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Similar Match Source Code This contract matches the deployed Bytecode of the Source Code for Contract 0x5Bc94f0D...B2C33225D The constructor portion of the code might be different and could alter the actual behaviour of the contract
Contract Name:
Conduit
Compiler Version
v0.8.14+commit.80d49f37
Contract Source Code (Solidity Standard Json-Input format)
// SPDX-License-Identifier: MIT pragma solidity 0.8.14; import { ConduitInterface } from "../interfaces/ConduitInterface.sol"; import { ConduitItemType } from "./lib/ConduitEnums.sol"; import { TokenTransferrer } from "../lib/TokenTransferrer.sol"; import { ConduitTransfer, ConduitBatch1155Transfer } from "./lib/ConduitStructs.sol"; import "./lib/ConduitConstants.sol"; /** * @title Conduit * @author 0age * @notice This contract serves as an originator for "proxied" transfers. Each * conduit is deployed and controlled by a "conduit controller" that can * add and remove "channels" or contracts that can instruct the conduit * to transfer approved ERC20/721/1155 tokens. *IMPORTANT NOTE: each * conduit has an owner that can arbitrarily add or remove channels, and * a malicious or negligent owner can add a channel that allows for any * approved ERC20/721/1155 tokens to be taken immediately — be extremely * cautious with what conduits you give token approvals to!* */ contract Conduit is ConduitInterface, TokenTransferrer { // Set deployer as an immutable controller that can update channel statuses. address private immutable _controller; // Track the status of each channel. mapping(address => bool) private _channels; /** * @notice Ensure that the caller is currently registered as an open channel * on the conduit. */ modifier onlyOpenChannel() { // Utilize assembly to access channel storage mapping directly. assembly { // Write the caller to scratch space. mstore(ChannelKey_channel_ptr, caller()) // Write the storage slot for _channels to scratch space. mstore(ChannelKey_slot_ptr, _channels.slot) // Derive the position in storage of _channels[msg.sender] // and check if the stored value is zero. if iszero( sload(keccak256(ChannelKey_channel_ptr, ChannelKey_length)) ) { // The caller is not an open channel; revert with // ChannelClosed(caller). First, set error signature in memory. mstore(ChannelClosed_error_ptr, ChannelClosed_error_signature) // Next, set the caller as the argument. mstore(ChannelClosed_channel_ptr, caller()) // Finally, revert, returning full custom error with argument. revert(ChannelClosed_error_ptr, ChannelClosed_error_length) } } // Continue with function execution. _; } /** * @notice In the constructor, set the deployer as the controller. */ constructor() { // Set the deployer as the controller. _controller = msg.sender; } /** * @notice Execute a sequence of ERC20/721/1155 transfers. Only a caller * with an open channel can call this function. Note that channels * are expected to implement reentrancy protection if desired, and * that cross-channel reentrancy may be possible if the conduit has * multiple open channels at once. Also note that channels are * expected to implement checks against transferring any zero-amount * items if that constraint is desired. * * @param transfers The ERC20/721/1155 transfers to perform. * * @return magicValue A magic value indicating that the transfers were * performed successfully. */ function execute(ConduitTransfer[] calldata transfers) external override onlyOpenChannel returns (bytes4 magicValue) { // Retrieve the total number of transfers and place on the stack. uint256 totalStandardTransfers = transfers.length; // Iterate over each transfer. for (uint256 i = 0; i < totalStandardTransfers; ) { // Retrieve the transfer in question and perform the transfer. _transfer(transfers[i]); // Skip overflow check as for loop is indexed starting at zero. unchecked { ++i; } } // Return a magic value indicating that the transfers were performed. magicValue = this.execute.selector; } /** * @notice Execute a sequence of batch 1155 item transfers. Only a caller * with an open channel can call this function. Note that channels * are expected to implement reentrancy protection if desired, and * that cross-channel reentrancy may be possible if the conduit has * multiple open channels at once. Also note that channels are * expected to implement checks against transferring any zero-amount * items if that constraint is desired. * * @param batchTransfers The 1155 batch item transfers to perform. * * @return magicValue A magic value indicating that the item transfers were * performed successfully. */ function executeBatch1155( ConduitBatch1155Transfer[] calldata batchTransfers ) external override onlyOpenChannel returns (bytes4 magicValue) { // Perform 1155 batch transfers. Note that memory should be considered // entirely corrupted from this point forward. _performERC1155BatchTransfers(batchTransfers); // Return a magic value indicating that the transfers were performed. magicValue = this.executeBatch1155.selector; } /** * @notice Execute a sequence of transfers, both single ERC20/721/1155 item * transfers as well as batch 1155 item transfers. Only a caller * with an open channel can call this function. Note that channels * are expected to implement reentrancy protection if desired, and * that cross-channel reentrancy may be possible if the conduit has * multiple open channels at once. Also note that channels are * expected to implement checks against transferring any zero-amount * items if that constraint is desired. * * @param standardTransfers The ERC20/721/1155 item transfers to perform. * @param batchTransfers The 1155 batch item transfers to perform. * * @return magicValue A magic value indicating that the item transfers were * performed successfully. */ function executeWithBatch1155( ConduitTransfer[] calldata standardTransfers, ConduitBatch1155Transfer[] calldata batchTransfers ) external override onlyOpenChannel returns (bytes4 magicValue) { // Retrieve the total number of transfers and place on the stack. uint256 totalStandardTransfers = standardTransfers.length; // Iterate over each standard transfer. for (uint256 i = 0; i < totalStandardTransfers; ) { // Retrieve the transfer in question and perform the transfer. _transfer(standardTransfers[i]); // Skip overflow check as for loop is indexed starting at zero. unchecked { ++i; } } // Perform 1155 batch transfers. Note that memory should be considered // entirely corrupted from this point forward aside from the free memory // pointer having the default value. _performERC1155BatchTransfers(batchTransfers); // Return a magic value indicating that the transfers were performed. magicValue = this.executeWithBatch1155.selector; } /** * @notice Open or close a given channel. Only callable by the controller. * * @param channel The channel to open or close. * @param isOpen The status of the channel (either open or closed). */ function updateChannel(address channel, bool isOpen) external override { // Ensure that the caller is the controller of this contract. if (msg.sender != _controller) { revert InvalidController(); } // Ensure that the channel does not already have the indicated status. if (_channels[channel] == isOpen) { revert ChannelStatusAlreadySet(channel, isOpen); } // Update the status of the channel. _channels[channel] = isOpen; // Emit a corresponding event. emit ChannelUpdated(channel, isOpen); } /** * @dev Internal function to transfer a given ERC20/721/1155 item. Note that * channels are expected to implement checks against transferring any * zero-amount items if that constraint is desired. * * @param item The ERC20/721/1155 item to transfer. */ function _transfer(ConduitTransfer calldata item) internal { // Determine the transfer method based on the respective item type. if (item.itemType == ConduitItemType.ERC20) { // Transfer ERC20 token. Note that item.identifier is ignored and // therefore ERC20 transfer items are potentially malleable — this // check should be performed by the calling channel if a constraint // on item malleability is desired. _performERC20Transfer(item.token, item.from, item.to, item.amount); } else if (item.itemType == ConduitItemType.ERC721) { // Ensure that exactly one 721 item is being transferred. if (item.amount != 1) { revert InvalidERC721TransferAmount(); } // Transfer ERC721 token. _performERC721Transfer( item.token, item.from, item.to, item.identifier ); } else if (item.itemType == ConduitItemType.ERC1155) { // Transfer ERC1155 token. _performERC1155Transfer( item.token, item.from, item.to, item.identifier, item.amount ); } else { // Throw with an error. revert InvalidItemType(); } } }
// SPDX-License-Identifier: MIT pragma solidity 0.8.14; import { ConduitTransfer, ConduitBatch1155Transfer } from "../conduit/lib/ConduitStructs.sol"; /** * @title ConduitInterface * @author 0age * @notice ConduitInterface contains all external function interfaces, events, * and errors for conduit contracts. */ interface ConduitInterface { /** * @dev Revert with an error when attempting to execute transfers using a * caller that does not have an open channel. */ error ChannelClosed(address channel); /** * @dev Revert with an error when attempting to update a channel to the * current status of that channel. */ error ChannelStatusAlreadySet(address channel, bool isOpen); /** * @dev Revert with an error when attempting to execute a transfer for an * item that does not have an ERC20/721/1155 item type. */ error InvalidItemType(); /** * @dev Revert with an error when attempting to update the status of a * channel from a caller that is not the conduit controller. */ error InvalidController(); /** * @dev Emit an event whenever a channel is opened or closed. * * @param channel The channel that has been updated. * @param open A boolean indicating whether the conduit is open or not. */ event ChannelUpdated(address indexed channel, bool open); /** * @notice Execute a sequence of ERC20/721/1155 transfers. Only a caller * with an open channel can call this function. * * @param transfers The ERC20/721/1155 transfers to perform. * * @return magicValue A magic value indicating that the transfers were * performed successfully. */ function execute(ConduitTransfer[] calldata transfers) external returns (bytes4 magicValue); /** * @notice Execute a sequence of batch 1155 transfers. Only a caller with an * open channel can call this function. * * @param batch1155Transfers The 1155 batch transfers to perform. * * @return magicValue A magic value indicating that the transfers were * performed successfully. */ function executeBatch1155( ConduitBatch1155Transfer[] calldata batch1155Transfers ) external returns (bytes4 magicValue); /** * @notice Execute a sequence of transfers, both single and batch 1155. Only * a caller with an open channel can call this function. * * @param standardTransfers The ERC20/721/1155 transfers to perform. * @param batch1155Transfers The 1155 batch transfers to perform. * * @return magicValue A magic value indicating that the transfers were * performed successfully. */ function executeWithBatch1155( ConduitTransfer[] calldata standardTransfers, ConduitBatch1155Transfer[] calldata batch1155Transfers ) external returns (bytes4 magicValue); /** * @notice Open or close a given channel. Only callable by the controller. * * @param channel The channel to open or close. * @param isOpen The status of the channel (either open or closed). */ function updateChannel(address channel, bool isOpen) external; }
// SPDX-License-Identifier: MIT pragma solidity 0.8.14; enum ConduitItemType { NATIVE, // unused ERC20, ERC721, ERC1155 }
// SPDX-License-Identifier: MIT pragma solidity 0.8.14; import "./TokenTransferrerConstants.sol"; import { TokenTransferrerErrors } from "../interfaces/TokenTransferrerErrors.sol"; import { ConduitBatch1155Transfer } from "../conduit/lib/ConduitStructs.sol"; /** * @title TokenTransferrer * @author 0age * @custom:coauthor d1ll0n * @custom:coauthor transmissions11 * @notice TokenTransferrer is a library for performing optimized ERC20, ERC721, * ERC1155, and batch ERC1155 transfers, used by both Seaport as well as * by conduits deployed by the ConduitController. Use great caution when * considering these functions for use in other codebases, as there are * significant side effects and edge cases that need to be thoroughly * understood and carefully addressed. */ contract TokenTransferrer is TokenTransferrerErrors { /** * @dev Internal function to transfer ERC20 tokens from a given originator * to a given recipient. Sufficient approvals must be set on the * contract performing the transfer. * * @param token The ERC20 token to transfer. * @param from The originator of the transfer. * @param to The recipient of the transfer. * @param amount The amount to transfer. */ function _performERC20Transfer( address token, address from, address to, uint256 amount ) internal { // Utilize assembly to perform an optimized ERC20 token transfer. assembly { // The free memory pointer memory slot will be used when populating // call data for the transfer; read the value and restore it later. let memPointer := mload(FreeMemoryPointerSlot) // Write call data into memory, starting with function selector. mstore(ERC20_transferFrom_sig_ptr, ERC20_transferFrom_signature) mstore(ERC20_transferFrom_from_ptr, from) mstore(ERC20_transferFrom_to_ptr, to) mstore(ERC20_transferFrom_amount_ptr, amount) // Make call & copy up to 32 bytes of return data to scratch space. // Scratch space does not need to be cleared ahead of time, as the // subsequent check will ensure that either at least a full word of // return data is received (in which case it will be overwritten) or // that no data is received (in which case scratch space will be // ignored) on a successful call to the given token. let callStatus := call( gas(), token, 0, ERC20_transferFrom_sig_ptr, ERC20_transferFrom_length, 0, OneWord ) // Determine whether transfer was successful using status & result. let success := and( // Set success to whether the call reverted, if not check it // either returned exactly 1 (can't just be non-zero data), or // had no return data. or( and(eq(mload(0), 1), gt(returndatasize(), 31)), iszero(returndatasize()) ), callStatus ) // Handle cases where either the transfer failed or no data was // returned. Group these, as most transfers will succeed with data. // Equivalent to `or(iszero(success), iszero(returndatasize()))` // but after it's inverted for JUMPI this expression is cheaper. if iszero(and(success, iszero(iszero(returndatasize())))) { // If the token has no code or the transfer failed: Equivalent // to `or(iszero(success), iszero(extcodesize(token)))` but // after it's inverted for JUMPI this expression is cheaper. if iszero(and(iszero(iszero(extcodesize(token))), success)) { // If the transfer failed: if iszero(success) { // If it was due to a revert: if iszero(callStatus) { // If it returned a message, bubble it up as long as // sufficient gas remains to do so: if returndatasize() { // Ensure that sufficient gas is available to // copy returndata while expanding memory where // necessary. Start by computing the word size // of returndata and allocated memory. Round up // to the nearest full word. let returnDataWords := div( add(returndatasize(), AlmostOneWord), OneWord ) // Note: use the free memory pointer in place of // msize() to work around a Yul warning that // prevents accessing msize directly when the IR // pipeline is activated. let msizeWords := div(memPointer, OneWord) // Next, compute the cost of the returndatacopy. let cost := mul(CostPerWord, returnDataWords) // Then, compute cost of new memory allocation. if gt(returnDataWords, msizeWords) { cost := add( cost, add( mul( sub( returnDataWords, msizeWords ), CostPerWord ), div( sub( mul( returnDataWords, returnDataWords ), mul(msizeWords, msizeWords) ), MemoryExpansionCoefficient ) ) ) } // Finally, add a small constant and compare to // gas remaining; bubble up the revert data if // enough gas is still available. if lt(add(cost, ExtraGasBuffer), gas()) { // Copy returndata to memory; overwrite // existing memory. returndatacopy(0, 0, returndatasize()) // Revert, specifying memory region with // copied returndata. revert(0, returndatasize()) } } // Otherwise revert with a generic error message. mstore( TokenTransferGenericFailure_error_sig_ptr, TokenTransferGenericFailure_error_signature ) mstore( TokenTransferGenericFailure_error_token_ptr, token ) mstore( TokenTransferGenericFailure_error_from_ptr, from ) mstore(TokenTransferGenericFailure_error_to_ptr, to) mstore(TokenTransferGenericFailure_error_id_ptr, 0) mstore( TokenTransferGenericFailure_error_amount_ptr, amount ) revert( TokenTransferGenericFailure_error_sig_ptr, TokenTransferGenericFailure_error_length ) } // Otherwise revert with a message about the token // returning false or non-compliant return values. mstore( BadReturnValueFromERC20OnTransfer_error_sig_ptr, BadReturnValueFromERC20OnTransfer_error_signature ) mstore( BadReturnValueFromERC20OnTransfer_error_token_ptr, token ) mstore( BadReturnValueFromERC20OnTransfer_error_from_ptr, from ) mstore( BadReturnValueFromERC20OnTransfer_error_to_ptr, to ) mstore( BadReturnValueFromERC20OnTransfer_error_amount_ptr, amount ) revert( BadReturnValueFromERC20OnTransfer_error_sig_ptr, BadReturnValueFromERC20OnTransfer_error_length ) } // Otherwise, revert with error about token not having code: mstore(NoContract_error_sig_ptr, NoContract_error_signature) mstore(NoContract_error_token_ptr, token) revert(NoContract_error_sig_ptr, NoContract_error_length) } // Otherwise, the token just returned no data despite the call // having succeeded; no need to optimize for this as it's not // technically ERC20 compliant. } // Restore the original free memory pointer. mstore(FreeMemoryPointerSlot, memPointer) // Restore the zero slot to zero. mstore(ZeroSlot, 0) } } /** * @dev Internal function to transfer an ERC721 token from a given * originator to a given recipient. Sufficient approvals must be set on * the contract performing the transfer. Note that this function does * not check whether the receiver can accept the ERC721 token (i.e. it * does not use `safeTransferFrom`). * * @param token The ERC721 token to transfer. * @param from The originator of the transfer. * @param to The recipient of the transfer. * @param identifier The tokenId to transfer. */ function _performERC721Transfer( address token, address from, address to, uint256 identifier ) internal { // Utilize assembly to perform an optimized ERC721 token transfer. assembly { // If the token has no code, revert. if iszero(extcodesize(token)) { mstore(NoContract_error_sig_ptr, NoContract_error_signature) mstore(NoContract_error_token_ptr, token) revert(NoContract_error_sig_ptr, NoContract_error_length) } // The free memory pointer memory slot will be used when populating // call data for the transfer; read the value and restore it later. let memPointer := mload(FreeMemoryPointerSlot) // Write call data to memory starting with function selector. mstore(ERC721_transferFrom_sig_ptr, ERC721_transferFrom_signature) mstore(ERC721_transferFrom_from_ptr, from) mstore(ERC721_transferFrom_to_ptr, to) mstore(ERC721_transferFrom_id_ptr, identifier) // Perform the call, ignoring return data. let success := call( gas(), token, 0, ERC721_transferFrom_sig_ptr, ERC721_transferFrom_length, 0, 0 ) // If the transfer reverted: if iszero(success) { // If it returned a message, bubble it up as long as sufficient // gas remains to do so: if returndatasize() { // Ensure that sufficient gas is available to copy // returndata while expanding memory where necessary. Start // by computing word size of returndata & allocated memory. // Round up to the nearest full word. let returnDataWords := div( add(returndatasize(), AlmostOneWord), OneWord ) // Note: use the free memory pointer in place of msize() to // work around a Yul warning that prevents accessing msize // directly when the IR pipeline is activated. let msizeWords := div(memPointer, OneWord) // Next, compute the cost of the returndatacopy. let cost := mul(CostPerWord, returnDataWords) // Then, compute cost of new memory allocation. if gt(returnDataWords, msizeWords) { cost := add( cost, add( mul( sub(returnDataWords, msizeWords), CostPerWord ), div( sub( mul(returnDataWords, returnDataWords), mul(msizeWords, msizeWords) ), MemoryExpansionCoefficient ) ) ) } // Finally, add a small constant and compare to gas // remaining; bubble up the revert data if enough gas is // still available. if lt(add(cost, ExtraGasBuffer), gas()) { // Copy returndata to memory; overwrite existing memory. returndatacopy(0, 0, returndatasize()) // Revert, giving memory region with copied returndata. revert(0, returndatasize()) } } // Otherwise revert with a generic error message. mstore( TokenTransferGenericFailure_error_sig_ptr, TokenTransferGenericFailure_error_signature ) mstore(TokenTransferGenericFailure_error_token_ptr, token) mstore(TokenTransferGenericFailure_error_from_ptr, from) mstore(TokenTransferGenericFailure_error_to_ptr, to) mstore(TokenTransferGenericFailure_error_id_ptr, identifier) mstore(TokenTransferGenericFailure_error_amount_ptr, 1) revert( TokenTransferGenericFailure_error_sig_ptr, TokenTransferGenericFailure_error_length ) } // Restore the original free memory pointer. mstore(FreeMemoryPointerSlot, memPointer) // Restore the zero slot to zero. mstore(ZeroSlot, 0) } } /** * @dev Internal function to transfer ERC1155 tokens from a given * originator to a given recipient. Sufficient approvals must be set on * the contract performing the transfer and contract recipients must * implement the ERC1155TokenReceiver interface to indicate that they * are willing to accept the transfer. * * @param token The ERC1155 token to transfer. * @param from The originator of the transfer. * @param to The recipient of the transfer. * @param identifier The id to transfer. * @param amount The amount to transfer. */ function _performERC1155Transfer( address token, address from, address to, uint256 identifier, uint256 amount ) internal { // Utilize assembly to perform an optimized ERC1155 token transfer. assembly { // If the token has no code, revert. if iszero(extcodesize(token)) { mstore(NoContract_error_sig_ptr, NoContract_error_signature) mstore(NoContract_error_token_ptr, token) revert(NoContract_error_sig_ptr, NoContract_error_length) } // The following memory slots will be used when populating call data // for the transfer; read the values and restore them later. let memPointer := mload(FreeMemoryPointerSlot) let slot0x80 := mload(Slot0x80) let slot0xA0 := mload(Slot0xA0) let slot0xC0 := mload(Slot0xC0) // Write call data into memory, beginning with function selector. mstore( ERC1155_safeTransferFrom_sig_ptr, ERC1155_safeTransferFrom_signature ) mstore(ERC1155_safeTransferFrom_from_ptr, from) mstore(ERC1155_safeTransferFrom_to_ptr, to) mstore(ERC1155_safeTransferFrom_id_ptr, identifier) mstore(ERC1155_safeTransferFrom_amount_ptr, amount) mstore( ERC1155_safeTransferFrom_data_offset_ptr, ERC1155_safeTransferFrom_data_length_offset ) mstore(ERC1155_safeTransferFrom_data_length_ptr, 0) // Perform the call, ignoring return data. let success := call( gas(), token, 0, ERC1155_safeTransferFrom_sig_ptr, ERC1155_safeTransferFrom_length, 0, 0 ) // If the transfer reverted: if iszero(success) { // If it returned a message, bubble it up as long as sufficient // gas remains to do so: if returndatasize() { // Ensure that sufficient gas is available to copy // returndata while expanding memory where necessary. Start // by computing word size of returndata & allocated memory. // Round up to the nearest full word. let returnDataWords := div( add(returndatasize(), AlmostOneWord), OneWord ) // Note: use the free memory pointer in place of msize() to // work around a Yul warning that prevents accessing msize // directly when the IR pipeline is activated. let msizeWords := div(memPointer, OneWord) // Next, compute the cost of the returndatacopy. let cost := mul(CostPerWord, returnDataWords) // Then, compute cost of new memory allocation. if gt(returnDataWords, msizeWords) { cost := add( cost, add( mul( sub(returnDataWords, msizeWords), CostPerWord ), div( sub( mul(returnDataWords, returnDataWords), mul(msizeWords, msizeWords) ), MemoryExpansionCoefficient ) ) ) } // Finally, add a small constant and compare to gas // remaining; bubble up the revert data if enough gas is // still available. if lt(add(cost, ExtraGasBuffer), gas()) { // Copy returndata to memory; overwrite existing memory. returndatacopy(0, 0, returndatasize()) // Revert, giving memory region with copied returndata. revert(0, returndatasize()) } } // Otherwise revert with a generic error message. mstore( TokenTransferGenericFailure_error_sig_ptr, TokenTransferGenericFailure_error_signature ) mstore(TokenTransferGenericFailure_error_token_ptr, token) mstore(TokenTransferGenericFailure_error_from_ptr, from) mstore(TokenTransferGenericFailure_error_to_ptr, to) mstore(TokenTransferGenericFailure_error_id_ptr, identifier) mstore(TokenTransferGenericFailure_error_amount_ptr, amount) revert( TokenTransferGenericFailure_error_sig_ptr, TokenTransferGenericFailure_error_length ) } mstore(Slot0x80, slot0x80) // Restore slot 0x80. mstore(Slot0xA0, slot0xA0) // Restore slot 0xA0. mstore(Slot0xC0, slot0xC0) // Restore slot 0xC0. // Restore the original free memory pointer. mstore(FreeMemoryPointerSlot, memPointer) // Restore the zero slot to zero. mstore(ZeroSlot, 0) } } /** * @dev Internal function to transfer ERC1155 tokens from a given * originator to a given recipient. Sufficient approvals must be set on * the contract performing the transfer and contract recipients must * implement the ERC1155TokenReceiver interface to indicate that they * are willing to accept the transfer. NOTE: this function is not * memory-safe; it will overwrite existing memory, restore the free * memory pointer to the default value, and overwrite the zero slot. * This function should only be called once memory is no longer * required and when uninitialized arrays are not utilized, and memory * should be considered fully corrupted (aside from the existence of a * default-value free memory pointer) after calling this function. * * @param batchTransfers The group of 1155 batch transfers to perform. */ function _performERC1155BatchTransfers( ConduitBatch1155Transfer[] calldata batchTransfers ) internal { // Utilize assembly to perform optimized batch 1155 transfers. assembly { let len := batchTransfers.length // Pointer to first head in the array, which is offset to the struct // at each index. This gets incremented after each loop to avoid // multiplying by 32 to get the offset for each element. let nextElementHeadPtr := batchTransfers.offset // Pointer to beginning of the head of the array. This is the // reference position each offset references. It's held static to // let each loop calculate the data position for an element. let arrayHeadPtr := nextElementHeadPtr // Write the function selector, which will be reused for each call: // safeBatchTransferFrom(address,address,uint256[],uint256[],bytes) mstore( ConduitBatch1155Transfer_from_offset, ERC1155_safeBatchTransferFrom_signature ) // Iterate over each batch transfer. for { let i := 0 } lt(i, len) { i := add(i, 1) } { // Read the offset to the beginning of the element and add // it to pointer to the beginning of the array head to get // the absolute position of the element in calldata. let elementPtr := add( arrayHeadPtr, calldataload(nextElementHeadPtr) ) // Retrieve the token from calldata. let token := calldataload(elementPtr) // If the token has no code, revert. if iszero(extcodesize(token)) { mstore(NoContract_error_sig_ptr, NoContract_error_signature) mstore(NoContract_error_token_ptr, token) revert(NoContract_error_sig_ptr, NoContract_error_length) } // Get the total number of supplied ids. let idsLength := calldataload( add(elementPtr, ConduitBatch1155Transfer_ids_length_offset) ) // Determine the expected offset for the amounts array. let expectedAmountsOffset := add( ConduitBatch1155Transfer_amounts_length_baseOffset, mul(idsLength, OneWord) ) // Validate struct encoding. let invalidEncoding := iszero( and( // ids.length == amounts.length eq( idsLength, calldataload(add(elementPtr, expectedAmountsOffset)) ), and( // ids_offset == 0xa0 eq( calldataload( add( elementPtr, ConduitBatch1155Transfer_ids_head_offset ) ), ConduitBatch1155Transfer_ids_length_offset ), // amounts_offset == 0xc0 + ids.length*32 eq( calldataload( add( elementPtr, ConduitBatchTransfer_amounts_head_offset ) ), expectedAmountsOffset ) ) ) ) // Revert with an error if the encoding is not valid. if invalidEncoding { mstore( Invalid1155BatchTransferEncoding_ptr, Invalid1155BatchTransferEncoding_selector ) revert( Invalid1155BatchTransferEncoding_ptr, Invalid1155BatchTransferEncoding_length ) } // Update the offset position for the next loop nextElementHeadPtr := add(nextElementHeadPtr, OneWord) // Copy the first section of calldata (before dynamic values). calldatacopy( BatchTransfer1155Params_ptr, add(elementPtr, ConduitBatch1155Transfer_from_offset), ConduitBatch1155Transfer_usable_head_size ) // Determine size of calldata required for ids and amounts. Note // that the size includes both lengths as well as the data. let idsAndAmountsSize := add(TwoWords, mul(idsLength, TwoWords)) // Update the offset for the data array in memory. mstore( BatchTransfer1155Params_data_head_ptr, add( BatchTransfer1155Params_ids_length_offset, idsAndAmountsSize ) ) // Set the length of the data array in memory to zero. mstore( add( BatchTransfer1155Params_data_length_basePtr, idsAndAmountsSize ), 0 ) // Determine the total calldata size for the call to transfer. let transferDataSize := add( BatchTransfer1155Params_calldata_baseSize, idsAndAmountsSize ) // Copy second section of calldata (including dynamic values). calldatacopy( BatchTransfer1155Params_ids_length_ptr, add(elementPtr, ConduitBatch1155Transfer_ids_length_offset), idsAndAmountsSize ) // Perform the call to transfer 1155 tokens. let success := call( gas(), token, 0, ConduitBatch1155Transfer_from_offset, // Data portion start. transferDataSize, // Location of the length of callData. 0, 0 ) // If the transfer reverted: if iszero(success) { // If it returned a message, bubble it up as long as // sufficient gas remains to do so: if returndatasize() { // Ensure that sufficient gas is available to copy // returndata while expanding memory where necessary. // Start by computing word size of returndata and // allocated memory. Round up to the nearest full word. let returnDataWords := div( add(returndatasize(), AlmostOneWord), OneWord ) // Note: use transferDataSize in place of msize() to // work around a Yul warning that prevents accessing // msize directly when the IR pipeline is activated. // The free memory pointer is not used here because // this function does almost all memory management // manually and does not update it, and transferDataSize // should be the largest memory value used (unless a // previous batch was larger). let msizeWords := div(transferDataSize, OneWord) // Next, compute the cost of the returndatacopy. let cost := mul(CostPerWord, returnDataWords) // Then, compute cost of new memory allocation. if gt(returnDataWords, msizeWords) { cost := add( cost, add( mul( sub(returnDataWords, msizeWords), CostPerWord ), div( sub( mul( returnDataWords, returnDataWords ), mul(msizeWords, msizeWords) ), MemoryExpansionCoefficient ) ) ) } // Finally, add a small constant and compare to gas // remaining; bubble up the revert data if enough gas is // still available. if lt(add(cost, ExtraGasBuffer), gas()) { // Copy returndata to memory; overwrite existing. returndatacopy(0, 0, returndatasize()) // Revert with memory region containing returndata. revert(0, returndatasize()) } } // Set the error signature. mstore( 0, ERC1155BatchTransferGenericFailure_error_signature ) // Write the token. mstore(ERC1155BatchTransferGenericFailure_token_ptr, token) // Increase the offset to ids by 32. mstore( BatchTransfer1155Params_ids_head_ptr, ERC1155BatchTransferGenericFailure_ids_offset ) // Increase the offset to amounts by 32. mstore( BatchTransfer1155Params_amounts_head_ptr, add( OneWord, mload(BatchTransfer1155Params_amounts_head_ptr) ) ) // Return modified region. The total size stays the same as // `token` uses the same number of bytes as `data.length`. revert(0, transferDataSize) } } // Reset the free memory pointer to the default value; memory must // be assumed to be dirtied and not reused from this point forward. // Also note that the zero slot is not reset to zero, meaning empty // arrays cannot be safely created or utilized until it is restored. mstore(FreeMemoryPointerSlot, DefaultFreeMemoryPointer) } } }
// SPDX-License-Identifier: MIT pragma solidity 0.8.14; import { ConduitItemType } from "./ConduitEnums.sol"; struct ConduitTransfer { ConduitItemType itemType; address token; address from; address to; uint256 identifier; uint256 amount; } struct ConduitBatch1155Transfer { address token; address from; address to; uint256[] ids; uint256[] amounts; }
// SPDX-License-Identifier: MIT pragma solidity 0.8.14; // error ChannelClosed(address channel) uint256 constant ChannelClosed_error_signature = ( 0x93daadf200000000000000000000000000000000000000000000000000000000 ); uint256 constant ChannelClosed_error_ptr = 0x00; uint256 constant ChannelClosed_channel_ptr = 0x4; uint256 constant ChannelClosed_error_length = 0x24; // For the mapping: // mapping(address => bool) channels // The position in storage for a particular account is: // keccak256(abi.encode(account, channels.slot)) uint256 constant ChannelKey_channel_ptr = 0x00; uint256 constant ChannelKey_slot_ptr = 0x20; uint256 constant ChannelKey_length = 0x40;
// SPDX-License-Identifier: MIT pragma solidity 0.8.14; /* * -------------------------- Disambiguation & Other Notes --------------------- * - The term "head" is used as it is in the documentation for ABI encoding, * but only in reference to dynamic types, i.e. it always refers to the * offset or pointer to the body of a dynamic type. In calldata, the head * is always an offset (relative to the parent object), while in memory, * the head is always the pointer to the body. More information found here: * https://docs.soliditylang.org/en/v0.8.14/abi-spec.html#argument-encoding * - Note that the length of an array is separate from and precedes the * head of the array. * * - The term "body" is used in place of the term "head" used in the ABI * documentation. It refers to the start of the data for a dynamic type, * e.g. the first word of a struct or the first word of the first element * in an array. * * - The term "pointer" is used to describe the absolute position of a value * and never an offset relative to another value. * - The suffix "_ptr" refers to a memory pointer. * - The suffix "_cdPtr" refers to a calldata pointer. * * - The term "offset" is used to describe the position of a value relative * to some parent value. For example, OrderParameters_conduit_offset is the * offset to the "conduit" value in the OrderParameters struct relative to * the start of the body. * - Note: Offsets are used to derive pointers. * * - Some structs have pointers defined for all of their fields in this file. * Lines which are commented out are fields that are not used in the * codebase but have been left in for readability. */ uint256 constant AlmostOneWord = 0x1f; uint256 constant OneWord = 0x20; uint256 constant TwoWords = 0x40; uint256 constant ThreeWords = 0x60; uint256 constant FreeMemoryPointerSlot = 0x40; uint256 constant ZeroSlot = 0x60; uint256 constant DefaultFreeMemoryPointer = 0x80; uint256 constant Slot0x80 = 0x80; uint256 constant Slot0xA0 = 0xa0; uint256 constant Slot0xC0 = 0xc0; // abi.encodeWithSignature("transferFrom(address,address,uint256)") uint256 constant ERC20_transferFrom_signature = ( 0x23b872dd00000000000000000000000000000000000000000000000000000000 ); uint256 constant ERC20_transferFrom_sig_ptr = 0x0; uint256 constant ERC20_transferFrom_from_ptr = 0x04; uint256 constant ERC20_transferFrom_to_ptr = 0x24; uint256 constant ERC20_transferFrom_amount_ptr = 0x44; uint256 constant ERC20_transferFrom_length = 0x64; // 4 + 32 * 3 == 100 // abi.encodeWithSignature( // "safeTransferFrom(address,address,uint256,uint256,bytes)" // ) uint256 constant ERC1155_safeTransferFrom_signature = ( 0xf242432a00000000000000000000000000000000000000000000000000000000 ); uint256 constant ERC1155_safeTransferFrom_sig_ptr = 0x0; uint256 constant ERC1155_safeTransferFrom_from_ptr = 0x04; uint256 constant ERC1155_safeTransferFrom_to_ptr = 0x24; uint256 constant ERC1155_safeTransferFrom_id_ptr = 0x44; uint256 constant ERC1155_safeTransferFrom_amount_ptr = 0x64; uint256 constant ERC1155_safeTransferFrom_data_offset_ptr = 0x84; uint256 constant ERC1155_safeTransferFrom_data_length_ptr = 0xa4; uint256 constant ERC1155_safeTransferFrom_length = 0xc4; // 4 + 32 * 6 == 196 uint256 constant ERC1155_safeTransferFrom_data_length_offset = 0xa0; // abi.encodeWithSignature( // "safeBatchTransferFrom(address,address,uint256[],uint256[],bytes)" // ) uint256 constant ERC1155_safeBatchTransferFrom_signature = ( 0x2eb2c2d600000000000000000000000000000000000000000000000000000000 ); bytes4 constant ERC1155_safeBatchTransferFrom_selector = bytes4( bytes32(ERC1155_safeBatchTransferFrom_signature) ); uint256 constant ERC721_transferFrom_signature = ERC20_transferFrom_signature; uint256 constant ERC721_transferFrom_sig_ptr = 0x0; uint256 constant ERC721_transferFrom_from_ptr = 0x04; uint256 constant ERC721_transferFrom_to_ptr = 0x24; uint256 constant ERC721_transferFrom_id_ptr = 0x44; uint256 constant ERC721_transferFrom_length = 0x64; // 4 + 32 * 3 == 100 // abi.encodeWithSignature("NoContract(address)") uint256 constant NoContract_error_signature = ( 0x5f15d67200000000000000000000000000000000000000000000000000000000 ); uint256 constant NoContract_error_sig_ptr = 0x0; uint256 constant NoContract_error_token_ptr = 0x4; uint256 constant NoContract_error_length = 0x24; // 4 + 32 == 36 // abi.encodeWithSignature( // "TokenTransferGenericFailure(address,address,address,uint256,uint256)" // ) uint256 constant TokenTransferGenericFailure_error_signature = ( 0xf486bc8700000000000000000000000000000000000000000000000000000000 ); uint256 constant TokenTransferGenericFailure_error_sig_ptr = 0x0; uint256 constant TokenTransferGenericFailure_error_token_ptr = 0x4; uint256 constant TokenTransferGenericFailure_error_from_ptr = 0x24; uint256 constant TokenTransferGenericFailure_error_to_ptr = 0x44; uint256 constant TokenTransferGenericFailure_error_id_ptr = 0x64; uint256 constant TokenTransferGenericFailure_error_amount_ptr = 0x84; // 4 + 32 * 5 == 164 uint256 constant TokenTransferGenericFailure_error_length = 0xa4; // abi.encodeWithSignature( // "BadReturnValueFromERC20OnTransfer(address,address,address,uint256)" // ) uint256 constant BadReturnValueFromERC20OnTransfer_error_signature = ( 0x9889192300000000000000000000000000000000000000000000000000000000 ); uint256 constant BadReturnValueFromERC20OnTransfer_error_sig_ptr = 0x0; uint256 constant BadReturnValueFromERC20OnTransfer_error_token_ptr = 0x4; uint256 constant BadReturnValueFromERC20OnTransfer_error_from_ptr = 0x24; uint256 constant BadReturnValueFromERC20OnTransfer_error_to_ptr = 0x44; uint256 constant BadReturnValueFromERC20OnTransfer_error_amount_ptr = 0x64; // 4 + 32 * 4 == 132 uint256 constant BadReturnValueFromERC20OnTransfer_error_length = 0x84; uint256 constant ExtraGasBuffer = 0x20; uint256 constant CostPerWord = 3; uint256 constant MemoryExpansionCoefficient = 0x200; // Values are offset by 32 bytes in order to write the token to the beginning // in the event of a revert uint256 constant BatchTransfer1155Params_ptr = 0x24; uint256 constant BatchTransfer1155Params_ids_head_ptr = 0x64; uint256 constant BatchTransfer1155Params_amounts_head_ptr = 0x84; uint256 constant BatchTransfer1155Params_data_head_ptr = 0xa4; uint256 constant BatchTransfer1155Params_data_length_basePtr = 0xc4; uint256 constant BatchTransfer1155Params_calldata_baseSize = 0xc4; uint256 constant BatchTransfer1155Params_ids_length_ptr = 0xc4; uint256 constant BatchTransfer1155Params_ids_length_offset = 0xa0; uint256 constant BatchTransfer1155Params_amounts_length_baseOffset = 0xc0; uint256 constant BatchTransfer1155Params_data_length_baseOffset = 0xe0; uint256 constant ConduitBatch1155Transfer_usable_head_size = 0x80; uint256 constant ConduitBatch1155Transfer_from_offset = 0x20; uint256 constant ConduitBatch1155Transfer_ids_head_offset = 0x60; uint256 constant ConduitBatch1155Transfer_amounts_head_offset = 0x80; uint256 constant ConduitBatch1155Transfer_ids_length_offset = 0xa0; uint256 constant ConduitBatch1155Transfer_amounts_length_baseOffset = 0xc0; uint256 constant ConduitBatch1155Transfer_calldata_baseSize = 0xc0; // Note: abbreviated version of above constant to adhere to line length limit. uint256 constant ConduitBatchTransfer_amounts_head_offset = 0x80; uint256 constant Invalid1155BatchTransferEncoding_ptr = 0x00; uint256 constant Invalid1155BatchTransferEncoding_length = 0x04; uint256 constant Invalid1155BatchTransferEncoding_selector = ( 0xeba2084c00000000000000000000000000000000000000000000000000000000 ); uint256 constant ERC1155BatchTransferGenericFailure_error_signature = ( 0xafc445e200000000000000000000000000000000000000000000000000000000 ); uint256 constant ERC1155BatchTransferGenericFailure_token_ptr = 0x04; uint256 constant ERC1155BatchTransferGenericFailure_ids_offset = 0xc0;
// SPDX-License-Identifier: MIT pragma solidity 0.8.14; /** * @title TokenTransferrerErrors */ interface TokenTransferrerErrors { /** * @dev Revert with an error when an ERC721 transfer with amount other than * one is attempted. */ error InvalidERC721TransferAmount(); /** * @dev Revert with an error when attempting to fulfill an order where an * item has an amount of zero. */ error MissingItemAmount(); /** * @dev Revert with an error when attempting to fulfill an order where an * item has unused parameters. This includes both the token and the * identifier parameters for native transfers as well as the identifier * parameter for ERC20 transfers. Note that the conduit does not * perform this check, leaving it up to the calling channel to enforce * when desired. */ error UnusedItemParameters(); /** * @dev Revert with an error when an ERC20, ERC721, or ERC1155 token * transfer reverts. * * @param token The token for which the transfer was attempted. * @param from The source of the attempted transfer. * @param to The recipient of the attempted transfer. * @param identifier The identifier for the attempted transfer. * @param amount The amount for the attempted transfer. */ error TokenTransferGenericFailure( address token, address from, address to, uint256 identifier, uint256 amount ); /** * @dev Revert with an error when a batch ERC1155 token transfer reverts. * * @param token The token for which the transfer was attempted. * @param from The source of the attempted transfer. * @param to The recipient of the attempted transfer. * @param identifiers The identifiers for the attempted transfer. * @param amounts The amounts for the attempted transfer. */ error ERC1155BatchTransferGenericFailure( address token, address from, address to, uint256[] identifiers, uint256[] amounts ); /** * @dev Revert with an error when an ERC20 token transfer returns a falsey * value. * * @param token The token for which the ERC20 transfer was attempted. * @param from The source of the attempted ERC20 transfer. * @param to The recipient of the attempted ERC20 transfer. * @param amount The amount for the attempted ERC20 transfer. */ error BadReturnValueFromERC20OnTransfer( address token, address from, address to, uint256 amount ); /** * @dev Revert with an error when an account being called as an assumed * contract does not have code and returns no data. * * @param account The account that should contain code. */ error NoContract(address account); /** * @dev Revert with an error when attempting to execute an 1155 batch * transfer using calldata not produced by default ABI encoding or with * different lengths for ids and amounts arrays. */ error Invalid1155BatchTransferEncoding(); }
{ "viaIR": true, "optimizer": { "enabled": true, "runs": 1000000 }, "outputSelection": { "*": { "*": [ "evm.bytecode", "evm.deployedBytecode", "abi" ] } } }
Contract Security Audit
- No Contract Security Audit Submitted- Submit Audit Here
[{"inputs":[],"stateMutability":"nonpayable","type":"constructor"},{"inputs":[{"internalType":"address","name":"token","type":"address"},{"internalType":"address","name":"from","type":"address"},{"internalType":"address","name":"to","type":"address"},{"internalType":"uint256","name":"amount","type":"uint256"}],"name":"BadReturnValueFromERC20OnTransfer","type":"error"},{"inputs":[{"internalType":"address","name":"channel","type":"address"}],"name":"ChannelClosed","type":"error"},{"inputs":[{"internalType":"address","name":"channel","type":"address"},{"internalType":"bool","name":"isOpen","type":"bool"}],"name":"ChannelStatusAlreadySet","type":"error"},{"inputs":[{"internalType":"address","name":"token","type":"address"},{"internalType":"address","name":"from","type":"address"},{"internalType":"address","name":"to","type":"address"},{"internalType":"uint256[]","name":"identifiers","type":"uint256[]"},{"internalType":"uint256[]","name":"amounts","type":"uint256[]"}],"name":"ERC1155BatchTransferGenericFailure","type":"error"},{"inputs":[],"name":"Invalid1155BatchTransferEncoding","type":"error"},{"inputs":[],"name":"InvalidController","type":"error"},{"inputs":[],"name":"InvalidERC721TransferAmount","type":"error"},{"inputs":[],"name":"InvalidItemType","type":"error"},{"inputs":[],"name":"MissingItemAmount","type":"error"},{"inputs":[{"internalType":"address","name":"account","type":"address"}],"name":"NoContract","type":"error"},{"inputs":[{"internalType":"address","name":"token","type":"address"},{"internalType":"address","name":"from","type":"address"},{"internalType":"address","name":"to","type":"address"},{"internalType":"uint256","name":"identifier","type":"uint256"},{"internalType":"uint256","name":"amount","type":"uint256"}],"name":"TokenTransferGenericFailure","type":"error"},{"inputs":[],"name":"UnusedItemParameters","type":"error"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"channel","type":"address"},{"indexed":false,"internalType":"bool","name":"open","type":"bool"}],"name":"ChannelUpdated","type":"event"},{"inputs":[{"components":[{"internalType":"enum ConduitItemType","name":"itemType","type":"uint8"},{"internalType":"address","name":"token","type":"address"},{"internalType":"address","name":"from","type":"address"},{"internalType":"address","name":"to","type":"address"},{"internalType":"uint256","name":"identifier","type":"uint256"},{"internalType":"uint256","name":"amount","type":"uint256"}],"internalType":"struct ConduitTransfer[]","name":"transfers","type":"tuple[]"}],"name":"execute","outputs":[{"internalType":"bytes4","name":"magicValue","type":"bytes4"}],"stateMutability":"nonpayable","type":"function"},{"inputs":[{"components":[{"internalType":"address","name":"token","type":"address"},{"internalType":"address","name":"from","type":"address"},{"internalType":"address","name":"to","type":"address"},{"internalType":"uint256[]","name":"ids","type":"uint256[]"},{"internalType":"uint256[]","name":"amounts","type":"uint256[]"}],"internalType":"struct ConduitBatch1155Transfer[]","name":"batchTransfers","type":"tuple[]"}],"name":"executeBatch1155","outputs":[{"internalType":"bytes4","name":"magicValue","type":"bytes4"}],"stateMutability":"nonpayable","type":"function"},{"inputs":[{"components":[{"internalType":"enum ConduitItemType","name":"itemType","type":"uint8"},{"internalType":"address","name":"token","type":"address"},{"internalType":"address","name":"from","type":"address"},{"internalType":"address","name":"to","type":"address"},{"internalType":"uint256","name":"identifier","type":"uint256"},{"internalType":"uint256","name":"amount","type":"uint256"}],"internalType":"struct ConduitTransfer[]","name":"standardTransfers","type":"tuple[]"},{"components":[{"internalType":"address","name":"token","type":"address"},{"internalType":"address","name":"from","type":"address"},{"internalType":"address","name":"to","type":"address"},{"internalType":"uint256[]","name":"ids","type":"uint256[]"},{"internalType":"uint256[]","name":"amounts","type":"uint256[]"}],"internalType":"struct ConduitBatch1155Transfer[]","name":"batchTransfers","type":"tuple[]"}],"name":"executeWithBatch1155","outputs":[{"internalType":"bytes4","name":"magicValue","type":"bytes4"}],"stateMutability":"nonpayable","type":"function"},{"inputs":[{"internalType":"address","name":"channel","type":"address"},{"internalType":"bool","name":"isOpen","type":"bool"}],"name":"updateChannel","outputs":[],"stateMutability":"nonpayable","type":"function"}]
Deployed Bytecode
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Deployed Bytecode Sourcemap
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Swarm Source
ipfs://c5c8d054d9d5df7c3530eab1c32506aad1fcb6772c1457f0da5443ad9e91b4a3
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Multichain Portfolio | 30 Chains
Chain | Token | Portfolio % | Price | Amount | Value |
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A contract address hosts a smart contract, which is a set of code stored on the blockchain that runs when predetermined conditions are met. Learn more about addresses in our Knowledge Base.