Here we describe the data structures in the Tendermint blockchain and the rules for validating them.
The Tendermint blockchains consists of a short list of basic data types:
Block
Header
Version
BlockID
Time
Data
(for transactions)Commit
and Vote
EvidenceData
and Evidence
A block consists of a header, transactions, votes (the commit), and a list of evidence of malfeasance (ie. signing conflicting votes).
type Block struct {
Header Header
Txs Data
Evidence EvidenceData
LastCommit Commit
}
Note the LastCommit
is the set of votes that committed the last block.
A block header contains metadata about the block and about the consensus, as well as commitments to the data in the current block, the previous block, and the results returned by the application:
type Header struct {
// basic block info
Version Version
ChainID string
Height int64
Time Time
NumTxs int64
TotalTxs int64
// prev block info
LastBlockID BlockID
// hashes of block data
LastCommitHash []byte // commit from validators from the last block
DataHash []byte // Merkle root of transactions
// hashes from the app output from the prev block
ValidatorsHash []byte // validators for the current block
NextValidatorsHash []byte // validators for the next block
ConsensusHash []byte // consensus params for current block
AppHash []byte // state after txs from the previous block
LastResultsHash []byte // root hash of all results from the txs from the previous block
// consensus info
EvidenceHash []byte // evidence included in the block
ProposerAddress []byte // original proposer of the block
Further details on each of these fields is described below.
The Version
contains the protocol version for the blockchain and the
application as two uint64
values:
type Version struct {
Block uint64
App uint64
}
The BlockID
contains two distinct Merkle roots of the block.
The first, used as the block's main hash, is the Merkle root
of all the fields in the header. The second, used for secure gossipping of
the block during consensus, is the Merkle root of the complete serialized block
cut into parts. The BlockID
includes these two hashes, as well as the number of
parts.
type BlockID struct {
Hash []byte
Parts PartsHeader
}
type PartsHeader struct {
Hash []byte
Total int32
}
TODO: link to details of merkle sums.
Tendermint uses the Google.Protobuf.WellKnownTypes.Timestamp format, which uses two integers, one for Seconds and for Nanoseconds.
Data is just a wrapper for a list of transactions, where transactions are arbitrary byte arrays:
type Data struct {
Txs [][]byte
}
Commit is a simple wrapper for a list of votes, with one vote for each validator. It also contains the relevant BlockID:
type Commit struct {
BlockID BlockID
Precommits []Vote
}
NOTE: this will likely change to reduce the commit size by eliminating redundant information - see issue #1648.
A vote is a signed message from a validator for a particular block. The vote includes information about the validator signing it.
type Vote struct {
Type SignedMsgType // byte
Height int64
Round int
Timestamp time.Time
BlockID BlockID
ValidatorAddress Address
ValidatorIndex int
Signature []byte
}
There are two types of votes:
a prevote has vote.Type == 1
and
a precommit has vote.Type == 2
.
Signatures in Tendermint are raw bytes representing the underlying signature. The only signature scheme currently supported for Tendermint validators is ED25519. The signature is the raw 64-byte ED25519 signature.
EvidenceData is a simple wrapper for a list of evidence:
type EvidenceData struct {
Evidence []Evidence
}
Evidence in Tendermint is implemented as an interface.
This means any evidence is encoded using its Amino prefix.
There is currently only a single type, the DuplicateVoteEvidence
.
// amino name: "tendermint/DuplicateVoteEvidence"
type DuplicateVoteEvidence struct {
PubKey PubKey
VoteA Vote
VoteB Vote
}
Here we describe the validation rules for every element in a block. Blocks which do not satisfy these rules are considered invalid.
We abuse notation by using something that looks like Go, supplemented with English.
A statement such as x == y
is an assertion - if it fails, the item is invalid.
We refer to certain globally available objects:
block
is the block under consideration,
prevBlock
is the block
at the previous height,
and state
keeps track of the validator set, the consensus parameters
and other results from the application. At the point when block
is the block under consideration,
the current version of the state
corresponds to the state
after executing transactions from the prevBlock
.
Elements of an object are accessed as expected,
ie. block.Header
.
See here for the definition of state
.
A Header is valid if its corresponding fields are valid.
block.Version.Block == state.Version.Block
block.Version.App == state.Version.App
The block version must match the state version.
len(block.ChainID) < 50
ChainID must be less than 50 bytes.
block.Header.Height > 0
block.Header.Height == prevBlock.Header.Height + 1
The height is an incrementing integer. The first block has block.Header.Height == 1
.
block.Header.Timestamp >= prevBlock.Header.Timestamp + 1 ms
block.Header.Timestamp == MedianTime(block.LastCommit, state.LastValidators)
The block timestamp must be monotonic. It must equal the weighted median of the timestamps of the valid votes in the block.LastCommit.
Note: the timestamp of a vote must be greater by at least one millisecond than that of the block being voted on.
The timestamp of the first block must be equal to the genesis time (since there's no votes to compute the median).
if block.Header.Height == 1 {
block.Header.Timestamp == genesisTime
}
See the section on BFT time for more details.
block.Header.NumTxs == len(block.Txs.Txs)
Number of transactions included in the block.
block.Header.TotalTxs == prevBlock.Header.TotalTxs + block.Header.NumTxs
The cumulative sum of all transactions included in this blockchain.
The first block has block.Header.TotalTxs = block.Header.NumberTxs
.
LastBlockID is the previous block's BlockID:
prevBlockParts := MakeParts(prevBlock, state.LastConsensusParams.BlockGossip.BlockPartSize)
block.Header.LastBlockID == BlockID {
Hash: SimpleMerkleRoot(prevBlock.Header),
PartsHeader{
Hash: SimpleMerkleRoot(prevBlockParts),
Total: len(prevBlockParts),
},
}
Note: it depends on the ConsensusParams,
which are held in the state
and may be updated by the application.
The first block has block.Header.LastBlockID == BlockID{}
.
block.Header.LastCommitHash == SimpleMerkleRoot(block.LastCommit)
Simple Merkle root of the votes included in the block. These are the votes that committed the previous block.
The first block has block.Header.LastCommitHash == []byte{}
block.Header.DataHash == SimpleMerkleRoot(block.Txs.Txs)
Simple Merkle root of the transactions included in the block.
block.ValidatorsHash == SimpleMerkleRoot(state.Validators)
Simple Merkle root of the current validator set that is committing the block.
This can be used to validate the LastCommit
included in the next block.
block.NextValidatorsHash == SimpleMerkleRoot(state.NextValidators)
Simple Merkle root of the next validator set that will be the validator set that commits the next block. This is included so that the current validator set gets a chance to sign the next validator sets Merkle root.
block.ConsensusParamsHash == TMHASH(amino(state.ConsensusParams))
Hash of the amino-encoded consensus parameters.
block.AppHash == state.AppHash
Arbitrary byte array returned by the application after executing and commiting the previous block. It serves as the basis for validating any merkle proofs that comes from the ABCI application and represents the state of the actual application rather than the state of the blockchain itself.
The first block has block.Header.AppHash == []byte{}
.
block.ResultsHash == SimpleMerkleRoot(state.LastResults)
Simple Merkle root of the results of the transactions in the previous block.
The first block has block.Header.ResultsHash == []byte{}
.
block.EvidenceHash == SimpleMerkleRoot(block.Evidence)
Simple Merkle root of the evidence of Byzantine behaviour included in this block.
block.Header.ProposerAddress in state.Validators
Address of the original proposer of the block. Must be a current validator.
Arbitrary length array of arbitrary length byte-arrays.
The first height is an exception - it requires the LastCommit to be empty:
if block.Header.Height == 1 {
len(b.LastCommit) == 0
}
Otherwise, we require:
len(block.LastCommit) == len(state.LastValidators)
talliedVotingPower := 0
for i, vote := range block.LastCommit{
if vote == nil{
continue
}
vote.Type == 2
vote.Height == block.LastCommit.Height()
vote.Round == block.LastCommit.Round()
vote.BlockID == block.LastBlockID
val := state.LastValidators[i]
vote.Verify(block.ChainID, val.PubKey) == true
talliedVotingPower += val.VotingPower
}
talliedVotingPower > (2/3) * TotalVotingPower(state.LastValidators)
Includes one (possibly nil) vote for every current validator. Non-nil votes must be Precommits. All votes must be for the same height and round. All votes must be for the previous block. All votes must have a valid signature from the corresponding validator. The sum total of the voting power of the validators that voted must be greater than 2/3 of the total voting power of the complete validator set.
A vote is a signed message broadcast in the consensus for a particular block at a particular height and round.
When stored in the blockchain or propagated over the network, votes are encoded in Amino.
For signing, votes are represented via CanonicalVote
and also encoded using amino (protobuf compatible) via
Vote.SignBytes
which includes the ChainID
, and uses a different ordering of
the fields.
We define a method Verify
that returns true
if the signature verifies against the pubkey for the SignBytes
using the given ChainID:
func (vote *Vote) Verify(chainID string, pubKey crypto.PubKey) error {
if !bytes.Equal(pubKey.Address(), vote.ValidatorAddress) {
return ErrVoteInvalidValidatorAddress
}
if !pubKey.VerifyBytes(vote.SignBytes(chainID), vote.Signature) {
return ErrVoteInvalidSignature
}
return nil
}
where pubKey.Verify
performs the appropriate digital signature verification of the pubKey
against the given signature and message bytes.
There is currently only one kind of evidence, DuplicateVoteEvidence
.
DuplicateVoteEvidence ev
is valid if
ev.VoteA
and ev.VoteB
can be verified with ev.PubKey
ev.VoteA
and ev.VoteB
have the same Height, Round, Address, Index, Type
ev.VoteA.BlockID != ev.VoteB.BlockID
(block.Height - ev.VoteA.Height) < MAX_EVIDENCE_AGE
Once a block is validated, it can be executed against the state.
The state follows this recursive equation:
state(1) = InitialState
state(h+1) <- Execute(state(h), ABCIApp, block(h))
where InitialState
includes the initial consensus parameters and validator set,
and ABCIApp
is an ABCI application that can return results and changes to the validator
set (TODO). Execute is defined as:
Execute(s State, app ABCIApp, block Block) State {
// Fuction ApplyBlock executes block of transactions against the app and returns the new root hash of the app state,
// modifications to the validator set and the changes of the consensus parameters.
AppHash, ValidatorChanges, ConsensusParamChanges := app.ApplyBlock(block)
return State{
LastResults: abciResponses.DeliverTxResults,
AppHash: AppHash,
LastValidators: state.Validators,
Validators: state.NextValidators,
NextValidators: UpdateValidators(state.NextValidators, ValidatorChanges),
ConsensusParams: UpdateConsensusParams(state.ConsensusParams, ConsensusParamChanges),
}
}