// Copyright 2019 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 . // Contains a batch of utility type declarations used by the tests. As the node // operates on unique types, a lot of them are needed to check various features. package statediff import ( "bytes" "fmt" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/core/state" "github.com/ethereum/go-ethereum/core/types" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/log" "github.com/ethereum/go-ethereum/rlp" "github.com/ethereum/go-ethereum/trie" ) var ( nullHashBytes = common.Hex2Bytes("0000000000000000000000000000000000000000000000000000000000000000") emptyNode, _ = rlp.EncodeToBytes([]byte{}) emptyContractRoot = crypto.Keccak256Hash(emptyNode) ) // Builder interface exposes the method for building a state diff between two blocks type Builder interface { BuildStateDiffObject(args Args, params Params) (StateObject, error) BuildStateTrieObject(current *types.Block) (StateObject, error) } type builder struct { stateCache state.Database } // NewBuilder is used to create a statediff builder func NewBuilder(stateCache state.Database) Builder { return &builder{ stateCache: stateCache, // state cache is safe for concurrent reads } } // BuildStateTrieObject builds a state trie object from the provided block func (sdb *builder) BuildStateTrieObject(current *types.Block) (StateObject, error) { currentTrie, err := sdb.stateCache.OpenTrie(current.Root()) if err != nil { return StateObject{}, fmt.Errorf("error creating trie for block %d: %v", current.Number(), err) } it := currentTrie.NodeIterator([]byte{}) stateNodes, err := sdb.buildStateTrie(it) if err != nil { return StateObject{}, fmt.Errorf("error collecting state nodes for block %d: %v", current.Number(), err) } return StateObject{ BlockNumber: current.Number(), BlockHash: current.Hash(), Nodes: stateNodes, }, nil } func (sdb *builder) buildStateTrie(it trie.NodeIterator) ([]StateNode, error) { stateNodes := make([]StateNode, 0) for it.Next(true) { // skip value nodes if it.Leaf() { continue } if bytes.Equal(nullHashBytes, it.Hash().Bytes()) { continue } nodePath := make([]byte, len(it.Path())) copy(nodePath, it.Path()) node, err := sdb.stateCache.TrieDB().Node(it.Hash()) if err != nil { return nil, err } var nodeElements []interface{} if err := rlp.DecodeBytes(node, &nodeElements); err != nil { return nil, err } ty, err := CheckKeyType(nodeElements) if err != nil { return nil, err } switch ty { case Leaf: var account state.Account if err := rlp.DecodeBytes(nodeElements[1].([]byte), &account); err != nil { return nil, fmt.Errorf("error decoding account for leaf node at path %x nerror: %v", nodePath, err) } partialPath := trie.CompactToHex(nodeElements[0].([]byte)) valueNodePath := append(nodePath, partialPath...) encodedPath := trie.HexToCompact(valueNodePath) leafKey := encodedPath[1:] storageNodes, err := sdb.buildStorageNodesEventual(account.Root, nil, true) if err != nil { return nil, fmt.Errorf("failed building eventual storage diffs for account %+v\r\nerror: %v", account, err) } stateNodes = append(stateNodes, StateNode{ NodeType: ty, Path: nodePath, LeafKey: leafKey, NodeValue: node, StorageNodes: storageNodes, }) case Extension, Branch: stateNodes = append(stateNodes, StateNode{ NodeType: ty, Path: nodePath, NodeValue: node, }) default: return nil, fmt.Errorf("unexpected node type %s", ty) } } return stateNodes, nil } // BuildStateDiffObject builds a statediff object from two blocks and the provided parameters func (sdb *builder) BuildStateDiffObject(args Args, params Params) (StateObject, error) { if !params.IntermediateStateNodes || len(params.WatchedAddresses) > 0 { // if we are watching only specific accounts then we are only diffing leaf nodes return sdb.buildStateDiffWithoutIntermediateStateNodes(args, params) } return sdb.buildStateDiffWithIntermediateStateNodes(args, params) } func (sdb *builder) buildStateDiffWithIntermediateStateNodes(args Args, params Params) (StateObject, error) { // Load tries for old and new states oldTrie, err := sdb.stateCache.OpenTrie(args.OldStateRoot) if err != nil { return StateObject{}, fmt.Errorf("error creating trie for oldStateRoot: %v", err) } newTrie, err := sdb.stateCache.OpenTrie(args.NewStateRoot) if err != nil { return StateObject{}, fmt.Errorf("error creating trie for newStateRoot: %v", err) } // collect a slice of all the intermediate nodes that were touched and exist at B // a map of their leafkey to all the accounts that were touched and exist at B // and a slice of all the paths for the nodes in both of the above sets createdOrUpdatedIntermediateNodes, diffAccountsAtB, diffPathsAtB, err := sdb.createdAndUpdatedStateWithIntermediateNodes(oldTrie.NodeIterator([]byte{}), newTrie.NodeIterator([]byte{})) if err != nil { return StateObject{}, fmt.Errorf("error collecting createdAndUpdatedNodes: %v", err) } // collect a slice of all the nodes that existed at a path in A that doesn't exist in B // a map of their leafkey to all the accounts that were touched and exist at A emptiedPaths, diffAccountsAtA, err := sdb.deletedOrUpdatedState(oldTrie.NodeIterator([]byte{}), newTrie.NodeIterator([]byte{}), diffPathsAtB) if err != nil { return StateObject{}, fmt.Errorf("error collecting deletedOrUpdatedNodes: %v", err) } // collect and sort the leafkey keys for both account mappings into a slice createKeys := sortKeys(diffAccountsAtB) deleteKeys := sortKeys(diffAccountsAtA) // and then find the intersection of these keys // these are the leafkeys for the accounts which exist at both A and B but are different // this also mutates the passed in createKeys and deleteKeys, removing the intersection keys // and leaving the truly created or deleted keys in place updatedKeys := findIntersection(createKeys, deleteKeys) // build the diff nodes for the updated accounts using the mappings at both A and B as directed by the keys found as the intersection of the two updatedAccounts, err := sdb.buildAccountUpdates(diffAccountsAtB, diffAccountsAtA, updatedKeys, params.WatchedStorageSlots, params.IntermediateStorageNodes) if err != nil { return StateObject{}, fmt.Errorf("error building diff for updated accounts: %v", err) } // build the diff nodes for created accounts createdAccounts, err := sdb.buildAccountCreations(diffAccountsAtB, params.WatchedStorageSlots, params.IntermediateStorageNodes) if err != nil { return StateObject{}, fmt.Errorf("error building diff for created accounts: %v", err) } // assemble all of the nodes into the statediff object, including the intermediate nodes return StateObject{ BlockNumber: args.BlockNumber, BlockHash: args.BlockHash, Nodes: append(append(append(updatedAccounts, createdAccounts...), createdOrUpdatedIntermediateNodes...), emptiedPaths...), }, nil } func (sdb *builder) buildStateDiffWithoutIntermediateStateNodes(args Args, params Params) (StateObject, error) { // Load tries for old (A) and new (B) states oldTrie, err := sdb.stateCache.OpenTrie(args.OldStateRoot) if err != nil { return StateObject{}, fmt.Errorf("error creating trie for oldStateRoot: %v", err) } newTrie, err := sdb.stateCache.OpenTrie(args.NewStateRoot) if err != nil { return StateObject{}, fmt.Errorf("error creating trie for newStateRoot: %v", err) } // collect a map of their leafkey to all the accounts that were touched and exist at B // and a slice of all the paths for the nodes in both of the above sets diffAccountsAtB, diffPathsAtB, err := sdb.createdAndUpdatedState(oldTrie.NodeIterator([]byte{}), newTrie.NodeIterator([]byte{}), params.WatchedAddresses) if err != nil { return StateObject{}, fmt.Errorf("error collecting createdAndUpdatedNodes: %v", err) } // collect a slice of all the nodes that existed at a path in A that doesn't exist in B // a map of their leafkey to all the accounts that were touched and exist at A emptiedPaths, diffAccountsAtA, err := sdb.deletedOrUpdatedState(oldTrie.NodeIterator([]byte{}), newTrie.NodeIterator([]byte{}), diffPathsAtB) if err != nil { return StateObject{}, fmt.Errorf("error collecting deletedOrUpdatedNodes: %v", err) } // collect and sort the leafkeys for both account mappings into a slice createKeys := sortKeys(diffAccountsAtB) deleteKeys := sortKeys(diffAccountsAtA) // and then find the intersection of these keys // these are the leafkeys for the accounts which exist at both A and B but are different // this also mutates the passed in createKeys and deleteKeys, removing in intersection keys // and leaving the truly created or deleted keys in place updatedKeys := findIntersection(createKeys, deleteKeys) // build the diff nodes for the updated accounts using the mappings at both A and B as directed by the keys found as the intersection of the two updatedAccounts, err := sdb.buildAccountUpdates(diffAccountsAtB, diffAccountsAtA, updatedKeys, params.WatchedStorageSlots, params.IntermediateStorageNodes) if err != nil { return StateObject{}, fmt.Errorf("error building diff for updated accounts: %v", err) } // build the diff nodes for created accounts createdAccounts, err := sdb.buildAccountCreations(diffAccountsAtB, params.WatchedStorageSlots, params.IntermediateStorageNodes) if err != nil { return StateObject{}, fmt.Errorf("error building diff for created accounts: %v", err) } // assemble all of the nodes into the statediff object return StateObject{ BlockNumber: args.BlockNumber, BlockHash: args.BlockHash, Nodes: append(append(updatedAccounts, createdAccounts...), emptiedPaths...), }, nil } // createdAndUpdatedState returns // a mapping of their leafkeys to all the accounts that exist in a different state at B than A // and a slice of the paths for all of the nodes included in both func (sdb *builder) createdAndUpdatedState(a, b trie.NodeIterator, watchedAddresses []common.Address) (AccountMap, map[string]bool, error) { diffPathsAtB := make(map[string]bool) diffAcountsAtB := make(AccountMap) it, _ := trie.NewDifferenceIterator(a, b) for it.Next(true) { // skip value nodes if it.Leaf() { continue } if bytes.Equal(nullHashBytes, it.Hash().Bytes()) { continue } nodePath := make([]byte, len(it.Path())) copy(nodePath, it.Path()) node, err := sdb.stateCache.TrieDB().Node(it.Hash()) if err != nil { return nil, nil, err } var nodeElements []interface{} if err := rlp.DecodeBytes(node, &nodeElements); err != nil { return nil, nil, err } ty, err := CheckKeyType(nodeElements) if err != nil { return nil, nil, err } if ty == Leaf { // created vs updated is important for leaf nodes since we need to diff their storage // so we need to map all changed accounts at B to their leafkey, since account can change pathes but not leafkey var account state.Account if err := rlp.DecodeBytes(nodeElements[1].([]byte), &account); err != nil { return nil, nil, fmt.Errorf("error decoding account for leaf node at path %x nerror: %v", nodePath, err) } partialPath := trie.CompactToHex(nodeElements[0].([]byte)) valueNodePath := append(nodePath, partialPath...) encodedPath := trie.HexToCompact(valueNodePath) leafKey := encodedPath[1:] if isWatchedAddress(watchedAddresses, leafKey) { diffAcountsAtB[common.Bytes2Hex(leafKey)] = accountWrapper{ NodeType: ty, Path: nodePath, NodeValue: node, LeafKey: leafKey, Account: &account, } } } // add both intermediate and leaf node paths to the list of diffPathsAtB diffPathsAtB[common.Bytes2Hex(nodePath)] = true } return diffAcountsAtB, diffPathsAtB, nil } // createdAndUpdatedStateWithIntermediateNodes returns // a slice of all the intermediate nodes that exist in a different state at B than A // a mapping of their leafkeys to all the accounts that exist in a different state at B than A // and a slice of the paths for all of the nodes included in both func (sdb *builder) createdAndUpdatedStateWithIntermediateNodes(a, b trie.NodeIterator) ([]StateNode, AccountMap, map[string]bool, error) { createdOrUpdatedIntermediateNodes := make([]StateNode, 0) diffPathsAtB := make(map[string]bool) diffAcountsAtB := make(AccountMap) it, _ := trie.NewDifferenceIterator(a, b) for it.Next(true) { // skip value nodes if it.Leaf() { continue } if bytes.Equal(nullHashBytes, it.Hash().Bytes()) { continue } nodePath := make([]byte, len(it.Path())) copy(nodePath, it.Path()) node, err := sdb.stateCache.TrieDB().Node(it.Hash()) if err != nil { return nil, nil, nil, err } var nodeElements []interface{} if err := rlp.DecodeBytes(node, &nodeElements); err != nil { return nil, nil, nil, err } ty, err := CheckKeyType(nodeElements) if err != nil { return nil, nil, nil, err } switch ty { case Leaf: // created vs updated is important for leaf nodes since we need to diff their storage // so we need to map all changed accounts at B to their leafkey, since account can change pathes but not leafkey var account state.Account if err := rlp.DecodeBytes(nodeElements[1].([]byte), &account); err != nil { return nil, nil, nil, fmt.Errorf("error decoding account for leaf node at path %x nerror: %v", nodePath, err) } partialPath := trie.CompactToHex(nodeElements[0].([]byte)) valueNodePath := append(nodePath, partialPath...) encodedPath := trie.HexToCompact(valueNodePath) leafKey := encodedPath[1:] diffAcountsAtB[common.Bytes2Hex(leafKey)] = accountWrapper{ NodeType: ty, Path: nodePath, NodeValue: node, LeafKey: leafKey, Account: &account, } case Extension, Branch: // create a diff for any intermediate node that has changed at b // created vs updated makes no difference for intermediate nodes since we do not need to diff storage createdOrUpdatedIntermediateNodes = append(createdOrUpdatedIntermediateNodes, StateNode{ NodeType: ty, Path: nodePath, NodeValue: node, }) default: return nil, nil, nil, fmt.Errorf("unexpected node type %s", ty) } // add both intermediate and leaf node paths to the list of diffPathsAtB diffPathsAtB[common.Bytes2Hex(nodePath)] = true } return createdOrUpdatedIntermediateNodes, diffAcountsAtB, diffPathsAtB, nil } // deletedOrUpdatedState returns a slice of all the pathes that are emptied at B // and a mapping of their leafkeys to all the accounts that exist in a different state at A than B func (sdb *builder) deletedOrUpdatedState(a, b trie.NodeIterator, diffPathsAtB map[string]bool) ([]StateNode, AccountMap, error) { emptiedPaths := make([]StateNode, 0) diffAccountAtA := make(AccountMap) it, _ := trie.NewDifferenceIterator(b, a) for it.Next(true) { // skip value nodes if it.Leaf() { continue } if bytes.Equal(nullHashBytes, it.Hash().Bytes()) { continue } nodePath := make([]byte, len(it.Path())) copy(nodePath, it.Path()) // if this nodePath did not show up in diffPathsAtB // that means the node at this path was deleted (or moved) in B // emit an empty "removed" diff to signify as such if _, ok := diffPathsAtB[common.Bytes2Hex(nodePath)]; !ok { emptiedPaths = append(emptiedPaths, StateNode{ Path: nodePath, NodeValue: []byte{}, NodeType: Removed, }) } node, err := sdb.stateCache.TrieDB().Node(it.Hash()) if err != nil { return nil, nil, err } var nodeElements []interface{} if err := rlp.DecodeBytes(node, &nodeElements); err != nil { return nil, nil, err } ty, err := CheckKeyType(nodeElements) if err != nil { return nil, nil, err } switch ty { case Leaf: // map all different accounts at A to their leafkey var account state.Account if err := rlp.DecodeBytes(nodeElements[1].([]byte), &account); err != nil { return nil, nil, fmt.Errorf("error decoding account for leaf node at path %x nerror: %v", nodePath, err) } partialPath := trie.CompactToHex(nodeElements[0].([]byte)) valueNodePath := append(nodePath, partialPath...) encodedPath := trie.HexToCompact(valueNodePath) leafKey := encodedPath[1:] diffAccountAtA[common.Bytes2Hex(leafKey)] = accountWrapper{ NodeType: ty, Path: nodePath, NodeValue: node, LeafKey: leafKey, Account: &account, } case Extension, Branch: // fall through, we did everything we need to do with these node types default: return nil, nil, fmt.Errorf("unexpected node type %s", ty) } } return emptiedPaths, diffAccountAtA, nil } // buildAccountUpdates uses the account diffs maps for A => B and B => A and the known intersection of their leafkeys // to generate the statediff node objects for all of the accounts that existed at both A and B but in different states // needs to be called before building account creations and deletions as this mutates // those account maps to remove the accounts which were updated func (sdb *builder) buildAccountUpdates(creations, deletions AccountMap, updatedKeys []string, watchedStorageKeys []common.Hash, intermediateStorageNodes bool) ([]StateNode, error) { updatedAccounts := make([]StateNode, 0, len(updatedKeys)) var err error for _, key := range updatedKeys { createdAcc := creations[key] deletedAcc := deletions[key] var storageDiffs []StorageNode if deletedAcc.Account != nil && createdAcc.Account != nil { oldSR := deletedAcc.Account.Root newSR := createdAcc.Account.Root storageDiffs, err = sdb.buildStorageNodesIncremental(oldSR, newSR, watchedStorageKeys, intermediateStorageNodes) if err != nil { return nil, fmt.Errorf("failed building incremental storage diffs for account with leafkey %s\r\nerror: %v", key, err) } } updatedAccounts = append(updatedAccounts, StateNode{ NodeType: createdAcc.NodeType, Path: createdAcc.Path, NodeValue: createdAcc.NodeValue, LeafKey: createdAcc.LeafKey, StorageNodes: storageDiffs, }) delete(creations, key) delete(deletions, key) } return updatedAccounts, nil } // buildAccountCreations returns the statediff node objects for all the accounts that exist at B but not at A func (sdb *builder) buildAccountCreations(accounts AccountMap, watchedStorageKeys []common.Hash, intermediateStorageNodes bool) ([]StateNode, error) { accountDiffs := make([]StateNode, 0, len(accounts)) for _, val := range accounts { // For account creations, any storage node contained is a diff storageDiffs, err := sdb.buildStorageNodesEventual(val.Account.Root, watchedStorageKeys, intermediateStorageNodes) if err != nil { return nil, fmt.Errorf("failed building eventual storage diffs for node %x\r\nerror: %v", val.Path, err) } accountDiffs = append(accountDiffs, StateNode{ NodeType: val.NodeType, Path: val.Path, LeafKey: val.LeafKey, NodeValue: val.NodeValue, StorageNodes: storageDiffs, }) } return accountDiffs, nil } // buildStorageNodesEventual builds the storage diff node objects for a created account // i.e. it returns all the storage nodes at this state, since there is no previous state func (sdb *builder) buildStorageNodesEventual(sr common.Hash, watchedStorageKeys []common.Hash, intermediateNodes bool) ([]StorageNode, error) { if bytes.Equal(sr.Bytes(), emptyContractRoot.Bytes()) { return nil, nil } log.Debug("Storage Root For Eventual Diff", "root", sr.Hex()) sTrie, err := sdb.stateCache.OpenTrie(sr) if err != nil { log.Info("error in build storage diff eventual", "error", err) return nil, err } it := sTrie.NodeIterator(make([]byte, 0)) return sdb.buildStorageNodesFromTrie(it, watchedStorageKeys, intermediateNodes) } // buildStorageNodesFromTrie returns all the storage diff node objects in the provided node interator // if any storage keys are provided it will only return those leaf nodes // including intermediate nodes can be turned on or off func (sdb *builder) buildStorageNodesFromTrie(it trie.NodeIterator, watchedStorageKeys []common.Hash, intermediateNodes bool) ([]StorageNode, error) { storageDiffs := make([]StorageNode, 0) for it.Next(true) { // skip value nodes if it.Leaf() { continue } if bytes.Equal(nullHashBytes, it.Hash().Bytes()) { continue } nodePath := make([]byte, len(it.Path())) copy(nodePath, it.Path()) node, err := sdb.stateCache.TrieDB().Node(it.Hash()) if err != nil { return nil, err } var nodeElements []interface{} if err := rlp.DecodeBytes(node, &nodeElements); err != nil { return nil, err } ty, err := CheckKeyType(nodeElements) if err != nil { return nil, err } switch ty { case Leaf: partialPath := trie.CompactToHex(nodeElements[0].([]byte)) valueNodePath := append(nodePath, partialPath...) encodedPath := trie.HexToCompact(valueNodePath) leafKey := encodedPath[1:] if isWatchedStorageKey(watchedStorageKeys, leafKey) { storageDiffs = append(storageDiffs, StorageNode{ NodeType: ty, Path: nodePath, NodeValue: node, LeafKey: leafKey, }) } case Extension, Branch: if intermediateNodes { storageDiffs = append(storageDiffs, StorageNode{ NodeType: ty, Path: nodePath, NodeValue: node, }) } default: return nil, fmt.Errorf("unexpected node type %s", ty) } } return storageDiffs, nil } // buildStorageNodesIncremental builds the storage diff node objects for all nodes that exist in a different state at B than A func (sdb *builder) buildStorageNodesIncremental(oldSR common.Hash, newSR common.Hash, watchedStorageKeys []common.Hash, intermediateNodes bool) ([]StorageNode, error) { if bytes.Equal(newSR.Bytes(), oldSR.Bytes()) { return nil, nil } log.Debug("Storage Roots for Incremental Diff", "old", oldSR.Hex(), "new", newSR.Hex()) oldTrie, err := sdb.stateCache.OpenTrie(oldSR) if err != nil { return nil, err } newTrie, err := sdb.stateCache.OpenTrie(newSR) if err != nil { return nil, err } createdOrUpdatedStorage, diffPathsAtB, err := sdb.createdAndUpdatedStorage(oldTrie.NodeIterator([]byte{}), newTrie.NodeIterator([]byte{}), watchedStorageKeys, intermediateNodes) if err != nil { return nil, err } deletedStorage, err := sdb.deletedOrUpdatedStorage(oldTrie.NodeIterator([]byte{}), newTrie.NodeIterator([]byte{}), diffPathsAtB, watchedStorageKeys, intermediateNodes) if err != nil { return nil, err } return append(createdOrUpdatedStorage, deletedStorage...), nil } func (sdb *builder) createdAndUpdatedStorage(a, b trie.NodeIterator, watchedKeys []common.Hash, intermediateNodes bool) ([]StorageNode, map[string]bool, error) { createdOrUpdatedStorage := make([]StorageNode, 0) diffPathsAtB := make(map[string]bool) it, _ := trie.NewDifferenceIterator(a, b) for it.Next(true) { // skip value nodes if it.Leaf() { continue } if bytes.Equal(nullHashBytes, it.Hash().Bytes()) { continue } nodePath := make([]byte, len(it.Path())) copy(nodePath, it.Path()) node, err := sdb.stateCache.TrieDB().Node(it.Hash()) if err != nil { return nil, nil, err } var nodeElements []interface{} if err := rlp.DecodeBytes(node, &nodeElements); err != nil { return nil, nil, err } ty, err := CheckKeyType(nodeElements) if err != nil { return nil, nil, err } switch ty { case Leaf: partialPath := trie.CompactToHex(nodeElements[0].([]byte)) valueNodePath := append(nodePath, partialPath...) encodedPath := trie.HexToCompact(valueNodePath) leafKey := encodedPath[1:] if isWatchedStorageKey(watchedKeys, leafKey) { createdOrUpdatedStorage = append(createdOrUpdatedStorage, StorageNode{ NodeType: ty, Path: nodePath, NodeValue: node, LeafKey: leafKey, }) } case Extension, Branch: if intermediateNodes { createdOrUpdatedStorage = append(createdOrUpdatedStorage, StorageNode{ NodeType: ty, Path: nodePath, NodeValue: node, }) } default: return nil, nil, fmt.Errorf("unexpected node type %s", ty) } diffPathsAtB[common.Bytes2Hex(nodePath)] = true } return createdOrUpdatedStorage, diffPathsAtB, nil } func (sdb *builder) deletedOrUpdatedStorage(a, b trie.NodeIterator, diffPathsAtB map[string]bool, watchedKeys []common.Hash, intermediateNodes bool) ([]StorageNode, error) { deletedStorage := make([]StorageNode, 0) it, _ := trie.NewDifferenceIterator(b, a) for it.Next(true) { // skip value nodes if it.Leaf() { continue } if bytes.Equal(nullHashBytes, it.Hash().Bytes()) { continue } nodePath := make([]byte, len(it.Path())) copy(nodePath, it.Path()) // if this node path showed up in diffPathsAtB // that means this node was updated at B and we already have the updated diff for it // otherwise that means this node was deleted in B and we need to add a "removed" diff to represent that event if _, ok := diffPathsAtB[common.Bytes2Hex(nodePath)]; ok { continue } node, err := sdb.stateCache.TrieDB().Node(it.Hash()) if err != nil { return nil, err } var nodeElements []interface{} if err := rlp.DecodeBytes(node, &nodeElements); err != nil { return nil, err } ty, err := CheckKeyType(nodeElements) if err != nil { return nil, err } switch ty { case Leaf: partialPath := trie.CompactToHex(nodeElements[0].([]byte)) valueNodePath := append(nodePath, partialPath...) encodedPath := trie.HexToCompact(valueNodePath) leafKey := encodedPath[1:] if isWatchedStorageKey(watchedKeys, leafKey) { deletedStorage = append(deletedStorage, StorageNode{ NodeType: Removed, Path: nodePath, NodeValue: []byte{}, }) } case Extension, Branch: if intermediateNodes { deletedStorage = append(deletedStorage, StorageNode{ NodeType: Removed, Path: nodePath, NodeValue: []byte{}, }) } default: return nil, fmt.Errorf("unexpected node type %s", ty) } } return deletedStorage, nil } // isWatchedAddress is used to check if a state account corresponds to one of the addresses the builder is configured to watch func isWatchedAddress(watchedAddresses []common.Address, stateLeafKey []byte) bool { // If we aren't watching any specific addresses, we are watching everything if len(watchedAddresses) == 0 { return true } for _, addr := range watchedAddresses { addrHashKey := crypto.Keccak256(addr.Bytes()) if bytes.Equal(addrHashKey, stateLeafKey) { return true } } return false } // isWatchedStorageKey is used to check if a storage leaf corresponds to one of the storage slots the builder is configured to watch func isWatchedStorageKey(watchedKeys []common.Hash, storageLeafKey []byte) bool { // If we aren't watching any specific addresses, we are watching everything if len(watchedKeys) == 0 { return true } for _, hashKey := range watchedKeys { if bytes.Equal(hashKey.Bytes(), storageLeafKey) { return true } } return false }