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- import numpy as np
- import scipy.interpolate as interp
- import msgpack
- import json
- import socket
- class ServerSimulator:
- def __init__(self):
- self.events = []
- self.rfwaves = []
- self.time = 0
- #Socket parameters
- self.sock = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
- self.conn = 0
- self.magic = 0xAA
- self.cmd = 0x00
- self.data = {}
- self.simview = {}
- #Simulation parameters
- self.freq = 3e6
- self.level = 20000
- #32bit Codes
- self.errCode = 0x00000000
- self.statCode = 0x00000000
- # Command callbacks
- self.cmd_dict = {
- 0x10: self.addEvent,
- 0x20: self.getRfwaveTable,
- 0x30: self.runEventList,
- 0x00: self.disconnect
- }
- def connect(self, host, port):
- self.sock.bind((host, port))
- self.sock.listen(1)
- self.conn, addr = self.sock.accept()
- print(f"New connection from {addr}")
- def disconnect(self):
- self.conn.close()
- def getErrorMsg(self, errCode, errString):
- error = {
- "magic": self.magic,
- "cmd": b'\xFF',
- "code": errCode,
- "message": errString
- }
- return msgpack.packb(error, use_bin_type=True)
- def getStatusMsg(self, statCode, statString):
- status = {
- "magic": self.magic,
- "cmd": b'\xFE',
- "code": statCode,
- "message": statString
- }
- return msgpack.packb(status, use_bin_type=True)
- def acceptCommand(self):
- rawdata = self.sock.recv(4096)
-
- # Check if data is received
- if not rawdata:
- return False
-
- # Unpack data using msgpack
- self.data = msgpack.unpackb(rawdata, raw=False)
- if self.data["magic"] != self.magic:
- print("Invalid magic byte")
- return False
- if self.data["cmd"] not in self.cmd_dict.keys():
- print("Invalid command")
- return False
- print(f"Received command: {self.data['cmd']}")
- # Process command
- self.cmd = self.data["cmd"]
- self.cmd_dict[self.cmd](self.data)
- return True
- def addEvent(self, data):
- if not all (k in data for k in ("time", "duration", "wave", "time_front_rf_trigger", "time_back_rf", "rf_start", "rf_end", "time_adc_trigger", "time_back_adc")):
- print("Missing event parameters")
- self.errCode = 0x00000001 # Missing parameters
- self.conn.sendall(self.getErrorMsg(self.errCode, "Missing event parameters"))
- return False
-
- event = {
- "start_time": data["time"],
- "duration": data["duration"],
- "wave": data["wave"],
- "time_front_rf_trigger": data["time_front_rf_trigger"],
- "time_back_rf_trigger": data["time_back_rf"],
- "rf_start": data["rf_start"],
- "rf_end": data["rf_end"],
- "time_front_adc_trigger": data["time_adc_trigger"],
- "time_back_adc_trigger": data["time_back_adc"],
- }
- if event["start_time"] < self.time:
- print("Event start time is in the past")
- self.errCode = 0x00000002 # Event in the past
- self.conn.sendall(self.getErrorMsg(self.errCode, "Event start time is in the past"))
- return False
-
- self.time = event["start_time"] + event["duration"]
- if event["time_front_rf_trigger"] < 0 or event["time_back_rf_trigger"] < 0 or event["rf_start"] < 0 or event["rf_end"] < 0:
- print("RF trigger times and delays must be non-negative")
- self.errCode = 0x00000003 # Negative times
- self.conn.sendall(self.getErrorMsg(self.errCode, "RF trigger times and delays must be non-negative"))
- return False
- if event["time_front_adc_trigger"] < 0 or event["time_back_adc_trigger"] < 0:
- print("ADC trigger times must be non-negative")
- self.errCode = 0x00000004 # Negative times
- self.conn.sendall(self.getErrorMsg(self.errCode, "ADC trigger times must be non-negative"))
- return False
- if event["time_front_rf_trigger"] > event["duration"] or event["time_back_rf_trigger"] > event["duration"]:
- print("RF trigger times must be within event duration")
- self.errCode = 0x00000005 # RF trigger times out of bounds
- self.conn.sendall(self.getErrorMsg(self.errCode, "RF trigger times must be within event duration"))
- return False
- if event["rf_start"] > event["duration"] or event["rf_end"] > event["duration"]:
- print("RF start and end times must be within event duration")
- self.errCode = 0x00000006 # RF start/end times out of bounds
- self.conn.sendall(self.getErrorMsg(self.errCode, "RF start and end times must be within event duration"))
- return False
- if event["time_front_adc_trigger"] > event["duration"] or event["time_back_adc_trigger"] > event["duration"]:
- print("ADC trigger times must be within event duration")
- self.errCode = 0x00000007 # ADC trigger times out of bounds
- self.conn.sendall(self.getErrorMsg(self.errCode, "ADC trigger times must be within event duration"))
- return False
- if event["time_front_rf_trigger"] < event["time_back_rf_trigger"]:
- print("RF triggers and delays overlap")
- self.errCode = 0x00000008 # RF triggers overlap
- self.conn.sendall(self.getErrorMsg(self.errCode, "RF triggers and delays overlap"))
- return False
- if event["time_front_adc_trigger"] < event["time_back_adc_trigger"]:
- print("ADC triggers overlap")
- self.errCode = 0x00000009 # ADC triggers overlap
- self.conn.sendall(self.getErrorMsg(self.errCode, "ADC triggers overlap"))
- return False
- if event["rf_start"] < event["rf_end"]:
- print("RF start and end times overlap")
- self.errCode = 0x0000000A # RF start/end times overlap
- self.conn.sendall(self.getErrorMsg(self.errCode, "RF start and end times overlap"))
- return False
- if event["rf_start"] < event["time_front_rf_trigger"] or event["rf_end"] > event["time_back_rf_trigger"]:
- print("RF start and end times must be within RF trigger times")
- self.errCode = 0x0000000B # RF start/end times outside triggers
- self.conn.sendall(self.getErrorMsg(self.errCode, "RF start and end times must be within RF trigger times"))
- return False
- if event["rf_end"] - event["rf_start"] < len(self.rfwaves[event["wave"]]):
- print("RF pulse duration must be at least as long as the wave length")
- self.errCode = 0x0000000C # Insufficient RF pulse duration
- self.conn.sendall(self.getErrorMsg(self.errCode, "RF pulse duration must be at least as long as the wave length"))
- return False
- self.events.append(event)
- print(f"Added event: {event}")
- return True
- def getRfwaveTable(self, data):
- if not all (k in data for k in ("wavetype", "total_length", "total_packets", "packet_index", "packet_length")):
- print("Missing RF wave parameters")
- self.errCode = 0x0000000F # Missing parameters
- self.conn.sendall(self.getErrorMsg(self.errCode, "Missing RF wave parameters"))
- return False
- wavetype = data["wavetype"]
- total_length = data["total_length"]
- total_packets = data["total_packets"]
- packet_index = data["packet_index"]
- packet_length = data["packet_length"]
- total_wave_q = np.array([], dtype=np.int16)
- total_wave_i = np.array([], dtype=np.int16)
- self.conn.sendall(self.getStatusMsg(0x00000001, f"Ready to receive RF wave data packet {packet_index+1}/{total_packets} with length {packet_length}"))
- for i in range(total_packets):
- rawdata = self.sock.recv(4096)
- if not rawdata:
- print("No data received for RF wave packet")
- return False
-
- packet_data = msgpack.unpackb(rawdata, raw=False)
- if packet_data["magic"] != self.magic:
- print("Invalid magic byte in RF wave packet")
- self.errCode = 0x00000014 # Invalid magic byte
- self.conn.sendall(self.getErrorMsg(self.errCode, "Invalid magic byte in RF wave packet"))
- return False
- if packet_data["cmd"] != 0x2C:
- print("Invalid command in RF wave packet")
- self.errCode = 0x00000013 # Invalid command
- self.conn.sendall(self.getErrorMsg(self.errCode, "Invalid command in RF wave packet"))
- return False
- if "wavedata_q" not in packet_data or "wavedata_i" not in packet_data:
- print("Missing wave data in RF wave packet")
- self.errCode = 0x00000010 # Missing wave data
- self.conn.sendall(self.getErrorMsg(self.errCode, "Missing wave data in RF wave packet"))
- return False
-
- wave_q = np.frombuffer(packet_data["wavedata_q"], dtype=np.int16)
- wave_i = np.frombuffer(packet_data["wavedata_i"], dtype=np.int16)
- if len(wave_q) != len(wave_i):
- print("In-phase and quadrature wave data must have the same length in RF wave packet")
- self.errCode = 0x00000012 # Mismatched wave data lengths
- self.conn.sendall(self.getErrorMsg(self.errCode, "In-phase and quadrature wave data must have the same length in RF wave packet"))
- return False
- total_wave_q = np.concatenate([total_wave_q, wave_q])
- total_wave_i = np.concatenate([total_wave_i, wave_i])
- print(f"Received RF wave packet {i+1}/{total_packets} with length {len(wave_q)}")
- if len(total_wave_q) != total_length or len(total_wave_i) != total_length:
- print("Total wave data length does not match expected length")
- self.errCode = 0x00000011 # Total length mismatch
- self.conn.sendall(self.getErrorMsg(self.errCode, "Total wave data length does not match expected length"))
- return False
- self.rfwaves.append({data["wavetype"]: (total_wave_q, total_wave_i)})
- return True
-
- def runEventList(self, data):
- time_linspace = np.linspace(0, self.time, self.time+1)
- channel_g = np.ones(self.time, dtype=np.int16) * np.floor(3.3 / 5 * 32767)
- channel_rf_ttl = np.zeros(self.time, dtype=np.int16)
- channel_adc_ttl = np.zeros(self.time, dtype=np.int16)
- channel_rf = np.zeros(self.time, dtype=np.int16)
- for event in self.events:
- print(f"Running event: {event}")
- # Simulate RF pulse
- rf_wave_q = self.rfwaves[event["wave"]][0]
- rf_wave_i = self.rfwaves[event["wave"]][1]
- rf_pulse_length = event["rf_end"] - event["rf_start"]
- rf_trigger_length = event["time_back_rf_trigger"] - event["time_front_rf_trigger"]
- adc_trigger_length = event["time_back_adc_trigger"] - event["time_front_adc_trigger"]
- rf_wave_length = len(rf_wave_q)
- event_length = event["duration"]
- rf_time = np.linspace(0, rf_pulse_length, rf_pulse_length+1)
- rf_trigger_time = np.linspace(0, rf_trigger_length, rf_trigger_length+1)
- adc_trigger_time = np.linspace(0, adc_trigger_length, adc_trigger_length+1)
- event_time = np.linspace(0, event_length, event_length+1)
- if rf_pulse_length < rf_wave_length:
- print("RF pulse length is shorter than RF wave length, cannot run event")
- self.errCode = 0x00000031 # Invalid RF pulse length
- self.conn.sendall(self.getErrorMsg(self.errCode, "RF pulse length is shorter than RF wave length, cannot run event"))
- continue
- print("Interpolating RF wave to fit pulse duration...")
- interp_wave_q = np.zeros(rf_pulse_length, dtype=np.int16)
- interp_wave_i = np.zeros(rf_pulse_length, dtype=np.int16)
- if data["interpolation_method"] == "linear":
- interp_func_q = interp.interp1d(np.linspace(0, rf_wave_length, rf_wave_length), rf_wave_q, kind='linear')
- interp_func_i = interp.interp1d(np.linspace(0, rf_wave_length, rf_wave_length), rf_wave_i, kind='linear')
- interp_wave_q = interp_func_q(rf_time).astype(np.int16)
- interp_wave_i = interp_func_i(rf_time).astype(np.int16)
- elif data["interpolation_method"] == "nearest":
- interp_func_q = interp.interp1d(np.linspace(0, rf_wave_length, rf_wave_length), rf_wave_q, kind='nearest')
- interp_func_i = interp.interp1d(np.linspace(0, rf_wave_length, rf_wave_length), rf_wave_i, kind='nearest')
- interp_wave_q = interp_func_q(rf_time).astype(np.int16)
- interp_wave_i = interp_func_i(rf_time).astype(np.int16)
- elif data["interpolation_method"] == "cubic":
- interp_func_q = interp.interp1d(np.linspace(0, rf_wave_length, rf_wave_length), rf_wave_q, kind='cubic')
- interp_func_i = interp.interp1d(np.linspace(0, rf_wave_length, rf_wave_length), rf_wave_i, kind='cubic')
- interp_wave_q = interp_func_q(rf_time).astype(np.int16)
- interp_wave_i = interp_func_i(rf_time).astype(np.int16)
- channel_rf[event["rf_start"]:event["rf_end"]+1] = np.floor((interp_wave_q * np.cos(2 * np.pi * self.freq * rf_time * 8e-9) - interp_wave_i * np.sin(2 * np.pi * self.freq * rf_time * 8e-9)) / np.sqrt(2)).astype(np.int16)
- channel_rf_ttl[event["time_front_rf_trigger"]:event["time_back_rf_trigger"]+1] = 1
- channel_adc_ttl[event["time_front_adc_trigger"]:event["time_back_adc_trigger"]+1] = 1
- channel_g[event["start_time"]:(event["start_time"]+event["duration"]+1)] = 0
- self.simview = {
- "time": time_linspace,
- "channel_g": channel_g,
- "channel_rf_ttl": channel_rf_ttl,
- "channel_adc_ttl": channel_adc_ttl,
- "channel_rf": channel_rf
- }
- self.conn.sendall(self.getStatusMsg(0x00000032, "Event list simulation complete"))
- return True
-
- def sendSimViewData(self, data):
- data_length = len(self.simview["time"])
- channels = ["channel_g", "channel_rf_ttl", "channel_adc_ttl", "channel_rf"]
- packet_size = 1024
- total_packets = (data_length * len(channels) * 2) // packet_size + 1
- packet_index = 0
- self.conn.sendall(self.getStatusMsg(0x00000043, f"Ready to send simulation data in {total_packets} packets with size {packet_size} bytes"))
- for channel in channels:
- channel_data = self.simview[channel].tobytes()
- for i in range(0, len(channel_data), packet_size):
- packet_num += 1
- packet_data = None
- if i + packet_size > len(channel_data):
- packet_data = channel_data[i:]
- else:
- packet_data = channel_data[i:i+packet_size]
- packet_msg = {
- "magic": self.magic,
- "cmd": 0x33,
- "channel": channel,
- "total_packets": total_packets,
- "packet_index": packet_index,
- "data": packet_data
- }
- self.conn.sendall(msgpack.packb(packet_msg, use_bin_type=True))
- rawdata = self.conn.recv(1024) # Wait for ACK
- ack_data = msgpack.unpackb(rawdata, raw=False)
- if ack_data["magic"] != self.magic or ack_data["cmd"] != 0x41 or ack_data["code"] != packet_index:
- print(f"Invalid ACK for packet {packet_index}")
- self.errCode = 0x00000045 # Invalid ACK
- self.conn.sendall(self.getErrorMsg(self.errCode, f"Invalid ACK for packet {packet_index}"))
- return False
- print("Simulation data sent successfully")
- self.conn.sendall(self.getStatusMsg(0x00000044, "All simulation data packets sent"))
- return True
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