// Copyright 2015 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 downloader import ( "errors" "fmt" "math/big" "strings" "sync" "sync/atomic" "testing" "time" "github.com/ethereum/go-ethereum" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/core/rawdb" "github.com/ethereum/go-ethereum/core/types" "github.com/ethereum/go-ethereum/ethdb" "github.com/ethereum/go-ethereum/event" "github.com/ethereum/go-ethereum/trie" ) // Reduce some of the parameters to make the tester faster. func init() { maxForkAncestry = 10000 blockCacheItems = 1024 fsHeaderContCheck = 500 * time.Millisecond } // downloadTester is a test simulator for mocking out local block chain. type downloadTester struct { downloader *Downloader genesis *types.Block // Genesis blocks used by the tester and peers stateDb ethdb.Database // Database used by the tester for syncing from peers peerDb ethdb.Database // Database of the peers containing all data peers map[string]*downloadTesterPeer ownHashes []common.Hash // Hash chain belonging to the tester ownHeaders map[common.Hash]*types.Header // Headers belonging to the tester ownBlocks map[common.Hash]*types.Block // Blocks belonging to the tester ownReceipts map[common.Hash]types.Receipts // Receipts belonging to the tester ownChainTd map[common.Hash]*big.Int // Total difficulties of the blocks in the local chain ancientHeaders map[common.Hash]*types.Header // Ancient headers belonging to the tester ancientBlocks map[common.Hash]*types.Block // Ancient blocks belonging to the tester ancientReceipts map[common.Hash]types.Receipts // Ancient receipts belonging to the tester ancientChainTd map[common.Hash]*big.Int // Ancient total difficulties of the blocks in the local chain lock sync.RWMutex } // newTester creates a new downloader test mocker. func newTester() *downloadTester { tester := &downloadTester{ genesis: testGenesis, peerDb: testDB, peers: make(map[string]*downloadTesterPeer), ownHashes: []common.Hash{testGenesis.Hash()}, ownHeaders: map[common.Hash]*types.Header{testGenesis.Hash(): testGenesis.Header()}, ownBlocks: map[common.Hash]*types.Block{testGenesis.Hash(): testGenesis}, ownReceipts: map[common.Hash]types.Receipts{testGenesis.Hash(): nil}, ownChainTd: map[common.Hash]*big.Int{testGenesis.Hash(): testGenesis.Difficulty()}, // Initialize ancient store with test genesis block ancientHeaders: map[common.Hash]*types.Header{testGenesis.Hash(): testGenesis.Header()}, ancientBlocks: map[common.Hash]*types.Block{testGenesis.Hash(): testGenesis}, ancientReceipts: map[common.Hash]types.Receipts{testGenesis.Hash(): nil}, ancientChainTd: map[common.Hash]*big.Int{testGenesis.Hash(): testGenesis.Difficulty()}, } tester.stateDb = rawdb.NewMemoryDatabase() tester.stateDb.Put(testGenesis.Root().Bytes(), []byte{0x00}) tester.downloader = New(0, tester.stateDb, trie.NewSyncBloom(1, tester.stateDb), new(event.TypeMux), tester, nil, tester.dropPeer) return tester } // terminate aborts any operations on the embedded downloader and releases all // held resources. func (dl *downloadTester) terminate() { dl.downloader.Terminate() } // sync starts synchronizing with a remote peer, blocking until it completes. func (dl *downloadTester) sync(id string, td *big.Int, mode SyncMode) error { dl.lock.RLock() hash := dl.peers[id].chain.headBlock().Hash() // If no particular TD was requested, load from the peer's blockchain if td == nil { td = dl.peers[id].chain.td(hash) } dl.lock.RUnlock() // Synchronise with the chosen peer and ensure proper cleanup afterwards err := dl.downloader.synchronise(id, hash, td, mode) select { case <-dl.downloader.cancelCh: // Ok, downloader fully cancelled after sync cycle default: // Downloader is still accepting packets, can block a peer up panic("downloader active post sync cycle") // panic will be caught by tester } return err } // HasHeader checks if a header is present in the testers canonical chain. func (dl *downloadTester) HasHeader(hash common.Hash, number uint64) bool { return dl.GetHeaderByHash(hash) != nil } // HasBlock checks if a block is present in the testers canonical chain. func (dl *downloadTester) HasBlock(hash common.Hash, number uint64) bool { return dl.GetBlockByHash(hash) != nil } // HasFastBlock checks if a block is present in the testers canonical chain. func (dl *downloadTester) HasFastBlock(hash common.Hash, number uint64) bool { dl.lock.RLock() defer dl.lock.RUnlock() if _, ok := dl.ancientReceipts[hash]; ok { return true } _, ok := dl.ownReceipts[hash] return ok } // GetHeader retrieves a header from the testers canonical chain. func (dl *downloadTester) GetHeaderByHash(hash common.Hash) *types.Header { dl.lock.RLock() defer dl.lock.RUnlock() header := dl.ancientHeaders[hash] if header != nil { return header } return dl.ownHeaders[hash] } // GetBlock retrieves a block from the testers canonical chain. func (dl *downloadTester) GetBlockByHash(hash common.Hash) *types.Block { dl.lock.RLock() defer dl.lock.RUnlock() block := dl.ancientBlocks[hash] if block != nil { return block } return dl.ownBlocks[hash] } // CurrentHeader retrieves the current head header from the canonical chain. func (dl *downloadTester) CurrentHeader() *types.Header { dl.lock.RLock() defer dl.lock.RUnlock() for i := len(dl.ownHashes) - 1; i >= 0; i-- { if header := dl.ancientHeaders[dl.ownHashes[i]]; header != nil { return header } if header := dl.ownHeaders[dl.ownHashes[i]]; header != nil { return header } } return dl.genesis.Header() } // CurrentBlock retrieves the current head block from the canonical chain. func (dl *downloadTester) CurrentBlock() *types.Block { dl.lock.RLock() defer dl.lock.RUnlock() for i := len(dl.ownHashes) - 1; i >= 0; i-- { if block := dl.ancientBlocks[dl.ownHashes[i]]; block != nil { if _, err := dl.stateDb.Get(block.Root().Bytes()); err == nil { return block } return block } if block := dl.ownBlocks[dl.ownHashes[i]]; block != nil { if _, err := dl.stateDb.Get(block.Root().Bytes()); err == nil { return block } } } return dl.genesis } // CurrentFastBlock retrieves the current head fast-sync block from the canonical chain. func (dl *downloadTester) CurrentFastBlock() *types.Block { dl.lock.RLock() defer dl.lock.RUnlock() for i := len(dl.ownHashes) - 1; i >= 0; i-- { if block := dl.ancientBlocks[dl.ownHashes[i]]; block != nil { return block } if block := dl.ownBlocks[dl.ownHashes[i]]; block != nil { return block } } return dl.genesis } // FastSyncCommitHead manually sets the head block to a given hash. func (dl *downloadTester) FastSyncCommitHead(hash common.Hash) error { // For now only check that the state trie is correct if block := dl.GetBlockByHash(hash); block != nil { _, err := trie.NewSecure(block.Root(), trie.NewDatabase(dl.stateDb)) return err } return fmt.Errorf("non existent block: %x", hash[:4]) } // GetTd retrieves the block's total difficulty from the canonical chain. func (dl *downloadTester) GetTd(hash common.Hash, number uint64) *big.Int { dl.lock.RLock() defer dl.lock.RUnlock() if td := dl.ancientChainTd[hash]; td != nil { return td } return dl.ownChainTd[hash] } // InsertHeaderChain injects a new batch of headers into the simulated chain. func (dl *downloadTester) InsertHeaderChain(headers []*types.Header, checkFreq int) (i int, err error) { dl.lock.Lock() defer dl.lock.Unlock() // Do a quick check, as the blockchain.InsertHeaderChain doesn't insert anything in case of errors if _, ok := dl.ownHeaders[headers[0].ParentHash]; !ok { return 0, errors.New("unknown parent") } for i := 1; i < len(headers); i++ { if headers[i].ParentHash != headers[i-1].Hash() { return i, errors.New("unknown parent") } } // Do a full insert if pre-checks passed for i, header := range headers { if _, ok := dl.ownHeaders[header.Hash()]; ok { continue } if _, ok := dl.ownHeaders[header.ParentHash]; !ok { return i, errors.New("unknown parent") } dl.ownHashes = append(dl.ownHashes, header.Hash()) dl.ownHeaders[header.Hash()] = header dl.ownChainTd[header.Hash()] = new(big.Int).Add(dl.ownChainTd[header.ParentHash], header.Difficulty) } return len(headers), nil } // InsertChain injects a new batch of blocks into the simulated chain. func (dl *downloadTester) InsertChain(blocks types.Blocks) (i int, err error) { dl.lock.Lock() defer dl.lock.Unlock() for i, block := range blocks { if parent, ok := dl.ownBlocks[block.ParentHash()]; !ok { return i, errors.New("unknown parent") } else if _, err := dl.stateDb.Get(parent.Root().Bytes()); err != nil { return i, fmt.Errorf("unknown parent state %x: %v", parent.Root(), err) } if _, ok := dl.ownHeaders[block.Hash()]; !ok { dl.ownHashes = append(dl.ownHashes, block.Hash()) dl.ownHeaders[block.Hash()] = block.Header() } dl.ownBlocks[block.Hash()] = block dl.ownReceipts[block.Hash()] = make(types.Receipts, 0) dl.stateDb.Put(block.Root().Bytes(), []byte{0x00}) dl.ownChainTd[block.Hash()] = new(big.Int).Add(dl.ownChainTd[block.ParentHash()], block.Difficulty()) } return len(blocks), nil } // InsertReceiptChain injects a new batch of receipts into the simulated chain. func (dl *downloadTester) InsertReceiptChain(blocks types.Blocks, receipts []types.Receipts, ancientLimit uint64) (i int, err error) { dl.lock.Lock() defer dl.lock.Unlock() for i := 0; i < len(blocks) && i < len(receipts); i++ { if _, ok := dl.ownHeaders[blocks[i].Hash()]; !ok { return i, errors.New("unknown owner") } if _, ok := dl.ancientBlocks[blocks[i].ParentHash()]; !ok { if _, ok := dl.ownBlocks[blocks[i].ParentHash()]; !ok { return i, errors.New("unknown parent") } } if blocks[i].NumberU64() <= ancientLimit { dl.ancientBlocks[blocks[i].Hash()] = blocks[i] dl.ancientReceipts[blocks[i].Hash()] = receipts[i] // Migrate from active db to ancient db dl.ancientHeaders[blocks[i].Hash()] = blocks[i].Header() dl.ancientChainTd[blocks[i].Hash()] = new(big.Int).Add(dl.ancientChainTd[blocks[i].ParentHash()], blocks[i].Difficulty()) delete(dl.ownHeaders, blocks[i].Hash()) delete(dl.ownChainTd, blocks[i].Hash()) } else { dl.ownBlocks[blocks[i].Hash()] = blocks[i] dl.ownReceipts[blocks[i].Hash()] = receipts[i] } } return len(blocks), nil } // Rollback removes some recently added elements from the chain. func (dl *downloadTester) Rollback(hashes []common.Hash) { dl.lock.Lock() defer dl.lock.Unlock() for i := len(hashes) - 1; i >= 0; i-- { if dl.ownHashes[len(dl.ownHashes)-1] == hashes[i] { dl.ownHashes = dl.ownHashes[:len(dl.ownHashes)-1] } delete(dl.ownChainTd, hashes[i]) delete(dl.ownHeaders, hashes[i]) delete(dl.ownReceipts, hashes[i]) delete(dl.ownBlocks, hashes[i]) delete(dl.ancientChainTd, hashes[i]) delete(dl.ancientHeaders, hashes[i]) delete(dl.ancientReceipts, hashes[i]) delete(dl.ancientBlocks, hashes[i]) } } // newPeer registers a new block download source into the downloader. func (dl *downloadTester) newPeer(id string, version int, chain *testChain) error { dl.lock.Lock() defer dl.lock.Unlock() peer := &downloadTesterPeer{dl: dl, id: id, chain: chain} dl.peers[id] = peer return dl.downloader.RegisterPeer(id, version, peer) } // dropPeer simulates a hard peer removal from the connection pool. func (dl *downloadTester) dropPeer(id string) { dl.lock.Lock() defer dl.lock.Unlock() delete(dl.peers, id) dl.downloader.UnregisterPeer(id) } type downloadTesterPeer struct { dl *downloadTester id string lock sync.RWMutex chain *testChain missingStates map[common.Hash]bool // State entries that fast sync should not return } // Head constructs a function to retrieve a peer's current head hash // and total difficulty. func (dlp *downloadTesterPeer) Head() (common.Hash, *big.Int) { b := dlp.chain.headBlock() return b.Hash(), dlp.chain.td(b.Hash()) } // RequestHeadersByHash constructs a GetBlockHeaders function based on a hashed // origin; associated with a particular peer in the download tester. The returned // function can be used to retrieve batches of headers from the particular peer. func (dlp *downloadTesterPeer) RequestHeadersByHash(origin common.Hash, amount int, skip int, reverse bool) error { if reverse { panic("reverse header requests not supported") } result := dlp.chain.headersByHash(origin, amount, skip) go dlp.dl.downloader.DeliverHeaders(dlp.id, result) return nil } // RequestHeadersByNumber constructs a GetBlockHeaders function based on a numbered // origin; associated with a particular peer in the download tester. The returned // function can be used to retrieve batches of headers from the particular peer. func (dlp *downloadTesterPeer) RequestHeadersByNumber(origin uint64, amount int, skip int, reverse bool) error { if reverse { panic("reverse header requests not supported") } result := dlp.chain.headersByNumber(origin, amount, skip) go dlp.dl.downloader.DeliverHeaders(dlp.id, result) return nil } // RequestBodies constructs a getBlockBodies method associated with a particular // peer in the download tester. The returned function can be used to retrieve // batches of block bodies from the particularly requested peer. func (dlp *downloadTesterPeer) RequestBodies(hashes []common.Hash) error { txs, uncles := dlp.chain.bodies(hashes) go dlp.dl.downloader.DeliverBodies(dlp.id, txs, uncles) return nil } // RequestReceipts constructs a getReceipts method associated with a particular // peer in the download tester. The returned function can be used to retrieve // batches of block receipts from the particularly requested peer. func (dlp *downloadTesterPeer) RequestReceipts(hashes []common.Hash) error { receipts := dlp.chain.receipts(hashes) go dlp.dl.downloader.DeliverReceipts(dlp.id, receipts) return nil } // RequestNodeData constructs a getNodeData method associated with a particular // peer in the download tester. The returned function can be used to retrieve // batches of node state data from the particularly requested peer. func (dlp *downloadTesterPeer) RequestNodeData(hashes []common.Hash) error { dlp.dl.lock.RLock() defer dlp.dl.lock.RUnlock() results := make([][]byte, 0, len(hashes)) for _, hash := range hashes { if data, err := dlp.dl.peerDb.Get(hash.Bytes()); err == nil { if !dlp.missingStates[hash] { results = append(results, data) } } } go dlp.dl.downloader.DeliverNodeData(dlp.id, results) return nil } // assertOwnChain checks if the local chain contains the correct number of items // of the various chain components. func assertOwnChain(t *testing.T, tester *downloadTester, length int) { // Mark this method as a helper to report errors at callsite, not in here t.Helper() assertOwnForkedChain(t, tester, 1, []int{length}) } // assertOwnForkedChain checks if the local forked chain contains the correct // number of items of the various chain components. func assertOwnForkedChain(t *testing.T, tester *downloadTester, common int, lengths []int) { // Mark this method as a helper to report errors at callsite, not in here t.Helper() // Initialize the counters for the first fork headers, blocks, receipts := lengths[0], lengths[0], lengths[0] // Update the counters for each subsequent fork for _, length := range lengths[1:] { headers += length - common blocks += length - common receipts += length - common } if tester.downloader.mode == LightSync { blocks, receipts = 1, 1 } if hs := len(tester.ownHeaders) + len(tester.ancientHeaders) - 1; hs != headers { t.Fatalf("synchronised headers mismatch: have %v, want %v", hs, headers) } if bs := len(tester.ownBlocks) + len(tester.ancientBlocks) - 1; bs != blocks { t.Fatalf("synchronised blocks mismatch: have %v, want %v", bs, blocks) } if rs := len(tester.ownReceipts) + len(tester.ancientReceipts) - 1; rs != receipts { t.Fatalf("synchronised receipts mismatch: have %v, want %v", rs, receipts) } } // Tests that simple synchronization against a canonical chain works correctly. // In this test common ancestor lookup should be short circuited and not require // binary searching. func TestCanonicalSynchronisation62(t *testing.T) { testCanonicalSynchronisation(t, 62, FullSync) } func TestCanonicalSynchronisation63Full(t *testing.T) { testCanonicalSynchronisation(t, 63, FullSync) } func TestCanonicalSynchronisation63Fast(t *testing.T) { testCanonicalSynchronisation(t, 63, FastSync) } func TestCanonicalSynchronisation64Full(t *testing.T) { testCanonicalSynchronisation(t, 64, FullSync) } func TestCanonicalSynchronisation64Fast(t *testing.T) { testCanonicalSynchronisation(t, 64, FastSync) } func TestCanonicalSynchronisation64Light(t *testing.T) { testCanonicalSynchronisation(t, 64, LightSync) } func testCanonicalSynchronisation(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() // Create a small enough block chain to download chain := testChainBase.shorten(blockCacheItems - 15) tester.newPeer("peer", protocol, chain) // Synchronise with the peer and make sure all relevant data was retrieved if err := tester.sync("peer", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chain.len()) } // Tests that if a large batch of blocks are being downloaded, it is throttled // until the cached blocks are retrieved. func TestThrottling62(t *testing.T) { testThrottling(t, 62, FullSync) } func TestThrottling63Full(t *testing.T) { testThrottling(t, 63, FullSync) } func TestThrottling63Fast(t *testing.T) { testThrottling(t, 63, FastSync) } func TestThrottling64Full(t *testing.T) { testThrottling(t, 64, FullSync) } func TestThrottling64Fast(t *testing.T) { testThrottling(t, 64, FastSync) } func testThrottling(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() // Create a long block chain to download and the tester targetBlocks := testChainBase.len() - 1 tester.newPeer("peer", protocol, testChainBase) // Wrap the importer to allow stepping blocked, proceed := uint32(0), make(chan struct{}) tester.downloader.chainInsertHook = func(results []*fetchResult) { atomic.StoreUint32(&blocked, uint32(len(results))) <-proceed } // Start a synchronisation concurrently errc := make(chan error) go func() { errc <- tester.sync("peer", nil, mode) }() // Iteratively take some blocks, always checking the retrieval count for { // Check the retrieval count synchronously (! reason for this ugly block) tester.lock.RLock() retrieved := len(tester.ownBlocks) tester.lock.RUnlock() if retrieved >= targetBlocks+1 { break } // Wait a bit for sync to throttle itself var cached, frozen int for start := time.Now(); time.Since(start) < 3*time.Second; { time.Sleep(25 * time.Millisecond) tester.lock.Lock() tester.downloader.queue.lock.Lock() cached = len(tester.downloader.queue.blockDonePool) if mode == FastSync { if receipts := len(tester.downloader.queue.receiptDonePool); receipts < cached { cached = receipts } } frozen = int(atomic.LoadUint32(&blocked)) retrieved = len(tester.ownBlocks) tester.downloader.queue.lock.Unlock() tester.lock.Unlock() if cached == blockCacheItems || cached == blockCacheItems-reorgProtHeaderDelay || retrieved+cached+frozen == targetBlocks+1 || retrieved+cached+frozen == targetBlocks+1-reorgProtHeaderDelay { break } } // Make sure we filled up the cache, then exhaust it time.Sleep(25 * time.Millisecond) // give it a chance to screw up tester.lock.RLock() retrieved = len(tester.ownBlocks) tester.lock.RUnlock() if cached != blockCacheItems && cached != blockCacheItems-reorgProtHeaderDelay && retrieved+cached+frozen != targetBlocks+1 && retrieved+cached+frozen != targetBlocks+1-reorgProtHeaderDelay { t.Fatalf("block count mismatch: have %v, want %v (owned %v, blocked %v, target %v)", cached, blockCacheItems, retrieved, frozen, targetBlocks+1) } // Permit the blocked blocks to import if atomic.LoadUint32(&blocked) > 0 { atomic.StoreUint32(&blocked, uint32(0)) proceed <- struct{}{} } } // Check that we haven't pulled more blocks than available assertOwnChain(t, tester, targetBlocks+1) if err := <-errc; err != nil { t.Fatalf("block synchronization failed: %v", err) } } // Tests that simple synchronization against a forked chain works correctly. In // this test common ancestor lookup should *not* be short circuited, and a full // binary search should be executed. func TestForkedSync62(t *testing.T) { testForkedSync(t, 62, FullSync) } func TestForkedSync63Full(t *testing.T) { testForkedSync(t, 63, FullSync) } func TestForkedSync63Fast(t *testing.T) { testForkedSync(t, 63, FastSync) } func TestForkedSync64Full(t *testing.T) { testForkedSync(t, 64, FullSync) } func TestForkedSync64Fast(t *testing.T) { testForkedSync(t, 64, FastSync) } func TestForkedSync64Light(t *testing.T) { testForkedSync(t, 64, LightSync) } func testForkedSync(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chainA := testChainForkLightA.shorten(testChainBase.len() + 80) chainB := testChainForkLightB.shorten(testChainBase.len() + 80) tester.newPeer("fork A", protocol, chainA) tester.newPeer("fork B", protocol, chainB) // Synchronise with the peer and make sure all blocks were retrieved if err := tester.sync("fork A", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chainA.len()) // Synchronise with the second peer and make sure that fork is pulled too if err := tester.sync("fork B", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnForkedChain(t, tester, testChainBase.len(), []int{chainA.len(), chainB.len()}) } // Tests that synchronising against a much shorter but much heavyer fork works // corrently and is not dropped. func TestHeavyForkedSync62(t *testing.T) { testHeavyForkedSync(t, 62, FullSync) } func TestHeavyForkedSync63Full(t *testing.T) { testHeavyForkedSync(t, 63, FullSync) } func TestHeavyForkedSync63Fast(t *testing.T) { testHeavyForkedSync(t, 63, FastSync) } func TestHeavyForkedSync64Full(t *testing.T) { testHeavyForkedSync(t, 64, FullSync) } func TestHeavyForkedSync64Fast(t *testing.T) { testHeavyForkedSync(t, 64, FastSync) } func TestHeavyForkedSync64Light(t *testing.T) { testHeavyForkedSync(t, 64, LightSync) } func testHeavyForkedSync(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chainA := testChainForkLightA.shorten(testChainBase.len() + 80) chainB := testChainForkHeavy.shorten(testChainBase.len() + 80) tester.newPeer("light", protocol, chainA) tester.newPeer("heavy", protocol, chainB) // Synchronise with the peer and make sure all blocks were retrieved if err := tester.sync("light", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chainA.len()) // Synchronise with the second peer and make sure that fork is pulled too if err := tester.sync("heavy", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnForkedChain(t, tester, testChainBase.len(), []int{chainA.len(), chainB.len()}) } // Tests that chain forks are contained within a certain interval of the current // chain head, ensuring that malicious peers cannot waste resources by feeding // long dead chains. func TestBoundedForkedSync62(t *testing.T) { testBoundedForkedSync(t, 62, FullSync) } func TestBoundedForkedSync63Full(t *testing.T) { testBoundedForkedSync(t, 63, FullSync) } func TestBoundedForkedSync63Fast(t *testing.T) { testBoundedForkedSync(t, 63, FastSync) } func TestBoundedForkedSync64Full(t *testing.T) { testBoundedForkedSync(t, 64, FullSync) } func TestBoundedForkedSync64Fast(t *testing.T) { testBoundedForkedSync(t, 64, FastSync) } func TestBoundedForkedSync64Light(t *testing.T) { testBoundedForkedSync(t, 64, LightSync) } func testBoundedForkedSync(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chainA := testChainForkLightA chainB := testChainForkLightB tester.newPeer("original", protocol, chainA) tester.newPeer("rewriter", protocol, chainB) // Synchronise with the peer and make sure all blocks were retrieved if err := tester.sync("original", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chainA.len()) // Synchronise with the second peer and ensure that the fork is rejected to being too old if err := tester.sync("rewriter", nil, mode); err != errInvalidAncestor { t.Fatalf("sync failure mismatch: have %v, want %v", err, errInvalidAncestor) } } // Tests that chain forks are contained within a certain interval of the current // chain head for short but heavy forks too. These are a bit special because they // take different ancestor lookup paths. func TestBoundedHeavyForkedSync62(t *testing.T) { testBoundedHeavyForkedSync(t, 62, FullSync) } func TestBoundedHeavyForkedSync63Full(t *testing.T) { testBoundedHeavyForkedSync(t, 63, FullSync) } func TestBoundedHeavyForkedSync63Fast(t *testing.T) { testBoundedHeavyForkedSync(t, 63, FastSync) } func TestBoundedHeavyForkedSync64Full(t *testing.T) { testBoundedHeavyForkedSync(t, 64, FullSync) } func TestBoundedHeavyForkedSync64Fast(t *testing.T) { testBoundedHeavyForkedSync(t, 64, FastSync) } func TestBoundedHeavyForkedSync64Light(t *testing.T) { testBoundedHeavyForkedSync(t, 64, LightSync) } func testBoundedHeavyForkedSync(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() // Create a long enough forked chain chainA := testChainForkLightA chainB := testChainForkHeavy tester.newPeer("original", protocol, chainA) tester.newPeer("heavy-rewriter", protocol, chainB) // Synchronise with the peer and make sure all blocks were retrieved if err := tester.sync("original", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chainA.len()) // Synchronise with the second peer and ensure that the fork is rejected to being too old if err := tester.sync("heavy-rewriter", nil, mode); err != errInvalidAncestor { t.Fatalf("sync failure mismatch: have %v, want %v", err, errInvalidAncestor) } } // Tests that an inactive downloader will not accept incoming block headers and // bodies. func TestInactiveDownloader62(t *testing.T) { t.Parallel() tester := newTester() defer tester.terminate() // Check that neither block headers nor bodies are accepted if err := tester.downloader.DeliverHeaders("bad peer", []*types.Header{}); err != errNoSyncActive { t.Errorf("error mismatch: have %v, want %v", err, errNoSyncActive) } if err := tester.downloader.DeliverBodies("bad peer", [][]*types.Transaction{}, [][]*types.Header{}); err != errNoSyncActive { t.Errorf("error mismatch: have %v, want %v", err, errNoSyncActive) } } // Tests that an inactive downloader will not accept incoming block headers, // bodies and receipts. func TestInactiveDownloader63(t *testing.T) { t.Parallel() tester := newTester() defer tester.terminate() // Check that neither block headers nor bodies are accepted if err := tester.downloader.DeliverHeaders("bad peer", []*types.Header{}); err != errNoSyncActive { t.Errorf("error mismatch: have %v, want %v", err, errNoSyncActive) } if err := tester.downloader.DeliverBodies("bad peer", [][]*types.Transaction{}, [][]*types.Header{}); err != errNoSyncActive { t.Errorf("error mismatch: have %v, want %v", err, errNoSyncActive) } if err := tester.downloader.DeliverReceipts("bad peer", [][]*types.Receipt{}); err != errNoSyncActive { t.Errorf("error mismatch: have %v, want %v", err, errNoSyncActive) } } // Tests that a canceled download wipes all previously accumulated state. func TestCancel62(t *testing.T) { testCancel(t, 62, FullSync) } func TestCancel63Full(t *testing.T) { testCancel(t, 63, FullSync) } func TestCancel63Fast(t *testing.T) { testCancel(t, 63, FastSync) } func TestCancel64Full(t *testing.T) { testCancel(t, 64, FullSync) } func TestCancel64Fast(t *testing.T) { testCancel(t, 64, FastSync) } func TestCancel64Light(t *testing.T) { testCancel(t, 64, LightSync) } func testCancel(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chain := testChainBase.shorten(MaxHeaderFetch) tester.newPeer("peer", protocol, chain) // Make sure canceling works with a pristine downloader tester.downloader.Cancel() if !tester.downloader.queue.Idle() { t.Errorf("download queue not idle") } // Synchronise with the peer, but cancel afterwards if err := tester.sync("peer", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } tester.downloader.Cancel() if !tester.downloader.queue.Idle() { t.Errorf("download queue not idle") } } // Tests that synchronisation from multiple peers works as intended (multi thread sanity test). func TestMultiSynchronisation62(t *testing.T) { testMultiSynchronisation(t, 62, FullSync) } func TestMultiSynchronisation63Full(t *testing.T) { testMultiSynchronisation(t, 63, FullSync) } func TestMultiSynchronisation63Fast(t *testing.T) { testMultiSynchronisation(t, 63, FastSync) } func TestMultiSynchronisation64Full(t *testing.T) { testMultiSynchronisation(t, 64, FullSync) } func TestMultiSynchronisation64Fast(t *testing.T) { testMultiSynchronisation(t, 64, FastSync) } func TestMultiSynchronisation64Light(t *testing.T) { testMultiSynchronisation(t, 64, LightSync) } func testMultiSynchronisation(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() // Create various peers with various parts of the chain targetPeers := 8 chain := testChainBase.shorten(targetPeers * 100) for i := 0; i < targetPeers; i++ { id := fmt.Sprintf("peer #%d", i) tester.newPeer(id, protocol, chain.shorten(chain.len()/(i+1))) } if err := tester.sync("peer #0", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chain.len()) } // Tests that synchronisations behave well in multi-version protocol environments // and not wreak havoc on other nodes in the network. func TestMultiProtoSynchronisation62(t *testing.T) { testMultiProtoSync(t, 62, FullSync) } func TestMultiProtoSynchronisation63Full(t *testing.T) { testMultiProtoSync(t, 63, FullSync) } func TestMultiProtoSynchronisation63Fast(t *testing.T) { testMultiProtoSync(t, 63, FastSync) } func TestMultiProtoSynchronisation64Full(t *testing.T) { testMultiProtoSync(t, 64, FullSync) } func TestMultiProtoSynchronisation64Fast(t *testing.T) { testMultiProtoSync(t, 64, FastSync) } func TestMultiProtoSynchronisation64Light(t *testing.T) { testMultiProtoSync(t, 64, LightSync) } func testMultiProtoSync(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() // Create a small enough block chain to download chain := testChainBase.shorten(blockCacheItems - 15) // Create peers of every type tester.newPeer("peer 62", 62, chain) tester.newPeer("peer 63", 63, chain) tester.newPeer("peer 64", 64, chain) // Synchronise with the requested peer and make sure all blocks were retrieved if err := tester.sync(fmt.Sprintf("peer %d", protocol), nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chain.len()) // Check that no peers have been dropped off for _, version := range []int{62, 63, 64} { peer := fmt.Sprintf("peer %d", version) if _, ok := tester.peers[peer]; !ok { t.Errorf("%s dropped", peer) } } } // Tests that if a block is empty (e.g. header only), no body request should be // made, and instead the header should be assembled into a whole block in itself. func TestEmptyShortCircuit62(t *testing.T) { testEmptyShortCircuit(t, 62, FullSync) } func TestEmptyShortCircuit63Full(t *testing.T) { testEmptyShortCircuit(t, 63, FullSync) } func TestEmptyShortCircuit63Fast(t *testing.T) { testEmptyShortCircuit(t, 63, FastSync) } func TestEmptyShortCircuit64Full(t *testing.T) { testEmptyShortCircuit(t, 64, FullSync) } func TestEmptyShortCircuit64Fast(t *testing.T) { testEmptyShortCircuit(t, 64, FastSync) } func TestEmptyShortCircuit64Light(t *testing.T) { testEmptyShortCircuit(t, 64, LightSync) } func testEmptyShortCircuit(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() // Create a block chain to download chain := testChainBase tester.newPeer("peer", protocol, chain) // Instrument the downloader to signal body requests bodiesHave, receiptsHave := int32(0), int32(0) tester.downloader.bodyFetchHook = func(headers []*types.Header) { atomic.AddInt32(&bodiesHave, int32(len(headers))) } tester.downloader.receiptFetchHook = func(headers []*types.Header) { atomic.AddInt32(&receiptsHave, int32(len(headers))) } // Synchronise with the peer and make sure all blocks were retrieved if err := tester.sync("peer", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chain.len()) // Validate the number of block bodies that should have been requested bodiesNeeded, receiptsNeeded := 0, 0 for _, block := range chain.blockm { if mode != LightSync && block != tester.genesis && (len(block.Transactions()) > 0 || len(block.Uncles()) > 0) { bodiesNeeded++ } } for _, receipt := range chain.receiptm { if mode == FastSync && len(receipt) > 0 { receiptsNeeded++ } } if int(bodiesHave) != bodiesNeeded { t.Errorf("body retrieval count mismatch: have %v, want %v", bodiesHave, bodiesNeeded) } if int(receiptsHave) != receiptsNeeded { t.Errorf("receipt retrieval count mismatch: have %v, want %v", receiptsHave, receiptsNeeded) } } // Tests that headers are enqueued continuously, preventing malicious nodes from // stalling the downloader by feeding gapped header chains. func TestMissingHeaderAttack62(t *testing.T) { testMissingHeaderAttack(t, 62, FullSync) } func TestMissingHeaderAttack63Full(t *testing.T) { testMissingHeaderAttack(t, 63, FullSync) } func TestMissingHeaderAttack63Fast(t *testing.T) { testMissingHeaderAttack(t, 63, FastSync) } func TestMissingHeaderAttack64Full(t *testing.T) { testMissingHeaderAttack(t, 64, FullSync) } func TestMissingHeaderAttack64Fast(t *testing.T) { testMissingHeaderAttack(t, 64, FastSync) } func TestMissingHeaderAttack64Light(t *testing.T) { testMissingHeaderAttack(t, 64, LightSync) } func testMissingHeaderAttack(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chain := testChainBase.shorten(blockCacheItems - 15) brokenChain := chain.shorten(chain.len()) delete(brokenChain.headerm, brokenChain.chain[brokenChain.len()/2]) tester.newPeer("attack", protocol, brokenChain) if err := tester.sync("attack", nil, mode); err == nil { t.Fatalf("succeeded attacker synchronisation") } // Synchronise with the valid peer and make sure sync succeeds tester.newPeer("valid", protocol, chain) if err := tester.sync("valid", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chain.len()) } // Tests that if requested headers are shifted (i.e. first is missing), the queue // detects the invalid numbering. func TestShiftedHeaderAttack62(t *testing.T) { testShiftedHeaderAttack(t, 62, FullSync) } func TestShiftedHeaderAttack63Full(t *testing.T) { testShiftedHeaderAttack(t, 63, FullSync) } func TestShiftedHeaderAttack63Fast(t *testing.T) { testShiftedHeaderAttack(t, 63, FastSync) } func TestShiftedHeaderAttack64Full(t *testing.T) { testShiftedHeaderAttack(t, 64, FullSync) } func TestShiftedHeaderAttack64Fast(t *testing.T) { testShiftedHeaderAttack(t, 64, FastSync) } func TestShiftedHeaderAttack64Light(t *testing.T) { testShiftedHeaderAttack(t, 64, LightSync) } func testShiftedHeaderAttack(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chain := testChainBase.shorten(blockCacheItems - 15) // Attempt a full sync with an attacker feeding shifted headers brokenChain := chain.shorten(chain.len()) delete(brokenChain.headerm, brokenChain.chain[1]) delete(brokenChain.blockm, brokenChain.chain[1]) delete(brokenChain.receiptm, brokenChain.chain[1]) tester.newPeer("attack", protocol, brokenChain) if err := tester.sync("attack", nil, mode); err == nil { t.Fatalf("succeeded attacker synchronisation") } // Synchronise with the valid peer and make sure sync succeeds tester.newPeer("valid", protocol, chain) if err := tester.sync("valid", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } assertOwnChain(t, tester, chain.len()) } // Tests that upon detecting an invalid header, the recent ones are rolled back // for various failure scenarios. Afterwards a full sync is attempted to make // sure no state was corrupted. func TestInvalidHeaderRollback63Fast(t *testing.T) { testInvalidHeaderRollback(t, 63, FastSync) } func TestInvalidHeaderRollback64Fast(t *testing.T) { testInvalidHeaderRollback(t, 64, FastSync) } func TestInvalidHeaderRollback64Light(t *testing.T) { testInvalidHeaderRollback(t, 64, LightSync) } func testInvalidHeaderRollback(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() // Create a small enough block chain to download targetBlocks := 3*fsHeaderSafetyNet + 256 + fsMinFullBlocks chain := testChainBase.shorten(targetBlocks) // Attempt to sync with an attacker that feeds junk during the fast sync phase. // This should result in the last fsHeaderSafetyNet headers being rolled back. missing := fsHeaderSafetyNet + MaxHeaderFetch + 1 fastAttackChain := chain.shorten(chain.len()) delete(fastAttackChain.headerm, fastAttackChain.chain[missing]) tester.newPeer("fast-attack", protocol, fastAttackChain) if err := tester.sync("fast-attack", nil, mode); err == nil { t.Fatalf("succeeded fast attacker synchronisation") } if head := tester.CurrentHeader().Number.Int64(); int(head) > MaxHeaderFetch { t.Errorf("rollback head mismatch: have %v, want at most %v", head, MaxHeaderFetch) } // Attempt to sync with an attacker that feeds junk during the block import phase. // This should result in both the last fsHeaderSafetyNet number of headers being // rolled back, and also the pivot point being reverted to a non-block status. missing = 3*fsHeaderSafetyNet + MaxHeaderFetch + 1 blockAttackChain := chain.shorten(chain.len()) delete(fastAttackChain.headerm, fastAttackChain.chain[missing]) // Make sure the fast-attacker doesn't fill in delete(blockAttackChain.headerm, blockAttackChain.chain[missing]) tester.newPeer("block-attack", protocol, blockAttackChain) if err := tester.sync("block-attack", nil, mode); err == nil { t.Fatalf("succeeded block attacker synchronisation") } if head := tester.CurrentHeader().Number.Int64(); int(head) > 2*fsHeaderSafetyNet+MaxHeaderFetch { t.Errorf("rollback head mismatch: have %v, want at most %v", head, 2*fsHeaderSafetyNet+MaxHeaderFetch) } if mode == FastSync { if head := tester.CurrentBlock().NumberU64(); head != 0 { t.Errorf("fast sync pivot block #%d not rolled back", head) } } // Attempt to sync with an attacker that withholds promised blocks after the // fast sync pivot point. This could be a trial to leave the node with a bad // but already imported pivot block. withholdAttackChain := chain.shorten(chain.len()) tester.newPeer("withhold-attack", protocol, withholdAttackChain) tester.downloader.syncInitHook = func(uint64, uint64) { for i := missing; i < withholdAttackChain.len(); i++ { delete(withholdAttackChain.headerm, withholdAttackChain.chain[i]) } tester.downloader.syncInitHook = nil } if err := tester.sync("withhold-attack", nil, mode); err == nil { t.Fatalf("succeeded withholding attacker synchronisation") } if head := tester.CurrentHeader().Number.Int64(); int(head) > 2*fsHeaderSafetyNet+MaxHeaderFetch { t.Errorf("rollback head mismatch: have %v, want at most %v", head, 2*fsHeaderSafetyNet+MaxHeaderFetch) } if mode == FastSync { if head := tester.CurrentBlock().NumberU64(); head != 0 { t.Errorf("fast sync pivot block #%d not rolled back", head) } } // synchronise with the valid peer and make sure sync succeeds. Since the last rollback // should also disable fast syncing for this process, verify that we did a fresh full // sync. Note, we can't assert anything about the receipts since we won't purge the // database of them, hence we can't use assertOwnChain. tester.newPeer("valid", protocol, chain) if err := tester.sync("valid", nil, mode); err != nil { t.Fatalf("failed to synchronise blocks: %v", err) } if hs := len(tester.ownHeaders); hs != chain.len() { t.Fatalf("synchronised headers mismatch: have %v, want %v", hs, chain.len()) } if mode != LightSync { if bs := len(tester.ownBlocks); bs != chain.len() { t.Fatalf("synchronised blocks mismatch: have %v, want %v", bs, chain.len()) } } } // Tests that a peer advertising an high TD doesn't get to stall the downloader // afterwards by not sending any useful hashes. func TestHighTDStarvationAttack62(t *testing.T) { testHighTDStarvationAttack(t, 62, FullSync) } func TestHighTDStarvationAttack63Full(t *testing.T) { testHighTDStarvationAttack(t, 63, FullSync) } func TestHighTDStarvationAttack63Fast(t *testing.T) { testHighTDStarvationAttack(t, 63, FastSync) } func TestHighTDStarvationAttack64Full(t *testing.T) { testHighTDStarvationAttack(t, 64, FullSync) } func TestHighTDStarvationAttack64Fast(t *testing.T) { testHighTDStarvationAttack(t, 64, FastSync) } func TestHighTDStarvationAttack64Light(t *testing.T) { testHighTDStarvationAttack(t, 64, LightSync) } func testHighTDStarvationAttack(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chain := testChainBase.shorten(1) tester.newPeer("attack", protocol, chain) if err := tester.sync("attack", big.NewInt(1000000), mode); err != errStallingPeer { t.Fatalf("synchronisation error mismatch: have %v, want %v", err, errStallingPeer) } } // Tests that misbehaving peers are disconnected, whilst behaving ones are not. func TestBlockHeaderAttackerDropping62(t *testing.T) { testBlockHeaderAttackerDropping(t, 62) } func TestBlockHeaderAttackerDropping63(t *testing.T) { testBlockHeaderAttackerDropping(t, 63) } func TestBlockHeaderAttackerDropping64(t *testing.T) { testBlockHeaderAttackerDropping(t, 64) } func testBlockHeaderAttackerDropping(t *testing.T, protocol int) { t.Parallel() // Define the disconnection requirement for individual hash fetch errors tests := []struct { result error drop bool }{ {nil, false}, // Sync succeeded, all is well {errBusy, false}, // Sync is already in progress, no problem {errUnknownPeer, false}, // Peer is unknown, was already dropped, don't double drop {errBadPeer, true}, // Peer was deemed bad for some reason, drop it {errStallingPeer, true}, // Peer was detected to be stalling, drop it {errUnsyncedPeer, true}, // Peer was detected to be unsynced, drop it {errNoPeers, false}, // No peers to download from, soft race, no issue {errTimeout, true}, // No hashes received in due time, drop the peer {errEmptyHeaderSet, true}, // No headers were returned as a response, drop as it's a dead end {errPeersUnavailable, true}, // Nobody had the advertised blocks, drop the advertiser {errInvalidAncestor, true}, // Agreed upon ancestor is not acceptable, drop the chain rewriter {errInvalidChain, true}, // Hash chain was detected as invalid, definitely drop {errInvalidBody, false}, // A bad peer was detected, but not the sync origin {errInvalidReceipt, false}, // A bad peer was detected, but not the sync origin {errCancelContentProcessing, false}, // Synchronisation was canceled, origin may be innocent, don't drop } // Run the tests and check disconnection status tester := newTester() defer tester.terminate() chain := testChainBase.shorten(1) for i, tt := range tests { // Register a new peer and ensure it's presence id := fmt.Sprintf("test %d", i) if err := tester.newPeer(id, protocol, chain); err != nil { t.Fatalf("test %d: failed to register new peer: %v", i, err) } if _, ok := tester.peers[id]; !ok { t.Fatalf("test %d: registered peer not found", i) } // Simulate a synchronisation and check the required result tester.downloader.synchroniseMock = func(string, common.Hash) error { return tt.result } tester.downloader.Synchronise(id, tester.genesis.Hash(), big.NewInt(1000), FullSync) if _, ok := tester.peers[id]; !ok != tt.drop { t.Errorf("test %d: peer drop mismatch for %v: have %v, want %v", i, tt.result, !ok, tt.drop) } } } // Tests that synchronisation progress (origin block number, current block number // and highest block number) is tracked and updated correctly. func TestSyncProgress62(t *testing.T) { testSyncProgress(t, 62, FullSync) } func TestSyncProgress63Full(t *testing.T) { testSyncProgress(t, 63, FullSync) } func TestSyncProgress63Fast(t *testing.T) { testSyncProgress(t, 63, FastSync) } func TestSyncProgress64Full(t *testing.T) { testSyncProgress(t, 64, FullSync) } func TestSyncProgress64Fast(t *testing.T) { testSyncProgress(t, 64, FastSync) } func TestSyncProgress64Light(t *testing.T) { testSyncProgress(t, 64, LightSync) } func testSyncProgress(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chain := testChainBase.shorten(blockCacheItems - 15) // Set a sync init hook to catch progress changes starting := make(chan struct{}) progress := make(chan struct{}) tester.downloader.syncInitHook = func(origin, latest uint64) { starting <- struct{}{} <-progress } checkProgress(t, tester.downloader, "pristine", ethereum.SyncProgress{}) // Synchronise half the blocks and check initial progress tester.newPeer("peer-half", protocol, chain.shorten(chain.len()/2)) pending := new(sync.WaitGroup) pending.Add(1) go func() { defer pending.Done() if err := tester.sync("peer-half", nil, mode); err != nil { panic(fmt.Sprintf("failed to synchronise blocks: %v", err)) } }() <-starting checkProgress(t, tester.downloader, "initial", ethereum.SyncProgress{ HighestBlock: uint64(chain.len()/2 - 1), }) progress <- struct{}{} pending.Wait() // Synchronise all the blocks and check continuation progress tester.newPeer("peer-full", protocol, chain) pending.Add(1) go func() { defer pending.Done() if err := tester.sync("peer-full", nil, mode); err != nil { panic(fmt.Sprintf("failed to synchronise blocks: %v", err)) } }() <-starting checkProgress(t, tester.downloader, "completing", ethereum.SyncProgress{ StartingBlock: uint64(chain.len()/2 - 1), CurrentBlock: uint64(chain.len()/2 - 1), HighestBlock: uint64(chain.len() - 1), }) // Check final progress after successful sync progress <- struct{}{} pending.Wait() checkProgress(t, tester.downloader, "final", ethereum.SyncProgress{ StartingBlock: uint64(chain.len()/2 - 1), CurrentBlock: uint64(chain.len() - 1), HighestBlock: uint64(chain.len() - 1), }) } func checkProgress(t *testing.T, d *Downloader, stage string, want ethereum.SyncProgress) { // Mark this method as a helper to report errors at callsite, not in here t.Helper() p := d.Progress() p.KnownStates, p.PulledStates = 0, 0 want.KnownStates, want.PulledStates = 0, 0 if p != want { t.Fatalf("%s progress mismatch:\nhave %+v\nwant %+v", stage, p, want) } } // Tests that synchronisation progress (origin block number and highest block // number) is tracked and updated correctly in case of a fork (or manual head // revertal). func TestForkedSyncProgress62(t *testing.T) { testForkedSyncProgress(t, 62, FullSync) } func TestForkedSyncProgress63Full(t *testing.T) { testForkedSyncProgress(t, 63, FullSync) } func TestForkedSyncProgress63Fast(t *testing.T) { testForkedSyncProgress(t, 63, FastSync) } func TestForkedSyncProgress64Full(t *testing.T) { testForkedSyncProgress(t, 64, FullSync) } func TestForkedSyncProgress64Fast(t *testing.T) { testForkedSyncProgress(t, 64, FastSync) } func TestForkedSyncProgress64Light(t *testing.T) { testForkedSyncProgress(t, 64, LightSync) } func testForkedSyncProgress(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chainA := testChainForkLightA.shorten(testChainBase.len() + MaxHashFetch) chainB := testChainForkLightB.shorten(testChainBase.len() + MaxHashFetch) // Set a sync init hook to catch progress changes starting := make(chan struct{}) progress := make(chan struct{}) tester.downloader.syncInitHook = func(origin, latest uint64) { starting <- struct{}{} <-progress } checkProgress(t, tester.downloader, "pristine", ethereum.SyncProgress{}) // Synchronise with one of the forks and check progress tester.newPeer("fork A", protocol, chainA) pending := new(sync.WaitGroup) pending.Add(1) go func() { defer pending.Done() if err := tester.sync("fork A", nil, mode); err != nil { panic(fmt.Sprintf("failed to synchronise blocks: %v", err)) } }() <-starting checkProgress(t, tester.downloader, "initial", ethereum.SyncProgress{ HighestBlock: uint64(chainA.len() - 1), }) progress <- struct{}{} pending.Wait() // Simulate a successful sync above the fork tester.downloader.syncStatsChainOrigin = tester.downloader.syncStatsChainHeight // Synchronise with the second fork and check progress resets tester.newPeer("fork B", protocol, chainB) pending.Add(1) go func() { defer pending.Done() if err := tester.sync("fork B", nil, mode); err != nil { panic(fmt.Sprintf("failed to synchronise blocks: %v", err)) } }() <-starting checkProgress(t, tester.downloader, "forking", ethereum.SyncProgress{ StartingBlock: uint64(testChainBase.len()) - 1, CurrentBlock: uint64(chainA.len() - 1), HighestBlock: uint64(chainB.len() - 1), }) // Check final progress after successful sync progress <- struct{}{} pending.Wait() checkProgress(t, tester.downloader, "final", ethereum.SyncProgress{ StartingBlock: uint64(testChainBase.len()) - 1, CurrentBlock: uint64(chainB.len() - 1), HighestBlock: uint64(chainB.len() - 1), }) } // Tests that if synchronisation is aborted due to some failure, then the progress // origin is not updated in the next sync cycle, as it should be considered the // continuation of the previous sync and not a new instance. func TestFailedSyncProgress62(t *testing.T) { testFailedSyncProgress(t, 62, FullSync) } func TestFailedSyncProgress63Full(t *testing.T) { testFailedSyncProgress(t, 63, FullSync) } func TestFailedSyncProgress63Fast(t *testing.T) { testFailedSyncProgress(t, 63, FastSync) } func TestFailedSyncProgress64Full(t *testing.T) { testFailedSyncProgress(t, 64, FullSync) } func TestFailedSyncProgress64Fast(t *testing.T) { testFailedSyncProgress(t, 64, FastSync) } func TestFailedSyncProgress64Light(t *testing.T) { testFailedSyncProgress(t, 64, LightSync) } func testFailedSyncProgress(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chain := testChainBase.shorten(blockCacheItems - 15) // Set a sync init hook to catch progress changes starting := make(chan struct{}) progress := make(chan struct{}) tester.downloader.syncInitHook = func(origin, latest uint64) { starting <- struct{}{} <-progress } checkProgress(t, tester.downloader, "pristine", ethereum.SyncProgress{}) // Attempt a full sync with a faulty peer brokenChain := chain.shorten(chain.len()) missing := brokenChain.len() / 2 delete(brokenChain.headerm, brokenChain.chain[missing]) delete(brokenChain.blockm, brokenChain.chain[missing]) delete(brokenChain.receiptm, brokenChain.chain[missing]) tester.newPeer("faulty", protocol, brokenChain) pending := new(sync.WaitGroup) pending.Add(1) go func() { defer pending.Done() if err := tester.sync("faulty", nil, mode); err == nil { panic("succeeded faulty synchronisation") } }() <-starting checkProgress(t, tester.downloader, "initial", ethereum.SyncProgress{ HighestBlock: uint64(brokenChain.len() - 1), }) progress <- struct{}{} pending.Wait() afterFailedSync := tester.downloader.Progress() // Synchronise with a good peer and check that the progress origin remind the same // after a failure tester.newPeer("valid", protocol, chain) pending.Add(1) go func() { defer pending.Done() if err := tester.sync("valid", nil, mode); err != nil { panic(fmt.Sprintf("failed to synchronise blocks: %v", err)) } }() <-starting checkProgress(t, tester.downloader, "completing", afterFailedSync) // Check final progress after successful sync progress <- struct{}{} pending.Wait() checkProgress(t, tester.downloader, "final", ethereum.SyncProgress{ CurrentBlock: uint64(chain.len() - 1), HighestBlock: uint64(chain.len() - 1), }) } // Tests that if an attacker fakes a chain height, after the attack is detected, // the progress height is successfully reduced at the next sync invocation. func TestFakedSyncProgress62(t *testing.T) { testFakedSyncProgress(t, 62, FullSync) } func TestFakedSyncProgress63Full(t *testing.T) { testFakedSyncProgress(t, 63, FullSync) } func TestFakedSyncProgress63Fast(t *testing.T) { testFakedSyncProgress(t, 63, FastSync) } func TestFakedSyncProgress64Full(t *testing.T) { testFakedSyncProgress(t, 64, FullSync) } func TestFakedSyncProgress64Fast(t *testing.T) { testFakedSyncProgress(t, 64, FastSync) } func TestFakedSyncProgress64Light(t *testing.T) { testFakedSyncProgress(t, 64, LightSync) } func testFakedSyncProgress(t *testing.T, protocol int, mode SyncMode) { t.Parallel() tester := newTester() defer tester.terminate() chain := testChainBase.shorten(blockCacheItems - 15) // Set a sync init hook to catch progress changes starting := make(chan struct{}) progress := make(chan struct{}) tester.downloader.syncInitHook = func(origin, latest uint64) { starting <- struct{}{} <-progress } checkProgress(t, tester.downloader, "pristine", ethereum.SyncProgress{}) // Create and sync with an attacker that promises a higher chain than available. brokenChain := chain.shorten(chain.len()) numMissing := 5 for i := brokenChain.len() - 2; i > brokenChain.len()-numMissing; i-- { delete(brokenChain.headerm, brokenChain.chain[i]) } tester.newPeer("attack", protocol, brokenChain) pending := new(sync.WaitGroup) pending.Add(1) go func() { defer pending.Done() if err := tester.sync("attack", nil, mode); err == nil { panic("succeeded attacker synchronisation") } }() <-starting checkProgress(t, tester.downloader, "initial", ethereum.SyncProgress{ HighestBlock: uint64(brokenChain.len() - 1), }) progress <- struct{}{} pending.Wait() afterFailedSync := tester.downloader.Progress() // Synchronise with a good peer and check that the progress height has been reduced to // the true value. validChain := chain.shorten(chain.len() - numMissing) tester.newPeer("valid", protocol, validChain) pending.Add(1) go func() { defer pending.Done() if err := tester.sync("valid", nil, mode); err != nil { panic(fmt.Sprintf("failed to synchronise blocks: %v", err)) } }() <-starting checkProgress(t, tester.downloader, "completing", ethereum.SyncProgress{ CurrentBlock: afterFailedSync.CurrentBlock, HighestBlock: uint64(validChain.len() - 1), }) // Check final progress after successful sync. progress <- struct{}{} pending.Wait() checkProgress(t, tester.downloader, "final", ethereum.SyncProgress{ CurrentBlock: uint64(validChain.len() - 1), HighestBlock: uint64(validChain.len() - 1), }) } // This test reproduces an issue where unexpected deliveries would // block indefinitely if they arrived at the right time. func TestDeliverHeadersHang(t *testing.T) { t.Parallel() testCases := []struct { protocol int syncMode SyncMode }{ {62, FullSync}, {63, FullSync}, {63, FastSync}, {64, FullSync}, {64, FastSync}, {64, LightSync}, } for _, tc := range testCases { t.Run(fmt.Sprintf("protocol %d mode %v", tc.protocol, tc.syncMode), func(t *testing.T) { t.Parallel() testDeliverHeadersHang(t, tc.protocol, tc.syncMode) }) } } func testDeliverHeadersHang(t *testing.T, protocol int, mode SyncMode) { master := newTester() defer master.terminate() chain := testChainBase.shorten(15) for i := 0; i < 200; i++ { tester := newTester() tester.peerDb = master.peerDb tester.newPeer("peer", protocol, chain) // Whenever the downloader requests headers, flood it with // a lot of unrequested header deliveries. tester.downloader.peers.peers["peer"].peer = &floodingTestPeer{ peer: tester.downloader.peers.peers["peer"].peer, tester: tester, } if err := tester.sync("peer", nil, mode); err != nil { t.Errorf("test %d: sync failed: %v", i, err) } tester.terminate() } } type floodingTestPeer struct { peer Peer tester *downloadTester } func (ftp *floodingTestPeer) Head() (common.Hash, *big.Int) { return ftp.peer.Head() } func (ftp *floodingTestPeer) RequestHeadersByHash(hash common.Hash, count int, skip int, reverse bool) error { return ftp.peer.RequestHeadersByHash(hash, count, skip, reverse) } func (ftp *floodingTestPeer) RequestBodies(hashes []common.Hash) error { return ftp.peer.RequestBodies(hashes) } func (ftp *floodingTestPeer) RequestReceipts(hashes []common.Hash) error { return ftp.peer.RequestReceipts(hashes) } func (ftp *floodingTestPeer) RequestNodeData(hashes []common.Hash) error { return ftp.peer.RequestNodeData(hashes) } func (ftp *floodingTestPeer) RequestHeadersByNumber(from uint64, count, skip int, reverse bool) error { deliveriesDone := make(chan struct{}, 500) for i := 0; i < cap(deliveriesDone)-1; i++ { peer := fmt.Sprintf("fake-peer%d", i) go func() { ftp.tester.downloader.DeliverHeaders(peer, []*types.Header{{}, {}, {}, {}}) deliveriesDone <- struct{}{} }() } // None of the extra deliveries should block. timeout := time.After(60 * time.Second) launched := false for i := 0; i < cap(deliveriesDone); i++ { select { case <-deliveriesDone: if !launched { // Start delivering the requested headers // after one of the flooding responses has arrived. go func() { ftp.peer.RequestHeadersByNumber(from, count, skip, reverse) deliveriesDone <- struct{}{} }() launched = true } case <-timeout: panic("blocked") } } return nil } func TestRemoteHeaderRequestSpan(t *testing.T) { testCases := []struct { remoteHeight uint64 localHeight uint64 expected []int }{ // Remote is way higher. We should ask for the remote head and go backwards {1500, 1000, []int{1323, 1339, 1355, 1371, 1387, 1403, 1419, 1435, 1451, 1467, 1483, 1499}, }, {15000, 13006, []int{14823, 14839, 14855, 14871, 14887, 14903, 14919, 14935, 14951, 14967, 14983, 14999}, }, //Remote is pretty close to us. We don't have to fetch as many {1200, 1150, []int{1149, 1154, 1159, 1164, 1169, 1174, 1179, 1184, 1189, 1194, 1199}, }, // Remote is equal to us (so on a fork with higher td) // We should get the closest couple of ancestors {1500, 1500, []int{1497, 1499}, }, // We're higher than the remote! Odd {1000, 1500, []int{997, 999}, }, // Check some weird edgecases that it behaves somewhat rationally {0, 1500, []int{0, 2}, }, {6000000, 0, []int{5999823, 5999839, 5999855, 5999871, 5999887, 5999903, 5999919, 5999935, 5999951, 5999967, 5999983, 5999999}, }, {0, 0, []int{0, 2}, }, } reqs := func(from, count, span int) []int { var r []int num := from for len(r) < count { r = append(r, num) num += span + 1 } return r } for i, tt := range testCases { from, count, span, max := calculateRequestSpan(tt.remoteHeight, tt.localHeight) data := reqs(int(from), count, span) if max != uint64(data[len(data)-1]) { t.Errorf("test %d: wrong last value %d != %d", i, data[len(data)-1], max) } failed := false if len(data) != len(tt.expected) { failed = true t.Errorf("test %d: length wrong, expected %d got %d", i, len(tt.expected), len(data)) } else { for j, n := range data { if n != tt.expected[j] { failed = true break } } } if failed { res := strings.Replace(fmt.Sprint(data), " ", ",", -1) exp := strings.Replace(fmt.Sprint(tt.expected), " ", ",", -1) t.Logf("got: %v\n", res) t.Logf("exp: %v\n", exp) t.Errorf("test %d: wrong values", i) } } } // Tests that peers below a pre-configured checkpoint block are prevented from // being fast-synced from, avoiding potential cheap eclipse attacks. func TestCheckpointEnforcement62(t *testing.T) { testCheckpointEnforcement(t, 62, FullSync) } func TestCheckpointEnforcement63Full(t *testing.T) { testCheckpointEnforcement(t, 63, FullSync) } func TestCheckpointEnforcement63Fast(t *testing.T) { testCheckpointEnforcement(t, 63, FastSync) } func TestCheckpointEnforcement64Full(t *testing.T) { testCheckpointEnforcement(t, 64, FullSync) } func TestCheckpointEnforcement64Fast(t *testing.T) { testCheckpointEnforcement(t, 64, FastSync) } func TestCheckpointEnforcement64Light(t *testing.T) { testCheckpointEnforcement(t, 64, LightSync) } func testCheckpointEnforcement(t *testing.T, protocol int, mode SyncMode) { t.Parallel() // Create a new tester with a particular hard coded checkpoint block tester := newTester() defer tester.terminate() tester.downloader.checkpoint = uint64(fsMinFullBlocks) + 256 chain := testChainBase.shorten(int(tester.downloader.checkpoint) - 1) // Attempt to sync with the peer and validate the result tester.newPeer("peer", protocol, chain) var expect error if mode == FastSync || mode == LightSync { expect = errUnsyncedPeer } if err := tester.sync("peer", nil, mode); err != expect { t.Fatalf("block sync error mismatch: have %v, want %v", err, expect) } if mode == FastSync || mode == LightSync { assertOwnChain(t, tester, 1) } else { assertOwnChain(t, tester, chain.len()) } }