288 lines
10 KiB
Plaintext
288 lines
10 KiB
Plaintext
@c $Id: programming.texi,v 1.2 2003/04/26 22:07:12 wiz Exp $
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@node Programming with Kerberos
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@chapter Programming with Kerberos
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First you need to know how the Kerberos model works, go read the
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introduction text (@pxref{What is Kerberos?}).
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@macro manpage{man, section}
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@cite{\man\(\section\)}
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@end macro
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@menu
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* Kerberos 5 API Overview::
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* Walkthru a sample Kerberos 5 client::
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* Validating a password in a server application::
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@end menu
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@node Kerberos 5 API Overview, Walkthru a sample Kerberos 5 client, Programming with Kerberos, Programming with Kerberos
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@section Kerberos 5 API Overview
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Most functions are documenteded in manual pages. This overview only
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tries to point to where to look for a specific function.
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@subsection Kerberos context
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A kerberos context (@code{krb5_context}) holds all per thread state. All global variables that
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are context specific are stored in this struture, including default
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encryption types, credential-cache (ticket file), and default realms.
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See the manual pages for @manpage{krb5_context,3} and
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@manpage{krb5_init_context,3}.
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@subsection Kerberos authenication context
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Kerberos authentication context (@code{krb5_auth_context}) holds all
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context related to an authenticated connection, in a similar way to the
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kerberos context that holds the context for the thread or process.
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The @code{krb5_auth_context} is used by various functions that are
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directly related to authentication between the server/client. Example of
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data that this structure contains are various flags, addresses of client
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and server, port numbers, keyblocks (and subkeys), sequence numbers,
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replay cache, and checksum types.
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See the manual page for @manpage{krb5_auth_context,3}.
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@subsection Keytab management
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A keytab is a storage for locally stored keys. Heimdal includes keytab
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support for Kerberos 5 keytabs, Kerberos 4 srvtab, AFS-KeyFile's,
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and for storing keys in memory.
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See also manual page for @manpage{krb5_keytab,3}
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@node Walkthru a sample Kerberos 5 client, Validating a password in a server application, Kerberos 5 API Overview, Programming with Kerberos
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@section Walkthru a sample Kerberos 5 client
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This example contains parts of a sample TCP Kerberos 5 clients, if you
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want a real working client, please look in @file{appl/test} directory in
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the Heimdal distribution.
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All Kerberos error-codes that are returned from kerberos functions in
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this program are passed to @code{krb5_err}, that will print a
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descriptive text of the error code and exit. Graphical programs can
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convert error-code to a humal readable error-string with the
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@manpage{krb5_get_err_text,3} function.
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Note that you should not use any Kerberos function before
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@code{krb5_init_context()} have completed successfully. That is the
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reson @code{err()} is used when @code{krb5_init_context()} fails.
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First the client needs to call @code{krb5_init_context} to initialize
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the Kerberos 5 library. This is only needed once per thread
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in the program. If the function returns a non-zero value it indicates
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that either the Kerberos implemtation is failing or its disabled on
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this host.
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@example
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#include <krb5.h>
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int
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main(int argc, char **argv)
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@{
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krb5_context context;
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if (krb5_context(&context))
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errx (1, "krb5_context");
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@end example
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Now the client wants to connect to the host at the other end. The
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preferred way of doing this is using @manpage{getaddrinfo,3} (for
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operating system that have this function implemented), since getaddrinfo
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is neutral to the address type and can use any protocol that is available.
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@example
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struct addrinfo *ai, *a;
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struct addrinfo hints;
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int error;
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memset (&hints, 0, sizeof(hints));
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hints.ai_socktype = SOCK_STREAM;
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hints.ai_protocol = IPPROTO_TCP;
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error = getaddrinfo (hostname, "pop3", &hints, &ai);
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if (error)
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errx (1, "%s: %s", hostname, gai_strerror(error));
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for (a = ai; a != NULL; a = a->ai_next) @{
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int s;
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s = socket (a->ai_family, a->ai_socktype, a->ai_protocol);
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if (s < 0)
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continue;
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if (connect (s, a->ai_addr, a->ai_addrlen) < 0) @{
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warn ("connect(%s)", hostname);
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close (s);
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continue;
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@}
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freeaddrinfo (ai);
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ai = NULL;
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@}
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if (ai) @{
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freeaddrinfo (ai);
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errx ("failed to contact %s", hostname);
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@}
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@end example
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Before authenticating, an authentication context needs to be
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created. This context keeps all information for one (to be) authenticated
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connection (see @manpage{krb5_auth_context,3}).
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@example
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status = krb5_auth_con_init (context, &auth_context);
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if (status)
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krb5_err (context, 1, status, "krb5_auth_con_init");
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@end example
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For setting the address in the authentication there is a help function
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@code{krb5_auth_con_setaddrs_from_fd} that does everthing that is needed
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when given a connected file descriptor to the socket.
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@example
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status = krb5_auth_con_setaddrs_from_fd (context,
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auth_context,
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&sock);
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if (status)
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krb5_err (context, 1, status,
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"krb5_auth_con_setaddrs_from_fd");
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@end example
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The next step is to build a server principal for the service we want
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to connect to. (See also @manpage{krb5_sname_to_principal,3}.)
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@example
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status = krb5_sname_to_principal (context,
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hostname,
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service,
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KRB5_NT_SRV_HST,
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&server);
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if (status)
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krb5_err (context, 1, status, "krb5_sname_to_principal");
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@end example
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The client principal is not passed to @manpage{krb5_sendauth,3}
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function, this causes the @code{krb5_sendauth} function to try to figure it
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out itself.
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The server program is using the function @manpage{krb5_recvauth,3} to
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receive the Kerberos 5 authenticator.
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In this case, mutual authenication will be tried. That means that the server
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will authenticate to the client. Using mutual authenication
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is good since it enables the user to verify that they are talking to the
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right server (a server that knows the key).
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If you are using a non-blocking socket you will need to do all work of
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@code{krb5_sendauth} yourself. Basically you need to send over the
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authenticator from @manpage{krb5_mk_req,3} and, in case of mutual
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authentication, verifying the result from the server with
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@manpage{krb5_rd_rep,3}.
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@example
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status = krb5_sendauth (context,
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&auth_context,
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&sock,
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VERSION,
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NULL,
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server,
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AP_OPTS_MUTUAL_REQUIRED,
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NULL,
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NULL,
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NULL,
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NULL,
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NULL,
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NULL);
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if (status)
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krb5_err (context, 1, status, "krb5_sendauth");
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@end example
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Once authentication has been performed, it is time to send some
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data. First we create a krb5_data structure, then we sign it with
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@manpage{krb5_mk_safe,3} using the @code{auth_context} that contains the
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session-key that was exchanged in the
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@manpage{krb5_sendauth,3}/@manpage{krb5_recvauth,3} authentication
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sequence.
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@example
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data.data = "hej";
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data.length = 3;
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krb5_data_zero (&packet);
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status = krb5_mk_safe (context,
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auth_context,
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&data,
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&packet,
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NULL);
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if (status)
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krb5_err (context, 1, status, "krb5_mk_safe");
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@end example
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And send it over the network.
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@example
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len = packet.length;
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net_len = htonl(len);
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if (krb5_net_write (context, &sock, &net_len, 4) != 4)
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err (1, "krb5_net_write");
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if (krb5_net_write (context, &sock, packet.data, len) != len)
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err (1, "krb5_net_write");
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@end example
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To send encrypted (and signed) data @manpage{krb5_mk_priv,3} should be
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used instead. @manpage{krb5_mk_priv,3} works the same way as
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@manpage{krb5_mk_safe,3}, with the exception that it encrypts the data
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in addition to signing it.
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@example
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data.data = "hemligt";
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data.length = 7;
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krb5_data_free (&packet);
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status = krb5_mk_priv (context,
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auth_context,
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&data,
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&packet,
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NULL);
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if (status)
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krb5_err (context, 1, status, "krb5_mk_priv");
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@end example
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And send it over the network.
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@example
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len = packet.length;
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net_len = htonl(len);
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if (krb5_net_write (context, &sock, &net_len, 4) != 4)
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err (1, "krb5_net_write");
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if (krb5_net_write (context, &sock, packet.data, len) != len)
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err (1, "krb5_net_write");
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@end example
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The server is using @manpage{krb5_rd_safe,3} and
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@manpage{krb5_rd_priv,3} to verify the signature and decrypt the packet.
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@node Validating a password in a server application, , Walkthru a sample Kerberos 5 client, Programming with Kerberos
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@section Validating a password in an application
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See the manual page for @manpage{krb5_verify_user,3}.
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@c @node Why you should use GSS-API for new applications, Walkthru a sample GSS-API client, Validating a password in a server application, Programming with Kerberos
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@c @section Why you should use GSS-API for new applications
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@c
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@c SSPI, bah, bah, microsoft, bah, bah, almost GSS-API.
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@c
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@c It would also be possible for other mechanisms then Kerberos, but that
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@c doesn't exist any other GSS-API implementations today.
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@c
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@c @node Walkthru a sample GSS-API client, , Why you should use GSS-API for new applications, Programming with Kerberos
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@c @section Walkthru a sample GSS-API client
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@c
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@c Write about how gssapi_clent.c works.
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