// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
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 ^0.8.7;
// 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 ^0.8.7;
/**
* @title ConduitControllerInterface
* @author 0age
* @notice ConduitControllerInterface contains all external function interfaces,
* structs, events, and errors for the conduit controller.
*/
interface ConduitControllerInterface {
/**
* @dev Track the conduit key, current owner, new potential owner, and open
* channels for each deployed conduit.
*/
struct ConduitProperties {
bytes32 key;
address owner;
address potentialOwner;
address[] channels;
mapping(address => uint256) channelIndexesPlusOne;
}
/**
* @dev Emit an event whenever a new conduit is created.
*
* @param conduit The newly created conduit.
* @param conduitKey The conduit key used to create the new conduit.
*/
event NewConduit(address conduit, bytes32 conduitKey);
/**
* @dev Emit an event whenever conduit ownership is transferred.
*
* @param conduit The conduit for which ownership has been
* transferred.
* @param previousOwner The previous owner of the conduit.
* @param newOwner The new owner of the conduit.
*/
event OwnershipTransferred(
address indexed conduit,
address indexed previousOwner,
address indexed newOwner
);
/**
* @dev Emit an event whenever a conduit owner registers a new potential
* owner for that conduit.
*
* @param newPotentialOwner The new potential owner of the conduit.
*/
event PotentialOwnerUpdated(address indexed newPotentialOwner);
/**
* @dev Revert with an error when attempting to create a new conduit using a
* conduit key where the first twenty bytes of the key do not match the
* address of the caller.
*/
error InvalidCreator();
/**
* @dev Revert with an error when attempting to create a new conduit when no
* initial owner address is supplied.
*/
error InvalidInitialOwner();
/**
* @dev Revert with an error when attempting to set a new potential owner
* that is already set.
*/
error NewPotentialOwnerAlreadySet(
address conduit,
address newPotentialOwner
);
/**
* @dev Revert with an error when attempting to cancel ownership transfer
* when no new potential owner is currently set.
*/
error NoPotentialOwnerCurrentlySet(address conduit);
/**
* @dev Revert with an error when attempting to interact with a conduit that
* does not yet exist.
*/
error NoConduit();
/**
* @dev Revert with an error when attempting to create a conduit that
* already exists.
*/
error ConduitAlreadyExists(address conduit);
/**
* @dev Revert with an error when attempting to update channels or transfer
* ownership of a conduit when the caller is not the owner of the
* conduit in question.
*/
error CallerIsNotOwner(address conduit);
/**
* @dev Revert with an error when attempting to register a new potential
* owner and supplying the null address.
*/
error NewPotentialOwnerIsZeroAddress(address conduit);
/**
* @dev Revert with an error when attempting to claim ownership of a conduit
* with a caller that is not the current potential owner for the
* conduit in question.
*/
error CallerIsNotNewPotentialOwner(address conduit);
/**
* @dev Revert with an error when attempting to retrieve a channel using an
* index that is out of range.
*/
error ChannelOutOfRange(address conduit);
/**
* @notice Deploy a new conduit using a supplied conduit key and assigning
* an initial owner for the deployed conduit. Note that the first
* twenty bytes of the supplied conduit key must match the caller
* and that a new conduit cannot be created if one has already been
* deployed using the same conduit key.
*
* @param conduitKey The conduit key used to deploy the conduit. Note that
* the first twenty bytes of the conduit key must match
* the caller of this contract.
* @param initialOwner The initial owner to set for the new conduit.
*
* @return conduit The address of the newly deployed conduit.
*/
function createConduit(bytes32 conduitKey, address initialOwner)
external
returns (address conduit);
/**
* @notice Open or close a channel on a given conduit, thereby allowing the
* specified account to execute transfers against that conduit.
* Extreme care must be taken when updating channels, as malicious
* or vulnerable channels can transfer any ERC20, ERC721 and ERC1155
* tokens where the token holder has granted the conduit approval.
* Only the owner of the conduit in question may call this function.
*
* @param conduit The conduit for which to open or close the channel.
* @param channel The channel to open or close on the conduit.
* @param isOpen A boolean indicating whether to open or close the channel.
*/
function updateChannel(
address conduit,
address channel,
bool isOpen
) external;
/**
* @notice Initiate conduit ownership transfer by assigning a new potential
* owner for the given conduit. Once set, the new potential owner
* may call `acceptOwnership` to claim ownership of the conduit.
* Only the owner of the conduit in question may call this function.
*
* @param conduit The conduit for which to initiate ownership transfer.
* @param newPotentialOwner The new potential owner of the conduit.
*/
function transferOwnership(address conduit, address newPotentialOwner)
external;
/**
* @notice Clear the currently set potential owner, if any, from a conduit.
* Only the owner of the conduit in question may call this function.
*
* @param conduit The conduit for which to cancel ownership transfer.
*/
function cancelOwnershipTransfer(address conduit) external;
/**
* @notice Accept ownership of a supplied conduit. Only accounts that the
* current owner has set as the new potential owner may call this
* function.
*
* @param conduit The conduit for which to accept ownership.
*/
function acceptOwnership(address conduit) external;
/**
* @notice Retrieve the current owner of a deployed conduit.
*
* @param conduit The conduit for which to retrieve the associated owner.
*
* @return owner The owner of the supplied conduit.
*/
function ownerOf(address conduit) external view returns (address owner);
/**
* @notice Retrieve the conduit key for a deployed conduit via reverse
* lookup.
*
* @param conduit The conduit for which to retrieve the associated conduit
* key.
*
* @return conduitKey The conduit key used to deploy the supplied conduit.
*/
function getKey(address conduit) external view returns (bytes32 conduitKey);
/**
* @notice Derive the conduit associated with a given conduit key and
* determine whether that conduit exists (i.e. whether it has been
* deployed).
*
* @param conduitKey The conduit key used to derive the conduit.
*
* @return conduit The derived address of the conduit.
* @return exists A boolean indicating whether the derived conduit has been
* deployed or not.
*/
function getConduit(bytes32 conduitKey)
external
view
returns (address conduit, bool exists);
/**
* @notice Retrieve the potential owner, if any, for a given conduit. The
* current owner may set a new potential owner via
* `transferOwnership` and that owner may then accept ownership of
* the conduit in question via `acceptOwnership`.
*
* @param conduit The conduit for which to retrieve the potential owner.
*
* @return potentialOwner The potential owner, if any, for the conduit.
*/
function getPotentialOwner(address conduit)
external
view
returns (address potentialOwner);
/**
* @notice Retrieve the status (either open or closed) of a given channel on
* a conduit.
*
* @param conduit The conduit for which to retrieve the channel status.
* @param channel The channel for which to retrieve the status.
*
* @return isOpen The status of the channel on the given conduit.
*/
function getChannelStatus(address conduit, address channel)
external
view
returns (bool isOpen);
/**
* @notice Retrieve the total number of open channels for a given conduit.
*
* @param conduit The conduit for which to retrieve the total channel count.
*
* @return totalChannels The total number of open channels for the conduit.
*/
function getTotalChannels(address conduit)
external
view
returns (uint256 totalChannels);
/**
* @notice Retrieve an open channel at a specific index for a given conduit.
* Note that the index of a channel can change as a result of other
* channels being closed on the conduit.
*
* @param conduit The conduit for which to retrieve the open channel.
* @param channelIndex The index of the channel in question.
*
* @return channel The open channel, if any, at the specified channel index.
*/
function getChannel(address conduit, uint256 channelIndex)
external
view
returns (address channel);
/**
* @notice Retrieve all open channels for a given conduit. Note that calling
* this function for a conduit with many channels will revert with
* an out-of-gas error.
*
* @param conduit The conduit for which to retrieve open channels.
*
* @return channels An array of open channels on the given conduit.
*/
function getChannels(address conduit)
external
view
returns (address[] memory channels);
/**
* @dev Retrieve the conduit creation code and runtime code hashes.
*/
function getConduitCodeHashes()
external
view
returns (bytes32 creationCodeHash, bytes32 runtimeCodeHash);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
enum ConduitItemType {
NATIVE, // unused
ERC20,
ERC721,
ERC1155
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
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 ^0.8.7;
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 ^0.8.7;
interface IERC721Receiver {
function onERC721Received(
address operator,
address from,
uint256 tokenId,
bytes calldata data
) external returns (bytes4);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
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 ^0.8.7;
/*
* -------------------------- 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 ^0.8.7;
/**
* @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();
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
import { IERC721Receiver } from "../interfaces/IERC721Receiver.sol";
import "./TransferHelperStructs.sol";
import { ConduitInterface } from "../interfaces/ConduitInterface.sol";
import {
ConduitControllerInterface
} from "../interfaces/ConduitControllerInterface.sol";
import { Conduit } from "../conduit/Conduit.sol";
import { ConduitTransfer } from "../conduit/lib/ConduitStructs.sol";
import {
TransferHelperInterface
} from "../interfaces/TransferHelperInterface.sol";
import { TransferHelperErrors } from "../interfaces/TransferHelperErrors.sol";
/**
* @title TransferHelper
* @author stephankmin, stuckinaboot, ryanio
* @notice TransferHelper is a utility contract for transferring
* ERC20/ERC721/ERC1155 items in bulk to specific recipients.
*/
contract TransferHelper is TransferHelperInterface, TransferHelperErrors {
// Allow for interaction with the conduit controller.
ConduitControllerInterface internal immutable _CONDUIT_CONTROLLER;
// Set conduit creation code and runtime code hashes as immutable arguments.
bytes32 internal immutable _CONDUIT_CREATION_CODE_HASH;
bytes32 internal immutable _CONDUIT_RUNTIME_CODE_HASH;
/**
* @dev Set the supplied conduit controller and retrieve its
* conduit creation code hash.
*
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(address conduitController) {
// Get the conduit creation code and runtime code hashes from the
// supplied conduit controller and set them as an immutable.
ConduitControllerInterface controller = ConduitControllerInterface(
conduitController
);
(_CONDUIT_CREATION_CODE_HASH, _CONDUIT_RUNTIME_CODE_HASH) = controller
.getConduitCodeHashes();
// Set the supplied conduit controller as an immutable.
_CONDUIT_CONTROLLER = controller;
}
/**
* @notice Transfer multiple ERC20/ERC721/ERC1155 items to
* specified recipients.
*
* @param items The items to transfer to an intended recipient.
* @param conduitKey An optional conduit key referring to a conduit through
* which the bulk transfer should occur.
*
* @return magicValue A value indicating that the transfers were successful.
*/
function bulkTransfer(
TransferHelperItemsWithRecipient[] calldata items,
bytes32 conduitKey
) external override returns (bytes4 magicValue) {
// Ensure that a conduit key has been supplied.
if (conduitKey == bytes32(0)) {
revert InvalidConduit(conduitKey, address(0));
}
// Use conduit derived from supplied conduit key to perform transfers.
_performTransfersWithConduit(items, conduitKey);
// Return a magic value indicating that the transfers were performed.
magicValue = this.bulkTransfer.selector;
}
/**
* @notice Perform multiple transfers to specified recipients via the
* conduit derived from the provided conduit key.
*
* @param transfers The items to transfer.
* @param conduitKey The conduit key referring to the conduit through
* which the bulk transfer should occur.
*/
function _performTransfersWithConduit(
TransferHelperItemsWithRecipient[] calldata transfers,
bytes32 conduitKey
) internal {
// Retrieve total number of transfers and place on stack.
uint256 numTransfers = transfers.length;
// Derive the conduit address from the deployer, conduit key
// and creation code hash.
address conduit = address(
uint160(
uint256(
keccak256(
abi.encodePacked(
bytes1(0xff),
address(_CONDUIT_CONTROLLER),
conduitKey,
_CONDUIT_CREATION_CODE_HASH
)
)
)
)
);
// Declare a variable to store the sum of all items across transfers.
uint256 sumOfItemsAcrossAllTransfers;
// Skip overflow checks: all for loops are indexed starting at zero.
unchecked {
// Iterate over each transfer.
for (uint256 i = 0; i < numTransfers; ++i) {
// Retrieve the transfer in question.
TransferHelperItemsWithRecipient calldata transfer = transfers[
i
];
// Increment totalItems by the number of items in the transfer.
sumOfItemsAcrossAllTransfers += transfer.items.length;
}
}
// Declare a new array in memory with length totalItems to populate with
// each conduit transfer.
ConduitTransfer[] memory conduitTransfers = new ConduitTransfer[](
sumOfItemsAcrossAllTransfers
);
// Declare an index for storing ConduitTransfers in conduitTransfers.
uint256 itemIndex;
// Skip overflow checks: all for loops are indexed starting at zero.
unchecked {
// Iterate over each transfer.
for (uint256 i = 0; i < numTransfers; ++i) {
// Retrieve the transfer in question.
TransferHelperItemsWithRecipient calldata transfer = transfers[
i
];
// Retrieve the items of the transfer in question.
TransferHelperItem[] calldata transferItems = transfer.items;
// Ensure recipient is not the zero address.
_checkRecipientIsNotZeroAddress(transfer.recipient);
// Create a boolean indicating whether validateERC721Receiver
// is true and recipient is a contract.
bool callERC721Receiver = transfer.validateERC721Receiver &&
transfer.recipient.code.length != 0;
// Retrieve the total number of items in the transfer and
// place on stack.
uint256 numItemsInTransfer = transferItems.length;
// Iterate over each item in the transfer to create a
// corresponding ConduitTransfer.
for (uint256 j = 0; j < numItemsInTransfer; ++j) {
// Retrieve the item from the transfer.
TransferHelperItem calldata item = transferItems[j];
if (item.itemType == ConduitItemType.ERC20) {
// Ensure that the identifier of an ERC20 token is 0.
if (item.identifier != 0) {
revert InvalidERC20Identifier();
}
}
// If the item is an ERC721 token and
// callERC721Receiver is true...
if (item.itemType == ConduitItemType.ERC721) {
if (callERC721Receiver) {
// Check if the recipient implements
// onERC721Received for the given tokenId.
_checkERC721Receiver(
conduit,
transfer.recipient,
item.identifier
);
}
}
// Create a ConduitTransfer corresponding to each
// TransferHelperItem.
conduitTransfers[itemIndex] = ConduitTransfer(
item.itemType,
item.token,
msg.sender,
transfer.recipient,
item.identifier,
item.amount
);
// Increment the index for storing ConduitTransfers.
++itemIndex;
}
}
}
// Attempt the external call to transfer tokens via the derived conduit.
try ConduitInterface(conduit).execute(conduitTransfers) returns (
bytes4 conduitMagicValue
) {
// Check if the value returned from the external call matches
// the conduit `execute` selector.
if (conduitMagicValue != ConduitInterface.execute.selector) {
// If the external call fails, revert with the conduit key
// and conduit address.
revert InvalidConduit(conduitKey, conduit);
}
} catch Error(string memory reason) {
// Catch reverts with a provided reason string and
// revert with the reason, conduit key and conduit address.
revert ConduitErrorRevertString(reason, conduitKey, conduit);
} catch (bytes memory data) {
// Conduits will throw a custom error when attempting to transfer
// native token item types or an ERC721 item amount other than 1.
// Bubble up these custom errors when encountered. Note that the
// conduit itself will bubble up revert reasons from transfers as
// well, meaning that these errors are not necessarily indicative of
// an issue with the item type or amount in cases where the same
// custom error signature is encountered during a conduit transfer.
// Set initial value of first four bytes of revert data to the mask.
bytes4 customErrorSelector = bytes4(0xffffffff);
// Utilize assembly to read first four bytes (if present) directly.
assembly {
// Combine original mask with first four bytes of revert data.
customErrorSelector := and(
mload(add(data, 0x20)), // Data begins after length offset.
customErrorSelector
)
}
// Pass through the custom error in question if the revert data is
// the correct length and matches an expected custom error selector.
if (
data.length == 4 &&
(customErrorSelector == InvalidItemType.selector ||
customErrorSelector == InvalidERC721TransferAmount.selector)
) {
// "Bubble up" the revert reason.
assembly {
revert(add(data, 0x20), 0x04)
}
}
// Catch all other reverts from the external call to the conduit and
// include the conduit's raw revert reason as a data argument to a
// new custom error.
revert ConduitErrorRevertBytes(data, conduitKey, conduit);
}
}
/**
* @notice An internal function to check if a recipient address implements
* onERC721Received for a given tokenId. Note that this check does
* not adhere to the safe transfer specification and is only meant
* to provide an additional layer of assurance that the recipient
* can receive the tokens — any hooks or post-transfer checks will
* fail and the caller will be the transfer helper rather than the
* ERC721 contract. Note that the conduit is set as the operator, as
* it will be the caller once the transfer is performed.
*
* @param conduit The conduit to provide as the operator when calling
* onERC721Received.
* @param recipient The ERC721 recipient on which to call onERC721Received.
* @param tokenId The ERC721 tokenId of the token being transferred.
*/
function _checkERC721Receiver(
address conduit,
address recipient,
uint256 tokenId
) internal {
// Check if recipient can receive ERC721 tokens.
try
IERC721Receiver(recipient).onERC721Received(
conduit,
msg.sender,
tokenId,
""
)
returns (bytes4 selector) {
// Check if onERC721Received selector is valid.
if (selector != IERC721Receiver.onERC721Received.selector) {
// Revert if recipient cannot accept
// ERC721 tokens.
revert InvalidERC721Recipient(recipient);
}
} catch (bytes memory data) {
// "Bubble up" recipient's revert reason.
revert ERC721ReceiverErrorRevertBytes(
data,
recipient,
msg.sender,
tokenId
);
} catch Error(string memory reason) {
// "Bubble up" recipient's revert reason.
revert ERC721ReceiverErrorRevertString(
reason,
recipient,
msg.sender,
tokenId
);
}
}
/**
* @notice An internal function that reverts if the passed-in recipient
* is the zero address.
*
* @param recipient The recipient on which to perform the check.
*/
function _checkRecipientIsNotZeroAddress(address recipient) internal pure {
// Revert if the recipient is the zero address.
if (recipient == address(0x0)) {
revert RecipientCannotBeZeroAddress();
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
/**
* @title TransferHelperErrors
*/
interface TransferHelperErrors {
/**
* @dev Revert with an error when attempting to execute transfers with a
* NATIVE itemType.
*/
error InvalidItemType();
/**
* @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 execute an ERC721 transfer
* to an invalid recipient.
*/
error InvalidERC721Recipient(address recipient);
/**
* @dev Revert with an error when a call to a ERC721 receiver reverts with
* bytes data.
*/
error ERC721ReceiverErrorRevertBytes(
bytes reason,
address receiver,
address sender,
uint256 identifier
);
/**
* @dev Revert with an error when a call to a ERC721 receiver reverts with
* string reason.
*/
error ERC721ReceiverErrorRevertString(
string reason,
address receiver,
address sender,
uint256 identifier
);
/**
* @dev Revert with an error when an ERC20 token has an invalid identifier.
*/
error InvalidERC20Identifier();
/**
* @dev Revert with an error if the recipient is the zero address.
*/
error RecipientCannotBeZeroAddress();
/**
* @dev Revert with an error when attempting to fill an order referencing an
* invalid conduit (i.e. one that has not been deployed).
*/
error InvalidConduit(bytes32 conduitKey, address conduit);
/**
* @dev Revert with an error when a call to a conduit reverts with a
* reason string.
*/
error ConduitErrorRevertString(
string reason,
bytes32 conduitKey,
address conduit
);
/**
* @dev Revert with an error when a call to a conduit reverts with bytes
* data.
*/
error ConduitErrorRevertBytes(
bytes reason,
bytes32 conduitKey,
address conduit
);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
import {
TransferHelperItem,
TransferHelperItemsWithRecipient
} from "../helpers/TransferHelperStructs.sol";
interface TransferHelperInterface {
/**
* @notice Transfer multiple items to a single recipient.
*
* @param items The items to transfer.
* @param conduitKey The key of the conduit performing the bulk transfer.
*/
function bulkTransfer(
TransferHelperItemsWithRecipient[] calldata items,
bytes32 conduitKey
) external returns (bytes4);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
import { ConduitItemType } from "../conduit/lib/ConduitEnums.sol";
/**
* @dev A TransferHelperItem specifies the itemType (ERC20/ERC721/ERC1155),
* token address, token identifier, and amount of the token to be
* transferred via the TransferHelper. For ERC20 tokens, identifier
* must be 0. For ERC721 tokens, amount must be 1.
*/
struct TransferHelperItem {
ConduitItemType itemType;
address token;
uint256 identifier;
uint256 amount;
}
/**
* @dev A TransferHelperItemsWithRecipient specifies the tokens to transfer
* via the TransferHelper, their intended recipient, and a boolean flag
* indicating whether onERC721Received should be called on a recipient
* contract.
*/
struct TransferHelperItemsWithRecipient {
TransferHelperItem[] items;
address recipient;
bool validateERC721Receiver;
}
{
"compilationTarget": {
"contracts/helpers/TransferHelper.sol": "TransferHelper"
},
"evmVersion": "london",
"libraries": {},
"metadata": {
"bytecodeHash": "ipfs"
},
"optimizer": {
"enabled": true,
"runs": 1000000
},
"remappings": [],
"viaIR": true
}[{"inputs":[{"internalType":"address","name":"conduitController","type":"address"}],"stateMutability":"nonpayable","type":"constructor"},{"inputs":[{"internalType":"bytes","name":"reason","type":"bytes"},{"internalType":"bytes32","name":"conduitKey","type":"bytes32"},{"internalType":"address","name":"conduit","type":"address"}],"name":"ConduitErrorRevertBytes","type":"error"},{"inputs":[{"internalType":"string","name":"reason","type":"string"},{"internalType":"bytes32","name":"conduitKey","type":"bytes32"},{"internalType":"address","name":"conduit","type":"address"}],"name":"ConduitErrorRevertString","type":"error"},{"inputs":[{"internalType":"bytes","name":"reason","type":"bytes"},{"internalType":"address","name":"receiver","type":"address"},{"internalType":"address","name":"sender","type":"address"},{"internalType":"uint256","name":"identifier","type":"uint256"}],"name":"ERC721ReceiverErrorRevertBytes","type":"error"},{"inputs":[{"internalType":"string","name":"reason","type":"string"},{"internalType":"address","name":"receiver","type":"address"},{"internalType":"address","name":"sender","type":"address"},{"internalType":"uint256","name":"identifier","type":"uint256"}],"name":"ERC721ReceiverErrorRevertString","type":"error"},{"inputs":[{"internalType":"bytes32","name":"conduitKey","type":"bytes32"},{"internalType":"address","name":"conduit","type":"address"}],"name":"InvalidConduit","type":"error"},{"inputs":[],"name":"InvalidERC20Identifier","type":"error"},{"inputs":[{"internalType":"address","name":"recipient","type":"address"}],"name":"InvalidERC721Recipient","type":"error"},{"inputs":[],"name":"InvalidERC721TransferAmount","type":"error"},{"inputs":[],"name":"InvalidItemType","type":"error"},{"inputs":[],"name":"RecipientCannotBeZeroAddress","type":"error"},{"inputs":[{"components":[{"components":[{"internalType":"enum ConduitItemType","name":"itemType","type":"uint8"},{"internalType":"address","name":"token","type":"address"},{"internalType":"uint256","name":"identifier","type":"uint256"},{"internalType":"uint256","name":"amount","type":"uint256"}],"internalType":"struct TransferHelperItem[]","name":"items","type":"tuple[]"},{"internalType":"address","name":"recipient","type":"address"},{"internalType":"bool","name":"validateERC721Receiver","type":"bool"}],"internalType":"struct TransferHelperItemsWithRecipient[]","name":"items","type":"tuple[]"},{"internalType":"bytes32","name":"conduitKey","type":"bytes32"}],"name":"bulkTransfer","outputs":[{"internalType":"bytes4","name":"magicValue","type":"bytes4"}],"stateMutability":"nonpayable","type":"function"}]