ics | title | stage | category | kind | implements | author | created | modified |
---|---|---|---|---|---|---|---|---|
7 |
Tendermint Client |
draft |
IBC/TAO |
instantiation |
2 |
Christopher Goes <cwgoes@tendermint.com> |
2019-12-10 |
2019-12-19 |
This specification document describes a client (verification algorithm) for a blockchain using Tendermint consensus.
State machines of various sorts replicated using the Tendermint consensus algorithm might like to interface with other replicated state machines or solo machines over IBC.
Functions & terms are as defined in ICS 2.
currentTimestamp
is as defined in ICS 24.
The Tendermint light client uses the generalised Merkle proof format as defined in ICS 8.
hash
is a generic collision-resistant hash function, and can easily be configured.
This specification must satisfy the client interface defined in ICS 2.
The basic idea of "would-have-been-fooled" detection is that it allows us to be a bit more conservative, and freeze our light client when we know that another light client somewhere else on the network with a slightly different update pattern could have been fooled, even though we weren't.
Consider a topology of three chains - A
, B
, and C
, and two clients for chain A
, A_1
and A_2
, running on chains B
and C
respectively. The following sequence of events occurs:
- Chain
A
produces a block at heighth_0
(correctly). - Clients
A_1
andA_2
are updated to the block at heighth_0
. - Chain
A
produces a block at heighth_0 + n
(correctly). - Client
A_1
is updated to the block at heighth_0 + n
(clientA_2
is not yet updated). - Chain
A
produces a second (equivocating) block at heighth_0 + k
, wherek <= n
.
Without "would-have-been-fooled", it will be possible to freeze client A_2
(since there are two valid blocks at height h_0 + k
which are newer than the latest header A_2
knows), but it will not be possible to freeze A_1
, since A_1
has already progressed beyond h_0 + k
.
Arguably, this is disadvantageous, since A_1
was just "lucky" in having been updated when A_2
was not, and clearly some Byzantine fault has happened that should probably be deal with by human or governance system intervention. The idea of "would-have-been-fooled" is to allow this to be detected by having A_1
start from a configurable past header to detect misbehaviour (so in this case, A_1
would be able to start from h_0
and would also be frozen).
There is a free parameter here - namely, how far back is A_1
willing to go (how big can n
be where A_1
will still be willing to look up h_0
, having been updated to h_0 + n
)? There is also a countervailing concern, in and of that double-signing is presumed to be costless after the unbonding period has passed, and we don't want to open up a denial-of-service vector for IBC clients.
The necessary condition is thus that A_1
should be willing to look up headers as old as it has stored, but should also enforce the "unbonding period" check on the misbehaviour, and avoid freezing the client if the misbehaviour is older than the unbonding period (relative to the client's local timestamp). If there are concerns about clock skew a slight delta could be added.
This specification depends on correct instantiation of the Tendermint consensus algorithm and light client algorithm.
The Tendermint client state tracks the current revision, current validator set, trusting period, unbonding period, latest height, latest timestamp (block time), and a possible frozen height.
interface ClientState {
chainID: string
validatorSet: List<Pair<Address, uint64>>
trustLevel: Rational
trustingPeriod: uint64
unbondingPeriod: uint64
latestHeight: Height
latestTimestamp: uint64
frozenHeight: Maybe<uint64>
upgradeCommitmentPrefix: CommitmentPrefix
upgradeKey: []byte
maxClockDrift: uint64
proofSpecs: []ProofSpec
}
The Tendermint client tracks the timestamp (block time), validator set, and commitment root for all previously verified consensus states (these can be pruned after the unbonding period has passed, but should not be pruned beforehand).
interface ConsensusState {
timestamp: uint64
validatorSet: List<Pair<Address, uint64>>
commitmentRoot: []byte
}
The height of a Tendermint client consists of two uint64
s: the revision number, and the height in the revision.
interface Height {
revisionNumber: uint64
revisionHeight: uint64
}
Comparison between heights is implemented as follows:
function compare(a: TendermintHeight, b: TendermintHeight): Ord {
if (a.revisionNumber < b.revisionNumber)
return LT
else if (a.revisionNumber === b.revisionNumber)
if (a.revisionHeight < b.revisionHeight)
return LT
else if (a.revisionHeight === b.revisionHeight)
return EQ
return GT
}
This is designed to allow the height to reset to 0
while the revision number increases by one in order to preserve timeouts through zero-height upgrades.
The Tendermint client headers include the height, the timestamp, the commitment root, the complete validator set, and the signatures by the validators who committed the block.
interface Header {
height: uint64
timestamp: uint64
commitmentRoot: []byte
validatorSet: List<Pair<Address, uint64>>
signatures: []Signature
}
The Misbehaviour
type is used for detecting misbehaviour and freezing the client - to prevent further packet flow - if applicable.
Tendermint client Misbehaviour
consists of two headers at the same height both of which the light client would have considered valid.
interface Misbehaviour {
fromHeight: Height
h1: Header
h2: Header
}
Tendermint client initialisation requires a (subjectively chosen) latest consensus state, including the full validator set.
function initialise(
chainID: string, consensusState: ConsensusState,
validatorSet: List<Pair<Address, uint64>>, trustLevel: Fraction,
height: Height, trustingPeriod: uint64, unbondingPeriod: uint64,
upgradeCommitmentPrefix: CommitmentPrefix, upgradeKey: []byte,
maxClockDrift: uint64, proofSpecs: []ProofSpec): ClientState {
assert(trustingPeriod < unbondingPeriod)
assert(height > 0)
assert(trustLevel > 0 && trustLevel < 1)
set("clients/{identifier}/consensusStates/{height}", consensusState)
return ClientState{
chainID,
validatorSet,
trustLevel,
latestHeight: height,
latestTimestamp: consensusState.timestamp,
trustingPeriod,
unbondingPeriod,
frozenHeight: null,
upgradeCommitmentPrefix,
upgradeKey,
maxClockDrift,
proofSpecs
}
}
The Tendermint client latestClientHeight
function returns the latest stored height, which is updated every time a new (more recent) header is validated.
function latestClientHeight(clientState: ClientState): Height {
return clientState.latestHeight
}
Tendermint client validity checking uses the bisection algorithm described in the Tendermint spec. If the provided header is valid, the client state is updated & the newly verified commitment written to the store.
function checkValidityAndUpdateState(
clientState: ClientState,
revision: uint64,
header: Header) {
// assert revision is correct
assert(revision === clientState.currentHeight.revision)
// check that revision is encoded correctly in chain ID
assert(revision === clientState.chainID.regex('[a-z]*-(0)'))
// assert trusting period has not yet passed
assert(currentTimestamp() - clientState.latestTimestamp < clientState.trustingPeriod)
// assert header timestamp is less than trust period in the future. This should be resolved with an intermediate header.
assert(header.timestamp - clientState.latestTimeStamp < trustingPeriod)
// assert header timestamp is past current timestamp
assert(header.timestamp > clientState.latestTimestamp)
// assert header height is newer than any we know
assert(header.height > clientState.latestHeight)
// call the `verify` function
assert(verify(clientState.validatorSet, clientState.latestHeight, clientState.trustingPeriod, maxClockDrift, header))
// update validator set
clientState.validatorSet = header.validatorSet
// update latest height
clientState.latestHeight = header.height
// update latest timestamp
clientState.latestTimestamp = header.timestamp
// create recorded consensus state, save it
consensusState = ConsensusState{header.timestamp, header.validatorSet, header.commitmentRoot}
set("clients/{identifier}/consensusStates/{header.height}", consensusState)
set("clients/{identifier}/processedTimes/{header.height}", currentTimestamp())
set("clients/{identifier}/processedHeights/{header.height}", currentHeight())
// save the client
set("clients/{identifier}", clientState)
}
Tendermint client misbehaviour checking determines whether or not two conflicting headers at the same height would have convinced the light client.
function checkMisbehaviourAndUpdateState(
clientState: ClientState,
misbehaviour: Misbehaviour) {
// assert that the heights are the same
assert(misbehaviour.h1.height === misbehaviour.h2.height)
// assert that the commitments are different
assert(misbehaviour.h1.commitmentRoot !== misbehaviour.h2.commitmentRoot)
// fetch the previously verified commitment root & validator set
consensusState = get("clients/{identifier}/consensusStates/{misbehaviour.fromHeight}")
// assert that the timestamp is not from more than an trusting period ago
assert(currentTimestamp() - misbehaviour.timestamp < clientState.trustingPeriod)
// check if the light client "would have been fooled"
assert(
verify(consensusState.validatorSet, misbehaviour.fromHeight, misbehaviour.h1) &&
verify(consensusState.validatorSet, misbehaviour.fromHeight, misbehaviour.h2)
)
// set the frozen height
clientState.frozenHeight = min(clientState.frozenHeight, misbehaviour.h1.height) // which is same as h2.height
// save the client
set("clients/{identifier}", clientState)
}
The chain which this light client is tracking can elect to write a special pre-determined key in state to allow the light client to update its client state (e.g. with a new chain ID or revision) in preparation for an upgrade.
As the client state change will be performed immediately, once the new client state information is written to the predetermined key, the client will no longer be able to follow blocks on the old chain, so it must upgrade promptly.
function upgradeClientState(
clientState: ClientState,
newClientState: ClientState,
height: Height,
proof: CommitmentPrefix) {
// assert trusting period has not yet passed
assert(currentTimestamp() - clientState.latestTimestamp < clientState.trustingPeriod)
// check that the revision has been incremented
assert(newClientState.latestHeight.revisionNumber > clientState.latestHeight.revisionNumber)
// check proof of updated client state in state at predetermined commitment prefix and key
path = applyPrefix(clientState.upgradeCommitmentPrefix, clientState.upgradeKey)
// check that the client is at a sufficient height
assert(clientState.latestHeight >= height)
// check that the client is unfrozen or frozen at a higher height
assert(clientState.frozenHeight === null || clientState.frozenHeight > height)
// fetch the previously verified commitment root & verify membership
root = get("clients/{identifier}/consensusStates/{height}")
// verify that the provided consensus state has been stored
assert(root.verifyMembership(path, newClientState, proof))
// update client state
clientState = newClientState
set("clients/{identifier}", clientState)
}
Tendermint client state verification functions check a Merkle proof against a previously validated commitment root.
These functions utilise the proofSpecs
with which the client was initialised.
function verifyClientConsensusState(
clientState: ClientState,
height: Height,
prefix: CommitmentPrefix,
proof: CommitmentProof,
clientIdentifier: Identifier,
consensusStateHeight: Height,
consensusState: ConsensusState) {
path = applyPrefix(prefix, "clients/{clientIdentifier}/consensusState/{consensusStateHeight}")
// check that the client is at a sufficient height
assert(clientState.latestHeight >= height)
// check that the client is unfrozen or frozen at a higher height
assert(clientState.frozenHeight === null || clientState.frozenHeight > height)
// fetch the previously verified commitment root & verify membership
root = get("clients/{identifier}/consensusStates/{height}")
// verify that the provided consensus state has been stored
assert(root.verifyMembership(path, consensusState, proof))
}
function verifyConnectionState(
clientState: ClientState,
height: Height,
prefix: CommitmentPrefix,
proof: CommitmentProof,
connectionIdentifier: Identifier,
connectionEnd: ConnectionEnd) {
path = applyPrefix(prefix, "connections/{connectionIdentifier}")
// check that the client is at a sufficient height
assert(clientState.latestHeight >= height)
// check that the client is unfrozen or frozen at a higher height
assert(clientState.frozenHeight === null || clientState.frozenHeight > height)
// fetch the previously verified commitment root & verify membership
root = get("clients/{identifier}/consensusStates/{height}")
// verify that the provided connection end has been stored
assert(root.verifyMembership(path, connectionEnd, proof))
}
function verifyChannelState(
clientState: ClientState,
height: Height,
prefix: CommitmentPrefix,
proof: CommitmentProof,
portIdentifier: Identifier,
channelIdentifier: Identifier,
channelEnd: ChannelEnd) {
path = applyPrefix(prefix, "ports/{portIdentifier}/channels/{channelIdentifier}")
// check that the client is at a sufficient height
assert(clientState.latestHeight >= height)
// check that the client is unfrozen or frozen at a higher height
assert(clientState.frozenHeight === null || clientState.frozenHeight > height)
// fetch the previously verified commitment root & verify membership
root = get("clients/{identifier}/consensusStates/{height}")
// verify that the provided channel end has been stored
assert(root.verifyMembership(clientState.proofSpecs, path, channelEnd, proof))
}
function verifyPacketData(
clientState: ClientState,
height: Height,
delayPeriodTime: uint64,
delayPeriodBlocks: uint64,
prefix: CommitmentPrefix,
proof: CommitmentProof,
portIdentifier: Identifier,
channelIdentifier: Identifier,
sequence: uint64,
data: bytes) {
path = applyPrefix(prefix, "ports/{portIdentifier}/channels/{channelIdentifier}/packets/{sequence}")
// check that the client is at a sufficient height
assert(clientState.latestHeight >= height)
// check that the client is unfrozen or frozen at a higher height
assert(clientState.frozenHeight === null || clientState.frozenHeight > height)
// fetch the processed time
processedTime = get("clients/{identifier}/processedTimes/{height}")
// fetch the processed height
processedHeight = get("clients/{identifier}/processedHeights/{height}")
// assert that enough time has elapsed
assert(currentTimestamp() >= processedTime + delayPeriodTime)
// assert that enough blocks have elapsed
assert(currentHeight() >= processedHeight + delayPeriodBlocks)
// fetch the previously verified commitment root & verify membership
root = get("clients/{identifier}/consensusStates/{height}")
// verify that the provided commitment has been stored
assert(root.verifyMembership(clientState.proofSpecs, path, hash(data), proof))
}
function verifyPacketAcknowledgement(
clientState: ClientState,
height: Height,
delayPeriodTime: uint64,
delayPeriodBlocks: uint64,
prefix: CommitmentPrefix,
proof: CommitmentProof,
portIdentifier: Identifier,
channelIdentifier: Identifier,
sequence: uint64,
acknowledgement: bytes) {
path = applyPrefix(prefix, "ports/{portIdentifier}/channels/{channelIdentifier}/acknowledgements/{sequence}")
// check that the client is at a sufficient height
assert(clientState.latestHeight >= height)
// check that the client is unfrozen or frozen at a higher height
assert(clientState.frozenHeight === null || clientState.frozenHeight > height)
// fetch the processed time
processedTime = get("clients/{identifier}/processedTimes/{height}")
// fetch the processed height
processedHeight = get("clients/{identifier}/processedHeights/{height}")
// assert that enough time has elapsed
assert(currentTimestamp() >= processedTime + delayPeriodTime)
// assert that enough blocks have elapsed
assert(currentHeight() >= processedHeight + delayPeriodBlocks)
// fetch the previously verified commitment root & verify membership
root = get("clients/{identifier}/consensusStates/{height}")
// verify that the provided acknowledgement has been stored
assert(root.verifyMembership(clientState.proofSpecs, path, hash(acknowledgement), proof))
}
function verifyPacketReceiptAbsence(
clientState: ClientState,
height: Height,
delayPeriodTime: uint64,
delayPeriodBlocks: uint64,
prefix: CommitmentPrefix,
proof: CommitmentProof,
portIdentifier: Identifier,
channelIdentifier: Identifier,
sequence: uint64) {
path = applyPrefix(prefix, "ports/{portIdentifier}/channels/{channelIdentifier}/receipts/{sequence}")
// check that the client is at a sufficient height
assert(clientState.latestHeight >= height)
// check that the client is unfrozen or frozen at a higher height
assert(clientState.frozenHeight === null || clientState.frozenHeight > height)
// fetch the processed time
processedTime = get("clients/{identifier}/processedTimes/{height}")
// fetch the processed height
processedHeight = get("clients/{identifier}/processedHeights/{height}")
// assert that enough time has elapsed
assert(currentTimestamp() >= processedTime + delayPeriodTime)
// assert that enough blocks have elapsed
assert(currentHeight() >= processedHeight + delayPeriodBlocks)
// fetch the previously verified commitment root & verify membership
root = get("clients/{identifier}/consensusStates/{height}")
// verify that no acknowledgement has been stored
assert(root.verifyNonMembership(clientState.proofSpecs, path, proof))
}
function verifyNextSequenceRecv(
clientState: ClientState,
height: Height,
delayPeriodTime: uint64,
delayPeriodBlocks: uint64,
prefix: CommitmentPrefix,
proof: CommitmentProof,
portIdentifier: Identifier,
channelIdentifier: Identifier,
nextSequenceRecv: uint64) {
path = applyPrefix(prefix, "ports/{portIdentifier}/channels/{channelIdentifier}/nextSequenceRecv")
// check that the client is at a sufficient height
assert(clientState.latestHeight >= height)
// check that the client is unfrozen or frozen at a higher height
assert(clientState.frozenHeight === null || clientState.frozenHeight > height)
// fetch the processed time
processedTime = get("clients/{identifier}/processedTimes/{height}")
// fetch the processed height
processedHeight = get("clients/{identifier}/processedHeights/{height}")
// assert that enough time has elapsed
assert(currentTimestamp() >= processedTime + delayPeriodTime)
// assert that enough blocks have elapsed
assert(currentHeight() >= processedHeight + delayPeriodBlocks)
// fetch the previously verified commitment root & verify membership
root = get("clients/{identifier}/consensusStates/{height}")
// verify that the nextSequenceRecv is as claimed
assert(root.verifyMembership(clientState.proofSpecs, path, nextSequenceRecv, proof))
}
Correctness guarantees as provided by the Tendermint light client algorithm.
Not applicable.
Not applicable. Alterations to the client verification algorithm will require a new client standard.
None yet.
None at present.
December 10th, 2019 - Initial version December 19th, 2019 - Final first draft
All content herein is licensed under Apache 2.0.