github.com/AlohaMobile/go-ethereum@v1.9.7/les/fetcher.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 "math/big" 21 "sync" 22 "time" 23 24 "github.com/ethereum/go-ethereum/common" 25 "github.com/ethereum/go-ethereum/common/mclock" 26 "github.com/ethereum/go-ethereum/consensus" 27 "github.com/ethereum/go-ethereum/core/rawdb" 28 "github.com/ethereum/go-ethereum/core/types" 29 "github.com/ethereum/go-ethereum/light" 30 "github.com/ethereum/go-ethereum/log" 31 ) 32 33 const ( 34 blockDelayTimeout = time.Second * 10 // timeout for a peer to announce a head that has already been confirmed by others 35 maxNodeCount = 20 // maximum number of fetcherTreeNode entries remembered for each peer 36 serverStateAvailable = 100 // number of recent blocks where state availability is assumed 37 ) 38 39 // lightFetcher implements retrieval of newly announced headers. It also provides a peerHasBlock function for the 40 // ODR system to ensure that we only request data related to a certain block from peers who have already processed 41 // and announced that block. 42 type lightFetcher struct { 43 handler *clientHandler 44 chain *light.LightChain 45 46 lock sync.Mutex // lock protects access to the fetcher's internal state variables except sent requests 47 maxConfirmedTd *big.Int 48 peers map[*peer]*fetcherPeerInfo 49 lastUpdateStats *updateStatsEntry 50 syncing bool 51 syncDone chan *peer 52 53 reqMu sync.RWMutex // reqMu protects access to sent header fetch requests 54 requested map[uint64]fetchRequest 55 deliverChn chan fetchResponse 56 timeoutChn chan uint64 57 requestTriggered bool 58 requestTrigger chan struct{} 59 lastTrustedHeader *types.Header 60 61 closeCh chan struct{} 62 wg sync.WaitGroup 63 } 64 65 // fetcherPeerInfo holds fetcher-specific information about each active peer 66 type fetcherPeerInfo struct { 67 root, lastAnnounced *fetcherTreeNode 68 nodeCnt int 69 confirmedTd *big.Int 70 bestConfirmed *fetcherTreeNode 71 nodeByHash map[common.Hash]*fetcherTreeNode 72 firstUpdateStats *updateStatsEntry 73 } 74 75 // fetcherTreeNode is a node of a tree that holds information about blocks recently 76 // announced and confirmed by a certain peer. Each new announce message from a peer 77 // adds nodes to the tree, based on the previous announced head and the reorg depth. 78 // There are three possible states for a tree node: 79 // - announced: not downloaded (known) yet, but we know its head, number and td 80 // - intermediate: not known, hash and td are empty, they are filled out when it becomes known 81 // - known: both announced by this peer and downloaded (from any peer). 82 // This structure makes it possible to always know which peer has a certain block, 83 // which is necessary for selecting a suitable peer for ODR requests and also for 84 // canonizing new heads. It also helps to always download the minimum necessary 85 // amount of headers with a single request. 86 type fetcherTreeNode struct { 87 hash common.Hash 88 number uint64 89 td *big.Int 90 known, requested bool 91 parent *fetcherTreeNode 92 children []*fetcherTreeNode 93 } 94 95 // fetchRequest represents a header download request 96 type fetchRequest struct { 97 hash common.Hash 98 amount uint64 99 peer *peer 100 sent mclock.AbsTime 101 timeout bool 102 } 103 104 // fetchResponse represents a header download response 105 type fetchResponse struct { 106 reqID uint64 107 headers []*types.Header 108 peer *peer 109 } 110 111 // newLightFetcher creates a new light fetcher 112 func newLightFetcher(h *clientHandler) *lightFetcher { 113 f := &lightFetcher{ 114 handler: h, 115 chain: h.backend.blockchain, 116 peers: make(map[*peer]*fetcherPeerInfo), 117 deliverChn: make(chan fetchResponse, 100), 118 requested: make(map[uint64]fetchRequest), 119 timeoutChn: make(chan uint64), 120 requestTrigger: make(chan struct{}, 1), 121 syncDone: make(chan *peer), 122 closeCh: make(chan struct{}), 123 maxConfirmedTd: big.NewInt(0), 124 } 125 h.backend.peers.notify(f) 126 127 f.wg.Add(1) 128 go f.syncLoop() 129 return f 130 } 131 132 func (f *lightFetcher) close() { 133 close(f.closeCh) 134 f.wg.Wait() 135 } 136 137 // syncLoop is the main event loop of the light fetcher 138 func (f *lightFetcher) syncLoop() { 139 defer f.wg.Done() 140 for { 141 select { 142 case <-f.closeCh: 143 return 144 // request loop keeps running until no further requests are necessary or possible 145 case <-f.requestTrigger: 146 f.lock.Lock() 147 var ( 148 rq *distReq 149 reqID uint64 150 syncing bool 151 ) 152 if !f.syncing { 153 rq, reqID, syncing = f.nextRequest() 154 } 155 f.requestTriggered = rq != nil 156 f.lock.Unlock() 157 158 if rq != nil { 159 if _, ok := <-f.handler.backend.reqDist.queue(rq); ok { 160 if syncing { 161 f.lock.Lock() 162 f.syncing = true 163 f.lock.Unlock() 164 } else { 165 go func() { 166 time.Sleep(softRequestTimeout) 167 f.reqMu.Lock() 168 req, ok := f.requested[reqID] 169 if ok { 170 req.timeout = true 171 f.requested[reqID] = req 172 } 173 f.reqMu.Unlock() 174 // keep starting new requests while possible 175 f.requestTrigger <- struct{}{} 176 }() 177 } 178 } else { 179 f.requestTrigger <- struct{}{} 180 } 181 } 182 case reqID := <-f.timeoutChn: 183 f.reqMu.Lock() 184 req, ok := f.requested[reqID] 185 if ok { 186 delete(f.requested, reqID) 187 } 188 f.reqMu.Unlock() 189 if ok { 190 f.handler.backend.serverPool.adjustResponseTime(req.peer.poolEntry, time.Duration(mclock.Now()-req.sent), true) 191 req.peer.Log().Debug("Fetching data timed out hard") 192 go f.handler.removePeer(req.peer.id) 193 } 194 case resp := <-f.deliverChn: 195 f.reqMu.Lock() 196 req, ok := f.requested[resp.reqID] 197 if ok && req.peer != resp.peer { 198 ok = false 199 } 200 if ok { 201 delete(f.requested, resp.reqID) 202 } 203 f.reqMu.Unlock() 204 if ok { 205 f.handler.backend.serverPool.adjustResponseTime(req.peer.poolEntry, time.Duration(mclock.Now()-req.sent), req.timeout) 206 } 207 f.lock.Lock() 208 if !ok || !(f.syncing || f.processResponse(req, resp)) { 209 resp.peer.Log().Debug("Failed processing response") 210 go f.handler.removePeer(resp.peer.id) 211 } 212 f.lock.Unlock() 213 case p := <-f.syncDone: 214 f.lock.Lock() 215 p.Log().Debug("Done synchronising with peer") 216 f.checkSyncedHeaders(p) 217 f.syncing = false 218 f.lock.Unlock() 219 f.requestTrigger <- struct{}{} // f.requestTriggered is always true here 220 } 221 } 222 } 223 224 // registerPeer adds a new peer to the fetcher's peer set 225 func (f *lightFetcher) registerPeer(p *peer) { 226 p.lock.Lock() 227 p.hasBlock = func(hash common.Hash, number uint64, hasState bool) bool { 228 return f.peerHasBlock(p, hash, number, hasState) 229 } 230 p.lock.Unlock() 231 232 f.lock.Lock() 233 defer f.lock.Unlock() 234 f.peers[p] = &fetcherPeerInfo{nodeByHash: make(map[common.Hash]*fetcherTreeNode)} 235 } 236 237 // unregisterPeer removes a new peer from the fetcher's peer set 238 func (f *lightFetcher) unregisterPeer(p *peer) { 239 p.lock.Lock() 240 p.hasBlock = nil 241 p.lock.Unlock() 242 243 f.lock.Lock() 244 defer f.lock.Unlock() 245 246 // check for potential timed out block delay statistics 247 f.checkUpdateStats(p, nil) 248 delete(f.peers, p) 249 } 250 251 // announce processes a new announcement message received from a peer, adding new 252 // nodes to the peer's block tree and removing old nodes if necessary 253 func (f *lightFetcher) announce(p *peer, head *announceData) { 254 f.lock.Lock() 255 defer f.lock.Unlock() 256 p.Log().Debug("Received new announcement", "number", head.Number, "hash", head.Hash, "reorg", head.ReorgDepth) 257 258 fp := f.peers[p] 259 if fp == nil { 260 p.Log().Debug("Announcement from unknown peer") 261 return 262 } 263 264 if fp.lastAnnounced != nil && head.Td.Cmp(fp.lastAnnounced.td) <= 0 { 265 // announced tds should be strictly monotonic 266 p.Log().Debug("Received non-monotonic td", "current", head.Td, "previous", fp.lastAnnounced.td) 267 go f.handler.removePeer(p.id) 268 return 269 } 270 271 n := fp.lastAnnounced 272 for i := uint64(0); i < head.ReorgDepth; i++ { 273 if n == nil { 274 break 275 } 276 n = n.parent 277 } 278 // n is now the reorg common ancestor, add a new branch of nodes 279 if n != nil && (head.Number >= n.number+maxNodeCount || head.Number <= n.number) { 280 // if announced head block height is lower or same as n or too far from it to add 281 // intermediate nodes then discard previous announcement info and trigger a resync 282 n = nil 283 fp.nodeCnt = 0 284 fp.nodeByHash = make(map[common.Hash]*fetcherTreeNode) 285 } 286 // check if the node count is too high to add new nodes, discard oldest ones if necessary 287 if n != nil { 288 // n is now the reorg common ancestor, add a new branch of nodes 289 // check if the node count is too high to add new nodes 290 locked := false 291 for uint64(fp.nodeCnt)+head.Number-n.number > maxNodeCount && fp.root != nil { 292 if !locked { 293 f.chain.LockChain() 294 defer f.chain.UnlockChain() 295 locked = true 296 } 297 // if one of root's children is canonical, keep it, delete other branches and root itself 298 var newRoot *fetcherTreeNode 299 for i, nn := range fp.root.children { 300 if rawdb.ReadCanonicalHash(f.handler.backend.chainDb, nn.number) == nn.hash { 301 fp.root.children = append(fp.root.children[:i], fp.root.children[i+1:]...) 302 nn.parent = nil 303 newRoot = nn 304 break 305 } 306 } 307 fp.deleteNode(fp.root) 308 if n == fp.root { 309 n = newRoot 310 } 311 fp.root = newRoot 312 if newRoot == nil || !f.checkKnownNode(p, newRoot) { 313 fp.bestConfirmed = nil 314 fp.confirmedTd = nil 315 } 316 317 if n == nil { 318 break 319 } 320 } 321 if n != nil { 322 for n.number < head.Number { 323 nn := &fetcherTreeNode{number: n.number + 1, parent: n} 324 n.children = append(n.children, nn) 325 n = nn 326 fp.nodeCnt++ 327 } 328 n.hash = head.Hash 329 n.td = head.Td 330 fp.nodeByHash[n.hash] = n 331 } 332 } 333 334 if n == nil { 335 // could not find reorg common ancestor or had to delete entire tree, a new root and a resync is needed 336 if fp.root != nil { 337 fp.deleteNode(fp.root) 338 } 339 n = &fetcherTreeNode{hash: head.Hash, number: head.Number, td: head.Td} 340 fp.root = n 341 fp.nodeCnt++ 342 fp.nodeByHash[n.hash] = n 343 fp.bestConfirmed = nil 344 fp.confirmedTd = nil 345 } 346 347 f.checkKnownNode(p, n) 348 p.lock.Lock() 349 p.headInfo = head 350 fp.lastAnnounced = n 351 p.lock.Unlock() 352 f.checkUpdateStats(p, nil) 353 if !f.requestTriggered { 354 f.requestTriggered = true 355 f.requestTrigger <- struct{}{} 356 } 357 } 358 359 // peerHasBlock returns true if we can assume the peer knows the given block 360 // based on its announcements 361 func (f *lightFetcher) peerHasBlock(p *peer, hash common.Hash, number uint64, hasState bool) bool { 362 f.lock.Lock() 363 defer f.lock.Unlock() 364 365 fp := f.peers[p] 366 if fp == nil || fp.root == nil { 367 return false 368 } 369 370 if hasState { 371 if fp.lastAnnounced == nil || fp.lastAnnounced.number > number+serverStateAvailable { 372 return false 373 } 374 } 375 376 if f.syncing { 377 // always return true when syncing 378 // false positives are acceptable, a more sophisticated condition can be implemented later 379 return true 380 } 381 382 if number >= fp.root.number { 383 // it is recent enough that if it is known, is should be in the peer's block tree 384 return fp.nodeByHash[hash] != nil 385 } 386 f.chain.LockChain() 387 defer f.chain.UnlockChain() 388 // if it's older than the peer's block tree root but it's in the same canonical chain 389 // as the root, we can still be sure the peer knows it 390 // 391 // when syncing, just check if it is part of the known chain, there is nothing better we 392 // can do since we do not know the most recent block hash yet 393 return rawdb.ReadCanonicalHash(f.handler.backend.chainDb, fp.root.number) == fp.root.hash && rawdb.ReadCanonicalHash(f.handler.backend.chainDb, number) == hash 394 } 395 396 // requestAmount calculates the amount of headers to be downloaded starting 397 // from a certain head backwards 398 func (f *lightFetcher) requestAmount(p *peer, n *fetcherTreeNode) uint64 { 399 amount := uint64(0) 400 nn := n 401 for nn != nil && !f.checkKnownNode(p, nn) { 402 nn = nn.parent 403 amount++ 404 } 405 if nn == nil { 406 amount = n.number 407 } 408 return amount 409 } 410 411 // requestedID tells if a certain reqID has been requested by the fetcher 412 func (f *lightFetcher) requestedID(reqID uint64) bool { 413 f.reqMu.RLock() 414 _, ok := f.requested[reqID] 415 f.reqMu.RUnlock() 416 return ok 417 } 418 419 // nextRequest selects the peer and announced head to be requested next, amount 420 // to be downloaded starting from the head backwards is also returned 421 func (f *lightFetcher) nextRequest() (*distReq, uint64, bool) { 422 var ( 423 bestHash common.Hash 424 bestAmount uint64 425 bestTd *big.Int 426 bestSyncing bool 427 ) 428 bestHash, bestAmount, bestTd, bestSyncing = f.findBestRequest() 429 430 if bestTd == f.maxConfirmedTd { 431 return nil, 0, false 432 } 433 434 var rq *distReq 435 reqID := genReqID() 436 if bestSyncing { 437 rq = f.newFetcherDistReqForSync(bestHash) 438 } else { 439 rq = f.newFetcherDistReq(bestHash, reqID, bestAmount) 440 } 441 return rq, reqID, bestSyncing 442 } 443 444 // findBestRequest finds the best head to request that has been announced by but not yet requested from a known peer. 445 // It also returns the announced Td (which should be verified after fetching the head), 446 // the necessary amount to request and whether a downloader sync is necessary instead of a normal header request. 447 func (f *lightFetcher) findBestRequest() (bestHash common.Hash, bestAmount uint64, bestTd *big.Int, bestSyncing bool) { 448 bestTd = f.maxConfirmedTd 449 bestSyncing = false 450 451 for p, fp := range f.peers { 452 for hash, n := range fp.nodeByHash { 453 if f.checkKnownNode(p, n) || n.requested { 454 continue 455 } 456 // if ulc mode is disabled, isTrustedHash returns true 457 amount := f.requestAmount(p, n) 458 if (bestTd == nil || n.td.Cmp(bestTd) > 0 || amount < bestAmount) && (f.isTrustedHash(hash) || f.maxConfirmedTd.Int64() == 0) { 459 bestHash = hash 460 bestTd = n.td 461 bestAmount = amount 462 bestSyncing = fp.bestConfirmed == nil || fp.root == nil || !f.checkKnownNode(p, fp.root) 463 } 464 } 465 } 466 return 467 } 468 469 // isTrustedHash checks if the block can be trusted by the minimum trusted fraction. 470 func (f *lightFetcher) isTrustedHash(hash common.Hash) bool { 471 // If ultra light cliet mode is disabled, trust all hashes 472 if f.handler.ulc == nil { 473 return true 474 } 475 // Ultra light enabled, only trust after enough confirmations 476 var agreed int 477 for peer, info := range f.peers { 478 if peer.trusted && info.nodeByHash[hash] != nil { 479 agreed++ 480 } 481 } 482 return 100*agreed/len(f.handler.ulc.keys) >= f.handler.ulc.fraction 483 } 484 485 func (f *lightFetcher) newFetcherDistReqForSync(bestHash common.Hash) *distReq { 486 return &distReq{ 487 getCost: func(dp distPeer) uint64 { 488 return 0 489 }, 490 canSend: func(dp distPeer) bool { 491 p := dp.(*peer) 492 f.lock.Lock() 493 defer f.lock.Unlock() 494 495 if p.onlyAnnounce { 496 return false 497 } 498 fp := f.peers[p] 499 return fp != nil && fp.nodeByHash[bestHash] != nil 500 }, 501 request: func(dp distPeer) func() { 502 if f.handler.ulc != nil { 503 // Keep last trusted header before sync 504 f.setLastTrustedHeader(f.chain.CurrentHeader()) 505 } 506 go func() { 507 p := dp.(*peer) 508 p.Log().Debug("Synchronisation started") 509 f.handler.synchronise(p) 510 f.syncDone <- p 511 }() 512 return nil 513 }, 514 } 515 } 516 517 // newFetcherDistReq creates a new request for the distributor. 518 func (f *lightFetcher) newFetcherDistReq(bestHash common.Hash, reqID uint64, bestAmount uint64) *distReq { 519 return &distReq{ 520 getCost: func(dp distPeer) uint64 { 521 p := dp.(*peer) 522 return p.GetRequestCost(GetBlockHeadersMsg, int(bestAmount)) 523 }, 524 canSend: func(dp distPeer) bool { 525 p := dp.(*peer) 526 f.lock.Lock() 527 defer f.lock.Unlock() 528 529 if p.onlyAnnounce { 530 return false 531 } 532 fp := f.peers[p] 533 if fp == nil { 534 return false 535 } 536 n := fp.nodeByHash[bestHash] 537 return n != nil && !n.requested 538 }, 539 request: func(dp distPeer) func() { 540 p := dp.(*peer) 541 f.lock.Lock() 542 fp := f.peers[p] 543 if fp != nil { 544 n := fp.nodeByHash[bestHash] 545 if n != nil { 546 n.requested = true 547 } 548 } 549 f.lock.Unlock() 550 551 cost := p.GetRequestCost(GetBlockHeadersMsg, int(bestAmount)) 552 p.fcServer.QueuedRequest(reqID, cost) 553 f.reqMu.Lock() 554 f.requested[reqID] = fetchRequest{hash: bestHash, amount: bestAmount, peer: p, sent: mclock.Now()} 555 f.reqMu.Unlock() 556 go func() { 557 time.Sleep(hardRequestTimeout) 558 f.timeoutChn <- reqID 559 }() 560 return func() { p.RequestHeadersByHash(reqID, cost, bestHash, int(bestAmount), 0, true) } 561 }, 562 } 563 } 564 565 // deliverHeaders delivers header download request responses for processing 566 func (f *lightFetcher) deliverHeaders(peer *peer, reqID uint64, headers []*types.Header) { 567 f.deliverChn <- fetchResponse{reqID: reqID, headers: headers, peer: peer} 568 } 569 570 // processResponse processes header download request responses, returns true if successful 571 func (f *lightFetcher) processResponse(req fetchRequest, resp fetchResponse) bool { 572 if uint64(len(resp.headers)) != req.amount || resp.headers[0].Hash() != req.hash { 573 req.peer.Log().Debug("Response content mismatch", "requested", len(resp.headers), "reqfrom", resp.headers[0], "delivered", req.amount, "delfrom", req.hash) 574 return false 575 } 576 headers := make([]*types.Header, req.amount) 577 for i, header := range resp.headers { 578 headers[int(req.amount)-1-i] = header 579 } 580 581 if _, err := f.chain.InsertHeaderChain(headers, 1); err != nil { 582 if err == consensus.ErrFutureBlock { 583 return true 584 } 585 log.Debug("Failed to insert header chain", "err", err) 586 return false 587 } 588 tds := make([]*big.Int, len(headers)) 589 for i, header := range headers { 590 td := f.chain.GetTd(header.Hash(), header.Number.Uint64()) 591 if td == nil { 592 log.Debug("Total difficulty not found for header", "index", i+1, "number", header.Number, "hash", header.Hash()) 593 return false 594 } 595 tds[i] = td 596 } 597 f.newHeaders(headers, tds) 598 return true 599 } 600 601 // newHeaders updates the block trees of all active peers according to a newly 602 // downloaded and validated batch or headers 603 func (f *lightFetcher) newHeaders(headers []*types.Header, tds []*big.Int) { 604 var maxTd *big.Int 605 606 for p, fp := range f.peers { 607 if !f.checkAnnouncedHeaders(fp, headers, tds) { 608 p.Log().Debug("Inconsistent announcement") 609 go f.handler.removePeer(p.id) 610 } 611 if fp.confirmedTd != nil && (maxTd == nil || maxTd.Cmp(fp.confirmedTd) > 0) { 612 maxTd = fp.confirmedTd 613 } 614 } 615 616 if maxTd != nil { 617 f.updateMaxConfirmedTd(maxTd) 618 } 619 } 620 621 // checkAnnouncedHeaders updates peer's block tree if necessary after validating 622 // a batch of headers. It searches for the latest header in the batch that has a 623 // matching tree node (if any), and if it has not been marked as known already, 624 // sets it and its parents to known (even those which are older than the currently 625 // validated ones). Return value shows if all hashes, numbers and Tds matched 626 // correctly to the announced values (otherwise the peer should be dropped). 627 func (f *lightFetcher) checkAnnouncedHeaders(fp *fetcherPeerInfo, headers []*types.Header, tds []*big.Int) bool { 628 var ( 629 n *fetcherTreeNode 630 header *types.Header 631 td *big.Int 632 ) 633 634 for i := len(headers) - 1; ; i-- { 635 if i < 0 { 636 if n == nil { 637 // no more headers and nothing to match 638 return true 639 } 640 // we ran out of recently delivered headers but have not reached a node known by this peer yet, continue matching 641 hash, number := header.ParentHash, header.Number.Uint64()-1 642 td = f.chain.GetTd(hash, number) 643 header = f.chain.GetHeader(hash, number) 644 if header == nil || td == nil { 645 log.Error("Missing parent of validated header", "hash", hash, "number", number) 646 return false 647 } 648 } else { 649 header = headers[i] 650 td = tds[i] 651 } 652 hash := header.Hash() 653 number := header.Number.Uint64() 654 if n == nil { 655 n = fp.nodeByHash[hash] 656 } 657 if n != nil { 658 if n.td == nil { 659 // node was unannounced 660 if nn := fp.nodeByHash[hash]; nn != nil { 661 // if there was already a node with the same hash, continue there and drop this one 662 nn.children = append(nn.children, n.children...) 663 n.children = nil 664 fp.deleteNode(n) 665 n = nn 666 } else { 667 n.hash = hash 668 n.td = td 669 fp.nodeByHash[hash] = n 670 } 671 } 672 // check if it matches the header 673 if n.hash != hash || n.number != number || n.td.Cmp(td) != 0 { 674 // peer has previously made an invalid announcement 675 return false 676 } 677 if n.known { 678 // we reached a known node that matched our expectations, return with success 679 return true 680 } 681 n.known = true 682 if fp.confirmedTd == nil || td.Cmp(fp.confirmedTd) > 0 { 683 fp.confirmedTd = td 684 fp.bestConfirmed = n 685 } 686 n = n.parent 687 if n == nil { 688 return true 689 } 690 } 691 } 692 } 693 694 // checkSyncedHeaders updates peer's block tree after synchronisation by marking 695 // downloaded headers as known. If none of the announced headers are found after 696 // syncing, the peer is dropped. 697 func (f *lightFetcher) checkSyncedHeaders(p *peer) { 698 fp := f.peers[p] 699 if fp == nil { 700 p.Log().Debug("Unknown peer to check sync headers") 701 return 702 } 703 var ( 704 node = fp.lastAnnounced 705 td *big.Int 706 ) 707 if f.handler.ulc != nil { 708 // Roll back untrusted blocks 709 h, unapproved := f.lastTrustedTreeNode(p) 710 f.chain.Rollback(unapproved) 711 node = fp.nodeByHash[h.Hash()] 712 } 713 // Find last valid block 714 for node != nil { 715 if td = f.chain.GetTd(node.hash, node.number); td != nil { 716 break 717 } 718 node = node.parent 719 } 720 // Now node is the latest downloaded/approved header after syncing 721 if node == nil { 722 p.Log().Debug("Synchronisation failed") 723 go f.handler.removePeer(p.id) 724 return 725 } 726 header := f.chain.GetHeader(node.hash, node.number) 727 f.newHeaders([]*types.Header{header}, []*big.Int{td}) 728 } 729 730 // lastTrustedTreeNode return last approved treeNode and a list of unapproved hashes 731 func (f *lightFetcher) lastTrustedTreeNode(p *peer) (*types.Header, []common.Hash) { 732 unapprovedHashes := make([]common.Hash, 0) 733 current := f.chain.CurrentHeader() 734 735 if f.lastTrustedHeader == nil { 736 return current, unapprovedHashes 737 } 738 739 canonical := f.chain.CurrentHeader() 740 if canonical.Number.Uint64() > f.lastTrustedHeader.Number.Uint64() { 741 canonical = f.chain.GetHeaderByNumber(f.lastTrustedHeader.Number.Uint64()) 742 } 743 commonAncestor := rawdb.FindCommonAncestor(f.handler.backend.chainDb, canonical, f.lastTrustedHeader) 744 if commonAncestor == nil { 745 log.Error("Common ancestor of last trusted header and canonical header is nil", "canonical hash", canonical.Hash(), "trusted hash", f.lastTrustedHeader.Hash()) 746 return current, unapprovedHashes 747 } 748 749 for current.Hash() == commonAncestor.Hash() { 750 if f.isTrustedHash(current.Hash()) { 751 break 752 } 753 unapprovedHashes = append(unapprovedHashes, current.Hash()) 754 current = f.chain.GetHeader(current.ParentHash, current.Number.Uint64()-1) 755 } 756 return current, unapprovedHashes 757 } 758 759 func (f *lightFetcher) setLastTrustedHeader(h *types.Header) { 760 f.lock.Lock() 761 defer f.lock.Unlock() 762 f.lastTrustedHeader = h 763 } 764 765 // checkKnownNode checks if a block tree node is known (downloaded and validated) 766 // If it was not known previously but found in the database, sets its known flag 767 func (f *lightFetcher) checkKnownNode(p *peer, n *fetcherTreeNode) bool { 768 if n.known { 769 return true 770 } 771 td := f.chain.GetTd(n.hash, n.number) 772 if td == nil { 773 return false 774 } 775 header := f.chain.GetHeader(n.hash, n.number) 776 // check the availability of both header and td because reads are not protected by chain db mutex 777 // Note: returning false is always safe here 778 if header == nil { 779 return false 780 } 781 782 fp := f.peers[p] 783 if fp == nil { 784 p.Log().Debug("Unknown peer to check known nodes") 785 return false 786 } 787 if !f.checkAnnouncedHeaders(fp, []*types.Header{header}, []*big.Int{td}) { 788 p.Log().Debug("Inconsistent announcement") 789 go f.handler.removePeer(p.id) 790 } 791 if fp.confirmedTd != nil { 792 f.updateMaxConfirmedTd(fp.confirmedTd) 793 } 794 return n.known 795 } 796 797 // deleteNode deletes a node and its child subtrees from a peer's block tree 798 func (fp *fetcherPeerInfo) deleteNode(n *fetcherTreeNode) { 799 if n.parent != nil { 800 for i, nn := range n.parent.children { 801 if nn == n { 802 n.parent.children = append(n.parent.children[:i], n.parent.children[i+1:]...) 803 break 804 } 805 } 806 } 807 for { 808 if n.td != nil { 809 delete(fp.nodeByHash, n.hash) 810 } 811 fp.nodeCnt-- 812 if len(n.children) == 0 { 813 return 814 } 815 for i, nn := range n.children { 816 if i == 0 { 817 n = nn 818 } else { 819 fp.deleteNode(nn) 820 } 821 } 822 } 823 } 824 825 // updateStatsEntry items form a linked list that is expanded with a new item every time a new head with a higher Td 826 // than the previous one has been downloaded and validated. The list contains a series of maximum confirmed Td values 827 // and the time these values have been confirmed, both increasing monotonically. A maximum confirmed Td is calculated 828 // both globally for all peers and also for each individual peer (meaning that the given peer has announced the head 829 // and it has also been downloaded from any peer, either before or after the given announcement). 830 // The linked list has a global tail where new confirmed Td entries are added and a separate head for each peer, 831 // pointing to the next Td entry that is higher than the peer's max confirmed Td (nil if it has already confirmed 832 // the current global head). 833 type updateStatsEntry struct { 834 time mclock.AbsTime 835 td *big.Int 836 next *updateStatsEntry 837 } 838 839 // updateMaxConfirmedTd updates the block delay statistics of active peers. Whenever a new highest Td is confirmed, 840 // adds it to the end of a linked list together with the time it has been confirmed. Then checks which peers have 841 // already confirmed a head with the same or higher Td (which counts as zero block delay) and updates their statistics. 842 // Those who have not confirmed such a head by now will be updated by a subsequent checkUpdateStats call with a 843 // positive block delay value. 844 func (f *lightFetcher) updateMaxConfirmedTd(td *big.Int) { 845 if f.maxConfirmedTd == nil || td.Cmp(f.maxConfirmedTd) > 0 { 846 f.maxConfirmedTd = td 847 newEntry := &updateStatsEntry{ 848 time: mclock.Now(), 849 td: td, 850 } 851 if f.lastUpdateStats != nil { 852 f.lastUpdateStats.next = newEntry 853 } 854 855 f.lastUpdateStats = newEntry 856 for p := range f.peers { 857 f.checkUpdateStats(p, newEntry) 858 } 859 } 860 } 861 862 // checkUpdateStats checks those peers who have not confirmed a certain highest Td (or a larger one) by the time it 863 // has been confirmed by another peer. If they have confirmed such a head by now, their stats are updated with the 864 // block delay which is (this peer's confirmation time)-(first confirmation time). After blockDelayTimeout has passed, 865 // the stats are updated with blockDelayTimeout value. In either case, the confirmed or timed out updateStatsEntry 866 // items are removed from the head of the linked list. 867 // If a new entry has been added to the global tail, it is passed as a parameter here even though this function 868 // assumes that it has already been added, so that if the peer's list is empty (all heads confirmed, head is nil), 869 // it can set the new head to newEntry. 870 func (f *lightFetcher) checkUpdateStats(p *peer, newEntry *updateStatsEntry) { 871 now := mclock.Now() 872 fp := f.peers[p] 873 if fp == nil { 874 p.Log().Debug("Unknown peer to check update stats") 875 return 876 } 877 878 if newEntry != nil && fp.firstUpdateStats == nil { 879 fp.firstUpdateStats = newEntry 880 } 881 for fp.firstUpdateStats != nil && fp.firstUpdateStats.time <= now-mclock.AbsTime(blockDelayTimeout) { 882 f.handler.backend.serverPool.adjustBlockDelay(p.poolEntry, blockDelayTimeout) 883 fp.firstUpdateStats = fp.firstUpdateStats.next 884 } 885 if fp.confirmedTd != nil { 886 for fp.firstUpdateStats != nil && fp.firstUpdateStats.td.Cmp(fp.confirmedTd) <= 0 { 887 f.handler.backend.serverPool.adjustBlockDelay(p.poolEntry, time.Duration(now-fp.firstUpdateStats.time)) 888 fp.firstUpdateStats = fp.firstUpdateStats.next 889 } 890 } 891 }