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Funtoo uses the OpenSSH daemon (sshd) to provide the SSH service by default. sshd is a member of [[OpenRC_(Funtoo)|OpenRC]]'s default runlevel.
Funtoo uses the OpenSSH daemon (sshd) to provide the SSH service by default. sshd is a member of [[OpenRC_(Funtoo)|OpenRC]]'s default runlevel.


By default login is allowed for all users via the ssh daemon on port 22 with any valid username and password combination.
By default login is allowed for all non-root users via the ssh daemon on port 22 with any valid username and password combination.


== Service configuration ==
== Service configuration ==
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# <code>sshd</code> may be configured to use PAM.<br/>Permission may be granted or denied via PAM, allowing you to store usernames etc. using text files.
# <code>sshd</code> may be configured to use PAM.<br/>Permission may be granted or denied via PAM, allowing you to store usernames etc. using text files.


== Protocol version selection ==
=== Protocol version selection ===
The '''''default''''' protocol version is SSH-2. SSH-1 requires explicit activation. To select a protocol version, use the <code>Protocol</code> directive.
The '''''default''''' protocol version is SSH-2. SSH-1 requires explicit activation. To select a protocol version, use the <code>Protocol</code> directive.


e.g. <code>Protocol 2</code>
e.g. <code>Protocol 2</code>


== Cipher selection ==
=== Cipher selection ===
The <code>Ciphers</code> directive specifies the ciphers allowed for protocol version 2.
The <code>Ciphers</code> directive specifies the ciphers allowed for protocol version 2.


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On your client, run
On your client, run


<console>###i## ssh-keygen -t rsa</console>
<console>###i## ssh-keygen -t ed25519 -a 100</console>


This command will generate a public and private key, stored at <code>~/.ssh/id_rsa.pub</code> and <code>~/.ssh/id_rsa</code> respectively. The private key should not be shared with anyone. The pubilc key can be freely shared, and can only be used to ''grant'' you access to remote systems by use of your private key. To grant yourself access to a remote account, append the contents of <code>~/.ssh/id_rsa.pub</code> to the file <code>~/.ssh/authorized_keys</code> on a remote system. Note that <code>~/.ssh/authorized_keys</code> must not be readable by anyone but the user for OpenSSH to process the file -- do this by running <code>chmod -R go-rwx ~/.ssh</code> on the remote system.
This command will generate a public and private key, stored at <code>~/.ssh/id_ed25519.pub</code> and <code>~/.ssh/id_ed25519</code> respectively. The private key should not be shared with anyone. The pubilc key can be freely shared, and can only be used to ''grant'' you access to remote systems by use of your private key. To grant yourself access to a remote account, append the contents of <code>~/.ssh/id_ed25519.pub</code> to the file <code>~/.ssh/authorized_keys</code> on a remote system. Note that <code>~/.ssh/authorized_keys</code> must not be readable by anyone but the user for OpenSSH to process the file -- do this by running <code>chmod -R go-rwx ~/.ssh</code> on the remote system.


Providing a passphrase for your private key will cause it to be stored in an encrypted format, using this passphrase. Before you can use your private key, you will be prompted by OpenSSH to type in this passphrase. This is similar to typing in a password, but with the use of this authentication method, your password is not sent over the network at all.
Providing a passphrase for your private key will cause it to be stored in an encrypted format, using this passphrase. Before you can use your private key, you will be prompted by OpenSSH to type in this passphrase. This is similar to typing in a password, but with the use of this authentication method, your password is not sent over the network at all.
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==== Server ====
==== Server ====
Create a user, or select which user the client will be accessing the server as,  then place clients id_rsa.pub file into the users <code>~/.ssh/authorized_keys</code>
Create a user, or select which user the client will be accessing the server as,  then place clients id_ed25519.pub file into the users <code>~/.ssh/authorized_keys</code>


==== Single Machine Testing ====
==== Single Machine Testing ====
<console>###i## ssh-keygen -t rsa</console>
<console>###i## ssh-keygen -t ed25519 -a 100</console>
Press enter several times to accept default settings.
Press enter several times to accept default settings.
<console>###i## cp ~/.ssh/id_rsa.pub ~/.ssh/authorized_keys</console>
<console>###i## cp ~/.ssh/id_ed25519.pub ~/.ssh/authorized_keys</console>
<console>###i## ssh localhost</console>
<console>###i## ssh localhost</console>
Backup your ~/.ssh directory.


# Host-based authentication
# Host-based authentication
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X forwarding will now be enabled from that machine, so if you connect from your remote with 'ssh -X <user>@<ipaddress>' X sessions will be forwarded
X forwarding will now be enabled from that machine, so if you connect from your remote with 'ssh -X <user>@<ipaddress>' X sessions will be forwarded


=== Intrusion Prevention ===
== HPN patch ==
HPN-SSH is a patch set designed to remove a networking bottleneck in the base OpenSSH code. Removing this bottleneck can improve performance drastically.
 
SSH implements a multiplexed connection protocol so a single TCP/IP connection can host multiple SSH sessions at the same time. This means that SSH also has to implement a flow control mechanism in order to make sure that the network connection isn't overwhelmed. Much like TCP/IP it uses a recieve buffer to indicate how much data the sender should be sending at any one point. The developers of OpenSSH have set this buffer size to 64KiloBytes. This is often too small for very high speed connections over long distances. HPN-SSH allows this buffer to grow well past 64KB allowing transfers at very high rates.
 
=== Speed gain ===
As a general rule of thumb, the farther away the destination and the faster your connection the greater the improvement will be. You can determine how much HPN-SSH will help by multiplying the bandwidth to the destination by the RTT (Round Trip Time). This is called the BDP (Bandwidth Delay Product) and is expressed as BDP = BW(B/s) * RTT(s) and gives you the number of bytes that can be in transit between any two hosts at one time. If this value is less than the previous mention receive buffer on the receiving host then the potential throughput of the connection will be near line rates*. If the BDP is greater than the receive buffer the throughput will be limited in direct proprotion to the difference between the BDP and the receive buffer. As a rule of thumb you will generally need at least a 10Mb/s connection to the internet to see a benefit from HPN-SSH.
 
=== Settings needed ===
Add these settings into /etc/ssh/sshd_config:
<pre>
HPNDisabled no
TcpRcvBufPoll yes
HPNBufferSize 8192
NoneEnabled yes # Enable none cipher
</pre>
 
=== The NONE Cipher ===
The NONE cipher switch disables data encryption AFTER you have been authenticated or logged into the remote host. This can significantly reduce the load on the CPUs of both machines and may improve performance even more. Its important to remember that the initial authentication process is still fully encrypted. Additionally, while the data is no longer encrypted each packet is still digitially signed and protected against in transit manipulation of the information. Anytime the NONE cipher is used a warning will be printed to screen saying "WARNING: NONE CIPHER ENABLED". If you do not see that warning then the None cipher is not in use.
 
Is it safe to switch off encryption? That depends entirelly on what you are trying to do. First off, you can't use the NONE Cipher Switch in an interactive session and is designed to be only used in the transfer of bulk data - like with scp. Second, you should be aware of what kind of data you are transfering. If you are copying financial or medical data then you would not want to use the NONE cipher. However, if you are copying non-sensitive data like MP3s, archives, images, and so forth it may make sense to use the NONE Cipher Switch. You will have to make that determination yourself. Lastly, since the authentication process is still encrypted hackers and eavesdroppers will not be able to steal your password.
 
You must use both '''-oNoneSwitch=yes''' and '''-oNoneEnabled=yes''' on the client command line. Additionally, the None cipher must be enabled on the server with NoneEnabled=yes in the sshd_config file or on the command line. Anytime the None cipher is used a warning will be printed to screen saying "WARNING: NONE CIPHER ENABLED". If you do not see that warning then the NONE cipher is not in use.
 
=== The multi-threaded AES-CTR ===
As of HPN13v1 there has been introduced a multi-threaded AES-CTR (MT-AES-CTR) patch that will allow SSH to make use of multiple cores. This can significantly improve throughput performance. In test environments one can commonly see near GigE line rate speeds - more than a 100% improvement over the default AES-CTR mode cipher.
 
To enable the multi-threaded variant use either ''-oCipher=aes[128|192|256]-ctr'' or ''-caes[128|192|256]-ctr''. The cipher stream is indistinguishable from the single threaded version and will be understood also by all compliant (single-threaded) implementations of AES-CTR.
 
== Intrusion Prevention ==
ssh is a commonly attacked service. {{package|app-admin/sshguard}} monitors logs, and black list remote users who have repeatedly failed to login.
ssh is a commonly attacked service. {{package|app-admin/sshguard}} monitors logs, and black list remote users who have repeatedly failed to login.
* [https://www.psc.edu/index.php/networking/695 HPN README]


[[Category:Networking]]
[[Category:Networking]]
{{EbuildFooter}}
{{EbuildFooter}}

Latest revision as of 23:29, September 13, 2020

OpenSSH

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Introduction

SSH is a cryptographically confidential network protocol for data transmission between 2 networked computers. There are 2 protocol versions; SSH-1 and SSH-2.

Default Installation

Funtoo uses the OpenSSH daemon (sshd) to provide the SSH service by default. sshd is a member of OpenRC's default runlevel.

By default login is allowed for all non-root users via the ssh daemon on port 22 with any valid username and password combination.

Service configuration

There are 2 means of configuring sshd. The first is required, the second is optional.

  1. sshd reads its configuration data from /etc/ssh/sshd_config by default.
  2. sshd may be configured to use PAM.
    Permission may be granted or denied via PAM, allowing you to store usernames etc. using text files.

Protocol version selection

The default protocol version is SSH-2. SSH-1 requires explicit activation. To select a protocol version, use the Protocol directive.

e.g. Protocol 2

Cipher selection

The Ciphers directive specifies the ciphers allowed for protocol version 2.

User Authentication

Single authentication method

  1. Password authentication
    This is enabled by default, it is configured using the PasswordAuthentication directive. Valid parameters are yes or no.
    When PasswordAuthentication yes is configured, the state of the PermitEmptyPasswords directive is evaluated.
  2. Public key authentication

This is enabled with combinations of AuthorizedKeysFile, AuthorizedKeysCommand and AuthorizedKeysCommandUser.

Passwordless Authentication

Client

On your client, run

root # ssh-keygen -t ed25519 -a 100

This command will generate a public and private key, stored at ~/.ssh/id_ed25519.pub and ~/.ssh/id_ed25519 respectively. The private key should not be shared with anyone. The pubilc key can be freely shared, and can only be used to grant you access to remote systems by use of your private key. To grant yourself access to a remote account, append the contents of ~/.ssh/id_ed25519.pub to the file ~/.ssh/authorized_keys on a remote system. Note that ~/.ssh/authorized_keys must not be readable by anyone but the user for OpenSSH to process the file -- do this by running chmod -R go-rwx ~/.ssh on the remote system.

Providing a passphrase for your private key will cause it to be stored in an encrypted format, using this passphrase. Before you can use your private key, you will be prompted by OpenSSH to type in this passphrase. This is similar to typing in a password, but with the use of this authentication method, your password is not sent over the network at all.

The program ssh-agent exists to allow decrypted private keys to be cached in memory for easy access, so you do not need to type in your passphrase every time. It can still be quite complex to use, so it's recommended to use a front-end for ssh-agent -- see the Keychain page to learn about such a tool. Keychain is also part of Funtoo.

Server

Create a user, or select which user the client will be accessing the server as, then place clients id_ed25519.pub file into the users ~/.ssh/authorized_keys

Single Machine Testing

root # ssh-keygen -t ed25519 -a 100

Press enter several times to accept default settings.

root # cp ~/.ssh/id_ed25519.pub ~/.ssh/authorized_keys
root # ssh localhost

Backup your ~/.ssh directory.

  1. Host-based authentication

Requiring multiple authentication factors

These options are only available for SSH-2. The default is not to require multiple authentication. To identify to the daemon that you wish to require more than one authentication, you must use the AuthenticationMethods directive. This directive is followed by one or more comma separated lists of authentication method names. Lists are separated with a space. Successful authentication requires completion of every method in at least one of these lists.

  1. password
  2. publickey
  3. keyboard-interactive

e.g. AuthenticationMethods "password,publickey password,keyboard-interactive"

Password authentication using sshd_config

The following 4 directives are listed in order of evaluation by OpenSSH. They are configured directly; within sshd_config. Only user or group _names_ are valid, numerical IDs are not recognized. If the pattern takes the form USER@HOST then access is restricted to the USER when originating from the HOST.

DenyUsers PATTERN PATTERN ...
Login is forbidden for users whose username matches one of the patterns
AllowUsers PATTERN PATTERN ...
Login is permitted to users whose username matches one of the patterns
DenyGroups PATTERN PATTERN ...
Login is forbidden for users whose primary group or supplementary group list matches one of the patterns
AllowGroups PATTERN PATTERN ...
Login is permitted to users whose primary group or supplementary group list matches one of the patterns

Public key authentication

AuthorizedKeysFile AuthorizedKeysCommand AuthorizedKeysCommandUser

Host based authentication

Access control

Controlling root access

Access by the root user can be controlled using the PermitRootLogin directive.

Permit empty passwords

Access to accounts with empty (i.e. blank) passwords can be controlled using the PermitEmptyPasswords directive.

ChallengeResponseAuthentication Ciphers

GSSAPIAuthenticaion GSSAPICleanupCredentials GSSAPIStrictAcceptorCheck HostBasedAuthentication HostBasedUsesNameFromPacketOnly HostCertificate HostKey HostKeyAgent LoginGraceTime MAC MaxAuthTries MaxSessions MaxStartups PasswordAuthentication PermitEmptyPasswords PubkeyAuthentication RevokedKeys RhostsRSAAuthentication RSAAuthentication TrustedUserCAKeys UseLogin UsePAM

X11 Forwarding

By default X11 forwarding is disabled in OpenSSHd,

If you would like to forward X11 from your Funtoo box to a remote system you must first edit your /etc/ssh/sshd_config file

change

#X11Forwarding no
#X11DisplayOffset 10
#X11UseLocalhost yes

to

X11Forwarding yes
X11DisplayOffset 10
X11UseLocalhost yes

X forwarding will now be enabled from that machine, so if you connect from your remote with 'ssh -X <user>@<ipaddress>' X sessions will be forwarded

HPN patch

HPN-SSH is a patch set designed to remove a networking bottleneck in the base OpenSSH code. Removing this bottleneck can improve performance drastically.

SSH implements a multiplexed connection protocol so a single TCP/IP connection can host multiple SSH sessions at the same time. This means that SSH also has to implement a flow control mechanism in order to make sure that the network connection isn't overwhelmed. Much like TCP/IP it uses a recieve buffer to indicate how much data the sender should be sending at any one point. The developers of OpenSSH have set this buffer size to 64KiloBytes. This is often too small for very high speed connections over long distances. HPN-SSH allows this buffer to grow well past 64KB allowing transfers at very high rates.

Speed gain

As a general rule of thumb, the farther away the destination and the faster your connection the greater the improvement will be. You can determine how much HPN-SSH will help by multiplying the bandwidth to the destination by the RTT (Round Trip Time). This is called the BDP (Bandwidth Delay Product) and is expressed as BDP = BW(B/s) * RTT(s) and gives you the number of bytes that can be in transit between any two hosts at one time. If this value is less than the previous mention receive buffer on the receiving host then the potential throughput of the connection will be near line rates*. If the BDP is greater than the receive buffer the throughput will be limited in direct proprotion to the difference between the BDP and the receive buffer. As a rule of thumb you will generally need at least a 10Mb/s connection to the internet to see a benefit from HPN-SSH.

Settings needed

Add these settings into /etc/ssh/sshd_config:

HPNDisabled no
TcpRcvBufPoll yes
HPNBufferSize 8192
NoneEnabled yes # Enable none cipher

The NONE Cipher

The NONE cipher switch disables data encryption AFTER you have been authenticated or logged into the remote host. This can significantly reduce the load on the CPUs of both machines and may improve performance even more. Its important to remember that the initial authentication process is still fully encrypted. Additionally, while the data is no longer encrypted each packet is still digitially signed and protected against in transit manipulation of the information. Anytime the NONE cipher is used a warning will be printed to screen saying "WARNING: NONE CIPHER ENABLED". If you do not see that warning then the None cipher is not in use.

Is it safe to switch off encryption? That depends entirelly on what you are trying to do. First off, you can't use the NONE Cipher Switch in an interactive session and is designed to be only used in the transfer of bulk data - like with scp. Second, you should be aware of what kind of data you are transfering. If you are copying financial or medical data then you would not want to use the NONE cipher. However, if you are copying non-sensitive data like MP3s, archives, images, and so forth it may make sense to use the NONE Cipher Switch. You will have to make that determination yourself. Lastly, since the authentication process is still encrypted hackers and eavesdroppers will not be able to steal your password.

You must use both -oNoneSwitch=yes and -oNoneEnabled=yes on the client command line. Additionally, the None cipher must be enabled on the server with NoneEnabled=yes in the sshd_config file or on the command line. Anytime the None cipher is used a warning will be printed to screen saying "WARNING: NONE CIPHER ENABLED". If you do not see that warning then the NONE cipher is not in use.

The multi-threaded AES-CTR

As of HPN13v1 there has been introduced a multi-threaded AES-CTR (MT-AES-CTR) patch that will allow SSH to make use of multiple cores. This can significantly improve throughput performance. In test environments one can commonly see near GigE line rate speeds - more than a 100% improvement over the default AES-CTR mode cipher.

To enable the multi-threaded variant use either -oCipher=aes[128|192|256]-ctr or -caes[128|192|256]-ctr. The cipher stream is indistinguishable from the single threaded version and will be understood also by all compliant (single-threaded) implementations of AES-CTR.

Intrusion Prevention

ssh is a commonly attacked service. app-admin/sshguard monitors logs, and black list remote users who have repeatedly failed to login.