class FbfProductController(object):
    """
    Wrapper class for an FBFUSE product.
    """
    STATES = ["idle", "preparing", "ready", "starting", "capturing", "stopping", "error"]
    IDLE, PREPARING, READY, STARTING, CAPTURING, STOPPING, ERROR = STATES

    def __init__(self, parent, product_id, katpoint_antennas,
                 n_channels, feng_streams, proxy_name, feng_config):
        """
        @brief      Construct new instance

        @param      parent            The parent FbfMasterController instance

        @param      product_id        The name of the product

        @param      katpoint_antennas A list of katpoint.Antenna objects

        @param      n_channels        The integer number of frequency channels provided by the CBF.

        @param      feng_streams      A string describing the multicast groups containing F-enging data
                                      (in the form: spead://239.11.1.150+15:7147)

        @param      proxy_name        The name of the proxy associated with this subarray (used as a sensor prefix)

        #NEED FENG CONFIG

        @param      servers           A list of FbfWorkerServer instances allocated to this product controller
        """
        self.log = logging.getLogger("mpikat.fbfuse_product_controller.{}".format(product_id))
        self.log.debug("Creating new FbfProductController with args: {}".format(
            ", ".join([str(i) for i in (parent, product_id, katpoint_antennas, n_channels,
                feng_streams, proxy_name, feng_config)])))
        self._parent = parent
        self._product_id = product_id
        self._antennas = ",".join([a.name for a in katpoint_antennas])
        self._katpoint_antennas = katpoint_antennas
        self._antenna_map = {a.name: a for a in self._katpoint_antennas}
        self._n_channels = n_channels
        self._streams = ip_range_from_stream(feng_streams)
        self._proxy_name = proxy_name
        self._feng_config = feng_config
        self._servers = []
        self._beam_manager = None
        self._delay_config_server = None
        self._ca_client = None
        self._previous_sb_config = None
        self._managed_sensors = []
        self._ibc_mcast_group = None
        self._cbc_mcast_groups = None
        self._default_sb_config = {
            u'coherent-beams-nbeams':400,
            u'coherent-beams-tscrunch':16,
            u'coherent-beams-fscrunch':1,
            u'coherent-beams-antennas':self._antennas,
            u'coherent-beams-granularity':6,
            u'incoherent-beam-tscrunch':16,
            u'incoherent-beam-fscrunch':1,
            u'incoherent-beam-antennas':self._antennas,
            u'bandwidth':self._feng_config['bandwidth'],
            u'centre-frequency':self._feng_config['centre-frequency']}
        self.setup_sensors()

    def __del__(self):
        self.teardown_sensors()

    def info(self):
        """
        @brief    Return a metadata dictionary describing this product controller
        """
        out = {
            "antennas":self._antennas,
            "nservers":len(self.servers),
            "capturing":self.capturing,
            "streams":self._streams,
            "nchannels":self._n_channels,
            "proxy_name":self._proxy_name
        }
        return out

    def add_sensor(self, sensor):
        """
        @brief    Add a sensor to the parent object

        @note     This method is used to wrap calls to the add_sensor method
                  on the parent FbfMasterController instance. In order to
                  disambiguate between sensors from describing different products
                  the associated proxy name is used as sensor prefix. For example
                  the "servers" sensor will be seen by clients connected to the
                  FbfMasterController server as "<proxy_name>-servers" (e.g.
                  "FBFUSE_1-servers").
        """
        prefix = "{}.".format(self._product_id)
        if sensor.name.startswith(prefix):
            self._parent.add_sensor(sensor)
        else:
            sensor.name = "{}{}".format(prefix,sensor.name)
            self._parent.add_sensor(sensor)
        self._managed_sensors.append(sensor)

    def setup_sensors(self):
        """
        @brief    Setup the default KATCP sensors.

        @note     As this call is made only upon an FBFUSE configure call a mass inform
                  is required to let connected clients know that the proxy interface has
                  changed.
        """
        self._state_sensor = LoggingSensor.discrete(
            "state",
            description = "Denotes the state of this FBF instance",
            params = self.STATES,
            default = self.IDLE,
            initial_status = Sensor.NOMINAL)
        self._state_sensor.set_logger(self.log)
        self.add_sensor(self._state_sensor)

        self._ca_address_sensor = Sensor.string(
            "configuration-authority",
            description = "The address of the server that will be deferred to for configurations",
            default = "",
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._ca_address_sensor)

        self._available_antennas_sensor = Sensor.string(
            "available-antennas",
            description = "The antennas that are currently available for beamforming",
            default = json.dumps({antenna.name:antenna.format_katcp() for antenna in self._katpoint_antennas}),
            initial_status = Sensor.NOMINAL)
        self.add_sensor(self._available_antennas_sensor)

        self._phase_reference_sensor = Sensor.string(
            "phase-reference",
            description="A KATPOINT target string denoting the F-engine phasing centre",
            default="unset,radec,0,0",
            initial_status=Sensor.UNKNOWN)
        self.add_sensor(self._phase_reference_sensor)

        reference_antenna = Antenna("reference,{ref.lat},{ref.lon},{ref.elev}".format(
            ref=self._katpoint_antennas[0].ref_observer))
        self._reference_antenna_sensor = Sensor.string(
            "reference-antenna",
            description="A KATPOINT antenna string denoting the reference antenna",
            default=reference_antenna.format_katcp(),
            initial_status=Sensor.NOMINAL)
        self.add_sensor(self._reference_antenna_sensor)

        self._bandwidth_sensor = Sensor.float(
            "bandwidth",
            description = "The bandwidth this product is configured to process",
            default = self._default_sb_config['bandwidth'],
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._bandwidth_sensor)

        self._nchans_sensor = Sensor.integer(
            "nchannels",
            description = "The number of channels to be processesed",
            default = self._n_channels,
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._nchans_sensor)

        self._cfreq_sensor = Sensor.float(
            "centre-frequency",
            description = "The centre frequency of the band this product configured to process",
            default = self._default_sb_config['centre-frequency'],
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cfreq_sensor)

        self._cbc_nbeams_sensor = Sensor.integer(
            "coherent-beam-count",
            description = "The number of coherent beams that this FBF instance can currently produce",
            default = self._default_sb_config['coherent-beams-nbeams'],
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cbc_nbeams_sensor)

        self._cbc_nbeams_per_group = Sensor.integer(
            "coherent-beam-count-per-group",
            description = "The number of coherent beams packed into a multicast group",
            default = 1,
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cbc_nbeams_per_group)

        self._cbc_ngroups = Sensor.integer(
            "coherent-beam-ngroups",
            description = "The number of multicast groups used for coherent beam transmission",
            default = 1,
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cbc_ngroups)

        self._cbc_nbeams_per_server_set = Sensor.integer(
            "coherent-beam-nbeams-per-server-set",
            description = "The number of beams produced by each server set",
            default = 1,
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cbc_nbeams_per_server_set)

        self._cbc_tscrunch_sensor = Sensor.integer(
            "coherent-beam-tscrunch",
            description = "The number time samples that will be integrated when producing coherent beams",
            default = self._default_sb_config['coherent-beams-tscrunch'],
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cbc_tscrunch_sensor)

        self._cbc_fscrunch_sensor = Sensor.integer(
            "coherent-beam-fscrunch",
            description = "The number frequency channels that will be integrated when producing coherent beams",
            default = self._default_sb_config['coherent-beams-fscrunch'],
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cbc_fscrunch_sensor)

        self._cbc_antennas_sensor = Sensor.string(
            "coherent-beam-antennas",
            description = "The antennas that will be used when producing coherent beams",
            default = self._default_sb_config['coherent-beams-antennas'],
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cbc_antennas_sensor)

        self._cbc_mcast_groups_sensor = Sensor.string(
            "coherent-beam-multicast-groups",
            description = "Multicast groups used by this instance for sending coherent beam data",
            default = "",
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cbc_mcast_groups_sensor)

        self._cbc_mcast_groups_mapping_sensor = Sensor.string(
            "coherent-beam-multicast-group-mapping",
            description = "Mapping of mutlicast group address to the coherent beams in that group",
            default= "",
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._cbc_mcast_groups_mapping_sensor)

        self._ibc_nbeams_sensor = Sensor.integer(
            "incoherent-beam-count",
            description = "The number of incoherent beams that this FBF instance can currently produce",
            default = 1,
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._ibc_nbeams_sensor)

        self._ibc_tscrunch_sensor = Sensor.integer(
            "incoherent-beam-tscrunch",
            description = "The number time samples that will be integrated when producing incoherent beams",
            default = self._default_sb_config['incoherent-beam-tscrunch'],
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._ibc_tscrunch_sensor)

        self._ibc_fscrunch_sensor = Sensor.integer(
            "incoherent-beam-fscrunch",
            description = "The number frequency channels that will be integrated when producing incoherent beams",
            default = self._default_sb_config['incoherent-beam-fscrunch'],
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._ibc_fscrunch_sensor)

        self._ibc_antennas_sensor = Sensor.string(
            "incoherent-beam-antennas",
            description = "The antennas that will be used when producing incoherent beams",
            default = self._default_sb_config['incoherent-beam-antennas'],
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._ibc_antennas_sensor)

        self._ibc_mcast_group_sensor = Sensor.string(
            "incoherent-beam-multicast-group",
            description = "Multicast group used by this instance for sending incoherent beam data",
            default = "",
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._ibc_mcast_group_sensor)

        self._servers_sensor = Sensor.string(
            "servers",
            description = "The worker server instances currently allocated to this product",
            default = ",".join(["{s.hostname}:{s.port}".format(s=server) for server in self._servers]),
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._servers_sensor)

        self._nserver_sets_sensor = Sensor.integer(
            "nserver-sets",
            description = "The number of server sets (independent subscriptions to the F-engines)",
            default = 1,
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._nserver_sets_sensor)

        self._nservers_per_set_sensor = Sensor.integer(
            "nservers-per-set",
            description = "The number of servers per server set",
            default = 1,
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._nservers_per_set_sensor)

        self._delay_config_server_sensor = Sensor.string(
            "delay-config-server",
            description = "The address of the delay configuration server for this product",
            default = "",
            initial_status = Sensor.UNKNOWN)
        self.add_sensor(self._delay_config_server_sensor)

    def teardown_sensors(self):
        """
        @brief    Remove all sensors created by this product from the parent server.

        @note     This method is required for cleanup to stop the FBF sensor pool
                  becoming swamped with unused sensors.
        """
        for sensor in self._managed_sensors:
            self._parent.remove_sensor(sensor)
        self._managed_sensors = []
        self._parent.mass_inform(Message.inform('interface-changed'))

    @property
    def servers(self):
        return self._servers

    @property
    def capturing(self):
        return self.state == self.CAPTURING

    @property
    def idle(self):
        return self.state == self.IDLE

    @property
    def starting(self):
        return self.state == self.STARTING

    @property
    def stopping(self):
        return self.state == self.STOPPING

    @property
    def ready(self):
        return self.state == self.READY

    @property
    def preparing(self):
        return self.state == self.PREPARING

    @property
    def error(self):
        return self.state == self.ERROR

    @property
    def state(self):
        return self._state_sensor.value()

    def _verify_antennas(self, antennas):
        """
        @brief      Verify that a set of antennas is available to this instance.

        @param      antennas   A CSV list of antenna names
        """
        self.log.debug("Verifying antenna set: {}".format(antennas))
        antennas_set = set([ant.name for ant in self._katpoint_antennas])
        requested_antennas = set(antennas)
        return requested_antennas.issubset(antennas_set)

    def set_configuration_authority(self, hostname, port):
        if self._ca_client:
            self._ca_client.stop()
        self._ca_client = KATCPClientResource(dict(
            name = 'configuration-authority-client',
            address = (hostname, port),
            controlled = True))
        self._ca_client.start()
        self._ca_address_sensor.set_value("{}:{}".format(hostname, port))

    @coroutine
    def get_ca_sb_configuration(self, sb_id):
        self.log.debug("Retrieving schedule block configuration from configuration authority")
        yield self._ca_client.until_synced()
        try:
            response = yield self._ca_client.req.get_schedule_block_configuration(self._proxy_name, sb_id)
        except Exception as error:
            self.log.error("Request for SB configuration to CA failed with error: {}".format(str(error)))
            raise error
        try:
            config_dict = json.loads(response.reply.arguments[1])
        except Exception as error:
            self.log.error("Could not parse CA SB configuration with error: {}".format(str(error)))
            raise error
        self.log.debug("Configuration authority returned: {}".format(config_dict))
        raise Return(config_dict)

    def reset_sb_configuration(self):
        self.log.debug("Reseting schedule block configuration")
        try:
            self.capture_stop()
        except Exception as error:
            self.log.warning("Received error while attempting capture stop: {}".format(str(error)))
        self._parent._server_pool.deallocate(self._servers)

        if self._ibc_mcast_group:
            self._parent._ip_pool.free(self._ibc_mcast_group)
        if self._cbc_mcast_groups:
            self._parent._ip_pool.free(self._cbc_mcast_groups)
        self._cbc_mcast_groups = None
        self._ibc_mcast_group = None
        self._servers = []
        if self._delay_config_server:
            self._delay_config_server.stop()
            self._delay_config_server = None
        self._beam_manager = None

    def set_error_state(self, message):
        self.reset_sb_configuration()
        self._state_sensor.set_value(self.ERROR)

    def set_sb_configuration(self, config_dict):
        """
        @brief  Set the schedule block configuration for this product

        @param  config_dict  A dictionary specifying configuation parameters, e.g.
                             @code
                                   {
                                   u'coherent-beams-nbeams':100,
                                   u'coherent-beams-tscrunch':22,
                                   u'coherent-beams-fscrunch':2,
                                   u'coherent-beams-antennas':'m007',
                                   u'coherent-beams-granularity':6,
                                   u'incoherent-beam-tscrunch':16,
                                   u'incoherent-beam-fscrunch':1,
                                   u'incoherent-beam-antennas':'m008'
                                   }
                             @endcode

        @detail Valid parameters for the configuration dictionary are as follows:

                 coherent-beams-nbeams      - The desired number of coherent beams to produce
                 coherent-beams-tscrunch    - The number of spectra to integrate in the coherent beamformer
                 coherent-beams-tscrunch    - The number of spectra to integrate in the coherent beamformer
                 coherent-beams-fscrunch    - The number of channels to integrate in the coherent beamformer
                 coherent-beams-antennas    - The specific antennas to use for the coherent beamformer
                 coherent-beams-granularity - The number of beams per output mutlicast group
                                              (an integer divisor or multiplier of this number will be used)
                 incoherent-beam-tscrunch   - The number of spectra to integrate in the incoherent beamformer
                 incoherent-beam-fscrunch   - The number of channels to integrate in the incoherent beamformer
                 incoherent-beam-antennas   - The specific antennas to use for the incoherent beamformer
                 centre-frequency           - The desired centre frequency in Hz
                 bandwidth                  - The desired bandwidth in Hz

        @note   FBFUSE reasonably assumes that the user does not know the possible configurations at
                any given time. As such it tries to satisfy the users request but will not throw an
                error if the requested configuration is not acheivable, instead opting to provide a
                reduced configuration. For example the user may request 1000 beams and 6 beams per
                multicast group but FBFUSE may configure to produce 860 beams and 24 beams per multicast
                group. If the user can only use 6 beams per multcast group, then in the 24-beam case
                they must subscribe to the same multicast group 4 times on different nodes.

        """
        if self._previous_sb_config == config_dict:
            self.log.info("Configuration is unchanged, proceeding with existing configuration")
            return
        else:
            self._previous_sb_config = config_dict
        self.reset_sb_configuration()
        self.log.info("Setting schedule block configuration")
        config = deepcopy(self._default_sb_config)
        config.update(config_dict)
        self.log.info("Configuring using: {}".format(config))
        requested_cbc_antenna = parse_csv_antennas(config['coherent-beams-antennas'])
        if not self._verify_antennas(requested_cbc_antenna):
            raise Exception("Requested coherent beam antennas are not a subset of the available antennas")
        requested_ibc_antenna = parse_csv_antennas(config['incoherent-beam-antennas'])
        if not self._verify_antennas(requested_ibc_antenna):
            raise Exception("Requested incoherent beam antennas are not a subset of the available antennas")
        # first we need to get one ip address for the incoherent beam
        self._ibc_mcast_group = self._parent._ip_pool.allocate(1)
        self._ibc_mcast_group_sensor.set_value(self._ibc_mcast_group.format_katcp())
        largest_ip_range = self._parent._ip_pool.largest_free_range()
        nworkers_available = self._parent._server_pool.navailable()
        cm = FbfConfigurationManager(len(self._katpoint_antennas),
            self._feng_config['bandwidth'], self._n_channels,
            nworkers_available, largest_ip_range)
        requested_nantennas = len(parse_csv_antennas(config['coherent-beams-antennas']))
        mcast_config = cm.get_configuration(
            config['coherent-beams-tscrunch'],
            config['coherent-beams-fscrunch'],
            config['coherent-beams-nbeams'],
            requested_nantennas,
            config['bandwidth'],
            config['coherent-beams-granularity'])
        self._bandwidth_sensor.set_value(config['bandwidth'])
        self._cfreq_sensor.set_value(config['centre-frequency'])
        self._nchans_sensor.set_value(mcast_config['num_chans'])
        self._cbc_nbeams_sensor.set_value(mcast_config['num_beams'])
        self._cbc_nbeams_per_group.set_value(mcast_config['num_beams_per_mcast_group'])
        self._cbc_ngroups.set_value(mcast_config['num_mcast_groups'])
        self._cbc_nbeams_per_server_set.set_value(mcast_config['num_beams_per_worker_set'])
        self._cbc_tscrunch_sensor.set_value(config['coherent-beams-tscrunch'])
        self._cbc_fscrunch_sensor.set_value(config['coherent-beams-fscrunch'])
        self._cbc_antennas_sensor.set_value(config['coherent-beams-antennas'])
        self._ibc_tscrunch_sensor.set_value(config['incoherent-beam-tscrunch'])
        self._ibc_fscrunch_sensor.set_value(config['incoherent-beam-fscrunch'])
        self._ibc_antennas_sensor.set_value(config['incoherent-beam-antennas'])
        self._servers = self._parent._server_pool.allocate(mcast_config['num_workers_total'])
        server_str = ",".join(["{s.hostname}:{s.port}".format(s=server) for server in self._servers])
        self._servers_sensor.set_value(server_str)
        self._nserver_sets_sensor.set_value(mcast_config['num_worker_sets'])
        self._nservers_per_set_sensor.set_value(mcast_config['num_workers_per_set'])
        self._cbc_mcast_groups = self._parent._ip_pool.allocate(mcast_config['num_mcast_groups'])
        self._cbc_mcast_groups_sensor.set_value(self._cbc_mcast_groups.format_katcp())
        return cm

    @coroutine
    def get_ca_target_configuration(self, target):
        def ca_target_update_callback(received_timestamp, timestamp, status, value):
            # TODO, should we really reset all the beams or should we have
            # a mechanism to only update changed beams
            config_dict = json.loads(value)
            self.reset_beams()
            for target_string in config_dict.get('beams',[]):
                target = Target(target_string)
                self.add_beam(target)
            for tiling in config_dict.get('tilings',[]):
                target  = Target(tiling['target']) #required
                freq    = float(tiling.get('reference_frequency', self._cfreq_sensor.value()))
                nbeams  = int(tiling['nbeams'])
                overlap = float(tiling.get('overlap', 0.5))
                epoch   = float(tiling.get('epoch', time.time()))
                self.add_tiling(target, nbeams, freq, overlap, epoch)
        yield self._ca_client.until_synced()
        try:
            response = yield self._ca_client.req.target_configuration_start(self._proxy_name, target.format_katcp())
        except Exception as error:
            self.log.error("Request for target configuration to CA failed with error: {}".format(str(error)))
            raise error
        if not response.reply.reply_ok():
            error = Exception(response.reply.arguments[1])
            self.log.error("Request for target configuration to CA failed with error: {}".format(str(error)))
            raise error
        yield self._ca_client.until_synced()
        sensor = self._ca_client.sensor["{}_beam_position_configuration".format(self._proxy_name)]
        sensor.register_listener(ca_target_update_callback)
        self._ca_client.set_sampling_strategy(sensor.name, "event")

    def _beam_to_sensor_string(self, beam):
        return beam.target.format_katcp()

    @coroutine
    def target_start(self, target):
        self._phase_reference_sensor.set_value(target)
        if self._ca_client:
            yield self.get_ca_target_configuration(target)
        else:
            self.log.warning("No configuration authority is set, using default beam configuration")

    @coroutine
    def target_stop(self):
        if self._ca_client:
            sensor_name = "{}_beam_position_configuration".format(self._proxy_name)
            self._ca_client.set_sampling_strategy(sensor_name, "none")

    @coroutine
    def prepare(self, sb_id):
        """
        @brief      Prepare the beamformer for streaming

        @detail     This method evaluates the current configuration creates a new DelayEngine
                    and passes a prepare call to all allocated servers.
        """
        if not self.idle:
            raise FbfProductStateError([self.IDLE], self.state)
        self.log.info("Preparing FBFUSE product")
        self._state_sensor.set_value(self.PREPARING)
        self.log.debug("Product moved to 'preparing' state")
        # Here we need to parse the streams and assign beams to streams:
        #mcast_addrs, mcast_port = parse_stream(self._streams['cbf.antenna_channelised_voltage']['i0.antenna-channelised-voltage'])

        if not self._ca_client:
            self.log.warning("No configuration authority found, using default configuration parameters")
            cm = self.set_sb_configuration(self._default_sb_config)
        else:
            #TODO: get the schedule block ID into this call from somewhere (configure?)
            try:
                config = yield self.get_ca_sb_configuration(sb_id)
                cm = self.set_sb_configuration(config)
            except Exception as error:
                self.log.error("Configuring from CA failed with error: {}".format(str(error)))
                self.log.warning("Reverting to default configuration")
                cm = self.set_sb_configuration(self._default_sb_config)

        cbc_antennas_names = parse_csv_antennas(self._cbc_antennas_sensor.value())
        cbc_antennas = [self._antenna_map[name] for name in cbc_antennas_names]
        self._beam_manager = BeamManager(self._cbc_nbeams_sensor.value(), cbc_antennas)
        self._delay_config_server = DelayConfigurationServer("127.0.0.1", 0, self._beam_manager)
        self._delay_config_server.start()
        self.log.info("Started delay engine at: {}".format(self._delay_config_server.bind_address))
        de_ip, de_port = self._delay_config_server.bind_address
        self._delay_config_server_sensor.set_value((de_ip, de_port))

        # Need to tear down the beam sensors here
        # Here calculate the beam to multicast map
        self._beam_sensors = []
        mcast_to_beam_map = {}
        groups = [ip for ip in self._cbc_mcast_groups]
        idxs = [beam.idx for beam in self._beam_manager.get_beams()]
        for group in groups:
            self.log.debug("Allocating beams to {}".format(str(group)))
            key = str(group)
            for _ in range(self._cbc_nbeams_per_group.value()):
                if not key in mcast_to_beam_map:
                    mcast_to_beam_map[str(group)] = []
                value = idxs.pop(0)
                self.log.debug("--> Allocated {} to {}".format(value, str(group)))
                mcast_to_beam_map[str(group)].append(value)
        self._cbc_mcast_groups_mapping_sensor.set_value(json.dumps(mcast_to_beam_map))
        for beam in self._beam_manager.get_beams():
            sensor = Sensor.string(
                "coherent-beam-{}".format(beam.idx),
                description="R.A. (deg), declination (deg) and source name for coherent beam with ID {}".format(beam.idx),
                default=self._beam_to_sensor_string(beam),
                initial_status=Sensor.UNKNOWN)
            beam.register_observer(lambda beam, sensor=sensor:
                sensor.set_value(self._beam_to_sensor_string(beam)))
            self._beam_sensors.append(sensor)
            self.add_sensor(sensor)
        self._parent.mass_inform(Message.inform('interface-changed'))

        #Here we actually start to prepare the remote workers
        ip_splits = self._streams.split(N_FENG_STREAMS_PER_WORKER)

        # This is assuming lower sideband and bandwidth is always +ve
        fbottom = self._feng_config['centre-frequency'] - self._feng_config['bandwidth']/2.

        coherent_beam_config = {
        'tscrunch':self._cbc_tscrunch_sensor.value(),
        'fscrunch':self._cbc_fscrunch_sensor.value(),
        'antennas':self._cbc_antennas_sensor.value()
        }

        incoherent_beam_config = {
        'tscrunch':self._ibc_tscrunch_sensor.value(),
        'fscrunch':self._ibc_fscrunch_sensor.value(),
        'antennas':self._ibc_antennas_sensor.value()
        }

        prepare_futures = []
        for ii, (server, ip_range) in enumerate(zip(self._servers, ip_splits)):
            chan0_idx = cm.nchans_per_worker * ii
            chan0_freq =  fbottom + chan0_idx * cm.channel_bandwidth
            future = server.prepare(ip_range.format_katcp(), cm.nchans_per_group,
                        chan0_idx, chan0_freq, cm.channel_bandwidth, mcast_to_beam_map,
                        self._feng_config['feng-antenna-map'], coherent_beam_config,
                        incoherent_beam_config, de_ip, de_port)
            prepare_futures.append(future)

        failure_count = 0
        for future in prepare_futures:
            try:
                yield future
            except Exception as error:
                log.error("Failed to configure server with error: {}".format(str(error)))
                failure_count += 1

        if failure_count > 0:
            self._state_sensor.set_value(self.ERROR)
            self.log.info("Failed to prepare FBFUSE product")
        else:
            self._state_sensor.set_value(self.READY)
            self.log.info("Successfully prepared FBFUSE product")

    def deconfigure(self):
        """
        @brief  Deconfigure the product. To be called on a subarray deconfigure.

        @detail This is the final cleanup operation for the product, it should delete all sensors
                and ensure the release of all resource allocations.
        """
        self.reset_sb_configuration()
        self.teardown_sensors()

    def capture_start(self):
        if not self.ready:
            raise FbfProductStateError([self.READY], self.state)
        self._state_sensor.set_value(self.STARTING)
        self.log.debug("Product moved to 'starting' state")
        """
        futures = []
        for server in self._servers:
            futures.append(server.req.start_capture())
        for future in futures:
            try:
                response = yield future
            except:
                pass
        """
        self._state_sensor.set_value(self.CAPTURING)
        self.log.debug("Product moved to 'capturing' state")

    def capture_stop(self):
        """
        @brief      Stops the beamformer servers streaming.

        @detail     This should only be called on a schedule block reconfiguration
                    if the same configuration persists between schedule blocks then
                    it is preferable to continue streaming rather than stopping and
                    starting again.
        """
        if not self.capturing and not self.error:
            return
        self._state_sensor.set_value(self.STOPPING)
        self.target_stop()
        for server in self._servers:
            #yield server.req.deconfigure()
            pass
        self._state_sensor.set_value(self.IDLE)

    def add_beam(self, target):
        """
        @brief      Specify the parameters of one managed beam

        @param      target      A KATPOINT target object

        @return     Returns the allocated Beam object
        """
        valid_states = [self.READY, self.CAPTURING, self.STARTING]
        if not self.state in valid_states:
            raise FbfProductStateError(valid_states, self.state)
        return self._beam_manager.add_beam(target)

    def add_tiling(self, target, number_of_beams, reference_frequency, overlap, epoch):
        """
        @brief   Add a tiling to be managed

        @param      target      A KATPOINT target object

        @param      reference_frequency     The reference frequency at which to calculate the synthesised beam shape,
                                            and thus the tiling pattern. Typically this would be chosen to be the
                                            centre frequency of the current observation.

        @param      overlap         The desired overlap point between beams in the pattern. The overlap defines
                                    at what power point neighbouring beams in the tiling pattern will meet. For
                                    example an overlap point of 0.1 corresponds to beams overlapping only at their
                                    10%-power points. Similarly a overlap of 0.5 corresponds to beams overlapping
                                    at their half-power points. [Note: This is currently a tricky parameter to use
                                    when values are close to zero. In future this may be define in sigma units or
                                    in multiples of the FWHM of the beam.]

        @returns    The created Tiling object
        """
        valid_states = [self.READY, self.CAPTURING, self.STARTING]
        if not self.state in valid_states:
            raise FbfProductStateError(valid_states, self.state)
        tiling = self._beam_manager.add_tiling(target, number_of_beams, reference_frequency, overlap)
        try:
            tiling.generate(self._katpoint_antennas, epoch)
        except Exception as error:
            self.log.error("Failed to generate tiling pattern with error: {}".format(str(error)))
        return tiling

    def reset_beams(self):
        """
        @brief  reset and deallocate all beams and tilings managed by this instance

        @note   All tiling will be lost on this call and must be remade for subsequent observations
        """
        valid_states = [self.READY, self.CAPTURING, self.STARTING]
        if not self.state in valid_states:
            raise FbfProductStateError(valid_states, self.state)
        self._beam_manager.reset()
示例#2
0
class KatcpSidecar(object):
    def __init__(self, host, port):
        """
        Constructs a new instance.

        :param      host:  The address of the server to sidecar
        :param      port:  The server port
        """
        log.debug("Constructing sidecar for {}:{}".format(host, port))
        self.rc = KATCPClientResource(
            dict(name="sidecar-client", address=(host, port), controlled=True))
        self._update_callbacks = set()
        self._previous_sensors = set()

    @coroutine
    def start(self):
        """
        @brief     Start the sidecar
        """
        @coroutine
        def _start():
            log.debug("Waiting on synchronisation with server")
            yield self.rc.until_synced()
            log.debug("Client synced")
            log.debug("Requesting version info")
            response = yield self.rc.req.version_list()
            log.info("response: {}".format(response))
            self.ioloop.add_callback(self.on_interface_changed)

        self.rc.start()
        self.ic = self.rc._inspecting_client
        self.ioloop = self.rc.ioloop
        self.ic.katcp_client.hook_inform(
            "interface-changed", lambda message: self.ioloop.add_callback(
                self.on_interface_changed))
        self.ioloop.add_callback(_start)

    def stop(self):
        """
        @brief      Stop the sidecar
        """
        self.rc.stop()

    @coroutine
    def on_interface_changed(self):
        """
        @brief    Synchronise with the sidecar'd servers new sensors
        """
        log.debug("Waiting on synchronisation with server")
        yield self.rc.until_synced()
        log.debug("Client synced")
        current_sensors = set(self.rc.sensor.keys())
        log.debug("Current sensor set: {}".format(current_sensors))
        removed = self._previous_sensors.difference(current_sensors)
        log.debug("Sensors removed since last update: {}".format(removed))
        added = current_sensors.difference(self._previous_sensors)
        log.debug("Sensors added since last update: {}".format(added))
        for name in list(added):
            log.debug("Setting sampling strategy and callbacks on sensor '{}'".
                      format(name))
            self.rc.set_sampling_strategy(name, "auto")
            self.rc.set_sensor_listener(name, self.on_sensor_update)
        self._previous_sensors = current_sensors

    @coroutine
    def on_sensor_update(self, sensor, reading):
        """
        @brief      Callback to be executed on a sensor being updated

        @param      sensor   A KATCP Sensor Object
        @param      reading  The sensor reading
        """
        log.debug("Recieved sensor update for sensor '{}': {}".format(
            sensor.name, repr(reading)))
        for callback in list(self._update_callbacks):
            try:
                callback(sensor, reading)
            except Exception as error:
                log.exception(
                    "Failed to call update callback {} with error: {}".format(
                        callback, str(error)))

    def add_sensor_update_callback(self, callback):
        """
        @brief    Add a sensor update callback.

        @param      callback:  The callback

        @note     The callback must have a call signature of
                  func(sensor, reading)
        """
        self._update_callbacks.add(callback)

    def remove_sensor_update_callback(self, callback):
        """
        @brief    Remove a sensor update callback.

        @param      callback:  The callback
        """
        self._update_callbacks.remove(callback)
示例#3
0
class KATCPToIGUIConverter(object):
    def __init__(self, host, port, igui_host, igui_user, igui_pass,
                 igui_device_id):
        """
        @brief      Class for katcp to igui converter.

        @param   host             KATCP host address
        @param   port             KATCP port number
        @param   igui_host        iGUI server hostname
        @param   igui_user        iGUI username
        @param   igui_pass        iGUI password
        @param   igui_device_id   iGUI device ID
        """
        self.rc = KATCPClientResource(
            dict(name="test-client", address=(host, port), controlled=True))
        self.host = host
        self.port = port
        self.igui_host = igui_host
        self.igui_user = igui_user
        self.igui_pass = igui_pass
        self.igui_group_id = None
        self.igui_device_id = igui_device_id
        self.igui_connection = IGUIConnection(self.igui_host, self.igui_user,
                                              self.igui_pass)
        self.igui_task_id = None
        self.igui_rxmap = None
        self.ioloop = None
        self.ic = None
        self.api_version = None
        self.implementation_version = None
        self.previous_sensors = set()

    def start(self):
        """
        @brief      Start the instance running

        @detail     This call will trigger connection of the KATCPResource client and
                    will login to the iGUI server. Once both connections are established
                    the instance will retrieve a mapping of the iGUI receivers, devices
                    and tasks and will try to identify the parent of the device_id
                    provided in the constructor.

        @param      self  The object

        @return     { description_of_the_return_value }
        """
        @tornado.gen.coroutine
        def _start():
            log.debug("Waiting on synchronisation with server")
            yield self.rc.until_synced()
            log.debug("Client synced")
            log.debug("Requesting version info")
            # This information can be used to get an iGUI device ID
            response = yield self.rc.req.version_list()
            log.info("response {}".format(response))
            # for internal device KATCP server, response.informs[2].arguments return index out of range
            #_, api, implementation = response.informs[2].arguments
            #self.api_version = api
            #self.implementation_version = implementation
            #log.info("katcp-device API: {}".format(self.api_version))
            #log.info("katcp-device implementation: {}".format(self.implementation_version))
            self.ioloop.add_callback(self.update)

        log.debug("Starting {} instance".format(self.__class__.__name__))
        # self.igui_connection.login()
        #self.igui_connection.login(self.igui_user, self.igui_pass)
        self.igui_rxmap = self.igui_connection.build_igui_representation()
        #log.debug(self.igui_rxmap)
        # Here we do a look up to find the parent of this device
        for rx in self.igui_rxmap:
            log.debug(rx.id)
            if self.igui_device_id in rx.devices._by_id.keys():
                log.debug(self.igui_device_id)
                log.debug(rx.id)
                self.igui_rx_id = rx.id
                log.debug("Found Rx parent: {}".format(self.igui_rx_id))
                break
        else:
            log.debug("Device '{}' is not a child of any receiver".format(
                self.igui_device_id))
            raise IGUIMappingException(
                "Device '{}' is not a child of any receiver".format(
                    self.igui_device_id))

        #log.debug("iGUI representation:\n{}".format(self.igui_rxmap))
        self.rc.start()
        self.ic = self.rc._inspecting_client
        self.ioloop = self.rc.ioloop
        self.ic.katcp_client.hook_inform(
            "interface-changed",
            lambda message: self.ioloop.add_callback(self.update))
        self.ioloop.add_callback(_start)

    @tornado.gen.coroutine
    def update(self):
        """
        @brief    Synchronise with the KATCP servers sensors and register new listners
        """
        log.debug("Waiting on synchronisation with server")
        yield self.rc.until_synced()
        log.debug("Client synced")
        current_sensors = set(self.rc.sensor.keys())
        log.debug("Current sensor set: {}".format(current_sensors))
        removed = self.previous_sensors.difference(current_sensors)
        log.debug("Sensors removed since last update: {}".format(removed))
        added = current_sensors.difference(self.previous_sensors)
        log.debug("Sensors added since last update: {}".format(added))
        for name in list(added):
            log.debug("Setting sampling strategy and callbacks on sensor '{}'".
                      format(name))
            # strat3 = ('event-rate', 2.0, 3.0)              #event-rate doesn't work
            # self.rc.set_sampling_strategy(name, strat3)    #KATCPSensorError:
            # Error setting strategy
            # not sure that auto means here
            self.rc.set_sampling_strategy(name, "auto")
            #self.rc.set_sampling_strategy(name, ["period", (10)])
            #self.rc.set_sampling_strategy(name, "event")
            self.rc.set_sensor_listener(name, self._sensor_updated)
        self.previous_sensors = current_sensors

    def _sensor_updated(self, sensor, reading):
        """
        @brief      Callback to be executed on a sensor being updated

        @param      sensor   The sensor
        @param      reading  The sensor reading
        """
        log.debug("Recieved sensor update for sensor '{}': {}".format(
            sensor.name, repr(reading)))
        try:
            rx = self.igui_rxmap.by_id(self.igui_rx_id)
        except KeyError:
            raise Exception("No iGUI receiver with ID {}".format(
                self.igui_rx_id))
        try:
            device = rx.devices.by_id(self.igui_device_id)
        except KeyError:
            raise Exception("No iGUI device with ID {}".format(
                self.igui_device_id))
        try:
            #self.igui_rxmap = self.igui_connection.build_igui_representation()
            #device = self.igui_rxmap.by_id(self.igui_rx_id).devices.by_id(self.igui_device_id)
            task = device.tasks.by_name(sensor.name)
        except KeyError:
            if (sensor.name[-3:] == 'PNG'):
                task = json.loads(
                    self.igui_connection.create_task(
                        device, (sensor.name, "NONE", "", "IMAGE", "GET_SET",
                                 "0", "0", "0", "-10000000000000000",
                                 "10000000000000000", "300")))
            else:
                task = json.loads(
                    self.igui_connection.create_task(
                        device, (sensor.name, "NONE", "", "GETSET", "GET", "0",
                                 "0", "0", "-10000000000000000",
                                 "10000000000000000", "300")))
            self.igui_task_id = str(task[0]['rx_task_id'])
            self.igui_connection.update_group_task_privileges(
                [self.igui_connection.igui_group_id, self.igui_task_id], "Y")
            self.igui_connection.update_group_task_privileges([
                self.igui_connection.igui_group_id, self.igui_task_id, "update"
            ], "Y")
            self.igui_rxmap = self.igui_connection.build_igui_representation()
            device = self.igui_rxmap.by_id(self.igui_rx_id).devices.by_id(
                self.igui_device_id)
            task = device.tasks.by_id(self.igui_task_id)

        if (sensor.name[-3:] == 'PNG'
            ):  # or some image type that we finally agreed on
            log.debug(sensor.name)
            log.debug(sensor.value)
            log.debug(len(sensor.value))
            self.igui_connection.set_task_blob(task, reading.value)
        else:
            self.igui_connection.set_task_value(task, sensor.value)

    def stop(self):
        """
        @brief      Stop the client
        """
        self.rc.stop()