scryptlib
Javascript/TypeScript SDK for integration of Bitcoin SV Smart Contracts written in the sCrypt language.
You can install scryptlib
in your project as below:
$ npm install scryptlib
A smart contract is compiled to a locking script template. A contract function call is transformed to an unlocking script. Developers are responsible for setting the locking and unlocking scripts of a transaction properly before sending it to the Bitcoin network. This may include some actions described below:
-
Instantiate locking script: replace the constructor formal parameters, represented by placeholders in the locking script template, with actual parameters/arguments to form the complete locking script.
-
Assemble unlocking script: convert the arguments of a contract function call to script format and concatenate them to form the unlocking script.
By using scryptlib
, both scripts can be obtained with ease.
Contract Description File
The compiler outputs results in a JSON file. It’s a representation used to build locking and unlocking scripts. We call this file a contract description file. Here's its structure:
{
"compilerVersion": "0.1.0+commit.312f643",
"contract": "DemoP2PKH",
"md5": "01234...",
"abi": [
{
"type": "constructor",
"name": "constructor",
"params": [
{
"name": "pubKeyHash",
"type": "Ripemd160"
}
]
},
{
"type": "function",
"name": "unlock",
"index": 0,
"params": [
{
"name": "sig",
"type": "Sig"
},
{
"name": "pubKey",
"type": "PubKey"
}
]
},
...
],
"asm": "$pubKeyHash OP_OVER OP_HASH160 ..."
}
There are two ways to generate this file (named as xxx_desc.json
):
- Use sCrypt VS Code extension to compile manually;
- Use the function
compile
programmatically:
import { compile } from 'scryptlib';
...
compile(
{
path: contractFilePath
},
{
desc: true
}
);
Deploy A Contract and Call Its Function
Both deploying a contract and calling a contract functionare achieved by sending a transaction. Generally speaking,
- Deploying a contract needs the locking script in the output of this transaction to be set properly;
- Calling a contract function needs the unlocking script in the input of this transaction to be set properly;
You can use the description file to build a reflected contract class in Javascript/TypeScript like this:
const MyContract = buildContractClass(JSON.parse(descFileContent));
To create an instance of the contract class, for example:
const instance = new MyContract(1234, true, ...parameters);
To get the locking script, use:
const lockingScript = instance.lockingScript;
const lockingScriptASM = lockingScript.toASM();
const lockingScriptHex = lockingScript.toHex();
To get the unlocking script, just call the function and turn the result to bsv.Script
object, for example:
const funcCall = instance.someFunc(new Sig('0123456'), new Bytes('aa11ff'), ...parameters);
const unlockingScript = funcCall.toScript();
const unlockingScriptASM = unlockingScript.toASM();
const unlockingScriptHex = unlockingScript.toHex();
Note that parameters
in both constructor and function call are mapped to sCrypt types as follows:
boolean
: mapped to sCrypt bool
number
: mapped to sCrypt int
new Byte(x)
/ new Bytes(x)
/ new Sig(x)
/ new PubKey(x)
/ new Ripemd160(x)
/ … : mapped to sCrypt byte
/ bytes
/ Sig
/ PubKey
/ Ripemd160
/ … , where x
is hex string
In this way, the type of parameters could be checked and potential bugs can be detected before running.
Local Unit Tests
A useful method verify(txContext)
is provided for each contract function call. It would execute the function call with the given context locally. The txContext
argument provides some context information of the current transaction, needed only if signature is checked inside the contract.
{
tx?: any;
inputIndex?: number;
inputSatoshis?: number;
}
It returns an object:
{
success: boolean;
error: string;
}
It usually appears in unit tests, like:
const context = { tx, inputIndex, inputSatoshis };
const funcCall = instance.someFunc(new Sig('0123456'), new Bytes('aa11ff'), ...parameters);
const result = funcCall.verify(context);
instance.txContext = context;
const result = funcCall.verify();
expect(result.success, result.error).to.be.true;
assert.isFalse(result.success, result.error);
Contracts with State
sCrypt offers stateful contracts. OP_RETURN
data of the contract locking script can be accessed by using an accessor named dataPart
, for example:
const dataPart = instance.dataPart;
const dataPartASM = instance.dataPart.toASM();
const dataPartHex = instance.dataPart.toHex();
instance.setDataPart(dataInASM);
let state = {'counter': 11, 'bytes': '1234', 'flag': true}
instance.setDataPart(state)
After that, the instance.lockingScript
would include the data part automatically.
If you want to access the code part of the contract's locking script including the trailing OP_RETURN
, use:
const codePart = instance.codePart;
const codePartASM = instance.codePart.toASM();
const codePartHex = instance.codePart.toHex();
Instantiate Inline Assembly Variables
Assembly variables can be replaced with literal Script in ASM format using replace()
. Each variable is prefixed by its unique scope, namely, the contract and the function it is under.
const asmVars = {
'contract1.function1.variable1': 'ff41',
'contract2.function2.variable2': 'OP_4'
};
instance.replaceAsmVars(asmVars);
You could find more examples using scryptlib
in the boilerplate repository.