EIP-225: Clique proof-of-authority consensus protocol
作者 | Péter Szilágyi |
---|---|
讨论-To | https://github.com/ethereum/EIPs/issues/225 |
状态 | Final |
类型 | Standards Track |
分类 | Core |
创建日期 | 2017-03-06 |
英文版 | https://eips.ethereum.org/EIPS/eip-225 |
Abstract
Clique is a proof-of-authority consensus protocol. It shadows the design of Ethereum mainnet, so it can be added to any client with minimal effort.
Motivation
Ethereum’s first official testnet was Morden. It ran from July 2015 to about November 2016, when due to the accumulated junk and some testnet consensus issues between Geth and Parity, it was finally laid to rest in favor of a testnet reboot.
Ropsten was thus born, clearing out all the junk and starting with a clean slate. This ran well until the end of February 2017, when malicious actors decided to abuse the low PoW and gradually inflate the block gas limits to 9 billion (from the normal 4.7 million), at which point sending in gigantic transactions crippling the entire network. Even before that, attackers attempted multiple extremely long reorgs, causing network splits between different clients, and even different versions.
The root cause of these attacks is that a PoW network is only as secure as the computing capacity placed behind it. Restarting a new testnet from zero wouldn’t solve anything, since the attacker can mount the same attack over and over again. The Parity team decided to go with an emergency solution of rolling back a significant number of blocks, and enacting a soft-fork rule that disallows gas limits above a certain threshold.
While this solution may work in the short term:
- It’s not elegant: Ethereum supposed to have dynamic block limits
- It’s not portable: other clients need to implement new fork logic themselves
- It’s not compatible with sync modes: fast and light clients are both out of luck
- It’s just prolonging the attacks: junk can still be steadily pushed in ad infinitum
Parity’s solution although not perfect, is nonetheless workable. I’d like to propose a longer term alternative solution, which is more involved, yet should be simple enough to allow rolling out in a reasonable amount of time.
Standardized proof-of-authority
As reasoned above, proof-of-work cannot work securely in a network with no value. Ethereum has its long term goal of proof-of-stake based on Casper, but that is heavy research so we cannot rely on that any time soon to fix today’s problems. One solution however is easy enough to implement, yet effective enough to fix the testnet properly, namely a proof-of-authority scheme.
The main design goals of the PoA protocol described here is that it should be very simple to implement and embed into any existing Ethereum client, while at the same time allow using existing sync technologies (fast, light, warp) without needing client developers to add custom logic to critical software.
Design constraints
There are two approaches to syncing a blockchain in general:
- The classical approach is to take the genesis block and crunch through all the transactions one by one. This is tried and proven, but in Ethereum complexity networks quickly turns out to be very costly computationally.
- The other is to only download the chain of block headers and verify their validity, after which point an arbitrary recent state may be downloaded from the network and checked against recent headers.
A PoA scheme is based on the idea that blocks may only be minted by trusted signers. As such, every block (or header) that a client sees can be matched against the list of trusted signers. The challenge here is how to maintain a list of authorized signers that can change in time? The obvious answer (store it in an Ethereum contract) is also the wrong answer: fast, light and warp sync don’t have access to the state during syncing.
The protocol of maintaining the list of authorized signers must be fully contained in the block headers.
The next obvious idea would be to change the structure of the block headers so it drops the notions of PoW, and introduces new fields to cater for voting mechanisms. This is also the wrong answer: changing such a core data structure in multiple implementations would be a nightmare development, maintenance and security wise.
The protocol of maintaining the list of authorized signers must fit fully into the current data models.
So, according to the above, we can’t use the EVM for voting, rather have to resort to headers. And we can’t change header fields, rather have to resort to the currently available ones. Not much wiggle room.
Repurposing header fields for signing and voting
The most obvious field that currently is used solely as fun metadata is the 32 byte extra-data section in block headers. Miners usually place their client and version in there, but some fill it with alternative “messages”. The protocol would extend this field to with 65 bytes with the purpose of a secp256k1 miner signature. This would allow anyone obtaining a block to verify it against a list of authorized signers. It also makes the miner section in block headers obsolete (since the address can be derived from the signature).
Note, changing the length of a header field is a non invasive operation as all code (such as RLP encoding, hashing) is agnostic to that, so clients wouldn’t need custom logic.
The above is enough to validate a chain, but how can we update a dynamic list of signers. The answer is that we can repurpose the newly obsoleted miner field and the PoA obsoleted nonce field to create a voting protocol:
- During regular blocks, both of these fields would be set to zero.
- If a signer wishes to enact a change to the list of authorized signers, it will:
- Set the miner to the signer it wishes to vote about
- Set the nonce to
0
or0xff...f
to vote in favor of adding or kicking out
Any clients syncing the chain can “tally” up the votes during block processing, and maintain a dynamically changing list of authorized signers by popular vote.
To avoid having an infinite window to tally up votes in, and also to allow periodically flushing stale proposals, we can reuse the concept of an epoch from ethash, where every epoch transition flushes all pending votes. Furthermore, these epoch transitions can also act as stateless checkpoints containing the list of current authorized signers within the header extra-data. This permits clients to sync up based only on a checkpoint hash without having to replay all the voting that was done on the chain up to that point. It also allows the genesis header to fully define the chain, containing the list of initial signers.
Attack vector: Malicious signer
It may happen that a malicious user gets added to the list of signers, or that a signer key/machine is compromised. In such a scenario the protocol needs to be able to defend itself against reorganizations and spamming. The proposed solution is that given a list of N authorized signers, any signer may only mint 1 block out of every K. This ensures that damage is limited, and the remainder of the miners can vote out the malicious user.
Attack vector: Censoring signer
Another interesting attack vector is if a signer (or group of signers) attempts to censor out blocks that vote on removing them from the authorization list. To work around this, we restrict the allowed minting frequency of signers to 1 out of N/2. This ensures that malicious signers need to control at least 51% of signing accounts, at which case it’s game over anyway.
Attack vector: Spamming signer
A final small attack vector is that of malicious signers injecting new vote proposals inside every block they mint. Since nodes need to tally up all votes to create the actual list of authorized signers, they need to track all votes through time. Without placing a limit on the vote window, this could grow slowly, yet unbounded. The solution is to place a moving window of W blocks after which votes are considered stale. A sane window might be 1-2 epochs. We’ll call this an epoch.
Attack vector: Concurrent blocks
If the number of authorized signers are N, and we allow each signer to mint 1 block out of K, then at any point in time N-K+1 miners are allowed to mint. To avoid these racing for blocks, every signer would add a small random “offset” to the time it releases a new block. This ensures that small forks are rare, but occasionally still happen (as on the main net). If a signer is caught abusing it’s authority and causing chaos, it can be voted out.
Specification
We define the following constants:
EPOCH_LENGTH
: Number of blocks after which to checkpoint and reset the pending votes.- Suggested
30000
for the testnet to remain analogous to the mainnetethash
epoch.
- Suggested
BLOCK_PERIOD
: Minimum difference between two consecutive block’s timestamps.- Suggested
15s
for the testnet to remain analogous to the mainnetethash
target.
- Suggested
EXTRA_VANITY
: Fixed number of extra-data prefix bytes reserved for signer vanity.- Suggested
32 bytes
to retain the current extra-data allowance and/or use.
- Suggested
EXTRA_SEAL
: Fixed number of extra-data suffix bytes reserved for signer seal.65 bytes
fixed as signatures are based on the standardsecp256k1
curve.- Filled with zeros on genesis block.
NONCE_AUTH
: Magic nonce number0xffffffffffffffff
to vote on adding a new signer.NONCE_DROP
: Magic nonce number0x0000000000000000
to vote on removing a signer.UNCLE_HASH
: AlwaysKeccak256(RLP([]))
as uncles are meaningless outside of PoW.DIFF_NOTURN
: Block score (difficulty) for blocks containing out-of-turn signatures.- Suggested
1
since it just needs to be an arbitrary baseline constant.
- Suggested
DIFF_INTURN
: Block score (difficulty) for blocks containing in-turn signatures.- Suggested
2
to show a slight preference over out-of-turn signatures.
- Suggested
We also define the following per-block constants:
BLOCK_NUMBER
: Block height in the chain, where the height of the genesis is block0
.SIGNER_COUNT
: Number of authorized signers valid at a particular instance in the chain.SIGNER_INDEX
: Zero-based index of the block signer in the sorted list of current authorized signers.SIGNER_LIMIT
: Number of consecutive blocks out of which a signer may only sign one.- Must be
floor(SIGNER_COUNT / 2) + 1
to enforce majority consensus on a chain.
- Must be
We repurpose the ethash
header fields as follows:
beneficiary
/miner
: Address to propose modifying the list of authorized signers with.- Should be filled with zeroes normally, modified only while voting.
- Arbitrary values are permitted nonetheless (even meaningless ones such as voting out non signers) to avoid extra complexity in implementations around voting mechanics.
- Must be filled with zeroes on checkpoint (i.e. epoch transition) blocks.
- Transaction execution must use the actual block signer (see
extraData
) for theCOINBASE
opcode and transaction fees must be attributed to the signer account.
nonce
: Signer proposal regarding the account defined by thebeneficiary
field.- Should be
NONCE_DROP
to propose deauthorizingbeneficiary
as an existing signer. - Should be
NONCE_AUTH
to propose authorizingbeneficiary
as a new signer. - Must be filled with zeroes on checkpoint (i.e. epoch transition) blocks.
- Must not take up any other value apart from the two above (for now).
- Should be
extraData
: Combined field for signer vanity, checkpointing and signer signatures.- First
EXTRA_VANITY
bytes (fixed) may contain arbitrary signer vanity data. - Last
EXTRA_SEAL
bytes (fixed) is the signer’s signature sealing the header. - Checkpoint blocks must contain a list of signers (
N*20 bytes
) in between, omitted otherwise. - The list of signers in checkpoint block extra-data sections must be sorted in ascending byte order.
- First
mixHash
: Reserved for fork protection logic, similar to the extra-data during the DAO.- Must be filled with zeroes during normal operation.
ommersHash
: Must beUNCLE_HASH
as uncles are meaningless outside of PoW.timestamp
: Must be at least the parent timestamp +BLOCK_PERIOD
.difficulty
: Contains the standalone score of the block to derive the quality of a chain.- Must be
DIFF_NOTURN
ifBLOCK_NUMBER % SIGNER_COUNT != SIGNER_INDEX
- Must be
DIFF_INTURN
ifBLOCK_NUMBER % SIGNER_COUNT == SIGNER_INDEX
- Must be
Authorizing a block
To authorize a block for the network, the signer needs to sign the block’s sighash containing everything except the signature itself. This means that this hash contains every field of the header (nonce
and mixDigest
included), and also the extraData
with the exception of the 65 byte signature suffix. The fields are hashed in the order of their definition in the yellow paper. Note that this sighash differs from the final block hash which also includes the signature.
The sighash is signed using the standard secp256k1
curve, and the resulting 65 byte signature (R
, S
, V
, where V
is 0
or 1
) is embedded into the extraData
as the trailing 65 byte suffix.
To ensure malicious signers (loss of signing key) cannot wreck havoc in the network, each singer is allowed to sign maximum one out of SIGNER_LIMIT
consecutive blocks. The order is not fixed, but in-turn signing weighs more (DIFF_INTURN
) than out of turn one (DIFF_NOTURN
).
Authorization strategies
As long as signers conform to the above specs, they can authorize and distribute blocks as they see fit. The following suggested strategy will however reduce network traffic and small forks, so it’s a suggested feature:
- If a signer is allowed to sign a block (is on the authorized list and didn’t sign recently).
- Calculate the optimal signing time of the next block (parent +
BLOCK_PERIOD
). - If the signer is in-turn, wait for the exact time to arrive, sign and broadcast immediately.
- If the signer is out-of-turn, delay signing by
rand(SIGNER_COUNT * 500ms)
.
- Calculate the optimal signing time of the next block (parent +
This small strategy will ensure that the in-turn signer (who’s block weighs more) has a slight advantage to sign and propagate versus the out-of-turn signers. Also the scheme allows a bit of scale with the increase of the number of signers.
Voting on signers
Every epoch transition (genesis block included) acts as a stateless checkpoint, from which capable clients should be able to sync without requiring any previous state. This means epoch headers must not contain votes, all non settled votes are discarded, and tallying starts from scratch.
For all non-epoch transition blocks:
- Signers may cast one vote per own block to propose a change to the authorization list.
- Only the latest proposal per target beneficiary is kept from a single signer.
- Votes are tallied live as the chain progresses (concurrent proposals allowed).
- Proposals reaching majority consensus
SIGNER_LIMIT
come into effect immediately. - Invalid proposals are not to be penalized for client implementation simplicity.
A proposal coming into effect entails discarding all pending votes for that proposal (both for and against) and starting with a clean slate.
Cascading votes
A complex corner case may arise during signer deauthorization. When a previously authorized signer is dropped, the number of signers required to approve a proposal might decrease by one. This might cause one or more pending proposals to reach majority consensus, the execution of which might further cascade into new proposals passing.
Handling this scenario is non obvious when multiple conflicting proposals pass simultaneously (e.g. add a new signer vs. drop an existing one), where the evaluation order might drastically change the outcome of the final authorization list. Since signers may invert their own votes in every block they mint, it’s not so obvious which proposal would be “first”.
To avoid the pitfalls cascading executions would entail, the Clique proposal explicitly forbids cascading effects. In other words: Only the beneficiary
of the current header/vote may be added to/dropped from the authorization list. If that causes other proposals to reach consensus, those will be executed when their respective beneficiaries are “touched” again (given that majority consensus still holds at that point).
Voting strategies
Since the blockchain can have small reorgs, a naive voting mechanism of “cast-and-forget” may not be optimal, since a block containing a singleton vote may not end up on the final chain.
A simplistic but working strategy is to allow users to configure “proposals” on the signers (e.g. “add 0x…”, “drop 0x…”). The signing code can then pick a random proposal for every block it signs and inject it. This ensures that multiple concurrent proposals as well as reorgs get eventually noted on the chain.
This list may be expired after a certain number of blocks / epochs, but it’s important to realize that “seeing” a proposal pass doesn’t mean it won’t get reorged, so it should not be immediately dropped when the proposal passes.
测试用例
// block represents a single block signed by a parcitular account, where
// the account may or may not have cast a Clique vote.
type block struct {
signer string // Account that signed this particular block
voted string // Optional value if the signer voted on adding/removing someone
auth bool // Whether the vote was to authorize (or deauthorize)
checkpoint []string // List of authorized signers if this is an epoch block
}
// Define the various voting scenarios to test
tests := []struct {
epoch uint64 // Number of blocks in an epoch (unset = 30000)
signers []string // Initial list of authorized signers in the genesis
blocks []block // Chain of signed blocks, potentially influencing auths
results []string // Final list of authorized signers after all blocks
failure error // Failure if some block is invalid according to the rules
}{
{
// Single signer, no votes cast
signers: []string{"A"},
blocks: []block{
{signer: "A"}
},
results: []string{"A"},
}, {
// Single signer, voting to add two others (only accept first, second needs 2 votes)
signers: []string{"A"},
blocks: []block{
{signer: "A", voted: "B", auth: true},
{signer: "B"},
{signer: "A", voted: "C", auth: true},
},
results: []string{"A", "B"},
}, {
// Two signers, voting to add three others (only accept first two, third needs 3 votes already)
signers: []string{"A", "B"},
blocks: []block{
{signer: "A", voted: "C", auth: true},
{signer: "B", voted: "C", auth: true},
{signer: "A", voted: "D", auth: true},
{signer: "B", voted: "D", auth: true},
{signer: "C"},
{signer: "A", voted: "E", auth: true},
{signer: "B", voted: "E", auth: true},
},
results: []string{"A", "B", "C", "D"},
}, {
// Single signer, dropping itself (weird, but one less cornercase by explicitly allowing this)
signers: []string{"A"},
blocks: []block{
{signer: "A", voted: "A", auth: false},
},
results: []string{},
}, {
// Two signers, actually needing mutual consent to drop either of them (not fulfilled)
signers: []string{"A", "B"},
blocks: []block{
{signer: "A", voted: "B", auth: false},
},
results: []string{"A", "B"},
}, {
// Two signers, actually needing mutual consent to drop either of them (fulfilled)
signers: []string{"A", "B"},
blocks: []block{
{signer: "A", voted: "B", auth: false},
{signer: "B", voted: "B", auth: false},
},
results: []string{"A"},
}, {
// Three signers, two of them deciding to drop the third
signers: []string{"A", "B", "C"},
blocks: []block{
{signer: "A", voted: "C", auth: false},
{signer: "B", voted: "C", auth: false},
},
results: []string{"A", "B"},
}, {
// Four signers, consensus of two not being enough to drop anyone
signers: []string{"A", "B", "C", "D"},
blocks: []block{
{signer: "A", voted: "C", auth: false},
{signer: "B", voted: "C", auth: false},
},
results: []string{"A", "B", "C", "D"},
}, {
// Four signers, consensus of three already being enough to drop someone
signers: []string{"A", "B", "C", "D"},
blocks: []block{
{signer: "A", voted: "D", auth: false},
{signer: "B", voted: "D", auth: false},
{signer: "C", voted: "D", auth: false},
},
results: []string{"A", "B", "C"},
}, {
// Authorizations are counted once per signer per target
signers: []string{"A", "B"},
blocks: []block{
{signer: "A", voted: "C", auth: true},
{signer: "B"},
{signer: "A", voted: "C", auth: true},
{signer: "B"},
{signer: "A", voted: "C", auth: true},
},
results: []string{"A", "B"},
}, {
// Authorizing multiple accounts concurrently is permitted
signers: []string{"A", "B"},
blocks: []block{
{signer: "A", voted: "C", auth: true},
{signer: "B"},
{signer: "A", voted: "D", auth: true},
{signer: "B"},
{signer: "A"},
{signer: "B", voted: "D", auth: true},
{signer: "A"},
{signer: "B", voted: "C", auth: true},
},
results: []string{"A", "B", "C", "D"},
}, {
// Deauthorizations are counted once per signer per target
signers: []string{"A", "B"},
blocks: []block{
{signer: "A", voted: "B", auth: false},
{signer: "B"},
{signer: "A", voted: "B", auth: false},
{signer: "B"},
{signer: "A", voted: "B", auth: false},
},
results: []string{"A", "B"},
}, {
// Deauthorizing multiple accounts concurrently is permitted
signers: []string{"A", "B", "C", "D"},
blocks: []block{
{signer: "A", voted: "C", auth: false},
{signer: "B"},
{signer: "C"},
{signer: "A", voted: "D", auth: false},
{signer: "B"},
{signer: "C"},
{signer: "A"},
{signer: "B", voted: "D", auth: false},
{signer: "C", voted: "D", auth: false},
{signer: "A"},
{signer: "B", voted: "C", auth: false},
},
results: []string{"A", "B"},
}, {
// Votes from deauthorized signers are discarded immediately (deauth votes)
signers: []string{"A", "B", "C"},
blocks: []block{
{signer: "C", voted: "B", auth: false},
{signer: "A", voted: "C", auth: false},
{signer: "B", voted: "C", auth: false},
{signer: "A", voted: "B", auth: false},
},
results: []string{"A", "B"},
}, {
// Votes from deauthorized signers are discarded immediately (auth votes)
signers: []string{"A", "B", "C"},
blocks: []block{
{signer: "C", voted: "D", auth: true},
{signer: "A", voted: "C", auth: false},
{signer: "B", voted: "C", auth: false},
{signer: "A", voted: "D", auth: true},
},
results: []string{"A", "B"},
}, {
// Cascading changes are not allowed, only the account being voted on may change
signers: []string{"A", "B", "C", "D"},
blocks: []block{
{signer: "A", voted: "C", auth: false},
{signer: "B"},
{signer: "C"},
{signer: "A", voted: "D", auth: false},
{signer: "B", voted: "C", auth: false},
{signer: "C"},
{signer: "A"},
{signer: "B", voted: "D", auth: false},
{signer: "C", voted: "D", auth: false},
},
results: []string{"A", "B", "C"},
}, {
// Changes reaching consensus out of bounds (via a deauth) execute on touch
signers: []string{"A", "B", "C", "D"},
blocks: []block{
{signer: "A", voted: "C", auth: false},
{signer: "B"},
{signer: "C"},
{signer: "A", voted: "D", auth: false},
{signer: "B", voted: "C", auth: false},
{signer: "C"},
{signer: "A"},
{signer: "B", voted: "D", auth: false},
{signer: "C", voted: "D", auth: false},
{signer: "A"},
{signer: "C", voted: "C", auth: true},
},
results: []string{"A", "B"},
}, {
// Changes reaching consensus out of bounds (via a deauth) may go out of consensus on first touch
signers: []string{"A", "B", "C", "D"},
blocks: []block{
{signer: "A", voted: "C", auth: false},
{signer: "B"},
{signer: "C"},
{signer: "A", voted: "D", auth: false},
{signer: "B", voted: "C", auth: false},
{signer: "C"},
{signer: "A"},
{signer: "B", voted: "D", auth: false},
{signer: "C", voted: "D", auth: false},
{signer: "A"},
{signer: "B", voted: "C", auth: true},
},
results: []string{"A", "B", "C"},
}, {
// Ensure that pending votes don't survive authorization status changes. This
// corner case can only appear if a signer is quickly added, removed and then
// readded (or the inverse), while one of the original voters dropped. If a
// past vote is left cached in the system somewhere, this will interfere with
// the final signer outcome.
signers: []string{"A", "B", "C", "D", "E"},
blocks: []block{
{signer: "A", voted: "F", auth: true}, // Authorize F, 3 votes needed
{signer: "B", voted: "F", auth: true},
{signer: "C", voted: "F", auth: true},
{signer: "D", voted: "F", auth: false}, // Deauthorize F, 4 votes needed (leave A's previous vote "unchanged")
{signer: "E", voted: "F", auth: false},
{signer: "B", voted: "F", auth: false},
{signer: "C", voted: "F", auth: false},
{signer: "D", voted: "F", auth: true}, // Almost authorize F, 2/3 votes needed
{signer: "E", voted: "F", auth: true},
{signer: "B", voted: "A", auth: false}, // Deauthorize A, 3 votes needed
{signer: "C", voted: "A", auth: false},
{signer: "D", voted: "A", auth: false},
{signer: "B", voted: "F", auth: true}, // Finish authorizing F, 3/3 votes needed
},
results: []string{"B", "C", "D", "E", "F"},
}, {
// Epoch transitions reset all votes to allow chain checkpointing
epoch: 3,
signers: []string{"A", "B"},
blocks: []block{
{signer: "A", voted: "C", auth: true},
{signer: "B"},
{signer: "A", checkpoint: []string{"A", "B"}},
{signer: "B", voted: "C", auth: true},
},
results: []string{"A", "B"},
}, {
// An unauthorized signer should not be able to sign blocks
signers: []string{"A"},
blocks: []block{
{signer: "B"},
},
failure: errUnauthorizedSigner,
}, {
// An authorized signer that signed recently should not be able to sign again
signers: []string{"A", "B"},
blocks []block{
{signer: "A"},
{signer: "A"},
},
failure: errRecentlySigned,
}, {
// Recent signatures should not reset on checkpoint blocks imported in a batch
epoch: 3,
signers: []string{"A", "B", "C"},
blocks: []block{
{signer: "A"},
{signer: "B"},
{signer: "A", checkpoint: []string{"A", "B", "C"}},
{signer: "A"},
},
failure: errRecentlySigned,
},,
}
Implementation
A reference implementation is part of go-ethereum and has been functioning as the consensus engine behind the Rinkeby testnet since April, 2017.
Copyright
Copyright and related rights waived via CC0.
参考文献
Please cite this document as:
Péter Szilágyi, "EIP-225: Clique proof-of-authority consensus protocol," Ethereum Improvement Proposals, no. 225, March 2017. [Online serial]. Available: https://eips.ethereum.org/EIPS/eip-225.