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mirror of https://git.kernel.org/pub/scm/network/wireless/iwd.git synced 2024-11-25 17:59:25 +01:00

sae: Add basic H2E support

This commit is contained in:
Denis Kenzior 2021-07-09 23:22:04 -05:00
parent d12ac0fa71
commit 891b78e9e8

502
src/sae.c
View File

@ -35,6 +35,9 @@
#include "src/sae.h"
#include "src/auth-proto.h"
/* SHA-512 is the highest supported hashing function as of 802.11-2020 */
#define SAE_MAX_HASH_LEN 64
#define SAE_RETRANSMIT_TIMEOUT 2
#define SAE_SYNC_MAX 3
#define SAE_MAX_ASSOC_RETRY 3
@ -53,15 +56,15 @@ struct sae_sm {
enum sae_state state;
const struct l_ecc_curve *curve;
unsigned int group;
uint8_t group_retry;
const unsigned int *ecc_groups;
int group_retry;
uint16_t *rejected_groups;
struct l_ecc_scalar *rand;
struct l_ecc_scalar *scalar;
struct l_ecc_scalar *p_scalar;
struct l_ecc_point *element;
struct l_ecc_point *p_element;
uint16_t send_confirm;
uint8_t kck[32];
uint8_t kck[SAE_MAX_HASH_LEN];
uint8_t pmk[32];
uint8_t pmkid[16];
uint8_t *token;
@ -79,8 +82,83 @@ struct sae_sm {
sae_tx_authenticate_func_t tx_auth;
sae_tx_associate_func_t tx_assoc;
void *user_data;
enum crypto_sae sae_type;
};
static enum mmpdu_status_code sae_status_code(struct sae_sm *sm)
{
switch (sm->sae_type) {
case CRYPTO_SAE_LOOPING:
return MMPDU_STATUS_CODE_SUCCESS;
case CRYPTO_SAE_HASH_TO_ELEMENT:
return MMPDU_STATUS_CODE_SAE_HASH_TO_ELEMENT;
}
return MMPDU_STATUS_CODE_UNSPECIFIED;
}
static void sae_rejected_groups_append(struct sae_sm *sm, uint16_t group)
{
uint16_t i;
if (!sm->rejected_groups) {
sm->rejected_groups = reallocarray(NULL, 2, sizeof(uint16_t));
sm->rejected_groups[0] = 1;
sm->rejected_groups[1] = group;
return;
}
for (i = 1; i <= sm->rejected_groups[0]; i++)
if (sm->rejected_groups[i] == group)
return;
sm->rejected_groups = reallocarray(sm->rejected_groups,
i + 1, sizeof(uint16_t));
sm->rejected_groups[0] += 1;
sm->rejected_groups[i] = group;
}
static void sae_reset_state(struct sae_sm *sm)
{
l_free(sm->token);
sm->token = NULL;
l_ecc_scalar_free(sm->scalar);
sm->scalar = NULL;
l_ecc_scalar_free(sm->p_scalar);
sm->p_scalar = NULL;
l_ecc_scalar_free(sm->rand);
sm->rand = NULL;
l_ecc_point_free(sm->element);
sm->element = NULL;
l_ecc_point_free(sm->p_element);
sm->p_element = NULL;
l_ecc_point_free(sm->pwe);
sm->pwe = NULL;
}
static int sae_choose_next_group(struct sae_sm *sm)
{
const unsigned int *ecc_groups = l_ecc_supported_ike_groups();
bool reset = sm->group_retry >= 0;
do {
sm->group_retry++;
if (ecc_groups[sm->group_retry] == 0)
return -ENOENT;
} while (sm->sae_type != CRYPTO_SAE_LOOPING &&
!sm->handshake->ecc_sae_pts[sm->group_retry]);
if (reset)
sae_reset_state(sm);
sm->group = ecc_groups[sm->group_retry];
sm->curve = l_ecc_curve_from_ike_group(sm->group);
return 0;
}
static bool sae_pwd_seed(const uint8_t *addr1, const uint8_t *addr2,
uint8_t *base, size_t base_len,
uint8_t counter, uint8_t *out)
@ -145,22 +223,26 @@ static struct l_ecc_scalar *sae_pwd_value(const struct l_ecc_curve *curve,
}
/* IEEE 802.11-2016 - Section 12.4.2 Assumptions on SAE */
static bool sae_cn(const uint8_t *kck, uint16_t send_confirm,
static ssize_t sae_cn(struct sae_sm *sm, uint16_t send_confirm,
struct l_ecc_scalar *scalar1,
struct l_ecc_point *element1,
struct l_ecc_scalar *scalar2,
struct l_ecc_point *element2,
uint8_t *confirm)
{
enum l_checksum_type hash =
crypto_sae_hash_from_ecc_prime_len(sm->sae_type,
l_ecc_curve_get_scalar_bytes(sm->curve));
size_t hash_len = l_checksum_digest_length(hash);
uint8_t s1[L_ECC_SCALAR_MAX_BYTES];
uint8_t s2[L_ECC_SCALAR_MAX_BYTES];
uint8_t e1[L_ECC_POINT_MAX_BYTES];
uint8_t e2[L_ECC_POINT_MAX_BYTES];
struct l_checksum *hmac;
struct iovec iov[5];
int ret;
ssize_t ret;
hmac = l_checksum_new_hmac(L_CHECKSUM_SHA256, kck, 32);
hmac = l_checksum_new_hmac(hash, sm->kck, hash_len);
if (!hmac)
return false;
@ -178,12 +260,10 @@ static bool sae_cn(const uint8_t *kck, uint16_t send_confirm,
iov[4].iov_len = l_ecc_point_get_data(element2, e2, sizeof(e2));
l_checksum_updatev(hmac, iov, 5);
ret = l_checksum_get_digest(hmac, confirm, 32);
ret = l_checksum_get_digest(hmac, confirm, hash_len);
l_checksum_free(hmac);
return (ret == 32);
return ret;
}
static int sae_reject(struct sae_sm *sm, uint16_t transaction, uint16_t status)
@ -382,28 +462,36 @@ static struct l_ecc_point *sae_compute_pwe(const struct l_ecc_curve *curve,
return pwe;
}
static bool sae_build_commit(struct sae_sm *sm, const uint8_t *addr1,
static int sae_build_commit(struct sae_sm *sm, const uint8_t *addr1,
const uint8_t *addr2, uint8_t *commit,
size_t *len, bool retry)
size_t len, bool retry)
{
struct l_ecc_scalar *mask;
uint8_t *ptr = commit;
struct l_ecc_scalar *order;
struct ie_tlv_builder builder;
if (retry)
goto old_commit;
if (!sm->handshake->passphrase) {
l_error("no handshake passphrase found");
return false;
}
switch (sm->sae_type) {
case CRYPTO_SAE_HASH_TO_ELEMENT:
{
const struct l_ecc_point *pt =
sm->handshake->ecc_sae_pts[sm->group_retry];
sm->pwe = sae_compute_pwe(sm->curve, sm->handshake->passphrase,
sm->pwe = crypto_derive_sae_pwe_from_pt_ecc(addr1, addr2, pt);
break;
}
case CRYPTO_SAE_LOOPING:
sm->pwe = sae_compute_pwe(sm->curve, sm->handshake->passphrase,
addr1, addr2);
break;
}
if (!sm->pwe) {
l_error("could not compute PWE");
return false;
return -EIO;
}
sm->scalar = l_ecc_scalar_new(sm->curve, NULL, 0);
@ -431,17 +519,25 @@ static bool sae_build_commit(struct sae_sm *sm, const uint8_t *addr1,
*/
old_commit:
/* transaction */
/*
* 12.4.7.4 Encoding and decoding of SAE Commit messages
* Refer to Table 9-40 for order and Table 9-41 for presence
* of elements
*/
/* "a Transaction Sequence Number of 1" */
l_put_le16(1, ptr);
ptr += 2;
/* status success */
l_put_le16(0, ptr);
/* "a Status Code of SUCCESS or SAE_HASH_TO_ELEMENT" */
l_put_le16(sae_status_code(sm), ptr);
ptr += 2;
/* group */
l_put_le16(sm->group, ptr);
ptr += 2;
if (sm->token) {
if (sm->sae_type == CRYPTO_SAE_LOOPING && sm->token) {
memcpy(ptr, sm->token, sm->token_len);
ptr += sm->token_len;
}
@ -449,23 +545,40 @@ old_commit:
ptr += l_ecc_scalar_get_data(sm->scalar, ptr, L_ECC_SCALAR_MAX_BYTES);
ptr += l_ecc_point_get_data(sm->element, ptr, L_ECC_POINT_MAX_BYTES);
*len = ptr - commit;
ie_tlv_builder_init(&builder, ptr, len - (ptr - commit));
return true;
if (sm->sae_type != CRYPTO_SAE_LOOPING && sm->rejected_groups) {
ie_tlv_builder_next(&builder, IE_TYPE_REJECTED_GROUPS);
ie_tlv_builder_set_data(&builder, sm->rejected_groups + 1,
sm->rejected_groups[0] * sizeof(uint16_t));
}
if (sm->sae_type != CRYPTO_SAE_LOOPING && sm->token) {
ie_tlv_builder_next(&builder,
IE_TYPE_ANTI_CLOGGING_TOKEN_CONTAINER);
ie_tlv_builder_set_data(&builder, sm->token, sm->token_len);
}
ie_tlv_builder_finalize(&builder, &len);
return ptr - commit + len;
}
static void sae_send_confirm(struct sae_sm *sm)
static bool sae_send_confirm(struct sae_sm *sm)
{
uint8_t confirm[32];
uint8_t body[38];
uint8_t confirm[SAE_MAX_HASH_LEN];
uint8_t body[sizeof(confirm) + 6];
uint8_t *ptr = body;
ssize_t r;
/*
* confirm = CN(KCK, send-confirm, commit-scalar, COMMIT-ELEMENT,
* peer-commit-scalar, PEER-COMMIT-ELEMENT)
*/
sae_cn(sm->kck, sm->sc, sm->scalar, sm->element, sm->p_scalar,
r = sae_cn(sm, sm->sc, sm->scalar, sm->element, sm->p_scalar,
sm->p_element, confirm);
if (r < 0)
return false;
l_put_le16(2, ptr);
ptr += 2;
@ -473,26 +586,31 @@ static void sae_send_confirm(struct sae_sm *sm)
ptr += 2;
l_put_le16(sm->sc, ptr);
ptr += 2;
memcpy(ptr, confirm, 32);
ptr += 32;
memcpy(ptr, confirm, r);
ptr += r;
sm->tx_auth(body, 38, sm->user_data);
sm->tx_auth(body, ptr - body, sm->user_data);
return true;
}
static int sae_process_commit(struct sae_sm *sm, const uint8_t *from,
const uint8_t *frame, size_t len)
{
uint8_t *ptr = (uint8_t *) frame;
uint8_t k[L_ECC_SCALAR_MAX_BYTES];
unsigned int nbytes = l_ecc_curve_get_scalar_bytes(sm->curve);
enum l_checksum_type hash =
crypto_sae_hash_from_ecc_prime_len(sm->sae_type, nbytes);
size_t hash_len = l_checksum_digest_length(hash);
struct l_ecc_point *k_point;
uint8_t zero_key[32] = { 0 };
uint8_t keyseed[32];
uint8_t kck_and_pmk[2][32];
uint8_t k[L_ECC_SCALAR_MAX_BYTES];
ssize_t klen;
const void *salt = NULL;
size_t salt_len = 0;
uint8_t keyseed[SAE_MAX_HASH_LEN];
uint8_t kck_and_pmk[SAE_MAX_HASH_LEN + 32];
uint8_t tmp[L_ECC_SCALAR_MAX_BYTES];
struct l_ecc_scalar *tmp_scalar;
ssize_t klen;
struct l_ecc_scalar *order;
unsigned int nbytes = l_ecc_curve_get_scalar_bytes(sm->curve);
ptr += 2;
@ -549,19 +667,46 @@ static int sae_process_commit(struct sae_sm *sm, const uint8_t *from,
* i.e., if P = (x, y) then F(P) = x.
*/
klen = l_ecc_point_get_x(k_point, k, sizeof(k));
l_ecc_point_free(k_point);
if (klen < 0)
return sae_reject(sm, SAE_STATE_COMMITTED,
MMPDU_STATUS_CODE_UNSPECIFIED);
/* keyseed = H(<0>32, k) */
hmac_sha256(zero_key, 32, k, klen, keyseed, 32);
/*
* keyseed = H(salt, k)
*
* 802.11-2020 12.4.5.4:
* Hash to Element case:
* "... a salt consisting of the concatenation of the rejected groups
* from each peer's Rejected Groups element shall be
* passed to the KDF; those of the peer with the highest MAC address go
* first (if only one sent a Rejected Groups element then the salt will
* consist of that list). "
*
* Looping case:
* "...the salt shall consist of a series of octets of the value zero
* whose length equals the length of the digest of the hash function
* used to instantiate H()."
*
* NOTE: We use hkdf_extract here since it is just an hmac invocation
* and it handles the case of the zero key for us.
*/
if (sm->sae_type != CRYPTO_SAE_LOOPING && sm->rejected_groups) {
salt = sm->rejected_groups + 1;
salt_len = sm->rejected_groups[0] * sizeof(uint16_t);
}
hkdf_extract(hash, salt, salt_len, 1, keyseed, k, klen);
/*
* kck_and_pmk = KDF-Hash-512(keyseed, "SAE KCK and PMK",
(commit-scalar + peer-commit-scalar) mod r)
* context = (commit-scalar + peer-commit-scalar) mod r
* Length = Q + 256
* kck_and_pmk = KDF-Hash-Length(keyseed, "SAE KCK and PMK", context)
* KCK = L(kck_and_pmk, 0, Q)
* PMK = L(kck_and_pmk, Q, 256)
*
* Q is the length of the digest of the H(), the hash function used
*/
tmp_scalar = l_ecc_scalar_new(sm->curve, NULL, 0);
order = l_ecc_curve_get_order(sm->curve);
@ -569,11 +714,12 @@ static int sae_process_commit(struct sae_sm *sm, const uint8_t *from,
l_ecc_scalar_add(tmp_scalar, sm->p_scalar, sm->scalar, order);
l_ecc_scalar_get_data(tmp_scalar, tmp, sizeof(tmp));
kdf_sha256(keyseed, 32, "SAE KCK and PMK", strlen("SAE KCK and PMK"),
tmp, nbytes, kck_and_pmk, 64);
crypto_kdf(hash, keyseed, hash_len,
"SAE KCK and PMK", strlen("SAE KCK and PMK"),
tmp, nbytes, kck_and_pmk, hash_len + 32);
memcpy(sm->kck, kck_and_pmk[0], 32);
memcpy(sm->pmk, kck_and_pmk[1], 32);
memcpy(sm->kck, kck_and_pmk, hash_len);
memcpy(sm->pmk, kck_and_pmk + hash_len, 32);
/*
* PMKID = L((commit-scalar + peer-commit-scalar) mod r, 0, 128)
@ -587,7 +733,9 @@ static int sae_process_commit(struct sae_sm *sm, const uint8_t *from,
/* don't set the handshakes pmkid until confirm is verified */
memcpy(sm->pmkid, tmp, 16);
sae_send_confirm(sm);
if (!sae_send_confirm(sm))
return -EPROTO;
sm->state = SAE_STATE_CONFIRMED;
return 0;
@ -595,13 +743,16 @@ static int sae_process_commit(struct sae_sm *sm, const uint8_t *from,
static bool sae_verify_confirm(struct sae_sm *sm, const uint8_t *frame)
{
uint8_t check[32];
uint8_t check[SAE_MAX_HASH_LEN];
uint16_t rc = l_get_le16(frame);
ssize_t r;
sae_cn(sm->kck, rc, sm->p_scalar, sm->p_element, sm->scalar,
r = sae_cn(sm, rc, sm->p_scalar, sm->p_element, sm->scalar,
sm->element, check);
if (r < 0)
return false;
if (memcmp(frame + 2, check, 32))
if (memcmp(frame + 2, check, r))
return false;
sm->rc = rc;
@ -614,11 +765,6 @@ static int sae_process_confirm(struct sae_sm *sm, const uint8_t *from,
{
const uint8_t *ptr = frame;
if (len < 34) {
l_error("bad length");
return -EBADMSG;
}
/*
* If processing is unsuccessful and the SAE Confirm message is not
* verified, protocol instance shall remain in Confirmed state.
@ -647,14 +793,16 @@ static int sae_process_confirm(struct sae_sm *sm, const uint8_t *from,
static bool sae_send_commit(struct sae_sm *sm, bool retry)
{
struct handshake_state *hs = sm->handshake;
/* regular commit + possible 256 byte token + 6 bytes header */
uint8_t commit[L_ECC_SCALAR_MAX_BYTES + L_ECC_POINT_MAX_BYTES + 262];
size_t len;
/* regular commit + 3x IEs (257 bytes) + 6 bytes header */
uint8_t commit[L_ECC_SCALAR_MAX_BYTES + L_ECC_POINT_MAX_BYTES + 777];
int r;
if (!sae_build_commit(sm, hs->spa, hs->aa, commit, &len, retry))
r = sae_build_commit(sm, hs->spa, hs->aa,
commit, sizeof(commit), retry);
if (r < 0)
return false;
sm->tx_auth(commit, len, sm->user_data);
sm->tx_auth(commit, r, sm->user_data);
return true;
}
@ -681,9 +829,33 @@ static bool sae_assoc_timeout(struct auth_proto *ap)
* sent. The new SAE Commit message shall be transmitted to the peer, Sync shall
* be zeroed, and the t0 (retransmission) timer shall be set.
*/
static void sae_process_anti_clogging(struct sae_sm *sm, const uint8_t *ptr,
static int sae_process_anti_clogging(struct sae_sm *sm, const uint8_t *ptr,
size_t len)
{
if (len < 2)
return -EBADMSG;
len -= 2;
ptr += 2;
/*
* 802.11-2020, Table 9-41:
* When the hash-to-element method is used to derive the PWE, the
* Anti-Clogging Token Container element is present if the
* Status Code field is ANTI_CLOGGING_TOKEN_REQUIRED
*/
if (sm->sae_type != CRYPTO_SAE_LOOPING) {
if (len < 3)
return -EBADMSG;
if (ptr[0] != IE_TYPE_EXTENSION || ptr[2] != 93 ||
ptr[1] < 2 || len < ptr[1] + 2u)
return -EBADMSG;
len = ptr[1] - 1;
ptr += 3;
}
/*
* IEEE 802.11-2016 - Section 12.4.6 Anti-clogging tokens
*
@ -694,16 +866,18 @@ static void sae_process_anti_clogging(struct sae_sm *sm, const uint8_t *ptr,
* going to be 2 bytes less than the passed in length. This is why we
* are checking 3 > len > 258.
*/
if (len < 3 || len > 258) {
if (len < 1 || len > 256) {
l_error("anti-clogging token size invalid %zu", len);
return;
return -EBADMSG;
}
sm->token = l_memdup(ptr + 2, len - 2);
sm->token_len = len - 2;
sm->token = l_memdup(ptr, len);
sm->token_len = len;
sm->sync = 0;
sae_send_commit(sm, true);
return -EAGAIN;
}
/*
@ -736,25 +910,6 @@ static int sae_verify_nothing(struct sae_sm *sm, uint16_t transaction,
return 0;
}
static void sae_reset_state(struct sae_sm *sm)
{
l_free(sm->token);
sm->token = NULL;
l_ecc_scalar_free(sm->scalar);
sm->scalar = NULL;
l_ecc_scalar_free(sm->p_scalar);
sm->p_scalar = NULL;
l_ecc_scalar_free(sm->rand);
sm->rand = NULL;
l_ecc_point_free(sm->element);
sm->element = NULL;
l_ecc_point_free(sm->p_element);
sm->p_element = NULL;
l_ecc_point_free(sm->pwe);
sm->pwe = NULL;
}
/*
* 802.11-2016 - 12.4.8.6.4 Protocol instance behavior - Committed state
*/
@ -762,6 +917,9 @@ static int sae_verify_committed(struct sae_sm *sm, uint16_t transaction,
uint16_t status, const uint8_t *frame,
size_t len)
{
unsigned int skip;
struct ie_tlv_iter iter;
/*
* Upon receipt of a Con event...
* Then the protocol instance checks the value of Sync. If it
@ -781,11 +939,10 @@ static int sae_verify_committed(struct sae_sm *sm, uint16_t transaction,
return -EAGAIN;
}
switch (status) {
case MMPDU_STATUS_CODE_ANTI_CLOGGING_TOKEN_REQ:
sae_process_anti_clogging(sm, frame, len);
return -EAGAIN;
case MMPDU_STATUS_CODE_UNSUPP_FINITE_CYCLIC_GROUP:
if (status == MMPDU_STATUS_CODE_ANTI_CLOGGING_TOKEN_REQ)
return sae_process_anti_clogging(sm, frame, len);
if (status == MMPDU_STATUS_CODE_UNSUPP_FINITE_CYCLIC_GROUP) {
/*
* TODO: hostapd in its current state does not include the
* group number as it should. This is a violation of the spec,
@ -808,17 +965,7 @@ static int sae_verify_committed(struct sae_sm *sm, uint16_t transaction,
else if (len >= 2 && (l_get_le16(frame) != sm->group))
return -ENOMSG;
sm->group_retry++;
if (sm->ecc_groups[sm->group_retry] == 0) {
/*
* "If there are no other groups to choose, the protocol
* instance shall send a Del event to the parent process
* and transitions back to Nothing state"
*/
sm->state = SAE_STATE_NOTHING;
goto reject_unsupp_group;
}
sae_rejected_groups_append(sm, L_CPU_TO_LE16(sm->group));
/*
* "If the rejected group matches the last offered group, the
@ -828,40 +975,85 @@ static int sae_verify_committed(struct sae_sm *sm, uint16_t transaction,
* zeros Sync, sets the t0 (retransmission) timer, and remains
* in Committed state"
*/
sae_reset_state(sm);
sm->group = sm->ecc_groups[sm->group_retry];
sm->curve = l_ecc_curve_from_ike_group(sm->group);
if (sae_choose_next_group(sm) < 0) {
/*
* "If there are no other groups to choose, the protocol
* instance shall send a Del event to the parent process
* and transitions back to Nothing state"
*/
sm->state = SAE_STATE_NOTHING;
goto reject_unsupp_group;
}
sm->sync = 0;
sae_send_commit(sm, false);
return -EAGAIN;
case 0:
if (len < 2)
return -EBADMSG;
if (l_get_le16(frame) != sm->group) {
l_error("SAE: Peer tried to change group -- Reject");
goto reject_unsupp_group;
}
len -= 2;
if (len < l_ecc_curve_get_scalar_bytes(sm->curve) * 3)
return -EBADMSG;
return 0;
default:
/*
* If the Status is some other nonzero value, the frame shall
* be silently discarded and the t0 (retransmission) timer
* shall be set.
*/
return -ENOMSG;
}
/*
* If the Status is some other nonzero value, the frame shall be
* silently discarded and the t0 (retransmission) timer shall be set.
*/
if (status != 0 && status != MMPDU_STATUS_CODE_SAE_HASH_TO_ELEMENT)
return -ENOMSG;
if (status != sae_status_code(sm))
return -EBADMSG;
if (len < 2)
return -EBADMSG;
if (l_get_le16(frame) != sm->group) {
l_error("SAE: Peer tried to change group -- Reject");
goto reject_unsupp_group;
}
len -= 2;
frame += 2;
skip = l_ecc_curve_get_scalar_bytes(sm->curve) * 3;
if (len < skip)
return -EBADMSG;
/* If H2E isn't being used, there should be no IEs in use */
if (status == 0)
return 0;
len -= skip;
frame += skip;
ie_tlv_iter_init(&iter, frame, len);
while (ie_tlv_iter_next(&iter)) {
switch (ie_tlv_iter_get_tag(&iter)) {
/*
* If the peer's SAE Commit message contains a Rejected Groups
* element, the list of rejected groups shall be checked to
* ensure that all of the groups in the list are groups that
* would be rejected. If any groups in the list would not be
* rejected then processing of the SAE Commit message
* terminates and the STA shall reject the peer's
* authentication.
*
* NOTE: We currently only support the Initiator role, and so
* do not reject any groups. We should never receive this
* element
*/
case IE_TYPE_REJECTED_GROUPS:
l_error("SAE: Unexpected Rejected Groups IE");
return sae_reject(sm, SAE_STATE_COMMITTED,
MMPDU_STATUS_CODE_UNSPECIFIED);
/* We don't request tokens, so we shouldn't get any */
case IE_TYPE_ANTI_CLOGGING_TOKEN_CONTAINER:
l_error("SAE: Unexpected Anti-Clogging Container IE");
return sae_reject(sm, SAE_STATE_COMMITTED,
MMPDU_STATUS_CODE_UNSPECIFIED);
}
}
return 0;
reject_unsupp_group:
return sae_reject(sm, SAE_STATE_COMMITTED,
MMPDU_STATUS_CODE_UNSUPP_FINITE_CYCLIC_GROUP);
@ -874,8 +1066,26 @@ static int sae_verify_confirmed(struct sae_sm *sm, uint16_t trans,
uint16_t status, const uint8_t *frame,
size_t len)
{
if (trans == SAE_STATE_CONFIRMED)
if (trans == SAE_STATE_CONFIRMED) {
enum l_checksum_type hash =
crypto_sae_hash_from_ecc_prime_len(sm->sae_type,
l_ecc_curve_get_scalar_bytes(sm->curve));
size_t hash_len = l_checksum_digest_length(hash);
/* Most likely the password is wrong */
if (status == MMPDU_STATUS_CODE_UNSPECIFIED && len == 0)
return -ENOKEY;
if (status != MMPDU_STATUS_CODE_SUCCESS)
return -EPROTO;
if (len < hash_len + 2) {
l_error("SAE: Confirm packet too short");
return -EBADMSG;
}
return 0;
}
/*
* Upon receipt of a Com event, the t0 (retransmission) timer shall be
@ -909,7 +1119,9 @@ static int sae_verify_confirmed(struct sae_sm *sm, uint16_t trans,
sm->sc++;
sae_send_commit(sm, true);
sae_send_confirm(sm);
if (!sae_send_confirm(sm))
return -EPROTO;
return -EAGAIN;
}
@ -961,7 +1173,8 @@ static int sae_verify_accepted(struct sae_sm *sm, uint16_t trans,
sm->sync++;
sm->sc = 0xffff;
sae_send_confirm(sm);
if (!sae_send_confirm(sm))
return -EPROTO;
return -EAGAIN;
}
@ -1055,6 +1268,14 @@ static bool sae_start(struct auth_proto *ap)
else
memcpy(sm->peer, sm->handshake->aa, 6);
if (sm->sae_type == CRYPTO_SAE_LOOPING && !sm->handshake->passphrase) {
l_error("SAE: No passphrase set");
return false;
}
if (sae_choose_next_group(sm) < 0)
return false;
sm->state = SAE_STATE_COMMITTED;
return sae_send_commit(sm, false);
}
@ -1065,6 +1286,9 @@ static void sae_free(struct auth_proto *ap)
sae_reset_state(sm);
if (sm->rejected_groups)
free(sm->rejected_groups);
/* zero out whole structure, including keys */
explicit_bzero(sm, sizeof(struct sae_sm));
@ -1077,20 +1301,17 @@ struct auth_proto *sae_sm_new(struct handshake_state *hs,
void *user_data)
{
struct sae_sm *sm;
const void *rsnxe;
sm = l_new(struct sae_sm, 1);
if (!sm)
return NULL;
sm->group_retry = -1;
sm->tx_auth = tx_auth;
sm->tx_assoc = tx_assoc;
sm->user_data = user_data;
sm->handshake = hs;
sm->state = SAE_STATE_NOTHING;
sm->ecc_groups = l_ecc_supported_ike_groups();
sm->group = sm->ecc_groups[sm->group_retry];
sm->curve = l_ecc_curve_from_ike_group(sm->group);
sm->ap.start = sae_start;
sm->ap.free = sae_free;
@ -1098,5 +1319,16 @@ struct auth_proto *sae_sm_new(struct handshake_state *hs,
sm->ap.rx_associate = sae_rx_associate;
sm->ap.assoc_timeout = sae_assoc_timeout;
rsnxe = hs->authenticator ? hs->supplicant_rsnxe :
hs->authenticator_rsnxe;
if (ie_rsnxe_capable(rsnxe, IE_RSNX_SAE_H2E) && hs->ecc_sae_pts) {
l_debug("Using SAE H2E");
sm->sae_type = CRYPTO_SAE_HASH_TO_ELEMENT;
} else {
l_debug("Using SAE Hunting and Pecking");
sm->sae_type = CRYPTO_SAE_LOOPING;
}
return &sm->ap;
}