def __init__(self, localDevice, localAddress, aseID=None):
if _debug:
TestApplication._debug("__init__ %r %r aseID=%r", localDevice,
localAddress, aseID)
Application.__init__(self, localDevice, localAddress, aseID)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(localDevice)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a multiplexer and device-to-device service
self.mux = TCPServerMultiplexer(self.localAddress)
# add this to the list of adapters
self.d2d = DeviceToDeviceServerService(self.mux, self.nsap, None)
def __init__(self, local_address, local_network, vlan_address, vlan_network):
if _debug: VLANRouter._debug("__init__ %r %r %r %r", local_address, local_network, vlan_address, vlan_network)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.bip = BIPSimple()
self.annexj = AnnexJCodec()
self.mux = UDPMultiplexer(local_address)
# bind the bottom layers
bind(self.bip, self.annexj, self.mux.annexJ)
# bind the BIP stack to the local network
self.nsap.bind(self.bip, local_network, local_address)
# create a vlan node
self.vlan_node = Node(vlan_address)
# bind the stack to the vlan network
self.nsap.bind(self.vlan_node, vlan_network)
def __init__(self, localNetwork, localAddress):
if _debug: TestRouter._debug("__init__ %r", localAddress)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.bip = BIPSimple()
self.annexj = AnnexJCodec()
self.mux = UDPMultiplexer(localAddress)
# bind the bottom layers
bind(self.bip, self.annexj, self.mux.annexJ)
# bind the BIP stack to localNetwork
self.nsap.bind(self.bip, localNetwork, localAddress)
# create a multiplexer for the service
self.mux = TCPClientMultiplexer()
# create the service, use 90 as the "hidden" network
self.r2rService = RouterToRouterService(self.mux, self.nsap, 90)
def __init__(self, vlan_device: LocalDeviceObject, vlan_address: Address) -> None:
if _debug:
_VLANApplication._debug("__init__ %r %r", vlan_device, vlan_address)
Application.__init__(self, localDevice=vlan_device, aseID=None)
# include a application decoder
self._asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self._smap = StateMachineAccessPoint(vlan_device)
# the segmentation state machines need access to the same device
# information cache as the application
self._smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self._nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self._nse = NetworkServiceElement()
bind(self._nse, self._nsap)
# bind the top layers
bind(self, self._asap, self._smap, self._nsap)
# create a vlan node at the assigned address
self._vlan_node = Node(vlan_address)
# bind the stack to the node, no network number
self._nsap.bind(self._vlan_node)
def __init__(self, vlan_device, vlan_address, aseID=None):
if _debug: VLANApplication._debug("__init__ %r %r aseID=%r", vlan_device, vlan_address, aseID)
ApplicationIOController.__init__(self, vlan_device, vlan_address, aseID=aseID)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(vlan_device)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a vlan node at the assigned address
self.vlan_node = Node(vlan_address)
# bind the stack to the node, no network number
self.nsap.bind(self.vlan_node, address=vlan_address)
# keep track of requests to line up responses
self._request = None
if _debug: VLANApplication._debug(" - nsap.local_address: %r", self.nsap.local_address)
def __init__(self, local_address, local_network):
if _debug:
VLANRouter._debug("__init__ %r %r", local_address, local_network)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# create a BBMD, bound to the Annex J server
# on the UDP multiplexer
# self.bip = BIPBBMD(local_address)
# self.annexj = AnnexJCodec()
# self.mux = UDPMultiplexer(local_address)
#ADDED
#from WhoIsIAmForeign ForeignApplication
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.bip = BIPForeign(Address('BBMD_ADDR'), 30)
self.annexj = AnnexJCodec()
self.mux = UDPMultiplexer(local_address, noBroadcast=True)
#end
# self.bip.add_peer(Address(BBMD_ADDR))
#ADDED
# bind the bottom layers
bind(self.bip, self.annexj, self.mux.annexJ)
# bind the BIP stack to the local network
self.nsap.bind(self.bip, local_network, local_address)
def __init__(self, address, vlan):
if _debug:
ApplicationLayerStateMachine._debug("__init__ %r %r", address,
vlan)
ClientStateMachine.__init__(self)
# build a name, save the address
self.name = "app @ %s" % (address, )
self.address = Address(address)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
if _debug:
ApplicationLayerStateMachine._debug(" - nsap: %r", self.nsap)
# bind this as a client of the network service access point
bind(self, self.nsap)
# create a node, added to the network
self.node = Node(self.address, vlan)
if _debug:
ApplicationLayerStateMachine._debug(" - node: %r", self.node)
# bind the stack to the local network
self.nsap.bind(self.node)
def __init__(self, vlan_device, vlan_address, aseID=None):
if _debug:
VLANApplication._debug("__init__ %r %r aseID=%r", vlan_device,
vlan_address, aseID)
Application.__init__(self, vlan_device, local_address, aseID)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(vlan_device)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a vlan node at the assigned address
self.vlan_node = Node(vlan_address)
# bind the stack to the node, no network number
self.nsap.bind(self.vlan_node)
def __init__(self, address, vlan):
if _debug:
BIPSimpleApplicationLayerStateMachine._debug(
"__init__ %r %r", address, vlan)
# build a name, save the address
self.name = "app @ %s" % (address, )
self.address = Address(address)
# build a local device object
local_device = TestDeviceObject(
objectName=self.name,
objectIdentifier=('device', 998),
vendorIdentifier=999,
)
# build an address and save it
self.address = Address(address)
if _debug:
BIPSimpleApplicationLayerStateMachine._debug(
" - address: %r", self.address)
# continue with initialization
ApplicationServiceElement.__init__(self)
ClientStateMachine.__init__(self, name=local_device.objectName)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(local_device)
# the segmentation state machines need access to some device
# information cache, usually shared with the application
self.smap.deviceInfoCache = DeviceInfoCache()
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = _NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# BACnet/IP interpreter
self.bip = BIPSimple()
self.annexj = AnnexJCodec()
# fake multiplexer has a VLAN node in it
self.mux = FauxMultiplexer(self.address, vlan)
# bind the stack together
bind(self.bip, self.annexj, self.mux)
# bind the stack to the local network
self.nsap.bind(self.bip)
def __init__(self, address, vlan):
if _debug: BIPBBMDApplication._debug("__init__ %r %r", address, vlan)
# build a name, save the address
self.name = "app @ %s" % (address,)
self.address = Address(address)
if _debug: BIPBBMDApplication._debug(" - address: %r", self.address)
# build a local device object
local_device = TestDeviceObject(
objectName=self.name,
objectIdentifier=('device', 999),
vendorIdentifier=999,
)
# continue with initialization
Application.__init__(self, local_device, self.address)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(local_device)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# BACnet/IP interpreter
self.bip = BIPBBMD(self.address)
self.annexj = AnnexJCodec()
# build an address, full mask
bdt_address = "%s/32:%d" % self.address.addrTuple
if _debug: BIPBBMDNode._debug(" - bdt_address: %r", bdt_address)
# add itself as the first entry in the BDT
self.bip.add_peer(Address(bdt_address))
# fake multiplexer has a VLAN node in it
self.mux = FauxMultiplexer(self.address, vlan)
# bind the stack together
bind(self.bip, self.annexj, self.mux)
# bind the stack to the local network
self.nsap.bind(self.bip)
def __init__(self):
if _debug: RouterNode._debug("__init__")
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
def __init__(self,
localDevice,
localAddress,
deviceInfoCache=None,
aseID=None):
if _debug:
DiscoverApplication._debug(
"__init__ %r %r deviceInfoCache=%r aseID=%r", localDevice,
localAddress, deviceInfoCache, aseID)
ApplicationIOController.__init__(self,
localDevice,
localAddress,
deviceInfoCache,
aseID=aseID)
# local address might be useful for subclasses
if isinstance(localAddress, Address):
self.localAddress = localAddress
else:
self.localAddress = Address(localAddress)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(localDevice)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = DiscoverNetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.bip = BIPSimple()
self.annexj = AnnexJCodec()
self.mux = UDPMultiplexer(self.localAddress)
# bind the bottom layers
bind(self.bip, self.annexj, self.mux.annexJ)
# bind the BIP stack to the network, no network number
self.nsap.bind(self.bip, address=self.localAddress)
# keep track of requests to line up responses
self._request = None
def __init__(self, address, vlan):
if _debug:
ApplicationLayerStateMachine._debug("__init__ %r %r", address,
vlan)
# build a name, save the address
self.name = "app @ %s" % (address, )
self.address = Address(address)
# build a local device object
local_device = TestDeviceObject(
objectName=self.name,
objectIdentifier=('device', int(address)),
vendorIdentifier=999,
)
# build an address and save it
self.address = Address(address)
if _debug:
ApplicationLayerStateMachine._debug(" - address: %r",
self.address)
# continue with initialization
ApplicationServiceElement.__init__(self)
ClientStateMachine.__init__(self, name=local_device.objectName)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(local_device)
# the segmentation state machines need access to some device
# information cache, usually shared with the application
self.smap.deviceInfoCache = DeviceInfoCache()
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a node, added to the network
self.node = Node(self.address, vlan)
if _debug:
ApplicationLayerStateMachine._debug(" - node: %r", self.node)
# bind the stack to the local network
self.nsap.bind(self.node)
def __init__(self, objectName, deviceInstance, address, aseID=None):
if _debug:
VLANApplication._debug("__init__ %r %r %r aseID=%r", objectName,
deviceInstance, address, aseID)
# make an address
vlan_address = Address(address)
_log.debug(" - vlan_address: %r", vlan_address)
# make a device object
vlan_device = LocalDeviceObject(
objectName=objectName,
objectIdentifier=("device", deviceInstance),
maxApduLengthAccepted=1024,
segmentationSupported="noSegmentation",
vendorIdentifier=15,
)
_log.debug(" - vlan_device: %r", vlan_device)
# continue with the initialization
Application.__init__(self, vlan_device, vlan_address, aseID)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(vlan_device)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a vlan node at the assigned address
self.vlan_node = Node(vlan_address)
if _debug:
VLANApplication._debug(" - vlan_node: %r", self.vlan_node)
# bind the stack to the node, no network number
self.nsap.bind(self.vlan_node)
if _debug:
VLANApplication._debug(" - node bound")
def __init__(self, addr1, port1, net1, addr2, port2, net2):
if _debug:
NATRouter._debug("__init__ %r %r %r %r %r %r", addr1, port1, net1,
addr2, port2, net2)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
#== First stack
# local address
local_addr = Address("{}:{}".format(addr1, port1))
# create a BBMD stack
self.s1_bip = BIPBBMD(local_addr)
self.s1_annexj = AnnexJCodec()
self.s1_mux = UDPMultiplexer(local_addr)
# bind the bottom layers
bind(self.s1_bip, self.s1_annexj, self.s1_mux.annexJ)
# bind the BIP stack to the local network
self.nsap.bind(self.s1_bip, net1, local_addr)
#== Second stack
# global address
global_addr = Address(addr2)
nat_addr = Address("{}:{}".format(addr1, port2))
# create a NAT stack
self.s2_bip = BIPNAT(global_addr)
self.s2_annexj = AnnexJCodec()
self.s2_mux = UDPMultiplexer(nat_addr)
# bind the bottom layers
bind(self.s2_bip, self.s2_annexj, self.s2_mux.annexJ)
# bind the BIP stack to the global network
self.nsap.bind(self.s2_bip, net2, global_addr)
def __init__(self, addr):
if _debug: TestBBMD._debug("TestBBMD %r", addr)
BIPBBMD.__init__(self, addr)
# save the address
self.address = addr
# make the lower layers
self.annexj = AnnexJCodec()
self.mux = UDPMultiplexer(self.address)
# bind the bottom layers
bind(self, self.annexj, self.mux.annexJ)
# give this a generic network layer service access point and element
self.nsap = NetworkServiceAccessPoint()
self.nse = NetworkServiceElement()
self.nsap.bind(self)
bind(self.nse, self.nsap)
def __init__(self, lan, addr1, net1, addr2, net2):
if _debug:
MQTT2IPRouter._debug("__init__ %r %r %r %r %r", lan, addr1, net1,
addr2, net2)
global args
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
#== First stack
# create an MQTT client
self.s1_msap = bacpypes_mqtt.MQTTClient(lan,
addr1,
args.host,
port=args.port,
keepalive=args.keepalive)
# create a service element for the client
self.s1_mse = bacpypes_mqtt.MQTTServiceElement()
bind(self.s1_mse, self.s1_msap)
# bind to the MQTT network
self.nsap.bind(self.s1_msap, net1)
#== Second stack
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.s2_bip = BIPSimple()
self.s2_annexj = AnnexJCodec()
self.s2_mux = UDPMultiplexer(addr2)
# bind the bottom layers
bind(self.s2_bip, self.s2_annexj, self.s2_mux.annexJ)
# bind the BIP stack to the local network
self.nsap.bind(self.s2_bip, net2)
def __init__(self, localDevice, vlan):
if _debug:
ApplicationStateMachine._debug("__init__ %r %r", localDevice, vlan)
# build an address and save it
self.address = Address(localDevice.objectIdentifier[1])
if _debug:
ApplicationStateMachine._debug(" - address: %r", self.address)
# continue with initialization
Application.__init__(self, localDevice, self.address)
StateMachine.__init__(self, name=localDevice.objectName)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(localDevice)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a node, added to the network
self.node = Node(self.address, vlan)
# bind the network service to the node, no network number
self.nsap.bind(self.node)
# placeholder for the result block
self.confirmed_private_result = None
def __init__(self, localDevice, localAddress, aseID=None):
if _debug:
TestProxyApplication._debug("__init__ %r %r aseID=%r", localDevice,
localAddress, aseID)
Application.__init__(self, localDevice, localAddress, aseID)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(localDevice)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.bip = BIPSimple()
self.annexj = AnnexJCodec()
self.mux = UDPMultiplexer(self.localAddress)
# bind the bottom layers
bind(self.bip, self.annexj, self.mux.annexJ)
# bind the BIP stack to network 5, the 'local' network
self.nsap.bind(self.bip, 5, self.localAddress)
# create a multiplexer for the service
self.mux = TCPServerMultiplexer(self.localAddress)
# proxy connections are bound to the nsap
self.proxyServer = TestProxyServer(self.mux, self.nsap)
def __init__(self,
vlan_device,
vlan_address,
aseID=None,
register_reader=None):
if _debug:
VLANApplication._debug("__init__ %r %r aseID=%r", vlan_device,
vlan_address, aseID)
Application.__init__(self, vlan_device, vlan_address, aseID)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(vlan_device)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a vlan node at the assigned address
self.vlan_node = Node(vlan_address)
# bind the stack to the node, no network number
self.nsap.bind(self.vlan_node)
# set register reader class that will look into block of registers for all associated slaves
self.register_reader = register_reader
def __init__(self, lan, addr1, net1):
if _debug:
VLANRouter._debug("__init__ %r %r %r", lan, addr1, net1)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# create an MQTT client
self.msap = bacpypes_mqtt.MQTTClient(
lan, addr1, args.host, port=args.port, keepalive=args.keepalive
)
# create a service element for the client
self.mse = bacpypes_mqtt.MQTTServiceElement()
bind(self.mse, self.msap)
# bind to the MQTT network
self.nsap.bind(self.msap, net1)
def __init__(self, addr1, net1, addr2, net2):
if _debug:
IP2IPRouter._debug("__init__ %r %r %r %r", addr1, net1, addr2,
net2)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
#== First stack
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.s1_bip = BIPSimple()
self.s1_annexj = AnnexJCodec()
self.s1_mux = UDPMultiplexer(addr1)
# bind the bottom layers
bind(self.s1_bip, self.s1_annexj, self.s1_mux.annexJ)
# bind the BIP stack to the local network
self.nsap.bind(self.s1_bip, net1, addr1)
#== Second stack
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.s2_bip = BIPSimple()
self.s2_annexj = AnnexJCodec()
self.s2_mux = UDPMultiplexer(addr2)
# bind the bottom layers
bind(self.s2_bip, self.s2_annexj, self.s2_mux.annexJ)
# bind the BIP stack to the local network
self.nsap.bind(self.s2_bip, net2, addr2)
def __init__(self, vlan_device, vlan_address, aseID=None):
if _debug:
VLANConsoleApplication._debug("__init__ %r %r aseID=%r",
vlan_device, vlan_address, aseID)
global args
# normal initialization
ApplicationIOController.__init__(self, vlan_device, aseID=aseID)
# optional read property multiple
if args.rpm:
self.add_capability(ReadWritePropertyMultipleServices)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(vlan_device)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a vlan node at the assigned address
self.vlan_node = Node(vlan_address)
# bind the stack to the node, no network number, no addresss
self.nsap.bind(self.vlan_node)
def __init__(self, local_address, local_network, foreign_address, bbmd_ttl=30, rebootQueue=None):
if _debug: VLANRouter._debug("__init__ %r %r", local_address, local_network)
if isinstance(local_address, Address):
self.local_address = local_address
else:
self.local_address = Address(local_address)
if isinstance(foreign_address, Address):
self.foreign_address = foreign_address
else:
self.foreign_address = Address(foreign_address)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# create a BBMD, bound to the Annex J server
# on the UDP multiplexer
# from WhoIsIAmForeign ForeignApplication
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.bip = BIPForeign(self.foreign_address, bbmd_ttl)
# self.bip = BIPForeign(Address('10.166.1.72'), 30)
# self.bip = BIPForeign(Address('192.168.1.10'), 30)
# self.bip = BIPForeign(Address('130.91.139.99'), 30)
self.annexj = AnnexJCodec()
# noBroadcast=True stops bcast to local ntwrk
self.mux = UDPMultiplexer(self.local_address, noBroadcast=True, rebootQueue=rebootQueue)
# bind the bottom layers
bind(self.bip, self.annexj, self.mux.annexJ)
# bind the BIP stack to the local network
self.nsap.bind(self.bip, local_network, self.local_address)
def __init__(self, local_address: Address, local_network: int):
if _debug:
# pylint: disable=no-member
# type: ignore
_VLANRouter._debug("__init__ %r %r", local_address, local_network)
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# create a BIPSimple, bound to the Annex J server
# on the UDP multiplexer
self.bip = BIPSimple(local_address)
self.annexj = AnnexJCodec()
self.mux = UDPMultiplexer(local_address)
# bind the bottom layers
bind(self.bip, self.annexj, self.mux.annexJ)
# bind the BIP stack to the local network
self.nsap.bind(self.bip, local_network, local_address)
# read in the configuration file
if not os.path.isfile(configFileName):
raise RuntimeError, "No config file: '%s'" % (configFileName, )
config = ConfigParser()
config.read(configFileName)
# maybe use a different port
addr = config.get('BACpypes', 'address')
if '--port' in sys.argv:
indx = sys.argv.index('--port')
addr += ':' + sys.argv[indx + 1]
del sys.argv[indx:indx + 2]
_log.debug(" - addr: %r", addr)
# a network service access point will be needed
nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
nse = NetworkServiceElement()
bind(nse, nsap)
# create a generic BIP stack, bound to the Annex J server on the UDP multiplexer
bip = BIPSimple()
annexj = AnnexJCodec()
udpmux = UDPMultiplexer(Address(addr))
# we need a way to make outgoing TCP connections and manage the proxy client service state
tcpmux = TCPClientMultiplexer()
# get the address of the server
server_address = Address(sys.argv[1])
def __init__(self,
localDevice,
localAddress,
deviceInfoCache=None,
aseID=None):
if _debug:
ReadPointListApplication._debug(
"__init__ %r %r deviceInfoCache=%r aseID=%r", localDevice,
localAddress, deviceInfoCache, aseID)
global args
Application.__init__(self, localDevice, deviceInfoCache, aseID=aseID)
RecurringTask.__init__(self, args.interval * 1000)
# local address might be useful for subclasses
if isinstance(localAddress, Address):
self.localAddress = localAddress
else:
self.localAddress = Address(localAddress)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(localDevice)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.bip = BIPSimple()
self.annexj = AnnexJCodec()
self.mux = UDPMultiplexer(self.localAddress)
# bind the bottom layers
bind(self.bip, self.annexj, self.mux.annexJ)
# bind the BIP stack to the network, no network number
self.nsap.bind(self.bip)
# install the task
self.install_task()
# timer
self.start_time = None
# pending requests
self.pending_requests = {}
def __init__(
self,
localDevice,
localAddress,
bbmdAddress=None,
bbmdTTL=0,
deviceInfoCache=None,
aseID=None,
iam_req=None,
):
ApplicationIOController.__init__(self,
localDevice,
deviceInfoCache,
aseID=aseID)
self.iam_req = iam_req
# local address might be useful for subclasses
if isinstance(localAddress, Address):
self.localAddress = localAddress
else:
self.localAddress = Address(localAddress)
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(localDevice)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElementWithRequests()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create a generic BIP stack, bound to the Annex J server
# on the UDP multiplexer
self.bip = BIPForeign(bbmdAddress, bbmdTTL)
self.annexj = AnnexJCodec()
self.mux = UDPMultiplexer(self.localAddress, noBroadcast=True)
# bind the bottom layers
bind(self.bip, self.annexj, self.mux.annexJ)
# bind the NSAP to the stack, no network number
self.nsap.bind(self.bip)
self.i_am_counter = defaultdict(int)
self.who_is_counter = defaultdict(int)
# keep track of requests to line up responses
self._request = None
self._last_i_am_received = []
def __init__(self,
localDevice,
lan,
localAddress,
deviceInfoCache=None,
aseID=None):
if _debug:
MQTTApplication._debug(
"__init__ %r %r %r deviceInfoCache=%r aseID=%r", localDevice,
lan, localAddress, deviceInfoCache, aseID)
ApplicationIOController.__init__(self,
localDevice,
localAddress,
deviceInfoCache,
aseID=aseID)
global args
# local address might be useful for subclasses
if isinstance(localAddress, str):
localAddress = Address(localAddress)
if len(localAddress.addrAddr) != bacpypes_mqtt.ADDRESS_LENGTH:
raise ValueError("local address must be %d octets" %
(bacpypes_mqtt.ADDRESS_LENGTH, ))
self.localAddress = localAddress
# include a application decoder
self.asap = ApplicationServiceAccessPoint()
# pass the device object to the state machine access point so it
# can know if it should support segmentation
self.smap = StateMachineAccessPoint(localDevice)
# the segmentation state machines need access to the same device
# information cache as the application
self.smap.deviceInfoCache = self.deviceInfoCache
# a network service access point will be needed
self.nsap = NetworkServiceAccessPoint()
# give the NSAP a generic network layer service element
self.nse = NetworkServiceElement()
bind(self.nse, self.nsap)
# bind the top layers
bind(self, self.asap, self.smap, self.nsap)
# create an MQTT client
self.msap = bacpypes_mqtt.MQTTClient(lan,
localAddress,
args.host,
port=args.port,
keepalive=args.keepalive)
# create a service element for the client
self.mse = bacpypes_mqtt.MQTTServiceElement()
bind(self.mse, self.msap)
# bind the stack to the virtual network, no network number
self.nsap.bind(self.msap)
# keep track of requests to line up responses
self._request = None
