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   1/*	$OpenBSD: event.h,v 1.31 2019/04/29 17:11:51 tobias Exp $	*/
   2
   3/*
   4 * Copyright (c) 2000-2007 Niels Provos <provos@citi.umich.edu>
   5 * All rights reserved.
   6 *
   7 * Redistribution and use in source and binary forms, with or without
   8 * modification, are permitted provided that the following conditions
   9 * are met:
  10 * 1. Redistributions of source code must retain the above copyright
  11 *    notice, this list of conditions and the following disclaimer.
  12 * 2. Redistributions in binary form must reproduce the above copyright
  13 *    notice, this list of conditions and the following disclaimer in the
  14 *    documentation and/or other materials provided with the distribution.
  15 * 3. The name of the author may not be used to endorse or promote products
  16 *    derived from this software without specific prior written permission.
  17 *
  18 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
  19 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
  20 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
  21 * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
  22 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
  23 * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
  24 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  25 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  26 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
  27 * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  28 */
  29#ifndef _EVENT_H_
  30#define _EVENT_H_
  31
  32/** @mainpage
  33
  34  @section intro Introduction
  35
  36  libevent is an event notification library for developing scalable network
  37  servers.  The libevent API provides a mechanism to execute a callback
  38  function when a specific event occurs on a file descriptor or after a
  39  timeout has been reached. Furthermore, libevent also support callbacks due
  40  to signals or regular timeouts.
  41
  42  libevent is meant to replace the event loop found in event driven network
  43  servers. An application just needs to call event_dispatch() and then add or
  44  remove events dynamically without having to change the event loop.
  45
  46  Currently, libevent supports /dev/poll, kqueue(2), select(2), poll(2) and
  47  epoll(4). It also has experimental support for real-time signals. The
  48  internal event mechanism is completely independent of the exposed event API,
  49  and a simple update of libevent can provide new functionality without having
  50  to redesign the applications. As a result, Libevent allows for portable
  51  application development and provides the most scalable event notification
  52  mechanism available on an operating system. Libevent can also be used for
  53  multi-threaded applications; see Steven Grimm's explanation. Libevent should
  54  compile on Linux, *BSD, Mac OS X, Solaris and Windows.
  55
  56  @section usage Standard usage
  57
  58  Every program that uses libevent must include the <event.h> header, and pass
  59  the -levent flag to the linker.  Before using any of the functions in the
  60  library, you must call event_init() or event_base_new() to perform one-time
  61  initialization of the libevent library.
  62
  63  @section event Event notification
  64
  65  For each file descriptor that you wish to monitor, you must declare an event
  66  structure and call event_set() to initialize the members of the structure.
  67  To enable notification, you add the structure to the list of monitored
  68  events by calling event_add().  The event structure must remain allocated as
  69  long as it is active, so it should be allocated on the heap. Finally, you
  70  call event_dispatch() to loop and dispatch events.
  71
  72  @section bufferevent I/O Buffers
  73
  74  libevent provides an abstraction on top of the regular event callbacks. This
  75  abstraction is called a buffered event. A buffered event provides input and
  76  output buffers that get filled and drained automatically. The user of a
  77  buffered event no longer deals directly with the I/O, but instead is reading
  78  from input and writing to output buffers.
  79
  80  Once initialized via bufferevent_new(), the bufferevent structure can be
  81  used repeatedly with bufferevent_enable() and bufferevent_disable().
  82  Instead of reading and writing directly to a socket, you would call
  83  bufferevent_read() and bufferevent_write().
  84
  85  When read enabled the bufferevent will try to read from the file descriptor
  86  and call the read callback. The write callback is executed whenever the
  87  output buffer is drained below the write low watermark, which is 0 by
  88  default.
  89
  90  @section timers Timers
  91
  92  libevent can also be used to create timers that invoke a callback after a
  93  certain amount of time has expired. The evtimer_set() function prepares an
  94  event struct to be used as a timer. To activate the timer, call
  95  evtimer_add(). Timers can be deactivated by calling evtimer_del().
  96
  97  @section timeouts Timeouts
  98
  99  In addition to simple timers, libevent can assign timeout events to file
 100  descriptors that are triggered whenever a certain amount of time has passed
 101  with no activity on a file descriptor.  The timeout_set() function
 102  initializes an event struct for use as a timeout. Once initialized, the
 103  event must be activated by using timeout_add().  To cancel the timeout, call
 104  timeout_del().
 105
 106  @section evdns Asynchronous DNS resolution
 107
 108  libevent provides an asynchronous DNS resolver that should be used instead
 109  of the standard DNS resolver functions.  These functions can be imported by
 110  including the <evdns.h> header in your program. Before using any of the
 111  resolver functions, you must call evdns_init() to initialize the library. To
 112  convert a hostname to an IP address, you call the evdns_resolve_ipv4()
 113  function.  To perform a reverse lookup, you would call the
 114  evdns_resolve_reverse() function.  All of these functions use callbacks to
 115  avoid blocking while the lookup is performed.
 116
 117  @section evhttp Event-driven HTTP servers
 118
 119  libevent provides a very simple event-driven HTTP server that can be
 120  embedded in your program and used to service HTTP requests.
 121
 122  To use this capability, you need to include the <evhttp.h> header in your
 123  program.  You create the server by calling evhttp_new(). Add addresses and
 124  ports to listen on with evhttp_bind_socket(). You then register one or more
 125  callbacks to handle incoming requests.  Each URI can be assigned a callback
 126  via the evhttp_set_cb() function.  A generic callback function can also be
 127  registered via evhttp_set_gencb(); this callback will be invoked if no other
 128  callbacks have been registered for a given URI.
 129
 130  @section evrpc A framework for RPC servers and clients
 131
 132  libevents provides a framework for creating RPC servers and clients.  It
 133  takes care of marshaling and unmarshaling all data structures.
 134
 135  @section api API Reference
 136
 137  To browse the complete documentation of the libevent API, click on any of
 138  the following links.
 139
 140  event.h
 141  The primary libevent header
 142
 143  evdns.h
 144  Asynchronous DNS resolution
 145
 146  evhttp.h
 147  An embedded libevent-based HTTP server
 148
 149  evrpc.h
 150  A framework for creating RPC servers and clients
 151
 152 */
 153
 154/** @file event.h
 155
 156  A library for writing event-driven network servers
 157
 158 */
 159
 160#ifdef __cplusplus
 161extern "C" {
 162#endif
 163
 164#include <sys/types.h>
 165#include <sys/time.h>
 166#include <sys/queue.h>
 167
 168#include <stdarg.h>
 169#include <stdint.h>
 170
 171#define ev_uint64_t uint64_t
 172#define ev_int64_t int64_t
 173#define ev_uint32_t uint32_t
 174#define ev_uint16_t uint16_t
 175#define ev_uint8_t uint8_t
 176
 177#define EVLIST_TIMEOUT	0x01
 178#define EVLIST_INSERTED	0x02
 179#define EVLIST_SIGNAL	0x04
 180#define EVLIST_ACTIVE	0x08
 181#define EVLIST_INTERNAL	0x10
 182#define EVLIST_INIT	0x80
 183
 184/* EVLIST_X_ Private space: 0x1000-0xf000 */
 185#define EVLIST_ALL	(0xf000 | 0x9f)
 186
 187#define EV_TIMEOUT	0x01
 188#define EV_READ		0x02
 189#define EV_WRITE	0x04
 190#define EV_SIGNAL	0x08
 191#define EV_PERSIST	0x10	/* Persistent event */
 192
 193struct event_base;
 194#ifndef EVENT_NO_STRUCT
 195struct event {
 196	TAILQ_ENTRY (event) ev_next;
 197	TAILQ_ENTRY (event) ev_active_next;
 198	TAILQ_ENTRY (event) ev_signal_next;
 199	size_t min_heap_idx;	/* for managing timeouts */
 200
 201	struct event_base *ev_base;
 202
 203	int ev_fd;
 204	short ev_events;
 205	short ev_ncalls;
 206	short *ev_pncalls;	/* Allows deletes in callback */
 207
 208	struct timeval ev_timeout;
 209
 210	int ev_pri;		/* smaller numbers are higher priority */
 211
 212	void (*ev_callback)(int, short, void *arg);
 213	void *ev_arg;
 214
 215	int ev_res;		/* result passed to event callback */
 216	int ev_flags;
 217};
 218#else
 219struct event;
 220#endif
 221
 222#define EVENT_SIGNAL(ev)	(int)(ev)->ev_fd
 223#define EVENT_FD(ev)		(int)(ev)->ev_fd
 224
 225/*
 226 * Key-Value pairs.  Can be used for HTTP headers but also for
 227 * query argument parsing.
 228 */
 229struct evkeyval {
 230	TAILQ_ENTRY(evkeyval) next;
 231
 232	char *key;
 233	char *value;
 234};
 235
 236TAILQ_HEAD (event_list, event);
 237TAILQ_HEAD (evkeyvalq, evkeyval);
 238
 239/**
 240  Initialize the event API.
 241
 242  Use event_base_new() to initialize a new event base, but does not set
 243  the current_base global.   If using only event_base_new(), each event
 244  added must have an event base set with event_base_set()
 245
 246  @see event_base_set(), event_base_free(), event_init()
 247 */
 248struct event_base *event_base_new(void);
 249
 250/**
 251  Initialize the event API.
 252
 253  The event API needs to be initialized with event_init() before it can be
 254  used.  Sets the current_base global representing the default base for
 255  events that have no base associated with them.
 256
 257  @see event_base_set(), event_base_new()
 258 */
 259struct event_base *event_init(void);
 260
 261/**
 262  Reinitialized the event base after a fork
 263
 264  Some event mechanisms do not survive across fork.   The event base needs
 265  to be reinitialized with the event_reinit() function.
 266
 267  @param base the event base that needs to be re-initialized
 268  @return 0 if successful, or -1 if some events could not be re-added.
 269  @see event_base_new(), event_init()
 270*/
 271int event_reinit(struct event_base *base);
 272
 273/**
 274  Loop to process events.
 275
 276  In order to process events, an application needs to call
 277  event_dispatch().  This function only returns on error, and should
 278  replace the event core of the application program.
 279
 280  @see event_base_dispatch()
 281 */
 282int event_dispatch(void);
 283
 284
 285/**
 286  Threadsafe event dispatching loop.
 287
 288  @param eb the event_base structure returned by event_init()
 289  @see event_init(), event_dispatch()
 290 */
 291int event_base_dispatch(struct event_base *);
 292
 293
 294/**
 295 Get the kernel event notification mechanism used by libevent.
 296
 297 @param eb the event_base structure returned by event_base_new()
 298 @return a string identifying the kernel event mechanism (kqueue, epoll, etc.)
 299 */
 300const char *event_base_get_method(struct event_base *);
 301
 302
 303/**
 304  Deallocate all memory associated with an event_base, and free the base.
 305
 306  Note that this function will not close any fds or free any memory passed
 307  to event_set as the argument to callback.
 308
 309  @param eb an event_base to be freed
 310 */
 311void event_base_free(struct event_base *);
 312
 313
 314#define _EVENT_LOG_DEBUG 0
 315#define _EVENT_LOG_MSG   1
 316#define _EVENT_LOG_WARN  2
 317#define _EVENT_LOG_ERR   3
 318typedef void (*event_log_cb)(int severity, const char *msg);
 319/**
 320  Redirect libevent's log messages.
 321
 322  @param cb a function taking two arguments: an integer severity between
 323     _EVENT_LOG_DEBUG and _EVENT_LOG_ERR, and a string.  If cb is NULL,
 324	 then the default log is used.
 325  */
 326void event_set_log_callback(event_log_cb cb);
 327
 328/**
 329  Associate a different event base with an event.
 330
 331  @param eb the event base
 332  @param ev the event
 333 */
 334int event_base_set(struct event_base *, struct event *);
 335
 336/**
 337 event_loop() flags
 338 */
 339/*@{*/
 340#define EVLOOP_ONCE	0x01	/**< Block at most once. */
 341#define EVLOOP_NONBLOCK	0x02	/**< Do not block. */
 342/*@}*/
 343
 344/**
 345  Handle events.
 346
 347  This is a more flexible version of event_dispatch().
 348
 349  @param flags any combination of EVLOOP_ONCE | EVLOOP_NONBLOCK
 350  @return 0 if successful, -1 if an error occurred, or 1 if no events were
 351    registered.
 352  @see event_loopexit(), event_base_loop()
 353*/
 354int event_loop(int);
 355
 356/**
 357  Handle events (threadsafe version).
 358
 359  This is a more flexible version of event_base_dispatch().
 360
 361  @param eb the event_base structure returned by event_init()
 362  @param flags any combination of EVLOOP_ONCE | EVLOOP_NONBLOCK
 363  @return 0 if successful, -1 if an error occurred, or 1 if no events were
 364    registered.
 365  @see event_loopexit(), event_base_loop()
 366  */
 367int event_base_loop(struct event_base *, int);
 368
 369/**
 370  Exit the event loop after the specified time.
 371
 372  The next event_loop() iteration after the given timer expires will
 373  complete normally (handling all queued events) then exit without
 374  blocking for events again.
 375
 376  Subsequent invocations of event_loop() will proceed normally.
 377
 378  @param tv the amount of time after which the loop should terminate.
 379  @return 0 if successful, or -1 if an error occurred
 380  @see event_loop(), event_base_loop(), event_base_loopexit()
 381  */
 382int event_loopexit(const struct timeval *);
 383
 384
 385/**
 386  Exit the event loop after the specified time (threadsafe variant).
 387
 388  The next event_base_loop() iteration after the given timer expires will
 389  complete normally (handling all queued events) then exit without
 390  blocking for events again.
 391
 392  Subsequent invocations of event_base_loop() will proceed normally.
 393
 394  @param eb the event_base structure returned by event_init()
 395  @param tv the amount of time after which the loop should terminate.
 396  @return 0 if successful, or -1 if an error occurred
 397  @see event_loopexit()
 398 */
 399int event_base_loopexit(struct event_base *, const struct timeval *);
 400
 401/**
 402  Abort the active event_loop() immediately.
 403
 404  event_loop() will abort the loop after the next event is completed;
 405  event_loopbreak() is typically invoked from this event's callback.
 406  This behavior is analogous to the "break;" statement.
 407
 408  Subsequent invocations of event_loop() will proceed normally.
 409
 410  @return 0 if successful, or -1 if an error occurred
 411  @see event_base_loopbreak(), event_loopexit()
 412 */
 413int event_loopbreak(void);
 414
 415/**
 416  Abort the active event_base_loop() immediately.
 417
 418  event_base_loop() will abort the loop after the next event is completed;
 419  event_base_loopbreak() is typically invoked from this event's callback.
 420  This behavior is analogous to the "break;" statement.
 421
 422  Subsequent invocations of event_loop() will proceed normally.
 423
 424  @param eb the event_base structure returned by event_init()
 425  @return 0 if successful, or -1 if an error occurred
 426  @see event_base_loopexit
 427 */
 428int event_base_loopbreak(struct event_base *);
 429
 430
 431/**
 432  Add a timer event.
 433
 434  @param ev the event struct
 435  @param tv timeval struct
 436 */
 437#define evtimer_add(ev, tv)		event_add(ev, tv)
 438
 439
 440/**
 441  Define a timer event.
 442
 443  @param ev event struct to be modified
 444  @param cb callback function
 445  @param arg argument that will be passed to the callback function
 446 */
 447#define evtimer_set(ev, cb, arg)	event_set(ev, -1, 0, cb, arg)
 448
 449
 450/**
 451 * Delete a timer event.
 452 *
 453 * @param ev the event struct to be disabled
 454 */
 455#define evtimer_del(ev)			event_del(ev)
 456#define evtimer_pending(ev, tv)		event_pending(ev, EV_TIMEOUT, tv)
 457#define evtimer_initialized(ev)		((ev)->ev_flags & EVLIST_INIT)
 458
 459#ifdef EVENT_DEPRECATED
 460/*
 461 * timeout_* are collision-prone names for macros, and they are
 462 * deprecated. Define EVENT_DEPRECATED to expose them anyway.
 463 *
 464 * It is recommended evtimer_* be used instead.
 465 */
 466
 467/**
 468 * Add a timeout event.
 469 *
 470 * @param ev the event struct to be disabled
 471 * @param tv the timeout value, in seconds
 472 */
 473#define timeout_add(ev, tv)		event_add(ev, tv)
 474
 475
 476/**
 477 * Define a timeout event.
 478 *
 479 * @param ev the event struct to be defined
 480 * @param cb the callback to be invoked when the timeout expires
 481 * @param arg the argument to be passed to the callback
 482 */
 483#define timeout_set(ev, cb, arg)	event_set(ev, -1, 0, cb, arg)
 484
 485
 486/**
 487 * Disable a timeout event.
 488 *
 489 * @param ev the timeout event to be disabled
 490 */
 491#define timeout_del(ev)			event_del(ev)
 492
 493#define timeout_pending(ev, tv)		event_pending(ev, EV_TIMEOUT, tv)
 494#define timeout_initialized(ev)		((ev)->ev_flags & EVLIST_INIT)
 495
 496#endif /* EVENT_DEPRECATED */
 497
 498#define signal_add(ev, tv)		event_add(ev, tv)
 499#define signal_set(ev, x, cb, arg)	\
 500	event_set(ev, x, EV_SIGNAL|EV_PERSIST, cb, arg)
 501#define signal_del(ev)			event_del(ev)
 502#define signal_pending(ev, tv)		event_pending(ev, EV_SIGNAL, tv)
 503#define signal_initialized(ev)		((ev)->ev_flags & EVLIST_INIT)
 504
 505/**
 506  Prepare an event structure to be added.
 507
 508  The function event_set() prepares the event structure ev to be used in
 509  future calls to event_add() and event_del().  The event will be prepared to
 510  call the function specified by the fn argument with an int argument
 511  indicating the file descriptor, a short argument indicating the type of
 512  event, and a void * argument given in the arg argument.  The fd indicates
 513  the file descriptor that should be monitored for events.  The events can be
 514  either EV_READ, EV_WRITE, or both.  Indicating that an application can read
 515  or write from the file descriptor respectively without blocking.
 516
 517  The function fn will be called with the file descriptor that triggered the
 518  event and the type of event which will be either EV_TIMEOUT, EV_SIGNAL,
 519  EV_READ, or EV_WRITE.  The additional flag EV_PERSIST makes an event_add()
 520  persistent until event_del() has been called.
 521
 522  @param ev an event struct to be modified
 523  @param fd the file descriptor to be monitored
 524  @param event desired events to monitor; can be EV_READ and/or EV_WRITE
 525  @param fn callback function to be invoked when the event occurs
 526  @param arg an argument to be passed to the callback function
 527
 528  @see event_add(), event_del(), event_once()
 529
 530 */
 531void event_set(struct event *, int, short, void (*)(int, short, void *), void *);
 532
 533/**
 534  Schedule a one-time event to occur.
 535
 536  The function event_once() is similar to event_set().  However, it schedules
 537  a callback to be called exactly once and does not require the caller to
 538  prepare an event structure.
 539
 540  @param fd a file descriptor to monitor
 541  @param events event(s) to monitor; can be any of EV_TIMEOUT | EV_READ |
 542         EV_WRITE
 543  @param callback callback function to be invoked when the event occurs
 544  @param arg an argument to be passed to the callback function
 545  @param timeout the maximum amount of time to wait for the event, or NULL
 546         to wait forever
 547  @return 0 if successful, or -1 if an error occurred
 548  @see event_set()
 549
 550 */
 551int event_once(int, short, void (*)(int, short, void *), void *,
 552    const struct timeval *);
 553
 554
 555/**
 556  Schedule a one-time event (threadsafe variant)
 557
 558  The function event_base_once() is similar to event_set().  However, it
 559  schedules a callback to be called exactly once and does not require the
 560  caller to prepare an event structure.
 561
 562  @param base an event_base returned by event_init()
 563  @param fd a file descriptor to monitor
 564  @param events event(s) to monitor; can be any of EV_TIMEOUT | EV_READ |
 565         EV_WRITE
 566  @param callback callback function to be invoked when the event occurs
 567  @param arg an argument to be passed to the callback function
 568  @param timeout the maximum amount of time to wait for the event, or NULL
 569         to wait forever
 570  @return 0 if successful, or -1 if an error occurred
 571  @see event_once()
 572 */
 573int event_base_once(struct event_base *base, int fd, short events,
 574    void (*callback)(int, short, void *), void *arg,
 575    const struct timeval *timeout);
 576
 577
 578/**
 579  Add an event to the set of monitored events.
 580
 581  The function event_add() schedules the execution of the ev event when the
 582  event specified in event_set() occurs or in at least the time specified in
 583  the tv.  If tv is NULL, no timeout occurs and the function will only be
 584  called if a matching event occurs on the file descriptor.  The event in the
 585  ev argument must be already initialized by event_set() and may not be used
 586  in calls to event_set() until it has timed out or been removed with
 587  event_del().  If the event in the ev argument already has a scheduled
 588  timeout, the old timeout will be replaced by the new one.
 589
 590  @param ev an event struct initialized via event_set()
 591  @param timeout the maximum amount of time to wait for the event, or NULL
 592         to wait forever
 593  @return 0 if successful, or -1 if an error occurred
 594  @see event_del(), event_set()
 595  */
 596int event_add(struct event *ev, const struct timeval *timeout);
 597
 598
 599/**
 600  Remove an event from the set of monitored events.
 601
 602  The function event_del() will cancel the event in the argument ev.  If the
 603  event has already executed or has never been added the call will have no
 604  effect.
 605
 606  @param ev an event struct to be removed from the working set
 607  @return 0 if successful, or -1 if an error occurred
 608  @see event_add()
 609 */
 610int event_del(struct event *);
 611
 612void event_active(struct event *, int, short);
 613
 614
 615/**
 616  Checks if a specific event is pending or scheduled.
 617
 618  @param ev an event struct previously passed to event_add()
 619  @param event the requested event type; any of EV_TIMEOUT|EV_READ|
 620         EV_WRITE|EV_SIGNAL
 621  @param tv an alternate timeout (FIXME - is this true?)
 622
 623  @return 1 if the event is pending, or 0 if the event has not occurred
 624
 625 */
 626int event_pending(struct event *ev, short event, struct timeval *tv);
 627
 628
 629/**
 630  Test if an event structure has been initialized.
 631
 632  The event_initialized() macro can be used to check if an event has been
 633  initialized.
 634
 635  @param ev an event structure to be tested
 636  @return 1 if the structure has been initialized, or 0 if it has not been
 637         initialized
 638 */
 639#define event_initialized(ev)		((ev)->ev_flags & EVLIST_INIT)
 640
 641
 642/**
 643  Get the libevent version number.
 644
 645  @return a string containing the version number of libevent
 646 */
 647const char *event_get_version(void);
 648
 649
 650/**
 651  Get the kernel event notification mechanism used by libevent.
 652
 653  @return a string identifying the kernel event mechanism (kqueue, epoll, etc.)
 654 */
 655const char *event_get_method(void);
 656
 657
 658/**
 659  Set the number of different event priorities.
 660
 661  By default libevent schedules all active events with the same priority.
 662  However, some time it is desirable to process some events with a higher
 663  priority than others.  For that reason, libevent supports strict priority
 664  queues.  Active events with a lower priority are always processed before
 665  events with a higher priority.
 666
 667  The number of different priorities can be set initially with the
 668  event_priority_init() function.  This function should be called before the
 669  first call to event_dispatch().  The event_priority_set() function can be
 670  used to assign a priority to an event.  By default, libevent assigns the
 671  middle priority to all events unless their priority is explicitly set.
 672
 673  @param npriorities the maximum number of priorities
 674  @return 0 if successful, or -1 if an error occurred
 675  @see event_base_priority_init(), event_priority_set()
 676
 677 */
 678int	event_priority_init(int);
 679
 680
 681/**
 682  Set the number of different event priorities (threadsafe variant).
 683
 684  See the description of event_priority_init() for more information.
 685
 686  @param eb the event_base structure returned by event_init()
 687  @param npriorities the maximum number of priorities
 688  @return 0 if successful, or -1 if an error occurred
 689  @see event_priority_init(), event_priority_set()
 690 */
 691int	event_base_priority_init(struct event_base *, int);
 692
 693
 694/**
 695  Assign a priority to an event.
 696
 697  @param ev an event struct
 698  @param priority the new priority to be assigned
 699  @return 0 if successful, or -1 if an error occurred
 700  @see event_priority_init()
 701  */
 702int	event_priority_set(struct event *, int);
 703
 704
 705/* Simple helpers for ASR async resolution API. */
 706
 707/* We don't want to pull asr.h here */
 708struct asr_query;
 709struct asr_result;
 710
 711struct event_asr;
 712
 713/**
 714 * Schedule an async query to run in the libevent event loop, and trigger
 715 * a callback when done. Returns an opaque async event handle.
 716 */
 717struct event_asr * event_asr_run(struct asr_query *,
 718    void (*)(struct asr_result *, void *), void *);
 719
 720/**
 721 * Cancel a running async query associated to an handle.
 722 */
 723void event_asr_abort(struct event_asr *);
 724
 725
 726/* These functions deal with buffering input and output */
 727
 728struct evbuffer {
 729	u_char *buffer;
 730	u_char *orig_buffer;
 731
 732	size_t misalign;
 733	size_t totallen;
 734	size_t off;
 735
 736	void (*cb)(struct evbuffer *, size_t, size_t, void *);
 737	void *cbarg;
 738};
 739
 740/* Just for error reporting - use other constants otherwise */
 741#define EVBUFFER_READ		0x01
 742#define EVBUFFER_WRITE		0x02
 743#define EVBUFFER_EOF		0x10
 744#define EVBUFFER_ERROR		0x20
 745#define EVBUFFER_TIMEOUT	0x40
 746
 747struct bufferevent;
 748typedef void (*evbuffercb)(struct bufferevent *, void *);
 749typedef void (*everrorcb)(struct bufferevent *, short what, void *);
 750
 751struct event_watermark {
 752	size_t low;
 753	size_t high;
 754};
 755
 756#ifndef EVENT_NO_STRUCT
 757struct bufferevent {
 758	struct event_base *ev_base;
 759
 760	struct event ev_read;
 761	struct event ev_write;
 762
 763	struct evbuffer *input;
 764	struct evbuffer *output;
 765
 766	struct event_watermark wm_read;
 767	struct event_watermark wm_write;
 768
 769	evbuffercb readcb;
 770	evbuffercb writecb;
 771	everrorcb errorcb;
 772	void *cbarg;
 773
 774	int timeout_read;	/* in seconds */
 775	int timeout_write;	/* in seconds */
 776
 777	short enabled;	/* events that are currently enabled */
 778};
 779#endif
 780
 781/**
 782  Create a new bufferevent.
 783
 784  libevent provides an abstraction on top of the regular event callbacks.
 785  This abstraction is called a buffered event.  A buffered event provides
 786  input and output buffers that get filled and drained automatically.  The
 787  user of a buffered event no longer deals directly with the I/O, but
 788  instead is reading from input and writing to output buffers.
 789
 790  Once initialized, the bufferevent structure can be used repeatedly with
 791  bufferevent_enable() and bufferevent_disable().
 792
 793  When read enabled the bufferevent will try to read from the file descriptor
 794  and call the read callback.  The write callback is executed whenever the
 795  output buffer is drained below the write low watermark, which is 0 by
 796  default.
 797
 798  If multiple bases are in use, bufferevent_base_set() must be called before
 799  enabling the bufferevent for the first time.
 800
 801  @param fd the file descriptor from which data is read and written to.
 802         This file descriptor is not allowed to be a pipe(2).
 803  @param readcb callback to invoke when there is data to be read, or NULL if
 804         no callback is desired
 805  @param writecb callback to invoke when the file descriptor is ready for
 806         writing, or NULL if no callback is desired
 807  @param errorcb callback to invoke when there is an error on the file
 808         descriptor
 809  @param cbarg an argument that will be supplied to each of the callbacks
 810         (readcb, writecb, and errorcb)
 811  @return a pointer to a newly allocated bufferevent struct, or NULL if an
 812         error occurred
 813  @see bufferevent_base_set(), bufferevent_free()
 814  */
 815struct bufferevent *bufferevent_new(int fd,
 816    evbuffercb readcb, evbuffercb writecb, everrorcb errorcb, void *cbarg);
 817
 818
 819/**
 820  Assign a bufferevent to a specific event_base.
 821
 822  @param base an event_base returned by event_init()
 823  @param bufev a bufferevent struct returned by bufferevent_new()
 824  @return 0 if successful, or -1 if an error occurred
 825  @see bufferevent_new()
 826 */
 827int bufferevent_base_set(struct event_base *base, struct bufferevent *bufev);
 828
 829
 830/**
 831  Assign a priority to a bufferevent.
 832
 833  @param bufev a bufferevent struct
 834  @param pri the priority to be assigned
 835  @return 0 if successful, or -1 if an error occurred
 836  */
 837int bufferevent_priority_set(struct bufferevent *bufev, int pri);
 838
 839
 840/**
 841  Deallocate the storage associated with a bufferevent structure.
 842
 843  @param bufev the bufferevent structure to be freed.
 844  */
 845void bufferevent_free(struct bufferevent *bufev);
 846
 847
 848/**
 849  Changes the callbacks for a bufferevent.
 850
 851  @param bufev the bufferevent object for which to change callbacks
 852  @param readcb callback to invoke when there is data to be read, or NULL if
 853         no callback is desired
 854  @param writecb callback to invoke when the file descriptor is ready for
 855         writing, or NULL if no callback is desired
 856  @param errorcb callback to invoke when there is an error on the file
 857         descriptor
 858  @param cbarg an argument that will be supplied to each of the callbacks
 859         (readcb, writecb, and errorcb)
 860  @see bufferevent_new()
 861  */
 862void bufferevent_setcb(struct bufferevent *bufev,
 863    evbuffercb readcb, evbuffercb writecb, everrorcb errorcb, void *cbarg);
 864
 865/**
 866  Changes the file descriptor on which the bufferevent operates.
 867
 868  @param bufev the bufferevent object for which to change the file descriptor
 869  @param fd the file descriptor to operate on
 870*/
 871void bufferevent_setfd(struct bufferevent *bufev, int fd);
 872
 873/**
 874  Write data to a bufferevent buffer.
 875
 876  The bufferevent_write() function can be used to write data to the file
 877  descriptor.  The data is appended to the output buffer and written to the
 878  descriptor automatically as it becomes available for writing.
 879
 880  @param bufev the bufferevent to be written to
 881  @param data a pointer to the data to be written
 882  @param size the length of the data, in bytes
 883  @return 0 if successful, or -1 if an error occurred
 884  @see bufferevent_write_buffer()
 885  */
 886int bufferevent_write(struct bufferevent *bufev,
 887    const void *data, size_t size);
 888
 889
 890/**
 891  Write data from an evbuffer to a bufferevent buffer.  The evbuffer is
 892  being drained as a result.
 893
 894  @param bufev the bufferevent to be written to
 895  @param buf the evbuffer to be written
 896  @return 0 if successful, or -1 if an error occurred
 897  @see bufferevent_write()
 898 */
 899int bufferevent_write_buffer(struct bufferevent *bufev, struct evbuffer *buf);
 900
 901
 902/**
 903  Read data from a bufferevent buffer.
 904
 905  The bufferevent_read() function is used to read data from the input buffer.
 906
 907  @param bufev the bufferevent to be read from
 908  @param data pointer to a buffer that will store the data
 909  @param size the size of the data buffer, in bytes
 910  @return the amount of data read, in bytes.
 911 */
 912size_t bufferevent_read(struct bufferevent *bufev, void *data, size_t size);
 913
 914/**
 915  Enable a bufferevent.
 916
 917  @param bufev the bufferevent to be enabled
 918  @param event any combination of EV_READ | EV_WRITE.
 919  @return 0 if successful, or -1 if an error occurred
 920  @see bufferevent_disable()
 921 */
 922int bufferevent_enable(struct bufferevent *bufev, short event);
 923
 924
 925/**
 926  Disable a bufferevent.
 927
 928  @param bufev the bufferevent to be disabled
 929  @param event any combination of EV_READ | EV_WRITE.
 930  @return 0 if successful, or -1 if an error occurred
 931  @see bufferevent_enable()
 932 */
 933int bufferevent_disable(struct bufferevent *bufev, short event);
 934
 935
 936/**
 937  Set the read and write timeout for a buffered event.
 938
 939  @param bufev the bufferevent to be modified
 940  @param timeout_read the read timeout
 941  @param timeout_write the write timeout
 942 */
 943void bufferevent_settimeout(struct bufferevent *bufev,
 944    int timeout_read, int timeout_write);
 945
 946
 947/**
 948  Sets the watermarks for read and write events.
 949
 950  On input, a bufferevent does not invoke the user read callback unless
 951  there is at least low watermark data in the buffer.   If the read buffer
 952  is beyond the high watermark, the buffevent stops reading from the network.
 953
 954  On output, the user write callback is invoked whenever the buffered data
 955  falls below the low watermark.
 956
 957  @param bufev the bufferevent to be modified
 958  @param events EV_READ, EV_WRITE or both
 959  @param lowmark the lower watermark to set
 960  @param highmark the high watermark to set
 961*/
 962
 963void bufferevent_setwatermark(struct bufferevent *bufev, short events,
 964    size_t lowmark, size_t highmark);
 965
 966#define EVBUFFER_LENGTH(x)	(x)->off
 967#define EVBUFFER_DATA(x)	(x)->buffer
 968#define EVBUFFER_INPUT(x)	(x)->input
 969#define EVBUFFER_OUTPUT(x)	(x)->output
 970
 971
 972/**
 973  Allocate storage for a new evbuffer.
 974
 975  @return a pointer to a newly allocated evbuffer struct, or NULL if an error
 976         occurred
 977 */
 978struct evbuffer *evbuffer_new(void);
 979
 980
 981/**
 982  Deallocate storage for an evbuffer.
 983
 984  @param pointer to the evbuffer to be freed
 985 */
 986void evbuffer_free(struct evbuffer *);
 987
 988
 989/**
 990  Expands the available space in an event buffer.
 991
 992  Expands the available space in the event buffer to at least datlen
 993
 994  @param buf the event buffer to be expanded
 995  @param datlen the new minimum length requirement
 996  @return 0 if successful, or -1 if an error occurred
 997*/
 998int evbuffer_expand(struct evbuffer *, size_t);
 999
1000
1001/**
1002  Append data to the end of an evbuffer.
1003
1004  @param buf the event buffer to be appended to
1005  @param data pointer to the beginning of the data buffer
1006  @param datlen the number of bytes to be copied from the data buffer
1007 */
1008int evbuffer_add(struct evbuffer *, const void *, size_t);
1009
1010
1011
1012/**
1013  Read data from an event buffer and drain the bytes read.
1014
1015  @param buf the event buffer to be read from
1016  @param data the destination buffer to store the result
1017  @param datlen the maximum size of the destination buffer
1018  @return the number of bytes read
1019 */
1020int evbuffer_remove(struct evbuffer *, void *, size_t);
1021
1022
1023/**
1024 * Read a single line from an event buffer.
1025 *
1026 * Reads a line terminated by either '\r\n', '\n\r' or '\r' or '\n'.
1027 * The returned buffer needs to be freed by the caller.
1028 *
1029 * @param buffer the evbuffer to read from
1030 * @return pointer to a single line, or NULL if an error occurred
1031 */
1032char *evbuffer_readline(struct evbuffer *);
1033
1034
1035/** Used to tell evbuffer_readln what kind of line-ending to look for.
1036 */
1037enum evbuffer_eol_style {
1038	/** Any sequence of CR and LF characters is acceptable as an EOL. */
1039	EVBUFFER_EOL_ANY,
1040	/** An EOL is an LF, optionally preceded by a CR.  This style is
1041	 * most useful for implementing text-based internet protocols. */
1042	EVBUFFER_EOL_CRLF,
1043	/** An EOL is a CR followed by an LF. */
1044	EVBUFFER_EOL_CRLF_STRICT,
1045	/** An EOL is a LF. */
1046        EVBUFFER_EOL_LF
1047};
1048
1049/**
1050 * Read a single line from an event buffer.
1051 *
1052 * Reads a line terminated by an EOL as determined by the evbuffer_eol_style
1053 * argument.  Returns a newly allocated nul-terminated string; the caller must
1054 * free the returned value.  The EOL is not included in the returned string.
1055 *
1056 * @param buffer the evbuffer to read from
1057 * @param n_read_out if non-NULL, points to a size_t that is set to the
1058 *       number of characters in the returned string.  This is useful for
1059 *       strings that can contain NUL characters.
1060 * @param eol_style the style of line-ending to use.
1061 * @return pointer to a single line, or NULL if an error occurred
1062 */
1063char *evbuffer_readln(struct evbuffer *buffer, size_t *n_read_out,
1064    enum evbuffer_eol_style eol_style);
1065
1066
1067/**
1068  Move data from one evbuffer into another evbuffer.
1069
1070  This is a destructive add.  The data from one buffer moves into
1071  the other buffer. The destination buffer is expanded as needed.
1072
1073  @param outbuf the output buffer
1074  @param inbuf the input buffer
1075  @return 0 if successful, or -1 if an error occurred
1076 */
1077int evbuffer_add_buffer(struct evbuffer *, struct evbuffer *);
1078
1079
1080/**
1081  Append a formatted string to the end of an evbuffer.
1082
1083  @param buf the evbuffer that will be appended to
1084  @param fmt a format string
1085  @param ... arguments that will be passed to printf(3)
1086  @return The number of bytes added if successful, or -1 if an error occurred.
1087 */
1088int evbuffer_add_printf(struct evbuffer *, const char *fmt, ...)
1089#ifdef __GNUC__
1090  __attribute__((format(printf, 2, 3)))
1091#endif
1092;
1093
1094
1095/**
1096  Append a va_list formatted string to the end of an evbuffer.
1097
1098  @param buf the evbuffer that will be appended to
1099  @param fmt a format string
1100  @param ap a varargs va_list argument array that will be passed to vprintf(3)
1101  @return The number of bytes added if successful, or -1 if an error occurred.
1102 */
1103int evbuffer_add_vprintf(struct evbuffer *, const char *fmt, va_list ap);
1104
1105
1106/**
1107  Remove a specified number of bytes data from the beginning of an evbuffer.
1108
1109  @param buf the evbuffer to be drained
1110  @param len the number of bytes to drain from the beginning of the buffer
1111 */
1112void evbuffer_drain(struct evbuffer *, size_t);
1113
1114
1115/**
1116  Write the contents of an evbuffer to a file descriptor.
1117
1118  The evbuffer will be drained after the bytes have been successfully written.
1119
1120  @param buffer the evbuffer to be written and drained
1121  @param fd the file descriptor to be written to
1122  @return the number of bytes written, or -1 if an error occurred
1123  @see evbuffer_read()
1124 */
1125int evbuffer_write(struct evbuffer *, int);
1126
1127
1128/**
1129  Read from a file descriptor and store the result in an evbuffer.
1130
1131  @param buf the evbuffer to store the result
1132  @param fd the file descriptor to read from
1133  @param howmuch the number of bytes to be read
1134  @return the number of bytes read, or -1 if an error occurred
1135  @see evbuffer_write()
1136 */
1137int evbuffer_read(struct evbuffer *, int, int);
1138
1139
1140/**
1141  Find a string within an evbuffer.
1142
1143  @param buffer the evbuffer to be searched
1144  @param what the string to be searched for
1145  @param len the length of the search string
1146  @return a pointer to the beginning of the search string, or NULL if the search failed.
1147 */
1148u_char *evbuffer_find(struct evbuffer *, const u_char *, size_t);
1149
1150/**
1151  Set a callback to invoke when the evbuffer is modified.
1152
1153  @param buffer the evbuffer to be monitored
1154  @param cb the callback function to invoke when the evbuffer is modified
1155  @param cbarg an argument to be provided to the callback function
1156 */
1157void evbuffer_setcb(struct evbuffer *, void (*)(struct evbuffer *, size_t, size_t, void *), void *);
1158
1159/*
1160 * Marshaling tagged data - We assume that all tags are inserted in their
1161 * numeric order - so that unknown tags will always be higher than the
1162 * known ones - and we can just ignore the end of an event buffer.
1163 */
1164
1165void evtag_init(void);
1166
1167void evtag_marshal(struct evbuffer *evbuf, ev_uint32_t tag, const void *data,
1168    ev_uint32_t len);
1169
1170/**
1171  Encode an integer and store it in an evbuffer.
1172
1173  We encode integer's by nibbles; the first nibble contains the number
1174  of significant nibbles - 1;  this allows us to encode up to 64-bit
1175  integers.  This function is byte-order independent.
1176
1177  @param evbuf evbuffer to store the encoded number
1178  @param number a 32-bit integer
1179 */
1180void encode_int(struct evbuffer *evbuf, ev_uint32_t number);
1181
1182void evtag_marshal_int(struct evbuffer *evbuf, ev_uint32_t tag,
1183    ev_uint32_t integer);
1184
1185void evtag_marshal_string(struct evbuffer *buf, ev_uint32_t tag,
1186    const char *string);
1187
1188void evtag_marshal_timeval(struct evbuffer *evbuf, ev_uint32_t tag,
1189    struct timeval *tv);
1190
1191int evtag_unmarshal(struct evbuffer *src, ev_uint32_t *ptag,
1192    struct evbuffer *dst);
1193int evtag_peek(struct evbuffer *evbuf, ev_uint32_t *ptag);
1194int evtag_peek_length(struct evbuffer *evbuf, ev_uint32_t *plength);
1195int evtag_payload_length(struct evbuffer *evbuf, ev_uint32_t *plength);
1196int evtag_consume(struct evbuffer *evbuf);
1197
1198int evtag_unmarshal_int(struct evbuffer *evbuf, ev_uint32_t need_tag,
1199    ev_uint32_t *pinteger);
1200
1201int evtag_unmarshal_fixed(struct evbuffer *src, ev_uint32_t need_tag,
1202    void *data, size_t len);
1203
1204int evtag_unmarshal_string(struct evbuffer *evbuf, ev_uint32_t need_tag,
1205    char **pstring);
1206
1207int evtag_unmarshal_timeval(struct evbuffer *evbuf, ev_uint32_t need_tag,
1208    struct timeval *ptv);
1209
1210#define _EVENT_VERSION "1.4.15-stable"
1211
1212#ifdef __cplusplus
1213}
1214#endif
1215
1216#endif /* _EVENT_H_ */