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3214563d8e
putty-source/sshrsa.c
Simon Tatham 3214563d8e Convert a lot of 'int' variables to 'bool'. 
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'!
2018-11-03 13:45:00 +00:00

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/*
* RSA implementation for PuTTY.
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include "ssh.h"
#include "misc.h"
void BinarySource_get_rsa_ssh1_pub(
BinarySource *src, struct RSAKey *rsa, RsaSsh1Order order)
{
unsigned bits;
Bignum e, m;
bits = get_uint32(src);
if (order == RSA_SSH1_EXPONENT_FIRST) {
e = get_mp_ssh1(src);
m = get_mp_ssh1(src);
} else {
m = get_mp_ssh1(src);
e = get_mp_ssh1(src);
}
if (rsa) {
rsa->bits = bits;
rsa->exponent = e;
rsa->modulus = m;
rsa->bytes = (bignum_bitcount(m) + 7) / 8;
} else {
freebn(e);
freebn(m);
}
}
void BinarySource_get_rsa_ssh1_priv(
BinarySource *src, struct RSAKey *rsa)
{
rsa->private_exponent = get_mp_ssh1(src);
}
bool rsa_ssh1_encrypt(unsigned char *data, int length, struct RSAKey *key)
{
Bignum b1, b2;
int i;
unsigned char *p;
if (key->bytes < length + 4)
return false; /* RSA key too short! */
memmove(data + key->bytes - length, data, length);
data[0] = 0;
data[1] = 2;
for (i = 2; i < key->bytes - length - 1; i++) {
do {
data[i] = random_byte();
} while (data[i] == 0);
}
data[key->bytes - length - 1] = 0;
b1 = bignum_from_bytes(data, key->bytes);
b2 = modpow(b1, key->exponent, key->modulus);
p = data;
for (i = key->bytes; i--;) {
*p++ = bignum_byte(b2, i);
}
freebn(b1);
freebn(b2);
return true;
}
/*
* Compute (base ^ exp) % mod, provided mod == p * q, with p,q
* distinct primes, and iqmp is the multiplicative inverse of q mod p.
* Uses Chinese Remainder Theorem to speed computation up over the
* obvious implementation of a single big modpow.
*/
Bignum crt_modpow(Bignum base, Bignum exp, Bignum mod,
Bignum p, Bignum q, Bignum iqmp)
{
Bignum pm1, qm1, pexp, qexp, presult, qresult, diff, multiplier, ret0, ret;
/*
* Reduce the exponent mod phi(p) and phi(q), to save time when
* exponentiating mod p and mod q respectively. Of course, since p
* and q are prime, phi(p) == p-1 and similarly for q.
*/
pm1 = copybn(p);
decbn(pm1);
qm1 = copybn(q);
decbn(qm1);
pexp = bigmod(exp, pm1);
qexp = bigmod(exp, qm1);
/*
* Do the two modpows.
*/
presult = modpow(base, pexp, p);
qresult = modpow(base, qexp, q);
/*
* Recombine the results. We want a value which is congruent to
* qresult mod q, and to presult mod p.
*
* We know that iqmp * q is congruent to 1 * mod p (by definition
* of iqmp) and to 0 mod q (obviously). So we start with qresult
* (which is congruent to qresult mod both primes), and add on
* (presult-qresult) * (iqmp * q) which adjusts it to be congruent
* to presult mod p without affecting its value mod q.
*/
if (bignum_cmp(presult, qresult) < 0) {
/*
* Can't subtract presult from qresult without first adding on
* p.
*/
Bignum tmp = presult;
presult = bigadd(presult, p);
freebn(tmp);
}
diff = bigsub(presult, qresult);
multiplier = bigmul(iqmp, q);
ret0 = bigmuladd(multiplier, diff, qresult);
/*
* Finally, reduce the result mod n.
*/
ret = bigmod(ret0, mod);
/*
* Free all the intermediate results before returning.
*/
freebn(pm1);
freebn(qm1);
freebn(pexp);
freebn(qexp);
freebn(presult);
freebn(qresult);
freebn(diff);
freebn(multiplier);
freebn(ret0);
return ret;
}
/*
* This function is a wrapper on modpow(). It has the same effect as
* modpow(), but employs RSA blinding to protect against timing
* attacks and also uses the Chinese Remainder Theorem (implemented
* above, in crt_modpow()) to speed up the main operation.
*/
static Bignum rsa_privkey_op(Bignum input, struct RSAKey *key)
{
Bignum random, random_encrypted, random_inverse;
Bignum input_blinded, ret_blinded;
Bignum ret;
SHA512_State ss;
unsigned char digest512[64];
int digestused = lenof(digest512);
int hashseq = 0;
/*
* Start by inventing a random number chosen uniformly from the
* range 2..modulus-1. (We do this by preparing a random number
* of the right length and retrying if it's greater than the
* modulus, to prevent any potential Bleichenbacher-like
* attacks making use of the uneven distribution within the
* range that would arise from just reducing our number mod n.
* There are timing implications to the potential retries, of
* course, but all they tell you is the modulus, which you
* already knew.)
*
* To preserve determinism and avoid Pageant needing to share
* the random number pool, we actually generate this `random'
* number by hashing stuff with the private key.
*/
while (1) {
int bits, byte, bitsleft, v;
random = copybn(key->modulus);
/*
* Find the topmost set bit. (This function will return its
* index plus one.) Then we'll set all bits from that one
* downwards randomly.
*/
bits = bignum_bitcount(random);
byte = 0;
bitsleft = 0;
while (bits--) {
if (bitsleft <= 0) {
bitsleft = 8;
/*
* Conceptually the following few lines are equivalent to
* byte = random_byte();
*/
if (digestused >= lenof(digest512)) {
SHA512_Init(&ss);
put_data(&ss, "RSA deterministic blinding", 26);
put_uint32(&ss, hashseq);
put_mp_ssh2(&ss, key->private_exponent);
SHA512_Final(&ss, digest512);
hashseq++;
/*
* Now hash that digest plus the signature
* input.
*/
SHA512_Init(&ss);
put_data(&ss, digest512, sizeof(digest512));
put_mp_ssh2(&ss, input);
SHA512_Final(&ss, digest512);
digestused = 0;
}
byte = digest512[digestused++];
}
v = byte & 1;
byte >>= 1;
bitsleft--;
bignum_set_bit(random, bits, v);
}
bn_restore_invariant(random);
/*
* Now check that this number is strictly greater than
* zero, and strictly less than modulus.
*/
if (bignum_cmp(random, Zero) <= 0 ||
bignum_cmp(random, key->modulus) >= 0) {
freebn(random);
continue;
}
/*
* Also, make sure it has an inverse mod modulus.
*/
random_inverse = modinv(random, key->modulus);
if (!random_inverse) {
freebn(random);
continue;
}
break;
}
/*
* RSA blinding relies on the fact that (xy)^d mod n is equal
* to (x^d mod n) * (y^d mod n) mod n. We invent a random pair
* y and y^d; then we multiply x by y, raise to the power d mod
* n as usual, and divide by y^d to recover x^d. Thus an
* attacker can't correlate the timing of the modpow with the
* input, because they don't know anything about the number
* that was input to the actual modpow.
*
* The clever bit is that we don't have to do a huge modpow to
* get y and y^d; we will use the number we just invented as
* _y^d_, and use the _public_ exponent to compute (y^d)^e = y
* from it, which is much faster to do.
*/
random_encrypted = crt_modpow(random, key->exponent,
key->modulus, key->p, key->q, key->iqmp);
input_blinded = modmul(input, random_encrypted, key->modulus);
ret_blinded = crt_modpow(input_blinded, key->private_exponent,
key->modulus, key->p, key->q, key->iqmp);
ret = modmul(ret_blinded, random_inverse, key->modulus);
freebn(ret_blinded);
freebn(input_blinded);
freebn(random_inverse);
freebn(random_encrypted);
freebn(random);
return ret;
}
Bignum rsa_ssh1_decrypt(Bignum input, struct RSAKey *key)
{
return rsa_privkey_op(input, key);
}
bool rsa_ssh1_decrypt_pkcs1(Bignum input, struct RSAKey *key, strbuf *outbuf)
{
strbuf *data = strbuf_new();
bool success = false;
BinarySource src[1];
{
Bignum *b = rsa_ssh1_decrypt(input, key);
int i;
for (i = (bignum_bitcount(key->modulus) + 7) / 8; i-- > 0 ;) {
put_byte(data, bignum_byte(b, i));
}
freebn(b);
}
BinarySource_BARE_INIT(src, data->u, data->len);
/* Check PKCS#1 formatting prefix */
if (get_byte(src) != 0) goto out;
if (get_byte(src) != 2) goto out;
while (1) {
unsigned char byte = get_byte(src);
if (get_err(src)) goto out;
if (byte == 0)
break;
}
/* Everything else is the payload */
success = true;
put_data(outbuf, get_ptr(src), get_avail(src));
out:
strbuf_free(data);
return success;
}
int rsastr_len(struct RSAKey *key)
{
Bignum md, ex;
int mdlen, exlen;
md = key->modulus;
ex = key->exponent;
mdlen = (bignum_bitcount(md) + 15) / 16;
exlen = (bignum_bitcount(ex) + 15) / 16;
return 4 * (mdlen + exlen) + 20;
}
void rsastr_fmt(char *str, struct RSAKey *key)
{
Bignum md, ex;
int len = 0, i, nibbles;
static const char hex[] = "0123456789abcdef";
md = key->modulus;
ex = key->exponent;
len += sprintf(str + len, "0x");
nibbles = (3 + bignum_bitcount(ex)) / 4;
if (nibbles < 1)
nibbles = 1;
for (i = nibbles; i--;)
str[len++] = hex[(bignum_byte(ex, i / 2) >> (4 * (i % 2))) & 0xF];
len += sprintf(str + len, ",0x");
nibbles = (3 + bignum_bitcount(md)) / 4;
if (nibbles < 1)
nibbles = 1;
for (i = nibbles; i--;)
str[len++] = hex[(bignum_byte(md, i / 2) >> (4 * (i % 2))) & 0xF];
str[len] = '\0';
}
/*
* Generate a fingerprint string for the key. Compatible with the
* OpenSSH fingerprint code.
*/
char *rsa_ssh1_fingerprint(struct RSAKey *key)
{
struct MD5Context md5c;
unsigned char digest[16];
strbuf *out;
int i;
MD5Init(&md5c);
put_mp_ssh1(&md5c, key->modulus);
put_mp_ssh1(&md5c, key->exponent);
MD5Final(digest, &md5c);
out = strbuf_new();
strbuf_catf(out, "%d ", bignum_bitcount(key->modulus));
for (i = 0; i < 16; i++)
strbuf_catf(out, "%s%02x", i ? ":" : "", digest[i]);
if (key->comment)
strbuf_catf(out, " %s", key->comment);
return strbuf_to_str(out);
}
/*
* Verify that the public data in an RSA key matches the private
* data. We also check the private data itself: we ensure that p >
* q and that iqmp really is the inverse of q mod p.
*/
bool rsa_verify(struct RSAKey *key)
{
Bignum n, ed, pm1, qm1;
int cmp;
/* n must equal pq. */
n = bigmul(key->p, key->q);
cmp = bignum_cmp(n, key->modulus);
freebn(n);
if (cmp != 0)
return false;
/* e * d must be congruent to 1, modulo (p-1) and modulo (q-1). */
pm1 = copybn(key->p);
decbn(pm1);
ed = modmul(key->exponent, key->private_exponent, pm1);
freebn(pm1);
cmp = bignum_cmp(ed, One);
freebn(ed);
if (cmp != 0)
return false;
qm1 = copybn(key->q);
decbn(qm1);
ed = modmul(key->exponent, key->private_exponent, qm1);
freebn(qm1);
cmp = bignum_cmp(ed, One);
freebn(ed);
if (cmp != 0)
return false;
/*
* Ensure p > q.
*
* I have seen key blobs in the wild which were generated with
* p < q, so instead of rejecting the key in this case we
* should instead flip them round into the canonical order of
* p > q. This also involves regenerating iqmp.
*/
if (bignum_cmp(key->p, key->q) <= 0) {
Bignum tmp = key->p;
key->p = key->q;
key->q = tmp;
freebn(key->iqmp);
key->iqmp = modinv(key->q, key->p);
if (!key->iqmp)
return false;
}
/*
* Ensure iqmp * q is congruent to 1, modulo p.
*/
n = modmul(key->iqmp, key->q, key->p);
cmp = bignum_cmp(n, One);
freebn(n);
if (cmp != 0)
return false;
return true;
}
void rsa_ssh1_public_blob(BinarySink *bs, struct RSAKey *key,
RsaSsh1Order order)
{
put_uint32(bs, bignum_bitcount(key->modulus));
if (order == RSA_SSH1_EXPONENT_FIRST) {
put_mp_ssh1(bs, key->exponent);
put_mp_ssh1(bs, key->modulus);
} else {
put_mp_ssh1(bs, key->modulus);
put_mp_ssh1(bs, key->exponent);
}
}
/* Given an SSH-1 public key blob, determine its length. */
int rsa_ssh1_public_blob_len(void *data, int maxlen)
{
BinarySource src[1];
BinarySource_BARE_INIT(src, data, maxlen);
/* Expect a length word, then exponent and modulus. (It doesn't
* even matter which order.) */
get_uint32(src);
freebn(get_mp_ssh1(src));
freebn(get_mp_ssh1(src));
if (get_err(src))
return -1;
/* Return the number of bytes consumed. */
return src->pos;
}
void freersakey(struct RSAKey *key)
{
if (key->modulus)
freebn(key->modulus);
if (key->exponent)
freebn(key->exponent);
if (key->private_exponent)
freebn(key->private_exponent);
if (key->p)
freebn(key->p);
if (key->q)
freebn(key->q);
if (key->iqmp)
freebn(key->iqmp);
if (key->comment)
sfree(key->comment);
}
/* ----------------------------------------------------------------------
* Implementation of the ssh-rsa signing key type.
*/
static void rsa2_freekey(ssh_key *key); /* forward reference */
static ssh_key *rsa2_new_pub(const ssh_keyalg *self, ptrlen data)
{
BinarySource src[1];
struct RSAKey *rsa;
BinarySource_BARE_INIT(src, data.ptr, data.len);
if (!ptrlen_eq_string(get_string(src), "ssh-rsa"))
return NULL;
rsa = snew(struct RSAKey);
rsa->sshk = &ssh_rsa;
rsa->exponent = get_mp_ssh2(src);
rsa->modulus = get_mp_ssh2(src);
rsa->private_exponent = NULL;
rsa->p = rsa->q = rsa->iqmp = NULL;
rsa->comment = NULL;
if (get_err(src)) {
rsa2_freekey(&rsa->sshk);
return NULL;
}
return &rsa->sshk;
}
static void rsa2_freekey(ssh_key *key)
{
struct RSAKey *rsa = container_of(key, struct RSAKey, sshk);
freersakey(rsa);
sfree(rsa);
}
static char *rsa2_cache_str(ssh_key *key)
{
struct RSAKey *rsa = container_of(key, struct RSAKey, sshk);
char *p;
int len;
len = rsastr_len(rsa);
p = snewn(len, char);
rsastr_fmt(p, rsa);
return p;
}
static void rsa2_public_blob(ssh_key *key, BinarySink *bs)
{
struct RSAKey *rsa = container_of(key, struct RSAKey, sshk);
put_stringz(bs, "ssh-rsa");
put_mp_ssh2(bs, rsa->exponent);
put_mp_ssh2(bs, rsa->modulus);
}
static void rsa2_private_blob(ssh_key *key, BinarySink *bs)
{
struct RSAKey *rsa = container_of(key, struct RSAKey, sshk);
put_mp_ssh2(bs, rsa->private_exponent);
put_mp_ssh2(bs, rsa->p);
put_mp_ssh2(bs, rsa->q);
put_mp_ssh2(bs, rsa->iqmp);
}
static ssh_key *rsa2_new_priv(const ssh_keyalg *self,
ptrlen pub, ptrlen priv)
{
BinarySource src[1];
ssh_key *sshk;
struct RSAKey *rsa;
sshk = rsa2_new_pub(self, pub);
if (!sshk)
return NULL;
rsa = container_of(sshk, struct RSAKey, sshk);
BinarySource_BARE_INIT(src, priv.ptr, priv.len);
rsa->private_exponent = get_mp_ssh2(src);
rsa->p = get_mp_ssh2(src);
rsa->q = get_mp_ssh2(src);
rsa->iqmp = get_mp_ssh2(src);
if (get_err(src) || !rsa_verify(rsa)) {
rsa2_freekey(&rsa->sshk);
return NULL;
}
return &rsa->sshk;
}
static ssh_key *rsa2_new_priv_openssh(const ssh_keyalg *self,
BinarySource *src)
{
struct RSAKey *rsa;
rsa = snew(struct RSAKey);
rsa->sshk = &ssh_rsa;
rsa->comment = NULL;
rsa->modulus = get_mp_ssh2(src);
rsa->exponent = get_mp_ssh2(src);
rsa->private_exponent = get_mp_ssh2(src);
rsa->iqmp = get_mp_ssh2(src);
rsa->p = get_mp_ssh2(src);
rsa->q = get_mp_ssh2(src);
if (get_err(src) || !rsa_verify(rsa)) {
rsa2_freekey(&rsa->sshk);
return NULL;
}
return &rsa->sshk;
}
static void rsa2_openssh_blob(ssh_key *key, BinarySink *bs)
{
struct RSAKey *rsa = container_of(key, struct RSAKey, sshk);
put_mp_ssh2(bs, rsa->modulus);
put_mp_ssh2(bs, rsa->exponent);
put_mp_ssh2(bs, rsa->private_exponent);
put_mp_ssh2(bs, rsa->iqmp);
put_mp_ssh2(bs, rsa->p);
put_mp_ssh2(bs, rsa->q);
}
static int rsa2_pubkey_bits(const ssh_keyalg *self, ptrlen pub)
{
ssh_key *sshk;
struct RSAKey *rsa;
int ret;
sshk = rsa2_new_pub(self, pub);
if (!sshk)
return -1;
rsa = container_of(sshk, struct RSAKey, sshk);
ret = bignum_bitcount(rsa->modulus);
rsa2_freekey(&rsa->sshk);
return ret;
}
/*
* This is the magic ASN.1/DER prefix that goes in the decoded
* signature, between the string of FFs and the actual SHA hash
* value. The meaning of it is:
*
* 00 -- this marks the end of the FFs; not part of the ASN.1 bit itself
*
* 30 21 -- a constructed SEQUENCE of length 0x21
* 30 09 -- a constructed sub-SEQUENCE of length 9
* 06 05 -- an object identifier, length 5
* 2B 0E 03 02 1A -- object id { 1 3 14 3 2 26 }
* (the 1,3 comes from 0x2B = 43 = 40*1+3)
* 05 00 -- NULL
* 04 14 -- a primitive OCTET STRING of length 0x14
* [0x14 bytes of hash data follows]
*
* The object id in the middle there is listed as `id-sha1' in
* ftp://ftp.rsasecurity.com/pub/pkcs/pkcs-1/pkcs-1v2-1d2.asn (the
* ASN module for PKCS #1) and its expanded form is as follows:
*
* id-sha1 OBJECT IDENTIFIER ::= {
* iso(1) identified-organization(3) oiw(14) secsig(3)
* algorithms(2) 26 }
*/
static const unsigned char asn1_weird_stuff[] = {
0x00, 0x30, 0x21, 0x30, 0x09, 0x06, 0x05, 0x2B,
0x0E, 0x03, 0x02, 0x1A, 0x05, 0x00, 0x04, 0x14,
};
#define ASN1_LEN ( (int) sizeof(asn1_weird_stuff) )
static bool rsa2_verify(ssh_key *key, ptrlen sig, ptrlen data)
{
struct RSAKey *rsa = container_of(key, struct RSAKey, sshk);
BinarySource src[1];
ptrlen type, in_pl;
Bignum in, out;
int bytes, i, j;
bool toret;
unsigned char hash[20];
BinarySource_BARE_INIT(src, sig.ptr, sig.len);
type = get_string(src);
/*
* RFC 4253 section 6.6: the signature integer in an ssh-rsa
* signature is 'without lengths or padding'. That is, we _don't_
* expect the usual leading zero byte if the topmost bit of the
* first byte is set. (However, because of the possibility of
* BUG_SSH2_RSA_PADDING at the other end, we tolerate it if it's
* there.) So we can't use get_mp_ssh2, which enforces that
* leading-byte scheme; instead we use get_string and
* bignum_from_bytes, which will tolerate anything.
*/
in_pl = get_string(src);
if (get_err(src) || !ptrlen_eq_string(type, "ssh-rsa"))
return false;
in = bignum_from_bytes(in_pl.ptr, in_pl.len);
out = modpow(in, rsa->exponent, rsa->modulus);
freebn(in);
toret = true;
bytes = (bignum_bitcount(rsa->modulus)+7) / 8;
/* Top (partial) byte should be zero. */
if (bignum_byte(out, bytes - 1) != 0)
toret = false;
/* First whole byte should be 1. */
if (bignum_byte(out, bytes - 2) != 1)
toret = false;
/* Most of the rest should be FF. */
for (i = bytes - 3; i >= 20 + ASN1_LEN; i--) {
if (bignum_byte(out, i) != 0xFF)
toret = false;
}
/* Then we expect to see the asn1_weird_stuff. */
for (i = 20 + ASN1_LEN - 1, j = 0; i >= 20; i--, j++) {
if (bignum_byte(out, i) != asn1_weird_stuff[j])
toret = false;
}
/* Finally, we expect to see the SHA-1 hash of the signed data. */
SHA_Simple(data.ptr, data.len, hash);
for (i = 19, j = 0; i >= 0; i--, j++) {
if (bignum_byte(out, i) != hash[j])
toret = false;
}
freebn(out);
return toret;
}
static void rsa2_sign(ssh_key *key, const void *data, int datalen,
BinarySink *bs)
{
struct RSAKey *rsa = container_of(key, struct RSAKey, sshk);
unsigned char *bytes;
int nbytes;
unsigned char hash[20];
Bignum in, out;
int i, j;
SHA_Simple(data, datalen, hash);
nbytes = (bignum_bitcount(rsa->modulus) - 1) / 8;
assert(1 <= nbytes - 20 - ASN1_LEN);
bytes = snewn(nbytes, unsigned char);
bytes[0] = 1;
for (i = 1; i < nbytes - 20 - ASN1_LEN; i++)
bytes[i] = 0xFF;
for (i = nbytes - 20 - ASN1_LEN, j = 0; i < nbytes - 20; i++, j++)
bytes[i] = asn1_weird_stuff[j];
for (i = nbytes - 20, j = 0; i < nbytes; i++, j++)
bytes[i] = hash[j];
in = bignum_from_bytes(bytes, nbytes);
sfree(bytes);
out = rsa_privkey_op(in, rsa);
freebn(in);
put_stringz(bs, "ssh-rsa");
nbytes = (bignum_bitcount(out) + 7) / 8;
put_uint32(bs, nbytes);
for (i = 0; i < nbytes; i++)
put_byte(bs, bignum_byte(out, nbytes - 1 - i));
freebn(out);
}
const ssh_keyalg ssh_rsa = {
rsa2_new_pub,
rsa2_new_priv,
rsa2_new_priv_openssh,
rsa2_freekey,
rsa2_sign,
rsa2_verify,
rsa2_public_blob,
rsa2_private_blob,
rsa2_openssh_blob,
rsa2_cache_str,
rsa2_pubkey_bits,
"ssh-rsa",
"rsa2",
NULL,
};
struct RSAKey *ssh_rsakex_newkey(const void *data, int len)
{
ssh_key *sshk = rsa2_new_pub(&ssh_rsa, make_ptrlen(data, len));
if (!sshk)
return NULL;
return container_of(sshk, struct RSAKey, sshk);
}
void ssh_rsakex_freekey(struct RSAKey *key)
{
rsa2_freekey(&key->sshk);
}
int ssh_rsakex_klen(struct RSAKey *rsa)
{
return bignum_bitcount(rsa->modulus);
}
static void oaep_mask(const struct ssh_hashalg *h, void *seed, int seedlen,
void *vdata, int datalen)
{
unsigned char *data = (unsigned char *)vdata;
unsigned count = 0;
while (datalen > 0) {
int i, max = (datalen > h->hlen ? h->hlen : datalen);
ssh_hash *s;
unsigned char hash[SSH2_KEX_MAX_HASH_LEN];
assert(h->hlen <= SSH2_KEX_MAX_HASH_LEN);
s = ssh_hash_new(h);
put_data(s, seed, seedlen);
put_uint32(s, count);
ssh_hash_final(s, hash);
count++;
for (i = 0; i < max; i++)
data[i] ^= hash[i];
data += max;
datalen -= max;
}
}
void ssh_rsakex_encrypt(const struct ssh_hashalg *h,
unsigned char *in, int inlen,
unsigned char *out, int outlen, struct RSAKey *rsa)
{
Bignum b1, b2;
int k, i;
char *p;
const int HLEN = h->hlen;
/*
* Here we encrypt using RSAES-OAEP. Essentially this means:
*
* - we have a SHA-based `mask generation function' which
* creates a pseudo-random stream of mask data
* deterministically from an input chunk of data.
*
* - we have a random chunk of data called a seed.
*
* - we use the seed to generate a mask which we XOR with our
* plaintext.
*
* - then we use _the masked plaintext_ to generate a mask
* which we XOR with the seed.
*
* - then we concatenate the masked seed and the masked
* plaintext, and RSA-encrypt that lot.
*
* The result is that the data input to the encryption function
* is random-looking and (hopefully) contains no exploitable
* structure such as PKCS1-v1_5 does.
*
* For a precise specification, see RFC 3447, section 7.1.1.
* Some of the variable names below are derived from that, so
* it'd probably help to read it anyway.
*/
/* k denotes the length in octets of the RSA modulus. */
k = (7 + bignum_bitcount(rsa->modulus)) / 8;
/* The length of the input data must be at most k - 2hLen - 2. */
assert(inlen > 0 && inlen <= k - 2*HLEN - 2);
/* The length of the output data wants to be precisely k. */
assert(outlen == k);
/*
* Now perform EME-OAEP encoding. First set up all the unmasked
* output data.
*/
/* Leading byte zero. */
out[0] = 0;
/* At position 1, the seed: HLEN bytes of random data. */
for (i = 0; i < HLEN; i++)
out[i + 1] = random_byte();
/* At position 1+HLEN, the data block DB, consisting of: */
/* The hash of the label (we only support an empty label here) */
{
ssh_hash *s = ssh_hash_new(h);
ssh_hash_final(s, out + HLEN + 1);
}
/* A bunch of zero octets */
memset(out + 2*HLEN + 1, 0, outlen - (2*HLEN + 1));
/* A single 1 octet, followed by the input message data. */
out[outlen - inlen - 1] = 1;
memcpy(out + outlen - inlen, in, inlen);
/*
* Now use the seed data to mask the block DB.
*/
oaep_mask(h, out+1, HLEN, out+HLEN+1, outlen-HLEN-1);
/*
* And now use the masked DB to mask the seed itself.
*/
oaep_mask(h, out+HLEN+1, outlen-HLEN-1, out+1, HLEN);
/*
* Now `out' contains precisely the data we want to
* RSA-encrypt.
*/
b1 = bignum_from_bytes(out, outlen);
b2 = modpow(b1, rsa->exponent, rsa->modulus);
p = (char *)out;
for (i = outlen; i--;) {
*p++ = bignum_byte(b2, i);
}
freebn(b1);
freebn(b2);
/*
* And we're done.
*/
}
Bignum ssh_rsakex_decrypt(const struct ssh_hashalg *h, ptrlen ciphertext,
struct RSAKey *rsa)
{
Bignum b1, b2;
int outlen, i;
unsigned char *out;
unsigned char labelhash[64];
ssh_hash *hash;
BinarySource src[1];
const int HLEN = h->hlen;
/*
* Decryption side of the RSA key exchange operation.
*/
/* The length of the encrypted data should be exactly the length
* in octets of the RSA modulus.. */
outlen = (7 + bignum_bitcount(rsa->modulus)) / 8;
if (ciphertext.len != outlen)
return NULL;
/* Do the RSA decryption, and extract the result into a byte array. */
b1 = bignum_from_bytes(ciphertext.ptr, ciphertext.len);
b2 = rsa_privkey_op(b1, rsa);
out = snewn(outlen, unsigned char);
for (i = 0; i < outlen; i++)
out[i] = bignum_byte(b2, outlen-1-i);
freebn(b1);
freebn(b2);
/* Do the OAEP masking operations, in the reverse order from encryption */
oaep_mask(h, out+HLEN+1, outlen-HLEN-1, out+1, HLEN);
oaep_mask(h, out+1, HLEN, out+HLEN+1, outlen-HLEN-1);
/* Check the leading byte is zero. */
if (out[0] != 0) {
sfree(out);
return NULL;
}
/* Check the label hash at position 1+HLEN */
assert(HLEN <= lenof(labelhash));
hash = ssh_hash_new(h);
ssh_hash_final(hash, labelhash);
if (memcmp(out + HLEN + 1, labelhash, HLEN)) {
sfree(out);
return NULL;
}
/* Expect zero bytes followed by a 1 byte */
for (i = 1 + 2 * HLEN; i < outlen; i++) {
if (out[i] == 1) {
i++; /* skip over the 1 byte */
break;
} else if (out[i] != 1) {
sfree(out);
return NULL;
}
}
/* And what's left is the input message data, which should be
* encoded as an ordinary SSH-2 mpint. */
BinarySource_BARE_INIT(src, out + i, outlen - i);
b1 = get_mp_ssh2(src);
sfree(out);
if (get_err(src) || get_avail(src) != 0) {
freebn(b1);
return NULL;
}
/* Success! */
return b1;
}
static const struct ssh_rsa_kex_extra ssh_rsa_kex_extra_sha1 = { 1024 };
static const struct ssh_rsa_kex_extra ssh_rsa_kex_extra_sha256 = { 2048 };
static const struct ssh_kex ssh_rsa_kex_sha1 = {
"rsa1024-sha1", NULL, KEXTYPE_RSA,
&ssh_sha1, &ssh_rsa_kex_extra_sha1,
};
static const struct ssh_kex ssh_rsa_kex_sha256 = {
"rsa2048-sha256", NULL, KEXTYPE_RSA,
&ssh_sha256, &ssh_rsa_kex_extra_sha256,
};
static const struct ssh_kex *const rsa_kex_list[] = {
&ssh_rsa_kex_sha256,
&ssh_rsa_kex_sha1
};
const struct ssh_kexes ssh_rsa_kex = {
sizeof(rsa_kex_list) / sizeof(*rsa_kex_list),
rsa_kex_list
};
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