import { addHexPrefix } from 'ethereumjs-util'; import abi from 'human-standard-token-abi'; import { GAS_LIMITS, MIN_GAS_LIMIT_HEX } from '../../../shared/constants/gas'; import { calcTokenAmount } from '../../../shared/lib/transactions-controller-utils'; import { CHAIN_ID_TO_GAS_LIMIT_BUFFER_MAP } from '../../../shared/constants/network'; import { ASSET_TYPES, TRANSACTION_ENVELOPE_TYPES, } from '../../../shared/constants/transaction'; import { readAddressAsContract } from '../../../shared/modules/contract-utils'; import { conversionUtil, multiplyCurrencies, } from '../../../shared/modules/conversion.utils'; import { ETH, GWEI } from '../../helpers/constants/common'; import { addGasBuffer, generateERC20TransferData, generateERC721TransferData, getAssetTransferData, } from '../../pages/send/send.utils'; import { getGasPriceInHexWei } from '../../selectors'; import { estimateGas } from '../../store/actions'; export async function estimateGasLimitForSend({ selectedAddress, value, gasPrice, sendToken, to, data, isNonStandardEthChain, chainId, gasLimit, ...options }) { let isSimpleSendOnNonStandardNetwork = false; // blockGasLimit may be a falsy, but defined, value when we receive it from // state, so we use logical or to fall back to MIN_GAS_LIMIT_HEX. Some // network implementations check the gas parameter supplied to // eth_estimateGas for validity. For this reason, we set token sends // blockGasLimit default to a higher number. Note that the current gasLimit // on a BLOCK is 15,000,000 and will be 30,000,000 on mainnet after London. // Meanwhile, MIN_GAS_LIMIT_HEX is 0x5208. let blockGasLimit = MIN_GAS_LIMIT_HEX; if (options.blockGasLimit) { blockGasLimit = options.blockGasLimit; } else if (sendToken) { blockGasLimit = GAS_LIMITS.BASE_TOKEN_ESTIMATE; } // The parameters below will be sent to our background process to estimate // how much gas will be used for a transaction. That background process is // located in tx-gas-utils.js in the transaction controller folder. const paramsForGasEstimate = { from: selectedAddress, value, gasPrice }; if (sendToken) { if (!to) { // If no to address is provided, we cannot generate the token transfer // hexData. hexData in a transaction largely dictates how much gas will // be consumed by a transaction. We must use our best guess, which is // represented in the gas shared constants. return GAS_LIMITS.BASE_TOKEN_ESTIMATE; } paramsForGasEstimate.value = '0x0'; // We have to generate the erc20/erc721 contract call to transfer tokens in // order to get a proper estimate for gasLimit. paramsForGasEstimate.data = getAssetTransferData({ sendToken, fromAddress: selectedAddress, toAddress: to, amount: value, }); paramsForGasEstimate.to = sendToken.address; } else { if (!data) { // eth.getCode will return the compiled smart contract code at the // address. If this returns 0x, 0x0 or a nullish value then the address // is an externally owned account (NOT a contract account). For these // types of transactions the gasLimit will always be 21,000 or 0x5208 const { isContractAddress } = to ? await readAddressAsContract(global.eth, to) : {}; if (!isContractAddress && !isNonStandardEthChain) { return GAS_LIMITS.SIMPLE; } else if (!isContractAddress && isNonStandardEthChain) { isSimpleSendOnNonStandardNetwork = true; } } paramsForGasEstimate.data = data; if (to) { paramsForGasEstimate.to = to; } if (!value || value === '0') { // TODO: Figure out what's going on here. According to eth_estimateGas // docs this value can be zero, or undefined, yet we are setting it to a // value here when the value is undefined or zero. For more context: // https://github.com/MetaMask/metamask-extension/pull/6195 paramsForGasEstimate.value = '0xff'; } } if (!isSimpleSendOnNonStandardNetwork) { // If we do not yet have a gasLimit, we must call into our background // process to get an estimate for gasLimit based on known parameters. paramsForGasEstimate.gas = addHexPrefix( multiplyCurrencies(blockGasLimit, 0.95, { multiplicandBase: 16, multiplierBase: 10, roundDown: '0', toNumericBase: 'hex', }), ); } // The buffer multipler reduces transaction failures by ensuring that the // estimated gas is always sufficient. Without the multiplier, estimates // for contract interactions can become inaccurate over time. This is because // gas estimation is non-deterministic. The gas required for the exact same // transaction call can change based on state of a contract or changes in the // contracts environment (blockchain data or contracts it interacts with). // Applying the 1.5 buffer has proven to be a useful guard against this non- // deterministic behaviour. // // Gas estimation of simple sends should, however, be deterministic. As such // no buffer is needed in those cases. let bufferMultiplier = 1.5; if (isSimpleSendOnNonStandardNetwork) { bufferMultiplier = 1; } else if (CHAIN_ID_TO_GAS_LIMIT_BUFFER_MAP[chainId]) { bufferMultiplier = CHAIN_ID_TO_GAS_LIMIT_BUFFER_MAP[chainId]; } try { // Call into the background process that will simulate transaction // execution on the node and return an estimate of gasLimit const estimatedGasLimit = await estimateGas(paramsForGasEstimate); const estimateWithBuffer = addGasBuffer( estimatedGasLimit, blockGasLimit, bufferMultiplier, ); return addHexPrefix(estimateWithBuffer); } catch (error) { const simulationFailed = error.message.includes('Transaction execution error.') || error.message.includes( 'gas required exceeds allowance or always failing transaction', ) || (CHAIN_ID_TO_GAS_LIMIT_BUFFER_MAP[chainId] && error.message.includes('gas required exceeds allowance')); if (simulationFailed) { const estimateWithBuffer = addGasBuffer( paramsForGasEstimate?.gas ?? gasLimit, blockGasLimit, bufferMultiplier, ); return addHexPrefix(estimateWithBuffer); } throw error; } } /** * Generates a txParams from the send slice. * * @param {import('.').SendState} sendState - the state of the send slice * @returns {import( * '../../../shared/constants/transaction' * ).TxParams} A txParams object that can be used to create a transaction or * update an existing transaction. */ export function generateTransactionParams(sendState) { const draftTransaction = sendState.draftTransactions[sendState.currentTransactionUUID]; const txParams = { // If the fromAccount has been specified we use that, if not we use the // selected account. from: draftTransaction.fromAccount?.address || sendState.selectedAccount.address, // gasLimit always needs to be set regardless of the asset being sent // or the type of transaction. gas: draftTransaction.gas.gasLimit, }; switch (draftTransaction.asset.type) { case ASSET_TYPES.TOKEN: // When sending a token the to address is the contract address of // the token being sent. The value is set to '0x0' and the data // is generated from the recipient address, token being sent and // amount. txParams.to = draftTransaction.asset.details.address; txParams.value = '0x0'; txParams.data = generateERC20TransferData({ toAddress: draftTransaction.recipient.address, amount: draftTransaction.amount.value, sendToken: draftTransaction.asset.details, }); break; case ASSET_TYPES.COLLECTIBLE: // When sending a token the to address is the contract address of // the token being sent. The value is set to '0x0' and the data // is generated from the recipient address, token being sent and // amount. txParams.to = draftTransaction.asset.details.address; txParams.value = '0x0'; txParams.data = generateERC721TransferData({ toAddress: draftTransaction.recipient.address, fromAddress: draftTransaction.fromAccount?.address ?? sendState.selectedAccount.address, tokenId: draftTransaction.asset.details.tokenId, }); break; case ASSET_TYPES.NATIVE: default: // When sending native currency the to and value fields use the // recipient and amount values and the data key is either null or // populated with the user input provided in hex field. txParams.to = draftTransaction.recipient.address; txParams.value = draftTransaction.amount.value; txParams.data = draftTransaction.userInputHexData ?? undefined; } // We need to make sure that we only include the right gas fee fields // based on the type of transaction the network supports. We will also set // the type param here. if (sendState.eip1559support) { txParams.type = TRANSACTION_ENVELOPE_TYPES.FEE_MARKET; txParams.maxFeePerGas = draftTransaction.gas.maxFeePerGas; txParams.maxPriorityFeePerGas = draftTransaction.gas.maxPriorityFeePerGas; if (!txParams.maxFeePerGas || txParams.maxFeePerGas === '0x0') { txParams.maxFeePerGas = draftTransaction.gas.gasPrice; } if ( !txParams.maxPriorityFeePerGas || txParams.maxPriorityFeePerGas === '0x0' ) { txParams.maxPriorityFeePerGas = txParams.maxFeePerGas; } } else { txParams.gasPrice = draftTransaction.gas.gasPrice; txParams.type = TRANSACTION_ENVELOPE_TYPES.LEGACY; } return txParams; } /** * This method is used to keep the original logic from the gas.duck.js file * after receiving a gasPrice from eth_gasPrice. First, the returned gasPrice * was converted to GWEI, then it was converted to a Number, then in the send * duck (here) we would use getGasPriceInHexWei to get back to hexWei. Now that * we receive a GWEI estimate from the controller, we still need to do this * weird conversion to get the proper rounding. * * @param {string} gasPriceEstimate * @returns {string} */ export function getRoundedGasPrice(gasPriceEstimate) { const gasPriceInDecGwei = conversionUtil(gasPriceEstimate, { numberOfDecimals: 9, toDenomination: GWEI, fromNumericBase: 'dec', toNumericBase: 'dec', fromCurrency: ETH, fromDenomination: GWEI, }); const gasPriceAsNumber = Number(gasPriceInDecGwei); return getGasPriceInHexWei(gasPriceAsNumber); } export async function getERC20Balance(token, accountAddress) { const contract = global.eth.contract(abi).at(token.address); const usersToken = (await contract.balanceOf(accountAddress)) ?? null; if (!usersToken) { return '0x0'; } const amount = calcTokenAmount( usersToken.balance.toString(), token.decimals, ).toString(16); return addHexPrefix(amount); }