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Introduce extra delay before closing unauthenticated sessions To make it harder for attackers, introduce a delay to keep an unauthenticated session open a bit longer, thus blocking a connection slot until after the delay. Without this, while there is a limit on the amount of attempts an attacker can make at the same time (MAX_UNAUTH_PER_IP), the time taken by dropbear to handle one attempt is still short and thus for each of the allowed parallel attempts many attempts can be chained one after the other. The attempt rate is then: "MAX_UNAUTH_PER_IP / <process time of one attempt>". With the delay, this rate becomes: "MAX_UNAUTH_PER_IP / UNAUTH_CLOSE_DELAY".
author Thomas De Schampheleire <thomas.de_schampheleire@nokia.com>
date Wed, 15 Feb 2017 13:53:04 +0100
parents 1051e4eea25a
children
line wrap: on
line source

#include "includes.h"
#include "ecc.h"
#include "dbutil.h"
#include "bignum.h"

#if DROPBEAR_ECC

/* .dp members are filled out by dropbear_ecc_fill_dp() at startup */
#if DROPBEAR_ECC_256
struct dropbear_ecc_curve ecc_curve_nistp256 = {
	32,		/* .ltc_size	*/
	NULL,		/* .dp		*/
	&sha256_desc,	/* .hash_desc	*/
	"nistp256"	/* .name	*/
};
#endif
#if DROPBEAR_ECC_384
struct dropbear_ecc_curve ecc_curve_nistp384 = {
	48,		/* .ltc_size	*/
	NULL,		/* .dp		*/
	&sha384_desc,	/* .hash_desc	*/
	"nistp384"	/* .name	*/
};
#endif
#if DROPBEAR_ECC_521
struct dropbear_ecc_curve ecc_curve_nistp521 = {
	66,		/* .ltc_size	*/
	NULL,		/* .dp		*/
	&sha512_desc,	/* .hash_desc	*/
	"nistp521"	/* .name	*/
};
#endif

struct dropbear_ecc_curve *dropbear_ecc_curves[] = {
#if DROPBEAR_ECC_256
	&ecc_curve_nistp256,
#endif
#if DROPBEAR_ECC_384
	&ecc_curve_nistp384,
#endif
#if DROPBEAR_ECC_521
	&ecc_curve_nistp521,
#endif
	NULL
};

void dropbear_ecc_fill_dp() {
	struct dropbear_ecc_curve **curve;
	/* libtomcrypt guarantees they're ordered by size */
	const ltc_ecc_set_type *dp = ltc_ecc_sets;
	for (curve = dropbear_ecc_curves; *curve; curve++) {
		for (;dp->size > 0; dp++) {
			if (dp->size == (*curve)->ltc_size) {
				(*curve)->dp = dp;
				break;
			}
		}
		if (!(*curve)->dp) {
			dropbear_exit("Missing ECC params %s", (*curve)->name);
		}
	}
}

struct dropbear_ecc_curve* curve_for_dp(const ltc_ecc_set_type *dp) {
	struct dropbear_ecc_curve **curve = NULL;
	for (curve = dropbear_ecc_curves; *curve; curve++) {
		if ((*curve)->dp == dp) {
			break;
		}
	}
	assert(*curve);
	return *curve;
}

ecc_key * new_ecc_key(void) {
	ecc_key *key = m_malloc(sizeof(*key));
	m_mp_alloc_init_multi((mp_int**)&key->pubkey.x, (mp_int**)&key->pubkey.y, 
		(mp_int**)&key->pubkey.z, (mp_int**)&key->k, NULL);
	return key;
}

/* Copied from libtomcrypt ecc_import.c (version there is static), modified
   for different mp_int pointer without LTC_SOURCE */
static int ecc_is_point(const ecc_key *key)
{
	mp_int *prime, *b, *t1, *t2;
	int err;
	
	m_mp_alloc_init_multi(&prime, &b, &t1, &t2, NULL);
	
   /* load prime and b */
	if ((err = mp_read_radix(prime, key->dp->prime, 16)) != CRYPT_OK)                          { goto error; }
	if ((err = mp_read_radix(b, key->dp->B, 16)) != CRYPT_OK)                                  { goto error; }
	
   /* compute y^2 */
	if ((err = mp_sqr(key->pubkey.y, t1)) != CRYPT_OK)                                         { goto error; }
	
   /* compute x^3 */
	if ((err = mp_sqr(key->pubkey.x, t2)) != CRYPT_OK)                                         { goto error; }
	if ((err = mp_mod(t2, prime, t2)) != CRYPT_OK)                                             { goto error; }
	if ((err = mp_mul(key->pubkey.x, t2, t2)) != CRYPT_OK)                                     { goto error; }
	
   /* compute y^2 - x^3 */
	if ((err = mp_sub(t1, t2, t1)) != CRYPT_OK)                                                { goto error; }
	
   /* compute y^2 - x^3 + 3x */
	if ((err = mp_add(t1, key->pubkey.x, t1)) != CRYPT_OK)                                     { goto error; }
	if ((err = mp_add(t1, key->pubkey.x, t1)) != CRYPT_OK)                                     { goto error; }
	if ((err = mp_add(t1, key->pubkey.x, t1)) != CRYPT_OK)                                     { goto error; }
	if ((err = mp_mod(t1, prime, t1)) != CRYPT_OK)                                             { goto error; }
	while (mp_cmp_d(t1, 0) == LTC_MP_LT) {
		if ((err = mp_add(t1, prime, t1)) != CRYPT_OK)                                          { goto error; }
	}
	while (mp_cmp(t1, prime) != LTC_MP_LT) {
		if ((err = mp_sub(t1, prime, t1)) != CRYPT_OK)                                          { goto error; }
	}
	
   /* compare to b */
	if (mp_cmp(t1, b) != LTC_MP_EQ) {
		err = CRYPT_INVALID_PACKET;
	} else {
		err = CRYPT_OK;
	}
	
	error:
	mp_clear_multi(prime, b, t1, t2, NULL);
	m_free(prime);
	m_free(b);
	m_free(t1);
	m_free(t2);
	return err;
}

/* For the "ephemeral public key octet string" in ECDH (rfc5656 section 4) */
void buf_put_ecc_raw_pubkey_string(buffer *buf, ecc_key *key) {
	unsigned long len = key->dp->size*2 + 1;
	int err;
	buf_putint(buf, len);
	err = ecc_ansi_x963_export(key, buf_getwriteptr(buf, len), &len);
	if (err != CRYPT_OK) {
		dropbear_exit("ECC error");
	}
	buf_incrwritepos(buf, len);
}

/* For the "ephemeral public key octet string" in ECDH (rfc5656 section 4) */
ecc_key * buf_get_ecc_raw_pubkey(buffer *buf, const struct dropbear_ecc_curve *curve) {
	ecc_key *key = NULL;
	int ret = DROPBEAR_FAILURE;
	const unsigned int size = curve->dp->size;
	unsigned char first;

	TRACE(("enter buf_get_ecc_raw_pubkey"))

	buf_setpos(buf, 0);
	first = buf_getbyte(buf);
	if (first == 2 || first == 3) {
		dropbear_log(LOG_WARNING, "Dropbear doesn't support ECC point compression");
		return NULL;
	}
	if (first != 4 || buf->len != 1+2*size) {
		TRACE(("leave, wrong size"))
		return NULL;
	}

	key = new_ecc_key();
	key->dp = curve->dp;

	if (mp_from_ubin(key->pubkey.x, buf_getptr(buf, size), size) != MP_OKAY) {
		TRACE(("failed to read x"))
		goto out;
	}
	buf_incrpos(buf, size);

	if (mp_from_ubin(key->pubkey.y, buf_getptr(buf, size), size) != MP_OKAY) {
		TRACE(("failed to read y"))
		goto out;
	}
	buf_incrpos(buf, size);

	mp_set(key->pubkey.z, 1);

	if (ecc_is_point(key) != CRYPT_OK) {
		TRACE(("failed, not a point"))
		goto out;
	}

   /* SEC1 3.2.3.1 Check that Q != 0 */
	if (mp_cmp_d(key->pubkey.x, 0) == LTC_MP_EQ) {
		TRACE(("failed, x == 0"))
		goto out;
	}
	if (mp_cmp_d(key->pubkey.y, 0) == LTC_MP_EQ) {
		TRACE(("failed, y == 0"))
		goto out;
	}

	ret = DROPBEAR_SUCCESS;

	out:
	if (ret == DROPBEAR_FAILURE) {
		if (key) {
			ecc_free(key);
			m_free(key);
			key = NULL;
		}
	}

	return key;

}

/* a modified version of libtomcrypt's "ecc_shared_secret" to output
   a mp_int instead. */
mp_int * dropbear_ecc_shared_secret(ecc_key *public_key, const ecc_key *private_key)
{
	ecc_point *result = NULL;
	mp_int *prime = NULL, *shared_secret = NULL;
	int err = DROPBEAR_FAILURE;

   /* type valid? */
	if (private_key->type != PK_PRIVATE) {
		goto out;
	}

	if (private_key->dp != public_key->dp) {
		goto out;
	}

   /* make new point */
	result = ltc_ecc_new_point();
	if (result == NULL) {
		goto out;
	}

	prime = m_malloc(sizeof(*prime));
	m_mp_init(prime);

	if (mp_read_radix(prime, (char *)private_key->dp->prime, 16) != CRYPT_OK) { 
		goto out;
	}
	if (ltc_mp.ecc_ptmul(private_key->k, &public_key->pubkey, result, prime, 1) != CRYPT_OK) { 
		goto out;
	}

	shared_secret = m_malloc(sizeof(*shared_secret));
	m_mp_init(shared_secret);
	if (mp_copy(result->x, shared_secret) != CRYPT_OK) {
		goto out;
	}

	mp_clear(prime);
	m_free(prime);
	ltc_ecc_del_point(result);

	err = DROPBEAR_SUCCESS;
	out:
	if (err == DROPBEAR_FAILURE) {
		dropbear_exit("ECC error");
	}
	return shared_secret;
}

#endif