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440 lines
14 KiB
440 lines
14 KiB
8 months ago
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// Copyright 2023 The go-ethereum Authors
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// This file is part of the go-ethereum library.
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//
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// The go-ethereum library is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Lesser General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// The go-ethereum library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public License
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// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
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package request
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import (
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"math"
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"sync"
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"time"
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"github.com/ethereum/go-ethereum/common/mclock"
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"github.com/ethereum/go-ethereum/log"
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)
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var (
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// request events
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EvResponse = &EventType{Name: "response", requestEvent: true} // data: RequestResponse; sent by requestServer
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EvFail = &EventType{Name: "fail", requestEvent: true} // data: RequestResponse; sent by requestServer
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EvTimeout = &EventType{Name: "timeout", requestEvent: true} // data: RequestResponse; sent by serverWithTimeout
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// server events
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EvRegistered = &EventType{Name: "registered"} // data: nil; sent by Scheduler
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EvUnregistered = &EventType{Name: "unregistered"} // data: nil; sent by Scheduler
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EvCanRequestAgain = &EventType{Name: "canRequestAgain"} // data: nil; sent by serverWithLimits
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)
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const (
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softRequestTimeout = time.Second // allow resending request to a different server but do not cancel yet
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hardRequestTimeout = time.Second * 10 // cancel request
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)
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const (
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// serverWithLimits parameters
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parallelAdjustUp = 0.1 // adjust parallelLimit up in case of success under full load
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parallelAdjustDown = 1 // adjust parallelLimit down in case of timeout/failure
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minParallelLimit = 1 // parallelLimit lower bound
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defaultParallelLimit = 3 // parallelLimit initial value
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minFailureDelay = time.Millisecond * 100 // minimum disable time in case of request failure
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maxFailureDelay = time.Minute // maximum disable time in case of request failure
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maxServerEventBuffer = 5 // server event allowance buffer limit
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maxServerEventRate = time.Second // server event allowance buffer recharge rate
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)
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// requestServer can send requests in a non-blocking way and feed back events
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// through the event callback. After each request it should send back either
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// EvResponse or EvFail. Additionally, it may also send application-defined
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// events that the Modules can interpret.
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type requestServer interface {
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Subscribe(eventCallback func(Event))
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SendRequest(ID, Request)
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Unsubscribe()
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}
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// server is implemented by a requestServer wrapped into serverWithTimeout and
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// serverWithLimits and is used by Scheduler.
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// In addition to requestServer functionality, server can also handle timeouts,
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// limit the number of parallel in-flight requests and temporarily disable
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// new requests based on timeouts and response failures.
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type server interface {
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subscribe(eventCallback func(Event))
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canRequestNow() bool
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sendRequest(Request) ID
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fail(string)
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unsubscribe()
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}
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// NewServer wraps a requestServer and returns a server
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func NewServer(rs requestServer, clock mclock.Clock) server {
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s := &serverWithLimits{}
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s.parent = rs
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s.serverWithTimeout.init(clock)
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s.init()
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return s
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}
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// EventType identifies an event type, either related to a request or the server
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// in general. Server events can also be externally defined.
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type EventType struct {
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Name string
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requestEvent bool // all request events are pre-defined in request package
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}
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// Event describes an event where the type of Data depends on Type.
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// Server field is not required when sent through the event callback; it is filled
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// out when processed by the Scheduler. Note that the Scheduler can also create
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// and send events (EvRegistered, EvUnregistered) directly.
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type Event struct {
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Type *EventType
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Server Server // filled by Scheduler
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Data any
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}
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// IsRequestEvent returns true if the event is a request event
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func (e *Event) IsRequestEvent() bool {
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return e.Type.requestEvent
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}
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// RequestInfo assumes that the event is a request event and returns its contents
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// in a convenient form.
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func (e *Event) RequestInfo() (ServerAndID, Request, Response) {
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data := e.Data.(RequestResponse)
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return ServerAndID{Server: e.Server, ID: data.ID}, data.Request, data.Response
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}
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// RequestResponse is the Data type of request events.
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type RequestResponse struct {
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ID ID
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Request Request
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Response Response
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}
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// serverWithTimeout wraps a requestServer and introduces timeouts.
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// The request's lifecycle is concluded if EvResponse or EvFail emitted by the
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// parent requestServer. If this does not happen until softRequestTimeout then
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// EvTimeout is emitted, after which the final EvResponse or EvFail is still
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// guaranteed to follow.
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// If the parent fails to send this final event for hardRequestTimeout then
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// serverWithTimeout emits EvFail and discards any further events from the
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// parent related to the given request.
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type serverWithTimeout struct {
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parent requestServer
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lock sync.Mutex
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clock mclock.Clock
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childEventCb func(event Event)
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timeouts map[ID]mclock.Timer
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lastID ID
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}
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// init initializes serverWithTimeout
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func (s *serverWithTimeout) init(clock mclock.Clock) {
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s.clock = clock
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s.timeouts = make(map[ID]mclock.Timer)
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}
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// subscribe subscribes to events which include parent (requestServer) events
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// plus EvTimeout.
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func (s *serverWithTimeout) subscribe(eventCallback func(event Event)) {
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s.lock.Lock()
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defer s.lock.Unlock()
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s.childEventCb = eventCallback
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s.parent.Subscribe(s.eventCallback)
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}
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// sendRequest generated a new request ID, emits EvRequest, sets up the timeout
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// timer, then sends the request through the parent (requestServer).
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func (s *serverWithTimeout) sendRequest(request Request) (reqId ID) {
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s.lock.Lock()
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s.lastID++
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id := s.lastID
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s.startTimeout(RequestResponse{ID: id, Request: request})
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s.lock.Unlock()
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s.parent.SendRequest(id, request)
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return id
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}
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// eventCallback is called by parent (requestServer) event subscription.
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func (s *serverWithTimeout) eventCallback(event Event) {
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s.lock.Lock()
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defer s.lock.Unlock()
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switch event.Type {
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case EvResponse, EvFail:
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id := event.Data.(RequestResponse).ID
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if timer, ok := s.timeouts[id]; ok {
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// Note: if stopping the timer is unsuccessful then the resulting AfterFunc
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// call will just do nothing
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timer.Stop()
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delete(s.timeouts, id)
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s.childEventCb(event)
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}
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default:
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s.childEventCb(event)
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}
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}
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// startTimeout starts a timeout timer for the given request.
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func (s *serverWithTimeout) startTimeout(reqData RequestResponse) {
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id := reqData.ID
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s.timeouts[id] = s.clock.AfterFunc(softRequestTimeout, func() {
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s.lock.Lock()
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if _, ok := s.timeouts[id]; !ok {
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s.lock.Unlock()
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return
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}
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s.timeouts[id] = s.clock.AfterFunc(hardRequestTimeout-softRequestTimeout, func() {
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s.lock.Lock()
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if _, ok := s.timeouts[id]; !ok {
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s.lock.Unlock()
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return
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}
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delete(s.timeouts, id)
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childEventCb := s.childEventCb
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s.lock.Unlock()
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childEventCb(Event{Type: EvFail, Data: reqData})
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})
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childEventCb := s.childEventCb
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s.lock.Unlock()
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childEventCb(Event{Type: EvTimeout, Data: reqData})
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})
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}
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// stop stops all goroutines associated with the server.
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func (s *serverWithTimeout) unsubscribe() {
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s.lock.Lock()
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defer s.lock.Unlock()
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for _, timer := range s.timeouts {
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if timer != nil {
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timer.Stop()
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}
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}
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s.childEventCb = nil
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s.parent.Unsubscribe()
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}
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// serverWithLimits wraps serverWithTimeout and implements server. It limits the
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// number of parallel in-flight requests and prevents sending new requests when a
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// pending one has already timed out. Server events are also rate limited.
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// It also implements a failure delay mechanism that adds an exponentially growing
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// delay each time a request fails (wrong answer or hard timeout). This makes the
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// syncing mechanism less brittle as temporary failures of the server might happen
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// sometimes, but still avoids hammering a non-functional server with requests.
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type serverWithLimits struct {
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serverWithTimeout
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lock sync.Mutex
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childEventCb func(event Event)
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softTimeouts map[ID]struct{}
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pendingCount, timeoutCount int
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parallelLimit float32
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sendEvent bool
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delayTimer mclock.Timer
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delayCounter int
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failureDelayEnd mclock.AbsTime
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failureDelay float64
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serverEventBuffer int
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eventBufferUpdated mclock.AbsTime
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}
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// init initializes serverWithLimits
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func (s *serverWithLimits) init() {
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s.softTimeouts = make(map[ID]struct{})
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s.parallelLimit = defaultParallelLimit
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s.serverEventBuffer = maxServerEventBuffer
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}
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// subscribe subscribes to events which include parent (serverWithTimeout) events
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// plus EvCanRequstAgain.
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func (s *serverWithLimits) subscribe(eventCallback func(event Event)) {
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s.lock.Lock()
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defer s.lock.Unlock()
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s.childEventCb = eventCallback
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s.serverWithTimeout.subscribe(s.eventCallback)
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}
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// eventCallback is called by parent (serverWithTimeout) event subscription.
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func (s *serverWithLimits) eventCallback(event Event) {
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s.lock.Lock()
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var sendCanRequestAgain bool
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passEvent := true
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switch event.Type {
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case EvTimeout:
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id := event.Data.(RequestResponse).ID
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s.softTimeouts[id] = struct{}{}
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s.timeoutCount++
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s.parallelLimit -= parallelAdjustDown
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if s.parallelLimit < minParallelLimit {
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s.parallelLimit = minParallelLimit
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}
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log.Debug("Server timeout", "count", s.timeoutCount, "parallelLimit", s.parallelLimit)
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case EvResponse, EvFail:
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id := event.Data.(RequestResponse).ID
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if _, ok := s.softTimeouts[id]; ok {
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delete(s.softTimeouts, id)
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s.timeoutCount--
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log.Debug("Server timeout finalized", "count", s.timeoutCount, "parallelLimit", s.parallelLimit)
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}
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if event.Type == EvResponse && s.pendingCount >= int(s.parallelLimit) {
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s.parallelLimit += parallelAdjustUp
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}
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s.pendingCount--
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if s.canRequest() {
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sendCanRequestAgain = s.sendEvent
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s.sendEvent = false
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}
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if event.Type == EvFail {
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s.failLocked("failed request")
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}
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default:
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// server event; check rate limit
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if s.serverEventBuffer < maxServerEventBuffer {
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now := s.clock.Now()
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sinceUpdate := time.Duration(now - s.eventBufferUpdated)
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if sinceUpdate >= maxServerEventRate*time.Duration(maxServerEventBuffer-s.serverEventBuffer) {
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s.serverEventBuffer = maxServerEventBuffer
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s.eventBufferUpdated = now
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} else {
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addBuffer := int(sinceUpdate / maxServerEventRate)
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s.serverEventBuffer += addBuffer
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s.eventBufferUpdated += mclock.AbsTime(maxServerEventRate * time.Duration(addBuffer))
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}
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}
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if s.serverEventBuffer > 0 {
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s.serverEventBuffer--
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} else {
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passEvent = false
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}
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}
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childEventCb := s.childEventCb
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s.lock.Unlock()
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if passEvent {
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childEventCb(event)
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}
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if sendCanRequestAgain {
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childEventCb(Event{Type: EvCanRequestAgain})
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}
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}
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// sendRequest sends a request through the parent (serverWithTimeout).
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func (s *serverWithLimits) sendRequest(request Request) (reqId ID) {
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s.lock.Lock()
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s.pendingCount++
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s.lock.Unlock()
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return s.serverWithTimeout.sendRequest(request)
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}
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// stop stops all goroutines associated with the server.
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func (s *serverWithLimits) unsubscribe() {
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s.lock.Lock()
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defer s.lock.Unlock()
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if s.delayTimer != nil {
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s.delayTimer.Stop()
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s.delayTimer = nil
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}
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s.childEventCb = nil
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s.serverWithTimeout.unsubscribe()
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}
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// canRequest checks whether a new request can be started.
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func (s *serverWithLimits) canRequest() bool {
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if s.delayTimer != nil || s.pendingCount >= int(s.parallelLimit) || s.timeoutCount > 0 {
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return false
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}
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if s.parallelLimit < minParallelLimit {
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s.parallelLimit = minParallelLimit
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}
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return true
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}
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// canRequestNow checks whether a new request can be started, according to the
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// current in-flight request count and parallelLimit, and also the failure delay
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// timer.
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// If it returns false then it is guaranteed that an EvCanRequestAgain will be
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// sent whenever the server becomes available for requesting again.
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func (s *serverWithLimits) canRequestNow() bool {
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var sendCanRequestAgain bool
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s.lock.Lock()
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canRequest := s.canRequest()
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if canRequest {
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sendCanRequestAgain = s.sendEvent
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s.sendEvent = false
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}
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childEventCb := s.childEventCb
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s.lock.Unlock()
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if sendCanRequestAgain {
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childEventCb(Event{Type: EvCanRequestAgain})
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}
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return canRequest
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}
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// delay sets the delay timer to the given duration, disabling new requests for
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// the given period.
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func (s *serverWithLimits) delay(delay time.Duration) {
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if s.delayTimer != nil {
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// Note: if stopping the timer is unsuccessful then the resulting AfterFunc
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// call will just do nothing
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s.delayTimer.Stop()
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s.delayTimer = nil
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}
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s.delayCounter++
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delayCounter := s.delayCounter
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log.Debug("Server delay started", "length", delay)
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s.delayTimer = s.clock.AfterFunc(delay, func() {
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log.Debug("Server delay ended", "length", delay)
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var sendCanRequestAgain bool
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s.lock.Lock()
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if s.delayTimer != nil && s.delayCounter == delayCounter { // do nothing if there is a new timer now
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s.delayTimer = nil
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if s.canRequest() {
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sendCanRequestAgain = s.sendEvent
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s.sendEvent = false
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}
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}
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childEventCb := s.childEventCb
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s.lock.Unlock()
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if sendCanRequestAgain {
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childEventCb(Event{Type: EvCanRequestAgain})
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}
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})
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}
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// fail reports that a response from the server was found invalid by the processing
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// Module, disabling new requests for a dynamically adjused time period.
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func (s *serverWithLimits) fail(desc string) {
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s.lock.Lock()
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defer s.lock.Unlock()
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s.failLocked(desc)
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}
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// failLocked calculates the dynamic failure delay and applies it.
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func (s *serverWithLimits) failLocked(desc string) {
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log.Debug("Server error", "description", desc)
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s.failureDelay *= 2
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now := s.clock.Now()
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if now > s.failureDelayEnd {
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||
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s.failureDelay *= math.Pow(2, -float64(now-s.failureDelayEnd)/float64(maxFailureDelay))
|
||
|
}
|
||
|
if s.failureDelay < float64(minFailureDelay) {
|
||
|
s.failureDelay = float64(minFailureDelay)
|
||
|
}
|
||
|
s.failureDelayEnd = now + mclock.AbsTime(s.failureDelay)
|
||
|
s.delay(time.Duration(s.failureDelay))
|
||
|
}
|