pragma solidity >=0.5.0 <0.7.0; import "./base/ModuleManager.sol"; import "./base/OwnerManager.sol"; import "./base/FallbackManager.sol"; import "./common/MasterCopy.sol"; import "./common/SignatureDecoder.sol"; import "./common/SecuredTokenTransfer.sol"; import "./interfaces/ISignatureValidator.sol"; import "./external/SafeMath.sol"; /// @title Gnosis Safe - A multisignature wallet with support for confirmations using signed messages based on ERC191. /// @author Stefan George - /// @author Richard Meissner - /// @author Ricardo Guilherme Schmidt - (Status Research & Development GmbH) - Gas Token Payment contract GnosisSafe is MasterCopy, ModuleManager, OwnerManager, SignatureDecoder, SecuredTokenTransfer, ISignatureValidatorConstants, FallbackManager { using SafeMath for uint256; string public constant NAME = "Gnosis Safe"; string public constant VERSION = "1.1.1"; //keccak256( // "EIP712Domain(address verifyingContract)" //); bytes32 private constant DOMAIN_SEPARATOR_TYPEHASH = 0x035aff83d86937d35b32e04f0ddc6ff469290eef2f1b692d8a815c89404d4749; //keccak256( // "SafeTx(address to,uint256 value,bytes data,uint8 operation,uint256 safeTxGas,uint256 baseGas,uint256 gasPrice,address gasToken,address refundReceiver,uint256 nonce)" //); bytes32 private constant SAFE_TX_TYPEHASH = 0xbb8310d486368db6bd6f849402fdd73ad53d316b5a4b2644ad6efe0f941286d8; //keccak256( // "SafeMessage(bytes message)" //); bytes32 private constant SAFE_MSG_TYPEHASH = 0x60b3cbf8b4a223d68d641b3b6ddf9a298e7f33710cf3d3a9d1146b5a6150fbca; event ApproveHash( bytes32 indexed approvedHash, address indexed owner ); event SignMsg( bytes32 indexed msgHash ); event ExecutionFailure( bytes32 txHash, uint256 payment ); event ExecutionSuccess( bytes32 txHash, uint256 payment ); uint256 public nonce; bytes32 public domainSeparator; // Mapping to keep track of all message hashes that have been approve by ALL REQUIRED owners mapping(bytes32 => uint256) public signedMessages; // Mapping to keep track of all hashes (message or transaction) that have been approve by ANY owners mapping(address => mapping(bytes32 => uint256)) public approvedHashes; // This constructor ensures that this contract can only be used as a master copy for Proxy contracts constructor() public { // By setting the threshold it is not possible to call setup anymore, // so we create a Safe with 0 owners and threshold 1. // This is an unusable Safe, perfect for the mastercopy threshold = 1; } /// @dev Setup function sets initial storage of contract. /// @param _owners List of Safe owners. /// @param _threshold Number of required confirmations for a Safe transaction. /// @param to Contract address for optional delegate call. /// @param data Data payload for optional delegate call. /// @param fallbackHandler Handler for fallback calls to this contract /// @param paymentToken Token that should be used for the payment (0 is ETH) /// @param payment Value that should be paid /// @param paymentReceiver Adddress that should receive the payment (or 0 if tx.origin) function setup( address[] calldata _owners, uint256 _threshold, address to, bytes calldata data, address fallbackHandler, address paymentToken, uint256 payment, address payable paymentReceiver ) external { require(domainSeparator == 0, "Domain Separator already set!"); domainSeparator = keccak256(abi.encode(DOMAIN_SEPARATOR_TYPEHASH, this)); setupOwners(_owners, _threshold); if (fallbackHandler != address(0)) internalSetFallbackHandler(fallbackHandler); // As setupOwners can only be called if the contract has not been initialized we don't need a check for setupModules setupModules(to, data); if (payment > 0) { // To avoid running into issues with EIP-170 we reuse the handlePayment function (to avoid adjusting code of that has been verified we do not adjust the method itself) // baseGas = 0, gasPrice = 1 and gas = payment => amount = (payment + 0) * 1 = payment handlePayment(payment, 0, 1, paymentToken, paymentReceiver); } } /// @dev Allows to execute a Safe transaction confirmed by required number of owners and then pays the account that submitted the transaction. /// Note: The fees are always transfered, even if the user transaction fails. /// @param to Destination address of Safe transaction. /// @param value Ether value of Safe transaction. /// @param data Data payload of Safe transaction. /// @param operation Operation type of Safe transaction. /// @param safeTxGas Gas that should be used for the Safe transaction. /// @param baseGas Gas costs for that are indipendent of the transaction execution(e.g. base transaction fee, signature check, payment of the refund) /// @param gasPrice Gas price that should be used for the payment calculation. /// @param gasToken Token address (or 0 if ETH) that is used for the payment. /// @param refundReceiver Address of receiver of gas payment (or 0 if tx.origin). /// @param signatures Packed signature data ({bytes32 r}{bytes32 s}{uint8 v}) function execTransaction( address to, uint256 value, bytes calldata data, Enum.Operation operation, uint256 safeTxGas, uint256 baseGas, uint256 gasPrice, address gasToken, address payable refundReceiver, bytes calldata signatures ) external returns (bool success) { bytes32 txHash; // Use scope here to limit variable lifetime and prevent `stack too deep` errors { bytes memory txHashData = encodeTransactionData( to, value, data, operation, // Transaction info safeTxGas, baseGas, gasPrice, gasToken, refundReceiver, // Payment info nonce ); // Increase nonce and execute transaction. nonce++; txHash = keccak256(txHashData); checkSignatures(txHash, txHashData, signatures, true); } require(gasleft() >= safeTxGas, "Not enough gas to execute safe transaction"); // Use scope here to limit variable lifetime and prevent `stack too deep` errors { uint256 gasUsed = gasleft(); // If no safeTxGas has been set and the gasPrice is 0 we assume that all available gas can be used success = execute(to, value, data, operation, safeTxGas == 0 && gasPrice == 0 ? gasleft() : safeTxGas); gasUsed = gasUsed.sub(gasleft()); // We transfer the calculated tx costs to the tx.origin to avoid sending it to intermediate contracts that have made calls uint256 payment = 0; if (gasPrice > 0) { payment = handlePayment(gasUsed, baseGas, gasPrice, gasToken, refundReceiver); } if (success) emit ExecutionSuccess(txHash, payment); else emit ExecutionFailure(txHash, payment); } } function handlePayment( uint256 gasUsed, uint256 baseGas, uint256 gasPrice, address gasToken, address payable refundReceiver ) private returns (uint256 payment) { // solium-disable-next-line security/no-tx-origin address payable receiver = refundReceiver == address(0) ? tx.origin : refundReceiver; if (gasToken == address(0)) { // For ETH we will only adjust the gas price to not be higher than the actual used gas price payment = gasUsed.add(baseGas).mul(gasPrice < tx.gasprice ? gasPrice : tx.gasprice); // solium-disable-next-line security/no-send require(receiver.send(payment), "Could not pay gas costs with ether"); } else { payment = gasUsed.add(baseGas).mul(gasPrice); require(transferToken(gasToken, receiver, payment), "Could not pay gas costs with token"); } } /** * @dev Checks whether the signature provided is valid for the provided data, hash. Will revert otherwise. * @param dataHash Hash of the data (could be either a message hash or transaction hash) * @param data That should be signed (this is passed to an external validator contract) * @param signatures Signature data that should be verified. Can be ECDSA signature, contract signature (EIP-1271) or approved hash. * @param consumeHash Indicates that in case of an approved hash the storage can be freed to save gas */ function checkSignatures(bytes32 dataHash, bytes memory data, bytes memory signatures, bool consumeHash) internal { // Load threshold to avoid multiple storage loads uint256 _threshold = threshold; // Check that a threshold is set require(_threshold > 0, "Threshold needs to be defined!"); // Check that the provided signature data is not too short require(signatures.length >= _threshold.mul(65), "Signatures data too short"); // There cannot be an owner with address 0. address lastOwner = address(0); address currentOwner; uint8 v; bytes32 r; bytes32 s; uint256 i; for (i = 0; i < _threshold; i++) { (v, r, s) = signatureSplit(signatures, i); // If v is 0 then it is a contract signature if (v == 0) { // When handling contract signatures the address of the contract is encoded into r currentOwner = address(uint256(r)); // Check that signature data pointer (s) is not pointing inside the static part of the signatures bytes // This check is not completely accurate, since it is possible that more signatures than the threshold are send. // Here we only check that the pointer is not pointing inside the part that is being processed require(uint256(s) >= _threshold.mul(65), "Invalid contract signature location: inside static part"); // Check that signature data pointer (s) is in bounds (points to the length of data -> 32 bytes) require(uint256(s).add(32) <= signatures.length, "Invalid contract signature location: length not present"); // Check if the contract signature is in bounds: start of data is s + 32 and end is start + signature length uint256 contractSignatureLen; // solium-disable-next-line security/no-inline-assembly assembly { contractSignatureLen := mload(add(add(signatures, s), 0x20)) } require(uint256(s).add(32).add(contractSignatureLen) <= signatures.length, "Invalid contract signature location: data not complete"); // Check signature bytes memory contractSignature; // solium-disable-next-line security/no-inline-assembly assembly { // The signature data for contract signatures is appended to the concatenated signatures and the offset is stored in s contractSignature := add(add(signatures, s), 0x20) } require(ISignatureValidator(currentOwner).isValidSignature(data, contractSignature) == EIP1271_MAGIC_VALUE, "Invalid contract signature provided"); // If v is 1 then it is an approved hash } else if (v == 1) { // When handling approved hashes the address of the approver is encoded into r currentOwner = address(uint256(r)); // Hashes are automatically approved by the sender of the message or when they have been pre-approved via a separate transaction require(msg.sender == currentOwner || approvedHashes[currentOwner][dataHash] != 0, "Hash has not been approved"); // Hash has been marked for consumption. If this hash was pre-approved free storage if (consumeHash && msg.sender != currentOwner) { approvedHashes[currentOwner][dataHash] = 0; } } else if (v > 30) { // To support eth_sign and similar we adjust v and hash the messageHash with the Ethereum message prefix before applying ecrecover currentOwner = ecrecover(keccak256(abi.encodePacked("\x19Ethereum Signed Message:\n32", dataHash)), v - 4, r, s); } else { // Use ecrecover with the messageHash for EOA signatures currentOwner = ecrecover(dataHash, v, r, s); } require ( currentOwner > lastOwner && owners[currentOwner] != address(0) && currentOwner != SENTINEL_OWNERS, "Invalid owner provided" ); lastOwner = currentOwner; } } /// @dev Allows to estimate a Safe transaction. /// This method is only meant for estimation purpose, therefore two different protection mechanism against execution in a transaction have been made: /// 1.) The method can only be called from the safe itself /// 2.) The response is returned with a revert /// When estimating set `from` to the address of the safe. /// Since the `estimateGas` function includes refunds, call this method to get an estimated of the costs that are deducted from the safe with `execTransaction` /// @param to Destination address of Safe transaction. /// @param value Ether value of Safe transaction. /// @param data Data payload of Safe transaction. /// @param operation Operation type of Safe transaction. /// @return Estimate without refunds and overhead fees (base transaction and payload data gas costs). function requiredTxGas(address to, uint256 value, bytes calldata data, Enum.Operation operation) external authorized returns (uint256) { uint256 startGas = gasleft(); // We don't provide an error message here, as we use it to return the estimate // solium-disable-next-line error-reason require(execute(to, value, data, operation, gasleft())); uint256 requiredGas = startGas - gasleft(); // Convert response to string and return via error message revert(string(abi.encodePacked(requiredGas))); } /** * @dev Marks a hash as approved. This can be used to validate a hash that is used by a signature. * @param hashToApprove The hash that should be marked as approved for signatures that are verified by this contract. */ function approveHash(bytes32 hashToApprove) external { require(owners[msg.sender] != address(0), "Only owners can approve a hash"); approvedHashes[msg.sender][hashToApprove] = 1; emit ApproveHash(hashToApprove, msg.sender); } /** * @dev Marks a message as signed * @param _data Arbitrary length data that should be marked as signed on the behalf of address(this) */ function signMessage(bytes calldata _data) external authorized { bytes32 msgHash = getMessageHash(_data); signedMessages[msgHash] = 1; emit SignMsg(msgHash); } /** * Implementation of ISignatureValidator (see `interfaces/ISignatureValidator.sol`) * @dev Should return whether the signature provided is valid for the provided data. * The save does not implement the interface since `checkSignatures` is not a view method. * The method will not perform any state changes (see parameters of `checkSignatures`) * @param _data Arbitrary length data signed on the behalf of address(this) * @param _signature Signature byte array associated with _data * @return a bool upon valid or invalid signature with corresponding _data */ function isValidSignature(bytes calldata _data, bytes calldata _signature) external returns (bytes4) { bytes32 messageHash = getMessageHash(_data); if (_signature.length == 0) { require(signedMessages[messageHash] != 0, "Hash not approved"); } else { // consumeHash needs to be false, as the state should not be changed checkSignatures(messageHash, _data, _signature, false); } return EIP1271_MAGIC_VALUE; } /// @dev Returns hash of a message that can be signed by owners. /// @param message Message that should be hashed /// @return Message hash. function getMessageHash( bytes memory message ) public view returns (bytes32) { bytes32 safeMessageHash = keccak256( abi.encode(SAFE_MSG_TYPEHASH, keccak256(message)) ); return keccak256( abi.encodePacked(byte(0x19), byte(0x01), domainSeparator, safeMessageHash) ); } /// @dev Returns the bytes that are hashed to be signed by owners. /// @param to Destination address. /// @param value Ether value. /// @param data Data payload. /// @param operation Operation type. /// @param safeTxGas Fas that should be used for the safe transaction. /// @param baseGas Gas costs for data used to trigger the safe transaction. /// @param gasPrice Maximum gas price that should be used for this transaction. /// @param gasToken Token address (or 0 if ETH) that is used for the payment. /// @param refundReceiver Address of receiver of gas payment (or 0 if tx.origin). /// @param _nonce Transaction nonce. /// @return Transaction hash bytes. function encodeTransactionData( address to, uint256 value, bytes memory data, Enum.Operation operation, uint256 safeTxGas, uint256 baseGas, uint256 gasPrice, address gasToken, address refundReceiver, uint256 _nonce ) public view returns (bytes memory) { bytes32 safeTxHash = keccak256( abi.encode(SAFE_TX_TYPEHASH, to, value, keccak256(data), operation, safeTxGas, baseGas, gasPrice, gasToken, refundReceiver, _nonce) ); return abi.encodePacked(byte(0x19), byte(0x01), domainSeparator, safeTxHash); } /// @dev Returns hash to be signed by owners. /// @param to Destination address. /// @param value Ether value. /// @param data Data payload. /// @param operation Operation type. /// @param safeTxGas Fas that should be used for the safe transaction. /// @param baseGas Gas costs for data used to trigger the safe transaction. /// @param gasPrice Maximum gas price that should be used for this transaction. /// @param gasToken Token address (or 0 if ETH) that is used for the payment. /// @param refundReceiver Address of receiver of gas payment (or 0 if tx.origin). /// @param _nonce Transaction nonce. /// @return Transaction hash. function getTransactionHash( address to, uint256 value, bytes memory data, Enum.Operation operation, uint256 safeTxGas, uint256 baseGas, uint256 gasPrice, address gasToken, address refundReceiver, uint256 _nonce ) public view returns (bytes32) { return keccak256(encodeTransactionData(to, value, data, operation, safeTxGas, baseGas, gasPrice, gasToken, refundReceiver, _nonce)); } }