stacks-transactions-test
v6.16.2
Published
Javascript library for constructing transactions on the Stacks blockchain.
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@stacks/transactions
Construct, decode transactions and work with Clarity smart contracts on the Stacks blockchain.
Installation
npm install @stacks/transactions
Overview
This library supports the creation of the following Stacks transaction types:
- STX token transfer
- Smart contract deploy
- Smart contract function call
Key Generation
import { createStacksPrivateKey, makeRandomPrivKey, getPublicKey } from '@stacks/transactions';
// Random key
const privateKey = makeRandomPrivKey();
// Get public key from private
const publicKey = getPublicKey(privateKey);
// Private key from hex string
const key = 'b244296d5907de9864c0b0d51f98a13c52890be0404e83f273144cd5b9960eed01';
const privateKey = createStacksPrivateKey(key);
STX Token Transfer Transaction
import { makeSTXTokenTransfer, broadcastTransaction, AnchorMode } from '@stacks/transactions';
const txOptions = {
recipient: 'SP3FGQ8Z7JY9BWYZ5WM53E0M9NK7WHJF0691NZ159',
amount: 12345n,
senderKey: 'b244296d5907de9864c0b0d51f98a13c52890be0404e83f273144cd5b9960eed01',
network: 'testnet', // for mainnet, use 'mainnet'
memo: 'test memo',
nonce: 0n, // set a nonce manually if you don't want builder to fetch from a Stacks node
fee: 200n, // set a tx fee if you don't want the builder to estimate
anchorMode: AnchorMode.Any,
};
const transaction = await makeSTXTokenTransfer(txOptions);
// to see the raw serialized tx
const serializedTx = transaction.serialize(); // Uint8Array
const serializedTxHex = bytesToHex(serializedTx); // hex string
// broadcasting transaction to the specified network
const broadcastResponse = await broadcastTransaction(transaction);
const txId = broadcastResponse.txid;
Smart Contract Deploy Transaction
import { makeContractDeploy, broadcastTransaction, AnchorMode } from '@stacks/transactions';
import { StacksTestnet, StacksMainnet } from '@stacks/network';
import { readFileSync } from 'fs';
// for mainnet, use `StacksMainnet()`
const network = new StacksTestnet();
const txOptions = {
contractName: 'contract_name',
codeBody: readFileSync('/path/to/contract.clar').toString(),
senderKey: 'b244296d5907de9864c0b0d51f98a13c52890be0404e83f273144cd5b9960eed01',
network,
anchorMode: AnchorMode.Any,
};
const transaction = await makeContractDeploy(txOptions);
const broadcastResponse = await broadcastTransaction(transaction, network);
const txId = broadcastResponse.txid;
Smart Contract Function Call
import {
makeContractCall,
broadcastTransaction,
AnchorMode,
FungibleConditionCode,
makeStandardSTXPostCondition,
bufferCVFromString,
} from '@stacks/transactions';
import { StacksTestnet, StacksMainnet } from '@stacks/network';
// for mainnet, use `StacksMainnet()`
const network = new StacksTestnet();
// Add an optional post condition
// See below for details on constructing post conditions
const postConditionAddress = 'SP2ZD731ANQZT6J4K3F5N8A40ZXWXC1XFXHVVQFKE';
const postConditionCode = FungibleConditionCode.GreaterEqual;
const postConditionAmount = 1000000n;
const postConditions = [
makeStandardSTXPostCondition(postConditionAddress, postConditionCode, postConditionAmount),
];
const txOptions = {
contractAddress: 'SPBMRFRPPGCDE3F384WCJPK8PQJGZ8K9QKK7F59X',
contractName: 'contract_name',
functionName: 'contract_function',
functionArgs: [bufferCVFromString('foo')],
senderKey: 'b244296d5907de9864c0b0d51f98a13c52890be0404e83f273144cd5b9960eed01',
validateWithAbi: true,
network,
postConditions,
anchorMode: AnchorMode.Any,
};
const transaction = await makeContractCall(txOptions);
const broadcastResponse = await broadcastTransaction(transaction, network);
const txId = broadcastResponse.txid;
In this example we construct a contract-call
transaction with a post condition. We have set the validateWithAbi
option to true
, so the makeContractCall
builder will attempt to fetch this contracts ABI from the specified Stacks network, and validate that the provided functionArgs match what is described in the ABI. This should help you avoid constructing invalid contract-call transactions. If you would prefer to provide your own ABI instead of fetching it from the network, the validateWithABI
option also accepts ClarityABI objects, which can be constructed from ABI files like so:
import { ClarityAbi } from '@stacks/transactions';
import { readFileSync } from 'fs';
const abi: ClarityAbi = JSON.parse(readFileSync('abi.json').toString());
// For sample abi json see: stacks.js/packages/transactions/tests/abi/test-abi.json
Sponsoring Transactions
To generate a sponsored transaction, first create and sign the transaction as the origin. The sponsored
property in the options object must be set to true.
import { bytesToHex } from '@stacks/common';
import { makeContractCall, BufferCV, AnchorMode, bufferCVFromString } from '@stacks/transactions';
const txOptions = {
contractAddress: 'SPBMRFRPPGCDE3F384WCJPK8PQJGZ8K9QKK7F59X',
contractName: 'contract_name',
functionName: 'contract_function',
functionArgs: [bufferCVFromString('foo')],
fee: 0,
senderKey: 'b244296d5907de9864c0b0d51f98a13c52890be0404e83f273144cd5b9960eed01',
validateWithAbi: true,
sponsored: true,
anchorMode: AnchorMode.Any,
};
const transaction = await makeContractCall(txOptions);
const serializedTx = bytesToHex(transaction.serialize());
The serialized transaction can now be passed to the sponsoring party which will sign the sponsor portion of the transaction and set the fee.
import {
sponsorTransaction,
BytesReader,
deserializeTransaction,
broadcastTransaction,
} from '@stacks/transactions';
import { StacksTestnet, StacksMainnet } from '@stacks/network';
const bytesReader = new BytesReader(Buffer.from(serializedTx, 'hex'));
const deserializedTx = deserializeTransaction(bytesReader);
const sponsorKey = '770287b9471081c8acd37d57190c7a70f0da2633311cc120853537362d32e67c01';
const fee = 1000n;
const sponsorOptions = {
transaction: deserializedTx,
sponsorPrivateKey: sponsorKey,
fee,
sponsorNonce: 0,
};
const sponsoredTx = await sponsorTransaction(sponsorOptions);
// for mainnet, use `StacksMainnet()`
const network = new StacksTestnet();
const broadcastResponse = await broadcastTransaction(sponsoredTx, network);
const txId = broadcastResponse.txid;
Supporting multi-signature transactions
To generate a multi-sig transaction, first create an unsigned transaction.
The numSignatures
and publicKeys
properties in the options object must be set:
import {
makeUnsignedSTXTokenTransfer,
createStacksPrivateKey,
deserializeTransaction,
pubKeyfromPrivKey,
publicKeyToString,
TransactionSigner,
standardPrincipalCV,
BytesReader,
AnchorMode,
} from '@stacks/transactions';
const recipient = standardPrincipalCV('SP3FGQ8...');
const amount = 2500000n;
const fee = 0n;
const memo = 'test memo';
// private keys of the participants in the transaction
const privKeyStrings = ['6d430bb9...', '2a584d89...', 'd5200dee...'];
// create private key objects from string array
const privKeys = privKeyStrings.map(createStacksPrivateKey);
// corresponding public keys
const pubKeys = privKeyStrings.map(pubKeyfromPrivKey);
// create public key string array from objects
const pubKeyStrings = pubKeys.map(publicKeyToString);
const transaction = await makeUnsignedSTXTokenTransfer({
recipient,
amount,
fee,
memo,
numSignatures: 2, // number of signature required
publicKeys: pubKeyStrings, // public key string array with >= numSignatures elements
anchorMode: AnchorMode.Any,
});
const serializedTx = transaction.serialize();
This transaction payload can be passed along to other participants to sign. In addition to meeting the numSignatures requirement, the public keys of the parties who did not sign the transaction must be appended to the signature.
// deserialize and sign transaction
const bytesReader = new BytesReader(serializedTx);
// Partially signed or unsigned multi-sig tx can be deserialized to add the required signatures
const deserializedTx = deserializeTransaction(bytesReader);
const signer = new TransactionSigner(deserializedTx);
// first signature
signer.signOrigin(privKeys[0]);
// second signature
signer.signOrigin(privKeys[1]);
// after meeting the numSignatures requirement, the public
// keys of the participants who did not sign must be appended
signer.appendOrigin(pubKeys[2]);
// the serialized multi-sig tx
const serializedSignedTx = deserializedTx.serialize();
Calling Read-only Contract Functions
Read-only contract functions can be called without generating or broadcasting a transaction. Instead it works via a direct API call to a Stacks node.
import { bufferCVFromString, callReadOnlyFunction } from '@stacks/transactions';
import { StacksTestnet } from '@stacks/network';
const contractAddress = 'ST3KC0MTNW34S1ZXD36JYKFD3JJMWA01M55DSJ4JE';
const contractName = 'kv-store';
const functionName = 'get-value';
const buffer = bufferCVFromString('foo');
const network = new StacksTestnet();
const senderAddress = 'ST2F4BK4GZH6YFBNHYDDGN4T1RKBA7DA1BJZPJEJJ';
const options = {
contractAddress,
contractName,
functionName,
functionArgs: [buffer],
network,
senderAddress,
};
const result = await callReadOnlyFunction(options);
Constructing Clarity Values
Building transactions that call functions in deployed clarity contracts requires you to construct valid Clarity Values to pass to the function as arguments. The Clarity type system contains the following types:
(tuple (key-name-0 key-type-0) (key-name-1 key-type-1) ...)
- a typed tuple with named fields.
(list max-len entry-type)
- a list of maximum length max-len, with entries of type entry-type
(response ok-type err-type)
- object used by public functions to commit their changes or abort. May be returned or used by other functions as well, however, only public functions have the commit/abort behavior.
(optional some-type)
- an option type for objects that can either be (some value) or none
(buff max-len)
- byte buffer or maximum length max-len.
principal
- object representing a principal (whether a contract principal or standard principal).
bool
- boolean value ('true or 'false)
int
- signed 128-bit integer
uint
- unsigned 128-bit integer
This library contains Typescript types and classes that map to the Clarity types, in order to make it easy to construct well-typed Clarity values in Javascript. These types all extend the abstract class ClarityValue
.
import {
trueCV,
falseCV,
noneCV,
someCV,
intCV,
uintCV,
standardPrincipalCV,
contractPrincipalCV,
responseErrorCV,
responseOkCV,
listCV,
tupleCV,
bufferCV,
} from '@stacks/transactions';
import { utf8ToBytes } from '@stacks/common';
// construct boolean clarity values
const t = trueCV();
const f = falseCV();
// construct optional clarity values
const nothing = noneCV();
const something = someCV(t);
// construct a buffer clarity value from an existing byte array
const bytes = utf8ToBytes('foo'); // Uint8Array(3) [ 102, 111, 111 ]
const bufCV = bufferCV(bytes);
// construct signed and unsigned integer clarity values
const i = intCV(-10);
const u = uintCV(10);
// construct principal clarity values
const address = 'SP2JXKMSH007NPYAQHKJPQMAQYAD90NQGTVJVQ02B';
const contractName = 'contract-name';
const spCV = standardPrincipalCV(address);
const cpCV = contractPrincipalCV(address, contractName);
// construct response clarity values
const errCV = responseErrorCV(trueCV());
const okCV = responseOkCV(falseCV());
// construct tuple clarity values
const tupCV = tupleCV({
a: intCV(1),
b: trueCV(),
c: falseCV(),
});
// construct list clarity values
const l = listCV([trueCV(), falseCV()]);
If you develop in Typescript, the type checker can help prevent you from creating wrongly-typed Clarity values. For example, the following code won't compile since in Clarity lists are homogeneous, meaning they can only contain values of a single type. It is important to include the type variable BooleanCV
in this example, otherwise the typescript type checker won't know which type the list is of and won't enforce homogeneity.
const l = listCV<BooleanCV>([trueCV(), intCV(1)]);
Post Conditions
Three types of post conditions can be added to transactions:
- STX post condition
- Fungible token post condition
- Non-Fungible token post condition
For details see: https://github.com/stacksgov/sips/blob/main/sips/sip-005/sip-005-blocks-and-transactions.md#transaction-post-conditions
STX post condition
import {
FungibleConditionCode,
makeStandardSTXPostCondition,
makeContractSTXPostCondition,
} from '@stacks/transactions';
// With a standard principal
const postConditionAddress = 'SP2ZD731ANQZT6J4K3F5N8A40ZXWXC1XFXHVVQFKE';
const postConditionCode = FungibleConditionCode.GreaterEqual;
const postConditionAmount = 12345n;
const standardSTXPostCondition = makeStandardSTXPostCondition(
postConditionAddress,
postConditionCode,
postConditionAmount
);
// With a contract principal
const contractAddress = 'SPBMRFRPPGCDE3F384WCJPK8PQJGZ8K9QKK7F59X';
const contractName = 'test-contract';
const contractSTXPostCondition = makeContractSTXPostCondition(
contractAddress,
contractName,
postConditionCode,
postConditionAmount
);
Fungible token post condition
import {
FungibleConditionCode,
createAssetInfo,
makeStandardFungiblePostCondition,
} from '@stacks/transactions';
// With a standard principal
const postConditionAddress = 'SP2ZD731ANQZT6J4K3F5N8A40ZXWXC1XFXHVVQFKE';
const postConditionCode = FungibleConditionCode.GreaterEqual;
const postConditionAmount = 12345n;
const assetAddress = 'SP62M8MEFH32WGSB7XSF9WJZD7TQB48VQB5ANWSJ';
const assetContractName = 'test-asset-contract';
const assetName = 'test-token';
const fungibleAssetInfo = createAssetInfo(assetAddress, assetContractName, assetName);
const standardFungiblePostCondition = makeStandardFungiblePostCondition(
postConditionAddress,
postConditionCode,
postConditionAmount,
fungibleAssetInfo
);
// With a contract principal
const contractAddress = 'SPBMRFRPPGCDE3F384WCJPK8PQJGZ8K9QKK7F59X';
const contractName = 'test-contract';
const assetAddress = 'SP62M8MEFH32WGSB7XSF9WJZD7TQB48VQB5ANWSJ';
const assetContractName = 'test-asset-contract';
const assetName = 'test-token';
const fungibleAssetInfo = createAssetInfo(assetAddress, assetContractName, assetName);
const contractFungiblePostCondition = makeContractFungiblePostCondition(
contractAddress,
contractName,
postConditionCode,
postConditionAmount,
fungibleAssetInfo
);
Non-fungible token post condition
Warning The Stacks blockchain's post-condition processor can NOT check ownership. It checks whether or not a principal will send or will not send an NFT. Post-conditions can NOT verify anything about the recipient of an asset. If you want to verify conditions about asset recipients, you will need to use Clarity.
import {
NonFungibleConditionCode,
createAssetInfo,
makeStandardNonFungiblePostCondition,
makeContractNonFungiblePostCondition,
bufferCVFromString,
} from '@stacks/transactions';
// With a standard principal
const postConditionAddress = 'SP2ZD731ANQZT6J4K3F5N8A40ZXWXC1XFXHVVQFKE';
const postConditionCode = NonFungibleConditionCode.DoesNotSend;
const assetAddress = 'SP62M8MEFH32WGSB7XSF9WJZD7TQB48VQB5ANWSJ';
const assetContractName = 'test-asset-contract';
const assetName = 'test-asset';
const assetId = bufferCVFromString('test-token-asset-id');
const nonFungibleAssetInfo = createAssetInfo(assetAddress, assetContractName, assetName);
const standardNonFungiblePostCondition = makeStandardNonFungiblePostCondition(
postConditionAddress,
postConditionCode,
nonFungibleAssetInfo,
assetId
);
// With a contract principal
const contractAddress = 'SPBMRFRPPGCDE3F384WCJPK8PQJGZ8K9QKK7F59X';
const contractName = 'test-contract';
const contractNonFungiblePostCondition = makeContractNonFungiblePostCondition(
contractAddress,
contractName,
postConditionCode,
nonFungibleAssetInfo,
assetId
);
Helper functions
Conversion of Clarity Values to JSON
Clarity Values represent values of Clarity contracts. If a JSON format is required the helper function cvToJSON
can be used.
import { cvToJSON, hexToCV } from '@stacks/transactions';
cvToJSON(hexToCV(tx.tx_result.hex));