The internals of the structure should never be accessed directly, functions exist for extracting information.
See the manual page for krb5_init_context() how to create a context and module Heimdal Kerberos 5 library for more information about the functions.
The krb5_auth_context is used by various functions that are directly related to authentication between the server/client. Example of data that this structure contains are various flags, addresses of client and server, port numbers, keyblocks (and subkeys), sequence numbers, replay cache, and checksum types.
The are several ways to create a principal (with different degree of portability), and one way to free it.
See also the page The principal handing functions. for more information and also module Heimdal Kerberos 5 principal functions.
The credential cache data can be stored internally in different way, each of them for different proposes. File credential (FILE) caches and processes based (KCM) caches are for permanent storage. While memory caches (MEMORY) are local caches to the local process.
Caches are opened with krb5_cc_resolve() or created with krb5_cc_new_unique().
If the cache needs to be opened again (using krb5_cc_resolve()) krb5_cc_close() will close the handle, but not the remove the cache. krb5_cc_destroy() will zero out the cache, remove the cache so it can no longer be referenced.
See also The credential cache functions and Heimdal Kerberos 5 credential cache functions .
This is a great improvement compared to just getting one of the unix error-codes back. However, Heimdal have an extention to pass back customised errors messages. Instead of getting ``Key table entry not found'', the user might back ``failed to find host/host.example.com@EXAMLE.COM(kvno 3) in keytab /etc/krb5.keytab (des-cbc-crc)''. This improves the chance that the user find the cause of the error so you should use the customised error message whenever it's available.
See also module Heimdal Kerberos 5 error reporting functions .
Keytabs are used for servers and long-running services.
See also The keytab handing functions and Heimdal Kerberos 5 keytab handling functions .
See also module Heimdal Kerberos 5 cryptography functions .
All Kerberos error-codes that are returned from kerberos functions in this program are passed to krb5_err, that will print a descriptive text of the error code and exit. Graphical programs can convert error-code to a human readable error-string with the krb5_get_error_message() function.
Note that you should not use any Kerberos function before krb5_init_context() have completed successfully. That is the reason err() is used when krb5_init_context() fails.
First the client needs to call krb5_init_context to initialise the Kerberos 5 library. This is only needed once per thread in the program. If the function returns a non-zero value it indicates that either the Kerberos implementation is failing or it's disabled on this host.
#include <krb5.h> int main(int argc, char **argv) { krb5_context context; if (krb5_init_context(&context)) errx (1, "krb5_context");
Now the client wants to connect to the host at the other end. The preferred way of doing this is using getaddrinfo (for operating system that have this function implemented), since getaddrinfo is neutral to the address type and can use any protocol that is available.
struct addrinfo *ai, *a; struct addrinfo hints; int error; memset (&hints, 0, sizeof(hints)); hints.ai_socktype = SOCK_STREAM; hints.ai_protocol = IPPROTO_TCP; error = getaddrinfo (hostname, "pop3", &hints, &ai); if (error) errx (1, "%s: %s", hostname, gai_strerror(error)); for (a = ai; a != NULL; a = a->ai_next) { int s; s = socket (a->ai_family, a->ai_socktype, a->ai_protocol); if (s < 0) continue; if (connect (s, a->ai_addr, a->ai_addrlen) < 0) { warn ("connect(%s)", hostname); close (s); continue; } freeaddrinfo (ai); ai = NULL; } if (ai) { freeaddrinfo (ai); errx ("failed to contact %s", hostname); }
Before authenticating, an authentication context needs to be created. This context keeps all information for one (to be) authenticated connection (see krb5_auth_context).
status = krb5_auth_con_init (context, &auth_context); if (status) krb5_err (context, 1, status, "krb5_auth_con_init");
For setting the address in the authentication there is a help function krb5_auth_con_setaddrs_from_fd() that does everything that is needed when given a connected file descriptor to the socket.
status = krb5_auth_con_setaddrs_from_fd (context, auth_context, &sock); if (status) krb5_err (context, 1, status, "krb5_auth_con_setaddrs_from_fd");
The next step is to build a server principal for the service we want to connect to. (See also krb5_sname_to_principal().)
status = krb5_sname_to_principal (context, hostname, service, KRB5_NT_SRV_HST, &server); if (status) krb5_err (context, 1, status, "krb5_sname_to_principal");
The client principal is not passed to krb5_sendauth() function, this causes the krb5_sendauth() function to try to figure it out itself.
The server program is using the function krb5_recvauth() to receive the Kerberos 5 authenticator.
In this case, mutual authentication will be tried. That means that the server will authenticate to the client. Using mutual authentication is good since it enables the user to verify that they are talking to the right server (a server that knows the key).
If you are using a non-blocking socket you will need to do all work of krb5_sendauth() yourself. Basically you need to send over the authenticator from krb5_mk_req() and, in case of mutual authentication, verifying the result from the server with krb5_rd_rep().
status = krb5_sendauth (context, &auth_context, &sock, VERSION, NULL, server, AP_OPTS_MUTUAL_REQUIRED, NULL, NULL, NULL, NULL, NULL, NULL); if (status) krb5_err (context, 1, status, "krb5_sendauth");
Once authentication has been performed, it is time to send some data. First we create a krb5_data structure, then we sign it with krb5_mk_safe() using the auth_context that contains the session-key that was exchanged in the krb5_sendauth()/krb5_recvauth() authentication sequence.
data.data = "hej"; data.length = 3; krb5_data_zero (&packet); status = krb5_mk_safe (context, auth_context, &data, &packet, NULL); if (status) krb5_err (context, 1, status, "krb5_mk_safe");
And send it over the network.
len = packet.length; net_len = htonl(len); if (krb5_net_write (context, &sock, &net_len, 4) != 4) err (1, "krb5_net_write"); if (krb5_net_write (context, &sock, packet.data, len) != len) err (1, "krb5_net_write");
To send encrypted (and signed) data krb5_mk_priv() should be used instead. krb5_mk_priv() works the same way as krb5_mk_safe(), with the exception that it encrypts the data in addition to signing it.
data.data = "hemligt"; data.length = 7; krb5_data_free (&packet); status = krb5_mk_priv (context, auth_context, &data, &packet, NULL); if (status) krb5_err (context, 1, status, "krb5_mk_priv");
And send it over the network.
len = packet.length; net_len = htonl(len); if (krb5_net_write (context, &sock, &net_len, 4) != 4) err (1, "krb5_net_write"); if (krb5_net_write (context, &sock, packet.data, len) != len) err (1, "krb5_net_write");
The server is using krb5_rd_safe() and krb5_rd_priv() to verify the signature and decrypt the packet.
In Heimdal krb5_principal doesn't contain the component name_type; it's instead stored in component name.name_type. To get and set the nametype in Heimdal, use krb5_principal_get_type() and krb5_principal_set_type().
For more information about principal and realms, see krb5_principal.
Heimdal uses a threadsafe(r) version of the com_err interface; the global com_err table isn't initialised. Then error_message returns quite a boring error string (just the error code itself).