nimbus-eth1/nimbus/sync/protocol/les_protocol.nim

521 lines
16 KiB
Nim

#
# Ethereum P2P
# (c) Copyright 2018
# Status Research & Development GmbH
#
# Licensed under either of
# Apache License, version 2.0, (LICENSE-APACHEv2)
# MIT license (LICENSE-MIT)
#
import
std/[times, tables, options, sets, hashes, strutils],
stew/shims/macros, chronicles, chronos, nimcrypto/[keccak, hash],
eth/[rlp, keys, common],
eth/p2p/[rlpx, kademlia, private/p2p_types],
./les/private/les_types, ./les/flow_control,
../types
export
les_types
type
ProofRequest* = object
blockHash*: KeccakHash
accountKey*: Blob
key*: Blob
fromLevel*: uint
ContractCodeRequest* = object
blockHash*: KeccakHash
key*: EthAddress
HelperTrieProofRequest* = object
subType*: uint
sectionIdx*: uint
key*: Blob
fromLevel*: uint
auxReq*: uint
LesStatus = object
difficulty : DifficultyInt
blockHash : Hash256
blockNumber: BlockNumber
genesisHash: Hash256
const
lesVersion = 2
maxHeadersFetch = 192
maxBodiesFetch = 32
maxReceiptsFetch = 128
maxCodeFetch = 64
maxProofsFetch = 64
maxHeaderProofsFetch = 64
maxTransactionsFetch = 64
# Handshake properties:
# https://github.com/zsfelfoldi/go-ethereum/wiki/Light-Ethereum-Subprotocol-(LES)
keyProtocolVersion = "protocolVersion"
## P: is 1 for the LPV1 protocol version.
keyNetworkId = "networkId"
## P: should be 0 for testnet, 1 for mainnet.
keyHeadTotalDifficulty = "headTd"
## P: Total Difficulty of the best chain.
## Integer, as found in block header.
keyHeadHash = "headHash"
## B_32: the hash of the best (i.e. highest TD) known block.
keyHeadNumber = "headNum"
## P: the number of the best (i.e. highest TD) known block.
keyGenesisHash = "genesisHash"
## B_32: the hash of the Genesis block.
#keyServeHeaders = "serveHeaders"
# ## (optional, no value)
# ## present if the peer can serve header chain downloads.
keyServeChainSince = "serveChainSince"
## P (optional)
## present if the peer can serve Body/Receipts ODR requests
## starting from the given block number.
keyServeStateSince = "serveStateSince"
## P (optional):
## present if the peer can serve Proof/Code ODR requests
## starting from the given block number.
keyRelaysTransactions = "txRelay"
## (optional, no value)
## present if the peer can relay transactions to the ETH network.
keyFlowControlBL = "flowControl/BL"
keyFlowControlMRC = "flowControl/MRC"
keyFlowControlMRR = "flowControl/MRR"
## see Client Side Flow Control:
## https://github.com/zsfelfoldi/go-ethereum/wiki/Client-Side-Flow-Control-model-for-the-LES-protocol
keyAnnounceType = "announceType"
keyAnnounceSignature = "sign"
proc getStatus(ctx: LesNetwork): LesStatus =
discard
proc getBlockBodies(ctx: LesNetwork, hashes: openArray[Hash256]): seq[BlockBody] =
discard
proc getBlockHeaders(ctx: LesNetwork, req: BlocksRequest): seq[BlockHeader] =
discard
proc getReceipts(ctx: LesNetwork, hashes: openArray[Hash256]): seq[Receipt] =
discard
proc getProofs(ctx: LesNetwork, proofs: openArray[ProofRequest]): seq[Blob] =
discard
proc getContractCodes(ctx: LesNetwork, reqs: openArray[ContractCodeRequest]): seq[Blob] =
discard
proc getHeaderProofs(ctx: LesNetwork, reqs: openArray[ProofRequest]): seq[Blob] =
discard
proc getHelperTrieProofs(ctx: LesNetwork,
reqs: openArray[HelperTrieProofRequest],
outNodes: var seq[Blob], outAuxData: var seq[Blob]) =
discard
proc getTransactionStatus(ctx: LesNetwork, txHash: KeccakHash): TransactionStatusMsg =
discard
proc addTransactions(ctx: LesNetwork, transactions: openArray[Transaction]) =
discard
proc initProtocolState(network: LesNetwork, node: EthereumNode) {.gcsafe.} =
network.peers = initHashSet[LesPeer]()
proc addPeer(network: LesNetwork, peer: LesPeer) =
network.enlistInFlowControl peer
network.peers.incl peer
proc removePeer(network: LesNetwork, peer: LesPeer) =
network.delistFromFlowControl peer
network.peers.excl peer
template costQuantity(quantityExpr, max: untyped) {.pragma.}
proc getCostQuantity(fn: NimNode): tuple[quantityExpr, maxQuantity: NimNode] =
# XXX: `getCustomPragmaVal` doesn't work yet on regular nnkProcDef nodes
# (TODO: file as an issue)
let costQuantity = fn.pragma.findPragma(bindSym"costQuantity")
doAssert costQuantity != nil
result.quantityExpr = costQuantity[1]
result.maxQuantity= costQuantity[2]
if result.maxQuantity.kind == nnkExprEqExpr:
result.maxQuantity = result.maxQuantity[1]
macro outgoingRequestDecorator(n: untyped): untyped =
result = n
#let (costQuantity, maxQuantity) = n.getCostQuantity
let (costQuantity, _) = n.getCostQuantity
result.body.add quote do:
trackOutgoingRequest(peer.networkState(les),
peer.state(les),
perProtocolMsgId, reqId, `costQuantity`)
# echo result.repr
macro incomingResponseDecorator(n: untyped): untyped =
result = n
let trackingCall = quote do:
trackIncomingResponse(peer.state(les), reqId, msg.bufValue)
result.body.insert(n.body.len - 1, trackingCall)
# echo result.repr
macro incomingRequestDecorator(n: untyped): untyped =
result = n
let (costQuantity, maxQuantity) = n.getCostQuantity
template acceptStep(quantityExpr, maxQuantity) {.dirty.} =
let requestCostQuantity = quantityExpr
if requestCostQuantity > maxQuantity:
await peer.disconnect(BreachOfProtocol)
return
let lesPeer = peer.state
let lesNetwork = peer.networkState
if not await acceptRequest(lesNetwork, lesPeer,
perProtocolMsgId,
requestCostQuantity): return
result.body.insert(1, getAst(acceptStep(costQuantity, maxQuantity)))
# echo result.repr
template updateBV: BufValueInt =
bufValueAfterRequest(lesNetwork, lesPeer,
perProtocolMsgId, requestCostQuantity)
func getValue(values: openArray[KeyValuePair],
key: string, T: typedesc): Option[T] =
for v in values:
if v.key == key:
return some(rlp.decode(v.value, T))
func getRequiredValue(values: openArray[KeyValuePair],
key: string, T: typedesc): T =
for v in values:
if v.key == key:
return rlp.decode(v.value, T)
raise newException(HandshakeError,
"Required handshake field " & key & " missing")
p2pProtocol les(version = lesVersion,
peerState = LesPeer,
networkState = LesNetwork,
outgoingRequestDecorator = outgoingRequestDecorator,
incomingRequestDecorator = incomingRequestDecorator,
incomingResponseThunkDecorator = incomingResponseDecorator):
handshake:
proc status(p: Peer, values: openArray[KeyValuePair])
onPeerConnected do (peer: Peer):
let
network = peer.network
lesPeer = peer.state
lesNetwork = peer.networkState
status = lesNetwork.getStatus()
template `=>`(k, v: untyped): untyped =
KeyValuePair(key: k, value: rlp.encode(v))
var lesProperties = @[
keyProtocolVersion => lesVersion,
keyNetworkId => network.networkId,
keyHeadTotalDifficulty => status.difficulty,
keyHeadHash => status.blockHash,
keyHeadNumber => status.blockNumber,
keyGenesisHash => status.genesisHash
]
lesPeer.remoteReqCosts = currentRequestsCosts(lesNetwork, les.protocolInfo)
if lesNetwork.areWeServingData:
lesProperties.add [
# keyServeHeaders => nil,
keyServeChainSince => 0,
keyServeStateSince => 0,
# keyRelaysTransactions => nil,
keyFlowControlBL => lesNetwork.bufferLimit,
keyFlowControlMRR => lesNetwork.minRechargingRate,
keyFlowControlMRC => lesPeer.remoteReqCosts
]
if lesNetwork.areWeRequestingData:
lesProperties.add(keyAnnounceType => lesNetwork.ourAnnounceType)
let
s = await peer.status(lesProperties, timeout = chronos.seconds(10))
peerNetworkId = s.values.getRequiredValue(keyNetworkId, NetworkId)
peerGenesisHash = s.values.getRequiredValue(keyGenesisHash, KeccakHash)
peerLesVersion = s.values.getRequiredValue(keyProtocolVersion, uint)
template requireCompatibility(peerVar, localVar, varName: untyped) =
if localVar != peerVar:
raise newException(HandshakeError,
"Incompatibility detected! $1 mismatch ($2 != $3)" %
[varName, $localVar, $peerVar])
requireCompatibility(peerLesVersion, uint(lesVersion), "les version")
requireCompatibility(peerNetworkId, network.networkId, "network id")
requireCompatibility(peerGenesisHash, status.genesisHash, "genesis hash")
template `:=`(lhs, key) =
lhs = s.values.getRequiredValue(key, type(lhs))
lesPeer.bestBlockHash := keyHeadHash
lesPeer.bestBlockNumber := keyHeadNumber
lesPeer.bestDifficulty := keyHeadTotalDifficulty
let peerAnnounceType = s.values.getValue(keyAnnounceType, AnnounceType)
if peerAnnounceType.isSome:
lesPeer.isClient = true
lesPeer.announceType = peerAnnounceType.get
else:
lesPeer.announceType = AnnounceType.Simple
lesPeer.hasChainSince := keyServeChainSince
lesPeer.hasStateSince := keyServeStateSince
lesPeer.relaysTransactions := keyRelaysTransactions
lesPeer.localFlowState.bufLimit := keyFlowControlBL
lesPeer.localFlowState.minRecharge := keyFlowControlMRR
lesPeer.localReqCosts := keyFlowControlMRC
lesNetwork.addPeer lesPeer
onPeerDisconnected do (peer: Peer, reason: DisconnectionReason) {.gcsafe.}:
peer.networkState.removePeer peer.state
## Header synchronisation
##
proc announce(
peer: Peer,
headHash: KeccakHash,
headNumber: BlockNumber,
headTotalDifficulty: DifficultyInt,
reorgDepth: BlockNumber,
values: openArray[KeyValuePair],
announceType: AnnounceType) =
if peer.state.announceType == AnnounceType.None:
error "unexpected announce message", peer
return
if announceType == AnnounceType.Signed:
let signature = values.getValue(keyAnnounceSignature, Blob)
if signature.isNone:
error "missing announce signature"
return
let sig = Signature.fromRaw(signature.get).tryGet()
let sigMsg = rlp.encodeList(headHash, headNumber, headTotalDifficulty)
let signerKey = recover(sig, sigMsg).tryGet()
if signerKey.toNodeId != peer.remote.id:
error "invalid announce signature"
# TODO: should we disconnect this peer?
return
# TODO: handle new block
requestResponse:
proc getBlockHeaders(
peer: Peer,
req: BlocksRequest) {.
costQuantity(req.maxResults.int, max = maxHeadersFetch).} =
let ctx = peer.networkState()
let headers = ctx.getBlockHeaders(req)
await response.send(updateBV(), headers)
proc blockHeaders(
peer: Peer,
bufValue: BufValueInt,
blocks: openArray[BlockHeader])
## On-damand data retrieval
##
requestResponse:
proc getBlockBodies(
peer: Peer,
blocks: openArray[KeccakHash]) {.
costQuantity(blocks.len, max = maxBodiesFetch), gcsafe.} =
let ctx = peer.networkState()
let blocks = ctx.getBlockBodies(blocks)
await response.send(updateBV(), blocks)
proc blockBodies(
peer: Peer,
bufValue: BufValueInt,
bodies: openArray[BlockBody])
requestResponse:
proc getReceipts(
peer: Peer,
hashes: openArray[KeccakHash])
{.costQuantity(hashes.len, max = maxReceiptsFetch).} =
let ctx = peer.networkState()
let receipts = ctx.getReceipts(hashes)
await response.send(updateBV(), receipts)
proc receipts(
peer: Peer,
bufValue: BufValueInt,
receipts: openArray[Receipt])
requestResponse:
proc getProofs(
peer: Peer,
proofs: openArray[ProofRequest]) {.
costQuantity(proofs.len, max = maxProofsFetch).} =
let ctx = peer.networkState()
let proofs = ctx.getProofs(proofs)
await response.send(updateBV(), proofs)
proc proofs(
peer: Peer,
bufValue: BufValueInt,
proofs: openArray[Blob])
requestResponse:
proc getContractCodes(
peer: Peer,
reqs: seq[ContractCodeRequest]) {.
costQuantity(reqs.len, max = maxCodeFetch).} =
let ctx = peer.networkState()
let results = ctx.getContractCodes(reqs)
await response.send(updateBV(), results)
proc contractCodes(
peer: Peer,
bufValue: BufValueInt,
results: seq[Blob])
nextID 15
requestResponse:
proc getHeaderProofs(
peer: Peer,
reqs: openArray[ProofRequest]) {.
costQuantity(reqs.len, max = maxHeaderProofsFetch).} =
let ctx = peer.networkState()
let proofs = ctx.getHeaderProofs(reqs)
await response.send(updateBV(), proofs)
proc headerProofs(
peer: Peer,
bufValue: BufValueInt,
proofs: openArray[Blob])
requestResponse:
proc getHelperTrieProofs(
peer: Peer,
reqs: openArray[HelperTrieProofRequest]) {.
costQuantity(reqs.len, max = maxProofsFetch).} =
let ctx = peer.networkState()
var nodes, auxData: seq[Blob]
ctx.getHelperTrieProofs(reqs, nodes, auxData)
await response.send(updateBV(), nodes, auxData)
proc helperTrieProofs(
peer: Peer,
bufValue: BufValueInt,
nodes: seq[Blob],
auxData: seq[Blob])
## Transaction relaying and status retrieval
##
requestResponse:
proc sendTxV2(
peer: Peer,
transactions: openArray[Transaction]) {.
costQuantity(transactions.len, max = maxTransactionsFetch).} =
let ctx = peer.networkState()
var results: seq[TransactionStatusMsg]
for t in transactions:
let hash = t.rlpHash
var s = ctx.getTransactionStatus(hash)
if s.status == TransactionStatus.Unknown:
ctx.addTransactions([t])
s = ctx.getTransactionStatus(hash)
results.add s
await response.send(updateBV(), results)
proc getTxStatus(
peer: Peer,
transactions: openArray[Transaction]) {.
costQuantity(transactions.len, max = maxTransactionsFetch).} =
let ctx = peer.networkState()
var results: seq[TransactionStatusMsg]
for t in transactions:
results.add ctx.getTransactionStatus(t.rlpHash)
await response.send(updateBV(), results)
proc txStatus(
peer: Peer,
bufValue: BufValueInt,
transactions: openArray[TransactionStatusMsg])
proc configureLes*(node: EthereumNode,
# Client options:
announceType = AnnounceType.Simple,
# Server options.
# The zero default values indicate that the
# LES server will be deactivated.
maxReqCount = 0,
maxReqCostSum = 0,
reqCostTarget = 0) =
doAssert announceType != AnnounceType.Unspecified or maxReqCount > 0
var lesNetwork = node.protocolState(les)
lesNetwork.ourAnnounceType = announceType
initFlowControl(lesNetwork, les.protocolInfo,
maxReqCount, maxReqCostSum, reqCostTarget)
proc configureLesServer*(node: EthereumNode,
# Client options:
announceType = AnnounceType.Unspecified,
# Server options.
# The zero default values indicate that the
# LES server will be deactivated.
maxReqCount = 0,
maxReqCostSum = 0,
reqCostTarget = 0) =
## This is similar to `configureLes`, but with default parameter
## values appropriate for a server.
node.configureLes(announceType, maxReqCount, maxReqCostSum, reqCostTarget)
proc persistLesMessageStats*(node: EthereumNode) =
persistMessageStats(node.protocolState(les))