/* * Copyright (c) 1997 - 2003 Kungliga Tekniska Högskolan * (Royal Institute of Technology, Stockholm, Sweden). * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * 3. Neither the name of the Institute nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE INSTITUTE AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE INSTITUTE OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include "gssapi_locl.h" RCSID("$Id: init_sec_context.c,v 1.59 2005/08/11 10:47:25 lha Exp $"); /* * copy the addresses from `input_chan_bindings' (if any) to * the auth context `ac' */ static OM_uint32 set_addresses (krb5_auth_context ac, const gss_channel_bindings_t input_chan_bindings) { /* Port numbers are expected to be in application_data.value, * initator's port first */ krb5_address initiator_addr, acceptor_addr; krb5_error_code kret; if (input_chan_bindings == GSS_C_NO_CHANNEL_BINDINGS || input_chan_bindings->application_data.length != 2 * sizeof(ac->local_port)) return 0; memset(&initiator_addr, 0, sizeof(initiator_addr)); memset(&acceptor_addr, 0, sizeof(acceptor_addr)); ac->local_port = *(int16_t *) input_chan_bindings->application_data.value; ac->remote_port = *((int16_t *) input_chan_bindings->application_data.value + 1); kret = gss_address_to_krb5addr(input_chan_bindings->acceptor_addrtype, &input_chan_bindings->acceptor_address, ac->remote_port, &acceptor_addr); if (kret) return kret; kret = gss_address_to_krb5addr(input_chan_bindings->initiator_addrtype, &input_chan_bindings->initiator_address, ac->local_port, &initiator_addr); if (kret) { krb5_free_address (gssapi_krb5_context, &acceptor_addr); return kret; } kret = krb5_auth_con_setaddrs(gssapi_krb5_context, ac, &initiator_addr, /* local address */ &acceptor_addr); /* remote address */ krb5_free_address (gssapi_krb5_context, &initiator_addr); krb5_free_address (gssapi_krb5_context, &acceptor_addr); #if 0 free(input_chan_bindings->application_data.value); input_chan_bindings->application_data.value = NULL; input_chan_bindings->application_data.length = 0; #endif return kret; } OM_uint32 _gsskrb5_create_ctx( OM_uint32 * minor_status, gss_ctx_id_t * context_handle, const gss_channel_bindings_t input_chan_bindings, enum gss_ctx_id_t_state state) { krb5_error_code kret; *context_handle = malloc(sizeof(**context_handle)); if (*context_handle == NULL) { *minor_status = ENOMEM; return GSS_S_FAILURE; } (*context_handle)->auth_context = NULL; (*context_handle)->source = NULL; (*context_handle)->target = NULL; (*context_handle)->state = state; (*context_handle)->flags = 0; (*context_handle)->more_flags = 0; (*context_handle)->service_keyblock = NULL; (*context_handle)->ticket = NULL; krb5_data_zero(&(*context_handle)->fwd_data); (*context_handle)->lifetime = GSS_C_INDEFINITE; (*context_handle)->order = NULL; HEIMDAL_MUTEX_init(&(*context_handle)->ctx_id_mutex); kret = krb5_auth_con_init (gssapi_krb5_context, &(*context_handle)->auth_context); if (kret) { *minor_status = kret; gssapi_krb5_set_error_string (); HEIMDAL_MUTEX_destroy(&(*context_handle)->ctx_id_mutex); return GSS_S_FAILURE; } kret = set_addresses((*context_handle)->auth_context, input_chan_bindings); if (kret) { *minor_status = kret; HEIMDAL_MUTEX_destroy(&(*context_handle)->ctx_id_mutex); krb5_auth_con_free(gssapi_krb5_context, (*context_handle)->auth_context); return GSS_S_BAD_BINDINGS; } return GSS_S_COMPLETE; } static OM_uint32 gsskrb5_get_creds( OM_uint32 * minor_status, const gss_cred_id_t initiator_cred_handle, gss_ctx_id_t * context_handle, const gss_name_t target_name, OM_uint32 time_req, OM_uint32 * time_rec, krb5_creds ** cred) { OM_uint32 ret; krb5_error_code kret; krb5_creds this_cred; krb5_ccache ccache = NULL; OM_uint32 lifetime_rec; *cred = NULL; if (initiator_cred_handle == GSS_C_NO_CREDENTIAL) { kret = krb5_cc_default (gssapi_krb5_context, &ccache); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } } else { ccache = initiator_cred_handle->ccache; } kret = krb5_cc_get_principal(gssapi_krb5_context, ccache, &(*context_handle)->source); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } kret = krb5_copy_principal(gssapi_krb5_context, target_name, &(*context_handle)->target); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } memset(&this_cred, 0, sizeof(this_cred)); this_cred.client = (*context_handle)->source; this_cred.server = (*context_handle)->target; if (time_req && time_req != GSS_C_INDEFINITE) { krb5_timestamp ts; krb5_timeofday (gssapi_krb5_context, &ts); this_cred.times.endtime = ts + time_req; } else { this_cred.times.endtime = 0; } this_cred.session.keytype = KEYTYPE_NULL; kret = krb5_get_credentials(gssapi_krb5_context, 0, ccache, &this_cred, cred); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } (*context_handle)->lifetime = (*cred)->times.endtime; ret = gssapi_lifetime_left(minor_status, (*context_handle)->lifetime, &lifetime_rec); if (ret) return ret; if (lifetime_rec == 0) { *minor_status = 0; return GSS_S_CONTEXT_EXPIRED; } if (time_rec) *time_rec = lifetime_rec; if (initiator_cred_handle == GSS_C_NO_CREDENTIAL) { krb5_cc_close(gssapi_krb5_context, ccache); } return GSS_S_COMPLETE; } static OM_uint32 gsskrb5_initiator_ready( OM_uint32 * minor_status, gss_ctx_id_t * context_handle) { OM_uint32 ret; int32_t seq_number; int is_cfx = 0; u_int32_t flags = (*context_handle)->flags; krb5_auth_getremoteseqnumber (gssapi_krb5_context, (*context_handle)->auth_context, &seq_number); gsskrb5_is_cfx(*context_handle, &is_cfx); ret = _gssapi_msg_order_create(minor_status, &(*context_handle)->order, _gssapi_msg_order_f(flags), seq_number, 0, is_cfx); if (ret) return ret; (*context_handle)->state = INITIATOR_READY; (*context_handle)->more_flags |= OPEN; return GSS_S_COMPLETE; } /* * handle delegated creds in init-sec-context */ static void do_delegation (krb5_auth_context ac, krb5_ccache ccache, krb5_creds *cred, const gss_name_t target_name, krb5_data *fwd_data, int *flags) { krb5_creds creds; krb5_kdc_flags fwd_flags; krb5_error_code kret; memset (&creds, 0, sizeof(creds)); krb5_data_zero (fwd_data); kret = krb5_cc_get_principal(gssapi_krb5_context, ccache, &creds.client); if (kret) goto out; kret = krb5_build_principal(gssapi_krb5_context, &creds.server, strlen(creds.client->realm), creds.client->realm, KRB5_TGS_NAME, creds.client->realm, NULL); if (kret) goto out; creds.times.endtime = 0; fwd_flags.i = 0; fwd_flags.b.forwarded = 1; fwd_flags.b.forwardable = 1; if ( /*target_name->name.name_type != KRB5_NT_SRV_HST ||*/ target_name->name.name_string.len < 2) goto out; kret = krb5_get_forwarded_creds(gssapi_krb5_context, ac, ccache, fwd_flags.i, target_name->name.name_string.val[1], &creds, fwd_data); out: if (kret) *flags &= ~GSS_C_DELEG_FLAG; else *flags |= GSS_C_DELEG_FLAG; if (creds.client) krb5_free_principal(gssapi_krb5_context, creds.client); if (creds.server) krb5_free_principal(gssapi_krb5_context, creds.server); } /* * first stage of init-sec-context */ static OM_uint32 gsskrb5_initiator_start (OM_uint32 * minor_status, const gss_cred_id_t initiator_cred_handle, gss_ctx_id_t * context_handle, const gss_name_t target_name, const gss_OID mech_type, OM_uint32 req_flags, OM_uint32 time_req, const gss_channel_bindings_t input_chan_bindings, const gss_buffer_t input_token, gss_buffer_t output_token, OM_uint32 * ret_flags, OM_uint32 * time_rec ) { OM_uint32 ret = GSS_S_FAILURE; krb5_error_code kret; krb5_flags ap_options; krb5_creds *cred = NULL; krb5_data outbuf; krb5_ccache ccache = NULL; u_int32_t flags; krb5_data authenticator; Checksum cksum; krb5_enctype enctype; krb5_data fwd_data; krb5_data_zero(&outbuf); krb5_data_zero(&fwd_data); (*context_handle)->more_flags |= LOCAL; /* We need to get the credentials for the requested target */ ret = gsskrb5_get_creds(minor_status, initiator_cred_handle, context_handle, target_name, time_req, time_rec, &cred); if (ret) return ret; /* * We need to setup some compat stuff, this assumes that context_handle->target is already set */ ret = _gss_DES3_get_mic_compat(minor_status, *context_handle); if (ret) return ret; /* * We need a sequence number */ krb5_auth_con_addflags(gssapi_krb5_context, (*context_handle)->auth_context, KRB5_AUTH_CONTEXT_DO_SEQUENCE, NULL); /* We need the key and a random local subkey */ { kret = krb5_auth_con_setkey(gssapi_krb5_context, (*context_handle)->auth_context, &cred->session); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } kret = krb5_auth_con_generatelocalsubkey(gssapi_krb5_context, (*context_handle)->auth_context, &cred->session); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } } /* We need to prepare the flags used for this context */ { flags = 0; ap_options = 0; if (req_flags & GSS_C_DELEG_FLAG) { do_delegation((*context_handle)->auth_context, ccache, cred, target_name, &fwd_data, &flags); } if (req_flags & GSS_C_MUTUAL_FLAG) { flags |= GSS_C_MUTUAL_FLAG; ap_options |= AP_OPTS_MUTUAL_REQUIRED; } if (req_flags & GSS_C_REPLAY_FLAG) { flags |= GSS_C_REPLAY_FLAG; } if (req_flags & GSS_C_SEQUENCE_FLAG) { flags |= GSS_C_SEQUENCE_FLAG; } if (req_flags & GSS_C_ANON_FLAG) { ;/* XXX */ } if (req_flags & GSS_C_DCE_STYLE) { flags |= GSS_C_DCE_STYLE; /* GSS_C_DCE_STYLE implies GSS_C_MUTUAL_FLAG */ flags |= GSS_C_MUTUAL_FLAG; ap_options |= AP_OPTS_MUTUAL_REQUIRED; } if (req_flags & GSS_C_IDENTIFY_FLAG) { flags |= GSS_C_IDENTIFY_FLAG; } if (req_flags & GSS_C_EXTENDED_ERROR_FLAG) { flags |= GSS_C_EXTENDED_ERROR_FLAG; } /* TODO: why are this always there? --metze */ flags |= GSS_C_CONF_FLAG; flags |= GSS_C_INTEG_FLAG; flags |= GSS_C_TRANS_FLAG; if (ret_flags) *ret_flags = flags; (*context_handle)->flags = flags; } /* We need to generate the 8003 checksum */ { ret = gssapi_krb5_create_8003_checksum(minor_status, input_chan_bindings, flags, &fwd_data, &cksum); krb5_data_free (&fwd_data); if (ret) return ret; } enctype = (*context_handle)->auth_context->keyblock->keytype; /* We need to create an Authenticator */ { kret = krb5_build_authenticator (gssapi_krb5_context, (*context_handle)->auth_context, enctype, cred, &cksum, NULL, &authenticator, KRB5_KU_AP_REQ_AUTH); free_Checksum(&cksum); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } } /* We need to create the AP_REQ */ { kret = krb5_build_ap_req(gssapi_krb5_context, enctype, cred, ap_options, authenticator, &outbuf); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } } /* We need to encapsulate the AP_REQ if GSS_C_DCE_STYLE isn't in use */ { if (!(flags & GSS_C_DCE_STYLE)) { ret = gssapi_krb5_encapsulate(minor_status, &outbuf, output_token, "\x01\x00", GSS_KRB5_MECHANISM); krb5_data_free (&outbuf); if (ret) return ret; } else { output_token->length = outbuf.length; output_token->value = outbuf.data; } } /* We no longer need the creds */ krb5_free_creds(gssapi_krb5_context, cred); /* We are done if GSS_C_MUTUAL_FLAG is in use */ if (flags & GSS_C_MUTUAL_FLAG) { (*context_handle)->state = INITIATOR_WAIT_FOR_MUTAL; return GSS_S_CONTINUE_NEEDED; } return gsskrb5_initiator_ready(minor_status, context_handle); } static OM_uint32 gsskrb5_initiator_wait_for_mutual( OM_uint32 * minor_status, const gss_cred_id_t initiator_cred_handle, gss_ctx_id_t * context_handle, const gss_name_t target_name, const gss_OID mech_type, OM_uint32 req_flags, OM_uint32 time_req, const gss_channel_bindings_t input_chan_bindings, const gss_buffer_t input_token, gss_buffer_t output_token, OM_uint32 * ret_flags, OM_uint32 * time_rec) { OM_uint32 ret; krb5_error_code kret; krb5_data inbuf; u_int32_t flags = (*context_handle)->flags; OM_uint32 l_seq_number; OM_uint32 r_seq_number; /* We need to decapsulate the AP_REP if GSS_C_DCE_STYLE isn't in use */ { if (!(flags & GSS_C_DCE_STYLE)) { ret = gssapi_krb5_decapsulate(minor_status, input_token, &inbuf, "\x02\x00", GSS_KRB5_MECHANISM); if (ret) return ret; } else { inbuf.length = input_token->length; inbuf.data = input_token->value; } } /* We need to verify the AP_REP */ { krb5_ap_rep_enc_part *repl; kret = krb5_rd_rep(gssapi_krb5_context, (*context_handle)->auth_context, &inbuf, &repl); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } krb5_free_ap_rep_enc_part(gssapi_krb5_context, repl); } /* We need to check the liftime */ { OM_uint32 lifetime_rec; ret = gssapi_lifetime_left(minor_status, (*context_handle)->lifetime, &lifetime_rec); if (ret) return ret; if (lifetime_rec == 0) { return GSS_S_CONTEXT_EXPIRED; } if (time_rec) *time_rec = lifetime_rec; } /* We need to give the caller the flags which are in use */ if (ret_flags) *ret_flags = (*context_handle)->flags; /* We are done here if GSS_C_DCE_STYLE isn't in use */ if (!(flags & GSS_C_DCE_STYLE)) { return gsskrb5_initiator_ready(minor_status, context_handle); } /* * We need to set the local seq_number to the remote one just for the krb5_mk_rep(), * and then we need to use the old local seq_number again for the GSS_Wrap() messages */ { kret = krb5_auth_getremoteseqnumber(gssapi_krb5_context, (*context_handle)->auth_context, &r_seq_number); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } kret = krb5_auth_con_getlocalseqnumber(gssapi_krb5_context, (*context_handle)->auth_context, &l_seq_number); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } kret = krb5_auth_con_setlocalseqnumber(gssapi_krb5_context, (*context_handle)->auth_context, r_seq_number); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } } /* We need to create an AP_REP */ { krb5_data outbuf; kret = krb5_mk_rep(gssapi_krb5_context, (*context_handle)->auth_context, &outbuf); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } output_token->length = outbuf.length; output_token->value = outbuf.data; } /* We need to reset the local seq_number */ { kret = krb5_auth_con_setlocalseqnumber(gssapi_krb5_context, (*context_handle)->auth_context, l_seq_number); if (kret) { gssapi_krb5_set_error_string (); *minor_status = kret; return GSS_S_FAILURE; } } return gsskrb5_initiator_ready(minor_status, context_handle); } static OM_uint32 gsskrb5_init_sec_context (OM_uint32 * minor_status, const gss_cred_id_t initiator_cred_handle, gss_ctx_id_t * context_handle, const gss_name_t target_name, const gss_OID mech_type, OM_uint32 req_flags, OM_uint32 time_req, const gss_channel_bindings_t input_chan_bindings, const gss_buffer_t input_token, gss_OID * actual_mech_type, gss_buffer_t output_token, OM_uint32 * ret_flags, OM_uint32 * time_rec ) { OM_uint32 ret; if (*context_handle == GSS_C_NO_CONTEXT) { ret = _gsskrb5_create_ctx(minor_status, context_handle, input_chan_bindings, INITIATOR_START); if (ret) return ret; } if (actual_mech_type) *actual_mech_type = GSS_KRB5_MECHANISM; HEIMDAL_MUTEX_lock(&(*context_handle)->ctx_id_mutex); switch ((*context_handle)->state) { case INITIATOR_START: ret = gsskrb5_initiator_start(minor_status, initiator_cred_handle, context_handle, target_name, mech_type, req_flags, time_req, input_chan_bindings, input_token, output_token, ret_flags, time_rec); break; case INITIATOR_WAIT_FOR_MUTAL: ret = gsskrb5_initiator_wait_for_mutual(minor_status, initiator_cred_handle, context_handle, target_name, mech_type, req_flags, time_req, input_chan_bindings, input_token, output_token, ret_flags, time_rec); break; case INITIATOR_READY: /* should this be GSS_S_BAD_STATUS ? --metze */ /* We need to check the liftime */ { OM_uint32 lifetime_rec; ret = gssapi_lifetime_left(minor_status, (*context_handle)->lifetime, &lifetime_rec); if (ret) break; if (lifetime_rec == 0) { *minor_status = 0; ret = GSS_S_CONTEXT_EXPIRED; break; } if (time_rec) *time_rec = lifetime_rec; } /* We need to give the caller the flags which are in use */ if (ret_flags) *ret_flags = (*context_handle)->flags; ret = GSS_S_COMPLETE; break; default: /* TODO: is this correct here? --metze */ ret = GSS_S_BAD_STATUS; break; } HEIMDAL_MUTEX_unlock(&(*context_handle)->ctx_id_mutex); return ret; } static OM_uint32 spnego_reply (OM_uint32 * minor_status, const gss_cred_id_t initiator_cred_handle, gss_ctx_id_t * context_handle, const gss_name_t target_name, const gss_OID mech_type, OM_uint32 req_flags, OM_uint32 time_req, const gss_channel_bindings_t input_chan_bindings, const gss_buffer_t input_token, gss_OID * actual_mech_type, gss_buffer_t output_token, OM_uint32 * ret_flags, OM_uint32 * time_rec ) { OM_uint32 ret; krb5_data indata; NegTokenTarg targ; u_char oidbuf[17]; size_t oidlen; gss_buffer_desc sub_token; ssize_t mech_len; const u_char *p; size_t len, taglen; krb5_boolean require_mic; output_token->length = 0; output_token->value = NULL; /* * SPNEGO doesn't include gss wrapping on SubsequentContextToken * like the Kerberos 5 mech does. But lets check for it anyway. */ mech_len = gssapi_krb5_get_mech (input_token->value, input_token->length, &p); if (mech_len < 0) { indata.data = input_token->value; indata.length = input_token->length; } else if (mech_len == GSS_KRB5_MECHANISM->length && memcmp(GSS_KRB5_MECHANISM->elements, p, mech_len) == 0) return gsskrb5_init_sec_context (minor_status, initiator_cred_handle, context_handle, target_name, GSS_KRB5_MECHANISM, req_flags, time_req, input_chan_bindings, input_token, actual_mech_type, output_token, ret_flags, time_rec); else if (mech_len == GSS_SPNEGO_MECHANISM->length && memcmp(GSS_SPNEGO_MECHANISM->elements, p, mech_len) == 0){ ret = _gssapi_decapsulate (minor_status, input_token, &indata, GSS_SPNEGO_MECHANISM); if (ret) return ret; } else return GSS_S_BAD_MECH; ret = der_match_tag_and_length((const char *)indata.data, indata.length, ASN1_C_CONTEXT, CONS, 1, &len, &taglen); if (ret) return ret; if(len > indata.length - taglen) return ASN1_OVERRUN; ret = decode_NegTokenTarg((const char *)indata.data + taglen, len, &targ, NULL); if (ret) { *minor_status = ENOMEM; return GSS_S_FAILURE; } if (targ.negResult == NULL || *(targ.negResult) == reject || targ.supportedMech == NULL) { free_NegTokenTarg(&targ); return GSS_S_BAD_MECH; } ret = der_put_oid(oidbuf + sizeof(oidbuf) - 1, sizeof(oidbuf), targ.supportedMech, &oidlen); if (ret || oidlen != GSS_KRB5_MECHANISM->length || memcmp(oidbuf + sizeof(oidbuf) - oidlen, GSS_KRB5_MECHANISM->elements, oidlen) != 0) { free_NegTokenTarg(&targ); return GSS_S_BAD_MECH; } if (targ.responseToken != NULL) { sub_token.length = targ.responseToken->length; sub_token.value = targ.responseToken->data; } else { sub_token.length = 0; sub_token.value = NULL; } ret = gsskrb5_init_sec_context(minor_status, initiator_cred_handle, context_handle, target_name, GSS_KRB5_MECHANISM, req_flags, time_req, input_chan_bindings, &sub_token, actual_mech_type, output_token, ret_flags, time_rec); if (ret) { free_NegTokenTarg(&targ); return ret; } /* * Verify the mechListMIC if CFX was used; or if local policy * dictated so. */ ret = _gss_spnego_require_mechlist_mic(minor_status, *context_handle, &require_mic); if (ret) { free_NegTokenTarg(&targ); return ret; } if (require_mic) { MechTypeList mechlist; MechType m0; size_t buf_len; gss_buffer_desc mic_buf, mech_buf; if (targ.mechListMIC == NULL) { free_NegTokenTarg(&targ); *minor_status = 0; return GSS_S_BAD_MIC; } mechlist.len = 1; mechlist.val = &m0; ret = der_get_oid(GSS_KRB5_MECHANISM->elements, GSS_KRB5_MECHANISM->length, &m0, NULL); if (ret) { free_NegTokenTarg(&targ); *minor_status = ENOMEM; return GSS_S_FAILURE; } ASN1_MALLOC_ENCODE(MechTypeList, mech_buf.value, mech_buf.length, &mechlist, &buf_len, ret); if (ret) { free_NegTokenTarg(&targ); free_oid(&m0); *minor_status = ENOMEM; return GSS_S_FAILURE; } if (mech_buf.length != buf_len) abort(); mic_buf.length = targ.mechListMIC->length; mic_buf.value = targ.mechListMIC->data; ret = gss_verify_mic(minor_status, *context_handle, &mech_buf, &mic_buf, NULL); free(mech_buf.value); free_oid(&m0); } free_NegTokenTarg(&targ); return ret; } static OM_uint32 spnego_initial (OM_uint32 * minor_status, const gss_cred_id_t initiator_cred_handle, gss_ctx_id_t * context_handle, const gss_name_t target_name, const gss_OID mech_type, OM_uint32 req_flags, OM_uint32 time_req, const gss_channel_bindings_t input_chan_bindings, const gss_buffer_t input_token, gss_OID * actual_mech_type, gss_buffer_t output_token, OM_uint32 * ret_flags, OM_uint32 * time_rec ) { NegTokenInit ni; int ret; OM_uint32 sub, minor; gss_buffer_desc mech_token; u_char *buf; size_t buf_size, buf_len; krb5_data data; memset (&ni, 0, sizeof(ni)); ALLOC(ni.mechTypes, 1); if (ni.mechTypes == NULL) { *minor_status = ENOMEM; return GSS_S_FAILURE; } ALLOC_SEQ(ni.mechTypes, 1); if (ni.mechTypes->val == NULL) { free_NegTokenInit(&ni); *minor_status = ENOMEM; return GSS_S_FAILURE; } ret = der_get_oid(GSS_KRB5_MECHANISM->elements, GSS_KRB5_MECHANISM->length, &ni.mechTypes->val[0], NULL); if (ret) { free_NegTokenInit(&ni); *minor_status = ENOMEM; return GSS_S_FAILURE; } #if 0 ALLOC(ni.reqFlags, 1); if (ni.reqFlags == NULL) { free_NegTokenInit(&ni); *minor_status = ENOMEM; return GSS_S_FAILURE; } ni.reqFlags->delegFlag = req_flags & GSS_C_DELEG_FLAG; ni.reqFlags->mutualFlag = req_flags & GSS_C_MUTUAL_FLAG; ni.reqFlags->replayFlag = req_flags & GSS_C_REPLAY_FLAG; ni.reqFlags->sequenceFlag = req_flags & GSS_C_SEQUENCE_FLAG; ni.reqFlags->anonFlag = req_flags & GSS_C_ANON_FLAG; ni.reqFlags->confFlag = req_flags & GSS_C_CONF_FLAG; ni.reqFlags->integFlag = req_flags & GSS_C_INTEG_FLAG; #else ni.reqFlags = NULL; #endif sub = gsskrb5_init_sec_context(&minor, initiator_cred_handle, context_handle, target_name, GSS_KRB5_MECHANISM, req_flags, time_req, input_chan_bindings, GSS_C_NO_BUFFER, actual_mech_type, &mech_token, ret_flags, time_rec); if (GSS_ERROR(sub)) { free_NegTokenInit(&ni); return sub; } if (mech_token.length != 0) { ALLOC(ni.mechToken, 1); if (ni.mechToken == NULL) { free_NegTokenInit(&ni); gss_release_buffer(&minor, &mech_token); *minor_status = ENOMEM; return GSS_S_FAILURE; } ni.mechToken->length = mech_token.length; ni.mechToken->data = malloc(mech_token.length); if (ni.mechToken->data == NULL && mech_token.length != 0) { free_NegTokenInit(&ni); gss_release_buffer(&minor, &mech_token); *minor_status = ENOMEM; return GSS_S_FAILURE; } memcpy(ni.mechToken->data, mech_token.value, mech_token.length); gss_release_buffer(&minor, &mech_token); } else ni.mechToken = NULL; /* XXX ignore mech list mic for now */ ni.mechListMIC = NULL; { NegotiationToken nt; nt.element = choice_NegotiationToken_negTokenInit; nt.u.negTokenInit = ni; ASN1_MALLOC_ENCODE(NegotiationToken, buf, buf_size, &nt, &buf_len, ret); if (ret == 0 && buf_size != buf_len) abort(); } data.data = buf; data.length = buf_size; free_NegTokenInit(&ni); if (ret) return ret; sub = _gssapi_encapsulate(minor_status, &data, output_token, GSS_SPNEGO_MECHANISM); free (buf); if (sub) return sub; return GSS_S_CONTINUE_NEEDED; } static OM_uint32 spnego_init_sec_context (OM_uint32 * minor_status, const gss_cred_id_t initiator_cred_handle, gss_ctx_id_t * context_handle, const gss_name_t target_name, const gss_OID mech_type, OM_uint32 req_flags, OM_uint32 time_req, const gss_channel_bindings_t input_chan_bindings, const gss_buffer_t input_token, gss_OID * actual_mech_type, gss_buffer_t output_token, OM_uint32 * ret_flags, OM_uint32 * time_rec ) { if (input_token == GSS_C_NO_BUFFER || input_token->length == 0) return spnego_initial (minor_status, initiator_cred_handle, context_handle, target_name, mech_type, req_flags, time_req, input_chan_bindings, input_token, actual_mech_type, output_token, ret_flags, time_rec); else return spnego_reply (minor_status, initiator_cred_handle, context_handle, target_name, mech_type, req_flags, time_req, input_chan_bindings, input_token, actual_mech_type, output_token, ret_flags, time_rec); } /* * gss_init_sec_context */ OM_uint32 gss_init_sec_context (OM_uint32 * minor_status, const gss_cred_id_t initiator_cred_handle, gss_ctx_id_t * context_handle, const gss_name_t target_name, const gss_OID mech_type, OM_uint32 req_flags, OM_uint32 time_req, const gss_channel_bindings_t input_chan_bindings, const gss_buffer_t input_token, gss_OID * actual_mech_type, gss_buffer_t output_token, OM_uint32 * ret_flags, OM_uint32 * time_rec ) { GSSAPI_KRB5_INIT (); output_token->length = 0; output_token->value = NULL; if (ret_flags) *ret_flags = 0; if (time_rec) *time_rec = 0; if (target_name == GSS_C_NO_NAME) { if (actual_mech_type) *actual_mech_type = GSS_C_NO_OID; *minor_status = 0; return GSS_S_BAD_NAME; } if (mech_type == GSS_C_NO_OID || gss_oid_equal(mech_type, GSS_KRB5_MECHANISM)) return gsskrb5_init_sec_context(minor_status, initiator_cred_handle, context_handle, target_name, mech_type, req_flags, time_req, input_chan_bindings, input_token, actual_mech_type, output_token, ret_flags, time_rec); else if (gss_oid_equal(mech_type, GSS_SPNEGO_MECHANISM)) return spnego_init_sec_context (minor_status, initiator_cred_handle, context_handle, target_name, mech_type, req_flags, time_req, input_chan_bindings, input_token, actual_mech_type, output_token, ret_flags, time_rec); else return GSS_S_BAD_MECH; }