github.com/Goplush/go-ethereum@v0.0.0-20191031044858-21506be82b68/les/serverpool.go (about) 1 // Copyright 2016 The go-ethereum Authors 2 // This file is part of the go-ethereum library. 3 // 4 // The go-ethereum library is free software: you can redistribute it and/or modify 5 // it under the terms of the GNU Lesser General Public License as published by 6 // the Free Software Foundation, either version 3 of the License, or 7 // (at your option) any later version. 8 // 9 // The go-ethereum library is distributed in the hope that it will be useful, 10 // but WITHOUT ANY WARRANTY; without even the implied warranty of 11 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 12 // GNU Lesser General Public License for more details. 13 // 14 // You should have received a copy of the GNU Lesser General Public License 15 // along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>. 16 17 package les 18 19 import ( 20 "crypto/ecdsa" 21 "fmt" 22 "io" 23 "math" 24 "math/rand" 25 "net" 26 "strconv" 27 "sync" 28 "time" 29 30 "github.com/Fantom-foundation/go-ethereum/common/mclock" 31 "github.com/Fantom-foundation/go-ethereum/crypto" 32 "github.com/Fantom-foundation/go-ethereum/ethdb" 33 "github.com/Fantom-foundation/go-ethereum/log" 34 "github.com/Fantom-foundation/go-ethereum/p2p" 35 "github.com/Fantom-foundation/go-ethereum/p2p/discv5" 36 "github.com/Fantom-foundation/go-ethereum/p2p/enode" 37 "github.com/Fantom-foundation/go-ethereum/rlp" 38 ) 39 40 const ( 41 // After a connection has been ended or timed out, there is a waiting period 42 // before it can be selected for connection again. 43 // waiting period = base delay * (1 + random(1)) 44 // base delay = shortRetryDelay for the first shortRetryCnt times after a 45 // successful connection, after that longRetryDelay is applied 46 shortRetryCnt = 5 47 shortRetryDelay = time.Second * 5 48 longRetryDelay = time.Minute * 10 49 // maxNewEntries is the maximum number of newly discovered (never connected) nodes. 50 // If the limit is reached, the least recently discovered one is thrown out. 51 maxNewEntries = 1000 52 // maxKnownEntries is the maximum number of known (already connected) nodes. 53 // If the limit is reached, the least recently connected one is thrown out. 54 // (not that unlike new entries, known entries are persistent) 55 maxKnownEntries = 1000 56 // target for simultaneously connected servers 57 targetServerCount = 5 58 // target for servers selected from the known table 59 // (we leave room for trying new ones if there is any) 60 targetKnownSelect = 3 61 // after dialTimeout, consider the server unavailable and adjust statistics 62 dialTimeout = time.Second * 30 63 // targetConnTime is the minimum expected connection duration before a server 64 // drops a client without any specific reason 65 targetConnTime = time.Minute * 10 66 // new entry selection weight calculation based on most recent discovery time: 67 // unity until discoverExpireStart, then exponential decay with discoverExpireConst 68 discoverExpireStart = time.Minute * 20 69 discoverExpireConst = time.Minute * 20 70 // known entry selection weight is dropped by a factor of exp(-failDropLn) after 71 // each unsuccessful connection (restored after a successful one) 72 failDropLn = 0.1 73 // known node connection success and quality statistics have a long term average 74 // and a short term value which is adjusted exponentially with a factor of 75 // pstatRecentAdjust with each dial/connection and also returned exponentially 76 // to the average with the time constant pstatReturnToMeanTC 77 pstatReturnToMeanTC = time.Hour 78 // node address selection weight is dropped by a factor of exp(-addrFailDropLn) after 79 // each unsuccessful connection (restored after a successful one) 80 addrFailDropLn = math.Ln2 81 // responseScoreTC and delayScoreTC are exponential decay time constants for 82 // calculating selection chances from response times and block delay times 83 responseScoreTC = time.Millisecond * 100 84 delayScoreTC = time.Second * 5 85 timeoutPow = 10 86 // initStatsWeight is used to initialize previously unknown peers with good 87 // statistics to give a chance to prove themselves 88 initStatsWeight = 1 89 ) 90 91 // connReq represents a request for peer connection. 92 type connReq struct { 93 p *peer 94 node *enode.Node 95 result chan *poolEntry 96 } 97 98 // disconnReq represents a request for peer disconnection. 99 type disconnReq struct { 100 entry *poolEntry 101 stopped bool 102 done chan struct{} 103 } 104 105 // registerReq represents a request for peer registration. 106 type registerReq struct { 107 entry *poolEntry 108 done chan struct{} 109 } 110 111 // serverPool implements a pool for storing and selecting newly discovered and already 112 // known light server nodes. It received discovered nodes, stores statistics about 113 // known nodes and takes care of always having enough good quality servers connected. 114 type serverPool struct { 115 db ethdb.Database 116 dbKey []byte 117 server *p2p.Server 118 connWg sync.WaitGroup 119 120 topic discv5.Topic 121 122 discSetPeriod chan time.Duration 123 discNodes chan *enode.Node 124 discLookups chan bool 125 126 trustedNodes map[enode.ID]*enode.Node 127 entries map[enode.ID]*poolEntry 128 timeout, enableRetry chan *poolEntry 129 adjustStats chan poolStatAdjust 130 131 knownQueue, newQueue poolEntryQueue 132 knownSelect, newSelect *weightedRandomSelect 133 knownSelected, newSelected int 134 fastDiscover bool 135 connCh chan *connReq 136 disconnCh chan *disconnReq 137 registerCh chan *registerReq 138 139 closeCh chan struct{} 140 wg sync.WaitGroup 141 } 142 143 // newServerPool creates a new serverPool instance 144 func newServerPool(db ethdb.Database, ulcServers []string) *serverPool { 145 pool := &serverPool{ 146 db: db, 147 entries: make(map[enode.ID]*poolEntry), 148 timeout: make(chan *poolEntry, 1), 149 adjustStats: make(chan poolStatAdjust, 100), 150 enableRetry: make(chan *poolEntry, 1), 151 connCh: make(chan *connReq), 152 disconnCh: make(chan *disconnReq), 153 registerCh: make(chan *registerReq), 154 closeCh: make(chan struct{}), 155 knownSelect: newWeightedRandomSelect(), 156 newSelect: newWeightedRandomSelect(), 157 fastDiscover: true, 158 trustedNodes: parseTrustedNodes(ulcServers), 159 } 160 161 pool.knownQueue = newPoolEntryQueue(maxKnownEntries, pool.removeEntry) 162 pool.newQueue = newPoolEntryQueue(maxNewEntries, pool.removeEntry) 163 return pool 164 } 165 166 func (pool *serverPool) start(server *p2p.Server, topic discv5.Topic) { 167 pool.server = server 168 pool.topic = topic 169 pool.dbKey = append([]byte("serverPool/"), []byte(topic)...) 170 pool.loadNodes() 171 pool.connectToTrustedNodes() 172 173 if pool.server.DiscV5 != nil { 174 pool.discSetPeriod = make(chan time.Duration, 1) 175 pool.discNodes = make(chan *enode.Node, 100) 176 pool.discLookups = make(chan bool, 100) 177 go pool.discoverNodes() 178 } 179 pool.checkDial() 180 pool.wg.Add(1) 181 go pool.eventLoop() 182 } 183 184 func (pool *serverPool) stop() { 185 close(pool.closeCh) 186 pool.wg.Wait() 187 } 188 189 // discoverNodes wraps SearchTopic, converting result nodes to enode.Node. 190 func (pool *serverPool) discoverNodes() { 191 ch := make(chan *discv5.Node) 192 go func() { 193 pool.server.DiscV5.SearchTopic(pool.topic, pool.discSetPeriod, ch, pool.discLookups) 194 close(ch) 195 }() 196 for n := range ch { 197 pubkey, err := decodePubkey64(n.ID[:]) 198 if err != nil { 199 continue 200 } 201 pool.discNodes <- enode.NewV4(pubkey, n.IP, int(n.TCP), int(n.UDP)) 202 } 203 } 204 205 // connect should be called upon any incoming connection. If the connection has been 206 // dialed by the server pool recently, the appropriate pool entry is returned. 207 // Otherwise, the connection should be rejected. 208 // Note that whenever a connection has been accepted and a pool entry has been returned, 209 // disconnect should also always be called. 210 func (pool *serverPool) connect(p *peer, node *enode.Node) *poolEntry { 211 log.Debug("Connect new entry", "enode", p.id) 212 req := &connReq{p: p, node: node, result: make(chan *poolEntry, 1)} 213 select { 214 case pool.connCh <- req: 215 case <-pool.closeCh: 216 return nil 217 } 218 return <-req.result 219 } 220 221 // registered should be called after a successful handshake 222 func (pool *serverPool) registered(entry *poolEntry) { 223 log.Debug("Registered new entry", "enode", entry.node.ID()) 224 req := ®isterReq{entry: entry, done: make(chan struct{})} 225 select { 226 case pool.registerCh <- req: 227 case <-pool.closeCh: 228 return 229 } 230 <-req.done 231 } 232 233 // disconnect should be called when ending a connection. Service quality statistics 234 // can be updated optionally (not updated if no registration happened, in this case 235 // only connection statistics are updated, just like in case of timeout) 236 func (pool *serverPool) disconnect(entry *poolEntry) { 237 stopped := false 238 select { 239 case <-pool.closeCh: 240 stopped = true 241 default: 242 } 243 log.Debug("Disconnected old entry", "enode", entry.node.ID()) 244 req := &disconnReq{entry: entry, stopped: stopped, done: make(chan struct{})} 245 246 // Block until disconnection request is served. 247 pool.disconnCh <- req 248 <-req.done 249 } 250 251 const ( 252 pseBlockDelay = iota 253 pseResponseTime 254 pseResponseTimeout 255 ) 256 257 // poolStatAdjust records are sent to adjust peer block delay/response time statistics 258 type poolStatAdjust struct { 259 adjustType int 260 entry *poolEntry 261 time time.Duration 262 } 263 264 // adjustBlockDelay adjusts the block announce delay statistics of a node 265 func (pool *serverPool) adjustBlockDelay(entry *poolEntry, time time.Duration) { 266 if entry == nil { 267 return 268 } 269 pool.adjustStats <- poolStatAdjust{pseBlockDelay, entry, time} 270 } 271 272 // adjustResponseTime adjusts the request response time statistics of a node 273 func (pool *serverPool) adjustResponseTime(entry *poolEntry, time time.Duration, timeout bool) { 274 if entry == nil { 275 return 276 } 277 if timeout { 278 pool.adjustStats <- poolStatAdjust{pseResponseTimeout, entry, time} 279 } else { 280 pool.adjustStats <- poolStatAdjust{pseResponseTime, entry, time} 281 } 282 } 283 284 // eventLoop handles pool events and mutex locking for all internal functions 285 func (pool *serverPool) eventLoop() { 286 defer pool.wg.Done() 287 lookupCnt := 0 288 var convTime mclock.AbsTime 289 if pool.discSetPeriod != nil { 290 pool.discSetPeriod <- time.Millisecond * 100 291 } 292 293 // disconnect updates service quality statistics depending on the connection time 294 // and disconnection initiator. 295 disconnect := func(req *disconnReq, stopped bool) { 296 // Handle peer disconnection requests. 297 entry := req.entry 298 if entry.state == psRegistered { 299 connAdjust := float64(mclock.Now()-entry.regTime) / float64(targetConnTime) 300 if connAdjust > 1 { 301 connAdjust = 1 302 } 303 if stopped { 304 // disconnect requested by ourselves. 305 entry.connectStats.add(1, connAdjust) 306 } else { 307 // disconnect requested by server side. 308 entry.connectStats.add(connAdjust, 1) 309 } 310 } 311 entry.state = psNotConnected 312 313 if entry.knownSelected { 314 pool.knownSelected-- 315 } else { 316 pool.newSelected-- 317 } 318 pool.setRetryDial(entry) 319 pool.connWg.Done() 320 close(req.done) 321 } 322 323 for { 324 select { 325 case entry := <-pool.timeout: 326 if !entry.removed { 327 pool.checkDialTimeout(entry) 328 } 329 330 case entry := <-pool.enableRetry: 331 if !entry.removed { 332 entry.delayedRetry = false 333 pool.updateCheckDial(entry) 334 } 335 336 case adj := <-pool.adjustStats: 337 switch adj.adjustType { 338 case pseBlockDelay: 339 adj.entry.delayStats.add(float64(adj.time), 1) 340 case pseResponseTime: 341 adj.entry.responseStats.add(float64(adj.time), 1) 342 adj.entry.timeoutStats.add(0, 1) 343 case pseResponseTimeout: 344 adj.entry.timeoutStats.add(1, 1) 345 } 346 347 case node := <-pool.discNodes: 348 if pool.trustedNodes[node.ID()] == nil { 349 entry := pool.findOrNewNode(node) 350 pool.updateCheckDial(entry) 351 } 352 353 case conv := <-pool.discLookups: 354 if conv { 355 if lookupCnt == 0 { 356 convTime = mclock.Now() 357 } 358 lookupCnt++ 359 if pool.fastDiscover && (lookupCnt == 50 || time.Duration(mclock.Now()-convTime) > time.Minute) { 360 pool.fastDiscover = false 361 if pool.discSetPeriod != nil { 362 pool.discSetPeriod <- time.Minute 363 } 364 } 365 } 366 367 case req := <-pool.connCh: 368 if pool.trustedNodes[req.p.ID()] != nil { 369 // ignore trusted nodes 370 req.result <- &poolEntry{trusted: true} 371 } else { 372 // Handle peer connection requests. 373 entry := pool.entries[req.p.ID()] 374 if entry == nil { 375 entry = pool.findOrNewNode(req.node) 376 } 377 if entry.state == psConnected || entry.state == psRegistered { 378 req.result <- nil 379 continue 380 } 381 pool.connWg.Add(1) 382 entry.peer = req.p 383 entry.state = psConnected 384 addr := &poolEntryAddress{ 385 ip: req.node.IP(), 386 port: uint16(req.node.TCP()), 387 lastSeen: mclock.Now(), 388 } 389 entry.lastConnected = addr 390 entry.addr = make(map[string]*poolEntryAddress) 391 entry.addr[addr.strKey()] = addr 392 entry.addrSelect = *newWeightedRandomSelect() 393 entry.addrSelect.update(addr) 394 req.result <- entry 395 } 396 397 case req := <-pool.registerCh: 398 if req.entry.trusted { 399 continue 400 } 401 // Handle peer registration requests. 402 entry := req.entry 403 entry.state = psRegistered 404 entry.regTime = mclock.Now() 405 if !entry.known { 406 pool.newQueue.remove(entry) 407 entry.known = true 408 } 409 pool.knownQueue.setLatest(entry) 410 entry.shortRetry = shortRetryCnt 411 close(req.done) 412 413 case req := <-pool.disconnCh: 414 if req.entry.trusted { 415 continue 416 } 417 // Handle peer disconnection requests. 418 disconnect(req, req.stopped) 419 420 case <-pool.closeCh: 421 if pool.discSetPeriod != nil { 422 close(pool.discSetPeriod) 423 } 424 425 // Spawn a goroutine to close the disconnCh after all connections are disconnected. 426 go func() { 427 pool.connWg.Wait() 428 close(pool.disconnCh) 429 }() 430 431 // Handle all remaining disconnection requests before exit. 432 for req := range pool.disconnCh { 433 disconnect(req, true) 434 } 435 pool.saveNodes() 436 return 437 } 438 } 439 } 440 441 func (pool *serverPool) findOrNewNode(node *enode.Node) *poolEntry { 442 now := mclock.Now() 443 entry := pool.entries[node.ID()] 444 if entry == nil { 445 log.Debug("Discovered new entry", "id", node.ID()) 446 entry = &poolEntry{ 447 node: node, 448 addr: make(map[string]*poolEntryAddress), 449 addrSelect: *newWeightedRandomSelect(), 450 shortRetry: shortRetryCnt, 451 } 452 pool.entries[node.ID()] = entry 453 // initialize previously unknown peers with good statistics to give a chance to prove themselves 454 entry.connectStats.add(1, initStatsWeight) 455 entry.delayStats.add(0, initStatsWeight) 456 entry.responseStats.add(0, initStatsWeight) 457 entry.timeoutStats.add(0, initStatsWeight) 458 } 459 entry.lastDiscovered = now 460 addr := &poolEntryAddress{ip: node.IP(), port: uint16(node.TCP())} 461 if a, ok := entry.addr[addr.strKey()]; ok { 462 addr = a 463 } else { 464 entry.addr[addr.strKey()] = addr 465 } 466 addr.lastSeen = now 467 entry.addrSelect.update(addr) 468 if !entry.known { 469 pool.newQueue.setLatest(entry) 470 } 471 return entry 472 } 473 474 // loadNodes loads known nodes and their statistics from the database 475 func (pool *serverPool) loadNodes() { 476 enc, err := pool.db.Get(pool.dbKey) 477 if err != nil { 478 return 479 } 480 var list []*poolEntry 481 err = rlp.DecodeBytes(enc, &list) 482 if err != nil { 483 log.Debug("Failed to decode node list", "err", err) 484 return 485 } 486 for _, e := range list { 487 log.Debug("Loaded server stats", "id", e.node.ID(), "fails", e.lastConnected.fails, 488 "conn", fmt.Sprintf("%v/%v", e.connectStats.avg, e.connectStats.weight), 489 "delay", fmt.Sprintf("%v/%v", time.Duration(e.delayStats.avg), e.delayStats.weight), 490 "response", fmt.Sprintf("%v/%v", time.Duration(e.responseStats.avg), e.responseStats.weight), 491 "timeout", fmt.Sprintf("%v/%v", e.timeoutStats.avg, e.timeoutStats.weight)) 492 pool.entries[e.node.ID()] = e 493 if pool.trustedNodes[e.node.ID()] == nil { 494 pool.knownQueue.setLatest(e) 495 pool.knownSelect.update((*knownEntry)(e)) 496 } 497 } 498 } 499 500 // connectToTrustedNodes adds trusted server nodes as static trusted peers. 501 // 502 // Note: trusted nodes are not handled by the server pool logic, they are not 503 // added to either the known or new selection pools. They are connected/reconnected 504 // by p2p.Server whenever possible. 505 func (pool *serverPool) connectToTrustedNodes() { 506 //connect to trusted nodes 507 for _, node := range pool.trustedNodes { 508 pool.server.AddTrustedPeer(node) 509 pool.server.AddPeer(node) 510 log.Debug("Added trusted node", "id", node.ID().String()) 511 } 512 } 513 514 // parseTrustedNodes returns valid and parsed enodes 515 func parseTrustedNodes(trustedNodes []string) map[enode.ID]*enode.Node { 516 nodes := make(map[enode.ID]*enode.Node) 517 518 for _, node := range trustedNodes { 519 node, err := enode.Parse(enode.ValidSchemes, node) 520 if err != nil { 521 log.Warn("Trusted node URL invalid", "enode", node, "err", err) 522 continue 523 } 524 nodes[node.ID()] = node 525 } 526 return nodes 527 } 528 529 // saveNodes saves known nodes and their statistics into the database. Nodes are 530 // ordered from least to most recently connected. 531 func (pool *serverPool) saveNodes() { 532 list := make([]*poolEntry, len(pool.knownQueue.queue)) 533 for i := range list { 534 list[i] = pool.knownQueue.fetchOldest() 535 } 536 enc, err := rlp.EncodeToBytes(list) 537 if err == nil { 538 pool.db.Put(pool.dbKey, enc) 539 } 540 } 541 542 // removeEntry removes a pool entry when the entry count limit is reached. 543 // Note that it is called by the new/known queues from which the entry has already 544 // been removed so removing it from the queues is not necessary. 545 func (pool *serverPool) removeEntry(entry *poolEntry) { 546 pool.newSelect.remove((*discoveredEntry)(entry)) 547 pool.knownSelect.remove((*knownEntry)(entry)) 548 entry.removed = true 549 delete(pool.entries, entry.node.ID()) 550 } 551 552 // setRetryDial starts the timer which will enable dialing a certain node again 553 func (pool *serverPool) setRetryDial(entry *poolEntry) { 554 delay := longRetryDelay 555 if entry.shortRetry > 0 { 556 entry.shortRetry-- 557 delay = shortRetryDelay 558 } 559 delay += time.Duration(rand.Int63n(int64(delay) + 1)) 560 entry.delayedRetry = true 561 go func() { 562 select { 563 case <-pool.closeCh: 564 case <-time.After(delay): 565 select { 566 case <-pool.closeCh: 567 case pool.enableRetry <- entry: 568 } 569 } 570 }() 571 } 572 573 // updateCheckDial is called when an entry can potentially be dialed again. It updates 574 // its selection weights and checks if new dials can/should be made. 575 func (pool *serverPool) updateCheckDial(entry *poolEntry) { 576 pool.newSelect.update((*discoveredEntry)(entry)) 577 pool.knownSelect.update((*knownEntry)(entry)) 578 pool.checkDial() 579 } 580 581 // checkDial checks if new dials can/should be made. It tries to select servers both 582 // based on good statistics and recent discovery. 583 func (pool *serverPool) checkDial() { 584 fillWithKnownSelects := !pool.fastDiscover 585 for pool.knownSelected < targetKnownSelect { 586 entry := pool.knownSelect.choose() 587 if entry == nil { 588 fillWithKnownSelects = false 589 break 590 } 591 pool.dial((*poolEntry)(entry.(*knownEntry)), true) 592 } 593 for pool.knownSelected+pool.newSelected < targetServerCount { 594 entry := pool.newSelect.choose() 595 if entry == nil { 596 break 597 } 598 pool.dial((*poolEntry)(entry.(*discoveredEntry)), false) 599 } 600 if fillWithKnownSelects { 601 // no more newly discovered nodes to select and since fast discover period 602 // is over, we probably won't find more in the near future so select more 603 // known entries if possible 604 for pool.knownSelected < targetServerCount { 605 entry := pool.knownSelect.choose() 606 if entry == nil { 607 break 608 } 609 pool.dial((*poolEntry)(entry.(*knownEntry)), true) 610 } 611 } 612 } 613 614 // dial initiates a new connection 615 func (pool *serverPool) dial(entry *poolEntry, knownSelected bool) { 616 if pool.server == nil || entry.state != psNotConnected { 617 return 618 } 619 entry.state = psDialed 620 entry.knownSelected = knownSelected 621 if knownSelected { 622 pool.knownSelected++ 623 } else { 624 pool.newSelected++ 625 } 626 addr := entry.addrSelect.choose().(*poolEntryAddress) 627 log.Debug("Dialing new peer", "lesaddr", entry.node.ID().String()+"@"+addr.strKey(), "set", len(entry.addr), "known", knownSelected) 628 entry.dialed = addr 629 go func() { 630 pool.server.AddPeer(entry.node) 631 select { 632 case <-pool.closeCh: 633 case <-time.After(dialTimeout): 634 select { 635 case <-pool.closeCh: 636 case pool.timeout <- entry: 637 } 638 } 639 }() 640 } 641 642 // checkDialTimeout checks if the node is still in dialed state and if so, resets it 643 // and adjusts connection statistics accordingly. 644 func (pool *serverPool) checkDialTimeout(entry *poolEntry) { 645 if entry.state != psDialed { 646 return 647 } 648 log.Debug("Dial timeout", "lesaddr", entry.node.ID().String()+"@"+entry.dialed.strKey()) 649 entry.state = psNotConnected 650 if entry.knownSelected { 651 pool.knownSelected-- 652 } else { 653 pool.newSelected-- 654 } 655 entry.connectStats.add(0, 1) 656 entry.dialed.fails++ 657 pool.setRetryDial(entry) 658 } 659 660 const ( 661 psNotConnected = iota 662 psDialed 663 psConnected 664 psRegistered 665 ) 666 667 // poolEntry represents a server node and stores its current state and statistics. 668 type poolEntry struct { 669 peer *peer 670 pubkey [64]byte // secp256k1 key of the node 671 addr map[string]*poolEntryAddress 672 node *enode.Node 673 lastConnected, dialed *poolEntryAddress 674 addrSelect weightedRandomSelect 675 676 lastDiscovered mclock.AbsTime 677 known, knownSelected, trusted bool 678 connectStats, delayStats poolStats 679 responseStats, timeoutStats poolStats 680 state int 681 regTime mclock.AbsTime 682 queueIdx int 683 removed bool 684 685 delayedRetry bool 686 shortRetry int 687 } 688 689 // poolEntryEnc is the RLP encoding of poolEntry. 690 type poolEntryEnc struct { 691 Pubkey []byte 692 IP net.IP 693 Port uint16 694 Fails uint 695 CStat, DStat, RStat, TStat poolStats 696 } 697 698 func (e *poolEntry) EncodeRLP(w io.Writer) error { 699 return rlp.Encode(w, &poolEntryEnc{ 700 Pubkey: encodePubkey64(e.node.Pubkey()), 701 IP: e.lastConnected.ip, 702 Port: e.lastConnected.port, 703 Fails: e.lastConnected.fails, 704 CStat: e.connectStats, 705 DStat: e.delayStats, 706 RStat: e.responseStats, 707 TStat: e.timeoutStats, 708 }) 709 } 710 711 func (e *poolEntry) DecodeRLP(s *rlp.Stream) error { 712 var entry poolEntryEnc 713 if err := s.Decode(&entry); err != nil { 714 return err 715 } 716 pubkey, err := decodePubkey64(entry.Pubkey) 717 if err != nil { 718 return err 719 } 720 addr := &poolEntryAddress{ip: entry.IP, port: entry.Port, fails: entry.Fails, lastSeen: mclock.Now()} 721 e.node = enode.NewV4(pubkey, entry.IP, int(entry.Port), int(entry.Port)) 722 e.addr = make(map[string]*poolEntryAddress) 723 e.addr[addr.strKey()] = addr 724 e.addrSelect = *newWeightedRandomSelect() 725 e.addrSelect.update(addr) 726 e.lastConnected = addr 727 e.connectStats = entry.CStat 728 e.delayStats = entry.DStat 729 e.responseStats = entry.RStat 730 e.timeoutStats = entry.TStat 731 e.shortRetry = shortRetryCnt 732 e.known = true 733 return nil 734 } 735 736 func encodePubkey64(pub *ecdsa.PublicKey) []byte { 737 return crypto.FromECDSAPub(pub)[1:] 738 } 739 740 func decodePubkey64(b []byte) (*ecdsa.PublicKey, error) { 741 return crypto.UnmarshalPubkey(append([]byte{0x04}, b...)) 742 } 743 744 // discoveredEntry implements wrsItem 745 type discoveredEntry poolEntry 746 747 // Weight calculates random selection weight for newly discovered entries 748 func (e *discoveredEntry) Weight() int64 { 749 if e.state != psNotConnected || e.delayedRetry { 750 return 0 751 } 752 t := time.Duration(mclock.Now() - e.lastDiscovered) 753 if t <= discoverExpireStart { 754 return 1000000000 755 } 756 return int64(1000000000 * math.Exp(-float64(t-discoverExpireStart)/float64(discoverExpireConst))) 757 } 758 759 // knownEntry implements wrsItem 760 type knownEntry poolEntry 761 762 // Weight calculates random selection weight for known entries 763 func (e *knownEntry) Weight() int64 { 764 if e.state != psNotConnected || !e.known || e.delayedRetry { 765 return 0 766 } 767 return int64(1000000000 * e.connectStats.recentAvg() * math.Exp(-float64(e.lastConnected.fails)*failDropLn-e.responseStats.recentAvg()/float64(responseScoreTC)-e.delayStats.recentAvg()/float64(delayScoreTC)) * math.Pow(1-e.timeoutStats.recentAvg(), timeoutPow)) 768 } 769 770 // poolEntryAddress is a separate object because currently it is necessary to remember 771 // multiple potential network addresses for a pool entry. This will be removed after 772 // the final implementation of v5 discovery which will retrieve signed and serial 773 // numbered advertisements, making it clear which IP/port is the latest one. 774 type poolEntryAddress struct { 775 ip net.IP 776 port uint16 777 lastSeen mclock.AbsTime // last time it was discovered, connected or loaded from db 778 fails uint // connection failures since last successful connection (persistent) 779 } 780 781 func (a *poolEntryAddress) Weight() int64 { 782 t := time.Duration(mclock.Now() - a.lastSeen) 783 return int64(1000000*math.Exp(-float64(t)/float64(discoverExpireConst)-float64(a.fails)*addrFailDropLn)) + 1 784 } 785 786 func (a *poolEntryAddress) strKey() string { 787 return a.ip.String() + ":" + strconv.Itoa(int(a.port)) 788 } 789 790 // poolStats implement statistics for a certain quantity with a long term average 791 // and a short term value which is adjusted exponentially with a factor of 792 // pstatRecentAdjust with each update and also returned exponentially to the 793 // average with the time constant pstatReturnToMeanTC 794 type poolStats struct { 795 sum, weight, avg, recent float64 796 lastRecalc mclock.AbsTime 797 } 798 799 // init initializes stats with a long term sum/update count pair retrieved from the database 800 func (s *poolStats) init(sum, weight float64) { 801 s.sum = sum 802 s.weight = weight 803 var avg float64 804 if weight > 0 { 805 avg = s.sum / weight 806 } 807 s.avg = avg 808 s.recent = avg 809 s.lastRecalc = mclock.Now() 810 } 811 812 // recalc recalculates recent value return-to-mean and long term average 813 func (s *poolStats) recalc() { 814 now := mclock.Now() 815 s.recent = s.avg + (s.recent-s.avg)*math.Exp(-float64(now-s.lastRecalc)/float64(pstatReturnToMeanTC)) 816 if s.sum == 0 { 817 s.avg = 0 818 } else { 819 if s.sum > s.weight*1e30 { 820 s.avg = 1e30 821 } else { 822 s.avg = s.sum / s.weight 823 } 824 } 825 s.lastRecalc = now 826 } 827 828 // add updates the stats with a new value 829 func (s *poolStats) add(value, weight float64) { 830 s.weight += weight 831 s.sum += value * weight 832 s.recalc() 833 } 834 835 // recentAvg returns the short-term adjusted average 836 func (s *poolStats) recentAvg() float64 { 837 s.recalc() 838 return s.recent 839 } 840 841 func (s *poolStats) EncodeRLP(w io.Writer) error { 842 return rlp.Encode(w, []interface{}{math.Float64bits(s.sum), math.Float64bits(s.weight)}) 843 } 844 845 func (s *poolStats) DecodeRLP(st *rlp.Stream) error { 846 var stats struct { 847 SumUint, WeightUint uint64 848 } 849 if err := st.Decode(&stats); err != nil { 850 return err 851 } 852 s.init(math.Float64frombits(stats.SumUint), math.Float64frombits(stats.WeightUint)) 853 return nil 854 } 855 856 // poolEntryQueue keeps track of its least recently accessed entries and removes 857 // them when the number of entries reaches the limit 858 type poolEntryQueue struct { 859 queue map[int]*poolEntry // known nodes indexed by their latest lastConnCnt value 860 newPtr, oldPtr, maxCnt int 861 removeFromPool func(*poolEntry) 862 } 863 864 // newPoolEntryQueue returns a new poolEntryQueue 865 func newPoolEntryQueue(maxCnt int, removeFromPool func(*poolEntry)) poolEntryQueue { 866 return poolEntryQueue{queue: make(map[int]*poolEntry), maxCnt: maxCnt, removeFromPool: removeFromPool} 867 } 868 869 // fetchOldest returns and removes the least recently accessed entry 870 func (q *poolEntryQueue) fetchOldest() *poolEntry { 871 if len(q.queue) == 0 { 872 return nil 873 } 874 for { 875 if e := q.queue[q.oldPtr]; e != nil { 876 delete(q.queue, q.oldPtr) 877 q.oldPtr++ 878 return e 879 } 880 q.oldPtr++ 881 } 882 } 883 884 // remove removes an entry from the queue 885 func (q *poolEntryQueue) remove(entry *poolEntry) { 886 if q.queue[entry.queueIdx] == entry { 887 delete(q.queue, entry.queueIdx) 888 } 889 } 890 891 // setLatest adds or updates a recently accessed entry. It also checks if an old entry 892 // needs to be removed and removes it from the parent pool too with a callback function. 893 func (q *poolEntryQueue) setLatest(entry *poolEntry) { 894 if q.queue[entry.queueIdx] == entry { 895 delete(q.queue, entry.queueIdx) 896 } else { 897 if len(q.queue) == q.maxCnt { 898 e := q.fetchOldest() 899 q.remove(e) 900 q.removeFromPool(e) 901 } 902 } 903 entry.queueIdx = q.newPtr 904 q.queue[entry.queueIdx] = entry 905 q.newPtr++ 906 }