def group_voice(self, _src_sub, _dst_group, _ts, _end, _peerid, _data):
if _end:
_self_peer = self._config['LOCAL']['RADIO_ID']
_self_src = _self_peer[1:]
if (_peerid == _self_peer) or (_src_sub == _self_src):
self._logger.error('(%s) Just received a packet that appears to have been originated by us. PeerID: %s Subscriber: %s TS: %s, TGID: %s', self._system, int_id(_peerid), int_id(_src_sub), int(_ts), int_id(_dst_group))
return
if trigger == False:
if (_ts == 1 and _dst_group not in trigger_groups_1) or (_ts == 2 and _dst_group not in trigger_groups_2):
return
else:
if (_ts == 1 and _dst_group not in trigger_groups_1) or (_ts == 2 and _dst_group not in trigger_groups_2):
return
self._logger.info('(%s) Event ID: %s - Playback triggered from SourceID: %s, TS: %s, TGID: %s, PeerID: %s', self._system, self.event_id, int_id(_src_sub), _ts, int_id(_dst_group), int_id(_peerid))
# Determine the type of voice packet this is (see top of file for possible types)
_burst_data_type = _data[30]
time.sleep(2)
self.CALL_DATA = pickle.load(open(filename, 'rb'))
self._logger.info('(%s) Event ID: %s - Playing back file: %s', self._system, self.event_id, filename)
for i in self.CALL_DATA:
_tmp_data = i
# re-Write the peer radio ID to that of this program
_tmp_data = _tmp_data.replace(_peerid, _self_peer)
# re-Write the source subscriber ID to that of this program
_tmp_data = _tmp_data.replace(_src_sub, _self_src)
# Re-Write the destination Group ID
_tmp_data = _tmp_data.replace(_tmp_data[9:12], _dst_group)
# Re-Write IPSC timeslot value
_call_info = int_id(_tmp_data[17:18])
if _ts == 1:
_call_info &= ~(1 << 5)
elif _ts == 2:
_call_info |= 1 << 5
_call_info = chr(_call_info)
_tmp_data = _tmp_data[:17] + _call_info + _tmp_data[18:]
# Re-Write DMR timeslot value
# Determine if the slot is present, so we can translate if need be
if _burst_data_type == BURST_DATA_TYPE['SLOT1_VOICE'] or _burst_data_type == BURST_DATA_TYPE['SLOT2_VOICE']:
# Re-Write timeslot if necessary...
if _ts == 1:
_burst_data_type = BURST_DATA_TYPE['SLOT1_VOICE']
elif _ts == 2:
_burst_data_type = BURST_DATA_TYPE['SLOT2_VOICE']
_tmp_data = _tmp_data[:30] + _burst_data_type + _tmp_data[31:]
# Send the packet to all peers in the target IPSC
self.send_to_ipsc(_tmp_data)
time.sleep(0.06)
self.CALL_DATA = []
self._logger.info('(%s) Event ID: %s - Playback Completed', self._system, self.event_id)
self.event_id = self.event_id + 1
def print_peer_list(_config, _network):
_peers = _config['SYSTEMS'][_network]['PEERS']
_status = _config['SYSTEMS'][_network]['MASTER']['STATUS']['PEER_LIST']
#print('Peer List Status for {}: {}' .format(_network, _status))
if _status and not _config['SYSTEMS'][_network]['PEERS']:
print('We are the only peer for: %s' % _network)
print('')
return
print('Peer List for: %s' % _network)
for peer in _peers.keys():
_this_peer = _peers[peer]
_this_peer_stat = _this_peer['STATUS']
if peer == _config['SYSTEMS'][_network]['LOCAL']['RADIO_ID']:
me = '(self)'
else:
me = ''
print('\tRADIO ID: {} {}' .format(int_id(peer), me))
print('\t\tIP Address: {}:{}' .format(_this_peer['IP'], _this_peer['PORT']))
if _this_peer['MODE_DECODE'] and _config['REPORTS']['PRINT_PEERS_INC_MODE']:
print('\t\tMode Values:')
for name, value in _this_peer['MODE_DECODE'].items():
print('\t\t\t{}: {}' .format(name, value))
if _this_peer['FLAGS_DECODE'] and _config['REPORTS']['PRINT_PEERS_INC_FLAGS']:
print('\t\tService Flags:')
for name, value in _this_peer['FLAGS_DECODE'].items():
print('\t\t\t{}: {}' .format(name, value))
print('\t\tStatus: {}, KeepAlives Sent: {}, KeepAlives Outstanding: {}, KeepAlives Missed: {}' .format(_this_peer_stat['CONNECTED'], _this_peer_stat['KEEP_ALIVES_SENT'], _this_peer_stat['KEEP_ALIVES_OUTSTANDING'], _this_peer_stat['KEEP_ALIVES_MISSED']))
print('\t\t KeepAlives Received: {}, Last KeepAlive Received at: {}' .format(_this_peer_stat['KEEP_ALIVES_RECEIVED'], _this_peer_stat['KEEP_ALIVE_RX_TIME']))
print('')
def readConfigFile(self, configFileName, sec, networkName='DEFAULTS'):
config = ConfigParser.ConfigParser()
try:
config.read(configFileName)
if sec == None:
sec = self.defaultOption(config, 'DEFAULTS', 'section', networkName)
if config.has_section(sec) == False:
logger.error('Section ' + sec + ' was not found, using DEFAULTS')
sec = 'DEFAULTS'
self._debug = bool(self.defaultOption(config, sec,'debug', self._debug) == 'True')
self._outToFile = bool(self.defaultOption(config, sec,'outToFile', self._outToFile) == 'True')
self._outToUDP = bool(self.defaultOption(config, sec,'outToUDP', self._outToUDP) == 'True')
self._gateway = self.defaultOption(config, sec,'gateway', self._gateway)
self._gateway_port = int(self.defaultOption(config, sec,'toGatewayPort', self._gateway_port))
self._remote_control_port = int(self.defaultOption(config, sec,'remoteControlPort', self._remote_control_port))
self._ambeRxPort = int(self.defaultOption(config, sec,'fromGatewayPort', self._ambeRxPort))
self._gateway_dmr_id = int(self.defaultOption(config, sec, 'gatewayDmrId', self._gateway_dmr_id))
_tgs = self.defaultOption(config, sec,'tgFilter', str(self._tg_filter).strip('[]'))
self._tg_filter = map(int, _tgs.split(','))
self._tx_tg = hex_str_3(int(self.defaultOption(config, sec, 'txTg', int_id(self._tx_tg))))
self._tx_ts = int(self.defaultOption(config, sec, 'txTs', self._tx_ts))
except ConfigParser.NoOptionError as e:
print('Using a default value:', e)
except:
traceback.print_exc()
sys.exit('Configuration file \''+configFileName+'\' is not a valid configuration file! Exiting...')
def playbackFromUDP(self, _sock):
_delay = 0.055 # Yes, I know it should be 0.06, but there seems to be some latency, so this is a hack
_src_sub = hex_str_3(self._gateway_dmr_id) # DMR ID to sign this transmission with
_src_peer = NETWORK[self._system]['LOCAL']['RADIO_ID'] # Use this peers ID as the source repeater
logger.info('Transmit from gateway to TG {}:'.format(int_id(self._tx_tg)) )
try:
try:
_t = open('template.bin', 'rb') # Open the template file. This was recorded OTA
_tempHead = [0] * 3 # It appears that there 3 frames of HEAD (mostly the same)
for i in range(0, 3):
_tempHead[i] = self.readRecord(_t, BURST_DATA_TYPE['VOICE_HEAD'])
_tempVoice = [0] * 6
for i in range(0, 6): # Then there are 6 frames of AMBE. We will just use them in order
_tempVoice[i] = self.readRecord(_t, BURST_DATA_TYPE['SLOT2_VOICE'])
_tempTerm = self.readRecord(_t, BURST_DATA_TYPE['VOICE_TERM'])
_t.close()
except IOError:
logger.error('Can not open template.bin file')
return
logger.debug('IPSC templates loaded')
_eof = False
self._seq = randint(0,32767) # A transmission uses a random number to begin its sequence (16 bit)
for i in range(0, 3): # Output the 3 HEAD frames to our peers
self.rewriteFrame(_tempHead[i], self._system, self._tx_ts, self._tx_tg, _src_sub, _src_peer)
#self.group_voice(self._system, _src_sub, self._tx_tg, True, '', hex_str_3(0), _tempHead[i])
sleep(_delay)
i = 0 # Initialize the VOICE template index
while(_eof == False):
_ambe = self.readAmbeFrameFromUDP(_sock) # Read the 49*3 bit sample from the stream
if _ambe:
i = (i + 1) % 6 # Round robbin with the 6 VOICE templates
_frame = _tempVoice[i][:33] + _ambe + _tempVoice[i][52:] # Insert the 3 49 bit AMBE frames
self.rewriteFrame(_frame, self._system, self._tx_ts, self._tx_tg, _src_sub, _src_peer)
#self.group_voice(self._system, _src_sub, self._tx_tg, True, '', hex_str_3(0), _frame)
sleep(_delay) # Since this comes from a file we have to add delay between IPSC frames
else:
_eof = True # There are no more AMBE frames, so terminate the loop
self.rewriteFrame(_tempTerm, self._system, self._tx_ts, self._tx_tg, _src_sub, _src_peer)
#self.group_voice(self._system, _src_sub, self._tx_tg, True, '', hex_str_3(0), _tempTerm)
except IOError:
logger.error('Can not transmit to peers')
logger.info('Transmit complete')
def launchUDP(self):
s = socket.socket() # Create a socket object
s.bind(('', self._ambeRxPort)) # Bind to the port
while (1): # Forever!
s.listen(5) # Now wait for client connection.
_sock, addr = s.accept() # Establish connection with client.
if int_id(self._tx_tg) > 0: # Test if we are allowed to transmit
self.playbackFromUDP(_sock, self._system)
else:
self.transmitDisabled(_sock, self._system) #tg is zero, so just eat the network trafic
_sock.close()
def call_mon_status(self, _data):
if not status:
return
_source = _data[1:5]
_ipsc_src = _data[5:9]
_seq_num = _data[9:13]
_ts = _data[13]
_status = _data[15] # suspect [14:16] but nothing in leading byte?
_rf_src = _data[16:19]
_rf_tgt = _data[19:22]
_type = _data[22]
_prio = _data[23]
_sec = _data[24]
_source = str(int_id(_source)) + ', ' + str(get_alias(_source, peer_ids))
_ipsc_src = str(int_id(_ipsc_src)) + ', ' + str(get_alias(_ipsc_src, peer_ids))
_rf_src = str(int_id(_rf_src)) + ', ' + str(get_alias(_rf_src, subscriber_ids))
if _type == '\x4F' or '\x51':
_rf_tgt = 'TGID: ' + str(int_id(_rf_tgt)) + ', ' + str(get_alias(_rf_tgt, talkgroup_ids))
else:
_rf_tgt = 'SID: ' + str(int_id(_rf_tgt)) + ', ' + str(get_alias(_rf_tgt, subscriber_ids))
print('Call Monitor - Call Status')
print('TIME: ', datetime.datetime.now().strftime("%Y-%m-%d %H:%M:%S"))
print('DATA SOURCE: ', _source)
print('IPSC: ', self._system)
print('IPSC Source: ', _ipsc_src)
print('Timeslot: ', TS[_ts])
try:
print('Status: ', STATUS[_status])
except KeyError:
print('Status (unknown): ', h(_status))
try:
print('Type: ', TYPE[_type])
except KeyError:
print('Type (unknown): ', h(_type))
print('Source Sub: ', _rf_src)
print('Target Sub: ', _rf_tgt)
print()
def __init__(self, _name, _config, _logger):
# Housekeeping: create references to the configuration and status data for this IPSC instance.
# Some configuration objects that are used frequently and have lengthy names are shortened
# such as (self._master_sock) expands to (self._config['MASTER']['IP'], self._config['MASTER']['PORT']).
# Note that many of them reference each other... this is the Pythonic way.
#
self._system = _name
self._CONFIG = _config
self._logger = _logger
self._config = self._CONFIG['SYSTEMS'][self._system]
#
self._local = self._config['LOCAL']
self._local_id = self._local['RADIO_ID']
#
self._master = self._config['MASTER']
self._master_stat = self._master['STATUS']
self._master_sock = self._master['IP'], self._master['PORT']
#
self._peers = self._config['PEERS']
#
# This is a regular list to store peers for the IPSC. At times, parsing a simple list is much less
# Spendy than iterating a list of dictionaries... Maybe I'll find a better way in the future. Also
# We have to know when we have a new peer list, so a variable to indicate we do (or don't)
#
args = ()
# Packet 'constructors' - builds the necessary control packets for this IPSC instance.
# This isn't really necessary for anything other than readability (reduction of code golf)
#
# General Items
self.TS_FLAGS = (self._local['MODE'] + self._local['FLAGS'])
#
# Peer Link Maintenance Packets
self.MASTER_REG_REQ_PKT = (MASTER_REG_REQ + self._local_id + self.TS_FLAGS + IPSC_VER)
self.MASTER_ALIVE_PKT = (MASTER_ALIVE_REQ + self._local_id + self.TS_FLAGS + IPSC_VER)
self.PEER_LIST_REQ_PKT = (PEER_LIST_REQ + self._local_id)
self.PEER_REG_REQ_PKT = (PEER_REG_REQ + self._local_id + IPSC_VER)
self.PEER_REG_REPLY_PKT = (PEER_REG_REPLY + self._local_id + IPSC_VER)
self.PEER_ALIVE_REQ_PKT = (PEER_ALIVE_REQ + self._local_id + self.TS_FLAGS)
self.PEER_ALIVE_REPLY_PKT = (PEER_ALIVE_REPLY + self._local_id + self.TS_FLAGS)
#
# Master Link Maintenance Packets
# self.MASTER_REG_REPLY_PKT is not static and must be generated when it is sent
self.MASTER_ALIVE_REPLY_PKT = (MASTER_ALIVE_REPLY + self._local_id + self.TS_FLAGS + IPSC_VER)
self.PEER_LIST_REPLY_PKT = (PEER_LIST_REPLY + self._local_id)
#
# General Link Maintenance Packets
self.DE_REG_REQ_PKT = (DE_REG_REQ + self._local_id)
self.DE_REG_REPLY_PKT = (DE_REG_REPLY + self._local_id)
#
self._logger.info('(%s) IPSC Instance Created: %s, %s:%s', self._system, int_id(self._local['RADIO_ID']), self._local['IP'], self._local['PORT'])
def dmrd_received(self, _peer_id, _rf_src, _dst_id, _seq, _slot, _call_type, _frame_type, _dtype_vseq, _stream_id, _data):
pkt_time = time()
dmrpkt = _data[20:53]
_bits = int_id(_data[15])
if _call_type == 'group':
# Is this is a new call stream?
if (_stream_id != self.STATUS[_slot]['RX_STREAM_ID']):
self.STATUS['RX_START'] = pkt_time
logger.info('(%s) *CALL START* STREAM ID: %s SUB: %s (%s) REPEATER: %s (%s) TGID %s (%s), TS %s', \
self._system, int_id(_stream_id), get_alias(_rf_src, subscriber_ids), int_id(_rf_src), get_alias(_peer_id, peer_ids), int_id(_peer_id), get_alias(_dst_id, talkgroup_ids), int_id(_dst_id), _slot)
# Final actions - Is this a voice terminator?
if (_frame_type == hb_const.HBPF_DATA_SYNC) and (_dtype_vseq == hb_const.HBPF_SLT_VTERM) and (self.STATUS[_slot]['RX_TYPE'] != hb_const.HBPF_SLT_VTERM):
call_duration = pkt_time - self.STATUS['RX_START']
logger.info('(%s) *CALL END* STREAM ID: %s SUB: %s (%s) REPEATER: %s (%s) TGID %s (%s), TS %s, Duration: %s', \
self._system, int_id(_stream_id), get_alias(_rf_src, subscriber_ids), int_id(_rf_src), get_alias(_peer_id, peer_ids), int_id(_peer_id), get_alias(_dst_id, talkgroup_ids), int_id(_dst_id), _slot, call_duration)
self.CALL_DATA.append(_data)
sleep(2)
logger.info('(%s) Playing back transmission from subscriber: %s', self._system, int_id(_rf_src))
for i in self.CALL_DATA:
self.send_system(i)
sleep(0.06)
self.CALL_DATA = []
else:
if not self.CALL_DATA:
logger.info('(%s) Receiving transmission to be played back from subscriber: %s', self._system, int_id(_rf_src))
self.CALL_DATA.append(_data)
# Mark status variables for use later
self.STATUS[_slot]['RX_RFS'] = _rf_src
self.STATUS[_slot]['RX_TYPE'] = _dtype_vseq
self.STATUS[_slot]['RX_TGID'] = _dst_id
self.STATUS[_slot]['RX_TIME'] = pkt_time
self.STATUS[_slot]['RX_STREAM_ID'] = _stream_id
def launchUDP(self, _name):
s = socket.socket() # Create a socket object
s.bind(('', self._ambeRxPort)) # Bind to the port
while (1): # Forever!
s.listen(5) # Now wait for client connection.
_sock, addr = s.accept() # Establish connection with client.
if int_id(self._tx_tg) > 0: # Test if we are allowed to transmit
self.playbackFromUDP(_sock) # SSZ was here.
else:
self.transmitDisabled(
_sock,
self._system) #tg is zero, so just eat the network trafic
_sock.close()
def rule_timer_loop():
logger.info('(ALL IPSC SYSTEMS) Rule timer loop started')
_now = time()
for _bridge in BRIDGES:
for _system in BRIDGES[_bridge]:
if _system['TO_TYPE'] == 'ON':
if _system['ACTIVE'] == True:
if _system['TIMER'] < _now:
_system['ACTIVE'] = False
logger.info(
'Conference Bridge TIMEOUT: DEACTIVATE System: %s, Bridge: %s, TS: %s, TGID: %s',
_system['SYSTEM'], _bridge, _system['TS'],
int_id(_system['TGID']))
else:
timeout_in = _system['TIMER'] - _now
logger.info(
'Conference Bridge ACTIVE (ON timer running): System: %s Bridge: %s, TS: %s, TGID: %s, Timeout in: %ss,',
_system['SYSTEM'], _bridge, _system['TS'],
int_id(_system['TGID']), timeout_in)
elif _system['ACTIVE'] == False:
logger.debug(
'Conference Bridge INACTIVE (no change): System: %s Bridge: %s, TS: %s, TGID: %s',
_system['SYSTEM'], _bridge, _system['TS'],
int_id(_system['TGID']))
elif _system['TO_TYPE'] == 'OFF':
if _system['ACTIVE'] == False:
if _system['TIMER'] < _now:
_system['ACTIVE'] = True
logger.info(
'Conference Bridge TIMEOUT: ACTIVATE System: %s, Bridge: %s, TS: %s, TGID: %s',
_system['SYSTEM'], _bridge, _system['TS'],
int_id(_system['TGID']))
else:
timeout_in = _system['TIMER'] - _now
logger.info(
'Conference Bridge INACTIVE (OFF timer running): System: %s Bridge: %s, TS: %s, TGID: %s, Timeout in: %ss,',
_system['SYSTEM'], _bridge, _system['TS'],
int_id(_system['TGID']), timeout_in)
elif _system['ACTIVE'] == True:
logger.debug(
'Conference Bridge ACTIVE (no change): System: %s Bridge: %s, TS: %s, TGID: %s',
_system['SYSTEM'], _bridge, _system['TS'],
int_id(_system['TGID']))
else:
logger.debug(
'Conference Bridge NO ACTION: System: %s, Bridge: %s, TS: %s, TGID: %s',
_system['SYSTEM'], _bridge, _system['TS'],
int_id(_system['TGID']))
if BRIDGE_CONF['REPORT'] == 'network':
report_server.send_clients('bridge updated')
def rule_timer_loop():
logger.debug('(ALL IPSC) Rule timer loop started')
_now = time()
for _network in RULES:
for _rule in RULES[_network]['GROUP_VOICE']:
if _rule['TO_TYPE'] == 'ON':
if _rule['ACTIVE'] == True:
if _rule['TIMER'] < _now:
_rule['ACTIVE'] = False
logger.info(
'(%s) Rule timout DEACTIVATE: Rule name: %s, Target IPSC: %s, TS: %s, TGID: %s',
_network, _rule['NAME'], _rule['DST_NET'],
_rule['DST_TS'], int_id(_rule['DST_GROUP']))
else:
timeout_in = _rule['TIMER'] - _now
logger.info(
'(%s) Rule ACTIVE with ON timer running: Timeout eligible in: %ds, Rule name: %s, Target IPSC: %s, TS: %s, TGID: %s',
_network, timeout_in, _rule['NAME'],
_rule['DST_NET'], _rule['DST_TS'],
int_id(_rule['DST_GROUP']))
elif _rule['TO_TYPE'] == 'OFF':
if _rule['ACTIVE'] == False:
if _rule['TIMER'] < _now:
_rule['ACTIVE'] = True
logger.info(
'(%s) Rule timout ACTIVATE: Rule name: %s, Target IPSC: %s, TS: %s, TGID: %s',
_network, _rule['NAME'], _rule['DST_NET'],
_rule['DST_TS'], int_id(_rule['DST_GROUP']))
else:
timeout_in = _rule['TIMER'] - _now
logger.info(
'(%s) Rule DEACTIVE with OFF timer running: Timeout eligible in: %ds, Rule name: %s, Target IPSC: %s, TS: %s, TGID: %s',
_network, timeout_in, _rule['NAME'],
_rule['DST_NET'], _rule['DST_TS'],
int_id(_rule['DST_GROUP']))
else:
logger.debug('Rule timer loop made no rule changes')
def bridge_presence_loop(self):
self._logger.debug('(%s) Bridge presence loop initiated', self._system)
_temp_bridge = True
for peer in self.BRIDGES:
_peer = hex_str_4(peer)
if _peer in self._peers.keys() and (
self._peers[_peer]['MODE_DECODE']['TS_1']
or self._peers[_peer]['MODE_DECODE']['TS_2']):
_temp_bridge = False
self._logger.debug('(%s) Peer %s is an active bridge',
self._system, int_id(_peer))
if _peer == self._master['RADIO_ID'] \
and self._master['STATUS']['CONNECTED'] \
and (self._master['MODE_DECODE']['TS_1'] or self._master['MODE_DECODE']['TS_2']):
_temp_bridge = False
self._logger.debug('(%s) Master %s is an active bridge',
self._system, int_id(_peer))
if self.BRIDGE != _temp_bridge:
self._logger.info('(%s) Changing bridge status to: %s',
self._system, _temp_bridge)
self.BRIDGE = _temp_bridge
def rewriteFrame(self, _frame, _newSlot, _newGroup, _newSouceID,
_newPeerID):
_peerid = _frame[1:5] # int32 peer who is sending us a packet
_src_sub = _frame[6:9] # int32 Id of source
_burst_data_type = _frame[30]
########################################################################
# re-Write the peer radio ID to that of this program
_frame = _frame.replace(_peerid, _newPeerID)
# re-Write the source subscriber ID to that of this program
_frame = _frame.replace(_src_sub, _newSouceID)
# Re-Write the destination Group ID
_frame = _frame.replace(_frame[9:12], _newGroup)
# Re-Write IPSC timeslot value
_call_info = int_id(_frame[17:18])
if _newSlot == 1:
_call_info &= ~(1 << 5)
elif _newSlot == 2:
_call_info |= 1 << 5
_call_info = chr(_call_info)
_frame = _frame[:17] + _call_info + _frame[18:]
_x = struct.pack("i", self._seq)
_frame = _frame[:20] + _x[1] + _x[0] + _frame[22:]
self._seq = self._seq + 1
# Re-Write DMR timeslot value
# Determine if the slot is present, so we can translate if need be
if _burst_data_type == BURST_DATA_TYPE[
'SLOT1_VOICE'] or _burst_data_type == BURST_DATA_TYPE[
'SLOT2_VOICE']:
# Re-Write timeslot if necessary...
if _newSlot == 1:
_burst_data_type = BURST_DATA_TYPE['SLOT1_VOICE']
elif _newSlot == 2:
_burst_data_type = BURST_DATA_TYPE['SLOT2_VOICE']
_frame = _frame[:30] + _burst_data_type + _frame[31:]
if (time() - self._busy_slots[_newSlot]
) >= 0.10: # slot is not busy so it is safe to transmit
# Send the packet to all peers in the target IPSC
self.send_to_ipsc(_frame)
else:
logger.info(
'Slot {} is busy, will not transmit packet from gateway'.
format(_newSlot))
def private_voice(self, _src_sub, _dst_sub, _ts, _end, _peerid, _data):
if id == _dst_sub and _ts in ts:
if not _end:
if not self.CALL_DATA:
print(
'({}) Recording transmission from subscriber: {}'.
format(self._system, int_id(_src_sub)))
self.CALL_DATA.append(_data)
if _end:
self.CALL_DATA.append(_data)
print(
'({}) Transmission ended, writing to disk: {}'.format(
self._system, filename))
pickle.dump(self.CALL_DATA, open(filename, 'wb'))
reactor.stop()
print('Recording created, program terminating')
def peer_alive_req(self, _data, _peerid, _host, _port):
_hex_mode = (_data[5])
_hex_flags = (_data[6:10])
_decoded_mode = process_mode_byte(_hex_mode)
_decoded_flags = process_flags_bytes(_hex_flags)
self._peers[_peerid]['MODE'] = _hex_mode
self._peers[_peerid]['MODE_DECODE'] = _decoded_mode
self._peers[_peerid]['FLAGS'] = _hex_flags
self._peers[_peerid]['FLAGS_DECODE'] = _decoded_flags
self.send_packet(self.PEER_ALIVE_REPLY_PKT, (_host, _port))
self.reset_keep_alive(
_peerid
) # Might as well reset our own counter, we know it's out there...
self._logger.debug('(%s) Keep-Alive reply sent to Peer %s, %s:%s',
self._system, int_id(_peerid), _host, _port)
def rewriteFrame( self, _frame, _newSlot, _newGroup, _newSourceID, _newPeerID ):
_peerid = _frame[1:5] # int32 peer who is sending us a packet
_src_sub = _frame[6:9] # int32 Id of source
_burst_data_type = _frame[30]
_group = _frame[9:12]
########################################################################
# re-Write the peer radio ID to that of this program
_frame = _frame.replace(_peerid, _newPeerID, 1)
# re-Write the source subscriber ID + destination Group ID combo in the IPSC Header
_frame = _frame.replace(_src_sub + _group, _newSourceID + _newGroup, 1)
# Re-Write the destination Group ID + source subscriber ID combo in the decoded LCs
_frame = _frame.replace(_group + _src_sub, _newGroup + _newSourceID, 1)
_frame = _frame[:5] + struct.pack("i", self.ipsc_seq)[0] + _frame[6:] # ipsc sequence number increments on each transmission (stream id)
# Re-Write IPSC timeslot value
_call_info = int_id(_frame[17:18])
if _newSlot == 1:
_call_info &= ~(1 << 5)
elif _newSlot == 2:
_call_info |= 1 << 5
_call_info = chr(_call_info)
_frame = _frame[:17] + _call_info + _frame[18:]
_x = struct.pack("i", self._seq)
_frame = _frame[:20] + _x[1] + _x[0] + _frame[22:] # rtp sequence number increments for EACH frame sent out
self._seq = self._seq + 1
# Re-Write DMR timeslot value
# Determine if the slot is present, so we can translate if need be
if _burst_data_type == BURST_DATA_TYPE['SLOT1_VOICE'] or _burst_data_type == BURST_DATA_TYPE['SLOT2_VOICE']:
# Re-Write timeslot if necessary...
if _newSlot == 1:
_burst_data_type = BURST_DATA_TYPE['SLOT1_VOICE']
elif _newSlot == 2:
_burst_data_type = BURST_DATA_TYPE['SLOT2_VOICE']
_frame = _frame[:30] + _burst_data_type + _frame[31:]
if (time() - self._parent._busy_slots[_newSlot]) >= 0.10 : # slot is not busy so it is safe to transmit
# Send the packet to all peers in the target IPSC
self._parent.send_to_ipsc(_frame)
else:
self._logger.info('Slot {} is busy, will not transmit packet from gateway'.format(_newSlot))
self.rx[_newSlot].frame_count += 1 # update count (used for stats and to make sure header was sent)
def print_peer_list(_config, _network):
_peers = _config['SYSTEMS'][_network]['PEERS']
_status = _config['SYSTEMS'][_network]['MASTER']['STATUS']['PEER_LIST']
#print('Peer List Status for {}: {}' .format(_network, _status))
if _status and not _config['SYSTEMS'][_network]['PEERS']:
print('We are the only peer for: %s' % _network)
print('')
return
print('Peer List for: %s' % _network)
for peer in _peers.keys():
_this_peer = _peers[peer]
_this_peer_stat = _this_peer['STATUS']
if peer == _config['SYSTEMS'][_network]['LOCAL']['RADIO_ID']:
me = '(self)'
else:
me = ''
print('\tRADIO ID: {} {}'.format(int_id(peer), me))
print('\t\tIP Address: {}:{}'.format(_this_peer['IP'],
_this_peer['PORT']))
if _this_peer['MODE_DECODE'] and _config['REPORTS'][
'PRINT_PEERS_INC_MODE']:
print('\t\tMode Values:')
for name, value in _this_peer['MODE_DECODE'].items():
print('\t\t\t{}: {}'.format(name, value))
if _this_peer['FLAGS_DECODE'] and _config['REPORTS'][
'PRINT_PEERS_INC_FLAGS']:
print('\t\tService Flags:')
for name, value in _this_peer['FLAGS_DECODE'].items():
print('\t\t\t{}: {}'.format(name, value))
print(
'\t\tStatus: {}, KeepAlives Sent: {}, KeepAlives Outstanding: {}, KeepAlives Missed: {}'
.format(_this_peer_stat['CONNECTED'],
_this_peer_stat['KEEP_ALIVES_SENT'],
_this_peer_stat['KEEP_ALIVES_OUTSTANDING'],
_this_peer_stat['KEEP_ALIVES_MISSED']))
print(
'\t\t KeepAlives Received: {}, Last KeepAlive Received at: {}'
.format(_this_peer_stat['KEEP_ALIVES_RECEIVED'],
_this_peer_stat['KEEP_ALIVE_RX_TIME']))
print('')
def bridge_presence_loop(self):
self._logger.debug('(%s) Bridge presence loop initiated', self._system)
_temp_bridge = True
for peer in self.BRIDGES:
_peer = hex_str_4(peer)
if _peer in self._peers.keys() and (self._peers[_peer]['MODE_DECODE']['TS_1'] or self._peers[_peer]['MODE_DECODE']['TS_2']):
_temp_bridge = False
self._logger.debug('(%s) Peer %s is an active bridge', self._system, int_id(_peer))
if _peer == self._master['RADIO_ID'] \
and self._master['STATUS']['CONNECTED'] \
and (self._master['MODE_DECODE']['TS_1'] or self._master['MODE_DECODE']['TS_2']):
_temp_bridge = False
self._logger.debug('(%s) Master %s is an active bridge',self._system, int_id(_peer))
if self.BRIDGE != _temp_bridge:
self._logger.info('(%s) Changing bridge status to: %s', self._system, _temp_bridge )
self.BRIDGE = _temp_bridge
def build_dmrlink_table(_config, _stats_table):
for _ipsc, _ipsc_data in _config.iteritems():
_stats_table[_ipsc] = {}
_stats_table[_ipsc]['PEERS'] = {}
_stats_table[_ipsc]['MASTER'] = _config[_ipsc]['LOCAL']['MASTER_PEER']
_stats_table[_ipsc]['RADIO_ID'] = int_id(_config[_ipsc]['LOCAL']['RADIO_ID'])
_stats_table[_ipsc]['IP'] = _config[_ipsc]['LOCAL']['IP']
_stats_peers = _stats_table[_ipsc]['PEERS']
# if this peer is the master
if _stats_table[_ipsc]['MASTER'] == False:
_peer = _config[_ipsc]['MASTER']['RADIO_ID']
_config_peer_data = _config[_ipsc]['MASTER']
add_peer(_stats_peers, _peer, _config_peer_data, 'Master')
# for all peers that are not the master
for _peer, _config_peer_data in _config[_ipsc]['PEERS'].iteritems():
if _peer != _config[_ipsc]['LOCAL']['RADIO_ID']:
add_peer(_stats_peers, _peer, _config_peer_data, 'Peer')
def master_reg_reply(self, _data, _peerid):
_hex_mode = _data[5]
_hex_flags = _data[6:10]
_num_peers = _data[10:12]
_decoded_mode = process_mode_byte(_hex_mode)
_decoded_flags = process_flags_bytes(_hex_flags)
self._local['NUM_PEERS'] = int(ahex(_num_peers), 16)
self._master['RADIO_ID'] = _peerid
self._master['MODE'] = _hex_mode
self._master['MODE_DECODE'] = _decoded_mode
self._master['FLAGS'] = _hex_flags
self._master['FLAGS_DECODE'] = _decoded_flags
self._master_stat['CONNECTED'] = True
self._master_stat['KEEP_ALIVES_OUTSTANDING'] = 0
self._logger.warning(
'(%s) Registration response (we requested reg) from the Master: %s, %s:%s (%s peers)',
self._system, int_id(_peerid), self._master['IP'],
self._master['PORT'], self._local['NUM_PEERS'])
def rewriteFrame( self, _frame, _newSlot, _newGroup, _newSouceID, _newPeerID ):
_peerid = _frame[1:5] # int32 peer who is sending us a packet
_src_sub = _frame[6:9] # int32 Id of source
_burst_data_type = _frame[30]
########################################################################
# re-Write the peer radio ID to that of this program
_frame = _frame.replace(_peerid, _newPeerID)
# re-Write the source subscriber ID to that of this program
_frame = _frame.replace(_src_sub, _newSouceID)
# Re-Write the destination Group ID
_frame = _frame.replace(_frame[9:12], _newGroup)
# Re-Write IPSC timeslot value
_call_info = int_id(_frame[17:18])
if _newSlot == 1:
_call_info &= ~(1 << 5)
elif _newSlot == 2:
_call_info |= 1 << 5
_call_info = chr(_call_info)
_frame = _frame[:17] + _call_info + _frame[18:]
_x = struct.pack("i", self._seq)
_frame = _frame[:20] + _x[1] + _x[0] + _frame[22:]
self._seq = self._seq + 1
# Re-Write DMR timeslot value
# Determine if the slot is present, so we can translate if need be
if _burst_data_type == BURST_DATA_TYPE['SLOT1_VOICE'] or _burst_data_type == BURST_DATA_TYPE['SLOT2_VOICE']:
# Re-Write timeslot if necessary...
if _newSlot == 1:
_burst_data_type = BURST_DATA_TYPE['SLOT1_VOICE']
elif _newSlot == 2:
_burst_data_type = BURST_DATA_TYPE['SLOT2_VOICE']
_frame = _frame[:30] + _burst_data_type + _frame[31:]
if (time() - self._busy_slots[_newSlot]) >= 0.10 : # slot is not busy so it is safe to transmit
# Send the packet to all peers in the target IPSC
self.send_to_ipsc(_frame)
else:
logger.info('Slot {} is busy, will not transmit packet from gateway'.format(_newSlot))
def begin_call(self, _slot, _src_id, _dst_id, _repeater_id, _cc, _seq, _stream_id):
subscriber_ids, talkgroup_ids, peer_ids = self._parent.get_globals()
_src_alias = get_alias(_src_id, subscriber_ids)
metadata = _src_id[0:3] + _repeater_id[0:4] + _dst_id[0:3] + struct.pack("b", _slot) + struct.pack("b", _cc)
self.send_tlv(TAG_BEGIN_TX, metadata) # start transmission
self._sock.sendto('reply log2 {} {}'.format(_src_alias, int_id(_dst_id)), (self._dmrgui, 34003))
self._logger.info('Voice Transmission Start on TS {} and TG {} ({}) from {}'.format(_slot, get_alias(_dst_id, talkgroup_ids), int_id(_dst_id), _src_alias))
_tx_slot = self.tx[_slot]
_tx_slot.slot = _slot
_tx_slot.rf_src = _src_id
_tx_slot.repeater_id = _repeater_id
_tx_slot.dst_id = _dst_id
_tx_slot.cc = _cc
_tx_slot.stream_id = _stream_id
_tx_slot.start_time = time()
_tx_slot.frame_count = 0
_tx_slot.lostFrame = 0
_tx_slot.lastSeq = _seq
def master_reg_req(self, _data, _peerid, _host, _port):
_ip_address = _host
_port = _port
_hex_mode = _data[5]
_hex_flags = _data[6:10]
_decoded_mode = process_mode_byte(_hex_mode)
_decoded_flags = process_flags_bytes(_hex_flags)
self.MASTER_REG_REPLY_PKT = (MASTER_REG_REPLY + self._local_id +
self.TS_FLAGS +
hex_str_2(self._local['NUM_PEERS']) +
IPSC_VER)
self.send_packet(self.MASTER_REG_REPLY_PKT, (_host, _port))
self._logger.info(
'(%s) Master Registration Packet Received from peer %s, %s:%s',
self._system, int_id(_peerid), _host, _port)
# If this entry was NOT already in our list, add it.
if _peerid not in self._peers.keys():
self._peers[_peerid] = {
'IP': _ip_address,
'PORT': _port,
'MODE': _hex_mode,
'MODE_DECODE': _decoded_mode,
'FLAGS': _hex_flags,
'FLAGS_DECODE': _decoded_flags,
'STATUS': {
'CONNECTED': True,
'KEEP_ALIVES_SENT': 0,
'KEEP_ALIVES_MISSED': 0,
'KEEP_ALIVES_OUTSTANDING': 0,
'KEEP_ALIVES_RECEIVED': 0,
'KEEP_ALIVE_RX_TIME': int(time())
}
}
self._local['NUM_PEERS'] = len(self._peers)
self._logger.debug(
'(%s) Peer Added To Peer List: %s, %s:%s (IPSC now has %s Peers)',
self._system, self._peers[_peerid], _host, _port,
self._local['NUM_PEERS'])
def build_hblink_table(_config):
_stats_table = {'MASTERS': {}, 'CLIENTS': {}}
for _hbp, _hbp_data in _config.iteritems():
if _hbp_data['ENABLED'] == True:
if _hbp_data['MODE'] == 'MASTER':
_stats_table['MASTERS'][_hbp] = {}
_stats_table['MASTERS'][_hbp]['REPEAT'] = _hbp_data['REPEAT']
_stats_table['MASTERS'][_hbp]['CLIENTS'] = {}
for _client in _hbp_data['CLIENTS']:
_stats_table['MASTERS'][_hbp]['CLIENTS'][int_id(
_client)] = {}
_stats_table['MASTERS'][_hbp]['CLIENTS'][int_id(_client)][
'CALLSIGN'] = _hbp_data['CLIENTS'][_client]['CALLSIGN']
_stats_table['MASTERS'][_hbp]['CLIENTS'][int_id(
_client)]['CONNECTION'] = _hbp_data['CLIENTS'][
_client]['CONNECTION']
_stats_table['MASTERS'][_hbp]['CLIENTS'][int_id(
_client)]['IP'] = _hbp_data['CLIENTS'][_client]['IP']
_stats_table['MASTERS'][_hbp]['CLIENTS'][int_id(
_client)]['PINGS_RECEIVED'] = _hbp_data['CLIENTS'][
_client]['PINGS_RECEIVED']
_stats_table['MASTERS'][_hbp]['CLIENTS'][int_id(
_client)]['LAST_PING'] = _hbp_data['CLIENTS'][_client][
'LAST_PING']
_stats_table['MASTERS'][_hbp]['CLIENTS'][int_id(_client)][
'PORT'] = _hbp_data['CLIENTS'][_client]['PORT']
elif _hbp_data['MODE'] == 'CLIENT':
_stats_table['CLIENTS'][_hbp] = {}
_stats_table['CLIENTS'][_hbp]['CALLSIGN'] = _hbp_data[
'CALLSIGN']
_stats_table['CLIENTS'][_hbp]['RADIO_ID'] = int_id(
_hbp_data['RADIO_ID'])
_stats_table['CLIENTS'][_hbp]['MASTER_IP'] = _hbp_data[
'MASTER_IP']
_stats_table['CLIENTS'][_hbp]['STATS'] = _hbp_data['STATS']
return (_stats_table)
def call_mon_rpt(self, _data):
if not rpt:
return
_source = _data[1:5]
_ts1_state = _data[5]
_ts2_state = _data[6]
_source = str(int_id(_source)) + ', ' + str(get_alias(_source, peer_ids))
print('Call Monitor - Repeater State')
print('TIME: ', datetime.datetime.now().strftime("%Y-%m-%d %H:%M:%S"))
print('DATA SOURCE: ', _source)
try:
print('TS1 State: ', REPEAT[_ts1_state])
except KeyError:
print('TS1 State (unknown): ', h(_ts1_state))
try:
print('TS2 State: ', REPEAT[_ts2_state])
except KeyError:
print('TS2 State (unknown): ', h(_ts2_state))
print()
def update_dmrlink_table(_config, _stats_table):
for _ipsc, _ipsc_data in _config.iteritems():
_stats_peers = _stats_table[_ipsc]['PEERS']
# if this peer is the master
if _stats_table[_ipsc]['MASTER'] == False:
_peer = _config[_ipsc]['MASTER']['RADIO_ID']
_config_peer_data = _config[_ipsc]['MASTER']
_stats_peers[_peer]['RADIO_ID'] = int_id(_peer)
update_peer(_stats_peers, _peer, _config_peer_data)
# for all of the peers that are not the master... update or add
for _peer, _config_peer_data in _config[_ipsc]['PEERS'].iteritems():
if _peer != _config[_ipsc]['LOCAL']['RADIO_ID']:
_stats_peers = _stats_table[_ipsc]['PEERS']
# update the peer if we already have it
if _peer in _stats_table[_ipsc]['PEERS']:
update_peer(_stats_peers, _peer, _config_peer_data)
# addit if we don't have it
if _peer not in _stats_table[_ipsc]['PEERS']:
add_peer(_stats_peers, _peer, _config_peer_data, 'peer')
# for peers that need to be removed, never the master. This is complicated
peers_to_delete = []
# find any peers missing in the config update
for _peer, _stats_peer_data in _stats_table[_ipsc]['PEERS'].iteritems(
):
if _peer not in _config[_ipsc][
'PEERS'] and _peer != _config[_ipsc]['MASTER']['RADIO_ID']:
peers_to_delete.append(_peer)
# delte anything identified from the right part of the stats table
delete_peers(peers_to_delete, _stats_table[_ipsc]['PEERS'])
def call_mon_rpt(self, _data):
if not rpt:
return
_source = _data[1:5]
_ts1_state = _data[5]
_ts2_state = _data[6]
_source = str(int_id(_source)) + ', ' + str(
get_alias(_source, peer_ids))
print('Call Monitor - Repeater State')
print('TIME: ',
datetime.datetime.now().strftime("%Y-%m-%d %H:%M:%S"))
print('DATA SOURCE: ', _source)
try:
print('TS1 State: ', REPEAT[_ts1_state])
except KeyError:
print('TS1 State (unknown): ', ahex(_ts1_state))
try:
print('TS2 State: ', REPEAT[_ts2_state])
except KeyError:
print('TS2 State (unknown): ', ahex(_ts2_state))
print()
def parseAMBE(self, _client, _data):
_seq = int_id(_data[4:5])
_srcID = int_id(_data[5:8])
_dstID = int_id(_data[8:11])
_rptID = int_id(_data[11:15])
_bits = int_id(_data[15:16]) # SCDV NNNN (Slot|Call type|Data|Voice|Seq or Data type)
_slot = 2 if _bits & 0x80 else 1
_callType = 1 if (_bits & 0x40) else 0
_frameType = (_bits & 0x30) >> 4
_voiceSeq = (_bits & 0x0f)
_streamID = int_id(_data[16:20])
logger.debug('(%s) seq: %d srcID: %d dstID: %d rptID: %d bits: %0X slot:%d callType: %d frameType: %d voiceSeq: %d streamID: %0X',
_client, _seq, _srcID, _dstID, _rptID, _bits, _slot, _callType, _frameType, _voiceSeq, _streamID )
#logger.debug('Frame 1:(%s)', self.ByteToHex(_data))
_dmr_frame = BitArray('0x'+ahex(_data[20:]))
_ambe = _dmr_frame[0:108] + _dmr_frame[156:264]
#_sock.sendto(_ambe.tobytes(), ("127.0.0.1", 31000))
ambeBytes = _ambe.tobytes()
self._sock.sendto(ambeBytes[0:9], (self._exp_ip, self._exp_port))
self._sock.sendto(ambeBytes[9:18], (self._exp_ip, self._exp_port))
self._sock.sendto(ambeBytes[18:27], (self._exp_ip, self._exp_port))
def master_maintenance_loop(self):
self._logger.debug('(%s) MASTER Connection Maintenance Loop Started', self._system)
update_time = int(time())
for peer in self._peers.keys():
keep_alive_delta = update_time - self._peers[peer]['STATUS']['KEEP_ALIVE_RX_TIME']
self._logger.debug('(%s) Time Since Last KeepAlive Request from Peer %s: %s seconds', self._system, int_id(peer), keep_alive_delta)
if keep_alive_delta > 120:
self.de_register_peer(peer)
self.send_to_ipsc(self.PEER_LIST_REPLY_PKT + build_peer_list(self._peers))
self._logger.warning('(%s) Timeout Exceeded for Peer %s, De-registering', self._system, int_id(peer))
def dmrd_received(self, _peer_id, _rf_src, _dst_id, _seq, _slot,
_call_type, _frame_type, _dtype_vseq, _stream_id, _data):
pkt_time = time()
dmrpkt = _data[20:53]
_bits = int_id(_data[15])
if _call_type == 'group':
# Check for ACL match, and return if the subscriber is not allowed
if allow_sub(_rf_src) == False:
self._logger.warning(
'(%s) Group Voice Packet ***REJECTED BY ACL*** From: %s, HBP Peer %s, Destination TGID %s',
self._system, int_id(_rf_src), int_id(_peer_id),
int_id(_dst_id))
return
# Is this a new call stream?
if (_stream_id != self.STATUS[_slot]['RX_STREAM_ID']):
if (self.STATUS[_slot]['RX_TYPE'] != hb_const.HBPF_SLT_VTERM
) and (pkt_time <
(self.STATUS[_slot]['RX_TIME'] + hb_const.STREAM_TO)
) and (_rf_src != self.STATUS[_slot]['RX_RFS']):
self._logger.warning(
'(%s) Packet received with STREAM ID: %s <FROM> SUB: %s PEER: %s <TO> TGID %s, SLOT %s collided with existing call',
self._system, int_id(_stream_id), int_id(_rf_src),
int_id(_peer_id), int_id(_dst_id), _slot)
return
# This is a new call stream
self.STATUS['RX_START'] = pkt_time
self._logger.info('(%s) *CALL START* STREAM ID: %s SUB: %s (%s) PEER: %s (%s) TGID %s (%s), TS %s', \
self._system, int_id(_stream_id), get_alias(_rf_src, subscriber_ids), int_id(_rf_src), get_alias(_peer_id, peer_ids), int_id(_peer_id), get_alias(_dst_id, talkgroup_ids), int_id(_dst_id), _slot)
# If we can, use the LC from the voice header as to keep all options intact
if _frame_type == hb_const.HBPF_DATA_SYNC and _dtype_vseq == hb_const.HBPF_SLT_VHEAD:
decoded = decode.voice_head_term(dmrpkt)
self.STATUS[_slot]['RX_LC'] = decoded['LC']
# If we don't have a voice header then don't wait to decode it from the Embedded LC
# just make a new one from the HBP header. This is good enough, and it saves lots of time
else:
self.STATUS[_slot][
'RX_LC'] = const.LC_OPT + _dst_id + _rf_src
for rule in RULES[self._system]['GROUP_VOICE']:
_target = rule['DST_NET']
_target_status = systems[_target].STATUS
if (rule['SRC_GROUP'] == _dst_id and rule['SRC_TS'] == _slot
and rule['ACTIVE'] == True):
# BEGIN CONTENTION HANDLING
#
# The rules for each of the 4 "ifs" below are listed here for readability. The Frame To Send is:
# From a different group than last RX from this HBSystem, but it has been less than Group Hangtime
# From a different group than last TX to this HBSystem, but it has been less than Group Hangtime
# From the same group as the last RX from this HBSystem, but from a different subscriber, and it has been less than stream timeout
# From the same group as the last TX to this HBSystem, but from a different subscriber, and it has been less than stream timeout
# The "continue" at the end of each means the next iteration of the for loop that tests for matching rules
#
if ((rule['DST_GROUP'] !=
_target_status[rule['DST_TS']]['RX_TGID']) and
((pkt_time - _target_status[rule['DST_TS']]['RX_TIME'])
< RULES[_target]['GROUP_HANGTIME'])):
if _frame_type == hb_const.HBPF_DATA_SYNC and _dtype_vseq == hb_const.HBPF_SLT_VHEAD:
self._logger.info(
'(%s) Call not routed to TGID%s, target active or in group hangtime: HBSystem: %s, TS: %s, TGID: %s',
self._system, int_id(rule['DST_GROUP']),
_target, rule['DST_TS'],
int_id(
_target_status[rule['DST_TS']]['RX_TGID']))
continue
if ((rule['DST_GROUP'] !=
_target_status[rule['DST_TS']]['TX_TGID']) and
((pkt_time - _target_status[rule['DST_TS']]['TX_TIME'])
< RULES[_target]['GROUP_HANGTIME'])):
if _frame_type == hb_const.HBPF_DATA_SYNC and _dtype_vseq == hb_const.HBPF_SLT_VHEAD:
self._logger.info(
'(%s) Call not routed to TGID%s, target in group hangtime: HBSystem: %s, TS: %s, TGID: %s',
self._system, int_id(rule['DST_GROUP']),
_target, rule['DST_TS'],
int_id(
_target_status[rule['DST_TS']]['TX_TGID']))
continue
if (rule['DST_GROUP']
== _target_status[rule['DST_TS']]['RX_TGID']) and (
(pkt_time -
_target_status[rule['DST_TS']]['RX_TIME']) <
hb_const.STREAM_TO):
if _frame_type == hb_const.HBPF_DATA_SYNC and _dtype_vseq == hb_const.HBPF_SLT_VHEAD:
self._logger.info(
'(%s) Call not routed to TGID%s, matching call already active on target: HBSystem: %s, TS: %s, TGID: %s',
self._system, int_id(rule['DST_GROUP']),
_target, rule['DST_TS'],
int_id(
_target_status[rule['DST_TS']]['RX_TGID']))
continue
if (rule['DST_GROUP']
== _target_status[rule['DST_TS']]['TX_TGID']) and (
_rf_src !=
_target_status[rule['DST_TS']]['TX_RFS']) and (
(pkt_time -
_target_status[rule['DST_TS']]['TX_TIME'])
< hb_const.STREAM_TO):
if _frame_type == hb_const.HBPF_DATA_SYNC and _dtype_vseq == hb_const.HBPF_SLT_VHEAD:
self._logger.info(
'(%s) Call not routed for subscriber %s, call route in progress on target: HBSystem: %s, TS: %s, TGID: %s, SUB: %s',
self._system, int_id(_rf_src), _target,
rule['DST_TS'],
int_id(
_target_status[rule['DST_TS']]['TX_TGID']),
_target_status[rule['DST_TS']]['TX_RFS'])
continue
# Set values for the contention handler to test next time there is a frame to forward
_target_status[rule['DST_TS']]['TX_TIME'] = pkt_time
if (_stream_id != self.STATUS[_slot]['RX_STREAM_ID']) or (
_target_status[rule['DST_TS']]['TX_RFS'] != _rf_src
) or (_target_status[rule['DST_TS']]['TX_TGID'] !=
rule['DST_GROUP']):
# Record the DST TGID and Stream ID
_target_status[
rule['DST_TS']]['TX_TGID'] = rule['DST_GROUP']
_target_status[
rule['DST_TS']]['TX_STREAM_ID'] = _stream_id
_target_status[rule['DST_TS']]['TX_RFS'] = _rf_src
# Generate LCs (full and EMB) for the TX stream
# if _dst_id != rule['DST_GROUP']:
dst_lc = self.STATUS[_slot]['RX_LC'][0:3] + rule[
'DST_GROUP'] + _rf_src
_target_status[rule['DST_TS']][
'TX_H_LC'] = bptc.encode_header_lc(dst_lc)
_target_status[rule['DST_TS']][
'TX_T_LC'] = bptc.encode_terminator_lc(dst_lc)
_target_status[rule['DST_TS']][
'TX_EMB_LC'] = bptc.encode_emblc(dst_lc)
self._logger.debug(
'(%s) Packet DST TGID (%s) does not match SRC TGID(%s) - Generating FULL and EMB LCs',
self._system, int_id(rule['DST_GROUP']),
int_id(_dst_id))
self._logger.info(
'(%s) Call routed to: System: %s TS: %s, TGID: %s',
self._system, _target, rule['DST_TS'],
int_id(rule['DST_GROUP']))
# Handle any necessary re-writes for the destination
if rule['SRC_TS'] != rule['DST_TS']:
_tmp_bits = _bits ^ 1 << 7
else:
_tmp_bits = _bits
# Assemble transmit HBP packet header
_tmp_data = _data[:8] + rule['DST_GROUP'] + _data[
11:15] + chr(_tmp_bits) + _data[16:20]
# MUST TEST FOR NEW STREAM AND IF SO, RE-WRITE THE LC FOR THE TARGET
# MUST RE-WRITE DESTINATION TGID IF DIFFERENT
# if _dst_id != rule['DST_GROUP']:
dmrbits = bitarray(endian='big')
dmrbits.frombytes(dmrpkt)
# Create a voice header packet (FULL LC)
if _frame_type == hb_const.HBPF_DATA_SYNC and _dtype_vseq == hb_const.HBPF_SLT_VHEAD:
dmrbits = _target_status[rule['DST_TS']]['TX_H_LC'][
0:98] + dmrbits[98:166] + _target_status[
rule['DST_TS']]['TX_H_LC'][98:197]
# Create a voice terminator packet (FULL LC)
elif _frame_type == hb_const.HBPF_DATA_SYNC and _dtype_vseq == hb_const.HBPF_SLT_VTERM:
dmrbits = _target_status[rule['DST_TS']]['TX_T_LC'][
0:98] + dmrbits[98:166] + _target_status[
rule['DST_TS']]['TX_T_LC'][98:197]
# Create a Burst B-E packet (Embedded LC)
elif _dtype_vseq in [1, 2, 3, 4]:
dmrbits = dmrbits[0:116] + _target_status[
rule['DST_TS']]['TX_EMB_LC'][
_dtype_vseq] + dmrbits[148:264]
dmrpkt = dmrbits.tobytes()
_tmp_data = _tmp_data + dmrpkt + _data[53:55]
# Transmit the packet to the destination system
systems[_target].send_system(_tmp_data)
self._logger.debug(
'(%s) Packet routed by rule: %s to %s system: %s',
self._system, rule['NAME'],
self._CONFIG['SYSTEMS'][_target]['MODE'], _target)
# Final actions - Is this a voice terminator?
if (_frame_type == hb_const.HBPF_DATA_SYNC
) and (_dtype_vseq == hb_const.HBPF_SLT_VTERM) and (
self.STATUS[_slot]['RX_TYPE'] != hb_const.HBPF_SLT_VTERM):
call_duration = pkt_time - self.STATUS['RX_START']
self._logger.info('(%s) *CALL END* STREAM ID: %s SUB: %s (%s) PEER: %s (%s) TGID %s (%s), TS %s, Duration: %s', \
self._system, int_id(_stream_id), get_alias(_rf_src, subscriber_ids), int_id(_rf_src), get_alias(_peer_id, peer_ids), int_id(_peer_id), get_alias(_dst_id, talkgroup_ids), int_id(_dst_id), _slot, call_duration)
#
# Begin in-band signalling for call end. This has nothign to do with routing traffic directly.
#
# Iterate the rules dictionary
for rule in RULES[self._system]['GROUP_VOICE']:
_target = rule['DST_NET']
# TGID matches a rule source, reset its timer
if _slot == rule['SRC_TS'] and _dst_id == rule[
'SRC_GROUP'] and ((rule['TO_TYPE'] == 'ON' and
(rule['ACTIVE'] == True)) or
(rule['TO_TYPE'] == 'OFF'
and rule['ACTIVE'] == False)):
rule['TIMER'] = pkt_time + rule['TIMEOUT']
self._logger.info(
'(%s) Source group transmission match for rule \"%s\". Reset timeout to %s',
self._system, rule['NAME'], rule['TIMER'])
# Scan for reciprocal rules and reset their timers as well.
for target_rule in RULES[_target]['GROUP_VOICE']:
if target_rule['NAME'] == rule['NAME']:
target_rule['TIMER'] = pkt_time + target_rule[
'TIMEOUT']
self._logger.info(
'(%s) Reciprocal group transmission match for rule \"%s\" on IPSC \"%s\". Reset timeout to %s',
self._system, target_rule['NAME'], _target,
rule['TIMER'])
# TGID matches an ACTIVATION trigger
if _dst_id in rule['ON']:
# Set the matching rule as ACTIVE
rule['ACTIVE'] = True
rule['TIMER'] = pkt_time + rule['TIMEOUT']
self._logger.info(
'(%s) Primary routing Rule \"%s\" changed to state: %s',
self._system, rule['NAME'], rule['ACTIVE'])
# Set reciprocal rules for other IPSCs as ACTIVE
for target_rule in RULES[_target]['GROUP_VOICE']:
if target_rule['NAME'] == rule['NAME']:
target_rule['ACTIVE'] = True
target_rule['TIMER'] = pkt_time + target_rule[
'TIMEOUT']
self._logger.info(
'(%s) Reciprocal routing Rule \"%s\" in IPSC \"%s\" changed to state: %s',
self._system, target_rule['NAME'], _target,
rule['ACTIVE'])
# TGID matches an DE-ACTIVATION trigger
if _dst_id in rule['OFF']:
# Set the matching rule as ACTIVE
rule['ACTIVE'] = False
self._logger.info(
'(%s) Routing Rule \"%s\" changed to state: %s',
self._system, rule['NAME'], rule['ACTIVE'])
# Set reciprocal rules for other IPSCs as ACTIVE
_target = rule['DST_NET']
for target_rule in RULES[_target]['GROUP_VOICE']:
if target_rule['NAME'] == rule['NAME']:
target_rule['ACTIVE'] = False
self._logger.info(
'(%s) Reciprocal routing Rule \"%s\" in IPSC \"%s\" changed to state: %s',
self._system, target_rule['NAME'], _target,
rule['ACTIVE'])
#
# END IN-BAND SIGNALLING
#
# Mark status variables for use later
self.STATUS[_slot]['RX_RFS'] = _rf_src
self.STATUS[_slot]['RX_TYPE'] = _dtype_vseq
self.STATUS[_slot]['RX_TGID'] = _dst_id
self.STATUS[_slot]['RX_TIME'] = pkt_time
self.STATUS[_slot]['RX_STREAM_ID'] = _stream_id
def peer_list_req(self, _peerid):
if _peerid in self._peers.keys():
self._logger.debug('(%s) Peer List Request from peer %s', self._system, int_id(_peerid))
self.send_to_ipsc(self.PEER_LIST_REPLY_PKT + build_peer_list(self._peers))
else:
self._logger.warning('(%s) Peer List Request Received from *UNREGISTERED* peer %s', self._system, int_id(_peerid))
def repeater_wake_up(self, _data):
_source = _data[1:5]
_source_name = get_alias(_source, peer_ids)
print('({}) Repeater Wake-Up Packet Received: {} ({})'.format(
self._system, _source_name, int_id(_source)))
class HBSYSTEM(DatagramProtocol):
def __init__(self, _name, _config, _logger):
# Define a few shortcuts to make the rest of the class more readable
self._CONFIG = _config
self._system = _name
self._logger = _logger
self._config = self._CONFIG['SYSTEMS'][self._system]
# Define shortcuts and generic function names based on the type of system we are
if self._config['MODE'] == 'MASTER':
self._clients = self._CONFIG['SYSTEMS'][self._system]['CLIENTS']
self.send_system = self.send_clients
self.maintenance_loop = self.master_maintenance_loop
self.datagramReceived = self.master_datagramReceived
self.dereg = self.master_dereg
elif self._config['MODE'] == 'CLIENT':
self._stats = self._config['STATS']
self.send_system = self.send_master
self.maintenance_loop = self.client_maintenance_loop
self.datagramReceived = self.client_datagramReceived
self.dereg = self.client_dereg
# Configure for AMBE audio export if enabled
if self._config['EXPORT_AMBE']:
self._ambe = AMBE()
def startProtocol(self):
# Set up periodic loop for tracking pings from clients. Run every 'PING_TIME' seconds
self._system_maintenance = task.LoopingCall(self.maintenance_loop)
self._system_maintenance_loop = self._system_maintenance.start(self._CONFIG['GLOBAL']['PING_TIME'])
# Aliased in __init__ to maintenance_loop if system is a master
def master_maintenance_loop(self):
self._logger.debug('(%s) Master maintenance loop started', self._system)
for client in self._clients:
_this_client = self._clients[client]
# Check to see if any of the clients have been quiet (no ping) longer than allowed
if _this_client['LAST_PING']+self._CONFIG['GLOBAL']['PING_TIME']*self._CONFIG['GLOBAL']['MAX_MISSED'] < time():
self._logger.info('(%s) Client %s (%s) has timed out', self._system, _this_client['CALLSIGN'], _this_client['RADIO_ID'])
# Remove any timed out clients from the configuration
del self._CONFIG['SYSTEMS'][self._system]['CLIENTS'][client]
# Aliased in __init__ to maintenance_loop if system is a client
def client_maintenance_loop(self):
self._logger.debug('(%s) Client maintenance loop started', self._system)
# If we're not connected, zero out the stats and send a login request RPTL
if self._stats['CONNECTION'] == 'NO' or self._stats['CONNECTION'] == 'RTPL_SENT':
self._stats['PINGS_SENT'] = 0
self._stats['PINGS_ACKD'] = 0
self._stats['CONNECTION'] = 'RTPL_SENT'
self.send_master('RPTL'+self._config['RADIO_ID'])
self._logger.info('(%s) Sending login request to master %s:%s', self._system, self._config['MASTER_IP'], self._config['MASTER_PORT'])
# If we are connected, sent a ping to the master and increment the counter
if self._stats['CONNECTION'] == 'YES':
self.send_master('RPTPING'+self._config['RADIO_ID'])
self._stats['PINGS_SENT'] += 1
self._logger.debug('(%s) RPTPING Sent to Master. Pings Since Connected: %s', self._system, self._stats['PINGS_SENT'])
def send_clients(self, _packet):
for _client in self._clients:
self.send_client(_client, _packet)
#self._logger.debug('(%s) Packet sent to client %s', self._system, self._clients[_client]['RADIO_ID'])
def send_client(self, _client, _packet):
_ip = self._clients[_client]['IP']
_port = self._clients[_client]['PORT']
self.transport.write(_packet, (_ip, _port))
# KEEP THE FOLLOWING COMMENTED OUT UNLESS YOU'RE DEBUGGING DEEPLY!!!!
#self._logger.debug('(%s) TX Packet to %s on port %s: %s', self._clients[_client]['RADIO_ID'], self._clients[_client]['IP'], self._clients[_client]['PORT'], ahex(_packet))
def send_master(self, _packet):
self.transport.write(_packet, (self._config['MASTER_IP'], self._config['MASTER_PORT']))
# KEEP THE FOLLOWING COMMENTED OUT UNLESS YOU'RE DEBUGGING DEEPLY!!!!
#self._logger.debug('(%s) TX Packet to %s:%s -- %s', self._system, self._config['MASTER_IP'], self._config['MASTER_PORT'], ahex(_packet))
def dmrd_received(self, _radio_id, _rf_src, _dst_id, _seq, _slot, _call_type, _frame_type, _dtype_vseq, _stream_id, _data):
pass
def master_dereg(self):
for _client in self._clients:
self.send_client(_client, 'MSTCL'+_client)
self._logger.info('(%s) De-Registration sent to Client: %s (%s)', self._system, self._clients[_client]['CALLSIGN'], self._clients[_client]['RADIO_ID'])
def client_dereg(self):
self.send_master('RPTCL'+self._config['RADIO_ID'])
self._logger.info('(%s) De-Registeration sent to Master: %s:%s', self._system, self._config['MASTER_IP'], self._config['MASTER_PORT'])
# Aliased in __init__ to datagramReceived if system is a master
def master_datagramReceived(self, _data, (_host, _port)):
# Keep This Line Commented Unless HEAVILY Debugging!
#self._logger.debug('(%s) RX packet from %s:%s -- %s', self._system, _host, _port, ahex(_data))
# Extract the command, which is various length, all but one 4 significant characters -- RPTCL
_command = _data[:4]
if _command == 'DMRD': # DMRData -- encapsulated DMR data frame
_radio_id = _data[11:15]
if _radio_id in self._clients \
and self._clients[_radio_id]['CONNECTION'] == 'YES' \
and self._clients[_radio_id]['IP'] == _host \
and self._clients[_radio_id]['PORT'] == _port:
_seq = _data[4]
_rf_src = _data[5:8]
_dst_id = _data[8:11]
_bits = int_id(_data[15])
_slot = 2 if (_bits & 0x80) else 1
_call_type = 'unit' if (_bits & 0x40) else 'group'
_frame_type = (_bits & 0x30) >> 4
_dtype_vseq = (_bits & 0xF) # data, 1=voice header, 2=voice terminator; voice, 0=burst A ... 5=burst F
_stream_id = _data[16:20]
#self._logger.debug('(%s) DMRD - Seqence: %s, RF Source: %s, Destination ID: %s', self._system, int_id(_seq), int_id(_rf_src), int_id(_dst_id))
# If AMBE audio exporting is configured...
if self._config['EXPORT_AMBE']:
self._ambe.parseAMBE(self._system, _data)
# The basic purpose of a master is to repeat to the clients
if self._config['REPEAT'] == True:
for _client in self._clients:
if _client != _radio_id:
self.send_client(_client, _data)
self._logger.debug('(%s) Packet on TS%s from %s (%s) for destination ID %s repeated to client: %s (%s) [Stream ID: %s]', self._system, _slot, self._clients[_radio_id]['CALLSIGN'], int_id(_radio_id), int_id(_dst_id), self._clients[_client]['CALLSIGN'], int_id(_client), int_id(_stream_id))
# Userland actions -- typically this is the function you subclass for an application
self.dmrd_received(_radio_id, _rf_src, _dst_id, _seq, _slot, _call_type, _frame_type, _dtype_vseq, _stream_id, _data)
elif _command == 'RPTL': # RPTLogin -- a repeater wants to login
_radio_id = _data[4:8]
if _radio_id: # Future check here for valid Radio ID
self._clients.update({_radio_id: { # Build the configuration data strcuture for the client
'CONNECTION': 'RPTL-RECEIVED',
'PINGS_RECEIVED': 0,
'LAST_PING': time(),
'IP': _host,
'PORT': _port,
'SALT': randint(0,0xFFFFFFFF),
'RADIO_ID': str(int(ahex(_radio_id), 16)),
'CALLSIGN': '',
'RX_FREQ': '',
'TX_FREQ': '',
'TX_POWER': '',
'COLORCODE': '',
'LATITUDE': '',
'LONGITUDE': '',
'HEIGHT': '',
'LOCATION': '',
'DESCRIPTION': '',
'SLOTS': '',
'URL': '',
'SOFTWARE_ID': '',
'PACKAGE_ID': '',
}})
self._logger.info('(%s) Repeater Logging in with Radio ID: %s, %s:%s', self._system, int_id(_radio_id), _host, _port)
_salt_str = hex_str_4(self._clients[_radio_id]['SALT'])
self.send_client(_radio_id, 'RPTACK'+_salt_str)
self._clients[_radio_id]['CONNECTION'] = 'CHALLENGE_SENT'
self._logger.info('(%s) Sent Challenge Response to %s for login: %s', self._system, int_id(_radio_id), self._clients[_radio_id]['SALT'])
else:
self.transport.write('MSTNAK'+_radio_id, (_host, _port))
self._logger.warning('(%s) Invalid Login from Radio ID: %s', self._system, int_id(_radio_id))
elif _command == 'RPTK': # Repeater has answered our login challenge
_radio_id = _data[4:8]
if _radio_id in self._clients \
and self._clients[_radio_id]['CONNECTION'] == 'CHALLENGE_SENT' \
and self._clients[_radio_id]['IP'] == _host \
and self._clients[_radio_id]['PORT'] == _port:
_this_client = self._clients[_radio_id]
_this_client['LAST_PING'] = time()
_sent_hash = _data[8:]
_salt_str = hex_str_4(_this_client['SALT'])
_calc_hash = bhex(sha256(_salt_str+self._config['PASSPHRASE']).hexdigest())
if _sent_hash == _calc_hash:
_this_client['CONNECTION'] = 'WAITING_CONFIG'
self.send_client(_radio_id, 'RPTACK'+_radio_id)
self._logger.info('(%s) Client %s has completed the login exchange successfully', self._system, _this_client['RADIO_ID'])
else:
self._logger.info('(%s) Client %s has FAILED the login exchange successfully', self._system, _this_client['RADIO_ID'])
self.transport.write('MSTNAK'+_radio_id, (_host, _port))
del self._clients[_radio_id]
else:
self.transport.write('MSTNAK'+_radio_id, (_host, _port))
self._logger.warning('(%s) Login challenge from Radio ID that has not logged in: %s', self._system, int_id(_radio_id))
elif _command == 'RPTC': # Repeater is sending it's configuraiton OR disconnecting
if _data[:5] == 'RPTCL': # Disconnect command
_radio_id = _data[5:9]
if _radio_id in self._clients \
and self._clients[_radio_id]['CONNECTION'] == 'YES' \
and self._clients[_radio_id]['IP'] == _host \
and self._clients[_radio_id]['PORT'] == _port:
self._logger.info('(%s) Client is closing down: %s (%s)', self._system, self._clients[_radio_id]['CALLSIGN'], int_id(_radio_id))
self.transport.write('MSTNAK'+_radio_id, (_host, _port))
del self._clients[_radio_id]
else:
_radio_id = _data[4:8] # Configure Command
if _radio_id in self._clients \
and self._clients[_radio_id]['CONNECTION'] == 'WAITING_CONFIG' \
and self._clients[_radio_id]['IP'] == _host \
and self._clients[_radio_id]['PORT'] == _port:
_this_client = self._clients[_radio_id]
_this_client['CONNECTION'] = 'YES'
_this_client['LAST_PING'] = time()
_this_client['CALLSIGN'] = _data[8:16]
_this_client['RX_FREQ'] = _data[16:25]
_this_client['TX_FREQ'] = _data[25:34]
_this_client['TX_POWER'] = _data[34:36]
_this_client['COLORCODE'] = _data[36:38]
_this_client['LATITUDE'] = _data[38:46]
_this_client['LONGITUDE'] = _data[46:55]
_this_client['HEIGHT'] = _data[55:58]
_this_client['LOCATION'] = _data[58:78]
_this_client['DESCRIPTION'] = _data[78:97]
_this_client['SLOTS'] = _data[97:98]
_this_client['URL'] = _data[98:222]
_this_client['SOFTWARE_ID'] = _data[222:262]
_this_client['PACKAGE_ID'] = _data[262:302]
self.send_client(_radio_id, 'RPTACK'+_radio_id)
self._logger.info('(%s) Client %s (%s) has sent repeater configuration', self._system, _this_client['CALLSIGN'], _this_client['RADIO_ID'])
else:
self.transport.write('MSTNAK'+_radio_id, (_host, _port))
self._logger.warning('(%s) Client info from Radio ID that has not logged in: %s', self._system, int_id(_radio_id))
elif _command == 'RPTP': # RPTPing -- client is pinging us
_radio_id = _data[7:11]
if _radio_id in self._clients \
and self._clients[_radio_id]['CONNECTION'] == "YES" \
and self._clients[_radio_id]['IP'] == _host \
and self._clients[_radio_id]['PORT'] == _port:
self._clients[_radio_id]['LAST_PING'] = time()
self.send_client(_radio_id, 'MSTPONG'+_radio_id)
self._logger.debug('(%s) Received and answered RPTPING from client %s (%s)', self._system, self._clients[_radio_id]['CALLSIGN'], int_id(_radio_id))
else:
self.transport.write('MSTNAK'+_radio_id, (_host, _port))
self._logger.warning('(%s) Client info from Radio ID that has not logged in: %s', self._system, int_id(_radio_id))
else:
self._logger.error('(%s) Unrecognized command from: %s. Packet: %s', self._system, int_id(_radio_id), ahex(_data))
def master_datagramReceived(self, _data, _sockaddr):
# Keep This Line Commented Unless HEAVILY Debugging!
# self._logger.debug('(%s) RX packet from %s -- %s', self._system, _sockaddr, ahex(_data))
# Extract the command, which is various length, all but one 4 significant characters -- RPTCL
_command = _data[:4]
if _command == 'DMRD': # DMRData -- encapsulated DMR data frame
_peer_id = _data[11:15]
if _peer_id in self._peers \
and self._peers[_peer_id]['CONNECTION'] == 'YES' \
and self._peers[_peer_id]['SOCKADDR'] == _sockaddr:
_seq = _data[4]
_rf_src = _data[5:8]
_dst_id = _data[8:11]
_bits = int_id(_data[15])
_slot = 2 if (_bits & 0x80) else 1
_call_type = 'unit' if (_bits & 0x40) else 'group'
_frame_type = (_bits & 0x30) >> 4
_dtype_vseq = (
_bits & 0xF
) # data, 1=voice header, 2=voice terminator; voice, 0=burst A ... 5=burst F
_stream_id = _data[16:20]
#self._logger.debug('(%s) DMRD - Seqence: %s, RF Source: %s, Destination ID: %s', self._system, int_id(_seq), int_id(_rf_src), int_id(_dst_id))
# If AMBE audio exporting is configured...
if self._config['EXPORT_AMBE']:
self._ambe.parseAMBE(self._system, _data)
# The basic purpose of a master is to repeat to the peers
if self._config['REPEAT'] == True:
for _peer in self._peers:
if _peer != _peer_id:
#self.send_peer(_peer, _data)
self.send_peer(_peer,
_data[:11] + _peer + _data[15:])
#self.send_peer(_peer, _data[:11] + self._config['RADIO_ID'] + _data[15:])
#self._logger.debug('(%s) Packet on TS%s from %s (%s) for destination ID %s repeated to peer: %s (%s) [Stream ID: %s]', self._system, _slot, self._peers[_peer_id]['CALLSIGN'], int_id(_peer_id), int_id(_dst_id), self._peers[_peer]['CALLSIGN'], int_id(_peer), int_id(_stream_id))
# Userland actions -- typically this is the function you subclass for an application
self.dmrd_received(_peer_id, _rf_src, _dst_id, _seq, _slot,
_call_type, _frame_type, _dtype_vseq,
_stream_id, _data)
elif _command == 'RPTL': # RPTLogin -- a repeater wants to login
_peer_id = _data[4:8]
if allow_reg(_peer_id): # Check for valid Radio ID
self._peers.update({_peer_id: { # Build the configuration data strcuture for the peer
'CONNECTION': 'RPTL-RECEIVED',
'PINGS_RECEIVED': 0,
'LAST_PING': time(),
'SOCKADDR': _sockaddr,
'IP': _sockaddr[0],
'PORT': _sockaddr[1],
'SALT': randint(0,0xFFFFFFFF),
'RADIO_ID': str(int(ahex(_peer_id), 16)),
'CALLSIGN': '',
'RX_FREQ': '',
'TX_FREQ': '',
'TX_POWER': '',
'COLORCODE': '',
'LATITUDE': '',
'LONGITUDE': '',
'HEIGHT': '',
'LOCATION': '',
'DESCRIPTION': '',
'SLOTS': '',
'URL': '',
'SOFTWARE_ID': '',
'PACKAGE_ID': '',
}})
self._logger.info(
'(%s) Repeater Logging in with Radio ID: %s, %s:%s',
self._system, int_id(_peer_id), _sockaddr[0], _sockaddr[1])
_salt_str = hex_str_4(self._peers[_peer_id]['SALT'])
self.send_peer(_peer_id, 'RPTACK' + _salt_str)
self._peers[_peer_id]['CONNECTION'] = 'CHALLENGE_SENT'
self._logger.info(
'(%s) Sent Challenge Response to %s for login: %s',
self._system, int_id(_peer_id),
self._peers[_peer_id]['SALT'])
else:
self.transport.write('MSTNAK' + _peer_id, _sockaddr)
self._logger.warning(
'(%s) Invalid Login from Radio ID: %s Denied by Registation ACL',
self._system, int_id(_peer_id))
elif _command == 'RPTK': # Repeater has answered our login challenge
_peer_id = _data[4:8]
if _peer_id in self._peers \
and self._peers[_peer_id]['CONNECTION'] == 'CHALLENGE_SENT' \
and self._peers[_peer_id]['SOCKADDR'] == _sockaddr:
_this_peer = self._peers[_peer_id]
_this_peer['LAST_PING'] = time()
_sent_hash = _data[8:]
_salt_str = hex_str_4(_this_peer['SALT'])
_calc_hash = bhex(
sha256(_salt_str + self._config['PASSPHRASE']).hexdigest())
if _sent_hash == _calc_hash:
_this_peer['CONNECTION'] = 'WAITING_CONFIG'
self.send_peer(_peer_id, 'RPTACK' + _peer_id)
self._logger.info(
'(%s) Peer %s has completed the login exchange successfully',
self._system, _this_peer['RADIO_ID'])
else:
self._logger.info(
'(%s) Peer %s has FAILED the login exchange successfully',
self._system, _this_peer['RADIO_ID'])
self.transport.write('MSTNAK' + _peer_id, _sockaddr)
del self._peers[_peer_id]
else:
self.transport.write('MSTNAK' + _peer_id, _sockaddr)
self._logger.warning(
'(%s) Login challenge from Radio ID that has not logged in: %s',
self._system, int_id(_peer_id))
elif _command == 'RPTC': # Repeater is sending it's configuraiton OR disconnecting
if _data[:5] == 'RPTCL': # Disconnect command
_peer_id = _data[5:9]
if _peer_id in self._peers \
and self._peers[_peer_id]['CONNECTION'] == 'YES' \
and self._peers[_peer_id]['SOCKADDR'] == _sockaddr:
self._logger.info('(%s) Peer is closing down: %s (%s)',
self._system,
self._peers[_peer_id]['CALLSIGN'],
int_id(_peer_id))
self.transport.write('MSTNAK' + _peer_id, _sockaddr)
del self._peers[_peer_id]
else:
_peer_id = _data[4:8] # Configure Command
if _peer_id in self._peers \
and self._peers[_peer_id]['CONNECTION'] == 'WAITING_CONFIG' \
and self._peers[_peer_id]['SOCKADDR'] == _sockaddr:
_this_peer = self._peers[_peer_id]
_this_peer['CONNECTION'] = 'YES'
_this_peer['LAST_PING'] = time()
_this_peer['CALLSIGN'] = _data[8:16]
_this_peer['RX_FREQ'] = _data[16:25]
_this_peer['TX_FREQ'] = _data[25:34]
_this_peer['TX_POWER'] = _data[34:36]
_this_peer['COLORCODE'] = _data[36:38]
_this_peer['LATITUDE'] = _data[38:46]
_this_peer['LONGITUDE'] = _data[46:55]
_this_peer['HEIGHT'] = _data[55:58]
_this_peer['LOCATION'] = _data[58:78]
_this_peer['DESCRIPTION'] = _data[78:97]
_this_peer['SLOTS'] = _data[97:98]
_this_peer['URL'] = _data[98:222]
_this_peer['SOFTWARE_ID'] = _data[222:262]
_this_peer['PACKAGE_ID'] = _data[262:302]
self.send_peer(_peer_id, 'RPTACK' + _peer_id)
self._logger.info(
'(%s) Peer %s (%s) has sent repeater configuration',
self._system, _this_peer['CALLSIGN'],
_this_peer['RADIO_ID'])
else:
self.transport.write('MSTNAK' + _peer_id, _sockaddr)
self._logger.warning(
'(%s) Peer info from Radio ID that has not logged in: %s',
self._system, int_id(_peer_id))
elif _command == 'RPTP': # RPTPing -- peer is pinging us
_peer_id = _data[7:11]
if _peer_id in self._peers \
and self._peers[_peer_id]['CONNECTION'] == "YES" \
and self._peers[_peer_id]['SOCKADDR'] == _sockaddr:
self._peers[_peer_id]['PINGS_RECEIVED'] += 1
self._peers[_peer_id]['LAST_PING'] = time()
self.send_peer(_peer_id, 'MSTPONG' + _peer_id)
self._logger.debug(
'(%s) Received and answered RPTPING from peer %s (%s)',
self._system, self._peers[_peer_id]['CALLSIGN'],
int_id(_peer_id))
else:
self.transport.write('MSTNAK' + _peer_id, _sockaddr)
self._logger.warning(
'(%s) Peer info from Radio ID that has not logged in: %s',
self._system, int_id(_peer_id))
else:
self._logger.error('(%s) Unrecognized command. Raw HBP PDU: %s',
self._system, ahex(_data))
# Keep This Line Commented Unless HEAVILY Debugging!
# self._logger.debug('(%s) RX packet from %s:%s -- %s', self._system, _host, _port, ahex(_data))
# Validate that we receveived this packet from the master - security check!
if self._config['MASTER_IP'] == _host and self._config[
'MASTER_PORT'] == _port:
# Extract the command, which is various length, but only 4 significant characters
_command = _data[:4]
if _command == 'DMRD': # DMRData -- encapsulated DMR data frame
_radio_id = _data[11:15]
if self._config['LOOSE'] or _radio_id == self._config[
'RADIO_ID']: # Validate the Radio_ID unless using loose validation
_seq = _data[4:5]
_rf_src = _data[5:8]
_dst_id = _data[8:11]
_bits = int_id(_data[15])
_slot = 2 if (_bits & 0x80) else 1
_call_type = 'unit' if (_bits & 0x40) else 'group'
_frame_type = (_bits & 0x30) >> 4
_dtype_vseq = (
_bits & 0xF
) # data, 1=voice header, 2=voice terminator; voice, 0=burst A ... 5=burst F
_stream_id = _data[16:20]
self._logger.debug(
'(%s) DMRD - Sequence: %s, RF Source: %s, Destination ID: %s',
self._system, int_id(_seq), int_id(_rf_src),
int_id(_dst_id))
# If AMBE audio exporting is configured...
if self._config['EXPORT_AMBE']:
self._ambe.parseAMBE(self._system, _data)
def private_voice(self, _src_sub, _dst_sub, _ts, _end, _peerid, _data):
if HEX_SUB == _dst_sub and _ts in PRIVATE_TS:
if not _end:
if not self.CALL_DATA:
self._logger.info('(%s) Receiving transmission to be played back from subscriber: %s, to subscriber: %s', self._system, int_id(_src_sub), int_id(_dst_sub))
_tmp_data = _data
self.CALL_DATA.append(_tmp_data)
if _end:
self.CALL_DATA.append(_data)
time.sleep(1)
self._logger.info('(%s) Playing back transmission from subscriber: %s, to subscriber %s', self._system, int_id(_src_sub), int_id(_dst_sub))
_orig_src = _src_sub
_orig_dst = _dst_sub
for i in self.CALL_DATA:
_tmp_data = i
_tmp_data = _tmp_data.replace(_peerid, self._config['LOCAL']['RADIO_ID'])
_tmp_data = _tmp_data.replace(_dst_sub, BOGUS_SUB)
_tmp_data = _tmp_data.replace(_src_sub, _orig_dst)
_tmp_data = _tmp_data.replace(BOGUS_SUB, _orig_src)
# Send the packet to all peers in the target IPSC
self.send_to_ipsc(_tmp_data)
time.sleep(0.06)
self.CALL_DATA = []
def build_bridge_table():
_now = time()
_cnow = strftime('%Y-%m-%d %H:%M:%S', localtime(_now))
table = '<h3>Bridge Group Status Tables</h3>'
table += '<p>Table Last Updated: {}<br>'.format(_cnow)
table += 'Data Last Updated: {}</p>'.format(BRIDGES_RX)
for bridge in BRIDGES:
table += '<style>table, td, th {border: .5px solid black; padding: 2px; border-collapse: collapse}</style>'
table += '<table style="width:90%; font: 10pt arial, sans-serif">'
table += '<colgroup>\
<col style="width: 20%" />\
<col style="width: 5%" />\
<col style="width: 5%" />\
<col style="width: 10%" />\
<col style="width: 10%" />\
<col style="width: 10%" />\
<col style="width: 10%" />\
<col style="width: 10%" />\
<col style="width: 10%" />\
</colgroup>'
table += '<caption>{}</caption>'.format(bridge)
table += '<tr><th>System</th>\
<th>Slot</th>\
<th>TGID</th>\
<th>Status</th>\
<th>Timeout</th>\
<th>Timeout Action</th>\
<th>ON Triggers</th>\
<th>OFF Triggers</th></tr>'
for system in BRIDGES[bridge]:
on = ''
off = ''
active = '<td bgcolor="#FFFF00">Unknown</td>'
if system['TO_TYPE'] == 'ON' or system['TO_TYPE'] == 'OFF':
if system['TIMER'] - _now > 0:
exp_time = int(system['TIMER'] - _now)
else:
exp_time = 'Expired'
if system['TO_TYPE'] == 'ON':
to_action = 'Turn OFF'
else:
to_action = 'Turn ON'
else:
exp_time = 'N/A'
to_action = 'None'
if system['ACTIVE'] == True:
active = '<td bgcolor="#00FF00">Connected</td>'
elif system['ACTIVE'] == False:
active = '<td bgcolor="#FF0000">Disconnected</td>'
for trigger in system['ON']:
on += str(int_id(trigger)) + ' '
for trigger in system['OFF']:
off += str(int_id(trigger)) + ' '
table += '<tr> <td>{}</td> <td>{}</td> <td>{}</td> {} <td>{}</td> <td>{}</td> <td>{}</td> <td>{}</td> </tr>'.format(\
system['SYSTEM'],\
system['TS'],\
int_id(system['TGID']),\
active,\
exp_time,\
to_action,\
on,\
off)
table += '</table><br>'
return table
def unknown_message(self, _packettype, _peerid, _data):
self._logger.error('(%s) Unknown Message - Type: %s From: %s Packet: %s', ahex(_packettype), self._system, int_id(_peerid), ahex(_data))
def peer_alive_req(self, _data, _peerid, _host, _port):
_hex_mode = (_data[5])
_hex_flags = (_data[6:10])
_decoded_mode = process_mode_byte(_hex_mode)
_decoded_flags = process_flags_bytes(_hex_flags)
self._peers[_peerid]['MODE'] = _hex_mode
self._peers[_peerid]['MODE_DECODE'] = _decoded_mode
self._peers[_peerid]['FLAGS'] = _hex_flags
self._peers[_peerid]['FLAGS_DECODE'] = _decoded_flags
self.send_packet(self.PEER_ALIVE_REPLY_PKT, (_host, _port))
self.reset_keep_alive(_peerid) # Might as well reset our own counter, we know it's out there...
self._logger.debug('(%s) Keep-Alive reply sent to Peer %s, %s:%s', self._system, int_id(_peerid), _host, _port)
def private_data(self, _src_sub, _dst_sub, _ts, _end, _peerid, _data):
self._logger.debug('(%s) Private Data Packet Received From: %s, IPSC Peer %s, Destination %s', self._system, int_id(_src_sub), int_id(_peerid), int_id(_dst_sub))
def group_voice(self, _src_sub, _dst_sub, _ts, _end, _peerid, _data):
self._logger.debug('(%s) Group Voice Packet Received From: %s, IPSC Peer %s, Destination %s', self._system, int_id(_src_sub), int_id(_peerid), int_id(_dst_sub))
self._logger.debug('(%s) import_datagramReceived', self._system)
_slot = self._slot
_rx_slot = self.rx[_slot]
# Parse out the TLV
t = _data[0]
if (t):
l = _data[1]
if (l):
v = _data[2:]
if (v):
t = ord(t)
if (t == TAG_BEGIN_TX) or (t == TAG_SET_INFO):
if ord(l) > 1:
_slot = int_id(v[10:11])
_rx_slot = self.rx[_slot]
_rx_slot.slot = _slot
_rx_slot.rf_src = hex_str_3(int_id(v[0:3]))
_rx_slot.repeater_id = self._parent.get_repeater_id(
hex_str_4(int_id(v[3:7])))
_rx_slot.dst_id = hex_str_3(int_id(v[7:10]))
_rx_slot.cc = int_id(v[11:12])
if t == TAG_BEGIN_TX:
_rx_slot.stream_id = hex_str_4(
randint(0, 0xFFFFFFFF)
) # Every stream has a unique ID
self._logger.info('(%s) Begin AMBE encode STREAM ID: %s SUB: %s (%s) REPEATER: %s (%s) TGID %s (%s), TS %s', \
self._system, int_id(_rx_slot.stream_id), get_alias(_rx_slot.rf_src, subscriber_ids), int_id(_rx_slot.rf_src), get_alias(_rx_slot.repeater_id, peer_ids), int_id(_rx_slot.repeater_id), get_alias(_rx_slot.dst_id, talkgroup_ids), int_id(_rx_slot.dst_id), _slot)
self.send_voice_header(_rx_slot)
def peer_maintenance_loop(self):
self._logger.debug('(%s) PEER Connection Maintenance Loop Started', self._system)
# If the master isn't connected, we have to do that before we can do anything else!
#
if not self._master_stat['CONNECTED']:
self.send_packet(self.MASTER_REG_REQ_PKT, self._master_sock)
self._logger.info('(%s) Registering with the Master: %s:%s', self._system, self._master['IP'], self._master['PORT'])
# Once the master is connected, we have to send keep-alives.. and make sure we get them back
elif self._master_stat['CONNECTED']:
# Send keep-alive to the master
self.send_packet(self.MASTER_ALIVE_PKT, self._master_sock)
self._logger.debug('(%s) Keep Alive Sent to the Master: %s, %s:%s', self._system, int_id(self._master['RADIO_ID']) ,self._master['IP'], self._master['PORT'])
# If we had a keep-alive outstanding by the time we send another, mark it missed.
if (self._master_stat['KEEP_ALIVES_OUTSTANDING']) > 0:
self._master_stat['KEEP_ALIVES_MISSED'] += 1
self._logger.info('(%s) Master Keep-Alive Missed: %s:%s', self._system, self._master['IP'], self._master['PORT'])
# If we have missed too many keep-alives, de-register the master and start over.
if self._master_stat['KEEP_ALIVES_OUTSTANDING'] >= self._local['MAX_MISSED']:
self._master_stat['CONNECTED'] = False
self._master_stat['KEEP_ALIVES_OUTSTANDING'] = 0
self._logger.error('(%s) Maximum Master Keep-Alives Missed -- De-registering the Master: %s:%s', self._system, self._master['IP'], self._master['PORT'])
# Update our stats before we move on...
self._master_stat['KEEP_ALIVES_SENT'] += 1
self._master_stat['KEEP_ALIVES_OUTSTANDING'] += 1
else:
# This is bad. If we get this message, we need to reset the state and try again
self._logger.error('->> (%s) Master in UNKOWN STATE: %s:%s', self._system, self._master_sock)
self._master_stat['CONNECTED'] = False
# If the master is connected and we don't have a peer-list yet....
#
if (self._master_stat['CONNECTED'] == True) and (self._master_stat['PEER_LIST'] == False):
# Ask the master for a peer-list
if self._local['NUM_PEERS']:
self.send_packet(self.PEER_LIST_REQ_PKT, self._master_sock)
self._logger.info('(%s), No Peer List - Requesting One From the Master', self._system)
else:
self._master_stat['PEER_LIST'] = True
self._logger.debug('(%s), Skip asking for a Peer List, we are the only Peer', self._system)
# If we do have a peer-list, we need to register with the peers and send keep-alives...
#
if self._master_stat['PEER_LIST']:
# Iterate the list of peers... so we do this for each one.
for peer in self._peers.keys():
# We will show up in the peer list, but shouldn't try to talk to ourselves.
if peer == self._local_id:
continue
# If we haven't registered to a peer, send a registration
if not self._peers[peer]['STATUS']['CONNECTED']:
self.send_packet(self.PEER_REG_REQ_PKT, (self._peers[peer]['IP'], self._peers[peer]['PORT']))
self._logger.info('(%s) Registering with Peer %s, %s:%s', self._system, int_id(peer), self._peers[peer]['IP'], self._peers[peer]['PORT'])
# If we have registered with the peer, then send a keep-alive
elif self._peers[peer]['STATUS']['CONNECTED']:
self.send_packet(self.PEER_ALIVE_REQ_PKT, (self._peers[peer]['IP'], self._peers[peer]['PORT']))
self._logger.debug('(%s) Keep-Alive Sent to the Peer %s, %s:%s', self._system, int_id(peer), self._peers[peer]['IP'], self._peers[peer]['PORT'])
# If we have a keep-alive outstanding by the time we send another, mark it missed.
if self._peers[peer]['STATUS']['KEEP_ALIVES_OUTSTANDING'] > 0:
self._peers[peer]['STATUS']['KEEP_ALIVES_MISSED'] += 1
self._logger.info('(%s) Peer Keep-Alive Missed for %s, %s:%s', self._system, int_id(peer), self._peers[peer]['IP'], self._peers[peer]['PORT'])
# If we have missed too many keep-alives, de-register the peer and start over.
if self._peers[peer]['STATUS']['KEEP_ALIVES_OUTSTANDING'] >= self._local['MAX_MISSED']:
self._peers[peer]['STATUS']['CONNECTED'] = False
#del peer # Becuase once it's out of the dictionary, you can't use it for anything else.
self._logger.warning('(%s) Maximum Peer Keep-Alives Missed -- De-registering the Peer: %s, %s:%s', self._system, int_id(peer), self._peers[peer]['IP'], self._peers[peer]['PORT'])
# Update our stats before moving on...
self._peers[peer]['STATUS']['KEEP_ALIVES_SENT'] += 1
self._peers[peer]['STATUS']['KEEP_ALIVES_OUTSTANDING'] += 1
def acl_check(_id, _acl):
id = int_id(_id)
for entry in _acl[1]:
if entry[0] <= id <= entry[1]:
return _acl[0]
return not _acl[0]
def build_hblink_table(_config, _stats_table):
for _hbp, _hbp_data in _config.iteritems():
if _hbp_data['ENABLED'] == True:
# Process Master Systems
if _hbp_data['MODE'] == 'MASTER':
_stats_table['MASTERS'][_hbp] = {}
if _hbp_data['REPEAT']:
_stats_table['MASTERS'][_hbp]['REPEAT'] = "repeat"
else:
_stats_table['MASTERS'][_hbp]['REPEAT'] = "isolate"
_stats_table['MASTERS'][_hbp]['PEERS'] = {}
for _peer in _hbp_data['PEERS']:
add_hb_peer(_hbp_data['PEERS'][_peer], _stats_table['MASTERS'][_hbp]['PEERS'], _peer)
# Proccess Peer Systems
elif _hbp_data['MODE'] == 'PEER' or _hbp_data['MODE'] == 'XLXPEER':
_stats_table['PEERS'][_hbp] = {}
_stats_table['PEERS'][_hbp]['MODE'] = _hbp_data['MODE']
_stats_table['PEERS'][_hbp]['CALLSIGN'] = _hbp_data['CALLSIGN']
_stats_table['PEERS'][_hbp]['LOCATION'] = _hbp_data['LOCATION']
_stats_table['PEERS'][_hbp]['RADIO_ID'] = int_id(_hbp_data['RADIO_ID'])
_stats_table['PEERS'][_hbp]['MASTER_IP'] = _hbp_data['MASTER_IP']
_stats_table['PEERS'][_hbp]['MASTER_PORT'] = _hbp_data['MASTER_PORT']
_stats_table['PEERS'][_hbp]['STATS'] = {}
if _stats_table['PEERS'][_hbp]['MODE'] == 'XLXPEER':
_stats_table['PEERS'][_hbp]['STATS']['CONNECTION'] = _hbp_data['XLXSTATS']['CONNECTION']
_stats_table['PEERS'][_hbp]['STATS']['CONNECTED'] = since(_hbp_data['XLXSTATS']['CONNECTED'])
_stats_table['PEERS'][_hbp]['STATS']['PINGS_SENT'] = _hbp_data['XLXSTATS']['PINGS_SENT']
_stats_table['PEERS'][_hbp]['STATS']['PINGS_ACKD'] = _hbp_data['XLXSTATS']['PINGS_ACKD']
else:
_stats_table['PEERS'][_hbp]['STATS']['CONNECTION'] = _hbp_data['STATS']['CONNECTION']
_stats_table['PEERS'][_hbp]['STATS']['CONNECTED'] = since(_hbp_data['STATS']['CONNECTED'])
_stats_table['PEERS'][_hbp]['STATS']['PINGS_SENT'] = _hbp_data['STATS']['PINGS_SENT']
_stats_table['PEERS'][_hbp]['STATS']['PINGS_ACKD'] = _hbp_data['STATS']['PINGS_ACKD']
if _hbp_data['SLOTS'] == 0:
_stats_table['PEERS'][_hbp]['SLOTS'] = 'NONE'
elif _hbp_data['SLOTS'] <= '2':
_stats_table['PEERS'][_hbp]['SLOTS'] = _hbp_data['SLOTS']
elif _hbp_data['SLOTS'] == '3':
_stats_table['PEERS'][_hbp]['SLOTS'] = 'BOTH'
else:
_stats_table['SLOTS'][_hbp]['SLOTS'] = 'DMO'
# SLOT 1&2 - for real-time montior: make the structure for later use
for ts in range(1,3):
_stats_table['PEERS'][_hbp][ts]= {}
_stats_table['PEERS'][_hbp][ts]['COLOR'] = ''
_stats_table['PEERS'][_hbp][ts]['BGCOLOR'] = ''
_stats_table['PEERS'][_hbp][ts]['TS'] = ''
_stats_table['PEERS'][_hbp][ts]['TYPE'] = ''
_stats_table['PEERS'][_hbp][ts]['SUB'] = ''
_stats_table['PEERS'][_hbp][ts]['SRC'] = ''
_stats_table['PEERS'][_hbp][ts]['DEST'] = ''
# Process OpenBridge systems
elif _hbp_data['MODE'] == 'OPENBRIDGE':
_stats_table['OPENBRIDGES'][_hbp] = {}
_stats_table['OPENBRIDGES'][_hbp]['NETWORK_ID'] = int_id(_hbp_data['NETWORK_ID'])
_stats_table['OPENBRIDGES'][_hbp]['TARGET_IP'] = _hbp_data['TARGET_IP']
_stats_table['OPENBRIDGES'][_hbp]['TARGET_PORT'] = _hbp_data['TARGET_PORT']
_stats_table['OPENBRIDGES'][_hbp]['STREAMS'] = {}
def peer_list_reply(self, _data, _peerid):
self._master['STATUS']['PEER_LIST'] = True
if len(_data) > 18:
self.process_peer_list(_data)
self._logger.debug('(%s) Peer List Reply Received From Master %s, %s:%s', self._system, int_id(_peerid), self._master['IP'], self._master['PORT'])
def peer_datagramReceived(self, _data, _sockaddr):
# Keep This Line Commented Unless HEAVILY Debugging!
# self._logger.debug('(%s) RX packet from %s -- %s', self._system, _sockaddr, ahex(_data))
# Validate that we receveived this packet from the master - security check!
if self._config['MASTER_SOCKADDR'] == _sockaddr:
# Extract the command, which is various length, but only 4 significant characters
_command = _data[:4]
if _command == 'DMRD': # DMRData -- encapsulated DMR data frame
_peer_id = _data[11:15]
if self._config['LOOSE'] or _peer_id == self._config[
'RADIO_ID']: # Validate the Radio_ID unless using loose validation
_seq = _data[4:5]
_rf_src = _data[5:8]
_dst_id = _data[8:11]
_bits = int_id(_data[15])
_slot = 2 if (_bits & 0x80) else 1
_call_type = 'unit' if (_bits & 0x40) else 'group'
_frame_type = (_bits & 0x30) >> 4
_dtype_vseq = (
_bits & 0xF
) # data, 1=voice header, 2=voice terminator; voice, 0=burst A ... 5=burst F
_stream_id = _data[16:20]
self._logger.debug(
'(%s) DMRD - Sequence: %s, RF Source: %s, Destination ID: %s',
self._system, int_id(_seq), int_id(_rf_src),
int_id(_dst_id))
# If AMBE audio exporting is configured...
if self._config['EXPORT_AMBE']:
self._ambe.parseAMBE(self._system, _data)
# Userland actions -- typically this is the function you subclass for an application
self.dmrd_received(_peer_id, _rf_src, _dst_id, _seq, _slot,
_call_type, _frame_type, _dtype_vseq,
_stream_id, _data)
elif _command == 'MSTN': # Actually MSTNAK -- a NACK from the master
_peer_id = _data[6:10]
if self._config['LOOSE'] or _peer_id == self._config[
'RADIO_ID']: # Validate the Radio_ID unless using loose validation
self._logger.warning(
'(%s) MSTNAK Received. Resetting connection to the Master.',
self._system)
self._stats[
'CONNECTION'] = 'NO' # Disconnect ourselves and re-register
elif _command == 'RPTA': # Actually RPTACK -- an ACK from the master
# Depending on the state, an RPTACK means different things, in each clause, we check and/or set the state
if self._stats[
'CONNECTION'] == 'RPTL_SENT': # If we've sent a login request...
_login_int32 = _data[6:10]
self._logger.info(
'(%s) Repeater Login ACK Received with 32bit ID: %s',
self._system, int_id(_login_int32))
_pass_hash = sha256(
_login_int32 + self._config['PASSPHRASE']).hexdigest()
_pass_hash = bhex(_pass_hash)
self.send_master('RPTK' + self._config['RADIO_ID'] +
_pass_hash)
self._stats['CONNECTION'] = 'AUTHENTICATED'
elif self._stats[
'CONNECTION'] == 'AUTHENTICATED': # If we've sent the login challenge...
_peer_id = _data[6:10]
if self._config['LOOSE'] or _peer_id == self._config[
'RADIO_ID']: # Validate the Radio_ID unless using loose validation
self._logger.info(
'(%s) Repeater Authentication Accepted',
self._system)
_config_packet = self._config['RADIO_ID']+\
self._config['CALLSIGN']+\
self._config['RX_FREQ']+\
self._config['TX_FREQ']+\
self._config['TX_POWER']+\
self._config['COLORCODE']+\
self._config['LATITUDE']+\
self._config['LONGITUDE']+\
self._config['HEIGHT']+\
self._config['LOCATION']+\
self._config['DESCRIPTION']+\
self._config['SLOTS']+\
self._config['URL']+\
self._config['SOFTWARE_ID']+\
self._config['PACKAGE_ID']
self.send_master('RPTC' + _config_packet)
self._stats['CONNECTION'] = 'CONFIG-SENT'
self._logger.info('(%s) Repeater Configuration Sent',
self._system)
else:
self._stats['CONNECTION'] = 'NO'
self._logger.error(
'(%s) Master ACK Contained wrong ID - Connection Reset',
self._system)
elif self._stats[
'CONNECTION'] == 'CONFIG-SENT': # If we've sent out configuration to the master
_peer_id = _data[6:10]
if self._config['LOOSE'] or _peer_id == self._config[
'RADIO_ID']: # Validate the Radio_ID unless using loose validation
self._logger.info(
'(%s) Repeater Configuration Accepted',
self._system)
if self._config['OPTIONS']:
self.send_master('RPTO' +
self._config['RADIO_ID'] +
self._config['OPTIONS'])
self._stats['CONNECTION'] = 'OPTIONS-SENT'
self._logger.info('(%s) Sent options: (%s)',
self._system,
self._config['OPTIONS'])
else:
self._stats['CONNECTION'] = 'YES'
self._logger.info(
'(%s) Connection to Master Completed',
self._system)
else:
self._stats['CONNECTION'] = 'NO'
self._logger.error(
'(%s) Master ACK Contained wrong ID - Connection Reset',
self._system)
elif self._stats[
'CONNECTION'] == 'OPTIONS-SENT': # If we've sent out options to the master
_peer_id = _data[6:10]
if self._config['LOOSE'] or _peer_id == self._config[
'RADIO_ID']: # Validate the Radio_ID unless using loose validation
self._logger.info('(%s) Repeater Options Accepted',
self._system)
self._stats['CONNECTION'] = 'YES'
self._logger.info(
'(%s) Connection to Master Completed with options',
self._system)
else:
self._stats['CONNECTION'] = 'NO'
self._logger.error(
'(%s) Master ACK Contained wrong ID - Connection Reset',
self._system)
elif _command == 'MSTP': # Actually MSTPONG -- a reply to RPTPING (send by peer)
_peer_id = _data[7:11]
if self._config['LOOSE'] or _peer_id == self._config[
'RADIO_ID']: # Validate the Radio_ID unless using loose validation
self._stats['PING_OUTSTANDING'] = False
self._stats['NUM_OUTSTANDING'] = 0
self._stats['PINGS_ACKD'] += 1
self._logger.debug(
'(%s) MSTPONG Received. Pongs Since Connected: %s',
self._system, self._stats['PINGS_ACKD'])
elif _command == 'MSTC': # Actually MSTCL -- notify us the master is closing down
_peer_id = _data[5:9]
if self._config['LOOSE'] or _peer_id == self._config[
'RADIO_ID']: # Validate the Radio_ID unless using loose validation
self._stats['CONNECTION'] = 'NO'
self._logger.info('(%s) MSTCL Recieved', self._system)
else:
self._logger.error(
'(%s) Received an invalid command in packet: %s',
self._system, ahex(_data))
def master_reg_reply(self, _data, _peerid):
_hex_mode = _data[5]
_hex_flags = _data[6:10]
_num_peers = _data[10:12]
_decoded_mode = process_mode_byte(_hex_mode)
_decoded_flags = process_flags_bytes(_hex_flags)
self._local['NUM_PEERS'] = int(ahex(_num_peers), 16)
self._master['RADIO_ID'] = _peerid
self._master['MODE'] = _hex_mode
self._master['MODE_DECODE'] = _decoded_mode
self._master['FLAGS'] = _hex_flags
self._master['FLAGS_DECODE'] = _decoded_flags
self._master_stat['CONNECTED'] = True
self._master_stat['KEEP_ALIVES_OUTSTANDING'] = 0
self._logger.warning('(%s) Registration response (we requested reg) from the Master: %s, %s:%s (%s peers)', self._system, int_id(_peerid), self._master['IP'], self._master['PORT'], self._local['NUM_PEERS'])
def group_voice(self, _src_sub, _dst_sub, _ts, _end, _peerid, _data):
if HEX_TGID == _dst_sub and _ts in GROUP_TS:
if not _end:
if not self.CALL_DATA:
self._logger.info('(%s) Receiving transmission to be played back from subscriber: %s', self._system, int_id(_src_sub))
_tmp_data = _data
#_tmp_data = dmr_nat(_data, _src_sub, self._config['LOCAL']['RADIO_ID'])
self.CALL_DATA.append(_tmp_data)
if _end:
self.CALL_DATA.append(_data)
time.sleep(2)
self._logger.info('(%s) Playing back transmission from subscriber: %s', self._system, int_id(_src_sub))
for i in self.CALL_DATA:
_tmp_data = i
_tmp_data = _tmp_data.replace(_peerid, self._config['LOCAL']['RADIO_ID'])
if GROUP_SRC_SUB:
_tmp_data = _tmp_data.replace(_src_sub, self.GROUP_SRC_SUB)
# Send the packet to all peers in the target IPSC
self.send_to_ipsc(_tmp_data)
time.sleep(0.06)
self.CALL_DATA = []
def master_reg_req(self, _data, _peerid, _host, _port):
_ip_address = _host
_port = _port
_hex_mode = _data[5]
_hex_flags = _data[6:10]
_decoded_mode = process_mode_byte(_hex_mode)
_decoded_flags = process_flags_bytes(_hex_flags)
self.MASTER_REG_REPLY_PKT = (MASTER_REG_REPLY + self._local_id + self.TS_FLAGS + hex_str_2(self._local['NUM_PEERS']) + IPSC_VER)
self.send_packet(self.MASTER_REG_REPLY_PKT, (_host, _port))
self._logger.info('(%s) Master Registration Packet Received from peer %s, %s:%s', self._system, int_id(_peerid), _host, _port)
# If this entry was NOT already in our list, add it.
if _peerid not in self._peers.keys():
self._peers[_peerid] = {
'IP': _ip_address,
'PORT': _port,
'MODE': _hex_mode,
'MODE_DECODE': _decoded_mode,
'FLAGS': _hex_flags,
'FLAGS_DECODE': _decoded_flags,
'STATUS': {
'CONNECTED': True,
'KEEP_ALIVES_SENT': 0,
'KEEP_ALIVES_MISSED': 0,
'KEEP_ALIVES_OUTSTANDING': 0,
'KEEP_ALIVES_RECEIVED': 0,
'KEEP_ALIVE_RX_TIME': int(time())
}
}
self._local['NUM_PEERS'] = len(self._peers)
self._logger.debug('(%s) Peer Added To Peer List: %s, %s:%s (IPSC now has %s Peers)', self._system, self._peers[_peerid], _host, _port, self._local['NUM_PEERS'])
# Aliased in __init__ to datagramReceived if system is a client
def client_datagramReceived(self, _data, (_host, _port)):
# Keep This Line Commented Unless HEAVILY Debugging!
# self._logger.debug('(%s) RX packet from %s:%s -- %s', self._system, _host, _port, ahex(_data))
# Validate that we receveived this packet from the master - security check!
if self._config['MASTER_IP'] == _host and self._config['MASTER_PORT'] == _port:
# Extract the command, which is various length, but only 4 significant characters
_command = _data[:4]
if _command == 'DMRD': # DMRData -- encapsulated DMR data frame
_radio_id = _data[11:15]
if _radio_id == self._config['RADIO_ID']: # Validate the source and intended target
_seq = _data[4:5]
_rf_src = _data[5:8]
_dst_id = _data[8:11]
_bits = int_id(_data[15])
_slot = 2 if (_bits & 0x80) else 1
_call_type = 'unit' if (_bits & 0x40) else 'group'
_frame_type = (_bits & 0x30) >> 4
_dtype_vseq = (_bits & 0xF) # data, 1=voice header, 2=voice terminator; voice, 0=burst A ... 5=burst F
_stream_id = _data[16:20]
#self._logger.debug('(%s) DMRD - Seqence: %s, RF Source: %s, Destination ID: %s', self._system, int_id(_seq), int_id(_rf_src), int_id(_dst_id))
# If AMBE audio exporting is configured...
if self._config['EXPORT_AMBE']:
self._ambe.parseAMBE(self._system, _data)
# Userland actions -- typically this is the function you subclass for an application
self.dmrd_received(_radio_id, _rf_src, _dst_id, _seq, _slot, _call_type, _frame_type, _dtype_vseq, _stream_id, _data)
elif _command == 'MSTN': # Actually MSTNAK -- a NACK from the master
def master_alive_req(self, _peerid, _host, _port):
if _peerid in self._peers.keys():
self._peers[_peerid]['STATUS']['KEEP_ALIVES_RECEIVED'] += 1
self._peers[_peerid]['STATUS']['KEEP_ALIVE_RX_TIME'] = int(time())
self.send_packet(self.MASTER_ALIVE_REPLY_PKT, (_host, _port))
self._logger.debug('(%s) Master Keep-Alive Request Received from peer %s, %s:%s', self._system, int_id(_peerid), _host, _port)
else:
self._logger.warning('(%s) Master Keep-Alive Request Received from *UNREGISTERED* peer %s, %s:%s', self._system, int_id(_peerid), _host, _port)
def peer_reg_req(self, _peerid, _host, _port):
self.send_packet(self.PEER_REG_REPLY_PKT, (_host, _port))
self._logger.info('(%s) Peer Registration Request From: %s, %s:%s', self._system, int_id(_peerid), _host, _port)
# Check for auth and authenticate the packet
# Strip the hash from the end... we don't need it anymore
#
# Once they're done, we move on to the processing or callbacks for each packet type.
#
# Callbacks are iterated in the order of "more likely" to "less likely" to reduce processing time
#
def datagramReceived(self, data, (host, port)):
_packettype = data[0:1]
_peerid = data[1:5]
_ipsc_seq = data[5:6]
# AUTHENTICATE THE PACKET
if self._local['AUTH_ENABLED']:
if not self.validate_auth(self._local['AUTH_KEY'], data):
self._logger.warning('(%s) AuthError: IPSC packet failed authentication. Type %s: Peer: %s, %s:%s', self._system, ahex(_packettype), int_id(_peerid), host, port)
return
# REMOVE SHA-1 AUTHENTICATION HASH: WE NO LONGER NEED IT
else:
data = self.strip_hash(data)
# PACKETS THAT WE RECEIVE FROM ANY VALID PEER OR VALID MASTER
if _packettype in ANY_PEER_REQUIRED:
if not(self.valid_master(_peerid) == False or self.valid_peer(_peerid) == False):
self._logger.warning('(%s) PeerError: Peer not in peer-list: %s, %s:%s', self._system, int_id(_peerid), host, port)
return
# ORIGINATED BY SUBSCRIBER UNITS - a.k.a someone transmitted
if _packettype in USER_PACKETS:
# Extract IPSC header not already extracted
def build_dmrlink_table():
_cnow = strftime('%Y-%m-%d %H:%M:%S', localtime(time()))
table = '<h3>IPSC Systems Status Tables</h3>'
table += '<p>Table Last Updated: {} <br>'.format(_cnow)
table += 'Data Last Updated: {}</p>'.format(CONFIG_RX)
table += '<style>table, td, th {border: .5px solid black; padding: 2px; border-collapse: collapse}</style>'
for ipsc in CONFIG:
master = CONFIG[ipsc]['LOCAL']['MASTER_PEER']
table += '<table style="width:90%; font: 10pt arial, sans-serif">'
table += '<colgroup>\
<col style="width: 30%" />\
<col style="width: 15%" />\
<col style="width: 15%" />\
<col style="width: 15%" />\
<col style="width: 10%" />\
<col style="width: 5%" />\
<col style="width: 5%" />\
<col style="width: 5%" />\
</colgroup>'
table += '<caption>IPSC System: <b>{}</b><br>'.format(ipsc)
if master:
table += 'DMRlink is the system Master'
else:
table += 'DMRlink is a system Peer'
table += '</caption>'
table += '<tr><th rowspan="2">Alias</th>\
<th rowspan="2">Type</th>\
<th rowspan="2">Radio ID</th>\
<th rowspan="2">IP Address</th>\
<th rowspan="2">Status</th>\
<th colspan="3">Keep Alives</th></tr>\
<tr><th>Sent</th><th>Received</th><th>Missed</th></tr>'
if not master:
stat = CONFIG[ipsc]['MASTER']['STATUS']
if stat['CONNECTED'] == True:
active = '<td bgcolor="#00FF00">Connected</td>'
elif stat['CONNECTED'] == False:
active = '<td bgcolor="#FF0000">Disconnected</td>'
table += '<tr><td>{}</td><td>Master</td><td>{}</td><td>{}</td>{}<td>{}</td><td>{}</td><td>{}</td></tr>'.format(\
alias_string(CONFIG[ipsc]['MASTER']['RADIO_ID'], peer_ids),\
str(int_id(CONFIG[ipsc]['MASTER']['RADIO_ID'])).rjust(8,'0'),\
CONFIG[ipsc]['MASTER']['IP'],\
active,\
stat['KEEP_ALIVES_SENT'],\
stat['KEEP_ALIVES_RECEIVED'],\
stat['KEEP_ALIVES_MISSED'],)
if master:
for peer in CONFIG[ipsc]['PEERS']:
stat = CONFIG[ipsc]['PEERS'][peer]['STATUS']
if stat['CONNECTED'] == True:
active = '<td bgcolor="#00FF00">Connected</td>'
elif stat['CONNECTED'] == False:
active = '<td bgcolor="#FF0000">Disconnected</td>'
table += '<tr><td>{}</td><td>Peer</td><td>{}</td><td>{}</td>{}<td>n/a</td><td>{}</td><td>n/a</td></tr>'.format(\
alias_string(peer, peer_ids),\
str(int_id(peer)).rjust(8,'0'),\
CONFIG[ipsc]['PEERS'][peer]['IP'],\
active,\
stat['KEEP_ALIVES_RECEIVED'])
else:
for peer in CONFIG[ipsc]['PEERS']:
stat = CONFIG[ipsc]['PEERS'][peer]['STATUS']
if stat['CONNECTED'] == True:
active = '<td bgcolor="#00FF00">Connected</td>'
elif stat['CONNECTED'] == False:
active = '<td bgcolor="#FF0000">Disconnected</td>'
if peer != CONFIG[ipsc]['LOCAL']['RADIO_ID']:
table += '<tr><td>{}</td><td>Peer</td><td>{}</td><td>{}</td>{}<td>{}</td><td>{}</td><td>{}</td></tr>'.format(\
alias_string(peer, peer_ids),\
str(int_id(peer)).rjust(8,'0'),\
CONFIG[ipsc]['PEERS'][peer]['IP'],\
active,\
stat['KEEP_ALIVES_SENT'],\
stat['KEEP_ALIVES_RECEIVED'],\
stat['KEEP_ALIVES_MISSED'])
table += '</table><br>'
return table
def peer_reg_reply(self, _peerid):
if _peerid in self._peers.keys():
self._peers[_peerid]['STATUS']['CONNECTED'] = True
self._logger.info('(%s) Registration Reply From: %s, %s:%s', self._system, int_id(_peerid), self._peers[_peerid]['IP'], self._peers[_peerid]['PORT'])
def de_register_peer(self, _peerid):
# Iterate for the peer in our data
if _peerid in self._peers.keys():
del self._peers[_peerid]
self._logger.info('(%s) Peer De-Registration Requested for: %s', self._system, int_id(_peerid))
return
else:
self._logger.warning('(%s) Peer De-Registration Requested for: %s, but we don\'t have a listing for this peer', self._system, int_id(_peerid))
pass
def master_alive_reply(self, _peerid):
self.reset_keep_alive(_peerid)
self._master['STATUS']['KEEP_ALIVES_RECEIVED'] += 1
self._master['STATUS']['KEEP_ALIVE_RX_TIME'] = int(time())
self._logger.debug('(%s) Keep-Alive Reply (we sent the request) Received from the Master %s, %s:%s', self._system, int_id(_peerid), self._master['IP'], self._master['PORT'])
def group_voice(self, _src_sub, _dst_group, _ts, _end, _peerid, _data):
# Check for ACL match, and return if the subscriber is not allowed
if allow_sub(_src_sub) == False:
self._logger.warning(
'(%s) Group Voice Packet ***REJECTED BY ACL*** From: %s, IPSC Peer %s, Destination %s',
self._system, int_id(_src_sub), int_id(_peerid),
int_id(_dst_group))
return
# Process the packet
self._logger.debug(
'(%s) Group Voice Packet Received From: %s, IPSC Peer %s, Destination %s',
self._system, int_id(_src_sub), int_id(_peerid),
int_id(_dst_group))
_burst_data_type = _data[
30] # Determine the type of voice packet this is (see top of file for possible types)
_seq_id = _data[5]
now = time(
) # Mark packet arrival time -- we'll need this for call contention handling
for rule in RULES[self._system]['GROUP_VOICE']:
_target = rule[
'DST_NET'] # Shorthand to reduce length and make it easier to read
_status = systems[
_target].IPSC_STATUS # Shorthand to reduce length and make it easier to read
# This is the primary rule match to determine if the call will be routed.
if (rule['SRC_GROUP'] == _dst_group and rule['SRC_TS'] == _ts
and rule['ACTIVE'] == True) and (self.BRIDGE == True
or systems[_target].BRIDGE
== True):
#
# BEGIN CONTENTION HANDLING
#
# If this is an inter-DMRlink trunk, this isn't necessary
if RULES[self._system]['TRUNK'] == False:
# The rules for each of the 4 "ifs" below are listed here for readability. The Frame To Send is:
# From a different group than last RX from this IPSC, but it has been less than Group Hangtime
# From a different group than last TX to this IPSC, but it has been less than Group Hangtime
# From the same group as the last RX from this IPSC, but from a different subscriber, and it has been less than TS Clear Time
# From the same group as the last TX to this IPSC, but from a different subscriber, and it has been less than TS Clear Time
# The "continue" at the end of each means the next iteration of the for loop that tests for matching rules
#
if ((rule['DST_GROUP'] !=
_status[rule['DST_TS']]['RX_GROUP'])
and ((now - _status[rule['DST_TS']]['RX_TIME']) <
RULES[_target]['GROUP_HANGTIME'])):
if _burst_data_type == BURST_DATA_TYPE['VOICE_HEAD']:
self._logger.info(
'(%s) Call not bridged to TGID%s, target active or in group hangtime: IPSC: %s, TS: %s, TGID: %s',
self._system, int_id(rule['DST_GROUP']),
_target, rule['DST_TS'],
int_id(_status[rule['DST_TS']]['RX_GROUP']))
continue
if ((rule['DST_GROUP'] !=
_status[rule['DST_TS']]['TX_GROUP'])
and ((now - _status[rule['DST_TS']]['TX_TIME']) <
RULES[_target]['GROUP_HANGTIME'])):
if _burst_data_type == BURST_DATA_TYPE['VOICE_HEAD']:
self._logger.info(
'(%s) Call not bridged to TGID%s, target in group hangtime: IPSC: %s, TS: %s, TGID: %s',
self._system, int_id(rule['DST_GROUP']),
_target, rule['DST_TS'],
int_id(_status[rule['DST_TS']]['TX_GROUP']))
continue
if (rule['DST_GROUP']
== _status[rule['DST_TS']]['RX_GROUP']) and (
(now - _status[rule['DST_TS']]['RX_TIME']) <
TS_CLEAR_TIME):
if _burst_data_type == BURST_DATA_TYPE['VOICE_HEAD']:
self._logger.info(
'(%s) Call not bridged to TGID%s, matching call already active on target: IPSC: %s, TS: %s, TGID: %s',
self._system, int_id(rule['DST_GROUP']),
_target, rule['DST_TS'],
int_id(_status[rule['DST_TS']]['RX_GROUP']))
continue
if (rule['DST_GROUP']
== _status[rule['DST_TS']]['TX_GROUP']) and (
_src_sub !=
_status[rule['DST_TS']]['TX_SRC_SUB']) and (
(now - _status[rule['DST_TS']]['TX_TIME'])
< TS_CLEAR_TIME):
if _burst_data_type == BURST_DATA_TYPE['VOICE_HEAD']:
self._logger.info(
'(%s) Call not bridged for subscriber %s, call bridge in progress on target: IPSC: %s, TS: %s, TGID: %s SUB: %s',
self._system, int_id(_src_sub), _target,
rule['DST_TS'],
int_id(_status[rule['DST_TS']]['TX_GROUP']),
int_id(_status[rule['DST_TS']]['TX_SRC_SUB']))
continue
#
# END CONTENTION HANDLING
#
#
# BEGIN FRAME FORWARDING
#
# Make a copy of the payload
_tmp_data = _data
# Re-Write the IPSC SRC to match the target network's ID
_tmp_data = _tmp_data.replace(
_peerid,
self._CONFIG['SYSTEMS'][_target]['LOCAL']['RADIO_ID'])
# Re-Write the destination Group ID
_tmp_data = _tmp_data.replace(_dst_group, rule['DST_GROUP'])
# Re-Write IPSC timeslot value
_call_info = int_id(_data[17:18])
if rule['DST_TS'] == 1:
_call_info &= ~(1 << 5)
elif rule['DST_TS'] == 2:
_call_info |= 1 << 5
_call_info = chr(_call_info)
_tmp_data = _tmp_data[:17] + _call_info + _tmp_data[18:]
# Re-Write DMR timeslot value
# Determine if the slot is present, so we can translate if need be
if _burst_data_type == BURST_DATA_TYPE[
'SLOT1_VOICE'] or _burst_data_type == BURST_DATA_TYPE[
'SLOT2_VOICE']:
_slot_valid = True
else:
_slot_valid = False
# Re-Write timeslot if necessary...
if _slot_valid:
if rule['DST_TS'] == 1:
_burst_data_type = BURST_DATA_TYPE['SLOT1_VOICE']
elif rule['DST_TS'] == 1:
_burst_data_type = BURST_DATA_TYPE['SLOT2_VOICE']
_tmp_data = _tmp_data[:30] + _burst_data_type + _tmp_data[
31:]
# Send the packet to all peers in the target IPSC
systems[_target].send_to_ipsc(_tmp_data)
#
# END FRAME FORWARDING
#
# Set values for the contention handler to test next time there is a frame to forward
_status[_ts]['TX_GROUP'] = rule['DST_GROUP']
_status[_ts]['TX_TIME'] = now
_status[_ts]['TX_SRC_SUB'] = _src_sub
# Mark the group and time that a packet was recieved for the contention handler to use later
self.IPSC_STATUS[_ts]['RX_GROUP'] = _dst_group
self.IPSC_STATUS[_ts]['RX_TIME'] = now
#
# BEGIN IN-BAND SIGNALING BASED ON TGID & VOICE TERMINATOR FRAME
#
# Activate/Deactivate rules based on group voice activity -- PTT or UA for you c-Bridge dorks.
# This will ONLY work for symmetrical rules!!!
# Action happens on key up
if _burst_data_type == BURST_DATA_TYPE['VOICE_HEAD']:
if self.last_seq_id != _seq_id:
self.last_seq_id = _seq_id
self.call_start = time()
self._logger.info(
'(%s) GROUP VOICE START: CallID: %s PEER: %s, SUB: %s, TS: %s, TGID: %s',
self._system, int_id(_seq_id), int_id(_peerid),
int_id(_src_sub), _ts, int_id(_dst_group))
# Action happens on un-key
if _burst_data_type == BURST_DATA_TYPE['VOICE_TERM']:
if self.last_seq_id == _seq_id:
self.call_duration = time() - self.call_start
self._logger.info(
'(%s) GROUP VOICE END: CallID: %s PEER: %s, SUB: %s, TS: %s, TGID: %s Duration: %.2fs',
self._system, int_id(_seq_id), int_id(_peerid),
int_id(_src_sub), _ts, int_id(_dst_group),
self.call_duration)
else:
self._logger.warning(
'(%s) GROUP VOICE END WITHOUT MATCHING START: CallID: %s PEER: %s, SUB: %s, TS: %s, TGID: %s',
self._system,
int_id(_seq_id),
int_id(_peerid),
int_id(_src_sub),
_ts,
int_id(_dst_group),
)
# Iterate the rules dictionary
for rule in RULES[self._system]['GROUP_VOICE']:
_target = rule['DST_NET']
# TGID matches a rule source, reset its timer
if _ts == rule['SRC_TS'] and _dst_group == rule[
'SRC_GROUP'] and ((rule['TO_TYPE'] == 'ON' and
(rule['ACTIVE'] == True)) or
(rule['TO_TYPE'] == 'OFF'
and rule['ACTIVE'] == False)):
rule['TIMER'] = now + rule['TIMEOUT']
self._logger.info(
'(%s) Source group transmission match for rule \"%s\". Reset timeout to %s',
self._system, rule['NAME'], rule['TIMER'])
# Scan for reciprocal rules and reset their timers as well.
for target_rule in RULES[_target]['GROUP_VOICE']:
if target_rule['NAME'] == rule['NAME']:
target_rule['TIMER'] = now + target_rule['TIMEOUT']
self._logger.info(
'(%s) Reciprocal group transmission match for rule \"%s\" on IPSC \"%s\". Reset timeout to %s',
self._system, target_rule['NAME'], _target,
rule['TIMER'])
# TGID matches an ACTIVATION trigger
if _dst_group in rule['ON']:
# Set the matching rule as ACTIVE
rule['ACTIVE'] = True
rule['TIMER'] = now + rule['TIMEOUT']
self._logger.info(
'(%s) Primary Bridge Rule \"%s\" changed to state: %s',
self._system, rule['NAME'], rule['ACTIVE'])
# Set reciprocal rules for other IPSCs as ACTIVE
for target_rule in RULES[_target]['GROUP_VOICE']:
if target_rule['NAME'] == rule['NAME']:
target_rule['ACTIVE'] = True
target_rule['TIMER'] = now + target_rule['TIMEOUT']
self._logger.info(
'(%s) Reciprocal Bridge Rule \"%s\" in IPSC \"%s\" changed to state: %s',
self._system, target_rule['NAME'], _target,
rule['ACTIVE'])
# TGID matches an DE-ACTIVATION trigger
if _dst_group in rule['OFF']:
# Set the matching rule as ACTIVE
rule['ACTIVE'] = False
self._logger.info(
'(%s) Bridge Rule \"%s\" changed to state: %s',
self._system, rule['NAME'], rule['ACTIVE'])
# Set reciprocal rules for other IPSCs as ACTIVE
_target = rule['DST_NET']
for target_rule in RULES[_target]['GROUP_VOICE']:
if target_rule['NAME'] == rule['NAME']:
target_rule['ACTIVE'] = False
self._logger.info(
'(%s) Reciprocal Bridge Rule \"%s\" in IPSC \"%s\" changed to state: %s',
self._system, target_rule['NAME'], _target,
rule['ACTIVE'])
def process_peer_list(self, _data):
# Create a temporary peer list to track who we should have in our list -- used to find old peers we should remove.
_temp_peers = []
# Determine the length of the peer list for the parsing iterator
_peer_list_length = int(ahex(_data[5:7]), 16)
# Record the number of peers in the data structure... we'll use it later (11 bytes per peer entry)
self._local['NUM_PEERS'] = _peer_list_length/11
self._logger.info('(%s) Peer List Received from Master: %s peers in this IPSC', self._system, self._local['NUM_PEERS'])
# Iterate each peer entry in the peer list. Skip the header, then pull the next peer, the next, etc.
for i in range(7, _peer_list_length +7, 11):
# Extract various elements from each entry...
_hex_radio_id = (_data[i:i+4])
_hex_address = (_data[i+4:i+8])
_ip_address = IPAddr(_hex_address)
_hex_port = (_data[i+8:i+10])
_port = int(ahex(_hex_port), 16)
_hex_mode = (_data[i+10:i+11])
# Add this peer to a temporary PeerID list - used to remove any old peers no longer with us
_temp_peers.append(_hex_radio_id)
# This is done elsewhere for the master too, so we use a separate function
_decoded_mode = process_mode_byte(_hex_mode)
# If this entry WAS already in our list, update everything except the stats
# in case this was a re-registration with a different mode, flags, etc.
if _hex_radio_id in self._peers.keys():
self._peers[_hex_radio_id]['IP'] = _ip_address
self._peers[_hex_radio_id]['PORT'] = _port
self._peers[_hex_radio_id]['MODE'] = _hex_mode
self._peers[_hex_radio_id]['MODE_DECODE'] = _decoded_mode
self._peers[_hex_radio_id]['FLAGS'] = ''
self._peers[_hex_radio_id]['FLAGS_DECODE'] = ''
self._logger.debug('(%s) Peer Updated: %s', self._system, self._peers[_hex_radio_id])
# If this entry was NOT already in our list, add it.
if _hex_radio_id not in self._peers.keys():
self._peers[_hex_radio_id] = {
'IP': _ip_address,
'PORT': _port,
'MODE': _hex_mode,
'MODE_DECODE': _decoded_mode,
'FLAGS': '',
'FLAGS_DECODE': '',
'STATUS': {
'CONNECTED': False,
'KEEP_ALIVES_SENT': 0,
'KEEP_ALIVES_MISSED': 0,
'KEEP_ALIVES_OUTSTANDING': 0,
'KEEP_ALIVES_RECEIVED': 0,
'KEEP_ALIVE_RX_TIME': 0
}
}
self._logger.debug('(%s) Peer Added: %s', self._system, self._peers[_hex_radio_id])
# Finally, check to see if there's a peer already in our list that was not in this peer list
# and if so, delete it.
for peer in self._peers.keys():
if peer not in _temp_peers:
self.de_register_peer(peer)
self._logger.warning('(%s) Peer Deleted (not in new peer list): %s', self._system, int_id(peer))
