mirror of
https://gitlab.com/pulsechaincom/erigon-pulse.git
synced 2024-12-25 13:07:17 +00:00
73bb98f686
* Move tests 6 * Compile fixes * Fix lint * Compile fixes * Fix compile * compile fixes * Compile fix * Fix consesus/clique * Cleanup * Add gas limit * Print * Prints * More print * Fix * Reinstate TestGetBlockReceipts66 Co-authored-by: Alex Sharp <alexsharp@Alexs-MacBook-Pro.local> Co-authored-by: Alexey Sharp <alexeysharp@Alexeys-iMac.local>
434 lines
15 KiB
Go
434 lines
15 KiB
Go
// Copyright 2019 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 off
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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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"fmt"
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"github.com/holiman/uint256"
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"github.com/ledgerwatch/erigon/common"
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"github.com/ledgerwatch/erigon/turbo/rlphacks"
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)
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// Experimental code for separating data and structural information
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// Each function corresponds to an opcode
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// DESCRIBED: docs/programmers_guide/guide.md#separation-of-keys-and-the-structure
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type structInfoReceiver interface {
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leaf(length int, keyHex []byte, val rlphacks.RlpSerializable) error
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leafHash(length int, keyHex []byte, val rlphacks.RlpSerializable) error
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accountLeaf(length int, keyHex []byte, balance *uint256.Int, nonce uint64, incarnation uint64, fieldset uint32, codeSize int) error
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accountLeafHash(length int, keyHex []byte, balance *uint256.Int, nonce uint64, incarnation uint64, fieldset uint32) error
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extension(key []byte) error
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extensionHash(key []byte) error
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branch(set uint16) error
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branchHash(set uint16) error
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hash(hash []byte) error
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topHash() []byte
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topHashes(prefix []byte, branches, children uint16) []byte
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printTopHashes(prefix []byte, branches, children uint16)
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}
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// hashCollector gets called whenever there might be a need to create intermediate hash record
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type HashCollector func(keyHex []byte, hash []byte) error
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type StorageHashCollector func(accWithInc []byte, keyHex []byte, hash []byte) error
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type HashCollector2 func(keyHex []byte, hasState, hasTree, hasHash uint16, hashes, rootHash []byte) error
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type StorageHashCollector2 func(accWithInc []byte, keyHex []byte, hasState, hasTree, hasHash uint16, hashes, rootHash []byte) error
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func calcPrecLen(groups []uint16) int {
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if len(groups) == 0 {
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return 0
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}
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return len(groups) - 1
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}
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type GenStructStepData interface {
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GenStructStepData()
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}
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type GenStructStepAccountData struct {
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FieldSet uint32
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Balance uint256.Int
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Nonce uint64
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Incarnation uint64
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}
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func (GenStructStepAccountData) GenStructStepData() {}
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type GenStructStepLeafData struct {
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Value rlphacks.RlpSerializable
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}
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func (GenStructStepLeafData) GenStructStepData() {}
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type GenStructStepHashData struct {
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Hash common.Hash
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HasTree bool
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}
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func (GenStructStepHashData) GenStructStepData() {}
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// GenStructStep is one step of the algorithm that generates the structural information based on the sequence of keys.
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// `retain` parameter is the function that, called for a certain prefix, determines whether the trie node for that prefix needs to be
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// compressed into just hash (if `false` is returned), or constructed (if `true` is returned). Usually the `retain` function is
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// implemented in such a way to guarantee that certain keys are always accessible in the resulting trie (see RetainList.Retain function).
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// `buildExtensions` is set to true if the algorithm's step is invoked recursively, i.e. not after a freshly provided leaf or hash
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// `curr`, `succ` are two full keys or prefixes that are currently visible to the algorithm. By comparing these, the algorithm
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// makes decisions about the local structure, i.e. the presence of the prefix groups.
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// `e` parameter is the trie builder, which uses the structure information to assemble trie on the stack and compute its hash.
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// `h` parameter is the hash collector, which is notified whenever branch node is constructed.
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// `data` parameter specified if a hash or a binary string or an account should be emitted.
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// `groups` parameter is the map of the stack. each element of the `groups` slice is a bitmask, one bit per element currently on the stack. Meaning - which children of given prefix have dbutils.HashedAccount records
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// `hasTree` same as `groups`, but meaning - which children of given prefix have dbutils.TrieOfAccountsBucket record
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// `hasHash` same as `groups`, but meaning - which children of given prefix are branch nodes and their hashes can be saved and used on next trie resolution.
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// Whenever a `BRANCH` or `BRANCHHASH` opcode is emitted, the set of digits is taken from the corresponding `groups` item, which is
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// then removed from the slice. This signifies the usage of the number of the stack items by the `BRANCH` or `BRANCHHASH` opcode.
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// DESCRIBED: docs/programmers_guide/guide.md#separation-of-keys-and-the-structure
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func GenStructStep(
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retain func(prefix []byte) bool,
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curr, succ []byte,
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e structInfoReceiver,
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h HashCollector2,
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data GenStructStepData,
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groups []uint16,
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hasTree []uint16,
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hasHash []uint16,
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trace bool,
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) ([]uint16, []uint16, []uint16, error) {
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for precLen, buildExtensions := calcPrecLen(groups), false; precLen >= 0; precLen, buildExtensions = calcPrecLen(groups), true {
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var precExists = len(groups) > 0
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// Calculate the prefix of the smallest prefix group containing curr
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var precLen int
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if len(groups) > 0 {
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precLen = len(groups) - 1
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}
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succLen := prefixLen(succ, curr)
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var maxLen int
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if precLen > succLen {
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maxLen = precLen
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} else {
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maxLen = succLen
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}
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if trace || maxLen >= len(curr) {
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fmt.Printf("curr: %x, succ: %x, maxLen %d, groups: %b, precLen: %d, succLen: %d, buildExtensions: %t\n", curr, succ, maxLen, groups, precLen, succLen, buildExtensions)
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}
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// Add the digit immediately following the max common prefix and compute length of remainder length
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extraDigit := curr[maxLen]
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for maxLen >= len(groups) {
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groups = append(groups, 0)
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}
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groups[maxLen] |= 1 << extraDigit
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remainderStart := maxLen
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if len(succ) > 0 || precExists {
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remainderStart++
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}
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remainderLen := len(curr) - remainderStart
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for remainderStart+remainderLen >= len(hasTree) {
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hasTree = append(hasTree, 0)
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hasHash = append(hasHash, 0)
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}
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//fmt.Printf("groups is now %x,%d,%b\n", extraDigit, maxLen, groups)
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if !buildExtensions {
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switch v := data.(type) {
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case *GenStructStepHashData:
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if trace {
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fmt.Printf("HashData before: %x, %t,%b,%b,%b\n", curr, v.HasTree, hasHash, hasTree, groups)
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}
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if v.HasTree {
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hasTree[len(curr)-1] |= 1 << curr[len(curr)-1] // keep track of existing records in DB
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}
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hasHash[len(curr)-1] |= 1 << curr[len(curr)-1] // register myself in parent bitmap
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if trace {
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fmt.Printf("HashData: %x, %t,%b,%b,%b\n", curr, v.HasTree, hasHash, hasTree, groups)
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}
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/* building a hash */
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if err := e.hash(v.Hash[:]); err != nil {
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return nil, nil, nil, err
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}
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buildExtensions = true
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case *GenStructStepAccountData:
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if retain(curr[:maxLen]) {
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if err := e.accountLeaf(remainderLen, curr, &v.Balance, v.Nonce, v.Incarnation, v.FieldSet, codeSizeUncached); err != nil {
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return nil, nil, nil, err
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}
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} else {
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if err := e.accountLeafHash(remainderLen, curr, &v.Balance, v.Nonce, v.Incarnation, v.FieldSet); err != nil {
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return nil, nil, nil, err
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}
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}
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case *GenStructStepLeafData:
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/* building leafs */
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if retain(curr[:maxLen]) {
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if err := e.leaf(remainderLen, curr, v.Value); err != nil {
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return nil, nil, nil, err
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}
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} else {
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if err := e.leafHash(remainderLen, curr, v.Value); err != nil {
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return nil, nil, nil, err
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}
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}
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default:
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panic(fmt.Errorf("unknown data type: %T", data))
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}
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}
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if buildExtensions {
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if remainderLen > 0 {
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if trace {
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fmt.Printf("Extension before: %x->%x,%b, %b, %b\n", curr[:remainderStart], curr[remainderStart:remainderStart+remainderLen], hasHash, hasTree, groups)
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}
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// can't use hash of extension node
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// but must propagate hasBranch bits to keep tracking all existing DB records
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// groups bit also require propagation, but it's done automatically
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from := remainderStart
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if from == 0 {
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from = 1
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}
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hasHash[from-1] &^= 1 << curr[from-1]
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for i := from; i < remainderStart+remainderLen; i++ {
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if 1<<curr[i]&hasTree[i] != 0 {
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hasTree[from-1] |= 1 << curr[from-1]
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}
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if h != nil {
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if err := h(curr[:i], 0, 0, 0, nil, nil); err != nil {
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return nil, nil, nil, err
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}
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}
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}
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hasTree = hasTree[:from]
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hasHash = hasHash[:from]
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if trace {
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fmt.Printf("Extension: %x, %b, %b, %b\n", curr[remainderStart:remainderStart+remainderLen], hasHash, hasTree, groups)
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}
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/* building extensions */
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if retain(curr[:maxLen]) {
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if err := e.extension(curr[remainderStart : remainderStart+remainderLen]); err != nil {
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return nil, nil, nil, err
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}
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} else {
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if err := e.extensionHash(curr[remainderStart : remainderStart+remainderLen]); err != nil {
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return nil, nil, nil, err
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}
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}
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}
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}
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// Check for the optional part
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if precLen <= succLen && len(succ) > 0 {
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return groups, hasTree, hasHash, nil
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}
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var usefulHashes []byte
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if h != nil && (hasHash[maxLen] != 0 || hasTree[maxLen] != 0) { // top level must be in db
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if trace {
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fmt.Printf("why now: %x,%b,%b,%b\n", curr[:maxLen], hasHash, hasTree, groups)
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}
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usefulHashes = e.topHashes(curr[:maxLen], hasHash[maxLen], groups[maxLen])
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if maxLen != 0 {
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hasTree[maxLen-1] |= 1 << curr[maxLen-1] // register myself in parent bitmap
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}
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if maxLen > 1 {
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if err := h(curr[:maxLen], groups[maxLen], hasTree[maxLen], hasHash[maxLen], usefulHashes, nil); err != nil {
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return nil, nil, nil, err
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}
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}
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}
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// Close the immediately encompassing prefix group, if needed
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if len(succ) > 0 || precExists {
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if maxLen > 0 {
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if trace {
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fmt.Printf("Branch before: %x, %b, %b, %b\n", curr[:maxLen], hasHash, hasTree, groups)
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}
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hasHash[maxLen-1] |= 1 << curr[maxLen-1]
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if hasTree[maxLen] != 0 {
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hasTree[maxLen-1] |= 1 << curr[maxLen-1]
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}
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if trace {
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fmt.Printf("Branch: %x, %b, %b, %b\n", curr[:maxLen], hasHash, hasTree, groups)
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}
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}
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if trace {
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e.printTopHashes(curr[:maxLen], 0, groups[maxLen])
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}
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if retain(curr[:maxLen]) {
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if err := e.branch(groups[maxLen]); err != nil {
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return nil, nil, nil, err
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}
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} else {
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if err := e.branchHash(groups[maxLen]); err != nil {
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return nil, nil, nil, err
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}
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}
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}
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if h != nil {
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send := maxLen == 0 && (hasTree[maxLen] != 0 || hasHash[maxLen] != 0) // account.root - store only if have useful info
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send = send || (maxLen == 1 && groups[maxLen] != 0) // first level of trie_account - store in any case
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if send {
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if err := h(curr[:maxLen], groups[maxLen], hasTree[maxLen], hasHash[maxLen], usefulHashes, e.topHash()); err != nil {
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return nil, nil, nil, err
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}
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}
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}
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groups = groups[:maxLen]
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hasTree = hasTree[:maxLen]
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hasHash = hasHash[:maxLen]
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// Check the end of recursion
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if precLen == 0 {
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return groups, hasTree, hasHash, nil
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}
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// Identify preceding key for the buildExtensions invocation
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curr = curr[:precLen]
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for len(groups) > 0 && groups[len(groups)-1] == 0 {
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groups = groups[:len(groups)-1]
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}
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}
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return nil, nil, nil, nil
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}
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func GenStructStepOld(
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retain func(prefix []byte) bool,
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curr, succ []byte,
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e structInfoReceiver,
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h HashCollector,
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data GenStructStepData,
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groups []uint16,
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trace bool,
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) ([]uint16, error) {
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for precLen, buildExtensions := calcPrecLen(groups), false; precLen >= 0; precLen, buildExtensions = calcPrecLen(groups), true {
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var precExists = len(groups) > 0
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// Calculate the prefix of the smallest prefix group containing curr
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var precLen int
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if len(groups) > 0 {
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precLen = len(groups) - 1
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}
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succLen := prefixLen(succ, curr)
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var maxLen int
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if precLen > succLen {
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maxLen = precLen
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} else {
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maxLen = succLen
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}
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if trace || maxLen >= len(curr) {
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fmt.Printf("curr: %x, succ: %x, maxLen %d, groups: %b, precLen: %d, succLen: %d, buildExtensions: %t\n", curr, succ, maxLen, groups, precLen, succLen, buildExtensions)
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}
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// Add the digit immediately following the max common prefix and compute length of remainder length
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extraDigit := curr[maxLen]
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for maxLen >= len(groups) {
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groups = append(groups, 0)
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}
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groups[maxLen] |= 1 << extraDigit
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//fmt.Printf("groups is now %b\n", groups)
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remainderStart := maxLen
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if len(succ) > 0 || precExists {
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remainderStart++
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}
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remainderLen := len(curr) - remainderStart
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if !buildExtensions {
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switch v := data.(type) {
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case *GenStructStepHashData:
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/* building a hash */
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if err := e.hash(v.Hash[:]); err != nil {
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return nil, err
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}
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buildExtensions = true
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case *GenStructStepAccountData:
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if retain(curr[:maxLen]) {
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if err := e.accountLeaf(remainderLen, curr, &v.Balance, v.Nonce, v.Incarnation, v.FieldSet, codeSizeUncached); err != nil {
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return nil, err
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}
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} else {
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if err := e.accountLeafHash(remainderLen, curr, &v.Balance, v.Nonce, v.Incarnation, v.FieldSet); err != nil {
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return nil, err
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}
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}
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case *GenStructStepLeafData:
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/* building leafs */
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if retain(curr[:maxLen]) {
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if err := e.leaf(remainderLen, curr, v.Value); err != nil {
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return nil, err
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}
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} else {
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if err := e.leafHash(remainderLen, curr, v.Value); err != nil {
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return nil, err
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}
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}
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default:
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panic(fmt.Errorf("unknown data type: %T", data))
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}
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}
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if buildExtensions {
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if remainderLen > 0 {
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if trace {
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fmt.Printf("Extension %x\n", curr[remainderStart:remainderStart+remainderLen])
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}
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/* building extensions */
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if retain(curr[:maxLen]) {
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if err := e.extension(curr[remainderStart : remainderStart+remainderLen]); err != nil {
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return nil, err
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}
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} else {
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if err := e.extensionHash(curr[remainderStart : remainderStart+remainderLen]); err != nil {
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return nil, err
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}
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}
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}
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}
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// Check for the optional part
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if precLen <= succLen && len(succ) > 0 {
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return groups, nil
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}
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// Close the immediately encompassing prefix group, if needed
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if len(succ) > 0 || precExists {
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if retain(curr[:maxLen]) {
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if err := e.branch(groups[maxLen]); err != nil {
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return nil, err
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}
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} else {
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if err := e.branchHash(groups[maxLen]); err != nil {
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return nil, err
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}
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}
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if h != nil {
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if err := h(curr[:maxLen], e.topHash()); err != nil {
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return nil, err
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}
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}
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}
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groups = groups[:maxLen]
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// Check the end of recursion
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if precLen == 0 {
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return groups, nil
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}
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// Identify preceding key for the buildExtensions invocation
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curr = curr[:precLen]
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for len(groups) > 0 && groups[len(groups)-1] == 0 {
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groups = groups[:len(groups)-1]
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}
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}
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return nil, nil
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}
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