pragma solidity ^0.5.7; interface RegistryInterface { function proxies(address) external view returns (address); } interface UserWalletInterface { function owner() external view returns (address); } interface TubInterface { function open() external returns (bytes32); function join(uint) external; function exit(uint) external; function lock(bytes32, uint) external; function free(bytes32, uint) external; function draw(bytes32, uint) external; function wipe(bytes32, uint) external; function give(bytes32, address) external; function shut(bytes32) external; function cups(bytes32) external view returns (address, uint, uint, uint); function gem() external view returns (ERC20Interface); function gov() external view returns (ERC20Interface); function skr() external view returns (ERC20Interface); function sai() external view returns (ERC20Interface); function ink(bytes32) external view returns (uint); function tab(bytes32) external returns (uint); function rap(bytes32) external returns (uint); function per() external view returns (uint); function pep() external view returns (PepInterface); } interface PepInterface { function peek() external returns (bytes32, bool); } interface ERC20Interface { function allowance(address, address) external view returns (uint); function balanceOf(address) external view returns (uint); function approve(address, uint) external; function transfer(address, uint) external returns (bool); function transferFrom(address, address, uint) external returns (bool); function deposit() external payable; function withdraw(uint) external; } interface UniswapExchange { function getEthToTokenOutputPrice(uint256 tokensBought) external view returns (uint256 ethSold); function getTokenToEthOutputPrice(uint256 ethBought) external view returns (uint256 tokensSold); function tokenToTokenSwapOutput( uint256 tokensBought, uint256 maxTokensSold, uint256 maxEthSold, uint256 deadline, address tokenAddr ) external returns (uint256 tokensSold); } interface CTokenInterface { function mint(uint mintAmount) external returns (uint); // For ERC20 function redeem(uint redeemTokens) external returns (uint); function redeemUnderlying(uint redeemAmount) external returns (uint); function exchangeRateCurrent() external returns (uint); function transfer(address, uint) external returns (bool); function transferFrom(address, address, uint) external returns (bool); function balanceOf(address) external view returns (uint); } interface CETHInterface { function mint() external payable; // For ETH function transfer(address, uint) external returns (bool); } interface CDAIInterface { function mint(uint mintAmount) external returns (uint); // For ERC20 function repayBorrowBehalf(address borrower, uint repayAmount) external returns (uint); function borrowBalanceCurrent(address account) external returns (uint); } contract DSMath { function add(uint x, uint y) internal pure returns (uint z) { require((z = x + y) >= x, "math-not-safe"); } function mul(uint x, uint y) internal pure returns (uint z) { require(y == 0 || (z = x * y) / y == x, "math-not-safe"); } uint constant WAD = 10 ** 18; uint constant RAY = 10 ** 27; function rmul(uint x, uint y) internal pure returns (uint z) { z = add(mul(x, y), RAY / 2) / RAY; } function rdiv(uint x, uint y) internal pure returns (uint z) { z = add(mul(x, RAY), y / 2) / y; } function wmul(uint x, uint y) internal pure returns (uint z) { z = add(mul(x, y), WAD / 2) / WAD; } function wdiv(uint x, uint y) internal pure returns (uint z) { z = add(mul(x, WAD), y / 2) / y; } function sub(uint a, uint b) internal pure returns (uint c) { require(b <= a, "SafeMath: subtraction overflow"); c = a - b; } } contract Helper is DSMath { address public ethAddr = 0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE; address public daiAddr = 0x89d24A6b4CcB1B6fAA2625fE562bDD9a23260359; address public registry = 0x498b3BfaBE9F73db90D252bCD4Fa9548Cd0Fd981; address public sai = 0x448a5065aeBB8E423F0896E6c5D525C040f59af3; address public ume = 0x2C4Bd064b998838076fa341A83d007FC2FA50957; // Uniswap Maker Exchange address public ude = 0x09cabEC1eAd1c0Ba254B09efb3EE13841712bE14; // Uniswap DAI Exchange address public cEth = 0x4Ddc2D193948926D02f9B1fE9e1daa0718270ED5; address public cDai = 0xF5DCe57282A584D2746FaF1593d3121Fcac444dC; address public feeOne = 0xd8db02A498E9AFbf4A32BC006DC1940495b4e592; address public feeTwo = 0xa7615CD307F323172331865181DC8b80a2834324; /** * @dev setting allowance to compound for the "user proxy" if required */ function setApproval(address erc20, uint srcAmt, address to) internal { ERC20Interface erc20Contract = ERC20Interface(erc20); uint tokenAllowance = erc20Contract.allowance(address(this), to); if (srcAmt > tokenAllowance) { erc20Contract.approve(to, 2**255); } } function setAllowance(ERC20Interface _token, address _spender) internal { if (_token.allowance(address(this), _spender) != uint(-1)) { _token.approve(_spender, uint(-1)); } } } contract CompoundResolver is Helper { /** * @dev Redeem ETH/ERC20 and mint Compound Tokens * @param tokenAmt Amount of token To Redeem */ function redeemUnderlying(address cErc20, uint tokenAmt) internal { if (tokenAmt > 0) { require(CTokenInterface(cErc20).redeemUnderlying(tokenAmt) == 0, "something went wrong"); } } /** * @dev Deposit ETH/ERC20 and mint Compound Tokens */ function mintCETH(uint ethAmt) internal { if (ethAmt > 0) { CETHInterface cToken = CETHInterface(cEth); cToken.mint.value(ethAmt)(); uint exchangeRate = CTokenInterface(cEth).exchangeRateCurrent(); uint cEthToReturn = wdiv(ethAmt, exchangeRate); cEthToReturn = wmul(cEthToReturn, exchangeRate) <= ethAmt ? cEthToReturn : cEthToReturn - 1; require(cToken.transfer(msg.sender, cEthToReturn), "CETH Transfer failed"); } } /** * @dev Deposit ETH/ERC20 and mint Compound Tokens */ function fetchCETH(uint ethAmt) internal { if (ethAmt > 0) { CTokenInterface cToken = CTokenInterface(cEth); uint exchangeRate = cToken.exchangeRateCurrent(); uint cTokenAmt = wdiv(ethAmt, exchangeRate); cTokenAmt = wmul(cTokenAmt, exchangeRate) <= ethAmt ? cTokenAmt : cTokenAmt - 1; require(ERC20Interface(cEth).transferFrom(msg.sender, address(this), cTokenAmt), "Contract Approved?"); } } /** * @dev If col/debt > user's balance/borrow. Then set max */ function checkCompound(uint ethAmt, uint daiAmt) internal returns (uint ethCol, uint daiDebt) { CTokenInterface cEthContract = CTokenInterface(cEth); uint cEthBal = cEthContract.balanceOf(msg.sender); uint ethExchangeRate = cEthContract.exchangeRateCurrent(); ethCol = wmul(cEthBal, ethExchangeRate); ethCol = wdiv(ethCol, ethExchangeRate) <= cEthBal ? ethCol : ethCol - 1; ethCol = ethCol <= ethAmt ? ethCol : ethAmt; // Set Max if amount is greater than the Col user have daiDebt = CDAIInterface(cDai).borrowBalanceCurrent(msg.sender); daiDebt = daiDebt <= daiAmt ? daiDebt : daiAmt; // Set Max if amount is greater than the Debt user have } } contract MakerResolver is CompoundResolver { event LogOpen(uint cdpNum, address owner); event LogWipe(uint cdpNum, uint daiAmt, uint mkrFee, uint daiFee, address owner); function open() internal returns (uint) { bytes32 cup = TubInterface(sai).open(); emit LogOpen(uint(cup), address(this)); return uint(cup); } /** * @dev transfer CDP ownership */ function give(uint cdpNum, address nextOwner) internal { TubInterface(sai).give(bytes32(cdpNum), nextOwner); } function wipe(uint cdpNum, uint _wad) internal returns (uint daiAmt) { if (_wad > 0) { TubInterface tub = TubInterface(sai); UniswapExchange daiEx = UniswapExchange(ude); UniswapExchange mkrEx = UniswapExchange(ume); ERC20Interface dai = tub.sai(); ERC20Interface mkr = tub.gov(); bytes32 cup = bytes32(cdpNum); (address lad,,,) = tub.cups(cup); require(lad == address(this), "cup-not-owned"); setAllowance(dai, sai); setAllowance(mkr, sai); setAllowance(dai, ude); (bytes32 val, bool ok) = tub.pep().peek(); // MKR required for wipe = Stability fees accrued in Dai / MKRUSD value uint mkrFee = wdiv(rmul(_wad, rdiv(tub.rap(cup), tub.tab(cup))), uint(val)); uint daiFeeAmt = daiEx.getTokenToEthOutputPrice(mkrEx.getEthToTokenOutputPrice(mkrFee)); daiAmt = add(_wad, daiFeeAmt); redeemUnderlying(cDai, daiAmt); if (ok && val != 0) { daiEx.tokenToTokenSwapOutput( mkrFee, daiAmt, uint(999000000000000000000), uint(1899063809), // 6th March 2030 GMT // no logic address(mkr) ); } tub.wipe(cup, _wad); emit LogWipe( cdpNum, daiAmt, mkrFee, daiFeeAmt, address(this) ); } } function free(uint cdpNum, uint jam) internal { if (jam > 0) { bytes32 cup = bytes32(cdpNum); address tubAddr = sai; TubInterface tub = TubInterface(tubAddr); ERC20Interface peth = tub.skr(); ERC20Interface weth = tub.gem(); uint ink = rdiv(jam, tub.per()); ink = rmul(ink, tub.per()) <= jam ? ink : ink - 1; tub.free(cup, ink); setAllowance(peth, tubAddr); tub.exit(ink); uint freeJam = weth.balanceOf(address(this)); // withdraw possible previous stuck WETH as well weth.withdraw(freeJam); } } function lock(uint cdpNum, uint ethAmt) internal { if (ethAmt > 0) { bytes32 cup = bytes32(cdpNum); address tubAddr = sai; TubInterface tub = TubInterface(tubAddr); ERC20Interface weth = tub.gem(); ERC20Interface peth = tub.skr(); (address lad,,,) = tub.cups(cup); require(lad == address(this), "cup-not-owned"); weth.deposit.value(ethAmt)(); uint ink = rdiv(ethAmt, tub.per()); ink = rmul(ink, tub.per()) <= ethAmt ? ink : ink - 1; setAllowance(weth, tubAddr); tub.join(ink); setAllowance(peth, tubAddr); tub.lock(cup, ink); } } function draw(uint cdpNum, uint _wad) internal { bytes32 cup = bytes32(cdpNum); if (_wad > 0) { TubInterface tub = TubInterface(sai); tub.draw(cup, _wad); } } function checkCDP(bytes32 cup, uint ethAmt, uint daiAmt) internal returns (uint ethCol, uint daiDebt) { TubInterface tub = TubInterface(sai); ethCol = rmul(tub.ink(cup), tub.per()); // get ETH col from PETH col daiDebt = tub.tab(cup); daiDebt = daiAmt < daiDebt ? daiAmt : daiDebt; // if DAI amount > max debt. Set max debt ethCol = ethAmt < ethCol ? ethAmt : ethCol; // if ETH amount > max Col. Set max col } function wipeAndFree(uint cdpNum, uint jam, uint _wad) internal returns (uint daiAmt) { daiAmt = wipe(cdpNum, _wad); free(cdpNum, jam); } function lockAndDraw(uint cdpNum, uint jam, uint _wad) internal { lock(cdpNum, jam); draw(cdpNum, _wad); } } contract BridgeResolver is MakerResolver { event LogMakerToCompound(uint cdpNum, uint ethAmt, uint daiAmt, uint fees, address owner); event LogCompoundToMaker(uint cdpNum, uint ethAmt, uint daiAmt, uint fees, address owner); /** * @dev initiated from user wallet to reimburse temporary DAI debt */ function refillFunds(uint daiDebt) external { if (daiDebt > 0) { require(ERC20Interface(daiAddr).transferFrom(msg.sender, address(this), daiDebt), "Contract Approved?"); assert(CDAIInterface(cDai).mint(daiDebt) == 0); } } /** * @dev paying back users debt */ function payUserDebt(uint daiDebt) internal { if (daiDebt > 0) { redeemUnderlying(cDai, daiDebt); require(CDAIInterface(cDai).repayBorrowBehalf(msg.sender, daiDebt) == 0, "Enough DAI?"); } } } contract LiquidityProvider is BridgeResolver { mapping (address => uint) public deposits; // amount of CDAI deposits uint public totalDeposits; /** * @dev Deposit DAI for liquidity */ function depositDAI(uint amt) public { require(ERC20Interface(daiAddr).transferFrom(msg.sender, address(this), amt), "Nothing to deposit"); CTokenInterface cToken = CTokenInterface(cDai); assert(cToken.mint(amt) == 0); uint exchangeRate = cToken.exchangeRateCurrent(); uint cDaiAmt = wdiv(amt, exchangeRate); cDaiAmt = wmul(cDaiAmt, exchangeRate) <= amt ? cDaiAmt : cDaiAmt - 1; deposits[msg.sender] += cDaiAmt; totalDeposits += cDaiAmt; } /** * @dev Withdraw DAI from liquidity */ function withdrawDAI(uint amt) public { require(deposits[msg.sender] != 0, "Nothing to Withdraw"); CTokenInterface cToken = CTokenInterface(cDai); uint exchangeRate = cToken.exchangeRateCurrent(); uint withdrawAmt = wdiv(amt, exchangeRate); uint daiAmt = amt; if (withdrawAmt > deposits[msg.sender]) { withdrawAmt = deposits[msg.sender]; daiAmt = wmul(withdrawAmt, exchangeRate); } require(cToken.redeem(withdrawAmt) == 0, "something went wrong"); require(ERC20Interface(daiAddr).transfer(msg.sender, daiAmt), "Dai Transfer failed"); deposits[msg.sender] -= withdrawAmt; totalDeposits -= withdrawAmt; } /** * @dev Deposit CDAI for liquidity */ function depositCDAI(uint amt) public { CTokenInterface cToken = CTokenInterface(cDai); require(cToken.transferFrom(msg.sender, address(this), amt) == true, "Nothing to deposit"); deposits[msg.sender] += amt; totalDeposits += amt; } /** * @dev Withdraw CDAI from liquidity */ function withdrawCDAI(uint amt) public { require(deposits[msg.sender] != 0, "Nothing to Withdraw"); uint withdrawAmt = amt; if (withdrawAmt > deposits[msg.sender]) { withdrawAmt = deposits[msg.sender]; } require(CTokenInterface(cDai).transfer(msg.sender, withdrawAmt), "Dai Transfer failed"); deposits[msg.sender] -= withdrawAmt; totalDeposits -= withdrawAmt; } /** * collecting unmapped CDAI */ function collectCDAI(uint num) public { CTokenInterface cToken = CTokenInterface(cDai); uint cDaiBal = cToken.balanceOf(address(this)); uint withdrawAmt = sub(cDaiBal, totalDeposits); if (num == 0) { require(cToken.transfer(feeOne, withdrawAmt), "CDai Transfer failed"); } else { require(cToken.transfer(feeTwo, withdrawAmt), "CDai Transfer failed"); } } /** * (HIGHLY UNLIKELY TO HAPPEN) * collecting Tokens/ETH other than CDAI */ function collectTokens(uint num, address token) public { require(token != cDai, "Token address == CDAI address"); if (token == ethAddr) { if (num == 0) { msg.sender.transfer(address(this).balance); } else { msg.sender.transfer(address(this).balance); } } else { ERC20Interface tokenContract = ERC20Interface(token); uint tokenBal = tokenContract.balanceOf(address(this)); uint withdrawAmt = sub(tokenBal, totalDeposits); if (num == 0) { require(tokenContract.transfer(feeOne, withdrawAmt), "Transfer failed"); } else { require(tokenContract.transfer(feeTwo, withdrawAmt), "Transfer failed"); } } } /** * (HIGHLY UNLIKELY TO HAPPEN) * Transfer CDP ownership (Just in case this contract has ownership of any CDP) */ function transferUnmappedCDP(uint cdpNum, uint num) public { if (num == 0) { give(cdpNum, feeOne); } else { give(cdpNum, feeTwo); } } } contract Bridge is LiquidityProvider { /** * FOR SECURITY PURPOSE * checks if only InstaDApp contract wallets can access the bridge */ modifier isUserWallet { address userAdd = UserWalletInterface(msg.sender).owner(); address walletAdd = RegistryInterface(registry).proxies(userAdd); require(walletAdd != address(0), "not-user-wallet"); require(walletAdd == msg.sender, "not-wallet-owner"); _; } /** * @dev MakerDAO to Compound */ function makerToCompound(uint cdpId, uint ethCol, uint daiDebt) public payable isUserWallet returns (uint daiAmt) { uint ethAmt; (ethAmt, daiAmt) = checkCDP(bytes32(cdpId), ethCol, daiDebt); daiAmt = wipeAndFree(cdpId, ethAmt, daiAmt); uint fees = wmul(daiAmt, 2000000000000000); // 0.2% fees daiAmt = wmul(daiAmt, 1002000000000000000); mintCETH(ethAmt); give(cdpId, msg.sender); emit LogMakerToCompound( cdpId, ethAmt, daiAmt, fees, msg.sender ); } /** * @dev Compound to MakerDAO */ function compoundToMaker(uint cdpId, uint ethCol, uint daiDebt) public payable isUserWallet { (uint ethAmt, uint daiAmt) = checkCompound(ethCol, daiDebt); payUserDebt(daiAmt); fetchCETH(ethAmt); redeemUnderlying(cEth, ethAmt); uint cdpNum = cdpId > 0 ? cdpId : open(); uint fees = wmul(daiAmt, 2000000000000000); // 0.2% fees daiAmt = wmul(daiAmt, 1002000000000000000); lockAndDraw(cdpNum, ethAmt, daiAmt); if (daiAmt > 0) { assert(CDAIInterface(cDai).mint(daiAmt) == 0); } give(cdpNum, msg.sender); emit LogCompoundToMaker( cdpNum, ethAmt, daiAmt, fees, msg.sender ); } } contract MakerCompoundBridge is Bridge { /** * @dev setting up all required token approvals */ constructor() public { setApproval(daiAddr, 10**30, cDai); setApproval(cDai, 10**30, cDai); setApproval(cEth, 10**30, cEth); } function() external payable {} }