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FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/crypto/openssh/jpake.c |
/* $OpenBSD: jpake.c,v 1.6 2010/09/20 04:54:07 djm Exp $ */ /* * Copyright (c) 2008 Damien Miller. All rights reserved. * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ /* * Shared components of zero-knowledge password auth using J-PAKE protocol * as described in: * * F. Hao, P. Ryan, "Password Authenticated Key Exchange by Juggling", * 16th Workshop on Security Protocols, Cambridge, April 2008 * * http://grouper.ieee.org/groups/1363/Research/contributions/hao-ryan-2008.pdf */ #include "includes.h" #include <sys/types.h> #include <stdio.h> #include <string.h> #include <stdarg.h> #include <openssl/bn.h> #include <openssl/evp.h> #include "xmalloc.h" #include "ssh2.h" #include "key.h" #include "hostfile.h" #include "auth.h" #include "buffer.h" #include "packet.h" #include "dispatch.h" #include "log.h" #include "misc.h" #include "jpake.h" #include "schnorr.h" #ifdef JPAKE /* RFC3526 group 5, 1536 bits */ #define JPAKE_GROUP_G "2" #define JPAKE_GROUP_P \ "FFFFFFFFFFFFFFFFC90FDAA22168C234C4C6628B80DC1CD129024E088A67CC74" \ "020BBEA63B139B22514A08798E3404DDEF9519B3CD3A431B302B0A6DF25F1437" \ "4FE1356D6D51C245E485B576625E7EC6F44C42E9A637ED6B0BFF5CB6F406B7ED" \ "EE386BFB5A899FA5AE9F24117C4B1FE649286651ECE45B3DC2007CB8A163BF05" \ "98DA48361C55D39A69163FA8FD24CF5F83655D23DCA3AD961C62F356208552BB" \ "9ED529077096966D670C354E4ABC9804F1746C08CA237327FFFFFFFFFFFFFFFF" struct modp_group * jpake_default_group(void) { return modp_group_from_g_and_safe_p(JPAKE_GROUP_G, JPAKE_GROUP_P); } struct jpake_ctx * jpake_new(void) { struct jpake_ctx *ret; ret = xcalloc(1, sizeof(*ret)); ret->grp = jpake_default_group(); ret->s = ret->k = NULL; ret->x1 = ret->x2 = ret->x3 = ret->x4 = NULL; ret->g_x1 = ret->g_x2 = ret->g_x3 = ret->g_x4 = NULL; ret->a = ret->b = NULL; ret->client_id = ret->server_id = NULL; ret->h_k_cid_sessid = ret->h_k_sid_sessid = NULL; debug3("%s: alloc %p", __func__, ret); return ret; } void jpake_free(struct jpake_ctx *pctx) { debug3("%s: free %p", __func__, pctx); #define JPAKE_BN_CLEAR_FREE(v) \ do { \ if ((v) != NULL) { \ BN_clear_free(v); \ (v) = NULL; \ } \ } while (0) #define JPAKE_BUF_CLEAR_FREE(v, l) \ do { \ if ((v) != NULL) { \ bzero((v), (l)); \ xfree(v); \ (v) = NULL; \ (l) = 0; \ } \ } while (0) JPAKE_BN_CLEAR_FREE(pctx->s); JPAKE_BN_CLEAR_FREE(pctx->k); JPAKE_BN_CLEAR_FREE(pctx->x1); JPAKE_BN_CLEAR_FREE(pctx->x2); JPAKE_BN_CLEAR_FREE(pctx->x3); JPAKE_BN_CLEAR_FREE(pctx->x4); JPAKE_BN_CLEAR_FREE(pctx->g_x1); JPAKE_BN_CLEAR_FREE(pctx->g_x2); JPAKE_BN_CLEAR_FREE(pctx->g_x3); JPAKE_BN_CLEAR_FREE(pctx->g_x4); JPAKE_BN_CLEAR_FREE(pctx->a); JPAKE_BN_CLEAR_FREE(pctx->b); JPAKE_BUF_CLEAR_FREE(pctx->client_id, pctx->client_id_len); JPAKE_BUF_CLEAR_FREE(pctx->server_id, pctx->server_id_len); JPAKE_BUF_CLEAR_FREE(pctx->h_k_cid_sessid, pctx->h_k_cid_sessid_len); JPAKE_BUF_CLEAR_FREE(pctx->h_k_sid_sessid, pctx->h_k_sid_sessid_len); #undef JPAKE_BN_CLEAR_FREE #undef JPAKE_BUF_CLEAR_FREE bzero(pctx, sizeof(pctx)); xfree(pctx); } /* dump entire jpake_ctx. NB. includes private values! */ void jpake_dump(struct jpake_ctx *pctx, const char *fmt, ...) { char *out; va_list args; out = NULL; va_start(args, fmt); vasprintf(&out, fmt, args); va_end(args); if (out == NULL) fatal("%s: vasprintf failed", __func__); debug3("%s: %s (ctx at %p)", __func__, out, pctx); if (pctx == NULL) { free(out); return; } #define JPAKE_DUMP_BN(a) do { \ if ((a) != NULL) \ JPAKE_DEBUG_BN(((a), "%s = ", #a)); \ } while (0) #define JPAKE_DUMP_BUF(a, b) do { \ if ((a) != NULL) \ JPAKE_DEBUG_BUF((a, b, "%s", #a)); \ } while (0) JPAKE_DUMP_BN(pctx->s); JPAKE_DUMP_BN(pctx->k); JPAKE_DUMP_BN(pctx->x1); JPAKE_DUMP_BN(pctx->x2); JPAKE_DUMP_BN(pctx->x3); JPAKE_DUMP_BN(pctx->x4); JPAKE_DUMP_BN(pctx->g_x1); JPAKE_DUMP_BN(pctx->g_x2); JPAKE_DUMP_BN(pctx->g_x3); JPAKE_DUMP_BN(pctx->g_x4); JPAKE_DUMP_BN(pctx->a); JPAKE_DUMP_BN(pctx->b); JPAKE_DUMP_BUF(pctx->client_id, pctx->client_id_len); JPAKE_DUMP_BUF(pctx->server_id, pctx->server_id_len); JPAKE_DUMP_BUF(pctx->h_k_cid_sessid, pctx->h_k_cid_sessid_len); JPAKE_DUMP_BUF(pctx->h_k_sid_sessid, pctx->h_k_sid_sessid_len); debug3("%s: %s done", __func__, out); free(out); } /* Shared parts of step 1 exchange calculation */ void jpake_step1(struct modp_group *grp, u_char **id, u_int *id_len, BIGNUM **priv1, BIGNUM **priv2, BIGNUM **g_priv1, BIGNUM **g_priv2, u_char **priv1_proof, u_int *priv1_proof_len, u_char **priv2_proof, u_int *priv2_proof_len) { BN_CTX *bn_ctx; if ((bn_ctx = BN_CTX_new()) == NULL) fatal("%s: BN_CTX_new", __func__); /* Random nonce to prevent replay */ *id = xmalloc(KZP_ID_LEN); *id_len = KZP_ID_LEN; arc4random_buf(*id, *id_len); /* * x1/x3 is a random element of Zq * x2/x4 is a random element of Z*q * We also exclude [1] from x1/x3 candidates and [0, 1] from * x2/x4 candiates to avoid possible degeneracy (i.e. g^0, g^1). */ if ((*priv1 = bn_rand_range_gt_one(grp->q)) == NULL || (*priv2 = bn_rand_range_gt_one(grp->q)) == NULL) fatal("%s: bn_rand_range_gt_one", __func__); /* * client: g_x1 = g^x1 mod p / server: g_x3 = g^x3 mod p * client: g_x2 = g^x2 mod p / server: g_x4 = g^x4 mod p */ if ((*g_priv1 = BN_new()) == NULL || (*g_priv2 = BN_new()) == NULL) fatal("%s: BN_new", __func__); if (BN_mod_exp(*g_priv1, grp->g, *priv1, grp->p, bn_ctx) == -1) fatal("%s: BN_mod_exp", __func__); if (BN_mod_exp(*g_priv2, grp->g, *priv2, grp->p, bn_ctx) == -1) fatal("%s: BN_mod_exp", __func__); /* Generate proofs for holding x1/x3 and x2/x4 */ if (schnorr_sign_buf(grp->p, grp->q, grp->g, *priv1, *g_priv1, *id, *id_len, priv1_proof, priv1_proof_len) != 0) fatal("%s: schnorr_sign", __func__); if (schnorr_sign_buf(grp->p, grp->q, grp->g, *priv2, *g_priv2, *id, *id_len, priv2_proof, priv2_proof_len) != 0) fatal("%s: schnorr_sign", __func__); BN_CTX_free(bn_ctx); } /* Shared parts of step 2 exchange calculation */ void jpake_step2(struct modp_group *grp, BIGNUM *s, BIGNUM *mypub1, BIGNUM *theirpub1, BIGNUM *theirpub2, BIGNUM *mypriv2, const u_char *theirid, u_int theirid_len, const u_char *myid, u_int myid_len, const u_char *theirpub1_proof, u_int theirpub1_proof_len, const u_char *theirpub2_proof, u_int theirpub2_proof_len, BIGNUM **newpub, u_char **newpub_exponent_proof, u_int *newpub_exponent_proof_len) { BN_CTX *bn_ctx; BIGNUM *tmp, *exponent; /* Validate peer's step 1 values */ if (BN_cmp(theirpub1, BN_value_one()) <= 0) fatal("%s: theirpub1 <= 1", __func__); if (BN_cmp(theirpub1, grp->p) >= 0) fatal("%s: theirpub1 >= p", __func__); if (BN_cmp(theirpub2, BN_value_one()) <= 0) fatal("%s: theirpub2 <= 1", __func__); if (BN_cmp(theirpub2, grp->p) >= 0) fatal("%s: theirpub2 >= p", __func__); if (schnorr_verify_buf(grp->p, grp->q, grp->g, theirpub1, theirid, theirid_len, theirpub1_proof, theirpub1_proof_len) != 1) fatal("%s: schnorr_verify theirpub1 failed", __func__); if (schnorr_verify_buf(grp->p, grp->q, grp->g, theirpub2, theirid, theirid_len, theirpub2_proof, theirpub2_proof_len) != 1) fatal("%s: schnorr_verify theirpub2 failed", __func__); if ((bn_ctx = BN_CTX_new()) == NULL) fatal("%s: BN_CTX_new", __func__); if ((*newpub = BN_new()) == NULL || (tmp = BN_new()) == NULL || (exponent = BN_new()) == NULL) fatal("%s: BN_new", __func__); /* * client: exponent = x2 * s mod p * server: exponent = x4 * s mod p */ if (BN_mod_mul(exponent, mypriv2, s, grp->q, bn_ctx) != 1) fatal("%s: BN_mod_mul (exponent = mypriv2 * s mod p)", __func__); /* * client: tmp = g^(x1 + x3 + x4) mod p * server: tmp = g^(x1 + x2 + x3) mod p */ if (BN_mod_mul(tmp, mypub1, theirpub1, grp->p, bn_ctx) != 1) fatal("%s: BN_mod_mul (tmp = mypub1 * theirpub1 mod p)", __func__); if (BN_mod_mul(tmp, tmp, theirpub2, grp->p, bn_ctx) != 1) fatal("%s: BN_mod_mul (tmp = tmp * theirpub2 mod p)", __func__); /* * client: a = tmp^exponent = g^((x1+x3+x4) * x2 * s) mod p * server: b = tmp^exponent = g^((x1+x2+x3) * x4 * s) mod p */ if (BN_mod_exp(*newpub, tmp, exponent, grp->p, bn_ctx) != 1) fatal("%s: BN_mod_mul (newpub = tmp^exponent mod p)", __func__); JPAKE_DEBUG_BN((tmp, "%s: tmp = ", __func__)); JPAKE_DEBUG_BN((exponent, "%s: exponent = ", __func__)); /* Note the generator here is 'tmp', not g */ if (schnorr_sign_buf(grp->p, grp->q, tmp, exponent, *newpub, myid, myid_len, newpub_exponent_proof, newpub_exponent_proof_len) != 0) fatal("%s: schnorr_sign newpub", __func__); BN_clear_free(tmp); /* XXX stash for later use? */ BN_clear_free(exponent); /* XXX stash for later use? (yes, in conf) */ BN_CTX_free(bn_ctx); } /* Confirmation hash calculation */ void jpake_confirm_hash(const BIGNUM *k, const u_char *endpoint_id, u_int endpoint_id_len, const u_char *sess_id, u_int sess_id_len, u_char **confirm_hash, u_int *confirm_hash_len) { Buffer b; /* * Calculate confirmation proof: * client: H(k || client_id || session_id) * server: H(k || server_id || session_id) */ buffer_init(&b); buffer_put_bignum2(&b, k); buffer_put_string(&b, endpoint_id, endpoint_id_len); buffer_put_string(&b, sess_id, sess_id_len); if (hash_buffer(buffer_ptr(&b), buffer_len(&b), EVP_sha256(), confirm_hash, confirm_hash_len) != 0) fatal("%s: hash_buffer", __func__); buffer_free(&b); } /* Shared parts of key derivation and confirmation calculation */ void jpake_key_confirm(struct modp_group *grp, BIGNUM *s, BIGNUM *step2_val, BIGNUM *mypriv2, BIGNUM *mypub1, BIGNUM *mypub2, BIGNUM *theirpub1, BIGNUM *theirpub2, const u_char *my_id, u_int my_id_len, const u_char *their_id, u_int their_id_len, const u_char *sess_id, u_int sess_id_len, const u_char *theirpriv2_s_proof, u_int theirpriv2_s_proof_len, BIGNUM **k, u_char **confirm_hash, u_int *confirm_hash_len) { BN_CTX *bn_ctx; BIGNUM *tmp; if ((bn_ctx = BN_CTX_new()) == NULL) fatal("%s: BN_CTX_new", __func__); if ((tmp = BN_new()) == NULL || (*k = BN_new()) == NULL) fatal("%s: BN_new", __func__); /* Validate step 2 values */ if (BN_cmp(step2_val, BN_value_one()) <= 0) fatal("%s: step2_val <= 1", __func__); if (BN_cmp(step2_val, grp->p) >= 0) fatal("%s: step2_val >= p", __func__); /* * theirpriv2_s_proof is calculated with a different generator: * tmp = g^(mypriv1+mypriv2+theirpub1) = g^mypub1*g^mypub2*g^theirpub1 * Calculate it here so we can check the signature. */ if (BN_mod_mul(tmp, mypub1, mypub2, grp->p, bn_ctx) != 1) fatal("%s: BN_mod_mul (tmp = mypub1 * mypub2 mod p)", __func__); if (BN_mod_mul(tmp, tmp, theirpub1, grp->p, bn_ctx) != 1) fatal("%s: BN_mod_mul (tmp = tmp * theirpub1 mod p)", __func__); JPAKE_DEBUG_BN((tmp, "%s: tmp = ", __func__)); if (schnorr_verify_buf(grp->p, grp->q, tmp, step2_val, their_id, their_id_len, theirpriv2_s_proof, theirpriv2_s_proof_len) != 1) fatal("%s: schnorr_verify theirpriv2_s_proof failed", __func__); /* * Derive shared key: * client: k = (b / g^(x2*x4*s))^x2 = g^((x1+x3)*x2*x4*s) * server: k = (a / g^(x2*x4*s))^x4 = g^((x1+x3)*x2*x4*s) * * Computed as: * client: k = (g_x4^(q - (x2 * s)) * b)^x2 mod p * server: k = (g_x2^(q - (x4 * s)) * b)^x4 mod p */ if (BN_mul(tmp, mypriv2, s, bn_ctx) != 1) fatal("%s: BN_mul (tmp = mypriv2 * s)", __func__); if (BN_mod_sub(tmp, grp->q, tmp, grp->q, bn_ctx) != 1) fatal("%s: BN_mod_sub (tmp = q - tmp mod q)", __func__); if (BN_mod_exp(tmp, theirpub2, tmp, grp->p, bn_ctx) != 1) fatal("%s: BN_mod_exp (tmp = theirpub2^tmp) mod p", __func__); if (BN_mod_mul(tmp, tmp, step2_val, grp->p, bn_ctx) != 1) fatal("%s: BN_mod_mul (tmp = tmp * step2_val) mod p", __func__); if (BN_mod_exp(*k, tmp, mypriv2, grp->p, bn_ctx) != 1) fatal("%s: BN_mod_exp (k = tmp^mypriv2) mod p", __func__); BN_CTX_free(bn_ctx); BN_clear_free(tmp); jpake_confirm_hash(*k, my_id, my_id_len, sess_id, sess_id_len, confirm_hash, confirm_hash_len); } /* * Calculate and check confirmation hash from peer. Returns 1 on success * 0 on failure/mismatch. */ int jpake_check_confirm(const BIGNUM *k, const u_char *peer_id, u_int peer_id_len, const u_char *sess_id, u_int sess_id_len, const u_char *peer_confirm_hash, u_int peer_confirm_hash_len) { u_char *expected_confirm_hash; u_int expected_confirm_hash_len; int success = 0; /* Calculate and verify expected confirmation hash */ jpake_confirm_hash(k, peer_id, peer_id_len, sess_id, sess_id_len, &expected_confirm_hash, &expected_confirm_hash_len); JPAKE_DEBUG_BUF((expected_confirm_hash, expected_confirm_hash_len, "%s: expected confirm hash", __func__)); JPAKE_DEBUG_BUF((peer_confirm_hash, peer_confirm_hash_len, "%s: received confirm hash", __func__)); if (peer_confirm_hash_len != expected_confirm_hash_len) error("%s: confirmation length mismatch (my %u them %u)", __func__, expected_confirm_hash_len, peer_confirm_hash_len); else if (timingsafe_bcmp(peer_confirm_hash, expected_confirm_hash, expected_confirm_hash_len) == 0) success = 1; bzero(expected_confirm_hash, expected_confirm_hash_len); xfree(expected_confirm_hash); debug3("%s: success = %d", __func__, success); return success; } /* XXX main() function with tests */ #endif /* JPAKE */