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gerrit.opencord.org / voltha-openonu-adapter-go / 3af1f032acfa49a8d6639d0b760fdd53bbdc2233 / . / internal / pkg / onuadaptercore / device_handler.go
blob: 44a5b6a54788273b2da24f5f42b63ce620c975fa [file] [log] [blame]
/*
* Copyright 2020-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 adaptercoreonu provides the utility for onu devices, flows and statistics
package adaptercoreonu
import (
"context"
"encoding/hex"
"errors"
"fmt"
"strconv"
"strings"
"sync"
"time"
"github.com/gogo/protobuf/proto"
"github.com/golang/protobuf/ptypes"
"github.com/looplab/fsm"
me "github.com/opencord/omci-lib-go/generated"
"github.com/opencord/voltha-lib-go/v3/pkg/adapters/adapterif"
"github.com/opencord/voltha-lib-go/v3/pkg/log"
vc "github.com/opencord/voltha-protos/v3/go/common"
ic "github.com/opencord/voltha-protos/v3/go/inter_container"
of "github.com/opencord/voltha-protos/v3/go/openflow_13"
oop "github.com/opencord/voltha-protos/v3/go/openolt"
"github.com/opencord/voltha-protos/v3/go/voltha"
)
/*
// Constants for number of retries and for timeout
const (
MaxRetry = 10
MaxTimeOutInMs = 500
)
*/
//Event category and subcategory definitions - same as defiend for OLT in eventmgr.go - should be done more centrally
const (
pon = voltha.EventSubCategory_PON
olt = voltha.EventSubCategory_OLT
ont = voltha.EventSubCategory_ONT
onu = voltha.EventSubCategory_ONU
nni = voltha.EventSubCategory_NNI
service = voltha.EventCategory_SERVICE
security = voltha.EventCategory_SECURITY
equipment = voltha.EventCategory_EQUIPMENT
processing = voltha.EventCategory_PROCESSING
environment = voltha.EventCategory_ENVIRONMENT
communication = voltha.EventCategory_COMMUNICATION
)
const (
cEventObjectType = "ONU"
)
const (
cOnuActivatedEvent = "ONU_ACTIVATED"
)
//DeviceHandler will interact with the ONU ? device.
type DeviceHandler struct {
deviceID string
DeviceType string
adminState string
device *voltha.Device
logicalDeviceID string
ProxyAddressID string
ProxyAddressType string
parentId string
ponPortNumber uint32
coreProxy adapterif.CoreProxy
AdapterProxy adapterif.AdapterProxy
EventProxy adapterif.EventProxy
pOpenOnuAc *OpenONUAC
pDeviceStateFsm *fsm.FSM
pPonPort *voltha.Port
deviceEntrySet chan bool //channel for DeviceEntry set event
pOnuOmciDevice *OnuDeviceEntry
exitChannel chan int
lockDevice sync.RWMutex
pOnuIndication *oop.OnuIndication
deviceReason string
pLockStateFsm *LockStateFsm
pUnlockStateFsm *LockStateFsm
//flowMgr *OpenOltFlowMgr
//eventMgr *OpenOltEventMgr
//resourceMgr *rsrcMgr.OpenOltResourceMgr
//discOnus sync.Map
//onus sync.Map
//portStats *OpenOltStatisticsMgr
//metrics *pmmetrics.PmMetrics
stopCollector chan bool
stopHeartbeatCheck chan bool
activePorts sync.Map
uniEntityMap map[uint32]*OnuUniPort
}
//NewDeviceHandler creates a new device handler
func NewDeviceHandler(cp adapterif.CoreProxy, ap adapterif.AdapterProxy, ep adapterif.EventProxy, device *voltha.Device, adapter *OpenONUAC) *DeviceHandler {
var dh DeviceHandler
dh.coreProxy = cp
dh.AdapterProxy = ap
dh.EventProxy = ep
cloned := (proto.Clone(device)).(*voltha.Device)
dh.deviceID = cloned.Id
dh.DeviceType = cloned.Type
dh.adminState = "up"
dh.device = cloned
dh.pOpenOnuAc = adapter
dh.exitChannel = make(chan int, 1)
dh.lockDevice = sync.RWMutex{}
dh.deviceEntrySet = make(chan bool, 1)
dh.stopCollector = make(chan bool, 2)
dh.stopHeartbeatCheck = make(chan bool, 2)
//dh.metrics = pmmetrics.NewPmMetrics(cloned.Id, pmmetrics.Frequency(150), pmmetrics.FrequencyOverride(false), pmmetrics.Grouped(false), pmmetrics.Metrics(pmNames))
dh.activePorts = sync.Map{}
//TODO initialize the support classes.
dh.uniEntityMap = make(map[uint32]*OnuUniPort)
// Device related state machine
dh.pDeviceStateFsm = fsm.NewFSM(
"null",
fsm.Events{
{Name: "DeviceInit", Src: []string{"null", "down"}, Dst: "init"},
{Name: "GrpcConnected", Src: []string{"init"}, Dst: "connected"},
{Name: "GrpcDisconnected", Src: []string{"connected", "down"}, Dst: "init"},
{Name: "DeviceUpInd", Src: []string{"connected", "down"}, Dst: "up"},
{Name: "DeviceDownInd", Src: []string{"up"}, Dst: "down"},
},
fsm.Callbacks{
"before_event": func(e *fsm.Event) { dh.logStateChange(e) },
"before_DeviceInit": func(e *fsm.Event) { dh.doStateInit(e) },
"after_DeviceInit": func(e *fsm.Event) { dh.postInit(e) },
"before_GrpcConnected": func(e *fsm.Event) { dh.doStateConnected(e) },
"before_GrpcDisconnected": func(e *fsm.Event) { dh.doStateInit(e) },
"after_GrpcDisconnected": func(e *fsm.Event) { dh.postInit(e) },
"before_DeviceUpInd": func(e *fsm.Event) { dh.doStateUp(e) },
"before_DeviceDownInd": func(e *fsm.Event) { dh.doStateDown(e) },
},
)
return &dh
}
// start save the device to the data model
func (dh *DeviceHandler) Start(ctx context.Context) {
logger.Debugw("starting-device-handler", log.Fields{"device": dh.device, "deviceId": dh.deviceID})
// Add the initial device to the local model
logger.Debug("device-handler-started")
}
// stop stops the device dh. Not much to do for now
func (dh *DeviceHandler) stop(ctx context.Context) {
logger.Debug("stopping-device-handler")
dh.exitChannel <- 1
}
// ##########################################################################################
// DeviceHandler methods that implement the adapters interface requests ##### begin #########
//AdoptDevice adopts the OLT device
func (dh *DeviceHandler) AdoptDevice(ctx context.Context, device *voltha.Device) {
logger.Debugw("Adopt_device", log.Fields{"deviceID": device.Id, "Address": device.GetHostAndPort()})
logger.Debugw("Device FSM: ", log.Fields{"state": string(dh.pDeviceStateFsm.Current())})
if dh.pDeviceStateFsm.Is("null") {
if err := dh.pDeviceStateFsm.Event("DeviceInit"); err != nil {
logger.Errorw("Device FSM: Can't go to state DeviceInit", log.Fields{"err": err})
}
logger.Debugw("Device FSM: ", log.Fields{"state": string(dh.pDeviceStateFsm.Current())})
} else {
logger.Debug("AdoptDevice: Agent/device init already done")
}
/*
// Now, set the initial PM configuration for that device
if err := dh.coreProxy.DevicePMConfigUpdate(nil, dh.metrics.ToPmConfigs()); err != nil {
logger.Errorw("error-updating-PMs", log.Fields{"deviceId": device.Id, "error": err})
}
go startCollector(dh)
go startHeartbeatCheck(dh)
*/
}
//ProcessInterAdapterMessage sends the proxied messages to the target device
// If the proxy address is not found in the unmarshalled message, it first fetches the onu device for which the message
// is meant, and then send the unmarshalled omci message to this onu
func (dh *DeviceHandler) ProcessInterAdapterMessage(msg *ic.InterAdapterMessage) error {
msgID := msg.Header.Id
msgType := msg.Header.Type
fromTopic := msg.Header.FromTopic
toTopic := msg.Header.ToTopic
toDeviceID := msg.Header.ToDeviceId
proxyDeviceID := msg.Header.ProxyDeviceId
logger.Debugw("InterAdapter message header", log.Fields{"msgID": msgID, "msgType": msgType,
"fromTopic": fromTopic, "toTopic": toTopic, "toDeviceID": toDeviceID, "proxyDeviceID": proxyDeviceID})
switch msgType {
case ic.InterAdapterMessageType_OMCI_REQUEST:
{
msgBody := msg.GetBody()
omciMsg := &ic.InterAdapterOmciMessage{}
if err := ptypes.UnmarshalAny(msgBody, omciMsg); err != nil {
logger.Warnw("cannot-unmarshal-omci-msg-body", log.Fields{"error": err})
return err
}
//assuming omci message content is hex coded!
// with restricted output of 16(?) bytes would be ...omciMsg.Message[:16]
logger.Debugw("inter-adapter-recv-omci",
log.Fields{"RxOmciMessage": hex.EncodeToString(omciMsg.Message)})
//receive_message(omci_msg.message)
pDevEntry := dh.GetOnuDeviceEntry(true)
if pDevEntry != nil {
return pDevEntry.PDevOmciCC.ReceiveMessage(context.TODO(), omciMsg.Message)
} else {
logger.Errorw("No valid OnuDevice -aborting", log.Fields{"deviceID": dh.deviceID})
return errors.New("No valid OnuDevice")
}
}
case ic.InterAdapterMessageType_ONU_IND_REQUEST:
{
msgBody := msg.GetBody()
onu_indication := &oop.OnuIndication{}
if err := ptypes.UnmarshalAny(msgBody, onu_indication); err != nil {
logger.Warnw("cannot-unmarshal-onu-indication-msg-body", log.Fields{"error": err})
return err
}
onu_operstate := onu_indication.GetOperState()
logger.Debugw("inter-adapter-recv-onu-ind", log.Fields{"OnuId": onu_indication.GetOnuId(),
"AdminState": onu_indication.GetAdminState(), "OperState": onu_operstate,
"SNR": onu_indication.GetSerialNumber()})
//interface related functions might be error checked ....
if onu_operstate == "up" {
dh.create_interface(onu_indication)
} else if (onu_operstate == "down") || (onu_operstate == "unreachable") {
dh.updateInterface(onu_indication)
} else {
logger.Errorw("unknown-onu-indication operState", log.Fields{"OnuId": onu_indication.GetOnuId()})
return errors.New("InvalidOperState")
}
}
default:
{
logger.Errorw("inter-adapter-unhandled-type", log.Fields{"msgType": msg.Header.Type})
return errors.New("unimplemented")
}
}
/* form py code:
elif request.header.type == InterAdapterMessageType.TECH_PROFILE_DOWNLOAD_REQUEST:
tech_msg = InterAdapterTechProfileDownloadMessage()
request.body.Unpack(tech_msg)
self.logger.debug('inter-adapter-recv-tech-profile', tech_msg=tech_msg)
self.load_and_configure_tech_profile(tech_msg.uni_id, tech_msg.path)
elif request.header.type == InterAdapterMessageType.DELETE_GEM_PORT_REQUEST:
del_gem_msg = InterAdapterDeleteGemPortMessage()
request.body.Unpack(del_gem_msg)
self.logger.debug('inter-adapter-recv-del-gem', gem_del_msg=del_gem_msg)
self.delete_tech_profile(uni_id=del_gem_msg.uni_id,
gem_port_id=del_gem_msg.gem_port_id,
tp_path=del_gem_msg.tp_path)
elif request.header.type == InterAdapterMessageType.DELETE_TCONT_REQUEST:
del_tcont_msg = InterAdapterDeleteTcontMessage()
request.body.Unpack(del_tcont_msg)
self.logger.debug('inter-adapter-recv-del-tcont', del_tcont_msg=del_tcont_msg)
self.delete_tech_profile(uni_id=del_tcont_msg.uni_id,
alloc_id=del_tcont_msg.alloc_id,
tp_path=del_tcont_msg.tp_path)
else:
self.logger.error("inter-adapter-unhandled-type", request=request)
*/
return nil
}
//DisableDevice locks the ONU and its UNI/VEIP ports (admin lock via OMCI)
// TODO!!! Clarify usage of this method, it is for sure not used within ONOS (OLT) device disable
// maybe it is obsolete by now
func (dh *DeviceHandler) DisableDevice(device *voltha.Device) {
logger.Debugw("disable-device", log.Fields{"DeviceId": device.Id, "SerialNumber": device.SerialNumber})
//admin-lock reason can also be used uniquely for setting the DeviceState accordingly - inblock
//state checking to prevent unneeded processing (eg. on ONU 'unreachable' and 'down')
if dh.deviceReason != "omci-admin-lock" {
// disable UNI ports/ONU
// *** should generate UniAdminStateDone event - unrelated to DeviceProcStatusUpdate!!
// here the result of the processing is not checked (trusted in background) *****
if dh.pLockStateFsm == nil {
dh.createUniLockFsm(true, UniAdminStateDone)
} else { //LockStateFSM already init
dh.pLockStateFsm.SetSuccessEvent(UniAdminStateDone)
dh.runUniLockFsm(true)
}
if err := dh.coreProxy.DeviceReasonUpdate(context.TODO(), dh.deviceID, "omci-admin-lock"); err != nil {
logger.Errorw("error-updating-reason-state", log.Fields{"deviceID": dh.deviceID, "error": err})
}
dh.deviceReason = "omci-admin-lock"
//200604: ConnState improved to 'unreachable' (was not set in python-code), OperState 'unknown' seems to be best choice
if err := dh.coreProxy.DeviceStateUpdate(context.TODO(), dh.deviceID, voltha.ConnectStatus_UNREACHABLE,
voltha.OperStatus_UNKNOWN); err != nil {
logger.Errorw("error-updating-device-state", log.Fields{"deviceID": dh.deviceID, "error": err})
}
}
}
//ReenableDevice unlocks the ONU and its UNI/VEIP ports (admin unlock via OMCI)
// TODO!!! Clarify usage of this method, compare above DisableDevice, usage may clarify resulting states
// maybe it is obsolete by now
func (dh *DeviceHandler) ReenableDevice(device *voltha.Device) {
logger.Debugw("reenable-device", log.Fields{"DeviceId": device.Id, "SerialNumber": device.SerialNumber})
// TODO!!! ConnectStatus and OperStatus to be set here could be more accurate, for now just ...(like python code)
if err := dh.coreProxy.DeviceStateUpdate(context.TODO(), dh.deviceID, voltha.ConnectStatus_REACHABLE,
voltha.OperStatus_ACTIVE); err != nil {
logger.Errorw("error-updating-device-state", log.Fields{"deviceID": dh.deviceID, "error": err})
}
// TODO!!! DeviceReason to be set here could be more accurate, for now just ...(like python code)
if err := dh.coreProxy.DeviceReasonUpdate(context.TODO(), dh.deviceID, "initial-mib-downloaded"); err != nil {
logger.Errorw("error-updating-reason-state", log.Fields{"deviceID": dh.deviceID, "error": err})
}
dh.deviceReason = "initial-mib-downloaded"
// enable ONU/UNI ports
// *** should generate UniAdminStateDone event - unrelated to DeviceProcStatusUpdate!!
// here the result of the processing is not checked (trusted in background) *****
if dh.pUnlockStateFsm == nil {
dh.createUniLockFsm(false, UniAdminStateDone)
} else { //UnlockStateFSM already init
dh.pUnlockStateFsm.SetSuccessEvent(UniAdminStateDone)
dh.runUniLockFsm(false)
}
}
//GetOfpPortInfo returns the Voltha PortCapabilty with the logical port
func (dh *DeviceHandler) GetOfpPortInfo(device *voltha.Device,
portNo int64) (*ic.PortCapability, error) {
logger.Debugw("GetOfpPortInfo start", log.Fields{"deviceID": device.Id, "portNo": portNo})
//function body as per OLTAdapter handler code
// adapted with values from py dapter code
if pUniPort, exist := dh.uniEntityMap[uint32(portNo)]; exist {
var macOctets [6]uint8
macOctets[5] = 0x08
macOctets[4] = uint8(dh.ponPortNumber >> 8)
macOctets[3] = uint8(dh.ponPortNumber)
macOctets[2] = uint8(portNo >> 16)
macOctets[1] = uint8(portNo >> 8)
macOctets[0] = uint8(portNo)
hwAddr := genMacFromOctets(macOctets)
capacity := uint32(of.OfpPortFeatures_OFPPF_1GB_FD | of.OfpPortFeatures_OFPPF_FIBER)
name := device.SerialNumber + "-" + strconv.FormatUint(uint64(pUniPort.macBpNo), 10)
ofUniPortState := of.OfpPortState_OFPPS_LINK_DOWN
if pUniPort.operState == vc.OperStatus_ACTIVE {
ofUniPortState = of.OfpPortState_OFPPS_LIVE
}
logger.Debugw("setting LogicalPort", log.Fields{"with-name": name,
"withUniPort": pUniPort.name, "withMacBase": hwAddr, "OperState": ofUniPortState})
return &ic.PortCapability{
Port: &voltha.LogicalPort{
OfpPort: &of.OfpPort{
Name: name,
//HwAddr: macAddressToUint32Array(dh.device.MacAddress),
HwAddr: macAddressToUint32Array(hwAddr),
Config: 0,
State: uint32(ofUniPortState),
Curr: capacity,
Advertised: capacity,
Peer: capacity,
CurrSpeed: uint32(of.OfpPortFeatures_OFPPF_1GB_FD),
MaxSpeed: uint32(of.OfpPortFeatures_OFPPF_1GB_FD),
},
DeviceId: device.Id,
DevicePortNo: uint32(portNo),
},
}, nil
}
logger.Warnw("No UniPort found - abort", log.Fields{"for PortNo": uint32(portNo)})
return nil, errors.New("UniPort not found")
}
// DeviceHandler methods that implement the adapters interface requests## end #########
// #####################################################################################
// ################ to be updated acc. needs of ONU Device ########################
// DeviceHandler StateMachine related state transition methods ##### begin #########
func (dh *DeviceHandler) logStateChange(e *fsm.Event) {
logger.Debugw("Device FSM: ", log.Fields{"event name": string(e.Event), "src state": string(e.Src), "dst state": string(e.Dst), "device-id": dh.deviceID})
}
// doStateInit provides the device update to the core
func (dh *DeviceHandler) doStateInit(e *fsm.Event) {
logger.Debug("doStateInit-started")
var err error
// populate what we know. rest comes later after mib sync
dh.device.Root = false
dh.device.Vendor = "OpenONU"
dh.device.Model = "go"
dh.device.Reason = "activating-onu"
dh.deviceReason = "activating-onu"
dh.logicalDeviceID = dh.deviceID // really needed - what for ??? //TODO!!!
dh.coreProxy.DeviceUpdate(context.TODO(), dh.device)
dh.parentId = dh.device.ParentId
dh.ponPortNumber = dh.device.ParentPortNo
// store proxy parameters for later communication - assumption: invariant, else they have to be requested dynamically!!
dh.ProxyAddressID = dh.device.ProxyAddress.GetDeviceId()
dh.ProxyAddressType = dh.device.ProxyAddress.GetDeviceType()
logger.Debugw("device-updated", log.Fields{"deviceID": dh.deviceID, "proxyAddressID": dh.ProxyAddressID,
"proxyAddressType": dh.ProxyAddressType, "SNR": dh.device.SerialNumber,
"ParentId": dh.parentId, "ParentPortNo": dh.ponPortNumber})
/*
self._pon = PonPort.create(self, self._pon_port_number)
self._pon.add_peer(self.parent_id, self._pon_port_number)
self.logger.debug('adding-pon-port-to-agent',
type=self._pon.get_port().type,
admin_state=self._pon.get_port().admin_state,
oper_status=self._pon.get_port().oper_status,
)
*/
logger.Debug("adding-pon-port")
var ponPortNo uint32 = 1
if dh.ponPortNumber != 0 {
ponPortNo = dh.ponPortNumber
}
pPonPort := &voltha.Port{
PortNo: ponPortNo,
Label: fmt.Sprintf("pon-%d", ponPortNo),
Type: voltha.Port_PON_ONU,
OperStatus: voltha.OperStatus_ACTIVE,
Peers: []*voltha.Port_PeerPort{{DeviceId: dh.parentId, // Peer device is OLT
PortNo: ponPortNo}}, // Peer port is parent's port number
}
if err = dh.coreProxy.PortCreated(context.TODO(), dh.deviceID, pPonPort); err != nil {
logger.Fatalf("Device FSM: PortCreated-failed-%s", err)
e.Cancel(err)
return
}
logger.Debug("doStateInit-done")
}
// postInit setups the DeviceEntry for the conerned device
func (dh *DeviceHandler) postInit(e *fsm.Event) {
logger.Debug("postInit-started")
var err error
/*
dh.Client = oop.NewOpenoltClient(dh.clientCon)
dh.pTransitionMap.Handle(ctx, GrpcConnected)
return nil
*/
if err = dh.AddOnuDeviceEntry(context.TODO()); err != nil {
logger.Fatalf("Device FSM: AddOnuDeviceEntry-failed-%s", err)
e.Cancel(err)
return
}
/*
############################################################################
# Setup Alarm handler
self.events = AdapterEvents(self.core_proxy, device.id, self.logical_device_id,
device.serial_number)
############################################################################
# Setup PM configuration for this device
# Pass in ONU specific options
kwargs = {
OnuPmMetrics.DEFAULT_FREQUENCY_KEY: OnuPmMetrics.DEFAULT_ONU_COLLECTION_FREQUENCY,
'heartbeat': self.heartbeat,
OnuOmciPmMetrics.OMCI_DEV_KEY: self._onu_omci_device
}
self.logger.debug('create-pm-metrics', device_id=device.id, serial_number=device.serial_number)
self._pm_metrics = OnuPmMetrics(self.events, self.core_proxy, self.device_id,
self.logical_device_id, device.serial_number,
grouped=True, freq_override=False, **kwargs)
pm_config = self._pm_metrics.make_proto()
self._onu_omci_device.set_pm_config(self._pm_metrics.omci_pm.openomci_interval_pm)
self.logger.info("initial-pm-config", device_id=device.id, serial_number=device.serial_number)
yield self.core_proxy.device_pm_config_update(pm_config, init=True)
# Note, ONU ID and UNI intf set in add_uni_port method
self._onu_omci_device.alarm_synchronizer.set_alarm_params(mgr=self.events,
ani_ports=[self._pon])
# Code to Run OMCI Test Action
kwargs_omci_test_action = {
OmciTestRequest.DEFAULT_FREQUENCY_KEY:
OmciTestRequest.DEFAULT_COLLECTION_FREQUENCY
}
serial_number = device.serial_number
self._test_request = OmciTestRequest(self.core_proxy,
self.omci_agent, self.device_id,
AniG, serial_number,
self.logical_device_id,
exclusive=False,
**kwargs_omci_test_action)
self.enabled = True
else:
self.logger.info('onu-already-activated')
*/
logger.Debug("postInit-done")
}
// doStateConnected get the device info and update to voltha core
// for comparison of the original method (not that easy to uncomment): compare here:
// voltha-openolt-adapter/adaptercore/device_handler.go
// -> this one obviously initiates all communication interfaces of the device ...?
func (dh *DeviceHandler) doStateConnected(e *fsm.Event) {
logger.Debug("doStateConnected-started")
var err error
err = errors.New("Device FSM: function not implemented yet!")
e.Cancel(err)
logger.Debug("doStateConnected-done")
return
}
// doStateUp handle the onu up indication and update to voltha core
func (dh *DeviceHandler) doStateUp(e *fsm.Event) {
logger.Debug("doStateUp-started")
var err error
err = errors.New("Device FSM: function not implemented yet!")
e.Cancel(err)
logger.Debug("doStateUp-done")
return
/*
// Synchronous call to update device state - this method is run in its own go routine
if err := dh.coreProxy.DeviceStateUpdate(ctx, dh.device.Id, voltha.ConnectStatus_REACHABLE,
voltha.OperStatus_ACTIVE); err != nil {
logger.Errorw("Failed to update device with OLT UP indication", log.Fields{"deviceID": dh.device.Id, "error": err})
return err
}
return nil
*/
}
// doStateDown handle the onu down indication
func (dh *DeviceHandler) doStateDown(e *fsm.Event) {
logger.Debug("doStateDown-started")
var err error
device := dh.device
if device == nil {
/*TODO: needs to handle error scenarios */
logger.Error("Failed to fetch handler device")
e.Cancel(err)
return
}
cloned := proto.Clone(device).(*voltha.Device)
logger.Debugw("do-state-down", log.Fields{"ClonedDeviceID": cloned.Id})
/*
// Update the all ports state on that device to disable
if er := dh.coreProxy.PortsStateUpdate(ctx, cloned.Id, voltha.OperStatus_UNKNOWN); er != nil {
logger.Errorw("updating-ports-failed", log.Fields{"deviceID": device.Id, "error": er})
return er
}
//Update the device oper state and connection status
cloned.OperStatus = voltha.OperStatus_UNKNOWN
cloned.ConnectStatus = common.ConnectStatus_UNREACHABLE
dh.device = cloned
if er := dh.coreProxy.DeviceStateUpdate(ctx, cloned.Id, cloned.ConnectStatus, cloned.OperStatus); er != nil {
logger.Errorw("error-updating-device-state", log.Fields{"deviceID": device.Id, "error": er})
return er
}
//get the child device for the parent device
onuDevices, err := dh.coreProxy.GetChildDevices(ctx, dh.device.Id)
if err != nil {
logger.Errorw("failed to get child devices information", log.Fields{"deviceID": dh.device.Id, "error": err})
return err
}
for _, onuDevice := range onuDevices.Items {
// Update onu state as down in onu adapter
onuInd := oop.OnuIndication{}
onuInd.OperState = "down"
er := dh.AdapterProxy.SendInterAdapterMessage(ctx, &onuInd, ic.InterAdapterMessageType_ONU_IND_REQUEST,
"openolt", onuDevice.Type, onuDevice.Id, onuDevice.ProxyAddress.DeviceId, "")
if er != nil {
logger.Errorw("Failed to send inter-adapter-message", log.Fields{"OnuInd": onuInd,
"From Adapter": "openolt", "DevieType": onuDevice.Type, "DeviceID": onuDevice.Id})
//Do not return here and continue to process other ONUs
}
}
// * Discovered ONUs entries need to be cleared , since after OLT
// is up, it starts sending discovery indications again* /
dh.discOnus = sync.Map{}
logger.Debugw("do-state-down-end", log.Fields{"deviceID": device.Id})
return nil
*/
err = errors.New("Device FSM: function not implemented yet!")
e.Cancel(err)
logger.Debug("doStateDown-done")
return
}
// DeviceHandler StateMachine related state transition methods ##### end #########
// #################################################################################
// ###################################################
// DeviceHandler utility methods ##### begin #########
//GetOnuDeviceEntry getsthe ONU device entry and may wait until its value is defined
func (dh *DeviceHandler) GetOnuDeviceEntry(aWait bool) *OnuDeviceEntry {
dh.lockDevice.RLock()
pOnuDeviceEntry := dh.pOnuOmciDevice
if aWait && pOnuDeviceEntry == nil {
//keep the read sema short to allow for subsequent write
dh.lockDevice.RUnlock()
logger.Debugw("Waiting for DeviceEntry to be set ...", log.Fields{"deviceID": dh.deviceID})
// based on concurrent processing the deviceEntry setup may not yet be finished at his point
// so it might be needed to wait here for that event with some timeout
select {
case <-time.After(60 * time.Second): //timer may be discussed ...
logger.Errorw("No valid DeviceEntry set after maxTime", log.Fields{"deviceID": dh.deviceID})
return nil
case <-dh.deviceEntrySet:
logger.Debugw("devicEntry ready now - continue", log.Fields{"deviceID": dh.deviceID})
// if written now, we can return the written value without sema
return dh.pOnuOmciDevice
}
}
dh.lockDevice.RUnlock()
return pOnuDeviceEntry
}
//SetOnuDeviceEntry sets the ONU device entry within the handler
func (dh *DeviceHandler) SetOnuDeviceEntry(pDeviceEntry *OnuDeviceEntry) error {
dh.lockDevice.Lock()
defer dh.lockDevice.Unlock()
dh.pOnuOmciDevice = pDeviceEntry
return nil
}
//AddOnuDeviceEntry creates a new ONU device or returns the existing
func (dh *DeviceHandler) AddOnuDeviceEntry(ctx context.Context) error {
logger.Debugw("adding-deviceEntry", log.Fields{"for deviceId": dh.deviceID})
deviceEntry := dh.GetOnuDeviceEntry(false)
if deviceEntry == nil {
/* costum_me_map in python code seems always to be None,
we omit that here first (declaration unclear) -> todo at Adapter specialization ...*/
/* also no 'clock' argument - usage open ...*/
/* and no alarm_db yet (oo.alarm_db) */
deviceEntry = NewOnuDeviceEntry(ctx, dh.deviceID, dh.pOpenOnuAc.KVStoreHost, dh.pOpenOnuAc.KVStorePort, dh.pOpenOnuAc.KVStoreType,
dh, dh.coreProxy, dh.AdapterProxy,
dh.pOpenOnuAc.pSupportedFsms) //nil as FSM pointer would yield deviceEntry internal defaults ...
//error treatment possible //TODO!!!
dh.SetOnuDeviceEntry(deviceEntry)
// fire deviceEntry ready event to spread to possibly waiting processing
dh.deviceEntrySet <- true
logger.Infow("onuDeviceEntry-added", log.Fields{"for deviceId": dh.deviceID})
} else {
logger.Infow("onuDeviceEntry-add: Device already exists", log.Fields{"for deviceId": dh.deviceID})
}
// might be updated with some error handling !!!
return nil
}
// doStateInit provides the device update to the core
func (dh *DeviceHandler) create_interface(onuind *oop.OnuIndication) error {
logger.Debugw("create_interface-started", log.Fields{"OnuId": onuind.GetOnuId(),
"OnuIntfId": onuind.GetIntfId(), "OnuSerialNumber": onuind.GetSerialNumber()})
dh.pOnuIndication = onuind // let's revise if storing the pointer is sufficient...
if err := dh.coreProxy.DeviceStateUpdate(context.TODO(), dh.deviceID,
voltha.ConnectStatus_REACHABLE, voltha.OperStatus_ACTIVATING); err != nil {
logger.Errorw("error-updating-device-state", log.Fields{"deviceID": dh.deviceID, "error": err})
}
// It does not look to me as if makes sense to work with the real core device here, (not the stored clone)?
// in this code the GetDevice would just make a check if the DeviceID's Device still exists in core
// in python code it looks as the started onu_omci_device might have been updated with some new instance state of the core device
// but I would not know why, and the go code anyway dows not work with the device directly anymore in the OnuDeviceEntry
// so let's just try to keep it simple ...
/*
device, err := dh.coreProxy.GetDevice(context.TODO(), dh.device.Id, dh.device.Id)
if err != nil || device == nil {
//TODO: needs to handle error scenarios
logger.Errorw("Failed to fetch device device at creating If", log.Fields{"err": err})
return errors.New("Voltha Device not found")
}
*/
pDevEntry := dh.GetOnuDeviceEntry(true)
if pDevEntry != nil {
pDevEntry.Start(context.TODO())
} else {
logger.Errorw("No valid OnuDevice -aborting", log.Fields{"deviceID": dh.deviceID})
return errors.New("No valid OnuDevice")
}
if err := dh.coreProxy.DeviceReasonUpdate(context.TODO(), dh.deviceID, "starting-openomci"); err != nil {
logger.Errorw("error-DeviceReasonUpdate to starting-openomci", log.Fields{"deviceID": dh.deviceID, "error": err})
}
dh.deviceReason = "starting-openomci"
/* this might be a good time for Omci Verify message? */
verifyExec := make(chan bool)
omci_verify := NewOmciTestRequest(context.TODO(),
dh.device.Id, pDevEntry.PDevOmciCC,
true, true) //eclusive and allowFailure (anyway not yet checked)
omci_verify.PerformOmciTest(context.TODO(), verifyExec)
/* give the handler some time here to wait for the OMCi verification result
after Timeout start and try MibUpload FSM anyway
(to prevent stopping on just not supported OMCI verification from ONU) */
select {
case <-time.After(2 * time.Second):
logger.Warn("omci start-verification timed out (continue normal)")
case testresult := <-verifyExec:
logger.Infow("Omci start verification done", log.Fields{"result": testresult})
}
/* In py code it looks earlier (on activate ..)
# Code to Run OMCI Test Action
kwargs_omci_test_action = {
OmciTestRequest.DEFAULT_FREQUENCY_KEY:
OmciTestRequest.DEFAULT_COLLECTION_FREQUENCY
}
serial_number = device.serial_number
self._test_request = OmciTestRequest(self.core_proxy,
self.omci_agent, self.device_id,
AniG, serial_number,
self.logical_device_id,
exclusive=False,
**kwargs_omci_test_action)
...
# Start test requests after a brief pause
if not self._test_request_started:
self._test_request_started = True
tststart = _STARTUP_RETRY_WAIT * (random.randint(1, 5))
reactor.callLater(tststart, self._test_request.start_collector)
*/
/* which is then: in omci_test_request.py : */
/*
def start_collector(self, callback=None):
"""
Start the collection loop for an adapter if the frequency > 0
:param callback: (callable) Function to call to collect PM data
"""
self.logger.info("starting-pm-collection", device_name=self.name, default_freq=self.default_freq)
if callback is None:
callback = self.perform_test_omci
if self.lc is None:
self.lc = LoopingCall(callback)
if self.default_freq > 0:
self.lc.start(interval=self.default_freq / 10)
def perform_test_omci(self):
"""
Perform the initial test request
"""
ani_g_entities = self._device.configuration.ani_g_entities
ani_g_entities_ids = list(ani_g_entities.keys()) if ani_g_entities \
is not None else None
self._entity_id = ani_g_entities_ids[0]
self.logger.info('perform-test', entity_class=self._entity_class,
entity_id=self._entity_id)
try:
frame = MEFrame(self._entity_class, self._entity_id, []).test()
result = yield self._device.omci_cc.send(frame)
if not result.fields['omci_message'].fields['success_code']:
self.logger.info('Self-Test Submitted Successfully',
code=result.fields[
'omci_message'].fields['success_code'])
else:
raise TestFailure('Test Failure: {}'.format(
result.fields['omci_message'].fields['success_code']))
except TimeoutError as e:
self.deferred.errback(failure.Failure(e))
except Exception as e:
self.logger.exception('perform-test-Error', e=e,
class_id=self._entity_class,
entity_id=self._entity_id)
self.deferred.errback(failure.Failure(e))
*/
// PM related heartbeat??? !!!TODO....
//self._heartbeat.enabled = True
//call MibUploadFSM - transition up to state "in_sync"
pMibUlFsm := pDevEntry.pMibUploadFsm.pFsm
if pMibUlFsm != nil {
if pMibUlFsm.Is("disabled") {
if err := pMibUlFsm.Event("start"); err != nil {
logger.Errorw("MibSyncFsm: Can't go to state starting", log.Fields{"err": err})
return errors.New("Can't go to state starting")
} else {
logger.Debugw("MibSyncFsm", log.Fields{"state": string(pMibUlFsm.Current())})
//Determine ONU status and start/re-start MIB Synchronization tasks
//Determine if this ONU has ever synchronized
if true { //TODO: insert valid check
if err := pMibUlFsm.Event("load_mib_template"); err != nil {
logger.Errorw("MibSyncFsm: Can't go to state loading_mib_template", log.Fields{"err": err})
return errors.New("Can't go to state loading_mib_template")
}
} else {
pMibUlFsm.Event("examine_mds")
logger.Debugw("state of MibSyncFsm", log.Fields{"state": string(pMibUlFsm.Current())})
//Examine the MIB Data Sync
// callbacks to be handled:
// Event("success")
// Event("timeout")
// Event("mismatch")
}
}
} else {
logger.Errorw("wrong state of MibSyncFsm - want: disabled", log.Fields{"have": string(pMibUlFsm.Current())})
return errors.New("wrong state of MibSyncFsm")
}
} else {
logger.Errorw("MibSyncFsm invalid - cannot be executed!!", log.Fields{"deviceID": dh.deviceID})
return errors.New("cannot execut MibSync")
}
return nil
}
func (dh *DeviceHandler) updateInterface(onuind *oop.OnuIndication) error {
//state checking to prevent unneeded processing (eg. on ONU 'unreachable' and 'down')
if dh.deviceReason != "stopping-openomci" {
logger.Debugw("updateInterface-started - stopping-device", log.Fields{"deviceID": dh.deviceID})
//stop all running SM processing - make use of the DH-state as mirrored in the deviceReason
pDevEntry := dh.GetOnuDeviceEntry(false)
if pDevEntry == nil {
logger.Errorw("No valid OnuDevice -aborting", log.Fields{"deviceID": dh.deviceID})
return errors.New("No valid OnuDevice")
}
switch dh.deviceReason {
case "starting-openomci":
{ //MIBSync FSM may run
pMibUlFsm := pDevEntry.pMibUploadFsm.pFsm
if pMibUlFsm != nil {
pMibUlFsm.Event("stop") //TODO!! verify if MibSyncFsm stop-processing is sufficient (to allow it again afterwards)
}
}
case "discovery-mibsync-complete":
{ //MibDownload may run
pMibDlFsm := pDevEntry.pMibDownloadFsm.pFsm
if pMibDlFsm != nil {
pMibDlFsm.Event("reset")
}
}
default:
{ //port lock/unlock FSM's may be active
if dh.pUnlockStateFsm != nil {
dh.pUnlockStateFsm.pAdaptFsm.pFsm.Event("reset")
}
if dh.pLockStateFsm != nil {
dh.pLockStateFsm.pAdaptFsm.pFsm.Event("reset")
}
}
//TODO!!! care about PM/Alarm processing once started
}
//TODO: from here the deviceHandler FSM itself may be stuck in some of the initial states
// (mainly the still seperate 'Event states')
// so it is questionable, how this is resolved after some possible re-enable
// assumption there is obviously, that the system may continue with some 'after "mib-download-done" state'
//stop/remove(?) the device entry
pDevEntry.Stop(context.TODO()) //maybe some more sophisticated context treatment should be used here?
//TODO!!! remove existing traffic profiles
/* from py code, if TP's exist, remove them - not yet implemented
self._tp = dict()
# Let TP download happen again
for uni_id in self._tp_service_specific_task:
self._tp_service_specific_task[uni_id].clear()
for uni_id in self._tech_profile_download_done:
self._tech_profile_download_done[uni_id].clear()
*/
dh.disableUniPortStateUpdate()
if err := dh.coreProxy.DeviceReasonUpdate(context.TODO(), dh.deviceID, "stopping-openomci"); err != nil {
logger.Errorw("error-DeviceReasonUpdate to 'stopping-openomci'",
log.Fields{"deviceID": dh.deviceID, "error": err})
// abort: system behavior is just unstable ...
return err
}
dh.deviceReason = "stopping-openomci"
if err := dh.coreProxy.DeviceStateUpdate(context.TODO(), dh.deviceID,
voltha.ConnectStatus_UNREACHABLE, voltha.OperStatus_DISCOVERED); err != nil {
logger.Errorw("error-updating-device-state unreachable-discovered",
log.Fields{"deviceID": dh.deviceID, "error": err})
// abort: system behavior is just unstable ...
return err
}
} else {
logger.Debugw("updateInterface - device already stopped", log.Fields{"deviceID": dh.deviceID})
}
return nil
}
//DeviceProcStatusUpdate evaluates possible processing events and initiates according next activities
func (dh *DeviceHandler) DeviceProcStatusUpdate(dev_Event OnuDeviceEvent) {
switch dev_Event {
case MibDatabaseSync:
{
logger.Infow("MibInSync event: update dev state to 'MibSync complete'", log.Fields{"deviceID": dh.deviceID})
//initiate DevStateUpdate
if err := dh.coreProxy.DeviceReasonUpdate(context.TODO(), dh.deviceID, "discovery-mibsync-complete"); err != nil {
logger.Errorw("error-DeviceReasonUpdate to 'mibsync-complete'", log.Fields{
"deviceID": dh.deviceID, "error": err})
}
dh.deviceReason = "discovery-mibsync-complete"
pDevEntry := dh.GetOnuDeviceEntry(false)
unigMap, ok := pDevEntry.pOnuDB.meDb[me.UniGClassID]
unigInstKeys := pDevEntry.pOnuDB.GetSortedInstKeys(unigMap)
i := uint8(0) //UNI Port limit: see MaxUnisPerOnu (by now 16) (OMCI supports max 255 p.b.)
if ok {
for _, mgmtEntityId := range unigInstKeys {
logger.Debugw("Add UNI port for stored UniG instance:", log.Fields{
"deviceId": dh.deviceID, "UnigMe EntityID": mgmtEntityId})
dh.addUniPort(mgmtEntityId, i, UniPPTP)
i++
}
} else {
logger.Debugw("No UniG instances found", log.Fields{"deviceId": dh.deviceID})
}
veipMap, ok := pDevEntry.pOnuDB.meDb[me.VirtualEthernetInterfacePointClassID]
veipInstKeys := pDevEntry.pOnuDB.GetSortedInstKeys(veipMap)
if ok {
for _, mgmtEntityId := range veipInstKeys {
logger.Debugw("Add VEIP acc. to stored VEIP instance:", log.Fields{
"deviceId": dh.deviceID, "VEIP EntityID": mgmtEntityId})
dh.addUniPort(mgmtEntityId, i, UniVEIP)
i++
}
} else {
logger.Debugw("No VEIP instances found", log.Fields{"deviceId": dh.deviceID})
}
if i == 0 {
logger.Warnw("No PPTP instances found", log.Fields{"deviceId": dh.deviceID})
}
/* 200605: lock processing after initial MIBUpload removed now as the ONU should be in the lock state per default here
* left the code here as comment in case such processing should prove needed unexpectedly
// Init Uni Ports to Admin locked state
// maybe not really needed here as UNI ports should be locked by default, but still left as available in python code
// *** should generate UniLockStateDone event *****
if dh.pLockStateFsm == nil {
dh.createUniLockFsm(true, UniLockStateDone)
} else { //LockStateFSM already init
dh.pLockStateFsm.SetSuccessEvent(UniLockStateDone)
dh.runUniLockFsm(true)
}
}
case UniLockStateDone:
{
logger.Infow("UniLockStateDone event: Starting MIB download", log.Fields{"deviceID": dh.deviceID})
* lockState processing commented out
*/
/* Mib download procedure -
***** should run over 'downloaded' state and generate MibDownloadDone event *****
*/
pMibDlFsm := pDevEntry.pMibDownloadFsm.pFsm
if pMibDlFsm != nil {
if pMibDlFsm.Is("disabled") {
if err := pMibDlFsm.Event("start"); err != nil {
logger.Errorw("MibDownloadFsm: Can't go to state starting", log.Fields{"err": err})
// maybe try a FSM reset and then again ... - TODO!!!
} else {
logger.Debugw("MibDownloadFsm", log.Fields{"state": string(pMibDlFsm.Current())})
// maybe use more specific states here for the specific download steps ...
if err := pMibDlFsm.Event("create_gal"); err != nil {
logger.Errorw("MibDownloadFsm: Can't start CreateGal", log.Fields{"err": err})
} else {
logger.Debugw("state of MibDownloadFsm", log.Fields{"state": string(pMibDlFsm.Current())})
//Begin MIB data download (running autonomously)
}
}
} else {
logger.Errorw("wrong state of MibDownloadFsm - want: disabled", log.Fields{"have": string(pMibDlFsm.Current())})
// maybe try a FSM reset and then again ... - TODO!!!
}
/***** Mib download started */
} else {
logger.Errorw("MibDownloadFsm invalid - cannot be executed!!", log.Fields{"deviceID": dh.deviceID})
}
}
case MibDownloadDone:
{
logger.Infow("MibDownloadDone event: update dev state to 'Oper.Active'", log.Fields{"deviceID": dh.deviceID})
//initiate DevStateUpdate
if err := dh.coreProxy.DeviceStateUpdate(context.TODO(), dh.deviceID,
voltha.ConnectStatus_REACHABLE, voltha.OperStatus_ACTIVE); err != nil {
logger.Errorw("error-updating-device-state", log.Fields{"deviceID": dh.deviceID, "error": err})
}
logger.Debug("MibDownloadDone Event: update dev reason to 'initial-mib-downloaded'")
if err := dh.coreProxy.DeviceReasonUpdate(context.TODO(), dh.deviceID, "initial-mib-downloaded"); err != nil {
logger.Errorw("error-DeviceReasonUpdate to 'initial-mib-downloaded'",
log.Fields{"deviceID": dh.deviceID, "error": err})
}
dh.deviceReason = "initial-mib-downloaded"
// *** should generate UniUnlockStateDone event *****
if dh.pUnlockStateFsm == nil {
dh.createUniLockFsm(false, UniUnlockStateDone)
} else { //UnlockStateFSM already init
dh.pUnlockStateFsm.SetSuccessEvent(UniUnlockStateDone)
dh.runUniLockFsm(false)
}
}
case UniUnlockStateDone:
{
go dh.enableUniPortStateUpdate() //cmp python yield self.enable_ports()
logger.Infow("UniUnlockStateDone event: Sending OnuUp event", log.Fields{"deviceID": dh.deviceID})
raisedTs := time.Now().UnixNano()
go dh.sendOnuOperStateEvent(voltha.OperStatus_ACTIVE, dh.deviceID, raisedTs) //cmp python onu_active_event
}
default:
{
logger.Warnw("unhandled-device-event", log.Fields{"deviceID": dh.deviceID, "event": dev_Event})
}
} //switch
}
func (dh *DeviceHandler) addUniPort(a_uniInstNo uint16, a_uniId uint8, a_portType UniPortType) {
// parameters are IntfId, OnuId, uniId
uniNo := MkUniPortNum(dh.pOnuIndication.GetIntfId(), dh.pOnuIndication.GetOnuId(),
uint32(a_uniId))
if _, present := dh.uniEntityMap[uniNo]; present {
logger.Warnw("onuUniPort-add: Port already exists", log.Fields{"for InstanceId": a_uniInstNo})
} else {
//with arguments a_uniId, a_portNo, a_portType
pUniPort := NewOnuUniPort(a_uniId, uniNo, a_uniInstNo, a_portType)
if pUniPort == nil {
logger.Warnw("onuUniPort-add: Could not create Port", log.Fields{"for InstanceId": a_uniInstNo})
} else {
//store UniPort with the System-PortNumber key
dh.uniEntityMap[uniNo] = pUniPort
// create announce the UniPort to the core as VOLTHA Port object
if err := pUniPort.CreateVolthaPort(dh); err == nil {
logger.Infow("onuUniPort-added", log.Fields{"for PortNo": uniNo})
} //error logging already within UniPort method
}
}
}
// enableUniPortStateUpdate enables UniPortState and update core port state accordingly
func (dh *DeviceHandler) enableUniPortStateUpdate() {
// py code was updated 2003xx to activate the real ONU UNI ports per OMCI (VEIP or PPTP)
// but towards core only the first port active state is signalled
// with following remark:
// # TODO: for now only support the first UNI given no requirement for multiple uni yet. Also needed to reduce flow
// # load on the core
// lock_ports(false) as done in py code here is shifted to separate call from devicevent processing
for uniNo, uniPort := range dh.uniEntityMap {
// only if this port is validated for operState transfer
if (1<<uniPort.uniId)&ActiveUniPortStateUpdateMask == (1 << uniPort.uniId) {
logger.Infow("onuUniPort-forced-OperState-ACTIVE", log.Fields{"for PortNo": uniNo})
uniPort.SetOperState(vc.OperStatus_ACTIVE)
//maybe also use getter functions on uniPort - perhaps later ...
go dh.coreProxy.PortStateUpdate(context.TODO(), dh.deviceID, voltha.Port_ETHERNET_UNI, uniPort.portNo, uniPort.operState)
}
}
}
// Disable UniPortState and update core port state accordingly
func (dh *DeviceHandler) disableUniPortStateUpdate() {
// compare enableUniPortStateUpdate() above
// -> use current restriction to operate only on first UNI port as inherited from actual Py code
for uniNo, uniPort := range dh.uniEntityMap {
// only if this port is validated for operState transfer
if (1<<uniPort.uniId)&ActiveUniPortStateUpdateMask == (1 << uniPort.uniId) {
logger.Infow("onuUniPort-forced-OperState-UNKNOWN", log.Fields{"for PortNo": uniNo})
uniPort.SetOperState(vc.OperStatus_UNKNOWN)
//maybe also use getter functions on uniPort - perhaps later ...
go dh.coreProxy.PortStateUpdate(context.TODO(), dh.deviceID, voltha.Port_ETHERNET_UNI, uniPort.portNo, uniPort.operState)
}
}
}
// ONU_Active/Inactive announcement on system KAFKA bus
// tried to re-use procedure of oltUpDownIndication from openolt_eventmgr.go with used values from Py code
func (dh *DeviceHandler) sendOnuOperStateEvent(a_OperState vc.OperStatus_Types, a_deviceID string, raisedTs int64) {
var de voltha.DeviceEvent
eventContext := make(map[string]string)
//Populating event context
// assume giving ParentId in GetDevice twice really gives the ParentDevice (there is no GetParentDevice()...)
parentDevice, err := dh.coreProxy.GetDevice(context.TODO(), dh.parentId, dh.parentId)
if err != nil || parentDevice == nil {
logger.Errorw("Failed to fetch parent device for OnuEvent",
log.Fields{"parentId": dh.parentId, "err": err})
}
oltSerialNumber := parentDevice.SerialNumber
eventContext["pon-id"] = strconv.FormatUint(uint64(dh.pOnuIndication.IntfId), 10)
eventContext["onu-id"] = strconv.FormatUint(uint64(dh.pOnuIndication.OnuId), 10)
eventContext["serial-number"] = dh.device.SerialNumber
eventContext["olt_serial_number"] = oltSerialNumber
eventContext["device_id"] = a_deviceID
eventContext["registration_id"] = a_deviceID //py: string(device_id)??
logger.Debugw("prepare ONU_ACTIVATED event",
log.Fields{"DeviceId": a_deviceID, "EventContext": eventContext})
/* Populating device event body */
de.Context = eventContext
de.ResourceId = a_deviceID
if a_OperState == voltha.OperStatus_ACTIVE {
de.DeviceEventName = fmt.Sprintf("%s_%s", cOnuActivatedEvent, "RAISE_EVENT")
de.Description = fmt.Sprintf("%s Event - %s - %s",
cEventObjectType, cOnuActivatedEvent, "Raised")
} else {
de.DeviceEventName = fmt.Sprintf("%s_%s", cOnuActivatedEvent, "CLEAR_EVENT")
de.Description = fmt.Sprintf("%s Event - %s - %s",
cEventObjectType, cOnuActivatedEvent, "Cleared")
}
/* Send event to KAFKA */
if err := dh.EventProxy.SendDeviceEvent(&de, equipment, pon, raisedTs); err != nil {
logger.Warnw("could not send ONU_ACTIVATED event",
log.Fields{"DeviceId": a_deviceID, "error": err})
}
logger.Debugw("ONU_ACTIVATED event sent to KAFKA",
log.Fields{"DeviceId": a_deviceID, "with-EventName": de.DeviceEventName})
}
// createUniLockFsm initialises and runs the UniLock FSM to transfer teh OMCi related commands for port lock/unlock
func (dh *DeviceHandler) createUniLockFsm(aAdminState bool, devEvent OnuDeviceEvent) {
chLSFsm := make(chan Message, 2048)
var sFsmName string
if aAdminState == true {
logger.Infow("createLockStateFSM", log.Fields{"deviceID": dh.deviceID})
sFsmName = "LockStateFSM"
} else {
logger.Infow("createUnlockStateFSM", log.Fields{"deviceID": dh.deviceID})
sFsmName = "UnLockStateFSM"
}
pDevEntry := dh.GetOnuDeviceEntry(true)
if pDevEntry == nil {
logger.Errorw("No valid OnuDevice -aborting", log.Fields{"deviceID": dh.deviceID})
return
}
pLSFsm := NewLockStateFsm(pDevEntry.PDevOmciCC, aAdminState, devEvent,
sFsmName, dh.deviceID, chLSFsm)
if pLSFsm != nil {
if aAdminState == true {
dh.pLockStateFsm = pLSFsm
} else {
dh.pUnlockStateFsm = pLSFsm
}
dh.runUniLockFsm(aAdminState)
} else {
logger.Errorw("LockStateFSM could not be created - abort!!", log.Fields{"deviceID": dh.deviceID})
}
}
// runUniLockFsm starts the UniLock FSM to transfer the OMCI related commands for port lock/unlock
func (dh *DeviceHandler) runUniLockFsm(aAdminState bool) {
/* Uni Port lock/unlock procedure -
***** should run via 'adminDone' state and generate the argument requested event *****
*/
var pLSStatemachine *fsm.FSM
if aAdminState == true {
pLSStatemachine = dh.pLockStateFsm.pAdaptFsm.pFsm
//make sure the opposite FSM is not running and if so, terminate it as not relevant anymore
if (dh.pUnlockStateFsm != nil) &&
(dh.pUnlockStateFsm.pAdaptFsm.pFsm.Current() != "disabled") {
dh.pUnlockStateFsm.pAdaptFsm.pFsm.Event("reset")
}
} else {
pLSStatemachine = dh.pUnlockStateFsm.pAdaptFsm.pFsm
//make sure the opposite FSM is not running and if so, terminate it as not relevant anymore
if (dh.pLockStateFsm != nil) &&
(dh.pLockStateFsm.pAdaptFsm.pFsm.Current() != "disabled") {
dh.pLockStateFsm.pAdaptFsm.pFsm.Event("reset")
}
}
if pLSStatemachine != nil {
if pLSStatemachine.Is("disabled") {
if err := pLSStatemachine.Event("start"); err != nil {
logger.Warnw("LockStateFSM: can't start", log.Fields{"err": err})
// maybe try a FSM reset and then again ... - TODO!!!
} else {
/***** LockStateFSM started */
logger.Debugw("LockStateFSM started", log.Fields{
"state": pLSStatemachine.Current(), "deviceID": dh.deviceID})
}
} else {
logger.Warnw("wrong state of LockStateFSM - want: disabled", log.Fields{
"have": pLSStatemachine.Current(), "deviceID": dh.deviceID})
// maybe try a FSM reset and then again ... - TODO!!!
}
} else {
logger.Errorw("LockStateFSM StateMachine invalid - cannot be executed!!", log.Fields{"deviceID": dh.deviceID})
// maybe try a FSM reset and then again ... - TODO!!!
}
}
/* *********************************************************** */
func genMacFromOctets(a_octets [6]uint8) string {
return fmt.Sprintf("%02x:%02x:%02x:%02x:%02x:%02x",
a_octets[5], a_octets[4], a_octets[3],
a_octets[2], a_octets[1], a_octets[0])
}
//copied from OLT Adapter: unify centrally ?
func macAddressToUint32Array(mac string) []uint32 {
slist := strings.Split(mac, ":")
result := make([]uint32, len(slist))
var err error
var tmp int64
for index, val := range slist {
if tmp, err = strconv.ParseInt(val, 16, 32); err != nil {
return []uint32{1, 2, 3, 4, 5, 6}
}
result[index] = uint32(tmp)
}
return result
}