         render_time = 0
         ret, frame = self.cap.read()

         frameList = []

         print("To close the application, press 'CTRL+C' or any key with focus on the output window")

         while True:
             if self.is_async_mode:
                 ret, next_frame = self.cap.read()
             else:
                 ret, frame = self.cap.read()
             if not ret:
                 break
             initial_w = self.cap.get(3)
             initial_h = self.cap.get(4)

             # Main sync point:
             # in the truly Async mode we start the NEXT infer request, while waiting for the CURRENT to complete
             # in the regular mode we start the CURRENT request and immediately wait for it's completion
             inf_start = time.time()
             if self.is_async_mode:
                 if ret:
                     in_frame = cv2.resize(next_frame, (self.w, self.h))
                     in_frame = in_frame.transpose((2, 0, 1))  # Change data layout from HWC to CHW
                     in_frame = in_frame.reshape((self.n, self.c, self.h, self.w))
                     self.exec_net.start_async(request_id=next_request_id, inputs={self.input_blob: in_frame})
             else:
                 if ret:
                     in_frame = cv2.resize(frame, (self.w, self.h))
                     in_frame = in_frame.transpose((2, 0, 1))  # Change data layout from HWC to CHW
                     in_frame = in_frame.reshape((self.n, self.c, self.h, self.w))
                     self.exec_net.start_async(request_id=cur_request_id, inputs={self.input_blob: in_frame})

             if self.exec_net.requests[cur_request_id].wait(-1) == 0:
                 inf_end = time.time()
                 det_time = inf_end - inf_start

                 # Parse detection results of the current request
                 res = self.exec_net.requests[cur_request_id].outputs[self.out_blob]

                 for obj in res[0][0]:
                     # Draw only objects when probability more than specified threshold
                     if obj[2] > self.args.prob_threshold:
                         xmin = int(obj[3] * initial_w)
                         ymin = int(obj[4] * initial_h)
                         xmax = int(obj[5] * initial_w)
                         ymax = int(obj[6] * initial_h)
                         class_id = int(obj[1])
                         # Draw box and label\class_id
                         color = (min(class_id * 12.5, 255), min(class_id * 7, 255), min(class_id * 5, 255))
                         cv2.rectangle(frame, (xmin, ymin), (xmax, ymax), color, 2)
                         det_label = self.labels_map[class_id] if self.labels_map else str(class_id)
                         cv2.putText(frame, det_label + ' ' + str(round(obj[2] * 100, 1)) + ' %', (xmin, ymin - 7),
                                     cv2.FONT_HERSHEY_COMPLEX, 0.6, color, 1)
                         print('Object detected, class_id:', class_id, 'probability:', obj[2], 'xmin:', xmin, 'ymin:', ymin,
                               'xmax:', xmax, 'ymax:', ymax)

                 # Draw performance stats
                 inf_time_message = "Inference time: Not applicable for async mode" if self.is_async_mode else \
                     "Inference time: {:.3f} ms".format(det_time * 1000)
                 render_time_message = "OpenCV rendering time: {:.3f} ms".format(render_time * 1000)
                 if self.is_async_mode:
                     async_mode_message = "Async mode is on. Processing request {}".format(cur_request_id)
                 else:
                     async_mode_message = "Async mode is off. Processing request {}".format(cur_request_id)

                 cv2.putText(frame, inf_time_message, (15, 15), cv2.FONT_HERSHEY_COMPLEX, 0.5, (200, 10, 10), 1)
                 cv2.putText(frame, render_time_message, (15, 30), cv2.FONT_HERSHEY_COMPLEX, 0.5, (10, 10, 200), 1)
                 cv2.putText(frame, async_mode_message, (10, int(initial_h - 20)), cv2.FONT_HERSHEY_COMPLEX, 0.5,
                             (10, 10, 200), 1)

             render_start = time.time()

             yield cv2.imencode('.jpg', frame)[1].tobytes()

             if not self.args.ns:
                 if ret:
                     cv2.imshow("Detection results", frame)
                 render_end = time.time()
                 render_time = render_end - render_start

             if self.is_async_mode:
                 cur_request_id, next_request_id = next_request_id, cur_request_id

                 frame = next_frame
             key = cv2.waitKey(1)
             if key == 27:
                 break
             if 9 == key:
                 self.is_async_mode = not self.is_async_mode
                 log.info("Switched to {} mode".format("async" if self.is_async_mode else "sync"))


 if __name__ == '__main__':
     args = build_argparser().parse_args()
     camera = Camera(args)
     camera.frames()
     del camera
	"""
	SPDX-FileCopyrightText: 2020-present Open Networking Foundation <info@opennetworking.org>
	SPDX-License-Identifier: LicenseRef-ONF-Member-1.01
	"""

	from __future__ import print_function

	import cv2
	import logging as log
	import os
	import sys
	import time
	from argparse import ArgumentParser, SUPPRESS
	from imutils import build_montages
	from openvino.inference_engine import IECore
	from base_camera import BaseCamera


	def build_argparser():
	parser = ArgumentParser(add_help=False)
	args = parser.add_argument_group('Options')
	args.add_argument('-h', '--help', action='help', default=SUPPRESS, help='Show this help message and exit.')
	args.add_argument("-m", "--model", help="Required. Path to an .xml file with a trained model.",
	required=True, type=str)
	args.add_argument("-i", "--input",
	help="Required. Path to video file or image. 'cam' for capturing video stream from camera",
	required=True, type=str)
	args.add_argument("-l", "--cpu_extension",
	help="Optional. Required for CPU custom layers. Absolute path to a shared library with the "
	"kernels implementations.", type=str, default=None)
	args.add_argument("-pp", "--plugin_dir", help="Optional. Path to a plugin folder", type=str, default=None)
	args.add_argument("-d", "--device",
	help="Optional. Specify the target device to infer on; CPU, GPU, FPGA, HDDL or MYRIAD is "
	"acceptable. The demo will look for a suitable plugin for device specified. "
	"Default value is CPU", default="CPU", type=str)
	args.add_argument("--labels", help="Optional. Path to labels mapping file", default=None, type=str)
	args.add_argument("-pt", "--prob_threshold", help="Optional. Probability threshold for detections filtering",
	default=0.5, type=float)
	args.add_argument("-ns", help='No show output', action='store_true')

	return parser


	class Camera(BaseCamera):

	def __init__(self, args):
	log.basicConfig(format="[ %(levelname)s ] %(message)s", level=log.INFO, stream=sys.stdout)
	model_xml = args.model
	model_bin = os.path.splitext(model_xml)[0] + ".bin"

	# Read IR
	log.info("Reading IR...")
	net = IECore().read_network(model=model_xml, weights=model_bin)

	assert len(net.inputs.keys()) == 1, "Demo supports only single input topologies"
	assert len(net.outputs) == 1, "Demo supports only single output topologies"
	self.input_blob = next(iter(net.inputs))
	self.out_blob = next(iter(net.outputs))

	log.info("Loading IR to the plugin...")
	self.exec_net = IECore().load_network(network=net, device_name=args.device, num_requests=2)
	# Read and pre-process input image
	self.n, self.c, self.h, self.w = net.inputs[self.input_blob].shape
	del net
	if args.input == 'cam':
	self.input_stream = 0
	elif args.input == 'gstreamer':
	# gst rtp sink
	self.input_stream = 'udpsrc port=5000 caps = " application/x-rtp, encoding-name=JPEG,payload=26" ! rtpjpegdepay ! decodebin ! videoconvert ! appsink'
	#self.input_stream = 'udpsrc port=5000 caps = "application/x-rtp, media=(string)video, clock-rate=(int)90000, encoding-name=(string)H264, payload=(int)96" ! rtph264depay ! decodebin ! videoconvert ! appsink'
	else:
	input_stream = args.input
	assert os.path.isfile(args.input), "Specified input file doesn't exist"

	if args.labels:
	with open(args.labels, 'r') as f:
	self.labels_map = [x.strip() for x in f]
	else:
	self.labels_map = None

	self.args = args

	super(Camera, self).__init__()

	def __del__(self):
	self.cap.release()
	cv2.destroyAllWindows()

	def frames(self):

	if self.input_stream == 'gstreamer':
	self.cap = cv2.VideoCapture(self.input_stream, cv2.CAP_GSTREAMER)
	else:
	self.cap = cv2.VideoCapture(self.input_stream)

	cur_request_id = 0
	next_request_id = 1

	log.info("Starting inference in async mode...")
	log.info("To switch between sync and async modes press Tab button")
	log.info("To stop the demo execution press Esc button")

	# Async doesn't work if True
	# Request issues = Runtime Error: [REQUEST BUSY]
	self.is_async_mode = False
	#is_async_mode = True
	render_time = 0
	ret, frame = self.cap.read()

	frameList = []

	print("To close the application, press 'CTRL+C' or any key with focus on the output window")

	while True:
	if self.is_async_mode:
	ret, next_frame = self.cap.read()
	else:
	ret, frame = self.cap.read()
	if not ret:
	break
	initial_w = self.cap.get(3)
	initial_h = self.cap.get(4)

	# Main sync point:
	# in the truly Async mode we start the NEXT infer request, while waiting for the CURRENT to complete
	# in the regular mode we start the CURRENT request and immediately wait for it's completion
	inf_start = time.time()
	if self.is_async_mode:
	if ret:
	in_frame = cv2.resize(next_frame, (self.w, self.h))
	in_frame = in_frame.transpose((2, 0, 1)) # Change data layout from HWC to CHW
	in_frame = in_frame.reshape((self.n, self.c, self.h, self.w))
	self.exec_net.start_async(request_id=next_request_id, inputs={self.input_blob: in_frame})
	else:
	if ret:
	in_frame = cv2.resize(frame, (self.w, self.h))
	in_frame = in_frame.transpose((2, 0, 1)) # Change data layout from HWC to CHW
	in_frame = in_frame.reshape((self.n, self.c, self.h, self.w))
	self.exec_net.start_async(request_id=cur_request_id, inputs={self.input_blob: in_frame})

	if self.exec_net.requests[cur_request_id].wait(-1) == 0:
	inf_end = time.time()
	det_time = inf_end - inf_start

	# Parse detection results of the current request
	res = self.exec_net.requests[cur_request_id].outputs[self.out_blob]

	for obj in res[0][0]:
	# Draw only objects when probability more than specified threshold
	if obj[2] > self.args.prob_threshold:
	xmin = int(obj[3] * initial_w)
	ymin = int(obj[4] * initial_h)
	xmax = int(obj[5] * initial_w)
	ymax = int(obj[6] * initial_h)
	class_id = int(obj[1])
	# Draw box and label\class_id
	color = (min(class_id * 12.5, 255), min(class_id * 7, 255), min(class_id * 5, 255))
	cv2.rectangle(frame, (xmin, ymin), (xmax, ymax), color, 2)
	det_label = self.labels_map[class_id] if self.labels_map else str(class_id)
	cv2.putText(frame, det_label + ' ' + str(round(obj[2] * 100, 1)) + ' %', (xmin, ymin - 7),
	cv2.FONT_HERSHEY_COMPLEX, 0.6, color, 1)
	print('Object detected, class_id:', class_id, 'probability:', obj[2], 'xmin:', xmin, 'ymin:', ymin,
	'xmax:', xmax, 'ymax:', ymax)

	# Draw performance stats
	inf_time_message = "Inference time: Not applicable for async mode" if self.is_async_mode else \
	"Inference time: {:.3f} ms".format(det_time * 1000)
	render_time_message = "OpenCV rendering time: {:.3f} ms".format(render_time * 1000)
	if self.is_async_mode:
	async_mode_message = "Async mode is on. Processing request {}".format(cur_request_id)
	else:
	async_mode_message = "Async mode is off. Processing request {}".format(cur_request_id)

	cv2.putText(frame, inf_time_message, (15, 15), cv2.FONT_HERSHEY_COMPLEX, 0.5, (200, 10, 10), 1)
	cv2.putText(frame, render_time_message, (15, 30), cv2.FONT_HERSHEY_COMPLEX, 0.5, (10, 10, 200), 1)
	cv2.putText(frame, async_mode_message, (10, int(initial_h - 20)), cv2.FONT_HERSHEY_COMPLEX, 0.5,
	(10, 10, 200), 1)

	render_start = time.time()

	yield cv2.imencode('.jpg', frame)[1].tobytes()

	if not self.args.ns:
	if ret:
	cv2.imshow("Detection results", frame)
	render_end = time.time()
	render_time = render_end - render_start

	if self.is_async_mode:
	cur_request_id, next_request_id = next_request_id, cur_request_id

	frame = next_frame
	key = cv2.waitKey(1)
	if key == 27:
	break
	if 9 == key:
	self.is_async_mode = not self.is_async_mode
	log.info("Switched to {} mode".format("async" if self.is_async_mode else "sync"))


	if __name__ == '__main__':
	args = build_argparser().parse_args()
	camera = Camera(args)
	camera.frames()
	del camera