ponsim/ponsim.py - voltha - Gitiles

 #
 # Copyright 2016 the original author or authors.
 #
 # Licensed under the Apache License, Version 2.0 (the "License");
 # you may not use this file except in compliance with the License.
 # You may obtain a copy of the License at
 #
 #      http://www.apache.org/licenses/LICENSE-2.0
 #
 # Unless required by applicable law or agreed to in writing, software
 # distributed under the License is distributed on an "AS IS" BASIS,
 # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 # See the License for the specific language governing permissions and
 # limitations under the License.
 #

 """
 Simple PON Simulator which would not be needed if openvswitch could do
 802.1ad (QinQ), which it cannot (the reason is beyond me), or if CPQD could
 handle 0-tagged packets (no comment).
 """
 import structlog
 import random
 import arrow
 import json
 from scapy.layers.inet import IP, UDP, TCP, Raw
 from scapy.layers.l2 import Ether, Dot1Q
 from scapy.packet import Packet

 from voltha.protos import third_party
 from voltha.protos.ponsim_pb2 import PonSimMetrics, PonSimPortMetrics, \
     PonSimPacketCounter
 from voltha.protos.events_pb2 import AlarmEventType, AlarmEventSeverity, \
     AlarmEventState, AlarmEventCategory
 from voltha.core.flow_decomposer import *
 from twisted.internet.task import LoopingCall
 from twisted.internet import reactor

 _ = third_party


 def ipv4int2str(ipv4int):
     return '{}.{}.{}.{}'.format(
         (ipv4int >> 24) & 0xff,
         (ipv4int >> 16) & 0xff,
         (ipv4int >> 8) & 0xff,
         ipv4int & 0xff
     )


 class _FlowMatchMask(object):
     """
     Enum of mask values based on flow match priority. For instance, a port
     match has higher priority when match that a UDP match.
     """
     UDP_DST = 1
     UDP_SRC = 2
     IPV4_DST = 4
     VLAN_PCP = 8
     VLAN_VID = 16
     IP_PROTO = 34
     ETH_TYPE = 64
     IN_PORT = 128


 class FrameIOCounter(object):
     class SingleFrameCounter(object):
         def __init__(self, name, min, max):
             # Currently there are 2 values, one for the PON interface (port 1)
             # and one for the Network Interface (port 2). This can be extended if
             # the virtual devices extend the number of ports.
             self.value = [0, 0]  # {PON,NI}
             self.name = name
             self.min = min
             self.max = max

     def __init__(self, device):
         self.device = device
         self.tx_counters = dict(
             tx_64_pkts=self.SingleFrameCounter("tx_64_pkts", 1, 64),
             tx_65_127_pkts=self.SingleFrameCounter("tx_65_127_pkts", 65, 127),
             tx_128_255_pkts=self.SingleFrameCounter("tx_128_255_pkts", 128, 255),
             tx_256_511_pkts=self.SingleFrameCounter("tx_256_511_pkts", 256, 511),
             tx_512_1023_pkts=self.SingleFrameCounter("tx_512_1023_pkts", 512, 1024),
             tx_1024_1518_pkts=self.SingleFrameCounter("tx_1024_1518_pkts", 1024, 1518),
             tx_1519_9k_pkts=self.SingleFrameCounter("tx_1519_9k_pkts", 1519, 9216),
         )
         self.rx_counters = dict(
             rx_64_pkts=self.SingleFrameCounter("rx_64_pkts", 1, 64),
             rx_65_127_pkts=self.SingleFrameCounter("rx_65_127_pkts", 65, 127),
             rx_128_255_pkts=self.SingleFrameCounter("rx_128_255_pkts", 128, 255),
             rx_256_511_pkts=self.SingleFrameCounter("rx_256_511_pkts", 256, 511),
             rx_512_1023_pkts=self.SingleFrameCounter("rx_512_1023_pkts", 512, 1024),
             rx_1024_1518_pkts=self.SingleFrameCounter("rx_1024_1518_pkts", 1024, 1518),
             rx_1519_9k_pkts=self.SingleFrameCounter("rx_1519_9k_pkts", 1519, 9216)
         )

     def count_rx_frame(self, port, size):
         log.info("counting-rx-frame", size=size, port=port)
         for k, v in self.rx_counters.iteritems():
             if size >= v.min and size <= v.max:
                 self.rx_counters[k].value[port - 1] += 1
                 return
         log.warn("unsupported-packet-size", size=size)

     def count_tx_frame(self, port, size):
         for k, v in self.tx_counters.iteritems():
             if size >= v.min and size <= v.max:
                 self.tx_counters[k].value[port - 1] += 1
                 return
         log.warn("unsupported-packet-size", size=size)

     def log_counts(self):
         rx_ct_list = [(v.name, v.value[0], v.value[1]) for v in
                       self.rx_counters.values()]
         tx_ct_list = [(v.name, v.value[0], v.value[1]) for v in
                       self.tx_counters.values()]
         log.info("rx-counts", rx_ct_list=rx_ct_list)
         log.info("tx-counts", tx_ct_list=tx_ct_list)

     def make_proto(self):
         sim_metrics = PonSimMetrics(
             device=self.device
         )
         pon_port_metrics = PonSimPortMetrics(
             port_name="pon"
         )
         ni_port_metrics = PonSimPortMetrics(
             port_name="nni"
         )
         for c in sorted(self.rx_counters):
             ctr = self.rx_counters[c]
             pon_port_metrics.packets.extend([
                 PonSimPacketCounter(name=ctr.name, value=ctr.value[0])
             ])
             # Since they're identical keys, save some time and cheat
             ni_port_metrics.packets.extend([
                 PonSimPacketCounter(name=ctr.name, value=ctr.value[1])
             ])

         for c in sorted(self.tx_counters):
             ctr = self.tx_counters[c]
             pon_port_metrics.packets.extend([
                 PonSimPacketCounter(name=ctr.name, value=ctr.value[0])
             ])
             # Since they're identical keys, save some time and cheat
             ni_port_metrics.packets.extend([
                 PonSimPacketCounter(name=ctr.name, value=ctr.value[1])
             ])
         sim_metrics.metrics.extend([pon_port_metrics])
         sim_metrics.metrics.extend([ni_port_metrics])

         return sim_metrics


 class SimAlarms:
     def __init__(self):
         self.lc = None

     @staticmethod
     def _prepare_alarm():
         alarm_event = dict()

         try:
             # Randomly choose values for each enum types
             alm_severity = random.choice(list(
                 v for k, v in
                 AlarmEventSeverity.DESCRIPTOR.enum_values_by_name.items()))

             alm_type = random.choice(list(
                 v for k, v in
                 AlarmEventType.DESCRIPTOR.enum_values_by_name.items()))

             alm_category = random.choice(list(
                 v for k, v in
                 AlarmEventCategory.DESCRIPTOR.enum_values_by_name.items()))

             alarm_event['severity'] = alm_severity.number
             alarm_event['type'] = alm_type.number
             alarm_event['category'] = alm_category.number
             alarm_event['state'] = AlarmEventState.RAISED
             alarm_event['ts'] = arrow.utcnow().timestamp
             alarm_event['description'] = "{}.{} alarm".format(alm_type.name, alm_category.name)

             return alarm_event

         except Exception as e:
             log.exception('failed-to-prepare-alarm', e=e)

     @staticmethod
     def _raise_alarm(alarm_event, olt, egress):
         try:
             frame = Ether() / Dot1Q(vlan=4000) / IP() / TCP() / Raw(load=json.dumps(alarm_event))
             egress(0, frame)

         except Exception as e:
             log.exception('failed-to-raise-alarm', e=e)

     @staticmethod
     def _clear_alarm(alarm_event, olt, egress):
         try:
             alarm_event['state'] = AlarmEventState.CLEARED
             frame = Ether() / Dot1Q(vlan=4000) / IP() / TCP() / Raw(load=json.dumps(alarm_event))
             egress(0, frame)

         except Exception as e:
             log.exception('failed-to-clear-alarm', e=e)

     def _generate_alarm(self, olt, egress):
         try:
             alarm = self._prepare_alarm()
             self._raise_alarm(alarm, olt, egress)
             reactor.callLater(random.randint(20, 60), self._clear_alarm, alarm, olt, egress)
         except Exception as e:
             log.exception(e=e)

     def start_simulation(self, olt, egress, config):
         log.info("starting-alarm-simulation")

         """Simulate periodic device alarms"""
         self.lc = LoopingCall(self._generate_alarm, olt, egress)
         self.lc.start(config['frequency'])

     def stop_simulation(self):
         log.info("stopping-alarm-simulation")
         self.lc.stop()


 class SimDevice(object):
     def __init__(self, name, logical_port_no):
         self.name = name
         self.logical_port_no = logical_port_no
         self.links = dict()
         self.flows = list()
         self.log = structlog.get_logger(name=name,
                                         logical_port_no=logical_port_no)
         self.counter = FrameIOCounter(name)

     def link(self, port, egress_fun):
         self.links.setdefault(port, []).append(egress_fun)

     def ingress(self, port, frame):
         self.log.debug('ingress', ingress_port=port, name=self.name)
         self.counter.count_rx_frame(port, len(frame["Ether"].payload))
         outcome = self.process_frame(port, frame)
         if outcome is not None:
             egress_port, egress_frame = outcome
             forwarded = 0
             links = self.links.get(egress_port)
             if links is not None:
                 self.counter.count_tx_frame(egress_port,
                                             len(egress_frame["Ether"].payload))
                 for fun in links:
                     forwarded += 1
                     self.log.debug('forwarding', egress_port=egress_port)
                     fun(egress_port, egress_frame)
             if not forwarded:
                 self.log.debug('no-one-to-forward-to', egress_port=egress_port)
         else:
             self.log.debug('dropped')

     def install_flows(self, flows):
         # store flows in precedence order so we can roll down on frame arrival
         self.flows = sorted(flows, key=lambda fm: fm.priority, reverse=True)

     def process_frame(self, ingress_port, ingress_frame):
         matched_mask = 0
         highest_priority = 0
         matched_flow = None
         for flow in self.flows:
             # flows are sorted by highest priority.
             if matched_flow and flow.priority < highest_priority:
                 break

             highest_priority = flow.priority
             current_mask = self.is_match(flow, ingress_port, ingress_frame)
             if current_mask > matched_mask:
                 matched_mask = current_mask
                 matched_flow = flow

         if matched_flow:
             egress_port, egress_frame = self.process_actions(
                 matched_flow, ingress_frame)
             return egress_port, egress_frame
         return None

     @staticmethod
     def is_match(flow, ingress_port, frame):
         matched_mask = 0

         def get_non_shim_ether_type(f):
             if f.haslayer(Dot1Q):
                 f = f.getlayer(Dot1Q)
             return f.type

         def get_vlan_pcp(f):
             if f.haslayer(Dot1Q):
                 return f.getlayer(Dot1Q).prio

         def get_ip_proto(f):
             if f.haslayer(IP):
                 return f.getlayer(IP).proto

         def get_ipv4_dst(f):
             if f.haslayer(IP):
                 return f.getlayer(IP).dst

         def get_udp_src(f):
             if f.haslayer(UDP):
                 return f.getlayer(UDP).sport

         def get_udp_dst(f):
             if f.haslayer(UDP):
                 return f.getlayer(UDP).dport

         for field in get_ofb_fields(flow):

             if field.type == IN_PORT:
                 if field.port != ingress_port:
                     return 0
                 matched_mask |= _FlowMatchMask.IN_PORT

             elif field.type == ETH_TYPE:
                 if field.eth_type != get_non_shim_ether_type(frame):
                     return 0
                 matched_mask |= _FlowMatchMask.ETH_TYPE

             elif field.type == IP_PROTO:
                 if field.ip_proto != get_ip_proto(frame):
                     return 0
                 matched_mask |= _FlowMatchMask.IP_PROTO

             elif field.type == VLAN_VID:
                 expected_vlan = field.vlan_vid
                 tagged = frame.haslayer(Dot1Q)
                 if bool(expected_vlan & 4096) != bool(tagged):
                     return 0
                 if tagged:
                     actual_vid = frame.getlayer(Dot1Q).vlan
                     if actual_vid != expected_vlan & 4095:
                         return 0
                 matched_mask |= _FlowMatchMask.VLAN_VID

             elif field.type == VLAN_PCP:
                 if field.vlan_pcp != get_vlan_pcp(frame):
                     return 0
                 matched_mask |= _FlowMatchMask.VLAN_PCP

             elif field.type == IPV4_DST:
                 if ipv4int2str(field.ipv4_dst) != get_ipv4_dst(frame):
                     return 0
                 matched_mask |= _FlowMatchMask.IPV4_DST

             elif field.type == UDP_SRC:
                 if field.udp_src != get_udp_src(frame):
                     return 0
                 matched_mask |= _FlowMatchMask.UDP_SRC

             elif field.type == UDP_DST:
                 if field.udp_dst != get_udp_dst(frame):
                     return 0
                 matched_mask |= _FlowMatchMask.UDP_DST

             elif field.type == METADATA:
                 pass  # safe to ignore

             else:
                 raise NotImplementedError('field.type=%d' % field.type)

         return matched_mask

     @staticmethod
     def process_actions(flow, frame):
         egress_port = None
         for action in get_actions(flow):

             if action.type == OUTPUT:
                 egress_port = action.output.port

             elif action.type == POP_VLAN:
                 if frame.haslayer(Dot1Q):
                     shim = frame.getlayer(Dot1Q)
                     frame = Ether(
                         src=frame.src,
                         dst=frame.dst,
                         type=shim.type) / shim.payload

             elif action.type == PUSH_VLAN:
                 frame = (
                     Ether(src=frame.src, dst=frame.dst,
                           type=action.push.ethertype) /
                     Dot1Q(type=frame.type) /
                     frame.payload
                 )

             elif action.type == SET_FIELD:
                 assert (action.set_field.field.oxm_class ==
                         ofp.OFPXMC_OPENFLOW_BASIC)
                 field = action.set_field.field.ofb_field

                 if field.type == VLAN_VID:
                     shim = frame.getlayer(Dot1Q)
                     shim.vlan = field.vlan_vid & 4095

                 elif field.type == VLAN_PCP:
                     shim = frame.getlayer(Dot1Q)
                     shim.prio = field.vlan_pcp

                 else:
                     raise NotImplementedError('set_field.field.type=%d'
                                               % field.type)

             else:
                 raise NotImplementedError('action.type=%d' % action.type)

         return egress_port, frame


 class PonSim(object):
     def __init__(self, onus, egress_fun, alarm_config):
         self.egress_fun = egress_fun

         self.log = structlog.get_logger()
         # Create OLT and hook NNI port up for egress
         self.olt = SimDevice('olt', 0)
         self.olt.link(2, lambda _, frame: self.egress_fun(0, frame))
         self.devices = dict()
         self.devices[0] = self.olt
         # TODO: This can be removed, it's for debugging purposes
         self.lc = LoopingCall(self.olt.counter.log_counts)
         self.lc.start(90)  # To correlate with Kafka

         # Create ONUs of the requested number and hook them up with OLT
         # and with egress fun
         def mk_egress_fun(port_no):
             return lambda _, frame: self.egress_fun(port_no, frame)

         def mk_onu_ingress(onu):
             return lambda _, frame: onu.ingress(1, frame)

         for i in range(onus):
             port_no = 128 + i
             onu = SimDevice('onu%d' % i, port_no)
             onu.link(1, lambda _, frame: self.olt.ingress(1,
                                                           frame))  # Send to the OLT
             onu.link(2,
                      mk_egress_fun(port_no))  # Send from the ONU to the world
             self.olt.link(1, mk_onu_ingress(onu))  # Internal send to the ONU
             self.devices[port_no] = onu
         for d in self.devices:
             self.log.info("pon-sim-init", port=d, name=self.devices[d].name,
                           links=self.devices[d].links)

         if alarm_config['simulation']:
             self.alarms = SimAlarms()
             self.alarms.start_simulation(self.olt, self.egress_fun, alarm_config)

     def get_ports(self):
         return sorted(self.devices.keys())

     def get_stats(self):
         return self.olt.counter.make_proto()

     def olt_install_flows(self, flows):
         self.olt.install_flows(flows)

     def onu_install_flows(self, onu_port, flows):
         self.devices[onu_port].install_flows(flows)

     def ingress(self, port, frame):
         if not isinstance(frame, Packet):
             frame = Ether(frame)
         self.devices[port].ingress(2, frame)

 class XPonSim(object):
     def __init__(self):
         self.log = structlog.get_logger()

     def CreateInterface(self, request):
         self.log.info("create-interface-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def UpdateInterface(self, request):
         self.log.info("update-interface-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def RemoveInterface(self, request):
         self.log.info("remove-interface-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def CreateTcont(self, request, request2):
         self.log.info("create-tcont-request",
                       tcont_config_data=request,
                       traffic_descriptor_profile_config_data=request2)
         return

     def UpdateTcont(self, request, request2):
         self.log.info("update-tcont-request",
                       tcont_config_data=request,
                       traffic_descriptor_profile_config_data=request2)
         return

     def RemoveTcont(self, request, request2):
         self.log.info("remove-tcont-request",
                       tcont_config_data=request,
                       traffic_descriptor_profile_config_data=request2)
         return

     def CreateGemport(self, request):
         self.log.info("create-gemport-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def UpdateGemport(self, request):
         self.log.info("update-gemport-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def RemoveGemport(self, request):
         self.log.info("remove-gemport-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def CreateMulticastGemport(self, request):
         self.log.info("create-multicast-gemport-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def UpdateMulticastGemport(self, request):
         self.log.info("update-multicast-gemport-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def RemoveMulticastGemport(self, request):
         self.log.info("remove-multicast-gemport-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def CreateMulticastDistributionSet(self, request):
         self.log.info("create-multicast-distribution-set-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def UpdateMulticastDistributionSet(self, request):
         self.log.info("update-multicast-distribution-set-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return

     def RemoveMulticastDistributionSet(self, request):
         self.log.info("remove-multicast-distribution-set-request",
                       interface_type=request.WhichOneof("interface_type"),
                       data=request)
         return
	#
	# Copyright 2016 the original author or authors.
	#
	# Licensed under the Apache License, Version 2.0 (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# http://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.
	#

	"""
	Simple PON Simulator which would not be needed if openvswitch could do
	802.1ad (QinQ), which it cannot (the reason is beyond me), or if CPQD could
	handle 0-tagged packets (no comment).
	"""
	import structlog
	import random
	import arrow
	import json
	from scapy.layers.inet import IP, UDP, TCP, Raw
	from scapy.layers.l2 import Ether, Dot1Q
	from scapy.packet import Packet

	from voltha.protos import third_party
	from voltha.protos.ponsim_pb2 import PonSimMetrics, PonSimPortMetrics, \
	PonSimPacketCounter
	from voltha.protos.events_pb2 import AlarmEventType, AlarmEventSeverity, \
	AlarmEventState, AlarmEventCategory
	from voltha.core.flow_decomposer import *
	from twisted.internet.task import LoopingCall
	from twisted.internet import reactor

	_ = third_party


	def ipv4int2str(ipv4int):
	return '{}.{}.{}.{}'.format(
	(ipv4int >> 24) & 0xff,
	(ipv4int >> 16) & 0xff,
	(ipv4int >> 8) & 0xff,
	ipv4int & 0xff
	)


	class _FlowMatchMask(object):
	"""
	Enum of mask values based on flow match priority. For instance, a port
	match has higher priority when match that a UDP match.
	"""
	UDP_DST = 1
	UDP_SRC = 2
	IPV4_DST = 4
	VLAN_PCP = 8
	VLAN_VID = 16
	IP_PROTO = 34
	ETH_TYPE = 64
	IN_PORT = 128


	class FrameIOCounter(object):
	class SingleFrameCounter(object):
	def __init__(self, name, min, max):
	# Currently there are 2 values, one for the PON interface (port 1)
	# and one for the Network Interface (port 2). This can be extended if
	# the virtual devices extend the number of ports.
	self.value = [0, 0] # {PON,NI}
	self.name = name
	self.min = min
	self.max = max

	def __init__(self, device):
	self.device = device
	self.tx_counters = dict(
	tx_64_pkts=self.SingleFrameCounter("tx_64_pkts", 1, 64),
	tx_65_127_pkts=self.SingleFrameCounter("tx_65_127_pkts", 65, 127),
	tx_128_255_pkts=self.SingleFrameCounter("tx_128_255_pkts", 128, 255),
	tx_256_511_pkts=self.SingleFrameCounter("tx_256_511_pkts", 256, 511),
	tx_512_1023_pkts=self.SingleFrameCounter("tx_512_1023_pkts", 512, 1024),
	tx_1024_1518_pkts=self.SingleFrameCounter("tx_1024_1518_pkts", 1024, 1518),
	tx_1519_9k_pkts=self.SingleFrameCounter("tx_1519_9k_pkts", 1519, 9216),
	)
	self.rx_counters = dict(
	rx_64_pkts=self.SingleFrameCounter("rx_64_pkts", 1, 64),
	rx_65_127_pkts=self.SingleFrameCounter("rx_65_127_pkts", 65, 127),
	rx_128_255_pkts=self.SingleFrameCounter("rx_128_255_pkts", 128, 255),
	rx_256_511_pkts=self.SingleFrameCounter("rx_256_511_pkts", 256, 511),
	rx_512_1023_pkts=self.SingleFrameCounter("rx_512_1023_pkts", 512, 1024),
	rx_1024_1518_pkts=self.SingleFrameCounter("rx_1024_1518_pkts", 1024, 1518),
	rx_1519_9k_pkts=self.SingleFrameCounter("rx_1519_9k_pkts", 1519, 9216)
	)

	def count_rx_frame(self, port, size):
	log.info("counting-rx-frame", size=size, port=port)
	for k, v in self.rx_counters.iteritems():
	if size >= v.min and size <= v.max:
	self.rx_counters[k].value[port - 1] += 1
	return
	log.warn("unsupported-packet-size", size=size)

	def count_tx_frame(self, port, size):
	for k, v in self.tx_counters.iteritems():
	if size >= v.min and size <= v.max:
	self.tx_counters[k].value[port - 1] += 1
	return
	log.warn("unsupported-packet-size", size=size)

	def log_counts(self):
	rx_ct_list = [(v.name, v.value[0], v.value[1]) for v in
	self.rx_counters.values()]
	tx_ct_list = [(v.name, v.value[0], v.value[1]) for v in
	self.tx_counters.values()]
	log.info("rx-counts", rx_ct_list=rx_ct_list)
	log.info("tx-counts", tx_ct_list=tx_ct_list)

	def make_proto(self):
	sim_metrics = PonSimMetrics(
	device=self.device
	)
	pon_port_metrics = PonSimPortMetrics(
	port_name="pon"
	)
	ni_port_metrics = PonSimPortMetrics(
	port_name="nni"
	)
	for c in sorted(self.rx_counters):
	ctr = self.rx_counters[c]
	pon_port_metrics.packets.extend([
	PonSimPacketCounter(name=ctr.name, value=ctr.value[0])
	])
	# Since they're identical keys, save some time and cheat
	ni_port_metrics.packets.extend([
	PonSimPacketCounter(name=ctr.name, value=ctr.value[1])
	])

	for c in sorted(self.tx_counters):
	ctr = self.tx_counters[c]
	pon_port_metrics.packets.extend([
	PonSimPacketCounter(name=ctr.name, value=ctr.value[0])
	])
	# Since they're identical keys, save some time and cheat
	ni_port_metrics.packets.extend([
	PonSimPacketCounter(name=ctr.name, value=ctr.value[1])
	])
	sim_metrics.metrics.extend([pon_port_metrics])
	sim_metrics.metrics.extend([ni_port_metrics])

	return sim_metrics


	class SimAlarms:
	def __init__(self):
	self.lc = None

	@staticmethod
	def _prepare_alarm():
	alarm_event = dict()

	try:
	# Randomly choose values for each enum types
	alm_severity = random.choice(list(
	v for k, v in
	AlarmEventSeverity.DESCRIPTOR.enum_values_by_name.items()))

	alm_type = random.choice(list(
	v for k, v in
	AlarmEventType.DESCRIPTOR.enum_values_by_name.items()))

	alm_category = random.choice(list(
	v for k, v in
	AlarmEventCategory.DESCRIPTOR.enum_values_by_name.items()))

	alarm_event['severity'] = alm_severity.number
	alarm_event['type'] = alm_type.number
	alarm_event['category'] = alm_category.number
	alarm_event['state'] = AlarmEventState.RAISED
	alarm_event['ts'] = arrow.utcnow().timestamp
	alarm_event['description'] = "{}.{} alarm".format(alm_type.name, alm_category.name)

	return alarm_event

	except Exception as e:
	log.exception('failed-to-prepare-alarm', e=e)

	@staticmethod
	def _raise_alarm(alarm_event, olt, egress):
	try:
	frame = Ether() / Dot1Q(vlan=4000) / IP() / TCP() / Raw(load=json.dumps(alarm_event))
	egress(0, frame)

	except Exception as e:
	log.exception('failed-to-raise-alarm', e=e)

	@staticmethod
	def _clear_alarm(alarm_event, olt, egress):
	try:
	alarm_event['state'] = AlarmEventState.CLEARED
	frame = Ether() / Dot1Q(vlan=4000) / IP() / TCP() / Raw(load=json.dumps(alarm_event))
	egress(0, frame)

	except Exception as e:
	log.exception('failed-to-clear-alarm', e=e)

	def _generate_alarm(self, olt, egress):
	try:
	alarm = self._prepare_alarm()
	self._raise_alarm(alarm, olt, egress)
	reactor.callLater(random.randint(20, 60), self._clear_alarm, alarm, olt, egress)
	except Exception as e:
	log.exception(e=e)

	def start_simulation(self, olt, egress, config):
	log.info("starting-alarm-simulation")

	"""Simulate periodic device alarms"""
	self.lc = LoopingCall(self._generate_alarm, olt, egress)
	self.lc.start(config['frequency'])

	def stop_simulation(self):
	log.info("stopping-alarm-simulation")
	self.lc.stop()


	class SimDevice(object):
	def __init__(self, name, logical_port_no):
	self.name = name
	self.logical_port_no = logical_port_no
	self.links = dict()
	self.flows = list()
	self.log = structlog.get_logger(name=name,
	logical_port_no=logical_port_no)
	self.counter = FrameIOCounter(name)

	def link(self, port, egress_fun):
	self.links.setdefault(port, []).append(egress_fun)

	def ingress(self, port, frame):
	self.log.debug('ingress', ingress_port=port, name=self.name)
	self.counter.count_rx_frame(port, len(frame["Ether"].payload))
	outcome = self.process_frame(port, frame)
	if outcome is not None:
	egress_port, egress_frame = outcome
	forwarded = 0
	links = self.links.get(egress_port)
	if links is not None:
	self.counter.count_tx_frame(egress_port,
	len(egress_frame["Ether"].payload))
	for fun in links:
	forwarded += 1
	self.log.debug('forwarding', egress_port=egress_port)
	fun(egress_port, egress_frame)
	if not forwarded:
	self.log.debug('no-one-to-forward-to', egress_port=egress_port)
	else:
	self.log.debug('dropped')

	def install_flows(self, flows):
	# store flows in precedence order so we can roll down on frame arrival
	self.flows = sorted(flows, key=lambda fm: fm.priority, reverse=True)

	def process_frame(self, ingress_port, ingress_frame):
	matched_mask = 0
	highest_priority = 0
	matched_flow = None
	for flow in self.flows:
	# flows are sorted by highest priority.
	if matched_flow and flow.priority < highest_priority:
	break

	highest_priority = flow.priority
	current_mask = self.is_match(flow, ingress_port, ingress_frame)
	if current_mask > matched_mask:
	matched_mask = current_mask
	matched_flow = flow

	if matched_flow:
	egress_port, egress_frame = self.process_actions(
	matched_flow, ingress_frame)
	return egress_port, egress_frame
	return None

	@staticmethod
	def is_match(flow, ingress_port, frame):
	matched_mask = 0

	def get_non_shim_ether_type(f):
	if f.haslayer(Dot1Q):
	f = f.getlayer(Dot1Q)
	return f.type

	def get_vlan_pcp(f):
	if f.haslayer(Dot1Q):
	return f.getlayer(Dot1Q).prio

	def get_ip_proto(f):
	if f.haslayer(IP):
	return f.getlayer(IP).proto

	def get_ipv4_dst(f):
	if f.haslayer(IP):
	return f.getlayer(IP).dst

	def get_udp_src(f):
	if f.haslayer(UDP):
	return f.getlayer(UDP).sport

	def get_udp_dst(f):
	if f.haslayer(UDP):
	return f.getlayer(UDP).dport

	for field in get_ofb_fields(flow):

	if field.type == IN_PORT:
	if field.port != ingress_port:
	return 0
	matched_mask \|= _FlowMatchMask.IN_PORT

	elif field.type == ETH_TYPE:
	if field.eth_type != get_non_shim_ether_type(frame):
	return 0
	matched_mask \|= _FlowMatchMask.ETH_TYPE

	elif field.type == IP_PROTO:
	if field.ip_proto != get_ip_proto(frame):
	return 0
	matched_mask \|= _FlowMatchMask.IP_PROTO

	elif field.type == VLAN_VID:
	expected_vlan = field.vlan_vid
	tagged = frame.haslayer(Dot1Q)
	if bool(expected_vlan & 4096) != bool(tagged):
	return 0
	if tagged:
	actual_vid = frame.getlayer(Dot1Q).vlan
	if actual_vid != expected_vlan & 4095:
	return 0
	matched_mask \|= _FlowMatchMask.VLAN_VID

	elif field.type == VLAN_PCP:
	if field.vlan_pcp != get_vlan_pcp(frame):
	return 0
	matched_mask \|= _FlowMatchMask.VLAN_PCP

	elif field.type == IPV4_DST:
	if ipv4int2str(field.ipv4_dst) != get_ipv4_dst(frame):
	return 0
	matched_mask \|= _FlowMatchMask.IPV4_DST

	elif field.type == UDP_SRC:
	if field.udp_src != get_udp_src(frame):
	return 0
	matched_mask \|= _FlowMatchMask.UDP_SRC

	elif field.type == UDP_DST:
	if field.udp_dst != get_udp_dst(frame):
	return 0
	matched_mask \|= _FlowMatchMask.UDP_DST

	elif field.type == METADATA:
	pass # safe to ignore

	else:
	raise NotImplementedError('field.type=%d' % field.type)

	return matched_mask

	@staticmethod
	def process_actions(flow, frame):
	egress_port = None
	for action in get_actions(flow):

	if action.type == OUTPUT:
	egress_port = action.output.port

	elif action.type == POP_VLAN:
	if frame.haslayer(Dot1Q):
	shim = frame.getlayer(Dot1Q)
	frame = Ether(
	src=frame.src,
	dst=frame.dst,
	type=shim.type) / shim.payload

	elif action.type == PUSH_VLAN:
	frame = (
	Ether(src=frame.src, dst=frame.dst,
	type=action.push.ethertype) /
	Dot1Q(type=frame.type) /
	frame.payload
	)

	elif action.type == SET_FIELD:
	assert (action.set_field.field.oxm_class ==
	ofp.OFPXMC_OPENFLOW_BASIC)
	field = action.set_field.field.ofb_field

	if field.type == VLAN_VID:
	shim = frame.getlayer(Dot1Q)
	shim.vlan = field.vlan_vid & 4095

	elif field.type == VLAN_PCP:
	shim = frame.getlayer(Dot1Q)
	shim.prio = field.vlan_pcp

	else:
	raise NotImplementedError('set_field.field.type=%d'
	% field.type)

	else:
	raise NotImplementedError('action.type=%d' % action.type)

	return egress_port, frame


	class PonSim(object):
	def __init__(self, onus, egress_fun, alarm_config):
	self.egress_fun = egress_fun

	self.log = structlog.get_logger()
	# Create OLT and hook NNI port up for egress
	self.olt = SimDevice('olt', 0)
	self.olt.link(2, lambda _, frame: self.egress_fun(0, frame))
	self.devices = dict()
	self.devices[0] = self.olt
	# TODO: This can be removed, it's for debugging purposes
	self.lc = LoopingCall(self.olt.counter.log_counts)
	self.lc.start(90) # To correlate with Kafka

	# Create ONUs of the requested number and hook them up with OLT
	# and with egress fun
	def mk_egress_fun(port_no):
	return lambda _, frame: self.egress_fun(port_no, frame)

	def mk_onu_ingress(onu):
	return lambda _, frame: onu.ingress(1, frame)

	for i in range(onus):
	port_no = 128 + i
	onu = SimDevice('onu%d' % i, port_no)
	onu.link(1, lambda _, frame: self.olt.ingress(1,
	frame)) # Send to the OLT
	onu.link(2,
	mk_egress_fun(port_no)) # Send from the ONU to the world
	self.olt.link(1, mk_onu_ingress(onu)) # Internal send to the ONU
	self.devices[port_no] = onu
	for d in self.devices:
	self.log.info("pon-sim-init", port=d, name=self.devices[d].name,
	links=self.devices[d].links)

	if alarm_config['simulation']:
	self.alarms = SimAlarms()
	self.alarms.start_simulation(self.olt, self.egress_fun, alarm_config)

	def get_ports(self):
	return sorted(self.devices.keys())

	def get_stats(self):
	return self.olt.counter.make_proto()

	def olt_install_flows(self, flows):
	self.olt.install_flows(flows)

	def onu_install_flows(self, onu_port, flows):
	self.devices[onu_port].install_flows(flows)

	def ingress(self, port, frame):
	if not isinstance(frame, Packet):
	frame = Ether(frame)
	self.devices[port].ingress(2, frame)

	class XPonSim(object):
	def __init__(self):
	self.log = structlog.get_logger()

	def CreateInterface(self, request):
	self.log.info("create-interface-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def UpdateInterface(self, request):
	self.log.info("update-interface-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def RemoveInterface(self, request):
	self.log.info("remove-interface-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def CreateTcont(self, request, request2):
	self.log.info("create-tcont-request",
	tcont_config_data=request,
	traffic_descriptor_profile_config_data=request2)
	return

	def UpdateTcont(self, request, request2):
	self.log.info("update-tcont-request",
	tcont_config_data=request,
	traffic_descriptor_profile_config_data=request2)
	return

	def RemoveTcont(self, request, request2):
	self.log.info("remove-tcont-request",
	tcont_config_data=request,
	traffic_descriptor_profile_config_data=request2)
	return

	def CreateGemport(self, request):
	self.log.info("create-gemport-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def UpdateGemport(self, request):
	self.log.info("update-gemport-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def RemoveGemport(self, request):
	self.log.info("remove-gemport-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def CreateMulticastGemport(self, request):
	self.log.info("create-multicast-gemport-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def UpdateMulticastGemport(self, request):
	self.log.info("update-multicast-gemport-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def RemoveMulticastGemport(self, request):
	self.log.info("remove-multicast-gemport-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def CreateMulticastDistributionSet(self, request):
	self.log.info("create-multicast-distribution-set-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def UpdateMulticastDistributionSet(self, request):
	self.log.info("update-multicast-distribution-set-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return

	def RemoveMulticastDistributionSet(self, request):
	self.log.info("remove-multicast-distribution-set-request",
	interface_type=request.WhichOneof("interface_type"),
	data=request)
	return