go-ethereum/trie/encoding.go
Guillaume Ballet 6c8310ebb4
trie: use stacktrie for Derivesha operation (#21407)
core/types: use stacktrie for derivesha

trie: add stacktrie file

trie: fix linter

core/types: use stacktrie for derivesha

rebased: adapt stacktrie to the newer version of DeriveSha

Co-authored-by: Martin Holst Swende <martin@swende.se>

More linter fixes

review feedback: no key offset for nodes converted to hashes

trie: use EncodeRLP for full nodes

core/types: insert txs in order in derivesha

trie: tests for derivesha with stacktrie

trie: make stacktrie use pooled hashers

trie: make stacktrie reuse tmp slice space

trie: minor polishes on stacktrie

trie/stacktrie: less rlp dancing

core/types: explain the contorsions in DeriveSha

ci: fix goimport errors

trie: clear mem on subtrie hashing

squashme: linter fix

stracktrie: use pooling, less allocs (#3)

trie: in-place hex prefix, reduce allocs and add rawNode.EncodeRLP

Reintroduce the `[]node` method, add the missing `EncodeRLP` implementation for `rawNode` and calculate the hex prefix in place.

Co-authored-by: Martin Holst Swende <martin@swende.se>

Co-authored-by: Martin Holst Swende <martin@swende.se>
2020-09-29 17:38:13 +02:00

146 lines
4.3 KiB
Go

// 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 <http://www.gnu.org/licenses/>.
package trie
// Trie keys are dealt with in three distinct encodings:
//
// KEYBYTES encoding contains the actual key and nothing else. This encoding is the
// input to most API functions.
//
// HEX encoding contains one byte for each nibble of the key and an optional trailing
// 'terminator' byte of value 0x10 which indicates whether or not the node at the key
// contains a value. Hex key encoding is used for nodes loaded in memory because it's
// convenient to access.
//
// COMPACT encoding is defined by the Ethereum Yellow Paper (it's called "hex prefix
// encoding" there) and contains the bytes of the key and a flag. The high nibble of the
// first byte contains the flag; the lowest bit encoding the oddness of the length and
// the second-lowest encoding whether the node at the key is a value node. The low nibble
// of the first byte is zero in the case of an even number of nibbles and the first nibble
// in the case of an odd number. All remaining nibbles (now an even number) fit properly
// into the remaining bytes. Compact encoding is used for nodes stored on disk.
func hexToCompact(hex []byte) []byte {
terminator := byte(0)
if hasTerm(hex) {
terminator = 1
hex = hex[:len(hex)-1]
}
buf := make([]byte, len(hex)/2+1)
buf[0] = terminator << 5 // the flag byte
if len(hex)&1 == 1 {
buf[0] |= 1 << 4 // odd flag
buf[0] |= hex[0] // first nibble is contained in the first byte
hex = hex[1:]
}
decodeNibbles(hex, buf[1:])
return buf
}
// hexToCompactInPlace places the compact key in input buffer, returning the length
// needed for the representation
func hexToCompactInPlace(hex []byte) int {
var (
hexLen = len(hex) // length of the hex input
firstByte = byte(0)
)
// Check if we have a terminator there
if hexLen > 0 && hex[hexLen-1] == 16 {
firstByte = 1 << 5
hexLen-- // last part was the terminator, ignore that
}
var (
binLen = hexLen/2 + 1
ni = 0 // index in hex
bi = 1 // index in bin (compact)
)
if hexLen&1 == 1 {
firstByte |= 1 << 4 // odd flag
firstByte |= hex[0] // first nibble is contained in the first byte
ni++
}
for ; ni < hexLen; bi, ni = bi+1, ni+2 {
hex[bi] = hex[ni]<<4 | hex[ni+1]
}
hex[0] = firstByte
return binLen
}
func compactToHex(compact []byte) []byte {
if len(compact) == 0 {
return compact
}
base := keybytesToHex(compact)
// delete terminator flag
if base[0] < 2 {
base = base[:len(base)-1]
}
// apply odd flag
chop := 2 - base[0]&1
return base[chop:]
}
func keybytesToHex(str []byte) []byte {
l := len(str)*2 + 1
var nibbles = make([]byte, l)
for i, b := range str {
nibbles[i*2] = b / 16
nibbles[i*2+1] = b % 16
}
nibbles[l-1] = 16
return nibbles
}
// hexToKeybytes turns hex nibbles into key bytes.
// This can only be used for keys of even length.
func hexToKeybytes(hex []byte) []byte {
if hasTerm(hex) {
hex = hex[:len(hex)-1]
}
if len(hex)&1 != 0 {
panic("can't convert hex key of odd length")
}
key := make([]byte, len(hex)/2)
decodeNibbles(hex, key)
return key
}
func decodeNibbles(nibbles []byte, bytes []byte) {
for bi, ni := 0, 0; ni < len(nibbles); bi, ni = bi+1, ni+2 {
bytes[bi] = nibbles[ni]<<4 | nibbles[ni+1]
}
}
// prefixLen returns the length of the common prefix of a and b.
func prefixLen(a, b []byte) int {
var i, length = 0, len(a)
if len(b) < length {
length = len(b)
}
for ; i < length; i++ {
if a[i] != b[i] {
break
}
}
return i
}
// hasTerm returns whether a hex key has the terminator flag.
func hasTerm(s []byte) bool {
return len(s) > 0 && s[len(s)-1] == 16
}