// Copyright 2014 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 trie import ( "bytes" "container/heap" "errors" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/ethdb" "github.com/ethereum/go-ethereum/rlp" ) // Iterator is a key-value trie iterator that traverses a Trie. type Iterator struct { nodeIt NodeIterator Key []byte // Current data key on which the iterator is positioned on Value []byte // Current data value on which the iterator is positioned on Err error } // NewIterator creates a new key-value iterator from a node iterator. // Note that the value returned by the iterator is raw. If the content is encoded // (e.g. storage value is RLP-encoded), it's caller's duty to decode it. func NewIterator(it NodeIterator) *Iterator { return &Iterator{ nodeIt: it, } } // Next moves the iterator forward one key-value entry. func (it *Iterator) Next() bool { for it.nodeIt.Next(true) { if it.nodeIt.Leaf() { it.Key = it.nodeIt.LeafKey() it.Value = it.nodeIt.LeafBlob() return true } } it.Key = nil it.Value = nil it.Err = it.nodeIt.Error() return false } // Prove generates the Merkle proof for the leaf node the iterator is currently // positioned on. func (it *Iterator) Prove() [][]byte { return it.nodeIt.LeafProof() } // NodeIterator is an iterator to traverse the trie pre-order. type NodeIterator interface { // Next moves the iterator to the next node. If the parameter is false, any child // nodes will be skipped. Next(bool) bool // Error returns the error status of the iterator. Error() error // Hash returns the hash of the current node. Hash() common.Hash // Parent returns the hash of the parent of the current node. The hash may be the one // grandparent if the immediate parent is an internal node with no hash. Parent() common.Hash // Path returns the hex-encoded path to the current node. // Callers must not retain references to the return value after calling Next. // For leaf nodes, the last element of the path is the 'terminator symbol' 0x10. Path() []byte // NodeBlob returns the rlp-encoded value of the current iterated node. // If the node is an embedded node in its parent, nil is returned then. NodeBlob() []byte // Leaf returns true iff the current node is a leaf node. Leaf() bool // LeafKey returns the key of the leaf. The method panics if the iterator is not // positioned at a leaf. Callers must not retain references to the value after // calling Next. LeafKey() []byte // LeafBlob returns the content of the leaf. The method panics if the iterator // is not positioned at a leaf. Callers must not retain references to the value // after calling Next. LeafBlob() []byte // LeafProof returns the Merkle proof of the leaf. The method panics if the // iterator is not positioned at a leaf. Callers must not retain references // to the value after calling Next. LeafProof() [][]byte // AddResolver sets an intermediate database to use for looking up trie nodes // before reaching into the real persistent layer. // // This is not required for normal operation, rather is an optimization for // cases where trie nodes can be recovered from some external mechanism without // reading from disk. In those cases, this resolver allows short circuiting // accesses and returning them from memory. // // Before adding a similar mechanism to any other place in Geth, consider // making trie.Database an interface and wrapping at that level. It's a huge // refactor, but it could be worth it if another occurrence arises. AddResolver(ethdb.KeyValueReader) } // nodeIteratorState represents the iteration state at one particular node of the // trie, which can be resumed at a later invocation. type nodeIteratorState struct { hash common.Hash // Hash of the node being iterated (nil if not standalone) node node // Trie node being iterated parent common.Hash // Hash of the first full ancestor node (nil if current is the root) index int // Child to be processed next pathlen int // Length of the path to this node } type nodeIterator struct { trie *Trie // Trie being iterated stack []*nodeIteratorState // Hierarchy of trie nodes persisting the iteration state path []byte // Path to the current node err error // Failure set in case of an internal error in the iterator resolver ethdb.KeyValueReader // Optional intermediate resolver above the disk layer } // errIteratorEnd is stored in nodeIterator.err when iteration is done. var errIteratorEnd = errors.New("end of iteration") // seekError is stored in nodeIterator.err if the initial seek has failed. type seekError struct { key []byte err error } func (e seekError) Error() string { return "seek error: " + e.err.Error() } func newNodeIterator(trie *Trie, start []byte) NodeIterator { if trie.Hash() == emptyState { return new(nodeIterator) } it := &nodeIterator{trie: trie} it.err = it.seek(start) return it } func (it *nodeIterator) AddResolver(resolver ethdb.KeyValueReader) { it.resolver = resolver } func (it *nodeIterator) Hash() common.Hash { if len(it.stack) == 0 { return common.Hash{} } return it.stack[len(it.stack)-1].hash } func (it *nodeIterator) Parent() common.Hash { if len(it.stack) == 0 { return common.Hash{} } return it.stack[len(it.stack)-1].parent } func (it *nodeIterator) Leaf() bool { return hasTerm(it.path) } func (it *nodeIterator) LeafKey() []byte { if len(it.stack) > 0 { if _, ok := it.stack[len(it.stack)-1].node.(valueNode); ok { return hexToKeybytes(it.path) } } panic("not at leaf") } func (it *nodeIterator) LeafBlob() []byte { if len(it.stack) > 0 { if node, ok := it.stack[len(it.stack)-1].node.(valueNode); ok { return node } } panic("not at leaf") } func (it *nodeIterator) LeafProof() [][]byte { if len(it.stack) > 0 { if _, ok := it.stack[len(it.stack)-1].node.(valueNode); ok { hasher := newHasher(false) defer returnHasherToPool(hasher) proofs := make([][]byte, 0, len(it.stack)) for i, item := range it.stack[:len(it.stack)-1] { // Gather nodes that end up as hash nodes (or the root) node, hashed := hasher.proofHash(item.node) if _, ok := hashed.(hashNode); ok || i == 0 { enc, _ := rlp.EncodeToBytes(node) proofs = append(proofs, enc) } } return proofs } } panic("not at leaf") } func (it *nodeIterator) Path() []byte { return it.path } func (it *nodeIterator) NodeBlob() []byte { if it.Hash() == (common.Hash{}) { return nil // skip the non-standalone node } blob, err := it.resolveBlob(it.Hash().Bytes(), it.Path()) if err != nil { it.err = err return nil } return blob } func (it *nodeIterator) Error() error { if it.err == errIteratorEnd { return nil } if seek, ok := it.err.(seekError); ok { return seek.err } return it.err } // Next moves the iterator to the next node, returning whether there are any // further nodes. In case of an internal error this method returns false and // sets the Error field to the encountered failure. If `descend` is false, // skips iterating over any subnodes of the current node. func (it *nodeIterator) Next(descend bool) bool { if it.err == errIteratorEnd { return false } if seek, ok := it.err.(seekError); ok { if it.err = it.seek(seek.key); it.err != nil { return false } } // Otherwise step forward with the iterator and report any errors. state, parentIndex, path, err := it.peek(descend) it.err = err if it.err != nil { return false } it.push(state, parentIndex, path) return true } func (it *nodeIterator) seek(prefix []byte) error { // The path we're looking for is the hex encoded key without terminator. key := keybytesToHex(prefix) key = key[:len(key)-1] // Move forward until we're just before the closest match to key. for { state, parentIndex, path, err := it.peekSeek(key) if err == errIteratorEnd { return errIteratorEnd } else if err != nil { return seekError{prefix, err} } else if bytes.Compare(path, key) >= 0 { return nil } it.push(state, parentIndex, path) } } // init initializes the iterator. func (it *nodeIterator) init() (*nodeIteratorState, error) { root := it.trie.Hash() state := &nodeIteratorState{node: it.trie.root, index: -1} if root != emptyRoot { state.hash = root } return state, state.resolve(it, nil) } // peek creates the next state of the iterator. func (it *nodeIterator) peek(descend bool) (*nodeIteratorState, *int, []byte, error) { // Initialize the iterator if we've just started. if len(it.stack) == 0 { state, err := it.init() return state, nil, nil, err } if !descend { // If we're skipping children, pop the current node first it.pop() } // Continue iteration to the next child for len(it.stack) > 0 { parent := it.stack[len(it.stack)-1] ancestor := parent.hash if (ancestor == common.Hash{}) { ancestor = parent.parent } state, path, ok := it.nextChild(parent, ancestor) if ok { if err := state.resolve(it, path); err != nil { return parent, &parent.index, path, err } return state, &parent.index, path, nil } // No more child nodes, move back up. it.pop() } return nil, nil, nil, errIteratorEnd } // peekSeek is like peek, but it also tries to skip resolving hashes by skipping // over the siblings that do not lead towards the desired seek position. func (it *nodeIterator) peekSeek(seekKey []byte) (*nodeIteratorState, *int, []byte, error) { // Initialize the iterator if we've just started. if len(it.stack) == 0 { state, err := it.init() return state, nil, nil, err } if !bytes.HasPrefix(seekKey, it.path) { // If we're skipping children, pop the current node first it.pop() } // Continue iteration to the next child for len(it.stack) > 0 { parent := it.stack[len(it.stack)-1] ancestor := parent.hash if (ancestor == common.Hash{}) { ancestor = parent.parent } state, path, ok := it.nextChildAt(parent, ancestor, seekKey) if ok { if err := state.resolve(it, path); err != nil { return parent, &parent.index, path, err } return state, &parent.index, path, nil } // No more child nodes, move back up. it.pop() } return nil, nil, nil, errIteratorEnd } func (it *nodeIterator) resolveHash(hash hashNode, path []byte) (node, error) { if it.resolver != nil { if blob, err := it.resolver.Get(hash); err == nil && len(blob) > 0 { if resolved, err := decodeNode(hash, blob); err == nil { return resolved, nil } } } resolved, err := it.trie.resolveHash(hash, path) return resolved, err } func (it *nodeIterator) resolveBlob(hash hashNode, path []byte) ([]byte, error) { if it.resolver != nil { if blob, err := it.resolver.Get(hash); err == nil && len(blob) > 0 { return blob, nil } } return it.trie.resolveBlob(hash, path) } func (st *nodeIteratorState) resolve(it *nodeIterator, path []byte) error { if hash, ok := st.node.(hashNode); ok { resolved, err := it.resolveHash(hash, path) if err != nil { return err } st.node = resolved st.hash = common.BytesToHash(hash) } return nil } func findChild(n *fullNode, index int, path []byte, ancestor common.Hash) (node, *nodeIteratorState, []byte, int) { var ( child node state *nodeIteratorState childPath []byte ) for ; index < len(n.Children); index++ { if n.Children[index] != nil { child = n.Children[index] hash, _ := child.cache() state = &nodeIteratorState{ hash: common.BytesToHash(hash), node: child, parent: ancestor, index: -1, pathlen: len(path), } childPath = append(childPath, path...) childPath = append(childPath, byte(index)) return child, state, childPath, index } } return nil, nil, nil, 0 } func (it *nodeIterator) nextChild(parent *nodeIteratorState, ancestor common.Hash) (*nodeIteratorState, []byte, bool) { switch node := parent.node.(type) { case *fullNode: //Full node, move to the first non-nil child. if child, state, path, index := findChild(node, parent.index+1, it.path, ancestor); child != nil { parent.index = index - 1 return state, path, true } case *shortNode: // Short node, return the pointer singleton child if parent.index < 0 { hash, _ := node.Val.cache() state := &nodeIteratorState{ hash: common.BytesToHash(hash), node: node.Val, parent: ancestor, index: -1, pathlen: len(it.path), } path := append(it.path, node.Key...) return state, path, true } } return parent, it.path, false } // nextChildAt is similar to nextChild, except that it targets a child as close to the // target key as possible, thus skipping siblings. func (it *nodeIterator) nextChildAt(parent *nodeIteratorState, ancestor common.Hash, key []byte) (*nodeIteratorState, []byte, bool) { switch n := parent.node.(type) { case *fullNode: // Full node, move to the first non-nil child before the desired key position child, state, path, index := findChild(n, parent.index+1, it.path, ancestor) if child == nil { // No more children in this fullnode return parent, it.path, false } // If the child we found is already past the seek position, just return it. if bytes.Compare(path, key) >= 0 { parent.index = index - 1 return state, path, true } // The child is before the seek position. Try advancing for { nextChild, nextState, nextPath, nextIndex := findChild(n, index+1, it.path, ancestor) // If we run out of children, or skipped past the target, return the // previous one if nextChild == nil || bytes.Compare(nextPath, key) >= 0 { parent.index = index - 1 return state, path, true } // We found a better child closer to the target state, path, index = nextState, nextPath, nextIndex } case *shortNode: // Short node, return the pointer singleton child if parent.index < 0 { hash, _ := n.Val.cache() state := &nodeIteratorState{ hash: common.BytesToHash(hash), node: n.Val, parent: ancestor, index: -1, pathlen: len(it.path), } path := append(it.path, n.Key...) return state, path, true } } return parent, it.path, false } func (it *nodeIterator) push(state *nodeIteratorState, parentIndex *int, path []byte) { it.path = path it.stack = append(it.stack, state) if parentIndex != nil { *parentIndex++ } } func (it *nodeIterator) pop() { parent := it.stack[len(it.stack)-1] it.path = it.path[:parent.pathlen] it.stack = it.stack[:len(it.stack)-1] } func compareNodes(a, b NodeIterator) int { if cmp := bytes.Compare(a.Path(), b.Path()); cmp != 0 { return cmp } if a.Leaf() && !b.Leaf() { return -1 } else if b.Leaf() && !a.Leaf() { return 1 } if cmp := bytes.Compare(a.Hash().Bytes(), b.Hash().Bytes()); cmp != 0 { return cmp } if a.Leaf() && b.Leaf() { return bytes.Compare(a.LeafBlob(), b.LeafBlob()) } return 0 } type differenceIterator struct { a, b NodeIterator // Nodes returned are those in b - a. eof bool // Indicates a has run out of elements count int // Number of nodes scanned on either trie } // NewDifferenceIterator constructs a NodeIterator that iterates over elements in b that // are not in a. Returns the iterator, and a pointer to an integer recording the number // of nodes seen. func NewDifferenceIterator(a, b NodeIterator) (NodeIterator, *int) { a.Next(true) it := &differenceIterator{ a: a, b: b, } return it, &it.count } func (it *differenceIterator) Hash() common.Hash { return it.b.Hash() } func (it *differenceIterator) Parent() common.Hash { return it.b.Parent() } func (it *differenceIterator) Leaf() bool { return it.b.Leaf() } func (it *differenceIterator) LeafKey() []byte { return it.b.LeafKey() } func (it *differenceIterator) LeafBlob() []byte { return it.b.LeafBlob() } func (it *differenceIterator) LeafProof() [][]byte { return it.b.LeafProof() } func (it *differenceIterator) Path() []byte { return it.b.Path() } func (it *differenceIterator) NodeBlob() []byte { return it.b.NodeBlob() } func (it *differenceIterator) AddResolver(resolver ethdb.KeyValueReader) { panic("not implemented") } func (it *differenceIterator) Next(bool) bool { // Invariants: // - We always advance at least one element in b. // - At the start of this function, a's path is lexically greater than b's. if !it.b.Next(true) { return false } it.count++ if it.eof { // a has reached eof, so we just return all elements from b return true } for { switch compareNodes(it.a, it.b) { case -1: // b jumped past a; advance a if !it.a.Next(true) { it.eof = true return true } it.count++ case 1: // b is before a return true case 0: // a and b are identical; skip this whole subtree if the nodes have hashes hasHash := it.a.Hash() == common.Hash{} if !it.b.Next(hasHash) { return false } it.count++ if !it.a.Next(hasHash) { it.eof = true return true } it.count++ } } } func (it *differenceIterator) Error() error { if err := it.a.Error(); err != nil { return err } return it.b.Error() } type nodeIteratorHeap []NodeIterator func (h nodeIteratorHeap) Len() int { return len(h) } func (h nodeIteratorHeap) Less(i, j int) bool { return compareNodes(h[i], h[j]) < 0 } func (h nodeIteratorHeap) Swap(i, j int) { h[i], h[j] = h[j], h[i] } func (h *nodeIteratorHeap) Push(x interface{}) { *h = append(*h, x.(NodeIterator)) } func (h *nodeIteratorHeap) Pop() interface{} { n := len(*h) x := (*h)[n-1] *h = (*h)[0 : n-1] return x } type unionIterator struct { items *nodeIteratorHeap // Nodes returned are the union of the ones in these iterators count int // Number of nodes scanned across all tries } // NewUnionIterator constructs a NodeIterator that iterates over elements in the union // of the provided NodeIterators. Returns the iterator, and a pointer to an integer // recording the number of nodes visited. func NewUnionIterator(iters []NodeIterator) (NodeIterator, *int) { h := make(nodeIteratorHeap, len(iters)) copy(h, iters) heap.Init(&h) ui := &unionIterator{items: &h} return ui, &ui.count } func (it *unionIterator) Hash() common.Hash { return (*it.items)[0].Hash() } func (it *unionIterator) Parent() common.Hash { return (*it.items)[0].Parent() } func (it *unionIterator) Leaf() bool { return (*it.items)[0].Leaf() } func (it *unionIterator) LeafKey() []byte { return (*it.items)[0].LeafKey() } func (it *unionIterator) LeafBlob() []byte { return (*it.items)[0].LeafBlob() } func (it *unionIterator) LeafProof() [][]byte { return (*it.items)[0].LeafProof() } func (it *unionIterator) Path() []byte { return (*it.items)[0].Path() } func (it *unionIterator) NodeBlob() []byte { return (*it.items)[0].NodeBlob() } func (it *unionIterator) AddResolver(resolver ethdb.KeyValueReader) { panic("not implemented") } // Next returns the next node in the union of tries being iterated over. // // It does this by maintaining a heap of iterators, sorted by the iteration // order of their next elements, with one entry for each source trie. Each // time Next() is called, it takes the least element from the heap to return, // advancing any other iterators that also point to that same element. These // iterators are called with descend=false, since we know that any nodes under // these nodes will also be duplicates, found in the currently selected iterator. // Whenever an iterator is advanced, it is pushed back into the heap if it still // has elements remaining. // // In the case that descend=false - eg, we're asked to ignore all subnodes of the // current node - we also advance any iterators in the heap that have the current // path as a prefix. func (it *unionIterator) Next(descend bool) bool { if len(*it.items) == 0 { return false } // Get the next key from the union least := heap.Pop(it.items).(NodeIterator) // Skip over other nodes as long as they're identical, or, if we're not descending, as // long as they have the same prefix as the current node. for len(*it.items) > 0 && ((!descend && bytes.HasPrefix((*it.items)[0].Path(), least.Path())) || compareNodes(least, (*it.items)[0]) == 0) { skipped := heap.Pop(it.items).(NodeIterator) // Skip the whole subtree if the nodes have hashes; otherwise just skip this node if skipped.Next(skipped.Hash() == common.Hash{}) { it.count++ // If there are more elements, push the iterator back on the heap heap.Push(it.items, skipped) } } if least.Next(descend) { it.count++ heap.Push(it.items, least) } return len(*it.items) > 0 } func (it *unionIterator) Error() error { for i := 0; i < len(*it.items); i++ { if err := (*it.items)[i].Error(); err != nil { return err } } return nil }