This section specifies what CometBFT expects from the Application. It is structured as a set of formal requirements that can be used for testing and verification of the Application’s logic.
Let p and q be two correct processes.
Let rp (resp. rq) be a round of height h where p (resp. q) is the
proposer.
Let sp,h-1 be p’s Application’s state committed for height h-1.
Let vp (resp. vq) be the block that p’s (resp. q’s) CometBFT passes
on to the Application
via PrepareProposalRequest
as proposer of round rp (resp rq), height h,
also known as the raw proposal.
Let up (resp. uq) the possibly modified block p’s (resp. q’s) Application
returns via PrepareProposalResponse
to CometBFT, also known as the prepared proposal.
Process p’s prepared proposal can differ in two different rounds where p is the proposer.
PrepareProposal
, timeliness]: If p’s Application fully executes prepared blocks in
PrepareProposal
and the network is in a synchronous period while processes p and q are in rp,
then the value of TimeoutPropose at q must be such that q’s propose timer does not time out
(which would result in q prevoting nil
in rp).Full execution of blocks at PrepareProposal
time stands on CometBFT’s critical path. Thus,
Requirement 1 ensures the Application or operator will set a value for TimeoutPropose
such that the time it takes
to fully execute blocks in PrepareProposal
does not interfere with CometBFT’s propose timer.
Note that the violation of Requirement 1 may lead to further rounds, but will not
compromise liveness because even though TimeoutPropose
is used as the initial
value for proposal timeouts, CometBFT will be dynamically adjust these timeouts
such that they will eventually be enough for completing PrepareProposal
.
PrepareProposal
, tx-size]: When p’s Application calls PrepareProposal
, the
total size in bytes of the transactions returned does not exceed PrepareProposalRequest.max_tx_bytes
.Busy blockchains might seek to gain full visibility into transactions in CometBFT’s mempool,
rather than having visibility only on a subset of those transactions that fit in a block.
The application can do so by setting ConsensusParams.Block.MaxBytes
to -1.
This instructs CometBFT (a) to enforce the maximum possible value for MaxBytes
(100 MB) at CometBFT level,
and (b) to provide all transactions in the mempool when calling PrepareProposal
.
Under these settings, the aggregated size of all transactions may exceed PrepareProposalRequest.max_tx_bytes
.
Hence, Requirement 2 ensures that the size in bytes of the transaction list returned by the application will never
cause the resulting block to go beyond its byte size limit.
PrepareProposal
, ProcessProposal
, coherence]: For any two correct processes p and q,
if q’s CometBFT calls ProcessProposal
on up,
q’s Application returns Accept in ProcessProposalResponse
.Requirement 3 makes sure that blocks proposed by correct processes always pass the correct receiving process’s
ProcessProposal
check.
On the other hand, if there is a deterministic bug in PrepareProposal
or ProcessProposal
(or in both),
strictly speaking, this makes all processes that hit the bug byzantine. This is a problem in practice,
as very often validators are running the Application from the same codebase, so potentially all would
likely hit the bug at the same time. This would result in most (or all) processes prevoting nil
, with the
serious consequences on CometBFT’s liveness that this entails. Due to its criticality, Requirement 3 is a
target for extensive testing and automated verification.
Requirement 4 [ProcessProposal
, determinism-1]: ProcessProposal
is a (deterministic) function of the current
state and the block that is about to be applied. In other words, for any correct process p, and any arbitrary block u,
if p’s CometBFT calls ProcessProposal
on u at height h,
then p’s Application’s acceptance or rejection exclusively depends on u and sp,h-1.
Requirement 5 [ProcessProposal
, determinism-2]: For any two correct processes p and q, and any arbitrary
block u,
if p’s (resp. q’s) CometBFT calls ProcessProposal
on u at height h,
then p’s Application accepts u if and only if q’s Application accepts u.
Note that this requirement follows from Requirement 4 and the Agreement property of consensus.
Requirements 4 and 5 ensure that all correct processes will react in the same way to a proposed block, even
if the proposer is Byzantine. However, ProcessProposal
may contain a bug that renders the
acceptance or rejection of the block non-deterministic, and therefore prevents processes hitting
the bug from fulfilling Requirements 4 or 5 (effectively making those processes Byzantine).
In such a scenario, CometBFT’s liveness cannot be guaranteed.
Again, this is a problem in practice if most validators are running the same software, as they are likely
to hit the bug at the same point. There is currently no clear solution to help with this situation, so
the Application designers/implementers must proceed very carefully with the logic/implementation
of ProcessProposal
. As a general rule ProcessProposal
SHOULD always accept the block.
According to the Tendermint consensus algorithm, currently adopted in CometBFT,
a correct process can broadcast at most one precommit
message in round r, height h.
Since, as stated in the Methods section, ExtendVote
is only called when the consensus algorithm
is about to broadcast a non-nil
precommit message, a correct process can only produce one vote extension
in round r, height h.
Let erp be the vote extension that the Application of a correct process p returns via
ExtendVoteResponse
in round r, height h.
Let wrp be the proposed block that p’s CometBFT passes to the Application via ExtendVoteRequest
in round r, height h.
ExtendVote
, VerifyVoteExtension
, coherence]: For any two different correct
processes p and q, if q receives erp from p in height h, q’s
Application returns Accept in VerifyVoteExtensionResponse
.Requirement 6 constrains the creation and handling of vote extensions in a similar way as Requirement 3
constrains the creation and handling of proposed blocks.
Requirement 6 ensures that extensions created by correct processes always pass the VerifyVoteExtension
checks performed by correct processes receiving those extensions.
However, if there is a (deterministic) bug in ExtendVote
or VerifyVoteExtension
(or in both),
we will face the same liveness issues as described for Requirement 5, as Precommit messages with invalid vote
extensions will be discarded.
Requirement 7 [VerifyVoteExtension
, determinism-1]: VerifyVoteExtension
is a (deterministic) function of
the current state, the vote extension received, and the prepared proposal that the extension refers to.
In other words, for any correct process p, and any arbitrary vote extension e, and any arbitrary
block w, if p’s (resp. q’s) CometBFT calls VerifyVoteExtension
on e and w at height h,
then p’s Application’s acceptance or rejection exclusively depends on e, w and sp,h-1.
Requirement 8 [VerifyVoteExtension
, determinism-2]: For any two correct processes p and q,
and any arbitrary vote extension e, and any arbitrary block w,
if p’s (resp. q’s) CometBFT calls VerifyVoteExtension
on e and w at height h,
then p’s Application accepts e if and only if q’s Application accepts e.
Note that this requirement follows from Requirement 7 and the Agreement property of consensus.
Requirements 7 and 8 ensure that the validation of vote extensions will be deterministic at all
correct processes.
Requirements 7 and 8 protect against arbitrary vote extension data from Byzantine processes,
in a similar way as Requirements 4 and 5 protect against arbitrary proposed blocks.
Requirements 7 and 8 can be violated by a bug inducing non-determinism in
VerifyVoteExtension
. In this case liveness can be compromised.
Extra care should be put in the implementation of ExtendVote
and VerifyVoteExtension
.
As a general rule, VerifyVoteExtension
SHOULD always accept the vote extension.
Requirement 9 [all, no-side-effects]: p’s calls to PrepareProposal
,
ProcessProposal
, ExtendVote
, and VerifyVoteExtension
at height h do
not modify sp,h-1.
Requirement 10 [ExtendVote
, FinalizeBlock
, non-dependency]: for any correct process p,
and any vote extension e that p received at height h, the computation of
sp,h does not depend on e.
The call to correct process p’s FinalizeBlock
at height h, with block vp,h
passed as parameter, creates state sp,h.
Additionally, p’s FinalizeBlock
creates a set of transaction results Tp,h.
Requirement 11 [FinalizeBlock
, determinism-1]: For any correct process p,
sp,h exclusively depends on sp,h-1 and vp,h.
Requirement 12 [FinalizeBlock
, determinism-2]: For any correct process p,
the contents of Tp,h exclusively depend on sp,h-1 and vp,h.
Note that Requirements 11 and 12, combined with the Agreement property of consensus ensure state machine replication, i.e., the Application state evolves consistently at all correct processes.
Also, notice that neither PrepareProposal
nor ExtendVote
have determinism-related
requirements associated.
Indeed, PrepareProposal
is not required to be deterministic:
Likewise, ExtendVote
can also be non-deterministic:
Let CheckTxCodestx,p,h denote the set of result codes returned by p’s Application,
via CheckTxResponse
,
to successive calls to CheckTx
occurring while the Application is at height h
and having transaction tx as parameter.
CheckTxCodestx,p,h is a set since p’s Application may
return different result codes during height h.
If CheckTxCodestx,p,h is a singleton set, i.e. the Application always returned
the same result code in CheckTxResponse
while at height h,
we define CheckTxCodetx,p,h as the singleton value of CheckTxCodestx,p,h.
If CheckTxCodestx,p,h is not a singleton set, CheckTxCodetx,p,h is undefined.
Let predicate OK(CheckTxCodetx,p,h) denote whether CheckTxCodetx,p,h is SUCCESS
.
CheckTx
, eventual non-oscillation]: For any transaction tx,
there exists a boolean value b,
and a height hstable such that,
for any correct process p,
CheckTxCodetx,p,h is defined, and
OK(CheckTxCodetx,p,h) = b
for any height h ≥ hstable.Requirement 13 ensures that
a transaction will eventually stop oscillating between CheckTx
success and failure
if it stays in p’s mempool for long enough.
This condition on the Application’s behavior allows the mempool to ensure that
a transaction will leave the mempool of all full nodes,
either because it is expunged everywhere due to failing CheckTx
calls,
or because it stays valid long enough to be gossipped, proposed and decided.
Although Requirement 13 defines a global hstable, application developers
can consider such stabilization height as local to process p (hp,stable),
without loss for generality.
In contrast, the value of b MUST be the same across all processes.
CometBFT maintains four concurrent ABCI connections, namely
Consensus Connection,
Mempool Connection,
Info/Query Connection, and
Snapshot Connection.
It is common for an application to maintain a distinct copy of
the state for each connection, which are synchronized upon Commit
calls.
In principle, each of the four ABCI connections operates concurrently with one
another. This means applications need to ensure access to state is
thread safe. Both the
default in-process ABCI client
and the
default Go ABCI server
use a global lock to guard the handling of events across all connections, so they are not
concurrent at all. This means whether your app is compiled in-process with
CometBFT using the NewLocalClient
, or run out-of-process using the SocketServer
,
ABCI messages from all connections are received in sequence, one at a
time.
The existence of this global mutex means Go application developers can get thread safety for application state by routing all reads and writes through the ABCI system. Thus it may be unsafe to expose application state directly to an RPC interface, and unless explicit measures are taken, all queries should be routed through the ABCI Query method.
When the consensus algorithm decides on a block, CometBFT uses FinalizeBlock
to send the
decided block’s data to the Application, which uses it to transition its state, but MUST NOT persist it;
persisting MUST be done during Commit
.
The Application must remember the latest height from which it
has run a successful Commit
so that it can tell CometBFT where to
pick up from when it recovers from a crash. See information on the Handshake
here.
The Application should persist its state during Commit
, before returning from it.
Before invoking Commit
, CometBFT locks the mempool and flushes the mempool connection. This ensures that
no new messages
will be received on the mempool connection during this processing step, providing an opportunity to safely
update all four
connection states to the latest committed state at the same time.
CometBFT unlocks the mempool after it has finished updating for the new block,
which occurs asynchronously from Commit
.
See Mempool Update for more information on what the update
task does.
WARNING: if the ABCI app logic processing the Commit
message sends a
/broadcast_tx_sync
or /broadcast_tx
and waits for the response
before proceeding, it will deadlock. Executing broadcast_tx
calls
involves acquiring the mempool lock that CometBFT holds during the Commit
call.
Synchronous mempool-related calls must be avoided as part of the sequential logic of the
Commit
function.
CometBFT calls PrepareProposal
when it is about to send a proposed block to the network.
Likewise, CometBFT calls ProcessProposal
upon reception of a proposed block from the
network. The proposed block’s data
that is disclosed to the Application by these two methods is the following:
LastCommit
referring to the previous blockPrepareProposal
, where it is not known yet)NextValidatorsHash
The Application may decide to immediately execute the given block (i.e., upon PrepareProposal
or ProcessProposal
). There are two main reasons why the Application may want to do this:
FinalizeBlock
execution.
Upon reception of the decided block via FinalizeBlock
, if that same block was executed
upon PrepareProposal
or ProcessProposal
and the resulting state was kept in memory, the
Application can simply apply that state (faster) to the main state, rather than reexecuting
the decided block (slower).PrepareProposal
/ProcessProposal
can be called many times for a given height. Moreover,
it is not possible to accurately predict which of the blocks proposed in a height will be decided,
being delivered to the Application in that height’s FinalizeBlock
.
Therefore, the state resulting from executing a proposed block, denoted a candidate state, should
be kept in memory as a possible final state for that height. When FinalizeBlock
is called, the Application should
check if the decided block corresponds to one of its candidate states; if so, it will apply it as
its ExecuteTxState (see Consensus Connection below),
which will be persisted during the upcoming Commit
call.
Under adverse conditions (e.g., network instability), the consensus algorithm might take many rounds.
In this case, potentially many proposed blocks will be disclosed to the Application for a given height.
By the nature of Tendermint consensus algorithm, currently adopted in CometBFT, the number of proposed blocks received by the Application
for a particular height cannot be bound, so Application developers must act with care and use mechanisms
to bound memory usage. As a general rule, the Application should be ready to discard candidate states
before FinalizeBlock
, even if one of them might end up corresponding to the
decided block and thus have to be reexecuted upon FinalizeBlock
.
The Consensus Connection should maintain an ExecuteTxState — the working state
for block execution. It should be updated by the call to FinalizeBlock
during block execution and committed to disk as the “latest
committed state” during Commit
. Execution of a proposed block (via PrepareProposal
/ProcessProposal
)
must not update the ExecuteTxState, but rather be kept as a separate candidate state until FinalizeBlock
confirms which of the candidate states (if any) can be used to update ExecuteTxState.
The mempool Connection maintains CheckTxState. CometBFT sequentially processes an incoming
transaction (via RPC from client or P2P from the gossip layer) against CheckTxState.
If the processing does not return any error, the transaction is accepted into the mempool
and CometBFT starts gossipping it.
CheckTxState should be reset to the latest committed state
at the end of every Commit
.
During the execution of a consensus instance, the CheckTxState may be updated concurrently with the
ExecuteTxState, as messages may be sent concurrently on the Consensus and Mempool connections.
At the end of the consensus instance, as described above, CometBFT locks the mempool and flushes
the mempool connection before calling Commit
. This ensures that all pending CheckTx
calls are
responded to and no new ones can begin.
After the Commit
call returns, while still holding the mempool lock, CheckTx
is run again on all
transactions that remain in the node’s local mempool after filtering those included in the block.
Parameter Type
in CheckTxRequest
indicates whether an incoming transaction is new (CHECK_TX_TYPE_NEW
), or a
recheck (CHECK_TX_TYPE_RECHECK
).
Finally, after re-checking transactions in the mempool, CometBFT will unlock
the mempool connection. New transactions are once again able to be processed through CheckTx
.
Note that CheckTx
is just a weak filter to keep invalid transactions out of the mempool and,
ultimately, ouf of the blockchain.
Since the transaction cannot be guaranteed to be checked against the exact same state as it
will be executed as part of a (potential) decided block, CheckTx
shouldn’t check everything
that affects the transaction’s validity, in particular those checks whose validity may depend on
transaction ordering. CheckTx
is weak because a Byzantine node need not care about CheckTx
;
it can propose a block full of invalid transactions if it wants. The mechanism ABCI, from version 1.0, has
in place for dealing with such behavior is ProcessProposal
.
It is possible for old transactions to be sent again to the Application. This is typically undesirable for all transactions, except for a generally small subset of them which are idempotent.
The mempool has a mechanism to prevent duplicated transactions from being processed.
This mechanism is nevertheless best-effort (currently based on the indexer)
and does not provide any guarantee of non duplication.
It is thus up to the Application to implement an application-specific
replay protection mechanism with strong guarantees as part of the logic in CheckTx
.
The Info (or Query) Connection should maintain a QueryState
. This connection has two
purposes: 1) having the application answer the queries CometBFT receives from users
(see section Query),
and 2) synchronizing CometBFT and the Application at start up time (see
Crash Recovery)
or after state sync (see State Sync).
QueryState
is a read-only copy of ExecuteTxState as it was after the last
Commit
, i.e.
after the full block has been processed and the state committed to disk.
The Snapshot Connection is used to serve state sync snapshots for other nodes and/or restore state sync snapshots to a local node being bootstrapped. Snapshot management is optional: an Application may choose not to implement it.
For more information, see Section State Sync.
The Application is expected to return a list of
ExecTxResult
in
FinalizeBlockResponse
. The list of transaction
results MUST respect the same order as the list of transactions delivered via
FinalizeBlockRequest
.
This section discusses the fields inside this structure, along with the fields in
CheckTxResponse
,
whose semantics are similar.
The Info
and Log
fields are
non-deterministic values for debugging/convenience purposes. CometBFT logs them but they
are otherwise ignored.
Ethereum introduced the notion of gas as an abstract representation of the cost of the resources consumed by nodes when processing a transaction. Every operation in the Ethereum Virtual Machine uses some amount of gas. Gas has a market-variable price based on which miners can accept or reject to execute a particular operation.
Users propose a maximum amount of gas for their transaction; if the transaction uses less, they get the difference credited back. CometBFT adopts a similar abstraction, though uses it only optionally and weakly, allowing applications to define their own sense of the cost of execution.
In CometBFT, the ConsensusParams.Block.MaxGas limits the amount of
total gas that can be used by all transactions in a block.
The default value is -1
, which means the block gas limit is not enforced, or that the concept of
gas is meaningless.
Responses contain a GasWanted
and GasUsed
field. The former is the maximum
amount of gas the sender of a transaction is willing to use, and the latter is how much it actually
used. Applications should enforce that GasUsed <= GasWanted
— i.e. transaction execution
or validation should fail before it can use more resources than it requested.
When MaxGas > -1
, CometBFT enforces the following rules:
GasWanted <= MaxGas
for every transaction in the mempool(sum of GasWanted in a block) <= MaxGas
when proposing a blockIf MaxGas == -1
, no rules about gas are enforced.
In v0.34.x and earlier versions, CometBFT does not enforce anything about Gas in consensus,
only in the mempool.
This means it does not guarantee that committed blocks satisfy these rules.
It is the application’s responsibility to return non-zero response codes when gas limits are exceeded
when executing the transactions of a block.
Since the introduction of PrepareProposal
and ProcessProposal
in v.0.37.x, it is now possible
for the Application to enforce that all blocks proposed (and voted for) in consensus — and thus all
blocks decided — respect the MaxGas
limits described above.
Since the Application should enforce that GasUsed <= GasWanted
when executing a transaction, and
it can use PrepareProposal
and ProcessProposal
to enforce that (sum of GasWanted in a block) <= MaxGas
in all proposed or prevoted blocks,
we have:
(sum of GasUsed in a block) <= MaxGas
for every blockThe GasUsed
field is ignored by CometBFT.
CheckTxResponse
If Code != 0
, it will be rejected from the mempool and hence
not broadcasted to other peers and not included in a proposal block.
Data
contains the result of the CheckTx
transaction execution, if any. It does not need to be
deterministic since, given a transaction, nodes’ Applications
might have a different CheckTxState values when they receive it and check their validity
via CheckTx
.
CometBFT ignores this value in CheckTxResponse
.
From v0.34.x on, there is a Priority
field in CheckTxResponse
that can be
used to explicitly prioritize transactions in the mempool for inclusion in a block
proposal.
ExecTxResult
FinalizeBlock
is the workhorse of the blockchain. CometBFT delivers the decided block,
including the list of all its transactions synchronously to the Application.
The block delivered (and thus the transaction order) is the same at all correct nodes as guaranteed
by the Agreement property of consensus.
The Data
field in ExecTxResult
contains an array of bytes with the transaction result.
It must be deterministic (i.e., the same value must be returned at all nodes), but it can contain arbitrary
data. Likewise, the value of Code
must be deterministic.
If Code != 0
, the transaction will be marked invalid,
though it is still included in the block. Invalid transactions are not indexed, as they are
considered analogous to those that failed CheckTx
.
Both the Code
and Data
are included in a structure that is hashed into the
LastResultsHash
of the block header in the next height.
Events
include any events for the execution, which CometBFT will use to index
the transaction by. This allows transactions to be queried according to what
events took place during their execution.
The application may set the validator set during
InitChain
, and may update it during
FinalizeBlock
. In both cases, a structure of type
ValidatorUpdate
is returned.
The InitChain
method, used to initialize the Application, can return a list of validators.
If the list is empty, CometBFT will use the validators loaded from the genesis
file.
If the list returned by InitChain
is not empty, CometBFT will use its contents as the validator set.
This way the application can set the initial validator set for the
blockchain.
Applications must ensure that a single set of validator updates does not contain duplicates, i.e. a given public key can only appear once within a given update. If an update includes duplicates, the block execution will fail irrecoverably.
Structure ValidatorUpdate
contains a public key, which is used to identify the validator:
The public key currently supports three types:
ed25519
secp256k1
bls12381
Structure ValidatorUpdate
also contains an ìnt64
field denoting the validator’s new power.
Applications must ensure that
ValidatorUpdate
structures abide by the following rules:
MaxTotalVotingPower
, where
MaxTotalVotingPower = MaxInt64 / 8
Note the updates returned after processing the block at height H
will only take effect
at block H+2
(see Section Methods).
ConsensusParams
are global parameters that apply to all validators in a blockchain.
They enforce certain limits in the blockchain, like the maximum size
of blocks, amount of gas used in a block, and the maximum acceptable age of
evidence. They can be set in
InitChain
, and updated in
FinalizeBlock
.
These parameters are deterministically set and/or updated by the Application, so
all full nodes have the same value at a given height.
These are the current consensus parameters (as of v1.0.x):
The maximum size of a complete Protobuf encoded block. This is enforced by the consensus algorithm.
This implies a maximum transaction size that is this MaxBytes
, less the expected size of
the header, the validator set, and any included evidence in the block.
The Application should be aware that honest validators may produce and
broadcast blocks with up to the configured MaxBytes
size.
As a result, the consensus
timeout parameters
adopted by nodes should be configured so as to account for the worst-case
latency for the delivery of a full block with MaxBytes
size to all validators.
If the Application wants full control over the size of blocks,
it can do so by enforcing a byte limit set up at the Application level.
This Application-internal limit is used by PrepareProposal
to bound the total size
of transactions it returns, and by ProcessProposal
to reject any received block
whose total transaction size is bigger than the enforced limit.
In such case, the Application MAY set MaxBytes
to -1.
If the Application sets value -1, consensus will:
PrepareProposal
Must have MaxBytes == -1
OR 0 < MaxBytes <= 100 MB
.
Bear in mind that the default value for the
BlockParams.MaxBytes
consensus parameter accepts as valid blocks with size up to 21 MB. If the Application’s use case does not need blocks of that size, or if the impact (specially on bandwidth consumption and block latency) of propagating blocks of that size was not evaluated, it is strongly recommended to wind down this default value.
The maximum of the sum of GasWanted
that will be allowed in a proposed block.
This is not enforced by the consensus algorithm.
It is left to the Application to enforce (ie. if transactions are included past the
limit, they should return non-zero codes). It is used by CometBFT to limit the
transactions included in a proposed block.
Must have MaxGas >= -1
.
If MaxGas == -1
, no limit is enforced.
This is the maximum age of evidence in time units. This is enforced by the consensus algorithm.
If a block includes evidence older than this (AND the evidence was created more
than MaxAgeNumBlocks
ago), the block will be rejected (validators won’t vote
for it).
Must have MaxAgeDuration > 0
.
This is the maximum age of evidence in blocks. This is enforced by the consensus algorithm.
If a block includes evidence older than this (AND the evidence was created more
than MaxAgeDuration
ago), the block will be rejected (validators won’t vote
for it).
Must have MaxAgeNumBlocks > 0
.
This is the maximum size of total evidence in bytes that can be committed to a single block. It should fall comfortably under the max block bytes.
Its value must not exceed the size of
a block minus its overhead ( ~ BlockParams.MaxBytes
).
Must have MaxBytes > 0
.
Height at which Proposer-Based Timestamps (PBTS) will be enabled.
A value of 0 means that PBTS is disabled. A value > 0 denotes the height at which PBTS will be (or has been) enabled.
From the specified height, and for all subsequent heights, the PBTS algorithm will be used to produce and validate block timestamps. Prior to this height, or when this height is set to 0, the legacy BFT Time algorithm is used to produce and validate timestamps.
PBTS cannot be disabled once it is enabled.
Cannot be set to heights lower or equal to the current blockchain height.
Must have PbtsEnableHeight > [Current height]
This parameter is either 0 or a positive height at which vote extensions
become mandatory. If the value is zero (which is the default), vote
extensions are disabled, and are therefore precommit messages received
from other nodes are not expected to contain vote extensions.
If the value is greater than zero, at all heights greater than the
configured height H
vote extensions must be present (even if empty).
When the configured height H
is reached, PrepareProposal
will not
include vote extensions yet, but ExtendVote
and VerifyVoteExtension
will
be called. Then, when reaching height H+1
, PrepareProposal
will
include the vote extensions from height H
. For all heights after H
Must always be set to a future height, 0, or the same height that was previously set. Once the chain’s height reaches the value set, it cannot be changed to a different value.
The parameter restricts the type of keys validators can use. The parameter uses ABCI pubkey naming, not Amino names.
This is the version of the ABCI application.
This sets a bound on how skewed a proposer’s clock may be from any validator on the network while still producing valid proposals.
This parameter is used by the Proposer-Based Timestamps (PBTS) algorithm.
This sets a bound on how long a proposal message may take to reach all validators on a network and still be considered valid.
This parameter is used by the Proposer-Based Timestamps (PBTS) algorithm.
The application may set the ConsensusParams
during
InitChain
,
and update them during
FinalizeBlock
.
If the ConsensusParams
is empty, it will be ignored. Each field
that is not empty will be applied in full. For instance, if updating the
Block.MaxBytes
, applications must also set the other Block
fields (like
Block.MaxGas
), even if they are unchanged, as they will otherwise cause the
value to be updated to the default.
InitChain
InitChainResponse
includes a ConsensusParams
parameter.
If ConsensusParams
is nil
, CometBFT will use the params loaded in the genesis
file. If ConsensusParams
is not nil
, CometBFT will use it.
This way the application can determine the initial consensus parameters for the
blockchain.
FinalizeBlock
, PrepareProposal
/ProcessProposal
FinalizeBlockResponse
accepts a ConsensusParams
parameter.
If ConsensusParams
is nil
, CometBFT will do nothing.
If ConsensusParams
is not nil
, CometBFT will use it.
This way the application can update the consensus parameters over time.
The updates returned in block H
will take effect right away for block
H+1
.
Query
Query
is a generic method with lots of flexibility to enable diverse sets
of queries on application state. CometBFT makes use of Query
to filter new peers
based on ID and IP, and exposes Query
to the user over RPC.
Note that calls to Query
are not replicated across nodes, but rather query the
local node’s state - hence they may return stale reads. For reads that require
consensus, use a transaction.
The most important use of Query
is to return Merkle proofs of the application state at some height
that can be used for efficient application-specific light-clients.
Note CometBFT has technically no requirements from the Query
message for normal operation - that is, the ABCI app developer need not implement
Query functionality if they do not wish to.
The CometBFT block header includes a number of hashes, each providing an
anchor for some type of proof about the blockchain. The ValidatorsHash
enables
quick verification of the validator set, the DataHash
gives quick
verification of the transactions included in the block.
The AppHash
is unique in that it is application specific, and allows for
application-specific Merkle proofs about the state of the application.
While some applications keep all relevant state in the transactions themselves
(like Bitcoin and its UTXOs), others maintain a separated state that is
computed deterministically from transactions, but is not contained directly in
the transactions themselves (like Ethereum contracts and accounts).
For such applications, the AppHash
provides a much more efficient way to verify light-client proofs.
ABCI applications can take advantage of more efficient light-client proofs for their state as follows:
FinalizeBlockResponse.Data
. This Merkle root will be included as the AppHash
in the next block.QueryResponse.Proof
that can be verified using the AppHash
of the corresponding block.For instance, this allows an application’s light-client to verify proofs of absence in the application state, something which is much less efficient to do using the block hash.
Some applications (eg. Ethereum, Cosmos-SDK) have multiple “levels” of Merkle trees,
where the leaves of one tree are the root hashes of others. To support this, and
the general variability in Merkle proofs, the QueryResponse.Proof
has some minimal structure:
message ProofOps {
repeated ProofOp ops = 1
}
message ProofOp {
string type = 1;
bytes key = 2;
bytes data = 3;
}
Each ProofOp
contains a proof for a single key in a single Merkle tree, of the specified type
.
This allows ABCI to support many different kinds of Merkle trees, encoding
formats, and proofs (eg. of presence and absence) just by varying the type
.
The data
contains the actual encoded proof, encoded according to the type
.
When verifying the full proof, the root hash for one ProofOp is the value being
verified for the next ProofOp in the list. The root hash of the final ProofOp in
the list should match the AppHash
being verified against.
When CometBFT connects to a peer, it sends two queries to the ABCI application using the following paths, with no additional data:
/p2p/filter/addr/<IP:PORT>
, where <IP:PORT>
denote the IP address and
the port of the connectionp2p/filter/id/<ID>
, where <ID>
is the peer node ID (ie. the
pubkey.Address() for the peer’s PubKey)If either of these queries return a non-zero ABCI code, CometBFT will refuse to connect to the peer.
Queries are directed at paths, and may optionally include additional data.
The expectation is for there to be some number of high level paths
differentiating concerns, like /p2p
, /store
, and /app
. Currently,
CometBFT only uses /p2p
, for filtering peers. For more advanced use, see the
implementation of
Query in the Cosmos-SDK.
CometBFT and the application are expected to crash together and there should not exist a scenario where the application has persisted state of a height greater than the latest height persisted by CometBFT.
In practice, persisting the state of a height consists of three steps, the last of which
is the call to the application’s Commit
method, the only place where the application is expected to
persist/commit its state.
On startup (upon recovery), CometBFT calls the Info
method on the Info Connection to get the latest
committed state of the app. The app MUST return information consistent with the
last block for which it successfully completed Commit
.
The three steps performed before the state of a height is considered persisted are:
FinalizeBlockResponse
Commit
.The following diagram depicts the order in which these events happen, and the corresponding ABCI functions that are called and executed by CometBFT and the application:
APP: Execute block Persist application state
/ return ResultFinalizeBlock /
/ /
Event: ------------- block_stored ------------ / ------------ state_stored --------------- / ----- app_persisted_state
| / | / |
CometBFT: Decide --- Persist block -- Call FinalizeBlock - Persist results ---------- Call Commit --
on in the (txResults, validator
Block block store updates...)
As these three steps are not atomic, we observe different cases based on which steps have been executed
before the crash occurred
(we assume that at least block_stored
has been executed, otherwise, there is no state persisted,
and the operations for this height are repeated entirely):
block_stored
: we replay FinalizeBlock
and the steps afterwards.block_stored
and state_stored
: As the app did not persist its state within Commit
, we need to re-execute
FinalizeBlock
to retrieve the results and compare them to the state stored by CometBFT within state_stored
.
The expected case is that the states will match, otherwise CometBFT panics.block_stored
, state_stored
, app_persisted_state
: we move on to the next height.Based on the sequence of these events, CometBFT will panic if any of the steps in the sequence happen out of order, that is if:
state_stored
.block_stored
step persisted a block at a height smaller than the state_stored
state_stored
and block_stored
is more
than 1 (this corresponds to a scenario where we stored two blocks in the block store but never persisted the state of the first
block, which should never happen).A special case is when a crash happens before the first block is committed - that is, after calling
InitChain
. In that case, the application’s state should still be at height 0 and thus InitChain
will be called again.
A new node joining the network can simply join consensus at the genesis height and replay all historical blocks until it is caught up. However, for large chains this can take a significant amount of time, often on the order of days or weeks.
State sync is an alternative mechanism for bootstrapping a new node, where it fetches a snapshot of the state machine at a given height and restores it. Depending on the application, this can be several orders of magnitude faster than replaying blocks.
Note that state sync does not currently backfill historical blocks, so the node will have a truncated block history - users are advised to consider the broader network implications of this in terms of block availability and auditability. This functionality may be added in the future.
For details on the specific ABCI calls and types, see the methods section.
Applications that want to support state syncing must take state snapshots at regular intervals. How this is accomplished is entirely up to the application. A snapshot consists of some metadata and a set of binary chunks in an arbitrary format:
Height (uint64)
: The height at which the snapshot is taken. It must be taken after the given
height has been committed, and must not contain data from any later heights.
Format (uint32)
: An arbitrary snapshot format identifier. This can be used to version snapshot
formats, e.g. to switch from Protobuf to MessagePack for serialization. The application can use
this when restoring to choose whether to accept or reject a snapshot.
Chunks (uint32)
: The number of chunks in the snapshot. Each chunk contains arbitrary binary
data, and should be less than 16 MB; 10 MB is a good starting point.
Hash ([]byte)
: An arbitrary hash of the snapshot. This is used to check whether a snapshot is
the same across nodes when downloading chunks.
Metadata ([]byte)
: Arbitrary snapshot metadata, e.g. chunk hashes for verification or any other
necessary info.
For a snapshot to be considered the same across nodes, all of these fields must be identical. When sent across the network, snapshot metadata messages are limited to 4 MB.
When a new node is running state sync and discovering snapshots, CometBFT will query an existing
application via the ABCI ListSnapshots
method to discover available snapshots, and load binary
snapshot chunks via LoadSnapshotChunk
. The application is free to choose how to implement this
and which formats to use, but must provide the following guarantees:
Consistent: A snapshot must be taken at a single isolated height, unaffected by concurrent writes. This can be accomplished by using a data store that supports ACID transactions with snapshot isolation.
Asynchronous: Taking a snapshot can be time-consuming, so it must not halt chain progress, for example by running in a separate thread.
Deterministic: A snapshot taken at the same height in the same format must be identical (at the byte level) across nodes, including all metadata. This ensures good availability of chunks, and that they fit together across nodes.
A very basic approach might be to use a datastore with MVCC transactions (such as RocksDB), start a transaction immediately after block commit, and spawn a new thread which is passed the transaction handle. This thread can then export all data items, serialize them using e.g. Protobuf, hash the byte stream, split it into chunks, and store the chunks in the file system along with some metadata - all while the blockchain is applying new blocks in parallel.
A more advanced approach might include incremental verification of individual chunks against the chain app hash, parallel or batched exports, compression, and so on.
Old snapshots should be removed after some time - generally only the last two snapshots are needed (to prevent the last one from being removed while a node is restoring it).
An empty node can be state synced by setting the configuration option statesync.enabled =
true
. The node also needs the chain genesis file for basic chain info, and configuration for
light client verification of the restored snapshot: a set of CometBFT RPC servers, and a
trusted header hash and corresponding height from a trusted source, via the statesync
configuration section.
Once started, the node will connect to the P2P network and begin discovering snapshots. These
will be offered to the local application via the OfferSnapshot
ABCI method. Once a snapshot
is accepted CometBFT will fetch and apply the snapshot chunks. After all chunks have been
successfully applied, CometBFT verifies the app’s AppHash
against the chain using the light
client, then switches the node to normal consensus operation.
When the empty node joins the P2P network, it asks all peers to report snapshots via the
ListSnapshots
ABCI call (limited to 10 per node). After some time, the node picks the most
suitable snapshot (generally prioritized by height, format, and number of peers), and offers it
to the application via OfferSnapshot
. The application can choose a number of responses,
including accepting or rejecting it, rejecting the offered format, rejecting the peer who sent
it, and so on. CometBFT will keep discovering and offering snapshots until one is accepted or
the application aborts.
Once a snapshot has been accepted via OfferSnapshot
, CometBFT begins downloading chunks from
any peers that have the same snapshot (i.e. that have identical metadata fields). Chunks are
spooled in a temporary directory, and then given to the application in sequential order via
ApplySnapshotChunk
until all chunks have been accepted.
The method for restoring snapshot chunks is entirely up to the application.
During restoration, the application can respond to ApplySnapshotChunk
with instructions for how
to continue. This will typically be to accept the chunk and await the next one, but it can also
ask for chunks to be refetched (either the current one or any number of previous ones), P2P peers
to be banned, snapshots to be rejected or retried, and a number of other responses - see the ABCI
reference for details.
If CometBFT fails to fetch a chunk after some time, it will reject the snapshot and try a
different one via OfferSnapshot
- the application can choose whether it wants to support
restarting restoration, or simply abort with an error.
Once all chunks have been accepted, CometBFT issues an Info
ABCI call to retrieve the
LastBlockAppHash
. This is compared with the trusted app hash from the chain, retrieved and
verified using the light client. CometBFT also checks that LastBlockHeight
corresponds to the
height of the snapshot.
This verification ensures that an application is valid before joining the network. However, the snapshot restoration may take a long time to complete, so applications may want to employ additional verification during the restore to detect failures early. This might e.g. include incremental verification of each chunk against the app hash (using bundled Merkle proofs), checksums to protect against data corruption by the disk or network, and so on. However, it is important to note that the only trusted information available is the app hash, and all other snapshot metadata can be spoofed by adversaries.
Apps may also want to consider state sync denial-of-service vectors, where adversaries provide invalid or harmful snapshots to prevent nodes from joining the network. The application can counteract this by asking CometBFT to ban peers. As a last resort, node operators can use P2P configuration options to whitelist a set of trusted peers that can provide valid snapshots.
Once the snapshots have all been restored, CometBFT gathers additional information necessary for
bootstrapping the node (e.g. chain ID, consensus parameters, validator sets, and block headers)
from the genesis file and light client RPC servers. It also calls Info
to verify the following:
InfoResponse
matches the version in the
current height’s block headerOnce the state machine has been restored and CometBFT has gathered this additional information, it transitions to consensus. As of ABCI 2.0, CometBFT ensures the necessary conditions to switch are met RFC-100. From the application’s point of view, these operations are transparent, unless the application has just upgraded to ABCI 2.0. In that case, the application needs to be properly configured and aware of certain constraints in terms of when to provide vote extensions. More details can be found in the section below.
Once a node switches to consensus, it operates like any other node, apart from having a truncated block history at the height of the restored snapshot.
Introducing vote extensions requires changes to the configuration of the application.
First of all, switching to a version of CometBFT with vote extensions, requires a coordinated upgrade. For a detailed description on the upgrade path, please refer to the corresponding section in RFC-100.
There is a newly introduced consensus parameter: VoteExtensionsEnableHeight
.
This parameter represents the height at which vote extensions are
required for consensus to proceed, with 0 being the default value (vote extensions disabled).
A chain can enable vote extensions either:
VoteExtensionsEnableHeight
to be equal, e.g., to the InitialHeight
ConsensusParam
to configure the
VoteExtensionsEnableHeight
.Once the (coordinated) upgrade to ABCI 2.0 has taken place, at height hu,
the value of VoteExtensionsEnableHeight
MAY be set to some height, he,
which MUST be higher than the current height of the chain. Thus the earliest value for
he is hu + 1.
Once a node reaches the configured height,
for all heights h ≥ he, the consensus algorithm will
reject as invalid any precommit messages that do not have signed vote extension data.
If the application requires it, a 0-length vote extension is allowed, but it MUST be signed
and present in the precommit message.
Likewise, for all heights h < he, any precommit messages that do have vote extensions
will also be rejected as malformed.
Height he is somewhat special, as calls to PrepareProposal
MUST NOT
have vote extension data, but all precommit votes in that height MUST carry a vote extension,
even if the extension is nil
.
Height he + 1 is the first height for which PrepareProposal
MUST have vote
extension data and all precommit votes in that height MUST have a vote extension.
Corollary, CometBFT will decide which data to store, and require for successful operations, based on the current height of the chain.