[ViewVC] Diff of: cvs/libev/ev.c

Comparing libev/ev.c (file contents):
Revision 1.233 by root, Tue May 6 23:34:16 2008 UTC vs.
Revision 1.249 by root, Wed May 21 23:30:52 2008 UTC

 # else
 #  define EV_USE_EVENTFD 0
 # endif
 #endif
+#if 0 /* debugging */
+# define EV_VERIFY 1
+# define EV_USE_4HEAP 1
+# define EV_HEAP_CACHE_AT 1
+#endif
+#ifndef EV_USE_4HEAP
+# define EV_USE_4HEAP !EV_MINIMAL
+#endif
+#ifndef EV_HEAP_CACHE_AT
+# define EV_HEAP_CACHE_AT !EV_MINIMAL
+#endif
 /* this block fixes any misconfiguration where we know we run into trouble otherwise */
 #ifndef CLOCK_MONOTONIC
 # undef EV_USE_MONOTONIC
 # define EV_USE_MONOTONIC 0
 }
 # endif
 #endif
 /**/
+/* EV_VERIFY: enable internal consistency checks
+ * undefined or zero: no verification done or available
+ * 1 or higher: ev_loop_verify function available
+ * 2 or higher: ev_loop_verify is called frequently
+ */
+#if EV_VERIFY >= 1
+# define EV_FREQUENT_CHECK ev_loop_verify (EV_A)
+#else
+# define EV_FREQUENT_CHECK do { } while (0)
+#endif
 /*
  * This is used to avoid floating point rounding problems.
  * It is added to ev_rt_now when scheduling periodics
  * to ensure progress, time-wise, even when rounding
   W w;
   int events;
 } ANPENDING;
 #if EV_USE_INOTIFY
+/* hash table entry per inotify-id */
 typedef struct
 {
   WL head;
 } ANFS;
+#endif
+/* Heap Entry */
+#if EV_HEAP_CACHE_AT
+  typedef struct {
+    ev_tstamp at;
+    WT w;
+  } ANHE;
+  #define ANHE_w(he)        (he).w     /* access watcher, read-write */
+  #define ANHE_at(he)       (he).at    /* access cached at, read-only */
+  #define ANHE_at_cache(he) (he).at = (he).w->at /* update at from watcher */
+#else
+  typedef WT ANHE;
+  #define ANHE_w(he)        (he)
+  #define ANHE_at(he)       (he)->at
+  #define ANHE_at_cache(he)
 #endif
 #if EV_MULTIPLICITY
   struct ev_loop
       }
 }
 /*****************************************************************************/
+/*
+ * the heap functions want a real array index. array index 0 uis guaranteed to not
+ * be in-use at any time. the first heap entry is at array [HEAP0]. DHEAP gives
+ * the branching factor of the d-tree.
+ */
+/*
+ * at the moment we allow libev the luxury of two heaps,
+ * a small-code-size 2-heap one and a ~1.5kb larger 4-heap
+ * which is more cache-efficient.
+ * the difference is about 5% with 50000+ watchers.
+ */
+#if EV_USE_4HEAP
+#define DHEAP 4
+#define HEAP0 (DHEAP - 1) /* index of first element in heap */
+#define HPARENT(k) ((((k) - HEAP0 - 1) / DHEAP) + HEAP0)
+#define UPHEAP_DONE(p,k) ((p) == (k))
+/* away from the root */
+void inline_speed
+downheap (ANHE *heap, int N, int k)
+{
+  ANHE he = heap [k];
+  ANHE *E = heap + N + HEAP0;
+  for (;;)
+    {
+      ev_tstamp minat;
+      ANHE *minpos;
+      ANHE *pos = heap + DHEAP * (k - HEAP0) + HEAP0 + 1;
+      /* find minimum child */
+      if (expect_true (pos + DHEAP - 1 < E))
+        {
+          /* fast path */                               (minpos = pos + 0), (minat = ANHE_at (*minpos));
+          if (               ANHE_at (pos [1]) < minat) (minpos = pos + 1), (minat = ANHE_at (*minpos));
+          if (               ANHE_at (pos [2]) < minat) (minpos = pos + 2), (minat = ANHE_at (*minpos));
+          if (               ANHE_at (pos [3]) < minat) (minpos = pos + 3), (minat = ANHE_at (*minpos));
+        }
+      else if (pos < E)
+        {
+          /* slow path */                               (minpos = pos + 0), (minat = ANHE_at (*minpos));
+          if (pos + 1 < E && ANHE_at (pos [1]) < minat) (minpos = pos + 1), (minat = ANHE_at (*minpos));
+          if (pos + 2 < E && ANHE_at (pos [2]) < minat) (minpos = pos + 2), (minat = ANHE_at (*minpos));
+          if (pos + 3 < E && ANHE_at (pos [3]) < minat) (minpos = pos + 3), (minat = ANHE_at (*minpos));
+        }
+      else
+        break;
+      if (ANHE_at (he) <= minat)
+        break;
+      heap [k] = *minpos;
+      ev_active (ANHE_w (*minpos)) = k;
+      k = minpos - heap;
+    }
+  heap [k] = he;
+  ev_active (ANHE_w (he)) = k;
+}
+#else /* 4HEAP */
+#define HEAP0 1
+#define HPARENT(k) ((k) >> 1)
+#define UPHEAP_DONE(p,k) (!(p))
+/* away from the root */
+void inline_speed
+downheap (ANHE *heap, int N, int k)
+{
+  ANHE he = heap [k];
+  for (;;)
+    {
+      int c = k << 1;
+      if (c > N + HEAP0 - 1)
+        break;
+      c += c + 1 < N + HEAP0 && ANHE_at (heap [c]) > ANHE_at (heap [c + 1])
+           ? 1 : 0;
+      if (ANHE_at (he) <= ANHE_at (heap [c]))
+        break;
+      heap [k] = heap [c];
+      ev_active (ANHE_w (heap [k])) = k;
+      k = c;
+    }
+  heap [k] = he;
+  ev_active (ANHE_w (he)) = k;
+}
+#endif
 /* towards the root */
 void inline_speed
-upheap (WT *heap, int k)
+upheap (ANHE *heap, int k)
 {
-  WT w = heap [k];
+  ANHE he = heap [k];
   for (;;)
     {
-      int p = k >> 1;
+      int p = HPARENT (k);
-      /* maybe we could use a dummy element at heap [0]? */
+      if (UPHEAP_DONE (p, k) || ANHE_at (heap [p]) <= ANHE_at (he))
-      if (!p || heap [p]->at <= w->at)
         break;
       heap [k] = heap [p];
-      ev_active (heap [k]) = k;
+      ev_active (ANHE_w (heap [k])) = k;
       k = p;
     }
-  heap [k] = w;
+  heap [k] = he;
-  ev_active (heap [k]) = k;
+  ev_active (ANHE_w (he)) = k;
-}
-/* away from the root */
-void inline_speed
-downheap (WT *heap, int N, int k)
-{
-  WT w = heap [k];
-  for (;;)
-    {
-      int c = k << 1;
-      if (c > N)
-        break;
-      c += c < N && heap [c]->at > heap [c + 1]->at
-           ? 1 : 0;
-      if (w->at <= heap [c]->at)
-        break;
-      heap [k] = heap [c];
-      ev_active (heap [k]) = k;
-      k = c;
-    }
-  heap [k] = w;
-  ev_active (heap [k]) = k;
 }
 void inline_size
-adjustheap (WT *heap, int N, int k)
+adjustheap (ANHE *heap, int N, int k)
 {
+  if (k > HEAP0 && ANHE_at (heap [HPARENT (k)]) >= ANHE_at (heap [k]))
-  upheap (heap, k);
+    upheap (heap, k);
+  else
-  downheap (heap, N, k);
+    downheap (heap, N, k);
 }
+/* rebuild the heap: this function is used only once and executed rarely */
+void inline_size
+reheap (ANHE *heap, int N)
+{
+  int i;
+  /* we don't use floyds algorithm, upheap is simpler and is more cache-efficient */
+  /* also, this is easy to implement and correct for both 2-heaps and 4-heaps */
+  for (i = 0; i < N; ++i)
+    upheap (heap, i + HEAP0);
+}
+#if EV_VERIFY
+static void
+checkheap (ANHE *heap, int N)
+{
+  int i;
+  for (i = HEAP0; i < N + HEAP0; ++i)
+    {
+      assert (("active index mismatch in heap", ev_active (ANHE_w (heap [i])) == i));
+      assert (("heap condition violated", i == HEAP0 || ANHE_at (heap [HPARENT (i)]) <= ANHE_at (heap [i])));
+      assert (("heap at cache mismatch", ANHE_at (heap [i]) == ev_at (ANHE_w (heap [i]))));
+    }
+}
+#endif
 /*****************************************************************************/
 typedef struct
 {
 ev_loop_fork (EV_P)
 {
   postfork = 1; /* must be in line with ev_default_fork */
 }
+#if EV_VERIFY
+static void
+array_check (W **ws, int cnt)
+{
+  while (cnt--)
+    assert (("active index mismatch", ev_active (ws [cnt]) == cnt + 1));
+}
+static void
+ev_loop_verify (EV_P)
+{
+  int i;
+  checkheap (timers, timercnt);
+#if EV_PERIODIC_ENABLE
+  checkheap (periodics, periodiccnt);
+#endif
+#if EV_IDLE_ENABLE
+  for (i = NUMPRI; i--; )
+    array_check ((W **)idles [i], idlecnt [i]);
+#endif
+#if EV_FORK_ENABLE
+  array_check ((W **)forks, forkcnt);
+#endif
+  array_check ((W **)prepares, preparecnt);
+  array_check ((W **)checks, checkcnt);
+#if EV_ASYNC_ENABLE
+  array_check ((W **)asyncs, asynccnt);
+#endif
+}
+#endif
 #endif
 #if EV_MULTIPLICITY
 struct ev_loop *
 ev_default_loop_init (unsigned int flags)
 void inline_speed
 call_pending (EV_P)
 {
   int pri;
+  EV_FREQUENT_CHECK;
   for (pri = NUMPRI; pri--; )
     while (pendingcnt [pri])
       {
         ANPENDING *p = pendings [pri] + --pendingcnt [pri];
             p->w->pending = 0;
             EV_CB_INVOKE (p->w, p->events);
           }
       }
-}
-void inline_size
+  EV_FREQUENT_CHECK;
-timers_reify (EV_P)
-{
-  while (timercnt && ev_at (timers [1]) <= mn_now)
-    {
-      ev_timer *w = (ev_timer *)timers [1];
-      /*assert (("inactive timer on timer heap detected", ev_is_active (w)));*/
-      /* first reschedule or stop timer */
-      if (w->repeat)
-        {
-          assert (("negative ev_timer repeat value found while processing timers", w->repeat > 0.));
-          ev_at (w) += w->repeat;
-          if (ev_at (w) < mn_now)
-            ev_at (w) = mn_now;
-          downheap (timers, timercnt, 1);
-        }
-      else
-        ev_timer_stop (EV_A_ w); /* nonrepeating: stop timer */
-      ev_feed_event (EV_A_ (W)w, EV_TIMEOUT);
-    }
 }
-#if EV_PERIODIC_ENABLE
-void inline_size
-periodics_reify (EV_P)
-{
-  while (periodiccnt && ev_at (periodics [1]) <= ev_rt_now)
-    {
-      ev_periodic *w = (ev_periodic *)periodics [1];
-      /*assert (("inactive timer on periodic heap detected", ev_is_active (w)));*/
-      /* first reschedule or stop timer */
-      if (w->reschedule_cb)
-        {
-          ev_at (w) = w->reschedule_cb (w, ev_rt_now + TIME_EPSILON);
-          assert (("ev_periodic reschedule callback returned time in the past", ev_at (w) > ev_rt_now));
-          downheap (periodics, periodiccnt, 1);
-        }
-      else if (w->interval)
-        {
-          ev_at (w) = w->offset + ceil ((ev_rt_now - w->offset) / w->interval) * w->interval;
-          if (ev_at (w) - ev_rt_now <= TIME_EPSILON) ev_at (w) += w->interval;
-          assert (("ev_periodic timeout in the past detected while processing timers, negative interval?", ev_at (w) > ev_rt_now));
-          downheap (periodics, periodiccnt, 1);
-        }
-      else
-        ev_periodic_stop (EV_A_ w); /* nonrepeating: stop timer */
-      ev_feed_event (EV_A_ (W)w, EV_PERIODIC);
-    }
-}
-static void noinline
-periodics_reschedule (EV_P)
-{
-  int i;
-  /* adjust periodics after time jump */
-  for (i = 1; i <= periodiccnt; ++i)
-    {
-      ev_periodic *w = (ev_periodic *)periodics [i];
-      if (w->reschedule_cb)
-        ev_at (w) = w->reschedule_cb (w, ev_rt_now);
-      else if (w->interval)
-        ev_at (w) = w->offset + ceil ((ev_rt_now - w->offset) / w->interval) * w->interval;
-    }
-  /* now rebuild the heap */
-  for (i = periodiccnt >> 1; i--; )
-    downheap (periodics, periodiccnt, i);
-}
-#endif
 #if EV_IDLE_ENABLE
 void inline_size
 idle_reify (EV_P)
 {
               queue_events (EV_A_ (W *)idles [pri], idlecnt [pri], EV_IDLE);
               break;
             }
         }
     }
+}
+#endif
+void inline_size
+timers_reify (EV_P)
+{
+  EV_FREQUENT_CHECK;
+  while (timercnt && ANHE_at (timers [HEAP0]) < mn_now)
+    {
+      ev_timer *w = (ev_timer *)ANHE_w (timers [HEAP0]);
+      /*assert (("inactive timer on timer heap detected", ev_is_active (w)));*/
+      /* first reschedule or stop timer */
+      if (w->repeat)
+        {
+          ev_at (w) += w->repeat;
+          if (ev_at (w) < mn_now)
+            ev_at (w) = mn_now;
+          assert (("negative ev_timer repeat value found while processing timers", w->repeat > 0.));
+          ANHE_at_cache (timers [HEAP0]);
+          downheap (timers, timercnt, HEAP0);
+        }
+      else
+        ev_timer_stop (EV_A_ w); /* nonrepeating: stop timer */
+      EV_FREQUENT_CHECK;
+      ev_feed_event (EV_A_ (W)w, EV_TIMEOUT);
+    }
+}
+#if EV_PERIODIC_ENABLE
+void inline_size
+periodics_reify (EV_P)
+{
+  EV_FREQUENT_CHECK;
+  while (periodiccnt && ANHE_at (periodics [HEAP0]) < ev_rt_now)
+    {
+      ev_periodic *w = (ev_periodic *)ANHE_w (periodics [HEAP0]);
+      /*assert (("inactive timer on periodic heap detected", ev_is_active (w)));*/
+      /* first reschedule or stop timer */
+      if (w->reschedule_cb)
+        {
+          ev_at (w) = w->reschedule_cb (w, ev_rt_now);
+          assert (("ev_periodic reschedule callback returned time in the past", ev_at (w) >= ev_rt_now));
+          ANHE_at_cache (periodics [HEAP0]);
+          downheap (periodics, periodiccnt, HEAP0);
+          EV_FREQUENT_CHECK;
+        }
+      else if (w->interval)
+        {
+          ev_at (w) = w->offset + ceil ((ev_rt_now - w->offset) / w->interval) * w->interval;
+          /* if next trigger time is not sufficiently in the future, put it there */
+          /* this might happen because of floating point inexactness */
+          if (ev_at (w) - ev_rt_now < TIME_EPSILON)
+            {
+              ev_at (w) += w->interval;
+              /* if interval is unreasonably low we might still have a time in the past */
+              /* so correct this. this will make the periodic very inexact, but the user */
+              /* has effectively asked to get triggered more often than possible */
+              if (ev_at (w) < ev_rt_now)
+                ev_at (w) = ev_rt_now;
+            }
+          ANHE_at_cache (periodics [HEAP0]);
+          downheap (periodics, periodiccnt, HEAP0);
+        }
+      else
+        ev_periodic_stop (EV_A_ w); /* nonrepeating: stop timer */
+      EV_FREQUENT_CHECK;
+      ev_feed_event (EV_A_ (W)w, EV_PERIODIC);
+    }
+}
+static void noinline
+periodics_reschedule (EV_P)
+{
+  int i;
+  /* adjust periodics after time jump */
+  for (i = HEAP0; i < periodiccnt + HEAP0; ++i)
+    {
+      ev_periodic *w = (ev_periodic *)ANHE_w (periodics [i]);
+      if (w->reschedule_cb)
+        ev_at (w) = w->reschedule_cb (w, ev_rt_now);
+      else if (w->interval)
+        ev_at (w) = w->offset + ceil ((ev_rt_now - w->offset) / w->interval) * w->interval;
+      ANHE_at_cache (periodics [i]);
+    }
+  reheap (periodics, periodiccnt);
 }
 #endif
 void inline_speed
 time_update (EV_P_ ev_tstamp max_block)
        */
       for (i = 4; --i; )
         {
           rtmn_diff = ev_rt_now - mn_now;
-          if (fabs (odiff - rtmn_diff) < MIN_TIMEJUMP)
+          if (expect_true (fabs (odiff - rtmn_diff) < MIN_TIMEJUMP))
             return; /* all is well */
           ev_rt_now = ev_time ();
           mn_now    = get_clock ();
           now_floor = mn_now;
         {
 #if EV_PERIODIC_ENABLE
           periodics_reschedule (EV_A);
 #endif
           /* adjust timers. this is easy, as the offset is the same for all of them */
-          for (i = 1; i <= timercnt; ++i)
+          for (i = 0; i < timercnt; ++i)
-            ev_at (timers [i]) += ev_rt_now - mn_now;
+            {
+              ANHE *he = timers + i + HEAP0;
+              ANHE_w (*he)->at += ev_rt_now - mn_now;
+              ANHE_at_cache (*he);
+            }
         }
       mn_now = ev_rt_now;
     }
 }
             waittime = MAX_BLOCKTIME;
             if (timercnt)
               {
-                ev_tstamp to = ev_at (timers [1]) - mn_now + backend_fudge;
+                ev_tstamp to = ANHE_at (timers [HEAP0]) - mn_now + backend_fudge;
                 if (waittime > to) waittime = to;
               }
 #if EV_PERIODIC_ENABLE
             if (periodiccnt)
               {
-                ev_tstamp to = ev_at (periodics [1]) - ev_rt_now + backend_fudge;
+                ev_tstamp to = ANHE_at (periodics [HEAP0]) - ev_rt_now + backend_fudge;
                 if (waittime > to) waittime = to;
               }
 #endif
             if (expect_false (waittime < timeout_blocktime))
   if (expect_false (ev_is_active (w)))
     return;
   assert (("ev_io_start called with negative fd", fd >= 0));
+  EV_FREQUENT_CHECK;
   ev_start (EV_A_ (W)w, 1);
   array_needsize (ANFD, anfds, anfdmax, fd + 1, anfds_init);
   wlist_add (&anfds[fd].head, (WL)w);
   fd_change (EV_A_ fd, w->events & EV_IOFDSET | 1);
   w->events &= ~EV_IOFDSET;
+  EV_FREQUENT_CHECK;
 }
 void noinline
 ev_io_stop (EV_P_ ev_io *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
-  assert (("ev_io_start called with illegal fd (must stay constant after start!)", w->fd >= 0 && w->fd < anfdmax));
+  assert (("ev_io_stop called with illegal fd (must stay constant after start!)", w->fd >= 0 && w->fd < anfdmax));
+  EV_FREQUENT_CHECK;
   wlist_del (&anfds[w->fd].head, (WL)w);
   ev_stop (EV_A_ (W)w);
   fd_change (EV_A_ w->fd, 1);
+  EV_FREQUENT_CHECK;
 }
 void noinline
 ev_timer_start (EV_P_ ev_timer *w)
 {
   ev_at (w) += mn_now;
   assert (("ev_timer_start called with negative timer repeat value", w->repeat >= 0.));
+  EV_FREQUENT_CHECK;
+  ++timercnt;
-  ev_start (EV_A_ (W)w, ++timercnt);
+  ev_start (EV_A_ (W)w, timercnt + HEAP0 - 1);
-  array_needsize (WT, timers, timermax, timercnt + 1, EMPTY2);
+  array_needsize (ANHE, timers, timermax, ev_active (w) + 1, EMPTY2);
-  timers [timercnt] = (WT)w;
+  ANHE_w (timers [ev_active (w)]) = (WT)w;
+  ANHE_at_cache (timers [ev_active (w)]);
-  upheap (timers, timercnt);
+  upheap (timers, ev_active (w));
+  EV_FREQUENT_CHECK;
-  /*assert (("internal timer heap corruption", timers [ev_active (w)] == w));*/
+  /*assert (("internal timer heap corruption", timers [ev_active (w)] == (WT)w));*/
 }
 void noinline
 ev_timer_stop (EV_P_ ev_timer *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   {
     int active = ev_active (w);
-    assert (("internal timer heap corruption", timers [active] == (WT)w));
+    assert (("internal timer heap corruption", ANHE_w (timers [active]) == (WT)w));
+    --timercnt;
-    if (expect_true (active < timercnt))
+    if (expect_true (active < timercnt + HEAP0))
       {
-        timers [active] = timers [timercnt];
+        timers [active] = timers [timercnt + HEAP0];
         adjustheap (timers, timercnt, active);
       }
-    --timercnt;
   }
+  EV_FREQUENT_CHECK;
   ev_at (w) -= mn_now;
   ev_stop (EV_A_ (W)w);
 }
 void noinline
 ev_timer_again (EV_P_ ev_timer *w)
 {
+  EV_FREQUENT_CHECK;
   if (ev_is_active (w))
     {
       if (w->repeat)
         {
           ev_at (w) = mn_now + w->repeat;
+          ANHE_at_cache (timers [ev_active (w)]);
           adjustheap (timers, timercnt, ev_active (w));
         }
       else
         ev_timer_stop (EV_A_ w);
     }
   else if (w->repeat)
     {
       ev_at (w) = w->repeat;
       ev_timer_start (EV_A_ w);
     }
+  EV_FREQUENT_CHECK;
 }
 #if EV_PERIODIC_ENABLE
 void noinline
 ev_periodic_start (EV_P_ ev_periodic *w)
       ev_at (w) = w->offset + ceil ((ev_rt_now - w->offset) / w->interval) * w->interval;
     }
   else
     ev_at (w) = w->offset;
+  EV_FREQUENT_CHECK;
+  ++periodiccnt;
-  ev_start (EV_A_ (W)w, ++periodiccnt);
+  ev_start (EV_A_ (W)w, periodiccnt + HEAP0 - 1);
-  array_needsize (WT, periodics, periodicmax, periodiccnt + 1, EMPTY2);
+  array_needsize (ANHE, periodics, periodicmax, ev_active (w) + 1, EMPTY2);
-  periodics [periodiccnt] = (WT)w;
+  ANHE_w (periodics [ev_active (w)]) = (WT)w;
-  upheap (periodics, periodiccnt);
+  ANHE_at_cache (periodics [ev_active (w)]);
+  upheap (periodics, ev_active (w));
+  EV_FREQUENT_CHECK;
-  /*assert (("internal periodic heap corruption", periodics [ev_active (w)] == w));*/
+  /*assert (("internal periodic heap corruption", ANHE_w (periodics [ev_active (w)]) == (WT)w));*/
 }
 void noinline
 ev_periodic_stop (EV_P_ ev_periodic *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   {
     int active = ev_active (w);
-    assert (("internal periodic heap corruption", periodics [active] == (WT)w));
+    assert (("internal periodic heap corruption", ANHE_w (periodics [active]) == (WT)w));
+    --periodiccnt;
-    if (expect_true (active < periodiccnt))
+    if (expect_true (active < periodiccnt + HEAP0))
       {
-        periodics [active] = periodics [periodiccnt];
+        periodics [active] = periodics [periodiccnt + HEAP0];
         adjustheap (periodics, periodiccnt, active);
       }
-    --periodiccnt;
   }
+  EV_FREQUENT_CHECK;
   ev_stop (EV_A_ (W)w);
 }
 void noinline
     return;
   assert (("ev_signal_start called with illegal signal number", w->signum > 0));
   evpipe_init (EV_A);
+  EV_FREQUENT_CHECK;
   {
 #ifndef _WIN32
     sigset_t full, prev;
     sigfillset (&full);
       sigfillset (&sa.sa_mask);
       sa.sa_flags = SA_RESTART; /* if restarting works we save one iteration */
       sigaction (w->signum, &sa, 0);
 #endif
     }
+  EV_FREQUENT_CHECK;
 }
 void noinline
 ev_signal_stop (EV_P_ ev_signal *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   wlist_del (&signals [w->signum - 1].head, (WL)w);
   ev_stop (EV_A_ (W)w);
   if (!signals [w->signum - 1].head)
     signal (w->signum, SIG_DFL);
+  EV_FREQUENT_CHECK;
 }
 void
 ev_child_start (EV_P_ ev_child *w)
 {
   assert (("child watchers are only supported in the default loop", loop == ev_default_loop_ptr));
 #endif
   if (expect_false (ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   ev_start (EV_A_ (W)w, 1);
   wlist_add (&childs [w->pid & (EV_PID_HASHSIZE - 1)], (WL)w);
+  EV_FREQUENT_CHECK;
 }
 void
 ev_child_stop (EV_P_ ev_child *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   wlist_del (&childs [w->pid & (EV_PID_HASHSIZE - 1)], (WL)w);
   ev_stop (EV_A_ (W)w);
+  EV_FREQUENT_CHECK;
 }
 #if EV_STAT_ENABLE
 # ifdef _WIN32
   else
 #endif
     ev_timer_start (EV_A_ &w->timer);
   ev_start (EV_A_ (W)w, 1);
+  EV_FREQUENT_CHECK;
 }
 void
 ev_stat_stop (EV_P_ ev_stat *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
 #if EV_USE_INOTIFY
   infy_del (EV_A_ w);
 #endif
   ev_timer_stop (EV_A_ &w->timer);
   ev_stop (EV_A_ (W)w);
+  EV_FREQUENT_CHECK;
 }
 #endif
 #if EV_IDLE_ENABLE
 void
 {
   if (expect_false (ev_is_active (w)))
     return;
   pri_adjust (EV_A_ (W)w);
+  EV_FREQUENT_CHECK;
   {
     int active = ++idlecnt [ABSPRI (w)];
     ++idleall;
     ev_start (EV_A_ (W)w, active);
     array_needsize (ev_idle *, idles [ABSPRI (w)], idlemax [ABSPRI (w)], active, EMPTY2);
     idles [ABSPRI (w)][active - 1] = w;
   }
+  EV_FREQUENT_CHECK;
 }
 void
 ev_idle_stop (EV_P_ ev_idle *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   {
     int active = ev_active (w);
     idles [ABSPRI (w)][active - 1] = idles [ABSPRI (w)][--idlecnt [ABSPRI (w)]];
     ev_active (idles [ABSPRI (w)][active - 1]) = active;
     ev_stop (EV_A_ (W)w);
     --idleall;
   }
+  EV_FREQUENT_CHECK;
 }
 #endif
 void
 ev_prepare_start (EV_P_ ev_prepare *w)
 {
   if (expect_false (ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   ev_start (EV_A_ (W)w, ++preparecnt);
   array_needsize (ev_prepare *, prepares, preparemax, preparecnt, EMPTY2);
   prepares [preparecnt - 1] = w;
+  EV_FREQUENT_CHECK;
 }
 void
 ev_prepare_stop (EV_P_ ev_prepare *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   {
     int active = ev_active (w);
     prepares [active - 1] = prepares [--preparecnt];
     ev_active (prepares [active - 1]) = active;
   }
   ev_stop (EV_A_ (W)w);
+  EV_FREQUENT_CHECK;
 }
 void
 ev_check_start (EV_P_ ev_check *w)
 {
   if (expect_false (ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   ev_start (EV_A_ (W)w, ++checkcnt);
   array_needsize (ev_check *, checks, checkmax, checkcnt, EMPTY2);
   checks [checkcnt - 1] = w;
+  EV_FREQUENT_CHECK;
 }
 void
 ev_check_stop (EV_P_ ev_check *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   {
     int active = ev_active (w);
     checks [active - 1] = checks [--checkcnt];
     ev_active (checks [active - 1]) = active;
   }
   ev_stop (EV_A_ (W)w);
+  EV_FREQUENT_CHECK;
 }
 #if EV_EMBED_ENABLE
 void noinline
 ev_embed_sweep (EV_P_ ev_embed *w)
     struct ev_loop *loop = w->other;
     assert (("loop to be embedded is not embeddable", backend & ev_embeddable_backends ()));
     ev_io_init (&w->io, embed_io_cb, backend_fd, EV_READ);
   }
+  EV_FREQUENT_CHECK;
   ev_set_priority (&w->io, ev_priority (w));
   ev_io_start (EV_A_ &w->io);
   ev_prepare_init (&w->prepare, embed_prepare_cb);
   ev_set_priority (&w->prepare, EV_MINPRI);
   ev_prepare_start (EV_A_ &w->prepare);
   /*ev_idle_init (&w->idle, e,bed_idle_cb);*/
   ev_start (EV_A_ (W)w, 1);
+  EV_FREQUENT_CHECK;
 }
 void
 ev_embed_stop (EV_P_ ev_embed *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   ev_io_stop (EV_A_ &w->io);
   ev_prepare_stop (EV_A_ &w->prepare);
   ev_stop (EV_A_ (W)w);
+  EV_FREQUENT_CHECK;
 }
 #endif
 #if EV_FORK_ENABLE
 void
 ev_fork_start (EV_P_ ev_fork *w)
 {
   if (expect_false (ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   ev_start (EV_A_ (W)w, ++forkcnt);
   array_needsize (ev_fork *, forks, forkmax, forkcnt, EMPTY2);
   forks [forkcnt - 1] = w;
+  EV_FREQUENT_CHECK;
 }
 void
 ev_fork_stop (EV_P_ ev_fork *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   {
     int active = ev_active (w);
     forks [active - 1] = forks [--forkcnt];
     ev_active (forks [active - 1]) = active;
   }
   ev_stop (EV_A_ (W)w);
+  EV_FREQUENT_CHECK;
 }
 #endif
 #if EV_ASYNC_ENABLE
 void
 {
   if (expect_false (ev_is_active (w)))
     return;
   evpipe_init (EV_A);
+  EV_FREQUENT_CHECK;
   ev_start (EV_A_ (W)w, ++asynccnt);
   array_needsize (ev_async *, asyncs, asyncmax, asynccnt, EMPTY2);
   asyncs [asynccnt - 1] = w;
+  EV_FREQUENT_CHECK;
 }
 void
 ev_async_stop (EV_P_ ev_async *w)
 {
   clear_pending (EV_A_ (W)w);
   if (expect_false (!ev_is_active (w)))
     return;
+  EV_FREQUENT_CHECK;
   {
     int active = ev_active (w);
     asyncs [active - 1] = asyncs [--asynccnt];
     ev_active (asyncs [active - 1]) = active;
   }
   ev_stop (EV_A_ (W)w);
+  EV_FREQUENT_CHECK;
 }
 void
 ev_async_send (EV_P_ ev_async *w)
 {

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Comparing libev/ev.c (file contents): Revision 1.233 by root, Tue May 6 23:34:16 2008 UTC vs. Revision 1.249 by root, Wed May 21 23:30:52 2008 UTC

Diff Legend

Comparing libev/ev.c (file contents):
Revision 1.233 by root, Tue May 6 23:34:16 2008 UTC vs.
Revision 1.249 by root, Wed May 21 23:30:52 2008 UTC