Ejemplo n.º 1
0
def initialize2(num_taxel, MTB_ID, num_taxel2, MTB_ID2, baud):
    for j in range(0, len(MTB_ID)):
        for k in range(0, num_taxel):
            cif_array[j, k] = ntcan.CIF(net, RxQS)  #configure parameters
            cif_array[j, k].baudrate = baud  # set baudrate 0 = 1MBaud
            cmsg_array[j, k] = ntcan.CMSG()

    for j in range(len(MTB_ID), len(MTB_ID) + len(MTB_ID2)):
        for k in range(0, num_taxel2):
            cif_array[j, k] = ntcan.CIF(net, RxQS)  #configure parameters
            cif_array[j, k].baudrate = baud  # set baudrate 0 = 1MBaud
            cmsg_array[j, k] = ntcan.CMSG()
Ejemplo n.º 2
0
def initialize(num_taxel, MTB_ID, baud):
    for j in range(0, len(MTB_ID)):
        for k in range(0, num_taxel):
            cif_array[j, k] = ntcan.CIF(net, RxQS)  #configure parameters
            cif_array[j, k].baudrate = baud  # set baudrate 0 = 1MBaud
            cmsg_array[j, k] = ntcan.CMSG()  #for

    # validate the configuration & check the CAN-USB availability
    print(cif_array[0, 0])
    print(cif_array[0, 0].net)
    print(cif_array[0, 0].tx_timeout)
    print(cif_array[0, 0].rx_timeout)
    print(cif_array[0, 0].features)
    util.print2lines()

    print "cmsg lost: %d" % (cmsg_array[0, 0].msg_lost)
    print "cmsg2 %s" % (cmsg_array[0, 0])
Ejemplo n.º 3
0
def ntcan_init():

    # cif = ntcan.CIF( net, RxQueueSize, RxTimeOut, TxQueueSize, TxTimeOut, Flags)
    # RxQS, TxQS = 1 for real time application

    # Initialise cif using a loop
    for j in range(board_start_num, board_start_num + num_of_board):
        for k in range(0, num_of_taxel):
            cif_array[j, k] = ntcan.CIF(net, RxQS)

            # CAN-API-Description & set baudrate 0 = 1MBaud
            cif_array[j, k].baudrate = 0

            # Create CAN-Message structure
            cmsg_array[j, k] = ntcan.CMSG()

        # Target ID of the MTB & trigger the MTB to return the data
        # canWrite...(cif, can-id, len, data ...)
        cmsg_array[j, 0].canWriteByte(cif_array[j, 0], (id_base | j), 2, 7, 0)

    print('\nSetting up ESD-CAN...')
    print(cif_array[board_start_num, 0])
    print(('Cmsg: %s') % (cmsg_array[board_start_num, 0]))
    print(('Cmsg lost: %d') % (cmsg_array[board_start_num, 0].msg_lost))
Ejemplo n.º 4
0
def ntcan_init():

    # cif = ntcan.CIF( net, RxQueueSize, RxTimeOut, TxQueueSize, TxTimeOut, Flags)
    # RxQS, TxQS = 1 for real time application
    net = 0  # Logical CAN Network [0, 255]
    RxQS = 1  # RxQueueSize [0, 10000]
    RxTO = 2000  # RxTimeOut in Millisconds
    TxQS = 1  # TxQueueSize [0, 10000]
    TxTO = 1000  # TxTimeOut in Millseconds

    # Initialise cif using a loop
    for j in range(board_start_num, board_start_num + num_of_board):
        for k in range(0, num_of_taxel):
            cif_array[j, k] = ntcan.CIF(net, RxQS)

            # CAN-API-Description & set baudrate 0 = 1MBaud
            cif_array[j, k].baudrate = 0

            # Create CAN-Message structure
            cmsg_array[j, k] = ntcan.CMSG()

        # Target ID of the MTB & trigger the MTB to return the data
        # canWrite...(cif, can-id, len, data ...)
        cmsg_array[j, 0].canWriteByte(cif_array[j, 0], (id_base | j), 2, 7, 0)
Ejemplo n.º 5
0
#        print("sCD[{}] = {} => old".format(i,sensorConfigData[i]['sens_type']))
#    cmd = "{}baseliner.pyc {} {} {} {} {} {} {}".format(path2p,can_bustype,can_channel,sensorConfigData[i]['ctrl_id'],i+1,"{}x{}".format(sensorConfigData[i]['num_sda'],sensorConfigData[i]['num_of_chip']),version,sensorConfigData[i]['num_sda']*sensorConfigData[i]['num_of_chip'])
#    print("Running: '{}'".format(cmd))
#    os.system(cmd)
try:
    if can_bustype != "esd":
        can_bus = can.interface.Bus(bustype=can_bustype,
                                    channel=can_channel,
                                    bitrate=1000000,
                                    ttyBaudrate=1000000)
    else:
        print("Using esd controller")
        import ntcan
        for j in range(board_start_num, num_of_board + board_start_num):
            for k in range(0, num_taxel):
                cif_array[j, k] = ntcan.CIF(0, 1)
                cif_array[j, k].baudrate = 0
                cif_array[j, k].canIdAdd(CAN_address[j - board_start_num][k])
except Exception, e:
    print("Error connecting to CAN: {}:{}".format(type(e).__name__, e))
    exit()

for j in range(board_start_num,
               num_of_board + board_start_num):  #setup the message handlers
    for k in range(0, num_taxel):
        if can_bustype == "esd":
            cmsg_array[j, k] = ntcan.CMSG()
        else:
            cmsg_array[j, k] = can.Message()

#sendToAllControllers([7,0])#Let's start all controllers
Ejemplo n.º 6
0
def main():
	print(sys.path)				#
	print(os.path)				#
	print(sys.version)				# version number of the Python interpreter 
	print(sys.copyright)			# containing the copyright pertaining to the Python interpreter
	print("Time: ", end=' ')				#
	print(time.asctime(time.localtime()))
	
	
	
	# Open CAN Interface
	# ---> cif = ntcan.CIF( net, RxQueueSize, RxTimeOut, TxQueueSize, TxTimeOut, Flags)
	net=0					# logical CAN Network [0, 255]
	RxQS=2000			        # RxQueueSize [0, 10000]
	RxTO=2000				# RxTimeOut in Millisconds
	TxQS=1					# TxQueueSize [0, 10000]
	TxTO=1000				# TxTimeOut in Millseconds
	#cifFlags=				# Flags
	cif = ntcan.CIF(net,RxQS,RxTO,TxQS,TxTO)
	print (cif)
	util.print2lines()
	
	# set baudrate 0 = 1MBaud
	# CAN-API-Description
	cif.baudrate = 0
	
	# Erzeuge CAN-Messagestruktur
	cmsg = ntcan.CMSG()
	print((cmsg.msg_lost))
	print (cmsg)
	
	
	
	
	# # examples for ntcan ----------------------------------------------------------
	# #cif2 = ntcan.CIF(net,RxQS,RxTO,TxQS,TxTO)
	# cif2 = ntcan.CIF(net)
	# print (cif2)
	# print((cif2.net))
	# print((cif2.tx_timeout))
	# print((cif2.rx_timeout))
	# print((cif2.features))
	# util.print2lines()
	
	# # set baudrate 0 = 1MBaud
	# # CAN-API-Description
	# cif2.baudrate = 0
	
	# # Erzeuge CAN-Messagestruktur
	# cmsg2 = ntcan.CMSG()
	# print("cmsg lost: %d"%(cmsg2.msg_lost))
	# print("cmsg2 %s" %(cmsg2))
	
	
	# id = 123
	# # can write
	# # canWrite...(cif,can-id,len,data ...)
	# #cmsg2.canWriteByte(cif2)
	# cmsg2.canWriteByte(cif2,id,8,1,2,3,4,5,6,7,8)			
	# cmsg2.canWriteShort(cif2,id,8,0x11,0x22,0x33,0x44)
	# cmsg2.canWriteLong(cif2,id,8,0x12345678,0xabcdef)
	# #cmsg2.canWriteLong(cif2,id,8,0x12345678,-0x1)


	
	# # can read
	# cif2.canIdAdd(0x234)						# add id
	
	# # receive can message
	# try: 
		# cmsg2.canRead(cif2)
		# print(cmsg2) 
	# except IOError as xxx_todo_changeme:
		# (errno) = xxx_todo_changeme
		# print("I/O error(%s): " % (errno))
	
	# cif2.canIdDelete(0x234)					# delete id
	
	
	# # clean up
	# del cif2
	# del cmsg2
	
	
	
	
	# # examples for canopen --------------------------------------------------------
	# # example for SYNC
	# print()
	# print("example for SYNC")
	# canopen.SYNCsend(cif)
	# time.sleep(0.5)
	# canopen.SYNCsend(cif)
	# time.sleep(0.5)
	# canopen.SYNCsend(cif)
	
	
	# # example for SYNC with class SYNC
	# print()
	# print("example for SYNC with class SYNC")
	# sync = canopen.SYNC(0,canopen.CANOPEN_1000kBd,1,2000,1.5) 		# (net,baudrate,TxQS,TxTO,[time_s])
	# print(sync)
	# print(sync.cif)
	# sync.send()		# send SYNC fame
	# sync.send()		# send SYNC fame
	# sync.send()		# send SYNC fame
	
	
	
	# # example for NMT
	# print()
	# print("example for NMT")
	# time.sleep(0.5)
	# canopen.NMTstop (cif,1)
	# time.sleep(0.5)
	# canopen.NMTpreop (cif,1)
	# time.sleep(0.5)
	# canopen.NMTreset (cif,1)
	# time.sleep(0.5)
	# canopen.NMTresetcomm (cif,1)
	# time.sleep(0.5)
	# canopen.NMTstart (cif,0)
	
	
	
	# # example for NMT with class NMT
	# print()
	# print("example for NMT with class NMT")
	# nmt = canopen.NMT(0,canopen.CANOPEN_1000kBd,1,2000) 		# (net,baudrate,TxQS,TxTO)
	# print(nmt)
	# print(nmt.cif)
	# nmt.start(3)
	# nmt.stop(3)
	# nmt.preop(3)
	# nmt.reset(3)
	# nmt.resetcomm(3)
	# nmt.start(0)
	
	
	
	# # example for NODEGUARD 
	# print()
	# print("example for NODEGUARD ")
	# canopen.NODEGUARDrequest (cif,1)
	# canopen.NODEGUARDrequest (cif,2)
	# canopen.NODEGUARDrequest (cif,3)
	# canopen.NODEGUARDrequest (cif,3)
	
	
	# result,state = canopen.NODEGUARDrequest (cif,3)
	# if result == True:
		# print("State %d" %state)
	
	# # example for NODEGUARD with class NODEGUARD
	# print("example for NODEGUARD with class NODEGUARD")
	# nodeguard = canopen.NODEGUARD(0,canopen.CANOPEN_1000kBd,100,2000,1,2000) 		# (net,baudrate,RxQS,RxTO,TxQS,TxTO)
	# print(nodeguard)
	# print(nodeguard.cif)
	# nodeguard.request(3)
	
	
	
	
	# # example for SDO
	# print()
	# print("example for SDO")
	# canopen.SDOread (cif,1,0x1000,0x00)		# read device type (node1,index:0x1000,subindex:0)
	# canopen.SDOread (cif,1,0x1001,0x00)
	# canopen.SDOread (cif,1,0x100,0x00)
	
	# result,data=canopen.SDOread (cif,1,0x1000,0)
	# if result == True:
		# print("Result %d  Data 0x%X" %(result,data))
	# result,data=canopen.SDOread (cif,2,0x1000,0)
	# if result == True:
		# print("Result %d  Data 0x%X" %(result,data))
		
	# result,data=canopen.SDOread (cif,3,0x1000,0)
	# if result == True:
		# print("Result %d  Data 0x%X" %(result,data))
	
	# #canopen.SDOwrite1Byte (cif,1,0x2400,0x01,0x12345678)
	# canopen.SDOwrite2Byte (cif,1,0x2400,0x07,0x12345678)
	# canopen.SDOwrite4Byte (cif,1,0x2008,0x01,0x12345678)
	
	# canopen.SDOwriteString (cif,1,0x2008,0x01,"a")
	# canopen.SDOwriteString (cif,1,0x2008,0x01,"ab")
	# canopen.SDOwriteString (cif,1,0x2008,0x01,"abc")
	# canopen.SDOwriteString (cif,1,0x2008,0x01,"abcd")
	# canopen.SDOwriteString (cif,1,0x2008,0x01,"abcdef")
	
	# canopen.SDOwriteString (cif,6,0x1010,0x01,"save")	# Object 1010h: store parameters
	# canopen.SDOwriteString (cif,6,0x1011,0x01,"load")  	# Object 1011h: restore default parameters
	
	
	# # example for SDO with class SDO
	# print()
	# print("example for SDO with class SDO")
	# sdo=canopen.SDO(0,canopen.CANOPEN_1000kBd,100,2000,1,2000) # (net,baudrate,RxQS,RxTO,TxQS,TxTO)
	# sdo.read (1,0x1000,0x00)
	# sdo.read (1,0x1001,0x00)
	# sdo.read (1,0x1234,0x00)
	
	# result,data=sdo.read (1,0x1000,0)
	# print("Result %d  Data 0x%X" %(result,data))
	# if result == True:
		# print("Result %d  Data 0x%X" %(result,data))
	
		
	# result,data=sdo.read (2,0x1008,0)
	# if result == True:
		# if isinstance(data,str):	# string?
			# print(data)
		# else:	
			# print("0x%X"%data)
		
	
	
	
	# #sdo.write1Byte (1,0x2400,0x01,0x12345678)
	# sdo.write2Byte (1,0x2400,0x07,0x12345678)
	# sdo.write4Byte (1,0x2008,0x01,0x12345678)
	
	# sdo.writeString (1,0x2008,0x01,"a")
	# sdo.writeString (1,0x2008,0x01,"ab")
	# sdo.writeString (1,0x2008,0x01,"abc")
	# sdo.writeString (1,0x2008,0x01,"abcd")
	# sdo.writeString (1,0x2008,0x01,"abcdef")
	# sdo.writeString (6,0x2008,0x01,"save")
	# sdo.writeString (6,0x2008,0x01,"load")
	
	
	# # read CANopen SDOs
	# node = 2
	
	
	# # 1001 VAR error register UNSIGNED8 ro M
	# result,data=sdo.read (node,0x1001,0)		
	# # 1002 VAR manufacturer status register UNSIGNED32 ro O
	# result,data=sdo.read (node,0x1002,0)		
	# # 1003 ARRAY pre-defined error field UNSIGNED32 ro O
	# result,data=sdo.read (node,0x1003,0)		
	# # 1004 reserved for compatibility reasons
	# result,data=sdo.read (node,0x1004,0)		
	# # 1005 VAR COB-ID SYNC UNSIGNED32 rw O
	# result,data=sdo.read (node,0x1005,0)		
	# # 1006 VAR communication cycle period UNSIGNED32 rw O
	# result,data=sdo.read (node,0x1006,0)		
	# # 1007 VAR synchronous window length UNSIGNED32 rw O
	# result,data=sdo.read (node,0x1007,0)		
	# # 1008 VAR manufacturer device name Vis-String const O
	# result,data=sdo.read (node,0x1008,0)		
	# # 1009 VAR manufacturer hardware version Vis-String const O
	# result,data=sdo.read (node,0x1009,0)		
	# # 100A VAR manufacturer software version Vis-String const O
	# result,data=sdo.read (node,0x100A,0)		
	# # 100B reserved for compatibility reasons
	# result,data=sdo.read (node,0x100B,0)		
	# # 100C VAR guard time UNSIGNED16 rw O
	# result,data=sdo.read (node,0x100C,0)		
	# # 100D VAR life time factor UNSIGNED8 rw O
	# result,data=sdo.read (node,0x100D,0)		
	# # 100E reserved for compatibility reasons
	# result,data=sdo.read (node,0x100E,0)		
	# # 100F reserved for compatibility reasons
	# result,data=sdo.read (node,0x100F,0)		
	# # 1010 ARRAY store parameters UNSIGNED32 rw O
	# result,data=sdo.read (node,0x1010,0)		
	# # 1011 ARRAY restore default parameters UNSIGNED32 rw O
	# result,data=sdo.read (node,0x1011,0)		
	# # 1012 VAR COB-ID TIME UNSIGNED32 rw O
	# result,data=sdo.read (node,0x1012,0)		
	# # 1013 VAR high resolution time stamp UNSIGNED32 rw O
	# result,data=sdo.read (node,0x1013,0)		
	# # 1014 VAR COB-ID EMCY UNSIGNED32 rw O
	# result,data=sdo.read (node,0x1014,0)		
	# # 1015 VAR Inhibit Time EMCY UNSIGNED16 rw O
	# result,data=sdo.read (node,0x1015,0)		
	# # 1016 ARRAY Consumer heartbeat time UNSIGNED32 rw O
	# result,data=sdo.read (node,0x1016,0)		
	# # 1017 VAR Producer heartbeat time UNSIGNED16 rw O
	# result,data=sdo.read (node,0x1017,0)		
	# # 1018 RECORD Identity Object Identity (23h) ro M
	# result,data=sdo.read (node,0x1018,0)		
	# if result == True:
		# sdo.read (node,0x1018,1)		
		# sdo.read (node,0x1018,2)		
		# sdo.read (node,0x1018,3)		
		# sdo.read (node,0x1018,4)		
	
	
	# sdo.write2Byte (2,0x1800,0x05,0)
	# del sdo
	
	
	
	# # example for PDO
	# #  
	# # canopenPDO1writeByte (cif,node,len, data)
	# # len: 0...8 always number of bytes!!!!!
	# print()
	# print("example for PDO")
	
	
	# canopen.PDO1read(cif,3)				# cif,node
	# canopen.PDO2read(cif,4)
	# canopen.PDO3read(cif,5)
	# canopen.PDO4read(cif,127)
	
	canopen.PDO1writeByte (cif,1,8,d0=0x10)
Ejemplo n.º 7
0
RxQS = 1  # RxQueueSize [0, 10000]
RxTO = 2000  # RxTimeOut in Millisconds
TxQS = 1  # TxQueueSize [0, 10000]
TxTO = 1000  # TxTimeOut in Millseconds

# examples for ntcan ----------------------------------------------------------
#cif1 = ntcan.CIF(net,RxQS,RxTO,TxQS,TxTO)
#cif1 = ntcan.CIF(net,RxQS) #RxQs = 1 --> Queue only 1 value, for real time application

#create cif using a loop
cif_array = {}  #Number of CAN ID or equal to taxel
cmsg_array = {}

for j in range(board_start_num, num_of_board + board_start_num):
    for k in range(0, num_taxel):
        cif_array[j, k] = ntcan.CIF(net, RxQS)

# validate the configuration & check the CAN-USB availability
print(cif_array[board_start_num, 0])
print(cif_array[board_start_num, 0].net)
print(cif_array[board_start_num, 0].tx_timeout)
print(cif_array[board_start_num, 0].rx_timeout)
print(cif_array[board_start_num, 0].features)
util.print2lines()

# set baudrate 0 = 1MBaud
# CAN-API-Description

for j in range(board_start_num, num_of_board + board_start_num):
    for k in range(0, num_taxel):
        cif_array[j, k].baudrate = 0
Ejemplo n.º 8
0
UDP_IP = "192.168.0.2"
UDP_PORT = 5005
UDP_IP_client = "192.168.0.4"
UDP_PORT_client = 5005
sock = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
sock.bind((UDP_IP, UDP_PORT))
hunt_flag = 0

net = 0  # logical CAN Network [0, 255]
RxQS = 2000  # RxQueueSize [0, 10000]
RxTO = 2000  # RxTimeOut in Millisconds
TxQS = 1  # TxQueueSize [0, 10000]
TxTO = 1000  # TxTimeOut in Millseconds
# cifFlags=                              # Flags
cif = ntcan.CIF(net, RxQS, RxTO, TxQS, TxTO)
print(cif)
util.print2lines()

# set baudrate 0 = 1MBaud
# CAN-API-Description
cif.baudrate = 0

# Erzeuge CAN-Messagestruktur
cmsg = ntcan.CMSG()
print(cmsg.msg_lost)
print(cmsg)
# examples for ntcan ----------------------------------------------------------
cif2 = ntcan.CIF(net)
print(cif2)
print(cif2.net)