// This contract is part of Zellic’s smart contract dataset, which is a collection of publicly available contract code gathered as of March 2023. // File: contracts\farming\FarmData.sol //SPDX-License-Identifier: MIT pragma solidity >=0.7.0; struct FarmingPositionRequest { uint256 setupIndex; // index of the chosen setup. uint256 amount0; // amount of main token or liquidity pool token. uint256 amount1; // amount of other token or liquidity pool token. Needed for gen2 address positionOwner; // position extension or address(0) [msg.sender]. uint256 amount0Min; uint256 amount1Min; } struct FarmingSetupConfiguration { bool add; // true if we're adding a new setup, false we're updating it. bool disable; uint256 index; // index of the setup we're updating. FarmingSetupInfo info; // data of the new or updated setup } struct FarmingSetupInfo { uint256 blockDuration; // duration of setup uint256 startBlock; // optional start block used for the delayed activation of the first setup uint256 originalRewardPerBlock; uint256 minStakeable; // minimum amount of staking tokens. uint256 renewTimes; // if the setup is renewable or if it's one time. address liquidityPoolTokenAddress; // address of the liquidity pool token address mainTokenAddress; // eg. buidl address. bool involvingETH; // if the setup involves ETH or not. uint256 setupsCount; // number of setups created by this info. uint256 lastSetupIndex; // index of last setup; int24 tickLower; // Gen2 Only - tickLower of the UniswapV3 pool int24 tickUpper; // Gen 2 Only - tickUpper of the UniswapV3 pool } struct FarmingSetup { uint256 infoIndex; // setup info bool active; // if the setup is active or not. uint256 startBlock; // farming setup start block. uint256 endBlock; // farming setup end block. uint256 lastUpdateBlock; // number of the block where an update was triggered. uint256 objectId; // need for gen2. uniswapV3 NFT position Id uint256 rewardPerBlock; // farming setup reward per single block. uint128 totalSupply; // Total LP token liquidity of all the positions of this setup } struct FarmingPosition { address uniqueOwner; // address representing the owner of the position. uint256 setupIndex; // the setup index related to this position. uint256 creationBlock; // block when this position was created. uint128 liquidityPoolTokenAmount; // amount of liquidity pool token in the position. uint256 reward; // position reward. } // File: contracts\farming\IFarmExtension.sol //SPDX_License_Identifier: MIT pragma solidity >=0.7.0; pragma abicoder v2; interface IFarmExtension { function init(bool byMint, address host, address treasury) external; function setHost(address host) external; function setTreasury(address treasury) external; function data() external view returns(address farmMainContract, bool byMint, address host, address treasury, address rewardTokenAddress); function transferTo(uint256 amount) external; function backToYou(uint256 amount) external payable; function setFarmingSetups(FarmingSetupConfiguration[] memory farmingSetups) external; } // File: contracts\farming\IFarmMain.sol //SPDX_License_Identifier: MIT pragma solidity >=0.7.0; //pragma abicoder v2; interface IFarmMain { function ONE_HUNDRED() external view returns(uint256); function _rewardTokenAddress() external view returns(address); function position(uint256 positionId) external view returns (FarmingPosition memory); function setups() external view returns (FarmingSetup[] memory); function setup(uint256 setupIndex) external view returns (FarmingSetup memory, FarmingSetupInfo memory); function setFarmingSetups(FarmingSetupConfiguration[] memory farmingSetups) external; function openPosition(FarmingPositionRequest calldata request) external payable returns(uint256 positionId); function addLiquidity(uint256 positionId, FarmingPositionRequest calldata request) external payable; } // File: contracts\farming\util\IERC20.sol // SPDX_License_Identifier: MIT pragma solidity >=0.7.0; interface IERC20 { function totalSupply() external view returns (uint256); function balanceOf(address account) external view returns (uint256); function transfer(address recipient, uint256 amount) external returns (bool); function allowance(address owner, address spender) external view returns (uint256); function approve(address spender, uint256 amount) external returns (bool); function safeApprove(address spender, uint256 amount) external; function transferFrom(address sender, address recipient, uint256 amount) external returns (bool); function decimals() external view returns (uint8); } // File: contracts\farming\util\IERC20Mintable.sol // SPDX_License_Identifier: MIT pragma solidity >=0.7.0; interface IERC20Mintable { function mint(address wallet, uint256 amount) external returns (bool); function burn(address wallet, uint256 amount) external returns (bool); } // File: contracts\farming\FarmExtension.sol //SPDX_License_Identifier: MIT pragma solidity >=0.7.0; //pragma abicoder v2; contract FarmExtension is IFarmExtension { // wallet who has control on the extension and treasury address internal _host; address internal _treasury; // address of the farm main contract linked to this extension address internal _farmMainContract; // the reward token address linked to this extension address internal _rewardTokenAddress; // whether the token is by mint or by reserve bool internal _byMint; /** MODIFIERS */ /** @dev farmMainOnly modifier used to check for unauthorized transfers. */ modifier farmMainOnly() { require(msg.sender == _farmMainContract, "Unauthorized"); _; } /** @dev hostOnly modifier used to check for unauthorized edits. */ modifier hostOnly() { require(msg.sender == _host, "Unauthorized"); _; } /** PUBLIC METHODS */ receive() external payable { require(_farmMainContract != address(0) && _rewardTokenAddress == address(0), "ETH not allowed"); } function init(bool byMint, address host, address treasury) public virtual override { require(_farmMainContract == address(0), "Already init"); require((_host = host) != address(0), "blank host"); _rewardTokenAddress = IFarmMain(_farmMainContract = msg.sender)._rewardTokenAddress(); _byMint = byMint; _treasury = treasury != address(0) ? treasury : host; } function data() view public virtual override returns(address farmMainContract, bool byMint, address host, address treasury, address rewardTokenAddress) { return (_farmMainContract, _byMint, _host, _treasury, _rewardTokenAddress); } /** @dev method used to update the extension host. * @param host new host address. */ function setHost(address host) public virtual override hostOnly { _host = host; } /** @dev method used to update the extension treasury. * @param treasury new treasury address. */ function setTreasury(address treasury) public virtual override hostOnly { _treasury = treasury; } /** @dev this function calls the farm main contract with the given address and sets the given farming setups. * @param farmingSetups array containing all the farming setups. */ function setFarmingSetups(FarmingSetupConfiguration[] memory farmingSetups) public virtual override hostOnly { IFarmMain(_farmMainContract).setFarmingSetups(farmingSetups); } /** @dev transfers the input amount to the caller farming contract. * @param amount amount of erc20 to transfer or mint. */ function transferTo(uint256 amount) public virtual override farmMainOnly { if(_rewardTokenAddress != address(0)) { return _byMint ? _mintAndTransfer(_rewardTokenAddress, _farmMainContract, amount) : _safeTransfer(_rewardTokenAddress, _farmMainContract, amount); } (bool result, ) = _farmMainContract.call{value:amount}(""); require(result, "ETH transfer failed."); } /** @dev transfers the input amount from the caller farming contract to the extension. * @param amount amount of erc20 to transfer back or burn. */ function backToYou(uint256 amount) payable public virtual override farmMainOnly { if(_rewardTokenAddress != address(0)) { _safeTransferFrom(_rewardTokenAddress, msg.sender, _byMint ? address(this) : _treasury, amount); if(_byMint) { _burn(_rewardTokenAddress, amount); } } else { require(msg.value == amount, "invalid sent amount"); if(_treasury != address(this)) { (bool result, ) = _treasury.call{value:amount}(""); require(result, "ETH transfer failed."); } } } /** INTERNAL METHODS */ function _mintAndTransfer(address erc20TokenAddress, address recipient, uint256 value) internal virtual { IERC20Mintable(erc20TokenAddress).mint(recipient, value); } function _burn(address erc20TokenAddress, uint256 value) internal virtual { IERC20Mintable(erc20TokenAddress).burn(msg.sender, value); } /** @dev function used to safely approve ERC20 transfers. * @param erc20TokenAddress address of the token to approve. * @param to receiver of the approval. * @param value amount to approve for. */ function _safeApprove(address erc20TokenAddress, address to, uint256 value) internal virtual { bytes memory returnData = _call(erc20TokenAddress, abi.encodeWithSelector(IERC20(erc20TokenAddress).approve.selector, to, value)); require(returnData.length == 0 || abi.decode(returnData, (bool)), 'APPROVE_FAILED'); } /** @dev function used to safe transfer ERC20 tokens. * @param erc20TokenAddress address of the token to transfer. * @param to receiver of the tokens. * @param value amount of tokens to transfer. */ function _safeTransfer(address erc20TokenAddress, address to, uint256 value) internal virtual { bytes memory returnData = _call(erc20TokenAddress, abi.encodeWithSelector(IERC20(erc20TokenAddress).transfer.selector, to, value)); require(returnData.length == 0 || abi.decode(returnData, (bool)), 'TRANSFER_FAILED'); } /** @dev this function safely transfers the given ERC20 value from an address to another. * @param erc20TokenAddress erc20 token address. * @param from address from. * @param to address to. * @param value amount to transfer. */ function _safeTransferFrom(address erc20TokenAddress, address from, address to, uint256 value) internal virtual { bytes memory returnData = _call(erc20TokenAddress, abi.encodeWithSelector(IERC20(erc20TokenAddress).transferFrom.selector, from, to, value)); require(returnData.length == 0 || abi.decode(returnData, (bool)), 'TRANSFERFROM_FAILED'); } /** @dev calls the contract at the given location using the given payload and returns the returnData. * @param location location to call. * @param payload call payload. * @return returnData call return data. */ function _call(address location, bytes memory payload) private returns(bytes memory returnData) { assembly { let result := call(gas(), location, 0, add(payload, 0x20), mload(payload), 0, 0) let size := returndatasize() returnData := mload(0x40) mstore(returnData, size) let returnDataPayloadStart := add(returnData, 0x20) returndatacopy(returnDataPayloadStart, 0, size) mstore(0x40, add(returnDataPayloadStart, size)) switch result case 0 {revert(returnDataPayloadStart, size)} } } }