# Generating, Signing and Broadcasting Transactions

This document describes how to generate an (unsigned) transaction, signing it (with one or multiple keys), and broadcasting it to the network.

# Using the CLI

The easiest way to send transactions is using the CLI, as we have seen in the previous page when interacting with a node. For example, running the following command

Copy simd tx bank send $MY_VALIDATOR_ADDRESS $RECIPIENT 1000stake --chain-id my-test-chain --keyring-backend test

will run the following steps:

  • generate a transaction with one Msg (x/bank's MsgSend), and print the generated transaction to the console.
  • ask the user for confirmation to send the transaction from the $MY_VALIDATOR_ADDRESS account.
  • fetch $MY_VALIDATOR_ADDRESS from the keyring. This is possible because we have set up the CLI's keyring in a previous step.
  • sign the generated transaction with the keyring's account.
  • broadcast the signed transaction to the network. This is possible because the CLI connects to the node's Tendermint RPC endpoint.

The CLI bundles all the necessary steps into a simple-to-use user experience. However, it's possible to run all the steps individually too.

# Generating a Transaction

Generating a transaction can simply be done by appending the --generate-only flag on any tx command, e.g.:

Copy simd tx bank send $MY_VALIDATOR_ADDRESS $RECIPIENT 1000stake --chain-id my-test-chain --generate-only

This will output the unsigned transaction as JSON in the console. We can also save the unsigned transaction to a file (to be passed around between signers more easily) by appending > unsigned_tx.json to the above command.

# Signing a Transaction

Signing a transaction using the CLI requires the unsigned transaction to be saved in a file. Let's assume the unsigned transaction is in a file called unsigned_tx.json in the current directory (see previous paragraph on how to do that). Then, simply run the following command:

Copy simd tx sign unsigned_tx.json --chain-id my-test-chain --keyring-backend test --from $MY_VALIDATOR_ADDRESS

This command will decode the unsigned transaction and sign it with SIGN_MODE_DIRECT with $MY_VALIDATOR_ADDRESS's key, which we already set up in the keyring. The signed transaction will be output as JSON to the console, and, as above, we can save it to a file by appending > signed_tx.json.

Some useful flags to consider in the tx sign command:

  • --sign-mode: you may use amino-json to sign the transaction using SIGN_MODE_LEGACY_AMINO_JSON,
  • --offline: sign in offline mode. This means that the tx sign command doesn't connect to the node to retrieve the signer's account number and sequence, both needed for signing. In this case, you must manually supply the --account-number and --sequence flags. This is useful for offline signing, i.e. signing in a secure environment which doesn't have access to the internet.

# Signing with Multiple Signers

Please note that signing a transaction with multiple signers or with a multisig account, where at least one signer uses SIGN_MODE_DIRECT, is not yet possible. You may follow this Github issue (opens new window) for more info.

Signing with multiple signers is done with the tx multisign command. This command assumes that all signers use SIGN_MODE_LEGACY_AMINO_JSON. The flow is similar to the tx sign command flow, but instead of signing an unsigned transaction file, each signer signs the file signed by previous signer(s). The tx multisign command will append signatures to the existing transactions. It is important that signers sign the transaction in the same order as given by the transaction, which is retrievable using the GetSigners() method.

For example, starting with the unsigned_tx.json, and assuming the transaction has 4 signers, we would run:

Copy # Let signer1 sign the unsigned tx. simd tx multisignsign unsigned_tx.json signer_key_1 --chain-id my-test-chain --keyring-backend test > partial_tx_1.json # Now signer1 will send the partial_tx_1.json to the signer2. # Signer2 appends their signature: simd tx multisignsign partial_tx_1.json signer_key_2 --chain-id my-test-chain --keyring-backend test > partial_tx_2.json # Signer2 sends the partial_tx_2.json file to signer3, and signer3 can append his signature: simd tx multisignsign partial_tx_2.json signer_key_3 --chain-id my-test-chain --keyring-backend test > partial_tx_3.json

# Broadcasting a Transaction

Broadcasting a transaction is done using the following command:

Copy simd tx broadcast tx_signed.json

You may optionally pass the --broadcast-mode flag to specify which response to receive from the node:

  • block: the CLI waits for the tx to be committed in a block.
  • sync: the CLI waits for a CheckTx execution response only.
  • async: the CLI returns immediately (transaction might fail).

# Programmatically with Go

It is possible to manipulate transactions programmatically via Go using the Cosmos SDK's TxBuilder interface.

# Generating a Transaction

Before generating a transaction, a new instance of a TxBuilder needs to be created. Since the SDK supports both Amino and Protobuf transactions, the first step would be to decide which encoding scheme to use. All the subsequent steps remain unchanged, whether you're using Amino or Protobuf, as TxBuilder abstracts the encoding mechanisms. In the following snippet, we will use Protobuf.

Copy import ( "github.com/cosmos/cosmos-sdk/simapp" ) func sendTx() error { // Choose your codec: Amino or Protobuf. Here, we use Protobuf, given by the // following function. encCfg := simapp.MakeTestEncodingConfig() // Create a new TxBuilder. txBuilder := encCfg.TxConfig.NewTxBuilder() // --snip-- }

We can also set up some keys and addresses that will send and receive the transactions. Here, for the purpose of the tutorial, we will be using some dummy data to create keys.

Copy import ( "github.com/cosmos/cosmos-sdk/testutil/testdata" ) priv1, _, addr1 := testdata.KeyTestPubAddr() priv2, _, addr2 := testdata.KeyTestPubAddr() priv3, _, addr3 := testdata.KeyTestPubAddr()

Populating the TxBuilder can be done via its methods (opens new window):

Copy import ( banktypes "github.com/cosmos/cosmos-sdk/x/bank/types" ) func sendTx() error { // --snip-- // Define two x/bank MsgSend messages: // - from addr1 to addr3, // - from addr2 to addr3. // This means that the transactions needs two signers: addr1 and addr2. msg1 := banktypes.NewMsgSend(addr1, addr3, types.NewCoins(types.NewInt64Coin("atom", 12))) msg2 := banktypes.NewMsgSend(addr2, addr3, types.NewCoins(types.NewInt64Coin("atom", 34))) err := txBuilder.SetMsgs(msg1, msg2) if err != nil { return err } txBuilder.SetGasLimit(...) txBuilder.SetFeeAmount(...) txBuilder.SetMemo(...) txBuilder.SetTimeoutHeight(...) }

At this point, TxBuilder's underlying transaction is ready to be signed.

# Signing a Transaction

We set encoding config to use Protobuf, which will use SIGN_MODE_DIRECT by default. As per ADR-020 (opens new window), each signer needs to sign the SignerInfos of all other signers. This means that we need to perform two steps sequentially:

  • for each signer, populate the signer's SignerInfo inside TxBuilder,
  • once all SignerInfos are populated, for each signer, sign the SignDoc (the payload to be signed).

In the current TxBuilder's API, both steps are done using the same method: SetSignatures(). The current API requires us to first perform a round of SetSignatures() with empty signatures, only to populate SignerInfos, and a second round of SetSignatures() to actually sign the correct payload.

Copy import ( cryptotypes "github.com/cosmos/cosmos-sdk/crypto/types" "github.com/cosmos/cosmos-sdk/types/tx/signing" xauthsigning "github.com/cosmos/cosmos-sdk/x/auth/signing" ) func sendTx() error { // --snip-- privs := []cryptotypes.PrivKey{priv1, priv2} accNums:= []uint64{..., ...} // The accounts' account numbers accSeqs:= []uint64{..., ...} // The accounts' sequence numbers // First round: we gather all the signer infos. We use the "set empty // signature" hack to do that. var sigsV2 []signing.SignatureV2 for i, priv := range privs { sigV2 := signing.SignatureV2{ PubKey: priv.PubKey(), Data: &signing.SingleSignatureData{ SignMode: encCfg.TxConfig.SignModeHandler().DefaultMode(), Signature: nil, }, Sequence: accSeqs[i], } sigsV2 = append(sigsV2, sigV2) } err := txBuilder.SetSignatures(sigsV2...) if err != nil { return err } // Second round: all signer infos are set, so each signer can sign. sigsV2 = []signing.SignatureV2{} for i, priv := range privs { signerData := xauthsigning.SignerData{ ChainID: chainID, AccountNumber: accNums[i], Sequence: accSeqs[i], } sigV2, err := tx.SignWithPrivKey( encCfg.TxConfig.SignModeHandler().DefaultMode(), signerData, txBuilder, priv, encCfg.TxConfig, accSeqs[i]) if err != nil { return nil, err } sigsV2 = append(sigsV2, sigV2) } err = txBuilder.SetSignatures(sigsV2...) if err != nil { return err } }

The TxBuilder is now correctly populated. To print it, you can use the TxConfig interface from the initial encoding config encCfg:

Copy func sendTx() error { // --snip-- // Generated Protobuf-encoded bytes. txBytes, err := encCfg.TxConfig.TxEncoder()(txBuilder.GetTx()) if err != nil { return err } // Generate a JSON string. txJSONBytes, err := encCfg.TxConfig.TxJSONEncoder()(txBuilder.GetTx()) if err != nil { return err } txJSON := string(txJSONBytes) }

# Broadcasting a Transaction

The preferred way to broadcast a transaction is to use gRPC, though using REST (via gRPC-gateway) or the Tendermint RPC is also posible. An overview of the differences between these methods is exposed here. For this tutorial, we will only describe the gRPC method.

Copy import ( "context" "fmt" "google.golang.org/grpc" "github.com/cosmos/cosmos-sdk/types/tx" ) func sendTx(ctx context.Context) error { // --snip-- // Create a connection to the gRPC server. grpcConn := grpc.Dial( "127.0.0.1:9090", // Or your gRPC server address. grpc.WithInsecure(), // The SDK doesn't support any transport security mechanism. ) defer grpcConn.Close() // Broadcast the tx via gRPC. We create a new client for the Protobuf Tx // service. txClient := tx.NewServiceClient(grpcConn) // We then call the BroadcastTx method on this client. grpcRes, err := txClient.BroadcastTx( ctx, &tx.BroadcastTxRequest{ Mode: tx.BroadcastMode_BROADCAST_MODE_SYNC, TxBytes: txBytes, // Proto-binary of the signed transaction, see previous step. }, ) if err != nil { return err } fmt.Println(grpcRes.TxResponse.Code) // Should be `0` if the tx is successful return nil }

# Simulating a Transaction

Before broadcasting a transaction, we sometimes may want to dry-run the transaction, to estimate some information about the transaction without actually committing it. This is called simulating a transaction, and can be done as follows:

Copy import ( "context" "fmt" "testing" "github.com/cosmos/cosmos-sdk/client" "github.com/cosmos/cosmos-sdk/types/tx" authtx "github.com/cosmos/cosmos-sdk/x/auth/tx" ) func simulateTx() error { // --snip-- // Simulate the tx via gRPC. We create a new client for the Protobuf Tx // service. txClient := tx.NewServiceClient(grpcConn) txBytes := /* Fill in with your signed transaction bytes. */ // We then call the Simulate method on this client. grpcRes, err := txClient.Simulate( context.Background(), &tx.SimulateRequest{ TxBytes: txBytes, }, ) if err != nil { return err } fmt.Println(grpcRes.GasInfo) // Prints estimated gas used. return nil }

# Using REST

It is not possible to generate or sign a transaction using REST, only to broadcast one.

# Broadcasting a Transaction

Broadcasting a transaction using the REST endpoint (served by gRPC-gateway) can be done by sending a POST request as follows, where the txBytes are the protobuf-encoded bytes of a signed transaction:

Copy curl -X POST \ -H "Content-Type: application/json" -d'{"tx_bytes":"{{txBytes}}","mode":"BROADCAST_MODE_SYNC"}' localhost:1317/cosmos/tx/v1beta1/txs

# Using CosmJS (JavaScript & TypeScript)

CosmJS aims to build client libraries in JavaScript that can be embedded in web applications. Please see https://cosmos.github.io/cosmjs (opens new window) for more information. As of January 2021, CosmJS documentation is still work in progress.