This allows for sharing a bit of code, and it also means that
deduplication of KEXINIT algorithms can be done while working out the
list of algorithms rather than when constructing the KEXINIT packet
itself.
The general plan is that if PuTTY knows a host key for a server, it
should preferentially ask for the same type of key so that there's some
chance of actually getting the same key again. This should mean that
when a server (or PuTTY) adds a new host key type, PuTTY doesn't
gratuitously switch to that key type and then warn the user about an
unrecognised key.
It seems like quite an important thing to mention in the event log!
Suppose there's a bug affecting only one curve, for example? Fixed-
group Diffie-Hellman has always logged the group, but the ECDH log
message just told you the hash and not also the curve.
To implement this, I've added a 'textname' field to all elliptic
curves, whether they're used for kex or signing or both, suitable for
use in this log message and any others we might find a need for in
future.
When anyone connects to a PuTTY tool's listening socket - whether it's
a user of a local->remote port forwarding, a connection-sharing
downstream or a client of Pageant - we'd like to log as much
information as we can find out about where the connection came from.
To that end, I've implemented a function sk_peer_info() in the socket
abstraction, which returns a freeform text string as best it can (or
NULL, if it can't get anything at all) describing the thing at the
other end of the connection. For TCP connections, this is done using
getpeername() to get an IP address and port in the obvious way; for
Unix-domain sockets, we attempt SO_PEERCRED (conditionalised on some
moderately hairy autoconfery) to get the pid and owner of the peer. I
haven't implemented anything for Windows named pipes, but I will if I
hear of anything useful.
The new code remembers the contents and meaning of the outgoing KEXINIT
and uses this to drive the algorithm negotiation, rather than trying to
reconstruct what the outgoing KEXINIT probably said. This removes the
need to maintain the KEXINIT generation and parsing code precisely in
parallel.
It also fixes a bug whereby PuTTY would have selected the wrong host key
type in cases where the server gained a host key type between rekeys.
Having found a lot of unfixed constness issues in recent development,
I thought perhaps it was time to get proactive, so I compiled the
whole codebase with -Wwrite-strings. That turned up a huge load of
const problems, which I've fixed in this commit: the Unix build now
goes cleanly through with -Wwrite-strings, and the Windows build is as
close as I could get it (there are some lingering issues due to
occasional Windows API functions like AcquireCredentialsHandle not
having the right constness).
Notable fallout beyond the purely mechanical changing of types:
- the stuff saved by cmdline_save_param() is now explicitly
dupstr()ed, and freed in cmdline_run_saved.
- I couldn't make both string arguments to cmdline_process_param()
const, because it intentionally writes to one of them in the case
where it's the argument to -pw (in the vain hope of being at least
slightly friendly to 'ps'), so elsewhere I had to temporarily
dupstr() something for the sake of passing it to that function
- I had to invent a silly parallel version of const_cmp() so I could
pass const string literals in to lookup functions.
- stripslashes() in pscp.c and psftp.c has the annoying strchr nature
The ec_name_to_curve and ec_curve_to_name functions shouldn't really
have had to exist at all: whenever any part of the PuTTY codebase
starts using sshecc.c, it's starting from an ssh_signkey or ssh_kex
pointer already found by some other means. So if we make sure not to
lose that pointer, we should never need to do any string-based lookups
to find the curve we want, and conversely, when we need to know the
name of our curve or our algorithm, we should be able to look it up as
a straightforward const char * starting from the algorithm pointer.
This commit cleans things up so that that is indeed what happens. The
ssh_signkey and ssh_kex structures defined in sshecc.c now have
'extra' fields containing pointers to all the necessary stuff;
ec_name_to_curve and ec_curve_to_name have been completely removed;
struct ec_curve has a string field giving the curve's name (but only
for those curves which _have_ a name exposed in the wire protocol,
i.e. the three NIST ones); struct ec_key keeps a pointer to the
ssh_signkey it started from, and uses that to remember the algorithm
name rather than reconstructing it from the curve. And I think I've
got rid of all the ad-hockery scattered around the code that switches
on curve->fieldBits or manually constructs curve names using stuff
like sprintf("nistp%d"); the only remaining switch on fieldBits
(necessary because that's the UI for choosing a curve in PuTTYgen) is
at least centralised into one place in sshecc.c.
One user-visible result is that the format of ed25519 host keys in the
registry has changed: there's now no curve name prefix on them,
because I think it's not really right to make up a name to use. So any
early adopters who've been using snapshot PuTTY in the last week will
be inconvenienced; sorry about that.
This gives families of public key and kex functions (by which I mean
those sharing a set of methods) a place to store parameters that allow
the methods to vary depending on which exact algorithm is in use.
The ssh_kex structure already had a set of parameters specific to
Diffie-Hellman key exchange; I've moved those into sshdh.c and made
them part of the 'extra' structure for that family only, so that
unrelated kex methods don't have to faff about saying NULL,NULL,0,0.
(This required me to write an extra accessor function for ssh.c to ask
whether a DH method was group-exchange style or fixed-group style, but
that doesn't seem too silly.)
Not all of them, but the ones that don't get a 'void *key' parameter.
This means I can share methods between multiple ssh_signkey
structures, and still give those methods an easy way to find out which
public key method they're dealing with, by loading parameters from a
larger structure in which the ssh_signkey is the first element.
(In OO terms, I'm arranging that all static methods of my public key
classes get a pointer to the class vtable, to make up for not having a
pointer to the class instance.)
I haven't actually done anything with the new facility in this commit,
but it will shortly allow me to clean up the constant lookups by curve
name in the ECDSA code.
All the name strings in ssh_cipher, ssh_mac, ssh_hash, ssh_signkey
point to compile-time string literals, hence should obviously be const
char *.
Most of these const-correctness patches are just a mechanical job of
adding a 'const' in the one place you need it right now, and then
chasing the implications through the code adding further consts until
it compiles. But this one has actually shown up a bug: the 'algorithm'
output parameter in ssh2_userkey_loadpub was sometimes returning a
pointer to a string literal, and sometimes a pointer to dynamically
allocated memory, so callers were forced to either sometimes leak
memory or sometimes free a bad thing. Now it's consistently
dynamically allocated, and should be freed everywhere too.
There were ad-hoc functions for fingerprinting a bare key blob in both
cmdgen.c and pageant.c, not quite doing the same thing. Also, every
SSH-2 public key algorithm in the code base included a dedicated
fingerprint() method, which is completely pointless since SSH-2 key
fingerprints are computed in an algorithm-independent way (just hash
the standard-format public key blob), so each of those methods was
just duplicating the work of the public_blob() method with a less
general output mechanism.
Now sshpubk.c centrally provides an ssh2_fingerprint_blob() function
that does all the real work, plus an ssh2_fingerprint() function that
wraps it and deals with calling public_blob() to get something to
fingerprint. And the fingerprint() method has been completely removed
from ssh_signkey and all its implementations, and good riddance.
Obviously PuTTY can't actually do public-key authentication itself, if
you give it a public rather than private key file. But it can still
match the supplied public key file against the list of keys in the
agent, and narrow down to that. So if for some reason you're
forwarding an agent to a machine you don't want to trust with your
_private_ key file (even encrypted), you can still use the '-i' option
to select which key from the agent to use, by uploading just the
public key file to that machine.
It's just ssh_pkt_addstring_data but using strlen to get the length of
string to add, so make that explicit by having it call
ssh_pkt_addstring_data. Good compilers should be unaffected by this
change.
This is the kex protocol id "curve25519-sha256@libssh.org", so called
because it's over the prime field of order 2^255 - 19.
Arithmetic in this curve is done using the Montgomery representation,
rather than the Weierstrass representation. So 'struct ec_curve' has
grown a discriminant field and a union of subtypes.
Several of the functions in ssh2_signkey, and one or two SSH-1 key
functions too, were still taking assorted non-const buffer parameters
that had never been properly constified. Sort them all out.
This causes the initial length field of the SSH-2 binary packet to be
unencrypted (with the knock-on effect that now the packet length not
including MAC must be congruent to 4 rather than 0 mod the cipher
block size), and then the MAC is applied over the unencrypted length
field and encrypted ciphertext (prefixed by the sequence number as
usual). At the cost of exposing some information about the packet
lengths to an attacker (but rarely anything they couldn't have
inferred from the TCP headers anyway), this closes down any
possibility of a MITM using the client as a decryption oracle, unless
they can _first_ fake a correct MAC.
ETM mode is enabled by means of selecting a different MAC identifier,
all the current ones of which are constructed by appending
"-etm@openssh.com" to the name of a MAC that already existed.
We currently prefer the original SSH-2 binary packet protocol (i.e. we
list all the ETM-mode MACs last in our KEXINIT), on the grounds that
it's better tested and more analysed, so at the moment the new mode is
only activated if a server refuses to speak anything else.
PuTTY now uses the updated version of Diffie-Hellman group exchange,
except for a few old OpenSSH versions which Darren Tucker reports only
support the old version.
FIXME: this needs further work because the Bugs config panel has now
overflowed.
Florent Daigniere of Matta points out that RFC 4253 actually
_requires_ us to refuse to accept out-of-range values, though it isn't
completely clear to me why this should be a MUST on the receiving end.
Matta considers this to be a security vulnerability, on the grounds
that if a server should accidentally send an obviously useless value
such as 1 then we will fail to reject it and agree a key that an
eavesdropper could also figure out. Their id for this vulnerability is
MATTA-2015-002.
I'm not actually sure why we've always had back ends notify ldisc of
changes to echo/edit settings by giving ldisc_send(ldisc,NULL,0,0) a
special meaning, instead of by having a separate dedicated notify
function with its own prototype and parameter set. Coverity's recent
observation that the two kinds of call don't even have the same
requirements on the ldisc (particularly, whether ldisc->term can be
NULL) makes me realise that it's really high time I separated the two
conceptually different operations into actually different functions.
While I'm here, I've renamed the confusing ldisc_update() function
which that special operation ends up feeding to, because it's not
actually a function applying to an ldisc - it applies to a front end.
So ldisc_send(ldisc,NULL,0,0) is now ldisc_echoedit_update(ldisc), and
that in turn figures out the current echo/edit settings before passing
them on to frontend_echoedit_update(). I think that should be clearer.
This ought to happen in ssh_do_close alongside the code that shuts
down other local listening things like port forwardings, for the same
obvious reason. In particular, we should get through this _before_ we
put up a modal dialog box telling the user what just went wrong with
the SSH connection, so that further sessions started while that box is
active don't try futilely to connect to the not-really-listening
zombie upstream.
This provides support for ECDSA public keys, for both hosts and users,
and also ECDH key exchange. Supported curves are currently just the
three NIST curves required by RFC 5656.
I had initially assumed that, since all of a user's per-connection
subdirectories live inside a top-level putty-connshare.$USER directory
that's not accessible to anyone else, there would be no need to
obfuscate the names of the internal directories for privacy, because
nobody would be able to look at them anyway.
Unfortunately, that's not true: 'netstat -ax' run by any user will
show up the full pathnames of Unix-domain sockets, including pathname
components that you wouldn't have had the access to go and look at
directly. So the Unix connection sharing socket names do need to be
obfuscated after all.
Since Unix doesn't have Windows's CryptProtectMemory, we have to do
this manually, by creating a file of random salt data inside the
top-level putty-connshare directory (if there isn't one there already)
and then hashing that salt with the "user@host" connection identifier
to get the socket directory name. What a pain.
[originally from svn r10222]
This option is available from the command line as '-hostkey', and is
also configurable through the GUI. When enabled, it completely
replaces all of the automated host key management: the server's host
key will be checked against the manually configured list, and the
connection will be allowed or disconnected on that basis, and the host
key store in the registry will not be either consulted or updated.
The main aim is to provide a means of automatically running Plink,
PSCP or PSFTP deep inside Windows services where HKEY_CURRENT_USER
isn't available to have stored the right host key in. But it also
permits you to specify a list of multiple host keys, which means a
second use case for the same mechanism will probably be round-robin
DNS names that select one of several servers with different host keys.
Host keys can be specified as the standard MD5 fingerprint or as an
SSH-2 base64 blob, and are canonicalised on input. (The base64 blob is
more unwieldy, especially with Windows command-line length limits, but
provides a means of specifying the _whole_ public key in case you
don't trust MD5. I haven't bothered to provide an analogous mechanism
for SSH-1, on the basis that anyone worrying about MD5 should have
stopped using SSH-1 already!)
[originally from svn r10220]
This is the same code I previously fixed for failing to check NULL
pointers coming back from ssh_pkt_getstring if the server's KEXINIT
ended early, leading to an embarrassing segfault in place of a fatal
error message. But I've now also had it pointed out to me that the
fatal error message passes the string as %s, which is inappropriate
because (being read straight out of the middle of an SSH packet) it
isn't necessarily zero-terminated!
This is still just an embarrassing segfault in place of a fatal error
message, and not exploitable as far as I can see, because the string
is passed to a dupprintf, which will either read off the end of
allocated address space and segfault non-exploitably, or else it will
find a NUL after all and carefully allocate enough space to format an
error message containing all of the previous junk. But still, how
embarrassing to have messed up the same code _twice_.
[originally from svn r10211]
We now expect that after the server has sent us CHANNEL_CLOSE, we
should not expect to see any replies to our outstanding channel
requests, and conversely after we have sent CHANNEL_CLOSE we avoid
sending any reply to channel requests from the server. This was the
consensus among implementors discussing the problem on ietf-ssh in
April 2014.
To cope with current OpenSSH's (and perhaps other servers we don't
know about yet) willingness to send request replies after
CHANNEL_CLOSE, I introduce a bug-compatibility flag which is detected
for every OpenSSH version up to and including the current 6.6 - but
not beyond, since https://bugzilla.mindrot.org/show_bug.cgi?id=1818
promises that 6.7 will also implement the new consensus behaviour.
[originally from svn r10200]
Martin Prikryl reports that it had the exact same bug as old OpenSSH
(insisting that RSA signature integers be padded with leading zero
bytes to the same length as the RSA modulus, where in fact RFC 4253
section 6.6 says it ought to have _no_ padding), but is recently
fixed. The first version string to not have the bug is reported to be
"mod_sftp/0.9.9", so here we recognise everything less than that as
requiring our existing workaround.
[originally from svn r10161]
If we search for a colon by computing ptr + host_strcspn(ptr,":"),
then the resulting pointer is always non-NULL, and the 'not found'
condition is not !p but !*p.
This typo could have caused PuTTY to overrun a string, but not in a
security-bug sense because any such string would have to have been
loaded from the configuration rather than received from a hostile
source.
[originally from svn r10123]
Both GUI PuTTY front ends have a piece of logic whereby a string is
interpreted as host:port if there's _one_ colon in it, but if there's
more than one colon then it's assumed to be an IPv6 literal with no
trailing port number. This permits the PuTTY command line to take
strings such as 'host', 'host:22' or '[::1]:22', but also cope with a
bare v6 literal such as '::1'.
This logic is also required in the two Plink front ends and in the
processing of CONF_loghost for host key indexing in ssh.c, but was
missing in all those places. Add it.
[originally from svn r10121]
I've gone through everywhere we handle host names / addresses (on
command lines, in PuTTY config, in port forwarding, in X display
names, in host key storage...) and tried to make them handle IPv6
literals sensibly, by using the host_str* functions I introduced in my
previous commit. Generally it's now OK to use a bracketed IPv6 literal
anywhere a hostname might have been valid; in a few cases where no
ambiguity exists (e.g. no :port suffix is permitted anyway)
unbracketed IPv6 literals are also acceptable.
[originally from svn r10120]
The line that resets st->pktin->length to cover only the semantic
payload of the SSH message was overwriting the modification to
st->pktin->length performed by the optional decompression step. I
didn't notice because I don't habitually enable compression.
[originally from svn r10103]
[r10070 == 9f5d51a4ac]
I've enabled gcc's format-string checking on dupprintf, by declaring
it in misc.h to have the appropriate GNU-specific attribute. This
pointed out a selection of warnings, which I've fixed.
[originally from svn r10084]
The basic strategy is described at the top of the new source file
sshshare.c. In very brief: an 'upstream' PuTTY opens a Unix-domain
socket or Windows named pipe, and listens for connections from other
PuTTYs wanting to run sessions on the same server. The protocol spoken
down that socket/pipe is essentially the bare ssh-connection protocol,
using a trivial binary packet protocol with no encryption, and the
upstream has to do some fiddly transformations that I've been
referring to as 'channel-number NAT' to avoid resource clashes between
the sessions it's managing.
This is quite different from OpenSSH's approach of using the Unix-
domain socket as a means of passing file descriptors around; the main
reason for that is that fd-passing is Unix-specific but this system
has to work on Windows too. However, there are additional advantages,
such as making it easy for each downstream PuTTY to run its own
independent set of port and X11 forwardings (though the method for
making the latter work is quite painful).
Sharing is off by default, but configuration is intended to be very
easy in the normal case - just tick one box in the SSH config panel
and everything else happens automatically.
[originally from svn r10083]
Now that it doesn't actually make a network connection because that's
deferred until after the X authorisation exchange, there's no point in
having it return an error message and write the real output through a
pointer argument. Instead, we can just have it return xconn directly
and simplify the call sites.
[originally from svn r10081]
Rather than the top-level component of X forwarding being an
X11Display structure which owns some auth data, it's now a collection
of X11FakeAuth structures, each of which owns a display. The idea is
that when we receive an X connection, we wait to see which of our
available auth cookies it matches, and then connect to whatever X
display that auth cookie identifies. At present the tree will only
have one thing in it; this is all groundwork for later changes.
[originally from svn r10079]
