/* * Copyright (C) 1996-2018 The Squid Software Foundation and contributors * * Squid software is distributed under GPLv2+ license and includes * contributions from numerous individuals and organizations. * Please see the COPYING and CONTRIBUTORS files for details. */ /* DEBUG: section 41 Event Processing */ #include "squid.h" #include "compat/drand48.h" #include "event.h" #include "mgr/Registration.h" #include "profiler/Profiler.h" #include "SquidTime.h" #include "Store.h" #include "tools.h" #include /* The list of event processes */ static OBJH eventDump; static const char *last_event_ran = NULL; // This AsyncCall dialer can be configured to check that the event cbdata is // valid before calling the event handler class EventDialer: public CallDialer { public: typedef CallDialer Parent; EventDialer(EVH *aHandler, void *anArg, bool lockedArg); EventDialer(const EventDialer &d); virtual ~EventDialer(); virtual void print(std::ostream &os) const; virtual bool canDial(AsyncCall &call); void dial(AsyncCall &) { theHandler(theArg); } private: EVH *theHandler; void *theArg; bool isLockedArg; }; EventDialer::EventDialer(EVH *aHandler, void *anArg, bool lockedArg): theHandler(aHandler), theArg(anArg), isLockedArg(lockedArg) { if (isLockedArg) (void)cbdataReference(theArg); } EventDialer::EventDialer(const EventDialer &d): theHandler(d.theHandler), theArg(d.theArg), isLockedArg(d.isLockedArg) { if (isLockedArg) (void)cbdataReference(theArg); } EventDialer::~EventDialer() { if (isLockedArg) cbdataReferenceDone(theArg); } bool EventDialer::canDial(AsyncCall &call) { // TODO: add Parent::canDial() that always returns true //if (!Parent::canDial()) // return false; if (isLockedArg && !cbdataReferenceValid(theArg)) return call.cancel("stale handler data"); return true; } void EventDialer::print(std::ostream &os) const { os << '('; if (theArg) os << theArg << (isLockedArg ? "*?" : ""); os << ')'; } ev_entry::ev_entry(char const * aName, EVH * aFunction, void * aArgument, double evWhen, int aWeight, bool haveArgument) : name(aName), func(aFunction), arg(haveArgument ? cbdataReference(aArgument) : aArgument), when(evWhen), weight(aWeight), cbdata(haveArgument) { } ev_entry::~ev_entry() { if (cbdata) cbdataReferenceDone(arg); } void eventAdd(const char *name, EVH * func, void *arg, double when, int weight, bool cbdata) { EventScheduler::GetInstance()->schedule(name, func, arg, when, weight, cbdata); } /* same as eventAdd but adds a random offset within +-1/3 of delta_ish */ void eventAddIsh(const char *name, EVH * func, void *arg, double delta_ish, int weight) { if (delta_ish >= 3.0) { const double two_third = (2.0 * delta_ish) / 3.0; delta_ish = two_third + (drand48() * two_third); /* * I'm sure drand48() isn't portable. Tell me what function * you have that returns a random double value in the range 0,1. */ } eventAdd(name, func, arg, delta_ish, weight); } void eventDelete(EVH * func, void *arg) { EventScheduler::GetInstance()->cancel(func, arg); } void eventInit(void) { Mgr::RegisterAction("events", "Event Queue", eventDump, 0, 1); } static void eventDump(StoreEntry * sentry) { EventScheduler::GetInstance()->dump(sentry); } void eventFreeMemory(void) { EventScheduler::GetInstance()->clean(); } int eventFind(EVH * func, void *arg) { return EventScheduler::GetInstance()->find(func, arg); } EventScheduler EventScheduler::_instance; EventScheduler::EventScheduler(): tasks(NULL) {} EventScheduler::~EventScheduler() { clean(); } void EventScheduler::cancel(EVH * func, void *arg) { ev_entry **E; ev_entry *event; for (E = &tasks; (event = *E) != NULL; E = &(*E)->next) { if (event->func != func) continue; if (arg && event->arg != arg) continue; *E = event->next; delete event; if (arg) return; /* * DPW 2007-04-12 * Since this method may now delete multiple events (when * arg is NULL) it no longer returns after a deletion and * we have a potential NULL pointer problem. If we just * deleted the last event in the list then *E is now equal * to NULL. We need to break here or else we'll get a NULL * pointer dereference in the last clause of the for loop. */ if (NULL == *E) break; } if (arg) debug_trap("eventDelete: event not found"); } // The event API does not guarantee exact timing, but guarantees that no event // is fired before it is due. We may delay firing, but never fire too early. int EventScheduler::timeRemaining() const { if (!tasks) return EVENT_IDLE; if (tasks->when <= current_dtime) // we are on time or late return 0; // fire the event ASAP const double diff = tasks->when - current_dtime; // microseconds // Round UP: If we come back a nanosecond earlier, we will wait again! const int timeLeft = static_cast(ceil(1000*diff)); // milliseconds // Avoid hot idle: A series of rapid select() calls with zero timeout. const int minDelay = 1; // millisecond return max(minDelay, timeLeft); } int EventScheduler::checkEvents(int timeout) { int result = timeRemaining(); if (result != 0) return result; PROF_start(eventRun); do { ev_entry *event = tasks; assert(event); /* XXX assumes event->name is static memory! */ AsyncCall::Pointer call = asyncCall(41,5, event->name, EventDialer(event->func, event->arg, event->cbdata)); ScheduleCallHere(call); last_event_ran = event->name; // XXX: move this to AsyncCallQueue const bool heavy = event->weight && (!event->cbdata || cbdataReferenceValid(event->arg)); tasks = event->next; delete event; result = timeRemaining(); // XXX: We may be called again during the same event loop iteration. // Is there a point in breaking now? if (heavy) break; // do not dequeue events following a heavy event } while (result == 0); PROF_stop(eventRun); return result; } void EventScheduler::clean() { while (ev_entry * event = tasks) { tasks = event->next; delete event; } tasks = NULL; } void EventScheduler::dump(StoreEntry * sentry) { ev_entry *e = tasks; if (last_event_ran) storeAppendPrintf(sentry, "Last event to run: %s\n\n", last_event_ran); storeAppendPrintf(sentry, "%-25s\t%-15s\t%s\t%s\n", "Operation", "Next Execution", "Weight", "Callback Valid?"); while (e != NULL) { storeAppendPrintf(sentry, "%-25s\t%0.3f sec\t%5d\t %s\n", e->name, e->when ? e->when - current_dtime : 0, e->weight, (e->arg && e->cbdata) ? cbdataReferenceValid(e->arg) ? "yes" : "no" : "N/A"); e = e->next; } } bool EventScheduler::find(EVH * func, void * arg) { ev_entry *event; for (event = tasks; event != NULL; event = event->next) { if (event->func == func && event->arg == arg) return true; } return false; } EventScheduler * EventScheduler::GetInstance() { return &_instance; } void EventScheduler::schedule(const char *name, EVH * func, void *arg, double when, int weight, bool cbdata) { // Use zero timestamp for when=0 events: Many of them are async calls that // must fire in the submission order. We cannot use current_dtime for them // because it may decrease if system clock is adjusted backwards. const double timestamp = when > 0.0 ? current_dtime + when : 0; ev_entry *event = new ev_entry(name, func, arg, timestamp, weight, cbdata); ev_entry **E; debugs(41, 7, HERE << "schedule: Adding '" << name << "', in " << when << " seconds"); /* Insert after the last event with the same or earlier time */ for (E = &tasks; *E; E = &(*E)->next) { if ((*E)->when > event->when) break; } event->next = *E; *E = event; }