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- Table of Contents
-
- 11-Network Management and Monitoring Configuration Guide
- 00-Preface
- 01-System maintenance and debugging configuration
- 02-NTP configuration
- 03-PTP configuration
- 04-Information center configuration
- 05-SNMP configuration
- 06-RMON configuration
- 07-NQA configuration
- 08-Mirroring configuration
- 09-sFlow configuration
- 10-Process monitoring and maintenance configuration
- 11-EAA configuration
- 12-CWMP configuration
- 13-NETCONF configuration
- 14-Packet capture configuration
- Related Documents
-
| Title | Size | Download |
|---|---|---|
| 02-NTP configuration | 381.00 KB |
Configuration restrictions and guidelines
Configuring NTP association mode
Configuring NTP in client/server mode
Configuring NTP in symmetric active/passive mode
Configuring NTP in broadcast mode
Configuring NTP in multicast mode
Configuring access control rights
Configuring NTP authentication
Configuring NTP authentication in client/server mode
Configuring NTP authentication in symmetric active/passive mode
Configuring NTP authentication in broadcast mode
Configuring NTP authentication in multicast mode
Configuring NTP optional parameters·
Specifying the source interface for NTP messages
Disabling an interface from receiving NTP messages
Configuring the maximum number of dynamic associations
Setting a DSCP value for NTP packets
Configuring the local clock as a reference source
Displaying and maintaining NTP
NTP client/server mode configuration example
IPv6 NTP client/server mode configuration example
NTP symmetric active/passive mode configuration example
IPv6 NTP symmetric active/passive mode configuration example
NTP broadcast mode configuration example
NTP multicast mode configuration example
IPv6 NTP multicast mode configuration example
Configuration example for NTP client/server mode with authentication
Configuration example for NTP broadcast mode with authentication
Configuration restrictions and guidelines
Specifying an NTP server for the device
Configuring SNTP authentication
Displaying and maintaining SNTP
Configuring NTP
Synchronize your device with a trusted time source by using the Network Time Protocol (NTP) or changing the system time before you run it on a live network. Various tasks, including network management, charging, auditing, and distributed computing depend on an accurate system time setting, because the timestamps of system messages and logs use the system time.
Overview
NTP is typically used in large networks to dynamically synchronize time among network devices. It guarantees higher clock accuracy than manual system clock setting. In a small network that does not require high clock accuracy, you can keep time synchronized among devices by changing their system clocks one by one.
NTP runs over UDP and uses UDP port 123.
How NTP works
Figure 1 shows how NTP synchronizes the system time between two devices, in this example, Device A and Device B. Assume that:
· Prior to the time synchronization, the time is set to 10:00:00 am for Device A and 11:00:00 am for Device B.
· Device B is used as the NTP server. Device A is to be synchronized to Device B.
· It takes 1 second for an NTP message to travel from Device A to Device B, and from Device B to Device A.
· It takes 1 second for Device B to process the NTP message.
The synchronization process is as follows:
1. Device A sends Device B an NTP message, which is timestamped when it leaves Device A. The time stamp is 10:00:00 am (T1).
2. When this NTP message arrives at Device B, Device B adds a timestamp showing the time when the message arrived at Device B. The timestamp is 11:00:01 am (T2).
3. When the NTP message leaves Device B, Device B adds a timestamp showing the time when the message left Device B. The timestamp is 11:00:02 am (T3).
4. When Device A receives the NTP message, the local time of Device A is 10:00:03 am (T4).
Up to now, Device A can calculate the following parameters based on the timestamps:
· The roundtrip delay of the NTP message: Delay = (T4 – T1) – (T3 – T2) = 2 seconds.
· Time difference between Device A and Device B: Offset = ((T2 – T1) + (T3 – T4)) /2 = 1 hour.
Based on these parameters, Device A can be synchronized to Device B.
This is only a rough description of the work mechanism of NTP. For more information, see the related protocols and standards.
NTP architecture
NTP uses stratums 1 to 16 to define clock accuracy, as shown in Figure 2. A lower stratum value represents higher accuracy. Clocks at stratums 1 through 15 are in synchronized state, and clocks at stratum 16 are not synchronized.
Typically, a stratum 1 NTP server gets its time from an authoritative time source, such as an atomic clock, and provides time for other devices as the primary NTP server. The accuracy of each server is the stratum, with the topmost level (primary servers) assigned as one and each level downwards in the hierarchy assigned as one greater than the preceding level. NTP uses a stratum to describe how many NTP hops away a device is from the primary time server. A stratum 2 time server receives its time from a stratum 1 time server, and so on.
To ensure time accuracy and availability, you can specify multiple NTP servers for a device. The device selects an optimal NTP server as the clock source based on parameters such as stratum. The clock that the device selects is called the reference source. For more information about clock selection, see the related protocols and standards.
If the devices in a network cannot synchronize to an authoritative time source, you can select a device that has a relatively accurate clock from the network, and use the local clock of the device as the reference clock to synchronize other devices in the network.
Association modes
NTP supports the following association modes:
· Client/server mode
· Symmetric active/passive mode
· Broadcast mode
· Multicast mode
Table 1 NTP association modes
|
Mode |
Working process |
Principle |
Application scenario |
|
Client/server |
On the client, specify the IP address of the NTP server. A client sends a clock synchronization message to the NTP servers. Upon receiving the message, the servers automatically operate in server mode and send a reply. If the client can be synchronized to multiple time servers, it selects an optimal clock and synchronizes its local clock to the optimal reference source after receiving the replies from the servers. |
A client can be synchronized to a server, but a server cannot be synchronized to a client. |
As Figure 2 shows, this mode is intended for configurations where devices of a higher stratum are synchronized to devices with a lower stratum. |
|
Symmetric active/passive |
On the symmetric active peer, specify the IP address of the symmetric passive peer. A symmetric active peer periodically sends clock synchronization messages to a symmetric passive peer. The symmetric passive peer automatically operates in symmetric passive mode and sends a reply. If the symmetric active peer can be synchronized to multiple time servers, it selects an optimal clock and synchronizes its local clock to the optimal reference source after receiving the replies from the servers. |
A symmetric active peer and a symmetric passive peer can be synchronized to each other. If both of them are synchronized, the peer with a higher stratum is synchronized to the peer with a lower stratum. |
As Figure 2 shows, this mode is most often used between two or more servers with the same stratum to operate as a backup for one another. If a server fails to communicate with all the servers of a higher stratum, the server can be synchronized to the servers of the same stratum. |
|
Broadcast |
A server periodically sends clock synchronization messages to the broadcast address 255.255.255.255. Clients listen to the broadcast messages from the servers to synchronize to the server according to the broadcast messages. When a client receives the first broadcast message, the client and the server start to exchange messages to calculate the network delay between them. Then, only the broadcast server sends clock synchronization messages. |
A broadcast client can be synchronized to a broadcast server, but a broadcast server cannot be synchronized to a broadcast client. |
A broadcast server sends clock synchronization messages to synchronize clients in the same subnet. As Figure 2 shows, broadcast mode is intended for configurations involving one or a few servers and a potentially large client population. The broadcast mode has a lower time accuracy than the client/server and symmetric active/passive modes because only the broadcast servers send clock synchronization messages. |
|
Multicast |
A multicast server periodically sends clock synchronization messages to the user-configured multicast address. Clients listen to the multicast messages from servers and synchronize to the server according to the received messages. |
A multicast client can be synchronized to a multicast server, but a multicast server cannot be synchronized to a multicast client. |
A multicast server can provide time synchronization for clients in the same subnet or in different subnets. The multicast mode has a lower time accuracy than the client/server and symmetric active/passive modes. |
In this document, an "NTP server" or a "server" refers to a device that operates as an NTP server in client/server mode. Time servers refer to all the devices that can provide time synchronization, including NTP servers, NTP symmetric peers, broadcast servers, and multicast servers.
NTP security
To improve time synchronization security, NTP provides the access control and authentication functions.
NTP access control
You can control NTP access by using an ACL. The access rights are in the following order, from least restrictive to most restrictive:
· Peer—Allows time requests and NTP control queries (such as alarms, authentication status, and time server information) and allows the local device to synchronize itself to a peer device.
· Server—Allows time requests and NTP control queries, but does not allow the local device to synchronize itself to a peer device.
· Synchronization—Allows only time requests from a system whose address passes the access list criteria.
· Query—Allows only NTP control queries from a peer device to the local device.
When the device receives an NTP request, it matches the request against the access rights in the order from the least restrictive to the most restrictive: peer, server, synchronization, and query.
· If no NTP access control is configured, the peer access right applies.
· If the IP address of the peer device matches a permit statement in an ACL, the access right is granted to the peer device. If a deny statement or no ACL is matched, no access right is granted.
· If no ACL is specified for an access right or the ACL specified for the access right is not created, the access right is not granted.
· If none of the ACLs specified for the access rights is created, the peer access right applies.
· If none of the ACLs specified for the access rights contains rules, no access right is granted.
This feature provides minimal security for a system running NTP. A more secure method is NTP authentication.
NTP authentication
Use this feature to authenticate the NTP messages for security purposes. If an NTP message passes authentication, the device can receive it and get time synchronization information. If not, the device discards the message. This function makes sure the device does not synchronize to an unauthorized time server.
Figure 3 NTP authentication
As shown in Figure 3, NTP authentication is performed as follows:
1. The sender uses the key identified by the key ID to calculate a digest for the NTP message through the specified authentication algorithm. Then it sends the calculated digest together with the NTP message and key ID to the receiver.
2. Upon receiving the message, the receiver performs the following actions:
a. Finds the key according to the key ID in the message.
b. Uses the key and the specified authentication algorithm to calculate the digest for the message.
c. Compares the digest with the digest contained in the NTP message.
- If they are different, the receiver discards the message.
- If they are the same, the local device determines whether the sender is allowed to use the authentication ID. If the sender is allowed to use the authentication ID, the receiver accepts the message. If the sender is not allowed to use the authentication ID, the receiver discards the message.
Protocols and standards
· RFC 1305, Network Time Protocol (Version 3) Specification, Implementation and Analysis
· RFC 5905, Network Time Protocol Version 4: Protocol and Algorithms Specification
Configuration restrictions and guidelines
Follow these restrictions and guidelines when you configure NTP:
· NTP is supported only on Layer 3 interfaces.
· You cannot configure both NTP and SNTP on the same device.
· Do not configure NTP on an aggregate member port.
· The NTP service and SNTP service are mutually exclusive. You can only enable either NTP service or SNTP service at a time.
· To ensure time synchronization accuracy, do not specify more than one reference source. Doing so might cause frequent time changes or even synchronization failures.
· Make sure you use the clock protocol command to specify the time protocol as NTP. For more information about the clock protocol command, see Fundamentals Command Reference.
Configuration task list
|
Tasks at a glance |
|
(Required.) Enabling the NTP service |
|
(Required.) Perform one or both of the following tasks: |
|
(Optional.) Configuring access control rights |
|
(Optional.) Configuring NTP authentication |
|
(Optional.) Configuring NTP optional parameters |
Enabling the NTP service
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable the NTP service. |
ntp-service enable |
By default, the NTP service is not enabled. |
Configuring NTP association mode
This section describes how to configure NTP association modes.
Configuring NTP in client/server mode
When the device operates in client/server mode, specify the IP address for the server on the client.
Follow these guidelines when you configure an NTP client:
· A server must be synchronized by other devices or use its local clock as a reference source before synchronizing an NTP client. Otherwise, the client will not be synchronized to the NTP server.
· If the stratum level of a server is higher than or equal to a client, the client will not synchronize to that server.
· You can configure multiple servers by repeating the ntp-service unicast-server and ntp-service ipv6 unicast-server commands.
To configure an NTP client:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
·
Specify an NTP server for the device: ·
Specify an IPv6 NTP server for the device: |
By default, no NTP server is specified for the device. |
Configuring NTP in symmetric active/passive mode
When the device operates in symmetric active/passive mode, specify on a symmetric-active peer the IP address for a symmetric-passive peer.
Follow these guidelines when you configure a symmetric-active peer:
· Execute the ntp-service enable command on a symmetric passive peer to enable NTP. Otherwise, the symmetric-passive peer will not process NTP messages from a symmetric-active peer.
· Either the symmetric-active peer, or the symmetric-passive peer, or both of them must be in synchronized state. Otherwise, their time cannot be synchronized.
· You can configure multiple symmetric-passive peers by repeating the ntp-service unicast-peer or ntp-service ipv6 unicast-peer command.
To configure a symmetric-active peer:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Specify a symmetric-passive peer for the device. |
·
Specify a symmetric-passive peer: ·
Specify an IPv6 symmetric-passive peer: |
By default, no symmetric-passive peer is specified. |
Configuring NTP in broadcast mode
A broadcast server must be synchronized by other devices or use its local clock as a reference source before synchronizing a broadcast client. Otherwise, the broadcast client will not be synchronized to the broadcast server.
Configure NTP in broadcast mode on both broadcast server and client.
Configuring a broadcast client
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enter interface view. |
interface interface-type interface-number |
Enter the interface for receiving NTP broadcast messages. |
|
3. Configure the device to operate in broadcast client mode. |
ntp-service broadcast-client |
By default, the device does not operate in broadcast client mode. After you execute the command, the device receives NTP broadcast messages from the specified interface. |
Configuring the broadcast server
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enter interface view. |
interface interface-type interface-number |
Enter the interface for sending NTP broadcast messages. |
|
3. Configure the device to operate in NTP broadcast server mode. |
ntp-service broadcast-server [ authentication-keyid keyid | version number ] * |
By default, the device does not operate in broadcast server mode. After you execute the command, the device receives NTP broadcast messages from the specified interface. |
Configuring NTP in multicast mode
A multicast server must be synchronized by other devices or use its local clock as a reference source before synchronizing a multicast client. Otherwise, the multicast client will not be synchronized to the multicast server.
Configure NTP in multicast mode on both a multicast server and client.
Configuring a multicast client
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enter interface view. |
interface interface-type interface-number |
Enter the interface for receiving NTP multicast messages. |
|
3. Configure the device to operate in multicast client mode. |
·
Configure the device to operate in multicast
client mode: ·
Configure the device to operate in IPv6 multicast
client mode: |
By default, the device does not operate in multicast server mode. After you execute the command, the device receives NTP multicast messages from the specified interface. |
Configuring the multicast server
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enter interface view. |
interface interface-type interface-number |
Enter the interface for sending NTP multicast message. |
|
3. Configure the device to operate in multicast server mode. |
·
Configure the device to operate in multicast
server mode: ·
Configure the device to operate in multicast
server mode: |
By default, the device does not operate in multicast server mode. After you execute the command, the device receives NTP multicast messages from the specified interface. |
Configuring access control rights
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Configure the NTP service access control right for a peer device to access the local device. |
·
Configure the NTP service access
control right for a peer device to access the local device ·
Configure the IPv6 NTP service access control
right for a peer device to access the local device |
By default, the NTP service access control right for a peer device to access the local device is peer. |
Before you configure the NTP service access control right to the local device, create and configure an ACL associated with the access control right. For more information about ACL, see ACL and QoS Configuration Guide.
Configuring NTP authentication
This section provides instructions for configuring NTP authentication.
Configuring NTP authentication in client/server mode
To ensure a successful NTP authentication, configure the same authentication key ID, algorithm, and key on the server and client. Make sure the peer device is allowed to use the key ID for authentication on the local device.
To configure NTP authentication for a client:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable NTP authentication. |
ntp-service authentication enable |
By default, NTP authentication is disabled. |
|
3. Configure an NTP authentication key. |
ntp-service authentication-keyid keyid authentication-mode { hmac-sha-1 | hmac-sha-256 | hmac-sha-384 | hmac-sha-512 | md5 } { cipher | simple } string [ acl ipv4-acl-number | ipv6 acl ipv6-acl-number ] * |
By default, no NTP authentication key is configured. |
|
4. Configure the key as a trusted key. |
ntp-service reliable authentication-keyid keyid |
By default, no authentication key is configured as a trusted key. |
|
5. Associate the specified key with an NTP server. |
·
Associate the specified key with an NTP
server: ·
Associate the specified key with an IPv6 NTP
server: |
N/A |
To configure NTP authentication for a server:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable NTP authentication. |
ntp-service authentication enable |
By default, NTP authentication is disabled. |
|
3. Configure an NTP authentication key. |
ntp-service authentication-keyid keyid authentication-mode { hmac-sha-1 | hmac-sha-256 | hmac-sha-384 | hmac-sha-512 | md5 } { cipher | simple } string [ acl ipv4-acl-number | ipv6 acl ipv6-acl-number ] * |
By default, no NTP authentication key is configured. |
|
4. Configure the key as a trusted key. |
ntp-service reliable authentication-keyid keyid |
By default, no authentication key is configured as a trusted key. |
NTP authentication results differ when different configurations are performed on client and server. For more information, see Table 2. (N/A in the table means that whether the configuration is performed does not make any difference.)
Table 2 NTP authentication results
|
Client |
Server |
Authentication result |
|||
|
Enable NTP authentication |
Configure a key and configure it as a trusted key |
Associate the key with an NTP server |
Enable NTP authentication |
Configure a key and configure it as a trusted key |
|
|
Yes |
Yes |
Yes |
Yes |
Yes |
Succeeded |
|
Yes |
Yes |
Yes |
Yes |
No |
Failed |
|
Yes |
Yes |
Yes |
No |
N/A |
Failed |
|
Yes |
No |
Yes |
N/A |
N/A |
Failed |
|
Yes |
N/A |
No |
N/A |
N/A |
No authentication |
|
No |
N/A |
N/A |
N/A |
N/A |
No authentication |
Configuring NTP authentication in symmetric active/passive mode
To ensure a successful NTP authentication, configure the same authentication key ID, algorithm, and key on the active peer and passive peer. Make sure the peer device is allowed to use the key ID for authentication on the local device.
To configure NTP authentication for an active peer:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable NTP authentication. |
ntp-service authentication enable |
By default, NTP authentication is disabled. |
|
3. Configure an NTP authentication key. |
ntp-service authentication-keyid keyid authentication-mode { hmac-sha-1 | hmac-sha-256 | hmac-sha-384 | hmac-sha-512 | md5 } { cipher | simple } string [ acl ipv4-acl-number | ipv6 acl ipv6-acl-number ] * |
By default, no NTP authentication key is configured. |
|
4. Configure the key as a trusted key. |
ntp-service reliable authentication-keyid keyid |
By default, no authentication key is configured as a trusted key. |
|
5. Associate the specified key with a passive peer. |
·
Associate the specified key with a passive peer: ·
Associate the specified key with a passive peer: |
N/A |
To configure NTP authentication for a passive peer:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable NTP authentication. |
ntp-service authentication enable |
By default, NTP authentication is disabled. |
|
3. Configure an NTP authentication key. |
ntp-service authentication-keyid keyid authentication-mode { hmac-sha-1 | hmac-sha-256 | hmac-sha-384 | hmac-sha-512 | md5 } { cipher | simple } string [ acl ipv4-acl-number | ipv6 acl ipv6-acl-number ] * |
By default, no NTP authentication key is configured. |
|
4. Configure the key as a trusted key. |
ntp-service reliable authentication-keyid keyid |
By default, no authentication key is configured as a trusted key. |
NTP authentication results differ when different configurations are performed on active peer and passive peer. For more information, see Table 3. (N/A in the table means that whether the configuration is performed does not make any difference.)
Table 3 NTP authentication results
|
Active peer |
Passive peer |
Authentication result |
|||||
|
Enable NTP authentication |
Configure a key and configure it as a trusted key |
Associate the key with a passive peer |
Enable NTP authentication |
Configure a key and configure it as a trusted key |
|||
|
Stratum level of the active and passive peers is not considered. |
|||||||
|
Yes |
Yes |
Yes |
Yes |
Yes |
Succeeded |
||
|
Yes |
Yes |
Yes |
Yes |
No |
Failed |
||
|
Yes |
Yes |
Yes |
No |
N/A |
Failed |
||
|
Yes |
N/A |
No |
Yes |
N/A |
Failed |
||
|
Yes |
N/A |
No |
No |
N/A |
No authentication |
||
|
No |
N/A |
N/A |
Yes |
N/A |
Failed |
||
|
No |
N/A |
N/A |
No |
N/A |
No authentication |
||
|
The active peer has a higher stratum than the passive peer. |
|||||||
|
Yes |
No |
Yes |
N/A |
N/A |
Failed |
||
|
The passive peer has a higher stratum than the active peer. |
|||||||
|
Yes |
No |
Yes |
Yes |
N/A |
Failed |
||
|
Yes |
No |
Yes |
No |
N/A |
No authentication |
||
Configuring NTP authentication in broadcast mode
To ensure a successful NTP authentication, configure the same authentication key ID, algorithm, and key on the broadcast server and client. Make sure the peer device is allowed to use the key ID for authentication on the local device.
To configure NTP authentication for a broadcast client:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable NTP authentication. |
ntp-service authentication enable |
By default, NTP authentication is disabled. |
|
3. Configure an NTP authentication key. |
ntp-service authentication-keyid keyid authentication-mode { hmac-sha-1 | hmac-sha-256 | hmac-sha-384 | hmac-sha-512 | md5 } { cipher | simple } string [ acl ipv4-acl-number | ipv6 acl ipv6-acl-number ] * |
By default, no NTP authentication key is configured. |
|
4. Configure the key as a trusted key. |
ntp-service reliable authentication-keyid keyid |
By default, no authentication key is configured as a trusted key. |
To configure NTP authentication for a broadcast server:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable NTP authentication. |
ntp-service authentication enable |
By default, NTP authentication is disabled. |
|
3. Configure an NTP authentication key. |
ntp-service authentication-keyid keyid authentication-mode { hmac-sha-1 | hmac-sha-256 | hmac-sha-384 | hmac-sha-512 | md5 } { cipher | simple } string [ acl ipv4-acl-number | ipv6 acl ipv6-acl-number ] * |
By default, no NTP authentication key is configured. |
|
4. Configure the key as a trusted key. |
ntp-service reliable authentication-keyid keyid |
By default, no authentication key is configured as a trusted key. |
|
5. Enter interface view. |
interface interface-type interface-number |
N/A |
|
6. Associate the specified key with the broadcast server. |
ntp-service broadcast-server authentication-keyid keyid |
By default, the broadcast server is not associated with any key. |
NTP authentication results differ when different configurations are performed on broadcast client and server. For more information, see Table 4. (N/A in the table means that whether the configuration is performed does not make any difference.)
Table 4 NTP authentication results
|
Broadcast server |
Broadcast client |
Authentication result |
|||
|
Enable NTP authentication |
Configure a key and configure it as a trusted key |
Associate the key with a broadcast server |
Enable NTP authentication |
Configure a key and configure it as a trusted key |
|
|
Yes |
Yes |
Yes |
Yes |
Yes |
Succeeded |
|
Yes |
Yes |
Yes |
Yes |
No |
Failed |
|
Yes |
Yes |
Yes |
No |
N/A |
Failed |
|
Yes |
No |
Yes |
Yes |
N/A |
Failed |
|
Yes |
No |
Yes |
No |
N/A |
No authentication |
|
Yes |
N/A |
No |
Yes |
N/A |
Failed |
|
Yes |
N/A |
No |
No |
N/A |
No authentication |
|
No |
N/A |
N/A |
Yes |
N/A |
Failed |
|
No |
N/A |
N/A |
No |
N/A |
No authentication |
Configuring NTP authentication in multicast mode
To ensure a successful NTP authentication, configure the same authentication key ID, algorithm, and key on the multicast server and client. Make sure the peer device is allowed to use the key ID for authentication on the local device.
To configure NTP authentication for a multicast client:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable NTP authentication. |
ntp-service authentication enable |
By default, NTP authentication is disabled. |
|
3. Configure an NTP authentication key. |
ntp-service authentication-keyid keyid authentication-mode { hmac-sha-1 | hmac-sha-256 | hmac-sha-384 | hmac-sha-512 | md5 } { cipher | simple } string [ acl ipv4-acl-number | ipv6 acl ipv6-acl-number ] * |
By default, no NTP authentication key is configured. |
|
4. Configure the key as a trusted key. |
ntp-service reliable authentication-keyid keyid |
By default, no authentication key is configured as a trusted key. |
To configure NTP authentication for a multicast server:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable NTP authentication. |
ntp-service authentication enable |
By default, NTP authentication is disabled. |
|
3. Configure an NTP authentication key. |
ntp-service authentication-keyid keyid authentication-mode { hmac-sha-1 | hmac-sha-256 | hmac-sha-384 | hmac-sha-512 | md5 } { cipher | simple } string [ acl ipv4-acl-number | ipv6 acl ipv6-acl-number ] * |
By default, no NTP authentication key is configured. |
|
4. Configure the key as a trusted key. |
ntp-service reliable authentication-keyid keyid |
By default, no authentication key is configured as a trusted key. |
|
5. Enter interface view. |
interface interface-type interface-number |
N/A |
|
6. Associate the specified key with the multicast server. |
·
Associate the specified key with a
multicast server: ·
Associate the specified key with an
IPv6 multicast server: |
By default, no multicast server is associated with the specified key. |
NTP authentication results differ when different configurations are performed on broadcast client and server. For more information, see Table 5. (N/A in the table means that whether the configuration is performed does not make any difference.)
Table 5 NTP authentication results
|
Multicast server |
Multicast client |
Authentication result |
|||
|
Enable NTP authentication |
Configure a key and configure it as a trusted key |
Associate the key with a multicast server |
Enable NTP authentication |
Configure a key and configure it as a trusted key |
|
|
Yes |
Yes |
Yes |
Yes |
Yes |
Succeeded |
|
Yes |
Yes |
Yes |
Yes |
No |
Failed |
|
Yes |
Yes |
Yes |
No |
N/A |
Failed |
|
Yes |
No |
Yes |
Yes |
N/A |
Failed |
|
Yes |
No |
Yes |
No |
N/A |
No authentication |
|
Yes |
N/A |
No |
Yes |
N/A |
Failed |
|
Yes |
N/A |
No |
No |
N/A |
No authentication |
|
No |
N/A |
N/A |
Yes |
N/A |
Failed |
|
No |
N/A |
N/A |
No |
N/A |
No authentication |
Configuring NTP optional parameters
The configuration tasks in this section are optional tasks. Configure them to improve NTP security, performance, or reliability.
Specifying the source interface for NTP messages
To prevent interface status changes from causing NTP communication failures, configure the device to use the IP address of an interface that is always up, for example, a loopback interface, as the source IP address for the NTP messages to be sent. Set the loopback interface as the source interface so that any interface status change on the device will not cause NTP messages to be unable to be received.
When the device responds to an NTP request, the source IP address of the NTP response is always the IP address of the interface that has received the NTP request.
Follow these guidelines when you specify the source interface for NTP messages:
· If you have specified the source interface for NTP messages in the ntp-service unicast-server/ntp-service ipv6 unicast-server or ntp-service unicast-peer/ntp-service ipv6 unicast-peer command, the specified interface acts as the source interface for NTP messages.
· If you have configured the ntp-service broadcast-server or ntp-service multicast-server/ntp-service ipv6 multicast-server command in an interface view, this interface acts as the source interface for broadcast or multicast NTP messages.
To specify the source interface for NTP messages:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Specify the source interface for NTP messages. |
·
Specify the source interface for NTP
messages: ·
Specify the source interface for IPv6 NTP messages: |
By default, no source interface is specified for NTP messages. |
Disabling an interface from receiving NTP messages
When NTP is enabled, all interfaces by default can receive NTP messages. For security purposes, you can disable some of the interfaces from receiving NTP messages.
To disable an interface from receiving NTP messages:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enter interface view. |
interface interface-type interface-number |
N/A |
|
3. Disable the interface from receiving NTP messages. |
·
For IPv4: ·
For IPv6: |
By default, an interface receives NTP messages. |
Configuring the maximum number of dynamic associations
NTP has the following types of associations:
· Static association—A manually created association.
· Dynamic association—Temporary association created by the system during NTP operation. A dynamic association is removed if no messages are exchanged within about 12 minutes.
The following describes how an association is established in different association modes:
· Client/server mode—After you specify an NTP server, the system creates a static association on the client. The server simply responds passively upon the receipt of a message, rather than creating an association (static or dynamic).
· Symmetric active/passive mode—After you specify a symmetric-passive peer on a symmetric active peer, static associations are created on the symmetric-active peer, and dynamic associations are created on the symmetric-passive peer.
· Broadcast or multicast mode—Static associations are created on the server, and dynamic associations are created on the client.
A single device can have a maximum of 128 concurrent associations, including static associations and dynamic associations.
Perform this task to restrict the number of dynamic associations to prevent dynamic associations from occupying too many system resources.
To configure the maximum number of dynamic associations:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Configure the maximum number of dynamic sessions allowed to be established. |
ntp-service max-dynamic-sessions number |
By default, the command can establish up to 100 dynamic sessions. |
Setting a DSCP value for NTP packets
The DSCP value determines the sending precedence of a packet.
To configure a DSCP value for NTP packets:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Set a DSCP value for NTP packets. |
·
IPv4 packets: ·
IPv6 packets: |
The default DSCP value is 48 for IPv4 packets and 56 for IPv6 packets. |
Configuring the local clock as a reference source
Follow these guidelines when you configure the local clock as a reference source:
· Make sure the local clock can provide the time accuracy required for the network. After you configure the local clock as a reference source, the local clock is synchronized, and can operate as a time server to synchronize other devices in the network. If the local clock is incorrect, timing errors occur.
· Before you configure this feature, adjust the local system time to make sure it is accurate.
To configure the local clock as a reference source:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Configure the local clock as a reference source. |
ntp-service refclock-master [ ip-address ] [ stratum ] |
By default, the device does not use the local clock as a reference source. |
Displaying and maintaining NTP
Execute display commands in any view.
|
Task |
Command |
|
Display information about IPv6 NTP associations. |
display ntp-service ipv6 sessions [ verbose ] |
|
Display information about IPv4 NTP associations. |
display ntp-service sessions [ verbose ] |
|
Display information about NTP service status. |
display ntp-service status |
|
Display brief information about the NTP servers from the local device back to the primary reference source. |
display ntp-service trace |
NTP configuration examples
NTP client/server mode configuration example
Network requirements
As shown in Figure 4:
· Configure the local clock of Device A as a reference source, with the stratum level 2.
· Configure Device B to operate in client mode and Device A to be used as the NTP server for Device B.
Configuration procedure
1. Set the IP address for each interface, and make sure Device A and Device B can reach each other, as shown in Figure 4. (Details not shown.)
2. Configure Device A:
# Enable the NTP service.
<DeviceA> system-view
[DeviceA] ntp-service enable
# Specify the local clock as the reference source, with the stratum level 2.
[DeviceA] ntp-service refclock-master 2
3. Configure Device B:
# Enable the NTP service.
<DeviceB> system-view
[DeviceB] ntp-service enable
# Specify Device A as the NTP server of Device B so that Device B is synchronized to Device A.
[DeviceB] ntp-service unicast-server 1.0.1.11
4. Verify the configuration:
# Verify that Device B has synchronized to Device A, and the clock stratum level is 3 on Device B and 2 on Device A.
[DeviceB] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 1.0.1.11
Local mode: client
Reference clock ID: 1.0.1.11
Leap indicator: 00
Clock jitter: 0.000977 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.00383 ms
Root dispersion: 16.26572 ms
Reference time: d0c6033f.b9923965 Wed, Dec 29 2010 18:58:07.724
# Verify that an IPv4 NTP association has been established between Device B and Device A.
[DeviceB] display ntp-service sessions
source reference stra reach poll now offset delay disper
********************************************************************************
[12345]1.0.1.11 127.127.1.0 2 1 64 15 -4.0 0.0038 16.262
Notes: 1 source(master), 2 source(peer), 3 selected, 4 candidate, 5 configured.
Total sessions: 1
IPv6 NTP client/server mode configuration example
Network requirements
As shown in Figure 5:
· Configure the local clock of Device A as a reference source, with the stratum level 2.
· Configure Device B to operate in client mode and Device A to be used as the IPv6 NTP server for Device B.
Configuration procedure
1. Set the IP address for each interface, and make sure Device A and Device B can reach each other, as shown in Figure 5. (Details not shown.)
2. Configure Device A:
# Enable the NTP service.
<DeviceA> system-view
[DeviceA] ntp-service enable
# Specify the local clock as the reference source, with the stratum level 2.
[DeviceA] ntp-service refclock-master 2
3. Configure Device B:
# Enable the NTP service.
<DeviceB> system-view
[DeviceB] ntp-service enable
# Specify Device A as the IPv6 NTP server of Device B so that Device B is synchronized to Device A.
[DeviceB] ntp-service ipv6 unicast-server 3000::34
4. Verify the configuration:
# Verify that Device B has synchronized to Device A, and the clock stratum level is 3 on Device B and 2 on Device A.
[DeviceB] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 3000::34
Local mode: client
Reference clock ID: 163.29.247.19
Leap indicator: 00
Clock jitter: 0.000977 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.02649 ms
Root dispersion: 12.24641 ms
Reference time: d0c60419.9952fb3e Wed, Dec 29 2010 19:01:45.598
# Verify that an IPv6 NTP association has been established between Device B and Device A.
[DeviceB] display ntp-service ipv6 sessions
Notes: 1 source(master), 2 source(peer), 3 selected, 4 candidate, 5 configured.
Source: [12345]3000::34
Reference: 127.127.1.0 Clock stratum: 2
Reachabilities: 15 Poll interval: 64
Last receive time: 19 Offset: 0.0
Roundtrip delay: 0.0 Dispersion: 0.0
Total sessions: 1
NTP symmetric active/passive mode configuration example
Network requirements
As shown in Figure 6:
· Configure the local clock of Device A as a reference source, with the stratum level 2.
· Configure Device A to operate in symmetric-active mode and specify Device B as the passive peer of Device A.
Configuration procedure
1. Set the IP address for each interface, and make sure Device A and Device B can reach each other, as shown in Figure 6. (Details not shown.)
2. Configure Device B:
# Enable the NTP service.
<DeviceB> system-view
[DeviceB] ntp-service enable
3. Configure Device A:
# Enable the NTP service.
<DeviceA> system-view
[DeviceA] ntp-service enable
# Specify the local clock as the reference source, with the stratum level 2.
[DeviceA] ntp-service refclock-master 2
# Configure Device B as a symmetric passive peer.
[DeviceA] ntp-service unicast-peer 3.0.1.32
4. Verify the configuration:
# Verify that Device B has synchronized to Device A.
[DeviceB] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 3.0.1.31
Local mode: sym_passive
Reference clock ID: 3.0.1.31
Leap indicator: 00
Clock jitter: 0.000916 s
Stability: 0.000 pps
Clock precision: 2^-17
Root delay: 0.00609 ms
Root dispersion: 1.95859 ms
Reference time: 83aec681.deb6d3e5 Wed, Jan 8 2014 14:33:11.081
# Verify that an IPv4 NTP association has been established between Device B and Device A.
[DeviceB] display ntp-service sessions
source reference stra reach poll now offset delay disper
********************************************************************************
[12]3.0.1.31 127.127.1.0 2 62 64 34 0.4251 6.0882 1392.1
Notes: 1 source(master), 2 source(peer), 3 selected, 4 candidate, 5 configured.
Total sessions: 1
IPv6 NTP symmetric active/passive mode configuration example
Network requirements
As shown in Figure 7:
· Configure the local clock of Device A as a reference source, with the stratum level 2.
· Configure Device A to operate in symmetric-active mode and specify Device B as the IPv6 passive peer of Device A.
Configuration procedure
1. Set the IP address for each interface as shown in Figure 7. (Details not shown.)
2. Configure Device B:
# Enable the NTP service.
<DeviceB> system-view
[DeviceB] ntp-service enable
3. Configure Device A:
# Enable the NTP service.
<DeviceA> system-view
[DeviceA] ntp-service enable
# Specify the local clock as the reference source, with the stratum level 2.
[DeviceA] ntp-service refclock-master 2
# Configure Device B as an IPv6 symmetric passive peer.
[DeviceA] ntp-service ipv6 unicast-peer 3000::36
4. Verify the configuration:
# Verify that Device B has synchronized to Device A.
[DeviceB] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 3000::35
Local mode: sym_passive
Reference clock ID: 251.73.79.32
Leap indicator: 11
Clock jitter: 0.000977 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.01855 ms
Root dispersion: 9.23483 ms
Reference time: d0c6047c.97199f9f Wed, Dec 29 2010 19:03:24.590
# Verify that an IPv6 NTP association has been established between Device B and Device A.
[DeviceB] display ntp-service ipv6 sessions
Notes: 1 source(master), 2 source(peer), 3 selected, 4 candidate, 5 configured.
Source: [1234]3000::35
Reference: 127.127.1.0 Clock stratum: 2
Reachabilities: 15 Poll interval: 64
Last receive time: 19 Offset: 0.0
Roundtrip delay: 0.0 Dispersion: 0.0
Total sessions: 1
NTP broadcast mode configuration example
Network requirements
As shown in Figure 8, Switch C functions as the NTP server for multiple devices on a network segment and synchronizes the time among multiple devices.
· Configure Switch C's local clock as a reference source, with the stratum level 2.
· Configure Switch C to operate in broadcast server mode and send out broadcast messages from VLAN-interface 2.
· Configure Switch A and Switch B to operate in broadcast client mode, and listen to broadcast messages through VLAN-interface 2.
Configuration procedure
1. Set the IP address for each interface, and make sure Switch A, Switch B, and Switch C can reach each other, as shown in Figure 8. (Details not shown.)
2. Configure Switch C:
# Enable the NTP service.
<SwitchC> system-view
[SwitchC] ntp-service enable
# Specify the local clock as the reference source, with the stratum level 2.
[SwitchC] ntp-service refclock-master 2
# Configure Switch C to operate in broadcast server mode and send broadcast messages through VLAN-interface 2.
[SwitchC] interface vlan-interface 2
[SwitchC-Vlan-interface2] ntp-service broadcast-server
3. Configure Switch A:
# Enable the NTP service.
<SwitchA> system-view
[SwitchA] ntp-service enable
# Configure Switch A to operate in broadcast client mode and receive broadcast messages on VLAN-interface 2.
[SwitchA] interface vlan-interface 2
[SwitchA-Vlan-interface2] ntp-service broadcast-client
4. Configure Switch B:
# Enable the NTP service.
<SwitchB> system-view
[SwitchB] ntp-service enable
# Configure Switch B to operate in broadcast client mode and receive broadcast messages on VLAN-interface 2.
[SwitchB] interface vlan-interface 2
[SwitchB-Vlan-interface2] ntp-service broadcast-client
5. Verify the configuration:
# Verify that Switch A has synchronized to Switch C, and the clock stratum level is 3 on Switch A and 2 on Switch C.
[SwitchA-Vlan-interface2] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 3.0.1.31
Local mode: bclient
Reference clock ID: 3.0.1.31
Leap indicator: 00
Clock jitter: 0.044281 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.00229 ms
Root dispersion: 4.12572 ms
Reference time: d0d289fe.ec43c720 Sat, Jan 8 2011 7:00:14.922
# Verify that an IPv4 NTP association has been established between Switch A and Switch C.
[SwitchA-Vlan-interface2] display ntp-service sessions
source reference stra reach poll now offset delay disper
********************************************************************************
[1245]3.0.1.31 127.127.1.0 2 1 64 519 -0.0 0.0022 4.1257
Notes: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured.
Total sessions: 1
NTP multicast mode configuration example
Network requirements
As shown in Figure 9, Switch C functions as the NTP server for multiple devices on different network segments and synchronizes the time among multiple devices.
· Configure Switch C's local clock as a reference source, with the stratum level 2.
· Configure Switch C to operate in multicast server mode and send out multicast messages from VLAN-interface 2.
· Configure Switch A and Switch D to operate in multicast client mode and receive multicast messages through VLAN-interface 3 and VLAN-interface 2, respectively.
Configuration procedure
1. Set the IP address for each interface, and make sure the switches can reach each other, as shown in Figure 9. (Details not shown.)
2. Configure Switch C:
# Enable the NTP service.
<SwitchC> system-view
[SwitchC] ntp-service enable
# Specify the local clock as the reference source, with the stratum level 2.
[SwitchC] ntp-service refclock-master 2
# Configure Switch C to operate in multicast server mode and send multicast messages through VLAN-interface 2.
[SwitchC] interface vlan-interface 2
[SwitchC-Vlan-interface2] ntp-service multicast-server
3. Configure Switch D:
# Enable the NTP service.
<SwitchD> system-view
[SwitchD] ntp-service enable
# Configure Switch D to operate in multicast client mode and receive multicast messages on VLAN-interface 2.
[SwitchD] interface vlan-interface 2
[SwitchD-Vlan-interface2] ntp-service multicast-client
4. Verify the configuration:
Switch D and Switch C are on the same subnet, so Switch D can do the following:
¡ Receive the multicast messages from Switch C without being enabled with the multicast functions.
¡ Synchronize to Switch C.
# Verify that Switch D has synchronized to Switch C, and the clock stratum level is 3 on Switch D and 2 on Switch C.
[SwitchD-Vlan-interface2] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 3.0.1.31
Local mode: bclient
Reference clock ID: 3.0.1.31
Leap indicator: 00
Clock jitter: 0.044281 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.00229 ms
Root dispersion: 4.12572 ms
Reference time: d0d289fe.ec43c720 Sat, Jan 8 2011 7:00:14.922
# Verify that an IPv4 NTP association has been established between Switch D and Switch C.
[SwitchD-Vlan-interface2] display ntp-service sessions
source reference stra reach poll now offset delay disper
********************************************************************************
[1245]3.0.1.31 127.127.1.0 2 1 64 519 -0.0 0.0022 4.1257
Notes: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured.
Total sessions: 1
5. Configure Switch B:
Because Switch A and Switch C are on different subnets, you must enable the multicast functions on Switch B before Switch A can receive multicast messages from Switch C.
# Enable IP multicast routing and IGMP.
<SwitchB> system-view
[SwitchB] multicast routing
[SwitchB-mrib] quit
[SwitchB] interface vlan-interface 2
[SwitchB-Vlan-interface2] pim dm
[SwitchB-Vlan-interface2] quit
[SwitchB] vlan 3
[SwitchB-vlan3] port ten-gigabitethernet 1/0/1
[SwitchB-vlan3] quit
[SwitchB] interface vlan-interface 3
[SwitchB-Vlan-interface3] igmp enable
[SwitchB-Vlan-interface3] igmp static-group 224.0.1.1
[SwitchB-Vlan-interface3] quit
[SwitchB] igmp-snooping
[SwitchB-igmp-snooping] quit
[SwitchB] interface ten-gigabitethernet 1/0/1
[SwitchB- Ten-GigabitEthernet1/0/1] igmp-snooping static-group 224.0.1.1 vlan 3
6. Configure Switch A:
# Enable the NTP service.
<SwitchA> system-view
[SwitchA] ntp-service enable
# Configure Switch A to operate in multicast client mode and receive multicast messages on VLAN-interface 3.
[SwitchA] interface vlan-interface 3
[SwitchA-Vlan-interface3] ntp-service multicast-client
7. Verify the configuration:
# Verify that Switch A has synchronized to Switch C, and the clock stratum level is 3 on Switch A and 2 on Switch C.
[SwitchA-Vlan-interface3] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 3.0.1.31
Local mode: bclient
Reference clock ID: 3.0.1.31
Leap indicator: 00
Clock jitter: 0.165741 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.00534 ms
Root dispersion: 4.51282 ms
Reference time: d0c61289.10b1193f Wed, Dec 29 2010 20:03:21.065
# Verify that an IPv4 NTP association has been established between Switch A and Switch C.
[SwitchA-Vlan-interface3] display ntp-service sessions
source reference stra reach poll now offset delay disper
********************************************************************************
[1234]3.0.1.31 127.127.1.0 2 247 64 381 -0.0 0.0053 4.5128
Notes: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured.
Total sessions: 1
IPv6 NTP multicast mode configuration example
Network requirements
As shown in Figure 10, Switch C functions as the NTP server for multiple devices on different network segments and synchronizes the time among multiple devices.
· Configure Switch C's local clock as a reference source, with the stratum level 2.
· Configure Switch C to operate in IPv6 multicast server mode and send out IPv6 multicast messages from VLAN-interface 2.
· Configure Switch A and Switch D to operate in IPv6 multicast client mode and receive IPv6 multicast messages through VLAN-interface 3 and VLAN-interface 2, respectively.
Configuration procedure
1. Set the IP address for each interface, and make sure the switches can reach each other, as shown in Figure 10. (Details not shown.)
2. Configure Switch C:
# Enable the NTP service.
<SwitchC> system-view
[SwitchC] ntp-service enable
# Specify the local clock as the reference source, with the stratum level 2.
[SwitchC] ntp-service refclock-master 2
# Configure Switch C to operate in IPv6 multicast server mode and send multicast messages through VLAN-interface 2.
[SwitchC] interface vlan-interface 2
[SwitchC-Vlan-interface2] ntp-service ipv6 multicast-server ff24::1
3. Configure Switch D:
# Enable the NTP service.
<SwitchD> system-view
[SwitchD] ntp-service enable
# Configure Switch D to operate in IPv6 multicast client mode and receive multicast messages on VLAN-interface 2.
[SwitchD] interface vlan-interface 2
[SwitchD-Vlan-interface2] ntp-service ipv6 multicast-client ff24::1
4. Verify the configuration:
Switch D and Switch C are on the same subnet, so Switch D can do the following:
¡ Receive the IPv6 multicast messages from Switch C without being enabled with the IPv6 multicast functions.
¡ Synchronize to Switch C.
# Verify that Switch D has synchronized to Switch C, and the clock stratum level is 3 on Switch D and 2 on Switch C.
[SwitchD-Vlan-interface2] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 3000::2
Local mode: bclient
Reference clock ID: 165.84.121.65
Leap indicator: 00
Clock jitter: 0.000977 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.00000 ms
Root dispersion: 8.00578 ms
Reference time: d0c60680.9754fb17 Wed, Dec 29 2010 19:12:00.591
# Verify that an IPv6 NTP association has been established between Switch D and Switch C.
[SwitchD-Vlan-interface2] display ntp-service ipv6 sessions
Notes: 1 source(master), 2 source(peer), 3 selected, 4 candidate, 5 configured.
Source: [1234]3000::2
Reference: 127.127.1.0 Clock stratum: 2
Reachabilities: 111 Poll interval: 64
Last receive time: 23 Offset: -0.0
Roundtrip delay: 0.0 Dispersion: 0.0
Total sessions: 1
5. Configure Switch B:
Because Switch A and Switch C are on different subnets, you must enable the IPv6 multicast functions on Switch B before Switch A can receive IPv6 multicast messages from Switch C.
# Enable IPv6 multicast functions.
<SwitchB> system-view
[SwitchB] ipv6 multicast routing
[SwitchB-mrib6] quit
[SwitchB] interface vlan-interface 2
[SwitchB-Vlan-interface2] ipv6 pim dm
[SwitchB-Vlan-interface2] quit
[SwitchB] vlan 3
[SwitchB-vlan3] port ten-gigabitethernet 1/0/1
[SwitchB-vlan3] quit
[SwitchB] interface vlan-interface 3
[SwitchB-Vlan-interface3] mld enable
[SwitchB-Vlan-interface3] mld static-group ff24::1
[SwitchB-Vlan-interface3] quit
[SwitchB] mld-snooping
[SwitchB-mld-snooping] quit
[SwitchB] interface ten-gigabitethernet 1/0/1
[SwitchB-Ten-GigabitEthernet1/0/1] mld-snooping static-group ff24::1 vlan 3
6. Configure Switch A:
# Enable the NTP service.
<SwitchA> system-view
[SwitchA] ntp-service enable
# Configure Switch A to operate in IPv6 multicast client mode and receive IPv6 multicast messages on VLAN-interface 3.
[SwitchA] interface vlan-interface 3
[SwitchA-Vlan-interface3] ntp-service ipv6 multicast-client ff24::1
7. Verify the configuration:
# Verify that Switch A has synchronized to Switch C, and the clock stratum level is 3 on Switch A and 2 on Switch C.
[SwitchA-Vlan-interface3] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 3000::2
Local mode: bclient
Reference clock ID: 165.84.121.65
Leap indicator: 00
Clock jitter: 0.165741 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.00534 ms
Root dispersion: 4.51282 ms
Reference time: d0c61289.10b1193f Wed, Dec 29 2010 20:03:21.065
# Verify that an IPv6 NTP association has been established between Switch A and Switch C.
[SwitchA-Vlan-interface3] display ntp-service ipv6 sessions
Notes: 1 source(master), 2 source(peer), 3 selected, 4 candidate, 5 configured.
Source: [124]3000::2
Reference: 127.127.1.0 Clock stratum: 2
Reachabilities: 2 Poll interval: 64
Last receive time: 71 Offset: -0.0
Roundtrip delay: 0.0 Dispersion: 0.0
Total sessions: 1
Configuration example for NTP client/server mode with authentication
Network requirements
As shown in Figure 11:
· Configure the local clock of Device A as a reference source, with the stratum level 2.
· Configure Device B to operate in client mode and specify Device A as the NTP server of Device B, with Device B as the client.
· Configure NTP authentication on both Device A and Device B.
Configuration procedure
1. Set the IP address for each interface, and make sure Device A and Device B can reach each other, as shown in Figure 11. (Details not shown.)
2. Configure Device A:
# Enable the NTP service.
<DeviceA> system-view
[DeviceA] ntp-service enable
# Specify the local clock as the reference source, with the stratum level 2.
[DeviceA] ntp-service refclock-master 2
3. Configure Device B:
# Enable the NTP service.
<DeviceB> system-view
[DeviceB] ntp-service enable
# Enable NTP authentication on Device B.
[DeviceB] ntp-service authentication enable
# Set an authentication key, and input the key in plain text.
[DeviceB] ntp-service authentication-keyid 42 authentication-mode md5 simple aNiceKey
# Specify the key as a trusted key.
[DeviceB] ntp-service reliable authentication-keyid 42
# Specify Device A as the NTP server of Device B, and associate the server with key 42.
[DeviceB] ntp-service unicast-server 1.0.1.11 authentication-keyid 42
Before Device B can synchronize its clock to that of Device A, enable NTP authentication for Device A.
4. Configure NTP authentication on Device A:
# Enable NTP authentication.
[DeviceA] ntp-service authentication enable
# Set an authentication key, and input the key in plain text.
[DeviceA] ntp-service authentication-keyid 42 authentication-mode md5 simple aNiceKey
# Specify the key as a trusted key.
[DeviceA] ntp-service reliable authentication-keyid 42
5. Verify the configuration:
# Verify that Device B has synchronized to Device A, and the clock stratum level is 3 on Device B and 2 on Device A.
[DeviceB] display ntp-service status
Clock status: synchronized
Clock stratum: 3
System peer: 1.0.1.11
Local mode: client
Reference clock ID: 1.0.1.11
Leap indicator: 00
Clock jitter: 0.005096 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.00655 ms
Root dispersion: 1.15869 ms
Reference time: d0c62687.ab1bba7d Wed, Dec 29 2010 21:28:39.668
# Verify that an IPv4 NTP association has been established between Device B and Device A.
[DeviceB] display ntp-service sessions
source reference stra reach poll now offset delay disper
********************************************************************************
[1245]1.0.1.11 127.127.1.0 2 1 64 519 -0.0 0.0065 0.0
Notes: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured.
Total sessions: 1
Configuration example for NTP broadcast mode with authentication
Network requirements
As shown in Figure 12, Switch C functions as the NTP server for multiple devices on different network segments and synchronizes the time among multiple devices. Switch A and Switch B authenticate the reference source.
· Configure Switch C's local clock as a reference source, with the stratum level 3.
· Configure Switch C to operate in broadcast server mode and send out broadcast messages from VLAN-interface 2.
· Configure Switch A and Switch B to operate in broadcast client mode and receive broadcast messages through VLAN-interface 2.
· Enable NTP authentication on Switch A, Switch B, and Switch C.
Configuration procedure
1. Set the IP address for each interface, and make sure Switch A, Switch B, and Switch C can reach each other, as shown in Figure 12. (Details not shown.)
2. Configure Switch A:
# Enable the NTP service.
<SwitchA> system-view
[SwitchA] ntp-service enable
# Enable NTP authentication on Switch A. Configure an NTP authentication key, with the key ID of 88 and key value of 123456. Input the key in plain text, and specify it as a trusted key.
[SwitchA] ntp-service authentication enable
[SwitchA] ntp-service authentication-keyid 88 authentication-mode md5 simple 123456
[SwitchA] ntp-service reliable authentication-keyid 88
# Configure Switch A to operate in NTP broadcast client mode and receive NTP broadcast messages on VLAN-interface 2.
[SwitchA] interface vlan-interface 2
[SwitchA-Vlan-interface2] ntp-service broadcast-client
3. Configure Switch B:
# Enable the NTP service.
<SwitchB> system-view
[SwitchB] ntp-service enable
# Enable NTP authentication on Switch B. Configure an NTP authentication key, with the key ID of 88 and key value of 123456. Input the key in plain text and specify it as a trusted key.
[SwitchB] ntp-service authentication enable
[SwitchB] ntp-service authentication-keyid 88 authentication-mode md5 simple 123456
[SwitchB] ntp-service reliable authentication-keyid 88
# Configure Switch B to operate in broadcast client mode and receive NTP broadcast messages on VLAN-interface 2.
[SwitchB] interface vlan-interface 2
[SwitchB-Vlan-interface2] ntp-service broadcast-client
4. Configure Switch C:
# Enable the NTP service.
<SwitchC> system-view
[SwitchC] ntp-service enable
# Specify the local clock as the reference source, with the stratum level 3.
[SwitchC] ntp-service refclock-master 3
# Configure Switch C to operate in NTP broadcast server mode and use VLAN-interface 2 to send NTP broadcast packets.
[SwitchC] interface vlan-interface 2
[SwitchC-Vlan-interface2] ntp-service broadcast-server
[SwitchC-Vlan-interface2] quit
5. Verify the configuration:
# NTP authentication is enabled on Switch A and Switch B, but not on Switch C, so Switch A and Switch B cannot synchronize their local clocks to Switch C. Display the NTP service status on Switch B.
[SwitchB-Vlan-interface2] display ntp-service status
Clock status: unsynchronized
Clock stratum: 16
Reference clock ID: none
6. Enable NTP authentication on Switch C:
# Enable NTP authentication on Switch C. Configure an NTP authentication key, with the key ID of 88 and key value of 123456. Input the key in plain text, and specify it as a trusted key.
[SwitchC] ntp-service authentication enable
[SwitchC] ntp-service authentication-keyid 88 authentication-mode md5 simple 123456
[SwitchC] ntp-service reliable authentication-keyid 88
# Specify Switch C as an NTP broadcast server, and associate the key 88 with Switch C.
[SwitchC] interface vlan-interface 2
[SwitchC-Vlan-interface2] ntp-service broadcast-server authentication-keyid 88
7. Verify the configuration:
After NTP authentication is enabled on Switch C, Switch A and Switch B can synchronize their local clocks to Switch C.
# Verify that Switch B has synchronized to Switch C, and the clock stratum level is 4 on Switch B and 3 on Switch C.
[SwitchB-Vlan-interface2] display ntp-service status
Clock status: synchronized
Clock stratum: 4
System peer: 3.0.1.31
Local mode: bclient
Reference clock ID: 3.0.1.31
Leap indicator: 00
Clock jitter: 0.006683 s
Stability: 0.000 pps
Clock precision: 2^-10
Root delay: 0.00127 ms
Root dispersion: 2.89877 ms
Reference time: d0d287a7.3119666f Sat, Jan 8 2011 6:50:15.191
# Verify that an IPv4 NTP association has been established between Switch B and Switch C.
[SwitchB-Vlan-interface2] display ntp-service sessions
source reference stra reach poll now offset delay disper
********************************************************************************
[1245]3.0.1.31 127.127.1.0 3 3 64 68 -0.0 0.0000 0.0
Notes: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured.
Total sessions: 1
Configuring SNTP
SNTP is a simplified, client-only version of NTP specified in RFC 4330. SNTP supports only the client/server mode. An SNTP-enabled device can receive time from NTP servers, but cannot provide time services to other devices.
SNTP uses the same packet format and packet exchange procedure as NTP, but provides faster synchronization at the price of time accuracy.
If you specify multiple NTP servers for an SNTP client, the server with the best stratum is selected. If multiple servers are at the same stratum, the NTP server whose time packet is first received is selected.
Configuration restrictions and guidelines
Follow these restrictions and guidelines when you configure SNTP:
· You cannot configure both NTP and SNTP on the same device.
· Make sure you use the clock protocol command to specify the time protocol as NTP.
Configuration task list
|
Tasks at a glance |
|
(Required.) Enabling the SNTP service |
|
(Required.) Specifying an NTP server for the device |
|
(Optional.) Configuring SNTP authentication |
Enabling the SNTP service
The NTP service and SNTP service are mutually exclusive. You can only enable either NTP service or SNTP service at a time.
To enable the SNTP service:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable the SNTP service. |
sntp enable |
By default, the SNTP service is not enabled. |
Specifying an NTP server for the device
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Specify an NTP server for the device. |
·
For IPv4: ·
For IPv6: |
By default, no NTP server is specified for the device. Repeat this step to specify multiple NTP servers. To use authentication, you must specify the authentication-keyid keyid option. |
To use an NTP server as the time source, make sure its clock has been synchronized. If the stratum level of the NTP server is greater than or equal to that of the client, the client does not synchronize with the NTP server.
Configuring SNTP authentication
SNTP authentication makes sure an SNTP client is synchronized only to an authenticated trustworthy NTP server.
Follow these guidelines when you configure SNTP authentication:
· Enable authentication on both the NTP server and the SNTP client.
· Use the same authentication key ID, algorithm, and key on the NTP server and SNTP client. Specify the key as a trusted key on both the NTP server and the SNTP client. For information about configuring NTP authentication on an NTP server, see "Configuring NTP
Configuration restrictions and guidelines
Configuring NTP association mode
Configuring NTP in client/server mode
Configuring NTP in symmetric active/passive mode
Configuring NTP in broadcast mode
Configuring NTP in multicast mode
Configuring access control rights
Configuring NTP authentication
Configuring NTP authentication in client/server mode
Configuring NTP authentication in symmetric active/passive mode
Configuring NTP authentication in broadcast mode
Configuring NTP authentication in multicast mode
Configuring NTP optional parameters
Specifying the source interface for NTP messages
Disabling an interface from receiving NTP messages
Configuring the maximum number of dynamic associations
Setting a DSCP value for NTP packets
Configuring the local clock as a reference source
Displaying and maintaining NTP
NTP client/server mode configuration example
IPv6 NTP client/server mode configuration example
NTP symmetric active/passive mode configuration example
IPv6 NTP symmetric active/passive mode configuration example
NTP broadcast mode configuration example
NTP multicast mode configuration example
IPv6 NTP multicast mode configuration example
Configuration example for NTP client/server mode with authentication
Configuration example for NTP broadcast mode with authentication
Configuration restrictions and guidelines
Specifying an NTP server for the device
Configuring SNTP authentication
Displaying and maintaining SNTP
· On the SNTP client, associate the specified key with the NTP server. Make sure the server is allowed to use the key ID for authentication on the client.
With authentication disabled, the SNTP client can synchronize with the NTP server regardless of whether the NTP server is enabled with authentication.
To configure SNTP authentication on the SNTP client:
|
Step |
Command |
Remarks |
|
1. Enter system view. |
system-view |
N/A |
|
2. Enable SNTP authentication. |
sntp authentication enable |
By default, SNTP authentication is disabled. |
|
3. Configure an SNTP authentication key. |
sntp authentication-keyid keyid authentication-mode { hmac-sha-1 | hmac-sha-256 | hmac-sha-384 | hmac-sha-512 | md5 } { cipher | simple } string [ acl ipv4-acl-number | ipv6 acl ipv6-acl-number ] * |
By default, no SNTP authentication key is configured. |
|
4. Specify the key as a trusted key. |
sntp reliable authentication-keyid keyid |
By default, no trusted key is specified. |
|
5. Associate the SNTP authentication key with an NTP server. |
·
For IPv4: ·
For IPv6: |
By default, no NTP server is specified. |
Displaying and maintaining SNTP
Execute display commands in any view.
|
Task |
Command |
|
Display information about all IPv6 SNTP associations. |
display sntp ipv6 sessions |
|
Display information about all IPv4 SNTP associations. |
display sntp sessions |
SNTP configuration example
Network requirements
As shown in Figure 13:
· Configure the local clock of Device A as a reference source, with the stratum level 2.
· Configure Device B to operate in SNTP client mode, and specify Device A as the NTP server.
· Configure NTP authentication on Device A and SNTP authentication on Device B.
Configuration procedure
1. Set the IP address for each interface, and make sure Device A and Device B can reach each other, as shown in Figure 13. (Details not shown.)
2. Configure Device A:
# Enable the NTP service.
<DeviceA> system-view
[DeviceA] ntp-service enable
# Configure the local clock of Device A as a reference source, with the stratum level 2.
[DeviceA] ntp-service refclock-master 2
# Enable NTP authentication on Device A.
[DeviceA] ntp-service authentication enable
# Configure an NTP authentication key, with the key ID of 10 and key value of aNiceKey. Input the key in plain text.
[DeviceA] ntp-service authentication-keyid 10 authentication-mode md5 simple aNiceKey
# Specify the key as a trusted key.
[DeviceA] ntp-service reliable authentication-keyid 10
3. Configure Device B:
# Enable the SNTP service.
<DeviceB> system-view
[DeviceB] sntp enable
# Enable SNTP authentication on Device B.
[DeviceB] sntp authentication enable
# Configure an SNTP authentication key, with the key ID of 10 and key value of aNiceKey. Input the key in plain text.
[DeviceB] sntp authentication-keyid 10 authentication-mode md5 simple aNiceKey
# Specify the key as a trusted key.
[DeviceB] sntp reliable authentication-keyid 10
# Specify Device A as the NTP server of Device B, and associate the server with key 10.
[DeviceB] sntp unicast-server 1.0.1.11 authentication-keyid 10
4. Verify the configuration:
# Verify that an SNTP association has been established between Device B and Device A, and Device B has synchronized to Device A.
[DeviceB] display sntp sessions
NTP server Stratum Version Last receive time
1.0.1.11 2 4 Tue, May 17 2011 9:11:20.833 (Synced)
