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L1ReverseCustomERC20Gateway.t.sol
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L1ReverseCustomERC20Gateway.t.sol
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// SPDX-License-Identifier: MIT
pragma solidity =0.8.24;
import {MockERC20} from "solmate/test/utils/mocks/MockERC20.sol";
import {ITransparentUpgradeableProxy} from "@openzeppelin/contracts/proxy/transparent/TransparentUpgradeableProxy.sol";
import {IL1ERC20Gateway} from "../L1/gateways/IL1ERC20Gateway.sol";
import {L1ReverseCustomERC20Gateway} from "../L1/gateways/L1ReverseCustomERC20Gateway.sol";
import {L1GatewayRouter} from "../L1/gateways/L1GatewayRouter.sol";
import {IL1ScrollMessenger} from "../L1/IL1ScrollMessenger.sol";
import {L1ScrollMessenger} from "../L1/L1ScrollMessenger.sol";
import {IL2ERC20Gateway} from "../L2/gateways/IL2ERC20Gateway.sol";
import {L2ReverseCustomERC20Gateway} from "../L2/gateways/L2ReverseCustomERC20Gateway.sol";
import {AddressAliasHelper} from "../libraries/common/AddressAliasHelper.sol";
import {ScrollConstants} from "../libraries/constants/ScrollConstants.sol";
import {L1GatewayTestBase} from "./L1GatewayTestBase.t.sol";
import {MockScrollMessenger} from "./mocks/MockScrollMessenger.sol";
import {MockGatewayRecipient} from "./mocks/MockGatewayRecipient.sol";
contract MockL1ReverseCustomERC20Gateway is L1ReverseCustomERC20Gateway {
constructor(
address _counterpart,
address _router,
address _messenger
) L1ReverseCustomERC20Gateway(_counterpart, _router, _messenger) {}
function reentrantCall(address target, bytes calldata data) external payable nonReentrant {
(bool success, ) = target.call{value: msg.value}(data);
if (!success) {
// solhint-disable-next-line no-inline-assembly
assembly {
let ptr := mload(0x40)
let size := returndatasize()
returndatacopy(ptr, 0, size)
revert(ptr, size)
}
}
}
}
contract L1ReverseCustomERC20GatewayTest is L1GatewayTestBase {
// from L1ReverseCustomERC20Gateway
event FinalizeWithdrawERC20(
address indexed _l1Token,
address indexed _l2Token,
address indexed _from,
address _to,
uint256 _amount,
bytes _data
);
event DepositERC20(
address indexed _l1Token,
address indexed _l2Token,
address indexed _from,
address _to,
uint256 _amount,
bytes _data
);
event RefundERC20(address indexed token, address indexed recipient, uint256 amount);
MockL1ReverseCustomERC20Gateway private gateway;
L1GatewayRouter private router;
L2ReverseCustomERC20Gateway private counterpartGateway;
MockERC20 private l1Token;
MockERC20 private l2Token;
function setUp() public {
__L1GatewayTestBase_setUp();
// Deploy tokens
l1Token = new MockERC20("Mock L1", "ML1", 18);
l2Token = new MockERC20("Mock L2", "ML2", 18);
// Deploy L2 contracts
counterpartGateway = new L2ReverseCustomERC20Gateway(address(1), address(1), address(1));
// Deploy L1 contracts
router = L1GatewayRouter(_deployProxy(address(new L1GatewayRouter())));
gateway = _deployGateway(address(l1Messenger));
// Initialize L1 contracts
gateway.initialize(address(counterpartGateway), address(router), address(l1Messenger));
router.initialize(address(0), address(gateway));
// Prepare token balances
l1Token.mint(address(this), type(uint128).max);
l1Token.approve(address(gateway), type(uint256).max);
l1Token.approve(address(router), type(uint256).max);
}
function testDepositERC20(
uint256 amount,
uint256 gasLimit,
uint256 feePerGas
) external {
_depositERC20(false, 0, amount, address(this), new bytes(0), gasLimit, feePerGas);
}
function testDepositERC20WithRecipient(
uint256 amount,
address recipient,
uint256 gasLimit,
uint256 feePerGas
) external {
_depositERC20(false, 1, amount, recipient, new bytes(0), gasLimit, feePerGas);
}
function testDepositERC20WithRecipientAndCalldata(
uint256 amount,
address recipient,
bytes memory dataToCall,
uint256 gasLimit,
uint256 feePerGas
) external {
_depositERC20(false, 2, amount, recipient, dataToCall, gasLimit, feePerGas);
}
function testDepositERC20ByRouter(
uint256 amount,
uint256 gasLimit,
uint256 feePerGas
) external {
_depositERC20(true, 0, amount, address(this), new bytes(0), gasLimit, feePerGas);
}
function testDepositERC20WithRecipientByRouter(
uint256 amount,
address recipient,
uint256 gasLimit,
uint256 feePerGas
) external {
_depositERC20(true, 1, amount, recipient, new bytes(0), gasLimit, feePerGas);
}
function testDepositERC20WithRecipientAndCalldataByRouter(
uint256 amount,
address recipient,
bytes memory dataToCall,
uint256 gasLimit,
uint256 feePerGas
) external {
_depositERC20(true, 2, amount, recipient, dataToCall, gasLimit, feePerGas);
}
function testDropMessage(
uint256 amount,
address recipient,
bytes memory dataToCall
) public {
// message 0 is append here
gateway.updateTokenMapping{value: 1 ether}(address(l1Token), address(l2Token));
// finalize message 0
hevm.startPrank(address(rollup));
messageQueue.popCrossDomainMessage(0, 1, 0);
messageQueue.finalizePoppedCrossDomainMessage(1);
hevm.stopPrank();
assertEq(messageQueue.pendingQueueIndex(), 1);
assertEq(messageQueue.nextUnfinalizedQueueIndex(), 1);
amount = bound(amount, 1, l1Token.balanceOf(address(this)));
bytes memory message = abi.encodeWithSelector(
IL2ERC20Gateway.finalizeDepositERC20.selector,
address(l1Token),
address(l2Token),
address(this),
recipient,
amount,
dataToCall
);
gateway.depositERC20AndCall(address(l1Token), recipient, amount, dataToCall, defaultGasLimit);
// skip message 1
hevm.startPrank(address(rollup));
messageQueue.popCrossDomainMessage(1, 1, 0x1);
messageQueue.finalizePoppedCrossDomainMessage(2);
assertEq(messageQueue.pendingQueueIndex(), 2);
assertEq(messageQueue.nextUnfinalizedQueueIndex(), 2);
hevm.stopPrank();
// drop message 1
hevm.expectEmit(true, true, false, true);
emit RefundERC20(address(l1Token), address(this), amount);
uint256 balance = l1Token.balanceOf(address(this));
uint256 gatewayBalance = l1Token.balanceOf(address(gateway));
l1Messenger.dropMessage(address(gateway), address(counterpartGateway), 0, 1, message);
assertEq(balance + amount, l1Token.balanceOf(address(this)));
assertEq(gatewayBalance, l1Token.balanceOf(address(gateway)));
}
function testFinalizeWithdrawERC20(
address sender,
uint256 amount,
bytes memory dataToCall
) public {
MockGatewayRecipient recipient = new MockGatewayRecipient();
gateway.updateTokenMapping{value: 1 ether}(address(l1Token), address(l2Token));
amount = bound(amount, 1, l1Token.balanceOf(address(this)));
// deposit some token to L1StandardERC20Gateway
gateway.depositERC20(address(l1Token), amount, defaultGasLimit);
// do finalize withdraw token
bytes memory message = abi.encodeWithSelector(
IL1ERC20Gateway.finalizeWithdrawERC20.selector,
address(l1Token),
address(l2Token),
sender,
address(recipient),
amount,
dataToCall
);
bytes memory xDomainCalldata = abi.encodeWithSignature(
"relayMessage(address,address,uint256,uint256,bytes)",
address(counterpartGateway),
address(gateway),
0,
0,
message
);
prepareL2MessageRoot(keccak256(xDomainCalldata));
IL1ScrollMessenger.L2MessageProof memory proof;
proof.batchIndex = rollup.lastFinalizedBatchIndex();
// emit FinalizeWithdrawERC20 from L1StandardERC20Gateway
{
hevm.expectEmit(true, true, true, true);
emit FinalizeWithdrawERC20(
address(l1Token),
address(l2Token),
sender,
address(recipient),
amount,
dataToCall
);
}
// emit RelayedMessage from L1ScrollMessenger
{
hevm.expectEmit(true, false, false, true);
emit RelayedMessage(keccak256(xDomainCalldata));
}
uint256 gatewayBalance = l1Token.balanceOf(address(gateway));
uint256 recipientBalance = l1Token.balanceOf(address(recipient));
assertBoolEq(false, l1Messenger.isL2MessageExecuted(keccak256(xDomainCalldata)));
l1Messenger.relayMessageWithProof(address(counterpartGateway), address(gateway), 0, 0, message, proof);
assertEq(gatewayBalance, l1Token.balanceOf(address(gateway)));
assertEq(recipientBalance + amount, l1Token.balanceOf(address(recipient)));
assertBoolEq(true, l1Messenger.isL2MessageExecuted(keccak256(xDomainCalldata)));
}
function _depositERC20(
bool useRouter,
uint256 methodType,
uint256 amount,
address recipient,
bytes memory dataToCall,
uint256 gasLimit,
uint256 feePerGas
) private {
hevm.assume(recipient != address(0));
amount = bound(amount, 1, l1Token.balanceOf(address(this)));
gasLimit = bound(gasLimit, defaultGasLimit / 2, defaultGasLimit);
feePerGas = bound(feePerGas, 0, 1000);
messageQueue.setL2BaseFee(feePerGas);
feePerGas = feePerGas * gasLimit;
// revert when reentrant
hevm.expectRevert("ReentrancyGuard: reentrant call");
{
bytes memory reentrantData;
if (methodType == 0) {
reentrantData = abi.encodeWithSignature(
"depositERC20(address,uint256,uint256)",
address(l1Token),
amount,
gasLimit
);
} else if (methodType == 1) {
reentrantData = abi.encodeWithSignature(
"depositERC20(address,address,uint256,uint256)",
address(l1Token),
recipient,
amount,
gasLimit
);
} else if (methodType == 2) {
reentrantData = abi.encodeCall(
IL1ERC20Gateway.depositERC20AndCall,
(address(l1Token), recipient, amount, dataToCall, gasLimit)
);
}
gateway.reentrantCall(useRouter ? address(router) : address(gateway), reentrantData);
}
// revert when l1 token not support
hevm.expectRevert("no corresponding l2 token");
_invokeDepositERC20Call(
useRouter,
methodType,
address(l2Token),
amount,
recipient,
dataToCall,
gasLimit,
feePerGas
);
gateway.updateTokenMapping{value: 1 ether}(address(l1Token), address(l2Token));
uint64 nonce = uint64(messageQueue.nextCrossDomainMessageIndex());
// revert when deposit zero amount
hevm.expectRevert("deposit zero amount");
_invokeDepositERC20Call(useRouter, methodType, address(l1Token), 0, recipient, dataToCall, gasLimit, feePerGas);
// succeed to deposit
bytes memory message = abi.encodeCall(
IL2ERC20Gateway.finalizeDepositERC20,
(address(l1Token), address(l2Token), address(this), recipient, amount, dataToCall)
);
bytes memory xDomainCalldata = abi.encodeCall(
l2Messenger.relayMessage,
(address(gateway), address(counterpartGateway), 0, nonce, message)
);
// should emit QueueTransaction from L1MessageQueue
{
hevm.expectEmit(true, true, false, true);
address sender = AddressAliasHelper.applyL1ToL2Alias(address(l1Messenger));
emit QueueTransaction(sender, address(l2Messenger), 0, nonce, gasLimit, xDomainCalldata);
}
// should emit SentMessage from L1ScrollMessenger
{
hevm.expectEmit(true, true, false, true);
emit SentMessage(address(gateway), address(counterpartGateway), 0, nonce, gasLimit, message);
}
// should emit DepositERC20 from L1CustomERC20Gateway
{
hevm.expectEmit(true, true, true, true);
emit DepositERC20(address(l1Token), address(l2Token), address(this), recipient, amount, dataToCall);
}
uint256 gatewayBalance = l1Token.balanceOf(address(gateway));
uint256 feeVaultBalance = address(feeVault).balance;
uint256 thisBalance = l1Token.balanceOf(address(this));
assertEq(l1Messenger.messageSendTimestamp(keccak256(xDomainCalldata)), 0);
uint256 balance = address(this).balance;
_invokeDepositERC20Call(
useRouter,
methodType,
address(l1Token),
amount,
recipient,
dataToCall,
gasLimit,
feePerGas
);
assertEq(balance - feePerGas, address(this).balance); // extra value is transferred back
assertGt(l1Messenger.messageSendTimestamp(keccak256(xDomainCalldata)), 0);
assertEq(thisBalance - amount, l1Token.balanceOf(address(this)));
assertEq(feeVaultBalance + feePerGas, address(feeVault).balance);
assertEq(gatewayBalance, l1Token.balanceOf(address(gateway)));
}
function _invokeDepositERC20Call(
bool useRouter,
uint256 methodType,
address token,
uint256 amount,
address recipient,
bytes memory dataToCall,
uint256 gasLimit,
uint256 feeToPay
) private {
uint256 value = feeToPay + extraValue;
if (useRouter) {
if (methodType == 0) {
router.depositERC20{value: value}(token, amount, gasLimit);
} else if (methodType == 1) {
router.depositERC20{value: value}(token, recipient, amount, gasLimit);
} else if (methodType == 2) {
router.depositERC20AndCall{value: value}(token, recipient, amount, dataToCall, gasLimit);
}
} else {
if (methodType == 0) {
gateway.depositERC20{value: value}(token, amount, gasLimit);
} else if (methodType == 1) {
gateway.depositERC20{value: value}(token, recipient, amount, gasLimit);
} else if (methodType == 2) {
gateway.depositERC20AndCall{value: value}(token, recipient, amount, dataToCall, gasLimit);
}
}
}
function _deployGateway(address messenger) internal returns (MockL1ReverseCustomERC20Gateway _gateway) {
_gateway = MockL1ReverseCustomERC20Gateway(_deployProxy(address(0)));
admin.upgrade(
ITransparentUpgradeableProxy(address(_gateway)),
address(new MockL1ReverseCustomERC20Gateway(address(counterpartGateway), address(router), messenger))
);
}
}