Invoke a contract function in a Stellar transaction using SDKs

This is a simple example using the Stellar SDK to create, simulate, and then assemble a Stellar transaction which invokes an increment function of the auth example contract.

JavaScript

tip

Please go to the project homepage of JavaScript SDK to learn how to install it.

(async () => {
  const {
    Keypair,
    Contract,
    SorobanRpc,
    TransactionBuilder,
    Networks,
    BASE_FEE,
    nativeToScVal,
    Address,
  } = require("@stellar/stellar-sdk");

  // The source account will be used to sign and send the transaction.
  // GCWY3M4VRW4NXJRI7IVAU3CC7XOPN6PRBG6I5M7TAOQNKZXLT3KAH362
  const sourceKeypair = Keypair.fromSecret(
    "SCQN3XGRO65BHNSWLSHYIR4B65AHLDUQ7YLHGIWQ4677AZFRS77TCZRB",
  );

  // Configure SorobanClient to use the `stellar-rpc` instance of your
  // choosing.
  const server = new SorobanRpc.Server(
    "https://soroban-testnet.stellar.org:443",
  );

  // Here we will use a deployed instance of the `increment` example contract.
  const contractAddress =
    "CCTAMZGXBVCQJJCX64EVYTM6BKW5BXDI5PRCXTAYT6DVEDXKGS347HWU";
  const contract = new Contract(contractAddress);

  // Transactions require a valid sequence number (which varies from one
  // account to another). We fetch this sequence number from the RPC server.
  const sourceAccount = await server.getAccount(sourceKeypair.publicKey());

  // The transaction begins as pretty standard. The source account, minimum
  // fee, and network passphrase are provided.
  let builtTransaction = new TransactionBuilder(sourceAccount, {
    fee: BASE_FEE,
    networkPassphrase: Networks.TESTNET,
  })
    // The invocation of the `increment` function of our contract is added
    // to the transaction.
    .addOperation(
      contract.call(
        "increment",
        nativeToScVal(Address.fromString(sourceKeypair.publicKey())),
        nativeToScVal(5, { type: "u32" }),
      ),
    )
    // This transaction will be valid for the next 30 seconds
    .setTimeout(30)
    .build();

  console.log(`builtTransaction=${builtTransaction.toXDR()}`);

  // We use the RPC server to "prepare" the transaction. This simulating the
  // transaction, discovering the storage footprint, and updating the
  // transaction to include that footprint. If you know the footprint ahead of
  // time, you could manually use `addFootprint` and skip this step.
  let preparedTransaction = await server.prepareTransaction(builtTransaction);

  // Sign the transaction with the source account's keypair.
  preparedTransaction.sign(sourceKeypair);

  // Let's see the base64-encoded XDR of the transaction we just built.
  console.log(
    `Signed prepared transaction XDR: ${preparedTransaction
      .toEnvelope()
      .toXDR("base64")}`,
  );

  // Submit the transaction to the Stellar-RPC server. The RPC server will
  // then submit the transaction into the network for us. Then we will have to
  // wait, polling `getTransaction` until the transaction completes.
  try {
    let sendResponse = await server.sendTransaction(preparedTransaction);
    console.log(`Sent transaction: ${JSON.stringify(sendResponse)}`);

    if (sendResponse.status === "PENDING") {
      let getResponse = await server.getTransaction(sendResponse.hash);
      // Poll `getTransaction` until the status is not "NOT_FOUND"
      while (getResponse.status === "NOT_FOUND") {
        console.log("Waiting for transaction confirmation...");
        // See if the transaction is complete
        getResponse = await server.getTransaction(sendResponse.hash);
        // Wait one second
        await new Promise((resolve) => setTimeout(resolve, 1000));
      }

      console.log(`getTransaction response: ${JSON.stringify(getResponse)}`);

      if (getResponse.status === "SUCCESS") {
        // Make sure the transaction's resultMetaXDR is not empty
        if (!getResponse.resultMetaXdr) {
          throw "Empty resultMetaXDR in getTransaction response";
        }
        // Find the return value from the contract and return it
        let transactionMeta = getResponse.resultMetaXdr;
        let returnValue = transactionMeta.v3().sorobanMeta().returnValue();
        console.log(`Transaction result: ${returnValue.value()}`);
      } else {
        throw `Transaction failed: ${getResponse.resultXdr}`;
      }
    } else {
      throw sendResponse.errorResultXdr;
    }
  } catch (err) {
    // Catch and report any errors we've thrown
    console.log("Sending transaction failed");
    console.log(JSON.stringify(err));
  }
})();

Python

tip

Please go to the project homepage of Python SDK to learn how to install it.

In addition, Python provides a lot of example code, which you can find here.

import time

from stellar_sdk import Keypair, Network, SorobanServer, TransactionBuilder, scval
from stellar_sdk import xdr as stellar_xdr
from stellar_sdk.exceptions import PrepareTransactionException
from stellar_sdk.soroban_rpc import GetTransactionStatus, SendTransactionStatus

secret = "SAAPYAPTTRZMCUZFPG3G66V4ZMHTK4TWA6NS7U4F7Z3IMUD52EK4DDEV"
rpc_server_url = "https://soroban-testnet.stellar.org:443"
network_passphrase = Network.TESTNET_NETWORK_PASSPHRASE

# Here we will use a deployed instance of the `increment` example contract.
contract_id = "CDOGJBJMRVVXW5K3UJ5BGVJ5RSQXQB4UFVQYVFOIARC2UYXSEPF4YAVR"
# The source account will be used to sign and send the transaction.
source_keypair = Keypair.from_secret(secret)
# Configure SorobanClient to use the `stellar-rpc` instance of your choosing.
soroban_server = SorobanServer(rpc_server_url)
# Transactions require a valid sequence number (which varies from one account to another).
# We fetch this sequence number from the RPC server.
source = soroban_server.load_account(source_keypair.public_key)

tx = (
    # The transaction begins as pretty standard. The source account, minimum fee,
    # and network passphrase are provided.
    TransactionBuilder(source, network_passphrase, base_fee=100)
    # This transaction will be valid for the next 30 seconds
    .set_timeout(30)
    # The invocation of the `increment` function of our contract is added to the transaction.
    .append_invoke_contract_function_op(
        contract_id=contract_id,
        function_name="increment",
        parameters=[scval.to_address(source_keypair.public_key), scval.to_uint32(5)],
    ).build()
)

print(f"builtTransaction: {tx.to_xdr()}")

try:
    # We use the RPC server to "prepare" the transaction. This simulating the
    # transaction, discovering the soroban data, and updating the
    # transaction to include that soroban data. If you know the soroban data ahead of
    # time, you could manually use `set_soroban_data` and skip this step.
    tx = soroban_server.prepare_transaction(tx)
except PrepareTransactionException as e:
    print(f"Prepare Transaction Failed: {e.simulate_transaction_response}")
    raise e

# Sign the transaction with the source account's keypair.
tx.sign(source_keypair)

# Let's see the base64-encoded XDR of the transaction we just built.
print(f"Signed prepared transaction XDR: {tx.to_xdr()}")

# Submit the transaction to the Stellar-RPC server. The RPC server will
# then submit the transaction into the network for us. Then we will have to
# wait, polling `get_transaction` until the transaction completes.
send_transaction_data = soroban_server.send_transaction(tx)
print(f"Sent transaction: {send_transaction_data}")
if send_transaction_data.status != SendTransactionStatus.PENDING:
    print(send_transaction_data.error_result_xdr)
    raise Exception("Send transaction failed")

while True:
    print("Waiting for transaction to be confirmed...")
    # Poll `get_transaction` until the status is not "NOT_FOUND"
    get_transaction_data = soroban_server.get_transaction(send_transaction_data.hash)
    if get_transaction_data.status != GetTransactionStatus.NOT_FOUND:
        break
    time.sleep(3)

print(f"getTransaction response: {get_transaction_data}")

if get_transaction_data.status == GetTransactionStatus.SUCCESS:
    # The transaction was successful, so we can extract the `result_meta_xdr`
    transaction_meta = stellar_xdr.TransactionMeta.from_xdr(
        get_transaction_data.result_meta_xdr
    )
    result = transaction_meta.v3.soroban_meta.return_value
    # Find the return value from the contract and return it
    print(f"Transaction result: {scval.from_uint32(result)}")
else:
    # The transaction failed, so we can extract the `result_xdr`
    print(f"Transaction failed: {get_transaction_data.result_xdr}")
    raise Exception("Transaction failed")

Java

tip

Please go to the project homepage of Java SDK to learn how to install it.

import org.stellar.sdk.AccountNotFoundException;
import org.stellar.sdk.InvokeHostFunctionOperation;
import org.stellar.sdk.KeyPair;
import org.stellar.sdk.Network;
import org.stellar.sdk.PrepareTransactionException;
import org.stellar.sdk.SorobanServer;
import org.stellar.sdk.Transaction;
import org.stellar.sdk.TransactionBuilder;
import org.stellar.sdk.TransactionBuilderAccount;
import org.stellar.sdk.requests.sorobanrpc.SorobanRpcErrorResponse;
import org.stellar.sdk.responses.sorobanrpc.GetTransactionResponse;
import org.stellar.sdk.responses.sorobanrpc.SendTransactionResponse;
import org.stellar.sdk.scval.Scv;
import org.stellar.sdk.xdr.SCVal;
import org.stellar.sdk.xdr.TransactionMeta;

import java.io.IOException;
import java.util.List;

public class Example {
    public static void main(String[] args) throws SorobanRpcErrorResponse, IOException, InterruptedException {
        // The source account will be used to sign and send the transaction.
        KeyPair sourceKeypair = KeyPair.fromSecretSeed("SAAPYAPTTRZMCUZFPG3G66V4ZMHTK4TWA6NS7U4F7Z3IMUD52EK4DDEV");

        // Configure SorobanClient to use the `stellar-rpc` instance of your choosing.
        SorobanServer sorobanServer = new SorobanServer("https://soroban-testnet.stellar.org");

        // Here we will use a deployed instance of the `increment` example contract.
        String contractAddress = "CDOGJBJMRVVXW5K3UJ5BGVJ5RSQXQB4UFVQYVFOIARC2UYXSEPF4YAVR";

        // Transactions require a valid sequence number (which varies from one account to
        // another). We fetch this sequence number from the RPC server.
        TransactionBuilderAccount sourceAccount = null;
        try {
            sourceAccount = sorobanServer.getAccount(sourceKeypair.getAccountId());
        } catch (AccountNotFoundException e) {
            throw new RuntimeException("Account not found, please activate it first");
        }

        // The invocation of the `increment` function.
        InvokeHostFunctionOperation operation = InvokeHostFunctionOperation.invokeContractFunctionOperationBuilder(contractAddress, "increment",
                List.of(
                        Scv.toAddress(sourceAccount.getAccountId()),
                        Scv.toUint32(5)
                )
        ).build();

        // Create a transaction with the source account and the operation we want to invoke.
        Transaction transaction = new TransactionBuilder(sourceAccount, Network.TESTNET)
                .addOperation(operation) // The invocation of the `increment` function of our contract is added to the transaction.
                .setTimeout(30) // This transaction will be valid for the next 30 seconds
                .setBaseFee(100)  // The base fee is 100 stroops (0.00001 XLM)
                .build();

        // We use the RPC server to "prepare" the transaction. This simulating the
        // transaction, discovering the soroban data, and updating the
        // transaction to include that soroban data. If you know the soroban data ahead of
        // time, you could manually use `setSorobanData` and skip this step.
        try {
            transaction = sorobanServer.prepareTransaction(transaction);
        } catch (PrepareTransactionException e) {
            // You should handle the error here
            System.out.println("Prepare Transaction Failed: " + e.getMessage());
            throw new RuntimeException(e);
        }

        // Sign the transaction with the source account's keypair.
        transaction.sign(sourceKeypair);

        // Let's see the base64-encoded XDR of the transaction we just built.
        System.out.println("Signed prepared transaction XDR: " + transaction.toEnvelopeXdrBase64());

        // Submit the transaction to the Stellar-RPC server. The RPC server will then
        // submit the transaction into the network for us. Then we will have to wait,
        // polling `getTransaction` until the transaction completes.
        SendTransactionResponse response = sorobanServer.sendTransaction(transaction);
        if (!SendTransactionResponse.SendTransactionStatus.PENDING.equals(response.getStatus())) {
            throw new RuntimeException("Sending transaction failed");
        }

        // Poll `getTransaction` until the status is not "NOT_FOUND"
        GetTransactionResponse getTransactionResponse;
        while (true) {
            System.out.println("Waiting for transaction confirmation...");
            // See if the transaction is complete
            getTransactionResponse = sorobanServer.getTransaction(response.getHash());
            if (!GetTransactionResponse.GetTransactionStatus.NOT_FOUND.equals(getTransactionResponse.getStatus())) {
                break;
            }
            // Wait one second
            Thread.sleep(1000);
        }

        System.out.println("Get transaction response: " + getTransactionResponse);

        if (GetTransactionResponse.GetTransactionStatus.SUCCESS.equals(getTransactionResponse.getStatus())) {
            // The transaction was successful, so we can extract the `resultMetaXdr`
            TransactionMeta transactionMeta = TransactionMeta.fromXdrBase64(getTransactionResponse.getResultMetaXdr());
            SCVal result = transactionMeta.getV3().getSorobanMeta().getReturnValue();
            long parsedResult = Scv.fromUint32(result);
            System.out.println("Transaction result: " + parsedResult);
        } else {
            // The transaction failed, so we can extract the `resultXdr`
            System.out.println("Transaction failed: " + getTransactionResponse.getResultXdr());
        }
    }
}