Please ensure you've first read the spec for ABCI Methods and Types
Here we cover the following components of ABCI applications:
CheckTx
and DeliverTx
.InitChain
and EndBlock
Query
method and proofs about the
application stateSince Tendermint maintains three concurrent ABCI connections, it is typical
for an application to maintain a distinct state for each, and for the states to
be synchronized during Commit
.
Application state should only be persisted to disk during Commit
.
Before Commit
is called, Tendermint locks and flushes the mempool so that no new messages will
be received on the mempool connection. This provides an opportunity to safely update all three
states to the latest committed state at once.
When Commit
completes, it unlocks the mempool.
WARNING: if the ABCI app logic processing the Commit
message sends a
/broadcast_tx_sync
or /broadcast_tx_commit
and waits for the response
before proceeding, it will deadlock. Executing those broadcast_tx
calls
involves acquiring a lock that is held during the Commit
call, so it's not
possible. If you make the call to the broadcast_tx
endpoints concurrently,
that's no problem, it just can't be part of the sequential logic of the
Commit
function.
The Consensus Connection should maintain a DeliverTxState
-
the working state for block execution. It should be updated by the calls to
BeginBlock
, DeliverTx
, and EndBlock
during block execution and committed to
disk as the "latest committed state" during Commit
.
Updates made to the DeliverTxState by each method call must be readable by each subsequent method - ie. the updates are linearizable.
The Mempool Connection should maintain a CheckTxState
to sequentially process pending transactions in the mempool that have
not yet been committed. It should be initialized to the latest committed state
at the end of every Commit
.
The CheckTxState may be updated concurrently with the DeliverTxState, as
messages may be sent concurrently on the Consensus and Mempool connections. However,
before calling Commit
, Tendermint will lock and flush the mempool connection,
ensuring that all existing CheckTx are responded to and no new ones can
begin.
After Commit
, CheckTx is run again on all transactions that remain in the
node's local mempool after filtering those included in the block. To prevent the
mempool from rechecking all transactions every time a block is committed, set
the configuration option mempool.recheck=false
.
Finally, the mempool will unlock and new transactions can be processed through CheckTx again.
Note that CheckTx doesn't have to check everything that affects transaction validity; the expensive things can be skipped. In fact, CheckTx doesn't have to check anything; it might say that any transaction is a valid transaction. Unlike DeliverTx, CheckTx is just there as a sort of weak filter to keep invalid transactions out of the blockchain. It's weak, because a Byzantine node doesn't care about CheckTx; it can propose a block full of invalid transactions if it wants.
The Info Connection should maintain a QueryState
for answering queries from the user,
and for initialization when Tendermint first starts up (both described further
below).
It should always contain the latest committed state associated with the
latest committed block.
QueryState should be set to the latest DeliverTxState
at the end of every Commit
,
ie. after the full block has been processed and the state committed to disk.
Otherwise it should never be modified.
ResponseCheckTx
and ResponseDeliverTx
contain the same fields.
The Info
and Log
fields are non-deterministic values for debugging/convenience purposes
that are otherwise ignored.
The Data
field must be strictly deterministic, but can be arbitrary data.
Ethereum introduced the notion of gas
as an abstract representation of the
cost of resources used by nodes when processing transactions. Every operation in the
Ethereum Virtual Machine uses some amount of gas, and gas can be accepted at a market-variable price.
Users propose a maximum amount of gas for their transaction; if the tx uses less, they get
the difference credited back. Tendermint adopts a similar abstraction,
though uses it only optionally and weakly, allowing applications to define
their own sense of the cost of execution.
In Tendermint, the ConsensusParams.Block.MaxGas
limits the amount of gas
that can be used in a block.
The default value is -1
, meaning no limit, 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 tx is willing to use, and the later is how much it actually
used. Applications should enforce that GasUsed <= GasWanted
- ie. tx execution
should halt before it can use more resources than it requested.
When MaxGas > -1
, Tendermint enforces the following rules:
GasWanted <= MaxGas
for all txs in the mempool(sum of GasWanted in a block) <= MaxGas
when proposing a blockIf MaxGas == -1
, no rules about gas are enforced.
Note that Tendermint does not currently enforce anything about Gas in the consensus, only 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.
The GasUsed
field is ignored completely by Tendermint. That said, applications should enforce:
GasUsed <= GasWanted
for any given transaction(sum of GasUsed in a block) <= MaxGas
for every blockIn the future, we intend to add a Priority
field to the responses that can be
used to explicitly prioritize txs in the mempool for inclusion in a block
proposal. See #1861.
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 is
semantically meaningless to Tendermint.
Tags
include any tags for the execution, though since the transaction has not
been committed yet, they are effectively ignored by Tendermint.
If DeliverTx returns Code != 0
, the transaction will be considered invalid,
though it is still included in the block.
Data
contains the result of the CheckTx transaction execution, if any. It is
semantically meaningless to Tendermint.
Both the Code
and Data
are included in a structure that is hashed into the
LastResultsHash
of the next block header.
Tags
include any tags for the execution, which Tendermint will use to index
the transaction by. This allows transactions to be queried according to what
events took place during their execution.
See issue #1007 for how the tags will be hashed into the next block header.
The application may set the validator set during InitChain, and update it during EndBlock.
Note that the maximum total power of the validator set is bounded by
MaxTotalVotingPower = MaxInt64 / 8
. Applications are responsible for ensuring
they do not make changes to the validator set that cause it to exceed this
limit.
Additionally, applications must ensure that a single set of updates does not contain any duplicates - a given public key can only appear in an update once. If an update includes duplicates, the block execution will fail irrecoverably.
ResponseInitChain can return a list of validators. If the list is empty, Tendermint will use the validators loaded in the genesis file. If the list is not empty, Tendermint will use it for the validator set. This way the application can determine the initial validator set for the blockchain.
Updates to the Tendermint validator set can be made by returning
ValidatorUpdate
objects in the ResponseEndBlock
:
message ValidatorUpdate {
PubKey pub_key
int64 power
}
message PubKey {
string type
bytes data
}
The pub_key
currently supports only one type:
type = "ed25519" and
data = <raw 32-byte public key>`The power
is the new voting power for the validator, with the
following rules:
Note the updates returned in block H
will only take effect at block H+2
.
ConsensusParams 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 EndBlock.
The maximum size of a complete Amino encoded block. This is enforced by Tendermint consensus.
This implies a maximum tx size that is this MaxBytes, less the expected size of the header, the validator set, and any included evidence in the block.
Must have 0 < MaxBytes < 100 MB
.
The maximum of the sum of GasWanted
in a proposed block.
This is not enforced by Tendermint consensus.
It is left to the app to enforce (ie. if txs are included past the
limit, they should return non-zero codes). It is used by Tendermint to limit the
txs included in a proposed block.
Must have MaxGas >= -1
.
If MaxGas == -1
, no limit is enforced.
The minimum time between consecutive blocks (in milliseconds). This is enforced by Tendermint consensus.
Must have TimeIotaMs > 0
to ensure time monotonicity.
This is the maximum age of evidence. This is enforced by Tendermint consensus. If a block includes evidence older than this, the block will be rejected (validators won't vote for it).
Must have 0 < MaxAge
.
The application may set the ConsensusParams during InitChain, and update them during EndBlock. 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 0.
ResponseInitChain includes a ConsensusParams. If its nil, Tendermint will use the params loaded in the genesis file. If it's not nil, Tendermint will use it. This way the application can determine the initial consensus params for the blockchain.
ResponseEndBlock includes a ConsensusParams. If its nil, Tendermint will do nothing. If it's not nil, Tendermint will use it. This way the application can update the consensus params over time.
Note the updates returned in block H
will take effect right away for block
H+1
.
Query is a generic method with lots of flexibility to enable diverse sets of queries on application state. Tendermint 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 lite-clients.
Note Tendermint 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 too.
The Tendermint 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, etc.
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 lite-client proofs.
ABCI applications can take advantage of more efficient lite-client proofs for their state as follows:
ResponseCommit.Data
.AppHash
in the next block.ResponseQuery.Proof
that can be verified using the AppHash
of the corresponding block.For instance, this allows an application's lite-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 ResponseQuery.Proof
has some minimal structure:
message Proof {
repeated ProofOp ops
}
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 Tendermint 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, Tendermint 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,
Tendermint only uses /p2p
, for filtering peers. For more advanced use, see the
implementation of
Query in the Cosmos-SDK.
On startup, Tendermint 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 it succesfully completed Commit for.
If the app succesfully committed block H but not H+1, then last_block_height = H
and last_block_app_hash = <hash returned by Commit for block H>
. If the app
failed during the Commit of block H, then last_block_height = H-1
and
last_block_app_hash = <hash returned by Commit for block H-1, which is the hash in the header of block H>
.
We now distinguish three heights, and describe how Tendermint syncs itself with the app.
storeBlockHeight = height of the last block Tendermint saw a commit for
stateBlockHeight = height of the last block for which Tendermint completed all
block processing and saved all ABCI results to disk
appBlockHeight = height of the last block for which ABCI app succesfully
completed Commit
Note we always have storeBlockHeight >= stateBlockHeight
and storeBlockHeight >= appBlockHeight
Note also we never call Commit on an ABCI app twice for the same height.
The procedure is as follows.
First, some simple start conditions:
If appBlockHeight == 0
, then call InitChain.
If storeBlockHeight == 0
, we're done.
Now, some sanity checks:
If storeBlockHeight < appBlockHeight
, error
If storeBlockHeight < stateBlockHeight
, panic
If storeBlockHeight > stateBlockHeight+1
, panic
Now, the meat:
If storeBlockHeight == stateBlockHeight && appBlockHeight < storeBlockHeight
,
replay all blocks in full from appBlockHeight
to storeBlockHeight
.
This happens if we completed processing the block, but the app forgot its height.
If storeBlockHeight == stateBlockHeight && appBlockHeight == storeBlockHeight
, we're done.
This happens if we crashed at an opportune spot.
If storeBlockHeight == stateBlockHeight+1
This happens if we started processing the block but didn't finish.
If appBlockHeight < stateBlockHeight
replay all blocks in full from appBlockHeight
to storeBlockHeight-1
,
and replay the block at storeBlockHeight
using the WAL.
This happens if the app forgot the last block it committed.
If appBlockHeight == stateBlockHeight
,
replay the last block (storeBlockHeight) in full.
This happens if we crashed before the app finished Commit
If appBlockHeight == storeBlockHeight
update the state using the saved ABCI responses but dont run the block against the real app.
This happens if we crashed after the app finished Commit but before Tendermint saved the state.