Now the Remove button is disabled if there aren't any keys at all
loaded, and the Re-encrypt button is disabled if no key is currently
in a state where it's decrypted but re-encryptable.
Not quite sure how that happened! But at some point in the past, a bunch
of other definitions in winpgnt.c managed to get in between the first
few IDM_FOO constants and the last few. Bring them all back together.
I'm tired of remembering all those fiddly magic numbers and copying
them back and forth between the .rc file and the source code. I'm even
more tired of having to remember that in the long string of numbers
after a dialog item definition, the first one of them _isn't_ one of
the position and size coordinates. I've given them all symbolic names,
like they should have had all along.
I think I originally didn't bother because this was such a small GUI
compared to the much larger one in PuTTY proper. But it's growing!
This causes the main key list window to open when Pageant starts up,
instead of waiting until you select 'View Keys' from the systray menu.
My main motivation for adding this option is for development: if I'm
_working_ on some detail of the key list window, it cuts down
keystrokes in my edit-compile-retry cycle if I can have it
automatically pop up in every new test run of Pageant.
Normally I'd solve that by hacking an extra couple of lines
temporarily into the code while I was doing that piece of development.
But it suddenly struck me that there's no reason _not_ to add an
option like this permanently (the space of word-length command-line
flags is huge, and that particular one is unlikely to be needed for a
different meaning), and who knows, it _might_ come in useful to
someone in normal use. And at the very least it'll save me doing
another temporary hack the next time I'm doing development work on the
Pageant GUI. So I'll leave it in.
On a system with 2 or more displays with different DPI settings,
moving the PuTTY window from one display to another will make Windows
resize the window using its "bitmap" strategy, stretching/compressing
the text, making it fuzzy and harder to read. This change makes PuTTY
resize its window and font size to accurately fit the DPI of the
display it is on.
We process the WM_DPICHANGED message, saving the new DPI, window size
and position. We proceed to then reset the window, recreating the
fonts using the new DPI and calculate the new window size and position
based on the new font size, user display options (ie. with/without
scrollbar) and the suggested window position provided by Windows. The
suggested window size is usually not a perfect fit, therefore we must
add a small offset to the new window position in order to avoid issues
with repeated DPI changes while dragging the window from one display
to another.
The GUI loop that responded to the 'Remove Key' button in the key list
worked by actually trying to retrieve a pointer to the ssh_key for a
stored key, and then passing that back to the delete function. But
when a key is encrypted, that pointer is NULL, so we segfaulted.
Fixed by changing pageant_delete_ssh2_key() to take a numeric index in
the list instead of a key pointer.
This makes Windows Pageant's slightly ad-hoc command-line handling a
bit more like a standard option loop: we start by deciding whether we
think any given argument _is_ an option or not, and if we think it is,
we give an error message if it's one we don't recognise.
Now Windows Pageant has two clearly distinct dialog boxes for
requesting a key passphrase: one to use synchronously when the user
has just used the 'Add Key' GUI action, and one to use asynchronously
in response to an agent client's attempt to use a key that was loaded
encrypted.
Also fixed the wording in the asynchronous box: there were two copies
of the 'enter passphrase' instruction, one from the dialog definition
in pageant.rc file and one from the cross-platform pageant.c. Now
pageant.c doesn't format a whole user-facing message any more: it
leaves that to the platform front end to do it the way it wants.
I've also added a call to SetForegroundWindow, to try to get the
passphrase prompt into the foreground. In my experience this doesn't
actually get it the keyboard focus, which I think is deliberate on
Windows's part and there's nothing I can do about it. But at least the
user should _see_ that the prompt is there, so they can focus it
themself.
Now they have '(encrypted)' or '(re-encryptable)' after them, the same
as Unix Pageant.
Mostly this just involved tinkering with the code in winpgnt.c that
makes up the entry to put in the list box. But I also had to sprinkle
a few more calls to keylist_update() into the cross-platform
pageant.c, to make sure that the key list window is proactively
updated whenever a key is decrypted, re-encrypted, or loaded in
encrypted-only form.
The advantage of this API is that it gives us the extra flags saying
whether each key is encrypted or re-encryptable.
NFC: we don't yet do anything with that information, just make it
available for future work.
Now you can press 'i' at the host key prompt, and it will print all
the key fingerprints we know about, plus the full public key. So if
you wanted to check against a fingerprint type that wasn't the one
shown in the default prompt, you can see all the ones we've got.
Now we pass the whole set of fingerprints, and also a displayable
format for the full host public key.
NFC: this commit doesn't modify any of the host key prompts to _use_
any of the new information. That's coming next.
There's now a drop-down list box below the key list, from which you
can select a fingerprint type. Also, like GUI PuTTYgen, I've widened
the key list window to make room for wider SHA256 fingerprints.
The fingerprint type shown in the PuTTYgen main dialog can now be
selected from the Key menu. Also, I've widened the dialog box, because
SHA256 fingerprints are wider than MD5 ones.
(In a fixed-pitch font, the fingerprint itself is slightly shorter -
43 base64 characters in place of 47 characters of colon-separated hex.
But the "SHA256:" prefix lengthens it, and also, in a non-fixed-pitch
font such as the default one in Windows dialogs, the colons are very
narrow, so the MD5 fingerprint has a far smaller pixel width.)
There's a new enumeration of fingerprint types, and you tell
ssh2_fingerprint() or ssh2_fingerprint_blob() which of them to use.
So far, this is only implemented behind the scenes, and exposed for
testcrypt to test. All the call sites of ssh2_fingerprint pass a fixed
default fptype, which is still set to the old MD5. That will change
shortly.
The assorted host-key and warning prompt messages have no reason to
differ between the two platforms, so let's centralise them. Also,
while I'm here, some basic support functions that are the same in both
modules.
I've replaced the old versions using the standard MessageBox with new
versions using custom-drawn dialog templates and dialog procedures.
The visible changes are that the acceptance buttons have custom text
describing the actions they'll take, like the GTK versions, instead of
having to stick with bog-standard "Yes" and "No" and hope the user
reads the explanation in the main box text.
Also, this gives me the opportunity to spiff up the looks a bit, by
making the "POTENTIAL SECURITY BREACH" in the wrong-host-key dialog
larger and boldface.
But those are minor cosmetic side effects of my real purpose, which is
to make it possible to add further controls to these boxes in future.
The About text is in a readonly edit control rather than a static
control, so that it can be copy-pasted. Previously, I haven't managed
to avoid the side effect of the edit control being surrounded by a
border - but now I've finally found out how you can do it: clear all
the border styles and _then_ use SetWindowPos to force a redraw of the
frame.
I left this out of yesterday's collection of cmdgen CLI options and
GUI PuTTYgen dialog box, but only because I forgot about it. I don't
know off the top of my head why someone would particularly want to
configure this detail, but given that it _is_ configurable, it seems
like no extra trouble to expose it along with the rest of the
parameters, just in case.
The GUI key generator doesn't need a --reencrypt option, because you
can already just click Load and then Save without changing anything in
between. But it does need a dialog box with all the fiddly Argon2
settings in it, plus a setting to go back to PPK v2.
This removes both uses of SHA-1 in the file format: it was used as the
MAC protecting the key file against tamperproofing, and also used in
the key derivation step that converted the user's passphrase to cipher
and MAC keys.
The MAC is simply upgraded from HMAC-SHA-1 to HMAC-SHA-256; it is
otherwise unchanged in how it's applied (in particular, to what data).
The key derivation is totally reworked, to be based on Argon2, which
I've just added to the code base. This should make stolen encrypted
key files more resistant to brute-force attack.
Argon2 has assorted configurable parameters for memory and CPU usage;
the new key format includes all those parameters. So there's no reason
we can't have them under user control, if a user wants to be
particularly vigorous or particularly lightweight with their own key
files. They could even switch to one of the other flavours of Argon2,
if they thought side channels were an especially large or small risk
in their particular environment. In this commit I haven't added any UI
for controlling that kind of thing, but the PPK loading function is
all set up to cope, so that can all be added in a future commit
without having to change the file format.
While I'm at it, I've also switched the CBC encryption to using a
random IV (or rather, one derived from the passphrase along with the
cipher and MAC keys). That's more like normal SSH-2 practice.
This one is triggered by the following sequence:
- fill up the terminal window with text ('ls -l /dev' or similar)
- Win+Right then Win+Up to snap to the top right quadrant
- interactively drag away from the top right quadrant with the title
bar, which returns the window to its pre-snap size.
After the snap, the window border will have been recomputed to take
account of the window size not being an integer number of character
cells. So it needs recomputing back again the next time the window
size changes to something that _is_ an integer number - which happens
(or rather, we process it in a deferred manner) at the EXITSIZEMOVE.
So that's where we need to recompute the border (again).
If you open a Windows PuTTY session and press Win+Right, Windows
auto-sizes the terminal window to cover the right-hand half of the
screen. Then if you press Win+Up it will be auto-sized again, this
time to the top right quadrant. In the second resize (if you don't
have font-based resize handling turned on), the WM_SIZE handler code
will find a path through the twisty maze of ifs on which the border
between the text and the client-area edges is not recomputed, or
invalidated, or redrawn. So you can end up with half a line of text
from the previous window size still visible at the bottom of the new
window.
Fixed by factoring out the offset-recomputation code from the large
and complicated reset_window(), so that I can call just that snippet
on the dangerous code path.
There were three separate clauses in the WM_SIZE message handler which
potentially called term_size() to resize the actual Terminal object.
Two of them (for maximisation and normal non-maximised resizing drags)
first checked if an interactive resize was in progress, and if so,
instead set the need_backend_resize, to defer the term_size call to
the end of the interactive operation. But the third, for
_un_-maximising a window, didn't have that check.
As a result, if you start with a maximised window, drag its title bar
downward from the top of the screen (which unmaximises it), and
without letting go, drag it back up again (which maximises it), the
effect would be that you'd get one call to term_size in the middle of
the drag, and a second at the end. This isn't what I intended, and it
can also cause a redraw failure in full-screen applications on the
server (such as a terminal-based text editor - I reproduced this with
emacs), in which after the second term_size the terminal doesn't
manage to redraw itself.
Now I've pulled out the common logic that was in two of those three
pieces of code (and should have been in all three) into a subroutine
wm_size_resize_term, and arranged to call that in all three cases.
This fixes the inconsistency, and also fixes the emacs redraw problem
in the edge case I describe above.
This removes code duplication between the front ends: now the terminal
itself knows when the Conf is asking it not to turn on mouse
reporting, and the front ends can assume that if the terminal asks
them to then they should just do it.
This also makes the behaviour on mid-session reconfiguration more
sensible, in both code organisation and consistent behaviour.
Previously, term_reconfig would detect that CONF_no_mouse_rep had been
*set* in mid-session, and turn off mouse reporting mode in response.
But it would do it by clearing term->xterm_mouse, which isn't how the
front end enabled and disabled that feature, so things could get into
different states from different sequences of events that should have
ended up in the same place.
Also, the terminal wouldn't re-enable mouse reporting if
CONF_no_mouse_rep was *cleared* and the currently running terminal app
had been asking for mouse reports all along. Also, it was silly to
have half the CONF_no_mouse_rep handling in term_reconfig and the
other half in the front ends.
Now it should all be sensible, and also all centralised.
term->xterm_mouse consistently tracks whether the terminal application
is _requesting_ mouse reports; term->xterm_mouse_forbidden tracks
whether the client user is vetoing them; every change to either one of
those settings triggers a call to term_update_raw_mouse_mode which
sets up the front end appropriately for the current combination.
Similarly to other recent changes, the frontend now proactively keeps
Terminal up to date with the current position and size of the terminal
window, so that escape-sequence queries can be answered immediately
from the Terminal's own internal data structures without needing a
call back to the frontend.
Mostly this has let me remove explicit window-system API calls that
retrieve the window position and size, in favour of having the front
ends listen for WM_MOVE / WM_SIZE / ConfigureNotify events and track
the position and size that way. One exception is that the window pixel
size is still requested by Seat via a callback, to put in the
wire-encoded termios settings. That won't be happening very much, so
I'm leaving it this way round for the moment.
Now terminal.c makes nearly all the decisions about what the colour
palette should actually contain: it does the job of reading the
GUI-configurable colours out of Conf, and also the job of making up
the rest of the xterm-256 palette. The only exception is that TermWin
can provide a method to override some of the default colours, which on
Windows is used to implement the 'Use system colours' config option.
This saves code overall, partly because the front ends don't have to
be able to send palette data back to the Terminal any more (the
Terminal keeps the master copy and can answer palette-query escape
sequences from its own knowledge), and also because now there's only
one copy of the xterm-256 palette setup code (previously gtkwin.c and
window.c each had their own version of it).
In this rewrite, I've also introduced a multi-layered storage system
for the palette data in Terminal. One layer contains the palette
information derived from Conf; the next contains platform overrides
(currently just Windows's 'Use system colours'); the last one contains
overrides set by escape sequences in the middle of the session. The
topmost two layers can each _conditionally_ override the ones below.
As a result, if a server-side application manually resets (say) the
default fg and bg colours in mid-session to something that works well
in a particular application, those changes won't be wiped out by a
change in the Windows system colours or the Conf, which they would
have been before. Instead, changes in Conf or the system colours alter
the lower layers of the structure, but then when palette_rebuild is
called, the upper layer continues to override them, until a palette
reset (ESC]R) or terminal reset (e.g. ESC c) removes those upper-layer
changes. This seems like a more consistent strategy, in that the same
set of configuration settings will produce the same end result
regardless of what order they were applied in.
The palette-related methods in TermWin have had a total rework.
palette_get and palette_reset are both gone; palette_set can now set a
contiguous range of colours in one go; and the new
palette_get_overrides replaces window.c's old systopalette().
There are three separate indexing schemes in use by various bits of
the PuTTY front ends, and _none_ of them was clearly documented, let
alone all in the same place. Worse, functions that looked obviously
related, like win_palette_set and win_palette_get, used different
encodings.
Now all the encodings are defined together in putty.h, with
explanation of why there are three in the first place and clear
documentation of where each one is used; terminal.c provides mapping
tables that convert between them; the terminology is consistent
throughout; and win_palette_set has been converted to use the sensible
encoding.
Again, I've replaced it with a push-based notification going in the
other direction, so that when the terminal output stream includes a
query for 'is the window minimised?', the Terminal doesn't have to
consult the TermWin, because it already knows the answer.
The GTK API I'm using here (getting a GdkEventWindowState via
GtkWidget's window-state-event) is not present in GTK 1. The API I was
previously using (gdk_window_is_viewable) _is_, but it turns out that
that API doesn't reliably give the right answer: it only checks
visibility of GDK window ancestors, not X window ancestors. So in fact
GTK 1 PuTTY/pterm was only ever _pretending_ to reliably support the
'am I minimised' terminal query. Now it won't pretend any more.
Previously, window title management happened in a bipartisan sort of
way: front ends would choose their initial window title once they knew
what host name they were connecting to, but then Terminal would
override that later if the server set the window title by escape
sequences.
Now it's all done the same way round: the Terminal object is always
where titles are invented, and they only propagate in one direction,
from the Terminal to the TermWin.
This allows us to avoid duplicating in multiple front ends the logic
for what the initial window title should be. The frontend just has to
make one initial call to term_setup_window_titles, to tell the
terminal what hostname should go in the default title (if the Conf
doesn't override even that). Thereafter, all it has to do is respond
to the TermWin title-setting methods.
Similarly, the logic that handles window-title changes as a result of
the Change Settings dialog is also centralised into terminal.c. This
involved introducing an extra term_pre_reconfig() call that each
frontend can call to modify the Conf that will be used for the GUI
configurer; that's where the code now lives that copies the current
window title into there. (This also means that GTK PuTTY now behaves
consistently with Windows PuTTY on that point; GTK's previous
behaviour was less well thought out.)
It also means there's no longer any need for Terminal to talk to the
front end when a remote query wants to _find out_ the window title:
the Terminal knows the answer already. So TermWin's get_title method
can go.
All implementations of it work by checking the line_codepage field in
the ucsdata structure that the terminal itself already has a pointer
to. Therefore, it's a totally unnecessary query function: the terminal
can check the same thing directly by inspecting that structure!
(In fact, it already _does_ do that, for the purpose of actually
deciding how to decode terminal output data. It only uses this query
function at all for the auxiliary purpose of inventing useful tty
modes to pass to the backend.)
I just happened to spot a couple of cases where I'd apparently
open-coded the dupstr() logic before writing dupstr() itself, and
never got round to replacing the long-winded version with a call to
the standard helper function.
I found recently that if I ran Windows PSCP as a connection-sharing
downstream, it would send the SSH greeting down the named pipe, but
never receive anything back, though the upstream PuTTY was sending it.
PuTTY and Plink from the same build of the code would act happily as
downstreams.
It turned out that this was because the WaitForMultipleObjects call in
cli_main_loop() in wincliloop.c was failing with ERROR_ACCESS_DENIED.
That happened because it had an INVALID_HANDLE_VALUE in its list of
objects to wait for. That in turn happened because winselcli_event was
set to INVALID_HANDLE_VALUE.
Why was winselcli_event not set up? Because it's set up lazily by
do_select(), so if the program isn't handling any network sockets at
all (which is the case when PSCP is speaking over a named pipe
instead), then it never gets made into a valid event object.
So the problem wasn't that winselcli_event was in a bad state; it was
quite legitimately invalid. The problem was that wincliloop ought to
have _coped_ with it being invalid, by not inserting it in its list of
objects to wait for.
So now we check that case, and only insert winselcli_event in the list
if it's valid. And PSCP works again over connection sharing.
A user wrote in to point out the one in winhandl.c, and out of sheer
curiosity, I grepped the whole source base for '([a-zA-Z])\1\1' to see
if there were any others. Of course there are a lot of perfectly
sensible ones, like 'www' or 'Grrr', not to mention any amount of
0xFFFF and the iiii/bbbb emphasis system in Halibut code paragraphs,
but I did spot one more in the recently added udp.but section on
traits, and another in a variable name in uxagentsock.c.
