nhyatt/putty-source
1
0
Fork 0
mirror of https://git.tartarus.org/simon/putty.git synced 2025-01-09 17:38:00 +00:00
Code Issues Projects Releases Wiki Activity
2762a2025f
putty-source/sshbpp.h
Simon Tatham b4e1bca2c3 Change vtable defs to use C99 designated initialisers. 
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.
2020-03-10 21:06:29 +00:00

177 lines
6.8 KiB
C
Raw Blame History

/*
* Abstraction of the binary packet protocols used in SSH.
*/
#ifndef PUTTY_SSHBPP_H
#define PUTTY_SSHBPP_H
typedef struct BinaryPacketProtocolVtable BinaryPacketProtocolVtable;
struct BinaryPacketProtocolVtable {
void (*free)(BinaryPacketProtocol *);
void (*handle_input)(BinaryPacketProtocol *);
void (*handle_output)(BinaryPacketProtocol *);
PktOut *(*new_pktout)(int type);
void (*queue_disconnect)(BinaryPacketProtocol *,
const char *msg, int category);
uint32_t packet_size_limit;
};
struct BinaryPacketProtocol {
const struct BinaryPacketProtocolVtable *vt;
bufchain *in_raw, *out_raw;
bool input_eof; /* set this if in_raw will never be added to again */
PktInQueue in_pq;
PktOutQueue out_pq;
PacketLogSettings *pls;
LogContext *logctx;
Ssh *ssh;
/* ic_in_raw is filled in by the BPP (probably by calling
* ssh_bpp_common_setup). The BPP's owner triggers it when data is
* added to in_raw, and also when the BPP is newly created. */
IdempotentCallback ic_in_raw;
/* ic_out_pq is entirely internal to the BPP itself; it's used as
* the callback on out_pq. */
IdempotentCallback ic_out_pq;
int remote_bugs;
/* Set this if remote connection closure should not generate an
* error message (either because it's not to be treated as an
* error at all, or because some other error message has already
* been emitted). */
bool expect_close;
};
static inline void ssh_bpp_handle_input(BinaryPacketProtocol *bpp)
{ bpp->vt->handle_input(bpp); }
static inline void ssh_bpp_handle_output(BinaryPacketProtocol *bpp)
{ bpp->vt->handle_output(bpp); }
static inline PktOut *ssh_bpp_new_pktout(BinaryPacketProtocol *bpp, int type)
{ return bpp->vt->new_pktout(type); }
static inline void ssh_bpp_queue_disconnect(BinaryPacketProtocol *bpp,
const char *msg, int category)
{ bpp->vt->queue_disconnect(bpp, msg, category); }
/* ssh_bpp_free is more than just a macro wrapper on the vtable; it
* does centralised parts of the freeing too. */
void ssh_bpp_free(BinaryPacketProtocol *bpp);
BinaryPacketProtocol *ssh1_bpp_new(LogContext *logctx);
void ssh1_bpp_new_cipher(BinaryPacketProtocol *bpp,
const ssh_cipheralg *cipher,
const void *session_key);
/* This is only called from outside the BPP in server mode; in client
* mode the BPP detects compression start time automatically by
* snooping message types */
void ssh1_bpp_start_compression(BinaryPacketProtocol *bpp);
/* Helper routine which does common BPP initialisation, e.g. setting
* up in_pq and out_pq, and initialising input_consumer. */
void ssh_bpp_common_setup(BinaryPacketProtocol *);
/* Common helper functions between the SSH-2 full and bare BPPs */
void ssh2_bpp_queue_disconnect(BinaryPacketProtocol *bpp,
const char *msg, int category);
bool ssh2_bpp_check_unimplemented(BinaryPacketProtocol *bpp, PktIn *pktin);
/* Convenience macro for BPPs to send formatted strings to the Event
* Log. Assumes a function parameter called 'bpp' is in scope. */
#define bpp_logevent(...) ( \
logevent_and_free((bpp)->logctx, dupprintf(__VA_ARGS__)))
/*
* Structure that tracks how much data is sent and received, for
* purposes of triggering an SSH-2 rekey when either one gets over a
* configured limit. In each direction, the flag 'running' indicates
* that we haven't hit the limit yet, and 'remaining' tracks how much
* longer until we do. The function dts_consume() subtracts a given
* amount from the counter in a particular direction, and sets
* 'expired' if the limit has been hit.
*
* The limit is sticky: once 'running' has flipped to false,
* 'remaining' is no longer decremented, so it shouldn't dangerously
* wrap round.
*/
struct DataTransferStatsDirection {
bool running, expired;
unsigned long remaining;
};
struct DataTransferStats {
struct DataTransferStatsDirection in, out;
};
static inline void dts_consume(struct DataTransferStatsDirection *s,
unsigned long size_consumed)
{
if (s->running) {
if (s->remaining <= size_consumed) {
s->running = false;
s->expired = true;
} else {
s->remaining -= size_consumed;
}
}
}
static inline void dts_reset(struct DataTransferStatsDirection *s,
unsigned long starting_size)
{
s->expired = false;
s->remaining = starting_size;
/*
* The semantics of setting CONF_ssh_rekey_data to zero are to
* disable data-volume based rekeying completely. So if the
* starting size is actually zero, we don't set 'running' to true
* in the first place, which means we won't ever set the expired
* flag.
*/
s->running = (starting_size != 0);
}
BinaryPacketProtocol *ssh2_bpp_new(
LogContext *logctx, struct DataTransferStats *stats, bool is_server);
void ssh2_bpp_new_outgoing_crypto(
BinaryPacketProtocol *bpp,
const ssh_cipheralg *cipher, const void *ckey, const void *iv,
const ssh2_macalg *mac, bool etm_mode, const void *mac_key,
const ssh_compression_alg *compression, bool delayed_compression);
void ssh2_bpp_new_incoming_crypto(
BinaryPacketProtocol *bpp,
const ssh_cipheralg *cipher, const void *ckey, const void *iv,
const ssh2_macalg *mac, bool etm_mode, const void *mac_key,
const ssh_compression_alg *compression, bool delayed_compression);
/*
* A query method specific to the interface between ssh2transport and
* ssh2bpp. If true, it indicates that we're potentially in the
* race-condition-prone part of delayed compression setup and so
* asynchronous outgoing transport-layer packets are currently not
* being sent, which means in particular that it would be a bad idea
* to start a rekey because then we'd stop responding to anything
* _other_ than transport-layer packets and deadlock the protocol.
*/
bool ssh2_bpp_rekey_inadvisable(BinaryPacketProtocol *bpp);
BinaryPacketProtocol *ssh2_bare_bpp_new(LogContext *logctx);
/*
* The initial code to handle the SSH version exchange is also
* structured as an implementation of BinaryPacketProtocol, because
* that makes it easy to switch from that to the next BPP once it
* tells us which one we're using.
*/
struct ssh_version_receiver {
void (*got_ssh_version)(struct ssh_version_receiver *rcv,
int major_version);
};
BinaryPacketProtocol *ssh_verstring_new(
Conf *conf, LogContext *logctx, bool bare_connection_mode,
const char *protoversion, struct ssh_version_receiver *rcv,
bool server_mode, const char *impl_name);
const char *ssh_verstring_get_remote(BinaryPacketProtocol *);
const char *ssh_verstring_get_local(BinaryPacketProtocol *);
int ssh_verstring_get_bugs(BinaryPacketProtocol *);
#endif /* PUTTY_SSHBPP_H */
Reference in New Issue View Git Blame Copy Permalink