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33 #include "gssapiP_eap.h"
35 #define EAP_MAX_METHODS 8
37 #define EAP_TTLS_AUTH_PAP 1
38 #define EAP_TTLS_AUTH_CHAP 2
39 #define EAP_TTLS_AUTH_MSCHAP 4
40 #define EAP_TTLS_AUTH_MSCHAPV2 8
47 } methods[EAP_MAX_METHODS];
50 int password_hash; /* whether password is hashed with
51 * nt_password_hash() */
54 int ttls_auth; /* bitfield of
55 * EAP_TTLS_AUTH_{PAP,CHAP,MSCHAP,MSCHAPV2} */
58 struct eap_eapol_interface {
59 /* Lower layer to full authenticator variables */
60 Boolean eapResp; /* shared with EAPOL Backend Authentication */
61 struct wpabuf *eapRespData;
64 Boolean eapRestart; /* shared with EAPOL Authenticator PAE */
68 /* Full authenticator to lower layer variables */
69 Boolean eapReq; /* shared with EAPOL Backend Authentication */
70 Boolean eapNoReq; /* shared with EAPOL Backend Authentication */
74 struct wpabuf *eapReqData;
77 Boolean eapKeyAvailable; /* called keyAvailable in IEEE 802.1X-2004 */
79 /* AAA interface to full authenticator variables */
84 struct wpabuf *aaaEapReqData;
86 size_t aaaEapKeyDataLen;
87 Boolean aaaEapKeyAvailable;
90 /* Full authenticator to AAA interface variables */
92 struct wpabuf *aaaEapRespData;
93 /* aaaIdentity -> eap_get_identity() */
97 #define eapol_callbacks SERVER_eapol_callbacks
99 struct eapol_callbacks {
100 int (*get_eap_user)(void *ctx, const u8 *identity, size_t identity_len,
101 int phase2, struct eap_user *user);
102 const char * (*get_eap_req_id_text)(void *ctx, size_t *len);
105 #define eap_config SERVER_eap_config
110 void *eap_sim_db_priv;
111 Boolean backend_auth;
113 u8 *pac_opaque_encr_key;
115 size_t eap_fast_a_id_len;
116 char *eap_fast_a_id_info;
118 int pac_key_lifetime;
119 int pac_key_refresh_time;
120 int eap_sim_aka_result_ind;
122 struct wps_context *wps;
123 const struct wpabuf *assoc_wps_ie;
128 struct eap_sm * eap_server_sm_init(void *eapol_ctx,
129 struct eapol_callbacks *eapol_cb,
130 struct eap_config *eap_conf);
131 void eap_server_sm_deinit(struct eap_sm *sm);
132 int eap_server_sm_step(struct eap_sm *sm);
133 void eap_sm_notify_cached(struct eap_sm *sm);
134 void eap_sm_pending_cb(struct eap_sm *sm);
135 int eap_sm_method_pending(struct eap_sm *sm);
136 const u8 * eap_get_identity(struct eap_sm *sm, size_t *len);
137 struct eap_eapol_interface * eap_get_interface(struct eap_sm *sm);
140 initTls(OM_uint32 *minor,
143 struct tls_config tconf;
144 struct tls_connection_params tparams;
146 memset(&tconf, 0, sizeof(tconf));
147 ctx->acceptorCtx.tlsContext = tls_init(&tconf);
148 if (ctx->acceptorCtx.tlsContext == NULL)
149 return GSS_S_FAILURE;
151 memset(&tparams, 0, sizeof(tparams));
152 tparams.ca_cert = "ca.pem";
153 tparams.client_cert = "server.pem";
154 tparams.private_key = "server-key.pem";
156 if (tls_global_set_params(ctx->acceptorCtx.tlsContext, &tparams)) {
157 return GSS_S_FAILURE;
160 if (tls_global_set_verify(ctx->acceptorCtx.tlsContext, 0)) {
161 return GSS_S_FAILURE;
164 return GSS_S_COMPLETE;
168 serverGetEapUser(void *ctx,
169 const unsigned char *identity,
170 size_t identityLength,
172 struct eap_user *user)
174 gss_ctx_id_t gssCtx = (gss_ctx_id_t)ctx;
175 OM_uint32 major, minor;
178 memset(user, 0, sizeof(*user));
180 buf.length = identityLength;
181 buf.value = (void *)identity;
184 user->methods[0].vendor = EAP_VENDOR_IETF;
185 user->methods[0].method = EAP_TYPE_PEAP;
189 major = gssEapImportName(&minor, &buf, GSS_C_NT_USER_NAME,
190 &gssCtx->initiatorName);
191 if (GSS_ERROR(major))
195 * OK, obviously there is no real security here, this is simply
196 * for testing the token exchange; this code will be completely
197 * replaced with libradsec once that library is available.
199 user->methods[0].vendor = EAP_VENDOR_IETF;
200 user->methods[0].method = EAP_TYPE_MSCHAPV2;
201 user->password = (unsigned char *)strdup(" ");
202 user->password_len = 1;
208 serverGetEapReqIdText(void *ctx,
217 completeAccept(OM_uint32 *minor, gss_ctx_id_t ctx)
220 krb5_context krbContext;
222 GSSEAP_KRB_INIT(&krbContext);
224 /* Cache encryption type derived from selected mechanism OID */
225 major = gssEapOidToEnctype(minor, ctx->mechanismUsed, &ctx->encryptionType);
226 if (GSS_ERROR(major))
229 if (ctx->encryptionType != ENCTYPE_NULL &&
230 ctx->acceptorCtx.eapPolInterface->eapKeyAvailable) {
231 major = gssEapDeriveRFC3961Key(minor,
232 ctx->acceptorCtx.eapPolInterface->eapKeyData,
233 ctx->acceptorCtx.eapPolInterface->eapKeyDataLen,
236 if (GSS_ERROR(major))
240 * draft-howlett-eap-gss says that integrity/confidentialty should
241 * always be advertised as available, but if we have no keying
242 * material it seems confusing to the caller to advertise this.
244 ctx->gssFlags &= ~(GSS_C_INTEG_FLAG | GSS_C_CONF_FLAG);
247 sequenceInit(&ctx->seqState, ctx->recvSeq,
248 ((ctx->gssFlags & GSS_C_REPLAY_FLAG) != 0),
249 ((ctx->gssFlags & GSS_C_SEQUENCE_FLAG) != 0),
252 return GSS_S_COMPLETE;
256 eapGssSmAcceptAuthenticate(OM_uint32 *minor,
259 gss_buffer_t inputToken,
260 gss_channel_bindings_t chanBindings,
261 gss_buffer_t outputToken)
264 OM_uint32 tmpMinor, tmpMajor;
266 struct wpabuf respData;
267 static struct eapol_callbacks cb = { serverGetEapUser, serverGetEapReqIdText };
269 if (ctx->acceptorCtx.eap == NULL) {
270 struct eap_config eapConfig;
272 major = initTls(minor, ctx);
273 if (GSS_ERROR(major))
276 memset(&eapConfig, 0, sizeof(eapConfig));
277 eapConfig.eap_server = 1;
278 eapConfig.ssl_ctx = ctx->acceptorCtx.tlsContext;
280 ctx->acceptorCtx.eap = eap_server_sm_init(ctx, &cb, &eapConfig);
281 if (ctx->acceptorCtx.eap == NULL) {
282 major = GSS_S_FAILURE;
286 ctx->acceptorCtx.eapPolInterface = eap_get_interface(ctx->acceptorCtx.eap);
287 ctx->acceptorCtx.eapPolInterface->portEnabled = TRUE;
288 ctx->acceptorCtx.eapPolInterface->eapRestart = TRUE;
291 if (ctx->acceptorName == GSS_C_NO_NAME &&
292 cred != GSS_C_NO_CREDENTIAL &&
293 cred->name != GSS_C_NO_NAME) {
294 major = gss_duplicate_name(minor, cred->name, &ctx->acceptorName);
295 if (GSS_ERROR(major))
299 wpabuf_set(&respData, inputToken->value, inputToken->length);
300 ctx->acceptorCtx.eapPolInterface->eapRespData = &respData;
301 ctx->acceptorCtx.eapPolInterface->eapResp = TRUE;
303 code = eap_server_sm_step(ctx->acceptorCtx.eap);
305 if (ctx->acceptorCtx.eapPolInterface->eapReq) {
306 ctx->acceptorCtx.eapPolInterface->eapReq = 0;
307 major = GSS_S_CONTINUE_NEEDED;
310 if (ctx->acceptorCtx.eapPolInterface->eapSuccess) {
311 ctx->acceptorCtx.eapPolInterface->eapSuccess = 0;
312 ctx->state = EAP_STATE_ESTABLISHED;
313 major = completeAccept(minor, ctx);
314 } else if (ctx->acceptorCtx.eapPolInterface->eapFail) {
315 ctx->acceptorCtx.eapPolInterface->eapFail = 0;
316 major = GSS_S_FAILURE;
317 } else if (code == 0) {
318 major = GSS_S_FAILURE;
321 if (ctx->acceptorCtx.eapPolInterface->eapReqData != NULL) {
324 buf.length = wpabuf_len(ctx->acceptorCtx.eapPolInterface->eapReqData);
325 buf.value = (void *)wpabuf_head(ctx->acceptorCtx.eapPolInterface->eapReqData);
327 tmpMajor = duplicateBuffer(&tmpMinor, &buf, outputToken);
328 if (GSS_ERROR(tmpMajor)) {
336 ctx->acceptorCtx.eapPolInterface->eapRespData = NULL;
342 eapGssSmAcceptEstablished(OM_uint32 *minor,
345 gss_buffer_t inputToken,
346 gss_channel_bindings_t chanBindings,
347 gss_buffer_t outputToken)
349 /* Called with already established context */
351 return GSS_S_BAD_STATUS;
354 static struct eap_gss_acceptor_sm {
355 enum gss_eap_token_type inputTokenType;
356 enum gss_eap_token_type outputTokenType;
357 OM_uint32 (*processToken)(OM_uint32 *,
361 gss_channel_bindings_t,
363 } eapGssAcceptorSm[] = {
364 { TOK_TYPE_EAP_RESP, TOK_TYPE_EAP_REQ, eapGssSmAcceptAuthenticate },
365 { TOK_TYPE_EAP_RESP, TOK_TYPE_EAP_REQ, NULL },
366 { TOK_TYPE_EAP_RESP, TOK_TYPE_EAP_REQ, NULL },
367 { TOK_TYPE_GSS_CB, TOK_TYPE_NONE, NULL },
368 { TOK_TYPE_NONE, TOK_TYPE_NONE, eapGssSmAcceptEstablished },
372 gss_accept_sec_context(OM_uint32 *minor,
373 gss_ctx_id_t *context_handle,
375 gss_buffer_t input_token,
376 gss_channel_bindings_t input_chan_bindings,
377 gss_name_t *src_name,
379 gss_buffer_t output_token,
380 OM_uint32 *ret_flags,
382 gss_cred_id_t *delegated_cred_handle)
385 OM_uint32 tmpMajor, tmpMinor;
386 gss_ctx_id_t ctx = *context_handle;
387 struct eap_gss_acceptor_sm *sm = NULL;
388 gss_buffer_desc innerInputToken, innerOutputToken;
392 innerOutputToken.length = 0;
393 innerOutputToken.value = NULL;
395 output_token->length = 0;
396 output_token->value = NULL;
398 if (cred != GSS_C_NO_CREDENTIAL && !(cred->flags & CRED_FLAG_ACCEPT)) {
399 return GSS_S_NO_CRED;
402 if (input_token == GSS_C_NO_BUFFER || input_token->length == 0) {
403 return GSS_S_DEFECTIVE_TOKEN;
406 if (ctx == GSS_C_NO_CONTEXT) {
407 major = gssEapAllocContext(minor, &ctx);
408 if (GSS_ERROR(major))
411 *context_handle = ctx;
414 GSSEAP_MUTEX_LOCK(&ctx->mutex);
416 sm = &eapGssAcceptorSm[ctx->state];
418 major = gssEapVerifyToken(minor, ctx, input_token,
419 sm->inputTokenType, &innerInputToken);
420 if (GSS_ERROR(major))
424 major = (sm->processToken)(minor,
430 if (GSS_ERROR(major))
432 } while (major == GSS_S_CONTINUE_NEEDED && innerOutputToken.length == 0);
434 if (mech_type != NULL) {
435 if (!gssEapInternalizeOid(ctx->mechanismUsed, mech_type))
436 duplicateOid(&tmpMinor, ctx->mechanismUsed, mech_type);
438 if (innerOutputToken.length != 0) {
439 tmpMajor = gssEapMakeToken(&tmpMinor, ctx, &innerOutputToken,
440 sm->outputTokenType, output_token);
441 if (GSS_ERROR(tmpMajor)) {
447 if (ret_flags != NULL)
448 *ret_flags = ctx->gssFlags;
449 if (delegated_cred_handle != NULL)
450 *delegated_cred_handle = GSS_C_NO_CREDENTIAL;
452 if (major == GSS_S_COMPLETE) {
453 if (src_name != NULL && ctx->initiatorName != GSS_C_NO_NAME) {
454 major = gss_duplicate_name(&tmpMinor, ctx->initiatorName, src_name);
455 if (GSS_ERROR(major))
458 if (time_rec != NULL)
459 gss_context_time(&tmpMinor, ctx, time_rec);
462 assert(ctx->state == EAP_STATE_ESTABLISHED || major == GSS_S_CONTINUE_NEEDED);
465 GSSEAP_MUTEX_UNLOCK(&ctx->mutex);
467 if (GSS_ERROR(major))
468 gssEapReleaseContext(&tmpMinor, context_handle);
470 gss_release_buffer(&tmpMinor, &innerOutputToken);