rw_core/flowdecomposition/flow_decomposer.go - voltha-go - Gitiles

 /*
  * Copyright 2018-present Open Networking Foundation
  *
  * 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.
  */

 package flowdecomposition

 import (
 	"github.com/gogo/protobuf/proto"
 	"github.com/opencord/voltha-go/rw_core/coreif"
 	"github.com/opencord/voltha-go/rw_core/graph"
 	fu "github.com/opencord/voltha-lib-go/v2/pkg/flows"
 	"github.com/opencord/voltha-lib-go/v2/pkg/log"
 	ofp "github.com/opencord/voltha-protos/v2/go/openflow_13"
 	"github.com/opencord/voltha-protos/v2/go/voltha"
 )

 func init() {
 	_, err := log.AddPackage(log.JSON, log.DebugLevel, nil)
 	if err != nil {
 		log.Errorw("unable-to-register-package-to-the-log-map", log.Fields{"error": err})
 	}
 }

 // FlowDecomposer represent flow decomposer attribute
 type FlowDecomposer struct {
 	deviceMgr coreif.DeviceManager
 }

 // NewFlowDecomposer creates flow decomposer instance
 func NewFlowDecomposer(deviceMgr coreif.DeviceManager) *FlowDecomposer {
 	var decomposer FlowDecomposer
 	decomposer.deviceMgr = deviceMgr
 	return &decomposer
 }

 //DecomposeRules decomposes per-device flows and flow-groups from the flows and groups defined on a logical device
 func (fd *FlowDecomposer) DecomposeRules(agent coreif.LogicalDeviceAgent, flows ofp.Flows, groups ofp.FlowGroups) *fu.DeviceRules {
 	deviceRules := *fu.NewDeviceRules()
 	devicesToUpdate := make(map[string]string)

 	groupMap := make(map[uint32]*ofp.OfpGroupEntry)
 	for _, groupEntry := range groups.Items {
 		groupMap[groupEntry.Desc.GroupId] = groupEntry
 	}

 	var decomposedRules *fu.DeviceRules
 	for _, flow := range flows.Items {
 		decomposedRules = fd.decomposeFlow(agent, flow, groupMap)
 		for deviceID, flowAndGroups := range decomposedRules.Rules {
 			deviceRules.CreateEntryIfNotExist(deviceID)
 			deviceRules.Rules[deviceID].AddFrom(flowAndGroups)
 			devicesToUpdate[deviceID] = deviceID
 		}
 	}
 	return deviceRules.FilterRules(devicesToUpdate)
 }

 // Handles special case of any controller-bound flow for a parent device
 func (fd *FlowDecomposer) updateOutputPortForControllerBoundFlowForParentDevide(flow *ofp.OfpFlowStats,
 	dr *fu.DeviceRules) *fu.DeviceRules {
 	EAPOL := fu.EthType(0x888e)
 	IGMP := fu.IpProto(2)
 	UDP := fu.IpProto(17)

 	newDeviceRules := dr.Copy()
 	//	Check whether we are dealing with a parent device
 	for deviceID, fg := range dr.GetRules() {
 		if root, _ := fd.deviceMgr.IsRootDevice(deviceID); root {
 			newDeviceRules.ClearFlows(deviceID)
 			for i := 0; i < fg.Flows.Len(); i++ {
 				f := fg.GetFlow(i)
 				UpdateOutPortNo := false
 				for _, field := range fu.GetOfbFields(f) {
 					UpdateOutPortNo = (field.String() == EAPOL.String())
 					UpdateOutPortNo = UpdateOutPortNo || (field.String() == IGMP.String())
 					UpdateOutPortNo = UpdateOutPortNo || (field.String() == UDP.String())
 					if UpdateOutPortNo {
 						break
 					}
 				}
 				if UpdateOutPortNo {
 					f = fu.UpdateOutputPortByActionType(f, uint32(ofp.OfpInstructionType_OFPIT_APPLY_ACTIONS),
 						uint32(ofp.OfpPortNo_OFPP_CONTROLLER))
 				}
 				// Update flow Id as a change in the instruction field will result in a new flow ID
 				f.Id = fu.HashFlowStats(f)
 				newDeviceRules.AddFlow(deviceID, (proto.Clone(f)).(*ofp.OfpFlowStats))
 			}
 		}
 	}

 	return newDeviceRules
 }

 //processControllerBoundFlow decomposes trap flows
 func (fd *FlowDecomposer) processControllerBoundFlow(agent coreif.LogicalDeviceAgent, route []graph.RouteHop,
 	inPortNo uint32, outPortNo uint32, flow *ofp.OfpFlowStats) *fu.DeviceRules {

 	log.Debugw("trap-flow", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo, "flow": flow})
 	deviceRules := fu.NewDeviceRules()
 	meterID := fu.GetMeterIdFromFlow(flow)
 	metadataFromwriteMetadata := fu.GetMetadataFromWriteMetadataAction(flow)

 	ingressHop := route[0]
 	egressHop := route[1]

 	//case of packet_in from NNI port rule
 	if agent.GetDeviceGraph().IsRootPort(inPortNo) {
 		// Trap flow for NNI port
 		log.Debug("trap-nni")

 		fa := &fu.FlowArgs{
 			KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie},
 			MatchFields: []*ofp.OfpOxmOfbField{
 				fu.InPort(egressHop.Egress),
 			},
 			Actions: fu.GetActions(flow),
 		}
 		// Augment the matchfields with the ofpfields from the flow
 		fg := fu.NewFlowsAndGroups()
 		fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)
 		fg.AddFlow(fu.MkFlowStat(fa))
 		deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fg)
 	} else {
 		// Trap flow for UNI port
 		log.Debug("trap-uni")

 		//inPortNo is 0 for wildcard input case, do not include upstream port for 4000 flow in input
 		var inPorts []uint32
 		if inPortNo == 0 {
 			inPorts = agent.GetWildcardInputPorts(egressHop.Egress) // exclude egress_hop.egress_port.port_no
 		} else {
 			inPorts = []uint32{inPortNo}
 		}
 		for _, inputPort := range inPorts {
 			// Upstream flow on parent (olt) device
 			faParent := &fu.FlowArgs{
 				KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
 				MatchFields: []*ofp.OfpOxmOfbField{
 					fu.InPort(egressHop.Ingress),
 					fu.TunnelId(uint64(inputPort)),
 				},
 				Actions: []*ofp.OfpAction{
 					fu.PushVlan(0x8100),
 					fu.SetField(fu.VlanVid(uint32(ofp.OfpVlanId_OFPVID_PRESENT) | 4000)),
 					fu.Output(egressHop.Egress),
 				},
 			}
 			// Augment the matchfields with the ofpfields from the flow
 			faParent.MatchFields = append(faParent.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)
 			fgParent := fu.NewFlowsAndGroups()
 			fgParent.AddFlow(fu.MkFlowStat(faParent))
 			deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fgParent)
 			log.Debugw("parent-trap-flow-set", log.Fields{"flow": faParent})

 			// Upstream flow on child (onu) device
 			var actions []*ofp.OfpAction
 			setvid := fu.GetVlanVid(flow)
 			if setvid != nil {
 				// have this child push the vlan the parent is matching/trapping on above
 				actions = []*ofp.OfpAction{
 					fu.PushVlan(0x8100),
 					fu.SetField(fu.VlanVid(*setvid)),
 					fu.Output(ingressHop.Egress),
 				}
 			} else {
 				// otherwise just set the egress port
 				actions = []*ofp.OfpAction{
 					fu.Output(ingressHop.Egress),
 				}
 			}
 			faChild := &fu.FlowArgs{
 				KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
 				MatchFields: []*ofp.OfpOxmOfbField{
 					fu.InPort(ingressHop.Ingress),
 					fu.TunnelId(uint64(inputPort)),
 				},
 				Actions: actions,
 			}
 			// Augment the matchfields with the ofpfields from the flow.
 			// If the parent has a match vid and the child is setting that match vid exclude the the match vlan
 			// for the child given it will be setting that vlan and the parent will be matching on it
 			if setvid != nil {
 				faChild.MatchFields = append(faChild.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT, fu.VLAN_VID)...)
 			} else {
 				faChild.MatchFields = append(faChild.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)
 			}
 			fgChild := fu.NewFlowsAndGroups()
 			fgChild.AddFlow(fu.MkFlowStat(faChild))
 			deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fgChild)
 			log.Debugw("child-trap-flow-set", log.Fields{"flow": faChild})
 		}
 	}

 	return deviceRules
 }

 // processUpstreamNonControllerBoundFlow processes non-controller bound flow. We assume that anything that is
 // upstream needs to get Q-in-Q treatment and that this is expressed via two flow rules, the first using the
 // goto-statement. We also assume that the inner tag is applied at the ONU, while the outer tag is
 // applied at the OLT
 func (fd *FlowDecomposer) processUpstreamNonControllerBoundFlow(agent coreif.LogicalDeviceAgent,
 	route []graph.RouteHop, inPortNo uint32, outPortNo uint32, flow *ofp.OfpFlowStats) *fu.DeviceRules {

 	log.Debugw("upstream-non-controller-bound-flow", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo})
 	deviceRules := fu.NewDeviceRules()

 	meterID := fu.GetMeterIdFromFlow(flow)
 	metadataFromwriteMetadata := fu.GetMetadataFromWriteMetadataAction(flow)

 	ingressHop := route[0]
 	egressHop := route[1]

 	if flow.TableId == 0 && fu.HasNextTable(flow) {
 		log.Debugw("decomposing-onu-flow-in-upstream-has-next-table", log.Fields{"table_id": flow.TableId})
 		if outPortNo != 0 {
 			log.Warnw("outPort-should-not-be-specified", log.Fields{"outPortNo": outPortNo})
 			return deviceRules
 		}
 		fa := &fu.FlowArgs{
 			KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
 			MatchFields: []*ofp.OfpOxmOfbField{
 				fu.InPort(ingressHop.Ingress),
 				fu.TunnelId(uint64(inPortNo)),
 			},
 			Actions: fu.GetActions(flow),
 		}
 		// Augment the matchfields with the ofpfields from the flow
 		fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

 		// Augment the Actions
 		fa.Actions = append(fa.Actions, fu.Output(ingressHop.Egress))

 		fg := fu.NewFlowsAndGroups()
 		fg.AddFlow(fu.MkFlowStat(fa))
 		deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fg)
 	} else if flow.TableId == 1 && outPortNo != 0 {
 		log.Debugw("decomposing-olt-flow-in-upstream-has-next-table", log.Fields{"table_id": flow.TableId})
 		fa := &fu.FlowArgs{
 			KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
 			MatchFields: []*ofp.OfpOxmOfbField{
 				fu.InPort(egressHop.Ingress),
 				fu.TunnelId(uint64(inPortNo)),
 			},
 		}
 		// Augment the matchfields with the ofpfields from the flow
 		fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

 		//Augment the actions
 		filteredAction := fu.GetActions(flow, fu.OUTPUT)
 		filteredAction = append(filteredAction, fu.Output(egressHop.Egress))
 		fa.Actions = filteredAction

 		fg := fu.NewFlowsAndGroups()
 		fg.AddFlow(fu.MkFlowStat(fa))
 		deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fg)
 	}
 	return deviceRules
 }

 // processDownstreamFlowWithNextTable decomposes downstream flows containing next table ID instructions
 func (fd *FlowDecomposer) processDownstreamFlowWithNextTable(agent coreif.LogicalDeviceAgent, route []graph.RouteHop,
 	inPortNo uint32, outPortNo uint32, flow *ofp.OfpFlowStats) *fu.DeviceRules {
 	log.Debugw("decomposing-olt-flow-in-downstream-flow-with-next-table", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo})
 	deviceRules := fu.NewDeviceRules()
 	meterID := fu.GetMeterIdFromFlow(flow)
 	metadataFromwriteMetadata := fu.GetMetadataFromWriteMetadataAction(flow)

 	if outPortNo != 0 {
 		log.Warnw("outPort-should-not-be-specified", log.Fields{"outPortNo": outPortNo})
 		return deviceRules
 	}

 	if flow.TableId != 0 {
 		log.Warnw("This is not olt pipeline table, so skipping", log.Fields{"tableId": flow.TableId})
 		return deviceRules
 	}

 	ingressHop := route[0]
 	egressHop := route[1]
 	if metadataFromwriteMetadata != 0 {
 		log.Debugw("creating-metadata-flow", log.Fields{"flow": flow})
 		portNumber := fu.GetEgressPortNumberFromWriteMetadata(flow)
 		if portNumber != 0 {
 			recalculatedRoute := agent.GetRoute(inPortNo, portNumber)
 			switch len(recalculatedRoute) {
 			case 0:
 				log.Errorw("no-route-double-tag", log.Fields{"inPortNo": inPortNo, "outPortNo": portNumber, "comment": "deleting-flow", "metadata": metadataFromwriteMetadata})
 				//TODO: Delete flow
 				return deviceRules
 			case 2:
 				log.Debugw("route-found", log.Fields{"ingressHop": ingressHop, "egressHop": egressHop})
 			default:
 				log.Errorw("invalid-route-length", log.Fields{"routeLen": len(route)})
 				return deviceRules
 			}
 			ingressHop = recalculatedRoute[0]
 		}
 		innerTag := fu.GetInnerTagFromMetaData(flow)
 		if innerTag == 0 {
 			log.Errorw("no-inner-route-double-tag", log.Fields{"inPortNo": inPortNo, "outPortNo": portNumber, "comment": "deleting-flow", "metadata": metadataFromwriteMetadata})
 			//TODO: Delete flow
 			return deviceRules
 		}
 		fa := &fu.FlowArgs{
 			KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
 			MatchFields: []*ofp.OfpOxmOfbField{
 				fu.InPort(ingressHop.Ingress),
 				fu.Metadata_ofp(uint64(innerTag)),
 				fu.TunnelId(uint64(portNumber)),
 			},
 			Actions: fu.GetActions(flow),
 		}
 		// Augment the matchfields with the ofpfields from the flow
 		fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT, fu.METADATA)...)

 		// Augment the Actions
 		fa.Actions = append(fa.Actions, fu.Output(ingressHop.Egress))

 		fg := fu.NewFlowsAndGroups()
 		fg.AddFlow(fu.MkFlowStat(fa))
 		deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fg)
 	} else { // Create standard flow
 		log.Debugw("creating-standard-flow", log.Fields{"flow": flow})
 		fa := &fu.FlowArgs{
 			KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
 			MatchFields: []*ofp.OfpOxmOfbField{
 				fu.InPort(ingressHop.Ingress),
 				fu.TunnelId(uint64(inPortNo)),
 			},
 			Actions: fu.GetActions(flow),
 		}
 		// Augment the matchfields with the ofpfields from the flow
 		fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

 		// Augment the Actions
 		fa.Actions = append(fa.Actions, fu.Output(ingressHop.Egress))

 		fg := fu.NewFlowsAndGroups()
 		fg.AddFlow(fu.MkFlowStat(fa))
 		deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fg)
 	}

 	return deviceRules
 }

 // processUnicastFlow decomposes unicast flows
 func (fd *FlowDecomposer) processUnicastFlow(agent coreif.LogicalDeviceAgent, route []graph.RouteHop,
 	inPortNo uint32, outPortNo uint32, flow *ofp.OfpFlowStats) *fu.DeviceRules {

 	log.Debugw("decomposing-onu-flow-in-downstream-unicast-flow", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo})
 	deviceRules := fu.NewDeviceRules()

 	egressHop := route[1]

 	meterID := fu.GetMeterIdFromFlow(flow)
 	metadataFromwriteMetadata := fu.GetMetadataFromWriteMetadataAction(flow)
 	fa := &fu.FlowArgs{
 		KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
 		MatchFields: []*ofp.OfpOxmOfbField{
 			fu.InPort(egressHop.Ingress),
 		},
 	}
 	// Augment the matchfields with the ofpfields from the flow
 	fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

 	// Augment the Actions
 	filteredAction := fu.GetActions(flow, fu.OUTPUT)
 	filteredAction = append(filteredAction, fu.Output(egressHop.Egress))
 	fa.Actions = filteredAction

 	fg := fu.NewFlowsAndGroups()
 	fg.AddFlow(fu.MkFlowStat(fa))
 	deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fg)
 	return deviceRules
 }

 // processMulticastFlow decompose multicast flows
 func (fd *FlowDecomposer) processMulticastFlow(agent coreif.LogicalDeviceAgent, route []graph.RouteHop,
 	inPortNo uint32, outPortNo uint32, flow *ofp.OfpFlowStats, grpID uint32,
 	groupMap map[uint32]*ofp.OfpGroupEntry) *fu.DeviceRules {

 	log.Debugw("multicast-flow", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo})
 	deviceRules := fu.NewDeviceRules()

 	//having no Group yet is the same as having a Group with no buckets
 	var grp *ofp.OfpGroupEntry
 	var ok bool
 	if grp, ok = groupMap[grpID]; !ok {
 		log.Warnw("Group-id-not-present-in-map", log.Fields{"grpId": grpID, "groupMap": groupMap})
 		return deviceRules
 	}
 	if grp == nil || grp.Desc == nil {
 		log.Warnw("Group-or-desc-nil", log.Fields{"grpId": grpID, "grp": grp})
 		return deviceRules
 	}
 	for _, bucket := range grp.Desc.Buckets {
 		otherActions := make([]*ofp.OfpAction, 0)
 		for _, action := range bucket.Actions {
 			if action.Type == fu.OUTPUT {
 				outPortNo = action.GetOutput().Port
 			} else if action.Type != fu.POP_VLAN {
 				otherActions = append(otherActions, action)
 			}
 		}

 		route2 := agent.GetRoute(inPortNo, outPortNo)
 		switch len(route2) {
 		case 0:
 			log.Errorw("mc-no-route", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo, "comment": "deleting flow"})
 			//	TODO: Delete flow
 			return deviceRules
 		case 2:
 			log.Debugw("route-found", log.Fields{"ingressHop": route2[0], "egressHop": route2[1]})
 		default:
 			log.Errorw("invalid-route-length", log.Fields{"routeLen": len(route)})
 			return deviceRules
 		}

 		ingressHop := route[0]
 		ingressHop2 := route2[0]
 		egressHop := route2[1]

 		if ingressHop.Ingress != ingressHop2.Ingress {
 			log.Errorw("mc-ingress-hop-hop2-mismatch", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo, "comment": "ignoring flow"})
 			return deviceRules
 		}
 		// Set the parent device flow
 		fa := &fu.FlowArgs{
 			KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie},
 			MatchFields: []*ofp.OfpOxmOfbField{
 				fu.InPort(ingressHop.Ingress),
 			},
 		}
 		// Augment the matchfields with the ofpfields from the flow
 		fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

 		// Augment the Actions
 		filteredAction := fu.GetActions(flow, fu.GROUP)
 		filteredAction = append(filteredAction, fu.PopVlan())
 		filteredAction = append(filteredAction, fu.Output(route2[1].Ingress))
 		fa.Actions = filteredAction

 		fg := fu.NewFlowsAndGroups()
 		fg.AddFlow(fu.MkFlowStat(fa))
 		deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fg)

 		// Set the child device flow
 		fa = &fu.FlowArgs{
 			KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie},
 			MatchFields: []*ofp.OfpOxmOfbField{
 				fu.InPort(egressHop.Ingress),
 			},
 		}
 		// Augment the matchfields with the ofpfields from the flow
 		fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT, fu.VLAN_VID, fu.VLAN_PCP)...)

 		// Augment the Actions
 		otherActions = append(otherActions, fu.Output(egressHop.Egress))
 		fa.Actions = otherActions

 		fg = fu.NewFlowsAndGroups()
 		fg.AddFlow(fu.MkFlowStat(fa))
 		deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fg)
 	}
 	return deviceRules
 }

 // decomposeFlow decomposes a flow for a logical device into flows for each physical device
 func (fd *FlowDecomposer) decomposeFlow(agent coreif.LogicalDeviceAgent, flow *ofp.OfpFlowStats,
 	groupMap map[uint32]*ofp.OfpGroupEntry) *fu.DeviceRules {

 	inPortNo := fu.GetInPort(flow)
 	outPortNo := fu.GetOutPort(flow)
 	deviceRules := fu.NewDeviceRules()
 	route := agent.GetRoute(inPortNo, outPortNo)

 	switch len(route) {
 	case 0:
 		log.Errorw("no-route", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo, "comment": "deleting-flow"})
 		//	TODO: Delete flow
 		return deviceRules
 	case 2:
 		log.Debugw("route-found", log.Fields{"ingressHop": route[0], "egressHop": route[1]})
 	default:
 		log.Errorw("invalid-route-length", log.Fields{"routeLen": len(route)})
 		return deviceRules
 	}

 	// Process controller bound flow
 	if outPortNo != 0 && (outPortNo&0x7fffffff) == uint32(ofp.OfpPortNo_OFPP_CONTROLLER) {
 		deviceRules = fd.processControllerBoundFlow(agent, route, inPortNo, outPortNo, flow)
 	} else {
 		var ingressDevice *voltha.Device
 		var err error
 		if ingressDevice, err = fd.deviceMgr.GetDevice(route[0].DeviceID); err != nil {
 			log.Errorw("ingress-device-not-found", log.Fields{"deviceId": route[0].DeviceID, "flow": flow})
 			return deviceRules
 		}
 		isUpstream := !ingressDevice.Root
 		if isUpstream { // Unicast OLT and ONU UL
 			log.Info("processOltAndOnuUpstreamNonControllerBoundUnicastFlows", log.Fields{"flows": flow})
 			deviceRules = fd.processUpstreamNonControllerBoundFlow(agent, route, inPortNo, outPortNo, flow)
 		} else if fu.HasNextTable(flow) && flow.TableId == 0 { // Unicast OLT flow DL
 			log.Debugw("processOltDownstreamNonControllerBoundFlowWithNextTable", log.Fields{"flows": flow})
 			deviceRules = fd.processDownstreamFlowWithNextTable(agent, route, inPortNo, outPortNo, flow)
 		} else if flow.TableId == 1 && outPortNo != 0 { // Unicast ONU flow DL
 			log.Debugw("processOnuDownstreamUnicastFlow", log.Fields{"flows": flow})
 			deviceRules = fd.processUnicastFlow(agent, route, inPortNo, outPortNo, flow)
 		} else if grpID := fu.GetGroup(flow); grpID != 0 && flow.TableId == 0 { //Multicast
 			log.Debugw("processMulticastFlow", log.Fields{"flows": flow})
 			deviceRules = fd.processMulticastFlow(agent, route, inPortNo, outPortNo, flow, grpID, groupMap)
 		} else {
 			log.Errorw("unknown-downstream-flow", log.Fields{"flow": *flow})
 		}
 	}
 	deviceRules = fd.updateOutputPortForControllerBoundFlowForParentDevide(flow, deviceRules)
 	return deviceRules
 }
	/*
	* Copyright 2018-present Open Networking Foundation
	*
	* 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.
	*/

	package flowdecomposition

	import (
	"github.com/gogo/protobuf/proto"
	"github.com/opencord/voltha-go/rw_core/coreif"
	"github.com/opencord/voltha-go/rw_core/graph"
	fu "github.com/opencord/voltha-lib-go/v2/pkg/flows"
	"github.com/opencord/voltha-lib-go/v2/pkg/log"
	ofp "github.com/opencord/voltha-protos/v2/go/openflow_13"
	"github.com/opencord/voltha-protos/v2/go/voltha"
	)

	func init() {
	_, err := log.AddPackage(log.JSON, log.DebugLevel, nil)
	if err != nil {
	log.Errorw("unable-to-register-package-to-the-log-map", log.Fields{"error": err})
	}
	}

	// FlowDecomposer represent flow decomposer attribute
	type FlowDecomposer struct {
	deviceMgr coreif.DeviceManager
	}

	// NewFlowDecomposer creates flow decomposer instance
	func NewFlowDecomposer(deviceMgr coreif.DeviceManager) *FlowDecomposer {
	var decomposer FlowDecomposer
	decomposer.deviceMgr = deviceMgr
	return &decomposer
	}

	//DecomposeRules decomposes per-device flows and flow-groups from the flows and groups defined on a logical device
	func (fd FlowDecomposer) DecomposeRules(agent coreif.LogicalDeviceAgent, flows ofp.Flows, groups ofp.FlowGroups) fu.DeviceRules {
	deviceRules := *fu.NewDeviceRules()
	devicesToUpdate := make(map[string]string)

	groupMap := make(map[uint32]*ofp.OfpGroupEntry)
	for _, groupEntry := range groups.Items {
	groupMap[groupEntry.Desc.GroupId] = groupEntry
	}

	var decomposedRules *fu.DeviceRules
	for _, flow := range flows.Items {
	decomposedRules = fd.decomposeFlow(agent, flow, groupMap)
	for deviceID, flowAndGroups := range decomposedRules.Rules {
	deviceRules.CreateEntryIfNotExist(deviceID)
	deviceRules.Rules[deviceID].AddFrom(flowAndGroups)
	devicesToUpdate[deviceID] = deviceID
	}
	}
	return deviceRules.FilterRules(devicesToUpdate)
	}

	// Handles special case of any controller-bound flow for a parent device
	func (fd FlowDecomposer) updateOutputPortForControllerBoundFlowForParentDevide(flow ofp.OfpFlowStats,
	dr fu.DeviceRules) fu.DeviceRules {
	EAPOL := fu.EthType(0x888e)
	IGMP := fu.IpProto(2)
	UDP := fu.IpProto(17)

	newDeviceRules := dr.Copy()
	// Check whether we are dealing with a parent device
	for deviceID, fg := range dr.GetRules() {
	if root, _ := fd.deviceMgr.IsRootDevice(deviceID); root {
	newDeviceRules.ClearFlows(deviceID)
	for i := 0; i < fg.Flows.Len(); i++ {
	f := fg.GetFlow(i)
	UpdateOutPortNo := false
	for _, field := range fu.GetOfbFields(f) {
	UpdateOutPortNo = (field.String() == EAPOL.String())
	UpdateOutPortNo = UpdateOutPortNo \|\| (field.String() == IGMP.String())
	UpdateOutPortNo = UpdateOutPortNo \|\| (field.String() == UDP.String())
	if UpdateOutPortNo {
	break
	}
	}
	if UpdateOutPortNo {
	f = fu.UpdateOutputPortByActionType(f, uint32(ofp.OfpInstructionType_OFPIT_APPLY_ACTIONS),
	uint32(ofp.OfpPortNo_OFPP_CONTROLLER))
	}
	// Update flow Id as a change in the instruction field will result in a new flow ID
	f.Id = fu.HashFlowStats(f)
	newDeviceRules.AddFlow(deviceID, (proto.Clone(f)).(*ofp.OfpFlowStats))
	}
	}
	}

	return newDeviceRules
	}

	//processControllerBoundFlow decomposes trap flows
	func (fd *FlowDecomposer) processControllerBoundFlow(agent coreif.LogicalDeviceAgent, route []graph.RouteHop,
	inPortNo uint32, outPortNo uint32, flow ofp.OfpFlowStats) fu.DeviceRules {

	log.Debugw("trap-flow", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo, "flow": flow})
	deviceRules := fu.NewDeviceRules()
	meterID := fu.GetMeterIdFromFlow(flow)
	metadataFromwriteMetadata := fu.GetMetadataFromWriteMetadataAction(flow)

	ingressHop := route[0]
	egressHop := route[1]

	//case of packet_in from NNI port rule
	if agent.GetDeviceGraph().IsRootPort(inPortNo) {
	// Trap flow for NNI port
	log.Debug("trap-nni")

	fa := &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(egressHop.Egress),
	},
	Actions: fu.GetActions(flow),
	}
	// Augment the matchfields with the ofpfields from the flow
	fg := fu.NewFlowsAndGroups()
	fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)
	fg.AddFlow(fu.MkFlowStat(fa))
	deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fg)
	} else {
	// Trap flow for UNI port
	log.Debug("trap-uni")

	//inPortNo is 0 for wildcard input case, do not include upstream port for 4000 flow in input
	var inPorts []uint32
	if inPortNo == 0 {
	inPorts = agent.GetWildcardInputPorts(egressHop.Egress) // exclude egress_hop.egress_port.port_no
	} else {
	inPorts = []uint32{inPortNo}
	}
	for _, inputPort := range inPorts {
	// Upstream flow on parent (olt) device
	faParent := &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(egressHop.Ingress),
	fu.TunnelId(uint64(inputPort)),
	},
	Actions: []*ofp.OfpAction{
	fu.PushVlan(0x8100),
	fu.SetField(fu.VlanVid(uint32(ofp.OfpVlanId_OFPVID_PRESENT) \| 4000)),
	fu.Output(egressHop.Egress),
	},
	}
	// Augment the matchfields with the ofpfields from the flow
	faParent.MatchFields = append(faParent.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)
	fgParent := fu.NewFlowsAndGroups()
	fgParent.AddFlow(fu.MkFlowStat(faParent))
	deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fgParent)
	log.Debugw("parent-trap-flow-set", log.Fields{"flow": faParent})

	// Upstream flow on child (onu) device
	var actions []*ofp.OfpAction
	setvid := fu.GetVlanVid(flow)
	if setvid != nil {
	// have this child push the vlan the parent is matching/trapping on above
	actions = []*ofp.OfpAction{
	fu.PushVlan(0x8100),
	fu.SetField(fu.VlanVid(*setvid)),
	fu.Output(ingressHop.Egress),
	}
	} else {
	// otherwise just set the egress port
	actions = []*ofp.OfpAction{
	fu.Output(ingressHop.Egress),
	}
	}
	faChild := &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(ingressHop.Ingress),
	fu.TunnelId(uint64(inputPort)),
	},
	Actions: actions,
	}
	// Augment the matchfields with the ofpfields from the flow.
	// If the parent has a match vid and the child is setting that match vid exclude the the match vlan
	// for the child given it will be setting that vlan and the parent will be matching on it
	if setvid != nil {
	faChild.MatchFields = append(faChild.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT, fu.VLAN_VID)...)
	} else {
	faChild.MatchFields = append(faChild.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)
	}
	fgChild := fu.NewFlowsAndGroups()
	fgChild.AddFlow(fu.MkFlowStat(faChild))
	deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fgChild)
	log.Debugw("child-trap-flow-set", log.Fields{"flow": faChild})
	}
	}

	return deviceRules
	}

	// processUpstreamNonControllerBoundFlow processes non-controller bound flow. We assume that anything that is
	// upstream needs to get Q-in-Q treatment and that this is expressed via two flow rules, the first using the
	// goto-statement. We also assume that the inner tag is applied at the ONU, while the outer tag is
	// applied at the OLT
	func (fd *FlowDecomposer) processUpstreamNonControllerBoundFlow(agent coreif.LogicalDeviceAgent,
	route []graph.RouteHop, inPortNo uint32, outPortNo uint32, flow ofp.OfpFlowStats) fu.DeviceRules {

	log.Debugw("upstream-non-controller-bound-flow", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo})
	deviceRules := fu.NewDeviceRules()

	meterID := fu.GetMeterIdFromFlow(flow)
	metadataFromwriteMetadata := fu.GetMetadataFromWriteMetadataAction(flow)

	ingressHop := route[0]
	egressHop := route[1]

	if flow.TableId == 0 && fu.HasNextTable(flow) {
	log.Debugw("decomposing-onu-flow-in-upstream-has-next-table", log.Fields{"table_id": flow.TableId})
	if outPortNo != 0 {
	log.Warnw("outPort-should-not-be-specified", log.Fields{"outPortNo": outPortNo})
	return deviceRules
	}
	fa := &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(ingressHop.Ingress),
	fu.TunnelId(uint64(inPortNo)),
	},
	Actions: fu.GetActions(flow),
	}
	// Augment the matchfields with the ofpfields from the flow
	fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

	// Augment the Actions
	fa.Actions = append(fa.Actions, fu.Output(ingressHop.Egress))

	fg := fu.NewFlowsAndGroups()
	fg.AddFlow(fu.MkFlowStat(fa))
	deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fg)
	} else if flow.TableId == 1 && outPortNo != 0 {
	log.Debugw("decomposing-olt-flow-in-upstream-has-next-table", log.Fields{"table_id": flow.TableId})
	fa := &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(egressHop.Ingress),
	fu.TunnelId(uint64(inPortNo)),
	},
	}
	// Augment the matchfields with the ofpfields from the flow
	fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

	//Augment the actions
	filteredAction := fu.GetActions(flow, fu.OUTPUT)
	filteredAction = append(filteredAction, fu.Output(egressHop.Egress))
	fa.Actions = filteredAction

	fg := fu.NewFlowsAndGroups()
	fg.AddFlow(fu.MkFlowStat(fa))
	deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fg)
	}
	return deviceRules
	}

	// processDownstreamFlowWithNextTable decomposes downstream flows containing next table ID instructions
	func (fd *FlowDecomposer) processDownstreamFlowWithNextTable(agent coreif.LogicalDeviceAgent, route []graph.RouteHop,
	inPortNo uint32, outPortNo uint32, flow ofp.OfpFlowStats) fu.DeviceRules {
	log.Debugw("decomposing-olt-flow-in-downstream-flow-with-next-table", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo})
	deviceRules := fu.NewDeviceRules()
	meterID := fu.GetMeterIdFromFlow(flow)
	metadataFromwriteMetadata := fu.GetMetadataFromWriteMetadataAction(flow)

	if outPortNo != 0 {
	log.Warnw("outPort-should-not-be-specified", log.Fields{"outPortNo": outPortNo})
	return deviceRules
	}

	if flow.TableId != 0 {
	log.Warnw("This is not olt pipeline table, so skipping", log.Fields{"tableId": flow.TableId})
	return deviceRules
	}

	ingressHop := route[0]
	egressHop := route[1]
	if metadataFromwriteMetadata != 0 {
	log.Debugw("creating-metadata-flow", log.Fields{"flow": flow})
	portNumber := fu.GetEgressPortNumberFromWriteMetadata(flow)
	if portNumber != 0 {
	recalculatedRoute := agent.GetRoute(inPortNo, portNumber)
	switch len(recalculatedRoute) {
	case 0:
	log.Errorw("no-route-double-tag", log.Fields{"inPortNo": inPortNo, "outPortNo": portNumber, "comment": "deleting-flow", "metadata": metadataFromwriteMetadata})
	//TODO: Delete flow
	return deviceRules
	case 2:
	log.Debugw("route-found", log.Fields{"ingressHop": ingressHop, "egressHop": egressHop})
	default:
	log.Errorw("invalid-route-length", log.Fields{"routeLen": len(route)})
	return deviceRules
	}
	ingressHop = recalculatedRoute[0]
	}
	innerTag := fu.GetInnerTagFromMetaData(flow)
	if innerTag == 0 {
	log.Errorw("no-inner-route-double-tag", log.Fields{"inPortNo": inPortNo, "outPortNo": portNumber, "comment": "deleting-flow", "metadata": metadataFromwriteMetadata})
	//TODO: Delete flow
	return deviceRules
	}
	fa := &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(ingressHop.Ingress),
	fu.Metadata_ofp(uint64(innerTag)),
	fu.TunnelId(uint64(portNumber)),
	},
	Actions: fu.GetActions(flow),
	}
	// Augment the matchfields with the ofpfields from the flow
	fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT, fu.METADATA)...)

	// Augment the Actions
	fa.Actions = append(fa.Actions, fu.Output(ingressHop.Egress))

	fg := fu.NewFlowsAndGroups()
	fg.AddFlow(fu.MkFlowStat(fa))
	deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fg)
	} else { // Create standard flow
	log.Debugw("creating-standard-flow", log.Fields{"flow": flow})
	fa := &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(ingressHop.Ingress),
	fu.TunnelId(uint64(inPortNo)),
	},
	Actions: fu.GetActions(flow),
	}
	// Augment the matchfields with the ofpfields from the flow
	fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

	// Augment the Actions
	fa.Actions = append(fa.Actions, fu.Output(ingressHop.Egress))

	fg := fu.NewFlowsAndGroups()
	fg.AddFlow(fu.MkFlowStat(fa))
	deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fg)
	}

	return deviceRules
	}

	// processUnicastFlow decomposes unicast flows
	func (fd *FlowDecomposer) processUnicastFlow(agent coreif.LogicalDeviceAgent, route []graph.RouteHop,
	inPortNo uint32, outPortNo uint32, flow ofp.OfpFlowStats) fu.DeviceRules {

	log.Debugw("decomposing-onu-flow-in-downstream-unicast-flow", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo})
	deviceRules := fu.NewDeviceRules()

	egressHop := route[1]

	meterID := fu.GetMeterIdFromFlow(flow)
	metadataFromwriteMetadata := fu.GetMetadataFromWriteMetadataAction(flow)
	fa := &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie, "meter_id": uint64(meterID), "write_metadata": metadataFromwriteMetadata},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(egressHop.Ingress),
	},
	}
	// Augment the matchfields with the ofpfields from the flow
	fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

	// Augment the Actions
	filteredAction := fu.GetActions(flow, fu.OUTPUT)
	filteredAction = append(filteredAction, fu.Output(egressHop.Egress))
	fa.Actions = filteredAction

	fg := fu.NewFlowsAndGroups()
	fg.AddFlow(fu.MkFlowStat(fa))
	deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fg)
	return deviceRules
	}

	// processMulticastFlow decompose multicast flows
	func (fd *FlowDecomposer) processMulticastFlow(agent coreif.LogicalDeviceAgent, route []graph.RouteHop,
	inPortNo uint32, outPortNo uint32, flow *ofp.OfpFlowStats, grpID uint32,
	groupMap map[uint32]ofp.OfpGroupEntry) fu.DeviceRules {

	log.Debugw("multicast-flow", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo})
	deviceRules := fu.NewDeviceRules()

	//having no Group yet is the same as having a Group with no buckets
	var grp *ofp.OfpGroupEntry
	var ok bool
	if grp, ok = groupMap[grpID]; !ok {
	log.Warnw("Group-id-not-present-in-map", log.Fields{"grpId": grpID, "groupMap": groupMap})
	return deviceRules
	}
	if grp == nil \|\| grp.Desc == nil {
	log.Warnw("Group-or-desc-nil", log.Fields{"grpId": grpID, "grp": grp})
	return deviceRules
	}
	for _, bucket := range grp.Desc.Buckets {
	otherActions := make([]*ofp.OfpAction, 0)
	for _, action := range bucket.Actions {
	if action.Type == fu.OUTPUT {
	outPortNo = action.GetOutput().Port
	} else if action.Type != fu.POP_VLAN {
	otherActions = append(otherActions, action)
	}
	}

	route2 := agent.GetRoute(inPortNo, outPortNo)
	switch len(route2) {
	case 0:
	log.Errorw("mc-no-route", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo, "comment": "deleting flow"})
	// TODO: Delete flow
	return deviceRules
	case 2:
	log.Debugw("route-found", log.Fields{"ingressHop": route2[0], "egressHop": route2[1]})
	default:
	log.Errorw("invalid-route-length", log.Fields{"routeLen": len(route)})
	return deviceRules
	}

	ingressHop := route[0]
	ingressHop2 := route2[0]
	egressHop := route2[1]

	if ingressHop.Ingress != ingressHop2.Ingress {
	log.Errorw("mc-ingress-hop-hop2-mismatch", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo, "comment": "ignoring flow"})
	return deviceRules
	}
	// Set the parent device flow
	fa := &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(ingressHop.Ingress),
	},
	}
	// Augment the matchfields with the ofpfields from the flow
	fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT)...)

	// Augment the Actions
	filteredAction := fu.GetActions(flow, fu.GROUP)
	filteredAction = append(filteredAction, fu.PopVlan())
	filteredAction = append(filteredAction, fu.Output(route2[1].Ingress))
	fa.Actions = filteredAction

	fg := fu.NewFlowsAndGroups()
	fg.AddFlow(fu.MkFlowStat(fa))
	deviceRules.AddFlowsAndGroup(ingressHop.DeviceID, fg)

	// Set the child device flow
	fa = &fu.FlowArgs{
	KV: fu.OfpFlowModArgs{"priority": uint64(flow.Priority), "cookie": flow.Cookie},
	MatchFields: []*ofp.OfpOxmOfbField{
	fu.InPort(egressHop.Ingress),
	},
	}
	// Augment the matchfields with the ofpfields from the flow
	fa.MatchFields = append(fa.MatchFields, fu.GetOfbFields(flow, fu.IN_PORT, fu.VLAN_VID, fu.VLAN_PCP)...)

	// Augment the Actions
	otherActions = append(otherActions, fu.Output(egressHop.Egress))
	fa.Actions = otherActions

	fg = fu.NewFlowsAndGroups()
	fg.AddFlow(fu.MkFlowStat(fa))
	deviceRules.AddFlowsAndGroup(egressHop.DeviceID, fg)
	}
	return deviceRules
	}

	// decomposeFlow decomposes a flow for a logical device into flows for each physical device
	func (fd FlowDecomposer) decomposeFlow(agent coreif.LogicalDeviceAgent, flow ofp.OfpFlowStats,
	groupMap map[uint32]ofp.OfpGroupEntry) fu.DeviceRules {

	inPortNo := fu.GetInPort(flow)
	outPortNo := fu.GetOutPort(flow)
	deviceRules := fu.NewDeviceRules()
	route := agent.GetRoute(inPortNo, outPortNo)

	switch len(route) {
	case 0:
	log.Errorw("no-route", log.Fields{"inPortNo": inPortNo, "outPortNo": outPortNo, "comment": "deleting-flow"})
	// TODO: Delete flow
	return deviceRules
	case 2:
	log.Debugw("route-found", log.Fields{"ingressHop": route[0], "egressHop": route[1]})
	default:
	log.Errorw("invalid-route-length", log.Fields{"routeLen": len(route)})
	return deviceRules
	}

	// Process controller bound flow
	if outPortNo != 0 && (outPortNo&0x7fffffff) == uint32(ofp.OfpPortNo_OFPP_CONTROLLER) {
	deviceRules = fd.processControllerBoundFlow(agent, route, inPortNo, outPortNo, flow)
	} else {
	var ingressDevice *voltha.Device
	var err error
	if ingressDevice, err = fd.deviceMgr.GetDevice(route[0].DeviceID); err != nil {
	log.Errorw("ingress-device-not-found", log.Fields{"deviceId": route[0].DeviceID, "flow": flow})
	return deviceRules
	}
	isUpstream := !ingressDevice.Root
	if isUpstream { // Unicast OLT and ONU UL
	log.Info("processOltAndOnuUpstreamNonControllerBoundUnicastFlows", log.Fields{"flows": flow})
	deviceRules = fd.processUpstreamNonControllerBoundFlow(agent, route, inPortNo, outPortNo, flow)
	} else if fu.HasNextTable(flow) && flow.TableId == 0 { // Unicast OLT flow DL
	log.Debugw("processOltDownstreamNonControllerBoundFlowWithNextTable", log.Fields{"flows": flow})
	deviceRules = fd.processDownstreamFlowWithNextTable(agent, route, inPortNo, outPortNo, flow)
	} else if flow.TableId == 1 && outPortNo != 0 { // Unicast ONU flow DL
	log.Debugw("processOnuDownstreamUnicastFlow", log.Fields{"flows": flow})
	deviceRules = fd.processUnicastFlow(agent, route, inPortNo, outPortNo, flow)
	} else if grpID := fu.GetGroup(flow); grpID != 0 && flow.TableId == 0 { //Multicast
	log.Debugw("processMulticastFlow", log.Fields{"flows": flow})
	deviceRules = fd.processMulticastFlow(agent, route, inPortNo, outPortNo, flow, grpID, groupMap)
	} else {
	log.Errorw("unknown-downstream-flow", log.Fields{"flow": *flow})
	}
	}
	deviceRules = fd.updateOutputPortForControllerBoundFlowForParentDevide(flow, deviceRules)
	return deviceRules
	}