Creating a built-in application in Go

Guide Assumptions

This guide is designed for beginners who want to get started with a CometBFT application from scratch. It does not assume that you have any prior experience with CometBFT.

CometBFT is a service that provides a Byzantine Fault Tolerant consensus engine for state-machine replication. The replicated state-machine, or “application”, can be written in any language that can send and receive protocol buffer messages in a client-server model. Applications written in Go can also use CometBFT as a library and run the service in the same process as the application.

By following along this tutorial you will create a CometBFT application called kvstore, a (very) simple distributed BFT key-value store. The application will be written in Go and some understanding of the Go programming language is expected. If you have never written Go, you may want to go through Learn X in Y minutes Where X=Go first, to familiarize yourself with the syntax.

Note: Please use the latest released version of this guide and of CometBFT. We strongly advise against using unreleased commits for your development.

Built-in app vs external app

On the one hand, to get maximum performance you can run your application in the same process as the CometBFT, as long as your application is written in Go. Cosmos SDK is written this way. This is the approach followed in this tutorial.

On the other hand, having a separate application might give you better security guarantees as two processes would be communicating via established binary protocol. CometBFT will not have access to application’s state. If that is the way you wish to proceed, use the Creating an application in Go guide instead of this one.

1.1 Installing Go

Verify that you have the latest version of Go installed (refer to the official guide for installing Go):

$ go version
go version go1.22.7 darwin/amd64

1.2 Creating a new Go project

We’ll start by creating a new Go project.

mkdir kvstore

Inside the example directory, create a main.go file with the following content:

package main

import (
    "fmt"
)

func main() {
    fmt.Println("Hello, CometBFT")
}

When run, this should print “Hello, CometBFT” to the standard output.

cd kvstore
$ go run main.go
Hello, CometBFT

We are going to use Go modules for dependency management, so let’s start by including a dependency on the latest version of CometBFT, v0.38.0 in this example.

go mod init kvstore
go get github.com/cometbft/cometbft@v0.38.0

After running the above commands you will see two generated files, go.mod and go.sum. The go.mod file should look similar to:

module kvstore

go 1.22

require (
github.com/cometbft/cometbft v0.38.0
)

XXX: CometBFT v0.38.0 uses a slightly outdated gogoproto library, which may fail to compile with newer Go versions. To avoid any compilation errors, upgrade gogoproto manually:

go get github.com/cosmos/gogoproto@v1.4.11

As you write the kvstore application, you can rebuild the binary by pulling any new dependencies and recompiling it.

go get
go build

1.3 Writing a CometBFT application

CometBFT communicates with the application through the Application BlockChain Interface (ABCI). The messages exchanged through the interface are defined in the ABCI protobuf file.

We begin by creating the basic scaffolding for an ABCI application by creating a new type, KVStoreApplication, which implements the methods defined by the abcitypes.Application interface.

Create a file called app.go with the following contents:

package main

import (
    abcitypes "github.com/cometbft/cometbft/abci/types"
    "context"
)

type KVStoreApplication struct{}

var _ abcitypes.Application = (*KVStoreApplication)(nil)

func NewKVStoreApplication() *KVStoreApplication {
    return &KVStoreApplication{}
}

func (app *KVStoreApplication) Info(_ context.Context, info *abcitypes.RequestInfo) (*abcitypes.ResponseInfo, error) {
    return &abcitypes.ResponseInfo{}, nil
}

func (app *KVStoreApplication) Query(_ context.Context, req *abcitypes.RequestQuery) (*abcitypes.ResponseQuery, error) {
    return &abcitypes.ResponseQuery{}, nil
}

func (app *KVStoreApplication) CheckTx(_ context.Context, check *abcitypes.RequestCheckTx) (*abcitypes.ResponseCheckTx, error) {
    return &abcitypes.ResponseCheckTx{}, nil
}

func (app *KVStoreApplication) InitChain(_ context.Context, chain *abcitypes.RequestInitChain) (*abcitypes.ResponseInitChain, error) {
    return &abcitypes.ResponseInitChain{}, nil
}

func (app *KVStoreApplication) PrepareProposal(_ context.Context, proposal *abcitypes.RequestPrepareProposal) (*abcitypes.ResponsePrepareProposal, error) {
    return &abcitypes.ResponsePrepareProposal{}, nil
}

func (app *KVStoreApplication) ProcessProposal(_ context.Context, proposal *abcitypes.RequestProcessProposal) (*abcitypes.ResponseProcessProposal, error) {
    return &abcitypes.ResponseProcessProposal{}, nil
}

func (app *KVStoreApplication) FinalizeBlock(_ context.Context, req *abcitypes.RequestFinalizeBlock) (*abcitypes.ResponseFinalizeBlock, error) {
    return &abcitypes.ResponseFinalizeBlock{}, nil
}

func (app KVStoreApplication) Commit(_ context.Context, commit *abcitypes.RequestCommit) (*abcitypes.ResponseCommit, error) {
    return &abcitypes.ResponseCommit{}, nil
}

func (app *KVStoreApplication) ListSnapshots(_ context.Context, snapshots *abcitypes.RequestListSnapshots) (*abcitypes.ResponseListSnapshots, error) {
    return &abcitypes.ResponseListSnapshots{}, nil
}

func (app *KVStoreApplication) OfferSnapshot(_ context.Context, snapshot *abcitypes.RequestOfferSnapshot) (*abcitypes.ResponseOfferSnapshot, error) {
    return &abcitypes.ResponseOfferSnapshot{}, nil
}

func (app *KVStoreApplication) LoadSnapshotChunk(_ context.Context, chunk *abcitypes.RequestLoadSnapshotChunk) (*abcitypes.ResponseLoadSnapshotChunk, error) {
    return &abcitypes.ResponseLoadSnapshotChunk{}, nil
}

func (app *KVStoreApplication) ApplySnapshotChunk(_ context.Context, chunk *abcitypes.RequestApplySnapshotChunk) (*abcitypes.ResponseApplySnapshotChunk, error) {
    return &abcitypes.ResponseApplySnapshotChunk{Result: abcitypes.ResponseApplySnapshotChunk_ACCEPT}, nil
}

func (app KVStoreApplication) ExtendVote(_ context.Context, extend *abcitypes.RequestExtendVote) (*abcitypes.ResponseExtendVote, error) {
    return &abcitypes.ResponseExtendVote{}, nil
}

func (app *KVStoreApplication) VerifyVoteExtension(_ context.Context, verify *abcitypes.RequestVerifyVoteExtension) (*abcitypes.ResponseVerifyVoteExtension, error) {
    return &abcitypes.ResponseVerifyVoteExtension{}, nil
}

The types used here are defined in the CometBFT library and were added as a dependency to the project when you ran go get. If your IDE is not recognizing the types, go ahead and run the command again.

go get github.com/cometbft/cometbft@v0.38.0

Now go back to the main.go and modify the main function so it matches the following, where an instance of the KVStoreApplication type is created.

func main() {
    fmt.Println("Hello, CometBFT")

    _ = NewKVStoreApplication()
}

You can recompile and run the application now by running go get and go build, but it does not do anything. So let’s revisit the code adding the logic needed to implement our minimal key/value store and to start it along with the CometBFT Service.

1.3.1 Add a persistent data store

Our application will need to write its state out to persistent storage so that it can stop and start without losing all of its data.

For this tutorial, we will use BadgerDB, a fast embedded key-value store.

First, add Badger as a dependency of your go module using the go get command:

go get github.com/dgraph-io/badger/v3

Next, let’s update the application and its constructor to receive a handle to the database, as follows:

type KVStoreApplication struct {
    db           *badger.DB
    onGoingBlock *badger.Txn
}

var _ abcitypes.Application = (*KVStoreApplication)(nil)

func NewKVStoreApplication(db *badger.DB) *KVStoreApplication {
    return &KVStoreApplication{db: db}
}

The onGoingBlock keeps track of the Badger transaction that will update the application’s state when a block is completed. Don’t worry about it for now, we’ll get to that later.

Next, update the import stanza at the top to include the Badger library:

import(
    "github.com/dgraph-io/badger/v3"
    abcitypes "github.com/cometbft/cometbft/abci/types"
)

Finally, update the main.go file to invoke the updated constructor:

    _ = NewKVStoreApplication(nil)

1.3.2 CheckTx

When CometBFT receives a new transaction from a client, or from another full node, CometBFT asks the application if the transaction is acceptable, using the CheckTx method. Invalid transactions will not be shared with other nodes and will not become part of any blocks and, therefore, will not be executed by the application.

In our application, a transaction is a string with the form key=value, indicating a key and value to write to the store.

The most basic validation check we can perform is to check if the transaction conforms to the key=value pattern. For that, let’s add the following helper method to app.go:

func (app *KVStoreApplication) isValid(tx []byte) uint32 {
    // check format
    parts := bytes.Split(tx, []byte("="))
    if len(parts) != 2 {
        return 1
    }

    return 0
}

Now you can rewrite the CheckTx method to use the helper function:

func (app *KVStoreApplication) CheckTx(_ context.Context, check *abcitypes.RequestCheckTx) (*abcitypes.ResponseCheckTx, error) {
    code := app.isValid(check.Tx)
    return &abcitypes.ResponseCheckTx{Code: code}, nil
}

While this CheckTx is simple and only validates that the transaction is well-formed, it is very common for CheckTx to make more complex use of the state of an application. For example, you may refuse to overwrite an existing value, or you can associate versions to the key/value pairs and allow the caller to specify a version to perform a conditional update.

Depending on the checks and on the conditions violated, the function may return different values, but any response with a non-zero code will be considered invalid by CometBFT. Our CheckTx logic returns 0 to CometBFT when a transaction passes its validation checks. The specific value of the code is meaningless to CometBFT. Non-zero codes are logged by CometBFT so applications can provide more specific information on why the transaction was rejected.

Note that CheckTx does not execute the transaction, it only verifies that the transaction could be executed. We do not know yet if the rest of the network has agreed to accept this transaction into a block.

Finally, make sure to add the bytes package to the import stanza at the top of app.go:

import(
    "bytes"

    "github.com/dgraph-io/badger/v3"
    abcitypes "github.com/cometbft/cometbft/abci/types"
)

1.3.3 FinalizeBlock

When the CometBFT consensus engine has decided on the block, the block is transferred to the application via FinalizeBlock. FinalizeBlock is an ABCI method introduced in CometBFT v0.38.0. This replaces the functionality provided previously (pre-v0.38.0) by the combination of ABCI methods BeginBlock, DeliverTx, and EndBlock. FinalizeBlock’s parameters are an aggregation of those in BeginBlock, DeliverTx, and EndBlock.

This method is responsible for executing the block and returning a response to the consensus engine. Providing a single FinalizeBlock method to signal the finalization of a block simplifies the ABCI interface and increases flexibility in the execution pipeline.

The FinalizeBlock method executes the block, including any necessary transaction processing and state updates, and returns a ResponseFinalizeBlock object which contains any necessary information about the executed block.

Note: FinalizeBlock only prepares the update to be made and does not change the state of the application. The state change is actually committed in a later stage i.e. in commit phase.

Note that, to implement these calls in our application we’re going to make use of Badger’s transaction mechanism. We will always refer to these as Badger transactions, not to confuse them with the transactions included in the blocks delivered by CometBFT, the application transactions.

First, let’s create a new Badger transaction during FinalizeBlock. All application transactions in the current block will be executed within this Badger transaction. Next, let’s modify FinalizeBlock to add the key and value to the Badger transaction every time our application processes a new application transaction from the list received through RequestFinalizeBlock.

Note that we check the validity of the transaction again during FinalizeBlock.

func (app *KVStoreApplication) FinalizeBlock(_ context.Context, req *abcitypes.RequestFinalizeBlock) (*abcitypes.ResponseFinalizeBlock, error) {
    var txs = make([]*abcitypes.ExecTxResult, len(req.Txs))

    app.onGoingBlock = app.db.NewTransaction(true)
    for i, tx := range req.Txs {
        if code := app.isValid(tx); code != 0 {
            log.Printf("Error: invalid transaction index %v", i)
            txs[i] = &abcitypes.ExecTxResult{Code: code}
        } else {
            parts := bytes.SplitN(tx, []byte("="), 2)
            key, value := parts[0], parts[1]
            log.Printf("Adding key %s with value %s", key, value)

            if err := app.onGoingBlock.Set(key, value); err != nil {
                log.Panicf("Error writing to database, unable to execute tx: %v", err)
            }

            log.Printf("Successfully added key %s with value %s", key, value)

            txs[i] = &abcitypes.ExecTxResult{}
        }
    }

    return &abcitypes.ResponseFinalizeBlock{
      TxResults:        txs,
    }, nil
}

Transactions are not guaranteed to be valid when they are delivered to an application, even if they were valid when they were proposed.

This can happen if the application state is used to determine transaction validity. The application state may have changed between the initial execution of CheckTx and the transaction delivery in FinalizeBlock in a way that rendered the transaction no longer valid.

Note that FinalizeBlock cannot yet commit the Badger transaction we were building during the block execution.

Other methods, such as Query, rely on a consistent view of the application’s state, the application should only update its state by committing the Badger transactions when the full block has been delivered and the Commit method is invoked.

The Commit method tells the application to make permanent the effects of the application transactions. Let’s update the method to terminate the pending Badger transaction and persist the resulting state:

func (app KVStoreApplication) Commit(_ context.Context, commit *abcitypes.RequestCommit) (*abcitypes.ResponseCommit, error) {
    return &abcitypes.ResponseCommit{}, app.onGoingBlock.Commit()
}

Finally, make sure to add the log library to the import stanza as well:

import (
    "bytes"
    "log"

    "github.com/dgraph-io/badger/v3"
    abcitypes "github.com/cometbft/cometbft/abci/types"
)

You may have noticed that the application we are writing will crash if it receives an unexpected error from the Badger database during the FinalizeBlock or Commit methods. This is not an accident. If the application received an error from the database, there is no deterministic way for it to make progress so the only safe option is to terminate. Once the application is restarted, the transactions in the block that failed execution will be re-executed and should succeed if the Badger error was transient.

1.3.4 Query

When a client tries to read some information from the kvstore, the request will be handled in the Query method. To do this, let’s rewrite the Query method in app.go:

func (app *KVStoreApplication) Query(_ context.Context, req *abcitypes.RequestQuery) (*abcitypes.ResponseQuery, error) {
    resp := abcitypes.ResponseQuery{Key: req.Data}

    dbErr := app.db.View(func(txn *badger.Txn) error {
        item, err := txn.Get(req.Data)
        if err != nil {
            if err != badger.ErrKeyNotFound {
                return err
            }
            resp.Log = "key does not exist"
            return nil
        }

        return item.Value(func(val []byte) error {
            resp.Log = "exists"
            resp.Value = val
            return nil
        })
    })
    if dbErr != nil {
        log.Panicf("Error reading database, unable to execute query: %v", dbErr)
    }
    return &resp, nil
}

Since it reads only committed data from the store, transactions that are part of a block that is being processed are not reflected in the query result.

1.3.5 PrepareProposal and ProcessProposal

PrepareProposal and ProcessProposal are methods introduced in CometBFT v0.37.0 to give the application more control over the construction and processing of transaction blocks.

When CometBFT sees that valid transactions (validated through CheckTx) are available to be included in blocks, it groups some of these transactions and then gives the application a chance to modify the group by invoking PrepareProposal.

The application is free to modify the group before returning from the call, as long as the resulting set does not use more bytes than RequestPrepareProposal.max_tx_bytes For example, the application may reorder, add, or even remove transactions from the group to improve the execution of the block once accepted.

In the following code, the application simply returns the unmodified group of transactions:

func (app *KVStoreApplication) PrepareProposal(_ context.Context, proposal *abcitypes.RequestPrepareProposal) (*abcitypes.ResponsePrepareProposal, error) {
    return &abcitypes.ResponsePrepareProposal{Txs: proposal.Txs}, nil
}

Once a proposed block is received by a node, the proposal is passed to the application to give its blessing before voting to accept the proposal.

This mechanism may be used for different reasons, for example to deal with blocks manipulated by malicious nodes, in which case the block should not be considered valid.

The following code simply accepts all proposals:

func (app *KVStoreApplication) ProcessProposal(_ context.Context, proposal *abcitypes.RequestProcessProposal) (*abcitypes.ResponseProcessProposal, error) {
    return &abcitypes.ResponseProcessProposal{Status: abcitypes.ResponseProcessProposal_ACCEPT}, nil
}

1.4 Starting an application and a CometBFT instance in the same process

Now that we have the basic functionality of our application in place, let’s put it all together inside of our main.go file.

Change the contents of your main.go file to the following.

package main

import (
    "flag"
    "fmt"
    "github.com/cometbft/cometbft/p2p"
    "github.com/cometbft/cometbft/privval"
    "github.com/cometbft/cometbft/proxy"
    "log"
    "os"
    "os/signal"
    "path/filepath"
    "syscall"

    "github.com/dgraph-io/badger/v3"
    "github.com/spf13/viper"
    cfg "github.com/cometbft/cometbft/config"
    cmtflags "github.com/cometbft/cometbft/libs/cli/flags"
    cmtlog "github.com/cometbft/cometbft/libs/log"
    nm "github.com/cometbft/cometbft/node"
)

var homeDir string

func init() {
    flag.StringVar(&homeDir, "cmt-home", "", "Path to the CometBFT config directory (if empty, uses $HOME/.cometbft)")
}

func main() {
    flag.Parse()
    if homeDir == "" {
        homeDir = os.ExpandEnv("$HOME/.cometbft")
    }

    config := cfg.DefaultConfig()
    config.SetRoot(homeDir)
    viper.SetConfigFile(fmt.Sprintf("%s/%s", homeDir, "config/config.toml"))

    if err := viper.ReadInConfig(); err != nil {
        log.Fatalf("Reading config: %v", err)
    }
    if err := viper.Unmarshal(config); err != nil {
        log.Fatalf("Decoding config: %v", err)
    }
    if err := config.ValidateBasic(); err != nil {
        log.Fatalf("Invalid configuration data: %v", err)
    }
    dbPath := filepath.Join(homeDir, "badger")
    db, err := badger.Open(badger.DefaultOptions(dbPath))

    if err != nil {
        log.Fatalf("Opening database: %v", err)
    }
    defer func() {
        if err := db.Close(); err != nil {
            log.Printf("Closing database: %v", err)
        }
    }()

    app := NewKVStoreApplication(db)

    pv := privval.LoadFilePV(
        config.PrivValidatorKeyFile(),
        config.PrivValidatorStateFile(),
    )

    nodeKey, err := p2p.LoadNodeKey(config.NodeKeyFile())
    if err != nil {
        log.Fatalf("failed to load node's key: %v", err)
    }

    logger := cmtlog.NewTMLogger(cmtlog.NewSyncWriter(os.Stdout))
    logger, err = cmtflags.ParseLogLevel(config.LogLevel, logger, cfg.DefaultLogLevel)

    if err != nil {
        log.Fatalf("failed to parse log level: %v", err)
    }

    node, err := nm.NewNode(
        config,
        pv,
        nodeKey,
        proxy.NewLocalClientCreator(app),
        nm.DefaultGenesisDocProviderFunc(config),
        cfg.DefaultDBProvider,
        nm.DefaultMetricsProvider(config.Instrumentation),
        logger,
    )

    if err != nil {
        log.Fatalf("Creating node: %v", err)
    }

    node.Start()
    defer func() {
        node.Stop()
        node.Wait()
    }()

    c := make(chan os.Signal, 1)
    signal.Notify(c, os.Interrupt, syscall.SIGTERM)
    <-c
}

This is a huge blob of code, so let’s break it down into pieces.

First, we use viper to load the CometBFT configuration files, which we will generate later:

config := cfg.DefaultValidatorConfig()

config.SetRoot(homeDir)

viper.SetConfigFile(fmt.Sprintf("%s/%s", homeDir, "config/config.toml"))
if err := viper.ReadInConfig(); err != nil {
    log.Fatalf("Reading config: %v", err)
}
if err := viper.Unmarshal(config); err != nil {
    log.Fatalf("Decoding config: %v", err)
}
if err := config.ValidateBasic(); err != nil {
    log.Fatalf("Invalid configuration data: %v", err)
}

Next, we initialize the Badger database and create an app instance.

dbPath := filepath.Join(homeDir, "badger")
db, err := badger.Open(badger.DefaultOptions(dbPath))
if err != nil {
    log.Fatalf("Opening database: %v", err)
}
defer func() {
    if err := db.Close(); err != nil {
        log.Fatalf("Closing database: %v", err)
    }
}()

app := NewKVStoreApplication(db)

We use FilePV, which is a private validator (i.e. thing which signs consensus messages). Normally, you would use SignerRemote to connect to an external HSM.

pv := privval.LoadFilePV(
    config.PrivValidatorKeyFile(),
    config.PrivValidatorStateFile(),
)

nodeKey is needed to identify the node in a p2p network.

nodeKey, err := p2p.LoadNodeKey(config.NodeKeyFile())
if err != nil {
    return nil, fmt.Errorf("failed to load node's key: %w", err)
}

Now we have everything set up to run the CometBFT node. We construct a node by passing it the configuration, the logger, a handle to our application and the genesis information:

node, err := nm.NewNode(
    config,
    pv,
    nodeKey,
    proxy.NewLocalClientCreator(app),
    nm.DefaultGenesisDocProviderFunc(config),
    cfg.DefaultDBProvider,
    nm.DefaultMetricsProvider(config.Instrumentation),
    logger)

if err != nil {
    log.Fatalf("Creating node: %v", err)
}

Finally, we start the node, i.e., the CometBFT service inside our application:

node.Start()
defer func() {
    node.Stop()
    node.Wait()
}()

The additional logic at the end of the file allows the program to catch SIGTERM. This means that the node can shut down gracefully when an operator tries to kill the program:

c := make(chan os.Signal, 1)
signal.Notify(c, os.Interrupt, syscall.SIGTERM)
<-c

1.5 Initializing and Running

Our application is almost ready to run, but first we’ll need to populate the CometBFT configuration files. The following command will create a cometbft-home directory in your project and add a basic set of configuration files in cometbft-home/config/. For more information on what these files contain see the configuration documentation.

From the root of your project, run:

go run github.com/cometbft/cometbft/cmd/cometbft@v0.38.0 init --home /tmp/cometbft-home

You should see an output similar to the following:

I[2023-25-04|09:06:34.444] Generated private validator                  module=main keyFile=/tmp/cometbft-home/config/priv_validator_key.json stateFile=/tmp/cometbft-home/data/priv_validator_state.json
I[2023-25-04|09:06:34.444] Generated node key                           module=main path=/tmp/cometbft-home/config/node_key.json
I[2023-25-04|09:06:34.444] Generated genesis file                       module=main path=/tmp/cometbft-home/config/genesis.json

Now rebuild the app:

go build -mod=mod # use -mod=mod to automatically refresh the dependencies

Everything is now in place to run your application. Run:

./kvstore -cmt-home /tmp/cometbft-home

The application will start and you should see a continuous output starting with:

badger 2023-04-25 09:08:50 INFO: All 0 tables opened in 0s
badger 2023-04-25 09:08:50 INFO: Discard stats nextEmptySlot: 0
badger 2023-04-25 09:08:50 INFO: Set nextTxnTs to 0
I[2023-04-25|09:08:50.085] service start                                module=proxy msg="Starting multiAppConn service" impl=multiAppConn
I[2023-04-25|09:08:50.085] service start                                module=abci-client connection=query msg="Starting localClient service" impl=localClient
I[2023-04-25|09:08:50.085] service start                                module=abci-client connection=snapshot msg="Starting localClient service" impl=localClient
...

More importantly, the application using CometBFT is producing blocks 🎉🎉 and you can see this reflected in the log output in lines like this:

I[2023-04-25|09:08:52.147] received proposal                            module=consensus proposal="Proposal{2/0 (F518444C0E348270436A73FD0F0B9DFEA758286BEB29482F1E3BEA75330E825C:1:C73D3D1273F2, -1) AD19AE292A45 @ 2023-04-25T12:08:52.143393Z}"
I[2023-04-25|09:08:52.152] received complete proposal block             module=consensus height=2 hash=F518444C0E348270436A73FD0F0B9DFEA758286BEB29482F1E3BEA75330E825C
I[2023-04-25|09:08:52.160] finalizing commit of block                   module=consensus height=2 hash=F518444C0E348270436A73FD0F0B9DFEA758286BEB29482F1E3BEA75330E825C root= num_txs=0
I[2023-04-25|09:08:52.167] executed block                               module=state height=2 num_valid_txs=0 num_invalid_txs=0
I[2023-04-25|09:08:52.171] committed state                              module=state height=2 num_txs=0 app_hash=

The blocks, as you can see from the num_valid_txs=0 part, are empty, but let’s remedy that next.

1.6 Using the application

Let’s try submitting a transaction to our new application. Open another terminal window and run the following curl command:

curl -s 'localhost:26657/broadcast_tx_commit?tx="cometbft=rocks"'

If everything went well, you should see a response indicating which height the transaction was included in the blockchain.

Finally, let’s make sure that transaction really was persisted by the application. Run the following command:

curl -s 'localhost:26657/abci_query?data="cometbft"'

Let’s examine the response object that this request returns. The request returns a json object with a key and value field set.

...
    "key": "dGVuZGVybWludA==",
    "value": "cm9ja3M=",
...

Those values don’t look like the key and value we sent to CometBFT. What’s going on here?

The response contains a base64 encoded representation of the data we submitted. To get the original value out of this data, we can use the base64 command line utility:

echo "cm9ja3M=" | base64 -d

Outro

Hope you could run everything smoothly. If you have any difficulties running through this tutorial, reach out to us via discord or open a new issue on Github.

Decorative Orb