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- # Byzantine Consensus Algorithm
-
- ## Terms
-
- - The network is composed of optionally connected _nodes_. Nodes
- directly connected to a particular node are called _peers_.
- - The consensus process in deciding the next block (at some _height_
- `H`) is composed of one or many _rounds_.
- - `NewHeight`, `Propose`, `Prevote`, `Precommit`, and `Commit`
- represent state machine states of a round. (aka `RoundStep` or
- just "step").
- - A node is said to be _at_ a given height, round, and step, or at
- `(H,R,S)`, or at `(H,R)` in short to omit the step.
- - To _prevote_ or _precommit_ something means to broadcast a [prevote
- vote](https://godoc.org/github.com/tendermint/tendermint/types#Vote)
- or [first precommit
- vote](https://godoc.org/github.com/tendermint/tendermint/types#FirstPrecommit)
- for something.
- - A vote _at_ `(H,R)` is a vote signed with the bytes for `H` and `R`
- included in its [sign-bytes](../blockchain/blockchain.md#vote).
- - _+2/3_ is short for "more than 2/3"
- - _1/3+_ is short for "1/3 or more"
- - A set of +2/3 of prevotes for a particular block or `<nil>` at
- `(H,R)` is called a _proof-of-lock-change_ or _PoLC_ for short.
-
- ## State Machine Overview
-
- At each height of the blockchain a round-based protocol is run to
- determine the next block. Each round is composed of three _steps_
- (`Propose`, `Prevote`, and `Precommit`), along with two special steps
- `Commit` and `NewHeight`.
-
- In the optimal scenario, the order of steps is:
-
- ```
- NewHeight -> (Propose -> Prevote -> Precommit)+ -> Commit -> NewHeight ->...
- ```
-
- The sequence `(Propose -> Prevote -> Precommit)` is called a _round_.
- There may be more than one round required to commit a block at a given
- height. Examples for why more rounds may be required include:
-
- - The designated proposer was not online.
- - The block proposed by the designated proposer was not valid.
- - The block proposed by the designated proposer did not propagate
- in time.
- - The block proposed was valid, but +2/3 of prevotes for the proposed
- block were not received in time for enough validator nodes by the
- time they reached the `Precommit` step. Even though +2/3 of prevotes
- are necessary to progress to the next step, at least one validator
- may have voted `<nil>` or maliciously voted for something else.
- - The block proposed was valid, and +2/3 of prevotes were received for
- enough nodes, but +2/3 of precommits for the proposed block were not
- received for enough validator nodes.
-
- Some of these problems are resolved by moving onto the next round &
- proposer. Others are resolved by increasing certain round timeout
- parameters over each successive round.
-
- ## State Machine Diagram
-
- ```
- +-------------------------------------+
- v |(Wait til `CommmitTime+timeoutCommit`)
- +-----------+ +-----+-----+
- +----------> | Propose +--------------+ | NewHeight |
- | +-----------+ | +-----------+
- | | ^
- |(Else, after timeoutPrecommit) v |
- +-----+-----+ +-----------+ |
- | Precommit | <------------------------+ Prevote | |
- +-----+-----+ +-----------+ |
- |(When +2/3 Precommits for block found) |
- v |
- +--------------------------------------------------------------------+
- | Commit |
- | |
- | * Set CommitTime = now; |
- | * Wait for block, then stage/save/commit block; |
- +--------------------------------------------------------------------+
- ```
-
- # Background Gossip
-
- A node may not have a corresponding validator private key, but it
- nevertheless plays an active role in the consensus process by relaying
- relevant meta-data, proposals, blocks, and votes to its peers. A node
- that has the private keys of an active validator and is engaged in
- signing votes is called a _validator-node_. All nodes (not just
- validator-nodes) have an associated state (the current height, round,
- and step) and work to make progress.
-
- Between two nodes there exists a `Connection`, and multiplexed on top of
- this connection are fairly throttled `Channel`s of information. An
- epidemic gossip protocol is implemented among some of these channels to
- bring peers up to speed on the most recent state of consensus. For
- example,
-
- - Nodes gossip `PartSet` parts of the current round's proposer's
- proposed block. A LibSwift inspired algorithm is used to quickly
- broadcast blocks across the gossip network.
- - Nodes gossip prevote/precommit votes. A node `NODE_A` that is ahead
- of `NODE_B` can send `NODE_B` prevotes or precommits for `NODE_B`'s
- current (or future) round to enable it to progress forward.
- - Nodes gossip prevotes for the proposed PoLC (proof-of-lock-change)
- round if one is proposed.
- - Nodes gossip to nodes lagging in blockchain height with block
- [commits](https://godoc.org/github.com/tendermint/tendermint/types#Commit)
- for older blocks.
- - Nodes opportunistically gossip `HasVote` messages to hint peers what
- votes it already has.
- - Nodes broadcast their current state to all neighboring peers. (but
- is not gossiped further)
-
- There's more, but let's not get ahead of ourselves here.
-
- ## Proposals
-
- A proposal is signed and published by the designated proposer at each
- round. The proposer is chosen by a deterministic and non-choking round
- robin selection algorithm that selects proposers in proportion to their
- voting power (see
- [implementation](https://github.com/tendermint/tendermint/blob/develop/types/validator_set.go)).
-
- A proposal at `(H,R)` is composed of a block and an optional latest
- `PoLC-Round < R` which is included iff the proposer knows of one. This
- hints the network to allow nodes to unlock (when safe) to ensure the
- liveness property.
-
- ## State Machine Spec
-
- ### Propose Step (height:H,round:R)
-
- Upon entering `Propose`: - The designated proposer proposes a block at
- `(H,R)`.
-
- The `Propose` step ends: - After `timeoutProposeR` after entering
- `Propose`. --> goto `Prevote(H,R)` - After receiving proposal block
- and all prevotes at `PoLC-Round`. --> goto `Prevote(H,R)` - After
- [common exit conditions](#common-exit-conditions)
-
- ### Prevote Step (height:H,round:R)
-
- Upon entering `Prevote`, each validator broadcasts its prevote vote.
-
- - First, if the validator is locked on a block since `LastLockRound`
- but now has a PoLC for something else at round `PoLC-Round` where
- `LastLockRound < PoLC-Round < R`, then it unlocks.
- - If the validator is still locked on a block, it prevotes that.
- - Else, if the proposed block from `Propose(H,R)` is good, it
- prevotes that.
- - Else, if the proposal is invalid or wasn't received on time, it
- prevotes `<nil>`.
-
- The `Prevote` step ends: - After +2/3 prevotes for a particular block or
- `<nil>`. -->; goto `Precommit(H,R)` - After `timeoutPrevote` after
- receiving any +2/3 prevotes. --> goto `Precommit(H,R)` - After
- [common exit conditions](#common-exit-conditions)
-
- ### Precommit Step (height:H,round:R)
-
- Upon entering `Precommit`, each validator broadcasts its precommit vote.
-
- - If the validator has a PoLC at `(H,R)` for a particular block `B`, it
- (re)locks (or changes lock to) and precommits `B` and sets
- `LastLockRound = R`. - Else, if the validator has a PoLC at `(H,R)` for
- `<nil>`, it unlocks and precommits `<nil>`. - Else, it keeps the lock
- unchanged and precommits `<nil>`.
-
- A precommit for `<nil>` means "I didn’t see a PoLC for this round, but I
- did get +2/3 prevotes and waited a bit".
-
- The Precommit step ends: - After +2/3 precommits for `<nil>`. -->
- goto `Propose(H,R+1)` - After `timeoutPrecommit` after receiving any
- +2/3 precommits. --> goto `Propose(H,R+1)` - After [common exit
- conditions](#common-exit-conditions)
-
- ### Common exit conditions
-
- - After +2/3 precommits for a particular block. --> goto
- `Commit(H)`
- - After any +2/3 prevotes received at `(H,R+x)`. --> goto
- `Prevote(H,R+x)`
- - After any +2/3 precommits received at `(H,R+x)`. --> goto
- `Precommit(H,R+x)`
-
- ### Commit Step (height:H)
-
- - Set `CommitTime = now()`
- - Wait until block is received. --> goto `NewHeight(H+1)`
-
- ### NewHeight Step (height:H)
-
- - Move `Precommits` to `LastCommit` and increment height.
- - Set `StartTime = CommitTime+timeoutCommit`
- - Wait until `StartTime` to receive straggler commits. --> goto
- `Propose(H,0)`
-
- ## Proofs
-
- ### Proof of Safety
-
- Assume that at most -1/3 of the voting power of validators is byzantine.
- If a validator commits block `B` at round `R`, it's because it saw +2/3
- of precommits at round `R`. This implies that 1/3+ of honest nodes are
- still locked at round `R' > R`. These locked validators will remain
- locked until they see a PoLC at `R' > R`, but this won't happen because
- 1/3+ are locked and honest, so at most -2/3 are available to vote for
- anything other than `B`.
-
- ### Proof of Liveness
-
- If 1/3+ honest validators are locked on two different blocks from
- different rounds, a proposers' `PoLC-Round` will eventually cause nodes
- locked from the earlier round to unlock. Eventually, the designated
- proposer will be one that is aware of a PoLC at the later round. Also,
- `timeoutProposalR` increments with round `R`, while the size of a
- proposal are capped, so eventually the network is able to "fully gossip"
- the whole proposal (e.g. the block & PoLC).
-
- ### Proof of Fork Accountability
-
- Define the JSet (justification-vote-set) at height `H` of a validator
- `V1` to be all the votes signed by the validator at `H` along with
- justification PoLC prevotes for each lock change. For example, if `V1`
- signed the following precommits: `Precommit(B1 @ round 0)`,
- `Precommit(<nil> @ round 1)`, `Precommit(B2 @ round 4)` (note that no
- precommits were signed for rounds 2 and 3, and that's ok),
- `Precommit(B1 @ round 0)` must be justified by a PoLC at round 0, and
- `Precommit(B2 @ round 4)` must be justified by a PoLC at round 4; but
- the precommit for `<nil>` at round 1 is not a lock-change by definition
- so the JSet for `V1` need not include any prevotes at round 1, 2, or 3
- (unless `V1` happened to have prevoted for those rounds).
-
- Further, define the JSet at height `H` of a set of validators `VSet` to
- be the union of the JSets for each validator in `VSet`. For a given
- commit by honest validators at round `R` for block `B` we can construct
- a JSet to justify the commit for `B` at `R`. We say that a JSet
- _justifies_ a commit at `(H,R)` if all the committers (validators in the
- commit-set) are each justified in the JSet with no duplicitous vote
- signatures (by the committers).
-
- - **Lemma**: When a fork is detected by the existence of two
- conflicting [commits](../blockchain/blockchain.md#commit), the
- union of the JSets for both commits (if they can be compiled) must
- include double-signing by at least 1/3+ of the validator set.
- **Proof**: The commit cannot be at the same round, because that
- would immediately imply double-signing by 1/3+. Take the union of
- the JSets of both commits. If there is no double-signing by at least
- 1/3+ of the validator set in the union, then no honest validator
- could have precommitted any different block after the first commit.
- Yet, +2/3 did. Reductio ad absurdum.
-
- As a corollary, when there is a fork, an external process can determine
- the blame by requiring each validator to justify all of its round votes.
- Either we will find 1/3+ who cannot justify at least one of their votes,
- and/or, we will find 1/3+ who had double-signed.
-
- ### Alternative algorithm
-
- Alternatively, we can take the JSet of a commit to be the "full commit".
- That is, if light clients and validators do not consider a block to be
- committed unless the JSet of the commit is also known, then we get the
- desirable property that if there ever is a fork (e.g. there are two
- conflicting "full commits"), then 1/3+ of the validators are immediately
- punishable for double-signing.
-
- There are many ways to ensure that the gossip network efficiently share
- the JSet of a commit. One solution is to add a new message type that
- tells peers that this node has (or does not have) a +2/3 majority for B
- (or) at (H,R), and a bitarray of which votes contributed towards that
- majority. Peers can react by responding with appropriate votes.
-
- We will implement such an algorithm for the next iteration of the
- Tendermint consensus protocol.
-
- Other potential improvements include adding more data in votes such as
- the last known PoLC round that caused a lock change, and the last voted
- round/step (or, we may require that validators not skip any votes). This
- may make JSet verification/gossip logic easier to implement.
-
- ### Censorship Attacks
-
- Due to the definition of a block
- [commit](../../tendermint-core/validators.md#commit-a-block), any 1/3+ coalition of
- validators can halt the blockchain by not broadcasting their votes. Such
- a coalition can also censor particular transactions by rejecting blocks
- that include these transactions, though this would result in a
- significant proportion of block proposals to be rejected, which would
- slow down the rate of block commits of the blockchain, reducing its
- utility and value. The malicious coalition might also broadcast votes in
- a trickle so as to grind blockchain block commits to a near halt, or
- engage in any combination of these attacks.
-
- If a global active adversary were also involved, it can partition the
- network in such a way that it may appear that the wrong subset of
- validators were responsible for the slowdown. This is not just a
- limitation of Tendermint, but rather a limitation of all consensus
- protocols whose network is potentially controlled by an active
- adversary.
-
- ### Overcoming Forks and Censorship Attacks
-
- For these types of attacks, a subset of the validators through external
- means should coordinate to sign a reorg-proposal that chooses a fork
- (and any evidence thereof) and the initial subset of validators with
- their signatures. Validators who sign such a reorg-proposal forego its
- collateral on all other forks. Clients should verify the signatures on
- the reorg-proposal, verify any evidence, and make a judgement or prompt
- the end-user for a decision. For example, a phone wallet app may prompt
- the user with a security warning, while a refrigerator may accept any
- reorg-proposal signed by +1/2 of the original validators.
-
- No non-synchronous Byzantine fault-tolerant algorithm can come to
- consensus when 1/3+ of validators are dishonest, yet a fork assumes that
- 1/3+ of validators have already been dishonest by double-signing or
- lock-changing without justification. So, signing the reorg-proposal is a
- coordination problem that cannot be solved by any non-synchronous
- protocol (i.e. automatically, and without making assumptions about the
- reliability of the underlying network). It must be provided by means
- external to the weakly-synchronous Tendermint consensus algorithm. For
- now, we leave the problem of reorg-proposal coordination to human
- coordination via internet media. Validators must take care to ensure
- that there are no significant network partitions, to avoid situations
- where two conflicting reorg-proposals are signed.
-
- Assuming that the external coordination medium and protocol is robust,
- it follows that forks are less of a concern than [censorship
- attacks](#censorship-attacks).
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