Starting with version 2.3.10, pppd includes support for `plugins' - pieces of code which can be loaded into pppd at runtime and which can affect its behaviour in various ways. The idea of plugins is to provide a way for people to customize the behaviour of pppd without having to either apply local patches to each version or get their patches accepted into the standard distribution. A plugin is a standard shared library object, typically with a name ending in .so. They are loaded using the standard dlopen() library call, so plugins are only supported on systems which support shared libraries and the dlopen call. At present pppd is compiled with plugin support only under Linux and Solaris. Plugins are loaded into pppd using the `plugin' option, which takes one argument, the name of a shared object file. The plugin option is a privileged option. If the name given does not contain a slash, pppd will look in the /usr/lib/pppd/ directory for the file, where is the version number of pppd, for example, 2.4.2. I suggest that you either give the full path name of the shared object file or just the base name; if you don't, it may be possible for unscrupulous users to substitute another shared object file for the one you mean to load, e.g. by setting the LD_LIBRARY_PATH variable. Plugins are usually written in C and compiled and linked to a shared object file in the appropriate manner for your platform. Using gcc under Linux, a plugin called `xyz' could be compiled and linked with the following commands: gcc -c -O xyz.c gcc -shared -o xyz.so xyz.o There are some example plugins in the pppd/plugins directory in the ppp distribution. Currently there is one example, minconn.c, which implements a `minconnect' option, which specifies a minimum connect time before the idle timeout applies. Plugins can access global variables within pppd, so it is useful for them to #include "pppd.h" from the pppd source directory. Every plugin must contain a global procedure called `plugin_init'. This procedure will get called (with no arguments) immediately after the plugin is loaded. Every plugin should also contain a variable called pppd_version declared as follows: char pppd_version[] = VERSION; If this declaration is included, pppd will not load the module if its version number differs from that compiled into the plugin binary. Plugins can affect the behaviour of pppd in at least four ways: 1. They can add extra options which pppd will then recognize. This is done by calling the add_options() procedure with a pointer to an array of option_t structures. The last entry in the array must have its name field set to NULL. 2. Pppd contains `hook' variables which are procedure pointers. If a given hook is not NULL, pppd will call the procedure it points to at the appropriate point in its processing. The plugin can set any of these hooks to point to its own procedures. See below for a description of the hooks which are currently implemented. 3. Plugin code can call any global procedures and access any global variables in pppd. 4. Plugins can register procedures to be called when particular events occur, using the `notifier' mechanism in pppd. The differences between hooks and notifiers are that a hook will only call one function, whereas a notifier can call an arbitrary number, and that a hook usually returns some value to pppd, whereas a notifier function returns nothing. Here is a list of the currently implemented hooks in pppd. int (*idle_time_hook)(struct ppp_idle *idlep); The idle_time_hook is called when the link first comes up (i.e. when the first network protocol comes up) and at intervals thereafter. On the first call, the idlep parameter is NULL, and the return value is the number of seconds before pppd should check the link activity, or 0 if there is to be no idle timeout. On subsequent calls, idlep points to a structure giving the number of seconds since the last packets were sent and received. If the return value is > 0, pppd will wait that many seconds before checking again. If it is <= 0, that indicates that the link should be terminated due to lack of activity. int (*holdoff_hook)(void); The holdoff_hook is called when an attempt to bring up the link fails, or the link is terminated, and the persist or demand option was used. It returns the number of seconds that pppd should wait before trying to reestablish the link (0 means immediately). int (*pap_check_hook)(void); int (*pap_passwd_hook)(char *user, char *passwd); int (*pap_auth_hook)(char *user, int userlen, char *passwd, int passlen, char **msgp, int *msglenp, struct wordlist **paddrs, struct wordlist **popts); void (*pap_logout_hook)(void); These hooks are designed to allow a plugin to replace the normal PAP password processing in pppd with something different (e.g. contacting an external server). The pap_check_hook is called to check whether there is any possibility that the peer could authenticate itself to us. If it returns 1, pppd will ask the peer to authenticate itself. If it returns 0, pppd will not ask the peer to authenticate itself (but if authentication is required, pppd may exit, or terminate the link before network protocol negotiation). If it returns -1, pppd will look in the pap-secrets file as it would normally. The pap_passwd_hook is called to determine what username and password pppd should use in authenticating itself to the peer with PAP. The user string will already be initialized, by the `user' option, the `name' option, or from the hostname, but can be changed if necessary. MAXNAMELEN bytes of space are available at *user, and MAXSECRETLEN bytes of space at *passwd. If this hook returns 0, pppd will use the values at *user and *passwd; if it returns -1, pppd will look in the pap-secrets file, or use the value from the +ua or password option, as it would normally. The pap_auth_hook is called to determine whether the username and password supplied by the peer are valid. user and passwd point to null-terminated strings containing the username and password supplied by the peer, with non-printable characters converted to a printable form. The pap_auth_hook function should set msg to a string to be returned to the peer and return 1 if the username/password was valid and 0 if not. If the hook returns -1, pppd will look in the pap-secrets file as usual. If the username/password was valid, the hook can set *paddrs to point to a wordlist containing the IP address(es) which the peer is permitted to use, formatted as in the pap-secrets file. It can also set *popts to a wordlist containing any extra options for this user which pppd should apply at this point. The pap_logout_hook is called when the link is terminated, instead of pppd's internal `plogout' function. It can be used for accounting purposes. This hook is deprecated and will be replaced by a notifier. int (*chap_check_hook)(void); int (*chap_passwd_hook)(char *user, char *passwd); int (*chap_auth_hook)(char *user, u_char *remmd, int remmd_len, chap_state *cstate); These hooks are designed to allow a plugin to replace the normal CHAP password processing in pppd with something different (e.g. contacting an external server). The chap_check_hook is called to check whether there is any possibility that the peer could authenticate itself to us. If it returns 1, pppd will ask the peer to authenticate itself. If it returns 0, pppd will not ask the peer to authenticate itself (but if authentication is required, pppd may exit, or terminate the link before network protocol negotiation). If it returns -1, pppd will look in the chap-secrets file as it would normally. The chap_passwd_hook is called to determine what password pppd should use in authenticating itself to the peer with CHAP. The user string will already be initialized, by the `user' option, the `name' option, or from the hostname, but can be changed if necessary. This hook is called only if pppd is a client, not if it is a server. MAXSECRETLEN bytes of space are available at *passwd. If this hook returns 0, pppd will use the value *passwd; if it returns -1, pppd will fail to authenticate. The chap_auth_hook is called to determine whether the response to a CHAP challenge provided by the peer is valid. user points to a null-terminated string containing the username supplied by the peer. remmd points to the response provided by the peer, of length remmd_len bytes. cstate is the internal CHAP state structure maintained by pppd. chap_auth_hook is expected to return one of CHAP_SUCCESS or CHAP_FAILURE. int (*null_auth_hook)(struct wordlist **paddrs, struct wordlist **popts); This hook allows a plugin to determine what the policy should be if the peer refuses to authenticate when it is requested to. If the return value is 0, the link will be terminated; if it is 1, the connection is allowed to proceed, and in this case *paddrs and *popts can be set as for pap_auth_hook, to specify what IP addresses are permitted and any extra options to be applied. If the return value is -1, pppd will look in the pap-secrets file as usual. void (*ip_choose_hook)(u_int32_t *addrp); This hook is called at the beginning of IPCP negotiation. It gives a plugin the opportunity to set the IP address for the peer; the address should be stored in *addrp. If nothing is stored in *addrp, pppd will determine the peer's address in the usual manner. int (*allowed_address_hook)(u_int32_t addr) This hook is called to see if a peer is allowed to use the specified address. If the hook returns 1, the address is accepted. If it returns 0, the address is rejected. If it returns -1, the address is verified in the normal away against the appropriate options and secrets files. void (*snoop_recv_hook)(unsigned char *p, int len) void (*snoop_send_hook)(unsigned char *p, int len) These hooks are called whenever pppd receives or sends a packet. The packet is in p; its length is len. This allows plugins to "snoop in" on the pppd conversation. The hooks may prove useful in implmenting L2TP. A plugin registers itself with a notifier by declaring a procedure of the form: void my_notify_proc(void *opaque, int arg); and then registering the procedure with the appropriate notifier with a call of the form add_notifier(&interesting_notifier, my_notify_proc, opaque); The `opaque' parameter in the add_notifier call will be passed to my_notify_proc every time it is called. The `arg' parameter to my_notify_proc depends on the notifier. A notify procedure can be removed from the list for a notifier with a call of the form remove_notifier(&interesting_notifier, my_notify_proc, opaque); Here is a list of the currently-implemented notifiers in pppd. * pidchange. This notifier is called in the parent when pppd has forked and the child is continuing pppd's processing, i.e. when pppd detaches from its controlling terminal. The argument is the pid of the child. * phasechange. This is called when pppd moves from one phase of operation to another. The argument is the new phase number. * exitnotify. This is called just before pppd exits. The argument is the status with which pppd will exit (i.e. the argument to exit()). * sigreceived. This is called when a signal is received, from within the signal handler. The argument is the signal number. * ip_up_notifier. This is called when IPCP has come up. * ip_down_notifier. This is called when IPCP goes down. * auth_up_notifier. This is called when the peer has successfully authenticated itself. * link_down_notifier. This is called when the link goes down. ## $Id: PLUGINS,v 1.5 2002/02/12 20:07:09 dfs Exp $ ##