The purpose of ABCI is to provide a clean interface between state transition machines on one computer and the mechanics of their replication across multiple computers. The former we call 'application logic' and the latter the 'consensus engine'. Application logic validates transactions and optionally executes transactions against some persistent state. A consensus engine ensures all transactions are replicated in the same order on every machine. We call each machine in a consensus engine a 'validator', and each validator runs the same transactions through the same application logic. In particular, we are interested in blockchain-style consensus engines, where transactions are committed in hash-linked blocks.
The ABCI design has a few distinct components:
CheckTx
BeginBlock, [DeliverTx, ...], EndBlock, Commit
The mempool and consensus logic act as clients, and each maintains an open ABCI connection with the application, which hosts an ABCI server. Shown are the request and response types sent on each connection.
The message protocol consists of pairs of requests and responses. Some
messages have no fields, while others may include byte-arrays, strings,
or integers. See the message Request
and message Response
definitions in the protobuf definition
file,
and the protobuf
documentation
for more details.
For each request, a server should respond with the corresponding response, where order of requests is preserved in the order of responses.
To use ABCI in your programming language of choice, there must be a ABCI server in that language. Tendermint supports two kinds of implementation of the server:
Both can be tested using the abci-cli
by setting the --abci
flag
appropriately (ie. to socket
or grpc
).
See examples, in various stages of maintenance, in Go, JavaScript, Python, C++, and Java.
If GRPC is available in your language, this is the easiest approach, though it will have significant performance overhead.
To get started with GRPC, copy in the protobuf
file
and compile it using the GRPC plugin for your language. For instance,
for golang, the command is protoc --go_out=plugins=grpc:. types.proto
.
See the grpc documentation for more details.
protoc
will autogenerate all the necessary code for ABCI client and
server in your language, including whatever interface your application
must satisfy to be used by the ABCI server for handling requests.
If GRPC is not available in your language, or you require higher
performance, or otherwise enjoy programming, you may implement your own
ABCI server using the Tendermint Socket Protocol, known affectionately
as Teaspoon. The first step is still to auto-generate the relevant data
types and codec in your language using protoc
. Messages coming over
the socket are proto3 encoded, but additionally length-prefixed to
facilitate use as a streaming protocol. proto3 doesn't have an
official length-prefix standard, so we use our own. The first byte in
the prefix represents the length of the Big Endian encoded length. The
remaining bytes in the prefix are the Big Endian encoded length.
For example, if the proto3 encoded ABCI message is 0xDEADBEEF (4 bytes), the length-prefixed message is 0x0104DEADBEEF. If the proto3 encoded ABCI message is 65535 bytes long, the length-prefixed message would be like 0x02FFFF....
Note this prefixing does not apply for grpc.
An ABCI server must also be able to support multiple connections, as Tendermint uses three connections.
There are currently two use-cases for an ABCI client. One is a testing
tool, as in the abci-cli
, which allows ABCI requests to be sent via
command line. The other is a consensus engine, such as Tendermint Core,
which makes requests to the application every time a new transaction is
received or a block is committed.
It is unlikely that you will need to implement a client. For details of our client, see here.
Most of the examples below are from kvstore
application,
which is a part of the abci repo. persistent_kvstore
application
is used to show BeginBlock
, EndBlock
and InitChain
example
implementations.
In ABCI, a transaction is simply an arbitrary length byte-array. It is the application's responsibility to define the transaction codec as they please, and to use it for both CheckTx and DeliverTx.
Note that there are two distinct means for running transactions, corresponding to stages of 'awareness' of the transaction in the network. The first stage is when a transaction is received by a validator from a client into the so-called mempool or transaction pool -this is where we use CheckTx. The second is when the transaction is successfully committed on more than 2/3 of validators - where we use DeliverTx. In the former case, it may not be necessary to run all the state transitions associated with the transaction, as the transaction may not ultimately be committed until some much later time, when the result of its execution will be different. For instance, an Ethereum ABCI app would check signatures and amounts in CheckTx, but would not actually execute any contract code until the DeliverTx, so as to avoid executing state transitions that have not been finalized.
To formalize the distinction further, two explicit ABCI connections are made between Tendermint Core and the application: the mempool connection and the consensus connection. We also make a third connection, the query connection, to query the local state of the app.
The mempool connection is used only for CheckTx requests. Transactions
are run using CheckTx in the same order they were received by the
validator. If the CheckTx returns OK
, the transaction is kept in
memory and relayed to other peers in the same order it was received.
Otherwise, it is discarded.
CheckTx requests run concurrently with block processing; so they should
run against a copy of the main application state which is reset after
every block. This copy is necessary to track transitions made by a
sequence of CheckTx requests before they are included in a block. When a
block is committed, the application must ensure to reset the mempool
state to the latest committed state. Tendermint Core will then filter
through all transactions in the mempool, removing any that were included
in the block, and re-run the rest using CheckTx against the post-Commit
mempool state (this behaviour can be turned off with
[mempool] recheck = false
).
In go:
func (app *KVStoreApplication) CheckTx(tx []byte) types.Result {
return types.OK
}
In Java:
ResponseCheckTx requestCheckTx(RequestCheckTx req) {
byte[] transaction = req.getTx().toByteArray();
// validate transaction
if (notValid) {
return ResponseCheckTx.newBuilder().setCode(CodeType.BadNonce).setLog("invalid tx").build();
} else {
return ResponseCheckTx.newBuilder().setCode(CodeType.OK).build();
}
}
To prevent old transactions from being replayed, CheckTx must implement replay protection.
Tendermint provides the first defence layer by keeping a lightweight
in-memory cache of 100k ([mempool] cache_size
) last transactions in
the mempool. If Tendermint is just started or the clients sent more than
100k transactions, old transactions may be sent to the application. So
it is important CheckTx implements some logic to handle them.
There are cases where a transaction will (or may) become valid in some
future state, in which case you probably want to disable Tendermint's
cache. You can do that by setting [mempool] cache_size = 0
in the
config.
The consensus connection is used only when a new block is committed, and
communicates all information from the block in a series of requests:
BeginBlock, [DeliverTx, ...], EndBlock, Commit
. That is, when a block
is committed in the consensus, we send a list of DeliverTx requests (one
for each transaction) sandwiched by BeginBlock and EndBlock requests,
and followed by a Commit.
DeliverTx is the workhorse of the blockchain. Tendermint sends the DeliverTx requests asynchronously but in order, and relies on the underlying socket protocol (ie. TCP) to ensure they are received by the app in order. They have already been ordered in the global consensus by the Tendermint protocol.
DeliverTx returns a abci.Result, which includes a Code, Data, and Log. The code may be non-zero (non-OK), meaning the corresponding transaction should have been rejected by the mempool, but may have been included in a block by a Byzantine proposer.
The block header will be updated (TODO) to include some commitment to the results of DeliverTx, be it a bitarray of non-OK transactions, or a merkle root of the data returned by the DeliverTx requests, or both.
In go:
// tx is either "key=value" or just arbitrary bytes
func (app *KVStoreApplication) DeliverTx(tx []byte) types.Result {
parts := strings.Split(string(tx), "=")
if len(parts) == 2 {
app.state.Set([]byte(parts[0]), []byte(parts[1]))
} else {
app.state.Set(tx, tx)
}
return types.OK
}
In Java:
/**
* Using Protobuf types from the protoc compiler, we always start with a byte[]
*/
ResponseDeliverTx deliverTx(RequestDeliverTx request) {
byte[] transaction = request.getTx().toByteArray();
// validate your transaction
if (notValid) {
return ResponseDeliverTx.newBuilder().setCode(CodeType.BadNonce).setLog("transaction was invalid").build();
} else {
ResponseDeliverTx.newBuilder().setCode(CodeType.OK).build();
}
}
Once all processing of the block is complete, Tendermint sends the Commit request and blocks waiting for a response. While the mempool may run concurrently with block processing (the BeginBlock, DeliverTxs, and EndBlock), it is locked for the Commit request so that its state can be safely reset during Commit. This means the app MUST NOT do any blocking communication with the mempool (ie. broadcast_tx) during Commit, or there will be deadlock. Note also that all remaining transactions in the mempool are replayed on the mempool connection (CheckTx) following a commit.
The app should respond to the Commit request with a byte array, which is the deterministic state root of the application. It is included in the header of the next block. It can be used to provide easily verified Merkle-proofs of the state of the application.
It is expected that the app will persist state to disk on Commit. The option to have all transactions replayed from some previous block is the job of the Handshake.
In go:
func (app *KVStoreApplication) Commit() types.Result {
hash := app.state.Hash()
return types.NewResultOK(hash, "")
}
In Java:
ResponseCommit requestCommit(RequestCommit requestCommit) {
// update the internal app-state
byte[] newAppState = calculateAppState();
// and return it to the node
return ResponseCommit.newBuilder().setCode(CodeType.OK).setData(ByteString.copyFrom(newAppState)).build();
}
The BeginBlock request can be used to run some code at the beginning of every block. It also allows Tendermint to send the current block hash and header to the application, before it sends any of the transactions.
The app should remember the latest height and header (ie. from which it has run a successful Commit) so that it can tell Tendermint where to pick up from when it restarts. See information on the Handshake, below.
In go:
// Track the block hash and header information
func (app *PersistentKVStoreApplication) BeginBlock(params types.RequestBeginBlock) {
// update latest block info
app.blockHeader = params.Header
// reset valset changes
app.changes = make([]*types.Validator, 0)
}
In Java:
/*
* all types come from protobuf definition
*/
ResponseBeginBlock requestBeginBlock(RequestBeginBlock req) {
Header header = req.getHeader();
byte[] prevAppHash = header.getAppHash().toByteArray();
long prevHeight = header.getHeight();
long numTxs = header.getNumTxs();
// run your pre-block logic. Maybe prepare a state snapshot, message components, etc
return ResponseBeginBlock.newBuilder().build();
}
The EndBlock request can be used to run some code at the end of every block.
Additionally, the response may contain a list of validators, which can be used
to update the validator set. To add a new validator or update an existing one,
simply include them in the list returned in the EndBlock response. To remove
one, include it in the list with a power
equal to 0
. Validator's address
field can be left empty. Tendermint core will take care of updating the
validator set. Note the change in voting power must be strictly less than 1/3
per block if you want a light client to be able to prove the transition
externally. See the light client
docs
for details on how it tracks validators.
In go:
// Update the validator set
func (app *PersistentKVStoreApplication) EndBlock(req types.RequestEndBlock) types.ResponseEndBlock {
return types.ResponseEndBlock{ValidatorUpdates: app.ValUpdates}
}
In Java:
/*
* Assume that one validator changes. The new validator has a power of 10
*/
ResponseEndBlock requestEndBlock(RequestEndBlock req) {
final long currentHeight = req.getHeight();
final byte[] validatorPubKey = getValPubKey();
ResponseEndBlock.Builder builder = ResponseEndBlock.newBuilder();
builder.addDiffs(1, Types.Validator.newBuilder().setPower(10L).setPubKey(ByteString.copyFrom(validatorPubKey)).build());
return builder.build();
}
This connection is used to query the application without engaging consensus. It's exposed over the tendermint core rpc, so clients can query the app without exposing a server on the app itself, but they must serialize each query as a single byte array. Additionally, certain "standardized" queries may be used to inform local decisions, for instance about which peers to connect to.
Tendermint Core currently uses the Query connection to filter peers upon connecting, according to IP address or node ID. For instance, returning non-OK ABCI response to either of the following queries will cause Tendermint to not connect to the corresponding peer:
p2p/filter/addr/<ip addr>
, where <ip addr>
is an IP address.p2p/filter/id/<id>
, where <is>
is the hex-encoded node ID (the hash of
the node's p2p pubkey).Note: these query formats are subject to change!
In go:
func (app *KVStoreApplication) Query(reqQuery types.RequestQuery) (resQuery types.ResponseQuery) {
if reqQuery.Prove {
value, proof, exists := app.state.Proof(reqQuery.Data)
resQuery.Index = -1 // TODO make Proof return index
resQuery.Key = reqQuery.Data
resQuery.Value = value
resQuery.Proof = proof
if exists {
resQuery.Log = "exists"
} else {
resQuery.Log = "does not exist"
}
return
} else {
index, value, exists := app.state.Get(reqQuery.Data)
resQuery.Index = int64(index)
resQuery.Value = value
if exists {
resQuery.Log = "exists"
} else {
resQuery.Log = "does not exist"
}
return
}
}
In Java:
ResponseQuery requestQuery(RequestQuery req) {
final boolean isProveQuery = req.getProve();
final ResponseQuery.Builder responseBuilder = ResponseQuery.newBuilder();
if (isProveQuery) {
com.app.example.ProofResult proofResult = generateProof(req.getData().toByteArray());
final byte[] proofAsByteArray = proofResult.getAsByteArray();
responseBuilder.setProof(ByteString.copyFrom(proofAsByteArray));
responseBuilder.setKey(req.getData());
responseBuilder.setValue(ByteString.copyFrom(proofResult.getData()));
responseBuilder.setLog(result.getLogValue());
} else {
byte[] queryData = req.getData().toByteArray();
final com.app.example.QueryResult result = generateQueryResult(queryData);
responseBuilder.setIndex(result.getIndex());
responseBuilder.setValue(ByteString.copyFrom(result.getValue()));
responseBuilder.setLog(result.getLogValue());
}
return responseBuilder.build();
}
When the app or tendermint restarts, they need to sync to a common
height. When an ABCI connection is first established, Tendermint will
call Info
on the Query connection. The response should contain the
LastBlockHeight and LastBlockAppHash - the former is the last block for
which the app ran Commit successfully, the latter is the response from
that Commit.
Using this information, Tendermint will determine what needs to be replayed, if anything, against the app, to ensure both Tendermint and the app are synced to the latest block height.
If the app returns a LastBlockHeight of 0, Tendermint will just replay all blocks.
In go:
func (app *KVStoreApplication) Info(req types.RequestInfo) (resInfo types.ResponseInfo) {
return types.ResponseInfo{Data: cmn.Fmt("{\"size\":%v}", app.state.Size())}
}
In Java:
ResponseInfo requestInfo(RequestInfo req) {
final byte[] lastAppHash = getLastAppHash();
final long lastHeight = getLastHeight();
return ResponseInfo.newBuilder().setLastBlockAppHash(ByteString.copyFrom(lastAppHash)).setLastBlockHeight(lastHeight).build();
}
InitChain
will be called once upon the genesis. params
includes the
initial validator set. Later on, it may be extended to take parts of the
consensus params.
In go:
// Save the validators in the merkle tree
func (app *PersistentKVStoreApplication) InitChain(params types.RequestInitChain) {
for _, v := range params.Validators {
r := app.updateValidator(v)
if r.IsErr() {
app.logger.Error("Error updating validators", "r", r)
}
}
}
In Java:
/*
* all types come from protobuf definition
*/
ResponseInitChain requestInitChain(RequestInitChain req) {
final int validatorsCount = req.getValidatorsCount();
final List<Types.Validator> validatorsList = req.getValidatorsList();
validatorsList.forEach((validator) -> {
long power = validator.getPower();
byte[] validatorPubKey = validator.getPubKey().toByteArray();
// do somehing for validator setup in app
});
return ResponseInitChain.newBuilder().build();
}