// Package handler handles incoming Gateway events. It reflects the function's // first argument and caches that for use in each event. // // # Performance // // Each call to the event would take 167 ns/op for roughly each handler. Scaling // that up to 100 handlers is roughly the same as multiplying 167 ns by 100, // which gives 16700 ns or 0.0167 ms. // // BenchmarkReflect-8 7260909 167 ns/op // // # Usage // // Handler's usage is mostly similar to Discordgo, in that AddHandler expects a // function with only one argument or an event channel. For more information, // refer to AddHandler. package handler import ( "context" "fmt" "reflect" "sync" "errors" ) // Handler is a container for command handlers. A zero-value instance is a valid // instance. type Handler struct { mutex sync.RWMutex events map[reflect.Type]slab // nil type for interfaces } func New() *Handler { return &Handler{} } // Call calls all handlers with the given event. This is an internal method; use // with care. func (h *Handler) Call(ev interface{}) { t := reflect.TypeOf(ev) h.mutex.RLock() defer h.mutex.RUnlock() typedHandlers := h.events[t].Entries anyHandlers := h.events[nil].Entries if len(typedHandlers) == 0 && len(anyHandlers) == 0 { return } v := reflect.ValueOf(ev) for _, entry := range typedHandlers { if entry.isInvalid() { continue } entry.Call(v) } for _, entry := range anyHandlers { if entry.isInvalid() || entry.not(t) { continue } entry.Call(v) } } // WaitFor blocks until there's an event. It's advised to use ChanFor instead, // as WaitFor may skip some events if it's not ran fast enough after the event // arrived. func (h *Handler) WaitFor(ctx context.Context, fn func(interface{}) bool) interface{} { var result = make(chan interface{}) cancel := h.AddHandler(func(v interface{}) { if fn(v) { result <- v } }) defer cancel() select { case r := <-result: return r case <-ctx.Done(): return nil } } // ChanFor returns a channel that would receive all incoming events that match // the callback given. The cancel() function removes the handler and drops all // hanging goroutines. // // This method is more intended to be used as a filter. For a persistent event // channel, consider adding it directly as a handler with AddHandler. func (h *Handler) ChanFor(fn func(interface{}) bool) (out <-chan interface{}, cancel func()) { result := make(chan interface{}) closer := make(chan struct{}) removeHandler := h.AddHandler(func(v interface{}) { if fn(v) { select { case result <- v: case <-closer: } } }) // Only allow cancel to be called once. var once sync.Once cancel = func() { once.Do(func() { removeHandler() close(closer) }) } out = result return } // AddHandler adds the handler, returning a function that would remove this // handler when called. A handler type is either a single-argument no-return // function or a channel. // // # Function // // A handler can be a function with a single argument that is the expected event // type. It must not have any returns or any other number of arguments. // // // An example of a valid function handler. // h.AddHandler(func(*gateway.MessageCreateEvent) {}) // // # Channel // // A handler can also be a channel. The underlying type that the channel wraps // around will be the event type. As such, the type rules are the same as // function handlers. // // Keep in mind that the user must NOT close the channel. In fact, the channel // should not be closed at all. The caller function WILL PANIC if the channel is // closed! // // When the rm callback that is returned is called, it will also guarantee that // all blocking sends will be cancelled. This helps prevent dangling goroutines. // // // An example of a valid channel handler. // ch := make(chan *gateway.MessageCreateEvent) // h.AddHandler(ch) func (h *Handler) AddHandler(handler interface{}) (rm func()) { rm, err := h.addHandler(handler, false) if err != nil { panic(err) } return rm } // AddSyncHandler is a synchronous variant of AddHandler. Handlers added using // this method will block the Call method, which is helpful if the user needs to // rely on the order of events arriving. Handlers added using this method should // not block for very long, as it may clog up other handlers. func (h *Handler) AddSyncHandler(handler interface{}) (rm func()) { rm, err := h.addHandler(handler, true) if err != nil { panic(err) } return rm } // AddHandlerCheck adds the handler, but safe-guards reflect panics with a // recoverer, returning the error. Refer to AddHandler for more information. func (h *Handler) AddHandlerCheck(handler interface{}) (rm func(), err error) { // Reflect would actually panic if anything goes wrong, so this is just in // case. defer func() { if rec := recover(); rec != nil { if recErr, ok := rec.(error); ok { err = recErr } else { err = fmt.Errorf("%v", rec) } } }() return h.addHandler(handler, false) } // AddSyncHandlerCheck is the safe-guarded version of AddSyncHandler. It is // similar to AddHandlerCheck. func (h *Handler) AddSyncHandlerCheck(handler interface{}) (rm func(), err error) { // Reflect would actually panic if anything goes wrong, so this is just in // case. defer func() { if rec := recover(); rec != nil { if recErr, ok := rec.(error); ok { err = recErr } else { err = fmt.Errorf("%v", rec) } } }() return h.addHandler(handler, true) } func (h *Handler) addHandler(fn interface{}, sync bool) (rm func(), err error) { // Reflect the handler r, err := newHandler(fn, sync) if err != nil { return nil, fmt.Errorf("handler reflect failed: %w", err) } var id int var t reflect.Type if !r.isIface { t = r.event } h.mutex.Lock() if h.events == nil { h.events = make(map[reflect.Type]slab, 10) } slab := h.events[t] id = slab.Put(r) h.events[t] = slab h.mutex.Unlock() return func() { h.mutex.Lock() slab := h.events[t] popped := slab.Pop(id) h.mutex.Unlock() popped.cleanup() }, nil } type handler struct { event reflect.Type // underlying type; arg0 or chan underlying type callback reflect.Value chanclose reflect.Value // IsValid() if chan isIface bool isSync bool isOnce bool } // newHandler reflects either a channel or a function into a handler. A function // must only have a single argument being the event and no return, and a channel // must have the event type as the underlying type. func newHandler(unknown interface{}, sync bool) (handler, error) { fnV := reflect.ValueOf(unknown) fnT := fnV.Type() // underlying event type handler := handler{ callback: fnV, isSync: sync, } switch fnT.Kind() { case reflect.Func: if fnT.NumIn() != 1 { return handler, errors.New("function can only accept 1 event as argument") } if fnT.NumOut() > 0 { return handler, errors.New("function can't accept returns") } handler.event = fnT.In(0) case reflect.Chan: handler.event = fnT.Elem() handler.chanclose = reflect.ValueOf(make(chan struct{})) default: return handler, errors.New("given interface is not a function or channel") } var kind = handler.event.Kind() // Accept either pointer type or interface{} type if kind != reflect.Ptr && kind != reflect.Interface { return handler, errors.New("first argument is not pointer") } handler.isIface = kind == reflect.Interface return handler, nil } func (h handler) not(event reflect.Type) bool { if h.isIface { return !event.Implements(h.event) } return h.event != event } func (h handler) Call(event reflect.Value) { if h.isSync { h.call(event) } else { go h.call(event) } } func (h handler) call(event reflect.Value) { if h.chanclose.IsValid() { reflect.Select([]reflect.SelectCase{ {Dir: reflect.SelectSend, Chan: h.callback, Send: event}, {Dir: reflect.SelectRecv, Chan: h.chanclose}, }) } else { h.callback.Call([]reflect.Value{event}) } } func (h handler) cleanup() { if h.chanclose.IsValid() { // Closing this channel will force all ongoing selects to return // immediately. h.chanclose.Close() } }