// SPDX-License-Identifier: BUSL-1.1 pragma solidity ^0.8.26; import "@src/executors/CurveExecutor.sol"; import {Test} from "../../lib/forge-std/src/Test.sol"; import {Constants} from "../Constants.sol"; interface ICurvePool { function coins(uint256 i) external view returns (address); } // Curve pool registry // This is the registry that contains the information about the pool // The naming convention is different because it is in vyper interface MetaRegistry { function get_n_coins(address pool) external view returns (uint256); function get_coin_indices(address pool, address from, address to) external view returns (int128, int128, bool); } interface IAaveLendingPool { function deposit( address asset, uint256 amount, address onBehalfOf, uint16 referralCode ) external; function withdraw(address asset, uint256 amount, address to) external returns (uint256); } contract CurveExecutorExposed is CurveExecutor { constructor(address _curveRouter, address _nativeToken) CurveExecutor(_curveRouter, _nativeToken) {} function decodeParams(bytes calldata data) external pure returns (CurveSwapParams memory params) { return _decodeData(data); } } contract CurveExecutorTest is Test, Constants { using SafeERC20 for IERC20; CurveExecutorExposed curveExecutorExposed; MetaRegistry metaRegistry; function setUp() public { uint256 forkBlock = 22031795; vm.createSelectFork(vm.rpcUrl("mainnet"), forkBlock); curveExecutorExposed = new CurveExecutorExposed(CURVE_ROUTER, ETH_ADDR); metaRegistry = MetaRegistry(CURVE_META_REGISTRY); } function testDecodeParams() public view { address[11] memory route = _getRoute(WETH_ADDR, USDC_ADDR, TRICRYPTO_POOL); // The meta registry does not have information about the pool. // We manually set the swap params. uint256[5][5] memory swapParams; swapParams[0][0] = 2; // tokenIn Index swapParams[0][1] = 0; // tokenOut Index swapParams[0][2] = 1; // swap type swapParams[0][3] = 3; // pool type swapParams[0][4] = 3; // n_coins bytes memory data = abi.encode(route, swapParams, address(this), true); CurveExecutor.CurveSwapParams memory params = curveExecutorExposed.decodeParams(data); assertEq(params.route[0], WETH_ADDR); assertEq(params.route[1], TRICRYPTO_POOL); assertEq(params.route[2], USDC_ADDR); assertEq(params.swapParams[0][0], 2); assertEq(params.swapParams[0][1], 0); assertEq(params.swapParams[0][2], 1); assertEq(params.swapParams[0][3], 3); assertEq(params.swapParams[0][4], 3); assertEq(params.receiver, address(this)); assertEq(params.needsApproval, true); } function testTriPool() public { // Swapping DAI -> USDC on TriPool 0xbEbc44782C7dB0a1A60Cb6fe97d0b483032FF1C7 address[11] memory route = _getRoute(DAI_ADDR, USDC_ADDR, TRIPOOL); uint256[5][5] memory swapParams = _getSwapParams(TRIPOOL, DAI_ADDR, USDC_ADDR, 1, 1); uint256 amountIn = 1 ether; deal(DAI_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(this), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 999796); assertEq(IERC20(USDC_ADDR).balanceOf(address(this)), amountOut); } function testStEthPool() public { // Swapping ETH -> stETH on StEthPool 0xDC24316b9AE028F1497c275EB9192a3Ea0f67022 address[11] memory route = _getRoute(ETH_ADDR, STETH_ADDR, STETH_POOL); uint256[5][5] memory swapParams = _getSwapParams(STETH_POOL, ETH_ADDR, STETH_ADDR, 1, 1); uint256 amountIn = 1 ether; deal(address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(this), false); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertTrue(amountOut == 1001072414418410898); assertEq(IERC20(STETH_ADDR).balanceOf(address(this)), amountOut - 1); //// Gets 1 wei less than amountOut } function testTricrypto2Pool() public { // Swapping WETH -> WBTC on Tricrypto2Pool 0xD51a44d3FaE010294C616388b506AcdA1bfAAE46 address[11] memory route = _getRoute(WETH_ADDR, WBTC_ADDR, TRICRYPTO2_POOL); uint256[5][5] memory swapParams = _getSwapParams(TRICRYPTO2_POOL, WETH_ADDR, WBTC_ADDR, 1, 3); uint256 amountIn = 1 ether; deal(WETH_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 2279618); assertEq( IERC20(WBTC_ADDR).balanceOf(address(curveExecutorExposed)), amountOut ); } function testSUSDPool() public { // Swapping USDC -> SUSD on SUSDPool 0xA5407eAE9Ba41422680e2e00537571bcC53efBfD address[11] memory route = _getRoute(USDC_ADDR, SUSD_ADDR, SUSD_POOL); uint256[5][5] memory swapParams = _getSwapParams(SUSD_POOL, USDC_ADDR, SUSD_ADDR, 1, 1); uint256 amountIn = 100 * 10 ** 6; deal(USDC_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 100488101605550214590); assertEq( IERC20(SUSD_ADDR).balanceOf(address(curveExecutorExposed)), amountOut ); } function testFraxUsdcPool() public { // Swapping FRAX -> USDC on FraxUsdcPool 0xDcEF968d416a41Cdac0ED8702fAC8128A64241A2 address[11] memory route = _getRoute(FRAX_ADDR, USDC_ADDR, FRAX_USDC_POOL); uint256[5][5] memory swapParams = _getSwapParams(FRAX_USDC_POOL, FRAX_ADDR, USDC_ADDR, 1, 1); uint256 amountIn = 1 ether; deal(FRAX_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 998096); assertEq( IERC20(USDC_ADDR).balanceOf(address(curveExecutorExposed)), amountOut ); } function testUsdeUsdcPool() public { // Swapping USDC -> USDE on a CryptoSwapNG, deployed by factory 0x6A8cbed756804B16E05E741eDaBd5cB544AE21bf (plain pool) address[11] memory route = _getRoute(USDC_ADDR, USDE_ADDR, USDE_USDC_POOL); uint256[5][5] memory swapParams = _getSwapParams(USDE_USDC_POOL, USDC_ADDR, USDE_ADDR, 1, 1); uint256 amountIn = 100 * 10 ** 6; deal(USDC_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 100064812138999986170); assertEq( IERC20(USDE_ADDR).balanceOf(address(curveExecutorExposed)), amountOut ); } function testDolaFraxPyusdPool() public { // Swapping DOLA -> FRAXPYUSD on a CryptoSwapNG, deployed by factory 0x6A8cbed756804B16E05E741eDaBd5cB544AE21bf (meta pool) address[11] memory route = _getRoute(DOLA_ADDR, FRAXPYUSD_POOL, DOLA_FRAXPYUSD_POOL); uint256[5][5] memory swapParams = _getSwapParams(DOLA_FRAXPYUSD_POOL, DOLA_ADDR, FRAXPYUSD_POOL, 1, 1); uint256 amountIn = 100 * 10 ** 6; deal(DOLA_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 99688991); assertEq( IERC20(FRAXPYUSD_POOL).balanceOf(address(curveExecutorExposed)), amountOut ); } function testCryptoPoolWithETH() public { // Swapping XYO -> ETH on a CryptoPool, deployed by factory 0xF18056Bbd320E96A48e3Fbf8bC061322531aac99 address[11] memory route = _getRoute(XYO_ADDR, ETH_ADDR, ETH_XYO_POOL); uint256[5][5] memory swapParams = _getSwapParams(ETH_XYO_POOL, XYO_ADDR, ETH_ADDR, 1, 2); uint256 amountIn = 1 ether; uint256 initialBalance = address(curveExecutorExposed).balance; // this address already has some ETH assigned to it deal(XYO_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 6081816039338); assertEq( address(curveExecutorExposed).balance, initialBalance + amountOut ); } function testCryptoPool() public { // Swapping BSGG -> USDT on a CryptoPool, deployed by factory 0xF18056Bbd320E96A48e3Fbf8bC061322531aac99 address[11] memory route = _getRoute(BSGG_ADDR, USDT_ADDR, BSGG_USDT_POOL); uint256[5][5] memory swapParams = _getSwapParams(BSGG_USDT_POOL, BSGG_ADDR, USDT_ADDR, 1, 2); uint256 amountIn = 1000 ether; deal(BSGG_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 23429); assertEq( IERC20(USDT_ADDR).balanceOf(address(curveExecutorExposed)), amountOut ); } function testTricryptoPool() public { // Swapping WETH -> USDC on a Tricrypto pool, deployed by factory 0x0c0e5f2fF0ff18a3be9b835635039256dC4B4963 address[11] memory route = _getRoute(WETH_ADDR, USDC_ADDR, TRICRYPTO_POOL); uint256[5][5] memory swapParams = _getSwapParams(TRICRYPTO_POOL, WETH_ADDR, USDC_ADDR, 1, 2); uint256 amountIn = 1 ether; deal(WETH_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(this), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 1861130973); assertEq(IERC20(USDC_ADDR).balanceOf(address(this)), amountOut); } function testTwoCryptoPool() public { // Swapping UWU -> WETH on a Twocrypto pool, deployed by factory 0x98ee851a00abee0d95d08cf4ca2bdce32aeaaf7f address[11] memory route = _getRoute(UWU_ADDR, WETH_ADDR, UWU_WETH_POOL); uint256[5][5] memory swapParams = _getSwapParams(UWU_WETH_POOL, UWU_ADDR, WETH_ADDR, 1, 2); uint256 amountIn = 1 ether; deal(UWU_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 2873786684675); assertEq( IERC20(WETH_ADDR).balanceOf(address(curveExecutorExposed)), amountOut ); } function testStableSwapPool() public { // Swapping CRVUSD -> USDT on a StableSwap pool, deployed by factory 0x4F8846Ae9380B90d2E71D5e3D042dff3E7ebb40d (plain pool) address[11] memory route = _getRoute(CRVUSD_ADDR, USDT_ADDR, CRVUSD_USDT_POOL); uint256[5][5] memory swapParams = _getSwapParams(CRVUSD_USDT_POOL, CRVUSD_ADDR, USDT_ADDR, 1, 1); uint256 amountIn = 1 ether; deal(CRVUSD_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 999910); assertEq( IERC20(USDT_ADDR).balanceOf(address(curveExecutorExposed)), amountOut ); } function testMetaPool() public { // Swapping WTAO -> WSTTAO on a MetaPool deployed by factory 0xB9fC157394Af804a3578134A6585C0dc9cc990d4 (plain pool) address[11] memory route = _getRoute(WTAO_ADDR, WSTTAO_ADDR, WSTTAO_WTAO_POOL); uint256[5][5] memory swapParams = _getSwapParams(WSTTAO_WTAO_POOL, WTAO_ADDR, WSTTAO_ADDR, 1, 1); uint256 amountIn = 100 * 10 ** 9; // 9 decimals deal(WTAO_ADDR, address(curveExecutorExposed), amountIn); bytes memory data = abi.encode(route, swapParams, address(curveExecutorExposed), true); uint256 amountOut = curveExecutorExposed.swap(amountIn, data); assertEq(amountOut, 32797923609); assertEq( IERC20(WSTTAO_ADDR).balanceOf(address(curveExecutorExposed)), amountOut ); } function _getRoute(address tokenIn, address tokenOut, address pool) internal pure returns (address[11] memory route) { route[0] = tokenIn; route[2] = tokenOut; route[1] = pool; } function _getSwapParams( address pool, address tokenIn, address tokenOut, uint256 swapType, uint256 poolType ) internal view returns (uint256[5][5] memory swapParams) { uint256 nCoins = metaRegistry.get_n_coins(pool); (int128 coinInIndex, int128 coinOutIndex,) = metaRegistry.get_coin_indices(pool, tokenIn, tokenOut); swapParams[0][0] = uint256(int256(coinInIndex)); swapParams[0][1] = uint256(int256(coinOutIndex)); swapParams[0][2] = swapType; swapParams[0][3] = poolType; swapParams[0][4] = nCoins; } function dealAaveDai() internal { deal(DAI_ADDR, address(curveExecutorExposed), 100_000 * 10 ** 18); IAaveLendingPool aave = IAaveLendingPool(0x7d2768dE32b0b80b7a3454c06BdAc94A69DDc7A9); vm.startPrank(address(curveExecutorExposed)); IERC20(DAI_ADDR).approve(address(aave), type(uint256).max); aave.deposit( DAI_ADDR, 100_000 * 10 ** 18, address(curveExecutorExposed), 0 ); vm.stopPrank(); } }