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34 * Establish a security context on the acceptor (server). These functions
35 * wrap around libradsec and (thus) talk to a RADIUS server or proxy.
38 #include "gssapiP_eap.h"
40 #ifdef GSSEAP_ENABLE_REAUTH
42 eapGssSmAcceptGssReauth(OM_uint32 *minor,
49 gss_channel_bindings_t chanBindings,
50 gss_buffer_t inputToken,
51 gss_buffer_t outputToken,
56 * Mark an acceptor context as ready for cryptographic operations
59 acceptReadyEap(OM_uint32 *minor, gss_ctx_id_t ctx, gss_cred_id_t cred)
61 OM_uint32 major, tmpMinor;
63 gss_buffer_desc nameBuf = GSS_C_EMPTY_BUFFER;
65 /* Cache encryption type derived from selected mechanism OID */
66 major = gssEapOidToEnctype(minor, ctx->mechanismUsed,
67 &ctx->encryptionType);
71 gssEapReleaseName(&tmpMinor, &ctx->initiatorName);
73 major = gssEapRadiusGetRawAvp(minor, ctx->acceptorCtx.vps,
74 PW_USER_NAME, 0, &vp);
75 if (major == GSS_S_COMPLETE && vp->length) {
76 nameBuf.length = vp->length;
77 nameBuf.value = vp->vp_strvalue;
79 ctx->gssFlags |= GSS_C_ANON_FLAG;
82 major = gssEapImportName(minor, &nameBuf,
83 (ctx->gssFlags & GSS_C_ANON_FLAG) ?
84 GSS_C_NT_ANONYMOUS : GSS_C_NT_USER_NAME,
90 major = gssEapRadiusGetRawAvp(minor, ctx->acceptorCtx.vps,
91 PW_MS_MPPE_SEND_KEY, VENDORPEC_MS, &vp);
92 if (GSS_ERROR(major)) {
93 *minor = GSSEAP_KEY_UNAVAILABLE;
94 return GSS_S_UNAVAILABLE;
97 major = gssEapDeriveRfc3961Key(minor,
102 if (GSS_ERROR(major))
105 major = rfc3961ChecksumTypeForKey(minor, &ctx->rfc3961Key,
107 if (GSS_ERROR(major))
110 major = sequenceInit(minor,
111 &ctx->seqState, ctx->recvSeq,
112 ((ctx->gssFlags & GSS_C_REPLAY_FLAG) != 0),
113 ((ctx->gssFlags & GSS_C_SEQUENCE_FLAG) != 0),
115 if (GSS_ERROR(major))
118 major = gssEapCreateAttrContext(minor, cred, ctx,
119 &ctx->initiatorName->attrCtx,
121 if (GSS_ERROR(major))
124 if (ctx->expiryTime != 0 && ctx->expiryTime < time(NULL)) {
125 *minor = GSSEAP_CRED_EXPIRED;
126 return GSS_S_CREDENTIALS_EXPIRED;
130 return GSS_S_COMPLETE;
134 eapGssSmAcceptAcceptorName(OM_uint32 *minor,
135 gss_cred_id_t cred GSSEAP_UNUSED,
137 gss_name_t target GSSEAP_UNUSED,
138 gss_OID mech GSSEAP_UNUSED,
139 OM_uint32 reqFlags GSSEAP_UNUSED,
140 OM_uint32 timeReq GSSEAP_UNUSED,
141 gss_channel_bindings_t chanBindings GSSEAP_UNUSED,
142 gss_buffer_t inputToken GSSEAP_UNUSED,
143 gss_buffer_t outputToken,
144 OM_uint32 *smFlags GSSEAP_UNUSED)
148 /* XXX TODO import and validate name from inputToken */
150 if (ctx->acceptorName != GSS_C_NO_NAME) {
151 /* Send desired target name to acceptor */
152 major = gssEapDisplayName(minor, ctx->acceptorName,
154 if (GSS_ERROR(major))
158 return GSS_S_CONTINUE_NEEDED;
163 eapGssSmAcceptVendorInfo(OM_uint32 *minor,
164 gss_cred_id_t cred GSSEAP_UNUSED,
165 gss_ctx_id_t ctx GSSEAP_UNUSED,
166 gss_name_t target GSSEAP_UNUSED,
167 gss_OID mech GSSEAP_UNUSED,
168 OM_uint32 reqFlags GSSEAP_UNUSED,
169 OM_uint32 timeReq GSSEAP_UNUSED,
170 gss_channel_bindings_t chanBindings GSSEAP_UNUSED,
171 gss_buffer_t inputToken,
172 gss_buffer_t outputToken GSSEAP_UNUSED,
173 OM_uint32 *smFlags GSSEAP_UNUSED)
175 fprintf(stderr, "GSS-EAP: vendor: %.*s\n",
176 (int)inputToken->length, (char *)inputToken->value);
179 return GSS_S_CONTINUE_NEEDED;
185 * Emit a identity EAP request to force the initiator (peer) to identify
189 eapGssSmAcceptIdentity(OM_uint32 *minor,
192 gss_name_t target GSSEAP_UNUSED,
193 gss_OID mech GSSEAP_UNUSED,
194 OM_uint32 reqFlags GSSEAP_UNUSED,
195 OM_uint32 timeReq GSSEAP_UNUSED,
196 gss_channel_bindings_t chanBindings GSSEAP_UNUSED,
197 gss_buffer_t inputToken,
198 gss_buffer_t outputToken,
202 struct wpabuf *reqData;
203 gss_buffer_desc pktBuffer;
205 if (!gssEapCredAvailable(cred, ctx->mechanismUsed)) {
206 *minor = GSSEAP_CRED_MECH_MISMATCH;
207 return GSS_S_BAD_MECH;
210 if (inputToken != GSS_C_NO_BUFFER && inputToken->length != 0) {
211 *minor = GSSEAP_WRONG_SIZE;
212 return GSS_S_DEFECTIVE_TOKEN;
215 reqData = eap_msg_alloc(EAP_VENDOR_IETF, EAP_TYPE_IDENTITY, 0,
216 EAP_CODE_REQUEST, 0);
217 if (reqData == NULL) {
219 return GSS_S_FAILURE;
222 pktBuffer.length = wpabuf_len(reqData);
223 pktBuffer.value = (void *)wpabuf_head(reqData);
225 major = duplicateBuffer(minor, &pktBuffer, outputToken);
226 if (GSS_ERROR(major))
229 wpabuf_free(reqData);
231 GSSEAP_SM_TRANSITION_NEXT(ctx);
234 *smFlags |= SM_FLAG_OUTPUT_TOKEN_CRITICAL;
236 return GSS_S_CONTINUE_NEEDED;
240 * Returns TRUE if the input token contains an EAP identity response.
243 isIdentityResponseP(gss_buffer_t inputToken)
245 struct wpabuf respData;
247 wpabuf_set(&respData, inputToken->value, inputToken->length);
249 return (eap_get_type(&respData) == EAP_TYPE_IDENTITY);
253 * Save the asserted initiator identity from the EAP identity response.
256 importInitiatorIdentity(OM_uint32 *minor,
258 gss_buffer_t inputToken)
261 struct wpabuf respData;
262 const unsigned char *pos;
264 gss_buffer_desc nameBuf;
266 wpabuf_set(&respData, inputToken->value, inputToken->length);
268 pos = eap_hdr_validate(EAP_VENDOR_IETF, EAP_TYPE_IDENTITY,
271 *minor = GSSEAP_PEER_BAD_MESSAGE;
272 return GSS_S_DEFECTIVE_TOKEN;
275 nameBuf.value = (void *)pos;
276 nameBuf.length = len;
278 gssEapReleaseName(&tmpMinor, &ctx->initiatorName);
280 return gssEapImportName(minor, &nameBuf, GSS_C_NT_USER_NAME,
281 ctx->mechanismUsed, &ctx->initiatorName);
285 * Pass the asserted initiator identity to the authentication server.
288 setInitiatorIdentity(OM_uint32 *minor,
292 OM_uint32 major, tmpMinor;
293 gss_buffer_desc nameBuf;
296 * We should have got an EAP identity response, but if we didn't, then
297 * we will just avoid sending User-Name. Note that radsecproxy requires
298 * User-Name to be sent on every request (presumably so it can remain
301 if (ctx->initiatorName != GSS_C_NO_NAME) {
302 major = gssEapDisplayName(minor, ctx->initiatorName, &nameBuf, NULL);
303 if (GSS_ERROR(major))
306 major = gssEapRadiusAddAvp(minor, vps, PW_USER_NAME, 0, &nameBuf);
307 if (GSS_ERROR(major))
310 gss_release_buffer(&tmpMinor, &nameBuf);
314 return GSS_S_COMPLETE;
318 * Pass the asserted acceptor identity to the authentication server.
321 setAcceptorIdentity(OM_uint32 *minor,
326 gss_buffer_desc nameBuf;
327 krb5_context krbContext = NULL;
328 krb5_principal krbPrinc;
329 struct rs_context *rc = ctx->acceptorCtx.radContext;
331 GSSEAP_ASSERT(rc != NULL);
333 if (ctx->acceptorName == GSS_C_NO_NAME) {
335 return GSS_S_COMPLETE;
338 if ((ctx->acceptorName->flags & NAME_FLAG_SERVICE) == 0) {
339 *minor = GSSEAP_BAD_SERVICE_NAME;
340 return GSS_S_BAD_NAME;
343 GSSEAP_KRB_INIT(&krbContext);
345 krbPrinc = ctx->acceptorName->krbPrincipal;
346 GSSEAP_ASSERT(krbPrinc != NULL);
347 GSSEAP_ASSERT(KRB_PRINC_LENGTH(krbPrinc) >= 2);
349 /* Acceptor-Service-Name */
350 krbPrincComponentToGssBuffer(krbPrinc, 0, &nameBuf);
352 major = gssEapRadiusAddAvp(minor, vps,
353 PW_GSS_ACCEPTOR_SERVICE_NAME,
356 if (GSS_ERROR(major))
359 /* Acceptor-Host-Name */
360 krbPrincComponentToGssBuffer(krbPrinc, 1, &nameBuf);
362 major = gssEapRadiusAddAvp(minor, vps,
363 PW_GSS_ACCEPTOR_HOST_NAME,
366 if (GSS_ERROR(major))
369 if (KRB_PRINC_LENGTH(krbPrinc) > 2) {
370 /* Acceptor-Service-Specific */
371 krb5_principal_data ssiPrinc = *krbPrinc;
374 KRB_PRINC_LENGTH(&ssiPrinc) -= 2;
375 KRB_PRINC_NAME(&ssiPrinc) += 2;
377 *minor = krb5_unparse_name_flags(krbContext, &ssiPrinc,
378 KRB5_PRINCIPAL_UNPARSE_NO_REALM, &ssi);
380 return GSS_S_FAILURE;
383 nameBuf.length = strlen(ssi);
385 major = gssEapRadiusAddAvp(minor, vps,
386 PW_GSS_ACCEPTOR_SERVICE_SPECIFIC,
390 if (GSS_ERROR(major)) {
391 krb5_free_unparsed_name(krbContext, ssi);
394 krb5_free_unparsed_name(krbContext, ssi);
397 krbPrincRealmToGssBuffer(krbPrinc, &nameBuf);
398 if (nameBuf.length != 0) {
399 /* Acceptor-Realm-Name */
400 major = gssEapRadiusAddAvp(minor, vps,
401 PW_GSS_ACCEPTOR_REALM_NAME,
404 if (GSS_ERROR(major))
409 return GSS_S_COMPLETE;
413 * Allocate a RadSec handle
416 createRadiusHandle(OM_uint32 *minor,
420 struct gss_eap_acceptor_ctx *actx = &ctx->acceptorCtx;
421 struct rs_error *err;
422 const char *configStanza = "gss-eap";
425 GSSEAP_ASSERT(actx->radContext == NULL);
426 GSSEAP_ASSERT(actx->radConn == NULL);
427 GSSEAP_ASSERT(cred != GSS_C_NO_CREDENTIAL);
429 major = gssEapCreateRadiusContext(minor, cred, &actx->radContext);
430 if (GSS_ERROR(major))
433 if (cred->radiusConfigStanza.value != NULL)
434 configStanza = (const char *)cred->radiusConfigStanza.value;
436 if (rs_conn_create(actx->radContext, &actx->radConn, configStanza) != 0) {
437 err = rs_err_conn_pop(actx->radConn);
438 return gssEapRadiusMapError(minor, err);
441 if (actx->radServer != NULL) {
442 if (rs_conn_select_peer(actx->radConn, actx->radServer) != 0) {
443 err = rs_err_conn_pop(actx->radConn);
444 return gssEapRadiusMapError(minor, err);
449 return GSS_S_COMPLETE;
453 * Process a EAP response from the initiator.
456 eapGssSmAcceptAuthenticate(OM_uint32 *minor,
459 gss_name_t target GSSEAP_UNUSED,
460 gss_OID mech GSSEAP_UNUSED,
461 OM_uint32 reqFlags GSSEAP_UNUSED,
462 OM_uint32 timeReq GSSEAP_UNUSED,
463 gss_channel_bindings_t chanBindings GSSEAP_UNUSED,
464 gss_buffer_t inputToken,
465 gss_buffer_t outputToken,
468 OM_uint32 major, tmpMinor;
469 struct rs_connection *rconn;
470 struct rs_request *request = NULL;
471 struct rs_packet *req = NULL, *resp = NULL;
472 struct radius_packet *frreq, *frresp;
474 if (ctx->acceptorCtx.radContext == NULL) {
475 /* May be NULL from an imported partial context */
476 major = createRadiusHandle(minor, cred, ctx);
477 if (GSS_ERROR(major))
481 if (isIdentityResponseP(inputToken)) {
482 major = importInitiatorIdentity(minor, ctx, inputToken);
483 if (GSS_ERROR(major))
487 rconn = ctx->acceptorCtx.radConn;
489 if (rs_packet_create_authn_request(rconn, &req, NULL, NULL) != 0) {
490 major = gssEapRadiusMapError(minor, rs_err_conn_pop(rconn));
493 frreq = rs_packet_frpkt(req);
495 major = setInitiatorIdentity(minor, ctx, &frreq->vps);
496 if (GSS_ERROR(major))
499 major = setAcceptorIdentity(minor, ctx, &frreq->vps);
500 if (GSS_ERROR(major))
503 major = gssEapRadiusAddAvp(minor, &frreq->vps,
504 PW_EAP_MESSAGE, 0, inputToken);
505 if (GSS_ERROR(major))
508 if (ctx->acceptorCtx.state.length != 0) {
509 major = gssEapRadiusAddAvp(minor, &frreq->vps, PW_STATE, 0,
510 &ctx->acceptorCtx.state);
511 if (GSS_ERROR(major))
514 gss_release_buffer(&tmpMinor, &ctx->acceptorCtx.state);
517 if (rs_request_create(rconn, &request) != 0) {
518 major = gssEapRadiusMapError(minor, rs_err_conn_pop(rconn));
522 rs_request_add_reqpkt(request, req);
525 if (rs_request_send(request, &resp) != 0) {
526 major = gssEapRadiusMapError(minor, rs_err_conn_pop(rconn));
530 GSSEAP_ASSERT(resp != NULL);
532 frresp = rs_packet_frpkt(resp);
533 switch (frresp->code) {
534 case PW_ACCESS_CHALLENGE:
535 case PW_AUTHENTICATION_ACK:
537 case PW_AUTHENTICATION_REJECT:
538 *minor = GSSEAP_RADIUS_AUTH_FAILURE;
539 major = GSS_S_DEFECTIVE_CREDENTIAL;
543 *minor = GSSEAP_UNKNOWN_RADIUS_CODE;
544 major = GSS_S_FAILURE;
549 major = gssEapRadiusGetAvp(minor, frresp->vps, PW_EAP_MESSAGE, 0,
551 if (major == GSS_S_UNAVAILABLE && frresp->code == PW_ACCESS_CHALLENGE) {
552 *minor = GSSEAP_MISSING_EAP_REQUEST;
553 major = GSS_S_DEFECTIVE_TOKEN;
555 } else if (GSS_ERROR(major))
558 if (frresp->code == PW_ACCESS_CHALLENGE) {
559 major = gssEapRadiusGetAvp(minor, frresp->vps, PW_STATE, 0,
560 &ctx->acceptorCtx.state, TRUE);
561 if (GSS_ERROR(major) && *minor != GSSEAP_NO_SUCH_ATTR)
564 ctx->acceptorCtx.vps = frresp->vps;
567 major = acceptReadyEap(minor, ctx, cred);
568 if (GSS_ERROR(major))
571 GSSEAP_SM_TRANSITION_NEXT(ctx);
574 major = GSS_S_CONTINUE_NEEDED;
576 *smFlags |= SM_FLAG_OUTPUT_TOKEN_CRITICAL;
580 rs_request_destroy(request);
582 rs_packet_destroy(req);
584 rs_packet_destroy(resp);
585 if (GSSEAP_SM_STATE(ctx) == GSSEAP_STATE_INITIATOR_EXTS) {
586 GSSEAP_ASSERT(major == GSS_S_CONTINUE_NEEDED);
588 rs_conn_destroy(ctx->acceptorCtx.radConn);
589 ctx->acceptorCtx.radConn = NULL;
596 eapGssSmAcceptGssFlags(OM_uint32 *minor,
597 gss_cred_id_t cred GSSEAP_UNUSED,
599 gss_name_t target GSSEAP_UNUSED,
600 gss_OID mech GSSEAP_UNUSED,
601 OM_uint32 reqFlags GSSEAP_UNUSED,
602 OM_uint32 timeReq GSSEAP_UNUSED,
603 gss_channel_bindings_t chanBindings GSSEAP_UNUSED,
604 gss_buffer_t inputToken,
605 gss_buffer_t outputToken GSSEAP_UNUSED,
606 OM_uint32 *smFlags GSSEAP_UNUSED)
609 OM_uint32 initiatorGssFlags;
611 GSSEAP_ASSERT((ctx->flags & CTX_FLAG_KRB_REAUTH) == 0);
613 if (inputToken->length < 4) {
614 *minor = GSSEAP_TOK_TRUNC;
615 return GSS_S_DEFECTIVE_TOKEN;
618 /* allow flags to grow for future expansion */
619 p = (unsigned char *)inputToken->value + inputToken->length - 4;
621 initiatorGssFlags = load_uint32_be(p);
622 initiatorGssFlags &= GSSEAP_WIRE_FLAGS_MASK;
624 ctx->gssFlags |= initiatorGssFlags;
626 return GSS_S_CONTINUE_NEEDED;
630 eapGssSmAcceptGssChannelBindings(OM_uint32 *minor,
631 gss_cred_id_t cred GSSEAP_UNUSED,
633 gss_name_t target GSSEAP_UNUSED,
634 gss_OID mech GSSEAP_UNUSED,
635 OM_uint32 reqFlags GSSEAP_UNUSED,
636 OM_uint32 timeReq GSSEAP_UNUSED,
637 gss_channel_bindings_t chanBindings,
638 gss_buffer_t inputToken,
639 gss_buffer_t outputToken GSSEAP_UNUSED,
640 OM_uint32 *smFlags GSSEAP_UNUSED)
643 gss_iov_buffer_desc iov[2];
645 iov[0].type = GSS_IOV_BUFFER_TYPE_DATA | GSS_IOV_BUFFER_FLAG_ALLOCATE;
646 iov[0].buffer.length = 0;
647 iov[0].buffer.value = NULL;
649 iov[1].type = GSS_IOV_BUFFER_TYPE_STREAM | GSS_IOV_BUFFER_FLAG_ALLOCATED;
651 /* XXX necessary because decrypted in place and we verify it later */
652 major = duplicateBuffer(minor, inputToken, &iov[1].buffer);
653 if (GSS_ERROR(major))
656 major = gssEapUnwrapOrVerifyMIC(minor, ctx, NULL, NULL,
657 iov, 2, TOK_TYPE_WRAP);
658 if (GSS_ERROR(major)) {
659 gssEapReleaseIov(iov, 2);
663 if (chanBindings != GSS_C_NO_CHANNEL_BINDINGS &&
664 !bufferEqual(&iov[0].buffer, &chanBindings->application_data)) {
665 major = GSS_S_BAD_BINDINGS;
666 *minor = GSSEAP_BINDINGS_MISMATCH;
668 major = GSS_S_CONTINUE_NEEDED;
672 gssEapReleaseIov(iov, 2);
678 eapGssSmAcceptInitiatorMIC(OM_uint32 *minor,
679 gss_cred_id_t cred GSSEAP_UNUSED,
681 gss_name_t target GSSEAP_UNUSED,
682 gss_OID mech GSSEAP_UNUSED,
683 OM_uint32 reqFlags GSSEAP_UNUSED,
684 OM_uint32 timeReq GSSEAP_UNUSED,
685 gss_channel_bindings_t chanBindings GSSEAP_UNUSED,
686 gss_buffer_t inputToken,
687 gss_buffer_t outputToken GSSEAP_UNUSED,
688 OM_uint32 *smFlags GSSEAP_UNUSED)
692 major = gssEapVerifyTokenMIC(minor, ctx, inputToken);
693 if (GSS_ERROR(major))
696 GSSEAP_SM_TRANSITION_NEXT(ctx);
699 return GSS_S_CONTINUE_NEEDED;
702 #ifdef GSSEAP_ENABLE_REAUTH
704 eapGssSmAcceptReauthCreds(OM_uint32 *minor,
707 gss_name_t target GSSEAP_UNUSED,
708 gss_OID mech GSSEAP_UNUSED,
709 OM_uint32 reqFlags GSSEAP_UNUSED,
710 OM_uint32 timeReq GSSEAP_UNUSED,
711 gss_channel_bindings_t chanBindings GSSEAP_UNUSED,
712 gss_buffer_t inputToken GSSEAP_UNUSED,
713 gss_buffer_t outputToken,
714 OM_uint32 *smFlags GSSEAP_UNUSED)
719 * If we're built with fast reauthentication enabled, then
720 * fabricate a ticket from the initiator to ourselves.
722 major = gssEapMakeReauthCreds(minor, ctx, cred, outputToken);
723 if (major == GSS_S_UNAVAILABLE)
724 major = GSS_S_COMPLETE;
725 if (major == GSS_S_COMPLETE)
726 major = GSS_S_CONTINUE_NEEDED;
733 eapGssSmAcceptAcceptorMIC(OM_uint32 *minor,
734 gss_cred_id_t cred GSSEAP_UNUSED,
736 gss_name_t target GSSEAP_UNUSED,
737 gss_OID mech GSSEAP_UNUSED,
738 OM_uint32 reqFlags GSSEAP_UNUSED,
739 OM_uint32 timeReq GSSEAP_UNUSED,
740 gss_channel_bindings_t chanBindings GSSEAP_UNUSED,
741 gss_buffer_t inputToken GSSEAP_UNUSED,
742 gss_buffer_t outputToken,
747 major = gssEapMakeTokenMIC(minor, ctx, outputToken);
748 if (GSS_ERROR(major))
751 GSSEAP_SM_TRANSITION(ctx, GSSEAP_STATE_ESTABLISHED);
754 *smFlags |= SM_FLAG_OUTPUT_TOKEN_CRITICAL;
756 return GSS_S_COMPLETE;
759 static struct gss_eap_sm eapGssAcceptorSm[] = {
761 ITOK_TYPE_ACCEPTOR_NAME_REQ,
762 ITOK_TYPE_ACCEPTOR_NAME_RESP,
763 GSSEAP_STATE_INITIAL,
765 eapGssSmAcceptAcceptorName
769 ITOK_TYPE_VENDOR_INFO,
771 GSSEAP_STATE_INITIAL,
773 eapGssSmAcceptVendorInfo,
776 #ifdef GSSEAP_ENABLE_REAUTH
778 ITOK_TYPE_REAUTH_REQ,
779 ITOK_TYPE_REAUTH_RESP,
780 GSSEAP_STATE_INITIAL,
782 eapGssSmAcceptGssReauth,
788 GSSEAP_STATE_INITIAL,
789 SM_ITOK_FLAG_REQUIRED,
790 eapGssSmAcceptIdentity,
795 GSSEAP_STATE_AUTHENTICATE,
796 SM_ITOK_FLAG_REQUIRED,
797 eapGssSmAcceptAuthenticate
802 GSSEAP_STATE_INITIATOR_EXTS,
804 eapGssSmAcceptGssFlags
807 ITOK_TYPE_GSS_CHANNEL_BINDINGS,
809 GSSEAP_STATE_INITIATOR_EXTS,
810 SM_ITOK_FLAG_REQUIRED,
811 eapGssSmAcceptGssChannelBindings,
814 ITOK_TYPE_INITIATOR_MIC,
816 GSSEAP_STATE_INITIATOR_EXTS,
817 SM_ITOK_FLAG_REQUIRED,
818 eapGssSmAcceptInitiatorMIC,
820 #ifdef GSSEAP_ENABLE_REAUTH
823 ITOK_TYPE_REAUTH_CREDS,
824 GSSEAP_STATE_ACCEPTOR_EXTS,
826 eapGssSmAcceptReauthCreds,
831 ITOK_TYPE_ACCEPTOR_MIC,
832 GSSEAP_STATE_ACCEPTOR_EXTS,
834 eapGssSmAcceptAcceptorMIC
839 gssEapAcceptSecContext(OM_uint32 *minor,
842 gss_buffer_t input_token,
843 gss_channel_bindings_t input_chan_bindings,
844 gss_name_t *src_name,
846 gss_buffer_t output_token,
847 OM_uint32 *ret_flags,
849 gss_cred_id_t *delegated_cred_handle)
851 OM_uint32 major, tmpMinor;
853 if (cred == GSS_C_NO_CREDENTIAL) {
854 if (ctx->cred == GSS_C_NO_CREDENTIAL) {
855 major = gssEapAcquireCred(minor,
863 if (GSS_ERROR(major))
870 GSSEAP_MUTEX_LOCK(&cred->mutex);
873 * Calling gssEapInquireCred() forces the default acceptor credential name
876 major = gssEapInquireCred(minor, cred, &ctx->acceptorName, NULL, NULL, NULL);
877 if (GSS_ERROR(major))
880 major = gssEapSmStep(minor,
891 sizeof(eapGssAcceptorSm) / sizeof(eapGssAcceptorSm[0]));
892 if (GSS_ERROR(major))
895 if (mech_type != NULL) {
898 tmpMajor = gssEapCanonicalizeOid(&tmpMinor, ctx->mechanismUsed, 0, mech_type);
899 if (GSS_ERROR(tmpMajor)) {
905 if (ret_flags != NULL)
906 *ret_flags = ctx->gssFlags;
907 if (delegated_cred_handle != NULL)
908 *delegated_cred_handle = GSS_C_NO_CREDENTIAL;
910 if (major == GSS_S_COMPLETE) {
911 if (src_name != NULL && ctx->initiatorName != GSS_C_NO_NAME) {
912 major = gssEapDuplicateName(&tmpMinor, ctx->initiatorName, src_name);
913 if (GSS_ERROR(major))
916 if (time_rec != NULL) {
917 major = gssEapContextTime(&tmpMinor, ctx, time_rec);
918 if (GSS_ERROR(major))
923 GSSEAP_ASSERT(CTX_IS_ESTABLISHED(ctx) || major == GSS_S_CONTINUE_NEEDED);
926 if (cred != GSS_C_NO_CREDENTIAL)
927 GSSEAP_MUTEX_UNLOCK(&cred->mutex);
932 #ifdef GSSEAP_ENABLE_REAUTH
934 acceptReadyKrb(OM_uint32 *minor,
937 const gss_name_t initiator,
943 major = gssEapGlueToMechName(minor, ctx, initiator, &ctx->initiatorName);
944 if (GSS_ERROR(major))
947 major = gssEapReauthComplete(minor, ctx, cred, mech, timeRec);
948 if (GSS_ERROR(major))
952 return GSS_S_COMPLETE;
956 eapGssSmAcceptGssReauth(OM_uint32 *minor,
959 gss_name_t target GSSEAP_UNUSED,
961 OM_uint32 reqFlags GSSEAP_UNUSED,
962 OM_uint32 timeReq GSSEAP_UNUSED,
963 gss_channel_bindings_t chanBindings,
964 gss_buffer_t inputToken,
965 gss_buffer_t outputToken,
968 OM_uint32 major, tmpMinor;
969 gss_name_t krbInitiator = GSS_C_NO_NAME;
970 OM_uint32 gssFlags, timeRec = GSS_C_INDEFINITE;
973 * If we're built with fast reauthentication support, it's valid
974 * for an initiator to send a GSS reauthentication token as its
975 * initial context token, causing us to short-circuit the state
976 * machine and process Kerberos GSS messages instead.
979 ctx->flags |= CTX_FLAG_KRB_REAUTH;
981 major = gssAcceptSecContext(minor,
992 if (major == GSS_S_COMPLETE) {
993 major = acceptReadyKrb(minor, ctx, cred,
994 krbInitiator, mech, timeRec);
995 if (major == GSS_S_COMPLETE) {
996 GSSEAP_SM_TRANSITION(ctx, GSSEAP_STATE_ESTABLISHED);
998 ctx->gssFlags = gssFlags;
999 } else if (GSS_ERROR(major) &&
1000 (*smFlags & SM_FLAG_INPUT_TOKEN_CRITICAL) == 0) {
1001 /* pretend reauthentication attempt never happened */
1002 gssDeleteSecContext(&tmpMinor, &ctx->reauthCtx, GSS_C_NO_BUFFER);
1003 ctx->flags &= ~(CTX_FLAG_KRB_REAUTH);
1004 GSSEAP_SM_TRANSITION(ctx, GSSEAP_STATE_INITIAL);
1005 major = GSS_S_CONTINUE_NEEDED;
1008 gssReleaseName(&tmpMinor, &krbInitiator);
1012 #endif /* GSSEAP_ENABLE_REAUTH */
1014 OM_uint32 GSSAPI_CALLCONV
1015 gss_accept_sec_context(OM_uint32 *minor,
1016 gss_ctx_id_t *context_handle,
1018 gss_buffer_t input_token,
1019 gss_channel_bindings_t input_chan_bindings,
1020 gss_name_t *src_name,
1022 gss_buffer_t output_token,
1023 OM_uint32 *ret_flags,
1024 OM_uint32 *time_rec,
1025 gss_cred_id_t *delegated_cred_handle)
1027 OM_uint32 major, tmpMinor;
1028 gss_ctx_id_t ctx = *context_handle;
1032 output_token->length = 0;
1033 output_token->value = NULL;
1035 if (src_name != NULL)
1036 *src_name = GSS_C_NO_NAME;
1038 if (input_token == GSS_C_NO_BUFFER || input_token->length == 0) {
1039 *minor = GSSEAP_TOK_TRUNC;
1040 return GSS_S_DEFECTIVE_TOKEN;
1043 if (ctx == GSS_C_NO_CONTEXT) {
1044 major = gssEapAllocContext(minor, &ctx);
1045 if (GSS_ERROR(major))
1048 *context_handle = ctx;
1051 GSSEAP_MUTEX_LOCK(&ctx->mutex);
1053 major = gssEapAcceptSecContext(minor,
1057 input_chan_bindings,
1063 delegated_cred_handle);
1065 GSSEAP_MUTEX_UNLOCK(&ctx->mutex);
1067 if (GSS_ERROR(major))
1068 gssEapReleaseContext(&tmpMinor, context_handle);