forked from Telos4/RoboRally
152 lines
7.3 KiB
Python
152 lines
7.3 KiB
Python
import socketserver
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import threading
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import time
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import json
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from queue import Queue
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from aruco_estimator import ArucoEstimator
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class MeasurementHandler(socketserver.BaseRequestHandler):
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def handle(self) -> None:
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data = self.request.recv(1024).strip()
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cur_thread = threading.current_thread()
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print(f"start current thread {cur_thread}")
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if 'events' in data.decode():
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print(f"{cur_thread} subscribed to events")
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self.request.sendall('subscribed to events\n'.encode())
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# send any events in the event queue to the subscriber
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event_loop_running = True
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while event_loop_running:
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try:
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while not self.server.estimator.event_queue.empty():
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event = self.server.estimator.event_queue.get()
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# we distinguish two kinds of events:
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if event[0] == 'response_event':
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# 1. for 'response_event' events we expect the event subscriber to give a reply which will then
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# by passed on to the response queue for transmitting to the original correspondent
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message = event[1]['event']
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#print(f"passing command {message} on to subscriber")
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self.request.sendall((json.dumps(message) + '\n').encode())
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reply = self.request.recv(1024)
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#print(f"putting reply {reply} in response queue")
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self.server.response_queue.put(reply)
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else:
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# 2. for other types of events we don't expect a reply and just pass them on to the subscriber
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self.request.sendall((json.dumps(event) + '\n').encode())
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self.server.estimator.last_event = None
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time.sleep(1.0 / self.server.max_measurements_per_second)
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except Exception as e:
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print(f"exception in event loop: {e}")
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event_loop_running = False
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print("after event loop")
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elif 'corners' in data.decode():
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print(f"{cur_thread} subscribed to corners")
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# send positions of the board markers
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corner_estimates = self.server.estimator.corner_estimates
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response = {}
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for corner, data in corner_estimates.items():
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response[corner] = {'x': data['x'], 'y': data['y']}
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self.request.sendall((json.dumps(response) + '\n').encode())
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elif 'move_grid_blocking' in data.decode():
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print(f"{cur_thread} subscribed move_grid_blocking")
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# if we receive a move_grid event
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# ( e.g. move_grid_blocking;{"x":1,"y":1,"dimx":10,"dimy":10,"orientation":"^"} )
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#move_grid_blocking;{"x": 1, "y": 2, "dimx": 7, "dimy": 4, "orientation": ">"}
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# we compute the corresponding real-world position the robot should drive to
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# and then create a new move event which is put in the event queue and will be propagated to the ControlCommander
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data_decode = data.decode()
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#print("data: ", data_decode)
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payload = data_decode.split(';')[1]
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#print("payload: ", payload)
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grid_pos = json.loads(payload)
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#print("grid_pos = ", grid_pos)
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pos = self.server.estimator.get_pos_from_grid_point(grid_pos['x'], grid_pos['y'], grid_pos['dimx'],
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grid_pos['dimy'], grid_pos['orientation'])
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#print("pos = ", pos)
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#print("event requiring response")
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# put blocking move command in event queue
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self.server.estimator.event_queue.put(('response_event',
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{'event': ('move_blocking', {'x': pos[0], 'y': pos[1], 'angle': pos[2]})}))
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# wait for response of the move command
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# TODO this assumes that we wait only for at most one response at a time
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# we could add some kind of reference here to handle multiple responses (e.g. id of the response to wait for)
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while self.server.response_queue.empty():
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time.sleep(0.2)
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self.request.sendall(b'.\n')
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pass
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while not self.server.response_queue.empty():
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reply = self.server.response_queue.get()
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# send back response to the original source
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print(f"sending reply {reply} back to correspondent {self.request}")
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self.request.sendall(reply)
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else:
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print(f"{cur_thread} subscribed to robot position")
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# send robot position
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try:
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marker_id = int(data)
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except ValueError:
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marker_id = None
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if marker_id is not None:
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if marker_id in self.server.estimator.robot_marker_estimates:
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marker_loop_running = True
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while marker_loop_running:
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try:
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self.request.sendall((json.dumps(self.server.estimator.robot_marker_estimates[marker_id])
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+ '\n').encode())
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time.sleep(1.0 / self.server.max_measurements_per_second)
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except Exception as e:
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print(f"exception in marker loop: {e}")
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marker_loop_running = False
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else:
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self.request.sendall("error: unknown robot marker id\n".encode())
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else:
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self.request.sendall("error: data not understood. "
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"expected <robot marker id (int)> or 'events'\n".encode())
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print(f"end current thread {cur_thread}")
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return
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class MeasurementServer(socketserver.ThreadingMixIn, socketserver.TCPServer):
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allow_reuse_address = True
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def __init__(self, server_address, RequestHandlerClass, estimator, max_measurements_per_second=30):
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super().__init__(server_address, RequestHandlerClass)
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self.estimator = estimator
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self.max_measurements_per_second = max_measurements_per_second
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self.response_queue = Queue()
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def handle_error(self, request, client_address):
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print("an error occurred -> terminating connection")
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if __name__ == "__main__":
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aruco_estimator = ArucoEstimator(use_realsense=True, robot_marker_ids=[12, 13])
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# first we start thread for the measurement server
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measurement_server = MeasurementServer(('0.0.0.0', 42424), MeasurementHandler, aruco_estimator,
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max_measurements_per_second=30)
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server_thread = threading.Thread(target=measurement_server.serve_forever)
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server_thread.start()
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# now we start the Aruco estimator GUI
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aruco_estimator.process_frame()
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import sys
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from pyqtgraph.Qt import QtCore, QtGui
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if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'):
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QtGui.QApplication.instance().exec_()
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#with MeasurementServer(('0.0.0.0', 42424), MeasurementHandler, aruco_estimator,
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# max_measurements_per_second=30) as measurement_server:
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# measurement_server.serve_forever()
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# receive with: nc 127.0.0.1 42424 -> 12 + Enter
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