github.com/codysnider/go-ethereum@v1.10.18-0.20220420071915-14f4ae99222a/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 "math/rand" 22 "sync" 23 "time" 24 25 "github.com/ethereum/go-ethereum/common" 26 "github.com/ethereum/go-ethereum/consensus" 27 "github.com/ethereum/go-ethereum/core" 28 "github.com/ethereum/go-ethereum/core/rawdb" 29 "github.com/ethereum/go-ethereum/core/types" 30 "github.com/ethereum/go-ethereum/ethdb" 31 "github.com/ethereum/go-ethereum/les/fetcher" 32 "github.com/ethereum/go-ethereum/light" 33 "github.com/ethereum/go-ethereum/log" 34 "github.com/ethereum/go-ethereum/p2p/enode" 35 ) 36 37 const ( 38 blockDelayTimeout = 10 * time.Second // Timeout for retrieving the headers from the peer 39 gatherSlack = 100 * time.Millisecond // Interval used to collate almost-expired requests 40 cachedAnnosThreshold = 64 // The maximum queued announcements 41 ) 42 43 // announce represents an new block announcement from the les server. 44 type announce struct { 45 data *announceData 46 trust bool 47 peerid enode.ID 48 } 49 50 // request represents a record when the header request is sent. 51 type request struct { 52 reqid uint64 53 peerid enode.ID 54 sendAt time.Time 55 hash common.Hash 56 } 57 58 // response represents a response packet from network as well as a channel 59 // to return all un-requested data. 60 type response struct { 61 reqid uint64 62 headers []*types.Header 63 peerid enode.ID 64 remain chan []*types.Header 65 } 66 67 // fetcherPeer holds the fetcher-specific information for each active peer 68 type fetcherPeer struct { 69 latest *announceData // The latest announcement sent from the peer 70 71 // These following two fields can track the latest announces 72 // from the peer with limited size for caching. We hold the 73 // assumption that all enqueued announces are td-monotonic. 74 announces map[common.Hash]*announce // Announcement map 75 fifo []common.Hash // FIFO announces list 76 } 77 78 // addAnno enqueues an new trusted announcement. If the queued announces overflow, 79 // evict from the oldest. 80 func (fp *fetcherPeer) addAnno(anno *announce) { 81 // Short circuit if the anno already exists. In normal case it should 82 // never happen since only monotonic anno is accepted. But the adversary 83 // may feed us fake announces with higher td but same hash. In this case, 84 // ignore the anno anyway. 85 hash := anno.data.Hash 86 if _, exist := fp.announces[hash]; exist { 87 return 88 } 89 fp.announces[hash] = anno 90 fp.fifo = append(fp.fifo, hash) 91 92 // Evict oldest if the announces are oversized. 93 if len(fp.fifo)-cachedAnnosThreshold > 0 { 94 for i := 0; i < len(fp.fifo)-cachedAnnosThreshold; i++ { 95 delete(fp.announces, fp.fifo[i]) 96 } 97 copy(fp.fifo, fp.fifo[len(fp.fifo)-cachedAnnosThreshold:]) 98 fp.fifo = fp.fifo[:cachedAnnosThreshold] 99 } 100 } 101 102 // forwardAnno removes all announces from the map with a number lower than 103 // the provided threshold. 104 func (fp *fetcherPeer) forwardAnno(td *big.Int) []*announce { 105 var ( 106 cutset int 107 evicted []*announce 108 ) 109 for ; cutset < len(fp.fifo); cutset++ { 110 anno := fp.announces[fp.fifo[cutset]] 111 if anno == nil { 112 continue // In theory it should never ever happen 113 } 114 if anno.data.Td.Cmp(td) > 0 { 115 break 116 } 117 evicted = append(evicted, anno) 118 delete(fp.announces, anno.data.Hash) 119 } 120 if cutset > 0 { 121 copy(fp.fifo, fp.fifo[cutset:]) 122 fp.fifo = fp.fifo[:len(fp.fifo)-cutset] 123 } 124 return evicted 125 } 126 127 // lightFetcher implements retrieval of newly announced headers. It reuses 128 // the eth.BlockFetcher as the underlying fetcher but adding more additional 129 // rules: e.g. evict "timeout" peers. 130 type lightFetcher struct { 131 // Various handlers 132 ulc *ulc 133 chaindb ethdb.Database 134 reqDist *requestDistributor 135 peerset *serverPeerSet // The global peerset of light client which shared by all components 136 chain *light.LightChain // The local light chain which maintains the canonical header chain. 137 fetcher *fetcher.BlockFetcher // The underlying fetcher which takes care block header retrieval. 138 139 // Peerset maintained by fetcher 140 plock sync.RWMutex 141 peers map[enode.ID]*fetcherPeer 142 143 // Various channels 144 announceCh chan *announce 145 requestCh chan *request 146 deliverCh chan *response 147 syncDone chan *types.Header 148 149 closeCh chan struct{} 150 wg sync.WaitGroup 151 152 // Callback 153 synchronise func(peer *serverPeer) 154 155 // Test fields or hooks 156 newHeadHook func(*types.Header) 157 } 158 159 // newLightFetcher creates a light fetcher instance. 160 func newLightFetcher(chain *light.LightChain, engine consensus.Engine, peers *serverPeerSet, ulc *ulc, chaindb ethdb.Database, reqDist *requestDistributor, syncFn func(p *serverPeer)) *lightFetcher { 161 // Construct the fetcher by offering all necessary APIs 162 validator := func(header *types.Header) error { 163 // Disable seal verification explicitly if we are running in ulc mode. 164 return engine.VerifyHeader(chain, header, ulc == nil) 165 } 166 heighter := func() uint64 { return chain.CurrentHeader().Number.Uint64() } 167 dropper := func(id string) { peers.unregister(id) } 168 inserter := func(headers []*types.Header) (int, error) { 169 // Disable PoW checking explicitly if we are running in ulc mode. 170 checkFreq := 1 171 if ulc != nil { 172 checkFreq = 0 173 } 174 return chain.InsertHeaderChain(headers, checkFreq) 175 } 176 f := &lightFetcher{ 177 ulc: ulc, 178 peerset: peers, 179 chaindb: chaindb, 180 chain: chain, 181 reqDist: reqDist, 182 fetcher: fetcher.NewBlockFetcher(true, chain.GetHeaderByHash, nil, validator, nil, heighter, inserter, nil, dropper), 183 peers: make(map[enode.ID]*fetcherPeer), 184 synchronise: syncFn, 185 announceCh: make(chan *announce), 186 requestCh: make(chan *request), 187 deliverCh: make(chan *response), 188 syncDone: make(chan *types.Header), 189 closeCh: make(chan struct{}), 190 } 191 peers.subscribe(f) 192 return f 193 } 194 195 func (f *lightFetcher) start() { 196 f.wg.Add(1) 197 f.fetcher.Start() 198 go f.mainloop() 199 } 200 201 func (f *lightFetcher) stop() { 202 close(f.closeCh) 203 f.fetcher.Stop() 204 f.wg.Wait() 205 } 206 207 // registerPeer adds an new peer to the fetcher's peer set 208 func (f *lightFetcher) registerPeer(p *serverPeer) { 209 f.plock.Lock() 210 defer f.plock.Unlock() 211 212 f.peers[p.ID()] = &fetcherPeer{announces: make(map[common.Hash]*announce)} 213 } 214 215 // unregisterPeer removes the specified peer from the fetcher's peer set 216 func (f *lightFetcher) unregisterPeer(p *serverPeer) { 217 f.plock.Lock() 218 defer f.plock.Unlock() 219 220 delete(f.peers, p.ID()) 221 } 222 223 // peer returns the peer from the fetcher peerset. 224 func (f *lightFetcher) peer(id enode.ID) *fetcherPeer { 225 f.plock.RLock() 226 defer f.plock.RUnlock() 227 228 return f.peers[id] 229 } 230 231 // forEachPeer iterates the fetcher peerset, abort the iteration if the 232 // callback returns false. 233 func (f *lightFetcher) forEachPeer(check func(id enode.ID, p *fetcherPeer) bool) { 234 f.plock.RLock() 235 defer f.plock.RUnlock() 236 237 for id, peer := range f.peers { 238 if !check(id, peer) { 239 return 240 } 241 } 242 } 243 244 // mainloop is the main event loop of the light fetcher, which is responsible for 245 // - announcement maintenance(ulc) 246 // If we are running in ultra light client mode, then all announcements from 247 // the trusted servers are maintained. If the same announcements from trusted 248 // servers reach the threshold, then the relevant header is requested for retrieval. 249 // 250 // - block header retrieval 251 // Whenever we receive announce with higher td compared with local chain, the 252 // request will be made for header retrieval. 253 // 254 // - re-sync trigger 255 // If the local chain lags too much, then the fetcher will enter "synnchronise" 256 // mode to retrieve missing headers in batch. 257 func (f *lightFetcher) mainloop() { 258 defer f.wg.Done() 259 260 var ( 261 syncInterval = uint64(1) // Interval used to trigger a light resync. 262 syncing bool // Indicator whether the client is syncing 263 264 ulc = f.ulc != nil 265 headCh = make(chan core.ChainHeadEvent, 100) 266 fetching = make(map[uint64]*request) 267 requestTimer = time.NewTimer(0) 268 269 // Local status 270 localHead = f.chain.CurrentHeader() 271 localTd = f.chain.GetTd(localHead.Hash(), localHead.Number.Uint64()) 272 ) 273 sub := f.chain.SubscribeChainHeadEvent(headCh) 274 defer sub.Unsubscribe() 275 276 // reset updates the local status with given header. 277 reset := func(header *types.Header) { 278 localHead = header 279 localTd = f.chain.GetTd(header.Hash(), header.Number.Uint64()) 280 } 281 // trustedHeader returns an indicator whether the header is regarded as 282 // trusted. If we are running in the ulc mode, only when we receive enough 283 // same announcement from trusted server, the header will be trusted. 284 trustedHeader := func(hash common.Hash, number uint64) (bool, []enode.ID) { 285 var ( 286 agreed []enode.ID 287 trusted bool 288 ) 289 f.forEachPeer(func(id enode.ID, p *fetcherPeer) bool { 290 if anno := p.announces[hash]; anno != nil && anno.trust && anno.data.Number == number { 291 agreed = append(agreed, id) 292 if 100*len(agreed)/len(f.ulc.keys) >= f.ulc.fraction { 293 trusted = true 294 return false // abort iteration 295 } 296 } 297 return true 298 }) 299 return trusted, agreed 300 } 301 for { 302 select { 303 case anno := <-f.announceCh: 304 peerid, data := anno.peerid, anno.data 305 log.Debug("Received new announce", "peer", peerid, "number", data.Number, "hash", data.Hash, "reorg", data.ReorgDepth) 306 307 peer := f.peer(peerid) 308 if peer == nil { 309 log.Debug("Receive announce from unknown peer", "peer", peerid) 310 continue 311 } 312 // Announced tds should be strictly monotonic, drop the peer if 313 // the announce is out-of-order. 314 if peer.latest != nil && data.Td.Cmp(peer.latest.Td) <= 0 { 315 f.peerset.unregister(peerid.String()) 316 log.Debug("Non-monotonic td", "peer", peerid, "current", data.Td, "previous", peer.latest.Td) 317 continue 318 } 319 peer.latest = data 320 321 // Filter out any stale announce, the local chain is ahead of announce 322 if localTd != nil && data.Td.Cmp(localTd) <= 0 { 323 continue 324 } 325 peer.addAnno(anno) 326 327 // If we are not syncing, try to trigger a single retrieval or re-sync 328 if !ulc && !syncing { 329 // Two scenarios lead to re-sync: 330 // - reorg happens 331 // - local chain lags 332 // We can't retrieve the parent of the announce by single retrieval 333 // in both cases, so resync is necessary. 334 if data.Number > localHead.Number.Uint64()+syncInterval || data.ReorgDepth > 0 { 335 syncing = true 336 go f.startSync(peerid) 337 log.Debug("Trigger light sync", "peer", peerid, "local", localHead.Number, "localhash", localHead.Hash(), "remote", data.Number, "remotehash", data.Hash) 338 continue 339 } 340 f.fetcher.Notify(peerid.String(), data.Hash, data.Number, time.Now(), f.requestHeaderByHash(peerid), nil) 341 log.Debug("Trigger header retrieval", "peer", peerid, "number", data.Number, "hash", data.Hash) 342 } 343 // Keep collecting announces from trusted server even we are syncing. 344 if ulc && anno.trust { 345 // Notify underlying fetcher to retrieve header or trigger a resync if 346 // we have receive enough announcements from trusted server. 347 trusted, agreed := trustedHeader(data.Hash, data.Number) 348 if trusted && !syncing { 349 if data.Number > localHead.Number.Uint64()+syncInterval || data.ReorgDepth > 0 { 350 syncing = true 351 go f.startSync(peerid) 352 log.Debug("Trigger trusted light sync", "local", localHead.Number, "localhash", localHead.Hash(), "remote", data.Number, "remotehash", data.Hash) 353 continue 354 } 355 p := agreed[rand.Intn(len(agreed))] 356 f.fetcher.Notify(p.String(), data.Hash, data.Number, time.Now(), f.requestHeaderByHash(p), nil) 357 log.Debug("Trigger trusted header retrieval", "number", data.Number, "hash", data.Hash) 358 } 359 } 360 361 case req := <-f.requestCh: 362 fetching[req.reqid] = req // Tracking all in-flight requests for response latency statistic. 363 if len(fetching) == 1 { 364 f.rescheduleTimer(fetching, requestTimer) 365 } 366 367 case <-requestTimer.C: 368 for reqid, request := range fetching { 369 if time.Since(request.sendAt) > blockDelayTimeout-gatherSlack { 370 delete(fetching, reqid) 371 f.peerset.unregister(request.peerid.String()) 372 log.Debug("Request timeout", "peer", request.peerid, "reqid", reqid) 373 } 374 } 375 f.rescheduleTimer(fetching, requestTimer) 376 377 case resp := <-f.deliverCh: 378 if req := fetching[resp.reqid]; req != nil { 379 delete(fetching, resp.reqid) 380 f.rescheduleTimer(fetching, requestTimer) 381 382 // The underlying fetcher does not check the consistency of request and response. 383 // The adversary can send the fake announces with invalid hash and number but always 384 // delivery some mismatched header. So it can't be punished by the underlying fetcher. 385 // We have to add two more rules here to detect. 386 if len(resp.headers) != 1 { 387 f.peerset.unregister(req.peerid.String()) 388 log.Debug("Deliver more than requested", "peer", req.peerid, "reqid", req.reqid) 389 continue 390 } 391 if resp.headers[0].Hash() != req.hash { 392 f.peerset.unregister(req.peerid.String()) 393 log.Debug("Deliver invalid header", "peer", req.peerid, "reqid", req.reqid) 394 continue 395 } 396 resp.remain <- f.fetcher.FilterHeaders(resp.peerid.String(), resp.headers, time.Now()) 397 } else { 398 // Discard the entire packet no matter it's a timeout response or unexpected one. 399 resp.remain <- resp.headers 400 } 401 402 case ev := <-headCh: 403 // Short circuit if we are still syncing. 404 if syncing { 405 continue 406 } 407 reset(ev.Block.Header()) 408 409 // Clean stale announcements from les-servers. 410 var droplist []enode.ID 411 f.forEachPeer(func(id enode.ID, p *fetcherPeer) bool { 412 removed := p.forwardAnno(localTd) 413 for _, anno := range removed { 414 if header := f.chain.GetHeaderByHash(anno.data.Hash); header != nil { 415 if header.Number.Uint64() != anno.data.Number { 416 droplist = append(droplist, id) 417 break 418 } 419 // In theory td should exists. 420 td := f.chain.GetTd(anno.data.Hash, anno.data.Number) 421 if td != nil && td.Cmp(anno.data.Td) != 0 { 422 droplist = append(droplist, id) 423 break 424 } 425 } 426 } 427 return true 428 }) 429 for _, id := range droplist { 430 f.peerset.unregister(id.String()) 431 log.Debug("Kicked out peer for invalid announcement") 432 } 433 if f.newHeadHook != nil { 434 f.newHeadHook(localHead) 435 } 436 437 case origin := <-f.syncDone: 438 syncing = false // Reset the status 439 440 // Rewind all untrusted headers for ulc mode. 441 if ulc { 442 head := f.chain.CurrentHeader() 443 ancestor := rawdb.FindCommonAncestor(f.chaindb, origin, head) 444 445 // Recap the ancestor with genesis header in case the ancestor 446 // is not found. It can happen the original head is before the 447 // checkpoint while the synced headers are after it. In this 448 // case there is no ancestor between them. 449 if ancestor == nil { 450 ancestor = f.chain.Genesis().Header() 451 } 452 var untrusted []common.Hash 453 for head.Number.Cmp(ancestor.Number) > 0 { 454 hash, number := head.Hash(), head.Number.Uint64() 455 if trusted, _ := trustedHeader(hash, number); trusted { 456 break 457 } 458 untrusted = append(untrusted, hash) 459 head = f.chain.GetHeader(head.ParentHash, number-1) 460 if head == nil { 461 break // all the synced headers will be dropped 462 } 463 } 464 if len(untrusted) > 0 { 465 for i, j := 0, len(untrusted)-1; i < j; i, j = i+1, j-1 { 466 untrusted[i], untrusted[j] = untrusted[j], untrusted[i] 467 } 468 f.chain.Rollback(untrusted) 469 } 470 } 471 // Reset local status. 472 reset(f.chain.CurrentHeader()) 473 if f.newHeadHook != nil { 474 f.newHeadHook(localHead) 475 } 476 log.Debug("light sync finished", "number", localHead.Number, "hash", localHead.Hash()) 477 478 case <-f.closeCh: 479 return 480 } 481 } 482 } 483 484 // announce processes a new announcement message received from a peer. 485 func (f *lightFetcher) announce(p *serverPeer, head *announceData) { 486 select { 487 case f.announceCh <- &announce{peerid: p.ID(), trust: p.trusted, data: head}: 488 case <-f.closeCh: 489 return 490 } 491 } 492 493 // trackRequest sends a reqID to main loop for in-flight request tracking. 494 func (f *lightFetcher) trackRequest(peerid enode.ID, reqid uint64, hash common.Hash) { 495 select { 496 case f.requestCh <- &request{reqid: reqid, peerid: peerid, sendAt: time.Now(), hash: hash}: 497 case <-f.closeCh: 498 } 499 } 500 501 // requestHeaderByHash constructs a header retrieval request and sends it to 502 // local request distributor. 503 // 504 // Note, we rely on the underlying eth/fetcher to retrieve and validate the 505 // response, so that we have to obey the rule of eth/fetcher which only accepts 506 // the response from given peer. 507 func (f *lightFetcher) requestHeaderByHash(peerid enode.ID) func(common.Hash) error { 508 return func(hash common.Hash) error { 509 req := &distReq{ 510 getCost: func(dp distPeer) uint64 { return dp.(*serverPeer).getRequestCost(GetBlockHeadersMsg, 1) }, 511 canSend: func(dp distPeer) bool { return dp.(*serverPeer).ID() == peerid }, 512 request: func(dp distPeer) func() { 513 peer, id := dp.(*serverPeer), rand.Uint64() 514 cost := peer.getRequestCost(GetBlockHeadersMsg, 1) 515 peer.fcServer.QueuedRequest(id, cost) 516 517 return func() { 518 f.trackRequest(peer.ID(), id, hash) 519 peer.requestHeadersByHash(id, hash, 1, 0, false) 520 } 521 }, 522 } 523 f.reqDist.queue(req) 524 return nil 525 } 526 } 527 528 // startSync invokes synchronisation callback to start syncing. 529 func (f *lightFetcher) startSync(id enode.ID) { 530 defer func(header *types.Header) { 531 f.syncDone <- header 532 }(f.chain.CurrentHeader()) 533 534 peer := f.peerset.peer(id.String()) 535 if peer == nil || peer.onlyAnnounce { 536 return 537 } 538 f.synchronise(peer) 539 } 540 541 // deliverHeaders delivers header download request responses for processing 542 func (f *lightFetcher) deliverHeaders(peer *serverPeer, reqid uint64, headers []*types.Header) []*types.Header { 543 remain := make(chan []*types.Header, 1) 544 select { 545 case f.deliverCh <- &response{reqid: reqid, headers: headers, peerid: peer.ID(), remain: remain}: 546 case <-f.closeCh: 547 return nil 548 } 549 return <-remain 550 } 551 552 // rescheduleTimer resets the specified timeout timer to the next request timeout. 553 func (f *lightFetcher) rescheduleTimer(requests map[uint64]*request, timer *time.Timer) { 554 // Short circuit if no inflight requests 555 if len(requests) == 0 { 556 timer.Stop() 557 return 558 } 559 // Otherwise find the earliest expiring request 560 earliest := time.Now() 561 for _, req := range requests { 562 if earliest.After(req.sendAt) { 563 earliest = req.sendAt 564 } 565 } 566 timer.Reset(blockDelayTimeout - time.Since(earliest)) 567 }