Implementing Secure Shell
Secure Shell (SSH) is an application and a protocol that provides a secure replacement to the Berkeley r-tools. The protocol secures sessions using standard cryptographic mechanisms, and the application can be used similarly to the Berkeley rexec and rsh tools.
Two versions of the SSH server are available: SSH Version 1 (SSHv1) and SSH Version 2 (SSHv2). SSHv1 uses Rivest, Shamir, and Adelman (RSA) keys and SSHv2 uses either Digital Signature Algorithm (DSA) keys or Rivest, Shamir, and Adelman (RSA) keys, or Elliptic Curve Digital Signature Algorithm (ECDSA) keys. Cisco software supports both SSHv1 and SSHv2.
This module describes how to implement Secure Shell.
Information About Implementing Secure Shell
To implement SSH, you should understand the following concepts:
SSH Server
The SSH server feature enables an SSH client to make a secure, encrypted connection to a Cisco router. This connection provides functionality that is similar to that of an inbound Telnet connection. Before SSH, security was limited to Telnet security. SSH allows a strong encryption to be used with the Cisco software authentication. The SSH server in Cisco software works with publicly and commercially available SSH clients.
SSH Client
The SSH client feature is an application running over the SSH protocol to provide device authentication and encryption. The SSH client enables a Cisco router to make a secure, encrypted connection to another Cisco router or to any other device running the SSH server. This connection provides functionality that is similar to that of an outbound Telnet connection except that the connection is encrypted. With authentication and encryption, the SSH client allows for a secure communication over an insecure network.
The SSH client works with publicly and commercially available SSH servers. The SSH client supports the ciphers of AES, 3DES, message digest algorithm 5 (MD5), SHA1, and password authentication. User authentication is performed in the Telnet session to the router. The user authentication mechanisms supported for SSH are RADIUS, TACACS+, and the use of locally stored usernames and passwords.
The SSH client supports setting DSCP value in the outgoing packets.
ssh client dscp <value from 0 – 63>
If not configured, the default DSCP value set in packets is 16 (for both client and server).
The SSH client supports the following options:
- DSCP—DSCP value for SSH
client sessions.
RP/0/5/CPU0:router#configure RP/0/5/CPU0:router(config)#ssh ? client Provide SSH client service server Provide SSH server service timeout Set timeout value for SSH RP/0/5/CPU0:router(config)#ssh client ?
- Knownhost—Enable the host pubkey check by local database.
- Source-interface—Source
interface for SSH client sessions.
RP/0/5/CPU0:router(config)#ssh client source-interface ? ATM ATM Network Interface(s) BVI Bridge-Group Virtual Interface Bundle-Ether Aggregated Ethernet interface(s) CEM Circuit Emulation interface(s) GigabitEthernet GigabitEthernet/IEEE 802.3 interface(s) IMA ATM Network Interface(s) IMtestmain IM Test Interface Loopback Loopback interface(s) MgmtEth Ethernet/IEEE 802.3 interface(s) Multilink Multilink network interface(s) Null Null interface PFItestmain PFI Test Interface PFItestnothw PFI Test Not-HW Interface PW-Ether PWHE Ethernet Interface PW-IW PWHE VC11 IP Interworking Interface Serial Serial network interface(s) VASILeft VASI Left interface(s) VASIRight VASI Right interface(s) test-bundle-channel Aggregated Test Bundle interface(s) tunnel-ipsec IPSec Tunnel interface(s) tunnel-mte MPLS Traffic Engineering P2MP Tunnel interface(s) tunnel-te MPLS Traffic Engineering Tunnel interface(s) tunnel-tp MPLS Transport Protocol Tunnel interface RP/0/5/CPU0:router(config)#ssh client source-interface RP/0/5/CPU0:router(config)#
RP/0/5/CPU0:router#ssh ?
A.B.C.D IPv4 (A.B.C.D) address
WORD Hostname of the remote node
X:X::X IPv6 (A:B:C:D...:D) address
vrf vrf table for the route lookup
RP/0/5/CPU0:router#ssh 10.1.1.1 ?
cipher Accept cipher type
command Specify remote command (non-interactive)
source-interface Specify source interface
username Accept userid for authentication
<cr>
RP/0/5/CPU0:router#ssh 192.68.46.6 username admin command "show redundancy sum"
Password:
Wed Jan 9 07:05:27.997 PST
Active Node Standby Node
----------- ------------
0/4/CPU0 0/5/CPU0 (Node Ready, NSR: Not Configured)
RP/0/5/CPU0:router#
SFTP Feature Overview
SSH includes support for standard file transfer protocol (SFTP) , a new standard file transfer protocol introduced in SSHv2. This feature provides a secure and authenticated method for copying router configuration or router image files.
The SFTP client functionality is provided as part of the SSH component and is always enabled on the router. Therefore, a user with the appropriate level can copy files to and from the router. Like the copy command, the sftp command can be used only in XR EXEC mode.
The SFTP client is VRF-aware, and you may configure the secure FTP client to use the VRF associated with a particular source interface during connections attempts. The SFTP client also supports interactive mode, where the user can log on to the server to perform specific tasks via the Unix server.
The SFTP Server is a sub-system of the SSH server. In other words, when an SSH server receives an SFTP server request, the SFTP API creates the SFTP server as a child process to the SSH server. A new SFTP server instance is created with each new request.
The SFTP requests for a new SFTP server in the following steps:
-
The user runs the sftp command with the required arguments
-
The SFTP API internally creates a child session that interacts with the SSH server
-
The SSH server creates the SFTP server child process
-
The SFTP server and client interact with each other in an encrypted format
-
The SFTP transfer is subject to LPTS policer "SSH-Known". Low policer values will affect SFTP transfer speeds
Note |
In IOS-XR SW release 4.3.1 onwards the default policer value for SSH-Known has been reset from 2500pps to 300pps. Slower transfers are expected due to this change. You can adjust the lpts policer value for this punt cause to higher values that will allow faster transfers |
When the SSH server establishes a new connection with the SSH client, the server daemon creates a new SSH server child process. The child server process builds a secure communications channel between the SSH client and server via key exchange and user authentication processes. If the SSH server receives a request for the sub-system to be an SFTP server, the SSH server daemon creates the SFTP server child process. For each incoming SFTP server subsystem request, a new SSH server child and a SFTP server instance is created. The SFTP server authenticates the user session and initiates a connection. It sets the environment for the client and the default directory for the user.
Once the initialization occurs, the SFTP server waits for the SSH_FXP_INIT message from the client, which is essential to start the file communication session. This message may then be followed by any message based on the client request. Here, the protocol adopts a 'request-response' model, where the client sends a request to the server; the server processes this request and sends a response.
The SFTP server displays the following responses:
-
Status Response
-
Handle Response
-
Data Response
-
Name Response
Note |
The server must be running in order to accept incoming SFTP connections. |
RSA Based Host Authentication
Verifying the authenticity of a server is the first step to a secure SSH connection. This process is called the host authentication, and is conducted to ensure that a client connects to a valid server.
The host authentication is performed using the public key of a server. The server, during the key-exchange phase, provides its public key to the client. The client checks its database for known hosts of this server and the corresponding public-key. If the client fails to find the server's IP address, it displays a warning message to the user, offering an option to either save the public key or discard it. If the server’s IP address is found, but the public-key does not match, the client closes the connection. If the public key is valid, the server is verified and a secure SSH connection is established.
The IOS XR SSH server and client had support for DSA based host authentication. But for compatibility with other products, like IOS, RSA based host authentication support is also added.
RSA Based User Authentication
One of the method for authenticating the user in SSH protocol is RSA public-key based user authentication. The possession of a private key serves as the authentication of the user. This method works by sending a signature created with a private key of the user. Each user has a RSA keypair on the client machine. The private key of the RSA keypair remains on the client machine.
The user generates an RSA public-private key pair on a unix client using a standard key generation mechanism such as ssh-keygen. The max length of the keys supported is 4096 bits, and the minimum length is 512 bits. The following example displays a typical key generation activity:
bash-2.05b$ ssh-keygen –b 1024 –t rsa
Generating RSA private key, 1024 bit long modulus
The public key must be in base64 encoded (binary) formats for it to be imported correctly into the router.
Note |
You can use third party tools available on the Internet to convert the key to the binary format. |
Once the public key is imported to the router, the SSH client can choose to use the public key authentication method by specifying the request using the “-o” option in the SSH client. For example:
client$ ssh -o PreferredAuthentications=publickey 1.2.3.4
If a public key is not imported to a router using the RSA method, the SSH server initiates the password based authentication. If a public key is imported, the server proposes the use of both the methods. The SSH client then chooses to use either method to establish the connection. The system allows only 10 outgoing SSH client connections.
Currently, only SSH version 2 and SFTP server support the RSA based authentication.
Note |
The preferred method of authentication would be as stated in the SSH RFC. The RSA based authentication support is only for local authentication, and not for TACACS/RADIUS servers. |
Authentication, Authorization, and Accounting (AAA) is a suite of network security services that provide the primary framework through which access control can be set up on your Cisco router or access server.
SSHv2 Client Keyboard-Interactive Authentication
An authentication method in which the authentication information is entered using a keyboard is known as keyboard-interactive authentication. This method is an interactive authentication method in the SSH protocol. This type of authentication allows the SSH client to support different methods of authentication without having to be aware of their underlying mechanisms.
Currently, the SSHv2 client supports the keyboard-interactive authentication. This type of authentication works only for interactive applications.
Note |
The password authentication is the default authentication method. The keyboard-interactive authentication method is selected if the server is configured to support only the keyboard-interactive authentication. |
Prerequisites for Implementing Secure Shell
The following prerequisites are required to implement Secure Shell:
-
Download the required image on your router. The SSH server and SSH client require you to have a a crypto package (data encryption standard [DES], 3DES and AES) from Cisco downloaded on your router.
Note
From Cisco IOS XR Software Release 7.0.1 and later, the SSH and SFTP components are available in the baseline Cisco IOS XR software image itself. For details, see, SSH and SFTP in Baseline Cisco IOS XR Software Image.
-
Configure user authentication for local or remote access. You can configure authentication with or without authentication, authorization, and accounting (AAA).
-
AAA authentication and authorization must be configured correctly for Secure Shell File Transfer Protocol (SFTP) to work.
SSH and SFTP in Baseline Cisco IOS XR Software Image
From Cisco IOS XR Software Release 7.0.1 and later, the management plane and control plane components that were part of the Cisco IOS XR security package (k9sec package) are moved to the base Cisco IOS XR software image. These include SSH, SCP and SFTP. However, 802.1X protocol (Port-Based Network Access Control) and data plane components remain as a part of the security package as per the export compliance regulations.This segregation of package components makes the software more modular. It also gives you the flexibility of including or excluding the security package as per your requirements.
The base package and the security package allow FIPS, so that the control plane can negotiate FIPS-approved algorithms.
Restrictions for Implementing Secure Shell
The following are some basic SSH restrictions and limitations of the SFTP feature:
-
In order for an outside client to connect to the router, the router needs to have an RSA (for SSHv1 or SSHv2) or DSA (for SSHv2) or ECDSA (for SSHv2) key pair configured. ECDSA, DSA and RSA keys are not required if you are initiating an SSH client connection from the router to an outside routing device. The same is true for SFTP: ECDSA, DSA and RSA keys are not required because SFTP operates only in client mode.
-
In order for SFTP to work properly, the remote SSH server must enable the SFTP server functionality. For example, the SSHv2 server is configured to handle the SFTP subsystem with a line such as /etc/ssh2/sshd2_config:
-
subsystem-sftp /usr/local/sbin/sftp-server
-
The SFTP server is usually included as part of SSH packages from public domain and is turned on by default configuration.
-
SFTP is compatible with sftp server version OpenSSH_2.9.9p2 or higher.
-
RSA-based user authentication is supported in the SSH and SFTP servers. The support however, is not extended to the SSH client.
-
Execution shell and SFTP are the only applications supported.
-
The SFTP client does not support remote filenames containing wildcards (* ?, []). The user must issue the sftp command multiple times or list all of the source files from the remote host to download them on to the router. For uploading, the router SFTP client can support multiple files specified using a wildcard provided that the issues mentioned in the first through third bullets in this section are resolved.
-
The cipher preference for the SSH server follows the order AES128, AES192, AES256, and, finally, 3DES. The server rejects any requests by the client for an unsupported cipher, and the SSH session does not proceed.
-
Use of a terminal type other than vt100 is not supported, and the software generates a warning message in this case.
-
Password messages of “none” are unsupported on the SSH client.
-
Files created on the local device lose the original permission information because the router infrastructure does not provide support for UNIX-like file permissions. For files created on the remote file system, the file permission adheres to the umask on the destination host and the modification and last access times are the time of the copy.
Configure SSH
Perform this task to configure SSH.
Note |
For SSHv1 configuration, Step 1 to Step 4 are required. For SSHv2 configuration, Step to Step 4 are optional. |
Note |
From Cisco IOS XR Software Release 7.0.1 and later, the SSH host-key pairs are auto-generated at the time of router boot up. Hence you need not perform steps 5 to 7 to generate the host keys explicilty. See, Automatic Generation of SSH Host-Key Pairs for details. |
Procedure
Step 1 |
configure Example:
Enters mode. |
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Step 2 |
hostname hostname Example:
Configures a hostname for your router. |
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Step 3 |
domain name domain-name Example:
Defines a default domain name that the software uses to complete unqualified host names. |
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Step 4 |
Use the commit or end command. commit —Saves the configuration changes and remains within the configuration session.
|
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Step 5 |
crypto key generate rsa [usage keys | general-keys] [keypair-label] Example:
Generates an RSA key pair. The RSA key modulus can be in the range of 512 to 4096 bits.
|
||
Step 6 |
crypto key generate dsa Example:
Enables the SSH server for local and remote authentication on the router. The supported key sizes are: 512, 768 and 1024 bits.
|
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Step 7 |
crypto key generate ecdsa [nistp256 | nistp384 | nistp521] Example:
Generates an ECDSA key pair. The supported ECDSA curve types are: Nistp256, Nistp384 and Nistp521.
|
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Step 8 |
configure Example:
Enters mode. |
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Step 9 |
ssh timeout seconds Example:
(Optional) Configures the timeout value for user authentication to AAA.
|
||
Step 10 |
Do one of the following:
Example:
|
||
Step 11 |
Use the commit or end command. commit —Saves the configuration changes and remains within the configuration session.
|
||
Step 12 |
show ssh Example:
(Optional) Displays all of the incoming and outgoing SSHv1 and SSHv2 connections to the router. |
||
Step 13 |
show ssh session details Example:
(Optional) Displays a detailed report of the SSHv2 connections to and from the router. |
||
Step 14 |
show ssh history Example:
(Optional) Displays the last hundred SSH connections that were terminated. |
||
Step 15 |
show ssh history details Example:
(Optional) Displays the last hundred SSH connections that were terminated with additional details. This command is similar to show ssh session details command but also mentions the start and end time of the session. |
||
Step 16 |
show tech-support ssh Example:
(Optional) Automatically runs the |
Note |
The order of priority while doing negotiation for a SSH connection is as follows:
|
Automatic Generation of SSH Host-Key Pairs
This feature brings in the functionality of automatically generating the SSH host-key pairs for the DSA, ECDSA (such as ecdsa-nistp256 , ecdsa-nistp384 , and ecdsa-nistp521 ) and RSA algorithms. This in turn eliminates the need for explicitly generating each SSH host-key pair after the router boots up. Because the keys are already present in the system, the SSH client can establish connection with the SSH server soon after the router boots up with the basic SSH configuration. This is useful especially during zero touch provisioning (ZTP) and Golden ISO boot up scenarios.
Before this automation, you had to execute the crypto key generate command to generate the required host-key pairs.
Although the host-key pairs are auto-generated with the introduction of this feature, you still have the flexibility to select only the required algorithms on the SSH server. You can use the ssh server algorithms host-key command in XR Config mode to achieve the same. Alternatively, you can also use the existing crypto key zeroize command in XR EXEC mode to remove the algorithms that are not required.
Prior to the introduction of this feature, you had to execute the crypto key generate command in XR EXEC mode to generate the required host-key pairs.
Note |
In a system upgrade scenario from version 1 to version 2, the system does not generate the SSH host-key pairs automatically if they were already generated in version 1. The host-key pairs are generated automatically only if they were not generated in version 1. |
Configure the Allowed SSH Host-Key Pair Algorithms
When the SSH client attempts a connection with the SSH server, it sends a list of SSH host-key pair algorithms (in the order of preference) internally in the connection request. The SSH server, in turn, picks the first matching algorithm from this request list. The server establishes a connection only if that host-key pair is already generated in the system, and if it is configured (using the ssh server algorithms host-key command) as the allowed algorithm.
Note |
If this configuration of allowed host-key pairs is not present in the SSH server, then you can consider that the SSH server allows all host-key pairs. In that case, the SSH client can connect with any one of the host-key pairs. Not having this configuration also ensures backward compatibility in system upgrade scenarios. |
Configuration Example
You may perform this (optional) task to specify the allowed SSH host-key pair algorithm (in this example, ecdsa ) from the list of auto-generated host-key pairs on the SSH server:
/* Example to select the ecdsa algorithm */
Router(config)#ssh server algorithms host-key ecdsa-nistp521
Similarly, you may configure other algorithms.
Running Configuration
ssh server algorithms host-key ecdsa-nistp521
!
Verify the SSH Host-Key Pair Algorithms
Note |
With the introduction of the automatic generation of SSH host-key pairs, the output of the show crypto key mypubkey command displays key information of all the keys that are auto-generated. Before its introduction, the output of this show command displayed key information of only those keys that you explicitly generated using the crypto key generate command. |
Router#show crypto key mypubkey ecdsa
Mon Nov 19 12:22:51.762 UTC
Key label: the_default
Type : ECDSA General Curve Nistp256
Degree : 256
Created : 10:59:08 UTC Mon Nov 19 2018
Data :
04AC7533 3ABE7874 43F024C1 9C24CC66 490E83BE 76CEF4E2 51BBEF11 170CDB26
14289D03 6625FC4F 3E7F8F45 0DA730C3 31E960FE CF511A05 2B0AA63E 9C022482
6E
Key label: the_default
Type : ECDSA General Curve Nistp384
Degree : 384
Created : 10:59:08 UTC Mon Nov 19 2018
Data :
04B70BAF C096E2CA D848EE72 6562F3CC 9F12FA40 BE09BFE6 AF0CA179 F29F6407
FEE24A43 84C5A5DE D7912208 CB67EE41 58CB9640 05E9421F 2DCDC41C EED31288
6CACC8DD 861DC887 98E535C4 893CB19F 5ED3F6BC 2C90C39B 10EAED57 87E96F78
B6
Key label: the_default
Type : ECDSA General Curve Nistp521
Degree : 521
Created : 10:59:09 UTC Mon Nov 19 2018
Data :
0400BA39 E3B35E13 810D8AE5 260B8047 84E8087B 5137319A C2865629 8455928F
D3D9CE39 00E097FF 6CA369C3 EE63BA57 A4C49C02 B408F682 C2153B7F AAE53EF8
A2926001 EF113896 5F1DA056 2D62F292 B860FDFB 0314CE72 F87AA2C9 D5DD29F4
DA85AE4D 1CA453AC 412E911A 419E9B43 0A13DAD3 7B7E88E4 7D96794B 369D6247
E3DA7B8A 5E
Related Topics
Automatic Generation of SSH Host-Key PairsAssociated Commands
-
ssh server algorithms host-key
-
show crypto key mypubkey
Configure SSH Client
Perform this task to configure an SSH client.
Procedure
Step 1 |
configure Example:
Enters mode. |
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Step 2 |
ssh client knownhost device : /filename Example:
(Optional) Enables the feature to authenticate and check the server public key (pubkey) at the client end.
|
||
Step 3 |
Use the commit or end command. commit —Saves the configuration changes and remains within the configuration session.
|
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Step 4 |
ssh {ipv4-address | ipv6-address | hostname} [ username user- cipher | source-interface type instance] Enables an outbound SSH connection.
|
-
If you are using SSHv1 and your SSH connection is being rejected, the reason could be that the RSA key pair might have been zeroed out. Another reason could be that the SSH server to which the user is connecting to using SSHv1 client does not accept SSHv1 connections. Make sure that you have specified a hostname and domain. Then use the crypto key generate rsa command to generate an RSA host-key pair, and then enable the SSH server.
-
If you are using SSHv2 and your SSH connection is being rejected, the reason could be that the DSA, RSA host-key pair might have been zeroed out. Make sure you follow similar steps as mentioned above to generate the required host-key pairs, and then enable the SSH server.
- When configuring the ECDSA, RSA or DSA key pair, you might encounter the following error messages:
-
No hostname specified
You must configure a hostname for the router using the hostname command.
-
No domain specified
You must configure a host domain for the router using the domain-name command.
-
-
The number of allowable SSH connections is limited to the maximum number of virtual terminal lines configured for the router. Each SSH connection uses a vty resource.
-
SSH uses either local security or the security protocol that is configured through AAA on your router for user authentication. When configuring AAA, you must ensure that the console is not running under AAA by applying a keyword in the global configuration mode to disable AAA on the console.
Note
If you are using Putty version 0.63 or higher to connect to the SSH client, set the 'Chokes on PuTTYs SSH2 winadj request' option under SSH > Bugs in your Putty configuration to 'On.' This helps avoid a possible breakdown of the session whenever some long output is sent from IOS XR to the Putty client.
Configuring Secure Shell
The following example shows how to configure SSHv2 by creating a hostname, defining a domain name, enabling the SSH server for local and remote authentication on the router by generating a DSA key pair, bringing up the SSH server, and saving the configuration commands to the running configuration file.
After SSH has been configured, the SFTP feature is available on the router.
From Cisco IOS XR Software Release 7.0.1 and later, the crypto keys are auto-generated at the time of router boot up. Hence, you need to explicitly generate the host-key pair only if it is not present in the router under some scenarios.
configure
hostname router1
domain name cisco.com
exit
crypto key generate rsa/dsa
configure
ssh server
end
SSH Configuration Option to Restrict Cipher Public Key and HMAC Algorithm
The Cisco IOS XR software provides a new configuration option to control the key algorithms to be negotiated with the peer while establishing an SSH connection with the router. With this feature, you can enable the insecure SSH algorithms on the SSH server, which are otherwise disabled by default. A new configuration option is also available to restrict the SSH client from choosing the HMAC, or hash-based message authentication codes algorithm while trying to connect to the SSH server on the router.
You can also configure a list of ciphers as the default cipher list, thereby having the flexibility to enable or disable any particular cipher.
Caution |
Use caution in enabling the insecure SSH algorithms to avoid any possible security attack. |
To disable the HMAC algorithm, use the ssh client disable hmac command or the ssh server disable hmac command in XR Config mode.
To enable the required cipher, use the ssh client enable cipher command or the ssh server enable cipher command in XR Config mode.
The supported encryption algorithms (in the order of preference) are:
-
aes128-ctr
-
aes192-ctr
-
aes256-ctr
-
aes128-gcm@openssh.com
-
aes256-gcm@openssh.com
-
aes128-cbc
-
aes192-cbc
-
aes256-cbc
-
3des-cbc
In SSH, the CBC-based ciphers are disabled by default. To enable these, you can use the ssh client enable cipher command or the ssh server enable cipher command with the respective CBC options (aes-cbc or 3des-cbc). All CTR-based and GCM-based ciphers are enabled by default.
Disable HMAC Algorithm
Configuration Example to Disable HMAC Algorithm
Router(config)# ssh server disable hmac hmac-sha1
Router(config)#commit
Router(config)# ssh client disable hmac hmac-sha1
Router(config)#commit
Running Configuration
ssh server disable hmac hmac-sha1
!
ssh client disable hmac hmac-sha1
!
Related Topics
SSH Configuration Option to Restrict Cipher Public Key and HMAC Algorithm
Associated Commands
-
ssh client disable hmac
-
ssh server disable hmac
Enable Cipher Public Key
Configuration Example to Enable Cipher Public Key
To enable all ciphers on the client and the server:
Router 1:
Router(config)# ssh client algorithms cipher aes256-cbc aes256-ctr aes192-ctr aes192-cbc aes128-ctr aes128-cbc aes128-gcm@openssh.com aes256-gcm@openssh.com 3des-cbc
Router 2:
Router(config)# ssh server algorithms cipher aes256-cbc aes256-ctr aes192-ctr aes192-cbc aes128-ctr aes128-cbc aes128-gcm@openssh.com aes256-gcm@openssh.com 3des-cbc
To enable the CTR cipher on the client and the CBC cipher on the server:
Router 1:
Router(config)# ssh client algorithms cipher aes128-ctr aes192-ctr aes256-ctr
Router 2:
Router(config)# ssh server algorithms cipher aes128-cbc aes256-cbc aes192-cbc 3des-cbc
Without any cipher on the client and the server:
Router 1:
Router(config)# no ssh client algorithms cipher
Router 2:
Router(config)# no ssh server algorithms cipher
Enable only the deprecated algorithms on the client and the server:
Router 1:
Router(config)# ssh client algorithms cipher aes128-cbc aes192-cbc aes256-cbc 3des-cbc
Router 2:
Router(config)# ssh server algorithms cipher aes128-cbc aes192-cbc aes256-cbc 3des-cbc
Enable the deprecated algorithm (using enable cipher command) and enable the CTR cipher (using algorithms cipher command) on the client and the server:
Router 1:
Router(config)# ssh client enable cipher aes-cbc 3des-cbc
Router(config)# ssh client algorithms cipher aes128-ctr aes192-ctr aes256-ctr
Router 2:
Router(config)# ssh server enable cipher aes-cbc 3des-cbc
Router(config)# ssh server algorithms cipher aes128-ctr aes192-ctr aes256-ctr
Running Configuration
All ciphers enabled on the client and the server:
Router 1:
ssh client algorithms cipher aes256-cbc aes256-ctr aes192-ctr aes192-cbc aes128-ctr aes128-cbc aes128-gcm@openssh.com aes256-gcm@openssh.com 3des-cbc
!
Router 2:
ssh client algorithms cipher aes256-cbc aes256-ctr aes192-ctr aes192-cbc aes128-ctr aes128-cbc aes128-gcm@openssh.com aes256-gcm@openssh.com 3des-cbc
!
Related Topics
SSH Configuration Option to Restrict Cipher Public Key and HMAC Algorithm
Associated Commands
-
ssh client enable cipher
-
ssh server enable cipher
-
ssh client algorithms cipher
-
ssh server algorithms cipher