/** * @file bus.h * * @brief Interface of bus_t. * */ /* * Copyright (C) 2006 Martin Willi * Hochschule fuer Technik Rapperswil * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2 of the License, or (at your * option) any later version. See . * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * for more details. */ #ifndef BUS_H_ #define BUS_H_ typedef enum signal_t signal_t; typedef enum level_t level_t; typedef struct bus_listener_t bus_listener_t; typedef struct bus_t bus_t; #include #include #include #include /** * @brief signals emitted by the daemon. * * Signaling is for different purporses. First, it allows debugging via * "debugging signal messages", sencondly, it allows to follow certain * mechanisms currently going on in the daemon. As we are multithreaded, * and multiple transactions are involved, it's not possible to follow * one connection setup without further infrastructure. These infrastructure * is provided by the bus and the signals the daemon emits to the bus. * * There are different scenarios to follow these signals, but all have * the same scheme. First, a START signal is emitted to indicate the daemon * has started to do something. After a start signal, a SUCCESS or a FAILED * signal of the same type follows. This allows to track the operation. Any * Debug signal betwee a START and a SUCCESS/FAILED belongs to that operation * if the IKE_SA is the same. The thread may change, as multiple threads * may be involved in a complex scenario. * * @ingroup bus */ enum signal_t { /** pseudo signal, representing any other signal */ SIG_ANY, /** debugging message from daemon main loop */ DBG_DMN, /** debugging message from IKE_SA_MANAGER */ DBG_MGR, /** debugging message from an IKE_SA */ DBG_IKE, /** debugging message from a CHILD_SA */ DBG_CHD, /** debugging message from job processing */ DBG_JOB, /** debugging message from configuration backends */ DBG_CFG, /** debugging message from kernel interface */ DBG_KNL, /** debugging message from networking */ DBG_NET, /** debugging message from message encoding/decoding */ DBG_ENC, /** debugging message from libstrongswan via logging hook */ DBG_LIB, /** number of debug signals */ DBG_MAX, /** signals for IKE_SA establishment */ IKE_UP_START, IKE_UP_SUCCESS, IKE_UP_FAILED, /** signals for IKE_SA delete */ IKE_DOWN_START, IKE_DOWN_SUCCESS, IKE_DOWN_FAILED, /** signals for IKE_SA rekeying */ IKE_REKEY_START, IKE_REKEY_SUCCESS, IKE_REKEY_FAILED, /** signals for CHILD_SA establishment */ CHILD_UP_START, CHILD_UP_SUCCESS, CHILD_UP_FAILED, /** signals for CHILD_SA delete */ CHILD_DOWN_START, CHILD_DOWN_SUCCESS, CHILD_DOWN_FAILED, /** signals for CHILD_SA rekeying */ CHILD_REKEY_START, CHILD_REKEY_SUCCESS, CHILD_REKEY_FAILED, /** signals for CHILD_SA routing */ CHILD_ROUTE_START, CHILD_ROUTE_SUCCESS, CHILD_ROUTE_FAILED, /** signals for CHILD_SA routing */ CHILD_UNROUTE_START, CHILD_UNROUTE_SUCCESS, CHILD_UNROUTE_FAILED, SIG_MAX }; /** * short names of signals using 3 chars */ extern enum_name_t *signal_names; /** * Signal levels used to control output verbosity. */ enum level_t { /** numerical levels from 0 to 4 */ LEVEL_0 = 0, LEVEL_1 = 1, LEVEL_2 = 2, LEVEL_3 = 3, LEVEL_4 = 4, /** absolutely silent, no signal is emitted with this level */ LEVEL_SILENT = -1, /** alias for numberical levels */ LEVEL_AUDIT = LEVEL_0, LEVEL_CTRL = LEVEL_1, LEVEL_CTRLMORE = LEVEL_2, LEVEL_RAW = LEVEL_3, LEVEL_PRIVATE = LEVEL_4, }; #ifndef DEBUG_LEVEL # define DEBUG_LEVEL 4 #endif /* DEBUG_LEVEL */ #if DEBUG_LEVEL >= 1 /** * @brief Log a debug message via the signal bus. * * @param signal signal_t signal description * @param format printf() style format string * @param ... printf() style agument list */ # define DBG1(sig, format, ...) charon->bus->signal(charon->bus, sig, LEVEL_1, format, ##__VA_ARGS__) #endif /* DEBUG_LEVEL */ #if DEBUG_LEVEL >= 2 #define DBG2(sig, format, ...) charon->bus->signal(charon->bus, sig, LEVEL_2, format, ##__VA_ARGS__) #endif /* DEBUG_LEVEL */ #if DEBUG_LEVEL >= 3 #define DBG3(sig, format, ...) charon->bus->signal(charon->bus, sig, LEVEL_3, format, ##__VA_ARGS__) #endif /* DEBUG_LEVEL */ #if DEBUG_LEVEL >= 4 #define DBG4(sig, format, ...) charon->bus->signal(charon->bus, sig, LEVEL_4, format, ##__VA_ARGS__) #endif /* DEBUG_LEVEL */ #ifndef DBG1 # define DBG1(...) {} #endif /* DBG1 */ #ifndef DBG2 # define DBG2(...) {} #endif /* DBG2 */ #ifndef DBG3 # define DBG3(...) {} #endif /* DBG3 */ #ifndef DBG4 # define DBG4(...) {} #endif /* DBG4 */ /** * @brief Raise a signal for an occured event. * * @param sig signal_t signal description * @param format printf() style format string * @param ... printf() style agument list */ #define SIG(sig, format, ...) charon->bus->signal(charon->bus, sig, LEVEL_0, format, ##__VA_ARGS__) /** * @brief Get the type of a signal. * * A signal may be a debugging signal with a specific context. They have * a level specific for their context > 0. All audit signals use the * type 0. This allows filtering of singals by their type. * * @param signal signal to get the type from * @return type of the signal, between 0..(DBG_MAX-1) */ #define SIG_TYPE(sig) (sig > DBG_MAX ? SIG_ANY : sig) /** * @brief Interface for registering at the signal bus. * * To receive signals from the bus, the client implementing the * bus_listener_t interface registers itself at the signal bus. * * @ingroup bus */ struct bus_listener_t { /** * @brief Send a signal to a bus listener. * * A numerical identification for the thread is included, as the * associated IKE_SA, if any. Signal specifies the type of * the event occured. The format string specifies * an additional informational or error message with a printf() like * variable argument list. This is in the va_list form, as forwarding * a "..." parameters to functions is not (cleanly) possible. * The implementing signal function returns TRUE to stay registered * to the bus, or FALSE to unregister itself. * * @param this listener * @param singal kind of the signal (up, down, rekeyed, ...) * @param level verbosity level of the signal * @param thread ID of the thread raised this signal * @param ike_sa IKE_SA associated to the event * @param format printf() style format string * @param args vprintf() style va_list argument list " @return TRUE to stay registered, FALSE to unregister */ bool (*signal) (bus_listener_t *this, signal_t signal, level_t level, int thread, ike_sa_t *ike_sa, char* format, va_list args); }; /** * @brief Signal bus which sends signals to registered listeners. * * The signal bus is not much more than a multiplexer. A listener interested * in receiving event signals registers at the bus. Any signals sent to * are delivered to all registered listeners. * To deliver signals to threads, the blocking listen() call may be used * to wait for a signal. * * @ingroup bus */ struct bus_t { /** * @brief Register a listener to the bus. * * A registered listener receives all signals which are sent to the bus. * The listener is passive; the thread which emitted the signal * processes the listener routine. * * @param this bus * @param listener listener to register. */ void (*add_listener) (bus_t *this, bus_listener_t *listener); /** * @brief Unregister a listener from the bus. * * @param this bus * @param listener listener to unregister. */ void (*remove_listener) (bus_t *this, bus_listener_t *listener); /** * @brief Register a listener and block the calling thread. * * This call registers a listener and blocks the calling thread until * its listeners function returns FALSE. This allows to wait for certain * events. The associated job is executed after the listener has been * registered, this allows to listen on events we initiate with the job * without missing any signals. * * @param this bus * @param listener listener to register * @param job job to execute asynchronously when registered, or NULL */ void (*listen)(bus_t *this, bus_listener_t *listener, job_t *job); /** * @brief Set the IKE_SA the calling thread is using. * * To associate an received signal to an IKE_SA without passing it as * parameter each time, the thread registers it's used IKE_SA each * time it checked it out. Before checking it in, the thread unregisters * the IKE_SA (by passing NULL). This IKE_SA is stored per-thread, so each * thread has one IKE_SA registered (or not). * * @param this bus * @param ike_sa ike_sa to register, or NULL to unregister */ void (*set_sa) (bus_t *this, ike_sa_t *ike_sa); /** * @brief Send a signal to the bus. * * The signal specifies the type of the event occured. The format string * specifies an additional informational or error message with a * printf() like variable argument list. * Some useful macros are available to shorten this call. * @see SIG(), DBG1() * * @param this bus * @param singal kind of the signal (up, down, rekeyed, ...) * @param level verbosity level of the signal * @param format printf() style format string * @param ... printf() style argument list */ void (*signal) (bus_t *this, signal_t signal, level_t level, char* format, ...); /** * @brief Send a signal to the bus using va_list arguments. * * Same as bus_t.signal(), but uses va_list argument list. * * @todo Improve performace of vsignal implementation. This method is * called extensively and therefore shouldn't allocate heap memory or * do other expensive tasks! * * @param this bus * @param singal kind of the signal (up, down, rekeyed, ...) * @param level verbosity level of the signal * @param format printf() style format string * @param args va_list arguments */ void (*vsignal) (bus_t *this, signal_t signal, level_t level, char* format, va_list args); /** * @brief Destroy the signal bus. * * @param this bus to destroy */ void (*destroy) (bus_t *this); }; /** * @brief Create the signal bus which multiplexes signals to its listeners. * * @return signal bus instance * * @ingroup bus */ bus_t *bus_create(); #endif /* BUS_H_ */