This is a sweeping change applied across the whole code base by a spot
of Emacs Lisp. Now, everywhere I declare a vtable filled with function
pointers (and the occasional const data member), all the members of
the vtable structure are initialised by name using the '.fieldname =
value' syntax introduced in C99.
We were already using this syntax for a handful of things in the new
key-generation progress report system, so it's not new to the code
base as a whole.
The advantage is that now, when a vtable only declares a subset of the
available fields, I can initialise the rest to NULL or zero just by
leaving them out. This is most dramatic in a couple of the outlying
vtables in things like psocks (which has a ConnectionLayerVtable
containing only one non-NULL method), but less dramatically, it means
that the new 'flags' field in BackendVtable can be completely left out
of every backend definition except for the SUPDUP one which defines it
to a nonzero value. Similarly, the test_for_upstream method only used
by SSH doesn't have to be mentioned in the rest of the backends;
network Plugs for listening sockets don't have to explicitly null out
'receive' and 'sent', and vice versa for 'accepting', and so on.
While I'm at it, I've normalised the declarations so they don't use
the unnecessarily verbose 'struct' keyword. Also a handful of them
weren't const; now they are.
Sometimes, within a switch statement, you want to declare local
variables specific to the handler for one particular case. Until now
I've mostly been writing this in the form
switch (discriminant) {
case SIMPLE:
do stuff;
break;
case COMPLICATED:
{
declare variables;
do stuff;
}
break;
}
which is ugly because the two pieces of essentially similar code
appear at different indent levels, and also inconvenient because you
have less horizontal space available to write the complicated case
handler in - particuarly undesirable because _complicated_ case
handlers are the ones most likely to need all the space they can get!
After encountering a rather nicer idiom in the LLVM source code, and
after a bit of hackery this morning figuring out how to persuade
Emacs's auto-indent to do what I wanted with it, I've decided to move
to an idiom in which the open brace comes right after the case
statement, and the code within it is indented the same as it would
have been without the brace. Then the whole case handler (including
the break) lives inside those braces, and you get something that looks
more like this:
switch (discriminant) {
case SIMPLE:
do stuff;
break;
case COMPLICATED: {
declare variables;
do stuff;
break;
}
}
This commit is a big-bang change that reformats all the complicated
case handlers I could find into the new layout. This is particularly
nice in the Pageant main function, in which almost _every_ case
handler had a bundle of variables and was long and complicated. (In
fact that's what motivated me to get round to this.) Some of the
innermost parts of the terminal escape-sequence handling are also
breathing a bit easier now the horizontal pressure on them is
relieved.
(Also, in a few cases, I was able to remove the extra braces
completely, because the only variable local to the case handler was a
loop variable which our new C99 policy allows me to move into the
initialiser clause of its for statement.)
Viewed with whitespace ignored, this is not too disruptive a change.
Downstream patches that conflict with it may need to be reapplied
using --ignore-whitespace or similar.
This exactly replicates the way it's done in SSH-2: at the start of
the connection layer we set the trust status to untrusted, and if that
reports that it didn't give any indication to the user, we fall back
to presenting an interactive anti-spoofing prompt.
I don't know how I forgot to do that in SSH-1, and even more, how we
haven't noticed for a month. We noticed the same bug in _Rlogin_
within a day of the 0.71 release, after all!
With this and the ciphers, I think we've now got the full range of
SSH-1 config options (such as they are) that correspond to varying the
KEXINIT strings in SSH-2.
This is much simpler than Conf, because I don't expect to have to copy
it around, load or save it to disk (or the Windows registry), or
serialise it between processes. So it can be a straightforward struct.
As yet there's nothing actually _in_ it. I've just created the
structure and arranged to pass it through to all the SSH layers. But
now it's here, it will be a place I can add configuration items as I
find I need them.
This is a general cleanup which has been overdue for some time: lots
of length fields are now the machine word type rather than the (in
practice) fixed 'int'.
I've only just noticed that the server-side SSH-1 connection layer had
no handler for that message, so when an SSH-1 connection terminates in
the normal way, Uppity's event log reports 'Unexpected packet
received, type 33 (SSH1_CMSG_EXIT_CONFIRMATION)', which is wrong in
that it _should_ be expected!
Taking a leaf out of the LLVM code base: this macro still includes an
assert(false) so that the message will show up in a typical build, but
it follows it up with a call to a function explicitly marked as no-
return.
So this ought to do a better job of convincing compilers that once a
code path hits this function it _really doesn't_ have to still faff
about with making up a bogus return value or filling in a variable
that 'might be used uninitialised' in the following code that won't be
reached anyway.
I've gone through the existing code looking for the assert(false) /
assert(0) idiom and replaced all the ones I found with the new macro,
which also meant I could remove a few pointless return statements and
variable initialisations that I'd already had to put in to placate
compiler front ends.
In the past, I've had a lot of macros which you call with double
parentheses, along the lines of debug(("format string", params)), so
that the inner parens protect the commas and permit the macro to treat
the whole printf-style argument list as one macro argument.
That's all very well, but it's a bit inconvenient (it doesn't leave
you any way to implement such a macro by prepending another argument
to the list), and now this code base's rules allow C99isms, I can
switch all those macros to using a single pair of parens, using the
C99 ability to say '...' in the parameter list of the #define and get
at the corresponding suffix of the arguments as __VA_ARGS__.
So I'm doing it. I've made the following printf-style macros variadic:
bpp_logevent, ppl_logevent, ppl_printf and debug.
While I'm here, I've also fixed up a collection of conditioned-out
calls to debug() in the Windows front end which were clearly expecting
a macro with a different calling syntax, because they had an integer
parameter first. If I ever have a need to condition those back in,
they should actually work now.
My normal habit these days, in new code, is to treat int and bool as
_almost_ completely separate types. I'm still willing to use C's
implicit test for zero on an integer (e.g. 'if (!blob.len)' is fine,
no need to spell it out as blob.len != 0), but generally, if a
variable is going to be conceptually a boolean, I like to declare it
bool and assign to it using 'true' or 'false' rather than 0 or 1.
PuTTY is an exception, because it predates the C99 bool, and I've
stuck to its existing coding style even when adding new code to it.
But it's been annoying me more and more, so now that I've decided C99
bool is an acceptable thing to require from our toolchain in the first
place, here's a quite thorough trawl through the source doing
'boolification'. Many variables and function parameters are now typed
as bool rather than int; many assignments of 0 or 1 to those variables
are now spelled 'true' or 'false'.
I managed this thorough conversion with the help of a custom clang
plugin that I wrote to trawl the AST and apply heuristics to point out
where things might want changing. So I've even managed to do a decent
job on parts of the code I haven't looked at in years!
To make the plugin's work easier, I pushed platform front ends
generally in the direction of using standard 'bool' in preference to
platform-specific boolean types like Windows BOOL or GTK's gboolean;
I've left the platform booleans in places they _have_ to be for the
platform APIs to work right, but variables only used by my own code
have been converted wherever I found them.
In a few places there are int values that look very like booleans in
_most_ of the places they're used, but have a rarely-used third value,
or a distinction between different nonzero values that most users
don't care about. In these cases, I've _removed_ uses of 'true' and
'false' for the return values, to emphasise that there's something
more subtle going on than a simple boolean answer:
- the 'multisel' field in dialog.h's list box structure, for which
the GTK front end in particular recognises a difference between 1
and 2 but nearly everything else treats as boolean
- the 'urgent' parameter to plug_receive, where 1 vs 2 tells you
something about the specific location of the urgent pointer, but
most clients only care about 0 vs 'something nonzero'
- the return value of wc_match, where -1 indicates a syntax error in
the wildcard.
- the return values from SSH-1 RSA-key loading functions, which use
-1 for 'wrong passphrase' and 0 for all other failures (so any
caller which already knows it's not loading an _encrypted private_
key can treat them as boolean)
- term->esc_query, and the 'query' parameter in toggle_mode in
terminal.c, which _usually_ hold 0 for ESC[123h or 1 for ESC[?123h,
but can also hold -1 for some other intervening character that we
don't support.
In a few places there's an integer that I haven't turned into a bool
even though it really _can_ only take values 0 or 1 (and, as above,
tried to make the call sites consistent in not calling those values
true and false), on the grounds that I thought it would make it more
confusing to imply that the 0 value was in some sense 'negative' or
bad and the 1 positive or good:
- the return value of plug_accepting uses the POSIXish convention of
0=success and nonzero=error; I think if I made it bool then I'd
also want to reverse its sense, and that's a job for a separate
piece of work.
- the 'screen' parameter to lineptr() in terminal.c, where 0 and 1
represent the default and alternate screens. There's no obvious
reason why one of those should be considered 'true' or 'positive'
or 'success' - they're just indices - so I've left it as int.
ssh_scp_recv had particularly confusing semantics for its previous int
return value: its call sites used '<= 0' to check for error, but it
never actually returned a negative number, just 0 or 1. Now the
function and its call sites agree that it's a bool.
In a couple of places I've renamed variables called 'ret', because I
don't like that name any more - it's unclear whether it means the
return value (in preparation) for the _containing_ function or the
return value received from a subroutine call, and occasionally I've
accidentally used the same variable for both and introduced a bug. So
where one of those got in my way, I've renamed it to 'toret' or 'retd'
(the latter short for 'returned') in line with my usual modern
practice, but I haven't done a thorough job of finding all of them.
Finally, one amusing side effect of doing this is that I've had to
separate quite a few chained assignments. It used to be perfectly fine
to write 'a = b = c = TRUE' when a,b,c were int and TRUE was just a
the 'true' defined by stdbool.h, that idiom provokes a warning from
gcc: 'suggest parentheses around assignment used as truth value'!
This commit includes <stdbool.h> from defs.h and deletes my
traditional definitions of TRUE and FALSE, but other than that, it's a
100% mechanical search-and-replace transforming all uses of TRUE and
FALSE into the C99-standardised lowercase spellings.
No actual types are changed in this commit; that will come next. This
is just getting the noise out of the way, so that subsequent commits
can have a higher proportion of signal.
Unlike the traditional Unix SSH server organisation, the SFTP server
is built into the same process as all the rest of the code. sesschan.c
spots a subsystem request for "sftp", and responds to it by
instantiating an SftpServer object and swapping out its own vtable for
one that talks to it.
(I rather like the idea of an object swapping its own vtable for a
different one in the middle of its lifetime! This is one of those
tricks that would be absurdly hard to implement in a 'proper' OO
language, but when you're doing vtables by hand in C, it's no more
difficult than any other piece of ordinary pointer manipulation. As
long as the methods in both vtables expect the same physical structure
layout, it doesn't cause a problem.)
The SftpServer object doesn't deal directly with SFTP packet formats;
it implements the SFTP server logic in a more abstract way, by having
a vtable method for each SFTP request type with an appropriate
parameter list. It sends its replies by calling methods in another
vtable called SftpReplyBuilder, which in the normal case will write an
SFTP reply packet to send back to the client. So SftpServer can focus
more or less completely on the details of a particular filesystem API
- and hence, the implementation I've got lives in the unix source
directory, and works directly with file descriptors and struct stat
and the like.
(One purpose of this abstraction layer is that I may well want to
write a second dummy implementation, for test-suite purposes, with
completely controllable behaviour, and now I have a handy place to
plug it in in place of the live filesystem.)
In between sesschan's parsing of the byte stream into SFTP packets and
the SftpServer object, there's a layer in the new file sftpserver.c
which does the actual packet decoding and encoding: each request
packet is passed to that, which pulls the fields out of the request
packet and calls the appropriate method of SftpServer. It also
provides the default SftpReplyBuilder which makes the output packet.
I've moved some code out of the previous SFTP client implementation -
basic packet construction code, and in particular the BinarySink/
BinarySource marshalling fuinction for fxp_attrs - into sftpcommon.c,
so that the two directions can share as much as possible.
This server is NOT SECURE! If anyone is reading this commit message,
DO NOT DEPLOY IT IN A HOSTILE-FACING ENVIRONMENT! Its purpose is to
speak the server end of everything PuTTY speaks on the client side, so
that I can test that I haven't broken PuTTY when I reorganise its
code, even things like RSA key exchange or chained auth methods which
it's hard to find a server that speaks at all.
(For this reason, it's declared with [UT] in the Recipe file, so that
it falls into the same category as programs like testbn, which won't
be installed by 'make install'.)
Working title is 'Uppity', partly for 'Universal PuTTY Protocol
Interaction Test Yoke', but mostly because it looks quite like the
word 'PuTTY' with part of it reversed. (Apparently 'test yoke' is a
very rarely used term meaning something not altogether unlike 'test
harness', which is a bit of a stretch, but it'll do.)
It doesn't actually _support_ everything I want yet. At the moment,
it's a proof of concept only. But it has most of the machinery
present, and the parts it's missing - such as chained auth methods -
should be easy enough to add because I've built in the required
flexibility, in the form of an AuthPolicy object which can request
them if it wants to. However, the current AuthPolicy object is
entirely trivial, and will let in any user with the password "weasel".
(Another way in which this is not a production-ready server is that it
also has no interaction with the OS's authentication system. In
particular, it will not only let in any user with the same password,
but it won't even change uid - it will open shells and forwardings
under whatever user id you started it up as.)
Currently, the program can only speak the SSH protocol on its standard
I/O channels (using the new FdSocket facility), so if you want it to
listen on a network port, you'll have to run it from some kind of
separate listening program similar to inetd. For my own tests, I'm not
even doing that: I'm just having PuTTY spawn it as a local proxy
process, which also conveniently eliminates the risk of anyone hostile
connecting to it.
The bulk of the actual code reorganisation is already done by previous
commits, so this change is _mostly_ just dropping in a new set of
server-specific source files alongside the client-specific ones I
created recently. The remaining changes in the shared SSH code are
numerous, but all minor:
- a few extra parameters to BPP and PPL constructors (e.g. 'are you
in server mode?'), and pass both sets of SSH-1 protocol flags from
the login to the connection layer
- in server mode, unconditionally send our version string _before_
waiting for the remote one
- a new hook in the SSH-1 BPP to handle enabling compression in
server mode, where the message exchange works the other way round
- new code in the SSH-2 BPP to do _deferred_ compression the other
way round (the non-deferred version is still nicely symmetric)
- in the SSH-2 transport layer, some adjustments to do key derivation
either way round (swapping round the identifying letters in the
various hash preimages, and making sure to list the KEXINITs in the
right order)
- also in the SSH-2 transport layer, an if statement that controls
whether we send SERVICE_REQUEST and wait for SERVICE_ACCEPT, or
vice versa
- new ConnectionLayer methods for opening outgoing channels for X and
agent forwardings
- new functions in portfwd.c to establish listening sockets suitable
for remote-to-local port forwarding (i.e. not under the direction
of a Conf the way it's done on the client side).
