// Copyright (c) 2011 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef NET_TOOLS_FLIP_SERVER_EPOLL_SERVER_H_ #define NET_TOOLS_FLIP_SERVER_EPOLL_SERVER_H_ #include #include #include // it is annoying that gcc does this. oh well. #include #include #include #include #include #include // #define EPOLL_SERVER_EVENT_TRACING 1 // // Defining EPOLL_SERVER_EVENT_TRACING // causes code to exist which didn't before. // This code tracks each event generated by the epollserver, // as well as providing a per-fd-registered summary of // events. Note that enabling this code vastly slows // down operations, and uses substantially more // memory. For these reasons, it should only be enabled when doing // developer debugging at his/her workstation. // // A structure called 'EventRecorder' will exist when // the macro is defined. See the EventRecorder class interface // within the EpollServer class for more details. #ifdef EPOLL_SERVER_EVENT_TRACING #include #include "base/logging.h" #endif #include "base/basictypes.h" #include "base/compiler_specific.h" #include "base/memory/scoped_ptr.h" #include namespace net { class EpollServer; class EpollAlarmCallbackInterface; class ReadPipeCallback; struct EpollEvent { EpollEvent(int events, bool is_epoll_wait) : in_events(events), out_ready_mask(0) { } int in_events; // incoming events int out_ready_mask; // the new event mask for ready list (0 means don't // get on the ready list). This field is always // initialized to 0 when the event is passed to // OnEvent. }; // Callbacks which go into EpollServers are expected to derive from this class. class EpollCallbackInterface { public: // Summary: // Called when the callback is registered into a EpollServer. // Args: // eps - the poll server into which this callback was registered // fd - the file descriptor which was registered // event_mask - the event mask (composed of EPOLLIN, EPOLLOUT, etc) // which was registered (and will initially be used // in the epoll() calls) virtual void OnRegistration(EpollServer* eps, int fd, int event_mask) = 0; // Summary: // Called when the event_mask is modified (for a file-descriptor) // Args: // fd - the file descriptor which was registered // event_mask - the event mask (composed of EPOLLIN, EPOLLOUT, etc) // which was is now curren (and will be used // in subsequent epoll() calls) virtual void OnModification(int fd, int event_mask) = 0; // Summary: // Called whenever an event occurs on the file-descriptor. // This is where the bulk of processing is expected to occur. // Args: // fd - the file descriptor which was registered // event - a struct that contains the event mask (composed of EPOLLIN, // EPOLLOUT, etc), a flag that indicates whether this is a true // epoll_wait event vs one from the ready list, and an output // parameter for OnEvent to inform the EpollServer whether to put // this fd on the ready list. virtual void OnEvent(int fd, EpollEvent* event) = 0; // Summary: // Called when the file-descriptor is unregistered from the poll-server. // Args: // fd - the file descriptor which was registered, and of this call, is now // unregistered. // replaced - If true, this callback is being replaced by another, otherwise // it is simply being removed. virtual void OnUnregistration(int fd, bool replaced) = 0; // Summary: // Called when the epoll server is shutting down. This is different from // OnUnregistration because the subclass may want to clean up memory. // This is called in leiu of OnUnregistration. // Args: // fd - the file descriptor which was registered. virtual void OnShutdown(EpollServer* eps, int fd) = 0; virtual ~EpollCallbackInterface() {} protected: EpollCallbackInterface() {} }; //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// class EpollServer { public: typedef EpollAlarmCallbackInterface AlarmCB; typedef EpollCallbackInterface CB; typedef std::multimap TimeToAlarmCBMap; typedef TimeToAlarmCBMap::iterator AlarmRegToken; // Summary: // Constructor: // By default, we don't wait any amount of time for events, and // we suggest to the epoll-system that we're going to use on-the-order // of 1024 FDs. EpollServer(); //////////////////////////////////////// // Destructor virtual ~EpollServer(); //////////////////////////////////////// // Summary // Register a callback to be called whenever an event contained // in the set of events included in event_mask occurs on the // file-descriptor 'fd' // // Note that only one callback is allowed to be registered for // any specific file-decriptor. // // If a callback is registered for a file-descriptor which has already // been registered, then the previous callback is unregistered with // the 'replaced' flag set to true. I.e. the previous callback's // OnUnregistration() function is called like so: // OnUnregistration(fd, true); // // The epoll server does NOT take on ownership of the callback: the callback // creator is responsible for managing that memory. // // Args: // fd - a valid file-descriptor // cb - an instance of a subclass of EpollCallbackInterface // event_mask - a combination of (EPOLLOUT, EPOLLIN.. etc) indicating // the events for which the callback would like to be // called. virtual void RegisterFD(int fd, CB* cb, int event_mask); //////////////////////////////////////// // Summary: // A shortcut for RegisterFD which sets things up such that the // callback is called when 'fd' is available for writing. // Args: // fd - a valid file-descriptor // cb - an instance of a subclass of EpollCallbackInterface virtual void RegisterFDForWrite(int fd, CB* cb); //////////////////////////////////////// // Summary: // A shortcut for RegisterFD which sets things up such that the // callback is called when 'fd' is available for reading or writing. // Args: // fd - a valid file-descriptor // cb - an instance of a subclass of EpollCallbackInterface virtual void RegisterFDForReadWrite(int fd, CB* cb); //////////////////////////////////////// // Summary: // A shortcut for RegisterFD which sets things up such that the // callback is called when 'fd' is available for reading. // Args: // fd - a valid file-descriptor // cb - an instance of a subclass of EpollCallbackInterface virtual void RegisterFDForRead(int fd, CB* cb); //////////////////////////////////////// // Summary: // Removes the FD and the associated callback from the pollserver. // If the callback is registered with other FDs, they will continue // to be processed using the callback without modification. // If the file-descriptor specified is not registered in the // epoll_server, then nothing happens as a result of this call. // Args: // fd - the file-descriptor which should no-longer be monitored. virtual void UnregisterFD(int fd); //////////////////////////////////////// // Summary: // Modifies the event mask for the file-descriptor, replacing // the old event_mask with the new one specified here. // If the file-descriptor specified is not registered in the // epoll_server, then nothing happens as a result of this call. // Args: // fd - the fd whose event mask should be modified. // event_mask - the new event mask. virtual void ModifyCallback(int fd, int event_mask); //////////////////////////////////////// // Summary: // Modifies the event mask for the file-descriptor such that we // no longer request events when 'fd' is readable. // If the file-descriptor specified is not registered in the // epoll_server, then nothing happens as a result of this call. // Args: // fd - the fd whose event mask should be modified. virtual void StopRead(int fd); //////////////////////////////////////// // Summary: // Modifies the event mask for the file-descriptor such that we // request events when 'fd' is readable. // If the file-descriptor specified is not registered in the // epoll_server, then nothing happens as a result of this call. // Args: // fd - the fd whose event mask should be modified. virtual void StartRead(int fd); //////////////////////////////////////// // Summary: // Modifies the event mask for the file-descriptor such that we // no longer request events when 'fd' is writable. // If the file-descriptor specified is not registered in the // epoll_server, then nothing happens as a result of this call. // Args: // fd - the fd whose event mask should be modified. virtual void StopWrite(int fd); //////////////////////////////////////// // Summary: // Modifies the event mask for the file-descriptor such that we // request events when 'fd' is writable. // If the file-descriptor specified is not registered in the // epoll_server, then nothing happens as a result of this call. // Args: // fd - the fd whose event mask should be modified. virtual void StartWrite(int fd); //////////////////////////////////////// // Summary: // Looks up the callback associated with the file-desriptor 'fd'. // If a callback is associated with this file-descriptor, then // it's OnEvent() method is called with the file-descriptor 'fd', // and event_mask 'event_mask' // // If no callback is registered for this file-descriptor, nothing // will happen as a result of this call. // // This function is used internally by the EpollServer, but is // available publically so that events might be 'faked'. Calling // this function with an fd and event_mask is equivalent (as far // as the callback is concerned) to having a real event generated // by epoll (except, of course, that read(), etc won't necessarily // be able to read anything) // Args: // fd - the file-descriptor on which an event has occured. // event_mask - a bitmask representing the events which have occured // on/for this fd. This bitmask is composed of // POLLIN, POLLOUT, etc. // void HandleEvent(int fd, int event_mask); // Summary: // Call this when you want the pollserver to // wait for events and execute the callbacks associated with // the file-descriptors on which those events have occured. // Depending on the value of timeout_in_us_, this may or may // not return immediately. Please reference the set_timeout() // function for the specific behaviour. virtual void WaitForEventsAndExecuteCallbacks(); // Summary: // When an fd is registered to use edge trigger notification, the ready // list can be used to simulate level trigger semantics. Edge trigger // registration doesn't send an initial event, and only rising edge (going // from blocked to unblocked) events are sent. A callback can put itself on // the ready list by calling SetFDReady() after calling RegisterFD(). The // OnEvent method of all callbacks associated with the fds on the ready // list will be called immediately after processing the events returned by // epoll_wait(). The fd is removed from the ready list before the // callback's OnEvent() method is invoked. To stay on the ready list, the // OnEvent() (or some function in that call chain) must call SetFDReady // again. When a fd is unregistered using UnregisterFD(), the fd is // automatically removed from the ready list. // // When the callback for a edge triggered fd hits the falling edge (about // to block, either because of it got an EAGAIN, or had a short read/write // operation), it should remove itself from the ready list using // SetFDNotReady() (since OnEvent cannot distinguish between invocation // from the ready list vs from a normal epoll event). All four ready list // methods are safe to be called within the context of the callbacks. // // Since the ready list invokes EpollCallbackInterface::OnEvent, only fds // that are registered with the EpollServer will be put on the ready list. // SetFDReady() and SetFDNotReady() will do nothing if the EpollServer // doesn't know about the fd passed in. // // Since the ready list cannot reliably determine proper set of events // which should be sent to the callback, SetFDReady() requests the caller // to provide the ready list with the event mask, which will be used later // when OnEvent() is invoked by the ready list. Hence, the event_mask // passedto SetFDReady() does not affect the actual epoll registration of // the fd with the kernel. If a fd is already put on the ready list, and // SetFDReady() is called again for that fd with a different event_mask, // the event_mask will be updated. virtual void SetFDReady(int fd, int events_to_fake); virtual void SetFDNotReady(int fd); // Summary: // IsFDReady(), ReadyListSize(), and VerifyReadyList are intended as // debugging tools and for writing unit tests. // ISFDReady() returns whether a fd is in the ready list. // ReadyListSize() returns the number of fds on the ready list. // VerifyReadyList() checks the consistency of internal data structure. It // will CHECK if it finds an error. virtual bool IsFDReady(int fd) const; size_t ReadyListSize() const { return ready_list_size_; } void VerifyReadyList() const; //////////////////////////////////////// // Summary: // Registers an alarm 'ac' to go off at time 'timeout_time_in_us'. // If the callback returns a positive number from its OnAlarm() function, // then the callback will be re-registered at that time, else the alarm // owner is responsible for freeing up memory. // // Important: A give AlarmCB* can not be registered again if it is already // registered. If a user wants to register a callback again it should first // unregister the previous callback before calling RegisterAlarm again. // Args: // timeout_time_in_us - the absolute time at which the alarm should go off // ac - the alarm which will be called. virtual void RegisterAlarm(int64 timeout_time_in_us, AlarmCB* ac); // Summary: // Registers an alarm 'ac' to go off at time: (ApproximateNowInUs() + // delta_in_us). While this is somewhat less accurate (see the description // for ApproximateNowInUs() to see how 'approximate'), the error is never // worse than the amount of time it takes to process all events in one // WaitForEvents. As with 'RegisterAlarm()', if the callback returns a // positive number from its OnAlarm() function, then the callback will be // re-registered at that time, else the alarm owner is responsible for // freeing up memory. // Note that this function is purely a convienence. The // same thing may be accomplished by using RegisterAlarm with // ApproximateNowInUs() directly. // // Important: A give AlarmCB* can not be registered again if it is already // registered. If a user wants to register a callback again it should first // unregister the previous callback before calling RegisterAlarm again. // Args: // delta_in_us - the delta in microseconds from the ApproximateTimeInUs() at // which point the alarm should go off. // ac - the alarm which will be called. void RegisterAlarmApproximateDelta(int64 delta_in_us, AlarmCB* ac) { RegisterAlarm(ApproximateNowInUsec() + delta_in_us, ac); } //////////////////////////////////////// // Summary: // Unregister the alarm referred to by iterator_token; Callers should // be warned that a token may have become already invalid when OnAlarm() // is called, was unregistered, or OnShutdown was called on that alarm. // Args: // iterator_token - iterator to the alarm callback to unregister. virtual void UnregisterAlarm( const EpollServer::AlarmRegToken& iterator_token); //////////////////////////////////////// // Summary: // returns the number of file-descriptors registered in this EpollServer. // Returns: // number of FDs registered (discounting the internal pipe used for Wake) virtual int NumFDsRegistered() const; // Summary: // Force the epoll server to wake up (by writing to an internal pipe). virtual void Wake(); // Summary: // Wrapper around WallTimer's NowInUsec. We do this so that we can test // EpollServer without using the system clock (and can avoid the flakiness // that would ensue) // Returns: // the current time as number of microseconds since the Unix epoch. virtual int64 NowInUsec() const; // Summary: // Since calling NowInUsec() many thousands of times per // WaitForEventsAndExecuteCallbacks function call is, to say the least, // inefficient, we allow users to use an approximate time instead. The // time returned from this function is as accurate as NowInUsec() when // WaitForEventsAndExecuteCallbacks is not an ancestor of the caller's // callstack. // However, when WaitForEventsAndExecuteCallbacks -is- an ancestor, then // this function returns the time at which the // WaitForEventsAndExecuteCallbacks function started to process events or // alarms. // // Essentially, this function makes available a fast and mostly accurate // mechanism for getting the time for any function handling an event or // alarm. When functions which are not handling callbacks or alarms call // this function, they get the slow and "absolutely" accurate time. // // Users should be encouraged to use this function. // Returns: // the "approximate" current time as number of microseconds since the Unix // epoch. virtual int64 ApproximateNowInUsec() const; static std::string EventMaskToString(int event_mask); // Summary: // Logs the state of the epoll server with LOG(ERROR). void LogStateOnCrash(); // Summary: // Set the timeout to the value specified. // If the timeout is set to a negative number, // WaitForEventsAndExecuteCallbacks() will only return when an event has // occured // If the timeout is set to zero, // WaitForEventsAndExecuteCallbacks() will return immediately // If the timeout is set to a positive number, // WaitForEventsAndExecuteCallbacks() will return when an event has // occured, or when timeout_in_us microseconds has elapsed, whichever // is first. // Args: // timeout_in_us - value specified depending on behaviour desired. // See above. void set_timeout_in_us(int64 timeout_in_us) { timeout_in_us_ = timeout_in_us; } //////////////////////////////////////// // Summary: // Accessor for the current value of timeout_in_us. int timeout_in_us() const { return timeout_in_us_; } // Summary: // Returns true when the EpollServer() is being destroyed. bool in_shutdown() const { return in_shutdown_; } bool ContainsAlarm(EpollAlarmCallbackInterface* alarm) const { return all_alarms_.find(alarm) != all_alarms_.end(); } // Summary: // A function for implementing the ready list. It invokes OnEvent for each // of the fd in the ready list, and takes care of adding them back to the // ready list if the callback requests it (by checking that out_ready_mask // is non-zero). void CallReadyListCallbacks(); // Granularity at which time moves when considering what alarms are on. // See function: DoRoundingOnNow() on exact usage. static const int kMinimumEffectiveAlarmQuantum; protected: virtual int GetFlags(int fd); inline int SetFlags(int fd, int flags) { return fcntl(fd, F_SETFL, flags | O_NONBLOCK); } virtual void SetNonblocking(int fd); // This exists here so that we can override this function in unittests // in order to make effective mock EpollServer objects. virtual int epoll_wait_impl(int epfd, struct epoll_event* events, int max_events, int timeout_in_ms); // this struct is used internally, and is never used by anything external // to this class. Some of its members are declared mutable to get around the // restriction imposed by hash_set. Since hash_set knows nothing about the // objects it stores, it has to assume that every bit of the object is used // in the hash function and equal_to comparison. Thus hash_set::iterator is a // const iterator. In this case, the only thing that must stay constant is // fd. Everything else are just along for the ride and changing them doesn't // compromise the hash_set integrity. struct CBAndEventMask { CBAndEventMask() : cb(NULL), fd(-1), event_mask(0), events_asserted(0), events_to_fake(0), in_use(false) { entry.le_next = NULL; entry.le_prev = NULL; } CBAndEventMask(EpollCallbackInterface* cb, int event_mask, int fd) : cb(cb), fd(fd), event_mask(event_mask), events_asserted(0), events_to_fake(0), in_use(false) { entry.le_next = NULL; entry.le_prev = NULL; } // Required operator for hash_set. Normally operator== should be a free // standing function. However, since CBAndEventMask is a protected type and // it will never be a base class, it makes no difference. bool operator==(const CBAndEventMask& cb_and_mask) const { return fd == cb_and_mask.fd; } // A callback. If the fd is unregistered inside the callchain of OnEvent, // the cb will be set to NULL. mutable EpollCallbackInterface* cb; mutable LIST_ENTRY(CBAndEventMask) entry; // file descriptor registered with the epoll server. int fd; // the current event_mask registered for this callback. mutable int event_mask; // the event_mask that was returned by epoll mutable int events_asserted; // the event_mask for the ready list to use to call OnEvent. mutable int events_to_fake; // toggle around calls to OnEvent to tell UnregisterFD to not erase the // iterator because HandleEvent is using it. mutable bool in_use; }; // Custom hash function to be used by hash_set. struct CBAndEventMaskHash { size_t operator()(const CBAndEventMask& cb_and_eventmask) const { return static_cast(cb_and_eventmask.fd); } }; typedef __gnu_cxx::hash_set FDToCBMap; // the following four functions are OS-specific, and are likely // to be changed in a subclass if the poll/select method is changed // from epoll. // Summary: // Deletes a file-descriptor from the set of FDs that should be // monitored with epoll. // Note that this only deals with modifying data relating -directly- // with the epoll call-- it does not modify any data within the // epoll_server. // Args: // fd - the file descriptor to-be-removed from the monitoring set virtual void DelFD(int fd) const; //////////////////////////////////////// // Summary: // Adds a file-descriptor to the set of FDs that should be // monitored with epoll. // Note that this only deals with modifying data relating -directly- // with the epoll call. // Args: // fd - the file descriptor to-be-added to the monitoring set // event_mask - the event mask (consisting of EPOLLIN, EPOLLOUT, etc // OR'd together) which will be associated with this // FD initially. virtual void AddFD(int fd, int event_mask) const; //////////////////////////////////////// // Summary: // Modifies a file-descriptor in the set of FDs that should be // monitored with epoll. // Note that this only deals with modifying data relating -directly- // with the epoll call. // Args: // fd - the file descriptor to-be-added to the monitoring set // event_mask - the event mask (consisting of EPOLLIN, EPOLLOUT, etc // OR'd together) which will be associated with this // FD after this call. virtual void ModFD(int fd, int event_mask) const; //////////////////////////////////////// // Summary: // Modified the event mask associated with an FD in the set of // data needed by epoll. // Events are removed before they are added, thus, if ~0 is put // in 'remove_event', whatever is put in 'add_event' will be // the new event mask. // If the file-descriptor specified is not registered in the // epoll_server, then nothing happens as a result of this call. // Args: // fd - the file descriptor whose event mask is to be modified // remove_event - the events which are to be removed from the current // event_mask // add_event - the events which are to be added to the current event_mask // // virtual void ModifyFD(int fd, int remove_event, int add_event); //////////////////////////////////////// // Summary: // Waits for events, and calls HandleEvents() for each // fd, event pair discovered to possibly have an event. // Note that a callback (B) may get a spurious event if // another callback (A) has closed a file-descriptor N, and // the callback (B) has a newly opened file-descriptor, which // also happens to be N. virtual void WaitForEventsAndCallHandleEvents(int64 timeout_in_us, struct epoll_event events[], int events_size); // Summary: // An internal function for implementing the ready list. It adds a fd's // CBAndEventMask to the ready list. If the fd is already on the ready // list, it is a no-op. void AddToReadyList(CBAndEventMask* cb_and_mask); // Summary: // An internal function for implementing the ready list. It remove a fd's // CBAndEventMask from the ready list. If the fd is not on the ready list, // it is a no-op. void RemoveFromReadyList(const CBAndEventMask& cb_and_mask); // Summary: // Calls any pending alarms that should go off and reregisters them if they // were recurring. virtual void CallAndReregisterAlarmEvents(); // The file-descriptor created for epolling int epoll_fd_; // The mapping of file-descriptor to CBAndEventMasks FDToCBMap cb_map_; // Custom hash function to be used by hash_set. struct AlarmCBHash { size_t operator()(AlarmCB*const& p) const { return reinterpret_cast(p); } }; // TOOD(sushantj): Having this hash_set is avoidable. We currently have it // only so that we can enforce stringent checks that a caller can not register // the same alarm twice. One option is to have an implementation in which // this hash_set is used only in the debug mode. typedef __gnu_cxx::hash_set AlarmCBMap; AlarmCBMap all_alarms_; TimeToAlarmCBMap alarm_map_; // The amount of time in microseconds that we'll wait before returning // from the WaitForEventsAndExecuteCallbacks() function. // If this is positive, wait that many microseconds. // If this is negative, wait forever, or for the first event that occurs // If this is zero, never wait for an event. int64 timeout_in_us_; // This is nonzero only after the invocation of epoll_wait_impl within // WaitForEventsAndCallHandleEvents and before the function // WaitForEventsAndExecuteCallbacks returns. At all other times, this is // zero. This enables us to have relatively accurate time returned from the // ApproximateNowInUs() function. See that function for more details. int64 recorded_now_in_us_; // This is used to implement CallAndReregisterAlarmEvents. This stores // all alarms that were reregistered because OnAlarm() returned a // value > 0 and the time at which they should be executed is less that // the current time. By storing such alarms in this map we ensure // that while calling CallAndReregisterAlarmEvents we do not call // OnAlarm on any alarm in this set. This ensures that we do not // go in an infinite loop. AlarmCBMap alarms_reregistered_and_should_be_skipped_; LIST_HEAD(ReadyList, CBAndEventMask) ready_list_; LIST_HEAD(TmpList, CBAndEventMask) tmp_list_; int ready_list_size_; // TODO(alyssar): make this into something that scales up. static const int events_size_ = 256; struct epoll_event events_[256]; // These controls the granularity for alarms // See function CallAndReregisterAlarmEvents() // TODO(sushantj): Add test for this. int64 DoRoundingOnNow(int64 now_in_us) const; #ifdef EPOLL_SERVER_EVENT_TRACING struct EventRecorder { public: EventRecorder() : num_records_(0), record_threshold_(10000) {} ~EventRecorder() { Clear(); } // When a number of events equals the record threshold, // the collected data summary for all FDs will be written // to LOG(INFO). Note that this does not include the // individual events (if you'reinterested in those, you'll // have to get at them programmatically). // After any such flushing to LOG(INFO) all events will // be cleared. // Note that the definition of an 'event' is a bit 'hazy', // as it includes the 'Unregistration' event, and perhaps // others. void set_record_threshold(int64 new_threshold) { record_threshold_ = new_threshold; } void Clear() { for (int i = 0; i < debug_events_.size(); ++i) { delete debug_events_[i]; } debug_events_.clear(); unregistered_fds_.clear(); event_counts_.clear(); } void MaybeRecordAndClear() { ++num_records_; if ((num_records_ > record_threshold_) && (record_threshold_ > 0)) { LOG(INFO) << "\n" << *this; num_records_ = 0; Clear(); } } void RecordFDMaskEvent(int fd, int mask, const char* function) { FDMaskOutput* fdmo = new FDMaskOutput(fd, mask, function); debug_events_.push_back(fdmo); MaybeRecordAndClear(); } void RecordEpollWaitEvent(int timeout_in_ms, int num_events_generated) { EpollWaitOutput* ewo = new EpollWaitOutput(timeout_in_ms, num_events_generated); debug_events_.push_back(ewo); MaybeRecordAndClear(); } void RecordEpollEvent(int fd, int event_mask) { Events& events_for_fd = event_counts_[fd]; events_for_fd.AssignFromMask(event_mask); MaybeRecordAndClear(); } friend ostream& operator<<(ostream& os, const EventRecorder& er) { for (int i = 0; i < er.unregistered_fds_.size(); ++i) { os << "fd: " << er.unregistered_fds_[i] << "\n"; os << er.unregistered_fds_[i]; } for (EventCountsMap::const_iterator i = er.event_counts_.begin(); i != er.event_counts_.end(); ++i) { os << "fd: " << i->first << "\n"; os << i->second; } for (int i = 0; i < er.debug_events_.size(); ++i) { os << *(er.debug_events_[i]) << "\n"; } return os; } void RecordUnregistration(int fd) { EventCountsMap::iterator i = event_counts_.find(fd); if (i != event_counts_.end()) { unregistered_fds_.push_back(i->second); event_counts_.erase(i); } MaybeRecordAndClear(); } protected: class DebugOutput { public: friend ostream& operator<<(ostream& os, const DebugOutput& debug_output) { debug_output.OutputToStream(os); return os; } virtual void OutputToStream(ostream* os) const = 0; virtual ~DebugOutput() {} }; class FDMaskOutput : public DebugOutput { public: FDMaskOutput(int fd, int mask, const char* function) : fd_(fd), mask_(mask), function_(function) {} virtual void OutputToStream(ostream* os) const { (*os) << "func: " << function_ << "\tfd: " << fd_; if (mask_ != 0) { (*os) << "\tmask: " << EventMaskToString(mask_); } } int fd_; int mask_; const char* function_; }; class EpollWaitOutput : public DebugOutput { public: EpollWaitOutput(int timeout_in_ms, int num_events_generated) : timeout_in_ms_(timeout_in_ms), num_events_generated_(num_events_generated) {} virtual void OutputToStream(ostream* os) const { (*os) << "timeout_in_ms: " << timeout_in_ms_ << "\tnum_events_generated: " << num_events_generated_; } protected: int timeout_in_ms_; int num_events_generated_; }; struct Events { Events() : epoll_in(0), epoll_pri(0), epoll_out(0), epoll_rdnorm(0), epoll_rdband(0), epoll_wrnorm(0), epoll_wrband(0), epoll_msg(0), epoll_err(0), epoll_hup(0), epoll_oneshot(0), epoll_et(0) {} void AssignFromMask(int event_mask) { if (event_mask & EPOLLIN) ++epoll_in; if (event_mask & EPOLLPRI) ++epoll_pri; if (event_mask & EPOLLOUT) ++epoll_out; if (event_mask & EPOLLRDNORM) ++epoll_rdnorm; if (event_mask & EPOLLRDBAND) ++epoll_rdband; if (event_mask & EPOLLWRNORM) ++epoll_wrnorm; if (event_mask & EPOLLWRBAND) ++epoll_wrband; if (event_mask & EPOLLMSG) ++epoll_msg; if (event_mask & EPOLLERR) ++epoll_err; if (event_mask & EPOLLHUP) ++epoll_hup; if (event_mask & EPOLLONESHOT) ++epoll_oneshot; if (event_mask & EPOLLET) ++epoll_et; }; friend ostream& operator<<(ostream& os, const Events& ev) { if (ev.epoll_in) { os << "\t EPOLLIN: " << ev.epoll_in << "\n"; } if (ev.epoll_pri) { os << "\t EPOLLPRI: " << ev.epoll_pri << "\n"; } if (ev.epoll_out) { os << "\t EPOLLOUT: " << ev.epoll_out << "\n"; } if (ev.epoll_rdnorm) { os << "\t EPOLLRDNORM: " << ev.epoll_rdnorm << "\n"; } if (ev.epoll_rdband) { os << "\t EPOLLRDBAND: " << ev.epoll_rdband << "\n"; } if (ev.epoll_wrnorm) { os << "\t EPOLLWRNORM: " << ev.epoll_wrnorm << "\n"; } if (ev.epoll_wrband) { os << "\t EPOLLWRBAND: " << ev.epoll_wrband << "\n"; } if (ev.epoll_msg) { os << "\t EPOLLMSG: " << ev.epoll_msg << "\n"; } if (ev.epoll_err) { os << "\t EPOLLERR: " << ev.epoll_err << "\n"; } if (ev.epoll_hup) { os << "\t EPOLLHUP: " << ev.epoll_hup << "\n"; } if (ev.epoll_oneshot) { os << "\t EPOLLONESHOT: " << ev.epoll_oneshot << "\n"; } if (ev.epoll_et) { os << "\t EPOLLET: " << ev.epoll_et << "\n"; } return os; } unsigned int epoll_in; unsigned int epoll_pri; unsigned int epoll_out; unsigned int epoll_rdnorm; unsigned int epoll_rdband; unsigned int epoll_wrnorm; unsigned int epoll_wrband; unsigned int epoll_msg; unsigned int epoll_err; unsigned int epoll_hup; unsigned int epoll_oneshot; unsigned int epoll_et; }; std::vector debug_events_; std::vector unregistered_fds_; typedef __gnu_cxx::hash_map EventCountsMap; EventCountsMap event_counts_; int64 num_records_; int64 record_threshold_; }; void ClearEventRecords() { event_recorder_.Clear(); } void WriteEventRecords(ostream* os) const { (*os) << event_recorder_; } mutable EventRecorder event_recorder_; #endif private: // Helper functions used in the destructor. void CleanupFDToCBMap(); void CleanupTimeToAlarmCBMap(); // The callback registered to the fds below. As the purpose of their // registration is to wake the epoll server it just clears the pipe and // returns. scoped_ptr wake_cb_; // A pipe owned by the epoll server. The server will be registered to listen // on read_fd_ and can be woken by Wake() which writes to write_fd_. int read_fd_; int write_fd_; // This boolean is checked to see if it is false at the top of the // WaitForEventsAndExecuteCallbacks function. If not, then it either returns // without doing work, and logs to ERROR, or aborts the program (in // DEBUG mode). If so, then it sets the bool to true, does work, and // sets it back to false when done. This catches unwanted recursion. bool in_wait_for_events_and_execute_callbacks_; // Returns true when the EpollServer() is being destroyed. bool in_shutdown_; DISALLOW_COPY_AND_ASSIGN(EpollServer); }; class EpollAlarmCallbackInterface { public: // Summary: // Called when an alarm times out. Invalidates an AlarmRegToken. // WARNING: If a token was saved to refer to an alarm callback, OnAlarm must // delete it, as the reference is no longer valid. // Returns: // the unix time (in microseconds) at which this alarm should be signaled // again, or 0 if the alarm should be removed. virtual int64 OnAlarm() = 0; // Summary: // Called when the an alarm is registered. Invalidates an AlarmRegToken. // Args: // token: the iterator to the the alarm registered in the alarm map. // WARNING: this token becomes invalid when the alarm fires, is // unregistered, or OnShutdown is called on that alarm. // eps: the epoll server the alarm is registered with. virtual void OnRegistration(const EpollServer::AlarmRegToken& token, EpollServer* eps) = 0; // Summary: // Called when the an alarm is unregistered. // WARNING: It is not valid to unregister a callback and then use the token // that was saved to refer to the callback. virtual void OnUnregistration() = 0; // Summary: // Called when the epoll server is shutting down. // Invalidates the AlarmRegToken that was given when this alarm was // registered. virtual void OnShutdown(EpollServer* eps) = 0; virtual ~EpollAlarmCallbackInterface() {} protected: EpollAlarmCallbackInterface() {} }; // A simple alarm which unregisters itself on destruction. // // PLEASE NOTE: // Any classes overriding these functions must either call the implementation // of the parent class, or is must otherwise make sure that the 'registered_' // boolean and the token, 'token_', are updated appropriately. class EpollAlarm : public EpollAlarmCallbackInterface { public: EpollAlarm(); virtual ~EpollAlarm(); // Marks the alarm as unregistered and returns 0. The return value may be // safely ignored by subclasses. virtual int64 OnAlarm() OVERRIDE; // Marks the alarm as registered, and stores the token. virtual void OnRegistration(const EpollServer::AlarmRegToken& token, EpollServer* eps) OVERRIDE; // Marks the alarm as unregistered. virtual void OnUnregistration() OVERRIDE; // Marks the alarm as unregistered. virtual void OnShutdown(EpollServer* eps) OVERRIDE; // If the alarm was registered, unregister it. void UnregisterIfRegistered(); bool registered() const { return registered_; } const EpollServer* eps() const { return eps_; } private: EpollServer::AlarmRegToken token_; EpollServer* eps_; bool registered_; }; } // namespace net #endif // NET_TOOLS_FLIP_SERVER_EPOLL_SERVER_H_