Table of Contents - JUNOS 10.1 High Availability Configuration Guide

About This Guide

JUNOS Documentation and Release Notes
Objectives
Audience
Supported Platforms
Using the Indexes
Using the Examples in This Manual
Documentation Conventions
Documentation Feedback
Requesting Technical Support

Overview

High Availability Overview

Introducing High Availability Features on Juniper Networks Routing Platforms

Routing Engine Redundancy
Graceful Routing Engine Switchover
Nonstop Bridging
Nonstop Active Routing
Graceful Restart
Nonstop Active Routing Versus Graceful Restart
Effects of a Routing Engine Switchover
VRRP
Unified ISSU

High Availability-Related Features in JUNOS Software

Routing Engine and Switching Control Board Redundancy

Routing Engine and Switching Control Board Redundancy Overview

Understanding Routing Engine Redundancy on Juniper Networks Routers

Routing Engine Redundancy Overview
Conditions That Trigger a Routing Engine Failover
Default Routing Engine Redundancy Behavior
Routing Engine Redundancy on a TX Matrix Router
Situations That Require You to Halt Routing Engines

Switching Control Board Redundancy

Redundant CFEBs on the M10i Router
Redundant FEBs on the M120 Router
Redundant SSBs on the M20 Router
Redundant SFMs on the M40e and M160 Routers

Routing Engine and Switching Control Board Redundancy Configuration Guidelines

Chassis Redundancy Hierarchy

Initial Routing Engine Configuration Example

Copying a Configuration File from One Routing Engine to the Other

Loading a Software Package from the Other Routing Engine

Configuring Routing Engine Redundancy

Modifying the Default Routing Engine Mastership

Configuring Automatic Failover to the Backup Routing Engine

Without Interruption to Packet Forwarding
On Detection of a Hard Disk Error on the Master Routing Engine
On Detection of a Loss of Keepalive Signal from the Master Routing Engine
When a Software Process Fails

Manually Switching Routing Engine Mastership

Verifying Routing Engine Redundancy Status

Configuring CFEB Redundancy on the M10i Router

Configuring FEB Redundancy on the M120 Router

Example: Configuring FEB Redundancy

Configuring SFM Redundancy on M40e and M160 Routers

Configuring SSB Redundancy on the M20 Router

Summary of Routing Engine and Switching Control Board Redundancy Statements

cfeb

description

failover on-disk-failure

failover on-loss-of-keepalives

failover other-routing-engine

feb

feb (Creating a Redundancy Group)
feb (Assigning a FEB to a Redundancy Group)

Graceful Routing Engine Switchover

Graceful Routing Engine Switchover Overview

Understanding Graceful Routing Engine Switchover in the JUNOS Software

Graceful Routing Engine Switchover Concepts
Effects of a Routing Engine Switchover

Graceful Routing Engine Switchover System Requirements

Graceful Routing Engine Switchover Platform Support
Graceful Routing Engine Switchover Feature Support
Graceful Routing Engine Switchover DPC Support
Graceful Routing Engine Switchover and Subscriber Access
Graceful Routing Engine Switchover PIC Support

Graceful Routing Engine Switchover Configuration Guidelines

Configuring Graceful Routing Engine Switchover

Enabling Graceful Routing Engine Switchover
Synchronizing the Routing Engine Configuration
Verifying Graceful Routing Engine Switchover Operation

Requirements for Routers with a Backup Router Configuration

Resetting Local Statistics

Summary of Graceful Routing Engine Switchover Configuration Statements

graceful-switchover

Nonstop Bridging

Nonstop Bridging Overview

Nonstop Bridging Concepts

Nonstop Bridging System Requirements

Platform Support
Protocol Support

Nonstop Bridging Configuration Guidelines

Configuring Nonstop Bridging

Enabling Nonstop Bridging
Synchronizing the Routing Engine Configuration
Verifying Nonstop Bridging Operation

Summary of Nonstop Bridging Statements

nonstop-bridging

Nonstop Active Routing

Nonstop Active Routing Overview

Nonstop Active Routing Concepts

Nonstop Active Routing System Requirements

Nonstop Active Routing Platform Support
Nonstop Active Routing Protocol and Feature Support
Nonstop Active Routing BFD Support
Nonstop Active Routing BGP Support
Nonstop Active Routing Layer 2 Circuit and LDP-Based VPLS Support
Nonstop Active Routing PIM Support
Nonstop Active Routing Support for RSVP-TE LSPs

Nonstop Active Routing Configuration Guidelines

Configuring Nonstop Active Routing

Enabling Nonstop Active Routing
Synchronizing the Routing Engine Configuration
Verifying Nonstop Active Routing Operation

Tracing Nonstop Active Routing Synchronization Events

Resetting Local Statistics

Example: Configuring Nonstop Active Routing

Summary of Nonstop Active Routing Configuration Statements

commit synchronize
nonstop-routing
traceoptions

Graceful Restart

Graceful Restart Overview

Graceful Restart Concepts

Graceful Restart System Requirements

Aggregate and Static Routes

Graceful Restart and Routing Protocols

BGP
ES-IS
IS-IS
OSPF and OSPFv3
PIM Sparse Mode
RIP and RIPng

Graceful Restart and MPLS-Related Protocols

LDP
RSVP
CCC and TCC

Graceful Restart and Layer 2 and Layer 3 VPNs

Graceful Restart on Logical Systems

Graceful Restart Configuration Guidelines

Configuring Graceful Restart for Aggregate and Static Routes

Configuring Routing Protocols Graceful Restart

Configuring Graceful Restart Globally
Configuring Graceful Restart Options for BGP
Configuring Graceful Restart Options for ES-IS
Configuring Graceful Restart Options for IS-IS
Configuring Graceful Restart Options for OSPF and OSPFv3
Configuring Graceful Restart Options for RIP and RIPng
Configuring Graceful Restart Options for PIM Sparse Mode
Tracking Graceful Restart Events

Configuring Graceful Restart for MPLS-Related Protocols

Configuring Graceful Restart Globally
Configuring Graceful Restart Options for RSVP, CCC, and TCC
Configuring Graceful Restart Options for LDP

Configuring VPN Graceful Restart

Configuring Graceful Restart Globally
Configuring Graceful Restart for the Routing Instance

Configuring Logical System Graceful Restart

Configuring Graceful Restart Globally
Configuring Graceful Restart for a Routing Instance

Verifying Graceful Restart Operation

Graceful Restart Operational Mode Commands
Verifying BGP Graceful Restart
Verifying IS-IS and OSPF Graceful Restart
Verifying CCC and TCC Graceful Restart

Example: Configuring Graceful Restart

Summary of Graceful Restart Configuration Statements

disable
graceful-restart
helper-disable
maximum-helper-recovery-time
maximum-helper-restart-time
maximum-neighbor-reconnect-time
maximum-neighbor-recovery-time
no-strict-lsa-checking
notify-duration
reconnect-time
recovery-time
restart-duration
restart-time
stale-routes-time
traceoptions

Virtual Router Redundancy Protocol

VRRP Overview

Understanding VRRP

VRRP Configuration Guidelines

VRRP Configuration Hierarchy

VRRP for IPv6 Configuration Hierarchy

Configuring the Startup Period for VRRP Operations

Configuring Basic VRRP Support

Configuring VRRP Authentication (IPv4 Only)

Configuring the Advertisement Interval for the VRRP Master Router

Modifying the Advertisement Interval in Seconds
Modifying the Advertisement Interval in Milliseconds

Configuring a Backup Router to Preempt the Master Router

Modifying the Preemption Hold-Time Value

Configuring an Interface to Accept Packets Destined for the Virtual IP Address

Configuring a Logical Interface to Be Tracked

Configuring a Route to Be Tracked

Configuring Inheritance for a VRRP Group

Tracing VRRP Operations

Configuring the Silent Period

Configuring Passive ARP Learning for Backup VRRP Routers

Enabling the Distributed Periodic Packet Management Process for VRRP

Example: Configuring VRRP

Example: Configuring VRRP for IPv6

Example: Configuring VRRP Route Tracking

Summary of VRRP Configuration Statements

accept-data
advertise-interval
authentication-key
authentication-type
bandwidth-threshold
fast-interval
hold-time
inet6-advertise-interval
interface
no-accept-data
no-preempt
preempt
priority
priority-cost
priority-hold-time
route
startup-silent-period
traceoptions
track
virtual-address
virtual-inet6-address
virtual-link-local-address
vrrp-group
vrrp-inet6-group

Unified ISSU

Unified ISSU Overview

Unified ISSU Concepts

Unified ISSU Process on the TX Matrix Router

Unified ISSU System Requirements

Unified ISSU JUNOS Software Release Support

Unified ISSU Platform Support

Unified ISSU Protocol Support

Unified ISSU Support for Layer 2 Control Protocol Process

Unified ISSU Feature Support

Unified ISSU PIC Support

PIC Considerations
SONET/SDH PICs
Fast Ethernet and Gigabit Ethernet PICs
Channelized PICs
Tunnel Services PICs
ATM PICs
Serial PICs
DS3, E1, E3, and T1 PICs
Enhanced IQ PICs
Enhanced IQ2 Ethernet Services Engine (ESE) PIC

Unified ISSU DPC and FPC Support on MX Series Routers

Unified ISSU Configuration Guidelines

Best Practices

Before You Begin

Verify That the Master and Backup Routing Engines Are Running the Same Software Version
Back Up the Router Software
Verify That Graceful Routing Engine Switchover and Nonstop Active Routing Are Configured

Performing a Unified ISSU

Upgrading and Rebooting Both Routing Engines Automatically
Upgrading Both Routing Engines and Rebooting the New Backup Routing Engine Manually
Upgrading and Rebooting Only One Routing Engine

Verifying a Unified ISSU

Troubleshooting Unified ISSU Problems

Managing and Tracing BFD Sessions During Unified ISSU Procedures

Unified ISSU Configuration Statements Summary

no-issu-timer-negotiation
traceoptions

Index

Index
Index of Statements and Commands