Exemplo n.º 1
0
    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
Exemplo n.º 2
0
    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)
Exemplo n.º 3
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    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)
Exemplo n.º 4
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    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)
Exemplo n.º 5
0
    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)
Exemplo n.º 6
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def main():
    # parse the command line arguments
    parser = ArgumentParser(description=__doc__)

    # add an argument for interval
    parser.add_argument(
        'localaddr',
        type=str,
        help='local address of the BBMD',
    )

    # add an argument for interval
    parser.add_argument(
        'bdtentry',
        type=str,
        nargs='*',
        help='list of addresses of peers',
    )

    # now parse the arguments
    args = parser.parse_args()

    if _debug: _log.debug("initialization")
    if _debug: _log.debug("    - args: %r", args)

    local_address = Address(args.localaddr)
    if _debug: _log.debug("    - local_address: %r", local_address)

    # create a null client that will accept, but do nothing with upstream
    # packets from the BBMD
    null_client = NullClient()
    if _debug: _log.debug("    - null_client: %r", null_client)

    # create a BBMD, bound to the Annex J server on a UDP multiplexer
    bbmd = BIPBBMD(local_address)
    annexj = AnnexJCodec()
    multiplexer = UDPMultiplexer(local_address)

    # bind the layers together
    bind(null_client, bbmd, annexj, multiplexer.annexJ)

    # loop through the rest of the addresses
    for bdtentry in args.bdtentry:
        if _debug: _log.debug("    - bdtentry: %r", bdtentry)

        bdt_address = Address(bdtentry)
        bbmd.add_peer(bdt_address)

    if _debug: _log.debug("    - bbmd: %r", bbmd)

    _log.debug("running")

    run()

    _log.debug("fini")
Exemplo n.º 7
0
    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, 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)
Exemplo n.º 9
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    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, 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)
Exemplo n.º 11
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    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)
Exemplo n.º 12
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    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)
Exemplo n.º 13
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class DiscoverApplication(ApplicationIOController, WhoIsIAmServices,
                          ReadWritePropertyServices):
    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 close_socket(self):
        if _debug: DiscoverApplication._debug("close_socket")

        # pass to the multiplexer, then down to the sockets
        self.mux.close_socket()

    def request(self, apdu):
        if _debug: DiscoverApplication._debug("request %r", apdu)

        # save a copy of the request
        self._request = apdu

        # forward it along
        super(DiscoverApplication, self).request(apdu)

    def indication(self, apdu):
        if _debug: DiscoverApplication._debug("indication %r", apdu)

        # forward it along
        super(DiscoverApplication, self).indication(apdu)

    def response(self, apdu):
        if _debug: DiscoverApplication._debug("response %r", apdu)

        # forward it along
        super(DiscoverApplication, self).response(apdu)

    def confirmation(self, apdu):
        if _debug: DiscoverApplication._debug("confirmation %r", apdu)

        # forward it along
        super(DiscoverApplication, self).confirmation(apdu)

    def do_IAmRequest(self, apdu):
        if _debug: DiscoverApplication._debug("do_IAmRequest %r", apdu)

        if not isinstance(self._request, WhoIsRequest):
            if _debug: DiscoverApplication._debug("    - no pending who-is")
            return

        device_instance = apdu.iAmDeviceIdentifier[1]
        if (self._request.deviceInstanceRangeLowLimit is not None) and \
                (device_instance < self._request.deviceInstanceRangeLowLimit):
            return
        if (self._request.deviceInstanceRangeHighLimit is not None) and \
                (device_instance > self._request.deviceInstanceRangeHighLimit):
            return

        # print out something
        if interactive:
            print("{} @ {}".format(device_instance, apdu.pduSource))

        # update the snapshot database
        snapshot.upsert(
            apdu.iAmDeviceIdentifier[1],
            '-',
            'address',
            str(apdu.pduSource),
        )
        snapshot.upsert(
            apdu.iAmDeviceIdentifier[1],
            '-',
            'maxAPDULengthAccepted',
            str(apdu.maxAPDULengthAccepted),
        )
        snapshot.upsert(
            apdu.iAmDeviceIdentifier[1],
            '-',
            'segmentationSupported',
            apdu.segmentationSupported,
        )
Exemplo n.º 14
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class BAC0BBMDDeviceApplication(
    common_mixin,
    ApplicationIOController,
    WhoIsIAmServices,
    WhoHasIHaveServices,
    ReadWritePropertyServices,
    ReadWritePropertyMultipleServices,
    ChangeOfValueServices,
):
    """
    Defines a basic BACnet/IP application to process BACnet requests.

    :param *args: local object device, local IP address
        See BAC0.scripts.BasicScript for more details.

    """

    bdt = []

    def __init__(
        self,
        localDevice,
        localAddress,
        bdtable=[],
        deviceInfoCache=None,
        aseID=None,
        iam_req=None,
        subscription_contexts=None,
    ):

        self.bdtable = bdtable

        null_client = NullClient()

        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 = BIPBBMD(self.localAddress)
        self.annexj = AnnexJCodec()
        self.mux = UDPMultiplexer(self.localAddress, noBroadcast=True)

        # bind the bottom layers
        # bind(self.bip, self.annexj, self.mux.annexJ)
        bind(null_client, self.bip, self.annexj, self.mux.annexJ)

        if self.bdtable:
            for bdtentry in self.bdtable:
                self.add_peer(bdtentry)

        # bind the NSAP to the stack, no network number
        self.nsap.bind(self.bip)

        self.i_am_counter = defaultdict(int)
        self.i_have_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 = []
        self._last_i_have_received = []

        # to support CoV
        self.subscription_contexts = subscription_contexts

    def add_peer(self, address):
        try:
            bdt_address = Address(address)
            self.bip.add_peer(bdt_address)
        except Exception:
            raise

    def remove_peer(self, address):
        try:
            bdt_address = Address(address)
            self.bip.remove_peer(bdt_address)
        except Exception:
            raise

    def close_socket(self):
        # pass to the multiplexer, then down to the sockets
        self.mux.close_socket()
Exemplo n.º 15
0
        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])
    _log.debug("    - server_address: %r", server_address)

    # create a ProxyClientService
    proxy_client = ProxyClientService(tcpmux, server_address, testUser)

    # bind everything together
    bind(proxy_client, bip, annexj, udpmux.annexJ)

    _log.debug("running")
Exemplo n.º 16
0
    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 = {}
Exemplo n.º 17
0
class BAC0Application(
        ApplicationIOController,
        WhoIsIAmServices,
        ReadWritePropertyServices,
        ReadWritePropertyMultipleServices,
):
    """
    Defines a basic BACnet/IP application to process BACnet requests.

    :param *args: local object device, local IP address
        See BAC0.scripts.BasicScript for more details.

    """
    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 = 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)

        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 do_IAmRequest(self, apdu):
        """Given an I-Am request, cache it."""
        self._log.debug("do_IAmRequest {!r}".format(apdu))

        # build a key from the source, just use the instance number
        key = (str(apdu.pduSource), apdu.iAmDeviceIdentifier[1])
        self.i_am_counter[key] += 1
        self._last_i_am_received.append(key)

    def do_WhoIsRequest(self, apdu):
        """Respond to a Who-Is request."""

        # build a key from the source and parameters
        key = (
            str(apdu.pduSource),
            apdu.deviceInstanceRangeLowLimit,
            apdu.deviceInstanceRangeHighLimit,
        )
        self._log.debug("do_WhoIsRequest from {} | {} to {}".format(
            key[0], key[1], key[2]))

        # count the times this has been received
        self.who_is_counter[key] += 1
        low_limit = key[1]
        high_limit = key[2]

        # count the times this has been received
        self.who_is_counter[key] += 1

        if low_limit is not None:
            if self.localDevice.objectIdentifier[1] < low_limit:
                return
        if high_limit is not None:
            if self.localDevice.objectIdentifier[1] > high_limit:
                return
        # generate an I-Am
        self._log.debug("Responding to Who is by a Iam")
        self.iam_req.pduDestination = apdu.pduSource
        iocb = IOCB(self.iam_req)  # make an IOCB
        deferred(self.request_io, iocb)

    def close_socket(self):
        # pass to the multiplexer, then down to the sockets
        self.mux.close_socket()

    def request(self, apdu):
        # save a copy of the request
        self._request = apdu

        # forward it along
        super(BAC0Application, self).request(apdu)
Exemplo n.º 18
0
    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 = []