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putty-source/ssh2bpp.c
Simon Tatham ad0c502cef Refactor the LogContext type. 
LogContext is now the owner of the logevent() function that back ends
and so forth are constantly calling. Previously, logevent was owned by
the Frontend, which would store the message into its list for the GUI
Event Log dialog (or print it to standard error, or whatever) and then
pass it _back_ to LogContext to write to the currently open log file.
Now it's the other way round: LogContext gets the message from the
back end first, writes it to its log file if it feels so inclined, and
communicates it back to the front end.

This means that lots of parts of the back end system no longer need to
have a pointer to a full-on Frontend; the only thing they needed it
for was logging, so now they just have a LogContext (which many of
them had to have anyway, e.g. for logging SSH packets or session
traffic).

LogContext itself also doesn't get a full Frontend pointer any more:
it now talks back to the front end via a little vtable of its own
called LogPolicy, which contains the method that passes Event Log
entries through, the old askappend() function that decides whether to
truncate a pre-existing log file, and an emergency function for
printing an especially prominent message if the log file can't be
created. One minor nice effect of this is that console and GUI apps
can implement that last function subtly differently, so that Unix
console apps can write it with a plain \n instead of the \r\n
(harmless but inelegant) that the old centralised implementation
generated.

One other consequence of this is that the LogContext has to be
provided to backend_init() so that it's available to backends from the
instant of creation, rather than being provided via a separate API
call a couple of function calls later, because backends have typically
started doing things that need logging (like making network
connections) before the call to backend_provide_logctx. Fortunately,
there's no case in the whole code base where we don't already have
logctx by the time we make a backend (so I don't actually remember why
I ever delayed providing one). So that shortens the backend API by one
function, which is always nice.

While I'm tidying up, I've also moved the printf-style logeventf() and
the handy logevent_and_free() into logging.c, instead of having copies
of them scattered around other places. This has also let me remove
some stub functions from a couple of outlying applications like
Pageant. Finally, I've removed the pointless "_tag" at the end of
LogContext's official struct name.
2018-10-10 21:50:50 +01:00

892 lines
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/*
* Binary packet protocol for SSH-2.
*/
#include <assert.h>
#include "putty.h"
#include "ssh.h"
#include "sshbpp.h"
#include "sshcr.h"
struct ssh2_bpp_direction {
unsigned long sequence;
ssh2_cipher *cipher;
ssh2_mac *mac;
int etm_mode;
const struct ssh_compression_alg *pending_compression;
};
struct ssh2_bpp_state {
int crState;
long len, pad, payload, packetlen, maclen, length, maxlen;
unsigned char *buf;
size_t bufsize;
unsigned char *data;
unsigned cipherblk;
PktIn *pktin;
struct DataTransferStats *stats;
int cbc_ignore_workaround;
struct ssh2_bpp_direction in, out;
/* comp and decomp logically belong in the per-direction
* substructure, except that they have different types */
ssh_decompressor *in_decomp;
ssh_compressor *out_comp;
int pending_newkeys;
int pending_compression, seen_userauth_success;
BinaryPacketProtocol bpp;
};
static void ssh2_bpp_free(BinaryPacketProtocol *bpp);
static void ssh2_bpp_handle_input(BinaryPacketProtocol *bpp);
static void ssh2_bpp_handle_output(BinaryPacketProtocol *bpp);
static PktOut *ssh2_bpp_new_pktout(int type);
static const struct BinaryPacketProtocolVtable ssh2_bpp_vtable = {
ssh2_bpp_free,
ssh2_bpp_handle_input,
ssh2_bpp_handle_output,
ssh2_bpp_new_pktout,
ssh2_bpp_queue_disconnect, /* in sshcommon.c */
};
BinaryPacketProtocol *ssh2_bpp_new(
LogContext *logctx, struct DataTransferStats *stats)
{
struct ssh2_bpp_state *s = snew(struct ssh2_bpp_state);
memset(s, 0, sizeof(*s));
s->bpp.vt = &ssh2_bpp_vtable;
s->bpp.logctx = logctx;
s->stats = stats;
ssh_bpp_common_setup(&s->bpp);
return &s->bpp;
}
static void ssh2_bpp_free(BinaryPacketProtocol *bpp)
{
struct ssh2_bpp_state *s = container_of(bpp, struct ssh2_bpp_state, bpp);
sfree(s->buf);
if (s->out.cipher)
ssh2_cipher_free(s->out.cipher);
if (s->out.mac)
ssh2_mac_free(s->out.mac);
if (s->out_comp)
ssh_compressor_free(s->out_comp);
if (s->in.cipher)
ssh2_cipher_free(s->in.cipher);
if (s->in.mac)
ssh2_mac_free(s->in.mac);
if (s->in_decomp)
ssh_decompressor_free(s->in_decomp);
sfree(s->pktin);
sfree(s);
}
void ssh2_bpp_new_outgoing_crypto(
BinaryPacketProtocol *bpp,
const struct ssh2_cipheralg *cipher, const void *ckey, const void *iv,
const struct ssh2_macalg *mac, int etm_mode, const void *mac_key,
const struct ssh_compression_alg *compression, int delayed_compression)
{
struct ssh2_bpp_state *s;
assert(bpp->vt == &ssh2_bpp_vtable);
s = container_of(bpp, struct ssh2_bpp_state, bpp);
if (s->out.cipher)
ssh2_cipher_free(s->out.cipher);
if (s->out.mac)
ssh2_mac_free(s->out.mac);
if (s->out_comp)
ssh_compressor_free(s->out_comp);
if (cipher) {
s->out.cipher = ssh2_cipher_new(cipher);
ssh2_cipher_setkey(s->out.cipher, ckey);
ssh2_cipher_setiv(s->out.cipher, iv);
s->cbc_ignore_workaround = (
(ssh2_cipher_alg(s->out.cipher)->flags & SSH_CIPHER_IS_CBC) &&
!(s->bpp.remote_bugs & BUG_CHOKES_ON_SSH2_IGNORE));
bpp_logevent(("Initialised %.200s client->server encryption",
ssh2_cipher_alg(s->out.cipher)->text_name));
} else {
s->out.cipher = NULL;
s->cbc_ignore_workaround = FALSE;
}
s->out.etm_mode = etm_mode;
if (mac) {
s->out.mac = ssh2_mac_new(mac, s->out.cipher);
mac->setkey(s->out.mac, mac_key);
bpp_logevent(("Initialised %.200s client->server"
" MAC algorithm%s%s",
ssh2_mac_alg(s->out.mac)->text_name,
etm_mode ? " (in ETM mode)" : "",
(s->out.cipher &&
ssh2_cipher_alg(s->out.cipher)->required_mac ?
" (required by cipher)" : "")));
} else {
s->out.mac = NULL;
}
if (delayed_compression && !s->seen_userauth_success) {
s->out.pending_compression = compression;
s->out_comp = NULL;
bpp_logevent(("Will enable %s compression after user authentication",
s->out.pending_compression->text_name));
} else {
s->out.pending_compression = NULL;
/* 'compression' is always non-NULL, because no compression is
* indicated by ssh_comp_none. But this setup call may return a
* null out_comp. */
s->out_comp = ssh_compressor_new(compression);
if (s->out_comp)
bpp_logevent(("Initialised %s compression",
ssh_compressor_alg(s->out_comp)->text_name));
}
}
void ssh2_bpp_new_incoming_crypto(
BinaryPacketProtocol *bpp,
const struct ssh2_cipheralg *cipher, const void *ckey, const void *iv,
const struct ssh2_macalg *mac, int etm_mode, const void *mac_key,
const struct ssh_compression_alg *compression, int delayed_compression)
{
struct ssh2_bpp_state *s;
assert(bpp->vt == &ssh2_bpp_vtable);
s = container_of(bpp, struct ssh2_bpp_state, bpp);
if (s->in.cipher)
ssh2_cipher_free(s->in.cipher);
if (s->in.mac)
ssh2_mac_free(s->in.mac);
if (s->in_decomp)
ssh_decompressor_free(s->in_decomp);
if (cipher) {
s->in.cipher = ssh2_cipher_new(cipher);
ssh2_cipher_setkey(s->in.cipher, ckey);
ssh2_cipher_setiv(s->in.cipher, iv);
bpp_logevent(("Initialised %.200s server->client encryption",
ssh2_cipher_alg(s->in.cipher)->text_name));
} else {
s->in.cipher = NULL;
}
s->in.etm_mode = etm_mode;
if (mac) {
s->in.mac = ssh2_mac_new(mac, s->in.cipher);
mac->setkey(s->in.mac, mac_key);
bpp_logevent(("Initialised %.200s server->client MAC algorithm%s%s",
ssh2_mac_alg(s->in.mac)->text_name,
etm_mode ? " (in ETM mode)" : "",
(s->in.cipher &&
ssh2_cipher_alg(s->in.cipher)->required_mac ?
" (required by cipher)" : "")));
} else {
s->in.mac = NULL;
}
if (delayed_compression && !s->seen_userauth_success) {
s->in.pending_compression = compression;
s->in_decomp = NULL;
bpp_logevent(("Will enable %s decompression after user authentication",
s->in.pending_compression->text_name));
} else {
s->in.pending_compression = NULL;
/* 'compression' is always non-NULL, because no compression is
* indicated by ssh_comp_none. But this setup call may return a
* null in_decomp. */
s->in_decomp = ssh_decompressor_new(compression);
if (s->in_decomp)
bpp_logevent(("Initialised %s decompression",
ssh_decompressor_alg(s->in_decomp)->text_name));
}
/* Clear the pending_newkeys flag, so that handle_input below will
* start consuming the input data again. */
s->pending_newkeys = FALSE;
}
int ssh2_bpp_rekey_inadvisable(BinaryPacketProtocol *bpp)
{
struct ssh2_bpp_state *s;
assert(bpp->vt == &ssh2_bpp_vtable);
s = container_of(bpp, struct ssh2_bpp_state, bpp);
return s->pending_compression;
}
#define BPP_READ(ptr, len) do \
{ \
crMaybeWaitUntilV(s->bpp.input_eof || \
bufchain_try_fetch_consume( \
s->bpp.in_raw, ptr, len)); \
if (s->bpp.input_eof) \
goto eof; \
} while (0)
#define userauth_range(pkttype) ((unsigned)((pkttype) - 50) < 20)
static void ssh2_bpp_handle_input(BinaryPacketProtocol *bpp)
{
struct ssh2_bpp_state *s = container_of(bpp, struct ssh2_bpp_state, bpp);
crBegin(s->crState);
while (1) {
s->maxlen = 0;
s->length = 0;
if (s->in.cipher)
s->cipherblk = ssh2_cipher_alg(s->in.cipher)->blksize;
else
s->cipherblk = 8;
if (s->cipherblk < 8)
s->cipherblk = 8;
s->maclen = s->in.mac ? ssh2_mac_alg(s->in.mac)->len : 0;
if (s->in.cipher &&
(ssh2_cipher_alg(s->in.cipher)->flags & SSH_CIPHER_IS_CBC) &&
s->in.mac && !s->in.etm_mode) {
/*
* When dealing with a CBC-mode cipher, we want to avoid the
* possibility of an attacker's tweaking the ciphertext stream
* so as to cause us to feed the same block to the block
* cipher more than once and thus leak information
* (VU#958563). The way we do this is not to take any
* decisions on the basis of anything we've decrypted until
* we've verified it with a MAC. That includes the packet
* length, so we just read data and check the MAC repeatedly,
* and when the MAC passes, see if the length we've got is
* plausible.
*
* This defence is unnecessary in OpenSSH ETM mode, because
* the whole point of ETM mode is that the attacker can't
* tweak the ciphertext stream at all without the MAC
* detecting it before we decrypt anything.
*/
/*
* Make sure we have buffer space for a maximum-size packet.
*/
unsigned buflimit = OUR_V2_PACKETLIMIT + s->maclen;
if (s->bufsize < buflimit) {
s->bufsize = buflimit;
s->buf = sresize(s->buf, s->bufsize, unsigned char);
}
/* Read an amount corresponding to the MAC. */
BPP_READ(s->buf, s->maclen);
s->packetlen = 0;
ssh2_mac_start(s->in.mac);
put_uint32(s->in.mac, s->in.sequence);
for (;;) { /* Once around this loop per cipher block. */
/* Read another cipher-block's worth, and tack it on to
* the end. */
BPP_READ(s->buf + (s->packetlen + s->maclen), s->cipherblk);
/* Decrypt one more block (a little further back in
* the stream). */
ssh2_cipher_decrypt(s->in.cipher,
s->buf + s->packetlen, s->cipherblk);
/* Feed that block to the MAC. */
put_data(s->in.mac,
s->buf + s->packetlen, s->cipherblk);
s->packetlen += s->cipherblk;
/* See if that gives us a valid packet. */
if (ssh2_mac_verresult(s->in.mac, s->buf + s->packetlen) &&
((s->len = toint(GET_32BIT(s->buf))) ==
s->packetlen-4))
break;
if (s->packetlen >= (long)OUR_V2_PACKETLIMIT) {
ssh_sw_abort(s->bpp.ssh,
"No valid incoming packet found");
crStopV;
}
}
s->maxlen = s->packetlen + s->maclen;
/*
* Now transfer the data into an output packet.
*/
s->pktin = snew_plus(PktIn, s->maxlen);
s->pktin->qnode.prev = s->pktin->qnode.next = NULL;
s->pktin->type = 0;
s->pktin->qnode.on_free_queue = FALSE;
s->data = snew_plus_get_aux(s->pktin);
memcpy(s->data, s->buf, s->maxlen);
} else if (s->in.mac && s->in.etm_mode) {
if (s->bufsize < 4) {
s->bufsize = 4;
s->buf = sresize(s->buf, s->bufsize, unsigned char);
}
/*
* OpenSSH encrypt-then-MAC mode: the packet length is
* unencrypted, unless the cipher supports length encryption.
*/
BPP_READ(s->buf, 4);
/* Cipher supports length decryption, so do it */
if (s->in.cipher && (ssh2_cipher_alg(s->in.cipher)->flags &
SSH_CIPHER_SEPARATE_LENGTH)) {
/* Keep the packet the same though, so the MAC passes */
unsigned char len[4];
memcpy(len, s->buf, 4);
ssh2_cipher_decrypt_length(
s->in.cipher, len, 4, s->in.sequence);
s->len = toint(GET_32BIT(len));
} else {
s->len = toint(GET_32BIT(s->buf));
}
/*
* _Completely_ silly lengths should be stomped on before they
* do us any more damage.
*/
if (s->len < 0 || s->len > (long)OUR_V2_PACKETLIMIT ||
s->len % s->cipherblk != 0) {
ssh_sw_abort(s->bpp.ssh,
"Incoming packet length field was garbled");
crStopV;
}
/*
* So now we can work out the total packet length.
*/
s->packetlen = s->len + 4;
/*
* Allocate the packet to return, now we know its length.
*/
s->pktin = snew_plus(PktIn, OUR_V2_PACKETLIMIT + s->maclen);
s->pktin->qnode.prev = s->pktin->qnode.next = NULL;
s->pktin->type = 0;
s->pktin->qnode.on_free_queue = FALSE;
s->data = snew_plus_get_aux(s->pktin);
memcpy(s->data, s->buf, 4);
/*
* Read the remainder of the packet.
*/
BPP_READ(s->data + 4, s->packetlen + s->maclen - 4);
/*
* Check the MAC.
*/
if (s->in.mac && !ssh2_mac_verify(
s->in.mac, s->data, s->len + 4, s->in.sequence)) {
ssh_sw_abort(s->bpp.ssh, "Incorrect MAC received on packet");
crStopV;
}
/* Decrypt everything between the length field and the MAC. */
if (s->in.cipher)
ssh2_cipher_decrypt(
s->in.cipher, s->data + 4, s->packetlen - 4);
} else {
if (s->bufsize < s->cipherblk) {
s->bufsize = s->cipherblk;
s->buf = sresize(s->buf, s->bufsize, unsigned char);
}
/*
* Acquire and decrypt the first block of the packet. This will
* contain the length and padding details.
*/
BPP_READ(s->buf, s->cipherblk);
if (s->in.cipher)
ssh2_cipher_decrypt(
s->in.cipher, s->buf, s->cipherblk);
/*
* Now get the length figure.
*/
s->len = toint(GET_32BIT(s->buf));
/*
* _Completely_ silly lengths should be stomped on before they
* do us any more damage.
*/
if (s->len < 0 || s->len > (long)OUR_V2_PACKETLIMIT ||
(s->len + 4) % s->cipherblk != 0) {
ssh_sw_abort(s->bpp.ssh,
"Incoming packet was garbled on decryption");
crStopV;
}
/*
* So now we can work out the total packet length.
*/
s->packetlen = s->len + 4;
/*
* Allocate the packet to return, now we know its length.
*/
s->maxlen = s->packetlen + s->maclen;
s->pktin = snew_plus(PktIn, s->maxlen);
s->pktin->qnode.prev = s->pktin->qnode.next = NULL;
s->pktin->type = 0;
s->pktin->qnode.on_free_queue = FALSE;
s->data = snew_plus_get_aux(s->pktin);
memcpy(s->data, s->buf, s->cipherblk);
/*
* Read and decrypt the remainder of the packet.
*/
BPP_READ(s->data + s->cipherblk,
s->packetlen + s->maclen - s->cipherblk);
/* Decrypt everything _except_ the MAC. */
if (s->in.cipher)
ssh2_cipher_decrypt(
s->in.cipher,
s->data + s->cipherblk, s->packetlen - s->cipherblk);
/*
* Check the MAC.
*/
if (s->in.mac && !ssh2_mac_verify(
s->in.mac, s->data, s->len + 4, s->in.sequence)) {
ssh_sw_abort(s->bpp.ssh, "Incorrect MAC received on packet");
crStopV;
}
}
/* Get and sanity-check the amount of random padding. */
s->pad = s->data[4];
if (s->pad < 4 || s->len - s->pad < 1) {
ssh_sw_abort(s->bpp.ssh,
"Invalid padding length on received packet");
crStopV;
}
/*
* This enables us to deduce the payload length.
*/
s->payload = s->len - s->pad - 1;
s->length = s->payload + 5;
DTS_CONSUME(s->stats, in, s->packetlen);
s->pktin->sequence = s->in.sequence++;
s->length = s->packetlen - s->pad;
assert(s->length >= 0);
/*
* Decompress packet payload.
*/
{
unsigned char *newpayload;
int newlen;
if (s->in_decomp && ssh_decompressor_decompress(
s->in_decomp, s->data + 5, s->length - 5,
&newpayload, &newlen)) {
if (s->maxlen < newlen + 5) {
PktIn *old_pktin = s->pktin;
s->maxlen = newlen + 5;
s->pktin = snew_plus(PktIn, s->maxlen);
*s->pktin = *old_pktin; /* structure copy */
s->data = snew_plus_get_aux(s->pktin);
smemclr(old_pktin, s->packetlen + s->maclen);
sfree(old_pktin);
}
s->length = 5 + newlen;
memcpy(s->data + 5, newpayload, newlen);
sfree(newpayload);
}
}
/*
* Now we can identify the semantic content of the packet,
* and also the initial type byte.
*/
if (s->length <= 5) { /* == 5 we hope, but robustness */
/*
* RFC 4253 doesn't explicitly say that completely empty
* packets with no type byte are forbidden. We handle them
* here by giving them a type code larger than 0xFF, which
* will be picked up at the next layer and trigger
* SSH_MSG_UNIMPLEMENTED.
*/
s->pktin->type = SSH_MSG_NO_TYPE_CODE;
s->data += 5;
s->length = 0;
} else {
s->pktin->type = s->data[5];
s->data += 6;
s->length -= 6;
}
BinarySource_INIT(s->pktin, s->data, s->length);
if (s->bpp.logctx) {
logblank_t blanks[MAX_BLANKS];
int nblanks = ssh2_censor_packet(
s->bpp.pls, s->pktin->type, FALSE,
make_ptrlen(s->data, s->length), blanks);
log_packet(s->bpp.logctx, PKT_INCOMING, s->pktin->type,
ssh2_pkt_type(s->bpp.pls->kctx, s->bpp.pls->actx,
s->pktin->type),
s->data, s->length, nblanks, blanks,
&s->pktin->sequence, 0, NULL);
}
if (ssh2_bpp_check_unimplemented(&s->bpp, s->pktin)) {
sfree(s->pktin);
s->pktin = NULL;
continue;
}
pq_push(&s->bpp.in_pq, s->pktin);
{
int type = s->pktin->type;
s->pktin = NULL;
if (type == SSH2_MSG_NEWKEYS) {
/*
* Mild layer violation: in this situation we must
* suspend processing of the input byte stream until
* the transport layer has initialised the new keys by
* calling ssh2_bpp_new_incoming_crypto above.
*/
s->pending_newkeys = TRUE;
crWaitUntilV(!s->pending_newkeys);
continue;
}
if (type == SSH2_MSG_USERAUTH_SUCCESS) {
/*
* Another one: if we were configured with OpenSSH's
* deferred compression which is triggered on receipt
* of USERAUTH_SUCCESS, then this is the moment to
* turn on compression.
*/
if (s->in.pending_compression) {
s->in_decomp =
ssh_decompressor_new(s->in.pending_compression);
bpp_logevent(("Initialised delayed %s decompression",
ssh_decompressor_alg(
s->in_decomp)->text_name));
s->in.pending_compression = NULL;
}
if (s->out.pending_compression) {
s->out_comp =
ssh_compressor_new(s->out.pending_compression);
bpp_logevent(("Initialised delayed %s compression",
ssh_compressor_alg(
s->out_comp)->text_name));
s->out.pending_compression = NULL;
}
/*
* Whether or not we were doing delayed compression in
* _this_ set of crypto parameters, we should set a
* flag indicating that we're now authenticated, so
* that a delayed compression method enabled in any
* future rekey will be treated as un-delayed.
*/
s->seen_userauth_success = TRUE;
}
if (s->pending_compression && userauth_range(type)) {
/*
* Receiving any userauth message at all indicates
* that we're not about to turn on delayed compression
* - either because we just _have_ done, or because
* this message is a USERAUTH_FAILURE or some kind of
* intermediate 'please send more data' continuation
* message. Either way, we turn off the outgoing
* packet blockage for now, and release any queued
* output packets, so that we can make another attempt
* to authenticate. The next userauth packet we send
* will re-block the output direction.
*/
s->pending_compression = FALSE;
queue_idempotent_callback(&s->bpp.ic_out_pq);
}
}
}
eof:
if (!s->bpp.expect_close) {
ssh_remote_error(s->bpp.ssh,
"Server unexpectedly closed network connection");
} else {
ssh_remote_eof(s->bpp.ssh, "Server closed network connection");
}
return; /* avoid touching s now it's been freed */
crFinishV;
}
static PktOut *ssh2_bpp_new_pktout(int pkt_type)
{
PktOut *pkt = ssh_new_packet();
pkt->length = 5; /* space for packet length + padding length */
pkt->minlen = 0;
pkt->type = pkt_type;
put_byte(pkt, pkt_type);
pkt->prefix = pkt->length;
return pkt;
}
static void ssh2_bpp_format_packet_inner(struct ssh2_bpp_state *s, PktOut *pkt)
{
int origlen, cipherblk, maclen, padding, unencrypted_prefix, i;
if (s->bpp.logctx) {
ptrlen pktdata = make_ptrlen(pkt->data + pkt->prefix,
pkt->length - pkt->prefix);
logblank_t blanks[MAX_BLANKS];
int nblanks = ssh2_censor_packet(
s->bpp.pls, pkt->type, TRUE, pktdata, blanks);
log_packet(s->bpp.logctx, PKT_OUTGOING, pkt->type,
ssh2_pkt_type(s->bpp.pls->kctx, s->bpp.pls->actx,
pkt->type),
pktdata.ptr, pktdata.len, nblanks, blanks, &s->out.sequence,
pkt->downstream_id, pkt->additional_log_text);
}
cipherblk = s->out.cipher ? ssh2_cipher_alg(s->out.cipher)->blksize : 8;
cipherblk = cipherblk < 8 ? 8 : cipherblk; /* or 8 if blksize < 8 */
if (s->out_comp) {
unsigned char *newpayload;
int minlen, newlen;
/*
* Compress packet payload.
*/
minlen = pkt->minlen;
if (minlen) {
/*
* Work out how much compressed data we need (at least) to
* make the overall packet length come to pkt->minlen.
*/
if (s->out.mac)
minlen -= ssh2_mac_alg(s->out.mac)->len;
minlen -= 8; /* length field + min padding */
}
ssh_compressor_compress(s->out_comp, pkt->data + 5, pkt->length - 5,
&newpayload, &newlen, minlen);
pkt->length = 5;
put_data(pkt, newpayload, newlen);
sfree(newpayload);
}
/*
* Add padding. At least four bytes, and must also bring total
* length (minus MAC) up to a multiple of the block size.
* If pkt->forcepad is set, make sure the packet is at least that size
* after padding.
*/
padding = 4;
unencrypted_prefix = (s->out.mac && s->out.etm_mode) ? 4 : 0;
padding +=
(cipherblk - (pkt->length - unencrypted_prefix + padding) % cipherblk)
% cipherblk;
assert(padding <= 255);
maclen = s->out.mac ? ssh2_mac_alg(s->out.mac)->len : 0;
origlen = pkt->length;
for (i = 0; i < padding; i++)
put_byte(pkt, random_byte());
pkt->data[4] = padding;
PUT_32BIT(pkt->data, origlen + padding - 4);
/* Encrypt length if the scheme requires it */
if (s->out.cipher &&
(ssh2_cipher_alg(s->out.cipher)->flags & SSH_CIPHER_SEPARATE_LENGTH)) {
ssh2_cipher_encrypt_length(s->out.cipher, pkt->data, 4,
s->out.sequence);
}
put_padding(pkt, maclen, 0);
if (s->out.mac && s->out.etm_mode) {
/*
* OpenSSH-defined encrypt-then-MAC protocol.
*/
if (s->out.cipher)
ssh2_cipher_encrypt(s->out.cipher,
pkt->data + 4, origlen + padding - 4);
ssh2_mac_generate(s->out.mac, pkt->data, origlen + padding,
s->out.sequence);
} else {
/*
* SSH-2 standard protocol.
*/
if (s->out.mac)
ssh2_mac_generate(s->out.mac, pkt->data, origlen + padding,
s->out.sequence);
if (s->out.cipher)
ssh2_cipher_encrypt(s->out.cipher, pkt->data, origlen + padding);
}
s->out.sequence++; /* whether or not we MACed */
DTS_CONSUME(s->stats, out, origlen + padding);
}
static void ssh2_bpp_format_packet(struct ssh2_bpp_state *s, PktOut *pkt)
{
if (pkt->minlen > 0 && !s->out_comp) {
/*
* If we've been told to pad the packet out to a given minimum
* length, but we're not compressing (and hence can't get the
* compression to do the padding by pointlessly opening and
* closing zlib blocks), then our other strategy is to precede
* this message with an SSH_MSG_IGNORE that makes it up to the
* right length.
*
* A third option in principle, and the most obviously
* sensible, would be to set the explicit padding field in the
* packet to more than its minimum value. Sadly, that turns
* out to break some servers (our institutional memory thinks
* Cisco in particular) and so we abandoned that idea shortly
* after trying it.
*/
/*
* Calculate the length we expect the real packet to have.
*/
int block, length;
PktOut *ignore_pkt;
block = s->out.cipher ? ssh2_cipher_alg(s->out.cipher)->blksize : 0;
if (block < 8)
block = 8;
length = pkt->length;
length += 4; /* minimum 4 byte padding */
length += block-1;
length -= (length % block);
if (s->out.mac)
length += ssh2_mac_alg(s->out.mac)->len;
if (length < pkt->minlen) {
/*
* We need an ignore message. Calculate its length.
*/
length = pkt->minlen - length;
/*
* And work backwards from that to the length of the
* contained string.
*/
if (s->out.mac)
length -= ssh2_mac_alg(s->out.mac)->len;
length -= 8; /* length field + min padding */
length -= 5; /* type code + string length prefix */
if (length < 0)
length = 0;
ignore_pkt = ssh2_bpp_new_pktout(SSH2_MSG_IGNORE);
put_uint32(ignore_pkt, length);
while (length-- > 0)
put_byte(ignore_pkt, random_byte());
ssh2_bpp_format_packet_inner(s, ignore_pkt);
bufchain_add(s->bpp.out_raw, ignore_pkt->data, ignore_pkt->length);
ssh_free_pktout(ignore_pkt);
}
}
ssh2_bpp_format_packet_inner(s, pkt);
bufchain_add(s->bpp.out_raw, pkt->data, pkt->length);
}
static void ssh2_bpp_handle_output(BinaryPacketProtocol *bpp)
{
struct ssh2_bpp_state *s = container_of(bpp, struct ssh2_bpp_state, bpp);
PktOut *pkt;
int n_userauth;
/*
* Count the userauth packets in the queue.
*/
n_userauth = 0;
for (pkt = pq_first(&s->bpp.out_pq); pkt != NULL;
pkt = pq_next(&s->bpp.out_pq, pkt))
if (userauth_range(pkt->type))
n_userauth++;
if (s->pending_compression && !n_userauth) {
/*
* We're currently blocked from sending any outgoing packets
* until the other end tells us whether we're going to have to
* enable compression or not.
*
* If our end has pushed a userauth packet on the queue, that
* must mean it knows that a USERAUTH_SUCCESS is not
* immediately forthcoming, so we unblock ourselves and send
* up to and including that packet. But in this if statement,
* there aren't any, so we're still blocked.
*/
return;
}
if (s->cbc_ignore_workaround) {
/*
* When using a CBC-mode cipher in SSH-2, it's necessary to
* ensure that an attacker can't provide data to be encrypted
* using an IV that they know. We ensure this by inserting an
* SSH_MSG_IGNORE if the last cipher block of the previous
* packet has already been sent to the network (which we
* approximate conservatively by checking if it's vanished
* from out_raw).
*/
if (bufchain_size(s->bpp.out_raw) <
(ssh2_cipher_alg(s->out.cipher)->blksize +
ssh2_mac_alg(s->out.mac)->len)) {
/*
* There's less data in out_raw than the MAC size plus the
* cipher block size, which means at least one byte of
* that cipher block must already have left. Add an
* IGNORE.
*/
pkt = ssh_bpp_new_pktout(&s->bpp, SSH2_MSG_IGNORE);
put_stringz(pkt, "");
ssh2_bpp_format_packet(s, pkt);
}
}
while ((pkt = pq_pop(&s->bpp.out_pq)) != NULL) {
if (userauth_range(pkt->type))
n_userauth--;
ssh2_bpp_format_packet(s, pkt);
ssh_free_pktout(pkt);
if (n_userauth == 0 && s->out.pending_compression) {
/*
* This is the last userauth packet in the queue, so
* unless our side decides to send another one in future,
* we have to assume will potentially provoke
* USERAUTH_SUCCESS. Block (non-userauth) outgoing packets
* until we see the reply.
*/
s->pending_compression = TRUE;
return;
}
}
}
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