H3C S5500-SI Series Operating instructions

Brand: H3C

Model: S5500-SI Series

Category: Networking

Type: Operating instructions

Operation Manual – IPv6 Configuration

H3C S5500-SI Series Ethernet Switches Table of Contents

Table of Contents

Chapter 1 IPv6 Configuration.......................................................................................................1-1

1.1 IPv6 Overview....................................................................................................................1-1

1.1.1 IPv6 Features..........................................................................................................1-2

1.1.2 Introduction to IPv6 Address...................................................................................1-3

1.1.3 Dual Stack Overview............................................................................................... 1-7

1.1.4 Introduction to IPv6 Neighbor Discovery Protocol .................................................. 1-7

1.1.5 IPv6 PMTU Discovery........................................................................................... 1-10

1.1.6 Introduction to IPv6 DNS....................................................................................... 1-11

1.1.7 Protocol Specifications.......................................................................................... 1-12

1.2 Configuring Basic IPv6 Functions....................................................................................1-12

1.2.1 Configuring the IPv6 Packet Forwarding Function................................................1-12

1.2.2 Configuring an IPv6 Unicast Address...................................................................1-12

1.3 Configuring IPv6 NDP...................................................................................................... 1-14

1.3.1 Configuring a Static Neighbor Entry...................................................................... 1-14

1.3.2 Configuring the Maximum Number of Neighbors Dynamically Learned...............1-15

1.3.3 Configuring Parameters Related to an RA Message............................................1-15

1.3.4 Configuring the Attempts to Send an NS Message for Duplicate Address Detection1-18

1.4 Configuring PMTU Discovery .......................................................................................... 1-19

1.4.1 Configuring a Static PMTU for a Specified IPv6 Address.....................................1-19

1.4.2 Configuring the Aging Time for PMTU.................................................................. 1-19

1.5 Configuring IPv6 TCP Properties.....................................................................................1-19

1.6 Configuring the Maximum Number of IPv6 ICMP Error Packets Sent within a Specified Time

...............................................................................................................................................1-20

1.7 Configuring IPv6 DNS...................................................................................................... 1-21

1.7.1 Configuring Static IPv6 DNS.................................................................................1-21

1.7.2 Configuring Dynamic IPv6 DNS............................................................................1-21

1.8 Displaying and Maintaining IPv6......................................................................................1-22

1.9 IPv6 Configuration Example............................................................................................1-24

Chapter 2 IPv6 Application Configuration..................................................................................2-1

2.1 Introduction to IPv6 Application.........................................................................................2-1

2.2 Ping IPv6............................................................................................................................ 2-1

2.3 Traceroute IPv6 ................................................................................................................. 2-1

2.4 FTP Configuration.............................................................................................................. 2-2

2.4.1 Configuration Prerequisites.....................................................................................2-3

2.4.2 Logging in to the FTP Server.................................................................................. 2-3

2.5 TFTP Configuration ...........................................................................................................2-4

2.5.1 Configuration Preparation....................................................................................... 2-4

Operation Manual – IPv6 Configuration

H3C S5500-SI Series Ethernet Switches Table of Contents

2.5.2 TFTP Configuration.................................................................................................2-4

2.6 IPv6 Telnet.........................................................................................................................2-5

2.6.1 Configuration Prerequisites.....................................................................................2-5

2.6.2 Setting up IPv6 Telnet Connections........................................................................2-5

2.6.3 Displaying and Maintaining IPv6 Telnet..................................................................2-6

2.7 Examples of Typical IPv6 Application Configurations ....................................................... 2-6

2.7.1 Network requirements............................................................................................. 2-6

2.7.2 Network diagram.....................................................................................................2-6

2.7.3 Configuration procedure..........................................................................................2-7

2.8 Troubleshooting IPv6 Application......................................................................................2-8

2.8.1 Unable to Ping a Remote Destination.....................................................................2-8

2.8.2 Unable to Run Traceroute.......................................................................................2-8

2.8.3 Unable to Run FTP .................................................................................................2-9

2.8.4 Unable to Run TFTP...............................................................................................2-9

2.8.5 Unable to Run Telnet..............................................................................................2-9

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Chapter 1 IPv6 Configuration

 Note:

The descriptions and examples in the text applies to both switches and routers, unless

there is a warning.

When configuring IPv6, go to these sections for information you are interested in:

z IPv6 Overview

z Configuring Basic IPv6 Functions

z Configuring IPv6 NDP

z Configuring PMTU Discovery

z Configuring IPv6 TCP Properties

z Configuring the Maximum Number of IPv6 ICMP Error Packets Sent within a

Specified Time

z Configuring IPv6 DNS

z Displaying and Maintaining IPv6

z IPv6 Configuration Example

1.1 IPv6 Overview

Internet protocol version 6 (IPv6), also called IP next generation (IPng), was designed

by the Internet Engineering Task Force (IETF) as the successor to Internet protocol

version 4 (IPv4).The significant difference between IPv6 and IPv4 is that IPv6

increases the IP address size from 32 bits to 128 bits. This section covers the following

sections:

z IPv6 Features

z Introduction to IPv6 Address

z Dual Stack Overview

z Introduction to IPv6 Neighbor Discovery Protocol

z IPv6 PMTU Discovery

z Introduction to IPv6 DNS

z Protocol Specifications

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1.1.1 IPv6 Features

I. Header format simplification

IPv6 cuts down some IPv4 header fields or move them to extension headers to reduce

the load of basic IPv6 headers, thus making IPv6 packet handling simple and improving

the forwarding efficiency. Although the IPv6 address size is four times that of IPv4

addresses, the size of basic IPv6 headers is only twice that of IPv4 headers (excluding

the Options field).

Ver

Traffic

class

Flow label

Payload length

header

Hop limit

Source

address

8 bits

Destinat

ion address

8 bits

Ver IHL Total length

Identification F Fragment offset

TTL

Source address (32 bits)

TOS

Header checksum

Destination address (32 bits)

Protocol

IPv4 header

IPv

6 header

Options Padding

0 7 15 31 0 7 15 31

Figure 1-1 Comparison between IPv4 header format and IPv6 header format

II. Adequate address space

The source IPv6 address and the destination IPv6 address are both 128 bits (16 bytes)

long.IPv6 can provide 3.4 x 10

addresses to completely meet the requirements of

hierarchical address division as well as allocation of public and private addresses.

III. Hierarchical address structure

IPv6 adopts the hierarchical address structure to quicken route search and reduce the

system source occupied by the IPv6 routing table by means of route aggregation.

IV. Automatic address configuration

To simplify the host configuration, IPv6 supports stateful address configuration and

stateless address configuration. Stateful address configuration means that a host

acquires an IPv6 address and related information from the server (for example, DHCP

server). Stateless address configuration means that the host automatically configures

an IPv6 address and related information based on its own link-layer address and the

prefix information issued by the router. In addition, a host can generate a link-local

address based on its own link-layer address and the default prefix (FE80::/64) to

communicate with other hosts on the link.

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V. Built-in security

IPv6 uses IPSec as its standard extension header to provide end-to-end security. This

feature provides a standard for network security solutions and improves the

interoperability between different IPv6 applications.

VI. Support for QoS

The Flow Label field in the IPv6 header allows the device to label packets in a flow and

provide special handling for these packets.

VII. Enhanced neighbor discovery mechanism

The IPv6 neighbor discovery protocol means a group of Internet control message

protocol version 6 (ICMPv6) messages manages the interaction between neighbor

nodes (nodes on the same link).The group of ICMPv6 messages takes the place of

address resolution protocol (ARP), Internet control message protocol version 4

(ICMPv4), and ICMPv4 redirection messages to provide a series of other functions.

VIII. Flexible extension headers

IPv6 cancels the Options field in IPv4 packets but introduces multiple extension

headers. In this way, IPv6 enhances the flexibility greatly to provide scalability for IP

while improving the processing efficiency. The Options field in IPv4 packets contains

only 40 bytes, while the size of IPv6 extension headers is restricted by that of IPv6

packets.

1.1.2 Introduction to IPv6 Address

I. IPv6 address format

An IPv6 address is represented as a series of 16-bit hexadecimals, separated by

colons. An IPv6 address is divided into eight groups, 16 bits of each group are

represented by four hexadecimal numbers which are separated by colons, for example,

2001:0000:130F:0000:0000:09C0:876A:130B.

To simplify the representation of IPv6 addresses, zeros in IPv6 addresses can be

handled as follows:

z Leading zeros in each group can be removed. For example, the above-mentioned

address can be represented in shorter format as

2001:0:130F:0:0:9C0:876A:130B.

z If an IPv6 address contains two or more consecutive groups of zeros, they can

replaced by the double-colon :: option. For example, the above-mentioned

address can be represented in the shortest format as

2001:0:130F::9C0:876A:130B.

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Caution:

The double-colon :: can be used only once in an IPv6 address. Otherwise, the device is

unable to determine how many zeros the double-colon represents when converting it to

zeros to restore the IPv6 address to a 128-bit address.

An IPv6 address consists of two parts: address prefix and interface ID. The address

prefix and the interface ID are respectively equivalent to the network ID to the host ID in

an IPv4 address.

An IPv6 address prefix is written in IPv6-address/prefix-length notation, where

IPv6-address is an IPv6 address in any of the notations and prefix-length is a decimal

number indicating how many bits from the utmost left of an IPv6 address are the

address prefix.

II. IPv6 address classification

IPv6 addresses mainly fall into three types: unicast address, multicast address and

anycast address.

z Unicast address: An identifier for a single interface, similar to an IPv4 unicast

address .A packet sent to a unicast address is delivered to the interface identified

by that address.

z Multicast address: An identifier for a set of interfaces (typically belonging to

different nodes), similar to an IPv4 multicast address. A packet sent to a multicast

address is delivered to all interfaces identified by that address.

z Anycast address: An identifier for a set of interfaces (typically belonging to

different nodes).A packet sent to an anycast address is delivered to one the

interfaces identified by that address (the nearest one, according to the routing

protocols’ measure of distance).

 Note:

There are no broadcast addresses in IPv6. Their function is superseded by multicast

addresses.

The type of an IPv6 address is designated by the first several bits called format prefix.

Table 1-1 lists the mapping between major address types and format prefixes.

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Table 1-1 Mapping between address types and format prefixes

Type Format prefix (binary) IPv6 prefix ID

Unassigned

address

00...0 (128 bits) ::/128

Loopback

address

00...1 (128 bits) ::1/128

Link-local

address

1111111010 FE80::/10

Site-local

address

1111111011 FEC0::/10

Unicast

address

Global unicast

address

other forms

—

Multicast address

11111111 FF00::/8

Anycast address

Anycast addresses are taken from unicast address

space and are not syntactically distinguishable

from unicast addresses.

III. Unicast address

There are several forms of unicast address assignment in IPv6, including aggregatable

global unicast address, link-local address, and site-local address.

z The aggregatable global unicast address, equivalent to an IPv4 public address, is

used for aggregatable links and provided for network service providers. The

structure of such a type of address allows efficient routing aggregation to restrict

the number of global routing entries.

z The link-local address is used for communication between link-local nodes in

neighbor discovery and stateless autoconfiguration. Routers must not forward any

packets with link-local source or destination addresses to other links.

z IPv6 unicast site-local addresses are similar to private IPv4 addresses. Routers

must not forward any packets with site-local source or destination addresses

outside of the site (equivalent to a private network).

z Loopback address: The unicast address 0:0:0:0:0:0:0:1 (represented in shorter

format as ::1) is called the loopback address and may never be assigned to any

physical interface. Like the loopback address in IPv4, it may be used by a node to

send an IPv6 packet to itself.

z Unassigned address: The unicast address :: is called the unassigned address and

may not be assigned to any node. Before acquiring a valid IPv6 address, a node

may fill this address in the source address field of an IPv6 packet, but may not use

it as a destination IPv6 address.

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IV. Multicast address

Multicast addresses listed in Table 1-2 are reserved for special purpose.

Table 1-2 Reserved IPv6 multicast addresses

Address Application

FF01::1 Node-local scope all-nodes multicast address

FF02::1 Link-local scope all-nodes multicast address

FF01::2 Node-local scope all-routers multicast address

FF02::2 Link-local scope all-routers multicast address

FF05::2 Site-local scope all-routers multicast address

Besides, there is another type of multicast address: solicited-node address. The

solicited-node multicast address is used to acquire the link-layer addresses of neighbor

nodes on the same link and is also used for duplicate address detection. Each IPv6

unicast or anycast address has one corresponding solicited-node address. The format

of a solicited-node multicast address is as follows:

FF02:0:0:0:0:1:FFXX:XXXX

Where, FF02:0:0:0:0:1:FF is permanent and consists of 104 bits, and XX:XXXX is the

last 24 bits of an IPv6 address.

V. Interface identifier in IEEE EUI-64 format

Interface identifiers in IPv6 unicast addresses are used to identify interfaces on a link

and they are required to be unique on that link. Interface identifiers in IPv6 unicast

addresses are currently required to be 64 bits long. An interface identifier is derived

from the link-layer address of that interface. Interface identifiers in IPv6 addresses are

64 bits long, while MAC addresses are 48 bits long. Therefore, the hexadecimal

number FFFE needs to be inserted in the middle of MAC addresses (behind the 24

high-order bits).To ensure the interface identifier obtained from a MAC address is

unique, it is necessary to set the universal/local (U/L) bit (the seventh high-order bit) to

“1”.Thus, an interface identifier in EUI-64 format is obtained.

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01011 11001101

0000 10101011 11001101

00000000 00010010 00110100 00000000 101

00000000 00010010 00110100 11111111 11111110 0000

0012-3400-ABCD

00000010 00010010 00110100 11111111 11111110 0000

0212:34FF:FE00:ABCD

MAC address:

Represented in binary:

Insert FFFE:

Set U/L bit:

EUI-64 address:

Figure 1-2 Convert a MAC address into an EUI-64 address

1.1.3 Dual Stack Overview

A network node that supports both IPv4 and IPv6 is called a dual stack node. A dual

stack node configured with an IPv4 and an IPv6 addresses can have both IPv4 and

IPv6 packets transmitted.

For an upper layer application supporting both IPv4 and IPv6, either TCP or UDP can

be selected at the transport layer, while at network layer, IPv6 stack is peferred.

Figure

1-3

illustrates the IPv4/IPv6 dual stack in relation to the IPv4 stack.

IPv4

IPv4/IPv6

TCP UDP

IPv6

application

Ethernet

Protoc

0x0800

ol ID:

Protocol ID:

0x86DD

IPv4

TCP UDP

IPv4 application

Ethernet

Protocol ID:

0x0800

IPv4 stack Dual

stack

Figure 1-3 IPv4/IPv6 dual stack in relation to IPv4 Stac

1.1.4 Introduction to IPv6 Neighbor Discovery Protocol

The IPv6 neighbor discovery protocol (NDP) uses five types of ICMPv6 messages to

implement the following functions:

z Address resolution

z Neighbor unreachability detection

z Duplicate address detection

z Router/prefix discovery and address autoconfiguration

z Redirection

Table 1-3 lists the types and functions of ICMPv6 messages used by the NDP.

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Table 1-3 Types and functions of ICMPv6 messages

ICMPv6 message Function

Used to acquire the link-layer address of a neighbor

Used to verify whether the neighbor is reachable

Neighbor solicitation

(NS) message

Used to perform a duplicate address detection

Used to respond to a neighbor solicitation message

Neighbor advertisement

(NA) message

When the link layer changes, the local node initiates a

neighbor advertisement message to notify neighbor

nodes of the node information change.

Router solicitation (RS)

message

After started, a host sends a router solicitation message

to request the router for an address prefix and other

configuration information for the purpose of

autoconfiguration.

Used to respond to a router solicitation message

Router advertisement

(RA) message

With the RA message suppression disabled, the router

regularly sends a router advertisement message

containing information such as address prefix and flag

bits

Redirect message

When a certain condition is satisfied, the default gateway

sends a redirect message to the source host so that the

host can reselect a correct next hop router to forward

packets.

The NDP mainly provides the following functions:

I. Address resolution

Similar to the ARP function in IPv4, a node acquires the link-layer address of neighbor

nodes on the same link through NS and NA messages.

Figure 1-4 shows how node A

acquires the link-layer address of node B.

ICMP Type = 135

Src = A

Dst = solicited-node multicast of B

Data = link-layer address of A

ICMP Type

Src = B

Dst = A

Data = link

= 136

-layer address of B

Figure 1-4 Address resolutio

The address resolution procedure is as follows:

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1) Node A multicasts an NS message. The source address of the NS message is the

IPv6 address for the interface of node A and the destination address is the

solicited-node multicast address of node B. The NS message contains the

link-layer address of node A.

2) After receiving the NS message, node B judges whether the destination address

of the packet is the corresponding solicited-node multicast address of its own IPv6

address. If yes, node B returns an NA message containing the link-layer address

of node B.

3) Node A acquires the link-layer address of node B fro the NA message. After that,

node A and node B can communicate.

II. Neighbor unreachability detection

After node A acquires the link-layer address of its neighbor node B, node A can verify

whether node B is reachable according to NS and NA messages.

1) Node A sends an NS message whose destination address is the IPv6 address of

node B.

2) If node A receives an NA message from node B, node A considers that node B is

reachable. Otherwise, node B is unreachable.

III. Duplicate address detection

After node A acquires an IPv6 address, it should perform the duplicate address

detection to determine whether the address is being used by other nodes (similar to the

gratuitous ARP function).The duplication address detection is accomplished through

NS and NA messages. Figure shows the duplicate address detection procedure.

ICMP Type = 135

Src = ::

Dst = FF02::1:FF00:1

Data = 2000::1

ICMP Ty

Src = 20

Dst = FF02::1

Target A

pe = 136

00::1

ddress = 2000::1

Figure 1-5 Duplicate address detectio

The duplicate address detection procedure is as follows:

1) Node A sends an NS message whose source address is the unassigned address ::

and destination address is the corresponding solicited-node multicast address of

the IPv6 address to be detected. The NS message contains the IPv6 address.

2) If node B uses this IPv6 address, node B returns an NA message. The NA

message contains the IPv6 address of node B.

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3) Node A learns that the IPv6 address is being used by node B after receiving the NA

message from node B. Otherwise, node B is not using the IPv6 address and node

A can use it.

IV. Router/prefix discovery and address autoconfiguration

Router/prefix discovery means that a host acquires the neighbor router, the prefix of the

network where the router is located, and other configuration parameters from the

received RA message.

Stateless address autoconfiguration means that a host automatically configure an IPv6

address according to the information obtained through router/prefix discovery.

The router/prefix discovery and address autoconfiguration is implemented through RS

and RA messages. The router/prefix discovery and address autoconfiguration

procedure is as follows:

1) After started, a host sends an RS message to request the router for the address

prefix and other configuration information for the purpose of autoconfiguration.

2) The router returns an RA message containing information such as address prefix

and flag bits. (The router also regularly sends an RA message.)

3) The host automatically configures an IPv6 address and other information for its

interface according to the address prefix and other configuration parameters in the

RA message.

V. Redirection

When a host is started, its routing table may contain only the default route to the

gateway. When certain conditions are satisfied, the gateway sends an ICMPv6 redirect

message to the source host so that the host can select a better next hop router to

forward packets (similar to the ICMP redirection function in IPv4).

The gateway will send an IPv6 ICMP redirect message when the following conditions

are satisfied:

z The receiving interface and the forwarding interface are the same.

z The selected route itself is not created or modified by an IPv6 ICMP redirect

message.

z The selected route is not the default route.

z The forwarded IPv6 packet does not contain any extension header carrying the

routing information of intermediate nodes on the forwarding path.

1.1.5 IPv6 PMTU Discovery

The links that a packet passes from the source to the destination may have different

MTUs. In IPv6, when the packet size exceeds the MTU of a link, the packet will be

fragmented at the source so as to reduce the processing pressure of the forwarding

device and utilize network resources rationally.

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The path MTU (PMTU) discovery mechanism is to find the minimum MTU on the path

from the source to the destination.

Figure 1-6 shows the working procedure of the

PMTU discovery.

MTU=1500 MTU=1500 MTU=1350 M

TU=1400

Source

Packet with MTU=1500

ICMP error:packet too big;use MTU=1350

Packet with MTU=1350

Packet received

Destination

Figure 1-6 Working procedure of the PMTU discover

The working procedure of the PMTU discovery is as follows:

1) The source host uses its MTU to fragment packets and then sends them to the

destination host.

2) If the MTU supported by the packet forwarding interface is less than the size of a

packet, the forwarding device will discard the packet and return an ICMPv6 error

packet containing the interface MTU to the source host.

3) After receiving the ICMPv6 error packet, the source host uses the returned MTU to

fragment the packet again and then sends it.

4) Step 2 to step 3 are repeated until the destination host receives the packet. In this

way, the minimum MTU on the path from the source host to the destination host is

determined.

1.1.6 Introduction to IPv6 DNS

In the IPv6 network, a domain name system (DNS) supporting IPv6 converts domain

names into IPv6 addresses. Different from an IPv4 DNS, an IPv6 DNS converts domain

names into IPv6 addresses, instead of IPv4 addresses.

However, just like an IPv4 DNS, an IPv6 DNS also covers static domain name

resolution and dynamic domain name resolution. The function and implementation of

these two types of domain name resolution are the same as those of an IPv4 DNS. For

details, refer to DNS module.

Usually, the DNS server connecting IPv4 and IPv6 networks contain not only A records

(IPv4 addresses) but also AAAA records (IPv6 addresses). The DNS server can

convert domain names into IPv4 addresses or IPv6 addresses. In this way, the DNS

server has the functions of both IPv6 DNS and IPv4 DNS.

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1.1.7 Protocol Specifications

Protocol specifications related to IPv6 include:

z RFC 1881: IPv6 Address Allocation Management

z RFC 1887: An Architecture for IPv6 Unicast Address Allocation

z RFC 1981: Path MTU Discovery for IP version 6

z RFC 2375: IPv6 Multicast Address Assignments

z RFC 2460: Internet Protocol, Version 6 (IPv6) Specification.

z RFC 2461: Neighbor Discovery for IP Version 6 (IPv6)

z RFC 2462: IPv6 Stateless Address Autoconfiguration

z RFC 2463: Internet Control Message Protocol (ICMPv6) for the Internet Protocol

Version 6 (IPv6) Specification

z RFC 2464: Transmission of IPv6 Packets over Ethernet Networks

z RFC 2526: Reserved IPv6 Subnet Anycast Addresses

z RFC 3307: Allocation Guidelines for IPv6 Multicast Addresses

z RFC 3513: Internet Protocol Version 6 (IPv6) Addressing Architecture

z RFC 3596: DNS Extensions to Support IP Version 6

1.2 Configuring Basic IPv6 Functions

1.2.1 Configuring the IPv6 Packet Forwarding Function

Before IPv6-related configurations, you must enable the IPv6 packet forwarding

function for an interface. Otherwise, the interface cannot forward IPv6 packets even if

an IPv6 address is configured, resulting in interworking failures in the IPv6 network.

Follow these steps to configure the IPv6 packet forwarding function:

To do... Use the command... Remarks

Enter system view

system-view

—

Enable the IPv6 packet

forwarding function

ipv6

Required

Disabled by default.

1.2.2 Configuring an IPv6 Unicast Address

IPv6 site-local addresses and aggregatable global unicast addresses can be

configured in either of the following ways:

z EUI-64 format: When the EUI-64 format is adopted to form IPv6 addresses, the

IPv6 address prefix of an interface is the configured prefix and the interface

identifier is derived from the link-layer address of the interface.

z Manual configuration: IPv6 site-local addresses or aggregatable global unicast

addresses are configured manually.

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IPv6 link-local addresses can be acquired in either of the following ways:

z Automatic generation: The device automatically generates a link-local address for

an interface according to the link-local address prefix (FE80::/64) and the

link-layer address of the interface.

z Manual assignment: IPv6 link-local addresses can be assigned manually.

Follow these steps to configure an IPv6 unicast address:

To do... Use the command... Remarks

Enter system view

system-view

—

Enter interface view

interface interface-type

interface-number

—

Manually

assign an

IPv6 address

ipv6 address

{ ipv6-address prefix-length

ipv6-address/prefix-length }

Configure

an IPv6

aggregatabl

e global

unicast

address or

site-local

address

Adopt the

EUI-64 format

to form an

IPv6 address

ipv6 address

ipv6-address/prefix-length

eui-64

Alternative

By default, no

site-local address or

aggregatable global

unicast address is

configured for an

interface.

Note that the prefix

length specified by

the prefix-length

argument cannot be

greater than 64.

Automatically

generate a

link-local

address

ipv6 address auto

link-local

Configure

an IPv6

link-local

address

Manually

assign a

link-local

address for an

interface.

ipv6 address ipv6-address

link-local

Optional

By default, after an

IPv6 site-local

address or

aggregatable global

unicast address is

configured for an

interface, a link-local

address will be

generated

automatically.

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 Note:

z After an IPv6 site-local address or aggregatable global unicast address is

configured for an interface, a link-local address will be generated automatically. The

automatically generated link-local address is the same as the one generated by

using the ipv6 address auto link-local command. If a link-local address is

manually assigned to an interface, this link-local address takes effect. If the

manually assigned link-local address is deleted, the automatically generated

link-local address takes effect.

z The manual assignment takes precedence over the automatic generation. That is, if

you first adopt the automatic generation and then the manual assignment, the

manually assigned link-local address will overwrite the automatically generated one.

If you first adopt the manual assignment and then the automatic generation, the

automatically generated link-local address will not take effect and the link-local

address of an interface is still the manually assigned one. You must delete the

manually assigned link-local address before adopting the automatic generation.

z You must have carried out the ipv6 address auto link-local command before you

carry out the undo ipv6 address auto link-local command. However, if an IPv6

site-local address or aggregatable global unicast address is already configured for

an interface, the interface still has a link-local address because the system

automatically generates one for the interface. If no IPv6 site-local address or

aggregatable global unicast address is configured, the interface has no link-local

address.

z You can configure IPv6 addresses for VLAN interface and LoopBack interface on

S5500-SI Series Ethernet Switches.

z The prefix length can only be 128 bits when the aggregatable global unicast

address(es) or site-local address(es) is configured in the LoopBack interface view.

1.3 Configuring IPv6 NDP

1.3.1 Configuring a Static Neighbor Entry

The IPv6 address of a neighbor node can be resolved into a link-layer address

dynamically through NS and NA messages or statically through manual configuration.

The device uniquely identifies a static neighbor entry according to the IPv6 address and

the layer 3 interface ID.

Configure the corresponding IPv6 address and link-layer address for a layer 3

interface.

Follow these steps to configure a static neighbor entry:

Operation Manual – IPv6 Configuration

H3C S5500-SI Series Ethernet Switches Chapter 1

IPv6 Configuration

1-15

To do... Use the command... Remarks

Enter system

view

system-view

—

Configure a

static neighbor

entry

ipv6 neighbor ipv6-address

mac-address { vlan-id port-type

port-number | interface interface-type

interface-number }

Required

1.3.2 Configuring the Maximum Number of Neighbors Dynamically Learned

The device can dynamically acquire the link-layer address of a neighbor node through

NS and NA messages. Too large a neighbor table from which neighbor entries can be

dynamically acquired may lead to the forwarding performance degradation of the

device. Therefore, you can restrict the size of the neighbor table by setting the

maximum number of neighbors that an interface can dynamically learn. When the

number of dynamically learned neighbors reaches the threshold, the interface will stop

learning neighbor information.

Follow these steps to configure the maximum number of neighbors dynamically

learned:

To do… Use the command… Remarks

Enter system view

system-view

—

Enter interface view

interface interface-type

interface-number

—

Configure the

maximum number of

neighbors dynamically

learned by an interface

ipv6 neighbors

max-learning-num number

Optional

The default value is

1024

1.3.3 Configuring Parameters Related to an RA Message

You can configure whether the interface sends an RA message, the interval for sending

RA messages, and parameters in RA messages. After receiving an RA message, a

host can use these parameters to perform corresponding operations.

Table 1-4 lists the

configurable parameters in an RA message and their descriptions.

Table 1-4 Parameters in an RA message and their descriptions

Parameters Description

Cur hop limit

When sending an IPv6 packet, a host uses the value of this

parameter to fill the Hop Limit field in IPv6 headers. Meanwhile,

the value of this parameter is equal to the value of the Cur Hop

Limit field in response messages of the device.

Operation Manual – IPv6 Configuration

H3C S5500-SI Series Ethernet Switches Chapter 1

IPv6 Configuration

1-16

Parameters Description

Prefix

information

options

After receiving the prefix information, the hosts on the same link

can perform stateless autoconfiguration operations.

M flag

This field determines whether hosts use the stateful

autoconfiguration to acquire IPv6 addresses.

If the M flag is set to 1, hosts use the stateful autoconfiguration

to acquire IPv6 addresses. Otherwise, hosts use the stateless

autoconfiguration to acquire IPv6 addresses, that is, hosts

configure IPv6 addresses according to their own link-layer

addresses and the prefix information issued by the router.

O flag

This field determines whether hosts use the stateful

autoconfiguration to acquire information other than IPv6

addresses.

If the O flag is set to 1, hosts use the stateful autoconfiguration

(for example, DHCP server) to acquire information other than

IPv6 addresses. Otherwise, hosts use the stateless

autoconfiguration to acquire information other than IPv6

addresses.

Router lifetime

This field is used to set the lifetime of the router that sends RA

messages to serve as the default router of hosts. According to

the router lifetime in the received RA messages, hosts

determine whether the router sending RA messages can serve

as the default router of hosts.

Retrans timer

If a node fails to receive a response message within the

specified time after sending an NS message, the node will

retransmit it.

Reachable time

After the neighbor unreachability detection shows that a

neighbor is reachable, a node considers the neighbor is

reachable within the reachable time. If the node needs to send a

packet to a neighbor after the reachable time expires, the node

will again confirm whether the neighbor is reachable.

 Note:

The values of the retrans timer field and the reachable time field configured for an

interface are sent to hosts via RA messages. Furthermore, the interface sends NS

messages at intervals of the value of the retrans timer field and considers a neighbor

reachable in the time of the value of the reachable time field.

Follow these steps to configure parameters related to an RA message:

Operation Manual – IPv6 Configuration

H3C S5500-SI Series Ethernet Switches Chapter 1

IPv6 Configuration

1-17

To do… Use the command… Remarks

Enter system view

system-view

—

Configure the

current hop limit

ipv6 nd hop-limit value

Optional

64 by default.

Enter interface view

interface interface-type

interface-number

—

Disable the RA

message

suppression.

undo ipv6 nd ra halt

Optional

By default, RA messages are

suppressed.

Configure the

interval for sending

RA messages

ipv6 nd ra interval

max-interval-value

min-interval-value

Optional

By default, the maximum interval

for sending RA messages is 600

seconds, and the minimum

interval is 200 seconds.

The device sends RA messages

at intervals of a random value

between the maximum interval

and the minimum interval.

The minimum interval should be

less than or equal to 0.75 times

the maximum interval.

Configure the prefix

information options

in RA messages

ipv6 nd ra prefix

{ ipv6-address

prefix-length |

ipv6-address/prefix-leng

th } valid-lifetime

preferred-lifetime

[ no-autoconfig |

off-link ]*

Optional

By default, no prefix information

is configured in RA messages

and the IPv6 address of the

interface sending RA messages

is used as the prefix information.

Set the M flag to 1

ipv6 nd autoconfig

managed-address-flag

Optional

By default, the M flag bit is set to

0, that is, hosts acquire IPv6

addresses through stateless

autoconfiguration.

Set the O flag bit to

ipv6 nd autoconfig

other-flag

Optional

By default, the O flag bit is set to

0, that is, hosts acquire other

information through stateless

autoconfiguration.

Configure the router

lifetime in RA

messages

ipv6 nd ra

router-lifetime value

Optional

1,800 seconds by default.

Operation Manual – IPv6 Configuration

H3C S5500-SI Series Ethernet Switches Chapter 1

IPv6 Configuration

1-18

To do… Use the command… Remarks

Set the retrans timer

ipv6 nd ns

retrans-timer value

Optional

By default, the local interface

sends NS messages at intervals

of 1,000 milliseconds and the

Retrans Timer field in RA

messages sent by the local

interface is equal to 0.

Set the reachable

time

ipv6 nd nud

reachable-time value

Optional

By default, the neighbor

reachable time on the local

interface is 30,000 milliseconds

and the Reachable Timer field in

RA messages is 0.

Caution:

The maximum interval for sending RA messages should be less than or equal to the

router lifetime in RA messages.

1.3.4 Configuring the Attempts to Send an NS Message for Duplicate

Address Detection

The device sends a neighbor solicitation (NS) message for duplicate address detection.

If the device does not receive a response within a specified time (set by the ipv6 nd ns

retrans-timer value command), the device continues to send an NS message. If the

device still does not receive a response after the number of attempts to send an NS

message reaches the maximum, the device judges the acquired address is available

Follow these steps to configure the attempts to send an NS message for duplicate

address detection:

To do… Use the command… Remarks

Enter system view

system-view

—

Enter interface view

interface

interface-type

interface-number

—

Configure the

attempts to send an

NS message for

duplicate address

detection

ipv6 nd dad attempts

value

Optional

1 by default. When the value

argument is set to 0, the

duplicate address detection is

disabled.

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H3C S5500-SI Series Operating instructions

Brand: H3C

Model: S5500-SI Series

Category: Networking

Type: Operating instructions

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