plugeth/les/odr_requests.go
gary rong 034ecc3210
les: remove useless protocol defines (#22115)
This PR has two changes in the les protocol:

- the auxRoot is not supported. See ethereum/devp2p#171 for more information
- the empty response will be returned in GetHelperTrieProofsMsg request if the merkle
   proving is failed. note, for backward compatibility, the empty merkle proof as well as
   the request auxiliary data will still be returned in  les2/3 protocol no matter the proving
   is successful or not. the proving failure can happen e.g. request the proving for a
   non-included entry in helper trie (unstable header).
2021-01-16 19:06:18 +01:00

538 lines
17 KiB
Go

// Copyright 2016 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 les
import (
"encoding/binary"
"errors"
"fmt"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core/rawdb"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/ethdb"
"github.com/ethereum/go-ethereum/light"
"github.com/ethereum/go-ethereum/log"
"github.com/ethereum/go-ethereum/rlp"
"github.com/ethereum/go-ethereum/trie"
)
var (
errInvalidMessageType = errors.New("invalid message type")
errInvalidEntryCount = errors.New("invalid number of response entries")
errHeaderUnavailable = errors.New("header unavailable")
errTxHashMismatch = errors.New("transaction hash mismatch")
errUncleHashMismatch = errors.New("uncle hash mismatch")
errReceiptHashMismatch = errors.New("receipt hash mismatch")
errDataHashMismatch = errors.New("data hash mismatch")
errCHTHashMismatch = errors.New("cht hash mismatch")
errCHTNumberMismatch = errors.New("cht number mismatch")
errUselessNodes = errors.New("useless nodes in merkle proof nodeset")
)
type LesOdrRequest interface {
GetCost(*serverPeer) uint64
CanSend(*serverPeer) bool
Request(uint64, *serverPeer) error
Validate(ethdb.Database, *Msg) error
}
func LesRequest(req light.OdrRequest) LesOdrRequest {
switch r := req.(type) {
case *light.BlockRequest:
return (*BlockRequest)(r)
case *light.ReceiptsRequest:
return (*ReceiptsRequest)(r)
case *light.TrieRequest:
return (*TrieRequest)(r)
case *light.CodeRequest:
return (*CodeRequest)(r)
case *light.ChtRequest:
return (*ChtRequest)(r)
case *light.BloomRequest:
return (*BloomRequest)(r)
case *light.TxStatusRequest:
return (*TxStatusRequest)(r)
default:
return nil
}
}
// BlockRequest is the ODR request type for block bodies
type BlockRequest light.BlockRequest
// GetCost returns the cost of the given ODR request according to the serving
// peer's cost table (implementation of LesOdrRequest)
func (r *BlockRequest) GetCost(peer *serverPeer) uint64 {
return peer.getRequestCost(GetBlockBodiesMsg, 1)
}
// CanSend tells if a certain peer is suitable for serving the given request
func (r *BlockRequest) CanSend(peer *serverPeer) bool {
return peer.HasBlock(r.Hash, r.Number, false)
}
// Request sends an ODR request to the LES network (implementation of LesOdrRequest)
func (r *BlockRequest) Request(reqID uint64, peer *serverPeer) error {
peer.Log().Debug("Requesting block body", "hash", r.Hash)
return peer.requestBodies(reqID, []common.Hash{r.Hash})
}
// Valid processes an ODR request reply message from the LES network
// returns true and stores results in memory if the message was a valid reply
// to the request (implementation of LesOdrRequest)
func (r *BlockRequest) Validate(db ethdb.Database, msg *Msg) error {
log.Debug("Validating block body", "hash", r.Hash)
// Ensure we have a correct message with a single block body
if msg.MsgType != MsgBlockBodies {
return errInvalidMessageType
}
bodies := msg.Obj.([]*types.Body)
if len(bodies) != 1 {
return errInvalidEntryCount
}
body := bodies[0]
// Retrieve our stored header and validate block content against it
if r.Header == nil {
r.Header = rawdb.ReadHeader(db, r.Hash, r.Number)
}
if r.Header == nil {
return errHeaderUnavailable
}
if r.Header.TxHash != types.DeriveSha(types.Transactions(body.Transactions), new(trie.Trie)) {
return errTxHashMismatch
}
if r.Header.UncleHash != types.CalcUncleHash(body.Uncles) {
return errUncleHashMismatch
}
// Validations passed, encode and store RLP
data, err := rlp.EncodeToBytes(body)
if err != nil {
return err
}
r.Rlp = data
return nil
}
// ReceiptsRequest is the ODR request type for block receipts by block hash
type ReceiptsRequest light.ReceiptsRequest
// GetCost returns the cost of the given ODR request according to the serving
// peer's cost table (implementation of LesOdrRequest)
func (r *ReceiptsRequest) GetCost(peer *serverPeer) uint64 {
return peer.getRequestCost(GetReceiptsMsg, 1)
}
// CanSend tells if a certain peer is suitable for serving the given request
func (r *ReceiptsRequest) CanSend(peer *serverPeer) bool {
return peer.HasBlock(r.Hash, r.Number, false)
}
// Request sends an ODR request to the LES network (implementation of LesOdrRequest)
func (r *ReceiptsRequest) Request(reqID uint64, peer *serverPeer) error {
peer.Log().Debug("Requesting block receipts", "hash", r.Hash)
return peer.requestReceipts(reqID, []common.Hash{r.Hash})
}
// Valid processes an ODR request reply message from the LES network
// returns true and stores results in memory if the message was a valid reply
// to the request (implementation of LesOdrRequest)
func (r *ReceiptsRequest) Validate(db ethdb.Database, msg *Msg) error {
log.Debug("Validating block receipts", "hash", r.Hash)
// Ensure we have a correct message with a single block receipt
if msg.MsgType != MsgReceipts {
return errInvalidMessageType
}
receipts := msg.Obj.([]types.Receipts)
if len(receipts) != 1 {
return errInvalidEntryCount
}
receipt := receipts[0]
// Retrieve our stored header and validate receipt content against it
if r.Header == nil {
r.Header = rawdb.ReadHeader(db, r.Hash, r.Number)
}
if r.Header == nil {
return errHeaderUnavailable
}
if r.Header.ReceiptHash != types.DeriveSha(receipt, new(trie.Trie)) {
return errReceiptHashMismatch
}
// Validations passed, store and return
r.Receipts = receipt
return nil
}
type ProofReq struct {
BHash common.Hash
AccKey, Key []byte
FromLevel uint
}
// ODR request type for state/storage trie entries, see LesOdrRequest interface
type TrieRequest light.TrieRequest
// GetCost returns the cost of the given ODR request according to the serving
// peer's cost table (implementation of LesOdrRequest)
func (r *TrieRequest) GetCost(peer *serverPeer) uint64 {
return peer.getRequestCost(GetProofsV2Msg, 1)
}
// CanSend tells if a certain peer is suitable for serving the given request
func (r *TrieRequest) CanSend(peer *serverPeer) bool {
return peer.HasBlock(r.Id.BlockHash, r.Id.BlockNumber, true)
}
// Request sends an ODR request to the LES network (implementation of LesOdrRequest)
func (r *TrieRequest) Request(reqID uint64, peer *serverPeer) error {
peer.Log().Debug("Requesting trie proof", "root", r.Id.Root, "key", r.Key)
req := ProofReq{
BHash: r.Id.BlockHash,
AccKey: r.Id.AccKey,
Key: r.Key,
}
return peer.requestProofs(reqID, []ProofReq{req})
}
// Valid processes an ODR request reply message from the LES network
// returns true and stores results in memory if the message was a valid reply
// to the request (implementation of LesOdrRequest)
func (r *TrieRequest) Validate(db ethdb.Database, msg *Msg) error {
log.Debug("Validating trie proof", "root", r.Id.Root, "key", r.Key)
if msg.MsgType != MsgProofsV2 {
return errInvalidMessageType
}
proofs := msg.Obj.(light.NodeList)
// Verify the proof and store if checks out
nodeSet := proofs.NodeSet()
reads := &readTraceDB{db: nodeSet}
if _, err := trie.VerifyProof(r.Id.Root, r.Key, reads); err != nil {
return fmt.Errorf("merkle proof verification failed: %v", err)
}
// check if all nodes have been read by VerifyProof
if len(reads.reads) != nodeSet.KeyCount() {
return errUselessNodes
}
r.Proof = nodeSet
return nil
}
type CodeReq struct {
BHash common.Hash
AccKey []byte
}
// ODR request type for node data (used for retrieving contract code), see LesOdrRequest interface
type CodeRequest light.CodeRequest
// GetCost returns the cost of the given ODR request according to the serving
// peer's cost table (implementation of LesOdrRequest)
func (r *CodeRequest) GetCost(peer *serverPeer) uint64 {
return peer.getRequestCost(GetCodeMsg, 1)
}
// CanSend tells if a certain peer is suitable for serving the given request
func (r *CodeRequest) CanSend(peer *serverPeer) bool {
return peer.HasBlock(r.Id.BlockHash, r.Id.BlockNumber, true)
}
// Request sends an ODR request to the LES network (implementation of LesOdrRequest)
func (r *CodeRequest) Request(reqID uint64, peer *serverPeer) error {
peer.Log().Debug("Requesting code data", "hash", r.Hash)
req := CodeReq{
BHash: r.Id.BlockHash,
AccKey: r.Id.AccKey,
}
return peer.requestCode(reqID, []CodeReq{req})
}
// Valid processes an ODR request reply message from the LES network
// returns true and stores results in memory if the message was a valid reply
// to the request (implementation of LesOdrRequest)
func (r *CodeRequest) Validate(db ethdb.Database, msg *Msg) error {
log.Debug("Validating code data", "hash", r.Hash)
// Ensure we have a correct message with a single code element
if msg.MsgType != MsgCode {
return errInvalidMessageType
}
reply := msg.Obj.([][]byte)
if len(reply) != 1 {
return errInvalidEntryCount
}
data := reply[0]
// Verify the data and store if checks out
if hash := crypto.Keccak256Hash(data); r.Hash != hash {
return errDataHashMismatch
}
r.Data = data
return nil
}
const (
// helper trie type constants
htCanonical = iota // Canonical hash trie
htBloomBits // BloomBits trie
// helper trie auxiliary types
// htAuxNone = 1 ; deprecated number, used in les2/3 previously.
htAuxHeader = 2 // applicable for htCanonical, requests for relevant headers
)
type HelperTrieReq struct {
Type uint
TrieIdx uint64
Key []byte
FromLevel, AuxReq uint
}
type HelperTrieResps struct { // describes all responses, not just a single one
Proofs light.NodeList
AuxData [][]byte
}
// ODR request type for requesting headers by Canonical Hash Trie, see LesOdrRequest interface
type ChtRequest light.ChtRequest
// GetCost returns the cost of the given ODR request according to the serving
// peer's cost table (implementation of LesOdrRequest)
func (r *ChtRequest) GetCost(peer *serverPeer) uint64 {
return peer.getRequestCost(GetHelperTrieProofsMsg, 1)
}
// CanSend tells if a certain peer is suitable for serving the given request
func (r *ChtRequest) CanSend(peer *serverPeer) bool {
peer.lock.RLock()
defer peer.lock.RUnlock()
return peer.headInfo.Number >= r.Config.ChtConfirms && r.ChtNum <= (peer.headInfo.Number-r.Config.ChtConfirms)/r.Config.ChtSize
}
// Request sends an ODR request to the LES network (implementation of LesOdrRequest)
func (r *ChtRequest) Request(reqID uint64, peer *serverPeer) error {
peer.Log().Debug("Requesting CHT", "cht", r.ChtNum, "block", r.BlockNum)
var encNum [8]byte
binary.BigEndian.PutUint64(encNum[:], r.BlockNum)
req := HelperTrieReq{
Type: htCanonical,
TrieIdx: r.ChtNum,
Key: encNum[:],
AuxReq: htAuxHeader,
}
return peer.requestHelperTrieProofs(reqID, []HelperTrieReq{req})
}
// Valid processes an ODR request reply message from the LES network
// returns true and stores results in memory if the message was a valid reply
// to the request (implementation of LesOdrRequest)
func (r *ChtRequest) Validate(db ethdb.Database, msg *Msg) error {
log.Debug("Validating CHT", "cht", r.ChtNum, "block", r.BlockNum)
if msg.MsgType != MsgHelperTrieProofs {
return errInvalidMessageType
}
resp := msg.Obj.(HelperTrieResps)
if len(resp.AuxData) != 1 {
return errInvalidEntryCount
}
nodeSet := resp.Proofs.NodeSet()
headerEnc := resp.AuxData[0]
if len(headerEnc) == 0 {
return errHeaderUnavailable
}
header := new(types.Header)
if err := rlp.DecodeBytes(headerEnc, header); err != nil {
return errHeaderUnavailable
}
// Verify the CHT
var (
node light.ChtNode
encNumber [8]byte
)
binary.BigEndian.PutUint64(encNumber[:], r.BlockNum)
reads := &readTraceDB{db: nodeSet}
value, err := trie.VerifyProof(r.ChtRoot, encNumber[:], reads)
if err != nil {
return fmt.Errorf("merkle proof verification failed: %v", err)
}
if len(reads.reads) != nodeSet.KeyCount() {
return errUselessNodes
}
if err := rlp.DecodeBytes(value, &node); err != nil {
return err
}
if node.Hash != header.Hash() {
return errCHTHashMismatch
}
if r.BlockNum != header.Number.Uint64() {
return errCHTNumberMismatch
}
// Verifications passed, store and return
r.Header = header
r.Proof = nodeSet
r.Td = node.Td
return nil
}
type BloomReq struct {
BloomTrieNum, BitIdx, SectionIndex, FromLevel uint64
}
// ODR request type for requesting headers by Canonical Hash Trie, see LesOdrRequest interface
type BloomRequest light.BloomRequest
// GetCost returns the cost of the given ODR request according to the serving
// peer's cost table (implementation of LesOdrRequest)
func (r *BloomRequest) GetCost(peer *serverPeer) uint64 {
return peer.getRequestCost(GetHelperTrieProofsMsg, len(r.SectionIndexList))
}
// CanSend tells if a certain peer is suitable for serving the given request
func (r *BloomRequest) CanSend(peer *serverPeer) bool {
peer.lock.RLock()
defer peer.lock.RUnlock()
if peer.version < lpv2 {
return false
}
return peer.headInfo.Number >= r.Config.BloomTrieConfirms && r.BloomTrieNum <= (peer.headInfo.Number-r.Config.BloomTrieConfirms)/r.Config.BloomTrieSize
}
// Request sends an ODR request to the LES network (implementation of LesOdrRequest)
func (r *BloomRequest) Request(reqID uint64, peer *serverPeer) error {
peer.Log().Debug("Requesting BloomBits", "bloomTrie", r.BloomTrieNum, "bitIdx", r.BitIdx, "sections", r.SectionIndexList)
reqs := make([]HelperTrieReq, len(r.SectionIndexList))
var encNumber [10]byte
binary.BigEndian.PutUint16(encNumber[:2], uint16(r.BitIdx))
for i, sectionIdx := range r.SectionIndexList {
binary.BigEndian.PutUint64(encNumber[2:], sectionIdx)
reqs[i] = HelperTrieReq{
Type: htBloomBits,
TrieIdx: r.BloomTrieNum,
Key: common.CopyBytes(encNumber[:]),
}
}
return peer.requestHelperTrieProofs(reqID, reqs)
}
// Valid processes an ODR request reply message from the LES network
// returns true and stores results in memory if the message was a valid reply
// to the request (implementation of LesOdrRequest)
func (r *BloomRequest) Validate(db ethdb.Database, msg *Msg) error {
log.Debug("Validating BloomBits", "bloomTrie", r.BloomTrieNum, "bitIdx", r.BitIdx, "sections", r.SectionIndexList)
// Ensure we have a correct message with a single proof element
if msg.MsgType != MsgHelperTrieProofs {
return errInvalidMessageType
}
resps := msg.Obj.(HelperTrieResps)
proofs := resps.Proofs
nodeSet := proofs.NodeSet()
reads := &readTraceDB{db: nodeSet}
r.BloomBits = make([][]byte, len(r.SectionIndexList))
// Verify the proofs
var encNumber [10]byte
binary.BigEndian.PutUint16(encNumber[:2], uint16(r.BitIdx))
for i, idx := range r.SectionIndexList {
binary.BigEndian.PutUint64(encNumber[2:], idx)
value, err := trie.VerifyProof(r.BloomTrieRoot, encNumber[:], reads)
if err != nil {
return err
}
r.BloomBits[i] = value
}
if len(reads.reads) != nodeSet.KeyCount() {
return errUselessNodes
}
r.Proofs = nodeSet
return nil
}
// TxStatusRequest is the ODR request type for transaction status
type TxStatusRequest light.TxStatusRequest
// GetCost returns the cost of the given ODR request according to the serving
// peer's cost table (implementation of LesOdrRequest)
func (r *TxStatusRequest) GetCost(peer *serverPeer) uint64 {
return peer.getRequestCost(GetTxStatusMsg, len(r.Hashes))
}
// CanSend tells if a certain peer is suitable for serving the given request
func (r *TxStatusRequest) CanSend(peer *serverPeer) bool {
return peer.serveTxLookup
}
// Request sends an ODR request to the LES network (implementation of LesOdrRequest)
func (r *TxStatusRequest) Request(reqID uint64, peer *serverPeer) error {
peer.Log().Debug("Requesting transaction status", "count", len(r.Hashes))
return peer.requestTxStatus(reqID, r.Hashes)
}
// Valid processes an ODR request reply message from the LES network
// returns true and stores results in memory if the message was a valid reply
// to the request (implementation of LesOdrRequest)
func (r *TxStatusRequest) Validate(db ethdb.Database, msg *Msg) error {
log.Debug("Validating transaction status", "count", len(r.Hashes))
// Ensure we have a correct message with a single block body
if msg.MsgType != MsgTxStatus {
return errInvalidMessageType
}
status := msg.Obj.([]light.TxStatus)
if len(status) != len(r.Hashes) {
return errInvalidEntryCount
}
r.Status = status
return nil
}
// readTraceDB stores the keys of database reads. We use this to check that received node
// sets contain only the trie nodes necessary to make proofs pass.
type readTraceDB struct {
db ethdb.KeyValueReader
reads map[string]struct{}
}
// Get returns a stored node
func (db *readTraceDB) Get(k []byte) ([]byte, error) {
if db.reads == nil {
db.reads = make(map[string]struct{})
}
db.reads[string(k)] = struct{}{}
return db.db.Get(k)
}
// Has returns true if the node set contains the given key
func (db *readTraceDB) Has(key []byte) (bool, error) {
_, err := db.Get(key)
return err == nil, nil
}