// Copyright 2016 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . package discv5 import ( "bytes" "encoding/binary" "fmt" "math" "math/rand" "sort" "time" "github.com/tangerine-network/go-tangerine/common" "github.com/tangerine-network/go-tangerine/common/mclock" "github.com/tangerine-network/go-tangerine/crypto" "github.com/tangerine-network/go-tangerine/log" ) const ( ticketTimeBucketLen = time.Minute timeWindow = 10 // * ticketTimeBucketLen wantTicketsInWindow = 10 collectFrequency = time.Second * 30 registerFrequency = time.Second * 60 maxCollectDebt = 10 maxRegisterDebt = 5 keepTicketConst = time.Minute * 10 keepTicketExp = time.Minute * 5 targetWaitTime = time.Minute * 10 topicQueryTimeout = time.Second * 5 topicQueryResend = time.Minute // topic radius detection maxRadius = 0xffffffffffffffff radiusTC = time.Minute * 20 radiusBucketsPerBit = 8 minSlope = 1 minPeakSize = 40 maxNoAdjust = 20 lookupWidth = 8 minRightSum = 20 searchForceQuery = 4 ) // timeBucket represents absolute monotonic time in minutes. // It is used as the index into the per-topic ticket buckets. type timeBucket int type ticket struct { topics []Topic regTime []mclock.AbsTime // Per-topic local absolute time when the ticket can be used. // The serial number that was issued by the server. serial uint32 // Used by registrar, tracks absolute time when the ticket was created. issueTime mclock.AbsTime // Fields used only by registrants node *Node // the registrar node that signed this ticket refCnt int // tracks number of topics that will be registered using this ticket pong []byte // encoded pong packet signed by the registrar } // ticketRef refers to a single topic in a ticket. type ticketRef struct { t *ticket idx int // index of the topic in t.topics and t.regTime } func (ref ticketRef) topic() Topic { return ref.t.topics[ref.idx] } func (ref ticketRef) topicRegTime() mclock.AbsTime { return ref.t.regTime[ref.idx] } func pongToTicket(localTime mclock.AbsTime, topics []Topic, node *Node, p *ingressPacket) (*ticket, error) { wps := p.data.(*pong).WaitPeriods if len(topics) != len(wps) { return nil, fmt.Errorf("bad wait period list: got %d values, want %d", len(topics), len(wps)) } if rlpHash(topics) != p.data.(*pong).TopicHash { return nil, fmt.Errorf("bad topic hash") } t := &ticket{ issueTime: localTime, node: node, topics: topics, pong: p.rawData, regTime: make([]mclock.AbsTime, len(wps)), } // Convert wait periods to local absolute time. for i, wp := range wps { t.regTime[i] = localTime + mclock.AbsTime(time.Second*time.Duration(wp)) } return t, nil } func ticketToPong(t *ticket, pong *pong) { pong.Expiration = uint64(t.issueTime / mclock.AbsTime(time.Second)) pong.TopicHash = rlpHash(t.topics) pong.TicketSerial = t.serial pong.WaitPeriods = make([]uint32, len(t.regTime)) for i, regTime := range t.regTime { pong.WaitPeriods[i] = uint32(time.Duration(regTime-t.issueTime) / time.Second) } } type ticketStore struct { // radius detector and target address generator // exists for both searched and registered topics radius map[Topic]*topicRadius // Contains buckets (for each absolute minute) of tickets // that can be used in that minute. // This is only set if the topic is being registered. tickets map[Topic]*topicTickets regQueue []Topic // Topic registration queue for round robin attempts regSet map[Topic]struct{} // Topic registration queue contents for fast filling nodes map[*Node]*ticket nodeLastReq map[*Node]reqInfo lastBucketFetched timeBucket nextTicketCached *ticketRef nextTicketReg mclock.AbsTime searchTopicMap map[Topic]searchTopic nextTopicQueryCleanup mclock.AbsTime queriesSent map[*Node]map[common.Hash]sentQuery } type searchTopic struct { foundChn chan<- *Node } type sentQuery struct { sent mclock.AbsTime lookup lookupInfo } type topicTickets struct { buckets map[timeBucket][]ticketRef nextLookup mclock.AbsTime nextReg mclock.AbsTime } func newTicketStore() *ticketStore { return &ticketStore{ radius: make(map[Topic]*topicRadius), tickets: make(map[Topic]*topicTickets), regSet: make(map[Topic]struct{}), nodes: make(map[*Node]*ticket), nodeLastReq: make(map[*Node]reqInfo), searchTopicMap: make(map[Topic]searchTopic), queriesSent: make(map[*Node]map[common.Hash]sentQuery), } } // addTopic starts tracking a topic. If register is true, // the local node will register the topic and tickets will be collected. func (s *ticketStore) addTopic(topic Topic, register bool) { log.Trace("Adding discovery topic", "topic", topic, "register", register) if s.radius[topic] == nil { s.radius[topic] = newTopicRadius(topic) } if register && s.tickets[topic] == nil { s.tickets[topic] = &topicTickets{buckets: make(map[timeBucket][]ticketRef)} } } func (s *ticketStore) addSearchTopic(t Topic, foundChn chan<- *Node) { s.addTopic(t, false) if s.searchTopicMap[t].foundChn == nil { s.searchTopicMap[t] = searchTopic{foundChn: foundChn} } } func (s *ticketStore) removeSearchTopic(t Topic) { if st := s.searchTopicMap[t]; st.foundChn != nil { delete(s.searchTopicMap, t) } } // removeRegisterTopic deletes all tickets for the given topic. func (s *ticketStore) removeRegisterTopic(topic Topic) { log.Trace("Removing discovery topic", "topic", topic) if s.tickets[topic] == nil { log.Warn("Removing non-existent discovery topic", "topic", topic) return } for _, list := range s.tickets[topic].buckets { for _, ref := range list { ref.t.refCnt-- if ref.t.refCnt == 0 { delete(s.nodes, ref.t.node) delete(s.nodeLastReq, ref.t.node) } } } delete(s.tickets, topic) } func (s *ticketStore) regTopicSet() []Topic { topics := make([]Topic, 0, len(s.tickets)) for topic := range s.tickets { topics = append(topics, topic) } return topics } // nextRegisterLookup returns the target of the next lookup for ticket collection. func (s *ticketStore) nextRegisterLookup() (lookupInfo, time.Duration) { // Queue up any new topics (or discarded ones), preserving iteration order for topic := range s.tickets { if _, ok := s.regSet[topic]; !ok { s.regQueue = append(s.regQueue, topic) s.regSet[topic] = struct{}{} } } // Iterate over the set of all topics and look up the next suitable one for len(s.regQueue) > 0 { // Fetch the next topic from the queue, and ensure it still exists topic := s.regQueue[0] s.regQueue = s.regQueue[1:] delete(s.regSet, topic) if s.tickets[topic] == nil { continue } // If the topic needs more tickets, return it if s.tickets[topic].nextLookup < mclock.Now() { next, delay := s.radius[topic].nextTarget(false), 100*time.Millisecond log.Trace("Found discovery topic to register", "topic", topic, "target", next.target, "delay", delay) return next, delay } } // No registration topics found or all exhausted, sleep delay := 40 * time.Second log.Trace("No topic found to register", "delay", delay) return lookupInfo{}, delay } func (s *ticketStore) nextSearchLookup(topic Topic) lookupInfo { tr := s.radius[topic] target := tr.nextTarget(tr.radiusLookupCnt >= searchForceQuery) if target.radiusLookup { tr.radiusLookupCnt++ } else { tr.radiusLookupCnt = 0 } return target } // ticketsInWindow returns the tickets of a given topic in the registration window. func (s *ticketStore) ticketsInWindow(topic Topic) []ticketRef { // Sanity check that the topic still exists before operating on it if s.tickets[topic] == nil { log.Warn("Listing non-existing discovery tickets", "topic", topic) return nil } // Gather all the tickers in the next time window var tickets []ticketRef buckets := s.tickets[topic].buckets for idx := timeBucket(0); idx < timeWindow; idx++ { tickets = append(tickets, buckets[s.lastBucketFetched+idx]...) } log.Trace("Retrieved discovery registration tickets", "topic", topic, "from", s.lastBucketFetched, "tickets", len(tickets)) return tickets } func (s *ticketStore) removeExcessTickets(t Topic) { tickets := s.ticketsInWindow(t) if len(tickets) <= wantTicketsInWindow { return } sort.Sort(ticketRefByWaitTime(tickets)) for _, r := range tickets[wantTicketsInWindow:] { s.removeTicketRef(r) } } type ticketRefByWaitTime []ticketRef // Len is the number of elements in the collection. func (s ticketRefByWaitTime) Len() int { return len(s) } func (ref ticketRef) waitTime() mclock.AbsTime { return ref.t.regTime[ref.idx] - ref.t.issueTime } // Less reports whether the element with // index i should sort before the element with index j. func (s ticketRefByWaitTime) Less(i, j int) bool { return s[i].waitTime() < s[j].waitTime() } // Swap swaps the elements with indexes i and j. func (s ticketRefByWaitTime) Swap(i, j int) { s[i], s[j] = s[j], s[i] } func (s *ticketStore) addTicketRef(r ticketRef) { topic := r.t.topics[r.idx] tickets := s.tickets[topic] if tickets == nil { log.Warn("Adding ticket to non-existent topic", "topic", topic) return } bucket := timeBucket(r.t.regTime[r.idx] / mclock.AbsTime(ticketTimeBucketLen)) tickets.buckets[bucket] = append(tickets.buckets[bucket], r) r.t.refCnt++ min := mclock.Now() - mclock.AbsTime(collectFrequency)*maxCollectDebt if tickets.nextLookup < min { tickets.nextLookup = min } tickets.nextLookup += mclock.AbsTime(collectFrequency) //s.removeExcessTickets(topic) } func (s *ticketStore) nextFilteredTicket() (*ticketRef, time.Duration) { now := mclock.Now() for { ticket, wait := s.nextRegisterableTicket() if ticket == nil { return ticket, wait } log.Trace("Found discovery ticket to register", "node", ticket.t.node, "serial", ticket.t.serial, "wait", wait) regTime := now + mclock.AbsTime(wait) topic := ticket.t.topics[ticket.idx] if s.tickets[topic] != nil && regTime >= s.tickets[topic].nextReg { return ticket, wait } s.removeTicketRef(*ticket) } } func (s *ticketStore) ticketRegistered(ref ticketRef) { now := mclock.Now() topic := ref.t.topics[ref.idx] tickets := s.tickets[topic] min := now - mclock.AbsTime(registerFrequency)*maxRegisterDebt if min > tickets.nextReg { tickets.nextReg = min } tickets.nextReg += mclock.AbsTime(registerFrequency) s.tickets[topic] = tickets s.removeTicketRef(ref) } // nextRegisterableTicket returns the next ticket that can be used // to register. // // If the returned wait time <= zero the ticket can be used. For a positive // wait time, the caller should requery the next ticket later. // // A ticket can be returned more than once with <= zero wait time in case // the ticket contains multiple topics. func (s *ticketStore) nextRegisterableTicket() (*ticketRef, time.Duration) { now := mclock.Now() if s.nextTicketCached != nil { return s.nextTicketCached, time.Duration(s.nextTicketCached.topicRegTime() - now) } for bucket := s.lastBucketFetched; ; bucket++ { var ( empty = true // true if there are no tickets nextTicket ticketRef // uninitialized if this bucket is empty ) for _, tickets := range s.tickets { //s.removeExcessTickets(topic) if len(tickets.buckets) != 0 { empty = false list := tickets.buckets[bucket] for _, ref := range list { //debugLog(fmt.Sprintf(" nrt bucket = %d node = %x sn = %v wait = %v", bucket, ref.t.node.ID[:8], ref.t.serial, time.Duration(ref.topicRegTime()-now))) if nextTicket.t == nil || ref.topicRegTime() < nextTicket.topicRegTime() { nextTicket = ref } } } } if empty { return nil, 0 } if nextTicket.t != nil { s.nextTicketCached = &nextTicket return &nextTicket, time.Duration(nextTicket.topicRegTime() - now) } s.lastBucketFetched = bucket } } // removeTicket removes a ticket from the ticket store func (s *ticketStore) removeTicketRef(ref ticketRef) { log.Trace("Removing discovery ticket reference", "node", ref.t.node.ID, "serial", ref.t.serial) // Make nextRegisterableTicket return the next available ticket. s.nextTicketCached = nil topic := ref.topic() tickets := s.tickets[topic] if tickets == nil { log.Trace("Removing tickets from unknown topic", "topic", topic) return } bucket := timeBucket(ref.t.regTime[ref.idx] / mclock.AbsTime(ticketTimeBucketLen)) list := tickets.buckets[bucket] idx := -1 for i, bt := range list { if bt.t == ref.t { idx = i break } } if idx == -1 { panic(nil) } list = append(list[:idx], list[idx+1:]...) if len(list) != 0 { tickets.buckets[bucket] = list } else { delete(tickets.buckets, bucket) } ref.t.refCnt-- if ref.t.refCnt == 0 { delete(s.nodes, ref.t.node) delete(s.nodeLastReq, ref.t.node) } } type lookupInfo struct { target common.Hash topic Topic radiusLookup bool } type reqInfo struct { pingHash []byte lookup lookupInfo time mclock.AbsTime } // returns -1 if not found func (t *ticket) findIdx(topic Topic) int { for i, tt := range t.topics { if tt == topic { return i } } return -1 } func (s *ticketStore) registerLookupDone(lookup lookupInfo, nodes []*Node, ping func(n *Node) []byte) { now := mclock.Now() for i, n := range nodes { if i == 0 || (binary.BigEndian.Uint64(n.sha[:8])^binary.BigEndian.Uint64(lookup.target[:8])) < s.radius[lookup.topic].minRadius { if lookup.radiusLookup { if lastReq, ok := s.nodeLastReq[n]; !ok || time.Duration(now-lastReq.time) > radiusTC { s.nodeLastReq[n] = reqInfo{pingHash: ping(n), lookup: lookup, time: now} } } else { if s.nodes[n] == nil { s.nodeLastReq[n] = reqInfo{pingHash: ping(n), lookup: lookup, time: now} } } } } } func (s *ticketStore) searchLookupDone(lookup lookupInfo, nodes []*Node, query func(n *Node, topic Topic) []byte) { now := mclock.Now() for i, n := range nodes { if i == 0 || (binary.BigEndian.Uint64(n.sha[:8])^binary.BigEndian.Uint64(lookup.target[:8])) < s.radius[lookup.topic].minRadius { if lookup.radiusLookup { if lastReq, ok := s.nodeLastReq[n]; !ok || time.Duration(now-lastReq.time) > radiusTC { s.nodeLastReq[n] = reqInfo{pingHash: nil, lookup: lookup, time: now} } } // else { if s.canQueryTopic(n, lookup.topic) { hash := query(n, lookup.topic) if hash != nil { s.addTopicQuery(common.BytesToHash(hash), n, lookup) } } //} } } } func (s *ticketStore) adjustWithTicket(now mclock.AbsTime, targetHash common.Hash, t *ticket) { for i, topic := range t.topics { if tt, ok := s.radius[topic]; ok { tt.adjustWithTicket(now, targetHash, ticketRef{t, i}) } } } func (s *ticketStore) addTicket(localTime mclock.AbsTime, pingHash []byte, ticket *ticket) { log.Trace("Adding discovery ticket", "node", ticket.node.ID, "serial", ticket.serial) lastReq, ok := s.nodeLastReq[ticket.node] if !(ok && bytes.Equal(pingHash, lastReq.pingHash)) { return } s.adjustWithTicket(localTime, lastReq.lookup.target, ticket) if lastReq.lookup.radiusLookup || s.nodes[ticket.node] != nil { return } topic := lastReq.lookup.topic topicIdx := ticket.findIdx(topic) if topicIdx == -1 { return } bucket := timeBucket(localTime / mclock.AbsTime(ticketTimeBucketLen)) if s.lastBucketFetched == 0 || bucket < s.lastBucketFetched { s.lastBucketFetched = bucket } if _, ok := s.tickets[topic]; ok { wait := ticket.regTime[topicIdx] - localTime rnd := rand.ExpFloat64() if rnd > 10 { rnd = 10 } if float64(wait) < float64(keepTicketConst)+float64(keepTicketExp)*rnd { // use the ticket to register this topic //fmt.Println("addTicket", ticket.node.ID[:8], ticket.node.addr().String(), ticket.serial, ticket.pong) s.addTicketRef(ticketRef{ticket, topicIdx}) } } if ticket.refCnt > 0 { s.nextTicketCached = nil s.nodes[ticket.node] = ticket } } func (s *ticketStore) getNodeTicket(node *Node) *ticket { if s.nodes[node] == nil { log.Trace("Retrieving node ticket", "node", node.ID, "serial", nil) } else { log.Trace("Retrieving node ticket", "node", node.ID, "serial", s.nodes[node].serial) } return s.nodes[node] } func (s *ticketStore) canQueryTopic(node *Node, topic Topic) bool { qq := s.queriesSent[node] if qq != nil { now := mclock.Now() for _, sq := range qq { if sq.lookup.topic == topic && sq.sent > now-mclock.AbsTime(topicQueryResend) { return false } } } return true } func (s *ticketStore) addTopicQuery(hash common.Hash, node *Node, lookup lookupInfo) { now := mclock.Now() qq := s.queriesSent[node] if qq == nil { qq = make(map[common.Hash]sentQuery) s.queriesSent[node] = qq } qq[hash] = sentQuery{sent: now, lookup: lookup} s.cleanupTopicQueries(now) } func (s *ticketStore) cleanupTopicQueries(now mclock.AbsTime) { if s.nextTopicQueryCleanup > now { return } exp := now - mclock.AbsTime(topicQueryResend) for n, qq := range s.queriesSent { for h, q := range qq { if q.sent < exp { delete(qq, h) } } if len(qq) == 0 { delete(s.queriesSent, n) } } s.nextTopicQueryCleanup = now + mclock.AbsTime(topicQueryTimeout) } func (s *ticketStore) gotTopicNodes(from *Node, hash common.Hash, nodes []rpcNode) (timeout bool) { now := mclock.Now() //fmt.Println("got", from.addr().String(), hash, len(nodes)) qq := s.queriesSent[from] if qq == nil { return true } q, ok := qq[hash] if !ok || now > q.sent+mclock.AbsTime(topicQueryTimeout) { return true } inside := float64(0) if len(nodes) > 0 { inside = 1 } s.radius[q.lookup.topic].adjust(now, q.lookup.target, from.sha, inside) chn := s.searchTopicMap[q.lookup.topic].foundChn if chn == nil { //fmt.Println("no channel") return false } for _, node := range nodes { ip := node.IP if ip.IsUnspecified() || ip.IsLoopback() { ip = from.IP } n := NewNode(node.ID, ip, node.UDP, node.TCP) select { case chn <- n: default: return false } } return false } type topicRadius struct { topic Topic topicHashPrefix uint64 radius, minRadius uint64 buckets []topicRadiusBucket converged bool radiusLookupCnt int } type topicRadiusEvent int const ( trOutside topicRadiusEvent = iota trInside trNoAdjust trCount ) type topicRadiusBucket struct { weights [trCount]float64 lastTime mclock.AbsTime value float64 lookupSent map[common.Hash]mclock.AbsTime } func (b *topicRadiusBucket) update(now mclock.AbsTime) { if now == b.lastTime { return } exp := math.Exp(-float64(now-b.lastTime) / float64(radiusTC)) for i, w := range b.weights { b.weights[i] = w * exp } b.lastTime = now for target, tm := range b.lookupSent { if now-tm > mclock.AbsTime(respTimeout) { b.weights[trNoAdjust] += 1 delete(b.lookupSent, target) } } } func (b *topicRadiusBucket) adjust(now mclock.AbsTime, inside float64) { b.update(now) if inside <= 0 { b.weights[trOutside] += 1 } else { if inside >= 1 { b.weights[trInside] += 1 } else { b.weights[trInside] += inside b.weights[trOutside] += 1 - inside } } } func newTopicRadius(t Topic) *topicRadius { topicHash := crypto.Keccak256Hash([]byte(t)) topicHashPrefix := binary.BigEndian.Uint64(topicHash[0:8]) return &topicRadius{ topic: t, topicHashPrefix: topicHashPrefix, radius: maxRadius, minRadius: maxRadius, } } func (r *topicRadius) getBucketIdx(addrHash common.Hash) int { prefix := binary.BigEndian.Uint64(addrHash[0:8]) var log2 float64 if prefix != r.topicHashPrefix { log2 = math.Log2(float64(prefix ^ r.topicHashPrefix)) } bucket := int((64 - log2) * radiusBucketsPerBit) max := 64*radiusBucketsPerBit - 1 if bucket > max { return max } if bucket < 0 { return 0 } return bucket } func (r *topicRadius) targetForBucket(bucket int) common.Hash { min := math.Pow(2, 64-float64(bucket+1)/radiusBucketsPerBit) max := math.Pow(2, 64-float64(bucket)/radiusBucketsPerBit) a := uint64(min) b := randUint64n(uint64(max - min)) xor := a + b if xor < a { xor = ^uint64(0) } prefix := r.topicHashPrefix ^ xor var target common.Hash binary.BigEndian.PutUint64(target[0:8], prefix) globalRandRead(target[8:]) return target } // package rand provides a Read function in Go 1.6 and later, but // we can't use it yet because we still support Go 1.5. func globalRandRead(b []byte) { pos := 0 val := 0 for n := 0; n < len(b); n++ { if pos == 0 { val = rand.Int() pos = 7 } b[n] = byte(val) val >>= 8 pos-- } } func (r *topicRadius) isInRadius(addrHash common.Hash) bool { nodePrefix := binary.BigEndian.Uint64(addrHash[0:8]) dist := nodePrefix ^ r.topicHashPrefix return dist < r.radius } func (r *topicRadius) chooseLookupBucket(a, b int) int { if a < 0 { a = 0 } if a > b { return -1 } c := 0 for i := a; i <= b; i++ { if i >= len(r.buckets) || r.buckets[i].weights[trNoAdjust] < maxNoAdjust { c++ } } if c == 0 { return -1 } rnd := randUint(uint32(c)) for i := a; i <= b; i++ { if i >= len(r.buckets) || r.buckets[i].weights[trNoAdjust] < maxNoAdjust { if rnd == 0 { return i } rnd-- } } panic(nil) // should never happen } func (r *topicRadius) needMoreLookups(a, b int, maxValue float64) bool { var max float64 if a < 0 { a = 0 } if b >= len(r.buckets) { b = len(r.buckets) - 1 if r.buckets[b].value > max { max = r.buckets[b].value } } if b >= a { for i := a; i <= b; i++ { if r.buckets[i].value > max { max = r.buckets[i].value } } } return maxValue-max < minPeakSize } func (r *topicRadius) recalcRadius() (radius uint64, radiusLookup int) { maxBucket := 0 maxValue := float64(0) now := mclock.Now() v := float64(0) for i := range r.buckets { r.buckets[i].update(now) v += r.buckets[i].weights[trOutside] - r.buckets[i].weights[trInside] r.buckets[i].value = v //fmt.Printf("%v %v | ", v, r.buckets[i].weights[trNoAdjust]) } //fmt.Println() slopeCross := -1 for i, b := range r.buckets { v := b.value if v < float64(i)*minSlope { slopeCross = i break } if v > maxValue { maxValue = v maxBucket = i + 1 } } minRadBucket := len(r.buckets) sum := float64(0) for minRadBucket > 0 && sum < minRightSum { minRadBucket-- b := r.buckets[minRadBucket] sum += b.weights[trInside] + b.weights[trOutside] } r.minRadius = uint64(math.Pow(2, 64-float64(minRadBucket)/radiusBucketsPerBit)) lookupLeft := -1 if r.needMoreLookups(0, maxBucket-lookupWidth-1, maxValue) { lookupLeft = r.chooseLookupBucket(maxBucket-lookupWidth, maxBucket-1) } lookupRight := -1 if slopeCross != maxBucket && (minRadBucket <= maxBucket || r.needMoreLookups(maxBucket+lookupWidth, len(r.buckets)-1, maxValue)) { for len(r.buckets) <= maxBucket+lookupWidth { r.buckets = append(r.buckets, topicRadiusBucket{lookupSent: make(map[common.Hash]mclock.AbsTime)}) } lookupRight = r.chooseLookupBucket(maxBucket, maxBucket+lookupWidth-1) } if lookupLeft == -1 { radiusLookup = lookupRight } else { if lookupRight == -1 { radiusLookup = lookupLeft } else { if randUint(2) == 0 { radiusLookup = lookupLeft } else { radiusLookup = lookupRight } } } //fmt.Println("mb", maxBucket, "sc", slopeCross, "mrb", minRadBucket, "ll", lookupLeft, "lr", lookupRight, "mv", maxValue) if radiusLookup == -1 { // no more radius lookups needed at the moment, return a radius r.converged = true rad := maxBucket if minRadBucket < rad { rad = minRadBucket } radius = ^uint64(0) if rad > 0 { radius = uint64(math.Pow(2, 64-float64(rad)/radiusBucketsPerBit)) } r.radius = radius } return } func (r *topicRadius) nextTarget(forceRegular bool) lookupInfo { if !forceRegular { _, radiusLookup := r.recalcRadius() if radiusLookup != -1 { target := r.targetForBucket(radiusLookup) r.buckets[radiusLookup].lookupSent[target] = mclock.Now() return lookupInfo{target: target, topic: r.topic, radiusLookup: true} } } radExt := r.radius / 2 if radExt > maxRadius-r.radius { radExt = maxRadius - r.radius } rnd := randUint64n(r.radius) + randUint64n(2*radExt) if rnd > radExt { rnd -= radExt } else { rnd = radExt - rnd } prefix := r.topicHashPrefix ^ rnd var target common.Hash binary.BigEndian.PutUint64(target[0:8], prefix) globalRandRead(target[8:]) return lookupInfo{target: target, topic: r.topic, radiusLookup: false} } func (r *topicRadius) adjustWithTicket(now mclock.AbsTime, targetHash common.Hash, t ticketRef) { wait := t.t.regTime[t.idx] - t.t.issueTime inside := float64(wait)/float64(targetWaitTime) - 0.5 if inside > 1 { inside = 1 } if inside < 0 { inside = 0 } r.adjust(now, targetHash, t.t.node.sha, inside) } func (r *topicRadius) adjust(now mclock.AbsTime, targetHash, addrHash common.Hash, inside float64) { bucket := r.getBucketIdx(addrHash) //fmt.Println("adjust", bucket, len(r.buckets), inside) if bucket >= len(r.buckets) { return } r.buckets[bucket].adjust(now, inside) delete(r.buckets[bucket].lookupSent, targetHash) }