/*
* hostapd / EAP Full Authenticator state machine (RFC 4137)
* Copyright (c) 2004-2007, Jouni Malinen <j@w1.fi>
*
* This software may be distributed under the terms of the BSD license.
* See README for more details.
*
* This state machine is based on the full authenticator state machine defined
* in RFC 4137. However, to support backend authentication in RADIUS
* authentication server functionality, parts of backend authenticator (also
* from RFC 4137) are mixed in. This functionality is enabled by setting
* backend_auth configuration variable to TRUE.
*/
#include "includes.h"
#include "common.h"
#include "eap_i.h"
#include "state_machine.h"
#include "common/wpa_ctrl.h"
#define STATE_MACHINE_DATA struct eap_sm
#define STATE_MACHINE_DEBUG_PREFIX "EAP"
#define EAP_MAX_AUTH_ROUNDS 50
static void eap_user_free(struct eap_user *user);
/* EAP state machines are described in RFC 4137 */
static int eap_sm_calculateTimeout(struct eap_sm *sm, int retransCount,
int eapSRTT, int eapRTTVAR,
int methodTimeout);
static void eap_sm_parseEapResp(struct eap_sm *sm, const struct wpabuf *resp);
static int eap_sm_getId(const struct wpabuf *data);
static struct wpabuf * eap_sm_buildSuccess(struct eap_sm *sm, u8 id);
static struct wpabuf * eap_sm_buildFailure(struct eap_sm *sm, u8 id);
static int eap_sm_nextId(struct eap_sm *sm, int id);
static void eap_sm_Policy_update(struct eap_sm *sm, const u8 *nak_list,
size_t len);
static EapType eap_sm_Policy_getNextMethod(struct eap_sm *sm, int *vendor);
static int eap_sm_Policy_getDecision(struct eap_sm *sm);
static Boolean eap_sm_Policy_doPickUp(struct eap_sm *sm, EapType method);
static int eap_copy_buf(struct wpabuf **dst, const struct wpabuf *src)
{
if (src == NULL)
return -1;
wpabuf_free(*dst);
*dst = wpabuf_dup(src);
return *dst ? 0 : -1;
}
static int eap_copy_data(u8 **dst, size_t *dst_len,
const u8 *src, size_t src_len)
{
if (src == NULL)
return -1;
os_free(*dst);
*dst = os_malloc(src_len);
if (*dst) {
os_memcpy(*dst, src, src_len);
*dst_len = src_len;
return 0;
} else {
*dst_len = 0;
return -1;
}
}
#define EAP_COPY(dst, src) \
eap_copy_data((dst), (dst ## Len), (src), (src ## Len))
/**
* eap_user_get - Fetch user information from the database
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
* @identity: Identity (User-Name) of the user
* @identity_len: Length of identity in bytes
* @phase2: 0 = EAP phase1 user, 1 = EAP phase2 (tunneled) user
* Returns: 0 on success, or -1 on failure
*
* This function is used to fetch user information for EAP. The user will be
* selected based on the specified identity. sm->user and
* sm->user_eap_method_index are updated for the new user when a matching user
* is found. sm->user can be used to get user information (e.g., password).
*/
int eap_user_get(struct eap_sm *sm, const u8 *identity, size_t identity_len,
int phase2)
{
struct eap_user *user;
if (sm == NULL || sm->eapol_cb == NULL ||
sm->eapol_cb->get_eap_user == NULL)
return -1;
eap_user_free(sm->user);
sm->user = NULL;
user = os_zalloc(sizeof(*user));
if (user == NULL)
return -1;
if (sm->eapol_cb->get_eap_user(sm->eapol_ctx, identity,
identity_len, phase2, user) != 0) {
eap_user_free(user);
return -1;
}
sm->user = user;
sm->user_eap_method_index = 0;
return 0;
}
SM_STATE(EAP, DISABLED)
{
SM_ENTRY(EAP, DISABLED);
sm->num_rounds = 0;
}
SM_STATE(EAP, INITIALIZE)
{
SM_ENTRY(EAP, INITIALIZE);
if (sm->eap_if.eapRestart && !sm->eap_server && sm->identity) {
/*
* Need to allow internal Identity method to be used instead
* of passthrough at the beginning of reauthentication.
*/
eap_server_clear_identity(sm);
}
sm->currentId = -1;
sm->eap_if.eapSuccess = FALSE;
sm->eap_if.eapFail = FALSE;
sm->eap_if.eapTimeout = FALSE;
os_free(sm->eap_if.eapKeyData);
sm->eap_if.eapKeyData = NULL;
sm->eap_if.eapKeyDataLen = 0;
sm->eap_if.eapKeyAvailable = FALSE;
sm->eap_if.eapRestart = FALSE;
/*
* This is not defined in RFC 4137, but method state needs to be
* reseted here so that it does not remain in success state when
* re-authentication starts.
*/
if (sm->m && sm->eap_method_priv) {
sm->m->reset(sm, sm->eap_method_priv);
sm->eap_method_priv = NULL;
}
sm->m = NULL;
sm->user_eap_method_index = 0;
if (sm->backend_auth) {
sm->currentMethod = EAP_TYPE_NONE;
/* parse rxResp, respId, respMethod */
eap_sm_parseEapResp(sm, sm->eap_if.eapRespData);
if (sm->rxResp) {
sm->currentId = sm->respId;
}
}
sm->num_rounds = 0;
sm->method_pending = METHOD_PENDING_NONE;
wpa_msg(sm->msg_ctx, MSG_INFO, WPA_EVENT_EAP_STARTED
MACSTR, MAC2STR(sm->peer_addr));
}
SM_STATE(EAP, PICK_UP_METHOD)
{
SM_ENTRY(EAP, PICK_UP_METHOD);
if (eap_sm_Policy_doPickUp(sm, sm->respMethod)) {
sm->currentMethod = sm->respMethod;
if (sm->m && sm->eap_method_priv) {
sm->m->reset(sm, sm->eap_method_priv);
sm->eap_method_priv = NULL;
}
sm->m = eap_server_get_eap_method(EAP_VENDOR_IETF,
sm->currentMethod);
if (sm->m && sm->m->initPickUp) {
sm->eap_method_priv = sm->m->initPickUp(sm);
if (sm->eap_method_priv == NULL) {
wpa_printf(MSG_DEBUG, "EAP: Failed to "
"initialize EAP method %d",
sm->currentMethod);
sm->m = NULL;
sm->currentMethod = EAP_TYPE_NONE;
}
} else {
sm->m = NULL;
sm->currentMethod = EAP_TYPE_NONE;
}
}
wpa_msg(sm->msg_ctx, MSG_INFO, WPA_EVENT_EAP_PROPOSED_METHOD
"method=%u", sm->currentMethod);
}
SM_STATE(EAP, IDLE)
{
SM_ENTRY(EAP, IDLE);
sm->eap_if.retransWhile = eap_sm_calculateTimeout(
sm, sm->retransCount, sm->eap_if.eapSRTT, sm->eap_if.eapRTTVAR,
sm->methodTimeout);
}
SM_STATE(EAP, RETRANSMIT)
{
SM_ENTRY(EAP, RETRANSMIT);
sm->retransCount++;
if (sm->retransCount <= sm->MaxRetrans && sm->lastReqData) {
if (eap_copy_buf(&sm->eap_if.eapReqData, sm->lastReqData) == 0)
sm->eap_if.eapReq = TRUE;
}
}
SM_STATE(EAP, RECEIVED)
{
SM_ENTRY(EAP, RECEIVED);
/* parse rxResp, respId, respMethod */
eap_sm_parseEapResp(sm, sm->eap_if.eapRespData);
sm->num_rounds++;
}
SM_STATE(EAP, DISCARD)
{
SM_ENTRY(EAP, DISCARD);
sm->eap_if.eapResp = FALSE;
sm->eap_if.eapNoReq = TRUE;
}
SM_STATE(EAP, SEND_REQUEST)
{
SM_ENTRY(EAP, SEND_REQUEST);
sm->retransCount = 0;
if (sm->eap_if.eapReqData) {
if (eap_copy_buf(&sm->lastReqData, sm->eap_if.eapReqData) == 0)
{
sm->eap_if.eapResp = FALSE;
sm->eap_if.eapReq = TRUE;
} else {
sm->eap_if.eapResp = FALSE;
sm->eap_if.eapReq = FALSE;
}
} else {
wpa_printf(MSG_INFO, "EAP: SEND_REQUEST - no eapReqData");
sm->eap_if.eapResp = FALSE;
sm->eap_if.eapReq = FALSE;
sm->eap_if.eapNoReq = TRUE;
}
}
SM_STATE(EAP, INTEGRITY_CHECK)
{
SM_ENTRY(EAP, INTEGRITY_CHECK);
if (!eap_hdr_len_valid(sm->eap_if.eapRespData, 1)) {
sm->ignore = TRUE;
return;
}
if (sm->m->check) {
sm->ignore = sm->m->check(sm, sm->eap_method_priv,
sm->eap_if.eapRespData);
}
}
SM_STATE(EAP, METHOD_REQUEST)
{
SM_ENTRY(EAP, METHOD_REQUEST);
if (sm->m == NULL) {
wpa_printf(MSG_DEBUG, "EAP: method not initialized");
return;
}
sm->currentId = eap_sm_nextId(sm, sm->currentId);
wpa_printf(MSG_DEBUG, "EAP: building EAP-Request: Identifier %d",
sm->currentId);
sm->lastId = sm->currentId;
wpabuf_free(sm->eap_if.eapReqData);
sm->eap_if.eapReqData = sm->m->buildReq(sm, sm->eap_method_priv,
sm->currentId);
if (sm->m->getTimeout)
sm->methodTimeout = sm->m->getTimeout(sm, sm->eap_method_priv);
else
sm->methodTimeout = 0;
}
SM_STATE(EAP, METHOD_RESPONSE)
{
SM_ENTRY(EAP, METHOD_RESPONSE);
if (!eap_hdr_len_valid(sm->eap_if.eapRespData, 1))
return;
sm->m->process(sm, sm->eap_method_priv, sm->eap_if.eapRespData);
if (sm->m->isDone(sm, sm->eap_method_priv)) {
eap_sm_Policy_update(sm, NULL, 0);
os_free(sm->eap_if.eapKeyData);
if (sm->m->getKey) {
sm->eap_if.eapKeyData = sm->m->getKey(
sm, sm->eap_method_priv,
&sm->eap_if.eapKeyDataLen);
} else {
sm->eap_if.eapKeyData = NULL;
sm->eap_if.eapKeyDataLen = 0;
}
sm->methodState = METHOD_END;
} else {
sm->methodState = METHOD_CONTINUE;
}
}
SM_STATE(EAP, PROPOSE_METHOD)
{
int vendor;
EapType type;
SM_ENTRY(EAP, PROPOSE_METHOD);
type = eap_sm_Policy_getNextMethod(sm, &vendor);
if (vendor == EAP_VENDOR_IETF)
sm->currentMethod = type;
else
sm->currentMethod = EAP_TYPE_EXPANDED;
if (sm->m && sm->eap_method_priv) {
sm->m->reset(sm, sm->eap_method_priv);
sm->eap_method_priv = NULL;
}
sm->m = eap_server_get_eap_method(vendor, type);
if (sm->m) {
sm->eap_method_priv = sm->m->init(sm);
if (sm->eap_method_priv == NULL) {
wpa_printf(MSG_DEBUG, "EAP: Failed to initialize EAP "
"method %d", sm->currentMethod);
sm->m = NULL;
sm->currentMethod = EAP_TYPE_NONE;
}
}
if (sm->currentMethod == EAP_TYPE_IDENTITY ||
sm->currentMethod == EAP_TYPE_NOTIFICATION)
sm->methodState = METHOD_CONTINUE;
else
sm->methodState = METHOD_PROPOSED;
wpa_msg(sm->msg_ctx, MSG_INFO, WPA_EVENT_EAP_PROPOSED_METHOD
"vendor=%u method=%u", vendor, sm->currentMethod);
}
SM_STATE(EAP, NAK)
{
const struct eap_hdr *nak;
size_t len = 0;
const u8 *pos;
const u8 *nak_list = NULL;
SM_ENTRY(EAP, NAK);
if (sm->eap_method_priv) {
sm->m->reset(sm, sm->eap_method_priv);
sm->eap_method_priv = NULL;
}
sm->m = NULL;
if (!eap_hdr_len_valid(sm->eap_if.eapRespData, 1))
return;
nak = wpabuf_head(sm->eap_if.eapRespData);
if (nak && wpabuf_len(sm->eap_if.eapRespData) > sizeof(*nak)) {
len = be_to_host16(nak->length);
if (len > wpabuf_len(sm->eap_if.eapRespData))
len = wpabuf_len(sm->eap_if.eapRespData);
pos = (const u8 *) (nak + 1);
len -= sizeof(*nak);
if (*pos == EAP_TYPE_NAK) {
pos++;
len--;
nak_list = pos;
}
}
eap_sm_Policy_update(sm, nak_list, len);
}
SM_STATE(EAP, SELECT_ACTION)
{
SM_ENTRY(EAP, SELECT_ACTION);
sm->decision = eap_sm_Policy_getDecision(sm);
}
SM_STATE(EAP, TIMEOUT_FAILURE)
{
SM_ENTRY(EAP, TIMEOUT_FAILURE);
sm->eap_if.eapTimeout = TRUE;
}
SM_STATE(EAP, FAILURE)
{
SM_ENTRY(EAP, FAILURE);
wpabuf_free(sm->eap_if.eapReqData);
sm->eap_if.eapReqData = eap_sm_buildFailure(sm, sm->currentId);
wpabuf_free(sm->lastReqData);
sm->lastReqData = NULL;
sm->eap_if.eapFail = TRUE;
wpa_msg(sm->msg_ctx, MSG_INFO, WPA_EVENT_EAP_FAILURE
MACSTR, MAC2STR(sm->peer_addr));
}
SM_STATE(EAP, SUCCESS)
{
SM_ENTRY(EAP, SUCCESS);
wpabuf_free(sm->eap_if.eapReqData);
sm->eap_if.eapReqData = eap_sm_buildSuccess(sm, sm->currentId);
wpabuf_free(sm->lastReqData);
sm->lastReqData = NULL;
if (sm->eap_if.eapKeyData)
sm->eap_if.eapKeyAvailable = TRUE;
sm->eap_if.eapSuccess = TRUE;
wpa_msg(sm->msg_ctx, MSG_INFO, WPA_EVENT_EAP_SUCCESS
MACSTR, MAC2STR(sm->peer_addr));
}
SM_STATE(EAP, INITIALIZE_PASSTHROUGH)
{
SM_ENTRY(EAP, INITIALIZE_PASSTHROUGH);
wpabuf_free(sm->eap_if.aaaEapRespData);
sm->eap_if.aaaEapRespData = NULL;
}
SM_STATE(EAP, IDLE2)
{
SM_ENTRY(EAP, IDLE2);
sm->eap_if.retransWhile = eap_sm_calculateTimeout(
sm, sm->retransCount, sm->eap_if.eapSRTT, sm->eap_if.eapRTTVAR,
sm->methodTimeout);
}
SM_STATE(EAP, RETRANSMIT2)
{
SM_ENTRY(EAP, RETRANSMIT2);
sm->retransCount++;
if (sm->retransCount <= sm->MaxRetrans && sm->lastReqData) {
if (eap_copy_buf(&sm->eap_if.eapReqData, sm->lastReqData) == 0)
sm->eap_if.eapReq = TRUE;
}
}
SM_STATE(EAP, RECEIVED2)
{
SM_ENTRY(EAP, RECEIVED2);
/* parse rxResp, respId, respMethod */
eap_sm_parseEapResp(sm, sm->eap_if.eapRespData);
}
SM_STATE(EAP, DISCARD2)
{
SM_ENTRY(EAP, DISCARD2);
sm->eap_if.eapResp = FALSE;
sm->eap_if.eapNoReq = TRUE;
}
SM_STATE(EAP, SEND_REQUEST2)
{
SM_ENTRY(EAP, SEND_REQUEST2);
sm->retransCount = 0;
if (sm->eap_if.eapReqData) {
if (eap_copy_buf(&sm->lastReqData, sm->eap_if.eapReqData) == 0)
{
sm->eap_if.eapResp = FALSE;
sm->eap_if.eapReq = TRUE;
} else {
sm->eap_if.eapResp = FALSE;
sm->eap_if.eapReq = FALSE;
}
} else {
wpa_printf(MSG_INFO, "EAP: SEND_REQUEST2 - no eapReqData");
sm->eap_if.eapResp = FALSE;
sm->eap_if.eapReq = FALSE;
sm->eap_if.eapNoReq = TRUE;
}
}
SM_STATE(EAP, AAA_REQUEST)
{
SM_ENTRY(EAP, AAA_REQUEST);
if (sm->eap_if.eapRespData == NULL) {
wpa_printf(MSG_INFO, "EAP: AAA_REQUEST - no eapRespData");
return;
}
/*
* if (respMethod == IDENTITY)
* aaaIdentity = eapRespData
* This is already taken care of by the EAP-Identity method which
* stores the identity into sm->identity.
*/
eap_copy_buf(&sm->eap_if.aaaEapRespData, sm->eap_if.eapRespData);
}
SM_STATE(EAP, AAA_RESPONSE)
{
SM_ENTRY(EAP, AAA_RESPONSE);
eap_copy_buf(&sm->eap_if.eapReqData, sm->eap_if.aaaEapReqData);
sm->currentId = eap_sm_getId(sm->eap_if.eapReqData);
sm->methodTimeout = sm->eap_if.aaaMethodTimeout;
}
SM_STATE(EAP, AAA_IDLE)
{
SM_ENTRY(EAP, AAA_IDLE);
sm->eap_if.aaaFail = FALSE;
sm->eap_if.aaaSuccess = FALSE;
sm->eap_if.aaaEapReq = FALSE;
sm->eap_if.aaaEapNoReq = FALSE;
sm->eap_if.aaaEapResp = TRUE;
}
SM_STATE(EAP, TIMEOUT_FAILURE2)
{
SM_ENTRY(EAP, TIMEOUT_FAILURE2);
sm->eap_if.eapTimeout = TRUE;
}
SM_STATE(EAP, FAILURE2)
{
SM_ENTRY(EAP, FAILURE2);
eap_copy_buf(&sm->eap_if.eapReqData, sm->eap_if.aaaEapReqData);
sm->eap_if.eapFail = TRUE;
}
SM_STATE(EAP, SUCCESS2)
{
SM_ENTRY(EAP, SUCCESS2);
eap_copy_buf(&sm->eap_if.eapReqData, sm->eap_if.aaaEapReqData);
sm->eap_if.eapKeyAvailable = sm->eap_if.aaaEapKeyAvailable;
if (sm->eap_if.aaaEapKeyAvailable) {
EAP_COPY(&sm->eap_if.eapKeyData, sm->eap_if.aaaEapKeyData);
} else {
os_free(sm->eap_if.eapKeyData);
sm->eap_if.eapKeyData = NULL;
sm->eap_if.eapKeyDataLen = 0;
}
sm->eap_if.eapSuccess = TRUE;
/*
* Start reauthentication with identity request even though we know the
* previously used identity. This is needed to get reauthentication
* started properly.
*/
sm->start_reauth = TRUE;
}
SM_STEP(EAP)
{
if (sm->eap_if.eapRestart && sm->eap_if.portEnabled)
SM_ENTER_GLOBAL(EAP, INITIALIZE);
else if (!sm->eap_if.portEnabled)
SM_ENTER_GLOBAL(EAP, DISABLED);
else if (sm->num_rounds > EAP_MAX_AUTH_ROUNDS) {
if (sm->num_rounds == EAP_MAX_AUTH_ROUNDS + 1) {
wpa_printf(MSG_DEBUG, "EAP: more than %d "
"authentication rounds - abort",
EAP_MAX_AUTH_ROUNDS);
sm->num_rounds++;
SM_ENTER_GLOBAL(EAP, FAILURE);
}
} else switch (sm->EAP_state) {
case EAP_INITIALIZE:
if (sm->backend_auth) {
if (!sm->rxResp)
SM_ENTER(EAP, SELECT_ACTION);
else if (sm->rxResp &&
(sm->respMethod == EAP_TYPE_NAK ||
(sm->respMethod == EAP_TYPE_EXPANDED &&
sm->respVendor == EAP_VENDOR_IETF &&
sm->respVendorMethod == EAP_TYPE_NAK)))
SM_ENTER(EAP, NAK);
else
SM_ENTER(EAP, PICK_UP_METHOD);
} else {
SM_ENTER(EAP, SELECT_ACTION);
}
break;
case EAP_PICK_UP_METHOD:
if (sm->currentMethod == EAP_TYPE_NONE) {
SM_ENTER(EAP, SELECT_ACTION);
} else {
SM_ENTER(EAP, METHOD_RESPONSE);
}
break;
case EAP_DISABLED:
if (sm->eap_if.portEnabled)
SM_ENTER(EAP, INITIALIZE);
break;
case EAP_IDLE:
if (sm->eap_if.retransWhile == 0)
SM_ENTER(EAP, RETRANSMIT);
else if (sm->eap_if.eapResp)
SM_ENTER(EAP, RECEIVED);
break;
case EAP_RETRANSMIT:
if (sm->retransCount > sm->MaxRetrans)
SM_ENTER(EAP, TIMEOUT_FAILURE);
else
SM_ENTER(EAP, IDLE);
break;
case EAP_RECEIVED:
if (sm->rxResp && (sm->respId == sm->currentId) &&
(sm->respMethod == EAP_TYPE_NAK ||
(sm->respMethod == EAP_TYPE_EXPANDED &&
sm->respVendor == EAP_VENDOR_IETF &&
sm->respVendorMethod == EAP_TYPE_NAK))
&& (sm->methodState == METHOD_PROPOSED))
SM_ENTER(EAP, NAK);
else if (sm->rxResp && (sm->respId == sm->currentId) &&
((sm->respMethod == sm->currentMethod) ||
(sm->respMethod == EAP_TYPE_EXPANDED &&
sm->respVendor == EAP_VENDOR_IETF &&
sm->respVendorMethod == sm->currentMethod)))
SM_ENTER(EAP, INTEGRITY_CHECK);
else {
wpa_printf(MSG_DEBUG, "EAP: RECEIVED->DISCARD: "
"rxResp=%d respId=%d currentId=%d "
"respMethod=%d currentMethod=%d",
sm->rxResp, sm->respId, sm->currentId,
sm->respMethod, sm->currentMethod);
SM_ENTER(EAP, DISCARD);
}
break;
case EAP_DISCARD:
SM_ENTER(EAP, IDLE);
break;
case EAP_SEND_REQUEST:
SM_ENTER(EAP, IDLE);
break;
case EAP_INTEGRITY_CHECK:
if (sm->ignore)
SM_ENTER(EAP, DISCARD);
else
SM_ENTER(EAP, METHOD_RESPONSE);
break;
case EAP_METHOD_REQUEST:
SM_ENTER(EAP, SEND_REQUEST);
break;
case EAP_METHOD_RESPONSE:
/*
* Note: Mechanism to allow EAP methods to wait while going
* through pending processing is an extension to RFC 4137
* which only defines the transits to SELECT_ACTION and
* METHOD_REQUEST from this METHOD_RESPONSE state.
*/
if (sm->methodState == METHOD_END)
SM_ENTER(EAP, SELECT_ACTION);
else if (sm->method_pending == METHOD_PENDING_WAIT) {
wpa_printf(MSG_DEBUG, "EAP: Method has pending "
"processing - wait before proceeding to "
"METHOD_REQUEST state");
} else if (sm->method_pending == METHOD_PENDING_CONT) {
wpa_printf(MSG_DEBUG, "EAP: Method has completed "
"pending processing - reprocess pending "
"EAP message");
sm->method_pending = METHOD_PENDING_NONE;
SM_ENTER(EAP, METHOD_RESPONSE);
} else
SM_ENTER(EAP, METHOD_REQUEST);
break;
case EAP_PROPOSE_METHOD:
/*
* Note: Mechanism to allow EAP methods to wait while going
* through pending processing is an extension to RFC 4137
* which only defines the transit to METHOD_REQUEST from this
* PROPOSE_METHOD state.
*/
if (sm->method_pending == METHOD_PENDING_WAIT) {
wpa_printf(MSG_DEBUG, "EAP: Method has pending "
"processing - wait before proceeding to "
"METHOD_REQUEST state");
if (sm->user_eap_method_index > 0)
sm->user_eap_method_index--;
} else if (sm->method_pending == METHOD_PENDING_CONT) {
wpa_printf(MSG_DEBUG, "EAP: Method has completed "
"pending processing - reprocess pending "
"EAP message");
sm->method_pending = METHOD_PENDING_NONE;
SM_ENTER(EAP, PROPOSE_METHOD);
} else
SM_ENTER(EAP, METHOD_REQUEST);
break;
case EAP_NAK:
SM_ENTER(EAP, SELECT_ACTION);
break;
case EAP_SELECT_ACTION:
if (sm->decision == DECISION_FAILURE)
SM_ENTER(EAP, FAILURE);
else if (sm->decision == DECISION_SUCCESS)
SM_ENTER(EAP, SUCCESS);
else if (sm->decision == DECISION_PASSTHROUGH)
SM_ENTER(EAP, INITIALIZE_PASSTHROUGH);
else
SM_ENTER(EAP, PROPOSE_METHOD);
break;
case EAP_TIMEOUT_FAILURE:
break;
case EAP_FAILURE:
break;
case EAP_SUCCESS:
break;
case EAP_INITIALIZE_PASSTHROUGH:
if (sm->currentId == -1)
SM_ENTER(EAP, AAA_IDLE);
else
SM_ENTER(EAP, AAA_REQUEST);
break;
case EAP_IDLE2:
if (sm->eap_if.eapResp)
SM_ENTER(EAP, RECEIVED2);
else if (sm->eap_if.retransWhile == 0)
SM_ENTER(EAP, RETRANSMIT2);
break;
case EAP_RETRANSMIT2:
if (sm->retransCount > sm->MaxRetrans)
SM_ENTER(EAP, TIMEOUT_FAILURE2);
else
SM_ENTER(EAP, IDLE2);
break;
case EAP_RECEIVED2:
if (sm->rxResp && (sm->respId == sm->currentId))
SM_ENTER(EAP, AAA_REQUEST);
else
SM_ENTER(EAP, DISCARD2);
break;
case EAP_DISCARD2:
SM_ENTER(EAP, IDLE2);
break;
case EAP_SEND_REQUEST2:
SM_ENTER(EAP, IDLE2);
break;
case EAP_AAA_REQUEST:
SM_ENTER(EAP, AAA_IDLE);
break;
case EAP_AAA_RESPONSE:
SM_ENTER(EAP, SEND_REQUEST2);
break;
case EAP_AAA_IDLE:
if (sm->eap_if.aaaFail)
SM_ENTER(EAP, FAILURE2);
else if (sm->eap_if.aaaSuccess)
SM_ENTER(EAP, SUCCESS2);
else if (sm->eap_if.aaaEapReq)
SM_ENTER(EAP, AAA_RESPONSE);
else if (sm->eap_if.aaaTimeout)
SM_ENTER(EAP, TIMEOUT_FAILURE2);
break;
case EAP_TIMEOUT_FAILURE2:
break;
case EAP_FAILURE2:
break;
case EAP_SUCCESS2:
break;
}
}
static int eap_sm_calculateTimeout(struct eap_sm *sm, int retransCount,
int eapSRTT, int eapRTTVAR,
int methodTimeout)
{
int rto, i;
if (methodTimeout) {
/*
* EAP method (either internal or through AAA server, provided
* timeout hint. Use that as-is as a timeout for retransmitting
* the EAP request if no response is received.
*/
wpa_printf(MSG_DEBUG, "EAP: retransmit timeout %d seconds "
"(from EAP method hint)", methodTimeout);
return methodTimeout;
}
/*
* RFC 3748 recommends algorithms described in RFC 2988 for estimation
* of the retransmission timeout. This should be implemented once
* round-trip time measurements are available. For nowm a simple
* backoff mechanism is used instead if there are no EAP method
* specific hints.
*
* SRTT = smoothed round-trip time
* RTTVAR = round-trip time variation
* RTO = retransmission timeout
*/
/*
* RFC 2988, 2.1: before RTT measurement, set RTO to 3 seconds for
* initial retransmission and then double the RTO to provide back off
* per 5.5. Limit the maximum RTO to 20 seconds per RFC 3748, 4.3
* modified RTOmax.
*/
rto = 3;
for (i = 0; i < retransCount; i++) {
rto *= 2;
if (rto >= 20) {
rto = 20;
break;
}
}
wpa_printf(MSG_DEBUG, "EAP: retransmit timeout %d seconds "
"(from dynamic back off; retransCount=%d)",
rto, retransCount);
return rto;
}
static void eap_sm_parseEapResp(struct eap_sm *sm, const struct wpabuf *resp)
{
const struct eap_hdr *hdr;
size_t plen;
/* parse rxResp, respId, respMethod */
sm->rxResp = FALSE;
sm->respId = -1;
sm->respMethod = EAP_TYPE_NONE;
sm->respVendor = EAP_VENDOR_IETF;
sm->respVendorMethod = EAP_TYPE_NONE;
if (resp == NULL || wpabuf_len(resp) < sizeof(*hdr)) {
wpa_printf(MSG_DEBUG, "EAP: parseEapResp: invalid resp=%p "
"len=%lu", resp,
resp ? (unsigned long) wpabuf_len(resp) : 0);
return;
}
hdr = wpabuf_head(resp);
plen = be_to_host16(hdr->length);
if (plen > wpabuf_len(resp)) {
wpa_printf(MSG_DEBUG, "EAP: Ignored truncated EAP-Packet "
"(len=%lu plen=%lu)",
(unsigned long) wpabuf_len(resp),
(unsigned long) plen);
return;
}
sm->respId = hdr->identifier;
if (hdr->code == EAP_CODE_RESPONSE)
sm->rxResp = TRUE;
if (plen > sizeof(*hdr)) {
u8 *pos = (u8 *) (hdr + 1);
sm->respMethod = *pos++;
if (sm->respMethod == EAP_TYPE_EXPANDED) {
if (plen < sizeof(*hdr) + 8) {
wpa_printf(MSG_DEBUG, "EAP: Ignored truncated "
"expanded EAP-Packet (plen=%lu)",
(unsigned long) plen);
return;
}
sm->respVendor = WPA_GET_BE24(pos);
pos += 3;
sm->respVendorMethod = WPA_GET_BE32(pos);
}
}
wpa_printf(MSG_DEBUG, "EAP: parseEapResp: rxResp=%d respId=%d "
"respMethod=%u respVendor=%u respVendorMethod=%u",
sm->rxResp, sm->respId, sm->respMethod, sm->respVendor,
sm->respVendorMethod);
}
static int eap_sm_getId(const struct wpabuf *data)
{
const struct eap_hdr *hdr;
if (data == NULL || wpabuf_len(data) < sizeof(*hdr))
return -1;
hdr = wpabuf_head(data);
wpa_printf(MSG_DEBUG, "EAP: getId: id=%d", hdr->identifier);
return hdr->identifier;
}
static struct wpabuf * eap_sm_buildSuccess(struct eap_sm *sm, u8 id)
{
struct wpabuf *msg;
struct eap_hdr *resp;
wpa_printf(MSG_DEBUG, "EAP: Building EAP-Success (id=%d)", id);
msg = wpabuf_alloc(sizeof(*resp));
if (msg == NULL)
return NULL;
resp = wpabuf_put(msg, sizeof(*resp));
resp->code = EAP_CODE_SUCCESS;
resp->identifier = id;
resp->length = host_to_be16(sizeof(*resp));
return msg;
}
static struct wpabuf * eap_sm_buildFailure(struct eap_sm *sm, u8 id)
{
struct wpabuf *msg;
struct eap_hdr *resp;
wpa_printf(MSG_DEBUG, "EAP: Building EAP-Failure (id=%d)", id);
msg = wpabuf_alloc(sizeof(*resp));
if (msg == NULL)
return NULL;
resp = wpabuf_put(msg, sizeof(*resp));
resp->code = EAP_CODE_FAILURE;
resp->identifier = id;
resp->length = host_to_be16(sizeof(*resp));
return msg;
}
static int eap_sm_nextId(struct eap_sm *sm, int id)
{
if (id < 0) {
/* RFC 3748 Ch 4.1: recommended to initialize Identifier with a
* random number */
id = rand() & 0xff;
if (id != sm->lastId)
return id;
}
return (id + 1) & 0xff;
}
/**
* eap_sm_process_nak - Process EAP-Response/Nak
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
* @nak_list: Nak list (allowed methods) from the supplicant
* @len: Length of nak_list in bytes
*
* This function is called when EAP-Response/Nak is received from the
* supplicant. This can happen for both phase 1 and phase 2 authentications.
*/
void eap_sm_process_nak(struct eap_sm *sm, const u8 *nak_list, size_t len)
{
int i;
size_t j;
if (sm->user == NULL)
return;
wpa_printf(MSG_MSGDUMP, "EAP: processing NAK (current EAP method "
"index %d)", sm->user_eap_method_index);
wpa_hexdump(MSG_MSGDUMP, "EAP: configured methods",
(u8 *) sm->user->methods,
EAP_MAX_METHODS * sizeof(sm->user->methods[0]));
wpa_hexdump(MSG_MSGDUMP, "EAP: list of methods supported by the peer",
nak_list, len);
i = sm->user_eap_method_index;
while (i < EAP_MAX_METHODS &&
(sm->user->methods[i].vendor != EAP_VENDOR_IETF ||
sm->user->methods[i].method != EAP_TYPE_NONE)) {
if (sm->user->methods[i].vendor != EAP_VENDOR_IETF)
goto not_found;
for (j = 0; j < len; j++) {
if (nak_list[j] == sm->user->methods[i].method) {
break;
}
}
if (j < len) {
/* found */
i++;
continue;
}
not_found:
/* not found - remove from the list */
if (i + 1 < EAP_MAX_METHODS) {
os_memmove(&sm->user->methods[i],
&sm->user->methods[i + 1],
(EAP_MAX_METHODS - i - 1) *
sizeof(sm->user->methods[0]));
}
sm->user->methods[EAP_MAX_METHODS - 1].vendor =
EAP_VENDOR_IETF;
sm->user->methods[EAP_MAX_METHODS - 1].method = EAP_TYPE_NONE;
}
wpa_hexdump(MSG_MSGDUMP, "EAP: new list of configured methods",
(u8 *) sm->user->methods, EAP_MAX_METHODS *
sizeof(sm->user->methods[0]));
}
static void eap_sm_Policy_update(struct eap_sm *sm, const u8 *nak_list,
size_t len)
{
if (nak_list == NULL || sm == NULL || sm->user == NULL)
return;
if (sm->user->phase2) {
wpa_printf(MSG_DEBUG, "EAP: EAP-Nak received after Phase2 user"
" info was selected - reject");
sm->decision = DECISION_FAILURE;
return;
}
eap_sm_process_nak(sm, nak_list, len);
}
static EapType eap_sm_Policy_getNextMethod(struct eap_sm *sm, int *vendor)
{
EapType next;
int idx = sm->user_eap_method_index;
/* In theory, there should be no problems with starting
* re-authentication with something else than EAP-Request/Identity and
* this does indeed work with wpa_supplicant. However, at least Funk
* Supplicant seemed to ignore re-auth if it skipped
* EAP-Request/Identity.
* Re-auth sets currentId == -1, so that can be used here to select
* whether Identity needs to be requested again. */
if (sm->identity == NULL || sm->currentId == -1) {
*vendor = EAP_VENDOR_IETF;
next = EAP_TYPE_IDENTITY;
sm->update_user = TRUE;
} else if (sm->user && idx < EAP_MAX_METHODS &&
(sm->user->methods[idx].vendor != EAP_VENDOR_IETF ||
sm->user->methods[idx].method != EAP_TYPE_NONE)) {
*vendor = sm->user->methods[idx].vendor;
next = sm->user->methods[idx].method;
sm->user_eap_method_index++;
} else {
*vendor = EAP_VENDOR_IETF;
next = EAP_TYPE_NONE;
}
wpa_printf(MSG_DEBUG, "EAP: getNextMethod: vendor %d type %d",
*vendor, next);
return next;
}
static int eap_sm_Policy_getDecision(struct eap_sm *sm)
{
if (!sm->eap_server && sm->identity && !sm->start_reauth) {
wpa_printf(MSG_DEBUG, "EAP: getDecision: -> PASSTHROUGH");
return DECISION_PASSTHROUGH;
}
if (sm->m && sm->currentMethod != EAP_TYPE_IDENTITY &&
sm->m->isSuccess(sm, sm->eap_method_priv)) {
wpa_printf(MSG_DEBUG, "EAP: getDecision: method succeeded -> "
"SUCCESS");
sm->update_user = TRUE;
return DECISION_SUCCESS;
}
if (sm->m && sm->m->isDone(sm, sm->eap_method_priv) &&
!sm->m->isSuccess(sm, sm->eap_method_priv)) {
wpa_printf(MSG_DEBUG, "EAP: getDecision: method failed -> "
"FAILURE");
sm->update_user = TRUE;
return DECISION_FAILURE;
}
if ((sm->user == NULL || sm->update_user) && sm->identity &&
!sm->start_reauth) {
/*
* Allow Identity method to be started once to allow identity
* selection hint to be sent from the authentication server,
* but prevent a loop of Identity requests by only allowing
* this to happen once.
*/
int id_req = 0;
if (sm->user && sm->currentMethod == EAP_TYPE_IDENTITY &&
sm->user->methods[0].vendor == EAP_VENDOR_IETF &&
sm->user->methods[0].method == EAP_TYPE_IDENTITY)
id_req = 1;
if (eap_user_get(sm, sm->identity, sm->identity_len, 0) != 0) {
wpa_printf(MSG_DEBUG, "EAP: getDecision: user not "
"found from database -> FAILURE");
return DECISION_FAILURE;
}
if (id_req && sm->user &&
sm->user->methods[0].vendor == EAP_VENDOR_IETF &&
sm->user->methods[0].method == EAP_TYPE_IDENTITY) {
wpa_printf(MSG_DEBUG, "EAP: getDecision: stop "
"identity request loop -> FAILURE");
sm->update_user = TRUE;
return DECISION_FAILURE;
}
sm->update_user = FALSE;
}
sm->start_reauth = FALSE;
if (sm->user && sm->user_eap_method_index < EAP_MAX_METHODS &&
(sm->user->methods[sm->user_eap_method_index].vendor !=
EAP_VENDOR_IETF ||
sm->user->methods[sm->user_eap_method_index].method !=
EAP_TYPE_NONE)) {
wpa_printf(MSG_DEBUG, "EAP: getDecision: another method "
"available -> CONTINUE");
return DECISION_CONTINUE;
}
if (sm->identity == NULL || sm->currentId == -1) {
wpa_printf(MSG_DEBUG, "EAP: getDecision: no identity known "
"yet -> CONTINUE");
return DECISION_CONTINUE;
}
wpa_printf(MSG_DEBUG, "EAP: getDecision: no more methods available -> "
"FAILURE");
return DECISION_FAILURE;
}
static Boolean eap_sm_Policy_doPickUp(struct eap_sm *sm, EapType method)
{
return method == EAP_TYPE_IDENTITY ? TRUE : FALSE;
}
/**
* eap_server_sm_step - Step EAP server state machine
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
* Returns: 1 if EAP state was changed or 0 if not
*
* This function advances EAP state machine to a new state to match with the
* current variables. This should be called whenever variables used by the EAP
* state machine have changed.
*/
int eap_server_sm_step(struct eap_sm *sm)
{
int res = 0;
do {
sm->changed = FALSE;
SM_STEP_RUN(EAP);
if (sm->changed)
res = 1;
} while (sm->changed);
return res;
}
static void eap_user_free(struct eap_user *user)
{
if (user == NULL)
return;
os_free(user->password);
user->password = NULL;
os_free(user);
}
/**
* eap_server_sm_init - Allocate and initialize EAP server state machine
* @eapol_ctx: Context data to be used with eapol_cb calls
* @eapol_cb: Pointer to EAPOL callback functions
* @conf: EAP configuration
* Returns: Pointer to the allocated EAP state machine or %NULL on failure
*
* This function allocates and initializes an EAP state machine.
*/
struct eap_sm * eap_server_sm_init(void *eapol_ctx,
struct eapol_callbacks *eapol_cb,
struct eap_config *conf)
{
struct eap_sm *sm;
sm = os_zalloc(sizeof(*sm));
if (sm == NULL)
return NULL;
sm->eapol_ctx = eapol_ctx;
sm->eapol_cb = eapol_cb;
sm->MaxRetrans = 5; /* RFC 3748: max 3-5 retransmissions suggested */
sm->ssl_ctx = conf->ssl_ctx;
sm->msg_ctx = conf->msg_ctx;
sm->eap_sim_db_priv = conf->eap_sim_db_priv;
sm->backend_auth = conf->backend_auth;
sm->eap_server = conf->eap_server;
if (conf->pac_opaque_encr_key) {
sm->pac_opaque_encr_key = os_malloc(16);
if (sm->pac_opaque_encr_key) {
os_memcpy(sm->pac_opaque_encr_key,
conf->pac_opaque_encr_key, 16);
}
}
if (conf->eap_fast_a_id) {
sm->eap_fast_a_id = os_malloc(conf->eap_fast_a_id_len);
if (sm->eap_fast_a_id) {
os_memcpy(sm->eap_fast_a_id, conf->eap_fast_a_id,
conf->eap_fast_a_id_len);
sm->eap_fast_a_id_len = conf->eap_fast_a_id_len;
}
}
if (conf->eap_fast_a_id_info)
sm->eap_fast_a_id_info = os_strdup(conf->eap_fast_a_id_info);
sm->eap_fast_prov = conf->eap_fast_prov;
sm->pac_key_lifetime = conf->pac_key_lifetime;
sm->pac_key_refresh_time = conf->pac_key_refresh_time;
sm->eap_sim_aka_result_ind = conf->eap_sim_aka_result_ind;
sm->tnc = conf->tnc;
sm->wps = conf->wps;
if (conf->assoc_wps_ie)
sm->assoc_wps_ie = wpabuf_dup(conf->assoc_wps_ie);
if (conf->assoc_p2p_ie)
sm->assoc_p2p_ie = wpabuf_dup(conf->assoc_p2p_ie);
if (conf->peer_addr)
os_memcpy(sm->peer_addr, conf->peer_addr, ETH_ALEN);
sm->fragment_size = conf->fragment_size;
sm->pwd_group = conf->pwd_group;
sm->pbc_in_m1 = conf->pbc_in_m1;
sm->server_id = conf->server_id;
sm->server_id_len = conf->server_id_len;
wpa_printf(MSG_DEBUG, "EAP: Server state machine created");
return sm;
}
/**
* eap_server_sm_deinit - Deinitialize and free an EAP server state machine
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
*
* This function deinitializes EAP state machine and frees all allocated
* resources.
*/
void eap_server_sm_deinit(struct eap_sm *sm)
{
if (sm == NULL)
return;
wpa_printf(MSG_DEBUG, "EAP: Server state machine removed");
if (sm->m && sm->eap_method_priv)
sm->m->reset(sm, sm->eap_method_priv);
wpabuf_free(sm->eap_if.eapReqData);
os_free(sm->eap_if.eapKeyData);
wpabuf_free(sm->lastReqData);
wpabuf_free(sm->eap_if.eapRespData);
os_free(sm->identity);
os_free(sm->pac_opaque_encr_key);
os_free(sm->eap_fast_a_id);
os_free(sm->eap_fast_a_id_info);
wpabuf_free(sm->eap_if.aaaEapReqData);
wpabuf_free(sm->eap_if.aaaEapRespData);
os_free(sm->eap_if.aaaEapKeyData);
eap_user_free(sm->user);
wpabuf_free(sm->assoc_wps_ie);
wpabuf_free(sm->assoc_p2p_ie);
os_free(sm);
}
/**
* eap_sm_notify_cached - Notify EAP state machine of cached PMK
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
*
* This function is called when PMKSA caching is used to skip EAP
* authentication.
*/
void eap_sm_notify_cached(struct eap_sm *sm)
{
if (sm == NULL)
return;
sm->EAP_state = EAP_SUCCESS;
}
/**
* eap_sm_pending_cb - EAP state machine callback for a pending EAP request
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
*
* This function is called when data for a pending EAP-Request is received.
*/
void eap_sm_pending_cb(struct eap_sm *sm)
{
if (sm == NULL)
return;
wpa_printf(MSG_DEBUG, "EAP: Callback for pending request received");
if (sm->method_pending == METHOD_PENDING_WAIT)
sm->method_pending = METHOD_PENDING_CONT;
}
/**
* eap_sm_method_pending - Query whether EAP method is waiting for pending data
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
* Returns: 1 if method is waiting for pending data or 0 if not
*/
int eap_sm_method_pending(struct eap_sm *sm)
{
if (sm == NULL)
return 0;
return sm->method_pending == METHOD_PENDING_WAIT;
}
/**
* eap_get_identity - Get the user identity (from EAP-Response/Identity)
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
* @len: Buffer for returning identity length
* Returns: Pointer to the user identity or %NULL if not available
*/
const u8 * eap_get_identity(struct eap_sm *sm, size_t *len)
{
*len = sm->identity_len;
return sm->identity;
}
/**
* eap_get_interface - Get pointer to EAP-EAPOL interface data
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
* Returns: Pointer to the EAP-EAPOL interface data
*/
struct eap_eapol_interface * eap_get_interface(struct eap_sm *sm)
{
return &sm->eap_if;
}
/**
* eap_server_clear_identity - Clear EAP identity information
* @sm: Pointer to EAP state machine allocated with eap_server_sm_init()
*
* This function can be used to clear the EAP identity information in the EAP
* server context. This allows the EAP/Identity method to be used again after
* EAPOL-Start or EAPOL-Logoff.
*/
void eap_server_clear_identity(struct eap_sm *sm)
{
os_free(sm->identity);
sm->identity = NULL;
}