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- Table of Contents
-
- 05-Network Connectivity
- 00-Preface
- 01-MAC address table commands
- 02-Ethernet link aggregation commands
- 03-VLAN commands
- 04-Loop detection commands
- 05-Spanning tree commands
- 06-LLDP commands
- 07-Layer 2 forwarding commands
- 08-L2TP commands
- 09-ARP commands
- 10-IP addressing commands
- 11-DHCP commands
- 12-DHCP snooping commands
- 13-DHCPv6 commands
- 14-DHCPv6 snooping commands
- 15-DNS commands
- 16-HTTP commands
- 17-IP forwarding basics commands
- 18-Fast forwarding commands
- 19-Adjacency table commands
- 20-IP performance optimization commands
- 21-IPv6 basics commands
- 22-IPv6 neighbor discovery commands
- 23-IPv6 fast forwarding commands
- 24-NAT commands
- 25-Basic IP routing commands
- 26-Static routing commands
- 27-RIP commands
- 28-OSPF commands
- 29-Policy-based routing commands
- 30-IPv6 policy-based routing commands
- 31-IPv6 static routing commands
- 32-RIPng commands
- 33-GRE commands
- 34-IGMP snooping commands
- 35-MLD snooping commands
- Related Documents
-
| Title | Size | Download |
|---|---|---|
| 28-OSPF commands | 611.72 KB |
Contents
display ospf fast-reroute lfa-candidate
display ospf global-statistics
enable out-of-band-resynchronization
graceful-restart helper enable
graceful-restart helper strict-lsa-checking
lsa-arrival-interval suppress-flapping
lsa-generation-interval suppress-flapping
maxage-lsa route-calculate-delay
OSPF commands
|
|
NOTE: The term router in this book refers to routing-capable devices. |
The following compatibility matrixes show the support of hardware platforms for OSPF:
|
Hardware series |
Model |
Product code |
OSPF compatibility |
|
WX3500X series |
WX3510X WX3520X WX3540X |
EWP-WX3510X EWP-WX3520X EWP-WX3540X |
No |
|
WCG380 series |
WCG382 |
EWP-WCG382 |
Yes |
|
Hardware series |
Model |
Product code |
OSPF compatibility |
|
WX3800X series |
WX3820X WX3840X |
EWP-WX3820X EWP-WX3840X |
No |
abr-summary
Use abr-summary to configure route summarization on an ABR.
Use undo abr-summary to remove the configuration.
Syntax
abr-summary ip-address { mask-length | mask } [ advertise | not-advertise ] [ cost cost-value ]
undo abr-summary ip-address { mask-length | mask }
Default
Route summarization is not configured on an ABR.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
ip-address: Specifies the destination IP address of the summary route in dotted decimal notation.
mask-length: Specifies the mask length in the range of 1 to 32.
mask: Specifies the mask of the IP address, in dotted decimal notation.
advertise | not-advertise: Advertises the summary route or not. By default, the command advertises the summary route.
cost cost-value: Specifies the cost of the summary route, in the range of 1 to 16777215. The default cost is the largest cost value among routes that are summarized.
Usage guidelines
This command applies only to an ABR to summarize multiple contiguous networks into one network.
To enable ABR to advertise specific routes that have been summarized, use the undo abr-summary command.
Examples
# Summarize networks 36.42.10.0/24 and 36.42.110.0/24 in Area 1 into 36.42.0.0/16.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 1
[Sysname-ospf-100-area-0.0.0.1] network 36.42.10.0 0.0.0.255
[Sysname-ospf-100-area-0.0.0.1] network 36.42.110.0 0.0.0.255
[Sysname-ospf-100-area-0.0.0.1] abr-summary 36.42.0.0 255.255.0.0
area
Use area to create an OSPF area and enter OSPF area view.
Use undo area to remove an OSPF area.
Syntax
area area-id
undo area area-id
Default
No OSPF areas exist.
Views
OSPF view
Predefined user roles
network-admin
Parameters
area-id: Specifies an area by its ID, an IP address or a decimal integer in the range of 0 to 4294967295 that is translated into the IP address format.
Examples
# Create Area 0 and enter Area 0 view.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 0
[Sysname-ospf-100-area-0.0.0.0]
asbr-summary
Use asbr-summary to configure route summarization on an ASBR.
Use undo asbr-summary to remove the configuration.
Syntax
asbr-summary ip-address { mask-length | mask } [ cost cost-value | not-advertise | nssa-only | tag tag ] *
undo asbr-summary ip-address { mask-length | mask }
Default
Route summarization is not configured on an ASBR.
Views
OSPF view
Predefined user roles
network-admin
Parameters
ip-address: Specifies the destination IP address of the summary route.
mask-length: Specifies the mask length in the range of 1 to 32.
mask: Specifies the mask in dotted decimal notation.
cost cost-value: Specifies the cost of the summary route, in the range of 1 to 16777214. If you do not specify this option, the largest cost among the summarized routes applies. If the routes in Type-5 LSAs translated from Type-7 LSAs are Type-2 external routes, the largest cost among the summarized routes plus 1 applies.
not-advertise: Disables advertising the summary route. If you do not specify this keyword, the command advertises the route.
nssa-only: Limits the route advertisement to the NSSA area by setting the P-bit of Type-7 LSAs to 0. By default, the P-bit of Type-7 LSAs is set to 1. If the ASBR is also an ABR and FULL state neighbors exist in the backbone area, the P-bit of Type-7 LSAs originated by the ASBR is set to 0. This keyword applies to the NSSA ASBR.
tag tag: Specifies a tag for the summary route, in the range of 0 to 4294967295. The default is 1. The tag can be used by a routing policy to control summary route advertisement.
Usage guidelines
An ASBR can summarize routes in the following LSAs:
· Type-5 LSAs.
· Type-7 LSAs in an NSSA area.
· Type-5 LSAs translated by the ASBR (also an ABR) from Type-7 LSAs in an NSSA area.
If the ASBR (ABR) is not a translator, it cannot summarize routes in Type-5 LSAs translated from Type-7 LSAs.
To enable ASBR to advertise specific routes that have been summarized, use the undo asbr-summary command.
Examples
# Summarize redistributed static routes into a single route, and specify a tag value of 2 and a cost of 100 for the summary route.
<Sysname> system-view
[Sysname] ip route-static 10.2.1.0 24 null 0
[Sysname] ip route-static 10.2.2.0 24 null 0
[Sysname] ospf 100
[Sysname-ospf-100] import-route static
[Sysname-ospf-100] asbr-summary 10.2.0.0 255.255.0.0 tag 2 cost 100
authentication-mode
Use authentication-mode to specify an authentication mode for an OSPF area.
Use undo authentication-mode to remove the configuration.
Syntax
For MD5/HMAC-MD5/HMAC-SHA-256 authentication:
authentication-mode { hmac-md5 | hmac-sha-256 | md5 } key-id { cipher | plain } string
undo authentication-mode [ { hmac-md5 | hmac-sha-256 | md5 } key-id ]
For simple authentication:
authentication-mode simple { cipher | plain } string
undo authentication-mode
Default
No authentication is performed for an area.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
hmac-md5: Specifies the HMAC-MD5 authentication mode.
hmac-sha-256: Specifies the HMAC-SHA-256 authentication mode.
md5: Specifies the MD5 authentication mode.
simple: Specifies the simple authentication mode.
key-id: Specifies a key by its ID in the range of 0 to 255.
cipher: Specifies a key in encrypted form.
plain: Specifies a key in plaintext form. For security purposes, the key specified in plaintext form will be stored in encrypted form.
string: Specifies the key. This argument is case sensitive.
· In simple authentication mode, the plaintext form of the key is a string of 1 to 8 characters. The encrypted form of the key is a string of 33 to 41 characters.
· In MD5/HMAC-MD5 authentication mode, the plaintext form of the key is a string of 1 to 16 characters. The encrypted form of the key is a string of 33 to 53 characters.
· In HMAC-SHA-256 authentication mode, the plaintext form of the key is a string of 1 to 255 characters. The encrypted form of the key is a string of 33 to 373 characters.
Usage guidelines
To establish or maintain adjacencies, routers in the same area must have the same authentication mode and key.
If MD5, HMAC-MD5, or HMAC-SHA-256 authentication is configured, you can configure multiple keys, each having a unique key ID and key string. As a best practice to minimize the risk of key compromise, use only one key for an area and delete the old key after key replacement.
To replace the key used for MD5, HMAC-MD5, or HMAC-SHA-256 authentication in an area, you must configure the new key before removing the old key from each router. OSPF uses the key rollover mechanism to ensure that the routers can pass authentication before the replacement is complete across the area. After you configure a new key on a router, the router sends copies of the same packet, each authenticated by a different key, including the new key and the keys in use. This practice continues until the router detects that all its neighbors have the new key.
Examples
# Configure OSPF Area 0 to use the MD5 authentication mode, and set the key ID to 15 and the key to abc in plaintext form.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 0
[Sysname-ospf-100-area-0.0.0.0] authentication-mode md5 15 plain abc
ospf authentication-mode
bandwidth-reference
Use bandwidth-reference to set a reference bandwidth value for link cost calculation.
Use undo bandwidth-reference to restore the default value.
Syntax
bandwidth-reference value
undo bandwidth-reference
Default
The reference bandwidth value is 100 Mbps for link cost calculation.
Views
OSPF view
Predefined user roles
network-admin
Parameters
value: Specifies the reference bandwidth value for link cost calculation, in the range of 1 to 4294967 Mbps.
Usage guidelines
If no cost values are configured for links, OSPF calculates their cost values by using the following formula: Cost = Reference bandwidth value / Expected interface bandwidth. The expected bandwidth of an interface is configured with the bandwidth command. If the calculated cost is greater than 65535, the value of 65535 is used. If the calculated cost is less than 1, the value of 1 is used.
Examples
# Set the reference bandwidth value to 1000 Mbps.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] bandwidth-reference 1000
Related commands
bandwidth (Interface Command Reference)
ospf cost
database-filter peer
Use database-filter peer to filter LSAs for the specified P2MP neighbor.
Use undo database-filter peer to restore the default.
Syntax
database-filter peer ip-address { all | { ase [ acl ipv4-acl-number ] | nssa [ acl ipv4-acl-number ] | summary [ acl ipv4-acl-number ] } * }
undo database-filter peer ip-address
Default
The LSAs for the specified P2MP neighbor are not filtered.
Views
OSPF view
Predefined user roles
network-admin
Parameters
ip-address: Specifies a P2MP neighbor by its IP address.
all: Filters all LSAs except the Grace LSAs.
ase: Filters Type-5 LSAs.
nssa: Filters Type-7 LSAs.
summary: Filters Type-3 LSAs.
acl ipv4-acl-number: Specifies an IPv4 ACL by its number in the range of 2000 to 3999.
Usage guidelines
On an P2MP network, a router might have multiple OSPF neighbors with the P2MP type. Use this command to prevent the router from sending LSAs to the specified neighbor.
If the specified ACL does not exist or has no rules, OSPF does not filter the LSAs sent to the specified neighbor.
To use an advanced ACL (with a number from 3000 to 3999) in the command, configure the ACL using one of the following methods:
· To deny/permit LSAs with the specified link state ID, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard command.
· To deny/permit LSAs with the specified link state ID and mask, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard destination dest-addr dest-wildcard command.
The source keyword specifies the link state ID of an LSA and the destination keyword specifies the subnet mask of the LSA. For the mask configuration to take effect, specify a contiguous subnet mask.
If the specified neighbor has already received an LSA, the LSA still exists in the LSDB of the neighbor after you execute the command.
Examples
# Filter all LSAs (except the Grace LSAs) for the P2MP neighbor with the IP address 121.20.20.121.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] database-filter peer 121.20.20.121 all
# Configure advanced ACL 3000 to filter Type-3 LSAs for the P2MP neighbor with the IP address 121.20.20.121.
<Sysname> system-view
[Sysname] acl advanced 3000
[Sysname-acl-ipv4-adv-3000]rule 10 deny ip source 121.20.0.0 0 destination 255.255.0.0 0
[Sysname-acl-ipv4-adv-3000] rule 100 permit ip
[Sysname-acl-ipv4-adv-3000] quit
[Sysname] ospf 1
[Sysname-ospf-1] database-filter peer 121.20.20.121 summary acl 3000
Related commands
ospf database-filter
default
Use default to configure default parameters for redistributed routes.
Use undo default to remove the configuration.
Syntax
default { cost cost-value | tag tag | type type } *
undo default { cost | tag | type } *
Default
The cost is 1, the tag is 1, and the route type is 2.
Views
OSPF view
Predefined user roles
network-admin
Parameters
cost cost-value: Specifies a default cost for redistributed routes, in the range of 0 to 16777214.
tag tag: Specifies a tag for redistributed routes, in the range of 0 to 4294967295.
type type: Specifies a type for redistributed routes: 1 or 2.
Examples
# Set the default cost, tag, and type to 10, 100, and 2 for redistributed external routes.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] default cost 10 tag 100 type 2
Related commands
import-route
default-cost
Use default-cost to set a cost for the default route advertised to the stub or NSSA area.
Use undo default-cost to restore the default value.
Syntax
default-cost cost-value
undo default-cost
Default
The cost is 1.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
cost-value: Specifies a cost for the default route advertised to the Stub or NSSA area, in the range of 0 to 16777214.
Usage guidelines
This command takes effect only on the ABR of a stub area or the ABR or ASBR of an NSSA area.
Examples
# Configure Area 1 as a stub area, and set the cost of the default route advertised to the stub area to 20.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 1
[Sysname-ospf-100-area-0.0.0.1] stub
[Sysname-ospf-100-area-0.0.0.1] default-cost 20
nssa
stub
default-route-advertise
Use default-route-advertise to redistribute a default route into the OSPF routing domain.
Use undo default-route-advertise to restore the default.
Syntax
default-route-advertise [ [ always | permit-calculate-other ] | cost cost-value | type type ] *
undo default-route-advertise
Default
No default route is redistributed into the OSPF routing domain.
Views
OSPF view
Predefined user roles
network-admin
Parameters
always: Redistributes a default route in a Type-5 LSA into the OSPF routing domain regardless of whether a default route exists in the routing table. If you do not specify this keyword, the router redistributes a default route only when an active default route that does not belong to the current OSPF process exists in the IP routing table.
permit-calculate-other: Enables OSPF to calculate default routes received from other routers. If you do not specify this keyword, OSPF does not calculate default routes from other routers. If the router does not redistribute any default route in a Type-5 LSA into the OSPF routing domain, the router calculates default routes from other routers. It calculates these routes regardless of whether this keyword is specified.
cost cost-value: Specifies a cost for the default route, in the range of 0 to 16777214. If you do not specify this option, the default cost specified by the default-cost command applies.
type type: Specifies a type for the Type-5 LSA: 1 or 2. If you do not specify this option, the default type for the Type-5 LSA specified by the default type command applies.
Usage guidelines
This command redistributes a default route in a Type-5 LSA, which cannot be redistributed with the import-route command. If the local routing table has no default route, you must specify the always keyword for the command.
Examples
# Redistribute a default route into the OSPF routing domain, regardless of whether the default route exists in the local routing table.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] default-route-advertise always
default
import-route
description
Use description to configure a description for an OSPF process or area.
Use undo description to restore the default.
Syntax
description text
undo description
Default
No description is configured for an OSPF process or area.
Views
OSPF view
OSPF area view
Predefined user roles
network-admin
Parameters
text: Specifies a description, a case-sensitive string of 1 to 80 characters.
Usage guidelines
The description specified by this command is used to identify an OSPF process or area.
Examples
# Describe OSPF process 100 as abc.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] description abc
# Describe OSPF Area 0 as bone area.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 0
[Sysname-ospf-100-area-0.0.0.0] description bone area
discard-route
Use discard-route to configure discard routes for summary networks.
Use undo discard-route to restore the default.
Syntax
discard-route { external { preference | suppression } | internal { preference | suppression } } *
undo discard-route [ external | internal ] *
Default
A device generates discard routes with preference 255 for summary networks.
Views
OSPF view
Predefined user roles
network-admin
Parameters
external: Specifies discard routes for redistributed summary networks on the ASBR. These discard routes are external discard routes.
preference: Specifies a preference for external discard routes, in the range of 1 to 255.
suppression: Disables the ASBR from generating external discard routes for summary networks.
internal: Specifies discard routes for summary networks on the ABR. These discard routes are internal discard routes.
preference: Specifies a preference for internal discard routes, in the range of 1 to 255.
suppression: Disables the ABR from generating internal discard routes for summary networks.
Examples
# Generate external and internal discard routes with preference 100 and 200, respectively.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] discard-route external 100 internal 200
display ospf
Use display ospf to display OSPF process information.
Syntax
display ospf [ process-id ] [ verbose ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays information about all OSPF processes.
verbose: Displays detailed OSPF process information. If you do not specify this keyword, the command displays brief OSPF process information.
Examples
# Display detailed OSPF process information.
<Sysname> display ospf verbose
OSPF Process 1 with Router ID 192.168.1.2
OSPF Protocol Information
RouterID: 192.168.1.2 Router type: NSSA
Route tag: 0
Multi-VPN-Instance is not enabled
Ext-community type: Domain ID 0x105, Route Type 0x8000, Router ID 0x8001
Domain ID: 0.0.0.0:23
Opaque capable
Isolation: Disabled
Originating router-LSAs with maximum metric
Condition: Always, State: Inactive
Advertise stub links with maximum metric in router-LSAs
Advertise summary-LSAs with metric 16711680
Advertise external-LSAs with metric 16711680
ISPF is enabled
SPF-schedule-interval: 50 (in milliseconds)
LSA generation interval: 5
LSA arrival interval: 1000
Transmit pacing: Interval: 20 Count: 3
Default ASE parameters: Metric: 1 Tag: 1 Type: 2
Route preference: 10
ASE route preference: 150
SPF computation count: 22
RFC 1583 compatible
Fast-reroute: lfa
Node-Protecing Preference: 40
Lowest-cost Preference: 20
SRLG Preference: 10
Microloop-avoidance: Enable
Microloop-avoidance RIB-update-delay: 5000 ms
Graceful restart interval: 120
SNMP trap rate limit interval: 2 Count: 300
This process is currently bound to MIB
Area count: 1 NSSA area count: 1
Normal areas with up interfaces: 0
NSSA areas with up interfaces: 1
Up interfaces: 1
ExChange/Loading neighbors: 0
Full neighbors:3
Area0 full neighbors: 1
Calculation trigger type: Full
Current calculation type: SPF calculation
Current calculation phase: Calculation area topology
Process reset state: N/A
Current reset type: N/A
Next reset type: N/A
Reset prepare message replied: -/-/-/-
Reset process message replied: -/-/-/-
Reset phase of module:
M-N/A, P-N/A, L-N/A, C-N/A, R-N/A
MPLS segment routing: Disabled
Segment routing adjacency : Disabled
Configured SRGB : 16000 16999
Effective SRGB : 16000 24000
Segment routing local block : 15000 15999
Segment routing tunnel count: 0
Area: 0.0.0.1 (MPLS TE not enabled)
Authentication type: None Area flag: NSSA
7/5 translator state: Disabled
7/5 translate stability timer interval: 0
SPF scheduled count: 5
ExChange/Loading neighbors: 0
Up interfaces: 1
Interface: 192.168.1.2 (Vlan-interface10)
Cost: 1 State: DR Type: Broadcast MTU: 1500
Priority: 1
Designated router: 192.168.1.2
Backup designated router: 192.168.1.1
Timers: Hello 10 , Dead 40 , Poll 40 , Retransmit 5 , Transmit Delay 1
FRR backup: Enabled
Enabled by network configuration
Packet size: 1000
Table 1 Command output
|
Field |
Description |
|
OSPF Process 1 with Router ID 192.168.1.2 |
OSPF process ID and OSPF router ID. |
|
RouterID |
Router ID. |
|
Router type |
Router type: · ABR. · ASBR. · NSSA. · Null. |
|
OSPF process state. If you shut down the process by using the shutdown process command, this field displays Admin-down. If the process is not shut down, this field is not displayed. |
|
|
Route tag |
Tag of redistributed routes. |
|
Multi-VPN-Instance is not enabled |
The OSPF process does not support multi-VPN-instance. |
|
Ext-community type |
OSPF extended community attribute type codes: · Domain ID—Domain ID code. · Router Type—Router type code. · Router ID—Router ID code. |
|
Domain ID |
OSPF domain ID (primary ID). |
|
Opaque capable |
Opaque LSA advertisement and reception capability is enabled. |
|
Isolation |
Whether OSPF isolation is enabled. |
|
Originating router-LSAs with maximum metric |
The maximum cost value for router LSAs (excluding stub links) is used. |
|
Condition |
Status of the stub router: · Always. · On startup for xxx seconds, where xxx is specified by the user. |
|
State |
Whether the stub router is active. |
|
Originating LSAs with metric xxx controlled by RBM |
The device is the backup device in the HA group. · Originating LSAs with metric +n controlled by RBM—When OSPF generates an LSA, the cost is the sum of the original cost and n. · Originating LSAs with metric n controlled by RBM—When OSPF generates an LSA, the cost is n. This field is displayed only when HA has adjusted the OSPF cost. For more information about HA, see High Availability Configuration Guide. |
|
SPF-schedule-interval |
Interval for SPF calculations. If the SPF calculation interval is fixed, this field also displays in milliseconds enclosed with brackets. |
|
LSA generation interval |
LSA generation interval. |
|
LSA arrival interval |
LSA arrival interval. |
|
Transmit pacing |
LSU packet transmit rate of the interface: · Interval—LSU transmit interval of the interface. · Count—Maximum number of LSU packets sent at each interval. |
|
Default ASE parameters |
Default ASE parameters: Metric, Tag, and Type. |
|
Route preference |
Internal route preference. |
|
ASE route preference |
External route preference. |
|
SPF computation count |
SPF computation count of the OSPF process. |
|
RFC1583 compatible |
Compatible with RFC 1583. |
|
Fast-reroute |
FRR type: LFA—LFA is enabled. |
|
Node-Protecting Preference |
Priority of the node-protection backup path selection policy. |
|
Lowest-cost Preference |
Priority of the lowest-cost backup path selection policy. |
|
SRLG preference |
Priority of the shared risk link group (SRLG)-disjoint backup path selection policy. |
|
Graceful restart interval |
GR interval. |
|
SNMP trap rate limit interval |
SNMP notification sending interval. |
|
Count |
Number of sent SNMP notifications. |
|
ExChange/Loading neighbors |
Neighbors in ExChange/Loading state. |
|
Full neighbors |
Neighbors in Full state. |
|
Area0 full neighbors |
Neighbors in Full state in the backbone area. |
|
Calculation trigger type |
Route calculation trigger type: · Full—Calculation of all routes is triggered. · Area topology change—Topology change in an area. · Intra router change—Incremental intra-area route change. · ASBR change—Incremental ASBR route change. · 7to5 translator—Type-7-to-Type-5 LSA translator role change. · Full IP prefix—Calculation of all IP prefixes is triggered. · Full intra AS—Calculation of all intra-AS prefixes is triggered. · Inc intra AS—Calculation of incremental intra-AS prefixes is triggered. · Full inter AS—Calculation of all AS-external prefixes is triggered. · Inc inter AS—Calculation of incremental AS-external prefixes is triggered. · N/A—Route calculation is not triggered. |
|
Current calculation type |
Current route calculation type: · SPF calculation. · Intra router calculation—Intra-area route calculation. · ASBR calculation—Inter-area ASBR route calculation. · Inc intra router—Incremental intra-area route calculation. · Inc ASBR calculation—Incremental inter-area ASBR route calculation. · 7to5 translator—Type-7-to-Type-5 LSA calculation. · Full intra AS—Calculation of all intra-AS prefixes. · Inc intra AS—Calculation of incremental intra-AS prefixes. · Full inter AS—Calculation of all AS-external prefixes. · Inc inter AS—Calculation of incremental AS-external prefixes. · Forward address—Forwarding address calculation. · N/A—Route calculation is not triggered. |
|
Current calculation phase |
Current route calculation phase: · Calculation area topology—Calculating area topology. · Calculation router—Calculating routes on routers. · Calculation intra AS—Calculating intra-AS routes. · 7to5 translator—Calculating Type-7-to-Type-5 LSAs. · Forward address—Calculating forwarding addresses. · Calculation inter AS—Calculating AS-external routes. · Calculation end—Ending phase of calculation. · N/A—Route calculation is not triggered. |
|
Process reset state |
Process reset state: · N/A—The process is not reset. · Under reset—The process is in the reset progress. · Under RIB smooth—The process is synchronizing the RIB. |
|
Current reset type |
Current process reset type: · N/A—The process is not reset. · Normal—Normal reset. · GR quit—Normal reset when GR quits abnormally. · Delete—Delete OSPF process. |
|
Next reset type |
Next process reset type: · N/A—The process is not reset. · Normal—Normal reset. · GR quit—Normal reset when GR quits abnormally. · Delete—Delete OSPF process. |
|
Reset prepare message replied |
Modules that reply reset prepare messages: · P—Neighbor maintenance module. · L—LSDB synchronization module. · C—Route calculation module. · R—Route redistribution module. |
|
Reset process message replied |
Modules that reply reset process messages: · P—Neighbor maintenance module. · L—LSDB synchronization module. · C—Route calculation module. · R—Route redistribution module. |
|
Reset phase of module |
Reset phase of each module: · Main control module: ¡ N/A—Not reset. ¡ Delete area. ¡ Delete process. · Neighbor maintenance (P) module: ¡ N/A—Not reset. ¡ Delete neighbor. ¡ Delete interface. ¡ Delete vlink—Delete virtual link. ¡ Delete shamlink—Delete sham link. · LSDB synchronization (L) module: ¡ N/A—Not reset. ¡ Stop timer. ¡ Delete ASE—Delete all ASE LSAs. ¡ Delete ASE maps—Delete ASE LSA maps. ¡ Clear process data. ¡ Delete area LSA—Delete LSAs and maps from an area. ¡ Delete area interface—Delete interfaces from an area. ¡ Delete process—Delete process-related resources. ¡ Restart—Restart process-related resources. · Route calculation (C) module: ¡ N/A—Not reset. ¡ Delete topology—Delete area topology. ¡ Delete router—Delete routes of routers. ¡ Delete intra AS—Delete intra-AS routes ¡ Delete inter AS—Delete AS-external routes. ¡ Delete forward address—Delete forwarding address list. ¡ Delete advertise—Delete advertising router list. · Route redistribution (R) module: ¡ N/A—Not reset. ¡ Delete ABR summary—Delete summary routes of the ABR. ¡ Delete ASBR summary—Delete summary routes of the ASBR. ¡ Delete import—Delete redistributed routes. |
|
Area |
Area ID in the IP address format. |
|
Authentication type |
Authentication type of the area: · None—No authentication. · Simple—Simple authentication. · Cryptographic—MD5, HMAC-MD5, or HMAC-SHA-256 authentication. |
|
Area flag |
Type of the area: · Normal. · Stub. · StubNoSummary (totally stub area). · NSSA. · NSSANoSummary (totally NSSA area). |
|
7/5 translator state |
State of the translator that translates Type-7 LSAs to Type-5 LSAs: · Enabled—The translator is specified through commands. · Elected—The translator is designated through election. · Disabled—The device is not a translator. |
|
7/5 translate stability timer interval |
Stability interval for Type-7 LSA-to-Type-5 LSA translation. |
|
SPF scheduled Count |
SPF calculation count in the OSPF area. |
|
Interface |
Interface in the area. |
|
Cost |
Interface cost. |
|
State |
Interface state. |
|
Type |
Interface network type. |
|
MTU |
Interface MTU. |
|
Priority |
Router priority. |
|
Timers |
OSPF timers: · Hello—Interval for sending hello packets. · Dead—Interval within which the neighbor is down. · Poll—Interval for sending hello packets. · Retransmit—Interval for retransmitting LSAs. |
|
FRR backup |
Whether Loop Free Alternate (LFA) calculation is enabled on an interface. |
|
Packet size |
The maximum length of OSPF packets that can be sent by an interface. |
display ospf abr-asbr
Use display ospf abr-asbr to display routes to the ABR or ASBR.
Syntax
display ospf [ process-id ] abr-asbr [ verbose ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays routes to the ABR and ASBR for all OSPF processes.
verbose: Displays detailed information. If you do not specify this keyword, the command displays brief information.
Usage guidelines
If you use this command on routers in a stub area, the commands displays no ASBR information.
Examples
# Display brief information about routes to the ABR or ASBR.
<Sysname> display ospf abr-asbr
OSPF Process 1 with Router ID 192.168.1.2
Routing Table to ABR and ASBR
Topology base (MTID 0)
Type Destination Area Cost Nexthop RtType
Inter 3.3.3.3 0.0.0.0 3124 10.1.1.2 ASBR
Intra 2.2.2.2 0.0.0.0 1562 10.1.1.2 ABR
# Display detailed information about routes to the ABR or ASBR.
<Sysname> display ospf abr-asbr verbose
OSPF Process 10 with Router ID 101.1.1.11
Routing Table to ABR and ASBR
Topology base (MTID 0)
Destination: 1.1.1.1 RtType : ASBR
Area : 0.0.0.1 Type : Intra
Nexthop : 150.0.1.12 BkNexthop : 0.0.0.0
Interface : Vlan10 BkInterface: N/A
Cost : 1000
Table 2 Command output
|
Field |
Description |
|
Type |
Type of the route to the ABR or ASBR: · Intra—Intra-area route. · Inter—Inter-area route. |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Destination |
Router ID of an ABR or ASBR. |
|
Area |
ID of the area of the next hop. |
|
Cost |
Cost from the router to the ABR or ASBR. |
|
Nexthop |
Next hop address. |
|
BkNexthop |
Backup next hop address. |
|
RtType |
Router type: ABR or ASBR. |
|
Interface |
Output interface. |
|
BkInterface |
Backup output interface. |
display ospf abr-summary
Use display ospf abr-summary to display ABR summary route information.
Syntax
display ospf [ process-id ] [ area area-id ] abr-summary [ ip-address { mask-length | mask } ] [ verbose ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays information about ABR summary routes for all OSPF processes.
area area-id: Specifies an OSPF area by its ID. The area ID is an IP address or a decimal integer in the range of 0 to 4294967295 that is translated into the IP address format. If you do not specify this option, the command displays information about ABR summary routes for all OSPF areas.
ip-address: Specifies a summary route by its IP address.
mask-length: Specifies the mask length in the range of 1 to 32.
mask: Specifies the mask in dotted decimal notation.
verbose: Displays detailed ABR summary route information. If you do not specify this keyword, the command displays brief ABR summary route information.
Usage guidelines
If you do not specify an IP address, this command displays information about all summary routes on the ABR.
Examples
# Display brief information about summary routes on the ABR.
<Sysname> display ospf abr-summary
OSPF Process 1 with Router ID 2.2.2.2
ABR Summary Addresses
Topology base (MTID 0)
Area: 0.0.0.1
Total summary address count: 1
Net Mask Status Count Cost
100.0.0.0 255.0.0.0 Advertise 1 (Not Configured)
Table 3 Command output
|
Field |
Description |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Area |
Area to which the summary routes belong. |
|
Total summary address count |
Total number of summary routes. |
|
Net |
Address of the summary route. |
|
Mask |
Mask of the summary route address. |
|
Status |
Advertisement status of the summary route: Advertise or Non-Advertise. |
|
Count |
Number of summarized routes. |
|
Cost |
Cost of the summary route. |
# Display detailed information about summary routes on the ABR.
<Sysname> display ospf abr-summary verbose
OSPF Process 1 with Router ID 2.2.2.2
ABR Summary Addresses
Topology base (MTID 0)
Area: 0.0.0.1
Total summary address count: 1
Net : 100.0.0.0
Mask : 255.0.0.0
Status : Advertise
Cost : (Not Configured)
Routes count: 1
Destination NetMask Metric
100.1.1.0 255.255.255.0 1000
Table 4 Command output
|
Field |
Description |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Destination |
Destination address of a summarized route. |
|
NetMask |
Network mask of a summarized route. |
|
Metric |
Metric of a summarized route. |
display ospf asbr-summary
Use display ospf asbr-summary to display ASBR summary route information.
Syntax
display ospf [ process-id ] asbr-summary [ ip-address { mask-length | mask } ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays information about ASBR summary routes for all OSPF processes.
ip-address: Specifies an IP address in dotted decimal notation.
mask-length: Specifies the mask length in the range of 1 to 32.
mask: Specifies the mask in dotted decimal notation.
Usage guidelines
If you do not specify an IP address, this command displays information about all ASBR summary routes.
Examples
# Display ASBR summary route information in OSPF process 1.
<Sysname> display ospf 1 asbr-summary
OSPF Process 1 with Router ID 2.2.2.2
Summary Addresses
Topology base (MTID 0)
Total summary address count: 1
Summary Address
Net : 30.1.0.0
Mask : 255.255.0.0
Tag : 20
Status : Advertise
Cost : 10 (Configured)
Route count : 2
Destination Net mask Proto Process Type Metric
30.1.2.0 255.255.255.0 OSPF 2 2 1
30.1.1.0 255.255.255.0 OSPF 2 2 1
Table 5 Command output
|
Field |
Description |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Total summary address count |
Total number of summary routes. |
|
Net |
Address of the summary route. |
|
Mask |
Mask of the summary route address. |
|
Tag |
Tag of the summary route. |
|
Status |
Advertisement status of the summary route. |
|
Cost |
Cost of the summary route. |
|
Route count |
Number of summarized routes. |
|
Destination |
Destination address of a summarized route. |
|
Net mask |
Network mask of a summarized route. |
|
Proto |
Routing protocol from which the route was redistributed. |
|
Process |
Process ID of the routing protocol from which the route was redistributed. |
|
Type |
Type of a summarized route. |
|
Metric |
Metric of a summarized route. |
display ospf event-log
Use display ospf event-log to display OSPF log information.
Syntax
display ospf [ process-id ] event-log { lsa-flush | lsa-history [ verbose ] | peer [ neighbor-id ] | route | spf }
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays OSPF log information for all processes.
lsa-flush: Specifies LSA aging log information.
lsa-history: Specifies self-originated and received LSA log information.
verbose: Displays detailed self-originated and received LSA log information. If you do not specify this keyword, the command displays brief self-originated and received LSA log information.
peer: Specifies neighbor state change log information.
neighbor-id: Specifies a neighbor by its router ID. If you do not specify a neighbor, this command displays state change log information for all neighbors.
route: Specifies OSPF route log information.
spf: Specifies route calculation log information.
Usage guidelines
Route calculation logs show the number of routes newly installed in the IP routing table.
Neighbor logs include information about the following events:
· The OSPF neighbor state goes down.
· The OSPF neighbor state goes backward because the local end receives BadLSReq, SeqNumberMismatch, and 1-Way events.
Examples
# Display OSPF LSA aging log information for all processes.
<Sysname> display ospf event-log lsa-flush
OSPF Process 1 with Router ID 1.1.1.1
LSA Flush Log
Date: 2019-09-22 Time: 14:47:33 Received MaxAge LSA from 10.1.1.1
Type: 1 LS ID: 2.2.2.2 AdvRtr: 2.2.2.2 Seq#: 80000001
Date: 2019-09-22 Time: 14:47:33 Flushed MaxAge LSA by the self
Type: 1 LS ID: 1.1.1.1 AdvRtr: 1.1.1.1 Seq#: 80000001
Date: 2019-09-22 Time: 14:47:33 Received MaxAge LSA from 10.1.2.2
Type: 1 LS ID: 2.2.2.2 AdvRtr: 2.2.2.2 Seq#: 80000001
Date: 2019-09-22 Time: 14:47:33 Flushed MaxAge LSA by the self
Type: 1 LS ID: 1.1.1.1 AdvRtr: 1.1.1.1 Seq#: 80000001
Table 6 Command output
|
Field |
Description |
|
Date/Time |
Time when the device receives an LSA that has reached the maximum age. |
|
Received MaxAge LSA from X.X.X.X |
The device received an LSA that has reached the maximum age from X.X.X.X. |
|
Flushed MaxAge LSA by the self |
The device flushed the LSA that has reached the maximum age. |
|
Type |
LSA type. |
|
LS ID |
LSA link state ID. |
|
AdvRtr |
Advertising router. |
|
Seq# |
LSA sequence number. |
# Display OSPF LSA log information for process 1.
<Sysname> display ospf event-log lsa-history
OSPF Process 1 with Router ID 1.1.1.1
LSA Log
Date:2019-09-06 Time:10:47:44:007923 Area 0.0.0.2 LSAs received from interface Vlan1 10.5.1.5
Type LinkState ID AdvRtr Age Length Sequence
1 10.1.1.5 10.1.1.5 1 36 80000002
Table 7 Command output
|
Field |
Description |
|
Date/Time |
Time when the device generated or received the LSA, which is accurate to microseconds. |
|
LSAs received from interface XXX X.X.X.X |
The device received an LSA from interface XXX with IP address X.X.X.X. |
|
Self-originated or self-aged LSAs |
The LSA is self-originated or self-aged. |
|
Type |
LSA type. |
|
LinkState ID |
LSA link state ID. |
|
AdvRtr |
Advertising router. |
|
Sequence |
LSA sequence number. |
# Display OSPF route log information for process 1.
<Sysname> display ospf event-log route
OSPF Process 1 with Router ID 1.1.1.1
Route Log
Topology base (MTID 0)
Date: 2019-09-22 Time: 14:47:33:070853 Modified 2.1.1.1/32,
Type:Stub
Interface: GE1/0/2, Nexthop:10.5.1.1, Rely NbrID:0x13000004, Flag:0x01
Table 8 Command output
|
Field |
Description |
|
Date/Time |
Route calculation time, which is accurate to microseconds. |
|
Added/Deleted/Modified |
The route was newly added, deleted, or modified. |
|
Type |
Route type, which can be Transit, Stub, Inter, Type1, or Type2. |
|
Interface |
Output interface of the route. |
|
Nexthop |
Next hop of the route. |
|
Rely NbrID |
Recursive neighbor router ID. If Rely is not displayed, the neighbor router is a non-recursive neighbor. |
|
Flag |
Route attribute flag. |
# Display OSPF route calculation log information for all processes.
<Sysname> display ospf event-log spf
OSPF Process 1 with Router ID 1.1.1.2
SPF Log
Topology base (MTID 0)
Date Time Duration Intra Inter External Reason
2019-09-27 15:28:26 0.95 1 1 10000 Intra-area LSA
2019-09-27 15:28:23 0.2 0 0 0 Area 0 full neighbor
2019-09-27 15:28:19 0 0 0 0 Intra-area LSA
2019-09-27 15:28:19 0 0 0 0 external LSA
2019-09-27 15:28:19 0.3 0 0 0 Intra-area LSA
2019-09-27 15:28:12 0 1 0 0 Intra-area LSA
2019-09-27 15:28:11 0 0 0 0 Routing policy
2019-09-27 15:28:11 0 0 0 0 Intra-area LSA
Table 9 Command output
|
Field |
Description |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Date/Time |
Time when the route calculation starts. |
|
Duration of the route calculation, in seconds. |
|
|
Intra |
Number of intra-area routes newly installed in the IP routing table. |
|
Inter |
Number of inter-area routes newly installed in the IP routing table. |
|
External |
Number of external routes newly installed in the IP routing table. |
|
Reason |
Reasons why the route calculation is performed: · Intra-area LSA—Intra-area LSA changes. · Inter-area LSA—Inter-area LSA changes. · External LSA—External LSA changes. · Configuration—Configuration changes. · Area 0 full neighbor—Number of FULL-state neighbors in Area 0 changes. · Area 0 up interface—Number of interfaces in up state in Area 0 changes. · LSDB overflow state—Overflow status changes. · AS number—AS number changes. · ABR summarization—ABR summarization changes. · GR end—GR ends. · Routing policy—Routing policy changes. · Intra-area tunnel—Intra-area tunnel changes. · Others—Other reasons. |
# Display OSPF neighbor log information for OSPF process 1.
<Sysname> display ospf 1 event-log peer
OSPF Process 1 with Router ID 1.1.1.1
Neighbors Log
Date Time Local Address Remote Address Router ID Reason
2019-12-31 12:35:45 197.168.1.1 197.168.1.2 2.2.2.2 IntPhyChange
2019-12-31 12:35:19 197.168.1.1 197.168.1.2 2.2.2.2 ConfNssaArea
2019-12-31 12:34:59 197.168.1.1 197.168.1.2 2.2.2.2 SilentInt
Table 10 Command output
|
Field |
Description |
|
Date/Time |
Time when the neighbor state changes. |
|
Local Address |
Local address of the neighbor relationship. |
|
Remote Address |
Peer address of the neighbor relationship. |
|
Router ID |
Neighbor router ID. |
|
Reason |
Reasons for neighbor state changes: · ResetConnect—The connection is lost due to insufficient memory. · IntChange—The interface parameter has changed. · VlinkChange—The virtual link parameter has changed. · ShamlinkChange—The sham link parameter has changed. · ResetOspf—The OSPF process is reset. · UndoOspf—The OSPF process is deleted. · UndoArea—The OSPF area is deleted. · UndoNetwork—The interface is disabled. · SilentInt—The interface is configured as a silent interface. · IntLogChange—The logical attribute of the interface has changed. · IntPhyChange—The physical attribute of the interface has changed. · IntVliChange—The virtual link attribute of the interface has changed. · VlinkDown—The virtual link goes down. · ShamlinkDown—The sham link goes down. · DeadExpired—The dead timer expires. · ConfStubArea—The interface is configured with stub area parameters. · ConfNssaArea—The interface is configured with NSSA area parameters. · AuthChange—The authentication type has changed. · OpaqueChange—The Opaque capability has changed. · Retrans—Excessive retransmissions. · LLSChange—The LLS capability has changed. · OOBChange—The OOB capability has changed. · GRChange—The GR capability has changed. · BadLSReq—The interface receives BadLSReq events. · SeqMismatch—The interface receives SeqNumberMismatch events. · 1-Way—The interface receives 1-Way events. |
Related commands
reset ospf event-log
display ospf event-log hello
Use display ospf event-log hello to display log information about received or sent OSPF hello packets.
Syntax
display ospf [ process-id ] event-log hello { received [ abnormal | dropped ] | sent } [ neighbor-id ]
display ospf [ process-id ] event-log hello sent { abnormal | failed } [ neighbor-address ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays log information about received or sent OSPF hello packets for all processes.
received: Specifies log information about received OSPF hello packets.
sent: Specifies log information about sent OSPF hello packets.
abnormal: Specifies log information about abnormal OSPF hello packets, which are received or sent at intervals greater than or equal to 1.5 times the hello interval.
dropped: Specifies log information about discarded OSPF hello packets.
failed: Specifies log information about OSPF hello packets that failed to be sent.
neighbor-address: Specifies a neighbor by its IP address. If you do not specify a neighbor, this command displays log information about received or sent OSPF hello packets for all neighbors.
neighbor-id: Specifies a neighbor by its router ID. If you do not specify a neighbor, this command displays log information about received or sent OSPF hello packets for all neighbors.
Examples
# Display log information about sent OSPF hello packets.
<Sysname> display ospf event-log hello sent
OSPF Process 1 with Router ID 5.5.5.5
Hello Log
Interface: Vlan10
Neighbor address: 10.1.1.2, NbrID: 1.0.0.2
First 4 hello packets sent:
2019-02-05 20:10:10:121, failed, errno: 132
2019-02-05 20:10:30:121, succeeded
2019-02-05 20:10:20:121, succeeded
2019-02-05 20:10:40:121, succeeded
Last 4 hello packets sent before Full->Down at 2019-02-06 14:52:10:121
2019-02-06 14:51:40:021, succeeded
2019-02-06 14:51:50:021, succeeded
2019-02-06 14:52:00:021, failed, errno: 132
2019-02-06 14:52:10:010, failed, errno: 132
Interface: Vlan10
Neighbor address: 10.1.1.2, NbrID: 1.0.0.2
First 4 hello packets sent:
2019-02-05 20:10:10:121, failed, errno: 132
2019-02-05 20:10:30:121, succeeded
2019-02-05 20:10:20:121, succeeded
2019-02-05 20:10:40:121, succeeded
Last 4 hello packets sent before Full->Init at 2019-02-06 11:16:20:171
2019-02-06 11:15:20:121, succeeded
2019-02-06 11:15:30:121, succeeded
2019-02-06 11:15:40:121, succeeded
2019-02-06 11:15:50:121, succeeded
Table 11 Command output
|
Field |
Description |
|
Interface |
Interface that sends the hello packets. |
|
Neighbor address |
IP address of the neighbor. |
|
NbrID |
Router ID of the neighbor. |
|
First 4 hello packets sent |
Time and result (succeeded or failed) for sending the first four hello packets. For a packet failed to be sent, an error code is displayed in the errno field. |
|
Last 4 hello packets sent before Full->Down at 2019-02-06 14:52:10:121 |
Time and result (succeeded or failed) for sending the last four hello packets before neighbor state change. For a packet failed to be sent, an error code is displayed in the errno field. |
# Display log information about OSPF hello packets that failed to be sent.
<Sysname> display ospf event-log hello sent failed
OSPF Process 1 with Router ID 5.5.5.5
Hello Log
Date: 2019-02-06 Time: 14:51:20:121 Interface: Vlan10
Destination address: 224.0.0.5, sent failed, errno: 132
Date: 2019-02-06 Time: 11:20:20:116 Interface: Vlan11
Destination address: 10.1.1.2, sent failed, errno: 132
Table 12 Command output
|
Field |
Description |
|
Date |
Date for the hello packet sending failure, in the format of YYYY-MM-DD. YYYY represents the year, MM represents the month, and DD represents the day. |
|
Time |
Time for the hello packet sending failure, in the format of hh:mm:ss:xxx. hh represents the hours, mm represents the minutes, ss represents the seconds, and xxx represents the milliseconds. |
|
Interface |
Interface that sends the hello packet. |
|
Destination address |
Destination IP address of the hello packet. |
|
error |
Error code for the hello packet sending failure. |
# Display log information about abnormal OSPF hello packets sent.
<Sysname> display ospf event-log hello sent abnormal
OSPF Process 1 with Router ID 5.5.5.5
Hello Log
Date: 2019-02-06 Time: 11:21:12:121 Interface: Vlan12
Destination address: 224.0.0.5, last one sent: 2019-02-06 11:20:51:916
Date: 2019-02-06 Time: 11:56:21:312 Interface: Vlan12
Destination address: 10.1.1.2, last one sent: 2019-02-06 11:56:02:691
Table 13 Command output
|
Field |
Description |
|
Date |
Date for sending the abnormal hello packet, in the format of YYYY-MM-DD. YYYY represents the year, MM represents the month, and DD represents the day. |
|
Time |
Time for sending the abnormal hello packet, in the format of hh:mm:ss:xxx. hh represents the hours, mm represents the minutes, ss represents the seconds, and xxx represents the milliseconds. |
|
Interface |
Interface that sends the abnormal hello packet. |
|
Destination address |
Destination IP address of the abnormal hello packet. |
|
last one sent |
Time for sending the last hello packet before sending the abnormal hello packet. |
# Display log information about received OSPF hello packets.
<Sysname> display ospf event-log hello received
OSPF Process 1 with Router ID 5.5.5.5
Hello Log
Interface: Vlan10
Neighbor address: 10.1.1.2, NbrID: 1.0.0.2
First 4 hello packets received:
2019-02-05 20:11:10:121
2019-02-05 20:11:30:121
2019-02-05 20:11:20:121
2019-02-05 20:11:40:121
Last 4 hello packets received before Exchange->Down at 2019-02-06 14:52:10:121
2019-02-06 14:51:10:121
2019-02-06 14:51:30:121
2019-02-06 14:51:20:121
2019-02-06 14:51:40:121
Interface: Vlan10
Neighbor address: 10.1.1.1, NbrID: 1.0.0.1
First 4 hello packets received:
2019-02-06 19:11:15:121
2019-02-06 19:11:35:121
2019-02-06 19:11:25:121
2019-02-06 19:11:45:121
Last 4 hello packets received before Full->Init at 2019-02-06 21:16:20:171
2019-02-06 21:15:45:121
2019-02-06 21:15:55:121
2019-02-06 21:16:05:121
2019-02-06 21:16:15:121
Table 14 Command output
|
Field |
Description |
|
Interface |
Interface that receives the hello packets. |
|
Neighbor address |
IP address of the neighbor. |
|
NbrID |
Router ID of the neighbor. |
|
First 4 hello packets received |
Time for receiving the first four hello packets. |
|
Last 4 hello packets received before Full->Init at 2019-02-06 21:16:20:171 |
Time for receiving the last four hello packets before neighbor state change, in the format of YYYY-MM-DD hh:mm:ss:xxx. YYYY represents the year, MM represents the month, and DD represents the day. hh represents the hours, mm represents the minutes, ss represents the seconds, and xxx represents the milliseconds. |
# Display log information about discarded OSPF hello packets.
<Sysname> display ospf event-log hello received dropped
OSPF Process 1 with Router ID 5.5.5.5
Hello Log
Date: 2019-02-06 Time: 14:51:22:791 Interface: GE1/0/1
Source address: 10.1.1.1, NbrID: 1.0.0.1, area: 0.0.0.1
Drop reason: Hello-time mismatch
Date: 2019-02-06 Time: 14:51:20:121 Interface: GE1/0/1
Source address: 10.1.1.2, NbrID: 1.0.0.2, area: 0.0.0.1
Drop reason: NP-bit mismatch
# Display log information about discarded OSPF hello packets.
<Sysname> display ospf event-log hello received dropped
OSPF Process 1 with Router ID 5.5.5.5
Hello Log
Date: 2019-02-06 Time: 14:51:22:791 Interface: Vlan10
Source address: 10.1.1.1, NbrID: 1.0.0.1, area: 0.0.0.1
Drop reason: Hello-time mismatch
Date: 2019-02-06 Time: 14:51:20:121 Interface: Vlan10
Source address: 10.1.1.2, NbrID: 1.0.0.2, area: 0.0.0.1
Drop reason: NP-bit mismatch
Table 15 Command output
|
Field |
Description |
|
Date |
Date for discarding the OSPF hello packet, in the format of YYYY-MM-DD. YYYY represents the year, MM represents the month, and DD represents the day. |
|
Time |
Time for discarding the OSPF hello packet, in the format of hh:mm:ss:xxx. hh represents the hours, mm represents the minutes, ss represents the seconds, and xxx represents the milliseconds. |
|
Interface |
Interface that receives the hello packet. |
|
Source address |
Source IP address of the hello packet. |
|
NbrID |
Router ID of the neighbor. |
|
area |
Area to which the neighbor interface belongs. |
|
Drop reason |
Reason for discarding the hello packet: · Area under reset—The area is in the reset progress. · Router ID conflict—Route ID conflict. · Area mismatch—Area ID mismatch. · Unknown virtual link—The hello packet is from an unknown virtual link. · Authentication failure—Authentication failure. · Peer address check failure—Neighbor address check failure. · Not DR or BDR—The destination IP address of the hello packet is 224.0.0.6, but the interface is not a DR or BDR. · Unknown unicast peer—The hello packet is from an unknown unicast neighbor. · Option mismatch—Option field mismatch. · Subnet mask mismatch—Subnet mask mismatch. · Address mismatch—Address range mismatch. · Hello timer mismatch—Hello timer mismatch. · Dead timer mismatch—Dead timer mismatch. · Peer change—The source IP address or router ID has changed. · FilterLSA—Peer disconnection occurs because LSA filter settings have changed or the ACL used by the LSA filter has changed. |
# Display log information about abnormal OSPF hello packets received.
<Sysname> display ospf event-log hello received abnormal
OSPF Process 1 with Router ID 5.5.5.5
Hello Log
Date: 2019-02-06 Time: 10:12:22:121 Interface: GE1/0/1
Source address: 10.1.1.2, NbrID: 1.0.0.2, area: 0.0.0.1
Last one received: 2019-02-06 10:12:04:212
Date: 2019-02-06 Time: 14:51:20:121 Interface: GE1/0/1
Source address: 10.1.1.2, NbrID: 1.0.0.2, area: 0.0.0.1
Last one received: 2019-02-06 14:51:05:113
# Display log information about abnormal OSPF hello packets received.
<Sysname> display ospf event-log hello received abnormal
OSPF Process 1 with Router ID 5.5.5.5
Hello Log
Date: 2019-02-06 Time: 10:12:22:121 Interface: Vlan10
Source address: 10.1.1.2, NbrID: 1.0.0.2, area: 0.0.0.1
Last one received: 2019-02-06 10:12:04:212
Date: 2019-02-06 Time: 14:51:20:121 Interface: Vlan10
Source address: 10.1.1.2, NbrID: 1.0.0.2, area: 0.0.0.1
Last one received: 2019-02-06 14:51:05:113
Table 16 Command output
|
Field |
Description |
|
Date&Tme |
Date for receiving the abnormal hello packet, in the format of YYYY-MM-DD. YYYY represents the year, MM represents the month, and DD represents the day. |
|
Time |
Time for receiving the abnormal hello packet, in the format of hh:mm:ss:xxx. hh represents the hours, mm represents the minutes, ss represents the seconds, and xxx represents the milliseconds. |
|
Interface |
Interface that receives the abnormal hello packet. |
|
Source address |
Source IP address of the received abnormal hello packet. |
|
NbrID |
Router ID of the neighbor. |
|
area |
Area to which the neighbor interface belongs. |
|
Last one received |
Time for receiving the last hello packet before receiving the abnormal hello packet. |
Related commands
reset ospf event-log hello
display ospf fast-reroute lfa-candidate
Use display ospf fast-reroute lfa-candidate to display OSPF FRR backup next hop information.
Syntax
display ospf [ process-id ] [ area area-id ] fast-reroute lfa-candidate
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays FRR backup next hop information for all processes.
area area-id: Specifies an OSPF area by its ID. The area ID is an IP address or a decimal integer in the range of 0 to 4294967295 that is translated into the IP address format. If you do not specify this option, the command displays FRR backup next hop information for all OSPF areas.
Examples
# Display OSPF FRR backup next hop information.
<Sysname> display ospf 1 area 0 fast-reroute lfa-candidate
OSPF Process 1 with Router ID 2.2.2.2
LFA Candidate List
Topology base (MTID 0)
Area: 0.0.0.0
Candidate nexthop count: 2
NextHop IntIP Interface
10.0.1.1 10.0.1.2 Vlan10
10.0.11.1 10.0.11.2 Vlan20
Table 17 Command output
|
Field |
Description |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Area |
Area to which the backup next hops belong. |
|
Candidate nexthop count |
Number of backup next hops. |
|
NextHop |
Backup next hop address. |
|
IntIP |
IP address of the output interface. |
|
Interface |
Output interface. |
display ospf global-statistics
Use display ospf global-statistics to display global OSPF statistics.
Syntax
display ospf global-statistics [ public ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
public: Specifies the public network.
Usage guidelines
If you do not specify any keyword, this command displays global OSPF statistics for the public network.
Examples
# Display global OSPF statistics.
<Sysname> display ospf global-statistics
OSPF global statistics
Instance count : 1
Process count : 3
Interface information
Down : 1
Up : 0
Neighbor information
Down : 0
Init : 0
Attempt : 0
2-Way : 0
ExStart : 0
Exchange : 0
Loading : 0
Full : 0
Packets sent : 0
Packets received : 0
LSA count : 0
Route count : 0
Table 18 Command output
|
Field |
Description |
|
Instance count |
VPN instances are not supported in the current software version. This field displays the number of VPN instances and public network that are configured with OSPF. · If OSPF is configured only for the public network, the value is fixed at 1. · If OSPF is configured only for VPN instances, the value equals the number of the VPN instances. · If OSPF is configured for both the public network and VPN instances, the value equals the number of VPN instances plus 1. |
|
Process count |
Number of OSPF processes. |
|
Interface information |
Statistics about interface status. |
|
Down |
Number of interfaces in Down status. |
|
Up |
Number of interfaces in Up status. |
|
Neighbor information |
Statistics about neighbor status. |
|
Down |
Number of neighbor routers in Down status. |
|
Attempt |
Number of neighbor routers in Up status. |
|
Init |
Number of neighbor routers in Init status. |
|
2-Way |
Number of neighbor routers in 2-Way status. |
|
ExStart |
Number of neighbor routers in ExStart status. |
|
Exchange |
Number of neighbor routers in Exchange status. |
|
Loading |
Number of neighbor routers in Loading status. |
|
Full |
Number of neighbor routers in Full status. |
|
Packets sent |
Number of OSPF packets sent. |
|
Packets received |
Number of OSPF packets received. |
|
LSA count |
Total number of LSAs in the LSDB. |
|
Route count |
Total number of OSPF routes. |
display ospf graceful-restart
Use display ospf graceful-restart to display GR information.
Syntax
display ospf [ process-id ] graceful-restart [ verbose ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays GR information for all processes.
verbose: Displays detailed GR information. If you do not specify this keyword, the command displays brief GR information.
Examples
# Display detailed GR information.
<Sysname> display ospf graceful-restart verbose
OSPF Process 1 with Router ID 1.1.1.1
Graceful Restart information
Graceful Restart capability : Enable(IETF)
Graceful Restart support : Planned and unplanned,Partial
Helper capability : Enable(IETF)
Helper support : Planned and unplanned(IETF),Strict LSA check
Current GR state : Normal
Graceful Restart period : 40 seconds
Number of neighbors under Helper: 0
Number of restarting neighbors : 0
Last exit reason:
Restarter : None
Helper : None
Area: 0.0.0.0
Authentication type: None Area flag: Normal
Area up Interface count: 2
Interface: 40.4.0.1 (Vlan-interface40)
Restarter state: Normal State: P-2-P Type: PTP
Last exit reason:
Restarter : None
Helper : None
Neighbor count of this interface: 1
Number of neighbors under Helper: 0
Neighbor IP address GR state Last Helper exit reason
3.3.3.3 40.4.0.3 Normal None
Virtual-link Neighbor-ID -> 4.4.4.4, Neighbor-State: Full
Restarter state: Normal
Interface: 20.2.0.1 (Vlink)
Transit Area: 0.0.0.1
Last exit reason:
Restarter : None
Helper : None
Neighbor IP address GR state Last Helper exit reason
4.4.4.4 20.2.0.4 Normal Reset neighbor
Table 19 Command output
|
Field |
Description |
|
OSPF Process 1 with Router ID 1.1.1.1 Graceful Restart information |
GR information for OSPF process 1 with router ID 1.1.1.1. |
|
Graceful Restart capability |
Whether GR is enabled: · Enable(IETF)—IETF GR is enabled. · Enable(Nonstandard)—Non-IETF GR is enabled. · Disable—GR is disabled. |
|
Graceful Restart support |
GR modes that the process supports (displayed only when GR is enabled): · Planned and unplanned—Supports both planned and unplanned GR. · Planned only—Supports only planned GR. · Partial—Supports partial GR. · Global—Supports global GR. |
|
Helper capability |
Helper capability that the process supports: · Enable(IETF)—Supports IETF GR helper capability. · Enable(Nonstandard)—Supports non-IETF GR helper capability. · Enable(IETF and nonstandard)—Supports both IETF GR helper capability and non-IETF GR helper capability. · Disable—Does not support GR helper capability. |
|
Helper support |
Policies that the helper supports (displayed only when GR helper is enabled): · Strict lsa check—The helper supports strict LSA checking. · Planned and unplanned—The helper supports planned and unplanned GR. · Planned only—The helper supports only planned GR. |
|
Current GR state |
GR state: · Normal—GR is not in progress or has completed. · Under GR—GR is in process. · Under Helper—The process is acting as GR helper. |
|
Last exit reason |
Last exit reason: · Restarter—Reason that the restarter exited most recently. · Helper—Reason that the helper exited most recently. |
|
Area |
Area ID in IP address format. |
|
Authentication type |
Authentication type of the area: · None—No authentication. · Simple—Simple authentication. · Cryptographic—MD5, HMAC-MD5, or HMAC-SHA-256 authentication. |
|
Area flag |
Type of the area: · Normal. · Stub. · StubNoSummary (totally stub area). · NSSA. · NSSANoSummary (totally NSSA area). |
|
Area up Interface count |
Number of up interfaces in the area. |
|
Interface |
Interface in the area. |
|
Restarter state |
Restarter state on the interface. |
|
State |
Interface state. |
|
Type |
Interface network type. |
|
Neighbor count of this interface |
Neighbors of an interface. |
|
Neighbor |
Neighbor router ID. |
|
IP address |
Neighbor IP address. |
|
GR state |
Neighbor GR state: · Normal—GR is not in progress or has completed. · Under GR—GR is in process. · Under Helper—The process is acting as GR helper. |
|
Last Helper exit reason |
Reason that the helper exited most recently. |
|
Virtual-link Neighbor-ID |
Router ID of the virtual link's neighbor. |
|
Neighbor-State |
Neighbor state: Down, Init, 2-Way, ExStart, Exchange, Loading, and Full. |
|
Interface |
Output interface of the virtual link. |
display ospf hostname-table
Use display ospf hostname-table to display the router ID-to-host name mapping table.
Syntax
display ospf [ process-id ] hostname-table
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify an OSPF process, this command displays the router ID-to-host name mapping tables for all OSPF processes.
Examples
# Display the router ID-to-host name mapping tables for all OSPF processes.
<RouterA> display ospf hostname-table
OSPF Process 1 with Router ID 192.168.56.21
Hostname Table Information
Area: 0.0.0.1
Router ID Hostname
192.168.56.21 RouterA
display ospf interface
Use display ospf interface to display OSPF interface information.
Syntax
display ospf [ process-id ] interface [ interface-type interface-number | verbose ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process ID in the range of 1 to 65535. If you do not specify this argument, the command displays the OSPF interface information for all OSPF processes.
interface-type interface-number: Specifies an interface by its type and number.
verbose: Displays detailed OSPF information for all interfaces.
Usage guidelines
If you do not specify the interface-type interface-number argument or the verbose keyword, this command displays OSPF brief information for all interfaces.
Examples
# Display all OSPF interface brief information.
<Sysname> display ospf interface
OSPF Process 1 with Router ID 192.168.1.1
Interfaces
Area: 0.0.0.0
IP Address Type State Cost Pri DR BDR
192.168.1.1 PTP P-2-P 1562 1 0.0.0.0 0.0.0.0
Area: 0.0.0.1
IP Address Type State Cost Pri DR BDR
172.16.0.1 Broadcast DR 1 1 172.16.0.1 0.0.0.0
Table 20 Command output
|
Field |
Description |
|
Area |
Area ID of the interface. |
|
IP Address |
Interface IP address (regardless of whether TE is enabled or not). |
|
Type |
Interface network type: PTP (P2P), PTMP (P2MP), Broadcast, or NBMA. |
|
State |
Interface state: · Down—No protocol traffic can be sent or received on the interface. · Loopback—The interface is in loopback state and it cannot forward traffic. · Waiting—The interface starts sending and receiving Hello packets. The router is trying to determine the identity of the (Backup) designated router for the network. · P-2-P—The interface will send Hello packets at the hello interval, and try to establish an adjacency with the neighbor. · DR—The router is the designated router on the network. · BDR—The router is the backup designated router on the network. · DROther—The router is a DR Other router on the attached network. |
|
Cost |
Interface cost. |
|
Pri |
Router priority. |
|
DR |
DR on the interface's network segment. |
|
BDR |
BDR on the interface's network segment. |
# Display detailed information about VLAN-interface 10.
<Sysname> display ospf interface vlan-interface 10
OSPF Process 1 with Router ID 192.168.1.1
Interfaces
Area: 0.0.0.0
Interface: 172.16.0.1 (Vlan-interface10)
Cost: 1 State: DR Type: Broadcast MTU: 1500
Priority: 1
Designated router: 172.16.0.1
Backup designated router: 0.0.0.0
Timers: Hello 10, Dead 40, Poll 40, Retransmit 5, Transmit Delay 1
FRR backup: Enabled
Cryptographic authentication: Enabled, inherited
The last key is 3.
The rollover is in progress, 2 neighbor(s) left.
Link quality: GOOD, cost adjusted at low quality: 50
Packet size: 1000
MTID Cost Disabled Topology name
0 1 No base
Table 21 Command output
|
Field |
Description |
|
Interface |
Information about the interface, such as the IP address. |
|
Timers |
OSPF timers (in seconds): Hello, Dead, Poll, and Retransmit. |
|
Transmit Delay |
LSA transmission delay on the interface, in seconds. |
|
FRR backup |
Whether LFA calculation is enabled on an interface. |
|
Enabled by interface configuration (including secondary IP addresses) |
OSPF is enabled on the interface (including secondary IP addresses). |
|
Cryptographic authentication: Enabled, inherited |
Cryptographic authentication mode (MD5, HMAC-MD5, or HMAC-SHA-256) is used by the interface. The inherited attribute indicates that the interface uses the authentication mode specified for the area to which the interface belongs. If the interface uses the simple authentication mode, this field displays Simple authentication: Enabled, inherited. |
|
The last key |
Most recent MD5, HMAC-MD5, or HMAC-SHA-256 authentication key ID. |
|
The rollover is in progress, 2 neighbor(s) left |
Key rollover for MD5, HMAC-MD5, or HMAC-SHA-256 authentication is in progress, and two neighbors have not completed the key rollover. |
|
Link quality |
Link quality: · GOOD—The bit error ratio is below the upper threshold or drops below the lower threshold. · LOW—The bit error ratio exceeds the upper threshold. This field is displayed only when the interface is configured with the ospf link-quality adjust-cost command. |
|
Interface cost adjustment parameters: · xx—Value added to the interface cost. When the link quality is LOW, the interface cost is xx plus the original interface cost. · Maximum—Sets the maximum interface cost when the link quality is LOW. This field is displayed only when the interface is configured with the ospf link-quality adjust-cost command. |
|
|
Packet size |
The maximum length of OSPF packets that can be sent by an interface. |
|
Nexthop |
Next hop address. This field displays 0.0.0.0 for a P2P network. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Cost |
Cost of the interface route in the topology. |
|
Disabled |
Whether OSPF is disabled from advertising the topology for the interface: Yes or No. |
|
Topology name |
Topologies except the base topology are not supported in the current software version. base indicates the base topology. |
display ospf interface hello
Use display ospf interface hello to display information about hello packets sent by an OSPF interface.
Syntax
display ospf [ process-id ] interface [ interface-type interface-number ] hello
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process ID in the range of 1 to 65535. If you do not specify this argument, the command displays hello packet information for all OSPF processes.
interface-type interface-number: Specifies an interface by its type and number. If you do not specify this argument, the command displays information about hello packets sent by all OSPF interfaces.
Usage guidelines
This command displays information about only multicast hello packets.
Examples
# Display information about hello packets sent by all OSPF interfaces.
<Sysname> display ospf interface hello
OSPF Process 1 with Router ID 192.168.1.1
Interfaces
Area: 0.0.0.0
Interface: 172.16.0.1 (Vlan-interface10)
First 4 hello packets sent:
2019-02-05 11:05:10:121, succeeded
2019-02-05 11:05:20:121, succeeded
2019-02-05 11:05:30:121, succeeded
2019-02-05 11:05:40:121, succeeded
Last 4 hello packets sent:
2019-02-06 11:15:10:121, succeeded
2019-02-06 11:15:20:121, succeeded
2019-02-06 11:15:30:121, succeeded
2019-02-06 11:15:40:121, succeeded
Table 22 Command output
|
Field |
Description |
|
Area |
Area to which the interface belongs. |
|
Interface |
IP address of the interface. |
|
First 4 hello packets sent |
Time and result (succeeded or failed) for sending the first four hello packets. |
|
Last 4 hello packets sent |
Time and result (succeeded or failed) for sending the last four hello packets when the command is executed. |
display ospf lsdb
Use display ospf lsdb to display OSPF LSDB information.
Syntax
display ospf [ process-id ] lsdb [ brief | originate-router advertising-router-id | self-originate ] [ age { max-value max-age-value | min-value min-age-value } * ] [ resolve-hostname ]
display ospf [ process-id ] lsdb hostname host-name [ age { max-value max-age-value | min-value min-age-value } * ]
display ospf [ process-id ] lsdb { ase | opaque-as } [ link-state-id ] [ originate-router advertising-router-id | self-originate ] [ age { max-value max-age-value | min-value min-age-value } * ] [ resolve-hostname ]
display ospf [ process-id ] lsdb { ase | opaque-as } [ link-state-id ] hostname host-name [ age { max-value max-age-value | min-value min-age-value } * ]
display ospf [ process-id ] [ area area-id ] lsdb { network | opaque-link } [ link-state-id ] [ originate-router advertising-router-id | self-originate ] [ age { max-value max-age-value | min-value min-age-value } * ] [ resolve-hostname ]
display ospf [ process-id ] [ area area-id ] lsdb { network | opaque-link } [ link-state-id ] hostname host-name [ age { max-value max-age-value | min-value min-age-value } * ]
display ospf [ process-id ] [ area area-id ] lsdb { asbr | nssa | router | summary } [ link-state-id ] [ originate-router advertising-router-id | self-originate ] [ age { max-value max-age-value | min-value min-age-value } * ] [ resolve-hostname ]
display ospf [ process-id ] [ area area-id ] lsdb { asbr | nssa | router | summary } [ link-state-id ] hostname host-name [ age { max-value max-age-value | min-value min-age-value } * ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays LSDB information for all OSPF processes.
age: Displays LSAs whose ages are in the specified range. If you do not specify this keyword, the command displays all LSAs in the LSDB.
max-value max-age-value: Specifies the maximum age of LSAs, in the range of 0 to 3600 seconds. The default value is 3600.
min-value min-age-value: Specifies the minimum age of LSAs, in the range of 0 to 3600 seconds. The default value is 0. The min-age-value cannot be greater than the max-age-value.
area area-id: Specifies an OSPF area by its ID. The area ID is an IP address or a decimal integer in the range of 0 to 4294967295 that is translated into the IP address format. If you do not specify this option, the command displays LSDB information for all OSPF areas.
brief: Displays brief LSDB information.
asbr: Displays Type-4 LSA (ASBR Summary LSA) information in the LSDB.
ase: Displays Type-5 LSA (AS External LSA) information in the LSDB.
network: Displays Type-2 LSA (Network LSA) information in the LSDB.
nssa: Displays Type-7 LSA (NSSA External LSA) information in the LSDB.
opaque-as: Displays Type-11 LSA (Opaque-AS LSA) information in the LSDB.
opaque-link: Displays Type-9 LSA (Opaque-link LSA) information in the LSDB.
router: Displays Type-1 LSA (Router LSA) information in the LSDB.
summary: Displays Type-3 LSA (Network Summary LSA) information in the LSDB.
link-state-id: Specifies a link state ID in the IP address format.
originate-router advertising-router-id: Specifies an advertising router by its ID.
self-originate: Displays information about self-originated LSAs.
hostname host-name: Displays LSAs advertised by the router with the specified host name. If you do not specify this option, the command displays all LSAs in the OSPF LSDB.
resolve-hostname: Displays host names in OSPF LSDB information. If you do not specify this keyword, the OSPF LSDB information does not include host names.
Examples
# Display OSPF LSDB information.
<Sysname> display ospf lsdb
OSPF Process 1 with Router ID 192.168.0.1
Link State Database
Area: 0.0.0.0
Type LinkState ID AdvRouter Age Len Sequence Metric
Router 192.168.0.2 192.168.0.2 474 36 80000004 0
Router 192.168.0.1 192.168.0.1 21 36 80000009 0
Network 192.168.0.1 192.168.0.1 321 32 80000003 0
Sum-Net 192.168.1.0 192.168.0.1 321 28 80000002 1
Sum-Net 192.168.2.0 192.168.0.2 474 28 80000002 1
Area: 0.0.0.1
Type LinkState ID AdvRouter Age Len Sequence Metric
Router 192.168.0.1 192.168.0.1 21 36 80000005 0
Sum-Net 192.168.2.0 192.168.0.1 321 28 80000002 2
Sum-Net 192.168.0.0 192.168.0.1 321 28 80000002 1
Type 9 Opaque (Link-Local Scope) Database
Flags: * -Vlink interface LSA
Type LinkState ID AdvRouter Age Len Sequence Interfaces
*Opq-Link 3.0.0.0 7.2.2.1 8 14 80000001 10.1.1.2
*Opq-Link 3.0.0.0 7.2.2.2 8 14 80000001 20.1.1.2
# Display OSPF LSDB information, including the host names of the advertising routers.
<Sysname> display ospf lsdb resolve-hostname
OSPF Process 1 with Router ID 2.2.2.2
Link State Database
Area: 0.0.0.0
Type LinkState ID AdvRouter Age Len Sequence Metric
Router 1.1.1.1 1.1.1.1 1419 36 80000004 0
Router 2.2.2.2 RouterB 1420 36 80000004 0
Network 192.168.12.2 RouterB 1420 32 80000001 0
Sum-Net 192.168.13.0 1.1.1.1 1456 28 80000001 1
Area: 0.0.0.1
Type LinkState ID AdvRouter Age Len Sequence Metric
Router 3.3.3.3 3.3.3.3 1416 36 80000003 0
Router 1.1.1.1 1.1.1.1 1415 36 80000003 0
Network 192.168.13.2 3.3.3.3 1416 32 80000001 0
Sum-Net 192.168.12.0 1.1.1.1 1456 28 80000001 1
Table 23 Command output
|
Field |
Description |
|
Area |
LSDB information for the area. |
|
Type |
LSA type. |
|
LinkState ID |
Link state ID. |
|
AdvRouter |
Advertising router or its host name. |
|
Age |
Age of the LSA. |
|
Len |
Length of the LSA. |
|
Sequence |
Sequence number of the LSA. |
|
Metric |
Cost of the LSA. |
|
*Opq-Link |
Opaque LSA generated by a virtual link. |
# Display Type-2 LSA (Network LSA) information in the LSDB.
<Sysname> display ospf 1 lsdb network
OSPF Process 1 with Router ID 192.168.1.1
Link State Database
Area: 0.0.0.0
Type : Network
LS ID : 192.168.0.2
Adv Rtr : 192.168.2.1
LS age : 922
Len : 32
Options : E
Seq# : 80000003
Checksum : 0x8d1b
Net mask : 255.255.255.0
Attached router 192.168.1.1
Attached router 192.168.2.1
Area: 0.0.0.1
Type : Network
LS ID : 192.168.1.2
Adv Rtr : 192.168.1.2
LS age : 782
Len : 32
Options : NP
Seq# : 80000003
Checksum : 0x2a77
Net mask : 255.255.255.0
Attached router 192.168.1.1
Attached router 192.168.1.2
# Display Type-2 LSA (Network LSA) information in the LSDB, including the host names of the advertising routers.
<Sysname> display ospf 1 lsdb network resolve-hostname
OSPF Process 1 with Router ID 2.2.2.2
Link State Database
Area: 0.0.0.0
Type : Network
LS ID : 192.168.12.2
Adv Rtr : 2.2.2.2
Hostname : RouterB
LS age : 1552
Len : 32
Options : O E
Seq# : 80000001
Checksum : 0xbdd0
Net mask : 255.255.255.0
Attached router 1.1.1.1
Attached router 2.2.2.2
Area: 0.0.0.1
Type : Network
LS ID : 192.168.13.2
Adv Rtr : 3.3.3.3
LS age : 1548
Len : 32
Options : O E
Seq# : 80000001
Checksum : 0xc6be
Net mask : 255.255.255.0
Attached router 1.1.1.1
Attached router 3.3.3.3
Table 24 Command output
|
Field |
Description |
|
Type |
LSA type. |
|
LS ID |
DR IP address. |
|
Adv Rtr |
Router that advertised the LSA. |
|
Hostname |
Host name of the advertising router. |
|
LS age |
LSA age time. |
|
Len |
LSA length. |
|
Options |
LSA options: · O—Opaque LSA advertisement capability. · E—AS External LSA reception capability. · EA—External extended LSA reception capability. · DC—On-demand link support. · N—NSSA external LSA support. · P—Capability of an NSSA ABR to translate Type-7 LSAs into Type-5 LSAs. |
|
Seq# |
LSA sequence number. |
|
Checksum |
LSA checksum. |
|
Net mask |
Network mask. |
|
Attached router |
ID of the router that established adjacency with the DR, and ID of the DR itself. |
# Display Type-9 LSA information in the LSDB for OSPF process 1.
<Sysname> display ospf 1 lsdb opaque-link
OSPF Process 1 with Router ID 1.1.1.1
Link State Database
Area: 0.0.0.0
Type : Opq-Link
LS ID : 3.0.0.0
Adv Rtr : 1.1.1.1
LS age : 2
Len : 44
Options : O E
Seq# : 80000001
Checksum : 0x31cf
Opaque type: 3(Grace LSA)
Opaque ID: 0
IETF Graceful Restart Period: 120
Restart Reason: 1 - software restart
Neighbor Interface Address : 192.168.12.1
display ospf nexthop
Use display ospf nexthop to display OSPF next hop information.
Syntax
display ospf [ process-id ] nexthop
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays next hop information for all OSPF processes.
Examples
# Display OSPF next hop information.
<Sysname> display ospf nexthop
OSPF Process 1 with Router ID 1.1.1.2
Neighbor Nexthop Information
NbrID Nexthop Interface RefCount Status
192.168.12.1 0.0.0.0 Vlan10 4 Valid
192.168.12.2 192.168.12.2 Vlan10 3 Valid
192.168.12.1 0.0.0.0 Loop100 1 Valid
Table 25 Command output
|
Field |
Description |
|
NbrID |
Neighbor router ID. |
|
Nexthop |
Next hop address. |
|
Interface |
Output interface. |
|
RefCount |
Reference count (routes that use the next hop). |
|
Status |
Next hop status: · Valid. · Invalid. · Valid-SR—The next hop type is SR tunnel and the SR tunnel has taken effect. · Invalid-SR—The next hop type is SR tunnel and the SR tunnel does not take effect. |
display ospf peer
Use display ospf peer to display information about OSPF neighbors.
Syntax
display ospf [ process-id ] peer [ hello | verbose ] [ interface-type interface-number ] [ [ neighbor-id ] [ resolve-hostname ] | hostname host-name ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by ID in the range of 1 to 65535. If you do not specify this argument, the command displays OSPF neighbor information for all OSPF processes.
hello: Displays information about hello packets sent to and received from neighbor routers. In scenarios where hello packets are sent in multicast, the command displays information about only hello packets received from neighbor routers.
verbose: Displays detailed neighbor information. If you do not specify this keyword, the command displays brief OSPF neighbor information.
interface-type interface-number: Specifies an interface by its type and number. If you do not specify this argument, the command displays neighbor information for all interfaces.
neighbor-id: Specifies a neighbor router ID. If you do not specify this argument, the command displays information for all neighbors.
resolve-hostname: Resolves the host names of the neighbor routers. If you do not specify this keyword, the command cannot resolve the host names of the neighbor routers.
hostname host-name: Specifies a neighbor router by its host name, a case-sensitive string of 1 to 255 characters. If you do not specify this option, the command displays information for all neighbors.
Examples
# Display detailed information about hello packets sent to and received from neighbor routers.
<Sysname> display ospf peer hello
OSPF Process 1 with Router ID 1.1.1.1
Neighbors
Area 0.0.0.0 interface 1.1.1.1(Vlan-interface10)'s neighbors
Router ID: 1.1.1.2 Address: 1.1.1.2
First 4 hello packets received:
2019-02-06 09:12:10:121
2019-02-06 09:12:20:121
2019-02-06 09:12:30:121
2019-02-06 09:12:40:121
Last 4 hello packets received:
2019-02-06 11:15:10:121
2019-02-06 11:15:20:121
2019-02-06 11:15:30:121
2019-02-06 11:15:40:121
First 4 hello packets sent:
2019-02-06 09:12:12:121, failed, errno:132
2019-02-06 09:12:22:121, succeeded
2019-02-06 09:12:32:121, succeeded
2019-02-06 09:12:42:121, succeeded
Last 4 hello packets sent:
2019-02-06 11:15:12:121, succeeded
2019-02-06 11:15:22:121, succeeded
2019-02-06 11:15:32:121, failed, errno:132
2019-02-06 11:15:42:121, failed, errno:132
Table 26 Command output
|
Field |
Description |
|
Router ID |
Router ID of the neighbor. |
|
Address |
IP address of the neighbor interface. |
|
First 4 hello packets received |
Time for receiving the first four hello packets from neighbors. |
|
Last 4 hello packets received |
Time for receiving the last four hello packets from neighbors. |
|
First 4 hello packets sent |
Time and result (succeeded or failed) for sending the first four hello packets to neighbors. For a packet failed to be sent, an error code is displayed in the errno field. This field is not displayed in scenarios where hello packets are sent in multicast. |
|
Last 4 hello packets sent |
Time and result (succeeded or failed) for sending the last four hello packets to neighbors when the command is executed. For a packet failed to be sent, an error code is displayed in the errno field. This field is not displayed in scenarios where hello packets are sent in multicast. |
# Display detailed OSPF neighbor information.
<Sysname> display ospf peer verbose
OSPF Process 1 with Router ID 1.1.1.1
Neighbors
Area 0.0.0.0 interface 1.1.1.1(Vlan-interface100)'s neighbors
Router ID: 1.1.1.2 Address: 1.1.1.2 GR state: Normal
State: Full Mode: Nbr is master Priority: 1
DR: 1.1.1.2 BDR: 1.1.1.1 MTU: 0
Options is 0x02 (-|-|-|-|-|-|E|-)
Dead timer due in 33 sec
Neighbor is up for 02:03:35
Authentication sequence: [ 0 ]
Neighbor state change count: 6
Last Neighbor Down Event:
Router ID: 22.22.22.22
Local Address: 11.11.11.11
Remote Address: 22.22.22.22
Time: Apr 9 03:18:19 2019
Reason: Ospf_ifachange
# Display detailed OSPF neighbor information and resolve the host names of the neighbor routers.
<Sysname> display ospf peer verbose resolve-hostname
Area 0.0.0.1 interface 1.1.1.2(Vlan-interface100)'s neighbors
Router ID: 3.3.3.3 Address: 13.1.1.2 GR state: Normal
Hostname: RouterA
State: Full Mode: Nbr is slave Priority: 1
DR: 13.1.1.2 BDR: 13.1.1.1 MTU: 0
Options is 0x42 (-|O|-|-|-|-|E|-)
Dead timer due in 31 sec
Neighbor is up for 00:04:42
Authentication sequence: [ 0 ]
Neighbor state change count: 5
Last Neighbor Down Event:
Router ID: 3.3.3.3
Local Address: 13.1.1.1
Remote Address: 13.1.1.2
Time: Jun 15 16:13:29 2019
Reason: Reset ospf command was performed
Table 27 Command output
|
Field |
Description |
|
Area areaID interface IPAddress(InterfaceName)'s neighbors |
Neighbor information for the interface in the specified area: · areaID—Area to which the neighbor belongs. · IPAddress—Interface IP address. · InterfaceName—Interface name. |
|
Router ID |
Neighbor router ID. |
|
Address |
Neighbor router address. |
|
GR state |
GR state: · Normal. · Restarter. · Complete. · Helper. |
|
Hostname |
Host name of the neighbor router. |
|
State |
Neighbor state: · Down—Initial state of a neighbor conversation. · Init—The router has received a Hello packet from the neighbor. However, the router has not established bidirectional communication with the neighbor. The router did not appear in the neighbor's hello packet. · Attempt—Available only in an NBMA network. In this state, the OSPF router has not received any information from a neighbor for a period. The router can send Hello packets at a longer interval to keep the neighbor relationship. · 2-Way—Communication between the two routers is bidirectional. The local router appears in the neighbor's Hello packet. · Exstart—The goal of this state is to decide which router is the master, and to decide upon the initial Database Description (DD) sequence number. · Exchange—The router is sending DD packets to the neighbor, describing its entire link-state database. · Loading—The router sends LSRs packets to the neighbor, requesting more recent LSAs. · Full—The neighboring routers are fully adjacent. |
|
Mode |
Neighbor mode for LSDB synchronization. |
|
Priority |
Neighboring router priority. |
|
DR |
DR on the interface's network segment. |
|
BDR |
BDR on the interface's network segment. |
|
MTU |
Interface MTU. |
|
Options |
LSA options: · O—Opaque LSA advertisement capability. · E—AS External LSA reception capability. · EA—External extended LSA reception capability. · DC—On-demand link support. · N—NSSA external LSA support. · P—Capability of an NSSA ABR to translate Type-7 LSAs into Type-5 LSAs. |
|
Dead timer due in 33 sec |
This dead timer will expire in 33 seconds. |
|
Neighbor is up for 02:03:35 |
The neighbor has been up for 02:03:35. |
|
Authentication sequence |
Authentication sequence number. |
|
Neighbor state change count |
Count of neighbor state changes. |
|
Last Neighbor Down Event |
The most recent neighbor down event. |
|
Time |
Time when the neighbor went down. |
|
Reason |
Reason for the neighbor down event. |
# Display brief OSPF neighbor information.
<Sysname> display ospf peer
OSPF Process 1 with Router ID 1.1.1.1
Neighbor Brief Information
Area: 0.0.0.0
Router ID Address Pri Dead-Time State Interface
1.1.1.2 1.1.1.2 1 40 Full/DR Vlan10
Sham link: 11.11.11.11 -> 22.22.22.22
Router ID Address Pri Dead-Time State
22.22.22.22 22.22.22.22 1 36 Full
# Display brief OSPF neighbor information and resolve the host names of the neighbor routers.
<Sysname> display ospf peer resolve-hostname
OSPF Process 1 with Router ID 1.1.1.1
Neighbor Brief Information
Area: 0.0.0.0
Router ID Address Pri Dead-Time State Interface
RouterA 1.1.1.2 1 34 Full/DR Vlan10
Table 28 Command output
|
Field |
Description |
|
Area |
Neighbor area. |
|
Router ID |
ID or host name of the neighbor router. |
|
Address |
Neighbor interface address. |
|
Pri |
Neighboring router priority. |
|
Dead-Time |
Dead interval remained. |
|
Interface |
Interface connected to the neighbor. |
|
State |
Neighbor state: Down, Init, Attempt, 2-Way, Exstart, Exchange, Loading, or Full. |
|
Sham link 11.11.11.11 -> 22.22.22.22 |
Sham link from 11.11.11.11 to 22.22.22.22. |
display ospf peer statistics
Use display ospf peer statistics to display OSPF neighbor statistics.
Syntax
display ospf [ process-id ] peer statistics
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays OSPF neighbor statistics for all OSPF processes.
Examples
# Display OSPF neighbor statistics.
<Sysname> display ospf peer statistics
OSPF Process 1 with Router ID 10.3.1.1
Neighbor Statistics
Area ID Down Attempt Init 2-Way ExStart Exchange Loading Full Total
0.0.0.0 0 0 0 0 0 0 0 1 1
0.0.0.2 0 0 0 0 0 0 0 1 1
Total 0 0 0 0 0 0 0 2 2
Sham links' neighbors (Total: 1):
Down: 0, Init: 0, 2-Way: 0, ExStart: 0, Exchange: 0, Loading: 0, Full: 1
Table 29 Command output
|
Field |
Description |
|
Area ID |
The state statistics for all the routers in the area to which the router belongs is displayed. |
|
Down |
Number of neighboring routers in Down state in the same area. |
|
Attempt |
Number of neighboring routers in Attempt state in the same area. |
|
Init |
Number of neighboring routers in Init state in the same area. |
|
2-Way |
Number of neighboring routers in 2-Way state in the same area. |
|
ExStart |
Number of neighboring routers in ExStart state in the same area. |
|
Exchange |
Number of neighboring routers in Exchange state in the same area. |
|
Loading |
Number of neighboring routers in Loading state in the same area. |
|
Full |
Number of neighboring routers in Full state in the same area. |
|
Total |
Total number of neighbors in the same state: Down, Attempt, Init, 2-Way, ExStart, Exchange, Loading, or Full. |
|
Sham links' neighbors |
Statistics about sham links' neighbors. |
display ospf request-queue
Use display ospf request-queue to display OSPF request queue information.
Syntax
display ospf [ process-id ] request-queue [ interface-type interface-number ] [ neighbor-id ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays the OSPF request queue information for all OSPF processes.
interface-type interface-number: Specifies an interface by its type and number. If you do not specify this argument, the command displays the OSPF request queue information for all interfaces.
neighbor-id: Specifies a neighbor's router ID. If you do not specify this argument, the command displays the OSPF request queue information for all OSPF neighbors.
Examples
# Display OSPF request queue information.
<Sysname> display ospf request-queue
OSPF Process 100 with Router ID 192.168.1.59
Link State Request List
The Router's Neighbor is Router ID 2.2.2.2 Address 10.1.1.2
Interface 10.1.1.1 Area 0.0.0.0
Request list:
Type LinkState ID AdvRouter Sequence Age
Router 2.2.2.2 1.1.1.1 80000004 1
Network 192.168.0.1 1.1.1.1 80000003 1
Sum-Net 192.168.1.0 1.1.1.1 80000002 2
Table 30 Command output
|
Field |
Description |
|
The Router's Neighbor is Router ID |
Neighbor router ID. |
|
Address |
Neighbor interface IP address. |
|
Interface |
Local interface IP address. |
|
Area |
Area ID. |
|
Request list |
Request list information. |
|
Type |
LSA type. |
|
LinkState ID |
Link state ID. |
|
AdvRouter |
Advertising router. |
|
Sequence |
LSA sequence number. |
|
Age |
LSA age. |
display ospf retrans-queue
Use display ospf retrans-queue to display retransmission queue information.
Syntax
display ospf [ process-id ] retrans-queue [ interface-type interface-number ] [ neighbor-id ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays retransmission queue information for all OSPF processes.
interface-type interface-number: Specifies an interface by its type and number. If you do not specify this argument, the command displays retransmission queue information for all interfaces.
neighbor-id: Specifies a neighbor's router ID. If you do not specify this argument, the command displays retransmission queue information for all neighbors.
Examples
# Display OSPF retransmission queue information.
<Sysname> display ospf retrans-queue
OSPF Process 100 with Router ID 192.168.1.59
Link State Retransmission List
The Router's Neighbor is Router ID 2.2.2.2 Address 10.1.1.2
Interface 10.1.1.1 Area 0.0.0.0
Retransmit list:
Type LinkState ID AdvRouter Sequence Age
Router 2.2.2.2 2.2.2.2 80000004 1
Network 12.18.0.1 2.2.2.2 80000003 1
Sum-Net 12.18.1.0 2.2.2.2 80000002 2
Table 31 Command output
|
Field |
Description |
|
The Router's Neighbor is Router ID |
Neighbor router ID. |
|
Address |
Neighbor interface IP address. |
|
Interface |
Interface address of the router. |
|
Area |
Area ID. |
|
Retransmit list |
Retransmission list. |
|
Type |
LSA type. |
|
LinkState ID |
Link state ID. |
|
AdvRouter |
Advertising router. |
|
Sequence |
LSA sequence number. |
|
Age |
LSA age. |
display ospf routing
Use display ospf routing to display OSPF routing information.
Syntax
display ospf [ process-id ] routing [ ip-address { mask-length | mask } ] [ interface interface-type interface-number ] [ nexthop nexthop-address ] [ verbose ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays the routing information for all OSPF processes.
ip-address: Specifies a destination IP address.
mask-length: Specifies mask length in the range of 0 to 32.
mask: Specifies the mask in dotted decimal notation.
interface interface-type interface-number: Displays routes passing the specified output interface. If you do not specify this option, the command displays OSPF routing information for all interfaces.
nexthop nexthop-address: Displays routes passing the specified next hop. If you do not specify this option, the command displays all OSPF routing information.
verbose: Displays detailed OSPF routing information. If you do not specify this keyword, the command displays brief OSPF routing information.
Examples
# Display OSPF routing information.
<Sysname> display ospf routing
OSPF Process 1 with Router ID 192.168.1.2
Routing Table
Topology base (MTID 0)
Routing for network
Destination Cost Type NextHop AdvRouter Area
192.168.1.0/24 1562 Stub 192.168.1.2 192.168.1.2 0.0.0.0
172.16.0.0/16 1563 Inter 192.168.1.1 192.168.1.1 0.0.0.0
Total nets: 2
Intra area: 1 Inter area: 1 ASE: 0 NSSA: 0
Table 32 Command output
|
Field |
Description |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Destination |
Destination network. |
|
Cost |
Cost to destination. |
|
Type |
Route type: transit, stub, inter, Type-1, and Type-2. |
|
NextHop |
Next hop address. |
|
AdvRouter |
Advertising router. |
|
Area |
Area ID. |
|
Total nets |
Total networks. |
|
Intra area |
Total intra-area routes. |
|
Inter area |
Total inter-area routes. |
|
ASE |
Total ASE routes. |
|
NSSA |
Total NSSA routes. |
# Display detailed OSPF routing information.
<Sysname> display ospf routing verbose
OSPF Process 2 with Router ID 192.168.1.112
Routing Table
Topology base (MTID 0)
Routing for network
Destination: 192.168.1.0/24
Priority: Low Type: Stub
AdvRouter: 192.168.1.2 Area: 0.0.0.0
SubProtoID: 0x1 Preference: 10
NextHop: 192.168.1.2 BkNextHop: N/A
IfType: Broadcast BkIfType: N/A
Interface: Vlan100 BkInterface: N/A
NibID: 0x1300000c Status: Normal
Cost: 1562
Destination: 172.16.0.0/16
Priority: Low Type: Inter
AdvRouter: 192.168.1.1 Area: 0.0.0.0
SubProtoID: 0x1 Preference: 10
NextHop: 192.168.1.1 BkNextHop: N/A
IfType: Broadcast BkIfType: N/A
Interface: Vlan101 BkInterface: N/A
NibID: 0x1300000c Status: Normal
Cost: 1563 SpfCost: 65535
Total nets: 2
Intra area: 2 Inter area: 0 ASE: 0 NSSA: 0
Table 33 Command output
|
Field |
Description |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Priority |
Prefix priority: critical, high, medium, and low. |
|
Type |
Route type: transit, stub, inter, Type-1, and Type-2. |
|
AdvRouter |
Advertising router. |
|
Area |
Area ID. |
|
SubProtoID |
Sub protocol ID. |
|
Preference |
OSPF route preference. |
|
NextHop |
Primary next hop IP address. |
|
BkNextHop |
Backup next hop IP address. |
|
IfType |
Type of the network to which the primary next hop belongs. |
|
BkIfType |
Type of the network to which the backup next hop belongs. |
|
Interface |
Output interface. |
|
BkInterface |
Backup output interface. |
|
NibID |
Next hop ID. |
|
Status |
Route status: · Local—The route is on the local end and is not sent to the route management module. · Invalid—The next hop is invalid. · Stale—The next hop is stale. · Normal—The route is available. · Delete—The route is deleted. · Host-Adv—The route is a host route. · Rely—The route is a recursive route. |
|
Cost |
Cost to destination. |
|
SpfCost |
SPF cost. |
display ospf spf-tree
Use display ospf spf-tree to display SPF tree information.
Syntax
display ospf [ process-id ] [ area area-id ] spf-tree [ verbose ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify a process, this command displays SPF tree information for all OSPF processes.
area area-id: Specifies an OSPF area by its ID. The area ID is an IP address or a decimal integer in the range of 0 to 4294967295 that is translated into the IP address format. If you do not specify an area, this command displays SPF tree information for all OSPF areas.
verbose: Displays detailed SPF tree information. If you do not specify this keyword, the command displays brief SPF tree information.
Examples
# Display brief SPF tree information for Area 0 in OSPF process 1.
<Sysname> display ospf 1 area 0 spf-tree
OSPF Process 1 with Router ID 100.0.0.4
Flags: S-Node is on SPF tree R-Node is directly reachable
I-Node or Link is init D-Node or Link is to be deleted
P-Neighbor is parent A-Node is in candidate list
C-Neighbor is child T-Node is tunnel destination
H-Nexthop changed N-Link is a new path
V-Link is involved G-Link is in change list
Topology base (MTID 0)
Area: 0.0.0.0 Shortest Path Tree
SpfNode Type Flag SpfLink Type Cost Flag
>192.168.119.130 Network S R
-->114.114.114.111 NET2RT 0 C
-->100.0.0.4 NET2RT 0 P
>114.114.114.111 Router S
-->192.168.119.130 RT2NET 65535 P
>100.0.0.4 Router S
-->192.168.119.130 RT2NET 10 C
Table 34 Command output
|
Field |
Description |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
SpfNode |
SPF node, represented by a router ID when the node type is Router, or the IP address of the DR when the node type is Network. Node flag: · I—The node is in initialization state. · A—The node is on the candidate list. · S—The node is on the SPF tree. · R—The node is directly connected to the root node. · D—The node is to be deleted. · T—The node is the tunnel destination. |
|
SpfLink |
SPF link, representing the peer node. Link type: · RT2RT—Router to router. · NET2RT—Network to router. · RT2NET—Router to network. Link flag: · I—The link is in initialization state. · P—The peer is the parent node. · C—The peer is the child node. · D—The link is to be deleted. · H—The next hop is changed. · V—When the peer node is deleted or added, the peer node is not on the SPF tree or is deleted. · N—The link is newly added, and both end nodes are on the SPF tree. · G—The link is on the area change list. |
# Display detailed SPF tree information for Area 0 in OSPF process 1.
<Sysname> display ospf 1 area 0 spf-tree verbose
OSPF Process 1 with Router ID 100.0.0.4
Flags: S-Node is on SPF tree R-Node is directly reachable
I-Node or Link is init D-Node or Link is to be deleted
P-Neighbor is parent A-Node is in candidate list
C-Neighbor is child T-Node is tunnel destination
H-Nexthop changed N-Link is a new path
V-Link is involved G-Link is in change list
Topology base (MTID 0)
Area: 0.0.0.0 Shortest Path Tree
>LsId(192.168.119.130)
AdvId : 100.0.0.4 NodeType : Network
Mask : 255.255.255.0 SPFLinkCnt : 2
Distance : 10
VlinkData: 0.0.0.0 ParentLinkCnt: 1 NodeFlag: S R
NextHop : 1
192.168.119.130 Interface: Vlan100
BkNextHop: 1
0.0.0.0 Interface: Vlan100
-->LinkId(114.114.114.111)
AdvId : 100.0.0.4 LinkType : NET2RT
LsId : 192.168.119.130 LinkCost : 0 NextHopCnt: 1
LinkData: 0.0.0.0 LinkNewCost: 0 LinkFlag : C
-->LinkId(100.0.0.4)
AdvId : 100.0.0.4 LinkType : NET2RT
LsId : 192.168.119.130 LinkCost : 0 NextHopCnt: 1
LinkData: 0.0.0.0 LinkNewCost: 0 LinkFlag : P
Table 35 Command output
|
Field |
Description |
|
Topology |
Topologies except the base topology are not supported in the current software version. Topology name. The topology name for base topology is base. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
LsId |
Link state ID. |
|
AdvId |
ID of the advertising router. |
|
NodeType |
Node type: · Network—Network node. · Router—Router node. |
|
Mask |
Network mask. Its value is 0 for a router node. |
|
SPFLinkCnt |
Number of SPF links. |
|
Distance |
Cost to the root node. |
|
VlinkData |
Destination address of virtual link packets. |
|
ParentLinkCnt |
Number of parent links. |
|
NodeFlag |
Node flag: · I—The node is in initialization state. · A—The node is on the candidate list. · S—The node is on the SPF tree. · R—The node is directly connected to the root node. · D—The node is to be deleted. · T—The node is the tunnel destination. |
|
NextHop |
Next hop. |
|
Interface |
Output interface. |
|
BkNextHop |
Backup next hop. |
|
BkNextHop |
Backup next hop. |
|
Flag |
Next hop type. SR indicates SR tunnel. This field displays a hyphen (-) for other next hop types. |
|
Protect |
Traffic protection type: Link or Node. |
|
LinkId |
Link ID. |
|
LinkType |
Link type: · RT2RT—Router to router. · NET2RT—Network to router. · RT2NET—Router to network. |
|
LinkCost |
Link cost. |
|
NextHopCnt |
Number of next hops. |
|
LinkData |
Link data. |
|
LinkNewCost |
New link cost. |
|
LinkFlag |
Link flag: · I—The link is in initialization state. · P—The peer is the parent node. · C—The peer is the child node. · D—The link is to be deleted. · H—The next hop is changed. · V—When the peer node is deleted or added, the peer node is not on the SPF tree or is deleted. · N—The link is newly added, and both end nodes are on the SPF tree. · G—The link is on the area change list. |
display ospf statistics
Use display ospf statistics to display OSPF statistics.
Syntax
display ospf [ process-id ] statistics [ error | packet [ hello | interface-type interface-number ] ]
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays OSPF statistics for all OSPF processes.
error: Displays error statistics. If you do not specify this keyword, the command displays OSPF packet, LSA, and route statistics.
packet: Displays OSPF packet statistics.
hello: Displays statistics information about sent and received hello packets. If you do not specify this keyword, the command displays statistics information about all types of sent and received OSPF packets.
interface-type interface-number: Specifies an interface by its type and number. If you do not specify this argument, the command displays statistics for all interfaces.
Examples
# Display OSPF statistics.
<Sysname> display ospf statistics
OSPF Process 1 with Router ID 2.2.2.2
Statistics
I/O statistics
Type Input Output
Hello 61 122
DB Description 2 3
Link-State Req 1 1
Link-State Update 3 3
Link-State Ack 3 2
LSAs originated by this router
Router : 4
Network : 0
Sum-Net : 0
Sum-Asbr: 0
External: 0
NSSA : 0
Opq-Link: 0
Opq-As : 0
LSAs originated: 4 LSAs received: 7
Routing table:
Intra area: 2 Inter area: 3 ASE/NSSA: 0
Table 36 Command output
|
Field |
Description |
|
I/O statistics |
Statistics about input/output packets and LSAs. |
|
Type |
OSPF packet type. |
|
Input |
Packets received. |
|
Output |
Packets sent. |
|
Hello |
Hell packet. |
|
DB Description |
Database Description packet. |
|
Link-State Req |
Link-State Request packet. |
|
Link-State Update |
Link-State Update packet. |
|
Link-State Ack |
Link-State Acknowledge packet. |
|
LSAs originated by this router |
LSAs originated by this router. |
|
Router |
Number of Type-1 LSAs originated. |
|
Network |
Number of Type-2 LSAs originated. |
|
Sum-Net |
Number of Type-3 LSAs originated. |
|
Sum-Asbr |
Number of Type-4 LSAs originated. |
|
External |
Number of Type-5 LSAs originated. |
|
NSSA |
Number of Type-7 LSAs originated. |
|
Opq-Link |
Number of Type-9 LSAs originated. |
|
Opq-As |
Number of Type-11 LSAs originated. |
|
LSA originated |
Number of LSAs originated. |
|
LSA received |
Number of LSAs received. |
|
Routing table |
Routing table information. |
|
Intra area |
Number of intra-area routes. |
|
Inter area |
Number of inter-area routes. |
|
ASE/NSSA |
Number of ASE/NSSA routes. |
# Display OSPF error statistics.
<Sysname> display ospf statistics error
OSPF Process 1 with Router ID 192.168.1.112
OSPF Packet Error Statistics
0 : Router ID confusion 0 : Bad packet
0 : Bad version 0 : Bad checksum
0 : Bad area ID 0 : Drop on unnumbered link
0 : Bad virtual link 0 : Bad authentication type
0 : Bad authentication key 0 : Packet too small
0 : Neighbor state low 0 : Transmit error
0 : Interface down 0 : Unknown neighbor
0 : HELLO: Netmask mismatch 0 : HELLO: Hello-time mismatch
0 : HELLO: Dead-time mismatch 0 : HELLO: Ebit option mismatch
0 : HELLO: Mbit option mismatch 0 : DD: MTU option mismatch
0 : DD: Unknown LSA type 0 : DD: Ebit option mismatch
0 : ACK: Bad ack 0 : ACK: Unknown LSA type
0 : REQ: Empty request 0 : REQ: Bad request
0 : UPD: LSA checksum bad 0 : UPD: Unknown LSA type
0 : UPD: Less recent LSA
Table 37 Command output
|
Field |
Description |
|
Router ID confusion |
Packets with duplicate router ID. |
|
Bad packet |
Packets illegal. |
|
Bad version |
Packets with wrong version. |
|
Bad checksum |
Packets with wrong checksum. |
|
Bad area ID |
Packets with invalid area ID. |
|
Drop on unnumbered link |
Packets dropped on the unnumbered interface. |
|
Bad virtual link |
Packets on wrong virtual links. |
|
Bad authentication type |
Packets with invalid authentication type. |
|
Bad authentication key |
Packets with invalid authentication key. |
|
Packet too small |
Packets too small in length. |
|
Neighbor state low |
Packets received in low neighbor state. |
|
Transmit error |
Packets with error when being transmitted. |
|
Interface down |
Shutdown times of the interface. |
|
Unknown neighbor |
Packets received from unknown neighbors. |
|
HELLO: Netmask mismatch |
Hello packets with mismatched mask. |
|
HELLO: Hello-time mismatch |
Hello packets with mismatched hello timer. |
|
HELLO: Dead-time mismatch |
Hello packets with mismatched dead timer. |
|
HELLO: Ebit option mismatch |
Hello packets with mismatched E-bit in the option field. |
|
HELLO: Mbit option mismatch |
Hello packets with mismatched M-bit in the option field. |
|
DD: MTU option mismatch |
DD packets with mismatched MTU. |
|
DD: Unknown LSA type |
DD packets with unknown LSA type. |
|
DD: Ebit option mismatch |
DD packets with mismatched E-bit in the option field. |
|
ACK: Bad ack |
Bad LSAck packets for LSU packets. |
|
ACK: Unknown LSA type |
LSAck packets with unknown LSA type. |
|
REQ: Empty request |
LSR packets with no request information. |
|
REQ: Bad request |
Bad LSR packets. |
|
UPD: LSA checksum bad |
LSU packets with wrong LSA checksum. |
|
UPD: Unknown LSA type |
LSU packets with unknown LSA type. |
|
UPD: Less recent LSA |
LSU packets without the most recent LSA. |
# Display OSPF packet statistics for all processes and interfaces.
<Sysname> display ospf statistics packet
OSPF Process 100 with Router ID 192.168.1.59
Packet Statistics
Waiting to send packet count: 0
Hello DD LSR LSU ACK Total
Input : 489 6 2 44 40 581
Output: 492 8 2 45 40 587
Area: 0.0.0.1
Interface: 20.1.1.1 (Vlan-interface100)
DD LSR LSU ACK Total
Input : 0 0 0 0 0
Output: 0 0 0 0 0
Interface: 100.1.1.1 (Vlan-interface100)
DD LSR LSU ACK Total
Input : 3 1 22 16 42
Output: 2 1 19 20 42
Table 38 Command output
|
Field |
Description |
|
Waiting to send packet count |
Number of packets waiting to be sent. |
|
Total |
Total number of packets. |
|
Input |
Number of received packets. |
|
Output |
Number of sent packets. |
|
Area |
Area ID. |
|
Interface |
Interface address and interface name. |
# Display statistics information about sent and received hello packets.
<Sysname> display ospf statistics packet hello
OSPF Process 1 with Router ID 1.1.1.1
Hello statistics
Total sent : 201
Total sent failed : 0
Sent after one and a half intervals : 0
Total received : 221
Total received dropped : 0
Received after one and a half intervals: 0
Table 39 Command output
|
Field |
Description |
|
Total sent |
Total number of hello packets sent. |
|
Total sent failed |
Total number of hello packets that failed to be sent. |
|
Sent after one and a half intervals |
Total number of hello packets sent at intervals greater than 1.5 times the hello interval. |
|
Total received |
Total number of hello packets received. |
|
Total received dropped |
Total number of discarded inbound hello packets. |
|
Received after one and a half intervals |
Total number of hello packets received at intervals greater than 1.5 times the hello interval. |
Related commands
reset ospf statistics
display ospf vlink
Use display ospf vlink to display OSPF virtual link information.
Syntax
display ospf [ process-id ] vlink
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command displays the OSPF virtual link information for all OSPF processes.
Examples
# Display OSPF virtual link information.
<Sysname> display ospf vlink
OSPF Process 1 with Router ID 3.3.3.3
Virtual Links
Virtual-link Neighbor-ID -> 2.2.2.2, Neighbor-State: Full
Interface: 10.1.2.1 (Vlan-interface100)
Cost: 1562 State: P-2-P Type: Virtual
Transit Area: 0.0.0.1
Timers: Hello 10 , Dead 40 , Retransmit 5 , Transmit Delay 1
Cryptographic authentication: Enabled, inherited
The last key is 3.
The rollover is in progress, 2 neighbor(s) left.
MTID Cost Disabled Topology name
0 16777215 No base
Table 40 Command output
|
Field |
Description |
|
Virtual-link Neighbor-ID |
ID of the neighbor on the virtual link. |
|
Neighbor-State |
Neighbor state: Down, Init, 2-Way, ExStart, Exchange, Loading, Full. |
|
Interface |
IP address and name of the local interface on the virtual link. |
|
Cost |
Interface route cost. |
|
State |
Interface state. |
|
Type |
Virtual link. |
|
Transit Area |
Transit area ID. |
|
Timers |
Values of timers (in seconds): Hello, Dead, and Retransmit. |
|
Transmit Delay |
LSA transmission delay on the interface, in seconds. |
|
Cryptographic authentication: Enabled, inherited |
Cryptographic authentication mode (MD5, HMAC-MD5, or HMAC-SHA-256) is used by the virtual link. The inherited attribute indicates that the virtual link uses the authentication mode specified for the backbone area. If the virtual link uses the simple authentication mode, this field displays Simple authentication: Enabled, inherited. |
|
The last key |
Most recent MD5, HMAC-MD5, or HMAC-SHA-256 authentication key ID. |
|
The rollover is in progress, 2 neighbor(s) left |
Key rollover for MD5, HMAC-MD5, or HMAC-SHA-256 authentication is in progress, and two neighbors have not completed the key rollover. |
|
MTID |
Topologies except the base topology are not supported in the current software version. Topology ID. The value of 0 indicates the base topology. |
|
Cost |
Cost of the interface route in the topology. |
|
Disabled |
Whether OSPF is disabled from advertising the topology for the virtual link: Yes or No. |
|
Topology name |
Topologies except the base topology are not supported in the current software version. The topology name for base topology is base. |
display router id
Use display router id to display the global router ID.
Syntax
display router id
Views
Any view
Predefined user roles
network-admin
network-operator
Parameters
Examples
# Display the global router ID.
<Sysname> display router id
Configured router ID is 1.1.1.1
dscp
Use dscp to set the DSCP value for outgoing OSPF packets.
Use undo dscp to restore the default.
Syntax
dscp dscp-value
undo dscp
Default
The DSCP value for outgoing OSPF packets is 48.
Views
OSPF view
Predefined user roles
network-admin
Parameters
dscp-value: Specifies the DSCP value in the range of 0 to 63 for outgoing OSPF packets.
Examples
# Set the DSCP value for outgoing OSPF packets to 63 in OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] dscp 63
enable link-local-signaling
Use enable link-local-signaling to enable the OSPF link-local signaling (LLS) capability.
Use undo enable link-local-signaling to disable the OSPF LLS capability.
Syntax
enable link-local-signaling
undo enable link-local-signaling
Default
OSPF link-local signaling capability is disabled.
Views
OSPF view
Predefined user roles
network-admin
Examples
# Enable link-local signaling for OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] enable link-local-signaling
enable out-of-band-resynchronization
Use enable out-of-band-resynchronization to enable the OSPF out-of-band resynchronization (OOB-Resynch) capability.
Use undo enable out-of-band-resynchronization to disable the OSPF out-of-band resynchronization capability.
Syntax
enable out-of-band-resynchronization
undo enable out-of-band-resynchronization
Default
The OSPF out-of-band resynchronization capability is disabled.
Views
OSPF view
Predefined user roles
network-admin
Usage guidelines
Before you configure this command, enable the link-local signaling capability.
Examples
# Enable the out-of-band resynchronization capability for OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] enable link-local-signaling
[Sysname-ospf-1] enable out-of-band-resynchronization
Related commands
enable link-local-signaling
event-log
Use event-log to configure the OSPF logging feature.
Use undo event-log to remove the configuration.
Syntax
event-log { hello { received [ abnormal | dropped ] | sent [ abnormal | failed ] } | lsa-flush | peer | route | spf } size count
event-log lsa-history { asbr | ase | include-duplicate | link-state-id | network | nssa | opaque-as | opaque-link | originate-router advertising-router-id | router | size count | summary | verbose } *
undo event-log { hello { received [ abnormal | dropped ] | sent [ abnormal | failed ] } | lsa-flush | peer | route | spf } size
undo event-log lsa-history
Default
The device can generate a maximum of 100 logs for each type.
Views
OSPF view
Predefined user roles
network-admin
Parameters
hello: Specifies the number of logs for received or sent hello packets.
received: Specifies the number of logs for received hello packets.
sent: Specifies the number of logs for sent hello packets.
abnormal: Specifies the number of logs for abnormal hello packets that are received or sent at intervals greater than or equal to 1.5 times the hello interval.
dropped: Specifies the number of logs for discarded inbound hello packets.
failed: Specifies the number of logs for hello packets that failed to be sent.
lsa-flush: Specifies the number of LSA aging logs.
peer: Specifies the number of neighbor state change logs.
route: Specifies the number of OSPF route logs.
spf: Specifies the number of route calculation logs.
size count: Specifies the number of OSPF logs, in the range of 0 to 65535.
lsa-history: Logs self-originated and received LSA information.
include-duplicate: Specifies all LSAs including duplicate LSAs. Duplicate LSAs refer to LSAs that carry the same options and contents.
verbose: Logs detailed information about self-originated and received LSAs. If you do not specify this keyword, the command logs brief information about self-originated and received LSAs.
asbr: Logs Type-4 LSA (ASBR Summary LSA) information.
ase: Logs Type-5 LSA (AS External LSA) information.
network: Logs Type-2 LSA (Network LSA) information.
nssa: Logs Type-7 LSA (NSSA External LSA) information.
opaque-as: Logs Type-11 LSA (Opaque-AS LSA) information.
opaque-link: Logs Type-9 LSA (Opaque-link LSA) information.
router: Logs Type-1 LSA (Router LSA) information.
summary: Logs Type-3 LSA (Network Summary LSA) information.
originate-router advertising-router-id: Specifies an advertising router by its ID.
link-state-id: Specifies a link state ID in the IP address format.
Examples
# Set the number of route calculation logs to 50 in OSPF process 100.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] event-log spf size 50
fast-reroute
Use fast-reroute to configure OSPF FRR.
Use undo fast-reroute to restore the default.
Syntax
fast-reroute lfa [ abr-only ]
undo fast-reroute
Default
OSPF FRR is disabled.
Views
OSPF view
Predefined user roles
network-admin
Parameters
lfa: Uses the LFA algorithm to calculate a backup next hop for all routes.
abr-only: Uses the next hop of the route to the ABR as the backup next hop.
Usage guidelines
When both OSPF FRR and PIC are configured, OSPF FRR takes effect.
Do not use the fast-reroute lfa command together with the vlink-peer command.
Examples
# Enable FRR to calculate a backup next hop for all routes by using LFA algorithm in OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] fast-reroute lfa
fast-reroute tiebreaker
Use fast-reroute tiebreaker to set the priority for FRR backup path selection policies.
Use undo fast-reroute tiebreaker to restore the default.
Syntax
fast-reroute tiebreaker { lowest-cost | node-protecting | srlg-disjoint } preference preference
undo fast-reroute tiebreaker { lowest-cost | node-protecting | srlg-disjoint }
Default
The priority values of the node-protection, lowest-cost, and SRLG-disjoint backup path selection policies are 40, 20, and 10, respectively.
Views
OSPF view
Predefined user roles
network-admin
Parameters
lowest-cost: Sets a priority value for the lowest-cost backup path selection policy.
node-protecting: Sets a priority value for the node-protection backup path selection policy.
srlg-disjoint: Sets a priority value for the SRLG-disjoint backup path selection policy.
preference preference: Specifies a priority value in the range of 1 to 255. A higher value indicates a higher priority.
Usage guidelines
If you execute this command multiple times for a backup path selection policy, the most recent configuration takes effect.
When you configure multiple backup path selection policies for an OSPF process, OSPF first uses the policy with the highest priority to calculate a backup path. If the backup path calculation fails, OSPF works as follows:
· If the SRLG-disjoint policy has the highest priority but the backup path calculation fails, OSPF selects the one with the higher priority from the node-protection and lowest-cost policies:
¡ If the node-protection policy has the higher priority but the backup path calculation still fails, OSPF uses the lowest-cost policy for further calculation.
¡ If the lowest-cost policy has the higher priority but the backup path calculation still fails, OSPF does not perform further backup path calculation.
· If the node-protection policy has the highest priority but the backup path calculation fails, OSPF selects the one with the higher priority from the SRLG-disjoint and lowest-cost policies:
¡ If the SRLG-disjoint policy has the higher priority but the backup path calculation still fails, OSPF uses the lowest-cost policy for further calculation.
¡ If the lowest-cost policy has the higher priority but the backup path calculation still fails, OSPF does not perform further backup path calculation.
· If the lowest-cost policy has the highest priority but the backup path calculation fails, OSPF does not perform further backup path calculation.
Examples
# Set the priority value of the node-protection backup path selection policy to 100 for OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] fast-reroute tiebreaker node-protecting preference 100
Related commands
fast-reroute
filter
Use filter to configure OSPF to filter inbound/outbound Type-3 LSAs on an ABR.
Use undo filter to disable Type-3 LSA filtering.
Syntax
filter { ipv4-acl-number | prefix-list prefix-list-name } { export | import }
undo filter { export | import }
Default
Type-3 LSAs are not filtered.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
ipv4-acl-number: Specifies an IPv4 ACL by its number in the range of 2000 to 3999 to filter inbound/outbound Type-3 LSAs.
prefix-list-name: Specifies an IP prefix list by its name, a case-sensitive string of 1 to 63 characters, to filter inbound/outbound Type-3 LSAs.
export: Filters Type-3 LSAs advertised to other areas.
import: Filters Type-3 LSAs advertised into the local area.
Usage guidelines
This command applies only to an ABR.
If the specified ACL does not exist or has no rules, the ABR does not filter Type-3 LSAs.
To use an advanced ACL (with a number from 3000 to 3999) in the command, configure the ACL using one of the following methods:
· To deny or permit Type-3 LSAs with the specified link state ID, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard command.
· To deny or permit Type-3 LSAs with the specified link state ID and mask, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard destination dest-addr dest-wildcard command.
The source keyword specifies the link state ID of a Type-3 LSA and the destination keyword specifies the subnet mask of the LSA. For the mask configuration to take effect, specify a contiguous subnet mask.
Examples
# Use IP prefix list my-prefix-list to filter inbound Type-3 LSAs. Use basic ACL 2000 to filter outbound Type-3 LSAs in OSPF Area 1.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 1
[Sysname-ospf-100-area-0.0.0.1] filter prefix-list my-prefix-list import
[Sysname-ospf-100-area-0.0.0.1] filter 2000 export
filter-policy export
Use filter-policy export to configure OSPF to filter redistributed routes.
Use undo filter-policy export to remove the configuration.
Syntax
filter-policy { ipv4-acl-number | prefix-list prefix-list-name } export [ | direct | { ospf | rip } [ process-id ] | static ]
undo filter-policy export [ | direct | { ospf | rip } [ process-id ] | static ]
Default
OSPF does not filter redistributed routes.
Views
OSPF view
Predefined user roles
network-admin
Parameters
ipv4-acl-number: Specifies an IPv4 ACL by its number in the range of 2000 to 3999 to filter redistributed routes by destination address.
prefix-list-name: Specifies an IP prefix list by its name, a case-sensitive string of 1 to 63 characters, to filter redistributed routes by destination address.
direct: Filter redistributed direct routes.
ospf: Filter redistributed OSPF routes.
rip: Filter redistributed RIP routes.
process-id: Specifies a process by its ID in the range of 1 to 65535. This argument is available only when the protocol argument is rip, ospf or isis.
static: Filter redistributed static routes.
Usage guidelines
If you do not specify any parameters, the command filters all redistributed routes.
If the specified ACL does not exist or has no rules, OSPF does not filter redistributed routes.
To use an advanced ACL (with a number from 3000 to 3999) in the command, configure the ACL using one of the following methods:
· To deny/permit a route with the specified destination, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard command.
· To deny/permit a route with the specified destination and mask, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard destination dest-addr dest-wildcard command.
The source keyword specifies the destination address of a route and the destination keyword specifies the subnet mask of the destination address. For the mask configuration to take effect, specify a contiguous subnet mask.
Examples
# Configure OSPF process 100 to filter redistributed routes by using basic ACL 2000.
<Sysname> system-view
[Sysname] acl basic 2000
[Sysname-acl-ipv4-basic-2000] rule deny source 192.168.10.0 0.0.0.255
[Sysname-acl-ipv4-basic-2000] quit
[Sysname] ospf 100
[Sysname-ospf-100] filter-policy 2000 export
# Configure advanced ACL 3000 to permit only route 113.0.0.0/16. Configure OSPF process 100 to filter redistributed routes by using advanced ACL 3000.
<Sysname> system-view
[Sysname] acl advanced 3000
[Sysname-acl-ipv4-adv-3000] rule 10 permit ip source 113.0.0.0 0 destination 255.255.0.0 0
[Sysname-acl-ipv4-adv-3000] rule 100 deny ip
[Sysname-acl-ipv4-adv-3000] quit
[Sysname] ospf 100
[Sysname-ospf-100] filter-policy 3000 export
Related commands
import-route
filter-policy import
Use filter-policy import to configure OSPF to filter routes calculated using received LSAs.
Use undo filter-policy import to restore the default.
Syntax
filter-policy { ipv4-acl-number [ gateway prefix-list-name ] | gateway prefix-list-name | prefix-list prefix-list-name [ gateway prefix-list-name ] } import
undo filter-policy import
Default
OSPF does not filter routes calculated using received LSAs.
Views
OSPF view
Predefined user roles
network-admin
Parameters
ipv4-acl-number: Specifies an IPv4 ACL by its number in the range of 2000 to 3999 to filter received routes by destination.
gateway prefix-list-name: Specifies an IP prefix list by its name, a case-sensitive string of 1 to 63 characters, to filter received routes by next hop.
prefix-list prefix-list-name: Specifies an IP prefix list by its name, a case-sensitive string of 1 to 63 characters, to filter received routes by destination.
Usage guidelines
If the specified ACL does not exist or has no rules, OSPF does not filter calculated routes.
To use an advanced ACL (with a number from 3000 to 3999) in the command or in the specified routing policy, configure the ACL in one of the following ways:
· To deny/permit a route with the specified destination, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard command.
· To deny/permit a route with the specified destination and mask, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard destination dest-addr dest-wildcard command.
The source keyword specifies the destination address of a route and the destination keyword specifies the subnet mask of the destination address. For the mask configuration to take effect, specify a contiguous subnet mask.
Examples
# Use basic ACL 2000 to filter received routes.
<Sysname> system-view
[Sysname] acl basic 2000
[Sysname-acl-ipv4-basic-2000] rule deny source 192.168.10.0 0.0.0.255
[Sysname-acl-ipv4-basic-2000] quit
[Sysname] ospf 100
[Sysname-ospf-100] filter-policy 2000 import
# Configure advanced ACL 3000 to permit only route 113.0.0.0/16. Use ACL 3000 to filter received routes.
<Sysname> system-view
[Sysname] acl advanced 3000
[Sysname-acl-ipv4-adv-3000] rule 10 permit ip source 113.0.0.0 0 destination 255.255.0.0 0
[Sysname-acl-ipv4-adv-3000] rule 100 deny ip
[Sysname-acl-ipv4-adv-3000] quit
[Sysname] ospf 100
[Sysname-ospf-100] filter-policy 3000 import
graceful-restart
Use graceful-restart to enable OSPF GR.
Use undo graceful-restart to disable OSPF GR.
Syntax
graceful-restart [ ietf | nonstandard ] [ global | planned-only ] *
undo graceful-restart
Default
OSPF GR is disabled.
Views
OSPF view
Predefined user roles
network-admin
Parameters
ietf: Enables IETF GR.
nonstandard: Enables non-IETF GR.
global: Enables global GR. In global GR mode, a GR process can be completed only when all GR helpers exist. A GR process fails if a GR helper fails (for example, the interface connected to the GR helper goes down). If you do not specify this keyword, the command enables partial GR. In partial GR mode, a GR process can be completed if a GR helper exists.
planned-only: Enables only planned GR. If you do not specify this keyword, the command enables both planned GR and unplanned GR.
Usage guidelines
GR includes planned GR and unplanned GR.
· Planned GR—Manually restarts OSPF by using the reset ospf process command or performs an active/standby process switchover by using the placement reoptimize command. Before OSPF restart or active/standby switchover, the GR restarter sends Grace-LSAs to GR helpers.
· Unplanned GR—OSPF restarts or an active/standby switchover occurs because of device failure. Before OSPF restart or active/standby switchover, the GR restarter does not send Grace-LSAs to GR helpers.
Before enabling IETF GR for OSPF, enable Opaque LSA advertisement and reception with the opaque-capability enable command.
Before enabling non-IETF GR for OSPF, enable OSPF LLS with the enable link-local-signaling command and OOB-Resynch with the enable out-of-band-resynchronization command.
If you do not specify the nonstandard or ietf keyword, this command enables non-IETF GR for OSPF.
Examples
# Enable IETF GR for OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] opaque-capability enable
[Sysname-ospf-1] graceful-restart ietf
# Enable non-IETF GR for OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] enable link-local-signaling
[Sysname-ospf-1] enable out-of-band-resynchronization
[Sysname-ospf-1] graceful-restart nonstandard
Related commands
enable link-local-signaling
enable out-of-band-resynchronization
opaque-capability enable
graceful-restart helper enable
Use graceful-restart helper enable to enable OSPF GR helper capability.
Use undo graceful-restart helper enable to disable OSPF GR helper capability.
Syntax
graceful-restart helper enable [ planned-only ]
undo graceful-restart helper enable
Default
OSPF GR helper capability is enabled.
Views
OSPF view
Predefined user roles
network-admin
Parameters
planned-only: Enables only planned GR for the GR helper. If you do not specify this keyword, the command enables both planned GR and unplanned GR for the GR helper.
Usage guidelines
The planned-only keyword is available only for the IETF GR helper.
Examples
# Enable GR helper capability for OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] graceful-restart helper enable
graceful-restart helper strict-lsa-checking
Use graceful-restart helper strict-lsa-checking to enable strict LSA checking capability for GR helper.
Use undo graceful-restart helper strict-lsa-checking to disable strict LSA checking capability for GR helper.
Syntax
graceful-restart helper strict-lsa-checking
undo graceful-restart helper strict-lsa-checking
Default
Strict LSA checking capability for GR helper is disabled.
Views
OSPF view
Predefined user roles
network-admin
Usage guidelines
When an LSA change on the GR helper is detected, the GR helper device exits the GR helper mode.
Examples
# Enable strict LSA checking capability for GR helper in OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] graceful-restart helper strict-lsa-checking
graceful-restart interval
Use graceful-restart interval to set the GR interval.
Use undo graceful-restart interval to restore the default.
Syntax
graceful-restart interval interval
undo graceful-restart interval
Default
The GR interval is 120 seconds.
Views
OSPF view
Predefined user roles
network-admin
Parameters
interval: Specifies the GR interval in the range of 40 to 1800 seconds.
Usage guidelines
For GR restart to succeed, the value of the GR restart interval cannot be smaller than the maximum OSPF neighbor dead time of all the OSPF interfaces.
Examples
# Set the GR interval for OSPF process 1 to 100 seconds.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] graceful-restart interval 100
Related commands
ospf timer dead
host-advertise
Use host-advertise to advertise a host route.
Use undo host-advertise to remove a host route.
Syntax
host-advertise ip-address cost-value
undo host-advertise ip-address
Default
No host route is advertised.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
ip-address: Specifies the IP address of a host.
cost-value: Specifies a cost for the route, in the range of 1 to 65535.
Examples
# Advertise host route 1.1.1.1 with a cost of 100.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 0
[Sysname-ospf-100-area-0.0.0.0] host-advertise 1.1.1.1 100
hostname
Use hostname to enable the OSPF dynamic host name mapping feature.
Use undo hostname disable the OSPF dynamic host name mapping feature.
Syntax
hostname [ host-name ]
undo hostname
Default
The OSPF dynamic host name mapping feature is disabled.
Views
OSPF view
Predefined user roles
network-admin
Parameters
host-name: Specifies the host name mapped to the router ID of the OSPF process, a case-sensitive string of 1 to 255 characters. If you do not specify this argument, the device name is mapped to the router ID of the OSPF process.
Usage guidelines
OSPF uses Type-11 LSAs to carry information about the dynamic host name attribute. Before using this command, make sure the opaque LSA reception and advertisement capability is enabled.
Examples
# Enable the dynamic host name mapping feature for OSPF process 1, and specify the host name mapped to the router ID as red.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] hostname red
Related commands
display ospf hostname-table
opaque-capability enable
import-route
Use import-route to enable route redistribution.
Use undo import-route to disable route redistribution.
Syntax
import-route { direct | static } [ [ cost cost-value | inherit-cost ] | nssa-only | tag tag | type type ] *
import-route { ospf | rip } [ process-id | all-processes ] [ allow-direct | [ cost cost-value | inherit-cost ] | nssa-only | tag tag | type type ] *
undo import-route { direct | { ospf | rip } [ process-id | all-processes ] | static }
Default
OSPF does not redistribute routes.
Views
OSPF view
Predefined user roles
network-admin
Parameters
direct: Redistributes direct routes.
ospf: Redistributes OSPF routes.
rip: Redistributes RIP routes.
process-id: Specifies a process by its ID in the range of 1 to 65535. The default is 1.
static: Redistributes static routes.
all-processes: Redistributes routes from all the processes of the specified routing protocol.
allow-direct: Redistributes the networks of the local interfaces enabled with the specified routing protocol. If you do not specify this keyword, the networks of the local interfaces are not redistributed.
cost cost-value: Specifies a route cost in the range of 0 to 16777214. The default is 1.
inherit-cost: Uses the original cost of redistributed routes.
nssa-only: Limits the route advertisement to the NSSA area by setting the P-bit of Type-7 LSAs to 0. If you do not specify this keyword, the P-bit of Type-7 LSAs is set to 1. If the router acts as both an ASBR and an ABR and FULL state neighbors exist in the backbone area, the P-bit is set to 0. This keyword applies to NSSA routers.
tag tag: Specifies a tag for external LSAs, in the range of 0 to 4294967295. The default is 1.
type type: Specifies a cost type, 1 or 2. The default is 2.
Usage guidelines
This command redistributes routes destined for other ASs from another protocol. AS external routes include the following types:
· Type-1 external routes—Have high credibility. The cost of Type-1 external routes is comparable with the cost of OSPF internal routes. The cost of a Type-1 external route equals the cost from the router to the ASBR plus the cost from the ASBR to the external route's destination.
· Type-2 external routes—Have low credibility. OSPF considers the cost from the ASBR to the destination of a Type-2 external route is much bigger than the cost from the ASBR to an OSPF internal router. The cost of a Type-2 external route equals the cost from the ASBR to the Type-2 external route's destination.
The import-route command redistributes only active routes. To display information about active routes, use the display ip routing-table protocol command. The import-route command cannot redistribute default external routes.
If you do not specify the cost or inherit-cost keyword, the cost of a redistributed route is 1.
The undo import-route protocol all-processes command removes only the configuration made by the import-route protocol all-processes command, instead of the configuration made by the import-route protocol process-id command.
Examples
# Redistribute routes from RIP process 40 and specify the type, tag, and cost as 2, 33, and 50 for redistributed routes.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] import-route rip 40 type 2 tag 33 cost 50
default-route-advertise (OSPF view)
isolate enable
Use isolate enable to enable OSPF isolation.
Use undo isolate enable to disable OSPF isolation.
Syntax
isolate enable
undo isolate enable
Default
OSPF isolation is disabled.
Views
OSPF view
Predefined user roles
network-admin
Usage guidelines
Isolation is a method used for network device maintenance. It gracefully removes a device from the packet forwarding path for maintenance and gracefully adds the device to the network after maintenance.
To reduce impact on traffic forwarding, you can isolate a device before upgrading it. OSPF isolation works as follows:
1. After OSPF isolation is enabled for a device, OSPF increases the link cost in LSAs advertised by the device based on the following rules:
¡ The link cost in Type-1 LSAs (Router LSAs) is increased to 65535.
¡ The link cost in the following LSAs is increased to 16711680:
- Type-3 LSAs (Network summary LSAs).
- Type-5 LSAs (AS external LSAs).
- Type-7 LSAs (NSSA external LSAs).
2. Each neighbor of the device reselects an optimal route based on the LSAs and stops forwarding traffic to the device. The device is fully isolated from the network and you can upgrade the device.
3. After the maintenance, disable OSPF isolation on the device to restore its link cost and gracefully add it back to the network.
Both the isolate enable and stub-router external-lsa 16711680 summary-lsa 16711680 include-stub commands can isolate the device from the network.
When you execute both the isolate enable and stub-router commands, follow these restrictions and guidelines:
· If you specify the external-lsa and summary-lsa keywords in the stub-router command, the higher one of the two link costs provided by the isolation feature and the stub router feature takes effect.
· If the on-startup keyword is specified in the stub-router command, traffic forwarding path selection is affected only by the isolation feature when the stub router feature does not take effect.
Examples
# Isolate the device from the network in OSPF process 100.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] isolate enable
Related commands
stub-router
ispf enable
Use ispf enable to enable OSPF incremental SPF (ISPF).
Use undo ispf enable to disable OSPF ISPF.
Syntax
ispf enable
undo ispf enable
Default
OSPF ISPF is enabled.
Views
OSPF view
Predefined user roles
network-admin
Usage guidelines
Upon topology changes, ISPF recomputes only the affected part of the SPT, instead of the entire SPT.
Examples
# Disable ISPF for OSPF process 100.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] undo ispf enable
log-peer-change
Use log-peer-change to enable logging for OSPF neighbor state changes.
Use undo log-peer-change to disable logging for OSPF neighbor state changes.
Syntax
log-peer-change
undo log-peer-change
Default
Logging for OSPF neighbor state changes is enabled.
Views
OSPF view
Predefined user roles
network-admin
Usage guidelines
This command enables output of OSPF neighbor state changes to the information center. The information center processes the logs according to user-defined output rules (whether and where to output logs). For more information about the information center, see information center configuration in System Management Configuration Guide.
Examples
# Disable logging for neighbor state changes for OSPF process 100.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] undo log-peer-change
lsa-arrival-interval
Use lsa-arrival-interval to set the LSA arrival interval.
Use undo lsa-arrival-interval to restore the default.
Syntax
lsa-arrival-interval maximum-interval [ minimum-interval [ incremental-interval ] ]
undo lsa-arrival-interval
Default
The maximum interval, incremental interval, and minimum interval are 1000 milliseconds, 500 milliseconds, and 500 milliseconds, respectively.
Views
OSPF view
Predefined user roles
network-admin
Parameters
maximum-interval: Specifies the maximum LSA arrival interval in the range of 0 to 10000 milliseconds.
minimum-interval: Specifies the minimum LSA arrival interval in the range of 0 to 1000 milliseconds.
incremental-interval: Specifies the incremental LSA arrival interval in the range of 0 to 5000 milliseconds.
Usage guidelines
For a stable network, LSAs arrive at the minimum interval. If network changes become frequent, the LSA arrival interval increases by the incremental interval × 2n-2 for each arrival until the maximum interval is reached. The value n is the number of arrival times.
OSPF drops any duplicate LSAs within the LSA arrival interval. An LSA is a duplicate of a previous LSA if they have the same LSA type, LS ID, and router ID.
On a stable network that requires fast convergence, you can set the LSA arrival interval to 0. In this way, OSPF can learn the changes of the topology or routes immediately.
The minimum interval and the incremental interval cannot be greater than the maximum interval.
Examples
# Set the maximum, minimum, and incremental LSA arrival intervals to 2000 milliseconds, 100 milliseconds, and 300 milliseconds, respectively.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] lsa-arrival-interval 2000 100 300
lsa-generation-interval
lsa-arrival-interval suppress-flapping
Use lsa-arrival-interval suppress-flapping to suppress incoming LSAs during route flapping.
Use undo lsa-arrival-interval suppress-flapping to restore the default.
Syntax
lsa-arrival-interval suppress-flapping delay-interval [ threshold threshold-value ]
undo lsa-arrival-interval suppress-flapping
Default
Incoming LSAs are not suppressed during route flapping.
Views
OSPF view
Predefined user roles
network-admin
Parameters
delay-interval: Specifies the suppression interval, which is the minimum interval for accepting instances of the same LSA during route flapping. The value range is 0 to 65535 seconds.
threshold threshold-value: Specifies the suppression trigger threshold as the number of route flaps. When the number of route flaps reaches the threshold, OSPF suppresses instances of the same LSA. The value range for the threshold-value argument is 3 to 100. The default value is 5.
Usage guidelines
Instances of an LSA have the same LSA type, LS ID, and originating router ID.
If OSPF receives multiple instances of the same LSA during the suppression interval, OSPF discards all the instances except the first one.
Examples
# Configure OSPF to suppress incoming LSAs after 10 route flaps, and set the LSA suppression interval to 5 seconds.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] lsa-arrival-interval suppress-flapping 5 threshold 10
Related commands
lsa-arrival-interval
lsa-generation-interval
Use lsa-generation-interval to set the OSPF LSA update interval.
Use undo lsa-generation-interval to restore the default.
Syntax
lsa-generation-interval maximum-interval [ minimum-interval [ incremental-interval ] ]
undo lsa-generation-interval
Default
The maximum interval is 5 seconds, the minimum interval is 50 milliseconds, and the incremental interval is 200 milliseconds.
Views
OSPF view
Predefined user roles
network-admin
Parameters
maximum-interval: Specifies the maximum LSA update interval in the range of 1 to 60 seconds.
minimum-interval: Specifies the minimum LSA update interval in the range of 10 to 60000 milliseconds.
incremental-interval: Specifies the LSA update incremental interval in the range of 10 to 60000 milliseconds.
Usage guidelines
For a stable network, LSAs are generated at the minimum interval. If network changes become frequent, the LSA update interval increases by the incremental interval × 2n-2 for each update until the maximum interval is reached. The value n is the number of update times.
The minimum interval and the incremental interval cannot be greater than the maximum interval.
Examples
# Set the maximum LSA update interval to 2 seconds, minimum interval to 100 milliseconds, and incremental interval to 100 milliseconds.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] lsa-generation-interval 2 100 100
Related commands
lsa-arrival-interval
lsa-generation-interval suppress-flapping
Use lsa-generation-interval suppress-flapping to suppress the update of LSAs during route flapping.
Use undo lsa-generation-interval suppress-flapping to restore the default.
Syntax
lsa-generation-interval suppress-flapping delay-interval [ threshold threshold-value ]
undo lsa-generation-interval suppress-flapping
Default
The update of LSAs is not suppressed during route flapping.
Views
OSPF view
Predefined user roles
network-admin
Parameters
delay-interval: Specifies the suppression interval, which is the minimum interval for generating LSAs during route flapping. The value range is 0 to 65535 seconds.
threshold threshold-value: Specifies the suppression trigger threshold as the number of route flaps. When the number of route flaps reaches the threshold, OSPF suppresses the update of LSAs. The value range for the threshold-value argument is 3 to 100. The default value is 5.
Examples
# Configure OSPF to suppress the LSA update after 10 route flaps, and set the suppression interval to 3 seconds.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] lsa-generation-interval suppress-flapping 3 threshold 10
Related commands
lsa-generation-interval
lsdb-overflow-interval
Use lsdb-overflow-interval to set the interval that OSPF exits overflow state.
Use undo lsdb-overflow-interval to restore the default.
Syntax
lsdb-overflow-interval interval
undo lsdb-overflow-interval
Default
The OSPF exit overflow interval is 300 seconds.
Views
OSPF view
Predefined user roles
network-admin
Parameters
interval: Specifies the interval that OSPF exits overflow state, in the range of 0 to 2147483647 seconds.
Usage guidelines
When the number of LSAs in the LSDB exceeds the upper limit, the LSDB is in an overflow state. In this state, OSPF does not receive any external LSAs and deletes the external LSAs generated by itself to save system resources.
You can configure the interval that OSPF exits overflow state. An interval of 0 indicates that the timer is not started and OSPF does not exit overflow state.
Examples
# Set the OSPF exit overflow interval to 10 seconds.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] lsdb-overflow-interval 10
lsdb-overflow-limit
Use lsdb-overflow-limit to set the upper limit of external LSAs in the LSDB.
Use undo lsdb-overflow-limit to restore the default.
Syntax
lsdb-overflow-limit number
undo lsdb-overflow-limit
Default
The number of external LSAs is not limited.
Views
OSPF view
Predefined user roles
network-admin
Parameters
number: Specifies the upper limit of external LSAs in the LSDB, in the range of 1 to 1000000.
Examples
# Set the upper limit of external LSAs to 400000.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] lsdb-overflow-limit 400000
maxage-lsa route-calculate-delay
Use maxage-lsa route-calculate-delay to set the delay for route calculation triggered by router LSAs with max age.
Use undo maxage-lsa route-calculate-delay to restore the default.
Syntax
maxage-lsa route-calculate-delay delay-interval
undo maxage-lsa route-calculate-delay
Default
The delay is 10 seconds for route calculation triggered by router LSAs with max age.
Views
OSPF view
Predefined user roles
network-admin
Parameters
delay-interval: Specifies the delay for route calculation triggered by router LSAs with max age, in the range of 0 to 65535 seconds.
Usage guidelines
When a router receives a router LSA with max age, it immediately computes routes with the SPF algorithm rather than with the router LSA. During route flapping, such a route calculation can make the situation worse. You can use this command to suppress frequent route flaps by setting the routing calculation delay.
Examples
# Set the delay to 20 seconds for route calculation triggered by router LSAs with max age.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] maxage-lsa route-calculate-delay 20
maximum load-balancing
Use maximum load-balancing to set the maximum number of equal-cost multi-path (ECMP) routes for load balancing.
Use undo maximum load-balancing to restore the default.
Syntax
maximum load-balancing number
undo maximum load-balancing
Default
The maximum number of OSPF ECMP routes equals the maximum number of ECMP routes supported by the system.
Views
OSPF view
Predefined user roles
network-admin
Parameters
number: Specifies the maximum number of ECMP routes. No ECMP load balancing is available when the number is set to 1. The value range for this argument is 1 to 32.
Usage guidelines
You can use the max-ecmp-num command to set the maximum number of ECMP routes supported by the system to m. After a reboot, the value range for the number argument of the maximum load-balancing command is 1 to m.
Examples
# Set the maximum number of ECMP routes to 2.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] maximum load-balancing 2
Related commands
max-ecmp-num (Network Connectivity Command Reference)
network
Use network to enable OSPF on the interface attached to the specified network in the area.
Use undo network to disable OSPF for the interface attached to the specified network in the area.
Syntax
network ip-address wildcard-mask
undo network ip-address wildcard-mask
Default
OSPF is not enabled for any interface.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
ip-address: Specifies the IP address of a network.
wildcard-mask: Specifies the wildcard mask of the IP address. For example, the wildcard mask of mask 255.0.0.0 is 0.255.255.255.
Usage guidelines
This command enables OSPF on the interface attached to the specified network. The interface's primary IP address must be in the specified network. If only the interface's secondary IP address is on the network, the interface cannot run OSPF.
Examples
# Specify the interface whose primary IP address is on network 131.108.20.0/24 to run OSPF in Area 2.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 2
[Sysname-ospf-100-area-0.0.0.2] network 131.108.20.0 0.0.0.255
ospf
nssa
Use nssa to configure an area as an NSSA area.
Use undo nssa to restore the default.
Syntax
nssa [ default-route-advertise [ cost cost-value | nssa-only | type type ] * | no-import-route | no-summary | suppress-fa | [ [ [ translate-always ] [ translate-ignore-checking-backbone ] ] | translate-never ] | translator-stability-interval value ] *
undo nssa [ default-route-advertise [ cost | nssa-only | type ] * | no-import-route | no-summary | suppress-fa | [ translate-always | translate-never ] | translator-stability-interval ] *
Default
No area is configured as an NSSA area.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
default-route-advertise: Used on an NSSA ABR or an ASBR only. With this keyword, an NSSA ABR redistributes a default route in a Type-7 LSA into the NSSA area. The ABR redistributes a default route regardless of whether a default route exists in the routing table. With this keyword, an ASBR redistributes a default route in a Type-7 LSA only when the default route exists in the routing table.
cost cost-value: Specifies a cost for the default route, in the range of 0 to 16777214. If you do not specify this option, the default cost specified by the default-cost command applies.
nssa-only: Limits the default route advertisement to the NSSA area by setting the P-bit of Type-7 LSAs to 0. By default, the P-bit of Type-7 LSAs is set to 1. If the router acts as both an ASBR and an ABR and FULL state neighbors exist in the backbone area, the P-bit is set to 0.
type type: Specifies a type for the Type-7 LSA, 1 or 2. If you do not specify this option, the default type specified by the default type command applies.
no-import-route: Used on an NSSA ABR to control the import-route command to not redistribute routes into the NSSA area.
no-summary: Used only on an ABR to advertise a default route in a Type-3 summary LSA into the NSSA area and to not advertise other summary LSAs into the area. The area is a totally NSSA area.
suppress-fa: Suppresses the forwarding address in the Type-7 LSAs from being placed in the Type-5 LSAs.
translate-always: Always translates Type-7 LSAs to Type-5 LSAs. This keyword takes effect only on an NSSA ABR.
translate-ignore-checking-backbone: Ignores checking for FULL state neighbors in the backbone area during the translator election in the NSSA area.
translate-never: Never translates Type-7 LSAs to Type-5 LSAs. This keyword takes effect only on an NSSA ABR.
translator-stability-interval value: Specifies the stability interval of the translator. During the interval, the translator can maintain its translating capability after another device becomes the new translator. The value argument is the stability interval in the range of 0 to 900 seconds and defaults to 0. A value of 0 means the translator does not maintain its translating capability when a new translator arises.
Usage guidelines
All routers attached to an NSSA area must be configured with the nssa command in area view.
If you specify the translate-ignore-checking-backbone keyword for an ABR, you must also specify the keyword for other ABRs in the NSSA area. This ensures that a translator can be elected among the ABRs.
Examples
# Configure Area 1 as an NSSA area.
[Sysname] ospf 100
[Sysname-ospf-100] area 1
[Sysname-ospf-100-area-0.0.0.1] nssa
default-cost (OSPF area view)
opaque-capability enable
Use opaque-capability enable to enable opaque LSA advertisement and reception.
Use undo opaque-capability to disable opaque LSA advertisement and reception.
Syntax
opaque-capability enable
undo opaque-capability
Default
The feature is enabled.
Views
OSPF view
Predefined user roles
network-admin
Usage guidelines
After the opaque LSA advertisement and reception capability is enabled, OSPF can receive and advertise Type-9, Type-10, and Type-11 opaque LSAs.
Examples
# Disable opaque LSA advertisement and reception.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] undo opaque-capability
ospf
Use ospf to enable OSPF and enter OSPF view.
Use undo ospf to disable OSPF.
Syntax
ospf [ process-id | router-id { auto-select | router-id } ] *
undo ospf [ process-id ] [ router-id ]
Default
OSPF is disabled.
Views
System view
Predefined user roles
network-admin
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535.
router-id: Specifies an OSPF router ID. If you do not specify an OSPF router ID, the global router ID is used.
auto-select: Automatically obtains an OSPF router ID.
router-id: Manually specifies an OSPF router ID in dotted decimal notation. The value range is from 0.0.0.1 to 255.255.255.255.
Usage guidelines
You can enable multiple OSPF processes on a router and specify different router IDs for them.
Enable an OSPF process before performing other tasks.
If you specify the auto-select keyword, the OSPF process obtains a router ID in the following ways:
· During the startup of the OSPF process, the primary IPv4 address of the first interface that runs the process is specified as the router ID.
· During the reboot of the router, the primary IPv4 address of the first interface that runs the process is specified as the router ID.
· During the restart of the OSPF process, the highest primary IPv4 address of the loopback interface that runs the process is specified as the router ID. If no loopback address is available, the highest primary IPv4 address of the interface that runs the process is used, regardless of the interface state (up or down).
If you do not specify the router-id keyword, the undo ospf command shuts down an OSPF process. If you specify the router-id keyword, the undo ospf command specifies the global router ID as the router ID. The setting takes effect after the OSPF process restarts.
Examples
# Enable OSPF process 100 and specify router ID 10.10.10.1.
<Sysname> system-view
[Sysname] ospf 100 router-id 10.10.10.1
[Sysname-ospf-100]
ospf area
Use ospf area to enable OSPF on an interface.
Use undo ospf area to disable OSPF on an interface.
Syntax
ospf process-id area area-id [ exclude-subip ]
undo ospf process-id area [ exclude-subip ]
Default
OSPF is not enabled on an interface.
Views
Interface view
Predefined user roles
network-admin
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535.
area-id: Specifies an area by its ID, an IP address or a decimal integer in the range of 0 to 4294967295 that is translated into the IP address format.
exclude-subip: Excludes secondary IP addresses. If you do not specify this keyword, the command enables OSPF also on secondary IP addresses.
Usage guidelines
The ospf area command has a higher priority than the network command.
If the specified process and area do not exist, the command creates the process and area. Disabling an OSPF process on an interface does not delete the OSPF process or the area.
Examples
# Enable OSPF process 1 on VLAN-interface 10 that is in Area 2 and exclude secondary IP addresses.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf 1 area 2 exclude-subip
Related commands
network
ospf authentication-mode
Use ospf authentication-mode to set the authentication mode and key on an interface.
Use undo ospf authentication-mode to remove specified configuration.
Syntax
For MD5/HMAC-MD5/HMAC-SHA-256 authentication:
ospf authentication-mode { hmac-md5 | hmac-sha-256 | md5 } key-id { cipher | plain } string
undo ospf authentication-mode { hmac-md5 | hmac-sha-256 | md5 } key-id
For simple authentication:
ospf authentication-mode simple { cipher | plain } string
undo ospf authentication-mode simple
Default
No authentication is performed for an interface.
Views
Interface view
Predefined user roles
network-admin
Parameters
hmac-md5: Specifies HMAC-MD5 authentication.
hmac-sha-256: Specifies HMAC-SHA-256 authentication.
md5: Specifies MD5 authentication.
simple: Specifies simple authentication.
key-id: Specifies a key by its ID in the range of 1 to 255.
cipher: Specifies a key in encrypted form.
plain: Specifies a key in plaintext form. For security purposes, the key specified in plaintext form will be stored in encrypted form.
string: Specifies the key. This argument is case sensitive.
· In simple authentication mode, the plaintext form of the key is a string of 1 to 8 characters. The encrypted form of the key is a string of 33 to 41 characters.
· In MD5/HMAC-MD5 authentication mode, the plaintext form of the key is a string of 1 to 16 characters. The encrypted form of the key is a string of 33 to 53 characters.
· In HMAC-SHA-256 authentication mode, the plaintext form of the key is a string of 1 to 255 characters. The encrypted form of the key is a string of 33 to 373 characters.
Usage guidelines
To establish or maintain adjacencies, interfaces attached to the same network segment must have the same authentication mode and key.
If MD5, HMAC-MD5, or HMAC-SHA-256 authentication is configured, you can configure multiple keys, each having a unique key ID and key string. To minimize the risk of key compromise, use only one key for an interface and delete the old key after key replacement.
To replace the key used for MD5, HMAC-MD5, or HMAC-SHA-256 authentication on an interface, you must configure the new key before removing the old key from each router. OSPF uses the key rollover mechanism to ensure that the routers can pass authentication before the replacement is complete on the interface. After you configure a new key on a router, the router sends copies of the same packet, each authenticated by a different key, including the new key and the keys in use. This practice continues until the router detects that all its neighbors have the new key.
Examples
# On VLAN-interface 10, enable MD5 authentication, and set the interface key ID to 15 and the key to 123456 in plaintext form.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf authentication-mode md5 15 plain 123456
# On VLAN-interface 10, enable simple authentication, and set the key to 123456 in plaintext form.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf authentication-mode simple plain 123456
authentication-mode
ospf cost
Use ospf cost to set an OSPF cost for an interface.
Use undo ospf cost to restore the default.
Syntax
ospf cost cost-value
undo ospf cost
Default
An interface computes its OSPF cost according to the interface bandwidth. For a loopback interface, the cost is 0.
Views
Interface view
Predefined user roles
network-admin
Parameters
cost-value: Specifies an OSPF cost in the range of 0 to 65535 for a loopback interface, and in the range of 1 to 65535 for other interfaces.
Usage guidelines
If you do not execute this command, the interface automatically computes its OSPF cost.
Examples
# Set the OSPF cost on VLAN-interface 10 to 65.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf cost 65
Related commands
bandwidth-reference
ospf database-filter
Use ospf database-filter to filter outbound LSAs on an interface.
Use undo ospf database-filter to restore the default.
Syntax
ospf database-filter { all | { ase [ acl ipv4-acl-number ] | nssa [ acl ipv4-acl-number ] | summary [ acl ipv4-acl-number ] } * }
undo ospf database-filter
Default
The outbound LSAs are not filtered on the interface.
Views
Interface view
Predefined user roles
network-admin
Parameters
all: Filters all outbound LSAs except the Grace LSAs.
ase: Filters outbound Type-5 LSAs.
nssa: Filters outbound Type-7 LSAs.
summary: Filters outbound Type-3 LSAs.
acl ipv4-acl-number: Specifies an IPv4 ACL by its number in the range of 2000 to 3999.
Usage guidelines
If the specified ACL does not exist or has no rules, OSPF does not filter outbound LSAs.
To use an advanced ACL (with a number from 3000 to 3999) in the command, configure the ACL using one of the following methods:
· To deny/permit LSAs with the specified link state ID, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard command.
· To deny/permit LSAs with the specified link state ID and mask, use the rule [ rule-id ] { deny | permit } ip source sour-addr sour-wildcard destination dest-addr dest-wildcard command.
The source keyword specifies the link state ID of an LSA and the destination keyword specifies the subnet mask of the LSA. For the mask configuration to take effect, specify a contiguous subnet mask.
If the neighbor has already received an LSA to be filtered, the LSA still exists in the LSDB of the neighbor after you execute the command.
Examples
# Filter all outbound LSAs (except the Grace LSAs) on VLAN-interface 10.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf database-filter all
# On VLAN-interface 20, configure ACL 2000, 2100, and 2200 to filter outbound Type-5, Type-7, and Type-3 LSAs, respectively.
<Sysname> system-view
[Sysname] interface vlan-interface 20
[Sysname- Vlan-interface20] ospf database-filter ase acl 2000 nssa acl 2100 summary acl 2200
Related commands
database-filter peer (OSPF view)
ospf dr-priority
Use ospf dr-priority to set the router priority for DR/BDR election on an interface.
Use undo ospf dr-priority to restore the default value.
Syntax
ospf dr-priority priority
undo ospf dr-priority
Default
The router priority is 1.
Views
Interface view
Predefined user roles
network-admin
Parameters
priority: Specifies the router priority for the interface, in the range of 0 to 255.
Usage guidelines
The greater the value, the higher the priority for DR/BDR election. If a device has a priority of 0, it will not be elected as a DR or BDR.
Examples
# Set the router priority on VLAN-interface 10 to 8.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf dr-priority 8
ospf fast-reroute lfa-backup
Use ospf fast-reroute lfa-backup to enable LFA on an interface.
Use undo ospf fast-reroute lfa-backup to disable LFA on an interface.
Syntax
ospf fast-reroute lfa-backup
undo ospf fast-reroute lfa-backup
Default
LFA is enabled on an interface.
Views
Interface view
Predefined user roles
network-admin
Usage guidelines
An interface enabled with LFA can be selected as a backup interface. After you disable LFA on the interface, it cannot be selected as a backup interface.
Examples
# Disable VLAN-interface 11 from calculating a backup next hop by using the LFA algorithm.
<Sysname> system-view
[Sysname] interface vlan-interface 11
[Sysname-Vlan-interface11] undo ospf fast-reroute lfa-backup
ospf link-quality adjust-cost
Use ospf link-quality adjust-cost to enable OSPF to adjust the interface cost according to the link quality.
Use undo ospf link-quality adjust-cost to restore the default.
Syntax
ospf link-quality adjust-cost { cost-offset | max }
undo ospf link-quality adjust-cost
Default
OSPF does not adjust the interface cost according to the link quality.
Views
Interface view
Predefined user roles
network-admin
Parameters
cost-offset: Specifies the value to be added to the interface cost when the link quality changes to LOW. The value range for this argument is 1 to 65534. When the link quality changes to LOW, the interface cost is cost-offset plus the original interface cost, and cannot exceed 65535.
max: Sets the interface cost to the maximum value 65535 when the link quality changes to LOW.
Usage guidelines
Error codes, which refer to bit differences between the received and source signals, cannot be avoided because of inevitable link aging and optical path jitter problems. A high error code ratio might cause service degradation or interruption.
To reduce the impact of error codes on an OSPF network, you can enable OSPF to adjust the interface cost according to the link quality.
After you configure this command on an interface, OSPF adjusts the interface cost as follows:
· When the link quality of the interface becomes LOW, OSPF increases the cost value for the interface.
· When the link quality of the interface restores to GOOD, OSPF restores the cost value for the interface.
Examples
# Enable OSPF to adjust the cost of interface VLAN-interface 10 according to the link quality, and set the value to be added to the interface cost to 200.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf link-quality adjust-cost 200
ospf mib-binding
Use ospf mib-binding to bind an OSPF process to MIB.
Use undo ospf mib-binding to restore the default.
Syntax
ospf mib-binding process-id
undo ospf mib-binding
Default
MIB is bound to the OSPF process with the smallest process ID.
Views
System view
Predefined user roles
network-admin
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535.
Usage guidelines
To access information or data about an OSPF process in RFC4750-OSPF.MIB, use this command. To access information or data about an OSPF process in a Comware MIB for the device, you do not need to use this command. You can access information or data about all OSPF processes in the Comware MIBs.
If the specified process ID does not exist, a notification is displayed to report that the MIB binding configuration has failed.
Deleting an OSPF process that has been bound to MIB unbinds the OSPF process from MIB, and re-binds MIB to the OSPF process with the smallest process ID.
Examples
# Bind OSPF process 100 to MIB.
<Sysname> system-view
[Sysname] ospf mib-binding 100
ospf mtu-enable
Use ospf mtu-enable to enable an interface to add the interface MTU into DD packets.
Use undo ospf mtu-enable to restore the default.
Syntax
ospf mtu-enable
undo ospf mtu-enable
Default
The MTU in DD packets is 0.
Views
Interface view
Predefined user roles
network-admin
Usage guidelines
After a virtual link is established through a Tunnel, two devices on the link from different vendors might have different MTU values. To make them consistent, restore the interfaces' MTU to the default value 0.
After you configure this command, the interface checks whether the MTU in a received DD packet is greater than its own MTU. If yes, the interface discards the packet.
Examples
# Enable VLAN-interface 10 to add the interface MTU value into DD packets.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf mtu-enable
ospf network-type
Use ospf network-type to specify the network type for an interface.
Use undo ospf network-type to restore the default.
Syntax
ospf network-type { broadcast | nbma | p2mp [ unicast ] | p2p [ peer-address-check ] }
undo ospf network-type
Default
The network type of an OSPF interface is broadcast.
Views
Interface view
Predefined user roles
network-admin
Parameters
broadcast: Specifies the network type as broadcast.
nbma: Specifies the network type as NBMA.
p2mp: Specifies the network type as P2MP.
unicast: Specifies the P2MP interface to unicast OSPF packets. By default, a P2MP interface multicasts OSPF packets.
p2p: Specifies the network type as P2P.
peer-address-check: Checks whether the peer interface and the local interface are on the same network segment. Two P2P interfaces can establish a neighbor relationship only when they are on the same network segment.
Usage guidelines
If a router on a broadcast network does not support multicast, configure the network type for the connected interfaces as NBMA.
If any two routers on an NBMA network are directly connected through a virtual link, the network is fully meshed. You can configure the network type for the connected interfaces as NBMA. If two routers are not directly connected, configure the P2MP network type so that the two routers can exchange routing information through another router.
When the network type of an interface is NBMA or P2MP unicast, you must use the peer command to specify the neighbor.
If only two routers run OSPF on a network, you can configure the network type for the connected interfaces as P2P.
When the network type of an interface is P2MP unicast, all OSPF packets are unicast by the interface.
Examples
# Specify the OSPF network type for VLAN-interface 10 as NBMA.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf network-type nbma
ospf dr-priority
ospf packet-size
Use ospf packet-size to set the maximum length of OSPF packets that can be sent by an interface.
Use undo ospf packet-size to restore the default.
Syntax
ospf packet-size value
undo ospf packet-size
Default
The maximum length of OSPF packets that an interface can send equals the interface's MTU.
Views
Interface view
Predefined user roles
network-admin
Parameters
value: Specifies the maximum length of OSPF packets that can be sent by an interface, in the range of 500 to 10000 bytes.
Usage guidelines
The interface chooses the smaller one between the value set in this command and the interface MTU, and uses it as the maximum length of OSPF packets that can be sent.
When you establish OSPF neighbors over a tunnel, you can use this command to prevent OSPF packet fragmentation on the outgoing tunnel interface. Make sure the maximum length of OSPF packets plus the encapsulated header length is no greater than the outgoing tunnel interface's MTU. For more information about tunnel interfaces, see tunnel interface configuration in Interface Configuration Guide.
Examples
# Set the maximum length of OSPF packets that can be sent by VLAN-interface 10.
<Sysname> system-view
[Sysname] interface vlan 10
[Sysname-Vlan-interface10] ospf packet-size 1000
ospf prefix-suppression
Use ospf prefix-suppression to disable an OSPF interface from advertising all its IP prefixes, except for the prefixes of secondary IP addresses.
Use undo ospf prefix-suppression to restore the default.
Syntax
ospf prefix-suppression [ disable ]
undo ospf prefix-suppression
Default
Prefix suppression is disabled.
Views
Interface view
Predefined user roles
network-admin
Parameters
disable: Disables prefix suppression for an interface.
Usage guidelines
To disable prefix suppression for an interface associated with an OSPF process that has been enabled with prefix suppression, use the ospf prefix-suppression disable command on that interface.
Examples
# Enable prefix suppression for VLAN-interface 10.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf prefix-suppression
Related commands
prefix-suppression
ospf timer dead
Use ospf timer dead to set the neighbor dead interval.
Use undo ospf timer dead to restore the default.
Syntax
ospf timer dead seconds
undo ospf timer dead
Default
The dead interval is 40 seconds for broadcast and P2P interfaces. The dead interval is 120 seconds for P2MP and NBMA interfaces.
Views
Interface view
Predefined user roles
network-admin
Parameters
seconds: Specifies the dead interval in the range of 1 to 2147483647 seconds.
Usage guidelines
If an interface receives no hello packet from a neighbor within the dead interval, the interface considers the neighbor down.
The dead interval on an interface is a minimum of four times the hello interval. Routers attached to the same segment must have the same dead interval.
Examples
# Set the dead interval for VLAN-interface 10 to 60 seconds.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf timer dead 60
ospf timer hello
ospf timer hello
Use ospf timer hello to set the hello interval on an interface.
Use undo ospf timer hello to restore the default.
Syntax
ospf timer hello seconds
undo ospf timer hello
Default
The hello interval is 10 seconds for P2P and broadcast interfaces, and is 30 seconds for P2MP and NBMA interfaces.
Views
Interface view
Predefined user roles
network-admin
Parameters
seconds: Specifies the hello interval in the range of 1 to 65535 seconds.
Usage guidelines
The shorter the hello interval, the faster the topology converges, and the more resources are consumed. Make sure the hello interval on two neighboring interfaces is the same.
Examples
# Set the hello interval on VLAN-interface to 20 seconds.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf timer hello 20
ospf timer dead
ospf timer poll
Use ospf timer poll to set the poll interval on an NBMA interface.
Use undo ospf timer poll to restore the default.
Syntax
ospf timer poll seconds
undo ospf timer poll
Default
The poll interval is 120 seconds on an interface.
Views
Interface view
Predefined user roles
network-admin
Parameters
seconds: Specifies the poll interval in the range of 1 to 2147483647 seconds.
Usage guidelines
When an NBMA interface finds its neighbor is down, it sends hello packets at the poll interval.
The poll interval must be a minimum of four times the hello interval.
Examples
# Set the poll timer interval on VLAN-interface 10 to 130 seconds.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf timer poll 130
ospf timer hello
ospf timer retransmit
Use ospf timer retransmit to set the LSA retransmission interval on an interface.
Use undo ospf timer retransmit to restore the default.
Syntax
ospf timer retransmit seconds
undo ospf timer retransmit
Default
The LSA retransmission interval is 5 seconds on an interface.
Views
Interface view
Predefined user roles
network-admin
Parameters
seconds: Specifies the LSA retransmission interval in the range of 1 to 3600 seconds.
Usage guidelines
After sending an LSA, an interface waits for an acknowledgment packet. If the interface receives no acknowledgment within the retransmission interval, it retransmits the LSA.
To avoid unnecessary retransmissions, set an appropriate retransmission interval. For example, you can set a large retransmission interval value on a low-speed link.
Examples
# Set the LSA retransmission interval to 8 seconds on VLAN-interface 10.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf timer retransmit 8
ospf ttl-security
Use ospf ttl-security to enable OSPF GTSM for an interface.
Use ospf ttl-security disable to disable OSPF GTSM for an interface.
Use undo ospf ttl-security to restore the default.
Syntax
ospf ttl-security [ hops hop-count | disable ]
undo ospf ttl-security
Default
An interface uses the GTSM configuration of the area to which the interface belongs.
Views
Interface view
Predefined user roles
network-admin
Parameters
hops hop-count: Specifies the hop limit for checking OSPF packets, in the range of 1 to 254. The default hop limit is 1 for packets from common neighbors and 255 for packets from virtual link neighbors.
disable: Disables OSPF GTSM for the interface.
Usage guidelines
GTSM checks OSPF packets from common neighbors and virtual link neighbors.
GTSM protects the device by comparing the TTL value in the IP header of incoming OSPF packets against a valid TTL range. If the TTL value is within the valid TTL range, the packet is accepted. If not, the packet is discarded.
The valid TTL range is from 255 – the configured hop count + 1 to 255.
When GTSM is configured, the OSPF packets sent by the device have a TTL of 255. To use GTSM, you must configure GTSM on both the local and peer devices. You can specify different hop-count values for them.
The GTSM configuration in OSPF area view applies to all OSPF interfaces in the area. The GTSM configuration in interface view takes precedence over the configuration in OSPF area view.
If a virtual link exists in an area, you can enable GTSM for the interfaces on the virtual link. If you do not know the interfaces on the virtual link, enable GTSM in area view to prevent packet loss.
Examples
# Enable OSPF GTSM for VLAN-interface 10 and set the hop limit to 254.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf ttl-security hops 254
Related commands
ttl-security
ospf trans-delay
Use ospf trans-delay to set the LSA transmission delay on an interface.
Use undo ospf trans-delay to restore the default.
Syntax
ospf trans-delay seconds
undo ospf trans-delay
Default
The LSA transmission delay is 1 second.
Views
Interface view
Predefined user roles
network-admin
Parameters
seconds: Specifies the LSA transmission delay in the range of 1 to 3600 seconds.
Usage guidelines
Each LSA in the LSDB has an age that increases by 1 every second, but the age does not change during transmission. Adding a transmission delay into the age time is important in low speed networks.
Examples
# Set the LSA transmission delay to 3 seconds on VLAN-interface 10.
<Sysname> system-view
[Sysname] interface vlan-interface 10
[Sysname-Vlan-interface10] ospf trans-delay 3
peer
Use peer to specify a neighbor in an NBMA or P2MP network.
Use undo peer to remove a neighbor in an NBMA or P2MP network.
Syntax
peer ip-address [ cost cost-value | dr-priority priority ]
undo peer ip-address
Default
No neighbor is specified.
Views
OSPF view
Predefined user roles
network-admin
Parameters
ip-address: Specifies a neighbor by its IP address.
cost cost-value: Specifies the cost to reach the neighbor, in the range of 1 to 65535.
dr-priority priority: Specifies the DR priority for the neighbor, in the range of 0 to 255. The default neighbor DR priority is 1.
Usage guidelines
On an NBMA or P2MP network, OSPF packets are sent in unicast, so you must use this command to specify neighbors.
The cost set with the peer command applies only to P2MP neighbors. If no cost is specified, the cost to the neighbor equals the local interface's cost.
A router uses the priority set with the peer command to determine whether to send a hello packet to the neighbor rather than for DR election. The DR priority set with the ospf dr-priority command is used for DR election.
Examples
# Specify the neighbor 1.1.1.1.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] peer 1.1.1.1
ospf dr-priority
pic
Use pic to enable OSPF PIC.
Use undo pic to disable OSPF PIC.
Syntax
pic [ additional-path-always ]
undo pic
Default
OSPF PIC is enabled.
Views
OSPF view
Predefined user roles
network-admin
Parameters
additional-path-always: Allows the indirect suboptimal route as the backup route.
Usage guidelines
Prefix Independent Convergence (PIC) enables the device to speed up network convergence by ignoring the number of prefixes. PIC applies only to inter-area routes and external routes.
When both OSPF PIC and OSPF FRR are configured, OSPF FRR takes effect.
Examples
# Configure OSPF PIC to support the suboptimal route as the backup route.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] pic additional-path-always
preference
Use preference to set a preference for OSPF.
Use undo preference to remove the configuration.
Syntax
preference [ ase ] { preference } *
undo preference [ ase ]
Default
The preference is 10 for OSPF internal routes and 150 for OSPF external routes (ASE routes).
Views
OSPF view
Predefined user roles
network-admin
Parameters
ase: Specifies a preference for OSPF external routes. If you do not specify this keyword, the command sets a preference for OSPF internal routes.
preference: Specifies the preference value in the range of 1 to 255. A smaller value represents a higher preference.
Usage guidelines
If multiple routing protocols find routes to the same destination, the router uses the route found by the protocol with the highest preference.
Examples
# Set a preference of 200 for OSPF external routes.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] preference ase 200
prefix-suppression
Use prefix-suppression to disable an OSPF process from advertising all IP prefixes except for the prefixes of loopback interfaces, secondary IP addresses, and passive interfaces.
Use undo prefix-suppression to restore the default.
Syntax
prefix-suppression
undo prefix-suppression
Default
An OSPF process advertises all prefixes.
Views
OSPF view
Predefined user roles
network-admin
Usage guidelines
By default, an OSPF interface advertises all of its prefixes in LSAs. To speed up OSPF convergence, you can suppress interfaces from advertising all their prefixes. This feature helps improve network security by preventing IP routing to the suppressed networks.
As a best practice, configure prefix suppression on all OSPF routers if you want to use prefix suppression.
To disable an OSPF process from advertising the prefixes of loopback and passive interfaces, configure prefix suppression on the interfaces by using the ospf prefix-suppression command.
When prefix suppression is enabled:
· On P2P and P2MP networks, OSPF does not advertise Type-3 links in Type-1 LSAs. Other routing information can still be advertised to ensure traffic forwarding.
· On broadcast and NBMA networks, the DR generates Type-2 LSAs with a mask length of 32 to suppress network routes. Other routing information can still be advertised to ensure traffic forwarding. If no neighbors exist, the DR also does not advertise the primary IP addresses of interfaces in Type-1 LSAs.
Examples
# Enable prefix suppression for OSPF process 1.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] prefix-suppression
Related commands
ospf prefix-suppression
reset ospf event-log
Use reset ospf event-log to clear OSPF log information.
Syntax
reset ospf [ process-id ] event-log [ lsa-flush | lsa-history | peer | route | spf ]
Views
User view
Predefined user roles
network-admin
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command clears OSPF log information for all OSPF processes.
lsa-flush: Clears LSA aging log information.
lsa-history: Clears self-originated and received LSA log information.
peer: Clears neighbor state change log information.
route: Clears OSPF route log information.
spf: Clears route calculation log information.
Usage guidelines
If you do not specify a log type, this command clears all log information.
Examples
# Clear OSPF route calculation log information for all OSPF processes.
<Sysname> reset ospf event-log spf
Related commands
display ospf event-log
reset ospf event-log hello
Use reset ospf event-log hello to clear log information about received or sent OSPF hello packets.
Syntax
reset ospf [ process-id ] event-log hello { received [ abnormal | dropped ] | sent [ abnormal | failed ] }
Views
User view
Predefined user roles
network-admin
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify this argument, the command clears log information about received or sent hello packets for all OSPF processes.
received: Specifies log information about received hello packets.
sent: Specifies log information about sent hello packets.
abnormal: Specifies log information about abnormal hello packets that are received or sent at intervals greater than or equal to 1.5 times the hello interval.
dropped: Specifies log information about discarded inbound hello packets.
failed: Specifies log information about hello packets that failed to be sent.
Examples
# Clear log information about sent hello packets for all OSPF processes.
<Sysname> reset ospf event-log hello sent
Related commands
display ospf event-log hello
reset ospf process
Use reset ospf process to restart all OSPF processes or a specified process.
Syntax
reset ospf [ process-id ] process [ graceful-restart ]
Views
User view
Predefined user roles
network-admin
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify a process, this command restarts all OSPF processes.
graceful-restart: Resets the OSPF process by using GR.
Usage guidelines
The reset ospf process command performs the following actions:
· Clears all invalid LSAs without waiting for their timeouts.
· Makes a newly configured router ID take effect.
· Starts a new DR/BDR election.
· Keeps previous OSPF configurations.
The system prompts you to select whether to restart OSPF process upon execution of this command.
Examples
# Restart all OSPF processes.
<Sysname> reset ospf process
Reset OSPF process? [Y/N]:y
reset ospf redistribution
Use reset ospf redistribution to restart route redistribution.
Syntax
reset ospf [ process-id ] redistribution
Views
User view
Predefined user roles
network-admin
Parameters
process-id: Specifies an OSPF process by its ID in the range of 1 to 65535. If you do not specify a process, this command restarts route redistribution for all OSPF processes.
Examples
# Restart route redistribution.
<Sysname> reset ospf redistribution
reset ospf statistics
Use reset ospf statistics to clear OSPF statistics.
Syntax
reset ospf [ process-id ] statistics
Views
User view
Predefined user roles
network-admin
Parameters
process-id: Clears the statistics for an OSPF process specified by its ID in the range of 1 to 65535.
Examples
# Clear OSPF statistics for all processes.
<Sysname> reset ospf statistics
Related commands
display ospf statistics
rfc1583 compatible
Use rfc1583 compatible to enable compatibility with RFC 1583.
Use undo rfc1583 compatible to disable compatibility with RFC 1583.
Syntax
rfc1583 compatible
undo rfc1583 compatible
Default
Compatibility with RFC 1583 is enabled.
Views
OSPF view
Predefined user roles
network-admin
Usage guidelines
RFC 1583 specifies a different method than RFC 2328 for selecting the optimal route to a destination in another AS. When multiple routes are available to the ASBR, OSPF selects the optimal route by using the following procedure:
1. Selects the route with the highest preference.
¡ If RFC 2328 is compatible with RFC 1583, all these routes have equal preference.
¡ If RFC 2328 is not compatible with RFC 1583, the intra-area route in a non-backbone area is preferred to reduce the burden of the backbone area. The inter-area route and intra-area route in the backbone area have equal preference.
2. Selects the route with lower cost if two routes have equal preference.
3. Selects the route with larger originating area ID if two routes have equal cost.
To avoid routing loops, set identical RFC 1583-compatibility on all routers in a routing domain.
Examples
# Disable compatibility with RFC 1583.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] undo rfc1583 compatible
router id
Use router id to configure a global router ID.
Use undo router id to restore the default.
Syntax
router id router-id
undo router id
Default
No global router ID is configured.
Views
System view
Predefined user roles
network-admin
Parameters
router-id: Specifies the router ID in dotted decimal format. The value range for this argument is 0.0.0.1 to 255.255.255.254.
Usage guidelines
OSPF uses a router ID to identify a device. If no router ID is specified, the global router ID is used.
If no global router ID is configured, the highest loopback interface IP address is used as the router ID. If no loopback interface IP address is available, the highest physical interface IP address is used, regardless of the interface status (up or down).
During an active/standby switchover, the new active main processing unit (MPU) checks whether the previously backed up router ID is valid. If not, it selects a new router ID.
A new router ID is selected only when the interface IP address used as the router ID is removed or changed. Other events will not trigger a router ID re-selection. For example, router ID re-selection is not triggered in the following situations:
· The interface goes down.
· You change the router ID to the address of a loopback interface after a physical interface address is selected as the router ID.
· A higher interface IP address is configured as the router ID.
After a router ID is changed, you must use the reset command to enable it.
Examples
# Configure a global router ID as 1.1.1.1.
<Sysname> system-view
[Sysname] router id 1.1.1.1
shutdown process
Use shutdown process to shut down an OSPF process.
Use undo shutdown process to restart an OSPF process.
Syntax
shutdown process
undo shutdown process
Default
An OSPF process is not shut down.
Views
OSPF view
Predefined user roles
network-admin
Usage guidelines
Both this feature and OSPF isolation can be used for OSPF maintenance.
After you execute the shutdown process command for an OSPF process, the process performs the following operations:
· Sends 1-way hello packets to its neighbors.
On receipt of the packets, the neighbors disconnect from the OSPF process.
· Stops receiving and sending OSPF packets.
· Clears its neighbor, LSDB, and OSPF route information.
After maintenance, you can use the undo shutdown process command to restart the process for neighbor relationship re-establishment.
Examples
# Shut down OSPF process 100.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] shutdown process
Related commands
isolate enable
silent-interface
Use silent-interface to disable an interface or all interfaces from receiving and sending OSPF packets.
Use undo silent-interface to remove the configuration.
Syntax
silent-interface { interface-type interface-number | all }
undo silent-interface { interface-type interface-number | all }
Default
An interface can receive and send OSPF packets.
Views
OSPF view
Predefined user roles
network-admin
Parameters
interface-type interface-number: Specifies an interface by its type and number.
all: Specifies all interfaces.
Usage guidelines
To disable a network from receiving and sending OSPF routes, use the command on the interface connected to the network.
Examples
# Disable VLAN-interface 10 from receiving and sending OSPF packets.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] silent-interface vlan-interface 10
snmp trap rate-limit
Use snmp trap rate-limit to set the SNMP notification output interval and the maximum number of SNMP notifications that can be output at each interval.
Use undo snmp trap rate-limit to restore the default.
Syntax
snmp trap rate-limit interval trap-interval count trap-number
undo snmp trap rate-limit
Default
OSPF outputs a maximum of seven SNMP notifications within 10 seconds.
Views
OSPF view
Predefined user roles
network-admin
Parameters
interval trap-interval: Specifies the SNMP notification output interval in the range of 2 to 60 seconds.
count trap-number: Specifies the number of SNMP notifications output by OSPF at each interval, in the range of 0 to 300. The value of 0 indicates that OSPF does not output SNMP notifications.
Examples
# Configure OSPF to output a maximum of 10 SNMP notifications within 5 seconds.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] snmp trap rate-limit interval 5 count 10
snmp-agent trap enable ospf
Use snmp-agent trap enable ospf to enable SNMP notifications for OSPF.
Use undo snmp-agent trap enable ospf to disable SNMP notifications for OSPF.
Syntax
snmp-agent trap enable ospf [ authentication-failure | bad-packet | config-error | grhelper-status-change | grrestarter-status-change | if-state-change | lsa-maxage | lsa-originate | lsdb-approaching-overflow | lsdb-overflow | neighbor-state-change | nssatranslator-status-change | retransmit | virt-authentication-failure | virt-bad-packet | virt-config-error | virt-retransmit | virtgrhelper-status-change | virtif-state-change | virtneighbor-state-change ] *
undo snmp-agent trap enable ospf [ authentication-failure | bad-packet | config-error | grhelper-status-change | grrestarter-status-change | if-state-change | lsa-maxage | lsa-originate | lsdb-approaching-overflow | lsdb-overflow | neighbor-state-change | nssatranslator-status-change | retransmit | virt-authentication-failure | virt-bad-packet | virt-config-error | virt-retransmit | virtgrhelper-status-change | virtif-state-change | virtneighbor-state-change ] *
Default
SNMP notifications for OSPF are enabled.
Views
System view
Predefined user roles
network-admin
Parameters
authentication-failure: Specifies notifications about authentication failures on an interface.
bad-packet: Specifies notifications about error messages received on an interface.
config-error: Specifies notifications about error configuration of an interface.
grhelper-status-change: Specifies notifications about GR helper state change.
grrestarter-status-change: Specifies notifications about GR restarter state change.
if-state-change: Specifies notifications about interface state change.
lsa-maxage: Specifies LSA max age notifications.
lsa-originate: Specifies notifications about locally generated LSAs.
lsdb-approaching-overflow: Specifies notifications about approaching LSDB overflows.
lsdb-overflow: Specifies LSDB overflow notifications.
neighbor-state-change: Specifies notifications about neighbor state change.
nssatranslator-status-change: Specifies notifications about NSSA translator state change.
retransmit: Specifies notifications about packets that are received and forwarded on an interface.
virt-authentication-failure: Specifies notifications about authentication failures on a virtual interface.
virt-bad-packet: Specifies notifications about error messages received on a virtual interface.
virt-config-error: Specifies notifications about error configuration of a virtual interface.
virt-retransmit: Specifies notifications about packets that are received and forwarded on a virtual interface.
virtgrhelper-status-change: Specifies notifications about neighbor GR helper state changes of a virtual interface.
virtif-state-change: Specifies notifications about virtual interface state change.
virtneighbor-state-change: Specifies notifications about the neighbor state change of a virtual interface.
Examples
# Disable SNMP notifications for OSPF.
<Sysname> system-view
[Sysname] undo snmp-agent trap enable ospf
spf-schedule-interval
Use spf-schedule-interval to set the OSPF SPF calculation interval.
Use undo spf-schedule-interval to restore the default.
Syntax
spf-schedule-interval { maximum-interval [ minimum-interval [ incremental-interval [ conservative ] ] ] | millisecond interval }
undo spf-schedule-interval
Default
The maximum calculation interval is 5 seconds, the minimum interval is 50 milliseconds, and the incremental interval is 200 milliseconds.
Views
OSPF view
Predefined user roles
network-admin
Parameters
maximum-interval: Specifies the maximum OSPF SPF calculation interval in the range of 1 to 60 seconds.
minimum-interval: Specifies the minimum OSPF SPF calculation interval in the range of 10 to 60000 milliseconds.
incremental-interval: Specifies the incremental OSPF SPF calculation interval in the range of 10 to 60000 milliseconds.
conservative: Keeps the maximum interval when route flapping occurs. If you do not specify this keyword, the OSPF SPF calculation is performed at the maximum interval for three consecutive times and then performed at the minimum interval.
millisecond interval: Specifies the fixed OSPF SPF calculation interval in the range of 0 to 10000 milliseconds.
Usage guidelines
Based on the LSDB, an OSPF router uses SPF to calculate a shortest path tree with itself as the root. OSPF uses the shortest path tree to determine the next hop to a destination. By adjusting the SPF calculation interval, you can prevent overconsumption of bandwidth and router resources due to frequent topology changes.
For a stable network, use the minimum interval set by the spf-schedule-interval maximum-interval [ minimum-interval [ incremental-interval ] ] command. If network changes become frequent, the SPF calculation interval increases by the incremental interval × 2n-2 for each calculation until the maximum interval is reached. The value n is the number of calculation times. The minimum interval and the incremental interval cannot be greater than the maximum interval.
For a network that requires fast route convergence, use the spf-schedule-interval millisecond interval command to set a short SPF calculation interval.
Examples
# Set the maximum SPF calculation interval to 10 seconds, minimum interval to 500 milliseconds, and incremental interval to 300 milliseconds.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] spf-schedule-interval 10 500 300
stub
Use stub to configure an area as a stub area.
Use undo stub to restore the default.
Syntax
stub [ default-route-advertise-always | no-summary ] *
undo stub
Default
No area is a stub area.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
default-route-advertise-always: Enables the ABR to advertise a default route in a Type-3 LSA into the stub area regardless of whether FULL-state neighbors exist in the backbone area. If you do not specify this keyword, the ABR advertises a default route in a Type-3 LSA into the stub area only when a minimum of one FULL-state neighbor exists in the backbone area.
no-summary: Enables the ABR to advertise only a default route in a Type-3 LSA into the stub area without advertising any other Type-3 LSAs. The area is a totally stub area.
Usage guidelines
To configure an area as a stub area, use the stub command on all routers attached to the area.
If you execute this command multiple times, the most recent configuration takes effect.
Examples
# Configure Area 1 as a stub area.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 1
[Sysname-ospf-100-area-0.0.0.1] stub
default-cost (OSPF area view)
stub-router
Use stub-router to configure a router as a stub router.
Use undo stub-router to restore the default.
Syntax
stub-router [ external-lsa [ max-metric-value ] | include-stub | on-startup seconds | summary-lsa [ max-metric-value ] ] *
undo stub-router
Default
The router is not configured as a stub router.
Views
OSPF view
Predefined user roles
network-admin
Parameters
external-lsa max-metric-value: Specifies a cost for the external LSAs, in the range of 1 to 16777215. The default is 16711680.
include-stub: Specifies the cost of the stub links (link type 3) in Router LSAs to the maximum value 65535.
on-startup seconds: Specifies the router as a stub router during reboot, and specifies the timeout time in the range of 5 to 86400 seconds.
summary-lsa max-metric-value: Specifies a cost for the Type-3 LSAs, in the range of 1 to 16777215. The default cost value is 16711680.
Usage guidelines
The router LSAs sent by the stub router over different links contain different link type values. A value of 3 represents a link to a stub network, and the cost of the link is not changed. A value of 1, 2, or 4 represents a point-to-point link, a link to a transit network, or a virtual link. The cost of these links is set to 65535. Neighbors on such links will not send packets to the stub router as long as they have a route with a smaller cost.
Examples
# Configure a stub router.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] stub-router
transmit-pacing
Use transmit-pacing to set the LSU transmission interval and the maximum number of LSU packets that can be sent at each interval.
Use undo transmit-pacing to restore the default.
Syntax
transmit-pacing interval interval count count
undo transmit-pacing
Default
An OSPF interface sends a maximum of three LSU packets every 20 milliseconds.
Views
OSPF view
Predefined user roles
network-admin
Parameters
interval interval: Specifies an interval at which an interface sends LSU packets, in the range of 0 to 1000 milliseconds. If the router has multiple OSPF interfaces, increase this interval to reduce the total number of LSU packets sent by the router every second. As a best practice to maintain network stability, do not set the interval to 0 milliseconds when the OSPF LSDB is large or network changes are frequent.
count count: Specifies the maximum number of LSU packets sent by an interface at each interval, in the range of 1 to 200. If the router has multiple OSPF interfaces, decrease the maximum number to reduce the total number of LSU packets sent by the router every second.
Examples
# Configure all the interfaces running OSPF process 1 to send a maximum of 10 LSU packets every 30 milliseconds.
<Sysname> system-view
[Sysname] ospf 1
[Sysname-ospf-1] transmit-pacing interval 30 count 10
ttl-security
Use ttl-security to enable OSPF GTSM for an area.
Use undo ttl-security to disable OSPF GTSM for an area.
Syntax
ttl-security [ hops hop-count ]
undo ttl-security
Default
OSPF GTSM is disabled for an OSPF area.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
hops hop-count: Specifies the hop limit for checking OSPF packets, in the range of 1 to 254. The default hop limit is 1 for packets from common neighbors and 255 for packets from virtual link neighbors.
Usage guidelines
After you enable GTSM in area view, GTSM checks OSPF packets from common neighbors and virtual link neighbors.
GTSM protects the device by comparing the TTL value in the IP header of incoming OSPF packets against a valid TTL range. If the TTL value is within the valid TTL range, the packet is accepted. If not, the packet is discarded.
The valid TTL range is from 255 – the configured hop count + 1 to 255.
When GTSM is configured, the OSPF packets sent by the device have a TTL of 255. To use GTSM, you must configure GTSM on both the local and peer devices. You can specify different hop-count values for them.
The GTSM configuration in OSPF area view applies to all OSPF interfaces in the area. The GTSM configuration in interface view takes precedence over the configuration in OSPF area view.
As a best practice, set the hop limit if a virtual link exists in an area. You can enable GTSM for the interfaces on the virtual link. If you do not know the interfaces on the virtual link, enable GTSM in area view to prevent packet loss.
Examples
# Enable OSPF GTSM for OSPF area 1.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 1
[Sysname-ospf-100-area-0.0.0.1] ttl-security
Related commands
ospf ttl-security
vlink-peer
Use vlink-peer to configure a virtual link.
Use undo vlink-peer to remove a virtual link.
Syntax
vlink-peer router-id [ dead seconds | hello seconds | { { hmac-md5 | hmac-sha-256 | md5 } key-id { cipher | plain } string | simple { cipher | plain } string } | retransmit seconds | trans-delay seconds ] *
undo vlink-peer router-id [ dead | hello | { hmac-md5 | hmac-sha-256 | md5 } key-id | retransmit | simple | trans-delay ] *
Default
No virtual links exist.
Views
OSPF area view
Predefined user roles
network-admin
Parameters
router-id: Specifies the router ID of the neighbor on the virtual link.
dead seconds: Specifies the dead interval in the range of 1 to 32768 seconds. The default is 40. The dead interval must be identical with that on the virtual link neighbor, and a minimum of four times the hello interval.
hello seconds: Specifies the hello interval in the range of 1 to 8192 seconds. The default is 10. It must be identical with the hello interval on the virtual link neighbor.
hmac-md5: Specifies the HMAC-MD5 authentication mode.
hmac-sha-256: Specifies the HMAC-SHA-256 authentication mode.
md5: Specifies the MD5 authentication mode.
simple: Specifies the simple authentication mode.
key-id: Specifies the key ID for MD5 or HMAC-MD5 authentication, in the range of 1 to 255.
cipher: Specifies a key in encrypted form.
plain: Specifies a key in plaintext form. For security purposes, the key specified in plaintext form will be stored in encrypted form.
string: Specifies the key. This argument is case sensitive.
· In simple authentication mode, the plaintext form of the key is a string of 1 to 8 characters. The encrypted form of the key is a string of 33 to 41 characters.
· In MD5/HMAC-MD5 authentication mode, the plaintext form of the key is a string of 1 to 16 characters. The encrypted form of the key is a string of 33 to 53 characters.
· In HMAC-SHA-256 authentication mode, the plaintext form of the key is a string of 1 to 255 characters. The encrypted form of the key is a string of 33 to 373 characters.
retransmit seconds: Specifies the retransmission interval in the range of 1 to 3600 seconds. The default is 5.
trans-delay seconds: Specifies the transmission delay interval in the range of 1 to 3600 seconds. The default is 1.
Usage guidelines
As defined in RFC 2328, all non-backbone areas must maintain connectivity to the backbone. You can use the vlink-peer command to configure a virtual link to connect an area to the backbone.
When you configure this command, follow these guidelines:
· The smaller the hello interval is, the faster the network converges, and the more network resources are consumed.
· A retransmission interval that is too small can cause unnecessary retransmissions. A large value is appropriate for a low speed link.
· Specify an appropriate transmission delay with the trans-delay keyword.
If MD5, HMAC-MD5, or HMAC-SHA-256 authentication is configured, you can configure multiple keys, each having a unique key ID and key string. As a best practice to minimize the risk of key compromise, use only one key for a virtual link and delete the old key after key replacement.
To replace the key used for MD5, HMAC-MD5, or HMAC-SHA-256 authentication for a virtual link, you must configure the new key before removing the old key from each router. OSPF uses the key rollover mechanism to ensure that the routers can pass authentication before the replacement is complete on the interface. After you configure a new key on a router, the router sends copies of the same packet, each authenticated by a different key, including the new key and the keys in use. This practice continues until the router detects that all its neighbors have the new key.
Examples
# Configure a virtual link to the neighbor with router ID 1.1.1.1.
<Sysname> system-view
[Sysname] ospf 100
[Sysname-ospf-100] area 2
[Sysname-ospf-100-area-0.0.0.2] vlink-peer 1.1.1.1
Related commands
authentication-mode
display ospf vlink
