// Copyright 2018 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 rawdb contains a collection of low level database accessors. package rawdb import ( "bytes" "encoding/binary" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/metrics" ) // The fields below define the low level database schema prefixing. var ( // databaseVersionKey tracks the current database version. databaseVersionKey = []byte("DatabaseVersion") // headHeaderKey tracks the latest known header's hash. headHeaderKey = []byte("LastHeader") // headBlockKey tracks the latest known full block's hash. headBlockKey = []byte("LastBlock") // headFastBlockKey tracks the latest known incomplete block's hash during fast sync. headFastBlockKey = []byte("LastFast") // headFinalizedBlockKey tracks the latest known finalized block hash. headFinalizedBlockKey = []byte("LastFinalized") // persistentStateIDKey tracks the id of latest stored state(for path-based only). persistentStateIDKey = []byte("LastStateID") // lastPivotKey tracks the last pivot block used by fast sync (to reenable on sethead). lastPivotKey = []byte("LastPivot") // fastTrieProgressKey tracks the number of trie entries imported during fast sync. fastTrieProgressKey = []byte("TrieSync") // snapshotDisabledKey flags that the snapshot should not be maintained due to initial sync. snapshotDisabledKey = []byte("SnapshotDisabled") // SnapshotRootKey tracks the hash of the last snapshot. SnapshotRootKey = []byte("SnapshotRoot") // snapshotJournalKey tracks the in-memory diff layers across restarts. snapshotJournalKey = []byte("SnapshotJournal") // snapshotGeneratorKey tracks the snapshot generation marker across restarts. snapshotGeneratorKey = []byte("SnapshotGenerator") // snapshotRecoveryKey tracks the snapshot recovery marker across restarts. snapshotRecoveryKey = []byte("SnapshotRecovery") // snapshotSyncStatusKey tracks the snapshot sync status across restarts. snapshotSyncStatusKey = []byte("SnapshotSyncStatus") // skeletonSyncStatusKey tracks the skeleton sync status across restarts. skeletonSyncStatusKey = []byte("SkeletonSyncStatus") // trieJournalKey tracks the in-memory trie node layers across restarts. trieJournalKey = []byte("TrieJournal") // txIndexTailKey tracks the oldest block whose transactions have been indexed. txIndexTailKey = []byte("TransactionIndexTail") // fastTxLookupLimitKey tracks the transaction lookup limit during fast sync. // This flag is deprecated, it's kept to avoid reporting errors when inspect // database. fastTxLookupLimitKey = []byte("FastTransactionLookupLimit") // badBlockKey tracks the list of bad blocks seen by local badBlockKey = []byte("InvalidBlock") // uncleanShutdownKey tracks the list of local crashes uncleanShutdownKey = []byte("unclean-shutdown") // config prefix for the db // transitionStatusKey tracks the eth2 transition status. transitionStatusKey = []byte("eth2-transition") // snapSyncStatusFlagKey flags that status of snap sync. snapSyncStatusFlagKey = []byte("SnapSyncStatus") // Data item prefixes (use single byte to avoid mixing data types, avoid `i`, used for indexes). headerPrefix = []byte("h") // headerPrefix + num (uint64 big endian) + hash -> header headerTDSuffix = []byte("t") // headerPrefix + num (uint64 big endian) + hash + headerTDSuffix -> td headerHashSuffix = []byte("n") // headerPrefix + num (uint64 big endian) + headerHashSuffix -> hash headerNumberPrefix = []byte("H") // headerNumberPrefix + hash -> num (uint64 big endian) blockBodyPrefix = []byte("b") // blockBodyPrefix + num (uint64 big endian) + hash -> block body blockReceiptsPrefix = []byte("r") // blockReceiptsPrefix + num (uint64 big endian) + hash -> block receipts txLookupPrefix = []byte("l") // txLookupPrefix + hash -> transaction/receipt lookup metadata bloomBitsPrefix = []byte("B") // bloomBitsPrefix + bit (uint16 big endian) + section (uint64 big endian) + hash -> bloom bits SnapshotAccountPrefix = []byte("a") // SnapshotAccountPrefix + account hash -> account trie value SnapshotStoragePrefix = []byte("o") // SnapshotStoragePrefix + account hash + storage hash -> storage trie value CodePrefix = []byte("c") // CodePrefix + code hash -> account code skeletonHeaderPrefix = []byte("S") // skeletonHeaderPrefix + num (uint64 big endian) -> header // Path-based storage scheme of merkle patricia trie. TrieNodeAccountPrefix = []byte("A") // TrieNodeAccountPrefix + hexPath -> trie node TrieNodeStoragePrefix = []byte("O") // TrieNodeStoragePrefix + accountHash + hexPath -> trie node stateIDPrefix = []byte("L") // stateIDPrefix + state root -> state id // VerklePrefix is the database prefix for Verkle trie data, which includes: // (a) Trie nodes // (b) In-memory trie node journal // (c) Persistent state ID // (d) State ID lookups, etc. VerklePrefix = []byte("v") PreimagePrefix = []byte("secure-key-") // PreimagePrefix + hash -> preimage configPrefix = []byte("ethereum-config-") // config prefix for the db genesisPrefix = []byte("ethereum-genesis-") // genesis state prefix for the db // BloomBitsIndexPrefix is the data table of a chain indexer to track its progress BloomBitsIndexPrefix = []byte("iB") ChtPrefix = []byte("chtRootV2-") // ChtPrefix + chtNum (uint64 big endian) -> trie root hash ChtTablePrefix = []byte("cht-") ChtIndexTablePrefix = []byte("chtIndexV2-") BloomTriePrefix = []byte("bltRoot-") // BloomTriePrefix + bloomTrieNum (uint64 big endian) -> trie root hash BloomTrieTablePrefix = []byte("blt-") BloomTrieIndexPrefix = []byte("bltIndex-") CliqueSnapshotPrefix = []byte("clique-") BestUpdateKey = []byte("update-") // bigEndian64(syncPeriod) -> RLP(types.LightClientUpdate) (nextCommittee only referenced by root hash) FixedCommitteeRootKey = []byte("fixedRoot-") // bigEndian64(syncPeriod) -> committee root hash SyncCommitteeKey = []byte("committee-") // bigEndian64(syncPeriod) -> serialized committee FilterMapsPrefix = []byte("fT5-") //TODO fm- filterMapsRangeKey = append(FilterMapsPrefix, byte('R')) filterMapRowPrefix = append(FilterMapsPrefix, byte('r')) // filterMapRowPrefix + mapRowIndex (uint64 big endian) -> filter row filterMapBlockPtrPrefix = append(FilterMapsPrefix, byte('b')) // filterMapBlockPtrPrefix + mapIndex (uint32 big endian) -> block number (uint64 big endian) blockLVPrefix = append(FilterMapsPrefix, byte('p')) // blockLVPrefix + num (uint64 big endian) -> log value pointer (uint64 big endian) revertPointPrefix = append(FilterMapsPrefix, byte('v')) // revertPointPrefix + num (uint64 big endian) -> revert data preimageCounter = metrics.NewRegisteredCounter("db/preimage/total", nil) preimageHitCounter = metrics.NewRegisteredCounter("db/preimage/hits", nil) ) // LegacyTxLookupEntry is the legacy TxLookupEntry definition with some unnecessary // fields. type LegacyTxLookupEntry struct { BlockHash common.Hash BlockIndex uint64 Index uint64 } // encodeBlockNumber encodes a block number as big endian uint64 func encodeBlockNumber(number uint64) []byte { enc := make([]byte, 8) binary.BigEndian.PutUint64(enc, number) return enc } // headerKeyPrefix = headerPrefix + num (uint64 big endian) func headerKeyPrefix(number uint64) []byte { return append(headerPrefix, encodeBlockNumber(number)...) } // headerKey = headerPrefix + num (uint64 big endian) + hash func headerKey(number uint64, hash common.Hash) []byte { return append(append(headerPrefix, encodeBlockNumber(number)...), hash.Bytes()...) } // headerTDKey = headerPrefix + num (uint64 big endian) + hash + headerTDSuffix func headerTDKey(number uint64, hash common.Hash) []byte { return append(headerKey(number, hash), headerTDSuffix...) } // headerHashKey = headerPrefix + num (uint64 big endian) + headerHashSuffix func headerHashKey(number uint64) []byte { return append(append(headerPrefix, encodeBlockNumber(number)...), headerHashSuffix...) } // headerNumberKey = headerNumberPrefix + hash func headerNumberKey(hash common.Hash) []byte { return append(headerNumberPrefix, hash.Bytes()...) } // blockBodyKey = blockBodyPrefix + num (uint64 big endian) + hash func blockBodyKey(number uint64, hash common.Hash) []byte { return append(append(blockBodyPrefix, encodeBlockNumber(number)...), hash.Bytes()...) } // blockReceiptsKey = blockReceiptsPrefix + num (uint64 big endian) + hash func blockReceiptsKey(number uint64, hash common.Hash) []byte { return append(append(blockReceiptsPrefix, encodeBlockNumber(number)...), hash.Bytes()...) } // txLookupKey = txLookupPrefix + hash func txLookupKey(hash common.Hash) []byte { return append(txLookupPrefix, hash.Bytes()...) } // accountSnapshotKey = SnapshotAccountPrefix + hash func accountSnapshotKey(hash common.Hash) []byte { return append(SnapshotAccountPrefix, hash.Bytes()...) } // storageSnapshotKey = SnapshotStoragePrefix + account hash + storage hash func storageSnapshotKey(accountHash, storageHash common.Hash) []byte { buf := make([]byte, len(SnapshotStoragePrefix)+common.HashLength+common.HashLength) n := copy(buf, SnapshotStoragePrefix) n += copy(buf[n:], accountHash.Bytes()) copy(buf[n:], storageHash.Bytes()) return buf } // storageSnapshotsKey = SnapshotStoragePrefix + account hash + storage hash func storageSnapshotsKey(accountHash common.Hash) []byte { return append(SnapshotStoragePrefix, accountHash.Bytes()...) } // skeletonHeaderKey = skeletonHeaderPrefix + num (uint64 big endian) func skeletonHeaderKey(number uint64) []byte { return append(skeletonHeaderPrefix, encodeBlockNumber(number)...) } // preimageKey = PreimagePrefix + hash func preimageKey(hash common.Hash) []byte { return append(PreimagePrefix, hash.Bytes()...) } // codeKey = CodePrefix + hash func codeKey(hash common.Hash) []byte { return append(CodePrefix, hash.Bytes()...) } // IsCodeKey reports whether the given byte slice is the key of contract code, // if so return the raw code hash as well. func IsCodeKey(key []byte) (bool, []byte) { if bytes.HasPrefix(key, CodePrefix) && len(key) == common.HashLength+len(CodePrefix) { return true, key[len(CodePrefix):] } return false, nil } // configKey = configPrefix + hash func configKey(hash common.Hash) []byte { return append(configPrefix, hash.Bytes()...) } // genesisStateSpecKey = genesisPrefix + hash func genesisStateSpecKey(hash common.Hash) []byte { return append(genesisPrefix, hash.Bytes()...) } // stateIDKey = stateIDPrefix + root (32 bytes) func stateIDKey(root common.Hash) []byte { return append(stateIDPrefix, root.Bytes()...) } // accountTrieNodeKey = TrieNodeAccountPrefix + nodePath. func accountTrieNodeKey(path []byte) []byte { return append(TrieNodeAccountPrefix, path...) } // storageTrieNodeKey = TrieNodeStoragePrefix + accountHash + nodePath. func storageTrieNodeKey(accountHash common.Hash, path []byte) []byte { buf := make([]byte, len(TrieNodeStoragePrefix)+common.HashLength+len(path)) n := copy(buf, TrieNodeStoragePrefix) n += copy(buf[n:], accountHash.Bytes()) copy(buf[n:], path) return buf } // IsLegacyTrieNode reports whether a provided database entry is a legacy trie // node. The characteristics of legacy trie node are: // - the key length is 32 bytes // - the key is the hash of val func IsLegacyTrieNode(key []byte, val []byte) bool { if len(key) != common.HashLength { return false } return bytes.Equal(key, crypto.Keccak256(val)) } // ResolveAccountTrieNodeKey reports whether a provided database entry is an // account trie node in path-based state scheme, and returns the resolved // node path if so. func ResolveAccountTrieNodeKey(key []byte) (bool, []byte) { if !bytes.HasPrefix(key, TrieNodeAccountPrefix) { return false, nil } // The remaining key should only consist a hex node path // whose length is in the range 0 to 64 (64 is excluded // since leaves are always wrapped with shortNode). if len(key) >= len(TrieNodeAccountPrefix)+common.HashLength*2 { return false, nil } return true, key[len(TrieNodeAccountPrefix):] } // IsAccountTrieNode reports whether a provided database entry is an account // trie node in path-based state scheme. func IsAccountTrieNode(key []byte) bool { ok, _ := ResolveAccountTrieNodeKey(key) return ok } // ResolveStorageTrieNode reports whether a provided database entry is a storage // trie node in path-based state scheme, and returns the resolved account hash // and node path if so. func ResolveStorageTrieNode(key []byte) (bool, common.Hash, []byte) { if !bytes.HasPrefix(key, TrieNodeStoragePrefix) { return false, common.Hash{}, nil } // The remaining key consists of 2 parts: // - 32 bytes account hash // - hex node path whose length is in the range 0 to 64 if len(key) < len(TrieNodeStoragePrefix)+common.HashLength { return false, common.Hash{}, nil } if len(key) >= len(TrieNodeStoragePrefix)+common.HashLength+common.HashLength*2 { return false, common.Hash{}, nil } accountHash := common.BytesToHash(key[len(TrieNodeStoragePrefix) : len(TrieNodeStoragePrefix)+common.HashLength]) return true, accountHash, key[len(TrieNodeStoragePrefix)+common.HashLength:] } // IsStorageTrieNode reports whether a provided database entry is a storage // trie node in path-based state scheme. func IsStorageTrieNode(key []byte) bool { ok, _, _ := ResolveStorageTrieNode(key) return ok } // filterMapRowKey = filterMapRowPrefix + mapRowIndex (uint64 big endian) func filterMapRowKey(mapRowIndex uint64) []byte { key := append(filterMapRowPrefix, make([]byte, 8)...) binary.BigEndian.PutUint64(key[1:], mapRowIndex) return key } // filterMapBlockPtrKey = filterMapBlockPtrPrefix + mapIndex (uint32 big endian) func filterMapBlockPtrKey(mapIndex uint32) []byte { key := append(filterMapBlockPtrPrefix, make([]byte, 4)...) binary.BigEndian.PutUint32(key[1:], mapIndex) return key } // blockLVKey = blockLVPrefix + num (uint64 big endian) func blockLVKey(number uint64) []byte { return append(blockLVPrefix, encodeBlockNumber(number)...) } // revertPointKey = revertPointPrefix + num (uint64 big endian) func revertPointKey(number uint64) []byte { return append(revertPointPrefix, encodeBlockNumber(number)...) }