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reauthentication time through rsa-pubkey
- reauthentication time
- reconnect
- redirect (identity policy)
- redirect gateway
- redundancy (cs-server)
- redundancy (firewall)
- redundancy (GDOI)
- redundancy asymmetric-routing enable
- redundancy group
- redundancy group (interface)
- redundancy inter-device
- redundancy rii
- redundancy stateful
- regenerate
- regexp (profile map configuration)
- registration interface
- registration periodic crl trustpoint
- registration retry count
- registration retry interval
- registration retry-interval (TIDP)
- rekey address ipv4
- rekey algorithm
- rekey authentication
- rekey lifetime
- rekey retransmit
- rekey sig-hash algorithm
- rekey transport unicast
- remark
- remark (IPv6)
- replay counter window-size
- replay time window-size
- request-method
- request-queue (GTP)
- request-timeout
- reset (policy-map)
- reset (zone-based policy)
- responder-only
- retired (IPS)
- retransmit (config-radius-server)
- reverse-route
- revocation-check
- revocation-check (ca-trustpool)
- root
- root CEP
- root PROXY
- root TFTP
- route accept
- route set
- route set remote
- router-preference maximum
- rsakeypair
- rsa-pubkey
reauthentication time
To enter the time limit after which the authenticator should reauthenticate, use the reauthentication timecommand in local RADIUS server group configuration mode. To remove the requirement that users reauthenticate after the specified duration, use the no form of this command.
Command History
Release
Modification
12.2(11)JA
This command was introduced on the Cisco Aironet Access Point 1100 and the Cisco Aironet Access Point 1200.
12.3(11)T
This command was integrated into Cisco IOS Release 12.3(11)T and implemented on the following platforms: Cisco 2600XM, Cisco 2691, Cisco 2811, Cisco 2821, Cisco 2851, Cisco 3700, and Cisco 3800 series routers.
Examples
The following example shows that the time limit after which the authenticator should reauthenticate is 30 seconds:
Router(config-radsrv-group)# reauthentication time 30Related Commands
Command
Description
block count
Configures the parameters for locking out members of a group to help protect against unauthorized attacks.
clear radius local-server
Clears the statistics display or unblocks a user.
debug radius local-server
Displays the debug information for the local server.
group
Enters user group configuration mode and configures shared setting for a user group.
nas
Adds an access point or router to the list of devices that use the local authentication server.
radius-server host
Specifies the remote RADIUS server host.
radius-server local
Enables the access point or router to be a local authentication server and enters into configuration mode for the authenticator.
show radius local-server statistics
Displays statistics for a local network access server.
ssid
Specifies up to 20 SSIDs to be used by a user group.
user
Authorizes a user to authenticate using the local authentication server.
vlan
Specifies a VLAN to be used by members of a user group.
reconnect
To enable Internet Key Exchange Version 2 (IKEv2) support for the Cisco AnyConnect Reconnect feature, use the reconnect command in IKEv2 profile configuration mode. To disable IKEv2 reconnect, use the no form of this command.
Syntax Description
timeout seconds (Optional) Interval, in seconds. The range is from 600 to 86400. The default is 1800.
Command History
Release Modification 15.4(1)T
This command was introduced.
Cisco IOS XE Release 3.11S
This command was integrated into Cisco IOS XE Release 3.11S.
Usage Guidelines
The Auto Reconnect feature in the Cisco AnyConnect client helps the Cisco AnyConnect VPN client to remember the session for a period of time and to resume the connection when a network goes down or a client drops out of network after establishing the secure channel. As AnyConnect Client is extensively used with IKEv2, IKEv2 extends the Auto Reconnect feature support on IOS through the IOS IKEv2 support for Auto Reconnect feature of AnyConnect feature.
redirect (identity policy)
To redirect clients to a particular URL, use the redirectcommand in identity policy configuration mode. To remove the URL, use the no form of this command.
Usage Guidelines
When you use this command, an identity policy has to be associated with an Extensible Authentication Protocol over UDP (EAPoUDP) identity profile.
redirect gateway
To configure an Internet Key Exchange Version 2 (IKEv2) redirect mechanism on a gateway for specific profiles, use the redirect gateway command in IKEv2 profile configuration mode. To remove the redirects mechanism, use the no form of this command.
Usage Guidelines
Use this command to enable the redirect mechanism on the gateway when authenticating an SA for specific IKEv2 profiles.
A thorough security analysis shows that redirect during IKE_AUTH is neither more nor less secure than redirect during IKE_INIT. However, for performance and scalability reasons, we recommend redirect during IKE_INIT.
redundancy (cs-server)
To specify that the active certificate server (CS) is synchronized to the standby CS, use the redundancy command in certificate server configuration mode. To return to the default, use the no version of this command.
Usage Guidelines
You must configure the crypto pki server command with the name of the certificate server in order to enter certificate server configuration mode and configure this command.
Use the redundancy command only if the your router has redundant capabilities for an active and standby CS.
Related Commands
Command
Description
auto-rollover
Enables the automated CA certificate rollover functionality.
cdp-url
Specifies a CDP to be used in certificates that are issued by the certificate server.
crl (cs-server)
Specifies the CRL PKI CS.
crypto pki server
Enables a CS and enters certificate server configuration mode, or immediately generates shadow CA credentials
database archive
Specifies the CA certificate and CA key archive format--and the password--to encrypt this CA certificate and CA key archive file.
database level
Controls what type of data is stored in the certificate enrollment database.
database url
Specifies the location where database entries for the CS is stored or published.
database username
Specifies the requirement of a username or password to be issued when accessing the primary database location.
default (cs-server)
Resets the value of the CS configuration command to its default.
grant auto rollover
Enables automatic granting of certificate reenrollment requests for a Cisco IOS subordinate CA server or RA mode CA.
grant auto trustpoint
Specifies the CA trustpoint of another vendor from which the Cisco IOS certificate server automatically grants certificate enrollment requests.
grant none
Specifies all certificate requests to be rejected.
grant ra-auto
Specifies that all enrollment requests from an RA be granted automatically.
hash (cs-server)
Specifies the cryptographic hash function the Cisco IOS certificate server uses to sign certificates issued by the CA.
issuer-name
Specifies the DN as the CA issuer name for the CS.
lifetime (cs-server)
Specifies the lifetime of the CA or a certificate.
mode ra
Enters the PKI server into RA certificate server mode.
mode sub-cs
Enters the PKI server into sub-certificate server mode
serial-number (cs-server)
Specifies whether the router serial number should be included in the certificate request.
show (cs-server)
Displays the PKI CS configuration.
shutdown (cs-server)
Allows a CS to be disabled without removing the configuration.
redundancy (firewall)
redundancy (GDOI)
To enable Group Domain of Interpretation (GDOI) redundancy configuration mode and to allow for key server redundancy, use the redundancy command in GDOI local server configuration mode. To disable GDOI redundancy, use the no form of this command.
Usage Guidelines
This command must be configured before configuring related redundancy commands, such as for key server peers, local priority, and timer values. Use the local priority command to set the local key server priority. Use the peer address ipv4command to configure the peer address that belongs to the redundancy key server group.
Examples
The following example shows that key server redundancy has been configured:
address ipv4 10.1.1.1 redundancy local priority 10 peer address ipv4 10.41.2.5 peer address ipv4 10.33.5.6Related Commands
Command
Description
address ipv4
Sets the source address, which is used as the source for packets originated by the local key server.
local priority
Sets the local key server priority.
peer address ipv4
Configures the peer key server.
server local
Designates a device as a GDOI key server and enters GDOI local server configuration mode.
redundancy asymmetric-routing enable
To establish an asymmetric flow diversion tunnel for each redundancy group, use the redundancy asymmetric-routing enable command in interface configuration mode. To remove the established flow diversion tunnel, use the no form of this command.
Command Default
An asymmetric routing traffic diversion tunnel is not configured for redundancy groups.
Usage Guidelines
You must configure this command on a traffic interface that sends or receives asymmetric routing traffic. A tunnel is established between the traffic interface and the asymmetric routing interface for each redundancy group.
redundancy group
To configure fault tolerance for the mobile router, use the redundancy group command in mobile router configuration mode. To disable this functionality, use the no form of this command.
Usage Guidelines
The redundancy group command provides f ault tolerance by selecting one mobile router in the redundancy group name argument to provide connectivity for the mobile networks. This mobile router is in the active state. The other mobile routers are passive and wait until the active mobile router fails before a new active mobile router is selected. Only the active mobile router registers and sets up proper routing for the mobile networks. The redundancy state is either active or passive.
redundancy group (interface)
To enable the redundancy group (RG) traffic interface configuration, use the redundancy group command in interface configuration mode. To remove the redundancy group traffic interface configuration, use the no form of this command.
redundancy group id { ip virtual-ip | ipv6 { link-local-address | ipv6-address/prefix-length } | autoconfig } [ exclusive ] [ decrement value ]
no redundancy group id { ip | ipv6 { link-local-address | ipv6-address/prefix-length } }
Syntax Description
id
Redundancy group ID. Valid values are from 1 and 2.
ip virtual-ip
Enables IPv4 RGs and sets a virtual IPv4 address.
ipv6
Enables IPv6 RGs.
link-local-address
Link local address.
ipv6-address/prefix-length
IPv6 address and the length of the IPv6 prefix. IPv6 prefix is a decimal value that indicates how many of the high-order contiguous bits of the address comprise the prefix (the network portion of the address). A slash mark must precede the decimal value.
autoconfig
Obtains IP addresses through autoconfiguration.
exclusive
(Optional) Specifies whether the interface is exclusive to an RG.
decrement number
(Optional) Specifies the number that is decremented from the priority when the state of an interface goes down. The configured decrement value overrides the default number that is configured for an RG. Valid values are from 1 to 255.
Command History
Release
Modification
Cisco IOS XE Release 3.1S
This command was introduced.
15.2(3)T
This command was integrated into Cisco IOS Release 15.2(3)T.
Cisco IOS XE Release 3.7S
This command was modified. The virtual-ip, link-local-address, ipv6-address/prefix-length arguments and ip, ipv6, and autoconfig keywords were added.
Usage Guidelines
Use this command to configure a redundancy group for stateful switchover.
The virtual IP address and the physical address must be in the same subnet.
When autoconfiguration is enabled, the interface obtains an IP address automatically.
Examples
The following example shows how to enable the IPv6 redundancy group traffic interface configuration:
Device(config)# interface gigabitethernet 0/0/1 Device(config-if)# redundancy group 2 ipv6 FE80::260:3EFF:FE11:6770 exclusiveRelated Commands
Command
Description
control
Configures the control interface type and number for a redundancy group.
data
Configures the data interface type and number for a redundancy group.
interface
Configures an interface and enters interface configuration mode.
name
Configures the name of a redundancy group.
preempt
Enables preemption on a redundancy group.
protocol
Defines a protocol instance in a redundancy group.
redundancy rii
Configures an RII for a redundancy group.
redundancy inter-device
To enter inter-device configuration mode, use the redundancy inter-device command in global configuration mode. To exit inter-device configuration mode, use the exit command. To remove all inter-device configuration, use the no form of this command.
Usage Guidelines
NoteSecurity threats, as well as the cryptographic technologies to help protect against them, are constantly changing. For more information about the latest Cisco cryptographic recommendations, see the Next Generation Encryption (NGE) white paper.
Use the redundancy inter-device command to enter inter-device configuration mode, which allows you to enable and protect Stateful Switchover (SSO) traffic.
Examples
The following example shows how to issue the redundancy inter-device command when enabling SSO:
redundancy inter-device scheme standby HA-in ! ! ipc zone default association 1 no shutdown protocol sctp local-port 5000 local-ip 10.0.0.1 remote-port 5000 remote-ip 10.0.0.2 !The following example shows how to issue the redundancy inter-device command when configuring SSO traffic protection:
crypto ipsec transform-set trans2 ah-md5-hmac esp-aes ! crypto ipsec profile sso-secure set transform-set trans2 ! redundancy inter-device scheme standby HA-in security ipsec sso-secureRelated Commands
Command
Description
local-ip
Defines at least one local IP address that is used to communicate with the redundant peer.
local-port
Defines the local SCTP that is used to communicate with the redundant peer.
remote-ip
Defines at least one IP address of the redundant peer that is used to communicate with the local device.
remote-port
Defines the remote SCTP that is used to communicate with the redundant peer.
scheme
Defines that redundancy scheme that is used between two devices.
redundancy rii
To configure the redundancy interface identifier (RII) for redundancy group protected traffic interfaces, use the redundancy rii command in interface configuration mode. To remove the redundant interface from the redundancy group, use the no form of this command.
Usage Guidelines
NoteSecurity threats, as well as the cryptographic technologies to help protect against them, are constantly changing. For more information about the latest Cisco cryptographic recommendations, see the Next Generation Encryption (NGE) white paper.
Every interface associated with one or more redundancy groups must have a unique RII assigned to it. The RII allows interfaces to have a one-to-one mapping between peers.
Examples
The following example shows how to configure the RII for Gigabit Ethernet interface 0/0/0:
Router# configure terminal Router(config)# interface GigabitEthernet 0/0/0 Router(config-if)# redundancy rii 100Related Commands
Command
Description
application redundancy
Enters redundancy application configuration mode.
authentication
Configures clear text authentication and MD5 authentication for a redundancy group.
control
Configures the control interface type and number for a redundancy group.
data
Configures the data interface type and number for a redundancy group.
name
Configures the redundancy group with a name.
preempt
Enables preemption on the redundancy group.
protocol
Defines a protocol instance in a redundancy group.
redundancy group
Enables redundancy group redundancy traffic interface configuration.
redundancy stateful
To configure stateful failover for tunnels using IP Security (IPSec), use the redundancy statefulcommand in crypto map configuration mode. To disable stateful failover for tunnel protection, use the no form of this command.
Usage Guidelines
The redundancy statefulcommand uses an existing IPSec profile (which is specified via the crypto ipsec profilecommand) to configure IPSec stateful failover for tunnel protection. (You do not configure the tunnel interface as you would with a crypto map configuration.) IPSec stateful failover enables you to define a backup IPSec peer (secondary) to take over the tasks of the active (primary) router if the active router is deemed unavailable.
The tunnel source address must be a VIP address, and it must not be an interface name.
Examples
The following example shows how to configure stateful failover for tunnel protection:
crypto ipsec profile peer-profile redundancy HA-out stateful interface Tunnel1 ip unnumbered Loopback0 tunnel source 209.165.201.3 tunnel destination 10.0.0.5 tunnel protection ipsec profile peer-profile ! interface Ethernet0/0 ip address 209.165.201.1 255.255.255.224 standby 1 ip 209.165.201.3 standby 1 name HA-outregenerate
To enable key rollover with manual certificate enrollment, use the regenerate command in ca-trustpoint configuration mode. To disable key rollover, use the no form of this command.
Command History
Release
Modification
12.3(7)T
This command was introduced.
12.2(18)SXE
This command was integrated into Cisco IOS Release 12.2(18)SXE.
12.2(33)SRA
This command was integrated into Cisco IOS release 12.(33)SRA.
12.2SX
This command is supported in the Cisco IOS Release 12.2SX train. Support in a specific 12.2SX release of this train depends on your feature set, platform, and platform hardware.
Usage Guidelines
Use the regenerate command to provide seamless key rollover for manual certificate enrollment. A new key pair is created with a temporary name, and the old certificate and key pair are retained until a new certificate is received from the certification authority (CA). When the new certificate is received, the old certificate and key pair are discarded and the new key pair is renamed with the name of the original key pair.
If the key pair being rolled over is exportable, the new key pair will also be exportable. The following comment will appear in the trustpoint configuration to indicate whether the key pair is exportable:
! RSA keypair associated with trustpoint is exportableDo not regenerate the keys manually; key rollover will occur when the crypto ca enroll command is issued.
Examples
The following example shows how to configure key rollover to regenerate new keys with a manual certificate enrollment from the CA named “trustme2”.
crypto ca trustpoint trustme2 enrollment url http:// trustme2 .company.com/ subject-name OU=Spiral Dept., O=tiedye.com ip-address ethernet0 serial-number none regenerate password revokeme rsakeypair trustme2 2048 exit crypto ca authenticate trustme2 crypto ca enroll trustme2regexp (profile map configuration)
To create an entry in a cache profile group that allows authentication and authorization matches based on a regular expression, use the regexp command in profile map configuration mode. To disable a regular expression entry, use the no form of this command.
Syntax Description
matchexpression
String representing a regular expression on which to match.
any
Specifies that any unique instance of a AAA server response that matches the regular expression is saved in the cache.
only
Specifies that only one instance of a AAA server response that matches the regular expression is saved in the cache.
no-auth
(Optional) Specifies that authentication is bypassed for this user.
Usage Guidelines
Use this command to create an entry in a cache profile group that matches based on a regular expression, such as .*@example.com or .*@xyz.com.
Because the number of entries in a regular expression cache profile group could be in the thousands, and validating each request against a regular expression can be time consuming, we do not recommend using regular expression entries in cache profile groups.
Examples
The following example creates an entry in the cache profile group networkusers that authorizes network access to any example company user. No authentication is performed for these users because the no-auth keyword is used.
Router# configure terminal Router(config)# aaa cache profile networkusers Router(config-profile-map)# regexp .*@example.com any no-authregistration interface
To specify the interface to be used for a Group Domain of Interpretation (GDOI) registration, use the registration interface command in GDOI local server configuration mode. To disable an interface, use the no form of this command.
Usage Guidelines
The table below lists the types of interface that may be used for the type argument.
Table 1 Type of Interface Interface
Description
Async
Async interface
BVI
Bridge-Group Virtual Interface
CDMA-1x
Code division multiple access 1x interface
CTunnel
CTunnel interface
Dialer
Dialer interface
Ethernet
Institute of Electrical and Electronics Engineers (IEEE) Standard 802.3
Lex
Lex interface
Loopback
Loopback interface
MFR
Multilink Frame Relay bundle interface
Multilink
Multilink group interface
Null
Null interface
Serial
Serial
Tunnel
Tunnel interface
Vif
Pragmatic General Multicast (PGM) Multicast Host interface
Virtual-PPP
Virtual PPP interface
Virtual-Template
Virtual Template interface
Virtual-TokenRing
Virtual TokenRing
registration periodic crl trustpoint
To enable periodic registrations for the Group Domain of Interpretation (GDOI) key server (KS) when new certificate revocation lists (CRLs) become available for the configured public key infrastructure (PKI) trustpoint certificate authority (CA), use the registration periodic crl trustpoint command in GDOI local server configuration mode. To disable the registration, use the no form of this command.
registration periodic crl trustpoint trustpoint-name
no registration periodic crl trustpoint trustpoint-name
registration retry count
To configure the number of times that a Transitory Messaging Services (TMS) registration message is sent to a controller, use the registration retry count command in parameter-map configuration mode. To configure the consumer to use the default registration retry count value, use the no form of this command.
NoteEffective with Cisco IOS Release 12.4(20)T, the registration retry count command is not available in Cisco IOS software.
Command Default
The following default value is used if this command is not configured or if the no form is entered: 3
Usage Guidelines
The registration retry count command is entered on a consumer to configure the number of times that an implicit registration request message is transmitted.
The consumer must register with the controller before the controller can send Control Information Messages (CIMs). Implicit registration requests are automatically sent to the controller when a TMS type service policy is activated on the consumer.
By default, a consumer sends a registration request message to the controller once every 3 minutes for up to three times or until successfully registered. If the consumer is a member of multiple groups, it sends a separate registration request messages to the controller of each group.
NoteExplicit registration is configured by entering the tms consumer registration command on a consumer in privileged EXEC mode. This command is unaffected by registration timer configuration and can be used to register the consumer if the count has been exceeded for implicit registration.
Examples
The following example configures a consumer to send up to five registration messages to a controller:
Router(config)# parameter-map type tms PARAMAP_1 Router(config-profile)# controller ipv4 10.1.1.1 Router(config-profile)# logging tms events Router(config-profile)# registration retry interval 60 Router(config-profile)# registration retry count 5 Router(config-profile)# exitregistration retry interval
To configure the length of time between consumer registration attempts, use the registration retry interval command in parameter-map configuration mode. To configure the consumer to use the default registration timer interval, use the no form of this command.
NoteEffective with Cisco IOS Release 12.4(20)T, the registration retry interval command is not available in Cisco IOS software.
Command Default
The following default value is used if this command is not configured or if the no form is entered:
180
Usage Guidelines
The registration retry interval command is entered on a consumer to configure the time interval between the transmission of implicit registration request messages.
The consumer must register with the controller before the controller can send Control Information Messages (CIMs). Implicit registration requests are automatically sent to the controller when a Transitory Messaging Services (TMS) type service policy is activated on the consumer.
By default, a consumer sends a registration request message to the controller once every 3 minutes for up to three times or until successfully registered. If the consumer is a member of multiple groups, it sends a separate registration request messages to the controller of each group.
NoteExplicit registration is configured by entering the tms consumer registration command on a consumer in privileged EXEC mode. This command is unaffected by registration timer configuration and can be used to register the consumer if the count has been exceeded for implicit registration.
Examples
The following example configures a consumer to send registration messages at 60-second intervals:
Router(config)# parameter-map type tms PARAMAP_1 Router(config-profile)# controller ipv4 10.1.1.1 Router(config-profile)# logging tms events Router(config-profile)# registration retry interval 60 Router(config-profile)# registration retry count 5 Router(config-profile)# exitregistration retry-interval (TIDP)
To configure the length of time and number of attempts for TIDP group registration, use the registration retry-interval command in TIDP group configuration mode. To configure TIDP to use default registration timer values, use the no form of this command.
NoteEffective with Cisco IOS Release 12.4(20)T, the registration retry-interval command is not available in Cisco IOS software.
Command Default
The following default values are used if this command is not configured or if the no form is entered:
min 60 max 3600
Usage Guidelines
The controller registers consumers. By default, the controller sends a registration request message once every 60 seconds for up to 1 hour until the consumer is successfully registered. The value entered for the max keyword must be equal to or greater than the value entered for the min keyword. Entering a value of zero after both the min and max keywords configures the controller not to retry registration if the initial registration message receives no response.
Examples
The following example configures TIDP to attempt to register group members at 30-second intervals for up to 10 minutes or until consumers are registered:
Router(config)# tidp group 10 Router(config-tidp-grp)# key-set KEY_1 Router(config-tidp-grp)# registration retry-interval min 30 max 600 Router(config-tidp-grp)# peer 10.1.1.1 Router(config-tidp-grp)# peer 10.1.1.2 Router(config-tidp-grp)# peer 10.1.1.3 Router(config-tidp-grp)# activerekey address ipv4
To specify the source or destination information of the rekey message, use the rekey address ipv4 command in GDOI local server configuration mode. To remove a source or destination address, use the no form of this command.
rekey address ipv4 { access-list-number | access-list-name }
no rekey address ipv4 { access-list-number | access-list-name }
Usage Guidelines
If rekeys are not required, this command is optional. If rekeys are required, this command is required.
The source is usually the key server interface from which the message leaves, and the destination is the multicast address on which the group members receive the rekeys (for example, access-list 101 permit 121 permit udp host 10.0.5.2 eq 848 host 192.168.1.2. eq 848).
Examples
The following example shows that the rekey address is access list “101”:
rekey address ipv4 101The following example shows that a rekey message is to be sent to access control list (ACL) address 239.10.10.10:
crypto gdoi group gdoigroup1 identity number 1111 server local rekey address ipv4 120 rekey lifetime seconds 400 no rekey retransmit rekey authentication mypubkey rsa ipseca-3845b.examplecompany.comaccess-list 120 permit udp host 10.5.90.1 eq 848 host 239.10.10.10 eq 848
rekey algorithm
To define the type of encryption algorithm used for a Group Domain of Interpretation (GDOI) group, use the rekey algorithm command in GDOI local server configuration mode. To disable an algorithm that was defined, use the no form of this command.
Command Default
If this command is not configured, the default value of 3des-cbc takes effect. However, the default is used only if the commands required for a rekey to occur are specified (see the Note below in “Usage Guidelines”).
Usage Guidelines
NoteSecurity threats, as well as the cryptographic technologies to help protect against them, are constantly changing. For more information about the latest Cisco cryptographic recommendations, see the Next Generation Encryption (NGE) white paper.
The table below lists the types of encryption algorithms that may be used.
Table 2 Types of Encryption Encryption Type
Description
3des-cbc
Cipher Block Chaining mode of the Triple Data Encryption Standard (3des).
aes 128
128-bit Advanced Encrytion Standard (AES).
aes 192
192-bit AES.
aes 256
256-bit AES.
des-cbc
Cipher Block Chaining mode of the Data Encryption Standard (des).
At a minimum, the following commands are required for a rekey to occur:
rekey address ipv4 {access-list-number| access-list-name}
rekey authentication {mypubkey | pubkey} {rsa key-name}
If the rekey algorithm command is not configured, the default of 3des-cbc is used if the above minimum rekey configuration is met.
Examples
The following example shows that the 3des-cbc encryption standard is used:
rekey algorithm 3des-cbcRelated Commands
Command
Description
crypto gdoi group
Identifies a GDOI group and enters GDOI group configuration mode.
rekey address ipv4
Specifies the source or destination information of the rekey message.
rekey authentication
Specifies the keys to be used to a rekey to GDOI group members.
server local
Designates a device as a GDOI key server and enters GDOI local server configuration mode.
rekey authentication
To specify the keys to be used for a rekey to Group Domain of Interpretation (GDOI) group members, use the rekey authenticationcommand in GDOI local server configuration mode. To disable the keys, use the no form of this command.
rekey authentication { mypubkey | pubkey } rsa key-name
no rekey authentication { mypubkey | pubkey } rsa key-name
Usage Guidelines
If rekeys are not required, this command is optional. If rekeys are required, this command is required.
For this command to work, Rivest, Shamir, and Adelman (RSA) keys must be generated first on the router using the following command:
crypto key generate rsa {general keys} [label key-label]
For example:
crypto key generate rsa general keys label group_1234_key_namerekey lifetime
To limit the number of days or seconds for which any one key encryption key (KEK) should be used, use the rekey lifetime command in GDOI local server configuration mode. To disable the number of days or seconds that were set, use the no form of this command.
rekey lifetime { days number-of-days | seconds number-of-seconds }
no rekey lifetime { days | seconds }
Command History
Release
Modification
12.4(6)T
This command was introduced.
Cisco IOS XE Release 2.3
This command was integrated into Cisco IOS XE Release 2.3.
15.3(2)T
This command was modified. The days number-of-days keyword and argument pair was added, and the maximum value for the seconds number-of-seconds keyword and argument pair was extended from 86400 seconds to 2592000 seconds.
Cisco IOS XE Release 3.9S
This command was modified. The days number-of-days keyword and argument pair was added, and the maximum value for the seconds number-of-seconds keyword and argument pair was extended from 86400 seconds to 2592000 seconds.
Usage Guidelines
When the rekey lifetime is reached, a new KEK is sent to the group members so that the next rekey is encrypted with the new KEK.
Examples
The following example shows how to set the rekey lifetime to 600 seconds:
Device> enable Device# configure terminal Device(config)# crypto gdoi group GETVPN Device(config-gdoi-group)# identity number 3333 Device(config-gdoi-group)# server local Device(gdoi-local-server)# rekey lifetime seconds 600 Device(gdoi-local-server)# endrekey retransmit
To specify the duration of a rekey message retransmission and the number of retransmissions, use the rekey retransmit command in GDOI local server configuration mode. To disable the duration and number that were specified, use the no form of this command.
rekey retransmit number-of-seconds { number number-of-retransmissions | periodic }
no rekey retransmit
Usage Guidelines
Use this command if you are concerned about network loss.
The periodic keyword sends periodic reminder rekeys to group members (GMs) that did not respond with an acknowledgment in the last scheduled rekey. Combining this keyword with the long SA lifetime feature makes a KS effectively synchronize GMs in case they miss a scheduled rekey before the keys roll over.
Each periodic rekey increments the sequence number, just as for rekey retransmissions. Also, the GM is removed from the GM database on the key server (KS) after three scheduled rekeys (not retransmissions) for which the GM does not send an acknowledgment.
Examples
The following example shows how to specify that the rekey message is retransmitted three times for 15 seconds each time:
Device> enable Device# configure terminal Device(config)# crypto gdoi group GETVPN Device(config-gdoi-group)# identity number 3333 Device(config-gdoi-group)# server local Device(gdoi-local-server)# rekey retransmit 15 number 3 Device(gdoi-local-server)# endExamples
The following example shows how to specify that the rekey message is retransmitted periodically for 30 seconds each time:
Device> enable Device# configure terminal Device(config)# crypto gdoi group GROUP-GDOI Device(config-gdoi-group)# identity number 4444 Device(config-gdoi-group)# server local Device(gdoi-local-server)# rekey retransmit 30 periodic Device(gdoi-local-server)# endrekey sig-hash algorithm
To configure the signature hash algorithm for a key encryption key (KEK), use the rekey sig-hash algorithm command in GDOI local server configuration mode. To return a signature hash algorithm to the default (SHA-1), use the no form of this command.
Usage Guidelines
Using SHA-1 guarantees interoperability with group members (GMs) that are running earlier versions of Cisco IOS software. Suite B requires SHA-256, SHA-384, or SHA-512.
rekey transport unicast
To configure unicast delivery of rekey messages to group members, use the rekey transport unicastcommand in global configuration mode. To remove unicast delivery of rekey messages and enable the default to multicast rekeying, use the no form of this command.
Command Default
If rekey transport unicast is not specified or no rekey transport unicast is specified, multicast rekeying is the default.
Usage Guidelines
This command is configured on the key server under the server local command, along with other rekey configurations.
Examples
The following example shows that unicast delivery of rekey messages to group members has been configured:
crypto gdoi group diffint identity number 3333 server local rekey lifetime seconds 300 rekey retransmit 10 number 2 rekey authentication mypubkey rsa mykeys rekey transport unicast sa ipsec 1 profile gdoi-p match address ipv4 120 replay counter window-size 64 address ipv4 10.0.5.2remark
To write a helpful comment (remark) for an entry in a named IP access list, use the remark command in access list configuration mode. To remove the remark, use the no form of this command.
Command History
Release
Modification
12.0(2)T
This command was introduced.
12.2(33)SRA
This command was integrated into Cisco IOS Release 12.2(33)SRA.
12.2SX
This command is supported in the Cisco IOS Release 12.2SX train. Support in a specific 12.2SX release of this train depends on your feature set, platform, and platform hardware.
Usage Guidelines
The remark can be up to 100 characters long; anything longer is truncated.
If you want to write a comment about an entry in a numbered IP access list, use the access-list remark command.
Examples
In the following example, the host1 subnet is not allowed to use outbound Telnet:
ip access-list extended telnetting remark Do not allow host1 subnet to telnet out deny tcp host 172.69.2.88 any eq telnetRelated Commands
Command
Description
access-list remark
Specifies a helpful comment (remark) for an entry in a numbered IP access list.
deny (IP)
Sets conditions under which a packet does not pass a named IP access list.
ip access-list
Defines an IP access list by name.
permit (IP)
Sets conditions under which a packet passes a named IP access list.
remark (IPv6)
To write a helpful comment (remark) for an entry in an IPv6 access list, use the remarkcommand in IPv6 access list configuration mode. To remove the remark, use the no form of this command.
Command History
Release
Modification
12.0(23)S
This command was introduced.
12.2(13)T
This command was integrated into Cisco IOS Release 12.2(13)T.
12.2(14)S
This command was integrated into Cisco IOS Release 12.2(14)S.
12.2(28)SB
This command was integrated into Cisco IOS Release 12.2(28)SB.
12.2(33)SRA
This command was integrated into Cisco IOS Release 12.2(33)SRA.
12.2(33)SXH
This command was integrated into Cisco IOS Release 12.2(33)SXH.
Usage Guidelines
The remark (IPv6) command is similar to the remark (IP) command, except that it is IPv6-specific.
The remark can be up to 100 characters long; anything longer is truncated.
Examples
The following example configures a remark for the IPv6 access list named TELNETTING. The remark is specific to not letting the Marketing subnet use outbound Telnet.
ipv6 access-list TELNETTING remark Do not allow Marketing subnet to telnet out deny tcp 2001:0DB8:0300:0201::/64 any eq telnetreplay counter window-size
To turn on counter-based anti-replay protection for traffic defined inside an access list using Group Domain of Interpretation (GDOI) if there are only two group members in a group, use the replay counter window-sizecommand in GDOI SA IPsec configuration mode. To disable counter-based anti-replay protection, use the no form of this command.
Usage Guidelines
This command is configured on the key server.
Cisco IPsec authentication provides anti-replay protection against an attacker duplicating encrypted packets by assigning a unique sequence number to each encrypted packet. (Security association [SA] anti-replay is a security service in which the receiver can reject old or duplicate packets to protect itself against replay attacks.) The decryptor checks off the sequence numbers that it has seen before. The encryptor assigns sequence numbers in an increasing order. The decryptor remembers the value X of the highest sequence number that it has already seen. N is the window size in bytes, and the decryptor also remembers whether it has seen packets having sequence numbers from X-N+1 through X. Any packet with the sequence number X-N is discarded. Currently, N is set at 64, so only 64 packets can be tracked by the decryptor.
At times, however, the 64-packet window size is not sufficient. For example, Cisco quality of service (QoS) gives priority to high-priority packets, which could cause some low-priority packets to be discarded even though they could be one of the last 64 packets received by the decryptor. The IPsec Anti-Replay Window: Expanding and Disabling feature allows you to expand the window size, allowing the decryptor to keep track of more than 64 packets.
Increasing the anti-replay window size has no impact on throughput and security. The impact on memory is insignificant because only an extra 128 bytes per incoming IPsec SA is needed to store the sequence number on the decryptor. It is recommended that you use the full 1024 window size to eliminate any future anti-replay problems.
NoteGDOI anti-replay can be either counter based or time based. Use this command for counter-based anti-replay protection. For time-based anti-replay protection, use the replay time window-size command.
Examples
The following example shows that the anti-replay window size for unicast traffic has been set to 512:
crypto gdoi group gdoigroup1 identity number 1111 server local rekey address ipv4 120 rekey lifetime seconds 400 no rekey retransmit rekey authentication mypubkey rsa ipseca-3845b.examplecompany.com sa ipsec 10 profile group1111 match address ipv4 101 replay counter window-size 512replay time window-size
To set the window size for anti-replay protection using Group Domain of Interpretation (GDOI) if there are more than two group members in a group, use the replay time window-sizecommand in GDOI SA IPsec configuration mode. To disable time-based anti-replay, use the no form of this command.
Usage Guidelines
This command is configured on the key server.
NoteGDOI anti-replay can be either counter based or time based. This command turns on time-based anti-replay. For counter-based anti-replay protection, use the replay counter window-size command.
Examples
The following example shows that the number of seconds of the interval duration of the SAR clock has been set to 1:
sa ipsec 10 profile group1111 match address ipv4 101 replay time window-size 1request-method
To permit or deny HTTP traffic according to either the request methods or the extension methods, use the request-methodcommand in appfw-policy-http configuration mode. To disable this inspection parameter, use the no form of this command.
request-method { rfc rfc-method | extension extension-method } action { reset | allow } [alarm]
no request-method { rfc rfc-method | extension extension-method } action { reset | allow } [alarm]
Syntax Description
rfc
Specifies that the supported methods of RFC 2616, Hypertext Transfer Protocol--HTTP/1.1 , are to be used for traffic inspection.
rfc-method
Any one of the following RFC 2616 methods can be specified: connect, default, delete, get, head, options, post, put, trace.
extension
Specifies that the extension methods are to be used for traffic inspection.
extension-method
Any one of the following extension methods can be specified: copy, default, edit, getattribute, getproperties, index, lock, mkdir, move, revadd, revlabel, revlog, save, setattribute, startrev, stoprev, unedit, unlock.
action
Methods and extension methods outside of the specified method are subject to the specified action (reset or allow).
reset
Sends a TCP reset notification to the client or server if the HTTP message fails the mode inspection.
allow
Forwards the packet through the firewall.
alarm
(Optional) Generates system logging (syslog) messages for the given action.
Command Default
If a given method is not specified, all methods and extension methods are supported with the reset alarm action.
Usage Guidelines
Only methods configured by the request-method command are allowed thorough the firewall; all other HTTP traffic is subjected to the specified action (reset or allow).
Examples
The following example shows how to define the HTTP application firewall policy “mypolicy.” This policy includes all supported HTTP policy rules. After the policy is defined, it is applied to the inspection rule “firewall,” which will inspect all HTTP traffic entering the FastEthernet0/0 interface.
! Define the HTTP policy. appfw policy-name mypolicy application http strict-http action allow alarm content-length maximum 1 action allow alarm content-type-verification match-req-rsp action allow alarm max-header-length request 1 response 1 action allow alarm max-uri-length 1 action allow alarm port-misuse default action allow alarm request-method rfc default action allow alarm request-method extension default action allow alarm transfer-encoding type default action allow alarm ! ! ! Apply the policy to an inspection rule. ip inspect name firewall appfw mypolicy ip inspect name firewall http ! ! ! Apply the inspection rule to all HTTP traffic entering the FastEthernet0/0 interface. interface FastEthernet0/0 ip inspect firewall in ! !request-queue (GTP)
To specify the number of General Packet Radio Service (GPRS) Tunneling Protocol (GTP) requests that can be queued to wait for a response, use the request-queue command in parameter-map type inspect configuration mode. To remove the specified number of GTP requests queued, use the no form of this command.
Usage Guidelines
The request-queue command specifies the maximum number of GTP requests that can be queued to wait for a response. When the specified maximum limit is reached and a new request arrives, the request that has been in the queue for the longest time is removed. The Error Indication, Version Not Supported, and Serving GPRS Support Node (SGSN) Context Acknowledge messages are considered as requests and these messages will not be part of the request queue.
request-timeout
To set the number of seconds before an authentication request times out, use the request-timeoutcommand in webvpn sso server configuration mode.
Usage Guidelines
This command is useful for networks that are congested and tend to have losses. Corporate networks are generally not affected by congestion or losses.
reset (policy-map)
reset (zone-based policy)
To reset a TCP connection if the data length of the Simple Mail Transfer Protocol (SMTP) body exceeds the value that you configured in the class-map type inspect smtpcommand, use the reset command in policy-map configuration mode.
Usage Guidelines
You can use this command only after entering the policy-map type inspect, class type inspect, and parameter-map type inspect commands.
You can enter reset only for TCP traffic.
Examples
The following example creates a Layer 7 SMTP policy map named mysmtp-policy and applies the reset action to each of the match criteria:
policy-map type inspect smtp mysmtp-policy class-map type inspect smtp huge-mails resetRelated Commands
Command
Description
class type inspect
Specifies the traffic (class) on which an action is to be performed.
parameter-map type inspect
Configures an inspect type parameter map for connecting thresholds, timeouts, and other parameters pertaining to the inspect action.
policy-map type inspect
Creates Layer 3 and Layer 4 inspect type policy maps.
responder-only
To configure a device as responder-only, use the responder-onlycommand in IPsec profile configuration mode. To remove the responder-only setting, use the no form of this command.
Usage Guidelines
NoteSecurity threats, as well as the cryptographic technologies to help protect against them, are constantly changing. For more information about the latest Cisco cryptographic recommendations, see the Next Generation Encryption (NGE) white paper.
This command is relevant only for a virtual interface scenario and is configurable only under an IPsec profile. Neither static nor crypto maps are supported.
retired (IPS)
specify whether or not a retired signature or signature category definition should be saved in the router memory, use the retiredcommand in signature-definition-status (config-sigdef-status) or IPS-category-action (config-ips-category-action) configuration mode. To return to the default action, use the no form of this command.
Command Modes
Signature-definition-status configuration (config-sigdef-status)
IPS-category-action configuration (config-ips-category-action)Usage Guidelines
Router memory and resource constraints prevent a router from loading all Cisco IOS IPS signatures. Thus, it is recommended that you load only a selected set of signatures that are defined by the categories. Because the categories are applied in a “top-down” order, you should first retire all signatures, followed by “unretiring” specific categories. Retiring signatures enables the router to load information for all signatures, but the router will not build the parallel scanning data structure.
Retired signatures are not scanned by Cisco IOS IPS, so they will not fire alarms. If a signature is irrelevant to your network or if you want to save router memory, you should retire signatures, as appropriate.
Examples
The following example shows how to retire all signatures and configure the Basic “ios_ips” category:
Router# configure terminal Enter configuration commands, one per line. End with CNTL/Z. Router(config)# ip ips signature category Router(config-ips-category)# category all Router(config-ips-category-action)# retired true Router(config-ips-category-action)# exit Router(config-ips-category)# category ios_ips basic Router(config-ips-category-action)# retired false Router(config-ips-category-action)# exit Router(config-ips-category)# exit Do you want to accept these changes? [confirm]yRelated Commands
Command
Description
enabled
Changes the enabled status of a given signature or signature category.
signature
Specifies a signature for which the CLI user tunings will be changed.
status
Enters the signature-definition-status configuration mode, which allows you to change the enabled or retired status of an individual signature.
retransmit (config-radius-server)
To specify the number of times a RADIUS request is re-sent to a server when that server is not responding or responding slowly, use the retransmit command in RADIUS server configuration mode. To restore the default value, use the no form of this command.
Usage Guidelines
The Cisco IOS software tries all servers, allowing each one to time out before increasing the retransmit count.
If the RADIUS server is only a few hops from the router, it is recommended that you configure the RADIUS server retransmit rate to 5.
Examples
The following example shows how to specify a retransmit counter value of five times:
Device(config)# aaa new-model Device(config)# radius server myserver Device(config-radius-server)# address ipv4 192.0.2.2 Device(config-radius-server)# retransmit 5reverse-route
To create source proxy information for a crypto map entry, use the reverse-route command in crypto map configuration mode. To remove the source proxy information from a crypto map entry, use the no form of this command.
Effective with Cisco IOS Release 12.4(15)T
reverse-route [ static | remote-peer ip-address [gateway] [static] ]
no reverse-route [ static | remote-peer ip-address [gateway] [static] ]
Before Cisco IOS Release 12.4(15)T
reverse-route [ static | tag tag-id [static] | remote-peer [static] | remote-peer ip-address [static] ]
no reverse-route [ static | tag tag-id [static] | remote-peer [static] | remote-peer ip-address [static] ]
Syntax Description
Command History
Release
Modification
12.1(9)E
This command was introduced.
12.2(8)T
This command was integrated into Cisco IOS Release 12.2(8)T.
12.2(11)T
This command was implemented on the Cisco AS5300 and Cisco AS5800 platforms.
12.2(9)YE
This command was integrated into Cisco IOS Release 12.2(9)YE.
12.2(14)S
This feature was integrated into Cisco IOS Release 12.2(14)S.
12.2(13)T
The remote-peer keyword and ip-address argument were added.
12.3(14)T
The static and tag keywords and tag-id argument were added.
12.2(33)SRA
This command was integrated into Cisco IOS Release 12.2(33)SRA.
12.4(15)T
The tag keyword and tag-id argument were deleted. The gateway keyword was added.
12.2SX
This command is supported in the Cisco IOS Release 12.2SX train. Support in a specific 12.2SX release of this train depends on your feature set, platform, and platform hardware.
Usage Guidelines
NoteSecurity threats, as well as the cryptographic technologies to help protect against them, are constantly changing. For more information about the latest Cisco cryptographic recommendations, see the Next Generation Encryption (NGE) white paper.
This command can be applied on a per-crypto map basis.
Reverse route injection (RRI) provides a scalable mechanism to dynamically learn and advertise the IP address and subnets that belong to a remote site that connects through an IPsec VPN tunnel.
When enabled in an IPSec crypto map, RRI will learn all the subnets from any network that is defined in the crypto ACL as the destination network. The learned routes are installed into the local routing table as static routes that point to the encrypted interface. When the IPsec tunnel is torn down, the associated static routes will be removed. These static routes may then be redistributed into other dynamic routing protocols so that they can be advertised to other parts of the network (usually done by redistributing RRI routes into dynamic routing protocols on the core side).
The remote-peer keyword is required when RRI is performed in a VRF-Aware IPsec scenario.
Examples
The following example shows how to configure RRI when crypto ACLs exist. The example shows that all remote VPN gateways connect to the router via 192.168.0.3. RRI is added on the static crypto map, which creates routes on the basis of the source network and source netmask that are defined in the crypto ACL.
crypto map mymap 1 ipsec-isakmp set peer 10.1.1.1 reverse-route set transform-set esp-3des-sha match address 102 Interface FastEthernet 0/0 ip address 192.168.0.2 255.255.255.0 standby name group1 standby ip 192.168.0.3 crypto map mymap redundancy group1 access-list 102 permit ip 192.168.1.0 0.0.0.255 10.0.0.0 0.0.255.255
NoteIn Cisco IOS Release 12.3(14)T and later releases, for the static map to retain this same behavior of creating routes on the basis of crypto ACL content, the static keyword will be necessary, that is, reverse-route static.
The reverse-route command in this situation creates routes that are analogous to the following static route CLI (ip route):
ip route 10.1.1.1 255.255.255.255 192.168.1.1ip route 10.1.1.1 255.255.255.255 vlan0.1In the following example, two routes are created, one for the remote endpoint and one for route recursion to the remote endpoint via the interface on which the crypto map is configured.
reverse-route remote-peerExamples
The following configuration example shows how to configure RRI for a situation in which there are existing ACLs:
crypto map mymap 1 ipsec-isakmp set peer 172.17.11.1 reverse-route static set transform-set esp-3des-sha match address 101 access-list 101 permit ip 192.168.1.0 0.0.0.255 172.17.11.0 0.0.0.255The following example shows how RRI-created routes can be tagged with a tag number and then used by a routing process to redistribute those tagged routes via a route map:
crypto dynamic-map ospf-clients 1 reverse-route tag 5 router ospf 109 redistribute rip route-map rip-to-ospf route-map rip-to-ospf permit match tag 5 set metric 5 set metric-type type1 Device# show ip ospf topology P 10.81.7.48/29, 1 successors, FD is 2588160, tag is 5 via 192.168.82.25 (2588160/2585600), FastEthernet0/1The following example shows that one route has been created to the remote proxy via a user-defined next hop. This next hop should not require a recursive route lookup unless it will recurse to a default route.
reverse-route remote-peer 10.4.4.4The previous example yields the following before Cisco IOS Release 12.3(14)T:
10.0.0.0/24 via 10.1.1.1 (in the VRF table if VRFs are configured) 10.1.1.1/32 via 10.4.4.4 (in the global route table)And this result occurs with RRI enhancements:
10.0.0.0/24 via 10.4.4.4 (in the VRF table if VRFs are configured, otherwise in the global table)Examples
In the following example, routes are created from the destination information in the access control list (ACL). One route will list 10.2.2.2 as the next-hop route to the ACL information, and one will indicate that to get to 10.2.2.2, the route will have to go via 10.1.1.1. All routes will have a metric of 10. Routes are created only at the time the map and specific ACL rule are created.
crypto map map1 1 ipsec-isakmp set peer 10.2.2.2 reverse-route remote-peer 10.1.1.1 gateway set reverse-route distance 10 match address 101 Configuring RRI with Route Tags 12.4(15)T or later: ExampleThe following example shows how RRI-created routes can be tagged with a tag number and then used by a routing process to redistribute those tagged routes via a route map:
crypto dynamic-map ospf-clients 1 set reverse-route tag 5 router ospf 109 redistribute rip route-map rip-to-ospf route-map rip-to-ospf permit match tag 5 set metric 5 set metric-type type1 Device# show ip ospf topology P 10.81.7.48/29, 1 successors, FD is 2588160, tag is 5 via 192.168.82.25 (2588160/2585600), FastEthernet0/1Related Commands
Command
Description
crypto map (global IPSec)
Creates or modifies a crypto map entry and enters the crypto map configuration mode.
crypto map local-address
Specifies and names an identifying interface to be used by the crypto map for IPsec traffic.
show crypto map (IPSec)
Displays the crypto map configuration.
revocation-check
To check the revocation status of a certificate, use the revocation-checkcommand in ca-trustpoint configuration mode. To disable this functionality, use the no form of this command.
Syntax Description
method1 [method2 method3]]
Method used by the router to check the revocation status of the certificate. Available methods are as follows:
- crl --Certificate checking is performed by a certificate revocation list (CRL). This is the default behavior.
- none --Certificate checking is not required.
- ocsp --Certificate checking is performed by an online certificate status protocol (OCSP) server.
If a second and third method are specified, each method will be used only if the previous method returns an error, such as a server being down.
Command Default
After a trustpoint is enabled, the default is set to revocation-check crl, which means that CRL checking is mandatory.
Command History
Release
Modification
12.3(2)T
This command was introduced. This command replaced the crl best-effort and crl optionalcommands.
12.2(33)SRA
This command was integrated into Cisco IOS release 12.(33)SRA.
12.2SX
This command is supported in the Cisco IOS Release 12.2SX train. Support in a specific 12.2SX release of this train depends on your feature set, platform, and platform hardware.
12.4(24)T
Support for IPv6 Secure Neighbor Discovery (SeND) was added.
Usage Guidelines
Use the revocation-check command to specify at least one method that is to be used to ensure that the certificate of a peer has not been revoked.
If your router does not have the applicable CRL and is unable to obtain one or if the OCSP server returns an error, your router will reject the peer’s certificate--unless you include the none keyword in your configuration. If the none keyword is configured, a revocation check will not be performed and the certificate will always be accepted. If the revocation-check none command is configured, you cannot manually download the CRL via the crypto pki crl requestcommand because the manually downloaded CRL may not be deleted after it expires. The expired CRL can cause all certificate verifications to be denied.
NoteThe none keyword replaces the optional keyword that is available from the crl command. If you enter the crl optionalcommand, it will be written back as the revocation-check nonecommand. However, there is a difference between the crl optional command and the revocation-check nonecommand. The crl optional command will perform revocation checks against any applicable in-memory CRL. If a CRL is not available, a CRL will not be downloaded and the certificate is treated as valid; the revocation-check none command ignores the revocation check completely and always treats the certificate as valid. Also, the crl and none keywords issued together replace the best-effort keyword that is available from the crl command. If you enter the crl best-effortcommand, it will be written back as the revocation-check crl nonecommand.
Examples
The following example shows how to configure the router to use the OCSP server that is specified in the AIA extension of the certificate:
Router(config)# crypto pki trustpoint mytp Router(ca-trustpoint)# revocation-check ocspThe following example shows how to configure the router to download the CRL from the CDP; if the CRL is unavailable, the OCSP server that is specified in the Authority Info Access (AIA) extension of the certificate will be used. If both options fail, certificate verification will also fail.
Router(config)# crypto pki trustpoint mytp Router(ca-trustpoint)# revocation-check crl ocspThe following example shows how to configure your router to use the OCSP server at the HTTP URL “http://myocspserver:81.” If the server is down, revocation check will be ignored.
Router(config)# crypto pki trustpoint mytp Router(ca-trustpoint)# ocsp url http://myocspserver:81 Router(ca-trustpoint)# revocation-check ocsp nonerevocation-check (ca-trustpool)
To disable a revocation checking method when the public key infrastructure (PKI) trustpool policy is being used, use the revocation-check command in ca-trustpool configuration mode. To return to the default, use the no form of this command.
Syntax Description
method1 [method2 method3]]
Method used by the router to check the revocation status of the certificate. Available methods are identified by the following keywords:
- crl--Certificate checking is performed by a certificate revocation list (CRL). This is the default behavior.
- none --Certificate checking is not required.
- ocsp--Certificate checking is performed by an online certificate status protocol (OCSP) server.
If a second and third method are specified, each method is used only if the previous method returns an error, such as a server being down.
Usage Guidelines
Before you can configure this command, you must enable the crypto pki trustpool policy command, which enters ca-trustpool configuration mode.
If a revocation policy needs to be altered for specific certificate authority (CA) certificates in the PKI trustpool, use certificate maps instead.
Examples
The revocation-check command in following example disables both CRL and OCSP revocation checks:
Router(config)# crypto pki trustpool policy Router(ca-trustpool)# revocation-check ocsp crl noneRelated Commands
Command
Description
cabundle url
Configures the URL from which the PKI trustpool CA bundle is downloaded.
chain-validation
Enables chain validation from the peer's certificate to the root CA certificate in the PKI trustpool.
crl
Specifes the CRL query and cache options for the PKI trustpool.
crypto pki trustpool import
Manually imports (downloads) the CA certificate bundle into the PKI trustpool to update or replace the existing CA bundle.
crypto pki trustpool policy
Configures PKI trustpool policy parameters.
default
Resets the value of a ca-trustpool configuration subcommand to its default.
match
Enables the use of certificate maps for the PKI trustpool.
ocsp
Specifies OCSP settings for the PKI trustpool.
show
Displays the PKI trustpool policy of the router in ca-trustpool configuration mode.
show crypto pki trustpool
Displays the PKI trustpool certificates of the router and optionally shows the PKI trustpool policy.
source interface
Specifies the source interface to be used for CRL retrieval, OCSP status, or the downloading of a CA certificate bundle for the PKI trustpool.
storage
Specifies a file system location where PKI trustpool certificates are stored on the router.
vrf
Specifies the VRF instance to be used for CRL retrieval.
root
To obtain the certification authority (CA) certificate via TFTP, use the root command in ca-trustpoint configuration mode. To deconfigure the CA, use the no form of this command.
Command History
Release
Modification
12.2(8)T
This command was introduced.
12.2(18)SXD
This command was integrated into Cisco IOS Release 12.2(18)SXD.
12.2(33)SRA
This command was integrated into Cisco IOS release 12.(33)SRA.
12.2SX
This command is supported in the Cisco IOS Release 12.2SX train. Support in a specific 12.2SX release of this train depends on your feature set, platform, and platform hardware.
Usage Guidelines
This command allows you to access the CA via the TFTP protocol, which is used to get the CA. You want to configure a CA certificate so that your router can verify certificates issued to peers. Thus, your router does not have to enroll with the CA that issued the certificates the peers.
Before you can configure this command, you must enable the crypto ca trustpointcommand , which puts you in ca-trustpoint configuration mode.
NoteThe crypto ca trustpointcommanddeprecates the crypto ca identityand crypto ca trusted-rootcommands and all related subcommands (all ca-identity and trusted-root configuration mode commands). If you enter a ca-identity or trusted-root subcommand, theconfiguration mode and command will be written back as ca-trustpoint.
route accept
To filter the routes received from the peer and save the routes on the router based on the specified values, use the route accept command in IKEv2 authorization policy configuration mode. To reject the routes , use the no form of this command.
Usage Guidelines
Before using the route accept command, you must first configure the crypto ikev2 authorization policy command.
route set
To specify the route set parameters to the peer via configuration mode, use the route set command in IKEv2 authorization policy configuration mode. To disable, use the no form of this command.
route set { interface interface | access-list { access-list-name | access-list-number | expanded-access-list-number | ipv6 access-list-name } }
no route set { interface | access-list { access-list-name | access-list-number | expanded-access-list-number | ipv6 access-list-name } }
Syntax Description
interface interface Specifies the route interface.
access-list Specifies the route access list.
access-list-name Specifies the access list name.
access-list-number Specifies the standard access list number. The range is from 1 to 99.
expanded-access-list-number Specifies the expanded access list number. The range is from 1300 to 1999.
ipv6 Specifies an IPv6 access list.
Usage Guidelines
Before using the route set command, you must first configure the crypto ikev2 authorization policy command. This command allows running routing protocols such as BGP over VPN.
route set remote
To push route set parameters to be pushed to the remote peer via configuration mode, use the route set remote command in IKEv2 authorization policy configuration mode. To disable, use the no form of this command.
route set remote { ipv4ip-address mask | ipv6ip-address/mask }
no route set remote { ipv4ip-address mask | ipv6ip-address/mask }
Usage Guidelines
Before using the route set remote command, you must first configure the crypto ikev2 authorization policy command.
router-preference maximum
To verify the advertised default router preference parameter value, use the router-preference maximum command in RA guard policy configuration mode.
Usage Guidelines
The router-preference maximum command enables verification that the advertised default router preference parameter value is lower than or equal to a specified limit. You can use this command to give a lower priority to default routers advertised on trunk ports, and to give precedence to default routers advertised on access ports.
The router-preference maximum command limit are high, medium, or low. If, for example, this value is set to medium and the advertised default router preference is set to high in the received packet, then the packet is dropped. If the command option is set to medium or low in the received packet, then the packet is not dropped.
Examples
The following example shows how the command defines a router advertisement (RA) guard policy name as raguard1, places the router in RA guard policy configuration mode, and configures router-preference maximum verification to be high:
Router(config)# ipv6 nd raguard policy raguard1 Router(config-ra-guard)# router-preference maximum highrsakeypair
To specify which Rivest, Shamir, and Adelman (RSA) key pair to associate with the certificate, use the rsakeypair command in ca-trustpoint configuration mode.
Syntax Description
key-label
Name of the key pair, which is generated during enrollment if it does not already exist or if the auto-enroll regenerate command is configured.
key-size
(Optional) Size of the desired Rivest, Shamir, Adelman (RSA) key pair. If the size is not specified, the existing key size is used.
encryption-key-size
(Optional) Size of the second key, which is used to request separate encryption, signature keys, and certificates.
Usage Guidelines
NoteSecurity threats, as well as the cryptographic technologies to help protect against them, are constantly changing. For more information about the latest Cisco cryptographic recommendations, see the Next Generation Encryption (NGE) white paper.
When you regenerate a key pair, you are responsible for reenrolling the identities associated with the key pair. Use the rsakeypair command to refer back to the named key pair.
rsa-pubkey
To define the Rivest, Shamir, and Adelman (RSA) manual key to be used for encryption or signature during Internet Key Exchange (IKE) authentication, use the rsa-pubkeycommand in keyring configuration mode. To remove the manual key that was defined, use the no form of this command.
rsa-pubkey { address address | name fqdn } [ encryption | signature ]
no rsa-pubkey { address address | name fqdn } [ encryption | signature ]
Usage Guidelines
Use this command to enter public key chain configuration mode. Use this command when you need to manually specify RSA public keys of other IP Security (IPSec) peers. You need to specify the keys of other peers when you configure RSA encrypted nonces as the authentication method in an IKE policy at your peer router.
Examples
The following example shows that the RSA public key of an IPSec peer has been specified:
Router(config)# crypto keyring vpnkeyring Router(conf-keyring)# rsa-pubkey name host.vpn.com Router(config-pubkey-key)# address 10.5.5.1 Router(config-pubkey)# key-string Router(config-pubkey)# 00302017 4A7D385B 1234EF29 335FC973 Router(config-pubkey)# 2DD50A37 C4F4B0FD 9DADE748 429618D5 Router(config-pubkey)# 18242BA3 2EDFBDD3 4296142A DDF7D3D8 Router(config-pubkey)# 08407685 2F2190A0 0B43F1BD 9A8A26DB Router(config-pubkey)# 07953829 791FCDE9 A98420F0 6A82045B Router(config-pubkey)# 90288A26 DBC64468 7789F76E EE21 Router(config-pubkey)# quit Router(config-pubkey-key)# exit Router(conf-keyring)# exit
