go-ethereum/core/forkid/forkid.go
Felföldi Zsolt b4a2681120
les, les/lespay: implement new server pool (#20758)
This PR reimplements the light client server pool. It is also a first step
to move certain logic into a new lespay package. This package will contain
the implementation of the lespay token sale functions, the token buying and
selling logic and other components related to peer selection/prioritization
and service quality evaluation. Over the long term this package will be
reusable for incentivizing future protocols.

Since the LES peer logic is now based on enode.Iterator, it can now use
DNS-based fallback discovery to find servers.

This document describes the function of the new components:
https://gist.github.com/zsfelfoldi/3c7ace895234b7b345ab4f71dab102d4
2020-05-22 13:46:34 +02:00

259 lines
9.3 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 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 forkid implements EIP-2124 (https://eips.ethereum.org/EIPS/eip-2124).
package forkid
import (
"encoding/binary"
"errors"
"hash/crc32"
"math"
"math/big"
"reflect"
"strings"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/log"
"github.com/ethereum/go-ethereum/params"
)
var (
// ErrRemoteStale is returned by the validator if a remote fork checksum is a
// subset of our already applied forks, but the announced next fork block is
// not on our already passed chain.
ErrRemoteStale = errors.New("remote needs update")
// ErrLocalIncompatibleOrStale is returned by the validator if a remote fork
// checksum does not match any local checksum variation, signalling that the
// two chains have diverged in the past at some point (possibly at genesis).
ErrLocalIncompatibleOrStale = errors.New("local incompatible or needs update")
)
// Blockchain defines all necessary method to build a forkID.
type Blockchain interface {
// Config retrieves the chain's fork configuration.
Config() *params.ChainConfig
// Genesis retrieves the chain's genesis block.
Genesis() *types.Block
// CurrentHeader retrieves the current head header of the canonical chain.
CurrentHeader() *types.Header
}
// ID is a fork identifier as defined by EIP-2124.
type ID struct {
Hash [4]byte // CRC32 checksum of the genesis block and passed fork block numbers
Next uint64 // Block number of the next upcoming fork, or 0 if no forks are known
}
// Filter is a fork id filter to validate a remotely advertised ID.
type Filter func(id ID) error
// NewID calculates the Ethereum fork ID from the chain config and head.
func NewID(chain Blockchain) ID {
return newID(
chain.Config(),
chain.Genesis().Hash(),
chain.CurrentHeader().Number.Uint64(),
)
}
// newID is the internal version of NewID, which takes extracted values as its
// arguments instead of a chain. The reason is to allow testing the IDs without
// having to simulate an entire blockchain.
func newID(config *params.ChainConfig, genesis common.Hash, head uint64) ID {
// Calculate the starting checksum from the genesis hash
hash := crc32.ChecksumIEEE(genesis[:])
// Calculate the current fork checksum and the next fork block
var next uint64
for _, fork := range gatherForks(config) {
if fork <= head {
// Fork already passed, checksum the previous hash and the fork number
hash = checksumUpdate(hash, fork)
continue
}
next = fork
break
}
return ID{Hash: checksumToBytes(hash), Next: next}
}
// NewFilter creates a filter that returns if a fork ID should be rejected or not
// based on the local chain's status.
func NewFilter(chain Blockchain) Filter {
return newFilter(
chain.Config(),
chain.Genesis().Hash(),
func() uint64 {
return chain.CurrentHeader().Number.Uint64()
},
)
}
// NewStaticFilter creates a filter at block zero.
func NewStaticFilter(config *params.ChainConfig, genesis common.Hash) Filter {
head := func() uint64 { return 0 }
return newFilter(config, genesis, head)
}
// newFilter is the internal version of NewFilter, taking closures as its arguments
// instead of a chain. The reason is to allow testing it without having to simulate
// an entire blockchain.
func newFilter(config *params.ChainConfig, genesis common.Hash, headfn func() uint64) Filter {
// Calculate the all the valid fork hash and fork next combos
var (
forks = gatherForks(config)
sums = make([][4]byte, len(forks)+1) // 0th is the genesis
)
hash := crc32.ChecksumIEEE(genesis[:])
sums[0] = checksumToBytes(hash)
for i, fork := range forks {
hash = checksumUpdate(hash, fork)
sums[i+1] = checksumToBytes(hash)
}
// Add two sentries to simplify the fork checks and don't require special
// casing the last one.
forks = append(forks, math.MaxUint64) // Last fork will never be passed
// Create a validator that will filter out incompatible chains
return func(id ID) error {
// Run the fork checksum validation ruleset:
// 1. If local and remote FORK_CSUM matches, compare local head to FORK_NEXT.
// The two nodes are in the same fork state currently. They might know
// of differing future forks, but that's not relevant until the fork
// triggers (might be postponed, nodes might be updated to match).
// 1a. A remotely announced but remotely not passed block is already passed
// locally, disconnect, since the chains are incompatible.
// 1b. No remotely announced fork; or not yet passed locally, connect.
// 2. If the remote FORK_CSUM is a subset of the local past forks and the
// remote FORK_NEXT matches with the locally following fork block number,
// connect.
// Remote node is currently syncing. It might eventually diverge from
// us, but at this current point in time we don't have enough information.
// 3. If the remote FORK_CSUM is a superset of the local past forks and can
// be completed with locally known future forks, connect.
// Local node is currently syncing. It might eventually diverge from
// the remote, but at this current point in time we don't have enough
// information.
// 4. Reject in all other cases.
head := headfn()
for i, fork := range forks {
// If our head is beyond this fork, continue to the next (we have a dummy
// fork of maxuint64 as the last item to always fail this check eventually).
if head > fork {
continue
}
// Found the first unpassed fork block, check if our current state matches
// the remote checksum (rule #1).
if sums[i] == id.Hash {
// Fork checksum matched, check if a remote future fork block already passed
// locally without the local node being aware of it (rule #1a).
if id.Next > 0 && head >= id.Next {
return ErrLocalIncompatibleOrStale
}
// Haven't passed locally a remote-only fork, accept the connection (rule #1b).
return nil
}
// The local and remote nodes are in different forks currently, check if the
// remote checksum is a subset of our local forks (rule #2).
for j := 0; j < i; j++ {
if sums[j] == id.Hash {
// Remote checksum is a subset, validate based on the announced next fork
if forks[j] != id.Next {
return ErrRemoteStale
}
return nil
}
}
// Remote chain is not a subset of our local one, check if it's a superset by
// any chance, signalling that we're simply out of sync (rule #3).
for j := i + 1; j < len(sums); j++ {
if sums[j] == id.Hash {
// Yay, remote checksum is a superset, ignore upcoming forks
return nil
}
}
// No exact, subset or superset match. We are on differing chains, reject.
return ErrLocalIncompatibleOrStale
}
log.Error("Impossible fork ID validation", "id", id)
return nil // Something's very wrong, accept rather than reject
}
}
// checksumUpdate calculates the next IEEE CRC32 checksum based on the previous
// one and a fork block number (equivalent to CRC32(original-blob || fork)).
func checksumUpdate(hash uint32, fork uint64) uint32 {
var blob [8]byte
binary.BigEndian.PutUint64(blob[:], fork)
return crc32.Update(hash, crc32.IEEETable, blob[:])
}
// checksumToBytes converts a uint32 checksum into a [4]byte array.
func checksumToBytes(hash uint32) [4]byte {
var blob [4]byte
binary.BigEndian.PutUint32(blob[:], hash)
return blob
}
// gatherForks gathers all the known forks and creates a sorted list out of them.
func gatherForks(config *params.ChainConfig) []uint64 {
// Gather all the fork block numbers via reflection
kind := reflect.TypeOf(params.ChainConfig{})
conf := reflect.ValueOf(config).Elem()
var forks []uint64
for i := 0; i < kind.NumField(); i++ {
// Fetch the next field and skip non-fork rules
field := kind.Field(i)
if !strings.HasSuffix(field.Name, "Block") {
continue
}
if field.Type != reflect.TypeOf(new(big.Int)) {
continue
}
// Extract the fork rule block number and aggregate it
rule := conf.Field(i).Interface().(*big.Int)
if rule != nil {
forks = append(forks, rule.Uint64())
}
}
// Sort the fork block numbers to permit chronologival XOR
for i := 0; i < len(forks); i++ {
for j := i + 1; j < len(forks); j++ {
if forks[i] > forks[j] {
forks[i], forks[j] = forks[j], forks[i]
}
}
}
// Deduplicate block numbers applying multiple forks
for i := 1; i < len(forks); i++ {
if forks[i] == forks[i-1] {
forks = append(forks[:i], forks[i+1:]...)
i--
}
}
// Skip any forks in block 0, that's the genesis ruleset
if len(forks) > 0 && forks[0] == 0 {
forks = forks[1:]
}
return forks
}