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The following section presents Kerberos terms and their definitions. These terms are used throughout the Kerberos documentation. To grasp Kerberos concepts, an understanding of these terms is essential.
You need to understand the terms in this section in order to administer KDCs.
The Key Distribution Center or KDC is the component of Kerberos that is responsible for issuing credentials. These credentials are created by using information that is stored in the KDC database. Each realm needs at least two KDCs, a master and at least one slave. All KDCs generate credentials, but only the master KDC handles any changes to the KDC database.
A stash file contains the master key for the KDC. This key is used when a server is rebooted to automatically authenticate the KDC before starting the kadmind and krb5kdc commands. Because this file includes the master key, the file and any backups of the file should be kept secure. The file is created with read-only permissions for root. To keep the file secure, do not change the permissions. If the file is compromised, then the key could be used to access or modify the KDC database.
You need to know the terms in this section to understand the authentication process. Programmers and system administrators should be familiar with these terms.
A client is the software that runs on a user's workstation. The Kerberos software that runs on the client makes many requests during this process. So, differentiating the actions of this software from the user is important.
The terms server and service are often used interchangeably. To clarify, the term server is used to define the physical system that Kerberos software is running on. The term service corresponds to a particular function that is being supported on a server (for example, ftp or nfs). Documentation often mentions servers as part of a service, but this definition clouds the meaning of the terms. Therefore, the term server refers to the physical system. The term service refers to the software.
The Kerberos product uses two types of keys. One type of key is a password derived key. The password derived key is given to each user principal and is known only to the user and to the KDC. The other type of key used by the Kerberos product is a random key that is not associated with a password and so is not suitable for use by user principals. Random keys are typically used for service principals that have entries in a keytab and session keys generated by the KDC. Service principals can use random keys since the service can access the key in the keytab which allows it to run non-interactively. Session keys are generated by the KDC (and shared between the client and service) to provide secure transactions between a client and a service.
A ticket is an information packet that is used to securely pass the identity of a user to a server or service. A ticket is valid for only a single client and a particular service on a specific server. A ticket contains:
Principal name of the service
Principal name of the user
IP address of the user's host
Value which defines the lifetime of the ticket
Copy of the session key
All of this data is encrypted in the server's service key. Note, the KDC issues the ticket embedded in a credential described below. After a ticket has been issued, it can be reused until the ticket expires.
A credential is a packet of information that includes a ticket and a matching session key. The credential is encrypted with the requesting principal's key. Typically, the KDC generates a credential in response to a ticket request from a client.
An authenticator is information used by the server to authenticate the client user principal. An authenticator includes the principal name of the user, a timestamp, and other data. Unlike a ticket, an authenticator can be used once only, usually when access to a service is requested. An authenticator is encrypted by using the session key shared by the client and server. Typically, the client creates the authenticator and sends it with the server's or service's ticket in order to authenticate to the server or service.
Tickets have properties that govern how they can be used. These properties are assigned to the ticket when it is created, although you can modify a ticket's properties later. For example, a ticket can change from being forwardable to being forwarded. You can view ticket properties with the klist command. See Viewing Kerberos Tickets.
Tickets can be described by one or more of the following terms:
A forwardable ticket can be sent from one host to another host, obviating the need for a client to reauthenticate itself. For example, if the user david obtains a forwardable ticket while on user jennifer's machine, he can log in to his own machine without having to get a new ticket (and thus authenticate himself again). See Example 26-1 for an example of a forwardable ticket.
An initial ticket is a ticket that is issued directly, not based on a ticket-granting ticket. Some services, such as applications that change passwords, can require tickets to be marked initial in order to assure themselves that the client can demonstrate a knowledge of its secret key. An initial ticket indicates that the client has recently authenticated itself, instead of relying on a ticket-granting ticket, which might have been around for a long time.
An invalid ticket is a postdated ticket that has not yet become usable. An invalid ticket will be rejected by an application server until it becomes validated. To be validated, a ticket must be presented to the KDC by the client in a ticket–granting service request, with the VALIDATE flag set, after its start time has passed.
A postdated ticket is a ticket that does not become valid until some specified time after its creation. Such a ticket is useful, for example, for batch jobs that are intended to be run late at night, because the ticket, if stolen, cannot be used until the batch job is to be run. When a postdated ticket is issued, it is issued as invalid and remains that way until its start time has passed, and the client requests validation by the KDC. A postdated ticket is normally valid until the expiration time of the ticket-granting ticket. However, if the ticket is marked renewable, its lifetime is normally set to be equal to the duration of the full life of the ticket-granting ticket.
At times, it is necessary for a principal to allow a service to perform an operation on its behalf. The principal name of the proxy must be specified when the ticket is created. The Oracle Solaris release does not support proxiable or proxy tickets.
A proxiable ticket is similar to a forwardable ticket, except that it is valid only for a single service, whereas a forwardable ticket grants the service the complete use of the client's identity. A forwardable ticket can therefore be thought of as a sort of super-proxy.
Because it is a security risk to have tickets with very long lives, tickets can be designated as renewable. A renewable ticket has two expiration times: the time at which the current instance of the ticket expires, and the maximum lifetime for any ticket, which is one week. If a client wants to continue to use a ticket, the client renews it before the first expiration occurs. For example, a ticket can be valid for one hour, with all tickets having a maximum lifetime of 10 hours. If the client that is holding the ticket wants to keep it for more than an hour, the client must renew it within that hour. When a ticket reaches the maximum ticket lifetime (10 hours), it automatically expires and cannot be renewed.
For information on how to view the attributes of tickets, see Viewing Kerberos Tickets.
Any time a principal obtains a ticket, including a ticket–granting ticket (TGT), the ticket's lifetime is set as the smallest of the following lifetime values:
The maximum lifetime value that is specified in the Kerberos database for the service principal that provides the ticket. In the case of kinit, the service principal is krbtgt/realm.
The maximum lifetime value that is specified in the Kerberos database for the user principal that requests the ticket.
Figure 27-1 shows how a TGT's lifetime is determined and where the four lifetime values come from. Even though this figure shows how a TGT's lifetime is determined, basically the same thing happens when any principal obtains a ticket. The only differences are that kinit doesn't provide a lifetime value, and the service principal that provides the ticket provides a maximum lifetime value (instead of the krbtgt/realm principal).
Figure 27-1 How a TGT's Lifetime is Determined
The renewable ticket lifetime is also determined from the minimum of four values, but renewable lifetime values are used instead, as follows:
The renewable lifetime value that is specified by the -r option of kinit, if kinit is used to obtain or renew the ticket.
The maximum lifetime renewable value that is specified in the Kerberos database for the service principal that provides the ticket. In the case of kinit, the service principal is krbtgt/realm.
The maximum lifetime renewable value that is specified in the Kerberos database for the user principal that requests the ticket.
Each ticket is identified by a principal name. The principal name can identify a user or a service. Here are examples of several principal names.
Table 27-4 Examples of Kerberos Principal Names