// Copyright 2022 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 pathdb import ( "bytes" "errors" "fmt" "math/big" "math/rand" "testing" "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/crypto" "github.com/ethereum/go-ethereum/rlp" "github.com/ethereum/go-ethereum/trie/testutil" "github.com/ethereum/go-ethereum/trie/trienode" "github.com/ethereum/go-ethereum/trie/triestate" ) func updateTrie(addrHash common.Hash, root common.Hash, dirties, cleans map[common.Hash][]byte) (common.Hash, *trienode.NodeSet) { h, err := newTestHasher(addrHash, root, cleans) if err != nil { panic(fmt.Errorf("failed to create hasher, err: %w", err)) } for key, val := range dirties { if len(val) == 0 { h.Delete(key.Bytes()) } else { h.Update(key.Bytes(), val) } } root, nodes, _ := h.Commit(false) return root, nodes } func generateAccount(storageRoot common.Hash) types.StateAccount { return types.StateAccount{ Nonce: uint64(rand.Intn(100)), Balance: big.NewInt(rand.Int63()), CodeHash: testutil.RandBytes(32), Root: storageRoot, } } const ( createAccountOp int = iota modifyAccountOp deleteAccountOp opLen ) type genctx struct { accounts map[common.Hash][]byte storages map[common.Hash]map[common.Hash][]byte accountOrigin map[common.Address][]byte storageOrigin map[common.Address]map[common.Hash][]byte nodes *trienode.MergedNodeSet } func newCtx() *genctx { return &genctx{ accounts: make(map[common.Hash][]byte), storages: make(map[common.Hash]map[common.Hash][]byte), accountOrigin: make(map[common.Address][]byte), storageOrigin: make(map[common.Address]map[common.Hash][]byte), nodes: trienode.NewMergedNodeSet(), } } type tester struct { db *Database roots []common.Hash preimages map[common.Hash]common.Address accounts map[common.Hash][]byte storages map[common.Hash]map[common.Hash][]byte // state snapshots snapAccounts map[common.Hash]map[common.Hash][]byte snapStorages map[common.Hash]map[common.Hash]map[common.Hash][]byte } func newTester(t *testing.T, historyLimit uint64) *tester { var ( disk, _ = rawdb.NewDatabaseWithFreezer(rawdb.NewMemoryDatabase(), t.TempDir(), "", false) db = New(disk, &Config{ StateHistory: historyLimit, CleanCacheSize: 256 * 1024, DirtyCacheSize: 256 * 1024, }) obj = &tester{ db: db, preimages: make(map[common.Hash]common.Address), accounts: make(map[common.Hash][]byte), storages: make(map[common.Hash]map[common.Hash][]byte), snapAccounts: make(map[common.Hash]map[common.Hash][]byte), snapStorages: make(map[common.Hash]map[common.Hash]map[common.Hash][]byte), } ) for i := 0; i < 2*128; i++ { var parent = types.EmptyRootHash if len(obj.roots) != 0 { parent = obj.roots[len(obj.roots)-1] } root, nodes, states := obj.generate(parent) if err := db.Update(root, parent, uint64(i), nodes, states); err != nil { panic(fmt.Errorf("failed to update state changes, err: %w", err)) } obj.roots = append(obj.roots, root) } return obj } func (t *tester) release() { t.db.Close() t.db.diskdb.Close() } func (t *tester) randAccount() (common.Address, []byte) { for addrHash, account := range t.accounts { return t.preimages[addrHash], account } return common.Address{}, nil } func (t *tester) generateStorage(ctx *genctx, addr common.Address) common.Hash { var ( addrHash = crypto.Keccak256Hash(addr.Bytes()) storage = make(map[common.Hash][]byte) origin = make(map[common.Hash][]byte) ) for i := 0; i < 10; i++ { v, _ := rlp.EncodeToBytes(common.TrimLeftZeroes(testutil.RandBytes(32))) hash := testutil.RandomHash() storage[hash] = v origin[hash] = nil } root, set := updateTrie(addrHash, types.EmptyRootHash, storage, nil) ctx.storages[addrHash] = storage ctx.storageOrigin[addr] = origin ctx.nodes.Merge(set) return root } func (t *tester) mutateStorage(ctx *genctx, addr common.Address, root common.Hash) common.Hash { var ( addrHash = crypto.Keccak256Hash(addr.Bytes()) storage = make(map[common.Hash][]byte) origin = make(map[common.Hash][]byte) ) for hash, val := range t.storages[addrHash] { origin[hash] = val storage[hash] = nil if len(origin) == 3 { break } } for i := 0; i < 3; i++ { v, _ := rlp.EncodeToBytes(common.TrimLeftZeroes(testutil.RandBytes(32))) hash := testutil.RandomHash() storage[hash] = v origin[hash] = nil } root, set := updateTrie(crypto.Keccak256Hash(addr.Bytes()), root, storage, t.storages[addrHash]) ctx.storages[addrHash] = storage ctx.storageOrigin[addr] = origin ctx.nodes.Merge(set) return root } func (t *tester) clearStorage(ctx *genctx, addr common.Address, root common.Hash) common.Hash { var ( addrHash = crypto.Keccak256Hash(addr.Bytes()) storage = make(map[common.Hash][]byte) origin = make(map[common.Hash][]byte) ) for hash, val := range t.storages[addrHash] { origin[hash] = val storage[hash] = nil } root, set := updateTrie(addrHash, root, storage, t.storages[addrHash]) if root != types.EmptyRootHash { panic("failed to clear storage trie") } ctx.storages[addrHash] = storage ctx.storageOrigin[addr] = origin ctx.nodes.Merge(set) return root } func (t *tester) generate(parent common.Hash) (common.Hash, *trienode.MergedNodeSet, *triestate.Set) { var ( ctx = newCtx() dirties = make(map[common.Hash]struct{}) ) for i := 0; i < 20; i++ { switch rand.Intn(opLen) { case createAccountOp: // account creation addr := testutil.RandomAddress() addrHash := crypto.Keccak256Hash(addr.Bytes()) if _, ok := t.accounts[addrHash]; ok { continue } if _, ok := dirties[addrHash]; ok { continue } dirties[addrHash] = struct{}{} root := t.generateStorage(ctx, addr) ctx.accounts[addrHash] = types.SlimAccountRLP(generateAccount(root)) ctx.accountOrigin[addr] = nil t.preimages[addrHash] = addr case modifyAccountOp: // account mutation addr, account := t.randAccount() if addr == (common.Address{}) { continue } addrHash := crypto.Keccak256Hash(addr.Bytes()) if _, ok := dirties[addrHash]; ok { continue } dirties[addrHash] = struct{}{} acct, _ := types.FullAccount(account) stRoot := t.mutateStorage(ctx, addr, acct.Root) newAccount := types.SlimAccountRLP(generateAccount(stRoot)) ctx.accounts[addrHash] = newAccount ctx.accountOrigin[addr] = account case deleteAccountOp: // account deletion addr, account := t.randAccount() if addr == (common.Address{}) { continue } addrHash := crypto.Keccak256Hash(addr.Bytes()) if _, ok := dirties[addrHash]; ok { continue } dirties[addrHash] = struct{}{} acct, _ := types.FullAccount(account) if acct.Root != types.EmptyRootHash { t.clearStorage(ctx, addr, acct.Root) } ctx.accounts[addrHash] = nil ctx.accountOrigin[addr] = account } } root, set := updateTrie(common.Hash{}, parent, ctx.accounts, t.accounts) ctx.nodes.Merge(set) // Save state snapshot before commit t.snapAccounts[parent] = copyAccounts(t.accounts) t.snapStorages[parent] = copyStorages(t.storages) // Commit all changes to live state set for addrHash, account := range ctx.accounts { if len(account) == 0 { delete(t.accounts, addrHash) } else { t.accounts[addrHash] = account } } for addrHash, slots := range ctx.storages { if _, ok := t.storages[addrHash]; !ok { t.storages[addrHash] = make(map[common.Hash][]byte) } for sHash, slot := range slots { if len(slot) == 0 { delete(t.storages[addrHash], sHash) } else { t.storages[addrHash][sHash] = slot } } } return root, ctx.nodes, triestate.New(ctx.accountOrigin, ctx.storageOrigin, nil) } // lastRoot returns the latest root hash, or empty if nothing is cached. func (t *tester) lastHash() common.Hash { if len(t.roots) == 0 { return common.Hash{} } return t.roots[len(t.roots)-1] } func (t *tester) verifyState(root common.Hash) error { reader, err := t.db.Reader(root) if err != nil { return err } _, err = reader.Node(common.Hash{}, nil, root) if err != nil { return errors.New("root node is not available") } for addrHash, account := range t.snapAccounts[root] { blob, err := reader.Node(common.Hash{}, addrHash.Bytes(), crypto.Keccak256Hash(account)) if err != nil || !bytes.Equal(blob, account) { return fmt.Errorf("account is mismatched: %w", err) } } for addrHash, slots := range t.snapStorages[root] { for hash, slot := range slots { blob, err := reader.Node(addrHash, hash.Bytes(), crypto.Keccak256Hash(slot)) if err != nil || !bytes.Equal(blob, slot) { return fmt.Errorf("slot is mismatched: %w", err) } } } return nil } func (t *tester) verifyHistory() error { bottom := t.bottomIndex() for i, root := range t.roots { // The state history related to the state above disk layer should not exist. if i > bottom { _, err := readHistory(t.db.freezer, uint64(i+1)) if err == nil { return errors.New("unexpected state history") } continue } // The state history related to the state below or equal to the disk layer // should exist. obj, err := readHistory(t.db.freezer, uint64(i+1)) if err != nil { return err } parent := types.EmptyRootHash if i != 0 { parent = t.roots[i-1] } if obj.meta.parent != parent { return fmt.Errorf("unexpected parent, want: %x, got: %x", parent, obj.meta.parent) } if obj.meta.root != root { return fmt.Errorf("unexpected root, want: %x, got: %x", root, obj.meta.root) } } return nil } // bottomIndex returns the index of current disk layer. func (t *tester) bottomIndex() int { bottom := t.db.tree.bottom() for i := 0; i < len(t.roots); i++ { if t.roots[i] == bottom.rootHash() { return i } } return -1 } func TestDatabaseRollback(t *testing.T) { // Verify state histories tester := newTester(t, 0) defer tester.release() if err := tester.verifyHistory(); err != nil { t.Fatalf("Invalid state history, err: %v", err) } // Revert database from top to bottom for i := tester.bottomIndex(); i >= 0; i-- { root := tester.roots[i] parent := types.EmptyRootHash if i > 0 { parent = tester.roots[i-1] } loader := newHashLoader(tester.snapAccounts[root], tester.snapStorages[root]) if err := tester.db.Recover(parent, loader); err != nil { t.Fatalf("Failed to revert db, err: %v", err) } tester.verifyState(parent) } if tester.db.tree.len() != 1 { t.Fatal("Only disk layer is expected") } } func TestDatabaseRecoverable(t *testing.T) { var ( tester = newTester(t, 0) index = tester.bottomIndex() ) defer tester.release() var cases = []struct { root common.Hash expect bool }{ // Unknown state should be unrecoverable {common.Hash{0x1}, false}, // Initial state should be recoverable {types.EmptyRootHash, true}, // Initial state should be recoverable {common.Hash{}, true}, // Layers below current disk layer are recoverable {tester.roots[index-1], true}, // Disklayer itself is not recoverable, since it's // available for accessing. {tester.roots[index], false}, // Layers above current disk layer are not recoverable // since they are available for accessing. {tester.roots[index+1], false}, } for i, c := range cases { result := tester.db.Recoverable(c.root) if result != c.expect { t.Fatalf("case: %d, unexpected result, want %t, got %t", i, c.expect, result) } } } func TestDisable(t *testing.T) { tester := newTester(t, 0) defer tester.release() _, stored := rawdb.ReadAccountTrieNode(tester.db.diskdb, nil) if err := tester.db.Disable(); err != nil { t.Fatal("Failed to deactivate database") } if err := tester.db.Enable(types.EmptyRootHash); err == nil { t.Fatalf("Invalid activation should be rejected") } if err := tester.db.Enable(stored); err != nil { t.Fatal("Failed to activate database") } // Ensure journal is deleted from disk if blob := rawdb.ReadTrieJournal(tester.db.diskdb); len(blob) != 0 { t.Fatal("Failed to clean journal") } // Ensure all trie histories are removed n, err := tester.db.freezer.Ancients() if err != nil { t.Fatal("Failed to clean state history") } if n != 0 { t.Fatal("Failed to clean state history") } // Verify layer tree structure, single disk layer is expected if tester.db.tree.len() != 1 { t.Fatalf("Extra layer kept %d", tester.db.tree.len()) } if tester.db.tree.bottom().rootHash() != stored { t.Fatalf("Root hash is not matched exp %x got %x", stored, tester.db.tree.bottom().rootHash()) } } func TestCommit(t *testing.T) { tester := newTester(t, 0) defer tester.release() if err := tester.db.Commit(tester.lastHash(), false); err != nil { t.Fatalf("Failed to cap database, err: %v", err) } // Verify layer tree structure, single disk layer is expected if tester.db.tree.len() != 1 { t.Fatal("Layer tree structure is invalid") } if tester.db.tree.bottom().rootHash() != tester.lastHash() { t.Fatal("Layer tree structure is invalid") } // Verify states if err := tester.verifyState(tester.lastHash()); err != nil { t.Fatalf("State is invalid, err: %v", err) } // Verify state histories if err := tester.verifyHistory(); err != nil { t.Fatalf("State history is invalid, err: %v", err) } } func TestJournal(t *testing.T) { tester := newTester(t, 0) defer tester.release() if err := tester.db.Journal(tester.lastHash()); err != nil { t.Errorf("Failed to journal, err: %v", err) } tester.db.Close() tester.db = New(tester.db.diskdb, nil) // Verify states including disk layer and all diff on top. for i := 0; i < len(tester.roots); i++ { if i >= tester.bottomIndex() { if err := tester.verifyState(tester.roots[i]); err != nil { t.Fatalf("Invalid state, err: %v", err) } continue } if err := tester.verifyState(tester.roots[i]); err == nil { t.Fatal("Unexpected state") } } } func TestCorruptedJournal(t *testing.T) { tester := newTester(t, 0) defer tester.release() if err := tester.db.Journal(tester.lastHash()); err != nil { t.Errorf("Failed to journal, err: %v", err) } tester.db.Close() _, root := rawdb.ReadAccountTrieNode(tester.db.diskdb, nil) // Mutate the journal in disk, it should be regarded as invalid blob := rawdb.ReadTrieJournal(tester.db.diskdb) blob[0] = 1 rawdb.WriteTrieJournal(tester.db.diskdb, blob) // Verify states, all not-yet-written states should be discarded tester.db = New(tester.db.diskdb, nil) for i := 0; i < len(tester.roots); i++ { if tester.roots[i] == root { if err := tester.verifyState(root); err != nil { t.Fatalf("Disk state is corrupted, err: %v", err) } continue } if err := tester.verifyState(tester.roots[i]); err == nil { t.Fatal("Unexpected state") } } } // TestTailTruncateHistory function is designed to test a specific edge case where, // when history objects are removed from the end, it should trigger a state flush // if the ID of the new tail object is even higher than the persisted state ID. // // For example, let's say the ID of the persistent state is 10, and the current // history objects range from ID(5) to ID(15). As we accumulate six more objects, // the history will expand to cover ID(11) to ID(21). ID(11) then becomes the // oldest history object, and its ID is even higher than the stored state. // // In this scenario, it is mandatory to update the persistent state before // truncating the tail histories. This ensures that the ID of the persistent state // always falls within the range of [oldest-history-id, latest-history-id]. func TestTailTruncateHistory(t *testing.T) { tester := newTester(t, 10) defer tester.release() tester.db.Close() tester.db = New(tester.db.diskdb, &Config{StateHistory: 10}) head, err := tester.db.freezer.Ancients() if err != nil { t.Fatalf("Failed to obtain freezer head") } stored := rawdb.ReadPersistentStateID(tester.db.diskdb) if head != stored { t.Fatalf("Failed to truncate excess history object above, stored: %d, head: %d", stored, head) } } // copyAccounts returns a deep-copied account set of the provided one. func copyAccounts(set map[common.Hash][]byte) map[common.Hash][]byte { copied := make(map[common.Hash][]byte, len(set)) for key, val := range set { copied[key] = common.CopyBytes(val) } return copied } // copyStorages returns a deep-copied storage set of the provided one. func copyStorages(set map[common.Hash]map[common.Hash][]byte) map[common.Hash]map[common.Hash][]byte { copied := make(map[common.Hash]map[common.Hash][]byte, len(set)) for addrHash, subset := range set { copied[addrHash] = make(map[common.Hash][]byte, len(subset)) for key, val := range subset { copied[addrHash][key] = common.CopyBytes(val) } } return copied }