Description:
Multi-signature wallet contract requiring multiple confirmations for transaction execution.
Blockchain: Ethereum
Source Code: View Code On The Blockchain
Solidity Source Code:
{{
"language": "Solidity",
"sources": {
"src/ViewVestingClaim.sol": {
"content": "// SPDX-License-Identifier: UNLICENSED
pragma solidity ^0.8.13;
import {Claim} from "./Claim.sol";
import {IClaim} from "./IClaim.sol";
import {IVestingClaim} from "./IVestingClaim.sol";
import {MerkleProof} from "@openzeppelin/contracts/utils/cryptography/MerkleProof.sol";
// Errors
error InvalidProof(); // Invalid merkle proof provided
error UserNotEligible(); // User did not choose Vest option or has not claimed yet
/**
* @title ViewVestingClaim
* @notice View contract to calculate vesting amounts without requiring first claim transaction
* @dev This contract allows viewing of vesting data by providing merkle proof parameters
* and handles cases where users haven't made their first vesting claim yet.
*
* Handles four main cases:
* 1. Cliff ended, no first claim made - calculates based on merkle data
* 2. Some tokens claimed - uses existing VestingClaim view functions
* 3. User ineligible - didn't select vesting or hasn't claimed initially
* 4. Cliff not ended - returns 0 claimable amount
*/
contract ViewVestingClaim {
/* ------------- IMMUTABLES ------------- */
Claim public immutable claimContract;
IVestingClaim public immutable vestingContract;
/* ------------- CONSTRUCTOR ------------- */
/**
* @notice Initialize the ViewVestingClaim contract
* @param _claimContract The initial Claim contract address
* @param _vestingContract The VestingClaim contract address
*/
constructor(address _claimContract, address _vestingContract) {
require(_claimContract != address(0), "claimContract not set");
require(_vestingContract != address(0), "vestingContract not set");
claimContract = Claim(_claimContract);
vestingContract = IVestingClaim(_vestingContract);
}
/* ------------- VIEW FUNCTIONS ------------- */
/**
* @notice Calculate how much has vested for a user using merkle proof data
* @dev This function works even if the user hasn't made their first claim
* @param index The index in the merkle tree
* @param account The user address
* @param vestingAmount The total vesting amount for this user from merkle tree
* @param merkleProof The merkle proof to verify the vesting amount
* @return The amount that has vested so far
*/
function getVestedAmount(uint256 index, address account, uint256 vestingAmount, bytes32[] calldata merkleProof)
public
view
returns (uint256)
{
// Verify merkle proof
if (!_verifyMerkleProof(index, account, vestingAmount, merkleProof)) {
revert InvalidProof();
}
// Check if user is eligible (chose Vest option)
if (!_isUserEligible(account)) {
revert UserNotEligible();
}
// If user has already registered in VestingClaim, use that contract's logic
if (vestingContract.isRegistered(account)) {
return vestingContract.getVestedAmount(account);
}
// User hasn't registered yet, calculate based on merkle data
return _calculateVestedAmount(account, vestingAmount);
}
/**
* @notice Calculate how much a user can claim right now using merkle proof data
* @dev This function works even if the user hasn't made their first claim
* @param index The index in the merkle tree
* @param account The user address
* @param vestingAmount The total vesting amount for this user from merkle tree
* @param merkleProof The merkle proof to verify the vesting amount
* @return The claimable amount
*/
function getClaimableAmount(uint256 index, address account, uint256 vestingAmount, bytes32[] calldata merkleProof)
public
view
returns (uint256)
{
// Verify merkle proof
if (!_verifyMerkleProof(index, account, vestingAmount, merkleProof)) {
revert InvalidProof();
}
// Check if user is eligible (chose Vest option)
if (!_isUserEligible(account)) {
revert UserNotEligible();
}
// If user has already registered in VestingClaim, use that contract's logic
if (vestingContract.isRegistered(account)) {
return vestingContract.getClaimableAmount(account);
}
// User hasn't registered yet, calculate based on merkle data
uint256 vested = _calculateVestedAmount(account, vestingAmount);
uint256 alreadyClaimed = vestingContract.claimedVestingAmount(account);
return vested > alreadyClaimed ? vested - alreadyClaimed : 0;
}
/**
* @notice Get the timestamp when cliff period ends for a user
* @param account The user address
* @return The timestamp when cliff ends (0 if user hasn't claimed initially)
*/
function getCliffEnd(address account) public view returns (uint256) {
return vestingContract.getCliffEnd(account);
}
/**
* @notice Get the timestamp when vesting period ends for a user
* @param account The user address
* @return The timestamp when vesting ends (0 if user hasn't claimed initially)
*/
function getVestingEnd(address account) public view returns (uint256) {
return vestingContract.getVestingEnd(account);
}
/**
* @notice Check if a user is eligible for vesting (chose Vest option and made initial claim)
* @param account The user address
* @return True if user is eligible for vesting
*/
function isUserEligible(address account) public view returns (bool) {
return _isUserEligible(account);
}
/**
* @notice Check if a user has registered their vesting amount in the VestingClaim contract
* @param account The user address
* @return True if user has completed at least one vesting claim
*/
function isRegistered(address account) public view returns (bool) {
return vestingContract.isRegistered(account);
}
/* ------------- INTERNAL FUNCTIONS ------------- */
/**
* @dev Verify the merkle proof for vesting amount
* @param index The index in the merkle tree
* @param account The user address
* @param vestingAmount The total vesting amount for this user
* @param merkleProof The merkle proof to verify
* @return True if proof is valid
*/
function _verifyMerkleProof(uint256 index, address account, uint256 vestingAmount, bytes32[] calldata merkleProof)
internal
view
returns (bool)
{
bytes32 node = keccak256(abi.encodePacked(index, account, vestingAmount));
return MerkleProof.verify(merkleProof, vestingContract.merkleRoot(), node);
}
/**
* @dev Check if user is eligible for vesting
* @param account The user address
* @return True if user chose Vest option and made initial claim
*/
function _isUserEligible(address account) internal view returns (bool) {
// Check if user chose Vest option
IClaim.Option userOption = claimContract.claimedOptionMap(account);
if (userOption != IClaim.Option.Vest) {
return false;
}
// Check if user has made initial claim (has a claim timestamp)
uint256 claimTimestamp = claimContract.claimedTimestampMap(account);
return claimTimestamp > 0;
}
/**
* @dev Calculate vested amount using VestingClaim logic but with provided vesting amount
* @dev This replicates the _getVestedAmount logic from VestingClaim.sol
* @param account The user address
* @param totalVestingAmount The total amount that will vest for this user
* @return The amount that has vested so far
*/
function _calculateVestedAmount(address account, uint256 totalVestingAmount) internal view returns (uint256) {
uint256 claimTimestamp = claimContract.claimedTimestampMap(account);
if (claimTimestamp == 0) {
return 0; // User hasn't claimed yet
}
// Check if cliff period has ended
uint256 cliffEnd = claimTimestamp + vestingContract.CLIFF_DURATION();
if (block.timestamp < cliffEnd) {
return 0; // Still in cliff period
}
uint256 vestingEnd = cliffEnd + vestingContract.VESTING_DURATION();
// Calculate effective end time (minimum of vestingEnd and globalEndTime)
uint256 globalEndTime = vestingContract.globalEndTime();
uint256 effectiveEnd = globalEndTime > 0 && globalEndTime < vestingEnd ? globalEndTime : vestingEnd;
// If effective end is at/before cliff, nothing vests
if (effectiveEnd <= cliffEnd) {
return 0;
}
// Time used for vesting calculation is capped at effectiveEnd
uint256 timeForCalc = block.timestamp < effectiveEnd ? block.timestamp : effectiveEnd;
// If we've reached the normal vesting end (and global end allows it), return full amount
if (timeForCalc >= vestingEnd && effectiveEnd == vestingEnd) {
return totalVestingAmount;
}
// Linear vesting: calculate based on time elapsed since cliff
uint256 timeElapsed = timeForCalc - cliffEnd;
return (totalVestingAmount * timeElapsed) / vestingContract.VESTING_DURATION();
}
}
"
},
"src/Claim.sol": {
"content": "// SPDX-License-Identifier: UNLICENSED
pragma solidity ^0.8.13;
import {IClaim} from "./IClaim.sol";
import {IERC4626} from "@openzeppelin/contracts/interfaces/IERC4626.sol";
import {ReentrancyGuard} from "@openzeppelin/contracts/utils/ReentrancyGuard.sol";
import {IERC20} from "@openzeppelin/contracts/token/ERC20/IERC20.sol";
import {SafeERC20} from "@openzeppelin/contracts/token/ERC20/utils/SafeERC20.sol";
import {MerkleProof} from "@openzeppelin/contracts/utils/cryptography/MerkleProof.sol";
import {Ownable2Step} from "@openzeppelin/contracts/access/Ownable2Step.sol";
import {Ownable} from "@openzeppelin/contracts/access/Ownable.sol";
error AlreadyClaimed();
error InvalidProof();
error ClaimWindowNotStarted();
error ClaimWindowFinished();
error InvalidBeneficiaryCaller();
error InvalidOption();
error InvalidStakeAmount();
contract Claim is IClaim, Ownable2Step, ReentrancyGuard {
using SafeERC20 for IERC20;
address public immutable override token;
address public immutable override stakedToken;
bytes32 public override merkleRoot;
uint256 public startTime;
uint256 public endTime;
uint256 public vestMultiplier;
uint256 public noVestMultiplier;
uint256 public constant multiplierDenominator = 100;
mapping(uint256 => uint256) private claimedBitMap;
mapping(address => uint256) public claimedTimestampMap;
mapping(address => Option) public claimedOptionMap;
constructor(
address _owner,
address _token,
address _stakedToken,
bytes32 _merkleRoot,
uint256 _startTime,
uint256 _endTime,
uint256 _vestMultiplier,
uint256 _noVestMultiplier
) Ownable(_owner) {
require(_token != address(0), "token not set");
require(_stakedToken != address(0), "stakedToken not set");
require(_merkleRoot != bytes32(0), "merkleRoot not set");
require(_startTime < _endTime, "endTime must be after startTime");
require(_vestMultiplier >= 0 && _vestMultiplier <= multiplierDenominator, "vestMultiplier invalid");
require(_noVestMultiplier >= 0 && _noVestMultiplier <= multiplierDenominator, "noVestMultiplier invalid");
require(_vestMultiplier < _noVestMultiplier, "vestMultiplier must be less than noVestMultiplier");
token = _token;
stakedToken = _stakedToken;
merkleRoot = _merkleRoot;
startTime = _startTime;
endTime = _endTime;
vestMultiplier = _vestMultiplier;
noVestMultiplier = _noVestMultiplier;
}
function isClaimed(uint256 index) public view override returns (bool) {
uint256 claimedWordIndex = index / 256;
uint256 claimedBitIndex = index % 256;
uint256 claimedWord = claimedBitMap[claimedWordIndex];
uint256 mask = (1 << claimedBitIndex);
return claimedWord & mask == mask;
}
function claim(
uint256 index,
address account,
uint256 amount,
bytes32[] calldata merkleProof,
Option option,
uint256 stakeAmount
) public virtual override nonReentrant {
if (msg.sender != account) revert InvalidBeneficiaryCaller();
if (block.timestamp < startTime) revert ClaimWindowNotStarted();
if (block.timestamp > endTime) revert ClaimWindowFinished();
if (isClaimed(index)) revert AlreadyClaimed();
// Verify the merkle proof.
bytes32 node = keccak256(abi.encodePacked(index, account, amount));
if (!MerkleProof.verify(merkleProof, merkleRoot, node)) {
revert InvalidProof();
}
uint256 claimAmount = _getOptionMultiplier(option) * amount / multiplierDenominator;
uint256 vestAmount = option == Option.Vest ? amount - claimAmount : 0;
if (stakeAmount > claimAmount) revert InvalidStakeAmount();
claimAmount = claimAmount - stakeAmount;
// Mark it claimed and send the token.
_setClaimed(index);
_setClaimedMetadata(account, option);
if (claimAmount > 0) {
IERC20(token).safeTransfer(account, claimAmount);
}
if (stakeAmount > 0) {
IERC20(token).approve(address(stakedToken), stakeAmount);
IERC4626(stakedToken).deposit(stakeAmount, account);
}
emit Claimed(index, account, amount, claimAmount, stakeAmount, vestAmount, option);
}
function setMerkleRoot(bytes32 root) external onlyOwner {
merkleRoot = root;
}
function withdraw(uint256 amount) external onlyOwner {
IERC20(token).safeTransfer(owner(), amount);
}
function withdrawERC20(address targetToken, uint256 amount) external onlyOwner {
IERC20(targetToken).safeTransfer(owner(), amount);
}
function _setClaimed(uint256 index) private {
uint256 claimedWordIndex = index / 256;
uint256 claimedBitIndex = index % 256;
claimedBitMap[claimedWordIndex] = claimedBitMap[claimedWordIndex] | (1 << claimedBitIndex);
}
function _setClaimedMetadata(address account, Option option) private {
claimedOptionMap[account] = option;
claimedTimestampMap[account] = block.timestamp;
}
function _getOptionMultiplier(Option option) private view returns (uint256) {
return option == Option.Vest ? vestMultiplier : noVestMultiplier;
}
}
"
},
"src/IClaim.sol": {
"content": "// SPDX-License-Identifier: UNLICENSED
pragma solidity ^0.8.13;
// Allows anyone to claim a token if they exist in a merkle root.
interface IClaim {
// Enums for claim options
enum Option {
Vest,
NoVest
}
// Returns the address of the token distributed by this contract.
function token() external view returns (address);
// Returns the address of the staked token
function stakedToken() external view returns (address);
// Returns the merkle root of the merkle tree containing account balances available to claim.
function merkleRoot() external view returns (bytes32);
// Returns true if the index has been marked claimed.
function isClaimed(uint256 index) external view returns (bool);
// Claim the given amount of the token to the given address. Reverts if the inputs are invalid.
function claim(
uint256 index,
address account,
uint256 amount,
bytes32[] calldata merkleProof,
Option option,
uint256 stakeAmount
) external;
// This event is triggered whenever a call to #claim succeeds.
event Claimed(
uint256 index,
address indexed account,
uint256 amount,
uint256 claimAmount,
uint256 stakeAmount,
uint256 vestAmount,
Option option
);
}
"
},
"src/IVestingClaim.sol": {
"content": "// SPDX-License-Identifier: UNLICENSED
pragma solidity ^0.8.13;
// Interface for the VestingClaim contract
interface IVestingClaim {
// Events
event VestingClaimed(address indexed account, uint256 amount, uint256 timestamp);
event MerkleRootUpdated(bytes32 newRoot);
event GlobalEndTimeUpdated(uint256 newEndTime);
/**
* @notice Returns the address of the token being vested
*/
function token() external view returns (address);
/**
* @notice Returns the merkle root for vesting amounts
*/
function merkleRoot() external view returns (bytes32);
/**
* @notice Returns the cliff duration in seconds (30 days)
*/
function CLIFF_DURATION() external view returns (uint256);
/**
* @notice Returns the vesting duration in seconds (180 days)
*/
function VESTING_DURATION() external view returns (uint256);
/**
* @notice Returns the global end time for vesting (0 = no limit)
*/
function globalEndTime() external view returns (uint256);
/**
* @notice Returns the total vesting amount for a user (set after first claim)
* @param account The user address
* @return The total amount that will vest for this user
*/
function totalVestingAmount(address account) external view returns (uint256);
/**
* @notice Returns how much a user has already claimed from vesting
* @param account The user address
* @return The amount already claimed by the user
*/
function claimedVestingAmount(address account) external view returns (uint256);
/**
* @notice Returns whether a user has registered their vesting amount
* @param account The user address to check
* @return True if user has completed at least one vesting claim
*/
function isRegistered(address account) external view returns (bool);
/**
* @notice Get the timestamp when cliff period ends for a user
* @param account The user address
* @return The timestamp when cliff ends (0 if user hasn't claimed)
*/
function getCliffEnd(address account) external view returns (uint256);
/**
* @notice Get the timestamp when vesting period ends for a user
* @param account The user address
* @return The timestamp when vesting ends (0 if user hasn't claimed)
*/
function getVestingEnd(address account) external view returns (uint256);
/**
* @notice Calculate how much has vested for a user at current time
* @param account The user address
* @return The amount that has vested so far
*/
function getVestedAmount(address account) external view returns (uint256);
/**
* @notice Calculate how much a user can claim right now
* @param account The user address
* @return The claimable amount
*/
function getClaimableAmount(address account) external view returns (uint256);
/**
* @notice Claim vested tokens
* @param index The index in the merkle tree
* @param account The user address (must be msg.sender)
* @param vestingAmount The total vesting amount for this user
* @param merkleProof The merkle proof to verify the vesting amount
*/
function claimVesting(uint256 index, address account, uint256 vestingAmount, bytes32[] calldata merkleProof)
external;
/**
* @notice Update merkle root (owner only)
* @param newRoot The new merkle root
*/
function setMerkleRoot(bytes32 newRoot) external;
/**
* @notice Set or extend the global end time for vesting (owner only)
* @param newEndTime The new global end timestamp (0 = no limit)
*/
function setGlobalEndTime(uint256 newEndTime) external;
/**
* @notice Owner can withdraw any ERC20 tokens sent to this contract
* @param targetToken The token address to withdraw
* @param amount The amount to withdraw
*/
function withdrawERC20(address targetToken, uint256 amount) external;
}
"
},
"lib/openzeppelin-contracts/contracts/utils/cryptography/MerkleProof.sol": {
"content": "// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.1.0) (utils/cryptography/MerkleProof.sol)
// This file was procedurally generated from scripts/generate/templates/MerkleProof.js.
pragma solidity ^0.8.20;
import {Hashes} from "./Hashes.sol";
/**
* @dev These functions deal with verification of Merkle Tree proofs.
*
* The tree and the proofs can be generated using our
* https://github.com/OpenZeppelin/merkle-tree[JavaScript library].
* You will find a quickstart guide in the readme.
*
* WARNING: You should avoid using leaf values that are 64 bytes long prior to
* hashing, or use a hash function other than keccak256 for hashing leaves.
* This is because the concatenation of a sorted pair of internal nodes in
* the Merkle tree could be reinterpreted as a leaf value.
* OpenZeppelin's JavaScript library generates Merkle trees that are safe
* against this attack out of the box.
*
* IMPORTANT: Consider memory side-effects when using custom hashing functions
* that access memory in an unsafe way.
*
* NOTE: This library supports proof verification for merkle trees built using
* custom _commutative_ hashing functions (i.e. `H(a, b) == H(b, a)`). Proving
* leaf inclusion in trees built using non-commutative hashing functions requires
* additional logic that is not supported by this library.
*/
library MerkleProof {
/**
*@dev The multiproof provided is not valid.
*/
error MerkleProofInvalidMultiproof();
/**
* @dev Returns true if a `leaf` can be proved to be a part of a Merkle tree
* defined by `root`. For this, a `proof` must be provided, containing
* sibling hashes on the branch from the leaf to the root of the tree. Each
* pair of leaves and each pair of pre-images are assumed to be sorted.
*
* This version handles proofs in memory with the default hashing function.
*/
function verify(bytes32[] memory proof, bytes32 root, bytes32 leaf) internal pure returns (bool) {
return processProof(proof, leaf) == root;
}
/**
* @dev Returns the rebuilt hash obtained by traversing a Merkle tree up
* from `leaf` using `proof`. A `proof` is valid if and only if the rebuilt
* hash matches the root of the tree. When processing the proof, the pairs
* of leaves & pre-images are assumed to be sorted.
*
* This version handles proofs in memory with the default hashing function.
*/
function processProof(bytes32[] memory proof, bytes32 leaf) internal pure returns (bytes32) {
bytes32 computedHash = leaf;
for (uint256 i = 0; i < proof.length; i++) {
computedHash = Hashes.commutativeKeccak256(computedHash, proof[i]);
}
return computedHash;
}
/**
* @dev Returns true if a `leaf` can be proved to be a part of a Merkle tree
* defined by `root`. For this, a `proof` must be provided, containing
* sibling hashes on the branch from the leaf to the root of the tree. Each
* pair of leaves and each pair of pre-images are assumed to be sorted.
*
* This version handles proofs in memory with a custom hashing function.
*/
function verify(
bytes32[] memory proof,
bytes32 root,
bytes32 leaf,
function(bytes32, bytes32) view returns (bytes32) hasher
) internal view returns (bool) {
return processProof(proof, leaf, hasher) == root;
}
/**
* @dev Returns the rebuilt hash obtained by traversing a Merkle tree up
* from `leaf` using `proof`. A `proof` is valid if and only if the rebuilt
* hash matches the root of the tree. When processing the proof, the pairs
* of leaves & pre-images are assumed to be sorted.
*
* This version handles proofs in memory with a custom hashing function.
*/
function processProof(
bytes32[] memory proof,
bytes32 leaf,
function(bytes32, bytes32) view returns (bytes32) hasher
) internal view returns (bytes32) {
bytes32 computedHash = leaf;
for (uint256 i = 0; i < proof.length; i++) {
computedHash = hasher(computedHash, proof[i]);
}
return computedHash;
}
/**
* @dev Returns true if a `leaf` can be proved to be a part of a Merkle tree
* defined by `root`. For this, a `proof` must be provided, containing
* sibling hashes on the branch from the leaf to the root of the tree. Each
* pair of leaves and each pair of pre-images are assumed to be sorted.
*
* This version handles proofs in calldata with the default hashing function.
*/
function verifyCalldata(bytes32[] calldata proof, bytes32 root, bytes32 leaf) internal pure returns (bool) {
return processProofCalldata(proof, leaf) == root;
}
/**
* @dev Returns the rebuilt hash obtained by traversing a Merkle tree up
* from `leaf` using `proof`. A `proof` is valid if and only if the rebuilt
* hash matches the root of the tree. When processing the proof, the pairs
* of leaves & pre-images are assumed to be sorted.
*
* This version handles proofs in calldata with the default hashing function.
*/
function processProofCalldata(bytes32[] calldata proof, bytes32 leaf) internal pure returns (bytes32) {
bytes32 computedHash = leaf;
for (uint256 i = 0; i < proof.length; i++) {
computedHash = Hashes.commutativeKeccak256(computedHash, proof[i]);
}
return computedHash;
}
/**
* @dev Returns true if a `leaf` can be proved to be a part of a Merkle tree
* defined by `root`. For this, a `proof` must be provided, containing
* sibling hashes on the branch from the leaf to the root of the tree. Each
* pair of leaves and each pair of pre-images are assumed to be sorted.
*
* This version handles proofs in calldata with a custom hashing function.
*/
function verifyCalldata(
bytes32[] calldata proof,
bytes32 root,
bytes32 leaf,
function(bytes32, bytes32) view returns (bytes32) hasher
) internal view returns (bool) {
return processProofCalldata(proof, leaf, hasher) == root;
}
/**
* @dev Returns the rebuilt hash obtained by traversing a Merkle tree up
* from `leaf` using `proof`. A `proof` is valid if and only if the rebuilt
* hash matches the root of the tree. When processing the proof, the pairs
* of leaves & pre-images are assumed to be sorted.
*
* This version handles proofs in calldata with a custom hashing function.
*/
function processProofCalldata(
bytes32[] calldata proof,
bytes32 leaf,
function(bytes32, bytes32) view returns (bytes32) hasher
) internal view returns (bytes32) {
bytes32 computedHash = leaf;
for (uint256 i = 0; i < proof.length; i++) {
computedHash = hasher(computedHash, proof[i]);
}
return computedHash;
}
/**
* @dev Returns true if the `leaves` can be simultaneously proven to be a part of a Merkle tree defined by
* `root`, according to `proof` and `proofFlags` as described in {processMultiProof}.
*
* This version handles multiproofs in memory with the default hashing function.
*
* CAUTION: Not all Merkle trees admit multiproofs. See {processMultiProof} for details.
*
* NOTE: Consider the case where `root == proof[0] && leaves.length == 0` as it will return `true`.
* The `leaves` must be validated independently. See {processMultiProof}.
*/
function multiProofVerify(
bytes32[] memory proof,
bool[] memory proofFlags,
bytes32 root,
bytes32[] memory leaves
) internal pure returns (bool) {
return processMultiProof(proof, proofFlags, leaves) == root;
}
/**
* @dev Returns the root of a tree reconstructed from `leaves` and sibling nodes in `proof`. The reconstruction
* proceeds by incrementally reconstructing all inner nodes by combining a leaf/inner node with either another
* leaf/inner node or a proof sibling node, depending on whether each `proofFlags` item is true or false
* respectively.
*
* This version handles multiproofs in memory with the default hashing function.
*
* CAUTION: Not all Merkle trees admit multiproofs. To use multiproofs, it is sufficient to ensure that: 1) the tree
* is complete (but not necessarily perfect), 2) the leaves to be proven are in the opposite order they are in the
* tree (i.e., as seen from right to left starting at the deepest layer and continuing at the next layer).
*
* NOTE: The _empty set_ (i.e. the case where `proof.length == 1 && leaves.length == 0`) is considered a no-op,
* and therefore a valid multiproof (i.e. it returns `proof[0]`). Consider disallowing this case if you're not
* validating the leaves elsewhere.
*/
function processMultiProof(
bytes32[] memory proof,
bool[] memory proofFlags,
bytes32[] memory leaves
) internal pure returns (bytes32 merkleRoot) {
// This function rebuilds the root hash by traversing the tree up from the leaves. The root is rebuilt by
// consuming and producing values on a queue. The queue starts with the `leaves` array, then goes onto the
// `hashes` array. At the end of the process, the last hash in the `hashes` array should contain the root of
// the Merkle tree.
uint256 leavesLen = leaves.length;
uint256 proofFlagsLen = proofFlags.length;
// Check proof validity.
if (leavesLen + proof.length != proofFlagsLen + 1) {
revert MerkleProofInvalidMultiproof();
}
// The xxxPos values are "pointers" to the next value to consume in each array. All accesses are done using
// `xxx[xxxPos++]`, which return the current value and increment the pointer, thus mimicking a queue's "pop".
bytes32[] memory hashes = new bytes32[](proofFlagsLen);
uint256 leafPos = 0;
uint256 hashPos = 0;
uint256 proofPos = 0;
// At each step, we compute the next hash using two values:
// - a value from the "main queue". If not all leaves have been consumed, we get the next leaf, otherwise we
// get the next hash.
// - depending on the flag, either another value from the "main queue" (merging branches) or an element from the
// `proof` array.
for (uint256 i = 0; i < proofFlagsLen; i++) {
bytes32 a = leafPos < leavesLen ? leaves[leafPos++] : hashes[hashPos++];
bytes32 b = proofFlags[i]
? (leafPos < leavesLen ? leaves[leafPos++] : hashes[hashPos++])
: proof[proofPos++];
hashes[i] = Hashes.commutativeKeccak256(a, b);
}
if (proofFlagsLen > 0) {
if (proofPos != proof.length) {
revert MerkleProofInvalidMultiproof();
}
unchecked {
return hashes[proofFlagsLen - 1];
}
} else if (leavesLen > 0) {
return leaves[0];
} else {
return proof[0];
}
}
/**
* @dev Returns true if the `leaves` can be simultaneously proven to be a part of a Merkle tree defined by
* `root`, according to `proof` and `proofFlags` as described in {processMultiProof}.
*
* This version handles multiproofs in memory with a custom hashing function.
*
* CAUTION: Not all Merkle trees admit multiproofs. See {processMultiProof} for details.
*
* NOTE: Consider the case where `root == proof[0] && leaves.length == 0` as it will return `true`.
* The `leaves` must be validated independently. See {processMultiProof}.
*/
function multiProofVerify(
bytes32[] memory proof,
bool[] memory proofFlags,
bytes32 root,
bytes32[] memory leaves,
function(bytes32, bytes32) view returns (bytes32) hasher
) internal view returns (bool) {
return processMultiProof(proof, proofFlags, leaves, hasher) == root;
}
/**
* @dev Returns the root of a tree reconstructed from `leaves` and sibling nodes in `proof`. The reconstruction
* proceeds by incrementally reconstructing all inner nodes by combining a leaf/inner node with either another
* leaf/inner node or a proof sibling node, depending on whether each `proofFlags` item is true or false
* respectively.
*
* This version handles multiproofs in memory with a custom hashing function.
*
* CAUTION: Not all Merkle trees admit multiproofs. To use multiproofs, it is sufficient to ensure that: 1) the tree
* is complete (but not necessarily perfect), 2) the leaves to be proven are in the opposite order they are in the
* tree (i.e., as seen from right to left starting at the deepest layer and continuing at the next layer).
*
* NOTE: The _empty set_ (i.e. the case where `proof.length == 1 && leaves.length == 0`) is considered a no-op,
* and therefore a valid multiproof (i.e. it returns `proof[0]`). Consider disallowing this case if you're not
* validating the leaves elsewhere.
*/
function processMultiProof(
bytes32[] memory proof,
bool[] memory proofFlags,
bytes32[] memory leaves,
function(bytes32, bytes32) view returns (bytes32) hasher
) internal view returns (bytes32 merkleRoot) {
// This function rebuilds the root hash by traversing the tree up from the leaves. The root is rebuilt by
// consuming and producing values on a queue. The queue starts with the `leaves` array, then goes onto the
// `hashes` array. At the end of the process, the last hash in the `hashes` array should contain the root of
// the Merkle tree.
uint256 leavesLen = leaves.length;
uint256 proofFlagsLen = proofFlags.length;
// Check proof validity.
if (leavesLen + proof.length != proofFlagsLen + 1) {
revert MerkleProofInvalidMultiproof();
}
// The xxxPos values are "pointers" to the next value to consume in each array. All accesses are done using
// `xxx[xxxPos++]`, which return the current value and increment the pointer, thus mimicking a queue's "pop".
bytes32[] memory hashes = new bytes32[](proofFlagsLen);
uint256 leafPos = 0;
uint256 hashPos = 0;
uint256 proofPos = 0;
// At each step, we compute the next hash using two values:
// - a value from the "main queue". If not all leaves have been consumed, we get the next leaf, otherwise we
// get the next hash.
// - depending on the flag, either another value from the "main queue" (merging branches) or an element from the
// `proof` array.
for (uint256 i = 0; i < proofFlagsLen; i++) {
bytes32 a = leafPos < leavesLen ? leaves[leafPos++] : hashes[hashPos++];
bytes32 b = proofFlags[i]
? (leafPos < leavesLen ? leaves[leafPos++] : hashes[hashPos++])
: proof[proofPos++];
hashes[i] = hasher(a, b);
}
if (proofFlagsLen > 0) {
if (proofPos != proof.length) {
revert MerkleProofInvalidMultiproof();
}
unchecked {
return hashes[proofFlagsLen - 1];
}
} else if (leavesLen > 0) {
return leaves[0];
} else {
return proof[0];
}
}
/**
* @dev Returns true if the `leaves` can be simultaneously proven to be a part of a Merkle tree defined by
* `root`, according to `proof` and `proofFlags` as described in {processMultiProof}.
*
* This version handles multiproofs in calldata with the default hashing function.
*
* CAUTION: Not all Merkle trees admit multiproofs. See {processMultiProof} for details.
*
* NOTE: Consider the case where `root == proof[0] && leaves.length == 0` as it will return `true`.
* The `leaves` must be validated independently. See {processMultiProofCalldata}.
*/
function multiProofVerifyCalldata(
bytes32[] calldata proof,
bool[] calldata proofFlags,
bytes32 root,
bytes32[] memory leaves
) internal pure returns (bool) {
return processMultiProofCalldata(proof, proofFlags, leaves) == root;
}
/**
* @dev Returns the root of a tree reconstructed from `leaves` and sibling nodes in `proof`. The reconstruction
* proceeds by incrementally reconstructing all inner nodes by combining a leaf/inner node with either another
* leaf/inner node or a proof sibling node, depending on whether each `proofFlags` item is true or false
* respectively.
*
* This version handles multiproofs in calldata with the default hashing function.
*
* CAUTION: Not all Merkle trees admit multiproofs. To use multiproofs, it is sufficient to ensure that: 1) the tree
* is complete (but not necessarily perfect), 2) the leaves to be proven are in the opposite order they are in the
* tree (i.e., as seen from right to left starting at the deepest layer and continuing at the next layer).
*
* NOTE: The _empty set_ (i.e. the case where `proof.length == 1 && leaves.length == 0`) is considered a no-op,
* and therefore a valid multiproof (i.e. it returns `proof[0]`). Consider disallowing this case if you're not
* validating the leaves elsewhere.
*/
function processMultiProofCalldata(
bytes32[] calldata proof,
bool[] calldata proofFlags,
bytes32[] memory leaves
) internal pure returns (bytes32 merkleRoot) {
// This function rebuilds the root hash by traversing the tree up from the leaves. The root is rebuilt by
// consuming and producing values on a queue. The queue starts with the `leaves` array, then goes onto the
// `hashes` array. At the end of the process, the last hash in the `hashes` array should contain the root of
// the Merkle tree.
uint256 leavesLen = leaves.length;
uint256 proofFlagsLen = proofFlags.length;
// Check proof validity.
if (leavesLen + proof.length != proofFlagsLen + 1) {
revert MerkleProofInvalidMultiproof();
}
// The xxxPos values are "pointers" to the next value to consume in each array. All accesses are done using
// `xxx[xxxPos++]`, which return the current value and increment the pointer, thus mimicking a queue's "pop".
bytes32[] memory hashes = new bytes32[](proofFlagsLen);
uint256 leafPos = 0;
uint256 hashPos = 0;
uint256 proofPos = 0;
// At each step, we compute the next hash using two values:
// - a value from the "main queue". If not all leaves have been consumed, we get the next leaf, otherwise we
// get the next hash.
// - depending on the flag, either another value from the "main queue" (merging branches) or an element from the
// `proof` array.
for (uint256 i = 0; i < proofFlagsLen; i++) {
bytes32 a = leafPos < leavesLen ? leaves[leafPos++] : hashes[hashPos++];
bytes32 b = proofFlags[i]
? (leafPos < leavesLen ? leaves[leafPos++] : hashes[hashPos++])
: proof[proofPos++];
hashes[i] = Hashes.commutativeKeccak256(a, b);
}
if (proofFlagsLen > 0) {
if (proofPos != proof.length) {
revert MerkleProofInvalidMultiproof();
}
unchecked {
return hashes[proofFlagsLen - 1];
}
} else if (leavesLen > 0) {
return leaves[0];
} else {
return proof[0];
}
}
/**
* @dev Returns true if the `leaves` can be simultaneously proven to be a part of a Merkle tree defined by
* `root`, according to `proof` and `proofFlags` as described in {processMultiProof}.
*
* This version handles multiproofs in calldata with a custom hashing function.
*
* CAUTION: Not all Merkle trees admit multiproofs. See {processMultiProof} for details.
*
* NOTE: Consider the case where `root == proof[0] && leaves.length == 0` as it will return `true`.
* The `leaves` must be validated independently. See {processMultiProofCalldata}.
*/
function multiProofVerifyCalldata(
bytes32[] calldata proof,
bool[] calldata proofFlags,
bytes32 root,
bytes32[] memory leaves,
function(bytes32, bytes32) view returns (bytes32) hasher
) internal view returns (bool) {
return processMultiProofCalldata(proof, proofFlags, leaves, hasher) == root;
}
/**
* @dev Returns the root of a tree reconstructed from `leaves` and sibling nodes in `proof`. The reconstruction
* proceeds by incrementally reconstructing all inner nodes by combining a leaf/inner node with either another
* leaf/inner node or a proof sibling node, depending on whether each `proofFlags` item is true or false
* respectively.
*
* This version handles multiproofs in calldata with a custom hashing function.
*
* CAUTION: Not all Merkle trees admit multiproofs. To use multiproofs, it is sufficient to ensure that: 1) the tree
* is complete (but not necessarily perfect), 2) the leaves to be proven are in the opposite order they are in the
* tree (i.e., as seen from right to left starting at the deepest layer and continuing at the next layer).
*
* NOTE: The _empty set_ (i.e. the case where `proof.length == 1 && leaves.length == 0`) is considered a no-op,
* and therefore a valid multiproof (i.e. it returns `proof[0]`). Consider disallowing this case if you're not
* validating the leaves elsewhere.
*/
function processMultiProofCalldata(
bytes32[] calldata proof,
bool[] calldata proofFlags,
bytes32[] memory leaves,
function(bytes32, bytes32) view returns (bytes32) hasher
) internal view returns (bytes32 merkleRoot) {
// This function rebuilds the root hash by traversing the tree up from the leaves. The root is rebuilt by
// consuming and producing values on a queue. The queue starts with the `leaves` array, then goes onto the
// `hashes` array. At the end of the process, the last hash in the `hashes` array should contain the root of
// the Merkle tree.
uint256 leavesLen = leaves.length;
uint256 proofFlagsLen = proofFlags.length;
// Check proof validity.
if (leavesLen + proof.length != proofFlagsLen + 1) {
revert MerkleProofInvalidMultiproof();
}
// The xxxPos values are "pointers" to the next value to consume in each array. All accesses are done using
// `xxx[xxxPos++]`, which return the current value and increment the pointer, thus mimicking a queue's "pop".
bytes32[] memory hashes = new bytes32[](proofFlagsLen);
uint256 leafPos = 0;
uint256 hashPos = 0;
uint256 proofPos = 0;
// At each step, we compute the next hash using two values:
// - a value from the "main queue". If not all leaves have been consumed, we get the next leaf, otherwise we
// get the next hash.
// - depending on the flag, either another value from the "main queue" (merging branches) or an element from the
// `proof` array.
for (uint256 i = 0; i < proofFlagsLen; i++) {
bytes32 a = leafPos < leavesLen ? leaves[leafPos++] : hashes[hashPos++];
bytes32 b = proofFlags[i]
? (leafPos < leavesLen ? leaves[leafPos++] : hashes[hashPos++])
: proof[proofPos++];
hashes[i] = hasher(a, b);
}
if (proofFlagsLen > 0) {
if (proofPos != proof.length) {
revert MerkleProofInvalidMultiproof();
}
unchecked {
return hashes[proofFlagsLen - 1];
}
} else if (leavesLen > 0) {
return leaves[0];
} else {
return proof[0];
}
}
}
"
},
"lib/openzeppelin-contracts/contracts/interfaces/IERC4626.sol": {
"content": "// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.4.0) (interfaces/IERC4626.sol)
pragma solidity >=0.6.2;
import {IERC20} from "../token/ERC20/IERC20.sol";
import {IERC20Metadata} from "../token/ERC20/extensions/IERC20Metadata.sol";
/**
* @dev Interface of the ERC-4626 "Tokenized Vault Standard", as defined in
* https://eips.ethereum.org/EIPS/eip-4626[ERC-4626].
*/
interface IERC4626 is IERC20, IERC20Metadata {
event Deposit(address indexed sender, address indexed owner, uint256 assets, uint256 shares);
event Withdraw(
address indexed sender,
address indexed receiver,
address indexed owner,
uint256 assets,
uint256 shares
);
/**
* @dev Returns the address of the underlying token used for the Vault for accounting, depositing, and withdrawing.
*
* - MUST be an ERC-20 token contract.
* - MUST NOT revert.
*/
function asset() external view returns (address assetTokenAddress);
/**
* @dev Returns the total amount of the underlying asset that is “managed” by Vault.
*
* - SHOULD include any compounding that occurs from yield.
* - MUST be inclusive of any fees that are charged against assets in the Vault.
* - MUST NOT revert.
*/
function totalAssets() external view returns (uint256 totalManagedAssets);
/**
* @dev Returns the amount of shares that the Vault would exchange for the amount of assets provided, in an ideal
* scenario where all the conditions are met.
*
* - MUST NOT be inclusive of any fees that are charged against assets in the Vault.
* - MUST NOT show any variations depending on the caller.
* - MUST NOT reflect slippage or other on-chain conditions, when performing the actual exchange.
* - MUST NOT revert.
*
* NOTE: This calculation MAY NOT reflect the “per-user” price-per-share, and instead should reflect the
* “average-user’s” price-per-share, meaning what the average user should expect to see when exchanging to and
* from.
*/
function convertToShares(uint256 assets) external view returns (uint256 shares);
/**
* @dev Returns the amount of assets that the Vault would exchange for the amount of shares provided, in an ideal
* scenario where all the conditions are met.
*
* - MUST NOT be inclusive of any fees that are charged against assets in the Vault.
* - MUST NOT show any variations depending on the caller.
* - MUST NOT reflect slippage or other on-chain conditions, when performing the actual exchange.
* - MUST NOT revert.
*
* NOTE: This calculation MAY NOT reflect the “per-user” price-per-share, and instead should reflect the
* “average-user’s” price-per-share, meaning what the average user should expect to see when exchanging to and
* from.
*/
function convertToAssets(uint256 shares) external view returns (uint256 assets);
/**
* @dev Returns the maximum amount of the underlying asset that can be deposited into the Vault for the receiver,
* through a deposit call.
*
* - MUST return a limited value if receiver is subject to some deposit limit.
* - MUST return 2 ** 256 - 1 if there is no limit on the maximum amount of assets that may be deposited.
* - MUST NOT revert.
*/
function maxDeposit(address receiver) external view returns (uint256 maxAssets);
/**
* @dev Allows an on-chain or off-chain user to simulate the effects of their deposit at the current block, given
* current on-chain conditions.
*
* - MUST return as close to and no more than the exact amount of Vault shares that would be minted in a deposit
* call in the same transaction. I.e. deposit should return the same or more shares as previewDeposit if called
* in the same transaction.
* - MUST NOT account for deposit limits like those returned from maxDeposit and should always act as though the
* deposit would be accepted, regardless if the user has enough tokens approved, etc.
* - MUST be inclusive of deposit fees. Integrators should be aware of the existence of deposit fees.
* - MUST NOT revert.
*
* NOTE: any unfavorable discrepancy between convertToShares and previewDeposit SHOULD be considered slippage in
* share price or some other type of condition, meaning the depositor will lose assets by depositing.
*/
function previewDeposit(uint256 assets) external view returns (uint256 shares);
/**
* @dev Mints shares Vault shares to receiver by depositing exactly amount of underlying tokens.
*
* - MUST emit the Deposit event.
* - MAY support an additional flow in which the underlying tokens are owned by the Vault contract before the
* deposit execution, and are accounted for during deposit.
* - MUST revert if all of assets cannot be deposited (due to deposit limit being reached, slippage, the user not
* approving enough underlying tokens to the Vault contract, etc).
*
* NOTE: most implementations will require pre-approval of the Vault with the Vault’s underlying asset token.
*/
function deposit(uint256 assets, address receiver) external returns (uint256 shares);
/**
* @dev Returns the maximum amount of the Vault shares that can be minted for the receiver, through a mint call.
* - MUST return a limited value if receiver is subject to some mint limit.
* - MUST return 2 ** 256 - 1 if there is no limit on the maximum amount of shares that may be minted.
* - MUST NOT revert.
*/
function maxMint(address receiver) external view returns (uint256 maxShares);
/**
* @dev Allows an on-chain or off-chain user to simulate the effects of their mint at the current block, given
* current on-chain conditions.
*
* - MUST return as close to and no fewer than the exact amount of assets that would be deposited in a mint call
* in the same transaction. I.e. mint should return the same or fewer assets as previewMint if called in the
* same transaction.
* - MUST NOT account for mint limits like those returned from maxMint and should always act as though the mint
* would be accepted, regardless if the user has enough tokens approved, etc.
* - MUST be inclusive of deposit fees. Integrators should be aware of the existence of deposit fees.
* - MUST NOT revert.
*
* NOTE: any unfavorable discrepancy between convertToAssets and previewMint SHOULD be considered slippage in
* share price or some other type of condition, meaning the depositor will lose assets by minting.
*/
function previewMint(uint256 shares) external view returns (uint256 assets);
/**
* @dev Mints exactly shares Vault shares to receiver by depositing amount of underlying tokens.
*
* - MUST emit the Deposit event.
* - MAY support an additional flow in which the underlying tokens are owned by the Vault contract before the mint
* execution, and are accounted for during mint.
* - MUST revert if all of shares cannot be minted (due to deposit limit being reached, slippage, the user not
* approving enough underlying tokens to the Vault contract, etc).
*
* NOTE: most implementations will require pre-approval of the Vault with the Vault’s underlying asset token.
*/
function mint(uint256 shares, address receiver) external returns (uint256 assets);
/**
* @dev Returns the maximum amount of the underlying asset that can be withdrawn from the owner balance in the
* Vault, through a withdraw call.
*
* - MUST return a limited value if owner is subject to some withdrawal limit or timelock.
* - MUST NOT revert.
*/
function maxWithdraw(address owner) external view returns (uint256 maxAssets);
/**
* @dev Allows an on-chain or off-chain user to simulate the effects of their withdrawal at the current block,
* given current on-chain conditions.
*
* - MUST return as close to and no fewer than the exact amount of Vault shares that would be burned in a withdraw
* call in the same transaction. I.e. withdraw should return the same or fewer shares as previewWithdraw if
* called
* in the same transaction.
* - MUST NOT account for withdrawal limits like those returned from maxWithdraw and should always act as though
* the withdrawal would be accepted, regardless if the user has enough shares, etc.
* - MUST be inclusive of withdrawal fees. Integrators should be aware of the existence of withdrawal fees.
* - MUST NOT revert.
*
* NOTE: any unfavorable discrepancy between convertToShares and previewWithdraw SHOULD be considered slippage in
* share price or some other type of condition, meaning the depositor will lose assets by depositing.
*/
function previewWithdraw(uint256 assets) external view returns (uint256 shares);
/**
* @dev Burns shares from owner and sends exactly assets of underlying tokens to receiver.
*
* - MUST emit the Withdraw event.
* - MAY support an additional flow in which the underlying tokens are owned by the Vault contract before the
* withdraw execution, and are accounted for during withdraw.
* - MUST revert if all of assets cannot be withdrawn (due to withdrawal limit being reached, slippage, the owner
* not having enough shares, etc).
*
* Note that some implementations will require pre-requesting to the Vault before a withdrawal may be performed.
* Those methods should be performed separately.
*/
function withdraw(uint256 assets, address receiver, address owner) external returns (uint256 shares);
/**
* @dev Returns the maximum amount of Vault shares that can be redeemed from the owner balance in the Vault,
* through a redeem call.
*
* - MUST return a limited value if owner is subject to some withdrawal limit or timelock.
* - MUST return balanceOf(owner) if owner is not subject to any withdrawal limit or timelock.
* - MUST NOT revert.
*/
function maxRedeem(address owner) external view returns (uint256 maxShares);
/**
* @dev Allows an on-chain or off-chain user to simulate the effects of their redemption at the current block,
* given current on-chain conditions.
*
* - MUST return as close to and no more than the exact amount of assets that would be withdrawn in a redeem call
* in the same transaction. I.e. redeem should return the same or more assets as previewRedeem if called in the
* same transaction.
* - MUST NOT account for redemption limits like those returned from maxRedeem and should always act as though the
* redemption would be accepted, regardless if the user has enough shares, etc.
* - MUST be inclusive of withdrawal fees. Integrators should be aware of the existence of withdrawal fees.
* - MUST NOT revert.
*
* NOTE: any unfavorable discrepancy between convertToAssets and previewRedeem SHOULD be considered slippage in
* share price or some other type of condition, meaning the depositor will lose assets by redeeming.
*/
function previewRedeem(uint256 shares) external view returns (uint256 assets);
/**
* @dev Burns exactly shares from owner and sends assets of underlying tokens to receiver.
*
* - MUST emit the Withdraw event.
* - MAY support an additional flow in which the underlying tokens are owned by the Vault contract before the
* redeem execution, and are accounted for during redeem.
* - MUST revert if all of shares cannot be redeemed (due to withdrawal limit being reached, slippage, the owner
* not having enough shares, etc).
*
* NOTE: some implementations will require pre-requesting to the Vault before a withdrawal may be performed.
* Those methods should be performed separately.
*/
function redeem(uint256 shares, address receiver, address owner) external returns (uint256 assets);
}
"
},
"lib/openzeppelin-contracts/contracts/utils/ReentrancyGuard.sol": {
"content": "// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.1.0) (utils/ReentrancyGuard.sol)
pragma solidity ^0.8.20;
/**
* @dev Contract module that helps prevent reentrant calls to a function.
*
* Inheriting from `ReentrancyGuard` will make the {nonReentrant} modifier
* available, which can be applied to functions to make sure there are no nested
* (reentrant) calls to them.
*
* Note that because there is a single `nonReentrant` guard, functions marked as
* `nonReentrant` may not call one another. This can be worked around by making
* those functions `private`, and then adding `external` `nonReentrant` entry
* points to them.
*
* TIP: If EIP-1153 (transient storage) is available on the chain you're deploying at,
* consider using {ReentrancyGuardTransient} instead.
*
* TIP: If you would like to learn more about reentrancy and alternative ways
* to protect against it, check out our blog post
* https://blog.openzeppelin.com/reentrancy-after-istanbul/[Reentrancy After Istanbul].
*/
abstract contract ReentrancyGuard {
// Booleans are more expensive than uint256 or any type that takes up a full
// word because each write operation emits an extra SLOAD to first read the
// slot's contents, replace the bits taken up by the boolean, and then write
// back. This is the compiler's defense against contract upgrades and
// pointer aliasing, and it cannot be disabled.
// The values being non-zero value makes deployment a bit more expensive,
// but in exchange the refund on every call to nonReentrant will be lower in
// amount. Since refunds are capped to a percentage of the total
// transaction's gas, it is best to keep them low in cases like this one, to
// increase the likelihood of the full refund coming into effect.
uint256 private constant NOT_ENTERED = 1;
uint256 private constant ENTERED = 2;
uint256 private _status;
/**
* @dev Unauthorized reentrant call.
*/
error ReentrancyGuardReentrantCall();
constructor() {
_status = NOT_ENTERED;
}
/**
* @dev Prevents a contract from calling itself, directly or indirectly.
* Calling a `nonReentrant` function from another `nonReentrant`
* function is not supported. It is possible to prevent this from happening
* by making the `nonReentrant` function external, and making it call a
* `private` function that does the actual work.
*/
modifier nonReentrant() {
_nonReentrantBefore();
_;
_nonReentrantAfter();
}
function _nonReentrantBefore() private {
// On the first call to nonReentrant, _status will be NOT_ENTERED
if (_status == ENTERED) {
revert ReentrancyGuardReentrantCall();
}
// Any calls to nonReentrant after this point will fail
_status = ENTERED;
}
function _nonReentrantAfter() private {
// By storing the original value once again, a refund is triggered (see
// https://eips.ethereum.org/EIPS/eip-2200)
_status = NOT_ENTERED;
}
/**
* @dev Returns true if the reentrancy guard is currently set to "entered", which indicates there is a
* `nonReentrant` function in the call stack.
*/
function _reentrancyGuardEntered() internal view returns (bool) {
return _status == ENTERED;
}
}
"
},
"lib/openzeppelin-contracts/contracts/token/ERC20/IERC20.sol": {
"content": "// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.4.0) (token/ERC20/IERC20.sol)
pragma solidity >=0.4.16;
/**
* @dev Interface of the ERC-20 standard as defined in the ERC.
*/
interface IERC20 {
/**
* @dev Emitted when `value` tokens are moved from one account (`from`) to
* another (`to`).
*
* Note that `value` may be zero.
*/
event Transfer(address indexed from, address indexed to, uint256 value);
/**
* @dev Emitted when the allowance of a `spender` for an `owner` is set by
* a call to {approve}. `value` is the new allowance.
*/
event Approval(address indexed owner, address indexed spender, uint256 value);
/**
* @dev Returns the value of tokens in existence.
*/
function totalSupply() external view returns (uint256);
/**
* @dev Returns the value of tokens owned by `account`.
*/
function balanceOf(address account) external view returns (uint256);
/**
* @dev Moves a `value` amount of tokens from the caller's account to `to`.
*
* Returns a boolean value indicating whether the operation succeeded.
*
* Emits a {Transfer} event.
*/
function transfer(address to, uint256 value) external returns (bool);
/**
* @dev Returns the remaining number of tokens that `spender` will be
* allowed to spend on behalf of `owner` through {transferFrom}. This is
* zero by default.
*
* This value changes when {approve} or {transferFrom} are called.
*/
function allowance(address owner, address spender) external view returns (uint256);
/**
* @dev Sets a `value` amount of tokens as the allowance of `spender` over the
* caller's tokens.
*
* Returns a boolean value indicating whether the operation succeeded.
*
* IMPORTANT: Beware that changing an allowance with this method brings the risk
* that someone may use both the old and the new allowance by unfortunate
* transaction ordering. One possible solution to mitigate this race
* condition is to first reduce the spender's allowance to 0 and set the
* desired value afterwards:
* https://github.com/ethereum/EIPs/issues/20#issuecomment-263524729
*
* Emits an {Approval} event.
*/
function approve(address spender, uint256 value) external returns (bool);
/**
* @dev Moves a `value` amount of tokens from `from` to `to` using the
* allowance mechanism. `value` is then deducted from the caller's
* allowance.
*
* Returns a boolean value indicating whether the operation succeeded.
*
* Emits a {Transfer} event.
*/
function transferFrom(address from, address to, uint256 value) external returns (bool);
}
"
},
"lib/openzeppelin-contracts/contracts/token/ERC20/utils/SafeERC20.sol": {
"content": "// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.3.0) (token/ERC20/utils/SafeERC20.sol)
pragma solidity ^0.8.20;
import {IERC20} from "../IERC20.sol";
import {IERC1363} from "../../../interfaces/IERC1363.sol";
/**
* @title SafeERC20
* @dev Wrappers around ERC-20 operations that throw on failure (when the token
* contract returns false). Tokens that return no value (and instead revert or
* throw on failure) are also supported, non-reverting calls are assumed to be
* successful.
* To use this library you can add a `using SafeERC20 for IERC20;` statement to your contractSubmitted on: 2025-11-01 11:41:50
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