blob: 5b070ab27066a639fcc725907fe220b9d84133e6 [file] [log] [blame]
/*
* Copyright 2021-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"
"errors"
"fmt"
"github.com/looplab/fsm"
"github.com/opencord/omci-lib-go"
me "github.com/opencord/omci-lib-go/generated"
"github.com/opencord/voltha-lib-go/v4/pkg/events/eventif"
"github.com/opencord/voltha-lib-go/v4/pkg/log"
"github.com/opencord/voltha-protos/v4/go/voltha"
"reflect"
"sync"
"time"
)
const (
circuitPackClassID = me.CircuitPackClassID
physicalPathTerminationPointEthernetUniClassID = me.PhysicalPathTerminationPointEthernetUniClassID
onuGClassID = me.OnuGClassID
aniGClassID = me.AniGClassID
defaultTimeoutDelay = 10
alarmBitMapSizeBytes = 28
)
const (
// events of alarm sync FSM
asEvStart = "asEvStart"
asEvStop = "asEvStop"
asEvAudit = "asEvAudit"
asEvSync = "asEvSync"
asEvSuccess = "asEvSuccess"
asEvFailure = "asEvFailure"
asEvResync = "asEvResync"
)
const (
// states of alarm sync FSM
asStStarting = "asStStarting"
asStDisabled = "asStDisabled"
asStInSync = "asStInSync"
asStAuditing = "asStAuditing"
asStResynchronizing = "asStResynchronizing"
asStIdle = "asStIdle"
)
//const cAsFsmIdleState = asStIdle not using idle state currently
type alarmInfo struct {
classID me.ClassID
instanceID uint16
alarmNo uint8
}
type alarms map[alarmInfo]struct{}
type meAlarmKey struct {
classID me.ClassID
instanceID uint16
}
type alarmBitMapDB map[meAlarmKey][alarmBitMapSizeBytes]byte
type onuAlarmManager struct {
pDeviceHandler *deviceHandler
eventProxy eventif.EventProxy
stopProcessingOmciMessages chan bool
eventChannel chan Message
onuAlarmManagerLock sync.RWMutex
processMessage bool
activeAlarms alarms
alarmBitMapDB alarmBitMapDB
onuEventsList map[onuDevice]onuDeviceEvent
lastAlarmSequence uint8
alarmSyncFsm *AdapterFsm
oltDbCopy alarmBitMapDB
onuDBCopy alarmBitMapDB
bufferedNotifications []*omci.AlarmNotificationMsg
alarmUploadSeqNo uint16
alarmUploadNoOfCmds uint16
stopAlarmAuditTimer chan struct{}
}
type onuDevice struct {
classID me.ClassID
alarmno uint8
}
type onuDeviceEvent struct {
EventName string
EventCategory eventif.EventCategory
EventSubCategory eventif.EventSubCategory
EventDescription string
}
func newAlarmManager(ctx context.Context, dh *deviceHandler) *onuAlarmManager {
var alarmManager onuAlarmManager
logger.Debugw(ctx, "init-alarm-manager", log.Fields{"device-id": dh.deviceID})
alarmManager.pDeviceHandler = dh
alarmManager.eventProxy = dh.EventProxy // Or event proxy should be on cluster address ??
alarmManager.eventChannel = make(chan Message)
alarmManager.stopProcessingOmciMessages = make(chan bool)
alarmManager.processMessage = false
alarmManager.activeAlarms = make(map[alarmInfo]struct{})
alarmManager.alarmBitMapDB = make(map[meAlarmKey][alarmBitMapSizeBytes]byte)
alarmManager.stopAlarmAuditTimer = make(chan struct{})
alarmManager.onuEventsList = map[onuDevice]onuDeviceEvent{
{classID: circuitPackClassID, alarmno: 0}: {EventName: "ONU_EQUIPMENT",
EventCategory: voltha.EventCategory_EQUIPMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu equipment"},
{classID: circuitPackClassID, alarmno: 2}: {EventName: "ONU_SELF_TEST_FAIL",
EventCategory: voltha.EventCategory_EQUIPMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu self-test failure"},
{classID: circuitPackClassID, alarmno: 3}: {EventName: "ONU_LASER_EOL",
EventCategory: voltha.EventCategory_EQUIPMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu laser EOL"},
{classID: circuitPackClassID, alarmno: 4}: {EventName: "ONU_TEMP_YELLOW",
EventCategory: voltha.EventCategory_ENVIRONMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu temperature yellow"},
{classID: circuitPackClassID, alarmno: 5}: {EventName: "ONU_TEMP_RED",
EventCategory: voltha.EventCategory_ENVIRONMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu temperature red"},
{classID: physicalPathTerminationPointEthernetUniClassID, alarmno: 0}: {EventName: "ONU_Ethernet_UNI", EventCategory: voltha.EventCategory_EQUIPMENT,
EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "LAN Loss Of Signal"},
{classID: onuGClassID, alarmno: 0}: {EventName: "ONU_EQUIPMENT",
EventCategory: voltha.EventCategory_EQUIPMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu equipment"},
{classID: onuGClassID, alarmno: 6}: {EventName: "ONU_SELF_TEST_FAIL",
EventCategory: voltha.EventCategory_EQUIPMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu self-test failure"},
{classID: onuGClassID, alarmno: 7}: {EventName: "ONU_DYING_GASP",
EventCategory: voltha.EventCategory_EQUIPMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu DYING_GASP"},
{classID: onuGClassID, alarmno: 8}: {EventName: "ONU_TEMP_YELLOW",
EventCategory: voltha.EventCategory_ENVIRONMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu temperature yellow"},
{classID: onuGClassID, alarmno: 9}: {EventName: "ONU_TEMP_RED",
EventCategory: voltha.EventCategory_ENVIRONMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu temperature red"},
{classID: onuGClassID, alarmno: 10}: {EventName: "ONU_VOLTAGE_YELLOW",
EventCategory: voltha.EventCategory_ENVIRONMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu voltage yellow"},
{classID: onuGClassID, alarmno: 11}: {EventName: "ONU_VOLTAGE_RED",
EventCategory: voltha.EventCategory_ENVIRONMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu voltage red"},
{classID: aniGClassID, alarmno: 0}: {EventName: "ONU_LOW_RX_OPTICAL",
EventCategory: voltha.EventCategory_COMMUNICATION, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu low rx optical power"},
{classID: aniGClassID, alarmno: 1}: {EventName: "ONU_HIGH_RX_OPTICAL",
EventCategory: voltha.EventCategory_COMMUNICATION, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu high rx optical power"},
{classID: aniGClassID, alarmno: 4}: {EventName: "ONU_LOW_TX_OPTICAL",
EventCategory: voltha.EventCategory_COMMUNICATION, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu low tx optical power"},
{classID: aniGClassID, alarmno: 5}: {EventName: "ONU_HIGH_TX_OPTICAL",
EventCategory: voltha.EventCategory_COMMUNICATION, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu high tx optical power"},
{classID: aniGClassID, alarmno: 6}: {EventName: "ONU_LASER_BIAS_CURRENT",
EventCategory: voltha.EventCategory_EQUIPMENT, EventSubCategory: voltha.EventSubCategory_ONU, EventDescription: "onu laser bias current"},
}
alarmManager.alarmSyncFsm = NewAdapterFsm("AlarmSync", dh.deviceID, alarmManager.eventChannel)
alarmManager.alarmSyncFsm.pFsm = fsm.NewFSM(
asStDisabled,
fsm.Events{
{Name: asEvStart, Src: []string{asStDisabled}, Dst: asStStarting},
{Name: asEvAudit, Src: []string{asStStarting, asStInSync}, Dst: asStAuditing},
{Name: asEvSync, Src: []string{asStStarting}, Dst: asStInSync},
{Name: asEvSuccess, Src: []string{asStAuditing, asStResynchronizing}, Dst: asStInSync},
{Name: asEvFailure, Src: []string{asStAuditing, asStResynchronizing}, Dst: asStAuditing},
{Name: asEvResync, Src: []string{asStAuditing}, Dst: asStResynchronizing},
{Name: asEvStop, Src: []string{asStDisabled, asStStarting, asStAuditing, asStInSync, asStIdle, asStResynchronizing}, Dst: asStDisabled},
},
fsm.Callbacks{
"enter_state": func(e *fsm.Event) { alarmManager.alarmSyncFsm.logFsmStateChange(ctx, e) },
"enter_" + asStStarting: func(e *fsm.Event) { alarmManager.asFsmStarting(ctx, e) },
"enter_" + asStAuditing: func(e *fsm.Event) { alarmManager.asFsmAuditing(ctx, e) },
"enter_" + asStInSync: func(e *fsm.Event) { alarmManager.asFsmInSync(ctx, e) },
"enter_" + asStResynchronizing: func(e *fsm.Event) { alarmManager.asFsmResynchronizing(ctx, e) },
},
)
return &alarmManager
}
func (am *onuAlarmManager) asFsmStarting(ctx context.Context, e *fsm.Event) {
logger.Debugw(ctx, "alarm-sync-fsm-start-processing-msgs-in-state", log.Fields{"state": e.FSM.Current(), "device-id": am.pDeviceHandler.deviceID})
go am.processAlarmSyncMessages(ctx)
// Start the first audit, if audit interval configured, else reach the sync state
if am.pDeviceHandler.pOnuOmciDevice.alarmAuditInterval > 0 {
select {
//Transition into auditing state, using a very shorter timeout delay here, hence it is the first audit
case <-time.After(defaultTimeoutDelay * time.Second):
go func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvAudit); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-auditing", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}()
case <-am.stopAlarmAuditTimer:
logger.Infow(ctx, "stopping-alarm-timer", log.Fields{"device-id": am.pDeviceHandler.deviceID})
return
}
} else {
// Transition into sync state directly.
go func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvSync); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-sync", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}()
}
}
func (am *onuAlarmManager) asFsmAuditing(ctx context.Context, e *fsm.Event) {
logger.Debugw(ctx, "alarm-sync-fsm-start-auditing", log.Fields{"state": e.FSM.Current(), "device-id": am.pDeviceHandler.deviceID})
// Always reset the buffered notifications and db copies before starting the audit
am.onuAlarmManagerLock.Lock()
am.bufferedNotifications = make([]*omci.AlarmNotificationMsg, 0)
am.oltDbCopy = make(map[meAlarmKey][alarmBitMapSizeBytes]byte)
am.onuDBCopy = make(map[meAlarmKey][alarmBitMapSizeBytes]byte)
am.onuAlarmManagerLock.Unlock()
failureTransition := func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvFailure); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-failure", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}
if err := am.pDeviceHandler.pOnuOmciDevice.PDevOmciCC.sendGetAllAlarm(log.WithSpanFromContext(context.TODO(), ctx), 0,
am.pDeviceHandler.pOpenOnuAc.omciTimeout, true); err != nil {
// Transition to failure so that alarm sync can be restarted again
go failureTransition()
}
}
func (am *onuAlarmManager) asFsmResynchronizing(ctx context.Context, e *fsm.Event) {
logger.Debugw(ctx, "alarm-sync-fsm", log.Fields{"state": e.FSM.Current(), "device-id": am.pDeviceHandler.deviceID})
failureTransition := func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvFailure); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-failure", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}
// See if there is any onu only diff, meaning the class and entity is only in onu DB
for alarm := range am.onuDBCopy {
if _, exists := am.oltDbCopy[meAlarmKey{
classID: alarm.classID,
instanceID: alarm.instanceID,
}]; !exists {
// We need to raise all such alarms as OLT wont have received notification for these alarms
omciAlarmMessage := &omci.AlarmNotificationMsg{
MeBasePacket: omci.MeBasePacket{
EntityClass: alarm.classID,
EntityInstance: alarm.instanceID,
},
AlarmBitmap: am.onuDBCopy[alarm],
}
if err := am.processAlarmData(ctx, omciAlarmMessage); err != nil {
logger.Errorw(ctx, "unable-to-process-alarm-notification", log.Fields{"device-id": am.pDeviceHandler.deviceID})
// Transition to failure.
go failureTransition()
return
}
}
}
// See if there is any olt only diff, meaning the class and entity is only in olt DB
for alarm := range am.oltDbCopy {
if _, exists := am.onuDBCopy[meAlarmKey{
classID: alarm.classID,
instanceID: alarm.instanceID,
}]; !exists {
// We need to clear all such alarms as OLT might have stale data and the alarms are already cleared.
omciAlarmMessage := &omci.AlarmNotificationMsg{
MeBasePacket: omci.MeBasePacket{
EntityClass: alarm.classID,
EntityInstance: alarm.instanceID,
},
AlarmBitmap: am.oltDbCopy[alarm],
}
if err := am.processAlarmData(ctx, omciAlarmMessage); err != nil {
logger.Errorw(ctx, "unable-to-process-alarm-notification", log.Fields{"device-id": am.pDeviceHandler.deviceID})
// Transition to failure
go failureTransition()
return
}
}
}
// See if there is any attribute difference
for alarm := range am.onuDBCopy {
if _, exists := am.oltDbCopy[alarm]; exists {
if am.onuDBCopy[alarm] != am.oltDbCopy[alarm] {
omciAlarmMessage := &omci.AlarmNotificationMsg{
MeBasePacket: omci.MeBasePacket{
EntityClass: alarm.classID,
EntityInstance: alarm.instanceID,
},
AlarmBitmap: am.onuDBCopy[alarm],
}
// We will assume that onudb is correct always in this case and process the changed bitmap.
if err := am.processAlarmData(ctx, omciAlarmMessage); err != nil {
logger.Errorw(ctx, "unable-to-process-alarm-notification", log.Fields{"device-id": am.pDeviceHandler.deviceID})
// Transition to failure
go failureTransition()
return
}
}
}
}
// Send the buffered notifications if no failure.
for _, notif := range am.bufferedNotifications {
logger.Debugw(ctx, "processing-buffered-alarm-notification", log.Fields{"device-id": am.pDeviceHandler.deviceID,
"notification": notif})
if err := am.processAlarmData(ctx, notif); err != nil {
logger.Errorw(ctx, "unable-to-process-alarm-notification", log.Fields{"device-id": am.pDeviceHandler.deviceID})
go failureTransition()
}
}
go func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvSuccess); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-sync", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}()
}
func (am *onuAlarmManager) asFsmInSync(ctx context.Context, e *fsm.Event) {
logger.Debugw(ctx, "alarm-sync-fsm", log.Fields{"state": e.FSM.Current(), "device-id": am.pDeviceHandler.deviceID})
if am.pDeviceHandler.pOnuOmciDevice.alarmAuditInterval > 0 {
select {
case <-time.After(am.pDeviceHandler.pOnuOmciDevice.alarmAuditInterval):
go func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvAudit); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-auditing", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}()
case <-am.stopAlarmAuditTimer:
logger.Infow(ctx, "stopping-alarm-timer", log.Fields{"device-id": am.pDeviceHandler.deviceID})
return
}
}
}
func (am *onuAlarmManager) processAlarmSyncMessages(ctx context.Context) {
logger.Debugw(ctx, "start-routine-to-process-omci-messages-for-alarm-sync", log.Fields{"device-id": am.pDeviceHandler.deviceID})
for {
select {
case message, ok := <-am.eventChannel:
if !ok {
logger.Info(ctx, "alarm-sync-omci-message-could-not-be-read-from-channel", log.Fields{"device-id": am.pDeviceHandler.deviceID})
continue
}
logger.Debugw(ctx, "alarm-sync-omci-message-received", log.Fields{"device-id": am.pDeviceHandler.deviceID})
switch message.Type {
case OMCI:
msg, _ := message.Data.(OmciMessage)
am.handleOmciMessage(ctx, msg)
default:
logger.Warn(ctx, "alarm-sync-unknown-message-type-received", log.Fields{"device-id": am.pDeviceHandler.deviceID, "message.Type": message.Type})
}
case <-am.stopProcessingOmciMessages:
logger.Infow(ctx, "alarm-manager-stop-omci-alarm-message-processing-routines", log.Fields{"device-id": am.pDeviceHandler.deviceID})
am.onuAlarmManagerLock.Lock()
am.processMessage = false
am.activeAlarms = nil
am.alarmBitMapDB = nil
am.alarmUploadNoOfCmds = 0
am.alarmUploadSeqNo = 0
am.onuAlarmManagerLock.Unlock()
return
}
}
}
func (am *onuAlarmManager) handleOmciMessage(ctx context.Context, msg OmciMessage) {
logger.Debugw(ctx, "alarm-sync-omci-message-received", log.Fields{"device-id": am.pDeviceHandler.deviceID,
"msg-type": msg.OmciMsg.MessageType, "msg": msg})
switch msg.OmciMsg.MessageType {
case omci.GetAllAlarmsResponseType:
am.handleOmciGetAllAlarmsResponseMessage(ctx, msg)
case omci.GetAllAlarmsNextResponseType:
am.handleOmciGetAllAlarmNextResponseMessage(ctx, msg)
default:
logger.Warnw(ctx, "unknown-message-type", log.Fields{"msg-type": msg.OmciMsg.MessageType})
}
}
func (am *onuAlarmManager) handleOmciGetAllAlarmsResponseMessage(ctx context.Context, msg OmciMessage) {
msgLayer := (*msg.OmciPacket).Layer(omci.LayerTypeGetAllAlarmsResponse)
if msgLayer == nil {
logger.Errorw(ctx, "omci-msg-layer-could-not-be-detected", log.Fields{"device-id": am.pDeviceHandler.deviceID})
return
}
msgObj, msgOk := msgLayer.(*omci.GetAllAlarmsResponse)
if !msgOk {
logger.Errorw(ctx, "omci-msg-layer-could-not-be-assigned", log.Fields{"device-id": am.pDeviceHandler.deviceID})
return
}
logger.Debugw(ctx, "get-all-alarm-response-data", log.Fields{"device-id": am.pDeviceHandler.deviceID, "data-fields": msgObj})
if am.alarmSyncFsm.pFsm.Is(asStDisabled) {
logger.Debugw(ctx, "alarm-sync-fsm-is-disabled-ignoring-response-message", log.Fields{"device-id": am.pDeviceHandler.deviceID, "data-fields": msgObj})
return
}
am.alarmUploadNoOfCmds = msgObj.NumberOfCommands
failureTransition := func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvFailure); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-failure", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}
if am.alarmUploadSeqNo < am.alarmUploadNoOfCmds {
// Reset Onu Alarm Sequence
am.onuAlarmManagerLock.Lock()
am.resetAlarmSequence()
// Get a copy of the alarm bit map db.
for alarms, bitmap := range am.alarmBitMapDB {
am.oltDbCopy[alarms] = bitmap
}
am.onuAlarmManagerLock.Unlock()
if err := am.pDeviceHandler.pOnuOmciDevice.PDevOmciCC.sendGetAllAlarmNext(
log.WithSpanFromContext(context.TODO(), ctx), am.pDeviceHandler.pOpenOnuAc.omciTimeout, true); err != nil {
// Transition to failure
go failureTransition()
}
} else if am.alarmUploadNoOfCmds == 0 {
// Reset Onu Alarm Sequence
am.onuAlarmManagerLock.Lock()
am.resetAlarmSequence()
// Get a copy of the alarm bit map db.
for alarms, bitmap := range am.alarmBitMapDB {
am.oltDbCopy[alarms] = bitmap
}
am.onuAlarmManagerLock.Unlock()
if am.isAlarmDBDiffPresent(ctx) {
// transition to resync state
go func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvResync); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-resynchronizing", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}()
} else {
// Transition to sync state
go func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvSuccess); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-sync", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}()
}
} else {
logger.Errorw(ctx, "invalid-number-of-commands-received", log.Fields{"device-id": am.pDeviceHandler.deviceID,
"upload-no-of-cmds": am.alarmUploadNoOfCmds, "upload-seq-no": am.alarmUploadSeqNo})
go failureTransition()
}
}
func (am *onuAlarmManager) handleOmciGetAllAlarmNextResponseMessage(ctx context.Context, msg OmciMessage) {
msgLayer := (*msg.OmciPacket).Layer(omci.LayerTypeGetAllAlarmsNextResponse)
if msgLayer == nil {
logger.Errorw(ctx, "omci-msg-layer-could-not-be-detected", log.Fields{"device-id": am.pDeviceHandler.deviceID})
return
}
msgObj, msgOk := msgLayer.(*omci.GetAllAlarmsNextResponse)
if !msgOk {
logger.Errorw(ctx, "omci-msg-layer-could-not-be-assigned", log.Fields{"device-id": am.pDeviceHandler.deviceID})
return
}
logger.Debugw(ctx, "get-all-alarms-next-response-data",
log.Fields{"device-id": am.pDeviceHandler.deviceID, "data-fields": msgObj})
meClassID := msgObj.AlarmEntityClass
meEntityID := msgObj.AlarmEntityInstance
meAlarmBitMap := msgObj.AlarmBitMap
am.onuAlarmManagerLock.Lock()
am.onuDBCopy[meAlarmKey{
classID: meClassID,
instanceID: meEntityID,
}] = meAlarmBitMap
am.onuAlarmManagerLock.Unlock()
failureTransition := func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvFailure); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-failure", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}
if am.alarmUploadSeqNo < am.alarmUploadNoOfCmds {
if err := am.pDeviceHandler.pOnuOmciDevice.PDevOmciCC.sendGetAllAlarmNext(
log.WithSpanFromContext(context.TODO(), ctx), am.pDeviceHandler.pOpenOnuAc.omciTimeout, true); err != nil {
// Transition to failure
go failureTransition()
} //TODO: needs to handle timeouts
} else {
if am.isAlarmDBDiffPresent(ctx) {
// transition to resync state
go func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvResync); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-resynchronizing", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}()
} else {
// Transition to sync state
go func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvSuccess); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-sync", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}()
}
}
}
func (am *onuAlarmManager) startOMCIAlarmMessageProcessing(ctx context.Context) {
logger.Infow(ctx, "alarm-manager-start-omci-alarm-message-processing-routines", log.Fields{"device-id": am.pDeviceHandler.deviceID})
am.onuAlarmManagerLock.Lock()
am.processMessage = true
if am.activeAlarms == nil {
am.activeAlarms = make(map[alarmInfo]struct{})
}
am.alarmBitMapDB = make(map[meAlarmKey][alarmBitMapSizeBytes]byte)
am.onuAlarmManagerLock.Unlock()
am.flushAlarmSyncChannels(ctx) // Need to do this first as there might be stale data on the channels and the start state waits on same channels
if am.alarmSyncFsm.pFsm.Is(asStDisabled) {
if err := am.alarmSyncFsm.pFsm.Event(asEvStart); err != nil {
logger.Errorw(ctx, "alarm-sync-fsm-can-not-go-to-state-starting", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
return
}
} else {
logger.Errorw(ctx, "wrong-state-of-alarm-sync-fsm-want-disabled", log.Fields{"state": string(am.alarmSyncFsm.pFsm.Current()),
"device-id": am.pDeviceHandler.deviceID})
return
}
logger.Debugw(ctx, "alarm-sync-fsm-started", log.Fields{"state": string(am.alarmSyncFsm.pFsm.Current())})
}
func (am *onuAlarmManager) handleOmciAlarmNotificationMessage(ctx context.Context, msg OmciMessage) {
logger.Debugw(ctx, "omci-alarm-notification-msg", log.Fields{"device-id": am.pDeviceHandler.deviceID,
"msg-type": msg.OmciMsg.MessageType})
am.onuAlarmManagerLock.RLock()
processMessage := am.processMessage
am.onuAlarmManagerLock.RUnlock()
if processMessage {
msgLayer := (*msg.OmciPacket).Layer(omci.LayerTypeAlarmNotification)
if msgLayer == nil {
logger.Errorw(ctx, "omci-msg-layer-could-not-be-detected-for-alarm-notification",
log.Fields{"device-id": am.pDeviceHandler.deviceID})
return
}
msgObj, msgOk := msgLayer.(*omci.AlarmNotificationMsg)
if !msgOk {
logger.Errorw(ctx, "omci-msg-layer-could-not-be-assigned-for-alarm-notification",
log.Fields{"device-id": am.pDeviceHandler.deviceID})
return
}
//Alarm Notification decoding at omci lib validates that the me class ID supports the
// alarm notifications.
logger.Debugw(ctx, "alarm-notification-data", log.Fields{"device-id": am.pDeviceHandler.deviceID, "data-fields": msgObj})
if err := am.processAlarmData(ctx, msgObj); err != nil {
logger.Errorw(ctx, "unable-to-process-alarm-notification", log.Fields{"device-id": am.pDeviceHandler.deviceID})
}
} else {
logger.Warnw(ctx, "ignoring-alarm-notification-received-for-me-as-channel-for-processing-is-closed",
log.Fields{"device-id": am.pDeviceHandler.deviceID})
}
}
func (am *onuAlarmManager) processAlarmData(ctx context.Context, msg *omci.AlarmNotificationMsg) error {
classID := msg.EntityClass
sequenceNo := msg.AlarmSequenceNumber
meInstance := msg.EntityInstance
alarmBitmap := msg.AlarmBitmap
logger.Debugw(ctx, "processing-alarm-data", log.Fields{"class-id": classID, "instance-id": meInstance,
"alarmBitMap": alarmBitmap, "sequence-no": sequenceNo})
if _, present := am.pDeviceHandler.pOnuOmciDevice.pOnuDB.meDb[classID][meInstance]; !present {
logger.Errorw(ctx, "me-class-instance-not-present", log.Fields{"class-id": classID, "instance-id": meInstance})
return fmt.Errorf("me-class-%d-instance-%d-not-present", classID, meInstance)
}
am.onuAlarmManagerLock.Lock()
defer am.onuAlarmManagerLock.Unlock()
if sequenceNo > 0 {
if am.alarmSyncFsm.pFsm.Is(asStAuditing) || am.alarmSyncFsm.pFsm.Is(asStResynchronizing) {
am.bufferedNotifications = append(am.bufferedNotifications, msg)
logger.Debugw(ctx, "adding-notification-to-buffered-notification-list", log.Fields{"device-id": am.pDeviceHandler.deviceID,
"notification": msg})
return nil
}
am.incrementAlarmSequence()
if sequenceNo != am.lastAlarmSequence && am.pDeviceHandler.pOnuOmciDevice.alarmAuditInterval > 0 {
// signal early audit, if no match(if we are reaching here it means that audit is not going on currently)
go func() {
if err := am.alarmSyncFsm.pFsm.Event(asEvAudit); err != nil {
logger.Debugw(ctx, "alarm-sync-fsm-cannot-go-to-state-auditing", log.Fields{"device-id": am.pDeviceHandler.deviceID, "err": err})
}
}()
}
}
entity, omciErr := me.LoadManagedEntityDefinition(classID,
me.ParamData{EntityID: meInstance})
if omciErr.StatusCode() != me.Success {
//log error and return
logger.Error(ctx, "unable-to-get-managed-entity", log.Fields{"class-id": classID, "instance-id": meInstance})
return fmt.Errorf("unable-to-get-managed-entity-class-%d-instance-%d", classID, meInstance)
}
meAlarmMap := entity.GetAlarmMap()
if meAlarmMap == nil {
logger.Error(ctx, "unable-to-get-managed-entity-alarm-map", log.Fields{"class-id": classID, "instance-id": meInstance})
return fmt.Errorf("unable-to-get-managed-entity-alarm-map-%d-instance-%d", classID, meInstance)
}
am.alarmBitMapDB[meAlarmKey{
classID: classID,
instanceID: meInstance,
}] = alarmBitmap
// Loop over the supported alarm list for this me
for alarmNo := range meAlarmMap {
// Check if alarmNo was previously active in the alarms, if yes clear it and remove it from active alarms
_, exists := am.activeAlarms[alarmInfo{
classID: classID,
instanceID: meInstance,
alarmNo: alarmNo,
}]
if exists {
// Clear this alarm if It is cleared now, in that case IsAlarmClear would return true
cleared, err := msg.IsAlarmClear(alarmNo)
if err != nil {
logger.Warnw(ctx, "unable-to-find-out-alarm-is-cleared", log.Fields{"class-id": classID,
"instance-id": meInstance, "alarm-no": alarmNo})
return err
}
if cleared {
// Clear this alarm.
am.clearAlarm(ctx, classID, meInstance, alarmNo)
}
} else {
// If alarm entry was not present in the list of active alarms, we need to see if this alarm is now active
// or not, if yes then raise it.
raised, err := msg.IsAlarmActive(alarmNo)
if err != nil {
logger.Warnw(ctx, "unable-to-find-out-alarm-is-raised", log.Fields{"class-id": classID,
"instance-id": meInstance, "alarm-no": alarmNo})
return err
}
if raised {
am.raiseAlarm(ctx, classID, meInstance, alarmNo)
}
}
}
return nil
}
func (am *onuAlarmManager) raiseAlarm(ctx context.Context, classID me.ClassID, instanceID uint16, alarm uint8) {
am.activeAlarms[alarmInfo{
classID: classID,
instanceID: instanceID,
alarmNo: alarm,
}] = struct{}{}
go am.sendAlarm(ctx, classID, instanceID, alarm, true)
}
func (am *onuAlarmManager) clearAlarm(ctx context.Context, classID me.ClassID, instanceID uint16, alarm uint8) {
go am.sendAlarm(ctx, classID, instanceID, alarm, false)
delete(am.activeAlarms, alarmInfo{
classID: classID,
instanceID: instanceID,
alarmNo: alarm,
})
key := meAlarmKey{
classID: classID,
instanceID: instanceID,
}
if am.alarmBitMapDB[key] == [alarmBitMapSizeBytes]byte{0} {
delete(am.alarmBitMapDB, key)
}
}
func (am *onuAlarmManager) getIntfIDAlarm(ctx context.Context, classID me.ClassID, instanceID uint16) *uint32 {
var intfID *uint32
if classID == circuitPackClassID || classID == physicalPathTerminationPointEthernetUniClassID {
for _, uniPort := range am.pDeviceHandler.uniEntityMap {
if uniPort.entityID == instanceID {
intfID = &uniPort.portNo
return intfID
}
}
} else if classID == aniGClassID || classID == onuGClassID {
intfID = &am.pDeviceHandler.ponPortNumber
return intfID
} else {
logger.Warnw(ctx, "me-not-supported", log.Fields{"class-id": classID, "instance-id": instanceID})
}
return nil
}
func (am *onuAlarmManager) sendAlarm(ctx context.Context, classID me.ClassID, instanceID uint16, alarm uint8, raised bool) {
context := make(map[string]string)
intfID := am.getIntfIDAlarm(ctx, classID, instanceID)
onuID := am.pDeviceHandler.deviceID
serialNo := am.pDeviceHandler.pOnuOmciDevice.sOnuPersistentData.PersSerialNumber
if intfID == nil {
logger.Warn(ctx, "intf-id-for-alarm-not-found", log.Fields{"alarm-no": alarm, "class-id": classID})
return
}
context["onu-intf-id"] = fmt.Sprintf("%d", *intfID)
context["onu-id"] = onuID
context["onu-serial-number"] = serialNo
raisedTimestamp := time.Now().UnixNano()
eventDetails, err := am.getDeviceEventData(ctx, classID, alarm)
if err != nil {
logger.Warn(ctx, "event-details-for-alarm-not-found", log.Fields{"alarm-no": alarm, "class-id": classID})
return
}
suffixDesc := "Raised"
if !raised {
suffixDesc = "Cleared"
}
deviceEvent := &voltha.DeviceEvent{
ResourceId: onuID,
DeviceEventName: fmt.Sprintf("%s_RAISE_EVENT", eventDetails.EventName),
Description: fmt.Sprintf("%s Event - %s - %s", eventDetails.EventDescription, eventDetails.EventName,
suffixDesc),
Context: context,
}
_ = am.eventProxy.SendDeviceEvent(ctx, deviceEvent, eventDetails.EventCategory, eventDetails.EventSubCategory,
raisedTimestamp)
}
func (am *onuAlarmManager) isAlarmDBDiffPresent(ctx context.Context) bool {
return !reflect.DeepEqual(am.onuDBCopy, am.oltDbCopy)
}
func (am *onuAlarmManager) incrementAlarmSequence() {
//alarm sequence number wraps from 255 to 1.
if am.lastAlarmSequence == 255 {
am.lastAlarmSequence = 1
} else {
am.lastAlarmSequence++
}
}
func (am *onuAlarmManager) resetAlarmSequence() {
am.lastAlarmSequence = 0
}
// flushAlarmSyncChannels flushes all alarm sync channels to discard any previous response
func (am *onuAlarmManager) flushAlarmSyncChannels(ctx context.Context) {
// flush alarm sync channel
select {
case <-am.eventChannel:
logger.Debug(ctx, "flushed-alarm-sync-channel")
default:
}
select {
case <-am.stopAlarmAuditTimer:
logger.Debug(ctx, "flushed-alarm-audit-timer-channel")
default:
}
}
// getDeviceEventData returns the event data for a device
func (am *onuAlarmManager) getDeviceEventData(ctx context.Context, classID me.ClassID, alarmNo uint8) (onuDeviceEvent, error) {
if onuEventDetails, ok := am.onuEventsList[onuDevice{classID: classID, alarmno: alarmNo}]; ok {
return onuEventDetails, nil
}
return onuDeviceEvent{}, errors.New("onu Event Detail not found")
}