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rfcat_server
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rfcat_server
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#!/usr/bin/python
from __future__ import print_function
import re
import os
import sys
import cmd
import socket
import threading
from rflib import *
DATA_START_IDX = 4 # without the app/cmd/len bytes, the data starts at byte 4
def splitargs(cmdline):
cmdline = cmdline.replace('\\\\"', '"').replace('\\"', '')
patt = re.compile('\".+?\"|\S+')
for item in cmdline.split('\n'):
return [s.strip('"') for s in patt.findall(item)]
RX = RFST_SRX
TX = RFST_STX
IDLE = RFST_SIDLE
CAL = RFST_SCAL
SYNC_MODES = {
"NONE" : SYNCM_NONE,
"15/16" : SYNCM_15_of_16,
"16/16" : SYNCM_16_of_16,
"CS" : SYNCM_CARRIER,
"CS15/16" : SYNCM_CARRIER_15_of_16,
"CS16/16" : SYNCM_CARRIER_16_of_16,
"CS30/32" : SYNCM_CARRIER_30_of_32,
}
READLINE_MAX_READ_LEN = 1000
class FileSocket(socket.socket):
def __init__(self, sock):
self._buf = ''
self._sock = sock
def __getattr__(self, attr):
if hasattr(self._sock, attr):
return getattr(self._sock, attr)
elif hasattr(self, attr):
return getattr(self.__class__, attr)
def write(self, data):
return self.sendall(data)
def read(self, maxlen):
return self.recv(maxlen)
def readline(self):
idx = self._buf.find('\n')
while idx == -1:
self._buf += self.read(READLINE_MAX_READ_LEN)
idx = self._buf.find('\n')
data = self._buf[:idx]
self._buf = self._buf[idx+1:]
return data
def flush(self):
pass
class KillCfgLoop(Exception):
pass
class CC1111NIC_Server(cmd.Cmd):
intro = """
welcome to the cc1111usb interactive config tool. hack fun!
"""
def __init__(self, nicidx=0, ip='0.0.0.0', nicport=1900, cfgport=1899, go=True, printable=False, rawinput=False):
cmd.Cmd.__init__(self)
self.use_rawinput = rawinput
self.printable = printable
#self.nic = FHSSNIC(nicidx)
self.nic = RfCat(nicidx)
self._ip = ip
self._nicport = nicport
self._nicsock = None
self._cfgport = cfgport
self._cfgsock = None
self._cfgthread = None
self._pause = False
self.startConfigThread()
if go:
self.start()
def start(self):
self._go = True
while self._go:
# serve the NIC port
try:
buf = ''
self._nicsock = socket.socket()
s = self._nicsock
s.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
s.bind((self._ip, self._nicport))
s.listen(100)
while True:
# implement pipe between the usb RF NIC and the TCP socket
try:
print(("Listening for NIC connection on port %d" % self._nicport), file=sys.stderr)
self._nicsock = s.accept()
rs, addr = self._nicsock
rs.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
print("== received DATA connection from %s:%d ==" % (addr))
# handing off the socket for rf_redirection, socket-style
self.nic.rf_redirection( (rs,) )
print(("NIC connection on port %d terminated" % self._nicport), file=sys.stderr)
except KeyboardInterrupt:
self._go = False
break
except:
sys.excepthook(*sys.exc_info())
except KeyboardInterrupt:
self._go = False
except:
sys.excepthook(*sys.exc_info())
def startConfigThread(self):
self._cfgthread = threading.Thread(target=self._cfgRun)
self._cfgthread.setDaemon(True)
self._cfgthread.start()
def _cfgRun(self):
self._cfgsock = socket.socket()
s = self._cfgsock
s.bind((self._ip, self._cfgport))
s.listen(100)
s.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
while True:
try:
self._cfgsock = s.accept()
rs,addr = self._cfgsock
rs.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
print("== received CONFIG connection from %s:%d ==" % (addr))
self.stdin = FileSocket(rs)
self.stdout = self.stdin
self.stderr = self.stdin
while True:
try:
self.cmdloop()
except KillCfgLoop:
break
except:
sys.excepthook(*sys.exc_info())
except:
sys.excepthook(*sys.exc_info())
def do_EOF(self, line):
self.Print("stopping the command loop now..")
#ok so just kill the connection :)
def Print(self, info):
print((info), file=self.stdout)
def do_stop(self, line):
"""
stop the nic
"""
self._pause = True
def do_start(self, line):
"""
start the nic
"""
self._pause = False
#### configuration ####
#def do_specan(self,basefreq=902e6,inc=25e3,count=104):
def do_specan(self,line):
'''
* SPECAN - spectrum analysis mode
'''
basefreq=902e6
inc=25e3
count=104
self.nic._doSpecAn(basefreq,inc,count)
def do_stopspecan(self,line):
'''
* SPECAN - spectrum analysis mode
'''
self.nic._stopSpecAn()
def do_rfmode(self, line):
'''
* RFMODE - set the radio in RX/IDLE/TX/CAL (CAL returns to IDLE)
'''
if len(line):
try:
self.nic.poke(X_RFST, eval(line))
except:
sys.excepthook(*sys.exc_info())
else:
self.Print(repr(self.getMARCSTATE()))
def do_calibrate(self, line):
'''
* CALIBRATE - force the radio to recalibrate. VCO characteristics will change with temperature and supply voltage changes
'''
self.Print("Calibrating radio...")
self.nic.setModeCAL()
while (self.getMARCSTATE()[1] not in (MARC_STATE_IDLE, MARC_STATE_RX, MARC_STATE_TX)):
sys.stdout.write('.')
self.Print("done calibrating.")
def do_modeTX(self, line):
'''
* modeTX - force the radio to the TX state. this should transmit a CARRIER only,
since there is no data which follows quickly. when the radio is placed in TX mode,
no TX_UNF timeouts occur unless at least some data is sent
'''
self.Print("Calibrating radio...")
self.nic.setModeTX()
while (self.getMARCSTATE()[1] not in (MARC_STATE_TX)):
sys.stdout.write('.')
self.Print("Radio has reached the TX state.")
def do_modeRX(self, line):
'''
* modeRX - force the radio to the RX state. this will allow the radio to receive
transmitted data and handle it. if an RX-timeout has been configured (not default)
then the radio should return to Idle state if the RX timeout is reached without
receiving a packet. if a packet is received, the radio returns to whatever state
it is configured to in MCSM1
'''
self.Print("Radio entering RX state...")
self.nic.setModeTX()
while (self.getMARCSTATE()[1] not in (MARC_STATE_RX)):
sys.stdout.write('.')
self.Print("Radio has reached the RX state.")
def do_modeIDLE(self, line):
'''
* modeIDLE - force the radio to the Idle state. no packets will be received or sent.
when exceptions occur in the radio, it must always be placed in the Idle state before
entering RX or TX. this is done automatically in the firmware (default for RX_OVF
and TX_UNF)
'''
self.Print("Radio entering IDLE state...")
self.nic.setModeIDLE()
while (self.getMARCSTATE()[1] not in (MARC_STATE_IDLE)):
sys.stdout.write('.')
self.Print("Radio has reached the IDLE state.")
def do_modeFSTXON(self, line):
'''
* modeFSTXON
'''
self.Print("Radio entering FSTXON state...")
self.nic.setModeFSTXON()
while (self.getMARCSTATE()[1] not in (MARC_STATE_FSTXON)):
sys.stdout.write('.')
self.Print("Radio has reached the FSTXON state.")
def do_modulation(self, line):
'''
* MODULATION - set the RF modulation scheme. values include "2FSK", "GFSK", "4FSK", "MSK", "ASK_OOK". note: GFSK/OOK/ASK only up to 250kbaud, MSK only above 26kbaud and no manchester encoding.
'''
if not len(line) or line not in ("2FSK", "GFSK", "4FSK", "MSK", "ASK_OOK"):
self.Print('need to give me one of the values "2FSK", "GFSK", "4FSK" (experimental), "MSK", "ASK_OOK" got: "%s"' % line)
return
mod = eval("MOD_"+line.strip())
self.nic.setModeIDLE()
self.nic.setMdmModulation(mod)
self.nic.setModeRX()
def complete_modulation(self, text, line, begidx, endidx):
self.Print("complete_modulation: %s %s %s %s") % (repr(text), repr(line), repr(begidx), repr(endidx))
def do_baud(self, line):
'''
* baud <BAUDRATE> - set the datarate, then recalculate channel bandwidth, intermediate frequency, deviation, and offset
'''
baud = int(line)
self.nic.setMdmDRate(baud)
self.nic.calculateMdmDeviatn()
self.nic.calculatePktChanBW()
self.nic.calculateFsIF()
self.nic.calculateFsOffset()
def do_bw(self, line):
'''
* bw [channel_bandwidth] - allow the setting of bandwidth settings separately from "baud"
'''
if len(line):
bw = int(line)
self.nic.setMdmChanBW(bw)
else:
self.Print(self.nic.getMdmChanBW())
def do_drate(self, line):
'''
* drate [datarate hz] - allow the setting of datarate settings separately from "baud"
'''
if len(line):
baud = int(line)
self.nic.setMdmDRate(baud)
else:
self.Print(self.nic.getMdmDRate())
def do_chanspc(self, line):
'''
* chanspc [spacing hz] - set channel spacing
'''
if len(line):
chanspc = int(line)
self.nic.setMdmChanSpc(chanspc)
else:
self.Print(self.nic.getMdmChanSpc())
def do_channel(self, line):
'''
* channel [chan_num] - set the channel
'''
if len(line):
channr = int(line)
self.nic.setChannel(channr)
else:
self.Print(self.nic.getChannel())
def do_freq(self, line):
'''
* freq [frequency hz] - set the base frequency. CHANNL and CHAN_SPC are used to calculate positive offset from this.
'''
if len(line):
freq = int(line)
self.nic.setFreq(freq)
else:
self.Print(self.nic.getFreq())
def do_intfreq(self, line):
'''
* intfreq [IF] - allow the setting of Intermediate Frequency separately from "baud"
'''
if len(line):
IF = int(line)
self.nic.setFsIF(IF)
else:
self.Print(self.nic.getFsIF())
def do_freqoff(self, line):
'''
* freqoff [IF] - allow the setting of Frequency Offset separately from "baud"
'''
if len(line):
fo = int(line)
self.nic.setFsOffset(fo)
else:
self.Print(self.nic.getFsOffset())
def do_vlen(self, line):
'''
* VLEN - configure the NIC for variable-length packets. provide max packet size (FLEN to switch to Fixed)
'''
maxlen = int(line)
self.nic.makePktVLEN(maxlen)
def do_flen(self, line):
'''
* FLEN # - configure the NIC for fixed-length packets. provide packet size (VLEN to switch to Variable)
'''
length = int(line)
self.nic.makePktFLEN(length)
def do_syncword(self, line):
'''
* SYNCWORD #### [double]- set the SYNC word (SYNC1 and SYNC0) (double tells the radio to repeat SYNCWORD twice)
'''
if len(line):
syncword = int(line)
self.setMdmSyncWord(syncword)
else:
self.Print(self.getMdmSyncWord())
def do_syncmode(self, line):
'''
* SYNCMODE - set the SYNCMODE. values include "NONE", "15/16", "16/16", "CS", "CS15/16", "CS16/16", "CS30/32"
'''
if len(line):
syncmode = SYNC_MODES.get(line)
if syncmode is None:
self.Print("please provide a *valid* sync-mode. see the help.")
self.Print(self.nic.setMdmSyncMode(syncmode))
else:
self.Print(self.nic.getMdmSyncMode())
def do_pqt(self, line):
'''
* PQT - set the Preamble Quality Threshold. provide the number of bits (multiple of 4) for PQT. values will be rounded down. 0-3 disables PQT checking.
'''
if len(line):
pqt = int(line)
self.setPktPQT(pqt)
else:
self.Print(self.getPktPQT())
def do_addr(self, line):
'''
* ADDR - configure the NIC's ADDRESS
'''
if len(line):
addr = int(line)
self.nic.setPktAddr(addr)
else:
self.Print(self.nic.getPktAddr())
def do_addr_chk(self, line):
'''
* ADDR_CHK - filter based on the optional address byte. values include "NOCHK", "FULL", "BCAST", indicating no filtering, full filtering, and filtering with broadcasts
'''
if len(line):
addr = int(line)
self.nic.setAddr(addr)
else:
self.Print(self.nic.getAddr())
def do_datawhiten(self, line):
'''
* DATAWHITEN - configure data whitening, include 9-bit PN9 xor sequence in command
'''
if len(line):
if line.startswith("off") or line.startswith("OFF"):
self.nic.setEnablePktDataWhitening(False)
else:
self.nic.setEnablePktDataWhitening(True)
else:
self.Print(self.nic.getPktDataWhitening())
def do_manchester(self, line):
'''
* MANCHESTER [ON | OFF] - configure Manchester encoding to enhance successful transmission. cannot use with MSK modulation or the FEC/Interleaver.
'''
if len(line):
if line.startswith("off") or line.startswith("OFF"):
self.nic.setEnableMdmManchester(False)
else:
self.nic.setEnableMdmManchester(True)
else:
self.Print(self.nic.getEnableMdmManchester())
def do_fec(self, line):
'''
* FEC - enable/disable Forward Error Correction. only works with FIXED LENGTH packets.
'''
if len(line):
if line.startswith("off") or line.startswith("OFF"):
self.nic.setEnableMdmFEC(False)
else:
self.nic.setEnableMdmFEC(True)
else:
self.Print(self.nic.getEnableMdmFEC())
def do_crc(self, line):
'''
* CRC - enable/disable Cyclic Redundancy Check. the last two bytes of a packet will be
considered CRC16 bytes, helpful for determining bad packets.
'''
if len(line):
if line.startswith("off") or line.startswith("OFF"):
self.nic.setEnablePktCRC(False)
else:
self.nic.setEnablePktCRC(True)
else:
self.Print(self.nic.getEnablePktCRC())
def do_DEM_DCFILT(self, line):
'''
* DEM_DCFILT - enable/disable digital DC blocking filter before demodulator. typically not good to muck with.
'''
if len(line):
if line.startswith("off") or line.startswith("OFF"):
self.nic.setEnableMdmDCFilter(False)
else:
self.nic.setEnableMdmDCFilter(True)
else:
self.Print(self.nic.getEnableMdmDCFilter())
def do_MAGN_TARGET(self, line):
'''
* MAGN_TARGET - configure Carrier Sense
'''
if len(line):
pass
else:
pass
def do_MAC_LNA_GAIN(self, line):
'''
* MAX_LNA_GAIN - configure Carrier Sense Threshold
'''
if len(line):
pass
else:
pass
def do_MAX_DVGA_GAIN(self, line):
'''
* MAX_DVGA_GAIN - configure Carrier Sense Threshold (use
'''
if len(line):
pass
else:
pass
def do_CARRIER_SENSE_ABS_THR (self, line):
'''
* CARRIER_SENSE_ABS_THR - configure Carrier Sense Absolute Threshold - values include "6", "10", "14" indicating the dB increase in RSSI
'''
if len(line):
pass
else:
pass
def do_CARRIER_SENSE_REL_THR (self, line):
'''
* CARRIER_SENSE_REL_THR - configure Carrier Sense Relative Threshold - values include "DISABLE", and -7 thru +7 to indicate dB from MAGN_TARGET setting
'''
if len(line):
pass
else:
pass
def do_cca_mode (self, line):
'''
* CCA_MODE - select the Clear Channel Assessment mode. values include "DISABLE", "RSSI", "RECVING", "BOTH".
'''
if len(line):
pass
else:
pass
def do_PA_POWER (self, line):
'''
* PA_POWER - select which PATABLE to use for power settings (0-7) (see CC1110/CC1111 manual SWRS033G section 13.15 and 13.16)
'''
if len(line):
pass
else:
pass
def do_FS_AUTOCAL (self, line):
'''
* FS_AUTOCAL - select mode of auto-VCO-calibration. values include "ON", "OFF", "MANUAL", indicating that calibration should be done when turning the synthesizer ON/OFF or manually
'''
if len(line):
pass
else:
pass
def do_REGS_TEST(self, line):
'''
* set register: TEST2/TEST1/TEST0
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REGS_AGCCTRL(self, line):
'''
* set register: AGCCTRL2/1/0
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REG_PKTCTRL(self, line):
'''
* set register: PKTCTRL1/0
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REG_PKTLEN(self, line):
'''
* set register: PKTLEN
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REG_PKTSTATUS(self, line):
'''
* view register: PKTSTATUS
'''
def do_REGS_MDMCFG(self, line):
'''
* set registers: MDMCFG4/3/2/1/0
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REGS_MCSM(self, line):
'''
* set register: MCSM2/1/0
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REG_DEVIATN(self, line):
'''
* set register: DEVIATN
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REGS_BSCFG_F0CCFG(self, line):
'''
* set register: BSCFG / FOCCFG
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REGS_FSCTRL(self, line):
'''
* set register: FSCTRL1/0
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REGS_FREQ(self, line):
'''
* set register: FREQ2/1/0
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REGS_FREND(self, line):
'''
* set register: FREND1/0
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_REGS_PATABLE(self, line):
'''
* set register: PATABLE7/6/5/4/3/2/1/0
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
def do_show_config(self, line):
'''
* show_config - Print a represented string of the radio configuration
'''
self.Print(self.nic.reprRadioConfig())
def do_dump_config(self, line):
'''
* dump_config - Print a hex representation of the radio configuration registers
'''
self.Print(repr(self.nic.getRadioConfig()))
def do_hack_loose_settings(self, line):
'''
* loose - no CRC, no FEC, no Data Whitening, no sync-word, carrier based receive, etc...
'''
def do_upload_config(self, line):
'''
* upload_config - configure the radio using a python repr string provided to the command
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
self.nic.setModeIDLE()
print("loading config from bytes: %s" % repr(line))
self.setRadioConfig(line)
self.nic.setModeRX()
def do_download_config(self, line):
'''
* download_config - pull current config bytes from radio and dump them in a python repr string
'''
self.Print(repr(self.nic.getRadioConfig()))
def do_save_config(self, line):
'''
* save_config <filename> - save the radio configuration to a file you specify
'''
open(line, "wb").write(repr(self.nic.getRadioConfig()))
def do_load_config(self, line):
'''
* load_config
(be very cautious! the firmware expects certain things like return-to-RX, and no RX-timeout, etc..)
'''
config = open(line, "rb").read()
self.nic.setModeIDLE()
print("loading config from bytes: %s" % repr(config))
self.setRadioConfig(config)
self.nic.setModeRX()
def do_peek(self, line):
'''
* peek <xaddr> [len] - view memory at whatever XDATA address (see the code for details on the memory layout)
'''
args = splitargs(line)
if 0 < len(args) < 3:
if len(args) == 1:
args.append('1')
self.Print(self.peek(int(args[0])), int(args[1]).encode('hex'))
else:
self.Print("please provide exactly one xdata address and an optional length!")
def do_poke(self, line):
'''
* poke - update memory at whatever XDATA address (see the code for details on the memory layout)
'''
args = splitargs(line)
try:
self.nic.poke(int(args[0]), args[1].decode('hex'))
except:
self.Print("please provide exactly one xdata address and hex data")
def do_ping(self, line):
'''
* ping - hello? is the dongle still responding?
'''
self.Print("Successful: %d, Failed: %d, Time: %f" % self.nic.ping())
def do_debug_codes(self, line):
'''
* debugcodes - see what the firmware has stored in it's lastCode[] array
'''
self.Print("lastcode: [%x, %x]") % (self.getDebugCodes())
def do_RESET(self, line):
'''
* reset the dongle
'''
self.Print("Sending the RESET command. Please be patient....")
self.nic.RESET()
def do_rssi(self, line):
'''
* get the last RSSI value
'''
self.Print("RSSI: %x" % (ord(self.getRSSI()) & 0x7f) )
def do_lqi(self, line):
'''
* get the last LQI value
'''
self.Print("%x") % (ord(self.getLQI()))
def do_rfregister(self, line):
'''
rfregister <reg> [value] - set or read a RF register
'''
if len(line):
args = splitargs(line)
val = eval(args[0])
try:
if len(args) > 1:
self.nic.setRFRegister(val)
else:
self.Print("%s : %x" % (args[0], ord(self.nic.peek(val))))
except:
self.Print(sys.exc_info())
else:
self.Print("must include the register to get/set")
def do_printable(self, line):
'''
printable y/n - repr() all data sent to TCP socket for readability of binary data
'''
if len(line):
args = splitargs(line)
val = (args[0])
if val.lower()[0] in ('y', '1'):
self.printable = True
else:
self.printable = False
else:
self.printable = True
self.Print("printable output is: %s" % ('disabled','enabled')[self.printable])
def do_rawinput(self, line):
'''
rawinput y/n - accept in pythonic string reprs (eg. \x80 gets translated to the actual byte '\x80')
input data is run through 'eval' before sending to get a real string from your typed binary input.
'''
if len(line):
args = splitargs(line)
val = (args[0])
if val.lower()[0] in ('y', '1'):
self.use_rawinput = True
else:
self.use_rawinput = False
else:
self.use_rawinput = True
self.Print("raw input is: %s" % ('disabled','enabled')[self.use_rawinput])
'''
def getInterruptRegisters(self):
def testTX(self, data="XYZABCDEFGHIJKL"):
def lowball(self, level=1):
def lowballRestore(self):
def getMACthreshold(self):
def setMACthreshold(self, value):
def setFHSSstate(self, state):
def getFHSSstate(self):
def mac_SyncCell(self, CellID=0x0000):
'''
if __name__ == "__main__":
dongleserver = CC1111NIC_Server()
import atexit
atexit.register(cleanupInteractiveAtExit)