LayerZero 跨链通信转账 2024极简示例
- Alvan
- 更新于 2024-03-03 22:58
- 阅读 1360
一个极简的layerzero入门教程
开篇
由于在站内看到了2022年layerzero极简教程,但是由于layerzero版本更迭,其官方示例的封装性高又缺乏注解,故写了这篇2024版layerzero示例。
本示例包含fantom testnet 跨链传递信息或native token至mumbai network的合约与脚本,希望能帮到诸位。
初始化项目
我们可以使用hardhat很轻松地创建一个solidity合约项目:
mkdir layerzero-tutorial
cd layerzero-tutorial
npm init
npm install --save-dev hardhat
npx hardhat init最后一项选择创建一个ts项目
👷 Welcome to Hardhat v2.20.1 👷
? What do you want to do? …
Create a JavaScript project
Create a TypeScript project
❯ Create a TypeScript project (with Viem)
Create an empty hardhat.config.js
Quit编写合约
我们期待从A链发送信息或者代币至B链,需要在A/B两条链上分别部署合约,如果你的操作是对称的,即相同业务的双向通信,则可以使用同一张合约,本示例的合约也只有一张,分别部署至 fantom testnet 和 mumbai。
下面是合约代码:
//SPDX-License-Identifier: MIT
pragma solidity ^0.8.9;
pragma abicoder v2;
import "../interfaces/ILayerZeroEndpoint.sol";
import "../interfaces/ILayerZeroReceiver.sol";
import "hardhat/console.sol";
contract LayerZeroDemo1 is ILayerZeroReceiver {
event ReceiveMsg(
uint16 _srcChainId,
address _from,
uint16 _count,
bytes _payload
);
ILayerZeroEndpoint public endpoint;
uint16 public messageCount;
bytes public message;
constructor(address _endpoint) {
endpoint = ILayerZeroEndpoint(_endpoint);
}
function sendMsg(
uint16 _dstChainId,
address _destination,
bytes calldata payload,
bytes calldata _adapterParams
) public payable {
require(abi.encodePacked(_destination,address(this)).length == 40, "Invalid destination");
endpoint.send{value: msg.value}(
_dstChainId,
abi.encodePacked(_destination,address(this)),
payload,
payable(msg.sender),
address(this),
_adapterParams
);
}
function sendNativeToken(
uint16 _dstChainId,
address _toAddress,
uint _amount
) public payable {
uint dstGas = 350000;
uint16 version = 2;
bytes memory adapterParams = abi.encodePacked(version, dstGas, _amount, _toAddress);
bytes memory payload = abi.encode(_amount, msg.sender, _toAddress);
//_lzSend(_dstChainId[i], payload, refundAddress, _zroPaymentAddress, adapterParams, address(this).balance);
endpoint.send{value: msg.value}(
_dstChainId,
abi.encodePacked(_toAddress,address(this)),
payload,
payable(msg.sender),
address(this),
adapterParams
);
}
function lzReceive(
uint16 _srcChainId,
bytes memory _from,
uint64,
bytes memory _payload
) external override {
require(msg.sender == address(endpoint));
address from;
assembly {
from := mload(add(_from, 20))
}
if (
keccak256(abi.encodePacked((_payload))) ==
keccak256(abi.encodePacked((bytes10("ff"))))
) {
endpoint.receivePayload(
1,
bytes(""),
address(0x0),
1,
1,
bytes("")
);
}
message = _payload;
messageCount += 1;
emit ReceiveMsg(_srcChainId, from, messageCount, message);
}
// Endpoint.sol estimateFees() returns the fees for the message
function estimateFees(
uint16 _dstChainId,
address _userApplication,
bytes calldata _payload,
bool _payInZRO,
bytes calldata _adapterParams
) external view returns (uint256 nativeFee, uint256 zroFee) {
return
endpoint.estimateFees(
_dstChainId,
_userApplication,
_payload,
_payInZRO,
_adapterParams
);
}
receive() external payable {
}
}接下来我会讲解这份合约:
首先是引用的几个接口:
import "../interfaces/ILayerZeroEndpoint.sol";
import "../interfaces/ILayerZeroReceiver.sol";这两个接口由LayerZero项目方提供,实现 ILayerZeroEndpoint 的 endpoint 合约与我们自己的业务合约直接对接,是我们使用LayerZero进行跨链操作的入口合约,而ILayerZeroReceiver 规定了一些标准使得我们处于目标链的合约可以接收到来自 LayerZero 桥的信息。
之后我们在构造函数中存储endpoint的地址,每条链上的endpoint地址都有不同,可以查询LayerZero官方文档: 文档
constructor(address _endpoint) {
endpoint = ILayerZeroEndpoint(_endpoint);
}我们再来写消息传递方法:
function sendMsg(
uint16 _dstChainId,
address _destination,
bytes calldata payload,
bytes calldata _adapterParams
) public payable {
require(abi.encodePacked(_destination,address(this)).length == 40, "Invalid destination");
endpoint.send{value: msg.value}(
_dstChainId,
abi.encodePacked(_destination,address(this)),
payload,
payable(msg.sender),
address(this),
_adapterParams
);
}这里我们可以看到一些意义不明的参数,由于业务代码可以随意设置,我们直接解释endpoint的send方法,_dstChainId 是目标链的id,注意不是我们区块链意义的chainId,而是目标链上的endpoint的ID,例如mumbai 的chain id是80001,mumbai上endpoint的id是10109,如果我们是想跨到mumbai,那这第一个参数应该写 10109。第二个参数名为 path,它是由目标合约和本业务合约 encodePacket形成的,第三个参数payload 和 第四个参数payloadAddress,分别是需要传递的信息和收退款的地址,这里我们设置为发送者本人了。第五个参数是给layerzero交手续费的地址,这里我们设置成合约本身。而最后一个adapterParams代表了对这次交易的gas设置和native token 处理方式,我会在下一个章节详细说明。
类似的我们也可以写出带有nativetoken 传递的方法,需要说明的是,上边的sendMsg本质上也可以通过手动构造adapterParams来实现这个类型的交易,我选择只是想使用sendNativeToken做例子说明在大多数的业务场景里,adapterParams在合约encode里更加便利一些。
function sendNativeToken(
uint16 _dstChainId,
address _toAddress,
uint _amount
) public payable {
uint dstGas = 350000;
uint16 version = 2;
bytes memory adapterParams = abi.encodePacked(version, dstGas, _amount, _toAddress);
bytes memory payload = abi.encode(_amount, msg.sender, _toAddress);
//_lzSend(_dstChainId[i], payload, refundAddress, _zroPaymentAddress, adapterParams, address(this).balance);
endpoint.send{value: msg.value}(
_dstChainId,
abi.encodePacked(_toAddress,address(this)),
payload,
payable(msg.sender),
address(this),
adapterParams
);
}其实和sendMsg差不多,只是我们在合约里给 adapterParams 赋了值。
adapterParams的格式被按照交易类型分为两种:
第一种是不给目标合约发送原生代币,它的adapterParams格式为: // txType 1 // bytes [2 32 ] // fields [txType extraGas] 总共34 byte,依次是交易类型,目标链gaslimit 第二种是给目标合约发送原生代币,它的adapterParams格式为: // txType 2 // bytes [2 32 32 bytes[] ] // fields [txType extraGas dstNativeAmt dstNativeAddress] // User App Address is not used in this version
依次是 交易类型,目标链gaslimit,发送代币数目,目标地址
所以我们的adapterParams构建为:
uint dstGas = 350000;
uint16 version = 2;
bytes memory adapterParams = abi.encodePacked(version, dstGas, _amount, _toAddress);编写部署脚本
我们的部署脚本其实是一模一样的,只是部署参数中的endpoint地址不同而已:
Fantom testnet:
async function main() {
const LayerZeroDemo1 = await ethers.getContractFactory("LayerZeroDemo1");
const layerZeroDemo1 = await LayerZeroDemo1.deploy(
"0x7dcAD72640F835B0FA36EFD3D6d3ec902C7E5acf"
);
await layerZeroDemo1.waitForDeployment();
console.log("layerZeroDemo1 deployed to:", await layerZeroDemo1.getAddress(),"on Fantom Testnet.");
}
/*Mumbai :
async function main() {
const LayerZeroDemo1 = await ethers.getContractFactory("LayerZeroDemo1");
const layerZeroDemo1 = await LayerZeroDemo1.deploy(
"0xf69186dfBa60DdB133E91E9A4B5673624293d8F8"
);
await layerZeroDemo1.waitForDeployment();
console.log("layerZeroDemo1 deployed to:", await layerZeroDemo1.getAddress(), " on Mumbai Testnet.");
}我们便可以得到fantomtestnet 和 mumbai 上的合约:
fantomtestnet:0xd79b3438968FB409340c9fd405109258C458C5F7
mumbai:0x55DD4f23aFA85305f8C7DCa8a9F86D0d0a5aE8Cd
编写测试脚本
现在我们开始调用fantomtestnet 的合约:
sendMsg方法:
async function main() {
const layerZeroDemo1 = await ethers.getContractAt("LayerZeroDemo1", "0xd79b3438968FB409340c9fd405109258C458C5F7");
const transaction = await layerZeroDemo1.sendMsg(
10109,
"0x55DD4f23aFA85305f8C7DCa8a9F86D0d0a5aE8Cd",
ethers.encodeBytes32String("Hello LayerZero1"),
"0x00010000000000000000000000000000000000000000000000000000000001111111",
{ value: ethers.parseEther("1") }
);
console.log(transaction.hash);
}这里值得一说的实际上只有 adapterparams, "0001"为transaction type,"0000000000000000000000000000000000000000000000000000000001111111"为gasLimit。而我们传入的 value,1个ftm会在扣除掉gas fee后还给我们。
sendNativeToken方法:
async function sendNativeToken(){
const layerZeroDemo1 = await ethers.getContractAt("LayerZeroDemo1", "0xd79b3438968FB409340c9fd405109258C458C5F7");
const transaction = await layerZeroDemo1.sendNativeToken(
10109,
"0x55DD4f23aFA85305f8C7DCa8a9F86D0d0a5aE8Cd",
100,
{ value: ethers.parseEther("1")}
)
console.log(transaction.hash);
}
检查方法:
我们可以在layerzero scan查看交易的情况: 浏览器
