// SPDX-License-Identifier: BUSL-1.1 pragma solidity ^0.8.26; import "@src/executors/UniswapV4Executor.sol"; import {TychoRouter} from "@src/TychoRouter.sol"; import "./TychoRouterTestSetup.sol"; import "./executors/UniswapV4Utils.sol"; import {SafeCallback} from "@uniswap/v4-periphery/src/base/SafeCallback.sol"; contract TychoRouterTest is TychoRouterTestSetup { bytes32 public constant EXECUTOR_SETTER_ROLE = 0x6a1dd52dcad5bd732e45b6af4e7344fa284e2d7d4b23b5b09cb55d36b0685c87; bytes32 public constant FEE_SETTER_ROLE = 0xe6ad9a47fbda1dc18de1eb5eeb7d935e5e81b4748f3cfc61e233e64f88182060; bytes32 public constant PAUSER_ROLE = 0x65d7a28e3265b37a6474929f336521b332c1681b933f6cb9f3376673440d862a; bytes32 public constant FUND_RESCUER_ROLE = 0x912e45d663a6f4cc1d0491d8f046e06c616f40352565ea1cdb86a0e1aaefa41b; event CallbackVerifierSet(address indexed callbackVerifier); event Withdrawal( address indexed token, uint256 amount, address indexed receiver ); function testSetExecutorsValidRole() public { // Set single executor address[] memory executors = new address[](1); executors[0] = DUMMY; vm.startPrank(EXECUTOR_SETTER); tychoRouter.setExecutors(executors); vm.stopPrank(); assert(tychoRouter.executors(DUMMY) == true); // Set multiple executors address[] memory executors2 = new address[](2); executors2[0] = DUMMY2; executors2[1] = DUMMY3; vm.startPrank(EXECUTOR_SETTER); tychoRouter.setExecutors(executors2); vm.stopPrank(); assert(tychoRouter.executors(DUMMY2) == true); assert(tychoRouter.executors(DUMMY3) == true); } function testRemoveExecutorValidRole() public { vm.startPrank(EXECUTOR_SETTER); address[] memory executors = new address[](1); executors[0] = DUMMY; tychoRouter.setExecutors(executors); tychoRouter.removeExecutor(DUMMY); vm.stopPrank(); assert(tychoRouter.executors(DUMMY) == false); } function testRemoveExecutorMissingSetterRole() public { vm.expectRevert(); tychoRouter.removeExecutor(BOB); } function testSetExecutorsMissingSetterRole() public { vm.expectRevert(); address[] memory executors = new address[](1); executors[0] = DUMMY; tychoRouter.setExecutors(executors); } function testWithdrawNative() public { vm.startPrank(FUND_RESCUER); // Send 100 ether to tychoRouter assertEq(tychoRouterAddr.balance, 0); assertEq(FUND_RESCUER.balance, 0); vm.deal(tychoRouterAddr, 100 ether); vm.expectEmit(); emit Withdrawal(address(0), 100 ether, FUND_RESCUER); tychoRouter.withdrawNative(FUND_RESCUER); assertEq(tychoRouterAddr.balance, 0); assertEq(FUND_RESCUER.balance, 100 ether); vm.stopPrank(); } function testWithdrawNativeFailures() public { vm.deal(tychoRouterAddr, 100 ether); vm.startPrank(FUND_RESCUER); vm.expectRevert(TychoRouter__AddressZero.selector); tychoRouter.withdrawNative(address(0)); vm.stopPrank(); // Not role FUND_RESCUER vm.startPrank(BOB); vm.expectRevert(); tychoRouter.withdrawNative(FUND_RESCUER); vm.stopPrank(); } function testWithdrawERC20Tokens() public { vm.startPrank(BOB); mintTokens(100 ether, tychoRouterAddr); vm.stopPrank(); vm.startPrank(FUND_RESCUER); IERC20[] memory tokensArray = new IERC20[](3); tokensArray[0] = IERC20(address(tokens[0])); tokensArray[1] = IERC20(address(tokens[1])); tokensArray[2] = IERC20(address(tokens[2])); tychoRouter.withdraw(tokensArray, FUND_RESCUER); // Check balances after withdrawing for (uint256 i = 0; i < tokens.length; i++) { // slither-disable-next-line calls-loop assertEq(tokens[i].balanceOf(tychoRouterAddr), 0); // slither-disable-next-line calls-loop assertEq(tokens[i].balanceOf(FUND_RESCUER), 100 ether); } vm.stopPrank(); } function testWithdrawERC20TokensFailures() public { mintTokens(100 ether, tychoRouterAddr); IERC20[] memory tokensArray = new IERC20[](3); tokensArray[0] = IERC20(address(tokens[0])); tokensArray[1] = IERC20(address(tokens[1])); tokensArray[2] = IERC20(address(tokens[2])); vm.startPrank(FUND_RESCUER); vm.expectRevert(TychoRouter__AddressZero.selector); tychoRouter.withdraw(tokensArray, address(0)); vm.stopPrank(); // Not role FUND_RESCUER vm.startPrank(BOB); vm.expectRevert(); tychoRouter.withdraw(tokensArray, FUND_RESCUER); vm.stopPrank(); } function testFeeSetting() public { vm.startPrank(FEE_SETTER); assertEq(tychoRouter.fee(), 0); tychoRouter.setFee(100); assertEq(tychoRouter.fee(), 100); vm.stopPrank(); vm.startPrank(BOB); vm.expectRevert(); tychoRouter.setFee(200); vm.stopPrank(); } function testFeeReceiverSetting() public { vm.startPrank(FEE_SETTER); assertEq(tychoRouter.feeReceiver(), address(0)); tychoRouter.setFeeReceiver(FEE_RECEIVER); assertEq(tychoRouter.feeReceiver(), FEE_RECEIVER); vm.stopPrank(); vm.startPrank(BOB); vm.expectRevert(); tychoRouter.setFeeReceiver(FEE_RECEIVER); vm.stopPrank(); } function testPause() public { vm.startPrank(PAUSER); assertEq(tychoRouter.paused(), false); tychoRouter.pause(); assertEq(tychoRouter.paused(), true); vm.stopPrank(); vm.startPrank(UNPAUSER); tychoRouter.unpause(); assertEq(tychoRouter.paused(), false); vm.stopPrank(); vm.startPrank(UNPAUSER); vm.expectRevert(); tychoRouter.unpause(); vm.stopPrank(); } function testPauseNonRole() public { vm.startPrank(BOB); vm.expectRevert(); tychoRouter.pause(); vm.stopPrank(); } function testWrapETH() public { uint256 amount = 1 ether; vm.deal(BOB, amount); vm.startPrank(BOB); tychoRouter.wrapETH{value: amount}(amount); vm.stopPrank(); assertEq(tychoRouterAddr.balance, 0); assertEq(IERC20(WETH_ADDR).balanceOf(tychoRouterAddr), amount); } function testUnwrapETH() public { uint256 amount = 1 ether; deal(WETH_ADDR, tychoRouterAddr, amount); tychoRouter.unwrapETH(amount); assertEq(tychoRouterAddr.balance, amount); assertEq(IERC20(WETH_ADDR).balanceOf(tychoRouterAddr), 0); } function testSplitSwapSimple() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V2 // 1 WETH -> DAI // (USV2) uint256 amountIn = 1 ether; deal(WETH_ADDR, tychoRouterAddr, amountIn); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; tychoRouter.exposedSplitSwap(amountIn, 2, pleEncode(swaps)); uint256 daiBalance = IERC20(DAI_ADDR).balanceOf(tychoRouterAddr); assertEq(daiBalance, 2659881924818443699787); assertEq(IERC20(WETH_ADDR).balanceOf(tychoRouterAddr), 0); } function testSingleSwapSimplePermit2() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V2 using Permit2 // 1 WETH -> DAI // (USV2) vm.startPrank(ALICE); uint256 amountIn = 1 ether; deal(WETH_ADDR, ALICE, amountIn); ( IAllowanceTransfer.PermitSingle memory permitSingle, bytes memory signature ) = handlePermit2Approval(WETH_ADDR, amountIn); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; tychoRouter.splitSwapPermit2( amountIn, WETH_ADDR, DAI_ADDR, 2659881924818443699786, false, false, 2, ALICE, permitSingle, signature, pleEncode(swaps) ); uint256 daiBalance = IERC20(DAI_ADDR).balanceOf(ALICE); assertEq(daiBalance, 2659881924818443699787); assertEq(IERC20(WETH_ADDR).balanceOf(ALICE), 0); vm.stopPrank(); } function testSequentialSwapMultipleHops() public { // Trade 1 WETH for USDC through DAI with 2 swaps on Uniswap V2 // 1 WETH -> DAI -> USDC // (univ2) (univ2) uint256 amountIn = 1 ether; deal(WETH_ADDR, tychoRouterAddr, amountIn); bytes[] memory swaps = new bytes[](2); // WETH -> DAI swaps[0] = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ) ); // DAI -> USDC swaps[1] = encodeSplitSwap( uint8(1), uint8(2), uint24(0), address(usv2Executor), encodeUniswapV2Swap(DAI_ADDR, DAI_USDC_POOL, tychoRouterAddr, true) ); tychoRouter.exposedSequentialSwap(amountIn, pleEncode(swaps)); uint256 usdcBalance = IERC20(USDC_ADDR).balanceOf(tychoRouterAddr); assertEq(usdcBalance, 2644659787); assertEq(IERC20(WETH_ADDR).balanceOf(tychoRouterAddr), 0); } function testSplitSwapSplitHops() public { // Trade 1 WETH for USDC through DAI and WBTC with 4 swaps on Uniswap V2 // -> DAI -> // 1 WETH USDC // -> WBTC -> // (univ2) (univ2) uint256 amountIn = 1 ether; deal(WETH_ADDR, tychoRouterAddr, amountIn); bytes[] memory swaps = new bytes[](4); // WETH -> WBTC (60%) swaps[0] = encodeSplitSwap( uint8(0), uint8(1), (0xffffff * 60) / 100, // 60% address(usv2Executor), encodeUniswapV2Swap( WETH_ADDR, WETH_WBTC_POOL, tychoRouterAddr, false ) ); // WBTC -> USDC swaps[1] = encodeSplitSwap( uint8(1), uint8(2), uint24(0), address(usv2Executor), encodeUniswapV2Swap( WBTC_ADDR, USDC_WBTC_POOL, tychoRouterAddr, true ) ); // WETH -> DAI swaps[2] = encodeSplitSwap( uint8(0), uint8(3), uint24(0), address(usv2Executor), encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ) ); // DAI -> USDC swaps[3] = encodeSplitSwap( uint8(3), uint8(2), uint24(0), address(usv2Executor), encodeUniswapV2Swap(DAI_ADDR, DAI_USDC_POOL, tychoRouterAddr, true) ); tychoRouter.exposedSplitSwap(amountIn, 4, pleEncode(swaps)); uint256 usdcBalance = IERC20(USDC_ADDR).balanceOf(tychoRouterAddr); assertEq(usdcBalance, 2615491639); assertEq(IERC20(WETH_ADDR).balanceOf(tychoRouterAddr), 0); } function testSingleSwapChecked() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V2 // Does permit2 token approval and transfer // Checks amount out at the end uint256 amountIn = 1 ether; deal(WETH_ADDR, ALICE, amountIn); vm.startPrank(ALICE); ( IAllowanceTransfer.PermitSingle memory permitSingle, bytes memory signature ) = handlePermit2Approval(WETH_ADDR, amountIn); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); uint256 minAmountOut = 2600 * 1e18; uint256 amountOut = tychoRouter.singleSwapPermit2( amountIn, WETH_ADDR, DAI_ADDR, minAmountOut, false, false, 2, ALICE, permitSingle, signature, swap ); uint256 expectedAmount = 2659881924818443699787; assertEq(amountOut, expectedAmount); uint256 daiBalance = IERC20(DAI_ADDR).balanceOf(ALICE); assertEq(daiBalance, expectedAmount); assertEq(IERC20(WETH_ADDR).balanceOf(ALICE), 0); vm.stopPrank(); } function testSplitSwapCheckedUndefinedMinAmount() public { // Min amount should always be non-zero. If zero, swap attempt should revert. uint256 amountIn = 1 ether; deal(WETH_ADDR, ALICE, amountIn); vm.startPrank(ALICE); ( IAllowanceTransfer.PermitSingle memory permitSingle, bytes memory signature ) = handlePermit2Approval(WETH_ADDR, amountIn); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; uint256 minAmountOut = 0; vm.expectRevert(TychoRouter__UndefinedMinAmountOut.selector); tychoRouter.splitSwapPermit2( amountIn, WETH_ADDR, DAI_ADDR, minAmountOut, false, false, 2, ALICE, permitSingle, signature, pleEncode(swaps) ); vm.stopPrank(); } function testSingleSwapCheckedNoPermit2() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V2 // Checks amount out at the end uint256 amountIn = 1 ether; deal(WETH_ADDR, ALICE, amountIn); vm.startPrank(ALICE); // Approve the tokenIn to be transferred to the router IERC20(WETH_ADDR).approve(address(tychoRouterAddr), amountIn); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); uint256 minAmountOut = 2600 * 1e18; uint256 amountOut = tychoRouter.singleSwap( amountIn, WETH_ADDR, DAI_ADDR, minAmountOut, false, false, 2, ALICE, swap ); uint256 expectedAmount = 2659881924818443699787; assertEq(amountOut, expectedAmount); uint256 daiBalance = IERC20(DAI_ADDR).balanceOf(ALICE); assertEq(daiBalance, expectedAmount); assertEq(IERC20(WETH_ADDR).balanceOf(ALICE), 0); vm.stopPrank(); } function testSplitSwapCheckedLessApprovalFailure() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V2 // Fails while transferring the tokenIn to the router due to insufficient approval uint256 amountIn = 1 ether; deal(WETH_ADDR, ALICE, amountIn); vm.startPrank(ALICE); // Approve less than the amountIn IERC20(WETH_ADDR).approve(address(tychoRouterAddr), amountIn - 1); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; uint256 minAmountOut = 2600 * 1e18; vm.expectRevert(); tychoRouter.splitSwap( amountIn, WETH_ADDR, DAI_ADDR, minAmountOut, false, false, 2, ALICE, pleEncode(swaps) ); vm.stopPrank(); } function testSplitSwapCheckedNegativeSlippageFailure() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V2 // Does permit2 token approval and transfer // Checks amount out at the end and fails uint256 amountIn = 1 ether; deal(WETH_ADDR, ALICE, amountIn); vm.startPrank(ALICE); ( IAllowanceTransfer.PermitSingle memory permitSingle, bytes memory signature ) = handlePermit2Approval(WETH_ADDR, amountIn); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; uint256 minAmountOut = 3000 * 1e18; vm.expectRevert( abi.encodeWithSelector( TychoRouter__NegativeSlippage.selector, 2659881924818443699787, // actual amountOut minAmountOut ) ); tychoRouter.splitSwapPermit2( amountIn, WETH_ADDR, DAI_ADDR, minAmountOut, false, false, 2, ALICE, permitSingle, signature, pleEncode(swaps) ); vm.stopPrank(); } function testSplitSwapFee() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V2 // Does permit2 token approval and transfer // Takes fee at the end vm.startPrank(FEE_SETTER); tychoRouter.setFee(100); tychoRouter.setFeeReceiver(FEE_RECEIVER); vm.stopPrank(); uint256 amountIn = 1 ether; deal(WETH_ADDR, ALICE, amountIn); vm.startPrank(ALICE); ( IAllowanceTransfer.PermitSingle memory permitSingle, bytes memory signature ) = handlePermit2Approval(WETH_ADDR, amountIn); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; uint256 amountOut = tychoRouter.splitSwapPermit2( amountIn, WETH_ADDR, DAI_ADDR, 2633283105570259262780, false, false, 2, ALICE, permitSingle, signature, pleEncode(swaps) ); uint256 expectedAmount = 2633283105570259262790; assertEq(amountOut, expectedAmount); uint256 daiBalance = IERC20(DAI_ADDR).balanceOf(ALICE); assertEq(daiBalance, expectedAmount); assertEq(IERC20(DAI_ADDR).balanceOf(FEE_RECEIVER), 26598819248184436997); vm.stopPrank(); } function testSplitSwapWrapETH() public { // Trade 1 ETH (and wrap it) for DAI with 1 swap on Uniswap V2 uint256 amountIn = 1 ether; deal(ALICE, amountIn); vm.startPrank(ALICE); IAllowanceTransfer.PermitSingle memory emptyPermitSingle = IAllowanceTransfer.PermitSingle({ details: IAllowanceTransfer.PermitDetails({ token: address(0), amount: 0, expiration: 0, nonce: 0 }), spender: address(0), sigDeadline: 0 }); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; uint256 amountOut = tychoRouter.splitSwapPermit2{value: amountIn}( amountIn, address(0), DAI_ADDR, 2659881924818443699780, true, false, 2, ALICE, emptyPermitSingle, "", pleEncode(swaps) ); uint256 expectedAmount = 2659881924818443699787; assertEq(amountOut, expectedAmount); uint256 daiBalance = IERC20(DAI_ADDR).balanceOf(ALICE); assertEq(daiBalance, expectedAmount); assertEq(ALICE.balance, 0); vm.stopPrank(); } function testSplitSwapUnwrapETH() public { // Trade 3k DAI for WETH with 1 swap on Uniswap V2 and unwrap it at the end uint256 amountIn = 3_000 * 10 ** 18; deal(DAI_ADDR, ALICE, amountIn); vm.startPrank(ALICE); ( IAllowanceTransfer.PermitSingle memory permitSingle, bytes memory signature ) = handlePermit2Approval(DAI_ADDR, amountIn); bytes memory protocolData = encodeUniswapV2Swap(DAI_ADDR, WETH_DAI_POOL, tychoRouterAddr, true); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; uint256 amountOut = tychoRouter.splitSwapPermit2( amountIn, DAI_ADDR, address(0), 1120007305574805920, false, true, 2, ALICE, permitSingle, signature, pleEncode(swaps) ); uint256 expectedAmount = 1120007305574805922; // 1.12 ETH assertEq(amountOut, expectedAmount); assertEq(ALICE.balance, expectedAmount); vm.stopPrank(); } function testSplitSwapSingleUSV3() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V3 // 1 WETH -> DAI // (USV3) uint256 amountIn = 10 ** 18; deal(WETH_ADDR, tychoRouterAddr, amountIn); uint256 expAmountOut = 1205_128428842122129186; //Swap 1 WETH for 1205.12 DAI bool zeroForOne = false; bytes memory protocolData = encodeUniswapV3Swap( WETH_ADDR, DAI_ADDR, tychoRouterAddr, DAI_WETH_USV3, zeroForOne ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv3Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; tychoRouter.exposedSplitSwap(amountIn, 2, pleEncode(swaps)); uint256 finalBalance = IERC20(DAI_ADDR).balanceOf(tychoRouterAddr); assertGe(finalBalance, expAmountOut); } function testSplitSwapSingleUSV3Permit2() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V3 using Permit2 // 1 WETH -> DAI // (USV3) vm.startPrank(ALICE); uint256 amountIn = 10 ** 18; deal(WETH_ADDR, ALICE, amountIn); ( IAllowanceTransfer.PermitSingle memory permitSingle, bytes memory signature ) = handlePermit2Approval(WETH_ADDR, amountIn); uint256 expAmountOut = 1205_128428842122129186; //Swap 1 WETH for 1205.12 DAI bool zeroForOne = false; bytes memory protocolData = encodeUniswapV3Swap( WETH_ADDR, DAI_ADDR, tychoRouterAddr, DAI_WETH_USV3, zeroForOne ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv3Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; tychoRouter.splitSwapPermit2( amountIn, WETH_ADDR, DAI_ADDR, expAmountOut - 1, false, false, 2, ALICE, permitSingle, signature, pleEncode(swaps) ); uint256 finalBalance = IERC20(DAI_ADDR).balanceOf(ALICE); assertGe(finalBalance, expAmountOut); vm.stopPrank(); } function testEmptySwapsRevert() public { uint256 amountIn = 10 ** 18; bytes memory swaps = ""; vm.expectRevert(TychoRouter__EmptySwaps.selector); tychoRouter.exposedSplitSwap(amountIn, 2, swaps); } function testSplitSwapAmountInNotFullySpent() public { // Trade 1 WETH for DAI with 1 swap on Uniswap V2 // Has invalid data as input! There is only one swap with 60% of the input amount uint256 amountIn = 1 ether; deal(WETH_ADDR, ALICE, amountIn); vm.startPrank(ALICE); ( IAllowanceTransfer.PermitSingle memory permitSingle, bytes memory signature ) = handlePermit2Approval(WETH_ADDR, amountIn); bytes memory protocolData = encodeUniswapV2Swap( WETH_ADDR, WETH_DAI_POOL, tychoRouterAddr, false ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), (0xffffff * 60) / 100, // 60% address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; vm.expectRevert( abi.encodeWithSelector( TychoRouter__AmountInDiffersFromConsumed.selector, 1000000000000000000, 600000000000000000 ) ); tychoRouter.splitSwapPermit2( amountIn, WETH_ADDR, DAI_ADDR, 1, false, false, 2, ALICE, permitSingle, signature, pleEncode(swaps) ); vm.stopPrank(); } function testSplitSwapSingleUSV4Callback() public { uint256 amountIn = 100 ether; deal(USDE_ADDR, tychoRouterAddr, amountIn); UniswapV4Executor.UniswapV4Pool[] memory pools = new UniswapV4Executor.UniswapV4Pool[](1); pools[0] = UniswapV4Executor.UniswapV4Pool({ intermediaryToken: USDT_ADDR, fee: uint24(100), tickSpacing: int24(1) }); bytes memory protocolData = UniswapV4Utils.encodeExactInput( USDE_ADDR, USDT_ADDR, true, address(usv4Executor), pools ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv4Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; tychoRouter.exposedSplitSwap(amountIn, 2, pleEncode(swaps)); assertEq(IERC20(USDT_ADDR).balanceOf(tychoRouterAddr), 99943852); } function testSplitSwapSingleUSV4CallbackPermit2() public { vm.startPrank(ALICE); uint256 amountIn = 100 ether; deal(USDE_ADDR, ALICE, amountIn); ( IAllowanceTransfer.PermitSingle memory permitSingle, bytes memory signature ) = handlePermit2Approval(USDE_ADDR, amountIn); UniswapV4Executor.UniswapV4Pool[] memory pools = new UniswapV4Executor.UniswapV4Pool[](1); pools[0] = UniswapV4Executor.UniswapV4Pool({ intermediaryToken: USDT_ADDR, fee: uint24(100), tickSpacing: int24(1) }); bytes memory protocolData = UniswapV4Utils.encodeExactInput( USDE_ADDR, USDT_ADDR, true, address(usv4Executor), pools ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv4Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; tychoRouter.splitSwapPermit2( amountIn, USDE_ADDR, USDT_ADDR, 99943850, false, false, 2, ALICE, permitSingle, signature, pleEncode(swaps) ); assertEq(IERC20(USDT_ADDR).balanceOf(ALICE), 99943852); vm.stopPrank(); } function testSplitSwapMultipleUSV4Callback() public { // This test has two uniswap v4 hops that will be executed inside of the V4 pool manager // USDE -> USDT -> WBTC uint256 amountIn = 100 ether; deal(USDE_ADDR, tychoRouterAddr, amountIn); UniswapV4Executor.UniswapV4Pool[] memory pools = new UniswapV4Executor.UniswapV4Pool[](2); pools[0] = UniswapV4Executor.UniswapV4Pool({ intermediaryToken: USDT_ADDR, fee: uint24(100), tickSpacing: int24(1) }); pools[1] = UniswapV4Executor.UniswapV4Pool({ intermediaryToken: WBTC_ADDR, fee: uint24(3000), tickSpacing: int24(60) }); bytes memory protocolData = UniswapV4Utils.encodeExactInput( USDE_ADDR, WBTC_ADDR, true, address(usv4Executor), pools ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv4Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; tychoRouter.exposedSplitSwap(amountIn, 2, pleEncode(swaps)); assertEq(IERC20(WBTC_ADDR).balanceOf(tychoRouterAddr), 102718); } function testCyclicSequentialSwap() public { // This test has start and end tokens that are the same // The flow is: // USDC --(USV3)--> WETH --(USV3)--> USDC uint256 amountIn = 100 * 10 ** 6; deal(USDC_ADDR, tychoRouterAddr, amountIn); bytes memory usdcWethV3Pool1ZeroOneData = encodeUniswapV3Swap( USDC_ADDR, WETH_ADDR, tychoRouterAddr, USDC_WETH_USV3, true ); bytes memory usdcWethV3Pool2OneZeroData = encodeUniswapV3Swap( WETH_ADDR, USDC_ADDR, tychoRouterAddr, USDC_WETH_USV3_2, false ); bytes[] memory swaps = new bytes[](2); // USDC -> WETH swaps[0] = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv3Executor), usdcWethV3Pool1ZeroOneData ); // WETH -> USDC swaps[1] = encodeSplitSwap( uint8(1), uint8(0), uint24(0), address(usv3Executor), usdcWethV3Pool2OneZeroData ); tychoRouter.exposedSequentialSwap(amountIn, pleEncode(swaps)); assertEq(IERC20(USDC_ADDR).balanceOf(tychoRouterAddr), 99889294); } function testSplitInputCyclicSwap() public { // This test has start and end tokens that are the same // The flow is: // ┌─ (USV3, 60% split) ──> WETH ─┐ // │ │ // USDC ──────┤ ├──(USV2)──> USDC // │ │ // └─ (USV3, 40% split) ──> WETH ─┘ uint256 amountIn = 100 * 10 ** 6; deal(USDC_ADDR, tychoRouterAddr, amountIn); bytes memory usdcWethV3Pool1ZeroOneData = encodeUniswapV3Swap( USDC_ADDR, WETH_ADDR, tychoRouterAddr, USDC_WETH_USV3, true ); bytes memory usdcWethV3Pool2ZeroOneData = encodeUniswapV3Swap( USDC_ADDR, WETH_ADDR, tychoRouterAddr, USDC_WETH_USV3_2, true ); bytes memory wethUsdcV2OneZeroData = encodeUniswapV2Swap( WETH_ADDR, USDC_WETH_USV2, tychoRouterAddr, false ); bytes[] memory swaps = new bytes[](3); // USDC -> WETH (60% split) swaps[0] = encodeSplitSwap( uint8(0), uint8(1), (0xffffff * 60) / 100, // 60% address(usv3Executor), usdcWethV3Pool1ZeroOneData ); // USDC -> WETH (40% remainder) swaps[1] = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv3Executor), usdcWethV3Pool2ZeroOneData ); // WETH -> USDC swaps[2] = encodeSplitSwap( uint8(1), uint8(0), uint24(0), address(usv2Executor), wethUsdcV2OneZeroData ); tychoRouter.exposedSplitSwap(amountIn, 2, pleEncode(swaps)); assertEq(IERC20(USDC_ADDR).balanceOf(tychoRouterAddr), 99574171); } function testSplitOutputCyclicSwap() public { // This test has start and end tokens that are the same // The flow is: // ┌─── (USV3, 60% split) ───┐ // │ │ // USDC ──(USV2) ── WETH──| ├─> USDC // │ │ // └─── (USV3, 40% split) ───┘ uint256 amountIn = 100 * 10 ** 6; deal(USDC_ADDR, tychoRouterAddr, amountIn); bytes memory usdcWethV2Data = encodeUniswapV2Swap( USDC_ADDR, USDC_WETH_USV2, tychoRouterAddr, true ); bytes memory usdcWethV3Pool1OneZeroData = encodeUniswapV3Swap( WETH_ADDR, USDC_ADDR, tychoRouterAddr, USDC_WETH_USV3, false ); bytes memory usdcWethV3Pool2OneZeroData = encodeUniswapV3Swap( WETH_ADDR, USDC_ADDR, tychoRouterAddr, USDC_WETH_USV3_2, false ); bytes[] memory swaps = new bytes[](3); // USDC -> WETH swaps[0] = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), usdcWethV2Data ); // WETH -> USDC swaps[1] = encodeSplitSwap( uint8(1), uint8(0), (0xffffff * 60) / 100, address(usv3Executor), usdcWethV3Pool1OneZeroData ); // WETH -> USDC swaps[2] = encodeSplitSwap( uint8(1), uint8(0), uint24(0), address(usv3Executor), usdcWethV3Pool2OneZeroData ); tychoRouter.exposedSplitSwap(amountIn, 2, pleEncode(swaps)); assertEq(IERC20(USDC_ADDR).balanceOf(tychoRouterAddr), 99525908); } // Base Network Tests // Make sure to set the RPC_URL to base network function testSplitSwapSingleBase() public { vm.skip(true); vm.rollFork(26857267); uint256 amountIn = 10 * 10 ** 6; deal(BASE_USDC, tychoRouterAddr, amountIn); bytes memory protocolData = encodeUniswapV2Swap( BASE_USDC, USDC_MAG7_POOL, tychoRouterAddr, true ); bytes memory swap = encodeSplitSwap( uint8(0), uint8(1), uint24(0), address(usv2Executor), protocolData ); bytes[] memory swaps = new bytes[](1); swaps[0] = swap; tychoRouter.exposedSplitSwap(amountIn, 2, pleEncode(swaps)); assertGt(IERC20(BASE_MAG7).balanceOf(tychoRouterAddr), 1379830606); } }