/* * Copyright (c) 1997 - 2001 Kungliga Tekniska Högskolan * (Royal Institute of Technology, Stockholm, Sweden). * All rights reserved. * * Portions Copyright (c) 2009 Apple Inc. 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. */ #define KRB5_KDB_DISALLOW_POSTDATED 0x00000001 #define KRB5_KDB_DISALLOW_FORWARDABLE 0x00000002 #define KRB5_KDB_DISALLOW_TGT_BASED 0x00000004 #define KRB5_KDB_DISALLOW_RENEWABLE 0x00000008 #define KRB5_KDB_DISALLOW_PROXIABLE 0x00000010 #define KRB5_KDB_DISALLOW_DUP_SKEY 0x00000020 #define KRB5_KDB_DISALLOW_ALL_TIX 0x00000040 #define KRB5_KDB_REQUIRES_PRE_AUTH 0x00000080 #define KRB5_KDB_REQUIRES_HW_AUTH 0x00000100 #define KRB5_KDB_REQUIRES_PWCHANGE 0x00000200 #define KRB5_KDB_DISALLOW_SVR 0x00001000 #define KRB5_KDB_PWCHANGE_SERVICE 0x00002000 #define KRB5_KDB_SUPPORT_DESMD5 0x00004000 #define KRB5_KDB_NEW_PRINC 0x00008000 /* key: krb5_unparse_name + NUL 16: baselength 32: attributes 32: max time 32: max renewable time 32: client expire 32: passwd expire 32: last successful passwd 32: last failed attempt 32: num of failed attempts 16: num tl data 16: num data data 16: principal length length: principal for num tl data times 16: tl data type 16: tl data length length: length for num key data times 16: version (num keyblocks) 16: kvno for version times: 16: type 16: length length: keydata key_data_contents[0] int16: length read-of-data: key-encrypted, key-usage 0, master-key salt: version2 = salt in key_data->key_data_contents[1] else default salt. */ #include "hdb_locl.h" static void attr_to_flags(unsigned attr, HDBFlags *flags) { flags->postdate = !(attr & KRB5_KDB_DISALLOW_POSTDATED); flags->forwardable = !(attr & KRB5_KDB_DISALLOW_FORWARDABLE); flags->initial = !!(attr & KRB5_KDB_DISALLOW_TGT_BASED); flags->renewable = !(attr & KRB5_KDB_DISALLOW_RENEWABLE); flags->proxiable = !(attr & KRB5_KDB_DISALLOW_PROXIABLE); /* DUP_SKEY */ flags->invalid = !!(attr & KRB5_KDB_DISALLOW_ALL_TIX); flags->require_preauth = !!(attr & KRB5_KDB_REQUIRES_PRE_AUTH); flags->require_hwauth = !!(attr & KRB5_KDB_REQUIRES_HW_AUTH); flags->server = !(attr & KRB5_KDB_DISALLOW_SVR); flags->change_pw = !!(attr & KRB5_KDB_PWCHANGE_SERVICE); flags->client = 1; /* XXX */ } #define KDB_V1_BASE_LENGTH 38 #define CHECK(x) do { if ((x)) goto out; } while(0) #ifdef HAVE_DB1 static krb5_error_code mdb_principal2key(krb5_context context, krb5_const_principal principal, krb5_data *key) { krb5_error_code ret; char *str; ret = krb5_unparse_name(context, principal, &str); if (ret) return ret; key->data = str; key->length = strlen(str) + 1; return 0; } #endif /* HAVE_DB1 */ #define KRB5_KDB_SALTTYPE_NORMAL 0 #define KRB5_KDB_SALTTYPE_V4 1 #define KRB5_KDB_SALTTYPE_NOREALM 2 #define KRB5_KDB_SALTTYPE_ONLYREALM 3 #define KRB5_KDB_SALTTYPE_SPECIAL 4 #define KRB5_KDB_SALTTYPE_AFS3 5 #define KRB5_KDB_SALTTYPE_CERTHASH 6 static krb5_error_code fix_salt(krb5_context context, hdb_entry *ent, int key_num) { krb5_error_code ret; Salt *salt = ent->keys.val[key_num].salt; /* fix salt type */ switch((int)salt->type) { case KRB5_KDB_SALTTYPE_NORMAL: salt->type = KRB5_PADATA_PW_SALT; break; case KRB5_KDB_SALTTYPE_V4: krb5_data_free(&salt->salt); salt->type = KRB5_PADATA_PW_SALT; break; case KRB5_KDB_SALTTYPE_NOREALM: { size_t len; size_t i; char *p; len = 0; for (i = 0; i < ent->principal->name.name_string.len; ++i) len += strlen(ent->principal->name.name_string.val[i]); ret = krb5_data_alloc (&salt->salt, len); if (ret) return ret; p = salt->salt.data; for (i = 0; i < ent->principal->name.name_string.len; ++i) { memcpy (p, ent->principal->name.name_string.val[i], strlen(ent->principal->name.name_string.val[i])); p += strlen(ent->principal->name.name_string.val[i]); } salt->type = KRB5_PADATA_PW_SALT; break; } case KRB5_KDB_SALTTYPE_ONLYREALM: krb5_data_free(&salt->salt); ret = krb5_data_copy(&salt->salt, ent->principal->realm, strlen(ent->principal->realm)); if(ret) return ret; salt->type = KRB5_PADATA_PW_SALT; break; case KRB5_KDB_SALTTYPE_SPECIAL: salt->type = KRB5_PADATA_PW_SALT; break; case KRB5_KDB_SALTTYPE_AFS3: krb5_data_free(&salt->salt); ret = krb5_data_copy(&salt->salt, ent->principal->realm, strlen(ent->principal->realm)); if(ret) return ret; salt->type = KRB5_PADATA_AFS3_SALT; break; case KRB5_KDB_SALTTYPE_CERTHASH: krb5_data_free(&salt->salt); free(ent->keys.val[key_num].salt); ent->keys.val[key_num].salt = NULL; break; default: abort(); } return 0; } krb5_error_code _hdb_mdb_value2entry(krb5_context context, krb5_data *data, krb5_kvno kvno, hdb_entry *entry) { krb5_error_code ret; krb5_storage *sp; uint32_t u32; uint16_t u16, num_keys, num_tl; ssize_t sz; size_t i, j; char *p; sp = krb5_storage_from_data(data); if (sp == NULL) { krb5_set_error_message(context, ENOMEM, "out of memory"); return ENOMEM; } krb5_storage_set_byteorder(sp, KRB5_STORAGE_BYTEORDER_LE); /* * 16: baselength * * The story here is that these 16 bits have to be a constant: * KDB_V1_BASE_LENGTH. Once upon a time a different value here * would have been used to indicate the presence of "extra data" * between the "base" contents and the {principal name, TL data, * keys} that follow it. Nothing supports such "extra data" * nowadays, so neither do we here. * * XXX But... surely we ought to log about this extra data, or skip * it, or something, in case anyone has MIT KDBs with ancient * entries in them... Logging would allow the admin to know which * entries to dump with MIT krb5's kdb5_util. */ CHECK(ret = krb5_ret_uint16(sp, &u16)); if (u16 != KDB_V1_BASE_LENGTH) { ret = EINVAL; goto out; } /* 32: attributes */ CHECK(ret = krb5_ret_uint32(sp, &u32)); attr_to_flags(u32, &entry->flags); /* 32: max time */ CHECK(ret = krb5_ret_uint32(sp, &u32)); if (u32) { entry->max_life = malloc(sizeof(*entry->max_life)); *entry->max_life = u32; } /* 32: max renewable time */ CHECK(ret = krb5_ret_uint32(sp, &u32)); if (u32) { entry->max_renew = malloc(sizeof(*entry->max_renew)); *entry->max_renew = u32; } /* 32: client expire */ CHECK(ret = krb5_ret_uint32(sp, &u32)); if (u32) { entry->valid_end = malloc(sizeof(*entry->valid_end)); *entry->valid_end = u32; } /* 32: passwd expire */ CHECK(ret = krb5_ret_uint32(sp, &u32)); if (u32) { entry->pw_end = malloc(sizeof(*entry->pw_end)); *entry->pw_end = u32; } /* 32: last successful passwd */ CHECK(ret = krb5_ret_uint32(sp, &u32)); /* 32: last failed attempt */ CHECK(ret = krb5_ret_uint32(sp, &u32)); /* 32: num of failed attempts */ CHECK(ret = krb5_ret_uint32(sp, &u32)); /* 16: num tl data */ CHECK(ret = krb5_ret_uint16(sp, &u16)); num_tl = u16; /* 16: num key data */ CHECK(ret = krb5_ret_uint16(sp, &u16)); num_keys = u16; /* 16: principal length */ CHECK(ret = krb5_ret_uint16(sp, &u16)); /* length: principal */ { /* * Note that the principal name includes the NUL in the entry, * but we don't want to take chances, so we add an extra NUL. */ p = malloc(u16 + 1); if (p == NULL) { ret = ENOMEM; goto out; } sz = krb5_storage_read(sp, p, u16); if (sz != u16) { ret = EINVAL; /* XXX */ goto out; } p[u16] = '\0'; CHECK(ret = krb5_parse_name(context, p, &entry->principal)); free(p); } /* for num tl data times 16: tl data type 16: tl data length length: length */ #define mit_KRB5_TL_LAST_PWD_CHANGE 1 #define mit_KRB5_TL_MOD_PRINC 2 for (i = 0; i < num_tl; i++) { int tl_type; krb5_principal modby; /* 16: TL data type */ CHECK(ret = krb5_ret_uint16(sp, &u16)); tl_type = u16; /* 16: TL data length */ CHECK(ret = krb5_ret_uint16(sp, &u16)); /* * For rollback to MIT purposes we really must understand some * TL data! * * XXX Move all this to separate functions, one per-TL type. */ switch (tl_type) { case mit_KRB5_TL_LAST_PWD_CHANGE: CHECK(ret = krb5_ret_uint32(sp, &u32)); CHECK(ret = hdb_entry_set_pw_change_time(context, entry, u32)); break; case mit_KRB5_TL_MOD_PRINC: if (u16 < 5) { ret = EINVAL; /* XXX */ goto out; } CHECK(ret = krb5_ret_uint32(sp, &u32)); /* mod time */ p = malloc(u16 - 4 + 1); if (!p) { ret = ENOMEM; goto out; } p[u16 - 4] = '\0'; sz = krb5_storage_read(sp, p, u16 - 4); if (sz != u16 - 4) { ret = EINVAL; /* XXX */ goto out; } CHECK(ret = krb5_parse_name(context, p, &modby)); ret = hdb_set_last_modified_by(context, entry, modby, u32); krb5_free_principal(context, modby); free(p); break; default: krb5_storage_seek(sp, u16, SEEK_CUR); break; } } /* * for num key data times * 16: "version" * 16: kvno * for version times: * 16: type * 16: length * length: keydata * * "version" here is really 1 or 2, the first meaning there's only * keys for this kvno, the second meaning there's keys and salt[s?]. * That's right... hold that gag reflex, you can do it. */ for (i = 0; i < num_keys; i++) { int keep = 0; uint16_t version; void *ptr; CHECK(ret = krb5_ret_uint16(sp, &u16)); version = u16; CHECK(ret = krb5_ret_uint16(sp, &u16)); /* * First time through, and until we find one matching key, * entry->kvno == 0. */ if ((entry->kvno < u16) && (kvno == 0 || kvno == u16)) { keep = 1; entry->kvno = u16; /* * Found a higher kvno than earlier, so free the old highest * kvno keys. * * XXX Of course, we actually want to extract the old kvnos * as well, for some of the kadm5 APIs. We shouldn't free * these keys, but keep them elsewhere. */ for (j = 0; j < entry->keys.len; j++) free_Key(&entry->keys.val[j]); free(entry->keys.val); entry->keys.len = 0; entry->keys.val = NULL; } else if (entry->kvno == u16) /* Accumulate keys */ keep = 1; if (keep) { Key *k; ptr = realloc(entry->keys.val, sizeof(entry->keys.val[0]) * (entry->keys.len + 1)); if (ptr == NULL) { ret = ENOMEM; goto out; } entry->keys.val = ptr; /* k points to current Key */ k = &entry->keys.val[entry->keys.len]; memset(k, 0, sizeof(*k)); entry->keys.len += 1; k->mkvno = malloc(sizeof(*k->mkvno)); if (k->mkvno == NULL) { ret = ENOMEM; goto out; } *k->mkvno = 1; for (j = 0; j < version; j++) { uint16_t type; CHECK(ret = krb5_ret_uint16(sp, &type)); CHECK(ret = krb5_ret_uint16(sp, &u16)); if (j == 0) { /* This "version" means we have a key */ k->key.keytype = type; if (u16 < 2) { ret = EINVAL; goto out; } /* * MIT stores keys encrypted keys as {16-bit length * of plaintext key, {encrypted key}}. The reason * for this is that the Kerberos cryptosystem is not * length-preserving. Heimdal's approach is to * truncate the plaintext to the expected length of * the key given its enctype, so we ignore this * 16-bit length-of-plaintext-key field. */ krb5_storage_seek(sp, 2, SEEK_CUR); /* skip real length */ k->key.keyvalue.length = u16 - 2; /* adjust cipher len */ k->key.keyvalue.data = malloc(k->key.keyvalue.length); krb5_storage_read(sp, k->key.keyvalue.data, k->key.keyvalue.length); } else if (j == 1) { /* This "version" means we have a salt */ k->salt = calloc(1, sizeof(*k->salt)); if (k->salt == NULL) { ret = ENOMEM; goto out; } k->salt->type = type; if (u16 != 0) { k->salt->salt.data = malloc(u16); if (k->salt->salt.data == NULL) { ret = ENOMEM; goto out; } k->salt->salt.length = u16; krb5_storage_read(sp, k->salt->salt.data, k->salt->salt.length); } fix_salt(context, entry, entry->keys.len - 1); } else { /* * Whatever this "version" might be, we skip it * * XXX A krb5.conf parameter requesting that we log * about strangeness like this, or return an error * from here, might be nice. */ krb5_storage_seek(sp, u16, SEEK_CUR); } } } else { /* * XXX For now we skip older kvnos, but we should extract * them... */ for (j = 0; j < version; j++) { /* enctype */ CHECK(ret = krb5_ret_uint16(sp, &u16)); /* encrypted key (or plaintext salt) */ CHECK(ret = krb5_ret_uint16(sp, &u16)); krb5_storage_seek(sp, u16, SEEK_CUR); } } } if (entry->kvno == 0 && kvno != 0) { ret = HDB_ERR_NOT_FOUND_HERE; goto out; } return 0; out: if (ret == HEIM_ERR_EOF) /* Better error code than "end of file" */ ret = HEIM_ERR_BAD_HDBENT_ENCODING; return ret; } #if 0 static krb5_error_code mdb_entry2value(krb5_context context, hdb_entry *entry, krb5_data *data) { return EINVAL; } #endif #if HAVE_DB1 #if defined(HAVE_DB_185_H) #include #elif defined(HAVE_DB_H) #include #endif static krb5_error_code mdb_close(krb5_context context, HDB *db) { DB *d = (DB*)db->hdb_db; (*d->close)(d); return 0; } static krb5_error_code mdb_destroy(krb5_context context, HDB *db) { krb5_error_code ret; ret = hdb_clear_master_key (context, db); free(db->hdb_name); free(db); return ret; } static krb5_error_code mdb_lock(krb5_context context, HDB *db, int operation) { DB *d = (DB*)db->hdb_db; int fd = (*d->fd)(d); if(fd < 0) { krb5_set_error_message(context, HDB_ERR_CANT_LOCK_DB, "Can't lock database: %s", db->hdb_name); return HDB_ERR_CANT_LOCK_DB; } return hdb_lock(fd, operation); } static krb5_error_code mdb_unlock(krb5_context context, HDB *db) { DB *d = (DB*)db->hdb_db; int fd = (*d->fd)(d); if(fd < 0) { krb5_set_error_message(context, HDB_ERR_CANT_LOCK_DB, "Can't unlock database: %s", db->hdb_name); return HDB_ERR_CANT_LOCK_DB; } return hdb_unlock(fd); } static krb5_error_code mdb_seq(krb5_context context, HDB *db, unsigned flags, hdb_entry_ex *entry, int flag) { DB *d = (DB*)db->hdb_db; DBT key, value; krb5_data key_data, data; int code; code = db->hdb_lock(context, db, HDB_RLOCK); if(code == -1) { krb5_set_error_message(context, HDB_ERR_DB_INUSE, "Database %s in use", db->hdb_name); return HDB_ERR_DB_INUSE; } code = (*d->seq)(d, &key, &value, flag); db->hdb_unlock(context, db); /* XXX check value */ if(code == -1) { code = errno; krb5_set_error_message(context, code, "Database %s seq error: %s", db->hdb_name, strerror(code)); return code; } if(code == 1) { krb5_clear_error_message(context); return HDB_ERR_NOENTRY; } key_data.data = key.data; key_data.length = key.size; data.data = value.data; data.length = value.size; memset(entry, 0, sizeof(*entry)); if (_hdb_mdb_value2entry(context, &data, 0, &entry->entry)) return mdb_seq(context, db, flags, entry, R_NEXT); if (db->hdb_master_key_set && (flags & HDB_F_DECRYPT)) { code = hdb_unseal_keys (context, db, &entry->entry); if (code) hdb_free_entry (context, entry); } return code; } static krb5_error_code mdb_firstkey(krb5_context context, HDB *db, unsigned flags, hdb_entry_ex *entry) { return mdb_seq(context, db, flags, entry, R_FIRST); } static krb5_error_code mdb_nextkey(krb5_context context, HDB *db, unsigned flags, hdb_entry_ex *entry) { return mdb_seq(context, db, flags, entry, R_NEXT); } static krb5_error_code mdb_rename(krb5_context context, HDB *db, const char *new_name) { int ret; char *old, *new; asprintf(&old, "%s.db", db->hdb_name); asprintf(&new, "%s.db", new_name); ret = rename(old, new); free(old); free(new); if(ret) return errno; free(db->hdb_name); db->hdb_name = strdup(new_name); return 0; } static krb5_error_code mdb__get(krb5_context context, HDB *db, krb5_data key, krb5_data *reply) { DB *d = (DB*)db->hdb_db; DBT k, v; int code; k.data = key.data; k.size = key.length; code = db->hdb_lock(context, db, HDB_RLOCK); if(code) return code; code = (*d->get)(d, &k, &v, 0); db->hdb_unlock(context, db); if(code < 0) { code = errno; krb5_set_error_message(context, code, "Database %s get error: %s", db->hdb_name, strerror(code)); return code; } if(code == 1) { krb5_clear_error_message(context); return HDB_ERR_NOENTRY; } krb5_data_copy(reply, v.data, v.size); return 0; } static krb5_error_code mdb__put(krb5_context context, HDB *db, int replace, krb5_data key, krb5_data value) { DB *d = (DB*)db->hdb_db; DBT k, v; int code; k.data = key.data; k.size = key.length; v.data = value.data; v.size = value.length; code = db->hdb_lock(context, db, HDB_WLOCK); if(code) return code; code = (*d->put)(d, &k, &v, replace ? 0 : R_NOOVERWRITE); db->hdb_unlock(context, db); if(code < 0) { code = errno; krb5_set_error_message(context, code, "Database %s put error: %s", db->hdb_name, strerror(code)); return code; } if(code == 1) { krb5_clear_error_message(context); return HDB_ERR_EXISTS; } return 0; } static krb5_error_code mdb__del(krb5_context context, HDB *db, krb5_data key) { DB *d = (DB*)db->hdb_db; DBT k; krb5_error_code code; k.data = key.data; k.size = key.length; code = db->hdb_lock(context, db, HDB_WLOCK); if(code) return code; code = (*d->del)(d, &k, 0); db->hdb_unlock(context, db); if(code == 1) { code = errno; krb5_set_error_message(context, code, "Database %s put error: %s", db->hdb_name, strerror(code)); return code; } if(code < 0) return errno; return 0; } static krb5_error_code mdb_fetch_kvno(krb5_context context, HDB *db, krb5_const_principal principal, unsigned flags, krb5_kvno kvno, hdb_entry_ex *entry) { krb5_data key, value; krb5_error_code ret; ret = mdb_principal2key(context, principal, &key); if (ret) return ret; ret = db->hdb__get(context, db, key, &value); krb5_data_free(&key); if(ret) return ret; ret = _hdb_mdb_value2entry(context, &value, kvno, &entry->entry); krb5_data_free(&value); if (ret) return ret; if (db->hdb_master_key_set && (flags & HDB_F_DECRYPT)) { ret = hdb_unseal_keys (context, db, &entry->entry); if (ret) { hdb_free_entry(context, entry); return ret; } } return 0; } static krb5_error_code mdb_store(krb5_context context, HDB *db, unsigned flags, hdb_entry_ex *entry) { krb5_error_code ret; krb5_storage *sp = NULL; krb5_storage *spent = NULL; krb5_data line = { 0, 0 }; krb5_data kdb_ent = { 0, 0 }; krb5_data key = { 0, 0 }; ssize_t sz; sp = krb5_storage_emem(); if (!sp) return ENOMEM; ret = _hdb_set_master_key_usage(context, db, 0); /* MIT KDB uses KU 0 */ ret = hdb_seal_keys(context, db, &entry->entry); if (ret) return ret; ret = entry2mit_string_int(context, sp, &entry->entry); if (ret) goto out; sz = krb5_storage_write(sp, "\n", 2); /* NUL-terminate */ ret = ENOMEM; if (sz == -1) goto out; ret = krb5_storage_to_data(sp, &line); if (ret) goto out; ret = ENOMEM; spent = krb5_storage_emem(); if (!spent) goto out; ret = _hdb_mit_dump2mitdb_entry(context, line.data, spent); if (ret) goto out; ret = krb5_storage_to_data(spent, &kdb_ent); if (ret) goto out; ret = mdb_principal2key(context, entry->entry.principal, &key); if (ret) goto out; ret = mdb__put(context, db, 1, key, kdb_ent); out: if (sp) krb5_storage_free(sp); if (spent) krb5_storage_free(spent); krb5_data_free(&line); krb5_data_free(&kdb_ent); krb5_data_free(&key); return ret; } static krb5_error_code mdb_remove(krb5_context context, HDB *db, krb5_const_principal principal) { krb5_error_code code; krb5_data key; code = db->hdb__del(context, db, key); krb5_data_free(&key); return code; } static krb5_error_code mdb_open(krb5_context context, HDB *db, int flags, mode_t mode) { char *fn; char *actual_fn; krb5_error_code ret; struct stat st; asprintf(&fn, "%s.db", db->hdb_name); if (fn == NULL) { krb5_set_error_message(context, ENOMEM, "malloc: out of memory"); return ENOMEM; } if (stat(fn, &st) == 0) actual_fn = fn; else actual_fn = db->hdb_name; db->hdb_db = dbopen(actual_fn, flags, mode, DB_BTREE, NULL); if (db->hdb_db == NULL) { switch (errno) { #ifdef EFTYPE case EFTYPE: #endif case EINVAL: db->hdb_db = dbopen(actual_fn, flags, mode, DB_BTREE, NULL); } } free(fn); /* try to open without .db extension */ if(db->hdb_db == NULL && errno == ENOENT) db->hdb_db = dbopen(db->hdb_name, flags, mode, DB_BTREE, NULL); if(db->hdb_db == NULL) { ret = errno; krb5_set_error_message(context, ret, "dbopen (%s): %s", db->hdb_name, strerror(ret)); return ret; } #if 0 /* * Don't do this -- MIT won't be able to handle the * HDB_DB_FORMAT_ENTRY key. */ if ((flags & O_ACCMODE) != O_RDONLY) ret = hdb_init_db(context, db); #endif ret = hdb_check_db_format(context, db); if (ret == HDB_ERR_NOENTRY) { krb5_clear_error_message(context); return 0; } if (ret) { mdb_close(context, db); krb5_set_error_message(context, ret, "hdb_open: failed %s database %s", (flags & O_ACCMODE) == O_RDONLY ? "checking format of" : "initialize", db->hdb_name); } return ret; } krb5_error_code hdb_mdb_create(krb5_context context, HDB **db, const char *filename) { *db = calloc(1, sizeof(**db)); if (*db == NULL) { krb5_set_error_message(context, ENOMEM, "malloc: out of memory"); return ENOMEM; } (*db)->hdb_db = NULL; (*db)->hdb_name = strdup(filename); if ((*db)->hdb_name == NULL) { free(*db); *db = NULL; krb5_set_error_message(context, ENOMEM, "malloc: out of memory"); return ENOMEM; } (*db)->hdb_master_key_set = 0; (*db)->hdb_openp = 0; (*db)->hdb_capability_flags = 0; (*db)->hdb_open = mdb_open; (*db)->hdb_close = mdb_close; (*db)->hdb_fetch_kvno = mdb_fetch_kvno; (*db)->hdb_store = mdb_store; (*db)->hdb_remove = mdb_remove; (*db)->hdb_firstkey = mdb_firstkey; (*db)->hdb_nextkey= mdb_nextkey; (*db)->hdb_lock = mdb_lock; (*db)->hdb_unlock = mdb_unlock; (*db)->hdb_rename = mdb_rename; (*db)->hdb__get = mdb__get; (*db)->hdb__put = mdb__put; (*db)->hdb__del = mdb__del; (*db)->hdb_destroy = mdb_destroy; return 0; } #endif /* HAVE_DB1 */ /* can have any number of princ stanzas. format is as follows (only \n indicates newlines) princ\t%d\t (%d is KRB5_KDB_V1_BASE_LENGTH, always 38) %d\t (strlen of principal e.g. shadow/foo@ANDREW.CMU.EDU) %d\t (number of tl_data) %d\t (number of key data, e.g. how many keys for this user) %d\t (extra data length) %s\t (principal name) %d\t (attributes) %d\t (max lifetime, seconds) %d\t (max renewable life, seconds) %d\t (expiration, seconds since epoch or 2145830400 for never) %d\t (password expiration, seconds, 0 for never) %d\t (last successful auth, seconds since epoch) %d\t (last failed auth, per above) %d\t (failed auth count) foreach tl_data 0 to number of tl_data - 1 as above %d\t%d\t (data type, data length) foreach tl_data 0 to length-1 %02x (tl data contents[element n]) except if tl_data length is 0 %d (always -1) \t foreach key 0 to number of keys - 1 as above %d\t%d\t (key data version, kvno) foreach version 0 to key data version - 1 (a key or a salt) %d\t%d\t(data type for this key, data length for this key) foreach key data length 0 to length-1 %02x (key data contents[element n]) except if key_data length is 0 %d (always -1) \t foreach extra data length 0 to length - 1 %02x (extra data part) unless no extra data %d (always -1) ;\n */ static char * nexttoken(char **p) { char *q; do { q = strsep(p, " \t"); } while(q && *q == '\0'); return q; } static size_t getdata(char **p, unsigned char *buf, size_t len) { size_t i; int v; char *q = nexttoken(p); i = 0; while(*q && i < len) { if(sscanf(q, "%02x", &v) != 1) break; buf[i++] = v; q += 2; } return i; } static int getint(char **p) { int val; char *q = nexttoken(p); sscanf(q, "%d", &val); return val; } static unsigned int getuint(char **p) { int val; char *q = nexttoken(p); sscanf(q, "%u", &val); return val; } #define KRB5_KDB_SALTTYPE_NORMAL 0 #define KRB5_KDB_SALTTYPE_V4 1 #define KRB5_KDB_SALTTYPE_NOREALM 2 #define KRB5_KDB_SALTTYPE_ONLYREALM 3 #define KRB5_KDB_SALTTYPE_SPECIAL 4 #define KRB5_KDB_SALTTYPE_AFS3 5 #define CHECK_UINT(num) \ if ((num) < 0 || (num) > INT_MAX) return EINVAL #define CHECK_UINT16(num) \ if ((num) < 0 || (num) > 1<<15) return EINVAL #define CHECK_NUM(num, maxv) \ if ((num) > (maxv)) return EINVAL /* * This utility function converts an MIT dump entry to an MIT on-disk * encoded entry, which can then be decoded with _hdb_mdb_value2entry(). * This allows us to have a single decoding function (_hdb_mdb_value2entry), * which makes the code cleaner (less code duplication), if a bit less * efficient. It also will allow us to have a function to dump an HDB * entry in MIT format so we can dump HDB into MIT format for rollback * purposes. And that will allow us to write to MIT KDBs, again * somewhat inefficiently, also for migration/rollback purposes. */ int _hdb_mit_dump2mitdb_entry(krb5_context context, char *line, krb5_storage *sp) { krb5_error_code ret = EINVAL; char *p = line, *q; char *princ; ssize_t sz; size_t i; size_t princ_len; unsigned int num_tl_data; size_t num_key_data; unsigned int attributes; int tmp; krb5_storage_set_byteorder(sp, KRB5_STORAGE_BYTEORDER_LE); q = nexttoken(&p); if (strcmp(q, "kdb5_util") == 0 || strcmp(q, "policy") == 0 || strcmp(q, "princ") != 0) { return -1; } if (getint(&p) != 38) return EINVAL; #define KDB_V1_BASE_LENGTH 38 ret = krb5_store_int16(sp, KDB_V1_BASE_LENGTH); if (ret) return ret; nexttoken(&p); /* length of principal */ num_tl_data = getuint(&p); /* number of tl-data */ num_key_data = getuint(&p); /* number of key-data */ getint(&p); /* length of extra data */ princ = nexttoken(&p); /* principal name */ attributes = getuint(&p); /* attributes */ ret = krb5_store_uint32(sp, attributes); if (ret) return ret; tmp = getint(&p); /* max life */ CHECK_UINT(tmp); ret = krb5_store_uint32(sp, tmp); if (ret) return ret; tmp = getint(&p); /* max renewable life */ CHECK_UINT(tmp); ret = krb5_store_uint32(sp, tmp); if (ret) return ret; tmp = getint(&p); /* expiration */ CHECK_UINT(tmp); ret = krb5_store_uint32(sp, tmp); if (ret) return ret; tmp = getint(&p); /* pw expiration */ CHECK_UINT(tmp); ret = krb5_store_uint32(sp, tmp); if (ret) return ret; tmp = getint(&p); /* last auth */ CHECK_UINT(tmp); ret = krb5_store_uint32(sp, tmp); if (ret) return ret; tmp = getint(&p); /* last failed auth */ CHECK_UINT(tmp); ret = krb5_store_uint32(sp, tmp); if (ret) return ret; tmp = getint(&p); /* fail auth count */ CHECK_UINT(tmp); ret = krb5_store_uint32(sp, tmp); if (ret) return ret; /* add TL data count */ CHECK_NUM(num_tl_data, 1023); ret = krb5_store_uint16(sp, num_tl_data); if (ret) return ret; /* add key count */ CHECK_NUM(num_key_data, 1023); ret = krb5_store_uint16(sp, num_key_data); if (ret) return ret; /* add principal unparsed name length and unparsed name */ princ_len = strlen(princ); if (princ_len > (1<<15) - 1) return EINVAL; princ_len++; /* must count and write the NUL in the on-disk encoding */ ret = krb5_store_uint16(sp, princ_len); if (ret) return ret; sz = krb5_storage_write(sp, princ, princ_len); if (sz == -1) return ENOMEM; /* scan and write TL data */ for (i = 0; i < num_tl_data; i++) { int tl_type, tl_length; unsigned char *buf; tl_type = getint(&p); /* data type */ tl_length = getint(&p); /* data length */ CHECK_UINT16(tl_type); ret = krb5_store_uint16(sp, tl_type); if (ret) return ret; CHECK_UINT16(tl_length); ret = krb5_store_uint16(sp, tl_length); if (ret) return ret; if (tl_length) { buf = malloc(tl_length); if (!buf) return ENOMEM; if (getdata(&p, buf, tl_length) != tl_length) return EINVAL; sz = krb5_storage_write(sp, buf, tl_length); free(buf); if (sz == -1) return ENOMEM; } else { if (strcmp(nexttoken(&p), "-1") != 0) return EINVAL; } } for (i = 0; i < num_key_data; i++) { unsigned char *buf; int key_versions; int kvno; int keytype; int keylen; size_t k; key_versions = getint(&p); /* key data version */ CHECK_UINT16(key_versions); ret = krb5_store_int16(sp, key_versions); if (ret) return ret; kvno = getint(&p); CHECK_UINT16(kvno); ret = krb5_store_int16(sp, kvno); if (ret) return ret; for (k = 0; k < key_versions; k++) { keytype = getint(&p); CHECK_UINT16(keytype); ret = krb5_store_int16(sp, keytype); if (ret) return ret; keylen = getint(&p); CHECK_UINT16(keylen); ret = krb5_store_int16(sp, keylen); if (ret) return ret; if (keylen) { buf = malloc(keylen); if (!buf) return ENOMEM; if (getdata(&p, buf, keylen) != keylen) return EINVAL; sz = krb5_storage_write(sp, buf, keylen); free(buf); if (sz == -1) return ENOMEM; } else { if (strcmp(nexttoken(&p), "-1") != 0) return EINVAL; } } } /* * The rest is "extra data", but there's never any and we wouldn't * know what to do with it. */ /* nexttoken(&p); */ return 0; }