def run_payload_server():
# ----------------------------------------------------------------------- #
# build your payload
# ----------------------------------------------------------------------- #
builder = BinaryPayloadBuilder(byteorder=Endian.Little,
wordorder=Endian.Little)
builder.add_string('abcdefgh')
builder.add_bits([0, 1, 0, 1, 1, 0, 1, 0])
builder.add_8bit_int(-0x12)
builder.add_8bit_uint(0x12)
builder.add_16bit_int(-0x5678)
builder.add_16bit_uint(0x1234)
builder.add_32bit_int(-0x1234)
builder.add_32bit_uint(0x12345678)
builder.add_16bit_float(12.34)
builder.add_16bit_float(-12.34)
builder.add_32bit_float(22.34)
builder.add_32bit_float(-22.34)
builder.add_64bit_int(-0xDEADBEEF)
builder.add_64bit_uint(0x12345678DEADBEEF)
builder.add_64bit_uint(0xDEADBEEFDEADBEED)
builder.add_64bit_float(123.45)
builder.add_64bit_float(-123.45)
# ----------------------------------------------------------------------- #
# use that payload in the data store
# ----------------------------------------------------------------------- #
# Here we use the same reference block for each underlying store.
# ----------------------------------------------------------------------- #
block = ModbusSequentialDataBlock(1, builder.to_registers())
store = ModbusSlaveContext(di=block, co=block, hr=block, ir=block)
context = ModbusServerContext(slaves=store, single=True)
# ----------------------------------------------------------------------- #
# initialize the server information
# ----------------------------------------------------------------------- #
# If you don't set this or any fields, they are defaulted to empty strings.
# ----------------------------------------------------------------------- #
identity = ModbusDeviceIdentification()
identity.VendorName = 'Pymodbus'
identity.ProductCode = 'PM'
identity.VendorUrl = 'http://github.com/riptideio/pymodbus/'
identity.ProductName = 'Pymodbus Server'
identity.ModelName = 'Pymodbus Server'
identity.MajorMinorRevision = version.short()
# ----------------------------------------------------------------------- #
# run the server you want
# ----------------------------------------------------------------------- #
StartTcpServer(context, identity=identity, address=("localhost", 5020))
def run_binary_payload_ex():
# ----------------------------------------------------------------------- #
# We are going to use a simple client to send our requests
# ----------------------------------------------------------------------- #
client = ModbusClient('127.0.0.1', port=5020)
client.connect()
# ----------------------------------------------------------------------- #
# If you need to build a complex message to send, you can use the payload
# builder to simplify the packing logic.
#
# Here we demonstrate packing a random payload layout, unpacked it looks
# like the following:
#
# - a 8 byte string 'abcdefgh'
# - a 32 bit float 22.34
# - a 16 bit unsigned int 0x1234
# - another 16 bit unsigned int 0x5678
# - an 8 bit int 0x12
# - an 8 bit bitstring [0,1,0,1,1,0,1,0]
# - an 32 bit uint 0x12345678
# - an 32 bit signed int -0x1234
# - an 64 bit signed int 0x12345678
# The packing can also be applied to the word (wordorder) and bytes in each
# word (byteorder)
# The wordorder is applicable only for 32 and 64 bit values
# Lets say we need to write a value 0x12345678 to a 32 bit register
# The following combinations could be used to write the register
# +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ #
# Word Order - Big Byte Order - Big
# word1 =0x1234 word2 = 0x5678
# Word Order - Big Byte Order - Little
# word1 =0x3412 word2 = 0x7856
# Word Order - Little Byte Order - Big
# word1 = 0x5678 word2 = 0x1234
# Word Order - Little Byte Order - Little
# word1 =0x7856 word2 = 0x3412
# +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ #
# ----------------------------------------------------------------------- #
combos = [(wo, bo) for wo in [Endian.Big, Endian.Little] for bo in [Endian.Big, Endian.Little]]
for wo, bo in combos:
print("-" * 60)
print("Word Order: {}".format(ORDER_DICT[wo]))
print("Byte Order: {}".format(ORDER_DICT[bo]))
print()
builder = BinaryPayloadBuilder(byteorder=bo,
wordorder=wo)
strng = "abcdefgh"
builder.add_string(strng)
builder.add_bits([0, 1, 0, 1, 1, 0, 1, 0])
builder.add_8bit_int(-0x12)
builder.add_8bit_uint(0x12)
builder.add_16bit_int(-0x5678)
builder.add_16bit_uint(0x1234)
builder.add_32bit_int(-0x1234)
builder.add_32bit_uint(0x12345678)
builder.add_16bit_float(12.34)
builder.add_16bit_float(-12.34)
builder.add_32bit_float(22.34)
builder.add_32bit_float(-22.34)
builder.add_64bit_int(-0xDEADBEEF)
builder.add_64bit_uint(0x12345678DEADBEEF)
builder.add_64bit_uint(0x12345678DEADBEEF)
builder.add_64bit_float(123.45)
builder.add_64bit_float(-123.45)
payload = builder.to_registers()
print("-" * 60)
print("Writing Registers")
print("-" * 60)
print(payload)
print("\n")
payload = builder.build()
address = 0
# Can write registers
# registers = builder.to_registers()
# client.write_registers(address, registers, unit=1)
# Or can write encoded binary string
client.write_registers(address, payload, skip_encode=True, unit=1)
# ----------------------------------------------------------------------- #
# If you need to decode a collection of registers in a weird layout, the
# payload decoder can help you as well.
#
# Here we demonstrate decoding a random register layout, unpacked it looks
# like the following:
#
# - a 8 byte string 'abcdefgh'
# - a 32 bit float 22.34
# - a 16 bit unsigned int 0x1234
# - another 16 bit unsigned int which we will ignore
# - an 8 bit int 0x12
# - an 8 bit bitstring [0,1,0,1,1,0,1,0]
# ----------------------------------------------------------------------- #
address = 0x0
count = len(payload)
result = client.read_holding_registers(address, count, unit=1)
print("-" * 60)
print("Registers")
print("-" * 60)
print(result.registers)
print("\n")
decoder = BinaryPayloadDecoder.fromRegisters(result.registers,
byteorder=bo,
wordorder=wo)
assert decoder._byteorder == builder._byteorder, \
"Make sure byteorder is consistent between BinaryPayloadBuilder and BinaryPayloadDecoder"
assert decoder._wordorder == builder._wordorder, \
"Make sure wordorder is consistent between BinaryPayloadBuilder and BinaryPayloadDecoder"
decoded = OrderedDict([
('string', decoder.decode_string(len(strng))),
('bits', decoder.decode_bits()),
('8int', decoder.decode_8bit_int()),
('8uint', decoder.decode_8bit_uint()),
('16int', decoder.decode_16bit_int()),
('16uint', decoder.decode_16bit_uint()),
('32int', decoder.decode_32bit_int()),
('32uint', decoder.decode_32bit_uint()),
('16float', decoder.decode_16bit_float()),
('16float2', decoder.decode_16bit_float()),
('32float', decoder.decode_32bit_float()),
('32float2', decoder.decode_32bit_float()),
('64int', decoder.decode_64bit_int()),
('64uint', decoder.decode_64bit_uint()),
('ignore', decoder.skip_bytes(8)),
('64float', decoder.decode_64bit_float()),
('64float2', decoder.decode_64bit_float()),
])
print("-" * 60)
print("Decoded Data")
print("-" * 60)
for name, value in iteritems(decoded):
print("%s\t" % name, hex(value) if isinstance(value, int) else value)
# ----------------------------------------------------------------------- #
# close the client
# ----------------------------------------------------------------------- #
client.close()
