Feature Tip: Add private address tag to any address under My Name Tag !
Overview
TokenID
0
Total Transfers
-
Market
Onchain Market Cap
$0.00
Circulating Supply Market Cap
-
Other Info
Token Contract
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# | Exchange | Pair | Price | 24H Volume | % Volume |
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Contract Name:
PoolProxy
Compiler Version
v0.8.9+commit.e5eed63a
Optimization Enabled:
Yes with 200 runs
Other Settings:
default evmVersion
Contract Source Code (Solidity Standard Json-Input format)
// SPDX-License-Identifier: BUSL-1.1 // For further clarification please see https://license.premia.legal pragma solidity ^0.8.0; import {OwnableStorage} from "@solidstate/contracts/access/OwnableStorage.sol"; import {ERC165Storage} from "@solidstate/contracts/introspection/ERC165Storage.sol"; import {Proxy} from "@solidstate/contracts/proxy/Proxy.sol"; import {IDiamondLoupe} from "@solidstate/contracts/proxy/diamond/IDiamondLoupe.sol"; import {IERC20Metadata} from "@solidstate/contracts/token/ERC20/metadata/IERC20Metadata.sol"; import {IERC1155} from "@solidstate/contracts/token/ERC1155/IERC1155.sol"; import {IERC165} from "@solidstate/contracts/introspection/IERC165.sol"; import {IProxyManager} from "../core/IProxyManager.sol"; import {PoolStorage} from "./PoolStorage.sol"; import {ABDKMath64x64Token} from "../libraries/ABDKMath64x64Token.sol"; /** * @title Upgradeable proxy with centrally controlled Pool implementation */ contract PoolProxy is Proxy { using PoolStorage for PoolStorage.Layout; using ERC165Storage for ERC165Storage.Layout; address private immutable DIAMOND; constructor( address diamond, address base, address underlying, address baseOracle, address underlyingOracle, int128 baseMinimum64x64, int128 underlyingMinimum64x64, int128 basePoolCap64x64, int128 underlyingPoolCap64x64, int128 initialCLevel64x64, int128 initialSteepness64x64 ) { DIAMOND = diamond; OwnableStorage.layout().owner = msg.sender; { PoolStorage.Layout storage l = PoolStorage.layout(); l.base = base; l.underlying = underlying; l.setOracles(baseOracle, underlyingOracle); uint8 baseDecimals = IERC20Metadata(base).decimals(); uint8 underlyingDecimals = IERC20Metadata(underlying).decimals(); l.baseDecimals = baseDecimals; l.underlyingDecimals = underlyingDecimals; l.baseMinimum = ABDKMath64x64Token.toDecimals( baseMinimum64x64, baseDecimals ); l.underlyingMinimum = ABDKMath64x64Token.toDecimals( underlyingMinimum64x64, underlyingDecimals ); l.basePoolCap = ABDKMath64x64Token.toDecimals( basePoolCap64x64, baseDecimals ); l.underlyingPoolCap = ABDKMath64x64Token.toDecimals( underlyingPoolCap64x64, underlyingDecimals ); l.steepness64x64 = initialSteepness64x64; l.cLevelBase64x64 = initialCLevel64x64; l.cLevelUnderlying64x64 = initialCLevel64x64; int128 newPrice64x64 = l.fetchPriceUpdate(); l.setPriceUpdate(block.timestamp, newPrice64x64); l.updatedAt = block.timestamp; l.cLevelBaseUpdatedAt = block.timestamp; l.cLevelUnderlyingUpdatedAt = block.timestamp; } { ERC165Storage.Layout storage l = ERC165Storage.layout(); l.setSupportedInterface(type(IERC165).interfaceId, true); l.setSupportedInterface(type(IERC1155).interfaceId, true); } } function _getImplementation() internal view override returns (address) { return IDiamondLoupe(DIAMOND).facetAddress(msg.sig); } }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; library OwnableStorage { struct Layout { address owner; } bytes32 internal constant STORAGE_SLOT = keccak256('solidstate.contracts.storage.Ownable'); function layout() internal pure returns (Layout storage l) { bytes32 slot = STORAGE_SLOT; assembly { l.slot := slot } } function setOwner(Layout storage l, address owner) internal { l.owner = owner; } }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; library ERC165Storage { struct Layout { mapping(bytes4 => bool) supportedInterfaces; } bytes32 internal constant STORAGE_SLOT = keccak256('solidstate.contracts.storage.ERC165'); function layout() internal pure returns (Layout storage l) { bytes32 slot = STORAGE_SLOT; assembly { l.slot := slot } } function isSupportedInterface(Layout storage l, bytes4 interfaceId) internal view returns (bool) { return l.supportedInterfaces[interfaceId]; } function setSupportedInterface( Layout storage l, bytes4 interfaceId, bool status ) internal { require(interfaceId != 0xffffffff, 'ERC165: invalid interface id'); l.supportedInterfaces[interfaceId] = status; } }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; import { AddressUtils } from '../utils/AddressUtils.sol'; /** * @title Base proxy contract */ abstract contract Proxy { using AddressUtils for address; /** * @notice delegate all calls to implementation contract * @dev reverts if implementation address contains no code, for compatibility with metamorphic contracts * @dev memory location in use by assembly may be unsafe in other contexts */ fallback() external payable virtual { address implementation = _getImplementation(); require( implementation.isContract(), 'Proxy: implementation must be contract' ); assembly { calldatacopy(0, 0, calldatasize()) let result := delegatecall( gas(), implementation, 0, calldatasize(), 0, 0 ) returndatacopy(0, 0, returndatasize()) switch result case 0 { revert(0, returndatasize()) } default { return(0, returndatasize()) } } } /** * @notice get logic implementation address * @return implementation address */ function _getImplementation() internal virtual returns (address); }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; /** * @title Diamond proxy introspection interface * @dev see https://eips.ethereum.org/EIPS/eip-2535 */ interface IDiamondLoupe { struct Facet { address target; bytes4[] selectors; } /** * @notice get all facets and their selectors * @return diamondFacets array of structured facet data */ function facets() external view returns (Facet[] memory diamondFacets); /** * @notice get all selectors for given facet address * @param facet address of facet to query * @return selectors array of function selectors */ function facetFunctionSelectors(address facet) external view returns (bytes4[] memory selectors); /** * @notice get addresses of all facets used by diamond * @return addresses array of facet addresses */ function facetAddresses() external view returns (address[] memory addresses); /** * @notice get the address of the facet associated with given selector * @param selector function selector to query * @return facet facet address (zero address if not found) */ function facetAddress(bytes4 selector) external view returns (address facet); }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; /** * @title ERC20 metadata interface */ interface IERC20Metadata { /** * @notice return token name * @return token name */ function name() external view returns (string memory); /** * @notice return token symbol * @return token symbol */ function symbol() external view returns (string memory); /** * @notice return token decimals, generally used only for display purposes * @return token decimals */ function decimals() external view returns (uint8); }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; import { IERC1155Internal } from './IERC1155Internal.sol'; import { IERC165 } from '../../introspection/IERC165.sol'; /** * @notice ERC1155 interface * @dev see https://github.com/ethereum/EIPs/issues/1155 */ interface IERC1155 is IERC1155Internal, IERC165 { /** * @notice query the balance of given token held by given address * @param account address to query * @param id token to query * @return token balance */ function balanceOf(address account, uint256 id) external view returns (uint256); /** * @notice query the balances of given tokens held by given addresses * @param accounts addresss to query * @param ids tokens to query * @return token balances */ function balanceOfBatch(address[] calldata accounts, uint256[] calldata ids) external view returns (uint256[] memory); /** * @notice query approval status of given operator with respect to given address * @param account address to query for approval granted * @param operator address to query for approval received * @return whether operator is approved to spend tokens held by account */ function isApprovedForAll(address account, address operator) external view returns (bool); /** * @notice grant approval to or revoke approval from given operator to spend held tokens * @param operator address whose approval status to update * @param status whether operator should be considered approved */ function setApprovalForAll(address operator, bool status) external; /** * @notice transfer tokens between given addresses, checking for ERC1155Receiver implementation if applicable * @param from sender of tokens * @param to receiver of tokens * @param id token ID * @param amount quantity of tokens to transfer * @param data data payload */ function safeTransferFrom( address from, address to, uint256 id, uint256 amount, bytes calldata data ) external; /** * @notice transfer batch of tokens between given addresses, checking for ERC1155Receiver implementation if applicable * @param from sender of tokens * @param to receiver of tokens * @param ids list of token IDs * @param amounts list of quantities of tokens to transfer * @param data data payload */ function safeBatchTransferFrom( address from, address to, uint256[] calldata ids, uint256[] calldata amounts, bytes calldata data ) external; }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; /** * @title ERC165 interface registration interface * @dev see https://eips.ethereum.org/EIPS/eip-165 */ interface IERC165 { /** * @notice query whether contract has registered support for given interface * @param interfaceId interface id * @return bool whether interface is supported */ function supportsInterface(bytes4 interfaceId) external view returns (bool); }
// SPDX-License-Identifier: LGPL-3.0-or-later pragma solidity ^0.8.0; interface IProxyManager { function getPoolList() external view returns (address[] memory); }
// SPDX-License-Identifier: BUSL-1.1 // For further clarification please see https://license.premia.legal pragma solidity ^0.8.0; import {AggregatorInterface} from "@chainlink/contracts/src/v0.8/interfaces/AggregatorInterface.sol"; import {AggregatorV3Interface} from "@chainlink/contracts/src/v0.8/interfaces/AggregatorV3Interface.sol"; import {EnumerableSet, ERC1155EnumerableStorage} from "@solidstate/contracts/token/ERC1155/enumerable/ERC1155EnumerableStorage.sol"; import {ABDKMath64x64} from "abdk-libraries-solidity/ABDKMath64x64.sol"; import {ABDKMath64x64Token} from "../libraries/ABDKMath64x64Token.sol"; import {OptionMath} from "../libraries/OptionMath.sol"; library PoolStorage { using ABDKMath64x64 for int128; using PoolStorage for PoolStorage.Layout; enum TokenType { UNDERLYING_FREE_LIQ, BASE_FREE_LIQ, UNDERLYING_RESERVED_LIQ, BASE_RESERVED_LIQ, LONG_CALL, SHORT_CALL, LONG_PUT, SHORT_PUT } struct PoolSettings { address underlying; address base; address underlyingOracle; address baseOracle; } struct QuoteArgsInternal { address feePayer; // address of the fee payer uint64 maturity; // timestamp of option maturity int128 strike64x64; // 64x64 fixed point representation of strike price int128 spot64x64; // 64x64 fixed point representation of spot price uint256 contractSize; // size of option contract bool isCall; // true for call, false for put } struct QuoteResultInternal { int128 baseCost64x64; // 64x64 fixed point representation of option cost denominated in underlying currency (without fee) int128 feeCost64x64; // 64x64 fixed point representation of option fee cost denominated in underlying currency for call, or base currency for put int128 cLevel64x64; // 64x64 fixed point representation of C-Level of Pool after purchase int128 slippageCoefficient64x64; // 64x64 fixed point representation of slippage coefficient for given order size } struct BatchData { uint256 eta; uint256 totalPendingDeposits; } bytes32 internal constant STORAGE_SLOT = keccak256("premia.contracts.storage.Pool"); uint256 private constant C_DECAY_BUFFER = 12 hours; uint256 private constant C_DECAY_INTERVAL = 4 hours; struct Layout { // ERC20 token addresses address base; address underlying; // AggregatorV3Interface oracle addresses address baseOracle; address underlyingOracle; // token metadata uint8 underlyingDecimals; uint8 baseDecimals; // minimum amounts uint256 baseMinimum; uint256 underlyingMinimum; // deposit caps uint256 basePoolCap; uint256 underlyingPoolCap; // market state int128 steepness64x64; int128 cLevelBase64x64; int128 cLevelUnderlying64x64; uint256 cLevelBaseUpdatedAt; uint256 cLevelUnderlyingUpdatedAt; uint256 updatedAt; // User -> isCall -> depositedAt mapping(address => mapping(bool => uint256)) depositedAt; mapping(address => mapping(bool => uint256)) divestmentTimestamps; // doubly linked list of free liquidity intervals // isCall -> User -> User mapping(bool => mapping(address => address)) liquidityQueueAscending; mapping(bool => mapping(address => address)) liquidityQueueDescending; // minimum resolution price bucket => price mapping(uint256 => int128) bucketPrices64x64; // sequence id (minimum resolution price bucket / 256) => price update sequence mapping(uint256 => uint256) priceUpdateSequences; // isCall -> batch data mapping(bool => BatchData) nextDeposits; // user -> batch timestamp -> isCall -> pending amount mapping(address => mapping(uint256 => mapping(bool => uint256))) pendingDeposits; EnumerableSet.UintSet tokenIds; // user -> isCallPool -> total value locked of user (Used for liquidity mining) mapping(address => mapping(bool => uint256)) userTVL; // isCallPool -> total value locked mapping(bool => uint256) totalTVL; } function layout() internal pure returns (Layout storage l) { bytes32 slot = STORAGE_SLOT; assembly { l.slot := slot } } /** * @notice calculate ERC1155 token id for given option parameters * @param tokenType TokenType enum * @param maturity timestamp of option maturity * @param strike64x64 64x64 fixed point representation of strike price * @return tokenId token id */ function formatTokenId( TokenType tokenType, uint64 maturity, int128 strike64x64 ) internal pure returns (uint256 tokenId) { tokenId = (uint256(tokenType) << 248) + (uint256(maturity) << 128) + uint256(int256(strike64x64)); } /** * @notice derive option maturity and strike price from ERC1155 token id * @param tokenId token id * @return tokenType TokenType enum * @return maturity timestamp of option maturity * @return strike64x64 option strike price */ function parseTokenId(uint256 tokenId) internal pure returns ( TokenType tokenType, uint64 maturity, int128 strike64x64 ) { assembly { tokenType := shr(248, tokenId) maturity := shr(128, tokenId) strike64x64 := tokenId } } function getTokenDecimals(Layout storage l, bool isCall) internal view returns (uint8 decimals) { decimals = isCall ? l.underlyingDecimals : l.baseDecimals; } function totalFreeLiquiditySupply64x64(Layout storage l, bool isCall) internal view returns (int128) { uint256 tokenId = formatTokenId( isCall ? TokenType.UNDERLYING_FREE_LIQ : TokenType.BASE_FREE_LIQ, 0, 0 ); return ABDKMath64x64Token.fromDecimals( ERC1155EnumerableStorage.layout().totalSupply[tokenId] - l.nextDeposits[isCall].totalPendingDeposits, l.getTokenDecimals(isCall) ); } function getReinvestmentStatus( Layout storage l, address account, bool isCallPool ) internal view returns (bool) { uint256 timestamp = l.divestmentTimestamps[account][isCallPool]; return timestamp == 0 || timestamp > block.timestamp; } function addUnderwriter( Layout storage l, address account, bool isCallPool ) internal { require(account != address(0)); mapping(address => address) storage asc = l.liquidityQueueAscending[ isCallPool ]; mapping(address => address) storage desc = l.liquidityQueueDescending[ isCallPool ]; if (_isInQueue(account, asc, desc)) return; address last = desc[address(0)]; asc[last] = account; desc[account] = last; desc[address(0)] = account; } function removeUnderwriter( Layout storage l, address account, bool isCallPool ) internal { require(account != address(0)); mapping(address => address) storage asc = l.liquidityQueueAscending[ isCallPool ]; mapping(address => address) storage desc = l.liquidityQueueDescending[ isCallPool ]; if (!_isInQueue(account, asc, desc)) return; address prev = desc[account]; address next = asc[account]; asc[prev] = next; desc[next] = prev; delete asc[account]; delete desc[account]; } function isInQueue( Layout storage l, address account, bool isCallPool ) internal view returns (bool) { mapping(address => address) storage asc = l.liquidityQueueAscending[ isCallPool ]; mapping(address => address) storage desc = l.liquidityQueueDescending[ isCallPool ]; return _isInQueue(account, asc, desc); } function _isInQueue( address account, mapping(address => address) storage asc, mapping(address => address) storage desc ) private view returns (bool) { return asc[account] != address(0) || desc[address(0)] == account; } function getCLevel(Layout storage l, bool isCall) internal view returns (int128 cLevel64x64) { int128 oldCLevel64x64 = isCall ? l.cLevelUnderlying64x64 : l.cLevelBase64x64; uint256 timeElapsed = block.timestamp - (isCall ? l.cLevelUnderlyingUpdatedAt : l.cLevelBaseUpdatedAt); // do not apply C decay if less than 24 hours have elapsed if (timeElapsed > C_DECAY_BUFFER) { timeElapsed -= C_DECAY_BUFFER; } else { return oldCLevel64x64; } int128 timeIntervalsElapsed64x64 = ABDKMath64x64.divu( timeElapsed, C_DECAY_INTERVAL ); uint256 tokenId = formatTokenId( isCall ? TokenType.UNDERLYING_FREE_LIQ : TokenType.BASE_FREE_LIQ, 0, 0 ); uint256 tvl = l.totalTVL[isCall]; int128 utilization = ABDKMath64x64.divu( tvl - (ERC1155EnumerableStorage.layout().totalSupply[tokenId] - l.nextDeposits[isCall].totalPendingDeposits), tvl ); cLevel64x64 = OptionMath.calculateCLevelDecay( OptionMath.CalculateCLevelDecayArgs( timeIntervalsElapsed64x64, oldCLevel64x64, utilization, 0xb333333333333333, // 0.7 0xe666666666666666, // 0.9 0x10000000000000000, // 1.0 0x10000000000000000, // 1.0 0xe666666666666666, // 0.9 0x56fc2a2c515da32ea // 2e ) ); } function setCLevel( Layout storage l, int128 oldLiquidity64x64, int128 newLiquidity64x64, bool isCallPool ) internal returns (int128 cLevel64x64) { cLevel64x64 = l.calculateCLevel( oldLiquidity64x64, newLiquidity64x64, isCallPool ); l.setCLevel(cLevel64x64, isCallPool); } function setCLevel( Layout storage l, int128 cLevel64x64, bool isCallPool ) internal { if (isCallPool) { l.cLevelUnderlying64x64 = cLevel64x64; l.cLevelUnderlyingUpdatedAt = block.timestamp; } else { l.cLevelBase64x64 = cLevel64x64; l.cLevelBaseUpdatedAt = block.timestamp; } } function calculateCLevel( Layout storage l, int128 oldLiquidity64x64, int128 newLiquidity64x64, bool isCallPool ) internal view returns (int128 cLevel64x64) { cLevel64x64 = OptionMath.calculateCLevel( l.getCLevel(isCallPool), oldLiquidity64x64, newLiquidity64x64, l.steepness64x64 ); if (cLevel64x64 < 0xb333333333333333) { cLevel64x64 = int128(0xb333333333333333); // 64x64 fixed point representation of 0.7 } } function setOracles( Layout storage l, address baseOracle, address underlyingOracle ) internal { require( AggregatorV3Interface(baseOracle).decimals() == AggregatorV3Interface(underlyingOracle).decimals(), "Pool: oracle decimals must match" ); l.baseOracle = baseOracle; l.underlyingOracle = underlyingOracle; } function fetchPriceUpdate(Layout storage l) internal view returns (int128 price64x64) { int256 priceUnderlying = AggregatorInterface(l.underlyingOracle) .latestAnswer(); int256 priceBase = AggregatorInterface(l.baseOracle).latestAnswer(); return ABDKMath64x64.divi(priceUnderlying, priceBase); } /** * @notice set price update for current hourly bucket * @param l storage layout struct * @param timestamp timestamp to update * @param price64x64 64x64 fixed point representation of price */ function setPriceUpdate( Layout storage l, uint256 timestamp, int128 price64x64 ) internal { uint256 bucket = timestamp / (1 hours); l.bucketPrices64x64[bucket] = price64x64; l.priceUpdateSequences[bucket >> 8] += 1 << (255 - (bucket & 255)); } /** * @notice get price update for hourly bucket corresponding to given timestamp * @param l storage layout struct * @param timestamp timestamp to query * @return 64x64 fixed point representation of price */ function getPriceUpdate(Layout storage l, uint256 timestamp) internal view returns (int128) { return l.bucketPrices64x64[timestamp / (1 hours)]; } /** * @notice get first price update available following given timestamp * @param l storage layout struct * @param timestamp timestamp to query * @return 64x64 fixed point representation of price */ function getPriceUpdateAfter(Layout storage l, uint256 timestamp) internal view returns (int128) { // price updates are grouped into hourly buckets uint256 bucket = timestamp / (1 hours); // divide by 256 to get the index of the relevant price update sequence uint256 sequenceId = bucket >> 8; // get position within sequence relevant to current price update uint256 offset = bucket & 255; // shift to skip buckets from earlier in sequence uint256 sequence = (l.priceUpdateSequences[sequenceId] << offset) >> offset; // iterate through future sequences until a price update is found // sequence corresponding to current timestamp used as upper bound uint256 currentPriceUpdateSequenceId = block.timestamp / (256 hours); while (sequence == 0 && sequenceId <= currentPriceUpdateSequenceId) { sequence = l.priceUpdateSequences[++sequenceId]; } // if no price update is found (sequence == 0) function will return 0 // this should never occur, as each relevant external function triggers a price update // the most significant bit of the sequence corresponds to the offset of the relevant bucket uint256 msb; for (uint256 i = 128; i > 0; i >>= 1) { if (sequence >> i > 0) { msb += i; sequence >>= i; } } return l.bucketPrices64x64[((sequenceId + 1) << 8) - msb - 1]; } function fromBaseToUnderlyingDecimals(Layout storage l, uint256 value) internal view returns (uint256) { int128 valueFixed64x64 = ABDKMath64x64Token.fromDecimals( value, l.baseDecimals ); return ABDKMath64x64Token.toDecimals( valueFixed64x64, l.underlyingDecimals ); } function fromUnderlyingToBaseDecimals(Layout storage l, uint256 value) internal view returns (uint256) { int128 valueFixed64x64 = ABDKMath64x64Token.fromDecimals( value, l.underlyingDecimals ); return ABDKMath64x64Token.toDecimals(valueFixed64x64, l.baseDecimals); } }
// SPDX-License-Identifier: BUSL-1.1 // For further clarification please see https://license.premia.legal pragma solidity ^0.8.0; import {ABDKMath64x64} from "abdk-libraries-solidity/ABDKMath64x64.sol"; library ABDKMath64x64Token { using ABDKMath64x64 for int128; /** * @notice convert 64x64 fixed point representation of token amount to decimal * @param value64x64 64x64 fixed point representation of token amount * @param decimals token display decimals * @return value decimal representation of token amount */ function toDecimals(int128 value64x64, uint8 decimals) internal pure returns (uint256 value) { value = value64x64.mulu(10**decimals); } /** * @notice convert decimal representation of token amount to 64x64 fixed point * @param value decimal representation of token amount * @param decimals token display decimals * @return value64x64 64x64 fixed point representation of token amount */ function fromDecimals(uint256 value, uint8 decimals) internal pure returns (int128 value64x64) { value64x64 = ABDKMath64x64.divu(value, 10**decimals); } /** * @notice convert 64x64 fixed point representation of token amount to wei (18 decimals) * @param value64x64 64x64 fixed point representation of token amount * @return value wei representation of token amount */ function toWei(int128 value64x64) internal pure returns (uint256 value) { value = toDecimals(value64x64, 18); } /** * @notice convert wei representation (18 decimals) of token amount to 64x64 fixed point * @param value wei representation of token amount * @return value64x64 64x64 fixed point representation of token amount */ function fromWei(uint256 value) internal pure returns (int128 value64x64) { value64x64 = fromDecimals(value, 18); } }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; library AddressUtils { function toString(address account) internal pure returns (string memory) { bytes32 value = bytes32(uint256(uint160(account))); bytes memory alphabet = '0123456789abcdef'; bytes memory chars = new bytes(42); chars[0] = '0'; chars[1] = 'x'; for (uint256 i = 0; i < 20; i++) { chars[2 + i * 2] = alphabet[uint8(value[i + 12] >> 4)]; chars[3 + i * 2] = alphabet[uint8(value[i + 12] & 0x0f)]; } return string(chars); } function isContract(address account) internal view returns (bool) { uint256 size; assembly { size := extcodesize(account) } return size > 0; } function sendValue(address payable account, uint256 amount) internal { (bool success, ) = account.call{ value: amount }(''); require(success, 'AddressUtils: failed to send value'); } function functionCall(address target, bytes memory data) internal returns (bytes memory) { return functionCall(target, data, 'AddressUtils: failed low-level call'); } function functionCall( address target, bytes memory data, string memory error ) internal returns (bytes memory) { return _functionCallWithValue(target, data, 0, error); } function functionCallWithValue( address target, bytes memory data, uint256 value ) internal returns (bytes memory) { return functionCallWithValue( target, data, value, 'AddressUtils: failed low-level call with value' ); } function functionCallWithValue( address target, bytes memory data, uint256 value, string memory error ) internal returns (bytes memory) { require( address(this).balance >= value, 'AddressUtils: insufficient balance for call' ); return _functionCallWithValue(target, data, value, error); } function _functionCallWithValue( address target, bytes memory data, uint256 value, string memory error ) private returns (bytes memory) { require( isContract(target), 'AddressUtils: function call to non-contract' ); (bool success, bytes memory returnData) = target.call{ value: value }( data ); if (success) { return returnData; } else if (returnData.length > 0) { assembly { let returnData_size := mload(returnData) revert(add(32, returnData), returnData_size) } } else { revert(error); } } }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; import { IERC165 } from '../../introspection/IERC165.sol'; /** * @notice Partial ERC1155 interface needed by internal functions */ interface IERC1155Internal { event TransferSingle( address indexed operator, address indexed from, address indexed to, uint256 id, uint256 value ); event TransferBatch( address indexed operator, address indexed from, address indexed to, uint256[] ids, uint256[] values ); event ApprovalForAll( address indexed account, address indexed operator, bool approved ); }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; interface AggregatorInterface { function latestAnswer() external view returns ( int256 ); function latestTimestamp() external view returns ( uint256 ); function latestRound() external view returns ( uint256 ); function getAnswer( uint256 roundId ) external view returns ( int256 ); function getTimestamp( uint256 roundId ) external view returns ( uint256 ); event AnswerUpdated( int256 indexed current, uint256 indexed roundId, uint256 updatedAt ); event NewRound( uint256 indexed roundId, address indexed startedBy, uint256 startedAt ); }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; interface AggregatorV3Interface { function decimals() external view returns ( uint8 ); function description() external view returns ( string memory ); function version() external view returns ( uint256 ); // getRoundData and latestRoundData should both raise "No data present" // if they do not have data to report, instead of returning unset values // which could be misinterpreted as actual reported values. 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: MIT pragma solidity ^0.8.0; import { EnumerableSet } from '../../../utils/EnumerableSet.sol'; library ERC1155EnumerableStorage { struct Layout { mapping(uint256 => uint256) totalSupply; mapping(uint256 => EnumerableSet.AddressSet) accountsByToken; mapping(address => EnumerableSet.UintSet) tokensByAccount; } bytes32 internal constant STORAGE_SLOT = keccak256('solidstate.contracts.storage.ERC1155Enumerable'); function layout() internal pure returns (Layout storage l) { bytes32 slot = STORAGE_SLOT; assembly { l.slot := slot } } }
// SPDX-License-Identifier: BSD-4-Clause /* * ABDK Math 64.64 Smart Contract Library. Copyright © 2019 by ABDK Consulting. * Author: Mikhail Vladimirov <[email protected]> */ pragma solidity ^0.8.0; /** * Smart contract library of mathematical functions operating with signed * 64.64-bit fixed point numbers. Signed 64.64-bit fixed point number is * basically a simple fraction whose numerator is signed 128-bit integer and * denominator is 2^64. As long as denominator is always the same, there is no * need to store it, thus in Solidity signed 64.64-bit fixed point numbers are * represented by int128 type holding only the numerator. */ library ABDKMath64x64 { /* * Minimum value signed 64.64-bit fixed point number may have. */ int128 private constant MIN_64x64 = -0x80000000000000000000000000000000; /* * Maximum value signed 64.64-bit fixed point number may have. */ int128 private constant MAX_64x64 = 0x7FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF; /** * Convert signed 256-bit integer number into signed 64.64-bit fixed point * number. Revert on overflow. * * @param x signed 256-bit integer number * @return signed 64.64-bit fixed point number */ function fromInt (int256 x) internal pure returns (int128) { unchecked { require (x >= -0x8000000000000000 && x <= 0x7FFFFFFFFFFFFFFF); return int128 (x << 64); } } /** * Convert signed 64.64 fixed point number into signed 64-bit integer number * rounding down. * * @param x signed 64.64-bit fixed point number * @return signed 64-bit integer number */ function toInt (int128 x) internal pure returns (int64) { unchecked { return int64 (x >> 64); } } /** * Convert unsigned 256-bit integer number into signed 64.64-bit fixed point * number. Revert on overflow. * * @param x unsigned 256-bit integer number * @return signed 64.64-bit fixed point number */ function fromUInt (uint256 x) internal pure returns (int128) { unchecked { require (x <= 0x7FFFFFFFFFFFFFFF); return int128 (int256 (x << 64)); } } /** * Convert signed 64.64 fixed point number into unsigned 64-bit integer * number rounding down. Revert on underflow. * * @param x signed 64.64-bit fixed point number * @return unsigned 64-bit integer number */ function toUInt (int128 x) internal pure returns (uint64) { unchecked { require (x >= 0); return uint64 (uint128 (x >> 64)); } } /** * Convert signed 128.128 fixed point number into signed 64.64-bit fixed point * number rounding down. Revert on overflow. * * @param x signed 128.128-bin fixed point number * @return signed 64.64-bit fixed point number */ function from128x128 (int256 x) internal pure returns (int128) { unchecked { int256 result = x >> 64; require (result >= MIN_64x64 && result <= MAX_64x64); return int128 (result); } } /** * Convert signed 64.64 fixed point number into signed 128.128 fixed point * number. * * @param x signed 64.64-bit fixed point number * @return signed 128.128 fixed point number */ function to128x128 (int128 x) internal pure returns (int256) { unchecked { return int256 (x) << 64; } } /** * Calculate x + y. Revert on overflow. * * @param x signed 64.64-bit fixed point number * @param y signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function add (int128 x, int128 y) internal pure returns (int128) { unchecked { int256 result = int256(x) + y; require (result >= MIN_64x64 && result <= MAX_64x64); return int128 (result); } } /** * Calculate x - y. Revert on overflow. * * @param x signed 64.64-bit fixed point number * @param y signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function sub (int128 x, int128 y) internal pure returns (int128) { unchecked { int256 result = int256(x) - y; require (result >= MIN_64x64 && result <= MAX_64x64); return int128 (result); } } /** * Calculate x * y rounding down. Revert on overflow. * * @param x signed 64.64-bit fixed point number * @param y signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function mul (int128 x, int128 y) internal pure returns (int128) { unchecked { int256 result = int256(x) * y >> 64; require (result >= MIN_64x64 && result <= MAX_64x64); return int128 (result); } } /** * Calculate x * y rounding towards zero, where x is signed 64.64 fixed point * number and y is signed 256-bit integer number. Revert on overflow. * * @param x signed 64.64 fixed point number * @param y signed 256-bit integer number * @return signed 256-bit integer number */ function muli (int128 x, int256 y) internal pure returns (int256) { unchecked { if (x == MIN_64x64) { require (y >= -0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF && y <= 0x1000000000000000000000000000000000000000000000000); return -y << 63; } else { bool negativeResult = false; if (x < 0) { x = -x; negativeResult = true; } if (y < 0) { y = -y; // We rely on overflow behavior here negativeResult = !negativeResult; } uint256 absoluteResult = mulu (x, uint256 (y)); if (negativeResult) { require (absoluteResult <= 0x8000000000000000000000000000000000000000000000000000000000000000); return -int256 (absoluteResult); // We rely on overflow behavior here } else { require (absoluteResult <= 0x7FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF); return int256 (absoluteResult); } } } } /** * Calculate x * y rounding down, where x is signed 64.64 fixed point number * and y is unsigned 256-bit integer number. Revert on overflow. * * @param x signed 64.64 fixed point number * @param y unsigned 256-bit integer number * @return unsigned 256-bit integer number */ function mulu (int128 x, uint256 y) internal pure returns (uint256) { unchecked { if (y == 0) return 0; require (x >= 0); uint256 lo = (uint256 (int256 (x)) * (y & 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF)) >> 64; uint256 hi = uint256 (int256 (x)) * (y >> 128); require (hi <= 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF); hi <<= 64; require (hi <= 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF - lo); return hi + lo; } } /** * Calculate x / y rounding towards zero. Revert on overflow or when y is * zero. * * @param x signed 64.64-bit fixed point number * @param y signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function div (int128 x, int128 y) internal pure returns (int128) { unchecked { require (y != 0); int256 result = (int256 (x) << 64) / y; require (result >= MIN_64x64 && result <= MAX_64x64); return int128 (result); } } /** * Calculate x / y rounding towards zero, where x and y are signed 256-bit * integer numbers. Revert on overflow or when y is zero. * * @param x signed 256-bit integer number * @param y signed 256-bit integer number * @return signed 64.64-bit fixed point number */ function divi (int256 x, int256 y) internal pure returns (int128) { unchecked { require (y != 0); bool negativeResult = false; if (x < 0) { x = -x; // We rely on overflow behavior here negativeResult = true; } if (y < 0) { y = -y; // We rely on overflow behavior here negativeResult = !negativeResult; } uint128 absoluteResult = divuu (uint256 (x), uint256 (y)); if (negativeResult) { require (absoluteResult <= 0x80000000000000000000000000000000); return -int128 (absoluteResult); // We rely on overflow behavior here } else { require (absoluteResult <= 0x7FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF); return int128 (absoluteResult); // We rely on overflow behavior here } } } /** * Calculate x / y rounding towards zero, where x and y are unsigned 256-bit * integer numbers. Revert on overflow or when y is zero. * * @param x unsigned 256-bit integer number * @param y unsigned 256-bit integer number * @return signed 64.64-bit fixed point number */ function divu (uint256 x, uint256 y) internal pure returns (int128) { unchecked { require (y != 0); uint128 result = divuu (x, y); require (result <= uint128 (MAX_64x64)); return int128 (result); } } /** * Calculate -x. Revert on overflow. * * @param x signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function neg (int128 x) internal pure returns (int128) { unchecked { require (x != MIN_64x64); return -x; } } /** * Calculate |x|. Revert on overflow. * * @param x signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function abs (int128 x) internal pure returns (int128) { unchecked { require (x != MIN_64x64); return x < 0 ? -x : x; } } /** * Calculate 1 / x rounding towards zero. Revert on overflow or when x is * zero. * * @param x signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function inv (int128 x) internal pure returns (int128) { unchecked { require (x != 0); int256 result = int256 (0x100000000000000000000000000000000) / x; require (result >= MIN_64x64 && result <= MAX_64x64); return int128 (result); } } /** * Calculate arithmetics average of x and y, i.e. (x + y) / 2 rounding down. * * @param x signed 64.64-bit fixed point number * @param y signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function avg (int128 x, int128 y) internal pure returns (int128) { unchecked { return int128 ((int256 (x) + int256 (y)) >> 1); } } /** * Calculate geometric average of x and y, i.e. sqrt (x * y) rounding down. * Revert on overflow or in case x * y is negative. * * @param x signed 64.64-bit fixed point number * @param y signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function gavg (int128 x, int128 y) internal pure returns (int128) { unchecked { int256 m = int256 (x) * int256 (y); require (m >= 0); require (m < 0x4000000000000000000000000000000000000000000000000000000000000000); return int128 (sqrtu (uint256 (m))); } } /** * Calculate x^y assuming 0^0 is 1, where x is signed 64.64 fixed point number * and y is unsigned 256-bit integer number. Revert on overflow. * * @param x signed 64.64-bit fixed point number * @param y uint256 value * @return signed 64.64-bit fixed point number */ function pow (int128 x, uint256 y) internal pure returns (int128) { unchecked { bool negative = x < 0 && y & 1 == 1; uint256 absX = uint128 (x < 0 ? -x : x); uint256 absResult; absResult = 0x100000000000000000000000000000000; if (absX <= 0x10000000000000000) { absX <<= 63; while (y != 0) { if (y & 0x1 != 0) { absResult = absResult * absX >> 127; } absX = absX * absX >> 127; if (y & 0x2 != 0) { absResult = absResult * absX >> 127; } absX = absX * absX >> 127; if (y & 0x4 != 0) { absResult = absResult * absX >> 127; } absX = absX * absX >> 127; if (y & 0x8 != 0) { absResult = absResult * absX >> 127; } absX = absX * absX >> 127; y >>= 4; } absResult >>= 64; } else { uint256 absXShift = 63; if (absX < 0x1000000000000000000000000) { absX <<= 32; absXShift -= 32; } if (absX < 0x10000000000000000000000000000) { absX <<= 16; absXShift -= 16; } if (absX < 0x1000000000000000000000000000000) { absX <<= 8; absXShift -= 8; } if (absX < 0x10000000000000000000000000000000) { absX <<= 4; absXShift -= 4; } if (absX < 0x40000000000000000000000000000000) { absX <<= 2; absXShift -= 2; } if (absX < 0x80000000000000000000000000000000) { absX <<= 1; absXShift -= 1; } uint256 resultShift = 0; while (y != 0) { require (absXShift < 64); if (y & 0x1 != 0) { absResult = absResult * absX >> 127; resultShift += absXShift; if (absResult > 0x100000000000000000000000000000000) { absResult >>= 1; resultShift += 1; } } absX = absX * absX >> 127; absXShift <<= 1; if (absX >= 0x100000000000000000000000000000000) { absX >>= 1; absXShift += 1; } y >>= 1; } require (resultShift < 64); absResult >>= 64 - resultShift; } int256 result = negative ? -int256 (absResult) : int256 (absResult); require (result >= MIN_64x64 && result <= MAX_64x64); return int128 (result); } } /** * Calculate sqrt (x) rounding down. Revert if x < 0. * * @param x signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function sqrt (int128 x) internal pure returns (int128) { unchecked { require (x >= 0); return int128 (sqrtu (uint256 (int256 (x)) << 64)); } } /** * Calculate binary logarithm of x. Revert if x <= 0. * * @param x signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function log_2 (int128 x) internal pure returns (int128) { unchecked { require (x > 0); int256 msb = 0; int256 xc = x; if (xc >= 0x10000000000000000) { xc >>= 64; msb += 64; } if (xc >= 0x100000000) { xc >>= 32; msb += 32; } if (xc >= 0x10000) { xc >>= 16; msb += 16; } if (xc >= 0x100) { xc >>= 8; msb += 8; } if (xc >= 0x10) { xc >>= 4; msb += 4; } if (xc >= 0x4) { xc >>= 2; msb += 2; } if (xc >= 0x2) msb += 1; // No need to shift xc anymore int256 result = msb - 64 << 64; uint256 ux = uint256 (int256 (x)) << uint256 (127 - msb); for (int256 bit = 0x8000000000000000; bit > 0; bit >>= 1) { ux *= ux; uint256 b = ux >> 255; ux >>= 127 + b; result += bit * int256 (b); } return int128 (result); } } /** * Calculate natural logarithm of x. Revert if x <= 0. * * @param x signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function ln (int128 x) internal pure returns (int128) { unchecked { require (x > 0); return int128 (int256 ( uint256 (int256 (log_2 (x))) * 0xB17217F7D1CF79ABC9E3B39803F2F6AF >> 128)); } } /** * Calculate binary exponent of x. Revert on overflow. * * @param x signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function exp_2 (int128 x) internal pure returns (int128) { unchecked { require (x < 0x400000000000000000); // Overflow if (x < -0x400000000000000000) return 0; // Underflow uint256 result = 0x80000000000000000000000000000000; if (x & 0x8000000000000000 > 0) result = result * 0x16A09E667F3BCC908B2FB1366EA957D3E >> 128; if (x & 0x4000000000000000 > 0) result = result * 0x1306FE0A31B7152DE8D5A46305C85EDEC >> 128; if (x & 0x2000000000000000 > 0) result = result * 0x1172B83C7D517ADCDF7C8C50EB14A791F >> 128; if (x & 0x1000000000000000 > 0) result = result * 0x10B5586CF9890F6298B92B71842A98363 >> 128; if (x & 0x800000000000000 > 0) result = result * 0x1059B0D31585743AE7C548EB68CA417FD >> 128; if (x & 0x400000000000000 > 0) result = result * 0x102C9A3E778060EE6F7CACA4F7A29BDE8 >> 128; if (x & 0x200000000000000 > 0) result = result * 0x10163DA9FB33356D84A66AE336DCDFA3F >> 128; if (x & 0x100000000000000 > 0) result = result * 0x100B1AFA5ABCBED6129AB13EC11DC9543 >> 128; if (x & 0x80000000000000 > 0) result = result * 0x10058C86DA1C09EA1FF19D294CF2F679B >> 128; if (x & 0x40000000000000 > 0) result = result * 0x1002C605E2E8CEC506D21BFC89A23A00F >> 128; if (x & 0x20000000000000 > 0) result = result * 0x100162F3904051FA128BCA9C55C31E5DF >> 128; if (x & 0x10000000000000 > 0) result = result * 0x1000B175EFFDC76BA38E31671CA939725 >> 128; if (x & 0x8000000000000 > 0) result = result * 0x100058BA01FB9F96D6CACD4B180917C3D >> 128; if (x & 0x4000000000000 > 0) result = result * 0x10002C5CC37DA9491D0985C348C68E7B3 >> 128; if (x & 0x2000000000000 > 0) result = result * 0x1000162E525EE054754457D5995292026 >> 128; if (x & 0x1000000000000 > 0) result = result * 0x10000B17255775C040618BF4A4ADE83FC >> 128; if (x & 0x800000000000 > 0) result = result * 0x1000058B91B5BC9AE2EED81E9B7D4CFAB >> 128; if (x & 0x400000000000 > 0) result = result * 0x100002C5C89D5EC6CA4D7C8ACC017B7C9 >> 128; if (x & 0x200000000000 > 0) result = result * 0x10000162E43F4F831060E02D839A9D16D >> 128; if (x & 0x100000000000 > 0) result = result * 0x100000B1721BCFC99D9F890EA06911763 >> 128; if (x & 0x80000000000 > 0) result = result * 0x10000058B90CF1E6D97F9CA14DBCC1628 >> 128; if (x & 0x40000000000 > 0) result = result * 0x1000002C5C863B73F016468F6BAC5CA2B >> 128; if (x & 0x20000000000 > 0) result = result * 0x100000162E430E5A18F6119E3C02282A5 >> 128; if (x & 0x10000000000 > 0) result = result * 0x1000000B1721835514B86E6D96EFD1BFE >> 128; if (x & 0x8000000000 > 0) result = result * 0x100000058B90C0B48C6BE5DF846C5B2EF >> 128; if (x & 0x4000000000 > 0) result = result * 0x10000002C5C8601CC6B9E94213C72737A >> 128; if (x & 0x2000000000 > 0) result = result * 0x1000000162E42FFF037DF38AA2B219F06 >> 128; if (x & 0x1000000000 > 0) result = result * 0x10000000B17217FBA9C739AA5819F44F9 >> 128; if (x & 0x800000000 > 0) result = result * 0x1000000058B90BFCDEE5ACD3C1CEDC823 >> 128; if (x & 0x400000000 > 0) result = result * 0x100000002C5C85FE31F35A6A30DA1BE50 >> 128; if (x & 0x200000000 > 0) result = result * 0x10000000162E42FF0999CE3541B9FFFCF >> 128; if (x & 0x100000000 > 0) result = result * 0x100000000B17217F80F4EF5AADDA45554 >> 128; if (x & 0x80000000 > 0) result = result * 0x10000000058B90BFBF8479BD5A81B51AD >> 128; if (x & 0x40000000 > 0) result = result * 0x1000000002C5C85FDF84BD62AE30A74CC >> 128; if (x & 0x20000000 > 0) result = result * 0x100000000162E42FEFB2FED257559BDAA >> 128; if (x & 0x10000000 > 0) result = result * 0x1000000000B17217F7D5A7716BBA4A9AE >> 128; if (x & 0x8000000 > 0) result = result * 0x100000000058B90BFBE9DDBAC5E109CCE >> 128; if (x & 0x4000000 > 0) result = result * 0x10000000002C5C85FDF4B15DE6F17EB0D >> 128; if (x & 0x2000000 > 0) result = result * 0x1000000000162E42FEFA494F1478FDE05 >> 128; if (x & 0x1000000 > 0) result = result * 0x10000000000B17217F7D20CF927C8E94C >> 128; if (x & 0x800000 > 0) result = result * 0x1000000000058B90BFBE8F71CB4E4B33D >> 128; if (x & 0x400000 > 0) result = result * 0x100000000002C5C85FDF477B662B26945 >> 128; if (x & 0x200000 > 0) result = result * 0x10000000000162E42FEFA3AE53369388C >> 128; if (x & 0x100000 > 0) result = result * 0x100000000000B17217F7D1D351A389D40 >> 128; if (x & 0x80000 > 0) result = result * 0x10000000000058B90BFBE8E8B2D3D4EDE >> 128; if (x & 0x40000 > 0) result = result * 0x1000000000002C5C85FDF4741BEA6E77E >> 128; if (x & 0x20000 > 0) result = result * 0x100000000000162E42FEFA39FE95583C2 >> 128; if (x & 0x10000 > 0) result = result * 0x1000000000000B17217F7D1CFB72B45E1 >> 128; if (x & 0x8000 > 0) result = result * 0x100000000000058B90BFBE8E7CC35C3F0 >> 128; if (x & 0x4000 > 0) result = result * 0x10000000000002C5C85FDF473E242EA38 >> 128; if (x & 0x2000 > 0) result = result * 0x1000000000000162E42FEFA39F02B772C >> 128; if (x & 0x1000 > 0) result = result * 0x10000000000000B17217F7D1CF7D83C1A >> 128; if (x & 0x800 > 0) result = result * 0x1000000000000058B90BFBE8E7BDCBE2E >> 128; if (x & 0x400 > 0) result = result * 0x100000000000002C5C85FDF473DEA871F >> 128; if (x & 0x200 > 0) result = result * 0x10000000000000162E42FEFA39EF44D91 >> 128; if (x & 0x100 > 0) result = result * 0x100000000000000B17217F7D1CF79E949 >> 128; if (x & 0x80 > 0) result = result * 0x10000000000000058B90BFBE8E7BCE544 >> 128; if (x & 0x40 > 0) result = result * 0x1000000000000002C5C85FDF473DE6ECA >> 128; if (x & 0x20 > 0) result = result * 0x100000000000000162E42FEFA39EF366F >> 128; if (x & 0x10 > 0) result = result * 0x1000000000000000B17217F7D1CF79AFA >> 128; if (x & 0x8 > 0) result = result * 0x100000000000000058B90BFBE8E7BCD6D >> 128; if (x & 0x4 > 0) result = result * 0x10000000000000002C5C85FDF473DE6B2 >> 128; if (x & 0x2 > 0) result = result * 0x1000000000000000162E42FEFA39EF358 >> 128; if (x & 0x1 > 0) result = result * 0x10000000000000000B17217F7D1CF79AB >> 128; result >>= uint256 (int256 (63 - (x >> 64))); require (result <= uint256 (int256 (MAX_64x64))); return int128 (int256 (result)); } } /** * Calculate natural exponent of x. Revert on overflow. * * @param x signed 64.64-bit fixed point number * @return signed 64.64-bit fixed point number */ function exp (int128 x) internal pure returns (int128) { unchecked { require (x < 0x400000000000000000); // Overflow if (x < -0x400000000000000000) return 0; // Underflow return exp_2 ( int128 (int256 (x) * 0x171547652B82FE1777D0FFDA0D23A7D12 >> 128)); } } /** * Calculate x / y rounding towards zero, where x and y are unsigned 256-bit * integer numbers. Revert on overflow or when y is zero. * * @param x unsigned 256-bit integer number * @param y unsigned 256-bit integer number * @return unsigned 64.64-bit fixed point number */ function divuu (uint256 x, uint256 y) private pure returns (uint128) { unchecked { require (y != 0); uint256 result; if (x <= 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF) result = (x << 64) / y; else { uint256 msb = 192; uint256 xc = x >> 192; if (xc >= 0x100000000) { xc >>= 32; msb += 32; } if (xc >= 0x10000) { xc >>= 16; msb += 16; } if (xc >= 0x100) { xc >>= 8; msb += 8; } if (xc >= 0x10) { xc >>= 4; msb += 4; } if (xc >= 0x4) { xc >>= 2; msb += 2; } if (xc >= 0x2) msb += 1; // No need to shift xc anymore result = (x << 255 - msb) / ((y - 1 >> msb - 191) + 1); require (result <= 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF); uint256 hi = result * (y >> 128); uint256 lo = result * (y & 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF); uint256 xh = x >> 192; uint256 xl = x << 64; if (xl < lo) xh -= 1; xl -= lo; // We rely on overflow behavior here lo = hi << 128; if (xl < lo) xh -= 1; xl -= lo; // We rely on overflow behavior here assert (xh == hi >> 128); result += xl / y; } require (result <= 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF); return uint128 (result); } } /** * Calculate sqrt (x) rounding down, where x is unsigned 256-bit integer * number. * * @param x unsigned 256-bit integer number * @return unsigned 128-bit integer number */ function sqrtu (uint256 x) private pure returns (uint128) { unchecked { if (x == 0) return 0; else { uint256 xx = x; uint256 r = 1; if (xx >= 0x100000000000000000000000000000000) { xx >>= 128; r <<= 64; } if (xx >= 0x10000000000000000) { xx >>= 64; r <<= 32; } if (xx >= 0x100000000) { xx >>= 32; r <<= 16; } if (xx >= 0x10000) { xx >>= 16; r <<= 8; } if (xx >= 0x100) { xx >>= 8; r <<= 4; } if (xx >= 0x10) { xx >>= 4; r <<= 2; } if (xx >= 0x8) { r <<= 1; } r = (r + x / r) >> 1; r = (r + x / r) >> 1; r = (r + x / r) >> 1; r = (r + x / r) >> 1; r = (r + x / r) >> 1; r = (r + x / r) >> 1; r = (r + x / r) >> 1; // Seven iterations should be enough uint256 r1 = x / r; return uint128 (r < r1 ? r : r1); } } } }
// SPDX-License-Identifier: BUSL-1.1 // For further clarification please see https://license.premia.legal pragma solidity ^0.8.0; import {ABDKMath64x64} from "abdk-libraries-solidity/ABDKMath64x64.sol"; library OptionMath { using ABDKMath64x64 for int128; struct QuoteArgs { int128 varianceAnnualized64x64; // 64x64 fixed point representation of annualized variance int128 strike64x64; // 64x64 fixed point representation of strike price int128 spot64x64; // 64x64 fixed point representation of spot price int128 timeToMaturity64x64; // 64x64 fixed point representation of duration of option contract (in years) int128 oldCLevel64x64; // 64x64 fixed point representation of C-Level of Pool before purchase int128 oldPoolState; // 64x64 fixed point representation of current state of the pool int128 newPoolState; // 64x64 fixed point representation of state of the pool after trade int128 steepness64x64; // 64x64 fixed point representation of Pool state delta multiplier int128 minAPY64x64; // 64x64 fixed point representation of minimum APY for capital locked up to underwrite options bool isCall; // whether to price "call" or "put" option } struct CalculateCLevelDecayArgs { int128 timeIntervalsElapsed64x64; // 64x64 fixed point representation of quantity of discrete arbitrary intervals elapsed since last update int128 oldCLevel64x64; // 64x64 fixed point representation of C-Level prior to accounting for decay int128 utilization64x64; // 64x64 fixed point representation of pool capital utilization rate int128 utilizationLowerBound64x64; int128 utilizationUpperBound64x64; int128 cLevelLowerBound64x64; int128 cLevelUpperBound64x64; int128 cConvergenceULowerBound64x64; int128 cConvergenceUUpperBound64x64; } // 64x64 fixed point integer constants int128 internal constant ONE_64x64 = 0x10000000000000000; int128 internal constant THREE_64x64 = 0x30000000000000000; // 64x64 fixed point constants used in Choudhury’s approximation of the Black-Scholes CDF int128 private constant CDF_CONST_0 = 0x09109f285df452394; // 2260 / 3989 int128 private constant CDF_CONST_1 = 0x19abac0ea1da65036; // 6400 / 3989 int128 private constant CDF_CONST_2 = 0x0d3c84b78b749bd6b; // 3300 / 3989 /** * @notice recalculate C-Level based on change in liquidity * @param initialCLevel64x64 64x64 fixed point representation of C-Level of Pool before update * @param oldPoolState64x64 64x64 fixed point representation of liquidity in pool before update * @param newPoolState64x64 64x64 fixed point representation of liquidity in pool after update * @param steepness64x64 64x64 fixed point representation of steepness coefficient * @return 64x64 fixed point representation of new C-Level */ function calculateCLevel( int128 initialCLevel64x64, int128 oldPoolState64x64, int128 newPoolState64x64, int128 steepness64x64 ) external pure returns (int128) { return newPoolState64x64 .sub(oldPoolState64x64) .div( oldPoolState64x64 > newPoolState64x64 ? oldPoolState64x64 : newPoolState64x64 ) .mul(steepness64x64) .neg() .exp() .mul(initialCLevel64x64); } /** * @notice calculate the price of an option using the Premia Finance model * @param args arguments of quotePrice * @return premiaPrice64x64 64x64 fixed point representation of Premia option price * @return cLevel64x64 64x64 fixed point representation of C-Level of Pool after purchase */ function quotePrice(QuoteArgs memory args) external pure returns ( int128 premiaPrice64x64, int128 cLevel64x64, int128 slippageCoefficient64x64 ) { int128 deltaPoolState64x64 = args .newPoolState .sub(args.oldPoolState) .div(args.oldPoolState) .mul(args.steepness64x64); int128 tradingDelta64x64 = deltaPoolState64x64.neg().exp(); int128 blackScholesPrice64x64 = _blackScholesPrice( args.varianceAnnualized64x64, args.strike64x64, args.spot64x64, args.timeToMaturity64x64, args.isCall ); cLevel64x64 = tradingDelta64x64.mul(args.oldCLevel64x64); slippageCoefficient64x64 = ONE_64x64.sub(tradingDelta64x64).div( deltaPoolState64x64 ); premiaPrice64x64 = blackScholesPrice64x64.mul(cLevel64x64).mul( slippageCoefficient64x64 ); int128 intrinsicValue64x64; if (args.isCall && args.strike64x64 < args.spot64x64) { intrinsicValue64x64 = args.spot64x64.sub(args.strike64x64); } else if (!args.isCall && args.strike64x64 > args.spot64x64) { intrinsicValue64x64 = args.strike64x64.sub(args.spot64x64); } int128 collateralValue64x64 = args.isCall ? args.spot64x64 : args.strike64x64; int128 minPrice64x64 = intrinsicValue64x64.add( collateralValue64x64.mul(args.minAPY64x64).mul( args.timeToMaturity64x64 ) ); if (minPrice64x64 > premiaPrice64x64) { premiaPrice64x64 = minPrice64x64; } } /** * @notice calculate the decay of C-Level based on heat diffusion function * @param args structured CalculateCLevelDecayArgs * @return cLevelDecayed64x64 C-Level after accounting for decay */ function calculateCLevelDecay(CalculateCLevelDecayArgs memory args) external pure returns (int128 cLevelDecayed64x64) { int128 convFHighU64x64 = (args.utilization64x64 >= args.utilizationUpperBound64x64 && args.oldCLevel64x64 <= args.cLevelLowerBound64x64) ? ONE_64x64 : int128(0); int128 convFLowU64x64 = (args.utilization64x64 <= args.utilizationLowerBound64x64 && args.oldCLevel64x64 >= args.cLevelUpperBound64x64) ? ONE_64x64 : int128(0); cLevelDecayed64x64 = args .oldCLevel64x64 .sub(args.cConvergenceULowerBound64x64.mul(convFLowU64x64)) .sub(args.cConvergenceUUpperBound64x64.mul(convFHighU64x64)) .mul( convFLowU64x64 .mul(ONE_64x64.sub(args.utilization64x64)) .add(convFHighU64x64.mul(args.utilization64x64)) .mul(args.timeIntervalsElapsed64x64) .neg() .exp() ) .add( args.cConvergenceULowerBound64x64.mul(convFLowU64x64).add( args.cConvergenceUUpperBound64x64.mul(convFHighU64x64) ) ); } /** * @notice calculate the exponential decay coefficient for a given interval * @param oldTimestamp timestamp of previous update * @param newTimestamp current timestamp * @return 64x64 fixed point representation of exponential decay coefficient */ function _decay(uint256 oldTimestamp, uint256 newTimestamp) internal pure returns (int128) { return ONE_64x64.sub( (-ABDKMath64x64.divu(newTimestamp - oldTimestamp, 7 days)).exp() ); } /** * @notice calculate Choudhury’s approximation of the Black-Scholes CDF * @param input64x64 64x64 fixed point representation of random variable * @return 64x64 fixed point representation of the approximated CDF of x */ function _N(int128 input64x64) internal pure returns (int128) { // squaring via mul is cheaper than via pow int128 inputSquared64x64 = input64x64.mul(input64x64); int128 value64x64 = (-inputSquared64x64 >> 1).exp().div( CDF_CONST_0.add(CDF_CONST_1.mul(input64x64.abs())).add( CDF_CONST_2.mul(inputSquared64x64.add(THREE_64x64).sqrt()) ) ); return input64x64 > 0 ? ONE_64x64.sub(value64x64) : value64x64; } /** * @notice calculate the price of an option using the Black-Scholes model * @param varianceAnnualized64x64 64x64 fixed point representation of annualized variance * @param strike64x64 64x64 fixed point representation of strike price * @param spot64x64 64x64 fixed point representation of spot price * @param timeToMaturity64x64 64x64 fixed point representation of duration of option contract (in years) * @param isCall whether to price "call" or "put" option * @return 64x64 fixed point representation of Black-Scholes option price */ function _blackScholesPrice( int128 varianceAnnualized64x64, int128 strike64x64, int128 spot64x64, int128 timeToMaturity64x64, bool isCall ) internal pure returns (int128) { int128 cumulativeVariance64x64 = timeToMaturity64x64.mul( varianceAnnualized64x64 ); int128 cumulativeVarianceSqrt64x64 = cumulativeVariance64x64.sqrt(); int128 d1_64x64 = spot64x64 .div(strike64x64) .ln() .add(cumulativeVariance64x64 >> 1) .div(cumulativeVarianceSqrt64x64); int128 d2_64x64 = d1_64x64.sub(cumulativeVarianceSqrt64x64); if (isCall) { return spot64x64.mul(_N(d1_64x64)).sub(strike64x64.mul(_N(d2_64x64))); } else { return -spot64x64.mul(_N(-d1_64x64)).sub( strike64x64.mul(_N(-d2_64x64)) ); } } }
// SPDX-License-Identifier: MIT pragma solidity ^0.8.0; /** * @title Set implementation with enumeration functions * @dev derived from https://github.com/OpenZeppelin/openzeppelin-contracts (MIT license) */ library EnumerableSet { struct Set { bytes32[] _values; // 1-indexed to allow 0 to signify nonexistence mapping(bytes32 => uint256) _indexes; } struct Bytes32Set { Set _inner; } struct AddressSet { Set _inner; } struct UintSet { Set _inner; } function at(Bytes32Set storage set, uint256 index) internal view returns (bytes32) { return _at(set._inner, index); } function at(AddressSet storage set, uint256 index) internal view returns (address) { return address(uint160(uint256(_at(set._inner, index)))); } function at(UintSet storage set, uint256 index) internal view returns (uint256) { return uint256(_at(set._inner, index)); } function contains(Bytes32Set storage set, bytes32 value) internal view returns (bool) { return _contains(set._inner, value); } function contains(AddressSet storage set, address value) internal view returns (bool) { return _contains(set._inner, bytes32(uint256(uint160(value)))); } function contains(UintSet storage set, uint256 value) internal view returns (bool) { return _contains(set._inner, bytes32(value)); } function indexOf(Bytes32Set storage set, bytes32 value) internal view returns (uint256) { return _indexOf(set._inner, value); } function indexOf(AddressSet storage set, address value) internal view returns (uint256) { return _indexOf(set._inner, bytes32(uint256(uint160(value)))); } function indexOf(UintSet storage set, uint256 value) internal view returns (uint256) { return _indexOf(set._inner, bytes32(value)); } function length(Bytes32Set storage set) internal view returns (uint256) { return _length(set._inner); } function length(AddressSet storage set) internal view returns (uint256) { return _length(set._inner); } function length(UintSet storage set) internal view returns (uint256) { return _length(set._inner); } function add(Bytes32Set storage set, bytes32 value) internal returns (bool) { return _add(set._inner, value); } function add(AddressSet storage set, address value) internal returns (bool) { return _add(set._inner, bytes32(uint256(uint160(value)))); } function add(UintSet storage set, uint256 value) internal returns (bool) { return _add(set._inner, bytes32(value)); } function remove(Bytes32Set storage set, bytes32 value) internal returns (bool) { return _remove(set._inner, value); } function remove(AddressSet storage set, address value) internal returns (bool) { return _remove(set._inner, bytes32(uint256(uint160(value)))); } function remove(UintSet storage set, uint256 value) internal returns (bool) { return _remove(set._inner, bytes32(value)); } function _at(Set storage set, uint256 index) private view returns (bytes32) { require( set._values.length > index, 'EnumerableSet: index out of bounds' ); return set._values[index]; } function _contains(Set storage set, bytes32 value) private view returns (bool) { return set._indexes[value] != 0; } function _indexOf(Set storage set, bytes32 value) private view returns (uint256) { unchecked { return set._indexes[value] - 1; } } function _length(Set storage set) private view returns (uint256) { return set._values.length; } function _add(Set storage set, bytes32 value) private returns (bool) { if (!_contains(set, value)) { set._values.push(value); set._indexes[value] = set._values.length; return true; } else { return false; } } function _remove(Set storage set, bytes32 value) private returns (bool) { uint256 valueIndex = set._indexes[value]; if (valueIndex != 0) { uint256 index = valueIndex - 1; bytes32 last = set._values[set._values.length - 1]; // move last value to now-vacant index set._values[index] = last; set._indexes[last] = index + 1; // clear last index set._values.pop(); delete set._indexes[value]; return true; } else { return false; } } }
{ "optimizer": { "enabled": true, "runs": 200 }, "outputSelection": { "*": { "*": [ "evm.bytecode", "evm.deployedBytecode", "devdoc", "userdoc", "metadata", "abi" ] } }, "libraries": {} }
Contract Security Audit
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[{"inputs":[{"internalType":"address","name":"diamond","type":"address"},{"internalType":"address","name":"base","type":"address"},{"internalType":"address","name":"underlying","type":"address"},{"internalType":"address","name":"baseOracle","type":"address"},{"internalType":"address","name":"underlyingOracle","type":"address"},{"internalType":"int128","name":"baseMinimum64x64","type":"int128"},{"internalType":"int128","name":"underlyingMinimum64x64","type":"int128"},{"internalType":"int128","name":"basePoolCap64x64","type":"int128"},{"internalType":"int128","name":"underlyingPoolCap64x64","type":"int128"},{"internalType":"int128","name":"initialCLevel64x64","type":"int128"},{"internalType":"int128","name":"initialSteepness64x64","type":"int128"}],"stateMutability":"nonpayable","type":"constructor"},{"stateMutability":"payable","type":"fallback"}]
Contract Creation Code
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Deployed Bytecode
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60045260246000fdfea264697066735822122058c06ac61f09b2e3004450aca37ba962c29cc0da5cc3de2630351ea57eddeccb64736f6c63430008090033
Constructor Arguments (ABI-Encoded and is the last bytes of the Contract Creation Code above)
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
-----Decoded View---------------
Arg [0] : diamond (address): 0x48D49466CB2EFbF05FaA5fa5E69f2984eDC8d1D7
Arg [1] : base (address): 0x6B175474E89094C44Da98b954EedeAC495271d0F
Arg [2] : underlying (address): 0xC02aaA39b223FE8D0A0e5C4F27eAD9083C756Cc2
Arg [3] : baseOracle (address): 0xAed0c38402a5d19df6E4c03F4E2DceD6e29c1ee9
Arg [4] : underlyingOracle (address): 0x5f4eC3Df9cbd43714FE2740f5E3616155c5b8419
Arg [5] : baseMinimum64x64 (int128): 3689348814741910323200
Arg [6] : underlyingMinimum64x64 (int128): 922337203685477580
Arg [7] : basePoolCap64x64 (int128): 184467440737095516160000
Arg [8] : underlyingPoolCap64x64 (int128): 46116860184273879040
Arg [9] : initialCLevel64x64 (int128): 50143449209799256683
Arg [10] : initialSteepness64x64 (int128): 9223372036854775808
-----Encoded View---------------
11 Constructor Arguments found :
Arg [0] : 00000000000000000000000048d49466cb2efbf05faa5fa5e69f2984edc8d1d7
Arg [1] : 0000000000000000000000006b175474e89094c44da98b954eedeac495271d0f
Arg [2] : 000000000000000000000000c02aaa39b223fe8d0a0e5c4f27ead9083c756cc2
Arg [3] : 000000000000000000000000aed0c38402a5d19df6e4c03f4e2dced6e29c1ee9
Arg [4] : 0000000000000000000000005f4ec3df9cbd43714fe2740f5e3616155c5b8419
Arg [5] : 0000000000000000000000000000000000000000000000c80000000000000000
Arg [6] : 0000000000000000000000000000000000000000000000000ccccccccccccccc
Arg [7] : 0000000000000000000000000000000000000000000027100000000000000000
Arg [8] : 0000000000000000000000000000000000000000000000028000000000000000
Arg [9] : 000000000000000000000000000000000000000000000002b7e151628aed2a6b
Arg [10] : 0000000000000000000000000000000000000000000000008000000000000000
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