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65ed1a6871
This change speeds up trie hashing and all other activities that require RLP encoding of trie nodes by approximately 20%. The speedup is achieved by avoiding reflection overhead during node encoding. The interface type trie.node now contains a method 'encode' that works with rlp.EncoderBuffer. Management of EncoderBuffers is left to calling code. trie.hasher, which is pooled to avoid allocations, now maintains an EncoderBuffer. This means memory resources related to trie node encoding are tied to the hasher pool. Co-authored-by: Felix Lange <fjl@twurst.com>
510 lines
13 KiB
Go
510 lines
13 KiB
Go
// Copyright 2020 The go-ethereum Authors
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// This file is part of the go-ethereum library.
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//
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// The go-ethereum library is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Lesser General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// The go-ethereum library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public License
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// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
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package trie
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import (
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"bufio"
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"bytes"
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"encoding/gob"
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"errors"
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"fmt"
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"io"
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"sync"
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"github.com/ethereum/go-ethereum/common"
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"github.com/ethereum/go-ethereum/ethdb"
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"github.com/ethereum/go-ethereum/log"
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)
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var ErrCommitDisabled = errors.New("no database for committing")
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var stPool = sync.Pool{
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New: func() interface{} {
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return NewStackTrie(nil)
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},
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}
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func stackTrieFromPool(db ethdb.KeyValueWriter) *StackTrie {
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st := stPool.Get().(*StackTrie)
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st.db = db
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return st
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}
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func returnToPool(st *StackTrie) {
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st.Reset()
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stPool.Put(st)
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}
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// StackTrie is a trie implementation that expects keys to be inserted
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// in order. Once it determines that a subtree will no longer be inserted
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// into, it will hash it and free up the memory it uses.
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type StackTrie struct {
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nodeType uint8 // node type (as in branch, ext, leaf)
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val []byte // value contained by this node if it's a leaf
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key []byte // key chunk covered by this (leaf|ext) node
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children [16]*StackTrie // list of children (for branch and exts)
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db ethdb.KeyValueWriter // Pointer to the commit db, can be nil
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}
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// NewStackTrie allocates and initializes an empty trie.
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func NewStackTrie(db ethdb.KeyValueWriter) *StackTrie {
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return &StackTrie{
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nodeType: emptyNode,
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db: db,
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}
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}
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// NewFromBinary initialises a serialized stacktrie with the given db.
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func NewFromBinary(data []byte, db ethdb.KeyValueWriter) (*StackTrie, error) {
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var st StackTrie
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if err := st.UnmarshalBinary(data); err != nil {
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return nil, err
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}
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// If a database is used, we need to recursively add it to every child
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if db != nil {
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st.setDb(db)
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}
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return &st, nil
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}
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// MarshalBinary implements encoding.BinaryMarshaler
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func (st *StackTrie) MarshalBinary() (data []byte, err error) {
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var (
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b bytes.Buffer
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w = bufio.NewWriter(&b)
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)
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if err := gob.NewEncoder(w).Encode(struct {
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Nodetype uint8
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Val []byte
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Key []byte
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}{
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st.nodeType,
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st.val,
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st.key,
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}); err != nil {
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return nil, err
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}
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for _, child := range st.children {
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if child == nil {
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w.WriteByte(0)
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continue
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}
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w.WriteByte(1)
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if childData, err := child.MarshalBinary(); err != nil {
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return nil, err
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} else {
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w.Write(childData)
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}
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}
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w.Flush()
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return b.Bytes(), nil
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}
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// UnmarshalBinary implements encoding.BinaryUnmarshaler
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func (st *StackTrie) UnmarshalBinary(data []byte) error {
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r := bytes.NewReader(data)
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return st.unmarshalBinary(r)
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}
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func (st *StackTrie) unmarshalBinary(r io.Reader) error {
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var dec struct {
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Nodetype uint8
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Val []byte
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Key []byte
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}
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gob.NewDecoder(r).Decode(&dec)
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st.nodeType = dec.Nodetype
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st.val = dec.Val
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st.key = dec.Key
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var hasChild = make([]byte, 1)
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for i := range st.children {
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if _, err := r.Read(hasChild); err != nil {
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return err
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} else if hasChild[0] == 0 {
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continue
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}
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var child StackTrie
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child.unmarshalBinary(r)
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st.children[i] = &child
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}
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return nil
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}
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func (st *StackTrie) setDb(db ethdb.KeyValueWriter) {
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st.db = db
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for _, child := range st.children {
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if child != nil {
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child.setDb(db)
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}
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}
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}
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func newLeaf(key, val []byte, db ethdb.KeyValueWriter) *StackTrie {
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st := stackTrieFromPool(db)
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st.nodeType = leafNode
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st.key = append(st.key, key...)
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st.val = val
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return st
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}
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func newExt(key []byte, child *StackTrie, db ethdb.KeyValueWriter) *StackTrie {
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st := stackTrieFromPool(db)
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st.nodeType = extNode
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st.key = append(st.key, key...)
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st.children[0] = child
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return st
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}
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// List all values that StackTrie#nodeType can hold
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const (
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emptyNode = iota
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branchNode
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extNode
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leafNode
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hashedNode
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)
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// TryUpdate inserts a (key, value) pair into the stack trie
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func (st *StackTrie) TryUpdate(key, value []byte) error {
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k := keybytesToHex(key)
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if len(value) == 0 {
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panic("deletion not supported")
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}
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st.insert(k[:len(k)-1], value)
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return nil
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}
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func (st *StackTrie) Update(key, value []byte) {
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if err := st.TryUpdate(key, value); err != nil {
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log.Error(fmt.Sprintf("Unhandled trie error: %v", err))
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}
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}
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func (st *StackTrie) Reset() {
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st.db = nil
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st.key = st.key[:0]
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st.val = nil
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for i := range st.children {
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st.children[i] = nil
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}
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st.nodeType = emptyNode
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}
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// Helper function that, given a full key, determines the index
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// at which the chunk pointed by st.keyOffset is different from
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// the same chunk in the full key.
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func (st *StackTrie) getDiffIndex(key []byte) int {
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for idx, nibble := range st.key {
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if nibble != key[idx] {
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return idx
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}
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}
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return len(st.key)
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}
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// Helper function to that inserts a (key, value) pair into
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// the trie.
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func (st *StackTrie) insert(key, value []byte) {
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switch st.nodeType {
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case branchNode: /* Branch */
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idx := int(key[0])
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// Unresolve elder siblings
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for i := idx - 1; i >= 0; i-- {
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if st.children[i] != nil {
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if st.children[i].nodeType != hashedNode {
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st.children[i].hash()
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}
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break
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}
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}
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// Add new child
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if st.children[idx] == nil {
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st.children[idx] = newLeaf(key[1:], value, st.db)
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} else {
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st.children[idx].insert(key[1:], value)
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}
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case extNode: /* Ext */
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// Compare both key chunks and see where they differ
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diffidx := st.getDiffIndex(key)
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// Check if chunks are identical. If so, recurse into
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// the child node. Otherwise, the key has to be split
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// into 1) an optional common prefix, 2) the fullnode
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// representing the two differing path, and 3) a leaf
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// for each of the differentiated subtrees.
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if diffidx == len(st.key) {
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// Ext key and key segment are identical, recurse into
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// the child node.
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st.children[0].insert(key[diffidx:], value)
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return
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}
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// Save the original part. Depending if the break is
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// at the extension's last byte or not, create an
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// intermediate extension or use the extension's child
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// node directly.
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var n *StackTrie
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if diffidx < len(st.key)-1 {
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n = newExt(st.key[diffidx+1:], st.children[0], st.db)
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} else {
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// Break on the last byte, no need to insert
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// an extension node: reuse the current node
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n = st.children[0]
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}
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// Convert to hash
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n.hash()
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var p *StackTrie
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if diffidx == 0 {
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// the break is on the first byte, so
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// the current node is converted into
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// a branch node.
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st.children[0] = nil
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p = st
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st.nodeType = branchNode
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} else {
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// the common prefix is at least one byte
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// long, insert a new intermediate branch
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// node.
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st.children[0] = stackTrieFromPool(st.db)
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st.children[0].nodeType = branchNode
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p = st.children[0]
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}
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// Create a leaf for the inserted part
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o := newLeaf(key[diffidx+1:], value, st.db)
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// Insert both child leaves where they belong:
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origIdx := st.key[diffidx]
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newIdx := key[diffidx]
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p.children[origIdx] = n
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p.children[newIdx] = o
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st.key = st.key[:diffidx]
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case leafNode: /* Leaf */
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// Compare both key chunks and see where they differ
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diffidx := st.getDiffIndex(key)
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// Overwriting a key isn't supported, which means that
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// the current leaf is expected to be split into 1) an
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// optional extension for the common prefix of these 2
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// keys, 2) a fullnode selecting the path on which the
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// keys differ, and 3) one leaf for the differentiated
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// component of each key.
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if diffidx >= len(st.key) {
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panic("Trying to insert into existing key")
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}
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// Check if the split occurs at the first nibble of the
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// chunk. In that case, no prefix extnode is necessary.
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// Otherwise, create that
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var p *StackTrie
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if diffidx == 0 {
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// Convert current leaf into a branch
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st.nodeType = branchNode
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p = st
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st.children[0] = nil
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} else {
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// Convert current node into an ext,
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// and insert a child branch node.
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st.nodeType = extNode
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st.children[0] = NewStackTrie(st.db)
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st.children[0].nodeType = branchNode
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p = st.children[0]
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}
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// Create the two child leaves: one containing the original
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// value and another containing the new value. The child leaf
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// is hashed directly in order to free up some memory.
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origIdx := st.key[diffidx]
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p.children[origIdx] = newLeaf(st.key[diffidx+1:], st.val, st.db)
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p.children[origIdx].hash()
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newIdx := key[diffidx]
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p.children[newIdx] = newLeaf(key[diffidx+1:], value, st.db)
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// Finally, cut off the key part that has been passed
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// over to the children.
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st.key = st.key[:diffidx]
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st.val = nil
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case emptyNode: /* Empty */
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st.nodeType = leafNode
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st.key = key
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st.val = value
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case hashedNode:
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panic("trying to insert into hash")
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default:
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panic("invalid type")
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}
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}
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// hash converts st into a 'hashedNode', if possible. Possible outcomes:
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//
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// 1. The rlp-encoded value was >= 32 bytes:
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// - Then the 32-byte `hash` will be accessible in `st.val`.
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// - And the 'st.type' will be 'hashedNode'
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// 2. The rlp-encoded value was < 32 bytes
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// - Then the <32 byte rlp-encoded value will be accessible in 'st.val'.
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// - And the 'st.type' will be 'hashedNode' AGAIN
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//
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// This method also sets 'st.type' to hashedNode, and clears 'st.key'.
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func (st *StackTrie) hash() {
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h := newHasher(false)
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defer returnHasherToPool(h)
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st.hashRec(h)
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}
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func (st *StackTrie) hashRec(hasher *hasher) {
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// The switch below sets this to the RLP-encoding of this node.
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var encodedNode []byte
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switch st.nodeType {
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case hashedNode:
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return
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case emptyNode:
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st.val = emptyRoot.Bytes()
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st.key = st.key[:0]
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st.nodeType = hashedNode
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return
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case branchNode:
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var nodes rawFullNode
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for i, child := range st.children {
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if child == nil {
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nodes[i] = nilValueNode
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continue
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}
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child.hashRec(hasher)
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if len(child.val) < 32 {
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nodes[i] = rawNode(child.val)
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} else {
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nodes[i] = hashNode(child.val)
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}
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// Release child back to pool.
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st.children[i] = nil
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returnToPool(child)
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}
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nodes.encode(hasher.encbuf)
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encodedNode = hasher.encodedBytes()
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case extNode:
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st.children[0].hashRec(hasher)
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sz := hexToCompactInPlace(st.key)
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n := rawShortNode{Key: st.key[:sz]}
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if len(st.children[0].val) < 32 {
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n.Val = rawNode(st.children[0].val)
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} else {
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n.Val = hashNode(st.children[0].val)
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}
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n.encode(hasher.encbuf)
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encodedNode = hasher.encodedBytes()
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// Release child back to pool.
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returnToPool(st.children[0])
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st.children[0] = nil
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case leafNode:
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st.key = append(st.key, byte(16))
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sz := hexToCompactInPlace(st.key)
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n := rawShortNode{Key: st.key[:sz], Val: valueNode(st.val)}
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n.encode(hasher.encbuf)
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encodedNode = hasher.encodedBytes()
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default:
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panic("invalid node type")
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}
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st.nodeType = hashedNode
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st.key = st.key[:0]
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if len(encodedNode) < 32 {
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st.val = common.CopyBytes(encodedNode)
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return
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}
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// Write the hash to the 'val'. We allocate a new val here to not mutate
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// input values
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st.val = hasher.hashData(encodedNode)
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if st.db != nil {
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// TODO! Is it safe to Put the slice here?
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// Do all db implementations copy the value provided?
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st.db.Put(st.val, encodedNode)
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}
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}
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// Hash returns the hash of the current node.
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func (st *StackTrie) Hash() (h common.Hash) {
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hasher := newHasher(false)
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defer returnHasherToPool(hasher)
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st.hashRec(hasher)
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if len(st.val) == 32 {
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copy(h[:], st.val)
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return h
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}
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// If the node's RLP isn't 32 bytes long, the node will not
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// be hashed, and instead contain the rlp-encoding of the
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// node. For the top level node, we need to force the hashing.
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hasher.sha.Reset()
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hasher.sha.Write(st.val)
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hasher.sha.Read(h[:])
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return h
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}
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// Commit will firstly hash the entrie trie if it's still not hashed
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// and then commit all nodes to the associated database. Actually most
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// of the trie nodes MAY have been committed already. The main purpose
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// here is to commit the root node.
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//
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// The associated database is expected, otherwise the whole commit
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// functionality should be disabled.
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func (st *StackTrie) Commit() (h common.Hash, err error) {
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if st.db == nil {
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return common.Hash{}, ErrCommitDisabled
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}
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hasher := newHasher(false)
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defer returnHasherToPool(hasher)
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st.hashRec(hasher)
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if len(st.val) == 32 {
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copy(h[:], st.val)
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return h, nil
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}
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// If the node's RLP isn't 32 bytes long, the node will not
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// be hashed (and committed), and instead contain the rlp-encoding of the
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// node. For the top level node, we need to force the hashing+commit.
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hasher.sha.Reset()
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hasher.sha.Write(st.val)
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hasher.sha.Read(h[:])
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st.db.Put(h[:], st.val)
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return h, nil
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}
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