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/*
* libev simple C++ wrapper classes * * Copyright (c) 2007,2008,2010 Marc Alexander Lehmann <libev@schmorp.de> * All rights reserved. * * Redistribution and use in source and binary forms, with or without modifica- * tion, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MER- * CHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO * EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPE- * CIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTH- * ERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED * OF THE POSSIBILITY OF SUCH DAMAGE. * * Alternatively, the contents of this file may be used under the terms of * the GNU General Public License ("GPL") version 2 or any later version, * in which case the provisions of the GPL are applicable instead of * the above. If you wish to allow the use of your version of this file * only under the terms of the GPL and not to allow others to use your * version of this file under the BSD license, indicate your decision * by deleting the provisions above and replace them with the notice * and other provisions required by the GPL. If you do not delete the * provisions above, a recipient may use your version of this file under * either the BSD or the GPL. */
#ifndef EVPP_H__
#define EVPP_H__
#ifdef EV_H
# include EV_H
#else
# include "ev.h"
#endif
#ifndef EV_USE_STDEXCEPT
# define EV_USE_STDEXCEPT 1
#endif
#if EV_USE_STDEXCEPT
# include <stdexcept>
#endif
namespace ev {
typedef ev_tstamp tstamp;
enum { UNDEF = EV_UNDEF, NONE = EV_NONE, READ = EV_READ, WRITE = EV_WRITE,#if EV_COMPAT3
TIMEOUT = EV_TIMEOUT,#endif
TIMER = EV_TIMER, PERIODIC = EV_PERIODIC, SIGNAL = EV_SIGNAL, CHILD = EV_CHILD, STAT = EV_STAT, IDLE = EV_IDLE, CHECK = EV_CHECK, PREPARE = EV_PREPARE, FORK = EV_FORK, ASYNC = EV_ASYNC, EMBED = EV_EMBED,# undef ERROR // some systems stupidly #define ERROR
ERROR = EV_ERROR };
enum { AUTO = EVFLAG_AUTO, NOENV = EVFLAG_NOENV, FORKCHECK = EVFLAG_FORKCHECK,
SELECT = EVBACKEND_SELECT, POLL = EVBACKEND_POLL, EPOLL = EVBACKEND_EPOLL, KQUEUE = EVBACKEND_KQUEUE, DEVPOLL = EVBACKEND_DEVPOLL, PORT = EVBACKEND_PORT };
enum {#if EV_COMPAT3
NONBLOCK = EVLOOP_NONBLOCK, ONESHOT = EVLOOP_ONESHOT,#endif
NOWAIT = EVRUN_NOWAIT, ONCE = EVRUN_ONCE };
enum how_t { ONE = EVBREAK_ONE, ALL = EVBREAK_ALL };
struct bad_loop#if EV_USE_STDEXCEPT
: std::runtime_error#endif
{#if EV_USE_STDEXCEPT
bad_loop () : std::runtime_error ("libev event loop cannot be initialized, bad value of LIBEV_FLAGS?") { }#endif
};
#ifdef EV_AX
# undef EV_AX
#endif
#ifdef EV_AX_
# undef EV_AX_
#endif
#if EV_MULTIPLICITY
# define EV_AX raw_loop
# define EV_AX_ raw_loop,
#else
# define EV_AX
# define EV_AX_
#endif
struct loop_ref { loop_ref (EV_P) throw ()#if EV_MULTIPLICITY
: EV_AX (EV_A)#endif
{ }
bool operator == (const loop_ref &other) const throw () {#if EV_MULTIPLICITY
return EV_AX == other.EV_AX;#else
return true;#endif
}
bool operator != (const loop_ref &other) const throw () {#if EV_MULTIPLICITY
return ! (*this == other);#else
return false;#endif
}
#if EV_MULTIPLICITY
bool operator == (const EV_P) const throw () { return this->EV_AX == EV_A; }
bool operator != (const EV_P) const throw () { return (*this == EV_A); }
operator struct ev_loop * () const throw () { return EV_AX; }
operator const struct ev_loop * () const throw () { return EV_AX; }
bool is_default () const throw () { return EV_AX == ev_default_loop (0); }#endif
#if EV_COMPAT3
void loop (int flags = 0) { ev_run (EV_AX_ flags); }
void unloop (how_t how = ONE) throw () { ev_break (EV_AX_ how); }#endif
void run (int flags = 0) { ev_run (EV_AX_ flags); }
void break_loop (how_t how = ONE) throw () { ev_break (EV_AX_ how); }
void post_fork () throw () { ev_loop_fork (EV_AX); }
unsigned int backend () const throw () { return ev_backend (EV_AX); }
tstamp now () const throw () { return ev_now (EV_AX); }
void ref () throw () { ev_ref (EV_AX); }
void unref () throw () { ev_unref (EV_AX); }
#if EV_FEATURE_API
unsigned int iteration () const throw () { return ev_iteration (EV_AX); }
unsigned int depth () const throw () { return ev_depth (EV_AX); }
void set_io_collect_interval (tstamp interval) throw () { ev_set_io_collect_interval (EV_AX_ interval); }
void set_timeout_collect_interval (tstamp interval) throw () { ev_set_timeout_collect_interval (EV_AX_ interval); }#endif
// function callback
void once (int fd, int events, tstamp timeout, void (*cb)(int, void *), void *arg = 0) throw () { ev_once (EV_AX_ fd, events, timeout, cb, arg); }
// method callback
template<class K, void (K::*method)(int)> void once (int fd, int events, tstamp timeout, K *object) throw () { once (fd, events, timeout, method_thunk<K, method>, object); }
// default method == operator ()
template<class K> void once (int fd, int events, tstamp timeout, K *object) throw () { once (fd, events, timeout, method_thunk<K, &K::operator ()>, object); }
template<class K, void (K::*method)(int)> static void method_thunk (int revents, void *arg) { (static_cast<K *>(arg)->*method) (revents); }
// no-argument method callback
template<class K, void (K::*method)()> void once (int fd, int events, tstamp timeout, K *object) throw () { once (fd, events, timeout, method_noargs_thunk<K, method>, object); }
template<class K, void (K::*method)()> static void method_noargs_thunk (int revents, void *arg) { (static_cast<K *>(arg)->*method) (); }
// simpler function callback
template<void (*cb)(int)> void once (int fd, int events, tstamp timeout) throw () { once (fd, events, timeout, simpler_func_thunk<cb>); }
template<void (*cb)(int)> static void simpler_func_thunk (int revents, void *arg) { (*cb) (revents); }
// simplest function callback
template<void (*cb)()> void once (int fd, int events, tstamp timeout) throw () { once (fd, events, timeout, simplest_func_thunk<cb>); }
template<void (*cb)()> static void simplest_func_thunk (int revents, void *arg) { (*cb) (); }
void feed_fd_event (int fd, int revents) throw () { ev_feed_fd_event (EV_AX_ fd, revents); }
void feed_signal_event (int signum) throw () { ev_feed_signal_event (EV_AX_ signum); }
#if EV_MULTIPLICITY
struct ev_loop* EV_AX;#endif
};
#if EV_MULTIPLICITY
struct dynamic_loop : loop_ref {
dynamic_loop (unsigned int flags = AUTO) throw (bad_loop) : loop_ref (ev_loop_new (flags)) { if (!EV_AX) throw bad_loop (); }
~dynamic_loop () throw () { ev_loop_destroy (EV_AX); EV_AX = 0; }
private:
dynamic_loop (const dynamic_loop &);
dynamic_loop & operator= (const dynamic_loop &);
};#endif
struct default_loop : loop_ref { default_loop (unsigned int flags = AUTO) throw (bad_loop)#if EV_MULTIPLICITY
: loop_ref (ev_default_loop (flags))#endif
{ if (#if EV_MULTIPLICITY
!EV_AX#else
!ev_default_loop (flags)#endif
) throw bad_loop (); }
private: default_loop (const default_loop &); default_loop &operator = (const default_loop &); };
inline loop_ref get_default_loop () throw () {#if EV_MULTIPLICITY
return ev_default_loop (0);#else
return loop_ref ();#endif
}
#undef EV_AX
#undef EV_AX_
#undef EV_PX
#undef EV_PX_
#if EV_MULTIPLICITY
# define EV_PX loop_ref EV_A
# define EV_PX_ loop_ref EV_A_
#else
# define EV_PX
# define EV_PX_
#endif
template<class ev_watcher, class watcher> struct base : ev_watcher { #if EV_MULTIPLICITY
EV_PX;
// loop set
void set (EV_P) throw () { this->EV_A = EV_A; } #endif
base (EV_PX) throw () #if EV_MULTIPLICITY
: EV_A (EV_A) #endif
{ ev_init (this, 0); }
void set_ (const void *data, void (*cb)(EV_P_ ev_watcher *w, int revents)) throw () { this->data = (void *)data; ev_set_cb (static_cast<ev_watcher *>(this), cb); }
// function callback
template<void (*function)(watcher &w, int)> void set (void *data = 0) throw () { set_ (data, function_thunk<function>); }
template<void (*function)(watcher &w, int)> static void function_thunk (EV_P_ ev_watcher *w, int revents) { function (*static_cast<watcher *>(w), revents); }
// method callback
template<class K, void (K::*method)(watcher &w, int)> void set (K *object) throw () { set_ (object, method_thunk<K, method>); }
// default method == operator ()
template<class K> void set (K *object) throw () { set_ (object, method_thunk<K, &K::operator ()>); }
template<class K, void (K::*method)(watcher &w, int)> static void method_thunk (EV_P_ ev_watcher *w, int revents) { (static_cast<K *>(w->data)->*method) (*static_cast<watcher *>(w), revents); }
// no-argument callback
template<class K, void (K::*method)()> void set (K *object) throw () { set_ (object, method_noargs_thunk<K, method>); }
template<class K, void (K::*method)()> static void method_noargs_thunk (EV_P_ ev_watcher *w, int revents) { (static_cast<K *>(w->data)->*method) (); }
void operator ()(int events = EV_UNDEF) { return ev_cb (static_cast<ev_watcher *>(this)) (static_cast<ev_watcher *>(this), events); }
bool is_active () const throw () { return ev_is_active (static_cast<const ev_watcher *>(this)); }
bool is_pending () const throw () { return ev_is_pending (static_cast<const ev_watcher *>(this)); }
void feed_event (int revents) throw () { ev_feed_event (EV_A_ static_cast<ev_watcher *>(this), revents); } };
inline tstamp now (EV_P) throw () { return ev_now (EV_A); }
inline void delay (tstamp interval) throw () { ev_sleep (interval); }
inline int version_major () throw () { return ev_version_major (); }
inline int version_minor () throw () { return ev_version_minor (); }
inline unsigned int supported_backends () throw () { return ev_supported_backends (); }
inline unsigned int recommended_backends () throw () { return ev_recommended_backends (); }
inline unsigned int embeddable_backends () throw () { return ev_embeddable_backends (); }
inline void set_allocator (void *(*cb)(void *ptr, long size) throw ()) throw () { ev_set_allocator (cb); }
inline void set_syserr_cb (void (*cb)(const char *msg) throw ()) throw () { ev_set_syserr_cb (cb); }
#if EV_MULTIPLICITY
#define EV_CONSTRUCT(cppstem,cstem) \
(EV_PX = get_default_loop ()) throw () \ : base<ev_ ## cstem, cppstem> (EV_A) \ { \ } #else
#define EV_CONSTRUCT(cppstem,cstem) \
() throw () \ { \ } #endif
/* using a template here would require quite a bit more lines,
* so a macro solution was chosen */ #define EV_BEGIN_WATCHER(cppstem,cstem) \
\ struct cppstem : base<ev_ ## cstem, cppstem> \ { \ void start () throw () \ { \ ev_ ## cstem ## _start (EV_A_ static_cast<ev_ ## cstem *>(this)); \ } \ \ void stop () throw () \ { \ ev_ ## cstem ## _stop (EV_A_ static_cast<ev_ ## cstem *>(this)); \ } \ \ cppstem EV_CONSTRUCT(cppstem,cstem) \ \ ~cppstem () throw () \ { \ stop (); \ } \ \ using base<ev_ ## cstem, cppstem>::set; \ \ private: \ \ cppstem (const cppstem &o); \ \ cppstem &operator =(const cppstem &o); \ \ public:
#define EV_END_WATCHER(cppstem,cstem) \
};
EV_BEGIN_WATCHER (io, io) void set (int fd, int events) throw () { int active = is_active (); if (active) stop (); ev_io_set (static_cast<ev_io *>(this), fd, events); if (active) start (); }
void set (int events) throw () { int active = is_active (); if (active) stop (); ev_io_set (static_cast<ev_io *>(this), fd, events); if (active) start (); }
void start (int fd, int events) throw () { set (fd, events); start (); } EV_END_WATCHER (io, io)
EV_BEGIN_WATCHER (timer, timer) void set (ev_tstamp after, ev_tstamp repeat = 0.) throw () { int active = is_active (); if (active) stop (); ev_timer_set (static_cast<ev_timer *>(this), after, repeat); if (active) start (); }
void start (ev_tstamp after, ev_tstamp repeat = 0.) throw () { set (after, repeat); start (); }
void again () throw () { ev_timer_again (EV_A_ static_cast<ev_timer *>(this)); }
ev_tstamp remaining () { return ev_timer_remaining (EV_A_ static_cast<ev_timer *>(this)); } EV_END_WATCHER (timer, timer)
#if EV_PERIODIC_ENABLE
EV_BEGIN_WATCHER (periodic, periodic) void set (ev_tstamp at, ev_tstamp interval = 0.) throw () { int active = is_active (); if (active) stop (); ev_periodic_set (static_cast<ev_periodic *>(this), at, interval, 0); if (active) start (); }
void start (ev_tstamp at, ev_tstamp interval = 0.) throw () { set (at, interval); start (); }
void again () throw () { ev_periodic_again (EV_A_ static_cast<ev_periodic *>(this)); } EV_END_WATCHER (periodic, periodic) #endif
#if EV_SIGNAL_ENABLE
EV_BEGIN_WATCHER (sig, signal) void set (int signum) throw () { int active = is_active (); if (active) stop (); ev_signal_set (static_cast<ev_signal *>(this), signum); if (active) start (); }
void start (int signum) throw () { set (signum); start (); } EV_END_WATCHER (sig, signal) #endif
#if EV_CHILD_ENABLE
EV_BEGIN_WATCHER (child, child) void set (int pid, int trace = 0) throw () { int active = is_active (); if (active) stop (); ev_child_set (static_cast<ev_child *>(this), pid, trace); if (active) start (); }
void start (int pid, int trace = 0) throw () { set (pid, trace); start (); } EV_END_WATCHER (child, child) #endif
#if EV_STAT_ENABLE
EV_BEGIN_WATCHER (stat, stat) void set (const char *path, ev_tstamp interval = 0.) throw () { int active = is_active (); if (active) stop (); ev_stat_set (static_cast<ev_stat *>(this), path, interval); if (active) start (); }
void start (const char *path, ev_tstamp interval = 0.) throw () { stop (); set (path, interval); start (); }
void update () throw () { ev_stat_stat (EV_A_ static_cast<ev_stat *>(this)); } EV_END_WATCHER (stat, stat) #endif
#if EV_IDLE_ENABLE
EV_BEGIN_WATCHER (idle, idle) void set () throw () { } EV_END_WATCHER (idle, idle) #endif
#if EV_PREPARE_ENABLE
EV_BEGIN_WATCHER (prepare, prepare) void set () throw () { } EV_END_WATCHER (prepare, prepare) #endif
#if EV_CHECK_ENABLE
EV_BEGIN_WATCHER (check, check) void set () throw () { } EV_END_WATCHER (check, check) #endif
#if EV_EMBED_ENABLE
EV_BEGIN_WATCHER (embed, embed) void set_embed (struct ev_loop *embedded_loop) throw () { int active = is_active (); if (active) stop (); ev_embed_set (static_cast<ev_embed *>(this), embedded_loop); if (active) start (); }
void start (struct ev_loop *embedded_loop) throw () { set (embedded_loop); start (); }
void sweep () { ev_embed_sweep (EV_A_ static_cast<ev_embed *>(this)); } EV_END_WATCHER (embed, embed) #endif
#if EV_FORK_ENABLE
EV_BEGIN_WATCHER (fork, fork) void set () throw () { } EV_END_WATCHER (fork, fork) #endif
#if EV_ASYNC_ENABLE
EV_BEGIN_WATCHER (async, async) void send () throw () { ev_async_send (EV_A_ static_cast<ev_async *>(this)); }
bool async_pending () throw () { return ev_async_pending (static_cast<ev_async *>(this)); } EV_END_WATCHER (async, async) #endif
#undef EV_PX
#undef EV_PX_
#undef EV_CONSTRUCT
#undef EV_BEGIN_WATCHER
#undef EV_END_WATCHER
}
#endif
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