erigon-pulse/trie/retain_list.go
Alex Sharov ec70cd2a9c
Revert "Only useful IH cursor (#694)" (#703)
This reverts commit 63c998c91f.

# Conflicts:
#	cmd/hack/hack.go
#	eth/stagedsync/stage_interhashes.go
2020-07-02 17:55:35 +07:00

252 lines
7.3 KiB
Go

// Copyright 2019 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty off
// 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 <http://www.gnu.org/licenses/>.
package trie
import (
"bytes"
"fmt"
"sort"
"github.com/ledgerwatch/turbo-geth/common"
)
type RetainDecider interface {
Retain([]byte) bool
IsCodeTouched(common.Hash) bool
}
// RetainList encapsulates the list of keys that are required to be fully available, or loaded
// (by using `BRANCH` opcode instead of `HASHER`) after processing of the sequence of key-value
// pairs
// DESCRIBED: docs/programmers_guide/guide.md#converting-sequence-of-keys-and-value-into-a-multiproof
type RetainList struct {
inited bool // Whether keys are sorted and "LTE" and "GT" indices set
binary bool // if true, use binary encoding instead of Hex
minLength int // Mininum length of prefixes for which `HashOnly` function can return `true`
lteIndex int // Index of the "LTE" key in the keys slice. Next one is "GT"
hexes sortable
codeTouches map[common.Hash]struct{}
}
// NewRetainList creates new RetainList
func NewRetainList(minLength int) *RetainList {
return &RetainList{minLength: minLength, codeTouches: make(map[common.Hash]struct{})}
}
func NewBinaryRetainList(minLength int) *RetainList {
return &RetainList{minLength: minLength, codeTouches: make(map[common.Hash]struct{}), binary: true}
}
// AddKey adds a new key (in KEY encoding) to the list
func (rl *RetainList) AddKey(key []byte) {
var nibbles = make([]byte, 2*len(key))
for i, b := range key {
nibbles[i*2] = b / 16
nibbles[i*2+1] = b % 16
}
rl.AddHex(nibbles)
}
// AddHex adds a new key (in HEX encoding) to the list
func (rl *RetainList) AddHex(hex []byte) {
if rl.binary {
rl.hexes = append(rl.hexes, keyHexToBin(hex))
} else {
rl.hexes = append(rl.hexes, hex)
}
}
// AddCodeTouch adds a new code touch into the resolve set
func (rl *RetainList) AddCodeTouch(codeHash common.Hash) {
rl.codeTouches[codeHash] = struct{}{}
}
func (rl *RetainList) IsCodeTouched(codeHash common.Hash) bool {
_, ok := rl.codeTouches[codeHash]
return ok
}
func (rl *RetainList) ensureInited() {
if rl.inited {
return
}
if !sort.IsSorted(rl.hexes) {
sort.Sort(rl.hexes)
}
rl.lteIndex = 0
rl.inited = true
}
// Retain decides whether to emit `HASHER` or `BRANCH` for a given prefix, by
// checking if this is prefix of any of the keys added to the set
// Since keys in the set are sorted, and we expect that the prefixes will
// come in monotonically ascending order, we optimise for this, though
// the function would still work if the order is different
func (rl *RetainList) Retain(prefix []byte) bool {
rl.ensureInited()
if len(prefix) < rl.minLength {
return true
}
// Adjust "GT" if necessary
var gtAdjusted bool
for rl.lteIndex < len(rl.hexes)-1 && bytes.Compare(rl.hexes[rl.lteIndex+1], prefix) <= 0 {
rl.lteIndex++
gtAdjusted = true
}
// Adjust "LTE" if necessary (normally will not be necessary)
for !gtAdjusted && rl.lteIndex > 0 && bytes.Compare(rl.hexes[rl.lteIndex], prefix) > 0 {
rl.lteIndex--
}
if rl.lteIndex < len(rl.hexes) {
if bytes.HasPrefix(rl.hexes[rl.lteIndex], prefix) {
return true
}
}
if rl.lteIndex < len(rl.hexes)-1 {
if bytes.HasPrefix(rl.hexes[rl.lteIndex+1], prefix) {
return true
}
}
return false
}
// Rewind lets us reuse this list from the beginning
func (rl *RetainList) Rewind() {
rl.lteIndex = 0
}
func (rl *RetainList) String() string {
return fmt.Sprintf("%x", rl.hexes)
}
// RetainRange encapsulates the range of keys that are required to be fully available, or loaded
// (by using `BRANCH` opcode instead of `HASHER`) after processing of the sequence of key-value
// pairs
// DESCRIBED: docs/programmers_guide/guide.md#converting-sequence-of-keys-and-value-into-a-multiproof
type RetainRange struct {
from []byte
to []byte
codeTouches map[common.Hash]struct{}
}
// NewRetainRange creates new NewRetainRange
// to=nil - means no upper bound
func NewRetainRange(from, to []byte) *RetainRange {
return &RetainRange{from: from, to: to, codeTouches: make(map[common.Hash]struct{})}
}
// Retain decides whether to emit `HASHER` or `BRANCH` for a given prefix, by
// checking if this is prefix of any of the keys added to the set
// it returns True:
// - for keys between from and to
// - for keys which are prefixes of from and to
// - for keys which are contains from and to as a prefix
func (rr *RetainRange) Retain(prefix []byte) (retain bool) {
if bytes.HasPrefix(rr.from, prefix) || bytes.HasPrefix(prefix, rr.from) {
return true
}
if bytes.HasPrefix(rr.to, prefix) || bytes.HasPrefix(prefix, rr.to) {
return true
}
from := bytes.Compare(prefix, rr.from)
to := -1
if rr.to != nil {
to = bytes.Compare(prefix, rr.to)
}
return from >= 0 && to <= 0
}
// AddCodeTouch adds a new code touch into the resolve set
func (rr *RetainRange) AddCodeTouch(codeHash common.Hash) {
rr.codeTouches[codeHash] = struct{}{}
}
func (rr *RetainRange) IsCodeTouched(codeHash common.Hash) bool {
_, ok := rr.codeTouches[codeHash]
return ok
}
func (rr *RetainRange) String() string {
return fmt.Sprintf("%x-%x", rr.from, rr.to)
}
// RetainAll - returns true to any prefix
type RetainAll struct {
codeTouches map[common.Hash]struct{}
decider RetainDecider
}
// NewRetainAll creates new NewRetainRange
// to=nil - means no upper bound
func NewRetainAll(decider RetainDecider) *RetainAll {
return &RetainAll{decider: decider, codeTouches: make(map[common.Hash]struct{})}
}
func (rr *RetainAll) Retain(prefix []byte) (retain bool) {
return true
}
// AddCodeTouch adds a new code touch into the resolve set
func (rr *RetainAll) AddCodeTouch(codeHash common.Hash) {
rr.codeTouches[codeHash] = struct{}{}
}
func (rr *RetainAll) IsCodeTouched(codeHash common.Hash) bool {
_, ok := rr.codeTouches[codeHash]
return ok
}
func (rr *RetainAll) String() string {
return ""
}
// RetainLevels - returns true to any prefix shorter than `levels`
type RetainLevels struct {
codeTouches map[common.Hash]struct{}
decider RetainDecider
levels int
}
// NewRetainLevels creates new NewRetainRange
// to=nil - means no upper bound
func NewRetainLevels(decider RetainDecider, levels int) *RetainLevels {
return &RetainLevels{decider: decider, codeTouches: make(map[common.Hash]struct{}), levels: levels}
}
func (rr *RetainLevels) Retain(prefix []byte) (retain bool) {
if len(prefix) > rr.levels {
return rr.decider.Retain(prefix)
}
return true
}
// AddCodeTouch adds a new code touch into the resolve set
func (rr *RetainLevels) AddCodeTouch(codeHash common.Hash) {
rr.codeTouches[codeHash] = struct{}{}
}
func (rr *RetainLevels) IsCodeTouched(codeHash common.Hash) bool {
_, ok := rr.codeTouches[codeHash]
return ok
}
func (rr *RetainLevels) String() string {
return ""
}