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Source Code
Overview
ETH Balance
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Contract Name:
PTWithPriceFeed
Compiler Version
v0.8.27+commit.40a35a09
Optimization Enabled:
Yes with 200 runs
Other Settings:
cancun EvmVersion
Contract Source Code (Solidity Standard Json-Input format)
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.27;
import {AggregatorV3Interface} from "@chainlink/contracts/src/v0.8/shared/interfaces/AggregatorV3Interface.sol";
import {PendlePYLpOracle} from "@pendle/core-v2/contracts/oracles/PtYtLpOracle/PendlePYLpOracle.sol";
import {PendlePYOracleLib} from "@pendle/core-v2/contracts/oracles/PtYtLpOracle/PendlePYOracleLib.sol";
import {PMath} from "@pendle/core-v2/contracts/core/libraries/math/PMath.sol";
import {IPMarket} from "@pendle/core-v2/contracts/interfaces/IPMarket.sol";
import {SafeCast} from "@openzeppelin/contracts/utils/math/SafeCast.sol";
import {Math} from "@openzeppelin/contracts/utils/math/Math.sol";
/**
* @title The customized Pendle PT price feed contract mutated from Chainlink AggregatorV3Interface
* @author Term Structure Labs
* @notice Use the customized price feed contract to normalized price feed interface for TermMax Protocol
*/
contract PTWithPriceFeed is AggregatorV3Interface {
using Math for uint256;
using SafeCast for *;
using PendlePYOracleLib for IPMarket;
// Pendle PY LP oracle, refer to `https://docs.pendle.finance/Developers/Oracles/HowToIntegratePtAndLpOracle`
PendlePYLpOracle public immutable PY_LP_ORACLE;
// Pendle market
IPMarket public immutable MARKET;
// TWAP duration
uint32 public immutable DURATION;
// Price feed interface
AggregatorV3Interface public immutable PRICE_FEED;
// error to call `getRoundData` function
error GetRoundDataNotSupported();
// error when Pendle PY LP oracle is not ready
error OracleIsNotReady();
// error when price is zero
error PriceIsZero();
/**
* @notice Construct the PT price feed contract
* @param pendlePYLpOracle The Pendle PY LP oracle contract
* @param market The Pendle market contract
* @param duration The TWAP duration
* @param priceFeed The price feed interface
*/
constructor(address pendlePYLpOracle, address market, uint32 duration, address priceFeed) {
(, int256 answer,,,) = AggregatorV3Interface(priceFeed).latestRoundData();
if (answer == 0) revert PriceIsZero();
PY_LP_ORACLE = PendlePYLpOracle(pendlePYLpOracle);
MARKET = IPMarket(market);
DURATION = duration;
PRICE_FEED = AggregatorV3Interface(priceFeed);
if (!_oracleIsReady()) revert OracleIsNotReady();
}
/**
* @notice Revert this function because cannot get the chi (rate accumulator) at a specific round
*/
function getRoundData(uint80 /* _roundId */ )
external
pure
returns (
uint80, /* roundId */
int256, /* answer */
uint256, /* startedAt */
uint256, /* updatedAt */
uint80 /* answeredInRound */
)
{
// error to call this function because cannot get the chi (rate accumulator) at a specific round
revert GetRoundDataNotSupported();
}
/**
* @notice Get the latest round data from chainlink and calculate the PT price by multiplying PT rate in SY and SY price
* @return roundId The round ID
* @return answer The calculated PT price
* @return startedAt Timestamp of when the round started
* @return updatedAt Timestamp of when the round was updated
* @return answeredInRound The round ID of the round in which the answer was computed
*/
function latestRoundData()
external
view
returns (uint80 roundId, int256 answer, uint256 startedAt, uint256 updatedAt, uint80 answeredInRound)
{
// PT price = PT rate in SY * SY price / PT to asset rate base
uint256 ptRateInSy = MARKET.getPtToSyRate(DURATION); // PT -> SY
(roundId, answer, startedAt, updatedAt, answeredInRound) = PRICE_FEED.latestRoundData();
answer = ptRateInSy.mulDiv(answer.toUint256(), PMath.ONE).toInt256();
return (roundId, answer, startedAt, updatedAt, answeredInRound);
}
/**
* @notice Check if the Pendle PY LP oracle is ready
* @return True if the oracle is ready, otherwise false
*/
function _oracleIsReady() internal view returns (bool) {
(bool increaseCardinalityRequired,, bool oldestObservationSatisfied) =
PY_LP_ORACLE.getOracleState(address(MARKET), DURATION);
return !increaseCardinalityRequired && oldestObservationSatisfied;
}
/**
* ========== Return original price feed data ==========
*/
function decimals() external view returns (uint8) {
return PRICE_FEED.decimals();
}
function description() external view returns (string memory) {
return PRICE_FEED.description();
}
function version() external view returns (uint256) {
return PRICE_FEED.version();
}
}// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
// solhint-disable-next-line interface-starts-with-i
interface AggregatorV3Interface {
function decimals() external view returns (uint8);
function description() external view returns (string memory);
function version() external view returns (uint256);
function getRoundData(
uint80 _roundId
) external view returns (uint80 roundId, int256 answer, uint256 startedAt, uint256 updatedAt, uint80 answeredInRound);
function latestRoundData()
external
view
returns (uint80 roundId, int256 answer, uint256 startedAt, uint256 updatedAt, uint80 answeredInRound);
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.17;
import "./PendlePYOracleLib.sol";
import "./PendleLpOracleLib.sol";
import "../../interfaces/IPPYLpOracle.sol";
import "../../core/libraries/BoringOwnableUpgradeable.sol";
// This is a pre-deployed version of PendlePtOracleLib & PendleLpOracleLib with additional utility functions.
// Use of this contract rather than direct library integration resulting in a smaller bytecode size and simpler structure
// but slightly higher gas usage (~ 4000 gas, 2 external calls & 1 cold code load)
contract PendlePYLpOracle is BoringOwnableUpgradeable, IPPYLpOracle {
using PendlePYOracleLib for IPMarket;
using PendleLpOracleLib for IPMarket;
error InvalidBlockRate(uint256 blockCycleNumerator);
error TwapDurationTooLarge(uint32 duration, uint32 cardinalityRequired);
/// @notice Oracles will be created ensuring a lowerbound in PendleMarket oracle's cardinality
/// @dev Cardinality lowerbound will be calculated as twap_duration * 1000 / blockCycleNumerator
/// @dev blockCycleNumerator should be configured so that blockCycleNumerator / 1000 < actual block cycle
/// @dev blockCycleNumerator should be greater or equal to 1000 since the oracle only records one
/// rate per timestamp
/// For example, on Ethereum blockCycleNumerator = 11000, where 11000/1000 = 11 < 12
/// Arbitrum blockCycleNumerator = 1000, since we can't do better than this
uint16 public blockCycleNumerator;
uint16 public constant BLOCK_CYCLE_DENOMINATOR = 1000;
constructor() {
_disableInitializers();
}
function initialize(uint16 _blockCycleNumerator) external initializer {
__BoringOwnable_init();
_setBlockCycleNumerator(_blockCycleNumerator);
}
// Refer to https://docs.pendle.finance/Home on how to use the oracle
/*///////////////////////////////////////////////////////////////
PT, YT, LP to SY
//////////////////////////////////////////////////////////////*/
function getPtToSyRate(address market, uint32 duration) external view returns (uint256) {
return IPMarket(market).getPtToSyRate(duration);
}
function getYtToSyRate(address market, uint32 duration) external view returns (uint256) {
return IPMarket(market).getYtToSyRate(duration);
}
function getLpToSyRate(address market, uint32 duration) external view returns (uint256) {
return IPMarket(market).getLpToSyRate(duration);
}
/*///////////////////////////////////////////////////////////////
PT, YT, LP to Asset
//////////////////////////////////////////////////////////////*/
/// @notice make sure you have taken into account the risk of not being able to withdraw from SY to Asset
function getPtToAssetRate(address market, uint32 duration) external view returns (uint256) {
return IPMarket(market).getPtToAssetRate(duration);
}
function getYtToAssetRate(address market, uint32 duration) external view returns (uint256) {
return IPMarket(market).getYtToAssetRate(duration);
}
function getLpToAssetRate(address market, uint32 duration) external view returns (uint256) {
return IPMarket(market).getLpToAssetRate(duration);
}
/*///////////////////////////////////////////////////////////////
Utility functions
//////////////////////////////////////////////////////////////*/
/**
* A check function for the cardinality status of the market
* @param market PendleMarket address
* @param duration twap duration
* @return increaseCardinalityRequired a boolean indicates whether the cardinality should be increased to serve the duration
* @return cardinalityRequired the amount of cardinality required for the twap duration
*/
function getOracleState(
address market,
uint32 duration
)
external
view
returns (bool increaseCardinalityRequired, uint16 cardinalityRequired, bool oldestObservationSatisfied)
{
(, , , uint16 observationIndex, uint16 observationCardinality, uint16 cardinalityReserved) = IPMarket(market)
._storage();
// checkIncreaseCardinalityRequired
cardinalityRequired = _calcCardinalityRequiredRequired(duration);
increaseCardinalityRequired = cardinalityReserved < cardinalityRequired;
// check oldestObservationSatisfied
(uint32 oldestTimestamp, , bool initialized) = IPMarket(market).observations(
(observationIndex + 1) % observationCardinality
);
if (!initialized) {
(oldestTimestamp, , ) = IPMarket(market).observations(0);
}
oldestObservationSatisfied = oldestTimestamp < block.timestamp - duration;
}
function _calcCardinalityRequiredRequired(uint32 duration) internal view returns (uint16) {
uint32 cardinalityRequired = (duration * BLOCK_CYCLE_DENOMINATOR + blockCycleNumerator - 1) /
blockCycleNumerator +
1;
if (cardinalityRequired > type(uint16).max) {
revert TwapDurationTooLarge(duration, cardinalityRequired);
}
return uint16(cardinalityRequired);
}
// --- Owner-Only Functions ---
function setBlockCycleNumerator(uint16 newBlockCycleNumerator) external onlyOwner {
_setBlockCycleNumerator(newBlockCycleNumerator);
}
function _setBlockCycleNumerator(uint16 newBlockCycleNumerator) internal {
if (newBlockCycleNumerator < BLOCK_CYCLE_DENOMINATOR) {
revert InvalidBlockRate(newBlockCycleNumerator);
}
blockCycleNumerator = newBlockCycleNumerator;
emit SetBlockCycleNumerator(newBlockCycleNumerator);
}
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
import "../../interfaces/IPMarket.sol";
import "../../core/libraries/math/PMath.sol";
// This library can & should be integrated directly for optimal gas usage.
// If you prefer not to integrate it directly, the PendlePtOracle contract (a pre-deployed version of this contract) can be used.
library PendlePYOracleLib {
using PMath for uint256;
using PMath for int256;
/**
* This function returns the twap rate PT/Asset on market, but take into account the current rate of SY
This is to account for special cases where underlying asset becomes insolvent and has decreasing exchangeRate
* @param market market to get rate from
* @param duration twap duration
*/
function getPtToAssetRate(IPMarket market, uint32 duration) internal view returns (uint256) {
(uint256 syIndex, uint256 pyIndex) = getSYandPYIndexCurrent(market);
if (syIndex >= pyIndex) {
return getPtToAssetRateRaw(market, duration);
} else {
return (getPtToAssetRateRaw(market, duration) * syIndex) / pyIndex;
}
}
/**
* This function returns the twap rate YT/Asset on market, but take into account the current rate of SY
This is to account for special cases where underlying asset becomes insolvent and has decreasing exchangeRate
* @param market market to get rate from
* @param duration twap duration
*/
function getYtToAssetRate(IPMarket market, uint32 duration) internal view returns (uint256) {
(uint256 syIndex, uint256 pyIndex) = getSYandPYIndexCurrent(market);
if (syIndex >= pyIndex) {
return getYtToAssetRateRaw(market, duration);
} else {
return (getYtToAssetRateRaw(market, duration) * syIndex) / pyIndex;
}
}
/// @notice Similar to getPtToAsset but returns the rate in SY instead
function getPtToSyRate(IPMarket market, uint32 duration) internal view returns (uint256) {
(uint256 syIndex, uint256 pyIndex) = getSYandPYIndexCurrent(market);
if (syIndex >= pyIndex) {
return getPtToAssetRateRaw(market, duration).divDown(syIndex);
} else {
return getPtToAssetRateRaw(market, duration).divDown(pyIndex);
}
}
/// @notice Similar to getPtToAsset but returns the rate in SY instead
function getYtToSyRate(IPMarket market, uint32 duration) internal view returns (uint256) {
(uint256 syIndex, uint256 pyIndex) = getSYandPYIndexCurrent(market);
if (syIndex >= pyIndex) {
return getYtToAssetRateRaw(market, duration).divDown(syIndex);
} else {
return getYtToAssetRateRaw(market, duration).divDown(pyIndex);
}
}
/// @notice returns the raw rate without taking into account whether SY is solvent
function getPtToAssetRateRaw(IPMarket market, uint32 duration) internal view returns (uint256) {
uint256 expiry = market.expiry();
if (expiry <= block.timestamp) {
return PMath.ONE;
} else {
uint256 lnImpliedRate = getMarketLnImpliedRate(market, duration);
uint256 timeToExpiry = expiry - block.timestamp;
uint256 assetToPtRate = MarketMathCore._getExchangeRateFromImpliedRate(lnImpliedRate, timeToExpiry).Uint();
return PMath.ONE.divDown(assetToPtRate);
}
}
/// @notice returns the raw rate without taking into account whether SY is solvent
function getYtToAssetRateRaw(IPMarket market, uint32 duration) internal view returns (uint256) {
return PMath.ONE - getPtToAssetRateRaw(market, duration);
}
function getSYandPYIndexCurrent(IPMarket market) internal view returns (uint256 syIndex, uint256 pyIndex) {
(IStandardizedYield SY, , IPYieldToken YT) = market.readTokens();
syIndex = SY.exchangeRate();
uint256 pyIndexStored = YT.pyIndexStored();
if (YT.doCacheIndexSameBlock() && YT.pyIndexLastUpdatedBlock() == block.number) {
pyIndex = pyIndexStored;
} else {
pyIndex = PMath.max(syIndex, pyIndexStored);
}
}
function getMarketLnImpliedRate(IPMarket market, uint32 duration) internal view returns (uint256) {
uint32[] memory durations = new uint32[](2);
durations[0] = duration;
uint216[] memory lnImpliedRateCumulative = market.observe(durations);
return (lnImpliedRateCumulative[1] - lnImpliedRateCumulative[0]) / duration;
}
}// SPDX-License-Identifier: GPL-3.0-or-later
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
pragma solidity ^0.8.0;
/* solhint-disable private-vars-leading-underscore, reason-string */
library PMath {
uint256 internal constant ONE = 1e18; // 18 decimal places
int256 internal constant IONE = 1e18; // 18 decimal places
function subMax0(uint256 a, uint256 b) internal pure returns (uint256) {
unchecked {
return (a >= b ? a - b : 0);
}
}
function subNoNeg(int256 a, int256 b) internal pure returns (int256) {
require(a >= b, "negative");
return a - b; // no unchecked since if b is very negative, a - b might overflow
}
function mulDown(uint256 a, uint256 b) internal pure returns (uint256) {
uint256 product = a * b;
unchecked {
return product / ONE;
}
}
function mulDown(int256 a, int256 b) internal pure returns (int256) {
int256 product = a * b;
unchecked {
return product / IONE;
}
}
function divDown(uint256 a, uint256 b) internal pure returns (uint256) {
uint256 aInflated = a * ONE;
unchecked {
return aInflated / b;
}
}
function divDown(int256 a, int256 b) internal pure returns (int256) {
int256 aInflated = a * IONE;
unchecked {
return aInflated / b;
}
}
function rawDivUp(uint256 a, uint256 b) internal pure returns (uint256) {
return (a + b - 1) / b;
}
function rawDivUp(int256 a, int256 b) internal pure returns (int256) {
return (a + b - 1) / b;
}
function tweakUp(uint256 a, uint256 factor) internal pure returns (uint256) {
return mulDown(a, ONE + factor);
}
function tweakDown(uint256 a, uint256 factor) internal pure returns (uint256) {
return mulDown(a, ONE - factor);
}
/// @return res = min(a + b, bound)
/// @dev This function should handle arithmetic operation and bound check without overflow/underflow
function addWithUpperBound(uint256 a, uint256 b, uint256 bound) internal pure returns (uint256 res) {
unchecked {
if (type(uint256).max - b < a) res = bound;
else res = min(bound, a + b);
}
}
/// @return res = max(a - b, bound)
/// @dev This function should handle arithmetic operation and bound check without overflow/underflow
function subWithLowerBound(uint256 a, uint256 b, uint256 bound) internal pure returns (uint256 res) {
unchecked {
if (b > a) res = bound;
else res = max(a - b, bound);
}
}
function clamp(uint256 x, uint256 lower, uint256 upper) internal pure returns (uint256 res) {
res = x;
if (x < lower) res = lower;
else if (x > upper) res = upper;
}
// @author Uniswap
function sqrt(uint256 y) internal pure returns (uint256 z) {
if (y > 3) {
z = y;
uint256 x = y / 2 + 1;
while (x < z) {
z = x;
x = (y / x + x) / 2;
}
} else if (y != 0) {
z = 1;
}
}
function square(uint256 x) internal pure returns (uint256) {
return x * x;
}
function squareDown(uint256 x) internal pure returns (uint256) {
return mulDown(x, x);
}
function abs(int256 x) internal pure returns (uint256) {
return uint256(x > 0 ? x : -x);
}
function neg(int256 x) internal pure returns (int256) {
return x * (-1);
}
function neg(uint256 x) internal pure returns (int256) {
return Int(x) * (-1);
}
function max(uint256 x, uint256 y) internal pure returns (uint256) {
return (x > y ? x : y);
}
function max(int256 x, int256 y) internal pure returns (int256) {
return (x > y ? x : y);
}
function min(uint256 x, uint256 y) internal pure returns (uint256) {
return (x < y ? x : y);
}
function min(int256 x, int256 y) internal pure returns (int256) {
return (x < y ? x : y);
}
/*///////////////////////////////////////////////////////////////
SIGNED CASTS
//////////////////////////////////////////////////////////////*/
function Int(uint256 x) internal pure returns (int256) {
require(x <= uint256(type(int256).max));
return int256(x);
}
function Int128(int256 x) internal pure returns (int128) {
require(type(int128).min <= x && x <= type(int128).max);
return int128(x);
}
function Int128(uint256 x) internal pure returns (int128) {
return Int128(Int(x));
}
/*///////////////////////////////////////////////////////////////
UNSIGNED CASTS
//////////////////////////////////////////////////////////////*/
function Uint(int256 x) internal pure returns (uint256) {
require(x >= 0);
return uint256(x);
}
function Uint32(uint256 x) internal pure returns (uint32) {
require(x <= type(uint32).max);
return uint32(x);
}
function Uint64(uint256 x) internal pure returns (uint64) {
require(x <= type(uint64).max);
return uint64(x);
}
function Uint112(uint256 x) internal pure returns (uint112) {
require(x <= type(uint112).max);
return uint112(x);
}
function Uint96(uint256 x) internal pure returns (uint96) {
require(x <= type(uint96).max);
return uint96(x);
}
function Uint128(uint256 x) internal pure returns (uint128) {
require(x <= type(uint128).max);
return uint128(x);
}
function Uint192(uint256 x) internal pure returns (uint192) {
require(x <= type(uint192).max);
return uint192(x);
}
function Uint80(uint256 x) internal pure returns (uint80) {
require(x <= type(uint80).max);
return uint80(x);
}
function isAApproxB(uint256 a, uint256 b, uint256 eps) internal pure returns (bool) {
return mulDown(b, ONE - eps) <= a && a <= mulDown(b, ONE + eps);
}
function isAGreaterApproxB(uint256 a, uint256 b, uint256 eps) internal pure returns (bool) {
return a >= b && a <= mulDown(b, ONE + eps);
}
function isASmallerApproxB(uint256 a, uint256 b, uint256 eps) internal pure returns (bool) {
return a <= b && a >= mulDown(b, ONE - eps);
}
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
import "@openzeppelin/contracts/token/ERC20/extensions/IERC20Metadata.sol";
import "./IPPrincipalToken.sol";
import "./IPYieldToken.sol";
import "./IStandardizedYield.sol";
import "./IPGauge.sol";
import "../core/Market/MarketMathCore.sol";
interface IPMarket is IERC20Metadata, IPGauge {
event Mint(address indexed receiver, uint256 netLpMinted, uint256 netSyUsed, uint256 netPtUsed);
event Burn(
address indexed receiverSy,
address indexed receiverPt,
uint256 netLpBurned,
uint256 netSyOut,
uint256 netPtOut
);
event Swap(
address indexed caller,
address indexed receiver,
int256 netPtOut,
int256 netSyOut,
uint256 netSyFee,
uint256 netSyToReserve
);
event UpdateImpliedRate(uint256 indexed timestamp, uint256 lnLastImpliedRate);
event IncreaseObservationCardinalityNext(
uint16 observationCardinalityNextOld,
uint16 observationCardinalityNextNew
);
function mint(
address receiver,
uint256 netSyDesired,
uint256 netPtDesired
) external returns (uint256 netLpOut, uint256 netSyUsed, uint256 netPtUsed);
function burn(
address receiverSy,
address receiverPt,
uint256 netLpToBurn
) external returns (uint256 netSyOut, uint256 netPtOut);
function swapExactPtForSy(
address receiver,
uint256 exactPtIn,
bytes calldata data
) external returns (uint256 netSyOut, uint256 netSyFee);
function swapSyForExactPt(
address receiver,
uint256 exactPtOut,
bytes calldata data
) external returns (uint256 netSyIn, uint256 netSyFee);
function redeemRewards(address user) external returns (uint256[] memory);
function readState(address router) external view returns (MarketState memory market);
function observe(uint32[] memory secondsAgos) external view returns (uint216[] memory lnImpliedRateCumulative);
function increaseObservationsCardinalityNext(uint16 cardinalityNext) external;
function readTokens() external view returns (IStandardizedYield _SY, IPPrincipalToken _PT, IPYieldToken _YT);
function getRewardTokens() external view returns (address[] memory);
function isExpired() external view returns (bool);
function expiry() external view returns (uint256);
function observations(
uint256 index
) external view returns (uint32 blockTimestamp, uint216 lnImpliedRateCumulative, bool initialized);
function _storage()
external
view
returns (
int128 totalPt,
int128 totalSy,
uint96 lastLnImpliedRate,
uint16 observationIndex,
uint16 observationCardinality,
uint16 observationCardinalityNext
);
}// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.1.0) (utils/math/SafeCast.sol)
// This file was procedurally generated from scripts/generate/templates/SafeCast.js.
pragma solidity ^0.8.20;
/**
* @dev Wrappers over Solidity's uintXX/intXX/bool casting operators with added overflow
* checks.
*
* Downcasting from uint256/int256 in Solidity does not revert on overflow. This can
* easily result in undesired exploitation or bugs, since developers usually
* assume that overflows raise errors. `SafeCast` restores this intuition by
* reverting the transaction when such an operation overflows.
*
* Using this library instead of the unchecked operations eliminates an entire
* class of bugs, so it's recommended to use it always.
*/
library SafeCast {
/**
* @dev Value doesn't fit in an uint of `bits` size.
*/
error SafeCastOverflowedUintDowncast(uint8 bits, uint256 value);
/**
* @dev An int value doesn't fit in an uint of `bits` size.
*/
error SafeCastOverflowedIntToUint(int256 value);
/**
* @dev Value doesn't fit in an int of `bits` size.
*/
error SafeCastOverflowedIntDowncast(uint8 bits, int256 value);
/**
* @dev An uint value doesn't fit in an int of `bits` size.
*/
error SafeCastOverflowedUintToInt(uint256 value);
/**
* @dev Returns the downcasted uint248 from uint256, reverting on
* overflow (when the input is greater than largest uint248).
*
* Counterpart to Solidity's `uint248` operator.
*
* Requirements:
*
* - input must fit into 248 bits
*/
function toUint248(uint256 value) internal pure returns (uint248) {
if (value > type(uint248).max) {
revert SafeCastOverflowedUintDowncast(248, value);
}
return uint248(value);
}
/**
* @dev Returns the downcasted uint240 from uint256, reverting on
* overflow (when the input is greater than largest uint240).
*
* Counterpart to Solidity's `uint240` operator.
*
* Requirements:
*
* - input must fit into 240 bits
*/
function toUint240(uint256 value) internal pure returns (uint240) {
if (value > type(uint240).max) {
revert SafeCastOverflowedUintDowncast(240, value);
}
return uint240(value);
}
/**
* @dev Returns the downcasted uint232 from uint256, reverting on
* overflow (when the input is greater than largest uint232).
*
* Counterpart to Solidity's `uint232` operator.
*
* Requirements:
*
* - input must fit into 232 bits
*/
function toUint232(uint256 value) internal pure returns (uint232) {
if (value > type(uint232).max) {
revert SafeCastOverflowedUintDowncast(232, value);
}
return uint232(value);
}
/**
* @dev Returns the downcasted uint224 from uint256, reverting on
* overflow (when the input is greater than largest uint224).
*
* Counterpart to Solidity's `uint224` operator.
*
* Requirements:
*
* - input must fit into 224 bits
*/
function toUint224(uint256 value) internal pure returns (uint224) {
if (value > type(uint224).max) {
revert SafeCastOverflowedUintDowncast(224, value);
}
return uint224(value);
}
/**
* @dev Returns the downcasted uint216 from uint256, reverting on
* overflow (when the input is greater than largest uint216).
*
* Counterpart to Solidity's `uint216` operator.
*
* Requirements:
*
* - input must fit into 216 bits
*/
function toUint216(uint256 value) internal pure returns (uint216) {
if (value > type(uint216).max) {
revert SafeCastOverflowedUintDowncast(216, value);
}
return uint216(value);
}
/**
* @dev Returns the downcasted uint208 from uint256, reverting on
* overflow (when the input is greater than largest uint208).
*
* Counterpart to Solidity's `uint208` operator.
*
* Requirements:
*
* - input must fit into 208 bits
*/
function toUint208(uint256 value) internal pure returns (uint208) {
if (value > type(uint208).max) {
revert SafeCastOverflowedUintDowncast(208, value);
}
return uint208(value);
}
/**
* @dev Returns the downcasted uint200 from uint256, reverting on
* overflow (when the input is greater than largest uint200).
*
* Counterpart to Solidity's `uint200` operator.
*
* Requirements:
*
* - input must fit into 200 bits
*/
function toUint200(uint256 value) internal pure returns (uint200) {
if (value > type(uint200).max) {
revert SafeCastOverflowedUintDowncast(200, value);
}
return uint200(value);
}
/**
* @dev Returns the downcasted uint192 from uint256, reverting on
* overflow (when the input is greater than largest uint192).
*
* Counterpart to Solidity's `uint192` operator.
*
* Requirements:
*
* - input must fit into 192 bits
*/
function toUint192(uint256 value) internal pure returns (uint192) {
if (value > type(uint192).max) {
revert SafeCastOverflowedUintDowncast(192, value);
}
return uint192(value);
}
/**
* @dev Returns the downcasted uint184 from uint256, reverting on
* overflow (when the input is greater than largest uint184).
*
* Counterpart to Solidity's `uint184` operator.
*
* Requirements:
*
* - input must fit into 184 bits
*/
function toUint184(uint256 value) internal pure returns (uint184) {
if (value > type(uint184).max) {
revert SafeCastOverflowedUintDowncast(184, value);
}
return uint184(value);
}
/**
* @dev Returns the downcasted uint176 from uint256, reverting on
* overflow (when the input is greater than largest uint176).
*
* Counterpart to Solidity's `uint176` operator.
*
* Requirements:
*
* - input must fit into 176 bits
*/
function toUint176(uint256 value) internal pure returns (uint176) {
if (value > type(uint176).max) {
revert SafeCastOverflowedUintDowncast(176, value);
}
return uint176(value);
}
/**
* @dev Returns the downcasted uint168 from uint256, reverting on
* overflow (when the input is greater than largest uint168).
*
* Counterpart to Solidity's `uint168` operator.
*
* Requirements:
*
* - input must fit into 168 bits
*/
function toUint168(uint256 value) internal pure returns (uint168) {
if (value > type(uint168).max) {
revert SafeCastOverflowedUintDowncast(168, value);
}
return uint168(value);
}
/**
* @dev Returns the downcasted uint160 from uint256, reverting on
* overflow (when the input is greater than largest uint160).
*
* Counterpart to Solidity's `uint160` operator.
*
* Requirements:
*
* - input must fit into 160 bits
*/
function toUint160(uint256 value) internal pure returns (uint160) {
if (value > type(uint160).max) {
revert SafeCastOverflowedUintDowncast(160, value);
}
return uint160(value);
}
/**
* @dev Returns the downcasted uint152 from uint256, reverting on
* overflow (when the input is greater than largest uint152).
*
* Counterpart to Solidity's `uint152` operator.
*
* Requirements:
*
* - input must fit into 152 bits
*/
function toUint152(uint256 value) internal pure returns (uint152) {
if (value > type(uint152).max) {
revert SafeCastOverflowedUintDowncast(152, value);
}
return uint152(value);
}
/**
* @dev Returns the downcasted uint144 from uint256, reverting on
* overflow (when the input is greater than largest uint144).
*
* Counterpart to Solidity's `uint144` operator.
*
* Requirements:
*
* - input must fit into 144 bits
*/
function toUint144(uint256 value) internal pure returns (uint144) {
if (value > type(uint144).max) {
revert SafeCastOverflowedUintDowncast(144, value);
}
return uint144(value);
}
/**
* @dev Returns the downcasted uint136 from uint256, reverting on
* overflow (when the input is greater than largest uint136).
*
* Counterpart to Solidity's `uint136` operator.
*
* Requirements:
*
* - input must fit into 136 bits
*/
function toUint136(uint256 value) internal pure returns (uint136) {
if (value > type(uint136).max) {
revert SafeCastOverflowedUintDowncast(136, value);
}
return uint136(value);
}
/**
* @dev Returns the downcasted uint128 from uint256, reverting on
* overflow (when the input is greater than largest uint128).
*
* Counterpart to Solidity's `uint128` operator.
*
* Requirements:
*
* - input must fit into 128 bits
*/
function toUint128(uint256 value) internal pure returns (uint128) {
if (value > type(uint128).max) {
revert SafeCastOverflowedUintDowncast(128, value);
}
return uint128(value);
}
/**
* @dev Returns the downcasted uint120 from uint256, reverting on
* overflow (when the input is greater than largest uint120).
*
* Counterpart to Solidity's `uint120` operator.
*
* Requirements:
*
* - input must fit into 120 bits
*/
function toUint120(uint256 value) internal pure returns (uint120) {
if (value > type(uint120).max) {
revert SafeCastOverflowedUintDowncast(120, value);
}
return uint120(value);
}
/**
* @dev Returns the downcasted uint112 from uint256, reverting on
* overflow (when the input is greater than largest uint112).
*
* Counterpart to Solidity's `uint112` operator.
*
* Requirements:
*
* - input must fit into 112 bits
*/
function toUint112(uint256 value) internal pure returns (uint112) {
if (value > type(uint112).max) {
revert SafeCastOverflowedUintDowncast(112, value);
}
return uint112(value);
}
/**
* @dev Returns the downcasted uint104 from uint256, reverting on
* overflow (when the input is greater than largest uint104).
*
* Counterpart to Solidity's `uint104` operator.
*
* Requirements:
*
* - input must fit into 104 bits
*/
function toUint104(uint256 value) internal pure returns (uint104) {
if (value > type(uint104).max) {
revert SafeCastOverflowedUintDowncast(104, value);
}
return uint104(value);
}
/**
* @dev Returns the downcasted uint96 from uint256, reverting on
* overflow (when the input is greater than largest uint96).
*
* Counterpart to Solidity's `uint96` operator.
*
* Requirements:
*
* - input must fit into 96 bits
*/
function toUint96(uint256 value) internal pure returns (uint96) {
if (value > type(uint96).max) {
revert SafeCastOverflowedUintDowncast(96, value);
}
return uint96(value);
}
/**
* @dev Returns the downcasted uint88 from uint256, reverting on
* overflow (when the input is greater than largest uint88).
*
* Counterpart to Solidity's `uint88` operator.
*
* Requirements:
*
* - input must fit into 88 bits
*/
function toUint88(uint256 value) internal pure returns (uint88) {
if (value > type(uint88).max) {
revert SafeCastOverflowedUintDowncast(88, value);
}
return uint88(value);
}
/**
* @dev Returns the downcasted uint80 from uint256, reverting on
* overflow (when the input is greater than largest uint80).
*
* Counterpart to Solidity's `uint80` operator.
*
* Requirements:
*
* - input must fit into 80 bits
*/
function toUint80(uint256 value) internal pure returns (uint80) {
if (value > type(uint80).max) {
revert SafeCastOverflowedUintDowncast(80, value);
}
return uint80(value);
}
/**
* @dev Returns the downcasted uint72 from uint256, reverting on
* overflow (when the input is greater than largest uint72).
*
* Counterpart to Solidity's `uint72` operator.
*
* Requirements:
*
* - input must fit into 72 bits
*/
function toUint72(uint256 value) internal pure returns (uint72) {
if (value > type(uint72).max) {
revert SafeCastOverflowedUintDowncast(72, value);
}
return uint72(value);
}
/**
* @dev Returns the downcasted uint64 from uint256, reverting on
* overflow (when the input is greater than largest uint64).
*
* Counterpart to Solidity's `uint64` operator.
*
* Requirements:
*
* - input must fit into 64 bits
*/
function toUint64(uint256 value) internal pure returns (uint64) {
if (value > type(uint64).max) {
revert SafeCastOverflowedUintDowncast(64, value);
}
return uint64(value);
}
/**
* @dev Returns the downcasted uint56 from uint256, reverting on
* overflow (when the input is greater than largest uint56).
*
* Counterpart to Solidity's `uint56` operator.
*
* Requirements:
*
* - input must fit into 56 bits
*/
function toUint56(uint256 value) internal pure returns (uint56) {
if (value > type(uint56).max) {
revert SafeCastOverflowedUintDowncast(56, value);
}
return uint56(value);
}
/**
* @dev Returns the downcasted uint48 from uint256, reverting on
* overflow (when the input is greater than largest uint48).
*
* Counterpart to Solidity's `uint48` operator.
*
* Requirements:
*
* - input must fit into 48 bits
*/
function toUint48(uint256 value) internal pure returns (uint48) {
if (value > type(uint48).max) {
revert SafeCastOverflowedUintDowncast(48, value);
}
return uint48(value);
}
/**
* @dev Returns the downcasted uint40 from uint256, reverting on
* overflow (when the input is greater than largest uint40).
*
* Counterpart to Solidity's `uint40` operator.
*
* Requirements:
*
* - input must fit into 40 bits
*/
function toUint40(uint256 value) internal pure returns (uint40) {
if (value > type(uint40).max) {
revert SafeCastOverflowedUintDowncast(40, value);
}
return uint40(value);
}
/**
* @dev Returns the downcasted uint32 from uint256, reverting on
* overflow (when the input is greater than largest uint32).
*
* Counterpart to Solidity's `uint32` operator.
*
* Requirements:
*
* - input must fit into 32 bits
*/
function toUint32(uint256 value) internal pure returns (uint32) {
if (value > type(uint32).max) {
revert SafeCastOverflowedUintDowncast(32, value);
}
return uint32(value);
}
/**
* @dev Returns the downcasted uint24 from uint256, reverting on
* overflow (when the input is greater than largest uint24).
*
* Counterpart to Solidity's `uint24` operator.
*
* Requirements:
*
* - input must fit into 24 bits
*/
function toUint24(uint256 value) internal pure returns (uint24) {
if (value > type(uint24).max) {
revert SafeCastOverflowedUintDowncast(24, value);
}
return uint24(value);
}
/**
* @dev Returns the downcasted uint16 from uint256, reverting on
* overflow (when the input is greater than largest uint16).
*
* Counterpart to Solidity's `uint16` operator.
*
* Requirements:
*
* - input must fit into 16 bits
*/
function toUint16(uint256 value) internal pure returns (uint16) {
if (value > type(uint16).max) {
revert SafeCastOverflowedUintDowncast(16, value);
}
return uint16(value);
}
/**
* @dev Returns the downcasted uint8 from uint256, reverting on
* overflow (when the input is greater than largest uint8).
*
* Counterpart to Solidity's `uint8` operator.
*
* Requirements:
*
* - input must fit into 8 bits
*/
function toUint8(uint256 value) internal pure returns (uint8) {
if (value > type(uint8).max) {
revert SafeCastOverflowedUintDowncast(8, value);
}
return uint8(value);
}
/**
* @dev Converts a signed int256 into an unsigned uint256.
*
* Requirements:
*
* - input must be greater than or equal to 0.
*/
function toUint256(int256 value) internal pure returns (uint256) {
if (value < 0) {
revert SafeCastOverflowedIntToUint(value);
}
return uint256(value);
}
/**
* @dev Returns the downcasted int248 from int256, reverting on
* overflow (when the input is less than smallest int248 or
* greater than largest int248).
*
* Counterpart to Solidity's `int248` operator.
*
* Requirements:
*
* - input must fit into 248 bits
*/
function toInt248(int256 value) internal pure returns (int248 downcasted) {
downcasted = int248(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(248, value);
}
}
/**
* @dev Returns the downcasted int240 from int256, reverting on
* overflow (when the input is less than smallest int240 or
* greater than largest int240).
*
* Counterpart to Solidity's `int240` operator.
*
* Requirements:
*
* - input must fit into 240 bits
*/
function toInt240(int256 value) internal pure returns (int240 downcasted) {
downcasted = int240(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(240, value);
}
}
/**
* @dev Returns the downcasted int232 from int256, reverting on
* overflow (when the input is less than smallest int232 or
* greater than largest int232).
*
* Counterpart to Solidity's `int232` operator.
*
* Requirements:
*
* - input must fit into 232 bits
*/
function toInt232(int256 value) internal pure returns (int232 downcasted) {
downcasted = int232(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(232, value);
}
}
/**
* @dev Returns the downcasted int224 from int256, reverting on
* overflow (when the input is less than smallest int224 or
* greater than largest int224).
*
* Counterpart to Solidity's `int224` operator.
*
* Requirements:
*
* - input must fit into 224 bits
*/
function toInt224(int256 value) internal pure returns (int224 downcasted) {
downcasted = int224(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(224, value);
}
}
/**
* @dev Returns the downcasted int216 from int256, reverting on
* overflow (when the input is less than smallest int216 or
* greater than largest int216).
*
* Counterpart to Solidity's `int216` operator.
*
* Requirements:
*
* - input must fit into 216 bits
*/
function toInt216(int256 value) internal pure returns (int216 downcasted) {
downcasted = int216(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(216, value);
}
}
/**
* @dev Returns the downcasted int208 from int256, reverting on
* overflow (when the input is less than smallest int208 or
* greater than largest int208).
*
* Counterpart to Solidity's `int208` operator.
*
* Requirements:
*
* - input must fit into 208 bits
*/
function toInt208(int256 value) internal pure returns (int208 downcasted) {
downcasted = int208(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(208, value);
}
}
/**
* @dev Returns the downcasted int200 from int256, reverting on
* overflow (when the input is less than smallest int200 or
* greater than largest int200).
*
* Counterpart to Solidity's `int200` operator.
*
* Requirements:
*
* - input must fit into 200 bits
*/
function toInt200(int256 value) internal pure returns (int200 downcasted) {
downcasted = int200(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(200, value);
}
}
/**
* @dev Returns the downcasted int192 from int256, reverting on
* overflow (when the input is less than smallest int192 or
* greater than largest int192).
*
* Counterpart to Solidity's `int192` operator.
*
* Requirements:
*
* - input must fit into 192 bits
*/
function toInt192(int256 value) internal pure returns (int192 downcasted) {
downcasted = int192(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(192, value);
}
}
/**
* @dev Returns the downcasted int184 from int256, reverting on
* overflow (when the input is less than smallest int184 or
* greater than largest int184).
*
* Counterpart to Solidity's `int184` operator.
*
* Requirements:
*
* - input must fit into 184 bits
*/
function toInt184(int256 value) internal pure returns (int184 downcasted) {
downcasted = int184(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(184, value);
}
}
/**
* @dev Returns the downcasted int176 from int256, reverting on
* overflow (when the input is less than smallest int176 or
* greater than largest int176).
*
* Counterpart to Solidity's `int176` operator.
*
* Requirements:
*
* - input must fit into 176 bits
*/
function toInt176(int256 value) internal pure returns (int176 downcasted) {
downcasted = int176(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(176, value);
}
}
/**
* @dev Returns the downcasted int168 from int256, reverting on
* overflow (when the input is less than smallest int168 or
* greater than largest int168).
*
* Counterpart to Solidity's `int168` operator.
*
* Requirements:
*
* - input must fit into 168 bits
*/
function toInt168(int256 value) internal pure returns (int168 downcasted) {
downcasted = int168(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(168, value);
}
}
/**
* @dev Returns the downcasted int160 from int256, reverting on
* overflow (when the input is less than smallest int160 or
* greater than largest int160).
*
* Counterpart to Solidity's `int160` operator.
*
* Requirements:
*
* - input must fit into 160 bits
*/
function toInt160(int256 value) internal pure returns (int160 downcasted) {
downcasted = int160(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(160, value);
}
}
/**
* @dev Returns the downcasted int152 from int256, reverting on
* overflow (when the input is less than smallest int152 or
* greater than largest int152).
*
* Counterpart to Solidity's `int152` operator.
*
* Requirements:
*
* - input must fit into 152 bits
*/
function toInt152(int256 value) internal pure returns (int152 downcasted) {
downcasted = int152(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(152, value);
}
}
/**
* @dev Returns the downcasted int144 from int256, reverting on
* overflow (when the input is less than smallest int144 or
* greater than largest int144).
*
* Counterpart to Solidity's `int144` operator.
*
* Requirements:
*
* - input must fit into 144 bits
*/
function toInt144(int256 value) internal pure returns (int144 downcasted) {
downcasted = int144(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(144, value);
}
}
/**
* @dev Returns the downcasted int136 from int256, reverting on
* overflow (when the input is less than smallest int136 or
* greater than largest int136).
*
* Counterpart to Solidity's `int136` operator.
*
* Requirements:
*
* - input must fit into 136 bits
*/
function toInt136(int256 value) internal pure returns (int136 downcasted) {
downcasted = int136(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(136, value);
}
}
/**
* @dev Returns the downcasted int128 from int256, reverting on
* overflow (when the input is less than smallest int128 or
* greater than largest int128).
*
* Counterpart to Solidity's `int128` operator.
*
* Requirements:
*
* - input must fit into 128 bits
*/
function toInt128(int256 value) internal pure returns (int128 downcasted) {
downcasted = int128(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(128, value);
}
}
/**
* @dev Returns the downcasted int120 from int256, reverting on
* overflow (when the input is less than smallest int120 or
* greater than largest int120).
*
* Counterpart to Solidity's `int120` operator.
*
* Requirements:
*
* - input must fit into 120 bits
*/
function toInt120(int256 value) internal pure returns (int120 downcasted) {
downcasted = int120(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(120, value);
}
}
/**
* @dev Returns the downcasted int112 from int256, reverting on
* overflow (when the input is less than smallest int112 or
* greater than largest int112).
*
* Counterpart to Solidity's `int112` operator.
*
* Requirements:
*
* - input must fit into 112 bits
*/
function toInt112(int256 value) internal pure returns (int112 downcasted) {
downcasted = int112(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(112, value);
}
}
/**
* @dev Returns the downcasted int104 from int256, reverting on
* overflow (when the input is less than smallest int104 or
* greater than largest int104).
*
* Counterpart to Solidity's `int104` operator.
*
* Requirements:
*
* - input must fit into 104 bits
*/
function toInt104(int256 value) internal pure returns (int104 downcasted) {
downcasted = int104(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(104, value);
}
}
/**
* @dev Returns the downcasted int96 from int256, reverting on
* overflow (when the input is less than smallest int96 or
* greater than largest int96).
*
* Counterpart to Solidity's `int96` operator.
*
* Requirements:
*
* - input must fit into 96 bits
*/
function toInt96(int256 value) internal pure returns (int96 downcasted) {
downcasted = int96(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(96, value);
}
}
/**
* @dev Returns the downcasted int88 from int256, reverting on
* overflow (when the input is less than smallest int88 or
* greater than largest int88).
*
* Counterpart to Solidity's `int88` operator.
*
* Requirements:
*
* - input must fit into 88 bits
*/
function toInt88(int256 value) internal pure returns (int88 downcasted) {
downcasted = int88(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(88, value);
}
}
/**
* @dev Returns the downcasted int80 from int256, reverting on
* overflow (when the input is less than smallest int80 or
* greater than largest int80).
*
* Counterpart to Solidity's `int80` operator.
*
* Requirements:
*
* - input must fit into 80 bits
*/
function toInt80(int256 value) internal pure returns (int80 downcasted) {
downcasted = int80(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(80, value);
}
}
/**
* @dev Returns the downcasted int72 from int256, reverting on
* overflow (when the input is less than smallest int72 or
* greater than largest int72).
*
* Counterpart to Solidity's `int72` operator.
*
* Requirements:
*
* - input must fit into 72 bits
*/
function toInt72(int256 value) internal pure returns (int72 downcasted) {
downcasted = int72(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(72, value);
}
}
/**
* @dev Returns the downcasted int64 from int256, reverting on
* overflow (when the input is less than smallest int64 or
* greater than largest int64).
*
* Counterpart to Solidity's `int64` operator.
*
* Requirements:
*
* - input must fit into 64 bits
*/
function toInt64(int256 value) internal pure returns (int64 downcasted) {
downcasted = int64(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(64, value);
}
}
/**
* @dev Returns the downcasted int56 from int256, reverting on
* overflow (when the input is less than smallest int56 or
* greater than largest int56).
*
* Counterpart to Solidity's `int56` operator.
*
* Requirements:
*
* - input must fit into 56 bits
*/
function toInt56(int256 value) internal pure returns (int56 downcasted) {
downcasted = int56(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(56, value);
}
}
/**
* @dev Returns the downcasted int48 from int256, reverting on
* overflow (when the input is less than smallest int48 or
* greater than largest int48).
*
* Counterpart to Solidity's `int48` operator.
*
* Requirements:
*
* - input must fit into 48 bits
*/
function toInt48(int256 value) internal pure returns (int48 downcasted) {
downcasted = int48(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(48, value);
}
}
/**
* @dev Returns the downcasted int40 from int256, reverting on
* overflow (when the input is less than smallest int40 or
* greater than largest int40).
*
* Counterpart to Solidity's `int40` operator.
*
* Requirements:
*
* - input must fit into 40 bits
*/
function toInt40(int256 value) internal pure returns (int40 downcasted) {
downcasted = int40(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(40, value);
}
}
/**
* @dev Returns the downcasted int32 from int256, reverting on
* overflow (when the input is less than smallest int32 or
* greater than largest int32).
*
* Counterpart to Solidity's `int32` operator.
*
* Requirements:
*
* - input must fit into 32 bits
*/
function toInt32(int256 value) internal pure returns (int32 downcasted) {
downcasted = int32(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(32, value);
}
}
/**
* @dev Returns the downcasted int24 from int256, reverting on
* overflow (when the input is less than smallest int24 or
* greater than largest int24).
*
* Counterpart to Solidity's `int24` operator.
*
* Requirements:
*
* - input must fit into 24 bits
*/
function toInt24(int256 value) internal pure returns (int24 downcasted) {
downcasted = int24(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(24, value);
}
}
/**
* @dev Returns the downcasted int16 from int256, reverting on
* overflow (when the input is less than smallest int16 or
* greater than largest int16).
*
* Counterpart to Solidity's `int16` operator.
*
* Requirements:
*
* - input must fit into 16 bits
*/
function toInt16(int256 value) internal pure returns (int16 downcasted) {
downcasted = int16(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(16, value);
}
}
/**
* @dev Returns the downcasted int8 from int256, reverting on
* overflow (when the input is less than smallest int8 or
* greater than largest int8).
*
* Counterpart to Solidity's `int8` operator.
*
* Requirements:
*
* - input must fit into 8 bits
*/
function toInt8(int256 value) internal pure returns (int8 downcasted) {
downcasted = int8(value);
if (downcasted != value) {
revert SafeCastOverflowedIntDowncast(8, value);
}
}
/**
* @dev Converts an unsigned uint256 into a signed int256.
*
* Requirements:
*
* - input must be less than or equal to maxInt256.
*/
function toInt256(uint256 value) internal pure returns (int256) {
// Note: Unsafe cast below is okay because `type(int256).max` is guaranteed to be positive
if (value > uint256(type(int256).max)) {
revert SafeCastOverflowedUintToInt(value);
}
return int256(value);
}
/**
* @dev Cast a boolean (false or true) to a uint256 (0 or 1) with no jump.
*/
function toUint(bool b) internal pure returns (uint256 u) {
assembly ("memory-safe") {
u := iszero(iszero(b))
}
}
}// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.1.0) (utils/math/Math.sol)
pragma solidity ^0.8.20;
import {Panic} from "../Panic.sol";
import {SafeCast} from "./SafeCast.sol";
/**
* @dev Standard math utilities missing in the Solidity language.
*/
library Math {
enum Rounding {
Floor, // Toward negative infinity
Ceil, // Toward positive infinity
Trunc, // Toward zero
Expand // Away from zero
}
/**
* @dev Returns the addition of two unsigned integers, with an success flag (no overflow).
*/
function tryAdd(uint256 a, uint256 b) internal pure returns (bool success, uint256 result) {
unchecked {
uint256 c = a + b;
if (c < a) return (false, 0);
return (true, c);
}
}
/**
* @dev Returns the subtraction of two unsigned integers, with an success flag (no overflow).
*/
function trySub(uint256 a, uint256 b) internal pure returns (bool success, uint256 result) {
unchecked {
if (b > a) return (false, 0);
return (true, a - b);
}
}
/**
* @dev Returns the multiplication of two unsigned integers, with an success flag (no overflow).
*/
function tryMul(uint256 a, uint256 b) internal pure returns (bool success, uint256 result) {
unchecked {
// Gas optimization: this is cheaper than requiring 'a' not being zero, but the
// benefit is lost if 'b' is also tested.
// See: https://github.com/OpenZeppelin/openzeppelin-contracts/pull/522
if (a == 0) return (true, 0);
uint256 c = a * b;
if (c / a != b) return (false, 0);
return (true, c);
}
}
/**
* @dev Returns the division of two unsigned integers, with a success flag (no division by zero).
*/
function tryDiv(uint256 a, uint256 b) internal pure returns (bool success, uint256 result) {
unchecked {
if (b == 0) return (false, 0);
return (true, a / b);
}
}
/**
* @dev Returns the remainder of dividing two unsigned integers, with a success flag (no division by zero).
*/
function tryMod(uint256 a, uint256 b) internal pure returns (bool success, uint256 result) {
unchecked {
if (b == 0) return (false, 0);
return (true, a % b);
}
}
/**
* @dev Branchless ternary evaluation for `a ? b : c`. Gas costs are constant.
*
* IMPORTANT: This function may reduce bytecode size and consume less gas when used standalone.
* However, the compiler may optimize Solidity ternary operations (i.e. `a ? b : c`) to only compute
* one branch when needed, making this function more expensive.
*/
function ternary(bool condition, uint256 a, uint256 b) internal pure returns (uint256) {
unchecked {
// branchless ternary works because:
// b ^ (a ^ b) == a
// b ^ 0 == b
return b ^ ((a ^ b) * SafeCast.toUint(condition));
}
}
/**
* @dev Returns the largest of two numbers.
*/
function max(uint256 a, uint256 b) internal pure returns (uint256) {
return ternary(a > b, a, b);
}
/**
* @dev Returns the smallest of two numbers.
*/
function min(uint256 a, uint256 b) internal pure returns (uint256) {
return ternary(a < b, a, b);
}
/**
* @dev Returns the average of two numbers. The result is rounded towards
* zero.
*/
function average(uint256 a, uint256 b) internal pure returns (uint256) {
// (a + b) / 2 can overflow.
return (a & b) + (a ^ b) / 2;
}
/**
* @dev Returns the ceiling of the division of two numbers.
*
* This differs from standard division with `/` in that it rounds towards infinity instead
* of rounding towards zero.
*/
function ceilDiv(uint256 a, uint256 b) internal pure returns (uint256) {
if (b == 0) {
// Guarantee the same behavior as in a regular Solidity division.
Panic.panic(Panic.DIVISION_BY_ZERO);
}
// The following calculation ensures accurate ceiling division without overflow.
// Since a is non-zero, (a - 1) / b will not overflow.
// The largest possible result occurs when (a - 1) / b is type(uint256).max,
// but the largest value we can obtain is type(uint256).max - 1, which happens
// when a = type(uint256).max and b = 1.
unchecked {
return SafeCast.toUint(a > 0) * ((a - 1) / b + 1);
}
}
/**
* @dev Calculates floor(x * y / denominator) with full precision. Throws if result overflows a uint256 or
* denominator == 0.
*
* Original credit to Remco Bloemen under MIT license (https://xn--2-umb.com/21/muldiv) with further edits by
* Uniswap Labs also under MIT license.
*/
function mulDiv(uint256 x, uint256 y, uint256 denominator) internal pure returns (uint256 result) {
unchecked {
// 512-bit multiply [prod1 prod0] = x * y. Compute the product mod 2²⁵⁶ and mod 2²⁵⁶ - 1, then use
// the Chinese Remainder Theorem to reconstruct the 512 bit result. The result is stored in two 256
// variables such that product = prod1 * 2²⁵⁶ + prod0.
uint256 prod0 = x * y; // Least significant 256 bits of the product
uint256 prod1; // Most significant 256 bits of the product
assembly {
let mm := mulmod(x, y, not(0))
prod1 := sub(sub(mm, prod0), lt(mm, prod0))
}
// Handle non-overflow cases, 256 by 256 division.
if (prod1 == 0) {
// Solidity will revert if denominator == 0, unlike the div opcode on its own.
// The surrounding unchecked block does not change this fact.
// See https://docs.soliditylang.org/en/latest/control-structures.html#checked-or-unchecked-arithmetic.
return prod0 / denominator;
}
// Make sure the result is less than 2²⁵⁶. Also prevents denominator == 0.
if (denominator <= prod1) {
Panic.panic(ternary(denominator == 0, Panic.DIVISION_BY_ZERO, Panic.UNDER_OVERFLOW));
}
///////////////////////////////////////////////
// 512 by 256 division.
///////////////////////////////////////////////
// Make division exact by subtracting the remainder from [prod1 prod0].
uint256 remainder;
assembly {
// Compute remainder using mulmod.
remainder := mulmod(x, y, denominator)
// Subtract 256 bit number from 512 bit number.
prod1 := sub(prod1, gt(remainder, prod0))
prod0 := sub(prod0, remainder)
}
// Factor powers of two out of denominator and compute largest power of two divisor of denominator.
// Always >= 1. See https://cs.stackexchange.com/q/138556/92363.
uint256 twos = denominator & (0 - denominator);
assembly {
// Divide denominator by twos.
denominator := div(denominator, twos)
// Divide [prod1 prod0] by twos.
prod0 := div(prod0, twos)
// Flip twos such that it is 2²⁵⁶ / twos. If twos is zero, then it becomes one.
twos := add(div(sub(0, twos), twos), 1)
}
// Shift in bits from prod1 into prod0.
prod0 |= prod1 * twos;
// Invert denominator mod 2²⁵⁶. Now that denominator is an odd number, it has an inverse modulo 2²⁵⁶ such
// that denominator * inv ≡ 1 mod 2²⁵⁶. Compute the inverse by starting with a seed that is correct for
// four bits. That is, denominator * inv ≡ 1 mod 2⁴.
uint256 inverse = (3 * denominator) ^ 2;
// Use the Newton-Raphson iteration to improve the precision. Thanks to Hensel's lifting lemma, this also
// works in modular arithmetic, doubling the correct bits in each step.
inverse *= 2 - denominator * inverse; // inverse mod 2⁸
inverse *= 2 - denominator * inverse; // inverse mod 2¹⁶
inverse *= 2 - denominator * inverse; // inverse mod 2³²
inverse *= 2 - denominator * inverse; // inverse mod 2⁶⁴
inverse *= 2 - denominator * inverse; // inverse mod 2¹²⁸
inverse *= 2 - denominator * inverse; // inverse mod 2²⁵⁶
// Because the division is now exact we can divide by multiplying with the modular inverse of denominator.
// This will give us the correct result modulo 2²⁵⁶. Since the preconditions guarantee that the outcome is
// less than 2²⁵⁶, this is the final result. We don't need to compute the high bits of the result and prod1
// is no longer required.
result = prod0 * inverse;
return result;
}
}
/**
* @dev Calculates x * y / denominator with full precision, following the selected rounding direction.
*/
function mulDiv(uint256 x, uint256 y, uint256 denominator, Rounding rounding) internal pure returns (uint256) {
return mulDiv(x, y, denominator) + SafeCast.toUint(unsignedRoundsUp(rounding) && mulmod(x, y, denominator) > 0);
}
/**
* @dev Calculate the modular multiplicative inverse of a number in Z/nZ.
*
* If n is a prime, then Z/nZ is a field. In that case all elements are inversible, except 0.
* If n is not a prime, then Z/nZ is not a field, and some elements might not be inversible.
*
* If the input value is not inversible, 0 is returned.
*
* NOTE: If you know for sure that n is (big) a prime, it may be cheaper to use Fermat's little theorem and get the
* inverse using `Math.modExp(a, n - 2, n)`. See {invModPrime}.
*/
function invMod(uint256 a, uint256 n) internal pure returns (uint256) {
unchecked {
if (n == 0) return 0;
// The inverse modulo is calculated using the Extended Euclidean Algorithm (iterative version)
// Used to compute integers x and y such that: ax + ny = gcd(a, n).
// When the gcd is 1, then the inverse of a modulo n exists and it's x.
// ax + ny = 1
// ax = 1 + (-y)n
// ax ≡ 1 (mod n) # x is the inverse of a modulo n
// If the remainder is 0 the gcd is n right away.
uint256 remainder = a % n;
uint256 gcd = n;
// Therefore the initial coefficients are:
// ax + ny = gcd(a, n) = n
// 0a + 1n = n
int256 x = 0;
int256 y = 1;
while (remainder != 0) {
uint256 quotient = gcd / remainder;
(gcd, remainder) = (
// The old remainder is the next gcd to try.
remainder,
// Compute the next remainder.
// Can't overflow given that (a % gcd) * (gcd // (a % gcd)) <= gcd
// where gcd is at most n (capped to type(uint256).max)
gcd - remainder * quotient
);
(x, y) = (
// Increment the coefficient of a.
y,
// Decrement the coefficient of n.
// Can overflow, but the result is casted to uint256 so that the
// next value of y is "wrapped around" to a value between 0 and n - 1.
x - y * int256(quotient)
);
}
if (gcd != 1) return 0; // No inverse exists.
return ternary(x < 0, n - uint256(-x), uint256(x)); // Wrap the result if it's negative.
}
}
/**
* @dev Variant of {invMod}. More efficient, but only works if `p` is known to be a prime greater than `2`.
*
* From https://en.wikipedia.org/wiki/Fermat%27s_little_theorem[Fermat's little theorem], we know that if p is
* prime, then `a**(p-1) ≡ 1 mod p`. As a consequence, we have `a * a**(p-2) ≡ 1 mod p`, which means that
* `a**(p-2)` is the modular multiplicative inverse of a in Fp.
*
* NOTE: this function does NOT check that `p` is a prime greater than `2`.
*/
function invModPrime(uint256 a, uint256 p) internal view returns (uint256) {
unchecked {
return Math.modExp(a, p - 2, p);
}
}
/**
* @dev Returns the modular exponentiation of the specified base, exponent and modulus (b ** e % m)
*
* Requirements:
* - modulus can't be zero
* - underlying staticcall to precompile must succeed
*
* IMPORTANT: The result is only valid if the underlying call succeeds. When using this function, make
* sure the chain you're using it on supports the precompiled contract for modular exponentiation
* at address 0x05 as specified in https://eips.ethereum.org/EIPS/eip-198[EIP-198]. Otherwise,
* the underlying function will succeed given the lack of a revert, but the result may be incorrectly
* interpreted as 0.
*/
function modExp(uint256 b, uint256 e, uint256 m) internal view returns (uint256) {
(bool success, uint256 result) = tryModExp(b, e, m);
if (!success) {
Panic.panic(Panic.DIVISION_BY_ZERO);
}
return result;
}
/**
* @dev Returns the modular exponentiation of the specified base, exponent and modulus (b ** e % m).
* It includes a success flag indicating if the operation succeeded. Operation will be marked as failed if trying
* to operate modulo 0 or if the underlying precompile reverted.
*
* IMPORTANT: The result is only valid if the success flag is true. When using this function, make sure the chain
* you're using it on supports the precompiled contract for modular exponentiation at address 0x05 as specified in
* https://eips.ethereum.org/EIPS/eip-198[EIP-198]. Otherwise, the underlying function will succeed given the lack
* of a revert, but the result may be incorrectly interpreted as 0.
*/
function tryModExp(uint256 b, uint256 e, uint256 m) internal view returns (bool success, uint256 result) {
if (m == 0) return (false, 0);
assembly ("memory-safe") {
let ptr := mload(0x40)
// | Offset | Content | Content (Hex) |
// |-----------|------------|--------------------------------------------------------------------|
// | 0x00:0x1f | size of b | 0x0000000000000000000000000000000000000000000000000000000000000020 |
// | 0x20:0x3f | size of e | 0x0000000000000000000000000000000000000000000000000000000000000020 |
// | 0x40:0x5f | size of m | 0x0000000000000000000000000000000000000000000000000000000000000020 |
// | 0x60:0x7f | value of b | 0x<.............................................................b> |
// | 0x80:0x9f | value of e | 0x<.............................................................e> |
// | 0xa0:0xbf | value of m | 0x<.............................................................m> |
mstore(ptr, 0x20)
mstore(add(ptr, 0x20), 0x20)
mstore(add(ptr, 0x40), 0x20)
mstore(add(ptr, 0x60), b)
mstore(add(ptr, 0x80), e)
mstore(add(ptr, 0xa0), m)
// Given the result < m, it's guaranteed to fit in 32 bytes,
// so we can use the memory scratch space located at offset 0.
success := staticcall(gas(), 0x05, ptr, 0xc0, 0x00, 0x20)
result := mload(0x00)
}
}
/**
* @dev Variant of {modExp} that supports inputs of arbitrary length.
*/
function modExp(bytes memory b, bytes memory e, bytes memory m) internal view returns (bytes memory) {
(bool success, bytes memory result) = tryModExp(b, e, m);
if (!success) {
Panic.panic(Panic.DIVISION_BY_ZERO);
}
return result;
}
/**
* @dev Variant of {tryModExp} that supports inputs of arbitrary length.
*/
function tryModExp(
bytes memory b,
bytes memory e,
bytes memory m
) internal view returns (bool success, bytes memory result) {
if (_zeroBytes(m)) return (false, new bytes(0));
uint256 mLen = m.length;
// Encode call args in result and move the free memory pointer
result = abi.encodePacked(b.length, e.length, mLen, b, e, m);
assembly ("memory-safe") {
let dataPtr := add(result, 0x20)
// Write result on top of args to avoid allocating extra memory.
success := staticcall(gas(), 0x05, dataPtr, mload(result), dataPtr, mLen)
// Overwrite the length.
// result.length > returndatasize() is guaranteed because returndatasize() == m.length
mstore(result, mLen)
// Set the memory pointer after the returned data.
mstore(0x40, add(dataPtr, mLen))
}
}
/**
* @dev Returns whether the provided byte array is zero.
*/
function _zeroBytes(bytes memory byteArray) private pure returns (bool) {
for (uint256 i = 0; i < byteArray.length; ++i) {
if (byteArray[i] != 0) {
return false;
}
}
return true;
}
/**
* @dev Returns the square root of a number. If the number is not a perfect square, the value is rounded
* towards zero.
*
* This method is based on Newton's method for computing square roots; the algorithm is restricted to only
* using integer operations.
*/
function sqrt(uint256 a) internal pure returns (uint256) {
unchecked {
// Take care of easy edge cases when a == 0 or a == 1
if (a <= 1) {
return a;
}
// In this function, we use Newton's method to get a root of `f(x) := x² - a`. It involves building a
// sequence x_n that converges toward sqrt(a). For each iteration x_n, we also define the error between
// the current value as `ε_n = | x_n - sqrt(a) |`.
//
// For our first estimation, we consider `e` the smallest power of 2 which is bigger than the square root
// of the target. (i.e. `2**(e-1) ≤ sqrt(a) < 2**e`). We know that `e ≤ 128` because `(2¹²⁸)² = 2²⁵⁶` is
// bigger than any uint256.
//
// By noticing that
// `2**(e-1) ≤ sqrt(a) < 2**e → (2**(e-1))² ≤ a < (2**e)² → 2**(2*e-2) ≤ a < 2**(2*e)`
// we can deduce that `e - 1` is `log2(a) / 2`. We can thus compute `x_n = 2**(e-1)` using a method similar
// to the msb function.
uint256 aa = a;
uint256 xn = 1;
if (aa >= (1 << 128)) {
aa >>= 128;
xn <<= 64;
}
if (aa >= (1 << 64)) {
aa >>= 64;
xn <<= 32;
}
if (aa >= (1 << 32)) {
aa >>= 32;
xn <<= 16;
}
if (aa >= (1 << 16)) {
aa >>= 16;
xn <<= 8;
}
if (aa >= (1 << 8)) {
aa >>= 8;
xn <<= 4;
}
if (aa >= (1 << 4)) {
aa >>= 4;
xn <<= 2;
}
if (aa >= (1 << 2)) {
xn <<= 1;
}
// We now have x_n such that `x_n = 2**(e-1) ≤ sqrt(a) < 2**e = 2 * x_n`. This implies ε_n ≤ 2**(e-1).
//
// We can refine our estimation by noticing that the middle of that interval minimizes the error.
// If we move x_n to equal 2**(e-1) + 2**(e-2), then we reduce the error to ε_n ≤ 2**(e-2).
// This is going to be our x_0 (and ε_0)
xn = (3 * xn) >> 1; // ε_0 := | x_0 - sqrt(a) | ≤ 2**(e-2)
// From here, Newton's method give us:
// x_{n+1} = (x_n + a / x_n) / 2
//
// One should note that:
// x_{n+1}² - a = ((x_n + a / x_n) / 2)² - a
// = ((x_n² + a) / (2 * x_n))² - a
// = (x_n⁴ + 2 * a * x_n² + a²) / (4 * x_n²) - a
// = (x_n⁴ + 2 * a * x_n² + a² - 4 * a * x_n²) / (4 * x_n²)
// = (x_n⁴ - 2 * a * x_n² + a²) / (4 * x_n²)
// = (x_n² - a)² / (2 * x_n)²
// = ((x_n² - a) / (2 * x_n))²
// ≥ 0
// Which proves that for all n ≥ 1, sqrt(a) ≤ x_n
//
// This gives us the proof of quadratic convergence of the sequence:
// ε_{n+1} = | x_{n+1} - sqrt(a) |
// = | (x_n + a / x_n) / 2 - sqrt(a) |
// = | (x_n² + a - 2*x_n*sqrt(a)) / (2 * x_n) |
// = | (x_n - sqrt(a))² / (2 * x_n) |
// = | ε_n² / (2 * x_n) |
// = ε_n² / | (2 * x_n) |
//
// For the first iteration, we have a special case where x_0 is known:
// ε_1 = ε_0² / | (2 * x_0) |
// ≤ (2**(e-2))² / (2 * (2**(e-1) + 2**(e-2)))
// ≤ 2**(2*e-4) / (3 * 2**(e-1))
// ≤ 2**(e-3) / 3
// ≤ 2**(e-3-log2(3))
// ≤ 2**(e-4.5)
//
// For the following iterations, we use the fact that, 2**(e-1) ≤ sqrt(a) ≤ x_n:
// ε_{n+1} = ε_n² / | (2 * x_n) |
// ≤ (2**(e-k))² / (2 * 2**(e-1))
// ≤ 2**(2*e-2*k) / 2**e
// ≤ 2**(e-2*k)
xn = (xn + a / xn) >> 1; // ε_1 := | x_1 - sqrt(a) | ≤ 2**(e-4.5) -- special case, see above
xn = (xn + a / xn) >> 1; // ε_2 := | x_2 - sqrt(a) | ≤ 2**(e-9) -- general case with k = 4.5
xn = (xn + a / xn) >> 1; // ε_3 := | x_3 - sqrt(a) | ≤ 2**(e-18) -- general case with k = 9
xn = (xn + a / xn) >> 1; // ε_4 := | x_4 - sqrt(a) | ≤ 2**(e-36) -- general case with k = 18
xn = (xn + a / xn) >> 1; // ε_5 := | x_5 - sqrt(a) | ≤ 2**(e-72) -- general case with k = 36
xn = (xn + a / xn) >> 1; // ε_6 := | x_6 - sqrt(a) | ≤ 2**(e-144) -- general case with k = 72
// Because e ≤ 128 (as discussed during the first estimation phase), we know have reached a precision
// ε_6 ≤ 2**(e-144) < 1. Given we're operating on integers, then we can ensure that xn is now either
// sqrt(a) or sqrt(a) + 1.
return xn - SafeCast.toUint(xn > a / xn);
}
}
/**
* @dev Calculates sqrt(a), following the selected rounding direction.
*/
function sqrt(uint256 a, Rounding rounding) internal pure returns (uint256) {
unchecked {
uint256 result = sqrt(a);
return result + SafeCast.toUint(unsignedRoundsUp(rounding) && result * result < a);
}
}
/**
* @dev Return the log in base 2 of a positive value rounded towards zero.
* Returns 0 if given 0.
*/
function log2(uint256 value) internal pure returns (uint256) {
uint256 result = 0;
uint256 exp;
unchecked {
exp = 128 * SafeCast.toUint(value > (1 << 128) - 1);
value >>= exp;
result += exp;
exp = 64 * SafeCast.toUint(value > (1 << 64) - 1);
value >>= exp;
result += exp;
exp = 32 * SafeCast.toUint(value > (1 << 32) - 1);
value >>= exp;
result += exp;
exp = 16 * SafeCast.toUint(value > (1 << 16) - 1);
value >>= exp;
result += exp;
exp = 8 * SafeCast.toUint(value > (1 << 8) - 1);
value >>= exp;
result += exp;
exp = 4 * SafeCast.toUint(value > (1 << 4) - 1);
value >>= exp;
result += exp;
exp = 2 * SafeCast.toUint(value > (1 << 2) - 1);
value >>= exp;
result += exp;
result += SafeCast.toUint(value > 1);
}
return result;
}
/**
* @dev Return the log in base 2, following the selected rounding direction, of a positive value.
* Returns 0 if given 0.
*/
function log2(uint256 value, Rounding rounding) internal pure returns (uint256) {
unchecked {
uint256 result = log2(value);
return result + SafeCast.toUint(unsignedRoundsUp(rounding) && 1 << result < value);
}
}
/**
* @dev Return the log in base 10 of a positive value rounded towards zero.
* Returns 0 if given 0.
*/
function log10(uint256 value) internal pure returns (uint256) {
uint256 result = 0;
unchecked {
if (value >= 10 ** 64) {
value /= 10 ** 64;
result += 64;
}
if (value >= 10 ** 32) {
value /= 10 ** 32;
result += 32;
}
if (value >= 10 ** 16) {
value /= 10 ** 16;
result += 16;
}
if (value >= 10 ** 8) {
value /= 10 ** 8;
result += 8;
}
if (value >= 10 ** 4) {
value /= 10 ** 4;
result += 4;
}
if (value >= 10 ** 2) {
value /= 10 ** 2;
result += 2;
}
if (value >= 10 ** 1) {
result += 1;
}
}
return result;
}
/**
* @dev Return the log in base 10, following the selected rounding direction, of a positive value.
* Returns 0 if given 0.
*/
function log10(uint256 value, Rounding rounding) internal pure returns (uint256) {
unchecked {
uint256 result = log10(value);
return result + SafeCast.toUint(unsignedRoundsUp(rounding) && 10 ** result < value);
}
}
/**
* @dev Return the log in base 256 of a positive value rounded towards zero.
* Returns 0 if given 0.
*
* Adding one to the result gives the number of pairs of hex symbols needed to represent `value` as a hex string.
*/
function log256(uint256 value) internal pure returns (uint256) {
uint256 result = 0;
uint256 isGt;
unchecked {
isGt = SafeCast.toUint(value > (1 << 128) - 1);
value >>= isGt * 128;
result += isGt * 16;
isGt = SafeCast.toUint(value > (1 << 64) - 1);
value >>= isGt * 64;
result += isGt * 8;
isGt = SafeCast.toUint(value > (1 << 32) - 1);
value >>= isGt * 32;
result += isGt * 4;
isGt = SafeCast.toUint(value > (1 << 16) - 1);
value >>= isGt * 16;
result += isGt * 2;
result += SafeCast.toUint(value > (1 << 8) - 1);
}
return result;
}
/**
* @dev Return the log in base 256, following the selected rounding direction, of a positive value.
* Returns 0 if given 0.
*/
function log256(uint256 value, Rounding rounding) internal pure returns (uint256) {
unchecked {
uint256 result = log256(value);
return result + SafeCast.toUint(unsignedRoundsUp(rounding) && 1 << (result << 3) < value);
}
}
/**
* @dev Returns whether a provided rounding mode is considered rounding up for unsigned integers.
*/
function unsignedRoundsUp(Rounding rounding) internal pure returns (bool) {
return uint8(rounding) % 2 == 1;
}
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
import "./PendlePYOracleLib.sol";
library PendleLpOracleLib {
using PendlePYOracleLib for IPMarket;
using PMath for uint256;
using PMath for int256;
using MarketMathCore for MarketState;
/**
* This function returns the approximated twap rate LP/asset on market, but take into account the current rate of SY
This is to account for special cases where underlying asset becomes insolvent and has decreasing exchangeRate
* @param market market to get rate from
* @param duration twap duration
*/
function getLpToAssetRate(IPMarket market, uint32 duration) internal view returns (uint256) {
(uint256 syIndex, uint256 pyIndex) = market.getSYandPYIndexCurrent();
uint256 lpToAssetRateRaw = _getLpToAssetRateRaw(market, duration, pyIndex);
if (syIndex >= pyIndex) {
return lpToAssetRateRaw;
} else {
return (lpToAssetRateRaw * syIndex) / pyIndex;
}
}
/**
* This function returns the approximated twap rate LP/asset on market, but take into account the current rate of SY
This is to account for special cases where underlying asset becomes insolvent and has decreasing exchangeRate
* @param market market to get rate from
* @param duration twap duration
*/
function getLpToSyRate(IPMarket market, uint32 duration) internal view returns (uint256) {
(uint256 syIndex, uint256 pyIndex) = market.getSYandPYIndexCurrent();
uint256 lpToAssetRateRaw = _getLpToAssetRateRaw(market, duration, pyIndex);
if (syIndex >= pyIndex) {
return lpToAssetRateRaw.divDown(syIndex);
} else {
return lpToAssetRateRaw.divDown(pyIndex);
}
}
function _getLpToAssetRateRaw(
IPMarket market,
uint32 duration,
uint256 pyIndex
) private view returns (uint256 lpToAssetRateRaw) {
MarketState memory state = market.readState(address(0));
int256 totalHypotheticalAsset;
if (state.expiry <= block.timestamp) {
// 1 PT = 1 Asset post-expiry
totalHypotheticalAsset = state.totalPt + PYIndexLib.syToAsset(PYIndex.wrap(pyIndex), state.totalSy);
} else {
MarketPreCompute memory comp = state.getMarketPreCompute(PYIndex.wrap(pyIndex), block.timestamp);
(int256 rateOracle, int256 rateHypTrade) = _getPtRatesRaw(market, state, duration);
int256 cParam = LogExpMath.exp(comp.rateScalar.mulDown((rateOracle - comp.rateAnchor)));
int256 tradeSize = (cParam.mulDown(comp.totalAsset) - state.totalPt).divDown(
PMath.IONE + cParam.divDown(rateHypTrade)
);
totalHypotheticalAsset =
comp.totalAsset -
tradeSize.divDown(rateHypTrade) +
(state.totalPt + tradeSize).divDown(rateOracle);
}
lpToAssetRateRaw = totalHypotheticalAsset.divDown(state.totalLp).Uint();
}
function _getPtRatesRaw(
IPMarket market,
MarketState memory state,
uint32 duration
) private view returns (int256 rateOracle, int256 rateHypTrade) {
uint256 lnImpliedRate = market.getMarketLnImpliedRate(duration);
uint256 timeToExpiry = state.expiry - block.timestamp;
rateOracle = MarketMathCore._getExchangeRateFromImpliedRate(lnImpliedRate, timeToExpiry);
int256 rateLastTrade = MarketMathCore._getExchangeRateFromImpliedRate(state.lastLnImpliedRate, timeToExpiry);
rateHypTrade = (rateLastTrade + rateOracle) / 2;
}
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
interface IPPYLpOracle {
event SetBlockCycleNumerator(uint16 newBlockCycleNumerator);
function getPtToAssetRate(address market, uint32 duration) external view returns (uint256);
function getYtToAssetRate(address market, uint32 duration) external view returns (uint256);
function getLpToAssetRate(address market, uint32 duration) external view returns (uint256);
function getPtToSyRate(address market, uint32 duration) external view returns (uint256);
function getYtToSyRate(address market, uint32 duration) external view returns (uint256);
function getLpToSyRate(address market, uint32 duration) external view returns (uint256);
function getOracleState(
address market,
uint32 duration
)
external
view
returns (bool increaseCardinalityRequired, uint16 cardinalityRequired, bool oldestObservationSatisfied);
function blockCycleNumerator() external view returns (uint16);
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
import "@openzeppelin/contracts-upgradeable/proxy/utils/Initializable.sol";
contract BoringOwnableUpgradeableData {
address public owner;
address public pendingOwner;
}
abstract contract BoringOwnableUpgradeable is BoringOwnableUpgradeableData, Initializable {
event OwnershipTransferred(address indexed previousOwner, address indexed newOwner);
function __BoringOwnable_init() internal onlyInitializing {
owner = msg.sender;
}
/// @notice Transfers ownership to `newOwner`. Either directly or claimable by the new pending owner.
/// Can only be invoked by the current `owner`.
/// @param newOwner Address of the new owner.
/// @param direct True if `newOwner` should be set immediately. False if `newOwner` needs to use `claimOwnership`.
/// @param renounce Allows the `newOwner` to be `address(0)` if `direct` and `renounce` is True. Has no effect otherwise.
function transferOwnership(address newOwner, bool direct, bool renounce) public onlyOwner {
if (direct) {
// Checks
require(newOwner != address(0) || renounce, "Ownable: zero address");
// Effects
emit OwnershipTransferred(owner, newOwner);
owner = newOwner;
pendingOwner = address(0);
} else {
// Effects
pendingOwner = newOwner;
}
}
/// @notice Needs to be called by `pendingOwner` to claim ownership.
function claimOwnership() public {
address _pendingOwner = pendingOwner;
// Checks
require(msg.sender == _pendingOwner, "Ownable: caller != pending owner");
// Effects
emit OwnershipTransferred(owner, _pendingOwner);
owner = _pendingOwner;
pendingOwner = address(0);
}
/// @notice Only allows the `owner` to execute the function.
modifier onlyOwner() {
require(msg.sender == owner, "Ownable: caller is not the owner");
_;
}
uint256[48] private __gap;
}// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.1.0) (token/ERC20/extensions/IERC20Metadata.sol)
pragma solidity ^0.8.20;
import {IERC20} from "../IERC20.sol";
/**
* @dev Interface for the optional metadata functions from the ERC-20 standard.
*/
interface IERC20Metadata is IERC20 {
/**
* @dev Returns the name of the token.
*/
function name() external view returns (string memory);
/**
* @dev Returns the symbol of the token.
*/
function symbol() external view returns (string memory);
/**
* @dev Returns the decimals places of the token.
*/
function decimals() external view returns (uint8);
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
import "@openzeppelin/contracts/token/ERC20/extensions/IERC20Metadata.sol";
interface IPPrincipalToken is IERC20Metadata {
function burnByYT(address user, uint256 amount) external;
function mintByYT(address user, uint256 amount) external;
function initialize(address _YT) external;
function SY() external view returns (address);
function YT() external view returns (address);
function factory() external view returns (address);
function expiry() external view returns (uint256);
function isExpired() external view returns (bool);
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
import "@openzeppelin/contracts/token/ERC20/extensions/IERC20Metadata.sol";
import "./IRewardManager.sol";
import "./IPInterestManagerYT.sol";
interface IPYieldToken is IERC20Metadata, IRewardManager, IPInterestManagerYT {
event NewInterestIndex(uint256 indexed newIndex);
event Mint(
address indexed caller,
address indexed receiverPT,
address indexed receiverYT,
uint256 amountSyToMint,
uint256 amountPYOut
);
event Burn(address indexed caller, address indexed receiver, uint256 amountPYToRedeem, uint256 amountSyOut);
event RedeemRewards(address indexed user, uint256[] amountRewardsOut);
event RedeemInterest(address indexed user, uint256 interestOut);
event CollectRewardFee(address indexed rewardToken, uint256 amountRewardFee);
function mintPY(address receiverPT, address receiverYT) external returns (uint256 amountPYOut);
function redeemPY(address receiver) external returns (uint256 amountSyOut);
function redeemPYMulti(
address[] calldata receivers,
uint256[] calldata amountPYToRedeems
) external returns (uint256[] memory amountSyOuts);
function redeemDueInterestAndRewards(
address user,
bool redeemInterest,
bool redeemRewards
) external returns (uint256 interestOut, uint256[] memory rewardsOut);
function rewardIndexesCurrent() external returns (uint256[] memory);
function pyIndexCurrent() external returns (uint256);
function pyIndexStored() external view returns (uint256);
function getRewardTokens() external view returns (address[] memory);
function SY() external view returns (address);
function PT() external view returns (address);
function factory() external view returns (address);
function expiry() external view returns (uint256);
function isExpired() external view returns (bool);
function doCacheIndexSameBlock() external view returns (bool);
function pyIndexLastUpdatedBlock() external view returns (uint128);
}// SPDX-License-Identifier: GPL-3.0-or-later
/*
* MIT License
* ===========
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
*/
pragma solidity ^0.8.0;
import "@openzeppelin/contracts/token/ERC20/extensions/IERC20Metadata.sol";
interface IStandardizedYield is IERC20Metadata {
/// @dev Emitted when any base tokens is deposited to mint shares
event Deposit(
address indexed caller,
address indexed receiver,
address indexed tokenIn,
uint256 amountDeposited,
uint256 amountSyOut
);
/// @dev Emitted when any shares are redeemed for base tokens
event Redeem(
address indexed caller,
address indexed receiver,
address indexed tokenOut,
uint256 amountSyToRedeem,
uint256 amountTokenOut
);
/// @dev check `assetInfo()` for more information
enum AssetType {
TOKEN,
LIQUIDITY
}
/// @dev Emitted when (`user`) claims their rewards
event ClaimRewards(address indexed user, address[] rewardTokens, uint256[] rewardAmounts);
/**
* @notice mints an amount of shares by depositing a base token.
* @param receiver shares recipient address
* @param tokenIn address of the base tokens to mint shares
* @param amountTokenToDeposit amount of base tokens to be transferred from (`msg.sender`)
* @param minSharesOut reverts if amount of shares minted is lower than this
* @return amountSharesOut amount of shares minted
* @dev Emits a {Deposit} event
*
* Requirements:
* - (`tokenIn`) must be a valid base token.
*/
function deposit(
address receiver,
address tokenIn,
uint256 amountTokenToDeposit,
uint256 minSharesOut
) external payable returns (uint256 amountSharesOut);
/**
* @notice redeems an amount of base tokens by burning some shares
* @param receiver recipient address
* @param amountSharesToRedeem amount of shares to be burned
* @param tokenOut address of the base token to be redeemed
* @param minTokenOut reverts if amount of base token redeemed is lower than this
* @param burnFromInternalBalance if true, burns from balance of `address(this)`, otherwise burns from `msg.sender`
* @return amountTokenOut amount of base tokens redeemed
* @dev Emits a {Redeem} event
*
* Requirements:
* - (`tokenOut`) must be a valid base token.
*/
function redeem(
address receiver,
uint256 amountSharesToRedeem,
address tokenOut,
uint256 minTokenOut,
bool burnFromInternalBalance
) external returns (uint256 amountTokenOut);
/**
* @notice exchangeRate * syBalance / 1e18 must return the asset balance of the account
* @notice vice-versa, if a user uses some amount of tokens equivalent to X asset, the amount of sy
he can mint must be X * exchangeRate / 1e18
* @dev SYUtils's assetToSy & syToAsset should be used instead of raw multiplication
& division
*/
function exchangeRate() external view returns (uint256 res);
/**
* @notice claims reward for (`user`)
* @param user the user receiving their rewards
* @return rewardAmounts an array of reward amounts in the same order as `getRewardTokens`
* @dev
* Emits a `ClaimRewards` event
* See {getRewardTokens} for list of reward tokens
*/
function claimRewards(address user) external returns (uint256[] memory rewardAmounts);
/**
* @notice get the amount of unclaimed rewards for (`user`)
* @param user the user to check for
* @return rewardAmounts an array of reward amounts in the same order as `getRewardTokens`
*/
function accruedRewards(address user) external view returns (uint256[] memory rewardAmounts);
function rewardIndexesCurrent() external returns (uint256[] memory indexes);
function rewardIndexesStored() external view returns (uint256[] memory indexes);
/**
* @notice returns the list of reward token addresses
*/
function getRewardTokens() external view returns (address[] memory);
/**
* @notice returns the address of the underlying yield token
*/
function yieldToken() external view returns (address);
/**
* @notice returns all tokens that can mint this SY
*/
function getTokensIn() external view returns (address[] memory res);
/**
* @notice returns all tokens that can be redeemed by this SY
*/
function getTokensOut() external view returns (address[] memory res);
function isValidTokenIn(address token) external view returns (bool);
function isValidTokenOut(address token) external view returns (bool);
function previewDeposit(
address tokenIn,
uint256 amountTokenToDeposit
) external view returns (uint256 amountSharesOut);
function previewRedeem(
address tokenOut,
uint256 amountSharesToRedeem
) external view returns (uint256 amountTokenOut);
/**
* @notice This function contains information to interpret what the asset is
* @return assetType the type of the asset (0 for ERC20 tokens, 1 for AMM liquidity tokens,
2 for bridged yield bearing tokens like wstETH, rETH on Arbi whose the underlying asset doesn't exist on the chain)
* @return assetAddress the address of the asset
* @return assetDecimals the decimals of the asset
*/
function assetInfo() external view returns (AssetType assetType, address assetAddress, uint8 assetDecimals);
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
interface IPGauge {
function totalActiveSupply() external view returns (uint256);
function activeBalance(address user) external view returns (uint256);
// only available for newer factories. please check the verified contracts
event RedeemRewards(address indexed user, uint256[] rewardsOut);
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
import "../libraries/math/PMath.sol";
import "../libraries/math/LogExpMath.sol";
import "../StandardizedYield/PYIndex.sol";
import "../libraries/MiniHelpers.sol";
import "../libraries/Errors.sol";
struct MarketState {
int256 totalPt;
int256 totalSy;
int256 totalLp;
address treasury;
/// immutable variables ///
int256 scalarRoot;
uint256 expiry;
/// fee data ///
uint256 lnFeeRateRoot;
uint256 reserveFeePercent; // base 100
/// last trade data ///
uint256 lastLnImpliedRate;
}
// params that are expensive to compute, therefore we pre-compute them
struct MarketPreCompute {
int256 rateScalar;
int256 totalAsset;
int256 rateAnchor;
int256 feeRate;
}
// solhint-disable ordering
library MarketMathCore {
using PMath for uint256;
using PMath for int256;
using LogExpMath for int256;
using PYIndexLib for PYIndex;
int256 internal constant MINIMUM_LIQUIDITY = 10 ** 3;
int256 internal constant PERCENTAGE_DECIMALS = 100;
uint256 internal constant DAY = 86400;
uint256 internal constant IMPLIED_RATE_TIME = 365 * DAY;
int256 internal constant MAX_MARKET_PROPORTION = (1e18 * 96) / 100;
using PMath for uint256;
using PMath for int256;
/*///////////////////////////////////////////////////////////////
UINT FUNCTIONS TO PROXY TO CORE FUNCTIONS
//////////////////////////////////////////////////////////////*/
function addLiquidity(
MarketState memory market,
uint256 syDesired,
uint256 ptDesired,
uint256 blockTime
) internal pure returns (uint256 lpToReserve, uint256 lpToAccount, uint256 syUsed, uint256 ptUsed) {
(int256 _lpToReserve, int256 _lpToAccount, int256 _syUsed, int256 _ptUsed) = addLiquidityCore(
market,
syDesired.Int(),
ptDesired.Int(),
blockTime
);
lpToReserve = _lpToReserve.Uint();
lpToAccount = _lpToAccount.Uint();
syUsed = _syUsed.Uint();
ptUsed = _ptUsed.Uint();
}
function removeLiquidity(
MarketState memory market,
uint256 lpToRemove
) internal pure returns (uint256 netSyToAccount, uint256 netPtToAccount) {
(int256 _syToAccount, int256 _ptToAccount) = removeLiquidityCore(market, lpToRemove.Int());
netSyToAccount = _syToAccount.Uint();
netPtToAccount = _ptToAccount.Uint();
}
function swapExactPtForSy(
MarketState memory market,
PYIndex index,
uint256 exactPtToMarket,
uint256 blockTime
) internal pure returns (uint256 netSyToAccount, uint256 netSyFee, uint256 netSyToReserve) {
(int256 _netSyToAccount, int256 _netSyFee, int256 _netSyToReserve) = executeTradeCore(
market,
index,
exactPtToMarket.neg(),
blockTime
);
netSyToAccount = _netSyToAccount.Uint();
netSyFee = _netSyFee.Uint();
netSyToReserve = _netSyToReserve.Uint();
}
function swapSyForExactPt(
MarketState memory market,
PYIndex index,
uint256 exactPtToAccount,
uint256 blockTime
) internal pure returns (uint256 netSyToMarket, uint256 netSyFee, uint256 netSyToReserve) {
(int256 _netSyToAccount, int256 _netSyFee, int256 _netSyToReserve) = executeTradeCore(
market,
index,
exactPtToAccount.Int(),
blockTime
);
netSyToMarket = _netSyToAccount.neg().Uint();
netSyFee = _netSyFee.Uint();
netSyToReserve = _netSyToReserve.Uint();
}
/*///////////////////////////////////////////////////////////////
CORE FUNCTIONS
//////////////////////////////////////////////////////////////*/
function addLiquidityCore(
MarketState memory market,
int256 syDesired,
int256 ptDesired,
uint256 blockTime
) internal pure returns (int256 lpToReserve, int256 lpToAccount, int256 syUsed, int256 ptUsed) {
/// ------------------------------------------------------------
/// CHECKS
/// ------------------------------------------------------------
if (syDesired == 0 || ptDesired == 0) revert Errors.MarketZeroAmountsInput();
if (MiniHelpers.isExpired(market.expiry, blockTime)) revert Errors.MarketExpired();
/// ------------------------------------------------------------
/// MATH
/// ------------------------------------------------------------
if (market.totalLp == 0) {
lpToAccount = PMath.sqrt((syDesired * ptDesired).Uint()).Int() - MINIMUM_LIQUIDITY;
lpToReserve = MINIMUM_LIQUIDITY;
syUsed = syDesired;
ptUsed = ptDesired;
} else {
int256 netLpByPt = (ptDesired * market.totalLp) / market.totalPt;
int256 netLpBySy = (syDesired * market.totalLp) / market.totalSy;
if (netLpByPt < netLpBySy) {
lpToAccount = netLpByPt;
ptUsed = ptDesired;
syUsed = (market.totalSy * lpToAccount).rawDivUp(market.totalLp);
} else {
lpToAccount = netLpBySy;
syUsed = syDesired;
ptUsed = (market.totalPt * lpToAccount).rawDivUp(market.totalLp);
}
}
if (lpToAccount <= 0 || syUsed <= 0 || ptUsed <= 0) revert Errors.MarketZeroAmountsOutput();
/// ------------------------------------------------------------
/// WRITE
/// ------------------------------------------------------------
market.totalSy += syUsed;
market.totalPt += ptUsed;
market.totalLp += lpToAccount + lpToReserve;
}
function removeLiquidityCore(
MarketState memory market,
int256 lpToRemove
) internal pure returns (int256 netSyToAccount, int256 netPtToAccount) {
/// ------------------------------------------------------------
/// CHECKS
/// ------------------------------------------------------------
if (lpToRemove == 0) revert Errors.MarketZeroAmountsInput();
/// ------------------------------------------------------------
/// MATH
/// ------------------------------------------------------------
netSyToAccount = (lpToRemove * market.totalSy) / market.totalLp;
netPtToAccount = (lpToRemove * market.totalPt) / market.totalLp;
if (netSyToAccount == 0 && netPtToAccount == 0) revert Errors.MarketZeroAmountsOutput();
/// ------------------------------------------------------------
/// WRITE
/// ------------------------------------------------------------
market.totalLp = market.totalLp.subNoNeg(lpToRemove);
market.totalPt = market.totalPt.subNoNeg(netPtToAccount);
market.totalSy = market.totalSy.subNoNeg(netSyToAccount);
}
function executeTradeCore(
MarketState memory market,
PYIndex index,
int256 netPtToAccount,
uint256 blockTime
) internal pure returns (int256 netSyToAccount, int256 netSyFee, int256 netSyToReserve) {
/// ------------------------------------------------------------
/// CHECKS
/// ------------------------------------------------------------
if (MiniHelpers.isExpired(market.expiry, blockTime)) revert Errors.MarketExpired();
if (market.totalPt <= netPtToAccount)
revert Errors.MarketInsufficientPtForTrade(market.totalPt, netPtToAccount);
/// ------------------------------------------------------------
/// MATH
/// ------------------------------------------------------------
MarketPreCompute memory comp = getMarketPreCompute(market, index, blockTime);
(netSyToAccount, netSyFee, netSyToReserve) = calcTrade(market, comp, index, netPtToAccount);
/// ------------------------------------------------------------
/// WRITE
/// ------------------------------------------------------------
_setNewMarketStateTrade(market, comp, index, netPtToAccount, netSyToAccount, netSyToReserve, blockTime);
}
function getMarketPreCompute(
MarketState memory market,
PYIndex index,
uint256 blockTime
) internal pure returns (MarketPreCompute memory res) {
if (MiniHelpers.isExpired(market.expiry, blockTime)) revert Errors.MarketExpired();
uint256 timeToExpiry = market.expiry - blockTime;
res.rateScalar = _getRateScalar(market, timeToExpiry);
res.totalAsset = index.syToAsset(market.totalSy);
if (market.totalPt == 0 || res.totalAsset == 0)
revert Errors.MarketZeroTotalPtOrTotalAsset(market.totalPt, res.totalAsset);
res.rateAnchor = _getRateAnchor(
market.totalPt,
market.lastLnImpliedRate,
res.totalAsset,
res.rateScalar,
timeToExpiry
);
res.feeRate = _getExchangeRateFromImpliedRate(market.lnFeeRateRoot, timeToExpiry);
}
function calcTrade(
MarketState memory market,
MarketPreCompute memory comp,
PYIndex index,
int256 netPtToAccount
) internal pure returns (int256 netSyToAccount, int256 netSyFee, int256 netSyToReserve) {
int256 preFeeExchangeRate = _getExchangeRate(
market.totalPt,
comp.totalAsset,
comp.rateScalar,
comp.rateAnchor,
netPtToAccount
);
int256 preFeeAssetToAccount = netPtToAccount.divDown(preFeeExchangeRate).neg();
int256 fee = comp.feeRate;
if (netPtToAccount > 0) {
int256 postFeeExchangeRate = preFeeExchangeRate.divDown(fee);
if (postFeeExchangeRate < PMath.IONE) revert Errors.MarketExchangeRateBelowOne(postFeeExchangeRate);
fee = preFeeAssetToAccount.mulDown(PMath.IONE - fee);
} else {
fee = ((preFeeAssetToAccount * (PMath.IONE - fee)) / fee).neg();
}
int256 netAssetToReserve = (fee * market.reserveFeePercent.Int()) / PERCENTAGE_DECIMALS;
int256 netAssetToAccount = preFeeAssetToAccount - fee;
netSyToAccount = netAssetToAccount < 0
? index.assetToSyUp(netAssetToAccount)
: index.assetToSy(netAssetToAccount);
netSyFee = index.assetToSy(fee);
netSyToReserve = index.assetToSy(netAssetToReserve);
}
function _setNewMarketStateTrade(
MarketState memory market,
MarketPreCompute memory comp,
PYIndex index,
int256 netPtToAccount,
int256 netSyToAccount,
int256 netSyToReserve,
uint256 blockTime
) internal pure {
uint256 timeToExpiry = market.expiry - blockTime;
market.totalPt = market.totalPt.subNoNeg(netPtToAccount);
market.totalSy = market.totalSy.subNoNeg(netSyToAccount + netSyToReserve);
market.lastLnImpliedRate = _getLnImpliedRate(
market.totalPt,
index.syToAsset(market.totalSy),
comp.rateScalar,
comp.rateAnchor,
timeToExpiry
);
if (market.lastLnImpliedRate == 0) revert Errors.MarketZeroLnImpliedRate();
}
function _getRateAnchor(
int256 totalPt,
uint256 lastLnImpliedRate,
int256 totalAsset,
int256 rateScalar,
uint256 timeToExpiry
) internal pure returns (int256 rateAnchor) {
int256 newExchangeRate = _getExchangeRateFromImpliedRate(lastLnImpliedRate, timeToExpiry);
if (newExchangeRate < PMath.IONE) revert Errors.MarketExchangeRateBelowOne(newExchangeRate);
{
int256 proportion = totalPt.divDown(totalPt + totalAsset);
int256 lnProportion = _logProportion(proportion);
rateAnchor = newExchangeRate - lnProportion.divDown(rateScalar);
}
}
/// @notice Calculates the current market implied rate.
/// @return lnImpliedRate the implied rate
function _getLnImpliedRate(
int256 totalPt,
int256 totalAsset,
int256 rateScalar,
int256 rateAnchor,
uint256 timeToExpiry
) internal pure returns (uint256 lnImpliedRate) {
// This will check for exchange rates < PMath.IONE
int256 exchangeRate = _getExchangeRate(totalPt, totalAsset, rateScalar, rateAnchor, 0);
// exchangeRate >= 1 so its ln >= 0
uint256 lnRate = exchangeRate.ln().Uint();
lnImpliedRate = (lnRate * IMPLIED_RATE_TIME) / timeToExpiry;
}
/// @notice Converts an implied rate to an exchange rate given a time to expiry. The
/// formula is E = e^rt
function _getExchangeRateFromImpliedRate(
uint256 lnImpliedRate,
uint256 timeToExpiry
) internal pure returns (int256 exchangeRate) {
uint256 rt = (lnImpliedRate * timeToExpiry) / IMPLIED_RATE_TIME;
exchangeRate = LogExpMath.exp(rt.Int());
}
function _getExchangeRate(
int256 totalPt,
int256 totalAsset,
int256 rateScalar,
int256 rateAnchor,
int256 netPtToAccount
) internal pure returns (int256 exchangeRate) {
int256 numerator = totalPt.subNoNeg(netPtToAccount);
int256 proportion = (numerator.divDown(totalPt + totalAsset));
if (proportion > MAX_MARKET_PROPORTION)
revert Errors.MarketProportionTooHigh(proportion, MAX_MARKET_PROPORTION);
int256 lnProportion = _logProportion(proportion);
exchangeRate = lnProportion.divDown(rateScalar) + rateAnchor;
if (exchangeRate < PMath.IONE) revert Errors.MarketExchangeRateBelowOne(exchangeRate);
}
function _logProportion(int256 proportion) internal pure returns (int256 res) {
if (proportion == PMath.IONE) revert Errors.MarketProportionMustNotEqualOne();
int256 logitP = proportion.divDown(PMath.IONE - proportion);
res = logitP.ln();
}
function _getRateScalar(MarketState memory market, uint256 timeToExpiry) internal pure returns (int256 rateScalar) {
rateScalar = (market.scalarRoot * IMPLIED_RATE_TIME.Int()) / timeToExpiry.Int();
if (rateScalar <= 0) revert Errors.MarketRateScalarBelowZero(rateScalar);
}
function setInitialLnImpliedRate(
MarketState memory market,
PYIndex index,
int256 initialAnchor,
uint256 blockTime
) internal pure {
/// ------------------------------------------------------------
/// CHECKS
/// ------------------------------------------------------------
if (MiniHelpers.isExpired(market.expiry, blockTime)) revert Errors.MarketExpired();
/// ------------------------------------------------------------
/// MATH
/// ------------------------------------------------------------
int256 totalAsset = index.syToAsset(market.totalSy);
uint256 timeToExpiry = market.expiry - blockTime;
int256 rateScalar = _getRateScalar(market, timeToExpiry);
/// ------------------------------------------------------------
/// WRITE
/// ------------------------------------------------------------
market.lastLnImpliedRate = _getLnImpliedRate(
market.totalPt,
totalAsset,
rateScalar,
initialAnchor,
timeToExpiry
);
}
}// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.1.0) (utils/Panic.sol)
pragma solidity ^0.8.20;
/**
* @dev Helper library for emitting standardized panic codes.
*
* ```solidity
* contract Example {
* using Panic for uint256;
*
* // Use any of the declared internal constants
* function foo() { Panic.GENERIC.panic(); }
*
* // Alternatively
* function foo() { Panic.panic(Panic.GENERIC); }
* }
* ```
*
* Follows the list from https://github.com/ethereum/solidity/blob/v0.8.24/libsolutil/ErrorCodes.h[libsolutil].
*
* _Available since v5.1._
*/
// slither-disable-next-line unused-state
library Panic {
/// @dev generic / unspecified error
uint256 internal constant GENERIC = 0x00;
/// @dev used by the assert() builtin
uint256 internal constant ASSERT = 0x01;
/// @dev arithmetic underflow or overflow
uint256 internal constant UNDER_OVERFLOW = 0x11;
/// @dev division or modulo by zero
uint256 internal constant DIVISION_BY_ZERO = 0x12;
/// @dev enum conversion error
uint256 internal constant ENUM_CONVERSION_ERROR = 0x21;
/// @dev invalid encoding in storage
uint256 internal constant STORAGE_ENCODING_ERROR = 0x22;
/// @dev empty array pop
uint256 internal constant EMPTY_ARRAY_POP = 0x31;
/// @dev array out of bounds access
uint256 internal constant ARRAY_OUT_OF_BOUNDS = 0x32;
/// @dev resource error (too large allocation or too large array)
uint256 internal constant RESOURCE_ERROR = 0x41;
/// @dev calling invalid internal function
uint256 internal constant INVALID_INTERNAL_FUNCTION = 0x51;
/// @dev Reverts with a panic code. Recommended to use with
/// the internal constants with predefined codes.
function panic(uint256 code) internal pure {
assembly ("memory-safe") {
mstore(0x00, 0x4e487b71)
mstore(0x20, code)
revert(0x1c, 0x24)
}
}
}// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.0.0) (proxy/utils/Initializable.sol)
pragma solidity ^0.8.20;
/**
* @dev This is a base contract to aid in writing upgradeable contracts, or any kind of contract that will be deployed
* behind a proxy. Since proxied contracts do not make use of a constructor, it's common to move constructor logic to an
* external initializer function, usually called `initialize`. It then becomes necessary to protect this initializer
* function so it can only be called once. The {initializer} modifier provided by this contract will have this effect.
*
* The initialization functions use a version number. Once a version number is used, it is consumed and cannot be
* reused. This mechanism prevents re-execution of each "step" but allows the creation of new initialization steps in
* case an upgrade adds a module that needs to be initialized.
*
* For example:
*
* [.hljs-theme-light.nopadding]
* ```solidity
* contract MyToken is ERC20Upgradeable {
* function initialize() initializer public {
* __ERC20_init("MyToken", "MTK");
* }
* }
*
* contract MyTokenV2 is MyToken, ERC20PermitUpgradeable {
* function initializeV2() reinitializer(2) public {
* __ERC20Permit_init("MyToken");
* }
* }
* ```
*
* TIP: To avoid leaving the proxy in an uninitialized state, the initializer function should be called as early as
* possible by providing the encoded function call as the `_data` argument to {ERC1967Proxy-constructor}.
*
* CAUTION: When used with inheritance, manual care must be taken to not invoke a parent initializer twice, or to ensure
* that all initializers are idempotent. This is not verified automatically as constructors are by Solidity.
*
* [CAUTION]
* ====
* Avoid leaving a contract uninitialized.
*
* An uninitialized contract can be taken over by an attacker. This applies to both a proxy and its implementation
* contract, which may impact the proxy. To prevent the implementation contract from being used, you should invoke
* the {_disableInitializers} function in the constructor to automatically lock it when it is deployed:
*
* [.hljs-theme-light.nopadding]
* ```
* /// @custom:oz-upgrades-unsafe-allow constructor
* constructor() {
* _disableInitializers();
* }
* ```
* ====
*/
abstract contract Initializable {
/**
* @dev Storage of the initializable contract.
*
* It's implemented on a custom ERC-7201 namespace to reduce the risk of storage collisions
* when using with upgradeable contracts.
*
* @custom:storage-location erc7201:openzeppelin.storage.Initializable
*/
struct InitializableStorage {
/**
* @dev Indicates that the contract has been initialized.
*/
uint64 _initialized;
/**
* @dev Indicates that the contract is in the process of being initialized.
*/
bool _initializing;
}
// keccak256(abi.encode(uint256(keccak256("openzeppelin.storage.Initializable")) - 1)) & ~bytes32(uint256(0xff))
bytes32 private constant INITIALIZABLE_STORAGE = 0xf0c57e16840df040f15088dc2f81fe391c3923bec73e23a9662efc9c229c6a00;
/**
* @dev The contract is already initialized.
*/
error InvalidInitialization();
/**
* @dev The contract is not initializing.
*/
error NotInitializing();
/**
* @dev Triggered when the contract has been initialized or reinitialized.
*/
event Initialized(uint64 version);
/**
* @dev A modifier that defines a protected initializer function that can be invoked at most once. In its scope,
* `onlyInitializing` functions can be used to initialize parent contracts.
*
* Similar to `reinitializer(1)`, except that in the context of a constructor an `initializer` may be invoked any
* number of times. This behavior in the constructor can be useful during testing and is not expected to be used in
* production.
*
* Emits an {Initialized} event.
*/
modifier initializer() {
// solhint-disable-next-line var-name-mixedcase
InitializableStorage storage $ = _getInitializableStorage();
// Cache values to avoid duplicated sloads
bool isTopLevelCall = !$._initializing;
uint64 initialized = $._initialized;
// Allowed calls:
// - initialSetup: the contract is not in the initializing state and no previous version was
// initialized
// - construction: the contract is initialized at version 1 (no reininitialization) and the
// current contract is just being deployed
bool initialSetup = initialized == 0 && isTopLevelCall;
bool construction = initialized == 1 && address(this).code.length == 0;
if (!initialSetup && !construction) {
revert InvalidInitialization();
}
$._initialized = 1;
if (isTopLevelCall) {
$._initializing = true;
}
_;
if (isTopLevelCall) {
$._initializing = false;
emit Initialized(1);
}
}
/**
* @dev A modifier that defines a protected reinitializer function that can be invoked at most once, and only if the
* contract hasn't been initialized to a greater version before. In its scope, `onlyInitializing` functions can be
* used to initialize parent contracts.
*
* A reinitializer may be used after the original initialization step. This is essential to configure modules that
* are added through upgrades and that require initialization.
*
* When `version` is 1, this modifier is similar to `initializer`, except that functions marked with `reinitializer`
* cannot be nested. If one is invoked in the context of another, execution will revert.
*
* Note that versions can jump in increments greater than 1; this implies that if multiple reinitializers coexist in
* a contract, executing them in the right order is up to the developer or operator.
*
* WARNING: Setting the version to 2**64 - 1 will prevent any future reinitialization.
*
* Emits an {Initialized} event.
*/
modifier reinitializer(uint64 version) {
// solhint-disable-next-line var-name-mixedcase
InitializableStorage storage $ = _getInitializableStorage();
if ($._initializing || $._initialized >= version) {
revert InvalidInitialization();
}
$._initialized = version;
$._initializing = true;
_;
$._initializing = false;
emit Initialized(version);
}
/**
* @dev Modifier to protect an initialization function so that it can only be invoked by functions with the
* {initializer} and {reinitializer} modifiers, directly or indirectly.
*/
modifier onlyInitializing() {
_checkInitializing();
_;
}
/**
* @dev Reverts if the contract is not in an initializing state. See {onlyInitializing}.
*/
function _checkInitializing() internal view virtual {
if (!_isInitializing()) {
revert NotInitializing();
}
}
/**
* @dev Locks the contract, preventing any future reinitialization. This cannot be part of an initializer call.
* Calling this in the constructor of a contract will prevent that contract from being initialized or reinitialized
* to any version. It is recommended to use this to lock implementation contracts that are designed to be called
* through proxies.
*
* Emits an {Initialized} event the first time it is successfully executed.
*/
function _disableInitializers() internal virtual {
// solhint-disable-next-line var-name-mixedcase
InitializableStorage storage $ = _getInitializableStorage();
if ($._initializing) {
revert InvalidInitialization();
}
if ($._initialized != type(uint64).max) {
$._initialized = type(uint64).max;
emit Initialized(type(uint64).max);
}
}
/**
* @dev Returns the highest version that has been initialized. See {reinitializer}.
*/
function _getInitializedVersion() internal view returns (uint64) {
return _getInitializableStorage()._initialized;
}
/**
* @dev Returns `true` if the contract is currently initializing. See {onlyInitializing}.
*/
function _isInitializing() internal view returns (bool) {
return _getInitializableStorage()._initializing;
}
/**
* @dev Returns a pointer to the storage namespace.
*/
// solhint-disable-next-line var-name-mixedcase
function _getInitializableStorage() private pure returns (InitializableStorage storage $) {
assembly {
$.slot := INITIALIZABLE_STORAGE
}
}
}// SPDX-License-Identifier: MIT
// OpenZeppelin Contracts (last updated v5.1.0) (token/ERC20/IERC20.sol)
pragma solidity ^0.8.20;
/**
* @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);
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
interface IRewardManager {
function userReward(address token, address user) external view returns (uint128 index, uint128 accrued);
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
interface IPInterestManagerYT {
event CollectInterestFee(uint256 amountInterestFee);
function userInterest(address user) external view returns (uint128 lastPYIndex, uint128 accruedInterest);
}// SPDX-License-Identifier: GPL-3.0-or-later
// Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated
// documentation files (the “Software”), to deal in the Software without restriction, including without limitation the
// rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to
// permit persons to whom the Software is furnished to do so, subject to the following conditions:
// The above copyright notice and this permission notice shall be included in all copies or substantial portions of the
// Software.
// THE SOFTWARE IS PROVIDED “AS IS”, WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE
// WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
// COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR
// OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
pragma solidity ^0.8.0;
/* solhint-disable */
/**
* @dev Exponentiation and logarithm functions for 18 decimal fixed point numbers (both base and exponent/argument).
*
* Exponentiation and logarithm with arbitrary bases (x^y and log_x(y)) are implemented by conversion to natural
* exponentiation and logarithm (where the base is Euler's number).
*
* @author Fernando Martinelli - @fernandomartinelli
* @author Sergio Yuhjtman - @sergioyuhjtman
* @author Daniel Fernandez - @dmf7z
*/
library LogExpMath {
// All fixed point multiplications and divisions are inlined. This means we need to divide by ONE when multiplying
// two numbers, and multiply by ONE when dividing them.
// All arguments and return values are 18 decimal fixed point numbers.
int256 constant ONE_18 = 1e18;
// Internally, intermediate values are computed with higher precision as 20 decimal fixed point numbers, and in the
// case of ln36, 36 decimals.
int256 constant ONE_20 = 1e20;
int256 constant ONE_36 = 1e36;
// The domain of natural exponentiation is bound by the word size and number of decimals used.
//
// Because internally the result will be stored using 20 decimals, the largest possible result is
// (2^255 - 1) / 10^20, which makes the largest exponent ln((2^255 - 1) / 10^20) = 130.700829182905140221.
// The smallest possible result is 10^(-18), which makes largest negative argument
// ln(10^(-18)) = -41.446531673892822312.
// We use 130.0 and -41.0 to have some safety margin.
int256 constant MAX_NATURAL_EXPONENT = 130e18;
int256 constant MIN_NATURAL_EXPONENT = -41e18;
// Bounds for ln_36's argument. Both ln(0.9) and ln(1.1) can be represented with 36 decimal places in a fixed point
// 256 bit integer.
int256 constant LN_36_LOWER_BOUND = ONE_18 - 1e17;
int256 constant LN_36_UPPER_BOUND = ONE_18 + 1e17;
uint256 constant MILD_EXPONENT_BOUND = 2 ** 254 / uint256(ONE_20);
// 18 decimal constants
int256 constant x0 = 128000000000000000000; // 2ˆ7
int256 constant a0 = 38877084059945950922200000000000000000000000000000000000; // eˆ(x0) (no decimals)
int256 constant x1 = 64000000000000000000; // 2ˆ6
int256 constant a1 = 6235149080811616882910000000; // eˆ(x1) (no decimals)
// 20 decimal constants
int256 constant x2 = 3200000000000000000000; // 2ˆ5
int256 constant a2 = 7896296018268069516100000000000000; // eˆ(x2)
int256 constant x3 = 1600000000000000000000; // 2ˆ4
int256 constant a3 = 888611052050787263676000000; // eˆ(x3)
int256 constant x4 = 800000000000000000000; // 2ˆ3
int256 constant a4 = 298095798704172827474000; // eˆ(x4)
int256 constant x5 = 400000000000000000000; // 2ˆ2
int256 constant a5 = 5459815003314423907810; // eˆ(x5)
int256 constant x6 = 200000000000000000000; // 2ˆ1
int256 constant a6 = 738905609893065022723; // eˆ(x6)
int256 constant x7 = 100000000000000000000; // 2ˆ0
int256 constant a7 = 271828182845904523536; // eˆ(x7)
int256 constant x8 = 50000000000000000000; // 2ˆ-1
int256 constant a8 = 164872127070012814685; // eˆ(x8)
int256 constant x9 = 25000000000000000000; // 2ˆ-2
int256 constant a9 = 128402541668774148407; // eˆ(x9)
int256 constant x10 = 12500000000000000000; // 2ˆ-3
int256 constant a10 = 113314845306682631683; // eˆ(x10)
int256 constant x11 = 6250000000000000000; // 2ˆ-4
int256 constant a11 = 106449445891785942956; // eˆ(x11)
/**
* @dev Natural exponentiation (e^x) with signed 18 decimal fixed point exponent.
*
* Reverts if `x` is smaller than MIN_NATURAL_EXPONENT, or larger than `MAX_NATURAL_EXPONENT`.
*/
function exp(int256 x) internal pure returns (int256) {
unchecked {
require(x >= MIN_NATURAL_EXPONENT && x <= MAX_NATURAL_EXPONENT, "Invalid exponent");
if (x < 0) {
// We only handle positive exponents: e^(-x) is computed as 1 / e^x. We can safely make x positive since it
// fits in the signed 256 bit range (as it is larger than MIN_NATURAL_EXPONENT).
// Fixed point division requires multiplying by ONE_18.
return ((ONE_18 * ONE_18) / exp(-x));
}
// First, we use the fact that e^(x+y) = e^x * e^y to decompose x into a sum of powers of two, which we call x_n,
// where x_n == 2^(7 - n), and e^x_n = a_n has been precomputed. We choose the first x_n, x0, to equal 2^7
// because all larger powers are larger than MAX_NATURAL_EXPONENT, and therefore not present in the
// decomposition.
// At the end of this process we will have the product of all e^x_n = a_n that apply, and the remainder of this
// decomposition, which will be lower than the smallest x_n.
// exp(x) = k_0 * a_0 * k_1 * a_1 * ... + k_n * a_n * exp(remainder), where each k_n equals either 0 or 1.
// We mutate x by subtracting x_n, making it the remainder of the decomposition.
// The first two a_n (e^(2^7) and e^(2^6)) are too large if stored as 18 decimal numbers, and could cause
// intermediate overflows. Instead we store them as plain integers, with 0 decimals.
// Additionally, x0 + x1 is larger than MAX_NATURAL_EXPONENT, which means they will not both be present in the
// decomposition.
// For each x_n, we test if that term is present in the decomposition (if x is larger than it), and if so deduct
// it and compute the accumulated product.
int256 firstAN;
if (x >= x0) {
x -= x0;
firstAN = a0;
} else if (x >= x1) {
x -= x1;
firstAN = a1;
} else {
firstAN = 1; // One with no decimal places
}
// We now transform x into a 20 decimal fixed point number, to have enhanced precision when computing the
// smaller terms.
x *= 100;
// `product` is the accumulated product of all a_n (except a0 and a1), which starts at 20 decimal fixed point
// one. Recall that fixed point multiplication requires dividing by ONE_20.
int256 product = ONE_20;
if (x >= x2) {
x -= x2;
product = (product * a2) / ONE_20;
}
if (x >= x3) {
x -= x3;
product = (product * a3) / ONE_20;
}
if (x >= x4) {
x -= x4;
product = (product * a4) / ONE_20;
}
if (x >= x5) {
x -= x5;
product = (product * a5) / ONE_20;
}
if (x >= x6) {
x -= x6;
product = (product * a6) / ONE_20;
}
if (x >= x7) {
x -= x7;
product = (product * a7) / ONE_20;
}
if (x >= x8) {
x -= x8;
product = (product * a8) / ONE_20;
}
if (x >= x9) {
x -= x9;
product = (product * a9) / ONE_20;
}
// x10 and x11 are unnecessary here since we have high enough precision already.
// Now we need to compute e^x, where x is small (in particular, it is smaller than x9). We use the Taylor series
// expansion for e^x: 1 + x + (x^2 / 2!) + (x^3 / 3!) + ... + (x^n / n!).
int256 seriesSum = ONE_20; // The initial one in the sum, with 20 decimal places.
int256 term; // Each term in the sum, where the nth term is (x^n / n!).
// The first term is simply x.
term = x;
seriesSum += term;
// Each term (x^n / n!) equals the previous one times x, divided by n. Since x is a fixed point number,
// multiplying by it requires dividing by ONE_20, but dividing by the non-fixed point n values does not.
term = ((term * x) / ONE_20) / 2;
seriesSum += term;
term = ((term * x) / ONE_20) / 3;
seriesSum += term;
term = ((term * x) / ONE_20) / 4;
seriesSum += term;
term = ((term * x) / ONE_20) / 5;
seriesSum += term;
term = ((term * x) / ONE_20) / 6;
seriesSum += term;
term = ((term * x) / ONE_20) / 7;
seriesSum += term;
term = ((term * x) / ONE_20) / 8;
seriesSum += term;
term = ((term * x) / ONE_20) / 9;
seriesSum += term;
term = ((term * x) / ONE_20) / 10;
seriesSum += term;
term = ((term * x) / ONE_20) / 11;
seriesSum += term;
term = ((term * x) / ONE_20) / 12;
seriesSum += term;
// 12 Taylor terms are sufficient for 18 decimal precision.
// We now have the first a_n (with no decimals), and the product of all other a_n present, and the Taylor
// approximation of the exponentiation of the remainder (both with 20 decimals). All that remains is to multiply
// all three (one 20 decimal fixed point multiplication, dividing by ONE_20, and one integer multiplication),
// and then drop two digits to return an 18 decimal value.
return (((product * seriesSum) / ONE_20) * firstAN) / 100;
}
}
/**
* @dev Natural logarithm (ln(a)) with signed 18 decimal fixed point argument.
*/
function ln(int256 a) internal pure returns (int256) {
unchecked {
// The real natural logarithm is not defined for negative numbers or zero.
require(a > 0, "out of bounds");
if (LN_36_LOWER_BOUND < a && a < LN_36_UPPER_BOUND) {
return _ln_36(a) / ONE_18;
} else {
return _ln(a);
}
}
}
/**
* @dev Exponentiation (x^y) with unsigned 18 decimal fixed point base and exponent.
*
* Reverts if ln(x) * y is smaller than `MIN_NATURAL_EXPONENT`, or larger than `MAX_NATURAL_EXPONENT`.
*/
function pow(uint256 x, uint256 y) internal pure returns (uint256) {
unchecked {
if (y == 0) {
// We solve the 0^0 indetermination by making it equal one.
return uint256(ONE_18);
}
if (x == 0) {
return 0;
}
// Instead of computing x^y directly, we instead rely on the properties of logarithms and exponentiation to
// arrive at that r`esult. In particular, exp(ln(x)) = x, and ln(x^y) = y * ln(x). This means
// x^y = exp(y * ln(x)).
// The ln function takes a signed value, so we need to make sure x fits in the signed 256 bit range.
require(x < 2 ** 255, "x out of bounds");
int256 x_int256 = int256(x);
// We will compute y * ln(x) in a single step. Depending on the value of x, we can either use ln or ln_36. In
// both cases, we leave the division by ONE_18 (due to fixed point multiplication) to the end.
// This prevents y * ln(x) from overflowing, and at the same time guarantees y fits in the signed 256 bit range.
require(y < MILD_EXPONENT_BOUND, "y out of bounds");
int256 y_int256 = int256(y);
int256 logx_times_y;
if (LN_36_LOWER_BOUND < x_int256 && x_int256 < LN_36_UPPER_BOUND) {
int256 ln_36_x = _ln_36(x_int256);
// ln_36_x has 36 decimal places, so multiplying by y_int256 isn't as straightforward, since we can't just
// bring y_int256 to 36 decimal places, as it might overflow. Instead, we perform two 18 decimal
// multiplications and add the results: one with the first 18 decimals of ln_36_x, and one with the
// (downscaled) last 18 decimals.
logx_times_y = ((ln_36_x / ONE_18) * y_int256 + ((ln_36_x % ONE_18) * y_int256) / ONE_18);
} else {
logx_times_y = _ln(x_int256) * y_int256;
}
logx_times_y /= ONE_18;
// Finally, we compute exp(y * ln(x)) to arrive at x^y
require(
MIN_NATURAL_EXPONENT <= logx_times_y && logx_times_y <= MAX_NATURAL_EXPONENT,
"product out of bounds"
);
return uint256(exp(logx_times_y));
}
}
/**
* @dev Internal natural logarithm (ln(a)) with signed 18 decimal fixed point argument.
*/
function _ln(int256 a) private pure returns (int256) {
unchecked {
if (a < ONE_18) {
// Since ln(a^k) = k * ln(a), we can compute ln(a) as ln(a) = ln((1/a)^(-1)) = - ln((1/a)). If a is less
// than one, 1/a will be greater than one, and this if statement will not be entered in the recursive call.
// Fixed point division requires multiplying by ONE_18.
return (-_ln((ONE_18 * ONE_18) / a));
}
// First, we use the fact that ln^(a * b) = ln(a) + ln(b) to decompose ln(a) into a sum of powers of two, which
// we call x_n, where x_n == 2^(7 - n), which are the natural logarithm of precomputed quantities a_n (that is,
// ln(a_n) = x_n). We choose the first x_n, x0, to equal 2^7 because the exponential of all larger powers cannot
// be represented as 18 fixed point decimal numbers in 256 bits, and are therefore larger than a.
// At the end of this process we will have the sum of all x_n = ln(a_n) that apply, and the remainder of this
// decomposition, which will be lower than the smallest a_n.
// ln(a) = k_0 * x_0 + k_1 * x_1 + ... + k_n * x_n + ln(remainder), where each k_n equals either 0 or 1.
// We mutate a by subtracting a_n, making it the remainder of the decomposition.
// For reasons related to how `exp` works, the first two a_n (e^(2^7) and e^(2^6)) are not stored as fixed point
// numbers with 18 decimals, but instead as plain integers with 0 decimals, so we need to multiply them by
// ONE_18 to convert them to fixed point.
// For each a_n, we test if that term is present in the decomposition (if a is larger than it), and if so divide
// by it and compute the accumulated sum.
int256 sum = 0;
if (a >= a0 * ONE_18) {
a /= a0; // Integer, not fixed point division
sum += x0;
}
if (a >= a1 * ONE_18) {
a /= a1; // Integer, not fixed point division
sum += x1;
}
// All other a_n and x_n are stored as 20 digit fixed point numbers, so we convert the sum and a to this format.
sum *= 100;
a *= 100;
// Because further a_n are 20 digit fixed point numbers, we multiply by ONE_20 when dividing by them.
if (a >= a2) {
a = (a * ONE_20) / a2;
sum += x2;
}
if (a >= a3) {
a = (a * ONE_20) / a3;
sum += x3;
}
if (a >= a4) {
a = (a * ONE_20) / a4;
sum += x4;
}
if (a >= a5) {
a = (a * ONE_20) / a5;
sum += x5;
}
if (a >= a6) {
a = (a * ONE_20) / a6;
sum += x6;
}
if (a >= a7) {
a = (a * ONE_20) / a7;
sum += x7;
}
if (a >= a8) {
a = (a * ONE_20) / a8;
sum += x8;
}
if (a >= a9) {
a = (a * ONE_20) / a9;
sum += x9;
}
if (a >= a10) {
a = (a * ONE_20) / a10;
sum += x10;
}
if (a >= a11) {
a = (a * ONE_20) / a11;
sum += x11;
}
// a is now a small number (smaller than a_11, which roughly equals 1.06). This means we can use a Taylor series
// that converges rapidly for values of `a` close to one - the same one used in ln_36.
// Let z = (a - 1) / (a + 1).
// ln(a) = 2 * (z + z^3 / 3 + z^5 / 5 + z^7 / 7 + ... + z^(2 * n + 1) / (2 * n + 1))
// Recall that 20 digit fixed point division requires multiplying by ONE_20, and multiplication requires
// division by ONE_20.
int256 z = ((a - ONE_20) * ONE_20) / (a + ONE_20);
int256 z_squared = (z * z) / ONE_20;
// num is the numerator of the series: the z^(2 * n + 1) term
int256 num = z;
// seriesSum holds the accumulated sum of each term in the series, starting with the initial z
int256 seriesSum = num;
// In each step, the numerator is multiplied by z^2
num = (num * z_squared) / ONE_20;
seriesSum += num / 3;
num = (num * z_squared) / ONE_20;
seriesSum += num / 5;
num = (num * z_squared) / ONE_20;
seriesSum += num / 7;
num = (num * z_squared) / ONE_20;
seriesSum += num / 9;
num = (num * z_squared) / ONE_20;
seriesSum += num / 11;
// 6 Taylor terms are sufficient for 36 decimal precision.
// Finally, we multiply by 2 (non fixed point) to compute ln(remainder)
seriesSum *= 2;
// We now have the sum of all x_n present, and the Taylor approximation of the logarithm of the remainder (both
// with 20 decimals). All that remains is to sum these two, and then drop two digits to return a 18 decimal
// value.
return (sum + seriesSum) / 100;
}
}
/**
* @dev Intrnal high precision (36 decimal places) natural logarithm (ln(x)) with signed 18 decimal fixed point argument,
* for x close to one.
*
* Should only be used if x is between LN_36_LOWER_BOUND and LN_36_UPPER_BOUND.
*/
function _ln_36(int256 x) private pure returns (int256) {
unchecked {
// Since ln(1) = 0, a value of x close to one will yield a very small result, which makes using 36 digits
// worthwhile.
// First, we transform x to a 36 digit fixed point value.
x *= ONE_18;
// We will use the following Taylor expansion, which converges very rapidly. Let z = (x - 1) / (x + 1).
// ln(x) = 2 * (z + z^3 / 3 + z^5 / 5 + z^7 / 7 + ... + z^(2 * n + 1) / (2 * n + 1))
// Recall that 36 digit fixed point division requires multiplying by ONE_36, and multiplication requires
// division by ONE_36.
int256 z = ((x - ONE_36) * ONE_36) / (x + ONE_36);
int256 z_squared = (z * z) / ONE_36;
// num is the numerator of the series: the z^(2 * n + 1) term
int256 num = z;
// seriesSum holds the accumulated sum of each term in the series, starting with the initial z
int256 seriesSum = num;
// In each step, the numerator is multiplied by z^2
num = (num * z_squared) / ONE_36;
seriesSum += num / 3;
num = (num * z_squared) / ONE_36;
seriesSum += num / 5;
num = (num * z_squared) / ONE_36;
seriesSum += num / 7;
num = (num * z_squared) / ONE_36;
seriesSum += num / 9;
num = (num * z_squared) / ONE_36;
seriesSum += num / 11;
num = (num * z_squared) / ONE_36;
seriesSum += num / 13;
num = (num * z_squared) / ONE_36;
seriesSum += num / 15;
// 8 Taylor terms are sufficient for 36 decimal precision.
// All that remains is multiplying by 2 (non fixed point).
return seriesSum * 2;
}
}
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
import "../../interfaces/IPYieldToken.sol";
import "../../interfaces/IPPrincipalToken.sol";
import "./SYUtils.sol";
import "../libraries/math/PMath.sol";
type PYIndex is uint256;
library PYIndexLib {
using PMath for uint256;
using PMath for int256;
function newIndex(IPYieldToken YT) internal returns (PYIndex) {
return PYIndex.wrap(YT.pyIndexCurrent());
}
function syToAsset(PYIndex index, uint256 syAmount) internal pure returns (uint256) {
return SYUtils.syToAsset(PYIndex.unwrap(index), syAmount);
}
function assetToSy(PYIndex index, uint256 assetAmount) internal pure returns (uint256) {
return SYUtils.assetToSy(PYIndex.unwrap(index), assetAmount);
}
function assetToSyUp(PYIndex index, uint256 assetAmount) internal pure returns (uint256) {
return SYUtils.assetToSyUp(PYIndex.unwrap(index), assetAmount);
}
function syToAssetUp(PYIndex index, uint256 syAmount) internal pure returns (uint256) {
uint256 _index = PYIndex.unwrap(index);
return SYUtils.syToAssetUp(_index, syAmount);
}
function syToAsset(PYIndex index, int256 syAmount) internal pure returns (int256) {
int256 sign = syAmount < 0 ? int256(-1) : int256(1);
return sign * (SYUtils.syToAsset(PYIndex.unwrap(index), syAmount.abs())).Int();
}
function assetToSy(PYIndex index, int256 assetAmount) internal pure returns (int256) {
int256 sign = assetAmount < 0 ? int256(-1) : int256(1);
return sign * (SYUtils.assetToSy(PYIndex.unwrap(index), assetAmount.abs())).Int();
}
function assetToSyUp(PYIndex index, int256 assetAmount) internal pure returns (int256) {
int256 sign = assetAmount < 0 ? int256(-1) : int256(1);
return sign * (SYUtils.assetToSyUp(PYIndex.unwrap(index), assetAmount.abs())).Int();
}
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
library MiniHelpers {
function isCurrentlyExpired(uint256 expiry) internal view returns (bool) {
return (expiry <= block.timestamp);
}
function isExpired(uint256 expiry, uint256 blockTime) internal pure returns (bool) {
return (expiry <= blockTime);
}
function isTimeInThePast(uint256 timestamp) internal view returns (bool) {
return (timestamp <= block.timestamp); // same definition as isCurrentlyExpired
}
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
library Errors {
// BulkSeller
error BulkInsufficientSyForTrade(uint256 currentAmount, uint256 requiredAmount);
error BulkInsufficientTokenForTrade(uint256 currentAmount, uint256 requiredAmount);
error BulkInSufficientSyOut(uint256 actualSyOut, uint256 requiredSyOut);
error BulkInSufficientTokenOut(uint256 actualTokenOut, uint256 requiredTokenOut);
error BulkInsufficientSyReceived(uint256 actualBalance, uint256 requiredBalance);
error BulkNotMaintainer();
error BulkNotAdmin();
error BulkSellerAlreadyExisted(address token, address SY, address bulk);
error BulkSellerInvalidToken(address token, address SY);
error BulkBadRateTokenToSy(uint256 actualRate, uint256 currentRate, uint256 eps);
error BulkBadRateSyToToken(uint256 actualRate, uint256 currentRate, uint256 eps);
// APPROX
error ApproxFail();
error ApproxParamsInvalid(uint256 guessMin, uint256 guessMax, uint256 eps);
error ApproxBinarySearchInputInvalid(
uint256 approxGuessMin,
uint256 approxGuessMax,
uint256 minGuessMin,
uint256 maxGuessMax
);
// MARKET + MARKET MATH CORE
error MarketExpired();
error MarketZeroAmountsInput();
error MarketZeroAmountsOutput();
error MarketZeroLnImpliedRate();
error MarketInsufficientPtForTrade(int256 currentAmount, int256 requiredAmount);
error MarketInsufficientPtReceived(uint256 actualBalance, uint256 requiredBalance);
error MarketInsufficientSyReceived(uint256 actualBalance, uint256 requiredBalance);
error MarketZeroTotalPtOrTotalAsset(int256 totalPt, int256 totalAsset);
error MarketExchangeRateBelowOne(int256 exchangeRate);
error MarketProportionMustNotEqualOne();
error MarketRateScalarBelowZero(int256 rateScalar);
error MarketScalarRootBelowZero(int256 scalarRoot);
error MarketProportionTooHigh(int256 proportion, int256 maxProportion);
error OracleUninitialized();
error OracleTargetTooOld(uint32 target, uint32 oldest);
error OracleZeroCardinality();
error MarketFactoryExpiredPt();
error MarketFactoryInvalidPt();
error MarketFactoryMarketExists();
error MarketFactoryLnFeeRateRootTooHigh(uint80 lnFeeRateRoot, uint256 maxLnFeeRateRoot);
error MarketFactoryOverriddenFeeTooHigh(uint80 overriddenFee, uint256 marketLnFeeRateRoot);
error MarketFactoryReserveFeePercentTooHigh(uint8 reserveFeePercent, uint8 maxReserveFeePercent);
error MarketFactoryZeroTreasury();
error MarketFactoryInitialAnchorTooLow(int256 initialAnchor, int256 minInitialAnchor);
error MFNotPendleMarket(address addr);
// ROUTER
error RouterInsufficientLpOut(uint256 actualLpOut, uint256 requiredLpOut);
error RouterInsufficientSyOut(uint256 actualSyOut, uint256 requiredSyOut);
error RouterInsufficientPtOut(uint256 actualPtOut, uint256 requiredPtOut);
error RouterInsufficientYtOut(uint256 actualYtOut, uint256 requiredYtOut);
error RouterInsufficientPYOut(uint256 actualPYOut, uint256 requiredPYOut);
error RouterInsufficientTokenOut(uint256 actualTokenOut, uint256 requiredTokenOut);
error RouterInsufficientSyRepay(uint256 actualSyRepay, uint256 requiredSyRepay);
error RouterInsufficientPtRepay(uint256 actualPtRepay, uint256 requiredPtRepay);
error RouterNotAllSyUsed(uint256 netSyDesired, uint256 netSyUsed);
error RouterTimeRangeZero();
error RouterCallbackNotPendleMarket(address caller);
error RouterInvalidAction(bytes4 selector);
error RouterInvalidFacet(address facet);
error RouterKyberSwapDataZero();
error SimulationResults(bool success, bytes res);
// YIELD CONTRACT
error YCExpired();
error YCNotExpired();
error YieldContractInsufficientSy(uint256 actualSy, uint256 requiredSy);
error YCNothingToRedeem();
error YCPostExpiryDataNotSet();
error YCNoFloatingSy();
// YieldFactory
error YCFactoryInvalidExpiry();
error YCFactoryYieldContractExisted();
error YCFactoryZeroExpiryDivisor();
error YCFactoryZeroTreasury();
error YCFactoryInterestFeeRateTooHigh(uint256 interestFeeRate, uint256 maxInterestFeeRate);
error YCFactoryRewardFeeRateTooHigh(uint256 newRewardFeeRate, uint256 maxRewardFeeRate);
// SY
error SYInvalidTokenIn(address token);
error SYInvalidTokenOut(address token);
error SYZeroDeposit();
error SYZeroRedeem();
error SYInsufficientSharesOut(uint256 actualSharesOut, uint256 requiredSharesOut);
error SYInsufficientTokenOut(uint256 actualTokenOut, uint256 requiredTokenOut);
// SY-specific
error SYQiTokenMintFailed(uint256 errCode);
error SYQiTokenRedeemFailed(uint256 errCode);
error SYQiTokenRedeemRewardsFailed(uint256 rewardAccruedType0, uint256 rewardAccruedType1);
error SYQiTokenBorrowRateTooHigh(uint256 borrowRate, uint256 borrowRateMax);
error SYCurveInvalidPid();
error SYCurve3crvPoolNotFound();
error SYApeDepositAmountTooSmall(uint256 amountDeposited);
error SYBalancerInvalidPid();
error SYInvalidRewardToken(address token);
error SYStargateRedeemCapExceeded(uint256 amountLpDesired, uint256 amountLpRedeemable);
error SYBalancerReentrancy();
error NotFromTrustedRemote(uint16 srcChainId, bytes path);
error ApxETHNotEnoughBuffer();
// Liquidity Mining
error VCInactivePool(address pool);
error VCPoolAlreadyActive(address pool);
error VCZeroVePendle(address user);
error VCExceededMaxWeight(uint256 totalWeight, uint256 maxWeight);
error VCEpochNotFinalized(uint256 wTime);
error VCPoolAlreadyAddAndRemoved(address pool);
error VEInvalidNewExpiry(uint256 newExpiry);
error VEExceededMaxLockTime();
error VEInsufficientLockTime();
error VENotAllowedReduceExpiry();
error VEZeroAmountLocked();
error VEPositionNotExpired();
error VEZeroPosition();
error VEZeroSlope(uint128 bias, uint128 slope);
error VEReceiveOldSupply(uint256 msgTime);
error GCNotPendleMarket(address caller);
error GCNotVotingController(address caller);
error InvalidWTime(uint256 wTime);
error ExpiryInThePast(uint256 expiry);
error ChainNotSupported(uint256 chainId);
error FDTotalAmountFundedNotMatch(uint256 actualTotalAmount, uint256 expectedTotalAmount);
error FDEpochLengthMismatch();
error FDInvalidPool(address pool);
error FDPoolAlreadyExists(address pool);
error FDInvalidNewFinishedEpoch(uint256 oldFinishedEpoch, uint256 newFinishedEpoch);
error FDInvalidStartEpoch(uint256 startEpoch);
error FDInvalidWTimeFund(uint256 lastFunded, uint256 wTime);
error FDFutureFunding(uint256 lastFunded, uint256 currentWTime);
error BDInvalidEpoch(uint256 epoch, uint256 startTime);
// Cross-Chain
error MsgNotFromSendEndpoint(uint16 srcChainId, bytes path);
error MsgNotFromReceiveEndpoint(address sender);
error InsufficientFeeToSendMsg(uint256 currentFee, uint256 requiredFee);
error ApproxDstExecutionGasNotSet();
error InvalidRetryData();
// GENERIC MSG
error ArrayLengthMismatch();
error ArrayEmpty();
error ArrayOutOfBounds();
error ZeroAddress();
error FailedToSendEther();
error InvalidMerkleProof();
error OnlyLayerZeroEndpoint();
error OnlyYT();
error OnlyYCFactory();
error OnlyWhitelisted();
// Swap Aggregator
error SAInsufficientTokenIn(address tokenIn, uint256 amountExpected, uint256 amountActual);
error UnsupportedSelector(uint256 aggregatorType, bytes4 selector);
}// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.8.0;
library SYUtils {
uint256 internal constant ONE = 1e18;
function syToAsset(uint256 exchangeRate, uint256 syAmount) internal pure returns (uint256) {
return (syAmount * exchangeRate) / ONE;
}
function syToAssetUp(uint256 exchangeRate, uint256 syAmount) internal pure returns (uint256) {
return (syAmount * exchangeRate + ONE - 1) / ONE;
}
function assetToSy(uint256 exchangeRate, uint256 assetAmount) internal pure returns (uint256) {
return (assetAmount * ONE) / exchangeRate;
}
function assetToSyUp(uint256 exchangeRate, uint256 assetAmount) internal pure returns (uint256) {
return (assetAmount * ONE + exchangeRate - 1) / exchangeRate;
}
}{
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],
"optimizer": {
"enabled": true,
"runs": 200
},
"metadata": {
"useLiteralContent": false,
"bytecodeHash": "ipfs",
"appendCBOR": true
},
"outputSelection": {
"*": {
"*": [
"evm.bytecode",
"evm.deployedBytecode",
"devdoc",
"userdoc",
"metadata",
"abi"
]
}
},
"evmVersion": "cancun",
"viaIR": true,
"libraries": {}
}Contract Security Audit
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Contract ABI
API[{"inputs":[{"internalType":"address","name":"pendlePYLpOracle","type":"address"},{"internalType":"address","name":"market","type":"address"},{"internalType":"uint32","name":"duration","type":"uint32"},{"internalType":"address","name":"priceFeed","type":"address"}],"stateMutability":"nonpayable","type":"constructor"},{"inputs":[],"name":"GetRoundDataNotSupported","type":"error"},{"inputs":[],"name":"OracleIsNotReady","type":"error"},{"inputs":[],"name":"PriceIsZero","type":"error"},{"inputs":[{"internalType":"int256","name":"value","type":"int256"}],"name":"SafeCastOverflowedIntToUint","type":"error"},{"inputs":[{"internalType":"uint256","name":"value","type":"uint256"}],"name":"SafeCastOverflowedUintToInt","type":"error"},{"inputs":[],"name":"DURATION","outputs":[{"internalType":"uint32","name":"","type":"uint32"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"MARKET","outputs":[{"internalType":"contract IPMarket","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"PRICE_FEED","outputs":[{"internalType":"contract AggregatorV3Interface","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"PY_LP_ORACLE","outputs":[{"internalType":"contract PendlePYLpOracle","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"decimals","outputs":[{"internalType":"uint8","name":"","type":"uint8"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"description","outputs":[{"internalType":"string","name":"","type":"string"}],"stateMutability":"view","type":"function"},{"inputs":[{"internalType":"uint80","name":"","type":"uint80"}],"name":"getRoundData","outputs":[{"internalType":"uint80","name":"","type":"uint80"},{"internalType":"int256","name":"","type":"int256"},{"internalType":"uint256","name":"","type":"uint256"},{"internalType":"uint256","name":"","type":"uint256"},{"internalType":"uint80","name":"","type":"uint80"}],"stateMutability":"pure","type":"function"},{"inputs":[],"name":"latestRoundData","outputs":[{"internalType":"uint80","name":"roundId","type":"uint80"},{"internalType":"int256","name":"answer","type":"int256"},{"internalType":"uint256","name":"startedAt","type":"uint256"},{"internalType":"uint256","name":"updatedAt","type":"uint256"},{"internalType":"uint80","name":"answeredInRound","type":"uint80"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"version","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"stateMutability":"view","type":"function"}]Contract Creation Code
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Deployed Bytecode
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Constructor Arguments (ABI-Encoded and is the last bytes of the Contract Creation Code above)
0000000000000000000000009a9fa8338dd5e5b2188006f1cd2ef26d921650c2000000000000000000000000461bc2ac3f80801bc11b0f20d63b73fef60c807600000000000000000000000000000000000000000000000000000000000003840000000000000000000000008fffffd4afb6115b954bd326cbe7b4ba576818f6
-----Decoded View---------------
Arg [0] : pendlePYLpOracle (address): 0x9a9Fa8338dd5E5B2188006f1Cd2Ef26d921650C2
Arg [1] : market (address): 0x461bc2ac3f80801BC11B0F20d63B73feF60C8076
Arg [2] : duration (uint32): 900
Arg [3] : priceFeed (address): 0x8fFfFfd4AfB6115b954Bd326cbe7B4BA576818f6
-----Encoded View---------------
4 Constructor Arguments found :
Arg [0] : 0000000000000000000000009a9fa8338dd5e5b2188006f1cd2ef26d921650c2
Arg [1] : 000000000000000000000000461bc2ac3f80801bc11b0f20d63b73fef60c8076
Arg [2] : 0000000000000000000000000000000000000000000000000000000000000384
Arg [3] : 0000000000000000000000008fffffd4afb6115b954bd326cbe7b4ba576818f6
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0x32401387EDCB60CD74E2FCae50B3C542E03B1ec5
Net Worth in USD
$0.00
Net Worth in ETH
0
Multichain Portfolio | 33 Chains
| Chain | Token | Portfolio % | Price | Amount | Value |
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A contract address hosts a smart contract, which is a set of code stored on the blockchain that runs when predetermined conditions are met. Learn more about addresses in our Knowledge Base.