/* Copyright (c) 2012, The Tor Project, Inc. */
/* See LICENSE for licensing information */
#include "orconfig.h"
#include "crypto.h"
#define ONION_NTOR_PRIVATE
#include "onion_ntor.h"
#include "torlog.h"
#include "util.h"
/** Free storage held in an ntor handshake state. */
void
ntor_handshake_state_free(ntor_handshake_state_t *state)
{
if (!state)
return;
memwipe(state, 0, sizeof(*state));
tor_free(state);
}
/** Convenience function to represent HMAC_SHA256 as our instantiation of
* ntor's "tweaked hash'. Hash the inp_len bytes at inp into
* a DIGEST256_LEN-byte digest at out, with the hash changing
* depending on the value of tweak. */
static void
h_tweak(uint8_t *out,
const uint8_t *inp, size_t inp_len,
const char *tweak)
{
size_t tweak_len = strlen(tweak);
crypto_hmac_sha256((char*)out, tweak, tweak_len, (const char*)inp, inp_len);
}
/** Wrapper around a set of tweak-values for use with the ntor handshake. */
typedef struct tweakset_t {
const char *t_mac;
const char *t_key;
const char *t_verify;
const char *m_expand;
} tweakset_t;
/** The tweaks to be used with our handshake. */
const tweakset_t proto1_tweaks = {
#define PROTOID "ntor-curve25519-sha256-1"
#define PROTOID_LEN 24
PROTOID ":mac",
PROTOID ":key_extract",
PROTOID ":verify",
PROTOID ":key_expand"
};
/** Convenience macro: copy len bytes from inp to ptr,
* and advance ptr by the number of bytes copied. */
#define APPEND(ptr, inp, len) \
STMT_BEGIN { \
memcpy(ptr, (inp), (len)); \
ptr += len; \
} STMT_END
/**
* Compute the first client-side step of the ntor handshake for communicating
* with a server whose DIGEST_LEN-byte server identity is router_id,
* and whose onion key is router_key. Store the NTOR_ONIONSKIN_LEN-byte
* message in onion_skin_out, and store the handshake state in
* *handshake_state_out. Return 0 on success, -1 on failure.
*/
int
onion_skin_ntor_create(const uint8_t *router_id,
const curve25519_public_key_t *router_key,
ntor_handshake_state_t **handshake_state_out,
uint8_t *onion_skin_out)
{
ntor_handshake_state_t *state;
uint8_t *op;
state = tor_malloc_zero(sizeof(ntor_handshake_state_t));
memcpy(state->router_id, router_id, DIGEST_LEN);
memcpy(&state->pubkey_B, router_key, sizeof(curve25519_public_key_t));
if (curve25519_secret_key_generate(&state->seckey_x, 0) < 0) {
tor_free(state);
return -1;
}
curve25519_public_key_generate(&state->pubkey_X, &state->seckey_x);
op = onion_skin_out;
APPEND(op, router_id, DIGEST_LEN);
APPEND(op, router_key->public_key, CURVE25519_PUBKEY_LEN);
APPEND(op, state->pubkey_X.public_key, CURVE25519_PUBKEY_LEN);
tor_assert(op == onion_skin_out + NTOR_ONIONSKIN_LEN);
*handshake_state_out = state;
return 0;
}
#define SERVER_STR "Server"
#define SERVER_STR_LEN 6
#define SECRET_INPUT_LEN (CURVE25519_PUBKEY_LEN * 3 + \
CURVE25519_OUTPUT_LEN * 2 + \
DIGEST_LEN + PROTOID_LEN)
#define AUTH_INPUT_LEN (DIGEST256_LEN + DIGEST_LEN + \
CURVE25519_PUBKEY_LEN*3 + \
PROTOID_LEN + SERVER_STR_LEN)
/**
* Perform the server side of an ntor handshake. Given an
* NTOR_ONIONSKIN_LEN-byte message in onion_skin, our own identity
* fingerprint as my_node_id, and an associative array mapping public
* onion keys to curve25519_keypair_t in private_keys, attempt to
* perform the handshake. Use junk_keys if present if the handshake
* indicates an unrecognized public key. Write an NTOR_REPLY_LEN-byte
* message to send back to the client into handshake_reply_out, and
* generate key_out_len bytes of key material in key_out. Return
* 0 on success, -1 on failure.
*/
int
onion_skin_ntor_server_handshake(const uint8_t *onion_skin,
const di_digest256_map_t *private_keys,
const curve25519_keypair_t *junk_keys,
const uint8_t *my_node_id,
uint8_t *handshake_reply_out,
uint8_t *key_out,
size_t key_out_len)
{
const tweakset_t *T = &proto1_tweaks;
/* Sensitive stack-allocated material. Kept in an anonymous struct to make
* it easy to wipe. */
struct {
uint8_t secret_input[SECRET_INPUT_LEN];
uint8_t auth_input[AUTH_INPUT_LEN];
curve25519_public_key_t pubkey_X;
curve25519_secret_key_t seckey_y;
curve25519_public_key_t pubkey_Y;
uint8_t verify[DIGEST256_LEN];
} s;
uint8_t *si = s.secret_input, *ai = s.auth_input;
const curve25519_keypair_t *keypair_bB;
int bad;
/* Decode the onion skin */
/* XXXX Does this possible early-return business threaten our security? */
if (tor_memneq(onion_skin, my_node_id, DIGEST_LEN))
return -1;
/* Note that on key-not-found, we go through with this operation anyway,
* using "junk_keys". This will result in failed authentication, but won't
* leak whether we recognized the key. */
keypair_bB = dimap_search(private_keys, onion_skin + DIGEST_LEN,
(void*)junk_keys);
if (!keypair_bB)
return -1;
memcpy(s.pubkey_X.public_key, onion_skin+DIGEST_LEN+DIGEST256_LEN,
CURVE25519_PUBKEY_LEN);
/* Make y, Y */
curve25519_secret_key_generate(&s.seckey_y, 0);
curve25519_public_key_generate(&s.pubkey_Y, &s.seckey_y);
/* NOTE: If we ever use a group other than curve25519, or a different
* representation for its points, we may need to perform different or
* additional checks on X here and on Y in the client handshake, or lose our
* security properties. What checks we need would depend on the properties
* of the group and its representation.
*
* In short: if you use anything other than curve25519, this aspect of the
* code will need to be reconsidered carefully. */
/* build secret_input */
curve25519_handshake(si, &s.seckey_y, &s.pubkey_X);
bad = safe_mem_is_zero(si, CURVE25519_OUTPUT_LEN);
si += CURVE25519_OUTPUT_LEN;
curve25519_handshake(si, &keypair_bB->seckey, &s.pubkey_X);
bad |= safe_mem_is_zero(si, CURVE25519_OUTPUT_LEN);
si += CURVE25519_OUTPUT_LEN;
APPEND(si, my_node_id, DIGEST_LEN);
APPEND(si, keypair_bB->pubkey.public_key, CURVE25519_PUBKEY_LEN);
APPEND(si, s.pubkey_X.public_key, CURVE25519_PUBKEY_LEN);
APPEND(si, s.pubkey_Y.public_key, CURVE25519_PUBKEY_LEN);
APPEND(si, PROTOID, PROTOID_LEN);
tor_assert(si == s.secret_input + sizeof(s.secret_input));
/* Compute hashes of secret_input */
h_tweak(s.verify, s.secret_input, sizeof(s.secret_input), T->t_verify);
/* Compute auth_input */
APPEND(ai, s.verify, DIGEST256_LEN);
APPEND(ai, my_node_id, DIGEST_LEN);
APPEND(ai, keypair_bB->pubkey.public_key, CURVE25519_PUBKEY_LEN);
APPEND(ai, s.pubkey_Y.public_key, CURVE25519_PUBKEY_LEN);
APPEND(ai, s.pubkey_X.public_key, CURVE25519_PUBKEY_LEN);
APPEND(ai, PROTOID, PROTOID_LEN);
APPEND(ai, SERVER_STR, SERVER_STR_LEN);
tor_assert(ai == s.auth_input + sizeof(s.auth_input));
/* Build the reply */
memcpy(handshake_reply_out, s.pubkey_Y.public_key, CURVE25519_PUBKEY_LEN);
h_tweak(handshake_reply_out+CURVE25519_PUBKEY_LEN,
s.auth_input, sizeof(s.auth_input),
T->t_mac);
/* Generate the key material */
crypto_expand_key_material_rfc5869_sha256(
s.secret_input, sizeof(s.secret_input),
(const uint8_t*)T->t_key, strlen(T->t_key),
(const uint8_t*)T->m_expand, strlen(T->m_expand),
key_out, key_out_len);
/* Wipe all of our local state */
memwipe(&s, 0, sizeof(s));
return bad ? -1 : 0;
}
/**
* Perform the final client side of the ntor handshake, using the state in
* handshake_state and the server's NTOR_REPLY_LEN-byte reply in
* handshake_reply. Generate key_out_len bytes of key material
* in key_out. Return 0 on success, -1 on failure.
*/
int
onion_skin_ntor_client_handshake(
const ntor_handshake_state_t *handshake_state,
const uint8_t *handshake_reply,
uint8_t *key_out,
size_t key_out_len)
{
const tweakset_t *T = &proto1_tweaks;
/* Sensitive stack-allocated material. Kept in an anonymous struct to make
* it easy to wipe. */
struct {
curve25519_public_key_t pubkey_Y;
uint8_t secret_input[SECRET_INPUT_LEN];
uint8_t verify[DIGEST256_LEN];
uint8_t auth_input[AUTH_INPUT_LEN];
uint8_t auth[DIGEST256_LEN];
} s;
uint8_t *ai = s.auth_input, *si = s.secret_input;
const uint8_t *auth_candidate;
int bad;
/* Decode input */
memcpy(s.pubkey_Y.public_key, handshake_reply, CURVE25519_PUBKEY_LEN);
auth_candidate = handshake_reply + CURVE25519_PUBKEY_LEN;
/* See note in server_handshake above about checking points. The
* circumstances under which we'd need to check Y for membership are
* different than those under which we'd be checking X. */
/* Compute secret_input */
curve25519_handshake(si, &handshake_state->seckey_x, &s.pubkey_Y);
bad = safe_mem_is_zero(si, CURVE25519_OUTPUT_LEN);
si += CURVE25519_OUTPUT_LEN;
curve25519_handshake(si, &handshake_state->seckey_x,
&handshake_state->pubkey_B);
bad |= safe_mem_is_zero(si, CURVE25519_OUTPUT_LEN);
si += CURVE25519_OUTPUT_LEN;
APPEND(si, handshake_state->router_id, DIGEST_LEN);
APPEND(si, handshake_state->pubkey_B.public_key, CURVE25519_PUBKEY_LEN);
APPEND(si, handshake_state->pubkey_X.public_key, CURVE25519_PUBKEY_LEN);
APPEND(si, s.pubkey_Y.public_key, CURVE25519_PUBKEY_LEN);
APPEND(si, PROTOID, PROTOID_LEN);
tor_assert(si == s.secret_input + sizeof(s.secret_input));
/* Compute verify from secret_input */
h_tweak(s.verify, s.secret_input, sizeof(s.secret_input), T->t_verify);
/* Compute auth_input */
APPEND(ai, s.verify, DIGEST256_LEN);
APPEND(ai, handshake_state->router_id, DIGEST_LEN);
APPEND(ai, handshake_state->pubkey_B.public_key, CURVE25519_PUBKEY_LEN);
APPEND(ai, s.pubkey_Y.public_key, CURVE25519_PUBKEY_LEN);
APPEND(ai, handshake_state->pubkey_X.public_key, CURVE25519_PUBKEY_LEN);
APPEND(ai, PROTOID, PROTOID_LEN);
APPEND(ai, SERVER_STR, SERVER_STR_LEN);
tor_assert(ai == s.auth_input + sizeof(s.auth_input));
/* Compute auth */
h_tweak(s.auth, s.auth_input, sizeof(s.auth_input), T->t_mac);
bad |= tor_memneq(s.auth, auth_candidate, DIGEST256_LEN);
crypto_expand_key_material_rfc5869_sha256(
s.secret_input, sizeof(s.secret_input),
(const uint8_t*)T->t_key, strlen(T->t_key),
(const uint8_t*)T->m_expand, strlen(T->m_expand),
key_out, key_out_len);
memwipe(&s, 0, sizeof(s));
return bad ? -1 : 0;
}