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xterm
-style mouse reportingwinadj
’ requests’KEXINIT
’ssh-connection
’ protocolThis chapter describes all the configuration options in PuTTY.
PuTTY is configured using the control panel that comes up before you start a session. Some options can also be changed in the middle of a session, by selecting ‘Change Settings’ from the window menu.
The Session configuration panel contains the basic options you need to specify in order to open a session at all, and also allows you to save your settings to be reloaded later.
The top box on the Session panel, labelled ‘Specify the destination you want to connect to’, contains the details that need to be filled in before PuTTY can open a session at all.
If you select ‘Serial’ from the ‘Connection type’ radio buttons, the ‘Host Name’ and ‘Port’ boxes are replaced by ‘Serial line’ and ‘Speed’; see section 4.29 for more details of these.
The next part of the Session configuration panel allows you to save your preferred PuTTY options so they will appear automatically the next time you start PuTTY. It also allows you to create saved sessions, which contain a full set of configuration options plus a host name and protocol. A saved session contains all the information PuTTY needs to start exactly the session you want.
If there is a specific host you want to store the details of how to connect to, you should create a saved session, which will be separate from the Default Settings.
You can also save settings in mid-session, from the ‘Change Settings’ dialog. Settings changed since the start of the session will be saved with their current values; as well as settings changed through the dialog, this includes changes in window size, window title changes sent by the server, and so on.
To save the new settings under a different name, you can enter the new name in the ‘Saved Sessions’ box, or single-click to select a session name in the list box to overwrite that session. To save ‘Default Settings’, you must single-click the name before saving.
Each saved session is independent of the Default Settings configuration. If you change your preferences and update Default Settings, you must also update every saved session separately.
Saved sessions are stored in the Registry, at the location
HKEY_CURRENT_USER\Software\SimonTatham\PuTTY\Sessions
If you need to store them in a file, you could try the method described in section 4.33.
Finally in the Session panel, there is an option labelled ‘Close window on exit’. This controls whether the PuTTY terminal window disappears as soon as the session inside it terminates. If you are likely to want to copy and paste text out of the session after it has terminated, or restart the session, you should arrange for this option to be off.
‘Close window on exit’ has three settings. ‘Always’ means always close the window on exit; ‘Never’ means never close on exit (always leave the window open, but inactive). The third setting, and the default one, is ‘Only on clean exit’. In this mode, a session which terminates normally will cause its window to close, but one which is aborted unexpectedly by network trouble or a confusing message from the server will leave the window up.
The Logging configuration panel allows you to save log files of your PuTTY sessions, for debugging, analysis or future reference.
The main option is a radio-button set that specifies whether PuTTY will log anything at all. The options are:
Note that the non-SSH logging options (‘Printable output’ and ‘All session output’) only work with PuTTY proper; in programs without terminal emulation (such as Plink), they will have no effect, even if enabled via saved settings.
In this edit box you enter the name of the file you want to log the session to. The ‘Browse’ button will let you look around your file system to find the right place to put the file; or if you already know exactly where you want it to go, you can just type a pathname into the edit box.
There are a few special features in this box. If you use the &
character in the file name box, PuTTY will insert details of the current session in the name of the file it actually opens. The precise replacements it will do are:
&Y
will be replaced by the current year, as four digits.
&M
will be replaced by the current month, as two digits.
&D
will be replaced by the current day of the month, as two digits.
&T
will be replaced by the current time, as six digits (HHMMSS) with no punctuation.
&H
will be replaced by the host name you are connecting to (or the serial line, for a serial connection).
&P
will be replaced by the port number you are connecting to on the target host.
(These are all case-insensitive.)
For example, if you enter the file name c:\puttylogs\log-&h-&y&m&d-&t.dat
, you will end up with files looking like
log-server1.example.com-20010528-110859.dat
log-unixbox.somewhere.org-20010611-221001.dat
This control allows you to specify what PuTTY should do if it tries to start writing to a log file and it finds the file already exists. You might want to automatically destroy the existing log file and start a new one with the same name. Alternatively, you might want to open the existing log file and add data to the end of it. Finally (the default option), you might not want to have any automatic behaviour, but to ask the user every time the problem comes up.
This option allows you to control how frequently logged data is flushed to disc. By default, PuTTY will flush data as soon as it is displayed, so that if you view the log file while a session is still open, it will be up to date; and if the client system crashes, there's a greater chance that the data will be preserved.
However, this can incur a performance penalty. If PuTTY is running slowly with logging enabled, you could try unchecking this option. Be warned that the log file may not always be up to date as a result (although it will of course be flushed when it is closed, for instance at the end of a session).
This option allows you to choose whether to include a header line with the date and time when the log file is opened. It may be useful to disable this if the log file is being used as realtime input to other programs that don't expect the header line.
These options only apply if SSH packet data is being logged.
The following options allow particularly sensitive portions of unencrypted packets to be automatically left out of the log file. They are only intended to deter casual nosiness; an attacker could glean a lot of useful information from even these obfuscated logs (e.g., length of password).
When checked, decrypted password fields are removed from the log of transmitted packets. (This includes any user responses to challenge-response authentication methods such as ‘keyboard-interactive’.) This does not include X11 authentication data if using X11 forwarding.
Note that this will only omit data that PuTTY knows to be a password. However, if you start another login session within your PuTTY session, for instance, any password used will appear in the clear in the packet log. The next option may be of use to protect against this.
This option is enabled by default.
When checked, all decrypted ‘session data’ is omitted; this is defined as data in terminal sessions and in forwarded channels (TCP, X11, and authentication agent). This will usually substantially reduce the size of the resulting log file.
This option is disabled by default.
The Terminal configuration panel allows you to control the behaviour of PuTTY's terminal emulation.
Auto wrap mode controls what happens when text printed in a PuTTY window reaches the right-hand edge of the window.
With auto wrap mode on, if a long line of text reaches the right-hand edge, it will wrap over on to the next line so you can still see all the text. With auto wrap mode off, the cursor will stay at the right-hand edge of the screen, and all the characters in the line will be printed on top of each other.
If you are running a full-screen application and you occasionally find the screen scrolling up when it looks as if it shouldn't, you could try turning this option off.
Auto wrap mode can be turned on and off by control sequences sent by the server. This configuration option controls the default state, which will be restored when you reset the terminal (see section 3.1.3.6). However, if you modify this option in mid-session using ‘Change Settings’, it will take effect immediately.
DEC Origin Mode is a minor option which controls how PuTTY interprets cursor-position control sequences sent by the server.
The server can send a control sequence that restricts the scrolling region of the display. For example, in an editor, the server might reserve a line at the top of the screen and a line at the bottom, and might send a control sequence that causes scrolling operations to affect only the remaining lines.
With DEC Origin Mode on, cursor coordinates are counted from the top of the scrolling region. With it turned off, cursor coordinates are counted from the top of the whole screen regardless of the scrolling region.
It is unlikely you would need to change this option, but if you find a full-screen application is displaying pieces of text in what looks like the wrong part of the screen, you could try turning DEC Origin Mode on to see whether that helps.
DEC Origin Mode can be turned on and off by control sequences sent by the server. This configuration option controls the default state, which will be restored when you reset the terminal (see section 3.1.3.6). However, if you modify this option in mid-session using ‘Change Settings’, it will take effect immediately.
Most servers send two control characters, CR and LF, to start a new line of the screen. The CR character makes the cursor return to the left-hand side of the screen. The LF character makes the cursor move one line down (and might make the screen scroll).
Some servers only send LF, and expect the terminal to move the cursor over to the left automatically. If you come across a server that does this, you will see a stepped effect on the screen, like this:
First line of text
Second line
Third line
If this happens to you, try enabling the ‘Implicit CR in every LF’ option, and things might go back to normal:
First line of text
Second line
Third line
Most servers send two control characters, CR and LF, to start a new line of the screen. The CR character makes the cursor return to the left-hand side of the screen. The LF character makes the cursor move one line down (and might make the screen scroll).
Some servers only send CR, and so the newly written line is overwritten by the following line. This option causes a line feed so that all lines are displayed.
Not all terminals agree on what colour to turn the screen when the server sends a ‘clear screen’ sequence. Some terminals believe the screen should always be cleared to the default background colour. Others believe the screen should be cleared to whatever the server has selected as a background colour.
There exist applications that expect both kinds of behaviour. Therefore, PuTTY can be configured to do either.
With this option disabled, screen clearing is always done in the default background colour. With this option enabled, it is done in the current background colour.
Background-colour erase can be turned on and off by control sequences sent by the server. This configuration option controls the default state, which will be restored when you reset the terminal (see section 3.1.3.6). However, if you modify this option in mid-session using ‘Change Settings’, it will take effect immediately.
The server can ask PuTTY to display text that blinks on and off. This is very distracting, so PuTTY allows you to turn blinking text off completely.
When blinking text is disabled and the server attempts to make some text blink, PuTTY will instead display the text with a bolded background colour.
Blinking text can be turned on and off by control sequences sent by the server. This configuration option controls the default state, which will be restored when you reset the terminal (see section 3.1.3.6). However, if you modify this option in mid-session using ‘Change Settings’, it will take effect immediately.
This option controls what PuTTY will send back to the server if the server sends it the ^E enquiry character. Normally it just sends the string ‘PuTTY’.
If you accidentally write the contents of a binary file to your terminal, you will probably find that it contains more than one ^E character, and as a result your next command line will probably read ‘PuTTYPuTTYPuTTY...’ as if you had typed the answerback string multiple times at the keyboard. If you set the answerback string to be empty, this problem should go away, but doing so might cause other problems.
Note that this is not the feature of PuTTY which the server will typically use to determine your terminal type. That feature is the ‘Terminal-type string’ in the Connection panel; see section 4.15.3 for details.
You can include control characters in the answerback string using ^C
notation. (Use ^~
to get a literal ^
.)
With local echo disabled, characters you type into the PuTTY window are not echoed in the window by PuTTY. They are simply sent to the server. (The server might choose to echo them back to you; this can't be controlled from the PuTTY control panel.)
Some types of session need local echo, and many do not. In its default mode, PuTTY will automatically attempt to deduce whether or not local echo is appropriate for the session you are working in. If you find it has made the wrong decision, you can use this configuration option to override its choice: you can force local echo to be turned on, or force it to be turned off, instead of relying on the automatic detection.
Normally, every character you type into the PuTTY window is sent immediately to the server the moment you type it.
If you enable local line editing, this changes. PuTTY will let you edit a whole line at a time locally, and the line will only be sent to the server when you press Return. If you make a mistake, you can use the Backspace key to correct it before you press Return, and the server will never see the mistake.
Since it is hard to edit a line locally without being able to see it, local line editing is mostly used in conjunction with local echo (section 4.3.8). This makes it ideal for use in raw mode or when connecting to MUDs or talkers. (Although some more advanced MUDs do occasionally turn local line editing on and turn local echo off, in order to accept a password from the user.)
Some types of session need local line editing, and many do not. In its default mode, PuTTY will automatically attempt to deduce whether or not local line editing is appropriate for the session you are working in. If you find it has made the wrong decision, you can use this configuration option to override its choice: you can force local line editing to be turned on, or force it to be turned off, instead of relying on the automatic detection.
A lot of VT100-compatible terminals support printing under control of the remote server (sometimes called ‘passthrough printing’). PuTTY supports this feature as well, but it is turned off by default.
To enable remote-controlled printing, choose a printer from the ‘Printer to send ANSI printer output to’ drop-down list box. This should allow you to select from all the printers you have installed drivers for on your computer. Alternatively, you can type the network name of a networked printer (for example, \\printserver\printer1
) even if you haven't already installed a driver for it on your own machine.
When the remote server attempts to print some data, PuTTY will send that data to the printer raw - without translating it, attempting to format it, or doing anything else to it. It is up to you to ensure your remote server knows what type of printer it is talking to.
Since PuTTY sends data to the printer raw, it cannot offer options such as portrait versus landscape, print quality, or paper tray selection. All these things would be done by your PC printer driver (which PuTTY bypasses); if you need them done, you will have to find a way to configure your remote server to do them.
To disable remote printing again, choose ‘None (printing disabled)’ from the printer selection list. This is the default state.
The Keyboard configuration panel allows you to control the behaviour of the keyboard in PuTTY. The correct state for many of these settings depends on what the server to which PuTTY is connecting expects. With a Unix server, this is likely to depend on the termcap
or terminfo
entry it uses, which in turn is likely to be controlled by the ‘Terminal-type string’ setting in the Connection panel; see section 4.15.3 for details. If none of the settings here seems to help, you may find question A.7.13 to be useful.
Some terminals believe that the Backspace key should send the same thing to the server as Control-H (ASCII code 8). Other terminals believe that the Backspace key should send ASCII code 127 (usually known as Control-?) so that it can be distinguished from Control-H. This option allows you to choose which code PuTTY generates when you press Backspace.
If you are connecting over SSH, PuTTY by default tells the server the value of this option (see section 4.24.2), so you may find that the Backspace key does the right thing either way. Similarly, if you are connecting to a Unix system, you will probably find that the Unix stty
command lets you configure which the server expects to see, so again you might not need to change which one PuTTY generates. On other systems, the server's expectation might be fixed and you might have no choice but to configure PuTTY.
If you do have the choice, we recommend configuring PuTTY to generate Control-? and configuring the server to expect it, because that allows applications such as emacs
to use Control-H for help.
(Typing Shift-Backspace will cause PuTTY to send whichever code isn't configured here as the default.)
The Unix terminal emulator rxvt
disagrees with the rest of the world about what character sequences should be sent to the server by the Home and End keys.
xterm
, and other terminals, send ESC [1~
for the Home key, and ESC [4~
for the End key. rxvt
sends ESC [H
for the Home key and ESC [Ow
for the End key.
If you find an application on which the Home and End keys aren't working, you could try switching this option to see if it helps.
This option affects the function keys (F1 to F12) and the top row of the numeric keypad.
ESC [n~
, the function keys generate sequences like ESC [11~
, ESC [12~
and so on. This matches the general behaviour of Digital's terminals.
ESC [[A
through to ESC [[E
. This mimics the Linux virtual console.
ESC OP
through to ESC OS
, which are the sequences produced by the top row of the keypad on Digital's terminals.
ESC OP
through to ESC OS
.
ESC OP
through to ESC O[
ESC [M
through to ESC [X
. Together with shift, they generate ESC [Y
through to ESC [j
. With control they generate ESC [k
through to ESC [v
, and with shift and control together they generate ESC [w
through to ESC [{
.
ESC OP
become ESC [1;
bitmapP
and similar; for F5 and above, ESC[
index~
becomes ESC[
index;
bitmap~
.
If you don't know what any of this means, you probably don't need to fiddle with it.
This option affects the arrow keys, if you press one with any of the modifier keys Shift, Ctrl or Alt held down.
Ctrl toggles app mode
, the Ctrl key toggles between the default arrow-key sequences like ESC [A
and ESC [B
, and the sequences Digital's terminals generate in ‘application cursor keys’ mode, i.e. ESC O A
and so on. Shift and Alt have no effect.
If you don't know what any of this means, you probably don't need to fiddle with it.
Application Cursor Keys mode is a way for the server to change the control sequences sent by the arrow keys. In normal mode, the arrow keys send ESC [A
through to ESC [D
. In application mode, they send ESC OA
through to ESC OD
.
Application Cursor Keys mode can be turned on and off by the server, depending on the application. PuTTY allows you to configure the initial state.
You can also disable application cursor keys mode completely, using the ‘Features’ configuration panel; see section 4.6.1.
Application Keypad mode is a way for the server to change the behaviour of the numeric keypad.
In normal mode, the keypad behaves like a normal Windows keypad: with NumLock on, the number keys generate numbers, and with NumLock off they act like the arrow keys and Home, End etc.
In application mode, all the keypad keys send special control sequences, including Num Lock. Num Lock stops behaving like Num Lock and becomes another function key.
Depending on which version of Windows you run, you may find the Num Lock light still flashes on and off every time you press Num Lock, even when application mode is active and Num Lock is acting like a function key. This is unavoidable.
Application keypad mode can be turned on and off by the server, depending on the application. PuTTY allows you to configure the initial state.
You can also disable application keypad mode completely, using the ‘Features’ configuration panel; see section 4.6.1.
PuTTY has a special mode for playing NetHack. You can enable it by selecting ‘NetHack’ in the ‘Initial state of numeric keypad’ control.
In this mode, the numeric keypad keys 1-9 generate the NetHack movement commands (hjklyubn
). The 5 key generates the .
command (do nothing).
In addition, pressing Shift or Ctrl with the keypad keys generate the Shift- or Ctrl-keys you would expect (e.g. keypad-7 generates ‘y
’, so Shift-keypad-7 generates ‘Y
’ and Ctrl-keypad-7 generates Ctrl-Y); these commands tell NetHack to keep moving you in the same direction until you encounter something interesting.
For some reason, this feature only works properly when Num Lock is on. We don't know why.
DEC terminals have a Compose key, which provides an easy-to-remember way of typing accented characters. You press Compose and then type two more characters. The two characters are ‘combined’ to produce an accented character. The choices of character are designed to be easy to remember; for example, composing ‘e’ and ‘`’ produces the ‘è’ character.
If your keyboard has a Windows Application key, it acts as a Compose key in PuTTY. Alternatively, if you enable the ‘AltGr acts as Compose key’ option, the AltGr key will become a Compose key.
Some old keyboards do not have an AltGr key, which can make it difficult to type some characters. PuTTY can be configured to treat the key combination Ctrl + Left Alt the same way as the AltGr key.
By default, this checkbox is checked, and the key combination Ctrl + Left Alt does something completely different. PuTTY's usual handling of the left Alt key is to prefix the Escape (Control-[
) character to whatever character sequence the rest of the keypress would generate. For example, Alt-A generates Escape followed by a
. So Alt-Ctrl-A would generate Escape, followed by Control-A.
If you uncheck this box, Ctrl-Alt will become a synonym for AltGr, so you can use it to type extra graphic characters if your keyboard has any.
(However, Ctrl-Alt will never act as a Compose key, regardless of the setting of ‘AltGr acts as Compose key’ described in section 4.4.8.)
The Bell panel controls the terminal bell feature: the server's ability to cause PuTTY to beep at you.
In the default configuration, when the server sends the character with ASCII code 7 (Control-G), PuTTY will play the Windows Default Beep sound. This is not always what you want the terminal bell feature to do; the Bell panel allows you to configure alternative actions.
This control allows you to select various different actions to occur on a terminal bell:
This feature controls what happens to the PuTTY window's entry in the Windows Taskbar if a bell occurs while the window does not have the input focus.
In the default state (‘Disabled’) nothing unusual happens.
If you select ‘Steady’, then when a bell occurs and the window is not in focus, the window's Taskbar entry and its title bar will change colour to let you know that PuTTY session is asking for your attention. The change of colour will persist until you select the window, so you can leave several PuTTY windows minimised in your terminal, go away from your keyboard, and be sure not to have missed any important beeps when you get back.
‘Flashing’ is even more eye-catching: the Taskbar entry will continuously flash on and off until you select the window.
A common user error in a terminal session is to accidentally run the Unix command cat
(or equivalent) on an inappropriate file type, such as an executable, image file, or ZIP file. This produces a huge stream of non-text characters sent to the terminal, which typically includes a lot of bell characters. As a result of this the terminal often doesn't stop beeping for ten minutes, and everybody else in the office gets annoyed.
To try to avoid this behaviour, or any other cause of excessive beeping, PuTTY includes a bell overload management feature. In the default configuration, receiving more than five bell characters in a two-second period will cause the overload feature to activate. Once the overload feature is active, further bells will have no effect at all, so the rest of your binary file will be sent to the screen in silence. After a period of five seconds during which no further bells are received, the overload feature will turn itself off again and bells will be re-enabled.
If you want this feature completely disabled, you can turn it off using the checkbox ‘Bell is temporarily disabled when over-used’.
Alternatively, if you like the bell overload feature but don't agree with the settings, you can configure the details: how many bells constitute an overload, how short a time period they have to arrive in to do so, and how much silent time is required before the overload feature will deactivate itself.
Bell overload mode is always deactivated by any keypress in the terminal. This means it can respond to large unexpected streams of data, but does not interfere with ordinary command-line activities that generate beeps (such as filename completion).
PuTTY's terminal emulation is very highly featured, and can do a lot of things under remote server control. Some of these features can cause problems due to buggy or strangely configured server applications.
The Features configuration panel allows you to disable some of PuTTY's more advanced terminal features, in case they cause trouble.
Application keypad mode (see section 4.4.6) and application cursor keys mode (see section 4.4.5) alter the behaviour of the keypad and cursor keys. Some applications enable these modes but then do not deal correctly with the modified keys. You can force these modes to be permanently disabled no matter what the server tries to do.
xterm
-style mouse reporting
PuTTY allows the server to send control codes that let it take over the mouse and use it for purposes other than copy and paste. Applications which use this feature include the text-mode web browser links
, the Usenet newsreader trn
version 4, and the file manager mc
(Midnight Commander).
If you find this feature inconvenient, you can disable it using the ‘Disable xterm-style mouse reporting’ control. With this box ticked, the mouse will always do copy and paste in the normal way.
Note that even if the application takes over the mouse, you can still manage PuTTY's copy and paste by holding down the Shift key while you select and paste, unless you have deliberately turned this feature off (see section 4.11.2).
PuTTY has the ability to change the terminal's size and position in response to commands from the server. If you find PuTTY is doing this unexpectedly or inconveniently, you can tell PuTTY not to respond to those server commands.
Many terminals, including PuTTY, support an ‘alternate screen’. This is the same size as the ordinary terminal screen, but separate. Typically a screen-based program such as a text editor might switch the terminal to the alternate screen before starting up. Then at the end of the run, it switches back to the primary screen, and you see the screen contents just as they were before starting the editor.
Some people prefer this not to happen. If you want your editor to run in the same screen as the rest of your terminal activity, you can disable the alternate screen feature completely.
PuTTY has the ability to change the window title in response to commands from the server. If you find PuTTY is doing this unexpectedly or inconveniently, you can tell PuTTY not to respond to those server commands.
PuTTY can optionally provide the xterm service of allowing server applications to find out the local window title. This feature is disabled by default, but you can turn it on if you really want it.
NOTE that this feature is a potential security hazard. If a malicious application can write data to your terminal (for example, if you merely cat
a file owned by someone else on the server machine), it can change your window title (unless you have disabled this as mentioned in section 4.6.5) and then use this service to have the new window title sent back to the server as if typed at the keyboard. This allows an attacker to fake keypresses and potentially cause your server-side applications to do things you didn't want. Therefore this feature is disabled by default, and we recommend you do not set it to ‘Window title’ unless you really know what you are doing.
There are three settings for this option:
PuTTY has the ability to clear the terminal's scrollback buffer in response to a command from the server. If you find PuTTY is doing this unexpectedly or inconveniently, you can tell PuTTY not to respond to that server command.
Normally, when PuTTY receives character 127 (^?) from the server, it will perform a ‘destructive backspace’: move the cursor one space left and delete the character under it. This can apparently cause problems in some applications, so PuTTY provides the ability to configure character 127 to perform a normal backspace (without deleting a character) instead.
PuTTY has the ability to change its character set configuration in response to commands from the server. Some programs send these commands unexpectedly or inconveniently. In particular, BitchX (an IRC client) seems to have a habit of reconfiguring the character set to something other than the user intended.
If you find that accented characters are not showing up the way you expect them to, particularly if you're running BitchX, you could try disabling the remote character set configuration commands.
PuTTY supports shaping of Arabic text, which means that if your server sends text written in the basic Unicode Arabic alphabet then it will convert it to the correct display forms before printing it on the screen.
If you are using full-screen software which was not expecting this to happen (especially if you are not an Arabic speaker and you unexpectedly find yourself dealing with Arabic text files in applications which are not Arabic-aware), you might find that the display becomes corrupted. By ticking this box, you can disable Arabic text shaping so that PuTTY displays precisely the characters it is told to display.
You may also find you need to disable bidirectional text display; see section 4.6.11.
PuTTY supports bidirectional text display, which means that if your server sends text written in a language which is usually displayed from right to left (such as Arabic or Hebrew) then PuTTY will automatically flip it round so that it is displayed in the right direction on the screen.
If you are using full-screen software which was not expecting this to happen (especially if you are not an Arabic speaker and you unexpectedly find yourself dealing with Arabic text files in applications which are not Arabic-aware), you might find that the display becomes corrupted. By ticking this box, you can disable bidirectional text display, so that PuTTY displays text from left to right in all situations.
You may also find you need to disable Arabic text shaping; see section 4.6.10.
By default, when you paste text into the terminal window, it's sent to the server as terminal input, exactly as if you'd typed the same text into the terminal window using the keyboard (except that it's all sent at once, much faster than you could type it).
However, a terminal application can change that, by asking the terminal to enable ‘bracketed paste mode’. In this mode, pasted data is marked in the input stream, by sending a special control sequence before the paste, and another one at the end.
A terminal application can use this information to treat pasted data differently from keyboard input. For example, a terminal-based text editor can treat the input as literal data, even if some of its characters would normally trigger special editor functions. A shell can treat pasted input as less trusted, in case another application somehow sneaked a malicious shell command into your clipboard: modern versions of bash
will highlight pasted data on the command line, and not run it until you've confirmed it by pressing Return, even if the pasted data contained a newline character.
In edge cases, it's possible that bracketed paste mode introduces bigger problems than the ones it solves. So you can use this checkbox to turn it off completely. If you do that, then PuTTY will always send your paste data exactly as if it had been typed at the keyboard, whether or not the server asked for bracketed paste mode.
The Window configuration panel allows you to control aspects of the PuTTY window.
The ‘Columns’ and ‘Rows’ boxes let you set the PuTTY window to a precise size. Of course you can also drag the window to a new size while a session is running.
These options allow you to control what happens when the user tries to resize the PuTTY window using its window furniture.
There are four options here:
These options let you configure the way PuTTY keeps text after it scrolls off the top of the screen (see section 3.1.2).
The ‘Lines of scrollback’ box lets you configure how many lines of text PuTTY keeps. The ‘Display scrollbar’ options allow you to hide the scrollbar (although you can still view the scrollback using the keyboard as described in section 3.1.2). You can separately configure whether the scrollbar is shown in full-screen mode and in normal modes.
If you are viewing part of the scrollback when the server sends more text to PuTTY, the screen will revert to showing the current terminal contents. You can disable this behaviour by turning off ‘Reset scrollback on display activity’. You can also make the screen revert when you press a key, by turning on ‘Reset scrollback on keypress’.
When this option is enabled, the contents of the terminal screen will be pushed into the scrollback when a server-side application clears the screen, so that your scrollback will contain a better record of what was on your screen in the past.
If the application switches to the alternate screen (see section 4.6.4 for more about this), then the contents of the primary screen will be visible in the scrollback until the application switches back again.
This option is enabled by default.
The Appearance configuration panel allows you to control aspects of the appearance of PuTTY's window.
The ‘Cursor appearance’ option lets you configure the cursor to be a block, an underline, or a vertical line. A block cursor becomes an empty box when the window loses focus; an underline or a vertical line becomes dotted.
The ‘Cursor blinks’ option makes the cursor blink on and off. This works in any of the cursor modes.
This option allows you to choose what font, in what size, the PuTTY terminal window uses to display the text in the session.
By default, you will be offered a choice from all the fixed-width fonts installed on the system, since VT100-style terminal handling expects a fixed-width font. If you tick the box marked ‘Allow selection of variable-pitch fonts’, however, PuTTY will offer variable-width fonts as well: if you select one of these, the font will be coerced into fixed-size character cells, which will probably not look very good (but can work OK with some fonts).
If you enable this option, the mouse pointer will disappear if the PuTTY window is selected and you press a key. This way, it will not obscure any of the text in the window while you work in your session. As soon as you move the mouse, the pointer will reappear.
This option is disabled by default, so the mouse pointer remains visible at all times.
PuTTY allows you to configure the appearance of the window border to some extent.
The checkbox marked ‘Sunken-edge border’ changes the appearance of the window border to something more like a DOS box: the inside edge of the border is highlighted as if it sank down to meet the surface inside the window. This makes the border a little bit thicker as well. It's hard to describe well. Try it and see if you like it.
You can also configure a completely blank gap between the text in the window and the border, using the ‘Gap between text and window edge’ control. By default this is set at one pixel. You can reduce it to zero, or increase it further.
The Behaviour configuration panel allows you to control aspects of the behaviour of PuTTY's window.
The ‘Window title’ edit box allows you to set the title of the PuTTY window. By default the window title will contain the host name followed by ‘PuTTY’, for example server1.example.com - PuTTY
. If you want a different window title, this is where to set it.
PuTTY allows the server to send xterm
control sequences which modify the title of the window in mid-session (unless this is disabled - see section 4.6.5); the title string set here is therefore only the initial window title.
As well as the window title, there is also an xterm
sequence to modify the title of the window's icon. This makes sense in a windowing system where the window becomes an icon when minimised, such as Windows 3.1 or most X Window System setups; but in the Windows 95-like user interface it isn't as applicable.
By default, PuTTY only uses the server-supplied window title, and ignores the icon title entirely. If for some reason you want to see both titles, check the box marked ‘Separate window and icon titles’. If you do this, PuTTY's window title and Taskbar caption will change into the server-supplied icon title if you minimise the PuTTY window, and change back to the server-supplied window title if you restore it. (If the server has not bothered to supply a window or icon title, none of this will happen.)
If you press the Close button in a PuTTY window that contains a running session, PuTTY will put up a warning window asking if you really meant to close the window. A window whose session has already terminated can always be closed without a warning.
If you want to be able to close a window quickly, you can disable the ‘Warn before closing window’ option.
By default, pressing ALT-F4 causes the window to close (or a warning box to appear; see section 4.9.2). If you disable the ‘Window closes on ALT-F4’ option, then pressing ALT-F4 will simply send a key sequence to the server.
If this option is enabled, then pressing ALT-Space will bring up the PuTTY window's menu, like clicking on the top left corner. If it is disabled, then pressing ALT-Space will just send ESC SPACE
to the server.
Some accessibility programs for Windows may need this option enabling to be able to control PuTTY's window successfully. For instance, Dragon NaturallySpeaking requires it both to open the system menu via voice, and to close, minimise, maximise and restore the window.
If this option is enabled, then pressing and releasing ALT will bring up the PuTTY window's menu, like clicking on the top left corner. If it is disabled, then pressing and releasing ALT will have no effect.
If this option is enabled, the PuTTY window will stay on top of all other windows.
If this option is enabled, then pressing Alt-Enter will cause the PuTTY window to become full-screen. Pressing Alt-Enter again will restore the previous window size.
The full-screen feature is also available from the System menu, even when it is configured not to be available on the Alt-Enter key. See section 3.1.3.7.
The Translation configuration panel allows you to control the translation between the character set understood by the server and the character set understood by PuTTY.
During an interactive session, PuTTY receives a stream of 8-bit bytes from the server, and in order to display them on the screen it needs to know what character set to interpret them in. Similarly, PuTTY needs to know how to translate your keystrokes into the encoding the server expects. Unfortunately, there is no satisfactory mechanism for PuTTY and the server to communicate this information, so it must usually be manually configured.
There are a lot of character sets to choose from. The ‘Remote character set’ option lets you select one.
By default PuTTY will use the UTF-8 encoding of Unicode, which can represent pretty much any character; data coming from the server is interpreted as UTF-8, and keystrokes are sent UTF-8 encoded. This is what most modern distributions of Linux will expect by default. However, if this is wrong for your server, you can select a different character set using this control.
A few other notable character sets are:
If you need support for a numeric code page which is not listed in the drop-down list, such as code page 866, then you can try entering its name manually (CP866
for example) in the list box. If the underlying version of Windows has the appropriate translation table installed, PuTTY will use it.
There are some Unicode characters whose width is not well-defined. In most contexts, such characters should be treated as single-width for the purposes of wrapping and so on; however, in some CJK contexts, they are better treated as double-width for historical reasons, and some server-side applications may expect them to be displayed as such. Setting this option will cause PuTTY to take the double-width interpretation.
If you use legacy CJK applications, and you find your lines are wrapping in the wrong places, or you are having other display problems, you might want to play with this setting.
This option only has any effect in UTF-8 mode (see section 4.10.1).
This feature allows you to switch between a US/UK keyboard layout and a Cyrillic keyboard layout by using the Caps Lock key, if you need to type (for example) Russian and English side by side in the same document.
Currently this feature is not expected to work properly if your native keyboard layout is not US or UK.
VT100-series terminals allow the server to send control sequences that shift temporarily into a separate character set for drawing simple lines and boxes. However, there are a variety of ways in which PuTTY can attempt to find appropriate characters, and the right one to use depends on the locally configured font. In general you should probably try lots of options until you find one that your particular font supports.
+
, -
and |
characters to draw approximations to boxes. You should use this option if none of the other options works.
By default, when you copy and paste a piece of the PuTTY screen that contains VT100 line and box drawing characters, PuTTY will paste them in the form they appear on the screen: either Unicode line drawing code points, or the ‘poor man's’ line-drawing characters +
, -
and |
. The checkbox ‘Copy and paste VT100 line drawing chars as lqqqk’ disables this feature, so line-drawing characters will be pasted as the ASCII characters that were printed to produce them. This will typically mean they come out mostly as q
and x
, with a scattering of jklmntuvw
at the corners. This might be useful if you were trying to recreate the same box layout in another program, for example.
Note that this option only applies to line-drawing characters which were printed by using the VT100 mechanism. Line-drawing characters that were received as Unicode code points will paste as Unicode always.
If PuTTY is configured to treat data from the server as encoded in UTF-8, then by default it disables the older VT100-style system of control sequences that cause the lower-case letters to be temporarily replaced by line drawing characters.
The rationale is that in UTF-8 mode you don't need those control sequences anyway, because all the line-drawing characters they access are available as Unicode characters already, so there's no need for applications to put the terminal into a special state to get at them.
Also, it removes a risk of the terminal accidentally getting into that state: if you accidentally write uncontrolled binary data to a non-UTF-8 terminal, it can be surprisingly common to find that your next shell prompt appears as a sequence of line-drawing characters and then you have to remember or look up how to get out of that mode. So by default, UTF-8 mode simply doesn't have a confusing mode like that to get into, accidentally or on purpose.
However, not all applications will see it that way. Even UTF-8 terminal users will still sometimes have to run software that tries to print line-drawing characters in the old-fashioned way. So the configuration option ‘Enable VT100 line drawing even in UTF-8 mode’ puts PuTTY into a hybrid mode in which it understands the VT100-style control sequences that change the meaning of the ASCII lower case letters, and understands UTF-8.
The Selection panel allows you to control the way copy and paste work in the PuTTY window.
PuTTY's copy and paste mechanism is by default modelled on the Unix xterm
application. The X Window System uses a three-button mouse, and the convention in that system is that the left button selects, the right button extends an existing selection, and the middle button pastes.
Windows often only has two mouse buttons, so when run on Windows, PuTTY is configurable. In PuTTY's default configuration (‘Compromise’), the right button pastes, and the middle button (if you have one) extends a selection.
If you have a three-button mouse and you are already used to the xterm
arrangement, you can select it using the ‘Action of mouse buttons’ control.
Alternatively, with the ‘Windows’ option selected, the middle button extends, and the right button brings up a context menu (on which one of the options is ‘Paste’). (This context menu is always available by holding down Ctrl and right-clicking, regardless of the setting of this option.)
(When PuTTY itself is running on Unix, it follows the X Window System convention.)
PuTTY allows the server to send control codes that let it take over the mouse and use it for purposes other than copy and paste. Applications which use this feature include the text-mode web browser links
, the Usenet newsreader trn
version 4, and the file manager mc
(Midnight Commander).
When running one of these applications, pressing the mouse buttons no longer performs copy and paste. If you do need to copy and paste, you can still do so if you hold down Shift while you do your mouse clicks.
However, it is possible in theory for applications to even detect and make use of Shift + mouse clicks. We don't know of any applications that do this, but in case someone ever writes one, unchecking the ‘Shift overrides application's use of mouse’ checkbox will cause Shift + mouse clicks to go to the server as well (so that mouse-driven copy and paste will be completely disabled).
If you want to prevent the application from taking over the mouse at all, you can do this using the Features control panel; see section 4.6.2.
As described in section 3.1.1, PuTTY has two modes of selecting text to be copied to the clipboard. In the default mode (‘Normal’), dragging the mouse from point A to point B selects to the end of the line containing A, all the lines in between, and from the very beginning of the line containing B. In the other mode (‘Rectangular block’), dragging the mouse between two points defines a rectangle, and everything within that rectangle is copied.
Normally, you have to hold down Alt while dragging the mouse to select a rectangular block. Using the ‘Default selection mode’ control, you can set rectangular selection as the default, and then you have to hold down Alt to get the normal behaviour.
Here you can configure which clipboard(s) are written or read by PuTTY's various copy and paste actions.
Most platforms, including Windows, have a single system clipboard. On these platforms, PuTTY provides a second clipboard-like facility by permitting you to paste the text you last selected in this window, whether or not it is currently also in the system clipboard. This is not enabled by default.
The X Window System (which underlies most Unix graphical interfaces) provides multiple clipboards (or ‘selections’), and many applications support more than one of them by a different user interface mechanism. When PuTTY itself is running on Unix, it has more configurability relating to these selections.
The two most commonly used selections are called ‘PRIMARY
’ and ‘CLIPBOARD
’; in applications supporting both, the usual behaviour is that PRIMARY
is used by mouse-only actions (selecting text automatically copies it to PRIMARY
, and middle-clicking pastes from PRIMARY
), whereas CLIPBOARD
is used by explicit Copy and Paste menu items or keypresses such as Ctrl-C and Ctrl-V.
The checkbox ‘Auto-copy selected text to system clipboard’ controls whether or not selecting text in the PuTTY terminal window automatically has the side effect of copying it to the system clipboard, without requiring a separate user interface action.
On X, the wording of this option is changed slightly so that ‘CLIPBOARD
’ is mentioned in place of the ‘system clipboard’. Text selected in the terminal window will always be automatically placed in the PRIMARY
selection, as is conventional, but if you tick this box, it will also be placed in ‘CLIPBOARD
’ at the same time.
PuTTY has three user-interface actions which can be configured to paste into the terminal (not counting menu items). You can click whichever mouse button (if any) is configured to paste (see section 4.11.1); you can press Shift-Ins; or you can press Ctrl-Shift-V, although that action is not enabled by default.
You can configure which of the available clipboards each of these actions pastes from (including turning the paste action off completely). On platforms with a single system clipboard (such as Windows), the available options are to paste from that clipboard or to paste from PuTTY's internal memory of the last selected text within that window. On X, the standard options are CLIPBOARD
or PRIMARY
.
(PRIMARY
is conceptually similar in that it also refers to the last selected text – just across all applications instead of just this window.)
The two keyboard options each come with a corresponding key to copy to the same clipboard. Whatever you configure Shift-Ins to paste from, Ctrl-Ins will copy to the same location; similarly, Ctrl-Shift-C will copy to whatever Ctrl-Shift-V pastes from.
On X, you can also enter a selection name of your choice. For example, there is a rarely-used standard selection called ‘SECONDARY
’, which Emacs (for example) can work with if you hold down the Meta key while dragging to select or clicking to paste; if you configure a PuTTY keyboard action to access this clipboard, then you can interoperate with other applications' use of it. Another thing you could do would be to invent a clipboard name yourself, to create a special clipboard shared only between instances of PuTTY, or between just instances configured in that particular way.
It is possible for the clipboard to contain not just text (with newlines and tabs) but also control characters such as ESC which could have surprising effects if pasted into a terminal session, depending on what program is running on the server side. Copying text from a mischievous web page could put such characters onto the clipboard.
By default, PuTTY filters out the more unusual control characters, only letting through the more obvious text-formatting characters (newlines, tab, backspace, and DEL).
Setting this option stops this filtering; on paste, any character on the clipboard is sent to the session uncensored. This might be useful if you are deliberately using control character pasting as a simple form of scripting, for instance.
The Copy configuration panel controls behaviour specifically related to copying from the terminal window to the clipboard.
PuTTY will select a word at a time in the terminal window if you double-click to begin the drag. This section allows you to control precisely what is considered to be a word.
Each character is given a class, which is a small number (typically 0, 1 or 2). PuTTY considers a single word to be any number of adjacent characters in the same class. So by modifying the assignment of characters to classes, you can modify the word-by-word selection behaviour.
In the default configuration, the character classes are:
So, for example, if you assign the @
symbol into character class 2, you will be able to select an e-mail address with just a double click.
In order to adjust these assignments, you start by selecting a group of characters in the list box. Then enter a class number in the edit box below, and press the ‘Set’ button.
This mechanism currently only covers ASCII characters, because it isn't feasible to expand the list to cover the whole of Unicode.
Character class definitions can be modified by control sequences sent by the server. This configuration option controls the default state, which will be restored when you reset the terminal (see section 3.1.3.6). However, if you modify this option in mid-session using ‘Change Settings’, it will take effect immediately.
If you enable ‘Copy to clipboard in RTF as well as plain text’, PuTTY will write formatting information to the clipboard as well as the actual text you copy. The effect of this is that if you paste into (say) a word processor, the text will appear in the word processor in the same font, colour, and style (e.g. bold, underline) PuTTY was using to display it.
This option can easily be inconvenient, so by default it is disabled.
The Colours panel allows you to control PuTTY's use of colour.
This option is enabled by default. If it is disabled, PuTTY will ignore any control sequences sent by the server to request coloured text.
If you have a particularly garish application, you might want to turn this option off and make PuTTY only use the default foreground and background colours.
This option is enabled by default. If it is disabled, PuTTY will ignore any control sequences sent by the server which use the extended 256-colour mode supported by recent versions of xterm
.
If you have an application which is supposed to use 256-colour mode and it isn't working, you may find you need to tell your server that your terminal supports 256 colours. On Unix, you do this by ensuring that the setting of TERM
describes a 256-colour-capable terminal. You can check this using a command such as infocmp
:
$ infocmp | grep colors
colors#256, cols#80, it#8, lines#24, pairs#256,
If you do not see ‘colors#256
’ in the output, you may need to change your terminal setting. On modern Linux machines, you could try ‘xterm-256color
’.
This option is enabled by default. If it is disabled, PuTTY will ignore any control sequences sent by the server which use the control sequences supported by modern terminals to specify arbitrary 24-bit RGB colour value.
When the server sends a control sequence indicating that some text should be displayed in bold, PuTTY can handle this in several ways. It can either change the font for a bold version, or use the same font in a brighter colour, or it can do both (brighten the colour and embolden the font). This control lets you choose which.
By default bold is indicated by colour, so non-bold text is displayed in light grey and bold text is displayed in bright white (and similarly in other colours). If you change the setting to ‘The font’ box, bold and non-bold text will be displayed in the same colour, and instead the font will change to indicate the difference. If you select ‘Both’, the font and the colour will both change.
Some applications rely on ‘bold black’ being distinguishable from a black background; if you choose ‘The font’, their text may become invisible.
Logical palettes are a mechanism by which a Windows application running on an 8-bit colour display can select precisely the colours it wants instead of going with the Windows standard defaults.
If you are not getting the colours you ask for on an 8-bit display, you can try enabling this option. However, be warned that it's never worked very well.
Enabling this option will cause PuTTY to ignore the configured colours for ‘Default Background/Foreground’ and ‘Cursor Colour/Text’ (see section 4.13.7), instead going with the system-wide defaults.
Note that non-bold and bold text will be the same colour if this option is enabled. You might want to change to indicating bold text by font changes (see section 4.13.4).
The main colour control allows you to specify exactly what colours things should be displayed in. To modify one of the PuTTY colours, use the list box to select which colour you want to modify. The RGB values for that colour will appear on the right-hand side of the list box. Now, if you press the ‘Modify’ button, you will be presented with a colour selector, in which you can choose a new colour to go in place of the old one. (You may also edit the RGB values directly in the edit boxes, if you wish; each value is an integer from 0 to 255.)
PuTTY allows you to set the cursor colour, the default foreground and background, and the precise shades of all the ANSI configurable colours (black, red, green, yellow, blue, magenta, cyan, and white). You can also modify the precise shades used for the bold versions of these colours; these are used to display bold text if you have chosen to indicate that by colour (see section 4.13.4), and can also be used if the server asks specifically to use them. (Note that ‘Default Bold Background’ is not the background colour used for bold text; it is only used if the server specifically asks for a bold background.)
The Connection panel allows you to configure options that apply to more than one type of connection.
If you find your sessions are closing unexpectedly (most often with ‘Connection reset by peer’) after they have been idle for a while, you might want to try using this option.
Some network routers and firewalls need to keep track of all connections through them. Usually, these firewalls will assume a connection is dead if no data is transferred in either direction after a certain time interval. This can cause PuTTY sessions to be unexpectedly closed by the firewall if no traffic is seen in the session for some time.
The keepalive option (‘Seconds between keepalives’) allows you to configure PuTTY to send data through the session at regular intervals, in a way that does not disrupt the actual terminal session. If you find your firewall is cutting idle connections off, you can try entering a non-zero value in this field. The value is measured in seconds; so, for example, if your firewall cuts connections off after ten minutes then you might want to enter 300 seconds (5 minutes) in the box.
Note that keepalives are not always helpful. They help if you have a firewall which drops your connection after an idle period; but if the network between you and the server suffers from breaks in connectivity then keepalives can actually make things worse. If a session is idle, and connectivity is temporarily lost between the endpoints, but the connectivity is restored before either side tries to send anything, then there will be no problem - neither endpoint will notice that anything was wrong. However, if one side does send something during the break, it will repeatedly try to re-send, and eventually give up and abandon the connection. Then when connectivity is restored, the other side will find that the first side doesn't believe there is an open connection any more. Keepalives can make this sort of problem worse, because they increase the probability that PuTTY will attempt to send data during a break in connectivity. (Other types of periodic network activity can cause this behaviour; in particular, SSH-2 re-keys can have this effect. See section 4.18.2.)
Therefore, you might find that keepalives help connection loss, or you might find they make it worse, depending on what kind of network problems you have between you and the server.
Keepalives are only supported in Telnet and SSH; the Rlogin, SUPDUP, and Raw protocols offer no way of implementing them. (For an alternative, see section 4.14.3.)
Note that if you are using SSH-1 and the server has a bug that makes it unable to deal with SSH-1 ignore messages (see section 4.27.14), enabling keepalives will have no effect.
Nagle's algorithm is a detail of TCP/IP implementations that tries to minimise the number of small data packets sent down a network connection. With Nagle's algorithm enabled, PuTTY's bandwidth usage will be slightly more efficient; with it disabled, you may find you get a faster response to your keystrokes when connecting to some types of server.
The Nagle algorithm is disabled by default for interactive connections.
NOTE: TCP keepalives should not be confused with the application-level keepalives described in section 4.14.1. If in doubt, you probably want application-level keepalives; TCP keepalives are provided for completeness.
The idea of TCP keepalives is similar to application-level keepalives, and the same caveats apply. The main differences are:
TCP keepalives may be more useful for ensuring that half-open connections are terminated than for keeping a connection alive.
TCP keepalives are disabled by default.
This option allows the user to select between the old and new Internet protocols and addressing schemes (IPv4 and IPv6). The selected protocol will be used for most outgoing network connections (including connections to proxies); however, tunnels have their own configuration, for which see section 4.26.2.
The default setting is ‘Auto’, which means PuTTY will do something sensible and try to guess which protocol you wanted. (If you specify a literal Internet address, it will use whichever protocol that address implies. If you provide a hostname, it will see what kinds of address exist for that hostname; it will use IPv6 if there is an IPv6 address available, and fall back to IPv4 if not.)
If you need to force PuTTY to use a particular protocol, you can explicitly set this to ‘IPv4’ or ‘IPv6’.
This allows you to tell PuTTY that the host it will really end up connecting to is different from where it thinks it is making a network connection.
You might use this, for instance, if you had set up an SSH port forwarding in one PuTTY session so that connections to some arbitrary port (say, localhost
port 10022) were forwarded to a second machine's SSH port (say, foovax
port 22), and then started a second PuTTY connecting to the forwarded port.
In normal usage, the second PuTTY will access the host key cache under the host name and port it actually connected to (i.e. localhost
port 10022 in this example). Using the logical host name option, however, you can configure the second PuTTY to cache the host key under the name of the host you know that it's really going to end up talking to (here foovax
).
This can be useful if you expect to connect to the same actual server through many different channels (perhaps because your port forwarding arrangements keep changing): by consistently setting the logical host name, you can arrange that PuTTY will not keep asking you to reconfirm its host key. Conversely, if you expect to use the same local port number for port forwardings to lots of different servers, you probably didn't want any particular server's host key cached under that local port number. (For this latter case, you could instead explicitly configure host keys in the relevant sessions; see section 4.19.3.)
If you just enter a host name for this option, PuTTY will cache the SSH host key under the default SSH port for that host, irrespective of the port you really connected to (since the typical scenario is like the above example: you connect to a silly real port number and your connection ends up forwarded to the normal port-22 SSH server of some other machine). To override this, you can append a port number to the logical host name, separated by a colon. E.g. entering ‘foovax:2200
’ as the logical host name will cause the host key to be cached as if you had connected to port 2200 of foovax
.
If you provide a host name using this option, it is also displayed in other locations which contain the remote host name, such as the default window title and the default SSH password prompt. This reflects the fact that this is the host you're really connecting to, which is more important than the mere means you happen to be using to contact that host. (This applies even if you're using a protocol other than SSH.)
The Data panel allows you to configure various pieces of data which can be sent to the server to affect your connection at the far end.
Each option on this panel applies to more than one protocol. Options which apply to only one protocol appear on that protocol's configuration panels.
All three of the SSH, Telnet, and Rlogin protocols allow you to specify what user name you want to log in as, without having to type it explicitly every time. (Some Telnet servers don't support this.)
In this box you can type that user name.
When the previous box (section 4.15.1) is left blank, by default, PuTTY will prompt for a username at the time you make a connection.
In some environments, such as the networks of large organisations implementing single sign-on, a more sensible default may be to use the name of the user logged in to the local operating system (if any); this is particularly likely to be useful with GSSAPI key exchange and user authentication (see section 4.23 and section 4.18.1.1). This control allows you to change the default behaviour.
The current system username is displayed in the dialog as a convenience. It is not saved in the configuration; if a saved session is later used by a different user, that user's name will be used.
Most servers you might connect to with PuTTY are designed to be connected to from lots of different types of terminal. In order to send the right control sequences to each one, the server will need to know what type of terminal it is dealing with. Therefore, each of the SSH, Telnet, and Rlogin protocols allow a text string to be sent down the connection describing the terminal. On a Unix server, this selects an entry from the termcap
or terminfo
database that tells applications what control sequences to send to the terminal, and what character sequences to expect the keyboard to generate.
PuTTY attempts to emulate the Unix xterm
program, and by default it reflects this by sending xterm
as a terminal-type string. If you find this is not doing what you want - perhaps the remote system reports ‘Unknown terminal type’ - you could try setting this to something different, such as vt220
.
If you're not sure whether a problem is due to the terminal type setting or not, you probably need to consult the manual for your application or your server.
The Telnet, Rlogin, and SSH protocols allow the client to specify terminal speeds to the server.
This parameter does not affect the actual speed of the connection, which is always ‘as fast as possible’; it is just a hint that is sometimes used by server software to modify its behaviour. For instance, if a slow speed is indicated, the server may switch to a less bandwidth-hungry display mode.
The value is usually meaningless in a network environment, but PuTTY lets you configure it, in case you find the server is reacting badly to the default value.
The format is a pair of numbers separated by a comma, for instance, 38400,38400
. The first number represents the output speed (from the server) in bits per second, and the second is the input speed (to the server). (Only the first is used in the Rlogin protocol.)
This option has no effect on Raw connections.
The Telnet protocol provides a means for the client to pass environment variables to the server. Many Telnet servers have stopped supporting this feature due to security flaws, but PuTTY still supports it for the benefit of any servers which have found other ways around the security problems than just disabling the whole mechanism.
Version 2 of the SSH protocol also provides a similar mechanism, which is easier to implement without security flaws. Newer SSH-2 servers are more likely to support it than older ones.
This configuration data is not used in the SSH-1, rlogin or raw protocols.
To add an environment variable to the list transmitted down the connection, you enter the variable name in the ‘Variable’ box, enter its value in the ‘Value’ box, and press the ‘Add’ button. To remove one from the list, select it in the list box and press ‘Remove’.
The Proxy panel allows you to configure PuTTY to use various types of proxy in order to make its network connections. The settings in this panel affect the primary network connection forming your PuTTY session, and also any extra connections made as a result of SSH port forwarding (see section 3.5).
Note that unlike some software (such as web browsers), PuTTY does not attempt to automatically determine whether to use a proxy and (if so) which one to use for a given destination. If you need to use a proxy, it must always be explicitly configured.
The ‘Proxy type’ drop-down allows you to configure what type of proxy you want PuTTY to use for its network connections. The default setting is ‘None’; in this mode no proxy is used for any connection.
CONNECT
command, as documented in RFC 2817.
connect myhost.com 22
to connect through to an external host. Selecting ‘Telnet’ allows you to tell PuTTY to use this type of proxy, with the precise command specified as described in section 4.16.5.
The ‘Proxy hostname’ field will be interpreted as the name of a PuTTY saved session if one exists, or a hostname if not. This allows multi-hop jump paths, if the referenced saved session is itself configured to use an SSH proxy; and it allows combining SSH and non-SSH proxying.
-J
option).
This could be used, for instance, to talk to some kind of network proxy that PuTTY does not natively support; or you could tunnel a connection over something other than TCP/IP entirely.
You can also enable this mode on the command line; see section 3.11.3.27.
Typically you will only need to use a proxy to connect to non-local parts of your network; for example, your proxy might be required for connections outside your company's internal network. In the ‘Exclude Hosts/IPs’ box you can enter ranges of IP addresses, or ranges of DNS names, for which PuTTY will avoid using the proxy and make a direct connection instead.
The ‘Exclude Hosts/IPs’ box may contain more than one exclusion range, separated by commas. Each range can be an IP address or a DNS name, with a *
character allowing wildcards. For example:
*.example.com
This excludes any host with a name ending in .example.com
from proxying.
192.168.88.*
This excludes any host with an IP address starting with 192.168.88 from proxying.
192.168.88.*,*.example.com
This excludes both of the above ranges at once.
Connections to the local host (the host name localhost
, and any loopback IP address) are never proxied, even if the proxy exclude list does not explicitly contain them. It is very unlikely that this behaviour would ever cause problems, but if it does you can change it by enabling ‘Consider proxying local host connections’.
Note that if you are doing DNS at the proxy (see section 4.16.3), you should make sure that your proxy exclusion settings do not depend on knowing the IP address of a host. If the name is passed on to the proxy without PuTTY looking it up, it will never know the IP address and cannot check it against your list.
If you are using a proxy to access a private network, it can make a difference whether DNS name resolution is performed by PuTTY itself (on the client machine) or performed by the proxy.
The ‘Do DNS name lookup at proxy end’ configuration option allows you to control this. If you set it to ‘No’, PuTTY will always do its own DNS, and will always pass an IP address to the proxy. If you set it to ‘Yes’, PuTTY will always pass host names straight to the proxy without trying to look them up first.
If you set this option to ‘Auto’ (the default), PuTTY will do something it considers appropriate for each type of proxy. Most types of proxy (HTTP, SOCK5, SSH, Telnet, and local) will have host names passed straight to them; SOCKS4 proxies will not.
Note that if you are doing DNS at the proxy, you should make sure that your proxy exclusion settings (see section 4.16.2) do not depend on knowing the IP address of a host. If the name is passed on to the proxy without PuTTY looking it up, it will never know the IP address and cannot check it against your list.
The original SOCKS 4 protocol does not support proxy-side DNS. There is a protocol extension (SOCKS 4A) which does support it, but not all SOCKS 4 servers provide this extension. If you enable proxy DNS and your SOCKS 4 server cannot deal with it, this might be why.
If you want to avoid PuTTY making any DNS query related to your destination host name (for example, because your local DNS resolver is very slow to return a negative response in that situation), then as well as setting this control to ‘Yes’, you may also need to turn off GSSAPI authentication and GSSAPI key exchange in SSH (see section 4.23 and section 4.18.1.1 respectively). This is because GSSAPI setup also involves a DNS query for the destination host name, and that query is performed by the separate GSSAPI library, so PuTTY can't override or reconfigure it.
You can enter a username and a password in the ‘Username’ and ‘Password’ boxes, which will be used if your proxy requires authentication.
Note that if you save your session, the proxy password will be saved in plain text, so anyone who can access your PuTTY configuration data will be able to discover it.
If PuTTY discovers that it needs a proxy username or password and you have not specified one here, PuTTY will prompt for it interactively in the terminal window.
Authentication is not fully supported for all forms of proxy:
If you are using the Telnet proxy type, the usual command required by the firewall's Telnet server is connect
, followed by a host name and a port number. If your proxy needs a different command, you can enter an alternative in the ‘Command to send to proxy’ box.
If you are using the Local proxy type, the local command to run is specified here.
If you are using the ‘SSH to proxy and execute a command’ type, the command to run on the SSH proxy server is specified here. Similarly, if you are using ‘SSH to proxy and invoke a subsystem’, the subsystem name is constructed as specified here.
In this string, you can use \n
to represent a new-line, \r
to represent a carriage return, \t
to represent a tab character, and \x
followed by two hex digits to represent any other character. \\
is used to encode the \
character itself.
Also, the special strings %host
and %port
will be replaced by the host name and port number you want to connect to. For Telnet and Local proxy types, the strings %user
and %pass
will be replaced by the proxy username and password (which, if not specified in the configuration, will be prompted for) – this does not happen with SSH proxy types (because the proxy username/password are used for SSH authentication). The strings %proxyhost
and %proxyport
will be replaced by the host details specified on the Proxy panel, if any (this is most likely to be useful for proxy types using a local or remote command). To get a literal %
sign, enter %%
.
If a Telnet proxy server prompts for a username and password before commands can be sent, you can use a command such as:
%user\n%pass\nconnect %host %port\n
This will send your username and password as the first two lines to the proxy, followed by a command to connect to the desired host and port. Note that if you do not include the %user
or %pass
tokens in the Telnet command, then anything specified in ‘Username’ and ‘Password’ configuration fields will be ignored.
Often the proxy interaction has its own diagnostic output; this is particularly the case for local proxy commands.
The setting ‘Print proxy diagnostics in the terminal window’ lets you control how much of the proxy's diagnostics are printed to the main terminal window, along with output from your main session.
By default (‘No’), proxy diagnostics are only sent to the Event Log; with ‘Yes’ they are also printed to the terminal, where they may get mixed up with your main session. ‘Only until session starts’ is a compromise; proxy messages will go to the terminal window until the main session is deemed to have started (in a protocol-dependent way), which is when they're most likely to be interesting; any further proxy-related messages during the session will only go to the Event Log.
The SSH panel allows you to configure options that only apply to SSH sessions.
In SSH, you don't have to run a general shell session on the server. Instead, you can choose to run a single specific command (such as a mail user agent, for example). If you want to do this, enter the command in the ‘Remote command’ box.
Note that most servers will close the session after executing the command.
If you tick this box, PuTTY will not attempt to run a shell or command after connecting to the remote server. You might want to use this option if you are only using the SSH connection for port forwarding, and your user account on the server does not have the ability to run a shell.
This feature is only available in SSH protocol version 2 (since the version 1 protocol assumes you will always want to run a shell).
This feature can also be enabled using the -N
command-line option; see section 3.11.3.13.
If you use this feature in Plink, you will not be able to terminate the Plink process by any graceful means; the only way to kill it will be by pressing Control-C or sending a kill signal from another program.
This enables data compression in the SSH connection: data sent by the server is compressed before sending, and decompressed at the client end. Likewise, data sent by PuTTY to the server is compressed first and the server decompresses it at the other end. This can help make the most of a low-bandwidth connection.
This allows you to select whether to use SSH protocol version 2 or the older version 1.
You should normally leave this at the default of ‘2’. As well as having fewer features, the older SSH-1 protocol is no longer developed, has many known cryptographic weaknesses, and is generally not considered to be secure. PuTTY's protocol 1 implementation is provided mainly for compatibility, and is no longer being enhanced.
If a server offers both versions, prefer ‘2’. If you have some server or piece of equipment that only talks SSH-1, select ‘1’ here, and do not treat the resulting connection as secure.
PuTTY will not automatically fall back to the other version of the protocol if the server turns out not to match your selection here; instead, it will put up an error message and abort the connection. This prevents an active attacker downgrading an intended SSH-2 connection to SSH-1.
The controls in this box allow you to configure PuTTY to reuse an existing SSH connection, where possible.
The SSH-2 protocol permits you to run multiple data channels over the same SSH connection, so that you can log in just once (and do the expensive encryption setup just once) and then have more than one terminal window open.
Each instance of PuTTY can still run at most one terminal session, but using the controls in this box, you can configure PuTTY to check if another instance of itself has already connected to the target host, and if so, share that instance's SSH connection instead of starting a separate new one.
To enable this feature, just tick the box ‘Share SSH connections if possible’. Then, whenever you start up a PuTTY session connecting to a particular host, it will try to reuse an existing SSH connection if one is available. For example, selecting ‘Duplicate Session’ from the system menu will launch another session on the same host, and if sharing is enabled then it will reuse the existing SSH connection.
When this mode is in use, the first PuTTY that connected to a given server becomes the ‘upstream’, which means that it is the one managing the real SSH connection. All subsequent PuTTYs which reuse the connection are referred to as ‘downstreams’: they do not connect to the real server at all, but instead connect to the upstream PuTTY via local inter-process communication methods.
For this system to be activated, both the upstream and downstream instances of PuTTY must have the sharing option enabled.
The upstream PuTTY can therefore not terminate until all its downstreams have closed. This is similar to the effect you get with port forwarding or X11 forwarding, in which a PuTTY whose terminal session has already finished will still remain open so as to keep serving forwarded connections.
In case you need to configure this system in more detail, there are two additional checkboxes which allow you to specify whether a particular PuTTY can act as an upstream or a downstream or both. (These boxes only take effect if the main ‘Share SSH connections if possible’ box is also ticked.) By default both of these boxes are ticked, so that multiple PuTTYs started from the same configuration will designate one of themselves as the upstream and share a single connection; but if for some reason you need a particular PuTTY configuration not to be an upstream (e.g. because you definitely need it to close promptly) or not to be a downstream (e.g. because it needs to do its own authentication using a special private key) then you can untick one or the other of these boxes.
I have referred to ‘PuTTY’ throughout the above discussion, but all the other PuTTY tools which make SSH connections can use this mechanism too. For example, if PSCP or PSFTP loads a configuration with sharing enabled, then it can act as a downstream and use an existing SSH connection set up by an instance of GUI PuTTY. The one special case is that PSCP and PSFTP will never act as upstreams.
It is possible to test programmatically for the existence of a live upstream using Plink. See section 7.2.3.4.
The Kex panel (short for ‘key exchange’) allows you to configure options related to SSH-2 key exchange.
Key exchange occurs at the start of an SSH connection (and occasionally thereafter); it establishes a shared secret that is used as the basis for all of SSH's security features. It is therefore very important for the security of the connection that the key exchange is secure.
Key exchange is a cryptographically intensive process; if either the client or the server is a relatively slow machine, the slower methods may take several tens of seconds to complete.
If connection startup is too slow, or the connection hangs periodically, you may want to try changing these settings.
If you don't understand what any of this means, it's safe to leave these settings alone.
This entire panel is only relevant to SSH protocol version 2; none of these settings affect SSH-1 at all.
PuTTY supports a variety of SSH-2 key exchange methods, and allows you to choose which one you prefer to use; configuration is similar to cipher selection (see section 4.20).
PuTTY currently supports the following key exchange methods:
If the first algorithm PuTTY finds is below the ‘warn below here’ line, you will see a warning box when you make the connection, similar to that for cipher selection (see section 4.20).
PuTTY supports a set of key exchange methods that also incorporates GSSAPI-based authentication. They are enabled with the ‘Attempt GSSAPI key exchange’ checkbox (which also appears on the ‘GSSAPI’ panel).
PuTTY can only perform the GSSAPI-authenticated key exchange methods when using Kerberos V5, and not other GSSAPI mechanisms. If the user running PuTTY has current Kerberos V5 credentials, then PuTTY will select the GSSAPI key exchange methods in preference to any of the ordinary SSH key exchange methods configured in the preference list. There's a GSSAPI-based equivalent to most of the ordinary methods listed in section 4.18.1; server support determines which one will be used. (PuTTY's preference order for GSSAPI-authenticated key exchange methods is fixed, not controlled by the preference list.)
The advantage of doing GSSAPI authentication as part of the SSH key exchange is apparent when you are using credential delegation (see section 4.23.1). The SSH key exchange can be repeated later in the session, and this allows your Kerberos V5 credentials (which are typically short-lived) to be automatically re-delegated to the server when they are refreshed on the client. (This feature is commonly referred to as ‘cascading credentials’.)
If your server doesn't support GSSAPI key exchange, it may still support GSSAPI in the SSH user authentication phase. This will still let you log in using your Kerberos credentials, but will only allow you to delegate the credentials that are active at the beginning of the session; they can't be refreshed automatically later, in a long-running session. See section 4.23 for how to control GSSAPI user authentication in PuTTY.
Another effect of GSSAPI key exchange is that it replaces the usual SSH mechanism of permanent host keys described in section 2.2. So if you use this method, then you won't be asked any interactive questions about whether to accept the server's host key. Instead, the Kerberos exchange will verify the identity of the host you connect to, at the same time as verifying your identity to it.
If the session key negotiated at connection startup is used too much or for too long, it may become feasible to mount attacks against the SSH connection. Therefore, the SSH-2 protocol specifies that a new key exchange should take place every so often; this can be initiated by either the client or the server.
While this renegotiation is taking place, no data can pass through the SSH connection, so it may appear to ‘freeze’. (The occurrence of repeat key exchange is noted in the Event Log; see section 3.1.3.1.) Usually the same algorithm is used as at the start of the connection, with a similar overhead.
These options control how often PuTTY will initiate a repeat key exchange (‘rekey’). You can also force a key exchange at any time from the Special Commands menu (see section 3.1.3.2).
You might have a need to disable time-based rekeys completely for the same reasons that keepalives aren't always helpful. If you anticipate suffering a network dropout of several hours in the middle of an SSH connection, but were not actually planning to send data down that connection during those hours, then an attempted rekey in the middle of the dropout will probably cause the connection to be abandoned, whereas if rekeys are disabled then the connection should in principle survive (in the absence of interfering firewalls). See section 4.14.1 for more discussion of these issues; for these purposes, rekeys have much the same properties as keepalives. (Except that rekeys have cryptographic value in themselves, so you should bear that in mind when deciding whether to turn them off.) Note, however, the the SSH server can still initiate rekeys.
As well as specifying a value in bytes, the following shorthand can be used:
1k
’ specifies 1 kilobyte (1024 bytes).
1M
’ specifies 1 megabyte (1024 kilobytes).
1G
’ specifies 1 gigabyte (1024 megabytes).
Disabling data-based rekeys entirely is a bad idea. The integrity, and to a lesser extent, confidentiality of the SSH-2 protocol depend in part on rekeys occurring before a 32-bit packet sequence number wraps around. Unlike time-based rekeys, data-based rekeys won't occur when the SSH connection is idle, so they shouldn't cause the same problems. The SSH-1 protocol, incidentally, has even weaker integrity protection than SSH-2 without rekeys.
The Host Keys panel allows you to configure options related to host key management.
Host keys are used to prove the server's identity, and assure you that the server is not being spoofed (either by a man-in-the-middle attack or by completely replacing it on the network). See section 2.2 for a basic introduction to host keys.
Much of this panel is only relevant to SSH protocol version 2; SSH-1 only supports one type of host key.
PuTTY supports a variety of SSH-2 host key types, and allows you to choose which one you prefer to use to identify the server. Configuration is similar to cipher selection (see section 4.20).
PuTTY currently supports the following host key types:
2^255-19
.
If PuTTY already has one or more host keys stored for the server, it will by default prefer to use one of those, even if the server has a key type that is higher in the preference order. You can add such a key to PuTTY's cache from within an existing session using the ‘Special Commands’ menu; see section 3.1.3.2.
Otherwise, PuTTY will choose a key type based purely on the preference order you specify in the configuration.
If the first key type PuTTY finds is below the ‘warn below here’ line, you will see a warning box when you make the connection, similar to that for cipher selection (see section 4.20).
By default, PuTTY will adjust the preference order for SSH-2 host key algorithms so that any host keys it already knows are moved to the top of the list.
This prevents you from having to check and confirm a new host key for a server you already had one for (e.g. because the server has generated an alternative key of a type higher in PuTTY's preference order, or because you changed the preference order itself).
However, on the other hand, it can leak information to a listener in the network about whether you already know a host key for this server.
For this reason, this policy is configurable. By turning this checkbox off, you can reset PuTTY to always use the exact order of host key algorithms configured in the preference list described in section 4.19.1, so that a listener will find out nothing about what keys you had stored.
In some situations, if PuTTY's automated host key management is not doing what you need, you might need to manually configure PuTTY to accept a specific host key, or one of a specific set of host keys.
One reason why you might want to do this is because the host name PuTTY is connecting to is using round-robin DNS to return one of multiple actual servers, and they all have different host keys. In that situation, you might need to configure PuTTY to accept any of a list of host keys for the possible servers, while still rejecting any key not in that list.
Another reason is if PuTTY's automated host key management is completely unavailable, e.g. because PuTTY (or Plink or PSFTP, etc) is running in a Windows environment without access to the Registry. In that situation, you will probably want to use the -hostkey
command-line option to configure the expected host key(s); see section 3.11.3.22.
For situations where PuTTY's automated host key management simply picks the wrong host name to store a key under, you may want to consider setting a ‘logical host name’ instead; see section 4.14.5.
To configure manual host keys via the GUI, enter some text describing the host key into the edit box in the ‘Manually configure host keys for this connection’ container, and press the ‘Add’ button. The text will appear in the ‘Host keys or fingerprints to accept’ list box. You can remove keys again with the ‘Remove’ button.
The text describing a host key can be in one of the following formats:
SHA256:
’ followed by 43 case-sensitive characters.
MD5:
’. (The case of the characters does not matter.)
/etc/ssh/ssh_host_rsa_key.pub
.
If this box contains at least one host key or fingerprint when PuTTY makes an SSH connection, then PuTTY's automated host key management is completely bypassed: the connection will be permitted if and only if the host key presented by the server is one of the keys listed in this box, and the host key store in the Registry will be neither read nor written, unless you explicitly do so.
If the box is empty (as it usually is), then PuTTY's automated host key management will work as normal.
In some environments, the SSH host keys for a lot of servers will all be signed in turn by a central ‘certification authority’ (‘CA’ for short). This simplifies host key configuration for users, because if they configure their SSH client to accept host keys certified by that CA, then they don't need to individually confirm each host key the first time they connect to that server.
In order to do this, press the ‘Configure host CAs’ button in the ‘Host keys’ configuration panel. This will launch a secondary configuration dialog box where you can configure what CAs PuTTY will accept signatures from.
Note that this configuration is common to all saved sessions. Everything in the main PuTTY configuration is specific to one saved session, and you can prepare a separate session with all the configuration different. But there's only one copy of the host CA configuration, and it applies to all sessions PuTTY runs, whether saved or not.
(Otherwise, it would be useless – configuring a CA by hand for each new host wouldn't be any more convenient than pressing the ‘confirm’ button for each new host's host key.)
To set up a new CA using this config box:
First, load the CA's public key from a file, or paste it directly into the ‘Public key of certification authority’ edit box. If your organisation signs its host keys in this way, they will publish the public key of their CA so that SSH users can include it in their configuration.
Next, in the ‘Valid hosts this key is trusted to certify’ box, configure at least one hostname wildcard to say what servers PuTTY should trust this CA to speak for. For example, suppose you work for Example Corporation (example.com
), and the Example Corporation IT department has advertised a CA that signs all the Example internal machines' host keys. Then probably you want to trust that CA to sign host keys for machines in the domain example.com
, but not for anything else. So you might enter ‘*.example.com
’ into the ‘Valid hosts’ box.
It's important to limit what the CA key is allowed to sign. Don't just enter ‘*
’ in that box! If you do that, you're saying that Example Corporation IT department is authorised to sign a host key for anything at all you might decide to connect to – even if you're connecting out of the company network to a machine somewhere else, such as your own personal server. So that configuration would enable the Example IT department to act as a ‘man-in-the-middle’ between your PuTTY process and your server, and listen in to your communications – exactly the thing SSH is supposed to avoid.
So, if the CA was provided to you by the sysadmins responsible for example.com
(or whatever), make sure PuTTY will only trust it for machines in the example.com
domain.
For the full syntax of the ‘Valid hosts’ expression, see section 4.19.4.1.
Finally, choose an identifying name for this CA; enter that name in the ‘Name for this CA’ edit box at the top of the window, and press ‘Save’ to record the CA in your configuration. The name you chose will appear in the list of saved CAs to the left of the ‘Save’ button.
The identifying name can be anything you like. It's there so that if you store multiple certificates you can tell which is which later when you want to edit or delete them. It also appears in the PuTTY Event Log when a server presents a certificate signed by that CA.
To reload an existing CA configuration, select it in the list box and press ‘Load’. Then you can make changes, and save it again.
To remove a CA from your configuration completely, select it in the list and press ‘Delete’.
The simplest thing you can enter in the ‘Valid hosts this key is trusted to certify’ edit box is just a hostname wildcard such as ‘*.example.com
’. This matches any host in any subdomain, so both ‘ssh.example.com
’ and ‘login.dept.example.com
’ would match, but ‘prod.example.net
’ would not.
But you can also enter multiple host name wildcards, and port number ranges, and make complicated Boolean expressions out of them using the operators ‘&&
’ for ‘and’, ‘||
’ for ‘or’, ‘!
’ for ‘not’, and parentheses.
For example, here are some other things you could enter.
*.foo.example.com || *.bar.example.com
’. This means the CA is trusted to sign the host key for a connection if the host name matches ‘*.foo.example.com’ or it matches ‘*.bar.example.com’. In other words, the CA has authority over those two particular subdomains of example.com
, but not for anything else, like www.example.com
.
*.example.com && ! *.extrasecure.example.com
’. This means the CA is trusted to sign the host key for a connection if the host name matches ‘*.example.com’ but does not match ‘*.extrasecure.example.com’. (Imagine if there was one top-secret set of servers in your company that the main IT department didn't have security clearance to administer.)
*.example.com && port:22
’. This means the CA is trusted to sign the host key for a connection if the host name matches ‘*.example.com’ and the port number is 22. SSH servers running on other ports would not be covered.
(*.foo.example.com || *.bar.example.com) && port:0-1023
’. This matches two subdomains of example.com
, as before, but also restricts the port number to the range 0-1023.
A certificate configuration expression consists of one or more individual requirements which can each be a hostname wildcard, a single port number, or a port number range, combined together with these Boolean operators.
Unlike other languages such as C, there is no implied priority between ‘&&
’ and ‘||
’. If you write ‘A && B || C
’ (where A
, B
and C
are some particular requirements), then PuTTY will report a syntax error, because you haven't said which of the ‘&&
’ and ‘||
’ takes priority tightly. You will have to write either ‘(A && B) || C
’, meaning ‘both of A
and B
, or alternatively just C
’, or ‘A && (B || C)
’ (‘A
, and also at least one of B
and C
’), to make it clear.
RSA keys can be used to generate signatures with a choice of secure hash function. Typically, any version of OpenSSH new enough to support certificates at all will also be new enough to avoid using SHA-1, so the default settings of accepting the more modern SHA-256 and SHA-512 should be suitable for nearly all cases. For completeness, however, you can configure which types of RSA signature PuTTY will accept in a certificate from a CA using an RSA key.
PuTTY supports a variety of different encryption algorithms, and allows you to choose which one you prefer to use. You can do this by dragging the algorithms up and down in the list box (or moving them using the Up and Down buttons) to specify a preference order. When you make an SSH connection, PuTTY will search down the list from the top until it finds an algorithm supported by the server, and then use that.
PuTTY currently supports the following algorithms:
If the algorithm PuTTY finds is below the ‘warn below here’ line, you will see a warning box when you make the connection:
The first cipher supported by the server
is single-DES, which is below the configured
warning threshold.
Do you want to continue with this connection?
This warns you that the first available encryption is not a very secure one. Typically you would put the ‘warn below here’ line between the encryptions you consider secure and the ones you consider substandard. By default, PuTTY supplies a preference order intended to reflect a reasonable preference in terms of security and speed.
In SSH-2, the encryption algorithm is negotiated independently for each direction of the connection, although PuTTY does not support separate configuration of the preference orders. As a result you may get two warnings similar to the one above, possibly with different encryptions.
Single-DES is not recommended in the SSH-2 protocol standards, but one or two server implementations do support it. PuTTY can use single-DES to interoperate with these servers if you enable the ‘Enable legacy use of single-DES in SSH-2’ option; by default this is disabled and PuTTY will stick to recommended ciphers.
The Auth panel allows you to configure authentication options for SSH sessions.
SSH-2 servers can provide a message for clients to display to the prospective user before the user logs in; this is sometimes known as a pre-authentication ‘banner’. Typically this is used to provide information about the server and legal notices.
By default, PuTTY displays this message before prompting for a password or similar credentials (although, unfortunately, not before prompting for a login name, due to the nature of the protocol design). By unchecking this option, display of the banner can be suppressed entirely.
In SSH-2, it is in principle possible to establish a connection without using SSH's mechanisms to identify or prove who you are to the server. An SSH server could prefer to handle authentication in the data channel, for instance, or simply require no user authentication whatsoever.
By default, PuTTY assumes the server requires authentication (we've never heard of one that doesn't), and thus must start this process with a username. If you find you are getting username prompts that you cannot answer, you could try enabling this option. However, most SSH servers will reject this.
This is not the option you want if you have a username and just want PuTTY to remember it; for that see section 4.15.1. It's also probably not what if you're trying to set up passwordless login to a mainstream SSH server; depending on the server, you probably wanted public-key authentication (chapter 8) or perhaps GSSAPI authentication (section 4.23). (These are still forms of authentication, even if you don't have to interact with them.)
This option only affects SSH-2 connections. SSH-1 connections always require an authentication step.
This option causes PuTTY to abandon an SSH session and disconnect from the server, if the server accepted authentication without ever having asked for any kind of password or signature or token.
This might be used as a security measure. There are some forms of attack against an SSH client user which work by terminating the SSH authentication stage early, and then doing something in the main part of the SSH session which looks like part of the authentication, but isn't really.
For example, instead of demanding a signature from your public key, for which PuTTY would ask for your key's passphrase, a compromised or malicious server might allow you to log in with no signature or password at all, and then print a message that imitates PuTTY's request for your passphrase, in the hope that you would type it in. (In fact, the passphrase for your public key should not be sent to any server.)
PuTTY's main defence against attacks of this type is the ‘trust sigil’ system: messages in the PuTTY window that are truly originated by PuTTY itself are shown next to a small copy of the PuTTY icon, which the server cannot fake when it tries to imitate the same message using terminal output.
However, if you think you might be at risk of this kind of thing anyway (if you don't watch closely for the trust sigils, or if you think you're at extra risk of one of your servers being malicious), then you could enable this option as an extra defence. Then, if the server tries any of these attacks involving letting you through the authentication stage, PuTTY will disconnect from the server before it can send a follow-up fake prompt or other type of attack.
On the other hand, some servers legitimately let you through the SSH authentication phase trivially, either because they are genuinely public, or because the important authentication step happens during the terminal session. (An example might be an SSH server that connects you directly to the terminal login prompt of a legacy mainframe.) So enabling this option might cause some kinds of session to stop working. It's up to you.
If this option is enabled, then PuTTY will look for Pageant (the SSH private-key storage agent) and attempt to authenticate with any suitable public keys Pageant currently holds.
This behaviour is almost always desirable, and is therefore enabled by default. In rare cases you might need to turn it off in order to force authentication by some non-public-key method such as passwords.
This option can also be controlled using the -noagent
command-line option. See section 3.11.3.9.
See chapter 9 for more information about Pageant in general.
TIS and CryptoCard authentication are (despite their names) generic forms of simple challenge/response authentication available in SSH protocol version 1 only. You might use them if you were using S/Key one-time passwords, for example, or if you had a physical security token that generated responses to authentication challenges. They can even be used to prompt for simple passwords.
With this switch enabled, PuTTY will attempt these forms of authentication if the server is willing to try them. You will be presented with a challenge string (which may be different every time) and must supply the correct response in order to log in. If your server supports this, you should talk to your system administrator about precisely what form these challenges and responses take.
The SSH-2 equivalent of TIS authentication is called ‘keyboard-interactive’. It is a flexible authentication method using an arbitrary sequence of requests and responses; so it is not only useful for challenge/response mechanisms such as S/Key, but it can also be used for (for example) asking the user for a new password when the old one has expired.
PuTTY leaves this option enabled by default, but supplies a switch to turn it off in case you should have trouble with it.
This option allows the SSH server to open forwarded connections back to your local copy of Pageant. If you are not running Pageant, this option will do nothing.
See chapter 9 for general information on Pageant, and section 9.4 for information on agent forwarding. Note that there is a security risk involved with enabling this option; see section 9.6 for details.
In the SSH-1 protocol, it is impossible to change username after failing to authenticate. So if you mis-type your username at the PuTTY ‘login as:’ prompt, you will not be able to change it except by restarting PuTTY.
The SSH-2 protocol does allow changes of username, in principle, but does not make it mandatory for SSH-2 servers to accept them. In particular, OpenSSH does not accept a change of username; once you have sent one username, it will reject attempts to try to authenticate as another user. (Depending on the version of OpenSSH, it may quietly return failure for all login attempts, or it may send an error message.)
For this reason, PuTTY will by default not prompt you for your username more than once, in case the server complains. If you know your server can cope with it, you can enable the ‘Allow attempted changes of username’ option to modify PuTTY's behaviour.
This subpane of the Auth panel contains configuration options that specify actual credentials to present to the server: key files and certificates.
This box is where you enter the name of your private key file if you are using public key authentication. See chapter 8 for information about public key authentication in SSH.
This key must be in PuTTY's native format (*.PPK
). If you have a private key in another format that you want to use with PuTTY, see section 8.2.15.
You can use the authentication agent Pageant so that you do not need to explicitly configure a key here; see chapter 9.
If a private key file is specified here with Pageant running, PuTTY will first try asking Pageant to authenticate with that key, and ignore any other keys Pageant may have. If that fails, PuTTY will ask for a passphrase as normal. You can also specify a public key file in this case (in RFC 4716 or OpenSSH format), as that's sufficient to identify the key to Pageant, but of course if Pageant isn't present PuTTY can't fall back to using this file itself.
(This is optional. If you don't know you need it, you can leave this blank.)
In some environments, user authentication keys can be signed in turn by a ‘certifying authority’ (‘CA’ for short), and user accounts on an SSH server can be configured to automatically trust any key that's certified by the right signature.
This can be a convenient setup if you have a very large number of servers. When you change your key pair, you might otherwise have to edit the authorized_keys
file on every server individually, to make them all accept the new key. But if instead you configure all those servers once to accept keys signed as yours by a CA, then when you change your public key, all you have to do is to get the new key certified by the same CA as before, and then all your servers will automatically accept it without needing individual reconfiguration.
One way to use a certificate is to incorporate it into your private key file. Section 8.2.9 explains how to do that using PuTTYgen. But another approach is to tell PuTTY itself where to find the public certificate file, and then it will automatically present that certificate when authenticating with the corresponding private key.
To do this, enter the pathname of the certificate file into the ‘Certificate to use with the private key’ file selector.
When this setting is configured, PuTTY will honour it no matter whether the private key is found in a file, or loaded into Pageant.
An SSH server can use the ‘keyboard-interactive’ protocol to present a series of arbitrary questions and answers. Sometimes this is used for ordinary passwords, but sometimes the server will use the same mechanism for something more complicated, such as a one-time password system.
Some of these systems can be automated. For this purpose, PuTTY allows you to provide a separate program to act as a ‘plugin’ which will take over the authentication and send answers to the questions on your behalf.
If you have been provided with a plugin of this type, you can configure it here, by entering a full command line in the ‘Plugin command to run’ box.
(If you want to write a plugin of this type, see appendix H for the full specification of how the plugin is expected to behave.)
The ‘GSSAPI’ subpanel of the ‘Auth’ panel controls the use of GSSAPI authentication. This is a mechanism which delegates the authentication exchange to a library elsewhere on the client machine, which in principle can authenticate in many different ways but in practice is usually used with the Kerberos single sign-on protocol to implement passwordless login.
GSSAPI authentication is only available in the SSH-2 protocol.
PuTTY supports two forms of GSSAPI-based authentication. In one of them, the SSH key exchange happens in the normal way, and GSSAPI is only involved in authenticating the user. The checkbox labelled ‘Attempt GSSAPI authentication’ controls this form.
In the other method, GSSAPI-based authentication is combined with the SSH key exchange phase. If this succeeds, then the SSH authentication step has nothing left to do. See section 4.18.1.1 for more information about this method. The checkbox labelled ‘Attempt GSSAPI key exchange’ controls this form. (The same checkbox appears on the ‘Kex’ panel.)
If one or both of these controls is enabled, then GSSAPI authentication will be attempted in one form or the other, and (typically) if your client machine has valid Kerberos credentials loaded, then PuTTY should be able to authenticate automatically to servers that support Kerberos logins.
If both of those checkboxes are disabled, PuTTY will not try any form of GSSAPI at all, and the rest of this panel will be unused.
GSSAPI credential delegation is a mechanism for passing on your Kerberos (or other) identity to the session on the SSH server. If you enable this option, then not only will PuTTY be able to log in automatically to a server that accepts your Kerberos credentials, but also you will be able to connect out from that server to other Kerberos-supporting services and use the same credentials just as automatically.
(This option is the Kerberos analogue of SSH agent forwarding; see section 9.4 for some information on that.)
Note that, like SSH agent forwarding, there is a security implication in the use of this option: the administrator of the server you connect to, or anyone else who has cracked the administrator account on that server, could fake your identity when connecting to further Kerberos-supporting services. However, Kerberos sites are typically run by a central authority, so the administrator of one server is likely to already have access to the other services too; so this would typically be less of a risk than SSH agent forwarding.
If your connection is not using GSSAPI key exchange, it is possible for the delegation to expire during your session. See section 4.18.1.1 for more information.
GSSAPI is a mechanism which allows more than one authentication method to be accessed through the same interface. Therefore, more than one authentication library may exist on your system which can be accessed using GSSAPI.
PuTTY contains native support for a few well-known such libraries (including Windows' SSPI), and will look for all of them on your system and use whichever it finds. If more than one exists on your system and you need to use a specific one, you can adjust the order in which it will search using this preference list control.
One of the options in the preference list is to use a user-specified GSSAPI library. If the library you want to use is not mentioned by name in PuTTY's list of options, you can enter its full pathname in the ‘User-supplied GSSAPI library path’ field, and move the ‘User-supplied GSSAPI library’ option in the preference list to make sure it is selected before anything else.
On Windows, such libraries are files with a .dll
extension, and must have been built in the same way as the PuTTY executable you're running; if you have a 32-bit DLL, you must run a 32-bit version of PuTTY, and the same with 64-bit (see question A.6.10). On Unix, shared libraries generally have a .so
extension.
The TTY panel lets you configure the remote pseudo-terminal.
When connecting to a Unix system, most interactive shell sessions are run in a pseudo-terminal, which allows the Unix system to pretend it's talking to a real physical terminal device but allows the SSH server to catch all the data coming from that fake device and send it back to the client.
Occasionally you might find you have a need to run a session not in a pseudo-terminal. In PuTTY, this is generally only useful for very specialist purposes; although in Plink (see chapter 7) it is the usual way of working.
The SSH protocol allows the client to send ‘terminal modes’ for the remote pseudo-terminal. These usually control the server's expectation of the local terminal's behaviour.
If your server does not have sensible defaults for these modes, you may find that changing them here helps, although the server is at liberty to ignore your changes. If you don't understand any of this, it's safe to leave these settings alone.
(None of these settings will have any effect if no pseudo-terminal is requested or allocated.)
You can change what happens for a particular mode by selecting it in the list, choosing one of the options and specifying the exact value if necessary, and hitting ‘Set’. The effect of the options is as follows:
PuTTY proper will send modes that it has an opinion on (currently only the code for the Backspace key, ERASE
, and whether the character set is UTF-8, IUTF8
). Plink on Unix will propagate appropriate modes from the local terminal, if any.
By default, all of the available modes are listed as ‘Auto’, which should do the right thing in most circumstances.
The precise effect of each setting, if any, is up to the server. Their names come from POSIX and other Unix systems, and they are most likely to have a useful effect on such systems. (These are the same settings that can usually be changed using the stty
command once logged in to such servers.)
Some notable modes are described below; for fuller explanations, see your server documentation.
ERASE
is the character that when typed by the user will delete one space to the left. When set to ‘Auto’ (the default setting), this follows the setting of the local Backspace key in PuTTY (see section 4.4.1).
This and other special characters are specified using ^C
notation for Ctrl-C, and so on. Use ^<27>
or ^<0x1B>
to specify a character numerically, and ^~
to get a literal ^
. Other non-control characters are denoted by themselves. Leaving the box entirely blank indicates that no character should be assigned to the specified function, although this may not be supported by all servers.
QUIT
is a special character that usually forcefully ends the current process on the server (SIGQUIT
). On many servers its default setting is Ctrl-backslash (^\
), which is easy to accidentally invoke on many keyboards. If this is getting in your way, you may want to change it to another character or turn it off entirely.
ECHO
and ICANON
can be specified in PuTTY in a variety of ways, such as true
/false
, yes
/no
, and 0
/1
. (Explicitly specifying a value of no
is different from not sending the mode at all.)
IUTF8
signals to the server whether the terminal character set is UTF-8 or not, for purposes such as basic line editing; if this is set incorrectly, the backspace key may erase the wrong amount of text, for instance. However, simply setting this is not usually sufficient for the server to use UTF-8; POSIX servers will generally also require the locale to be set (by some server-dependent means), although many newer installations default to UTF-8. Also, since this mode was added to the SSH protocol much later than the others, many servers (particularly older servers) do not honour this mode sent over SSH; indeed, a few poorly-written servers object to its mere presence, so you may find you need to set it to not be sent at all. When set to ‘Auto’, this follows the local configured character set (see section 4.10.1).
The X11 panel allows you to configure forwarding of X11 over an SSH connection.
If your server lets you run X Window System graphical applications, X11 forwarding allows you to securely give those applications access to a local X display on your PC.
To enable X11 forwarding, check the ‘Enable X11 forwarding’ box. If your X display is somewhere unusual, you will need to enter its location in the ‘X display location’ box; if this is left blank, PuTTY will try to find a sensible default in the environment, or use the primary local display (:0
) if that fails.
See section 3.4 for more information about X11 forwarding.
If you are using X11 forwarding, the virtual X server created on the SSH server machine will be protected by authorisation data. This data is invented, and checked, by PuTTY.
The usual authorisation method used for this is called MIT-MAGIC-COOKIE-1
. This is a simple password-style protocol: the X client sends some cookie data to the server, and the server checks that it matches the real cookie. The cookie data is sent over an unencrypted X11 connection; so if you allow a client on a third machine to access the virtual X server, then the cookie will be sent in the clear.
PuTTY offers the alternative protocol XDM-AUTHORIZATION-1
. This is a cryptographically authenticated protocol: the data sent by the X client is different every time, and it depends on the IP address and port of the client's end of the connection and is also stamped with the current time. So an eavesdropper who captures an XDM-AUTHORIZATION-1
string cannot immediately re-use it for their own X connection.
PuTTY's support for XDM-AUTHORIZATION-1
is a somewhat experimental feature, and may encounter several problems:
XDM-AUTHORIZATION-1
, so they will not know what to do with the data PuTTY has provided.
XDM-AUTHORIZATION-1
data.
XDM-AUTHORIZATION-1
data after a session, so that if you then connect to the same server using a client which only does MIT-MAGIC-COOKIE-1
and are allocated the same remote display number, you might find that out-of-date authentication data is still present on your server and your X connections fail.
PuTTY's default is MIT-MAGIC-COOKIE-1
. If you change it, you should be sure you know what you're doing.
If you are using X11 forwarding, the local X server to which your forwarded connections are eventually directed may itself require authorisation.
Some Windows X servers do not require this: they do authorisation by simpler means, such as accepting any connection from the local machine but not from anywhere else. However, if your X server does require authorisation, then PuTTY needs to know what authorisation is required.
One way in which this data might be made available is for the X server to store it somewhere in a file which has the same format as the Unix .Xauthority
file. If this is how your Windows X server works, then you can tell PuTTY where to find this file by configuring this option. By default, PuTTY will not attempt to find any authorisation for your local display.
The Tunnels panel allows you to configure tunnelling of arbitrary connection types through an SSH connection.
Port forwarding allows you to tunnel other types of network connection down an SSH session. See section 3.5 for a general discussion of port forwarding and how it works.
The port forwarding section in the Tunnels panel shows a list of all the port forwardings that PuTTY will try to set up when it connects to the server. By default no port forwardings are set up, so this list is empty.
To add a port forwarding:
popserver.example.com:110
. (If you need to enter a literal IPv6 address, enclose it in square brackets, for instance ‘[::1]:2200
’.)
To remove a port forwarding, simply select its details in the list box, and click the ‘Remove’ button.
In the ‘Source port’ box, you can also optionally enter an IP address to listen on, by specifying (for instance) 127.0.0.5:79
. See section 3.5 for more information on how this works and its restrictions.
In place of port numbers, you can enter service names, if they are known to the local system. For instance, in the ‘Destination’ box, you could enter popserver.example.com:pop3
.
You can modify the currently active set of port forwardings in mid-session using ‘Change Settings’ (see section 3.1.3.4). If you delete a local or dynamic port forwarding in mid-session, PuTTY will stop listening for connections on that port, so it can be re-used by another program. If you delete a remote port forwarding, note that:
If you ask to delete a remote port forwarding and PuTTY cannot make the server actually stop listening on the port, it will instead just start refusing incoming connections on that port. Therefore, although the port cannot be reused by another program, you can at least be reasonably sure that server-side programs can no longer access the service at your end of the port forwarding.
If you delete a forwarding, any existing connections established using that forwarding remain open. Similarly, changes to global settings such as ‘Local ports accept connections from other hosts’ only take effect on new forwardings.
If the connection you are forwarding over SSH is itself a second SSH connection made by another copy of PuTTY, you might find the ‘logical host name’ configuration option useful to warn PuTTY of which host key it should be expecting. See section 4.14.5 for details of this.
The source port for a forwarded connection usually does not accept connections from any machine except the SSH client or server machine itself (for local and remote forwardings respectively). There are controls in the Tunnels panel to change this:
This switch allows you to select a specific Internet protocol (IPv4 or IPv6) for the local end of a forwarded port. By default, it is set on ‘Auto’, which means that:
This overrides the general Internet protocol version preference on the Connection panel (see section 4.14.4).
Note that some operating systems may listen for incoming connections in IPv4 even if you specifically asked for IPv6, because their IPv4 and IPv6 protocol stacks are linked together. Apparently Linux does this, and Windows does not. So if you're running PuTTY on Windows and you tick ‘IPv6’ for a local or dynamic port forwarding, it will only be usable by connecting to it using IPv6; whereas if you do the same on Linux, you can also use it with IPv4. However, ticking ‘Auto’ should always give you a port which you can connect to using either protocol.
Not all SSH servers work properly. Various existing servers have bugs in them, which can make it impossible for a client to talk to them unless it knows about the bug and works around it.
Since most servers announce their software version number at the beginning of the SSH connection, PuTTY will attempt to detect which bugs it can expect to see in the server and automatically enable workarounds. However, sometimes it will make mistakes; if the server has been deliberately configured to conceal its version number, or if the server is a version which PuTTY's bug database does not know about, then PuTTY will not know what bugs to expect.
The Bugs and More Bugs panels (there are two because we have so many bug compatibility modes) allow you to manually configure the bugs PuTTY expects to see in the server. Each bug can be configured in three states:
(The PuTTY project has a defined policy about when we're prepared to add auto-detection for a bug workaround. See section B.6.)
An ignore message (SSH_MSG_IGNORE) is a message in the SSH protocol which can be sent from the client to the server, or from the server to the client, at any time. Either side is required to ignore the message whenever it receives it. PuTTY uses ignore messages in SSH-2 to confuse the encrypted data stream and make it harder to cryptanalyse. It also uses ignore messages for connection keepalives (see section 4.14.1).
If it believes the server to have this bug, PuTTY will stop using ignore messages. If this bug is enabled when talking to a correct server, the session will succeed, but keepalives will not work and the session might be less cryptographically secure than it could be.
Some SSH servers cannot cope with repeat key exchange at all, and will ignore attempts by the client to start one. Since PuTTY pauses the session while performing a repeat key exchange, the effect of this would be to cause the session to hang after an hour (unless you have your rekey timeout set differently; see section 4.18.2 for more about rekeys). Other, very old, SSH servers handle repeat key exchange even more badly, and disconnect upon receiving a repeat key exchange request.
If this bug is detected, PuTTY will never initiate a repeat key exchange. If this bug is enabled when talking to a correct server, the session should still function, but may be less secure than you would expect.
This is an SSH-2-specific bug.
winadj
’ requests’
PuTTY sometimes sends a special request to SSH servers in the middle of channel data, with the name winadj@putty.projects.tartarus.org
(see section G.1). The purpose of this request is to measure the round-trip time to the server, which PuTTY uses to tune its flow control. The server does not actually have to understand the message; it is expected to send back a SSH_MSG_CHANNEL_FAILURE
message indicating that it didn't understand it. (All PuTTY needs for its timing calculations is some kind of response.)
It has been known for some SSH servers to get confused by this message in one way or another – because it has a long name, or because they can't cope with unrecognised request names even to the extent of sending back the correct failure response, or because they handle it sensibly but fill up the server's log file with pointless spam, or whatever. PuTTY therefore supports this bug-compatibility flag: if it believes the server has this bug, it will never send its ‘winadj@putty.projects.tartarus.org
’ request, and will make do without its timing data.
The SSH protocol as published in RFC 4254 has an ambiguity which arises if one side of a connection tries to close a channel, while the other side simultaneously sends a request within the channel and asks for a reply. RFC 4254 leaves it unclear whether the closing side should reply to the channel request after having announced its intention to close the channel.
Discussion on the ietf-ssh
mailing list in April 2014 formed a clear consensus that the right answer is no. However, because of the ambiguity in the specification, some SSH servers have implemented the other policy; for example, OpenSSH used to until it was fixed.
Because PuTTY sends channel requests with the ‘want reply’ flag throughout channels' lifetime (see section 4.27.3), it's possible that when connecting to such a server it might receive a reply to a request after it thinks the channel has entirely closed, and terminate with an error along the lines of ‘Received SSH2_MSG_CHANNEL_FAILURE
for nonexistent channel 256’.
When an SSH-2 channel is set up, each end announces the maximum size of data packet that it is willing to receive for that channel. Some servers ignore PuTTY's announcement and send packets larger than PuTTY is willing to accept, causing it to report ‘Incoming packet was garbled on decryption’.
If this bug is detected, PuTTY never allows the channel's flow-control window to grow large enough to allow the server to send an over-sized packet. If this bug is enabled when talking to a correct server, the session will work correctly, but download performance will be less than it could be.
Just occasionally, an SSH connection can be established over some channel that will accidentally discard outgoing data very early in the connection.
This is not typically seen as a bug in an actual SSH server, but it can sometimes occur in situations involving a complicated proxy process. An example is Debian bug #991958, in which a connection going over the console of a User Mode Linux kernel can lose outgoing data before the kernel has fully booted.
You can work around this problem by manually enabling this bug flag, which will cause PuTTY to wait to send its initial SSH greeting until after it sees the greeting from the server.
Note that this bug flag can never be automatically detected, since auto-detection relies on the version string in the server's greeting, and PuTTY has to decide whether to expect this bug before it sees the server's greeting. So this is a manual workaround only.
KEXINIT
’
At the start of an SSH connection, the client and server exchange long messages of type SSH_MSG_KEXINIT
, containing lists of all the cryptographic algorithms they're prepared to use. This is used to negotiate a set of algorithms that both ends can speak.
Occasionally, a badly written server might have a length limit on the list it's prepared to receive, and refuse to make a connection simply because PuTTY is giving it too many choices.
A workaround is to enable this flag, which will make PuTTY wait to send KEXINIT
until after it receives the one from the server, and then filter its own KEXINIT
to leave out any algorithm the server doesn't also announce support for. This will generally make PuTTY's KEXINIT
at most the size of the server's, and will otherwise make no difference to the algorithm negotiation.
This flag is a minor violation of the SSH protocol, because both sides are supposed to send KEXINIT
proactively. It still works provided one side sends its KEXINIT
without waiting, but if both client and server waited for the other one to speak first, the connection would deadlock. We don't know of any servers that do this, but if there is one, then this flag will make PuTTY unable to speak to them at all.
If PuTTY is trying to do SSH-2 user authentication using an RSA key, and the server is using one of the newer SHA-2 based versions of the SSH RSA protocol, and the user's key is also a certificate, then earlier versions of OpenSSH (up to 7.7) disagree with later versions about the right key algorithm string to send in the SSH2_MSG_USERAUTH_REQUEST
packet. Modern versions send a string that indicates both the SHA-2 nature and the certificate nature of the key, such as ‘rsa-sha2-512-cert-v01@openssh.com
’. Earlier versions would reject that, and insist on seeing ‘ssh-rsa-cert-v01@openssh.com
’ followed by a SHA-2 based signature.
PuTTY should auto-detect the presence of this bug in earlier OpenSSH and adjust to send the right string.
Versions below 3.3 of OpenSSH require SSH-2 RSA signatures to be padded with zero bytes to the same length as the RSA key modulus. The SSH-2 specification says that an unpadded signature MUST be accepted, so this is a bug. A typical symptom of this problem is that PuTTY mysteriously fails RSA authentication once in every few hundred attempts, and falls back to passwords.
If this bug is detected, PuTTY will pad its signatures in the way OpenSSH expects. If this bug is enabled when talking to a correct server, it is likely that no damage will be done, since correct servers usually still accept padded signatures because they're used to talking to OpenSSH.
This is an SSH-2-specific bug.
The SSH key exchange method that uses Diffie-Hellman group exchange was redesigned after its original release, to use a slightly more sophisticated setup message. Almost all SSH implementations switched over to the new version. (PuTTY was one of the last.) A few old servers still only support the old one.
If this bug is detected, and the client and server negotiate Diffie-Hellman group exchange, then PuTTY will send the old message now known as SSH2_MSG_KEX_DH_GEX_REQUEST_OLD
in place of the new SSH2_MSG_KEX_DH_GEX_REQUEST
.
This is an SSH-2-specific bug.
Versions 2.3.0 and below of the SSH server software from ssh.com
compute the keys for their HMAC message authentication codes incorrectly. A typical symptom of this problem is that PuTTY dies unexpectedly at the beginning of the session, saying ‘Incorrect MAC received on packet’.
If this bug is detected, PuTTY will compute its HMAC keys in the same way as the buggy server, so that communication will still be possible. If this bug is enabled when talking to a correct server, communication will fail.
This is an SSH-2-specific bug.
Versions below 2.3 of OpenSSH require SSH-2 public-key authentication to be done slightly differently: the data to be signed by the client contains the session ID formatted in a different way. If public-key authentication mysteriously does not work but the Event Log (see section 3.1.3.1) thinks it has successfully sent a signature, it might be worth enabling the workaround for this bug to see if it helps.
If this bug is detected, PuTTY will sign data in the way OpenSSH expects. If this bug is enabled when talking to a correct server, SSH-2 public-key authentication will fail.
This is an SSH-2-specific bug.
Versions below 2.0.11 of the SSH server software from ssh.com
compute the keys for the session encryption incorrectly. This problem can cause various error messages, such as ‘Incoming packet was garbled on decryption’, or possibly even ‘Out of memory’.
If this bug is detected, PuTTY will compute its encryption keys in the same way as the buggy server, so that communication will still be possible. If this bug is enabled when talking to a correct server, communication will fail.
This is an SSH-2-specific bug.
An ignore message (SSH_MSG_IGNORE) is a message in the SSH protocol which can be sent from the client to the server, or from the server to the client, at any time. Either side is required to ignore the message whenever it receives it. PuTTY uses ignore messages to hide the password packet in SSH-1, so that a listener cannot tell the length of the user's password; it also uses ignore messages for connection keepalives (see section 4.14.1).
If this bug is detected, PuTTY will stop using ignore messages. This means that keepalives will stop working, and PuTTY will have to fall back to a secondary defence against SSH-1 password-length eavesdropping. See section 4.27.15. If this bug is enabled when talking to a correct server, the session will succeed, but keepalives will not work and the session might be more vulnerable to eavesdroppers than it could be.
When talking to an SSH-1 server which cannot deal with ignore messages (see section 4.27.14), PuTTY will attempt to disguise the length of the user's password by sending additional padding within the password packet. This is technically a violation of the SSH-1 specification, and so PuTTY will only do it when it cannot use standards-compliant ignore messages as camouflage. In this sense, for a server to refuse to accept a padded password packet is not really a bug, but it does make life inconvenient if the server can also not handle ignore messages.
If this ‘bug’ is detected, PuTTY will assume that neither ignore messages nor padding are acceptable, and that it thus has no choice but to send the user's password with no form of camouflage, so that an eavesdropping user will be easily able to find out the exact length of the password. If this bug is enabled when talking to a correct server, the session will succeed, but will be more vulnerable to eavesdroppers than it could be.
This is an SSH-1-specific bug. SSH-2 is secure against this type of attack.
Some SSH-1 servers cannot deal with RSA authentication messages at all. If Pageant is running and contains any SSH-1 keys, PuTTY will normally automatically try RSA authentication before falling back to passwords, so these servers will crash when they see the RSA attempt.
If this bug is detected, PuTTY will go straight to password authentication. If this bug is enabled when talking to a correct server, the session will succeed, but of course RSA authentication will be impossible.
This is an SSH-1-specific bug.
ssh-connection
’ protocol
In addition to SSH itself, PuTTY also supports a second protocol that is derived from SSH. It's listed in the PuTTY GUI under the name ‘Bare ssh-connection
’.
This protocol consists of just the innermost of SSH-2's three layers: it leaves out the cryptography layer providing network security, and it leaves out the authentication layer where you provide a username and prove you're allowed to log in as that user.
It is therefore completely unsuited to any network connection. Don't try to use it over a network!
The purpose of this protocol is for various specialist circumstances in which the ‘connection’ is not over a real network, but is a pipe or IPC channel between different processes running on the same computer. In these contexts, the operating system will already have guaranteed that each of the two communicating processes is owned by the expected user (so that no authentication is necessary), and that the communications channel cannot be tapped by a hostile user on the same machine (so that no cryptography is necessary either). Examples of possible uses involve communicating with a strongly separated context such as the inside of a container, or a VM, or a different network namespace.
Explicit support for this protocol is new in PuTTY 0.75. As of 2021-04, the only known server for the bare ssh-connection
protocol is the Unix program ‘psusan
’ that is also part of the PuTTY tool suite.
(However, this protocol is also the same one used between instances of PuTTY to implement connection sharing: see section 4.17.5. In fact, in the Unix version of PuTTY, when a sharing upstream records ‘Sharing this connection at [pathname]’ in the Event Log, it's possible to connect another instance of PuTTY directly to that Unix socket, by entering its pathname in the host name box and selecting ‘Bare ssh-connection
’ as the protocol!)
Many of the options under the SSH panel also affect this protocol, although options to do with cryptography and authentication do not, for obvious reasons.
I repeat, DON'T TRY TO USE THIS PROTOCOL FOR NETWORK CONNECTIONS! That's not what it's for, and it's not at all safe to do it.
The Serial panel allows you to configure options that only apply when PuTTY is connecting to a local serial line.
The ‘Serial line to connect to’ box allows you to choose which serial line you want PuTTY to talk to, if your computer has more than one serial port.
On Windows, the first serial line is called COM1
, and if there is a second it is called COM2
, and so on.
This configuration setting is also visible on the Session panel, where it replaces the ‘Host Name’ box (see section 4.1.1) if the connection type is set to ‘Serial’.
The ‘Speed’ box allows you to choose the speed (or ‘baud rate’) at which to talk to the serial line. Typical values might be 9600, 19200, 38400 or 57600. Which one you need will depend on the device at the other end of the serial cable; consult the manual for that device if you are in doubt.
This configuration setting is also visible on the Session panel, where it replaces the ‘Port’ box (see section 4.1.1) if the connection type is set to ‘Serial’.
The ‘Data bits’ box allows you to choose how many data bits are transmitted in each byte sent or received through the serial line. Typical values are 7 or 8.
The ‘Stop bits’ box allows you to choose how many stop bits are used in the serial line protocol. Typical values are 1, 1.5 or 2.
The ‘Parity’ box allows you to choose what type of parity checking is used on the serial line. The settings are:
The ‘Flow control’ box allows you to choose what type of flow control checking is used on the serial line. The settings are:
The Telnet panel allows you to configure options that only apply to Telnet sessions.
The original Telnet mechanism for passing environment variables was badly specified. At the time the standard (RFC 1408) was written, BSD telnet implementations were already supporting the feature, and the intention of the standard was to describe the behaviour the BSD implementations were already using.
Sadly there was a typing error in the standard when it was issued, and two vital function codes were specified the wrong way round. BSD implementations did not change, and the standard was not corrected. Therefore, it's possible you might find either BSD or RFC-compliant implementations out there. This switch allows you to choose which one PuTTY claims to be.
The problem was solved by issuing a second standard, defining a new Telnet mechanism called NEW_ENVIRON
, which behaved exactly like the original OLD_ENVIRON
but was not encumbered by existing implementations. Most Telnet servers now support this, and it's unambiguous. This feature should only be needed if you have trouble passing environment variables to quite an old server.
In a Telnet connection, there are two types of data passed between the client and the server: actual text, and negotiations about which Telnet extra features to use.
PuTTY can use two different strategies for negotiation:
The obvious disadvantage of passive mode is that if the server is also operating in a passive mode, then negotiation will never begin at all. For this reason PuTTY defaults to active mode.
However, sometimes passive mode is required in order to successfully get through certain types of firewall and Telnet proxy server. If you have confusing trouble with a firewall, you could try enabling passive mode to see if it helps.
If this box is checked, several key sequences will have their normal actions modified:
You probably shouldn't enable this unless you know what you're doing.
Unlike most other remote login protocols, the Telnet protocol has a special ‘new line’ code that is not the same as the usual line endings of Control-M or Control-J. By default, PuTTY sends the Telnet New Line code when you press Return, instead of sending Control-M as it does in most other protocols.
Most Unix-style Telnet servers don't mind whether they receive Telnet New Line or Control-M; some servers do expect New Line, and some servers prefer to see ^M. If you are seeing surprising behaviour when you press Return in a Telnet session, you might try turning this option off to see if it helps.
The Rlogin panel allows you to configure options that only apply to Rlogin sessions.
Rlogin allows an automated (password-free) form of login by means of a file called .rhosts
on the server. You put a line in your .rhosts
file saying something like jbloggs@pc1.example.com
, and then when you make an Rlogin connection the client transmits the username of the user running the Rlogin client. The server checks the username and hostname against .rhosts
, and if they match it does not ask for a password.
This only works because Unix systems contain a safeguard to stop a user from pretending to be another user in an Rlogin connection. Rlogin connections have to come from port numbers below 1024, and Unix systems prohibit this to unprivileged processes; so when the server sees a connection from a low-numbered port, it assumes the client end of the connection is held by a privileged (and therefore trusted) process, so it believes the claim of who the user is.
Windows does not have this restriction: any user can initiate an outgoing connection from a low-numbered port. Hence, the Rlogin .rhosts
mechanism is completely useless for securely distinguishing several different users on a Windows machine. If you have a .rhosts
entry pointing at a Windows PC, you should assume that anyone using that PC can spoof your username in an Rlogin connection and access your account on the server.
The ‘Local username’ control allows you to specify what user name PuTTY should claim you have, in case it doesn't match your Windows user name (or in case you didn't bother to set up a Windows user name).
The SUPDUP panel allows you to configure options that only apply to SUPDUP sessions. See section 3.10 for more about the SUPDUP protocol.
In SUPDUP, the client sends a piece of text of its choice to the server giving the user's location. This is typically displayed in lists of logged-in users.
By default, PuTTY just defaults this to "The Internet". If you want your location to show up as something more specific, you can configure it here.
This declares what kind of character set extension your terminal supports. If the server supports it, it will send text using that character set. ‘None’ means the standard 95 printable ASCII characters. ‘ITS’ means ASCII extended with printable characters in the control character range. This character set is documented in the SUPDUP protocol definition. ‘WAITS’ is similar to ‘ITS’ but uses some alternative characters in the extended set: most prominently, it will display arrows instead of ^
and _
, and }
instead of ~
. ‘ITS’ extended ASCII is used by ITS and Lisp machines, whilst ‘WAITS’ is only used by the WAITS operating system from the Stanford AI Laboratory.
When **MORE** processing is enabled, the server causes output to pause at the bottom of the screen, until a space is typed.
This controls whether the terminal will perform scrolling when the cursor goes below the last line, or if the cursor will return to the first line.
PuTTY does not currently support storing its configuration in a file instead of the Registry. However, you can work around this with a couple of batch files.
You will need a file called (say) PUTTY.BAT
which imports the contents of a file into the Registry, then runs PuTTY, exports the contents of the Registry back into the file, and deletes the Registry entries. This can all be done using the Regedit command line options, so it's all automatic. Here is what you need in PUTTY.BAT
:
@ECHO OFF
regedit /s putty.reg
regedit /s puttyrnd.reg
start /w putty.exe
regedit /ea new.reg HKEY_CURRENT_USER\Software\SimonTatham\PuTTY
copy new.reg putty.reg
del new.reg
regedit /s puttydel.reg
This batch file needs two auxiliary files: PUTTYRND.REG
which sets up an initial safe location for the PUTTY.RND
random seed file, and PUTTYDEL.REG
which destroys everything in the Registry once it's been successfully saved back to the file.
Here is PUTTYDEL.REG
:
REGEDIT4
[-HKEY_CURRENT_USER\Software\SimonTatham\PuTTY]
Here is an example PUTTYRND.REG
file:
REGEDIT4
[HKEY_CURRENT_USER\Software\SimonTatham\PuTTY]
"RandSeedFile"="a:\\putty.rnd"
You should replace a:\putty.rnd
with the location where you want to store your random number data. If the aim is to carry around PuTTY and its settings on one USB stick, you probably want to store it on the USB stick.
If you want to provide feedback on this manual or on the PuTTY tools themselves, see the Feedback page.
[PuTTY pre-release 0.83:2024-12-26.98200d1]