/* Unix SMB/CIFS implementation. generalised event loop handling Copyright (C) Andrew Tridgell 2005 Copyright (C) Stefan Metzmacher 2005-2009 Copyright (C) Volker Lendecke 2008 ** NOTE! The following LGPL license applies to the tevent ** library. This does NOT imply that all of Samba is released ** under the LGPL This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This library 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, see . */ #ifndef __TEVENT_H__ #define __TEVENT_H__ #include #include #include #include struct tevent_context; struct tevent_ops; struct tevent_fd; struct tevent_timer; struct tevent_immediate; struct tevent_signal; struct tevent_thread_proxy; struct tevent_threaded_context; /** * @defgroup tevent The tevent API * * The tevent low-level API * * This API provides the public interface to manage events in the tevent * mainloop. Functions are provided for managing low-level events such * as timer events, fd events and signal handling. * * @{ */ /* event handler types */ /** * Called when a file descriptor monitored by tevent has * data to be read or written on it. */ typedef void (*tevent_fd_handler_t)(struct tevent_context *ev, struct tevent_fd *fde, uint16_t flags, void *private_data); /** * Called when tevent is ceasing the monitoring of a file descriptor. */ typedef void (*tevent_fd_close_fn_t)(struct tevent_context *ev, struct tevent_fd *fde, int fd, void *private_data); /** * Called when a tevent timer has fired. */ typedef void (*tevent_timer_handler_t)(struct tevent_context *ev, struct tevent_timer *te, struct timeval current_time, void *private_data); /** * Called when a tevent immediate event is invoked. */ typedef void (*tevent_immediate_handler_t)(struct tevent_context *ctx, struct tevent_immediate *im, void *private_data); /** * Called after tevent detects the specified signal. */ typedef void (*tevent_signal_handler_t)(struct tevent_context *ev, struct tevent_signal *se, int signum, int count, void *siginfo, void *private_data); /** * @brief Create a event_context structure. * * This must be the first events call, and all subsequent calls pass this * event_context as the first element. Event handlers also receive this as * their first argument. * * @param[in] mem_ctx The memory context to use. * * @return An allocated tevent context, NULL on error. * * @see tevent_context_init() */ struct tevent_context *tevent_context_init(TALLOC_CTX *mem_ctx); /** * @brief Create a event_context structure and select a specific backend. * * This must be the first events call, and all subsequent calls pass this * event_context as the first element. Event handlers also receive this as * their first argument. * * @param[in] mem_ctx The memory context to use. * * @param[in] name The name of the backend to use. * * @return An allocated tevent context, NULL on error. */ struct tevent_context *tevent_context_init_byname(TALLOC_CTX *mem_ctx, const char *name); /** * @brief Create a custom event context * * @param[in] mem_ctx The memory context to use. * @param[in] ops The function pointer table of the backend. * @param[in] additional_data The additional/private data to this instance * * @return An allocated tevent context, NULL on error. * */ struct tevent_context *tevent_context_init_ops(TALLOC_CTX *mem_ctx, const struct tevent_ops *ops, void *additional_data); /** * @brief List available backends. * * @param[in] mem_ctx The memory context to use. * * @return A string vector with a terminating NULL element, NULL * on error. */ const char **tevent_backend_list(TALLOC_CTX *mem_ctx); /** * @brief Set the default tevent backend. * * @param[in] backend The name of the backend to set. */ void tevent_set_default_backend(const char *backend); #ifdef DOXYGEN /** * @brief Add a file descriptor based event. * * @param[in] ev The event context to work on. * * @param[in] mem_ctx The talloc memory context to use. * * @param[in] fd The file descriptor to base the event on. * * @param[in] flags #TEVENT_FD_READ or #TEVENT_FD_WRITE * * @param[in] handler The callback handler for the event. * * @param[in] private_data The private data passed to the callback handler. * * @return The file descriptor based event, NULL on error. * * @note To cancel the monitoring of a file descriptor, call talloc_free() * on the object returned by this function. * * @note The caller should avoid closing the file descriptor before * calling talloc_free()! Otherwise the behaviour is undefined which * might result in crashes. See https://bugzilla.samba.org/show_bug.cgi?id=11141 * for an example. */ struct tevent_fd *tevent_add_fd(struct tevent_context *ev, TALLOC_CTX *mem_ctx, int fd, uint16_t flags, tevent_fd_handler_t handler, void *private_data); #else struct tevent_fd *_tevent_add_fd(struct tevent_context *ev, TALLOC_CTX *mem_ctx, int fd, uint16_t flags, tevent_fd_handler_t handler, void *private_data, const char *handler_name, const char *location); #define tevent_add_fd(ev, mem_ctx, fd, flags, handler, private_data) \ _tevent_add_fd(ev, mem_ctx, fd, flags, handler, private_data, \ #handler, __location__) #endif #ifdef DOXYGEN /** * @brief Add a timed event * * @param[in] ev The event context to work on. * * @param[in] mem_ctx The talloc memory context to use. * * @param[in] next_event Timeval specifying the absolute time to fire this * event. This is not an offset. * * @param[in] handler The callback handler for the event. * * @param[in] private_data The private data passed to the callback handler. * * @return The newly-created timer event, or NULL on error. * * @note To cancel a timer event before it fires, call talloc_free() on the * event returned from this function. This event is automatically * talloc_free()-ed after its event handler files, if it hasn't been freed yet. * * @note Unlike some mainloops, tevent timers are one-time events. To set up * a recurring event, it is necessary to call tevent_add_timer() again during * the handler processing. * * @note Due to the internal mainloop processing, a timer set to run * immediately will do so after any other pending timers fire, but before * any further file descriptor or signal handling events fire. Callers should * not rely on this behavior! */ struct tevent_timer *tevent_add_timer(struct tevent_context *ev, TALLOC_CTX *mem_ctx, struct timeval next_event, tevent_timer_handler_t handler, void *private_data); #else struct tevent_timer *_tevent_add_timer(struct tevent_context *ev, TALLOC_CTX *mem_ctx, struct timeval next_event, tevent_timer_handler_t handler, void *private_data, const char *handler_name, const char *location); #define tevent_add_timer(ev, mem_ctx, next_event, handler, private_data) \ _tevent_add_timer(ev, mem_ctx, next_event, handler, private_data, \ #handler, __location__) #endif /** * @brief Set the time a tevent_timer fires * * @param[in] te The timer event to reset * * @param[in] next_event Timeval specifying the absolute time to fire this * event. This is not an offset. */ void tevent_update_timer(struct tevent_timer *te, struct timeval next_event); #ifdef DOXYGEN /** * Initialize an immediate event object * * This object can be used to trigger an event to occur immediately after * returning from the current event (before any other event occurs) * * @param[in] mem_ctx The talloc memory context to use as the parent * * @return An empty tevent_immediate object. Use tevent_schedule_immediate * to populate and use it. * * @note Available as of tevent 0.9.8 */ struct tevent_immediate *tevent_create_immediate(TALLOC_CTX *mem_ctx); #else struct tevent_immediate *_tevent_create_immediate(TALLOC_CTX *mem_ctx, const char *location); #define tevent_create_immediate(mem_ctx) \ _tevent_create_immediate(mem_ctx, __location__) #endif #ifdef DOXYGEN /** * Schedule an event for immediate execution. This event will occur * immediately after returning from the current event (before any other * event occurs) * * @param[in] im The tevent_immediate object to populate and use * @param[in] ctx The tevent_context to run this event * @param[in] handler The event handler to run when this event fires * @param[in] private_data Data to pass to the event handler */ void tevent_schedule_immediate(struct tevent_immediate *im, struct tevent_context *ctx, tevent_immediate_handler_t handler, void *private_data); #else void _tevent_schedule_immediate(struct tevent_immediate *im, struct tevent_context *ctx, tevent_immediate_handler_t handler, void *private_data, const char *handler_name, const char *location); #define tevent_schedule_immediate(im, ctx, handler, private_data) \ _tevent_schedule_immediate(im, ctx, handler, private_data, \ #handler, __location__); #endif #ifdef DOXYGEN /** * @brief Add a tevent signal handler * * tevent_add_signal() creates a new event for handling a signal the next * time through the mainloop. It implements a very simple traditional signal * handler whose only purpose is to add the handler event into the mainloop. * * @param[in] ev The event context to work on. * * @param[in] mem_ctx The talloc memory context to use. * * @param[in] signum The signal to trap * * @param[in] handler The callback handler for the signal. * * @param[in] sa_flags sigaction flags for this signal handler. * * @param[in] private_data The private data passed to the callback handler. * * @return The newly-created signal handler event, or NULL on error. * * @note To cancel a signal handler, call talloc_free() on the event returned * from this function. * * @see tevent_num_signals, tevent_sa_info_queue_count */ struct tevent_signal *tevent_add_signal(struct tevent_context *ev, TALLOC_CTX *mem_ctx, int signum, int sa_flags, tevent_signal_handler_t handler, void *private_data); #else struct tevent_signal *_tevent_add_signal(struct tevent_context *ev, TALLOC_CTX *mem_ctx, int signum, int sa_flags, tevent_signal_handler_t handler, void *private_data, const char *handler_name, const char *location); #define tevent_add_signal(ev, mem_ctx, signum, sa_flags, handler, private_data) \ _tevent_add_signal(ev, mem_ctx, signum, sa_flags, handler, private_data, \ #handler, __location__) #endif /** * @brief the number of supported signals * * This returns value of the configure time TEVENT_NUM_SIGNALS constant. * * The 'signum' argument of tevent_add_signal() must be less than * TEVENT_NUM_SIGNALS. * * @see tevent_add_signal */ size_t tevent_num_signals(void); /** * @brief the number of pending realtime signals * * This returns value of TEVENT_SA_INFO_QUEUE_COUNT. * * The tevent internals remember the last TEVENT_SA_INFO_QUEUE_COUNT * siginfo_t structures for SA_SIGINFO signals. If the system generates * more some signals get lost. * * @see tevent_add_signal */ size_t tevent_sa_info_queue_count(void); #ifdef DOXYGEN /** * @brief Pass a single time through the mainloop * * This will process any appropriate signal, immediate, fd and timer events * * @param[in] ev The event context to process * * @return Zero on success, nonzero if an internal error occurred */ int tevent_loop_once(struct tevent_context *ev); #else int _tevent_loop_once(struct tevent_context *ev, const char *location); #define tevent_loop_once(ev) \ _tevent_loop_once(ev, __location__) #endif #ifdef DOXYGEN /** * @brief Run the mainloop * * The mainloop will run until there are no events remaining to be processed * * @param[in] ev The event context to process * * @return Zero if all events have been processed. Nonzero if an internal * error occurred. */ int tevent_loop_wait(struct tevent_context *ev); #else int _tevent_loop_wait(struct tevent_context *ev, const char *location); #define tevent_loop_wait(ev) \ _tevent_loop_wait(ev, __location__) #endif /** * Assign a function to run when a tevent_fd is freed * * This function is a destructor for the tevent_fd. It does not automatically * close the file descriptor. If this is the desired behavior, then it must be * performed by the close_fn. * * @param[in] fde File descriptor event on which to set the destructor * @param[in] close_fn Destructor to execute when fde is freed */ void tevent_fd_set_close_fn(struct tevent_fd *fde, tevent_fd_close_fn_t close_fn); /** * Automatically close the file descriptor when the tevent_fd is freed * * This function calls close(fd) internally. * * @param[in] fde File descriptor event to auto-close */ void tevent_fd_set_auto_close(struct tevent_fd *fde); /** * Return the flags set on this file descriptor event * * @param[in] fde File descriptor event to query * * @return The flags set on the event. See #TEVENT_FD_READ and * #TEVENT_FD_WRITE */ uint16_t tevent_fd_get_flags(struct tevent_fd *fde); /** * Set flags on a file descriptor event * * @param[in] fde File descriptor event to set * @param[in] flags Flags to set on the event. See #TEVENT_FD_READ and * #TEVENT_FD_WRITE */ void tevent_fd_set_flags(struct tevent_fd *fde, uint16_t flags); /** * Query whether tevent supports signal handling * * @param[in] ev An initialized tevent context * * @return True if this platform and tevent context support signal handling */ bool tevent_signal_support(struct tevent_context *ev); void tevent_set_abort_fn(void (*abort_fn)(const char *reason)); /* bits for file descriptor event flags */ /** * Monitor a file descriptor for data to be read */ #define TEVENT_FD_READ 1 /** * Monitor a file descriptor for writeability */ #define TEVENT_FD_WRITE 2 /** * Convenience function for declaring a tevent_fd writable */ #define TEVENT_FD_WRITEABLE(fde) \ tevent_fd_set_flags(fde, tevent_fd_get_flags(fde) | TEVENT_FD_WRITE) /** * Convenience function for declaring a tevent_fd readable */ #define TEVENT_FD_READABLE(fde) \ tevent_fd_set_flags(fde, tevent_fd_get_flags(fde) | TEVENT_FD_READ) /** * Convenience function for declaring a tevent_fd non-writable */ #define TEVENT_FD_NOT_WRITEABLE(fde) \ tevent_fd_set_flags(fde, tevent_fd_get_flags(fde) & ~TEVENT_FD_WRITE) /** * Convenience function for declaring a tevent_fd non-readable */ #define TEVENT_FD_NOT_READABLE(fde) \ tevent_fd_set_flags(fde, tevent_fd_get_flags(fde) & ~TEVENT_FD_READ) /** * Debug level of tevent */ enum tevent_debug_level { TEVENT_DEBUG_FATAL, TEVENT_DEBUG_ERROR, TEVENT_DEBUG_WARNING, TEVENT_DEBUG_TRACE }; /** * @brief The tevent debug callbac. * * @param[in] context The memory context to use. * * @param[in] level The debug level. * * @param[in] fmt The format string. * * @param[in] ap The arguments for the format string. */ typedef void (*tevent_debug_fn)(void *context, enum tevent_debug_level level, const char *fmt, va_list ap) PRINTF_ATTRIBUTE(3,0); /** * Set destination for tevent debug messages * * @param[in] ev Event context to debug * @param[in] debug Function to handle output printing * @param[in] context The context to pass to the debug function. * * @return Always returns 0 as of version 0.9.8 * * @note Default is to emit no debug messages */ int tevent_set_debug(struct tevent_context *ev, tevent_debug_fn debug, void *context); /** * Designate stderr for debug message output * * @param[in] ev Event context to debug * * @note This function will only output TEVENT_DEBUG_FATAL, TEVENT_DEBUG_ERROR * and TEVENT_DEBUG_WARNING messages. For TEVENT_DEBUG_TRACE, please define a * function for tevent_set_debug() */ int tevent_set_debug_stderr(struct tevent_context *ev); enum tevent_trace_point { /** * Corresponds to a trace point just before waiting */ TEVENT_TRACE_BEFORE_WAIT, /** * Corresponds to a trace point just after waiting */ TEVENT_TRACE_AFTER_WAIT, #define TEVENT_HAS_LOOP_ONCE_TRACE_POINTS 1 /** * Corresponds to a trace point just before calling * the loop_once() backend function. */ TEVENT_TRACE_BEFORE_LOOP_ONCE, /** * Corresponds to a trace point right after the * loop_once() backend function has returned. */ TEVENT_TRACE_AFTER_LOOP_ONCE, }; typedef void (*tevent_trace_callback_t)(enum tevent_trace_point, void *private_data); /** * Register a callback to be called at certain trace points * * @param[in] ev Event context * @param[in] cb Trace callback * @param[in] private_data Data to be passed to callback * * @note The callback will be called at trace points defined by * tevent_trace_point. Call with NULL to reset. */ void tevent_set_trace_callback(struct tevent_context *ev, tevent_trace_callback_t cb, void *private_data); /** * Retrieve the current trace callback * * @param[in] ev Event context * @param[out] cb Registered trace callback * @param[out] private_data Registered data to be passed to callback * * @note This can be used to allow one component that wants to * register a callback to respect the callback that another component * has already registered. */ void tevent_get_trace_callback(struct tevent_context *ev, tevent_trace_callback_t *cb, void *private_data); /** * @} */ /** * @defgroup tevent_request The tevent request functions. * @ingroup tevent * * A tevent_req represents an asynchronous computation. * * The tevent_req group of API calls is the recommended way of * programming async computations within tevent. In particular the * file descriptor (tevent_add_fd) and timer (tevent_add_timed) events * are considered too low-level to be used in larger computations. To * read and write from and to sockets, Samba provides two calls on top * of tevent_add_fd: tstream_read_packet_send/recv and tstream_writev_send/recv. * These requests are much easier to compose than the low-level event * handlers called from tevent_add_fd. * * A lot of the simplicity tevent_req has brought to the notoriously * hairy async programming came via a set of conventions that every * async computation programmed should follow. One central piece of * these conventions is the naming of routines and variables. * * Every async computation needs a name (sensibly called "computation" * down from here). From this name quite a few naming conventions are * derived. * * Every computation that requires local state needs a * @code * struct computation_state { * int local_var; * }; * @endcode * Even if no local variables are required, such a state struct should * be created containing a dummy variable. Quite a few helper * functions and macros (for example tevent_req_create()) assume such * a state struct. * * An async computation is started by a computation_send * function. When it is finished, its result can be received by a * computation_recv function. For an example how to set up an async * computation, see the code example in the documentation for * tevent_req_create() and tevent_req_post(). The prototypes for _send * and _recv functions should follow some conventions: * * @code * struct tevent_req *computation_send(TALLOC_CTX *mem_ctx, * struct tevent_req *ev, * ... further args); * int computation_recv(struct tevent_req *req, ... further output args); * @endcode * * The "int" result of computation_recv() depends on the result the * sync version of the function would have, "int" is just an example * here. * * Another important piece of the conventions is that the program flow * is interrupted as little as possible. Because a blocking * sub-computation requires that the flow needs to continue in a * separate function that is the logical sequel of some computation, * it should lexically follow sending off the blocking * sub-computation. Setting the callback function via * tevent_req_set_callback() requires referencing a function lexically * below the call to tevent_req_set_callback(), forward declarations * are required. A lot of the async computations thus begin with a * sequence of declarations such as * * @code * static void computation_step1_done(struct tevent_req *subreq); * static void computation_step2_done(struct tevent_req *subreq); * static void computation_step3_done(struct tevent_req *subreq); * @endcode * * It really helps readability a lot to do these forward declarations, * because the lexically sequential program flow makes the async * computations almost as clear to read as a normal, sync program * flow. * * It is up to the user of the async computation to talloc_free it * after it has finished. If an async computation should be aborted, * the tevent_req structure can be talloc_free'ed. After it has * finished, it should talloc_free'ed by the API user. * * @{ */ /** * An async request moves from TEVENT_REQ_INIT to * TEVENT_REQ_IN_PROGRESS. All other states are valid after a request * has finished. */ enum tevent_req_state { /** * We are creating the request */ TEVENT_REQ_INIT, /** * We are waiting the request to complete */ TEVENT_REQ_IN_PROGRESS, /** * The request is finished successfully */ TEVENT_REQ_DONE, /** * A user error has occurred. The user error has been * indicated by tevent_req_error(), it can be retrieved via * tevent_req_is_error(). */ TEVENT_REQ_USER_ERROR, /** * Request timed out after the timeout set by tevent_req_set_endtime. */ TEVENT_REQ_TIMED_OUT, /** * An internal allocation has failed, or tevent_req_nomem has * been given a NULL pointer as the first argument. */ TEVENT_REQ_NO_MEMORY, /** * The request has been received by the caller. No further * action is valid. */ TEVENT_REQ_RECEIVED }; /** * @brief An async request */ struct tevent_req; /** * @brief A tevent request callback function. * * @param[in] req The tevent async request which executed this callback. */ typedef void (*tevent_req_fn)(struct tevent_req *req); /** * @brief Set an async request callback. * * See the documentation of tevent_req_post() for an example how this * is supposed to be used. * * @param[in] req The async request to set the callback. * * @param[in] fn The callback function to set. * * @param[in] pvt A pointer to private data to pass to the async request * callback. */ void tevent_req_set_callback(struct tevent_req *req, tevent_req_fn fn, void *pvt); #ifdef DOXYGEN /** * @brief Get the private data cast to the given type for a callback from * a tevent request structure. * * @code * static void computation_done(struct tevent_req *subreq) { * struct tevent_req *req = tevent_req_callback_data(subreq, struct tevent_req); * struct computation_state *state = tevent_req_data(req, struct computation_state); * .... more things, eventually maybe call tevent_req_done(req); * } * @endcode * * @param[in] req The structure to get the callback data from. * * @param[in] type The type of the private callback data to get. * * @return The type casted private data set NULL if not set. */ void *tevent_req_callback_data(struct tevent_req *req, #type); #else void *_tevent_req_callback_data(struct tevent_req *req); #define tevent_req_callback_data(_req, _type) \ talloc_get_type_abort(_tevent_req_callback_data(_req), _type) #endif #ifdef DOXYGEN /** * @brief Get the private data for a callback from a tevent request structure. * * @param[in] req The structure to get the callback data from. * * @param[in] req The structure to get the data from. * * @return The private data or NULL if not set. */ void *tevent_req_callback_data_void(struct tevent_req *req); #else #define tevent_req_callback_data_void(_req) \ _tevent_req_callback_data(_req) #endif #ifdef DOXYGEN /** * @brief Get the private data from a tevent request structure. * * When the tevent_req has been created by tevent_req_create, the * result of tevent_req_data() is the state variable created by * tevent_req_create() as a child of the req. * * @param[in] req The structure to get the private data from. * * @param[in] type The type of the private data * * @return The private data or NULL if not set. */ void *tevent_req_data(struct tevent_req *req, #type); #else void *_tevent_req_data(struct tevent_req *req); #define tevent_req_data(_req, _type) \ talloc_get_type_abort(_tevent_req_data(_req), _type) #endif /** * @brief The print function which can be set for a tevent async request. * * @param[in] req The tevent async request. * * @param[in] ctx A talloc memory context which can be uses to allocate * memory. * * @return An allocated string buffer to print. * * Example: * @code * static char *my_print(struct tevent_req *req, TALLOC_CTX *mem_ctx) * { * struct my_data *data = tevent_req_data(req, struct my_data); * char *result; * * result = tevent_req_default_print(mem_ctx, req); * if (result == NULL) { * return NULL; * } * * return talloc_asprintf_append_buffer(result, "foo=%d, bar=%d", * data->foo, data->bar); * } * @endcode */ typedef char *(*tevent_req_print_fn)(struct tevent_req *req, TALLOC_CTX *ctx); /** * @brief This function sets a print function for the given request. * * This function can be used to setup a print function for the given request. * This will be triggered if the tevent_req_print() function was * called on the given request. * * @param[in] req The request to use. * * @param[in] fn A pointer to the print function * * @note This function should only be used for debugging. */ void tevent_req_set_print_fn(struct tevent_req *req, tevent_req_print_fn fn); /** * @brief The default print function for creating debug messages. * * The function should not be used by users of the async API, * but custom print function can use it and append custom text * to the string. * * @param[in] req The request to be printed. * * @param[in] mem_ctx The memory context for the result. * * @return Text representation of request. * */ char *tevent_req_default_print(struct tevent_req *req, TALLOC_CTX *mem_ctx); /** * @brief Print an tevent_req structure in debug messages. * * This function should be used by callers of the async API. * * @param[in] mem_ctx The memory context for the result. * * @param[in] req The request to be printed. * * @return Text representation of request. */ char *tevent_req_print(TALLOC_CTX *mem_ctx, struct tevent_req *req); /** * @brief A typedef for a cancel function for a tevent request. * * @param[in] req The tevent request calling this function. * * @return True if the request could be canceled, false if not. */ typedef bool (*tevent_req_cancel_fn)(struct tevent_req *req); /** * @brief This function sets a cancel function for the given tevent request. * * This function can be used to setup a cancel function for the given request. * This will be triggered if the tevent_req_cancel() function was * called on the given request. * * @param[in] req The request to use. * * @param[in] fn A pointer to the cancel function. */ void tevent_req_set_cancel_fn(struct tevent_req *req, tevent_req_cancel_fn fn); #ifdef DOXYGEN /** * @brief Try to cancel the given tevent request. * * This function can be used to cancel the given request. * * It is only possible to cancel a request when the implementation * has registered a cancel function via the tevent_req_set_cancel_fn(). * * @param[in] req The request to use. * * @return This function returns true if the request is * cancelable, otherwise false is returned. * * @note Even if the function returns true, the caller need to wait * for the function to complete normally. * Only the _recv() function of the given request indicates * if the request was really canceled. */ bool tevent_req_cancel(struct tevent_req *req); #else bool _tevent_req_cancel(struct tevent_req *req, const char *location); #define tevent_req_cancel(req) \ _tevent_req_cancel(req, __location__) #endif /** * @brief A typedef for a cleanup function for a tevent request. * * @param[in] req The tevent request calling this function. * * @param[in] req_state The current tevent_req_state. * */ typedef void (*tevent_req_cleanup_fn)(struct tevent_req *req, enum tevent_req_state req_state); /** * @brief This function sets a cleanup function for the given tevent request. * * This function can be used to setup a cleanup function for the given request. * This will be triggered when the tevent_req_done() or tevent_req_error() * function was called, before notifying the callers callback function, * and also before scheduling the deferred trigger. * * This might be useful if more than one tevent_req belong together * and need to finish both requests at the same time. * * The cleanup function is able to call tevent_req_done() or tevent_req_error() * recursively, the cleanup function is only triggered the first time. * * The cleanup function is also called by tevent_req_received() * (possibly triggered from tevent_req_destructor()) before destroying * the private data of the tevent_req. * * @param[in] req The request to use. * * @param[in] fn A pointer to the cancel function. */ void tevent_req_set_cleanup_fn(struct tevent_req *req, tevent_req_cleanup_fn fn); #ifdef DOXYGEN /** * @brief Create an async tevent request. * * The new async request will be initialized in state TEVENT_REQ_IN_PROGRESS. * * @code * struct tevent_req *req; * struct computation_state *state; * req = tevent_req_create(mem_ctx, &state, struct computation_state); * @endcode * * Tevent_req_create() allocates and zeros the state variable as a talloc * child of its result. The state variable should be used as the talloc * parent for all temporary variables that are allocated during the async * computation. This way, when the user of the async computation frees * the request, the state as a talloc child will be free'd along with * all the temporary variables hanging off the state. * * @param[in] mem_ctx The memory context for the result. * @param[in] pstate Pointer to the private request state. * @param[in] type The name of the request. * * @return A new async request. NULL on error. */ struct tevent_req *tevent_req_create(TALLOC_CTX *mem_ctx, void **pstate, #type); #else struct tevent_req *_tevent_req_create(TALLOC_CTX *mem_ctx, void *pstate, size_t state_size, const char *type, const char *location); #define tevent_req_create(_mem_ctx, _pstate, _type) \ _tevent_req_create((_mem_ctx), (_pstate), sizeof(_type), \ #_type, __location__) #endif /** * @brief Set a timeout for an async request. On failure, "req" is already * set to state TEVENT_REQ_NO_MEMORY. * * @param[in] req The request to set the timeout for. * * @param[in] ev The event context to use for the timer. * * @param[in] endtime The endtime of the request. * * @return True if succeeded, false if not. */ bool tevent_req_set_endtime(struct tevent_req *req, struct tevent_context *ev, struct timeval endtime); /** * @brief Reset the timer set by tevent_req_set_endtime. * * @param[in] req The request to reset the timeout for */ void tevent_req_reset_endtime(struct tevent_req *req); #ifdef DOXYGEN /** * @brief Call the notify callback of the given tevent request manually. * * @param[in] req The tevent request to call the notify function from. * * @see tevent_req_set_callback() */ void tevent_req_notify_callback(struct tevent_req *req); #else void _tevent_req_notify_callback(struct tevent_req *req, const char *location); #define tevent_req_notify_callback(req) \ _tevent_req_notify_callback(req, __location__) #endif #ifdef DOXYGEN /** * @brief An async request has successfully finished. * * This function is to be used by implementors of async requests. When a * request is successfully finished, this function calls the user's completion * function. * * @param[in] req The finished request. */ void tevent_req_done(struct tevent_req *req); #else void _tevent_req_done(struct tevent_req *req, const char *location); #define tevent_req_done(req) \ _tevent_req_done(req, __location__) #endif #ifdef DOXYGEN /** * @brief An async request has seen an error. * * This function is to be used by implementors of async requests. When a * request can not successfully completed, the implementation should call this * function with the appropriate status code. * * If error is 0 the function returns false and does nothing more. * * @param[in] req The request with an error. * * @param[in] error The error code. * * @return On success true is returned, false if error is 0. * * @code * int error = first_function(); * if (tevent_req_error(req, error)) { * return; * } * * error = second_function(); * if (tevent_req_error(req, error)) { * return; * } * * tevent_req_done(req); * return; * @endcode */ bool tevent_req_error(struct tevent_req *req, uint64_t error); #else bool _tevent_req_error(struct tevent_req *req, uint64_t error, const char *location); #define tevent_req_error(req, error) \ _tevent_req_error(req, error, __location__) #endif #ifdef DOXYGEN /** * @brief Helper function for nomem check. * * Convenience helper to easily check alloc failure within a callback * implementing the next step of an async request. * * @param[in] p The pointer to be checked. * * @param[in] req The request being processed. * * @code * p = talloc(mem_ctx, bla); * if (tevent_req_nomem(p, req)) { * return; * } * @endcode */ bool tevent_req_nomem(const void *p, struct tevent_req *req); #else bool _tevent_req_nomem(const void *p, struct tevent_req *req, const char *location); #define tevent_req_nomem(p, req) \ _tevent_req_nomem(p, req, __location__) #endif #ifdef DOXYGEN /** * @brief Indicate out of memory to a request * * @param[in] req The request being processed. */ void tevent_req_oom(struct tevent_req *req); #else void _tevent_req_oom(struct tevent_req *req, const char *location); #define tevent_req_oom(req) \ _tevent_req_oom(req, __location__) #endif /** * @brief Finish a request before the caller had the change to set the callback. * * An implementation of an async request might find that it can either finish * the request without waiting for an external event, or it can not even start * the engine. To present the illusion of a callback to the user of the API, * the implementation can call this helper function which triggers an * immediate event. This way the caller can use the same calling * conventions, independent of whether the request was actually deferred. * * @code * struct tevent_req *computation_send(TALLOC_CTX *mem_ctx, * struct tevent_context *ev) * { * struct tevent_req *req, *subreq; * struct computation_state *state; * req = tevent_req_create(mem_ctx, &state, struct computation_state); * if (req == NULL) { * return NULL; * } * subreq = subcomputation_send(state, ev); * if (tevent_req_nomem(subreq, req)) { * return tevent_req_post(req, ev); * } * tevent_req_set_callback(subreq, computation_done, req); * return req; * } * @endcode * * @param[in] req The finished request. * * @param[in] ev The tevent_context for the immediate event. * * @return The given request will be returned. */ struct tevent_req *tevent_req_post(struct tevent_req *req, struct tevent_context *ev); /** * @brief Finish multiple requests within one function * * Normally tevent_req_notify_callback() and all wrappers * (e.g. tevent_req_done() and tevent_req_error()) * need to be the last thing an event handler should call. * This is because the callback is likely to destroy the * context of the current function. * * If a function wants to notify more than one caller, * it is dangerous if it just triggers multiple callbacks * in a row. With tevent_req_defer_callback() it is possible * to set an event context that will be used to defer the callback * via an immediate event (similar to tevent_req_post()). * * @code * struct complete_state { * struct tevent_context *ev; * * struct tevent_req **reqs; * }; * * void complete(struct complete_state *state) * { * size_t i, c = talloc_array_length(state->reqs); * * for (i=0; i < c; i++) { * tevent_req_defer_callback(state->reqs[i], state->ev); * tevent_req_done(state->reqs[i]); * } * } * @endcode * * @param[in] req The finished request. * * @param[in] ev The tevent_context for the immediate event. * * @return The given request will be returned. */ void tevent_req_defer_callback(struct tevent_req *req, struct tevent_context *ev); /** * @brief Check if the given request is still in progress. * * It is typically used by sync wrapper functions. * * @param[in] req The request to poll. * * @return The boolean form of "is in progress". */ bool tevent_req_is_in_progress(struct tevent_req *req); /** * @brief Actively poll for the given request to finish. * * This function is typically used by sync wrapper functions. * * @param[in] req The request to poll. * * @param[in] ev The tevent_context to be used. * * @return On success true is returned. If a critical error has * happened in the tevent loop layer false is returned. * This is not the return value of the given request! * * @note This should only be used if the given tevent context was created by the * caller, to avoid event loop nesting. * * @code * req = tstream_writev_queue_send(mem_ctx, * ev_ctx, * tstream, * send_queue, * iov, 2); * ok = tevent_req_poll(req, tctx->ev); * rc = tstream_writev_queue_recv(req, &sys_errno); * TALLOC_FREE(req); * @endcode */ bool tevent_req_poll(struct tevent_req *req, struct tevent_context *ev); /** * @brief Get the tevent request state and the actual error set by * tevent_req_error. * * @code * int computation_recv(struct tevent_req *req, uint64_t *perr) * { * enum tevent_req_state state; * uint64_t err; * if (tevent_req_is_error(req, &state, &err)) { * *perr = err; * return -1; * } * return 0; * } * @endcode * * @param[in] req The tevent request to get the error from. * * @param[out] state A pointer to store the tevent request error state. * * @param[out] error A pointer to store the error set by tevent_req_error(). * * @return True if the function could set error and state, false * otherwise. * * @see tevent_req_error() */ bool tevent_req_is_error(struct tevent_req *req, enum tevent_req_state *state, uint64_t *error); /** * @brief Use as the last action of a _recv() function. * * This function destroys the attached private data. * * @param[in] req The finished request. */ void tevent_req_received(struct tevent_req *req); /** * @brief Create a tevent subrequest at a given time. * * The idea is that always the same syntax for tevent requests. * * @param[in] mem_ctx The talloc memory context to use. * * @param[in] ev The event handle to setup the request. * * @param[in] wakeup_time The time to wakeup and execute the request. * * @return The new subrequest, NULL on error. * * Example: * @code * static void my_callback_wakeup_done(tevent_req *subreq) * { * struct tevent_req *req = tevent_req_callback_data(subreq, * struct tevent_req); * bool ok; * * ok = tevent_wakeup_recv(subreq); * TALLOC_FREE(subreq); * if (!ok) { * tevent_req_error(req, -1); * return; * } * ... * } * @endcode * * @code * subreq = tevent_wakeup_send(mem_ctx, ev, wakeup_time); * if (tevent_req_nomem(subreq, req)) { * return false; * } * tevent_set_callback(subreq, my_callback_wakeup_done, req); * @endcode * * @see tevent_wakeup_recv() */ struct tevent_req *tevent_wakeup_send(TALLOC_CTX *mem_ctx, struct tevent_context *ev, struct timeval wakeup_time); /** * @brief Check if the wakeup has been correctly executed. * * This function needs to be called in the callback function set after calling * tevent_wakeup_send(). * * @param[in] req The tevent request to check. * * @return True on success, false otherwise. * * @see tevent_wakeup_recv() */ bool tevent_wakeup_recv(struct tevent_req *req); /* @} */ /** * @defgroup tevent_helpers The tevent helper functions * @ingroup tevent * * @todo description * * @{ */ /** * @brief Compare two timeval values. * * @param[in] tv1 The first timeval value to compare. * * @param[in] tv2 The second timeval value to compare. * * @return 0 if they are equal. * 1 if the first time is greater than the second. * -1 if the first time is smaller than the second. */ int tevent_timeval_compare(const struct timeval *tv1, const struct timeval *tv2); /** * @brief Get a zero timeval value. * * @return A zero timeval value. */ struct timeval tevent_timeval_zero(void); /** * @brief Get a timeval value for the current time. * * @return A timeval value with the current time. */ struct timeval tevent_timeval_current(void); /** * @brief Get a timeval structure with the given values. * * @param[in] secs The seconds to set. * * @param[in] usecs The microseconds to set. * * @return A timeval structure with the given values. */ struct timeval tevent_timeval_set(uint32_t secs, uint32_t usecs); /** * @brief Get the difference between two timeval values. * * @param[in] tv1 The first timeval. * * @param[in] tv2 The second timeval. * * @return A timeval structure with the difference between the * first and the second value. */ struct timeval tevent_timeval_until(const struct timeval *tv1, const struct timeval *tv2); /** * @brief Check if a given timeval structure is zero. * * @param[in] tv The timeval to check if it is zero. * * @return True if it is zero, false otherwise. */ bool tevent_timeval_is_zero(const struct timeval *tv); /** * @brief Add the given amount of time to a timeval structure. * * @param[in] tv The timeval structure to add the time. * * @param[in] secs The seconds to add to the timeval. * * @param[in] usecs The microseconds to add to the timeval. * * @return The timeval structure with the new time. */ struct timeval tevent_timeval_add(const struct timeval *tv, uint32_t secs, uint32_t usecs); /** * @brief Get a timeval in the future with a specified offset from now. * * @param[in] secs The seconds of the offset from now. * * @param[in] usecs The microseconds of the offset from now. * * @return A timval with the given offset in the future. */ struct timeval tevent_timeval_current_ofs(uint32_t secs, uint32_t usecs); /* @} */ /** * @defgroup tevent_queue The tevent queue functions * @ingroup tevent * * A tevent_queue is used to queue up async requests that must be * serialized. For example writing buffers into a socket must be * serialized. Writing a large lump of data into a socket can require * multiple write(2) or send(2) system calls. If more than one async * request is outstanding to write large buffers into a socket, every * request must individually be completed before the next one begins, * even if multiple syscalls are required. * * Take a look at @ref tevent_queue_tutorial for more details. * @{ */ struct tevent_queue; struct tevent_queue_entry; #ifdef DOXYGEN /** * @brief Create and start a tevent queue. * * @param[in] mem_ctx The talloc memory context to allocate the queue. * * @param[in] name The name to use to identify the queue. * * @return An allocated tevent queue on success, NULL on error. * * @see tevent_queue_start() * @see tevent_queue_stop() */ struct tevent_queue *tevent_queue_create(TALLOC_CTX *mem_ctx, const char *name); #else struct tevent_queue *_tevent_queue_create(TALLOC_CTX *mem_ctx, const char *name, const char *location); #define tevent_queue_create(_mem_ctx, _name) \ _tevent_queue_create((_mem_ctx), (_name), __location__) #endif /** * @brief A callback trigger function run by the queue. * * @param[in] req The tevent request the trigger function is executed on. * * @param[in] private_data The private data pointer specified by * tevent_queue_add(). * * @see tevent_queue_add() * @see tevent_queue_add_entry() * @see tevent_queue_add_optimize_empty() */ typedef void (*tevent_queue_trigger_fn_t)(struct tevent_req *req, void *private_data); /** * @brief Add a tevent request to the queue. * * @param[in] queue The queue to add the request. * * @param[in] ev The event handle to use for the request. * * @param[in] req The tevent request to add to the queue. * * @param[in] trigger The function triggered by the queue when the request * is called. Since tevent 0.9.14 it's possible to * pass NULL, in order to just add a "blocker" to the * queue. * * @param[in] private_data The private data passed to the trigger function. * * @return True if the request has been successfully added, false * otherwise. */ bool tevent_queue_add(struct tevent_queue *queue, struct tevent_context *ev, struct tevent_req *req, tevent_queue_trigger_fn_t trigger, void *private_data); /** * @brief Add a tevent request to the queue. * * The request can be removed from the queue by calling talloc_free() * (or a similar function) on the returned queue entry. This * is the only difference to tevent_queue_add(). * * @param[in] queue The queue to add the request. * * @param[in] ev The event handle to use for the request. * * @param[in] req The tevent request to add to the queue. * * @param[in] trigger The function triggered by the queue when the request * is called. Since tevent 0.9.14 it's possible to * pass NULL, in order to just add a "blocker" to the * queue. * * @param[in] private_data The private data passed to the trigger function. * * @return a pointer to the tevent_queue_entry if the request * has been successfully added, NULL otherwise. * * @see tevent_queue_add() * @see tevent_queue_add_optimize_empty() */ struct tevent_queue_entry *tevent_queue_add_entry( struct tevent_queue *queue, struct tevent_context *ev, struct tevent_req *req, tevent_queue_trigger_fn_t trigger, void *private_data); /** * @brief Add a tevent request to the queue using a possible optimization. * * This tries to optimize for the empty queue case and may calls * the trigger function directly. This is the only difference compared * to tevent_queue_add_entry(). * * The caller needs to be prepared that the trigger function has * already called tevent_req_notify_callback(), tevent_req_error(), * tevent_req_done() or a similar function. * * The trigger function has no chance to see the returned * queue_entry in the optimized case. * * The request can be removed from the queue by calling talloc_free() * (or a similar function) on the returned queue entry. * * @param[in] queue The queue to add the request. * * @param[in] ev The event handle to use for the request. * * @param[in] req The tevent request to add to the queue. * * @param[in] trigger The function triggered by the queue when the request * is called. Since tevent 0.9.14 it's possible to * pass NULL, in order to just add a "blocker" to the * queue. * * @param[in] private_data The private data passed to the trigger function. * * @return a pointer to the tevent_queue_entry if the request * has been successfully added, NULL otherwise. * * @see tevent_queue_add() * @see tevent_queue_add_entry() */ struct tevent_queue_entry *tevent_queue_add_optimize_empty( struct tevent_queue *queue, struct tevent_context *ev, struct tevent_req *req, tevent_queue_trigger_fn_t trigger, void *private_data); /** * @brief Untrigger an already triggered queue entry. * * If a trigger function detects that it needs to remain * in the queue, it needs to call tevent_queue_stop() * followed by tevent_queue_entry_untrigger(). * * @note In order to call tevent_queue_entry_untrigger() * the queue must be already stopped and the given queue_entry * must be the first one in the queue! Otherwise it calls abort(). * * @note You can't use this together with tevent_queue_add_optimize_empty() * because the trigger function don't have access to the quene entry * in the case of an empty queue. * * @param[in] queue_entry The queue entry to rearm. * * @see tevent_queue_add_entry() * @see tevent_queue_stop() */ void tevent_queue_entry_untrigger(struct tevent_queue_entry *entry); /** * @brief Start a tevent queue. * * The queue is started by default. * * @param[in] queue The queue to start. */ void tevent_queue_start(struct tevent_queue *queue); /** * @brief Stop a tevent queue. * * The queue is started by default. * * @param[in] queue The queue to stop. */ void tevent_queue_stop(struct tevent_queue *queue); /** * @brief Get the length of the queue. * * @param[in] queue The queue to get the length from. * * @return The number of elements. */ size_t tevent_queue_length(struct tevent_queue *queue); /** * @brief Is the tevent queue running. * * The queue is started by default. * * @param[in] queue The queue. * * @return Wether the queue is running or not.. */ bool tevent_queue_running(struct tevent_queue *queue); /** * @brief Create a tevent subrequest that waits in a tevent_queue * * The idea is that always the same syntax for tevent requests. * * @param[in] mem_ctx The talloc memory context to use. * * @param[in] ev The event handle to setup the request. * * @param[in] queue The queue to wait in. * * @return The new subrequest, NULL on error. * * @see tevent_queue_wait_recv() */ struct tevent_req *tevent_queue_wait_send(TALLOC_CTX *mem_ctx, struct tevent_context *ev, struct tevent_queue *queue); /** * @brief Check if we no longer need to wait in the queue. * * This function needs to be called in the callback function set after calling * tevent_queue_wait_send(). * * @param[in] req The tevent request to check. * * @return True on success, false otherwise. * * @see tevent_queue_wait_send() */ bool tevent_queue_wait_recv(struct tevent_req *req); typedef int (*tevent_nesting_hook)(struct tevent_context *ev, void *private_data, uint32_t level, bool begin, void *stack_ptr, const char *location); /** * @brief Create a tevent_thread_proxy for message passing between threads. * * The tevent_context must have been allocated on the NULL * talloc context, and talloc_disable_null_tracking() must * have been called. * * @param[in] dest_ev_ctx The tevent_context to receive events. * * @return An allocated tevent_thread_proxy, NULL on error. * If tevent was compiled without PTHREAD support * NULL is always returned and errno set to ENOSYS. * * @see tevent_thread_proxy_schedule() */ struct tevent_thread_proxy *tevent_thread_proxy_create( struct tevent_context *dest_ev_ctx); /** * @brief Schedule an immediate event on an event context from another thread. * * Causes dest_ev_ctx, being run by another thread, to receive an * immediate event calling the handler with the *pp_private parameter. * * *pp_im must be a pointer to an immediate event talloced on a context owned * by the calling thread, or the NULL context. Ownership will * be transferred to the tevent_thread_proxy and *pp_im will be returned as NULL. * * *pp_private_data must be a talloced area of memory with no destructors. * Ownership of this memory will be transferred to the tevent library and * *pp_private_data will be set to NULL on successful completion of * the call. Set pp_private to NULL if no parameter transfer * needed (a pure callback). This is an asynchronous request, caller * does not wait for callback to be completed before returning. * * @param[in] tp The tevent_thread_proxy to use. * * @param[in] pp_im Pointer to immediate event pointer. * * @param[in] handler The function that will be called. * * @param[in] pp_private_data The talloced memory to transfer. * * @see tevent_thread_proxy_create() */ void tevent_thread_proxy_schedule(struct tevent_thread_proxy *tp, struct tevent_immediate **pp_im, tevent_immediate_handler_t handler, void *pp_private_data); /* * @brief Create a context for threaded activation of immediates * * A tevent_treaded_context provides a link into an event * context. Using tevent_threaded_schedule_immediate, it is possible * to activate an immediate event from within a thread. * * It is the duty of the caller of tevent_threaded_context_create() to * keep the event context around longer than any * tevent_threaded_context. tevent will abort if ev is talloc_free'ed * with an active tevent_threaded_context. * * If tevent is build without pthread support, this always returns * NULL with errno=ENOSYS. * * @param[in] mem_ctx The talloc memory context to use. * @param[in] ev The event context to link this to. * @return The threaded context, or NULL with errno set. * * @see tevent_threaded_schedule_immediate() * * @note Available as of tevent 0.9.30 */ struct tevent_threaded_context *tevent_threaded_context_create( TALLOC_CTX *mem_ctx, struct tevent_context *ev); #ifdef DOXYGEN /* * @brief Activate an immediate from a thread * * Activate an immediate from within a thread. * * This routine does not watch out for talloc hierarchies. This means * that it is highly recommended to create the tevent_immediate in the * thread owning tctx, allocate a threaded job description for the * thread, hand over both pointers to a helper thread and not touch it * in the main thread at all anymore. * * tevent_threaded_schedule_immediate is intended as a job completion * indicator for simple threaded helpers. * * Please be aware that tevent_threaded_schedule_immediate is very * picky about its arguments: An immediate may not already be * activated and the handler must exist. With * tevent_threaded_schedule_immediate memory ownership is transferred * to the main thread holding the tevent context behind tctx, the * helper thread can't access it anymore. * * @param[in] tctx The threaded context to go through * @param[in] im The immediate event to activate * @param[in] handler The immediate handler to call in the main thread * @param[in] private_data Pointer for the immediate handler * * @see tevent_threaded_context_create() * * @note Available as of tevent 0.9.30 */ void tevent_threaded_schedule_immediate(struct tevent_threaded_context *tctx, struct tevent_immediate *im, tevent_immediate_handler_t handler, void *private_data); #else void _tevent_threaded_schedule_immediate(struct tevent_threaded_context *tctx, struct tevent_immediate *im, tevent_immediate_handler_t handler, void *private_data, const char *handler_name, const char *location); #define tevent_threaded_schedule_immediate(tctx, im, handler, private_data) \ _tevent_threaded_schedule_immediate(tctx, im, handler, private_data, \ #handler, __location__); #endif #ifdef TEVENT_DEPRECATED #ifndef _DEPRECATED_ #ifdef HAVE___ATTRIBUTE__ #define _DEPRECATED_ __attribute__ ((deprecated)) #else #define _DEPRECATED_ #endif #endif void tevent_loop_allow_nesting(struct tevent_context *ev) _DEPRECATED_; void tevent_loop_set_nesting_hook(struct tevent_context *ev, tevent_nesting_hook hook, void *private_data) _DEPRECATED_; int _tevent_loop_until(struct tevent_context *ev, bool (*finished)(void *private_data), void *private_data, const char *location) _DEPRECATED_; #define tevent_loop_until(ev, finished, private_data) \ _tevent_loop_until(ev, finished, private_data, __location__) #endif int tevent_re_initialise(struct tevent_context *ev); /* @} */ /** * @defgroup tevent_ops The tevent operation functions * @ingroup tevent * * The following structure and registration functions are exclusively * needed for people writing and pluggin a different event engine. * There is nothing useful for normal tevent user in here. * @{ */ struct tevent_ops { /* context init */ int (*context_init)(struct tevent_context *ev); /* fd_event functions */ struct tevent_fd *(*add_fd)(struct tevent_context *ev, TALLOC_CTX *mem_ctx, int fd, uint16_t flags, tevent_fd_handler_t handler, void *private_data, const char *handler_name, const char *location); void (*set_fd_close_fn)(struct tevent_fd *fde, tevent_fd_close_fn_t close_fn); uint16_t (*get_fd_flags)(struct tevent_fd *fde); void (*set_fd_flags)(struct tevent_fd *fde, uint16_t flags); /* timed_event functions */ struct tevent_timer *(*add_timer)(struct tevent_context *ev, TALLOC_CTX *mem_ctx, struct timeval next_event, tevent_timer_handler_t handler, void *private_data, const char *handler_name, const char *location); /* immediate event functions */ void (*schedule_immediate)(struct tevent_immediate *im, struct tevent_context *ev, tevent_immediate_handler_t handler, void *private_data, const char *handler_name, const char *location); /* signal functions */ struct tevent_signal *(*add_signal)(struct tevent_context *ev, TALLOC_CTX *mem_ctx, int signum, int sa_flags, tevent_signal_handler_t handler, void *private_data, const char *handler_name, const char *location); /* loop functions */ int (*loop_once)(struct tevent_context *ev, const char *location); int (*loop_wait)(struct tevent_context *ev, const char *location); }; bool tevent_register_backend(const char *name, const struct tevent_ops *ops); /* @} */ /** * @defgroup tevent_compat The tevent compatibility functions * @ingroup tevent * * The following definitions are usueful only for compatibility with the * implementation originally developed within the samba4 code and will be * soon removed. Please NEVER use in new code. * * @todo Ignore it? * * @{ */ #ifdef TEVENT_COMPAT_DEFINES #define event_context tevent_context #define event_ops tevent_ops #define fd_event tevent_fd #define timed_event tevent_timer #define signal_event tevent_signal #define event_fd_handler_t tevent_fd_handler_t #define event_timed_handler_t tevent_timer_handler_t #define event_signal_handler_t tevent_signal_handler_t #define event_context_init(mem_ctx) \ tevent_context_init(mem_ctx) #define event_context_init_byname(mem_ctx, name) \ tevent_context_init_byname(mem_ctx, name) #define event_backend_list(mem_ctx) \ tevent_backend_list(mem_ctx) #define event_set_default_backend(backend) \ tevent_set_default_backend(backend) #define event_add_fd(ev, mem_ctx, fd, flags, handler, private_data) \ tevent_add_fd(ev, mem_ctx, fd, flags, handler, private_data) #define event_add_timed(ev, mem_ctx, next_event, handler, private_data) \ tevent_add_timer(ev, mem_ctx, next_event, handler, private_data) #define event_add_signal(ev, mem_ctx, signum, sa_flags, handler, private_data) \ tevent_add_signal(ev, mem_ctx, signum, sa_flags, handler, private_data) #define event_loop_once(ev) \ tevent_loop_once(ev) #define event_loop_wait(ev) \ tevent_loop_wait(ev) #define event_get_fd_flags(fde) \ tevent_fd_get_flags(fde) #define event_set_fd_flags(fde, flags) \ tevent_fd_set_flags(fde, flags) #define EVENT_FD_READ TEVENT_FD_READ #define EVENT_FD_WRITE TEVENT_FD_WRITE #define EVENT_FD_WRITEABLE(fde) \ TEVENT_FD_WRITEABLE(fde) #define EVENT_FD_READABLE(fde) \ TEVENT_FD_READABLE(fde) #define EVENT_FD_NOT_WRITEABLE(fde) \ TEVENT_FD_NOT_WRITEABLE(fde) #define EVENT_FD_NOT_READABLE(fde) \ TEVENT_FD_NOT_READABLE(fde) #define ev_debug_level tevent_debug_level #define EV_DEBUG_FATAL TEVENT_DEBUG_FATAL #define EV_DEBUG_ERROR TEVENT_DEBUG_ERROR #define EV_DEBUG_WARNING TEVENT_DEBUG_WARNING #define EV_DEBUG_TRACE TEVENT_DEBUG_TRACE #define ev_set_debug(ev, debug, context) \ tevent_set_debug(ev, debug, context) #define ev_set_debug_stderr(_ev) tevent_set_debug_stderr(ev) #endif /* TEVENT_COMPAT_DEFINES */ /* @} */ #endif /* __TEVENT_H__ */