The state contains information whose cryptographic digest is included in block headers, and thus is necessary for validating new blocks. For instance, the validators set and the results of transactions are never included in blocks, but their Merkle roots are - the state keeps track of them.
Note that the State
object itself is an implementation detail, since it is never
included in a block or gossipped over the network, and we never compute
its hash. Thus we do not include here details of how the State
object is
persisted or queried. That said, the types it contains are part of the specification, since
their Merkle roots are included in blocks and their values are used in
validation.
type State struct {
Version Version
LastResults []Result
AppHash []byte
LastValidators []Validator
Validators []Validator
NextValidators []Validator
ConsensusParams ConsensusParams
}
Note there is a hard-coded limit of 10000 validators. This is inherited from the limit on the number of votes in a commit.
type Result struct {
Code uint32
Data []byte
}
Result
is the result of executing a transaction against the application.
It returns a result code and an arbitrary byte array (ie. a return value).
NOTE: the Result needs to be updated to include more fields returned from processing transactions, like gas variables and tags - see issue 1007.
A validator is an active participant in the consensus with a public key and a voting power. Validator's also contain an address field, which is a hash digest of the PubKey.
type Validator struct {
Address []byte
PubKey PubKey
VotingPower int64
}
When hashing the Validator struct, the address is not included, because it is redundant with the pubkey.
The state.Validators
, state.LastValidators
, and state.NextValidators
, must always be sorted by validator address,
so that there is a canonical order for computing the MerkleRoot.
We also define a TotalVotingPower
function, to return the total voting power:
func TotalVotingPower(vals []Validators) int64{
sum := 0
for v := range vals{
sum += v.VotingPower
}
return sum
}
ConsensusParams define various limits for blockchain data structures. Like validator sets, they are set during genesis and can be updated by the application through ABCI. When hashed, only a subset of the params are included, to allow the params to evolve without breaking the header.
type ConsensusParams struct {
Block
Evidence
Validator
}
type hashedParams struct {
BlockMaxBytes int64
BlockMaxGas int64
}
func (params ConsensusParams) Hash() []byte {
SHA256(hashedParams{
BlockMaxBytes: params.Block.MaxBytes,
BlockMaxGas: params.Block.MaxGas,
})
}
type BlockParams struct {
MaxBytes int64
MaxGas int64
TimeIotaMs int64
}
type EvidenceParams struct {
MaxAgeNumBlocks int64
MaxAgeDuration time.Duration
}
type ValidatorParams struct {
PubKeyTypes []string
}
The total size of a block is limited in bytes by the ConsensusParams.Block.MaxBytes
.
Proposed blocks must be less than this size, and will be considered invalid
otherwise.
Blocks should additionally be limited by the amount of "gas" consumed by the transactions in the block, though this is not yet implemented.
The minimal time between consecutive blocks is controlled by the
ConsensusParams.Block.TimeIotaMs
.
For evidence in a block to be valid, it must satisfy:
block.Header.Height - evidence.Height < ConsensusParams.Evidence.MaxAgeNumBlocks
block.Header.Time - evidence.Time < ConsensusParams.Evidence.MaxAgeDuration
Validators from genesis file and ResponseEndBlock
must have pubkeys of type ∈
ConsensusParams.Validator.PubKeyTypes
.